FREESCALE MKL04Z8VFK4

KL04 Sub-Family Reference Manual
Supports: MKL04Z8VFK4, MKL04Z16VFK4, MKL04Z32VFK4,
MKL04Z8VLC4, MKL04Z16VLC4, MKL04Z32VLC4, MKL04Z8VFM4,
MKL04Z16VFM4, MKL04Z32VFM4, MKL04Z16VLF4, and
MKL04Z32VLF4
Document Number: KL04P48M48SF1RM
Rev. 3.1, November 2012
KL04 Sub-Family Reference Manual, Rev. 3.1, November 2012
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Freescale Semiconductor, Inc.
Contents
Section number
Title
Page
Chapter 1
About This Document
1.1
1.2
Overview.......................................................................................................................................................................29
1.1.1
Purpose.........................................................................................................................................................29
1.1.2
Audience......................................................................................................................................................29
Conventions..................................................................................................................................................................29
1.2.1
Numbering systems......................................................................................................................................29
1.2.2
Typographic notation...................................................................................................................................30
1.2.3
Special terms................................................................................................................................................30
Chapter 2
Introduction
2.1
Overview.......................................................................................................................................................................31
2.2
Kinetis L Series.............................................................................................................................................................31
2.3
KL04 Sub-Family Introduction.....................................................................................................................................34
2.4
Module functional categories........................................................................................................................................35
2.5
2.4.1
ARM® Cortex™-M0+ Core Modules.........................................................................................................35
2.4.2
System Modules...........................................................................................................................................36
2.4.3
Memories and Memory Interfaces...............................................................................................................37
2.4.4
Clocks...........................................................................................................................................................37
2.4.5
Security and Integrity modules....................................................................................................................37
2.4.6
Analog modules...........................................................................................................................................38
2.4.7
Timer modules.............................................................................................................................................38
2.4.8
Communication interfaces...........................................................................................................................39
2.4.9
Human-machine interfaces..........................................................................................................................39
Orderable part numbers.................................................................................................................................................39
Chapter 3
Chip Configuration
3.1
Introduction...................................................................................................................................................................41
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Section number
3.2
3.3
3.4
3.5
3.6
Title
Page
Module to Module Interconnects..................................................................................................................................41
3.2.1
Module to Module Interconnects.................................................................................................................41
3.2.2
Analog reference options.............................................................................................................................43
Core Modules................................................................................................................................................................44
3.3.1
ARM Cortex-M0+ Core Configuration.......................................................................................................44
3.3.2
Nested Vectored Interrupt Controller (NVIC) Configuration......................................................................46
3.3.3
Asynchronous wake-up interrupt controller (AWIC) configuration............................................................50
System Modules............................................................................................................................................................51
3.4.1
SIM Configuration.......................................................................................................................................51
3.4.2
System Mode Controller (SMC) Configuration...........................................................................................52
3.4.3
PMC Configuration......................................................................................................................................52
3.4.4
Low-Leakage Wake-up Unit (LLWU) Configuration.................................................................................53
3.4.5
MCM Configuration....................................................................................................................................55
3.4.6
Crossbar-Light Switch Configuration..........................................................................................................56
3.4.7
Peripheral Bridge Configuration..................................................................................................................57
3.4.8
DMA request multiplexer configuration......................................................................................................58
3.4.9
DMA Controller Configuration...................................................................................................................61
3.4.10
Computer Operating Properly (COP) Watchdog Configuration..................................................................61
Clock Modules..............................................................................................................................................................64
3.5.1
MCG Configuration.....................................................................................................................................64
3.5.2
OSC Configuration......................................................................................................................................65
Memories and Memory Interfaces................................................................................................................................66
3.6.1
Flash Memory Configuration.......................................................................................................................66
3.6.2
Flash Memory Controller Configuration.....................................................................................................68
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Section number
3.6.3
3.7
3.8
3.9
3.10
Title
Page
SRAM Configuration...................................................................................................................................69
Analog...........................................................................................................................................................................71
3.7.1
12-bit SAR ADC Configuration..................................................................................................................71
3.7.2
CMP Configuration......................................................................................................................................75
Timers...........................................................................................................................................................................77
3.8.1
Timer/PWM Module Configuration............................................................................................................77
3.8.2
PIT Configuration........................................................................................................................................79
3.8.3
Low-power timer configuration...................................................................................................................81
3.8.4
RTC configuration.......................................................................................................................................82
Communication interfaces............................................................................................................................................84
3.9.1
SPI configuration.........................................................................................................................................84
3.9.2
I2C Configuration........................................................................................................................................85
3.9.3
UART Configuration...................................................................................................................................85
Human-machine interfaces (HMI)................................................................................................................................87
3.10.1
GPIO Configuration.....................................................................................................................................87
Chapter 4
Memory Map
4.1
Introduction...................................................................................................................................................................91
4.2
System memory map.....................................................................................................................................................91
4.3
Flash Memory Map.......................................................................................................................................................92
4.3.1
Alternate Non-Volatile IRC User Trim Description....................................................................................92
4.4
SRAM memory map.....................................................................................................................................................93
4.5
Bit Manipulation Engine...............................................................................................................................................93
4.6
Peripheral bridge (AIPS-Lite) memory map.................................................................................................................94
4.7
4.6.1
Read-after-write sequence and required serialization of memory operations..............................................94
4.6.2
Peripheral Bridge (AIPS-Lite) Memory Map..............................................................................................95
4.6.3
Modules Restricted Access in User Mode...................................................................................................98
Private Peripheral Bus (PPB) memory map..................................................................................................................98
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Section number
Title
Page
Chapter 5
Clock Distribution
5.1
Introduction...................................................................................................................................................................101
5.2
Programming model......................................................................................................................................................101
5.3
High-Level device clocking diagram............................................................................................................................101
5.4
Clock definitions...........................................................................................................................................................102
5.4.1
5.5
Device clock summary.................................................................................................................................103
Internal clocking requirements.....................................................................................................................................105
5.5.1
Clock divider values after reset....................................................................................................................105
5.5.2
VLPR mode clocking...................................................................................................................................106
5.6
Clock Gating.................................................................................................................................................................106
5.7
Module clocks...............................................................................................................................................................106
5.7.1
PMC 1-kHz LPO clock................................................................................................................................107
5.7.2
COP clocking...............................................................................................................................................108
5.7.3
RTC clocking...............................................................................................................................................108
5.7.4
LPTMR clocking..........................................................................................................................................109
5.7.5
TPM clocking...............................................................................................................................................109
5.7.6
UART clocking............................................................................................................................................110
Chapter 6
Reset and Boot
6.1
Introduction...................................................................................................................................................................111
6.2
Reset..............................................................................................................................................................................111
6.3
6.2.1
Power-on reset (POR)..................................................................................................................................112
6.2.2
System reset sources....................................................................................................................................112
6.2.3
MCU Resets.................................................................................................................................................115
6.2.4
Reset Pin .....................................................................................................................................................116
6.2.5
Debug resets.................................................................................................................................................117
Boot...............................................................................................................................................................................118
6.3.1
Boot sources.................................................................................................................................................118
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Section number
Title
Page
6.3.2
FOPT boot options.......................................................................................................................................118
6.3.3
Boot sequence..............................................................................................................................................119
Chapter 7
Power Management
7.1
Introduction...................................................................................................................................................................121
7.2
Clocking Modes............................................................................................................................................................121
7.2.1
Partial Stop...................................................................................................................................................121
7.2.2
DMA Wakeup..............................................................................................................................................122
7.2.3
Compute Operation......................................................................................................................................123
7.2.4
Peripheral Doze............................................................................................................................................124
7.2.5
Clock Gating................................................................................................................................................125
7.3
Power modes.................................................................................................................................................................125
7.4
Entering and exiting power modes...............................................................................................................................127
7.5
Module Operation in Low Power Modes......................................................................................................................127
Chapter 8
Security
8.1
Introduction...................................................................................................................................................................131
8.2
Flash Security...............................................................................................................................................................131
8.3
Security Interactions with other Modules.....................................................................................................................131
8.3.1
Security Interactions with Debug.................................................................................................................132
Chapter 9
Debug
9.1
Introduction...................................................................................................................................................................133
9.2
Debug Port Pin Descriptions.........................................................................................................................................133
9.3
SWD status and control registers..................................................................................................................................134
9.3.1
MDM-AP Control Register..........................................................................................................................135
9.3.2
MDM-AP Status Register............................................................................................................................136
9.4
Debug Resets................................................................................................................................................................138
9.5
Micro Trace Buffer (MTB)...........................................................................................................................................139
9.6
Debug in Low Power Modes........................................................................................................................................139
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Section number
9.7
Title
Page
Debug & Security.........................................................................................................................................................139
Chapter 10
Signal Multiplexing and Signal Descriptions
10.1
Introduction...................................................................................................................................................................141
10.2
Signal Multiplexing Integration....................................................................................................................................141
10.3
10.4
10.2.1
Port control and interrupt module features..................................................................................................142
10.2.2
Clock gating.................................................................................................................................................143
10.2.3
Signal multiplexing constraints....................................................................................................................143
Pinout............................................................................................................................................................................143
10.3.1
KL04 signal multiplexing and pin assignments...........................................................................................143
10.3.2
KL04 Pinouts...............................................................................................................................................145
Module Signal Description Tables................................................................................................................................149
10.4.1
Core Modules...............................................................................................................................................149
10.4.2
System Modules...........................................................................................................................................150
10.4.3
Clock Modules.............................................................................................................................................150
10.4.4
Memories and Memory Interfaces...............................................................................................................150
10.4.5
Analog..........................................................................................................................................................150
10.4.6
Timer Modules.............................................................................................................................................151
10.4.7
Communication Interfaces...........................................................................................................................152
10.4.8
Human-Machine Interfaces (HMI)..............................................................................................................152
Chapter 11
Port control and interrupts (PORT)
11.1
Introduction...................................................................................................................................................................153
11.2
Overview.......................................................................................................................................................................153
11.2.1
Features........................................................................................................................................................153
11.2.2
Modes of operation......................................................................................................................................154
11.3
External signal description............................................................................................................................................154
11.4
Detailed signal description............................................................................................................................................155
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11.5
11.6
Title
Page
Memory map and register definition.............................................................................................................................155
11.5.1
Pin Control Register n (PORTx_PCRn).......................................................................................................158
11.5.2
Global Pin Control Low Register (PORTx_GPCLR)..................................................................................160
11.5.3
Global Pin Control High Register (PORTx_GPCHR).................................................................................161
11.5.4
Interrupt Status Flag Register (PORTx_ISFR)............................................................................................161
Functional description...................................................................................................................................................162
11.6.1
Pin control....................................................................................................................................................162
11.6.2
Global pin control........................................................................................................................................163
11.6.3
External interrupts........................................................................................................................................163
Chapter 12
System integration module (SIM)
12.1
Introduction...................................................................................................................................................................165
12.1.1
12.2
Features........................................................................................................................................................165
Memory map and register definition.............................................................................................................................165
12.2.1
System Options Register 1 (SIM_SOPT1)..................................................................................................167
12.2.2
SOPT1 Configuration Register (SIM_SOPT1CFG)....................................................................................167
12.2.3
System Options Register 2 (SIM_SOPT2)..................................................................................................168
12.2.4
System Options Register 4 (SIM_SOPT4)..................................................................................................170
12.2.5
System Options Register 5 (SIM_SOPT5)..................................................................................................171
12.2.6
System Options Register 7 (SIM_SOPT7)..................................................................................................172
12.2.7
System Device Identification Register (SIM_SDID)...................................................................................174
12.2.8
System Clock Gating Control Register 4 (SIM_SCGC4)............................................................................176
12.2.9
System Clock Gating Control Register 5 (SIM_SCGC5)............................................................................177
12.2.10
System Clock Gating Control Register 6 (SIM_SCGC6)............................................................................179
12.2.11
System Clock Gating Control Register 7 (SIM_SCGC7)............................................................................180
12.2.12
System Clock Divider Register 1 (SIM_CLKDIV1)...................................................................................181
12.2.13
Flash Configuration Register 1 (SIM_FCFG1)...........................................................................................183
12.2.14
Flash Configuration Register 2 (SIM_FCFG2)...........................................................................................184
12.2.15
Unique Identification Register Mid-High (SIM_UIDMH)..........................................................................185
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Section number
12.3
Title
Page
12.2.16
Unique Identification Register Mid Low (SIM_UIDML)...........................................................................185
12.2.17
Unique Identification Register Low (SIM_UIDL)......................................................................................186
12.2.18
COP Control Register (SIM_COPC)...........................................................................................................186
12.2.19
Service COP Register (SIM_SRVCOP)......................................................................................................187
Functional description...................................................................................................................................................188
Chapter 13
System Mode Controller (SMC)
13.1
Introduction...................................................................................................................................................................189
13.2
Modes of operation.......................................................................................................................................................189
13.3
Memory map and register descriptions.........................................................................................................................191
13.4
13.3.1
Power Mode Protection register (SMC_PMPROT).....................................................................................191
13.3.2
Power Mode Control register (SMC_PMCTRL).........................................................................................193
13.3.3
Stop Control Register (SMC_STOPCTRL).................................................................................................194
13.3.4
Power Mode Status register (SMC_PMSTAT)...........................................................................................195
Functional description...................................................................................................................................................196
13.4.1
Power mode transitions................................................................................................................................196
13.4.2
Power mode entry/exit sequencing..............................................................................................................199
13.4.3
Run modes....................................................................................................................................................201
13.4.4
Wait modes..................................................................................................................................................203
13.4.5
Stop modes...................................................................................................................................................204
13.4.6
Debug in low power modes.........................................................................................................................207
Chapter 14
Power Management Controller (PMC)
14.1
Introduction...................................................................................................................................................................209
14.2
Features.........................................................................................................................................................................209
14.3
Low-voltage detect (LVD) system................................................................................................................................209
14.3.1
LVD reset operation.....................................................................................................................................210
14.3.2
LVD interrupt operation...............................................................................................................................210
14.3.3
Low-voltage warning (LVW) interrupt operation.......................................................................................210
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Section number
Title
Page
14.4
I/O retention..................................................................................................................................................................211
14.5
Memory map and register descriptions.........................................................................................................................211
14.5.1
Low Voltage Detect Status And Control 1 register (PMC_LVDSC1)........................................................212
14.5.2
Low Voltage Detect Status And Control 2 register (PMC_LVDSC2)........................................................213
14.5.3
Regulator Status And Control register (PMC_REGSC)..............................................................................214
Chapter 15
Low-Leakage Wakeup Unit (LLWU)
15.1
Introduction...................................................................................................................................................................217
15.1.1
Features........................................................................................................................................................217
15.1.2
Modes of operation......................................................................................................................................218
15.1.3
Block diagram..............................................................................................................................................219
15.2
LLWU signal descriptions............................................................................................................................................220
15.3
Memory map/register definition...................................................................................................................................220
15.4
15.3.1
LLWU Pin Enable 1 register (LLWU_PE1)................................................................................................221
15.3.2
LLWU Pin Enable 2 register (LLWU_PE2)................................................................................................222
15.3.3
LLWU Module Enable register (LLWU_ME)............................................................................................223
15.3.4
LLWU Flag 1 register (LLWU_F1).............................................................................................................225
15.3.5
LLWU Flag 3 register (LLWU_F3).............................................................................................................226
15.3.6
LLWU Pin Filter 1 register (LLWU_FILT1)..............................................................................................228
15.3.7
LLWU Pin Filter 2 register (LLWU_FILT2)..............................................................................................229
Functional description...................................................................................................................................................230
15.4.1
LLS mode.....................................................................................................................................................231
15.4.2
VLLS modes................................................................................................................................................231
15.4.3
Initialization.................................................................................................................................................231
Chapter 16
Reset Control Module (RCM)
16.1
Introduction...................................................................................................................................................................233
16.2
Reset memory map and register descriptions...............................................................................................................233
16.2.1
System Reset Status Register 0 (RCM_SRS0)............................................................................................233
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16.2.2
System Reset Status Register 1 (RCM_SRS1)............................................................................................235
16.2.3
Reset Pin Filter Control register (RCM_RPFC)..........................................................................................236
16.2.4
Reset Pin Filter Width register (RCM_RPFW)...........................................................................................237
Chapter 17
Bit Manipulation Engine (BME)
17.1
Introduction...................................................................................................................................................................239
17.1.1
Overview......................................................................................................................................................240
17.1.2
Features........................................................................................................................................................240
17.1.3
Modes of Operation.....................................................................................................................................241
17.2
External Signal Description..........................................................................................................................................241
17.3
Memory Map and Register Definition..........................................................................................................................242
17.4
Functional Description..................................................................................................................................................242
17.5
17.4.1
BME Decorated Stores.................................................................................................................................242
17.4.2
BME Decorated Loads.................................................................................................................................248
17.4.3
Additional Details on Decorated Addresses and GPIO Accesses................................................................255
Application Information................................................................................................................................................256
Chapter 18
Miscellaneous Control Module (MCM)
18.1
Introduction...................................................................................................................................................................259
18.1.1
18.2
Features........................................................................................................................................................259
Memory map/register descriptions...............................................................................................................................259
18.2.1
Crossbar Switch (AXBS) Slave Configuration (MCM_PLASC)................................................................260
18.2.2
Crossbar Switch (AXBS) Master Configuration (MCM_PLAMC)............................................................261
18.2.3
Platform Control Register (MCM_PLACR)................................................................................................261
18.2.4
Compute Operation Control Register (MCM_CPO)...................................................................................264
Chapter 19
Micro Trace Buffer (MTB)
19.1
Introduction...................................................................................................................................................................267
19.1.1
Overview......................................................................................................................................................267
19.1.2
Features........................................................................................................................................................270
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Section number
19.1.3
Title
Page
Modes of Operation.....................................................................................................................................271
19.2
External Signal Description..........................................................................................................................................271
19.3
Memory Map and Register Definition..........................................................................................................................272
19.3.1
MTB_RAM Memory Map...........................................................................................................................272
19.3.2
MTB_DWT Memory Map...........................................................................................................................285
19.3.3
System ROM Memory Map.........................................................................................................................295
Chapter 20
Crossbar Switch Lite (AXBS-Lite)
20.1
Introduction...................................................................................................................................................................301
20.1.1
Features........................................................................................................................................................301
20.2
Memory Map / Register Definition...............................................................................................................................301
20.3
Functional Description..................................................................................................................................................302
20.4
20.3.1
General operation.........................................................................................................................................302
20.3.2
Arbitration....................................................................................................................................................303
Initialization/application information...........................................................................................................................304
Chapter 21
Peripheral Bridge (AIPS-Lite)
21.1
21.2
Introduction...................................................................................................................................................................305
21.1.1
Features........................................................................................................................................................305
21.1.2
General operation.........................................................................................................................................305
Functional description...................................................................................................................................................306
21.2.1
Access support.............................................................................................................................................306
Chapter 22
Direct Memory Access Multiplexer (DMAMUX)
22.1
22.2
Introduction...................................................................................................................................................................307
22.1.1
Overview......................................................................................................................................................307
22.1.2
Features........................................................................................................................................................308
22.1.3
Modes of operation......................................................................................................................................308
External signal description............................................................................................................................................309
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Section number
22.3
22.5
Page
Memory map/register definition...................................................................................................................................309
22.3.1
22.4
Title
Channel Configuration register (DMAMUXx_CHCFGn)..........................................................................309
Functional description...................................................................................................................................................310
22.4.1
DMA channels with periodic triggering capability......................................................................................311
22.4.2
DMA channels with no triggering capability...............................................................................................313
22.4.3
Always-enabled DMA sources....................................................................................................................313
Initialization/application information...........................................................................................................................314
22.5.1
Reset.............................................................................................................................................................314
22.5.2
Enabling and configuring sources................................................................................................................314
Chapter 23
DMA Controller Module
23.1
Introduction...................................................................................................................................................................319
23.1.1
Overview......................................................................................................................................................319
23.1.2
Features........................................................................................................................................................320
23.2
DMA Transfer Overview..............................................................................................................................................321
23.3
Memory Map and Registers..........................................................................................................................................322
23.4
23.3.1
Source Address Register (DMA_SARn).....................................................................................................323
23.3.2
Destination Address Register (DMA_DARn).............................................................................................324
23.3.3
DMA Status Register / Byte Count Register (DMA_DSR_BCRn).............................................................325
23.3.4
DMA Control Register (DMA_DCRn)........................................................................................................327
Functional Description..................................................................................................................................................331
23.4.1
Transfer Requests (Cycle-Steal and Continuous Modes)............................................................................331
23.4.2
Channel Initialization and Startup................................................................................................................331
23.4.3
Dual-Address Data Transfer Mode..............................................................................................................333
23.4.4
Advanced Data Transfer Controls: Auto-Alignment...................................................................................334
23.4.5
Termination..................................................................................................................................................335
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Section number
Title
Page
Chapter 24
Multipurpose Clock Generator (MCG)
24.1
Introduction...................................................................................................................................................................337
24.1.1
Features........................................................................................................................................................337
24.1.2
Modes of Operation.....................................................................................................................................339
24.2
External Signal Description..........................................................................................................................................340
24.3
Memory Map/Register Definition.................................................................................................................................340
24.4
24.5
24.3.1
MCG Control 1 Register (MCG_C1)...........................................................................................................340
24.3.2
MCG Control 2 Register (MCG_C2)...........................................................................................................342
24.3.3
MCG Control 3 Register (MCG_C3)...........................................................................................................343
24.3.4
MCG Control 4 Register (MCG_C4)...........................................................................................................343
24.3.5
MCG Control 6 Register (MCG_C6)...........................................................................................................345
24.3.6
MCG Status Register (MCG_S)..................................................................................................................345
24.3.7
MCG Status and Control Register (MCG_SC)............................................................................................346
24.3.8
MCG Auto Trim Compare Value High Register (MCG_ATCVH)............................................................348
24.3.9
MCG Auto Trim Compare Value Low Register (MCG_ATCVL)..............................................................348
Functional Description..................................................................................................................................................348
24.4.1
MCG mode state diagram............................................................................................................................348
24.4.2
Low Power Bit Usage..................................................................................................................................352
24.4.3
MCG Internal Reference Clocks..................................................................................................................352
24.4.4
External Reference Clock............................................................................................................................353
24.4.5
MCG Fixed frequency clock .......................................................................................................................353
24.4.6
MCG Auto TRIM (ATM)............................................................................................................................353
Initialization / Application information........................................................................................................................355
24.5.1
MCG module initialization sequence...........................................................................................................355
24.5.2
Using a 32.768 kHz reference......................................................................................................................357
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Section number
24.5.3
Title
Page
MCG mode switching..................................................................................................................................358
Chapter 25
Oscillator (OSC)
25.1
Introduction...................................................................................................................................................................365
25.2
Features and Modes......................................................................................................................................................365
25.3
Block Diagram..............................................................................................................................................................366
25.4
OSC Signal Descriptions..............................................................................................................................................366
25.5
External Crystal / Resonator Connections....................................................................................................................367
25.6
External Clock Connections.........................................................................................................................................368
25.7
Memory Map/Register Definitions...............................................................................................................................369
25.7.1
25.8
25.9
OSC Memory Map/Register Definition.......................................................................................................369
Functional Description..................................................................................................................................................370
25.8.1
OSC Module States......................................................................................................................................370
25.8.2
OSC Module Modes.....................................................................................................................................372
25.8.3
Counter.........................................................................................................................................................373
25.8.4
Reference Clock Pin Requirements.............................................................................................................373
Reset..............................................................................................................................................................................374
25.10 Low Power Modes Operation.......................................................................................................................................374
25.11 Interrupts.......................................................................................................................................................................374
Chapter 26
Flash Memory Controller (FMC)
26.1
Introduction...................................................................................................................................................................375
26.1.1
Overview......................................................................................................................................................375
26.1.2
Features........................................................................................................................................................375
26.2
Modes of operation.......................................................................................................................................................376
26.3
External signal description............................................................................................................................................376
26.4
Memory map and register descriptions.........................................................................................................................376
26.5
Functional description...................................................................................................................................................376
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Section number
Title
Page
Chapter 27
Flash Memory Module (FTFA)
27.1
Introduction...................................................................................................................................................................379
27.1.1
Features........................................................................................................................................................380
27.1.2
Block Diagram.............................................................................................................................................380
27.1.3
Glossary.......................................................................................................................................................381
27.2
External Signal Description..........................................................................................................................................382
27.3
Memory Map and Registers..........................................................................................................................................382
27.4
27.3.1
Flash Configuration Field Description.........................................................................................................382
27.3.2
Program Flash IFR Map...............................................................................................................................383
27.3.3
Register Descriptions...................................................................................................................................384
Functional Description..................................................................................................................................................392
27.4.1
Flash Protection............................................................................................................................................393
27.4.2
Interrupts......................................................................................................................................................393
27.4.3
Flash Operation in Low-Power Modes........................................................................................................394
27.4.4
Functional Modes of Operation...................................................................................................................394
27.4.5
Flash Reads and Ignored Writes..................................................................................................................394
27.4.6
Read While Write (RWW)...........................................................................................................................395
27.4.7
Flash Program and Erase..............................................................................................................................395
27.4.8
Flash Command Operations.........................................................................................................................395
27.4.9
Margin Read Commands.............................................................................................................................400
27.4.10
Flash Command Description........................................................................................................................401
27.4.11
Security........................................................................................................................................................414
27.4.12
Reset Sequence............................................................................................................................................416
Chapter 28
Analog-to-Digital Converter (ADC)
28.1
Introduction...................................................................................................................................................................417
28.1.1
Features........................................................................................................................................................417
28.1.2
Block diagram..............................................................................................................................................418
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Section number
28.2
28.3
28.4
Title
Page
ADC Signal Descriptions..............................................................................................................................................419
28.2.1
Analog Power (VDDA)...............................................................................................................................420
28.2.2
Analog Ground (VSSA)...............................................................................................................................420
28.2.3
Voltage Reference Select.............................................................................................................................420
28.2.4
Analog Channel Inputs (ADx).....................................................................................................................421
Register definition.........................................................................................................................................................421
28.3.1
ADC Status and Control Registers 1 (ADCx_SC1n)...................................................................................422
28.3.2
ADC Configuration Register 1 (ADCx_CFG1)...........................................................................................425
28.3.3
ADC Configuration Register 2 (ADCx_CFG2)...........................................................................................427
28.3.4
ADC Data Result Register (ADCx_Rn).......................................................................................................428
28.3.5
Compare Value Registers (ADCx_CVn).....................................................................................................429
28.3.6
Status and Control Register 2 (ADCx_SC2)................................................................................................430
28.3.7
Status and Control Register 3 (ADCx_SC3)................................................................................................432
28.3.8
ADC Offset Correction Register (ADCx_OFS)...........................................................................................433
28.3.9
ADC Plus-Side Gain Register (ADCx_PG).................................................................................................434
28.3.10
ADC Plus-Side General Calibration Value Register (ADCx_CLPD).........................................................434
28.3.11
ADC Plus-Side General Calibration Value Register (ADCx_CLPS)..........................................................435
28.3.12
ADC Plus-Side General Calibration Value Register (ADCx_CLP4)..........................................................435
28.3.13
ADC Plus-Side General Calibration Value Register (ADCx_CLP3)..........................................................436
28.3.14
ADC Plus-Side General Calibration Value Register (ADCx_CLP2)..........................................................436
28.3.15
ADC Plus-Side General Calibration Value Register (ADCx_CLP1)..........................................................437
28.3.16
ADC Plus-Side General Calibration Value Register (ADCx_CLP0)..........................................................437
Functional description...................................................................................................................................................438
28.4.1
Clock select and divide control....................................................................................................................438
28.4.2
Voltage reference selection..........................................................................................................................439
28.4.3
Hardware trigger and channel selects..........................................................................................................439
28.4.4
Conversion control.......................................................................................................................................440
28.4.5
Automatic compare function........................................................................................................................447
28.4.6
Calibration function.....................................................................................................................................449
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Section number
28.5
Page
28.4.7
User-defined offset function........................................................................................................................450
28.4.8
Temperature sensor......................................................................................................................................451
28.4.9
MCU wait mode operation...........................................................................................................................452
28.4.10
MCU Normal Stop mode operation.............................................................................................................452
28.4.11
MCU Low-Power Stop mode operation......................................................................................................453
Initialization information..............................................................................................................................................454
28.5.1
28.6
Title
ADC module initialization example............................................................................................................454
Application information................................................................................................................................................456
28.6.1
External pins and routing.............................................................................................................................456
28.6.2
Sources of error............................................................................................................................................458
Chapter 29
Comparator (CMP)
29.1
Introduction...................................................................................................................................................................463
29.2
CMP features................................................................................................................................................................463
29.3
6-bit DAC key features.................................................................................................................................................464
29.4
ANMUX key features...................................................................................................................................................465
29.5
CMP, DAC and ANMUX diagram...............................................................................................................................465
29.6
CMP block diagram......................................................................................................................................................466
29.7
Memory map/register definitions..................................................................................................................................468
29.8
29.7.1
CMP Control Register 0 (CMPx_CR0).......................................................................................................468
29.7.2
CMP Control Register 1 (CMPx_CR1).......................................................................................................469
29.7.3
CMP Filter Period Register (CMPx_FPR)...................................................................................................471
29.7.4
CMP Status and Control Register (CMPx_SCR).........................................................................................471
29.7.5
DAC Control Register (CMPx_DACCR)....................................................................................................472
29.7.6
MUX Control Register (CMPx_MUXCR)..................................................................................................473
Functional description...................................................................................................................................................474
29.8.1
CMP functional modes.................................................................................................................................474
29.8.2
Power modes................................................................................................................................................483
29.8.3
Startup and operation...................................................................................................................................484
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Section number
29.8.4
29.9
Title
Page
Low-pass filter.............................................................................................................................................484
CMP interrupts..............................................................................................................................................................487
29.10 DMA support................................................................................................................................................................487
29.11 CMP Asyncrhonous DMA support...............................................................................................................................487
29.12 Digital-to-analog converter...........................................................................................................................................488
29.13 DAC functional description..........................................................................................................................................488
29.13.1
Voltage reference source select....................................................................................................................488
29.14 DAC resets....................................................................................................................................................................489
29.15 DAC clocks...................................................................................................................................................................489
29.16 DAC interrupts..............................................................................................................................................................489
29.17 CMP Trigger Mode.......................................................................................................................................................489
Chapter 30
Timer/PWM Module (TPM)
30.1
30.2
30.3
Introduction...................................................................................................................................................................491
30.1.1
TPM Philosophy..........................................................................................................................................491
30.1.2
Features........................................................................................................................................................491
30.1.3
Modes of Operation.....................................................................................................................................492
30.1.4
Block Diagram.............................................................................................................................................492
TPM Signal Descriptions..............................................................................................................................................493
30.2.1
TPM_EXTCLK — TPM External Clock....................................................................................................493
30.2.2
TPM_CHn — TPM Channel (n) I/O Pin.....................................................................................................494
Memory Map and Register Definition..........................................................................................................................494
30.3.1
Status and Control (TPMx_SC)...................................................................................................................496
30.3.2
Counter (TPMx_CNT).................................................................................................................................497
30.3.3
Modulo (TPMx_MOD)................................................................................................................................498
30.3.4
Channel (n) Status and Control (TPMx_CnSC)...........................................................................................499
30.3.5
Channel (n) Value (TPMx_CnV).................................................................................................................501
30.3.6
Capture and Compare Status (TPMx_STATUS).........................................................................................501
30.3.7
Configuration (TPMx_CONF).....................................................................................................................503
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Section number
30.4
Title
Page
Functional Description..................................................................................................................................................505
30.4.1
Clock Domains.............................................................................................................................................505
30.4.2
Prescaler.......................................................................................................................................................506
30.4.3
Counter.........................................................................................................................................................506
30.4.4
Input Capture Mode.....................................................................................................................................508
30.4.5
Output Compare Mode.................................................................................................................................509
30.4.6
Edge-Aligned PWM (EPWM) Mode...........................................................................................................510
30.4.7
Center-Aligned PWM (CPWM) Mode........................................................................................................512
30.4.8
Registers Updated from Write Buffers........................................................................................................514
30.4.9
DMA............................................................................................................................................................514
30.4.10
Reset Overview............................................................................................................................................515
30.4.11
TPM Interrupts.............................................................................................................................................515
Chapter 31
Periodic Interrupt Timer (PIT-RTI)
31.1
Introduction...................................................................................................................................................................517
31.1.1
Block diagram..............................................................................................................................................517
31.1.2
Features........................................................................................................................................................518
31.2
Signal description..........................................................................................................................................................518
31.3
Memory map/register description.................................................................................................................................519
31.4
31.3.1
PIT Module Control Register (PIT_MCR)..................................................................................................519
31.3.2
PIT Upper Lifetime Timer Register (PIT_LTMR64H)...............................................................................521
31.3.3
PIT Lower Lifetime Timer Register (PIT_LTMR64L)...............................................................................521
31.3.4
Timer Load Value Register (PIT_LDVALn)...............................................................................................522
31.3.5
Current Timer Value Register (PIT_CVALn).............................................................................................522
31.3.6
Timer Control Register (PIT_TCTRLn)......................................................................................................523
31.3.7
Timer Flag Register (PIT_TFLGn)..............................................................................................................524
Functional description...................................................................................................................................................524
31.4.1
General operation.........................................................................................................................................524
31.4.2
Interrupts......................................................................................................................................................526
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Section number
31.4.3
Title
Page
Chained timers.............................................................................................................................................526
31.5
Initialization and application information.....................................................................................................................526
31.6
Example configuration for chained timers....................................................................................................................527
31.7
Example configuration for the lifetime timer...............................................................................................................528
Chapter 32
Low-Power Timer (LPTMR)
32.1
32.2
Introduction...................................................................................................................................................................531
32.1.1
Features........................................................................................................................................................531
32.1.2
Modes of operation......................................................................................................................................531
LPTMR signal descriptions..........................................................................................................................................532
32.2.1
32.3
32.4
Detailed signal descriptions.........................................................................................................................532
Memory map and register definition.............................................................................................................................532
32.3.1
Low Power Timer Control Status Register (LPTMRx_CSR)......................................................................533
32.3.2
Low Power Timer Prescale Register (LPTMRx_PSR)................................................................................534
32.3.3
Low Power Timer Compare Register (LPTMRx_CMR).............................................................................536
32.3.4
Low Power Timer Counter Register (LPTMRx_CNR)...............................................................................536
Functional description...................................................................................................................................................537
32.4.1
LPTMR power and reset..............................................................................................................................537
32.4.2
LPTMR clocking..........................................................................................................................................537
32.4.3
LPTMR prescaler/glitch filter......................................................................................................................537
32.4.4
LPTMR compare..........................................................................................................................................539
32.4.5
LPTMR counter...........................................................................................................................................539
32.4.6
LPTMR hardware trigger.............................................................................................................................540
32.4.7
LPTMR interrupt..........................................................................................................................................540
Chapter 33
Real Time Clock (RTC)
33.1
Introduction...................................................................................................................................................................541
33.1.1
Features........................................................................................................................................................541
33.1.2
Modes of operation......................................................................................................................................541
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Section number
33.1.3
33.2
33.3
Title
Page
RTC Signal Descriptions.............................................................................................................................541
Register definition.........................................................................................................................................................542
33.2.1
RTC Time Seconds Register (RTC_TSR)...................................................................................................543
33.2.2
RTC Time Prescaler Register (RTC_TPR)..................................................................................................543
33.2.3
RTC Time Alarm Register (RTC_TAR).....................................................................................................544
33.2.4
RTC Time Compensation Register (RTC_TCR).........................................................................................544
33.2.5
RTC Control Register (RTC_CR)................................................................................................................545
33.2.6
RTC Status Register (RTC_SR)..................................................................................................................547
33.2.7
RTC Lock Register (RTC_LR)....................................................................................................................548
33.2.8
RTC Interrupt Enable Register (RTC_IER).................................................................................................549
Functional description...................................................................................................................................................550
33.3.1
Power, clocking, and reset...........................................................................................................................550
33.3.2
Time counter................................................................................................................................................551
33.3.3
Compensation...............................................................................................................................................551
33.3.4
Time alarm...................................................................................................................................................552
33.3.5
Update mode................................................................................................................................................552
33.3.6
Register lock................................................................................................................................................553
33.3.7
Interrupt........................................................................................................................................................553
Chapter 34
Serial Peripheral Interface (SPI)
34.1
34.2
Introduction...................................................................................................................................................................555
34.1.1
Features........................................................................................................................................................555
34.1.2
Modes of Operation.....................................................................................................................................556
34.1.3
Block Diagrams............................................................................................................................................557
External Signal Description..........................................................................................................................................559
34.2.1
SPSCK — SPI Serial Clock.........................................................................................................................559
34.2.2
MOSI — Master Data Out, Slave Data In...................................................................................................560
34.2.3
MISO — Master Data In, Slave Data Out...................................................................................................560
34.2.4
SS — Slave Select........................................................................................................................................560
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Section number
34.3
34.4
34.5
Title
Page
Memory Map and Register Descriptions......................................................................................................................561
34.3.1
SPI control register 1 (SPIx_C1)..................................................................................................................561
34.3.2
SPI control register 2 (SPIx_C2)..................................................................................................................563
34.3.3
SPI baud rate register (SPIx_BR).................................................................................................................564
34.3.4
SPI status register (SPIx_S).........................................................................................................................565
34.3.5
SPI data register (SPIx_D)...........................................................................................................................566
34.3.6
SPI match register (SPIx_M).......................................................................................................................567
Functional Description..................................................................................................................................................568
34.4.1
General.........................................................................................................................................................568
34.4.2
Master Mode................................................................................................................................................568
34.4.3
Slave Mode..................................................................................................................................................570
34.4.4
SPI Transmission by DMA..........................................................................................................................571
34.4.5
SPI Clock Formats.......................................................................................................................................573
34.4.6
SPI Baud Rate Generation...........................................................................................................................576
34.4.7
Special Features...........................................................................................................................................576
34.4.8
Error Conditions...........................................................................................................................................578
34.4.9
Low Power Mode Options...........................................................................................................................579
34.4.10
Reset.............................................................................................................................................................580
34.4.11
Interrupts......................................................................................................................................................581
Initialization/Application Information..........................................................................................................................582
34.5.1
Initialization Sequence.................................................................................................................................582
34.5.2
Pseudo-Code Example.................................................................................................................................583
Chapter 35
Inter-Integrated Circuit (I2C)
35.1
35.2
Introduction...................................................................................................................................................................587
35.1.1
Features........................................................................................................................................................587
35.1.2
Modes of operation......................................................................................................................................588
35.1.3
Block diagram..............................................................................................................................................588
I2C signal descriptions..................................................................................................................................................589
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Section number
35.3
35.4
35.5
Title
Page
Memory map and register descriptions.........................................................................................................................589
35.3.1
I2C Address Register 1 (I2Cx_A1)..............................................................................................................590
35.3.2
I2C Frequency Divider register (I2Cx_F)....................................................................................................591
35.3.3
I2C Control Register 1 (I2Cx_C1)...............................................................................................................592
35.3.4
I2C Status register (I2Cx_S)........................................................................................................................593
35.3.5
I2C Data I/O register (I2Cx_D)...................................................................................................................595
35.3.6
I2C Control Register 2 (I2Cx_C2)...............................................................................................................596
35.3.7
I2C Programmable Input Glitch Filter register (I2Cx_FLT).......................................................................597
35.3.8
I2C Range Address register (I2Cx_RA)......................................................................................................598
35.3.9
I2C SMBus Control and Status register (I2Cx_SMB).................................................................................599
35.3.10
I2C Address Register 2 (I2Cx_A2)..............................................................................................................600
35.3.11
I2C SCL Low Timeout Register High (I2Cx_SLTH)..................................................................................601
35.3.12
I2C SCL Low Timeout Register Low (I2Cx_SLTL)...................................................................................601
Functional description...................................................................................................................................................601
35.4.1
I2C protocol.................................................................................................................................................601
35.4.2
10-bit address...............................................................................................................................................607
35.4.3
Address matching.........................................................................................................................................608
35.4.4
System management bus specification........................................................................................................609
35.4.5
Resets...........................................................................................................................................................612
35.4.6
Interrupts......................................................................................................................................................612
35.4.7
Programmable input glitch filter..................................................................................................................614
35.4.8
Address matching wakeup...........................................................................................................................615
35.4.9
DMA support...............................................................................................................................................615
Initialization/application information...........................................................................................................................616
Chapter 36
Universal Asynchronous Receiver/Transmitter (UART0)
36.1
Introduction...................................................................................................................................................................619
36.1.1
Features........................................................................................................................................................619
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Section number
36.2
36.3
Title
Page
36.1.2
Modes of operation......................................................................................................................................620
36.1.3
Block diagram..............................................................................................................................................620
Register definition.........................................................................................................................................................622
36.2.1
UART Baud Rate Register High (UARTx_BDH).......................................................................................623
36.2.2
UART Baud Rate Register Low (UARTx_BDL)........................................................................................624
36.2.3
UART Control Register 1 (UARTx_C1).....................................................................................................624
36.2.4
UART Control Register 2 (UARTx_C2).....................................................................................................626
36.2.5
UART Status Register 1 (UARTx_S1)........................................................................................................627
36.2.6
UART Status Register 2 (UARTx_S2)........................................................................................................629
36.2.7
UART Control Register 3 (UARTx_C3).....................................................................................................631
36.2.8
UART Data Register (UARTx_D)...............................................................................................................632
36.2.9
UART Match Address Registers 1 (UARTx_MA1)....................................................................................633
36.2.10
UART Match Address Registers 2 (UARTx_MA2)....................................................................................634
36.2.11
UART Control Register 4 (UARTx_C4).....................................................................................................634
36.2.12
UART Control Register 5 (UARTx_C5).....................................................................................................635
Functional description...................................................................................................................................................636
36.3.1
Baud rate generation....................................................................................................................................636
36.3.2
Transmitter functional description...............................................................................................................636
36.3.3
Receiver functional description...................................................................................................................638
36.3.4
Additional UART functions.........................................................................................................................641
36.3.5
Interrupts and status flags............................................................................................................................643
Chapter 37
General-Purpose Input/Output (GPIO)
37.1
37.2
Introduction...................................................................................................................................................................645
37.1.1
Features........................................................................................................................................................645
37.1.2
Modes of operation......................................................................................................................................645
37.1.3
GPIO signal descriptions.............................................................................................................................646
Memory map and register definition.............................................................................................................................647
37.2.1
Port Data Output Register (GPIOx_PDOR).................................................................................................648
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Section number
37.3
37.4
Title
Page
37.2.2
Port Set Output Register (GPIOx_PSOR)....................................................................................................649
37.2.3
Port Clear Output Register (GPIOx_PCOR)................................................................................................649
37.2.4
Port Toggle Output Register (GPIOx_PTOR).............................................................................................650
37.2.5
Port Data Input Register (GPIOx_PDIR).....................................................................................................650
37.2.6
Port Data Direction Register (GPIOx_PDDR).............................................................................................651
FGPIO memory map and register definition................................................................................................................651
37.3.1
Port Data Output Register (FGPIOx_PDOR)..............................................................................................652
37.3.2
Port Set Output Register (FGPIOx_PSOR).................................................................................................652
37.3.3
Port Clear Output Register (FGPIOx_PCOR).............................................................................................653
37.3.4
Port Toggle Output Register (FGPIOx_PTOR)...........................................................................................653
37.3.5
Port Data Input Register (FGPIOx_PDIR)...................................................................................................654
37.3.6
Port Data Direction Register (FGPIOx_PDDR)..........................................................................................654
Functional description...................................................................................................................................................655
37.4.1
General-purpose input..................................................................................................................................655
37.4.2
General-purpose output................................................................................................................................655
37.4.3
IOPORT.......................................................................................................................................................655
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Chapter 1
About This Document
1.1 Overview
1.1.1 Purpose
This document describes the features, architecture, and programming model of the
Freescale KL04 microcontroller.
1.1.2 Audience
This document is primarily for system architects and software application developers
who are using or considering using the KL04KL02 microcontroller in a system.
1.2 Conventions
1.2.1 Numbering systems
The following suffixes identify different numbering systems:
This suffix
Identifies a
b
Binary number. For example, the binary equivalent of the
number 5 is written 101b. In some cases, binary numbers are
shown with the prefix 0b.
d
Decimal number. Decimal numbers are followed by this suffix
only when the possibility of confusion exists. In general,
decimal numbers are shown without a suffix.
h
Hexadecimal number. For example, the hexadecimal
equivalent of the number 60 is written 3Ch. In some cases,
hexadecimal numbers are shown with the prefix 0x.
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Conventions
1.2.2 Typographic notation
The following typographic notation is used throughout this document:
Example
Description
placeholder, x
Items in italics are placeholders for information that you provide. Italicized text is also used for
the titles of publications and for emphasis. Plain lowercase letters are also used as
placeholders for single letters and numbers.
code
Fixed-width type indicates text that must be typed exactly as shown. It is used for instruction
mnemonics, directives, symbols, subcommands, parameters, and operators. Fixed-width type
is also used for example code. Instruction mnemonics and directives in text and tables are
shown in all caps; for example, BSR.
SR[SCM]
A mnemonic in brackets represents a named field in a register. This example refers to the
Scaling Mode (SCM) field in the Status Register (SR).
REVNO[6:4], XAD[7:0]
Numbers in brackets and separated by a colon represent either:
• A subset of a register's named field
For example, REVNO[6:4] refers to bits 6–4 that are part of the COREREV field that
occupies bits 6–0 of the REVNO register.
• A continuous range of individual signals of a bus
For example, XAD[7:0] refers to signals 7–0 of the XAD bus.
1.2.3 Special terms
The following terms have special meanings:
Term
Meaning
asserted
Refers to the state of a signal as follows:
• An active-high signal is asserted when high (1).
• An active-low signal is asserted when low (0).
deasserted
Refers to the state of a signal as follows:
• An active-high signal is deasserted when low (0).
• An active-low signal is deasserted when high (1).
In some cases, deasserted signals are described as negated.
reserved
Refers to a memory space, register, or field that is either
reserved for future use or for which, when written to, the
module or chip behavior is unpredictable.
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Chapter 2
Introduction
2.1 Overview
This chapter provides an overview of the Kinetis L series of ARM® Cortex™-M0+
MCUs and KL04 product family. It also presents high-level descriptions of the modules
available on the devices covered by this document.
2.2 Kinetis L Series
The Kinetis L series is the most scalable portfolio of ultra low-power, mixed-signal ARM
Cortex-M0+ MCUs in the industry. The portfolio includes 5 MCU families that offer a
broad range of memory, peripheral and package options. Kinetis L Series families share
common peripherals and pin-counts allowing developers to migrate easily within an
MCU family or between MCU families to take advantage of more memory or feature
integration. This scalability allows developers to standardize on the Kinetis L Series for
their end product platforms, maximising hardware and software reuse and reducing timeto-market.
Features common to all Kinetis L series families include:
• 48 MHz ARM Cortex-M0+ core
• High-speed 12/16-bit analog-to-digital converters
• 12-bit digital-to-analog converters for all series except for KLx4/KLx2 family
• High-speed analog comparators
• Low-power touch sensing with wake-up on touch from reduced power states for all
series except for KLx4/KLx2 family
• Powerful timers for a broad range of applications including motor control
• Low power focused serial communication interfaces such as low power UART, SPI,
I2C etc.
• Single power supply: 1.71V - 3.6V with multiple low-power modes support single
operation temperature: -40 ~ 105 °C (exclude CSP package)
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Kinetis L Series
Kinetis L series MCU families combine the latest low-power innovations with precision
mixed-signal capability and a broad range of communication, connectivity, and humanmachine interface peripherals. Each MCU family is supported by a market-leading
enablement bundle from Freescale and numerous ARM 3rd party ecosystem partners.
The KL0x family is the entry-point to the Kinetis L series and is pin compatible with the
8-bit S08PT family. The KL1x/2x/3x/4x families are compatible with each other and
their equivalent ARM Cortex-M4 Kinetis K series families - K10/20/30/40.
Family
Program
Flash
Packages
KL4x Family 128-256KB
64-121pin
KL3x Family 64-256KB
64-121pin
KL2x Family 32-256KB
32-121pin
KL1x Family 32-256KB
32-80pin
KL0x Family
16-48pin
8-32KB
Low power
Mixed signal
Key Features
USB
Segment LCD
Figure 2-1. Kinetis L series families of MCU portfolio
All Kinetis L series families include a powerful array of analog, communication and
timing and control peripherals with the level of feature integration increasing with flash
memory size and the pin count. Features within the Kinetis L series families include:
• Core and Architecture:
• ARM Cortex-M0+ Core running up to 48 MHz with zero wait state execution
from memories
• Single-cycle access to I/O: Up to 50 percent faster than standard I/O,
improves reaction time to external events allowing bit banging and software
protocol emulation
• Two-stage pipeline: Reduced number of cycles per instruction (CPI),
enabling faster branch instruction and ISR entry, and reducing power
consumption
• Excellent code density vs. 8-bit and 16-bit MCUs - reduces flash size,
system cost and power consumption
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Chapter 2 Introduction
•
•
•
•
• Optimized access to program memory: Accesses on alternate cycles reduces
power consumption
• 100 percent compatible with ARM Cortex-M0 and a subset ARM CortexM3/M4: Reuse existing compilers and debug tools
• Simplified architecture: 56 instructions and 17 registers enables easy
programming and efficient packaging of 8/16/32-bit data in memory
• Linear 4 GB address space removes the need for paging/banking, reducing
software complexity
• ARM third-party ecosystem support: Software and tools to help minimize
development time/cost
• Micro Trace Buffer: Lightweight trace solution allows fast bug identification and
correction
• BME: Bit manipulation engine reduces code size and cycles for bit oriented
operations to peripheral registers eliminating traditional methods where the core
would need to perform read-modify-write operations.
• Up to 4-channel DMA for peripheral and memory servicing with minimal CPU
intervention (feature not available on KL02 family)
Ultra low-power:
• Extreme dynamic efficiency: 32-bit ARM Cortex-M0+ core combined with
Freescale 90 nm thin film storage flash technology delivers 50% energy savings
per Coremark versus the closest 8/16-bit competitive solution
• Multiple flexible low-power modes, including new operation clocking option
which reduces dynamic power by shutting off bus and system clocks for lowest
power core processing. Peripherals with an alternate asynchronous clock source
can continue operation.
• UART, SPI, I2C, ADC, DAC, TPM, LPT, and DMA support low-power mode
operation without waking up the core
Memory:
• Scalable memory footprints from 8 KB flash / 1 KB SRAM to 256 KB flash / 32
KB SRAM
• Embedded 64 B cache memory for optimizing bus bandwidth and flash
execution performance (32 B cache on KL02 family)
Mixed-signal analog:
• Fast, high precision 16-, or 12-bit ADC with optional differential pairs, 12-bit
DAC, high speed comparators. Powerful signal conditioning, conversion and
analysis capability with reduced system cost (12-bit DAC not available on KL02
family)
Human Machine Interface (HMI):
• Optional capacitive Touch Sensing Interface with full low-power support and
minimal current adder when enabled
• Segment LCD controller
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KL04 Sub-Family Introduction
• Connectivity and Communications:
• Up to three UARTs, all UARTs support DMA transfers, and can trigger when
data on bus is detected, UART0 supports 4x to 32x over sampling ratio.
Asynchronous transmit and receive operation for operating in STOP/VLPS
modes.
• Up to two SPIs
• Up to two I2Cs
• Full-speed USB OTG controller with on-chip transceiver
• 5 V to 3.3 V USB on-chip regulator
• Up to one I2S
• Reliability, Safety and Security:
• Internal watchdog with independent clock source
• Timing and Control:
• Powerful timer modules which support general purpose, PWM, and motor
control functions
• Periodic Interrupt Timer for RTOS task scheduler time base or trigger source for
ADC conversion and timer modules
• System:
• GPIO with pin interrupt functionality
• Wide operating voltage range from 1.71 V to 3.6 V with flash programmable
down to 1.71 V with fully functional flash and analog peripherals
• Ambient operating temperature ranges from -40 °C to 105 °C
2.3 KL04 Sub-Family Introduction
The device is highly-integrated, market leading ultra low power 32-bit microcontroller
based on the enhanced Cortex-M0+ (CM0+) core platform. The family derivatives
feature:
• Core platform clock up to 48 MHz, bus clock up to 24 MHz
• Memory option is up to 32 KB Flash and 4 KB RAM
• Wide operating voltage ranges from 1.71V to 3.6V with full functional Flash
program/erase/read operations
• Multiple package options from 24-pin to 48-pin
• Ambient operating temperature ranges from –40 °C to 105 °C
The family acts as an ultra low power, cost effective microcontroller to provide
developers an appropriate entry-level 32-bit solution. The family is next generation MCU
solution for low cost, low power, high performance devices applications. It’s valuable for
cost-sensitive, portable applications requiring long battery life-time.
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Chapter 2 Introduction
2.4 Module functional categories
The modules on this device are grouped into functional categories. The following
sections describe the modules assigned to each category in more detail.
Table 2-1. Module functional categories
Module category
Description
ARM Cortex-M0+ core
• 32-bit MCU core from ARM’s Cortex-M class, 1.77 CoreMark®/MHz from
single-cycle access memories, 48 MHz CPU frequency
System
• System integration module
• Power management and mode controllers
• Multiple power modes available based on run, wait, stop, and powerdown modes
• Miscellaneous control module
• Low-leakage wakeup unit
• Peripheral bridge
• Direct memory access (DMA) controller with multiplexer to increase available
DMA requests
• COP watchdog
Memories
• Internal memories include:
• Up to 32 KB flash memory
• up to 4 KB SRAM
Clocks
• Multiple clock generation options available from internally- and externallygenerated clocks
• MCG module with FLL for systems and CPU clock sources
• Low power 1 kHz RC oscillator for RTC and COP watchdog
• System oscillator to provide clock source for the MCU
Security
• COP watchdog timer (COP)
Analog
• 12-bit analog-to-digital converters with DMA supported
• Comparator (CMP) with internal 6-bit digital-to-analog converter (DAC)
Timers
•
•
•
•
•
•
Communications
• One8-bit serial peripheral interface
• One inter-integrated circuit (I2C) module
• One low power UART module
Human-Machine Interfaces (HMI)
• General purpose input/output controller
One 6-channel TPM
One 2-channel TPM
2-channel periodic interrupt timer
Real time clock
Low-power timer
System tick timer
2.4.1 ARM® Cortex™-M0+ Core Modules
The following core modules are available on this device.
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Module functional categories
Table 2-2. Core modules
Module
Description
ARM® Cortex™-M0+
The ARM® Cortex™-M0+ is the newest member of the Cortex M Series of
processors targeting microcontroller applications focused on very cost sensitive,
deterministic, interrupt driven environments. The Cortex M0+ processor is based
on the ARMv6 Architecture and Thumb®-2 ISA and is 100% instruction set
compatible with its predecessor, the Cortex-M0 core, and upward compatible to
Cortex-M3 and M4 cores.
NVIC
The ARMv6-M exception model and nested-vectored interrupt controller (NVIC)
implement a relocatable vector table supporting many external interrupts, a single
non-maskable interrupt (NMI), and priority levels.
The NVIC replaces shadow registers with equivalent system and simplified
programmability. The NVIC contains the address of the function to execute for a
particular handler. The address is fetched via the instruction port allowing parallel
register stacking and look-up. The first sixteen entries are allocated to ARM
internal sources with the others mapping to MCU-defined interrupts.
AWIC
The primary function of the Asynchronous Wake-up Interrupt Controller (AWIC) is
to detect asynchronous wake-up events in stop modes and signal to clock control
logic to resume system clocking. After clock restart, the NVIC observes the
pending interrupt and performs the normal interrupt or event processing.
Single-cycle I/O Port
For high-speed, single-cycle access to peripherals, the Cortex-M0+ processor
implements a dedicated single-cycle I/O port.
Debug interfaces
Most of this device's debug is based on the ARM CoreSight™ architecture. One
debug interface is supported:
• Serial Wire Debug (SWD)
2.4.2 System Modules
The following system modules are available on this device.
Table 2-3. System modules
Module
Description
System integration module (SIM)
The SIM includes integration logic and several module configuration settings.
System mode controller
The SMC provides control and protection on entry and exit to each power mode,
control for the Power management controller (PMC), and reset entry and exit for
the complete MCU.
Power management controller (PMC)
The PMC provides the user with multiple power options. Multiple modes are
supported that allow the user to optimize power consumption for the level of
functionality needed. Includes power-on-reset (POR) and integrated low voltage
detect (LVD) with reset (brownout) capability and selectable LVD trip points.
Miscellaneous control module (MCM)
The MCM includes integration logic and details.
Crossbar switch (XBS)
The XBS connects bus masters and bus slaves, allowing all bus masters to access
different bus slaves simultaneously and providing arbitration among the bus
masters when they access the same slave.
Low-leakage wakeup unit (LLWU)
The LLWU module allows the device to wake from low leakage power modes (LLS
and VLLS) through various internal peripheral and external pin sources.
Table continues on the next page...
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Chapter 2 Introduction
Table 2-3. System modules (continued)
Module
Description
Peripheral bridge
The peripheral bridge converts the crossbar switch interface to an interface to
access a majority of peripherals on the device.
DMA multiplexer (DMAMUX)
The DMA multiplexer selects from many DMA requests down to 4 for the DMA
controller.
Direct memory access (DMA) controller
The DMA controller provides programmable channels with transfer control
descriptors for data movement via dual-address transfers for 8-, 16- and 32-bit
data values.
Computer operating properly watchdog
(WDOG)
The WDOG monitors internal system operation and forces a reset in case of
failure. It can run from an independent 1 kHz low power oscillator with a
programmable refresh window to detect deviations in program flow or system
frequency.
2.4.3 Memories and Memory Interfaces
The following memories and memory interfaces are available on this device.
Table 2-4. Memories and memory interfaces
Module
Description
Flash memory
Program flash memory — up to 32 KB of the non-volatile flash memory that can
execute program code
Flash memory controller
Manages the interface between the device and the on-chip flash memory.
SRAM
Up to 4 KB internal system RAM.
2.4.4 Clocks
The following clock modules are available on this device.
Table 2-5. Clock modules
Module
Description
Multipurpose Clock Generator (MCG)
MCG module containing a frequency-locked-loop (FLL) controlled by internal or
external reference oscillator.
System oscillator
The system oscillator, in conjunction with an external crystal or resonator,
generates a reference clock for the MCU.
2.4.5 Security and Integrity modules
The following security and integrity modules are available on this device:
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Module functional categories
Table 2-6. Security and integrity modules
Module
Description
Watchdog Timer (WDOG)
Watchdog Timer keeps a watch on the system functioning and resets it in case of
its failure.
2.4.6 Analog modules
The following analog modules are available on this device:
Table 2-7. Analog modules
Module
Description
Analog-to-digital converters (ADC)
12-bit successive-approximation ADC module.
Analog comparators
One comparator that compares two analog input voltages across the full range of
the supply voltage and can trigger an ADC acquisition, TPM update, or CPU
interrupt.
6-bit digital-to-analog converters (DAC)
64-tap resistor ladder network which provides a selectable voltage reference for
comparator.
2.4.7 Timer modules
The following timer modules are available on this device:
Table 2-8. Timer modules
Module
Description
Timer/PWM module (TPM)
• Selectable TPM clock mode
• Prescaler divide-by 1, 2, 4, 8, 16, 32, 64, or 128
• 16-bit free-running counter or modulo counter with counting be up or updown
• Six configurable channels for input capture, output compare, or edge-aligned
PWM mode
• Support the generation of an interrupt and/or DMA request per channel
• Support the generation of an interrupt and/or DMA request when the counter
overflows
• Support selectable trigger input to optionally reset or cause the counter to
start incrementing.
• Support the generation of hardware triggers when the counter overflows and
per channel
Periodic interrupt timers (PIT)
•
•
•
•
•
One general purpose interrupt timer
Interrupt timers for triggering ADC conversions
32-bit counter resolution
Clocked by bus clock frequency
DMA support
Table continues on the next page...
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Chapter 2 Introduction
Table 2-8. Timer modules (continued)
Module
Description
Low power timer (LPTMR)
• 16-bit time counter or pulse counter with compare
• Configurable clock source for prescaler/glitch filter
• Configurable input source for pulse counter
Real-time counter (RTC)
• 16-bit up-counter
• 16-bit modulo match limit
• Software controllable periodic interrupt on match
• Software selectable clock sources for input to prescaler with programmable
16-bit prescaler
• XOSC 32.678 kHz nominal
• LPO (~1 kHz)
• External RTC_CLKIN
2.4.8 Communication interfaces
The following communication interfaces are available on this device:
Table 2-9. Communication modules
Module
Description
Serial peripheral interface (SPI)
Synchronous serial bus for communication to an external device
Inter-integrated circuit (I2C)
Allows communication between a number of devices. Also supports the System
Management Bus (SMBus) Specification, version 2.
Universal asynchronous receiver/
transmitters (UART)
One low power UART module that retains functional in stop modes.
2.4.9 Human-machine interfaces
The following human-machine interfaces (HMI) are available on this device:
Table 2-10. HMI modules
Module
Description
General purpose input/output (GPIO)
Some general purpose input or output (GPIO) pins are capable of interrupt and
DMA request generation.
2.5 Orderable part numbers
The following table summarizes the part numbers of the devices covered by this
document.
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Orderable part numbers
Table 2-11. Orderable part numbers summary
Freescale part number
CPU
frequency
Pin count
Package
Total flash
memory
RAM
Temperature range
MKL04Z8VFK4
48 MHz
24
QFN
8 KB
1 KB
-40 to 105 °C
MKL04Z16VFK4
48 MHz
24
QFN
16 KB
2 KB
-40 to 105 °C
MKL04Z32VFK4
48 MHz
24
QFN
32 KB
4 KB
-40 to 105 °C
MKL04Z8VLC4
48 MHz
32
LQFP
8 KB
1 KB
-40 to 105 °C
MKL04Z16VLC4
48 MHz
32
LQFP
16 KB
2 KB
-40 to 105 °C
MKL04Z32VLC4
48 MHz
32
LQFP
32 KB
4 KB
-40 to 105 °C
MKL04Z8VFM4
48 MHz
32
QFN
8 KB
1 KB
-40 to 105 °C
MKL04Z16VFM4
48 MHz
32
QFN
16 KB
2 KB
-40 to 105 °C
MKL04Z32VFM4
48 MHz
32
QFN
32 KB
4 KB
-40 to 105 °C
MKL04Z16VLF4
48 MHz
48
LQFP
16 KB
2 KB
-40 to 105 °C
MKL04Z32VLF4
48 MHz
48
LQFP
32 KB
4 KB
-40 to 105 °C
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Chapter 3
Chip Configuration
3.1 Introduction
This chapter provides details on the individual modules of the microcontroller. It
includes:
• Module block diagrams showing immediate connections within the device
• Specific module-to-module interactions not necessarily discussed in the individual
module chapters
• Links for more information
3.2 Module to Module Interconnects
3.2.1 Module to Module Interconnects
The below table captures the module to module interconnections for this device.
Table 3-1. Module to Module Interconnects
Peripheral
Signal
—
to Peripheral
TPM1
CH0F, CH1F
to
ADC (Trigger)
Use Case
Control
ADC Triggering SOPT7_ADCAL
(A AND B)
TTRGEN = 0
Comment
Ch0 is A, and
Ch1 is B,
selecting this
ADC trigger is
for supporting A
and B triggering.
In Stop and
VLPS modes,
the second
trigger must be
set to >10us
after the first
trigger
Table continues on the next page...
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Module to Module Interconnects
Table 3-1. Module to Module Interconnects (continued)
Peripheral
Signal
—
to Peripheral
Use Case
Control
Comment
LPTMR
Hardware trigger
to
ADC (Trigger)
ADC Triggering SOPT7_ADC0T
(A or B)
RGSEL (4 bit
field),
ADC0PRETRG
SEL to select A
or B
—
TPMx
TOF
to
ADC (Trigger)
ADC Triggering SOPT7_ADC0T
(A or B)
RGSEL (4 bit
field),
SOPT7_ADC0P
RETRGSEL to
select A or B
—
PIT CHx
TIF0, TIF1
to
ADC (Trigger)
ADC Triggering SOPT7_ADC0T
(A or B)
RGSEL (4 bit
field),
ADC0PRETRG
SEL to select A
or B
—
RTC
ALARM or
SECONDS
to
ADC (Trigger)
ADC Triggering SOPT7_ADC0T
(A or B)
RGSEL (4 bit
field)
ADC0PRETRG
SEL to select A
or B
—
EXTRG_IN
EXTRG_IN
to
ADC (Trigger)
ADC Triggering SOPT7_ADC0T
(A or B)
RGSEL (4 bit
field)
ADC0PRETRG
SEL to select A
or B
—
CMP0
CMP0_OUT
to
ADC (Trigger)
ADC Triggering SOPT7_ADC0T
(Aor B)
RGSEL (4 bit
field)
ADC0PRETRG
SEL to select A
or B
—
CMP0
CMP0_OUT
to
LPTMR_ALT0
Count CMP
events
LPTMR_CSR[T
PS]
—
CMP0
CMP0_OUT
to
TPM1 CH0
Input capture
SOPT4_TPM1C
H0SRC
—
CMP0
CMP0_OUT
to
UART0_RX
IR interface
SOPT5_UART0
RXSRC
—
LPTMR
Hardware trigger
to
CMPx
Low power
CMP_CR1[TRIG
triggering of the
M]
comparator
—
LPTMR
Hardware trigger
to
TPMx
TPM Trigger
input
TPMx_CONF[T
RGSEL] (4 bit
field)
—
TPMx
TOF
to
TPMx
TPM Trigger
input
TPMx_CONF[T
RGSEL] (4 bit
field)
—
Table continues on the next page...
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Chapter 3 Chip Configuration
Table 3-1. Module to Module Interconnects (continued)
Peripheral
Signal
—
to Peripheral
Use Case
Control
Comment
TPM1
Timebase
to
TPMx
TPM Global
timebase input
TPMx_CONF[G
TBEEN]
—
PIT CHx
TIF0, TIF1
to
TPMx
TPM Trigger
input
TPMx_CONF[T
RGSEL] (4 bit
field)
If PIT is
triggering the
TPM, the TPM
clock must be
faster than Bus
clock.
RTC
ALARM or
SECONDS
to
TPMx
TPM Trigger
input
TPMx_CONF[T
RGSEL] (4 bit
field)
—
EXTRG_IN
EXTRG_IN
to
TPMx
TPM Trigger
input
TPMx_CONF[T
RGSEL] (4 bit
field)
—
CMP0
CMP0_OUT
to
TPMx
TPM Trigger
input
TPMx_CONF[T
RGSEL] (4 bit
field)
—
UART0
UART0_TX
to
Modulated by
TPM1 CH0
UART
modulation
SOPT5_UART0
TXSRC
—
PIT
TIF0
to
DAC
Advance DAC
FIFO
DAC HWTRG
Select
—
PIT
TIF0
to
DMA CH0
DMA HW
Trigger
DMA MUX
register option
—
PIT
TIF1
to
DMA CH1
DMA HW
Trigger
DMA MUX
register option
—
3.2.2 Analog reference options
Several analog blocks have selectable reference voltages as shown in the below table.
These options allow analog peripherals to share or have separate analog references. Care
should be taken when selecting analog references to avoid cross talk noise.
Table 3-2. Analog reference options
Module
Reference option
Comment/ Reference selection
12-bit SAR ADC
1 - VREFH
Selected by ADCx_SC2[REFSEL] bits
2 - VDDA
3 - Reserved
CMP with 6-bit DAC
Vin1 - VREFH
Selected by CMPx_DACCR[VRSEL] bit
Vin2 - VDD1
1. Use this option for the best ADC operation.
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Core Modules
3.3 Core Modules
3.3.1 ARM Cortex-M0+ Core Configuration
This section summarizes how the module has been configured in the chip. Full
documentation for this module is provided by ARM and can be found at www.arm.com.
Debug
Crossbar
switch
Interrupts
ARM Cortex-M0+
Core
Figure 3-1. Core configuration
Table 3-3. Reference links to related information
Topic
Related module
Reference
Full description
ARM Cortex-M0+ core,
r0p0
ARM Cortex-M0+ Technical Reference Manual, r0p0
System memory map
System memory map
Clocking
Clock distribution
Power management
Power management
System/instruction/data
bus module
Crossbar switch
Crossbar switch
Debug
Serial Wire Debug
(SWD)
Debug
Interrupts
Nested Vectored
Interrupt Controller
(NVIC)
NVIC
Miscellaneous Control
Module (MCM)
MCM
3.3.1.1 ARM Cortex M0+ Core
The ARM Cortex M0+ parameter settings are as follows:
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Chapter 3 Chip Configuration
Table 3-4. ARM Cortex-M0+ parameter settings
Parameter
Verilog Name
Value
Description
Arch Clock Gating
ACG
1 = Present
DAP Slave Port Support
AHBSLV
1
DAP ROM Table Base
BASEADDR
0xF000_2003
Endianess
BE
0
Little endian control for data transfers
Breakpoints
BKPT
2
Implements 2 breakpoints
Implements architectural clock gating
Support any AHB debug access port (like the
CM4 DAP)
Base address for DAP ROM table
Debug Support
DBG
1 = Present
Halt Event Support
HALTEV
1 = Present
I/O Port
IOP
1 = Present
Implements single-cycle ld/st accesses to
special address space
IRQ Mask Enable
IRQDIS
0x00000000
Assume (for now) all 32 IRQs are used (set if
IRQ is disabled)
Debug Port Protocol
JTAGnSW
0 = SWD
Core Memory Protection
MPU
0 = Absent
SWD protocol, not JTAG
Number of IRQs
NUMIRQ
32
Reset all regs
RAR
0 = Standard
Do not force all registers to be async reset
Multiplier
SMUL
0 = Fast Mul
Implements single-cycle multiplier
Multi-drop Support
SWMD
0 = Absent
Do not include serial wire support for multidrop
System Tick Timer
SYST
1 = Present
Implements system tick timer (for CM4
compatibility)
DAP Target ID
TARGETID
0
User/Privileged
USER
1 = Present
Implements processor operating modes
Vector Table Offset Register
VTOR
1 = Present
Implements relocation of exception vector
table
Implements WIC interface
No MPU
Assume full NVIC request vector
WIC Support
WIC
1 = Present
WIC Requests
WICLINES
34
Exact number of wakeup IRQs is 34
Watchpoints
WPT
2
Implements 2 watchpoints
For details on the ARM Cortex-M0+ processor core, see the ARM website:
www.arm.com.
3.3.1.2 Buses, Interconnects, and Interfaces
The ARM Cortex-M0+ core has two bus interfaces:
• single 32-bit AMBA-3 AHB-Lite system interface that provides connections to
peripherals and all system memory, which includes flash and RAM.
• single 32-bit I/O port bus interfacing to the GPIO with 1-cycle loads and stores.
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Core Modules
3.3.1.3 System Tick Timer
The CLKSOURCE bit in SysTick Control and Status register selects either the core clock
(when CLKSOURCE = 1) or a divide-by-16 of the core clock (when CLKSOURCE = 0).
Because the timing reference is a variable frequency, the TENMS bit in the SysTick
Calibration Value Register is always zero.
3.3.1.4 Debug Facilities
This device supports standard ARM 2-pin SWD debug port.
3.3.1.5 Core Privilege Levels
The Core on this device is implemented with both Privileged and Unprivileged levels.
The ARM documentation uses different terms than this document to distinguish between
privilege levels.
If you see this term...
it also means this term...
Privileged
Supervisor
Unprivileged or user
User
3.3.2 Nested Vectored Interrupt Controller (NVIC) Configuration
ARM Cortex-M0+
core
This section summarizes how the module has been configured in the chip. Full
documentation for this module is provided by ARM and can be found at www.arm.com.
Interrupts
Module
Nested Vectored
Interrupt Controller
(NVIC)
PPB
Module
Module
Figure 3-2. NVIC configuration
Table 3-5. Reference links to related information
Topic
Related module
Reference
Full description
Nested Vectored
Interrupt Controller
(NVIC)
ARM Cortex-M0+ Technical Reference Manual
System memory map
System memory map
Clocking
Clock distribution
Table continues on the next page...
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Chapter 3 Chip Configuration
Table 3-5. Reference links to related information (continued)
Topic
Related module
Reference
Power management
Power management
Private Peripheral Bus
(PPB)
ARM Cortex-M0+ core
ARM Cortex-M0+ core
3.3.2.1 Interrupt priority levels
This device supports 4 priority levels for interrupts. Therefore, in the NVIC each source
in the IPR registers contains 2 bits. For example, IPR0 is shown below:
31
R
W
30
IRQ3
29
28
27
26
25
24
0
0
0
0
0
0
23
22
IRQ2
21
20
19
18
17
16
0
0
0
0
0
0
15
14
IRQ1
13
12
11
10
9
8
0
0
0
0
0
0
7
6
IRQ0
5
4
3
2
1
0
0
0
0
0
0
0
3.3.2.2 Non-maskable interrupt
The non-maskable interrupt request to the NVIC is controlled by the external NMI signal.
The pin the NMI signal is multiplexed on, must be configured for the NMI function to
generate the non-maskable interrupt request.
3.3.2.3 Interrupt channel assignments
The interrupt vector assignments are defined in the following table.
• Vector number — the value stored on the stack when an interrupt is serviced.
• IRQ number — non-core interrupt source count, which is the vector number minus
16.
The IRQ number is used within ARM's NVIC documentation.
Table 3-7. Interrupt vector assignments
Address
IRQ1
Vector
NVIC
IPR
register
number2
Source module
Source description
ARM Core System Handler Vectors
0x0000_0000
0
—
—
ARM core
Initial Stack Pointer
0x0000_0004
1
—
—
ARM core
Initial Program Counter
Table continues on the next page...
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Core Modules
Table 3-7. Interrupt vector assignments (continued)
Address
IRQ1
Vector
NVIC
IPR
register
number2
Source module
Source description
0x0000_0008
2
—
—
ARM core
Non-maskable Interrupt (NMI)
0x0000_000C
3
—
—
ARM core
Hard Fault
0x0000_0010
4
—
—
—
—
0x0000_0014
5
—
—
—
—
0x0000_0018
6
—
—
—
—
0x0000_001C
7
—
—
—
—
0x0000_0020
8
—
—
—
—
0x0000_0024
9
—
—
—
—
0x0000_0028
10
—
—
—
—
0x0000_002C
11
—
—
ARM core
Supervisor call (SVCall)
0x0000_0030
12
—
—
—
—
0x0000_0034
13
—
—
—
—
0x0000_0038
14
—
—
ARM core
Pendable request for system service
(PendableSrvReq)
0x0000_003C
15
—
—
ARM core
System tick timer (SysTick)
0x0000_0040
16
0
0
DMA
DMA channel 0 transfer complete and error
0x0000_0044
17
1
0
DMA
DMA channel 1 transfer complete and error
0x0000_0048
18
2
0
DMA
DMA channel 2 transfer complete and error
0x0000_004C
19
3
0
DMA
DMA channel 3 transfer complete and error
0x0000_0050
20
4
1
—
—
0x0000_0054
21
5
1
FTFA
Command complete and read collision
0x0000_0058
22
6
1
PMC
Low-voltage detect, low-voltage warning
0x0000_005C
23
7
1
LLWU
Low Leakage Wakeup
0x0000_0060
24
8
2
I2C0
0x0000_0064
25
9
2
—
0x0000_0068
26
10
2
SPI0
0x0000_006C
27
11
2
—
0x0000_0070
28
12
3
UART0
0x0000_0074
29
13
3
—
0x0000_0078
30
14
3
—
0x0000_007C
31
15
3
ADC0
0x0000_0080
32
16
4
CMP0
0x0000_0084
33
17
4
TPM0
0x0000_0088
34
18
4
TPM1
0x0000_008C
35
19
4
—
0x0000_0090
36
20
5
RTC
Alarm interrupt
0x0000_0094
37
21
5
RTC
Seconds interrupt
Non-Core Vectors
Single interrupt vector for all sources
Status and error
Table continues on the next page...
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Chapter 3 Chip Configuration
Table 3-7. Interrupt vector assignments (continued)
Address
IRQ1
Vector
NVIC
IPR
register
number2
Source module
Source description
0x0000_0098
38
22
5
PIT
Single interrupt vector for all channels
0x0000_009C
39
23
5
—
—
0x0000_00A0
40
24
6
—
0x0000_00A4
41
25
6
—
0x0000_00A8
42
26
6
—
0x0000_00AC
43
27
6
MCG
0x0000_00B0
44
28
7
LPTMR0
0x0000_00B4
45
29
7
—
0x0000_00B8
46
30
7
Port control module
Pin detect (Port A)
0x0000_00BC
47
31
7
Port control module
Pin detect (Port B )
1. Indicates the NVIC's interrupt source number.
2. Indicates the NVIC's IPR register number used for this IRQ. The equation to calculate this value is: IRQ div 4
3.3.2.3.1
Determining the bitfield and register location for configuring a
particular interrupt
Suppose you need to configure the SPI0 interrupt. The following table is an excerpt of the
SPI0 row from Interrupt priority levels.
Table 3-8. Interrupt vector assignments
Address
0x0000_0068
IRQ1
Vector
26
10
NVIC IPR
register
number2
2
Source module
SPI0
Source description
Single interrupt vector for all sources
1. Indicates the NVIC's interrupt source number.
2. Indicates the NVIC's IPR register number used for this IRQ. The equation to calculate this value is: IRQ div 4.
• The NVIC registers you would use to configure the interrupt are:
• NVICIPR2
• To determine the particular IRQ's bitfield location within these particular registers:
• NVICIPR2 bitfield starting location = 8 * (IRQ mod 4) + 6 = 22
Since the NVICIPR bitfields are 2-bit wide (4 priority levels), the NVICIPR2 bitfield
range is 22-23
Therefore, the following bitfield locations are used to configure the SPI0 interrupts:
• NVICIPR2[23:22]
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Core Modules
3.3.3 Asynchronous wake-up interrupt controller (AWIC)
configuration
This section summarizes how the module has been configured in the chip. Full
documentation for this module is provided by ARM and can be found at www.arm.com.
Clock logic
Nested vectored
interrupt controller
(NVIC)
Wake-up
requests
Asynchronous
Wake-up Interrupt
Controller (AWIC)
Module
Module
Figure 3-3. Asynchronous wake-up interrupt controller configuration
Table 3-9. Reference links to related information
Topic
Related module
Reference
System memory map
System memory map
Clocking
Clock distribution
Power management
Power management
Nested vectored
interrupt controller
(NVIC)
Wake-up requests
NVIC
AWIC wake-up sources
3.3.3.1 Wake-up sources
The device uses the following internal and external inputs to the AWIC module.
Table 3-10. AWIC stop wake-up sources
Wake-up source
Description
Available system resets
RESET pin when LPO is its clock source
Low-voltage detect
Power management controller - functional in Stop mode
Low-voltage warning
Power management controller - functional in Stop mode
Pin interrupts
Port control module - any enabled pin interrupt is capable of waking the system
ADC
The ADC is functional when using internal clock source
CMP0
Interrupt in normal or trigger mode
Table continues on the next page...
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Chapter 3 Chip Configuration
Table 3-10. AWIC stop wake-up sources (continued)
Wake-up source
Description
I2Cx
Address match wakeup
UART0
Any interrupt provided clock remains enabled
RTC
Alarm or seconds interrupt
NMI
NMI pin
TPMx
Any interrupt provided clock remains enabled
LPTMR
Any interrupt provided clock remains enabled
SPI
Slave mode interrupt
3.4 System Modules
3.4.1 SIM Configuration
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
Peripheral
bridge
Register
access
System integration
module (SIM)
Figure 3-4. SIM configuration
Table 3-11. Reference links to related information
Topic
Related module
Reference
Full description
SIM
SIM
System memory map
System memory map
Clocking
Clock distribution
Power management
Power management
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System Modules
3.4.2 System Mode Controller (SMC) Configuration
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
Peripheral
bridge
Resets
System Mode
Controller (SMC)
Power Management
Controller (PMC)
Register
access
Figure 3-5. System Mode Controller configuration
Table 3-12. Reference links to related information
Topic
Related module
Reference
Full description
System Mode
Controller (SMC)
SMC
System memory map
System memory map
Power management
Power management
Power management
controller (PMC)
PMC
Low-Leakage Wakeup
Unit (LLWU)
LLWU
Reset Control Module
(RCM)
Reset
3.4.2.1 VLLS2 not supported
VLLS2 power mode is not supported on this device.
3.4.3 PMC Configuration
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
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Chapter 3 Chip Configuration
Peripheral
bridge
Module
signals
Power Management
Controller (PMC)
Module
signals
System Mode
Controller (SMC)
Low-Leakage
Wakeup Unit
Register access
Figure 3-6. PMC configuration
Table 3-13. Reference links to related information
Topic
Related module
Reference
Full description
PMC
PMC
System memory map
System memory map
Power management
Power management
Full description
System Mode
Controller (SMC)
System Mode Controller
Low-Leakage Wakeup
Unit (LLWU)
LLWU
Reset Control Module
(RCM)
Reset
3.4.4 Low-Leakage Wake-up Unit (LLWU) Configuration
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
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System Modules
Peripheral
bridge 0
Power Management
Controller (PMC)
Register
access
Wake-up
requests
Low-Leakage Wake-up
Unit (LLWU)
Module
Module
Figure 3-7. Low-Leakage Wake-up Unit configuration
Table 3-14. Reference links to related information
Topic
Related module
Reference
Full description
LLWU
LLWU
System memory map
System memory map
Clocking
Clock distribution
Power management
Power management chapter
Power Management
Controller (PMC)
Power Management Controller (PMC)
System Mode
Controller (SMC)
System Mode Controller
Wake-up requests
LLWU wake-up sources
3.4.4.1 LLWU interrupt
NOTE
Do not mask the LLWU interrupt when in LLS mode. Masking
the interrupt prevents the device from exiting stop mode when a
wakeup is detected.
3.4.4.2 Wake-up Sources
The device uses the following internal peripheral and external pin inputs as wakeup
sources to the LLWU module. LLWU_Px are external pin inputs, and LLWU_M0IFM7IF are connections to the internal peripheral interrupt flags.
NOTE
In addition to the LLWU wakeup sources, the device also
wakes from low power modes when NMI or RESET pins are
enabled and the respective pin is asserted.
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Chapter 3 Chip Configuration
Table 3-15. LLWU Wakeup Sources
IRQ
Module source or pin name
LLWU_P0
PTA4
LLWU_P1
PTA5
LLWU_P2
PTA6
LLWU_P3
PTA7
LLWU_P4
PTB0
LLWU_P5
PTB2
LLWU_P6
PTB4
LLWU_P7
PTA0
LLWU_M0IF
LPTMR0
LLWU_M1IF
CMP0
LLWU_M2IF
Reserved
LLWU_M3IF
Reserved
LLWU_M4IF
TSI0
LLWU_M5IF
RTC Alarm
LLWU_M6IF
Reserved
LLWU_M7IF
RTC Seconds
3.4.5 MCM Configuration
Miscellaneous
Control Module
(MCM)
Transfers
Transfers
Flash Memory
Controller
ARM Cortex-M0+
core
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
Figure 3-8. MCM configuration
Table 3-16. Reference links to related information
Topic
Related module
Reference
Full description
Miscellaneous control
module (MCM)
MCM
System memory map
System memory map
Clocking
Clock distribution
Power management
Power management
Private Peripheral Bus
(PPB)
ARM Cortex-M0+ core
ARM Cortex-M0+ core
Table continues on the next page...
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System Modules
Table 3-16. Reference links to related information (continued)
Topic
Related module
Reference
Transfer
Flash memory
controller
Flash memory controller
3.4.6 Crossbar-Light Switch Configuration
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
GPIO
controller
Crossbar Switch
S0
Flash
controller
M0
ARM core
unified bus
M2
S1
SRAML
DMA
Master Modules
BME
S2
SRAMU
Peripheral
bridge 0
Peripherals
Slave Modules
Figure 3-9. Crossbar-Light switch integration
Table 3-17. Reference links to related information
Topic
Related module
Reference
Full description
Crossbar switch
Crossbar Switch
System memory map
System memory map
Clocking
Clock Distribution
Crossbar switch master ARM Cortex-M0+ core
ARM Cortex-M0+ core
Crossbar switch master
DMA controller
DMA controller
Crossbar switch slave
Flash memory
controller
Flash memory controller
Crossbar switch slave
SRAM controller
SRAM configuration
Crossbar switch slave
Peripheral bridge
Peripheral bridge
2-ported peripheral
GPIO controller
GPIO controleer
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Chapter 3 Chip Configuration
3.4.6.1 Crossbar-Light Switch Master Assignments
The masters connected to the crossbar switch are assigned as follows:
Master module
Master port number
ARM core unified bus
0
DMA
2
3.4.6.2 Crossbar Switch Slave Assignments
This device contains 3 slaves connected to the crossbar switch.
The slave assignment is as follows:
Slave module
Slave port number
Flash memory controller
0
SRAM controller
1
Peripheral bridge 0
2
3.4.7 Peripheral Bridge Configuration
Transfers
AIPS-Lite
peripheral bridge
Transfers
Peripherals
Crossbar switch
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
Figure 3-10. Peripheral bridge configuration
Table 3-18. Reference links to related information
Topic
Related module
Reference
Full description
Peripheral bridge
(AIPS-Lite)
Peripheral bridge (AIPS-Lite)
System memory map
System memory map
Clocking
Clock Distribution
Crossbar switch
Crossbar switch
Crossbar switch
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System Modules
3.4.7.1 Number of peripheral bridges
This device contains one peripheral bridge.
3.4.7.2 Memory maps
The peripheral bridges are used to access the registers of most of the modules on this
device. See AIPS0 Memory Map for the memory slot assignment for each module.
3.4.8 DMA request multiplexer configuration
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
Peripheral
bridge 0
Register
access
DMA controller
Requests
Channel
request
DMA Request
Multiplexer
Module
Module
Module
Figure 3-11. DMA request multiplexer configuration
Table 3-19. Reference links to related information
Topic
Related module
Reference
Full description
DMA request
multiplexer
DMA Mux
System memory map
System memory map
Clocking
Clock distribution
Power management
Channel request
Requests
Power management
DMA controller
DMA Controller
DMA request sources
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Chapter 3 Chip Configuration
3.4.8.1 DMA MUX Request Sources
This device includes a DMA request mux that allows up to 63 DMA request signals to be
mapped to any of the 4 DMA channels. Because of the mux there is no hard correlation
between any of the DMA request sources and a specific DMA channel. Some of the
modules support Asynchronous DMA operation as indicated by the last column in the
following DMA source assignment table.
Table 3-20. DMA request sources - MUX 0
Source
number
Source module
Source description
Async DMA
capable
0
—
Channel disabled1
1
Reserved
Not used
2
UART0
Receive
Yes
3
UART0
Transmit
Yes
4
Reserved
—
5
Reserved
—
6
Reserved
—
7
Reserved
—
8
Reserved
—
9
Reserved
—
10
Reserved
—
11
Reserved
—
12
Reserved
—
13
Reserved
—
14
Reserved
—
15
Reserved
—
16
SPI0
Receive
17
SPI0
Transmit
18
Reserved
—
19
Reserved
—
20
Reserved
—
21
Reserved
—
22
I2C0
—
23
Reserved
—
24
TPM0
Channel 0
Yes
25
TPM0
Channel 1
Yes
26
TPM0
Channel 2
Yes
27
TPM0
Channel 3
Yes
28
TPM0
Channel 4
Yes
29
TPM0
Channel 5
Yes
30
Reserved
—
Table continues on the next page...
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System Modules
Table 3-20. DMA request sources - MUX 0 (continued)
Source
number
Source module
Source description
Async DMA
capable
31
Reserved
—
32
TPM1
Channel 0
Yes
33
TPM1
Channel 1
Yes
34
Reserved
—
35
Reserved
—
36
Reserved
—
37
Reserved
—
38
Reserved
—
39
Reserved
—
40
ADC0
—
41
Reserved
—
42
CMP0
—
43
Reserved
—
44
Reserved
—
45
Reserved
—
46
Reserved
—
47
Reserved
—
48
Reserved
—
49
Port control module
Port A
Yes
50
Port control module
Port B
Yes
51
Reserved
—
52
Reserved
—
53
Reserved
—
54
TPM0
Overflow
Yes
55
TPM1
Overflow
Yes
56
Reserved
—
57
Reserved
—
58
Reserved
—
59
Reserved
—
60
DMA MUX
Always enabled
61
DMA MUX
Always enabled
62
DMA MUX
Always enabled
63
DMA MUX
Always enabled
Yes
Yes
1. Configuring a DMA channel to select source 0 or any of the reserved sources disables that DMA channel.
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Chapter 3 Chip Configuration
3.4.8.2 DMA transfers via PIT trigger
The PIT module can trigger a DMA transfer on the first two DMA channels. The
assignments are detailed at PIT/DMA Periodic Trigger Assignments .
3.4.9 DMA Controller Configuration
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
Peripheral
bridge 0
Transfers
DMA Controller
Requests
DMA Multiplexer
Crossbar switch
Register
access
Figure 3-12. DMA Controller configuration
Table 3-21. Reference links to related information
Topic
Related module
Reference
Full description
DMA controller
DMA controller
System memory map
System memory map
Clocking
Clock distribution
Power management
Crossbar switch
Power management
Crossbar switch
Requests
Crossbar switch
DMA request sources
3.4.10 Computer Operating Properly (COP) Watchdog
Configuration
This section summarizes how the module has been configured in the chip.
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System Modules
Peripheral
bridge 0
Mode Controller
Register
access
WDOG
Figure 3-13. COP watchdog configuration
Table 3-22. Reference links to related information
Topic
Related module
Reference
Clocking
Clock distribution
Power management
Power management
Programming model
System Integration
Module (SIM)
SIM
3.4.10.1 COP clocks
The two clock inputs for the COP are the 1 kHz clock and the bus clock.
3.4.10.2 COP watchdog operation
The COP watchdog is intended to force a system reset when the application software fails
to execute as expected. To prevent a system reset from the COP timer (when it is
enabled), application software must reset the COP counter periodically. If the application
program gets lost and fails to reset the COP counter before it times out, a system reset is
generated to force the system back to a known starting point.
After any reset, the COP watchdog is enabled. If the COP watchdog is not used in an
application, it can be disabled by clearing COPCTRL[COPT] in the SIM.
The COP counter is reset by writing 0x55 and 0xAA (in that order) to the address of the
SIM's Service COP (SRVCOP) register during the selected timeout period. Writes do not
affect the data in the SRVCOP register. As soon as the write sequence is complete, the
COP timeout period is restarted. If the program fails to perform this restart during the
timeout period, the microcontroller resets. Also, if any value other than 0x55 or 0xAA is
written to the SRVCOP register, the microcontroller immediately resets.
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Chapter 3 Chip Configuration
The SIM's COPCTRL[COPCLKS] field selects the clock source used for the COP timer.
The clock source options are either the bus clock or an internal 1 kHz clock source. With
each clock source, there are three associated timeouts controlled by COPCTRL[COPT].
The following table summarizes the control functions of the COPCLKS and COPT bits.
The COP watchdog defaults to operation from the 1 kHz clock source and the longest
timeout for that clock source (210 cycles).
Table 3-23. COP configuration options
Control Bits
Clock Source
COP Window Opens
COP Overflow Count
COPCTRL[COPCLKS]
COPCTRL[COPT]
N/A
00
N/A
N/A
COP is disabled
0
01
1 kHz
N/A
25 cycles (32 ms)
0
10
1 kHz
N/A
28 cycles (256 ms)
0
11
1 kHz
N/A
210 cycles (1024 ms)
1
01
Bus
6,144 cycles
213 cycles
1
10
Bus
49,152 cycles
216 cycles
1
11
Bus
196,608 cycles
218 cycles
(COPCTRL[COPW]=1)
After the bus clock source is selected, windowed COP operation is available by setting
COPCTRL[COPW] in the SIM. In this mode, writes to the SRVCOP register to clear the
COP timer must occur in the last 25% of the selected timeout period. A premature write
immediately resets the chip. When the 1 kHz clock source is selected, windowed COP
operation is not available.
The COP counter is initialized by the first writes to the SIM's COPCTRL register and
after any system reset. Subsequent writes to the SIM's COPCTRL register have no effect
on COP operation. Even if an application uses the reset default settings of the COPT,
COPCLKS, and COPW bits, the user should write to the write-once COPCTRL register
during reset initialization to lock in the settings. This approach prevents accidental
changes if the application program becomes lost.
The write to the SRVCOP register that services (clears) the COP counter should not be
placed in an interrupt service routine (ISR) because the ISR could continue to be
executed periodically even if the main application program fails.
If the bus clock source is selected, the COP counter does not increment while the
microcontroller is in debug mode or while the system is in stop (including VLPS or LLS)
mode. The COP counter resumes when the microcontroller exits debug mode or stop
mode.
If the 1 kHz clock source is selected, the COP counter is re-initialized to zero upon entry
to either debug mode or stop (including VLPS or LLS) mode. The counter begins from
zero upon exit from debug mode or stop mode.
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Clock Modules
Regardless of the clock selected, the COP is disabled when the chip enters a VLLSx
mode. Upon a reset that wakes the chip from the VLLSx mode, the COP is re-initialized
and enabled as for any reset.
3.4.10.3 Clock Gating
This family of devices includes clock gating control for each peripheral, that is, the clock
to each peripheral can explicitly be gated on or off, using clock-gate control bits in the
SIM module.
3.5 Clock Modules
3.5.1 MCG Configuration
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
Peripheral
bridge
System integration
module (SIM)
System
oscillator
Register
access
Multipurpose Clock
Generator (MCG)
Figure 3-14. MCG configuration
Table 3-24. Reference links to related information
Topic
Related module
Reference
Full description
MCG
MCG
System memory map
System memory map
Clocking
Clock distribution
Power management
Power management
Signal multiplexing
Port control
Signal multiplexing
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Chapter 3 Chip Configuration
3.5.1.1 MCG FLL modes
On L-series devices the MCGFLLCLK frequency is limited to 48 MHz max. The DCO is
limited to the two lowest range settings (MCG_C4[DRST_DRS] must be set to either
0b00 or 0b01).
3.5.2 OSC Configuration
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
Peripheral
bridge
Module signals
RTC
System oscillator
Signal multiplexing
MCG
Register
access
Figure 3-15. OSC configuration
Table 3-25. Reference links to related information
Topic
Related module
Reference
Full description
OSC
OSC
System memory map
System memory map
Clocking
Clock distribution
Power management
Power management
Signal multiplexing
Port control
Signal multiplexing
Full description
MCG
MCG
3.5.2.1 OSC modes of operation with MCG and RTC
The most common method of controlling the OSC block is through MCG clock source
selection MCG_C1[CLKS] and the MCG_C2 register bits to configure the oscillator
frequency range, gain-mode, and for crystal or external clock operation. The OSC_CR
also provides control for enabling the OSC and configuring internal load capacitors for
the EXTAL and XTAL pins. See the OSC and MCG chapters for more details.
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Memories and Memory Interfaces
The RTC_CR[OSCE] bit has overriding control over the MCG and OSC_CR enable
functions. When RTC_CR[OSCE] is set, the OSC is configured for low frequency, low
power and the RTC_CR[SCxP] bits override the OSC_CR[SCxP] bits to control the
internal capacitance configuration. See the RTC chapter for more details.
3.6 Memories and Memory Interfaces
3.6.1 Flash Memory Configuration
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
Peripheral bus
controller 0
Flash memory
controller
Register
access
Transfers
Flash memory
Figure 3-16. Flash memory configuration
Table 3-26. Reference links to related information
Topic
Related module
Reference
Full description
Flash memory
Flash memory
System memory map
System memory map
Clocking
Clock Distribution
Transfers
Flash memory
controller
Flash memory controller
Register access
Peripheral bridge
Peripheral bridge
3.6.1.1 Flash Memory Sizes
The devices covered in this document contain 1 program flash block consisting of 1 KB
sectors.
The amounts of flash memory for the devices covered in this document are:
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Chapter 3 Chip Configuration
Table 3-27. KL04 flash memory size
Device
Program flash (KB)
Block 0 (P-Flash) address range
MKL04Z8VFK4
8
0x0000_0000 – 0x0000_1FFF
MKL04Z16VFK4
16
0x0000_0000 – 0x0000_3FFF
MKL04Z32VFK4
32
0x0000_0000 – 0x0000_7FFF
MKL04Z8VLC4
8
0x0000_0000 – 0x0000_1FFF
MKL04Z16VLC4
16
0x0000_0000 – 0x0000_3FFF
MKL04Z32VLC4
32
0x0000_0000 – 0x0000_7FFF
MKL04Z8VFM4
8
0x0000_0000 – 0x0000_1FFF
MKL04Z16VFM4
16
0x0000_0000 – 0x0000_3FFF
MKL04Z32VFM4
32
0x0000_0000 – 0x0000_7FFF
MKL04Z16VLF4
16
0x0000_0000 – 0x0000_3FFF
MKL04Z32VLF4
32
0x0000_0000 – 0x0000_7FFF
3.6.1.2 Flash Memory Map
The flash memory and the flash registers are located at different base addresses as shown
in the following figure. The base address for each is specified in System memory map.
Flash memory base address
Registers
Program flash base address
Flash configuration field
Program flash
Figure 3-17. Flash memory map
The on-chip Flash is implemented in a portion of the allocated Flash range to form a
contiguous block in the memory map beginning at address 0x0000_0000. See Flash
Memory Sizes for details of supported ranges.
Accesses to the flash memory ranges outside the amount of Flash on the device causes
the bus cycle to be terminated with an error followed by the appropriate response in the
requesting bus master. Read collision events in which flash memory is accessed while a
flash memory resource is being manipulated by a flash command also generates a bus
error response.
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Memories and Memory Interfaces
3.6.1.3 Flash Security
How flash security is implemented on this device is described in Chip Security.
3.6.1.4 Flash Modes
The flash memory chapter defines two modes of operation - NVM normal and NVM
special modes. On this device, The flash memory only operates in NVM normal mode.
All references to NVM special mode should be ignored.
3.6.1.5 Erase All Flash Contents
In addition to software, the entire flash memory may be erased external to the flash
memory via the SW-DP debug port by setting MDM-AP CONTROL[0]. MDM-AP
STATUS[0] is set to indicate the mass erase command has been accepted. MDM-AP
STATUS[0] is cleared when the mass erase completes.
3.6.1.6 FTFA_FOPT Register
The flash memory's FTFA_FOPT register allows the user to customize the operation of
the MCU at boot time. See FOPT boot options for details of its definition.
3.6.2 Flash Memory Controller Configuration
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
See MCM_PLACR register description for details on the reset configuration of the FMC.
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Chapter 3 Chip Configuration
Transfers
Flash memory
controller
Transfers
Flash memory
Crossbar switch
MCM
Figure 3-18. Flash memory controller configuration
Table 3-28. Reference links to related information
Topic
Related module
Reference
Full description
Flash memory
controller
Flash memory controller
System memory map
System memory map
Clocking
Clock Distribution
Transfers
Flash memory
Flash memory
Transfers
Crossbar switch
Crossbar Switch
Register access
MCM
MCM
3.6.3 SRAM Configuration
This section summarizes how the module has been configured in the chip.
Transfers
SRAM upper
crossbar
Cortex-M0+
core
switch
SRAM
controller
SRAM lower
Figure 3-19. SRAM configuration
Table 3-29. Reference links to related information
Topic
Related module
Reference
Full description
SRAM
SRAM
System memory map
System memory map
Clocking
Clock Distribution
ARM Cortex-M0+ core
ARM Cortex-M0+ core
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Memories and Memory Interfaces
3.6.3.1 SRAM Sizes
This device contains SRAM which could be accessed by bus masters through the crossbar switch. The amount of SRAM for the devices covered in this document is shown in
the following table.
Table 3-30. KL04 SRAM memory size
Device
SRAM (KB)
MKL04Z8VFK4
1
MKL04Z16VFK4
2
MKL04Z32VFK4
4
MKL04Z8VLC4
1
MKL04Z16VLC4
2
MKL04Z32VLC4
4
MKL04Z8VFM4
1
MKL04Z16VFM4
2
MKL04Z32VFM4
4
MKL04Z16VLF4
2
MKL04Z32VLF4
4
3.6.3.2 SRAM Ranges
The on-chip SRAM is split into two ranges, 1/4 is allocated SRAM_L and 3/4 is allocated
to SRAM_U.
The on-chip RAM is implemented such that the SRAM_L and SRAM_U ranges form a
contiguous block in the memory map. As such:
• SRAM_L is anchored to 0x1FFF_FFFF and occupies the space before this ending
address.
• SRAM_U is anchored to 0x2000_0000 and occupies the space after this beginning
address.
Valid address ranges for SRAM_L and SRAM_U are then defined as:
• SRAM_L = [0x2000_0000–(SRAM_size/4)] to 0x1FFF_FFFF
• SRAM_U = 0x2000_0000 to [0x2000_0000+(SRAM_size*(3/4))-1]
This is illustrated in the following figure.
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SRAM size *(1/4)
Chapter 3 Chip Configuration
0x2000_0000 – SRAM_size/4
SRAM_L
SRAM size * (3/4)
0x1FFF_FFFF
0x2000_0000
SRAM_U
0x2000_0000 + SRAM_size(3/4) - 1
Figure 3-20. SRAM blocks memory map
For example, for a device containing 16 KB of SRAM the ranges are:
• SRAM_L: 0x1FFF_F000 – 0x1FFF_FFFF
• SRAM_U: 0x2000_0000 – 0x2000_2FFF
3.6.3.3 SRAM retention in low power modes
The SRAM is retained down to VLLS3 mode. In VLLS1 and VLLS0 no SRAM is
retained.
3.7 Analog
3.7.1 12-bit SAR ADC Configuration
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
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Analog
Peripheral bus
controller 0
Module signals
12-bit SAR ADC
Other peripherals
Signal multiplexing
Register
access
Figure 3-21. 12-bit SAR ADC configuration
Table 3-31. Reference links to related information
Topic
Related module
Reference
Full description
12-bit SAR ADC
12-bit SAR ADC
System memory map
System memory map
Clocking
Clock distribution
Power management
Power management
Signal multiplexing
Port control
Signal multiplexing
3.7.1.1 ADC Instantiation Information
This device contains one 12-bit successive approximation ADC with up to 14-channels.
The ADC supports both software and hardware triggers. The hardware trigger sources are
listed in the Module-to-Module section.
The number of ADC channels present on the device is determined by the pinout of the
specific device package and is shown in the following table.
Table 3-32. Number of KL04 ADC channels
Device
Number of ADC channels
MKL04Z8VFK4
12
MKL04Z16VFK4
12
MKL04Z32VFK4
12
MKL04Z8VLC4
14
MKL04Z16VLC4
14
MKL04Z32VLC4
14
MKL04Z8VFM4
14
MKL04Z16VFM4
14
MKL04Z32VFM4
14
MKL04Z16VLF4
14
Table continues on the next page...
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Chapter 3 Chip Configuration
Table 3-32. Number of KL04 ADC channels (continued)
Device
Number of ADC channels
MKL04Z32VLF4
14
3.7.1.2 DMA Support on ADC
Applications may require continuous sampling of the ADC that may have considerable
load on the CPU. The ADC supports DMA request functionality for higher performance
when the ADC is sampled at a very high rate. The ADC can trigger the DMA (via DMA
req) on conversion completion.
3.7.1.3 ADC0 Connections/Channel Assignment
3.7.1.3.1
ADC0 Channel Assignment
ADC Channel
(SC1n[ADCH])
Channel
Input signal
(SC1n[DIFF]= 1)
Input signal
(SC1n[DIFF]= 0)
00000
AD0
Reserved
ADC0_SE0
00001
AD1
Reserved
ADC0_SE1
00010
AD2
Reserved
ADC0_SE2
00011
AD3
Reserved
ADC0_SE3
00100
AD4
Reserved
ADC0_SE4
00101
AD5
Reserved
ADC0_SE5
00110
AD6
Reserved
ADC0_SE6
00111
AD7
Reserved
ADC0_SE7
01000
AD8
Reserved
ADC0_SE8
01001
AD9
Reserved
ADC0_SE9
01010
AD10
Reserved
ADC0_SE10
01011
AD11
Reserved
ADC0_SE11
01100
AD12
Reserved
ADC0_SE12
01101
AD13
Reserved
ADC0_SE13
01110
AD14
Reserved
Reserved
01111
AD15
Reserved
Reserved
10000
AD16
Reserved
Reserved
10001
AD17
Reserved
Reserved
10010
AD18
Reserved
Reserved
10011
AD19
Reserved
Reserved
10100
AD20
Reserved
Reserved
Table continues on the next page...
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Analog
ADC Channel
(SC1n[ADCH])
Channel
Input signal
(SC1n[DIFF]= 1)
Input signal
(SC1n[DIFF]= 0)
10101
AD21
Reserved
Reserved
10110
AD22
Reserved
Reserved
10111
AD23
Reserved
Reserved
11000
AD24
Reserved
Reserved
11001
AD25
Reserved
Reserved
11010
AD26
Temperature Sensor (Diff)
Temperature Sensor (S.E)
11011
AD27
Bandgap (Diff)1
Bandgap (S.E)1
11100
AD28
Reserved
Reserved
11101
AD29
-VREFH (Diff)
VREFH (S.E)
11110
AD30
Reserved
VREFL
11111
AD31
Module Disabled
Module Disabled
1. This is the PMC bandgap 1V reference voltage. Prior to reading from this ADC channel, ensure that you enable the
bandgap buffer by setting the PMC_REGSC[BGBE] bit. Refer to the device data sheet for the bandgap voltage (VBG)
specification.
3.7.1.4 ADC Analog Supply and Reference Connections
This device internally connects VDDA to VDD and VSSA to VSS.
This device contains separate VREFH and VREFL pins on 32-pin and higher devices.
These pins are internally connected to VDD and VSS respectively, on packages less than
32-pin.
3.7.1.5 ADC Reference Options
The ADC supports the following references:
• VREFH/VREFL - connected as the primary reference option
• VDDA - connected as the VALT reference option
3.7.1.6 Alternate clock
For this device, the alternate clock is connected to OSCERCLK.
NOTE
This clock option is only usable when OSCERCLK is in the
MHz range. A system with OSCERCLK in the kHz range has
the optional clock source below minimum ADC clock operating
frequency.
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Chapter 3 Chip Configuration
3.7.2 CMP Configuration
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
Peripheral
bridge 0
Other peripherals
CMP
Module signals
Signal multiplexing
Register
access
Figure 3-22. CMP configuration
Table 3-33. Reference links to related information
Topic
Related module
Full description
Comparator (CMP)
Reference
Comparator
System memory map
System memory map
Clocking
Clock distribution
Power management
Power management
Signal multiplexing
Port control
Signal multiplexing
3.7.2.1 CMP Instantiation Information
The device includes one high speed comparator and two 8-input multiplexors for both the
inverting and non-inverting inputs of the comparator. Each CMP input channel connects
to both muxes. Two of the channels are connected to internal sources, leaving resources
to support up to 6 input pins. See the channel assignment table for a summary of CMP
input connections for this device.
The CMP also includes one 6-bit DAC with a 64-tap resistor ladder network, which
provides a selectable voltage reference for applications where voltage reference is needed
for internal connection to the CMP.
The CMP can be optionally on in all modes except VLLS0.
The CMP has several module to module interconnects in order to facilitate ADC
triggering, TPM triggering and UART IR interfaces. For complete details on the CMP
module interconnects please refer to the Module-to-Module section.
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Analog
The CMP does not support window compare function and CMP_CR1[WE] must always
be written to 0. The sample function has limited functionality since the SAMPLE input to
the block is not connected to a valid input. Usage of sample operation is limited to a
divided version of the bus clock (CMP_CR1[SE] = 0).
Due to the pin number limitation, the CMP pass through mode is not supported by this
device, so the CMPx_MUXCR[PSTM] must be left as 0.
3.7.2.2 CMP input connections
The following table shows the fixed internal connections to the CMP.
Table 3-34. CMP input connections
CMP Inputs
CMP0
IN0
CMP0_IN0
IN1
CMP0_IN1
IN2
CMP0_IN2
IN3
CMP0_IN3
IN4
—
IN5
—
IN6
Bandgap1
IN7
6-bit DAC0 reference
1. This is the PMC bandgap 1V reference voltage. Prior to using as CMP input, ensure that you enable the bandgap buffer by
setting the PMC_REGSC[BGBE] bit. Refer to the device data sheet for the bandgap voltage (VBG) specification.
3.7.2.3 CMP external references
The 6-bit DAC sub-block supports selection of two references. For this device, the
references are connected as follows:
• VREFH - Vin1 input. When using VREFH, any ADC conversion using this same
reference at the same time is negatively impacted.
• VDD - Vin2 input
3.7.2.4 CMP trigger mode
The CMP and 6-bit DAC sub-block supports trigger mode operation when the
CMP_CR1[TRIGM] is set. When trigger mode is enabled, the trigger event will initiate a
compare sequence that must first enable the CMP and DAC prior to performing a CMP
operation and capturing the output. In this device, control for this two staged sequencing
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Chapter 3 Chip Configuration
is provided from the LPTMR. The LPTMR triggering output is always enabled when the
LPTMR is enabled. The first signal is supplied to enable the CMP and DAC and is
asserted at the same time as the TCF flag is set. The delay to the second signal that
triggers the CMP to capture the result of the compare operation is dependent on the
LPTMR configuration. In Time Counter mode with prescaler enabled, the delay is 1/2
Prescaler output period. In Time Counter mode with prescaler bypassed, the delay is 1/2
Prescaler clock period.
The delay between the first signal from LPTMR and the second signal from LPTMR
must be greater than the Analog comparator initialization delay as defined in the device
datasheet.
3.8 Timers
3.8.1 Timer/PWM Module Configuration
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
Peripheral bus
controller 0
Other peripherals
TPM
Module signals
Signal multiplexing
Register
access
Figure 3-23. TPM configuration
Table 3-35. Reference links to related information
Topic
Related module
Reference
Full description
Timer/PWM Module
Timer/PWM Module
System memory map
System memory map
Clocking
Clock distribution
Power management
Power management
Signal multiplexing
Port control
Signal multiplexing
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Timers
3.8.1.1 TPM Instantiation Information
This device contains two Low Power TPM modules (TPM). All TPM modules in the
device only are configured as basic TPM function, and no quadrature decoder function
and all can be functional in Stop/VLPS mode. The clock source is either external or
internal in Stop/VLPS mode.
The following table shows how these modules are configured.
Table 3-36. TPM configuration
TPM instance
Number of channels
Features/usage
TPM0
6
Basic TPM,functional in Stop/VLPS mode
TPM1
2
Basic TPM,functional in Stop/VLPS mode
There are several connections to and from the TPMs in order to facilitate customer use
cases. For complete details on the TPM module interconnects please refer to the Moduleto-Module section.
3.8.1.2 Clock Options
The TPM blocks are clocked from a single TPM clock that can be selected from
OSCERCLK, MCGIRCLK, or MCGFLLCLK. The selected source is controlled by
SIM_SOPT2[TPMSRC] control registers.
Each TPM also supports an external clock mode (TPM_SC[CMOD]=1x) in which the
counter increments after a synchronized (to the selected TPM clock source) rising edge
detect of an external clock input. The available external clock (either TPM_CLKIN0 or
TPM_CLKIN1) is selected by SIM_SOPT4[TPMxCLKSEL] control register. To
guarantee valid operation the selected external clock must be less than half the frequency
of the selected TPM clock source.
3.8.1.3 Trigger Options
Each TPM has a selectable trigger input source controlled by the
TPMx_CONF[TRGSEL] field to use for starting the counter and/or reloading the
counter. The options available are shown in the following table.
Table 3-37. TPM trigger options
TPMx_CONF[TRGSEL]
Selected source
0000
External trigger pin input (EXTRG_IN)
Table continues on the next page...
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Chapter 3 Chip Configuration
Table 3-37. TPM trigger options (continued)
TPMx_CONF[TRGSEL]
Selected source
0001
CMP0 output
0010
Reserved
0011
Reserved
0100
PIT trigger 0
0101
PIT trigger 1
0110
Reserved
0111
Reserved
1000
TPM0 overflow
1001
TPM1 overflow
1010
Reserved
1011
Reserved
1100
RTC alarm
1101
RTC seconds
1110
LPTMR trigger
1111
Reserved
3.8.1.4 Global Timebase
Each TPM has a global timebase feature controlled by the TPMx_CONF[GTBEEN] bit.
TPM1 is configured as the global time when this option is enabled.
3.8.1.5 TPM Interrupts
The TPM has multiple sources of interrupt. However, these sources are OR'd together to
generate a single interrupt request to the interrupt controller. When an TPM interrupt
occurs, read the TPM status registers to determine the exact interrupt source.
3.8.2 PIT Configuration
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
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Timers
Peripheral
bridge
Register
access
Periodic interrupt
timer
Figure 3-24. PIT configuration
Table 3-38. Reference links to related information
Topic
Related module
Reference
Full description
PIT
PIT
System memory map
System memory map
Clocking
Clock Distribution
Power management
Power management
3.8.2.1 PIT/DMA Periodic Trigger Assignments
The PIT generates periodic trigger events to the DMA channel mux as shown in the table
below.
Table 3-39. PIT channel assignments for periodic DMA triggering
PIT Channel
DMA Channel Number
PIT Channel 0
DMA Channel 0
PIT Channel 1
DMA Channel 1
3.8.2.2 PIT/ADC Triggers
PIT triggers are selected as ADCx trigger sources using the SOPT7[ADCxTRGSEL] bits
in the SIM module. For more details, refer to SIM chapter.
3.8.2.3 PIT/TPM Triggers
PIT triggers are selected as TPMx trigger sources using the TPMx_CONF[TRGSEL] bits
in the TPM module. For more details, refer to TPM chapter.
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Chapter 3 Chip Configuration
3.8.2.4 PIT/DAC Triggers
PIT Channel 0 is configured as the DAC hardware trigger source. For more details, refer
to DAC chapter.
3.8.3 Low-power timer configuration
Peripheral
bridge
Low-power timer
Module signals
Signal multiplexing
Register
access
Figure 3-25. LPT configuration
Table 3-40. Reference links to related information
Topic
Related module
Reference
Full description
Low-power timer
Low-power timer
System memory map
System memory map
Clocking
Clock Distribution
Power management
Power management
Signal Multiplexing
Port control
Signal Multiplexing
3.8.3.1 LPTMR Instantiation Information
The low-power timer (LPTMR) allows operation during all power modes. The LPTMR
can operate as a real-time interrupt or pulse accumulator. It includes a 15-bit prescaler
(real-time interrupt mode) or glitch filter (pulse accumulator mode).
The LPTMR can be clocked from the internal reference clock, the internal 1 kHz LPO,
OSCERCLK, or an external 32.768 kHz crystal. In VLLS0 mode, the clocking option is
limited to an external pin with the OSC configured for bypass (external clock) operation.
An interrupt is generated (and the counter may reset) when the counter equals the value
in the 16-bit compare register.
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Timers
3.8.3.2 LPTMR pulse counter input options
The LPTMR_CSR[TPS] bitfield configures the input source used in pulse counter mode.
The following table shows the chip-specific input assignments for this bitfield.
LPTMR_CSR[TPS]
Pulse counter input number
Chip input
00
0
CMP0 output
01
1
LPTMR_ALT1 pin
10
2
LPTMR_ALT2 pin
11
3
LPTMR_ALT3 pin
3.8.3.3 LPTMR prescaler/glitch filter clocking options
The prescaler and glitch filter of the LPTMR module can be clocked from one of four
sources determined by the LPTMR0_PSR[PCS] bitfield. The following table shows the
chip-specific clock assignments for this bitfield.
NOTE
The chosen clock must remain enabled if the LPTMR is to
continue operating in all required low-power modes.
LPTMR0_PSR[PCS]
Prescaler/glitch filter clock
number
Chip clock
00
0
MCGIRCLK — internal reference clock
(not available in LLS and VLLS modes)
01
1
LPO — 1 kHz clock (not available in
VLLS0 mode)
10
2
ERCLK32K (not available in VLLS0
mode when using 32 kHz oscillator)
11
3
OSCERCLK — external reference clock
(not available in VLLS0 mode)
See Clock Distribution for more details on these clocks.
3.8.4 RTC configuration
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
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Chapter 3 Chip Configuration
Peripheral
bridge
Module signals
Real-time clock
Signal multiplexing
Register
access
Figure 3-26. RTC configuration
Table 3-41. Reference links to related information
Topic
Related module
Reference
Full description
RTC
RTC
System memory map
System memory map
Clocking
Clock Distribution
Power management
Power management
3.8.4.1 RTC Instantiation Information
RTC prescaler is clocked by ERCLK32K.
RTC is reset on POR Only.
RTC_CR[OSCE] can override the configuration of the System OSC, configuring the
OSC for 32 kHz crystal operation in all power modes except VLLS0, and through any
System Reset. When OSCE is enabled, the RTC also overrides the capacitor
configurations.
3.8.4.2 RTC_CLKOUT options
RTC_CLKOUT pin can be driven either with the RTC 1 Hz output or with the
OSCERCLK on-chip clock source. Control for this option is through
SIM_SOPT2[RTCCLKOUTSEL] bit.
When RTCCLKOUTSEL = 0, the RTC 1 Hz clock is output is selected on the
RTC_CLKOUT pin. When RTCCLKOUTSEL = 1, OSCERCLK clock is output on the
RTC_CLKOUT pin.
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Communication interfaces
3.9 Communication interfaces
3.9.1 SPI configuration
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
Peripheral
bridge
SPI
Module signals
Signal multiplexing
Register
access
Figure 3-27. SPI configuration
Table 3-42. Reference links to related information
Topic
Related module
Reference
Full description
SPI
SPI
System memory map
System memory map
Clocking
Clock Distribution
Signal Multiplexing
Port control
Signal Multiplexing
3.9.1.1 SPI Instantiation Information
This device contains one SPI module that supports 8-bit data length.
SPI0 is clocked on the bus clock.
The SPI supports DMA request and can operate in VLPS mode. When the SPI is
operating in VLPS mode, it will operate as a slave.
SPI can wakeup MCU from VLPS mode upon reception of SPI data in slave mode.
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Chapter 3 Chip Configuration
3.9.2 I2C Configuration
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
Peripheral
bridge
I2 C
Module signals
Signal multiplexing
Register
access
Figure 3-28. I2C configuration
Table 3-43. Reference links to related information
Topic
Related module
Reference
Full description
I2C
I2C
System memory map
System memory map
Clocking
Clock Distribution
Power management
Power management
Signal Multiplexing
Port control
Signal Multiplexing
3.9.2.1 IIC Instantiation Information
This device has one IIC module.
When the package pins associated with IIC have their mux select configured for IIC
operation, the pins (SCL and SDA) are driven in a pseudo open drain configuration.
The digital glitch filter implemented in the IIC0 module, controlled by the
I2C0_FLT[FLT] registers, is clocked from the bus clock and thus has filter granularity in
bus clock cycle counts.
3.9.3 UART Configuration
This section summarizes how the module has been configured in the chip. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
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Communication interfaces
Peripheral
bridge
Module signals
UART
Signal multiplexing
Register
access
Figure 3-29. UART configuration
Table 3-44. Reference links to related information
Topic
Related module
Reference
Full description
UART0
UART
System memory map
System memory map
Clocking
Clock Distribution
Power management
Power management
Signal Multiplexing
Port control
Signal Multiplexing
3.9.3.1 UART0 overview
The UART0 module supports basic UART with DMA interface function, x4 to x32
oversampling of baud-rate.
This module supports LIN slave operation.
The module can remain functional in VLPS mode provided the clock it is using remains
enabled.
ISO7816 protocol is intended to be handled in software for this product. To support smart
card reading, TxD pin can be configured as pseudo open drain for 1-wire half-duplex like
ISO7816 communication via the SIM_SOPT5[UART0ODE] bit.
3.9.3.2 UART1 and UART2 Overview
This device contains two basic universal asynchronous receiver/transmitter (UART)
modules with DMA function support. Generally, these modules are used in RS-232,
RS-485, and other communications. This module supports LIN Slave operation.
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Chapter 3 Chip Configuration
3.10 Human-machine interfaces (HMI)
3.10.1 GPIO Configuration
Peripheral
bridge
Register access
Module signals
GPIO controller
Signal multiplexing
ARM Cortex -M0+
Core
Register
access
Figure 3-30. GPIO configuration
Table 3-45. Reference links to related information
Topic
Related module
Reference
Full description
GPIO
GPIO
System memory map
System memory map
Clocking
Clock Distribution
Power management
Power management
Crossbar switch
Crossbar switch
Crossbar switch
Signal Multiplexing
Port control
Signal Multiplexing
3.10.1.1 GPIO Instantiation Information
The device includes four pins, PTB0, PTB1, PTA12, and PTA13, with high current drive
capability. These pins can be used to drive LED or power MOSFET directly. The high
drive capability applies to all functions which are multiplexed on these pins (UART,
TPM, SPI...etc)
3.10.1.1.1
Pull Devices and Directions
The pull devices are enabled out of POR only on RESET_B, NMI_b and respective SWD
signals. Other pins can be enabled by writing to PORTx_PCRn[PE] field.
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Human-machine interfaces (HMI)
All the pins are hard wired to be pullup except for SWD_CLK. The state will be reflected
in the PORTx_PCRn[PS] field.
3.10.1.2 Port Control and Interrupt Summary
The following table provides more information regarding the Port Control and Interrupt
configurations .
Table 3-46. Ports Summary
Feature
Port A
Port B
Pull Select control
No
No
Pull Select at reset
PTA0=Pull down, Others=Pull up
Pull up
Pull Enable control
Yes
Yes
Pull Enable at reset
PTA0/PTA2/RESET_b=Enabled;
Others=Disabled
PTB5=Enabled; Others=Disabled
Slew Rate Enable control
No
No
Slew Rate Enable at reset
PTA2/PTA6/PTA7/PTA15=Disabled;
Others=Enabled
PTB0/PTB15/PTB16/PTB17= Disabled;
Others=Enabled
Passive Filter Enable control
RESET_b only
PTB5 only
Passive Filter Enable at reset
RESET_b=Enabled; Others=Disabled
Disabled
Open Drain Enable control1
No
No
Open Drain Enable at reset
Disabled
Disabled
Drive Strength Enable control
PTA12/PTA13 only
PTB0/PTB1 only
Drive Strength Enable at reset
Disabled
Disabled
Pin Mux control
Yes
Yes
Pin Mux at reset
PTA0/PTA2=ALT3; Others=ALT0
PTB5=ALT3; Others=ALT0
No
No
PTA0/PTA1/PTA7/PTA10/PTA11/
PTA12/PTA16/PTA17/PTA18 only
PTB0/PTB1/PTB2/PTB3/PTB4/PTB5/
PTB6/PTB7/PTB14 only
No
No
Lock Bit
Interrupt and DMA Request
Digital Glitch Filter
1. UART signals can be configured for open-drain using SIM_SOPT5 register. IIC signals are automatically enabled for open
drain when selected.
3.10.1.3 GPIO accessibility in the memory map
The GPIO is multi-ported and can be accessed directly by the core with zero wait states at
base address 0xF800_0000. It can also be accessed by the core and DMA masters
through the cross bar/AIPS interface at 0x400F_F000 and at an aliased slot (15) at
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Chapter 3 Chip Configuration
address 0x4000_F000. All BME operations to the GPIO space can be accomplished
referencing the aliased slot (15) at address 0x4000_F000. Only some of the BME
operations can be accomplished referencing GPIO at address 0x400F_F000.
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Human-machine interfaces (HMI)
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Chapter 4
Memory Map
4.1 Introduction
This device contains various memories and memory-mapped peripherals which are
located in a 4 GB memory space. This chapter describes the memory and peripheral
locations within that memory space.
4.2 System memory map
The following table shows the high-level device memory map.
Table 4-1. System memory map
System 32-bit Address Range
0x0000_0000–0x07FF_FFFF1
Destination Slave
Program flash and read-only data
Access
All masters
(Includes exception vectors in first 196 bytes)
0x0800_0000–0x1FFF_FBFF
Reserved
—
0x1FFF_FC00-0x1FFF_FFFF2
SRAM_L: Lower SRAM
All masters
0x2000_0000-0x2000_0BFF2
SRAM_U: Upper SRAM
All masters
0x2000_0C00–0x3FFF_FFFF
Reserved
–
0x4000_0000–0x4007_FFFF
AIPS Peripherals
Cortex-M0+ core &
DMA
0x4008_0000–0x400F_EFFF
Reserved
–
0x400F_F000–0x400F_FFFF
General purpose input/output (GPIO)
Cortex-M0+ core &
DMA
0x4010_0000–0x43FF_FFFF
Reserved
–
0x4400_0000–0x5FFF_FFFF
Bit Manipulation Engine (BME) access to AIPS Peripherals for Cortex-M0+ core
slots 0-1273
0x6000_0000–0xDFFF_FFFF
Reserved
–
0xE000_0000–0xE00F_FFFF
Private Peripherals
Cortex-M0+ core
0xE010_0000–0xEFFF_FFFF
Reserved
–
0xF000_0000–0xF000_0FFF
Micro Trace Buffer (MTB) registers
Cortex-M0+ core
Table continues on the next page...
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Flash Memory Map
Table 4-1. System memory map (continued)
System 32-bit Address Range
Destination Slave
Access
0xF000_1000–0xF000_1FFF
MTB Data Watchpoint and Trace (MTBDWT) registers
Cortex-M0+ core
0xF000_2000–0xF000_2FFF
ROM table
Cortex-M0+ core
0xF000_3000–0xF000_3FFF
Miscellaneous Control Module (MCM)
Cortex-M0+ core
0xF000_4000–0xF7FF_FFFF
Reserved
–
0xF800_0000–0xFFFF_FFFF
IOPORT: GPIO (single cycle)
Cortex-M0+ core
1. The program flash always begins at 0x0000_0000 but the end of implemented flash varies depending on the amount of
flash implemented for a particular device. See Flash Memory Sizes for details.
2. This range varies depending on SRAM sizes. See SRAM Ranges for details.
3. Includes BME operations to GPIO at slot 15 (based at 0x4000_F000).
4.3 Flash Memory Map
The flash memory and the flash registers are located at different base addresses as shown
in the following figure. The base address for each is specified in System memory map.
Flash memory base address
Registers
Program flash base address
Flash configuration field
Program flash
Figure 4-1. Flash memory map
The on-chip Flash is implemented in a portion of the allocated Flash range to form a
contiguous block in the memory map beginning at address 0x0000_0000. See Flash
Memory Sizes for details of supported ranges.
Accesses to the flash memory ranges outside the amount of Flash on the device causes
the bus cycle to be terminated with an error followed by the appropriate response in the
requesting bus master. Read collision events in which flash memory is accessed while a
flash memory resource is being manipulated by a flash command also generates a bus
error response.
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Chapter 4 Memory Map
4.3.1 Alternate Non-Volatile IRC User Trim Description
The following non-volatile locations (4 bytes) are reserved for custom IRC user trim
supported by some development tools. An alternate IRC trim to the factory loaded trim
can be stored at this location. To override the factory trim, user software must load new
values into the MCG trim registers.
Non-Volatile Byte Address
Alternate IRC Trim Value
0x0000_03FC
Reserved
0x0000_03FD
Reserved
0x0000_03FE (bit 0)
SCFTRIM
0x0000_03FE (bit 4:1)
FCTRIM
0x0000_03FF
SCTRIM
4.4 SRAM memory map
The on-chip RAM is split between SRAM_L and SRAM_U. The RAM is also
implemented such that the SRAM_L and SRAM_U ranges form a contiguous block in
the memory map. See SRAM Ranges for details.
Accesses to the SRAM_L and SRAM_U memory ranges outside the amount of RAM on
the device causes the bus cycle to be terminated with an error followed by the appropriate
response in the requesting bus master.
4.5 Bit Manipulation Engine
The Bit Manipulation Engine (BME) provides hardware support for atomic read-modifywrite memory operations to the peripheral address space. By combining the basic load
and store instruction support in the Cortex-M instruction set architecture with the concept
of decorated storage provided by the BME, the resulting implementation provides a
robust and efficient read-modify-write capability to this class of ultra low-end
microcontrollers. See the Bit Manipulation Engine Block Guide (BME) for a detailed
description of BME functionality.
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Peripheral bridge (AIPS-Lite) memory map
4.6 Peripheral bridge (AIPS-Lite) memory map
The peripheral memory map is accessible via one slave port on the crossbar in the
0x4000_0000–0x400F_FFFF region. The device implements one peripheral bridge that
defines a 1024 KB address space.
The three regions associated with this space are:
• A 128 KB region, partitioned as 32 spaces, each 4 KB in size and reserved for onplatform peripheral devices. The AIPS controller generates unique module enables
for all 32 spaces.
• A 384 KB region, partitioned as 96 spaces, each 4 KB in size and reserved for offplatform modules. The AIPS controller generates unique module enables for all 96
spaces.
• The last slot is a 4 KB region beginning at 0x400F_F000 for accessing the GPIO
module. The GPIO slot (slot 128) is an alias of slot 15. This block is also directly
interfaced to the core and provides direct access without incurring wait states
associated with accesses via the AIPS controller.
Modules that are disabled via their clock gate control bits in the SIM registers disable the
associated AIPS slots. Access to any address within an unimplemented or disabled
peripheral bridge slot results in a transfer error termination.
For programming model accesses via the peripheral bridges, there is generally only a
small range within the 4 KB slots that is implemented. Accessing an address that is not
implemented in the peripheral results in a transfer error termination.
4.6.1 Read-after-write sequence and required serialization of
memory operations
In some situations, a write to a peripheral must be completed fully before a subsequent
action can occur. Examples of such situations include:
• Exiting an interrupt service routine (ISR)
• Changing a mode
• Configuring a function
In these situations, application software must perform a read-after-write sequence to
guarantee the required serialization of the memory operations:
1. Write the peripheral register.
2. Read the written peripheral register to verify the write.
3. Continue with subsequent operations.
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Chapter 4 Memory Map
4.6.2 Peripheral Bridge (AIPS-Lite) Memory Map
Table 4-2. Peripheral bridge 0 slot assignments
System 32-bit base address
Slot
number
Module
0x4000_0000
0
—
0x4000_1000
1
—
0x4000_2000
2
—
0x4000_3000
3
—
0x4000_4000
4
—
0x4000_5000
5
—
0x4000_6000
6
—
0x4000_7000
7
—
0x4000_8000
8
DMA controller
0x4000_9000
9
—
0x4000_A000
10
—
0x4000_B000
11
—
0x4000_C000
12
—
0x4000_D000
13
—
0x4000_E000
14
—
0x4000_F000
15
GPIO controller (aliased to 0x400F_F000)
0x4001_0000
16
—
0x4001_1000
17
—
0x4001_2000
18
—
0x4001_3000
19
—
0x4001_4000
20
—
0x4001_5000
21
—
0x4001_6000
22
—
0x4001_7000
23
—
0x4001_8000
24
—
0x4001_9000
25
—
0x4001_A000
26
—
0x4001_B000
27
—
0x4001_C000
28
—
0x4001_D000
29
—
0x4001_E000
30
—
0x4001_F000
31
—
0x4002_0000
32
Flash memory
0x4002_1000
33
DMA channel mutiplexer 0
0x4002_2000
34
—
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Peripheral bridge (AIPS-Lite) memory map
Table 4-2. Peripheral bridge 0 slot assignments (continued)
System 32-bit base address
Slot
number
Module
0x4002_3000
35
—
0x4002_4000
36
—
0x4002_5000
37
—
0x4002_6000
38
—
0x4002_7000
39
—
0x4002_8000
40
—
0x4002_9000
41
—
0x4002_A000
42
—
0x4002_B000
43
—
0x4002_C000
44
—
0x4002_D000
45
—
0x4002_E000
46
—
0x4002_F000
47
—
0x4003_0000
48
—
0x4003_1000
49
—
0x4003_2000
50
—
0x4003_3000
51
—
0x4003_4000
52
—
0x4003_5000
53
—
0x4003_6000
54
—
0x4003_7000
55
Periodic interrupt timers (PIT)
0x4003_8000
56
Timer'/PWM (TPM) 0
0x4003_9000
57
Timer'/PWM (TPM) 1
0x4003_A000
58
—
0x4003_B000
59
Analog-to-digital converter (ADC) 0
0x4003_C000
60
—
0x4003_D000
61
Real-time clock (RTC)
0x4003_E000
62
—
0x4003_F000
63
—
0x4004_0000
64
Low-power timer (LPTMR)
0x4004_1000
65
—
0x4004_2000
66
—
0x4004_3000
67
—
0x4004_4000
68
—
0x4004_5000
69
—
0x4004_6000
70
—
0x4004_7000
71
SIM low-power logic
0x4004_8000
72
System integration module (SIM)
0x4004_9000
73
Port A multiplexing control
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Chapter 4 Memory Map
Table 4-2. Peripheral bridge 0 slot assignments (continued)
System 32-bit base address
Slot
number
Module
0x4004_A000
74
Port B multiplexing control
0x4004_B000
75
—
0x4004_C000
76
—
0x4004_D000
77
—
0x4004_E000
78
—
0x4004_F000
79
—
0x4005_0000
80
—
0x4005_1000
81
—
0x4005_2000
82
—
0x4005_3000
83
—
0x4005_4000
84
—
0x4005_5000
85
—
0x4005_6000
86
—
0x4005_7000
87
—
0x4005_8000
88
—
0x4005_9000
89
—
0x4005_A000
90
—
0x4005_B000
91
—
0x4005_C000
92
—
0x4005_D000
93
—
0x4005_E000
94
—
0x4005_F000
95
—
0x4006_0000
96
—
0x4006_1000
97
—
0x4006_2000
98
—
0x4006_3000
99
—
0x4006_4000
100
Multi-purpose Clock Generator (MCG)
0x4006_5000
101
System oscillator (OSC)
0x4006_6000
102
I2C 0
0x4006_7000
103
—
0x4006_8000
104
—
0x4006_9000
105
—
0x4006_A000
106
UART 0
0x4006_B000
107
—
0x4006_C000
108
—
0x4006_D000
109
—
0x4006_E000
110
—
0x4006_F000
111
—
0x4007_0000
112
—
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Private Peripheral Bus (PPB) memory map
Table 4-2. Peripheral bridge 0 slot assignments (continued)
System 32-bit base address
Slot
number
Module
0x4007_1000
113
—
0x4007_2000
114
—
0x4007_3000
115
Analog comparator (CMP) / 6-bit digital-to-analog converter (DAC)
0x4007_4000
116
—
0x4007_5000
117
—
0x4007_6000
118
SPI 0
0x4007_7000
119
—
0x4007_8000
120
—
0x4007_9000
121
—
0x4007_A000
122
—
0x4007_B000
123
—
0x4007_C000
124
Low-leakage wakeup unit (LLWU)
0x4007_D000
125
Power management controller (PMC)
0x4007_E000
126
System Mode controller (SMC)
0x4007_F000
127
Reset Control Module (RCM)
0x400F_F000
128
GPIO controller
4.6.3 Modules Restricted Access in User Mode
In user mode, for MCG, RCM, SIM (slot 71 and 72), SMC, LLWU, and PMC, reads are
allowed, but writes are blocked and generate bus error.
4.7 Private Peripheral Bus (PPB) memory map
The PPB is part of the defined ARM bus architecture and provides access to select
processor-local modules. These resources are only accessible from the core; other system
masters do not have access to them.
Table 4-3. PPB memory map
System 32-bit Address Range
0xE000_0000–0xE000_DFFF
Resource
Additional Range Detail
Resource
Reserved
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Chapter 4 Memory Map
Table 4-3. PPB memory map (continued)
System 32-bit Address Range
0xE000_E000–0xE000_EFFF
Resource
System Control Space
(SCS)
0xE000_F000–0xE00F_EFFF
Reserved
0xE00F_F000–0xE00F_FFFF
Core ROM Space (CRS)
Additional Range Detail
Resource
0xE000_E000–0xE000_E00F
Reserved
0xE000_E010–0xE000_E0FF
SysTick
0xE000_E100–0xE000_ECFF
NVIC
0xE000_ED00–0xE000_ED8F
System Control Block
0xE000_ED90–0xE000_EDEF
Reserved
0xE000_EDF0–0xE000_EEFF
Debug
0xE000_EF00–0xE000_EFFF
Reserved
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Private Peripheral Bus (PPB) memory map
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Chapter 5
Clock Distribution
5.1 Introduction
This chapter presents the clock architecture for the device, the overview of the clocks and
includes a terminology section.
The Cortex M0+ resides within a synchronous core platform, where the processor and
bus masters, Flash and peripherals clocks can be configured independently. The clock
distribution figure shows how clocks from the MCG and XOSC modules are distributed
to the microcontroller’s other function units. Some modules in the microcontroller have
selectable clock input.
5.2 Programming model
The selection and multiplexing of system clock sources is controlled and programmed via
the MCG module. The setting of clock dividers and module clock gating for the system
are programmed via the SIM module. Reference those sections for detailed register and
bit descriptions.
5.3 High-Level device clocking diagram
The following system oscillator, MCG, and SIM module registers control the
multiplexers, dividers, and clock gates shown in the below figure:
OSC
MCG
SIM
Multiplexers
MCG_Cx
MCG_Cx
SIM_SOPT1, SIM_SOPT2
Dividers
—
MCG_Cx
SIM_CLKDIVx
Clock gates
OSC_CR
MCG_C1
SIM_SCGCx
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Clock definitions
SIM
MCG
4 MHz IRC
FCRDIV
MCGIRCLK
CG
32 kHz IRC
FLL
OUTDIV1
CG
OUTDIV4
CG
Clock options for
some peripherals
(see note)
Core clock,
platform clock,
and system clock
MCGOUTCLK
Bus clock/
Flash clock
FRDIV
System oscillator
EXTAL0
OSCCLK
XTAL_CLK
XTAL0
OSC
logic
OSCERCLK
CG
ERCLK32K
OSC32KCLK
RTC_CLKIN
Clock options for some
peripherals (see note)
MCGFLLCLK
PMC
PMC logic
Counter logic
LPO
RTC_CLKOUT
1Hz
RTC
CG — Clock gate
Note: See subsequent sections for details on where these clocks are used.
Figure 5-1. Clocking diagram
5.4 Clock definitions
The following table describes the clocks in the previous block diagram.
Clock name
Description
Core clock
MCGOUTCLK divided by OUTDIV1, clocks the ARM CortexM0+ core
Platform clock
MCGOUTCLK divided by OUTDIV1, clocks the crossbar
switch and NVIC
System clock
MCGOUTCLK divided by OUTDIV1, clocks the bus masters
directly
Bus clock
System clock divided by OUTDIV4, clocks the bus slaves and
peripherals.
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Chapter 5 Clock Distribution
Clock name
Description
Flash clock
Flash memory clock. On this device it is the same as Bus
clock.
MCGIRCLK
MCG output of the slow or fast internal reference clock
MCGOUTCLK
MCG output of either IRC, MCGFLLCLK or MCG's external
reference clock that sources the core, system, bus, and flash
clock.
MCGFLLCLK
MCG output of the FLL. MCGFLLCLK may clock some
modules. In addition, this clock is used for UART0 and TPM
modules.
OSCCLK
System oscillator output of the internal oscillator or sourced
directly from EXTAL. Used as MCG external reference clock.
OSCERCLK
System oscillator output sourced from OSCCLK that may
clock some on-chip modules
OSC32KCLK
System oscillator 32kHz output
ERCLK32K
Clock source for some modules that is chosen as
OSC32KCLK or RTC_CLKIN
LPO
PMC 1kHz output
5.4.1 Device clock summary
The following table provides more information regarding the on-chip clocks.
Table 5-1. Clock Summary
Clock name
Run mode
VLPR mode
Clock source
Clock is disabled
when…
clock frequency
clock frequency
MCGOUTCLK
Up to 48 MHz
Up to 4 MHz
MCG
In all stop modes
except for partial stop
modes and during PLL
locking when
MCGOUTCLK derived
from PLL.
MCGFLLCLK
Up to 48 MHz
N/A
MCG
MCG clock controls do
not enable and in all
stop modes
Core clock
Up to 48 MHz
Up to 4 MHz
MCGOUTCLK clock
divider
In all wait and stop
modes
Platform clock
Up to 48 MHz
Up to 4 MHz
MCGOUTCLK clock
divider
In all stop modes
System clock
Up to 48 MHz
Up to 4 MHz
MCGOUTCLK clock
divider
In all stop modes and
Compute Operation
Bus clock
Up to 24 MHz
Up to 1 MHz 1
MCGOUTCLK clock
divider
In all stop modes
except for partial
STOP2 mode, and
Compute Operation
SWD Clock
Up to 24MHz
Up to 1MHz
SWD_CLK pin
In all stop modes
Table continues on the next page...
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Clock definitions
Table 5-1. Clock Summary (continued)
Clock name
Flash clock
Run mode
VLPR mode
clock frequency
clock frequency
Up to 24 MHz
Up to 1 MHz in BLPE
Up to 800 kHz in BLPI
Internal reference
(MCGIRCLK)
30-40 kHz Slow IRC
4 MHz Fast IRC only
Clock source
Clock is disabled
when…
MCGOUTCLK clock
divider
In all stop modes
except for partial
STOP2 mode
MCG
MCG_C1[IRCLKEN]
cleared,
or 4 MHz Fast IRC
Stop/VLPS mode and
MCG_C1[IREFSTEN]
cleared, or
LLS/VLLS mode
External reference
(OSCERCLK)
Up to 48 MHz (bypass), Up to 16 MHz (bypass), System OSC
30-40 kHz
or
3-32 MHz (crystal)
System OSC's
OSC_CR[ERCLKEN]
cleared, or
30-40 kHz (low-range
crystal)
Stop mode and
OSC_CR[EREFSTEN]
cleared
or
3-16 MHz (high-range
crystal)
External reference
32kHz
30-40 kHz
30-40 kHz
or VLLS0 and oscillator
not in external clock
mode.
System OSC
System OSC's
OSC_CR[ERCLKEN]
cleared
, or RTC_CLKIN
(ERCLK32K)
and RTC's
RTC_CR[OSCE]
cleared
or VLLS0 and oscillator
not in external clock
mode.
RTC_CLKOUT
LPO
TPM clock
RTC 1Hz,
RTC 1Hz,
RTC 1Hz,
Clock is disabled in LLS
and VLLSx modes
OSCERCLK
OSCERCLK
OSCERCLK
1 kHz
1 kHz
PMC
in VLLS0
Up to 48 MHz
Up to 8 MHz
MCGIRCLK,
MCGFLLCLK, or
SIM_SOPT2[TPMSRC
]=00 or selected clock
source disabled.
OSCERCLK
UART0 clock
Up to 48 MHz
Up to 8 MHz
MCGIRCLK,
MCGFLLCLK, or
SIM_SOPT2[UART0SR
C]=00 or selected clock
source disabled.
OSCERCLK
1. If in BLPI mode, where clocking is derived from the fast internal reference clock, the Bus clock and flash clock frequency
needs to be limited to 800 kHz if executing from flash.
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Chapter 5 Clock Distribution
5.5 Internal clocking requirements
The clock dividers are programmed via the SIM module’s CLKDIV registers. The
following requirements must be met when configuring the clocks for this device:
1. The core, platform, and system clock are programmable from a divide-by-1 through
divide-by-16 setting. The core, platform, and system clock frequencies must be 48
MHz or slower.
2. The bus clock and flash clock frequency is divided from the system clock and is
programmable from a divide-by-1 through divide-by-8 setting. The bus clock and
flash clock must be programmed to 24 MHz or slower.
The following is a common clock configuration for this device:
Clock
Frequency
Core clock
48 MHz
Platform clock
48 MHz
System clock
48 MHz
Bus clock
24 MHz
Flash clock
24 MHz
5.5.1 Clock divider values after reset
Each clock divider is programmed via the SIM module’s CLKDIV1 registers. Two bits in
the flash memory's FTFA_FOPT register controls the reset value of the core clock,
system clock, bus clock, and flash clock dividers as shown below:
FTFA_FOPT [4,0]
Core/system clock
Bus/Flash clock
Description
00
0x7 (divide by 8)
0x1 (divide by 2)
Low power boot
01
0x3 (divide by 4)
0x1 (divide by 2)
Low power boot
10
0x1 (divide by 2)
0x1 (divide by 2)
Low power boot
11
0x0 (divide by 1)
0x1 (divide by 2)
Fast clock boot
This gives the user flexibility in selecting between a lower frequency, low-power boot
option vs. higher frequency, higher power during and after reset.
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Clock Gating
The flash erased state defaults to fast clocking mode, since these bits reside in flash,
which is logic 1 in the flash erased state. To enable a lower power boot option, program
the appropriate bits in FTFA_FOPT. During the reset sequence, if either of the control
bits is cleared, the system is in a slower clock configuration. Upon any system reset, the
clock dividers return to this configurable reset state.
5.5.2 VLPR mode clocking
The clock dividers cannot be changed while in VLPR mode. They must be programmed
prior to entering VLPR mode to guarantee operation. Max frequency limitations for
VLPR mode is as follows :
• the core/system clocks are less than or equal to 4 MHz, and
• the bus and flash clocks are less than or equal to 1 MHz
NOTE
When the MCG is in BLPI and clocking is derived from the
Fast IRC, the clock divider controls (MCG_SC[FCRDIV],
SIM_CLKDIV1[OUTDIV1], and SIM_CLKDIV1[OUTDIV4])
must be programmed such that the resulting flash clock nominal
frequency is 800 kHz or less. In this case, one example of
correct configuration is MCG_SC[FCRDIV]=000b,
SIM_CLKDIV1[OUTDIV1]=0000b and
SIM_CLKDIV1[OUTDIV4]=100b, resulting in a divide by 5
setting.
5.6 Clock Gating
The clock to each module can be individually gated on and off using the SIM module's
SCGCx registers. These bits are cleared after any reset, which disables the clock to the
corresponding module to conserve power. Prior to initializing a module, set the
corresponding bit in SCGCx register to enable the clock. Before turning off the clock,
make sure to disable the module.
Any bus access to a peripheral that has its clock disabled generates an error termination.
5.7 Module clocks
The following table summarizes the clocks associated with each module.
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Chapter 5 Clock Distribution
Table 5-2. Module clocks
Module
Bus interface clock
Internal clocks
I/O interface clocks
Core modules
ARM Cortex-M0+ core
Platform clock
Core clock
—
NVIC
Platform clock
—
—
DAP
Platform clock
—
SWD_CLK
System modules
DMA
System clock
—
—
DMA Mux
Bus clock
—
—
Port control
Bus clock
—
—
Crossbar Switch
Platform clock
—
—
Peripheral bridges
System clock
Bus clock
—
LLWU, PMC, SIM, RCM
Bus clock
LPO
—
Mode controller
Bus clock
—
—
MCM
Platform clock
—
—
Watchdog timer
Bus clock
LPO
—
Clocks
MCG
Bus clock
MCGOUTCLK, MCGFLLCLK,
MCGIRCLK, OSCERCLK
—
OSC
Bus clock
OSCERCLK
—
Memory and memory interfaces
Flash Controller
Platform clock
Flash clock
—
Flash memory
Flash clock
—
—
Analog
ADC
Bus clock
OSCERCLK
—
CMP
Bus clock
—
—
Timers
TPM
Bus clock
TPM clock
TPM_CLKIN0, TPM_CLKIN1
PIT
Bus clock
—
—
LPTMR
Bus clock
LPO, OSCERCLK,
MCGIRCLK, ERCLK32K
—
RTC
Bus clock
ERCLK32K
RTC_CLKOUT
Communication interfaces
SPI0
Bus clock
—
SPI0_SCK
I2C0
Bus clock
—
I2C0_SCL
UART0
Bus clock
UART0 clock
—
Human-machine interfaces
GPIO
Platform clock
—
—
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Module clocks
5.7.1 PMC 1-kHz LPO clock
The Power Management Controller (PMC) generates a 1-kHz clock that is enabled in all
modes of operation, including all low power modes except VLLS0. This 1-kHz source is
commonly referred to as LPO clock or 1-kHz LPO clock.
5.7.2 COP clocking
The COP may be clocked from two clock sources as shown in the following figure.
LPO
COP clock
Bus clock
SIM_COPCTRL[COPCLKS]
Figure 5-2. COP clock generation
5.7.3 RTC clocking
The RTC module can be clocked as shown in the following figure.
NOTE
The chosen clock must remain enabled if the RTC is to
continue operating in all required low-power modes.
LPO
ERCLK32K
(to RTC)
RTC_CLKIN
OSC32KCLK
SIM_SOPT1[OSC32KSEL]
Figure 5-3. RTC clock generation
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Chapter 5 Clock Distribution
5.7.4 LPTMR clocking
The prescaler and glitch filters in each of the LPTMRx modules can be clocked as shown
in the following figure.
NOTE
The chosen clock must remain enabled if the LPTMRx is to
continue operating in all required low-power modes.
MCGIRCLK
LPO
LPO
LPTMRx prescaler/glitch
filter clock
ERCLK32K
RTC_CLKIN
OSCERCLK
OSC32KCLK
SIM_SOPT1[OSC32KSEL]
LPTMRx_PSR[PCS]
Figure 5-4. LPTMRx prescaler/glitch filter clock generation
5.7.5 TPM clocking
The counter for the TPM modules have a selectable clock as shown in the following
figure.
NOTE
The chosen clock must remain enabled if the TPMx is to
continue operating in all required low-power modes.
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Module clocks
MCGIRCLK
OSCERCLK
TPM clock
MCGFLLCLK
SIM_SOPT2[TPMSRC]
Figure 5-5. TPM clock generation
5.7.6 UART clocking
The UART0 module has a selectable clock as shown in the following figure.
NOTE
The chosen clock must remain enabled if the UART0 is to
continue operating in all required low-power modes.
MCGIRCLK
OSCERCLK
UART0 clock
MCGFLLCLK
SIM_SOPT2[UART0SRC]
Figure 5-6. UART0 clock generation
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Chapter 6
Reset and Boot
6.1 Introduction
The following reset sources are supported in this MCU:
Table 6-1. Reset sources
Reset sources
POR reset
Description
• Power-on reset (POR)
System resets
Debug reset
•
•
•
•
•
•
•
•
•
External pin reset (PIN)
Low-voltage detect (LVD)
Computer operating properly (COP) watchdog reset
Low leakage wakeup (LLWU) reset
Multipurpose clock generator loss of clock (LOC) reset
Stop mode acknowledge error (SACKERR)
Software reset (SW)
Lockup reset (LOCKUP)
MDM DAP system reset
• Debug reset
Each of the system reset sources has an associated bit in the system reset status (SRS)
registers. See the Reset Control Module for register details.
The MCU can exit and reset in functional mode where the CPU is executing code
(default) or the CPU is in a debug halted state. There are several boot options that can be
configured. See Boot information for more details.
6.2 Reset
This section discusses basic reset mechanisms and sources. Some modules that cause
resets can be configured to cause interrupts instead. Consult the individual peripheral
chapters for more information.
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Reset
6.2.1 Power-on reset (POR)
When power is initially applied to the MCU or when the supply voltage drops below the
power-on reset re-arm voltage level (VPOR), the POR circuit causes a POR reset
condition.
As the supply voltage rises, the LVD circuit holds the MCU in reset until the supply has
risen above the LVD low threshold (VLVDL). The POR and LVD bits in reset status
register are set following a POR.
6.2.2 System reset sources
Resetting the MCU provides a way to start processing from a known set of initial
conditions. System reset begins with the on-chip regulator in full regulation and system
clocking generation from an internal reference. When the processor exits reset, it
performs the following:
• Reads the start SP (SP_main) from vector-table offset 0
• Reads the start PC from vector-table offset 4
• LR is set to 0xFFFF_FFFF
The on-chip peripheral modules are disabled and the non-analog I/O pins are initially
configured as disabled. The pins with analog functions assigned to them default to their
analog function after reset.
During and following a reset, the SWD pins have their associated input pins configured
as:
• SWD_CLK in pull-down (PD)
• SWD_DIO in pull-up (PU)
6.2.2.1 External pin reset (RESET)
This pin is open drain and has an internal pullup device. Asserting RESET wakes the
device from any mode.
The RESET pin can be disabled by programming RESET_PIN_CFG option bit to 0.
When this option selected, there could be a short period of contention during a POR ramp
where the device drives the pin out low prior to establishing the setting of this option and
releasing the RESET function on the pin.
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Chapter 6 Reset and Boot
6.2.2.1.1
Reset pin filter
The RESET pin filter supports filtering from both the 1 kHz LPO clock and the bus
clock. The RPFC[RSTFLTSS], RPFC[RSTFLTSRW], and RPFW[RSTFLTSEL] fields
in the reset control (RCM) register set control this functionality; see the RCM chapter.
The filters are asynchronously reset by Chip POR. The reset value for each filter assumes
the RESET pin is negated.
For all stop modes where LPO clock is still active (Stop, VLPS, LLS, VLLS3, and
VLLS1), the only filtering option is the LPO based digital filter. The filtering logic either
switches to bypass operation or has continued filtering operation depending on the
filtering mode selected. When entering VLLS0, the RESET pin filter is disabled and
bypassed.
The LPO filter has a fixed filter value of 3. Due to a synchronizer on the input data, there
is also some associated latency (2 cycles). As a result, 5 cycles are required to complete a
transition from low to high or high to low.
6.2.2.2 Low-voltage detect (LVD)
The chip includes a system for managing low voltage conditions to protect memory
contents and control MCU system states during supply voltage variations. The system
consists of a power-on reset (POR) circuit and an LVD circuit with a user-selectable trip
voltage. The LVD system is always enabled in normal run, wait, or stop mode. The LVD
system is disabled when entering VLPx, LLS, or VLLSx modes.
The LVD can be configured to generate a reset upon detection of a low voltage condition
by setting the PMC's LVDSC1[LVDRE] bit to 1. The low voltage detection threshold is
determined by the PMC's LVDSC1[LVDV] field. After an LVD reset has occurred, the
LVD system holds the MCU in reset until the supply voltage has risen above the low
voltage detection threshold. The RCM's SRS0[LVD] bit is set following either an LVD
reset or POR.
6.2.2.3 Computer operating properly (COP) watchdog timer
The computer operating properly (COP) watchdog timer (WDOG) monitors the operation
of the system by expecting periodic communication from the software. This
communication is generally known as servicing (or refreshing) the COP watchdog. If this
periodic refreshing does not occur, the watchdog issues a system reset. The COP reset
causes the RCM's SRS0[WDOG] bit to set.
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Reset
6.2.2.4 Low leakage wakeup (LLWU)
The LLWU module provides the means for a number of external pins and a number of
internal peripherals to wake the MCU from low leakage power modes. The LLWU
module is functional only in low leakage power modes. In VLLSx modes, all enabled
inputs to the LLWU can generate a system reset.
After a system reset, the LLWU retains the flags indicating the input source of the last
wakeup until the user clears them.
NOTE
Some flags are cleared in the LLWU and some flags are
required to be cleared in the peripheral module. Refer to the
individual peripheral chapters for more information.
6.2.2.5 Multipurpose clock generator loss-of-clock (LOC)
The MCG module supports an external reference clock.
If the C6[CME] bit in the MCG module is set, the clock monitor is enabled. If the
external reference falls below floc_low or floc_high, as controlled by the C2[RANGE] field
in the MCG module, the MCU resets. The RCM's SRS0[LOC] bit is set to indicate this
reset source.
NOTE
To prevent unexpected loss of clock reset events, all clock
monitors must be disabled before entering any low power
modes, including VLPR and VLPW.
6.2.2.6 Stop mode acknowledge error (SACKERR)
This reset is generated if the core attempts to enter stop mode or Compute Operation, but
not all modules acknowledge stop mode within 1025 cycles of the 1 kHz LPO clock.
A module might not acknowledge the entry to stop mode if an error condition occurs. The
error can be caused by a failure of an external clock input to a module.
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Chapter 6 Reset and Boot
6.2.2.7 Software reset (SW)
The SYSRESETREQ bit in the NVIC application interrupt and reset control register can
be set to force a software reset on the device. (See ARM's NVIC documentation for the
full description of the register fields, especially the VECTKEY field requirements.)
Setting SYSRESETREQ generates a software reset request. This reset forces a system
reset of all major components except for the debug module. A software reset causes the
RCM's SRS1[SW] bit to set.
6.2.2.8 Lockup reset (LOCKUP)
The LOCKUP gives immediate indication of seriously errant kernel software. This is the
result of the core being locked because of an unrecoverable exception following the
activation of the processor’s built in system state protection hardware.
The LOCKUP condition causes a system reset and also causes the RCM's
SRS1[LOCKUP] bit to set.
6.2.2.9 MDM-AP system reset request
Set the system reset request bit in the MDM-AP control register to initiate a system reset.
This is the primary method for resets via the SWD interface. The system reset is held
until this bit is cleared.
Set the core hold reset bit in the MDM-AP control register to hold the core in reset as the
rest of the chip comes out of system reset.
6.2.3 MCU Resets
A variety of resets are generated by the MCU to reset different modules.
6.2.3.1 POR Only
The POR Only reset asserts on the POR reset source only. It resets the PMC and RTC.
The POR Only reset also causes all other reset types to occur.
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Reset
6.2.3.2 Chip POR not VLLS
The Chip POR not VLLS reset asserts on POR and LVD reset sources. It resets parts of
the SMC and SIM. It also resets the LPTMR.
The Chip POR not VLLS reset also causes these resets to occur: Chip POR, Chip Reset
not VLLS, and Chip Reset (including Early Chip Reset).
6.2.3.3 Chip POR
The Chip POR asserts on POR, LVD, and VLLS Wakeup reset sources. It resets the
Reset Pin Filter registers and parts of the SIM and MCG.
The Chip POR also causes the Chip Reset (including Early Chip Reset) to occur.
6.2.3.4 Chip Reset not VLLS
The Chip Reset not VLLS reset asserts on all reset sources except a VLLS Wakeup that
does not occur via the RESET pin. It resets parts of the SMC, LLWU, and other modules
that remain powered during VLLS mode.
The Chip Reset not VLLS reset also causes the Chip Reset (including Early Chip Reset)
to occur.
6.2.3.5 Early Chip Reset
The Early Chip Reset asserts on all reset sources. It resets only the flash memory module.
It negates before flash memory initialization begins ("earlier" than when the Chip Reset
negates).
6.2.3.6 Chip Reset
Chip Reset asserts on all reset sources and only negates after flash initialization has
completed and the RESET pin has also negated. It resets the remaining modules (the
modules not reset by other reset types).
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Chapter 6 Reset and Boot
6.2.4 Reset Pin
For all reset sources except a VLLS Wakeup that does not occur via the RESET pin, the
RESET pin is driven low by the MCU for at least 128 bus clock cycles and until flash
initialization has completed.
After flash initialization has completed, the RESET pin is released, and the internal Chip
Reset negates after the RESET pin is pulled high. Keeping the RESET pin asserted
externally delays the negation of the internal Chip Reset.
The RESET pin can be disabled by programming RESET_PIN_CFG option bit to 0.
When this option is selected, there could be a short period of contention during a POR
ramp where the device drives the pin out low prior to establishing the setting of this
option and releasing the RESET function on the pin.
6.2.5 Debug resets
The following sections detail the debug resets available on the device.
6.2.5.1 Resetting the Debug subsystem
Use the CDBGRSTREQ bit within the DP CTRL/STAT register to reset the debug
modules. However, as explained below, using the CDBGRSTREQ bit does not reset all
debug-related registers.
CDBGRSTREQ resets the debug-related registers within the following modules:
• SW-DP
• AHB-AP
• MDM-AP (MDM control and status registers)
CDBGRSTREQ does not reset the debug-related registers within the following modules:
•
•
•
•
•
•
•
CM0+ core (core debug registers: DHCSR, DCRSR, DCRDR, DEMCR)
BPU
DWT
NVIC
Crossbar bus switch1
AHB-AP1
Private peripheral bus1
1.
CDBGRSTREQ does not affect AHB resources so that debug resources on the private peripheral bus are available
during System Reset.
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Boot
6.3 Boot
This section describes the boot sequence, including sources and options.
Some configuration information such as clock trim values stored in factory programmed
flash locations is autoloaded.
6.3.1 Boot sources
The CM0+ core adds support for a programmable Vector Table Offset Register (VTOR)
to relocate the exception vector table. This device supports booting from internal flash
and RAM.
This device supports booting from internal flash with the reset vectors located at
addresses 0x0 (initial SP_main), 0x4 (initial PC), and RAM with relocating the exception
vector table to RAM.
6.3.2 FOPT boot options
The flash option register (FOPT) in flash memory module (FTFA) allows the user to
customize the operation of the MCU at boot time. The register contains read-only bits
that are loaded from the NVM's option byte in the flash configuration field. The default
setting for all values in the FOPT register is logic 1 since it is copied from the option byte
residing in flash, which has all bits as logic 1 in the flash erased state. To configure for
alternate settings, program the appropriate bits in the NVM option byte. The new settings
will take effect on subsequent POR, VLLSx recoveries, and any system reset. For more
details on programming the option byte, refer to the flash memory chapter.
The MCU uses the FTFA_FOPT register bits to configure the device at reset as shown in
the following table.
Table 6-2. Flash Option Register (FTFA_FOPT) Bit Definitions
Bit
Num
7-6
Field
Reserved
Value
Definition
Reserved for future expansion.
Table continues on the next page...
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Chapter 6 Reset and Boot
Table 6-2. Flash Option Register (FTFA_FOPT) Bit Definitions
(continued)
Bit
Num
5
3
Field
Value
FAST_INIT
Definition
Select initialization speed on POR, VLLSx, and any system reset .
RESET_PIN_CFG
0
Slower initialization. The Flash initialization will be slower with the benefit of
reduced average current during this time. The duration of the recovery will be
controlled by the clock divider selection determined by the LPBOOT setting.
1
Fast Initialization.The Flash has faster recoveries at the expense of higher current
during these times.
Enable/disable control for the RESET pin.
0
RESET pin is disabled following a POR and cannot be enabled as RESET
function. When this option is selected, there could be a short period of contention
during a POR ramp where the device drives the pin out low prior to establishing the
setting of this option and releasing the RESET function on the pin.
This bit is preserved through system resets and low power modes. When RESET
pin function is disabled it cannot be used as a source for low power mode wakeup.
NOTE: When the reset pin has been disabled and security has been enabled by
means of the FSEC register, a mass erase can be performed only by
setting both the mass erase and system reset request bits in the MDM-AP
register.
1
2
NMI_DIS
RESET pin is dedicated. The port is configured with pullup enabled, open drain,
passive filter enabled.
Enable/disable control for the NMI function.
0
NMI interrupts are always blocked. The associated pin continues to default to NMI
pin controls with internal pullup enabled. When NMI pin function is disabled it
cannot be used as a source for low power mode wakeup.
1
NMI pin/interrupts reset default to enabled.
1
Reserved
Reserved for future expansion.
4,0
LPBOOT
Control the reset value of OUTDIV1 value in SIM_CLKDIV1 register. Larger divide value
selections produce lower average power consumption during POR, VLLSx recoveries and
reset sequencing and after reset exit. The recovery times are also extended if the
FAST_INIT option is not selected.
00
Core and system clock divider (OUTDIV1) is 0x7 (divide by 8)
01
Core and system clock divider (OUTDIV1) is 0x3 (divide by 4)
10
Core and system clock divider (OUTDIV1) is 0x1 (divide by 2)
11
Core and system clock divider (OUTDIV1) is 0x0 (divide by 1)
6.3.3 Boot sequence
At power up, the on-chip regulator holds the system in a POR state until the input supply
is above the POR threshold. The system continues to be held in this static state until the
internally regulated supplies have reached a safe operating voltage as determined by the
LVD. The Reset Controller logic then controls a sequence to exit reset.
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Boot
1. A system reset is held on internal logic, the RESET pin is driven out low, and the
MCG is enabled in its default clocking mode.
2. Required clocks are enabled (System Clock, Flash Clock, and any Bus Clocks that do
not have clock gate control reset to disabled).
3. The system reset on internal logic continues to be held, but the Flash Controller is
released from reset and begins initialization operation while the Reset Control logic
continues to drive the RESET pin out low.
4. Early in reset sequencing the NVM option byte is read and stored to FTFA_FOPT. If
the bits associated with LPBOOT are programmed for an alternate clock divider reset
value, the system/core clock is switched to a slower clock speed. If the FAST_INIT
bit is programmed clear, the Flash initialization switches to slower clock resulting
longer recovery times.
5. When Flash Initialization completes, the RESET pin is released. If RESET continues
to be asserted (an indication of a slow rise time on the RESET pin or external drive
in low), the system continues to be held in reset. Once the RESET pin is detected
high, the Core clock is enabled and the system is released from reset.
6. When the system exits reset, the processor sets up the stack, program counter (PC),
and link register (LR). The processor reads the start SP (SP_main) from vector-table
offset 0. The core reads the start PC from vector-table offset 4. LR is set to
0xFFFF_FFFF. The CPU begins execution at the PC location.
Subsequent system resets follow this same reset flow.
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Chapter 7
Power Management
7.1 Introduction
This chapter describes the various chip power modes and functionality of the individual
modules in these modes.
7.2 Clocking Modes
This sections describes the various clocking modes supported on this device.
7.2.1 Partial Stop
Partial Stop is a clocking option that can be taken instead of entering STOP mode and is
configured in the SMC Stop Control Register (SMC_STOPCTRL). The Stop mode is
only partially entered, which leaves some additional functionality alive at the expense of
higher power consumption. Partial Stop can be entered from either Run mode or VLP
Run mode.
When configured for PSTOP2, only the core and system clocks are gated and the bus
clock remains active. The bus masters and bus slaves clocked by the system clock enter
Stop mode, but the bus slaves clocked by bus clock remain in Run (or VLP Run) mode.
The clock generators in the MCG and the on-chip regulator in the PMC also remain in
Run (or VLP Run) mode. Exit from PSTOP2 can be initiated by a reset, an asynchronous
interrupt from a bus master or bus slave clocked by the system clock, or a synchronous
interrupt from a bus slave clocked by the bus clock. If configured, a DMA request (using
the asynchronous DMA wakeup) can also be used to exit Partial Stop for the duration of a
DMA transfer before the device is transitioned back into PSTOP2.
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Clocking Modes
When configured for PSTOP1, both the system clock and bus clock are gated. All bus
masters and bus slaves enter Stop mode, but the clock generators in the MCG and the onchip regulator in the PMC remain in Run (or VLP Run) mode. Exit from PSTOP1 can be
initiated by a reset or an asynchronous interrupt from a bus master or bus slave. If
configured, an asynchronous DMA request can also be used to exit Partial Stop for the
duration of a DMA transfer before the device is transitioned back into PSTOP1.
PSTOP1 is functionally similar to STOP mode, but offers faster wakeup at the expense of
higher power consumption. Another benefit is that it keeps all of the MCG clocks
enabled, which can be useful for some of the asynchronous peripherals that can remain
functional in Stop modes.
7.2.2 DMA Wakeup
The DMA can be configured to wakeup the device on a DMA request whenever it is
placed in stop mode. The wakeup is configured per DMA channel and is supported in
Compute Operation, PSTOP, STOP and VLPS low power modes.
When a DMA wakeup is detected in PSTOP, STOP or VLPS then the device will initiate
a normal exit from the low power mode. This can include restoring the on-chip regulator
and internal power switches, enabling the clock generators in the MCG, enabling the
system and bus clocks (but not the core clock) and negating the stop mode signal to the
bus masters and bus slaves. The only difference is that the CPU will remain in the low
power mode with the CPU clock disabled.
During Compute Operation, a DMA wakeup will initiate a normal exit from Compute
Operation. This includes enabling the clocks and negating the stop mode signal to the bus
masters and bus slaves. The core clock always remains enabled during Compute
Operation.
Since the DMA wakeup will enable the clocks and negate the stop mode signals to all bus
masters and slaves, software needs to ensure that bus masters and slaves that are not
involved with the DMA wakeup and transfer remain in a known state. That can be
accomplished by disabling the modules before entry into the low power mode or by
setting the Doze enable bit in selected modules.
Once the DMA request that initiated the wakeup negates and the DMA completes the
current transfer, the device will transition back into the original low power mode. This
includes requesting all non-CPU bus masters to enter Stop mode and then requesting bus
slaves to enter Stop mode. In STOP and VLPS modes the MCG and PMC would then
also enter their appropriate modes.
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Chapter 7 Power Management
NOTE
If the requested DMA transfer cannot cause the DMA request
to negate then the device will remain in a higher power state
until the low power mode is fully exited.
An enabled DMA wakeup can cause an aborted entry into the low power mode, if the
DMA request asserts during the stop mode entry sequence (or reentry if the request
asserts during a DMA wakeup) and can cause the SMC to assert its Stop Abort flag. Once
the DMA wakeup completes, entry into the low power mode will restart.
An interrupt that occurs during a DMA wakeup will cause an immediate exit from the
low power mode (this is optional for Compute Operation) without impacting the DMA
transfer.
A DMA wakeup can be generated by either a synchronous DMA request or an
asynchronous DMA request. Not all peripherals can generate an asynchronous DMA
request in stop modes, although in general if a peripheral can generate synchronous DMA
requests and also supports asynchronous interrupts in stop modes, then it can generate an
asynchronous DMA request.
7.2.3 Compute Operation
Compute Operation is an execution or compute-only mode of operation that keeps the
CPU enabled with full access to the SRAM and Flash read port, but places all other bus
masters and bus slaves into their stop mode. Compute Operation can be enabled in either
Run mode or VLP Run mode.
NOTE
Do not enter any stop mode without first exiting Compute
Operation.
Because Compute Operation reuses the stop mode logic (including the staged entry with
bus masters disabled before bus slaves), any bus master or bus slave that can remain
functional in stop mode also remains functional in Compute Operation, including
generation of asynchronous interrupts and DMA requests. When enabling Compute
Operation in Run mode, module functionality for bus masters and slaves is the equivalent
of STOP mode. When enabling Compute Operation in VLP Run mode, module
functionality for bus masters and slaves is the equivalent of VLPS mode. The MCG,
PMC, SRAM and Flash read port are not affected by Compute Operation, although the
Flash register interface is disabled.
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Clocking Modes
During Compute Operation, the AIPS peripheral space is disabled and attempted accesses
generate bus errors. The private peripheral space remains accessible during Compute
Operation, including the MCM, NVIC, IOPORT and SysTick. Although access to the
GPIO registers via the IOPORT is supported, the GPIO port data input registers do not
return valid data since clocks are disabled to the Port Control and Interrupt modules. By
writing to the GPIO port data output registers, it is possible to control those GPIO ports
that are configured as output pins.
Compute Operation is controlled by the CPO register in the MCM, which is only
accessible to the CPU. Setting or clearing the CPOREQ bit in the MCM initiates entry or
exit into Compute Operation. Compute Operation can also be configured to exit
automatically on detection of an interrupt, which is required in order to service most
interrupts. Only the core system interrupts (exceptions, including NMI and SysTick) and
any edge sensitive interrupts can be serviced without exiting Compute Operation.
When entering Compute Operation, the CPOACK status bit indicates when entry has
completed. When exiting Compute Operation in Run mode, the CPOACK status bit
negates immediately. When exiting Compute Operation in VLP Run mode, the exit is
delayed to allow the PMC to handle the change in power consumption. This delay means
the CPOACK bit is polled to determine when the AIPS peripheral space can be accessed
without generating a bus error.
The DMA wakeup is also supported during Compute Operation and causes the CPOACK
status bit to clear and the AIPS peripheral space to be accessible for the duration of the
DMA wakeup. At the completion of the DMA wakeup, the device transitions back into
Compute Operation.
7.2.4 Peripheral Doze
Several peripherals support a peripheral Doze mode, where a register bit can be used to
disable the peripheral for the duration of a low power mode. The Flash can also be placed
in a low power state during Peripheral Doze via a register bit in the SIM.
Peripheral Doze is defined to include all of the modes of operation listed below.
• The CPU is in wait mode.
• The CPU is in stop mode, including the entry sequence and for the duration of a
DMA wakeup.
• The CPU is in Compute Operation, including the entry sequence and for the duration
of a DMA wakeup.
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Chapter 7 Power Management
Peripheral Doze can therefore be used to disable selected bus masters or slaves for the
duration of WAIT or VLPW mode. It can also be used to disable selected bus slaves
immediately on entry into any stop mode (or Compute Operation), instead of waiting for
the bus masters to acknowledge the entry as part of the stop entry sequence. Finally, it
can be used to disable selected bus masters or slaves that should remain inactive during a
DMA wakeup.
If the Flash is not being accessed during WAIT and PSTOP modes, then the Flash Doze
mode can be used to reduce power consumption, at the expense of a slightly longer
wakeup when executing code and vectors from Flash. It can also be used to reduce power
consumption during Compute Operation when executing code and vectors from SRAM.
7.2.5 Clock Gating
To conserve power, the clocks to most modules can be turned off using the SCGCx
registers in the SIM module. These bits are cleared after any reset, which disables the
clock to the corresponding module. Prior to initializing a module, set the corresponding
bit in the SCGCx register to enable the clock. Before turning off the clock, make sure to
disable the module. For more details, refer to the clock distribution and SIM chapters.
7.3 Power modes
The power management controller (PMC) provides multiple power options to allow the
user to optimize power consumption for the level of functionality needed.
Depending on the stop requirements of the user application, a variety of stop modes are
available that provide state retention, partial power down or full power down of certain
logic and/or memory. I/O states are held in all modes of operation. The following table
compares the various power modes available.
For each run mode there is a corresponding wait and stop mode. Wait modes are similar
to ARM sleep modes. Stop modes (VLPS, STOP) are similar to ARM sleep deep mode.
The very low power run (VLPR) operating mode can drastically reduce runtime power
when the maximum bus frequency is not required to handle the application needs.
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Power modes
The three primary modes of operation are run, wait and stop. The WFI instruction
invokes both wait and stop modes for the chip. The primary modes are augmented in a
number of ways to provide lower power based on application needs.
Table 7-1. Chip power modes
Chip mode
Description
Normal run
Allows maximum performance of chip. Default mode out of reset; onchip voltage regulator is on.
Core mode
Normal
recovery
method
Run
—
Normal Wait via WFI
Allows peripherals to function while the core is in sleep mode, reducing
power. NVIC remains sensitive to interrupts; peripherals continue to be
clocked.
Sleep
Interrupt
Normal Stop via WFI
Places chip in static state. Lowest power mode that retains all registers
while maintaining LVD protection. NVIC is disabled; AWIC is used to
wake up from interrupt; peripheral clocks are stopped.
Sleep Deep
Interrupt
Run
—
Sleep
Interrupt
VLPS (Very Low Places chip in static state with LVD operation off. Lowest power mode
Power Stop)-via with ADC and pin interrupts functional. Peripheral clocks are stopped,
WFI
but OSC, LPTMR, RTC, CMP can be used. TPM and UART can
optionally be enabled if their clock source is enabled. NVIC is disabled
(FCLK = OFF); AWIC is used to wake up from interrupt. On-chip
voltage regulator is in a low power mode that supplies only enough
power to run the chip at a reduced frequency. All SRAM is operating
(content retained and I/O states held).
Sleep Deep
Interrupt
LLS (Low
State retention power mode. Most peripherals are in state retention
Leakage Stop) mode (with clocks stopped), but OSC, LLWU, LPTMR, RTC, CMP, can
be used. NVIC is disabled; LLWU is used to wake up.
Sleep Deep
Wakeup
Interrupt1
Sleep Deep
Wakeup Reset2
VLPR (Very Low On-chip voltage regulator is in a low power mode that supplies only
Power Run)
enough power to run the chip at a reduced frequency. Only MCG
modes BLPI and BLPE can be used in VLPR. Reduced frequency
Flash access mode (1 MHz); LVD off; in BLPI clock mode, only the fast
internal reference oscillator is available to provide a low power nominal
4MHz source for the core with the nominal bus and flash clock required
to be <800kHz; alternatively, BLPE clock mode can be used with an
external clock or the crystal oscillator providing the clock source.
VLPW (Very
Low Power
Wait) -via WFI
Same as VLPR but with the core in sleep mode to further reduce
power; NVIC remains sensitive to interrupts (FCLK = ON). On-chip
voltage regulator is in a low power mode that supplies only enough
power to run the chip at a reduced frequency.
NOTE: The LLWU interrupt must not be masked by the interrupt
controller to avoid a scenario where the system does not fully
exit stop mode on an LLS recovery.
All SRAM is operating (content retained and I/O states held).
VLLS3 (Very
Low Leakage
Stop3)
Most peripherals are disabled (with clocks stopped), but OSC, LLWU,
LPTMR, RTC, CMP can be used. NVIC is disabled; LLWU is used to
wake up.
SRAM_U and SRAM_L remain powered on (content retained and I/O
states held).
Table continues on the next page...
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Chapter 7 Power Management
Table 7-1. Chip power modes (continued)
Chip mode
Description
Core mode
Normal
recovery
method
VLLS1 (Very
Low Leakage
Stop1)
Most peripherals are disabled (with clocks stopped), but OSC, LLWU,
LPTMR, RTC, CMP can be used. NVIC is disabled; LLWU is used to
wake up.
Sleep Deep
Wakeup Reset2
VLLS0 (Very
Low Leakage
Stop 0)
Most peripherals are disabled (with clocks stopped), but LLWU,
LPTMR, RTC can be used. NVIC is disabled; LLWU is used to wake
up.
Sleep Deep
Wakeup Reset2
All of SRAM_U and SRAM_L are powered off.
All of SRAM_U and SRAM_L are powered off.
LPO disabled, optional POR brown-out detection
1. Resumes normal run mode operation by executing the LLWU interrupt service routine.
2. Follows the reset flow with the LLWU interrupt flag set for the NVIC.
7.4 Entering and exiting power modes
The WFI instruction invokes wait and stop modes for the chip. The processor exits the
low-power mode via an interrupt. For LLS and VLLS modes, the wakeup sources are
limited to LLWU generated wakeups, NMI pin, or RESET pin assertions. When the NMI
pin or RESET pin have been disabled through associated FOPT settings, then these pins
are ignored as wakeup sources. The wake-up flow from VLLSx is always through reset.
NOTE
The WFE instruction can have the side effect of entering a lowpower mode, but that is not its intended usage. See ARM
documentation for more on the WFE instruction.
On VLLS recoveries, the I/O pins continue to be held in a static state after code execution
begins, allowing software to reconfigure the system before unlocking the I/O. RAM is
retained in VLLS3 only.
7.5 Module Operation in Low Power Modes
The following table illustrates the functionality of each module while the chip is in each
of the low power modes. The standard behavior is shown with some exceptions for
Compute Operation (CPO) and Partial Stop2 (PSTOP2).
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Module Operation in Low Power Modes
(Debug modules are discussed separately; see Debug in Low Power Modes.) Number
ratings (such as 4 MHz and 1 Mbps) represent the maximum frequencies or maximum
data rates per mode. Also, these terms are used:
• FF = Full functionality. In VLPR and VLPW the system frequency is limited, but if a
module does not have a limitation in its functionality, it is still listed as FF.
• Async operation = Fully functional with alternate clock source, provided the selected
clock source remains enabled
• static = Module register states and associated memories are retained.
• powered = Memory is powered to retain contents.
• low power = Memory is powered to retain contents in a lower power state
• OFF = Modules are powered off; module is in reset state upon wakeup. For clocks,
OFF means disabled.
• wakeup = Modules can serve as a wakeup source for the chip.
Table 7-2. Module operation in low power modes
Modules
VLPR
VLPW
Stop
VLPS
LLS
VLLSx
static
static
OFF
Core modules
NVIC
FF
FF
static
System modules
Mode Controller
FF
FF
FF
FF
FF
FF
static
static
static
static
FF
FF2
low power
low power
ON
low power
low power
low power in
VLLS3, OFF in
VLLS0/1
disabled
disabled
ON
disabled
disabled
disabled
Brown-out
Detection
ON
ON
ON
ON
ON
ON in VLLS1/3,
optionally
disabled in
VLLS03
DMA
FF
FF
static
OFF
static
static
OFF
ON
ON in VLLS1/3,
OFF in VLLS0
LLWU1
Regulator
LVD
Async operation Async operation
Async operation
in CPO
Watchdog
FF
FF
static in CPO
static
FF in PSTOP2
Clocks
1kHz LPO
System
oscillator (OSC)
MCG
ON
ON
ON
ON
OSCERCLK
max of 16MHz
crystal
OSCERCLK
max of 16MHz
crystal
OSCERCLK
optional
OSCERCLK
max of 16MHz
crystal
4 MHz IRC
4 MHz IRC
static MCGIRCLK
optional
static MCGIRCLK
optional
limited to low
limited to low
range/low power range/low power
in VLLS1/3, OFF
in VLLS0
static - no clock
output
OFF
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Chapter 7 Power Management
Table 7-2. Module operation in low power modes (continued)
Modules
VLPR
VLPW
Stop
VLPS
LLS
VLLSx
Core clock
4 MHz max
OFF
OFF
OFF
OFF
OFF
Platform clock
4 MHz max
4 MHz max
OFF
OFF
OFF
OFF
System clock
4 MHz max
4 MHz max
OFF
OFF
OFF
OFF
1 MHz max
OFF
OFF
OFF
OFF
OFF in CPO
Bus clock
1 MHz max
OFF in CPO
24 MHz max in
PSTOP2 from
RUN
1 MHz max in
PSTOP2 from
VLPR
Memory and memory interfaces
Flash
1 MHz max
access - no
program
low power
low power
low power
OFF
OFF
low power
low power
low power
low power
low power
low power in
VLLS3, OFF in
VLLS0/1
1 Mbps
1 Mbps
static
OFF
static, slave
mode receive
static
OFF
static, address
match wakeup
static
OFF
static
OFF
static
OFF
No register
access in CPO
SRAM_U and
SRAM_L
Communication interfaces
UART0
Async operation
in CPO
SPI0
master mode
500 kbps,
Async operation Async operation
FF in PSTOP2
master mode
500 kbps,
slave mode 250 slave mode 250
kbps
kbps
static, slave
mode receive
FF in PSTOP2
static, slave
mode receive in
CPO
I2C0
50 kbps
50 kbps
static, address
match wakeup
in CPO
static, address
match wakeup
FF in PSTOP2
Timers
TPM
FF
FF
Async operation
in CPO
PIT
FF
Async operation Async operation
FF in PSTOP2
FF
static
static
static in CPO
LPTMR
FF
FF
Async operation Async operation Async operation
FF in PSTOP2
Async
operation4
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Module Operation in Low Power Modes
Table 7-2. Module operation in low power modes (continued)
Modules
RTC
VLPR
VLPW
FF
FF
Async operation
in CPO
Stop
VLPS
LLS
Async operation Async operation Async operation
FF in PSTOP2
VLLSx
Async
operation5
Analog
12-bit ADC
FF
FF
ADC internal
clock only in
CPO
CMP6
FF
FF
ADC internal
clock only
static
OFF
HS or LS
compare
LS compare
LS compare in
VLLS1/3, OFF in
VLLS0
static
static
static, OFF in
VLLS0
static output,
wakeup input
static, pins
latched
OFF, pins
latched
FF in PSTOP2
FF
HS or LS
compare in CPO
6-bit DAC
ADC internal
clock only
HS or LS
compare
FF in PSTOP2
FF
static in CPO
static
FF in PSTOP2
Human-machine interfaces
GPIO
FF
IOPORT write
only in CPO
FF
static output,
wakeup input
FF in PSTOP2
1. Using the LLWU module, the external pins available for this chip do not require the associated peripheral function to be
enabled. It only requires the function controlling the pin (GPIO or peripheral) to be configured as an input to allow a
transition to occur to the LLWU.
2. Since LPO clock source is disabled, filters will be bypassed during VLLS0.
3. The STOPCTRL[PORPO] bit in the SMC module controls this option.
4. LPO clock source is not available in VLLS0. Also, to use system OSC in VLLS0 it must be configured for bypass (external
clock) operation. Pulse counting is available in all modes.
5. In VLLS0 the only clocking option is from RTC_CLKIN.
6. CMP in stop or VLPS supports high speed or low speed external pin to pin or external pin to DAC compares. CMP in LLS
or VLLSx only supports low speed external pin to pin or external pin to DAC compares. Windowed, sampled & filtered
modes of operation are not available while in stop, VLPS, LLS, or VLLSx modes.
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Chapter 8
Security
8.1 Introduction
This device implements security based on the mode selected from the flash module. The
following sections provide an overview of flash security and details the effects of security
on non-flash modules.
8.2 Flash Security
The flash module provides security information to the MCU based on the state held by
the FSEC[SEC] bits. The MCU, in turn, confirms the security request and limits access to
flash resources. During reset, the flash module initializes the FSEC register using data
read from the security byte of the flash configuration field.
NOTE
The security features apply only to external accesses: debug.
CPU accesses to the flash are not affected by the status of
FSEC.
In the unsecured state all flash commands are available on the programming interfaces
either from the debug port (SWD) or user code execution. When the flash is secured
(FSEC[SEC] = 00, 01, or 11), the programmer interfaces are only allowed to launch mass
erase operations. Additionally, in this mode, the debug port has no access to memory
locations.
8.3 Security Interactions with other Modules
The flash security settings are used by the system to determine what resources are
available. The following sections describe the interactions between modules and the flash
security settings or the impact that the flash security has on non-flash modules.
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Security Interactions with other Modules
8.3.1 Security Interactions with Debug
When flash security is active the SWD port cannot access the memory resources of the
MCU.
Although most debug functions are disabled, the debugger can write to the Flash Mass
Erase in Progress bit to trigger a mass erase (Erase All Blocks) command. A mass erase
via the debugger is allowed even when some memory locations are protected.
When mass erase is disabled, mass erase via the debugger is blocked.
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Chapter 9
Debug
9.1 Introduction
This device's debug is based on the ARM CoreSightTM architecture and is configured to
provide the maximum flexibility as allowed by the restrictions of the pinout and other
available resources.
It provides register and memory accessibility from the external debugger interface, basic
run/halt control plus 2 breakpoints and 2 watchpoints.
Only one debug interface is supported:
• Serial Wire Debug (SWD)
9.2 Debug Port Pin Descriptions
The debug port pins default after POR to their SWD functionality.
Table 9-1. Serial wire debug pin description
Pin Name
Type
Description
SWD_CLK
Input
Serial Wire Clock. This pin is the clock for debug logic when in the Serial
Wire Debug mode. This pin is pulled down internally.
SWD_DIO
Input / Output
Serial wire debug data input/output. The SWD_DIO pin is used by an
external debug tool for communication and device control. This pin is
pulled up internally.
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SWD status and control registers
9.3 SWD status and control registers
Through the ARM Debug Access Port (DAP), the debugger has access to the status and
control elements, implemented as registers on the DAP bus as shown in the following
figure. These registers provide additional control and status for low power mode recovery
and typical run-control scenarios. The status register bits also provide a means for the
debugger to get updated status of the core without having to initiate a bus transaction
across the crossbar switch, thus remaining less intrusive during a debug session.
It is important to note that these DAP control and status registers are not memory mapped
within the system memory map and are only accessible via the Debug Access Port using
SWD. The MDM-AP is accessible as Debug Access Port 1 with the available registers
shown in the table below.
Table 9-2. MDM-AP Register Summary
Address
Register
Description
0x0100_0000
Status
See MDM-AP Status Register
0x0100_0004
Control
See MDM-AP Control Register
0x0100_00FC
IDR
Read-only identification register that
always reads as 0x001C_0020
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Chapter 9 Debug
DPACC
APACC
A[3:2] RnW
Debug Port
0x0C
SW-DP
See the ARM Debug Interface v5p1 Supplement.
Bus Matrix
Status
MDM-AP
SELECT[7:4] (APBANKSEL) selects the bank
A[3:2] from the APACC selects the register
within the bank
SELECT[31:24] = 0x00 selects the AHB-AP
See ARM documentation for further details
Access Port
(AHB-AP)
IDR
AHB Access Port
SELECT[31:24] (APSEL) selects the AP
AHB-AP
0x3F
A[7:4] A[3:2] RnW
0x00
Data[31:0]
0x01
APSEL
Decode
Internal Bus
Generic
Debug Port
(DP)
Control
0x08
Data[31:0]
Read Buffer (RDBUFF)
AP Select (SELECT)
0x04
A[3:2] RnW
Control/Status (CTRL/STAT)
Debug Port ID Register (IDCODE)
DP Registers
0x00
Data[31:0]
See Control and Status Register
Descriptions
MDM-AP
SELECT[31:24] = 0x01 selects the MDM-AP
SELECT[7:4] = 0x0 selects the bank with Status and Ctrl
A[3:2] = 2’b00 selects the Status Register
A[3:2] = 2’b01 selects the Control Register
SELECT[7:4] = 0xF selects the bank with IDR
A[3:2] = 2’b11 selects the IDR Register
(IDR register reads 0x001C_0020)
Figure 9-1. MDM AP Addressing
9.3.1 MDM-AP Control Register
Table 9-3. MDM-AP Control register assignments
Bit
0
Name
Flash Mass Erase in Progress
Secure1
Y
Description
Set to cause mass erase. Cleared by hardware after mass erase
operation completes.
When mass erase is disabled (via MEEN and SEC settings), the erase
request does not occur and the Flash Mass Erase in Progress bit
continues to assert until the next system reset.
1
Debug Disable
N
Set to disable debug. Clear to allow debug operation. When set it
overrides the C_DEBUGEN bit within the DHCSR and force disables
Debug logic.
Table continues on the next page...
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SWD status and control registers
Table 9-3. MDM-AP Control register assignments (continued)
Bit
2
Name
Debug Request
Secure1
N
Description
Set to force the core to halt.
If the core is in a stop or wait mode, this bit can be used to wakeup the
core and transition to a halted state.
3
System Reset Request
Y
Set to force a system reset. The system remains held in reset until this
bit is cleared.
4
Core Hold Reset
N
Configuration bit to control core operation at the end of system reset
sequencing.
0 Normal operation - release the core from reset along with the rest of
the system at the end of system reset sequencing.
1 Suspend operation - hold the core in reset at the end of reset
sequencing. Once the system enters this suspended state, clearing
this control bit immediately releases the core from reset and CPU
operation begins.
5
VLLSx Debug Request
(VLLDBGREQ)
N
Set to configure the system to be held in reset after the next recovery
from a VLLSx mode. This bit is ignored on a VLLS wakeup via the
Reset pin. During a VLLS wakeup via the Reset pin, the system can be
held in reset by holding the reset pin asserted allowing the debugger to
re-initialize the debug modules.
This bit holds the system in reset when VLLSx modes are exited to
allow the debugger time to re-initialize debug IP before the debug
session continues.
The Mode Controller captures this bit logic on entry to VLLSx modes.
Upon exit from VLLSx modes, the Mode Controller will hold the system
in reset until VLLDBGACK is asserted.
The VLLDBGREQ bit clears automatically due to the POR reset
generated as part of the VLLSx recovery.
6
VLLSx Debug Acknowledge
(VLLDBGACK)
N
Set to release a system being held in reset following a VLLSx recovery
This bit is used by the debugger to release the system reset when it is
being held on VLLSx mode exit. The debugger re-initializes all debug
IP and then assert this control bit to allow the Mode Controller to
release the system from reset and allow CPU operation to begin.
The VLLDBGACK bit is cleared by the debugger or can be left set
because it clears automatically due to the POR reset generated as part
of the next VLLSx recovery.
7
LLS, VLLSx Status Acknowledge
N
Set this bit to acknowledge the DAP LLS and VLLS Status bits have
been read. This acknowledge automatically clears the status bits.
This bit is used by the debugger to clear the sticky LLS and VLLSx
mode entry status bits. This bit is asserted and cleared by the
debugger.
8–
31
Reserved for future use
N
1. Command available in secure mode
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Chapter 9 Debug
9.3.2 MDM-AP Status Register
Table 9-4. MDM-AP Status register assignments
Bit
0
Name
Flash Mass Erase Acknowledge
Description
The Flash Mass Erase Acknowledge bit is cleared after any system reset.
The bit is also cleared at launch of a mass erase command due to write of
Flash Mass Erase in Progress bit in MDM AP Control Register. The Flash
Mass Erase Acknowledge is set after Flash control logic has started the
mass erase operation.
When mass erase is disabled (via MEEN and SEC settings), an erase
request due to seting of Flash Mass Erase in Progress bit is not
acknowledged.
1
Flash Ready
Indicate Flash has been initialized and debugger can be configured even if
system is continuing to be held in reset via the debugger.
2
System Security
Indicates the security state. When secure, the debugger does not have
access to the system bus or any memory mapped peripherals. This bit
indicates when the part is locked and no system bus access is possible.
3
System Reset
Indicates the system reset state.
0 System is in reset
1 System is not in reset
4
Reserved
5
Mass Erase Enable
Indicates if the MCU can be mass erased or not
0 Mass erase is disabled
1 Mass erase is enabled
6
Backdoor Access Key Enable
Indicates if the MCU has the backdoor access key enabled.
0 Disabled
1 Enabled
7
LP Enabled
Decode of SMC_PMCTRL[STOPM] field to indicate that VLPS, LLS, or
VLLSx are the selected power mode the next time the ARM Core enters
Deep Sleep.
0 Low Power Stop Mode is not enabled
1 Low Power Stop Mode is enabled
Usage intended for debug operation in which Run to VLPS is attempted.
Per debug definition, the system actually enters the Stop state. A
debugger should interpret deep sleep indication (with SLEEPDEEP and
SLEEPING asserted), in conjuntion with this bit asserted as the debuggerVLPS status indication.
8
Very Low Power Mode
Indicates current power mode is VLPx. This bit is not ‘sticky’ and should
always represent whether VLPx is enabled or not.
This bit is used to throttle SWD_CLK frequency up/down.
Table continues on the next page...
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Debug Resets
Table 9-4. MDM-AP Status register assignments (continued)
Bit
9
Name
LLS Mode Exit
Description
This bit indicates an exit from LLS mode has occurred. The debugger will
lose communication while the system is in LLS (including access to this
register). Once communication is reestablished, this bit indicates that the
system had been in LLS. Since the debug modules held their state during
LLS, they do not need to be reconfigured.
This bit is set during the LLS recovery sequence. The LLS Mode Exit bit is
held until the debugger has had a chance to recognize that LLS was exited
and is cleared by a write of 1 to the LLS, VLLSx Status Acknowledge bit in
MDM AP Control register.
10
VLLSx Modes Exit
This bit indicates an exit from VLLSx mode has occurred. The debugger
will lose communication while the system is in VLLSx (including access to
this register). Once communication is reestablished, this bit indicates that
the system had been in VLLSx. Since the debug modules lose their state
during VLLSx modes, they need to be reconfigured.
This bit is set during the VLLSx recovery sequence. The VLLSx Mode Exit
bit is held until the debugger has had a chance to recognize that a VLLS
mode was exited and is cleared by a write of 1 to the LLS, VLLSx Status
Acknowledge bit in MDM AP Control register.
11 – 15
Reserved for future use
Always read 0.
16
Core Halted
Indicates the Core has entered debug halt mode
17
Core SLEEPDEEP
Indicates the Core has entered a low power mode
18
Core SLEEPING
SLEEPING==1 and SLEEPDEEP==0 indicates wait or VLPW mode.
SLEEPING==1 and SLEEPDEEP==1 indicates stop or VLPS mode.
19 – 31
Reserved for future use
Always read 0.
9.4 Debug Resets
The debug system receives the following sources of reset:
• Debug reset (CDBGRSTREQ bit within the DP CTRL/STAT register) that allows
the debugger to reset the debug logic.
• System POR reset
Conversely the debug system is capable of generating system reset using the following
mechanism:
• A system reset in the DAP control register which allows the debugger to hold the
system in reset.
• SYSRESETREQ bit in the NVIC application interrupt and reset control register
• A system reset in the DAP control register which allows the debugger to hold the
Core in reset.
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Chapter 9 Debug
9.5 Micro Trace Buffer (MTB)
The Micro Trace Buffer (MTB) provides a simple execution trace capability for the
Cortex-M0+ processor. When enabled, the MTB records changes in program flow
reported by the Cortex-M0+ processor, via the execution trace interface, into a
configurable region of the SRAM. Subsequently an off-chip debugger may extract the
trace information, which would allow reconstruction of an instruction flow trace. The
MTB does not include any form of load/store data trace capability or tracing of any other
information.
In addition to providing the trace capability, the MTB also operates as a simple AHB-Lite
SRAM controller. The system bus masters, including the processor, have read/write
access to all of the SRAM via the AHB-Lite interface, allowing the memory to also be
used to store program and data information. The MTB simultaneously stores the trace
information into an attached SRAM and allows bus masters to access the memory. The
MTB ensures that trace information write accesses to the SRAM take priority over
accesses from the AHB-Lite interface.
The MTB includes trace control registers for configuring and triggering the MTB
functions. The MTB also supports triggering via TSTART and TSTOP control functions
in the MTB DWT module.
9.6 Debug in Low Power Modes
In low power modes in which the debug modules are kept static or powered off, the
debugger cannot gather any debug data for the duration of the low power mode. In the
case that the debugger is held static, the debug port returns to full functionality as soon as
the low power mode exits and the system returns to a state with active debug. In the case
that the debugger logic is powered off, the debugger is reset on recovery and must be
reconfigured once the low power mode is exited.
9.7 Debug & Security
When flash security is enabled, the debug port capabilities are limited in order to prevent
exploitation of secure data. In the secure state the debugger still has access to the status
register and can determine the current security state of the device. In the case of a secure
device, the debugger only has the capability of performing a mass erase operation.
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Debug & Security
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Chapter 10
Signal Multiplexing and Signal Descriptions
10.1 Introduction
To optimize functionality in small packages, pins have several functions available via
signal multiplexing. This chapter illustrates which of this device's signals are multiplexed
on which external pin.
The Port Control block controls which signal is present on the external pin. Reference
that chapter to find which register controls the operation of a specific pin.
10.2 Signal Multiplexing Integration
This section summarizes how the module is integrated into the device. For a
comprehensive description of the module itself, see the module’s dedicated chapter.
Peripheral bus
controller 1
Register
access
Transfers
Transfers
External Pins
Module
Signal Multiplexing/
Port Control
Module
Module
Figure 10-1. Signal multiplexing integration
Table 10-1. Reference links to related information
Topic
Related module
Reference
Full description
Port control
Port control
System memory map
System memory map
Table continues on the next page...
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Signal Multiplexing Integration
Table 10-1. Reference links to related information (continued)
Topic
Related module
Reference
Clocking
Clock Distribution
Register access
Peripheral bus
controller
Peripheral bridge
10.2.1 Port control and interrupt module features
• 32-pin ports
NOTE
Not all pins are available on the device. See the following
section for details.
• Each port is assigned one interrupt.
• For DMA requests, each port has a dedicated input to the DMA MUX.
The reset state and read/write characteristics of the bit fields within the PORTx_PCRn
registers is summarized in the table below.
Table 10-2. Port control register configuration summary
This field
of
PORTx_PC
Rn
Generally
resets to
Except for
Resets to
Configurability
PS
1
PTA0
0
Fixed - All are read only
PE
0
PTA0 and PTA2
1
Yes - All GPIO are
configurable
DSE
0
No exceptions - all DSE are cleared on reset.
—
4 pins are configurable for
High Drive (PTB0, PTB1,
PTA12 and PTA13). All
are others are fixed for
Normal Drive and the
associated DSE bit is read
only.
SRE
1
PTA2, PTA6, PTA7, PTA15, PTB0, PTB15, PTB16
and PTB17
0
Yes - All GPIO are
configurable
MUX
000
PTA0, PTA2 and PTB5
011
Yes - All GPIO are
configurable. MSB (bit2) of
MUX is not writable and
always reads 0.
PFE
0
No exceptions - all PFE are cleared on reset.1
—
The GPIO shared with
NMI_b pin is configurable.
All other GPIO is fixed and
read only.
IRQC
000
No exceptions - all are cleared on reset.
—
Yes
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Chapter 10 Signal Multiplexing and Signal Descriptions
Table 10-2. Port control register configuration summary (continued)
This field
of
PORTx_PC
Rn
Generally
resets to
ISF
0
Except for
Resets to
No exceptions - all are cleared on reset.
Configurability
—
1. The RESET pin has the passive analog filter fixed enabled when functioning as the RESET pin (FOPT[RESET_PIN_CFG]
= 1) and fixed disabled when configured for other shared functions.
10.2.2 Clock gating
The clock to the port control module can be gated on and off using the SCGC5[PORTx]
bits in the SIM module. These bits are cleared after any reset, which disables the clock to
the corresponding module to conserve power. Prior to initializing the corresponding
module, set SCGC5[PORTx] in the SIM module to enable the clock. Before turning off
the clock, make sure to disable the module. For more details, refer to the clock
distribution chapter.
10.2.3 Signal multiplexing constraints
1. A given peripheral function must be assigned to a maximum of one package pin. Do
not program the same function to more than one pin.
2. To ensure the best signal timing for a given peripheral's interface, choose the pins in
closest proximity to each other.
10.3 Pinout
10.3.1 KL04 signal multiplexing and pin assignments
The following table shows the signals available on each pin and the locations of these
pins on the devices supported by this document. The Port Control Module is responsible
for selecting which ALT functionality is available on each pin.
48
LQFP
32
QFN
32
LQFP
24
QFN
Pin Name
Default
ALT0
ALT1
ALT2
1
1
1
1
PTB6/
IRQ_2/
LPTMR0_ALT3
DISABLED
DISABLED
PTB6/
IRQ_2/
LPTMR0_ALT3
TPM0_CH3
2
2
2
2
PTB7/
IRQ_3
DISABLED
DISABLED
PTB7/
IRQ_3
TPM0_CH2
ALT3
TPM_CLKIN1
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143
Pinout
48
LQFP
32
QFN
32
LQFP
24
QFN
Pin Name
Default
ALT0
ALT1
3
—
—
—
PTA14
DISABLED
DISABLED
PTA14
TPM_CLKIN0
4
—
—
—
PTA15
DISABLED
DISABLED
PTA15
CLKOUT
5
3
3
3
VDD
VDD
VDD
6
4
4
3
VREFH
VREFH
VREFH
7
5
5
4
VREFL
VREFL
VREFL
8
6
6
4
VSS
VSS
VSS
9
7
7
5
PTA3
EXTAL0
EXTAL0
PTA3
I2C0_SCL
I2C0_SDA
10
8
8
6
PTA4/
LLWU_P0
XTAL0
XTAL0
PTA4/
LLWU_P0
I2C0_SDA
I2C0_SCL
11
—
—
—
VSS
VSS
VSS
12
—
—
—
PTB18
DISABLED
DISABLED
PTB18
13
—
—
—
PTB19
DISABLED
DISABLED
PTB19
14
9
9
7
PTA5/
LLWU_P1/
RTC_CLK_IN
DISABLED
DISABLED
PTA5/
LLWU_P1/
RTC_CLK_IN
TPM0_CH5
SPI0_SS_b
15
10
10
8
PTA6/
LLWU_P2
DISABLED
DISABLED
PTA6/
LLWU_P2
TPM0_CH4
SPI0_MISO
16
11
11
—
PTB8
ADC0_SE11
ADC0_SE11
PTB8
TPM0_CH3
17
12
12
—
PTB9
ADC0_SE10
ADC0_SE10
PTB9
TPM0_CH2
18
—
—
—
PTA16/
IRQ_4
DISABLED
DISABLED
PTA16/
IRQ_4
19
—
—
—
PTA17/
IRQ_5
DISABLED
DISABLED
PTA17/
IRQ_5
20
—
—
—
PTA18/
IRQ_6
DISABLED
DISABLED
PTA18/
IRQ_6
21
13
13
9
PTB10
ADC0_SE9
ADC0_SE9
PTB10
TPM0_CH1
22
14
14
10
PTB11
ADC0_SE8
ADC0_SE8
PTB11
TPM0_CH0
23
15
15
11
PTA7/
IRQ_7/
LLWU_P3
ADC0_SE7
ADC0_SE7
PTA7/
IRQ_7/
LLWU_P3
SPI0_MISO
SPI0_MOSI
24
16
16
12
PTB0/
IRQ_8/
LLWU_P4
ADC0_SE6
ADC0_SE6
PTB0/
IRQ_8/
LLWU_P4
EXTRG_IN
SPI0_SCK
25
17
17
13
PTB1/
IRQ_9
ADC0_SE5/
CMP0_IN3
ADC0_SE5/
CMP0_IN3
PTB1/
IRQ_9
UART0_TX
UART0_RX
26
18
18
14
PTB2/
IRQ_10/
LLWU_P5
ADC0_SE4
ADC0_SE4
PTB2/
IRQ_10/
LLWU_P5
UART0_RX
UART0_TX
27
19
19
15
PTA8
ADC0_SE3
ADC0_SE3
PTA8
28
20
20
16
PTA9
ADC0_SE2
ADC0_SE2
PTA9
29
—
—
—
PTB20
DISABLED
DISABLED
PTB20
30
—
—
—
VSS
VSS
VSS
31
—
—
—
VDD
VDD
VDD
32
—
—
—
PTB14/
IRQ_11
DISABLED
DISABLED
PTB14/
IRQ_11
ALT2
ALT3
EXTRG_IN
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Chapter 10 Signal Multiplexing and Signal Descriptions
48
LQFP
32
QFN
32
LQFP
24
QFN
Pin Name
Default
ALT0
ALT1
ALT2
ALT3
33
21
21
—
PTA10/
IRQ_12
DISABLED
DISABLED
PTA10/
IRQ_12
34
22
22
—
PTA11/
IRQ_13
DISABLED
DISABLED
PTA11/
IRQ_13
35
23
23
17
PTB3/
IRQ_14
DISABLED
DISABLED
PTB3/
IRQ_14
I2C0_SCL
UART0_TX
36
24
24
18
PTB4/
IRQ_15/
LLWU_P6
DISABLED
DISABLED
PTB4/
IRQ_15/
LLWU_P6
I2C0_SDA
UART0_RX
37
25
25
19
PTB5/
IRQ_16
NMI_b
ADC0_SE1/
CMP0_IN1
PTB5/
IRQ_16
TPM1_CH1
NMI_b
38
26
26
20
PTA12/
IRQ_17/
LPTMR0_ALT2
ADC0_SE0/
CMP0_IN0
ADC0_SE0/
CMP0_IN0
PTA12/
IRQ_17/
LPTMR0_ALT2
TPM1_CH0
TPM_CLKIN0
39
27
27
—
PTA13
DISABLED
DISABLED
PTA13
40
28
28
—
PTB12
DISABLED
DISABLED
PTB12
41
—
—
—
PTA19
DISABLED
DISABLED
PTA19
42
—
—
—
PTB15
DISABLED
DISABLED
PTB15
SPI0_MOSI
SPI0_MISO
43
—
—
—
PTB16
DISABLED
DISABLED
PTB16
SPI0_MISO
SPI0_MOSI
44
—
—
—
PTB17
DISABLED
DISABLED
PTB17
TPM_CLKIN1
SPI0_SCK
45
29
29
21
PTB13
ADC0_SE13
ADC0_SE13
PTB13
TPM1_CH1
RTC_CLKOUT
46
30
30
22
PTA0/
IRQ_0/
LLWU_P7
SWD_CLK
ADC0_SE12/
CMP0_IN2
PTA0/
IRQ_0/
LLWU_P7
TPM1_CH0
SWD_CLK
47
31
31
23
PTA1/
IRQ_1/
LPTMR0_ALT1
RESET_b
DISABLED
PTA1/
IRQ_1/
LPTMR0_ALT1
TPM_CLKIN0
RESET_b
48
32
32
24
PTA2
SWD_DIO
DISABLED
PTA2
CMP0_OUT
SWD_DIO
SPI0_SS_b
10.3.2 KL04 Pinouts
The following figures show the pinout diagrams for the devices supported by this
document. Many signals may be multiplexed onto a single pin. To determine what signals
can be used on which pin, see the previous section.
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PTA2
PTA1/IRQ_1/LPTMR0_ALT1
PTA0/IRQ_0/LLWU_P7
PTB13
PTB17
PTB16
PTB15
PTA19
PTB12
PTA13
PTA12/IRQ_17/LPTMR0_ALT2
PTB5/IRQ_16
48
47
46
45
44
43
42
41
40
39
38
37
Pinout
VREFL
7
30
VSS
VSS
8
29
PTB20
PTA3
9
28
PTA9
PTA4/LLWU_P0
10
27
PTA8
VSS
11
26
PTB2/IRQ_10/LLWU_P5
PTB18
12
25
PTB1/IRQ_9
24
VDD
PTB0/IRQ_8/LLWU_P4
31
23
6
PTA7/IRQ_7/LLWU_P3
VREFH
22
PTB14/IRQ_11
PTB11
32
21
5
PTB10
VDD
20
PTA10/IRQ_12
PTA18/IRQ_6
33
19
4
PTA17/IRQ_5
PTA15
18
PTA11/IRQ_13
PTA16/IRQ_4
34
17
3
PTB9
PTA14
16
PTB3/IRQ_14
PTB8
35
15
2
PTA6/LLWU_P2
PTB7/IRQ_3
14
PTB4/IRQ_15/LLWU_P6
PTA5/LLWU_P1/RTC_CLK_IN
36
13
1
PTB19
PTB6/IRQ_2/LPTMR0_ALT3
Figure 10-2. KL04 48-pin LQFP pinout diagram
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Freescale Semiconductor, Inc.
PTA2
PTA1/IRQ_1/LPTMR0_ALT1
PTA0/IRQ_0/LLWU_P7
PTB13
PTB12
PTA13
PTA12/IRQ_17/LPTMR0_ALT2
PTB5/IRQ_16
32
31
30
29
28
27
26
25
Chapter 10 Signal Multiplexing and Signal Descriptions
21
PTA10/IRQ_12
VREFL
5
20
PTA9
VSS
6
19
PTA8
PTA3
7
18
PTB2/IRQ_10/LLWU_P5
PTA4/LLWU_P0
8
17
PTB1/IRQ_9
PTA6/LLWU_P2
PTA5/LLWU_P1/RTC_CLK_IN
16
4
PTB0/IRQ_8/LLWU_P4
VREFH
15
PTA11/IRQ_13
PTA7/IRQ_7/LLWU_P3
22
14
3
PTB11
VDD
13
PTB3/IRQ_14
PTB10
23
12
2
PTB9
PTB7/IRQ_3
11
PTB4/IRQ_15/LLWU_P6
PTB8
24
10
1
9
PTB6/IRQ_2/LPTMR0_ALT3
Figure 10-3. KL04 32-pin LQFP pinout diagram
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Freescale Semiconductor, Inc.
147
PTA2
PTA1/IRQ_1/LPTMR0_ALT1
PTA0/IRQ_0/LLWU_P7
PTB13
PTB12
PTA13
PTA12/IRQ_17/LPTMR0_ALT2
PTB5/IRQ_16
32
31
30
29
28
27
26
25
Pinout
21
PTA10/IRQ_12
VREFL
5
20
PTA9
VSS
6
19
PTA8
PTA3
7
18
PTB2/IRQ_10/LLWU_P5
PTA4/LLWU_P0
8
17
PTB1/IRQ_9
PTA6/LLWU_P2
PTA5/LLWU_P1/RTC_CLK_IN
16
4
PTB0/IRQ_8/LLWU_P4
VREFH
15
PTA11/IRQ_13
PTA7/IRQ_7/LLWU_P3
22
14
3
PTB11
VDD
13
PTB3/IRQ_14
PTB10
23
12
2
PTB9
PTB7/IRQ_3
11
PTB4/IRQ_15/LLWU_P6
PTB8
24
10
1
9
PTB6/IRQ_2/LPTMR0_ALT3
Figure 10-4. KL04 32-pin QFN pinout diagram
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Freescale Semiconductor, Inc.
PTA2
PTA1/IRQ_1/LPTMR0_ALT1
PTA0/IRQ_0/LLWU_P7
PTB13
PTA12/IRQ_17/LPTMR0_ALT2
PTB5/IRQ_16
24
23
22
21
20
19
Chapter 10 Signal Multiplexing and Signal Descriptions
VDD VREFH
3
16
PTA9
VREFL VSS
4
15
PTA8
PTA3
5
14
PTB2/IRQ_10/LLWU_P5
PTA4/LLWU_P0
6
13
PTB1/IRQ_9
8
PTB10
PTA6/LLWU_P2
PTA5/LLWU_P1/RTC_CLK_IN
12
PTB3/IRQ_14
PTB0/IRQ_8/LLWU_P4
17
11
2
PTA7/IRQ_7/LLWU_P3
PTB7/IRQ_3
10
PTB4/IRQ_15/LLWU_P6
PTB11
18
9
1
7
PTB6/IRQ_2/LPTMR0_ALT3
Figure 10-5. KL04 24-pin QFN pinout diagram
10.4 Module Signal Description Tables
The following sections correlate the chip-level signal name with the signal name used in
the module's chapter. They also briefly describe the signal function and direction.
10.4.1 Core Modules
Table 10-3. SWD Signal Descriptions
Chip signal name
Module signal
name
SWD_DIO
SWD_DIO
Description
Serial wire debug data input/output. The SWD_DIO pin is used by
an external debug tool for communication and device control. This
pin is pulled up internally.
I/O
Input /
Output
Table continues on the next page...
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Module Signal Description Tables
Table 10-3. SWD Signal Descriptions
(continued)
Chip signal name
Module signal
name
SWD_CLK
SWD_CLK
Description
I/O
Serial Wire Clock. This pin is the clock for debug logic when in the
Serial Wire Debug mode. This pin is pulled down internally.
Input
10.4.2 System Modules
Table 10-4. System Signal Descriptions
Chip signal name
Module signal
name
NMI
—
Description
I/O
Non-maskable interrupt
I
NOTE: Driving the NMI signal low forces a non-maskable
interrupt, if the NMI function is selected on the
corresponding pin.
RESET
—
Reset bi-directional signal
I/O
VDD
—
MCU power
I
VSS
—
MCU ground
I
10.4.3 Clock Modules
Table 10-5. OSC Signal Descriptions
Chip signal name
Module signal
name
EXTAL0
EXTAL
XTAL0
XTAL
Description
I/O
External clock/Oscillator input
I
Oscillator output
O
10.4.4 Memories and Memory Interfaces
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Chapter 10 Signal Multiplexing and Signal Descriptions
10.4.5 Analog
Table 10-6. ADC 0 Signal Descriptions
Chip signal name
Module signal
name
ADC0_SEn
ADn
VREFH
VREFL
VDDA
VSSA
Description
I/O
Single-Ended Analog Channel Inputs
I
VREFSH
Voltage Reference Select High
I
VREFSL
Voltage Reference Select Low
I
VDDA
Analog Power Supply
I
VSSA
Analog Ground
I
Table 10-7. CMP 0 Signal Descriptions
Chip signal name
Module signal
name
Description
I/O
CMP0_IN[5:0]
IN[5:0]
Analog voltage inputs
I
CMP0_OUT
CMPO
Comparator output
O
10.4.6 Timer Modules
Table 10-8. TPM 0 Signal Descriptions
Chip signal name
Module signal
name
TPM_CLKIN[1:0]
EXTCLK
TPM0_CH[5:0]
CHn
Description
External clock. FTM external clock can be selected to drive the
FTM counter.
FTM channel (n), where n can be 7-0
I/O
I
I/O
Table 10-9. TPM 1 Signal Descriptions
Chip signal name
Module signal
name
Description
TPM_CLKIN[1:0]
TPM_EXTCLK
External clock. TPM external clock can be selected to increment the
TPM counter on every rising edge synchronized to the counter
clock.
TPM1_CH[1:0]
TPM_CHn
TPM channel (n = 5 to 0)
I/O
I
I/O
Table 10-10. LPTMR 0 Signal Descriptions
Chip signal name
Module signal
name
Description
LPTMR0_ALT[2:1]
LPTMR_ALTn
Pulse Counter Input pin
I/O
I
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Module Signal Description Tables
Table 10-11. RTC Signal Descriptions
Chip signal name
Module signal
name
Description
I/O
RTC_CLKOUT1
RTC_CLKOUT
1 Hz square-wave output
O
1. RTC_CLKOUT can also be driven with OSCERCLK via SIM control bit SIM_SOPT[RCTCLKOUTSEL]
10.4.7 Communication Interfaces
Table 10-12. SPI0 Signal Descriptions
Chip signal name
Module signal
name
Description
I/O
SPI0_MISO
MISO
Master Data In, Slave Data Out
I/O
SPI0_MOSI
MOSI
Master Data Out, Slave Data In
I/O
SPI0_SCLK
SPSCK
SPI Serial Clock
I/O
SPI0_PCS0
SS
Slave Select
I/O
Table 10-13. I2C 0 Signal Descriptions
Chip signal name
Module signal
name
I2C0_SCL
SCL
I2C0_SDA
SDA
Description
I/O
Bidirectional serial clock line of the I2C system.
Bidirectional serial data line of the
I2C
I/O
system.
I/O
Table 10-14. UART 0 Signal Descriptions
Chip signal name
Module signal
name
Description
I/O
UART0_TX
TXD
Transmit data
O
UART0_RX
RXD
Receive data
I
10.4.8 Human-Machine Interfaces (HMI)
Table 10-15. GPIO Signal Descriptions
Chip signal name
Module signal
name
Description
I/O
PTA[31:0]1
PORTA31–PORTA0 General-purpose input/output
I/O
PTB[31:0]1
PORTB31–PORTB0 General-purpose input/output
I/O
1. The available GPIO pins depends on the specific package. See the signal multiplexing section for which exact GPIO
signals are available.
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Chapter 11
Port control and interrupts (PORT)
11.1 Introduction
NOTE
For the chip-specific implementation details of this module's
instances see the chip configuration information.
11.2 Overview
The port control and interrupt (PORT) module provides support for port control, and
external interrupt functions. Most functions can be configured independently for each pin
in the 32-bit port and affect the pin regardless of its pin muxing state.
There is one instance of the PORT module for each port. Not all pins within each port are
implemented on a specific device.
11.2.1 Features
The PORT module has the following features:
• Pin interrupt on selected pins
• Interrupt flag and enable registers for each pin
• Support for edge sensitive (rising, falling, both) or level sensitive (low, high)
configured per pin
• Support for interrupt or DMA request configured per pin
• Asynchronous wakeup in Low-Power modes
• Pin interrupt is functional in all digital Pin Muxing modes
• Port control
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External signal description
• Individual pull control fields with pullup, pulldown, and pull-disablesupport on
selected pins
• Individual drive strength field supporting high and low drive strength on selected
pins
• Individual slew rate field supporting fast and slow slew rates on selected pins
• Individual input passive filter field supporting enable and disable of the
individual input passive filter on selected pins
• Individual mux control field supporting analog or pin disabled, GPIO, and up to
four chip-specific digital functions
• Pad configuration fields are functional in all digital Pin Muxing modes
11.2.2 Modes of operation
11.2.2.1 Run mode
In Run mode, the PORT operates normally.
11.2.2.2 Wait mode
In Wait mode, PORT continues to operate normally and may be configured to exit the
Low-Power mode if an enabled interrupt is detected. DMA requests are still generated
during the Wait mode, but do not cause an exit from the Low-Power mode.
11.2.2.3 Stop mode
In Stop mode, the PORT can be configured to exit the Low-Power mode via an
asynchronous wakeup signal if an enabled interrupt is detected.
11.2.2.4 Debug mode
In Debug mode, PORT operates normally.
11.3 External signal description
The following table describes the PORT external signal.
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Chapter 11 Port control and interrupts (PORT)
Table 11-1. Signal properties
Name
Function
I/O
Reset
Pull
PORTx[31:0]
External interrupt
I/O
0
-
NOTE
Not all pins within each port are implemented on each device.
11.4 Detailed signal description
The following table contains the detailed signal description for the PORT interface.
Table 11-2. PORT interface—detailed signal description
Signal
PORTx[31:0]
I/O
I/O
Description
External interrupt.
State meaning
Asserted—pin is logic one.
Negated—pin is logic zero.
Timing
Assertion—may occur at any time and can assert
asynchronously to the system clock.
Negation—may occur at any time and can assert
asynchronously to the system clock.
11.5 Memory map and register definition
Any read or write access to the PORT memory space that is outside the valid memory
map results in a bus error. All register accesses complete with zero wait states.
PORT memory map
Absolute
address
(hex)
Register name
Width
Access
(in bits)
Reset value
Section/
page
4004_9000
Pin Control Register n (PORTA_PCR0)
32
R/W
See section
11.5.1/158
4004_9004
Pin Control Register n (PORTA_PCR1)
32
R/W
See section
11.5.1/158
4004_9008
Pin Control Register n (PORTA_PCR2)
32
R/W
See section
11.5.1/158
4004_900C
Pin Control Register n (PORTA_PCR3)
32
R/W
See section
11.5.1/158
4004_9010
Pin Control Register n (PORTA_PCR4)
32
R/W
See section
11.5.1/158
4004_9014
Pin Control Register n (PORTA_PCR5)
32
R/W
See section
11.5.1/158
4004_9018
Pin Control Register n (PORTA_PCR6)
32
R/W
See section
11.5.1/158
4004_901C
Pin Control Register n (PORTA_PCR7)
32
R/W
See section
11.5.1/158
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Memory map and register definition
PORT memory map (continued)
Absolute
address
(hex)
Register name
Width
Access
(in bits)
Reset value
Section/
page
4004_9020
Pin Control Register n (PORTA_PCR8)
32
R/W
See section
11.5.1/158
4004_9024
Pin Control Register n (PORTA_PCR9)
32
R/W
See section
11.5.1/158
4004_9028
Pin Control Register n (PORTA_PCR10)
32
R/W
See section
11.5.1/158
4004_902C
Pin Control Register n (PORTA_PCR11)
32
R/W
See section
11.5.1/158
4004_9030
Pin Control Register n (PORTA_PCR12)
32
R/W
See section
11.5.1/158
4004_9034
Pin Control Register n (PORTA_PCR13)
32
R/W
See section
11.5.1/158
4004_9038
Pin Control Register n (PORTA_PCR14)
32
R/W
See section
11.5.1/158
4004_903C
Pin Control Register n (PORTA_PCR15)
32
R/W
See section
11.5.1/158
4004_9040
Pin Control Register n (PORTA_PCR16)
32
R/W
See section
11.5.1/158
4004_9044
Pin Control Register n (PORTA_PCR17)
32
R/W
See section
11.5.1/158
4004_9048
Pin Control Register n (PORTA_PCR18)
32
R/W
See section
11.5.1/158
4004_904C
Pin Control Register n (PORTA_PCR19)
32
R/W
See section
11.5.1/158
4004_9050
Pin Control Register n (PORTA_PCR20)
32
R/W
See section
11.5.1/158
4004_9054
Pin Control Register n (PORTA_PCR21)
32
R/W
See section
11.5.1/158
4004_9058
Pin Control Register n (PORTA_PCR22)
32
R/W
See section
11.5.1/158
4004_905C
Pin Control Register n (PORTA_PCR23)
32
R/W
See section
11.5.1/158
4004_9060
Pin Control Register n (PORTA_PCR24)
32
R/W
See section
11.5.1/158
4004_9064
Pin Control Register n (PORTA_PCR25)
32
R/W
See section
11.5.1/158
4004_9068
Pin Control Register n (PORTA_PCR26)
32
R/W
See section
11.5.1/158
4004_906C
Pin Control Register n (PORTA_PCR27)
32
R/W
See section
11.5.1/158
4004_9070
Pin Control Register n (PORTA_PCR28)
32
R/W
See section
11.5.1/158
4004_9074
Pin Control Register n (PORTA_PCR29)
32
R/W
See section
11.5.1/158
4004_9078
Pin Control Register n (PORTA_PCR30)
32
R/W
See section
11.5.1/158
4004_907C
Pin Control Register n (PORTA_PCR31)
32
R/W
See section
11.5.1/158
4004_9080
Global Pin Control Low Register (PORTA_GPCLR)
32
W
(always 0000_0000h
reads 0)
11.5.2/160
4004_9084
Global Pin Control High Register (PORTA_GPCHR)
32
W
(always 0000_0000h
reads 0)
11.5.3/161
4004_90A0
Interrupt Status Flag Register (PORTA_ISFR)
32
w1c
0000_0000h
11.5.4/161
4004_A000
Pin Control Register n (PORTB_PCR0)
32
R/W
See section
11.5.1/158
4004_A004
Pin Control Register n (PORTB_PCR1)
32
R/W
See section
11.5.1/158
4004_A008
Pin Control Register n (PORTB_PCR2)
32
R/W
See section
11.5.1/158
4004_A00C Pin Control Register n (PORTB_PCR3)
32
R/W
See section
11.5.1/158
4004_A010
Pin Control Register n (PORTB_PCR4)
32
R/W
See section
11.5.1/158
4004_A014
Pin Control Register n (PORTB_PCR5)
32
R/W
See section
11.5.1/158
4004_A018
Pin Control Register n (PORTB_PCR6)
32
R/W
See section
11.5.1/158
4004_A01C Pin Control Register n (PORTB_PCR7)
32
R/W
See section
11.5.1/158
Table continues on the next page...
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Chapter 11 Port control and interrupts (PORT)
PORT memory map (continued)
Absolute
address
(hex)
Register name
Width
Access
(in bits)
Reset value
Section/
page
4004_A020
Pin Control Register n (PORTB_PCR8)
32
R/W
See section
11.5.1/158
4004_A024
Pin Control Register n (PORTB_PCR9)
32
R/W
See section
11.5.1/158
4004_A028
Pin Control Register n (PORTB_PCR10)
32
R/W
See section
11.5.1/158
4004_A02C Pin Control Register n (PORTB_PCR11)
32
R/W
See section
11.5.1/158
4004_A030
Pin Control Register n (PORTB_PCR12)
32
R/W
See section
11.5.1/158
4004_A034
Pin Control Register n (PORTB_PCR13)
32
R/W
See section
11.5.1/158
4004_A038
Pin Control Register n (PORTB_PCR14)
32
R/W
See section
11.5.1/158
4004_A03C Pin Control Register n (PORTB_PCR15)
32
R/W
See section
11.5.1/158
4004_A040
Pin Control Register n (PORTB_PCR16)
32
R/W
See section
11.5.1/158
4004_A044
Pin Control Register n (PORTB_PCR17)
32
R/W
See section
11.5.1/158
4004_A048
Pin Control Register n (PORTB_PCR18)
32
R/W
See section
11.5.1/158
4004_A04C Pin Control Register n (PORTB_PCR19)
32
R/W
See section
11.5.1/158
4004_A050
Pin Control Register n (PORTB_PCR20)
32
R/W
See section
11.5.1/158
4004_A054
Pin Control Register n (PORTB_PCR21)
32
R/W
See section
11.5.1/158
4004_A058
Pin Control Register n (PORTB_PCR22)
32
R/W
See section
11.5.1/158
4004_A05C Pin Control Register n (PORTB_PCR23)
32
R/W
See section
11.5.1/158
4004_A060
Pin Control Register n (PORTB_PCR24)
32
R/W
See section
11.5.1/158
4004_A064
Pin Control Register n (PORTB_PCR25)
32
R/W
See section
11.5.1/158
4004_A068
Pin Control Register n (PORTB_PCR26)
32
R/W
See section
11.5.1/158
4004_A06C Pin Control Register n (PORTB_PCR27)
32
R/W
See section
11.5.1/158
4004_A070
Pin Control Register n (PORTB_PCR28)
32
R/W
See section
11.5.1/158
4004_A074
Pin Control Register n (PORTB_PCR29)
32
R/W
See section
11.5.1/158
4004_A078
Pin Control Register n (PORTB_PCR30)
32
R/W
See section
11.5.1/158
4004_A07C Pin Control Register n (PORTB_PCR31)
32
R/W
See section
11.5.1/158
4004_A080
Global Pin Control Low Register (PORTB_GPCLR)
32
W
(always 0000_0000h
reads 0)
11.5.2/160
4004_A084
Global Pin Control High Register (PORTB_GPCHR)
32
W
(always 0000_0000h
reads 0)
11.5.3/161
4004_A0A0 Interrupt Status Flag Register (PORTB_ISFR)
32
w1c
0000_0000h
11.5.4/161
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Memory map and register definition
11.5.1 Pin Control Register n (PORTx_PCRn)
NOTE
Refer to the Signal Multiplexing and Pin Assignment chapter
for the reset value of this device.
See the GPIO Configuration section for details on the available
functions for each pin.
Do not modify pin configuration registers associated with pins
not available in your selected package. All un-bonded pins not
available in your package will default to DISABLE state for
lowest power consumption.
Address: Base address + 0h offset + (4d × i), where i=0d to 31d
Bit
31
30
29
28
27
26
25
0
R
24
22
ISF
21
20
19
18
0
Reset
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
0
R
0
0
0
0
0
*
*
0
7
6
0
MUX
W
0
*
0
DSE
*
17
16
IRQC
w1c
W
Reset
23
0
0
5
4
0
0
PFE
*
0
0
0
0
3
2
1
0
SRE
PE
PS
*
*
*
0
0
* Notes:
• MUX field: Varies by port. See Signal Multiplexing and Signal Descriptions chapter for reset values per port.
• DSE field: Varies by port. See Signal Multiplexing and Signal Descriptions chapter for reset values per port.
• PFE field: Varies by port. See Signal Multiplexing and Signal Descriptions chapter for reset values per port.
• SRE field: Varies by port. See Signal Multiplexing and Signal Descriptions chapter for reset values per port.
• PE field: Varies by port. See Signal Multiplexing and Signal Descriptions chapter for reset values per port.
• PS field: Varies by port. See Signal Multiplexing and Signal Descriptions chapter for reset values per port.
PORTx_PCRn field descriptions
Field
31–25
Reserved
24
ISF
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Interrupt Status Flag
This bit is read only for pins that do not support interrupt generation.
The pin interrupt configuration is valid in all digital pin muxing modes.
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Chapter 11 Port control and interrupts (PORT)
PORTx_PCRn field descriptions (continued)
Field
Description
0
1
23–20
Reserved
19–16
IRQC
Configured interrupt is not detected.
Configured interrupt is detected. If the pin is configured to generate a DMA request, then the
corresponding flag will be cleared automatically at the completion of the requested DMA transfer.
Otherwise, the flag remains set until a logic one is written to the flag. If the pin is configured for a level
sensitive interrupt and the pin remains asserted, then the flag is set again immediately after it is
cleared.
This field is reserved.
This read-only field is reserved and always has the value 0.
Interrupt Configuration
This field is read only for pins that do not support interrupt generation.
The pin interrupt configuration is valid in all digital pin muxing modes. The corresponding pin is configured
to generate interrupt/DMA request as follows:
0000
0001
0010
0011
1000
1001
1010
1011
1100
Others
15–11
Reserved
10–8
MUX
Interrupt/DMA request disabled.
DMA request on rising edge.
DMA request on falling edge.
DMA request on either edge.
Interrupt when logic zero.
Interrupt on rising edge.
Interrupt on falling edge.
Interrupt on either edge.
Interrupt when logic one.
Reserved.
This field is reserved.
This read-only field is reserved and always has the value 0.
Pin Mux Control
Not all pins support all pin muxing slots. Unimplemented pin muxing slots are reserved and may result in
configuring the pin for a different pin muxing slot.
The corresponding pin is configured in the following pin muxing slot as follows:
000
001
010
011
100
101
110
111
7
Reserved
6
DSE
Pin disabled (analog).
Alternative 1 (GPIO).
Alternative 2 (chip-specific).
Alternative 3 (chip-specific).
Alternative 4 (chip-specific).
Alternative 5 (chip-specific).
Alternative 6 (chip-specific).
Alternative 7 (chip-specific).
This field is reserved.
This read-only field is reserved and always has the value 0.
Drive Strength Enable
This bit is read only for pins that do not support a configurable drive strength.
Drive strength configuration is valid in all digital pin muxing modes.
0
1
Low drive strength is configured on the corresponding pin, if pin is configured as a digital output.
High drive strength is configured on the corresponding pin, if pin is configured as a digital output.
Table continues on the next page...
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Memory map and register definition
PORTx_PCRn field descriptions (continued)
Field
Description
5
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
4
PFE
Passive Filter Enable
This bit is read only for pins that do not support a configurable passive input filter.
Passive filter configuration is valid in all digital pin muxing modes.
0
1
3
Reserved
Passive input filter is disabled on the corresponding pin.
Passive input filter is enabled on the corresponding pin, if the pin is configured as a digital input. Refer
to the device data sheet for filter characteristics.
This field is reserved.
This read-only field is reserved and always has the value 0.
2
SRE
Slew Rate Enable
This bit is read only for pins that do not support a configurable slew rate.
Slew rate configuration is valid in all digital pin muxing modes.
0
1
1
PE
Fast slew rate is configured on the corresponding pin, if the pin is configured as a digital output.
Slow slew rate is configured on the corresponding pin, if the pin is configured as a digital output.
Pull Enable
This bit is read only for pins that do not support a configurable pull resistor. Refer to the Chapter of Signal
Multiplexing and Signal Descriptions for the pins that support a configurable pull resistor.
Pull configuration is valid in all digital pin muxing modes.
0
1
0
PS
Internal pullup or pulldown resistor is not enabled on the corresponding pin.
Internal pullup or pulldown resistor is enabled on the corresponding pin, if the pin is configured as a
digital input.
Pull Select
This bit is read only for pins that do not support a configurable pull resistor direction.
Pull configuration is valid in all digital pin muxing modes.
0
1
Internal pulldown resistor is enabled on the corresponding pin, if the corresponding Port Pull Enable
field is set.
Internal pullup resistor is enabled on the corresponding pin, if the corresponding Port Pull Enable field
is set.
11.5.2 Global Pin Control Low Register (PORTx_GPCLR)
Only 32-bit writes are supported to this register.
Address: Base address + 80h offset
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
R
0
0
W
GPWE
GPWD
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
6
5
4
3
2
1
0
0
0
0
0
0
0
0
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Chapter 11 Port control and interrupts (PORT)
PORTx_GPCLR field descriptions
Field
Description
31–16
GPWE
Global Pin Write Enable
Selects which Pin Control Registers (15 through 0) bits [15:0] update with the value in GPWD.
0
1
15–0
GPWD
Corresponding Pin Control Register is not updated with the value in GPWD.
Corresponding Pin Control Register is updated with the value in GPWD.
Global Pin Write Data
Write value that is written to all Pin Control Registers bits [15:0] that are selected by GPWE.
11.5.3 Global Pin Control High Register (PORTx_GPCHR)
Only 32-bit writes are supported to this register.
Address: Base address + 84h offset
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
R
0
0
W
GPWE
GPWD
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
6
5
4
3
2
1
0
0
0
0
0
0
0
0
PORTx_GPCHR field descriptions
Field
31–16
GPWE
Description
Global Pin Write Enable
Selects which Pin Control Registers (31 through 16) bits [15:0] update with the value in GPWD.
0
1
15–0
GPWD
Corresponding Pin Control Register is not updated with the value in GPWD.
Corresponding Pin Control Register is updated with the value in GPWD.
Global Pin Write Data
Write value that is written to all Pin Control Registers bits [15:0] that are selected by GPWE.
11.5.4 Interrupt Status Flag Register (PORTx_ISFR)
The corresponding bit is read only for pins that do not support interrupt generation.
The pin interrupt configuration is valid in all digital pin muxing modes. The Interrupt
Status Flag for each pin is also visible in the corresponding Pin Control Register, and
each flag can be cleared in either location.
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Functional description
Address: Base address + A0h offset
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
R
ISF
W
w1c
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
PORTx_ISFR field descriptions
Field
31–0
ISF
Description
Interrupt Status Flag
Each bit in the field indicates the detection of the configured interrupt of the same number as the field.
0
1
Configured interrupt is not detected.
Configured interrupt is detected. If the pin is configured to generate a DMA request, then the
corresponding flag will be cleared automatically at the completion of the requested DMA transfer.
Otherwise, the flag remains set until a logic one is written to the flag. If the pin is configured for a level
sensitive interrupt and the pin remains asserted, then the flag is set again immediately after it is
cleared.
11.6 Functional description
11.6.1 Pin control
Each port pin has a corresponding pin control register, PORT_PCRn, associated with it.
The upper half of the pin control register configures the pin's capability to either interrupt
the CPU or request a DMA transfer, on a rising/falling edge or both edges as well as a
logic level occurring on the port pin. It also includes a flag to indicate that an interrupt
has occurred.
The lower half of the pin control register configures the following functions for each pin
within the 32-bit port.
•
•
•
•
Pullup or pulldown enable on selected pins
Drive strength and slew rate configuration on selected pins
Passive input filter enable on selected pins
Pin Muxing mode
The functions apply across all digital Pin Muxing modes and individual peripherals do
not override the configuration in the pin control register. For example, if an I2C function
is enabled on a pin, that does not override the pullup configuration for that pin.
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Chapter 11 Port control and interrupts (PORT)
When the Pin Muxing mode is configured for analog or is disabled, all the digital
functions on that pin are disabled. This includes the pullup and pulldown enables, and
passive filter enable.
The configuration of each pin control register is retained when the PORT module is
disabled.
11.6.2 Global pin control
The two global pin control registers allow a single register write to update the lower half
of the pin control register on up to sixteen pins, all with the same value.
The global pin control registers are designed to enable software to quickly configure
multiple pins within the one port for the same peripheral function. However, the interrupt
functions cannot be configured using the global pin control registers.
The global pin control registers are write-only registers, that always read as zero.
11.6.3 External interrupts
The external interrupt capability of the PORT module is available in all digital pin
muxing modes provided the PORT module is enabled.
Each pin can be individually configured for any of the following external interrupt
modes:
•
•
•
•
•
•
•
•
•
Interrupt disabled, default out of reset
Active high level sensitive interrupt
Active low level sensitive interrupt
Rising edge sensitive interrupt
Falling edge sensitive interrupt
Rising and falling edge sensitive interrupt
Rising edge sensitive DMA request
Falling edge sensitive DMA request
Rising and falling edge sensitive DMA request
The interrupt status flag is set when the configured edge or level is detected on the output
of the pin. When not in Stop mode, the input is first synchronized to the bus clock to
detect the configured level or edge transition.
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Functional description
The PORT module generates a single interrupt that asserts when the interrupt status flag
is set for any enabled interrupt for that port. The interrupt negates after the interrupt status
flags for all enabled interrupts have been cleared by writing a logic 1 to the ISF flag in
either the PORT_ISFR or PORT_PCRn registers.
The PORT module generates a single DMA request that asserts when the interrupt status
flag is set for any enabled DMA request in that port. The DMA request negates after the
DMA transfer is completed, because that clears the interrupt status flags for all enabled
DMA requests.
During Stop mode, the interrupt status flag for any enabled interrupt is asynchronously
set if the required level or edge is detected. This also generates an asynchronous wakeup
signal to exit the Low-Power mode.
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Chapter 12
System integration module (SIM)
12.1 Introduction
The system integration module (SIM) provides system control and chip configuration
registers.
12.1.1 Features
• System clocking configuration
• System clock divide values
• Architectural clock gating control
• ERCLK32K clock selection
• UART0 and TPM clock selection
• Flash and System RAM size configuration
• TPM external clock and input capture selection
• UART receive/transmit source selection/configuration
12.2 Memory map and register definition
The SIM module contains many bitfields for selecting the clock source and dividers for
various module clocks.
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Memory map and register definition
NOTE
The SIM registers can be written only in supervisor mode. In
user mode, write accesses are blocked and will result in a bus
error.
NOTE
The SIM_SOPT1 and SIM_SOPT1CFG registers are located at
a different base address than the other SIM registers.
SIM memory map
Absolute
address
(hex)
Register name
Width
Access
(in bits)
Reset value
Section/
page
4004_7000
System Options Register 1 (SIM_SOPT1)
32
R/W
0000_0000h
12.2.1/167
4004_7004
SOPT1 Configuration Register (SIM_SOPT1CFG)
32
R/W
0000_0000h
12.2.2/167
4004_8004
System Options Register 2 (SIM_SOPT2)
32
R/W
0000_0000h
12.2.3/168
4004_800C
System Options Register 4 (SIM_SOPT4)
32
R/W
0000_0000h
12.2.4/170
4004_8010
System Options Register 5 (SIM_SOPT5)
32
R/W
0000_0000h
12.2.5/171
4004_8018
System Options Register 7 (SIM_SOPT7)
32
R/W
0000_0000h
12.2.6/172
4004_8024
System Device Identification Register (SIM_SDID)
32
R
See section
12.2.7/174
4004_8034
System Clock Gating Control Register 4 (SIM_SCGC4)
32
R/W
F000_0030h
12.2.8/176
4004_8038
System Clock Gating Control Register 5 (SIM_SCGC5)
32
R/W
0000_0180h
12.2.9/177
4004_803C
System Clock Gating Control Register 6 (SIM_SCGC6)
32
R/W
0000_0001h
12.2.10/179
4004_8040
System Clock Gating Control Register 7 (SIM_SCGC7)
32
R/W
0000_0100h
12.2.11/180
4004_8044
System Clock Divider Register 1 (SIM_CLKDIV1)
32
R/W
See section
12.2.12/181
4004_804C
Flash Configuration Register 1 (SIM_FCFG1)
32
R/W
See section
12.2.13/183
4004_8050
Flash Configuration Register 2 (SIM_FCFG2)
32
R
See section
12.2.14/184
4004_8058
Unique Identification Register Mid-High (SIM_UIDMH)
32
R
See section
12.2.15/185
4004_805C
Unique Identification Register Mid Low (SIM_UIDML)
32
R
See section
12.2.16/185
4004_8060
Unique Identification Register Low (SIM_UIDL)
32
R
See section
12.2.17/186
4004_8100
COP Control Register (SIM_COPC)
32
R/W
4004_8104
Service COP Register (SIM_SRVCOP)
32
W
0000_000Ch 12.2.18/186
0000_0000h
12.2.19/187
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Chapter 12 System integration module (SIM)
12.2.1 System Options Register 1 (SIM_SOPT1)
NOTE
The SOPT1 register is only reset on POR or LVD.
Address: 4004_7000h base + 0h offset = 4004_7000h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
0
R
19
18
17
16
0
OSC32KSEL
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
R
W
Reset
0
0
0
0
0
0
0
0
SIM_SOPT1 field descriptions
Field
Description
31–20
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
19–18
OSC32KSEL
32K oscillator clock select
Selects the 32 kHz clock source (ERCLK32K) for RTC and LPTMR. This bit is reset only on POR/LVD.
00
01
10
11
17–0
Reserved
System oscillator (OSC32KCLK)
Reserved
RTC_CLKIN
LPO 1kHz
This field is reserved.
This read-only field is reserved and always has the value 0.
12.2.2 SOPT1 Configuration Register (SIM_SOPT1CFG)
NOTE
The SOPT1CFG register is reset on System Reset not VLLS.
Address: 4004_7000h base + 4h offset = 4004_7004h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
0
R
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
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Memory map and register definition
SIM_SOPT1CFG field descriptions
Field
Description
31–24
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
23–0
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
12.2.3 System Options Register 2 (SIM_SOPT2)
SOPT2 contains the controls for selecting many of the module clock source options on
this device. See the Clock Distribution chapter for more information including clocking
diagrams and definitions of device clocks.
Address: 4004_7000h base + 1004h offset = 4004_8004h
Bit
31
30
29
28
27
26
25
24
23
22
21
0
R
20
19
18
17
0
UART0SRC
16
0
TPMSRC
W
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
RTCCLKOUTS
EL
Reset
0
R
CLKOUTSEL
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
SIM_SOPT2 field descriptions
Field
31–28
Reserved
27–26
UART0SRC
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
UART0 clock source select
Selects the clock source for the UART0 transmit and receive clock.
00
01
10
11
25–24
TPMSRC
Clock disabled
MCGFLLCLK clock
OSCERCLK clock
MCGIRCLK clock
TPM clock source select
Table continues on the next page...
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Chapter 12 System integration module (SIM)
SIM_SOPT2 field descriptions (continued)
Field
Description
Selects the clock source for the TPM counter clock
00
01
10
11
Clock disabled
MCGFLLCLK clock
OSCERCLK clock
MCGIRCLK clock
23–18
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
17–16
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
15–8
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
7–5
CLKOUTSEL
CLKOUT select
Selects the clock to output on the CLKOUT pin.
000
001
010
011
100
101
110
111
Reserved
Reserved
Bus clock
LPO clock (1 kHz)
MCGIRCLK
Reserved
OSCERCLK
Reserved
4
RTC clock out select
RTCCLKOUTSEL
Selects either the RTC 1 Hz clock or the OSC clock to be output on the RTC_CLKOUT pin.
0
1
3–0
Reserved
RTC 1 Hz clock is output on the RTC_CLKOUT pin.
OSCERCLK clock is output on the RTC_CLKOUT pin.
This field is reserved.
This read-only field is reserved and always has the value 0.
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Memory map and register definition
12.2.4 System Options Register 4 (SIM_SOPT4)
Address: 4004_7000h base + 100Ch offset = 4004_800Ch
29
28
27
26
25
24
23
22
21
20
19
0
0
18
17
TPM1CH0SRC
30
16
TPM0CLKSEL
31
TPM1CLKSEL
Bit
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
R
0
W
0
0
0
R
W
Reset
0
0
0
0
0
0
0
0
SIM_SOPT4 field descriptions
Field
Description
31–27
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
26
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
25
TPM1CLKSEL
TPM1 External Clock Pin Select
Selects the external pin used to drive the clock to the TPM1 module.
NOTE: The selected pin must also be configured for the TPM external clock function through the
appropriate pin control register in the port control module.
0
1
24
TPM0CLKSEL
TPM1 external clock driven by TPM_CLKIN0 pin.
TPM1 external clock driven by TPM_CLKIN1 pin.
TPM0 External Clock Pin Select
Selects the external pin used to drive the clock to the TPM0 module.
NOTE: The selected pin must also be configured for the TPM external clock function through the
appropriate pin control register in the port control module.
0
1
TPM0 external clock driven by TPM_CLKIN0 pin.
TPM0 external clock driven by TPM_CLKIN1 pin.
23–21
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
20
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
19
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
Table continues on the next page...
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Chapter 12 System integration module (SIM)
SIM_SOPT4 field descriptions (continued)
Field
Description
18
TPM1CH0SRC
TPM1 channel 0 input capture source select
Selects the source for TPM1 channel 0 input capture.
NOTE: When TPM1 is not in input capture mode, clear this field.
0
1
17–0
Reserved
TPM1_CH0 signal
CMP0 output
This field is reserved.
This read-only field is reserved and always has the value 0.
12.2.5 System Options Register 5 (SIM_SOPT5)
Bit
31
30
29
28
27
26
25
24
23
22
21
20
0
R
19
18
17
16
0
0
0
UART0ODE
Address: 4004_7000h base + 1010h offset = 4004_8010h
W
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
R
0
0
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
UART0TXSRC
0
UART0RXSRC
Reset
0
SIM_SOPT5 field descriptions
Field
Description
31–20
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
19
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
18
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
17
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
16
UART0ODE
UART0 Open Drain Enable
0
1
Open drain is disabled on UART0
Open drain is enabled on UART0
Table continues on the next page...
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Memory map and register definition
SIM_SOPT5 field descriptions (continued)
Field
Description
15–7
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
6–4
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
3
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
2
UART0RXSRC
UART0 receive data source select
Selects the source for the UART0 receive data.
0
1
1
Reserved
UART0_RX pin
CMP0 output
This field is reserved.
This read-only field is reserved and always has the value 0.
0
UART0TXSRC
UART0 transmit data source select
Selects the source for the UART0 transmit data.
0
1
UART0_TX pin
UART0_TX pin modulated with TPM1 channel 0 output
12.2.6 System Options Register 7 (SIM_SOPT7)
Address: 4004_7000h base + 1018h offset = 4004_8018h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
R
W
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
R
W
Reset
0
0
0
0
0
0
0
0
0
ADC0PRETRGS
EL
0
ADC0ALTTRGE
N
Reset
0
0
0
0
ADC0TRGSEL
0
0
0
0
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Chapter 12 System integration module (SIM)
SIM_SOPT7 field descriptions
Field
31–8
Reserved
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
7
ADC0 alternate trigger enable
ADC0ALTTRGEN
Enable alternative conversion triggers for ADC0.
0
1
6–5
Reserved
TPM1 channel 0 (A) and channel 1 (B) triggers selected for ADC0.
Alternate trigger selected for ADC0.
This field is reserved.
This read-only field is reserved and always has the value 0.
4
ADC0 pretrigger select
ADC0PRETRGSEL
Selects the ADC0 pre-trigger source when alternative triggers are enabled through ADC0ALTTRGEN.
0
1
3–0
ADC0TRGSEL
Pre-trigger A
Pre-trigger B
ADC0 trigger select
Selects the ADC0 trigger source when alternative triggers are functional in stop and VLPS modes. .
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
External trigger pin input (EXTRG_IN)
CMP0 output
Reserved
Reserved
PIT trigger 0
PIT trigger 1
Reserved
Reserved
TPM0 overflow
TPM1 overflow
Reserved
Reserved
RTC alarm
RTC seconds
LPTMR0 trigger
Reserved
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Memory map and register definition
12.2.7 System Device Identification Register (SIM_SDID)
Address: 4004_7000h base + 1024h offset = 4004_8024h
Bit
31
30
29
28
FAMID
R
27
26
25
24
23
SUBFAMID
22
21
20
SERIESID
19
18
17
16
15
SRAMSIZE
14
13
12
11
10
REVID
9
8
7
6
DIEID
5
4
3
0
2
1
0
PINID
W
Reset
*
*
*
*
*
*
*
*
0
0
0
1
*
*
*
*
*
*
*
*
0
1
0
0
0
0
0
0
*
*
*
*
* Notes:
• FAMID field: Device specific value.
• SUBFAMID field: Device specific value.
• SRAMSIZE field: Device specific value.
• REVID field: Device specific value.
• PINID field: Device specific value.
SIM_SDID field descriptions
Field
31–28
FAMID
Description
Kinetis family ID
Specifies the Kinetis family of the device.
0000
0001
0010
0011
0100
27–24
SUBFAMID
Kinetis Sub-Family ID
Specifies the Kinetis sub-family of the device.
0010
0100
0101
0110
23–20
SERIESID
KLx2 Subfamily (low end)
KLx4 Subfamily (basic analog)
KLx5 Subfamily (advanced analog)
KLx6 Subfamily (advanced analog with I2S)
Kinetis Series ID
Specifies the Kinetis family of the device.
0001
19–16
SRAMSIZE
KL0x Family (low end)
KL1x Family (basic)
KL2x Family (USB)
KL3x Family (Segment LCD)
KL4x Family (USB and Segment LCD)
KL family
System SRAM Size
Specifies the size of the System SRAM
0000
0001
0010
0011
0100
0101
0.5 KB
1 KB
2 KB
4 KB
8 KB
16 KB
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SIM_SDID field descriptions (continued)
Field
Description
0110
0111
32 KB
64 KB
15–12
REVID
Device revision number
11–7
DIEID
Device die number
6–4
Reserved
3–0
PINID
Specifies the silicon implementation number for the device.
Specifies the silicon implementation number for the device.
This field is reserved.
This read-only field is reserved and always has the value 0.
Pincount identification
Specifies the pincount of the device.
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
16-pin
24-pin
32-pin
Reserved
48-pin
64-pin
80-pin
Reserved
100-pin
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
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12.2.8 System Clock Gating Control Register 4 (SIM_SCGC4)
Address: 4004_7000h base + 1034h offset = 4004_8034h
Bit
31
30
29
28
27
26
1
R
25
24
0
23
22
21
0
20
19
0
18
17
0
SPI0
16
0
CMP
W
Reset
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
W
Reset
0
0
0
0
0
UART0
0
R
0
0
0
1
0
I2C0
0
0
0
0
1
1
0
0
SIM_SCGC4 field descriptions
Field
Description
31–28
Reserved
This field is reserved.
This read-only field is reserved and always has the value 1.
27–24
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
23
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
22
SPI0
SPI0 Clock Gate Control
This bit controls the clock gate to the SPI0 module.
0
1
21–20
Reserved
19
CMP
Clock disabled
Clock enabled
This field is reserved.
This read-only field is reserved and always has the value 0.
Comparator Clock Gate Control
This bit controls the clock gate to the comparator module.
0
1
Clock disabled
Clock enabled
18
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
17–14
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
13
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
12
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
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SIM_SCGC4 field descriptions (continued)
Field
Description
11
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
10
UART0
UART0 Clock Gate Control
This bit controls the clock gate to the UART0 module.
0
1
Clock disabled
Clock enabled
9–8
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
7
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
6
I2C0
I2C0 Clock Gate Control
This bit controls the clock gate to the I 2 C0 module.
0
1
Clock disabled
Clock enabled
5–4
Reserved
This field is reserved.
This read-only field is reserved and always has the value 1.
3–0
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
12.2.9 System Clock Gating Control Register 5 (SIM_SCGC5)
Address: 4004_7000h base + 1038h offset = 4004_8038h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
0
R
19
18
0
17
16
0
W
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
R
0
W
Reset
0
0
0
0
0
0
0
1
1
1
0
0
0
0
0
0
LPTMR
0
PORTA
0
PORTB
Reset
0
SIM_SCGC5 field descriptions
Field
31–20
Reserved
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
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Memory map and register definition
SIM_SCGC5 field descriptions (continued)
Field
Description
19
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
18–14
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
13–11
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
10
PORTB
Port B Clock Gate Control
This bit controls the clock gate to the Port B module.
0
1
9
PORTA
Clock disabled
Clock enabled
Port A Clock Gate Control
This bit controls the clock gate to the Port A module.
0
1
Clock disabled
Clock enabled
8–7
Reserved
This field is reserved.
This read-only field is reserved and always has the value 1.
6
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
5
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
4–2
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
1
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
0
LPTMR
Low Power Timer Access Control
This bit controls software access to the Low Power Timer module.
0
1
Access disabled
Access enabled
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12.2.10 System Clock Gating Control Register 6 (SIM_SCGC6)
Address: 4004_7000h base + 103Ch offset = 4004_803Ch
31
30
R
0
0
29
28
26
24
23
22
21
20
19
18
17
16
PIT
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
R
0
DMAMUX
0
TPM0
0
25
TPM1
0
27
FTF
0
1
RTC
W
ADC0
Bit
0
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
SIM_SCGC6 field descriptions
Field
Description
31
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
30
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
29
RTC
RTC Access Control
This bit controls software access and interrupts to the RTC module.
0
1
28
Reserved
27
ADC0
This field is reserved.
This read-only field is reserved and always has the value 0.
ADC0 Clock Gate Control
This bit controls the clock gate to the ADC0 module.
0
1
26
Reserved
25
TPM1
Clock disabled
Clock enabled
This field is reserved.
This read-only field is reserved and always has the value 0.
TPM1 Clock Gate Control
This bit controls the clock gate to the TPM1 module.
0
1
24
TPM0
Access and interrupts disabled
Access and interrupts enabled
Clock disabled
Clock enabled
TPM0 Clock Gate Control
This bit controls the clock gate to the TPM0 module.
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Memory map and register definition
SIM_SCGC6 field descriptions (continued)
Field
Description
0
1
23
PIT
Clock disabled
Clock enabled
PIT Clock Gate Control
This bit controls the clock gate to the PIT module.
0
1
Clock disabled
Clock enabled
22–16
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
15
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
14–2
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
1
DMAMUX
DMA Mux Clock Gate Control
This bit controls the clock gate to the DMA Mux module.
0
1
0
FTF
Clock disabled
Clock enabled
Flash Memory Clock Gate Control
This bit controls the clock gate to the flash memory. Flash reads are still supported while the flash memory
is clock gated, but entry into low power modes is blocked.
0
1
Clock disabled
Clock enabled
12.2.11 System Clock Gating Control Register 7 (SIM_SCGC7)
Address: 4004_7000h base + 1040h offset = 4004_8040h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
0
0
0
3
2
1
0
0
0
0
0
0
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
0
R
DMA
W
Reset
0
0
0
0
0
0
0
0
1
0
0
0
0
SIM_SCGC7 field descriptions
Field
31–9
Reserved
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
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SIM_SCGC7 field descriptions (continued)
Field
Description
8
DMA
DMA Clock Gate Control
This bit controls the clock gate to the DMA module.
0
1
7–0
Reserved
Clock disabled
Clock enabled
This field is reserved.
This read-only field is reserved and always has the value 0.
12.2.12 System Clock Divider Register 1 (SIM_CLKDIV1)
NOTE
The CLKDIV1 register cannot be written to when the device is
in VLPR mode.
NOTE
Reset value loaded during System Reset from
FTF_FOPT[LPBOOT].
Address: 4004_7000h base + 1044h offset = 4004_8044h
Bit
31
R
29
28
27
26
25
24
*
*
*
23
22
21
20
19
0
OUTDIV1
W
Reset
30
*
0
0
0
0
0
18
17
16
15
14
13
12
11
10
9
8
OUTDIV4
0
0
0
0
0
0
1
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
* Notes:
• OUTDIV1 field: The reset value depends on the FTF_FOPT[LPBOOT]. it is loaded with 0000 (divide by one), 0001 (divide
by two), 0011 (divide by four), or 0111 (divide by eight).
SIM_CLKDIV1 field descriptions
Field
31–28
OUTDIV1
Description
Clock 1 output divider value
This field sets the divide value for the core/system clock, as well as the bus/flash clocks. At the end of
reset, it is loaded with 0000 (divide by one), 0001 (divide by two), 0011 (divide by four), or 0111 (divide by
eight) depending on the setting of the two FTF_FOPT[LPBOOT] configuration bits.
0000
0001
0010
0011
0100
0101
0110
0111
Divide-by-1.
Divide-by-2.
Divide-by-3.
Divide-by-4.
Divide-by-5.
Divide-by-6.
Divide-by-7.
Divide-by-8.
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Memory map and register definition
SIM_CLKDIV1 field descriptions (continued)
Field
Description
1000
1001
1010
1011
1100
1101
1110
1111
Divide-by-9.
Divide-by-10.
Divide-by-11.
Divide-by-12.
Divide-by-13.
Divide-by-14.
Divide-by-15.
Divide-by-16.
27–19
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
18–16
OUTDIV4
Clock 4 output divider value
This field sets the divide value for the bus and flash clock and is in addition to the System clock divide
ratio. At the end of reset, it is loaded with 0001 (divide by two).
000
001
010
011
100
101
110
111
15–0
Reserved
Divide-by-1.
Divide-by-2.
Divide-by-3.
Divide-by-4.
Divide-by-5.
Divide-by-6.
Divide-by-7.
Divide-by-8.
This field is reserved.
This read-only field is reserved and always has the value 0.
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12.2.13 Flash Configuration Register 1 (SIM_FCFG1)
Address: 4004_7000h base + 104Ch offset = 4004_804Ch
Bit
31
30
29
28
27
0
R
26
25
24
23
22
21
20
PFSIZE
19
18
17
16
0
Reset
0
0
0
0
*
*
*
*
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
FLASHDOZE
FLASHDIS
W
0
0
0
0
0
0
0
0
0
0
R
W
Reset
0
0
0
0
0
0
0
* Notes:
• PFSIZE field: Device specific value.
SIM_FCFG1 field descriptions
Field
31–28
Reserved
27–24
PFSIZE
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Program flash size
This field specifies the amount of program flash memory available on the device . Undefined values are
reserved.
0000
0001
0011
0101
0111
1001
1111
8 KB of program flash memory, 0.25 KB protection region
16 KB of program flash memory, 0.5 KB protection region
32 KB of program flash memory, 1 KB protection region
64 KB of program flash memory, 2 KB protection region
128 KB of program flash memory, 4 KB protection region
256 KB of program flash memory, 8 KB protection region
32 KB of program flash memory, 1 KB protection region
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Memory map and register definition
SIM_FCFG1 field descriptions (continued)
Field
Description
23–2
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
1
FLASHDOZE
Flash Doze
When set, Flash memory is disabled for the duration of Doze mode. This bit should be clear during VLP
modes. The Flash will be automatically enabled again at the end of Doze mode so interrupt vectors do not
need to be relocated out of Flash memory. The wakeup time from Doze mode is extended when this bit is
set. An attempt by the DMA or other bus master to access the Flash when the Flash is disabled will result
in a bus error.
0
1
0
FLASHDIS
Flash remains enabled during Doze mode
Flash is disabled for the duration of Doze mode
Flash Disable
Flash accesses are disabled (and generate a bus error) and the Flash memory is placed in a low power
state. This bit should not be changed during VLP modes. Relocate the interrupt vectors out of Flash
memory before disabling the Flash.
0
1
Flash is enabled
Flash is disabled
12.2.14 Flash Configuration Register 2 (SIM_FCFG2)
Address: 4004_7000h base + 1050h offset = 4004_8050h
Bit
31
R
0
30
29
28
27
26
25
24
23
MAXADDR0
22
21
20
1
19
18
17
16
0
W
Reset
0
*
*
*
*
*
*
*
Bit
15
14
13
12
11
10
9
8
1
0
0
0
0
0
0
0
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
R
W
Reset
0
0
0
0
0
0
0
0
* Notes:
• MAXADDR0 field: Device specific value indicating amount of implemented flash.
SIM_FCFG2 field descriptions
Field
31
Reserved
30–24
MAXADDR0
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Max address block
This field concatenated with leading zeros indicates the first invalid address of program flash.
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SIM_FCFG2 field descriptions (continued)
Field
Description
For example, if MAXADDR0 = 0x10 the first invalid address of program flash is 0x0002_0000. This would
be the MAXADDR0 value for a device with 128 KB program flash.
23
Reserved
This field is reserved.
This read-only field is reserved and always has the value 1.
22–16
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
15–0
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
12.2.15 Unique Identification Register Mid-High (SIM_UIDMH)
Address: 4004_7000h base + 1058h offset = 4004_8058h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
0
R
8
7
6
5
4
3
2
1
0
*
*
*
*
*
*
*
UID
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
*
*
*
*
*
*
*
*
*
* Notes:
• UID field: Device specific value.
SIM_UIDMH field descriptions
Field
Description
31–16
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
15–0
UID
Unique Identification
Unique identification for the device.
12.2.16 Unique Identification Register Mid Low (SIM_UIDML)
Address: 4004_7000h base + 105Ch offset = 4004_805Ch
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
UID
R
W
Reset
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
* Notes:
• UID field: Device specific value.
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Memory map and register definition
SIM_UIDML field descriptions
Field
Description
31–0
UID
Unique Identification
Unique identification for the device.
12.2.17 Unique Identification Register Low (SIM_UIDL)
Address: 4004_7000h base + 1060h offset = 4004_8060h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
UID
R
W
Reset
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
* Notes:
• UID field: Device specific value.
SIM_UIDL field descriptions
Field
Description
31–0
UID
Unique Identification
Unique identification for the device.
12.2.18 COP Control Register (SIM_COPC)
All of the bits in this register can be written only once after a reset.
Address: 4004_7000h base + 1100h offset = 4004_8100h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
R
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
COPCLKS
COPW
W
0
0
0
R
COPT
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
1
1
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Chapter 12 System integration module (SIM)
SIM_COPC field descriptions
Field
Description
31–4
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
3–2
COPT
COP Watchdog Timeout
These write-once bits select the timeout period of the COP. The COPT field along with the COPCLKS bit
define the COP timeout period.
00
01
10
11
1
COPCLKS
COP disabled
COP timeout after 25 LPO cycles or 213 bus clock cycles
COP timeout after 28 LPO cycles or 216 bus clock cycles
COP timeout after 210 LPO cycles or 218 bus clock cycles
COP Clock Select
This write-once bit selects the clock source of the COP watchdog.
0
1
0
COPW
Internal 1 kHz clock is source to COP
Bus clock is source to COP
COP windowed mode
Windowed mode is only supported when COP is running from the bus clock. The COP window is opened
three quarters through the timeout period.
0
1
Normal mode
Windowed mode
12.2.19 Service COP Register (SIM_SRVCOP)
Address: 4004_7000h base + 1104h offset = 4004_8104h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
R
Reserved
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
SRVCOP
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
SIM_SRVCOP field descriptions
Field
Description
31–8
Reserved
This field is reserved.
7–0
SRVCOP
Sevice COP Register
Write 0x55 and then 0xAA (in that order) to reset the COP timeout counter.
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Functional description
12.3 Functional description
See Introduction section.
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Chapter 13
System Mode Controller (SMC)
13.1 Introduction
NOTE
For the chip-specific implementation details of this module's
instances see the chip configuration information.
The system mode controller (SMC) is responsible for sequencing the system into and out
of all low power stop and run modes. Specifically, it monitors events to trigger transitions
between power modes while controlling the power, clocks, and memories of the system
to achieve the power consumption and functionality of that mode.
This chapter describes all the available low power modes, the sequence followed to enter/
exit each mode, and the functionality available while in each of the modes.
The SMC is able to function during even the deepest low power modes.
13.2 Modes of operation
The ARM CPU has three primary modes of operation:
• Run
• Sleep
• Deep Sleep
The WFI or WFE instruction is used to invoke Sleep and Deep Sleep modes. Run, wait
and stop are the common terms used for the primary operating modes of Freescale
microcontrollers. The following table shows the translation between the ARM CPU
modes and the Freescale MCU power modes.
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Modes of operation
ARM CPU mode
MCU mode
Sleep
Wait
Deep Sleep
Stop
Accordingly, the ARM CPU documentation refers to sleep and deep sleep, while the
Freescale MCU documentation normally uses wait and stop.
In addition, Freescale MCUs also augment stop, wait, and run modes in a number of
ways. The power management controller (PMC) contains a run and a stop mode
regulator. Run regulation is used in normal run, wait and stop modes. Stop mode
regulation is used during all very low power and low leakage modes. During stop mode
regulation, the bus frequencies are limited in the very low power modes.
The SMC provides the user with multiple power options. The Very Low Power Run
(VLPR) mode can drastically reduce run time power when maximum bus frequency is
not required to handle the application needs. From Normal Run mode, the Run Mode
(RUNM) field can be modified to change the MCU into VLPR mode when limited
frequency is sufficient for the application. From VLPR mode, a corresponding wait
(VLPW) and stop (VLPS) mode can be entered.
Depending on the needs of the user application, a variety of stop modes are available that
allow the state retention, partial power down or full power down of certain logic and/or
memory. I/O states are held in all modes of operation. Several registers are used to
configure the various modes of operation for the device.
The following table describes the power modes available for the device.
Table 13-1. Power modes
Mode
Description
RUN
The MCU can be run at full speed and the internal supply is fully regulated, that is, in run regulation.
This mode is also referred to as Normal Run mode.
WAIT
The core clock is gated off. The system clock continues to operate. Bus clocks, if enabled, continue
to operate. Run regulation is maintained.
STOP
The core clock is gated off. System clocks to other masters and bus clocks are gated off after all
stop acknowledge signals from supporting peripherals are valid.
VLPR
The core, system, bus, and flash clock maximum frequencies are restricted in this mode. See the
Power Management chapter for details about the maximum allowable frequencies.
VLPW
The core clock is gated off. The system, bus, and flash clocks continue to operate, although their
maximum frequency is restricted. See the Power Management chapter for details on the maximum
allowable frequencies.
VLPS
The core clock is gated off. System clocks to other masters and bus clocks are gated off after all
stop acknowledge signals from supporting peripherals are valid.
LLS
The core clock is gated off. System clocks to other masters and bus clocks are gated off after all
stop acknowledge signals from supporting peripherals are valid. The MCU is placed in a low
leakage mode by reducing the voltage to internal logic. Internal logic states are retained.
Table continues on the next page...
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Chapter 13 System Mode Controller (SMC)
Table 13-1. Power modes (continued)
Mode
Description
VLLS3
The core clock is gated off. System clocks to other masters and bus clocks are gated off after all
stop acknowledge signals from supporting peripherals are valid. The MCU is placed in a low
leakage mode by powering down the internal logic. All system RAM contents are retained and I/O
states are held. Internal logic states are not retained.
VLLS1
The core clock is gated off. System clocks to other masters and bus clocks are gated off after all
stop acknowledge signals from supporting peripherals are valid. The MCU is placed in a low
leakage mode by powering down the internal logic and all system RAM. I/O states are held. Internal
logic states are not retained.
VLLS0
The core clock is gated off. System clocks to other masters and bus clocks are gated off after all
stop acknowledge signals from supporting peripherals are valid. The MCU is placed in a low
leakage mode by powering down the internal logic and all system RAM. I/O states are held. Internal
logic states are not retained. The 1kHz LPO clock is disabled and the power on reset (POR) circuit
can be optionally enabled using STOPCTRL[PORPO].
13.3 Memory map and register descriptions
Details follow about the registers related to the system mode controller.
Different SMC registers reset on different reset types. Each register's description provides
details. For more information about the types of reset on this chip, refer to the Reset
section details.
NOTE
The SMC registers can be written only in supervisor mode.
Write accesses in user mode are blocked and will result in a bus
error.
SMC memory map
Absolute
address
(hex)
Register name
Width
Access
(in bits)
Reset value
Section/
page
4007_E000
Power Mode Protection register (SMC_PMPROT)
8
R/W
00h
13.3.1/191
4007_E001
Power Mode Control register (SMC_PMCTRL)
8
R/W
00h
13.3.2/193
4007_E002
Stop Control Register (SMC_STOPCTRL)
8
R/W
03h
13.3.3/194
4007_E003
Power Mode Status register (SMC_PMSTAT)
8
R
01h
13.3.4/195
13.3.1 Power Mode Protection register (SMC_PMPROT)
This register provides protection for entry into any low-power run or stop mode. The
enabling of the low-power run or stop mode occurs by configuring the Power Mode
Control register (PMCTRL).
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Memory map and register descriptions
The PMPROT register can be written only once after any system reset.
If the MCU is configured for a disallowed or reserved power mode, the MCU remains in
its current power mode. For example, if the MCU is in normal RUN mode and AVLP is
0, an attempt to enter VLPR mode using PMCTRL[RUNM] is blocked and the RUNM
bits remain 00b, indicating the MCU is still in Normal Run mode.
NOTE
This register is reset on Chip Reset not VLLS and by reset
types that trigger Chip Reset not VLLS. It is unaffected by reset
types that do not trigger Chip Reset not VLLS. See the Reset
section details for more information.
Address: 4007_E000h base + 0h offset = 4007_E000h
Bit
Read
Write
Reset
7
6
5
0
0
0
4
AVLP
0
0
0
3
2
1
0
ALLS
0
AVLLS
0
0
0
0
0
SMC_PMPROT field descriptions
Field
7–6
Reserved
5
AVLP
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Allow Very-Low-Power Modes
Provided the appropriate control bits are set up in PMCTRL, this write-once bit allows the MCU to enter
any very-low-power modes: VLPR, VLPW, and VLPS.
0
1
4
Reserved
3
ALLS
This field is reserved.
This read-only field is reserved and always has the value 0.
Allow Low-Leakage Stop Mode
This write once bit allows the MCU to enter any low-leakage stop mode (LLS), provided the appropriate
control bits are set up in PMCTRL.
0
1
2
Reserved
1
AVLLS
LLS is not allowed
LLS is allowed
This field is reserved.
This read-only field is reserved and always has the value 0.
Allow Very-Low-Leakage Stop Mode
Provided the appropriate control bits are set up in PMCTRL, this write once bit allows the MCU to enter
any very-low-leakage stop mode (VLLSx).
0
1
0
Reserved
VLPR, VLPW and VLPS are not allowed
VLPR, VLPW and VLPS are allowed
Any VLLSx mode is not allowed
Any VLLSx mode is allowed
This field is reserved.
This read-only field is reserved and always has the value 0.
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Chapter 13 System Mode Controller (SMC)
13.3.2 Power Mode Control register (SMC_PMCTRL)
The PMCTRL register controls entry into low-power run and stop modes, provided that
the selected power mode is allowed via an appropriate setting of the protection
(PMPROT) register.
NOTE
This register is reset on Chip POR not VLLS and by reset types
that trigger Chip POR not VLLS. It is unaffected by reset types
that do not trigger Chip POR not VLLS. See the Reset section
details for more information.
Address: 4007_E000h base + 1h offset = 4007_E001h
Bit
7
Read
0
6
RUNM
Write
Reset
5
0
0
0
4
3
0
STOPA
0
0
2
1
0
STOPM
0
0
0
SMC_PMCTRL field descriptions
Field
7
Reserved
6–5
RUNM
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Run Mode Control
When written, causes entry into the selected run mode. Writes to this field are blocked if the protection
level has not been enabled using the PMPROT register. This field is cleared by hardware on any exit to
normal RUN mode.
NOTE: RUNM must be set to VLPR only when PMSTAT=RUN. After being written to VLPR, RUNM
should not be written back to RUN until PMSTAT=VLPR.
NOTE: RUNM must be set to RUN only when PMSTAT=VLPR. After being written to RUN, RUNM
should not be written back to VLPR until PMSTAT=RUN.
00
01
10
11
4
Reserved
3
STOPA
Normal Run mode (RUN)
Reserved
Very-Low-Power Run mode (VLPR)
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
Stop Aborted
When set, this read-only status bit indicates an interrupt or reset occured during the previous stop mode
entry sequence, preventing the system from entering that mode. This bit is cleared by hardware at the
beginning of any stop mode entry sequence and is set if the sequence was aborted.
0
1
The previous stop mode entry was successsful.
The previous stop mode entry was aborted.
Table continues on the next page...
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Memory map and register descriptions
SMC_PMCTRL field descriptions (continued)
Field
2–0
STOPM
Description
Stop Mode Control
When written, controls entry into the selected stop mode when Sleep-Now or Sleep-On-Exit mode is
entered with SLEEPDEEP=1 . Writes to this field are blocked if the protection level has not been enabled
using the PMPROT register. After any system reset, this field is cleared by hardware on any successful
write to the PMPROT register.
NOTE: When set to VLLSx, the VLLSM bits in the STOPCTRL register is used to further select the
particular VLLS submode which will be entered.
NOTE: When set to STOP, the PSTOPO bits in the STOPCTRL register can be used to select a Partial
Stop mode if desired.
000
001
010
011
100
101
110
111
Normal Stop (STOP)
Reserved
Very-Low-Power Stop (VLPS)
Low-Leakage Stop (LLS)
Very-Low-Leakage Stop (VLLSx)
Reserved
Reseved
Reserved
13.3.3 Stop Control Register (SMC_STOPCTRL)
The STOPCTRL register provides various control bits allowing the user to fine tune
power consumption during the stop mode selected by the STOPM field.
NOTE
This register is reset on Chip POR not VLLS and by reset types
that trigger Chip POR not VLLS. It is unaffected by reset types
that do not trigger Chip POR not VLLS. See the Reset section
details for more information.
Address: 4007_E000h base + 2h offset = 4007_E002h
Bit
Read
Write
Reset
7
6
5
PSTOPO
0
0
4
3
PORPO
0
0
0
0
0
2
1
0
VLLSM
0
1
1
SMC_STOPCTRL field descriptions
Field
7–6
PSTOPO
Description
Partial Stop Option
These bits control whether a Partial Stop mode is entered when STOPM=STOP. When entering a Partial
Stop mode from RUN mode, the PMC, MCG and flash remain fully powered, allowing the device to
wakeup almost instantaneously at the expense of higher power consumption. In PSTOP2, only system
Table continues on the next page...
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Chapter 13 System Mode Controller (SMC)
SMC_STOPCTRL field descriptions (continued)
Field
Description
clocks are gated allowing peripherals running on bus clock to remain fully functional. In PSTOP1, both
system and bus clocks are gated.
00
01
10
11
5
PORPO
STOP - Normal Stop mode
PSTOP1 - Partial Stop with both system and bus clocks disabled
PSTOP2 - Partial Stop with system clock disabled and bus clock enabled
Reserved
POR Power Option
This bit controls whether the POR detect circuit is enabled in VLLS0 mode.
0
1
POR detect circuit is enabled in VLLS0
POR detect circuit is disabled in VLLS0
4
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
3
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
2–0
VLLSM
VLLS Mode Control.
This field controls which VLLS sub-mode to enter if STOPM=VLLS.
000
001
010
011
100
101
110
111
VLLS0
VLLS1
Reserved
VLLS3
Reserved
Reserved
Reserved
Reserved
13.3.4 Power Mode Status register (SMC_PMSTAT)
PMSTAT is a read-only, one-hot register which indicates the current power mode of the
system.
NOTE
This register is reset on Chip POR not VLLS and by reset types
that trigger Chip POR not VLLS. It is unaffected by reset types
that do not trigger Chip POR not VLLS. See the Reset section
details for more information.
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Functional description
Address: 4007_E000h base + 3h offset = 4007_E003h
Bit
7
Read
0
6
5
4
3
2
1
0
0
0
1
PMSTAT
Write
Reset
0
0
0
0
0
SMC_PMSTAT field descriptions
Field
7
Reserved
6–0
PMSTAT
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
NOTE: When debug is enabled, the PMSTAT will not update to STOP or VLPS
NOTE: When a PSTOP mode is enabled, the PMSTAT will not update to STOP or VLPS
000_0001
000_0010
000_0100
000_1000
001_0000
010_0000
100_0000
Current power mode is RUN
Current power mode is STOP
Current power mode is VLPR
Current power mode is VLPW
Current power mode is VLPS
Current power mode is LLS
Current power mode is VLLS
13.4 Functional description
13.4.1 Power mode transitions
The following figure shows the power mode state transitions available on the chip. Any
reset always brings the MCU back to the normal run state.
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Chapter 13 System Mode Controller (SMC)
Any RESET
VLPW
4
5
VLPR
WAIT
1
3
RUN
7
2
STOP
6
VLPS
10
8
VLLS
3, 1, 0
LLS
9
11
Figure 13-5. Power mode state diagram
The following table defines triggers for the various state transitions shown in the previous
figure.
Table 13-7. Power mode transition triggers
Transition #
From
To
1
RUN
WAIT
Trigger conditions
Sleep-now or sleep-on-exit modes entered with SLEEPDEEP
clear, controlled in System Control Register in ARM core.
See note.1
WAIT
RUN
Interrupt or Reset
Table continues on the next page...
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Functional description
Table 13-7. Power mode transition triggers (continued)
Transition #
From
To
2
RUN
STOP
Trigger conditions
PMCTRL[RUNM]=00, PMCTRL[STOPM]=0002
Sleep-now or sleep-on-exit modes entered with SLEEPDEEP
set, which is controlled in System Control Register in ARM
core.
See note.1
3
STOP
RUN
Interrupt or Reset
RUN
VLPR
The core, system, bus and flash clock frequencies are
restricted in this mode. See the Power Management chapter
for the maximum allowable frequencies.
Set PMPROT[AVLP]=1, PMCTRL[RUNM]=10.
VLPR
RUN
Set PMCTRL[RUNM]=00 or
Reset.
4
VLPR
VLPW
Sleep-now or sleep-on-exit modes entered with SLEEPDEEP
clear, which is controlled in System Control Register in ARM
core.
See note.1
VLPW
VLPR
Interrupt
5
VLPW
RUN
Reset
6
VLPR
VLPS
PMCTRL[STOPM]=0003 or 010,
Sleep-now or sleep-on-exit modes entered with SLEEPDEEP
set, which is controlled in System Control Register in ARM
core.
See note.1
VLPS
VLPR
Interrupt
NOTE: If VLPS was entered directly from RUN, hardware
will not allow this transition and will force exit back to
RUN
7
RUN
VLPS
PMPROT[AVLP]=1, PMCTRL[STOPM]=010,
Sleep-now or sleep-on-exit modes entered with SLEEPDEEP
set, which is controlled in System Control Register in ARM
core.
See note.1
VLPS
RUN
Interrupt and VLPS mode was entered directly from RUN or
Reset
8
9
RUN
VLLSx
VLLSx
RUN
VLPR
VLLSx
PMPROT[AVLLS]=1, PMCTRL[STOPM]=100,
STOPCTRL[VLLSM]=x (VLLSx), Sleep-now or sleep-on-exit
modes entered with SLEEPDEEP set, which is controlled in
System Control Register in ARM core.
Wakeup from enabled LLWU input source or RESET pin
PMPROT[AVLLS]=1, PMCTRL[STOPM]=100,
STOPCTRL[VLLSM]=x (VLLSx), Sleep-now or sleep-on-exit
modes entered with SLEEPDEEP set, which is controlled in
System Control Register in ARM core.
Table continues on the next page...
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Chapter 13 System Mode Controller (SMC)
Table 13-7. Power mode transition triggers (continued)
Transition #
From
To
10
RUN
LLS
PMPROT[ALLS]=1, PMCTRL[STOPM]=011, Sleep-now or
sleep-on-exit modes entered with SLEEPDEEP set, which is
controlled in System Control Register in ARM core.
LLS
RUN
Wakeup from enabled LLWU input source or RESET pin.
VLPR
LLS
PMPROT[ALLS]=1, PMCTRL[STOPM]=011, Sleep-now or
sleep-on-exit modes entered with SLEEPDEEP set, which is
controlled in System Control Register in ARM core.
11
Trigger conditions
1. If debug is enabled, the core clock remains to support debug.
2. If PMCTRL[STOPM]=000 and STOPCTRL[PSTOPO]=01 or 10, then only a Partial Stop mode is entered instead of STOP
3. If PMCTRL[STOPM]=000 and STOPCTRL[PSTOPO]=00, then VLPS mode is entered instead of STOP. If
PMCTRL[STOPM]=000 and STOPCTRL[PSTOPO]=01 or 10, then only a Partial Stop mode is entered instead of VLPS
13.4.2 Power mode entry/exit sequencing
When entering or exiting low-power modes, the system must conform to an orderly
sequence to manage transitions safely. The SMC manages the system's entry into and exit
from all power modes. The following diagram illustrates the connections of the SMC
with other system components in the chip that are necessary to sequence the system
through all power modes.
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Functional description
Reset
Control
Module
LowLeakage
Wakeup
CPU
(RCM)
(LLWU)
Stop/Wait
LP exit
LP exit
System
Mode
Controller
CCM low power bus
(SMC)
Clock
Control
Module
Bus masters low power bus (non-CPU)
Bus slaves low power bus
(CCM)
PMC low power bus
MCG enable
System
Power
(PMC)
System
Clocks
(MCG)
Flash low power bus
Flash
Memory
Module
Figure 13-6. Low-power system components and connections
13.4.2.1 Stop mode entry sequence
Entry into a low-power stop mode (Stop, VLPS, LLS, VLLSx) is initiated by CPU
execution of the WFI instruction. After the instruction is executed, the following
sequence occurs:
1. The CPU clock is gated off immediately.
2. Requests are made to all non-CPU bus masters to enter Stop mode.
3. After all masters have acknowledged they are ready to enter Stop mode, requests are
made to all bus slaves to enter Stop mode.
4. After all slaves have acknowledged they are ready to enter Stop mode, all system and
bus clocks are gated off.
5. Clock generators are disabled in the MCG.
6. The on-chip regulator in the PMC and internal power switches are configured to
meet the power consumption goals for the targeted low-power mode.
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Chapter 13 System Mode Controller (SMC)
13.4.2.2 Stop mode exit sequence
Exit from a low-power stop mode is initiated either by a reset or an interrupt event. The
following sequence then executes to restore the system to a run mode (RUN or VLPR):
1. The on-chip regulator in the PMC and internal power switches are restored.
2. Clock generators are enabled in the MCG.
3. System and bus clocks are enabled to all masters and slaves.
4. The CPU clock is enabled and the CPU begins servicing the reset or interrupt that
initiated the exit from the low-power stop mode.
13.4.2.3 Aborted stop mode entry
If an interrupt or a reset occurs during a stop entry sequence, the SMC can abort the
transition early and return to RUN mode without completely entering the stop mode. An
aborted entry is possible only if the reset or interrupt occurs before the PMC begins the
transition to stop mode regulation. After this point, the interrupt or reset is ignored until
the PMC has completed its transition to stop mode regulation. When an aborted stop
mode entry sequence occurs, the SMC's PMCTRL[STOPA] is set to 1.
13.4.2.4 Transition to wait modes
For wait modes (WAIT and VLPW), the CPU clock is gated off while all other clocking
continues, as in RUN and VLPR mode operation. Some modules that support stop-inwait functionality have their clocks disabled in these configurations.
13.4.2.5 Transition from stop modes to Debug mode
The debugger module supports a transition from STOP, WAIT, VLPS, and VLPW back
to a Halted state when the debugger has been enabled, that is, ENBDM is 1. As part of
this transition, system clocking is re-established and is equivalent to the normal RUN and
VLPR mode clocking configuration.
13.4.3 Run modes
The device contains two different run modes:
• Run
• Very Low-Power Run (VLPR)
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Functional description
13.4.3.1 RUN mode
This is the normal operating mode for the device.
This mode is selected after any reset. When the ARM processor exits reset, it sets up the
stack, program counter (PC), and link register (LR):
• The processor reads the start SP (SP_main) from vector-table offset 0x000
• The processor reads the start PC from vector-table offset 0x004
• LR is set to 0xFFFF_FFFF.
To reduce power in this mode, disable the clocks to unused modules using their
corresponding clock gating control bits in the SIM's registers.
13.4.3.2 Very-Low Power Run (VLPR) mode
In VLPR mode, the on-chip voltage regulator is put into a stop mode regulation state. In
this state, the regulator is designed to supply enough current to the MCU over a reduced
frequency. To further reduce power in this mode, disable the clocks to unused modules
using their corresponding clock gating control bits in the SIM's registers.
Before entering this mode, the following conditions must be met:
• The MCG must be configured in a mode which is supported during VLPR. See the
Power Management details for information about these MCG modes.
• All clock monitors in the MCG must be disabled.
• The maximum frequencies of the system, bus, flash, and core are restricted. See the
Power Management details about which frequencies are supported.
• Mode protection must be set to allow VLP modes, that is, PMPROT[AVLP] is 1.
• PMCTRL[RUNM] is set to 10b to enter VLPR.
• Flash programming/erasing is not allowed.
NOTE
Do not change the clock frequency while in VLPR mode,
because the regulator is slow responding and cannot manage
fast load transitions. In addition, do not modify the clock source
in the MCG module, the module clock enables in the SIM, or
any clock divider registers.
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To reenter Normal Run mode, clear RUNM. The PMSTAT register is a read-only status
register that can be used to determine when the system has completed an exit to RUN
mode. When PMSTAT=RUN, the system is in run regulation and the MCU can run at
full speed in any clock mode. If a higher execution frequency is desired, poll the
PMSTAT register until it is set to RUN when returning from VLPR mode.
Any reset always causes an exit from VLPR and returns the device to RUN mode after
the MCU exits its reset flow.
13.4.4 Wait modes
This device contains two different wait modes:
• Wait
• Very-Low Power Wait (VLPW)
13.4.4.1 WAIT mode
WAIT mode is entered when the ARM core enters the Sleep-Now or Sleep-On-Exit
modes while SLEEDEEP is cleared. The ARM CPU enters a low-power state in which it
is not clocked, but peripherals continue to be clocked provided they are enabled. Clock
gating to the peripheral is enabled via the SIM..
When an interrupt request occurs, the CPU exits WAIT mode and resumes processing in
RUN mode, beginning with the stacking operations leading to the interrupt service
routine.
A system reset will cause an exit from WAIT mode, returning the device to normal RUN
mode.
13.4.4.2 Very-Low-Power Wait (VLPW) mode
VLPW is entered by the entering the Sleep-Now or Sleep-On-Exit mode while
SLEEPDEEP is cleared and the MCU is in VLPR mode.
In VLPW, the on-chip voltage regulator remains in its stop regulation state. In this state,
the regulator is designed to supply enough current to the MCU over a reduced frequency.
To further reduce power in this mode, disable the clocks to unused modules by clearing
the peripherals' corresponding clock gating control bits in the SIM.
VLPR mode restrictions also apply to VLPW.
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Functional description
When an interrupt from VLPW occurs, the device returns to VLPR mode to execute the
interrupt service routine.
A system reset will cause an exit from VLPW mode, returning the device to normal RUN
mode.
13.4.5 Stop modes
This device contains a variety of stop modes to meet your application needs. The stop
modes range from:
• a stopped CPU, with all I/O, logic, and memory states retained, and certain
asynchronous mode peripherals operating
to:
• a powered down CPU, with only I/O and a small register file retained, very few
asynchronous mode peripherals operating, while the remainder of the MCU is
powered down.
The choice of stop mode depends upon the user's application, and how power usage and
state retention versus functional needs may be traded off.
NOTE
All clock monitors must be disabled before entering these lowpower modes: Stop, VLPS, VLPR, VLPW, LLS, and VLLSx.
The various stop modes are selected by setting the appropriate fields in PMPROT and
PMCTRL. The selected stop mode mode is entered during the sleep-now or sleep-on-exit
entry with the SLEEPDEEP bit set in the System Control Register in the ARM core.
The available stop modes are:
•
•
•
•
Normal Stop (STOP)
Very-Low Power Stop (VLPS)
Low-Leakage Stop (LLS)
Very-Low-Leakage Stop (VLLSx)
13.4.5.1 STOP mode
STOP mode is entered via the sleep-now or sleep-on-exit with the SLEEPDEEP bit set in
the System Control Register in the ARM core.
The MCG module can be configured to leave the reference clocks running.
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Chapter 13 System Mode Controller (SMC)
A module capable of providing an asynchronous interrupt to the device takes the device
out of STOP mode and returns the device to normal RUN mode. Refer to the device's
Power Management chapter for peripheral, I/O, and memory operation in STOP mode.
When an interrupt request occurs, the CPU exits STOP mode and resumes processing,
beginning with the stacking operations leading to the interrupt service routine.
A system reset will cause an exit from STOP mode, returning the device to normal RUN
mode via an MCU reset.
13.4.5.2 Very-Low-Power Stop (VLPS) mode
VLPS mode can be entered in one of two ways:
• Entry into stop via the sleep-now or sleep-on-exit with the SLEEPDEEP bit set in the
System Control Register in the ARM core while the MCU is in VLPR mode and
STOPM=010 or 000 in the PMCTRL register.
• Entry into stop via the sleep-now or sleep-on-exit with the SLEEPDEEP bit set in the
System Control Register in the ARM core while the MCU is in normal RUN mode
and STOPM=010 in the PMCTRL register. When VLPS is entered directly from
RUN mode, exit to VLPR is disabled by hardware and the system will always exit
back to RUN.
In VLPS, the on-chip voltage regulator remains in its stop regulation state as in VLPR.
A module capable of providing an asynchronous interrupt to the device takes the device
out of VLPS and returns the device to VLPR mode.
A system reset will also cause a VLPS exit, returning the device to normal RUN mode.
13.4.5.3 Low-Leakage Stop (LLS) mode
Low-Leakage Stop (LLS) mode can be entered from normal RUN or VLPR modes.
The MCU enters LLS mode if:
• In Sleep-Now or Sleep-On-Exit mode, SLEEPDEEP is set in the System Control
Register in the ARM core, and
• The device is configured as shown in Table 13-7.
In LLS, the on-chip voltage regulator is in stop regulation. Most of the peripherals are put
in a state-retention mode that does not allow them to operate while in LLS.
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Functional description
Before entering LLS mode, the user should configure the low-leakage wakeup (LLWU)
module to enable the desired wakeup sources. The available wakeup sources in LLS are
detailed in the chip configuration details for this device.
After wakeup from LLS, the device returns to normal RUN mode with a pending LLWU
module interrupt. In the LLWU interrupt service routine (ISR), the user can poll the
LLWU module wakeup flags to determine the source of the wakeup.
NOTE
The LLWU interrupt must not be masked by the interrupt
controller to avoid a scenario where the system does not fully
exit stop mode on an LLS recovery.
An asserted RESET pin will cause an exit from LLS mode, returning the device to
normal RUN mode. When LLS is exiting via the RESET pin, the PIN and WAKEUP bits
are set in the SRS0 register of the reset control module (RCM).
13.4.5.4 Very-Low-Leakage Stop (VLLSx) modes
This device contains these very low leakage modes:
• VLLS3
• VLLS1
• VLLS0
VLLSx is often used in this document to refer to all of these modes.
All VLLSx modes can be entered from normal RUN or VLPR modes.
The MCU enters the configured VLLS mode if:
• In Sleep-Now or Sleep-On-Exit mode, the SLEEPDEEP bit is set in the System
Control Register in the ARM core, and
• The device is configured as shown in Table 13-7.
In VLLS, the on-chip voltage regulator is in its stop-regulation state while most digital
logic is powered off.
Before entering VLLS mode, the user should configure the low-leakage wakeup (LLWU)
module to enable the desired wakeup sources. The available wakeup sources in VLLS are
detailed in the chip configuration details for this device.
After wakeup from VLLS, the device returns to normal RUN mode with a pending
LLWU interrupt. In the LLWU interrupt service routine (ISR), the user can poll the
LLWU module wakeup flags to determine the source of the wakeup.
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Chapter 13 System Mode Controller (SMC)
When entering VLLS, each I/O pin is latched as configured before executing VLLS.
Because all digital logic in the MCU is powered off, all port and peripheral data is lost
during VLLS. This information must be restored before the ACKISO bit in the PMC is
set.
An asserted RESET pin will cause an exit from any VLLS mode, returning the device to
normal RUN mode. When exiting VLLS via the RESET pin, the PIN and WAKEUP bits
are set in the SRS0 register of the reset control module (RCM).
13.4.6 Debug in low power modes
When the MCU is secure, the device disables/limits debugger operation. When the MCU
is unsecure, the ARM debugger can assert two power-up request signals:
• System power up, via SYSPWR in the Debug Port Control/Stat register
• Debug power up, via CDBGPWRUPREQ in the Debug Port Control/Stat register
When asserted while in RUN, WAIT, VLPR, or VLPW, the mode controller drives a
corresponding acknowledge for each signal, that is, both CDBGPWRUPACK and
CSYSPWRUPACK. When both requests are asserted, the mode controller handles
attempts to enter STOP and VLPS by entering an emulated stop state. In this emulated
stop state:
•
•
•
•
•
the regulator is in run regulation,
the MCG-generated clock source is enabled,
all system clocks, except the core clock, are disabled,
the debug module has access to core registers, and
access to the on-chip peripherals is blocked.
No debug is available while the MCU is in LLS or VLLS modes. LLS is a state-retention
mode and all debug operation can continue after waking from LLS, even in cases where
system wakeup is due to a system reset event.
Entering into a VLLS mode causes all of the debug controls and settings to be powered
off. To give time to the debugger to sync with the MCU, the MDM AP Control Register
includes a Very-Low-Leakage Debug Request (VLLDBGREQ) bit that is set to configure
the Reset Controller logic to hold the system in reset after the next recovery from a VLLS
mode. This bit allows the debugger time to reinitialize the debug module before the
debug session continues.
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Functional description
The MDM AP Control Register also includes a Very Low Leakage Debug Acknowledge
(VLLDBGACK) bit that is set to release the ARM core being held in reset following a
VLLS recovery. The debugger reinitializes all debug IP, and then asserts the
VLLDBGACK control bit to allow the RCM to release the ARM core from reset and
allow CPU operation to begin.
The VLLDBGACK bit is cleared by the debugger (or can be left set as is) or clears
automatically due to the reset generated as part of the next VLLS recovery.
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Chapter 14
Power Management Controller (PMC)
14.1 Introduction
NOTE
For the chip-specific implementation details of this module's
instances see the chip configuration information.
The power management controller (PMC) contains the internal voltage regulator, power
on reset (POR), and low voltage detect system.
14.2 Features
The PMC features include:
• Internal voltage regulator
• Active POR providing brown-out detect
• Low-voltage detect supporting two low-voltage trip points with four warning levels
per trip point
14.3 Low-voltage detect (LVD) system
This device includes a system to guard against low-voltage conditions. This protects
memory contents and controls MCU system states during supply voltage variations. The
system is comprised of a power-on reset (POR) circuit and a LVD circuit with a userselectable trip voltage: high (VLVDH) or low (VLVDL). The trip voltage is selected by the
LVDSC1[LVDV] bits. The LVD is disabled upon entering VLPx, LLS, and VLLSx
modes.
Two flags are available to indicate the status of the low-voltage detect system:
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Low-voltage detect (LVD) system
• The low voltage detect flag (LVDF) operates in a level sensitive manner. The LVDF
bit is set when the supply voltage falls below the selected trip point (VLVD). The
LVDF bit is cleared by writing one to the LVDACK bit, but only if the internal
supply has returned above the trip point; otherwise, the LVDF bit remains set.
• The low voltage warning flag (LVWF) operates in a level sensitive manner. The
LVWF bit is set when the supply voltage falls below the selected monitor trip point
(VLVW). The LVWF bit is cleared by writing one to the LVWACK bit, but only if
the internal supply has returned above the trip point; otherwise, the LVWF bit
remains set.
14.3.1 LVD reset operation
By setting the LVDRE bit, the LVD generates a reset upon detection of a low voltage
condition. The low voltage detection threshold is determined by the LVDV bits. After an
LVD reset occurs, the LVD system holds the MCU in reset until the supply voltage rises
above this threshold. The LVD bit in the SRS register is set following an LVD or poweron reset.
14.3.2 LVD interrupt operation
By configuring the LVD circuit for interrupt operation (LVDIE set and LVDRE clear),
LVDSC1[LVDF] is set and an LVD interrupt request occurs upon detection of a low
voltage condition. The LVDF bit is cleared by writing one to the LVDSC1[LVDACK]
bit.
14.3.3 Low-voltage warning (LVW) interrupt operation
The LVD system contains a low-voltage warning flag (LVWF) to indicate that the supply
voltage is approaching, but is above, the LVD voltage. The LVW also has an interrupt,
which is enabled by setting the LVDSC2[LVWIE] bit. If enabled, an LVW interrupt
request occurs when the LVWF is set. LVWF is cleared by writing one to the
LVDSC2[LVWACK] bit.
The LVDSC2[LVWV] bits select one of four trip voltages:
• Highest: VLVW4
• Two mid-levels: VLVW3 and VLVW2
• Lowest: VLVW1
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Chapter 14 Power Management Controller (PMC)
14.4 I/O retention
When in LLS mode, the I/O pins are held in their input or output state. Upon wakeup, the
PMC is re-enabled, goes through a power up sequence to full regulation, and releases the
logic from state retention mode. The I/O are released immediately after a wakeup or reset
event. In the case of LLS exit via a RESET pin, the I/O default to their reset state.
When in VLLS modes, the I/O states are held on a wakeup event (with the exception of
wakeup by reset event) until the wakeup has been acknowledged via a write to the
ACKISO bit. In the case of VLLS exit via a RESET pin, the I/O are released and default
to their reset state. In this case, no write to the ACKISO is needed.
14.5 Memory map and register descriptions
PMC register details follow.
NOTE
Different portions of PMC registers are reset only by particular
reset types. Each register's description provides details. For
more information about the types of reset on this chip, refer to
the Reset section details.
The PMC registers can be written only in supervisor mode.
Write accesses in user mode are blocked and will result in a bus
error.
PMC memory map
Absolute
address
(hex)
Register name
Width
Access
(in bits)
Reset value
Section/
page
4007_D000
Low Voltage Detect Status And Control 1 register
(PMC_LVDSC1)
8
R/W
10h
14.5.1/212
4007_D001
Low Voltage Detect Status And Control 2 register
(PMC_LVDSC2)
8
R/W
00h
14.5.2/213
4007_D002
Regulator Status And Control register (PMC_REGSC)
8
R/W
04h
14.5.3/214
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Memory map and register descriptions
14.5.1 Low Voltage Detect Status And Control 1 register
(PMC_LVDSC1)
This register contains status and control bits to support the low voltage detect function.
This register should be written during the reset initialization program to set the desired
controls even if the desired settings are the same as the reset settings.
While the device is in the very low power or low leakage modes, the LVD system is
disabled regardless of LVDSC1 settings. To protect systems that must have LVD always
on, configure the SMC's power mode protection register (PMPROT) to disallow any very
low power or low leakage modes from being enabled.
See the device's data sheet for the exact LVD trip voltages.
NOTE
The LVDV bits are reset solely on a POR Only event. The
register's other bits are reset on Chip Reset Not VLLS. For
more information about these reset types, refer to the Reset
section details.
Address: 4007_D000h base + 0h offset = 4007_D000h
Bit
Read
7
6
LVDF
0
Write
Reset
LVDACK
0
0
5
4
3
LVDIE
LVDRE
0
1
2
1
0
0
0
LVDV
0
0
0
PMC_LVDSC1 field descriptions
Field
7
LVDF
Description
Low-Voltage Detect Flag
This read-only status bit indicates a low-voltage detect event.
0
1
6
LVDACK
5
LVDIE
Low-voltage event not detected
Low-voltage event detected
Low-Voltage Detect Acknowledge
This write-only bit is used to acknowledge low voltage detection errors. Write 1 to clear LVDF. Reads
always return 0.
Low-Voltage Detect Interrupt Enable
Enables hardware interrupt requests for LVDF.
0
1
Hardware interrupt disabled (use polling)
Request a hardware interrupt when LVDF = 1
Table continues on the next page...
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Chapter 14 Power Management Controller (PMC)
PMC_LVDSC1 field descriptions (continued)
Field
4
LVDRE
Description
Low-Voltage Detect Reset Enable
This write-once bit enables LVDF events to generate a hardware reset. Additional writes are ignored.
0
1
3–2
Reserved
1–0
LVDV
LVDF does not generate hardware resets
Force an MCU reset when LVDF = 1
This field is reserved.
This read-only field is reserved and always has the value 0.
Low-Voltage Detect Voltage Select
Selects the LVD trip point voltage (V LVD ).
00
01
10
11
Low trip point selected (V LVD = V LVDL )
High trip point selected (V LVD = V LVDH )
Reserved
Reserved
14.5.2 Low Voltage Detect Status And Control 2 register
(PMC_LVDSC2)
This register contains status and control bits to support the low voltage warning function.
While the device is in the very low power or low leakage modes, the LVD system is
disabled regardless of LVDSC2 settings.
See the device's data sheet for the exact LVD trip voltages.
NOTE
The LVW trip voltages depend on LVWV and LVDV bits.
NOTE
The LVWV bits are reset solely on a POR Only event. The
register's other bits are reset on Chip Reset Not VLLS. For
more information about these reset types, refer to the Reset
section details.
Address: 4007_D000h base + 1h offset = 4007_D001h
Bit
Read
7
6
LVWF
0
Write
Reset
LVWACK
0
0
5
4
2
1
0
LVWIE
0
3
0
0
0
LVWV
0
0
0
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Memory map and register descriptions
PMC_LVDSC2 field descriptions
Field
7
LVWF
Description
Low-Voltage Warning Flag
This read-only status bit indicates a low-voltage warning event. LVWF is set when VSupply transitions below
the trip point, or after reset and VSupply is already below VLVW. LVWF bit may be 1 after power on reset,
therefore, to use LVW interrupt function, before enabling LVWIE, LVWF must be cleared by writing
LVWACK first.
0
1
6
LVWACK
5
LVWIE
Low-Voltage Warning Acknowledge
This write-only bit is used to acknowledge low voltage warning errors. Write 1 to clear LVWF. Reads
always return 0.
Low-Voltage Warning Interrupt Enable
Enables hardware interrupt requests for LVWF.
0
1
4–2
Reserved
1–0
LVWV
Low-voltage warning event not detected
Low-voltage warning event detected
Hardware interrupt disabled (use polling)
Request a hardware interrupt when LVWF = 1
This field is reserved.
This read-only field is reserved and always has the value 0.
Low-Voltage Warning Voltage Select
Selects the LVW trip point voltage (VLVW). The actual voltage for the warning depends on LVDSC1[LVDV].
00
01
10
11
Low trip point selected (VLVW = VLVW1)
Mid 1 trip point selected (VLVW = VLVW2)
Mid 2 trip point selected (VLVW = VLVW3)
High trip point selected (VLVW = VLVW4)
14.5.3 Regulator Status And Control register (PMC_REGSC)
The PMC contains an internal voltage regulator. The voltage regulator design uses a
bandgap reference that is also available through a buffer as input to certain internal
peripherals, such as the CMP and ADC. The internal regulator provides a status bit
(REGONS) indicating the regulator is in run regulation.
NOTE
This register is reset on Chip Reset Not VLLS and by reset
types that trigger Chip Reset not VLLS. See the Reset section
for more information.
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Chapter 14 Power Management Controller (PMC)
Address: 4007_D000h base + 2h offset = 4007_D002h
Bit
7
Read
6
5
0
Write
Reset
0
4
Reserved
BGEN
0
0
0
3
2
ACKISO
REGONS
w1c
0
1
1
0
Reserved
BGBE
0
0
PMC_REGSC field descriptions
Field
Description
7–6
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
5
Reserved
This field is reserved.
4
BGEN
Bandgap Enable In VLPx Operation
BGEN controls whether the bandgap is enabled in lower power modes of operation (VLPx, LLS, and
VLLSx). When on-chip peripherals require the bandgap voltage reference in low power modes of
operation, set BGEN to continue to enable the bandgap operation.
NOTE: When the bandgap voltage reference is not needed in low power modes, clear BGEN to avoid
excess power consumption.
0
1
3
ACKISO
Bandgap voltage reference is disabled in VLPx , LLS , and VLLSx modes
Bandgap voltage reference is enabled in VLPx , LLS , and VLLSx modes
Acknowledge Isolation
Reading this bit indicates whether certain peripherals and the I/O pads are in a latched state as a result of
having been in a VLLS mode. Writing one to this bit when it is set releases the I/O pads and certain
peripherals to their normal run mode state.
NOTE: After recovering from a VLLS mode, user should restore chip configuration before clearing
ACKISO. In particular, pin configuration for enabled LLWU wakeup pins should be restored to
avoid any LLWU flag from being falsely set when ACKISO is cleared.
0
1
2
REGONS
Regulator In Run Regulation Status
This read-only bit provides the current status of the internal voltage regulator.
0
1
1
Reserved
Peripherals and I/O pads are in normal run state
Certain peripherals and I/O pads are in an isolated and latched state
Regulator is in stop regulation or in transition to/from it
Regulator is in run regulation
This field is reserved.
NOTE: This reserved bit must remain cleared (set to 0).
0
BGBE
Bandgap Buffer Enable
Enables the bandgap buffer.
0
1
Bandgap buffer not enabled
Bandgap buffer enabled
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Memory map and register descriptions
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Chapter 15
Low-Leakage Wakeup Unit (LLWU)
15.1 Introduction
NOTE
For the chip-specific implementation details of this module's
instances see the chip configuration information.
The LLWU module allows the user to select up to 16 external pin sources and up to 8
internal modules as a wakeup source from low-leakage power modes. The input sources
are described in the device's chip configuration details. Each of the available wakeup
sources can be individually enabled.
The LLWU module also includes two optional digital pin filters for the external wakeup
pins.
15.1.1 Features
The LLWU module features include:
• Support for up to 16 external input pins and up to 8 internal modules with individual
enable bits
• Input sources may be external pins or from internal peripherals capable of running in
LLS or VLLS. See the chip configuration information for wakeup input sources for
this device.
• External pin wakeup inputs, each of which is programmable as falling-edge, risingedge, or any change
• Wakeup inputs that are activated if enabled after MCU enters a low-leakage power
mode
• Optional digital filters provided to qualify an external pin detect. When entering
VLLS0, the filters are disabled and bypassed.
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Introduction
15.1.2 Modes of operation
The LLWU module becomes functional on entry into a low-leakage power mode. After
recovery from LLS, the LLWU is immediately disabled. After recovery from VLLS, the
LLWU continues to detect wakeup events until the user has acknowledged the wakeup
via a write to the PMC_REGSC[ACKISO] bit.
15.1.2.1 LLS mode
The LLWU module provides up to 16 external wakeup inputs and up to 8 internal module
wakeup inputs.
Wakeup events due to external wakeup inputs and internal module wakeup inputs result
in an interrupt flow when exiting LLS.
NOTE
The LLWU interrupt must not be masked by the interrupt
controller to avoid a scenario where the system does not fully
exit Stop mode on an LLS recovery.
15.1.2.2 VLLS modes
The LLWU module provides up to 16 external wakeup inputs and up to 8 internal module
wakeup inputs. All wakeup events result in VLLS exit via a reset flow.
15.1.2.3 Non-low leakage modes
The LLWU is not active in all non-low leakage modes where detection and control logic
are in a static state. The LLWU registers are accessible in non-low leakage modes and are
available for configuring and reading status when bus transactions are possible.
When the wakeup pin filters are enabled, filter operation begins immediately. If a low
leakage mode is entered within 5 LPO clock cycles of an active edge, the edge event will
be detected by the LLWU.
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Chapter 15 Low-Leakage Wakeup Unit (LLWU)
15.1.2.4 Debug mode
When the chip is in Debug mode and then enters LLS or a VLLSx mode, no debug logic
works in the fully-functional low-leakage mode. Upon an exit from the LLS or VLLSx
mode, the LLWU becomes inactive.
15.1.3 Block diagram
The following figure is the block diagram for the LLWU module.
enter low leakge mode
WUME7
Module7 interrupt flag
(LLWU_M7IF)
Module0 interrupt flag
(LLWU_M0IF)
Interrupt module
flag detect
LLWU_MWUF7 occurred
Internal
module
sources
Interrupt module
flag detect
FILT1[FILTSEL]
LLWU_MWUF0 occurred
WUME0
LPO
LLWU_P15
Synchronizer
LLWU_P0
Pin filter 1
LPO
Synchronizer
Pin filter 2
FILT1[FILTE]
Edge
detect
Pin filter 1
wakeup
occurred
LLWU
controller
FILT2[FILTE]
Edge
detect
exit low leakge mode
Pin filter 2
wakeup
occurred
interrupt flow
reset flow
WUPE15
2
FILT2[FILTSEL]
Edge
detect
Edge
detect
LLWU_P15
wakeup occurred
LLWU_P0
wakeup occurred
External
pin sources
2
WUPE0
Figure 15-1. LLWU block diagram
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LLWU signal descriptions
15.2 LLWU signal descriptions
The signal properties of LLWU are shown in the following table. The external wakeup
input pins can be enabled to detect either rising-edge, falling-edge, or on any change.
Table 15-1. LLWU signal descriptions
Signal
LLWU_Pn
Description
I/O
Wakeup inputs (n = 0-15)
I
15.3 Memory map/register definition
The LLWU includes the following registers:
• Five 8-bit wakeup source enable registers
• Enable external pin input sources
• Enable internal peripheral sources
• Three 8-bit wakeup flag registers
• Indication of wakeup source that caused exit from a low-leakage power mode
includes external pin or internal module interrupt
• Two 8-bit wakeup pin filter enable registers
NOTE
The LLWU registers can be written only in supervisor mode.
Write accesses in user mode are blocked and will result in a bus
error.
All LLWU registers are reset by Chip Reset not VLLS and by
reset types that trigger Chip Reset not VLLS. Each register's
displayed reset value represents this subset of reset types.
LLWU registers are unaffected by reset types that do not trigger
Chip Reset not VLLS. For more information about the types of
reset on this chip, refer to the Introduction details.
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Chapter 15 Low-Leakage Wakeup Unit (LLWU)
LLWU memory map
Absolute
address
(hex)
Width
Access
(in bits)
Register name
Reset value
Section/
page
4007_C000
LLWU Pin Enable 1 register (LLWU_PE1)
8
R/W
00h
15.3.1/221
4007_C001
LLWU Pin Enable 2 register (LLWU_PE2)
8
R/W
00h
15.3.2/222
4007_C002
LLWU Module Enable register (LLWU_ME)
8
R/W
00h
15.3.3/223
4007_C003
LLWU Flag 1 register (LLWU_F1)
8
R/W
00h
15.3.4/225
4007_C004
LLWU Flag 3 register (LLWU_F3)
8
R
00h
15.3.5/226
4007_C005
LLWU Pin Filter 1 register (LLWU_FILT1)
8
R/W
00h
15.3.6/228
4007_C006
LLWU Pin Filter 2 register (LLWU_FILT2)
8
R/W
00h
15.3.7/229
15.3.1 LLWU Pin Enable 1 register (LLWU_PE1)
LLWU_PE1 contains the field to enable and select the edge detect type for the external
wakeup input pins LLWU_P3-LLWU_P0.
NOTE
This register is reset on Chip Reset not VLLS and by reset
types that trigger Chip Reset not VLLS. It is unaffected by reset
types that do not trigger Chip Reset not VLLS. See the
Introduction details for more information.
Address: 4007_C000h base + 0h offset = 4007_C000h
Bit
Read
Write
Reset
7
6
5
WUPE3
0
4
3
WUPE2
0
0
2
1
WUPE1
0
0
0
WUPE0
0
0
0
LLWU_PE1 field descriptions
Field
7–6
WUPE3
Description
Wakeup Pin Enable For LLWU_P3
Enables and configures the edge detection for the wakeup pin.
00
01
10
11
5–4
WUPE2
External input pin disabled as wakeup input
External input pin enabled with rising edge detection
External input pin enabled with falling edge detection
External input pin enabled with any change detection
Wakeup Pin Enable For LLWU_P2
Enables and configures the edge detection for the wakeup pin.
00
01
External input pin disabled as wakeup input
External input pin enabled with rising edge detection
Table continues on the next page...
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Memory map/register definition
LLWU_PE1 field descriptions (continued)
Field
Description
10
11
3–2
WUPE1
Wakeup Pin Enable For LLWU_P1
Enables and configures the edge detection for the wakeup pin.
00
01
10
11
1–0
WUPE0
External input pin enabled with falling edge detection
External input pin enabled with any change detection
External input pin disabled as wakeup input
External input pin enabled with rising edge detection
External input pin enabled with falling edge detection
External input pin enabled with any change detection
Wakeup Pin Enable For LLWU_P0
Enables and configures the edge detection for the wakeup pin.
00
01
10
11
External input pin disabled as wakeup input
External input pin enabled with rising edge detection
External input pin enabled with falling edge detection
External input pin enabled with any change detection
15.3.2 LLWU Pin Enable 2 register (LLWU_PE2)
LLWU_PE2 contains the field to enable and select the edge detect type for the external
wakeup input pins LLWU_P7-LLWU_P4.
NOTE
This register is reset on Chip Reset not VLLS and by reset
types that trigger Chip Reset not VLLS. It is unaffected by reset
types that do not trigger Chip Reset not VLLS. See the
Introduction details for more information.
Address: 4007_C000h base + 1h offset = 4007_C001h
Bit
Read
Write
Reset
7
6
5
WUPE7
0
4
3
WUPE6
0
0
2
1
WUPE5
0
0
0
WUPE4
0
0
0
LLWU_PE2 field descriptions
Field
7–6
WUPE7
Description
Wakeup Pin Enable For LLWU_P7
Enables and configures the edge detection for the wakeup pin.
00
01
External input pin disabled as wakeup input
External input pin enabled with rising edge detection
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Chapter 15 Low-Leakage Wakeup Unit (LLWU)
LLWU_PE2 field descriptions (continued)
Field
Description
10
11
5–4
WUPE6
Wakeup Pin Enable For LLWU_P6
Enables and configures the edge detection for the wakeup pin.
00
01
10
11
3–2
WUPE5
External input pin disabled as wakeup input
External input pin enabled with rising edge detection
External input pin enabled with falling edge detection
External input pin enabled with any change detection
Wakeup Pin Enable For LLWU_P5
Enables and configures the edge detection for the wakeup pin.
00
01
10
11
1–0
WUPE4
External input pin enabled with falling edge detection
External input pin enabled with any change detection
External input pin disabled as wakeup input
External input pin enabled with rising edge detection
External input pin enabled with falling edge detection
External input pin enabled with any change detection
Wakeup Pin Enable For LLWU_P4
Enables and configures the edge detection for the wakeup pin.
00
01
10
11
External input pin disabled as wakeup input
External input pin enabled with rising edge detection
External input pin enabled with falling edge detection
External input pin enabled with any change detection
15.3.3 LLWU Module Enable register (LLWU_ME)
LLWU_ME contains the bits to enable the internal module flag as a wakeup input source
for inputs MWUF7-MWUF0.
NOTE
This register is reset on Chip Reset not VLLS and by reset
types that trigger Chip Reset not VLLS. It is unaffected by reset
types that do not trigger Chip Reset not VLLS. See the
Introduction details for more information.
Address: 4007_C000h base + 2h offset = 4007_C002h
Bit
Read
Write
Reset
7
6
5
4
3
2
1
0
WUME7
WUME6
WUME5
WUME4
WUME3
WUME2
WUME1
WUME0
0
0
0
0
0
0
0
0
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Memory map/register definition
LLWU_ME field descriptions
Field
7
WUME7
Description
Wakeup Module Enable For Module 7
Enables an internal module as a wakeup source input.
0
1
6
WUME6
Wakeup Module Enable For Module 6
Enables an internal module as a wakeup source input.
0
1
5
WUME5
Enables an internal module as a wakeup source input.
Enables an internal module as a wakeup source input.
Enables an internal module as a wakeup source input.
Enables an internal module as a wakeup source input.
Internal module flag not used as wakeup source
Internal module flag used as wakeup source
Wakeup Module Enable for Module 1
Enables an internal module as a wakeup source input.
0
1
0
WUME0
Internal module flag not used as wakeup source
Internal module flag used as wakeup source
Wakeup Module Enable For Module 2
0
1
1
WUME1
Internal module flag not used as wakeup source
Internal module flag used as wakeup source
Wakeup Module Enable For Module 3
0
1
2
WUME2
Internal module flag not used as wakeup source
Internal module flag used as wakeup source
Wakeup Module Enable For Module 4
0
1
3
WUME3
Internal module flag not used as wakeup source
Internal module flag used as wakeup source
Wakeup Module Enable For Module 5
0
1
4
WUME4
Internal module flag not used as wakeup source
Internal module flag used as wakeup source
Internal module flag not used as wakeup source
Internal module flag used as wakeup source
Wakeup Module Enable For Module 0
Enables an internal module as a wakeup source input.
0
1
Internal module flag not used as wakeup source
Internal module flag used as wakeup source
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Chapter 15 Low-Leakage Wakeup Unit (LLWU)
15.3.4 LLWU Flag 1 register (LLWU_F1)
LLWU_F1 contains the wakeup flags indicating which wakeup source caused the MCU
to exit LLS or VLLS mode. For LLS, this is the source causing the CPU interrupt flow.
For VLLS, this is the source causing the MCU reset flow.
The external wakeup flags are read-only and clearing a flag is accomplished by a write of
a 1 to the corresponding WUFx bit. The wakeup flag (WUFx), if set, will remain set if
the associated WUPEx bit is cleared.
NOTE
This register is reset on Chip Reset not VLLS and by reset
types that trigger Chip Reset not VLLS. It is unaffected by reset
types that do not trigger Chip Reset not VLLS. See the
Introduction details for more information.
Address: 4007_C000h base + 3h offset = 4007_C003h
Bit
7
6
5
4
3
2
1
0
Read
WUF7
WUF6
WUF5
WUF4
WUF3
WUF2
WUF1
WUF0
Write
w1c
w1c
w1c
w1c
w1c
w1c
w1c
w1c
Reset
0
0
0
0
0
0
0
0
LLWU_F1 field descriptions
Field
7
WUF7
Description
Wakeup Flag For LLWU_P7
Indicates that an enabled external wakeup pin was a source of exiting a low-leakage power mode. To
clear the flag write a one to WUF7.
0
1
6
WUF6
Wakeup Flag For LLWU_P6
Indicates that an enabled external wakeup pin was a source of exiting a low-leakage power mode. To
clear the flag write a one to WUF6.
0
1
5
WUF5
LLWU_P7 input was not a wakeup source
LLWU_P7 input was a wakeup source
LLWU_P6 input was not a wakeup source
LLWU_P6 input was a wakeup source
Wakeup Flag For LLWU_P5
Indicates that an enabled external wakeup pin was a source of exiting a low-leakage power mode. To
clear the flag write a one to WUF5.
0
1
LLWU_P5 input was not a wakeup source
LLWU_P5 input was a wakeup source
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Memory map/register definition
LLWU_F1 field descriptions (continued)
Field
4
WUF4
Description
Wakeup Flag For LLWU_P4
Indicates that an enabled external wakeup pin was a source of exiting a low-leakage power mode. To
clear the flag write a one to WUF4.
0
1
3
WUF3
Wakeup Flag For LLWU_P3
Indicates that an enabled external wakeup pin was a source of exiting a low-leakage power mode. To
clear the flag write a one to WUF3.
0
1
2
WUF2
Indicates that an enabled external wakeup pin was a source of exiting a low-leakage power mode. To
clear the flag write a one to WUF2.
LLWU_P2 input was not a wakeup source
LLWU_P2 input was a wakeup source
Wakeup Flag For LLWU_P1
Indicates that an enabled external wakeup pin was a source of exiting a low-leakage power mode. To
clear the flag write a one to WUF1.
0
1
0
WUF0
LLWU_P3 input was not a wakeup source
LLWU_P3 input was a wakeup source
Wakeup Flag For LLWU_P2
0
1
1
WUF1
LLWU_P4 input was not a wakeup source
LLWU_P4 input was a wakeup source
LLWU_P1 input was not a wakeup source
LLWU_P1 input was a wakeup source
Wakeup Flag For LLWU_P0
Indicates that an enabled external wakeup pin was a source of exiting a low-leakage power mode. To
clear the flag write a one to WUF0.
0
1
LLWU_P0 input was not a wakeup source
LLWU_P0 input was a wakeup source
15.3.5 LLWU Flag 3 register (LLWU_F3)
LLWU_F3 contains the wakeup flags indicating which internal wakeup source caused the
MCU to exit LLS or VLLS mode. For LLS, this is the source causing the CPU interrupt
flow. For VLLS, this is the source causing the MCU reset flow.
For internal peripherals that are capable of running in a low-leakage power mode, such as
iRTC or CMP modules, the flag from the associated peripheral is accessible as the
MWUFx bit. The flag will need to be cleared in the peripheral instead of writing a 1 to
the MWUFx bit.
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Chapter 15 Low-Leakage Wakeup Unit (LLWU)
NOTE
This register is reset on Chip Reset not VLLS and by reset
types that trigger Chip Reset not VLLS. It is unaffected by reset
types that do not trigger Chip Reset not VLLS. See the
Introduction details for more information.
Address: 4007_C000h base + 4h offset = 4007_C004h
Bit
Read
7
6
5
4
3
2
1
0
MWUF7
MWUF6
MWUF5
MWUF4
MWUF3
MWUF2
MWUF1
MWUF0
0
0
0
0
0
0
0
0
Write
Reset
LLWU_F3 field descriptions
Field
7
MWUF7
Description
Wakeup flag For module 7
Indicates that an enabled internal peripheral was a source of exiting a low-leakage power mode. To clear
the flag, follow the internal peripheral flag clearing mechanism.
0
1
6
MWUF6
Wakeup flag For module 6
Indicates that an enabled internal peripheral was a source of exiting a low-leakage power mode. To clear
the flag, follow the internal peripheral flag clearing mechanism.
0
1
5
MWUF5
Indicates that an enabled internal peripheral was a source of exiting a low-leakage power mode. To clear
the flag, follow the internal peripheral flag clearing mechanism.
Indicates that an enabled internal peripheral was a source of exiting a low-leakage power mode. To clear
the flag, follow the internal peripheral flag clearing mechanism.
Module 4 input was not a wakeup source
Module 4 input was a wakeup source
Wakeup flag For module 3
Indicates that an enabled internal peripheral was a source of exiting a low-leakage power mode. To clear
the flag, follow the internal peripheral flag clearing mechanism.
0
1
2
MWUF2
Module 5 input was not a wakeup source
Module 5 input was a wakeup source
Wakeup flag For module 4
0
1
3
MWUF3
Module 6 input was not a wakeup source
Module 6 input was a wakeup source
Wakeup flag For module 5
0
1
4
MWUF4
Module 7 input was not a wakeup source
Module 7 input was a wakeup source
Module 3 input was not a wakeup source
Module 3 input was a wakeup source
Wakeup flag For module 2
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Memory map/register definition
LLWU_F3 field descriptions (continued)
Field
Description
Indicates that an enabled internal peripheral was a source of exiting a low-leakage power mode. To clear
the flag, follow the internal peripheral flag clearing mechanism.
0
1
1
MWUF1
Wakeup flag For module 1
Indicates that an enabled internal peripheral was a source of exiting a low-leakage power mode. To clear
the flag, follow the internal peripheral flag clearing mechanism.
0
1
0
MWUF0
Module 2 input was not a wakeup source
Module 2 input was a wakeup source
Module 1 input was not a wakeup source
Module 1 input was a wakeup source
Wakeup flag For module 0
Indicates that an enabled internal peripheral was a source of exiting a low-leakage power mode. To clear
the flag, follow the internal peripheral flag clearing mechanism.
0
1
Module 0 input was not a wakeup source
Module 0 input was a wakeup source
15.3.6 LLWU Pin Filter 1 register (LLWU_FILT1)
LLWU_FILT1 is a control and status register that is used to enable/disable the digital
filter 1 features for an external pin.
NOTE
This register is reset on Chip Reset not VLLS and by reset
types that trigger Chip Reset not VLLS. It is unaffected by reset
types that do not trigger Chip Reset not VLLS. See the
Introduction details for more information.
Address: 4007_C000h base + 5h offset = 4007_C005h
Bit
7
Read
FILTF
Write
w1c
Reset
0
6
5
3
2
0
FILTE
0
4
0
0
1
0
0
0
FILTSEL
0
0
LLWU_FILT1 field descriptions
Field
7
FILTF
Description
Filter Detect Flag
Indicates that the filtered external wakeup pin, selected by FILTSEL, was a source of exiting a low-leakage
power mode. To clear the flag write a one to FILTF.
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Chapter 15 Low-Leakage Wakeup Unit (LLWU)
LLWU_FILT1 field descriptions (continued)
Field
Description
0
1
6–5
FILTE
Pin Filter 1 was not a wakeup source
Pin Filter 1 was a wakeup source
Digital Filter On External Pin
Controls the digital filter options for the external pin detect.
00
01
10
11
Filter disabled
Filter posedge detect enabled
Filter negedge detect enabled
Filter any edge detect enabled
4
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
3–0
FILTSEL
Filter Pin Select
Selects 1 out of the 16 wakeup pins to be muxed into the filter.
0000
...
1111
Select LLWU_P0 for filter
...
Select LLWU_P15 for filter
15.3.7 LLWU Pin Filter 2 register (LLWU_FILT2)
LLWU_FILT2 is a control and status register that is used to enable/disable the digital
filter 2 features for an external pin.
NOTE
This register is reset on Chip Reset not VLLS and by reset
types that trigger Chip Reset not VLLS. It is unaffected by reset
types that do not trigger Chip Reset not VLLS. See the
Introduction details for more information.
Address: 4007_C000h base + 6h offset = 4007_C006h
Bit
7
Read
FILTF
Write
w1c
Reset
0
6
5
FILTE
0
4
3
2
0
0
0
1
0
0
0
FILTSEL
0
0
LLWU_FILT2 field descriptions
Field
7
FILTF
Description
Filter Detect Flag
Indicates that the filtered external wakeup pin, selected by FILTSEL, was a source of exiting a low-leakage
power mode. To clear the flag write a one to FILTF.
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Functional description
LLWU_FILT2 field descriptions (continued)
Field
Description
0
1
6–5
FILTE
Pin Filter 2 was not a wakeup source
Pin Filter 2 was a wakeup source
Digital Filter On External Pin
Controls the digital filter options for the external pin detect.
00
01
10
11
Filter disabled
Filter posedge detect enabled
Filter negedge detect enabled
Filter any edge detect enabled
4
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
3–0
FILTSEL
Filter Pin Select
Selects 1 out of the 16 wakeup pins to be muxed into the filter.
0000
...
1111
Select LLWU_P0 for filter
...
Select LLWU_P15 for filter
15.4 Functional description
This on-chip peripheral module is called a low-leakage wakeup unit (LLWU) module
because it allows internal peripherals and external input pins as a source of wakeup from
low-leakage modes. It is operational only in LLS and VLLSx modes.
The LLWU module contains pin enables for each external pin and internal module. For
each external pin, the user can disable or select the edge type for the wakeup. Type
options are:
• Falling-edge
• Rising-edge
• Either-edge
When an external pin is enabled as a wakeup source, the pin must be configured as an
input pin.
The LLWU implements optional 3-cycle glitch filters, based on the LPO clock. A
detected external pin is required to remain asserted until the enabled glitch filter times
out. Additional latency of up to 2 cycles is due to synchronization, which results in a total
of up to 5 cycles of delay before the detect circuit alerts the system to the wakeup or reset
event when the filter function is enabled. Two wakeup detect filters are available to
detect up to two external pins. Glitch filtering is not provided on the internal modules.
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Chapter 15 Low-Leakage Wakeup Unit (LLWU)
For internal module wakeup operation, the WUMEx bit enables the associated module as
a wakeup source.
15.4.1 LLS mode
Wakeup events triggered from either an external pin input or an internal module input
result in a CPU interrupt flow to begin user code execution.
15.4.2 VLLS modes
In the case of a wakeup due to external pin or internal module wakeup, recovery is
always via a reset flow and the RCM_SRS[WAKEUP] is set indicating the low-leakage
mode was active. State retention data is lost and I/O will be restored after
PMC_REGSC[ACKISO] has been written.
15.4.3 Initialization
For an enabled peripheral wakeup input, the peripheral flag must be cleared by software
before entering LLS or VLLSx mode to avoid an immediate exit from the mode.
Flags associated with external input pins, filtered and unfiltered, must also be cleared by
software prior to entry to LLS or VLLSx mode.
After enabling an external pin filter or changing the source pin, wait at least 5 LPO clock
cycles before entering LLS or VLLSx mode to allow the filter to initialize.
NOTE
After recovering from a VLLS mode, user must restore chip
configuration before clearing ACKISO. In particular, pin
configuration for enabled LLWU wakeup pins must be restored
to avoid any LLWU flag from being falsely set when ACKISO
is cleared.
The signal selected as a wakeup source pin must be a digital
pin, as selected in the pin mux control.
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Functional description
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Chapter 16
Reset Control Module (RCM)
16.1 Introduction
This chapter describes the registers of the Reset Control Module (RCM). The RCM
implements many of the reset functions for the chip. See the chip's reset chapter for more
information.
16.2 Reset memory map and register descriptions
The Reset Control Module (RCM) registers provide reset status information and reset
filter control.
NOTE
The RCM registers can be written only in supervisor mode.
Write accesses in user mode are blocked and will result in a bus
error.
RCM memory map
Absolute
address
(hex)
Register name
Width
Access
(in bits)
Reset value
Section/
page
4007_F000
System Reset Status Register 0 (RCM_SRS0)
8
R
82h
16.2.1/233
4007_F001
System Reset Status Register 1 (RCM_SRS1)
8
R
00h
16.2.2/235
4007_F004
Reset Pin Filter Control register (RCM_RPFC)
8
R/W
00h
16.2.3/236
4007_F005
Reset Pin Filter Width register (RCM_RPFW)
8
R/W
00h
16.2.4/237
16.2.1 System Reset Status Register 0 (RCM_SRS0)
This register includes read-only status flags to indicate the source of the most recent
reset. The reset state of these bits depends on what caused the MCU to reset.
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Reset memory map and register descriptions
NOTE
The reset value of this register depends on the reset source:
• POR (including LVD) — 0x82
• LVD (without POR) — 0x02
• VLLS mode wakeup due to RESET pin assertion — 0x41
• VLLS mode wakeup due to other wakeup sources — 0x01
• Other reset — a bit is set if its corresponding reset source
caused the reset
Address: 4007_F000h base + 0h offset = 4007_F000h
Bit
Read
7
6
5
POR
PIN
WDOG
1
0
0
4
3
0
2
1
0
LOC
LVD
WAKEUP
0
1
0
Write
Reset
0
0
RCM_SRS0 field descriptions
Field
7
POR
Description
Power-On Reset
Indicates a reset has been caused by the power-on detection logic. Because the internal supply voltage
was ramping up at the time, the low-voltage reset (LVD) status bit is also set to indicate that the reset
occurred while the internal supply was below the LVD threshold.
0
1
6
PIN
External Reset Pin
Indicates a reset has been caused by an active-low level on the external RESET pin.
0
1
5
WDOG
2
LOC
Reset not caused by external reset pin
Reset caused by external reset pin
Watchdog
Indicates a reset has been caused by the watchdog timer Computer Operating Properly (COP) timing out.
This reset source can be blocked by disabling the COP watchdog: write 00 to the SIM's COPC[COPT]
field.
0
1
4–3
Reserved
Reset not caused by POR
Reset caused by POR
Reset not caused by watchdog timeout
Reset caused by watchdog timeout
This field is reserved.
This read-only field is reserved and always has the value 0.
Loss-of-Clock Reset
Indicates a reset has been caused by a loss of external clock. The MCG clock monitor must be enabled
for a loss of clock to be detected. Refer to the detailed MCG description for information on enabling the
clock monitor.
0
1
Reset not caused by a loss of external clock.
Reset caused by a loss of external clock.
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Chapter 16 Reset Control Module (RCM)
RCM_SRS0 field descriptions (continued)
Field
1
LVD
Description
Low-Voltage Detect Reset
If the LVDRE bit is set and the supply drops below the LVD trip voltage, an LVD reset occurs. This bit is
also set by POR.
0
1
0
WAKEUP
Reset not caused by LVD trip or POR
Reset caused by LVD trip or POR
Low Leakage Wakeup Reset
Indicates a reset has been caused by an enabled LLWU module wakeup source while the chip was in a
low leakage mode. In LLS mode, the RESET pin is the only wakeup source that can cause this reset. Any
enabled wakeup source in a VLLSx mode causes a reset. This bit is cleared by any reset except
WAKEUP.
0
1
Reset not caused by LLWU module wakeup source
Reset caused by LLWU module wakeup source
16.2.2 System Reset Status Register 1 (RCM_SRS1)
This register includes read-only status flags to indicate the source of the most recent
reset. The reset state of these bits depends on what caused the MCU to reset.
NOTE
The reset value of this register depends on the reset source:
• POR (including LVD) — 0x00
• LVD (without POR) — 0x00
• VLLS mode wakeup — 0x00
• Other reset — a bit is set if its corresponding reset source
caused the reset
Address: 4007_F000h base + 1h offset = 4007_F001h
Bit
7
6
5
4
3
2
1
0
Read
0
0
SACKERR
0
MDM_AP
SW
LOCKUP
0
0
0
0
0
0
0
0
0
Write
Reset
RCM_SRS1 field descriptions
Field
Description
7
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
6
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
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Reset memory map and register descriptions
RCM_SRS1 field descriptions (continued)
Field
5
SACKERR
Description
Stop Mode Acknowledge Error Reset
Indicates that after an attempt to enter Stop mode, a reset has been caused by a failure of one or more
peripherals to acknowledge within approximately one second to enter stop mode.
0
1
Reset not caused by peripheral failure to acknowledge attempt to enter stop mode
Reset caused by peripheral failure to acknowledge attempt to enter stop mode
4
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
3
MDM_AP
MDM-AP System Reset Request
Indicates a reset has been caused by the host debugger system setting of the System Reset Request bit
in the MDM-AP Control Register.
0
1
2
SW
Software
Indicates a reset has been caused by software setting of SYSRESETREQ bit in Application Interrupt and
Reset Control Register in the ARM core.
0
1
1
LOCKUP
Reset not caused by software setting of SYSRESETREQ bit
Reset caused by software setting of SYSRESETREQ bit
Core Lockup
Indicates a reset has been caused by the ARM core indication of a LOCKUP event.
0
1
0
Reserved
Reset not caused by host debugger system setting of the System Reset Request bit
Reset caused by host debugger system setting of the System Reset Request bit
Reset not caused by core LOCKUP event
Reset caused by core LOCKUP event
This field is reserved.
This read-only field is reserved and always has the value 0.
16.2.3 Reset Pin Filter Control register (RCM_RPFC)
NOTE
The reset values of bits 2-0 are for Chip POR only. They are
unaffected by other reset types.
NOTE
The bus clock filter is reset when disabled or when entering
stop mode. The LPO filter is reset when disabled .
Address: 4007_F000h base + 4h offset = 4007_F004h
Bit
Read
Write
Reset
7
6
5
4
3
0
0
0
0
2
1
RSTFLTSS
0
0
0
0
RSTFLTSRW
0
0
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Chapter 16 Reset Control Module (RCM)
RCM_RPFC field descriptions
Field
7–3
Reserved
2
RSTFLTSS
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Reset Pin Filter Select in Stop Mode
Selects how the reset pin filter is enabled in Stop and VLPS modes , and also during LLS and VLLS
modes. On exit from VLLS mode, this bit should be reconfigured before clearing ACKISO in the PMC.
0
1
1–0
RSTFLTSRW
All filtering disabled
LPO clock filter enabled
Reset Pin Filter Select in Run and Wait Modes
Selects how the reset pin filter is enabled in run and wait modes.
00
01
10
11
All filtering disabled
Bus clock filter enabled for normal operation
LPO clock filter enabled for normal operation
Reserved
16.2.4 Reset Pin Filter Width register (RCM_RPFW)
NOTE
The reset values of the bits in the RSTFLTSEL field are for
Chip POR only. They are unaffected by other reset types.
Address: 4007_F000h base + 5h offset = 4007_F005h
Bit
Read
Write
Reset
7
6
5
4
3
0
0
0
2
1
0
0
0
RSTFLTSEL
0
0
0
0
RCM_RPFW field descriptions
Field
7–5
Reserved
4–0
RSTFLTSEL
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Reset Pin Filter Bus Clock Select
Selects the reset pin bus clock filter width.
00000
00001
00010
00011
00100
Bus clock filter count is 1
Bus clock filter count is 2
Bus clock filter count is 3
Bus clock filter count is 4
Bus clock filter count is 5
Table continues on the next page...
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Reset memory map and register descriptions
RCM_RPFW field descriptions (continued)
Field
Description
00101
00110
00111
01000
01001
01010
01011
01100
01101
01110
01111
10000
10001
10010
10011
10100
10101
10110
10111
11000
11001
11010
11011
11100
11101
11110
11111
Bus clock filter count is 6
Bus clock filter count is 7
Bus clock filter count is 8
Bus clock filter count is 9
Bus clock filter count is 10
Bus clock filter count is 11
Bus clock filter count is 12
Bus clock filter count is 13
Bus clock filter count is 14
Bus clock filter count is 15
Bus clock filter count is 16
Bus clock filter count is 17
Bus clock filter count is 18
Bus clock filter count is 19
Bus clock filter count is 20
Bus clock filter count is 21
Bus clock filter count is 22
Bus clock filter count is 23
Bus clock filter count is 24
Bus clock filter count is 25
Bus clock filter count is 26
Bus clock filter count is 27
Bus clock filter count is 28
Bus clock filter count is 29
Bus clock filter count is 30
Bus clock filter count is 31
Bus clock filter count is 32
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Chapter 17
Bit Manipulation Engine (BME)
17.1 Introduction
The Bit Manipulation Engine (BME) provides hardware support for atomic read-modifywrite memory operations to the peripheral address space in Cortex-M0+ based
microcontrollers. This architectural capability is also known as "decorated storage" as it
defines a mechanism for providing additional semantics for load and store operations to
memory-mapped peripherals beyond just the reading and writing of data values to the
addressed memory locations. In the BME definition, the "decoration", that is, the
additional semantic information, is encoded into the peripheral address used to reference
the memory.
By combining the basic load and store instructions of the Cortex-M instruction set
architecture (v6M, v7M) with the concept of decorated storage provided by the BME, the
resulting implementation provides a robust and efficient read-modify-write capability to
this class of ultra low-end microcontrollers. The resulting architectural capability defined
by this core platform function is targeted at the manipulation of n-bit fields in peripheral
registers and is consistent with I/O hardware addressing in the Embedded C standard. For
most BME commands, a single core read or write bus cycle is converted into an atomic
read-modify-write, that is, an indivisible "read followed by a write" bus sequence.
BME decorated references are only available on system bus transactions generated by the
processor core and targeted at the standard 512 KB peripheral address space based at
0x4000_00001. The decoration semantic is embedded into address bits[28:19], creating a
448 MB space at addresses 0x4400_0000 - 0x5FFF_FFFF; these bits are stripped out of
the actual address sent to the peripheral bus controller and used by the BME to define and
control its operation.
1.
To be perfectly accurate, the peripheral address space occupies a 516 KB region: 512 KB based at 0x4000_0000 plus a 4
KB space based at 0x400F_F000 for GPIO accesses. This organization provides compatibility with the Kinetis K Family.
Attempted accesses to the memory space located between 0x4008_0000 - 0x400E_FFFF are error terminated due to an
illegal address.
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Introduction
17.1.1 Overview
The following figure is a generic block diagram of the processor core and platform for
this class of ultra low-end microcontrollers.
Cortex-M0+ Core
NVIC
CM0+ Core Platform
Fetch
Dbg
AGU
Dec
Rn
LD/ST
SHFT
ALU
MUL
AHB Bus
IO Port
MTB Port
32
PRAM
RAM
Array
RGPIO
m0
s1
AXBS
-Lite
Alt-Master
DMA_4ch
32
m3
s2
m2
s0
BME
PBRIDGE
32
FMC
Slave
Peripherals
NVM
Array
Note: BME can be accessed only by the core.
Figure 17-1. Generic Cortex-M0+ core platform block diagram
As shown in the block diagram, the BME module interfaces to a crossbar switch AHB
slave port as its primary input and sources an AHB bus output to the Peripheral Bridge
(PBRIDGE) controller. The BME hardware microarchitecture is a 2-stage pipeline design
matching the protocol of the AMBA-AHB system bus interfaces. The PBRIDGE module
converts the AHB system bus protocol into the IPS/APB protocol used by the attached
slave peripherals.
17.1.2 Features
The key features of the BME include:
• Lightweight implementation of decorated storage for peripheral address space
• Additional access semantics encoded into the reference address
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Chapter 17 Bit Manipulation Engine (BME)
•
•
•
•
•
•
•
•
Resides between a crossbar switch slave port and a peripheral bridge bus controller
2-stage pipeline design matching the AHB system bus protocol
Combinationally passes non-decorated accesses to peripheral bridge bus controller
Conversion of decorated loads and stores from processor core into atomic readmodify-writes
Decorated loads support unsigned bit field extracts, load-and-{set,clear}-1bit
operations
Decorated stores support bit field inserts, logical AND, OR and XOR operations
Support for byte, halfword and word-sized decorated operations
Supports minimum signal toggling on AHB output bus to reduce power dissipation
17.1.3 Modes of Operation
The BME module does not support any special modes of operation. As a memorymapped device located on a crossbar slave AHB system bus port, BME responds based
strictly on memory addresses for accesses to the connected peripheral bridge bus
controller.
All functionality associated with the BME module resides in the core platform's clock
domain; this includes its connections with the crossbar slave port and the PBRIDGE bus
controller.
17.2 External Signal Description
The BME module does not directly support any external interfaces.
The internal interfaces include two standard AHB buses with 32-bit datapath widths: the
primary input from the appropriate crossbar slave port (mx_h<signal>) and the primary
output to the PBRIDGE bus controller (sx_h<signal>).
Note the signal directions are defined by the BME's view and are labeled based on the
dominant direction. Accordingly, the mx_h<signal> AHB bus is the primary input, even
though there are certain data phase signals (mx_h{rdata, ready, resp}) which are outputs
from BME. Likewise, the sx_h<signal> AHB bus is the primary output even though there
are specific data phase signals (sx_h{rdata, ready, resp}) which are inputs to BME.
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Memory Map and Register Definition
17.3 Memory Map and Register Definition
The BME module provides a memory-mapped capability and does not include any
programming model registers. The exact set of functions supported by the BME are
detailed in the Functional Description.
The peripheral address space occupies a 516 KB region: 512 KB based at 0x4000_0000
plus a 4 KB space based at 0x400F_F000 for GPIO accesses; the decorated address space
is mapped to the 448 MB region located at 0x4400_0000 - 0x5FFF_FFFF.
17.4 Functional Description
This section details the specific functions supported by the BME.
Recall the combination of the basic load and store instructions of the Cortex-M
instruction set architecture (v6M, v7M) plus the concept of decorated storage provided by
the BME, the resulting implementation provides a robust and efficient read-modify-write
capability to this class of ultra low-end microcontrollers. The resulting architectural
capability defined by this core platform function is targeted at the manipulation of n-bit
fields in peripheral registers and is consistent with I/O hardware addressing in the
Embedded C standard. For most BME commands, a single core read or write bus cycle is
converted into an atomic read-modify-write, that is, an indivisible "read followed by a
write" bus sequence.
Consider decorated store operations first, then decorated loads.
17.4.1 BME Decorated Stores
The functions supported by the BME's decorated stores include three logical operators
(AND, OR, XOR) plus a bit field insert. For all these operations, BME converts a single
decorated AHB store transaction into a 2-cycle atomic read-modify-write sequence,
where the combined read-modify operation is performed in the first AHB data phase, and
then the write is performed in the second AHB data phase.
A generic timing diagram of a decorated store showing a bit field insert operation is
shown as follows:
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Chapter 17 Bit Manipulation Engine (BME)
CYCLE RULER
x
x+1
x+2
x+3
hclk
BME AHB Input Bus
mx_haddr
next
5..v_wxyz
mx_hattr
next
mx_hwrite
next
mx_hwdata
wdata
mx_hrdata
mx_hready
BME AHB Output Bus
sx_haddr
400v_wxyz
400v_wxyz
next
sx_hattr
next
sx_hwrite
next
sx_hwdata
wdata bfi rdata
sx_hrdata
rdata
sx_hready
BME States + Datapath
control_state_dp1
control_state_dp2
reg_addr_data_dp
5..v_wxyz
wdata bfi rdata
Figure 17-2. Decorated store: bit field insert timing diagram
All the decorated store operations follow the same execution template shown in the figure
above, a 2-cycle read-modify-write operation:
• Cycle x, 1st AHB address phase: Write from input bus (mx_h<signal>) is translated
into a read operation on the output bus (sx_h<signal>) using the actual memory
address (with the decoration removed) and then captured in a register
(reg_addr_data_dp)
• Cycle x+1, 2nd AHB address phase: Write access with the registered (but actual)
memory address is output (sx_h<signal>)
• Cycle x+1, 1st AHB data phase: Memory read data (sx_hrdata) is modified using the
input bus write data (mx_hwdata) and the function defined by the decoration and
captured in a data register (reg_addr_data_dp); the input bus cycle is stalled
(mx_hready = 0)
• Cycle x+2, 2nd AHB data phase: Registered write data is sourced onto the output
write data bus (sx_hwdata)
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Functional Description
NOTE
Any wait states inserted by the peripheral slave device
(sx_hready = 0) are simply passed through the BME back to the
master input bus, stalling the AHB transaction cycle for cycle.
17.4.1.1 Decorated Store Logical AND (AND)
This command performs an atomic read-modify-write of the referenced memory location.
First, the location is read; it is then modified by performing a logical AND operation
using the write data operand sourced for the system bus cycle; finally, the result of the
AND operation is written back into the referenced memory location.
The data size is specified by the write operation and can be byte (8-bit), halfword (16-bit)
or word (32-bit). The core performs the required write data lane replication on byte and
halfword transfers.
31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10
9
8
ioandb 0
1
0
0
0
1
-
-
-
-
-
-
mem_addr
ioandh 0
1
0
0
0
1
-
-
-
-
-
-
mem_addr
ioandw 0
1
0
0
0
1
-
-
-
-
-
-
mem_addr
7
6
5
4
3
2
1
0
0
0
0
Figure 17-3. Decorated store address: logical AND
where addr[28:26] = 001 specifies the AND operation, and mem_addr[19:0] specifies the
address offset into the peripheral space based at 0x4000_0000. The "-" indicates an
address bit "don't care".
The decorated AND write operation is defined in the following pseudo-code as:
ioand<sz>(accessAddress, wdata)
tmp
= mem[accessAddress & 0xE00FFFFF, size]
tmp
= tmp & wdata
mem[accessAddress & 0xE00FFFFF, size] = tmp
//
//
//
//
decorated store AND
memory read
modify
memory write
where the operand size <sz> is defined as b(yte, 8-bit), h(alfword, 16-bit) and w(ord, 32bit). This notation is used throughout the document.
In the cycle definition tables, the notation AHB_ap and AHB_dp refers to the address and
data phases of the BME AHB transaction. The cycle-by-cycle BME operations are
detailed in the following table.
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Chapter 17 Bit Manipulation Engine (BME)
Table 17-1. Cycle definitions of decorated store: logical AND
Pipeline Stage
Cycle
x
BME AHB_ap
x+1
Forward addr to memory;
Decode decoration; Convert
master_wt to slave_rd;
Capture address, attributes
BME AHB_dp
<previous>
x+2
Recirculate captured addr +
attr to memory as slave_wt
<next>
Perform memory read; Form
(rdata & wdata) and capture
destination data in register
Perform write sending
registered data to memory
17.4.1.2 Decorated Store Logical OR (OR)
This command performs an atomic read-modify-write of the referenced memory location.
First, the location is read; it is then modified by performing a logical OR operation using
the write data operand sourced for the system bus cycle; finally, the result of the OR
operation is written back into the referenced memory location.
The data size is specified by the write operation and can be byte (8 bit), halfword (16 bit)
or word (32 bit). The core performs the required write data lane replication on byte and
halfword transfers.
31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10
9
8
ioorb 0
1
0
0
1
0
-
-
-
-
-
-
mem_addr
ioorh 0
1
0
0
1
0
-
-
-
-
-
-
mem_addr
ioorw 0
1
0
0
1
0
-
-
-
-
-
-
mem_addr
7
6
5
4
3
2
1
0
0
0
0
Figure 17-4. Decorated Address Store: Logical OR
where addr[28:26] = 010 specifies the OR operation, and mem_addr[19:0] specifies the
address offset into the peripheral space based at 0x4000_0000. The "-" indicates an
address bit "don't care".
The decorated OR write operation is defined in the following pseudo-code as:
ioor<sz>(accessAddress, wdata)
// decorated store OR
tmp
= mem[accessAddress & 0xE00FFFFF, size]
tmp
= tmp | wdata
mem[accessAddress & 0xE00FFFFF, size] = tmp
// memory read
// modify
// memory write
The cycle-by-cycle BME operations are detailed in the following table
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Functional Description
Table 17-2. Cycle definitions of decorated store: logical OR
Pipeline Stage
Cycle
x
BME AHB_ap
x+1
Forward addr to memory;
Decode decoration; Convert
master_wt to slave_rd;
Capture address, attributes
BME AHB_dp
<previous>
x+2
Recirculate captured addr +
attr to memory as slave_wt
<next>
Perform memory read; Form
(rdata | wdata) and capture
destination data in register
Perform write sending
registered data to memory
17.4.1.3 Decorated Store: Logical XOR (XOR)
This command performs an atomic read-modify-write of the referenced memory location.
First, the location is read; it is then modified by performing a logical XOR (exclusiveOR) operation using the write data operand sourced for the system bus cycle; finally, the
result of the XOR operation is written back into the referenced memory location.
The data size is specified by the write operation and can be byte (8-bit), halfword (16-bit)
or word (32-bit). The core performs the required write data lane replication on byte and
halfword transfers.
31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10
9
8
ioxorb 0
1
0
0
1
1
-
-
-
-
-
-
mem_addr
ioxorh 0
1
0
0
1
1
-
-
-
-
-
-
mem_addr
ioxorw 0
1
0
0
1
1
-
-
-
-
-
-
mem_addr
7
6
5
4
3
2
1
0
0
0
0
Figure 17-5. Decorated Address Store: Logical XOR
where addr[28:26] = 011 specifies the XOR operation, and mem_addr[19:0] specifies the
address offset into the peripheral space based at 0x4000_0000. The "-" indicates an
address bit "don't care".
The decorated XOR write operation is defined in the following pseudo-code as:
ioxor<sz>(accessAddress, wdata)
// decorated store XOR
tmp
= mem[accessAddress & 0xE00FFFFF, size]
tmp
= tmp ^ wdata
mem[accessAddress & 0xE00FFFFF, size] = tmp
// memory read
// modify
// memory write
The cycle-by-cycle BME operations are detailed in the following table.
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Chapter 17 Bit Manipulation Engine (BME)
Table 17-3. Cycle definitions of decorated store: logical XOR
Pipeline Stage
Cycle
x
BME AHB_ap
Forward addr to memory;
Decode decoration; Convert
master_wt to slave_rd;
Capture address, attributes
BME AHB_dp
<previous>
x+1
x+2
Recirculate captured addr +
attr to memory as slave_wt
<next>
Perform memory read; Form
(rdata ^ wdata) and capture
destination data in register
Perform write sending
registered data to memory
17.4.1.4 Decorated Store Bit Field Insert (BFI)
This command inserts a bit field contained in the write data operand, defined by LSB
position (b) and the bit field width (w+1), into the memory "container" defined by the
access size associated with the store instruction using an atomic read-modify-write
sequence.
The data size is specified by the write operation and can be byte (8-bit), halfword (16-bit)
or word (32-bit). Note for the word sized operation, the maximum bit field width is 16
bits. The core performs the required write data lane replication on byte and halfword
transfers.
The BFI operation can be used to insert a single bit into a peripheral. For this case, the w
field is simply set to 0, indicating a bit field width of 1.
31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10
-
9
8
iobfib 0
1
0
1
-
-
b
b
b
w w w
mem_addr
iobfih 0
1
0
1
-
b
b
b
b w w w w
mem_addr
iobfiw 0
1
0
1
b
b
b
b
b w w w w
mem_addr
7
6
5
4
3
2
1
0
0
0
0
Figure 17-6. Decorated address store: bit field insert
where addr[28] = 1 signals a BFI operation, addr[27:23] is "b", the LSB identifier,
addr[22:19] is "w", the bit field width minus 1 identifier, and addr[18:0] specifies the
address offset into the peripheral space based at 0x4000_0000. The "-" indicates an
address bit "don't care". Note, unlike the other decorated store operations, BFI uses
addr[19] as the least significant bit in the "w" specifier and not as an address bit.
The decorated BFI write operation is defined in the following pseudo-code as:
iobfi<sz>(accessAddress, wdata)
// decorated bit field insert
tmp
mask
// memory read
// generate bit mask
= mem[accessAddress & 0xE007FFFF, size]
= ((1 << (w+1)) - 1) << b
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Functional Description
tmp
= tmp
& ~mask
| wdata & mask
mem[accessAddress & 0xE007FFFF, size] = tmp
// modify
// memory write
The write data operand (wdata) associated with the store instruction contains the bit field
to be inserted. It must be properly aligned within a right-justified container, that is, within
the lower 8 bits for a byte operation, the lower 16 bits for a halfword or the entire 32 bits
for a word operation.
To illustrate, consider the following example of the insertion of the 3-bit field "xyz" into
an 8-bit memory container, initially set to "abcd_efgh". For all cases, w is 2, signaling a
bit field width of 3.
if b = 0 and the decorated store (strb)
then destination is "abcd_exyz"
if b = 1 and the decorated store (strb)
then destination is "abcd_xyzh"
if b = 2 and the decorated store (strb)
then destination is "abcx_yzgh"
if b = 3 and the decorated store (strb)
then destination is "abxy_zfgh"
if b = 4 and the decorated store (strb)
then destination is "axyz_efgh"
if b = 5 and the decorated store (strb)
then destination is "xyzd_efgh"
if b = 6 and the decorated store (strb)
then destination is "yzcd_efgh"
if b = 7 and the decorated store (strb)
then destination is "zbcd_efgh"
Rt register[7:0] = ----_-xyz,
Rt register[7:0] = ----_xyz-,
Rt register[7:0] = ---x_yz--,
Rt register[7:0] = --xy_z---,
Rt register[7:0] = -xyz_----,
Rt register[7:0] = xyz-_----,
Rt register[7:0] = yz--_----,
Rt register[7:0] = z---_----,
Note from the example, when the starting bit position plus the field width exceeds the
container size, only part of the source bit field is inserted into the destination memory
location. Stated differently, if (b + w+1) > container_width, only the low-order
"container_width - b" bits are actually inserted.
The cycle-by-cycle BME operations are detailed in the following table.
Table 17-4. Cycle definitions of decorated store: bit field insert
Pipeline Stage
Cycle
x
BME AHB_ap
BME AHB_dp
Forward addr to memory;
Decode decoration; Convert
master_wt to slave_rd;
Capture address, attributes
<previous>
x+1
x+2
Recirculate captured addr +
attr to memory as slave_wt
Perform memory read; Form
bit mask; Form bitwise
((mask) ? wdata : rdata)) and
capture destination data in
register
<next>
Perform write sending
registered data to memory
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Chapter 17 Bit Manipulation Engine (BME)
17.4.2 BME Decorated Loads
The functions supported by the BME's decorated loads include two single-bit load-and{set, clear} operators plus unsigned bit field extracts. For the two load-and-{set, clear}
operations, BME converts a single decorated AHB load transaction into a 2-cycle atomic
read-modify-write sequence, where the combined read-modify operations are performed
in the first AHB data phase, and then the write is performed in the second AHB data
phase as the original read data is returned to the processor core. For an unsigned bit field
extract, the decorated load transaction is stalled for one cycle in the BME as the data field
is extracted, then aligned and returned to the processor in the 2nd AHB data phase. This
is the only decorated transaction that is not an atomic read-modify-write, as it is a simple
data read.
A generic timing diagram of a decorated load showing a load-and-set 1-bit operation is
shown as follows.
CYCLE RULER
x
x+1
x+2
x+3
hclk
BME AHB Input Bus
mx_haddr
4c.v_wxyz
next
mx_hattr
next
mx_hwrite
next
mx_hwdata
orig_1bit
mx_hrdata
mx_hready
BME AHB Output Bus
sx_haddr
400v_wxyz
400v_wxyz
next
sx_hattr
next
sx_hwrite
next
sx_hwdata
rdata + 1bit
sx_hrdata
rdata
sx_hready
BME States + Datapath
control_state_dp1
control_state_dp2
reg_addr_data_dp
4c.v_wxyz
rdata + 1bit
Figure 17-7. Decorated load: load-and-set 1-bit field insert timing diagram
Decorated load-and-{set, clear} 1-bit operations follow the execution template shown in
the above figure: a 2-cycle read-modify-write operation:
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Functional Description
• Cycle x, 1st AHB address phase: Read from input bus is translated into a read
operation on the output bus with the actual memory address (with the decoration
removed) and then captured in a register
• Cycle x+1, 2nd AHB address phase: Write access with the registered (but actual)
memory address is output
• Cycle x+1, 1st AHB data phase: The "original" 1-bit memory read data is captured in
a register, while the 1-bit field is set or clear based on the function defined by the
decoration with the modified data captured in a register; the input bus cycle is stalled
• Cycle x+2, 2nd AHB data phase: The selected original 1-bit is right justified, zero
filled and then driven onto the input read data bus, while the registered write data is
sourced onto the output write data bus
NOTE
Any wait states inserted by the peripheral slave device
(sx_hready = 0) are simply passed through the BME back to the
master input bus, stalling the AHB transaction cycle for cycle.
A generic timing diagram of a decorated load showing an unsigned bit field operation is
shown in the following figure.
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CYCLE RULER
1
2
3
4
hclk
BME AHB Input Bus
mx_haddr
5..v_wxyz
next
mx_hattr
next
mx_hwrite
next
mx_hwdata
ubfx
mx_hrdata
mx_hready
BME AHB Output Bus
sx_haddr
400v_wxyz
next
sx_hattr
next
sx_hwrite
next
sx_hwdata
sx_hrdata
rdata
sx_hready
BME States + Datapath
control_state_dp1
control_state_dp2
reg_addr_data_dp
5..v_wxyz
rdata
Figure 17-8. Decorated load: unsigned bit field insert timing diagram
The decorated unsigned bit field extract follows the same execution template shown in
the above figure, a 2-cycle read operation:
• Cycle x, 1st AHB address phase: Read from input bus is translated into a read
operation on the output bus with the actual memory address (with the decoration
removed) and then captured in a register
• Cycle x+1, 2nd AHB address phase: Idle cycle
• Cycle x+1, 1st AHB data phase: A bit mask is generated based on the starting bit
position and the field width; the mask is AND'ed with the memory read data to
isolate the bit field; the resulting data is captured in a data register; the input bus
cycle is stalled
• Cycle x+2, 2nd AHB data phase: Registered data is logically right shifted for proper
alignment and driven onto the input read data bus
NOTE
Any wait states inserted by the peripheral slave device
(sx_hready = 0) are simply passed through the BME back to the
master input bus, stalling the AHB transaction cycle for cycle.
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Functional Description
17.4.2.1 Decorated Load Load-and-Clear 1 Bit (LAC1)
This command loads a 1-bit field defined by the LSB position (b) into the core's general
purpose destination register (Rt) and zeroes the bit in the memory space after performing
an atomic read-modify-write sequence.
The extracted one bit data field from the memory address is right justified and zero filled
in the operand returned to the core.
The data size is specified by the read operation and can be byte (8-bit), halfword (16-bit)
or word (32-bit).
31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10
iolac1b 0
1
0
0
1
0
iolac1h 0
1
0
0
1
iolac1w 0
1
0
0
1
9
8
-
-
b
b
b
-
mem_addr
0
-
b
b
b
b
-
mem_addr
0
b
b
b
b
b
-
mem_addr
7
6
5
4
3
2
1
0
0
0
0
Figure 17-9. Decorated load address: load-and-clear 1 bit
where addr[28:26] = 010 specifies the load-and-clear 1 bit operation, addr[25:21] is "b",
the bit identifier, and mem_addr[19:0] specifies the address offset into the peripheral
space based at 0x4000_0000. The "-" indicates an address bit "don't care".
The decorated Load-and-Clear 1 Bit read operation is defined in the following pseudocode as:
rdata =
iolac1<sz>(accessAddress)
// decorated load-and-clear 1
tmp
= mem[accessAddress & 0xE00FFFFF, size]
mask = 1 << b
rdata = (tmp & mask) >> b
tmp
= tmp & ~mask
mem[accessAddress & 0xE00FFFFF, size] = tmp
//
//
//
//
//
memory read
generate bit mask
read data returned to core
modify
memory write
The cycle-by-cycle BME operations are detailed in the following table.
Table 17-5. Cycle definitions of decorated load: load-and-clear 1 bit
Pipeline Stage
Cycle
x
BME AHB_ap
BME AHB_dp
Forward addr to memory;
Decode decoration; Capture
address, attributes
<previous>
x+1
x+2
Recirculate captured addr +
attr to memory as slave_wt
<next>
Perform memory read; Form
bit mask; Extract bit from
rdata; Form (rdata & ~mask)
and capture destination data
in register
Return extracted bit to master;
Perform write sending
registered data to memory
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Chapter 17 Bit Manipulation Engine (BME)
17.4.2.2 Decorated Load: Load-and-Set 1 Bit (LAS1)
This command loads a 1-bit field defined by the LSB position (b) into the core's general
purpose destination register (Rt) and sets the bit in the memory space after performing an
atomic read-modify-write sequence.
The extracted one bit data field from the memory address is right justified and zero filled
in the operand returned to the core.
The data size is specified by the read operation and can be byte (8-bit), halfword (16-bit)
or word (32-bit).
31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10
9
8
iolas1b 0
1
0
0
1
1
-
-
b
b
b
-
mem_addr
iolas1h 0
1
0
0
1
1
-
b
b
b
b
-
mem_addr
iolas1w 0
1
0
0
1
1
b
b
b
b
b
-
mem_addr
7
6
5
4
3
2
1
0
0
0
0
Figure 17-10. Decorated load address: load-and-set 1 bit
where addr[28:26] = 011 specifies the load-and-set 1 bit operation, addr[25:21] is "b", the
bit identifier, and mem_addr[19:0] specifies the address offset into the peripheral space
based at 0x4000_0000. The "-" indicates an address bit "don't care".
The decorated Load-and-Set 1 Bit read operation is defined in the following pseudo-code
as:
rdata =
iolas1<sz>(accessAddress)
// decorated load-and-set 1
tmp
= mem[accessAddress & 0xE00FFFFF, size]
mask = 1 << b
rdata = (tmp & mask) >> b
tmp
= tmp | mask
mem[accessAddress & 0xE00FFFFF, size] = tmp
//
//
//
//
//
memory read
generate bit mask
read data returned to core
modify
memory write
The cycle-by-cycle BME operations are detailed in the following table.
Table 17-6. Cycle definitions of decorated load: load-and-set 1-bit
Pipeline Stage
Cycle
x
BME AHB_ap
Forward addr to memory;
Decode decoration; Capture
address, attributes
BME AHB_dp
<previous>
x+1
x+2
Recirculate captured addr +
attr to memory as slave_wt
<next>
Perform memory read; Form
bit mask; Extract bit from
rdata; Form (rdata | mask)
and capture destination data
in register
Return extracted bit to master;
Perform write sending
registered data to memory
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Functional Description
17.4.2.3 Decorated Load Unsigned Bit Field Extract (UBFX)
This command extracts a bit field defined by LSB position (b) and the bit field width (w
+1) from the memory "container" defined by the access size associated with the load
instruction using a 2-cycle read sequence.
The extracted bit field from the memory address is right justified and zero filled in the
operand returned to the core. Recall this is the only decorated operation that does not
perform a memory write, that is, UBFX only performs a read.
The data size is specified by the write operation and can be byte (8-bit), halfword (16-bit)
or word (32-bit). Note for the word sized operation, the maximum bit field width is 16
bits.
The use of a UBFX operation is recommended to extract a single bit from a peripheral.
For this case, the w field is simply set to 0, indicating a bit field width of 1.
31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10
-
9
8
7
ioubfxb 0
1
0
1
-
-
b
b
b
w w w
mem_addr
ioubfxh 0
1
0
1
-
b
b
b
b w w w w
mem_addr
ioubfxw 0
1
0
1
b
b
b
b
b w w w w
mem_addr
6
5
4
3
2
1
0
0
0
0
Figure 17-11. Decorated load address: unsigned bit field extract
where addr[28] = 1 specifies the unsigned bit field extract operation, addr[27:23] is "b",
the LSB identifier, addr[22:19] is "w", the bit field width minus 1 identifier, and
mem_addr[18:0] specifies the address offset into the peripheral space based at
0x4000_0000. The "-" indicates an address bit "don't care". Note, unlike the other
decorated load operations, UBFX uses addr[19] as the least significant bit in the "w"
specifier and not as an address bit.
The decorated unsigned bit field extract read operation is defined in the following
pseudo-code as:
rdata =
ioubfx<sz>(accessAddress)
tmp
= mem[accessAddress & 0xE007FFFF, size]
mask = ((1 << (w+1)) - 1) << b
rdata = (tmp & mask) >> b
// unsigned bit field extract
// memory read
// generate bit mask
// read data returned to core
Like the BFI operation, when the starting bit position plus the field width exceeds the
container size, only part of the source bit field is extracted from the destination memory
location. Stated differently, if (b + w+1) > container_width, only the low-order
"container_width - b" bits are actually extracted. The cycle-by-cycle BME operations are
detailed in the following table.
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Chapter 17 Bit Manipulation Engine (BME)
Table 17-7. Cycle definitions of decorated load: unsigned bit field extract
Pipeline Stage
Cycle
x
BME AHB_ap
Forward addr to memory;
Decode decoration; Capture
address, attributes
BME AHB_dp
<previous>
x+1
Idle AHB address phase
x+2
<next>
Perform memory read; Form Logically right shift registered
bit mask; Form (rdata & mask) data; Return justified rdata to
and capture destination data master
in register
17.4.3 Additional Details on Decorated Addresses and GPIO
Accesses
As previously noted, the peripheral address space occupies a 516 KB region: 512 KB
based at 0x4000_0000 plus a 4 KB space based at 0x400F_F000 for GPIO accesses. This
memory layout provides compatibility with the Kinetis K Family and provides 129
address "slots", each 4 KB in size.
The GPIO address space is multiply-mapped by the hardware: it appears at the "standard"
system address 0x400F_F000 and is physically located in the address slot corresponding
to address 0x4000_F000. Decorated loads and stores create a slight complication
involving accesses to the GPIO. Recall the use of address[19] varies by decorated
operation; for AND, OR, XOR, LAC1 and LAS1, this bit functions as a true address bit,
while for BFI and UBFX, this bit defines the least significant bit of the "w" bit field
specifier.
As a result, undecorated GPIO references and decorated AND, OR, XOR, LAC1 and
LAS1 operations can use the standard 0x400F_F000 base address, while decorated BFI
and UBFX operations must use the alternate 0x4000_F000 base address. Another
implementation can simply use 0x400F_F000 as the base address for all undecorated
GPIO accesses and 0x4000_F000 as the base address for all decorated accesses. Both
implementations are supported by the hardware.
Table 17-8. Decorated peripheral and GPIO address details
Peripheral address space
Description
0x4000_0000 - 0x4007_FFFF
Undecorated (normal) peripheral accesses
0x4008_0000 - 0x400F_EFFF
Illegal addresses; attempted references are aborted and error terminated
0x400F_F000 - 0x400F_FFFF
Undecorated (normal) GPIO accesses using standard address
0x4010_0000 - 0x43FF_FFFF
Illegal addresses; attempted references are aborted and error terminated
Table continues on the next page...
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Application Information
Table 17-8. Decorated peripheral and GPIO address details (continued)
Peripheral address space
Description
0x4400_0000 - 0x4FFF_FFFF
Decorated AND, OR, XOR, LAC1, LAS1 references to peripherals and GPIO based at
either 0x4000_F000 or 0x400F_F000
0x5000_0000 - 0x5FFF_FFFF
Decorated BFI, UBFX references to peripherals and GPIO only based at 0x4000_F000
17.5 Application Information
In this section, GNU assembler macros with C expression operands are presented as
examples of the required instructions to perform decorated operations. This section
specifically presents a partial bme.h file defining the assembly language expressions for
decorated logical stores: AND, OR and XOR. Comparable functions for BFI and the
decorated loads are more complex and available in the complete BME header file.
These macros use the same function names presented in Functional Description.
#define IOANDW(ADDR,WDATA)
\
__asm("ldr
r3, =(1<<26);"
\
"orr
r3, %[addr];"
\
"mov
r2, %[wdata];"
\
"str
r2, [r3];"
\
:: [addr] "r" (ADDR), [wdata] "r" (WDATA) : "r2", "r3");
#define IOANDH(ADDR,WDATA)
\
__asm("ldr
r3, =(1<<26);"
\
"orr
r3, %[addr];"
\
"mov
r2, %[wdata];"
\
"strh
r2, [r3];"
\
:: [addr] "r" (ADDR), [wdata] "r" (WDATA) : "r2", "r3");
#define IOANDB(ADDR,WDATA)
\
__asm("ldr
r3, =(1<<26);"
\
"orr
r3, %[addr];"
\
"mov
r2, %[wdata];"
\
"strb
r2, [r3];"
\
:: [addr] "r" (ADDR), [wdata] "r" (WDATA) : "r2", "r3");
#define IOORW(ADDR,WDATA)
\
__asm("ldr
r3, =(1<<27);"
\
"orr
r3, %[addr];"
\
"mov
r2, %[wdata];"
\
"str
r2, [r3];"
\
:: [addr] "r" (ADDR), [wdata] "r" (WDATA) : "r2", "r3");
#define IOORH(ADDR,WDATA)
\
__asm("ldr
r3, =(1<<27);"
\
"orr
r3, %[addr];"
\
"mov
r2, %[wdata];"
\
"strh
r2, [r3];"
\
:: [addr] "r" (ADDR), [wdata] "r" (WDATA) : "r2", "r3");
#define IOORB(ADDR,WDATA)
__asm("ldr
r3, =(1<<27);"
"orr
r3, %[addr];"
"mov
r2, %[wdata];"
"strb
r2, [r3];"
\
\
\
\
\
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Chapter 17 Bit Manipulation Engine (BME)
:: [addr] "r" (ADDR), [wdata] "r" (WDATA) : "r2", "r3");
#define IOXORW(ADDR,WDATA)
\
__asm("ldr
r3, =(3<<26);"
\
"orr
r3, %[addr];"
\
"mov
r2, %[wdata];"
\
"str
r2, [r3];"
\
:: [addr] "r" (ADDR), [wdata] "r" (WDATA) : "r2", "r3");
#define IOXORH(ADDR,WDATA)
\
__asm("ldr
r3, =(3<<26);"
\
"orr
r3, %[addr];"
\
"mov
r2, %[wdata];"
\
"strh
r2, [r3];"
\
:: [addr] "r" (ADDR), [wdata] "r" (WDATA) : "r2", "r3");
#define IOXORB(ADDR,WDATA)
\
__asm("ldr
r3, =(3<<26);"
\
"orr
r3, %[addr];"
\
"mov
r2, %[wdata];"
\
"strb
r2, [r3];"
\
:: [addr] "r" (ADDR), [wdata] "r" (WDATA) : "r2", "r3");
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Application Information
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Chapter 18
Miscellaneous Control Module (MCM)
18.1 Introduction
NOTE
For the chip-specific implementation details of this module's
instances see the chip configuration information.
The Miscellaneous Control Module (MCM) provides a myriad of miscellaneous control
functions.
18.1.1 Features
The MCM includes the following features:
• Program-visible information on the platform configuration
• Crossbar master arbitration policy selection
• Flash controller speculation buffer and cache configurations
18.2 Memory map/register descriptions
The memory map and register descriptions below describe the registers using byte
addresses.
MCM memory map
Absolute
address
(hex)
F000_3008
Register name
Crossbar Switch (AXBS) Slave Configuration
(MCM_PLASC)
Width
Access
(in bits)
16
Reset value
Section/
page
0007h
18.2.1/260
R
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Memory map/register descriptions
MCM memory map (continued)
Absolute
address
(hex)
F000_300A
Width
Access
(in bits)
Register name
Crossbar Switch (AXBS) Master Configuration
(MCM_PLAMC)
Reset value
Section/
page
16
R
0005h
18.2.2/261
F000_300C Platform Control Register (MCM_PLACR)
32
R/W
0000_0000h
18.2.3/261
F000_3040
32
R/W
0000_0000h
18.2.4/264
Compute Operation Control Register (MCM_CPO)
18.2.1 Crossbar Switch (AXBS) Slave Configuration (MCM_PLASC)
PLASC is a 16-bit read-only register identifying the presence/absence of bus slave
connections to the device’s crossbar switch.
Address: F000_3000h base + 8h offset = F000_3008h
Bit
15
14
13
12
Read
11
10
9
8
7
6
5
4
0
3
2
1
0
0
1
1
1
ASC
Write
Reset
0
0
0
0
0
0
0
0
0
0
0
0
MCM_PLASC field descriptions
Field
15–8
Reserved
7–0
ASC
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Each bit in the ASC field indicates whether there is a corresponding connection to the crossbar switch's
slave input port.
0
1
A bus slave connection to AXBS input port n is absent
A bus slave connection to AXBS input port n is present
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Chapter 18 Miscellaneous Control Module (MCM)
18.2.2 Crossbar Switch (AXBS) Master Configuration (MCM_PLAMC)
PLAMC is a 16-bit read-only register identifying the presence/absence of bus master
connections to the device's crossbar switch.
Address: F000_3000h base + Ah offset = F000_300Ah
Bit
15
14
13
12
Read
11
10
9
8
7
6
5
4
0
3
2
1
0
0
1
0
1
AMC
Write
Reset
0
0
0
0
0
0
0
0
0
0
0
0
MCM_PLAMC field descriptions
Field
15–8
Reserved
7–0
AMC
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Each bit in the AMC field indicates whether there is a corresponding connection to the AXBS master input
port.
0
1
A bus master connection to AXBS input port n is absent
A bus master connection to AXBS input port n is present
18.2.3 Platform Control Register (MCM_PLACR)
The PLACR register selects the arbitration policy for the crossbar masters and configures
the flash memory controller.
The speculation buffer and cache in the flash memory controller is configurable via
MCM_PLACR[15:10].
The speculation buffer is enabled only for instructions after reset. It is possible to have
these states for the speculation buffer:
DFCS
EFDS
Description
0
0
Speculation buffer is on for instruction
and off for data.
0
1
Speculation buffer is on for instruction
and on for data.
1
X
Speculation buffer is off.
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Memory map/register descriptions
The cache in flash controller is enabled and caching both instruction and data type fetches
after reset. It is possible to have these states for the cache:
DFCC
DFCIC
DFCDA
Description
0
0
0
Cache is on for both
instruction and data.
0
0
1
Cache is on for instruction
and off for data.
0
1
0
Cache is off for instruction
and on for data.
0
1
1
Cache is off for both
instruction and data.
1
X
X
Cache is off.
Address: F000_3000h base + Ch offset = F000_300Ch
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
R
ESFC
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
EFDS
DFCC
DFCIC
DFCDA
0
0
0
0
0
W
Reset
0
ARB
CFCC
DFCS
R
0
0
0
0
0
0
0
MCM_PLACR field descriptions
Field
31–17
Reserved
16
ESFC
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Enable Stalling Flash Controller
This field is used to enable stalling flash controller when flash is busy.
0
1
Disable stalling flash controller when flash is busy.
Enable stalling flash controller when flash is busy.
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Chapter 18 Miscellaneous Control Module (MCM)
MCM_PLACR field descriptions (continued)
Field
15
DFCS
Description
Disable Flash Controller Speculation
This field is used to disable flash controller speculation.
0
1
14
EFDS
Enable Flash Data Speculation
This field is used to enable flash data speculation.
0
1
13
DFCC
This field is used to disable flash controller cache.
This field is used to disable flash controller instruction caching.
9
ARB
8–0
Reserved
Enable flash controller instruction caching.
Disable flash controller instruction caching.
Disable Flash Controller Data Caching
This field is used to disable flash controller data caching.
0
1
10
CFCC
Enable flash controller cache.
Disable flash controller cache.
Disable Flash Controller Instruction Caching
0
1
11
DFCDA
Disable flash data speculation.
Enable flash data speculation.
Disable Flash Controller Cache
0
1
12
DFCIC
Enable flash controller speculation.
Disable flash controller speculation.
Enable flash controller data caching
Disable flash controller data caching.
Clear Flash Controller Cache
Writing a 1 to this field clears the cache. Writing a 0 to this field is ignored. This field always reads as 0.
Arbitration select
0
1
Fixed-priority arbitration for the crossbar masters
Round-robin arbitration for the crossbar masters
This field is reserved.
This read-only field is reserved and always has the value 0.
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Memory map/register descriptions
18.2.4 Compute Operation Control Register (MCM_CPO)
This register controls the Compute Operation.
Address: F000_3000h base + 40h offset = F000_3040h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
R
W
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
CPOWOI
R
CPOREQ
0
CPOACK
Reset
W
Reset
0
0
0
0
0
0
0
0
0
0
MCM_CPO field descriptions
Field
Description
31–3
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
2
CPOWOI
Compute Operation wakeup on interrupt
1
CPOACK
Compute Operation acknowledge
0
CPOREQ
Compute Operation request
0
1
0
1
No effect.
When set, the CPOREQ is cleared on any interrupt or exception vector fetch.
Compute operation entry has not completed or compute operation exit has completed.
Compute operation entry has completed or compute operation exit has not completed.
This bit is auto-cleared by vector fetching if CPOWOI = 1.
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Chapter 18 Miscellaneous Control Module (MCM)
MCM_CPO field descriptions (continued)
Field
Description
0
1
Request is cleared.
Request Compute Operation.
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Memory map/register descriptions
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Chapter 19
Micro Trace Buffer (MTB)
19.1 Introduction
Microcontrollers using the Cortex-M0+ processor core include support for a CoreSight
Micro Trace Buffer to provide program trace capabilities. The proper name for this
function is the CoreSight Micro Trace Buffer for the Cortex-M0+ Processor; in this
document, it is simply abbreviated as the MTB.
The simple program trace function creates instruction address change-of-flow data
packets in a user-defined region of the system RAM. Accordingly, the system RAM
controller manages requests from two sources:
• AMBA-AHB reads and writes from the system bus
• program trace packet writes from the processor
As part of the MTB functionality, there is a DWT (Data Watchpoint and Trace) module
that allows the user to define watchpoint addresses, or optionally, an address and data
value, that when triggered, can be used to start or stop the program trace recording.
This document details the functionality of both the MTB_RAM and MTB_DWT
capabilities.
19.1.1 Overview
A generic block diagram of the processor core and platform for this class of ultra low-end
microcontrollers is shown as follows:
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Cortex-M0+ Core
Dbg
NVIC
CM0+ Core Platform
Fetch
AGU
Dec
Rn
LD/ST
SHFT
ALU
MUL
AHB Bus
IO Port
MTB Port
32
PRAM
RAM
Array
RGPIO
s1
m0
32
Alt-Master
s2
m3
DMA_4ch
m2
AXBS
BME
PBRIDGE
Slave
Peripherals
s0
32
FMC
NVM
Array
Figure 19-1. Generic Cortex-M0+ core platform block diagram
As shown in the block diagram, the platform RAM (PRAM) controller connects to two
input buses:
• the crossbar slave port for system bus accesses
• a "private execution MTB port" from the core
The logical paths from the crossbar master input ports to the PRAM controller are
highlighted along with the private execution trace port from the processor core. The
private MTB port signals the instruction address information needed for the 64-bit
program trace packets written into the system RAM. The PRAM controller output
interfaces to the attached RAM array. In this document, the PRAM controller is the
MTB_RAM controller.
The following information is taken from the ARM CoreSight Micro Trace Buffer
documentation.
"The execution trace packet consists of a pair of 32-bit words that the MTB generates
when it detects the processor PC value changes non-sequentially. A non-sequential PC
change can occur during branch instructions or during exception entry.
The processor can cause a trace packet to be generated for any instruction.
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Chapter 19 Micro Trace Buffer (MTB)
The following figure shows how the execution trace information is stored in memory as a
sequence of packets.
31
1
Nth destination address
Nth source address
Incrementing
SRAM memory
address
31
1
2nd destination address
2nd source address
1st destination address
1st source address
0
S
A
0
S
A
S
A
Odd word address
Even word address
Start bit
Odd word address
Even word address
Atom bit
Figure 19-2. MTB execution trace storage format
The first, lower addressed, word contains the source of the branch, the address it
branched from. The value stored only records bits[31:1] of the source address, because
Thumb instructions are at least halfword aligned. The least significant bit of the value is
the A-bit. The A-bit indicates the atomic state of the processor at the time of the branch,
and can differentiate whether the branch originated from an instruction in a program, an
exception, or a PC update in Debug state. When it is zero the branch originated from an
instruction, when it is one the branch originated from an exception or PC update in
Debug state. This word is always stored at an even word location.
The second, higher addressed word contains the destination of the branch, the address it
branched to. The value stored only records bits[31:1] of the branch address. The least
significant bit of the value is the S-bit. The S-bit indicates where the trace started. An Sbit value of 1 indicates where the first packet after the trace started and a value of 0 is
used for other packets. Because it is possible to start and stop tracing multiple times in a
trace session, the memory might contain several packets with the S-bit set to 1. This word
is always stored in the next higher word in memory, an odd word address.
When the A-bit is set to 1, the source address field contains the architecturally-preferred
return address for the exception. For example, if an exception was caused by an SVC
instruction, then the source address field contains the address of the following instruction.
This is different from the case where the A-bit is set to 0. In this case, the source address
contains the address of the branch instruction.
For an exception return operation, two packets are generated:
• The first packet has the:
• Source address field set to the address of the instruction that causes the exception
return, BX or POP.
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Introduction
• Destination address field set to bits[31:1] of the EXC_RETURN value. See the
ARM v6-M Architecture Reference Manual.
• The A-bit set to 0.
• The second packet has the:
• Source address field set to bits[31:1] of the EXC_RETURN value.
• Destination address field set to the address of the instruction where execution
commences.
• A-bit set to 1."
Given the recorded change-of-flow trace packets in system RAM and the memory image
of the application, a debugger can read out the data and create an instruction-byinstruction program trace. In keeping with the low area and power implementation cost
design targets, the MTB trace format is less efficient than other CoreSight trace modules,
for example, the ETM (Embedded Trace Macrocell). Since each branch packet is 8 bytes
in size, a 1 KB block of system RAM can contain 128 branches. Using the Dhrystone 2.1
benchmark's dynamic runtime as an example, this corresponds to about 875 instructions
per KB of trace RAM, or with a zero wait state memory, this corresponds to
approximately 1600 processor cycles per KB. This metric is obviously very sensitive to
the runtime characteristics of the user code.
The MTB_DWT function (not shown in the core platform block diagram) monitors the
processor address and data buses so that configurable watchpoints can be detected to
trigger the appropriate response in the MTB recording.
19.1.2 Features
The key features of the MTB_RAM and MTB_DWT include:
• Memory controller for system RAM and Micro Trace Buffer for program trace
packets
• Read/write capabilities for system RAM accesses, write-only for program trace
packets
• Supports zero wait state response to system bus accesses when no trace data is being
written
• Can buffer two AHB address phases and one data write for system RAM accesses
• Supports 64-bit program trace packets including source and destination instruction
addresses
• Program trace information in RAM available to MCU's application code or external
debugger
• Program trace watchpoint configuration accessible by MCU's application code or
debugger
• Location and size of RAM trace buffer is configured by software
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Chapter 19 Micro Trace Buffer (MTB)
• Two DWT comparators (addresses or address + data) provide programmable start/
stop recording
• CoreSight compliant debug functionality
19.1.3 Modes of Operation
The MTB_RAM and MTB_DWT functions do not support any special modes of
operation. The MTB_RAM controller, as a memory-mapped device located on the
platform's slave AHB system bus, responds based strictly on memory addresses for
accesses to its attached RAM array. The MTB private execution bus provides program
trace packet write information to the RAM controller. Both the MTB_RAM and
MTB_DWT modules are memory-mapped so their programming models can be
accessed.
All functionality associated with the MTB_RAM and MTB_DWT modules resides in the
core platform's clock domain; this includes its connections with the RAM array.
19.2 External Signal Description
The MTB_RAM and MTB_DWT modules do not directly support any external
interfaces.
The internal interfaces includes a standard AHB bus with a 32-bit datapath width from
the appropriate crossbar slave port plus the private execution trace bus from the processor
core. The signals in the private execution trace bus are detailed in the following table
taken from the ARM CoreSight Micro Trace Buffer documentation. The signal direction
is defined as viewed by the MTB_RAM controller.
Table 19-1. Private execution trace port from the core to MTB_RAM
Signal
Direction
Description
LOCKUP
Input
Indicates the processor is in the Lockup state. This signal is driven LOW for cycles
when the processor is executing normally and driven HIGH for every cycle the
processor is waiting in the Lockup state. This signal is valid on every cycle.
IAESEQ
Input
Indicates the next instruction address in execute, IAEX, is sequential, that is nonbranching.
IAEXEN
Input
IAEX register enable.
IAEX[30:0]
Input
Registered address of the instruction in the execution stage, shifted right by one
bit, that is, PC >> 1.
ATOMIC
Input
Indicates the processor is performing non-instruction related activities.
EDBGRQ
Output
Request for the processor to enter the Debug state, if enabled, and halt.
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Memory Map and Register Definition
In addition, there are two signals formed by the MTB_DWT module and driven to the
MTB_RAM controller: TSTART (trace start) and TSTOP (trace stop). These signals can
be configured using the trace watchpoints to define programmable addresses and data
values to affect the program trace recording state.
19.3 Memory Map and Register Definition
The MTB_RAM and MTB_DWT modules each support a sparsely-populated 4 KB
address space for their programming models. For each address space, there are a variety
of control and configurable registers near the base address, followed by a large unused
address space and finally a set of CoreSight registers to support dynamic determination of
the debug configuration for the device.
Accesses to the programming model follow standard ARM conventions. Taken from the
ARM CoreSight Micro Trace Buffer documentation, these are:
• Do not attempt to access reserved or unused address locations. Attempting to access
these locations can result in UNPREDICTABLE behavior.
• The behavior of the MTB is UNPREDICTABLE if the registers with UNKNOWN
reset values are not programmed prior to enabling trace.
• Unless otherwise stated in the accompanying text:
• Do not modify reserved register bits
• Ignore reserved register bits on reads
• All register bits are reset to a logic 0 by a system or power-on reset
• Use only word size, 32-bit, transactions to access all registers
19.3.1 MTB_RAM Memory Map
MTB memory map
Absolute
address
(hex)
Register name
Width
Access
(in bits)
Reset value
Section/
page
F000_0000
MTB Position Register (MTB_POSITION)
32
R/W
Undefined
19.31.1/273
F000_0004
MTB Master Register (MTB_MASTER)
32
R/W
See section
19.31.2/275
F000_0008
MTB Flow Register (MTB_FLOW)
32
R/W
Undefined
19.31.3/277
F000_000C MTB Base Register (MTB_BASE)
32
R
Undefined
19.31.4/279
F000_0F00
32
R
0000_0000h
19.31.5/279
F000_0FA0 Claim TAG Set Register (MTB_TAGSET)
32
R
0000_0000h
19.31.6/280
F000_0FA4 Claim TAG Clear Register (MTB_TAGCLEAR)
32
R
0000_0000h
19.31.7/280
F000_0FB0 Lock Access Register (MTB_LOCKACCESS)
32
R
0000_0000h
19.31.8/281
Integration Mode Control Register (MTB_MODECTRL)
Table continues on the next page...
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Chapter 19 Micro Trace Buffer (MTB)
MTB memory map (continued)
Absolute
address
(hex)
Register name
Width
Access
(in bits)
Reset value
Section/
page
F000_0FB4 Lock Status Register (MTB_LOCKSTAT)
32
R
0000_0000h
19.31.9/281
F000_0FB8 Authentication Status Register (MTB_AUTHSTAT)
32
R
0000_0000h
19.31.10/
282
F000_0FBC Device Architecture Register (MTB_DEVICEARCH)
32
R
4770_0A31h
19.31.11/
283
F000_0FC8 Device Configuration Register (MTB_DEVICECFG)
32
R
0000_0000h
19.31.12/
283
F000_0FCC Device Type Identifier Register (MTB_DEVICETYPID)
32
R
0000_0031h
19.31.13/
284
F000_0FD0 Peripheral ID Register (MTB_PERIPHID4)
32
R
See section
19.31.14/
284
F000_0FD4 Peripheral ID Register (MTB_PERIPHID5)
32
R
See section
19.31.14/
284
F000_0FD8 Peripheral ID Register (MTB_PERIPHID6)
32
R
See section
19.31.14/
284
F000_0FDC Peripheral ID Register (MTB_PERIPHID7)
32
R
See section
19.31.14/
284
F000_0FE0 Peripheral ID Register (MTB_PERIPHID0)
32
R
See section
19.31.14/
284
F000_0FE4 Peripheral ID Register (MTB_PERIPHID1)
32
R
See section
19.31.14/
284
F000_0FE8 Peripheral ID Register (MTB_PERIPHID2)
32
R
See section
19.31.14/
284
F000_0FEC Peripheral ID Register (MTB_PERIPHID3)
32
R
See section
19.31.14/
284
F000_0FF0
Component ID Register (MTB_COMPID0)
32
R
See section
19.31.15/
285
F000_0FF4
Component ID Register (MTB_COMPID1)
32
R
See section
19.31.15/
285
F000_0FF8
Component ID Register (MTB_COMPID2)
32
R
See section
19.31.15/
285
F000_0FFC Component ID Register (MTB_COMPID3)
32
R
See section
19.31.15/
285
19.31.1 MTB Position Register (MTB_POSITION)
The MTB_POSITION register is the trace write address pointer and wrap bit. This
register can be modified by the explicit programming model writes. It is also
automatically updated by the MTB hardware when trace packets are being recorded.
The base address of the system RAM in the memory map dictates special consideration
for the placement of the MTB. Consider the following guidelines:
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For the standard configuration where the size of the MTB is ≤ 25% of the total RAM
capacity, it is recommended the MTB be based at the address defined by the MTB_BASE
register. The read-only MTB_BASE register is defined by the expression (0x2000_0000 (RAM_Size/4)). For this configuration, the MTB_POSITION register is initialized to
(MTB_BASE & 0x0000_7FF8).
If the size of the MTB is more than 25% but less than or equal to 50% of the total RAM
capacity, it is recommended the MTB be based at address 0x2000_0000. In this
configuration, the MTB_POSITION register is initialized to (0x2000_0000 &
0x0000_7FF8) = 0x0000_00000.
Following these two suggested placements provides a full-featured circular memory
buffer containing program trace packets.
In the unlikely event an even larger trace buffer is required, a write-once capacity of 75%
of the total RAM capacity can be based at address 0x2000_0000. The MTB_POSITION
register is initialized to (0x2000_0000 & 0x0000_7FF8) = 0x0000_0000. However, this
configuration cannot support operation as a circular queue and instead requires the use of
the MTB_FLOW[WATERMARK] capability to automatically disable tracing or halting
the processor as the number of packet writes approach the buffer capacity. See the
MTB_FLOW register description for more details.
Address: F000_0000h base + 0h offset = F000_0000h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
R
POINTER
W
Reset
x*
x*
x*
x*
x*
x*
x*
x*
x*
x*
x*
x*
x*
x*
x*
x*
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
POINTER
W
Reset
x*
x*
x*
x*
x*
x*
x*
0
WRAP
R
x*
x*
x*
x*
x*
x*
x*
0
0
* Notes:
• x = Undefined at reset.
MTB_POSITION field descriptions
Field
31–3
POINTER
Description
Trace Packet Address Pointer[28:0]
Trace packet address pointer. Because a packet consists of two words, the POINTER field is the address
of the first word of a packet. This field contains bits[31:3] of the RAM address where the next trace packet
is written. Therefore, it points to an unused location and is automatically incremented.
Table continues on the next page...
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MTB_POSITION field descriptions (continued)
Field
Description
A debug agent can calculate the system memory map address for the current location in the MTB using
the following "generic" equation:
Given mtb_size = 1 << (MTB_MASTER[MASK] + 4),
systemAddress = MTB_BASE + (((MTB_POSITION & 0xFFFF_FFF8) + (mtb_size - (MTB_BASE &
(mtb_size-1)))) & 0x0000_7FF8);
For this device, a simpler expression also applies. See the following pseudo-code:
if ((MTB_POSITION >> 13) == 0x3) systemAddress = (0x1FFF << 16) + (0x1 << 15) + (MTB_POSITION &
0x7FF8); else systemAddress = (0x2000 << 16) + (0x0 << 15) + (MTB_POSITION & 0x7FF8);
NOTE: The size of the RAM is parameterized and the most significant bits of the POINTER field are
RAZ/WI.
For these devices, POSITION[31:15] == POSITION[POINTER[28:12]] are RAZ/WI. Therefore, the active
bits in this field are POSITION[14:3] == POSITION[POINTER[11:0]].
2
WRAP
1–0
Reserved
This bit is set to 1 automatically when the POINTER value wraps as determined by the
MTB_MASTER[MASK] field in the MASTER Trace Control Register. A debug agent might use the WRAP
bit to determine whether the trace information above and below the pointer address is valid.
This field is reserved.
This read-only field is reserved and always has the value 0.
19.31.2 MTB Master Register (MTB_MASTER)
The MTB_MASTER register contains the main program trace enable plus other trace
controls. This register can be modified by the explicit programming model writes.
MTB_MASTER[EN] and MTB_MASTER[HALTREQ] fields are also automatically
updated by the MTB hardware.
Before the MTB_MASTER[EN] or MTB_MASTER[TSTARTEN] bits are set to 1,
software must initialize the MTB_POSITION and MTB_FLOW registers.
If the MTB_FLOW[WATERMARK] field is used to stop tracing or to halt the processor,
the MTB_MASTER[MASK] field must still be set to a value that prevents the
MTB_POSITION[POINTER] field from wrapping before it reaches the
MTB_FLOW[WATERMARK] value.
NOTE
The format of this mask field is different than the
MTBDWT_MASKn[MASK].
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Address: F000_0000h base + 4h offset = F000_0004h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
R
EN
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
HALTREQ
RAMPRIV
SFRWPRIV
TSTOPEN
TSTARTEN
W
0
0
1
0
0
x*
x*
0
R
W
Reset
0
0
0
0
0
0
MASK
x*
x*
x*
* Notes:
• x = Undefined at reset.
MTB_MASTER field descriptions
Field
31
EN
Description
Main trace enable bit
When this bit is 1, trace data is written into the RAM memory location addressed by
MTB_POSITION[POINTER]. The MTB_POSITION[POINTER] value auto increments after the trace data
packet is written.
The EN bit can be automatically set to 0 using the MTB_FLOW[WATERMARK] field and the
MTB_FLOW[AUTOSTOP] bit.
The EN bit is automatically set to 1 if the TSTARTEN bit is 1 and the TSTART signal is HIGH.
The EN bit is automatically set to 0 if TSTOPEN bit is 1 and the TSTOP signal is HIGH.
NOTE: If the EN bit is set to 0 because the MTB_FLOW[WATERMARK] field is set, then it is not
automatically set to 1 if the TSTARTEN bit is 1 and the TSTART input is HIGH. In this case,
tracing can only be restarted if the MTB_FLOW[WATERMARK] or MTB_POSITION[POINTER]
value is changed by software.
30–10
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
9
HALTREQ
Halt request bit
8
RAMPRIV
RAM privilege bit
7
SFRWPRIV
This bit is connected to the halt request signal of the trace logic, EDBGRQ. When HALTREQ is set to 1,
the EDBFGRQ is asserted if DBGEN (invasive debug enable, one of the debug authentication interface
signals) is also HIGH. The HALTREQ bit can be automatically set to 1 using the
MTB_FLOW[WATERMARK] field.
If this bit is 0, then user or privileged AHB read and write accesses to the RAM are permitted. If this bit is
1, then only privileged AHB read and write accesses to the RAM are permitted and user accesses are
RAZ/WI. The HPROT[1] signal determines if an access is a user or privileged mode reference.
Special Function Register Write Privilege bit
If this bit is 0, then user or privileged AHB read and write accesses to the MTB_RAM Special Function
Registers (programming model) are permitted. If this bit is 1, then only privileged write accesses are
Table continues on the next page...
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Chapter 19 Micro Trace Buffer (MTB)
MTB_MASTER field descriptions (continued)
Field
Description
permitted; user write accesses are ignored. The HPROT[1] signal determines if an access is user or
privileged. Note MTB_RAM SFR read access are not controlled by this bit and are always permitted.
6
TSTOPEN
Trace stop input enable
5
TSTARTEN
Trace start input enable
4–0
MASK
If this bit is 1 and the TSTOP signal is HIGH, then the EN bit is set to 0. If a trace packet is being written to
memory, the write is completed before tracing is stopped.
If this bit is 1 and the TSTART signal is HIGH, then the EN bit is set to 1. Tracing continues until a stop
condition occurs.
Mask
This value determines the maximum size of the trace buffer in RAM. It specifies the most-significant bit of
the MTB_POSITION[POINTER] field that can be updated by automatic increment. If the trace tries to
advance past this power of two, the MTB_POSITION[WRAP] bit is set to 1, the MTB_POSITION[MASK
+3:3] == MTB_POSITION[POINTER[MASK:0]] bits are set to zero, and the MTB_POSITION[14:MASK+3]
== MTB_POSITION[POINTER[11:MASK+1]] bits remain unchanged.
This field causes the trace packet information to be stored in a circular buffer of size 2^[MASK+4] bytes,
that can be positioned in memory at multiples of this size. As detailed in the MTB_POSITION description,
typical "upper limits" for the MTB size are RAM_Size/4 or RAM_Size/2. Values greater than the maximum
have the same effect as the maximum.
19.31.3 MTB Flow Register (MTB_FLOW)
The MTB_FLOW register contains the watermark address and the autostop/autohalt
control bits.
If tracing is stopped using the watermark autostop feature, it cannot be restarted until
software clears the watermark autostop. This can be achieved in one of the following
ways:
• Changing the MTB_POSITION[POINTER] field value to point to the beginning of
the trace buffer, or
• Setting MTB_FLOW[AUTOSTOP] = 0.
A debug agent can use the MTB_FLOW[AUTOSTOP] bit to fill the trace buffer once
only without halting the processor.
A debug agent can use the MTB_FLOW[AUTOHALT] bit to fill the trace buffer once
before causing the Cortex-M0+ processor to enter the Debug state. To enter Debug state,
the Cortex-M0+ processor might have to perform additional branch type operations.
Therefore, the MTB_FLOW[WATERMARK] field must be set below the final entry in
the trace buffer region.
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Address: F000_0000h base + 8h offset = F000_0008h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
R
WATERMARK
Reset
x*
x*
x*
x*
x*
x*
x*
x*
x*
x*
x*
x*
x*
x*
x*
x*
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
AUTOHALT
AUTOSTOP
W
0
x*
x*
R
WATERMARK
W
Reset
x*
x*
x*
x*
x*
x*
x*
x*
x*
x*
x*
x*
x*
* Notes:
• x = Undefined at reset.
MTB_FLOW field descriptions
Field
31–3
WATERMARK
2
Reserved
Description
WATERMARK[28:0]
This field contains an address in the same format as the MTB_POSITION[POINTER] field. When the
MTB_POSITION[POINTER] matches the WATERMARK field value, actions defined by the AUTOHALT
and AUTOSTOP bits are performed.
This field is reserved.
This read-only field is reserved and always has the value 0.
1
AUTOHALT
If this bit is 1 and WATERMARK is equal to MTB_POSITION[POINTER], then the
MTB_MASTER[HALTREQ] bit is automatically set to 1. If the DBGEN signal is HIGH, the MTB asserts this
halt request to the Cortex-M0+ processor by asserting the EDBGRQ signal.
0
AUTOSTOP
If this bit is 1 and WATERMARK is equal to MTB_POSITION[POINTER], then the MTB_MASTER[EN] bit
is automatically set to 0. This stops tracing.
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Chapter 19 Micro Trace Buffer (MTB)
19.31.4 MTB Base Register (MTB_BASE)
The read-only MTB_BASE Register indicates where the RAM is located in the system
memory map. This register is provided to enable auto discovery of the MTB RAM
location, by a debug agent and is defined by a hardware design parameter. For this
device, the base address is defined by the expression: MTB_BASE[BASEADDR] =
0x2000_0000 - (RAM_Size/4)
Address: F000_0000h base + Ch offset = F000_000Ch
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
BASEADDR
R
W
Reset
x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x*
* Notes:
• x = Undefined at reset.
MTB_BASE field descriptions
Field
Description
31–0
BASEADDR
This value is defined with a hardwired signal and the expression: 0x2000_0000 - (RAM_Size/4). For
example, if the total RAM capacity is 16 KB, this field is 0x1FFF_F000.
19.31.5 Integration Mode Control Register (MTB_MODECTRL)
This register enables the device to switch from a functional mode, or default behavior,
into integration mode. It is hardwired to specific values used during the auto-discovery
process by an external debug agent.
Address: F000_0000h base + F00h offset = F000_0F00h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
MODECTRL
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
MTB_MODECTRL field descriptions
Field
31–0
MODECTRL
Description
Hardwired to 0x0000_0000
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Memory Map and Register Definition
19.31.6 Claim TAG Set Register (MTB_TAGSET)
The Claim Tag Set Register returns the number of bits that can be set on a read, and
enables individual bits to be set on a write. It is hardwired to specific values used during
the auto-discovery process by an external debug agent.
Address: F000_0000h base + FA0h offset = F000_0FA0h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
TAGSET
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
MTB_TAGSET field descriptions
Field
Description
31–0
TAGSET
Hardwired to 0x0000_0000
19.31.7 Claim TAG Clear Register (MTB_TAGCLEAR)
The read/write Claim Tag Clear Register is used to read the claim status on debug
resources. A read indicates the claim tag status. Writing 1 to a specific bit clears the
corresponding claim tag to 0. It is hardwired to specific values used during the autodiscovery process by an external debug agent.
Address: F000_0000h base + FA4h offset = F000_0FA4h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
TAGCLEAR
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
MTB_TAGCLEAR field descriptions
Field
31–0
TAGCLEAR
Description
Hardwired to 0x0000_0000
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Chapter 19 Micro Trace Buffer (MTB)
19.31.8 Lock Access Register (MTB_LOCKACCESS)
The Lock Access Register enables a write access to component registers. It is hardwired
to specific values used during the auto-discovery process by an external debug agent.
Address: F000_0000h base + FB0h offset = F000_0FB0h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
LOCKACCESS
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
MTB_LOCKACCESS field descriptions
Field
Description
31–0
LOCKACCESS
Hardwired to 0x0000_0000
19.31.9 Lock Status Register (MTB_LOCKSTAT)
The Lock Status Register indicates the status of the lock control mechanism. This register
is used in conjunction with the Lock Access Register. It is hardwired to specific values
used during the auto-discovery process by an external debug agent.
Address: F000_0000h base + FB4h offset = F000_0FB4h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
LOCKSTAT
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
MTB_LOCKSTAT field descriptions
Field
31–0
LOCKSTAT
Description
Hardwired to 0x0000_0000
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Memory Map and Register Definition
19.31.10 Authentication Status Register (MTB_AUTHSTAT)
The Authentication Status Register reports the required security level and current status
of the security enable bit pairs. Where functionality changes on a given security level,
this change must be reported in this register. It is connected to specific signals used
during the auto-discovery process by an external debug agent.
MTB_AUTHSTAT[3:2] indicates if nonsecure, noninvasive debug is enabled or
disabled, while MTB_AUTHSTAT[1:0] indicates the enabled/disabled state of
nonsecure, invasive debug. For both 2-bit fields, 0b10 indicates the functionality is
disabled and 0b11 indicates it is enabled.
Address: F000_0000h base + FB8h offset = F000_0FB8h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
1
BIT2
1
BIT0
0
0
0
0
0
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
MTB_AUTHSTAT field descriptions
Field
Description
31–4
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
3
Reserved
This read-only field is reserved and always has the value 1.
2
BIT2
1
Reserved
0
BIT0
Connected to NIDEN or DBGEN signal.
This read-only field is reserved and always has the value 1.
Connected to DBGEN.
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Chapter 19 Micro Trace Buffer (MTB)
19.31.11 Device Architecture Register (MTB_DEVICEARCH)
This register indicates the device architecture. It is hardwired to specific values used
during the auto-discovery process by an external debug agent.
Address: F000_0000h base + FBCh offset = F000_0FBCh
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
1
0
1
0
0
0
1
1
0
0
0
1
DEVICEARCH
R
W
Reset
0
1
0
0
0
1
1
1
0
1
1
1
0
0
0
0
0
0
MTB_DEVICEARCH field descriptions
Field
Description
31–0
DEVICEARCH
Hardwired to 0x4770_0A31.
19.31.12 Device Configuration Register (MTB_DEVICECFG)
This register indicates the device configuration. It is hardwired to specific values used
during the auto-discovery process by an external debug agent.
Address: F000_0000h base + FC8h offset = F000_0FC8h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
DEVICECFG
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
MTB_DEVICECFG field descriptions
Field
31–0
DEVICECFG
Description
Hardwired to 0x0000_0000.
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Memory Map and Register Definition
19.31.13 Device Type Identifier Register (MTB_DEVICETYPID)
This register indicates the device type ID. It is hardwired to specific values used during
the auto-discovery process by an external debug agent.
Address: F000_0000h base + FCCh offset = F000_0FCCh
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
1
1
0
0
0
1
DEVICETYPID
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
MTB_DEVICETYPID field descriptions
Field
Description
31–0
DEVICETYPID
Hardwired to 0x0000_0031.
19.31.14 Peripheral ID Register (MTB_PERIPHIDn)
These registers indicate the peripheral IDs. They are hardwired to specific values used
during the auto-discovery process by an external debug agent.
Address: F000_0000h base + FD0h offset + (4d × i), where i=0d to 7d
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
PERIPHID
R
W
Reset
x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x*
* Notes:
• See field descriptions for the reset values.x = Undefined at reset.
MTB_PERIPHIDn field descriptions
Field
31–0
PERIPHID
Description
Peripheral ID4 is hardwired to 0x0000_0004; ID0 to 0x0000_0032; ID1 to 0x0000_00B9; ID2 to
0x0000_000B; and all the others to 0x0000_0000.
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Chapter 19 Micro Trace Buffer (MTB)
19.31.15 Component ID Register (MTB_COMPIDn)
These registers indicate the component IDs. They are hardwired to specific values used
during the auto-discovery process by an external debug agent.
Address: F000_0000h base + FF0h offset + (4d × i), where i=0d to 3d
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
COMPID
R
W
Reset
x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x*
* Notes:
• See field descriptions for the reset values.x = Undefined at reset.
MTB_COMPIDn field descriptions
Field
31–0
COMPID
Description
Component ID
Component ID0 is hardwired to 0x0000_000D; ID1 to 0x0000_0090; ID2 to 0x0000_0005; ID3 to
0x0000_00B1.
19.3.2 MTB_DWT Memory Map
The MTB_DWT programming model supports a very simplified subset of the v7M debug
architecture and follows the standard ARM DWT definition.
MTBDWT memory map
Absolute
address
(hex)
Register name
Width
Access
(in bits)
Reset value
Section/
page
F000_1000
MTB DWT Control Register (MTBDWT_CTRL)
32
R
2F00_0000h 19.32.1/286
F000_1020
MTB_DWT Comparator Register (MTBDWT_COMP0)
32
R/W
0000_0000h
19.32.2/287
F000_1024
MTB_DWT Comparator Mask Register (MTBDWT_MASK0)
32
R/W
0000_0000h
19.32.3/288
F000_1028
MTB_DWT Comparator Function Register 0
(MTBDWT_FCT0)
32
R/W
0000_0000h
19.32.4/289
F000_1030
MTB_DWT Comparator Register (MTBDWT_COMP1)
32
R/W
0000_0000h
19.32.2/287
F000_1034
MTB_DWT Comparator Mask Register (MTBDWT_MASK1)
32
R/W
0000_0000h
19.32.3/288
F000_1038
MTB_DWT Comparator Function Register 1
(MTBDWT_FCT1)
32
R/W
0000_0000h
19.32.5/291
F000_1200
MTB_DWT Trace Buffer Control Register
(MTBDWT_TBCTRL)
32
R/W
2000_0000h
19.32.6/292
F000_1FC8 Device Configuration Register (MTBDWT_DEVICECFG)
32
R
0000_0000h
19.32.7/294
Table continues on the next page...
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Memory Map and Register Definition
MTBDWT memory map (continued)
Absolute
address
(hex)
Width
Access
(in bits)
Register name
Reset value
Section/
page
F000_1FCC Device Type Identifier Register (MTBDWT_DEVICETYPID)
32
R
0000_0004h
19.32.8/294
F000_1FD0 Peripheral ID Register (MTBDWT_PERIPHID4)
32
R
See section
19.32.9/295
F000_1FD4 Peripheral ID Register (MTBDWT_PERIPHID5)
32
R
See section
19.32.9/295
F000_1FD8 Peripheral ID Register (MTBDWT_PERIPHID6)
32
R
See section
19.32.9/295
F000_1FDC Peripheral ID Register (MTBDWT_PERIPHID7)
32
R
See section
19.32.9/295
F000_1FE0 Peripheral ID Register (MTBDWT_PERIPHID0)
32
R
See section
19.32.9/295
F000_1FE4 Peripheral ID Register (MTBDWT_PERIPHID1)
32
R
See section
19.32.9/295
F000_1FE8 Peripheral ID Register (MTBDWT_PERIPHID2)
32
R
See section
19.32.9/295
F000_1FEC Peripheral ID Register (MTBDWT_PERIPHID3)
32
R
See section
19.32.9/295
F000_1FF0
Component ID Register (MTBDWT_COMPID0)
32
R
See section
19.32.10/
295
F000_1FF4
Component ID Register (MTBDWT_COMPID1)
32
R
See section
19.32.10/
295
F000_1FF8
Component ID Register (MTBDWT_COMPID2)
32
R
See section
19.32.10/
295
F000_1FFC Component ID Register (MTBDWT_COMPID3)
32
R
See section
19.32.10/
295
19.32.1 MTB DWT Control Register (MTBDWT_CTRL)
The MTBDWT_CTRL register provides read-only information on the watchpoint
configuration for the MTB_DWT.
Address: F000_1000h base + 0h offset = F000_1000h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
NUMCMP
R
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
DWTCFGCTRL
W
Reset
0
0
1
0
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
MTBDWT_CTRL field descriptions
Field
31–28
NUMCMP
Description
Number of comparators
The MTB_DWT implements two comparators.
27–0
DWT configuration controls
DWTCFGCTRL
This field is hardwired to 0xF00_0000, disabling all the remaining DWT functionality. The specific fields
and their state are:
MTBDWT_CTRL[27] = NOTRCPKT = 1, trace sample and exception trace is not supported
Table continues on the next page...
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Chapter 19 Micro Trace Buffer (MTB)
MTBDWT_CTRL field descriptions (continued)
Field
Description
MTBDWT_CTRL[26] = NOEXTTRIG = 1, external match signals are not supported
MTBDWT_CTRL[25] = NOCYCCNT = 1, cycle counter is not supported
MTBDWT_CTRL[24] = NOPRFCNT = 1, profiling counters are not supported
MTBDWT_CTRL[22] = CYCEBTENA = 0, no POSTCNT underflow packets generated
MTBDWT_CTRL[21] = FOLDEVTENA = 0, no folded instruction counter overflow events
MTBDWT_CTRL[20] = LSUEVTENA = 0, no LSU counter overflow events
MTBDWT_CTRL[19] = SLEEPEVTENA = 0, no sleep counter overflow events
MTBDWT_CTRL[18] = EXCEVTENA = 0, no exception overhead counter events
MTBDWT_CTRL[17] = CPIEVTENA = 0, no CPI counter overflow events
MTBDWT_CTRL[16] = EXCTRCENA = 0, generation of exception trace disabled
MTBDWT_CTRL[12] = PCSAMPLENA = 0, no periodic PC sample packets generated
MTBDWT_CTRL[11:10] = SYNCTAP = 0, no synchronization packets
MTBDWT_CTRL[9] = CYCTAP = 0, cycle counter is not supported
MTBDWT_CTRL[8:5] = POSTINIT = 0, cycle counter is not supported
MTBDWT_CTRL[4:1] = POSTPRESET = 0, cycle counter is not supported
MTBDWT_CTRL[0] = CYCCNTENA = 0, cycle counter is not supported
19.32.2 MTB_DWT Comparator Register (MTBDWT_COMPn)
The MTBDWT_COMPn registers provide the reference value for comparator n.
Address: F000_1000h base + 20h offset + (16d × i), where i=0d to 1d
Bit
R
W
31
Reset
0
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
COMP
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
MTBDWT_COMPn field descriptions
Field
31–0
COMP
Description
Reference value for comparison
If MTBDWT_COMP0 is used for a data value comparator and the access size is byte or halfword, the data
value must be replicated across all appropriate byte lanes of this register. For example, if the data is a
byte-sized "x" value, then COMP[31:24] = COMP[23:16] = COMP[15:8] = COMP[7:0] = "x". Likewise, if the
data is a halfword-size "y" value, then COMP[31:16] = COMP[15:0] = "y".
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Memory Map and Register Definition
19.32.3 MTB_DWT Comparator Mask Register
(MTBDWT_MASKn)
The MTBDWT_MASKn registers define the size of the ignore mask applied to the
reference address for address range matching by comparator n. Note the format of this
mask field is different than the MTB_MASTER[MASK].
Address: F000_1000h base + 24h offset + (16d × i), where i=0d to 1d
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
0
R
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
MASK
W
Reset
2
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
MTBDWT_MASKn field descriptions
Field
31–5
Reserved
4–0
MASK
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
MASK
The value of the ignore mask, 0-31 bits, is applied to address range matching. MASK = 0 is used to
include all bits of the address in the comparison, except if MASK = 0 and the comparator is configured to
watch instruction fetch addresses, address bit [0] is ignored by the hardware since all fetches must be at
least halfword aligned. For MASK != 0 and regardless of watch type, address bits [x-1:0] are ignored in the
address comparison.
Using a mask means the comparator matches on a range of addresses, defined by the unmasked most
significant bits of the address, bits [31:x]. The maximum MASK value is 24, producing a 16 Mbyte mask.
An attempted write of a MASK value > 24 is limited by the MTBDWT hardware to 24.
If MTBDWT_COMP0 is used as a data value comparator, then MTBDWT_MASK0 should be programmed
to zero.
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Chapter 19 Micro Trace Buffer (MTB)
19.32.4 MTB_DWT Comparator Function Register 0
(MTBDWT_FCT0)
The MTBDWT_FCTn registers control the operation of comparator n.
Address: F000_1000h base + 28h offset = F000_1028h
31
30
29
28
27
26
25
0
R
24
23
22
MATCHED
Bit
21
20
19
18
0
17
16
0
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
DATAVADDR0
DATAVSIZE
W
Reset
0
0
0
0
0
0
0
0
DATAVMATCH
0
R
0
FUNCTION
0
0
0
0
0
0
0
0
MTBDWT_FCT0 field descriptions
Field
31–25
Reserved
24
MATCHED
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Comparator match
If this read-only flag is asserted, it indicates the operation defined by the FUNCTION field occurred since
the last read of the register. Reading the register clears this bit.
Table continues on the next page...
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Memory Map and Register Definition
MTBDWT_FCT0 field descriptions (continued)
Field
Description
0
1
No match.
Match occurred.
23–20
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
19–16
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
15–12
DATAVADDR0
Data Value Address 0
Since the MTB_DWT implements two comparators, the DATAVADDR0 field is restricted to values {0,1}.
When the DATAVMATCH bit is asserted, this field defines the comparator number to use for linked
address comparison.
If MTBDWT_COMP0 is used as a data watchpoint and MTBDWT_COMP1 as an address watchpoint,
DATAVADDR0 must be set.
11–10
DATAVSIZE
Data Value Size
For data value matching, this field defines the size of the required data comparison.
00
01
10
11
9
Reserved
8
DATAVMATCH
This field is reserved.
This read-only field is reserved and always has the value 0.
Data Value Match
The assertion of this bit enables data value comparison. For this implementation, MTBDWT_COMP0
supports address or data value comparisons; MTBDWT_COMP1 only supports address comparisons.
0
1
7–4
Reserved
3–0
FUNCTION
Byte.
Halfword.
Word.
Reserved. Any attempts to use this value results in UNPREDICTABLE behavior.
Perform address comparison.
Perform data value comparison.
This field is reserved.
This read-only field is reserved and always has the value 0.
Function
Selects the action taken on a comparator match. If MTBDWT_COMP0 is used for a data value and
MTBDWT_COMP1 for an address value, then MTBDWT_FCT1[FUNCTION] must be set to zero. For this
configuration, MTBDWT_MASK1 can be set to a non-zero value, so the combined comparators match on
a range of addresses.
0000
0100
0101
0110
0111
others
Disabled.
Instruction fetch.
Data operand read.
Data operand write.
Data operand (read + write).
Reserved. Any attempts to use this value results in UNPREDICTABLE behavior.
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Chapter 19 Micro Trace Buffer (MTB)
19.32.5 MTB_DWT Comparator Function Register 1
(MTBDWT_FCT1)
The MTBDWT_FCTn registers control the operation of comparator n. Since the
MTB_DWT only supports data value comparisons on comparator 0, there are several
fields in the MTBDWT_FCT1 register that are RAZ/WI (bits 12, 11:10, 8).
Address: F000_1000h base + 38h offset = F000_1038h
31
30
29
28
27
26
25
0
R
24
23
22
21
20
MATCHED
Bit
19
18
17
16
0
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
R
FUNCTION
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
MTBDWT_FCT1 field descriptions
Field
31–25
Reserved
24
MATCHED
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Comparator match
If this read-only flag is asserted, it indicates the operation defined by the FUNCTION field occurred since
the last read of the register. Reading the register clears this bit.
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Memory Map and Register Definition
MTBDWT_FCT1 field descriptions (continued)
Field
Description
0
1
23–4
Reserved
No match.
Match occurred.
This field is reserved.
This read-only field is reserved and always has the value 0.
3–0
FUNCTION
Function
Selects the action taken on a comparator match. If MTBDWT_COMP0 is used for a data value and
MTBDWT_COMP1 for an address value, then MTBDWT_FCT1[FUNCTION] must be set to zero. For this
configuration, MTBDWT_MASK1 can be set to a non-zero value, so the combined comparators match on
a range of addresses.
0000
0100
0101
0110
0111
others
Disabled.
Instruction fetch.
Data operand read.
Data operand write.
Data operand (read + write).
Reserved. Any attempts to use this value results in UNPREDICTABLE behavior.
19.32.6 MTB_DWT Trace Buffer Control Register
(MTBDWT_TBCTRL)
The MTBDWT_TBCTRL register defines how the watchpoint comparisons control the
actual trace buffer operation.
Recall the MTB supports starting and stopping the program trace based on the watchpoint
comparisons signaled via TSTART and TSTOP. The watchpoint comparison signals are
enabled in the MTB's control logic by setting the appropriate enable bits,
MTB_MASTER[TSTARTEN, TSTOPEN]. In the event of simultaneous assertion of
both TSTART and TSTOP, TSTART takes priority.
Address: F000_1000h base + 200h offset = F000_1200h
Bit
31
30
29
28
27
26
25
24
23
22
NUMCOMP
R
21
20
19
18
17
16
0
0
0
0
0
0
0
W
Reset
0
0
1
0
0
0
0
0
0
0
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15
14
13
12
11
10
9
8
7
6
5
4
3
2
0
0
0
0
0
0
0
1
0
ACOMP0
Bit
ACOMP1
Chapter 19 Micro Trace Buffer (MTB)
0
0
0
R
W
Reset
0
0
0
0
0
0
0
MTBDWT_TBCTRL field descriptions
Field
31–28
NUMCOMP
Description
Number of Comparators
This read-only field specifies the number of comparators in the MTB_DWT. This implementation includes
two registers.
27–2
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
1
ACOMP1
Action based on Comparator 1 match
When the MTBDWT_FCT1[MATCHED] is set, it indicates MTBDWT_COMP1 address compare has
triggered and the trace buffer's recording state is changed.
0
1
0
ACOMP0
Trigger TSTOP based on the assertion of MTBDWT_FCT1[MATCHED].
Trigger TSTART based on the assertion of MTBDWT_FCT1[MATCHED].
Action based on Comparator 0 match
When the MTBDWT_FCT0[MATCHED] is set, it indicates MTBDWT_COMP0 address compare has
triggered and the trace buffer's recording state is changed. The assertion of MTBDWT_FCT0[MATCHED]
is caused by the following conditions:
• Address match in MTBDWT_COMP0 when MTBDWT_FCT0[DATAVMATCH] = 0
• Data match in MTBDWT_COMP0 when MTBDWT_FCT0[DATAVMATCH, DATAVADDR0] = {1,0}
• Data match in MTBDWT_COMP0 and address match in MTBDWT_COMP1 when
MTBDWT_FCT0[DATAVMATCH, DATAVADDR0] = {1,1}
0
1
Trigger TSTOP based on the assertion of MTBDWT_FCT0[MATCHED].
Trigger TSTART based on the assertion of MTBDWT_FCT0[MATCHED].
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Memory Map and Register Definition
19.32.7 Device Configuration Register (MTBDWT_DEVICECFG)
This register indicates the device configuration. It is hardwired to specific values used
during the auto-discovery process by an external debug agent.
Address: F000_1000h base + FC8h offset = F000_1FC8h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
DEVICECFG
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
MTBDWT_DEVICECFG field descriptions
Field
Description
31–0
DEVICECFG
Hardwired to 0x0000_0000.
19.32.8 Device Type Identifier Register (MTBDWT_DEVICETYPID)
This register indicates the device type ID. It is hardwired to specific values used during
the auto-discovery process by an external debug agent.
Address: F000_1000h base + FCCh offset = F000_1FCCh
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
DEVICETYPID
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
MTBDWT_DEVICETYPID field descriptions
Field
31–0
DEVICETYPID
Description
Hardwired to 0x0000_0004.
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Chapter 19 Micro Trace Buffer (MTB)
19.32.9 Peripheral ID Register (MTBDWT_PERIPHIDn)
These registers indicate the peripheral IDs. They are hardwired to specific values used
during the auto-discovery process by an external debug agent.
Address: F000_1000h base + FD0h offset + (4d × i), where i=0d to 7d
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
PERIPHID
R
W
Reset
x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x*
* Notes:
• See field descriptions for the reset values. x = Undefined at reset.
MTBDWT_PERIPHIDn field descriptions
Field
Description
31–0
PERIPHID
Peripheral ID1 is hardwired to 0x0000_00E0; ID2 to 0x0000_0008; and all the others to 0x0000_0000.
19.32.10 Component ID Register (MTBDWT_COMPIDn)
These registers indicate the component IDs. They are hardwired to specific values used
during the auto-discovery process by an external debug agent.
Address: F000_1000h base + FF0h offset + (4d × i), where i=0d to 3d
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
COMPID
R
W
Reset
x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x*
* Notes:
• See field descriptions for the reset values.x = Undefined at reset.
MTBDWT_COMPIDn field descriptions
Field
31–0
COMPID
Description
Component ID
Component ID0 is hardwired to 0x0000_000D; ID1 to 0x0000_0090; ID2 to 0x0000_0005; ID3 to
0x0000_00B1.
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Memory Map and Register Definition
19.3.3 System ROM Memory Map
The System ROM Table registers are also mapped into a sparsely-populated 4 KB
address space.
For core configurations like that supported by Cortex-M0+, ARM recommends that a
debugger identifies and connects to the debug components using the CoreSight debug
infrastructure.
ARM recommends that a debugger follows the flow as shown in the following figure to
discover the components in the CoreSight debug infrastructure. In this case a debugger
reads the peripheral and component ID registers for each CoreSight component in the
CoreSight system.
Figure 19-56. CoreSight discovery process
ROM memory map
Absolute
address
(hex)
Register name
Width
Access
(in bits)
Reset value
Section/
page
F000_2000
Entry (ROM_ENTRY0)
32
R
See section
19.33.1/297
F000_2004
Entry (ROM_ENTRY1)
32
R
See section
19.33.1/297
F000_2008
Entry (ROM_ENTRY2)
32
R
See section
19.33.1/297
F000_200C End of Table Marker Register (ROM_TABLEMARK)
32
R
0000_0000h
19.33.2/298
F000_2FCC System Access Register (ROM_SYSACCESS)
32
R
0000_0001h
19.33.3/298
F000_2FD0 Peripheral ID Register (ROM_PERIPHID4)
32
R
See section
19.33.4/299
F000_2FD4 Peripheral ID Register (ROM_PERIPHID5)
32
R
See section
19.33.4/299
F000_2FD8 Peripheral ID Register (ROM_PERIPHID6)
32
R
See section
19.33.4/299
Table continues on the next page...
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Chapter 19 Micro Trace Buffer (MTB)
ROM memory map (continued)
Absolute
address
(hex)
Width
Access
(in bits)
Register name
Reset value
Section/
page
F000_2FDC Peripheral ID Register (ROM_PERIPHID7)
32
R
See section
19.33.4/299
F000_2FE0 Peripheral ID Register (ROM_PERIPHID0)
32
R
See section
19.33.4/299
F000_2FE4 Peripheral ID Register (ROM_PERIPHID1)
32
R
See section
19.33.4/299
F000_2FE8 Peripheral ID Register (ROM_PERIPHID2)
32
R
See section
19.33.4/299
F000_2FEC Peripheral ID Register (ROM_PERIPHID3)
32
R
See section
19.33.4/299
F000_2FF0
Component ID Register (ROM_COMPID0)
32
R
See section
19.33.5/299
F000_2FF4
Component ID Register (ROM_COMPID1)
32
R
See section
19.33.5/299
F000_2FF8
Component ID Register (ROM_COMPID2)
32
R
See section
19.33.5/299
F000_2FFC Component ID Register (ROM_COMPID3)
32
R
See section
19.33.5/299
19.33.1 Entry (ROM_ENTRYn)
The System ROM Table begins with "n" relative 32-bit addresses, one for each debug
component present in the device and terminating with an all-zero value signaling the end
of the table at the "n+1"-th value.
It is hardwired to specific values used during the auto-discovery process by an external
debug agent.
Address: F000_2000h base + 0h offset + (4d × i), where i=0d to 2d
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
ENTRY
R
W
Reset
x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x*
* Notes:
• See field descriptions for reset values.x = Undefined at reset.
ROM_ENTRYn field descriptions
Field
31–0
ENTRY
Description
ENTRY
Entry 0 (MTB) is hardwired to 0xFFFF_E003; Entry 1 (MTBDWT) to 0xFFFF_F003; Entry 2 (CM0+ ROM
Table) to 0xF00F_D003.
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19.33.2 End of Table Marker Register (ROM_TABLEMARK)
This register indicates end of table marker. It is hardwired to specific values used during
the auto-discovery process by an external debug agent.
Address: F000_2000h base + Ch offset = F000_200Ch
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
MARK
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
ROM_TABLEMARK field descriptions
Field
Description
31–0
MARK
Hardwired to 0x0000_0000
19.33.3 System Access Register (ROM_SYSACCESS)
This register indicates system access. It is hardwired to specific values used during the
auto-discovery process by an external debug agent.
Address: F000_2000h base + FCCh offset = F000_2FCCh
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
SYSACCESS
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
ROM_SYSACCESS field descriptions
Field
31–0
SYSACCESS
Description
Hardwired to 0x0000_0001
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Chapter 19 Micro Trace Buffer (MTB)
19.33.4 Peripheral ID Register (ROM_PERIPHIDn)
These registers indicate the peripheral IDs. They are hardwired to specific values used
during the auto-discovery process by an external debug agent.
Address: F000_2000h base + FD0h offset + (4d × i), where i=0d to 7d
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
PERIPHID
R
W
Reset
x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x*
* Notes:
• See field descriptions for reset values.x = Undefined at reset.
ROM_PERIPHIDn field descriptions
Field
Description
31–0
PERIPHID
Peripheral ID1 is hardwired to 0x0000_00E0; ID2 to 0x0000_0008; and all the others to 0x0000_0000.
19.33.5 Component ID Register (ROM_COMPIDn)
These registers indicate the component IDs. They are hardwired to specific values used
during the auto-discovery process by an external debug agent.
Address: F000_2000h base + FF0h offset + (4d × i), where i=0d to 3d
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
COMPID
R
W
Reset
x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x* x*
* Notes:
• See field descriptions for reset values.x = Undefined at reset.
ROM_COMPIDn field descriptions
Field
31–0
COMPID
Description
Component ID
Component ID0 is hardwired to 0x0000_000D; ID1 to 0x0000_0010; ID2 to 0x0000_0005; ID3 to
0x0000_00B1.
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Chapter 20
Crossbar Switch Lite (AXBS-Lite)
20.1 Introduction
NOTE
For the chip-specific implementation details of this module's
instances see the chip configuration information.
This chapter provides information on the layout, configuration, and programming of the
crossbar switch. The crossbar switch connects bus masters and bus slaves using a
crossbar switch structure. This structure allows up to four bus masters to access different
bus slaves simultaneously, while providing arbitration among the bus masters when they
access the same slave.
20.1.1 Features
The crossbar switch includes these features:
• Symmetric crossbar bus switch implementation
• Allows concurrent accesses from different masters to different slaves
• 32-bit data bus
• Operation at a 1-to-1 clock frequency with the bus masters
• Programmable configuration for fixed-priority or round-robin slave port arbitration
20.2 Memory Map / Register Definition
This crossbar switch is designed for minimal gate count. It, therefore, has no memorymapped configuration registers.
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Functional Description
20.3 Functional Description
20.3.1 General operation
When a master accesses the crossbar switch the access is immediately taken. If the
targeted slave port of the access is available, then the access is immediately presented on
the slave port. Single-clock or zero-wait-state accesses are possible through the crossbar.
If the targeted slave port of the access is busy or parked on a different master port, the
requesting master simply sees wait states inserted until the targeted slave port can service
the master's request. The latency in servicing the request depends on each master's
priority level and the responding slave's access time.
Because the crossbar switch appears to be just another slave to the master device, the
master device has no knowledge of whether it actually owns the slave port it is targeting.
While the master does not have control of the slave port it is targeting, it simply waits.
A master is given control of the targeted slave port only after a previous access to a
different slave port completes, regardless of its priority on the newly targeted slave port.
This prevents deadlock from occurring when:
• A higher priority master has:
• An outstanding request to one slave port that has a long response time and
• A pending access to a different slave port, and
• A lower priority master is also making a request to the same slave port as the pending
access of the higher priority master.
After the master has control of the slave port it is targeting, the master remains in control
of the slave port until it relinquishes the slave port by running an IDLE cycle or by
targeting a different slave port for its next access.
The master can also lose control of the slave port if another higher-priority master makes
a request to the slave port.
The crossbar terminates all master IDLE transfers, as opposed to allowing the termination
to come from one of the slave buses. Additionally, when no master is requesting access to
a slave port, the crossbar drives IDLE transfers onto the slave bus, even though a default
master may be granted access to the slave port.
When a slave bus is being idled by the crossbar, it remains parked with the last master to
use the slave port. This is done to save the initial clock of arbitration delay that otherwise
would be seen if the master had to arbitrate to gain control of the slave port.
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Chapter 20 Crossbar Switch Lite (AXBS-Lite)
20.3.2 Arbitration
The crossbar switch supports two arbitration algorithms:
• Fixed priority
• Round robin
The selection of the global slave port arbitration is controlled by MCM_PLACR[ARB].
For fixed priority, set ARB to 0. For round robin, set ARB to 1. This arbitration setting
applies to all slave ports.
20.3.2.1 Arbitration During Undefined Length Bursts
All lengths of burst accesses lock out arbitration until the last beat of the burst.
20.3.2.2 Fixed-priority operation
When operating in fixed-priority mode, each master is assigned a unique priority level
with the highest numbered master having the highest priority (master 1 has lower priority
than master 3). If two masters request access to the same slave port, the master with the
highest priority gains control over the slave port.
NOTE
In this arbitration mode, a higher-priority master can
monopolize a slave port, preventing accesses from any lowerpriority master to the port.
When a master makes a request to a slave port, the slave port checks whether the new
requesting master's priority level is higher than that of the master that currently has
control over the slave port, unless the slave port is in a parked state. The slave port
performs an arbitration check at every clock edge to ensure that the proper master, if any,
has control of the slave port.
The following table describes possible scenarios based on the requesting master port:
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Initialization/application information
Table 20-1. How AXBS grants control of a slave port to a master
When
Then AXBS grants control to the requesting master
Both of the following are true:
At the next clock edge
• The current master is not running a transfer.
• The new requesting master's priority level is higher than
that of the current master.
The requesting master's priority level is lower than the current At the conclusion of one of the following cycles:
master.
• An IDLE cycle
• A non-IDLE cycle to a location other than the current
slave port
20.3.2.3 Round-robin priority operation
When operating in round-robin mode, each master is assigned a relative priority based on
the master port number. This relative priority is compared to the master port number (ID)
of the last master to perform a transfer on the slave bus. The highest priority requesting
master becomes owner of the slave bus at the next transfer boundary. Priority is based on
how far ahead the ID of the requesting master is to the ID of the last master.
After granted access to a slave port, a master may perform as many transfers as desired to
that port until another master makes a request to the same slave port. The next master in
line is granted access to the slave port at the next transfer boundary, or possibly on the
next clock cycle if the current master has no pending access request.
As an example of arbitration in round-robin mode, assume the crossbar is implemented
with master ports 0, 1, 4, and 5. If the last master of the slave port was master 1, and
master 0, 4, and 5 make simultaneous requests, they are serviced in the order: 4 then 5
then 0.
The round-robin arbitration mode generally provides a more fair allocation of the
available slave-port bandwidth (compared to fixed priority) as the fixed master priority
does not affect the master selection.
20.4 Initialization/application information
No initialization is required for the crossbar switch. See the AXBS section of the
configuration chapter for the reset state of the arbitration scheme.
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Chapter 21
Peripheral Bridge (AIPS-Lite)
21.1 Introduction
NOTE
For the chip-specific implementation details of this module's
instances see the chip configuration information.
The peripheral bridge converts the crossbar switch interface to an interface that can
access most of the slave peripherals on this chip.
The peripheral bridge supports up to 128 peripherals, each with a 4K-byte address space.
(Not all peripheral slots might be used. See the chip configuration chapter and memory
map chapter for details on slot assignment.) The bridge includes separate clock enable
inputs for each of the slots to accommodate slower peripherals.
21.1.1 Features
Key features of the peripheral bridge are:
• Supports peripheral slots with 8-, 16-, and 32-bit datapath width
• Dedicated clock enables for independently configurable peripherals allow each on- or
off-platform peripheral to operate at any integer-divisible speed less than or equal to
the system clock frequency.
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Functional description
21.1.2 General operation
The slave devices connected to the peripheral bridge are modules which contain a
programming model of control and status registers. The system masters read and write
these registers through the peripheral bridge. The peripheral bridge performs a bus
protocol conversion of the master transactions and generates the following as inputs to
the peripherals:
• Module enables
• Module addresses
• Transfer attributes
• Byte enables
• Write data
The peripheral bridge selects and captures read data from the peripheral interface and
returns it to the crossbar switch.
The register maps of the peripherals are located on 4-KB boundaries. Each peripheral is
allocated one or more 4-KB block(s) of the memory map.
The AIPS-Lite module uses the accessed peripheral's data width to perform proper data
byte lane routing; bus decomposition (bus sizing) is performed when the access size is
larger than the peripheral's data width.
21.2 Functional description
The peripheral bridge functions as a bus protocol translator between the crossbar switch
and the slave peripheral bus.
The peripheral bridge manages all transactions destined for the attached slave devices and
generates select signals for modules on the peripheral bus by decoding accesses within
the attached address space.
By default, reads and writes on the crossbar side of the peripheral bridge take two dataphase cycles. On the IPS side, accesses complete in one cycle. If wait states are inserted
by the slave peripheral, access time will be extended accordingly.
21.2.1 Access support
All combinations of access size and peripheral data port width are supported. An access
that is larger than the target peripheral's data width will be decomposed to multiple,
smaller accesses. Bus decomposition is terminated by a transfer error caused by an access
to an empty register area.
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Chapter 22
Direct Memory Access Multiplexer (DMAMUX)
22.1 Introduction
NOTE
For the chip-specific implementation details of this module's
instances see the chip configuration information.
22.1.1 Overview
The direct memory access multiplexer (DMAMUX) routes DMA sources, called slots, to
any of the 4 DMA channels. This process is illustrated in the following figure.
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Introduction
DMAMUX
Source #1
DMA channel #0
DMA channel #1
Source #2
Source #3
Source #x
Always #1
Always #y
Trigger #1
DMA channel #n
Trigger #z
Figure 22-1. DMAMUX block diagram
22.1.2 Features
The DMAMUX module provides these features:
• 6353 peripheral slots and 6 always-on slots can be routed to 4 channels.
• 4 independently selectable DMA channel routers.
• The first 2 channels additionally provide a trigger functionality.
• Each channel router can be assigned to one of the 6353 possible peripheral DMA
slots or to one of the 6 always-on slots.
22.1.3 Modes of operation
The following operating modes are available:
• Disabled mode
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In this mode, the DMA channel is disabled. Because disabling and enabling of DMA
channels is done primarily via the DMA configuration registers, this mode is used
mainly as the reset state for a DMA channel in the DMA channel MUX. It may also
be used to temporarily suspend a DMA channel while reconfiguration of the system
takes place, for example, changing the period of a DMA trigger.
• Normal mode
In this mode, a DMA source is routed directly to the specified DMA channel. The
operation of the DMAMUX in this mode is completely transparent to the system.
• Periodic Trigger mode
In this mode, a DMA source may only request a DMA transfer, such as when a
transmit buffer becomes empty or a receive buffer becomes full, periodically.
Configuration of the period is done in the registers of the periodic interrupt timer
(PIT). This mode is available only for channels 0–1.
22.2 External signal description
The DMAMUX has no external pins.
22.3 Memory map/register definition
This section provides a detailed description of all memory-mapped registers in the
DMAMUX.
DMAMUX memory map
Absolute
address
(hex)
Register name
Width
Access
(in bits)
Reset value
Section/
page
4002_1000
Channel Configuration register (DMAMUX0_CHCFG0)
8
R/W
00h
22.3.1/309
4002_1001
Channel Configuration register (DMAMUX0_CHCFG1)
8
R/W
00h
22.3.1/309
4002_1002
Channel Configuration register (DMAMUX0_CHCFG2)
8
R/W
00h
22.3.1/309
4002_1003
Channel Configuration register (DMAMUX0_CHCFG3)
8
R/W
00h
22.3.1/309
22.3.1 Channel Configuration register (DMAMUXx_CHCFGn)
Each of the DMA channels can be independently enabled/disabled and associated with
one of the DMA slots (peripheral slots or always-on slots) in the system.
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Functional description
NOTE
Setting multiple CHCFG registers with the same Source value
will result in unpredictable behavior.
NOTE
Before changing the trigger or source settings a DMA channel
must be disabled via the CHCFGn[ENBL] bit.
Address: 4002_1000h base + 0h offset + (1d × i), where i=0d to 3d
Bit
Read
Write
Reset
0
1
ENBL
TRIG
2
0
0
3
4
5
6
7
0
0
0
SOURCE
0
0
0
DMAMUXx_CHCFGn field descriptions
Field
0
ENBL
Description
DMA Channel Enable
Enables the DMA channel.
0
1
1
TRIG
DMA Channel Trigger Enable
Enables the periodic trigger capability for the triggered DMA channel.
0
1
2–7
SOURCE
DMA channel is disabled. This mode is primarily used during configuration of the DMA Mux. The DMA
has separate channel enables/disables, which should be used to disable or re-configure a DMA
channel.
DMA channel is enabled
Triggering is disabled. If triggering is disabled, and the ENBL bit is set, the DMA Channel will simply
route the specified source to the DMA channel. (Normal mode)
Triggering is enabled. If triggering is enabled, and the ENBL bit is set, the DMAMUX is in Periodic
Trigger mode.
DMA Channel Source (Slot)
Specifies which DMA source, if any, is routed to a particular DMA channel. See your device's chip
configuration details for further details about the peripherals and their slot numbers.
22.4 Functional description
The primary purpose of the DMAMUX is to provide flexibility in the system's use of the
available DMA channels. As such, configuration of the DMAMUX is intended to be a
static procedure done during execution of the system boot code. However, if the
procedure outlined in Enabling and configuring sources is followed, the configuration of
the DMAMUX may be changed during the normal operation of the system.
Functionally, the DMAMUX channels may be divided into two classes:
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• Channels which implement the normal routing functionality plus periodic triggering
capability
• Channels which implement only the normal routing functionality
22.4.1 DMA channels with periodic triggering capability
Besides the normal routing functionality, the first 2 channels of the DMAMUX provide a
special periodic triggering capability that can be used to provide an automatic mechanism
to transmit bytes, frames, or packets at fixed intervals without the need for processor
intervention. The trigger is generated by the periodic interrupt timer (PIT); as such, the
configuration of the periodic triggering interval is done via configuration registers in the
PIT. See the section on periodic interrupt timer for more information on this topic.
Note
Because of the dynamic nature of the system (due to DMA
channel priorities, bus arbitration, interrupt service routine
lengths, etc.), the number of clock cycles between a trigger and
the actual DMA transfer cannot be guaranteed.
Source #1
Source #2
Source #3
Trigger #1
Trigger #2
DMA channel #0
DMA channel #1
Source #x
Trigger #4
Always #1
DMA channel #3
Always #y
Figure 22-12. DMAMUX triggered channels
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Functional description
The DMA channel triggering capability allows the system to schedule regular DMA
transfers, usually on the transmit side of certain peripherals, without the intervention of
the processor. This trigger works by gating the request from the peripheral to the DMA
until a trigger event has been seen. This is illustrated in the following figure.
Peripheral request
Trigger
DMA request
Figure 22-13. DMAMUX channel triggering: normal operation
After the DMA request has been serviced, the peripheral will negate its request,
effectively resetting the gating mechanism until the peripheral re-asserts its request AND
the next trigger event is seen. This means that if a trigger is seen, but the peripheral is not
requesting a transfer, then that trigger will be ignored. This situation is illustrated in the
following figure.
Peripheral request
Trigger
DMA request
Figure 22-14. DMAMUX channel triggering: ignored trigger
This triggering capability may be used with any peripheral that supports DMA transfers,
and is most useful for two types of situations:
• Periodically polling external devices on a particular bus
As an example, the transmit side of an SPI is assigned to a DMA channel with a
trigger, as described above. After it has been set up, the SPI will request DMA
transfers, presumably from memory, as long as its transmit buffer is empty. By using
a trigger on this channel, the SPI transfers can be automatically performed every 5μs
(as an example). On the receive side of the SPI, the SPI and DMA can be configured
to transfer receive data into memory, effectively implementing a method to
periodically read data from external devices and transfer the results into memory
without processor intervention.
• Using the GPIO ports to drive or sample waveforms
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By configuring the DMA to transfer data to one or more GPIO ports, it is possible to
create complex waveforms using tabular data stored in on-chip memory. Conversely,
using the DMA to periodically transfer data from one or more GPIO ports, it is
possible to sample complex waveforms and store the results in tabular form in onchip memory.
A more detailed description of the capability of each trigger, including resolution, range
of values, and so on, may be found in the periodic interrupt timer section.
22.4.2 DMA channels with no triggering capability
The other channels of the DMAMUX provide the normal routing functionality as
described in Modes of operation.
22.4.3 Always-enabled DMA sources
In addition to the peripherals that can be used as DMA sources, there are 6 additional
DMA sources that are always enabled. Unlike the peripheral DMA sources, where the
peripheral controls the flow of data during DMA transfers, the sources that are always
enabled provide no such "throttling" of the data transfers. These sources are most useful
in the following cases:
• Performing DMA transfers to/from GPIO—Moving data from/to one or more GPIO
pins, either unthrottled (that is as fast as possible), or periodically (using the DMA
triggering capability).
• Performing DMA transfers from memory to memory—Moving data from memory to
memory, typically as fast as possible, sometimes with software activation.
• Performing DMA transfers from memory to the external bus, or vice-versa—Similar
to memory to memory transfers, this is typically done as quickly as possible.
• Any DMA transfer that requires software activation—Any DMA transfer that should
be explicitly started by software.
In cases where software should initiate the start of a DMA transfer, an always-enabled
DMA source can be used to provide maximum flexibility. When activating a DMA
channel via software, subsequent executions of the minor loop require that a new start
event be sent. This can either be a new software activation, or a transfer request from the
DMA channel MUX. The options for doing this are:
• Transfer all data in a single minor loop.
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Initialization/application information
By configuring the DMA to transfer all of the data in a single minor loop (that is,
major loop counter = 1), no reactivation of the channel is necessary. The
disadvantage to this option is the reduced granularity in determining the load that the
DMA transfer will impose on the system. For this option, the DMA channel must be
disabled in the DMA channel MUX.
• Use explicit software reactivation.
In this option, the DMA is configured to transfer the data using both minor and major
loops, but the processor is required to reactivate the channel by writing to the DMA
registers after every minor loop. For this option, the DMA channel must be disabled
in the DMA channel MUX.
• Use an always-enabled DMA source.
In this option, the DMA is configured to transfer the data using both minor and major
loops, and the DMA channel MUX does the channel reactivation. For this option, the
DMA channel should be enabled and pointing to an "always enabled" source. Note
that the reactivation of the channel can be continuous (DMA triggering is disabled)
or can use the DMA triggering capability. In this manner, it is possible to execute
periodic transfers of packets of data from one source to another, without processor
intervention.
22.5 Initialization/application information
This section provides instructions for initializing the DMA channel MUX.
22.5.1 Reset
The reset state of each individual bit is shown in Memory map/register definition. In
summary, after reset, all channels are disabled and must be explicitly enabled before use.
22.5.2 Enabling and configuring sources
To enable a source with periodic triggering:
1. Determine with which DMA channel the source will be associated. Note that only the
first 2 DMA channels have periodic triggering capability.
2. Clear the CHCFG[ENBL] and CHCFG[TRIG] fields of the DMA channel.
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3. Ensure that the DMA channel is properly configured in the DMA. The DMA channel
may be enabled at this point.
4. Configure the corresponding timer.
5. Select the source to be routed to the DMA channel. Write to the corresponding
CHCFG register, ensuring that the CHCFG[ENBL] and CHCFG[TRIG] fields are
set.
NOTE
The following is an example. See chip configuration section for
the number of this device's DMA channels that have triggering
capability.
To configure source #5 transmit for use with DMA channel 2, with periodic triggering
capability:
1. Write 0x00 to CHCFG2 (base address + 0x02).
2. Configure channel 2 in the DMA, including enabling the channel.
3. Configure a timer for the desired trigger interval.
4. Write 0xC5 to CHCFG2 (base address + 0x02).
The following code example illustrates steps 1 and 4 above:
In File registers.h:
#define DMAMUX_BASE_ADDR
0xFC084000/* Example only
/* Following example assumes char is 8-bits */
volatile unsigned char *CHCONFIG0 = (volatile unsigned
volatile unsigned char *CHCONFIG1 = (volatile unsigned
volatile unsigned char *CHCONFIG2 = (volatile unsigned
volatile unsigned char *CHCONFIG3 = (volatile unsigned
volatile unsigned char *CHCONFIG4 = (volatile unsigned
volatile unsigned char *CHCONFIG5 = (volatile unsigned
volatile unsigned char *CHCONFIG6 = (volatile unsigned
volatile unsigned char *CHCONFIG7 = (volatile unsigned
volatile unsigned char *CHCONFIG8 = (volatile unsigned
volatile unsigned char *CHCONFIG9 = (volatile unsigned
volatile unsigned char *CHCONFIG10= (volatile unsigned
volatile unsigned char *CHCONFIG11= (volatile unsigned
volatile unsigned char *CHCONFIG12= (volatile unsigned
volatile unsigned char *CHCONFIG13= (volatile unsigned
volatile unsigned char *CHCONFIG14= (volatile unsigned
volatile unsigned char *CHCONFIG15= (volatile unsigned
! */
char
char
char
char
char
char
char
char
char
char
char
char
char
char
char
char
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
(DMAMUX_BASE_ADDR+0x0000);
(DMAMUX_BASE_ADDR+0x0001);
(DMAMUX_BASE_ADDR+0x0002);
(DMAMUX_BASE_ADDR+0x0003);
(DMAMUX_BASE_ADDR+0x0004);
(DMAMUX_BASE_ADDR+0x0005);
(DMAMUX_BASE_ADDR+0x0006);
(DMAMUX_BASE_ADDR+0x0007);
(DMAMUX_BASE_ADDR+0x0008);
(DMAMUX_BASE_ADDR+0x0009);
(DMAMUX_BASE_ADDR+0x000A);
(DMAMUX_BASE_ADDR+0x000B);
(DMAMUX_BASE_ADDR+0x000C);
(DMAMUX_BASE_ADDR+0x000D);
(DMAMUX_BASE_ADDR+0x000E);
(DMAMUX_BASE_ADDR+0x000F);
In File main.c:
#include "registers.h"
:
:
*CHCONFIG2 = 0x00;
*CHCONFIG2 = 0xC5;
To enable a source without periodic triggering:
1. Determine with which DMA channel the source will be associated. Note that only the
first 2 DMA channels have periodic triggering capability.
2. Clear the CHCFG[ENBL] and CHCFG[TRIG] fields of the DMA channel.
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Initialization/application information
3. Ensure that the DMA channel is properly configured in the DMA. The DMA channel
may be enabled at this point.
4. Select the source to be routed to the DMA channel. Write to the corresponding
CHCFG register, ensuring that CHCFG[ENBL] is set while CHCFG[TRIG] is
cleared.
NOTE
The following is an example. See chip configuration section for
the number of this device's DMA channels that have triggering
capability.
To configure source #5 transmit for use with DMA channel 2, with no periodic triggering
capability:
1. Write 0x00 to CHCFG2 (base address + 0x02).
2. Configure channel 2 in the DMA, including enabling the channel.
3. Write 0x85 to CHCFG2 (base address + 0x02).
The following code example illustrates steps 1 and 3 above:
In File registers.h:
#define DMAMUX_BASE_ADDR
0xFC084000/* Example only
/* Following example assumes char is 8-bits */
volatile unsigned char *CHCONFIG0 = (volatile unsigned
volatile unsigned char *CHCONFIG1 = (volatile unsigned
volatile unsigned char *CHCONFIG2 = (volatile unsigned
volatile unsigned char *CHCONFIG3 = (volatile unsigned
volatile unsigned char *CHCONFIG4 = (volatile unsigned
volatile unsigned char *CHCONFIG5 = (volatile unsigned
volatile unsigned char *CHCONFIG6 = (volatile unsigned
volatile unsigned char *CHCONFIG7 = (volatile unsigned
volatile unsigned char *CHCONFIG8 = (volatile unsigned
volatile unsigned char *CHCONFIG9 = (volatile unsigned
volatile unsigned char *CHCONFIG10= (volatile unsigned
volatile unsigned char *CHCONFIG11= (volatile unsigned
volatile unsigned char *CHCONFIG12= (volatile unsigned
volatile unsigned char *CHCONFIG13= (volatile unsigned
volatile unsigned char *CHCONFIG14= (volatile unsigned
volatile unsigned char *CHCONFIG15= (volatile unsigned
! */
char
char
char
char
char
char
char
char
char
char
char
char
char
char
char
char
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
(DMAMUX_BASE_ADDR+0x0000);
(DMAMUX_BASE_ADDR+0x0001);
(DMAMUX_BASE_ADDR+0x0002);
(DMAMUX_BASE_ADDR+0x0003);
(DMAMUX_BASE_ADDR+0x0004);
(DMAMUX_BASE_ADDR+0x0005);
(DMAMUX_BASE_ADDR+0x0006);
(DMAMUX_BASE_ADDR+0x0007);
(DMAMUX_BASE_ADDR+0x0008);
(DMAMUX_BASE_ADDR+0x0009);
(DMAMUX_BASE_ADDR+0x000A);
(DMAMUX_BASE_ADDR+0x000B);
(DMAMUX_BASE_ADDR+0x000C);
(DMAMUX_BASE_ADDR+0x000D);
(DMAMUX_BASE_ADDR+0x000E);
(DMAMUX_BASE_ADDR+0x000F);
In File main.c:
#include "registers.h"
:
:
*CHCONFIG2 = 0x00;
*CHCONFIG2 = 0x85;
To disable a source:
A particular DMA source may be disabled by not writing the corresponding source value
into any of the CHCFG registers. Additionally, some module-specific configuration may
be necessary. See the appropriate section for more details.
To switch the source of a DMA channel:
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1. Disable the DMA channel in the DMA and re-configure the channel for the new
source.
2. Clear the CHCFG[ENBL] and CHCFG[TRIG] bits of the DMA channel.
3. Select the source to be routed to the DMA channel. Write to the corresponding
CHCFG register, ensuring that the CHCFG[ENBL] and CHCFG[TRIG] fields are
set.
To switch DMA channel 8 from source #5 transmit to source #7 transmit:
1. In the DMA configuration registers, disable DMA channel 8 and reconfigure it to
handle the transfers to peripheral slot 7. This example assumes channel 8 doesn't
have triggering capability.
2. Write 0x00 to CHCFG8 (base address + 0x08).
3. Write 0x87 to CHCFG8 (base address + 0x08). (In this example, setting
CHCFG[TRIG] would have no effect, due to the assumption that channel 8 does not
support the periodic triggering functionality).
The following code example illustrates steps 2 and 3 above:
In File registers.h:
#define DMAMUX_BASE_ADDR
0xFC084000/* Example only
/* Following example assumes char is 8-bits */
volatile unsigned char *CHCONFIG0 = (volatile unsigned
volatile unsigned char *CHCONFIG1 = (volatile unsigned
volatile unsigned char *CHCONFIG2 = (volatile unsigned
volatile unsigned char *CHCONFIG3 = (volatile unsigned
volatile unsigned char *CHCONFIG4 = (volatile unsigned
volatile unsigned char *CHCONFIG5 = (volatile unsigned
volatile unsigned char *CHCONFIG6 = (volatile unsigned
volatile unsigned char *CHCONFIG7 = (volatile unsigned
volatile unsigned char *CHCONFIG8 = (volatile unsigned
volatile unsigned char *CHCONFIG9 = (volatile unsigned
volatile unsigned char *CHCONFIG10= (volatile unsigned
volatile unsigned char *CHCONFIG11= (volatile unsigned
volatile unsigned char *CHCONFIG12= (volatile unsigned
volatile unsigned char *CHCONFIG13= (volatile unsigned
volatile unsigned char *CHCONFIG14= (volatile unsigned
volatile unsigned char *CHCONFIG15= (volatile unsigned
! */
char
char
char
char
char
char
char
char
char
char
char
char
char
char
char
char
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
(DMAMUX_BASE_ADDR+0x0000);
(DMAMUX_BASE_ADDR+0x0001);
(DMAMUX_BASE_ADDR+0x0002);
(DMAMUX_BASE_ADDR+0x0003);
(DMAMUX_BASE_ADDR+0x0004);
(DMAMUX_BASE_ADDR+0x0005);
(DMAMUX_BASE_ADDR+0x0006);
(DMAMUX_BASE_ADDR+0x0007);
(DMAMUX_BASE_ADDR+0x0008);
(DMAMUX_BASE_ADDR+0x0009);
(DMAMUX_BASE_ADDR+0x000A);
(DMAMUX_BASE_ADDR+0x000B);
(DMAMUX_BASE_ADDR+0x000C);
(DMAMUX_BASE_ADDR+0x000D);
(DMAMUX_BASE_ADDR+0x000E);
(DMAMUX_BASE_ADDR+0x000F);
In File main.c:
#include "registers.h"
:
:
*CHCONFIG8 = 0x00;
*CHCONFIG8 = 0x87;
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Chapter 23
DMA Controller Module
23.1 Introduction
NOTE
For the chip-specific implementation details of this module's
instances see the chip configuration information.
This chapter describes the direct memory access (DMA) controller module. It provides an
overview of the module and describes in detail its signals and programming model. The
latter sections of this chapter describe operations, features, and supported data transfer
modes in detail.
Note
The designation n is used throughout this section to refer to
registers or signals associated with one of the four identical
DMA channels: DMA0, DMA1, DMA2, or DMA3.
23.1.1 Overview
The DMA controller module enables fast transfers of data, providing an efficient way to
move blocks of data with minimal processor interaction. The DMA module, shown in the
following figure, has four channels that allow 8-bit, 16-bit, or 32-bit data transfers. Each
channel has a dedicated source address register (SARn), destination address register
(DARn), status register (DSRn), byte count register (BCRn), and control register
(DCRn). Collectively, the combined program-visible registers associated with each
channel define a transfer control descriptor (TCD). All transfers are dual address, moving
data from a source memory location to a destination memory location with the module
operating as a 32-bit bus master connected to the system bus. The programming model is
accessed through a 32-bit connection with the slave peripheral bus. DMA data transfers
may be explicitly initiated by software or by peripheral hardware requests.
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Introduction
The following figure is a simplified block diagram of the 4-channel DMA controller.
DREQ3
DREQ0
DREQ1
DREQ2
DACK0
DACK1
DACK2
DACK3
Channel 0 Channel 1 Channel 2 Channel 3
Slave
Peripheral Bus
SAR0
SAR1
SAR2
SAR3
DAR0
DAR1
DAR2
DAR3
DSR0
DSR1
DSR2
DSR3
BCR0
BCR1
BCR2
BCR3
DCR0
DCR1
DCR2
DCR3
Channel
Requests
Channel
Attributes
Channel
Enables
System Bus Address
MUX
MUX
Control
SysBus Interface
Data Path
Read Data Bus
Interrupts
System Bus Size
Current Master Attributes
Arbitraton/
Control
Data Path
Control
SysBus Interface
Addr + Attr
Registered Addr
Phase Bus Signals
Write Data Bus
Figure 23-1. 4-Channel DMA Block Diagram
The terms peripheral request and DREQ refer to a DMA request from one of the on-chip
peripherals or package pins. The DMA provides hardware handshake signals: either a
DMA acknowledge (DACK) or a done indicator back to the peripheral.
23.1.2 Features
The DMA controller module features:
• Four independently programmable DMA controller channels
• Dual-address transfers via 32-bit master connection to the system bus
• Data transfers in 8-, 16-, or 32-bit blocks
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• Continuous-mode or cycle-steal transfers from software or peripheral initiation
• Automatic hardware acknowledge/done indicator from each channel
• Independent source and destination address registers
• Optional modulo addressing and automatic updates of source and destination
addresses
• Independent transfer sizes for source and destination
• Optional auto-alignment feature for source or destination accesses
• Optional automatic single or double channel linking
• Programming model accessed via 32-bit slave peripheral bus
• Channel arbitration on transfer boundaries using fixed priority scheme
23.2 DMA Transfer Overview
The DMA module can move data within system memory (including memory and
peripheral devices) with minimal processor intervention, greatly improving overall
system performance. The DMA module consists of four independent, functionally
equivalent channels, so references to DMA in this chapter apply to any of the channels. It
is not possible to address all four channels at once.
As soon as a channel has been initialized, it may be started by setting DCRn[START] or
a properly-selected peripheral DMA request, depending on the status of DCRn[ERQ].
The DMA controller supports dual-address transfers using its bus master connection to
the system bus. The DMA channels support transfers up to 32 data bits in size and have
the same memory map addressibility as the processor.
• Dual-address transfers—A dual-address transfer consists of a read followed by a
write and is initiated by a request using the DCRn[START] bit or by a peripheral
DMA request. The read data is temporarily held in the DMA channel hardware until
the write operation. Two types of single transfers occur: a read from a source address
followed by a write to a destination address. See the following figure.
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Memory Map and Registers
Control and Data
Read
Memory/
Peripheral
DMA
Write
Control and Data
Memory/
Peripheral
Figure 23-2. Dual-Address Transfer
Any operation involving a DMA channel follows the same three steps:
1. Channel initialization—The transfer control descriptor, contained in the channel
registers, is loaded with address pointers, a byte-transfer count, and control
information using accesses from the slave peripheral bus.
2. Data transfer—The DMA accepts requests for data transfers. Upon receipt of a
request, it provides address and bus control for the transfers via its master connection
to the system bus and temporary storage for the read data. The channel performs one
or more source read and destination write data transfers.
3. Channel termination—Occurs after the operation is finished successfully or due to an
error. The channel indicates the operation status in the channel's DSR, described in
the definitions of the DMA Status Registers (DSRn) and Byte Count Registers
(BCRn).
23.3 Memory Map and Registers
Descriptions of each register and its bit assignments follow. Modifying DMA control
registers during a transfer can result in undefined operation. The following table shows
the mapping of DMA controller registers. The DMA programming model is accessed via
the slave peripheral bus. The concatenation of the source and destination address
registers, the status and byte count register, and the control register create a 128-bit
transfer control descriptor (TCD) that defines the operation of each DMA channel.
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Chapter 23 DMA Controller Module
DMA memory map
Absolute
address
(hex)
Width
Access
(in bits)
Register name
Reset value
Section/
page
4000_8100
Source Address Register (DMA_SAR0)
32
R/W
0000_0000h
23.3.1/323
4000_8104
Destination Address Register (DMA_DAR0)
32
R/W
0000_0000h
23.3.2/324
4000_8108
DMA Status Register / Byte Count Register
(DMA_DSR_BCR0)
32
R/W
0000_0000h
23.3.3/325
4000_810C
DMA Control Register (DMA_DCR0)
32
R/W
0000_0000h
23.3.4/327
4000_8110
Source Address Register (DMA_SAR1)
32
R/W
0000_0000h
23.3.1/323
4000_8114
Destination Address Register (DMA_DAR1)
32
R/W
0000_0000h
23.3.2/324
4000_8118
DMA Status Register / Byte Count Register
(DMA_DSR_BCR1)
32
R/W
0000_0000h
23.3.3/325
4000_811C
DMA Control Register (DMA_DCR1)
32
R/W
0000_0000h
23.3.4/327
4000_8120
Source Address Register (DMA_SAR2)
32
R/W
0000_0000h
23.3.1/323
4000_8124
Destination Address Register (DMA_DAR2)
32
R/W
0000_0000h
23.3.2/324
4000_8128
DMA Status Register / Byte Count Register
(DMA_DSR_BCR2)
32
R/W
0000_0000h
23.3.3/325
4000_812C
DMA Control Register (DMA_DCR2)
32
R/W
0000_0000h
23.3.4/327
4000_8130
Source Address Register (DMA_SAR3)
32
R/W
0000_0000h
23.3.1/323
4000_8134
Destination Address Register (DMA_DAR3)
32
R/W
0000_0000h
23.3.2/324
4000_8138
DMA Status Register / Byte Count Register
(DMA_DSR_BCR3)
32
R/W
0000_0000h
23.3.3/325
4000_813C
DMA Control Register (DMA_DCR3)
32
R/W
0000_0000h
23.3.4/327
23.3.1 Source Address Register (DMA_SARn)
Restriction
For this register:
• Only 32-bit writes are allowed. 16-bit and 8-bit writes
result in a bus error.
• Only four values are allowed to be written to bits 31-20 of
this register. A write of any other value to these bits causes
a configuration error when the channel starts to execute.
For more information about the configuration error, see the
description of the CE field of DSR.
Address: 4000_8000h base + 100h offset + (16d × i), where i=0d to 3d
Bit
R
W
31
Reset
0
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
SAR
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
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DMA_SARn field descriptions
Field
Description
31–0
SAR
Each SAR contains the byte address used by the DMA controller to read data. The SARn is typically
aligned on a 0-modulo-ssize boundary—that is, on the natural alignment of the source data.
Restriction: Bits 31-20 of this register must be written with one of only four allowed values. Each of
these four allowed values corresponds to a valid region of the device's memory map. The
allowed values are:
• 0x000x_xxxx
• 0x1FFx_xxxx
• 0x200x_xxxx
• 0x400x_xxxx
After being written with one of the allowed values, bits 31-20 read back as the written value.
After being written with any other value, bits 31-20 read back as an indeterminate value.
23.3.2 Destination Address Register (DMA_DARn)
Restriction
For this register:
• Only 32-bit writes are allowed. 16-bit and 8-bit writes
result in a bus error.
• Only four values are allowed to be written to bits 31-20 of
this register. A write of any other value to these bits causes
a configuration error when the channel starts to execute.
For more information about the configuration error, see the
description of the CE field of DSR.
Address: 4000_8000h base + 104h offset + (16d × i), where i=0d to 3d
Bit
R
W
31
Reset
0
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
DAR
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
DMA_DARn field descriptions
Field
31–0
DAR
Description
Each DAR contains the byte address used by the DMA controller to write data. The DARn is typically
aligned on a 0-modulo-dsize boundary—that is, on the natural alignment of the destination data.
Restriction: Bits 31-20 of this register must be written with one of only four allowed values. Each of
these four allowed values corresponds to a valid region of the device's memory map. The
allowed values are:
• 0x000x_xxxx
• 0x1FFx_xxxx
• 0x200x_xxxx
• 0x400x_xxxx
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Chapter 23 DMA Controller Module
DMA_DARn field descriptions (continued)
Field
Description
After being written with one of the allowed values, bits 31-20 read back as the written value.
After being written with any other value, bits 31-20 read back as an indeterminate value.
23.3.3 DMA Status Register / Byte Count Register (DMA_DSR_BCRn)
DSR and BCR are two logical registers that occupy one 32-bit address. DSRn occupies
bits 31–24, and BCRn occupies bits 23–0. DSRn contains flags indicating the channel
status, and BCRn contains the number of bytes yet to be transferred for a given block.
On the successful completion of the write transfer, BCRn decrements by 1, 2, or 4 for 8bit, 16-bit, or 32-bit accesses, respectively. BCRn is cleared if a 1 is written to
DSR[DONE].
In response to an event, the DMA controller writes to the appropriate DSRn bit. Only a
write to DSRn[DONE] results in action. DSRn[DONE] is set when the block transfer is
complete.
When a transfer sequence is initiated and BCRn[BCR] is not a multiple of 4 or 2 when
the DMA is configured for 32-bit or 16-bit transfers, respectively, DSRn[CE] is set and
no transfer occurs.
Bit
31
30
29
28
27
26
25
24
R
0
CE
BES
BED
0
REQ
BSY
DONE
Address: 4000_8000h base + 108h offset + (16d × i), where i=0d to 3d
23
22
21
20
19
18
17
16
BCR
w1c
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
R
BCR
W
Reset
0
0
0
0
0
0
0
0
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DMA_DSR_BCRn field descriptions
Field
31
Reserved
30
CE
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Configuration error
Any of the following conditions causes a configuration error:
• BCR, SAR, or DAR does not match the requested transfer size.
• A value greater than 0F_FFFFh is written to BCR.
• Bits 31-20 of SAR or DAR are written with a value other than one of the allowed values. See SAR
and DAR.
• SSIZE or DSIZE is set to an unsupported value.
• BCR equals 0 when the DMA receives a start condition.
CE is cleared at hardware reset or by writing a 1 to the DONE bit.
0
1
29
BES
Bus error on source
BES is cleared at hardware reset or by writing a 1 to the DONE bit.
0
1
28
BED
No bus error occurred.
The DMA channel terminated with a bus error during the read portion of a transfer.
Bus error on destination
BED is cleared at hardware reset or by writing a 1 to the DONE bit.
0
1
27
Reserved
No configuration error exists.
A configuration error has occurred.
No bus error occurred.
The DMA channel terminated with a bus error during the write portion of a transfer.
This field is reserved.
This read-only field is reserved and always has the value 0.
26
REQ
Request
25
BSY
Busy
24
DONE
0
1
0
1
DMA channel is inactive. Cleared when the DMA has finished the last transaction.
BSY is set the first time the channel is enabled after a transfer is initiated.
Transactions done
Set when all DMA controller transactions complete as determined by transfer count, or based on error
conditions. When BCR reaches zero, DONE is set when the final transfer completes successfully. DONE
can also be used to abort a transfer by resetting the status bits. When a transfer completes, software must
clear DONE before reprogramming the DMA.
0
1
23–0
BCR
No request is pending or the channel is currently active. Cleared when the channel is selected.
The DMA channel has a transfer remaining and the channel is not selected.
DMA transfer is not yet complete. Writing a 0 has no effect.
DMA transfer completed. Writing a 1 to this bit clears all DMA status bits and should be used in an
interrupt service routine to clear the DMA interrupt and error bits.
This field contains the number of bytes yet to be transferred for a given block.
Restriction: BCR must be written with a value equal to or less than 0F_FFFFh. After being written with a
value in this range, bits 23-20 of BCR read back as 1110b. A write to BCR of a value
Table continues on the next page...
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Chapter 23 DMA Controller Module
DMA_DSR_BCRn field descriptions (continued)
Field
Description
greater than 0F_FFFFh causes a configuration error when the channel starts to execute.
After being written with a value in this range, bits 23-20 of BCR read back as 1111b.
23.3.4 DMA Control Register (DMA_DCRn)
Address: 4000_8000h base + 10Ch offset + (16d × i), where i=0d to 3d
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
EINT
ERQ
CS
AA
EADREQ
0
Reserved
R
SINC
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
DINC
DSIZE
START
SSIZE
W
0
SMOD
D_REQ
R
DMOD
LINKCC
LCH1
LCH2
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
DMA_DCRn field descriptions
Field
31
EINT
Description
Enable interrupt on completion of transfer
Determines whether an interrupt is generated by completing a transfer or by the occurrence of an error
condition.
0
1
30
ERQ
No interrupt is generated.
Interrupt signal is enabled.
Enable peripheral request
CAUTION: Be careful: a collision can occur between the START bit and D_REQ when the ERQ bit is 1.
0
1
Peripheral request is ignored.
Enables peripheral request to initiate transfer. A software-initiated request (setting the START bit) is
always enabled.
Table continues on the next page...
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DMA_DCRn field descriptions (continued)
Field
Description
29
CS
Cycle steal
28
AA
Auto-align
0
1
DMA continuously makes read/write transfers until the BCR decrements to 0.
Forces a single read/write transfer per request.
AA and SIZE bits determine whether the source or destination is auto-aligned; that is, transfers are
optimized based on the address and size.
0
1
Auto-align disabled
If SSIZE indicates a transfer no smaller than DSIZE, source accesses are auto-aligned; otherwise,
destination accesses are auto-aligned. Source alignment takes precedence over destination
alignment. If auto-alignment is enabled, the appropriate address register increments, regardless of
DINC or SINC.
27–25
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
24
Reserved
This field is reserved.
CAUTION: Must be written as zero; otherwise, undefined behavior results.
23
EADREQ
Enable asynchronous DMA requests
Enables the channel to support asynchronous DREQs while the MCU is in Stop mode.
0
1
22
SINC
Source increment
Controls whether the source address increments after each successful transfer.
0
1
21–20
SSIZE
Determines the data size of the source bus cycle for the DMA controller.
32-bit
8-bit
16-bit
Reserved (generates a configuration error (DSRn[CE]) if incorrectly specified at time of channel
activation)
Destination increment
Controls whether the destination address increments after each successful transfer.
0
1
18–17
DSIZE
No change to SAR after a successful transfer.
The SAR increments by 1, 2, 4 as determined by the transfer size.
Source size
00
01
10
11
19
DINC
Disabled
Enabled
No change to the DAR after a successful transfer.
The DAR increments by 1, 2, 4 depending upon the size of the transfer.
Destination size
Determines the data size of the destination bus cycle for the DMA controller.
00
01
32-bit
8-bit
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Chapter 23 DMA Controller Module
DMA_DCRn field descriptions (continued)
Field
Description
10
11
16-bit
Reserved (generates a configuration error (DSRn[CE]) if incorrectly specified at time of channel
activation)
16
START
Start transfer
15–12
SMOD
Source address modulo
0
1
DMA inactive
The DMA begins the transfer in accordance to the values in the TCDn. START is cleared
automatically after one module clock and always reads as logic 0.
Defines the size of the source data circular buffer used by the DMA Controller. If enabled (SMOD is nonzero), the buffer base address is located on a boundary of the buffer size. The value of this boundary is
based upon the initial source address (SAR). The base address should be aligned to a 0-modulo-(circular
buffer size) boundary. Misaligned buffers are not possible. The boundary is forced to the value determined
by the upper address bits in the field selection.
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
11–8
DMOD
Buffer disabled
Circular buffer size is 16 bytes
Circular buffer size is 32 bytes
Circular buffer size is 64 bytes
Circular buffer size is 128 bytes
Circular buffer size is 256 bytes
Circular buffer size is 512 bytes
Circular buffer size is 1 KB
Circular buffer size is 2 KB
Circular buffer size is 4 KB
Circular buffer size is 8 KB
Circular buffer size is 16 KB
Circular buffer size is 32 KB
Circular buffer size is 64 KB
Circular buffer size is 128 KB
Circular buffer size is 256 KB
Destination address modulo
Defines the size of the destination data circular buffer used by the DMA Controller. If enabled (DMOD
value is non-zero), the buffer base address is located on a boundary of the buffer size. The value of this
boundary depends on the initial destination address (DAR). The base address should be aligned to a 0modulo-(circular buffer size) boundary. Misaligned buffers are not possible. The boundary is forced to the
value determined by the upper address bits in the field selection.
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
Buffer disabled
Circular buffer size is 16 bytes
Circular buffer size is 32 bytes
Circular buffer size is 64 bytes
Circular buffer size is 128 bytes
Circular buffer size is 256 bytes
Circular buffer size is 512 bytes
Circular buffer size is 1 KB
Circular buffer size is 2 KB
Circular buffer size is 4 KB
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DMA_DCRn field descriptions (continued)
Field
Description
1010
1011
1100
1101
1110
1111
7
D_REQ
Disable request
DMA hardware automatically clears the corresponding DCRn[ERQ] bit when the byte count register
reaches zero.
0
1
6
Reserved
5–4
LINKCC
Circular buffer size is 8 KB
Circular buffer size is 16 KB
Circular buffer size is 32 KB
Circular buffer size is 64 KB
Circular buffer size is 128 KB
Circular buffer size is 256 KB
ERQ bit is not affected.
ERQ bit is cleared when the BCR is exhausted.
This field is reserved.
This read-only field is reserved and always has the value 0.
Link channel control
Allows DMA channels to have their transfers linked. The current DMA channel triggers a DMA request to
the linked channels (LCH1 or LCH2) depending on the condition described by the LINKCC bits.
If not in cycle steal mode (DCRn[CS]=0) and LINKCC equals 01 or 10, no link to LCH1 occurs.
If LINKCC equals 01, a link to LCH1 is created after each cycle-steal transfer performed by the current
DMA channel is completed. As the last cycle-steal is performed and the BCR reaches zero, then the link to
LCH1 is closed and a link to LCH2 is created.
00
01
10
11
3–2
LCH1
Link channel 1
Indicates the DMA channel assigned as link channel 1. The link channel number cannot be the same as
the currently executing channel, and generates a configuration error if this is attempted (DSRn[CE] is set).
00
01
10
11
1–0
LCH2
No channel-to-channel linking
Perform a link to channel LCH1 after each cycle-steal transfer followed by a link to LCH2 after the
BCR decrements to zero
Perform a link to channel LCH1 after each cycle-steal transfer
Perform a link to channel LCH1 after the BCR decrements to zero
DMA Channel 0
DMA Channel 1
DMA Channel 2
DMA Channel 3
Link channel 2
Indicates the DMA channel assigned as link channel 2. The link channel number cannot be the same as
the currently executing channel, and generates a configuration error if this is attempted (DSRn[CE] is set).
00
01
10
11
DMA Channel 0
DMA Channel 1
DMA Channel 2
DMA Channel 3
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Chapter 23 DMA Controller Module
23.4 Functional Description
In the following discussion, the term DMA request implies that DCRn[START] is set, or
DCRn[ERQ] is set and then followed by assertion of the properly selected DMA
peripheral request. The START bit is cleared when the channel is activated.
Before initiating a dual-address access, the DMA module verifies that DCRn[SSIZE] and
DCRn[DSIZE] are consistent with the source and destination addresses. If they are not
consistent, the configuration error bit, DSRn[CE], is set. If misalignment is detected, no
transfer occurs, DSRn[CE] is set, and, depending on the DCR configuration, an interrupt
event may be issued. If the auto-align bit, DCRn[AA], is set, error checking is performed
on the appropriate registers.
A read/write transfer sequence reads data from the source address and writes it to the
destination address. The number of bytes transferred is the largest of the sizes specified
by DCRn[SSIZE] and DCRn[DSIZE] in the DMA Control Registers (DCRn).
Source and destination address registers (SARn and DARn) can be programmed in the
DCRn to increment at the completion of a successful transfer.
23.4.1 Transfer Requests (Cycle-Steal and Continuous Modes)
The DMA channel supports software-initiated or peripheral-initiated requests. A request
is issued by setting DCRn[START] or when the selected peripheral request asserts and
DCRn[ERQ] is set. Setting DCRn[ERQ] enables recognition of the peripheral DMA
requests. Selecting between cycle-steal and continuous modes minimizes bus usage for
either type of request.
• Cycle-steal mode (DCRn[CS] = 1)—Only one complete transfer from source to
destination occurs for each request. If DCRn[ERQ] is set, the request is peripheral
initiated. A software-initiated request is enabled by setting DCRn[START].
• Continuous mode (DCRn[CS] = 0)—After a software-initiated or peripheral request,
the DMA continuously transfers data until BCRn reaches zero. The DMA performs
the specified number of transfers, then retires the channel.
In either mode, the crossbar switch performs independent arbitration on each slave port
after each transaction.
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Functional Description
23.4.2 Channel Initialization and Startup
Before a data transfer starts, the channel's transfer control descriptor must be initialized
with information describing configuration, request-generation method, and pointers to the
data to be moved.
23.4.2.1 Channel Prioritization
The four DMA channels are prioritized based on number, with channel 0 having highest
priority and channel 3 having the lowest, that is, channel 0 > channel 1 > channel 2 >
channel 3.
Simultaneous peripheral requests activate the channels based on this priority order. Once
activated, a channel runs to completion as defined by DCRn[CS] and BCRn.
23.4.2.2 Programming the DMA Controller Module
CAUTION
During a channel's execution, writes to programming model
registers can corrupt the data transfer. The DMA module itself
does not have a mechanism to prevent writes to registers during
a channel's execution.
General guidelines for programming the DMA are:
• TCDn is initialized.
• SARn is loaded with the source (read) address. If the transfer is from a
peripheral device to memory or to another peripheral, the source address is the
location of the peripheral data register. If the transfer is from memory to a
peripheral device or to memory, the source address is the starting address of the
data block. This can be any appropriately aligned address.
• DARn is initialized with the destination (write) address. If the transfer is from a
peripheral device to memory, or from memory to memory, DARn is loaded with
the starting address of the data block to be written. If the transfer is from
memory to a peripheral device, or from a peripheral device to a peripheral
device, DARn is loaded with the address of the peripheral data register. This
address can be any appropriately aligned address.
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Chapter 23 DMA Controller Module
• SARn and DARn change after each data transfer depending on DCRn[SSIZE,
DSIZE, SINC, DINC, SMOD, DMOD] and the starting addresses. Increment
values can be 1, 2, or 4 for 8-bit, 16-bit, or 32-bit transfers, respectively. If the
address register is programmed to remain unchanged, the register is not
incremented after the data transfer.
• BCRn[BCR] must be loaded with the total number of bytes to be transferred. It
is decremented by 1, 2, or 4 at the end of each transfer, depending on the transfer
size. DSRn[DONE] must be cleared for channel startup.
• After the channel has been initialized, it may be started by setting DCRn[START] or
a properly selected peripheral DMA request, depending on the status of
DCRn[ERQ]. For a software-initiated transfer, the channel can be started by setting
DCRn[START] as part of a single 32-bit write to the last 32 bits of the TCDn; that is,
it is not required to write the DCRn with START cleared and then perform a second
write to explicitly set START.
• Programming the channel for a software-initiated request causes the channel to
request the system bus and start transferring data immediately. If the channel is
programmed for peripheral-initiated request, a properly selected peripheral DMA
request must be asserted before the channel begins the system bus transfers.
• The hardware can automatically clear DCRn[ERQ], disabling the peripheral request,
when BCRn reaches zero by setting DCRn[D_REQ].
• Changes to DCRn are effective immediately while the channel is active. To avoid
problems with changing a DMA channel setup, write a one to DSRn[DONE] to stop
the DMA channel.
23.4.3 Dual-Address Data Transfer Mode
Each channel supports dual-address transfers. Dual-address transfers consist of a source
data read and a destination data write. The DMA controller module begins a dual-address
transfer sequence after a DMA request. If no error condition exists, DSRn[REQ] is set.
• Dual-address read—The DMA controller drives the SARn value onto the system
address bus. If DCRn[SINC] is set, the SARn increments by the appropriate number
of bytes upon a successful read cycle. When the appropriate number of read cycles
complete (multiple reads if the destination size is larger than the source), the DMA
initiates the write portion of the transfer.
If a termination error occurs, DSRn[BES, DONE] are set and DMA transactions stop.
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Functional Description
• Dual-address write—The DMA controller drives the DARn value onto the system
address bus. When the appropriate number of write cycles complete (multiple writes
if the source size is larger than the destination), DARn increments by the appropriate
number of bytes if DCRn[DINC] is set. BCRn decrements by the appropriate number
of bytes. DSRn[DONE] is set when BCRn reaches zero. If the BCRn is greater than
zero, another read/write transfer is initiated if continuous mode is enabled
(DCRn[CS] = 0).
If a termination error occurs, DSRn[BED, DONE] are set and DMA transactions
stop.
23.4.4 Advanced Data Transfer Controls: Auto-Alignment
Typically, auto-alignment for DMA transfers applies for transfers of large blocks of data.
As a result, it does not apply for peripheral-initiated cycle-steal transfers.
Auto-alignment allows block transfers to occur at the optimal size based on the address,
byte count, and programmed size. To use this feature, DCRn[AA] must be set. The
source is auto-aligned if DCRn[SSIZE] indicates a transfer size larger than
DCRn[DSIZE]. Source alignment takes precedence over the destination when the source
and destination sizes are equal. Otherwise, the destination is auto-aligned. The address
register chosen for alignment increments regardless of the increment value. Configuration
error checking is performed on registers not chosen for alignment.
If BCRn is greater than 16, the address determines transfer size. Transfers of 8 bits, 16
bits, or 32 bits are transferred until the address is aligned to the programmed size
boundary, at which time accesses begin using the programmed size. If BCRn is less than
16 at the start of a transfer, the number of bytes remaining dictates transfer size.
Consider this example:
• AA equals 1.
• SARn equals 0x2000_0001.
• BCRn equals 0x00_00F0.
• SSIZE equals 00 (32 bits).
• DSIZE equals 01 (8 bits).
Because SSIZE > DSIZE, the source is auto-aligned. Error checking is performed on
destination registers. The access sequence is as follows:
1. Read 1 byte from 0x2000_0001, increment SARn, write 1 byte (using DARn).
2. Read 2 bytes from 0x2000_0002, increment SARn, write 2 bytes.
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Chapter 23 DMA Controller Module
3. Read 4 bytes from 0x2000_0004, increment SARn, write 4 bytes.
4. Repeat 4-byte operations until SARn equals 0x2000_00F0.
5. Read byte from 0x2000_00F0, increment SARn, write byte.
If DSIZE is another size, data writes are optimized to write the largest size allowed based
on the address, but not exceeding the configured size.
23.4.5 Termination
An unsuccessful transfer can terminate for one of the following reasons:
• Error conditions—When the DMA encounters a read or write cycle that terminates
with an error condition, DSRn[BES] is set for a read and DSRn[BED] is set for a
write before the transfer is halted. If the error occurred in a write cycle, data in the
internal holding registers is lost.
• Interrupts—If DCRn[EINT] is set, the DMA drives the appropriate interrupt request
signal. The processor can read DSRn to determine whether the transfer terminated
successfully or with an error. DSRn[DONE] is then written with a one to clear the
interrupt, the DONE, and error status bits.
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Functional Description
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Chapter 24
Multipurpose Clock Generator (MCG)
24.1 Introduction
NOTE
For the chip-specific implementation details of this module's
instances see the chip configuration information.
The multipurpose clock generator (MCG) module provides several clock source choices
for the MCU. The module contains a frequency-locked loop (FLL). The FLL is
controllable by either an internal or an external reference clock. The module can select
either of the FLL orthe internal or external reference clocks as a source for the MCU
system clock. The MCG operates in conjuction with a crystal oscillator, which allows an
external crystal, ceramic resonator, or another external clock source to produce the
external reference clock.
24.1.1 Features
Key features of the MCG module are:
• Frequency-locked loop (FLL):
• Digitally-controlled oscillator (DCO)
• DCO frequency range is programmable for up to four different frequency ranges.
• Option to program and maximize DCO output frequency for a low frequency
external reference clock source.
• Option to prevent FLL from resetting its current locked frequency when
switching clock modes if FLL reference frequency is not changed.
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Introduction
• Internal or external reference clock can be used as the FLL source.
• Can be used as a clock source for other on-chip peripherals.
• Internal reference clock generator:
• Slow clock with nine trim bits for accuracy
• Fast clock with four trim bits
• Can be used as source clock for the FLL. In FEI mode, only the slow Internal
Reference Clock (IRC) can be used as the FLL source.
• Either the slow or the fast clock can be selected as the clock source for the MCU.
• Can be used as a clock source for other on-chip peripherals.
• Control signals for the MCG external reference low power oscillator clock generators
are provided:
• HGO0, RANGE0, EREFS0
• External clock from the Crystal Oscillator :
• Can be used as a source for the FLL.
• Can be selected as the clock source for the MCU.
• External clock monitor with reset and interrupt request capability to check for
external clock failure when running in FBE, BLPE, or FEE modes
• Internal Reference Clocks Auto Trim Machine (ATM) capability using an external
clock as a reference
• Reference dividers for the FLL are provided
• Reference dividers for the Fast Internal Reference Clock are provided
• MCG FLL Clock (MCGFLLCLK) is provided as a clock source for other on-chip
peripherals
• MCG Fixed Frequency Clock (MCGFFCLK) is provided as a clock source for other
on-chip peripherals
• MCG Internal Reference Clock (MCGIRCLK) is provided as a clock source for other
on-chip peripherals
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Chapter 24 Multipurpose Clock Generator (MCG)
Crystal Oscillator
External Reference Clock
CLKS
OSCINIT0
MCG Crystal Oscillator
Enable Detect
IREFS
EREFS0
HGO0
ATMS
RANGE0
STOP
IREFSTEN
Auto Trim Machine
IRCLKEN
SCTRIM
Internal
Reference
SCFTRIM
Clock
Generator
FCTRIM
MCGIRCLK
IRCS
CLKS
Slow Clock
Fast Clock
/
2n
IRCSCLK
n=0-7
MCGOUTCLK
CME0 LOCRE0
DRS
External
Clock
Monitor
DMX32
MCGFLLCLK
Filter
DCO
FLTPRSRV
LOCS0
DCOOUT
FLL
FRDIV
/
Clock
Valid
LP
2n
n=0-7
/ 25
MCGFFCLK
Sync
IREFS
Peripheral BUSCLK
Multipurpose Clock Generator (MCG)
Figure 24-1. Multipurpose Clock Generator (MCG) block diagram
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External Signal Description
24.1.2 Modes of Operation
The MCG has the following modes of operation: FEI, FEE, FBI, FBE, BLPI, BLPE, and
Stop. For details, see MCG modes of operation.
24.2 External Signal Description
There are no MCG signals that connect off chip.
24.3 Memory Map/Register Definition
This section includes the memory map and register definition.
The MCG registers can only be written when in supervisor mode. Write accesses when in
user mode will result in a bus error. Read accesses may be performed in both supervisor
and user mode.
MCG memory map
Absolute
address
(hex)
Width
Access
(in bits)
Register name
Reset value
Section/
page
04h
24.3.1/340
4006_4000
MCG Control 1 Register (MCG_C1)
8
R/W
4006_4001
MCG Control 2 Register (MCG_C2)
8
R/W
80h
24.3.2/342
4006_4002
MCG Control 3 Register (MCG_C3)
8
R/W
Undefined
24.3.3/343
4006_4003
MCG Control 4 Register (MCG_C4)
8
R/W
Undefined
24.3.4/343
4006_4005
MCG Control 6 Register (MCG_C6)
8
R/W
00h
24.3.5/345
4006_4006
MCG Status Register (MCG_S)
8
R
10h
24.3.6/345
4006_4008
MCG Status and Control Register (MCG_SC)
8
R/W
02h
24.3.7/346
4006_400A
MCG Auto Trim Compare Value High Register
(MCG_ATCVH)
8
R/W
00h
24.3.8/348
4006_400B
MCG Auto Trim Compare Value Low Register
(MCG_ATCVL)
8
R/W
00h
24.3.9/348
2
1
0
IREFS
IRCLKEN
IREFSTEN
1
0
0
24.3.1 MCG Control 1 Register (MCG_C1)
Address: 4006_4000h base + 0h offset = 4006_4000h
Bit
Read
Write
Reset
7
6
5
CLKS
0
4
3
FRDIV
0
0
0
0
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Chapter 24 Multipurpose Clock Generator (MCG)
MCG_C1 field descriptions
Field
7–6
CLKS
Description
Clock Source Select
Selects the clock source for MCGOUTCLK .
00
01
10
11
5–3
FRDIV
FLL External Reference Divider
Selects the amount to divide down the external reference clock for the FLL. The resulting frequency must
be in the range 31.25 kHz to 39.0625 kHz (This is required when FLL/DCO is the clock source for
MCGOUTCLK . In FBE mode, it is not required to meet this range, but it is recommended in the cases
when trying to enter a FLL mode from FBE).
000
001
010
011
100
101
110
111
2
IREFS
Selects the reference clock source for the FLL.
External reference clock is selected.
The slow internal reference clock is selected.
Internal Reference Clock Enable
Enables the internal reference clock for use as MCGIRCLK.
0
1
0
IREFSTEN
If RANGE 0 = 0 , Divide Factor is 1; for all other RANGE 0 values, Divide Factor is 32.
If RANGE 0 = 0 , Divide Factor is 2; for all other RANGE 0 values, Divide Factor is 64.
If RANGE 0 = 0 , Divide Factor is 4; for all other RANGE 0 values, Divide Factor is 128.
If RANGE 0 = 0 , Divide Factor is 8; for all other RANGE 0 values, Divide Factor is 256.
If RANGE 0 = 0 , Divide Factor is 16; for all other RANGE 0 values, Divide Factor is 512.
If RANGE 0 = 0 , Divide Factor is 32; for all other RANGE 0 values, Divide Factor is 1024.
If RANGE 0 = 0 , Divide Factor is 64; for all other RANGE 0 values, Divide Factor is 1280 .
If RANGE 0 = 0 , Divide Factor is 128; for all other RANGE 0 values, Divide Factor is 1536 .
Internal Reference Select
0
1
1
IRCLKEN
Encoding 0 — Output of FLL is selected.
Encoding 1 — Internal reference clock is selected.
Encoding 2 — External reference clock is selected.
Encoding 3 — Reserved.
MCGIRCLK inactive.
MCGIRCLK active.
Internal Reference Stop Enable
Controls whether or not the internal reference clock remains enabled when the MCG enters Stop mode.
0
1
Internal reference clock is disabled in Stop mode.
Internal reference clock is enabled in Stop mode if IRCLKEN is set or if MCG is in FEI, FBI, or BLPI
modes before entering Stop mode.
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Memory Map/Register Definition
24.3.2 MCG Control 2 Register (MCG_C2)
Address: 4006_4000h base + 1h offset = 4006_4001h
Bit
Read
Write
Reset
7
6
LOCRE0
0
1
0
5
4
RANGE0
0
3
2
1
0
HGO0
EREFS0
LP
IRCS
0
0
0
0
0
MCG_C2 field descriptions
Field
7
LOCRE0
Description
Loss of Clock Reset Enable
Determines whether an interrupt or a reset request is made following a loss of OSC0 external reference
clock. The LOCRE0 only has an affect when CME0 is set.
0
1
Interrupt request is generated on a loss of OSC0 external reference clock.
Generate a reset request on a loss of OSC0 external reference clock.
6
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
5–4
RANGE0
Frequency Range Select
Selects the frequency range for the crystal oscillator or external clock source. See the Oscillator (OSC)
chapter for more details and the device data sheet for the frequency ranges used.
00
01
1X
3
HGO0
High Gain Oscillator Select
Controls the crystal oscillator mode of operation. See the Oscillator (OSC) chapter for more details.
0
1
2
EREFS0
Selects the source for the external reference clock. See the Oscillator (OSC) chapter for more details.
External reference clock requested.
Oscillator requested.
Low Power Select
Controls whether the FLL is disabled in BLPI and BLPE modes. In FBE mode, setting this bit to 1 will
transition the MCG into BLPE mode; in FBI mode, setting this bit to 1 will transition the MCG into BLPI
mode. In any other MCG mode, LP bit has no affect.
0
1
0
IRCS
Configure crystal oscillator for low-power operation.
Configure crystal oscillator for high-gain operation.
External Reference Select
0
1
1
LP
Encoding 0 — Low frequency range selected for the crystal oscillator .
Encoding 1 — High frequency range selected for the crystal oscillator .
Encoding 2 — Very high frequency range selected for the crystal oscillator .
FLL is not disabled in bypass modes.
FLL is disabled in bypass modes (lower power)
Internal Reference Clock Select
Selects between the fast or slow internal reference clock source.
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Chapter 24 Multipurpose Clock Generator (MCG)
MCG_C2 field descriptions (continued)
Field
Description
0
1
Slow internal reference clock selected.
Fast internal reference clock selected.
24.3.3 MCG Control 3 Register (MCG_C3)
Address: 4006_4000h base + 2h offset = 4006_4002h
Bit
Read
Write
Reset
7
6
5
4
3
2
1
0
x*
x*
x*
x*
SCTRIM
x*
x*
x*
x*
* Notes:
• x = Undefined at reset.
MCG_C3 field descriptions
Field
7–0
SCTRIM
Description
Slow Internal Reference Clock Trim Setting
SCTRIM 1 controls the slow internal reference clock frequency by controlling the slow internal reference
clock period. The SCTRIM bits are binary weighted, that is, bit 1 adjusts twice as much as bit 0. Increasing
the binary value increases the period, and decreasing the value decreases the period.
An additional fine trim bit is available in C4 register as the SCFTRIM bit. Upon reset, this value is loaded
with a factory trim value.
If an SCTRIM value stored in nonvolatile memory is to be used, it is your responsibility to copy that value
from the nonvolatile memory location to this register.
1. A value for SCTRIM is loaded during reset from a factory programmed location .
24.3.4 MCG Control 4 Register (MCG_C4)
NOTE
Reset values for DRST and DMX32 bits are 0.
Address: 4006_4000h base + 3h offset = 4006_4003h
Bit
Read
Write
Reset
7
6
DMX32
5
4
3
DRST_DRS
0
0
2
1
FCTRIM
0
x*
x*
0
SCFTRIM
x*
x*
x*
* Notes:
• x = Undefined at reset.
• A value for FCTRIM is loaded during reset from a factory programmed location . x = Undefined at reset.
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Memory Map/Register Definition
MCG_C4 field descriptions
Field
7
DMX32
Description
DCO Maximum Frequency with 32.768 kHz Reference
The DMX32 bit controls whether the DCO frequency range is narrowed to its maximum frequency with a
32.768 kHz reference.
The following table identifies settings for the DCO frequency range.
NOTE: The system clocks derived from this source should not exceed their specified maximums.
DRST_DRS
DMX32
Reference Range
FLL Factor
DCO Range
00
0
31.25–39.0625 kHz
640
20–25 MHz
1
32.768 kHz
732
24 MHz
0
31.25–39.0625 kHz
1280
40–50 MHz
1
32.768 kHz
1464
48 MHz
0
31.25–39.0625 kHz
1920
60–75 MHz
1
32.768 kHz
2197
72 MHz
0
31.25–39.0625 kHz
2560
80–100 MHz
1
32.768 kHz
2929
96 MHz
01
10
11
0
1
6–5
DRST_DRS
DCO Range Select
The DRS bits select the frequency range for the FLL output, DCOOUT. When the LP bit is set, writes to
the DRS bits are ignored. The DRST read field indicates the current frequency range for DCOOUT. The
DRST field does not update immediately after a write to the DRS field due to internal synchronization
between clock domains. See the DCO Frequency Range table for more details.
00
01
10
11
4–1
FCTRIM
DCO has a default range of 25%.
DCO is fine-tuned for maximum frequency with 32.768 kHz reference.
Encoding 0 — Low range (reset default).
Encoding 1 — Mid range.
Encoding 2 — Mid-high range.
Encoding 3 — High range.
Fast Internal Reference Clock Trim Setting
FCTRIM 1 controls the fast internal reference clock frequency by controlling the fast internal reference
clock period. The FCTRIM bits are binary weighted, that is, bit 1 adjusts twice as much as bit 0. Increasing
the binary value increases the period, and decreasing the value decreases the period.
If an FCTRIM[3:0] value stored in nonvolatile memory is to be used, it is your responsibility to copy that
value from the nonvolatile memory location to this register.
0
SCFTRIM
Slow Internal Reference Clock Fine Trim
SCFTRIM 2 controls the smallest adjustment of the slow internal reference clock frequency. Setting
SCFTRIM increases the period and clearing SCFTRIM decreases the period by the smallest amount
possible.
If an SCFTRIM value stored in nonvolatile memory is to be used, it is your responsibility to copy that value
from the nonvolatile memory location to this bit.
1. A value for FCTRIM is loaded during reset from a factory programmed location .
2. A value for SCFTRIM is loaded during reset from a factory programmed location .
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Chapter 24 Multipurpose Clock Generator (MCG)
24.3.5 MCG Control 6 Register (MCG_C6)
Address: 4006_4000h base + 5h offset = 4006_4005h
Bit
Read
Write
Reset
7
6
0
0
5
4
3
2
CME
0
0
1
0
0
0
0
0
0
0
MCG_C6 field descriptions
Field
7–6
Reserved
5
CME
Description
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
Clock Monitor Enable
Determines if a reset request is made following a loss of external clock indication. The CME bit should
only be set to a logic 1 when the MCG is in an operational mode that uses the external clock (FEE, FBE,
PEE, PBE, or BLPE). Whenever the CME bit is set to a logic 1, the value of the RANGE bits in the C2
register should not be changed. CME bit should be set to a logic 0 before the MCG enters any Stop mode.
Otherwise, a reset request may occur when in Stop mode. CME should also be set to a logic 0 before
entering VLPR or VLPW power modes if the MCG is in BLPE mode.
0
1
4–0
Reserved
External clock monitor is disabled.
Generate a reset request on loss of external clock.
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
24.3.6 MCG Status Register (MCG_S)
Address: 4006_4000h base + 6h offset = 4006_4006h
Bit
7
6
Read
5
0
4
3
IREFST
2
CLKST
1
0
OSCINIT0
IRCST
0
0
Write
Reset
0
0
0
1
0
0
MCG_S field descriptions
Field
7–5
Reserved
Description
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
Table continues on the next page...
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Memory Map/Register Definition
MCG_S field descriptions (continued)
Field
4
IREFST
Description
Internal Reference Status
This bit indicates the current source for the FLL reference clock. The IREFST bit does not update
immediately after a write to the IREFS bit due to internal synchronization between clock domains.
0
1
3–2
CLKST
Source of FLL reference clock is the external reference clock.
Source of FLL reference clock is the internal reference clock.
Clock Mode Status
These bits indicate the current clock mode. The CLKST bits do not update immediately after a write to the
CLKS bits due to internal synchronization between clock domains.
00
01
10
11
1
OSCINIT0
0
IRCST
Encoding 0 — Output of the FLL is selected (reset default).
Encoding 1 — Internal reference clock is selected.
Encoding 2 — External reference clock is selected.
Reserved.
OSC Initialization
This bit, which resets to 0, is set to 1 after the initialization cycles of the crystal oscillator clock have
completed. After being set, the bit is cleared to 0 if the OSC is subsequently disabled. See the OSC
module's detailed description for more information.
Internal Reference Clock Status
The IRCST bit indicates the current source for the internal reference clock select clock (IRCSCLK). The
IRCST bit does not update immediately after a write to the IRCS bit due to internal synchronization
between clock domains. The IRCST bit will only be updated if the internal reference clock is enabled,
either by the MCG being in a mode that uses the IRC or by setting the C1[IRCLKEN] bit .
0
1
Source of internal reference clock is the slow clock (32 kHz IRC).
Source of internal reference clock is the fast clock (4 MHz IRC).
24.3.7 MCG Status and Control Register (MCG_SC)
Address: 4006_4000h base + 8h offset = 4006_4008h
Bit
Read
Write
Reset
7
6
ATME
ATMS
0
0
5
ATMF
0
4
3
FLTPRSRV
0
2
1
LOCS0
FCRDIV
0
0
0
1
0
MCG_SC field descriptions
Field
7
ATME
Description
Automatic Trim Machine Enable
Enables the Auto Trim Machine to start automatically trimming the selected Internal Reference Clock.
NOTE: ATME deasserts after the Auto Trim Machine has completed trimming all trim bits of the IRCS
clock selected by the ATMS bit.
Table continues on the next page...
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Chapter 24 Multipurpose Clock Generator (MCG)
MCG_SC field descriptions (continued)
Field
Description
Writing to C1, C3, C4, and SC registers or entering Stop mode aborts the auto trim operation and clears
this bit.
0
1
6
ATMS
Automatic Trim Machine Select
Selects the IRCS clock for Auto Trim Test.
0
1
5
ATMF
Fail flag for the Automatic Trim Machine (ATM). This bit asserts when the Automatic Trim Machine is
enabled, ATME=1, and a write to the C1, C3, C4, and SC registers is detected or the MCG enters into any
Stop mode. A write to ATMF clears the flag.
This bit will prevent the FLL filter values from resetting allowing the FLL output frequency to remain the
same during clock mode changes where the FLL/DCO output is still valid. (Note: This requires that the
FLL reference frequency to remain the same as what it was prior to the new clock mode switch. Otherwise
FLL filter and frequency values will change.)
FLL filter and FLL frequency will reset on changes to currect clock mode.
Fll filter and FLL frequency retain their previous values during new clock mode change.
Fast Clock Internal Reference Divider
Selects the amount to divide down the fast internal reference clock. The resulting frequency will be in the
range 31.25 kHz to 4 MHz (Note: Changing the divider when the Fast IRC is enabled is not supported).
000
001
010
011
100
101
110
111
0
LOCS0
Automatic Trim Machine completed normally.
Automatic Trim Machine failed.
FLL Filter Preserve Enable
0
1
3–1
FCRDIV
32 kHz Internal Reference Clock selected.
4 MHz Internal Reference Clock selected.
Automatic Trim Machine Fail Flag
0
1
4
FLTPRSRV
Auto Trim Machine disabled.
Auto Trim Machine enabled.
Divide Factor is 1
Divide Factor is 2.
Divide Factor is 4.
Divide Factor is 8.
Divide Factor is 16
Divide Factor is 32
Divide Factor is 64
Divide Factor is 128.
OSC0 Loss of Clock Status
The LOCS0 indicates when a loss of OSC0 reference clock has occurred. The LOCS0 bit only has an
effect when CME0 is set. This bit is cleared by writing a logic 1 to it when set.
0
1
Loss of OSC0 has not occurred.
Loss of OSC0 has occurred.
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Functional Description
24.3.8 MCG Auto Trim Compare Value High Register (MCG_ATCVH)
Address: 4006_4000h base + Ah offset = 4006_400Ah
Bit
Read
Write
Reset
7
6
5
4
3
2
1
0
0
0
0
0
ATCVH
0
0
0
0
MCG_ATCVH field descriptions
Field
7–0
ATCVH
Description
ATM Compare Value High
Values are used by Auto Trim Machine to compare and adjust Internal Reference trim values during ATM
SAR conversion.
24.3.9 MCG Auto Trim Compare Value Low Register (MCG_ATCVL)
Address: 4006_4000h base + Bh offset = 4006_400Bh
Bit
Read
Write
Reset
7
6
5
4
3
2
1
0
0
0
0
0
ATCVL
0
0
0
0
MCG_ATCVL field descriptions
Field
7–0
ATCVL
Description
ATM Compare Value Low
Values are used by Auto Trim Machine to compare and adjust Internal Reference trim values during ATM
SAR conversion.
24.4 Functional Description
24.4.1 MCG mode state diagram
The seven states of the MCG are shown in the following figure and are described in
Table 24-11. The arrows indicate the permitted MCG mode transitions.
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Reset
FEI
FEE
FBI
FBE
BLPE
BLPI
Entered from any state when
the MCU enters Stop mode
Stop
Returns to the state that was active before
the MCU entered Stop mode, unless a
reset occurs while in Stop mode.
Figure 24-11. MCG mode state diagram
24.4.1.1 MCG modes of operation
The MCG operates in one of the following modes.
Note
The MCG restricts transitions between modes. For the
permitted transitions, see Figure 24-11.
Table 24-11. MCG modes of operation
Mode
Description
FLL Engaged Internal
(FEI)
FLL engaged internal (FEI) is the default mode of operation and is entered when all the following
condtions occur:
• C1[CLKS] bits are written to 00
• C1[IREFS] bit is written to 1
In FEI mode, MCGOUTCLK is derived from the FLL clock (DCOCLK) that is controlled by the 32
kHz Internal Reference Clock (IRC). The FLL loop will lock the DCO frequency to the FLL factor, as
selected by C4[DRST_DRS] and C4[DMX32] bits, times the internal reference frequency. See the
C4[DMX32] bit description for more details.
Table continues on the next page...
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Table 24-11. MCG modes of operation (continued)
Mode
Description
FLL Engaged External
(FEE)
FLL engaged external (FEE) mode is entered when all the following conditions occur:
• C1[CLKS] bits are written to 00
• C1[IREFS] bit is written to 0
• C1[FRDIV] must be written to divide external reference clock to be within the range of 31.25
kHz to 39.0625 kHz
In FEE mode, MCGOUTCLK is derived from the FLL clock (DCOCLK) that is controlled by the
external reference clock. The FLL loop will lock the DCO frequency to the FLL factor, as selected by
C4[DRST_DRS] and C4[DMX32] bits, times the external reference frequency, as specified by
C1[FRDIV] and C2[RANGE0]. See the C4[DMX32] bit description for more details.
FLL Bypassed Internal
(FBI)
FLL bypassed internal (FBI) mode is entered when all the following conditions occur:
• C1[CLKS] bits are written to 01
• C1[IREFS] bit is written to 1
• C2[LP] is written to 0
In FBI mode, the MCGOUTCLK is derived either from the slow (32 kHz IRC) or fast (4 MHz IRC)
internal reference clock, as selected by the C2[IRCS] bit. The FLL is operational but its output is not
used. This mode is useful to allow the FLL to acquire its target frequency while the MCGOUTCLK is
driven from the C2[IRCS] selected internal reference clock. The FLL clock (DCOCLK) is controlled
by the slow internal reference clock, and the DCO clock frequency locks to a multiplication factor, as
selected by C4[DRST_DRS] and C4[DMX32] bits, times the internal reference frequency. See the
C4[DMX32] bit description for more details.
FLL Bypassed External FLL bypassed external (FBE) mode is entered when all the following conditions occur:
(FBE)
• C1[CLKS] bits are written to 10
• C1[IREFS] bit is written to 0
• C1[FRDIV] must be written to divide external reference clock to be within the range of 31.25
kHz to 39.0625 kHz.
• C2[LP] is written to 0
In FBE mode, the MCGOUTCLK is derived from the external reference clock. The FLL is
operational but its output is not used. This mode is useful to allow the FLL to acquire its target
frequency while the MCGOUTCLK is driven from the external reference clock. The FLL clock
(DCOCLK) is controlled by the external reference clock, and the DCO clock frequency locks to a
multiplication factor, as selected by C4[DRST_DRS] and C4[DMX32] bits, times the divided external
reference frequency. See the C4[DMX32] bit description for more details.
Bypassed Low Power
Internal (BLPI)1
Bypassed Low Power Internal (BLPI) mode is entered when all the following conditions occur:
• C1[CLKS] bits are written to 01
• C1[IREFS] bit is written to 1
• C2[LP] bit is written to 1
In BLPI mode, MCGOUTCLK is derived from the internal reference clock. The FLL is disabled
Table continues on the next page...
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Chapter 24 Multipurpose Clock Generator (MCG)
Table 24-11. MCG modes of operation (continued)
Mode
Description
Bypassed Low Power
External (BLPE)
Bypassed Low Power External (BLPE) mode is entered when all the following conditions occur:
• C1[CLKS] bits are written to 10
• C1[IREFS] bit is written to 0
• C2[LP] bit is written to 1
In BLPE mode, MCGOUTCLK is derived from the external reference clock. The FLL is disabled
Stop
Entered whenever the MCU enters a Stop state. The power modes are chip specific. For power
mode assignments, see the chapter that describes how modules are configured and MCG behavior
during Stop recovery. Entering Stop mode, the FLL is disabled, and all MCG clock signals are static
except in the following case:
MCGIRCLK is active in Normal Stop mode when all the following conditions become true:
• C1[IRCLKEN] = 1
• C1[IREFSTEN] = 1
1. If entering VLPR mode, MCG has to be configured and enter BLPE mode or BLPI mode with the Fast IRC clock selected
(C2[IRCS]=1). After it enters VLPR mode, writes to any of the MCG control registers that can cause an MCG clock mode
switch to a non low power clock mode must be avoided.
NOTE
For the chip-specific modes of operation, see the power
management chapter of this MCU.
24.4.1.2 MCG mode switching
The C1[IREFS] bit can be changed at any time, but the actual switch to the newly
selected reference clocks is shown by the S[IREFST] bit. When switching between
engaged internal and engaged external modes, the FLL will begin locking again after the
switch is completed.
The C1[CLKS] bits can also be changed at any time, but the actual switch to the newly
selected clock is shown by the S[CLKST] bits. If the newly selected clock is not
available, the previous clock will remain selected.
The C4[DRST_DRS] write bits can be changed at any time except when C2[LP] bit is 1.
If the C4[DRST_DRS] write bits are changed while in FLL engaged internal (FEI) or
FLL engaged external (FEE), the MCGOUTCLK will switch to the new selected DCO
range within three clocks of the selected DCO clock. After switching to the new DCO,
the FLL remains unlocked for several reference cycles. DCO startup time is equal to the
FLL acquisition time. After the selected DCO startup time is over, the FLL is locked. The
completion of the switch is shown by the C4[DRST_DRS] read bits.
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24.4.2 Low Power Bit Usage
The C2[LP] bit is provided to allow the FLL to be disabled and thus conserve power
when these systems are not being used. The C4[DRST_DRS] can not be written while
C2[LP] bit is 1. However, in some applications, it may be desirable to enable the FLL
and allow it to lock for maximum accuracy before switching to an engaged mode. Do this
by writing C2[LP] to 0.
24.4.3 MCG Internal Reference Clocks
This module supports two internal reference clocks with nominal frequencies of 32 kHz
(slow IRC) and 4 MHz (fast IRC). The fast IRC frequency can be divided down by
programming of the FCRDIV to produce a frequency range of 32 kHz to 4 MHz.
24.4.3.1 MCG Internal Reference Clock
The MCG Internal Reference Clock (MCGIRCLK) provides a clock source for other onchip peripherals and is enabled when C1[IRCLKEN]=1. When enabled, MCGIRCLK is
driven by either the fast internal reference clock (4 MHz IRC which can be divided down
by the FRDIV factors) or the slow internal reference clock (32 kHz IRC). The IRCS
clock frequency can be re-targeted by trimming the period of its IRCS selected internal
reference clock. This can be done by writing a new trim value to the
C3[SCTRIM]:C4[SCFTRIM] bits when the slow IRC clock is selected or by writing a
new trim value to the C4[FCTRIM] bits when the fast IRC clock is selected. The internal
reference clock period is proportional to the trim value written.
C3[SCTRIM]:C4[SCFTRIM] (if C2[IRCS]=0) and C4[FCTRIM] (if C2[IRCS]=1) bits
affect the MCGOUTCLK frequency if the MCG is in FBI or BLPI modes.
C3[SCTRIM]:C4[SCFTRIM] (if C2[IRCS]=0) bits also affect the MCGOUTCLK
frequency if the MCG is in FEI mode.
Additionally, this clock can be enabled in Stop mode by setting C1[IRCLKEN] and
C1[IREFSTEN], otherwise this clock is disabled in Stop mode.
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24.4.4 External Reference Clock
The MCG module can support an external reference clock in all modes. See the device
datasheet for external reference frequency range. When C1[IREFS] is set, the external
reference clock will not be used by the FLL. In these mode, the frequency can be equal to
the maximum frequency the chip-level timing specifications will support.
If any of the CME bits are asserted the slow internal reference clock is enabled along
with the enabled external clock monitor. For the case when C6[CME0]=1, a loss of clock
is detected if the OSC0 external reference falls below a minimum frequency (floc_high or
floc_low depending on C2[RANGE0]).
NOTE
All clock monitors must be disabled before entering these lowpower modes: Stop, VLPS, VLPR, VLPW, LLS, and VLLSx.
Upon detect of a loss of clock event, the MCU generates a system reset if the respective
LOCRE bit is set. Otherwise the MCG sets the respective LOCS bit and the MCG
generates a LOCS interrupt request.
24.4.5 MCG Fixed frequency clock
The MCG Fixed Frequency Clock (MCGFFCLK) provides a fixed frequency clock
source for other on-chip peripherals; see the block diagram. This clock is driven by either
the slow clock from the internal reference clock generator or the external reference clock
from the Crystal Oscillator, divided by the FLL reference clock divider. The source of
MCGFFCLK is selected by C1[IREFS].
This clock is synchronized to the peripheral bus clock and is valid only when its
frequency is not more than 1/8 of the MCGOUTCLK frequency. When it is not valid, it is
disabled and held high. The MCGFFCLK is not available when the MCG is in BLPI
mode. This clock is also disabled in Stop mode. The FLL reference clock must be set
within the valid frequency range for the MCGFFCLK.
24.4.6 MCG Auto TRIM (ATM)
The MCG Auto Trim (ATM) is a MCG feature that when enabled, it configures the MCG
hardware to automatically trim the MCG Internal Reference Clocks using an external
clock as a reference. The selection between which MCG IRC clock gets tested and
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Functional Description
enabled is controlled by the ATC[ATMS] control bit (ATC[ATMS]=0 selects the 32 kHz
IRC and ATC[ATMS]=1 selects the 4 MHz IRC). If 4 MHz IRC is selected for the ATM,
a divide by 128 is enabled to divide down the 4 MHz IRC to a range of 31.250 kHz.
When MCG ATM is enabled by writing ATC[ATME] bit to 1, The ATM machine will
start auto trimming the selected IRC clock. During the autotrim process, ATC[ATME]
will remain asserted and will deassert after ATM is completed or an abort occurs. The
MCG ATM is aborted if a write to any of the following control registers is detected : C1,
C3, C4, or ATC or if Stop mode is entered. If an abort occurs, ATC[ATMF] fail flag is
asserted.
The ATM machine uses the bus clock as the external reference clock to perform the IRC
auto-trim. Therefore, it is required that the MCG is configured in a clock mode where the
reference clock used to generate the system clock is the external reference clock such as
FBE clock mode. The MCG must not be configured in a clock mode where selected IRC
ATM clock is used to generate the system clock. The bus clock is also required to be
running with in the range of 8–16 MHz.
To perform the ATM on the selected IRC, the ATM machine uses the successive
approximation technique to adjust the IRC trim bits to generate the desired IRC trimmed
frequency. The ATM SARs each of the ATM IRC trim bits starting with the MSB. For
each trim bit test, the ATM uses a pulse that is generated by the ATM selected IRC clock
to enable a counter that counts number of ATM external clocks. At end of each trim bit,
the ATM external counter value is compared to the ATCV[15:0] register value. Based on
the comparison result, the ATM trim bit under test will get cleared or stay asserted. This
is done until all trim bits have been tested by ATM SAR machine.
Before the ATM can be enabled, the ATM expected count needs to be derived and stored
into the ATCV register. The ATCV expected count is derived based on the required
target Internal Reference Clock (IRC) frequency, and the frequency of the external
reference clock using the following formula:
ATCV
• Fr = Target Internal Reference Clock (IRC) Trimmed Frequency
• Fe = External Clock Frequency
If the auto trim is being performed on the 4 MHz IRC, the calculated expected count
value must be multiplied by 128 before storing it in the ATCV register. Therefore, the
ATCV Expected Count Value for trimming the 4 MHz IRC is calculated using the
following formula.
(128)
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Chapter 24 Multipurpose Clock Generator (MCG)
24.5 Initialization / Application information
This section describes how to initialize and configure the MCG module in an application.
The following sections include examples on how to initialize the MCG and properly
switch between the various available modes.
24.5.1 MCG module initialization sequence
The MCG comes out of reset configured for FEI mode. The internal reference will
stabilize in tirefsts microseconds before the FLL can acquire lock. As soon as the internal
reference is stable, the FLL will acquire lock in tfll_acquire milliseconds.
24.5.1.1 Initializing the MCG
Because the MCG comes out of reset in FEI mode, the only MCG modes that can be
directly switched to upon reset are FEE, FBE, and FBI modes (see Figure 24-11).
Reaching any of the other modes requires first configuring the MCG for one of these
three intermediate modes. Care must be taken to check relevant status bits in the MCG
status register reflecting all configuration changes within each mode.
To change from FEI mode to FEE or FBE modes, follow this procedure:
1. Enable the external clock source by setting the appropriate bits in C2 register.
2. Write to C1 register to select the clock mode.
• If entering FEE mode, set C1[FRDIV] appropriately, clear the C1[IREFS] bit to
switch to the external reference, and leave the C1[CLKS] bits at 2'b00 so that the
output of the FLL is selected as the system clock source.
• If entering FBE, clear the C1[IREFS] bit to switch to the external reference and
change the C1[CLKS] bits to 2'b10 so that the external reference clock is
selected as the system clock source. The C1[FRDIV] bits should also be set
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appropriately here according to the external reference frequency to keep the FLL
reference clock in the range of 31.25 kHz to 39.0625 kHz. Although the FLL is
bypassed, it is still on in FBE mode.
• The internal reference can optionally be kept running by setting the
C1[IRCLKEN] bit. This is useful if the application will switch back and forth
between internal and external modes. For minimum power consumption, leave
the internal reference disabled while in an external clock mode.
3. Once the proper configuration bits have been set, wait for the affected bits in the
MCG status register to be changed appropriately, reflecting that the MCG has moved
into the proper mode.
• If the MCG is in FEE, FBE, or BLPE mode, and C2[EREFS0] was also set in
step 1, wait here for S[OSCINIT0] bit to become set indicating that the external
clock source has finished its initialization cycles and stabilized.
• If in FEE mode, check to make sure the S[IREFST] bit is cleared before moving
on.
• If in FBE mode, check to make sure the S[IREFST] bit is cleared and S[CLKST]
bits have changed to 2'b10 indicating the external reference clock has been
appropriately selected. Although the FLL is bypassed, it is still on in FBE mode.
4. Write to the C4 register to determine the DCO output (MCGFLLCLK) frequency
range.
• By default, with C4[DMX32] cleared to 0, the FLL multiplier for the DCO
output is 640. For greater flexibility, if a mid-low-range FLL multiplier of 1280
is desired instead, set C4[DRST_DRS] bits to 2'b01 for a DCO output frequency
of 40 MHz. If a mid high-range FLL multiplier of 1920 is desired instead, set the
C4[DRST_DRS] bits to 2'b10 for a DCO output frequency of 60 MHz. If a highrange FLL multiplier of 2560 is desired instead, set the C4[DRST_DRS] bits to
2'b11 for a DCO output frequency of 80 MHz.
• When using a 32.768 kHz external reference, if the maximum low-range DCO
frequency that can be achieved with a 32.768 kHz reference is desired, set
C4[DRST_DRS] bits to 2'b00 and set C4[DMX32] bit to 1. The resulting DCO
output (MCGOUTCLK) frequency with the new multiplier of 732 will be 24
MHz.
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• When using a 32.768 kHz external reference, if the maximum mid-range DCO
frequency that can be achieved with a 32.768 kHz reference is desired, set
C4[DRST_DRS] bits to 2'b01 and set C4[DMX32] bit to 1. The resulting DCO
output (MCGOUTCLK) frequency with the new multiplier of 1464 will be 48
MHz.
• When using a 32.768 kHz external reference, if the maximum mid high-range
DCO frequency that can be achieved with a 32.768 kHz reference is desired, set
C4[DRST_DRS] bits to 2'b10 and set C4[DMX32] bit to 1. The resulting DCO
output (MCGOUTCLK) frequency with the new multiplier of 2197 will be 72
MHz.
• When using a 32.768 kHz external reference, if the maximum high-range DCO
frequency that can be achieved with a 32.768 kHz reference is desired, set
C4[DRST_DRS] bits to 2'b11 and set C4[DMX32] bit to 1. The resulting DCO
output (MCGOUTCLK) frequency with the new multiplier of 2929 will be 96
MHz.
5. Wait for the FLL lock time to guarantee FLL is running at new C4[DRST_DRS] and
C4[DMX32] programmed frequency.
To change from FEI clock mode to FBI clock mode, follow this procedure:
1. Change C1[CLKS] bits in C1 register to 2'b01 so that the internal reference clock is
selected as the system clock source.
2. Wait for S[CLKST] bits in the MCG status register to change to 2'b01, indicating
that the internal reference clock has been appropriately selected.
3. Write to the C2 register to determine the IRCS output (IRCSCLK) frequency range.
• By default, with C2[IRCS] cleared to 0, the IRCS selected output clock is the
slow internal reference clock (32 kHz IRC). If the faster IRC is desired, set
C2[IRCS] bit to 1 for a IRCS clock derived from the 4 MHz IRC source.
24.5.2 Using a 32.768 kHz reference
In FEE and FBE modes, if using a 32.768 kHz external reference, at the default FLL
multiplication factor of 640, the DCO output (MCGFLLCLK) frequency is 20.97 MHz at
low-range. If C4[DRST_DRS] bits are set to 2'b01, the multiplication factor is doubled to
1280, and the resulting DCO output frequency is 41.94 MHz at mid-low-range. If
C4[DRST_DRS] bits are set to 2'b10, the multiplication factor is set to 1920, and the
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resulting DCO output frequency is 62.91 MHz at mid high-range. If C4[DRST_DRS] bits
are set to 2'b11, the multiplication factor is set to 2560, and the resulting DCO output
frequency is 83.89 MHz at high-range.
In FBI and FEI modes, setting C4[DMX32] bit is not recommended. If the internal
reference is trimmed to a frequency above 32.768 kHz, the greater FLL multiplication
factor could potentially push the microcontroller system clock out of specification and
damage the part.
24.5.3 MCG mode switching
When switching between operational modes of the MCG, certain configuration bits must
be changed in order to properly move from one mode to another. Each time any of these
bits are changed (C1[IREFS], C1[CLKS], C2[IRCS], or C2[EREFS0]), the
corresponding bits in the MCG status register (IREFST, CLKST, IRCST, or OSCINIT)
must be checked before moving on in the application software.
Additionally, care must be taken to ensure that the reference clock divider (C1[FRDIV])
is set properly for the mode being switched to. For instance, in FEE mode, if using a
4MHz crystal, C1[FRDIV] must be set to 3'b010 (divide-by-128) to devide the external
frequency down to the required frequency between 31.25 and 39.0625 kHz.
In FBE, FEE, FBI, and FEI modes, at any time, the application can switch the FLL
multiplication factor between 640, 1280, 1920, and 2560 with C4[DRST_DRS] bits.
Writes to C4[DRST_DRS] bits will be ignored if C2[LP]=1.
The table below shows MCGOUTCLK frequency calculations using C1[FRDIV]settings
for each clock mode.
Table 24-12. MCGOUTCLK Frequency Calculation Options
Clock Mode
fMCGOUTCLK1
Note
FEI (FLL engaged internal)
(fint * F)
Typical fMCGOUTCLK = 21 MHz
immediately after reset.
FEE (FLL engaged external)
(fext / FLL_R) *F
fext / FLL_R must be in the range of
31.25 kHz to 39.0625 kHz
FBE (FLL bypassed external)
OSCCLK
OSCCLK / FLL_R must be in the
range of 31.25 kHz to 39.0625 kHz
FBI (FLL bypassed internal)
MCGIRCLK
Selectable between slow and fast
IRC
BLPI (Bypassed low power internal)
MCGIRCLK
Selectable between slow and fast
IRC
BLPE (Bypassed low power external)
OSCCLK
1. FLL_R is the reference divider selected by the C1[FRDIV] bits, F is the FLL factor selected by C4[DRST_DRS] and
C4[DMX32] bits.
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Chapter 24 Multipurpose Clock Generator (MCG)
This section will include three mode switching examples using an 4 MHz external
crystal.
24.5.3.1 Example 1: Moving from FEI to BLPE mode: External Crystal
= 4 MHz, MCGOUTCLK frequency = 4 MHz
In this example, the MCG will move through the proper operational modes from FEI to
BLPE to achieve 4 MHz MCGOUTCLK frequency from 4 MHz external crystal
reference. First, the code sequence will be described. Then there is a flowchart that
illustrates the sequence.
1. First, FEI must transition to FBE mode:
a. C2 = 0x1C
• C2[RANGE0] set to 2'b01 because the frequency of 4 MHz is within the
high frequency range.
• C2[HGO0] set to 1 to configure the crystal oscillator for high gain operation.
• C2[EREFS0] set to 1, because a crystal is being used.
b. C1 = 0x90
• C1[CLKS] set to 2'b10 to select external reference clock as system clock
source
• C1[FRDIV] set to 3'b010, or divide-by-128 because 4 MHz / 128 = 31.25
kHz which is in the 31.25 kHz to 39.0625 kHz range required by the FLL
• C1[IREFS] cleared to 0, selecting the external reference clock and enabling
the external oscillator.
c. Loop until S[OSCINIT0] is 1, indicating the crystal selected by C2[EREFS0] has
been initialized.
d. Loop until S[IREFST] is 0, indicating the external reference is the current source
for the reference clock.
e. Loop until S[CLKST] is 2'b10, indicating that the external reference clock is
selected to feed MCGOUTCLK.
2. Then, transition to BLPE:
a. Set C2[LP] to 1.
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Initialization / Application information
START
IN FEI MODE
C2 = 0x1C
C1 = 0x40
NO
CHECK
S[OSCINIT0] = 1?
YES
CHECK
S[IREFST] = 0?
NO
YES
CHECK
NO
S[CLKST] = %10?
YES
C2 = 0x1E
(C2[LP] = 1)
Continue
in BLPE mode
Figure 24-12. Flowchart of FEI to BLPE mode transition using a 4 MHz crystal
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Chapter 24 Multipurpose Clock Generator (MCG)
24.5.3.2 Example 2: Moving from BLPE to BLPI mode: MCGOUTCLK
frequency = 2 MHz
In this example, the MCG will move through the proper operational modes from BLPE
mode with a 4 MHz crystal configured for a 4 MHz MCGOUTCLK frequency (see
previous example) to BLPI mode with a 2 MHz MCGOUTCLK frequency. First, the
code sequence will be described. Then there is a flowchart that illustrates the sequence.
1. First, BLPE must transition to FBE mode:
a. Clear C2[LP] to 0 here to switch to FBE mode.
2. Next, FBE mode transitions into FBI mode:
a. C1 = 0x54
• C1[CLKS] set to 2'b01 to switch the system clock to the internal reference
clock.
• C1[IREFS] set to 1 to select the internal reference clock as the reference
clock source.
• C1[FRDIV] remain unchanged because the reference divider does not affect
the internal reference.
b. Loop until S[IREFST] is 1, indicating the internal reference clock has been
selected as the reference clock source.
c. Loop until S[CLKST] are 2'b01, indicating that the internal reference clock is
selected to feed MCGOUTCLK.
3. Lastly, FBI transitions into BLPI mode with IRCS selecting Fast Internal Reference
Clock.
a. C2 = 0x03
• C2[IRCS] is 1
• C2[LP] is 1
• C2[RANGE0], C2[HGO0], C2[EREFS0], C1[IRCLKEN], and
C1[IREFSTEN] bits are ignored when the C1[IREFS] bit is set. They can
remain set, or be cleared at this point.
b. Loop until S[IRCST] is 1, indicating the internal reference clock is the fast
clock.
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START
IN BLPE MODE
C2 = 0x1C
(C2[LP] = 0)
C1 = 0x64
CHECK
S[IREFST] = 0?
NO
YES
CHECK
S[CLKST] = %01?
NO
YES
C2 = 0x23
CHECK
S[IRCST] = 1?
NO
YES
CONTINUE
IN BLPI MODE
Figure 24-13. Flowchart of BLPE to BLPI mode transition using an 4 MHz crystal
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Chapter 24 Multipurpose Clock Generator (MCG)
24.5.3.3 Example 3: Moving from BLPI to FEE mode
In this example, the MCG will move through the proper operational modes from BLPI
mode at a 32 kHz MCGOUTCLK frequency running off the internal reference clock (see
previous example) to FEE mode using a 4 MHz crystal configured for a 20 MHz
MCGOUTCLK frequency. First, the code sequence will be described. Then there is a
flowchart that illustrates the sequence.
1. First, BLPI must transition to FBI mode.
a. C2 = 0x00
• C2[LP] is 0
2. Next, FBI will transition to FEE mode.
a. C2 = 0x1C
• C2[RANGE0] set to 2'b01 because the frequency of 4 MHz is within the
high frequency range.
• C2[HGO0] set to 1 to configure the crystal oscillator for high gain operation.
• C2[EREFS0] set to 1, because a crystal is being used.
b. C1 = 0x10
• C1[CLKS] set to 2'b00 to select the output of the FLL as system clock
source.
• C1[FRDIV] remain at 3'b010, or divide-by-128 for a reference of 4 MHz /
128 = 31.25 kHz.
• C1[IREFS] cleared to 0, selecting the external reference clock.
c. Loop until S[OSCINIT0] is 1, indicating the crystal selected by the C2[EREFS0]
bit has been initialized.
d. Loop until S[IREFST] is 0, indicating the external reference clock is the current
source for the reference clock.
e. Loop until S[CLKST] are 2'b00, indicating that the output of the FLL is selected
to feed MCGOUTCLK.
f. Now, with a 31.25 kHz reference frequency, a fixed DCO multiplier of 640,
MCGOUTCLK = 31.25 kHz * 640 / 1 = 20 MHz.
g. At this point, by default, the C4[DRST_DRS] bits are set to 2'b00 and
C4[DMX32] is cleared to 0. If the MCGOUTCLK frequency of 40 MHz is
desired instead, set the C4[DRST_DRS] bits to 0x01 to switch the FLL
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Initialization / Application information
multiplication factor from 640 to 1280. To return the MCGOUTCLK frequency
to 20 MHz, set C4[DRST_DRS] bits to 2'b00 again, and the FLL multiplication
factor will switch back to 640.
START
IN BLPI MODE
CHECK
NO
S[IREFST] = 0?
C2 =0x00
YES
C2 = 0x1C
NO
CHECK
S[CLKST] = %00?
C1 =0x10
YES
CONTINUE
CHECK
S[OSCINIT] = 1 ?
NO
IN FEE MODE
YES
Figure 24-14. Flowchart of BLPI to FEE mode transition using an 4 MHz crystal
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Chapter 25
Oscillator (OSC)
25.1 Introduction
NOTE
For the chip-specific implementation details of this module's
instances see the chip configuration information.
The OSC module is a crystal oscillator. The module, in conjunction with an external
crystal or resonator, generates a reference clock for the MCU.
25.2 Features and Modes
Key features of the module are:
• Supports 32 kHz crystals (Low Range mode)
• Voltage and frequency filtering to guarantee clock frequency and stability
• Optionally external input bypass clock from EXTAL signal directly
• One clock for MCU clock system
• Two clocks for on-chip peripherals that can work in Stop modes
Functional Description describes the module's operation in more detail.
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Block Diagram
25.3 Block Diagram
The OSC module uses a crystal or resonator to generate three filtered oscillator clock
signals. Three clocks are output from OSC module: OSCCLK for MCU system,
OSCERCLK for on-chip peripherals, and OSC32KCLK. The OSCCLK can only work in
run mode. OSCERCLK and OSC32KCLK can work in low power modes. For the clock
source assignments, refer to the clock distribution information of this MCU.
Refer to the chip configuration chapter for the external reference clock source in this
MCU.
The following figure shows the block diagram of the OSC module.
EXTAL
XTAL
OSC_CLK_OUT
Mux
OSC Clock Enable
ERCLKEN
XTL_CLK
Oscillator Circuits
OSCERCLK
EN
OSC32KCLK
ERCLKEN
OSC clock selection
EREFSTEN
OSC_EN
4096
Counter
CNT_DONE_4096
Control and Decoding
logic
OSCCLK
STOP
Figure 25-1. OSC Module Block Diagram
25.4 OSC Signal Descriptions
The following table shows the user-accessible signals available for the OSC module.
Refer to signal multiplexing information for this MCU for more details.
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Chapter 25 Oscillator (OSC)
Table 25-1. OSC Signal Descriptions
Signal
Description
EXTAL
External clock/Oscillator input
I
Oscillator output
O
XTAL
I/O
25.5 External Crystal / Resonator Connections
The connections for a crystal/resonator frequency reference are shown in the following
figures. When using low-frequency, low-power mode, the only external component is the
crystal or ceramic resonator itself. In the other oscillator modes, load capacitors (Cx, Cy)
and feedback resistor (RF) are required. The following table shows all possible
connections.
Table 25-2. External Caystal/Resonator Connections
Oscillator Mode
Connections
Low-frequency (32 kHz), low-power
Connection 11
Low-frequency (32 kHz), high-gain
Connection 2/Connection 32
High-frequency (3~32 MHz), low-power
Connection 31
High-frequency (3~32 MHz), high-gain
Connection 3
1. With the low-power mode, the oscillator has the internal feedback resistor RF. Therefore, the feedback resistor must not be
externally with the Connection 3.
2. When the load capacitors (Cx, Cy) are greater than 30 pF, use Connection 3.
OSC
XTAL
VSS
EXTAL
Crystal or Resonator
Figure 25-2. Crystal/Ceramic Resonator Connections - Connection 1
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External Clock Connections
OSC
XTAL
EXTAL
VSS
RF
Crystal or Resonator
Figure 25-3. Crystal/Ceramic Resonator Connections - Connection 2
NOTE
Connection 1 and Connection 2 should use internal capacitors
as the load of the oscillator by configuring the CR[SCxP] bits.
OSC
XTAL
EXTAL
VSS
Cx
Cy
RF
Crystal or Resonator
Figure 25-4. Crystal/Ceramic Resonator Connections - Connection 3
25.6 External Clock Connections
In external clock mode, the pins can be connected as shown below.
NOTE
XTAL can be used as a GPIO when the GPIO alternate function
is configured for it.
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Chapter 25 Oscillator (OSC)
OSC
XTAL
EXTAL
VSS
Clock Input
I/O
Figure 25-5. External Clock Connections
25.7 Memory Map/Register Definitions
Some oscillator module register bits are typically incorporated into other peripherals such
as MCG or SIM.
25.7.1 OSC Memory Map/Register Definition
OSC memory map
Absolute
address
(hex)
4006_5000
Width
Access
(in bits)
Register name
OSC Control Register (OSC0_CR)
8
Reset value
Section/
page
00h
25.71.1/369
R/W
25.71.1 OSC Control Register (OSCx_CR)
NOTE
After OSC is enabled and starts generating the clocks, the
configurations such as low power and frequency range, must
not be changed.
Address: 4006_5000h base + 0h offset = 4006_5000h
Bit
Read
Write
Reset
7
6
ERCLKEN
0
0
0
5
3
2
1
0
EREFSTEN
0
4
SC2P
SC4P
SC8P
SC16P
0
0
0
0
0
0
OSCx_CR field descriptions
Field
7
ERCLKEN
Description
External Reference Enable
Enables external reference clock (OSCERCLK).
Table continues on the next page...
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Functional Description
OSCx_CR field descriptions (continued)
Field
Description
0
1
6
Reserved
5
EREFSTEN
This field is reserved.
This read-only field is reserved and always has the value 0.
External Reference Stop Enable
Controls whether or not the external reference clock (OSCERCLK) remains enabled when MCU enters
Stop mode.
0
1
4
Reserved
3
SC2P
Oscillator 2 pF Capacitor Load Configure
Configures the oscillator load.
Configures the oscillator load.
Disable the selection.
Add 4 pF capacitor to the oscillator load.
Oscillator 8 pF Capacitor Load Configure
Configures the oscillator load.
0
1
0
SC16P
Disable the selection.
Add 2 pF capacitor to the oscillator load.
Oscillator 4 pF Capacitor Load Configure
0
1
1
SC8P
External reference clock is disabled in Stop mode.
External reference clock stays enabled in Stop mode if ERCLKEN is set before entering Stop mode.
This field is reserved.
This read-only field is reserved and always has the value 0.
0
1
2
SC4P
External reference clock is inactive.
External reference clock is enabled.
Disable the selection.
Add 8 pF capacitor to the oscillator load.
Oscillator 16 pF Capacitor Load Configure
Configures the oscillator load.
0
1
Disable the selection.
Add 16 pF capacitor to the oscillator load.
25.8 Functional Description
This following sections provide functional details of the module.
25.8.1 OSC Module States
The states of the OSC module are shown in the following figure. The states and their
transitions between each other are described in this section.
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Chapter 25 Oscillator (OSC)
Off
Oscillator OFF
OSC_CLK_OUT = Static
OSCCLK
not requested
OSCCLK requested
OSCCLK requested
&&
&&
Select OSC internal clock
Select clock from EXTAL signal
Start-Up
External Clock Mode
Oscillator ON, not yet stable
OSC_CLK_OUT = Static
Oscillator ON
OSC_CLK_OUT = EXTAL
CNT_DONE_4096
Stable
Oscillator ON, Stable
OSC_CLK_OUT = XTL_CLK
Figure 25-8. OSC Module State Diagram
NOTE
XTL_CLK is the clock generated internally from OSC circuits.
25.8.1.1 Off
The OSC enters the Off state when the system does not require OSC clocks. Upon
entering this state, XTL_CLK is static unless OSC is configured to select the clock from
the EXTAL pad by clearing the external reference clock selection bit. For details
regarding the external reference clock source in this MCU, refer to the chip configuration
chapter. The EXTAL and XTAL pins are also decoupled from all other oscillator
circuitry in this state. The OSC module circuitry is configured to draw minimal current.
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Functional Description
25.8.1.2 Oscillator Start-Up
The OSC enters start-up state when it is configured to generate clocks (internally the
OSC_EN transitions high) using the internal oscillator circuits by setting the external
reference clock selection bit. In this state, the OSC module is enabled and oscillations are
starting up, but have not yet stabilized. When the oscillation amplitude becomes large
enough to pass through the input buffer, XTL_CLK begins clocking the counter. When
the counter reaches 4096 cycles of XTL_CLK, the oscillator is considered stable and
XTL_CLK is passed to the output clock OSC_CLK_OUT.
25.8.1.3 Oscillator Stable
The OSC enters stable state when it is configured to generate clocks (internally the
OSC_EN transitions high) using the internal oscillator circuits by setting the external
reference clock selection bit and the counter reaches 4096 cycles of XTL_CLK (when
CNT_DONE_4096 is high). In this state, the OSC module is producing a stable output
clock on OSC_CLK_OUT. Its frequency is determined by the external components being
used.
25.8.1.4 External Clock Mode
The OSC enters external clock state when it is enabled and external reference clock
selection bit is cleared. For details regarding external reference clock source in this MCU,
refer to the chip configuration chapter. In this state, the OSC module is set to buffer (with
hysteresis) a clock from EXTAL onto the OSC_CLK_OUT. Its frequency is determined
by the external clock being supplied.
25.8.2 OSC Module Modes
The OSC is a Pierce-type oscillator that supports external crystals or resonators operating
over the frequency ranges shown in Table 25-7. These modes assume the following
conditions: OSC is enabled to generate clocks (OSC_EN=1), configured to generate
clocks internally (MCG_C2[EREFS] = 1), and some or one of the other peripherals
(MCG, Timer, and so on) is configured to use the oscillator output clock
(OSC_CLK_OUT).
Table 25-7. Oscillator Modes
Mode
Frequency Range
Low-frequency, low-power (VLP)
fosc_lo (1 kHz) up to fosc_lo (32.768 kHz)
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Chapter 25 Oscillator (OSC)
NOTE
For information about low power modes of operation used in
this chip and their alignment with some OSC modes, refer to
the chip's Power Management details.
25.8.2.1 Low-Frequency, Low-Power Mode
In low-frequency, low-power mode, the oscillator uses a gain control loop to minimize
power consumption. As the oscillation amplitude increases, the amplifier current is
reduced. This continues until a desired amplitude is achieved at steady-state. This mode
provides low pass frequency filtering as well as hysteresis for voltage filtering and
converts the output to logic levels. In this mode, the internal capacitors could be used, the
internal feedback resistor is connected, and no external resistor should be used.
In this mode, the amplifier inputs, gain-control input, and input buffer input are all
capacitively coupled for leakage tolerance (not sensitive to the DC level of EXTAL).
Also in this mode, all external components except for the resonator itself are integrated,
which includes the load capacitors and feeback resistor that biases EXTAL.
25.8.3 Counter
The oscillator output clock (OSC_CLK_OUT) is gated off until the counter has detected
4096 cycles of its input clock (XTL_CLK). After 4096 cycles are completed, the counter
passes XTL_CLK onto OSC_CLK_OUT. This counting time-out is used to guarantee
output clock stability.
25.8.4 Reference Clock Pin Requirements
The OSC module requires use of both the EXTAL and XTAL pins to generate an output
clock in Oscillator mode, but requires only the EXTAL pin in External clock mode. The
EXTAL and XTAL pins are available for I/O. For the implementation of these pins on
this device, refer to the Signal Multiplexing chapter.
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Reset
25.9 Reset
There is no reset state associated with the OSC module. The counter logic is reset when
the OSC is not configured to generate clocks.
There are no sources of reset requests for the OSC module.
25.10 Low Power Modes Operation
When the MCU enters Stop modes, the OSC is functional depending on ERCLKEN and
EREFSETN bit settings. If both these bits are set, the OSC is in operation. In Low
Leakage Stop (LLS) modes, the OSC holds all register settings. If ERCLKEN and
EREFSTEN bits are set before entry to Low Leakage Stop modes, the OSC is still
functional in these modes. After waking up from Very Low Leakage Stop (VLLSx)
modes, all OSC register bits are reset and initialization is required through software.
25.11 Interrupts
The OSC module does not generate any interrupts.
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Chapter 26
Flash Memory Controller (FMC)
26.1 Introduction
The Flash Memory Controller (FMC) is a memory acceleration unit that provides:
• an interface between bus masters and the 32-bit program flash memory.
• a buffer and a cache that can accelerate program flash memory data transfers.
26.1.1 Overview
The Flash Memory Controller manages the interface between bus masters and the 32-bit
program flash memory. The FMC receives status information detailing the configuration
of the flash memory and uses this information to ensure a proper interface. The FMC
supports 8-bit, 16-bit, and 32-bit read operations from the program flash memory. A write
operation to program flash memory results in a bus error.
In addition, the FMC provides two separate mechanisms for accelerating the interface
between bus masters and program flash memory. A 32-bit speculation buffer can prefetch
the next 32-bit flash memory location, and a 4-way, 4-set program flash memory cache
can store previously accessed program flash memory data for quick access times.
26.1.2 Features
The FMC's features include:
• Interface between bus masters and the 32-bit program flash memory:
• 8-bit, 16-bit, and 32-bit read operations to nonvolatile flash memory.
• Acceleration of data transfer from the program flash memory to the device:
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Modes of operation
• 32-bit prefetch speculation buffer for program flash accesses with controls for
instruction/data access
• 4-way, 4-set, 32-bit line size program flash memory cache for a total of sixteen
32-bit entries with invalidation control
26.2 Modes of operation
The FMC operates only when a bus master accesses the program flash memory. In terms
of chip power modes:
• The FMC operates only in run and wait modes, including VLPR and VLPW modes.
• For any power mode where the program flash memory cannot be accessed, the FMC
is disabled.
26.3 External signal description
The FMC has no external (off-chip) signals.
26.4 Memory map and register descriptions
The MCM's programming model provides control and configuration of the FMC's
features. For details, see the description of the MCM's Platform Control Register
(PLACR).
26.5 Functional description
The FMC is a flash acceleration unit with flexible buffers for user configuration. Besides
managing the interface between bus masters and the program flash memory, the FMC can
be used to customize the program flash memory cache and buffer to provide single-cycle
system clock data access times. Whenever a hit occurs for the prefetch speculation buffer
or the cache (when enabled), the requested data is transferred within a single system
clock.
Upon system reset, the FMC is configured as follows:
• Flash cache is enabled
• Instruction speculation and caching are enabled
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Chapter 26 Flash Memory Controller (FMC)
• Data speculation is disabled
• Data caching is enabled
Though the default configuration provides flash acceleration, advanced users may desire
to customize the FMC buffer configurations to maximize throughput for their use cases.
For example, the user may adjust the controls to enable buffering per access type (data or
instruction).
NOTE
When reconfiguring the FMC, do not program the control and
configuration inputs to the FMC while the program flash
memory is being accessed. Instead, change them with a routine
executing from RAM in supervisor mode.
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Functional description
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Chapter 27
Flash Memory Module (FTFA)
27.1 Introduction
NOTE
For the chip-specific implementation details of this module's
instances see the chip configuration information.
The flash memory module includes the following accessible memory regions:
• Program flash memory for vector space and code store
Flash memory is ideal for single-supply applications, permitting in-the-field erase and
reprogramming operations without the need for any external high voltage power sources.
The flash memory module includes a memory controller that executes commands to
modify flash memory contents. An erased bit reads '1' and a programmed bit reads '0'.
The programming operation is unidirectional; it can only move bits from the '1' state
(erased) to the '0' state (programmed). Only the erase operation restores bits from '0' to
'1'; bits cannot be programmed from a '0' to a '1'.
CAUTION
A flash memory location must be in the erased state before
being programmed. Cumulative programming of bits (back-toback program operations without an intervening erase) within a
flash memory location is not allowed. Re-programming of
existing 0s to 0 is not allowed as this overstresses the device.
The standard shipping condition for flash memory is erased
with security disabled. Data loss over time may occur due to
degradation of the erased ('1') states and/or programmed ('0')
states. Therefore, it is recommended that each flash block or
sector be re-erased immediately prior to factory programming
to ensure that the full data retention capability is achieved.
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Introduction
27.1.1 Features
The flash memory module includes the following features.
NOTE
See the device's Chip Configuration details for the exact
amount of flash memory available on your device.
27.1.1.1 Program Flash Memory Features
• Sector size of 1 Kbyte
• Program flash protection scheme prevents accidental program or erase of stored data
• Automated, built-in, program and erase algorithms with verify
27.1.1.2 Other Flash Memory Module Features
• Internal high-voltage supply generator for flash memory program and erase
operations
• Optional interrupt generation upon flash command completion
• Supports MCU security mechanisms which prevent unauthorized access to the flash
memory contents
27.1.2 Block Diagram
The block diagram of the flash memory module is shown in the following figure.
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Chapter 27 Flash Memory Module (FTFA)
Interrupt
Status
registers
Register access
Memory controller
Program flash
0
Control
registers
To MCU's
flash controller
Figure 27-1. Flash Block Diagram
27.1.3 Glossary
Command write sequence — A series of MCU writes to the flash FCCOB register
group that initiates and controls the execution of flash algorithms that are built into the
flash memory module.
Endurance — The number of times that a flash memory location can be erased and
reprogrammed.
FCCOB (Flash Common Command Object) — A group of flash registers that are used
to pass command, address, data, and any associated parameters to the memory controller
in the flash memory module.
Flash block — A macro within the flash memory module which provides the nonvolatile
memory storage.
Flash Memory Module — All flash blocks plus a flash management unit providing
high-level control and an interface to MCU buses.
IFR — Nonvolatile information register found in each flash block, separate from the
main memory array.
NVM — Nonvolatile memory. A memory technology that maintains stored data during
power-off. The flash array is an NVM using NOR-type flash memory technology.
NVM Normal Mode — An NVM mode that provides basic user access to flash memory
module resources. The CPU or other bus masters initiate flash program and erase
operations (or other flash commands) using writes to the FCCOB register group in the
flash memory module.
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External Signal Description
NVM Special Mode — An NVM mode enabling external, off-chip access to the memory
resources in the flash memory module. A reduced flash command set is available when
the MCU is secured. See the Chip Configuration details for information on when this
mode is used.
Longword — 32 bits of data with an aligned longword having byte-address[1:0] = 00.
Word — 16 bits of data with an aligned word having byte-address[0] = 0.
Program flash — The program flash memory provides nonvolatile storage for vectors
and code store.
Program flash Sector — The smallest portion of the program flash memory
(consecutive addresses) that can be erased.
Retention — The length of time that data can be kept in the NVM without experiencing
errors upon readout. Since erased (1) states are subject to degradation just like
programmed (0) states, the data retention limit may be reached from the last erase
operation (not from the programming time).
RWW— Read-While-Write. The ability to simultaneously read from one memory
resource while commanded operations are active in another memory resource.
Secure — An MCU state conveyed to the flash memory module as described in the Chip
Configuration details for this device. In the secure state, reading and changing NVM
contents is restricted.
27.2 External Signal Description
The flash memory module contains no signals that connect off-chip.
27.3 Memory Map and Registers
This section describes the memory map and registers for the flash memory module. Data
read from unimplemented memory space in the flash memory module is undefined.
Writes to unimplemented or reserved memory space (registers) in the flash memory
module are ignored.
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Chapter 27 Flash Memory Module (FTFA)
27.3.1 Flash Configuration Field Description
The program flash memory contains a 16-byte flash configuration field that stores default
protection settings (loaded on reset) and security information that allows the MCU to
restrict access to the flash memory module.
Flash Configuration Field Byte
Address
Size (Bytes)
Field Description
0x0_0400 - 0x0_0407
8
Backdoor Comparison Key. Refer to
Verify Backdoor Access Key Command
and Unsecuring the Chip Using
Backdoor Key Access.
0x0_0408 - 0x0_040B
4
Program flash protection bytes. Refer to
the description of the Program Flash
Protection Registers (FPROT0-3).
0x0_040F
1
Reserved
0x0_040E
1
Reserved
0x0_040D
1
Flash nonvolatile option byte. Refer to
the description of the Flash Option
Register (FOPT).
0x0_040C
1
Flash security byte. Refer to the
description of the Flash Security
Register (FSEC).
27.3.2 Program Flash IFR Map
The program flash IFR is nonvolatile information memory that can be read freely, but the
user has no erase and limited program capabilities (see the Read Once, Program Once,
and Read Resource commands in Read Once Command, Program Once Command and
Read Resource Command). The contents of the program flash IFR are summarized in the
following table and further described in the subsequent paragraphs.
The program flash IFR is located within the program flash 0 memory block.
Address Range
Size (Bytes)
Field Description
0x00 – 0xBF
192
Reserved
0xC0 – 0xFF
64
Program Once Field
27.3.2.1 Program Once Field
The Program Once Field in the program flash IFR provides 64 bytes of user data storage
separate from the program flash main array. The user can program the Program Once
Field one time only as there is no program flash IFR erase mechanism available to the
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Memory Map and Registers
user. The Program Once Field can be read any number of times. This section of the
program flash IFR is accessed in 4-Byte records using the Read Once and Program Once
commands (see Read Once Command and Program Once Command).
27.3.3 Register Descriptions
The flash memory module contains a set of memory-mapped control and status registers.
NOTE
While a command is running (FSTAT[CCIF]=0), register
writes are not accepted to any register except FCNFG and
FSTAT. The no-write rule is relaxed during the start-up reset
sequence, prior to the initial rise of CCIF. During this
initialization period the user may write any register. All register
writes are also disabled (except for registers FCNFG and
FSTAT) whenever an erase suspend request is active
(FCNFG[ERSSUSP]=1).
FTFA memory map
Absolute
address
(hex)
Register name
Width
Access
(in bits)
Reset value
Section/
page
4002_0000
Flash Status Register (FTFA_FSTAT)
8
R/W
00h
27.33.1/385
4002_0001
Flash Configuration Register (FTFA_FCNFG)
8
R/W
00h
27.33.2/386
4002_0002
Flash Security Register (FTFA_FSEC)
8
R
Undefined
27.33.3/388
4002_0003
Flash Option Register (FTFA_FOPT)
8
R
Undefined
27.33.4/389
4002_0004
Flash Common Command Object Registers
(FTFA_FCCOB3)
8
R/W
00h
27.33.5/390
4002_0005
Flash Common Command Object Registers
(FTFA_FCCOB2)
8
R/W
00h
27.33.5/390
4002_0006
Flash Common Command Object Registers
(FTFA_FCCOB1)
8
R/W
00h
27.33.5/390
4002_0007
Flash Common Command Object Registers
(FTFA_FCCOB0)
8
R/W
00h
27.33.5/390
4002_0008
Flash Common Command Object Registers
(FTFA_FCCOB7)
8
R/W
00h
27.33.5/390
4002_0009
Flash Common Command Object Registers
(FTFA_FCCOB6)
8
R/W
00h
27.33.5/390
4002_000A
Flash Common Command Object Registers
(FTFA_FCCOB5)
8
R/W
00h
27.33.5/390
4002_000B
Flash Common Command Object Registers
(FTFA_FCCOB4)
8
R/W
00h
27.33.5/390
4002_000C
Flash Common Command Object Registers
(FTFA_FCCOBB)
8
R/W
00h
27.33.5/390
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Chapter 27 Flash Memory Module (FTFA)
FTFA memory map (continued)
Absolute
address
(hex)
Width
Access
(in bits)
Register name
Reset value
Section/
page
4002_000D
Flash Common Command Object Registers
(FTFA_FCCOBA)
8
R/W
00h
27.33.5/390
4002_000E
Flash Common Command Object Registers
(FTFA_FCCOB9)
8
R/W
00h
27.33.5/390
4002_000F
Flash Common Command Object Registers
(FTFA_FCCOB8)
8
R/W
00h
27.33.5/390
4002_0010
Program Flash Protection Registers (FTFA_FPROT3)
8
R/W
Undefined
27.33.6/391
4002_0011
Program Flash Protection Registers (FTFA_FPROT2)
8
R/W
Undefined
27.33.6/391
4002_0012
Program Flash Protection Registers (FTFA_FPROT1)
8
R/W
Undefined
27.33.6/391
4002_0013
Program Flash Protection Registers (FTFA_FPROT0)
8
R/W
Undefined
27.33.6/391
27.33.1 Flash Status Register (FTFA_FSTAT)
The FSTAT register reports the operational status of the flash memory module.
The CCIF, RDCOLERR, ACCERR, and FPVIOL bits are readable and writable. The
MGSTAT0 bit is read only. The unassigned bits read 0 and are not writable.
NOTE
When set, the Access Error (ACCERR) and Flash Protection
Violation (FPVIOL) bits in this register prevent the launch of
any more commands until the flag is cleared (by writing a one
to it).
Address: 4002_0000h base + 0h offset = 4002_0000h
Bit
7
6
5
4
3
Read
CCIF
RDCOLERR
ACCERR
FPVIOL
Write
w1c
w1c
w1c
w1c
Reset
0
0
0
0
2
1
0
0
0
0
MGSTAT0
0
0
FTFA_FSTAT field descriptions
Field
7
CCIF
Description
Command Complete Interrupt Flag
The CCIF flag indicates that a flash command has completed. The CCIF flag is cleared by writing a 1 to
CCIF to launch a command, and CCIF stays low until command completion or command violation.
The CCIF bit is reset to 0 but is set to 1 by the memory controller at the end of the reset initialization
sequence. Depending on how quickly the read occurs after reset release, the user may or may not see the
0 hardware reset value.
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Memory Map and Registers
FTFA_FSTAT field descriptions (continued)
Field
Description
0
1
6
RDCOLERR
Flash Read Collision Error Flag
The RDCOLERR error bit indicates that the MCU attempted a read from a flash memory resource that
was being manipulated by a flash command (CCIF=0). Any simultaneous access is detected as a collision
error by the block arbitration logic. The read data in this case cannot be guaranteed. The RDCOLERR bit
is cleared by writing a 1 to it. Writing a 0 to RDCOLERR has no effect.
0
1
5
ACCERR
No collision error detected
Collision error detected
Flash Access Error Flag
The ACCERR error bit indicates an illegal access has occurred to a flash memory resource caused by a
violation of the command write sequence or issuing an illegal flash command. While ACCERR is set, the
CCIF flag cannot be cleared to launch a command. The ACCERR bit is cleared by writing a 1 to it. Writing
a 0 to the ACCERR bit has no effect.
0
1
4
FPVIOL
Flash command in progress
Flash command has completed
No access error detected
Access error detected
Flash Protection Violation Flag
The FPVIOL error bit indicates an attempt was made to program or erase an address in a protected area
of program flash memory during a command write sequence . While FPVIOL is set, the CCIF flag cannot
be cleared to launch a command. The FPVIOL bit is cleared by writing a 1 to it. Writing a 0 to the FPVIOL
bit has no effect.
0
1
No protection violation detected
Protection violation detected
3–1
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
0
MGSTAT0
Memory Controller Command Completion Status Flag
The MGSTAT0 status flag is set if an error is detected during execution of a flash command or during the
flash reset sequence. As a status flag, this bit cannot (and need not) be cleared by the user like the other
error flags in this register.
The value of the MGSTAT0 bit for "command-N" is valid only at the end of the "command-N" execution
when CCIF=1 and before the next command has been launched. At some point during the execution of
"command-N+1," the previous result is discarded and any previous error is cleared.
27.33.2 Flash Configuration Register (FTFA_FCNFG)
This register provides information on the current functional state of the flash memory
module.
The erase control bits (ERSAREQ and ERSSUSP) have write restrictions. The
unassigned bits read as noted and are not writable.
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Chapter 27 Flash Memory Module (FTFA)
Address: 4002_0000h base + 1h offset = 4002_0001h
Bit
Read
Write
Reset
7
6
5
CCIE
RDCOLLIE
0
0
ERSAREQ
0
4
ERSSUSP
0
3
2
1
0
0
0
0
0
0
0
0
0
FTFA_FCNFG field descriptions
Field
7
CCIE
Description
Command Complete Interrupt Enable
The CCIE bit controls interrupt generation when a flash command completes.
0
1
6
RDCOLLIE
Read Collision Error Interrupt Enable
The RDCOLLIE bit controls interrupt generation when a flash memory read collision error occurs.
0
1
5
ERSAREQ
Command complete interrupt disabled
Command complete interrupt enabled. An interrupt request is generated whenever the FSTAT[CCIF]
flag is set.
Read collision error interrupt disabled
Read collision error interrupt enabled. An interrupt request is generated whenever a flash memory
read collision error is detected (see the description of FSTAT[RDCOLERR]).
Erase All Request
This bit issues a request to the memory controller to execute the Erase All Blocks command and release
security. ERSAREQ is not directly writable but is under indirect user control. Refer to the device's Chip
Configuration details on how to request this command.
The ERSAREQ bit sets when an erase all request is triggered external to the flash memory module and
CCIF is set (no command is currently being executed). ERSAREQ is cleared by the flash memory module
when the operation completes.
0
1
4
ERSSUSP
No request or request complete
Request to:
1. run the Erase All Blocks command,
2. verify the erased state,
3. program the security byte in the Flash Configuration Field to the unsecure state, and
4. release MCU security by setting the FSEC[SEC] field to the unsecure state.
Erase Suspend
The ERSSUSP bit allows the user to suspend (interrupt) the Erase Flash Sector command while it is
executing.
0
1
No suspend requested
Suspend the current Erase Flash Sector command execution.
3
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
2
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
1
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
0
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
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Memory Map and Registers
27.33.3 Flash Security Register (FTFA_FSEC)
This read-only register holds all bits associated with the security of the MCU and flash
memory module.
During the reset sequence, the register is loaded with the contents of the flash security
byte in the Flash Configuration Field located in program flash memory. The flash basis
for the values is signified by X in the reset value.
Address: 4002_0000h base + 2h offset = 4002_0002h
Bit
7
Read
6
5
KEYEN
4
3
MEEN
2
1
FSLACC
0
SEC
Write
Reset
x*
x*
x*
x*
x*
x*
x*
x*
* Notes:
• x = Undefined at reset.
FTFA_FSEC field descriptions
Field
7–6
KEYEN
Description
Backdoor Key Security Enable
These bits enable and disable backdoor key access to the flash memory module.
00
01
10
11
5–4
MEEN
Mass Erase Enable Bits
Enables and disables mass erase capability of the flash memory module. The state of the MEEN bits is
only relevant when the SEC bits are set to secure outside of NVM Normal Mode. When the SEC field is
set to unsecure, the MEEN setting does not matter.
00
01
10
11
3–2
FSLACC
Backdoor key access disabled
Backdoor key access disabled (preferred KEYEN state to disable backdoor key access)
Backdoor key access enabled
Backdoor key access disabled
Mass erase is enabled
Mass erase is enabled
Mass erase is disabled
Mass erase is enabled
Freescale Failure Analysis Access Code
These bits enable or disable access to the flash memory contents during returned part failure analysis at
Freescale. When SEC is secure and FSLACC is denied, access to the program flash contents is denied
and any failure analysis performed by Freescale factory test must begin with a full erase to unsecure the
part.
When access is granted (SEC is unsecure, or SEC is secure and FSLACC is granted), Freescale factory
testing has visibility of the current flash contents. The state of the FSLACC bits is only relevant when the
SEC bits are set to secure. When the SEC field is set to unsecure, the FSLACC setting does not matter.
Table continues on the next page...
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Chapter 27 Flash Memory Module (FTFA)
FTFA_FSEC field descriptions (continued)
Field
Description
00
01
10
11
1–0
SEC
Freescale factory access granted
Freescale factory access denied
Freescale factory access denied
Freescale factory access granted
Flash Security
These bits define the security state of the MCU. In the secure state, the MCU limits access to flash
memory module resources. The limitations are defined per device and are detailed in the Chip
Configuration details. If the flash memory module is unsecured using backdoor key access, the SEC bits
are forced to 10b.
00
01
10
11
MCU security status is secure
MCU security status is secure
MCU security status is unsecure (The standard shipping condition of the flash memory module is
unsecure.)
MCU security status is secure
27.33.4 Flash Option Register (FTFA_FOPT)
The flash option register allows the MCU to customize its operations by examining the
state of these read-only bits, which are loaded from NVM at reset. The function of the
bits is defined in the device's Chip Configuration details.
All bits in the register are read-only .
During the reset sequence, the register is loaded from the flash nonvolatile option byte in
the Flash Configuration Field located in program flash memory. The flash basis for the
values is signified by X in the reset value.
Address: 4002_0000h base + 3h offset = 4002_0003h
Bit
7
6
5
4
Read
3
2
1
0
x*
x*
x*
x*
OPT
Write
Reset
x*
x*
x*
x*
* Notes:
• x = Undefined at reset.
FTFA_FOPT field descriptions
Field
7–0
OPT
Description
Nonvolatile Option
These bits are loaded from flash to this register at reset. Refer to the device's Chip Configuration details
for the definition and use of these bits.
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Memory Map and Registers
27.33.5 Flash Common Command Object Registers
(FTFA_FCCOBn)
The FCCOB register group provides 12 bytes for command codes and parameters. The
individual bytes within the set append a 0-B hex identifier to the FCCOB register name:
FCCOB0, FCCOB1, ..., FCCOBB.
Address: 4002_0000h base + 4h offset + (1d × i), where i=0d to 11d
Bit
Read
Write
Reset
7
6
5
4
3
2
1
0
0
0
0
0
CCOBn
0
0
0
0
FTFA_FCCOBn field descriptions
Field
Description
7–0
CCOBn
The FCCOB register provides a command code and relevant parameters to the memory controller. The
individual registers that compose the FCCOB data set can be written in any order, but you must provide all
needed values, which vary from command to command. First, set up all required FCCOB fields and then
initiate the command’s execution by writing a 1 to the FSTAT[CCIF] bit. This clears the CCIF bit, which
locks all FCCOB parameter fields and they cannot be changed by the user until the command completes
(CCIF returns to 1). No command buffering or queueing is provided; the next command can be loaded
only after the current command completes.
Some commands return information to the FCCOB registers. Any values returned to FCCOB are available
for reading after the FSTAT[CCIF] flag returns to 1 by the memory controller.
The following table shows a generic flash command format. The first FCCOB register, FCCOB0, always
contains the command code. This 8-bit value defines the command to be executed. The command code is
followed by the parameters required for this specific flash command, typically an address and/or data
values.
NOTE: The command parameter table is written in terms of FCCOB Number (which is equivalent to the
byte number). This number is a reference to the FCCOB register name and is not the register
address.
FCCOB Number
Typical Command Parameter Contents [7:0]
0
FCMD (a code that defines the flash command)
1
Flash address [23:16]
2
Flash address [15:8]
3
Flash address [7:0]
4
Data Byte 0
5
Data Byte 1
6
Data Byte 2
7
Data Byte 3
8
Data Byte 4
9
Data Byte 5
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Chapter 27 Flash Memory Module (FTFA)
FTFA_FCCOBn field descriptions (continued)
Field
Description
FCCOB Number
Typical Command Parameter Contents [7:0]
A
Data Byte 6
B
Data Byte 7
FCCOB Endianness and Multi-Byte Access :
The FCCOB register group uses a big endian addressing convention. For all command parameter fields
larger than 1 byte, the most significant data resides in the lowest FCCOB register number. The FCCOB
register group may be read and written as individual bytes, aligned words (2 bytes) or aligned longwords
(4 bytes).
27.33.6 Program Flash Protection Registers (FTFA_FPROTn)
The FPROT registers define which logical program flash regions are protected from
program and erase operations. Protected flash regions cannot have their content changed;
that is, these regions cannot be programmed and cannot be erased by any flash command.
Unprotected regions can be changed by program and erase operations.
The four FPROT registers allow up to 32 protectable regions. Each bit protects a 1/32
region of the program flash memory except for memory configurations with less than 32
Kbytes of program flash where each assigned bit protects 1 Kbyte . For configurations
with 24 Kbytes of program flash memory or less, FPROT0 is not used. For configurations
with 16 Kbytes of program flash memory or less, FPROT1 is not used. For configurations
with 8 Kbytes of program flash memory, FPROT2 is not used. The bitfields are defined
in each register as follows:
Program flash protection register
Program flash protection bits
FPROT0
PROT[31:24]
FPROT1
PROT[23:16]
FPROT2
PROT[15:8]
FPROT3
PROT[7:0]
During the reset sequence, the FPROT registers are loaded with the contents of the
program flash protection bytes in the Flash Configuration Field as indicated in the
following table.
Program flash protection register
Flash Configuration Field offset address
FPROT0
0x000B
FPROT1
0x000A
Table continues on the next page...
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Functional Description
Program flash protection register
Flash Configuration Field offset address
FPROT2
0x0009
FPROT3
0x0008
To change the program flash protection that is loaded during the reset sequence,
unprotect the sector of program flash memory that contains the Flash Configuration
Field. Then, reprogram the program flash protection byte.
Address: 4002_0000h base + 10h offset + (1d × i), where i=0d to 3d
Bit
Read
Write
Reset
7
6
5
4
3
2
1
0
x*
x*
x*
x*
PROT
x*
x*
x*
x*
* Notes:
• x = Undefined at reset.
FTFA_FPROTn field descriptions
Field
7–0
PROT
Description
Program Flash Region Protect
Each program flash region can be protected from program and erase operations by setting the associated
PROT bit.
In NVM Normal mode: The protection can only be increased, meaning that currently unprotected memory
can be protected, but currently protected memory cannot be unprotected. Since unprotected regions are
marked with a 1 and protected regions use a 0, only writes changing 1s to 0s are accepted. This 1-to-0
transition check is performed on a bit-by-bit basis. Those FPROT bits with 1-to-0 transitions are accepted
while all bits with 0-to-1 transitions are ignored.
In NVM Special mode: All bits of FPROT are writable without restriction. Unprotected areas can be
protected and protected areas can be unprotected.
Restriction: The user must never write to any FPROT register while a command is running (CCIF=0).
Trying to alter data in any protected area in the program flash memory results in a protection violation
error and sets the FSTAT[FPVIOL] bit. A full block erase of a program flash block is not possible if it
contains any protected region.
Each bit in the 32-bit protection register represents 1/32 of the total program flash except for
configurations where program flash memory is less than 32 Kbytes. For configurations with less than 32
Kbytes of program flash memory, each assigned bit represents 1 Kbyte.
0
1
Program flash region is protected.
Program flash region is not protected
27.4 Functional Description
The following sections describe functional details of the flash memory module.
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27.4.1 Flash Protection
Individual regions within the flash memory can be protected from program and erase
operations. Protection is controlled by the following registers:
• FPROTn — Four registers that protect 32 regions of the program flash memory as
shown in the following figure
Program flash
0x0_0000
Last program flash address
Program flash size / 32
FPROT3[PROT0]
Program flash size / 32
FPROT3[PROT1]
Program flash size / 32
FPROT3[PROT2]
Program flash size / 32
FPROT3[PROT3]
Program flash size / 32
FPROT0[PROT29]
Program flash size / 32
FPROT0[PROT30]
Program flash size / 32
FPROT0[PROT31]
Figure 27-24. Program flash protection
27.4.2 Interrupts
The flash memory module can generate interrupt requests to the MCU upon the
occurrence of various flash events. These interrupt events and their associated status and
control bits are shown in the following table.
Table 27-24. Flash Interrupt Sources
Flash Event
Readable
Interrupt
Status Bit
Enable Bit
Flash Command Complete
FSTAT[CCIF]
FCNFG[CCIE]
Flash Read Collision Error
FSTAT[RDCOLERR]
FCNFG[RDCOLLIE]
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Functional Description
Note
Vector addresses and their relative interrupt priority are
determined at the MCU level.
Some devices also generate a bus error response as a result of a Read Collision Error
event. See the chip configuration information to determine if a bus error response is also
supported.
27.4.3 Flash Operation in Low-Power Modes
27.4.3.1 Wait Mode
When the MCU enters wait mode, the flash memory module is not affected. The flash
memory module can recover the MCU from wait via the command complete interrupt
(see Interrupts).
27.4.3.2 Stop Mode
When the MCU requests stop mode, if a flash command is active (CCIF = 0) the
command execution completes before the MCU is allowed to enter stop mode.
CAUTION
The MCU should never enter stop mode while any flash
command is running (CCIF = 0).
NOTE
While the MCU is in very-low-power modes (VLPR, VLPW,
VLPS), the flash memory module does not accept flash
commands.
27.4.4 Functional Modes of Operation
The flash memory module has two operating modes: NVM Normal and NVM Special.
The operating mode affects the command set availability (see Table 27-25). Refer to the
Chip Configuration details of this device for how to activate each mode.
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27.4.5 Flash Reads and Ignored Writes
The flash memory module requires only the flash address to execute a flash memory
read.
The MCU must not read from the flash memory while commands are running (as
evidenced by CCIF=0) on that block. Read data cannot be guaranteed from a flash block
while any command is processing within that block. The block arbitration logic detects
any simultaneous access and reports this as a read collision error (see the
FSTAT[RDCOLERR] bit).
27.4.6 Read While Write (RWW)
The following simultaneous accesses are not allowed:
• Reading from program flash memory space while a flash command is active
(CCIF=0).
27.4.7 Flash Program and Erase
All flash functions except read require the user to setup and launch a flash command
through a series of peripheral bus writes. The user cannot initiate any further flash
commands until notified that the current command has completed. The flash command
structure and operation are detailed in Flash Command Operations.
27.4.8 Flash Command Operations
Flash command operations are typically used to modify flash memory contents. The next
sections describe:
• The command write sequence used to set flash command parameters and launch
execution
• A description of all flash commands available
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Functional Description
27.4.8.1 Command Write Sequence
Flash commands are specified using a command write sequence illustrated in Figure
27-25. The flash memory module performs various checks on the command (FCCOB)
content and continues with command execution if all requirements are fulfilled.
Before launching a command, the ACCERR and FPVIOL bits in the FSTAT register
must be zero and the CCIF flag must read 1 to verify that any previous command has
completed. If CCIF is zero, the previous command execution is still active, a new
command write sequence cannot be started, and all writes to the FCCOB registers are
ignored.
27.4.8.1.1
Load the FCCOB Registers
The user must load the FCCOB registers with all parameters required by the desired flash
command. The individual registers that make up the FCCOB data set can be written in
any order.
27.4.8.1.2
Launch the Command by Clearing CCIF
Once all relevant command parameters have been loaded, the user launches the command
by clearing the FSTAT[CCIF] bit by writing a '1' to it. The CCIF flag remains zero until
the flash command completes.
The FSTAT register contains a blocking mechanism that prevents a new command from
launching (can't clear CCIF) if the previous command resulted in an access error
(FSTAT[ACCERR]=1) or a protection violation (FSTAT[FPVIOL]=1). In error
scenarios, two writes to FSTAT are required to initiate the next command: the first write
clears the error flags, the second write clears CCIF.
27.4.8.1.3
Command Execution and Error Reporting
The command processing has several steps:
1. The flash memory module reads the command code and performs a series of
parameter checks and protection checks, if applicable, which are unique to each
command.
If the parameter check fails, the FSTAT[ACCERR] (access error) flag is set.
ACCERR reports invalid instruction codes and out-of bounds addresses. Usually,
access errors suggest that the command was not set-up with valid parameters in the
FCCOB register group.
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Program and erase commands also check the address to determine if the operation is
requested to execute on protected areas. If the protection check fails, the
FSTAT[FPVIOL] (protection error) flag is set.
Command processing never proceeds to execution when the parameter or protection
step fails. Instead, command processing is terminated after setting the FSTAT[CCIF]
bit.
2. If the parameter and protection checks pass, the command proceeds to execution.
Run-time errors, such as failure to erase verify, may occur during the execution
phase. Run-time errors are reported in the FSTAT[MGSTAT0] bit. A command may
have access errors, protection errors, and run-time errors, but the run-time errors are
not seen until all access and protection errors have been corrected.
3. Command execution results, if applicable, are reported back to the user via the
FCCOB and FSTAT registers.
4. The flash memory module sets the FSTAT[CCIF] bit signifying that the command
has completed.
The flow for a generic command write sequence is illustrated in the following figure.
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Functional Description
START
Read: FSTAT register
FCCOB
Availability Check
no
CCIF
= ‘1’?
Previous command complete?
yes
Access Error and
Protection Violation
Check
Results from previous command
yes
ACCERR/
FPVIOL
Set?
Clear the old errors
Write 0x30 to FSTAT register
no
Write to the FCCOB registers
to load the required command parameter.
More
Parameters?
yes
no
Clear the CCIF to launch the command
Write 0x80 to FSTAT register
EXIT
Figure 27-25. Generic Flash Command Write Sequence Flowchart
27.4.8.2 Flash Commands
The following table summarizes the function of all flash commands.
FCMD
Command
Program flash
Function
0x01
Read 1s Section
×
Verify that a given number of
program flash locations from
a starting address are
erased.
0x02
Program Check
×
Tests previously-programmed
locations at margin read
levels.
0x03
Read Resource
IFR, ID
Read 4 bytes from program
flash IFR or version ID.
0x06
Program Longword
×
Program 4 bytes in a program
flash block.
Table continues on the next page...
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FCMD
Command
Program flash
Function
0x09
Erase Flash Sector
×
Erase all bytes in a program
flash sector.
0x40
Read 1s All Blocks
×
Verify that the program flash
block is erased then release
MCU security.
0x41
Read Once
IFR
Read 4 bytes of a dedicated
64 byte field in the program
flash 0 IFR.
0x43
Program Once
IFR
One-time program of 4 bytes
of a dedicated 64-byte field in
the program flash 0 IFR.
0x44
Erase All Blocks
×
Erase the program flash
block, verify-erase and
release MCU security.
NOTE:
0x45
Verify Backdoor Access Key
×
An erase is only
possible when all
memory locations
are unprotected.
Release MCU security after
comparing a set of usersupplied security keys to
those stored in the program
flash.
27.4.8.3 Flash Commands by Mode
The following table shows the flash commands that can be executed in each flash
operating mode.
Table 27-25. Flash Commands by Mode
FCMD
Command
0x01
NVM Normal
NVM Special
Unsecure
Secure
MEEN=10
Unsecure
Secure
MEEN=10
Read 1s Section
×
×
×
×
—
—
0x02
Program Check
×
×
×
×
—
—
0x03
Read Resource
×
×
×
×
—
—
0x06
Program Longword
×
×
×
×
—
—
0x09
Erase Flash Sector
×
×
×
×
—
—
0x40
Read 1s All Blocks
×
×
×
×
×
—
0x41
Read Once
×
×
×
×
—
—
0x43
Program Once
×
×
×
×
—
—
0x44
Erase All Blocks
×
×
×
×
×
—
0x45
Verify Backdoor Access
Key
×
×
×
×
—
—
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Functional Description
27.4.9 Margin Read Commands
The Read-1s commands (Read 1s All Blocks and Read 1s Section) and the Program
Check command have a margin choice parameter that allows the user to apply nonstandard read reference levels to the program flash array reads performed by these
commands. Using the preset 'user' and 'factory' margin levels, these commands perform
their associated read operations at tighter tolerances than a 'normal' read. These nonstandard read levels are applied only during the command execution. All simple
(uncommanded) flash array reads to the MCU always use the standard, un-margined, read
reference level.
Only the 'normal' read level should be employed during normal flash usage. The nonstandard, 'user' and 'factory' margin levels should be employed only in special cases.
They can be used during special diagnostic routines to gain confidence that the device is
not suffering from the end-of-life data loss customary of flash memory devices.
Erased ('1') and programmed ('0') bit states can degrade due to elapsed time and data
cycling (number of times a bit is erased and re-programmed). The lifetime of the erased
states is relative to the last erase operation. The lifetime of the programmed states is
measured from the last program time.
The 'user' and 'factory' levels become, in effect, a minimum safety margin; i.e. if the reads
pass at the tighter tolerances of the 'user' and 'factory' margins, then the 'normal' reads
have at least this much safety margin before they experience data loss.
The 'user' margin is a small delta to the normal read reference level. 'User' margin levels
can be employed to check that flash memory contents have adequate margin for normal
level read operations. If unexpected read results are encountered when checking flash
memory contents at the 'user' margin levels, loss of information might soon occur during
'normal' readout.
The 'factory' margin is a bigger deviation from the norm, a more stringent read criteria
that should only be attempted immediately (or very soon) after completion of an erase or
program command, early in the cycling life. 'Factory' margin levels can be used to check
that flash memory contents have adequate margin for long-term data retention at the
normal level setting. If unexpected results are encountered when checking flash memory
contents at 'factory' margin levels, the flash memory contents should be erased and
reprogrammed.
CAUTION
Factory margin levels must only be used during verify of the
initial factory programming.
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Chapter 27 Flash Memory Module (FTFA)
27.4.10 Flash Command Description
This section describes all flash commands that can be launched by a command write
sequence. The flash memory module sets the FSTAT[ACCERR] bit and aborts the
command execution if any of the following illegal conditions occur:
• There is an unrecognized command code in the FCCOB FCMD field.
• There is an error in a FCCOB field for the specific commands. Refer to the error
handling table provided for each command.
Ensure that the ACCERR and FPVIOL bits in the FSTAT register are cleared prior to
starting the command write sequence. As described in Launch the Command by Clearing
CCIF, a new command cannot be launched while these error flags are set.
Do not attempt to read a flash block while the flash memory module is running a
command (CCIF = 0) on that same block. The flash memory module may return invalid
data to the MCU with the collision error flag (FSTAT[RDCOLERR]) set.
CAUTION
Flash data must be in the erased state before being
programmed. Cumulative programming of bits (adding more
zeros) is not allowed.
27.4.10.1 Read 1s Section Command
The Read 1s Section command checks if a section of program flash memory is erased to
the specified read margin level. The Read 1s Section command defines the starting
address and the number of longwords to be verified.
Table 27-26. Read 1s Section Command FCCOB Requirements
FCCOB Number
FCCOB Contents [7:0]
0
0x01 (RD1SEC)
1
Flash address [23:16] of the first longword to be verified
2
Flash address [15:8] of the first longword to be verified
3
Flash address [7:0]1 of the first longword to be verified
4
Number of longwords to be verified [15:8]
5
Number of longwords to be verified [7:0]
6
Read-1 Margin Choice
1. Must be longword aligned (Flash address [1:0] = 00).
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Functional Description
Upon clearing CCIF to launch the Read 1s Section command, the flash memory module
sets the read margin for 1s according to Table 27-27 and then reads all locations within
the specified section of flash memory. If the flash memory module fails to read all 1s (i.e.
the flash section is not erased), the FSTAT[MGSTAT0] bit is set. The CCIF flag sets
after the Read 1s Section operation completes.
Table 27-27. Margin Level Choices for Read 1s Section
Read Margin Choice
Margin Level Description
0x00
Use the 'normal' read level for 1s
0x01
Apply the 'User' margin to the normal read-1 level
0x02
Apply the 'Factory' margin to the normal read-1 level
Table 27-28. Read 1s Section Command Error Handling
Error Condition
Error Bit
Command not available in current mode/security
FSTAT[ACCERR]
An invalid margin code is supplied
FSTAT[ACCERR]
An invalid flash address is supplied
FSTAT[ACCERR]
Flash address is not longword aligned
FSTAT[ACCERR]
The requested section crosses a Flash block boundary
FSTAT[ACCERR]
The requested number of longwords is zero
FSTAT[ACCERR]
Read-1s fails
FSTAT[MGSTAT0]
27.4.10.2 Program Check Command
The Program Check command tests a previously programmed program flash longword to
see if it reads correctly at the specified margin level.
Table 27-29. Program Check Command FCCOB Requirements
FCCOB Number
FCCOB Contents [7:0]
0
0x02 (PGMCHK)
1
Flash address [23:16]
2
Flash address [15:8]
3
Flash address [7:0]1
4
Margin Choice
8
Byte 0 expected data
9
Byte 1 expected data
A
Byte 2 expected data
B
Byte 3 expected data
1. Must be longword aligned (Flash address [1:0] = 00).
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Upon clearing CCIF to launch the Program Check command, the flash memory module
sets the read margin for 1s according to Table 27-30, reads the specified longword, and
compares the actual read data to the expected data provided by the FCCOB. If the
comparison at margin-1 fails, the FSTAT[MGSTAT0] bit is set.
The flash memory module then sets the read margin for 0s, re-reads, and compares again.
If the comparison at margin-0 fails, the FSTAT[MGSTAT0] bit is set. The CCIF flag is
set after the Program Check operation completes.
The supplied address must be longword aligned (the lowest two bits of the byte address
must be 00):
• Byte 3 data is written to the supplied byte address ('start'),
• Byte 2 data is programmed to byte address start+0b01,
• Byte 1 data is programmed to byte address start+0b10,
• Byte 0 data is programmed to byte address start+0b11.
NOTE
See the description of margin reads, Margin Read Commands
Table 27-30. Margin Level Choices for Program Check
Read Margin Choice
Margin Level Description
0x01
Read at 'User' margin-1 and 'User' margin-0
0x02
Read at 'Factory' margin-1 and 'Factory' margin-0
Table 27-31. Program Check Command Error Handling
Error Condition
Error Bit
Command not available in current mode/security
FSTAT[ACCERR]
An invalid flash address is supplied
FSTAT[ACCERR]
Flash address is not longword aligned
FSTAT[ACCERR]
An invalid margin choice is supplied
FSTAT[ACCERR]
Either of the margin reads does not match the expected data
FSTAT[MGSTAT0]
27.4.10.3 Read Resource Command
The Read Resource command allows the user to read data from special-purpose memory
resources located within the flash memory module. The special-purpose memory
resources available include program flash IFR space and the Version ID field. Each
resource is assigned a select code as shown in Table 27-33.
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Functional Description
Table 27-32. Read Resource Command FCCOB Requirements
FCCOB Number
FCCOB Contents [7:0]
0
0x03 (RDRSRC)
1
Flash address [23:16]
2
Flash address [15:8]
3
Flash address [7:0]1
Returned Values
4
Read Data [31:24]
5
Read Data [23:16]
6
Read Data [15:8]
7
Read Data [7:0]
User-provided values
8
Resource Select Code (see Table 27-33)
1. Must be longword aligned (Flash address [1:0] = 00).
Table 27-33. Read Resource Select Codes
Resource
Select Code
Description
Resource Size
Local Address Range
0x00
Program Flash 0 IFR
256 Bytes
0x00_0000 - 0x00_00FF
0x011
Version ID
8 Bytes
0x00_0000 - 0x00_0007
1. Located in program flash 0 reserved space.
After clearing CCIF to launch the Read Resource command, four consecutive bytes are
read from the selected resource at the provided relative address and stored in the FCCOB
register. The CCIF flag sets after the Read Resource operation completes. The Read
Resource command exits with an access error if an invalid resource code is provided or if
the address for the applicable area is out-of-range.
Table 27-34. Read Resource Command Error Handling
Error Condition
Error Bit
Command not available in current mode/security
FSTAT[ACCERR]
An invalid resource code is entered
FSTAT[ACCERR]
Flash address is out-of-range for the targeted resource.
FSTAT[ACCERR]
Flash address is not longword aligned
FSTAT[ACCERR]
27.4.10.4 Program Longword Command
The Program Longword command programs four previously-erased bytes in the program
flash memory using an embedded algorithm.
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Chapter 27 Flash Memory Module (FTFA)
CAUTION
A flash memory location must be in the erased state before
being programmed. Cumulative programming of bits (back-toback program operations without an intervening erase) within a
flash memory location is not allowed. Re-programming of
existing 0s to 0 is not allowed as this overstresses the device.
Table 27-35. Program Longword Command FCCOB Requirements
FCCOB Number
FCCOB Contents [7:0]
0
0x06 (PGM4)
1
Flash address [23:16]
2
Flash address [15:8]
3
Flash address [7:0]1
4
Byte 0 program value
5
Byte 1 program value
6
Byte 2 program value
7
Byte 3 program value
1. Must be longword aligned (Flash address [1:0] = 00).
Upon clearing CCIF to launch the Program Longword command, the flash memory
module programs the data bytes into the flash using the supplied address. The targeted
flash locations must be currently unprotected (see the description of the FPROT registers)
to permit execution of the Program Longword operation.
The programming operation is unidirectional. It can only move NVM bits from the erased
state ('1') to the programmed state ('0'). Erased bits that fail to program to the '0' state are
flagged as errors in FSTAT[MGSTAT0]. The CCIF flag is set after the Program
Longword operation completes.
The supplied address must be longword aligned (flash address [1:0] = 00):
•
•
•
•
Byte 3 data is written to the supplied byte address ('start'),
Byte 2 data is programmed to byte address start+0b01,
Byte 1 data is programmed to byte address start+0b10, and
Byte 0 data is programmed to byte address start+0b11.
Table 27-36. Program Longword Command Error Handling
Error Condition
Error Bit
Command not available in current mode/security
FSTAT[ACCERR]
An invalid flash address is supplied
FSTAT[ACCERR]
Flash address is not longword aligned
FSTAT[ACCERR]
Flash address points to a protected area
FSTAT[FPVIOL]
Table continues on the next page...
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Functional Description
Table 27-36. Program Longword Command Error Handling (continued)
Error Condition
Error Bit
Any errors have been encountered during the verify operation
FSTAT[MGSTAT0]
27.4.10.5 Erase Flash Sector Command
The Erase Flash Sector operation erases all addresses in a flash sector.
Table 27-37. Erase Flash Sector Command FCCOB Requirements
FCCOB Number
FCCOB Contents [7:0]
0
0x09 (ERSSCR)
1
Flash address [23:16] in the flash sector to be erased
2
Flash address [15:8] in the flash sector to be erased
3
Flash address [7:0]1 in the flash sector to be erased
1. Must be longword aligned (flash address [1:0] = 00).
After clearing CCIF to launch the Erase Flash Sector command, the flash memory
module erases the selected program flash sector and then verifies that it is erased. The
Erase Flash Sector command aborts if the selected sector is protected (see the description
of the FPROT registers). If the erase-verify fails the FSTAT[MGSTAT0] bit is set. The
CCIF flag is set after the Erase Flash Sector operation completes. The Erase Flash Sector
command is suspendable (see the FCNFG[ERSSUSP] bit and Figure 27-26).
Table 27-38. Erase Flash Sector Command Error Handling
Error Condition
Error Bit
Command not available in current mode/security
FSTAT[ACCERR]
An invalid Flash address is supplied
FSTAT[ACCERR]
Flash address is not longword aligned
FSTAT[ACCERR]
The selected program flash sector is protected
Any errors have been encountered during the verify
FSTAT[FPVIOL]
operation1
FSTAT[MGSTAT0]
1. User margin read may be run using the Read 1s Section command to verify all bits are erased.
27.4.10.5.1
Suspending an Erase Flash Sector Operation
To suspend an Erase Flash Sector operation set the FCNFG[ERSSUSP] bit (see Flash
Configuration Field Description) when CCIF is clear and the CCOB command field holds
the code for the Erase Flash Sector command. During the Erase Flash Sector operation
(see Erase Flash Sector Command), the flash memory module samples the state of the
ERSSUSP bit at convenient points. If the flash memory module detects that the
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Chapter 27 Flash Memory Module (FTFA)
ERSSUSP bit is set, the Erase Flash Sector operation is suspended and the flash memory
module sets CCIF. While ERSSUSP is set, all writes to flash registers are ignored except
for writes to the FSTAT and FCNFG registers.
If an Erase Flash Sector operation effectively completes before the flash memory module
detects that a suspend request has been made, the flash memory module clears the
ERSSUSP bit prior to setting CCIF. When an Erase Flash Sector operation has been
successfully suspended, the flash memory module sets CCIF and leaves the ERSSUSP bit
set. While CCIF is set, the ERSSUSP bit can only be cleared to prevent the withdrawal of
a suspend request before the flash memory module has acknowledged it.
27.4.10.5.2
Resuming a Suspended Erase Flash Sector Operation
If the ERSSUSP bit is still set when CCIF is cleared to launch the next command, the
previous Erase Flash Sector operation resumes. The flash memory module acknowledges
the request to resume a suspended operation by clearing the ERSSUSP bit. A new
suspend request can then be made by setting ERSSUSP. A single Erase Flash Sector
operation can be suspended and resumed multiple times.
There is a minimum elapsed time limit between the request to resume the Erase Flash
Sector operation (CCIF is cleared) and the request to suspend the operation again
(ERSSUSP is set). This minimum time period is required to ensure that the Erase Flash
Sector operation will eventually complete. If the minimum period is continually violated,
i.e. the suspend requests come repeatedly and too quickly, no forward progress is made
by the Erase Flash Sector algorithm. The resume/suspend sequence runs indefinitely
without completing the erase.
27.4.10.5.3
Aborting a Suspended Erase Flash Sector Operation
The user may choose to abort a suspended Erase Flash Sector operation by clearing the
ERSSUSP bit prior to clearing CCIF for the next command launch. When a suspended
operation is aborted, the flash memory module starts the new command using the new
FCCOB contents.
Note
Aborting the erase leaves the bitcells in an indeterminate,
partially-erased state. Data in this sector is not reliable until a
new erase command fully completes.
The following figure shows how to suspend and resume the Erase Flash Sector operation.
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Functional Description
Enter with CCIF = 1
Command Initiation
ERSSCR Command
(Write FCCOB)
Memory Controller
Command Processing
Launch/Resume Command
(Clear CCIF)
Yes
SUSPACK=1
Next Command
(Write FCCOB)
Yes
CCIF = 1?
No
No
Interrupt?
Yes
Request Suspend
(Set ERSSUSP)
Start
New
No
Restore Erase Algo
Clear SUSPACK = 0
Execute
Yes
DONE?
No
ERSSUSP=1?
No
CCIF = 1?
Resume
ERSSCR
No
Yes
Save Erase Algo
Clear ERSSUSP
Yes
Service Interrupt
(Read Flash)
ERSSCR Suspended
ERSSUSP=1
ERSSCR
Completed
Yes
ERSSUSP=0?
ERSSCR Suspended
Yes
Set SUSPACK = 1
ERSSCR Completed
ERSSUSP=0
Set CCIF
No
Resume Erase?
No, Abort
ERSSUSP: Bit in FCNFG register
SUSPACK: Internal Suspend Acknowledge
Clear ERSSUSP
User Cmd Interrupt/Suspend
Figure 27-26. Suspend and Resume of Erase Flash Sector Operation
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Chapter 27 Flash Memory Module (FTFA)
27.4.10.6 Read 1s All Blocks Command
The Read 1s All Blocks command checks if the program flash blocks have been erased to
the specified read margin level, if applicable, and releases security if the readout passes,
i.e. all data reads as '1'.
Table 27-39. Read 1s All Blocks Command FCCOB Requirements
FCCOB Number
FCCOB Contents [7:0]
0
0x40 (RD1ALL)
1
Read-1 Margin Choice
After clearing CCIF to launch the Read 1s All Blocks command, the flash memory
module :
• sets the read margin for 1s according to Table 27-40,
• checks the contents of the program flash are in the erased state.
If the flash memory module confirms that these memory resources are erased, security is
released by setting the FSEC[SEC] field to the unsecure state. The security byte in the
flash configuration field (see Flash Configuration Field Description) remains unaffected
by the Read 1s All Blocks command. If the read fails, i.e. all memory resources are not in
the fully erased state, the FSTAT[MGSTAT0] bit is set.
The CCIF flag sets after the Read 1s All Blocks operation has completed.
Table 27-40. Margin Level Choices for Read 1s All Blocks
Read Margin Choice
Margin Level Description
0x00
Use the 'normal' read level for 1s
0x01
Apply the 'User' margin to the normal read-1 level
0x02
Apply the 'Factory' margin to the normal read-1 level
Table 27-41. Read 1s All Blocks Command Error Handling
Error Condition
Error Bit
An invalid margin choice is specified
FSTAT[ACCERR]
Read-1s fails
FSTAT[MGSTAT0]
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Functional Description
27.4.10.7 Read Once Command
The Read Once command provides read access to a reserved 64-byte field located in the
program flash 0 IFR (see Program Flash IFR Map and Program Once Field). Access to
this field is via 16 records, each 4 bytes long. The Read Once field is programmed using
the Program Once command described in Program Once Command.
Table 27-42. Read Once Command FCCOB Requirements
FCCOB Number
FCCOB Contents [7:0]
0
0x41 (RDONCE)
1
Read Once record index (0x00 - 0x0F)
2
Not used
3
Not used
Returned Values
4
Read Once byte 0 value
5
Read Once byte 1 value
6
Read Once byte 2 value
7
Read Once byte 3 value
After clearing CCIF to launch the Read Once command, a 4-byte Read Once record is
read from the program flash IFR and stored in the FCCOB register. The CCIF flag is set
after the Read Once operation completes. Valid record index values for the Read Once
command range from 0x00 to 0x0F. During execution of the Read Once command, any
attempt to read addresses within the program flash block containing this 64-byte field
returns invalid data. The Read Once command can be executed any number of times.
Table 27-43. Read Once Command Error Handling
Error Condition
Error Bit
Command not available in current mode/security
FSTAT[ACCERR]
An invalid record index is supplied
FSTAT[ACCERR]
27.4.10.8 Program Once Command
The Program Once command enables programming to a reserved 64-byte field in the
program flash 0 IFR (see Program Flash IFR Map and Program Once Field). Access to
the Program Once field is via 16 records, each 4 bytes long. The Program Once field can
be read using the Read Once command (see Read Once Command) or using the Read
Resource command (see Read Resource Command). Each Program Once record can be
programmed only once since the program flash 0 IFR cannot be erased.
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Chapter 27 Flash Memory Module (FTFA)
Table 27-44. Program Once Command FCCOB Requirements
FCCOB Number
FCCOB Contents [7:0]
0
0x43 (PGMONCE)
1
Program Once record index (0x00 - 0x0F)
2
Not Used
3
Not Used
4
Program Once Byte 0 value
5
Program Once Byte 1 value
6
Program Once Byte 2 value
7
Program Once Byte 3 value
After clearing CCIF to launch the Program Once command, the flash memory module
first verifies that the selected record is erased. If erased, then the selected record is
programmed using the values provided. The Program Once command also verifies that
the programmed values read back correctly. The CCIF flag is set after the Program Once
operation has completed.
The reserved program flash 0 IFR location accessed by the Program Once command
cannot be erased and any attempt to program one of these records when the existing value
is not Fs (erased) is not allowed. Valid record index values for the Program Once
command range from 0x00 to 0x0F. During execution of the Program Once command,
any attempt to read addresses within the program flash block containing this 64-byte field
returns invalid data.
Table 27-45. Program Once Command Error Handling
Error Condition
Error Bit
Command not available in current mode/security
FSTAT[ACCERR]
An invalid record index is supplied
The requested record has already been programmed to a non-FFFF
FSTAT[ACCERR]
value1
Any errors have been encountered during the verify operation
FSTAT[ACCERR]
FSTAT[MGSTAT0]
1. If a Program Once record is initially programmed to 0xFFFF_FFFF, the Program Once command is allowed to execute
again on that same record.
27.4.10.9 Erase All Blocks Command
The Erase All Blocks operation erases all flash memory, verifies all memory contents,
and releases MCU security.
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Functional Description
Table 27-46. Erase All Blocks Command FCCOB Requirements
FCCOB Number
FCCOB Contents [7:0]
0
0x44 (ERSALL)
After clearing CCIF to launch the Erase All Blocks command, the flash memory module
erases all program flash memory, then verifies that all are erased.
If the flash memory module verifies that all flash memories were properly erased,
security is released by setting the FSEC[SEC] field to the unsecure state. The Erase All
Blocks command aborts if any flash region is protected. The security byte and all other
contents of the flash configuration field (see Flash Configuration Field Description) are
erased by the Erase All Blocks command. If the erase-verify fails, the
FSTAT[MGSTAT0] bit is set. The CCIF flag is set after the Erase All Blocks operation
completes.
Table 27-47. Erase All Blocks Command Error Handling
Error Condition
Error Bit
Command not available in current mode/security
FSTAT[ACCERR]
Any region of the program flash memory is protected
Any errors have been encountered during the verify
FSTAT[FPVIOL]
operation1
FSTAT[MGSTAT0]
1. User margin read may be run using the Read 1s All Blocks command to verify all bits are erased.
27.4.10.9.1
Triggering an Erase All External to the Flash Memory Module
The functionality of the Erase All Blocks command is also available in an uncommanded
fashion outside of the flash memory. Refer to the device's Chip Configuration details for
information on this functionality.
Before invoking the external erase all function, the FSTAT[ACCERR and PVIOL] flags
must be cleared and the FCCOB0 register must not contain 0x44. When invoked, the
erase-all function erases all program flash memory regardless of the protection settings. If
the post-erase verify passes, the routine then releases security by setting the FSEC[SEC]
field register to the unsecure state. The security byte in the Flash Configuration Field is
also programmed to the unsecure state. The status of the erase-all request is reflected in
the FCNFG[ERSAREQ] bit. The FCNFG[ERSAREQ] bit is cleared once the operation
completes and the normal FSTAT error reporting is available as described in Erase All
Blocks Command.
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Chapter 27 Flash Memory Module (FTFA)
27.4.10.10 Verify Backdoor Access Key Command
The Verify Backdoor Access Key command only executes if the mode and security
conditions are satisfied (see Flash Commands by Mode). Execution of the Verify
Backdoor Access Key command is further qualified by the FSEC[KEYEN] bits. The
Verify Backdoor Access Key command releases security if user-supplied keys in the
FCCOB match those stored in the Backdoor Comparison Key bytes of the Flash
Configuration Field (see Flash Configuration Field Description). The column labelled
Flash Configuration Field offset address shows the location of the matching byte in the
Flash Configuration Field.
Table 27-48. Verify Backdoor Access Key Command FCCOB Requirements
FCCOB Number
FCCOB Contents [7:0]
0
0x45 (VFYKEY)
Flash Configuration Field Offset Address
1-3
Not Used
4
Key Byte 0
0x0_0000
5
Key Byte 1
0x0_0001
6
Key Byte 2
0x0_0002
7
Key Byte 3
0x0_0003
8
Key Byte 4
0x0_0004
9
Key Byte 5
0x0_0005
A
Key Byte 6
0x0_0006
B
Key Byte 7
0x0_0007
After clearing CCIF to launch the Verify Backdoor Access Key command, the flash
memory module checks the FSEC[KEYEN] bits to verify that this command is enabled.
If not enabled, the flash memory module sets the FSTAT[ACCERR] bit and terminates.
If the command is enabled, the flash memory module compares the key provided in
FCCOB to the backdoor comparison key in the Flash Configuration Field. If the
backdoor keys match, the FSEC[SEC] field is changed to the unsecure state and security
is released. If the backdoor keys do not match, security is not released and all future
attempts to execute the Verify Backdoor Access Key command are immediately aborted
and the FSTAT[ACCERR] bit is (again) set to 1 until a reset of the flash memory module
module occurs. If the entire 8-byte key is all zeros or all ones, the Verify Backdoor
Access Key command fails with an access error. The CCIF flag is set after the Verify
Backdoor Access Key operation completes.
Table 27-49. Verify Backdoor Access Key Command Error Handling
Error Condition
Error Bit
The supplied key is all-0s or all-Fs
FSTAT[ACCERR]
An incorrect backdoor key is supplied
FSTAT[ACCERR]
Table continues on the next page...
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Functional Description
Table 27-49. Verify Backdoor Access Key Command Error Handling (continued)
Error Condition
Error Bit
Backdoor key access has not been enabled (see the description of the FSEC register)
FSTAT[ACCERR]
This command is launched and the backdoor key has mismatched since the last power down
reset
FSTAT[ACCERR]
27.4.11 Security
The flash memory module provides security information to the MCU based on contents
of the FSEC security register. The MCU then limits access to flash memory resources as
defined in the device's Chip Configuration details. During reset, the flash memory
module initializes the FSEC register using data read from the security byte of the Flash
Configuration Field (see Flash Configuration Field Description).
The following fields are available in the FSEC register. The settings are described in the
Flash Security Register (FTFA_FSEC) details.
Table 27-50. FSEC register fields
FSEC field
Description
KEYEN
Backdoor Key Access
MEEN
Mass Erase Capability
FSLACC
Freescale Factory Access
SEC
MCU security
27.4.11.1 Flash Memory Access by Mode and Security
The following table summarizes how access to the flash memory module is affected by
security and operating mode.
Table 27-51. Flash Memory Access Summary
Operating Mode
Chip Security State
Unsecure
NVM Normal
NVM Special
Secure
Full command set
Full command set
Only the Erase All Blocks and Read 1s All
Blocks commands.
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Chapter 27 Flash Memory Module (FTFA)
27.4.11.2 Changing the Security State
The security state out of reset can be permanently changed by programming the security
byte of the flash configuration field. This assumes that you are starting from a mode
where the necessary program flash erase and program commands are available and that
the region of the program flash containing the flash configuration field is unprotected. If
the flash security byte is successfully programmed, its new value takes affect after the
next chip reset.
27.4.11.2.1
Unsecuring the Chip Using Backdoor Key Access
The chip can be unsecured by using the backdoor key access feature, which requires
knowledge of the contents of the 8-byte backdoor key value stored in the Flash
Configuration Field (see Flash Configuration Field Description). If the FSEC[KEYEN]
bits are in the enabled state, the Verify Backdoor Access Key command (see Verify
Backdoor Access Key Command) can be run; it allows the user to present prospective
keys for comparison to the stored keys. If the keys match, the FSEC[SEC] bits are
changed to unsecure the chip. The entire 8-byte key cannot be all 0s or all 1s; that is,
0000_0000_0000_0000h and FFFF_FFFF_FFFF_FFFFh are not accepted by the Verify
Backdoor Access Key command as valid comparison values. While the Verify Backdoor
Access Key command is active, program flash memory is not available for read access
and returns invalid data.
The user code stored in the program flash memory must have a method of receiving the
backdoor keys from an external stimulus. This external stimulus would typically be
through one of the on-chip serial ports.
If the KEYEN bits are in the enabled state, the chip can be unsecured by the following
backdoor key access sequence:
1. Follow the command sequence for the Verify Backdoor Access Key command as
explained in Verify Backdoor Access Key Command
2. If the Verify Backdoor Access Key command is successful, the chip is unsecured and
the FSEC[SEC] bits are forced to the unsecure state
An illegal key provided to the Verify Backdoor Access Key command prohibits further
use of the Verify Backdoor Access Key command. A reset of the chip is the only method
to re-enable the Verify Backdoor Access Key command when a comparison fails.
After the backdoor keys have been correctly matched, the chip is unsecured by changing
the FSEC[SEC] bits. A successful execution of the Verify Backdoor Access Key
command changes the security in the FSEC register only. It does not alter the security
byte or the keys stored in the Flash Configuration Field (Flash Configuration Field
Description). After the next reset of the chip, the security state of the flash memory
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Functional Description
module reverts back to the flash security byte in the Flash Configuration Field. The
Verify Backdoor Access Key command sequence has no effect on the program and erase
protections defined in the program flash protection registers.
If the backdoor keys successfully match, the unsecured chip has full control of the
contents of the Flash Configuration Field. The chip may erase the sector containing the
Flash Configuration Field and reprogram the flash security byte to the unsecure state and
change the backdoor keys to any desired value.
27.4.12 Reset Sequence
On each system reset the flash memory module executes a sequence which establishes
initial values for the flash block configuration parameters, FPROT, FOPT, and FSEC
registers.
FSTAT[CCIF] is cleared throughout the reset sequence. The flash memory module holds
off CPU access during the reset sequence. Flash reads are possible when the hold is
removed. Completion of the reset sequence is marked by setting CCIF which enables
flash user commands.
If a reset occurs while any flash command is in progress, that command is immediately
aborted. The state of the word being programmed or the sector/block being erased is not
guaranteed. Commands and operations do not automatically resume after exiting reset.
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Chapter 28
Analog-to-Digital Converter (ADC)
28.1 Introduction
NOTE
For the chip-specific implementation details of this module's
instances see the chip configuration information.
The 12-bit analog-to-digital converter (ADC) is a successive approximation ADC
designed for operation within an integrated microcontroller system-on-chip.
NOTE
For the chip specific modes of operation, see the power
management information of the device.
28.1.1 Features
Features of the ADC module include:
• Linear successive approximation algorithm with up to 12-bit resolution
• Up to 24 single-ended external analog inputs
• Output modes:
• single-ended 12-bit, 10-bit, and 8-bit modes
• Output in right-justified unsigned format for single-ended
• Single or continuous conversion, that is, automatic return to idle after single
conversion
• Configurable sample time and conversion speed/power
• Conversion complete/hardware average complete flag and interrupt
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Introduction
• Input clock selectable from up to four sources
• Operation in Low-Power modes for lower noise
• Asynchronous clock source for lower noise operation with option to output the clock
• Selectable hardware conversion trigger with hardware channel select
• Automatic compare with interrupt for less-than, greater-than or equal-to, within
range, or out-of-range, programmable value
• Temperature sensor
• Hardware average function
• Selectable voltage reference: external or alternate
• Self-Calibration mode
28.1.2 Block diagram
The following figure is the ADC module block diagram.
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Chapter 28 Analog-to-Digital Converter (ADC)
ADHWTSA
SC1A
Conversion
trigger
control
ADHWTSn
ADHWT
SC1n
ADTRG
Control Registers (SC2, CFG1, CFG2)
ADACKEN
Interrupt
ADCK
ADACK
Clock
divide
Bus clock
2
ALTCLK
abort
transfer
convert
initialize
AD0
sample
Control sequencer
MCU STOP
Async
Clock Gen
A D IC L K
A D IV
ADLPC/ADHSC
ADLSMP/ADLSTS
ADCO
MODE
trig g e r
c o m p le te
AIEN
COCO
ADCH
C o m p a re tru e 1
PG, MG
A D V IN
AD23
Temp
PG, MG
CLPx
SAR converter
CLPx
CLM x
Offset subtractor
CLMx
OFS
ADCOFS
Calibration
CALF
CAL
AVGE, AVGS
V REFSH
Averager
MODE
Formatting
V REFH
SC3
CFG1,2
D
RA
VALTH
V REFSL
tra n s fe r
V REFL
Rn
Compare
logic
VALTL
C V1
ACFE
ACFGT, ACREN
Compare true
SC2
1
CV2
CV1:CV2
Figure 28-1. ADC block diagram
28.2 ADC Signal Descriptions
The ADC module supports up to 24 single-ended inputs. The ADC also requires four
supply/reference/ground connections.
NOTE
Refer to ADC configuration section in chip configuration
chapter for the number of channels supported on this device.
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ADC Signal Descriptions
Table 28-1. ADC Signal Descriptions
Signal
ADn
Description
I/O
Single-Ended Analog Channel Inputs
I
VREFSH
Voltage Reference Select High
I
VREFSL
Voltage Reference Select Low
I
VDDA
Analog Power Supply
I
VSSA
Analog Ground
I
28.2.1 Analog Power (VDDA)
The ADC analog portion uses VDDA as its power connection. In some packages, VDDA is
connected internally to VDD. If externally available, connect the VDDA pin to the same
voltage potential as VDD. External filtering may be necessary to ensure clean VDDA for
good results.
28.2.2 Analog Ground (VSSA)
The ADC analog portion uses VSSA as its ground connection. In some packages, VSSA is
connected internally to VSS. If externally available, connect the VSSA pin to the same
voltage potential as VSS.
28.2.3 Voltage Reference Select
VREFSH and VREFSL are the high and low reference voltages for the ADC module.
The ADC can be configured to accept one of two voltage reference pairs for VREFSH and
VREFSL. Each pair contains a positive reference that must be between the minimum Ref
Voltage High and VDDA, and a ground reference that must be at the same potential as
VSSA. The two pairs are external (VREFH and VREFL) and alternate (VALTH and VALTL).
These voltage references are selected using SC2[REFSEL]. The alternate VALTH and
VALTL voltage reference pair may select additional external pins or internal sources
depending on MCU configuration. See the chip configuration information on the Voltage
References specific to this MCU.
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Chapter 28 Analog-to-Digital Converter (ADC)
In some packages, VREFH is connected in the package to VDDA and VREFL to VSSA. If
externally available, the positive reference(s) may be connected to the same potential as
VDDA or may be driven by an external source to a level between the minimum Ref
Voltage High and the VDDA potential. VREFH must never exceed VDDA. Connect the
ground references to the same voltage potential as VSSA.
28.2.4 Analog Channel Inputs (ADx)
The ADC module supports up to 24 single-ended analog inputs. A single-ended input is
selected for conversion through the SC1[ADCH] channel select bits.
28.3 Register definition
This section describes the ADC registers.
ADC memory map
Absolute
address
(hex)
Register name
Width
Access
(in bits)
Reset value
Section/
page
4003_B000
ADC Status and Control Registers 1 (ADC0_SC1A)
32
R/W
0000_001Fh
28.3.1/422
4003_B004
ADC Status and Control Registers 1 (ADC0_SC1B)
32
R/W
0000_001Fh
28.3.1/422
4003_B008
ADC Configuration Register 1 (ADC0_CFG1)
32
R/W
0000_0000h
28.3.2/425
4003_B00C ADC Configuration Register 2 (ADC0_CFG2)
32
R/W
0000_0000h
28.3.3/427
4003_B010
ADC Data Result Register (ADC0_RA)
32
R
0000_0000h
28.3.4/428
4003_B014
ADC Data Result Register (ADC0_RB)
32
R
0000_0000h
28.3.4/428
4003_B018
Compare Value Registers (ADC0_CV1)
32
R/W
0000_0000h
28.3.5/429
4003_B01C Compare Value Registers (ADC0_CV2)
32
R/W
0000_0000h
28.3.5/429
4003_B020
Status and Control Register 2 (ADC0_SC2)
32
R/W
0000_0000h
28.3.6/430
4003_B024
Status and Control Register 3 (ADC0_SC3)
32
R/W
0000_0000h
28.3.7/432
4003_B028
ADC Offset Correction Register (ADC0_OFS)
32
R/W
0000_0004h
28.3.8/433
28.3.9/434
4003_B02C ADC Plus-Side Gain Register (ADC0_PG)
32
R/W
0000_8200h
4003_B034
ADC Plus-Side General Calibration Value Register
(ADC0_CLPD)
32
R/W
0000_000Ah 28.3.10/434
4003_B038
ADC Plus-Side General Calibration Value Register
(ADC0_CLPS)
32
R/W
0000_0020h
28.3.11/435
4003_B03C
ADC Plus-Side General Calibration Value Register
(ADC0_CLP4)
32
R/W
0000_0200h
28.3.12/435
4003_B040
ADC Plus-Side General Calibration Value Register
(ADC0_CLP3)
32
R/W
0000_0100h
28.3.13/436
4003_B044
ADC Plus-Side General Calibration Value Register
(ADC0_CLP2)
32
R/W
0000_0080h
28.3.14/436
Table continues on the next page...
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Register definition
ADC memory map (continued)
Absolute
address
(hex)
Register name
Width
Access
(in bits)
Reset value
Section/
page
4003_B048
ADC Plus-Side General Calibration Value Register
(ADC0_CLP1)
32
R/W
0000_0040h
28.3.15/437
4003_B04C
ADC Plus-Side General Calibration Value Register
(ADC0_CLP0)
32
R/W
0000_0020h
28.3.16/437
28.3.1 ADC Status and Control Registers 1 (ADCx_SC1n)
SC1A is used for both software and hardware trigger modes of operation.
To allow sequential conversions of the ADC to be triggered by internal peripherals, the
ADC can have more then one status and control register: one for each conversion. The
SC1B–SC1n registers indicate potentially multiple SC1 registers for use only in hardware
trigger mode. See the chip configuration information about the number of SC1n registers
specific to this device. The SC1n registers have identical fields, and are used in a "pingpong" approach to control ADC operation.
At any one point in time, only one of the SC1n registers is actively controlling ADC
conversions. Updating SC1A while SC1n is actively controlling a conversion is allowed,
and vice-versa for any of the SC1n registers specific to this MCU.
Writing SC1A while SC1A is actively controlling a conversion aborts the current
conversion. In Software Trigger mode, when SC2[ADTRG]=0, writes to SC1A
subsequently initiate a new conversion, if SC1[ADCH] contains a value other than all 1s.
Writing any of the SC1n registers while that specific SC1n register is actively controlling
a conversion aborts the current conversion. None of the SC1B-SC1n registers are used for
software trigger operation and therefore writes to the SC1B–SC1n registers do not initiate
a new conversion.
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Chapter 28 Analog-to-Digital Converter (ADC)
Address: 4003_B000h base + 0h offset + (4d × i), where i=0d to 1d
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
R
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
AIEN
0
0
1
1
COCO
Reset
Reserved
W
0
R
ADCH
W
Reset
0
0
0
0
0
0
0
0
0
1
1
1
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Register definition
ADCx_SC1n field descriptions
Field
31–8
Reserved
7
COCO
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Conversion Complete Flag
This is a read-only field that is set each time a conversion is completed when the compare function is
disabled, or SC2[ACFE]=0 and the hardware average function is disabled, or SC3[AVGE]=0. When the
compare function is enabled, or SC2[ACFE]=1, COCO is set upon completion of a conversion only if the
compare result is true. When the hardware average function is enabled, or SC3[AVGE]=1, COCO is set
upon completion of the selected number of conversions (determined by AVGS). COCO in SC1A is also set
at the completion of a calibration sequence. COCO is cleared when the respective SC1n register is written
or when the respective Rn register is read.
0
1
6
AIEN
Interrupt Enable
Enables conversion complete interrupts. When COCO becomes set while the respective AIEN is high, an
interrupt is asserted.
0
1
5
Reserved
4–0
ADCH
Conversion is not completed.
Conversion is completed.
Conversion complete interrupt is disabled.
Conversion complete interrupt is enabled.
This field is reserved.
This reserved bit should not be changed.
Input channel select
Selects one of the input channels.
NOTE: Some of the input channel options in the bitfield-setting descriptions might not be available for
your device. For the actual ADC channel assignments for your device, see the Chip Configuration
details.
The successive approximation converter subsystem is turned off when the channel select bits are all set,
that is, ADCH = 11111. This feature allows explicit disabling of the ADC and isolation of the input channel
from all sources. Terminating continuous conversions this way prevents an additional single conversion
from being performed. It is not necessary to set ADCH to all 1s to place the ADC in a low-power state
when continuous conversions are not enabled because the module automatically enters a low-power state
when a conversion completes.
00000
00001
00010
00011
00100
00101
00110
00111
01000
01001
01010
01011
01100
01101
AD0 is selected as input.
AD1 is selected as input.
AD2 is selected as input.
AD3 is selected as input.
AD4 is selected as input.
AD5 is selected as input.
AD6 is selected as input.
AD7 is selected as input.
AD8 is selected as input.
AD9 is selected as input.
AD10 is selected as input.
AD11 is selected as input.
AD12 is selected as input.
AD13 is selected as input.
Table continues on the next page...
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Chapter 28 Analog-to-Digital Converter (ADC)
ADCx_SC1n field descriptions (continued)
Field
Description
01110
01111
10000
10001
10010
10011
10100
10101
10110
10111
11000
11001
11010
11011
11100
11101
11110
11111
AD14 is selected as input.
AD15 is selected as input.
AD16 is selected as input.
AD17 is selected as input.
AD18 is selected as input.
AD19 is selected as input.
AD20 is selected as input.
AD21 is selected as input.
AD22 is selected as input.
AD23 is selected as input.
Reserved.
Reserved.
Temp Sensor (single-ended) is selected as input.
Bandgap (single-ended) is selected as input.
Reserved.
VREFSH is selected as input. Voltage reference selected is determined by SC2[REFSEL].
VREFSL is selected as input. Voltage reference selected is determined by SC2[REFSEL].
Module is disabled.
28.3.2 ADC Configuration Register 1 (ADCx_CFG1)
The configuration Register 1 (CFG1) selects the mode of operation, clock source, clock
divide, and configuration for low power or long sample time.
Address: 4003_B000h base + 8h offset = 4003_B008h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
R
W
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
ADLPC
0
R
W
Reset
0
0
0
0
0
0
0
0
0
ADLSMP
Reset
ADIV
0
0
0
MODE
0
0
ADICLK
0
0
ADCx_CFG1 field descriptions
Field
31–8
Reserved
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Table continues on the next page...
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Register definition
ADCx_CFG1 field descriptions (continued)
Field
7
ADLPC
Description
Low-Power Configuration
Controls the power configuration of the successive approximation converter. This optimizes power
consumption when higher sample rates are not required.
0
1
6–5
ADIV
Clock Divide Select
ADIV selects the divide ratio used by the ADC to generate the internal clock ADCK.
00
01
10
11
4
ADLSMP
ADLSMP selects between different sample times based on the conversion mode selected. This bit adjusts
the sample period to allow higher impedance inputs to be accurately sampled or to maximize conversion
speed for lower impedance inputs. Longer sample times can also be used to lower overall power
consumption if continuous conversions are enabled and high conversion rates are not required. When
ADLSMP=1, the long sample time select bits, (ADLSTS[1:0]), can select the extent of the long sample
time.
Short sample time.
Long sample time.
Conversion mode selection
Selects the ADC resolution mode.
00
01
10
11
1–0
ADICLK
The divide ratio is 1 and the clock rate is input clock.
The divide ratio is 2 and the clock rate is (input clock)/2.
The divide ratio is 4 and the clock rate is (input clock)/4.
The divide ratio is 8 and the clock rate is (input clock)/8.
Sample time configuration
0
1
3–2
MODE
Normal power configuration.
Low-power configuration. The power is reduced at the expense of maximum clock speed.
It is single-ended 8-bit conversion.
It is single-ended 12-bit conversion .
It is single-ended 10-bit conversion .
Reserved. Do not set the bitfield to this value.
Input Clock Select
Selects the input clock source to generate the internal clock, ADCK. Note that when the ADACK clock
source is selected, it is not required to be active prior to conversion start. When it is selected and it is not
active prior to a conversion start, when CFG2[ADACKEN]=0, the asynchronous clock is activated at the
start of a conversion and deactivated when conversions are terminated. In this case, there is an
associated clock startup delay each time the clock source is re-activated.
00
01
10
11
Bus clock
(Bus clock)/2
Alternate clock (ALTCLK)
Asynchronous clock (ADACK)
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Chapter 28 Analog-to-Digital Converter (ADC)
28.3.3 ADC Configuration Register 2 (ADCx_CFG2)
Configuration Register 2 (CFG2) selects the special high-speed configuration for very
high speed conversions and selects the long sample time duration during long sample
mode.
Address: 4003_B000h base + Ch offset = 4003_B00Ch
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
R
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
MUXSEL
ADACKEN
ADHSC
W
0
0
0
0
R
0
W
Reset
0
0
0
0
0
0
0
0
0
0
0
ADLSTS
0
0
ADCx_CFG2 field descriptions
Field
Description
31–8
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
7–5
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
4
MUXSEL
ADC Mux Select
Changes the ADC mux setting to select between alternate sets of ADC channels.
0
1
3
ADACKEN
Asynchronous Clock Output Enable
Enables the asynchronous clock source and the clock source output regardless of the conversion and
status of CFG1[ADICLK]. Based on MCU configuration, the asynchronous clock may be used by other
modules. See chip configuration information. Setting this field allows the clock to be used even while the
ADC is idle or operating from a different clock source. Also, latency of initiating a single or first-continuous
conversion with the asynchronous clock selected is reduced because the ADACK clock is already
operational.
0
1
2
ADHSC
ADxxa channels are selected.
ADxxb channels are selected.
Asynchronous clock output disabled; Asynchronous clock is enabled only if selected by ADICLK and a
conversion is active.
Asynchronous clock and clock output is enabled regardless of the state of the ADC.
High-Speed Configuration
Table continues on the next page...
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Register definition
ADCx_CFG2 field descriptions (continued)
Field
Description
Configures the ADC for very high-speed operation. The conversion sequence is altered with 2 ADCK
cycles added to the conversion time to allow higher speed conversion clocks.
0
1
1–0
ADLSTS
Normal conversion sequence selected.
High-speed conversion sequence selected with 2 additional ADCK cycles to total conversion time.
Long Sample Time Select
Selects between the extended sample times when long sample time is selected, that is, when
CFG1[ADLSMP]=1. This allows higher impedance inputs to be accurately sampled or to maximize
conversion speed for lower impedance inputs. Longer sample times can also be used to lower overall
power consumption when continuous conversions are enabled if high conversion rates are not required.
00
01
10
11
Default longest sample time; 20 extra ADCK cycles; 24 ADCK cycles total.
12 extra ADCK cycles; 16 ADCK cycles total sample time.
6 extra ADCK cycles; 10 ADCK cycles total sample time.
2 extra ADCK cycles; 6 ADCK cycles total sample time.
28.3.4 ADC Data Result Register (ADCx_Rn)
The data result registers (Rn) contain the result of an ADC conversion of the channel
selected by the corresponding status and channel control register (SC1A:SC1n). For
every status and channel control register, there is a corresponding data result register.
Unused bits in R n are cleared in unsigned right-justified modes and carry the sign bit
(MSB) in sign-extended 2's complement modes.
The following table describes the behavior of the data result registers in the different
modes of operation.
Table 28-35. Data result register description
Conversion
mode
D15 D14 D13 D12 D11 D10 D9 D8 D7 D6 D5 D4 D3 D2 D1 D0
Format
12-bit singleended
0
0
0
0
D
D
D
D
D
D
D
D
D
D
D
D
Unsigned rightjustified
10-bit singleended
0
0
0
0
0
0
D
D
D
D
D
D
D
D
D
D
Unsigned rightjustified
8-bit singleended
0
0
0
0
0
0
0
0
D
D
D
D
D
D
D
D
Unsigned rightjustified
NOTE
S: Sign bit or sign bit extension;
D: Data, which is 2's complement data if indicated
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Chapter 28 Analog-to-Digital Converter (ADC)
Address: 4003_B000h base + 10h offset + (4d × i), where i=0d to 1d
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
0
R
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
D
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
ADCx_Rn field descriptions
Field
Description
31–16
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
15–0
D
Data result
28.3.5 Compare Value Registers (ADCx_CVn)
The compare value registers (CV1 and CV2) contain a compare value used to compare
the conversion result when the compare function is enabled, that is, SC2[ACFE]=1. This
register is formatted in the same way as the Rn registers in different modes of operation
for both bit position definition and value format using unsigned or sign-extended 2's
complement. Therefore, the compare function uses only the CVn fields that are related to
the ADC mode of operation.
The compare value 2 register (CV2) is used only when the compare range function is
enabled, that is, SC2[ACREN]=1.
Address: 4003_B000h base + 18h offset + (4d × i), where i=0d to 1d
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
0
R
0
0
0
0
0
0
0
0
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
CV
W
Reset
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
ADCx_CVn field descriptions
Field
31–16
Reserved
15–0
CV
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Compare Value.
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Register definition
28.3.6 Status and Control Register 2 (ADCx_SC2)
The status and control register 2 (SC2) contains the conversion active, hardware/software
trigger select, compare function, and voltage reference select of the ADC module.
Address: 4003_B000h base + 20h offset = 4003_B020h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
R
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
ACFE
ACFGT
ACREN
DMAEN
0
0
0
0
0
ADACT
Reset
ADTRG
W
0
R
REFSEL
W
Reset
0
0
0
0
0
0
0
0
0
0
0
ADCx_SC2 field descriptions
Field
31–8
Reserved
7
ADACT
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Conversion Active
Indicates that a conversion or hardware averaging is in progress. ADACT is set when a conversion is
initiated and cleared when a conversion is completed or aborted.
0
1
6
ADTRG
Conversion not in progress.
Conversion in progress.
Conversion Trigger Select
Selects the type of trigger used for initiating a conversion. Two types of trigger are selectable:
Table continues on the next page...
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Chapter 28 Analog-to-Digital Converter (ADC)
ADCx_SC2 field descriptions (continued)
Field
Description
• Software trigger: When software trigger is selected, a conversion is initiated following a write to
SC1A.
• Hardware trigger: When hardware trigger is selected, a conversion is initiated following the assertion
of the ADHWT input after a pulse of the ADHWTSn input.
0
1
5
ACFE
Compare Function Enable
Enables the compare function.
0
1
4
ACFGT
Compare function disabled.
Compare function enabled.
Compare Function Greater Than Enable
Configures the compare function to check the conversion result relative to the CV1 and CV2 based upon
the value of ACREN. ACFE must be set for ACFGT to have any effect.
0
1
3
ACREN
Software trigger selected.
Hardware trigger selected.
Configures less than threshold, outside range not inclusive and inside range not inclusive; functionality
based on the values placed in CV1 and CV2.
Configures greater than or equal to threshold, outside and inside ranges inclusive; functionality based
on the values placed in CV1 and CV2.
Compare Function Range Enable
Configures the compare function to check if the conversion result of the input being monitored is either
between or outside the range formed by CV1 and CV2 determined by the value of ACFGT. ACFE must be
set for ACFGT to have any effect.
0
1
Range function disabled. Only CV1 is compared.
Range function enabled. Both CV1 and CV2 are compared.
2
DMAEN
DMA Enable
1–0
REFSEL
Voltage Reference Selection
0
1
DMA is disabled.
DMA is enabled and will assert the ADC DMA request during an ADC conversion complete event
noted when any of the SC1n[COCO] flags is asserted.
Selects the voltage reference source used for conversions.
00
01
10
11
Default voltage reference pin pair, that is, external pins VREFH and VREFL
Alternate reference pair, that is, VALTH and VALTL . This pair may be additional external pins or
internal sources depending on the MCU configuration. See the chip configuration information for
details specific to this MCU
Reserved
Reserved
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Register definition
28.3.7 Status and Control Register 3 (ADCx_SC3)
The Status and Control Register 3 (SC3) controls the calibration, continuous convert, and
hardware averaging functions of the ADC module.
Address: 4003_B000h base + 24h offset = 4003_B024h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
R
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
AVGE
0
0
CALF
Reset
ADCO
W
0
R
0
CAL
AVGS
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
ADCx_SC3 field descriptions
Field
31–8
Reserved
7
CAL
6
CALF
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Calibration
Begins the calibration sequence when set. This field stays set while the calibration is in progress and is
cleared when the calibration sequence is completed. CALF must be checked to determine the result of the
calibration sequence. Once started, the calibration routine cannot be interrupted by writes to the ADC
registers or the results will be invalid and CALF will set. Setting CAL will abort any current conversion.
Calibration Failed Flag
Displays the result of the calibration sequence. The calibration sequence will fail if SC2[ADTRG] = 1, any
ADC register is written, or any stop mode is entered before the calibration sequence completes. Writing 1
to CALF clears it.
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Chapter 28 Analog-to-Digital Converter (ADC)
ADCx_SC3 field descriptions (continued)
Field
Description
0
1
5–4
Reserved
Calibration completed normally.
Calibration failed. ADC accuracy specifications are not guaranteed.
This field is reserved.
This read-only field is reserved and always has the value 0.
3
ADCO
Continuous Conversion Enable
Enables continuous conversions.
0
1
2
AVGE
One conversion or one set of conversions if the hardware average function is enabled, that is,
AVGE=1, after initiating a conversion.
Continuous conversions or sets of conversions if the hardware average function is enabled, that is,
AVGE=1, after initiating a conversion.
Hardware Average Enable
Enables the hardware average function of the ADC.
0
1
1–0
AVGS
Hardware average function disabled.
Hardware average function enabled.
Hardware Average Select
Determines how many ADC conversions will be averaged to create the ADC average result.
00
01
10
11
4 samples averaged.
8 samples averaged.
16 samples averaged.
32 samples averaged.
28.3.8 ADC Offset Correction Register (ADCx_OFS)
The ADC Offset Correction Register (OFS) contains the user-selected or calibrationgenerated offset error correction value. This register is a 2’s complement, left-justified,
16-bit value . The value in OFS is subtracted from the conversion and the result is
transferred into the result registers, Rn. If the result is greater than the maximum or less
than the minimum result value, it is forced to the appropriate limit for the current mode of
operation.
Address: 4003_B000h base + 28h offset = 4003_B028h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
0
R
0
0
0
0
0
0
0
0
7
6
5
4
3
2
1
0
0
0
0
0
1
0
0
OFS
W
Reset
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
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Register definition
ADCx_OFS field descriptions
Field
Description
31–16
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
15–0
OFS
Offset Error Correction Value
28.3.9 ADC Plus-Side Gain Register (ADCx_PG)
The Plus-Side Gain Register (PG) contains the gain error correction for the overall
conversion in single-ended mode. PG, a 16-bit real number in binary format, is the gain
adjustment factor, with the radix point fixed between ADPG15 and ADPG14. This
register must be written by the user with the value described in the calibration procedure.
Otherwise, the gain error specifications may not be met.
Address: 4003_B000h base + 2Ch offset = 4003_B02Ch
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
0
R
0
0
0
0
0
0
0
0
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
PG
W
Reset
8
0
0
0
0
0
0
0
0
1
0
0
0
0
0
1
0
0
ADCx_PG field descriptions
Field
31–16
Reserved
15–0
PG
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Plus-Side Gain
28.3.10 ADC Plus-Side General Calibration Value Register
(ADCx_CLPD)
The Plus-Side General Calibration Value Registers (CLPx) contain calibration
information that is generated by the calibration function. These registers contain seven
calibration values of varying widths: CLP0[5:0], CLP1[6:0], CLP2[7:0], CLP3[8:0],
CLP4[9:0], CLPS[5:0], and CLPD[5:0]. CLPx are automatically set when the selfcalibration sequence is done, that is, CAL is cleared. If these registers are written by the
user after calibration, the linearity error specifications may not be met.
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Chapter 28 Analog-to-Digital Converter (ADC)
Address: 4003_B000h base + 34h offset = 4003_B034h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
0
R
0
0
0
0
0
0
0
0
0
0
0
0
0
2
1
0
CLPD
W
Reset
3
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
1
0
4
3
2
1
0
ADCx_CLPD field descriptions
Field
Description
31–6
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
5–0
CLPD
Calibration Value
28.3.11 ADC Plus-Side General Calibration Value Register
(ADCx_CLPS)
For more information, see CLPD register description.
Address: 4003_B000h base + 38h offset = 4003_B038h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
0
R
CLPS
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
4
3
2
1
0
0
0
0
0
ADCx_CLPS field descriptions
Field
Description
31–6
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
5–0
CLPS
Calibration Value
28.3.12 ADC Plus-Side General Calibration Value Register
(ADCx_CLP4)
For more information, see CLPD register description.
Address: 4003_B000h base + 3Ch offset = 4003_B03Ch
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
0
R
CLP4
W
Reset
0
0
0
0
0
0
0
0
0
0
0
5
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
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Register definition
ADCx_CLP4 field descriptions
Field
Description
31–10
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
9–0
CLP4
Calibration Value
28.3.13 ADC Plus-Side General Calibration Value Register
(ADCx_CLP3)
For more information, see CLPD register description.
Address: 4003_B000h base + 40h offset = 4003_B040h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
0
R
0
0
0
0
0
0
0
0
0
0
0
3
2
1
0
0
0
0
0
0
4
3
2
1
0
0
0
0
CLP3
W
Reset
4
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
ADCx_CLP3 field descriptions
Field
Description
31–9
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
8–0
CLP3
Calibration Value
28.3.14 ADC Plus-Side General Calibration Value Register
(ADCx_CLP2)
For more information, see CLPD register description.
Address: 4003_B000h base + 44h offset = 4003_B044h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
0
R
CLP2
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
0
ADCx_CLP2 field descriptions
Field
31–8
Reserved
7–0
CLP2
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Calibration Value
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Chapter 28 Analog-to-Digital Converter (ADC)
28.3.15 ADC Plus-Side General Calibration Value Register
(ADCx_CLP1)
For more information, see CLPD register description.
Address: 4003_B000h base + 48h offset = 4003_B048h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
0
R
0
0
0
0
0
0
0
0
0
0
0
0
2
1
0
CLP1
W
Reset
3
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
4
3
2
1
0
0
0
ADCx_CLP1 field descriptions
Field
Description
31–7
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
6–0
CLP1
Calibration Value
28.3.16 ADC Plus-Side General Calibration Value Register
(ADCx_CLP0)
For more information, see CLPD register description.
Address: 4003_B000h base + 4Ch offset = 4003_B04Ch
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
0
R
CLP0
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
ADCx_CLP0 field descriptions
Field
31–6
Reserved
5–0
CLP0
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Calibration Value
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Functional description
28.4 Functional description
The ADC module is disabled during reset, in Low-Power Stop mode, or when
SC1n[ADCH] are all high; see the power management information for details. The
module is idle when a conversion has completed and another conversion has not been
initiated. When it is idle and the asynchronous clock output enable is disabled, or
CFG2[ADACKEN]= 0, the module is in its lowest power state. The ADC can perform an
analog-to-digital conversion on any of the software selectable channels. All modes
perform conversion by a successive approximation algorithm.
To meet accuracy specifications, the ADC module must be calibrated using the on-chip
calibration function. See Calibration function for details on how to perform calibration.
When the conversion is completed, the result is placed in the Rn data registers. The
respective SC1n[COCO] is then set and an interrupt is generated if the respective
conversion complete interrupt has been enabled, or, when SC1n[AIEN]=1.
The ADC module has the capability of automatically comparing the result of a
conversion with the contents of the CV1 and CV2 registers. The compare function is
enabled by setting SC2[ACFE] and operates in any of the conversion modes and
configurations.
The ADC module has the capability of automatically averaging the result of multiple
conversions. The hardware average function is enabled by setting SC3[AVGE] and
operates in any of the conversion modes and configurations.
NOTE
For the chip specific modes of operation, see the power
management information of this MCU.
28.4.1 Clock select and divide control
One of four clock sources can be selected as the clock source for the ADC module. This
clock source is then divided by a configurable value to generate the input clock ADCK,
to the module. The clock is selected from one of the following sources by means of
CFG1[ADICLK].
• Bus clock. This is the default selection following reset.
• Bus clock divided by two. For higher bus clock rates, this allows a maximum divideby-16 of the bus clock using CFG1[ADIV].
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Chapter 28 Analog-to-Digital Converter (ADC)
• ALTCLK: As defined for this MCU. See the chip configuration information.
• Asynchronous clock (ADACK): This clock is generated from a clock source within
the ADC module. When the ADACK clock source is selected, it is not required to be
active prior to conversion start. When it is selected and it is not active prior to a
conversion start CFG2[ADACKEN]=0, ADACK is activated at the start of a
conversion and deactivated when conversions are terminated. In this case, there is an
associated clock startup delay each time the clock source is re-activated. To avoid the
conversion time variability and latency associated with the ADACK clock startup, set
CFG2[ADACKEN]=1 and wait the worst-case startup time of 5 µs prior to initiating
any conversions using the ADACK clock source. Conversions are possible using
ADACK as the input clock source while the MCU is in Normal Stop mode. See
Power Control for more information.
Whichever clock is selected, its frequency must fall within the specified frequency range
for ADCK. If the available clocks are too slow, the ADC may not perform according to
specifications. If the available clocks are too fast, the clock must be divided to the
appropriate frequency. This divider is specified by CFG1[ADIV] and can be divide-by 1,
2, 4, or 8.
28.4.2 Voltage reference selection
The ADC can be configured to accept one of the two voltage reference pairs as the
reference voltage (VREFSH and VREFSL) used for conversions. Each pair contains a
positive reference that must be between the minimum Ref Voltage High and VDDA, and a
ground reference that must be at the same potential as VSSA. The two pairs are external
(VREFH and VREFL) and alternate (VALTH and VALTL). These voltage references are
selected using SC2[REFSEL]. The alternate (VALTH and VALTL) voltage reference pair
may select additional external pins or internal sources depending on MCU configuration.
See the chip configuration information on the voltage references specific to this MCU.
28.4.3 Hardware trigger and channel selects
The ADC module has a selectable asynchronous hardware conversion trigger, ADHWT,
that is enabled when SC2[ADTRG] is set and a hardware trigger select event,
ADHWTSn, has occurred. This source is not available on all MCUs. See the Chip
Configuration chapter for information on the ADHWT source and the ADHWTSn
configurations specific to this MCU.
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Functional description
When an ADHWT source is available and hardware trigger is enabled, that is
SC2[ADTRG]=1, a conversion is initiated on the rising-edge of ADHWT after a
hardware trigger select event, that is, ADHWTSn, has occurred. If a conversion is in
progress when a rising-edge of a trigger occurs, the rising-edge is ignored. In continuous
convert configuration, only the initial rising-edge to launch continuous conversions is
observed, and until conversion is aborted, the ADC continues to do conversions on the
same SCn register that initiated the conversion. The hardware trigger function operates in
conjunction with any of the conversion modes and configurations.
The hardware trigger select event, that is, ADHWTSn, must be set prior to the receipt of
the ADHWT signal. If these conditions are not met, the converter may ignore the trigger
or use the incorrect configuration. If a hardware trigger select event is asserted during a
conversion, it must stay asserted until the end of current conversion and remain set until
the receipt of the ADHWT signal to trigger a new conversion. The channel and status
fields selected for the conversion depend on the active trigger select signal:
• ADHWTSA active selects SC1A
• ADHWTSn active selects SC1n
Note
Asserting more than one hardware trigger select signal
(ADHWTSn) at the same time results in unknown results. To
avoid this, select only one hardware trigger select signal
(ADHWTSn) prior to the next intended conversion.
When the conversion is completed, the result is placed in the Rn registers associated with
the ADHWTSn received. For example:
• ADHWTSA active selects RA register
• ADHWTSn active selects Rn register
The conversion complete flag associated with the ADHWTSn received, that is,
SC1n[COCO], is then set and an interrupt is generated if the respective conversion
complete interrupt has been enabled, that is, SC1[AIEN]=1.
28.4.4 Conversion control
Conversions can be performed as determined by CFG1[MODE] as shown in the
description of CFG1[MODE].
Conversions can be initiated by a software or hardware trigger. In addition, the ADC
module can be configured for:
• Low-power operation
• Long sample time
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Chapter 28 Analog-to-Digital Converter (ADC)
• Continuous conversion
• Hardware average
• Automatic compare of the conversion result to a software determined compare value
28.4.4.1 Initiating conversions
A conversion is initiated:
• Following a write to SC1A, with SC1n[ADCH] not all 1's, if software triggered
operation is selected, that is, when SC2[ADTRG]=0.
• Following a hardware trigger, or ADHWT event, if hardware triggered operation is
selected, that is, SC2[ADTRG]=1, and a hardware trigger select event, ADHWTSn,
has occurred. The channel and status fields selected depend on the active trigger
select signal:
• ADHWTSA active selects SC1A
• ADHWTSn active selects SC1n
• if neither is active, the off condition is selected
Note
Selecting more than one ADHWTSn prior to a conversion
completion will result in unknown results. To avoid this,
select only one ADHWTSn prior to a conversion
completion.
• Following the transfer of the result to the data registers when continuous conversion
is enabled, that is, when ADCO=1.
If continuous conversions are enabled, a new conversion is automatically initiated after
the completion of the current conversion, by:. In software triggered operation, that is,
when ADTRG=0, continuous conversions begin after SC1A is written and continue until
aborted. In hardware triggered operation, that is, when ADTRG=1 and one ADHWTSn
event has occurred, continuous conversions begin after a hardware trigger event and
continue until aborted.
If hardware averaging is enabled, a new conversion is automatically initiated after the
completion of the current conversion until the correct number of conversions are
completed. In software triggered operation, conversions begin after SC1A is written. In
hardware triggered operation, conversions begin after a hardware trigger. If continuous
conversions are also enabled, a new set of conversions to be averaged are initiated
following the last of the selected number of conversions.
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28.4.4.2 Completing conversions
A conversion is completed when the result of the conversion is transferred into the data
result registers, Rn. If the compare functions are disabled, this is indicated by setting of
SC1n[COCO]. If hardware averaging is enabled, the respective SC1n[COCO] sets only if
the last of the selected number of conversions is completed. If the compare function is
enabled, the respective SC1n[COCO] sets and conversion result data is transferred only if
the compare condition is true. If both hardware averaging and compare functions are
enabled, then the respective SC1n[COCO] sets only if the last of the selected number of
conversions is completed and the compare condition is true. An interrupt is generated if
the respective SC1n[AIEN] is high at the time that the respective SC1n[COCO] is set.
28.4.4.3 Aborting conversions
Any conversion in progress is aborted when:
• Writing to SC1A while it is actively controlling a conversion, aborts the current
conversion. In Software Trigger mode, when SC2[ADTRG]=0, a write to SC1A
initiates a new conversion if SC1A[ADCH] is equal to a value other than all 1s.
Writing to any of the SC1B–SC1n registers while that specific SC1B–SC1n register
is actively controlling a conversion aborts the current conversion. The SC1(B-n)
registers are not used for software trigger operation and therefore writes to the
SC1(B-n) registers do not initiate a new conversion.
• A write to any ADC register besides the SC1A-SC1n registers occurs. This indicates
that a change in mode of operation has occurred and the current conversion is
therefore invalid.
• The MCU is reset or enters Low-Power Stop modes.
• The MCU enters Normal Stop mode with ADACK not enabled.
When a conversion is aborted, the contents of the data registers, Rn, are not altered. The
data registers continue to be the values transferred after the completion of the last
successful conversion. If the conversion was aborted by a reset or Low-Power Stop
modes, RA and Rn return to their reset states.
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Chapter 28 Analog-to-Digital Converter (ADC)
28.4.4.4 Power control
The ADC module remains in its idle state until a conversion is initiated. If ADACK is
selected as the conversion clock source, but the asynchronous clock output is disabled,
that is CFG2[ADACKEN]=0, the ADACK clock generator also remains in its idle state
(disabled) until a conversion is initiated. If the asynchronous clock output is enabled, that
is, CFG2[ADACKEN]=1, it remains active regardless of the state of the ADC or the
MCU power mode.
Power consumption when the ADC is active can be reduced by setting CFG1[ADLPC].
This results in a lower maximum value for fADCK.
28.4.4.5 Sample time and total conversion time
For short sample, that is, when CFG1[ADLSMP]=0, there is a 2-cycle adder for first
conversion over the base sample time of four ADCK cycles. For high speed conversions,
that is, when CFG2[ADHSC]=1, there is an additional 2-cycle adder on any conversion.
The table below summarizes sample times for the possible ADC configurations.
ADC configuration
Sample time (ADCK cycles)
CFG1[ADLSMP]
CFG2[ADLSTS]
CFG2[ADHSC]
First or Single
Subsequent
0
X
0
6
4
1
00
0
24
1
01
0
16
1
10
0
10
1
11
0
6
0
X
1
1
00
1
26
1
01
1
18
1
10
1
12
1
11
1
8
8
6
The total conversion time depends upon:
• The sample time as determined by CFG1[ADLSMP] and CFG2[ADLSTS]
• The MCU bus frequency
• The conversion mode, as determined by CFG1[MODE]
• The high speed configuration, that is, CFG2[ADHSC]
• The frequency of the conversion clock, that is, fADCK.
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CFG2[ADHSC] is used to configure a higher clock input frequency. This will allow
faster overall conversion times. To meet internal ADC timing requirements,
CFG2[ADHSC] adds additional ADCK cycles. Conversions with CFG2[ADHSC]=1 take
two more ADCK cycles. CFG2[ADHSC] must be used when the ADCLK exceeds the
limit for CFG2[ADHSC]=0.
After the module becomes active, sampling of the input begins.
1. CFG1[ADLSMP] and CFG2[ADLSTS] select between sample times based on the
conversion mode that is selected.
2. When sampling is completed, the converter is isolated from the input channel and a
successive approximation algorithm is applied to determine the digital value of the
analog signal.
3. The result of the conversion is transferred to Rn upon completion of the conversion
algorithm.
If the bus frequency is less than fADCK, precise sample time for continuous conversions
cannot be guaranteed when short sample is enabled, that is, when CFG1[ADLSMP]=0.
The maximum total conversion time is determined by the clock source chosen and the
divide ratio selected. The clock source is selectable by CFG1[ADICLK], and the divide
ratio is specified by CFG1[ADIV].
The maximum total conversion time for all configurations is summarized in the equation
below. See the following tables for the variables referenced in the equation.
Figure 28-46. Conversion time equation
Table 28-54. Single or first continuous time adder (SFCAdder)
CFG1[AD
LSMP]
CFG2[AD
ACKEN]
CFG1[ADICLK]
Single or first continuous time adder (SFCAdder)
1
x
0x, 10
3 ADCK cycles + 5 bus clock cycles
1
1
11
3 ADCK cycles + 5 bus clock cycles1
1
0
11
5 μs + 3 ADCK cycles + 5 bus clock cycles
0
x
0x, 10
5 ADCK cycles + 5 bus clock cycles
0
1
11
5 ADCK cycles + 5 bus clock cycles1
0
0
11
5 μs + 5 ADCK cycles + 5 bus clock cycles
1. To achieve this time, CFG2[ADACKEN] must be 1 for at least 5 μs prior to the conversion is initiated.
Table 28-55. Average number factor (AverageNum)
SC3[AVGE]
SC3[AVGS]
Average number factor (AverageNum)
0
xx
1
Table continues on the next page...
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Chapter 28 Analog-to-Digital Converter (ADC)
Table 28-55. Average number factor (AverageNum) (continued)
SC3[AVGE]
SC3[AVGS]
Average number factor (AverageNum)
1
00
4
1
01
8
1
10
16
1
11
32
Table 28-56. Base conversion time (BCT)
Mode
Base conversion time (BCT)
8b single-ended
17 ADCK cycles
10b single-ended
20 ADCK cycles
12b single-ended
20 ADCK cycles
Table 28-57. Long sample time adder (LSTAdder)
CFG1[ADLSMP]
CFG2[ADLSTS]
Long sample time adder
(LSTAdder)
0
xx
0 ADCK cycles
1
00
20 ADCK cycles
1
01
12 ADCK cycles
1
10
6 ADCK cycles
1
11
2 ADCK cycles
Table 28-58. High-speed conversion time adder (HSCAdder)
CFG2[ADHSC]
High-speed conversion time adder (HSCAdder)
0
0 ADCK cycles
1
2 ADCK cycles
Note
The ADCK frequency must be between fADCK minimum and
fADCK maximum to meet ADC specifications.
28.4.4.6 Conversion time examples
The following examples use the Figure 28-46, and the information provided in Table
28-54 through Table 28-58.
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Functional description
28.4.4.6.1 Typical conversion time configuration
A typical configuration for ADC conversion is:
• 10-bit mode, with the bus clock selected as the input clock source
• The input clock divide-by-1 ratio selected
• Bus frequency of 8 MHz
• Long sample time disabled
• High-speed conversion disabled
The conversion time for a single conversion is calculated by using the Figure 28-46, and
the information provided in Table 28-54 through Table 28-58. The table below lists the
variables of Figure 28-46.
Table 28-59. Typical conversion time
Variable
Time
SFCAdder
5 ADCK cycles + 5 bus clock cycles
AverageNum
1
BCT
20 ADCK cycles
LSTAdder
0
HSCAdder
0
The resulting conversion time is generated using the parameters listed in the preceding
table. Therefore, for a bus clock and an ADCK frequency equal to 8 MHz, the resulting
conversion time is 3.75 µs.
28.4.4.6.2 Short conversion time configuration
A configuration for short ADC conversion is:
• 8-bit Single-Ended mode with the bus clock selected as the input clock source
• The input clock divide-by-1 ratio selected
• Bus frequency of 20 MHz
• Long sample time disabled
• High-speed conversion enabled
The conversion time for this conversion is calculated by using the Figure 28-46, and the
information provided in Table 28-54 through Table 28-58. The table below lists the
variables of Figure 28-46.
Table 28-60. Typical conversion time
Variable
Time
SFCAdder
5 ADCK cycles + 5 bus clock cycles
AverageNum
1
BCT
17 ADCK cycles
Table continues on the next page...
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Chapter 28 Analog-to-Digital Converter (ADC)
Table 28-60. Typical conversion time (continued)
Variable
Time
LSTAdder
0 ADCK cycles
HSCAdder
2
The resulting conversion time is generated using the parameters listed in in the preceding
table. Therefore, for bus clock and ADCK frequency equal to 20 MHz, the resulting
conversion time is 1.45 µs.
28.4.4.7 Hardware average function
The hardware average function can be enabled by setting SC3[AVGE]=1 to perform a
hardware average of multiple conversions. The number of conversions is determined by
the AVGS[1:0] bits, which can select 4, 8, 16, or 32 conversions to be averaged. While
the hardware average function is in progress, SC2[ADACT] will be set.
After the selected input is sampled and converted, the result is placed in an accumulator
from which an average is calculated once the selected number of conversions have been
completed. When hardware averaging is selected, the completion of a single conversion
will not set SC1n[COCO].
If the compare function is either disabled or evaluates true, after the selected number of
conversions are completed, the average conversion result is transferred into the data
result registers, Rn, and SC1n[COCO] is set. An ADC interrupt is generated upon the
setting of SC1n[COCO] if the respective ADC interrupt is enabled, that is,
SC1n[AIEN]=1.
Note
The hardware average function can perform conversions on a
channel while the MCU is in Wait or Normal Stop modes. The
ADC interrupt wakes the MCU when the hardware average is
completed if SC1n[AIEN] was set.
28.4.5 Automatic compare function
The compare function can be configured to check whether the result is less than or
greater-than-or-equal-to a single compare value, or, if the result falls within or outside a
range determined by two compare values. The compare mode is determined by
SC2[ACFGT], SC2[ACREN], and the values in the compare value registers, CV1 and
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Functional description
CV2. After the input is sampled and converted, the compare values in CV1 and CV2 are
used as described in the following table. There are six Compare modes as shown in the
following table.
Table 28-61. Compare modes
SC2[AC
FGT]
SC2[AC
REN]
ADCCV1
relative to
ADCCV2
0
0
1
Function
Compare mode description
—
Less than threshold
Compare true if the result is less than the
CV1 registers.
0
—
Greater than or equal to threshold
Compare true if the result is greater than or
equal to CV1 registers.
0
1
Less than or
equal
Outside range, not inclusive
Compare true if the result is less than CV1
Or the result is greater than CV2.
0
1
Greater than
Inside range, not inclusive
Compare true if the result is less than CV1
And the result is greater than CV2.
1
1
Less than or
equal
Inside range, inclusive
Compare true if the result is greater than or
equal to CV1 And the result is less than or
equal to CV2.
1
1
Greater than
Outside range, inclusive
Compare true if the result is greater than or
equal to CV1 Or the result is less than or
equal to CV2.
With SC2[ACREN] =1, and if the value of CV1 is less than or equal to the value of CV2,
then setting SC2[ACFGT] will select a trigger-if-inside-compare-range inclusive-ofendpoints function. Clearing SC2[ACFGT] will select a trigger-if-outside-comparerange, not-inclusive-of-endpoints function.
If CV1 is greater than CV2, setting SC2[ACFGT] will select a trigger-if-outsidecompare-range, inclusive-of-endpoints function. Clearing SC2[ACFGT] will select a
trigger-if-inside-compare-range, not-inclusive-of-endpoints function.
If the condition selected evaluates true, SC1n[COCO] is set.
Upon completion of a conversion while the compare function is enabled, if the compare
condition is not true, SC1n[COCO] is not set and the conversion result data will not be
transferred to the result register, Rn. If the hardware averaging function is enabled, the
compare function compares the averaged result to the compare values. The same compare
function definitions apply. An ADC interrupt is generated when SC1n[COCO] is set and
the respective ADC interrupt is enabled, that is, SC1n[AIEN]=1.
Note
The compare function can monitor the voltage on a channel
while the MCU is in Wait or Normal Stop modes. The ADC
interrupt wakes the MCU when the compare condition is met.
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Chapter 28 Analog-to-Digital Converter (ADC)
28.4.6 Calibration function
The ADC contains a self-calibration function that is required to achieve the specified
accuracy. Calibration must be run, or valid calibration values written, after any reset and
before a conversion is initiated. The calibration function sets the offset calibration value
and the plus-side calibration values. The offset calibration value is automatically stored in
the ADC offset correction register (OFS), and the plus-side calibration values are
automatically stored in the ADC plus-side calibration registers, CLPx. The user must
configure the ADC correctly prior to calibration, and must generate the plus-side gain
calibration results and store them in the ADC plus-side gain register (PG) after the
calibration function completes.
Prior to calibration, the user must configure the ADC's clock source and frequency, low
power configuration, voltage reference selection, sample time, and high speed
configuration according to the application's clock source availability and needs. If the
application uses the ADC in a wide variety of configurations, the configuration for which
the highest accuracy is required should be selected, or multiple calibrations can be done
for the different configurations. For best calibration results:
• Set hardware averaging to maximum, that is, SC3[AVGE]=1 and SC3[AVGS]=11
for an average of 32
• Set ADC clock frequency fADCK less than or equal to 4 MHz
• VREFH=VDDA
• Calibrate at nominal voltage and temperature
The input channel, conversion mode continuous function, compare function, resolution
mode, and single-ended mode are all ignored during the calibration function.
To initiate calibration, the user sets SC3[CAL] and the calibration will automatically
begin if the SC2[ADTRG] is 0. If SC2[ADTRG] is 1, SC3[CAL] will not get set and
SC3[CALF] will be set. While calibration is active, no ADC register can be written and
no stop mode may be entered, or the calibration routine will be aborted causing
SC3[CAL] to clear and SC3[CALF] to set. At the end of a calibration sequence,
SC1n[COCO] will be set. SC1n[AIEN] can be used to allow an interrupt to occur at the
end of a calibration sequence. At the end of the calibration routine, if SC3[CALF] is not
set, the automatic calibration routine is completed successfully.
To complete calibration, the user must generate the gain calibration values using the
following procedure:
1. Initialize or clear a 16-bit variable in RAM.
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Functional description
2. Add the plus-side calibration results CLP0, CLP1, CLP2, CLP3, CLP4, and CLPS to
the variable.
3. Divide the variable by two.
4. Set the MSB of the variable.
5. The previous two steps can be achieved by setting the carry bit, rotating to the right
through the carry bit on the high byte and again on the low byte.
6. Store the value in the plus-side gain calibration register PG.
When calibration is complete, the user may reconfigure and use the ADC as desired. A
second calibration may also be performed, if desired, by clearing and again setting
SC3[CAL].
Overall, the calibration routine may take as many as 14k ADCK cycles and 100 bus
cycles, depending on the results and the clock source chosen. For an 8 MHz clock source,
this length amounts to about 1.7 ms. To reduce this latency, the calibration values, which
are offset, plus-side gain, and plus-side calibration values, may be stored in flash memory
after an initial calibration and recovered prior to the first ADC conversion. This method
can reduce the calibration latency to 20 register store operations on all subsequent power,
reset, or Low-Power Stop mode recoveries.
28.4.7 User-defined offset function
OFS contains the user-selected or calibration-generated offset error correction value. This
register is a 2’s complement, left-justified. The value in OFS is subtracted from the
conversion and the result is transferred into the result registers, Rn. If the result is greater
than the maximum or less than the minimum result value, it is forced to the appropriate
limit for the current mode of operation.
The formatting of the OFS is different from the data result register, Rn, to preserve the
resolution of the calibration value regardless of the conversion mode selected. Lower
order bits are ignored in lower resolution modes. For example, in 8-bit single-ended
mode, OFS[14:7] are subtracted from D[7:0]; OFS[15] indicates the sign (negative
numbers are effectively added to the result) and OFS[6:0] are ignored.
OFS is automatically set according to calibration requirements once the self-calibration
sequence is done, that is, SC3[CAL] is cleared. The user may write to OFS to override
the calibration result if desired. If the OFS is written by the user to a value that is
different from the calibration value, the ADC error specifications may not be met. Storing
the value generated by the calibration function in memory before overwriting with a userspecified value is recommended.
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Chapter 28 Analog-to-Digital Converter (ADC)
Note
There is an effective limit to the values of offset that can be set
by the user. If the magnitude of the offset is too high, the results
of the conversions will cap off at the limits.
The offset calibration function may be employed by the user to remove application
offsets or DC bias values. OFS may be written with a number in 2's complement format
and this offset will be subtracted from the result, or hardware averaged value. To add an
offset, store the negative offset in 2's complement format and the effect will be an
addition. An offset correction that results in an out-of-range value will be forced to the
minimum or maximum value. The minimum value for single-ended conversions is
0x0000.
To preserve accuracy, the calibrated offset value initially stored in OFS must be added to
the user-defined offset. For applications that may change the offset repeatedly during
operation, store the initial offset calibration value in flash so it can be recovered and
added to any user offset adjustment value and the sum stored in OFS.
28.4.8 Temperature sensor
The ADC module includes a temperature sensor whose output is connected to one of the
ADC analog channel inputs. The following equation provides an approximate transfer
function of the temperature sensor.
m
Figure 28-47. Approximate transfer function of the temperature sensor
where:
• VTEMP is the voltage of the temperature sensor channel at the ambient temperature.
• VTEMP25 is the voltage of the temperature sensor channel at 25 °C.
• m is referred as temperature sensor slope in the device data sheet. It is the hot or cold
voltage versus temperature slope in V/°C.
For temperature calculations, use the VTEMP25 and temperature sensor slope values from
the ADC Electricals table.
In application code, the user reads the temperature sensor channel, calculates VTEMP, and
compares to VTEMP25. If VTEMP is greater than VTEMP25 the cold slope value is applied in
the preceding equation. If VTEMP is less than VTEMP25, the hot slope value is applied in
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Functional description
the preceding equation. ADC Electricals table may only specify one temperature sensor
slope value. In that case, the user could use the same slope for the calculation across the
operational temperature range.
For more information on using the temperature sensor, see the application note titled
Temperature Sensor for the HCS08 Microcontroller Family (document AN3031).
28.4.9 MCU wait mode operation
Wait mode is a lower-power consumption Standby mode from which recovery is fast
because the clock sources remain active. If a conversion is in progress when the MCU
enters Wait mode, it continues until completion. Conversions can be initiated while the
MCU is in Wait mode by means of the hardware trigger or if continuous conversions are
enabled.
The bus clock, bus clock divided by two, and ADACK are available as conversion clock
sources while in Wait mode. The use of ALTCLK as the conversion clock source in Wait
is dependent on the definition of ALTCLK for this MCU. See the Chip Configuration
information on ALTCLK specific to this MCU.
If the compare and hardware averaging functions are disabled, a conversion complete
event sets SC1n[COCO] and generates an ADC interrupt to wake the MCU from Wait
mode if the respective ADC interrupt is enabled, that is, when SC1n[AIEN]=1. If the
hardware averaging function is enabled, SC1n[COCO] will set, and generate an interrupt
if enabled, when the selected number of conversions are completed. If the compare
function is enabled, SC1n[COCO] will set, and generate an interrupt if enabled, only if
the compare conditions are met. If a single conversion is selected and the compare trigger
is not met, the ADC will return to its idle state and cannot wake the MCU from Wait
mode unless a new conversion is initiated by the hardware trigger.
28.4.10 MCU Normal Stop mode operation
Stop mode is a low-power consumption Standby mode during which most or all clock
sources on the MCU are disabled.
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Chapter 28 Analog-to-Digital Converter (ADC)
28.4.10.1 Normal Stop mode with ADACK disabled
If the asynchronous clock, ADACK, is not selected as the conversion clock, executing a
stop instruction aborts the current conversion and places the ADC in its Idle state. The
contents of the ADC registers, including Rn, are unaffected by Normal Stop mode. After
exiting from Normal Stop mode, a software or hardware trigger is required to resume
conversions.
28.4.10.2 Normal Stop mode with ADACK enabled
If ADACK is selected as the conversion clock, the ADC continues operation during
Normal Stop mode. See the chip configuration chapter for configuration information for
this MCU.
If a conversion is in progress when the MCU enters Normal Stop mode, it continues until
completion. Conversions can be initiated while the MCU is in Normal Stop mode by
means of the hardware trigger or if continuous conversions are enabled.
If the compare and hardware averaging functions are disabled, a conversion complete
event sets SC1n[COCO] and generates an ADC interrupt to wake the MCU from Normal
Stop mode if the respective ADC interrupt is enabled, that is, when SC1n[AIEN]=1. The
result register, Rn, will contain the data from the first completed conversion that occurred
during Normal Stop mode. If the hardware averaging function is enabled, SC1n[COCO]
will set, and generate an interrupt if enabled, when the selected number of conversions
are completed. If the compare function is enabled, SC1n[COCO] will set, and generate an
interrupt if enabled, only if the compare conditions are met. If a single conversion is
selected and the compare is not true, the ADC will return to its Idle state and cannot wake
the MCU from Normal Stop mode unless a new conversion is initiated by another
hardware trigger.
28.4.11 MCU Low-Power Stop mode operation
The ADC module is automatically disabled when the MCU enters Low-Power Stop
mode. All module registers contain their reset values following exit from Low-Power
Stop mode. Therefore, the module must be re-enabled and re-configured following exit
from Low-Power Stop mode.
NOTE
For the chip specific modes of operation, see the power
management information for the device.
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Initialization information
28.5 Initialization information
This section gives an example that provides some basic direction on how to initialize and
configure the ADC module. The user can configure the module for 12-bit, 10-bit, or 8-bit
single-ended resolution, single or continuous conversion, and a polled or interrupt
approach, among many other options. For information used in this example, refer to
Table 28-57, Table 28-58, and Table 28-59.
Note
Hexadecimal values are designated by a preceding 0x, binary
values designated by a preceding %, and decimal values have
no preceding character.
28.5.1 ADC module initialization example
28.5.1.1 Initialization sequence
Before the ADC module can be used to complete conversions, an initialization procedure
must be performed. A typical sequence is:
1. Calibrate the ADC by following the calibration instructions in Calibration function.
2. Update CFG to select the input clock source and the divide ratio used to generate
ADCK. This register is also used for selecting sample time and low-power
configuration.
3. Update SC2 to select the conversion trigger, hardware or software, and compare
function options, if enabled.
4. Update SC3 to select whether conversions will be continuous or completed only once
(ADCO) and whether to perform hardware averaging.
5. Update SC1:SC1n registers to enable or disable conversion complete interrupts.
Also, select the input channel which can be used to perform conversions.
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Chapter 28 Analog-to-Digital Converter (ADC)
28.5.1.2 Pseudo-code example
In this example, the ADC module is set up with interrupts enabled to perform a single 10bit conversion at low-power with a long sample time on input channel 1, where ADCK is
derived from the bus clock divided by 1.
CFG1 = 0x98 (%10011000)
Bit
Bit
Bit
Bit
Bit
7
ADLPC
1
6:5 ADIV
00
4
ADLSMP 1
3:2
MODE
10
1:0
ADICLK
00
Configures for low power, lowers maximum clock speed.
Sets the ADCK to the input clock ÷ 1.
Configures for long sample time.
Selects the single-ended 10-bit conversion.
Selects the bus clock.
SC2 = 0x00 (%00000000)
Bit
Bit
Bit
Bit
Bit
Bit
Bit
and VREFL).
7
6
5
4
3
2
1:0
ADACT
ADTRG
ACFE
ACFGT
ACREN
DMAEN
REFSEL
0
0
0
0
0
0
00
Flag indicates if a conversion is in progress.
Software trigger selected.
Compare function disabled.
Not used in this example.
Compare range disabled.
DMA request disabled.
Selects default voltage reference pin pair (External pins VREFH
SC1A = 0x41 (%01000001)
Bit 7
Bit 6
COCO
AIEN
Bit 4:0 ADCH
0
1
Read-only flag which is set when a conversion completes.
Conversion complete interrupt enabled.
00001
Input channel 1 selected as ADC input channel.
RA = 0xxx
Holds results of conversion.
CV = 0xxx
Holds compare value when compare function enabled.
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Application information
Reset
Initialize ADC
CFG1 = 0x98
SC2 = 0x00
SC1n = 0x41
Check
No
SC1n[COCO]=1?
Yes
Read Rn
to clear
SC1n[COCO]
Continue
Figure 28-48. Initialization flowchart example
28.6 Application information
The ADC has been designed to be integrated into a microcontroller for use in embedded
control applications requiring an ADC.
28.6.1 External pins and routing
28.6.1.1 Analog supply pins
Depending on the device, the analog power and ground supplies, VDDA and VSSA, of the
ADC module are available as:
• VDDA and VSSA available as separate pins—When available on a separate pin, both
VDDA and VSSA must be connected to the same voltage potential as their
corresponding MCU digital supply, VDD and VSS, and must be routed carefully for
maximum noise immunity and bypass capacitors placed as near as possible to the
package.
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Chapter 28 Analog-to-Digital Converter (ADC)
• VSSA is shared on the same pin as the MCU digital VSS.
• VSSA and VDDA are shared with the MCU digital supply pins—In these cases, there
are separate pads for the analog supplies bonded to the same pin as the corresponding
digital supply so that some degree of isolation between the supplies is maintained.
If separate power supplies are used for analog and digital power, the ground connection
between these supplies must be at the VSSA pin. This must be the only ground connection
between these supplies, if possible. VSSA makes a good single point ground location.
28.6.1.2 Analog voltage reference pins
In addition to the analog supplies, the ADC module has connections for two reference
voltage inputs used by the converter:
• VREFSH is the high reference voltage for the converter.
• VREFSL is the low reference voltage for the converter.
The ADC can be configured to accept one of two voltage reference pairs for VREFSH and
VREFSL. Each pair contains a positive reference and a ground reference. The two pairs are
external, VREFH and VREFL and alternate, VALTH and VALTL. These voltage references are
selected using SC2[REFSEL]. The alternate voltage reference pair, VALTH and VALTL,
may select additional external pins or internal sources based on MCU configuration. See
the chip configuration information on the voltage references specific to this MCU.
In some packages, the external or alternate pairs are connected in the package to VDDA
and VSSA, respectively. One of these positive references may be shared on the same pin
as VDDA on some devices. One of these ground references may be shared on the same pin
as VSSA on some devices.
If externally available, the positive reference may be connected to the same potential as
VDDA or may be driven by an external source to a level between the minimum Ref
Voltage High and the VDDA potential. The positive reference must never exceed VDDA. If
externally available, the ground reference must be connected to the same voltage
potential as VSSA. The voltage reference pairs must be routed carefully for maximum
noise immunity and bypass capacitors placed as near as possible to the package.
AC current in the form of current spikes required to supply charge to the capacitor array
at each successive approximation step is drawn through the VREFH and VREFL loop. The
best external component to meet this current demand is a 0.1 μF capacitor with good
high-frequency characteristics. This capacitor is connected between VREFH and VREFL
and must be placed as near as possible to the package pins. Resistance in the path is not
recommended because the current causes a voltage drop that could result in conversion
errors. Inductance in this path must be minimum, that is, parasitic only.
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28.6.1.3 Analog input pins
The external analog inputs are typically shared with digital I/O pins on MCU devices.
Empirical data shows that capacitors on the analog inputs improve performance in the
presence of noise or when the source impedance is high. Use of 0.01 μF capacitors with
good high-frequency characteristics is sufficient. These capacitors are not necessary in all
cases, but when used, they must be placed as near as possible to the package pins and be
referenced to VSSA.
For proper conversion, the input voltage must fall between VREFH and VREFL. If the input
is equal to or exceeds VREFH, the converter circuit converts the signal to 0xFFF, which is
full scale 12-bit representation, 0x3FF, which is full scale 10-bit representation, or 0xFF,
which is full scale 8-bit representation. If the input is equal to or less than VREFL, the
converter circuit converts it to 0x000. Input voltages between VREFH and VREFL are
straight-line linear conversions. There is a brief current associated with VREFL when the
sampling capacitor is charging.
For minimal loss of accuracy due to current injection, pins adjacent to the analog input
pins must not be transitioning during conversions.
28.6.2 Sources of error
28.6.2.1 Sampling error
For proper conversions, the input must be sampled long enough to achieve the proper
accuracy.
RAS + RADIN =SC / (FMAX * NUMTAU * CADIN)
Figure 28-49. Sampling equation
Where:
RAS = External analog source resistance
SC = Number of ADCK cycles used during sample window
CADIN = Internal ADC input capacitance
NUMTAU = -ln(LSBERR / 2N)
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Chapter 28 Analog-to-Digital Converter (ADC)
LSBERR = value of acceptable sampling error in LSBs
N = 8 in 8-bit mode, 10 in 10-bit mode, 12 in 12-bit mode
Higher source resistances or higher-accuracy sampling is possible by setting
CFG1[ADLSMP] and changing CFG2[ADLSTS] to increase the sample window, or
decreasing ADCK frequency to increase sample time.
28.6.2.2 Pin leakage error
Leakage on the I/O pins can cause conversion error if the external analog source
resistance, RAS, is high. If this error cannot be tolerated by the application, keep RAS
lower than VREFH / (4 × ILEAK × 2N) for less than 1/4 LSB leakage error, where N = 8 in
8-bit mode, 10 in 10-bit mode, 12 in 12-bit mode.
28.6.2.3 Noise-induced errors
System noise that occurs during the sample or conversion process can affect the accuracy
of the conversion. The ADC accuracy numbers are guaranteed as specified only if the
following conditions are met:
• There is a 0.1 μF low-ESR capacitor from VREFH to VREFL.
• There is a 0.1 μF low-ESR capacitor from VDDA to VSSA.
• If inductive isolation is used from the primary supply, an additional 1 μF capacitor is
placed from VDDA to VSSA.
• VSSA, and VREFL, if connected, is connected to VSS at a quiet point in the ground
plane.
• Operate the MCU in Wait or Normal Stop mode before initiating (hardware-triggered
conversions) or immediately after initiating (hardware- or software-triggered
conversions) the ADC conversion.
• For software triggered conversions, immediately follow the write to SC1 with a
Wait instruction or Stop instruction.
• For Normal Stop mode operation, select ADACK as the clock source. Operation
in Normal Stop reduces VDD noise but increases effective conversion time due to
stop recovery.
• There is no I/O switching, input or output, on the MCU during the conversion.
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Application information
There are some situations where external system activity causes radiated or conducted
noise emissions or excessive VDD noise is coupled into the ADC. In these situations, or
when the MCU cannot be placed in Wait or Normal Stop mode, or I/O activity cannot be
halted, the following actions may reduce the effect of noise on the accuracy:
• Place a 0.01 μF capacitor (CAS) on the selected input channel to VREFL or VSSA. This
improves noise issues, but affects the sample rate based on the external analog source
resistance.
• Average the result by converting the analog input many times in succession and
dividing the sum of the results. Four samples are required to eliminate the effect of a
1 LSB, one-time error.
• Reduce the effect of synchronous noise by operating off the asynchronous clock, that
is, ADACK, and averaging. Noise that is synchronous to ADCK cannot be averaged
out.
28.6.2.4 Code width and quantization error
The ADC quantizes the ideal straight-line transfer function into 4096 steps in the 12-bit
mode). Each step ideally has the same height, that is, 1 code, and width. The width is
defined as the delta between the transition points to one code and the next. The ideal code
width for an N-bit converter, where N can be 12, 10, or 8, defined as 1 LSB, is:
LSB
Figure 28-50. Ideal code width for an N-bit converter
There is an inherent quantization error due to the digitization of the result. For 8-bit, 10bit, or 12-bit conversions, the code transitions when the voltage is at the midpoint
between the points where the straight line transfer function is exactly represented by the
actual transfer function. Therefore, the quantization error will be ± 1/2 LSB in 8-bit, 10bit, or 12-bit modes. As a consequence, however, the code width of the first (0x000)
conversion is only 1/2 LSB and the code width of the last (0xFF or 0x3FF) is 1.5 LSB.
28.6.2.5 Linearity errors
The ADC may also exhibit non-linearity of several forms. Every effort has been made to
reduce these errors, but the system designers must be aware of these errors because they
affect overall accuracy:
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Chapter 28 Analog-to-Digital Converter (ADC)
• Zero-scale error (EZS), sometimes called offset: This error is defined as the difference
between the actual code width of the first conversion and the ideal code width. This
is 1/2 LSB in 8-bit, 10-bit, or 12-bit modes. If the first conversion is 0x001, the
difference between the actual 0x001 code width and its ideal (1 LSB) is used.
• Full-scale error (EFS): This error is defined as the difference between the actual code
width of the last conversion and the ideal code width. This is 1.5 LSB in 8-bit, 10-bit,
or 12-bit modes. If the last conversion is 0x3FE, the difference between the actual
0x3FE code width and its ideal (1 LSB) is used.
• Differential non-linearity (DNL): This error is defined as the worst-case difference
between the actual code width and the ideal code width for all conversions.
• Integral non-linearity (INL): This error is defined as the highest-value or absolute
value that the running sum of DNL achieves. More simply, this is the worst-case
difference of the actual transition voltage to a given code and its corresponding ideal
transition voltage, for all codes.
• Total unadjusted error (TUE): This error is defined as the difference between the
actual transfer function and the ideal straight-line transfer function and includes all
forms of error.
28.6.2.6 Code jitter, non-monotonicity, and missing codes
Analog-to-digital converters are susceptible to three special forms of error:
• Code jitter: Code jitter is when, at certain points, a given input voltage converts to
one of the two values when sampled repeatedly. Ideally, when the input voltage is
infinitesimally smaller than the transition voltage, the converter yields the lower
code, and vice-versa. However, even small amounts of system noise can cause the
converter to be indeterminate, between two codes, for a range of input voltages
around the transition voltage.
This error may be reduced by repeatedly sampling the input and averaging the result.
Additionally, the techniques discussed in Noise-induced errors reduces this error.
• Non-monotonicity: Non-monotonicity is defined as when, except for code jitter, the
converter converts to a lower code for a higher input voltage.
• Missing codes: Missing codes are those values never converted for any input value.
In 8-bit or 10-bit mode, the ADC is guaranteed to be monotonic and have no missing
codes.
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Chapter 29
Comparator (CMP)
29.1 Introduction
NOTE
For the chip-specific implementation details of this module's
instances see the chip configuration information.
The comparator (CMP) module provides a circuit for comparing two analog input
voltages. The comparator circuit is designed to operate across the full range of the supply
voltage, known as rail-to-rail operation.
The Analog MUX (ANMUX) provides a circuit for selecting an analog input signal from
eight channels. One signal is provided by the 6-bit digital-to-analog converter (DAC).
The mux circuit is designed to operate across the full range of the supply voltage.
The 6-bit DAC is 64-tap resistor ladder network which provides a selectable voltage
reference for applications where voltage reference is needed. The 64-tap resistor ladder
network divides the supply reference Vin into 64 voltage levels. A 6-bit digital signal
input selects the output voltage level, which varies from Vin to Vin/64. Vin can be selected
from two voltage sources, Vin1 and Vin2. The 6-bit DAC from a comparator is available
as an on-chip internal signal only and is not available externally to a pin.
29.2 CMP features
The CMP has the following features:
• Operational over the entire supply range
• Inputs may range from rail to rail
• Programmable hysteresis control
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6-bit DAC key features
• Selectable interrupt on rising-edge, falling-edge, or both rising or falling edges of the
comparator output
• Selectable inversion on comparator output
• Capability to produce a wide range of outputs such as:
• Sampled
• Windowed, which is ideal for certain PWM zero-crossing-detection applications
• Digitally filtered:
• Filter can be bypassed
• Can be clocked via external SAMPLE signal or scaled bus clock
• External hysteresis can be used at the same time that the output filter is used for
internal functions
• Two software selectable performance levels:
• Shorter propagation delay at the expense of higher power
• Low power, with longer propagation delay
• DMA transfer support
• A comparison event can be selected to trigger a DMA transfer
• Functional in all modes of operation
• The window and filter functions are not available in the following modes:
• Stop
• VLPS
• LLS
• VLLSx
29.3 6-bit DAC key features
•
•
•
•
6-bit resolution
Selectable supply reference source
Power Down mode to conserve power when not in use
Option to route the output to internal comparator input
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Chapter 29 Comparator (CMP)
29.4 ANMUX key features
• Two 8-to-1 channel mux
• Operational over the entire supply range
29.5 CMP, DAC and ANMUX diagram
The following figure shows the block diagram for the High-Speed Comparator, DAC,
and ANMUX modules.
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CMP block diagram
VRSEL
Vin1
Vin2
VOSEL[5:0]
MUX
DAC output
MUX
64-level
DACEN
DAC
PSEL[2:0]
CMP
MUX
Reference Input 0
Reference Input 1
Reference Input 2
Reference Input 3
Reference Input 4
Reference Input 5
Reference Input 6
INP
Sample input
CMP
MUX
ANMUX
Window
and filter
control
INM
IRQ
CMPO
MSEL[2:0]
Figure 29-1. CMP, DAC and ANMUX block diagram
29.6 CMP block diagram
The following figure shows the block diagram for the CMP module.
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Chapter 29 Comparator (CMP)
Internal bus
FILT_PER
EN,PMODE,HYSCTRL[1:0] COS
INV
OPE
WE
FILTER_CNT SE COUT
IER/F
CFR/F
INP
+
-
CMPO
Polarity
select
Window
control
Interrupt
control
Filter
block
INM
IRQ
COUT
To other SOC functions
WINDOW/SAMPLE
bus clock
Clock
prescaler
FILT_PER
1
0
0
divided
bus
clock
COUTA
CGMUX
SE
1
CMPO to
PAD
COS
Figure 29-2. Comparator module block diagram
In the CMP block diagram:
• The Window Control block is bypassed when CR1[WE] = 0
• If CR1[WE] = 1, the comparator output will be sampled on every bus clock when
WINDOW=1 to generate COUTA. Sampling does NOT occur when WINDOW = 0.
• The Filter block is bypassed when not in use.
• The Filter block acts as a simple sampler if the filter is bypassed and
CR0[FILTER_CNT] is set to 0x01.
• The Filter block filters based on multiple samples when the filter is bypassed and
CR0[FILTER_CNT] is set greater than 0x01.
• If CR1[SE] = 1, the external SAMPLE input is used as sampling clock
• IF CR1[SE] = 0, the divided bus clock is used as sampling clock
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Memory map/register definitions
• If enabled, the Filter block will incur up to one bus clock additional latency penalty
on COUT due to the fact that COUT, which is crossing clock domain boundaries,
must be resynchronized to the bus clock.
• CR1[WE] and CR1[SE] are mutually exclusive.
29.7 Memory map/register definitions
CMP memory map
Absolute
address
(hex)
Width
Access
(in bits)
Register name
Reset value
Section/
page
4007_3000
CMP Control Register 0 (CMP0_CR0)
8
R/W
00h
29.7.1/468
4007_3001
CMP Control Register 1 (CMP0_CR1)
8
R/W
00h
29.7.2/469
4007_3002
CMP Filter Period Register (CMP0_FPR)
8
R/W
00h
29.7.3/471
4007_3003
CMP Status and Control Register (CMP0_SCR)
8
R/W
00h
29.7.4/471
4007_3004
DAC Control Register (CMP0_DACCR)
8
R/W
00h
29.7.5/472
4007_3005
MUX Control Register (CMP0_MUXCR)
8
R/W
00h
29.7.6/473
1
0
29.7.1 CMP Control Register 0 (CMPx_CR0)
Address: 4007_3000h base + 0h offset = 4007_3000h
Bit
7
Read
Write
Reset
0
0
6
5
4
FILTER_CNT
0
0
0
3
2
0
0
0
0
HYSTCTR
0
0
CMPx_CR0 field descriptions
Field
7
Reserved
6–4
FILTER_CNT
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Filter Sample Count
Represents the number of consecutive samples that must agree prior to the comparator ouput filter
accepting a new output state. For information regarding filter programming and latency, see the Functional
description.
000
001
010
011
100
Filter is disabled. If SE = 1, then COUT is a logic 0. This is not a legal state, and is not
recommended. If SE = 0, COUT = COUTA.
One sample must agree. The comparator output is simply sampled.
2 consecutive samples must agree.
3 consecutive samples must agree.
4 consecutive samples must agree.
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CMPx_CR0 field descriptions (continued)
Field
Description
101
110
111
5 consecutive samples must agree.
6 consecutive samples must agree.
7 consecutive samples must agree.
3
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
2
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
1–0
HYSTCTR
Comparator hard block hysteresis control
Defines the programmable hysteresis level. The hysteresis values associated with each level are devicespecific. See the Data Sheet of the device for the exact values.
00
01
10
11
Level 0
Level 1
Level 2
Level 3
29.7.2 CMP Control Register 1 (CMPx_CR1)
Address: 4007_3000h base + 1h offset = 4007_3001h
Bit
Read
Write
Reset
7
6
5
4
3
2
1
0
SE
WE
TRIGM
PMODE
INV
COS
OPE
EN
0
0
0
0
0
0
0
0
CMPx_CR1 field descriptions
Field
7
SE
Description
Sample Enable
At any given time, either SE or WE can be set. It is mandatory request to not set SE and WE both at a
given time.
0
1
6
WE
Windowing Enable
At any given time, either SE or WE can be set. It is mandatory request to not set SE and WE both at a
given time.
0
1
5
TRIGM
Sampling mode is not selected.
Sampling mode is selected.
Windowing mode is not selected.
Windowing mode is selected.
Trigger Mode Enable
CMP and DAC are configured to CMP Trigger mode when CMP_CR1[TRIGM] is set to 1. In addition, the
CMP should be enabled. If the DAC is to be used as a reference to the CMP, it should also be enabled.
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CMPx_CR1 field descriptions (continued)
Field
Description
CMP Trigger mode depends on an external timer resource to periodically enable the CMP and 6-bit DAC
in order to generate a triggered compare.
Upon setting TRIGM, the CMP and DAC are placed in a standby state until an external timer resource
trigger is received.
See the chip configuration chapter for details about the external timer resource.
0
1
4
PMODE
Power Mode Select
See the electrical specifications table in the device Data Sheet for details.
0
1
3
INV
Trigger mode is disabled.
Trigger mode is enabled.
Low-Speed (LS) Comparison mode selected. In this mode, CMP has slower output propagation delay
and lower current consumption.
High-Speed (HS) Comparison mode selected. In this mode, CMP has faster output propagation delay
and higher current consumption.
Comparator INVERT
Allows selection of the polarity of the analog comparator function. It is also driven to the COUT output, on
both the device pin and as SCR[COUT], when OPE=0.
0
1
Does not invert the comparator output.
Inverts the comparator output.
2
COS
Comparator Output Select
1
OPE
Comparator Output Pin Enable
0
1
0
1
Set the filtered comparator output (CMPO) to equal COUT.
Set the unfiltered comparator output (CMPO) to equal COUTA.
CMPO is not available on the associated CMPO output pin. If the comparator does not own the pin,
this field has no effect.
CMPO is available on the associated CMPO output pin.
The comparator output (CMPO) is driven out on the associated CMPO output pin if the comparator
owns the pin. If the comparator does not own the field, this bit has no effect.
0
EN
Comparator Module Enable
Enables the Analog Comparator module. When the module is not enabled, it remains in the off state, and
consumes no power. When the user selects the same input from analog mux to the positive and negative
port, the comparator is disabled automatically.
0
1
Analog Comparator is disabled.
Analog Comparator is enabled.
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29.7.3 CMP Filter Period Register (CMPx_FPR)
Address: 4007_3000h base + 2h offset = 4007_3002h
Bit
Read
Write
Reset
7
6
5
4
3
2
1
0
0
0
0
0
FILT_PER
0
0
0
0
CMPx_FPR field descriptions
Field
7–0
FILT_PER
Description
Filter Sample Period
Specifies the sampling period, in bus clock cycles, of the comparator output filter, when CR1[SE]=0.
Setting FILT_PER to 0x0 disables the filter. Filter programming and latency details appear in the
Functional description.
This field has no effect when CR1[SE]=1. In that case, the external SAMPLE signal is used to determine
the sampling period.
29.7.4 CMP Status and Control Register (CMPx_SCR)
Address: 4007_3000h base + 3h offset = 4007_3003h
Bit
7
Read
0
6
DMAEN
Write
Reset
0
0
5
0
0
4
3
IER
IEF
0
0
2
1
0
CFR
CFF
COUT
w1c
w1c
0
0
0
CMPx_SCR field descriptions
Field
7
Reserved
6
DMAEN
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
DMA Enable Control
Enables the DMA transfer triggered from the CMP module. When this field is set, a DMA request is
asserted when CFR or CFF is set.
0
1
5
Reserved
4
IER
DMA is disabled.
DMA is enabled.
This field is reserved.
This read-only field is reserved and always has the value 0.
Comparator Interrupt Enable Rising
Enables the CFR interrupt from the CMP. When this field is set, an interrupt will be asserted when CFR is
set.
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CMPx_SCR field descriptions (continued)
Field
Description
0
1
3
IEF
Comparator Interrupt Enable Falling
Enables the CFF interrupt from the CMP. When this field is set, an interrupt will be asserted when CFF is
set.
0
1
2
CFR
Detects a rising-edge on COUT, when set, during normal operation. CFR is cleared by writing 1 to it.
During Stop modes, CFR is level sensitive .
Rising-edge on COUT has not been detected.
Rising-edge on COUT has occurred.
Analog Comparator Flag Falling
Detects a falling-edge on COUT, when set, during normal operation. CFF is cleared by writing 1 to it.
During Stop modes, CFF is level senstive .
0
1
0
COUT
Interrupt is disabled.
Interrupt is enabled.
Analog Comparator Flag Rising
0
1
1
CFF
Interrupt is disabled.
Interrupt is enabled.
Falling-edge on COUT has not been detected.
Falling-edge on COUT has occurred.
Analog Comparator Output
Returns the current value of the Analog Comparator output, when read. The field is reset to 0 and will read
as CR1[INV] when the Analog Comparator module is disabled, that is, when CR1[EN] = 0. Writes to this
field are ignored.
29.7.5 DAC Control Register (CMPx_DACCR)
Address: 4007_3000h base + 4h offset = 4007_3004h
Bit
Read
Write
Reset
7
6
DACEN
VRSEL
0
0
5
4
3
2
1
0
0
0
0
VOSEL
0
0
0
CMPx_DACCR field descriptions
Field
7
DACEN
Description
DAC Enable
Enables the DAC. When the DAC is disabled, it is powered down to conserve power.
0
1
6
VRSEL
DAC is disabled.
DAC is enabled.
Supply Voltage Reference Source Select
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CMPx_DACCR field descriptions (continued)
Field
Description
0
1
5–0
VOSEL
V is selected as resistor ladder network supply reference V. in1in
V is selected as resistor ladder network supply reference V. in2in
DAC Output Voltage Select
Selects an output voltage from one of 64 distinct levels.
DACO = (V
in
/64) * (VOSEL[5:0] + 1) , so the DACO range is from V in /64 to V in .
29.7.6 MUX Control Register (CMPx_MUXCR)
Address: 4007_3000h base + 5h offset = 4007_3005h
Bit
Read
Write
Reset
7
6
Reserved
0
0
0
5
4
3
2
PSEL
0
0
1
0
MSEL
0
0
0
0
CMPx_MUXCR field descriptions
Field
Description
7
Reserved
Bit can be programmed to zero only .
6
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
5–3
PSEL
This field is reserved.
Plus Input Mux Control
Determines which input is selected for the plus input of the comparator. For INx inputs, see CMP, DAC,
and ANMUX block diagrams.
NOTE: When an inappropriate operation selects the same input for both muxes, the comparator
automatically shuts down to prevent itself from becoming a noise generator.
000
001
010
011
100
101
110
111
2–0
MSEL
IN0
IN1
IN2
IN3
IN4
IN5
IN6
IN7
Minus Input Mux Control
Determines which input is selected for the minus input of the comparator. For INx inputs, see CMP, DAC,
and ANMUX block diagrams.
NOTE: When an inappropriate operation selects the same input for both muxes, the comparator
automatically shuts down to prevent itself from becoming a noise generator.
000
IN0
Table continues on the next page...
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Functional description
CMPx_MUXCR field descriptions (continued)
Field
Description
001
010
011
100
101
110
111
IN1
IN2
IN3
IN4
IN5
IN6
IN7
29.8 Functional description
The CMP module can be used to compare two analog input voltages applied to INP and
INM. CMPO is high when the non-inverting input is greater than the inverting input, and
is low when the non-inverting input is less than the inverting input. This signal can be
selectively inverted by setting CR1[INV] = 1.
SCR[IER] and SCR[IEF] are used to select the condition which will cause the CMP
module to assert an interrupt to the processor. SCR[CFF] is set on a falling-edge and
SCR[CFR] is set on rising-edge of the comparator output. The optionally filtered CMPO
can be read directly through SCR[COUT].
29.8.1 CMP functional modes
There are three main sub-blocks to the CMP module:
• The comparator itself
• The window function
• The filter function
The filter, CR0[FILTER_CNT], can be clocked from an internal or external clock source.
The filter is programmable with respect to the number of samples that must agree before
a change in the output is registered. In the simplest case, only one sample must agree. In
this case, the filter acts as a simple sampler.
The external sample input is enabled using CR1[SE]. When set, the output of the
comparator is sampled only on rising edges of the sample input.
The "windowing mode" is enabled by setting CR1[WE]. When set, the comparator output
is sampled only when WINDOW=1. This feature can be used to ignore the comparator
output during time periods in which the input voltages are not valid. This is especially
useful when implementing zero-crossing-detection for certain PWM applications.
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Chapter 29 Comparator (CMP)
The comparator filter and sampling features can be combined as shown in the following
table. Individual modes are discussed below.
Table 29-15. Comparator sample/filter controls
Mode #
CR1[EN]
CR1[WE]
CR1[SE]
CR0[FILTER_C
NT]
FPR[FILT_PER]
Operation
1
0
X
X
X
X
Disabled
See the Disabled mode (# 1).
2A
1
0
0
0x00
X
Continuous Mode
2B
1
0
0
X
0x00
See the Continuous mode (#s 2A &
2B).
3A
1
0
1
0x01
X
Sampled, Non-Filtered mode
3B
1
0
0
0x01
> 0x00
See the Sampled, Non-Filtered
mode (#s 3A & 3B).
4A
1
0
1
> 0x01
X
Sampled, Filtered mode
4B
1
0
0
> 0x01
> 0x00
See the Sampled, Filtered mode (#s
4A & 4B).
5A
1
1
0
0x00
X
Windowed mode
5B
1
1
0
X
0x00
Comparator output is sampled on
every rising bus clock edge when
SAMPLE=1 to generate COUTA.
See the Windowed mode (#s 5A &
5B).
6
1
1
0
0x01
0x01–0xFF
Windowed/Resampled mode
Comparator output is sampled on
every rising bus clock edge when
SAMPLE=1 to generate COUTA,
which is then resampled on an
interval determined by FILT_PER to
generate COUT.
See the Windowed/Resampled
mode (# 6).
7
1
1
0
> 0x01
0x01–0xFF
Windowed/Filtered mode
Comparator output is sampled on
every rising bus clock edge when
SAMPLE=1 to generate COUTA,
which is then resampled and filtered
to generate COUT.
See the Windowed/Filtered mode
(#7).
All other combinations of CR1[EN], CR1[WE], CR1[SE], CR0[FILTER_CNT], and FPR[FILT_PER] are illegal.
For cases where a comparator is used to drive a fault input, for example, for a motorcontrol module such as FTM, it must be configured to operate in Continuous mode so
that an external fault can immediately pass through the comparator to the target fault
circuitry.
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Functional description
Note
Filtering and sampling settings must be changed only after
setting CR1[SE]=0 and CR0[FILTER_CNT]=0x00. This resets
the filter to a known state.
29.8.1.1 Disabled mode (# 1)
In Disabled mode, the analog comparator is non-functional and consumes no power.
CMPO is 0 in this mode.
29.8.1.2 Continuous mode (#s 2A & 2B)
Internal bus
EN,PMODE,HYSTCTR[1:0]
FILT_PER
INV
COS
WE
OPE
FILTER_CNT SE COUT
IER/F
CFR/F
0
INP
+
-
CMPO
Polarity
select
Window
control
INM
Filter
block
Interrupt
control
IRQ
COUT
To other system functions
WINDOW/SAMPLE
bus clock
FILT_PER
Clock
prescaler
1
0
0
divided
bus
clock
COUTA
CGMUX
SE
1
CMPO to
PAD
COS
Figure 29-15. Comparator operation in Continuous mode
NOTE
See the chip configuration section for the source of sample/
window input.
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Chapter 29 Comparator (CMP)
The analog comparator block is powered and active. CMPO may be optionally inverted,
but is not subject to external sampling or filtering. Both window control and filter blocks
are completely bypassed. SCR[COUT] is updated continuously. The path from
comparator input pins to output pin is operating in combinational unclocked mode.
COUT and COUTA are identical.
For control configurations which result in disabling the filter block, see the Filter Block
Bypass Logic diagram.
29.8.1.3 Sampled, Non-Filtered mode (#s 3A & 3B)
Internal bus
EN,PMODE,HYSTCTR[1:0]
FILT_PER
INV
COS
OPE
WE
FILTER_CNT SE COUT
0x01
0
IER/F
CFR/F
1
INP
+
-
CMPO
Polarity
select
Window
control
INM
Filter
block
Interrupt
control
IRQ
COUT
To other SOC functions
WINDOW/SAMPLE
Clock
prescaler
bus clock
FILT_PER
1
0
0
divided
bus
clock
COUTA
CGMUX
SE=1
1
CMPO to
PAD
COS
Figure 29-16. Sampled, Non-Filtered (# 3A): sampling point externally driven
In Sampled, Non-Filtered mode, the analog comparator block is powered and active. The
path from analog inputs to COUTA is combinational unclocked. Windowing control is
completely bypassed. COUTA is sampled whenever a rising-edge is detected on the filter
block clock input.
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Functional description
The only difference in operation between Sampled, Non-Filtered (# 3A) and Sampled,
Non-Filtered (# 3B) is in how the clock to the filter block is derived. In #3A, the clock to
filter block is externally derived while in #3B, the clock to filter block is internally
derived.
The comparator filter has no other function than sample/hold of the comparator output in
this mode (# 3B).
Internal bus
EN,PMODE,HYSTCTR[1:0]
FILT_PER
INV
COS
OPE
WE
FILTER_CNT SE COUT
0
IER/F
CFR/F
0
0x01
INP
+
-
CMPO
Polarity
select
Window
control
Filter
block
INM
Interrupt
control
IRQ
COUT
WINDOW/SAMPLE
bus clock
FILT_PER
Clock
prescaler
To other SOC functions
1
0
0
divided bus clock
COUTA
CGMUX
SE=0
1
CMPO to
PAD
COS
Figure 29-17. Sampled, Non-Filtered (# 3B): sampling interval internally derived
29.8.1.4 Sampled, Filtered mode (#s 4A & 4B)
In Sampled, Filtered mode, the analog comparator block is powered and active. The path
from analog inputs to COUTA is combinational unclocked. Windowing control is
completely bypassed. COUTA is sampled whenever a rising edge is detected on the filter
block clock input.
The only difference in operation between Sampled, Non-Filtered (# 3A) and Sampled,
Filtered (# 4A) is that, now, CR0[FILTER_CNT]>1, which activates filter operation.
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Chapter 29 Comparator (CMP)
Internal bus
EN, PMODE, HYSTCTR[1:0]
FILT_PER
INV
COS
OPE
WE
FILTER_CNT SE COUT
> 0x01
0
INP
+
-
CMPO
Polarity
select
Window
control
INM
IER/F
CFR/F
1
Interrupt
control
Filter
block
IRQ
COUT
To other SOC functions
WINDOW/SAMPLE
bus clock
Clock
prescaler
FILT_PER
1
0
0
divided
bus
clock
COUTA
CGMUX
SE=1
1
CMPO to
PAD
COS
Figure 29-18. Sampled, Filtered (# 4A): sampling point externally driven
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Functional description
Internal bus
OPE
FILT_PER
EN, PMODE,HYSTCTR[1:0] COS
INV
WE
FILTER_CNT SE COUT
IER/F
CFR/F
>0x01
0
0
INP
+
-
Polarity
CMPO select
Window
control
INM
Filter
block
Interrupt
control
IRQ
COUT
WINDOW/SAMPLE
bus clock
FILT_PER
Clock
prescaler
To other SOC functions
1
0
0
divided
bus
clock
COUTA
CGMUX
SE=0
1
CMPO to
PAD
COS
Figure 29-19. Sampled, Filtered (# 4B): sampling point internally derived
The only difference in operation between Sampled, Non-Filtered (# 3B) and Sampled,
Filtered (# 4B) is that now, CR0[FILTER_CNT]>1, which activates filter operation.
29.8.1.5 Windowed mode (#s 5A & 5B)
The following figure illustrates comparator operation in the Windowed mode, ignoring
latency of the analog comparator, polarity select, and window control block. It also
assumes that the polarity select is set to non-inverting state.
NOTE
The analog comparator output is passed to COUTA only when
the WINDOW signal is high.
In actual operation, COUTA may lag the analog inputs by up to one bus clock cycle plus
the combinational path delay through the comparator and polarity select logic.
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Chapter 29 Comparator (CMP)
WI NDOW
Plus input
Minus input
CMPO
COUTA
Figure 29-20. Windowed mode operation
Internal bus
EN, PMODE,HYSCTR[1:0]
FILT_PER
INV
COS
OPE
WE
FILTER_CNT SE COUT
0x01
IER/F
CFR/F
0
INP
+
-
CMPO
Polarity
select
Window
control
Interrupt
control
Filter
block
INM
IRQ
COUT
To other SOC functions
WINDOW/SAMPLE
bus clock
Clock
prescaler
FILT_PER
1
0
0
divided
bus
clock
COUTA
CGMUX
SE=0
1
CMPO to
PAD
COS
Figure 29-21. Windowed mode
For control configurations which result in disabling the filter block, see Filter Block
Bypass Logic diagram.
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Functional description
When any windowed mode is active, COUTA is clocked by the bus clock whenever
WINDOW = 1. The last latched value is held when WINDOW = 0.
29.8.1.6 Windowed/Resampled mode (# 6)
The following figure uses the same input stimulus shown in Figure 29-20, and adds
resampling of COUTA to generate COUT. Samples are taken at the time points indicated
by the arrows in the figure. Again, prop delays and latency are ignored for the sake of
clarity.
This example was generated solely to demonstrate operation of the comparator in
windowed/resampled mode, and does not reflect any specific application. Depending
upon the sampling rate and window placement, COUT may not see zero-crossing events
detected by the analog comparator. Sampling period and/or window placement must be
carefully considered for a given application.
WI NDOW
Plus input
Minus input
CMPO
COUTA
COUT
Figure 29-22. Windowed/resampled mode operation
This mode of operation results in an unfiltered string of comparator samples where the
interval between the samples is determined by FPR[FILT_PER] and the bus clock rate.
Configuration for this mode is virtually identical to that for the Windowed/Filtered Mode
shown in the next section. The only difference is that the value of CR0[FILTER_CNT]
must be 1.
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29.8.1.7 Windowed/Filtered mode (#7)
This is the most complex mode of operation for the comparator block, as it uses both
windowing and filtering features. It also has the highest latency of any of the modes. This
can be approximated: up to 1 bus clock synchronization in the window function +
((CR0[FILTER_CNT] * FPR[FILT_PER]) + 1) * bus clock for the filter function.
When any windowed mode is active, COUTA is clocked by the bus clock whenever
WINDOW = 1. The last latched value is held when WINDOW = 0.
Internal bus
EN, PMODE,HYSCTR[1:0]
FILT_PER
INV
COS
OPE
WE
FILTER_CNT SE COUT
> 0x01
1
INP
+
Polarity
CMPO select
-
Window
control
IER/F
CFR/F
0
Interrupt
control
Filter
block
INM
IRQ
COUT
To other SOC functions
WINDOW/SAMPLE
bus clock
Clock
prescaler
FILT_PER
1
0
0
divided
bus
clock
COUTA
CGMUX
SE=0
1
CMPO to
PAD
COS
Figure 29-23. Windowed/Filtered mode
29.8.2 Power modes
29.8.2.1 Wait mode operation
During Wait and VLPW modes, the CMP, if enabled, continues to operate normally and
a CMP interrupt can wake the MCU.
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Functional description
29.8.2.2 Stop mode operation
Depending on clock restrictions related to the MCU core or core peripherals, the MCU is
brought out of stop when a compare event occurs and the corresponding interrupt is
enabled. Similarly, if CR1[OPE] is enabled, the comparator output operates as in the
normal operating mode and comparator output is placed onto the external pin. In Stop
modes, the comparator can be operational in both:
• High-Speed (HS) Comparison mode when CR1[PMODE] = 1
• Low-Speed (LS) Comparison mode when CR1[PMODE] = 0
It is recommended to use the LS mode to minimize power consumption.
If stop is exited with a reset, all comparator registers are put into their reset state.
29.8.2.3 Background Debug Mode Operation
When the microcontroller is in active background debug mode, the CMP continues to
operate normally.
29.8.3 Startup and operation
A typical startup sequence is as follows.
The time required to stabilize COUT will be the power-on delay of the comparators plus
the largest propagation delay from a selected analog source through the analog
comparator, windowing function and filter. See the Data Sheets for power-on delays of
the comparators. The windowing function has a maximum of one bus clock period delay.
The filter delay is specified in the Low-pass filter.
During operation, the propagation delay of the selected data paths must always be
considered. It may take many bus clock cycles for COUT and SCR[CFR]/SCR[CFF] to
reflect an input change or a configuration change to one of the components involved in
the data path.
When programmed for filtering modes, COUT will initially be equal to 0, until sufficient
clock cycles have elapsed to fill all stages of the filter. This occurs even if COUTA is at a
logic 1.
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Chapter 29 Comparator (CMP)
29.8.4 Low-pass filter
The low-pass filter operates on the unfiltered and unsynchronized and optionally inverted
comparator output COUTA and generates the filtered and synchronized output COUT.
Both COUTA and COUT can be configured as module outputs and are used for different
purposes within the system.
Synchronization and edge detection are always used to determine status register bit
values. They also apply to COUT for all sampling and windowed modes. Filtering can be
performed using an internal timebase defined by FPR[FILT_PER], or using an external
SAMPLE input to determine sample time.
The need for digital filtering and the amount of filtering is dependent on user
requirements. Filtering can become more useful in the absence of an external hysteresis
circuit. Without external hysteresis, high-frequency oscillations can be generated at
COUTA when the selected INM and INP input voltages differ by less than the offset
voltage of the differential comparator.
29.8.4.1 Enabling filter modes
Filter modes can be enabled by:
• Setting CR0[FILTER_CNT] > 0x01 and
• Setting FPR[FILT_PER] to a nonzero value or setting CR1[SE]=1
If using the divided bus clock to drive the filter, it will take samples of COUTA every
FPR[FILT_PER] bus clock cycles.
The filter output will be at logic 0 when first initalized, and will subsequently change
when all the consecutive CR0[FILTER_CNT] samples agree that the output value has
changed. In other words, SCR[COUT] will be 0 for some initial period, even when
COUTA is at logic 1.
Setting both CR1[SE] and FPR[FILT_PER] to 0 disables the filter and eliminates
switching current associated with the filtering process.
Note
Always switch to this setting prior to making any changes in
filter parameters. This resets the filter to a known state.
Switching CR0[FILTER_CNT] on the fly without this
intermediate step can result in unexpected behavior.
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Functional description
If CR1[SE]=1, the filter takes samples of COUTA on each positive transition of the
sample input. The output state of the filter changes when all the consecutive
CR0[FILTER_CNT] samples agree that the output value has changed.
29.8.4.2 Latency issues
The value of FPR[FILT_PER] or SAMPLE period must be set such that the sampling
period is just longer than the period of the expected noise. This way a noise spike will
corrupt only one sample. The value of CR0[FILTER_CNT] must be chosen to reduce the
probability of noisy samples causing an incorrect transition to be recognized. The
probability of an incorrect transition is defined as the probability of an incorrect sample
raised to the power of CR0[FILTER_CNT].
The values of FPR[FILT_PER] or SAMPLE period and CR0[FILTER_CNT] must also
be traded off against the desire for minimal latency in recognizing actual comparator
output transitions. The probability of detecting an actual output change within the
nominal latency is the probability of a correct sample raised to the power of
CR0[FILTER_CNT].
The following table summarizes maximum latency values for the various modes of
operation in the absence of noise. Filtering latency is restarted each time an actual output
transition is masked by noise.
Table 29-16. Comparator sample/filter maximum latencies
Mode #
CR1[
EN]
CR1[
WE]
CR1[
SE]
CR0[FILTER
_CNT]
FPR[FILT_P
ER]
Operation
Maximum latency1
1
0
X
X
X
X
Disabled
N/A
2A
1
0
0
0x00
X
Continuous Mode
TPD
2B
1
0
0
X
0x00
3A
1
0
1
0x01
X
Sampled, Non-Filtered mode
TPD + TSAMPLE + Tper
3B
1
0
0
0x01
> 0x00
4A
1
0
1
> 0x01
X
4B
1
0
0
> 0x01
> 0x00
5A
1
1
0
0x00
X
5B
1
1
0
X
0x00
6
1
1
0
0x01
0x01 - 0xFF
Windowed / Resampled
mode
TPD + (FPR[FILT_PER] *
Tper) + 2Tper
7
1
1
0
> 0x01
0x01 - 0xFF
Windowed / Filtered mode
TPD + (CR0[FILTER_CNT] *
FPR[FILT_PER] x Tper) +
2Tper
TPD + (FPR[FILT_PER] *
Tper) + Tper
Sampled, Filtered mode
TPD + (CR0[FILTER_CNT] *
TSAMPLE) + Tper
TPD + (CR0[FILTER_CNT] *
FPR[FILT_PER] x Tper) + Tper
Windowed mode
TPD + Tper
TPD + Tper
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Chapter 29 Comparator (CMP)
1. TPD represents the intrinsic delay of the analog component plus the polarity select logic. TSAMPLE is the clock period of the
external sample clock. Tper is the period of the bus clock.
29.9 CMP interrupts
The CMP module is capable of generating an interrupt on either the rising- or fallingedge of the comparator output, or both. The following table gives the conditions in which
the interrupt request is asserted and deasserted.
When
Then
SCR[IER] and SCR[CFR] are set
The interrupt request is asserted
SCR[IEF] and SCR[CFF] are set
The interrupt request is asserted
SCR[IER] and SCR[CFR] are cleared for a rising-edge
interrupt
The interrupt request is deasserted
SCR[IEF] and SCR[CFF] are cleared for a falling-edge
interrupt
The interrupt request is deasserted
29.10 DMA support
Normally, the CMP generates a CPU interrupt if there is a change on the COUT. When
DMA support is enabled by setting SCR[DMAEN] and the interrupt is enabled by setting
SCR[IER], SCR[IEF], or both, the corresponding change on COUT forces a DMA
transfer request rather than a CPU interrupt instead. When the DMA has completed the
transfer, it sends a transfer completing indicator that deasserts the DMA transfer request
and clears the flag to allow a subsequent change on comparator output to occur and force
another DMA request.
The comparator can remain functional in STOP modes. When DMA support is enabled
by setting SCR[DMAEN] and the interrupt is enabled by setting SCR[IER], SCR[IEF], or
both, the corresponding change on COUT forces a DMA transfer request to wake up the
system from STOP modes. After the data transfer has finished, system will go back to
STOP modes. Refer to DMA chapters in the device reference manual for the
asynchronous DMA function for details.
29.11 CMP Asyncrhonous DMA support
The comparator can remain functional in STOP modes. When DMA support is enabled
by setting SCR[DMAEN] and the interrupt is enabled by setting SCR[IER], SCR[IEF], or
both, the corresponding change on COUT forces a DMA transfer request to wake up the
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Digital-to-analog converter
system from STOP modes. After the data transfer has finished, system will go back to
STOP modes. Refer to DMA chapters in the device reference manual for the
asynchronous DMA function for details.
29.12 Digital-to-analog converter
The following figure shows the block diagram of the DAC module. It contains a 64-tap
resistor ladder network and a 64-to-1 multiplexer, which selects an output voltage from
one of 64 distinct levels that outputs from DACO. It is controlled through the DAC
Control Register (DACCR). Its supply reference source can be selected from two sources
Vin1 and Vin2. The module can be powered down or disabled when not in use. When in
Disabled mode, DACO is connected to the analog ground.
Vin1
VRSEL
Vin2
MUX
DACEN
VOSEL[5:0]
Vin
MUX
DACO
Figure 29-24. 6-bit DAC block diagram
29.13 DAC functional description
This section provides DAC functional description.
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Chapter 29 Comparator (CMP)
29.13.1 Voltage reference source select
• Vin1 connects to the primary voltage source as supply reference of 64 tap resistor
ladder
• Vin2 connects to an alternate voltage source
29.14 DAC resets
This module has a single reset input, corresponding to the chip-wide peripheral reset.
29.15 DAC clocks
This module has a single clock input, the bus clock.
29.16 DAC interrupts
This module has no interrupts.
29.17 CMP Trigger Mode
CMP and DAC are configured to CMP Trigger mode when CMP_CR1[TRIGM] is set to
1. In addition, the CMP must be enabled. If the DAC is to be used as a reference to the
CMP, it must also be enabled.
CMP Trigger mode depends on an external timer resource to periodically enable the
CMP and 6-bit DAC in order to generate a triggered compare.
Upon setting TRIGM, the CMP and DAC are placed in a standby state until an external
timer resource trigger is received.
See the chip configuration chapter for details about the external timer resource.
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Chapter 30
Timer/PWM Module (TPM)
30.1 Introduction
The TPM (Timer/PWM Module) is a two to eight channel timer which supports input
capture, output compare, and the generation of PWM signals to control electric motor and
power management applications. The counter, compare and capture registers are clocked
by an asynchronous clock that can remain enabled in low power modes.
30.1.1 TPM Philosophy
The TPM is built upon a very simple timer (HCS08 Timer PWM Module – TPM) used
for many years on Freescale's 8-bit microcontrollers. The TPM extends the functionality
to support operation in low power modes by clocking the counter, compare and capture
registers from an asynchronous clock that can remain functional in low power modes.
30.1.2 Features
The TPM features include:
• TPM clock mode is selectable
• Can increment on every edge of the asynchronous counter clock
• Can increment on rising edge of an external clock input synchronized to the
asynchronous counter clock
• Prescaler divide-by 1, 2, 4, 8, 16, 32, 64, or 128
• TPM includes a 16-bit counter
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Introduction
• It can be a free-running counter or modulo counter
• The counting can be up or up-down
• Includes 6 channels that can be configured for input capture, output compare, or
edge-aligned PWM mode
• In input capture mode the capture can occur on rising edges, falling edges or
both edges
• In output compare mode the output signal can be set, cleared, pulsed, or toggled
on match
• All channels can be configured for center-aligned PWM mode
• Support the generation of an interrupt and/or DMA request per channel
• Support the generation of an interrupt and/or DMA request when the counter
overflows
• Support selectable trigger input to optionally reset or cause the counter to start
incrementing.
• The counter can also optionally stop incrementing on counter overflow
• Support the generation of hardware triggers when the counter overflows and per
channel
30.1.3 Modes of Operation
During debug mode, the TPM can can be configured to temporarily pause all counting
until the core returns to normal user operating mode or to operate normally. When the
counter is paused, trigger inputs and input capture events are ignored.
During doze mode, the TPM can be configured to operate normally or to pause all
counting for the duration of doze mode. When the counter is paused, trigger inputs and
input capture events are ignored.
During stop mode, the TPM counter clock can remain functional and the TPM can
generate an asynchronous interrupt to exit the MCU from stop mode.
30.1.4 Block Diagram
The TPM uses one input/output (I/O) pin per channel, CHn (TPM channel (n)) where n is
the channel number.
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Chapter 30 Timer/PWM Module (TPM)
The following figure shows the TPM structure. The central component of the TPM is the
16-bit counter with programmable final value and its counting can be up or up-down.
CMOD
no clock selected
(counter disable)
module clock
PS
external clock
prescaler
synchronizer
3
(1, 2, 4, 8, 16, 32, 64 or 128)
CPWMS
Module counter
TOIE
MOD
CH0IE
CH0F
input capture
mode logic
channel 0
interrupt
output modes logic
(generation of channel 0 outputs signals in
output compare, EPWM and CPWM modes)
C0V
channel 0
output signal
Channel N
MSNB:MSNA
ELSNB:ELSNA
CHNIE
CHNF
channel N
input
timer overflow
interrupt
Channel 0
MS0B:MS0A
ELS0B:ELS0A
channel 0
input
TOF
input capture
mode logic
CNV
channel N
interrupt
output modes logic
(generation of channel N outputs signals in
output compare, EPWM and CPWM modes)
channel N
output signal
Figure 30-1. TPM block diagram
30.2 TPM Signal Descriptions
Table 30-1 shows the user-accessible signals for the TPM.
Table 30-1. TPM signal descriptions
Signal
TPM_EXTCLK
TPM_CHn
Description
External clock. TPM external clock can be selected to increment the TPM
counter on every rising edge synchronized to the counter clock.
TPM channel (n = 5 to 0)
I/O
I
I/O
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Memory Map and Register Definition
30.2.1 TPM_EXTCLK — TPM External Clock
The rising edge of the external input signal is used to increment the TPM counter if
selected by CMOD[1:0] bits in the SC register. This input signal must be less than half of
the TPM counter clock frequency. The TPM counter prescaler selection and settings are
also used when an external input is selected.
30.2.2 TPM_CHn — TPM Channel (n) I/O Pin
Each TPM channel can be configured to operate either as input or output. The direction
associated with each channel, input or output, is selected according to the mode assigned
for that channel.
30.3 Memory Map and Register Definition
This section provides a detailed description of all TPM registers.
Attempting to access a reserved register location in the TPM memory map will generate a
bus error.
TPM memory map
Absolute
address
(hex)
Register name
Width
Access
(in bits)
Reset value
Section/
page
4003_8000
Status and Control (TPM0_SC)
32
R/W
0000_0000h
30.3.1/496
4003_8004
Counter (TPM0_CNT)
32
R/W
0000_0000h
30.3.2/497
4003_8008
Modulo (TPM0_MOD)
32
R/W
0000_FFFFh
30.3.3/498
4003_800C
Channel (n) Status and Control (TPM0_C0SC)
32
R/W
0000_0000h
30.3.4/499
4003_8010
Channel (n) Value (TPM0_C0V)
32
R/W
0000_0000h
30.3.5/501
4003_8014
Channel (n) Status and Control (TPM0_C1SC)
32
R/W
0000_0000h
30.3.4/499
4003_8018
Channel (n) Value (TPM0_C1V)
32
R/W
0000_0000h
30.3.5/501
4003_801C
Channel (n) Status and Control (TPM0_C2SC)
32
R/W
0000_0000h
30.3.4/499
4003_8020
Channel (n) Value (TPM0_C2V)
32
R/W
0000_0000h
30.3.5/501
4003_8024
Channel (n) Status and Control (TPM0_C3SC)
32
R/W
0000_0000h
30.3.4/499
4003_8028
Channel (n) Value (TPM0_C3V)
32
R/W
0000_0000h
30.3.5/501
4003_802C
Channel (n) Status and Control (TPM0_C4SC)
32
R/W
0000_0000h
30.3.4/499
4003_8030
Channel (n) Value (TPM0_C4V)
32
R/W
0000_0000h
30.3.5/501
4003_8034
Channel (n) Status and Control (TPM0_C5SC)
32
R/W
0000_0000h
30.3.4/499
4003_8038
Channel (n) Value (TPM0_C5V)
32
R/W
0000_0000h
30.3.5/501
4003_8050
Capture and Compare Status (TPM0_STATUS)
32
R/W
0000_0000h
30.3.6/501
4003_8084
Configuration (TPM0_CONF)
32
R/W
0000_0000h
30.3.7/503
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Chapter 30 Timer/PWM Module (TPM)
TPM memory map (continued)
Absolute
address
(hex)
Register name
Width
Access
(in bits)
Reset value
Section/
page
4003_9000
Status and Control (TPM1_SC)
32
R/W
0000_0000h
30.3.1/496
4003_9004
Counter (TPM1_CNT)
32
R/W
0000_0000h
30.3.2/497
4003_9008
Modulo (TPM1_MOD)
32
R/W
0000_FFFFh
30.3.3/498
4003_900C
Channel (n) Status and Control (TPM1_C0SC)
32
R/W
0000_0000h
30.3.4/499
4003_9010
Channel (n) Value (TPM1_C0V)
32
R/W
0000_0000h
30.3.5/501
4003_9014
Channel (n) Status and Control (TPM1_C1SC)
32
R/W
0000_0000h
30.3.4/499
4003_9018
Channel (n) Value (TPM1_C1V)
32
R/W
0000_0000h
30.3.5/501
4003_901C
Channel (n) Status and Control (TPM1_C2SC)
32
R/W
0000_0000h
30.3.4/499
4003_9020
Channel (n) Value (TPM1_C2V)
32
R/W
0000_0000h
30.3.5/501
4003_9024
Channel (n) Status and Control (TPM1_C3SC)
32
R/W
0000_0000h
30.3.4/499
4003_9028
Channel (n) Value (TPM1_C3V)
32
R/W
0000_0000h
30.3.5/501
4003_902C
Channel (n) Status and Control (TPM1_C4SC)
32
R/W
0000_0000h
30.3.4/499
4003_9030
Channel (n) Value (TPM1_C4V)
32
R/W
0000_0000h
30.3.5/501
4003_9034
Channel (n) Status and Control (TPM1_C5SC)
32
R/W
0000_0000h
30.3.4/499
4003_9038
Channel (n) Value (TPM1_C5V)
32
R/W
0000_0000h
30.3.5/501
4003_9050
Capture and Compare Status (TPM1_STATUS)
32
R/W
0000_0000h
30.3.6/501
4003_9084
Configuration (TPM1_CONF)
32
R/W
0000_0000h
30.3.7/503
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Memory Map and Register Definition
30.3.1 Status and Control (TPMx_SC)
SC contains the overflow status flag and control bits used to configure the interrupt
enable, module configuration and prescaler factor. These controls relate to all channels
within this module.
Address: Base address + 0h offset
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
R
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
TOIE
0
0
TOF
Reset
CPWMS
W
0
R
DMA
PS
w1c
W
Reset
CMOD
0
0
0
0
0
0
0
0
0
0
0
0
0
0
TPMx_SC field descriptions
Field
31–9
Reserved
8
DMA
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
DMA Enable
Enables DMA transfers for the overflow flag.
0
1
7
TOF
Disables DMA transfers.
Enables DMA transfers.
Timer Overflow Flag
Set by hardware when the LPTPM counter equals the value in the MOD register and increments. The TOF
bit is cleared by writing a 1 to TOF bit. Writing a 0 to TOF has no effect.
If another LPTPM overflow occurs between the flag setting and the flag clearing, the write operation has
no effect; therefore, TOF remains set indicating another overflow has occurred. In this case a TOF
interrupt request is not lost due to a delay in clearing the previous TOF.
Table continues on the next page...
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Chapter 30 Timer/PWM Module (TPM)
TPMx_SC field descriptions (continued)
Field
Description
0
1
6
TOIE
Timer Overflow Interrupt Enable
Enables LPTPM overflow interrupts.
0
1
5
CPWMS
LPTPM counter has not overflowed.
LPTPM counter has overflowed.
Disable TOF interrupts. Use software polling or DMA request.
Enable TOF interrupts. An interrupt is generated when TOF equals one.
Center-aligned PWM Select
Selects CPWM mode. This mode configures the LPTPM to operate in up-down counting mode.
This field is write protected. It can be written only when the counter is disabled.
0
1
4–3
CMOD
Clock Mode Selection
Selects the LPTPM counter clock modes. When disabling the counter, this field remain set until
acknolwedged in the LPTPM clock domain.
00
01
10
11
2–0
PS
LPTPM counter operates in up counting mode.
LPTPM counter operates in up-down counting mode.
LPTPM counter is disabled
LPTPM counter increments on every LPTPM counter clock
LPTPM counter increments on rising edge of LPTPM_EXTCLK synchronized to the LPTPM counter
clock
Reserved
Prescale Factor Selection
Selects one of 8 division factors for the clock mode selected by CMOD.
This field is write protected. It can be written only when the counter is disabled.
000
001
010
011
100
101
110
111
Divide by 1
Divide by 2
Divide by 4
Divide by 8
Divide by 16
Divide by 32
Divide by 64
Divide by 128
30.3.2 Counter (TPMx_CNT)
The CNT register contains the LPTPM counter value.
Reset clears the CNT register. Writing any value to COUNT also clears the counter.
When debug is active, the LPTPM counter does not increment unless configured
otherwise.
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Memory Map and Register Definition
Reading the CNT register adds two wait states to the register access due to
synchronization delays.
Address: Base address + 4h offset
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
0
R
0
0
0
0
0
0
0
0
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
COUNT
W
Reset
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
TPMx_CNT field descriptions
Field
Description
31–16
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
15–0
COUNT
Counter value
30.3.3 Modulo (TPMx_MOD)
The Modulo register contains the modulo value for the LPTPM counter. When the
LPTPM counter reaches the modulo value and increments, the overflow flag (TOF) is set
and the next value of LPTPM counter depends on the selected counting method (see
Counter ).
Writing to the MOD register latches the value into a buffer. The MOD register is updated
with the value of its write buffer according to MOD Register Update .
It is recommended to initialize the LPTPM counter (write to CNT) before writing to the
MOD register to avoid confusion about when the first counter overflow will occur.
Address: Base address + 8h offset
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
0
R
0
0
0
0
0
0
0
0
7
6
5
4
3
2
1
0
1
1
1
1
1
1
1
MOD
W
Reset
8
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
1
TPMx_MOD field descriptions
Field
31–16
Reserved
15–0
MOD
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Modulo value
When writing this field, all bytes must be written at the same time.
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Chapter 30 Timer/PWM Module (TPM)
30.3.4 Channel (n) Status and Control (TPMx_CnSC)
CnSC contains the channel-interrupt-status flag and control bits used to configure the
interrupt enable, channel configuration, and pin function. When switching from one
channel mode to a different channel mode, the channel must first be disabled and this
must be acknowledged in the LPTPM counter clock domain.
Table 30-34. Mode, Edge, and Level Selection
CPWMS
MSnB:MSnA
ELSnB:ELSnA
Mode
Configuration
X
00
00
None
Channel disabled
X
01/10/11
00
Software compare
Pin not used for LPTPM
0
00
01
Input capture
Capture on Rising Edge
Only
01
10
Capture on Falling
Edge Only
11
Capture on Rising or
Falling Edge
01
10
Output compare
Toggle Output on
match
10
Clear Output on match
11
Set Output on match
10
Edge-aligned PWM
High-true pulses (clear
Output on match, set
Output on reload)
X1
11
Low-true pulses (set
Output on match, clear
Output on reload)
10
Output compare
Pulse Output low on
match
X1
1
10
Pulse Output high on
match
10
Center-aligned PWM
High-true pulses (clear
Output on match-up,
set Output on matchdown)
X1
Low-true pulses (set
Output on match-up,
clear Output on matchdown)
Address: Base address + Ch offset + (8d × i), where i=0d to 5d
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
0
0
0
0
0
0
0
0
R
W
Reset
0
0
0
0
0
0
0
0
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Bit
15
14
13
12
11
10
9
8
0
R
CHF
w1c
W
Reset
7
0
0
0
0
0
0
0
0
0
6
5
CHIE
MSB
0
0
4
3
2
MSA ELSB ELSA
0
0
0
1
0
0
0
DMA
0
TPMx_CnSC field descriptions
Field
31–8
Reserved
7
CHF
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Channel Flag
Set by hardware when an event occurs on the channel. CHF is cleared by writing a 1 to the CHF bit.
Writing a 0 to CHF has no effect.
If another event occurs between the CHF sets and the write operation, the write operation has no effect;
therefore, CHF remains set indicating another event has occurred. In this case a CHF interrupt request is
not lost due to the delay in clearing the previous CHF.
0
1
6
CHIE
No channel event has occurred.
A channel event has occurred.
Channel Interrupt Enable
Enables channel interrupts.
0
1
Disable channel interrupts.
Enable channel interrupts.
5
MSB
Channel Mode Select
4
MSA
Channel Mode Select
3
ELSB
Edge or Level Select
2
ELSA
Edge or Level Select
1
Reserved
0
DMA
Used for further selections in the channel logic. Its functionality is dependent on the channel mode. When
a channel is disabled, this bit will not change state until acknowledged in the LPTPM counter clock
domain.
Used for further selections in the channel logic. Its functionality is dependent on the channel mode. When
a channel is disabled, this bit will not change state until acknowledged in the LPTPM counter clock
domain.
The functionality of ELSB and ELSA depends on the channel mode. When a channel is disabled, this bit
will not change state until acknowledged in the LPTPM counter clock domain.
The functionality of ELSB and ELSA depends on the channel mode. When a channel is disabled, this bit
will not change state until acknowledged in the LPTPM counter clock domain.
This field is reserved.
This read-only field is reserved and always has the value 0.
DMA Enable
Enables DMA transfers for the channel.
0
1
Disable DMA transfers.
Enable DMA transfers.
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Chapter 30 Timer/PWM Module (TPM)
30.3.5 Channel (n) Value (TPMx_CnV)
These registers contain the captured LPTPM counter value for the input modes or the
match value for the output modes.
In input capture mode, any write to a CnV register is ignored.
In compare modes, writing to a CnV register latches the value into a buffer. A CnV
register is updated with the value of its write buffer according to CnV Register Update .
Address: Base address + 10h offset + (8d × i), where i=0d to 5d
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
0
R
0
0
0
0
0
0
0
0
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
VAL
W
Reset
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
TPMx_CnV field descriptions
Field
31–16
Reserved
15–0
VAL
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Channel Value
Captured LPTPM counter value of the input modes or the match value for the output modes. When writing
this field, all bytes must be written at the same time.
30.3.6 Capture and Compare Status (TPMx_STATUS)
The STATUS register contains a copy of the status flag CHnF bit (in CnSC) for each
LPTPM channel, as well as the TOF bit (in SC), for software convenience.
Each CHnF bit in STATUS is a mirror of CHnF bit in CnSC. All CHnF bits can be
checked using only one read of STATUS. All CHnF bits can be cleared by writing all
ones to STATUS.
Hardware sets the individual channel flags when an event occurs on the channel. CHF is
cleared by writing a 1 to the CHF bit. Writing a 0 to CHF has no effect.
If another event occurs between the flag setting and the write operation, the write
operation has no effect; therefore, CHF remains set indicating another event has occurred.
In this case a CHF interrupt request is not lost due to the clearing sequence for a previous
CHF.
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Memory Map and Register Definition
Address: Base address + 50h offset
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
R
W
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
R
w1c
W
Reset
0
0
0
0
0
0
0
0
0
0
0
CH0F
0
CH1F
0
CH2F
0
CH3F
0
CH4F
0
CH5F
0
TOF
Reset
w1c
w1c
w1c
w1c
w1c
w1c
0
0
0
0
0
0
TPMx_STATUS field descriptions
Field
31–9
Reserved
8
TOF
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Timer Overflow Flag
See register description
0
1
7–6
Reserved
5
CH5F
This field is reserved.
This read-only field is reserved and always has the value 0.
Channel 5 Flag
See the register description.
0
1
4
CH4F
No channel event has occurred.
A channel event has occurred.
Channel 4 Flag
See the register description.
0
1
3
CH3F
LPTPM counter has not overflowed.
LPTPM counter has overflowed.
No channel event has occurred.
A channel event has occurred.
Channel 3 Flag
See the register description.
0
1
No channel event has occurred.
A channel event has occurred.
Table continues on the next page...
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Chapter 30 Timer/PWM Module (TPM)
TPMx_STATUS field descriptions (continued)
Field
Description
2
CH2F
Channel 2 Flag
See the register description.
0
1
1
CH1F
No channel event has occurred.
A channel event has occurred.
Channel 1 Flag
See the register description.
0
1
0
CH0F
No channel event has occurred.
A channel event has occurred.
Channel 0 Flag
See the register description.
0
1
No channel event has occurred.
A channel event has occurred.
30.3.7 Configuration (TPMx_CONF)
This register selects the behavior in debug and wait modes and the use of an external
global time base.
Address: Base address + 84h offset
Bit
31
30
29
28
27
26
25
24
23
22
0
20
19
CSOT
16
CSOO
17
CROT
0
18
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
GTBEEN
R
21
0
0
0
0
0
TRGSEL
W
W
Reset
0
0
0
0
0
0
DBGMODE
0
0
0
DOZEEN
0
R
0
0
0
0
TPMx_CONF field descriptions
Field
31–28
Reserved
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Table continues on the next page...
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Memory Map and Register Definition
TPMx_CONF field descriptions (continued)
Field
Description
27–24
TRGSEL
Trigger Select
23–19
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
18
CROT
Selects the input trigger to use for starting the counter and/or reloading the counter. This field should only
be changed when the LPTPM counter is disabled. See Chip configuration section for available options.
Counter Reload On Trigger
When set, the LPTPM counter will reload with zero (and initialize PWM outputs to their default value) when
a rising edge is detected on the selected trigger input.
The trigger input is ignored if the LPTPM counter is paused during debug mode or doze mode. This field
should only be changed when the LPTPM counter is disabled.
0
1
17
CSOO
Counter is not reloaded due to a rising edge on the selected input trigger
Counter is reloaded when a rising edge is detected on the selected input trigger
Counter Stop On Overflow
When set, the LPTPM counter will stop incrementing once the counter equals the MOD value and
incremented (this also sets the TOF). Reloading the counter with zero due to writing to the counter register
or due to a trigger input does not cause the counter to stop incrementing. Once the counter has stopped
incrementing, the counter will not start incrementing unless it is disabled and then enabled again, or a
rising edge on the selected trigger input is detected when CSOT set.
This field should only be changed when the LPTPM counter is disabled.
0
1
16
CSOT
LPTPM counter continues incrementing or decrementing after overflow
LPTPM counter stops incrementing or decrementing after overflow.
Counter Start on Trigger
When set, the LPTPM counter will not start incrementing after it is enabled until a rising edge on the
selected trigger input is detected. If the LPTPM counter is stopped due to an overflow, a rising edge on the
selected trigger input will also cause the LPTPM counter to start incrementing again.
The trigger input is ignored if the LPTPM counter is paused during debug mode or doze mode. This field
should only be changed when the LPTPM counter is disabled.
0
1
LPTPM counter starts to increment immediately, once it is enabled.
LPTPM counter only starts to increment when it a rising edge on the selected input trigger is detected,
after it has been enabled or after it has stopped due to overflow.
15–10
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
9
GTBEEN
Global time base enable
Configures the LPTPM to use an externally generated global time base counter. When an externally
generated timebase is used, the internal LPTPM counter is not used by the channels but can be used to
generate a periodic interrupt or DMA request using the Modulo register and timer overflow flag.
0
1
8
Reserved
7–6
DBGMODE
All channels use the internally generated LPTPM counter as their timebase
All channels use an externally generated global timebase as their timebase
This field is reserved.
This read-only field is reserved and always has the value 0.
Debug Mode
Table continues on the next page...
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Chapter 30 Timer/PWM Module (TPM)
TPMx_CONF field descriptions (continued)
Field
Description
Configures the LPTPM behavior in debug mode. All other configurations are reserved.
00
11
5
DOZEEN
Doze Enable
Configures the LPTPM behavior in wait mode.
0
1
4–0
Reserved
LPTPM counter is paused and does not increment during debug mode. Trigger inputs and input
capture events are also ignored.
LPTPM counter continues in debug mode.
Internal LPTPM counter continues in Doze mode.
Internal LPTPM counter is paused and does not increment during Doze mode. Trigger inputs and
input capture events are also ignored.
This field is reserved.
This read-only field is reserved and always has the value 0.
30.4 Functional Description
The following sections describe the TPM features.
30.4.1 Clock Domains
The TPM module supports two clock domains.
The bus clock domain is used by the register interface and for synchronizing interrupts
and DMA requests.
The TPM counter clock domain is used to clock the counter and prescaler along with the
output compare and input capture logic. The TPM counter clock is considered
asynchronous to the bus clock, can be a higher or lower frequency than the bus clock and
can remain operational in Stop mode. Multiple TPM instances are all clocked by the
same TPM counter clock in support of the external timebase feature.
30.4.1.1 Counter Clock Mode
The CMOD[1:0] bits in the SC register either disable the TPM counter or select one of
two possible clock modes for the TPM counter. After any reset, CMOD[1:0] = 0:0 so the
TPM counter is disabled.
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Functional Description
The CMOD[1:0] bits may be read or written at any time. Disabling the TPM counter by
writing zero to the CMOD[1:0] bits does not affect the TPM counter value or other
registers, but must be acknowledged by the TPM counter clock domain before they read
as zero.
The external clock input passes through a synchronizer clocked by the TPM counter
clock to assure that counter transitions are properly aligned to counter clock transitions.
Therefore, to meet Nyquist criteria considering also jitter, the frequency of the external
clock source must be less than half of the counter clock frequency.
30.4.2 Prescaler
The selected counter clock source passes through a prescaler that is a 7-bit counter. The
value of the prescaler is selected by the PS[2:0] bits. The following figure shows an
example of the prescaler counter and TPM counter.
timer module counting is up.
PS[2:0] = 001
CNTIN = 0x0000
selected input clock
prescaler counter
1
timer module counter
0
0
1
1
0
1
2
0
1
0
3
1
0
0
1
1
0
1
2
0
1
3
0
1
0
0
1
Figure 30-59. Example of the Prescaler Counter
30.4.3 Counter
The TPM has a 16-bit counter that is used by the channels either for input or output
modes. The counter updates from the selected clock divided by the prescaler.
The TPM counter has these modes of operation:
• up counting (see Up Counting)
• up-down counting (see Up-Down Counting)
30.4.3.1 Up Counting
Up counting is selected when (CPWMS = 0)
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The value of zero is loaded into the TPM counter, and the counter increments until the
value of MOD is reached, at which point the counter is reloaded with zero.
The TPM period when using up counting is (MOD + 0x0001) × period of the TPM
counter clock.
The TOF bit is set when the TPM counter changes from MOD to zero.
MOD = 0x0004
timer module counter
3
4
0
1
2
3
4
0
1
2
3
0
4
1
2
TOF bit
set TOF bit
set TOF bit
set TOF bit
period of timer module counter clock
period of counting = (MOD + 0x0001) x period of timer module counter clock
Figure 30-60. Example of TPM Up Counting
Note
• MOD = 0000 is a redundant condition. In this case, the
TPM counter is always equal to MOD and the TOF bit is
set in each rising edge of the TPM counter clock.
30.4.3.2 Up-Down Counting
Up-down counting is selected when (CPWMS = 1). When configured for up-down
counting, configuring MOD to less than 2 is not supported.
The value of zero is loaded into the TPM counter, and the counter increments until the
value of MOD is reached, at which point the counter is decremented until it returns to
zero and the up-down counting restarts.
The TPM period when using up-down counting is 2 × MOD × period of the TPM counter
clock.
The TOF bit is set when the TPM counter changes from MOD to (MOD – 1).
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Functional Description
MOD = 0x0004
Timer module counter
0
1
2
3
4
3
2
1
0
1
2
3
4
3
2
1
0
1
2
3
4
TOF bit
set TOF bit
set TOF bit
period of timer module counter clock
period of counting = 2 x MOD x period of timer module counter clock
Figure 30-61. Example of Up-Down Counting
30.4.3.3 Counter Reset
Any write to CNT resets the TPM counter and the channel outputs to their initial values
(except for channels in output compare mode).
30.4.4 Input Capture Mode
The input capture mode is selected when (CPWMS = 0), (MSnB:MSnA = 0:0), and
(ELSnB:ELSnA ≠ 0:0).
When a selected edge occurs on the channel input, the current value of the TPM counter
is captured into the CnV register, at the same time the CHnF bit is set and the channel
interrupt is generated if enabled by CHnIE = 1 (see the following figure).
When a channel is configured for input capture, the TPM_CHn pin is an edge-sensitive
input. ELSnB:ELSnA control bits determine which edge, falling or rising, triggers inputcapture event. Note that the maximum frequency for the channel input signal to be
detected correctly is counter clock divided by 4, which is required to meet Nyquist
criteria for signal sampling.
Writes to the CnV register are ignored in input capture mode.
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Chapter 30 Timer/PWM Module (TPM)
was rising
edge selected?
0
synchronizer
channel (n) input
timer module clock
D
Q
CLK
D
rising edge
Q
CLK
0
CHnIE
channel (n) interrupt
CHnF
1
edge
detector
CnV
falling edge
0
1
0
was falling
edge selected?
timer module counter
Figure 30-62. Input capture mode
The CHnF bit is set on the third rising edge of the counter clock after a valid edge occurs
on the channel input.
30.4.5 Output Compare Mode
The output compare mode is selected when (CPWMS = 0), and (MSnB:MSnA = 0:1).
In output compare mode, the TPM can generate timed pulses with programmable
position, polarity, duration, and frequency. When the counter matches the value in the
CnV register of an output compare channel, the channel (n) output can be set, cleared, or
toggled.
When a channel is initially configured to output compare mode, the channel output
updates with its negated value (logic 0 for set/toggle/pulse high and logic one for clear/
pulse low).
The CHnF bit is set and the channel (n) interrupt is generated (if CHnIE = 1) at the
channel (n) match (TPM counter = CnV).
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Functional Description
MOD = 0x0005
CnV = 0x0003
channel (n)
match
counter
overflow
CNT
...
2
1
0
channel (n) output
previous value
CHnF bit
previous value
4
3
channel (n)
match
counter
overflow
5
1
0
2
counter
overflow
4
3
5
1
0
...
TOF bit
Figure 30-63. Example of the output compare mode when the match toggles the channel
output
MOD = 0x0005
CnV = 0x0003
CNT
channel (n) output
CHnF bit
...
0
counter
overflow
channel (n)
match
counter
overflow
2
1
3
4
5
0
counter
overflow
channel (n)
match
1
2
3
4
5
0
1
...
previous value
previous value
TOF bit
Figure 30-64. Example of the output compare mode when the match clears the channel
output
MOD = 0x0005
CnV = 0x0003
channel (n)
match
counter
overflow
CNT
channel (n) output
CHnF bit
...
0
1
2
3
counter
overflow
4
5
0
channel (n)
match
1
2
3
counter
overflow
4
5
0
1
...
previous value
previous value
TOF bit
Figure 30-65. Example of the output compare mode when the match sets the channel
output
It is possible to use the output compare mode with (ELSnB:ELSnA = 0:0). In this case,
when the counter reaches the value in the CnV register, the CHnF bit is set and the
channel (n) interrupt is generated (if CHnIE = 1), however the channel (n) output is not
modified and controlled by TPM.
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Chapter 30 Timer/PWM Module (TPM)
30.4.6 Edge-Aligned PWM (EPWM) Mode
The edge-aligned mode is selected when (CPWMS = 0), and (MSnB:MSnA = 1:0). The
EPWM period is determined by (MOD + 0x0001) and the pulse width (duty cycle) is
determined by CnV.
The CHnF bit is set and the channel (n) interrupt is generated (if CHnIE = 1) at the
channel (n) match (TPM counter = CnV), that is, at the end of the pulse width.
This type of PWM signal is called edge-aligned because the leading edges of all PWM
signals are aligned with the beginning of the period, which is the same for all channels
within an TPM.
counter overflow
counter overflow
counter overflow
period
pulse
width
channel (n) output
channel (n) match
channel (n) match
channel (n) match
Figure 30-66. EPWM period and pulse width with ELSnB:ELSnA = 1:0
If (ELSnB:ELSnA = 0:0) when the counter reaches the value in the CnV register, the
CHnF bit is set and the channel (n) interrupt is generated (if CHnIE = 1), however the
channel (n) output is not controlled by TPM.
If (ELSnB:ELSnA = 1:0), then the channel (n) output is forced high at the counter
overflow (when the zero is loaded into the TPM counter), and it is forced low at the
channel (n) match (TPM counter = CnV) (see the following figure).
MOD = 0x0008
CnV = 0x0005
counter
overflow
CNT
...
0
channel (n)
match
1
2
3
4
5
counter
overflow
6
7
8
0
1
2
...
channel (n) output
CHnF bit
previous value
TOF bit
Figure 30-67. EPWM signal with ELSnB:ELSnA = 1:0
If (ELSnB:ELSnA = X:1), then the channel (n) output is forced low at the counter
overflow (when zero is loaded into the TPM counter), and it is forced high at the channel
(n) match (TPM counter = CnV) (see the following figure).
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Functional Description
MOD = 0x0008
CnV = 0x0005
counter
overflow
CNT
...
0
channel (n)
match
1
2
3
4
5
counter
overflow
6
7
8
0
1
2
...
channel (n) output
CHnF bit
previous value
TOF bit
Figure 30-68. EPWM signal with ELSnB:ELSnA = X:1
If (CnV = 0x0000), then the channel (n) output is a 0% duty cycle EPWM signal. If (CnV
> MOD), then the channel (n) output is a 100% duty cycle EPWM signal and CHnF bit is
not set since there is never a channel (n) match. Therefore, MOD must be less than
0xFFFF in order to get a 100% duty cycle EPWM signal.
30.4.7 Center-Aligned PWM (CPWM) Mode
The center-aligned mode is selected when (CPWMS = 1) and (MSnB:MSnA = 1:0).
The CPWM pulse width (duty cycle) is determined by 2 × CnV and the period is
determined by 2 × MOD (see the following figure). MOD must be kept in the range of
0x0001 to 0x7FFF because values outside this range can produce ambiguous results.
In the CPWM mode, the TPM counter counts up until it reaches MOD and then counts
down until it reaches zero.
The CHnF bit is set and channel (n) interrupt is generated (if CHnIE = 1) at the channel
(n) match (TPM counter = CnV) when the TPM counting is down (at the begin of the
pulse width) and when the TPM counting is up (at the end of the pulse width).
This type of PWM signal is called center-aligned because the pulse width centers for all
channels are when the TPM counter is zero.
The other channel modes are not designed to be used with the up-down counter (CPWMS
= 1). Therefore, all TPM channels should be used in CPWM mode when (CPWMS = 1).
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Chapter 30 Timer/PWM Module (TPM)
timer module counter = 0
channel (n) match
(timer module counting
is down)
counter overflow
timer module counter =
MOD
channel (n) match
counter overflow
(timer module counting timer module counter =
is up)
MOD
channel (n) output
pulse width
(2 x CnV)
period
(2 x MOD)
Figure 30-69. CPWM period and pulse width with ELSnB:ELSnA = 1:0
If (ELSnB:ELSnA = 0:0) when the TPM counter reaches the value in the CnV register,
the CHnF bit is set and the channel (n) interrupt is generated (if CHnIE = 1), however the
channel (n) output is not controlled by TPM.
If (ELSnB:ELSnA = 1:0), then the channel (n) output is forced high at the channel (n)
match (TPM counter = CnV) when counting down, and it is forced low at the channel (n)
match when counting up (see the following figure).
counter
overflow
channel (n) match in
down counting
MOD = 0x0008
CnV = 0x0005
CNT
...
7
8
7
6
5
4
3
counter
overflow
channel (n) match in
down counting
channel (n) match in
up counting
2
1
0
1
2
3
4
5
6
7
8
7
6
5
...
channel (n) output
previous value
CHnF bit
TOF bit
Figure 30-70. CPWM signal with ELSnB:ELSnA = 1:0
If (ELSnB:ELSnA = X:1), then the channel (n) output is forced low at the channel (n)
match (TPM counter = CnV) when counting down, and it is forced high at the channel (n)
match when counting up (see the following figure).
counter
overflow
counter
overflow
MOD = 0x0008
CnV = 0x0005
channel (n) match in
down counting
CNT
...
7
8
7
6
5
4
3
channel (n) match in
up counting
2
1
0
1
2
3
4
5
6
channel (n) match in
down counting
7
8
7
6
5
...
channel (n) output
CHnF bit
previous value
TOF bit
Figure 30-71. CPWM signal with ELSnB:ELSnA = X:1
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Functional Description
If (CnV = 0x0000) then the channel (n) output is a 0% duty cycle CPWM signal.
If (CnV > MOD), then the channel (n) output is a 100% duty cycle CPWM signal,
although the CHnF bit is set when the counter changes from incrementing to
decrementing. Therefore, MOD must be less than 0xFFFF in order to get a 100% duty
cycle CPWM signal.
30.4.8 Registers Updated from Write Buffers
30.4.8.1 MOD Register Update
If (CMOD[1:0] = 0:0) then MOD register is updated when MOD register is written.
If (CMOD[1:0] ≠ 0:0), then MOD register is updated according to the CPWMS bit, that
is:
• If the selected mode is not CPWM then MOD register is updated after MOD register
was written and the TPM counter changes from MOD to zero.
• If the selected mode is CPWM then MOD register is updated after MOD register was
written and the TPM counter changes from MOD to (MOD – 1).
30.4.8.2 CnV Register Update
If (CMOD[1:0] = 0:0) then CnV register is updated when CnV register is written.
If (CMOD[1:0] ≠ 0:0), then CnV register is updated according to the selected mode, that
is:
• If the selected mode is output compare then CnV register is updated on the next TPM
counter increment (end of the prescaler counting) after CnV register was written.
• If the selected mode is EPWM then CnV register is updated after CnV register was
written and the TPM counter changes from MOD to zero.
• If the selected mode is CPWM then CnV register is updated after CnV register was
written and the TPM counter changes from MOD to (MOD – 1).
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Chapter 30 Timer/PWM Module (TPM)
30.4.9 DMA
The channel generates a DMA transfer request according to DMA and CHnIE bits (see
the following table).
Table 30-83. Channel DMA Transfer Request
DMA
CHnIE
Channel DMA Transfer Request
Channel Interrupt
0
0
The channel DMA transfer request is not
generated.
The channel interrupt is not generated.
0
1
The channel DMA transfer request is not
generated.
The channel interrupt is generated if (CHnF = 1).
1
0
The channel DMA transfer request is generated if The channel interrupt is not generated.
(CHnF = 1).
1
1
The channel DMA transfer request is generated if The channel interrupt is generated if (CHnF = 1).
(CHnF = 1).
If DMA = 1, the CHnF bit can be cleared either by channel DMA transfer done or writing
a one to CHnF bit (see the following table).
Table 30-84. Clear CHnF Bit
DMA
How CHnF Bit Can Be Cleared
0
CHnF bit is cleared by writing a 1 to CHnF bit.
1
CHnF bit is cleared either when the channel DMA transfer is done or by writing a 1 to CHnF bit.
30.4.10 Reset Overview
The TPM is reset whenever any chip reset occurs.
When the TPM exits from reset:
• the TPM counter and the prescaler counter are zero and are stopped (CMOD[1:0] =
0:0);
• the timer overflow interrupt is zero;
• the channels interrupts are zero;
• the channels are in input capture mode;
• the channels outputs are zero;
• the channels pins are not controlled by TPM (ELS(n)B:ELS(n)A = 0:0).
30.4.11 TPM Interrupts
This section describes TPM interrupts.
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Functional Description
30.4.11.1 Timer Overflow Interrupt
The timer overflow interrupt is generated when (TOIE = 1) and (TOF = 1).
30.4.11.2 Channel (n) Interrupt
The channel (n) interrupt is generated when (CHnIE = 1) and (CHnF = 1).
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Chapter 31
Periodic Interrupt Timer (PIT-RTI)
31.1 Introduction
NOTE
For the chip-specific implementation details of this module's
instances see the chip configuration information.
The PIT module is an array of timers that can be used to raise interrupts and trigger DMA
channels.
31.1.1 Block diagram
The following figure shows the block diagram of the PIT-RTI module.
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Signal description
PIT
Peripheral
bus
PIT
registers
load_value
Timer 1
Iinterrupts
Triggers
Timer n
Peripheral
bus clock
Figure 31-1. Block diagram of the PIT
NOTE
See the chip configuration details for the number of PIT
channels used in this MCU.
31.1.2 Features
The main features of this block are:
• Ability of timers to generate DMA trigger pulses
• Ability of timers to generate interrupts
• Maskable interrupts
• Independent timeout periods for each timer
31.2 Signal description
The PIT module has no external pins.
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Chapter 31 Periodic Interrupt Timer (PIT-RTI)
31.3 Memory map/register description
This section provides a detailed description of all registers accessible in the PIT module.
NOTE
• Reserved registers will read as 0, writes will have no effect.
• See the chip configuration details for the number of PIT channels used in this MCU.
Table 31-2. Timer Channel n
Address Offset
Use
Access
Channel + 0x00
Timer Load Value Register
R/W
Channel + 0x04
Current Timer Value Register
R
Channel + 0x08
Timer Control Register
R/W
Channel + 0x0C
Timer Flag Register
R/W
PIT memory map
Absolute
address
(hex)
Register name
Width
Access
(in bits)
Reset value
Section/
page
4003_7000
PIT Module Control Register (PIT_MCR)
32
R/W
0000_0002h
31.3.1/519
4003_70E0
PIT Upper Lifetime Timer Register (PIT_LTMR64H)
32
R
0000_0000h
31.3.2/521
4003_70E4
PIT Lower Lifetime Timer Register (PIT_LTMR64L)
32
R
0000_0000h
31.3.3/521
4003_7100
Timer Load Value Register (PIT_LDVAL0)
32
R/W
0000_0000h
31.3.4/522
4003_7104
Current Timer Value Register (PIT_CVAL0)
32
R
0000_0000h
31.3.5/522
4003_7108
Timer Control Register (PIT_TCTRL0)
32
R/W
0000_0000h
31.3.6/523
4003_710C
Timer Flag Register (PIT_TFLG0)
32
R/W
0000_0000h
31.3.7/524
4003_7110
Timer Load Value Register (PIT_LDVAL1)
32
R/W
0000_0000h
31.3.4/522
4003_7114
Current Timer Value Register (PIT_CVAL1)
32
R
0000_0000h
31.3.5/522
4003_7118
Timer Control Register (PIT_TCTRL1)
32
R/W
0000_0000h
31.3.6/523
4003_711C
Timer Flag Register (PIT_TFLG1)
32
R/W
0000_0000h
31.3.7/524
31.3.1 PIT Module Control Register (PIT_MCR)
This register enables or disables the PIT timer clocks and controls the timers when the
PIT enters the Debug mode.
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Memory map/register description
Address: 4003_7000h base + 0h offset = 4003_7000h
Bit
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
0
R
W
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
MDIS
FRZ
1
0
Reserved
Reset
0
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
PIT_MCR field descriptions
Field
Description
0–28
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
29
Reserved
This field is reserved.
30
MDIS
Module Disable - (PIT section)
Disables the standard timers. This field must be enabled before any other setup is done.
0
1
31
FRZ
Clock for standard PIT timers is enabled.
Clock for standard PIT timers is disabled.
Freeze
Allows the timers to be stopped when the device enters the Debug mode.
0
1
Timers continue to run in Debug mode.
Timers are stopped in Debug mode.
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Chapter 31 Periodic Interrupt Timer (PIT-RTI)
31.3.2 PIT Upper Lifetime Timer Register (PIT_LTMR64H)
This register is intended for applications that chain timer 0 and timer 1 to build a 64-bit
lifetimer.
Address: 4003_7000h base + E0h offset = 4003_70E0h
Bit
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
LTH
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
PIT_LTMR64H field descriptions
Field
Description
0–31
LTH
Life Timer value
Shows the timer value of timer 1. If this register is read at a time t1, LTMR64L shows the value of timer 0
at time t1.
31.3.3 PIT Lower Lifetime Timer Register (PIT_LTMR64L)
This register is intended for applications that chain timer 0 and timer 1 to build a 64-bit
lifetimer.
To use LTMR64H and LTMR64L, timer 0 and timer 1 need to be chained. To obtain the
correct value, first read LTMR64H and then LTMR64L. LTMR64H will have the value
of CVAL1 at the time of the first access, LTMR64L will have the value of CVAL0 at the
time of the first access, therefore the application does not need to worry about carry-over
effects of the running counter.
Address: 4003_7000h base + E4h offset = 4003_70E4h
Bit
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
LTL
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
PIT_LTMR64L field descriptions
Field
0–31
LTL
Description
Life Timer value
Shows the value of timer 0 at the time LTMR64H was last read. It will only update if LTMR64H is read.
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Memory map/register description
31.3.4 Timer Load Value Register (PIT_LDVALn)
These registers select the timeout period for the timer interrupts.
Address: 4003_7000h base + 100h offset + (16d × i), where i=0d to 1d
Bit
R
W
0
Reset
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
TSV
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
PIT_LDVALn field descriptions
Field
Description
0–31
TSV
Timer Start Value
Sets the timer start value. The timer will count down until it reaches 0, then it will generate an interrupt and
load this register value again. Writing a new value to this register will not restart the timer; instead the
value will be loaded after the timer expires. To abort the current cycle and start a timer period with the new
value, the timer must be disabled and enabled again.
31.3.5 Current Timer Value Register (PIT_CVALn)
These registers indicate the current timer position.
Address: 4003_7000h base + 104h offset + (16d × i), where i=0d to 1d
Bit
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
TVL
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
PIT_CVALn field descriptions
Field
0–31
TVL
Description
Current Timer Value
Represents the current timer value, if the timer is enabled.
NOTE:
• If the timer is disabled, do not use this field as its value is unreliable.
• The timer uses a downcounter. The timer values are frozen in Debug mode if MCR[FRZ] is
set.
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Chapter 31 Periodic Interrupt Timer (PIT-RTI)
31.3.6 Timer Control Register (PIT_TCTRLn)
These register contain the control bits for each timer.
Address: 4003_7000h base + 108h offset + (16d × i), where i=0d to 1d
Bit
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
0
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
CHN
TIE
TEN
0
0
0
0
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
PIT_TCTRLn field descriptions
Field
0–28
Reserved
29
CHN
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Chain Mode
When activated, Timer n-1 needs to expire before timer n can decrement by 1.
Timer 0 can not be changed.
0
1
30
TIE
Timer Interrupt Enable
When an interrupt is pending, or, TFLGn[TIF] is set, enabling the interrupt will immediately cause an
interrupt event. To avoid this, the associated TFLGn[TIF] must be cleared first.
0
1
31
TEN
Timer is not chained.
Timer is chained to previous timer. For example, for Channel 2, if this field is set, Timer 2 is chained to
Timer 1.
Interrupt requests from Timer n are disabled.
Interrupt will be requested whenever TIF is set.
Timer Enable
Enables or disables the timer.
0
1
Timer n is disabled.
Timer n is enabled.
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Functional description
31.3.7 Timer Flag Register (PIT_TFLGn)
These registers hold the PIT interrupt flags.
Address: 4003_7000h base + 10Ch offset + (16d × i), where i=0d to 1d
Bit
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
0
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
0
R
TIF
w1c
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
PIT_TFLGn field descriptions
Field
0–30
Reserved
31
TIF
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Timer Interrupt Flag
Sets to 1 at the end of the timer period. Writing 1 to this flag clears it. Writing 0 has no effect. If enabled,
or, when TCTRLn[TIE] = 1, TIF causes an interrupt request.
0
1
Timeout has not yet occurred.
Timeout has occurred.
31.4 Functional description
This section provides the functional description of the module.
31.4.1 General operation
This section gives detailed information on the internal operation of the module. Each
timer can be used to generate trigger pulses and interrupts. Each interrupt is available on
a separate interrupt line.
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Chapter 31 Periodic Interrupt Timer (PIT-RTI)
31.4.1.1 Timers
The timers generate triggers at periodic intervals, when enabled. The timers load the start
values as specified in their LDVAL registers, count down to 0 and then load the
respective start value again. Each time a timer reaches 0, it will generate a trigger pulse
and set the interrupt flag.
All interrupts can be enabled or masked by setting TCTRLn[TIE]. A new interrupt can be
generated only after the previous one is cleared.
If desired, the current counter value of the timer can be read via the CVAL registers.
The counter period can be restarted, by first disabling, and then enabling the timer with
TCTRLn[TEN]. See the following figure.
Disable
timer
Timer enabled
Start value = p1
Re-enable
timer
Trigger
event
p1
p1
p1
p1
Figure 31-17. Stopping and starting a timer
The counter period of a running timer can be modified, by first disabling the timer,
setting a new load value, and then enabling the timer again. See the following figure.
Timer enabled
Start value = p1
Trigger
event
Re-enable
Disable timer,
Set new load value timer
p2
p1
p2
p2
p1
Figure 31-18. Modifying running timer period
It is also possible to change the counter period without restarting the timer by writing
LDVAL with the new load value. This value will then be loaded after the next trigger
event. See the following figure.
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Initialization and application information
Timer enabled
Start value = p1
New start
Value p2 set
Trigger
event
p1
p1
p1
p2
p2
Figure 31-19. Dynamically setting a new load value
31.4.1.2 Debug mode
In Debug mode, the timers will be frozen based on MCR[FRZ]. This is intended to aid
software development, allowing the developer to halt the processor, investigate the
current state of the system, for example, the timer values, and then continue the
operation.
31.4.2 Interrupts
All the timers support interrupt generation. See the MCU specification for related vector
addresses and priorities.
Timer interrupts can be enabled by setting TCTRLn[TIE]. TFLGn[TIF] are set to 1 when
a timeout occurs on the associated timer, and are cleared to 0 by writing a 1 to the
corresponding TFLGn[TIF].
31.4.3 Chained timers
When a timer has chain mode enabled, it will only count after the previous timer has
expired. So if timer n-1 has counted down to 0, counter n will decrement the value by
one. This allows to chain some of the timers together to form a longer timer. The first
timer (timer 0) cannot be chained to any other timer.
31.5 Initialization and application information
In the example configuration:
• The PIT clock has a frequency of 50 MHz.
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Chapter 31 Periodic Interrupt Timer (PIT-RTI)
• Timer 1 creates an interrupt every 5.12 ms.
• Timer 3 creates a trigger event every 30 ms.
The PIT module must be activated by writing a 0 to MCR[MDIS].
The 50 MHz clock frequency equates to a clock period of 20 ns. Timer 1 needs to trigger
every 5.12 ms/20 ns = 256,000 cycles and Timer 3 every 30 ms/20 ns = 1,500,000 cycles.
The value for the LDVAL register trigger is calculated as:
LDVAL trigger = (period / clock period) -1
This means LDVAL1 and LDVAL3 must be written with 0x0003E7FF and 0x0016E35F
respectively.
The interrupt for Timer 1 is enabled by setting TCTRL1[TIE]. The timer is started by
writing 1 to TCTRL1[TEN].
Timer 3 shall be used only for triggering. Therefore, Timer 3 is started by writing a 1 to
TCTRL3[TEN]. TCTRL3[TIE] stays at 0.
The following example code matches the described setup:
// turn on PIT
PIT_MCR = 0x00;
// Timer 1
PIT_LDVAL1 = 0x0003E7FF; // setup timer 1 for 256000 cycles
PIT_TCTRL1 = TIE; // enable Timer 1 interrupts
PIT_TCTRL1 |= TEN; // start Timer 1
// Timer 3
PIT_LDVAL3 = 0x0016E35F; // setup timer 3for 1500000 cycles
PIT_TCTRL3 |= TEN; // start Timer 3
31.6 Example configuration for chained timers
In the example configuration:
• The PIT clock has a frequency of 100 MHz.
• Timers 1 and 2 are available.
• An interrupt shall be raised every 1 hour.
The PIT module needs to be activated by writing a 0 to MCR[MDIS].
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Example configuration for the lifetime timer
The 100 MHz clock frequency equates to a clock period of 10 ns, so the PIT needs to
count for 6000 million cycles, which is more than a single timer can do. So, Timer 1 is
set up to trigger every 6 s (600 million cycles). Timer 2 is chained to Timer 1 and
programmed to trigger 10 times.
The value for the LDVAL register trigger is calculated as number of cycles-1, so
LDVAL1 receives the value 0x23C345FF and LDVAL2 receives the value 0x00000009.
The interrupt for Timer 2 is enabled by setting TCTRL2[TIE], the Chain mode is
activated by setting TCTRL2[CHN], and the timer is started by writing a 1 to
TCTRL2[TEN]. TCTRL1[TEN] needs to be set, and TCTRL1[CHN] and TCTRL1[TIE]
are cleared.
The following example code matches the described setup:
// turn on PIT
PIT_MCR = 0x00;
// Timer 2
PIT_LDVAL2
PIT_TCTRL2
PIT_TCTRL2
PIT_TCTRL2
= 0x00000009; //
= TIE; // enable
|= CHN; // chain
|= TEN; // start
setup
Timer
Timer
Timer
Timer 2 for 10 counts
2 interrupt
2 to Timer 1
2
// Timer 1
PIT_LDVAL1 = 0x23C345FF; // setup Timer 1 for 600 000 000 cycles
PIT_TCTRL1 = TEN; // start Timer 1
31.7 Example configuration for the lifetime timer
To configure the lifetimer timer, channels 0 and 1 need to be chained together.
First the PIT module needs to be activated by writing a 0 to the MDIS bit in the CTRL
register, then the LDVAL registers need to be set to the maximum value.
The timer is a downcounter.
The following example code matches the described setup:
// turn on PIT
PIT_MCR = 0x00;
// Timer 1
PIT_LDVAL1
PIT_TCTRL1
PIT_TCTRL1
PIT_TCTRL1
= 0xFFFFFFFF; // setup timer 1 for maximum counting period
= 0x0; // disable timer 1 interrupts
|= CHN; // chain timer 1 to timer 0
|= TEN; // start timer 1
// Timer 0
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Chapter 31 Periodic Interrupt Timer (PIT-RTI)
PIT_LDVAL0 = 0xFFFFFFFF; // setup timer 0 for maximum counting period
PIT_TCTRL0 = TEN; // start timer 0
To access the lifetime, read first LTMR64H and then LTMR64L.
current_uptime = PIT_LTMR64H<<32;
current_uptime = current_uptime + PIT_LTMR64L;
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Example configuration for the lifetime timer
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Chapter 32
Low-Power Timer (LPTMR)
32.1 Introduction
NOTE
For the chip-specific implementation details of this module's
instances see the chip configuration information.
The low-power timer (LPTMR) can be configured to operate as a time counter with
optional prescaler, or as a pulse counter with optional glitch filter, across all power
modes, including the low-leakage modes. It can also continue operating through most
system reset events, allowing it to be used as a time of day counter.
32.1.1 Features
The features of the LPTMR module include:
• 16-bit time counter or pulse counter with compare
• Optional interrupt can generate asynchronous wakeup from any low-power mode
• Hardware trigger output
• Counter supports free-running mode or reset on compare
• Configurable clock source for prescaler/glitch filter
• Configurable input source for pulse counter
• Rising-edge or falling-edge
32.1.2 Modes of operation
The following table describes the operation of the LPTMR module in various modes.
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LPTMR signal descriptions
Table 32-1. Modes of operation
Modes
Description
Run
The LPTMR operates normally.
Wait
The LPTMR continues to operate normally and
may be configured to exit the low-power mode
by generating an interrupt request.
Stop
The LPTMR continues to operate normally and
may be configured to exit the low-power mode
by generating an interrupt request.
Low-Leakage
The LPTMR continues to operate normally and
may be configured to exit the low-power mode
by generating an interrupt request.
Debug
The LPTMR operates normally in Pulse Counter
mode, but counter does not increment in Time
Counter mode.
32.2 LPTMR signal descriptions
Table 32-2. LPTMR signal descriptions
Signal
I/O
LPTMR_ALTn
I
Description
Pulse Counter Input pin
32.2.1 Detailed signal descriptions
Table 32-3. LPTMR interface—detailed signal descriptions
Signal
I/O
LPTMR_ALTn
I
Description
Pulse Counter Input
The LPTMR can select one of the input pins to be used in Pulse Counter mode.
State meaning
Assertion—If configured for pulse counter mode with
active-high input, then assertion causes the CNR to
increment.
Deassertion—If configured for pulse counter mode with
active-low input, then deassertion causes the CNR to
increment.
Timing
Assertion or deassertion may occur at any time; input may
assert asynchronously to the bus clock.
32.3 Memory map and register definition
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Chapter 32 Low-Power Timer (LPTMR)
LPTMR memory map
Absolute
address
(hex)
Width
Access
(in bits)
Register name
Reset value
Section/
page
4004_0000
Low Power Timer Control Status Register (LPTMR0_CSR)
32
R/W
0000_0000h
32.3.1/533
4004_0004
Low Power Timer Prescale Register (LPTMR0_PSR)
32
R/W
0000_0000h
32.3.2/534
4004_0008
Low Power Timer Compare Register (LPTMR0_CMR)
32
R/W
0000_0000h
32.3.3/536
4004_000C
Low Power Timer Counter Register (LPTMR0_CNR)
32
R
0000_0000h
32.3.4/536
32.3.1 Low Power Timer Control Status Register (LPTMRx_CSR)
Address: 4004_0000h base + 0h offset = 4004_0000h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
TPP
TFC
TMS
TEN
0
0
0
0
0
R
TCF
w1c
W
Reset
0
0
0
0
0
0
0
0
0
TIE
0
TPS
0
0
LPTMRx_CSR field descriptions
Field
31–8
Reserved
7
TCF
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Timer Compare Flag
TCF is set when the LPTMR is enabled and the CNR equals the CMR and increments. TCF is cleared
when the LPTMR is disabled or a logic 1 is written to it.
0
1
6
TIE
Timer Interrupt Enable
When TIE is set, the LPTMR Interrupt is generated whenever TCF is also set.
0
1
5–4
TPS
The value of CNR is not equal to CMR and increments.
The value of CNR is equal to CMR and increments.
Timer interrupt disabled.
Timer interrupt enabled.
Timer Pin Select
Configures the input source to be used in Pulse Counter mode. TPS must be altered only when the
LPTMR is disabled. The input connections vary by device. See the chip configuration details for
information on the connections to these inputs.
00
Pulse counter input 0 is selected.
Table continues on the next page...
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Memory map and register definition
LPTMRx_CSR field descriptions (continued)
Field
Description
01
10
11
3
TPP
Pulse counter input 1 is selected.
Pulse counter input 2 is selected.
Pulse counter input 3 is selected.
Timer Pin Polarity
Configures the polarity of the input source in Pulse Counter mode. TPP must be changed only when the
LPTMR is disabled.
0
1
2
TFC
Pulse Counter input source is active-high, and the CNR will increment on the rising-edge.
Pulse Counter input source is active-low, and the CNR will increment on the falling-edge.
Timer Free-Running Counter
When clear, TFC configures the CNR to reset whenever TCF is set. When set, TFC configures the CNR to
reset on overflow. TFC must be altered only when the LPTMR is disabled.
0
1
1
TMS
CNR is reset whenever TCF is set.
CNR is reset on overflow.
Timer Mode Select
Configures the mode of the LPTMR. TMS must be altered only when the LPTMR is disabled.
0
1
0
TEN
Time Counter mode.
Pulse Counter mode.
Timer Enable
When TEN is clear, it resets the LPTMR internal logic, including the CNR and TCF. When TEN is set, the
LPTMR is enabled. While writing 1 to this field, CSR[5:1] must not be altered.
0
1
LPTMR is disabled and internal logic is reset.
LPTMR is enabled.
32.3.2 Low Power Timer Prescale Register (LPTMRx_PSR)
Address: 4004_0000h base + 4h offset = 4004_0004h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
R
PRESCALE
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
PBYP
0
0
PCS
0
0
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Chapter 32 Low-Power Timer (LPTMR)
LPTMRx_PSR field descriptions
Field
31–7
Reserved
6–3
PRESCALE
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Prescale Value
Configures the size of the Prescaler in Time Counter mode or width of the glitch filter in Pulse Counter
mode. PRESCALE must be altered only when the LPTMR is disabled.
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
2
PBYP
Prescaler Bypass
When PBYP is set, the selected prescaler clock in Time Counter mode or selected input source in Pulse
Counter mode directly clocks the CNR. When PBYP is clear, the CNR is clocked by the output of the
prescaler/glitch filter. PBYP must be altered only when the LPTMR is disabled.
0
1
1–0
PCS
Prescaler divides the prescaler clock by 2; glitch filter does not support this configuration.
Prescaler divides the prescaler clock by 4; glitch filter recognizes change on input pin after 2 rising
clock edges.
Prescaler divides the prescaler clock by 8; glitch filter recognizes change on input pin after 4 rising
clock edges.
Prescaler divides the prescaler clock by 16; glitch filter recognizes change on input pin after 8
rising clock edges.
Prescaler divides the prescaler clock by 32; glitch filter recognizes change on input pin after 16
rising clock edges.
Prescaler divides the prescaler clock by 64; glitch filter recognizes change on input pin after 32
rising clock edges.
Prescaler divides the prescaler clock by 128; glitch filter recognizes change on input pin after 64
rising clock edges.
Prescaler divides the prescaler clock by 256; glitch filter recognizes change on input pin after 128
rising clock edges.
Prescaler divides the prescaler clock by 512; glitch filter recognizes change on input pin after 256
rising clock edges.
Prescaler divides the prescaler clock by 1024; glitch filter recognizes change on input pin after 512
rising clock edges.
Prescaler divides the prescaler clock by 2048; glitch filter recognizes change on input pin after
1024 rising clock edges.
Prescaler divides the prescaler clock by 4096; glitch filter recognizes change on input pin after
2048 rising clock edges.
Prescaler divides the prescaler clock by 8192; glitch filter recognizes change on input pin after
4096 rising clock edges.
Prescaler divides the prescaler clock by 16,384; glitch filter recognizes change on input pin after
8192 rising clock edges.
Prescaler divides the prescaler clock by 32,768; glitch filter recognizes change on input pin after
16,384 rising clock edges.
Prescaler divides the prescaler clock by 65,536; glitch filter recognizes change on input pin after
32,768 rising clock edges.
Prescaler/glitch filter is enabled.
Prescaler/glitch filter is bypassed.
Prescaler Clock Select
Selects the clock to be used by the LPTMR prescaler/glitch filter. PCS must be altered only when the
LPTMR is disabled. The clock connections vary by device.
NOTE: See the chip configuration details for information on the connections to these inputs.
Table continues on the next page...
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Memory map and register definition
LPTMRx_PSR field descriptions (continued)
Field
Description
00
01
10
11
Prescaler/glitch filter clock 0 selected.
Prescaler/glitch filter clock 1 selected.
Prescaler/glitch filter clock 2 selected.
Prescaler/glitch filter clock 3 selected.
32.3.3 Low Power Timer Compare Register (LPTMRx_CMR)
Address: 4004_0000h base + 8h offset = 4004_0008h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
0
R
0
0
0
0
0
0
0
0
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
COMPARE
W
Reset
9
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
LPTMRx_CMR field descriptions
Field
Description
31–16
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
15–0
COMPARE
Compare Value
When the LPTMR is enabled and the CNR equals the value in the CMR and increments, TCF is set and
the hardware trigger asserts until the next time the CNR increments. If the CMR is 0, the hardware trigger
will remain asserted until the LPTMR is disabled. If the LPTMR is enabled, the CMR must be altered only
when TCF is set.
32.3.4 Low Power Timer Counter Register (LPTMRx_CNR)
Address: 4004_0000h base + Ch offset = 4004_000Ch
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
0
R
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
COUNTER
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
LPTMRx_CNR field descriptions
Field
31–16
Reserved
15–0
COUNTER
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Counter Value
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Chapter 32 Low-Power Timer (LPTMR)
32.4 Functional description
32.4.1 LPTMR power and reset
The LPTMR remains powered in all power modes, including low-leakage modes. If the
LPTMR is not required to remain operating during a low-power mode, then it must be
disabled before entering the mode.
The LPTMR is reset only on global Power On Reset (POR) or Low Voltage Detect
(LVD). When configuring the LPTMR registers, the CSR must be initially written with
the timer disabled, before configuring the PSR and CMR. Then, CSR[TIE] must be set as
the last step in the initialization. This ensures the LPTMR is configured correctly and the
LPTMR counter is reset to zero following a warm reset.
32.4.2 LPTMR clocking
The LPTMR prescaler/glitch filter can be clocked by one of the four clocks. The clock
source must be enabled before the LPTMR is enabled.
NOTE
The clock source selected may need to be configured to remain
enabled in low-power modes, otherwise the LPTMR will not
operate during low-power modes.
In Pulse Counter mode with the prescaler/glitch filter bypassed, the selected input source
directly clocks the CNR and no other clock source is required. To minimize power in this
case, configure the prescaler clock source for a clock that is not toggling.
NOTE
The clock source or pulse input source selected for the LPTMR
should not exceed the frequency fLPTMR defined in the device
datasheet.
32.4.3 LPTMR prescaler/glitch filter
The LPTMR prescaler and glitch filter share the same logic which operates as a prescaler
in Time Counter mode and as a glitch filter in Pulse Counter mode.
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Functional description
NOTE
The prescaler/glitch filter configuration must not be altered
when the LPTMR is enabled.
32.4.3.1 Prescaler enabled
In Time Counter mode, when the prescaler is enabled, the output of the prescaler directly
clocks the CNR. When the LPTMR is enabled, the CNR will increment every 22 to 216
prescaler clock cycles. After the LPTMR is enabled, the first increment of the CNR will
take an additional one or two prescaler clock cycles due to synchronization logic.
32.4.3.2 Prescaler bypassed
In Time Counter mode, when the prescaler is bypassed, the selected prescaler clock
increments the CNR on every clock cycle. When the LPTMR is enabled, the first
increment will take an additional one or two prescaler clock cycles due to
synchronization logic.
32.4.3.3 Glitch filter
In Pulse Counter mode, when the glitch filter is enabled, the output of the glitch filter
directly clocks the CNR. When the LPTMR is first enabled, the output of the glitch filter
is asserted, that is, logic 1 for active-high and logic 0 for active-low. The following table
shows the change in glitch filter output with the selected input source.
If
The selected input source remains deasserted for at least
to 215 consecutive prescaler clock rising edges
Then
21
The selected input source remains asserted for at least 21 to
215 consecutive prescaler clock rising-edges
The glitch filter output will also deassert.
The glitch filter output will also assert.
NOTE
The input is only sampled on the rising clock edge.
The CNR will increment each time the glitch filter output asserts. In Pulse Counter mode,
the maximum rate at which the CNR can increment is once every 22 to 216 prescaler
clock edges. When first enabled, the glitch filter will wait an additional one or two
prescaler clock edges due to synchronization logic.
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Chapter 32 Low-Power Timer (LPTMR)
32.4.3.4 Glitch filter bypassed
In Pulse Counter mode, when the glitch filter is bypassed, the selected input source
increments the CNR every time it asserts. Before the LPTMR is first enabled, the selected
input source is forced to be asserted. This prevents the CNR from incrementing if the
selected input source is already asserted when the LPTMR is first enabled.
32.4.4 LPTMR compare
When the CNR equals the value of the CMR and increments, the following events occur:
•
•
•
•
CSR[TCF] is set.
LPTMR interrupt is generated if CSR[TIE] is also set.
LPTMR hardware trigger is generated.
CNR is reset if CSR[TFC] is clear.
When the LPTMR is enabled, the CMR can be altered only when CSR[TCF] is set. When
updating the CMR, the CMR must be written and CSR[TCF] must be cleared before the
LPTMR counter has incremented past the new LPTMR compare value.
32.4.5 LPTMR counter
The CNR increments by one on every:
•
•
•
•
Prescaler clock in Time Counter mode with prescaler bypassed
Prescaler output in Time Counter mode with prescaler enabled
Input source assertion in Pulse Counter mode with glitch filter bypassed
Glitch filter output in Pulse Counter mode with glitch filter enabled
The CNR is reset when the LPTMR is disabled or if the counter register overflows. If
CSR[TFC] is cleared, then the CNR is also reset whenever CSR[TCF] is set.
The CNR continues incrementing when the core is halted in Debug mode when
configured for Pulse Counter mode, the CNR will stop incrementing when the core is
halted in Debug mode when configured for Time Counter mode.
The CNR cannot be initialized, but can be read at any time. On each read of the CNR,
software must first write to the CNR with any value. This will synchronize and register
the current value of the CNR into a temporary register. The contents of the temporary
register are returned on each read of the CNR.
When reading the CNR, the bus clock must be at least two times faster than the rate at
which the LPTMR counter is incrementing, otherwise incorrect data may be returned.
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Functional description
32.4.6 LPTMR hardware trigger
The LPTMR hardware trigger asserts at the same time the CSR[TCF] is set and can be
used to trigger hardware events in other peripherals without software intervention. The
hardware trigger is always enabled.
When
Then
The CMR is set to 0 with CSR[TFC] clear
The LPTMR hardware trigger will assert on the first compare
and does not deassert.
The CMR is set to a nonzero value, or, if CSR[TFC] is set
The LPTMR hardware trigger will assert on each compare
and deassert on the following increment of the CNR.
32.4.7 LPTMR interrupt
The LPTMR interrupt is generated whenever CSR[TIE] and CSR[TCF] are set.
CSR[TCF] is cleared by disabling the LPTMR or by writing a logic 1 to it.
CSR[TIE] can be altered and CSR[TCF] can be cleared while the LPTMR is enabled.
The LPTMR interrupt is generated asynchronously to the system clock and can be used to
generate a wakeup from any low-power mode, including the low-leakage modes,
provided the LPTMR is enabled as a wakeup source.
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Chapter 33
Real Time Clock (RTC)
33.1 Introduction
NOTE
For the chip-specific implementation details of this module's
instances see the chip configuration information.
33.1.1 Features
The RTC module features include:
• 32-bit seconds counter with roll-over protection and 32-bit alarm
• 16-bit prescaler with compensation that can correct errors between 0.12 ppm and
3906 ppm
• Register write protection
• Lock register requires POR or software reset to enable write access
• 1 Hz square wave output
33.1.2 Modes of operation
The RTC remains functional in all low power modes and can generate an interrupt to exit
any low power mode.
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Register definition
33.1.3 RTC Signal Descriptions
Table 33-1. RTC signal descriptions
Signal
Description
RTC_CLKOUT
I/O
1 Hz square-wave output
O
33.1.3.1 RTC clock output
The clock to the seconds counter is available on the RTC_CLKOUT signal. It is a 1 Hz
square wave output.
33.2 Register definition
All registers must be accessed using 32-bit writes and all register accesses incur three
wait states.
Write accesses to any register by non-supervisor mode software, when the supervisor
access bit in the control register is clear, will terminate with a bus error.
Read accesses by non-supervisor mode software complete as normal.
Writing to a register protected by the lock register does not generate a bus error, but the
write will not complete.
RTC memory map
Absolute
address
(hex)
Register name
Width
Access
(in bits)
Reset value
Section/
page
4003_D000
RTC Time Seconds Register (RTC_TSR)
32
R/W
0000_0000h
33.2.1/543
4003_D004
RTC Time Prescaler Register (RTC_TPR)
32
R/W
0000_0000h
33.2.2/543
4003_D008
RTC Time Alarm Register (RTC_TAR)
32
R/W
0000_0000h
33.2.3/544
4003_D00C RTC Time Compensation Register (RTC_TCR)
32
R/W
0000_0000h
33.2.4/544
4003_D010
RTC Control Register (RTC_CR)
32
R/W
0000_0000h
33.2.5/545
4003_D014
RTC Status Register (RTC_SR)
32
R/W
0000_0001h
33.2.6/547
4003_D018
RTC Lock Register (RTC_LR)
32
R/W
0000_00FFh
33.2.7/548
32
R/W
0000_0007h
33.2.8/549
4003_D01C RTC Interrupt Enable Register (RTC_IER)
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Chapter 33 Real Time Clock (RTC)
33.2.1 RTC Time Seconds Register (RTC_TSR)
Address: 4003_D000h base + 0h offset = 4003_D000h
Bit
R
W
31
Reset
0
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
TSR
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
RTC_TSR field descriptions
Field
Description
31–0
TSR
Time Seconds Register
When the time counter is enabled, the TSR is read only and increments once a second provided SR[TOF]
or SR[TIF] are not set. The time counter will read as zero when SR[TOF] or SR[TIF] are set. When the
time counter is disabled, the TSR can be read or written. Writing to the TSR when the time counter is
disabled will clear the SR[TOF] and/or the SR[TIF]. Writing to TSR with zero is supported, but not
recommended because TSR will read as zero when SR[TIF] or SR[TOF] are set (indicating the time is
invalid).
33.2.2 RTC Time Prescaler Register (RTC_TPR)
Address: 4003_D000h base + 4h offset = 4003_D004h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
0
R
0
0
0
0
0
0
0
0
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
TPR
W
Reset
8
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
RTC_TPR field descriptions
Field
31–16
Reserved
15–0
TPR
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Time Prescaler Register
When the time counter is enabled, the TPR is read only and increments every 32.768 kHz clock cycle. The
time counter will read as zero when SR[TOF] or SR[TIF] are set. When the time counter is disabled, the
TPR can be read or written. The TSR[TSR] increments when bit 14 of the TPR transitions from a logic one
to a logic zero.
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Register definition
33.2.3 RTC Time Alarm Register (RTC_TAR)
Address: 4003_D000h base + 8h offset = 4003_D008h
Bit
R
W
31
Reset
0
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
TAR
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
RTC_TAR field descriptions
Field
Description
31–0
TAR
Time Alarm Register
When the time counter is enabled, the SR[TAF] is set whenever the TAR[TAR] equals the TSR[TSR] and
the TSR[TSR] increments. Writing to the TAR clears the SR[TAF].
33.2.4 RTC Time Compensation Register (RTC_TCR)
Address: 4003_D000h base + Ch offset = 4003_D00Ch
Bit
31
30
29
28
27
26
25
24
23
22
21
20
CIC
R
19
18
17
16
15
14
13
TCV
0
0
0
0
0
0
0
0
0
0
0
0
0
11
10
9
8
7
6
5
CIR
W
Reset
12
0
0
0
0
0
0
0
0
4
3
2
1
0
0
0
0
TCR
0
0
0
0
0
0
0
0
RTC_TCR field descriptions
Field
Description
31–24
CIC
Compensation Interval Counter
23–16
TCV
Time Compensation Value
15–8
CIR
Compensation Interval Register
7–0
TCR
Time Compensation Register
Current value of the compensation interval counter. If the compensation interval counter equals zero then
it is loaded with the contents of the CIR. If the CIC does not equal zero then it is decremented once a
second.
Current value used by the compensation logic for the present second interval. Updated once a second if
the CIC equals 0 with the contents of the TCR field. If the CIC does not equal zero then it is loaded with
zero (compensation is not enabled for that second increment).
Configures the compensation interval in seconds from 1 to 256 to control how frequently the TCR should
adjust the number of 32.768 kHz cycles in each second. The value written should be one less than the
number of seconds. For example, write zero to configure for a compensation interval of one second. This
register is double buffered and writes do not take affect until the end of the current compensation interval.
Configures the number of 32.768 kHz clock cycles in each second. This register is double buffered and
writes do not take affect until the end of the current compensation interval.
Table continues on the next page...
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Chapter 33 Real Time Clock (RTC)
RTC_TCR field descriptions (continued)
Field
Description
80h
...
FFh
00h
01h
...
7Fh
Time Prescaler Register overflows every 32896 clock cycles.
...
Time Prescaler Register overflows every 32769 clock cycles.
Time Prescaler Register overflows every 32768 clock cycles.
Time Prescaler Register overflows every 32767 clock cycles.
...
Time Prescaler Register overflows every 32641 clock cycles.
33.2.5 RTC Control Register (RTC_CR)
Address: 4003_D000h base + 10h offset = 4003_D010h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
R
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
R
0
Reserved
W
UM
SUP
0
0
OSCE
0
0
0
WPE SWR
0
W
Reset
CLKO
SC2P SC4P SC8P
SC16P
0
0
0
0
0
0
0
0
0
0
0
0
RTC_CR field descriptions
Field
31–15
Reserved
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Table continues on the next page...
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Register definition
RTC_CR field descriptions (continued)
Field
Description
14
Reserved
This field is reserved.
It must always be written to 0.
13
SC2P
Oscillator 2pF Load Configure
12
SC4P
Oscillator 4pF Load Configure
11
SC8P
Oscillator 8pF Load Configure
10
SC16P
Oscillator 16pF Load Configure
9
CLKO
Clock Output
8
OSCE
Oscillator Enable
7–4
Reserved
3
UM
0
1
0
1
0
1
0
1
0
1
0
1
Disable the load.
Enable the additional load.
Disable the load.
Enable the additional load.
Disable the load.
Enable the additional load.
Disable the load.
Enable the additional load.
The 32 kHz clock is output to other peripherals.
The 32 kHz clock is not output to other peripherals.
32.768 kHz oscillator is disabled.
32.768 kHz oscillator is enabled. After setting this bit, wait the oscillator startup time before enabling
the time counter to allow the 32.768 kHz clock time to stabilize.
This field is reserved.
This read-only field is reserved and always has the value 0.
Update Mode
Allows SR[TCE] to be written even when the Status Register is locked. When set, the SR[TCE] can always
be written if the SR[TIF] or SR[TOF] are set or if the SR[TCE] is clear.
0
1
Registers cannot be written when locked.
Registers can be written when locked under limited conditions.
2
SUP
Supervisor Access
1
WPE
Wakeup Pin Enable
0
1
The wakeup pin is optional and not available on all devices.
0
1
0
SWR
Non-supervisor mode write accesses are not supported and generate a bus error.
Non-supervisor mode write accesses are supported.
Wakeup pin is disabled.
Wakeup pin is enabled and wakeup pin asserts if the RTC interrupt asserts or the wakeup pin is
turned on.
Software Reset
Table continues on the next page...
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Chapter 33 Real Time Clock (RTC)
RTC_CR field descriptions (continued)
Field
Description
0
1
No effect.
Resets all RTC registers except for the SWR bit . The SWR bit is cleared by POR and by software
explicitly clearing it.
33.2.6 RTC Status Register (RTC_SR)
Address: 4003_D000h base + 14h offset = 4003_D014h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
R
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
TAF
TOF
TIF
0
0
0
1
0
R
TCE
W
Reset
0
0
0
0
0
0
0
0
0
0
0
0
RTC_SR field descriptions
Field
31–5
Reserved
4
TCE
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Time Counter Enable
When time counter is disabled the TSR register and TPR register are writeable, but do not increment.
When time counter is enabled the TSR register and TPR register are not writeable, but increment.
0
1
3
Reserved
2
TAF
This field is reserved.
This read-only field is reserved and always has the value 0.
Time Alarm Flag
Time alarm flag is set when the TAR[TAR] equals the TSR[TSR] and the TSR[TSR] increments. This bit is
cleared by writing the TAR register.
0
1
1
TOF
Time counter is disabled.
Time counter is enabled.
Time alarm has not occurred.
Time alarm has occurred.
Time Overflow Flag
Time overflow flag is set when the time counter is enabled and overflows. The TSR and TPR do not
increment and read as zero when this bit is set. This bit is cleared by writing the TSR register when the
time counter is disabled.
0
1
Time overflow has not occurred.
Time overflow has occurred and time counter is read as zero.
Table continues on the next page...
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Register definition
RTC_SR field descriptions (continued)
Field
Description
0
TIF
Time Invalid Flag
The time invalid flag is set on POR or software reset. The TSR and TPR do not increment and read as
zero when this bit is set. This bit is cleared by writing the TSR register when the time counter is disabled.
0
1
Time is valid.
Time is invalid and time counter is read as zero.
33.2.7 RTC Lock Register (RTC_LR)
Address: 4003_D000h base + 18h offset = 4003_D018h
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
0
0
0
0
0
0
0
7
6
5
4
3
2
1
0
0
R
W
Reset
0
0
0
0
Bit
15
14
13
12
0
0
0
0
11
10
9
8
0
R
1
LRL
SRL
CRL
TCL
1
1
1
1
1
W
Reset
0
0
0
0
0
0
0
0
1
1
1
1
RTC_LR field descriptions
Field
Description
31–8
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
7
Reserved
This field is reserved.
This read-only field is reserved and always has the value 1.
6
LRL
Lock Register Lock
After being cleared, this bit can be set only by POR or software reset.
0
1
5
SRL
Status Register Lock
After being cleared, this bit can be set only by POR or software reset.
0
1
4
CRL
Lock Register is locked and writes are ignored.
Lock Register is not locked and writes complete as normal.
Status Register is locked and writes are ignored.
Status Register is not locked and writes complete as normal.
Control Register Lock
After being cleared, this bit can only be set by POR.
0
1
Control Register is locked and writes are ignored.
Control Register is not locked and writes complete as normal.
Table continues on the next page...
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Chapter 33 Real Time Clock (RTC)
RTC_LR field descriptions (continued)
Field
Description
3
TCL
Time Compensation Lock
After being cleared, this bit can be set only by POR or software reset.
0
1
2–0
Reserved
Time Compensation Register is locked and writes are ignored.
Time Compensation Register is not locked and writes complete as normal.
This field is reserved.
This read-only field is reserved and always has the value 1.
33.2.8 RTC Interrupt Enable Register (RTC_IER)
Address: 4003_D000h base + 1Ch offset = 4003_D01Ch
Bit
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
0
R
Reset
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
TSIE
Reserved
W
TAIE
TOIE
TIIE
0
0
1
1
1
WPON
0
R
W
Reset
0
0
0
0
0
0
0
0
0
Reserved
0
0
RTC_IER field descriptions
Field
31–8
Reserved
7
WPON
Description
This field is reserved.
This read-only field is reserved and always has the value 0.
Wakeup Pin On
The wakeup pin is optional and not available on all devices. Whenever the wakeup pin is enabled and this
bit is set, the wakeup pin will assert.
0
1
6–5
Reserved
4
TSIE
No effect.
If the wakeup pin is enabled, then the wakeup pin will assert.
This field is reserved.
Time Seconds Interrupt Enable
The seconds interrupt is an edge-sensitive interrupt with a dedicated interrupt vector. It is generated once
a second and requires no software overhead (there is no corresponding status flag to clear).
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RTC_IER field descriptions (continued)
Field
Description
0
1
3
Reserved
Seconds interrupt is disabled.
Seconds interrupt is enabled.
This field is reserved.
2
TAIE
Time Alarm Interrupt Enable
1
TOIE
Time Overflow Interrupt Enable
0
TIIE
Time Invalid Interrupt Enable
0
1
0
1
0
1
Time alarm flag does not generate an interrupt.
Time alarm flag does generate an interrupt.
Time overflow flag does not generate an interrupt.
Time overflow flag does generate an interrupt.
Time invalid flag does not generate an interrupt.
Time invalid flag does generate an interrupt.
33.3 Functional description
33.3.1 Power, clocking, and reset
The RTC is an always powered block that remains active in all low power modes.
The time counter within the RTC is clocked by a 32.768 kHz clock sourced from an
external crystal using the oscillator.
The power-on-reset signal initializes all RTC registers to their default state. A software
reset bit can also initialize all RTC registers.
33.3.1.1 Oscillator control
The 32.768 kHz crystal oscillator is disabled at POR and must be enabled by software.
After enabling the cystal oscillator, wait the oscillator startup time before setting
SR[TCE] or using the oscillator clock external to the RTC.
The crystal oscillator includes tunable capacitors that can be configured by software. Do
not change the capacitance unless the oscillator is disabled.
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Chapter 33 Real Time Clock (RTC)
33.3.1.2 Software reset
Writing one to the CR[SWR] forces the equivalent of a POR to the rest of the RTC
module. The CR[SWR] is not affected by the software reset and must be cleared by
software.
33.3.1.3 Supervisor access
When the supervisor access control bit is clear, only supervisor mode software can write
to the RTC registers, non-supervisor mode software will generate a bus error. Both
supervisor and non-supervisor mode software can always read the RTC registers.
33.3.2 Time counter
The time counter consists of a 32-bit seconds counter that increments once every second
and a 16-bit prescaler register that increments once every 32.768 kHz clock cycle.
The time seconds register and time prescaler register can be written only when SR[TCE]
is clear. Always write to the prescaler register before writing to the seconds register,
because the seconds register increments on the falling edge of bit 14 of the prescaler
register.
The time prescaler register increments provided SR[TCE] is set, SR[TIF] is clear,
SR[TOF] is clear, and the 32.768 kHz clock source is present. After enabling the
oscillator, wait the oscillator startup time before setting SR[TCE] to allow time for the
oscillator clock output to stabilize.
If the time seconds register overflows then the SR[TOF] will set and the time prescaler
register will stop incrementing. Clear SR[TOF] by initializing the time seconds register.
The time seconds register and time prescaler register read as zero whenever SR[TOF] is
set.
SR[TIF] is set on POR and software reset and is cleared by initializing the time seconds
register. The time seconds register and time prescaler register read as zero whenever
SR[TIF] is set.
33.3.3 Compensation
The compensation logic provides an accurate and wide compensation range and can
correct errors as high as 3906 ppm and as low as 0.12 ppm. The compensation factor
must be calculated externally to the RTC and supplied by software to the compensation
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Functional description
register. The RTC itself does not calculate the amount of compensation that is required,
although the 1 Hz clock is output to an external pin in support of external calibration
logic.
Crystal compensation can be supported by using firmware and crystal characteristics to
determine the compensation amount. Temperature compensation can be supported by
firmware that periodically measures the external temperature via ADC and updates the
compensation register based on a look-up table that specifies the change in crystal
frequency over temperature.
The compensation logic alters the number of 32.768 kHz clock cycles it takes for the
prescaler register to overflow and increment the time seconds counter. The time
compensation value is used to adjust the number of clock cycles between -127 and +128.
Cycles are added or subtracted from the prescaler register when the prescaler register
equals 0x3FFF and then increments. The compensation interval is used to adjust the
frequency at which the time compensation value is used, that is, from once a second to
once every 256 seconds.
Updates to the time compensation register will not take effect until the next time the time
seconds register increments and provided the previous compensation interval has expired.
When the compensation interval is set to other than once a second then the compensation
is applied in the first second interval and the remaining second intervals receive no
compensation.
Compensation is disabled by configuring the time compensation register to zero.
33.3.4 Time alarm
The time alarm register, SR[TAF], and IER[TAIE] allow the RTC to generate an
interrupt at a predefined time. The 32-bit time alarm register is compared with the 32-bit
time seconds register each time it increments. The SR[TAF] will set when the time alarm
register equals the time seconds register and the time seconds register increments.
The time alarm flag is cleared by writing the time alarm register. This will usually be the
next alarm value, although writing a value that is less than the time seconds register, such
as zero, will prevent the time alarm flag from setting again. The time alarm flag cannot
otherwise be disabled, although the interrupt it generates is enabled or disabled by
IER[TAIE].
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Chapter 33 Real Time Clock (RTC)
33.3.5 Update mode
The Update Mode bit in the Control register (CR[UM]) configures software write access
to the Time Counter Enable (SR[TCE]) bit. When CR[UM] is clear, SR[TCE] can be
written only when the LR[SRL] bit is set. When CR[UM] is set, the SR[TCE] can also be
written when SR[TCE] is clear or when SR[TIF] or SR[TOF] are set. This allows the
time seconds and prescaler registers to be initialized whenever time is invalidated, while
preventing the time seconds and prescaler registers from being changed on the fly. When
LR[SRL] is set, CR[UM] has no effect on SR[TCE].
33.3.6 Register lock
The lock register can be used to block write accesses to certain registers until the next
POR or software reset. Locking the control register will disable the software reset.
Locking the lock register will block future updates to the lock register.
Write accesses to a locked register are ignored and do not generate a bus error.
33.3.7 Interrupt
The RTC interrupt is asserted whenever a status flag and the corresponding interrupt
enable bit are both set. It is always asserted on POR, and software reset. The RTC
interrupt is enabled at the chip level by enabling the chip-specific RTC clock gate control
bit. The RTC interrupt can be used to wakeup the chip from any low-power mode.
The optional RTC seconds interrupt is an edge-sensitive interrupt with a dedicated
interrupt vector that is generated once a second and requires no software overhead (there
is no corresponding status flag to clear). It is enabled in the RTC by the time seconds
interrupt enable bit and enabled at the chip level by setting the chip-specific RTC clock
gate control bit. This interrupt is optional and may not be implemented on all devices.
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Chapter 34
Serial Peripheral Interface (SPI)
34.1 Introduction
NOTE
For the chip-specific implementation details of this module's
instances see the chip configuration information.
The serial peripheral interface (SPI) module provides for full-duplex, synchronous, serial
communication between the MCU and peripheral devices. These peripheral devices can
include other microcontrollers, analog-to-digital converters, shift registers, sensors, and
memories, among others.
The SPI runs at a baud rate up to the bus clock divided by two in master mode and up to
the bus clock divided by four in slave mode. Software can poll the status flags, or SPI
operation can be interrupt driven.
NOTE
For the actual maximum SPI baud rate, refer to the Chip
Configuration details and to the device’s Data Sheet.
The SPI also includes a hardware match feature for the receive data buffer.
The SPI includes an internal DMA interface to support continuous SPI transmission
through an on-chip DMA controller instead of through the CPU. This feature decreases
CPU loading, allowing CPU time to be used for other work.
34.1.1 Features
The SPI includes these distinctive features:
• Master mode or slave mode operation
• Full-duplex or single-wire bidirectional mode
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Introduction
• Programmable transmit bit rate
• Double-buffered transmit and receive data register
• Serial clock phase and polarity options
• Slave select output
• Mode fault error flag with CPU interrupt capability
• Control of SPI operation during wait mode
• Selectable MSB-first or LSB-first shifting
• Receive data buffer hardware match feature
• Support transmission of both Transmit and Receive by DMA
34.1.2 Modes of Operation
The SPI functions in three modes, run, wait, and stop.
• Run Mode
This is the basic mode of operation.
• Wait Mode
SPI operation in wait mode is a configurable low power mode, controlled by the
SPISWAI bit located in the SPIx_C2 register. In wait mode, if the SPISWAI bit is
clear, the SPI operates like in Run Mode. If the SPISWAI bit is set, the SPI goes into
a power conservative state, with the SPI clock generation turned off. If the SPI is
configured as a master, any transmission in progress stops, but is resumed after CPU
enters run mode. If the SPI is configured as a slave, reception and transmission of a
byte continues, so that the slave stays synchronized to the master.
• Stop Mode
To reduce power consumption, the SPI is inactive in stop modes where the peripheral
bus clock is stopped but internal logic states are retained. If the SPI is configured as a
master, any transmission in progress stops, but is resumed after the CPU enters run
mode. If the SPI is configured as a slave, reception and transmission of a data
continues, so that the slave stays synchronized to the master.
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Chapter 34 Serial Peripheral Interface (SPI)
The SPI is completely disabled in stop modes where the peripheral bus clock is
stopped and internal logic states are not retained. When the CPU wakes from these
stop modes, all SPI register content is reset.
Detailed descriptions of operating modes appear in Low Power Mode Options.
34.1.3 Block Diagrams
This section includes block diagrams showing SPI system connections, the internal
organization of the SPI module, and the SPI clock dividers that control the master mode
bit rate.
34.1.3.1 SPI System Block Diagram
The following figure shows the SPI modules of two MCUs connected in a master-slave
arrangement. The master device initiates all SPI data transfers. During a transfer, the
master shifts data out (on the MOSI pin) to the slave while simultaneously shifting data
in (on the MISO pin) from the slave. The transfer effectively exchanges the data that was
in the SPI shift registers of the two SPI systems. The SPSCK signal is a clock output
from the master and an input to the slave. The slave device must be selected by a low
level on the slave select input (SS pin). In this system, the master device has configured
its SS pin as an optional slave select output.
SLAVE
MASTER
MOSI
MOSI
SPI SHIFTER
8 BITS
SPI SHIFTER
MISO
SPSCK
CLOCK
GENERATOR
SS
MISO
8 BITS
SPSCK
SS
Figure 34-1. SPI System Connections
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34.1.3.2 SPI Module Block Diagram
The following is a block diagram of the SPI module. The central element of the SPI is the
SPI shift register. Data is written to the double-buffered transmitter (write to SPIx_D) and
gets transferred to the SPI shift register at the start of a data transfer. After shifting in 8
bits of data, the data is transferred into the double-buffered receiver where it can be read
from SPIx_D. Pin multiplexing logic controls connections between MCU pins and the
SPI module.
When the SPI is configured as a master, the clock output is routed to the SPSCK pin, the
shifter output is routed to MOSI, and the shifter input is routed from the MISO pin.
When the SPI is configured as a slave, the SPSCK pin is routed to the clock input of the
SPI, the shifter output is routed to MISO, and the shifter input is routed from the MOSI
pin.
In the external SPI system, simply connect all SPSCK pins to each other, all MISO pins
together, and all MOSI pins together. Peripheral devices often use slightly different
names for these pins.
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Chapter 34 Serial Peripheral Interface (SPI)
PIN CONTROL
M
SPE
MOSI
(MOMI)
S
Tx BUFFER (WRITE SPIxD)
ENABLE
SPI SYSTEM
M
SPI SHIFT REGISTER
SHIFT
OUT
SHIFT
IN
Rx BUFFER (READ SPIxD)
MISO
(SISO)
S
SPC0
BIDIROE
LSBFE
SHIFT
DIRECTION
Rx BUFFER Tx BUFFER
SHIFT
FULL
CLOCK
EMPTY
MASTER CLOCK
BUS RATE
CLOCK
CLOCK
LOGIC
SPIBR
CLOCK GENERATOR
MSTR
SLAVE CLOCK
MASTER/SLAVE
M
SPSCK
S
MASTER/
SLAVE
MODE SELECT
MODSSOE
MODE FAULT
DETECTION
RX DMA DONE
SPRF
Rx_DMA REQ
8-BIT COMPARATOR
RXDMAE
SPIxM
TX DMA DONE
SS
SPMF
SPMIE
SPTEF
TX DMA REQ
TXDMAE
SPTIE
MODF
SPIE
INTERRUPT
REQUEST
Figure 34-2. SPI Module Block Diagram without FIFO
34.2 External Signal Description
The SPI optionally shares four port pins. The function of these pins depends on the
settings of SPI control bits. When the SPI is disabled (SPE = 0), these four pins revert to
other functions that are not controlled by the SPI (based on chip configuration).
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External Signal Description
34.2.1 SPSCK — SPI Serial Clock
When the SPI is enabled as a slave, this pin is the serial clock input. When the SPI is
enabled as a master, this pin is the serial clock output.
34.2.2 MOSI — Master Data Out, Slave Data In
When the SPI is enabled as a master and SPI pin control zero (SPC0) is 0 (not
bidirectional mode), this pin is the serial data output. When the SPI is enabled as a slave
and SPC0 is 0, this pin is the serial data input. If SPC0 is 1 to select single-wire
bidirectional mode, and master mode is selected, this pin becomes the bidirectional data
I/O pin (MOMI). Also, the bidirectional mode output enable bit determines whether the
pin acts as an input (BIDIROE is 0) or an output (BIDIROE is 1). If SPC0 is 1 and slave
mode is selected, this pin is not used by the SPI and reverts to other functions (based on
chip configuration).
34.2.3 MISO — Master Data In, Slave Data Out
When the SPI is enabled as a master and SPI pin control zero (SPC0) is 0 (not
bidirectional mode), this pin is the serial data input. When the SPI is enabled as a slave
and SPC0 is 0, this pin is the serial data output. If SPC0 is 1 to select single-wire
bidirectional mode, and slave mode is selected, this pin becomes the bidirectional data I/
O pin (SISO), and the bidirectional mode output enable bit determines whether the pin
acts as an input (BIDIROE is 0) or an output (BIDIROE is 1). If SPC0 is 1 and master
mode is selected, this pin is not used by the SPI and reverts to other functions (based on
chip configuration).
34.2.4 SS — Slave Select
When the SPI is enabled as a slave, this pin is the low-true slave select input. When the
SPI is enabled as a master and mode fault enable is off (MODFEN is 0), this pin is not
used by the SPI and reverts to other functions (based on chip configuration). When the
SPI is enabled as a master and MODFEN is 1, the slave select output enable bit
determines whether this pin acts as the mode fault input (SSOE is 0) or as the slave select
output (SSOE is 1).
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Chapter 34 Serial Peripheral Interface (SPI)
34.3 Memory Map and Register Descriptions
The SPI has 8-bit registers to select SPI options, to control baud rate, to report SPI status,
to hold an SPI data match value, and for transmit/receive data.
SPI memory map
Address
offset (hex)
Absolute
address
(hex)
Width
Access
(in bits)
Register name
Reset value
Section/
page
0
4007_6000 SPI control register 1 (SPI0_C1)
8
R/W
04h
34.3.1/561
1
4007_6001 SPI control register 2 (SPI0_C2)
8
R/W
00h
34.3.2/563
2
4007_6002 SPI baud rate register (SPI0_BR)
8
R/W
00h
34.3.3/564
3
4007_6003 SPI status register (SPI0_S)
8
R
20h
34.3.4/565
5
4007_6005 SPI data register (SPI0_D)
8
R/W
00h
34.3.5/566
7
4007_6007 SPI match register (SPI0_M)
8
R/W
00h
34.3.6/567
34.3.1 SPI control register 1 (SPIx_C1)
This read/write register includes the SPI enable control, interrupt enables, and
configuration options.
Address: 4007_6000h base + 0h offset = 4007_6000h
Bit
Read
Write
Reset
7
6
5
4
3
2
1
0
SPIE
SPE
SPTIE
MSTR
CPOL
CPHA
SSOE
LSBFE
0
0
0
0
0
1
0
0
SPI0_C1 field descriptions
Field
7
SPIE
Description
SPI interrupt enable: for SPRF and MODF
This bit enables the interrupt for SPI receive buffer full (SPRF) and mode fault (MODF) events.
0
1
6
SPE
Interrupts from SPRF and MODF are inhibited—use polling
Request a hardware interrupt when SPRF or MODF is 1
SPI system enable
This bit enables the SPI system and dedicates the SPI port pins to SPI system functions. If SPE is
cleared, the SPI is disabled and forced into an idle state, and all status bits in the S register are reset.
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SPI0_C1 field descriptions (continued)
Field
Description
0
1
5
SPTIE
SPI transmit interrupt enable
This is the interrupt enable bit for SPI transmit buffer empty (SPTEF). An interrupt occurs when the SPI
transmit buffer is empty (SPTEF is set).
0
1
4
MSTR
Interrupts from SPTEF inhibited (use polling)
When SPTEF is 1, hardware interrupt requested
Master/slave mode select
This bit selects master or slave mode operation.
0
1
3
CPOL
SPI system inactive
SPI system enabled
SPI module configured as a slave SPI device
SPI module configured as a master SPI device
Clock polarity
This bit selects an inverted or non-inverted SPI clock. To transmit data between SPI modules, the SPI
modules must have identical CPOL values.
This bit effectively places an inverter in series with the clock signal either from a master SPI device or to a
slave SPI device. Refer to the description of “SPI Clock Formats” for details.
0
1
2
CPHA
Clock phase
This bit selects one of two clock formats for different kinds of synchronous serial peripheral devices. Refer
to the description of “SPI Clock Formats” for details.
0
1
1
SSOE
Active-high SPI clock (idles low)
Active-low SPI clock (idles high)
First edge on SPSCK occurs at the middle of the first cycle of a data transfer
First edge on SPSCK occurs at the start of the first cycle of a data transfer
Slave select output enable
This bit is used in combination with the mode fault enable (MODFEN) bit in the C2 register and the master/
slave (MSTR) control bit to determine the function of the SS pin.
0
1
When MODFEN is 0: In master mode, SS pin function is general-purpose I/O (not SPI). In slave mode,
SS pin function is slave select input.
When MODFEN is 1: In master mode, SS pin function is SS input for mode fault. In slave mode, SS
pin function is slave select input.
When MODFEN is 0: In master mode, SS pin function is general-purpose I/O (not SPI). In slave mode,
SS pin function is slave select input.
When MODFEN is 1: In master mode, SS pin function is automatic SS output. In slave mode: SS pin
function is slave select input.
0
LSBFE
LSB first (shifter direction)
This bit does not affect the position of the MSB and LSB in the data register. Reads and writes of the data
register always have the MSB in bit 7.
0
1
SPI serial data transfers start with most significant bit
SPI serial data transfers start with least significant bit
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Chapter 34 Serial Peripheral Interface (SPI)
34.3.2 SPI control register 2 (SPIx_C2)
This read/write register is used to control optional features of the SPI system. Bit 6 is not
implemented and always reads 0.
Address: 4007_6000h base + 1h offset = 4007_6001h
Bit
Read
Write
Reset
7
6
5
4
3
2
1
0
SPMIE
Reserved
TXDMAE
MODFEN
BIDIROE
RXDMAE
SPISWAI
SPC0
0
0
0
0
0
0
0
0
SPI0_C2 field descriptions
Field
7
SPMIE
Description
SPI match interrupt enable
This is the interrupt enable bit for the SPI receive data buffer hardware match (SPMF) function.
0
1
Interrupts from SPMF inhibited (use polling)
When SPMF is 1, requests a hardware interrupt
6
Reserved
This field is reserved.
Do not write to this reserved bit.
5
TXDMAE
Transmit DMA enable
This bit enables a transmit DMA request. When this bit is set to 1, a transmit DMA request is asserted
when both SPTEF and SPE are set, and the interrupt from SPTEF is disabled.
0
1
4
MODFEN
Master mode-fault function enable
When the SPI is configured for slave mode, this bit has no meaning or effect. (The SS pin is the slave
select input.) In master mode, this bit determines how the SS pin is used. For details, refer to the
description of the SSOE bit in the C1 register.
0
1
3
BIDIROE
Mode fault function disabled, master SS pin reverts to general-purpose I/O not controlled by SPI
Mode fault function enabled, master SS pin acts as the mode fault input or the slave select output
Bidirectional mode output enable
When bidirectional mode is enabled because SPI pin control 0 (SPC0) is set to 1, the BIDIROE bit
determines whether the SPI data output driver is enabled to the single bidirectional SPI I/O pin. Depending
on whether the SPI is configured as a master or a slave, it uses the MOSI (MOMI) or MISO (SISO) pin,
respectively, as the single SPI data I/O pin. When SPC0 is 0, BIDIROE has no meaning or effect.
0
1
2
RXDMAE
DMA request for transmit is disabled and interrupt from SPTEF is allowed
DMA request for transmit is enabled and interrupt from SPTEF is disabled
Output driver disabled so SPI data I/O pin acts as an input
SPI I/O pin enabled as an output
Receive DMA enable
This is the enable bit for a receive DMA request. When this bit is set to 1, a receive DMA request is
asserted when both SPRF and SPE are set, and the interrupt from SPRF is disabled.
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SPI0_C2 field descriptions (continued)
Field
Description
0
1
1
SPISWAI
SPI stop in wait mode
This bit is used for power conservation while the device is in wait mode.
0
1
0
SPC0
DMA request for receive is disabled and interrupt from SPRF is allowed
DMA request for receive is enabled and interrupt from SPRF is disabled
SPI clocks continue to operate in wait mode
SPI clocks stop when the MCU enters wait mode
SPI pin control 0
This bit enables bidirectional pin configurations.
0
SPI uses separate pins for data input and data output (pin mode is normal).
In master mode of operation: MISO is master in and MOSI is master out.
1
In slave mode of operation: MISO is slave out and MOSI is slave in.
SPI configured for single-wire bidirectional operation (pin mode is bidirectional).
In master mode of operation: MISO is not used by SPI; MOSI is master in when BIDIROE is 0 or
master I/O when BIDIROE is 1.
In slave mode of operation: MISO is slave in when BIDIROE is 0 or slave I/O when BIDIROE is 1;
MOSI is not used by SPI.
34.3.3 SPI baud rate register (SPIx_BR)
Use this register to set the prescaler and bit rate divisor for an SPI master. This register
may be read or written at any time.
Address: 4007_6000h base + 2h offset = 4007_6002h
Bit
7
Read
Write
Reset
0
0
6
5
4
3
2
SPPR[2:0]
0
0
1
0
0
0
SPR[3:0]
0
0
0
SPI0_BR field descriptions
Field
Description
7
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
6–4
SPPR[2:0]
SPI baud rate prescale divisor
This 3-bit field selects one of eight divisors for the SPI baud rate prescaler. The input to this prescaler is
the bus rate clock (BUSCLK). The output of this prescaler drives the input of the SPI baud rate divider.
Refer to the description of “SPI Baud Rate Generation” for details.
000
Baud rate prescaler divisor is 1
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Chapter 34 Serial Peripheral Interface (SPI)
SPI0_BR field descriptions (continued)
Field
Description
001
010
011
100
101
110
111
3–0
SPR[3:0]
Baud rate prescaler divisor is 2
Baud rate prescaler divisor is 3
Baud rate prescaler divisor is 4
Baud rate prescaler divisor is 5
Baud rate prescaler divisor is 6
Baud rate prescaler divisor is 7
Baud rate prescaler divisor is 8
SPI baud rate divisor
This 4-bit field selects one of nine divisors for the SPI baud rate divider. The input to this divider comes
from the SPI baud rate prescaler. Refer to the description of “SPI Baud Rate Generation” for details.
0000
0001
0010
0011
0100
0101
0110
0111
1000
All others
Baud rate divisor is 2
Baud rate divisor is 4
Baud rate divisor is 8
Baud rate divisor is 16
Baud rate divisor is 32
Baud rate divisor is 64
Baud rate divisor is 128
Baud rate divisor is 256
Baud rate divisor is 512
Reserved
34.3.4 SPI status register (SPIx_S)
This register contains read-only status bits. Writes have no meaning or effect.
NOTE
Bits 3 through 0 are not implemented and always read 0.
Address: 4007_6000h base + 3h offset = 4007_6003h
Bit
Read
7
6
5
4
SPRF
SPMF
SPTEF
MODF
0
0
1
0
3
2
1
0
0
0
0
Write
Reset
0
0
SPI0_S field descriptions
Field
7
SPRF
Description
SPI read buffer full flag
SPRF is set at the completion of an SPI transfer to indicate that received data may be read from the SPI
data (D) register. When the receive DMA request is disabled (RXDMAE is 0), SPRF is cleared by reading
SPRF while it is set and then reading the SPI data register. When the receive DMA request is enabled
(RXDMAE is 1), SPRF is automatically cleared when the DMA transfer for the receive DMA request is
completed (RX DMA Done is asserted).
Table continues on the next page...
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SPI0_S field descriptions (continued)
Field
Description
0
1
6
SPMF
Data available in the receive data buffer
SPI match flag
SPMF is set after SPRF is 1 when the value in the receive data buffer matches the value in the M register.
To clear the flag, read SPMF when it is set and then write a 1 to it.
0
1
5
SPTEF
No data available in the receive data buffer
Value in the receive data buffer does not match the value in the M register
Value in the receive data buffer matches the value in the M register
SPI transmit buffer empty flag
This bit is set when the transmit data buffer is empty. When the transmit DMA request is disabled
(TXDMAE is 0), SPTEF is cleared by reading the S register with SPTEF set and then writing a data value
to the transmit buffer at D. The S register must be read with SPTEF set to 1 before writing data to the D
register; otherwise, the D write is ignored. When the transmit DMA request is enabled (TXDMAE is 1),
SPTEF is automatically cleared when the DMA transfer for the transmit DMA request is completed (TX
DMA Done is asserted). SPTEF is automatically set when all data from the transmit buffer transfers into
the transmit shift register. For an idle SPI, data written to D is transferred to the shifter almost immediately
so that SPTEF is set within two bus cycles, allowing a second set of data to be queued into the transmit
buffer. After completion of the transfer of the data in the shift register, the queued data from the transmit
buffer automatically moves to the shifter, and SPTEF is set to indicate that room exists for new data in the
transmit buffer. If no new data is waiting in the transmit buffer, SPTEF simply remains set and no data
moves from the buffer to the shifter.
If a transfer does not stop, the last data that was transmitted is sent out again.
0
1
4
MODF
SPI transmit buffer empty
Master mode fault flag
MODF is set if the SPI is configured as a master and the slave select input goes low, indicating some
other SPI device is also configured as a master. The SS pin acts as a mode fault error input only when
MSTR is 1, MODFEN is 1, and SSOE is 0; otherwise, MODF will never be set. MODF is cleared by
reading MODF while it is 1 and then writing to the SPI control register 1 (C1).
0
1
3–0
Reserved
SPI transmit buffer not empty
No mode fault error
Mode fault error detected
This field is reserved.
This read-only field is reserved and always has the value 0.
34.3.5 SPI data register (SPIx_D)
This register is both the input and output register for SPI data. A write to the register
writes to the transmit data buffer, allowing data to be queued and transmitted.
When the SPI is configured as a master, data queued in the transmit data buffer is
transmitted immediately after the previous transmission has completed.
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The SPTEF bit in the S register indicates when the transmit data buffer is ready to accept
new data. When the transmit DMA request is disabled (TXDMAE is 0): The S register
must be read when SPTEF is set before writing to the SPI data register; otherwise, the
write is ignored. When the transmit DMA request is enabled (TXDMAE is 1) when
SPTEF is set, the SPI data register can be written automatically by DMA without reading
the S register first.
Data may be read from the SPI data register any time after SPRF is set and before another
transfer is finished. Failure to read the data out of the receive data buffer before a new
transfer ends causes a receive overrun condition, and the data from the new transfer is
lost. The new data is lost because the receive buffer still held the previous character and
was not ready to accept the new data. There is no indication for a receive overrun
condition, so the application system designer must ensure that previous data has been
read from the receive buffer before a new transfer is initiated.
Address: 4007_6000h base + 5h offset = 4007_6005h
Bit
Read
Write
Reset
7
6
5
4
3
2
1
0
0
0
0
0
Bits[7:0]
0
0
0
0
SPI0_D field descriptions
Field
7–0
Bits[7:0]
Description
Data (low byte)
34.3.6 SPI match register (SPIx_M)
This register contains the hardware compare value. When the value received in the SPI
receive data buffer equals this hardware compare value, the SPI match flag (SPMF) sets.
Address: 4007_6000h base + 7h offset = 4007_6007h
Bit
Read
Write
Reset
7
6
5
4
3
2
1
0
0
0
0
0
Bits[7:0]
0
0
0
0
SPI0_M field descriptions
Field
7–0
Bits[7:0]
Description
Hardware compare value (low byte)
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Functional Description
34.4 Functional Description
This section provides the functional description of the module.
34.4.1 General
The SPI system is enabled by setting the SPI enable (SPE) bit in SPI Control Register 1.
While the SPE bit is set, the four associated SPI port pins are dedicated to the SPI
function as:
• Slave select (SS)
• Serial clock (SPSCK)
• Master out/slave in (MOSI)
• Master in/slave out (MISO)
An SPI transfer is initiated in the master SPI device by reading the SPI status register
(SPIx_S) when SPTEF = 1 and then writing data to the transmit data buffer (write to
SPIxD ). When a transfer is complete, received data is moved into the receive data buffer.
The SPIxD register acts as the SPI receive data buffer for reads and as the SPI transmit
data buffer for writes.
The clock phase control bit (CPHA) and clock polarity control bit (CPOL) in the SPI
Control Register 1 (SPIx_C1) select one of four possible clock formats to be used by the
SPI system. The CPOL bit simply selects a non-inverted or inverted clock. The CPHA bit
is used to accommodate two fundamentally different protocols by sampling data on odd
numbered SPSCK edges or on even numbered SPSCK edges.
The SPI can be configured to operate as a master or as a slave. When the MSTR bit in
SPI Control Register 1 is set, master mode is selected; when the MSTR bit is clear, slave
mode is selected.
34.4.2 Master Mode
The SPI operates in master mode when the MSTR bit is set. Only a master SPI module
can initiate transmissions. A transmission begins by reading the SPIx_S register while
SPTEF = 1 and writing to the master SPI data registers. If the shift register is empty, the
byte immediately transfers to the shift register. The data begins shifting out on the MOSI
pin under the control of the serial clock.
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• SPSCK
• The SPR3, SPR2, SPR1, and SPR0 baud rate selection bits in conjunction with
the SPPR2, SPPR1, and SPPR0 baud rate preselection bits in the SPI Baud Rate
register control the baud rate generator and determine the speed of the
transmission. The SPSCK pin is the SPI clock output. Through the SPSCK pin,
the baud rate generator of the master controls the shift register of the slave
peripheral.
• MOSI, MISO pin
• In master mode, the function of the serial data output pin (MOSI) and the serial
data input pin (MISO) is determined by the SPC0 and BIDIROE control bits.
• SS pin
• If MODFEN and SSOE bit are set, the SS pin is configured as slave select
output. The SS output becomes low during each transmission and is high when
the SPI is in idle state. If MODFEN is set and SSOE is cleared, the SS pin is
configured as input for detecting mode fault error. If the SS input becomes low
this indicates a mode fault error where another master tries to drive the MOSI
and SPSCK lines. In this case, the SPI immediately switches to slave mode by
clearing the MSTR bit and also disables the slave output buffer MISO (or SISO
in bidirectional mode). As a result, all outputs are disabled, and SPSCK, MOSI
and MISO are inputs. If a transmission is in progress when the mode fault
occurs, the transmission is aborted and the SPI is forced into idle state. This
mode fault error also sets the mode fault (MODF) flag in the SPI Status Register
(SPIx_S). If the SPI interrupt enable bit (SPIE) is set when the MODF flag gets
set, then an SPI interrupt sequence is also requested. When a write to the SPI
Data Register in the master occurs, there is a half SPSCK-cycle delay. After the
delay, SPSCK is started within the master. The rest of the transfer operation
differs slightly, depending on the clock format specified by the SPI clock phase
bit, CPHA, in SPI Control Register 1 (see SPI Clock Formats).
Note
A change of the bits CPOL, CPHA, SSOE, LSBFE, MODFEN,
SPC0, BIDIROE with SPC0 set, SPPR2-SPPR0 and SPR3SPR0 in master mode abort a transmission in progress and force
the SPI into idle state. The remote slave cannot detect this,
therefore the master has to ensure that the remote slave is set
back to idle state.
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Functional Description
34.4.3 Slave Mode
The SPI operates in slave mode when the MSTR bit in SPI Control Register1 is clear.
• SPSCK
In slave mode, SPSCK is the SPI clock input from the master.
• MISO, MOSI pin
In slave mode, the function of the serial data output pin (MISO) and serial data input
pin (MOSI) is determined by the SPC0 bit and BIDIROE bit in SPI Control Register
2.
• SS pin
The SS pin is the slave select input. Before a data transmission occurs, the SS pin of
the slave SPI must be low. SS must remain low until the transmission is complete. If
SS goes high, the SPI is forced into an idle state.
The SS input also controls the serial data output pin. If SS is high (not selected), the
serial data output pin is high impedance. If SS is low, the first bit in the SPI Data
Register is driven out of the serial data output pin. Also, if the slave is not selected
(SS is high), then the SPSCK input is ignored and no internal shifting of the SPI shift
register occurs.
Although the SPI is capable of duplex operation, some SPI peripherals are capable of
only receiving SPI data in a slave mode. For these simpler devices, there is no serial
data out pin.
Note
When peripherals with duplex capability are used, take care not
to simultaneously enable two receivers whose serial outputs
drive the same system slave's serial data output line.
As long as no more than one slave device drives the system slave's serial data output line,
it is possible for several slaves to receive the same transmission from a master, although
the master would not receive return information from all of the receiving slaves.
If the CPHA bit in SPI Control Register 1 is clear, odd numbered edges on the SPSCK
input cause the data at the serial data input pin to be latched. Even numbered edges cause
the value previously latched from the serial data input pin to shift into the LSB or MSB
of the SPI shift register, depending on the LSBFE bit.
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If the CPHA bit is set, even numbered edges on the SPSCK input cause the data at the
serial data input pin to be latched. Odd numbered edges cause the value previously
latched from the serial data input pin to shift into the LSB or MSB of the SPI shift
register, depending on the LSBFE bit.
When CPHA is set, the first edge is used to get the first data bit onto the serial data output
pin. When CPHA is clear and the SS input is low (slave selected), the first bit of the SPI
data is driven out of the serial data output pin. After the eighth shift, the transfer is
considered complete and the received data is transferred into the SPI Data register. To
indicate transfer is complete, the SPRF flag in the SPI Status Register is set.
Note
A change of the bits BIDIROE with SPC0 set, CPOL, CPHA,
SSOE, LSBFE, MODFEN, and SPC0 in slave mode will
corrupt a transmission in progress and must be avoided.
34.4.4 SPI Transmission by DMA
SPI supports both Transmit and Receive by DMA. The basic flow of SPI transmission by
DMA is as below.
RESET
Configure DMA Controller
for SPI Transmission
Configure SPI before Transmission
Set TXDMAE/RXDMAE=1 to enable
Transmit/Receive by DMA
Set SPE=1 to start transmission in
master mode or enable SPI for
transmission in slave moe
Wait for interrupt(s) of DMA Controller
indicating end of SPI transmission
Figure 34-15. Basic Flow of SPI Transmission by DMA
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Functional Description
34.4.4.1 Transmit by DMA
Transmit by DMA is supported only when TXDMAE is set. A transmit DMA request is
asserted when both SPE and SPTEF are set. Then the on-chip DMA controller detects
this request and transfers data from memory into the SPI data register. After that, TX
DMA DONE is asserted to clear SPTEF automatically. This process repeats until all data
for transmission (the number is decided by the configuration register[s] of the DMA
controller) is sent.
After DMA transfers the first byte to the SPI data register, the SPI pushes this data into
the shifter, thereby making SPTEF high again. This generates another DMA request
immediately, but the CPU lacks enough time to service the first DMA interrupt service
request (ISR). The subsequent DMA request is paced at the SPI transfer rate. Manage this
behavior during the first byte transfer through the DMA channel. Write the first byte to
the SPI data register via the CPU. The other bytes are transmitted by the DMA.
RESET
Configure DMA Controller
for SPI transmission
Configure SPI before Transmission
Set SPE=1 to start transmission in
master mode or enable SPI for
transmission in slave mode
Read SPI status register
Write the first byte to SPI data register
via CPU
Set TXDMAE to enable Transmit by
DMA
Wait for interrupt(s) of DMA Controller
indicating end of SPI transmission
Figure 34-16. Recommended startup of SPI transmit by DMA
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34.4.4.2 Receive by DMA
Receive by DMA is supported only when RXDMAE is set. A receive DMA request is
asserted when both SPE and SPRF are set. Then the on-chip DMA controller detects this
request and transfers data from the SPI data register into memory. After that, RX DMA
DONE is asserted to clear SPRF automatically. This process repeats until all data to be
received (the number is decided by configuration register[s] of the DMA controller) is
received or no receive DMA request is generated again because the SPI transmission is
finished.
34.4.5 SPI Clock Formats
To accommodate a wide variety of synchronous serial peripherals from different
manufacturers, the SPI system has a clock polarity (CPOL) bit and a clock phase (CPHA)
control bit to select one of four clock formats for data transfers. CPOL selectively inserts
an inverter in series with the clock. CPHA chooses between two different clock phase
relationships between the clock and data.
The following figure shows the clock formats when CPHA = 1. At the top of the figure,
the eight bit times are shown for reference with bit 1 starting at the first SPSCK edge and
bit 8 ending one-half SPSCK cycle after the eighth SPSCK edge. The MSB first and LSB
first lines show the order of SPI data bits depending on the setting in LSBFE. Both
variations of SPSCK polarity are shown, but only one of these waveforms applies for a
specific transfer, depending on the value in CPOL. The SAMPLE IN waveform applies
to the MOSI input of a slave or the MISO input of a master. The MOSI waveform applies
to the MOSI output pin from a master and the MISO waveform applies to the MISO
output from a slave. The SS OUT waveform applies to the slave select output from a
master (provided MODFEN and SSOE = 1). The master SS output goes to active low
one-half SPSCK cycle before the start of the transfer and goes back high at the end of the
eighth bit time of the transfer. The SS IN waveform applies to the slave select input of a
slave.
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Functional Description
BIT TIME #
(REFERENCE)
1
2
...
6
8
7
SPSCK
(CPOL = 0)
SPSCK
(CPOL = 1)
SAMPLE IN
(MISO OR MOSI)
MOSI
(MASTER OUT)
MSB FIRST
LSB FIRST
BIT 7
BIT 0
BIT 6
BIT 1
...
...
BIT 2
BIT 5
BIT 1
BIT 6
BIT 0
BIT 7
MISO
(SLAVE OUT)
SS OUT
(MASTER)
SS IN
(SLAVE)
Figure 34-17. SPI Clock Formats (CPHA = 1)
When CPHA = 1, the slave begins to drive its MISO output when SS goes to active low,
but the data is not defined until the first SPSCK edge. The first SPSCK edge shifts the
first bit of data from the shifter onto the MOSI output of the master and the MISO output
of the slave. The next SPSCK edge causes both the master and the slave to sample the
data bit values on their MISO and MOSI inputs, respectively. At the third SPSCK edge,
the SPI shifter shifts one bit position which shifts in the bit value that was just sampled,
and shifts the second data bit value out the other end of the shifter to the MOSI and
MISO outputs of the master and slave, respectively.
When CPHA = 1, the slave's SS input is not required to go to its inactive high level
between transfers. In this clock format, a back-to-back transmission can occur, as
follows:
1. A transmission is in progress.
2. A new data byte is written to the transmit buffer before the in-progress transmission
is complete.
3. When the in-progress transmission is complete, the new, ready data byte is
transmitted immediately.
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Between these two successive transmissions, no pause is inserted; the SS pin remains
low.
The following figure shows the clock formats when CPHA = 0. At the top of the figure,
the eight bit times are shown for reference with bit 1 starting as the slave is selected (SS
IN goes low), and bit 8 ends at the last SPSCK edge. The MSB first and LSB first lines
show the order of SPI data bits depending on the setting in LSBFE. Both variations of
SPSCK polarity are shown, but only one of these waveforms applies for a specific
transfer, depending on the value in CPOL. The SAMPLE IN waveform applies to the
MOSI input of a slave or the MISO input of a master. The MOSI waveform applies to the
MOSI output pin from a master and the MISO waveform applies to the MISO output
from a slave. The SS OUT waveform applies to the slave select output from a master
(provided MODFEN and SSOE = 1). The master SS output goes to active low at the start
of the first bit time of the transfer and goes back high one-half SPSCK cycle after the end
of the eighth bit time of the transfer. The SS IN waveform applies to the slave select input
of a slave.
BIT TIME #
(REFERENCE)
1
2
...
6
7
8
SPSCK
(CPOL = 0)
SPSCK
(CPOL = 1)
SAMPLE IN
(MISO OR MOSI)
MOSI
(MASTER OUT)
BIT 7
BIT 0
MSB FIRST
LSB FIRST
BIT 6
BIT 1
...
...
BIT 2
BIT 5
BIT 1
BIT 6
BIT 0
BIT 7
MISO
(SLAVE OUT)
SS OUT
(MASTER)
SS IN
(SLAVE)
Figure 34-18. SPI Clock Formats (CPHA = 0)
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Functional Description
When CPHA = 0, the slave begins to drive its MISO output with the first data bit value
(MSB or LSB depending on LSBFE) when SS goes to active low. The first SPSCK edge
causes both the master and the slave to sample the data bit values on their MISO and
MOSI inputs, respectively. At the second SPSCK edge, the SPI shifter shifts one bit
position which shifts in the bit value that was just sampled and shifts the second data bit
value out the other end of the shifter to the MOSI and MISO outputs of the master and
slave, respectively. When CPHA = 0, the slave's SS input must go to its inactive high
level between transfers.
34.4.6 SPI Baud Rate Generation
As shown in the following figure, the clock source for the SPI baud rate generator is the
bus clock. The three prescale bits (SPPR2:SPPR1:SPPR0) choose a prescale divisor of 1,
2, 3, 4, 5, 6, 7, or 8. The three rate select bits (SPR3:SPR2:SPR1:SPR0) divide the output
of the prescaler stage by 2, 4, 8, 16, 32, 64, 128, 256, or 512 to get the internal SPI master
mode bit-rate clock.
The baud rate generator is activated only when the SPI is in the master mode and a serial
transfer is taking place. In the other cases, the divider is disabled to decrease IDD current.
The baud rate divisor equation is as follows (except those reserved combinations in the
SPI Baud Rate Divisor table).
BaudRateDivisor = (SPPR + 1) × 2(SPR
+ 1)
The baud rate can be calculated with the following equation:
BaudRate = BusClock / BaudRateDivisor
BUS
CLOCK
PRESCALER
BAUD RATE DIVIDER
DIVIDE BY
1, 2, 3, 4, 5, 6, 7, or 8
DIVIDE BY
2, 4, 8, 16, 32, 64, 128,
256, or 512
SPPR2:SPPR1:SPPR0
SPR3:SPR2:SPR1:SPR0
MASTER
SPI
BIT RATE
Figure 34-19. SPI Baud Rate Generation
34.4.7 Special Features
The following section shows the module special features.
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34.4.7.1 SS Output
The SS output feature automatically drives the SS pin low during transmission to select
external devices and drives the SS pin high during idle to deselect external devices. When
the SS output is selected, the SS output pin is connected to the SS input pin of the
external device.
The SS output is available only in master mode during normal SPI operation by asserting
the SSOE and MODFEN bits as shown in the description of the C1[SSOE] bit.
The mode fault feature is disabled while SS output is enabled.
Note
Be careful when using the SS output feature in a multimaster
system because the mode fault feature is not available for
detecting system errors between masters.
34.4.7.2 Bidirectional Mode (MOMI or SISO)
The bidirectional mode is selected when the SPC0 bit is set in SPI Control Register 2 (see
the following table). In this mode, the SPI uses only one serial data pin for the interface
with one or more external devices. The MSTR bit decides which pin to use. The MOSI
pin becomes the serial data I/O (MOMI) pin for the master mode, and the MISO pin
becomes serial data I/O (SISO) pin for the slave mode. The MISO pin in master mode
and MOSI pin in slave mode are not used by the SPI.
Table 34-15. Normal Mode and Bidirectional Mode
When SPE = 1
Master Mode MSTR = 1
Serial Out
Normal Mode
Slave Mode MSTR = 0
MOSI
SPI
SPC0 = 0
Bidirectional Mode
SPC0 = 1
SPI
Serial In
MISO
Serial Out
Serial Out
MOMI
Serial In
SPI
Serial In
MOSI
Serial In
BIDIROE
SPI
MISO
BIDIROE
Serial Out
SISO
The direction of each serial I/O pin depends on the BIDIROE bit. If the pin is configured
as an output, serial data from the shift register is driven out on the pin. The same pin is
also the serial input to the shift register.
The SPSCK is an output for the master mode and an input for the slave mode.
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Functional Description
SS is the input or output for the master mode, and it is always the input for the slave
mode.
The bidirectional mode does not affect SPSCK and SS functions.
Note
In bidirectional master mode, with the mode fault feature
enabled, both data pins MISO and MOSI can be occupied by
the SPI, though MOSI is normally used for transmissions in
bidirectional mode and MISO is not used by the SPI. If a mode
fault occurs, the SPI is automatically switched to slave mode. In
this case, MISO becomes occupied by the SPI and MOSI is not
used. Consider this scenario if the MISO pin is used for another
purpose.
34.4.8 Error Conditions
The SPI module has one error condition: the mode fault error.
34.4.8.1 Mode Fault Error
If the SS input becomes low while the SPI is configured as a master, it indicates a system
error where more than one master may be trying to drive the MOSI and SPSCK lines
simultaneously. This condition is not permitted in normal operation, and it sets the
MODF bit in the SPI status register automatically provided that the MODFEN bit is set.
In the special case where the SPI is in master mode and the MODFEN bit is cleared, the
SS pin is not used by the SPI. In this special case, the mode fault error function is
inhibited and MODF remains cleared. If the SPI system is configured as a slave, the SS
pin is a dedicated input pin. A mode fault error does not occur in slave mode.
If a mode fault error occurs, the SPI is switched to slave mode, with the exception that
the slave output buffer is disabled. So the SPSCK, MISO and MOSI pins are forced to be
high impedance inputs to avoid any possibility of conflict with another output driver. A
transmission in progress is aborted and the SPI is forced into idle state.
If the mode fault error occurs in the bidirectional mode for an SPI system configured in
master mode, the output enable of MOMI (MOSI in bidirectional mode) is cleared if it
was set. No mode fault error occurs in the bidirectional mode for the SPI system
configured in slave mode.
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The mode fault flag is cleared automatically by a read of the SPI Status Register (with
MODF set) followed by a write to SPI Control Register 1. If the mode fault flag is
cleared, the SPI becomes a normal master or slave again.
34.4.9 Low Power Mode Options
This section describes the low power mode options.
34.4.9.1 SPI in Run Mode
In run mode, with the SPI system enable (SPE) bit in the SPI control register clear, the
SPI system is in a low-power, disabled state. SPI registers can still be accessed, but
clocks to the core of this module are disabled.
34.4.9.2 SPI in Wait Mode
SPI operation in wait mode depends upon the state of the SPISWAI bit in SPI Control
Register 2.
• If SPISWAI is clear, the SPI operates normally when the CPU is in wait mode.
• If SPISWAI is set, SPI clock generation ceases and the SPI module enters a power
conservation state when the CPU is in wait mode.
• If SPISWAI is set and the SPI is configured for master, any transmission and
reception in progress stops at wait mode entry. The transmission and reception
resumes when the SPI exits wait mode.
• If SPISWAI is set and the SPI is configured as a slave, any transmission and
reception in progress continues if the SPSCK continues to be driven from the
master. This keeps the slave synchronized to the master and the SPSCK.
If the master transmits data while the slave is in wait mode, the slave continues
to send data consistent with the operation mode at the start of wait mode (that is,
if the slave is currently sending its SPIx_D to the master, it continues to send the
same byte. Otherwise, if the slave is currently sending the last data received byte
from the master, it continues to send each previously received data from the
master byte).
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Functional Description
Note
Care must be taken when expecting data from a master while
the slave is in a wait mode or a stop mode where the peripheral
bus clock is stopped but internal logic states are retained. Even
though the shift register continues to operate, the rest of the SPI
is shut down (that is, an SPRF interrupt is not generated until an
exit from stop or wait mode). Also, the data from the shift
register is not copied into the SPIx_D registers until after the
slave SPI has exited wait or stop mode. An SPRF flag and
SPIx_D copy is only generated if wait mode is entered or exited
during a transmission. If the slave enters wait mode in idle
mode and exits wait mode in idle mode, neither an SPRF nor a
SPIx_D copy occurs.
34.4.9.3 SPI in Stop Mode
Operation in a stop mode where the peripheral bus clock is stopped but internal logic
states are retained depends on the SPI system. The stop mode does not depend on the
SPISWAI bit. Upon entry to this type of stop mode, the SPI module clock is disabled
(held high or low).
• If the SPI is in master mode and exchanging data when the CPU enters the stop
mode, the transmission is frozen until the CPU exits stop mode. After the exit from
stop mode, data to and from the external SPI is exchanged correctly.
• In slave mode, the SPI remains synchronized with the master.
The SPI is completely disabled in a stop mode where the peripheral bus clock is stopped
and internal logic states are not retained. After an exit from this type of stop mode, all
registers are reset to their default values, and the SPI module must be re-initialized.
34.4.10 Reset
The reset values of registers and signals are described in the Memory Map and Register
Descriptions content, which details the registers and their bitfields.
• If a data transmission occurs in slave mode after a reset without a write to SPIx_D,
the transmission consists of "garbage" or the data last received from the master
before the reset.
• Reading from SPIx_D after reset always returns zeros.
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Chapter 34 Serial Peripheral Interface (SPI)
34.4.11 Interrupts
The SPI originates interrupt requests only when the SPI is enabled (the SPE bit in the
SPIx_C1 register is set). The following is a description of how the SPI makes a request
and how the MCU should acknowledge that request. The interrupt vector offset and
interrupt priority are chip dependent.
Four flag bits, three interrupt mask bits, and one interrupt vector are associated with the
SPI system. The SPI interrupt enable mask (SPIE) enables interrupts from the SPI
receiver full flag (SPRF) and mode fault flag (MODF). The SPI transmit interrupt enable
mask (SPTIE) enables interrupts from the SPI transmit buffer empty flag (SPTEF). The
SPI match interrupt enable mask bit (SPIMIE) enables interrupts from the SPI match flag
(SPMF). When one of the flag bits is set, and the associated interrupt mask bit is set, a
hardware interrupt request is sent to the CPU. If the interrupt mask bits are cleared,
software can poll the associated flag bits instead of using interrupts. The SPI interrupt
service routine (ISR) should check the flag bits to determine which event caused the
interrupt. The service routine should also clear the flag bit(s) before returning from the
ISR (usually near the beginning of the ISR).
34.4.11.1 MODF
MODF occurs when the master detects an error on the SS pin. The master SPI must be
configured for the MODF feature (see the description of the C1[SSOE] bit). Once MODF
is set, the current transfer is aborted and the master (MSTR) bit in the SPIx_C1 register
resets to 0.
The MODF interrupt is reflected in the status register's MODF flag. Clearing the flag also
clears the interrupt. This interrupt stays active while the MODF flag is set. MODF has an
automatic clearing process that is described in the SPI Status Register.
34.4.11.2 SPRF
SPRF occurs when new data has been received and copied to the SPI receive data buffer.
After SPRF is set, it does not clear until it is serviced. SPRF has an automatic clearing
process that is described in the SPI Status Register details. If the SPRF is not serviced
before the end of the next transfer (that is, SPRF remains active throughout another
transfer), the subsequent transfers are ignored and no new data is copied into the Data
register.
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Initialization/Application Information
34.4.11.3 SPTEF
SPTEF occurs when the SPI transmit buffer is ready to accept new data.
After SPTEF is set, it does not clear until it is serviced. SPTEF has an automatic clearing
process that is described in the SPI Status Register details.
34.4.11.4 SPMF
SPMF occurs when the data in the receive data buffer is equal to the data in the SPI
match register.
34.4.11.5 Asynchronous interrupt in low power modes
When the CPU is in wait mode or stop mode and the SPI module receives a transmission,
the SPI module can generate an asynchronous interrupt to wake the CPU from the low
power mode. The module generates the asynchronous interrupt only when all of the
following conditions apply:
1. The C1[SPIE] bit is set to 1.
2. The CPU is in wait mode—in which case the C2[SPISWAI] bit must be 1—or in
stop mode where the peripheral bus clock is stopped but internal logic states are
retained.
3. The SPI module is in slave mode.
4. The received transmission ends.
After the interrupt wakes the CPU and the peripheral bus clock is active again, the SPI
module copies the received data from the shifter into the Data register and generates flags
or DMA request signals. During the wakeup phase, a continuous transmission from a
master would destroy the first received data.
34.5 Initialization/Application Information
This section discusses an example of how to initialize and use the SPI.
34.5.1 Initialization Sequence
Before the SPI module can be used for communication, an initialization procedure must
be carried out, as follows:
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Chapter 34 Serial Peripheral Interface (SPI)
1. Update control register 1 (SPIx_C1) to enable the SPI and to control interrupt
enables. This register also sets the SPI as master or slave, determines clock phase and
polarity, and configures the main SPI options.
2. Update control register 2 (SPIx_C2) to enable additional SPI functions such as the
SPI match interrupt feature, the master mode-fault function, and bidirectional mode
output as well as to control and other optional features.
3. Update the baud rate register (SPIx_BR) to set the prescaler and bit rate divisor for
an SPI master.
4. Update the hardware match register (SPIx_M) with the value to be compared to the
receive data register for triggering an interrupt if hardware match interrupts are
enabled.
5. In the master, read SPIx_S while SPTEF = 1, and then write to the transmit data
register (SPIx_D) to begin transfer.
34.5.2 Pseudo-Code Example
In this example, the SPI module is set up for master mode with only hardware match
interrupts enabled. The SPI runs at a maximum baud rate of bus clock divided by 2.
Clock phase and polarity are set for an active-high SPI clock where the first edge on
SPSCK occurs at the start of the first cycle of a data transfer.
SPIx_C1=0x54(%01010100)
Bit 7
SPIE
=
0
Disables receive and mode fault interrupts
Bit 6
SPE
=
1
Enables the SPI system
Bit 5
SPTIE
=
0
Disables SPI transmit interrupts
Bit 4
MSTR
=
1
Sets the SPI module as a master SPI device
Bit 3
CPOL
=
0
Configures SPI clock as active-high
Bit 2
CPHA
=
1
First edge on SPSCK at start of first data transfer cycle
Bit 1
SSOE
=
0
Determines SS pin function when mode fault enabled
Bit 0
LSBFE
=
0
SPI serial data transfers start with most significant bit
SPMIE
=
1
SPI hardware match interrupt enabled
=
0
Unimplemented
SPIx_C2 = 0x80(%10000000)
Bit 7
Bit 6
Bit 5
TXDMAE
=
0
DMA request disabled
Bit 4
MODFEN
=
0
Disables mode fault function
Bit 3
BIDIROE
=
0
SPI data I/O pin acts as input
Table continues on the next page...
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Initialization/Application Information
SPIx_C2 = 0x80(%10000000)
Bit 2
RXDMAE
=
0
DMA request disabled
Bit 1
SPISWAI
=
0
SPI clocks operate in wait mode
Bit 0
SPC0
=
0
uses separate pins for data input and output
Bit 7
=
0
Reserved
Bit 6:4
=
000
Sets prescale divisor to 1
Bit 3:0
=
0000 Sets baud rate divisor to 2
SPIx_BR = 0x00(%00000000)
SPIx_S = 0x00(%00000000)
Bit 7
SPRF
=
0
Flag is set when receive data buffer is full
Bit 6
SPMF
=
0
Flag is set when SPIx_M = receive data buffer
Bit 5
SPTEF
=
0
Flag is set when transmit data buffer is empty
Bit 4
MODF
=
0
Mode fault flag for master mode
=
0
Reserved
Bit 3:0
SPIx_M = 0xXX
Holds bits 0–7 of the hardware match buffer.
SPIx_D = 0xxx
Holds bits 0–7 of the data to be transmitted by the transmit buffer and received by the receive buffer.
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Chapter 34 Serial Peripheral Interface (SPI)
RESET
INITIALIZE SPI
SPIxC1 = 0x54
SPIxC2 = 0x80
SPIxBR = 0x00
YES
SPTEF = 1
?
NO
YES
WRITE TO
SPIxD
SPRF = 1
?
NO
YES
READ
SPIxD
SPMF = 1
?
NO
YES
READ SPMF WHILE SET
TO CLEAR FLAG,
THEN WRITE A 1 TO IT
CONTINUE
Figure 34-20. Initialization Flowchart Example for SPI Master Device
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Initialization/Application Information
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Chapter 35
Inter-Integrated Circuit (I2C)
35.1 Introduction
NOTE
For the chip-specific implementation details of this module's
instances see the chip configuration information.
The inter-integrated circuit (I2C, I2C, or IIC) module provides a method of
communication between a number of devices. The interface is designed to operate up to
100 kbit/s with maximum bus loading and timing. The I2C device is capable of operating
at higher baud rates, up to a maximum of clock/20, with reduced bus loading. The
maximum communication length and the number of devices that can be connected are
limited by a maximum bus capacitance of 400 pF. The I2C module also complies with
the System Management Bus (SMBus) Specification, version 2.
35.1.1 Features
The I2C module has the following features:
•
•
•
•
•
•
•
•
•
•
•
•
Compatible with The I2C-Bus Specification
Multimaster operation
Software programmable for one of 64 different serial clock frequencies
Software-selectable acknowledge bit
Interrupt-driven byte-by-byte data transfer
Arbitration-lost interrupt with automatic mode switching from master to slave
Calling address identification interrupt
START and STOP signal generation and detection
Repeated START signal generation and detection
Acknowledge bit generation and detection
Bus busy detection
General call recognition
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Introduction
•
•
•
•
•
•
10-bit address extension
Support for System Management Bus (SMBus) Specification, version 2
Programmable glitch input filter
Low power mode wakeup on slave address match
Range slave address support
DMA support
35.1.2 Modes of operation
The I2C module's operation in various low power modes is as follows:
• Run mode: This is the basic mode of operation. To conserve power in this mode,
disable the module.
• Wait mode: The module continues to operate when the core is in Wait mode and can
provide a wakeup interrupt.
• Stop mode: The module is inactive in Stop mode for reduced power consumption,
except that address matching is enabled in Stop mode. The STOP instruction does
not affect the I2C module's register states.
35.1.3 Block diagram
The following figure is a functional block diagram of the I2C module.
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Chapter 35 Inter-Integrated Circuit (I2C)
Address
Module Enable
Write/Read
Interrupt
ADDR_DECODE
DATA_MUX
CTRL_REG FREQ_REG ADDR_REG
STATUS_REG
DATA_REG
Input
Sync
START
STOP
Arbitration
Control
Clock
Control
In/Out
Data
Shift
Register
Address
Compare
SDA
SCL
Figure 35-1. I2C Functional block diagram
35.2 I2C signal descriptions
The signal properties of I2C are shown in the following table.
Table 35-1. I2C signal descriptions
Signal
SCL
SDA
Description
I/O
Bidirectional serial clock line of the
Bidirectional serial data line of the
I2C
I2C
system.
system.
I/O
I/O
35.3 Memory map and register descriptions
This section describes in detail all I2C registers accessible to the end user.
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Memory map and register descriptions
I2C memory map
Absolute
address
(hex)
Width
Access
(in bits)
Register name
Reset value
Section/
page
4006_6000
I2C Address Register 1 (I2C0_A1)
8
R/W
00h
35.3.1/590
4006_6001
I2C Frequency Divider register (I2C0_F)
8
R/W
00h
35.3.2/591
4006_6002
I2C Control Register 1 (I2C0_C1)
8
R/W
00h
35.3.3/592
4006_6003
I2C Status register (I2C0_S)
8
R/W
80h
35.3.4/593
4006_6004
I2C Data I/O register (I2C0_D)
8
R/W
00h
35.3.5/595
4006_6005
I2C Control Register 2 (I2C0_C2)
8
R/W
00h
35.3.6/596
4006_6006
I2C Programmable Input Glitch Filter register (I2C0_FLT)
8
R/W
00h
35.3.7/597
4006_6007
I2C Range Address register (I2C0_RA)
8
R/W
00h
35.3.8/598
4006_6008
I2C SMBus Control and Status register (I2C0_SMB)
8
R/W
00h
35.3.9/599
4006_6009
I2C Address Register 2 (I2C0_A2)
8
R/W
C2h
35.3.10/
600
4006_600A
I2C SCL Low Timeout Register High (I2C0_SLTH)
8
R/W
00h
35.3.11/
601
4006_600B
I2C SCL Low Timeout Register Low (I2C0_SLTL)
8
R/W
00h
35.3.12/
601
35.3.1 I2C Address Register 1 (I2Cx_A1)
This register contains the slave address to be used by the I2C module.
Address: 4006_6000h base + 0h offset = 4006_6000h
Bit
Read
Write
Reset
7
6
5
4
3
2
1
AD[7:1]
0
0
0
0
0
0
0
0
0
0
I2Cx_A1 field descriptions
Field
7–1
AD[7:1]
0
Reserved
Description
Address
Contains the primary slave address used by the I2C module when it is addressed as a slave. This field is
used in the 7-bit address scheme and the lower seven bits in the 10-bit address scheme.
This field is reserved.
This read-only field is reserved and always has the value 0.
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Chapter 35 Inter-Integrated Circuit (I2C)
35.3.2 I2C Frequency Divider register (I2Cx_F)
Address: 4006_6000h base + 1h offset = 4006_6001h
Bit
Read
Write
Reset
7
6
5
4
3
MULT
0
2
1
0
0
0
0
ICR
0
0
0
0
I2Cx_F field descriptions
Field
7–6
MULT
Description
The MULT bits define the multiplier factor mul. This factor is used along with the SCL divider to generate
the I2C baud rate.
00
01
10
11
5–0
ICR
mul = 1
mul = 2
mul = 4
Reserved
ClockRate
Prescales the bus clock for bit rate selection. This field and the MULT field determine the I2C baud rate,
the SDA hold time, the SCL start hold time, and the SCL stop hold time. For a list of values corresponding
to each ICR setting, see I2C divider and hold values.
The SCL divider multiplied by multiplier factor (mul) determines the I2C baud rate.
I2C baud rate = bus speed (Hz)/(mul × SCL divider)
The SDA hold time is the delay from the falling edge of SCL (I2C clock) to the changing of SDA (I2C data).
SDA hold time = bus period (s) × mul × SDA hold value
The SCL start hold time is the delay from the falling edge of SDA (I2C data) while SCL is high (start
condition) to the falling edge of SCL (I2C clock).
SCL start hold time = bus period (s) × mul × SCL start hold value
The SCL stop hold time is the delay from the rising edge of SCL (I2C clock) to the rising edge of SDA (I2C
data) while SCL is high (stop condition).
SCL stop hold time = bus period (s) × mul × SCL stop hold value
For example, if the bus speed is 8 MHz, the following table shows the possible hold time values with
different ICR and MULT selections to achieve an I2C baud rate of 100 kbps.
MULT
ICR
2h
Hold times (μs)
SDA
SCL Start
SCL Stop
00h
3.500
3.000
5.500
1h
07h
2.500
4.000
5.250
1h
0Bh
2.250
4.000
5.250
0h
14h
2.125
4.250
5.125
0h
18h
1.125
4.750
5.125
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Memory map and register descriptions
35.3.3 I2C Control Register 1 (I2Cx_C1)
Address: 4006_6000h base + 2h offset = 4006_6002h
Bit
Read
Write
Reset
7
6
5
4
3
IICEN
IICIE
MST
TX
TXAK
0
0
0
0
0
2
0
RSTA
0
1
0
WUEN
DMAEN
0
0
I2Cx_C1 field descriptions
Field
7
IICEN
Description
I2C Enable
Enables I2C module operation.
0
1
6
IICIE
I2C Interrupt Enable
Enables I2C interrupt requests.
0
1
5
MST
When the MST bit is changed from a 0 to a 1, a START signal is generated on the bus and master mode
is selected. When this bit changes from a 1 to a 0, a STOP signal is generated and the mode of operation
changes from master to slave.
Slave mode
Master mode
Transmit Mode Select
Selects the direction of master and slave transfers. In master mode this bit must be set according to the
type of transfer required. Therefore, for address cycles, this bit is always set. When addressed as a slave
this bit must be set by software according to the SRW bit in the status register.
0
1
3
TXAK
Disabled
Enabled
Master Mode Select
0
1
4
TX
Disabled
Enabled
Receive
Transmit
Transmit Acknowledge Enable
Specifies the value driven onto the SDA during data acknowledge cycles for both master and slave
receivers. The value of the FACK bit affects NACK/ACK generation.
NOTE: SCL is held low until TXAK is written.
0
1
An acknowledge signal is sent to the bus on the following receiving byte (if FACK is cleared) or the
current receiving byte (if FACK is set).
No acknowledge signal is sent to the bus on the following receiving data byte (if FACK is cleared) or
the current receiving data byte (if FACK is set).
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Chapter 35 Inter-Integrated Circuit (I2C)
I2Cx_C1 field descriptions (continued)
Field
Description
2
RSTA
Repeat START
1
WUEN
Wakeup Enable
Writing a one to this bit generates a repeated START condition provided it is the current master. This bit
will always be read as zero. Attempting a repeat at the wrong time results in loss of arbitration.
The I2C module can wake the MCU from low power mode with no peripheral bus running when slave
address matching occurs.
0
1
0
DMAEN
Normal operation. No interrupt generated when address matching in low power mode.
Enables the wakeup function in low power mode.
DMA Enable
The DMAEN bit enables or disables the DMA function.
0
1
All DMA signalling disabled.
DMA transfer is enabled and the following conditions trigger the DMA request:
• While FACK = 0, a data byte is received, either address or data is transmitted. (ACK/NACK
automatic)
• While FACK = 0, the first byte received matches the A1 register or is general call address.
If any address matching occurs, IAAS and TCF are set. If the direction of transfer is known from
master to slave, then it is not required to check the SRW. With this assumption, DMA can also be
used in this case. In other cases, if the master reads data from the slave, then it is required to rewrite
the C1 register operation. With this assumption, DMA cannot be used.
When FACK = 1, an address or a data byte is transmitted.
35.3.4 I2C Status register (I2Cx_S)
Address: 4006_6000h base + 3h offset = 4006_6003h
Bit
Read
7
6
TCF
IAAS
Write
Reset
1
0
5
4
BUSY
ARBL
w1c
0
0
3
RAM
0
2
1
0
SRW
IICIF
RXAK
w1c
0
0
0
I2Cx_S field descriptions
Field
7
TCF
Description
Transfer Complete Flag
This bit sets on the completion of a byte and acknowledge bit transfer. This bit is valid only during or
immediately following a transfer to or from the I2C module. The TCF bit is cleared by reading the I2C data
register in receive mode or by writing to the I2C data register in transmit mode.
0
1
Transfer in progress
Transfer complete
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Memory map and register descriptions
I2Cx_S field descriptions (continued)
Field
6
IAAS
Description
Addressed As A Slave
This bit is set by one of the following conditions:
• The calling address matches the programmed slave primary address in the A1 register or range
address in the RA register (which must be set to a nonzero value).
• GCAEN is set and a general call is received.
• SIICAEN is set and the calling address matches the second programmed slave address.
• ALERTEN is set and an SMBus alert response address is received
• RMEN is set and an address is received that is within the range between the values of the A1 and
RA registers.
This bit sets before the ACK bit. The CPU must check the SRW bit and set TX/RX accordingly. Writing the
C1 register with any value clears this bit.
0
1
5
BUSY
Bus Busy
Indicates the status of the bus regardless of slave or master mode. This bit is set when a START signal is
detected and cleared when a STOP signal is detected.
0
1
4
ARBL
Bus is idle
Bus is busy
Arbitration Lost
This bit is set by hardware when the arbitration procedure is lost. The ARBL bit must be cleared by
software, by writing a one to it.
0
1
3
RAM
Not addressed
Addressed as a slave
Standard bus operation.
Loss of arbitration.
Range Address Match
This bit is set to 1 by any of the following conditions:
• Any nonzero calling address is received that matches the address in the RA register.
• The RMEN bit is set and the calling address is within the range of values of the A1 and RA registers.
NOTE: For the RAM bit to be set to 1 correctly, C1[IICIE] must be set to 1.
Writing the C1 register with any value clears this bit to 0.
0
1
2
SRW
Slave Read/Write
When addressed as a slave, SRW indicates the value of the R/W command bit of the calling address sent
to the master.
0
1
1
IICIF
Not addressed
Addressed as a slave
Slave receive, master writing to slave
Slave transmit, master reading from slave
Interrupt Flag
This bit sets when an interrupt is pending. This bit must be cleared by software by writing a 1 to it, such as
in the interrupt routine. One of the following events can set this bit:
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Chapter 35 Inter-Integrated Circuit (I2C)
I2Cx_S field descriptions (continued)
Field
Description
• One byte transfer, including ACK/NACK bit, completes if FACK is 0. An ACK or NACK is sent on the
bus by writing 0 or 1 to TXAK after this bit is set in receive mode.
• One byte transfer, excluding ACK/NACK bit, completes if FACK is 1.
• Match of slave address to calling address including primary slave address, range slave address,
alert response address, second slave address, or general call address.
• Arbitration lost
• In SMBus mode, any timeouts except SCL and SDA high timeouts
• I2C bus stop detection if the STOPIE bit in the Input Glitch Filter register is 1
NOTE:
0
1
0
RXAK
To clear the I2C bus stop detection interrupt: In the interrupt service routine,
first clear the STOPF bit in the Input Glitch Filter register by writing 1 to it, and
then clear the IICIF bit. If this sequence is reversed, the IICIF bit is asserted
again.
No interrupt pending
Interrupt pending
Receive Acknowledge
0
1
Acknowledge signal was received after the completion of one byte of data transmission on the bus
No acknowledge signal detected
35.3.5 I2C Data I/O register (I2Cx_D)
Address: 4006_6000h base + 4h offset = 4006_6004h
Bit
Read
Write
Reset
7
6
5
4
3
2
1
0
0
0
0
0
DATA
0
0
0
0
I2Cx_D field descriptions
Field
7–0
DATA
Description
Data
In master transmit mode, when data is written to this register, a data transfer is initiated. The most
significant bit is sent first. In master receive mode, reading this register initiates receiving of the next byte
of data.
NOTE: When making the transition out of master receive mode, switch the I2C mode before reading the
Data register to prevent an inadvertent initiation of a master receive data transfer.
In slave mode, the same functions are available after an address match occurs.
The C1[TX] bit must correctly reflect the desired direction of transfer in master and slave modes for the
transmission to begin. For example, if the I2C module is configured for master transmit but a master
receive is desired, reading the Data register does not initiate the receive.
Reading the Data register returns the last byte received while the I2C module is configured in master
receive or slave receive mode. The Data register does not reflect every byte that is transmitted on the I2C
bus, and neither can software verify that a byte has been written to the Data register correctly by reading it
back.
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Memory map and register descriptions
I2Cx_D field descriptions (continued)
Field
Description
In master transmit mode, the first byte of data written to the Data register following assertion of MST (start
bit) or assertion of RSTA (repeated start bit) is used for the address transfer and must consist of the
calling address (in bits 7-1) concatenated with the required R/W bit (in position bit 0).
35.3.6 I2C Control Register 2 (I2Cx_C2)
Address: 4006_6000h base + 5h offset = 4006_6005h
Bit
Read
Write
Reset
7
6
5
4
3
GCAEN
ADEXT
HDRS
SBRC
RMEN
0
0
0
0
0
2
1
0
AD[10:8]
0
0
0
I2Cx_C2 field descriptions
Field
7
GCAEN
Description
General Call Address Enable
Enables general call address.
0
1
6
ADEXT
Address Extension
Controls the number of bits used for the slave address.
0
1
5
HDRS
Controls the drive capability of the I2C pads.
Normal drive mode
High drive mode
Slave Baud Rate Control
Enables independent slave mode baud rate at maximum frequency, which forces clock stretching on SCL
in very fast I2C modes. To a slave, an example of a "very fast" mode is when the master transfers at 40
kbps but the slave can capture the master's data at only 10 kbps.
0
1
3
RMEN
7-bit address scheme
10-bit address scheme
High Drive Select
0
1
4
SBRC
Disabled
Enabled
The slave baud rate follows the master baud rate and clock stretching may occur
Slave baud rate is independent of the master baud rate
Range Address Matching Enable
This bit controls slave address matching for addresses between the values of the A1 and RA registers.
When this bit is set, a slave address match occurs for any address greater than the value of the A1
register and less than or equal to the value of the RA register.
Table continues on the next page...
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Chapter 35 Inter-Integrated Circuit (I2C)
I2Cx_C2 field descriptions (continued)
Field
Description
0
1
2–0
AD[10:8]
Range mode disabled. No address match occurs for an address within the range of values of the A1
and RA registers.
Range mode enabled. Address matching occurs when a slave receives an address within the range of
values of the A1 and RA registers.
Slave Address
Contains the upper three bits of the slave address in the 10-bit address scheme. This field is valid only
while the ADEXT bit is set.
35.3.7 I2C Programmable Input Glitch Filter register (I2Cx_FLT)
Address: 4006_6000h base + 6h offset = 4006_6006h
Bit
Read
Write
Reset
7
6
5
STOPF
SHEN
3
STOPIE
w1c
0
4
0
0
2
1
0
0
0
FLT
0
0
0
I2Cx_FLT field descriptions
Field
7
SHEN
Description
Stop Hold Enable
Set this bit to hold off entry to stop mode when any data transmission or reception is occurring.
The following scenario explains the holdoff functionality:
1. The I2C module is configured for a basic transfer, and the SHEN bit is set to 1.
2. A transfer begins.
3. The MCU signals the I2C module to enter stop mode.
4. The byte currently being transferred, including both address and data, completes its transfer.
5. The I2C slave or master acknowledges that the in-transfer byte completed its transfer and
acknowledges the request to enter stop mode.
6. After receiving the I2C module's acknowledgment of the request to enter stop mode, the MCU
determines whether to shut off the I2C module's clock.
If the SHEN bit is set to 1 and the I2C module is in an idle or disabled state when the MCU signals to enter
stop mode, the module immediately acknowledges the request to enter stop mode.
If SHEN is cleared to 0 and the overall data transmission or reception that was suspended by stop mode
entry was incomplete: To resume the overall transmission or reception after the MCU exits stop mode,
software must reinitialize the transfer by resending the address of the slave.
If the I2C Control Register 1's IICIE bit was set to 1 before the MCU entered stop mode, system software
will receive the interrupt triggered by the I2C Status Register's TCF bit after the MCU wakes from the stop
mode.
0
1
6
STOPF
Stop holdoff is disabled. The MCU's entry to stop mode is not gated.
Stop holdoff is enabled.
I2C Bus Stop Detect Flag
Table continues on the next page...
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Memory map and register descriptions
I2Cx_FLT field descriptions (continued)
Field
Description
Hardware sets this bit when the I2C bus's stop status is detected. The STOPF bit must be cleared by
writing 1 to it.
0
1
5
STOPIE
No stop happens on I2C bus
Stop detected on I2C bus
I2C Bus Stop Interrupt Enable
This bit enables the interrupt for I2C bus stop detection.
NOTE: To clear the I2C bus stop detection interrupt: In the interrupt service routine, first clear the STOPF
bit by writing 1 to it, and then clear the IICIF bit in the status register. If this sequence is reversed,
the IICIF bit is asserted again.
0
1
4–0
FLT
Stop detection interrupt is disabled
Stop detection interrupt is enabled
I2C Programmable Filter Factor
Controls the width of the glitch, in terms of bus clock cycles, that the filter must absorb. For any glitch
whose size is less than or equal to this width setting, the filter does not allow the glitch to pass.
00h
01-1Fh
No filter/bypass
Filter glitches up to width of n bus clock cycles, where n=1-31d
35.3.8 I2C Range Address register (I2Cx_RA)
Address: 4006_6000h base + 7h offset = 4006_6007h
Bit
Read
Write
Reset
7
6
5
4
3
2
1
0
RAD
0
0
0
0
0
0
0
0
0
I2Cx_RA field descriptions
Field
7–1
RAD
0
Reserved
Description
Range Slave Address
This field contains the slave address to be used by the I2C module. The field is used in the 7-bit address
scheme. Any nonzero write enables this register. This register's use is similar to that of the A1 register, but
in addition this register can be considered a maximum boundary in range matching mode.
This field is reserved.
This read-only field is reserved and always has the value 0.
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Chapter 35 Inter-Integrated Circuit (I2C)
35.3.9 I2C SMBus Control and Status register (I2Cx_SMB)
NOTE
When the SCL and SDA signals are held high for a length of
time greater than the high timeout period, the SHTF1 flag sets.
Before reaching this threshold, while the system is detecting
how long these signals are being held high, a master assumes
that the bus is free. However, the SHTF1 bit rises in the bus
transmission process with the idle bus state.
NOTE
When the TCKSEL bit is set, there is no need to monitor the
SHTF1 bit because the bus speed is too high to match the
protocol of SMBus.
Address: 4006_6000h base + 8h offset = 4006_6008h
Bit
Read
Write
Reset
7
6
5
4
FACK
ALERTEN
SIICAEN
TCKSEL
0
0
0
0
3
2
1
SLTF
SHTF1
SHTF2
w1c
0
w1c
0
0
0
SHTF2IE
0
I2Cx_SMB field descriptions
Field
7
FACK
Description
Fast NACK/ACK Enable
For SMBus packet error checking, the CPU must be able to issue an ACK or NACK according to the result
of receiving data byte.
0
1
6
ALERTEN
An ACK or NACK is sent on the following receiving data byte
Writing 0 to TXAK after receiving a data byte generates an ACK. Writing 1 to TXAK after receiving a
data byte generates a NACK.
SMBus Alert Response Address Enable
Enables or disables SMBus alert response address matching.
NOTE: After the host responds to a device that used the alert response address, you must use software
to put the device's address on the bus. The alert protocol is described in the SMBus specification.
0
1
5
SIICAEN
SMBus alert response address matching is disabled
SMBus alert response address matching is enabled
Second I2C Address Enable
Enables or disables SMBus device default address.
0
1
I2C address register 2 matching is disabled
I2C address register 2 matching is enabled
Table continues on the next page...
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Memory map and register descriptions
I2Cx_SMB field descriptions (continued)
Field
4
TCKSEL
Description
Timeout Counter Clock Select
Selects the clock source of the timeout counter.
0
1
3
SLTF
Timeout counter counts at the frequency of the bus clock / 64
Timeout counter counts at the frequency of the bus clock
SCL Low Timeout Flag
This bit is set when the SLT register (consisting of the SLTH and SLTL registers) is loaded with a non-zero
value (LoValue) and an SCL low timeout occurs. Software clears this bit by writing a logic 1 to it.
NOTE: The low timeout function is disabled when the SLT register's value is zero.
0
1
2
SHTF1
SCL High Timeout Flag 1
This read-only bit sets when SCL and SDA are held high more than clock × LoValue / 512, which indicates
the bus is free. This bit is cleared automatically.
0
1
1
SHTF2
No SCL high and SDA high timeout occurs
SCL high and SDA high timeout occurs
SCL High Timeout Flag 2
This bit sets when SCL is held high and SDA is held low more than clock × LoValue/512. Software clears
this bit by writing a 1 to it.
0
1
0
SHTF2IE
No low timeout occurs
Low timeout occurs
No SCL high and SDA low timeout occurs
SCL high and SDA low timeout occurs
SHTF2 Interrupt Enable
Enables SCL high and SDA low timeout interrupt.
0
1
SHTF2 interrupt is disabled
SHTF2 interrupt is enabled
35.3.10 I2C Address Register 2 (I2Cx_A2)
Address: 4006_6000h base + 9h offset = 4006_6009h
Bit
Read
Write
Reset
7
6
5
4
3
2
1
0
SAD
1
1
0
0
0
0
0
1
0
I2Cx_A2 field descriptions
Field
7–1
SAD
Description
SMBus Address
Table continues on the next page...
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Chapter 35 Inter-Integrated Circuit (I2C)
I2Cx_A2 field descriptions (continued)
Field
Description
Contains the slave address used by the SMBus. This field is used on the device default address or other
related addresses.
0
Reserved
This field is reserved.
This read-only field is reserved and always has the value 0.
35.3.11 I2C SCL Low Timeout Register High (I2Cx_SLTH)
Address: 4006_6000h base + Ah offset = 4006_600Ah
Bit
Read
Write
Reset
7
6
5
4
3
2
1
0
0
0
0
0
SSLT[15:8]
0
0
0
0
I2Cx_SLTH field descriptions
Field
7–0
SSLT[15:8]
Description
Most significant byte of SCL low timeout value that determines the timeout period of SCL low.
35.3.12 I2C SCL Low Timeout Register Low (I2Cx_SLTL)
Address: 4006_6000h base + Bh offset = 4006_600Bh
Bit
Read
Write
Reset
7
6
5
4
3
2
1
0
0
0
0
0
SSLT[7:0]
0
0
0
0
I2Cx_SLTL field descriptions
Field
7–0
SSLT[7:0]
Description
Least significant byte of SCL low timeout value that determines the timeout period of SCL low.
35.4 Functional description
This section provides a comprehensive functional description of the I2C module.
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Functional description
35.4.1 I2C protocol
The I2C bus system uses a serial data line (SDA) and a serial clock line (SCL) for data
transfers. All devices connected to it must have open drain or open collector outputs. A
logic AND function is exercised on both lines with external pull-up resistors. The value
of these resistors depends on the system.
Normally, a standard instance of communication is composed of four parts:
1.
2.
3.
4.
START signal
Slave address transmission
Data transfer
STOP signal
The STOP signal should not be confused with the CPU STOP instruction. The following
figure illustrates I2C bus system communication.
M SB
SCL
SDA
1
SDA
Start
Signal
3
4
5
6
7
8
9
A D 7 A D 6 A D 5 A D 4 A D 3 A D 2 A D 1 R /W
C a llin g A d d re s s
Start Signal
SCL
M SB
LSB
2
3
4
3
4
5
6
7
8
D7
D6
D5
D4
D3
D2
D1
D0
D a ta B y te
5
6
7
8
A D 7 A D 6 A D 5 A D 4 A D 3 A D 2 A D 1 R /W
C a llin g A d d re s s
1
9
R e a d / Ack
W rite Bit
XX
9
No Stop
Ack Signal
Bit
M SB
LSB
2
2
R e a d / Ack
W rite Bit
M SB
1
XXX
LSB
1
LSB
2
3
4
5
6
7
8
9
A D 7 A D 6 A D 5 A D 4 A D 3 A D 2 A D 1 R /W
Repeated
Start
Signal
N e w C a llin g A d d re s s
Read/
W rite
No Stop
Ack Signal
Bit
Figure 35-26. I2C bus transmission signals
35.4.1.1 START signal
The bus is free when no master device is engaging the bus (both SCL and SDA are high).
When the bus is free, a master may initiate communication by sending a START signal.
A START signal is defined as a high-to-low transition of SDA while SCL is high. This
signal denotes the beginning of a new data transfer—each data transfer might contain
several bytes of data—and brings all slaves out of their idle states.
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Chapter 35 Inter-Integrated Circuit (I2C)
35.4.1.2 Slave address transmission
Immediately after the START signal, the first byte of a data transfer is the slave address
transmitted by the master. This address is a 7-bit calling address followed by an R/W bit.
The R/W bit tells the slave the desired direction of data transfer.
• 1 = Read transfer: The slave transmits data to the master
• 0 = Write transfer: The master transmits data to the slave
Only the slave with a calling address that matches the one transmitted by the master
responds by sending an acknowledge bit. The slave sends the acknowledge bit by pulling
SDA low at the ninth clock.
No two slaves in the system can have the same address. If the I2C module is the master, it
must not transmit an address that is equal to its own slave address. The I2C module
cannot be master and slave at the same time. However, if arbitration is lost during an
address cycle, the I2C module reverts to slave mode and operates correctly even if it is
being addressed by another master.
35.4.1.3 Data transfers
When successful slave addressing is achieved, data transfer can proceed on a byte-bybyte basis in the direction specified by the R/W bit sent by the calling master.
All transfers that follow an address cycle are referred to as data transfers, even if they
carry subaddress information for the slave device.
Each data byte is 8 bits long. Data may be changed only while SCL is low. Data must be
held stable while SCL is high. There is one clock pulse on SCL for each data bit, and the
MSB is transferred first. Each data byte is followed by a ninth (acknowledge) bit, which
is signaled from the receiving device by pulling SDA low at the ninth clock. In summary,
one complete data transfer needs nine clock pulses.
If the slave receiver does not acknowledge the master in the ninth bit, the slave must
leave SDA high. The master interprets the failed acknowledgement as an unsuccessful
data transfer.
If the master receiver does not acknowledge the slave transmitter after a data byte
transmission, the slave interprets it as an end to data transfer and releases the SDA line.
In the case of a failed acknowledgement by either the slave or master, the data transfer is
aborted and the master does one of two things:
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Functional description
• Relinquishes the bus by generating a STOP signal.
• Commences a new call by generating a repeated START signal.
35.4.1.4 STOP signal
The master can terminate the communication by generating a STOP signal to free the
bus. A STOP signal is defined as a low-to-high transition of SDA while SCL is asserted.
The master can generate a STOP signal even if the slave has generated an
acknowledgement, at which point the slave must release the bus.
35.4.1.5 Repeated START signal
The master may generate a START signal followed by a calling command without
generating a STOP signal first. This action is called a repeated START. The master uses
a repeated START to communicate with another slave or with the same slave in a
different mode (transmit/receive mode) without releasing the bus.
35.4.1.6 Arbitration procedure
The I2C bus is a true multimaster bus that allows more than one master to be connected
on it.
If two or more masters try to control the bus at the same time, a clock synchronization
procedure determines the bus clock. The bus clock's low period is equal to the longest
clock low period, and the high period is equal to the shortest one among the masters.
The relative priority of the contending masters is determined by a data arbitration
procedure. A bus master loses arbitration if it transmits logic level 1 while another master
transmits logic level 0. The losing masters immediately switch to slave receive mode and
stop driving SDA output. In this case, the transition from master to slave mode does not
generate a STOP condition. Meanwhile, hardware sets a status bit to indicate the loss of
arbitration.
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Chapter 35 Inter-Integrated Circuit (I2C)
35.4.1.7 Clock synchronization
Because wire AND logic is performed on SCL, a high-to-low transition on SCL affects
all devices connected on the bus. The devices start counting their low period and, after a
device's clock has gone low, that device holds SCL low until the clock reaches its high
state. However, the change of low to high in this device clock might not change the state
of SCL if another device clock is still within its low period. Therefore, the synchronized
clock SCL is held low by the device with the longest low period. Devices with shorter
low periods enter a high wait state during this time; see the following diagram. When all
applicable devices have counted off their low period, the synchronized clock SCL is
released and pulled high. Afterward there is no difference between the device clocks and
the state of SCL, and all devices start counting their high periods. The first device to
complete its high period pulls SCL low again.
D e la y
S ta rt C o u n tin g H ig h P e rio d
SCL1
SCL2
SCL
In te rn a l C o u n te r R e s e t
Figure 35-27. I2C clock synchronization
35.4.1.8 Handshaking
The clock synchronization mechanism can be used as a handshake in data transfers. A
slave device may hold SCL low after completing a single byte transfer (9 bits). In this
case, it halts the bus clock and forces the master clock into wait states until the slave
releases SCL.
35.4.1.9 Clock stretching
The clock synchronization mechanism can be used by slaves to slow down the bit rate of
a transfer. After the master drives SCL low, a slave can drive SCL low for the required
period and then release it. If the slave's SCL low period is greater than the master's SCL
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Functional description
low period, the resulting SCL bus signal's low period is stretched. In other words, the
SCL bus signal's low period is increased to be the same length as the slave's SCL low
period.
35.4.1.10 I2C divider and hold values
NOTE
For some cases on some devices, the SCL divider value may
vary by +/-2 or +/-4 when ICR’s value ranges from 00h to 0Fh.
These potentially varying SCL divider values are highlighted in
the following table. For the actual SCL divider values for your
device, see the chip-specific details about the I2C module.
Table 35-28. I2C divider and hold values
ICR
SCL
divider
SDA hold
value
SCL hold
(start)
value
SCL hold
(stop)
value
SCL
divider
(clocks)
SDA hold
(clocks)
SCL hold
(start)
value
SCL hold
(stop)
value
00
20
7
6
11
20
160
17
78
81
01
22
7
7
12
21
192
17
94
97
02
24
8
8
13
22
224
33
110
113
03
26
8
9
14
23
256
33
126
129
04
28
9
10
15
24
288
49
142
145
05
06
30
9
11
16
25
320
49
158
161
34
10
13
18
26
384
65
190
193
07
40
10
16
21
27
480
65
238
241
08
28
7
10
15
28
320
33
158
161
09
32
7
12
17
29
384
33
190
193
0A
36
9
14
19
2A
448
65
222
225
0B
40
9
16
21
2B
512
65
254
257
0C
44
11
18
23
2C
576
97
286
289
0D
48
11
20
25
2D
640
97
318
321
0E
56
13
24
29
2E
768
129
382
385
0F
68
13
30
35
2F
960
129
478
481
10
48
9
18
25
30
640
65
318
321
11
56
9
22
29
31
768
65
382
385
12
64
13
26
33
32
896
129
446
44