DtSheet

TI LM3S828-IQN50-C2T

TE X AS I NS TRUM E NTS - P RO DUCTION D ATA
®
Stellaris LM3S828 Microcontroller
D ATA SHE E T
D S -LM3S 828- 1 2 7 3 9 . 2 5 1 5
S P M S 163H
C o p yri g h t © 2 0 07-2012
Te xa s In stru me n ts In co rporated
Copyright
Copyright © 2007-2012 Texas Instruments Incorporated All rights reserved. Stellaris and StellarisWare® are registered trademarks of Texas Instruments
Incorporated. ARM and Thumb are registered trademarks and Cortex is a trademark of ARM Limited. Other names and brands may be claimed as the
property of others.
PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of Texas Instruments standard
warranty. Production processing does not necessarily include testing of all parameters.
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas Instruments semiconductor
products and disclaimers thereto appears at the end of this data sheet.
Texas Instruments Incorporated
108 Wild Basin, Suite 350
Austin, TX 78746
http://www.ti.com/stellaris
http://www-k.ext.ti.com/sc/technical-support/product-information-centers.htm
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Stellaris LM3S828 Microcontroller
Table of Contents
Revision History ............................................................................................................................. 19
About This Document .................................................................................................................... 23
Audience ..............................................................................................................................................
About This Manual ................................................................................................................................
Related Documents ...............................................................................................................................
Documentation Conventions ..................................................................................................................
23
23
23
24
1
Architectural Overview .......................................................................................... 26
1.1
1.2
1.3
1.4
1.4.1
1.4.2
1.4.3
1.4.4
1.4.5
1.4.6
1.4.7
1.4.8
1.4.9
Product Features ..........................................................................................................
Target Applications ........................................................................................................
High-Level Block Diagram .............................................................................................
Functional Overview ......................................................................................................
ARM Cortex™-M3 .........................................................................................................
Motor Control Peripherals ..............................................................................................
Analog Peripherals ........................................................................................................
Serial Communications Peripherals ................................................................................
System Peripherals .......................................................................................................
Memory Peripherals ......................................................................................................
Additional Features .......................................................................................................
Hardware Details ..........................................................................................................
System Block Diagram ..................................................................................................
26
32
32
34
34
35
35
35
37
37
38
38
39
2
The Cortex-M3 Processor ...................................................................................... 40
2.1
2.2
2.2.1
2.2.2
2.2.3
2.2.4
2.3
2.3.1
2.3.2
2.3.3
2.3.4
2.3.5
2.3.6
2.4
2.4.1
2.4.2
2.4.3
2.4.4
2.4.5
2.4.6
2.4.7
2.5
2.5.1
2.5.2
Block Diagram .............................................................................................................. 41
Overview ...................................................................................................................... 42
System-Level Interface .................................................................................................. 42
Integrated Configurable Debug ...................................................................................... 42
Trace Port Interface Unit (TPIU) ..................................................................................... 43
Cortex-M3 System Component Details ........................................................................... 43
Programming Model ...................................................................................................... 44
Processor Mode and Privilege Levels for Software Execution ........................................... 44
Stacks .......................................................................................................................... 44
Register Map ................................................................................................................ 45
Register Descriptions .................................................................................................... 46
Exceptions and Interrupts .............................................................................................. 59
Data Types ................................................................................................................... 59
Memory Model .............................................................................................................. 59
Memory Regions, Types and Attributes ........................................................................... 60
Memory System Ordering of Memory Accesses .............................................................. 61
Behavior of Memory Accesses ....................................................................................... 61
Software Ordering of Memory Accesses ......................................................................... 62
Bit-Banding ................................................................................................................... 63
Data Storage ................................................................................................................ 65
Synchronization Primitives ............................................................................................. 66
Exception Model ........................................................................................................... 67
Exception States ........................................................................................................... 68
Exception Types ............................................................................................................ 68
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2.5.3
2.5.4
2.5.5
2.5.6
2.5.7
2.6
2.6.1
2.6.2
2.6.3
2.6.4
2.7
2.7.1
2.7.2
2.8
Exception Handlers ....................................................................................................... 70
Vector Table .................................................................................................................. 71
Exception Priorities ....................................................................................................... 72
Interrupt Priority Grouping .............................................................................................. 72
Exception Entry and Return ........................................................................................... 72
Fault Handling .............................................................................................................. 74
Fault Types ................................................................................................................... 75
Fault Escalation and Hard Faults .................................................................................... 75
Fault Status Registers and Fault Address Registers ........................................................ 76
Lockup ......................................................................................................................... 76
Power Management ...................................................................................................... 77
Entering Sleep Modes ................................................................................................... 77
Wake Up from Sleep Mode ............................................................................................ 77
Instruction Set Summary ............................................................................................... 78
3
Cortex-M3 Peripherals ........................................................................................... 82
3.1
3.1.1
3.1.2
3.1.3
3.1.4
3.2
3.3
3.4
3.5
3.6
Functional Description ................................................................................................... 82
System Timer (SysTick) ................................................................................................. 82
Nested Vectored Interrupt Controller (NVIC) .................................................................... 83
System Control Block (SCB) .......................................................................................... 85
Memory Protection Unit (MPU) ....................................................................................... 85
Register Map ................................................................................................................ 90
System Timer (SysTick) Register Descriptions ................................................................ 91
NVIC Register Descriptions ........................................................................................... 95
System Control Block (SCB) Register Descriptions ........................................................ 103
Memory Protection Unit (MPU) Register Descriptions .................................................... 130
4
JTAG Interface ...................................................................................................... 140
4.1
4.2
4.3
4.3.1
4.3.2
4.3.3
4.3.4
4.4
4.5
4.5.1
4.5.2
Block Diagram ............................................................................................................
Signal Description .......................................................................................................
Functional Description .................................................................................................
JTAG Interface Pins .....................................................................................................
JTAG TAP Controller ...................................................................................................
Shift Registers ............................................................................................................
Operational Considerations ..........................................................................................
Initialization and Configuration .....................................................................................
Register Descriptions ..................................................................................................
Instruction Register (IR) ...............................................................................................
Data Registers ............................................................................................................
141
141
142
142
143
144
144
146
146
146
148
5
System Control ..................................................................................................... 150
5.1
5.2
5.2.1
5.2.2
5.2.3
5.2.4
5.2.5
5.3
5.4
5.5
Signal Description .......................................................................................................
Functional Description .................................................................................................
Device Identification ....................................................................................................
Reset Control ..............................................................................................................
Power Control .............................................................................................................
Clock Control ..............................................................................................................
System Control ...........................................................................................................
Initialization and Configuration .....................................................................................
Register Map ..............................................................................................................
Register Descriptions ..................................................................................................
4
150
150
150
150
155
155
158
159
160
161
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6
Internal Memory ................................................................................................... 206
6.1
6.2
6.2.1
6.2.2
6.3
6.3.1
6.3.2
6.4
6.5
6.6
Block Diagram ............................................................................................................ 206
Functional Description ................................................................................................. 206
SRAM Memory ............................................................................................................ 206
Flash Memory ............................................................................................................. 207
Flash Memory Initialization and Configuration ............................................................... 209
Changing Flash Protection Bits .................................................................................... 209
Flash Programming ..................................................................................................... 210
Register Map .............................................................................................................. 211
Flash Register Descriptions (Flash Control Offset) ......................................................... 211
Flash Register Descriptions (System Control Offset) ...................................................... 219
7
General-Purpose Input/Outputs (GPIOs) ........................................................... 223
7.1
7.2
7.3
7.3.1
7.3.2
7.3.3
7.3.4
7.3.5
7.4
7.5
7.6
Block Diagram ............................................................................................................ 224
Signal Description ....................................................................................................... 224
Functional Description ................................................................................................. 226
Data Control ............................................................................................................... 227
Interrupt Control .......................................................................................................... 228
Mode Control .............................................................................................................. 229
Pad Control ................................................................................................................. 229
Identification ............................................................................................................... 229
Initialization and Configuration ..................................................................................... 229
Register Map .............................................................................................................. 230
Register Descriptions .................................................................................................. 232
8
General-Purpose Timers ...................................................................................... 264
8.1
8.2
8.3
8.3.1
8.3.2
8.3.3
8.4
8.4.1
8.4.2
8.4.3
8.4.4
8.4.5
8.4.6
8.5
8.6
Block Diagram ............................................................................................................
Signal Description .......................................................................................................
Functional Description .................................................................................................
GPTM Reset Conditions ..............................................................................................
32-Bit Timer Operating Modes ......................................................................................
16-Bit Timer Operating Modes ......................................................................................
Initialization and Configuration .....................................................................................
32-Bit One-Shot/Periodic Timer Mode ...........................................................................
32-Bit Real-Time Clock (RTC) Mode .............................................................................
16-Bit One-Shot/Periodic Timer Mode ...........................................................................
16-Bit Input Edge Count Mode .....................................................................................
16-Bit Input Edge Timing Mode ....................................................................................
16-Bit PWM Mode .......................................................................................................
Register Map ..............................................................................................................
Register Descriptions ..................................................................................................
265
265
266
266
266
268
271
271
272
272
273
273
274
274
275
9
Watchdog Timer ................................................................................................... 300
9.1
9.2
9.3
9.4
9.5
Block Diagram ............................................................................................................
Functional Description .................................................................................................
Initialization and Configuration .....................................................................................
Register Map ..............................................................................................................
Register Descriptions ..................................................................................................
301
301
302
302
303
10
Analog-to-Digital Converter (ADC) ..................................................................... 324
10.1
Block Diagram ............................................................................................................ 324
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10.2
10.3
10.3.1
10.3.2
10.3.3
10.3.4
10.3.5
10.3.6
10.3.7
10.4
10.4.1
10.4.2
10.5
10.6
Signal Description ....................................................................................................... 325
Functional Description ................................................................................................. 325
Sample Sequencers .................................................................................................... 326
Module Control ............................................................................................................ 326
Hardware Sample Averaging Circuit ............................................................................. 327
Analog-to-Digital Converter .......................................................................................... 327
Differential Sampling ................................................................................................... 328
Test Modes ................................................................................................................. 330
Internal Temperature Sensor ........................................................................................ 330
Initialization and Configuration ..................................................................................... 331
Module Initialization ..................................................................................................... 331
Sample Sequencer Configuration ................................................................................. 331
Register Map .............................................................................................................. 332
Register Descriptions .................................................................................................. 333
11
Universal Asynchronous Receivers/Transmitters (UARTs) ............................. 360
11.1
11.2
11.3
11.3.1
11.3.2
11.3.3
11.3.4
11.3.5
11.3.6
11.4
11.5
11.6
Block Diagram ............................................................................................................
Signal Description .......................................................................................................
Functional Description .................................................................................................
Transmit/Receive Logic ...............................................................................................
Baud-Rate Generation .................................................................................................
Data Transmission ......................................................................................................
FIFO Operation ...........................................................................................................
Interrupts ....................................................................................................................
Loopback Operation ....................................................................................................
Initialization and Configuration .....................................................................................
Register Map ..............................................................................................................
Register Descriptions ..................................................................................................
361
361
362
362
362
363
363
364
365
365
366
367
12
Synchronous Serial Interface (SSI) .................................................................... 400
12.1
12.2
12.3
12.3.1
12.3.2
12.3.3
12.3.4
12.4
12.5
12.6
Block Diagram ............................................................................................................
Signal Description .......................................................................................................
Functional Description .................................................................................................
Bit Rate Generation .....................................................................................................
FIFO Operation ...........................................................................................................
Interrupts ....................................................................................................................
Frame Formats ...........................................................................................................
Initialization and Configuration .....................................................................................
Register Map ..............................................................................................................
Register Descriptions ..................................................................................................
13
Inter-Integrated Circuit (I2C) Interface ................................................................ 438
13.1
13.2
13.3
13.3.1
13.3.2
13.3.3
13.3.4
13.3.5
13.4
Block Diagram ............................................................................................................
Signal Description .......................................................................................................
Functional Description .................................................................................................
I2C Bus Functional Overview ........................................................................................
Available Speed Modes ...............................................................................................
Interrupts ....................................................................................................................
Loopback Operation ....................................................................................................
Command Sequence Flow Charts ................................................................................
Initialization and Configuration .....................................................................................
6
400
400
401
401
401
402
402
410
411
412
439
439
439
440
442
443
443
443
451
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13.5
13.6
13.7
Register Map .............................................................................................................. 452
Register Descriptions (I2C Master) ............................................................................... 453
Register Descriptions (I2C Slave) ................................................................................. 466
14
Pin Diagram .......................................................................................................... 475
15
Signal Tables ........................................................................................................ 476
15.1
15.2
15.3
15.4
15.5
Signals by Pin Number ................................................................................................ 476
Signals by Signal Name ............................................................................................... 478
Signals by Function, Except for GPIO ........................................................................... 480
GPIO Pins and Alternate Functions .............................................................................. 481
Connections for Unused Signals ................................................................................... 482
16
Operating Characteristics ................................................................................... 483
17
Electrical Characteristics .................................................................................... 484
17.1
17.1.1
17.1.2
17.1.3
17.1.4
17.1.5
17.1.6
17.2
17.2.1
17.2.2
17.2.3
17.2.4
17.2.5
17.2.6
17.2.7
17.2.8
17.2.9
DC Characteristics ...................................................................................................... 484
Maximum Ratings ....................................................................................................... 484
Recommended DC Operating Conditions ...................................................................... 484
On-Chip Low Drop-Out (LDO) Regulator Characteristics ................................................ 485
GPIO Module Characteristics ....................................................................................... 485
Power Specifications ................................................................................................... 485
Flash Memory Characteristics ...................................................................................... 486
AC Characteristics ....................................................................................................... 486
Load Conditions .......................................................................................................... 486
Clocks ........................................................................................................................ 487
JTAG and Boundary Scan ............................................................................................ 487
Reset ......................................................................................................................... 489
Sleep Modes ............................................................................................................... 491
General-Purpose I/O (GPIO) ........................................................................................ 491
Analog-to-Digital Converter .......................................................................................... 492
Synchronous Serial Interface (SSI) ............................................................................... 493
Inter-Integrated Circuit (I2C) Interface ........................................................................... 495
A
Serial Flash Loader .............................................................................................. 497
A.1
A.2
A.2.1
A.2.2
A.3
A.3.1
A.3.2
A.3.3
A.4
A.4.1
A.4.2
A.4.3
A.4.4
A.4.5
A.4.6
Serial Flash Loader .....................................................................................................
Interfaces ...................................................................................................................
UART .........................................................................................................................
SSI .............................................................................................................................
Packet Handling ..........................................................................................................
Packet Format ............................................................................................................
Sending Packets .........................................................................................................
Receiving Packets .......................................................................................................
Commands .................................................................................................................
COMMAND_PING (0X20) ............................................................................................
COMMAND_GET_STATUS (0x23) ...............................................................................
COMMAND_DOWNLOAD (0x21) .................................................................................
COMMAND_SEND_DATA (0x24) .................................................................................
COMMAND_RUN (0x22) .............................................................................................
COMMAND_RESET (0x25) .........................................................................................
B
Register Quick Reference ................................................................................... 502
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497
497
497
497
498
498
498
498
499
499
499
499
500
500
500
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C
Ordering and Contact Information ..................................................................... 519
C.1
C.2
C.3
C.4
Ordering Information .................................................................................................... 519
Part Markings .............................................................................................................. 519
Kits ............................................................................................................................. 520
Support Information ..................................................................................................... 520
D
Package Information ............................................................................................ 521
D.1
D.1.1
D.1.2
D.1.3
48-Pin LQFP Package .................................................................................................
Package Dimensions ...................................................................................................
Tray Dimensions .........................................................................................................
Tape and Reel Dimensions ..........................................................................................
8
521
521
523
525
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Stellaris LM3S828 Microcontroller
List of Figures
Figure 1-1.
Figure 1-2.
Figure 2-1.
Figure 2-2.
Figure 2-3.
Figure 2-4.
Figure 2-5.
Figure 2-6.
Figure 2-7.
Figure 3-1.
Figure 4-1.
Figure 4-2.
Figure 4-3.
Figure 4-4.
Figure 4-5.
Figure 5-1.
Figure 5-2.
Figure 5-3.
Figure 5-4.
Figure 6-1.
Figure 7-1.
Figure 7-2.
Figure 7-3.
Figure 7-4.
Figure 8-1.
Figure 8-2.
Figure 8-3.
Figure 8-4.
Figure 9-1.
Figure 10-1.
Figure 10-2.
Figure 10-3.
Figure 10-4.
Figure 10-5.
Figure 11-1.
Figure 11-2.
Figure 12-1.
Figure 12-2.
Figure 12-3.
Figure 12-4.
Figure 12-5.
Figure 12-6.
Figure 12-7.
Figure 12-8.
Figure 12-9.
Figure 12-10.
Stellaris LM3S828 Microcontroller High-Level Block Diagram ................................. 33
LM3S828 Controller System-Level Block Diagram ................................................. 39
CPU Block Diagram ............................................................................................. 42
TPIU Block Diagram ............................................................................................ 43
Cortex-M3 Register Set ........................................................................................ 45
Bit-Band Mapping ................................................................................................ 65
Data Storage ....................................................................................................... 66
Vector Table ........................................................................................................ 71
Exception Stack Frame ........................................................................................ 73
SRD Use Example ............................................................................................... 88
JTAG Module Block Diagram .............................................................................. 141
Test Access Port State Machine ......................................................................... 144
IDCODE Register Format ................................................................................... 148
BYPASS Register Format ................................................................................... 149
Boundary Scan Register Format ......................................................................... 149
Basic RST Configuration .................................................................................... 152
External Circuitry to Extend Power-On Reset ....................................................... 152
Reset Circuit Controlled by Switch ...................................................................... 153
Main Clock Tree ................................................................................................ 156
Flash Block Diagram .......................................................................................... 206
GPIO Module Block Diagram .............................................................................. 224
GPIO Port Block Diagram ................................................................................... 227
GPIODATA Write Example ................................................................................. 228
GPIODATA Read Example ................................................................................. 228
GPTM Module Block Diagram ............................................................................ 265
16-Bit Input Edge Count Mode Example .............................................................. 269
16-Bit Input Edge Time Mode Example ............................................................... 270
16-Bit PWM Mode Example ................................................................................ 271
WDT Module Block Diagram .............................................................................. 301
ADC Module Block Diagram ............................................................................... 325
Differential Sampling Range, VIN_ODD = 1.5 V ...................................................... 329
Differential Sampling Range, VIN_ODD = 0.75 V .................................................... 329
Differential Sampling Range, VIN_ODD = 2.25 V .................................................... 330
Internal Temperature Sensor Characteristic ......................................................... 331
UART Module Block Diagram ............................................................................. 361
UART Character Frame ..................................................................................... 362
SSI Module Block Diagram ................................................................................. 400
TI Synchronous Serial Frame Format (Single Transfer) ........................................ 403
TI Synchronous Serial Frame Format (Continuous Transfer) ................................ 404
Freescale SPI Format (Single Transfer) with SPO=0 and SPH=0 .......................... 404
Freescale SPI Format (Continuous Transfer) with SPO=0 and SPH=0 .................. 405
Freescale SPI Frame Format with SPO=0 and SPH=1 ......................................... 406
Freescale SPI Frame Format (Single Transfer) with SPO=1 and SPH=0 ............... 406
Freescale SPI Frame Format (Continuous Transfer) with SPO=1 and SPH=0 ........ 407
Freescale SPI Frame Format with SPO=1 and SPH=1 ......................................... 408
MICROWIRE Frame Format (Single Frame) ........................................................ 408
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Figure 12-11.
Figure 12-12.
Figure 13-1.
Figure 13-2.
Figure 13-3.
Figure 13-4.
Figure 13-5.
Figure 13-6.
Figure 13-7.
Figure 13-8.
Figure 13-9.
Figure 13-10.
Figure 13-11.
Figure 13-12.
Figure 13-13.
Figure 14-1.
Figure 17-1.
Figure 17-2.
Figure 17-3.
Figure 17-4.
Figure 17-5.
Figure 17-6.
Figure 17-7.
Figure 17-8.
Figure 17-9.
Figure 17-10.
Figure 17-11.
Figure 17-12.
MICROWIRE Frame Format (Continuous Transfer) ............................................. 409
MICROWIRE Frame Format, SSIFss Input Setup and Hold Requirements ............ 410
I2C Block Diagram ............................................................................................. 439
I2C Bus Configuration ........................................................................................ 440
START and STOP Conditions ............................................................................. 440
Complete Data Transfer with a 7-Bit Address ....................................................... 441
R/S Bit in First Byte ............................................................................................ 441
Data Validity During Bit Transfer on the I2C Bus ................................................... 441
Master Single SEND .......................................................................................... 445
Master Single RECEIVE ..................................................................................... 446
Master Burst SEND ........................................................................................... 447
Master Burst RECEIVE ...................................................................................... 448
Master Burst RECEIVE after Burst SEND ............................................................ 449
Master Burst SEND after Burst RECEIVE ............................................................ 450
Slave Command Sequence ................................................................................ 451
48-Pin QFP Package Pin Diagram ...................................................................... 475
Load Conditions ................................................................................................ 487
JTAG Test Clock Input Timing ............................................................................. 488
JTAG Test Access Port (TAP) Timing .................................................................. 489
JTAG TRST Timing ............................................................................................ 489
External Reset Timing (RST) .............................................................................. 490
Power-On Reset Timing ..................................................................................... 490
Brown-Out Reset Timing .................................................................................... 490
Software Reset Timing ....................................................................................... 491
Watchdog Reset Timing ..................................................................................... 491
LDO Reset Timing ............................................................................................. 491
ADC Input Equivalency Diagram ......................................................................... 493
SSI Timing for TI Frame Format (FRF=01), Single Transfer Timing
Measurement .................................................................................................... 494
Figure 17-13. SSI Timing for MICROWIRE Frame Format (FRF=10), Single Transfer ................. 494
Figure 17-14. SSI Timing for SPI Frame Format (FRF=00), with SPH=1 ..................................... 495
Figure 17-15. I2C Timing ......................................................................................................... 496
Figure D-1. Stellaris LM3S828 48-Pin LQFP Package ........................................................... 521
Figure D-2. 48-Pin LQFP Tray Dimensions ........................................................................... 523
Figure D-3. 48-Pin LQFP Tape and Reel Dimensions ............................................................. 525
10
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Stellaris LM3S828 Microcontroller
List of Tables
Table 1.
Table 2.
Table 2-1.
Table 2-2.
Table 2-3.
Table 2-4.
Table 2-5.
Table 2-6.
Table 2-7.
Table 2-8.
Table 2-9.
Table 2-10.
Table 2-11.
Table 2-12.
Table 2-13.
Table 3-1.
Table 3-2.
Table 3-3.
Table 3-4.
Table 3-5.
Table 3-6.
Table 3-7.
Table 3-8.
Table 3-9.
Table 4-1.
Table 4-2.
Table 4-3.
Table 5-1.
Table 5-2.
Table 5-3.
Table 5-4.
Table 5-5.
Table 5-6.
Table 6-1.
Table 6-2.
Table 7-1.
Table 7-2.
Table 7-3.
Table 7-4.
Table 7-5.
Table 7-6.
Table 8-1.
Table 8-2.
Table 8-3.
Table 8-4.
Table 9-1.
Revision History .................................................................................................. 19
Documentation Conventions ................................................................................ 24
Summary of Processor Mode, Privilege Level, and Stack Use ................................ 45
Processor Register Map ....................................................................................... 46
PSR Register Combinations ................................................................................. 51
Memory Map ....................................................................................................... 59
Memory Access Behavior ..................................................................................... 61
SRAM Memory Bit-Banding Regions .................................................................... 63
Peripheral Memory Bit-Banding Regions ............................................................... 63
Exception Types .................................................................................................. 69
Interrupts ............................................................................................................ 70
Exception Return Behavior ................................................................................... 74
Faults ................................................................................................................. 75
Fault Status and Fault Address Registers .............................................................. 76
Cortex-M3 Instruction Summary ........................................................................... 78
Core Peripheral Register Regions ......................................................................... 82
Memory Attributes Summary ................................................................................ 85
TEX, S, C, and B Bit Field Encoding ..................................................................... 88
Cache Policy for Memory Attribute Encoding ......................................................... 89
AP Bit Field Encoding .......................................................................................... 89
Memory Region Attributes for Stellaris Microcontrollers .......................................... 89
Peripherals Register Map ..................................................................................... 90
Interrupt Priority Levels ...................................................................................... 109
Example SIZE Field Values ................................................................................ 137
JTAG_SWD_SWO Signals (48QFP) ................................................................... 141
JTAG Port Pins Reset State ............................................................................... 142
JTAG Instruction Register Commands ................................................................. 146
System Control & Clocks Signals (48QFP) .......................................................... 150
Reset Sources ................................................................................................... 151
Clock Source Options ........................................................................................ 155
Possible System Clock Frequencies Using the SYSDIV Field ............................... 156
System Control Register Map ............................................................................. 160
PLL Mode Control .............................................................................................. 172
Flash Protection Policy Combinations ................................................................. 207
Flash Register Map ............................................................................................ 211
GPIO Pins With Non-Zero Reset Values .............................................................. 224
GPIO Pins and Alternate Functions (48QFP) ....................................................... 225
GPIO Signals (48QFP) ....................................................................................... 225
GPIO Pad Configuration Examples ..................................................................... 230
GPIO Interrupt Configuration Example ................................................................ 230
GPIO Register Map ........................................................................................... 231
Available CCP Pins ............................................................................................ 265
General-Purpose Timers Signals (48QFP) ........................................................... 266
16-Bit Timer With Prescaler Configurations ......................................................... 268
Timers Register Map .......................................................................................... 275
Watchdog Timer Register Map ............................................................................ 302
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Table 10-1.
Table 10-2.
Table 10-3.
Table 10-4.
Table 11-1.
Table 11-2.
Table 12-1.
Table 12-2.
Table 13-1.
Table 13-2.
Table 13-3.
Table 13-4.
Table 15-1.
Table 15-2.
Table 15-3.
Table 15-4.
Table 15-5.
Table 16-1.
Table 16-2.
Table 16-3.
Table 17-1.
Table 17-2.
Table 17-3.
Table 17-4.
Table 17-5.
Table 17-6.
Table 17-7.
Table 17-8.
Table 17-9.
Table 17-10.
Table 17-11.
Table 17-12.
Table 17-13.
Table 17-14.
Table 17-15.
Table 17-16.
Table 17-17.
Table C-1.
ADC Signals (48QFP) ........................................................................................ 325
Samples and FIFO Depth of Sequencers ............................................................ 326
Differential Sampling Pairs ................................................................................. 328
ADC Register Map ............................................................................................. 332
UART Signals (48QFP) ...................................................................................... 361
UART Register Map ........................................................................................... 366
SSI Signals (48QFP) .......................................................................................... 401
SSI Register Map .............................................................................................. 411
I2C Signals (48QFP) .......................................................................................... 439
Examples of I2C Master Timer Period versus Speed Mode ................................... 442
Inter-Integrated Circuit (I2C) Interface Register Map ............................................. 452
Write Field Decoding for I2CMCS[3:0] Field (Sheet 1 of 3) .................................... 457
Signals by Pin Number ....................................................................................... 476
Signals by Signal Name ..................................................................................... 478
Signals by Function, Except for GPIO ................................................................. 480
GPIO Pins and Alternate Functions ..................................................................... 481
Connections for Unused Signals ......................................................................... 482
Temperature Characteristics ............................................................................... 483
Thermal Characteristics ..................................................................................... 483
ESD Absolute Maximum Ratings ........................................................................ 483
Maximum Ratings .............................................................................................. 484
Recommended DC Operating Conditions ............................................................ 484
LDO Regulator Characteristics ........................................................................... 485
GPIO Module DC Characteristics ........................................................................ 485
Detailed Power Specifications ............................................................................ 486
Flash Memory Characteristics ............................................................................ 486
Phase Locked Loop (PLL) Characteristics ........................................................... 487
Clock Characteristics ......................................................................................... 487
System Clock Characteristics with ADC Operation ............................................... 487
JTAG Characteristics ......................................................................................... 487
Reset Characteristics ......................................................................................... 489
Sleep Modes AC Characteristics ......................................................................... 491
GPIO Characteristics ......................................................................................... 492
ADC Characteristics ........................................................................................... 492
ADC Module Internal Reference Characteristics .................................................. 493
SSI Characteristics ............................................................................................ 493
I2C Characteristics ............................................................................................. 495
Part Ordering Information ................................................................................... 519
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List of Registers
The Cortex-M3 Processor ............................................................................................................. 40
Register 1:
Register 2:
Register 3:
Register 4:
Register 5:
Register 6:
Register 7:
Register 8:
Register 9:
Register 10:
Register 11:
Register 12:
Register 13:
Register 14:
Register 15:
Register 16:
Register 17:
Register 18:
Register 19:
Register 20:
Register 21:
Cortex General-Purpose Register 0 (R0) ........................................................................... 47
Cortex General-Purpose Register 1 (R1) ........................................................................... 47
Cortex General-Purpose Register 2 (R2) ........................................................................... 47
Cortex General-Purpose Register 3 (R3) ........................................................................... 47
Cortex General-Purpose Register 4 (R4) ........................................................................... 47
Cortex General-Purpose Register 5 (R5) ........................................................................... 47
Cortex General-Purpose Register 6 (R6) ........................................................................... 47
Cortex General-Purpose Register 7 (R7) ........................................................................... 47
Cortex General-Purpose Register 8 (R8) ........................................................................... 47
Cortex General-Purpose Register 9 (R9) ........................................................................... 47
Cortex General-Purpose Register 10 (R10) ....................................................................... 47
Cortex General-Purpose Register 11 (R11) ........................................................................ 47
Cortex General-Purpose Register 12 (R12) ....................................................................... 47
Stack Pointer (SP) ........................................................................................................... 48
Link Register (LR) ............................................................................................................ 49
Program Counter (PC) ..................................................................................................... 50
Program Status Register (PSR) ........................................................................................ 51
Priority Mask Register (PRIMASK) .................................................................................... 55
Fault Mask Register (FAULTMASK) .................................................................................. 56
Base Priority Mask Register (BASEPRI) ............................................................................ 57
Control Register (CONTROL) ........................................................................................... 58
Cortex-M3 Peripherals ................................................................................................................... 82
Register 1:
Register 2:
Register 3:
Register 4:
Register 5:
Register 6:
Register 7:
Register 8:
Register 9:
Register 10:
Register 11:
Register 12:
Register 13:
Register 14:
Register 15:
Register 16:
Register 17:
Register 18:
Register 19:
Register 20:
Register 21:
Register 22:
SysTick Control and Status Register (STCTRL), offset 0x010 ............................................. 92
SysTick Reload Value Register (STRELOAD), offset 0x014 ................................................ 94
SysTick Current Value Register (STCURRENT), offset 0x018 ............................................. 95
Interrupt 0-29 Set Enable (EN0), offset 0x100 .................................................................... 96
Interrupt 0-29 Clear Enable (DIS0), offset 0x180 ................................................................ 97
Interrupt 0-29 Set Pending (PEND0), offset 0x200 ............................................................. 98
Interrupt 0-29 Clear Pending (UNPEND0), offset 0x280 ..................................................... 99
Interrupt 0-29 Active Bit (ACTIVE0), offset 0x300 ............................................................. 100
Interrupt 0-3 Priority (PRI0), offset 0x400 ......................................................................... 101
Interrupt 4-7 Priority (PRI1), offset 0x404 ......................................................................... 101
Interrupt 8-11 Priority (PRI2), offset 0x408 ....................................................................... 101
Interrupt 12-15 Priority (PRI3), offset 0x40C .................................................................... 101
Interrupt 16-19 Priority (PRI4), offset 0x410 ..................................................................... 101
Interrupt 20-23 Priority (PRI5), offset 0x414 ..................................................................... 101
Interrupt 24-27 Priority (PRI6), offset 0x418 ..................................................................... 101
Interrupt 28-29 Priority (PRI7), offset 0x41C .................................................................... 101
Software Trigger Interrupt (SWTRIG), offset 0xF00 .......................................................... 103
CPU ID Base (CPUID), offset 0xD00 ............................................................................... 104
Interrupt Control and State (INTCTRL), offset 0xD04 ........................................................ 105
Vector Table Offset (VTABLE), offset 0xD08 .................................................................... 108
Application Interrupt and Reset Control (APINT), offset 0xD0C ......................................... 109
System Control (SYSCTRL), offset 0xD10 ....................................................................... 111
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Register 23:
Register 24:
Register 25:
Register 26:
Register 27:
Register 28:
Register 29:
Register 30:
Register 31:
Register 32:
Register 33:
Register 34:
Register 35:
Register 36:
Register 37:
Register 38:
Register 39:
Register 40:
Register 41:
Register 42:
Configuration and Control (CFGCTRL), offset 0xD14 ....................................................... 113
System Handler Priority 1 (SYSPRI1), offset 0xD18 ......................................................... 115
System Handler Priority 2 (SYSPRI2), offset 0xD1C ........................................................ 116
System Handler Priority 3 (SYSPRI3), offset 0xD20 ......................................................... 117
System Handler Control and State (SYSHNDCTRL), offset 0xD24 .................................... 118
Configurable Fault Status (FAULTSTAT), offset 0xD28 ..................................................... 122
Hard Fault Status (HFAULTSTAT), offset 0xD2C .............................................................. 128
Memory Management Fault Address (MMADDR), offset 0xD34 ........................................ 129
Bus Fault Address (FAULTADDR), offset 0xD38 .............................................................. 130
MPU Type (MPUTYPE), offset 0xD90 ............................................................................. 131
MPU Control (MPUCTRL), offset 0xD94 .......................................................................... 132
MPU Region Number (MPUNUMBER), offset 0xD98 ....................................................... 134
MPU Region Base Address (MPUBASE), offset 0xD9C ................................................... 135
MPU Region Base Address Alias 1 (MPUBASE1), offset 0xDA4 ....................................... 135
MPU Region Base Address Alias 2 (MPUBASE2), offset 0xDAC ...................................... 135
MPU Region Base Address Alias 3 (MPUBASE3), offset 0xDB4 ....................................... 135
MPU Region Attribute and Size (MPUATTR), offset 0xDA0 ............................................... 137
MPU Region Attribute and Size Alias 1 (MPUATTR1), offset 0xDA8 .................................. 137
MPU Region Attribute and Size Alias 2 (MPUATTR2), offset 0xDB0 .................................. 137
MPU Region Attribute and Size Alias 3 (MPUATTR3), offset 0xDB8 .................................. 137
System Control ............................................................................................................................ 150
Register 1:
Register 2:
Register 3:
Register 4:
Register 5:
Register 6:
Register 7:
Register 8:
Register 9:
Register 10:
Register 11:
Register 12:
Register 13:
Register 14:
Register 15:
Register 16:
Register 17:
Register 18:
Register 19:
Register 20:
Register 21:
Register 22:
Register 23:
Register 24:
Register 25:
Register 26:
Register 27:
Device Identification 0 (DID0), offset 0x000 ..................................................................... 162
Power-On and Brown-Out Reset Control (PBORCTL), offset 0x030 .................................. 164
LDO Power Control (LDOPCTL), offset 0x034 ................................................................. 165
Raw Interrupt Status (RIS), offset 0x050 .......................................................................... 166
Interrupt Mask Control (IMC), offset 0x054 ...................................................................... 167
Masked Interrupt Status and Clear (MISC), offset 0x058 .................................................. 168
Reset Cause (RESC), offset 0x05C ................................................................................ 169
Run-Mode Clock Configuration (RCC), offset 0x060 ......................................................... 170
XTAL to PLL Translation (PLLCFG), offset 0x064 ............................................................. 173
Deep Sleep Clock Configuration (DSLPCLKCFG), offset 0x144 ........................................ 174
Clock Verification Clear (CLKVCLR), offset 0x150 ............................................................ 175
Allow Unregulated LDO to Reset the Part (LDOARST), offset 0x160 ................................. 176
Device Identification 1 (DID1), offset 0x004 ..................................................................... 177
Device Capabilities 0 (DC0), offset 0x008 ........................................................................ 179
Device Capabilities 1 (DC1), offset 0x010 ........................................................................ 180
Device Capabilities 2 (DC2), offset 0x014 ........................................................................ 182
Device Capabilities 3 (DC3), offset 0x018 ........................................................................ 184
Device Capabilities 4 (DC4), offset 0x01C ....................................................................... 186
Run Mode Clock Gating Control Register 0 (RCGC0), offset 0x100 ................................... 187
Sleep Mode Clock Gating Control Register 0 (SCGC0), offset 0x110 ................................. 189
Deep Sleep Mode Clock Gating Control Register 0 (DCGC0), offset 0x120 ....................... 191
Run Mode Clock Gating Control Register 1 (RCGC1), offset 0x104 ................................... 192
Sleep Mode Clock Gating Control Register 1 (SCGC1), offset 0x114 ................................. 194
Deep Sleep Mode Clock Gating Control Register 1 (DCGC1), offset 0x124 ....................... 196
Run Mode Clock Gating Control Register 2 (RCGC2), offset 0x108 ................................... 198
Sleep Mode Clock Gating Control Register 2 (SCGC2), offset 0x118 ................................. 199
Deep Sleep Mode Clock Gating Control Register 2 (DCGC2), offset 0x128 ....................... 201
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Register 28:
Register 29:
Register 30:
Software Reset Control 0 (SRCR0), offset 0x040 ............................................................. 203
Software Reset Control 1 (SRCR1), offset 0x044 ............................................................. 204
Software Reset Control 2 (SRCR2), offset 0x048 ............................................................. 205
Internal Memory ........................................................................................................................... 206
Register 1:
Register 2:
Register 3:
Register 4:
Register 5:
Register 6:
Register 7:
Register 8:
Register 9:
Flash Memory Address (FMA), offset 0x000 .................................................................... 212
Flash Memory Data (FMD), offset 0x004 ......................................................................... 213
Flash Memory Control (FMC), offset 0x008 ..................................................................... 214
Flash Controller Raw Interrupt Status (FCRIS), offset 0x00C ............................................ 216
Flash Controller Interrupt Mask (FCIM), offset 0x010 ........................................................ 217
Flash Controller Masked Interrupt Status and Clear (FCMISC), offset 0x014 ..................... 218
USec Reload (USECRL), offset 0x140 ............................................................................ 220
Flash Memory Protection Read Enable (FMPRE), offset 0x130 ......................................... 221
Flash Memory Protection Program Enable (FMPPE), offset 0x134 .................................... 222
General-Purpose Input/Outputs (GPIOs) ................................................................................... 223
Register 1:
Register 2:
Register 3:
Register 4:
Register 5:
Register 6:
Register 7:
Register 8:
Register 9:
Register 10:
Register 11:
Register 12:
Register 13:
Register 14:
Register 15:
Register 16:
Register 17:
Register 18:
Register 19:
Register 20:
Register 21:
Register 22:
Register 23:
Register 24:
Register 25:
Register 26:
Register 27:
Register 28:
Register 29:
Register 30:
GPIO Data (GPIODATA), offset 0x000 ............................................................................ 233
GPIO Direction (GPIODIR), offset 0x400 ......................................................................... 234
GPIO Interrupt Sense (GPIOIS), offset 0x404 .................................................................. 235
GPIO Interrupt Both Edges (GPIOIBE), offset 0x408 ........................................................ 236
GPIO Interrupt Event (GPIOIEV), offset 0x40C ................................................................ 237
GPIO Interrupt Mask (GPIOIM), offset 0x410 ................................................................... 238
GPIO Raw Interrupt Status (GPIORIS), offset 0x414 ........................................................ 239
GPIO Masked Interrupt Status (GPIOMIS), offset 0x418 ................................................... 240
GPIO Interrupt Clear (GPIOICR), offset 0x41C ................................................................ 241
GPIO Alternate Function Select (GPIOAFSEL), offset 0x420 ............................................ 242
GPIO 2-mA Drive Select (GPIODR2R), offset 0x500 ........................................................ 244
GPIO 4-mA Drive Select (GPIODR4R), offset 0x504 ........................................................ 245
GPIO 8-mA Drive Select (GPIODR8R), offset 0x508 ........................................................ 246
GPIO Open Drain Select (GPIOODR), offset 0x50C ......................................................... 247
GPIO Pull-Up Select (GPIOPUR), offset 0x510 ................................................................ 248
GPIO Pull-Down Select (GPIOPDR), offset 0x514 ........................................................... 249
GPIO Slew Rate Control Select (GPIOSLR), offset 0x518 ................................................ 250
GPIO Digital Enable (GPIODEN), offset 0x51C ................................................................ 251
GPIO Peripheral Identification 4 (GPIOPeriphID4), offset 0xFD0 ....................................... 252
GPIO Peripheral Identification 5 (GPIOPeriphID5), offset 0xFD4 ....................................... 253
GPIO Peripheral Identification 6 (GPIOPeriphID6), offset 0xFD8 ....................................... 254
GPIO Peripheral Identification 7 (GPIOPeriphID7), offset 0xFDC ...................................... 255
GPIO Peripheral Identification 0 (GPIOPeriphID0), offset 0xFE0 ....................................... 256
GPIO Peripheral Identification 1 (GPIOPeriphID1), offset 0xFE4 ....................................... 257
GPIO Peripheral Identification 2 (GPIOPeriphID2), offset 0xFE8 ....................................... 258
GPIO Peripheral Identification 3 (GPIOPeriphID3), offset 0xFEC ...................................... 259
GPIO PrimeCell Identification 0 (GPIOPCellID0), offset 0xFF0 .......................................... 260
GPIO PrimeCell Identification 1 (GPIOPCellID1), offset 0xFF4 .......................................... 261
GPIO PrimeCell Identification 2 (GPIOPCellID2), offset 0xFF8 .......................................... 262
GPIO PrimeCell Identification 3 (GPIOPCellID3), offset 0xFFC ......................................... 263
General-Purpose Timers ............................................................................................................. 264
Register 1:
Register 2:
Register 3:
GPTM Configuration (GPTMCFG), offset 0x000 .............................................................. 276
GPTM TimerA Mode (GPTMTAMR), offset 0x004 ............................................................ 277
GPTM TimerB Mode (GPTMTBMR), offset 0x008 ............................................................ 279
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Register 4:
Register 5:
Register 6:
Register 7:
Register 8:
Register 9:
Register 10:
Register 11:
Register 12:
Register 13:
Register 14:
Register 15:
Register 16:
Register 17:
Register 18:
GPTM Control (GPTMCTL), offset 0x00C ........................................................................ 281
GPTM Interrupt Mask (GPTMIMR), offset 0x018 .............................................................. 284
GPTM Raw Interrupt Status (GPTMRIS), offset 0x01C ..................................................... 286
GPTM Masked Interrupt Status (GPTMMIS), offset 0x020 ................................................ 287
GPTM Interrupt Clear (GPTMICR), offset 0x024 .............................................................. 288
GPTM TimerA Interval Load (GPTMTAILR), offset 0x028 ................................................. 290
GPTM TimerB Interval Load (GPTMTBILR), offset 0x02C ................................................ 291
GPTM TimerA Match (GPTMTAMATCHR), offset 0x030 ................................................... 292
GPTM TimerB Match (GPTMTBMATCHR), offset 0x034 .................................................. 293
GPTM TimerA Prescale (GPTMTAPR), offset 0x038 ........................................................ 294
GPTM TimerB Prescale (GPTMTBPR), offset 0x03C ....................................................... 295
GPTM TimerA Prescale Match (GPTMTAPMR), offset 0x040 ........................................... 296
GPTM TimerB Prescale Match (GPTMTBPMR), offset 0x044 ........................................... 297
GPTM TimerA (GPTMTAR), offset 0x048 ........................................................................ 298
GPTM TimerB (GPTMTBR), offset 0x04C ....................................................................... 299
Watchdog Timer ........................................................................................................................... 300
Register 1:
Register 2:
Register 3:
Register 4:
Register 5:
Register 6:
Register 7:
Register 8:
Register 9:
Register 10:
Register 11:
Register 12:
Register 13:
Register 14:
Register 15:
Register 16:
Register 17:
Register 18:
Register 19:
Register 20:
Watchdog Load (WDTLOAD), offset 0x000 ...................................................................... 304
Watchdog Value (WDTVALUE), offset 0x004 ................................................................... 305
Watchdog Control (WDTCTL), offset 0x008 ..................................................................... 306
Watchdog Interrupt Clear (WDTICR), offset 0x00C .......................................................... 307
Watchdog Raw Interrupt Status (WDTRIS), offset 0x010 .................................................. 308
Watchdog Masked Interrupt Status (WDTMIS), offset 0x014 ............................................. 309
Watchdog Test (WDTTEST), offset 0x418 ....................................................................... 310
Watchdog Lock (WDTLOCK), offset 0xC00 ..................................................................... 311
Watchdog Peripheral Identification 4 (WDTPeriphID4), offset 0xFD0 ................................. 312
Watchdog Peripheral Identification 5 (WDTPeriphID5), offset 0xFD4 ................................. 313
Watchdog Peripheral Identification 6 (WDTPeriphID6), offset 0xFD8 ................................. 314
Watchdog Peripheral Identification 7 (WDTPeriphID7), offset 0xFDC ................................ 315
Watchdog Peripheral Identification 0 (WDTPeriphID0), offset 0xFE0 ................................. 316
Watchdog Peripheral Identification 1 (WDTPeriphID1), offset 0xFE4 ................................. 317
Watchdog Peripheral Identification 2 (WDTPeriphID2), offset 0xFE8 ................................. 318
Watchdog Peripheral Identification 3 (WDTPeriphID3), offset 0xFEC ................................. 319
Watchdog PrimeCell Identification 0 (WDTPCellID0), offset 0xFF0 .................................... 320
Watchdog PrimeCell Identification 1 (WDTPCellID1), offset 0xFF4 .................................... 321
Watchdog PrimeCell Identification 2 (WDTPCellID2), offset 0xFF8 .................................... 322
Watchdog PrimeCell Identification 3 (WDTPCellID3 ), offset 0xFFC .................................. 323
Analog-to-Digital Converter (ADC) ............................................................................................. 324
Register 1:
Register 2:
Register 3:
Register 4:
Register 5:
Register 6:
Register 7:
Register 8:
Register 9:
Register 10:
Register 11:
ADC Active Sample Sequencer (ADCACTSS), offset 0x000 ............................................. 334
ADC Raw Interrupt Status (ADCRIS), offset 0x004 ........................................................... 335
ADC Interrupt Mask (ADCIM), offset 0x008 ..................................................................... 336
ADC Interrupt Status and Clear (ADCISC), offset 0x00C .................................................. 337
ADC Overflow Status (ADCOSTAT), offset 0x010 ............................................................ 338
ADC Event Multiplexer Select (ADCEMUX), offset 0x014 ................................................. 339
ADC Underflow Status (ADCUSTAT), offset 0x018 ........................................................... 342
ADC Sample Sequencer Priority (ADCSSPRI), offset 0x020 ............................................. 343
ADC Processor Sample Sequence Initiate (ADCPSSI), offset 0x028 ................................. 345
ADC Sample Averaging Control (ADCSAC), offset 0x030 ................................................. 346
ADC Sample Sequence Input Multiplexer Select 0 (ADCSSMUX0), offset 0x040 ............... 347
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Register 12:
Register 13:
Register 14:
Register 15:
Register 16:
Register 17:
Register 18:
Register 19:
Register 20:
Register 21:
Register 22:
Register 23:
Register 24:
Register 25:
Register 26:
Register 27:
ADC Sample Sequence Control 0 (ADCSSCTL0), offset 0x044 ........................................ 349
ADC Sample Sequence Result FIFO 0 (ADCSSFIFO0), offset 0x048 ................................ 352
ADC Sample Sequence Result FIFO 1 (ADCSSFIFO1), offset 0x068 ................................ 352
ADC Sample Sequence Result FIFO 2 (ADCSSFIFO2), offset 0x088 ................................ 352
ADC Sample Sequence Result FIFO 3 (ADCSSFIFO3), offset 0x0A8 ............................... 352
ADC Sample Sequence FIFO 0 Status (ADCSSFSTAT0), offset 0x04C ............................. 353
ADC Sample Sequence FIFO 1 Status (ADCSSFSTAT1), offset 0x06C ............................. 353
ADC Sample Sequence FIFO 2 Status (ADCSSFSTAT2), offset 0x08C ............................ 353
ADC Sample Sequence FIFO 3 Status (ADCSSFSTAT3), offset 0x0AC ............................ 353
ADC Sample Sequence Input Multiplexer Select 1 (ADCSSMUX1), offset 0x060 ............... 354
ADC Sample Sequence Input Multiplexer Select 2 (ADCSSMUX2), offset 0x080 ............... 354
ADC Sample Sequence Control 1 (ADCSSCTL1), offset 0x064 ........................................ 355
ADC Sample Sequence Control 2 (ADCSSCTL2), offset 0x084 ........................................ 355
ADC Sample Sequence Input Multiplexer Select 3 (ADCSSMUX3), offset 0x0A0 ............... 357
ADC Sample Sequence Control 3 (ADCSSCTL3), offset 0x0A4 ........................................ 358
ADC Test Mode Loopback (ADCTMLB), offset 0x100 ....................................................... 359
Universal Asynchronous Receivers/Transmitters (UARTs) ..................................................... 360
Register 1:
Register 2:
Register 3:
Register 4:
Register 5:
Register 6:
Register 7:
Register 8:
Register 9:
Register 10:
Register 11:
Register 12:
Register 13:
Register 14:
Register 15:
Register 16:
Register 17:
Register 18:
Register 19:
Register 20:
Register 21:
Register 22:
Register 23:
Register 24:
UART Data (UARTDR), offset 0x000 ............................................................................... 368
UART Receive Status/Error Clear (UARTRSR/UARTECR), offset 0x004 ........................... 370
UART Flag (UARTFR), offset 0x018 ................................................................................ 372
UART Integer Baud-Rate Divisor (UARTIBRD), offset 0x024 ............................................ 374
UART Fractional Baud-Rate Divisor (UARTFBRD), offset 0x028 ....................................... 375
UART Line Control (UARTLCRH), offset 0x02C ............................................................... 376
UART Control (UARTCTL), offset 0x030 ......................................................................... 378
UART Interrupt FIFO Level Select (UARTIFLS), offset 0x034 ........................................... 380
UART Interrupt Mask (UARTIM), offset 0x038 ................................................................. 382
UART Raw Interrupt Status (UARTRIS), offset 0x03C ...................................................... 384
UART Masked Interrupt Status (UARTMIS), offset 0x040 ................................................. 385
UART Interrupt Clear (UARTICR), offset 0x044 ............................................................... 386
UART Peripheral Identification 4 (UARTPeriphID4), offset 0xFD0 ..................................... 388
UART Peripheral Identification 5 (UARTPeriphID5), offset 0xFD4 ..................................... 389
UART Peripheral Identification 6 (UARTPeriphID6), offset 0xFD8 ..................................... 390
UART Peripheral Identification 7 (UARTPeriphID7), offset 0xFDC ..................................... 391
UART Peripheral Identification 0 (UARTPeriphID0), offset 0xFE0 ...................................... 392
UART Peripheral Identification 1 (UARTPeriphID1), offset 0xFE4 ...................................... 393
UART Peripheral Identification 2 (UARTPeriphID2), offset 0xFE8 ...................................... 394
UART Peripheral Identification 3 (UARTPeriphID3), offset 0xFEC ..................................... 395
UART PrimeCell Identification 0 (UARTPCellID0), offset 0xFF0 ........................................ 396
UART PrimeCell Identification 1 (UARTPCellID1), offset 0xFF4 ........................................ 397
UART PrimeCell Identification 2 (UARTPCellID2), offset 0xFF8 ........................................ 398
UART PrimeCell Identification 3 (UARTPCellID3), offset 0xFFC ........................................ 399
Synchronous Serial Interface (SSI) ............................................................................................ 400
Register 1:
Register 2:
Register 3:
Register 4:
Register 5:
Register 6:
SSI Control 0 (SSICR0), offset 0x000 ..............................................................................
SSI Control 1 (SSICR1), offset 0x004 ..............................................................................
SSI Data (SSIDR), offset 0x008 ......................................................................................
SSI Status (SSISR), offset 0x00C ...................................................................................
SSI Clock Prescale (SSICPSR), offset 0x010 ..................................................................
SSI Interrupt Mask (SSIIM), offset 0x014 .........................................................................
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415
417
418
420
421
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Register 7:
Register 8:
Register 9:
Register 10:
Register 11:
Register 12:
Register 13:
Register 14:
Register 15:
Register 16:
Register 17:
Register 18:
Register 19:
Register 20:
Register 21:
SSI Raw Interrupt Status (SSIRIS), offset 0x018 .............................................................. 423
SSI Masked Interrupt Status (SSIMIS), offset 0x01C ........................................................ 424
SSI Interrupt Clear (SSIICR), offset 0x020 ....................................................................... 425
SSI Peripheral Identification 4 (SSIPeriphID4), offset 0xFD0 ............................................. 426
SSI Peripheral Identification 5 (SSIPeriphID5), offset 0xFD4 ............................................. 427
SSI Peripheral Identification 6 (SSIPeriphID6), offset 0xFD8 ............................................. 428
SSI Peripheral Identification 7 (SSIPeriphID7), offset 0xFDC ............................................ 429
SSI Peripheral Identification 0 (SSIPeriphID0), offset 0xFE0 ............................................. 430
SSI Peripheral Identification 1 (SSIPeriphID1), offset 0xFE4 ............................................. 431
SSI Peripheral Identification 2 (SSIPeriphID2), offset 0xFE8 ............................................. 432
SSI Peripheral Identification 3 (SSIPeriphID3), offset 0xFEC ............................................ 433
SSI PrimeCell Identification 0 (SSIPCellID0), offset 0xFF0 ............................................... 434
SSI PrimeCell Identification 1 (SSIPCellID1), offset 0xFF4 ............................................... 435
SSI PrimeCell Identification 2 (SSIPCellID2), offset 0xFF8 ............................................... 436
SSI PrimeCell Identification 3 (SSIPCellID3), offset 0xFFC ............................................... 437
Inter-Integrated Circuit (I2C) Interface ........................................................................................ 438
Register 1:
Register 2:
Register 3:
Register 4:
Register 5:
Register 6:
Register 7:
Register 8:
Register 9:
Register 10:
Register 11:
Register 12:
Register 13:
Register 14:
Register 15:
Register 16:
I2C Master Slave Address (I2CMSA), offset 0x000 ........................................................... 454
I2C Master Control/Status (I2CMCS), offset 0x004 ........................................................... 455
I2C Master Data (I2CMDR), offset 0x008 ......................................................................... 459
I2C Master Timer Period (I2CMTPR), offset 0x00C ........................................................... 460
I2C Master Interrupt Mask (I2CMIMR), offset 0x010 ......................................................... 461
I2C Master Raw Interrupt Status (I2CMRIS), offset 0x014 ................................................. 462
I2C Master Masked Interrupt Status (I2CMMIS), offset 0x018 ........................................... 463
I2C Master Interrupt Clear (I2CMICR), offset 0x01C ......................................................... 464
I2C Master Configuration (I2CMCR), offset 0x020 ............................................................ 465
I2C Slave Own Address (I2CSOAR), offset 0x800 ............................................................ 467
I2C Slave Control/Status (I2CSCSR), offset 0x804 ........................................................... 468
I2C Slave Data (I2CSDR), offset 0x808 ........................................................................... 470
I2C Slave Interrupt Mask (I2CSIMR), offset 0x80C ........................................................... 471
I2C Slave Raw Interrupt Status (I2CSRIS), offset 0x810 ................................................... 472
I2C Slave Masked Interrupt Status (I2CSMIS), offset 0x814 .............................................. 473
I2C Slave Interrupt Clear (I2CSICR), offset 0x818 ............................................................ 474
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Revision History
The revision history table notes changes made between the indicated revisions of the LM3S828
data sheet.
Table 1. Revision History
Date
June 2012
November 2011
Revision
Description
12739.2515 ■
11107
In Reset Characteristics table, changed values and units for Internal reset timeout after hardware
reset (R7).
■
Removed 48QFN package.
■
Removed extended temperature package.
■
Minor data sheet clarifications and corrections.
■
Added module-specific pin tables to each chapter in the new Signal Description sections.
■
In Timer chapter, clarified that in 16-Bit Input Edge Time Mode, the timer is capable of capturing
three types of events: rising edge, falling edge, or both.
■
In UART chapter, clarified interrupt behavior.
■
In SSI chapter, corrected SSIClk in the figure "Synchronous Serial Frame Format (Single Transfer)".
■
In Signal Tables chapter:
–
■
■
Corrected pin numbers in table "Connections for Unused Signals" (other pin tables were correct).
In Electrical Characteristics chapter:
–
Added parameter "Input voltage for a GPIO configured as an analog input" to the "Maximum
Ratings" table.
–
Corrected Nom values for parameters "TCK clock Low time" and "TCK clock High time" in "JTAG
Characteristics" table.
Additional minor data sheet clarifications and corrections.
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Revision History
Table 1. Revision History (continued)
Date
Revision
January 2011
9102
September 2010
June 2010
7783
7393
Description
■
In Application Interrupt and Reset Control (APINT) register, changed bit name from SYSRESETREQ
to SYSRESREQ.
■
Added DEBUG (Debug Priority) bit field to System Handler Priority 3 (SYSPRI3) register.
■
Added "Reset Sources" table to System Control chapter.
■
Removed mention of false-start bit detection in the UART chapter. This feature is not supported.
■
Added note that specific module clocks must be enabled before that module's registers can be
programmed. There must be a delay of 3 system clocks after the module clock is enabled before
any of that module's registers are accessed.
■
Changed I2C slave register base addresses and offsets to be relative to the I2C module base address
of 0x4002.0000 , so register bases and offsets were changed for all I2C slave registers. Note that
®
the hw_i2c.h file in the StellarisWare Driver Library uses a base address of 0x4002.0800 for the
2
I C slave registers. Be aware when using registers with offsets between 0x800 and 0x818 that
StellarisWare uses the old slave base address for these offsets.
■
Corrected nonlinearity and offset error parameters (EL, ED, and EO) in ADC Characteristics table.
■
Added specification for maximum input voltage on a non-power pin when the microcontroller is
unpowered (VNON parameter in Maximum Ratings table).
■
Additional minor data sheet clarifications and corrections.
■
Reorganized ARM Cortex-M3 Processor Core, Memory Map and Interrupts chapters, creating two
new chapters, The Cortex-M3 Processor and Cortex-M3 Peripherals. Much additional content was
added, including all the Cortex-M3 registers.
■
Changed register names to be consistent with StellarisWare names: the Cortex-M3 Interrupt Control
and Status (ICSR) register to the Interrupt Control and State (INTCTRL) register, and the
Cortex-M3 Interrupt Set Enable (SETNA) register to the Interrupt 0-31 Set Enable (EN0) register.
■
Added clarification of instruction execution during Flash operations.
■
Modified Figure 7-2 on page 227 to clarify operation of the GPIO inputs when used as an alternate
function.
■
Added caution not to apply a Low value to PB7 when debugging; a Low value on the pin causes
the JTAG controller to be reset, resulting in a loss of JTAG communication.
■
In General-Purpose Timers chapter, clarified operation of the 32-bit RTC mode.
■
Added missing table "Connections for Unused Signals" (Table 15-5 on page 482).
■
In Electrical Characteristics chapter:
– Added ILKG parameter (GPIO input leakage current) to Table 17-4 on page 485.
– Corrected values for tCLKRF parameter (SSIClk rise/fall time) in Table 17-16 on page 493.
■
Added dimensions for Tray and Tape and Reel shipping mediums.
■
Corrected base address for SRAM in architectural overview chapter.
■
Clarified system clock operation, adding content to “Clock Control” on page 155.
■
In Signal Tables chapter, added table "Connections for Unused Signals."
■
In "Reset Characteristics" table, corrected value for supply voltage (VDD) rise time.
■
Additional minor data sheet clarifications and corrections.
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Table 1. Revision History (continued)
Date
Revision
April 2010
7004
January 2010
6712
Description
■
Added caution note to the I2C Master Timer Period (I2CMTPR) register description and changed
field width to 7 bits.
■
Added note about RST signal routing.
■
Clarified the function of the TnSTALL bit in the GPTMCTL register.
■
Additional minor data sheet clarifications and corrections.
■
In "System Control" section, clarified Debug Access Port operation after Sleep modes.
■
Clarified wording on Flash memory access errors.
■
Added section on Flash interrupts.
■
Changed the reset value of the ADC Sample Sequence Result FIFO n (ADCSSFIFOn) registers
to be indeterminate.
■
Clarified operation of SSI transmit FIFO.
■
Made these changes to the Operating Characteristics chapter:
■
October 2009
July 2009
6438
5953
–
Added storage temperature ratings to "Temperature Characteristics" table
–
Added "ESD Absolute Maximum Ratings" table
Made these changes to the Electrical Characteristics chapter:
–
In "Flash Memory Characteristics" table, corrected Mass erase time
–
Added sleep and deep-sleep wake-up times ("Sleep Modes AC Characteristics" table)
–
In "Reset Characteristics" table, corrected supply voltage (VDD) rise time
■
The reset value for the DID1 register may change, depending on the package.
■
Deleted MAXADCSPD bit field from DCGC0 register as it is not applicable in Deep-Sleep mode.
■
Deleted reset value for 16-bit mode from GPTMTAILR, GPTMTAMATCHR, and GPTMTAR registers
because the module resets in 32-bit mode.
■
Made these changes to the Electrical Characteristics chapter:
–
Removed VSIH and VSIL parameters from Operating Conditions table.
–
Changed SSI set up and hold times to be expressed in system clocks, not ns.
–
Revised ADC electrical specifications to clarify, including reorganizing and adding new data.
■
Added 48QFN package.
■
Additional minor data sheet clarifications and corrections.
■
Clarified Power-on reset and RST pin operation; added new diagrams.
■
Added DBG bits missing from FMPRE register. This changes register reset value.
■
In ADC characteristics table, changed Max value for GAIN parameter from ±1 to ±3 and added EIR
(Internal voltage reference error) parameter.
■
Corrected ordering numbers.
■
Additional minor data sheet clarifications and corrections.
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Revision History
Table 1. Revision History (continued)
Date
Revision
April 2009
5369
January 2009
November 2008
October 2008
4644
4283
4149
Description
■
Added JTAG/SWD clarification (see “Communication with JTAG/SWD” on page 145).
■
Added "GPIO Module DC Characteristics" table (see Table 17-4 on page 485).
■
Additional minor data sheet clarifications and corrections.
■
Incorrect bit type for RELOAD bit field in SysTick Reload Value register; changed to R/W.
■
Clarification added as to what happens when the SSI in slave mode is required to transmit but there
is no data in the TX FIFO.
■
Minor corrections to comparator operating mode tables.
■
Additional minor data sheet clarifications and corrections.
■
Revised High-Level Block Diagram.
■
Corrected descriptions for UART1 signals.
■
Additional minor data sheet clarifications and corrections were made.
■
Added note on clearing interrupts to the Interrupts chapter:
Note:
■
It may take several processor cycles after a write to clear an interrupt source in order for
NVIC to see the interrupt source de-assert. This means if the interrupt clear is done as
the last action in an interrupt handler, it is possible for the interrupt handler to complete
while NVIC sees the interrupt as still asserted, causing the interrupt handler to be
re-entered errantly. This can be avoided by either clearing the interrupt source at the
beginning of the interrupt handler or by performing a read or write after the write to clear
the interrupt source (and flush the write buffer)
Step 1 of the Initialization and Configuration procedure in the ADC chapter states the wrong register
to use to enable the ADC clock. Sentence changed to:
1. Enable the ADC clock by writing a value of 0x0001.0000 to the RCGC0 register.
■
June 2008
2972
Additional minor data sheet clarifications and corrections were made.
Started tracking revision history.
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About This Document
This data sheet provides reference information for the LM3S828 microcontroller, describing the
functional blocks of the system-on-chip (SoC) device designed around the ARM® Cortex™-M3
core.
Audience
This manual is intended for system software developers, hardware designers, and application
developers.
About This Manual
This document is organized into sections that correspond to each major feature.
Related Documents
®
The following related documents are available on the Stellaris web site at www.ti.com/stellaris:
■ Stellaris® Errata
■ ARM® Cortex™-M3 Errata
■ Cortex™-M3/M4 Instruction Set Technical User's Manual
■ Stellaris® Graphics Library User's Guide
■ Stellaris® Peripheral Driver Library User's Guide
The following related documents are also referenced:
■ ARM® Debug Interface V5 Architecture Specification
■ ARM® Embedded Trace Macrocell Architecture Specification
■ IEEE Standard 1149.1-Test Access Port and Boundary-Scan Architecture
This documentation list was current as of publication date. Please check the web site for additional
documentation, including application notes and white papers.
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About This Document
Documentation Conventions
This document uses the conventions shown in Table 2 on page 24.
Table 2. Documentation Conventions
Notation
Meaning
General Register Notation
REGISTER
APB registers are indicated in uppercase bold. For example, PBORCTL is the Power-On and
Brown-Out Reset Control register. If a register name contains a lowercase n, it represents more
than one register. For example, SRCRn represents any (or all) of the three Software Reset Control
registers: SRCR0, SRCR1 , and SRCR2.
bit
A single bit in a register.
bit field
Two or more consecutive and related bits.
offset 0xnnn
A hexadecimal increment to a register's address, relative to that module's base address as specified
in Table 2-4 on page 59.
Register N
Registers are numbered consecutively throughout the document to aid in referencing them. The
register number has no meaning to software.
reserved
Register bits marked reserved are reserved for future use. In most cases, reserved bits are set to
0; however, user software should not rely on the value of a reserved bit. To provide software
compatibility with future products, the value of a reserved bit should be preserved across a
read-modify-write operation.
yy:xx
The range of register bits inclusive from xx to yy. For example, 31:15 means bits 15 through 31 in
that register.
Register Bit/Field
Types
This value in the register bit diagram indicates whether software running on the controller can
change the value of the bit field.
RC
Software can read this field. The bit or field is cleared by hardware after reading the bit/field.
RO
Software can read this field. Always write the chip reset value.
R/W
Software can read or write this field.
R/WC
Software can read or write this field. Writing to it with any value clears the register.
R/W1C
Software can read or write this field. A write of a 0 to a W1C bit does not affect the bit value in the
register. A write of a 1 clears the value of the bit in the register; the remaining bits remain unchanged.
This register type is primarily used for clearing interrupt status bits where the read operation
provides the interrupt status and the write of the read value clears only the interrupts being reported
at the time the register was read.
R/W1S
Software can read or write a 1 to this field. A write of a 0 to a R/W1S bit does not affect the bit
value in the register.
W1C
Software can write this field. A write of a 0 to a W1C bit does not affect the bit value in the register.
A write of a 1 clears the value of the bit in the register; the remaining bits remain unchanged. A
read of the register returns no meaningful data.
This register is typically used to clear the corresponding bit in an interrupt register.
WO
Only a write by software is valid; a read of the register returns no meaningful data.
Register Bit/Field
Reset Value
This value in the register bit diagram shows the bit/field value after any reset, unless noted.
0
Bit cleared to 0 on chip reset.
1
Bit set to 1 on chip reset.
-
Nondeterministic.
Pin/Signal Notation
[]
Pin alternate function; a pin defaults to the signal without the brackets.
pin
Refers to the physical connection on the package.
signal
Refers to the electrical signal encoding of a pin.
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Table 2. Documentation Conventions (continued)
Notation
Meaning
assert a signal
Change the value of the signal from the logically False state to the logically True state. For active
High signals, the asserted signal value is 1 (High); for active Low signals, the asserted signal value
is 0 (Low). The active polarity (High or Low) is defined by the signal name (see SIGNAL and SIGNAL
below).
deassert a signal
Change the value of the signal from the logically True state to the logically False state.
SIGNAL
Signal names are in uppercase and in the Courier font. An overbar on a signal name indicates that
it is active Low. To assert SIGNAL is to drive it Low; to deassert SIGNAL is to drive it High.
SIGNAL
Signal names are in uppercase and in the Courier font. An active High signal has no overbar. To
assert SIGNAL is to drive it High; to deassert SIGNAL is to drive it Low.
Numbers
X
An uppercase X indicates any of several values is allowed, where X can be any legal pattern. For
example, a binary value of 0X00 can be either 0100 or 0000, a hex value of 0xX is 0x0 or 0x1, and
so on.
0x
Hexadecimal numbers have a prefix of 0x. For example, 0x00FF is the hexadecimal number FF.
All other numbers within register tables are assumed to be binary. Within conceptual information,
binary numbers are indicated with a b suffix, for example, 1011b, and decimal numbers are written
without a prefix or suffix.
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Architectural Overview
1
Architectural Overview
®
The Stellaris family of microcontrollers—the first ARM® Cortex™-M3 based controllers—brings
high-performance 32-bit computing to cost-sensitive embedded microcontroller applications. These
pioneering parts deliver customers 32-bit performance at a cost equivalent to legacy 8- and 16-bit
devices, all in a package with a small footprint.
The LM3S828 microcontroller is targeted for industrial applications, including test and measurement
equipment, factory automation, HVAC and building control, motion control, medical instrumentation,
fire and security, and power/energy.
In addition, the LM3S828 microcontroller offers the advantages of ARM's widely available
development tools, System-on-Chip (SoC) infrastructure IP applications, and a large user community.
Additionally, the microcontroller uses ARM's Thumb®-compatible Thumb-2 instruction set to reduce
memory requirements and, thereby, cost. Finally, the LM3S828 microcontroller is code-compatible
to all members of the extensive Stellaris family; providing flexibility to fit our customers' precise
needs.
Texas Instruments offers a complete solution to get to market quickly, with evaluation and
development boards, white papers and application notes, an easy-to-use peripheral driver library,
and a strong support, sales, and distributor network. See “Ordering and Contact
Information” on page 519 for ordering information for Stellaris family devices.
1.1
Product Features
The LM3S828 microcontroller includes the following product features:
■ 32-Bit RISC Performance
– 32-bit ARM® Cortex™-M3 v7M architecture optimized for small-footprint embedded
applications
– System timer (SysTick), providing a simple, 24-bit clear-on-write, decrementing, wrap-on-zero
counter with a flexible control mechanism
– Thumb®-compatible Thumb-2-only instruction set processor core for high code density
– 50-MHz operation
– Hardware-division and single-cycle-multiplication
– Integrated Nested Vectored Interrupt Controller (NVIC) providing deterministic interrupt
handling
– 22 interrupts with eight priority levels
– Memory protection unit (MPU), providing a privileged mode for protected operating system
functionality
– Unaligned data access, enabling data to be efficiently packed into memory
– Atomic bit manipulation (bit-banding), delivering maximum memory utilization and streamlined
peripheral control
■ ARM® Cortex™-M3 Processor Core
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– Compact core.
– Thumb-2 instruction set, delivering the high-performance expected of an ARM core in the
memory size usually associated with 8- and 16-bit devices; typically in the range of a few
kilobytes of memory for microcontroller class applications.
– Rapid application execution through Harvard architecture characterized by separate buses
for instruction and data.
– Exceptional interrupt handling, by implementing the register manipulations required for handling
an interrupt in hardware.
– Deterministic, fast interrupt processing: always 12 cycles, or just 6 cycles with tail-chaining
– Memory protection unit (MPU) to provide a privileged mode of operation for complex
applications.
– Migration from the ARM7™ processor family for better performance and power efficiency.
– Full-featured debug solution
•
Serial Wire JTAG Debug Port (SWJ-DP)
•
Flash Patch and Breakpoint (FPB) unit for implementing breakpoints
•
Data Watchpoint and Trigger (DWT) unit for implementing watchpoints, trigger resources,
and system profiling
•
Instrumentation Trace Macrocell (ITM) for support of printf style debugging
•
Trace Port Interface Unit (TPIU) for bridging to a Trace Port Analyzer
– Optimized for single-cycle flash usage
– Three sleep modes with clock gating for low power
– Single-cycle multiply instruction and hardware divide
– Atomic operations
– ARM Thumb2 mixed 16-/32-bit instruction set
– 1.25 DMIPS/MHz
■ JTAG
– IEEE 1149.1-1990 compatible Test Access Port (TAP) controller
– Four-bit Instruction Register (IR) chain for storing JTAG instructions
– IEEE standard instructions: BYPASS, IDCODE, SAMPLE/PRELOAD, EXTEST and INTEST
– ARM additional instructions: APACC, DPACC and ABORT
– Integrated ARM Serial Wire Debug (SWD)
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Architectural Overview
■ Internal Memory
– 64 KB single-cycle flash
•
User-managed flash block protection on a 2-KB block basis
•
User-managed flash data programming
•
User-defined and managed flash-protection block
– 8 KB single-cycle SRAM
■ GPIOs
– 7-28 GPIOs, depending on configuration
– 5-V-tolerant in input configuration
– Fast toggle capable of a change every two clock cycles
– Programmable control for GPIO interrupts
•
Interrupt generation masking
•
Edge-triggered on rising, falling, or both
•
Level-sensitive on High or Low values
– Bit masking in both read and write operations through address lines
– Can initiate an ADC sample sequence
– Pins configured as digital inputs are Schmitt-triggered.
– Programmable control for GPIO pad configuration
•
Weak pull-up or pull-down resistors
•
2-mA, 4-mA, and 8-mA pad drive for digital communication
•
Slew rate control for the 8-mA drive
•
Open drain enables
•
Digital input enables
■ General-Purpose Timers
– Three General-Purpose Timer Modules (GPTM), each of which provides two 16-bit
timers/counters. Each GPTM can be configured to operate independently:
•
As a single 32-bit timer
•
As one 32-bit Real-Time Clock (RTC) to event capture
•
For Pulse Width Modulation (PWM)
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•
To trigger analog-to-digital conversions
– 32-bit Timer modes
•
Programmable one-shot timer
•
Programmable periodic timer
•
Real-Time Clock when using an external 32.768-KHz clock as the input
•
User-enabled stalling when the controller asserts CPU Halt flag during debug
•
ADC event trigger
– 16-bit Timer modes
•
General-purpose timer function with an 8-bit prescaler (for one-shot and periodic modes
only)
•
Programmable one-shot timer
•
Programmable periodic timer
•
User-enabled stalling when the controller asserts CPU Halt flag during debug
•
ADC event trigger
– 16-bit Input Capture modes
•
Input edge count capture
•
Input edge time capture
– 16-bit PWM mode
•
Simple PWM mode with software-programmable output inversion of the PWM signal
■ ARM FiRM-compliant Watchdog Timer
– 32-bit down counter with a programmable load register
– Separate watchdog clock with an enable
– Programmable interrupt generation logic with interrupt masking
– Lock register protection from runaway software
– Reset generation logic with an enable/disable
– User-enabled stalling when the controller asserts the CPU Halt flag during debug
■ ADC
– Eight analog input channels
– Single-ended and differential-input configurations
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Architectural Overview
– On-chip internal temperature sensor
– Sample rate of one million samples/second
– Flexible, configurable analog-to-digital conversion
– Four programmable sample conversion sequences from one to eight entries long, with
corresponding conversion result FIFOs
– Flexible trigger control
•
Controller (software)
•
Timers
•
GPIO
– Hardware averaging of up to 64 samples for improved accuracy
– Converter uses an internal 3-V reference
■ UART
– Two fully programmable 16C550-type UARTs
– Separate 16x8 transmit (TX) and receive (RX) FIFOs to reduce CPU interrupt service loading
– Programmable baud-rate generator allowing speeds up to 3.125 Mbps
– Programmable FIFO length, including 1-byte deep operation providing conventional
double-buffered interface
– FIFO trigger levels of 1/8, 1/4, 1/2, 3/4, and 7/8
– Standard asynchronous communication bits for start, stop, and parity
– Line-break generation and detection
– Fully programmable serial interface characteristics
•
5, 6, 7, or 8 data bits
•
Even, odd, stick, or no-parity bit generation/detection
•
1 or 2 stop bit generation
■ Synchronous Serial Interface (SSI)
– Master or slave operation
– Programmable clock bit rate and prescale
– Separate transmit and receive FIFOs, 16 bits wide, 8 locations deep
– Programmable interface operation for Freescale SPI, MICROWIRE, or Texas Instruments
synchronous serial interfaces
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– Programmable data frame size from 4 to 16 bits
– Internal loopback test mode for diagnostic/debug testing
■ I2C
– Devices on the I2C bus can be designated as either a master or a slave
•
Supports both sending and receiving data as either a master or a slave
•
Supports simultaneous master and slave operation
– Four I2C modes
•
Master transmit
•
Master receive
•
Slave transmit
•
Slave receive
– Two transmission speeds: Standard (100 Kbps) and Fast (400 Kbps)
– Master and slave interrupt generation
•
Master generates interrupts when a transmit or receive operation completes (or aborts
due to an error)
•
Slave generates interrupts when data has been sent or requested by a master
– Master with arbitration and clock synchronization, multimaster support, and 7-bit addressing
mode
■ Power
– On-chip Low Drop-Out (LDO) voltage regulator, with programmable output user-adjustable
from 2.25 V to 2.75 V
– Low-power options on controller: Sleep and Deep-sleep modes
– Low-power options for peripherals: software controls shutdown of individual peripherals
– User-enabled LDO unregulated voltage detection and automatic reset
– 3.3-V supply brown-out detection and reporting via interrupt or reset
■ Flexible Reset Sources
– Power-on reset (POR)
– Reset pin assertion
– Brown-out (BOR) detector alerts to system power drops
– Software reset
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Architectural Overview
– Watchdog timer reset
– Internal low drop-out (LDO) regulator output goes unregulated
■ Industrial temperature 48-pin RoHS-compliant LQFP package
1.2
Target Applications
■ Factory automation and control
■ Industrial control power devices
■ Building and home automation
■ Stepper motors
■ Brushless DC motors
■ AC induction motors
1.3
High-Level Block Diagram
Figure 1-1 on page 33 depicts the features on the Stellaris LM3S828 microcontroller.
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Figure 1-1. Stellaris LM3S828 Microcontroller High-Level Block Diagram
JTAG/SWD
ARM®
Cortex™-M3
(50MHz)
System
Control and
Clocks
(w/ Precis. Osc.)
Flash
(64KB)
DCode bus
NVIC
MPU
ICode bus
System Bus
LM3S828
Bus Matrix
SRAM
(8KB)
SYSTEM PERIPHERALS
I2C
(1)
Watchdog
Timer
(1)
Advanced Peripheral Bus (APB)
GeneralPurpose
Timer (3)
GPIOs
(7-28)
SERIAL PERIPHERALS
UART
(2)
SSI
(1)
ANALOG PERIPHERALS
10- Bit ADC
Channels
(8)
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Architectural Overview
1.4
Functional Overview
The following sections provide an overview of the features of the LM3S828 microcontroller. The
page number in parenthesis indicates where that feature is discussed in detail. Ordering and support
information can be found in “Ordering and Contact Information” on page 519.
1.4.1
ARM Cortex™-M3
1.4.1.1
Processor Core (see page 40)
All members of the Stellaris product family, including the LM3S828 microcontroller, are designed
around an ARM Cortex™-M3 processor core. The ARM Cortex-M3 processor provides the core for
a high-performance, low-cost platform that meets the needs of minimal memory implementation,
reduced pin count, and low-power consumption, while delivering outstanding computational
performance and exceptional system response to interrupts.
1.4.1.2
Memory Map (see page 59)
A memory map lists the location of instructions and data in memory. The memory map for the
LM3S828 controller can be found in Table 2-4 on page 59. Register addresses are given as a
hexadecimal increment, relative to the module's base address as shown in the memory map.
1.4.1.3
System Timer (SysTick) (see page 82)
Cortex-M3 includes an integrated system timer, SysTick. SysTick provides a simple, 24-bit
clear-on-write, decrementing, wrap-on-zero counter with a flexible control mechanism. The counter
can be used in several different ways, for example:
■ An RTOS tick timer which fires at a programmable rate (for example, 100 Hz) and invokes a
SysTick routine.
■ A high-speed alarm timer using the system clock.
■ A variable rate alarm or signal timer—the duration is range-dependent on the reference clock
used and the dynamic range of the counter.
■ A simple counter. Software can use this to measure time to completion and time used.
■ An internal clock source control based on missing/meeting durations. The COUNTFLAG bit-field
in the control and status register can be used to determine if an action completed within a set
duration, as part of a dynamic clock management control loop.
1.4.1.4
Nested Vectored Interrupt Controller (NVIC) (see page 83)
The LM3S828 controller includes the ARM Nested Vectored Interrupt Controller (NVIC) on the
ARM® Cortex™-M3 core. The NVIC and Cortex-M3 prioritize and handle all exceptions. All exceptions
are handled in Handler Mode. The processor state is automatically stored to the stack on an
exception, and automatically restored from the stack at the end of the Interrupt Service Routine
(ISR). The vector is fetched in parallel to the state saving, which enables efficient interrupt entry.
The processor supports tail-chaining, which enables back-to-back interrupts to be performed without
the overhead of state saving and restoration. Software can set eight priority levels on 7 exceptions
(system handlers) and 22 interrupts.
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1.4.1.5
System Control Block (SCB) (see page 85)
The SCB provides system implementation information and system control, including configuration,
control, and reporting of system exceptions.
1.4.1.6
Memory Protection Unit (MPU) (see page 85)
The MPU supports the standard ARMv7 Protected Memory System Architecture (PMSA) model.
The MPU provides full support for protection regions, overlapping protection regions, access
permissions, and exporting memory attributes to the system.
1.4.2
Motor Control Peripherals
To enhance motor control, the LM3S828 controller features Pulse Width Modulation (PWM) outputs.
1.4.2.1
PWM
Pulse width modulation (PWM) is a powerful technique for digitally encoding analog signal levels.
High-resolution counters are used to generate a square wave, and the duty cycle of the square
wave is modulated to encode an analog signal. Typical applications include switching power supplies
and motor control.
On the LM3S828, PWM motion control functionality can be achieved through:
■ The motion control features of the general-purpose timers using the CCP pins
CCP Pins (see page 270)
The General-Purpose Timer Module's CCP (Capture Compare PWM) pins are software programmable
to support a simple PWM mode with a software-programmable output inversion of the PWM signal.
1.4.3
Analog Peripherals
To handle analog signals, the LM3S828 microcontroller offers an Analog-to-Digital Converter (ADC).
1.4.3.1
ADC (see page 324)
An analog-to-digital converter (ADC) is a peripheral that converts a continuous analog voltage to a
discrete digital number.
The LM3S828 ADC module features 10-bit conversion resolution and supports eight input channels,
plus an internal temperature sensor. Four buffered sample sequences allow rapid sampling of up
to eight analog input sources without controller intervention. Each sample sequence provides flexible
programming with fully configurable input source, trigger events, interrupt generation, and sequence
priority.
1.4.4
Serial Communications Peripherals
The LM3S828 controller supports both asynchronous and synchronous serial communications with:
■ Two fully programmable 16C550-type UARTs
■ One SSI module
■ One I2C module
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Architectural Overview
1.4.4.1
UART (see page 360)
A Universal Asynchronous Receiver/Transmitter (UART) is an integrated circuit used for RS-232C
serial communications, containing a transmitter (parallel-to-serial converter) and a receiver
(serial-to-parallel converter), each clocked separately.
The LM3S828 controller includes two fully programmable 16C550-type UARTs that support data
transfer speeds up to 3.125 Mbps. (Although similar in functionality to a 16C550 UART, it is not
register-compatible.)
Separate 16x8 transmit (TX) and receive (RX) FIFOs reduce CPU interrupt service loading. The
UART can generate individually masked interrupts from the RX, TX, modem status, and error
conditions. The module provides a single combined interrupt when any of the interrupts are asserted
and are unmasked.
1.4.4.2
SSI (see page 400)
Synchronous Serial Interface (SSI) is a four-wire bi-directional full and low-speed communications
interface.
The LM3S828 controller includes one SSI module that provides the functionality for synchronous
serial communications with peripheral devices, and can be configured to use the Freescale SPI,
MICROWIRE, or TI synchronous serial interface frame formats. The size of the data frame is also
configurable, and can be set between 4 and 16 bits, inclusive.
The SSI module performs serial-to-parallel conversion on data received from a peripheral device,
and parallel-to-serial conversion on data transmitted to a peripheral device. The TX and RX paths
are buffered with internal FIFOs, allowing up to eight 16-bit values to be stored independently.
The SSI module can be configured as either a master or slave device. As a slave device, the SSI
module can also be configured to disable its output, which allows a master device to be coupled
with multiple slave devices.
The SSI module also includes a programmable bit rate clock divider and prescaler to generate the
output serial clock derived from the SSI module's input clock. Bit rates are generated based on the
input clock and the maximum bit rate is determined by the connected peripheral.
1.4.4.3
I2C (see page 438)
The Inter-Integrated Circuit (I2C) bus provides bi-directional data transfer through a two-wire design
(a serial data line SDA and a serial clock line SCL).
The I2C bus interfaces to external I2C devices such as serial memory (RAMs and ROMs), networking
devices, LCDs, tone generators, and so on. The I2C bus may also be used for system testing and
diagnostic purposes in product development and manufacture.
The LM3S828 controller includes one I2C module that provides the ability to communicate to other
IC devices over an I2C bus. The I2C bus supports devices that can both transmit and receive (write
and read) data.
Devices on the I2C bus can be designated as either a master or a slave. The I2C module supports
both sending and receiving data as either a master or a slave, and also supports the simultaneous
operation as both a master and a slave. The four I2C modes are: Master Transmit, Master Receive,
Slave Transmit, and Slave Receive.
A Stellaris I2C module can operate at two speeds: Standard (100 Kbps) and Fast (400 Kbps).
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Both the I2C master and slave can generate interrupts. The I2C master generates interrupts when
a transmit or receive operation completes (or aborts due to an error). The I2C slave generates
interrupts when data has been sent or requested by a master.
1.4.5
System Peripherals
1.4.5.1
Programmable GPIOs (see page 223)
General-purpose input/output (GPIO) pins offer flexibility for a variety of connections.
The Stellaris GPIO module is comprised of five physical GPIO blocks, each corresponding to an
individual GPIO port. The GPIO module is FiRM-compliant (compliant to the ARM Foundation IP
for Real-Time Microcontrollers specification) and supports 7-28 programmable input/output pins.
The number of GPIOs available depends on the peripherals being used (see “Signal
Tables” on page 476 for the signals available to each GPIO pin).
The GPIO module features programmable interrupt generation as either edge-triggered or
level-sensitive on all pins, programmable control for GPIO pad configuration, and bit masking in
both read and write operations through address lines. Pins configured as digital inputs are
Schmitt-triggered.
1.4.5.2
Three Programmable Timers (see page 264)
Programmable timers can be used to count or time external events that drive the Timer input pins.
The Stellaris General-Purpose Timer Module (GPTM) contains three GPTM blocks. Each GPTM
block provides two 16-bit timers/counters that can be configured to operate independently as timers
or event counters, or configured to operate as one 32-bit timer or one 32-bit Real-Time Clock (RTC).
Timers can also be used to trigger analog-to-digital (ADC) conversions.
When configured in 32-bit mode, a timer can run as a Real-Time Clock (RTC), one-shot timer or
periodic timer. When in 16-bit mode, a timer can run as a one-shot timer or periodic timer, and can
extend its precision by using an 8-bit prescaler. A 16-bit timer can also be configured for event
capture or Pulse Width Modulation (PWM) generation.
1.4.5.3
Watchdog Timer (see page 300)
A watchdog timer can generate an interrupt or a reset when a time-out value is reached. The
watchdog timer is used to regain control when a system has failed due to a software error or to the
failure of an external device to respond in the expected way.
The Stellaris Watchdog Timer module consists of a 32-bit down counter, a programmable load
register, interrupt generation logic, and a locking register.
The Watchdog Timer can be configured to generate an interrupt to the controller on its first time-out,
and to generate a reset signal on its second time-out. Once the Watchdog Timer has been configured,
the lock register can be written to prevent the timer configuration from being inadvertently altered.
1.4.6
Memory Peripherals
The LM3S828 controller offers both single-cycle SRAM and single-cycle Flash memory.
1.4.6.1
SRAM (see page 206)
The LM3S828 static random access memory (SRAM) controller supports 8 KB SRAM. The internal
SRAM of the Stellaris devices starts at base address 0x2000.0000 of the device memory map. To
reduce the number of time-consuming read-modify-write (RMW) operations, ARM has introduced
bit-banding technology in the new Cortex-M3 processor. With a bit-band-enabled processor, certain
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Architectural Overview
regions in the memory map (SRAM and peripheral space) can use address aliases to access
individual bits in a single, atomic operation.
1.4.6.2
Flash (see page 207)
The LM3S828 Flash controller supports 64 KB of flash memory. The flash is organized as a set of
1-KB blocks that can be individually erased. Erasing a block causes the entire contents of the block
to be reset to all 1s. These blocks are paired into a set of 2-KB blocks that can be individually
protected. The blocks can be marked as read-only or execute-only, providing different levels of code
protection. Read-only blocks cannot be erased or programmed, protecting the contents of those
blocks from being modified. Execute-only blocks cannot be erased or programmed, and can only
be read by the controller instruction fetch mechanism, protecting the contents of those blocks from
being read by either the controller or by a debugger.
1.4.7
Additional Features
1.4.7.1
JTAG TAP Controller (see page 140)
The Joint Test Action Group (JTAG) port is an IEEE standard that defines a Test Access Port and
Boundary Scan Architecture for digital integrated circuits and provides a standardized serial interface
for controlling the associated test logic. The TAP, Instruction Register (IR), and Data Registers (DR)
can be used to test the interconnections of assembled printed circuit boards and obtain manufacturing
information on the components. The JTAG Port also provides a means of accessing and controlling
design-for-test features such as I/O pin observation and control, scan testing, and debugging.
The JTAG port is composed of the standard five pins: TRST, TCK, TMS, TDI, and TDO. Data is
transmitted serially into the controller on TDI and out of the controller on TDO. The interpretation of
this data is dependent on the current state of the TAP controller. For detailed information on the
operation of the JTAG port and TAP controller, please refer to the IEEE Standard 1149.1-Test
Access Port and Boundary-Scan Architecture.
The Stellaris JTAG controller works with the ARM JTAG controller built into the Cortex-M3 core.
This is implemented by multiplexing the TDO outputs from both JTAG controllers. ARM JTAG
instructions select the ARM TDO output while Stellaris JTAG instructions select the Stellaris TDO
outputs. The multiplexer is controlled by the Stellaris JTAG controller, which has comprehensive
programming for the ARM, Stellaris, and unimplemented JTAG instructions.
1.4.7.2
System Control and Clocks (see page 150)
System control determines the overall operation of the device. It provides information about the
device, controls the clocking of the device and individual peripherals, and handles reset detection
and reporting.
1.4.8
Hardware Details
Details on the pins and package can be found in the following sections:
■ “Pin Diagram” on page 475
■ “Signal Tables” on page 476
■ “Operating Characteristics” on page 483
■ “Electrical Characteristics” on page 484
■ “Package Information” on page 521
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1.4.9
System Block Diagram
Figure 1-2. LM3S828 Controller System-Level Block Diagram
VDD_3.3V
LDO
LDO
VDD_2.5V
GND
ARM Cortex-M3
(50 MHz)
CM3Core
DCode
Debug
OSC0
IOSC
Flash
(64 KB)
ICode
NVIC
Bus
PLL
APB Bridge
OSC1
SRAM
(8 KB)
POR
BOR
RST
Watchdog
Timer
System
Control
& Clocks
GPIO Port B
GPIO Port A
PB7/TRST
PB6
PB5/CCP5
PB4
PA5/SSITx
PA4/SSIRx
PA3/SSIFss
PA2/SSIClk
SSI
PA1/U0Tx
PA0/U0Rx
UART0
I2C
Master
PB3/I2CSDA
PB2/I2CSCL
GPIO Port C
Peripheral Bus
Slave
GP Timer0
PB0/CCP0
GP Timer1
PB1/CCP2
PC6/CCP3
PC3/TDO/SWO
PC2/TDI
PC1/TMS/SWDIO
PC0/TCK/SWCLK
JTAG
SWD/SWO
PC4
PC7/CCP4
GP Timer2
GPIO Port D
PD0
PD1
UART1
PC5/CCP1
PD2/U1Rx
PD3/U1Tx
GPIO Port E
PE0
PE1
ADC
ADC7
ADC6
ADC5
ADC4
ADC3
ADC2
ADC1
ADC0
Temperature
Sensor
LM3S828
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The Cortex-M3 Processor
2
The Cortex-M3 Processor
The ARM® Cortex™-M3 processor provides a high-performance, low-cost platform that meets the
system requirements of minimal memory implementation, reduced pin count, and low power
consumption, while delivering outstanding computational performance and exceptional system
response to interrupts. Features include:
■ Compact core.
■ Thumb-2 instruction set, delivering the high-performance expected of an ARM core in the memory
size usually associated with 8- and 16-bit devices; typically in the range of a few kilobytes of
memory for microcontroller class applications.
■ Rapid application execution through Harvard architecture characterized by separate buses for
instruction and data.
■ Exceptional interrupt handling, by implementing the register manipulations required for handling
an interrupt in hardware.
■ Deterministic, fast interrupt processing: always 12 cycles, or just 6 cycles with tail-chaining
■ Memory protection unit (MPU) to provide a privileged mode of operation for complex applications.
■ Migration from the ARM7™ processor family for better performance and power efficiency.
■ Full-featured debug solution
– Serial Wire JTAG Debug Port (SWJ-DP)
– Flash Patch and Breakpoint (FPB) unit for implementing breakpoints
– Data Watchpoint and Trigger (DWT) unit for implementing watchpoints, trigger resources,
and system profiling
– Instrumentation Trace Macrocell (ITM) for support of printf style debugging
– Trace Port Interface Unit (TPIU) for bridging to a Trace Port Analyzer
■ Optimized for single-cycle flash usage
■ Three sleep modes with clock gating for low power
■ Single-cycle multiply instruction and hardware divide
■ Atomic operations
■ ARM Thumb2 mixed 16-/32-bit instruction set
■ 1.25 DMIPS/MHz
®
The Stellaris family of microcontrollers builds on this core to bring high-performance 32-bit computing
to cost-sensitive embedded microcontroller applications, such as factory automation and control,
industrial control power devices, building and home automation, and stepper motor control.
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This chapter provides information on the Stellaris implementation of the Cortex-M3 processor,
including the programming model, the memory model, the exception model, fault handling, and
power management.
For technical details on the instruction set, see the Cortex™-M3/M4 Instruction Set Technical User's
Manual.
2.1
Block Diagram
The Cortex-M3 processor is built on a high-performance processor core, with a 3-stage pipeline
Harvard architecture, making it ideal for demanding embedded applications. The processor delivers
exceptional power efficiency through an efficient instruction set and extensively optimized design,
providing high-end processing hardware including a range of single-cycle and SIMD multiplication
and multiply-with-accumulate capabilities, saturating arithmetic and dedicated hardware division.
To facilitate the design of cost-sensitive devices, the Cortex-M3 processor implements tightly coupled
system components that reduce processor area while significantly improving interrupt handling and
system debug capabilities. The Cortex-M3 processor implements a version of the Thumb® instruction
set based on Thumb-2 technology, ensuring high code density and reduced program memory
requirements. The Cortex-M3 instruction set provides the exceptional performance expected of a
modern 32-bit architecture, with the high code density of 8-bit and 16-bit microcontrollers.
The Cortex-M3 processor closely integrates a nested interrupt controller (NVIC), to deliver
industry-leading interrupt performance. The Stellaris NVIC includes a non-maskable interrupt (NMI)
and provides eight interrupt priority levels. The tight integration of the processor core and NVIC
provides fast execution of interrupt service routines (ISRs), dramatically reducing interrupt latency.
The hardware stacking of registers and the ability to suspend load-multiple and store-multiple
operations further reduce interrupt latency. Interrupt handlers do not require any assembler stubs
which removes code overhead from the ISRs. Tail-chaining optimization also significantly reduces
the overhead when switching from one ISR to another. To optimize low-power designs, the NVIC
integrates with the sleep modes, including Deep-sleep mode, which enables the entire device to be
rapidly powered down.
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The Cortex-M3 Processor
Figure 2-1. CPU Block Diagram
Nested
Vectored
Interrupt
Controller
Interrupts
Sleep
ARM
Cortex-M3
CM3 Core
Debug
Instructions
Data
Trace
Port
Interface
Unit
Memory
Protection
Unit
Flash
Patch and
Breakpoint
Instrumentation
Data
Watchpoint Trace Macrocell
and Trace
ROM
Table
Private Peripheral
Bus
(internal)
Adv. Peripheral
Bus
Bus
Matrix
Serial Wire JTAG
Debug Port
Debug
Access Port
2.2
Overview
2.2.1
System-Level Interface
Serial
Wire
Output
Trace
Port
(SWO)
I-code bus
D-code bus
System bus
The Cortex-M3 processor provides multiple interfaces using AMBA® technology to provide
high-speed, low-latency memory accesses. The core supports unaligned data accesses and
implements atomic bit manipulation that enables faster peripheral controls, system spinlocks, and
thread-safe Boolean data handling.
The Cortex-M3 processor has a memory protection unit (MPU) that provides fine-grain memory
control, enabling applications to implement security privilege levels and separate code, data and
stack on a task-by-task basis.
2.2.2
Integrated Configurable Debug
The Cortex-M3 processor implements a complete hardware debug solution, providing high system
visibility of the processor and memory through either a traditional JTAG port or a 2-pin Serial Wire
Debug (SWD) port that is ideal for microcontrollers and other small package devices. The Stellaris
implementation replaces the ARM SW-DP and JTAG-DP with the ARM CoreSight™-compliant
Serial Wire JTAG Debug Port (SWJ-DP) interface. The SWJ-DP interface combines the SWD and
JTAG debug ports into one module. See the ARM® Debug Interface V5 Architecture Specification
for details on SWJ-DP.
For system trace, the processor integrates an Instrumentation Trace Macrocell (ITM) alongside data
watchpoints and a profiling unit. To enable simple and cost-effective profiling of the system trace
events, a Serial Wire Viewer (SWV) can export a stream of software-generated messages, data
trace, and profiling information through a single pin.
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The Flash Patch and Breakpoint Unit (FPB) provides up to eight hardware breakpoint comparators
that debuggers can use. The comparators in the FPB also provide remap functions of up to eight
words in the program code in the CODE memory region. This enables applications stored in a
read-only area of Flash memory to be patched in another area of on-chip SRAM or Flash memory.
If a patch is required, the application programs the FPB to remap a number of addresses. When
those addresses are accessed, the accesses are redirected to a remap table specified in the FPB
configuration.
For more information on the Cortex-M3 debug capabilities, see theARM® Debug Interface V5
Architecture Specification.
2.2.3
Trace Port Interface Unit (TPIU)
The TPIU acts as a bridge between the Cortex-M3 trace data from the ITM, and an off-chip Trace
Port Analyzer, as shown in Figure 2-2 on page 43.
Figure 2-2. TPIU Block Diagram
2.2.4
Debug
ATB
Slave
Port
ATB
Interface
APB
Slave
Port
APB
Interface
Asynchronous FIFO
Trace Out
(serializer)
Serial Wire
Trace Port
(SWO)
Cortex-M3 System Component Details
The Cortex-M3 includes the following system components:
■ SysTick
A 24-bit count-down timer that can be used as a Real-Time Operating System (RTOS) tick timer
or as a simple counter (see “System Timer (SysTick)” on page 82).
■ Nested Vectored Interrupt Controller (NVIC)
An embedded interrupt controller that supports low latency interrupt processing (see “Nested
Vectored Interrupt Controller (NVIC)” on page 83).
■ System Control Block (SCB)
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The programming model interface to the processor. The SCB provides system implementation
information and system control, including configuration, control, and reporting of system exceptions
(see “System Control Block (SCB)” on page 85).
■ Memory Protection Unit (MPU)
Improves system reliability by defining the memory attributes for different memory regions. The
MPU provides up to eight different regions and an optional predefined background region (see
“Memory Protection Unit (MPU)” on page 85).
2.3
Programming Model
This section describes the Cortex-M3 programming model. In addition to the individual core register
descriptions, information about the processor modes and privilege levels for software execution and
stacks is included.
2.3.1
Processor Mode and Privilege Levels for Software Execution
The Cortex-M3 has two modes of operation:
■ Thread mode
Used to execute application software. The processor enters Thread mode when it comes out of
reset.
■ Handler mode
Used to handle exceptions. When the processor has finished exception processing, it returns to
Thread mode.
In addition, the Cortex-M3 has two privilege levels:
■ Unprivileged
In this mode, software has the following restrictions:
– Limited access to the MSR and MRS instructions and no use of the CPS instruction
– No access to the system timer, NVIC, or system control block
– Possibly restricted access to memory or peripherals
■ Privileged
In this mode, software can use all the instructions and has access to all resources.
In Thread mode, the CONTROL register (see page 58) controls whether software execution is
privileged or unprivileged. In Handler mode, software execution is always privileged.
Only privileged software can write to the CONTROL register to change the privilege level for software
execution in Thread mode. Unprivileged software can use the SVC instruction to make a supervisor
call to transfer control to privileged software.
2.3.2
Stacks
The processor uses a full descending stack, meaning that the stack pointer indicates the last stacked
item on the memory. When the processor pushes a new item onto the stack, it decrements the stack
pointer and then writes the item to the new memory location. The processor implements two stacks:
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the main stack and the process stack, with a pointer for each held in independent registers (see the
SP register on page 48).
In Thread mode, the CONTROL register (see page 58) controls whether the processor uses the
main stack or the process stack. In Handler mode, the processor always uses the main stack. The
options for processor operations are shown in Table 2-1 on page 45.
Table 2-1. Summary of Processor Mode, Privilege Level, and Stack Use
Processor Mode
Use
Privilege Level
Thread
Applications
Privileged or unprivileged
Stack Used
Handler
Exception handlers
Always privileged
a
Main stack or process stack
a
Main stack
a. See CONTROL (page 58).
2.3.3
Register Map
Figure 2-3 on page 45 shows the Cortex-M3 register set. Table 2-2 on page 46 lists the Core
registers. The core registers are not memory mapped and are accessed by register name, so the
base address is n/a (not applicable) and there is no offset.
Figure 2-3. Cortex-M3 Register Set
R0
R1
R2
Low registers
R3
R4
R5
R6
General-purpose registers
R7
R8
R9
High registers
R10
R11
R12
Stack Pointer
SP (R13)
Link Register
LR (R14)
Program Counter
PC (R15)
PSR
PSP‡
MSP‡
‡
Banked version of SP
Program status register
PRIMASK
FAULTMASK
Exception mask registers
Special registers
BASEPRI
CONTROL
CONTROL register
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The Cortex-M3 Processor
Table 2-2. Processor Register Map
Offset
Type
Reset
-
R0
R/W
-
Cortex General-Purpose Register 0
47
-
R1
R/W
-
Cortex General-Purpose Register 1
47
-
R2
R/W
-
Cortex General-Purpose Register 2
47
-
R3
R/W
-
Cortex General-Purpose Register 3
47
-
R4
R/W
-
Cortex General-Purpose Register 4
47
-
R5
R/W
-
Cortex General-Purpose Register 5
47
-
R6
R/W
-
Cortex General-Purpose Register 6
47
-
R7
R/W
-
Cortex General-Purpose Register 7
47
-
R8
R/W
-
Cortex General-Purpose Register 8
47
-
R9
R/W
-
Cortex General-Purpose Register 9
47
-
R10
R/W
-
Cortex General-Purpose Register 10
47
-
R11
R/W
-
Cortex General-Purpose Register 11
47
-
R12
R/W
-
Cortex General-Purpose Register 12
47
-
SP
R/W
-
Stack Pointer
48
-
LR
R/W
0xFFFF.FFFF
Link Register
49
-
PC
R/W
-
Program Counter
50
-
PSR
R/W
0x0100.0000
Program Status Register
51
-
PRIMASK
R/W
0x0000.0000
Priority Mask Register
55
-
FAULTMASK
R/W
0x0000.0000
Fault Mask Register
56
-
BASEPRI
R/W
0x0000.0000
Base Priority Mask Register
57
-
CONTROL
R/W
0x0000.0000
Control Register
58
2.3.4
Description
See
page
Name
Register Descriptions
This section lists and describes the Cortex-M3 registers, in the order shown in Figure 2-3 on page 45.
The core registers are not memory mapped and are accessed by register name rather than offset.
Note:
The register type shown in the register descriptions refers to type during program execution
in Thread mode and Handler mode. Debug access can differ.
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Register 1: Cortex General-Purpose Register 0 (R0)
Register 2: Cortex General-Purpose Register 1 (R1)
Register 3: Cortex General-Purpose Register 2 (R2)
Register 4: Cortex General-Purpose Register 3 (R3)
Register 5: Cortex General-Purpose Register 4 (R4)
Register 6: Cortex General-Purpose Register 5 (R5)
Register 7: Cortex General-Purpose Register 6 (R6)
Register 8: Cortex General-Purpose Register 7 (R7)
Register 9: Cortex General-Purpose Register 8 (R8)
Register 10: Cortex General-Purpose Register 9 (R9)
Register 11: Cortex General-Purpose Register 10 (R10)
Register 12: Cortex General-Purpose Register 11 (R11)
Register 13: Cortex General-Purpose Register 12 (R12)
The Rn registers are 32-bit general-purpose registers for data operations and can be accessed
from either privileged or unprivileged mode.
Cortex General-Purpose Register 0 (R0)
Type R/W, reset 31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
DATA
Type
Reset
DATA
Type
Reset
Bit/Field
Name
Type
Reset
31:0
DATA
R/W
-
Description
Register data.
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Register 14: Stack Pointer (SP)
The Stack Pointer (SP) is register R13. In Thread mode, the function of this register changes
depending on the ASP bit in the Control Register (CONTROL) register. When the ASP bit is clear,
this register is the Main Stack Pointer (MSP). When the ASP bit is set, this register is the Process
Stack Pointer (PSP). On reset, the ASP bit is clear, and the processor loads the MSP with the value
from address 0x0000.0000. The MSP can only be accessed in privileged mode; the PSP can be
accessed in either privileged or unprivileged mode.
Stack Pointer (SP)
Type R/W, reset 31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
SP
Type
Reset
SP
Type
Reset
Bit/Field
Name
Type
Reset
31:0
SP
R/W
-
Description
This field is the address of the stack pointer.
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Register 15: Link Register (LR)
The Link Register (LR) is register R14, and it stores the return information for subroutines, function
calls, and exceptions. LR can be accessed from either privileged or unprivileged mode.
EXC_RETURN is loaded into LR on exception entry. See Table 2-10 on page 74 for the values and
description.
Link Register (LR)
Type R/W, reset 0xFFFF.FFFF
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
7
6
5
4
3
2
1
0
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
LINK
Type
Reset
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
15
14
13
12
11
10
9
8
LINK
Type
Reset
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
Bit/Field
Name
Type
31:0
LINK
R/W
R/W
1
Reset
R/W
1
Description
0xFFFF.FFFF This field is the return address.
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Register 16: Program Counter (PC)
The Program Counter (PC) is register R15, and it contains the current program address. On reset,
the processor loads the PC with the value of the reset vector, which is at address 0x0000.0004. Bit
0 of the reset vector is loaded into the THUMB bit of the EPSR at reset and must be 1. The PC register
can be accessed in either privileged or unprivileged mode.
Program Counter (PC)
Type R/W, reset 31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
PC
Type
Reset
PC
Type
Reset
Bit/Field
Name
Type
Reset
31:0
PC
R/W
-
Description
This field is the current program address.
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Register 17: Program Status Register (PSR)
Note:
This register is also referred to as xPSR.
The Program Status Register (PSR) has three functions, and the register bits are assigned to the
different functions:
■ Application Program Status Register (APSR), bits 31:27,
■ Execution Program Status Register (EPSR), bits 26:24, 15:10
■ Interrupt Program Status Register (IPSR), bits 5:0
The PSR, IPSR, and EPSR registers can only be accessed in privileged mode; the APSR register
can be accessed in either privileged or unprivileged mode.
APSR contains the current state of the condition flags from previous instruction executions.
EPSR contains the Thumb state bit and the execution state bits for the If-Then (IT) instruction or
the Interruptible-Continuable Instruction (ICI) field for an interrupted load multiple or store multiple
instruction. Attempts to read the EPSR directly through application software using the MSR instruction
always return zero. Attempts to write the EPSR using the MSR instruction in application software
are always ignored. Fault handlers can examine the EPSR value in the stacked PSR to determine
the operation that faulted (see “Exception Entry and Return” on page 72).
IPSR contains the exception type number of the current Interrupt Service Routine (ISR).
These registers can be accessed individually or as a combination of any two or all three registers,
using the register name as an argument to the MSR or MRS instructions. For example, all of the
registers can be read using PSR with the MRS instruction, or APSR only can be written to using
APSR with the MSR instruction. page 51 shows the possible register combinations for the PSR. See
the MRS and MSR instruction descriptions in the Cortex™-M3/M4 Instruction Set Technical User's
Manual for more information about how to access the program status registers.
Table 2-3. PSR Register Combinations
Register
Type
PSR
R/W
Combination
APSR, EPSR, and IPSR
IEPSR
RO
EPSR and IPSR
a, b
a
APSR and IPSR
b
APSR and EPSR
IAPSR
R/W
EAPSR
R/W
a. The processor ignores writes to the IPSR bits.
b. Reads of the EPSR bits return zero, and the processor ignores writes to these bits.
Program Status Register (PSR)
Type R/W, reset 0x0100.0000
Type
Reset
31
30
29
28
27
N
Z
C
V
Q
26
25
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
RO
0
RO
0
RO
1
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
ICI / IT
ICI / IT
Type
Reset
RO
0
RO
0
RO
0
24
23
22
21
20
THUMB
reserved
RO
0
RO
0
RO
0
RO
0
RO
0
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
0
RO
0
RO
0
reserved
RO
0
ISRNUM
RO
0
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0
RO
0
RO
0
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Bit/Field
Name
Type
Reset
31
N
R/W
0
Description
APSR Negative or Less Flag
Value Description
1
The previous operation result was negative or less than.
0
The previous operation result was positive, zero, greater than,
or equal.
The value of this bit is only meaningful when accessing PSR or APSR.
30
Z
R/W
0
APSR Zero Flag
Value Description
1
The previous operation result was zero.
0
The previous operation result was non-zero.
The value of this bit is only meaningful when accessing PSR or APSR.
29
C
R/W
0
APSR Carry or Borrow Flag
Value Description
1
The previous add operation resulted in a carry bit or the previous
subtract operation did not result in a borrow bit.
0
The previous add operation did not result in a carry bit or the
previous subtract operation resulted in a borrow bit.
The value of this bit is only meaningful when accessing PSR or APSR.
28
V
R/W
0
APSR Overflow Flag
Value Description
1
The previous operation resulted in an overflow.
0
The previous operation did not result in an overflow.
The value of this bit is only meaningful when accessing PSR or APSR.
27
Q
R/W
0
APSR DSP Overflow and Saturation Flag
Value Description
1
DSP Overflow or saturation has occurred.
0
DSP overflow or saturation has not occurred since reset or since
the bit was last cleared.
The value of this bit is only meaningful when accessing PSR or APSR.
This bit is cleared by software using an MRS instruction.
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Bit/Field
Name
Type
Reset
26:25
ICI / IT
RO
0x0
Description
EPSR ICI / IT status
These bits, along with bits 15:10, contain the Interruptible-Continuable
Instruction (ICI) field for an interrupted load multiple or store multiple
instruction or the execution state bits of the IT instruction.
When EPSR holds the ICI execution state, bits 26:25 are zero.
The If-Then block contains up to four instructions following an IT
instruction. Each instruction in the block is conditional. The conditions
for the instructions are either all the same, or some can be the inverse
of others. See the Cortex™-M3/M4 Instruction Set Technical User's
Manual for more information.
The value of this field is only meaningful when accessing PSR or EPSR.
24
THUMB
RO
1
EPSR Thumb State
This bit indicates the Thumb state and should always be set.
The following can clear the THUMB bit:
■
The BLX, BX and POP{PC} instructions
■
Restoration from the stacked xPSR value on an exception return
■
Bit 0 of the vector value on an exception entry or reset
Attempting to execute instructions when this bit is clear results in a fault
or lockup. See “Lockup” on page 76 for more information.
The value of this bit is only meaningful when accessing PSR or EPSR.
23:16
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
15:10
ICI / IT
RO
0x0
EPSR ICI / IT status
These bits, along with bits 26:25, contain the Interruptible-Continuable
Instruction (ICI) field for an interrupted load multiple or store multiple
instruction or the execution state bits of the IT instruction.
When an interrupt occurs during the execution of an LDM, STM, PUSH
or POP instruction, the processor stops the load multiple or store multiple
instruction operation temporarily and stores the next register operand
in the multiple operation to bits 15:12. After servicing the interrupt, the
processor returns to the register pointed to by bits 15:12 and resumes
execution of the multiple load or store instruction. When EPSR holds
the ICI execution state, bits 11:10 are zero.
The If-Then block contains up to four instructions following a 16-bit IT
instruction. Each instruction in the block is conditional. The conditions
for the instructions are either all the same, or some can be the inverse
of others. See the Cortex™-M3/M4 Instruction Set Technical User's
Manual for more information.
The value of this field is only meaningful when accessing PSR or EPSR.
9:6
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Bit/Field
Name
Type
Reset
Description
5:0
ISRNUM
RO
0x00
IPSR ISR Number
This field contains the exception type number of the current Interrupt
Service Routine (ISR).
Value
Description
0x00
Thread mode
0x01
Reserved
0x02
NMI
0x03
Hard fault
0x04
Memory management fault
0x05
Bus fault
0x06
Usage fault
0x07-0x0A Reserved
0x0B
SVCall
0x0C
Reserved for Debug
0x0D
Reserved
0x0E
PendSV
0x0F
SysTick
0x10
Interrupt Vector 0
0x11
Interrupt Vector 1
...
...
0x2D
Interrupt Vector 29
0x2E-0x3F Reserved
See “Exception Types” on page 68 for more information.
The value of this field is only meaningful when accessing PSR or IPSR.
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Register 18: Priority Mask Register (PRIMASK)
The PRIMASK register prevents activation of all exceptions with programmable priority. Reset,
non-maskable interrupt (NMI), and hard fault are the only exceptions with fixed priority. Exceptions
should be disabled when they might impact the timing of critical tasks. This register is only accessible
in privileged mode. The MSR and MRS instructions are used to access the PRIMASK register, and
the CPS instruction may be used to change the value of the PRIMASK register. See the
Cortex™-M3/M4 Instruction Set Technical User's Manual for more information on these instructions.
For more information on exception priority levels, see “Exception Types” on page 68.
Priority Mask Register (PRIMASK)
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
31:1
reserved
RO
0x0000.000
0
PRIMASK
R/W
0
RO
0
PRIMASK
R/W
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Priority Mask
Value Description
1
Prevents the activation of all exceptions with configurable
priority.
0
No effect.
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Register 19: Fault Mask Register (FAULTMASK)
The FAULTMASK register prevents activation of all exceptions except for the Non-Maskable Interrupt
(NMI). Exceptions should be disabled when they might impact the timing of critical tasks. This register
is only accessible in privileged mode. The MSR and MRS instructions are used to access the
FAULTMASK register, and the CPS instruction may be used to change the value of the FAULTMASK
register. See the Cortex™-M3/M4 Instruction Set Technical User's Manual for more information on
these instructions. For more information on exception priority levels, see “Exception
Types” on page 68.
Fault Mask Register (FAULTMASK)
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
31:1
reserved
RO
0x0000.000
0
FAULTMASK
R/W
0
RO
0
FAULTMASK
R/W
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Fault Mask
Value Description
1
Prevents the activation of all exceptions except for NMI.
0
No effect.
The processor clears the FAULTMASK bit on exit from any exception
handler except the NMI handler.
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Register 20: Base Priority Mask Register (BASEPRI)
The BASEPRI register defines the minimum priority for exception processing. When BASEPRI is
set to a nonzero value, it prevents the activation of all exceptions with the same or lower priority
level as the BASEPRI value. Exceptions should be disabled when they might impact the timing of
critical tasks. This register is only accessible in privileged mode. For more information on exception
priority levels, see “Exception Types” on page 68.
Base Priority Mask Register (BASEPRI)
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
R/W
0
R/W
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
BASEPRI
RO
0
Bit/Field
Name
Type
Reset
31:8
reserved
RO
0x0000.00
7:5
BASEPRI
R/W
0x0
R/W
0
reserved
RO
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Base Priority
Any exception that has a programmable priority level with the same or
lower priority as the value of this field is masked. The PRIMASK register
can be used to mask all exceptions with programmable priority levels.
Higher priority exceptions have lower priority levels.
Value Description
4:0
reserved
RO
0x0
0x0
All exceptions are unmasked.
0x1
All exceptions with priority level 1-7 are masked.
0x2
All exceptions with priority level 2-7 are masked.
0x3
All exceptions with priority level 3-7 are masked.
0x4
All exceptions with priority level 4-7 are masked.
0x5
All exceptions with priority level 5-7 are masked.
0x6
All exceptions with priority level 6-7 are masked.
0x7
All exceptions with priority level 7 are masked.
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Register 21: Control Register (CONTROL)
The CONTROL register controls the stack used and the privilege level for software execution when
the processor is in Thread mode. This register is only accessible in privileged mode.
Handler mode always uses MSP, so the processor ignores explicit writes to the ASP bit of the
CONTROL register when in Handler mode. The exception entry and return mechanisms automatically
update the CONTROL register based on the EXC_RETURN value (see Table 2-10 on page 74).
In an OS environment, threads running in Thread mode should use the process stack and the kernel
and exception handlers should use the main stack. By default, Thread mode uses MSP. To switch
the stack pointer used in Thread mode to PSP, either use the MSR instruction to set the ASP bit, as
detailed in the Cortex™-M3/M4 Instruction Set Technical User's Manual, or perform an exception
return to Thread mode with the appropriate EXC_RETURN value, as shown in Table 2-10 on page 74.
Note:
When changing the stack pointer, software must use an ISB instruction immediately after
the MSR instruction, ensuring that instructions after the ISB execute use the new stack
pointer. See the Cortex™-M3/M4 Instruction Set Technical User's Manual.
Control Register (CONTROL)
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
ASP
TMPL
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
31:2
reserved
RO
0x0000.000
1
ASP
R/W
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Active Stack Pointer
Value Description
1
PSP is the current stack pointer.
0
MSP is the current stack pointer
In Handler mode, this bit reads as zero and ignores writes. The
Cortex-M3 updates this bit automatically on exception return.
0
TMPL
R/W
0
Thread Mode Privilege Level
Value Description
1
Unprivileged software can be executed in Thread mode.
0
Only privileged software can be executed in Thread mode.
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2.3.5
Exceptions and Interrupts
The Cortex-M3 processor supports interrupts and system exceptions. The processor and the Nested
Vectored Interrupt Controller (NVIC) prioritize and handle all exceptions. An exception changes the
normal flow of software control. The processor uses Handler mode to handle all exceptions except
for reset. See “Exception Entry and Return” on page 72 for more information.
The NVIC registers control interrupt handling. See “Nested Vectored Interrupt Controller
(NVIC)” on page 83 for more information.
2.3.6
Data Types
The Cortex-M3 supports 32-bit words, 16-bit halfwords, and 8-bit bytes. The processor also supports
64-bit data transfer instructions. All instruction and data memory accesses are little endian. See
“Memory Regions, Types and Attributes” on page 60 for more information.
2.4
Memory Model
This section describes the processor memory map, the behavior of memory accesses, and the
bit-banding features. The processor has a fixed memory map that provides up to 4 GB of addressable
memory.
The memory map for the LM3S828 controller is provided in Table 2-4 on page 59. In this manual,
register addresses are given as a hexadecimal increment, relative to the module’s base address
as shown in the memory map.
The regions for SRAM and peripherals include bit-band regions. Bit-banding provides atomic
operations to bit data (see “Bit-Banding” on page 63).
The processor reserves regions of the Private peripheral bus (PPB) address range for core peripheral
registers (see “Cortex-M3 Peripherals” on page 82).
Note:
Within the memory map, all reserved space returns a bus fault when read or written.
Table 2-4. Memory Map
Start
End
Description
For details,
see page ...
0x0000.0000
0x0000.FFFF
On-chip Flash
211
0x0001.0000
0x1FFF.FFFF
Reserved
-
0x2000.0000
0x2000.1FFF
Bit-banded on-chip SRAM
206
0x2000.2000
0x21FF.FFFF
Reserved
-
0x2200.0000
0x2203.FFFF
Bit-band alias of bit-banded on-chip SRAM starting at
0x2000.0000
206
0x2204.0000
0x3FFF.FFFF
Reserved
-
0x4000.0000
0x4000.0FFF
Watchdog timer 0
303
0x4000.1000
0x4000.3FFF
Reserved
-
0x4000.4000
0x4000.4FFF
GPIO Port A
232
0x4000.5000
0x4000.5FFF
GPIO Port B
232
0x4000.6000
0x4000.6FFF
GPIO Port C
232
0x4000.7000
0x4000.7FFF
GPIO Port D
232
0x4000.8000
0x4000.8FFF
SSI0
412
Memory
FiRM Peripherals
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Table 2-4. Memory Map (continued)
Start
End
Description
For details,
see page ...
0x4000.9000
0x4000.BFFF
Reserved
-
0x4000.C000
0x4000.CFFF
UART0
367
0x4000.D000
0x4000.DFFF
UART1
367
0x4000.E000
0x4001.FFFF
Reserved
-
0x4002.0000
0x4002.0FFF
I2C 0
453
0x4002.1000
0x4002.3FFF
Reserved
-
0x4002.4000
0x4002.4FFF
GPIO Port E
232
0x4002.5000
0x4002.FFFF
Reserved
-
0x4003.0000
0x4003.0FFF
Timer 0
275
0x4003.1000
0x4003.1FFF
Timer 1
275
0x4003.2000
0x4003.2FFF
Timer 2
275
0x4003.3000
0x4003.7FFF
Reserved
-
0x4003.8000
0x4003.8FFF
ADC0
333
0x4003.9000
0x400F.CFFF
Reserved
-
0x400F.D000
0x400F.DFFF
Flash memory control
211
0x400F.E000
0x400F.EFFF
System control
161
0x400F.F000
0x41FF.FFFF
Reserved
-
0x4200.0000
0x43FF.FFFF
Bit-banded alias of 0x4000.0000 through 0x400F.FFFF
-
0x4400.0000
0xDFFF.FFFF
Reserved
-
0xE000.0000
0xE000.0FFF
Instrumentation Trace Macrocell (ITM)
42
0xE000.1000
0xE000.1FFF
Data Watchpoint and Trace (DWT)
42
0xE000.2000
0xE000.2FFF
Flash Patch and Breakpoint (FPB)
42
0xE000.3000
0xE000.DFFF
Reserved
-
0xE000.E000
0xE000.EFFF
Cortex-M3 Peripherals (SysTick, NVIC, MPU and SCB)
90
0xE000.F000
0xE003.FFFF
Reserved
-
0xE004.0000
0xE004.0FFF
Trace Port Interface Unit (TPIU)
43
0xE004.1000
0xFFFF.FFFF
Reserved
-
Peripherals
Private Peripheral Bus
2.4.1
Memory Regions, Types and Attributes
The memory map and the programming of the MPU split the memory map into regions. Each region
has a defined memory type, and some regions have additional memory attributes. The memory
type and attributes determine the behavior of accesses to the region.
The memory types are:
■ Normal: The processor can re-order transactions for efficiency and perform speculative reads.
■ Device: The processor preserves transaction order relative to other transactions to Device or
Strongly Ordered memory.
■ Strongly Ordered: The processor preserves transaction order relative to all other transactions.
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The different ordering requirements for Device and Strongly Ordered memory mean that the memory
system can buffer a write to Device memory but must not buffer a write to Strongly Ordered memory.
An additional memory attribute is Execute Never (XN), which means the processor prevents
instruction accesses. A fault exception is generated only on execution of an instruction executed
from an XN region.
2.4.2
Memory System Ordering of Memory Accesses
For most memory accesses caused by explicit memory access instructions, the memory system
does not guarantee that the order in which the accesses complete matches the program order of
the instructions, providing the order does not affect the behavior of the instruction sequence. Normally,
if correct program execution depends on two memory accesses completing in program order,
software must insert a memory barrier instruction between the memory access instructions (see
“Software Ordering of Memory Accesses” on page 62).
However, the memory system does guarantee ordering of accesses to Device and Strongly Ordered
memory. For two memory access instructions A1 and A2, if both A1 and A2 are accesses to either
Device or Strongly Ordered memory, and if A1 occurs before A2 in program order, A1 is always
observed before A2.
2.4.3
Behavior of Memory Accesses
Table 2-5 on page 61 shows the behavior of accesses to each region in the memory map. See
“Memory Regions, Types and Attributes” on page 60 for more information on memory types and
the XN attribute. Stellaris devices may have reserved memory areas within the address ranges
shown below (refer to Table 2-4 on page 59 for more information).
Table 2-5. Memory Access Behavior
Address Range
Memory Region
Memory Type
Execute
Never
(XN)
Description
0x0000.0000 - 0x1FFF.FFFF Code
Normal
-
This executable region is for program code.
Data can also be stored here.
0x2000.0000 - 0x3FFF.FFFF SRAM
Normal
-
This executable region is for data. Code
can also be stored here. This region
includes bit band and bit band alias areas
(see Table 2-6 on page 63).
0x4000.0000 - 0x5FFF.FFFF Peripheral
Device
XN
This region includes bit band and bit band
alias areas (see Table 2-7 on page 63).
0x6000.0000 - 0x9FFF.FFFF External RAM
Normal
-
This executable region is for data.
0xA000.0000 - 0xDFFF.FFFF External device
Device
XN
This region is for external device memory.
0xE000.0000- 0xE00F.FFFF Private peripheral
bus
Strongly
Ordered
XN
This region includes the NVIC, system
timer, and system control block.
0xE010.0000- 0xFFFF.FFFF Reserved
-
-
-
The Code, SRAM, and external RAM regions can hold programs. However, it is recommended that
programs always use the Code region because the Cortex-M3 has separate buses that can perform
instruction fetches and data accesses simultaneously.
The MPU can override the default memory access behavior described in this section. For more
information, see “Memory Protection Unit (MPU)” on page 85.
The Cortex-M3 prefetches instructions ahead of execution and speculatively prefetches from branch
target addresses.
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2.4.4
Software Ordering of Memory Accesses
The order of instructions in the program flow does not always guarantee the order of the
corresponding memory transactions for the following reasons:
■ The processor can reorder some memory accesses to improve efficiency, providing this does
not affect the behavior of the instruction sequence.
■ The processor has multiple bus interfaces.
■ Memory or devices in the memory map have different wait states.
■ Some memory accesses are buffered or speculative.
“Memory System Ordering of Memory Accesses” on page 61 describes the cases where the memory
system guarantees the order of memory accesses. Otherwise, if the order of memory accesses is
critical, software must include memory barrier instructions to force that ordering. The Cortex-M3
has the following memory barrier instructions:
■ The Data Memory Barrier (DMB) instruction ensures that outstanding memory transactions
complete before subsequent memory transactions.
■ The Data Synchronization Barrier (DSB) instruction ensures that outstanding memory transactions
complete before subsequent instructions execute.
■ The Instruction Synchronization Barrier (ISB) instruction ensures that the effect of all completed
memory transactions is recognizable by subsequent instructions.
Memory barrier instructions can be used in the following situations:
■ MPU programming
– If the MPU settings are changed and the change must be effective on the very next instruction,
use a DSB instruction to ensure the effect of the MPU takes place immediately at the end of
context switching.
– Use an ISB instruction to ensure the new MPU setting takes effect immediately after
programming the MPU region or regions, if the MPU configuration code was accessed using
a branch or call. If the MPU configuration code is entered using exception mechanisms, then
an ISB instruction is not required.
■ Vector table
If the program changes an entry in the vector table and then enables the corresponding exception,
use a DMB instruction between the operations. The DMB instruction ensures that if the exception
is taken immediately after being enabled, the processor uses the new exception vector.
■ Self-modifying code
If a program contains self-modifying code, use an ISB instruction immediately after the code
modification in the program. The ISB instruction ensures subsequent instruction execution uses
the updated program.
■ Memory map switching
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If the system contains a memory map switching mechanism, use a DSB instruction after switching
the memory map in the program. The DSB instruction ensures subsequent instruction execution
uses the updated memory map.
■ Dynamic exception priority change
When an exception priority has to change when the exception is pending or active, use DSB
instructions after the change. The change then takes effect on completion of the DSB instruction.
Memory accesses to Strongly Ordered memory, such as the System Control Block, do not require
the use of DMB instructions.
For more information on the memory barrier instructions, see the Cortex™-M3/M4 Instruction Set
Technical User's Manual.
2.4.5
Bit-Banding
A bit-band region maps each word in a bit-band alias region to a single bit in the bit-band region.
The bit-band regions occupy the lowest 1 MB of the SRAM and peripheral memory regions. Accesses
to the 32-MB SRAM alias region map to the 1-MB SRAM bit-band region, as shown in Table
2-6 on page 63. Accesses to the 32-MB peripheral alias region map to the 1-MB peripheral bit-band
region, as shown in Table 2-7 on page 63. For the specific address range of the bit-band regions,
see Table 2-4 on page 59.
Note:
A word access to the SRAM or the peripheral bit-band alias region maps to a single bit in
the SRAM or peripheral bit-band region.
A word access to a bit band address results in a word access to the underlying memory,
and similarly for halfword and byte accesses. This allows bit band accesses to match the
access requirements of the underlying peripheral.
Table 2-6. SRAM Memory Bit-Banding Regions
Address Range
Memory Region
Instruction and Data Accesses
Start
End
0x2000.0000
0x2000.1FFF
SRAM bit-band region Direct accesses to this memory range behave as SRAM
memory accesses, but this region is also bit addressable
through bit-band alias.
0x2200.0000
0x2203.FFFF
SRAM bit-band alias
Data accesses to this region are remapped to bit band
region. A write operation is performed as
read-modify-write. Instruction accesses are not remapped.
Table 2-7. Peripheral Memory Bit-Banding Regions
Address Range
Memory Region
Instruction and Data Accesses
0x400F.FFFF
Peripheral bit-band
region
Direct accesses to this memory range behave as
peripheral memory accesses, but this region is also bit
addressable through bit-band alias.
0x43FF.FFFF
Peripheral bit-band alias Data accesses to this region are remapped to bit band
region. A write operation is performed as
read-modify-write. Instruction accesses are not permitted.
Start
End
0x4000.0000
0x4200.0000
The following formula shows how the alias region maps onto the bit-band region:
bit_word_offset = (byte_offset x 32) + (bit_number x 4)
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bit_word_addr = bit_band_base + bit_word_offset
where:
bit_word_offset
The position of the target bit in the bit-band memory region.
bit_word_addr
The address of the word in the alias memory region that maps to the targeted bit.
bit_band_base
The starting address of the alias region.
byte_offset
The number of the byte in the bit-band region that contains the targeted bit.
bit_number
The bit position, 0-7, of the targeted bit.
Figure 2-4 on page 65 shows examples of bit-band mapping between the SRAM bit-band alias
region and the SRAM bit-band region:
■ The alias word at 0x23FF.FFE0 maps to bit 0 of the bit-band byte at 0x200F.FFFF:
0x23FF.FFE0 = 0x2200.0000 + (0x000F.FFFF*32) + (0*4)
■ The alias word at 0x23FF.FFFC maps to bit 7 of the bit-band byte at 0x200F.FFFF:
0x23FF.FFFC = 0x2200.0000 + (0x000F.FFFF*32) + (7*4)
■ The alias word at 0x2200.0000 maps to bit 0 of the bit-band byte at 0x2000.0000:
0x2200.0000 = 0x2200.0000 + (0*32) + (0*4)
■ The alias word at 0x2200.001C maps to bit 7 of the bit-band byte at 0x2000.0000:
0x2200.001C = 0x2200.0000+ (0*32) + (7*4)
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Figure 2-4. Bit-Band Mapping
32-MB Alias Region
0x23FF.FFFC
0x23FF.FFF8
0x23FF.FFF4
0x23FF.FFF0
0x23FF.FFEC
0x23FF.FFE8
0x23FF.FFE4
0x23FF.FFE0
0x2200.001C
0x2200.0018
0x2200.0014
0x2200.0010
0x2200.000C
0x2200.0008
0x2200.0004
0x2200.0000
7
3
1-MB SRAM Bit-Band Region
7
6
5
4
3
2
1
0
7
6
0x200F.FFFF
7
6
5
4
3
2
0x2000.0003
2.4.5.1
5
4
3
2
1
0
7
6
0x200F.FFFE
1
0
7
6
5
4
3
2
5
4
3
2
1
0
6
0x200F.FFFD
1
0
0x2000.0002
7
6
5
4
3
2
0x2000.0001
5
4
2
1
0
1
0
0x200F.FFFC
1
0
7
6
5
4
3
2
0x2000.0000
Directly Accessing an Alias Region
Writing to a word in the alias region updates a single bit in the bit-band region.
Bit 0 of the value written to a word in the alias region determines the value written to the targeted
bit in the bit-band region. Writing a value with bit 0 set writes a 1 to the bit-band bit, and writing a
value with bit 0 clear writes a 0 to the bit-band bit.
Bits 31:1 of the alias word have no effect on the bit-band bit. Writing 0x01 has the same effect as
writing 0xFF. Writing 0x00 has the same effect as writing 0x0E.
When reading a word in the alias region, 0x0000.0000 indicates that the targeted bit in the bit-band
region is clear and 0x0000.0001 indicates that the targeted bit in the bit-band region is set.
2.4.5.2
Directly Accessing a Bit-Band Region
“Behavior of Memory Accesses” on page 61 describes the behavior of direct byte, halfword, or word
accesses to the bit-band regions.
2.4.6
Data Storage
The processor views memory as a linear collection of bytes numbered in ascending order from zero.
For example, bytes 0-3 hold the first stored word, and bytes 4-7 hold the second stored word. Data
is stored in little-endian format, with the least-significant byte (lsbyte) of a word stored at the
lowest-numbered byte, and the most-significant byte (msbyte) stored at the highest-numbered byte.
Figure 2-5 on page 66 illustrates how data is stored.
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Figure 2-5. Data Storage
Memory
7
Register
0
31
2.4.7
Address A
B0
A+1
B1
A+2
B2
A+3
B3
lsbyte
24 23
B3
16 15
B2
8 7
B1
0
B0
msbyte
Synchronization Primitives
The Cortex-M3 instruction set includes pairs of synchronization primitives which provide a
non-blocking mechanism that a thread or process can use to obtain exclusive access to a memory
location. Software can use these primitives to perform a guaranteed read-modify-write memory
update sequence or for a semaphore mechanism.
A pair of synchronization primitives consists of:
■ A Load-Exclusive instruction, which is used to read the value of a memory location and requests
exclusive access to that location.
■ A Store-Exclusive instruction, which is used to attempt to write to the same memory location and
returns a status bit to a register. If this status bit is clear, it indicates that the thread or process
gained exclusive access to the memory and the write succeeds; if this status bit is set, it indicates
that the thread or process did not gain exclusive access to the memory and no write was
performed.
The pairs of Load-Exclusive and Store-Exclusive instructions are:
■ The word instructions LDREX and STREX
■ The halfword instructions LDREXH and STREXH
■ The byte instructions LDREXB and STREXB
Software must use a Load-Exclusive instruction with the corresponding Store-Exclusive instruction.
To perform an exclusive read-modify-write of a memory location, software must:
1. Use a Load-Exclusive instruction to read the value of the location.
2. Modify the value, as required.
3. Use a Store-Exclusive instruction to attempt to write the new value back to the memory location.
4. Test the returned status bit.
If the status bit is clear, the read-modify-write completed successfully. If the status bit is set, no
write was performed, which indicates that the value returned at step 1 might be out of date. The
software must retry the entire read-modify-write sequence.
Software can use the synchronization primitives to implement a semaphore as follows:
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1. Use a Load-Exclusive instruction to read from the semaphore address to check whether the
semaphore is free.
2. If the semaphore is free, use a Store-Exclusive to write the claim value to the semaphore
address.
3. If the returned status bit from step 2 indicates that the Store-Exclusive succeeded, then the
software has claimed the semaphore. However, if the Store-Exclusive failed, another process
might have claimed the semaphore after the software performed step 1.
The Cortex-M3 includes an exclusive access monitor that tags the fact that the processor has
executed a Load-Exclusive instruction. The processor removes its exclusive access tag if:
■ It executes a CLREX instruction.
■ It executes a Store-Exclusive instruction, regardless of whether the write succeeds.
■ An exception occurs, which means the processor can resolve semaphore conflicts between
different threads.
For more information about the synchronization primitive instructions, see the Cortex™-M3/M4
Instruction Set Technical User's Manual.
2.5
Exception Model
The ARM Cortex-M3 processor and the Nested Vectored Interrupt Controller (NVIC) prioritize and
handle all exceptions in Handler Mode. The processor state is automatically stored to the stack on
an exception and automatically restored from the stack at the end of the Interrupt Service Routine
(ISR). The vector is fetched in parallel to the state saving, enabling efficient interrupt entry. The
processor supports tail-chaining, which enables back-to-back interrupts to be performed without the
overhead of state saving and restoration.
Table 2-8 on page 69 lists all exception types. Software can set eight priority levels on seven of
these exceptions (system handlers) as well as on 22 interrupts (listed in Table 2-9 on page 70).
Priorities on the system handlers are set with the NVIC System Handler Priority n (SYSPRIn)
registers. Interrupts are enabled through the NVIC Interrupt Set Enable n (ENn) register and
prioritized with the NVIC Interrupt Priority n (PRIn) registers. Priorities can be grouped by splitting
priority levels into preemption priorities and subpriorities. All the interrupt registers are described in
“Nested Vectored Interrupt Controller (NVIC)” on page 83.
Internally, the highest user-programmable priority (0) is treated as fourth priority, after a Reset,
Non-Maskable Interrupt (NMI), and a Hard Fault, in that order. Note that 0 is the default priority for
all the programmable priorities.
Important: After a write to clear an interrupt source, it may take several processor cycles for the
NVIC to see the interrupt source de-assert. Thus if the interrupt clear is done as the
last action in an interrupt handler, it is possible for the interrupt handler to complete
while the NVIC sees the interrupt as still asserted, causing the interrupt handler to be
re-entered errantly. This situation can be avoided by either clearing the interrupt source
at the beginning of the interrupt handler or by performing a read or write after the write
to clear the interrupt source (and flush the write buffer).
See “Nested Vectored Interrupt Controller (NVIC)” on page 83 for more information on exceptions
and interrupts.
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2.5.1
Exception States
Each exception is in one of the following states:
■ Inactive. The exception is not active and not pending.
■ Pending. The exception is waiting to be serviced by the processor. An interrupt request from a
peripheral or from software can change the state of the corresponding interrupt to pending.
■ Active. An exception that is being serviced by the processor but has not completed.
Note:
An exception handler can interrupt the execution of another exception handler. In this
case, both exceptions are in the active state.
■ Active and Pending. The exception is being serviced by the processor, and there is a pending
exception from the same source.
2.5.2
Exception Types
The exception types are:
■ Reset. Reset is invoked on power up or a warm reset. The exception model treats reset as a
special form of exception. When reset is asserted, the operation of the processor stops, potentially
at any point in an instruction. When reset is deasserted, execution restarts from the address
provided by the reset entry in the vector table. Execution restarts as privileged execution in
Thread mode.
■ NMI. A non-maskable Interrupt (NMI) can be signaled using the NMI signal or triggered by
software using the Interrupt Control and State (INTCTRL) register. This exception has the
highest priority other than reset. NMI is permanently enabled and has a fixed priority of -2. NMIs
cannot be masked or prevented from activation by any other exception or preempted by any
exception other than reset.
■ Hard Fault. A hard fault is an exception that occurs because of an error during exception
processing, or because an exception cannot be managed by any other exception mechanism.
Hard faults have a fixed priority of -1, meaning they have higher priority than any exception with
configurable priority.
■ Memory Management Fault. A memory management fault is an exception that occurs because
of a memory protection related fault, including access violation and no match. The MPU or the
fixed memory protection constraints determine this fault, for both instruction and data memory
transactions. This fault is used to abort instruction accesses to Execute Never (XN) memory
regions, even if the MPU is disabled.
■ Bus Fault. A bus fault is an exception that occurs because of a memory-related fault for an
instruction or data memory transaction such as a prefetch fault or a memory access fault. This
fault can be enabled or disabled.
■ Usage Fault. A usage fault is an exception that occurs because of a fault related to instruction
execution, such as:
– An undefined instruction
– An illegal unaligned access
– Invalid state on instruction execution
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– An error on exception return
An unaligned address on a word or halfword memory access or division by zero can cause a
usage fault when the core is properly configured.
■ SVCall. A supervisor call (SVC) is an exception that is triggered by the SVC instruction. In an
OS environment, applications can use SVC instructions to access OS kernel functions and device
drivers.
■ Debug Monitor. This exception is caused by the debug monitor (when not halting). This exception
is only active when enabled. This exception does not activate if it is a lower priority than the
current activation.
■ PendSV. PendSV is a pendable, interrupt-driven request for system-level service. In an OS
environment, use PendSV for context switching when no other exception is active. PendSV is
triggered using the Interrupt Control and State (INTCTRL) register.
■ SysTick. A SysTick exception is an exception that the system timer generates when it reaches
zero when it is enabled to generate an interrupt. Software can also generate a SysTick exception
using the Interrupt Control and State (INTCTRL) register. In an OS environment, the processor
can use this exception as system tick.
■ Interrupt (IRQ). An interrupt, or IRQ, is an exception signaled by a peripheral or generated by
a software request and fed through the NVIC (prioritized). All interrupts are asynchronous to
instruction execution. In the system, peripherals use interrupts to communicate with the processor.
Table 2-9 on page 70 lists the interrupts on the LM3S828 controller.
For an asynchronous exception, other than reset, the processor can execute another instruction
between when the exception is triggered and when the processor enters the exception handler.
Privileged software can disable the exceptions that Table 2-8 on page 69 shows as having
configurable priority (see the SYSHNDCTRL register on page 118 and the DIS0 register on page 97).
For more information about hard faults, memory management faults, bus faults, and usage faults,
see “Fault Handling” on page 74.
Table 2-8. Exception Types
Exception Type
a
Vector
Number
Priority
Vector Address or
b
Offset
-
0
-
0x0000.0000
Stack top is loaded from the first
entry of the vector table on reset.
Reset
1
-3 (highest)
0x0000.0004
Asynchronous
Non-Maskable Interrupt
(NMI)
2
-2
0x0000.0008
Asynchronous
Hard Fault
3
-1
0x0000.000C
-
c
0x0000.0010
Synchronous
c
0x0000.0014
Synchronous when precise and
asynchronous when imprecise
c
Synchronous
Memory Management
4
programmable
Bus Fault
5
programmable
Usage Fault
6
programmable
0x0000.0018
7-10
-
-
-
Activation
c
c
Reserved
SVCall
11
programmable
0x0000.002C
Synchronous
Debug Monitor
12
programmable
0x0000.0030
Synchronous
-
13
-
-
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Table 2-8. Exception Types (continued)
Exception Type
PendSV
SysTick
a
Vector
Number
Priority
14
programmable
15
Interrupts
Vector Address or
b
Offset
c
0x0000.0038
Asynchronous
c
0x0000.003C
Asynchronous
programmable
16 and above
Activation
d
programmable
0x0000.0040 and above Asynchronous
a. 0 is the default priority for all the programmable priorities.
b. See “Vector Table” on page 71.
c. See SYSPRI1 on page 115.
d. See PRIn registers on page 101.
Table 2-9. Interrupts
2.5.3
Vector Number
Interrupt Number (Bit
in Interrupt Registers)
Vector Address or
Offset
Description
0-15
-
0x0000.0000 0x0000.003C
16
0
0x0000.0040
GPIO Port A
17
1
0x0000.0044
GPIO Port B
18
2
0x0000.0048
GPIO Port C
19
3
0x0000.004C
GPIO Port D
20
4
0x0000.0050
GPIO Port E
21
5
0x0000.0054
UART0
22
6
0x0000.0058
UART1
23
7
0x0000.005C
SSI0
24
8
0x0000.0060
I2C0
25-29
9-13
-
30
14
0x0000.0078
ADC0 Sequence 0
31
15
0x0000.007C
ADC0 Sequence 1
32
16
0x0000.0080
ADC0 Sequence 2
33
17
0x0000.0084
ADC0 Sequence 3
34
18
0x0000.0088
Watchdog Timer 0
35
19
0x0000.008C
Timer 0A
36
20
0x0000.0090
Timer 0B
37
21
0x0000.0094
Timer 1A
38
22
0x0000.0098
Timer 1B
39
23
0x0000.009C
Timer 2A
40
24
0x0000.00A0
Timer 2B
41-43
25-27
-
Reserved
44
28
0x0000.00B0
System Control
45
29
0x0000.00B4
Flash Memory Control
Processor exceptions
Reserved
Exception Handlers
The processor handles exceptions using:
■ Interrupt Service Routines (ISRs). Interrupts (IRQx) are the exceptions handled by ISRs.
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■ Fault Handlers. Hard fault, memory management fault, usage fault, and bus fault are fault
exceptions handled by the fault handlers.
■ System Handlers. NMI, PendSV, SVCall, SysTick, and the fault exceptions are all system
exceptions that are handled by system handlers.
2.5.4
Vector Table
The vector table contains the reset value of the stack pointer and the start addresses, also called
exception vectors, for all exception handlers. The vector table is constructed using the vector address
or offset shown in Table 2-8 on page 69. Figure 2-6 on page 71 shows the order of the exception
vectors in the vector table. The least-significant bit of each vector must be 1, indicating that the
exception handler is Thumb code
Figure 2-6. Vector Table
Exception number IRQ number
45
29
.
.
.
18
2
17
1
16
0
15
-1
14
-2
13
Offset
0x00B4
.
.
.
0x004C
0x0048
0x0044
0x0040
0x003C
0x0038
12
11
Vector
IRQ29
.
.
.
IRQ2
IRQ1
IRQ0
Systick
PendSV
Reserved
Reserved for Debug
-5
10
0x002C
9
SVCall
Reserved
8
7
6
-10
5
-11
4
-12
3
-13
2
-14
1
0x0018
0x0014
0x0010
0x000C
0x0008
0x0004
0x0000
Usage fault
Bus fault
Memory management fault
Hard fault
NMI
Reset
Initial SP value
On system reset, the vector table is fixed at address 0x0000.0000. Privileged software can write to
the Vector Table Offset (VTABLE) register to relocate the vector table start address to a different
memory location, in the range 0x0000.0100 to 0x3FFF.FF00 (see “Vector Table” on page 71). Note
that when configuring the VTABLE register, the offset must be aligned on a 256-byte boundary.
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2.5.5
Exception Priorities
As Table 2-8 on page 69 shows, all exceptions have an associated priority, with a lower priority
value indicating a higher priority and configurable priorities for all exceptions except Reset, Hard
fault, and NMI. If software does not configure any priorities, then all exceptions with a configurable
priority have a priority of 0. For information about configuring exception priorities, see page 115 and
page 101.
Note:
Configurable priority values for the Stellaris implementation are in the range 0-7. This means
that the Reset, Hard fault, and NMI exceptions, with fixed negative priority values, always
have higher priority than any other exception.
For example, assigning a higher priority value to IRQ[0] and a lower priority value to IRQ[1] means
that IRQ[1] has higher priority than IRQ[0]. If both IRQ[1] and IRQ[0] are asserted, IRQ[1] is processed
before IRQ[0].
If multiple pending exceptions have the same priority, the pending exception with the lowest exception
number takes precedence. For example, if both IRQ[0] and IRQ[1] are pending and have the same
priority, then IRQ[0] is processed before IRQ[1].
When the processor is executing an exception handler, the exception handler is preempted if a
higher priority exception occurs. If an exception occurs with the same priority as the exception being
handled, the handler is not preempted, irrespective of the exception number. However, the status
of the new interrupt changes to pending.
2.5.6
Interrupt Priority Grouping
To increase priority control in systems with interrupts, the NVIC supports priority grouping. This
grouping divides each interrupt priority register entry into two fields:
■ An upper field that defines the group priority
■ A lower field that defines a subpriority within the group
Only the group priority determines preemption of interrupt exceptions. When the processor is
executing an interrupt exception handler, another interrupt with the same group priority as the
interrupt being handled does not preempt the handler.
If multiple pending interrupts have the same group priority, the subpriority field determines the order
in which they are processed. If multiple pending interrupts have the same group priority and
subpriority, the interrupt with the lowest IRQ number is processed first.
For information about splitting the interrupt priority fields into group priority and subpriority, see
page 109.
2.5.7
Exception Entry and Return
Descriptions of exception handling use the following terms:
■ Preemption. When the processor is executing an exception handler, an exception can preempt
the exception handler if its priority is higher than the priority of the exception being handled. See
“Interrupt Priority Grouping” on page 72 for more information about preemption by an interrupt.
When one exception preempts another, the exceptions are called nested exceptions. See
“Exception Entry” on page 73 more information.
■ Return. Return occurs when the exception handler is completed, and there is no pending
exception with sufficient priority to be serviced and the completed exception handler was not
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handling a late-arriving exception. The processor pops the stack and restores the processor
state to the state it had before the interrupt occurred. See “Exception Return” on page 74 for
more information.
■ Tail-Chaining. This mechanism speeds up exception servicing. On completion of an exception
handler, if there is a pending exception that meets the requirements for exception entry, the
stack pop is skipped and control transfers to the new exception handler.
■ Late-Arriving. This mechanism speeds up preemption. If a higher priority exception occurs
during state saving for a previous exception, the processor switches to handle the higher priority
exception and initiates the vector fetch for that exception. State saving is not affected by late
arrival because the state saved is the same for both exceptions. Therefore, the state saving
continues uninterrupted. The processor can accept a late arriving exception until the first instruction
of the exception handler of the original exception enters the execute stage of the processor. On
return from the exception handler of the late-arriving exception, the normal tail-chaining rules
apply.
2.5.7.1
Exception Entry
Exception entry occurs when there is a pending exception with sufficient priority and either the
processor is in Thread mode or the new exception is of higher priority than the exception being
handled, in which case the new exception preempts the original exception.
When one exception preempts another, the exceptions are nested.
Sufficient priority means the exception has more priority than any limits set by the mask registers
(see PRIMASK on page 55, FAULTMASK on page 56, and BASEPRI on page 57). An exception
with less priority than this is pending but is not handled by the processor.
When the processor takes an exception, unless the exception is a tail-chained or a late-arriving
exception, the processor pushes information onto the current stack. This operation is referred to as
stacking and the structure of eight data words is referred to as stack frame.
Figure 2-7. Exception Stack Frame
...
{aligner}
xPSR
PC
LR
R12
R3
R2
R1
R0
Pre-IRQ top of stack
IRQ top of stack
Immediately after stacking, the stack pointer indicates the lowest address in the stack frame. Unless
stack alignment is disabled, the stack frame is aligned to a double-word address. If the STKALIGN
bit of the Configuration Control (CCR) register is set, stack align adjustment is performed during
stacking.
The stack frame includes the return address, which is the address of the next instruction in the
interrupted program. This value is restored to the PC at exception return so that the interrupted
program resumes.
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In parallel to the stacking operation, the processor performs a vector fetch that reads the exception
handler start address from the vector table. When stacking is complete, the processor starts executing
the exception handler. At the same time, the processor writes an EXC_RETURN value to the LR,
indicating which stack pointer corresponds to the stack frame and what operation mode the processor
was in before the entry occurred.
If no higher-priority exception occurs during exception entry, the processor starts executing the
exception handler and automatically changes the status of the corresponding pending interrupt to
active.
If another higher-priority exception occurs during exception entry, known as late arrival, the processor
starts executing the exception handler for this exception and does not change the pending status
of the earlier exception.
2.5.7.2
Exception Return
Exception return occurs when the processor is in Handler mode and executes one of the following
instructions to load the EXC_RETURN value into the PC:
■ An LDM or POP instruction that loads the PC
■ A BX instruction using any register
■ An LDR instruction with the PC as the destination
EXC_RETURN is the value loaded into the LR on exception entry. The exception mechanism relies
on this value to detect when the processor has completed an exception handler. The lowest four
bits of this value provide information on the return stack and processor mode. Table 2-10 on page 74
shows the EXC_RETURN values with a description of the exception return behavior.
EXC_RETURN bits 31:4 are all set. When this value is loaded into the PC, it indicates to the processor
that the exception is complete, and the processor initiates the appropriate exception return sequence.
Table 2-10. Exception Return Behavior
EXC_RETURN[31:0]
Description
0xFFFF.FFF0
Reserved
0xFFFF.FFF1
Return to Handler mode.
Exception return uses state from MSP.
Execution uses MSP after return.
0xFFFF.FFF2 - 0xFFFF.FFF8
Reserved
0xFFFF.FFF9
Return to Thread mode.
Exception return uses state from MSP.
Execution uses MSP after return.
0xFFFF.FFFA - 0xFFFF.FFFC
Reserved
0xFFFF.FFFD
Return to Thread mode.
Exception return uses state from PSP.
Execution uses PSP after return.
0xFFFF.FFFE - 0xFFFF.FFFF
2.6
Reserved
Fault Handling
Faults are a subset of the exceptions (see “Exception Model” on page 67). The following conditions
generate a fault:
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■ A bus error on an instruction fetch or vector table load or a data access.
■ An internally detected error such as an undefined instruction or an attempt to change state with
a BX instruction.
■ Attempting to execute an instruction from a memory region marked as Non-Executable (XN).
■ An MPU fault because of a privilege violation or an attempt to access an unmanaged region.
2.6.1
Fault Types
Table 2-11 on page 75 shows the types of fault, the handler used for the fault, the corresponding
fault status register, and the register bit that indicates the fault has occurred. See page 122 for more
information about the fault status registers.
Table 2-11. Faults
Fault
Handler
Fault Status Register
Bit Name
Bus error on a vector read
Hard fault
Hard Fault Status (HFAULTSTAT)
VECT
Fault escalated to a hard fault
Hard fault
Hard Fault Status (HFAULTSTAT)
FORCED
MPU or default memory mismatch on Memory management
instruction access
fault
Memory Management Fault Status
(MFAULTSTAT)
IERR
MPU or default memory mismatch on Memory management
data access
fault
Memory Management Fault Status
(MFAULTSTAT)
DERR
MPU or default memory mismatch on Memory management
exception stacking
fault
Memory Management Fault Status
(MFAULTSTAT)
MSTKE
MPU or default memory mismatch on Memory management
exception unstacking
fault
Memory Management Fault Status
(MFAULTSTAT)
MUSTKE
Bus error during exception stacking
Bus fault
Bus Fault Status (BFAULTSTAT)
BSTKE
Bus error during exception unstacking Bus fault
Bus Fault Status (BFAULTSTAT)
BUSTKE
Bus error during instruction prefetch
Bus fault
Bus Fault Status (BFAULTSTAT)
IBUS
Precise data bus error
Bus fault
Bus Fault Status (BFAULTSTAT)
PRECISE
Imprecise data bus error
Bus fault
Bus Fault Status (BFAULTSTAT)
IMPRE
Attempt to access a coprocessor
Usage fault
Usage Fault Status (UFAULTSTAT)
NOCP
Undefined instruction
Usage fault
Usage Fault Status (UFAULTSTAT)
UNDEF
Attempt to enter an invalid instruction Usage fault
b
set state
Usage Fault Status (UFAULTSTAT)
INVSTAT
a
Invalid EXC_RETURN value
Usage fault
Usage Fault Status (UFAULTSTAT)
INVPC
Illegal unaligned load or store
Usage fault
Usage Fault Status (UFAULTSTAT)
UNALIGN
Divide by 0
Usage fault
Usage Fault Status (UFAULTSTAT)
DIV0
a. Occurs on an access to an XN region even if the MPU is disabled.
b. Attempting to use an instruction set other than the Thumb instruction set, or returning to a non load-store-multiple instruction
with ICI continuation.
2.6.2
Fault Escalation and Hard Faults
All fault exceptions except for hard fault have configurable exception priority (see SYSPRI1 on
page 115). Software can disable execution of the handlers for these faults (see SYSHNDCTRL on
page 118).
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Usually, the exception priority, together with the values of the exception mask registers, determines
whether the processor enters the fault handler, and whether a fault handler can preempt another
fault handler as described in “Exception Model” on page 67.
In some situations, a fault with configurable priority is treated as a hard fault. This process is called
priority escalation, and the fault is described as escalated to hard fault. Escalation to hard fault
occurs when:
■ A fault handler causes the same kind of fault as the one it is servicing. This escalation to hard
fault occurs because a fault handler cannot preempt itself because it must have the same priority
as the current priority level.
■ A fault handler causes a fault with the same or lower priority as the fault it is servicing. This
situation happens because the handler for the new fault cannot preempt the currently executing
fault handler.
■ An exception handler causes a fault for which the priority is the same as or lower than the currently
executing exception.
■ A fault occurs and the handler for that fault is not enabled.
If a bus fault occurs during a stack push when entering a bus fault handler, the bus fault does not
escalate to a hard fault. Thus if a corrupted stack causes a fault, the fault handler executes even
though the stack push for the handler failed. The fault handler operates but the stack contents are
corrupted.
Note:
2.6.3
Only Reset and NMI can preempt the fixed priority hard fault. A hard fault can preempt any
exception other than Reset, NMI, or another hard fault.
Fault Status Registers and Fault Address Registers
The fault status registers indicate the cause of a fault. For bus faults and memory management
faults, the fault address register indicates the address accessed by the operation that caused the
fault, as shown in Table 2-12 on page 76.
Table 2-12. Fault Status and Fault Address Registers
Handler
Status Register Name
Address Register Name
Register Description
Hard fault
Hard Fault Status (HFAULTSTAT)
-
page 128
Memory management Memory Management Fault Status
fault
(MFAULTSTAT)
Memory Management Fault
Address (MMADDR)
page 122
Bus fault
Bus Fault Address
(FAULTADDR)
page 122
-
page 122
Bus Fault Status (BFAULTSTAT)
Usage fault
2.6.4
Usage Fault Status (UFAULTSTAT)
page 129
page 130
Lockup
The processor enters a lockup state if a hard fault occurs when executing the NMI or hard fault
handlers. When the processor is in the lockup state, it does not execute any instructions. The
processor remains in lockup state until it is reset, an NMI occurs, or it is halted by a debugger.
Note:
If the lockup state occurs from the NMI handler, a subsequent NMI does not cause the
processor to leave the lockup state.
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2.7
Power Management
The Cortex-M3 processor sleep modes reduce power consumption:
■ Sleep mode stops the processor clock.
■ Deep-sleep mode stops the system clock and switches off the PLL and Flash memory.
The SLEEPDEEP bit of the System Control (SYSCTRL) register selects which sleep mode is used
(see page 111). For more information about the behavior of the sleep modes, see “System
Control” on page 158.
This section describes the mechanisms for entering sleep mode and the conditions for waking up
from sleep mode, both of which apply to Sleep mode and Deep-sleep mode.
2.7.1
Entering Sleep Modes
This section describes the mechanisms software can use to put the processor into one of the sleep
modes.
The system can generate spurious wake-up events, for example a debug operation wakes up the
processor. Therefore, software must be able to put the processor back into sleep mode after such
an event. A program might have an idle loop to put the processor back to sleep mode.
2.7.1.1
Wait for Interrupt
The wait for interrupt instruction, WFI, causes immediate entry to sleep mode unless the wake-up
condition is true (see “Wake Up from WFI or Sleep-on-Exit” on page 78). When the processor
executes a WFI instruction, it stops executing instructions and enters sleep mode. See the
Cortex™-M3/M4 Instruction Set Technical User's Manual for more information.
2.7.1.2
Wait for Event
The wait for event instruction, WFE, causes entry to sleep mode conditional on the value of a one-bit
event register. When the processor executes a WFE instruction, it checks the event register. If the
register is 0, the processor stops executing instructions and enters sleep mode. If the register is 1,
the processor clears the register and continues executing instructions without entering sleep mode.
If the event register is 1, the processor must not enter sleep mode on execution of a WFE instruction.
Typically, this situation occurs if an SEV instruction has been executed. Software cannot access
this register directly.
See the Cortex™-M3/M4 Instruction Set Technical User's Manual for more information.
2.7.1.3
Sleep-on-Exit
If the SLEEPEXIT bit of the SYSCTRL register is set, when the processor completes the execution
of all exception handlers, it returns to Thread mode and immediately enters sleep mode. This
mechanism can be used in applications that only require the processor to run when an exception
occurs.
2.7.2
Wake Up from Sleep Mode
The conditions for the processor to wake up depend on the mechanism that cause it to enter sleep
mode.
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2.7.2.1
Wake Up from WFI or Sleep-on-Exit
Normally, the processor wakes up only when the NVIC detects an exception with sufficient priority
to cause exception entry. Some embedded systems might have to execute system restore tasks
after the processor wakes up and before executing an interrupt handler. Entry to the interrupt handler
can be delayed by setting the PRIMASK bit and clearing the FAULTMASK bit. If an interrupt arrives
that is enabled and has a higher priority than current exception priority, the processor wakes up but
does not execute the interrupt handler until the processor clears PRIMASK. For more information
about PRIMASK and FAULTMASK, see page 55 and page 56.
2.7.2.2
Wake Up from WFE
The processor wakes up if it detects an exception with sufficient priority to cause exception entry.
In addition, if the SEVONPEND bit in the SYSCTRL register is set, any new pending interrupt triggers
an event and wakes up the processor, even if the interrupt is disabled or has insufficient priority to
cause exception entry. For more information about SYSCTRL, see page 111.
2.8
Instruction Set Summary
The processor implements a version of the Thumb instruction set. Table 2-13 on page 78 lists the
supported instructions.
Note:
In Table 2-13 on page 78:
■
■
■
■
■
Angle brackets, <>, enclose alternative forms of the operand
Braces, {}, enclose optional operands
The Operands column is not exhaustive
Op2 is a flexible second operand that can be either a register or a constant
Most instructions can use an optional condition code suffix
For more information on the instructions and operands, see the instruction descriptions in
the Cortex™-M3/M4 Instruction Set Technical User's Manual.
Table 2-13. Cortex-M3 Instruction Summary
Mnemonic
Operands
Brief Description
Flags
ADC, ADCS
{Rd,} Rn, Op2
Add with carry
N,Z,C,V
ADD, ADDS
{Rd,} Rn, Op2
Add
N,Z,C,V
ADD, ADDW
{Rd,} Rn , #imm12
Add
N,Z,C,V
ADR
Rd, label
Load PC-relative address
-
AND, ANDS
{Rd,} Rn, Op2
Logical AND
N,Z,C
ASR, ASRS
Rd, Rm, <Rs|#n>
Arithmetic shift right
N,Z,C
B
label
Branch
-
BFC
Rd, #lsb, #width
Bit field clear
-
BFI
Rd, Rn, #lsb, #width
Bit field insert
-
BIC, BICS
{Rd,} Rn, Op2
Bit clear
N,Z,C
BKPT
#imm
Breakpoint
-
BL
label
Branch with link
-
BLX
Rm
Branch indirect with link
-
BX
Rm
Branch indirect
-
CBNZ
Rn, label
Compare and branch if non-zero
-
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Table 2-13. Cortex-M3 Instruction Summary (continued)
Mnemonic
Operands
Brief Description
Flags
CBZ
Rn, label
Compare and branch if zero
-
CLREX
-
Clear exclusive
-
CLZ
Rd, Rm
Count leading zeros
-
CMN
Rn, Op2
Compare negative
N,Z,C,V
CMP
Rn, Op2
Compare
N,Z,C,V
CPSID
i
Change processor state, disable
interrupts
-
CPSIE
i
Change processor state, enable
interrupts
-
DMB
-
Data memory barrier
-
DSB
-
Data synchronization barrier
-
EOR, EORS
{Rd,} Rn, Op2
Exclusive OR
N,Z,C
ISB
-
Instruction synchronization barrier
-
IT
-
If-Then condition block
-
LDM
Rn{!}, reglist
Load multiple registers, increment after -
LDMDB, LDMEA
Rn{!}, reglist
Load multiple registers, decrement
before
LDMFD, LDMIA
Rn{!}, reglist
Load multiple registers, increment after -
LDR
Rt, [Rn, #offset]
Load register with word
-
LDRB, LDRBT
Rt, [Rn, #offset]
Load register with byte
-
LDRD
Rt, Rt2, [Rn, #offset]
Load register with two bytes
-
LDREX
Rt, [Rn, #offset]
Load register exclusive
-
LDREXB
Rt, [Rn]
Load register exclusive with byte
-
LDREXH
Rt, [Rn]
Load register exclusive with halfword
-
LDRH, LDRHT
Rt, [Rn, #offset]
Load register with halfword
-
LDRSB, LDRSBT
Rt, [Rn, #offset]
Load register with signed byte
-
LDRSH, LDRSHT
Rt, [Rn, #offset]
Load register with signed halfword
-
LDRT
Rt, [Rn, #offset]
Load register with word
-
LSL, LSLS
Rd, Rm, <Rs|#n>
Logical shift left
N,Z,C
LSR, LSRS
Rd, Rm, <Rs|#n>
Logical shift right
N,Z,C
MLA
Rd, Rn, Rm, Ra
Multiply with accumulate, 32-bit result
-
MLS
Rd, Rn, Rm, Ra
Multiply and subtract, 32-bit result
-
MOV, MOVS
Rd, Op2
Move
N,Z,C
MOV, MOVW
Rd, #imm16
Move 16-bit constant
N,Z,C
MOVT
Rd, #imm16
Move top
-
MRS
Rd, spec_reg
Move from special register to general
register
-
MSR
spec_reg, Rm
Move from general register to special
register
N,Z,C,V
MUL, MULS
{Rd,} Rn, Rm
Multiply, 32-bit result
N,Z
MVN, MVNS
Rd, Op2
Move NOT
N,Z,C
NOP
-
No operation
-
ORN, ORNS
{Rd,} Rn, Op2
Logical OR NOT
N,Z,C
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Table 2-13. Cortex-M3 Instruction Summary (continued)
Mnemonic
Operands
Brief Description
Flags
ORR, ORRS
{Rd,} Rn, Op2
Logical OR
N,Z,C
POP
reglist
Pop registers from stack
-
PUSH
reglist
Push registers onto stack
-
RBIT
Rd, Rn
Reverse bits
-
REV
Rd, Rn
Reverse byte order in a word
-
REV16
Rd, Rn
Reverse byte order in each halfword
-
REVSH
Rd, Rn
Reverse byte order in bottom halfword
and sign extend
-
ROR, RORS
Rd, Rm, <Rs|#n>
Rotate right
N,Z,C
RRX, RRXS
Rd, Rm
Rotate right with extend
N,Z,C
RSB, RSBS
{Rd,} Rn, Op2
Reverse subtract
N,Z,C,V
SBC, SBCS
{Rd,} Rn, Op2
Subtract with carry
N,Z,C,V
SBFX
Rd, Rn, #lsb, #width
Signed bit field extract
-
SDIV
{Rd,} Rn, Rm
Signed divide
-
SEV
-
Send event
-
SMLAL
RdLo, RdHi, Rn, Rm
Signed multiply with accumulate
(32x32+64), 64-bit result
-
SMULL
RdLo, RdHi, Rn, Rm
Signed multiply (32x32), 64-bit result
-
SSAT
Rd, #n, Rm {,shift #s}
Signed saturate
Q
STM
Rn{!}, reglist
Store multiple registers, increment after -
STMDB, STMEA
Rn{!}, reglist
Store multiple registers, decrement
before
STMFD, STMIA
Rn{!}, reglist
Store multiple registers, increment after -
STR
Rt, [Rn {, #offset}]
Store register word
-
STRB, STRBT
Rt, [Rn {, #offset}]
Store register byte
-
STRD
Rt, Rt2, [Rn {, #offset}]
Store register two words
-
STREX
Rt, Rt, [Rn {, #offset}]
Store register exclusive
-
STREXB
Rd, Rt, [Rn]
Store register exclusive byte
-
STREXH
Rd, Rt, [Rn]
Store register exclusive halfword
-
STRH, STRHT
Rt, [Rn {, #offset}]
Store register halfword
-
STRSB, STRSBT
Rt, [Rn {, #offset}]
Store register signed byte
-
STRSH, STRSHT
Rt, [Rn {, #offset}]
Store register signed halfword
-
STRT
Rt, [Rn {, #offset}]
Store register word
-
SUB, SUBS
{Rd,} Rn, Op2
Subtract
N,Z,C,V
SUB, SUBW
{Rd,} Rn, #imm12
Subtract 12-bit constant
N,Z,C,V
SVC
#imm
Supervisor call
-
SXTB
{Rd,} Rm {,ROR #n}
Sign extend a byte
-
SXTH
{Rd,} Rm {,ROR #n}
Sign extend a halfword
-
TBB
[Rn, Rm]
Table branch byte
-
TBH
[Rn, Rm, LSL #1]
Table branch halfword
-
TEQ
Rn, Op2
Test equivalence
N,Z,C
TST
Rn, Op2
Test
N,Z,C
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Table 2-13. Cortex-M3 Instruction Summary (continued)
Mnemonic
Operands
Brief Description
Flags
UBFX
Rd, Rn, #lsb, #width
Unsigned bit field extract
-
UDIV
{Rd,} Rn, Rm
Unsigned divide
-
UMLAL
RdLo, RdHi, Rn, Rm
Unsigned multiply with accumulate
(32x32+32+32), 64-bit result
-
UMULL
RdLo, RdHi, Rn, Rm
Unsigned multiply (32x 2), 64-bit result -
USAT
Rd, #n, Rm {,shift #s}
Unsigned Saturate
Q
UXTB
{Rd,} Rm, {,ROR #n}
Zero extend a Byte
-
UXTH
{Rd,} Rm, {,ROR #n}
Zero extend a Halfword
-
WFE
-
Wait for event
-
WFI
-
Wait for interrupt
-
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3
Cortex-M3 Peripherals
®
This chapter provides information on the Stellaris implementation of the Cortex-M3 processor
peripherals, including:
■ SysTick (see page 82)
Provides a simple, 24-bit clear-on-write, decrementing, wrap-on-zero counter with a flexible
control mechanism.
■ Nested Vectored Interrupt Controller (NVIC) (see page 83)
– Facilitates low-latency exception and interrupt handling
– Controls power management
– Implements system control registers
■ System Control Block (SCB) (see page 85)
Provides system implementation information and system control, including configuration, control,
and reporting of system exceptions.
■ Memory Protection Unit (MPU) (see page 85)
Supports the standard ARMv7 Protected Memory System Architecture (PMSA) model. The MPU
provides full support for protection regions, overlapping protection regions, access permissions,
and exporting memory attributes to the system.
Table 3-1 on page 82 shows the address map of the Private Peripheral Bus (PPB). Some peripheral
register regions are split into two address regions, as indicated by two addresses listed.
Table 3-1. Core Peripheral Register Regions
Address
Core Peripheral
Description (see page ...)
0xE000.E010-0xE000.E01F
System Timer
82
0xE000.E100-0xE000.E4EF
Nested Vectored Interrupt Controller
83
0xE000.ED00-0xE000.ED3F
System Control Block
85
0xE000.ED90-0xE000.EDB8
Memory Protection Unit
85
0xE000.EF00-0xE000.EF03
3.1
Functional Description
This chapter provides information on the Stellaris implementation of the Cortex-M3 processor
peripherals: SysTick, NVIC, SCB and MPU.
3.1.1
System Timer (SysTick)
Cortex-M3 includes an integrated system timer, SysTick, which provides a simple, 24-bit
clear-on-write, decrementing, wrap-on-zero counter with a flexible control mechanism. The counter
can be used in several different ways, for example as:
■ An RTOS tick timer that fires at a programmable rate (for example, 100 Hz) and invokes a SysTick
routine.
■ A high-speed alarm timer using the system clock.
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■ A variable rate alarm or signal timer—the duration is range-dependent on the reference clock
used and the dynamic range of the counter.
■ A simple counter used to measure time to completion and time used.
■ An internal clock source control based on missing/meeting durations. The COUNT bit in the
STCTRL control and status register can be used to determine if an action completed within a
set duration, as part of a dynamic clock management control loop.
The timer consists of three registers:
■ SysTick Control and Status (STCTRL): A control and status counter to configure its clock,
enable the counter, enable the SysTick interrupt, and determine counter status.
■ SysTick Reload Value (STRELOAD): The reload value for the counter, used to provide the
counter's wrap value.
■ SysTick Current Value (STCURRENT): The current value of the counter.
When enabled, the timer counts down on each clock from the reload value to zero, reloads (wraps)
to the value in the STRELOAD register on the next clock edge, then decrements on subsequent
clocks. Clearing the STRELOAD register disables the counter on the next wrap. When the counter
reaches zero, the COUNT status bit is set. The COUNT bit clears on reads.
Writing to the STCURRENT register clears the register and the COUNT status bit. The write does
not trigger the SysTick exception logic. On a read, the current value is the value of the register at
the time the register is accessed.
The SysTick counter runs on the system clock. If this clock signal is stopped for low power mode,
the SysTick counter stops. Ensure software uses aligned word accesses to access the SysTick
registers.
Note:
3.1.2
When the processor is halted for debugging, the counter does not decrement.
Nested Vectored Interrupt Controller (NVIC)
This section describes the Nested Vectored Interrupt Controller (NVIC) and the registers it uses.
The NVIC supports:
■ 22 interrupts.
■ A programmable priority level of 0-7 for each interrupt. A higher level corresponds to a lower
priority, so level 0 is the highest interrupt priority.
■ Low-latency exception and interrupt handling.
■ Level and pulse detection of interrupt signals.
■ Dynamic reprioritization of interrupts.
■ Grouping of priority values into group priority and subpriority fields.
■ Interrupt tail-chaining.
■ An external Non-maskable interrupt (NMI).
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The processor automatically stacks its state on exception entry and unstacks this state on exception
exit, with no instruction overhead, providing low latency exception handling.
3.1.2.1
Level-Sensitive and Pulse Interrupts
The processor supports both level-sensitive and pulse interrupts. Pulse interrupts are also described
as edge-triggered interrupts.
A level-sensitive interrupt is held asserted until the peripheral deasserts the interrupt signal. Typically
this happens because the ISR accesses the peripheral, causing it to clear the interrupt request. A
pulse interrupt is an interrupt signal sampled synchronously on the rising edge of the processor
clock. To ensure the NVIC detects the interrupt, the peripheral must assert the interrupt signal for
at least one clock cycle, during which the NVIC detects the pulse and latches the interrupt.
When the processor enters the ISR, it automatically removes the pending state from the interrupt
(see “Hardware and Software Control of Interrupts” on page 84 for more information). For a
level-sensitive interrupt, if the signal is not deasserted before the processor returns from the ISR,
the interrupt becomes pending again, and the processor must execute its ISR again. As a result,
the peripheral can hold the interrupt signal asserted until it no longer needs servicing.
3.1.2.2
Hardware and Software Control of Interrupts
The Cortex-M3 latches all interrupts. A peripheral interrupt becomes pending for one of the following
reasons:
■ The NVIC detects that the interrupt signal is High and the interrupt is not active.
■ The NVIC detects a rising edge on the interrupt signal.
■ Software writes to the corresponding interrupt set-pending register bit, or to the Software Trigger
Interrupt (SWTRIG) register to make a Software-Generated Interrupt pending. See the INT bit
in the PEND0 register on page 98 or SWTRIG on page 103.
A pending interrupt remains pending until one of the following:
■ The processor enters the ISR for the interrupt, changing the state of the interrupt from pending
to active. Then:
– For a level-sensitive interrupt, when the processor returns from the ISR, the NVIC samples
the interrupt signal. If the signal is asserted, the state of the interrupt changes to pending,
which might cause the processor to immediately re-enter the ISR. Otherwise, the state of the
interrupt changes to inactive.
– For a pulse interrupt, the NVIC continues to monitor the interrupt signal, and if this is pulsed
the state of the interrupt changes to pending and active. In this case, when the processor
returns from the ISR the state of the interrupt changes to pending, which might cause the
processor to immediately re-enter the ISR.
If the interrupt signal is not pulsed while the processor is in the ISR, when the processor
returns from the ISR the state of the interrupt changes to inactive.
■ Software writes to the corresponding interrupt clear-pending register bit
– For a level-sensitive interrupt, if the interrupt signal is still asserted, the state of the interrupt
does not change. Otherwise, the state of the interrupt changes to inactive.
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– For a pulse interrupt, the state of the interrupt changes to inactive, if the state was pending
or to active, if the state was active and pending.
3.1.3
System Control Block (SCB)
The System Control Block (SCB) provides system implementation information and system control,
including configuration, control, and reporting of the system exceptions.
3.1.4
Memory Protection Unit (MPU)
This section describes the Memory protection unit (MPU). The MPU divides the memory map into
a number of regions and defines the location, size, access permissions, and memory attributes of
each region. The MPU supports independent attribute settings for each region, overlapping regions,
and export of memory attributes to the system.
The memory attributes affect the behavior of memory accesses to the region. The Cortex-M3 MPU
defines eight separate memory regions, 0-7, and a background region.
When memory regions overlap, a memory access is affected by the attributes of the region with the
highest number. For example, the attributes for region 7 take precedence over the attributes of any
region that overlaps region 7.
The background region has the same memory access attributes as the default memory map, but is
accessible from privileged software only.
The Cortex-M3 MPU memory map is unified, meaning that instruction accesses and data accesses
have the same region settings.
If a program accesses a memory location that is prohibited by the MPU, the processor generates
a memory management fault, causing a fault exception and possibly causing termination of the
process in an OS environment. In an OS environment, the kernel can update the MPU region setting
dynamically based on the process to be executed. Typically, an embedded OS uses the MPU for
memory protection.
Configuration of MPU regions is based on memory types (see “Memory Regions, Types and
Attributes” on page 60 for more information).
Table 3-2 on page 85 shows the possible MPU region attributes. See the section called “MPU
Configuration for a Stellaris Microcontroller” on page 89 for guidelines for programming a
microcontroller implementation.
Table 3-2. Memory Attributes Summary
Memory Type
Description
Strongly Ordered
All accesses to Strongly Ordered memory occur in program order.
Device
Memory-mapped peripherals
Normal
Normal memory
To avoid unexpected behavior, disable the interrupts before updating the attributes of a region that
the interrupt handlers might access.
Ensure software uses aligned accesses of the correct size to access MPU registers:
■ Except for the MPU Region Attribute and Size (MPUATTR) register, all MPU registers must
be accessed with aligned word accesses.
■ The MPUATTR register can be accessed with byte or aligned halfword or word accesses.
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The processor does not support unaligned accesses to MPU registers.
When setting up the MPU, and if the MPU has previously been programmed, disable unused regions
to prevent any previous region settings from affecting the new MPU setup.
3.1.4.1
Updating an MPU Region
To update the attributes for an MPU region, the MPU Region Number (MPUNUMBER), MPU
Region Base Address (MPUBASE) and MPUATTR registers must be updated. Each register can
be programmed separately or with a multiple-word write to program all of these registers. You can
use the MPUBASEx and MPUATTRx aliases to program up to four regions simultaneously using
an STM instruction.
Updating an MPU Region Using Separate Words
This example simple code configures one region:
; R1 = region number
; R2 = size/enable
; R3 = attributes
; R4 = address
LDR R0,=MPUNUMBER
STR R1, [R0, #0x0]
STR R4, [R0, #0x4]
STRH R2, [R0, #0x8]
STRH R3, [R0, #0xA]
;
;
;
;
;
0xE000ED98, MPU region number register
Region Number
Region Base Address
Region Size and Enable
Region Attribute
Disable a region before writing new region settings to the MPU if you have previously enabled the
region being changed. For example:
; R1 = region number
; R2 = size/enable
; R3 = attributes
; R4 = address
LDR R0,=MPUNUMBER
STR R1, [R0, #0x0]
BIC R2, R2, #1
STRH R2, [R0, #0x8]
STR R4, [R0, #0x4]
STRH R3, [R0, #0xA]
ORR R2, #1
STRH R2, [R0, #0x8]
;
;
;
;
;
;
;
;
0xE000ED98, MPU region number register
Region Number
Disable
Region Size and Enable
Region Base Address
Region Attribute
Enable
Region Size and Enable
Software must use memory barrier instructions:
■ Before MPU setup, if there might be outstanding memory transfers, such as buffered writes, that
might be affected by the change in MPU settings.
■ After MPU setup, if it includes memory transfers that must use the new MPU settings.
However, memory barrier instructions are not required if the MPU setup process starts by entering
an exception handler, or is followed by an exception return, because the exception entry and
exception return mechanism cause memory barrier behavior.
Software does not need any memory barrier instructions during MPU setup, because it accesses
the MPU through the Private Peripheral Bus (PPB), which is a Strongly Ordered memory region.
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For example, if all of the memory access behavior is intended to take effect immediately after the
programming sequence, then a DSB instruction and an ISB instruction should be used. A DSB is
required after changing MPU settings, such as at the end of context switch. An ISB is required if
the code that programs the MPU region or regions is entered using a branch or call. If the
programming sequence is entered using a return from exception, or by taking an exception, then
an ISB is not required.
Updating an MPU Region Using Multi-Word Writes
The MPU can be programmed directly using multi-word writes, depending how the information is
divided. Consider the following reprogramming:
; R1 = region number
; R2 = address
; R3 = size, attributes in one
LDR R0, =MPUNUMBER ; 0xE000ED98, MPU region number register
STR R1, [R0, #0x0] ; Region Number
STR R2, [R0, #0x4] ; Region Base Address
STR R3, [R0, #0x8] ; Region Attribute, Size and Enable
An STM instruction can be used to optimize this:
; R1 = region number
; R2 = address
; R3 = size, attributes in one
LDR R0, =MPUNUMBER ; 0xE000ED98, MPU region number register
STM R0, {R1-R3}
; Region number, address, attribute, size and enable
This operation can be done in two words for pre-packed information, meaning that the MPU Region
Base Address (MPUBASE) register (see page 135) contains the required region number and has
the VALID bit set. This method can be used when the data is statically packed, for example in a
boot loader:
; R1 = address and region number in one
; R2 = size and attributes in one
LDR R0, =MPUBASE
; 0xE000ED9C, MPU Region Base register
STR R1, [R0, #0x0] ; Region base address and region number combined
; with VALID (bit 4) set
STR R2, [R0, #0x4] ; Region Attribute, Size and Enable
Subregions
Regions of 256 bytes or more are divided into eight equal-sized subregions. Set the corresponding
bit in the SRD field of the MPU Region Attribute and Size (MPUATTR) register (see page 137) to
disable a subregion. The least-significant bit of the SRD field controls the first subregion, and the
most-significant bit controls the last subregion. Disabling a subregion means another region
overlapping the disabled range matches instead. If no other enabled region overlaps the disabled
subregion, the MPU issues a fault.
Regions of 32, 64, and 128 bytes do not support subregions. With regions of these sizes, the SRD
field must be configured to 0x00, otherwise the MPU behavior is unpredictable.
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Example of SRD Use
Two regions with the same base address overlap. Region one is 128 KB, and region two is 512 KB.
To ensure the attributes from region one apply to the first 128 KB region, configure the SRD field for
region two to 0x03 to disable the first two subregions, as Figure 3-1 on page 88 shows.
Figure 3-1. SRD Use Example
Region 2, with
subregions
Region 1
Base address of both regions
3.1.4.2
Offset from
base address
512KB
448KB
384KB
320KB
256KB
192KB
128KB
Disabled subregion
64KB
Disabled subregion
0
MPU Access Permission Attributes
The access permission bits, TEX, S, C, B, AP, and XN of the MPUATTR register, control access to
the corresponding memory region. If an access is made to an area of memory without the required
permissions, then the MPU generates a permission fault.
Table 3-3 on page 88 shows the encodings for the TEX, C, B, and S access permission bits. All
encodings are shown for completeness, however the current implementation of the Cortex-M3 does
not support the concept of cacheability or shareability. Refer to the section called “MPU Configuration
for a Stellaris Microcontroller” on page 89 for information on programming the MPU for Stellaris
implementations.
Table 3-3. TEX, S, C, and B Bit Field Encoding
TEX
S
000b
x
C
B
Memory Type
Shareability
Other Attributes
a
0
0
Strongly Ordered
Shareable
-
a
-
000
x
0
1
Device
Shareable
000
0
1
0
Normal
Not shareable
000
1
1
0
Normal
Shareable
000
0
1
1
Normal
Not shareable
000
1
1
1
Normal
Shareable
001
0
0
0
Normal
Not shareable
001
1
0
0
Normal
Shareable
Outer and inner
noncacheable.
001
x
a
0
1
Reserved encoding
-
-
a
Outer and inner
write-through. No write
allocate.
001
x
1
0
Reserved encoding
-
-
001
0
1
1
Normal
Not shareable
001
1
1
1
Normal
Shareable
Outer and inner
write-back. Write and
read allocate.
010
x
a
0
0
Device
Not shareable
Nonshared Device.
a
0
1
Reserved encoding
-
-
a
1
x
Reserved encoding
-
-
010
x
010
x
a
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Table 3-3. TEX, S, C, and B Bit Field Encoding (continued)
TEX
S
C
B
Memory Type
Shareability
Other Attributes
1BB
0
A
A
Normal
Not shareable
1BB
1
A
A
Normal
Shareable
Cached memory (BB =
outer policy, AA = inner
policy).
See Table 3-4 for the
encoding of the AA and
BB bits.
a. The MPU ignores the value of this bit.
Table 3-4 on page 89 shows the cache policy for memory attribute encodings with a TEX value in
the range of 0x4-0x7.
Table 3-4. Cache Policy for Memory Attribute Encoding
Encoding, AA or BB
Corresponding Cache Policy
00
Non-cacheable
01
Write back, write and read allocate
10
Write through, no write allocate
11
Write back, no write allocate
Table 3-5 on page 89 shows the AP encodings in the MPUATTR register that define the access
permissions for privileged and unprivileged software.
Table 3-5. AP Bit Field Encoding
AP Bit Field
Privileged
Permissions
Unprivileged
Permissions
Description
000
No access
No access
All accesses generate a permission fault.
001
R/W
No access
Access from privileged software only.
010
R/W
RO
Writes by unprivileged software generate a
permission fault.
011
R/W
R/W
Full access.
100
Unpredictable
Unpredictable
Reserved.
101
RO
No access
Reads by privileged software only.
110
RO
RO
Read-only, by privileged or unprivileged software.
111
RO
RO
Read-only, by privileged or unprivileged software.
MPU Configuration for a Stellaris Microcontroller
Stellaris microcontrollers have only a single processor and no caches. As a result, the MPU should
be programmed as shown in Table 3-6 on page 89.
Table 3-6. Memory Region Attributes for Stellaris Microcontrollers
Memory Region
TEX
S
C
B
Memory Type and Attributes
Flash memory
000b
0
1
0
Normal memory, non-shareable, write-through
Internal SRAM
000b
1
1
0
Normal memory, shareable, write-through
External SRAM
000b
1
1
1
Normal memory, shareable, write-back,
write-allocate
Peripherals
000b
1
0
1
Device memory, shareable
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In current Stellaris microcontroller implementations, the shareability and cache policy attributes do
not affect the system behavior. However, using these settings for the MPU regions can make the
application code more portable. The values given are for typical situations.
3.1.4.3
MPU Mismatch
When an access violates the MPU permissions, the processor generates a memory management
fault (see “Exceptions and Interrupts” on page 59 for more information). The MFAULTSTAT register
indicates the cause of the fault. See page 122 for more information.
3.2
Register Map
Table 3-7 on page 90 lists the Cortex-M3 Peripheral SysTick, NVIC, MPU and SCB registers. The
offset listed is a hexadecimal increment to the register's address, relative to the Core Peripherals
base address of 0xE000.E000.
Note:
Register spaces that are not used are reserved for future or internal use. Software should
not modify any reserved memory address.
Table 3-7. Peripherals Register Map
Offset
Name
Type
Reset
Description
See
page
System Timer (SysTick) Registers
0x010
STCTRL
R/W
0x0000.0000
SysTick Control and Status Register
92
0x014
STRELOAD
R/W
0x0000.0000
SysTick Reload Value Register
94
0x018
STCURRENT
R/WC
0x0000.0000
SysTick Current Value Register
95
Nested Vectored Interrupt Controller (NVIC) Registers
0x100
EN0
R/W
0x0000.0000
Interrupt 0-29 Set Enable
96
0x180
DIS0
R/W
0x0000.0000
Interrupt 0-29 Clear Enable
97
0x200
PEND0
R/W
0x0000.0000
Interrupt 0-29 Set Pending
98
0x280
UNPEND0
R/W
0x0000.0000
Interrupt 0-29 Clear Pending
99
0x300
ACTIVE0
RO
0x0000.0000
Interrupt 0-29 Active Bit
100
0x400
PRI0
R/W
0x0000.0000
Interrupt 0-3 Priority
101
0x404
PRI1
R/W
0x0000.0000
Interrupt 4-7 Priority
101
0x408
PRI2
R/W
0x0000.0000
Interrupt 8-11 Priority
101
0x40C
PRI3
R/W
0x0000.0000
Interrupt 12-15 Priority
101
0x410
PRI4
R/W
0x0000.0000
Interrupt 16-19 Priority
101
0x414
PRI5
R/W
0x0000.0000
Interrupt 20-23 Priority
101
0x418
PRI6
R/W
0x0000.0000
Interrupt 24-27 Priority
101
0x41C
PRI7
R/W
0x0000.0000
Interrupt 28-29 Priority
101
0xF00
SWTRIG
WO
0x0000.0000
Software Trigger Interrupt
103
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Table 3-7. Peripherals Register Map (continued)
Offset
Name
Type
Reset
Description
See
page
System Control Block (SCB) Registers
0xD00
CPUID
RO
0x410F.C231
CPU ID Base
104
0xD04
INTCTRL
R/W
0x0000.0000
Interrupt Control and State
105
0xD08
VTABLE
R/W
0x0000.0000
Vector Table Offset
108
0xD0C
APINT
R/W
0xFA05.0000
Application Interrupt and Reset Control
109
0xD10
SYSCTRL
R/W
0x0000.0000
System Control
111
0xD14
CFGCTRL
R/W
0x0000.0000
Configuration and Control
113
0xD18
SYSPRI1
R/W
0x0000.0000
System Handler Priority 1
115
0xD1C
SYSPRI2
R/W
0x0000.0000
System Handler Priority 2
116
0xD20
SYSPRI3
R/W
0x0000.0000
System Handler Priority 3
117
0xD24
SYSHNDCTRL
R/W
0x0000.0000
System Handler Control and State
118
0xD28
FAULTSTAT
R/W1C
0x0000.0000
Configurable Fault Status
122
0xD2C
HFAULTSTAT
R/W1C
0x0000.0000
Hard Fault Status
128
0xD34
MMADDR
R/W
-
Memory Management Fault Address
129
0xD38
FAULTADDR
R/W
-
Bus Fault Address
130
Memory Protection Unit (MPU) Registers
0xD90
MPUTYPE
RO
0x0000.0800
MPU Type
131
0xD94
MPUCTRL
R/W
0x0000.0000
MPU Control
132
0xD98
MPUNUMBER
R/W
0x0000.0000
MPU Region Number
134
0xD9C
MPUBASE
R/W
0x0000.0000
MPU Region Base Address
135
0xDA0
MPUATTR
R/W
0x0000.0000
MPU Region Attribute and Size
137
0xDA4
MPUBASE1
R/W
0x0000.0000
MPU Region Base Address Alias 1
135
0xDA8
MPUATTR1
R/W
0x0000.0000
MPU Region Attribute and Size Alias 1
137
0xDAC
MPUBASE2
R/W
0x0000.0000
MPU Region Base Address Alias 2
135
0xDB0
MPUATTR2
R/W
0x0000.0000
MPU Region Attribute and Size Alias 2
137
0xDB4
MPUBASE3
R/W
0x0000.0000
MPU Region Base Address Alias 3
135
0xDB8
MPUATTR3
R/W
0x0000.0000
MPU Region Attribute and Size Alias 3
137
3.3
System Timer (SysTick) Register Descriptions
This section lists and describes the System Timer registers, in numerical order by address offset.
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Register 1: SysTick Control and Status Register (STCTRL), offset 0x010
Note:
This register can only be accessed from privileged mode.
The SysTick STCTRL register enables the SysTick features.
SysTick Control and Status Register (STCTRL)
Base 0xE000.E000
Offset 0x010
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
9
8
7
6
5
4
3
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
16
COUNT
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
2
1
0
CLK_SRC
INTEN
ENABLE
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:17
reserved
RO
0x000
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
16
COUNT
RO
0
Count Flag
Value
Description
0
The SysTick timer has not counted to 0 since the last time
this bit was read.
1
The SysTick timer has counted to 0 since the last time
this bit was read.
This bit is cleared by a read of the register or if the STCURRENT register
is written with any value.
If read by the debugger using the DAP, this bit is cleared only if the
MasterType bit in the AHB-AP Control Register is clear. Otherwise,
the COUNT bit is not changed by the debugger read. See the ARM®
Debug Interface V5 Architecture Specification for more information on
MasterType.
15:3
reserved
RO
0x000
2
CLK_SRC
R/W
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Clock Source
Value Description
0
External reference clock. (Not implemented for most Stellaris
microcontrollers.)
1
System clock
Because an external reference clock is not implemented, this bit must
be set in order for SysTick to operate.
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Bit/Field
Name
Type
Reset
1
INTEN
R/W
0
0
ENABLE
R/W
0
Description
Interrupt Enable
Value
Description
0
Interrupt generation is disabled. Software can use the
COUNT bit to determine if the counter has ever reached 0.
1
An interrupt is generated to the NVIC when SysTick counts
to 0.
Enable
Value
Description
0
The counter is disabled.
1
Enables SysTick to operate in a multi-shot way. That is, the
counter loads the RELOAD value and begins counting down.
On reaching 0, the COUNT bit is set and an interrupt is
generated if enabled by INTEN. The counter then loads the
RELOAD value again and begins counting.
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Register 2: SysTick Reload Value Register (STRELOAD), offset 0x014
Note:
This register can only be accessed from privileged mode.
The STRELOAD register specifies the start value to load into the SysTick Current Value
(STCURRENT) register when the counter reaches 0. The start value can be between 0x1 and
0x00FF.FFFF. A start value of 0 is possible but has no effect because the SysTick interrupt and the
COUNT bit are activated when counting from 1 to 0.
SysTick can be configured as a multi-shot timer, repeated over and over, firing every N+1 clock
pulses, where N is any value from 1 to 0x00FF.FFFF. For example, if a tick interrupt is required
every 100 clock pulses, 99 must be written into the RELOAD field.
SysTick Reload Value Register (STRELOAD)
Base 0xE000.E000
Offset 0x014
Type R/W, reset 0x0000.0000
31
30
29
28
RO
0
RO
0
RO
0
RO
0
15
14
13
R/W
0
R/W
0
R/W
0
27
26
25
24
23
22
21
20
18
17
16
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
12
11
10
9
8
7
6
5
4
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
19
RELOAD
RELOAD
Type
Reset
Bit/Field
Name
Type
Reset
Description
31:24
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
23:0
RELOAD
R/W
0x00.0000
Reload Value
Value to load into the SysTick Current Value (STCURRENT) register
when the counter reaches 0.
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Register 3: SysTick Current Value Register (STCURRENT), offset 0x018
Note:
This register can only be accessed from privileged mode.
The STCURRENT register contains the current value of the SysTick counter.
SysTick Current Value Register (STCURRENT)
Base 0xE000.E000
Offset 0x018
Type R/WC, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
reserved
Type
Reset
20
19
18
17
16
CURRENT
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
R/WC
0
R/WC
0
R/WC
0
R/WC
0
R/WC
0
R/WC
0
R/WC
0
R/WC
0
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
R/WC
0
R/WC
0
R/WC
0
R/WC
0
R/WC
0
R/WC
0
R/WC
0
CURRENT
Type
Reset
R/WC
0
R/WC
0
R/WC
0
R/WC
0
R/WC
0
R/WC
0
R/WC
0
R/WC
0
R/WC
0
Bit/Field
Name
Type
Reset
Description
31:24
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
23:0
CURRENT
R/WC
0x00.0000
Current Value
This field contains the current value at the time the register is accessed.
No read-modify-write protection is provided, so change with care.
This register is write-clear. Writing to it with any value clears the register.
Clearing this register also clears the COUNT bit of the STCTRL register.
3.4
NVIC Register Descriptions
This section lists and describes the NVIC registers, in numerical order by address offset.
The NVIC registers can only be fully accessed from privileged mode, but interrupts can be pended
while in unprivileged mode by enabling the Configuration and Control (CFGCTRL) register. Any
other unprivileged mode access causes a bus fault.
Ensure software uses correctly aligned register accesses. The processor does not support unaligned
accesses to NVIC registers.
An interrupt can enter the pending state even if it is disabled.
Before programming the VTABLE register to relocate the vector table, ensure the vector table
entries of the new vector table are set up for fault handlers, NMI, and all enabled exceptions such
as interrupts. For more information, see page 108.
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Register 4: Interrupt 0-29 Set Enable (EN0), offset 0x100
Note:
This register can only be accessed from privileged mode.
The EN0 register enables interrupts and shows which interrupts are enabled. Bit 0 corresponds to
Interrupt 0; bit 29 corresponds to Interrupt 29.
See Table 2-9 on page 70 for interrupt assignments.
If a pending interrupt is enabled, the NVIC activates the interrupt based on its priority. If an interrupt
is not enabled, asserting its interrupt signal changes the interrupt state to pending, but the NVIC
never activates the interrupt, regardless of its priority.
Interrupt 0-29 Set Enable (EN0)
Base 0xE000.E000
Offset 0x100
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
7
6
5
4
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
INT
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
15
14
13
12
11
10
9
8
INT
Type
Reset
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
31:30
reserved
RO
0x0
29:0
INT
R/W
0x000.0000
R/W
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Interrupt Enable
Value
Description
0
On a read, indicates the interrupt is disabled.
On a write, no effect.
1
On a read, indicates the interrupt is enabled.
On a write, enables the interrupt.
A bit can only be cleared by setting the corresponding INT[n] bit in
the DISn register.
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Register 5: Interrupt 0-29 Clear Enable (DIS0), offset 0x180
Note:
This register can only be accessed from privileged mode.
The DIS0 register disables interrupts. Bit 0 corresponds to Interrupt 0; bit 29 corresponds to Interrupt
29.
See Table 2-9 on page 70 for interrupt assignments.
Interrupt 0-29 Clear Enable (DIS0)
Base 0xE000.E000
Offset 0x180
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
reserved
Type
Reset
22
21
20
19
18
17
16
INT
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
INT
Type
Reset
Bit/Field
Name
Type
Reset
31:30
reserved
RO
0x0
29:0
INT
R/W
0x000.0000
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Interrupt Disable
Value Description
0
On a read, indicates the interrupt is disabled.
On a write, no effect.
1
On a read, indicates the interrupt is enabled.
On a write, clears the corresponding INT[n] bit in the EN0
register, disabling interrupt [n].
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Register 6: Interrupt 0-29 Set Pending (PEND0), offset 0x200
Note:
This register can only be accessed from privileged mode.
The PEND0 register forces interrupts into the pending state and shows which interrupts are pending.
Bit 0 corresponds to Interrupt 0; bit 29 corresponds to Interrupt 29.
See Table 2-9 on page 70 for interrupt assignments.
Interrupt 0-29 Set Pending (PEND0)
Base 0xE000.E000
Offset 0x200
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
reserved
Type
Reset
22
21
20
19
18
17
16
INT
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
INT
Type
Reset
Bit/Field
Name
Type
Reset
31:30
reserved
RO
0x0
29:0
INT
R/W
0x000.0000
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Interrupt Set Pending
Value
Description
0
On a read, indicates that the interrupt is not pending.
On a write, no effect.
1
On a read, indicates that the interrupt is pending.
On a write, the corresponding interrupt is set to pending
even if it is disabled.
If the corresponding interrupt is already pending, setting a bit has no
effect.
A bit can only be cleared by setting the corresponding INT[n] bit in
the UNPEND0 register.
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Register 7: Interrupt 0-29 Clear Pending (UNPEND0), offset 0x280
Note:
This register can only be accessed from privileged mode.
The UNPEND0 register shows which interrupts are pending and removes the pending state from
interrupts. Bit 0 corresponds to Interrupt 0; bit 29 corresponds to Interrupt 29.
See Table 2-9 on page 70 for interrupt assignments.
Interrupt 0-29 Clear Pending (UNPEND0)
Base 0xE000.E000
Offset 0x280
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
reserved
Type
Reset
22
21
20
19
18
17
16
INT
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
INT
Type
Reset
Bit/Field
Name
Type
Reset
31:30
reserved
RO
0x0
29:0
INT
R/W
0x000.0000
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Interrupt Clear Pending
Value Description
0
On a read, indicates that the interrupt is not pending.
On a write, no effect.
1
On a read, indicates that the interrupt is pending.
On a write, clears the corresponding INT[n] bit in the PEND0
register, so that interrupt [n] is no longer pending.
Setting a bit does not affect the active state of the corresponding
interrupt.
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Register 8: Interrupt 0-29 Active Bit (ACTIVE0), offset 0x300
Note:
This register can only be accessed from privileged mode.
The ACTIVE0 register indicates which interrupts are active. Bit 0 corresponds to Interrupt 0; bit 29
corresponds to Interrupt 29.
See Table 2-9 on page 70 for interrupt assignments.
Caution – Do not manually set or clear the bits in this register.
Interrupt 0-29 Active Bit (ACTIVE0)
Base 0xE000.E000
Offset 0x300
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
reserved
Type
Reset
22
21
20
19
18
17
16
INT
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
INT
Type
Reset
Bit/Field
Name
Type
Reset
31:30
reserved
RO
0x0
29:0
INT
RO
0x000.0000
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Interrupt Active
Value Description
0
The corresponding interrupt is not active.
1
The corresponding interrupt is active, or active and pending.
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Register 9: Interrupt 0-3 Priority (PRI0), offset 0x400
Register 10: Interrupt 4-7 Priority (PRI1), offset 0x404
Register 11: Interrupt 8-11 Priority (PRI2), offset 0x408
Register 12: Interrupt 12-15 Priority (PRI3), offset 0x40C
Register 13: Interrupt 16-19 Priority (PRI4), offset 0x410
Register 14: Interrupt 20-23 Priority (PRI5), offset 0x414
Register 15: Interrupt 24-27 Priority (PRI6), offset 0x418
Register 16: Interrupt 28-29 Priority (PRI7), offset 0x41C
Note:
This register can only be accessed from privileged mode.
The PRIn registers provide 3-bit priority fields for each interrupt. These registers are byte accessible.
Each register holds four priority fields that are assigned to interrupts as follows:
PRIn Register Bit Field
Interrupt
Bits 31:29
Interrupt [4n+3]
Bits 23:21
Interrupt [4n+2]
Bits 15:13
Interrupt [4n+1]
Bits 7:5
Interrupt [4n]
See Table 2-9 on page 70 for interrupt assignments.
Each priority level can be split into separate group priority and subpriority fields. The PRIGROUP
field in the Application Interrupt and Reset Control (APINT) register (see page 109) indicates the
position of the binary point that splits the priority and subpriority fields.
These registers can only be accessed from privileged mode.
Interrupt 0-3 Priority (PRI0)
Base 0xE000.E000
Offset 0x400
Type R/W, reset 0x0000.0000
31
30
29
28
27
INTD
Type
Reset
R/W
0
15
R/W
0
R/W
0
RO
0
RO
0
14
13
12
11
INTB
Type
Reset
R/W
0
R/W
0
26
25
24
23
reserved
RO
0
RO
0
RO
0
R/W
0
10
9
8
7
reserved
R/W
0
RO
0
RO
0
RO
0
22
21
20
19
INTC
R/W
0
R/W
0
RO
0
RO
0
6
5
4
3
INTA
RO
0
Bit/Field
Name
Type
Reset
31:29
INTD
R/W
0x0
RO
0
R/W
0
R/W
0
18
17
16
RO
0
RO
0
RO
0
2
1
0
RO
0
RO
0
reserved
reserved
R/W
0
RO
0
RO
0
RO
0
Description
Interrupt Priority for Interrupt [4n+3]
This field holds a priority value, 0-7, for the interrupt with the number
[4n+3], where n is the number of the Interrupt Priority register (n=0 for
PRI0, and so on). The lower the value, the greater the priority of the
corresponding interrupt.
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Bit/Field
Name
Type
Reset
Description
28:24
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
23:21
INTC
R/W
0x0
Interrupt Priority for Interrupt [4n+2]
This field holds a priority value, 0-7, for the interrupt with the number
[4n+2], where n is the number of the Interrupt Priority register (n=0 for
PRI0, and so on). The lower the value, the greater the priority of the
corresponding interrupt.
20:16
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
15:13
INTB
R/W
0x0
Interrupt Priority for Interrupt [4n+1]
This field holds a priority value, 0-7, for the interrupt with the number
[4n+1], where n is the number of the Interrupt Priority register (n=0 for
PRI0, and so on). The lower the value, the greater the priority of the
corresponding interrupt.
12:8
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:5
INTA
R/W
0x0
Interrupt Priority for Interrupt [4n]
This field holds a priority value, 0-7, for the interrupt with the number
[4n], where n is the number of the Interrupt Priority register (n=0 for
PRI0, and so on). The lower the value, the greater the priority of the
corresponding interrupt.
4:0
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Register 17: Software Trigger Interrupt (SWTRIG), offset 0xF00
Note:
Only privileged software can enable unprivileged access to the SWTRIG register.
Writing an interrupt number to the SWTRIG register generates a Software Generated Interrupt (SGI).
See Table 2-9 on page 70 for interrupt assignments.
When the MAINPEND bit in the Configuration and Control (CFGCTRL) register (see page 113) is
set, unprivileged software can access the SWTRIG register.
Software Trigger Interrupt (SWTRIG)
Base 0xE000.E000
Offset 0xF00
Type WO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
WO
0
WO
0
WO
0
WO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
INTID
Bit/Field
Name
Type
Reset
31:5
reserved
RO
0x0000.00
4:0
INTID
WO
0x00
WO
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Interrupt ID
This field holds the interrupt ID of the required SGI. For example, a value
of 0x3 generates an interrupt on IRQ3.
3.5
System Control Block (SCB) Register Descriptions
This section lists and describes the System Control Block (SCB) registers, in numerical order by
address offset. The SCB registers can only be accessed from privileged mode.
All registers must be accessed with aligned word accesses except for the FAULTSTAT and
SYSPRI1-SYSPRI3 registers, which can be accessed with byte or aligned halfword or word accesses.
The processor does not support unaligned accesses to system control block registers.
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Register 18: CPU ID Base (CPUID), offset 0xD00
Note:
This register can only be accessed from privileged mode.
The CPUID register contains the ARM® Cortex™-M3 processor part number, version, and
implementation information.
CPU ID Base (CPUID)
Base 0xE000.E000
Offset 0xD00
Type RO, reset 0x410F.C231
31
30
29
28
27
26
25
24
23
22
IMP
Type
Reset
21
20
19
18
VAR
RO
0
RO
1
RO
0
RO
0
RO
0
RO
0
RO
0
RO
1
RO
0
RO
0
RO
0
RO
0
RO
1
RO
1
15
14
13
12
11
10
9
8
7
6
5
4
3
2
PARTNO
Type
Reset
RO
1
RO
1
RO
0
RO
0
RO
0
RO
0
RO
1
17
16
RO
1
RO
1
1
0
RO
0
RO
1
CON
REV
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:24
IMP
RO
0x41
Implementer Code
RO
1
RO
1
RO
0
RO
0
Value Description
0x41 ARM
23:20
VAR
RO
0x0
Variant Number
Value Description
0x0
19:16
CON
RO
0xF
The rn value in the rnpn product revision identifier, for example,
the 0 in r0p1.
Constant
Value Description
0xF
15:4
PARTNO
RO
0xC23
Always reads as 0xF.
Part Number
Value Description
0xC23 Cortex-M3 processor.
3:0
REV
RO
0x1
Revision Number
Value Description
0x1
The pn value in the rnpn product revision identifier, for example,
the 1 in r0p1.
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Register 19: Interrupt Control and State (INTCTRL), offset 0xD04
Note:
This register can only be accessed from privileged mode.
The INCTRL register provides a set-pending bit for the NMI exception, and set-pending and
clear-pending bits for the PendSV and SysTick exceptions. In addition, bits in this register indicate
the exception number of the exception being processed, whether there are preempted active
exceptions, the exception number of the highest priority pending exception, and whether any interrupts
are pending.
When writing to INCTRL, the effect is unpredictable when writing a 1 to both the PENDSV and
UNPENDSV bits, or writing a 1 to both the PENDSTSET and PENDSTCLR bits.
Interrupt Control and State (INTCTRL)
Base 0xE000.E000
Offset 0xD04
Type R/W, reset 0x0000.0000
31
30
NMISET
Type
Reset
29
reserved
28
26
25
24
PENDSV UNPENDSV PENDSTSET PENDSTCLR reserved
23
22
21
20
ISRPRE ISRPEND
19
18
17
reserved
16
VECPEND
R/W
0
RO
0
RO
0
R/W
0
WO
0
R/W
0
WO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
VECPEND
Type
Reset
27
RO
0
RETBASE
RO
0
reserved
RO
0
Bit/Field
Name
Type
Reset
31
NMISET
R/W
0
RO
0
VECACT
Description
NMI Set Pending
Value Description
0
On a read, indicates an NMI exception is not pending.
On a write, no effect.
1
On a read, indicates an NMI exception is pending.
On a write, changes the NMI exception state to pending.
Because NMI is the highest-priority exception, normally the processor
enters the NMI exception handler as soon as it registers the setting of
this bit, and clears this bit on entering the interrupt handler. A read of
this bit by the NMI exception handler returns 1 only if the NMI signal is
reasserted while the processor is executing that handler.
30:29
reserved
RO
0x0
28
PENDSV
R/W
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
PendSV Set Pending
Value Description
0
On a read, indicates a PendSV exception is not pending.
On a write, no effect.
1
On a read, indicates a PendSV exception is pending.
On a write, changes the PendSV exception state to pending.
Setting this bit is the only way to set the PendSV exception state to
pending. This bit is cleared by writing a 1 to the UNPENDSV bit.
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Bit/Field
Name
Type
Reset
27
UNPENDSV
WO
0
Description
PendSV Clear Pending
Value Description
0
On a write, no effect.
1
On a write, removes the pending state from the PendSV
exception.
This bit is write only; on a register read, its value is unknown.
26
PENDSTSET
R/W
0
SysTick Set Pending
Value Description
0
On a read, indicates a SysTick exception is not pending.
On a write, no effect.
1
On a read, indicates a SysTick exception is pending.
On a write, changes the SysTick exception state to pending.
This bit is cleared by writing a 1 to the PENDSTCLR bit.
25
PENDSTCLR
WO
0
SysTick Clear Pending
Value Description
0
On a write, no effect.
1
On a write, removes the pending state from the SysTick
exception.
This bit is write only; on a register read, its value is unknown.
24
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
23
ISRPRE
RO
0
Debug Interrupt Handling
Value Description
0
The release from halt does not take an interrupt.
1
The release from halt takes an interrupt.
This bit is only meaningful in Debug mode and reads as zero when the
processor is not in Debug mode.
22
ISRPEND
RO
0
Interrupt Pending
Value Description
0
No interrupt is pending.
1
An interrupt is pending.
This bit provides status for all interrupts excluding NMI and Faults.
21:18
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Bit/Field
Name
Type
Reset
Description
17:12
VECPEND
RO
0x00
Interrupt Pending Vector Number
This field contains the exception number of the highest priority pending
enabled exception. The value indicated by this field includes the effect
of the BASEPRI and FAULTMASK registers, but not any effect of the
PRIMASK register.
Value
Description
0x00
No exceptions are pending
0x01
Reserved
0x02
NMI
0x03
Hard fault
0x04
Memory management fault
0x05
Bus fault
0x06
Usage fault
0x07-0x0A Reserved
0x0B
SVCall
0x0C
Reserved for Debug
0x0D
Reserved
0x0E
PendSV
0x0F
SysTick
0x10
Interrupt Vector 0
0x11
Interrupt Vector 1
...
...
0x2D
Interrupt Vector 29
0x2E-0x3F Reserved
11
RETBASE
RO
0
Return to Base
Value Description
0
There are preempted active exceptions to execute.
1
There are no active exceptions, or the currently executing
exception is the only active exception.
This bit provides status for all interrupts excluding NMI and Faults. This
bit only has meaning if the processor is currently executing an ISR (the
Interrupt Program Status (IPSR) register is non-zero).
10:6
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
5:0
VECACT
RO
0x00
Interrupt Pending Vector Number
This field contains the active exception number. The exception numbers
can be found in the description for the VECPEND field. If this field is clear,
the processor is in Thread mode. This field contains the same value as
the ISRNUM field in the IPSR register.
Subtract 16 from this value to obtain the IRQ number required to index
into the Interrupt Set Enable (ENn), Interrupt Clear Enable (DISn),
Interrupt Set Pending (PENDn), Interrupt Clear Pending (UNPENDn),
and Interrupt Priority (PRIn) registers (see page 51).
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Register 20: Vector Table Offset (VTABLE), offset 0xD08
Note:
This register can only be accessed from privileged mode.
The VTABLE register indicates the offset of the vector table base address from memory address
0x0000.0000.
Vector Table Offset (VTABLE)
Base 0xE000.E000
Offset 0xD08
Type R/W, reset 0x0000.0000
31
30
reserved
Type
Reset
29
28
27
26
25
24
23
BASE
22
21
20
19
18
17
16
OFFSET
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
OFFSET
Type
Reset
R/W
0
R/W
0
R/W
0
R/W
0
reserved
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
31:30
reserved
RO
0x0
29
BASE
R/W
0
R/W
0
RO
0
RO
0
RO
0
RO
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Vector Table Base
Value Description
28:8
OFFSET
R/W
0x000.00
0
The vector table is in the code memory region.
1
The vector table is in the SRAM memory region.
Vector Table Offset
When configuring the OFFSET field, the offset must be aligned to the
number of exception entries in the vector table. Because there are 29
interrupts, the offset must be aligned on a 256-byte boundary.
7:0
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Register 21: Application Interrupt and Reset Control (APINT), offset 0xD0C
Note:
This register can only be accessed from privileged mode.
The APINT register provides priority grouping control for the exception model, endian status for
data accesses, and reset control of the system. To write to this register, 0x05FA must be written to
the VECTKEY field, otherwise the write is ignored.
The PRIGROUP field indicates the position of the binary point that splits the INTx fields in the
Interrupt Priority (PRIx) registers into separate group priority and subpriority fields. Table
3-8 on page 109 shows how the PRIGROUP value controls this split. The bit numbers in the Group
Priority Field and Subpriority Field columns in the table refer to the bits in the INTA field. For the
INTB field, the corresponding bits are 15:13; for INTC, 23:21; and for INTD, 31:29.
Note:
Determining preemption of an exception uses only the group priority field.
Table 3-8. Interrupt Priority Levels
a
PRIGROUP Bit Field
Binary Point
Group Priority Field Subpriority Field
Group
Priorities
Subpriorities
0x0 - 0x4
bxxx.
[7:5]
None
8
1
0x5
bxx.y
[7:6]
[5]
4
2
0x6
bx.yy
[7]
[6:5]
2
4
0x7
b.yyy
None
[7:5]
1
8
a. INTx field showing the binary point. An x denotes a group priority field bit, and a y denotes a subpriority field bit.
Application Interrupt and Reset Control (APINT)
Base 0xE000.E000
Offset 0xD0C
Type R/W, reset 0xFA05.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
R/W
0
R/W
0
R/W
0
R/W
1
R/W
0
R/W
1
5
4
3
2
1
0
VECTKEY
Type
Reset
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
0
15
14
13
12
11
10
reserved
ENDIANESS
Type
Reset
RO
0
RO
0
RO
0
RO
0
R/W
1
R/W
0
R/W
0
R/W
0
9
8
7
6
PRIGROUP
RO
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
31:16
VECTKEY
R/W
0xFA05
reserved
R/W
0
RO
0
RO
0
RO
0
SYSRESREQ VECTCLRACT VECTRESET
RO
0
RO
0
WO
0
WO
0
WO
0
Description
Register Key
This field is used to guard against accidental writes to this register.
0x05FA must be written to this field in order to change the bits in this
register. On a read, 0xFA05 is returned.
15
ENDIANESS
RO
0
Data Endianess
The Stellaris implementation uses only little-endian mode so this is
cleared to 0.
14:11
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Bit/Field
Name
Type
Reset
10:8
PRIGROUP
R/W
0x0
Description
Interrupt Priority Grouping
This field determines the split of group priority from subpriority (see
Table 3-8 on page 109 for more information).
7:3
reserved
RO
0x0
2
SYSRESREQ
WO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
System Reset Request
Value Description
0
No effect.
1
Resets the core and all on-chip peripherals except the Debug
interface.
This bit is automatically cleared during the reset of the core and reads
as 0.
1
VECTCLRACT
WO
0
Clear Active NMI / Fault
This bit is reserved for Debug use and reads as 0. This bit must be
written as a 0, otherwise behavior is unpredictable.
0
VECTRESET
WO
0
System Reset
This bit is reserved for Debug use and reads as 0. This bit must be
written as a 0, otherwise behavior is unpredictable.
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Register 22: System Control (SYSCTRL), offset 0xD10
Note:
This register can only be accessed from privileged mode.
The SYSCTRL register controls features of entry to and exit from low-power state.
System Control (SYSCTRL)
Base 0xE000.E000
Offset 0xD10
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
2
1
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
10
9
8
7
6
5
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
31:5
reserved
RO
0x0000.00
4
SEVONPEND
R/W
0
RO
0
RO
0
RO
0
RO
0
4
3
SEVONPEND
reserved
R/W
0
RO
0
SLEEPDEEP SLEEPEXIT
R/W
0
R/W
0
0
reserved
RO
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Wake Up on Pending
Value Description
0
Only enabled interrupts or events can wake up the processor;
disabled interrupts are excluded.
1
Enabled events and all interrupts, including disabled interrupts,
can wake up the processor.
When an event or interrupt enters the pending state, the event signal
wakes up the processor from WFE. If the processor is not waiting for an
event, the event is registered and affects the next WFE.
The processor also wakes up on execution of a SEV instruction or an
external event.
3
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
2
SLEEPDEEP
R/W
0
Deep Sleep Enable
Value Description
0
Use Sleep mode as the low power mode.
1
Use Deep-sleep mode as the low power mode.
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Bit/Field
Name
Type
Reset
1
SLEEPEXIT
R/W
0
Description
Sleep on ISR Exit
Value Description
0
When returning from Handler mode to Thread mode, do not
sleep when returning to Thread mode.
1
When returning from Handler mode to Thread mode, enter sleep
or deep sleep on return from an ISR.
Setting this bit enables an interrupt-driven application to avoid returning
to an empty main application.
0
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Register 23: Configuration and Control (CFGCTRL), offset 0xD14
Note:
This register can only be accessed from privileged mode.
The CFGCTRL register controls entry to Thread mode and enables: the handlers for NMI, hard fault
and faults escalated by the FAULTMASK register to ignore bus faults; trapping of divide by zero
and unaligned accesses; and access to the SWTRIG register by unprivileged software (see page 103).
Configuration and Control (CFGCTRL)
Base 0xE000.E000
Offset 0xD14
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
6
5
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
9
8
7
reserved
STKALIGN BFHFNMIGN
RO
0
RO
0
R/W
0
Bit/Field
Name
Type
Reset
31:10
reserved
RO
0x0000.00
9
STKALIGN
R/W
0
R/W
0
RO
0
RO
0
RO
0
4
3
2
1
0
DIV0
UNALIGNED
reserved
MAINPEND
BASETHR
R/W
0
R/W
0
RO
0
R/W
0
R/W
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Stack Alignment on Exception Entry
Value Description
0
The stack is 4-byte aligned.
1
The stack is 8-byte aligned.
On exception entry, the processor uses bit 9 of the stacked PSR to
indicate the stack alignment. On return from the exception, it uses this
stacked bit to restore the correct stack alignment.
8
BFHFNMIGN
R/W
0
Ignore Bus Fault in NMI and Fault
This bit enables handlers with priority -1 or -2 to ignore data bus faults
caused by load and store instructions. The setting of this bit applies to
the hard fault, NMI, and FAULTMASK escalated handlers.
Value Description
0
Data bus faults caused by load and store instructions cause a
lock-up.
1
Handlers running at priority -1 and -2 ignore data bus faults
caused by load and store instructions.
Set this bit only when the handler and its data are in absolutely safe
memory. The normal use of this bit is to probe system devices and
bridges to detect control path problems and fix them.
7:5
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Bit/Field
Name
Type
Reset
4
DIV0
R/W
0
Description
Trap on Divide by 0
This bit enables faulting or halting when the processor executes an
SDIV or UDIV instruction with a divisor of 0.
Value Description
3
UNALIGNED
R/W
0
0
Do not trap on divide by 0. A divide by zero returns a quotient
of 0.
1
Trap on divide by 0.
Trap on Unaligned Access
Value Description
0
Do not trap on unaligned halfword and word accesses.
1
Trap on unaligned halfword and word accesses. An unaligned
access generates a usage fault.
Unaligned LDM, STM, LDRD, and STRD instructions always fault
regardless of whether UNALIGNED is set.
2
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
1
MAINPEND
R/W
0
Allow Main Interrupt Trigger
Value Description
0
BASETHR
R/W
0
0
Disables unprivileged software access to the SWTRIG register.
1
Enables unprivileged software access to the SWTRIG register
(see page 103).
Thread State Control
Value Description
0
The processor can enter Thread mode only when no exception
is active.
1
The processor can enter Thread mode from any level under the
control of an EXC_RETURN value (see “Exception
Return” on page 74 for more information).
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Register 24: System Handler Priority 1 (SYSPRI1), offset 0xD18
Note:
This register can only be accessed from privileged mode.
The SYSPRI1 register configures the priority level, 0 to 7 of the usage fault, bus fault, and memory
management fault exception handlers. This register is byte-accessible.
System Handler Priority 1 (SYSPRI1)
Base 0xE000.E000
Offset 0xD18
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
reserved
Type
Reset
RO
0
15
RO
0
RO
0
RO
0
RO
0
14
13
12
11
BUS
Type
Reset
R/W
0
R/W
0
RO
0
RO
0
RO
0
R/W
0
10
9
8
7
reserved
R/W
0
RO
0
22
21
20
19
USAGE
RO
0
RO
0
R/W
0
R/W
0
RO
0
RO
0
6
5
4
3
MEM
RO
0
RO
0
R/W
0
R/W
0
18
17
16
RO
0
RO
0
RO
0
2
1
0
RO
0
RO
0
reserved
reserved
R/W
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:24
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
23:21
USAGE
R/W
0x0
Usage Fault Priority
This field configures the priority level of the usage fault. Configurable
priority values are in the range 0-7, with lower values having higher
priority.
20:16
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
15:13
BUS
R/W
0x0
Bus Fault Priority
This field configures the priority level of the bus fault. Configurable priority
values are in the range 0-7, with lower values having higher priority.
12:8
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:5
MEM
R/W
0x0
Memory Management Fault Priority
This field configures the priority level of the memory management fault.
Configurable priority values are in the range 0-7, with lower values
having higher priority.
4:0
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Register 25: System Handler Priority 2 (SYSPRI2), offset 0xD1C
Note:
This register can only be accessed from privileged mode.
The SYSPRI2 register configures the priority level, 0 to 7 of the SVCall handler. This register is
byte-accessible.
System Handler Priority 2 (SYSPRI2)
Base 0xE000.E000
Offset 0xD1C
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
SVC
Type
Reset
22
21
20
19
18
17
16
reserved
R/W
0
R/W
0
R/W
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
31:29
SVC
R/W
0x0
RO
0
Description
SVCall Priority
This field configures the priority level of SVCall. Configurable priority
values are in the range 0-7, with lower values having higher priority.
28:0
reserved
RO
0x000.0000
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Register 26: System Handler Priority 3 (SYSPRI3), offset 0xD20
Note:
This register can only be accessed from privileged mode.
The SYSPRI3 register configures the priority level, 0 to 7 of the SysTick exception and PendSV
handlers. This register is byte-accessible.
System Handler Priority 3 (SYSPRI3)
Base 0xE000.E000
Offset 0xD20
Type R/W, reset 0x0000.0000
31
30
29
28
27
TICK
Type
Reset
26
25
24
23
reserved
R/W
0
R/W
0
R/W
0
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
15
14
13
12
11
10
9
8
7
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
22
21
20
19
PENDSV
R/W
0
R/W
0
RO
0
RO
0
6
5
4
3
DEBUG
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
31:29
TICK
R/W
0x0
RO
0
R/W
0
R/W
0
18
17
16
RO
0
RO
0
RO
0
2
1
0
RO
0
RO
0
reserved
reserved
R/W
0
RO
0
RO
0
RO
0
Description
SysTick Exception Priority
This field configures the priority level of the SysTick exception.
Configurable priority values are in the range 0-7, with lower values
having higher priority.
28:24
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
23:21
PENDSV
R/W
0x0
PendSV Priority
This field configures the priority level of PendSV. Configurable priority
values are in the range 0-7, with lower values having higher priority.
20:8
reserved
RO
0x000
7:5
DEBUG
R/W
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Debug Priority
This field configures the priority level of Debug. Configurable priority
values are in the range 0-7, with lower values having higher priority.
4:0
reserved
RO
0x0.0000
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Register 27: System Handler Control and State (SYSHNDCTRL), offset 0xD24
Note:
This register can only be accessed from privileged mode.
The SYSHNDCTRL register enables the system handlers, and indicates the pending status of the
usage fault, bus fault, memory management fault, and SVC exceptions as well as the active status
of the system handlers.
If a system handler is disabled and the corresponding fault occurs, the processor treats the fault as
a hard fault.
This register can be modified to change the pending or active status of system exceptions. An OS
kernel can write to the active bits to perform a context switch that changes the current exception
type.
Caution – Software that changes the value of an active bit in this register without correct adjustment
to the stacked content can cause the processor to generate a fault exception. Ensure software that writes
to this register retains and subsequently restores the current active status.
If the value of a bit in this register must be modified after enabling the system handlers, a
read-modify-write procedure must be used to ensure that only the required bit is modified.
System Handler Control and State (SYSHNDCTRL)
Base 0xE000.E000
Offset 0xD24
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
SVC
BUSP
MEMP
USAGEP
R/W
0
R/W
0
R/W
0
R/W
0
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
USAGE
BUS
MEM
R/W
0
R/W
0
R/W
0
10
9
8
7
6
5
4
3
2
1
0
TICK
PNDSV
reserved
MON
SVCA
R/W
0
R/W
0
RO
0
R/W
0
R/W
0
USGA
reserved
BUSA
MEMA
R/W
0
RO
0
R/W
0
R/W
0
reserved
Type
Reset
Type
Reset
reserved
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:19
reserved
RO
0x000
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
18
USAGE
R/W
0
Usage Fault Enable
Value Description
17
BUS
R/W
0
0
Disables the usage fault exception.
1
Enables the usage fault exception.
Bus Fault Enable
Value Description
0
Disables the bus fault exception.
1
Enables the bus fault exception.
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Bit/Field
Name
Type
Reset
16
MEM
R/W
0
Description
Memory Management Fault Enable
Value Description
15
SVC
R/W
0
0
Disables the memory management fault exception.
1
Enables the memory management fault exception.
SVC Call Pending
Value Description
0
An SVC call exception is not pending.
1
An SVC call exception is pending.
This bit can be modified to change the pending status of the SVC call
exception.
14
BUSP
R/W
0
Bus Fault Pending
Value Description
0
A bus fault exception is not pending.
1
A bus fault exception is pending.
This bit can be modified to change the pending status of the bus fault
exception.
13
MEMP
R/W
0
Memory Management Fault Pending
Value Description
0
A memory management fault exception is not pending.
1
A memory management fault exception is pending.
This bit can be modified to change the pending status of the memory
management fault exception.
12
USAGEP
R/W
0
Usage Fault Pending
Value Description
0
A usage fault exception is not pending.
1
A usage fault exception is pending.
This bit can be modified to change the pending status of the usage fault
exception.
11
TICK
R/W
0
SysTick Exception Active
Value Description
0
A SysTick exception is not active.
1
A SysTick exception is active.
This bit can be modified to change the active status of the SysTick
exception, however, see the Caution above before setting this bit.
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Bit/Field
Name
Type
Reset
10
PNDSV
R/W
0
Description
PendSV Exception Active
Value Description
0
A PendSV exception is not active.
1
A PendSV exception is active.
This bit can be modified to change the active status of the PendSV
exception, however, see the Caution above before setting this bit.
9
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
8
MON
R/W
0
Debug Monitor Active
Value Description
7
SVCA
R/W
0
0
The Debug monitor is not active.
1
The Debug monitor is active.
SVC Call Active
Value Description
0
SVC call is not active.
1
SVC call is active.
This bit can be modified to change the active status of the SVC call
exception, however, see the Caution above before setting this bit.
6:4
reserved
RO
0x0
3
USGA
R/W
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Usage Fault Active
Value Description
0
Usage fault is not active.
1
Usage fault is active.
This bit can be modified to change the active status of the usage fault
exception, however, see the Caution above before setting this bit.
2
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
1
BUSA
R/W
0
Bus Fault Active
Value Description
0
Bus fault is not active.
1
Bus fault is active.
This bit can be modified to change the active status of the bus fault
exception, however, see the Caution above before setting this bit.
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Bit/Field
Name
Type
Reset
0
MEMA
R/W
0
Description
Memory Management Fault Active
Value Description
0
Memory management fault is not active.
1
Memory management fault is active.
This bit can be modified to change the active status of the memory
management fault exception, however, see the Caution above before
setting this bit.
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Register 28: Configurable Fault Status (FAULTSTAT), offset 0xD28
Note:
This register can only be accessed from privileged mode.
The FAULTSTAT register indicates the cause of a memory management fault, bus fault, or usage
fault. Each of these functions is assigned to a subregister as follows:
■ Usage Fault Status (UFAULTSTAT), bits 31:16
■ Bus Fault Status (BFAULTSTAT), bits 15:8
■ Memory Management Fault Status (MFAULTSTAT), bits 7:0
FAULTSTAT is byte accessible. FAULTSTAT or its subregisters can be accessed as follows:
■
■
■
■
■
The complete FAULTSTAT register, with a word access to offset 0xD28
The MFAULTSTAT, with a byte access to offset 0xD28
The MFAULTSTAT and BFAULTSTAT, with a halfword access to offset 0xD28
The BFAULTSTAT, with a byte access to offset 0xD29
The UFAULTSTAT, with a halfword access to offset 0xD2A
Bits are cleared by writing a 1 to them.
In a fault handler, the true faulting address can be determined by:
1. Read and save the Memory Management Fault Address (MMADDR) or Bus Fault Address
(FAULTADDR) value.
2. Read the MMARV bit in MFAULTSTAT, or the BFARV bit in BFAULTSTAT to determine if the
MMADDR or FAULTADDR contents are valid.
Software must follow this sequence because another higher priority exception might change the
MMADDR or FAULTADDR value. For example, if a higher priority handler preempts the current
fault handler, the other fault might change the MMADDR or FAULTADDR value.
Configurable Fault Status (FAULTSTAT)
Base 0xE000.E000
Offset 0xD28
Type R/W1C, reset 0x0000.0000
31
30
29
28
27
26
reserved
Type
Reset
RO
0
RO
0
RO
0
15
14
13
BFARV
Type
Reset
R/W1C
0
reserved
RO
0
RO
0
RO
0
RO
0
RO
0
25
24
DIV0
UNALIGN
R/W1C
0
R/W1C
0
23
22
21
20
reserved
RO
0
RO
0
RO
0
6
5
12
11
10
9
8
7
BSTKE
BUSTKE
IMPRE
PRECISE
IBUS
MMARV
R/W1C
0
R/W1C
0
R/W1C
0
R/W1C
0
R/W1C
0
R/W1C
0
reserved
RO
0
RO
0
RO
0
19
18
17
16
NOCP
INVPC
INVSTAT
UNDEF
R/W1C
0
R/W1C
0
R/W1C
0
R/W1C
0
4
3
2
1
0
MSTKE
MUSTKE
reserved
DERR
IERR
R/W1C
0
R/W1C
0
RO
0
R/W1C
0
R/W1C
0
Bit/Field
Name
Type
Reset
Description
31:26
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Bit/Field
Name
Type
Reset
25
DIV0
R/W1C
0
Description
Divide-by-Zero Usage Fault
Value Description
0
No divide-by-zero fault has occurred, or divide-by-zero trapping
is not enabled.
1
The processor has executed an SDIV or UDIV instruction with
a divisor of 0.
When this bit is set, the PC value stacked for the exception return points
to the instruction that performed the divide by zero.
Trapping on divide-by-zero is enabled by setting the DIV0 bit in the
Configuration and Control (CFGCTRL) register (see page 113).
This bit is cleared by writing a 1 to it.
24
UNALIGN
R/W1C
0
Unaligned Access Usage Fault
Value Description
0
No unaligned access fault has occurred, or unaligned access
trapping is not enabled.
1
The processor has made an unaligned memory access.
Unaligned LDM, STM, LDRD, and STRD instructions always fault
regardless of the configuration of this bit.
Trapping on unaligned access is enabled by setting the UNALIGNED bit
in the CFGCTRL register (see page 113).
This bit is cleared by writing a 1 to it.
23:20
reserved
RO
0x00
19
NOCP
R/W1C
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
No Coprocessor Usage Fault
Value Description
0
A usage fault has not been caused by attempting to access a
coprocessor.
1
The processor has attempted to access a coprocessor.
This bit is cleared by writing a 1 to it.
18
INVPC
R/W1C
0
Invalid PC Load Usage Fault
Value Description
0
A usage fault has not been caused by attempting to load an
invalid PC value.
1
The processor has attempted an illegal load of EXC_RETURN
to the PC as a result of an invalid context or an invalid
EXC_RETURN value.
When this bit is set, the PC value stacked for the exception return points
to the instruction that tried to perform the illegal load of the PC.
This bit is cleared by writing a 1 to it.
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Bit/Field
Name
Type
Reset
17
INVSTAT
R/W1C
0
Description
Invalid State Usage Fault
Value Description
0
A usage fault has not been caused by an invalid state.
1
The processor has attempted to execute an instruction that
makes illegal use of the EPSR register.
When this bit is set, the PC value stacked for the exception return points
to the instruction that attempted the illegal use of the Execution
Program Status Register (EPSR) register.
This bit is not set if an undefined instruction uses the EPSR register.
This bit is cleared by writing a 1 to it.
16
UNDEF
R/W1C
0
Undefined Instruction Usage Fault
Value Description
0
A usage fault has not been caused by an undefined instruction.
1
The processor has attempted to execute an undefined
instruction.
When this bit is set, the PC value stacked for the exception return points
to the undefined instruction.
An undefined instruction is an instruction that the processor cannot
decode.
This bit is cleared by writing a 1 to it.
15
BFARV
R/W1C
0
Bus Fault Address Register Valid
Value Description
0
The value in the Bus Fault Address (FAULTADDR) register
is not a valid fault address.
1
The FAULTADDR register is holding a valid fault address.
This bit is set after a bus fault, where the address is known. Other faults
can clear this bit, such as a memory management fault occurring later.
If a bus fault occurs and is escalated to a hard fault because of priority,
the hard fault handler must clear this bit. This action prevents problems
if returning to a stacked active bus fault handler whose FAULTADDR
register value has been overwritten.
This bit is cleared by writing a 1 to it.
14:13
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Bit/Field
Name
Type
Reset
12
BSTKE
R/W1C
0
Description
Stack Bus Fault
Value Description
0
No bus fault has occurred on stacking for exception entry.
1
Stacking for an exception entry has caused one or more bus
faults.
When this bit is set, the SP is still adjusted but the values in the context
area on the stack might be incorrect. A fault address is not written to
the FAULTADDR register.
This bit is cleared by writing a 1 to it.
11
BUSTKE
R/W1C
0
Unstack Bus Fault
Value Description
0
No bus fault has occurred on unstacking for a return from
exception.
1
Unstacking for a return from exception has caused one or more
bus faults.
This fault is chained to the handler. Thus, when this bit is set, the original
return stack is still present. The SP is not adjusted from the failing return,
a new save is not performed, and a fault address is not written to the
FAULTADDR register.
This bit is cleared by writing a 1 to it.
10
IMPRE
R/W1C
0
Imprecise Data Bus Error
Value Description
0
An imprecise data bus error has not occurred.
1
A data bus error has occurred, but the return address in the
stack frame is not related to the instruction that caused the error.
When this bit is set, a fault address is not written to the FAULTADDR
register.
This fault is asynchronous. Therefore, if the fault is detected when the
priority of the current process is higher than the bus fault priority, the
bus fault becomes pending and becomes active only when the processor
returns from all higher-priority processes. If a precise fault occurs before
the processor enters the handler for the imprecise bus fault, the handler
detects that both the IMPRE bit is set and one of the precise fault status
bits is set.
This bit is cleared by writing a 1 to it.
9
PRECISE
R/W1C
0
Precise Data Bus Error
Value Description
0
A precise data bus error has not occurred.
1
A data bus error has occurred, and the PC value stacked for
the exception return points to the instruction that caused the
fault.
When this bit is set, the fault address is written to the FAULTADDR
register.
This bit is cleared by writing a 1 to it.
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Bit/Field
Name
Type
Reset
8
IBUS
R/W1C
0
Description
Instruction Bus Error
Value Description
0
An instruction bus error has not occurred.
1
An instruction bus error has occurred.
The processor detects the instruction bus error on prefetching an
instruction, but sets this bit only if it attempts to issue the faulting
instruction.
When this bit is set, a fault address is not written to the FAULTADDR
register.
This bit is cleared by writing a 1 to it.
7
MMARV
R/W1C
0
Memory Management Fault Address Register Valid
Value Description
0
The value in the Memory Management Fault Address
(MMADDR) register is not a valid fault address.
1
The MMADDR register is holding a valid fault address.
If a memory management fault occurs and is escalated to a hard fault
because of priority, the hard fault handler must clear this bit. This action
prevents problems if returning to a stacked active memory management
fault handler whose MMADDR register value has been overwritten.
This bit is cleared by writing a 1 to it.
6:5
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
4
MSTKE
R/W1C
0
Stack Access Violation
Value Description
0
No memory management fault has occurred on stacking for
exception entry.
1
Stacking for an exception entry has caused one or more access
violations.
When this bit is set, the SP is still adjusted but the values in the context
area on the stack might be incorrect. A fault address is not written to
the MMADDR register.
This bit is cleared by writing a 1 to it.
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Bit/Field
Name
Type
Reset
3
MUSTKE
R/W1C
0
Description
Unstack Access Violation
Value Description
0
No memory management fault has occurred on unstacking for
a return from exception.
1
Unstacking for a return from exception has caused one or more
access violations.
This fault is chained to the handler. Thus, when this bit is set, the original
return stack is still present. The SP is not adjusted from the failing return,
a new save is not performed, and a fault address is not written to the
MMADDR register.
This bit is cleared by writing a 1 to it.
2
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
1
DERR
R/W1C
0
Data Access Violation
Value Description
0
A data access violation has not occurred.
1
The processor attempted a load or store at a location that does
not permit the operation.
When this bit is set, the PC value stacked for the exception return points
to the faulting instruction and the address of the attempted access is
written to the MMADDR register.
This bit is cleared by writing a 1 to it.
0
IERR
R/W1C
0
Instruction Access Violation
Value Description
0
An instruction access violation has not occurred.
1
The processor attempted an instruction fetch from a location
that does not permit execution.
This fault occurs on any access to an XN region, even when the MPU
is disabled or not present.
When this bit is set, the PC value stacked for the exception return points
to the faulting instruction and the address of the attempted access is
not written to the MMADDR register.
This bit is cleared by writing a 1 to it.
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Register 29: Hard Fault Status (HFAULTSTAT), offset 0xD2C
Note:
This register can only be accessed from privileged mode.
The HFAULTSTAT register gives information about events that activate the hard fault handler.
Bits are cleared by writing a 1 to them.
Hard Fault Status (HFAULTSTAT)
Base 0xE000.E000
Offset 0xD2C
Type R/W1C, reset 0x0000.0000
Type
Reset
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
DBG
FORCED
R/W1C
0
R/W1C
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
VECT
reserved
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
R/W1C
0
RO
0
reserved
Type
Reset
Bit/Field
Name
Type
Reset
31
DBG
R/W1C
0
Description
Debug Event
This bit is reserved for Debug use. This bit must be written as a 0,
otherwise behavior is unpredictable.
30
FORCED
R/W1C
0
Forced Hard Fault
Value Description
0
No forced hard fault has occurred.
1
A forced hard fault has been generated by escalation of a fault
with configurable priority that cannot be handled, either because
of priority or because it is disabled.
When this bit is set, the hard fault handler must read the other fault
status registers to find the cause of the fault.
This bit is cleared by writing a 1 to it.
29:2
reserved
RO
0x00
1
VECT
R/W1C
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Vector Table Read Fault
Value Description
0
No bus fault has occurred on a vector table read.
1
A bus fault occurred on a vector table read.
This error is always handled by the hard fault handler.
When this bit is set, the PC value stacked for the exception return points
to the instruction that was preempted by the exception.
This bit is cleared by writing a 1 to it.
0
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Register 30: Memory Management Fault Address (MMADDR), offset 0xD34
Note:
This register can only be accessed from privileged mode.
The MMADDR register contains the address of the location that generated a memory management
fault. When an unaligned access faults, the address in the MMADDR register is the actual address
that faulted. Because a single read or write instruction can be split into multiple aligned accesses,
the fault address can be any address in the range of the requested access size. Bits in the Memory
Management Fault Status (MFAULTSTAT) register indicate the cause of the fault and whether
the value in the MMADDR register is valid (see page 122).
Memory Management Fault Address (MMADDR)
Base 0xE000.E000
Offset 0xD34
Type R/W, reset 31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
7
6
5
4
3
2
1
0
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
ADDR
Type
Reset
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
15
14
13
12
11
10
9
8
ADDR
Type
Reset
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
Bit/Field
Name
Type
Reset
31:0
ADDR
R/W
-
R/W
-
Description
Fault Address
When the MMARV bit of MFAULTSTAT is set, this field holds the address
of the location that generated the memory management fault.
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Register 31: Bus Fault Address (FAULTADDR), offset 0xD38
Note:
This register can only be accessed from privileged mode.
The FAULTADDR register contains the address of the location that generated a bus fault. When
an unaligned access faults, the address in the FAULTADDR register is the one requested by the
instruction, even if it is not the address of the fault. Bits in the Bus Fault Status (BFAULTSTAT)
register indicate the cause of the fault and whether the value in the FAULTADDR register is valid
(see page 122).
Bus Fault Address (FAULTADDR)
Base 0xE000.E000
Offset 0xD38
Type R/W, reset 31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
7
6
5
4
3
2
1
0
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
ADDR
Type
Reset
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
15
14
13
12
11
10
9
8
ADDR
Type
Reset
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
Bit/Field
Name
Type
Reset
31:0
ADDR
R/W
-
R/W
-
Description
Fault Address
When the FAULTADDRV bit of BFAULTSTAT is set, this field holds the
address of the location that generated the bus fault.
3.6
Memory Protection Unit (MPU) Register Descriptions
This section lists and describes the Memory Protection Unit (MPU) registers, in numerical order by
address offset.
The MPU registers can only be accessed from privileged mode.
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Register 32: MPU Type (MPUTYPE), offset 0xD90
Note:
This register can only be accessed from privileged mode.
The MPUTYPE register indicates whether the MPU is present, and if so, how many regions it
supports.
MPU Type (MPUTYPE)
Base 0xE000.E000
Offset 0xD90
Type RO, reset 0x0000.0800
31
30
29
28
27
26
25
24
23
22
21
20
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
DREGION
Type
Reset
RO
0
RO
0
RO
0
RO
0
19
18
17
16
RO
0
IREGION
RO
0
RO
0
RO
0
RO
0
4
3
2
1
reserved
RO
1
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
0
SEPARATE
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:24
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
23:16
IREGION
RO
0x00
Number of I Regions
This field indicates the number of supported MPU instruction regions.
This field always contains 0x00. The MPU memory map is unified and
is described by the DREGION field.
15:8
DREGION
RO
0x08
Number of D Regions
Value Description
0x08 Indicates there are eight supported MPU data regions.
7:1
reserved
RO
0x00
0
SEPARATE
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Separate or Unified MPU
Value Description
0
Indicates the MPU is unified.
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Register 33: MPU Control (MPUCTRL), offset 0xD94
Note:
This register can only be accessed from privileged mode.
The MPUCTRL register enables the MPU, enables the default memory map background region,
and enables use of the MPU when in the hard fault, Non-maskable Interrupt (NMI), and Fault Mask
Register (FAULTMASK) escalated handlers.
When the ENABLE and PRIVDEFEN bits are both set:
■ For privileged accesses, the default memory map is as described in “Memory Model” on page 59.
Any access by privileged software that does not address an enabled memory region behaves
as defined by the default memory map.
■ Any access by unprivileged software that does not address an enabled memory region causes
a memory management fault.
Execute Never (XN) and Strongly Ordered rules always apply to the System Control Space regardless
of the value of the ENABLE bit.
When the ENABLE bit is set, at least one region of the memory map must be enabled for the system
to function unless the PRIVDEFEN bit is set. If the PRIVDEFEN bit is set and no regions are enabled,
then only privileged software can operate.
When the ENABLE bit is clear, the system uses the default memory map, which has the same
memory attributes as if the MPU is not implemented (see Table 2-5 on page 61 for more information).
The default memory map applies to accesses from both privileged and unprivileged software.
When the MPU is enabled, accesses to the System Control Space and vector table are always
permitted. Other areas are accessible based on regions and whether PRIVDEFEN is set.
Unless HFNMIENA is set, the MPU is not enabled when the processor is executing the handler for
an exception with priority –1 or –2. These priorities are only possible when handling a hard fault or
NMI exception or when FAULTMASK is enabled. Setting the HFNMIENA bit enables the MPU when
operating with these two priorities.
MPU Control (MPUCTRL)
Base 0xE000.E000
Offset 0xD94
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
Bit/Field
Name
Type
Reset
31:3
reserved
RO
0x0000.000
PRIVDEFEN HFNMIENA
R/W
0
R/W
0
ENABLE
R/W
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Bit/Field
Name
Type
Reset
2
PRIVDEFEN
R/W
0
Description
MPU Default Region
This bit enables privileged software access to the default memory map.
Value Description
0
If the MPU is enabled, this bit disables use of the default memory
map. Any memory access to a location not covered by any
enabled region causes a fault.
1
If the MPU is enabled, this bit enables use of the default memory
map as a background region for privileged software accesses.
When this bit is set, the background region acts as if it is region number
-1. Any region that is defined and enabled has priority over this default
map.
If the MPU is disabled, the processor ignores this bit.
1
HFNMIENA
R/W
0
MPU Enabled During Faults
This bit controls the operation of the MPU during hard fault, NMI, and
FAULTMASK handlers.
Value Description
0
The MPU is disabled during hard fault, NMI, and FAULTMASK
handlers, regardless of the value of the ENABLE bit.
1
The MPU is enabled during hard fault, NMI, and FAULTMASK
handlers.
When the MPU is disabled and this bit is set, the resulting behavior is
unpredictable.
0
ENABLE
R/W
0
MPU Enable
Value Description
0
The MPU is disabled.
1
The MPU is enabled.
When the MPU is disabled and the HFNMIENA bit is set, the resulting
behavior is unpredictable.
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Register 34: MPU Region Number (MPUNUMBER), offset 0xD98
Note:
This register can only be accessed from privileged mode.
The MPUNUMBER register selects which memory region is referenced by the MPU Region Base
Address (MPUBASE) and MPU Region Attribute and Size (MPUATTR) registers. Normally, the
required region number should be written to this register before accessing the MPUBASE or the
MPUATTR register. However, the region number can be changed by writing to the MPUBASE
register with the VALID bit set (see page 135). This write updates the value of the REGION field.
MPU Region Number (MPUNUMBER)
Base 0xE000.E000
Offset 0xD98
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
1
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
9
8
7
6
5
4
3
2
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
31:3
reserved
RO
0x0000.000
2:0
NUMBER
R/W
0x0
NUMBER
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
MPU Region to Access
This field indicates the MPU region referenced by the MPUBASE and
MPUATTR registers. The MPU supports eight memory regions.
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Register 35: MPU Region Base Address (MPUBASE), offset 0xD9C
Register 36: MPU Region Base Address Alias 1 (MPUBASE1), offset 0xDA4
Register 37: MPU Region Base Address Alias 2 (MPUBASE2), offset 0xDAC
Register 38: MPU Region Base Address Alias 3 (MPUBASE3), offset 0xDB4
Note:
This register can only be accessed from privileged mode.
The MPUBASE register defines the base address of the MPU region selected by the MPU Region
Number (MPUNUMBER) register and can update the value of the MPUNUMBER register. To
change the current region number and update the MPUNUMBER register, write the MPUBASE
register with the VALID bit set.
The ADDR field is bits 31:N of the MPUBASE register. Bits (N-1):5 are reserved. The region size,
as specified by the SIZE field in the MPU Region Attribute and Size (MPUATTR) register, defines
the value of N where:
N = Log2(Region size in bytes)
If the region size is configured to 4 GB in the MPUATTR register, there is no valid ADDR field. In
this case, the region occupies the complete memory map, and the base address is 0x0000.0000.
The base address is aligned to the size of the region. For example, a 64-KB region must be aligned
on a multiple of 64 KB, for example, at 0x0001.0000 or 0x0002.0000.
MPU Region Base Address (MPUBASE)
Base 0xE000.E000
Offset 0xD9C
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
VALID
reserved
WO
0
RO
0
ADDR
Type
Reset
ADDR
Type
Reset
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
31:5
ADDR
R/W
0x0000.000
R/W
0
R/W
0
R/W
0
R/W
0
REGION
R/W
0
R/W
0
R/W
0
Description
Base Address Mask
Bits 31:N in this field contain the region base address. The value of N
depends on the region size, as shown above. The remaining bits (N-1):5
are reserved.
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Bit/Field
Name
Type
Reset
4
VALID
WO
0
Description
Region Number Valid
Value Description
0
The MPUNUMBER register is not changed and the processor
updates the base address for the region specified in the
MPUNUMBER register and ignores the value of the REGION
field.
1
The MPUNUMBER register is updated with the value of the
REGION field and the base address is updated for the region
specified in the REGION field.
This bit is always read as 0.
3
reserved
RO
0
2:0
REGION
R/W
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Region Number
On a write, contains the value to be written to the MPUNUMBER register.
On a read, returns the current region number in the MPUNUMBER
register.
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Register 39: MPU Region Attribute and Size (MPUATTR), offset 0xDA0
Register 40: MPU Region Attribute and Size Alias 1 (MPUATTR1), offset 0xDA8
Register 41: MPU Region Attribute and Size Alias 2 (MPUATTR2), offset 0xDB0
Register 42: MPU Region Attribute and Size Alias 3 (MPUATTR3), offset 0xDB8
Note:
This register can only be accessed from privileged mode.
The MPUATTR register defines the region size and memory attributes of the MPU region specified
by the MPU Region Number (MPUNUMBER) register and enables that region and any subregions.
The MPUATTR register is accessible using word or halfword accesses with the most-significant
halfword holding the region attributes and the least-significant halfword holds the region size and
the region and subregion enable bits.
The MPU access permission attribute bits, XN, AP, TEX, S, C, and B, control access to the
corresponding memory region. If an access is made to an area of memory without the required
permissions, then the MPU generates a permission fault.
The SIZE field defines the size of the MPU memory region specified by the MPUNUMBER register
as follows:
(Region size in bytes) = 2(SIZE+1)
The smallest permitted region size is 32 bytes, corresponding to a SIZE value of 4. Table
3-9 on page 137 gives example SIZE values with the corresponding region size and value of N in
the MPU Region Base Address (MPUBASE) register.
Table 3-9. Example SIZE Field Values
a
SIZE Encoding
Region Size
Value of N
Note
00100b (0x4)
32 B
5
Minimum permitted size
01001b (0x9)
1 KB
10
-
10011b (0x13)
1 MB
20
-
11101b (0x1D)
1 GB
30
-
11111b (0x1F)
4 GB
No valid ADDR field in MPUBASE; the Maximum possible size
region occupies the complete
memory map.
a. Refers to the N parameter in the MPUBASE register (see page 135).
MPU Region Attribute and Size (MPUATTR)
Base 0xE000.E000
Offset 0xDA0
Type R/W, reset 0x0000.0000
31
30
29
28
27
reserved
Type
Reset
26
25
24
23
AP
21
reserved
20
19
18
TEX
17
16
XN
reserved
S
C
B
RO
0
RO
0
RO
0
R/W
0
RO
0
R/W
0
R/W
0
R/W
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
SRD
Type
Reset
22
reserved
SIZE
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R/W
0
ENABLE
R/W
0
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Bit/Field
Name
Type
Reset
Description
31:29
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
28
XN
R/W
0
Instruction Access Disable
Value Description
0
Instruction fetches are enabled.
1
Instruction fetches are disabled.
27
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
26:24
AP
R/W
0
Access Privilege
For information on using this bit field, see Table 3-5 on page 89.
23:22
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
21:19
TEX
R/W
0x0
Type Extension Mask
For information on using this bit field, see Table 3-3 on page 88.
18
S
R/W
0
Shareable
For information on using this bit, see Table 3-3 on page 88.
17
C
R/W
0
Cacheable
For information on using this bit, see Table 3-3 on page 88.
16
B
R/W
0
Bufferable
For information on using this bit, see Table 3-3 on page 88.
15:8
SRD
R/W
0x00
Subregion Disable Bits
Value Description
0
The corresponding subregion is enabled.
1
The corresponding subregion is disabled.
Region sizes of 128 bytes and less do not support subregions. When
writing the attributes for such a region, configure the SRD field as 0x00.
See the section called “Subregions” on page 87 for more information.
7:6
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
5:1
SIZE
R/W
0x0
Region Size Mask
The SIZE field defines the size of the MPU memory region specified by
the MPUNUMBER register. Refer to Table 3-9 on page 137 for more
information.
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Bit/Field
Name
Type
Reset
0
ENABLE
R/W
0
Description
Region Enable
Value Description
0
The region is disabled.
1
The region is enabled.
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JTAG Interface
4
JTAG Interface
The Joint Test Action Group (JTAG) port is an IEEE standard that defines a Test Access Port and
Boundary Scan Architecture for digital integrated circuits and provides a standardized serial interface
for controlling the associated test logic. The TAP, Instruction Register (IR), and Data Registers (DR)
can be used to test the interconnections of assembled printed circuit boards and obtain manufacturing
information on the components. The JTAG Port also provides a means of accessing and controlling
design-for-test features such as I/O pin observation and control, scan testing, and debugging.
The JTAG port is comprised of five pins: TRST, TCK, TMS, TDI, and TDO. Data is transmitted serially
into the controller on TDI and out of the controller on TDO. The interpretation of this data is dependent
on the current state of the TAP controller. For detailed information on the operation of the JTAG
port and TAP controller, please refer to the IEEE Standard 1149.1-Test Access Port and
Boundary-Scan Architecture.
®
The Stellaris JTAG controller works with the ARM JTAG controller built into the Cortex-M3 core.
This is implemented by multiplexing the TDO outputs from both JTAG controllers. ARM JTAG
instructions select the ARM TDO output while Stellaris JTAG instructions select the Stellaris TDO
outputs. The multiplexer is controlled by the Stellaris JTAG controller, which has comprehensive
programming for the ARM, Stellaris, and unimplemented JTAG instructions.
The Stellaris JTAG module has the following features:
■ IEEE 1149.1-1990 compatible Test Access Port (TAP) controller
■ Four-bit Instruction Register (IR) chain for storing JTAG instructions
■ IEEE standard instructions: BYPASS, IDCODE, SAMPLE/PRELOAD, EXTEST and INTEST
■ ARM additional instructions: APACC, DPACC and ABORT
■ Integrated ARM Serial Wire Debug (SWD)
See the ARM® Debug Interface V5 Architecture Specification for more information on the ARM
JTAG controller.
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4.1
Block Diagram
Figure 4-1. JTAG Module Block Diagram
TRST
TCK
TMS
TAP Controller
TDI
Instruction Register (IR)
BYPASS Data Register
TDO
Boundary Scan Data Register
IDCODE Data Register
ABORT Data Register
DPACC Data Register
APACC Data Register
Cortex-M3
Debug
Port
4.2
Signal Description
Table 4-1 on page 141 lists the external signals of the JTAG/SWD controller and describes the
function of each. The JTAG/SWD controller signals are alternate functions for some GPIO signals,
however note that the reset state of the pins is for the JTAG/SWD function. The column in the table
below titled "Pin Assignment" lists the GPIO pin placement for the JTAG/SWD controller signals.
The AFSEL bit in the GPIO Alternate Function Select (GPIOAFSEL) register (page 242) is set to
choose the JTAG/SWD function. For more information on configuring GPIOs, see “General-Purpose
Input/Outputs (GPIOs)” on page 223.
Table 4-1. JTAG_SWD_SWO Signals (48QFP)
a
Pin Name
Pin Number
Pin Type
Buffer Type
SWCLK
40
I
TTL
Description
JTAG/SWD CLK.
SWDIO
39
I/O
TTL
JTAG TMS and SWDIO.
SWO
37
O
TTL
JTAG TDO and SWO.
TCK
40
I
TTL
JTAG/SWD CLK.
TDI
38
I
TTL
JTAG TDI.
TDO
37
O
TTL
JTAG TDO and SWO.
TMS
39
I/O
TTL
JTAG TMS and SWDIO.
TRST
41
I
TTL
JTAG TRST.
a. The TTL designation indicates the pin has TTL-compatible voltage levels.
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4.3
Functional Description
A high-level conceptual drawing of the JTAG module is shown in Figure 4-1 on page 141. The JTAG
module is composed of the Test Access Port (TAP) controller and serial shift chains with parallel
update registers. The TAP controller is a simple state machine controlled by the TRST, TCK and
TMS inputs. The current state of the TAP controller depends on the current value of TRST and the
sequence of values captured on TMS at the rising edge of TCK. The TAP controller determines when
the serial shift chains capture new data, shift data from TDI towards TDO, and update the parallel
load registers. The current state of the TAP controller also determines whether the Instruction
Register (IR) chain or one of the Data Register (DR) chains is being accessed.
The serial shift chains with parallel load registers are comprised of a single Instruction Register (IR)
chain and multiple Data Register (DR) chains. The current instruction loaded in the parallel load
register determines which DR chain is captured, shifted, or updated during the sequencing of the
TAP controller.
Some instructions, like EXTEST and INTEST, operate on data currently in a DR chain and do not
capture, shift, or update any of the chains. Instructions that are not implemented decode to the
BYPASS instruction to ensure that the serial path between TDI and TDO is always connected (see
Table 4-3 on page 146 for a list of implemented instructions).
See “JTAG and Boundary Scan” on page 487 for JTAG timing diagrams.
4.3.1
JTAG Interface Pins
The JTAG interface consists of five standard pins: TRST,TCK, TMS, TDI, and TDO. These pins and
their associated reset state are given in Table 4-2 on page 142. Detailed information on each pin
follows.
Table 4-2. JTAG Port Pins Reset State
4.3.1.1
Pin Name
Data Direction
Internal Pull-Up
Internal Pull-Down
Drive Strength
Drive Value
TRST
Input
Enabled
Disabled
N/A
N/A
TCK
Input
Enabled
Disabled
N/A
N/A
TMS
Input
Enabled
Disabled
N/A
N/A
TDI
Input
Enabled
Disabled
N/A
N/A
TDO
Output
Enabled
Disabled
2-mA driver
High-Z
Test Reset Input (TRST)
The TRST pin is an asynchronous active Low input signal for initializing and resetting the JTAG TAP
controller and associated JTAG circuitry. When TRST is asserted, the TAP controller resets to the
Test-Logic-Reset state and remains there while TRST is asserted. When the TAP controller enters
the Test-Logic-Reset state, the JTAG Instruction Register (IR) resets to the default instruction,
IDCODE.
By default, the internal pull-up resistor on the TRST pin is enabled after reset. Changes to the pull-up
resistor settings on GPIO Port B should ensure that the internal pull-up resistor remains enabled
on PB7/TRST; otherwise JTAG communication could be lost.
4.3.1.2
Test Clock Input (TCK)
The TCK pin is the clock for the JTAG module. This clock is provided so the test logic can operate
independently of any other system clocks. In addition, it ensures that multiple JTAG TAP controllers
that are daisy-chained together can synchronously communicate serial test data between
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components. During normal operation, TCK is driven by a free-running clock with a nominal 50%
duty cycle. When necessary, TCK can be stopped at 0 or 1 for extended periods of time. While TCK
is stopped at 0 or 1, the state of the TAP controller does not change and data in the JTAG Instruction
and Data Registers is not lost.
By default, the internal pull-up resistor on the TCK pin is enabled after reset. This assures that no
clocking occurs if the pin is not driven from an external source. The internal pull-up and pull-down
resistors can be turned off to save internal power as long as the TCK pin is constantly being driven
by an external source.
4.3.1.3
Test Mode Select (TMS)
The TMS pin selects the next state of the JTAG TAP controller. TMS is sampled on the rising edge
of TCK. Depending on the current TAP state and the sampled value of TMS, the next state is entered.
Because the TMS pin is sampled on the rising edge of TCK, the IEEE Standard 1149.1 expects the
value on TMS to change on the falling edge of TCK.
Holding TMS high for five consecutive TCK cycles drives the TAP controller state machine to the
Test-Logic-Reset state. When the TAP controller enters the Test-Logic-Reset state, the JTAG
Instruction Register (IR) resets to the default instruction, IDCODE. Therefore, this sequence can
be used as a reset mechanism, similar to asserting TRST. The JTAG Test Access Port state machine
can be seen in its entirety in Figure 4-2 on page 144.
By default, the internal pull-up resistor on the TMS pin is enabled after reset. Changes to the pull-up
resistor settings on GPIO Port C should ensure that the internal pull-up resistor remains enabled
on PC1/TMS; otherwise JTAG communication could be lost.
4.3.1.4
Test Data Input (TDI)
The TDI pin provides a stream of serial information to the IR chain and the DR chains. TDI is
sampled on the rising edge of TCK and, depending on the current TAP state and the current
instruction, presents this data to the proper shift register chain. Because the TDI pin is sampled on
the rising edge of TCK, the IEEE Standard 1149.1 expects the value on TDI to change on the falling
edge of TCK.
By default, the internal pull-up resistor on the TDI pin is enabled after reset. Changes to the pull-up
resistor settings on GPIO Port C should ensure that the internal pull-up resistor remains enabled
on PC2/TDI; otherwise JTAG communication could be lost.
4.3.1.5
Test Data Output (TDO)
The TDO pin provides an output stream of serial information from the IR chain or the DR chains.
The value of TDO depends on the current TAP state, the current instruction, and the data in the
chain being accessed. In order to save power when the JTAG port is not being used, the TDO pin
is placed in an inactive drive state when not actively shifting out data. Because TDO can be connected
to the TDI of another controller in a daisy-chain configuration, the IEEE Standard 1149.1 expects
the value on TDO to change on the falling edge of TCK.
By default, the internal pull-up resistor on the TDO pin is enabled after reset. This assures that the
pin remains at a constant logic level when the JTAG port is not being used. The internal pull-up and
pull-down resistors can be turned off to save internal power if a High-Z output value is acceptable
during certain TAP controller states.
4.3.2
JTAG TAP Controller
The JTAG TAP controller state machine is shown in Figure 4-2 on page 144. The TAP controller
state machine is reset to the Test-Logic-Reset state on the assertion of a Power-On-Reset (POR)
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or the assertion of TRST. Asserting the correct sequence on the TMS pin allows the JTAG module
to shift in new instructions, shift in data, or idle during extended testing sequences. For detailed
information on the function of the TAP controller and the operations that occur in each state, please
refer to IEEE Standard 1149.1.
Figure 4-2. Test Access Port State Machine
Test Logic Reset
1
0
Run Test Idle
0
Select DR Scan
1
Select IR Scan
1
0
1
Capture DR
1
Capture IR
0
0
Shift DR
Shift IR
0
1
Exit 1 DR
Exit 1 IR
1
Pause IR
0
1
Exit 2 DR
0
1
0
Exit 2 IR
1
1
Update DR
4.3.3
1
0
Pause DR
1
0
1
0
0
1
0
0
Update IR
1
0
Shift Registers
The Shift Registers consist of a serial shift register chain and a parallel load register. The serial shift
register chain samples specific information during the TAP controller’s CAPTURE states and allows
this information to be shifted out of TDO during the TAP controller’s SHIFT states. While the sampled
data is being shifted out of the chain on TDO, new data is being shifted into the serial shift register
on TDI. This new data is stored in the parallel load register during the TAP controller’s UPDATE
states. Each of the shift registers is discussed in detail in “Register Descriptions” on page 146.
4.3.4
Operational Considerations
There are certain operational considerations when using the JTAG module. Because the JTAG pins
can be programmed to be GPIOs, board configuration and reset conditions on these pins must be
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considered. In addition, because the JTAG module has integrated ARM Serial Wire Debug, the
method for switching between these two operational modes is described below.
4.3.4.1
GPIO Functionality
When the microcontroller is reset with either a POR or RST, the JTAG port pins default to their JTAG
configurations. The default configuration includes enabling the pull-up resistors (setting GPIOPUR
to 1 for PB7 and PC[3:0]) and enabling the alternate hardware function (setting GPIOAFSEL to
1 for PB7 and PC[3:0]) on the JTAG pins.
It is possible for software to configure these pins as GPIOs after reset by writing 0s to PB7 and
PC[3:0] in the GPIOAFSEL register. If the user does not require the JTAG port for debugging or
board-level testing, this provides five more GPIOs for use in the design.
Caution – If the JTAG pins are used as GPIOs in a design, PB7 and PC2 cannot have external pull-down
resistors connected to both of them at the same time. If both pins are pulled Low during reset, the
controller has unpredictable behavior. If this happens, remove one or both of the pull-down resistors,
and apply RST or power-cycle the part.
It is possible to create a software sequence that prevents the debugger from connecting to the Stellaris
microcontroller. If the program code loaded into flash immediately changes the JTAG pins to their
GPIO functionality, the debugger may not have enough time to connect and halt the controller before
the JTAG pin functionality switches. This may lock the debugger out of the part. This can be avoided
with a software routine that restores JTAG functionality based on an external or software trigger.
4.3.4.2
Communication with JTAG/SWD
Because the debug clock and the system clock can be running at different frequencies, care must
be taken to maintain reliable communication with the JTAG/SWD interface. In the Capture-DR state,
the result of the previous transaction, if any, is returned, together with a 3-bit ACK response. Software
should check the ACK response to see if the previous operation has completed before initiating a
new transaction. Alternatively, if the system clock is at least 8 times faster than the debug clock
(TCK or SWCLK), the previous operation has enough time to complete and the ACK bits do not have
to be checked.
4.3.4.3
ARM Serial Wire Debug (SWD)
In order to seamlessly integrate the ARM Serial Wire Debug (SWD) functionality, a serial-wire
debugger must be able to connect to the Cortex-M3 core without having to perform, or have any
knowledge of, JTAG cycles. This is accomplished with a SWD preamble that is issued before the
SWD session begins.
The switching preamble used to enable the SWD interface of the SWJ-DP module starts with the
TAP controller in the Test-Logic-Reset state. From here, the preamble sequences the TAP controller
through the following states: Run Test Idle, Select DR, Select IR, Capture IR, Exit1 IR, Update IR,
Run Test Idle, Select DR, Select IR, Capture IR, Exit1 IR, Update IR, Run Test Idle, Select DR,
Select IR, and Test-Logic-Reset states.
Stepping through the JTAG TAP Instruction Register (IR) load sequences of the TAP state machine
twice without shifting in a new instruction enables the SWD interface and disables the JTAG interface.
For more information on this operation and the SWD interface, see the ARM® Debug Interface V5
Architecture Specification.
Because this sequence is a valid series of JTAG operations that could be issued, the ARM JTAG
TAP controller is not fully compliant to the IEEE Standard 1149.1. This is the only instance where
the ARM JTAG TAP controller does not meet full compliance with the specification. Due to the low
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probability of this sequence occurring during normal operation of the TAP controller, it should not
affect normal performance of the JTAG interface.
4.4
Initialization and Configuration
After a Power-On-Reset or an external reset (RST), the JTAG pins are automatically configured for
JTAG communication. No user-defined initialization or configuration is needed. However, if the user
application changes these pins to their GPIO function, they must be configured back to their JTAG
functionality before JTAG communication can be restored. This is done by enabling the five JTAG
pins (PB7 and PC[3:0]) for their alternate function using the GPIOAFSEL register. In addition to
enabling the alternate functions, any other changes to the GPIO pad configurations on the five JTAG
pins (PB7 andPC[3:0]) should be reverted to their default settings.
4.5
Register Descriptions
There are no APB-accessible registers in the JTAG TAP Controller or Shift Register chains. The
registers within the JTAG controller are all accessed serially through the TAP Controller. The registers
can be broken down into two main categories: Instruction Registers and Data Registers.
4.5.1
Instruction Register (IR)
The JTAG TAP Instruction Register (IR) is a four-bit serial scan chain connected between the JTAG
TDI and TDO pins with a parallel load register. When the TAP Controller is placed in the correct
states, bits can be shifted into the Instruction Register. Once these bits have been shifted into the
chain and updated, they are interpreted as the current instruction. The decode of the Instruction
Register bits is shown in Table 4-3 on page 146. A detailed explanation of each instruction, along
with its associated Data Register, follows.
Table 4-3. JTAG Instruction Register Commands
4.5.1.1
IR[3:0]
Instruction
Description
0000
EXTEST
Drives the values preloaded into the Boundary Scan Chain by the
SAMPLE/PRELOAD instruction onto the pads.
0001
INTEST
Drives the values preloaded into the Boundary Scan Chain by the
SAMPLE/PRELOAD instruction into the controller.
0010
SAMPLE / PRELOAD
1000
ABORT
Shifts data into the ARM Debug Port Abort Register.
1010
DPACC
Shifts data into and out of the ARM DP Access Register.
1011
APACC
Shifts data into and out of the ARM AC Access Register.
1110
IDCODE
Loads manufacturing information defined by the IEEE Standard 1149.1
into the IDCODE chain and shifts it out.
Captures the current I/O values and shifts the sampled values out of the
Boundary Scan Chain while new preload data is shifted in.
1111
BYPASS
Connects TDI to TDO through a single Shift Register chain.
All Others
Reserved
Defaults to the BYPASS instruction to ensure that TDI is always connected
to TDO.
EXTEST Instruction
The EXTEST instruction is not associated with its own Data Register chain. The EXTEST instruction
uses the data that has been preloaded into the Boundary Scan Data Register using the
SAMPLE/PRELOAD instruction. When the EXTEST instruction is present in the Instruction Register,
the preloaded data in the Boundary Scan Data Register associated with the outputs and output
enables are used to drive the GPIO pads rather than the signals coming from the core. This allows
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tests to be developed that drive known values out of the controller, which can be used to verify
connectivity. While the EXTEST instruction is present in the Instruction Register, the Boundary Scan
Data Register can be accessed to sample and shift out the current data and load new data into the
Boundary Scan Data Register.
4.5.1.2
INTEST Instruction
The INTEST instruction is not associated with its own Data Register chain. The INTEST instruction
uses the data that has been preloaded into the Boundary Scan Data Register using the
SAMPLE/PRELOAD instruction. When the INTEST instruction is present in the Instruction Register,
the preloaded data in the Boundary Scan Data Register associated with the inputs are used to drive
the signals going into the core rather than the signals coming from the GPIO pads. This allows tests
to be developed that drive known values into the controller, which can be used for testing. It is
important to note that although the RST input pin is on the Boundary Scan Data Register chain, it
is only observable. While the INTEXT instruction is present in the Instruction Register, the Boundary
Scan Data Register can be accessed to sample and shift out the current data and load new data
into the Boundary Scan Data Register.
4.5.1.3
SAMPLE/PRELOAD Instruction
The SAMPLE/PRELOAD instruction connects the Boundary Scan Data Register chain between
TDI and TDO. This instruction samples the current state of the pad pins for observation and preloads
new test data. Each GPIO pad has an associated input, output, and output enable signal. When the
TAP controller enters the Capture DR state during this instruction, the input, output, and output-enable
signals to each of the GPIO pads are captured. These samples are serially shifted out of TDO while
the TAP controller is in the Shift DR state and can be used for observation or comparison in various
tests.
While these samples of the inputs, outputs, and output enables are being shifted out of the Boundary
Scan Data Register, new data is being shifted into the Boundary Scan Data Register from TDI.
Once the new data has been shifted into the Boundary Scan Data Register, the data is saved in the
parallel load registers when the TAP controller enters the Update DR state. This update of the
parallel load register preloads data into the Boundary Scan Data Register that is associated with
each input, output, and output enable. This preloaded data can be used with the EXTEST and
INTEST instructions to drive data into or out of the controller. Please see “Boundary Scan Data
Register” on page 149 for more information.
4.5.1.4
ABORT Instruction
The ABORT instruction connects the associated ABORT Data Register chain between TDI and
TDO. This instruction provides read and write access to the ABORT Register of the ARM Debug
Access Port (DAP). Shifting the proper data into this Data Register clears various error bits or initiates
a DAP abort of a previous request. Please see the “ABORT Data Register” on page 149 for more
information.
4.5.1.5
DPACC Instruction
The DPACC instruction connects the associated DPACC Data Register chain between TDI and
TDO. This instruction provides read and write access to the DPACC Register of the ARM Debug
Access Port (DAP). Shifting the proper data into this register and reading the data output from this
register allows read and write access to the ARM debug and status registers. Please see “DPACC
Data Register” on page 149 for more information.
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4.5.1.6
APACC Instruction
The APACC instruction connects the associated APACC Data Register chain between TDI and
TDO. This instruction provides read and write access to the APACC Register of the ARM Debug
Access Port (DAP). Shifting the proper data into this register and reading the data output from this
register allows read and write access to internal components and buses through the Debug Port.
Please see “APACC Data Register” on page 149 for more information.
4.5.1.7
IDCODE Instruction
The IDCODE instruction connects the associated IDCODE Data Register chain between TDI and
TDO. This instruction provides information on the manufacturer, part number, and version of the
ARM core. This information can be used by testing equipment and debuggers to automatically
configure their input and output data streams. IDCODE is the default instruction that is loaded into
the JTAG Instruction Register when a Power-On-Reset (POR) is asserted, TRST is asserted, or the
Test-Logic-Reset state is entered. Please see “IDCODE Data Register” on page 148 for more
information.
4.5.1.8
BYPASS Instruction
The BYPASS instruction connects the associated BYPASS Data Register chain between TDI and
TDO. This instruction is used to create a minimum length serial path between the TDI and TDO ports.
The BYPASS Data Register is a single-bit shift register. This instruction improves test efficiency by
allowing components that are not needed for a specific test to be bypassed in the JTAG scan chain
by loading them with the BYPASS instruction. Please see “BYPASS Data Register” on page 149 for
more information.
4.5.2
Data Registers
The JTAG module contains six Data Registers. These include: IDCODE, BYPASS, Boundary Scan,
APACC, DPACC, and ABORT serial Data Register chains. Each of these Data Registers is discussed
in the following sections.
4.5.2.1
IDCODE Data Register
The format for the 32-bit IDCODE Data Register defined by the IEEE Standard 1149.1 is shown in
Figure 4-3 on page 148. The standard requires that every JTAG-compliant device implement either
the IDCODE instruction or the BYPASS instruction as the default instruction. The LSB of the IDCODE
Data Register is defined to be a 1 to distinguish it from the BYPASS instruction, which has an LSB
of 0. This allows auto configuration test tools to determine which instruction is the default instruction.
The major uses of the JTAG port are for manufacturer testing of component assembly, and program
development and debug. To facilitate the use of auto-configuration debug tools, the IDCODE
instruction outputs a value of 0x1BA0.0477. This allows the debuggers to automatically configure
themselves to work correctly with the Cortex-M3 during debug.
Figure 4-3. IDCODE Register Format
31
TDI
28 27
Version
12 11
Part Number
148
1 0
Manufacturer ID
1
TDO
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4.5.2.2
BYPASS Data Register
The format for the 1-bit BYPASS Data Register defined by the IEEE Standard 1149.1 is shown in
Figure 4-4 on page 149. The standard requires that every JTAG-compliant device implement either
the BYPASS instruction or the IDCODE instruction as the default instruction. The LSB of the BYPASS
Data Register is defined to be a 0 to distinguish it from the IDCODE instruction, which has an LSB
of 1. This allows auto configuration test tools to determine which instruction is the default instruction.
Figure 4-4. BYPASS Register Format
0
0
TDI
4.5.2.3
TDO
Boundary Scan Data Register
The format of the Boundary Scan Data Register is shown in Figure 4-5 on page 149. Each GPIO
pin, starting with a GPIO pin next to the JTAG port pins, is included in the Boundary Scan Data
Register. Each GPIO pin has three associated digital signals that are included in the chain. These
signals are input, output, and output enable, and are arranged in that order as can be seen in the
figure.
When the Boundary Scan Data Register is accessed with the SAMPLE/PRELOAD instruction, the
input, output, and output enable from each digital pad are sampled and then shifted out of the chain
to be verified. The sampling of these values occurs on the rising edge of TCK in the Capture DR
state of the TAP controller. While the sampled data is being shifted out of the Boundary Scan chain
in the Shift DR state of the TAP controller, new data can be preloaded into the chain for use with
the EXTEST and INTEST instructions. These instructions either force data out of the controller, with
the EXTEST instruction, or into the controller, with the INTEST instruction.
Figure 4-5. Boundary Scan Register Format
TDI
I
N
O
U
T
O
E
...
GPIO PB6
4.5.2.4
I
N
O
U
T
GPIO m
O
E
I
N
RST
I
N
O
U
T
GPIO m+1
O
E
...
I
N
O
U
T
O TDO
E
GPIO n
APACC Data Register
The format for the 35-bit APACC Data Register defined by ARM is described in the ARM® Debug
Interface V5 Architecture Specification.
4.5.2.5
DPACC Data Register
The format for the 35-bit DPACC Data Register defined by ARM is described in the ARM® Debug
Interface V5 Architecture Specification.
4.5.2.6
ABORT Data Register
The format for the 35-bit ABORT Data Register defined by ARM is described in the ARM® Debug
Interface V5 Architecture Specification.
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5
System Control
System control determines the overall operation of the device. It provides information about the
device, controls the clocking to the core and individual peripherals, and handles reset detection and
reporting.
5.1
Signal Description
Table 5-1 on page 150 lists the external signals of the System Control module and describes the
function of each. The NMI signal is the alternate function for and functions as a GPIO after reset.
under commit protection and require a special process to be configured as any alternate function
or to subsequently return to the GPIO function. The column in the table below titled "Pin Assignment"
lists the GPIO pin placement for the NMI signal. The AFSEL bit in the GPIO Alternate Function
Select (GPIOAFSEL) register (page 242) should be set to choose the NMI function. For more
information on configuring GPIOs, see “General-Purpose Input/Outputs (GPIOs)” on page 223. The
remaining signals (with the word "fixed" in the Pin Assignment column) have a fixed pin assignment
and function.
Table 5-1. System Control & Clocks Signals (48QFP)
a
Pin Name
Pin Number
Pin Type
Buffer Type
Description
OSC0
9
I
Analog
Main oscillator crystal input or an external clock reference
input.
OSC1
10
O
Analog
Main oscillator crystal output. Leave unconnected when using
a single-ended clock source.
RST
5
I
TTL
System reset input.
a. The TTL designation indicates the pin has TTL-compatible voltage levels.
5.2
Functional Description
The System Control module provides the following capabilities:
■ Device identification (see “Device Identification” on page 150)
■ Local control, such as reset (see “Reset Control” on page 150), power (see “Power
Control” on page 155) and clock control (see “Clock Control” on page 155)
■ System control (Run, Sleep, and Deep-Sleep modes); see “System Control” on page 158
5.2.1
Device Identification
Several read-only registers provide software with information on the microcontroller, such as version,
part number, SRAM size, flash size, and other features. See the DID0, DID1, and DC0-DC4 registers.
5.2.2
Reset Control
This section discusses aspects of hardware functions during reset as well as system software
requirements following the reset sequence.
5.2.2.1
Reset Sources
The controller has six sources of reset:
1. External reset input pin (RST) assertion; see “External RST Pin” on page 152.
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2. Power-on reset (POR); see “Power-On Reset (POR)” on page 151.
3. Internal brown-out (BOR) detector; see “Brown-Out Reset (BOR)” on page 153.
4. Software-initiated reset (with the software reset registers); see “Software Reset” on page 154.
5. A watchdog timer reset condition violation; see “Watchdog Timer Reset” on page 154.
6. Internal low drop-out (LDO) regulator output.
Table 5-2 provides a summary of results of the various reset operations.
Table 5-2. Reset Sources
Core Reset?
JTAG Reset?
On-Chip Peripherals Reset?
Power-On Reset
Reset Source
Yes
Yes
Yes
RST
Yes
Pin Config Only
Yes
Brown-Out Reset
Yes
No
Yes
Software System Request
a
Reset
Yes
No
Yes
Software Peripheral Reset
No
No
Yes
Watchdog Reset
Yes
No
Yes
LDO Reset
Yes
No
Yes
b
a. By using the SYSRESREQ bit in the ARM Cortex-M3 Application Interrupt and Reset Control (APINT) register
b. Programmable on a module-by-module basis using the Software Reset Control Registers.
After a reset, the Reset Cause (RESC) register is set with the reset cause. The bits in this register
are sticky and maintain their state across multiple reset sequences,except when an external reset
is the cause, and then all the other bits in the RESC register are cleared.
Note:
5.2.2.2
The main oscillator is used for external resets and power-on resets; the internal oscillator
is used during the internal process by internal reset and clock verification circuitry.
Power-On Reset (POR)
Note:
The power-on reset also resets the JTAG controller. An external reset does not.
The internal Power-On Reset (POR) circuit monitors the power supply voltage (VDD) and generates
a reset signal to all of the internal logic including JTAG when the power supply ramp reaches a
threshold value (VTH). The microcontroller must be operating within the specified operating parameters
when the on-chip power-on reset pulse is complete. The 3.3-V power supply to the microcontroller
must reach 3.0 V within 10 msec of VDD crossing 2.0 V to guarantee proper operation. For applications
that require the use of an external reset signal to hold the microcontroller in reset longer than the
internal POR, the RST input may be used as discussed in “External RST Pin” on page 152.
The Power-On Reset sequence is as follows:
1. The microcontroller waits for internal POR to go inactive.
2. The internal reset is released and the core loads from memory the initial stack pointer, the initial
program counter, and the first instruction designated by the program counter, and then begins
execution.
The internal POR is only active on the initial power-up of the microcontroller. The Power-On Reset
timing is shown in Figure 17-6 on page 490.
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5.2.2.3
External RST Pin
Note:
It is recommended that the trace for the RST signal must be kept as short as possible. Be
sure to place any components connected to the RST signal as close to the microcontroller
as possible.
If the application only uses the internal POR circuit, the RST input must be connected to the power
supply (VDD) through an optional pull-up resistor (0 to 100K Ω) as shown in Figure 5-1 on page 152.
Figure 5-1. Basic RST Configuration
VDD
Stellaris®
RPU
RST
RPU = 0 to 100 kΩ
The external reset pin (RST) resets the microcontroller including the core and all the on-chip
peripherals except the JTAG TAP controller (see “JTAG Interface” on page 140). The external reset
sequence is as follows:
1. The external reset pin (RST) is asserted for the duration specified by TMIN and then de-asserted
(see “Reset” on page 489).
2. The internal reset is released and the core loads from memory the initial stack pointer, the initial
program counter, and the first instruction designated by the program counter, and then begins
execution.
To improve noise immunity and/or to delay reset at power up, the RST input may be connected to
an RC network as shown in Figure 5-2 on page 152.
Figure 5-2. External Circuitry to Extend Power-On Reset
VDD
Stellaris®
RPU
RST
C1
RPU = 1 kΩ to 100 kΩ
C1 = 1 nF to 10 µF
If the application requires the use of an external reset switch, Figure 5-3 on page 153 shows the
proper circuitry to use.
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Figure 5-3. Reset Circuit Controlled by Switch
VDD
Stellaris®
RPU
RST
C1
RS
Typical RPU = 10 kΩ
Typical RS = 470 Ω
C1 = 10 nF
The RPU and C1 components define the power-on delay.
The external reset timing is shown in Figure 17-5 on page 490.
5.2.2.4
Brown-Out Reset (BOR)
A drop in the input voltage resulting in the assertion of the internal brown-out detector can be used
to reset the controller. This is initially disabled and may be enabled by software.
The system provides a brown-out detection circuit that triggers if the power supply (VDD) drops
below a brown-out threshold voltage (VBTH). The circuit is provided to guard against improper
operation of logic and peripherals that operate off the power supply voltage (VDD) and not the LDO
voltage. If a brown-out condition is detected, the system may generate a controller interrupt or a
system reset. The BOR circuit has a digital filter that protects against noise-related detection for the
interrupt condition. This feature may be optionally enabled.
Brown-out resets are controlled with the Power-On and Brown-Out Reset Control (PBORCTL)
register. The BORIOR bit in the PBORCTL register must be set for a brown-out condition to trigger
a reset.
The brown-out reset sequence is as follows:
1. When VDD drops below VBTH, an internal BOR condition is set.
2. If the BORWT bit in the PBORCTL register is set and BORIOR is not set, the BOR condition is
resampled, after a delay specified by BORTIM, to determine if the original condition was caused
by noise. If the BOR condition is not met the second time, then no further action is taken.
3. If the BOR condition exists, an internal reset is asserted.
4. The internal reset is released and the controller fetches and loads the initial stack pointer, the
initial program counter, the first instruction designated by the program counter, and begins
execution.
5. The internal BOR condition is reset after 500 µs to prevent another BOR condition from being
set before software has a chance to investigate the original cause.
The internal Brown-Out Reset timing is shown in Figure 17-7 on page 490.
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5.2.2.5
Software Reset
Software can reset a specific peripheral or generate a reset to the entire system .
Peripherals can be individually reset by software via three registers that control reset signals to each
peripheral (see the SRCRn registers). If the bit position corresponding to a peripheral is set and
subsequently cleared, the peripheral is reset. The encoding of the reset registers is consistent with
the encoding of the clock gating control for peripherals and on-chip functions (see “System
Control” on page 158). Note that all reset signals for all clocks of the specified unit are asserted as
a result of a software-initiated reset.
The entire system can be reset by software by setting the SYSRESETREQ bit in the Cortex-M3
Application Interrupt and Reset Control register resets the entire system including the core. The
software-initiated system reset sequence is as follows:
1. A software system reset is initiated by writing the SYSRESETREQ bit in the ARM Cortex-M3
Application Interrupt and Reset Control register.
2. An internal reset is asserted.
3. The internal reset is deasserted and the controller loads from memory the initial stack pointer,
the initial program counter, and the first instruction designated by the program counter, and
then begins execution.
The software-initiated system reset timing is shown in Figure 17-8 on page 491.
5.2.2.6
Watchdog Timer Reset
The watchdog timer module's function is to prevent system hangs. The watchdog timer can be
configured to generate an interrupt to the controller on its first time-out, and to generate a reset
signal on its second time-out.
After the first time-out event, the 32-bit counter is reloaded with the value of the Watchdog Timer
Load (WDTLOAD) register, and the timer resumes counting down from that value. If the timer counts
down to its zero state again before the first time-out interrupt is cleared, and the reset signal has
been enabled, the watchdog timer asserts its reset signal to the system. The watchdog timer reset
sequence is as follows:
1. The watchdog timer times out for the second time without being serviced.
2. An internal reset is asserted.
3. The internal reset is released and the controller loads from memory the initial stack pointer, the
initial program counter, the first instruction designated by the program counter, and begins
execution.
The watchdog reset timing is shown in Figure 17-9 on page 491.
5.2.2.7
Low Drop-Out (LDO)
A reset can be initiated when the internal low drop-out (LDO) regulator output goes unregulated.
This is initially disabled and may be enabled by software. LDO is controlled with the LDO Power
Control (LDOPCTL) register. The LDO reset sequence is as follows:
1. LDO goes unregulated and the LDOARST bit in the LDOARST register is set.
2. An internal reset is asserted.
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3. The internal reset is released and the controller fetches and loads the initial stack pointer, the
initial program counter, the first instruction designated by the program counter, and begins
execution.
The LDO reset timing is shown in Figure 17-10 on page 491.
5.2.3
Power Control
®
The Stellaris microcontroller provides an integrated LDO regulator that is used to provide power
to the majority of the controller's internal logic. For power reduction, the LDO regulator provides
software a mechanism to adjust the regulated value, in small increments (VSTEP), over the range
of 2.25 V to 2.75 V (inclusive)—or 2.5 V ± 10%. The adjustment is made by changing the value of
the VADJ field in the LDO Power Control (LDOPCTL) register.
5.2.4
Clock Control
System control determines the control of clocks in this part.
5.2.4.1
Fundamental Clock Sources
There are multiple clock sources for use in the device:
■ Internal Oscillator (IOSC). The internal oscillator is an on-chip clock source. It does not require
the use of any external components. The frequency of the internal oscillator is 12 MHz ± 30%.
■ Main Oscillator (MOSC). The main oscillator provides a frequency-accurate clock source by
one of two means: an external single-ended clock source is connected to the OSC0 input pin, or
an external crystal is connected across the OSC0 input and OSC1 output pins. The crystal value
allowed depends on whether the main oscillator is used as the clock reference source to the
PLL. If so, the crystal must be one of the supported frequencies between 3.579545 MHz through
8.192 MHz (inclusive). If the PLL is not being used, the crystal may be any one of the supported
frequencies between 1 MHz and 8.192 MHz. The single-ended clock source range is from DC
through the specified speed of the device. The supported crystals are listed in the XTAL bit field
in the RCC register (see page 170).
The internal system clock (SysClk), is derived from any of the above sources plus two others: the
output of the main internal PLL, and the internal oscillator divided by four (3 MHz ± 30%). The
frequency of the PLL clock reference must be in the range of 3.579545 MHz to 8.192 MHz (inclusive).
Table 5-3 on page 155 shows how the various clock sources can be used in a system.
Table 5-3. Clock Source Options
5.2.4.2
Clock Source
Drive PLL?
Internal Oscillator (12 MHz)
Yes
BYPASS = 0, OSCSRC = 0x1
Yes
BYPASS = 1, OSCSRC = 0x1
Internal Oscillator divide by 4 (3 Yes
MHz)
BYPASS = 0, OSCSRC = 0x2
Yes
BYPASS = 1, OSCSRC = 0x2
Main Oscillator
BYPASS = 0, OSCSRC = 0x0
Yes
BYPASS = 1, OSCSRC = 0x0
Yes
Used as SysClk?
Clock Configuration
Nearly all of the control for the clocks is provided by the Run-Mode Clock Configuration (RCC)
register. This register controls the following clock functionality:
■ Source of clocks in sleep and deep-sleep modes
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■ System clock derived from PLL or other clock source
■ Enabling/disabling of oscillators and PLL
■ Clock divisors
■ Crystal input selection
Figure 5-4 on page 156 shows the logic for the main clock tree. The peripheral blocks are driven by
the system clock signal and can be individually enabled/disabled. The ADC clock signal is
automatically divided down to 16.67 MHz for proper ADC operation.
Note:
When the ADC module is in operation, the system clock must be at least 16.667 MHz.
Figure 5-4. Main Clock Tree
USESYSDIVa
OSC1
OSC2
Main
Osc
1-8 MHz
System Clock
SYSDIVa
Internal
Osc
12 MHz
PLL
(200 MHz
output)
÷4
OSCSRCa
OENa
Constant
Divide
BYPASSa
a
(16.667 MHz output)
XTAL
ADC Clock
a
PWRDN
a. These are bit fields within the Run-Mode Clock Configuration (RCC) register.
In the RCC register, the SYSDIV field specifies which divisor is used to generate the system clock
from either the PLL output or the oscillator source (depending on how the BYPASS bit in this register
is configured). Table 5-4 shows how the SYSDIV encoding affects the system clock frequency,
depending on whether the PLL is used (BYPASS=0) or another clock source is used (BYPASS=1).
The divisor is equivalent to the SYSDIV encoding plus 1. For a list of possible clock sources, see
Table 5-3 on page 155.
Table 5-4. Possible System Clock Frequencies Using the SYSDIV Field
SYSDIV
Divisor
a
Frequency
(BYPASS=0)
Frequency (BYPASS=1)
StellarisWare Parameter
b
0x0
/1
reserved
Clock source frequency/2
SYSCTL_SYSDIV_1
0x1
/2
reserved
Clock source frequency/2
SYSCTL_SYSDIV_2
0x2
/3
reserved
Clock source frequency/3
SYSCTL_SYSDIV_3
0x3
/4
50 MHz
Clock source frequency/4
SYSCTL_SYSDIV_4
0x4
/5
40 MHz
Clock source frequency/5
SYSCTL_SYSDIV_5
0x5
/6
33.33 MHz
Clock source frequency/6
SYSCTL_SYSDIV_6
0x6
/7
28.57 MHz
Clock source frequency/7
SYSCTL_SYSDIV_7
0x7
/8
25 MHz
Clock source frequency/8
SYSCTL_SYSDIV_8
0x8
/9
22.22 MHz
Clock source frequency/9
SYSCTL_SYSDIV_9
0x9
/10
20 MHz
Clock source frequency/10
SYSCTL_SYSDIV_10
0xA
/11
18.18 MHz
Clock source frequency/11
SYSCTL_SYSDIV_11
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Table 5-4. Possible System Clock Frequencies Using the SYSDIV Field (continued)
a
Divisor
Frequency
(BYPASS=0)
Frequency (BYPASS=1)
StellarisWare Parameter
0xB
/12
16.67 MHz
Clock source frequency/12
SYSCTL_SYSDIV_12
0xC
/13
15.38 MHz
Clock source frequency/13
SYSCTL_SYSDIV_13
0xD
/14
14.29 MHz
Clock source frequency/14
SYSCTL_SYSDIV_14
0xE
/15
13.33 MHz
Clock source frequency/15
SYSCTL_SYSDIV_15
0xF
/16
12.5 MHz (default)
Clock source frequency/16
SYSCTL_SYSDIV_16
SYSDIV
a. This parameter is used in functions such as SysCtlClockSet() in the Stellaris Peripheral Driver Library.
b. SYSCTL_SYSDIV_1 does not set the USESYSDIV bit. As a result, using this parameter without enabling the PLL results
in the system clock having the same frequency as the clock source.
5.2.4.3
Crystal Configuration for the Main Oscillator (MOSC)
The main oscillator supports the use of a select number of crystals. If the main oscillator is used by
the PLL as a reference clock, the supported range of crystals is 3.579545 to 8.192 MHz, otherwise,
the range of supported crystals is 1 to 8.192 MHz.
The XTAL bit in the RCC register (see page 170) describes the available crystal choices and default
programming values.
Software configures the RCC register XTAL field with the crystal number. If the PLL is used in the
design, the XTAL field value is internally translated to the PLL settings.
5.2.4.4
Main PLL Frequency Configuration
The main PLL is disabled by default during power-on reset and is enabled later by software if
required. Software configures the main PLL input reference clock source, specifies the output divisor
to set the system clock frequency, and enables the main PLL to drive the output.
If the main oscillator provides the clock reference to the main PLL, the translation provided by
hardware and used to program the PLL is available for software in the XTAL to PLL Translation
(PLLCFG) register (see page 173). The internal translation provides a translation within ± 1% of the
targeted PLL VCO frequency.
The Crystal Value field (XTAL) in the Run-Mode Clock Configuration (RCC) register (see page 170)
describes the available crystal choices and default programming of the PLLCFG register. Any time
the XTAL field changes, the new settings are translated and the internal PLL settings are updated.
5.2.4.5
PLL Modes
The PLL has two modes of operation: Normal and Power-Down
■ Normal: The PLL multiplies the input clock reference and drives the output.
■ Power-Down: Most of the PLL internal circuitry is disabled and the PLL does not drive the output.
The modes are programmed using the RCC register fields (see page 170).
5.2.4.6
PLL Operation
If a PLL configuration is changed, the PLL output frequency is unstable until it reconverges (relocks)
to the new setting. The time between the configuration change and relock is TREADY (see Table
17-7 on page 487). During the relock time, the affected PLL is not usable as a clock reference.
PLL is changed by one of the following:
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■ Change to the XTAL value in the RCC register—writes of the same value do not cause a relock.
■ Change in the PLL from Power-Down to Normal mode.
A counter is defined to measure the TREADY requirement. The counter is clocked by the main
oscillator. The range of the main oscillator has been taken into account and the down counter is set
to 0x1200 (that is, ~600 μs at an 8.192 MHz external oscillator clock). Hardware is provided to keep
the PLL from being used as a system clock until the TREADY condition is met after one of the two
changes above. It is the user's responsibility to have a stable clock source (like the main oscillator)
before the RCC register is switched to use the PLL.
If the main PLL is enabled and the system clock is switched to use the PLL in one step, the system
control hardware continues to clock the controller from the oscillator selected by the RCC register
until the main PLL is stable (TREADY time met), after which it changes to the PLL. Software can use
many methods to ensure that the system is clocked from the main PLL, including periodically polling
the PLLLRIS bit in the Raw Interrupt Status (RIS) register, and enabling the PLL Lock interrupt.
5.2.4.7
Clock Verification Timers
There are three identical clock verification circuits that can be enabled though software. The circuit
checks the faster clock by a slower clock using timers:
■ The main oscillator checks the PLL.
■ The main oscillator checks the internal oscillator.
■ The internal oscillator divided by 64 checks the main oscillator.
If the verification timer function is enabled and a failure is detected, the main clock tree is immediately
switched to a working clock and an interrupt is generated to the controller. Software can then
determine the course of action to take. The actual failure indication and clock switching does not
clear without a write to the CLKVCLR register, an external reset, or a POR reset. The clock
verification timers are controlled by the PLLVER , IOSCVER , and MOSCVER bits in the RCC register.
5.2.5
System Control
For power-savings purposes, the RCGCn , SCGCn , and DCGCn registers control the clock gating
logic for each peripheral or block in the system while the controller is in Run, Sleep, and Deep-Sleep
mode, respectively. The DC1 , DC2 and DC4 registers act as a write mask for the RCGCn , SCGCn,
and DCGCn registers.
There are three levels of operation for the device defined as:
■ Run Mode. In Run mode, the controller actively executes code. Run mode provides normal
operation of the processor and all of the peripherals that are currently enabled by the RCGCn
registers. The system clock can be any of the available clock sources including the PLL.
■ Sleep Mode. In Sleep mode, the clock frequency of the active peripherals is unchanged, but the
processor and the memory subsystem are not clocked and therefore no longer execute code.
Sleep mode is entered by the Cortex-M3 core executing a WFI(Wait for Interrupt)
instruction. Any properly configured interrupt event in the system will bring the processor back
into Run mode. See “Power Management” on page 77 for more details.
Peripherals are clocked that are enabled in the SCGCn register when auto-clock gating is enabled
(see the RCC register) or the RCGCn register when the auto-clock gating is disabled. The system
clock has the same source and frequency as that during Run mode.
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■ Deep-Sleep Mode. In Deep-Sleep mode, the clock frequency of the active peripherals may
change (depending on the Run mode clock configuration) in addition to the processor clock being
stopped. An interrupt returns the device to Run mode from one of the sleep modes. Deep-Sleep
mode is entered by first writing the Deep Sleep Enable bit in the ARM Cortex-M3 NVIC system
control register and then executing a WFI instruction. Any properly configured interrupt event in
the system will bring the processor back into Run mode. See “Power Management” on page 77
for more details.
The Cortex-M3 processor core and the memory subsystem are not clocked. Peripherals are
clocked that are enabled in the DCGCn register when auto-clock gating is enabled (see the RCC
register) or the RCGCn register when auto-clock gating is disabled. The system clock source is
the main oscillator by default or the internal oscillator specified in the DSLPCLKCFG register if
one is enabled. When the DSLPCLKCFG register is used, the internal oscillator is powered up,
if necessary, and the main oscillator is powered down. If the PLL is running at the time of the
WFI instruction, hardware will power the PLL down. When the Deep-Sleep exit event occurs,
hardware brings the system clock back to the source and frequency it had at the onset of
Deep-Sleep mode before enabling the clocks that had been stopped during the Deep-Sleep
duration.
Caution – If the Cortex-M3 Debug Access Port (DAP) has been enabled, and the device wakes from a
low power sleep or deep-sleep mode, the core may start executing code before all clocks to peripherals
have been restored to their run mode configuration. The DAP is usually enabled by software tools
accessing the JTAG or SWD interface when debugging or flash programming. If this condition occurs,
a Hard Fault is triggered when software accesses a peripheral with an invalid clock.
A software delay loop can be used at the beginning of the interrupt routine that is used to wake up a
system from a WFI (Wait For Interrupt) instruction. This stalls the execution of any code that accesses
a peripheral register that might cause a fault. This loop can be removed for production software as the
DAP is most likely not enabled during normal execution.
Because the DAP is disabled by default (power on reset), the user can also power-cycle the device. The
DAP is not enabled unless it is enabled through the JTAG or SWD interface.
5.3
Initialization and Configuration
The PLL is configured using direct register writes to the RCC register. The steps required to
successfully change the PLL-based system clock are:
1. Bypass the PLL and system clock divider by setting the BYPASS bit and clearing the USESYS
bit in the RCC register. This configures the system to run off a “raw” clock source and allows
for the new PLL configuration to be validated before switching the system clock to the PLL.
2. Select the crystal value (XTAL) and oscillator source (OSCSRC), and clear the PWRDN and OEN
bits in RCC. Setting the XTAL field automatically pulls valid PLL configuration data for the
appropriate crystal, and clearing the PWRDN and OEN bits powers and enables the PLL and its
output.
3. Select the desired system divider (SYSDIV) in RCC and set the USESYS bit in RCC. The SYSDIV
field determines the system frequency for the microcontroller.
4. Wait for the PLL to lock by polling the PLLLRIS bit in the Raw Interrupt Status (RIS) register.
5. Enable use of the PLL by clearing the BYPASS bit in RCC.
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Note:
5.4
If the BYPASS bit is cleared before the PLL locks, it is possible to render the device unusable.
Register Map
Table 5-5 on page 160 lists the System Control registers, grouped by function. The offset listed is a
hexadecimal increment to the register's address, relative to the System Control base address of
0x400F.E000.
Note:
Spaces in the System Control register space that are not used are reserved for future or
internal use. Software should not modify any reserved memory address.
Table 5-5. System Control Register Map
See
page
Offset
Name
Type
Reset
Description
0x000
DID0
RO
-
Device Identification 0
162
0x004
DID1
RO
-
Device Identification 1
177
0x008
DC0
RO
0x001F.001F
Device Capabilities 0
179
0x010
DC1
RO
0x0001.33BF
Device Capabilities 1
180
0x014
DC2
RO
0x0007.1013
Device Capabilities 2
182
0x018
DC3
RO
0xBFFF.0000
Device Capabilities 3
184
0x01C
DC4
RO
0x0000.001F
Device Capabilities 4
186
0x030
PBORCTL
R/W
0x0000.7FFD
Power-On and Brown-Out Reset Control
164
0x034
LDOPCTL
R/W
0x0000.0000
LDO Power Control
165
0x040
SRCR0
R/W
0x00000000
Software Reset Control 0
203
0x044
SRCR1
R/W
0x00000000
Software Reset Control 1
204
0x048
SRCR2
R/W
0x00000000
Software Reset Control 2
205
0x050
RIS
RO
0x0000.0000
Raw Interrupt Status
166
0x054
IMC
R/W
0x0000.0000
Interrupt Mask Control
167
0x058
MISC
R/W1C
0x0000.0000
Masked Interrupt Status and Clear
168
0x05C
RESC
R/W
-
Reset Cause
169
0x060
RCC
R/W
0x0780.3AC0
Run-Mode Clock Configuration
170
0x064
PLLCFG
RO
-
XTAL to PLL Translation
173
0x100
RCGC0
R/W
0x00000040
Run Mode Clock Gating Control Register 0
187
0x104
RCGC1
R/W
0x00000000
Run Mode Clock Gating Control Register 1
192
0x108
RCGC2
R/W
0x00000000
Run Mode Clock Gating Control Register 2
198
0x110
SCGC0
R/W
0x00000040
Sleep Mode Clock Gating Control Register 0
189
0x114
SCGC1
R/W
0x00000000
Sleep Mode Clock Gating Control Register 1
194
0x118
SCGC2
R/W
0x00000000
Sleep Mode Clock Gating Control Register 2
199
0x120
DCGC0
R/W
0x00000040
Deep Sleep Mode Clock Gating Control Register 0
191
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Table 5-5. System Control Register Map (continued)
Name
Type
Reset
0x124
DCGC1
R/W
0x00000000
Deep Sleep Mode Clock Gating Control Register 1
196
0x128
DCGC2
R/W
0x00000000
Deep Sleep Mode Clock Gating Control Register 2
201
0x144
DSLPCLKCFG
R/W
0x0780.0000
Deep Sleep Clock Configuration
174
0x150
CLKVCLR
R/W
0x0000.0000
Clock Verification Clear
175
0x160
LDOARST
R/W
0x0000.0000
Allow Unregulated LDO to Reset the Part
176
5.5
Description
See
page
Offset
Register Descriptions
All addresses given are relative to the System Control base address of 0x400F.E000.
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Register 1: Device Identification 0 (DID0), offset 0x000
This register identifies the version of the microcontroller. Each microcontroller is uniquely identified
by the combined values of the CLASS field in the DID0 register and the PARTNO field in the DID1
register.
Device Identification 0 (DID0)
Base 0x400F.E000
Offset 0x000
Type RO, reset 31
30
28
27
26
25
24
23
22
VER
reserved
Type
Reset
29
21
20
19
18
17
16
reserved
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
MAJOR
Type
Reset
MINOR
Bit/Field
Name
Type
Reset
31
reserved
RO
0
30:28
VER
RO
0x0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
DID0 Version
This field defines the DID0 register format version. The version number
is numeric. The value of the VER field is encoded as follows:
Value Description
0x0
27:16
reserved
RO
0x0
15:8
MAJOR
RO
-
Initial DID0 register format definition for Stellaris®
Sandstorm-class devices.
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Major Revision
This field specifies the major revision number of the device. The major
revision reflects changes to base layers of the design. The major revision
number is indicated in the part number as a letter (A for first revision, B
for second, and so on). This field is encoded as follows:
Value Description
0x0
Revision A (initial device)
0x1
Revision B (first base layer revision)
0x2
Revision C (second base layer revision)
and so on.
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Bit/Field
Name
Type
Reset
7:0
MINOR
RO
-
Description
Minor Revision
This field specifies the minor revision number of the device. The minor
revision reflects changes to the metal layers of the design. The MINOR
field value is reset when the MAJOR field is changed. This field is numeric
and is encoded as follows:
Value Description
0x0
Initial device, or a major revision update.
0x1
First metal layer change.
0x2
Second metal layer change.
and so on.
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Register 2: Power-On and Brown-Out Reset Control (PBORCTL), offset 0x030
This register is responsible for controlling reset conditions after initial power-on reset.
Power-On and Brown-Out Reset Control (PBORCTL)
Base 0x400F.E000
Offset 0x030
Type R/W, reset 0x0000.7FFD
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
R/W
0
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
BORIOR
BORWT
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
0
R/W
1
reserved
Type
Reset
BORTIM
Type
Reset
Bit/Field
Name
Type
Reset
31:16
reserved
RO
0x0
15:2
BORTIM
R/W
0x1FFF
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
BOR Time Delay
This field specifies the number of internal oscillator clocks delayed before
the BOR output is resampled if the BORWT bit is set.
The width of this field is derived by the t BOR width of 500 μs and the
internal oscillator (IOSC) frequency of 12 MHz ± 30%. At +30%, the
counter value has to exceed 7,800.
1
BORIOR
R/W
0
BOR Interrupt or Reset
This bit controls how a BOR event is signaled to the controller. If set, a
reset is signaled. Otherwise, an interrupt is signaled.
0
BORWT
R/W
1
BOR Wait and Check for Noise
This bit specifies the response to a brown-out signal assertion if BORIOR
is not set.
If BORWT is set to 1 and BORIOR is cleared to 0, the controller waits
BORTIM IOSC periods and resamples the BOR output. If still asserted,
a BOR interrupt is signalled. If no longer asserted, the initial assertion
is suppressed (attributable to noise).
If BORWT is 0, BOR assertions do not resample the output and any
condition is reported immediately if enabled.
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Register 3: LDO Power Control (LDOPCTL), offset 0x034
The VADJ field in this register adjusts the on-chip output voltage (VOUT).
LDO Power Control (LDOPCTL)
Base 0x400F.E000
Offset 0x034
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
VADJ
Bit/Field
Name
Type
Reset
31:6
reserved
RO
0
5:0
VADJ
R/W
0x0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
LDO Output Voltage
This field sets the on-chip output voltage. The programming values for
the VADJ field are provided below.
Value
VOUT (V)
0x00
2.50
0x01
2.45
0x02
2.40
0x03
2.35
0x04
2.30
0x05
2.25
0x06-0x3F Reserved
0x1B
2.75
0x1C
2.70
0x1D
2.65
0x1E
2.60
0x1F
2.55
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System Control
Register 4: Raw Interrupt Status (RIS), offset 0x050
Central location for system control raw interrupts. These are set and cleared by hardware.
Raw Interrupt Status (RIS)
Base 0x400F.E000
Offset 0x050
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
PLLLRIS
CLRIS
IOFRIS
MOFRIS
LDORIS
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
BORRIS PLLFRIS
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:7
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
6
PLLLRIS
RO
0
PLL Lock Raw Interrupt Status
This bit is set when the PLL TREADY Timer asserts.
5
CLRIS
RO
0
Current Limit Raw Interrupt Status
This bit is set if the LDO’s CLE output asserts.
4
IOFRIS
RO
0
Internal Oscillator Fault Raw Interrupt Status
This bit is set if an internal oscillator fault is detected.
3
MOFRIS
RO
0
Main Oscillator Fault Raw Interrupt Status
This bit is set if a main oscillator fault is detected.
2
LDORIS
RO
0
LDO Power Unregulated Raw Interrupt Status
This bit is set if a LDO voltage is unregulated.
1
BORRIS
RO
0
Brown-Out Reset Raw Interrupt Status
This bit is the raw interrupt status for any brown-out conditions. If set,
a brown-out condition is currently active. This is an unregistered signal
from the brown-out detection circuit. An interrupt is reported if the BORIM
bit in the IMC register is set and the BORIOR bit in the PBORCTL register
is cleared.
0
PLLFRIS
RO
0
PLL Fault Raw Interrupt Status
This bit is set if a PLL fault is detected (stops oscillating).
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Register 5: Interrupt Mask Control (IMC), offset 0x054
Central location for system control interrupt masks.
Interrupt Mask Control (IMC)
Base 0x400F.E000
Offset 0x054
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
PLLLIM
CLIM
IOFIM
MOFIM
LDOIM
BORIM
PLLFIM
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
Bit/Field
Name
Type
Reset
Description
31:7
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
6
PLLLIM
R/W
0
PLL Lock Interrupt Mask
This bit specifies whether a PLL Lock interrupt is promoted to a controller
interrupt. If set, an interrupt is generated if PLLLRIS in RIS is set;
otherwise, an interrupt is not generated.
5
CLIM
R/W
0
Current Limit Interrupt Mask
This bit specifies whether a current limit detection is promoted to a
controller interrupt. If set, an interrupt is generated if CLRIS is set;
otherwise, an interrupt is not generated.
4
IOFIM
R/W
0
Internal Oscillator Fault Interrupt Mask
This bit specifies whether an internal oscillator fault detection is promoted
to a controller interrupt. If set, an interrupt is generated if IOFRIS is set;
otherwise, an interrupt is not generated.
3
MOFIM
R/W
0
Main Oscillator Fault Interrupt Mask
This bit specifies whether a main oscillator fault detection is promoted
to a controller interrupt. If set, an interrupt is generated if MOFRIS is set;
otherwise, an interrupt is not generated.
2
LDOIM
R/W
0
LDO Power Unregulated Interrupt Mask
This bit specifies whether an LDO unregulated power situation is
promoted to a controller interrupt. If set, an interrupt is generated if
LDORIS is set; otherwise, an interrupt is not generated.
1
BORIM
R/W
0
Brown-Out Reset Interrupt Mask
This bit specifies whether a brown-out condition is promoted to a
controller interrupt. If set, an interrupt is generated if BORRIS is set;
otherwise, an interrupt is not generated.
0
PLLFIM
R/W
0
PLL Fault Interrupt Mask
This bit specifies whether a PLL fault detection is promoted to a controller
interrupt. If set, an interrupt is generated if PLLFRIS is set; otherwise,
an interrupt is not generated.
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System Control
Register 6: Masked Interrupt Status and Clear (MISC), offset 0x058
On a read, this register gives the current masked status value of the corresponding interrupt. All of
the bits are R/W1C and this action also clears the corresponding raw interrupt bit in the RIS register
(see page 166).
Masked Interrupt Status and Clear (MISC)
Base 0x400F.E000
Offset 0x058
Type R/W1C, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
PLLLMIS
CLMIS
IOFMIS
BORMIS
reserved
RO
0
RO
0
R/W1C
0
R/W1C
0
R/W1C
0
R/W1C
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
MOFMIS LDOMIS
R/W1C
0
R/W1C
0
Bit/Field
Name
Type
Reset
Description
31:7
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
6
PLLLMIS
R/W1C
0
PLL Lock Masked Interrupt Status
This bit is set when the PLL TREADY timer asserts. The interrupt is cleared
by writing a 1 to this bit.
5
CLMIS
R/W1C
0
Current Limit Masked Interrupt Status
This bit is set if the LDO’s CLE output asserts. The interrupt is cleared
by writing a 1 to this bit.
4
IOFMIS
R/W1C
0
Internal Oscillator Fault Masked Interrupt Status
This bit is set if an internal oscillator fault is detected. The interrupt is
cleared by writing a 1 to this bit.
3
MOFMIS
R/W1C
0
Main Oscillator Fault Masked Interrupt Status
This bit is set if a main oscillator fault is detected. The interrupt is cleared
by writing a 1 to this bit.
2
LDOMIS
R/W1C
0
LDO Power Unregulated Masked Interrupt Status
This bit is set if LDO power is unregulated. The interrupt is cleared by
writing a 1 to this bit.
1
BORMIS
R/W1C
0
BOR Masked Interrupt Status
This bit is the masked interrupt status for any brown-out conditions. If
set, a brown-out condition was detected. An interrupt is reported if the
BORIM bit in the IMC register is set and the BORIOR bit in the PBORCTL
register is cleared. The interrupt is cleared by writing a 1 to this bit.
0
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Register 7: Reset Cause (RESC), offset 0x05C
This field specifies the cause of the reset event to software. The reset value is determined by the
cause of the reset. When an external reset is the cause (EXT is set), all other reset bits are cleared.
However, if the reset is due to any other cause, the remaining bits are sticky, allowing software to
see all causes.
Reset Cause (RESC)
Base 0x400F.E000
Offset 0x05C
Type R/W, reset 31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
LDO
SW
WDT
BOR
POR
EXT
RO
0
RO
0
RO
0
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
R/W
-
reserved
Type
Reset
reserved
Type
Reset
RO
0
Bit/Field
Name
Type
Reset
Description
31:6
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
5
LDO
R/W
-
LDO Reset
When set, indicates the LDO circuit has lost regulation and has
generated a reset event.
4
SW
R/W
-
Software Reset
When set, indicates a software reset is the cause of the reset event.
3
WDT
R/W
-
Watchdog Timer Reset
When set, indicates a watchdog reset is the cause of the reset event.
2
BOR
R/W
-
Brown-Out Reset
When set, indicates a brown-out reset is the cause of the reset event.
1
POR
R/W
-
Power-On Reset
When set, indicates a power-on reset is the cause of the reset event.
0
EXT
R/W
-
External Reset
When set, indicates an external reset (RST assertion) is the cause of
the reset event.
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Register 8: Run-Mode Clock Configuration (RCC), offset 0x060
This register is defined to provide source control and frequency speed.
Run-Mode Clock Configuration (RCC)
Base 0x400F.E000
Offset 0x060
Type R/W, reset 0x0780.3AC0
31
30
29
28
26
25
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
1
15
14
13
12
11
10
PWRDN
OEN
BYPASS
PLLVER
R/W
1
R/W
1
R/W
1
R/W
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
RO
0
27
24
23
R/W
1
R/W
1
R/W
1
9
8
R/W
1
R/W
0
ACG
21
20
19
R/W
0
RO
0
RO
0
RO
0
7
6
5
4
3
R/W
1
R/W
1
R/W
0
SYSDIV
22
Name
Type
Reset
31:28
reserved
RO
0x0
27
ACG
R/W
0
17
16
RO
0
RO
0
RO
0
2
1
0
reserved
USESYSDIV
XTAL
Bit/Field
18
OSCSRC
R/W
0
IOSCVER MOSCVER IOSCDIS MOSCDIS
R/W
0
R/W
0
R/W
0
R/W
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Auto Clock Gating
This bit specifies whether the system uses the Sleep-Mode Clock
Gating Control (SCGCn) registers and Deep-Sleep-Mode Clock
Gating Control (DCGCn) registers if the controller enters a Sleep or
Deep-Sleep mode (respectively). If set, the SCGCn or DCGCn registers
are used to control the clocks distributed to the peripherals when the
controller is in a sleep mode. Otherwise, the Run-Mode Clock Gating
Control (RCGCn) registers are used when the controller enters a sleep
mode.
The RCGCn registers are always used to control the clocks in Run
mode.
This allows peripherals to consume less power when the controller is
in a sleep mode and the peripheral is unused.
26:23
SYSDIV
R/W
0xF
System Clock Divisor
Specifies which divisor is used to generate the system clock from either
the PLL output or the oscillator source (depending on how the BYPASS
bit in this register is configured). See Table 5-4 on page 156 for bit
encodings.
The PLL VCO frequency is 200 MHz.
If the SYSDIV value is less than MINSYSDIV (see page 180), and the
PLL is being used, then the MINSYSDIV value is used as the divisor.
If the PLL is not being used, the SYSDIV value can be less than
MINSYSDIV.
22
USESYSDIV
R/W
0
Enable System Clock Divider
Use the system clock divider as the source for the system clock. The
system clock divider is forced to be used when the PLL is selected as
the source.
If the USERCC2 bit in the RCC2 register is set, then the SYSDIV2 field
in the RCC2 register is used as the system clock divider rather than the
SYSDIV field in this register.
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Bit/Field
Name
Type
Reset
Description
21:14
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
13
PWRDN
R/W
1
PLL Power Down
This bit connects to the PLL PWRDN input. The reset value of 1 powers
down the PLL. See Table 5-6 on page 172 for PLL mode control.
12
OEN
R/W
1
PLL Output Enable
This bit specifies whether the PLL output driver is enabled. If cleared,
the driver transmits the PLL clock to the output. Otherwise, the PLL
clock does not oscillate outside the PLL module.
Note:
11
BYPASS
R/W
1
Both PWRDN and OEN must be cleared to run the PLL.
PLL Bypass
Chooses whether the system clock is derived from the PLL output or
the OSC source. If set, the clock that drives the system is the OSC
source. Otherwise, the clock that drives the system is the PLL output
clock divided by the system divider.
See Table 5-4 on page 156 for programming guidelines.
Note:
10
PLLVER
R/W
0
The ADC must be clocked from the PLL or directly from a
14-MHz to 18-MHz clock source to operate properly.
PLL Verification
This bit controls the PLL verification timer function. If set, the verification
timer is enabled and an interrupt is generated if the PLL becomes
inoperative. Otherwise, the verification timer is not enabled.
9:6
XTAL
R/W
0xB
Crystal Value
This field specifies the crystal value attached to the main oscillator. The
encoding for this field is provided below.
Value Crystal Frequency (MHz) Not
Using the PLL
Crystal Frequency (MHz) Using
the PLL
0x0
1.000
reserved
0x1
1.8432
reserved
0x2
2.000
reserved
0x3
2.4576
reserved
0x4
3.579545 MHz
0x5
3.6864 MHz
0x6
4 MHz
0x7
4.096 MHz
0x8
4.9152 MHz
0x9
5 MHz
0xA
5.12 MHz
0xB
6 MHz (reset value)
0xC
6.144 MHz
0xD
7.3728 MHz
0xE
8 MHz
0xF
8.192 MHz
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Bit/Field
Name
Type
Reset
5:4
OSCSRC
R/W
0x0
Description
Oscillator Source
Selects the input source for the OSC. The values are:
Value Input Source
0x0
MOSC
Main oscillator (default)
0x1
IOSC
Internal oscillator
0x2
IOSC/4
Internal oscillator / 4 (this is necessary if used as input to PLL)
0x3
3
IOSCVER
R/W
0
reserved
Internal Oscillator Verification Timer
This bit controls the internal oscillator verification timer function. If set,
the verification timer is enabled and an interrupt is generated if the timer
becomes inoperative. Otherwise, the verification timer is not enabled.
2
MOSCVER
R/W
0
Main Oscillator Verification Timer
This bit controls the main oscillator verification timer function. If set, the
verification timer is enabled and an interrupt is generated if the timer
becomes inoperative. Otherwise, the verification timer is not enabled.
1
IOSCDIS
R/W
0
Internal Oscillator Disable
0: Internal oscillator (IOSC) is enabled.
1: Internal oscillator is disabled.
0
MOSCDIS
R/W
0
Main Oscillator Disable
0: Main oscillator is enabled (default).
1: Main oscillator is disabled .
Table 5-6. PLL Mode Control
PWRDN
OEN
Mode
1
X
Power down
0
0
Normal
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Register 9: XTAL to PLL Translation (PLLCFG), offset 0x064
This register provides a means of translating external crystal frequencies into the appropriate PLL
settings. This register is initialized during the reset sequence and updated anytime that the XTAL
field changes in the Run-Mode Clock Configuration (RCC) register (see page 170).
The PLL frequency is calculated using the PLLCFG field values, as follows:
PLLFreq = OSCFreq * (F + 2) / (R + 2)
XTAL to PLL Translation (PLLCFG)
Base 0x400F.E000
Offset 0x064
Type RO, reset 31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
reserved
Type
Reset
OD
Type
Reset
RO
-
F
Bit/Field
Name
Type
Reset
31:16
reserved
RO
0x0
15:14
OD
RO
-
R
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
PLL OD Value
This field specifies the value supplied to the PLL’s OD input.
Value Description
13:5
F
RO
-
0x0
Divide by 1
0x1
Divide by 2
0x2
Divide by 4
0x3
Reserved
PLL F Value
This field specifies the value supplied to the PLL’s F input.
4:0
R
RO
-
PLL R Value
This field specifies the value supplied to the PLL’s R input.
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Register 10: Deep Sleep Clock Configuration (DSLPCLKCFG), offset 0x144
This register is used to automatically switch from the main oscillator to the internal oscillator when
entering Deep-Sleep mode. The system clock source is the main oscillator by default. When this
register is set, the internal oscillator is powered up and the main oscillator is powered down. When
the Deep-Sleep exit event occurs, hardware brings the system clock back to the source and frequency
it had at the onset of Deep-Sleep mode.
Deep Sleep Clock Configuration (DSLPCLKCFG)
Base 0x400F.E000
Offset 0x144
Type R/W, reset 0x0780.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
31:1
reserved
RO
0x0
0
IOSC
R/W
0
RO
0
IOSC
R/W
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
IOSC Clock Source
When set, forces IOSC to be clock source during Deep-Sleep (overrides
DSOSCSRC field if set)
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Register 11: Clock Verification Clear (CLKVCLR), offset 0x150
This register is provided as a means of clearing the clock verification circuits by software. Since the
clock verification circuits force a known good clock to control the process, the controller is allowed
the opportunity to solve the problem and clear the verification fault. This register clears all clock
verification faults. To clear a clock verification fault, the VERCLR bit must be set and then cleared
by software. This bit is not self-clearing.
Clock Verification Clear (CLKVCLR)
Base 0x400F.E000
Offset 0x150
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
VERCLR
R/W
0
Bit/Field
Name
Type
Reset
Description
31:1
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
0
VERCLR
R/W
0
Clock Verification Clear
Clears clock verification faults.
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Register 12: Allow Unregulated LDO to Reset the Part (LDOARST), offset
0x160
This register is provided as a means of allowing the LDO to reset the part if the voltage goes
unregulated. Use this register to choose whether to automatically reset the part if the LDO goes
unregulated, based on the design tolerance for LDO fluctuation.
Allow Unregulated LDO to Reset the Part (LDOARST)
Base 0x400F.E000
Offset 0x160
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
0
LDOARST
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:1
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
0
LDOARST
R/W
0
LDO Reset
When set, allows unregulated LDO output to reset the part.
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Register 13: Device Identification 1 (DID1), offset 0x004
This register identifies the device family, part number, temperature range, pin count, and package
type. Each microcontroller is uniquely identified by the combined values of the CLASS field in the
DID0 register and the PARTNO field in the DID1 register.
Device Identification 1 (DID1)
Base 0x400F.E000
Offset 0x004
Type RO, reset 31
30
29
28
27
26
RO
0
25
24
23
22
21
20
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
1
RO
1
15
14
13
12
11
10
9
8
7
6
5
4
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
-
RO
-
RO
-
VER
Type
Reset
FAM
TEMP
RO
0
18
17
16
RO
0
RO
1
RO
0
RO
1
3
2
1
0
PARTNO
reserved
Type
Reset
19
Bit/Field
Name
Type
Reset
31:28
VER
RO
0x0
RO
-
PKG
ROHS
RO
-
RO
1
QUAL
RO
-
RO
-
Description
DID1 Version
This field defines the DID1 register format version. The version number
is numeric. The value of the VER field is encoded as follows (all other
encodings are reserved):
Value Description
0x0
27:24
FAM
RO
0x0
Initial DID1 register format definition, indicating a Stellaris
LM3Snnn device.
Family
This field provides the family identification of the device within the
Luminary Micro product portfolio. The value is encoded as follows (all
other encodings are reserved):
Value Description
0x0
23:16
PARTNO
RO
0x35
Stellaris family of microcontollers, that is, all devices with
external part numbers starting with LM3S.
Part Number
This field provides the part number of the device within the family. The
value is encoded as follows (all other encodings are reserved):
Value Description
0x35 LM3S828
15:8
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Bit/Field
Name
Type
Reset
7:5
TEMP
RO
-
Description
Temperature Range
This field specifies the temperature rating of the device. The value is
encoded as follows (all other encodings are reserved):
Value Description
4:3
PKG
RO
-
0x0
Commercial temperature range (0°C to 70°C)
0x1
Industrial temperature range (-40°C to 85°C)
0x2
Extended temperature range (-40°C to 105°C)
Package Type
This field specifies the package type. The value is encoded as follows
(all other encodings are reserved):
Value Description
2
ROHS
RO
1
0x0
28-pin SOIC package
0x1
48-pin LQFP package
0x3
48-pin QFN package
RoHS-Compliance
This bit specifies whether the device is RoHS-compliant. A 1 indicates
the part is RoHS-compliant.
1:0
QUAL
RO
-
Qualification Status
This field specifies the qualification status of the device. The value is
encoded as follows (all other encodings are reserved):
Value Description
0x0
Engineering Sample (unqualified)
0x1
Pilot Production (unqualified)
0x2
Fully Qualified
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Register 14: Device Capabilities 0 (DC0), offset 0x008
This register is predefined by the part and can be used to verify features.
Device Capabilities 0 (DC0)
Base 0x400F.E000
Offset 0x008
Type RO, reset 0x001F.001F
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
1
RO
1
RO
1
RO
1
RO
1
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
1
RO
1
RO
1
RO
1
RO
1
SRAMSZ
Type
Reset
FLASHSZ
Type
Reset
RO
0
Bit/Field
Name
Type
Reset
Description
31:16
SRAMSZ
RO
0x001F
SRAM Size
Indicates the size of the on-chip SRAM memory.
Value
Description
0x001F 8 KB of SRAM
15:0
FLASHSZ
RO
0x001F
Flash Size
Indicates the size of the on-chip flash memory.
Value
Description
0x001F 64 KB of Flash
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Register 15: Device Capabilities 1 (DC1), offset 0x010
This register provides a list of features available in the system. The Stellaris family uses this register
format to indicate the availability of the following family features in the specific device: PWM, ADC,
Watchdog timer, and debug capabilities. This register also indicates the maximum clock frequency
and maximum ADC sample rate. The format of this register is consistent with the RCGC0, SCGC0,
and DCGC0 clock control registers and the SRCR0 software reset control register.
Device Capabilities 1 (DC1)
Base 0x400F.E000
Offset 0x010
Type RO, reset 0x0001.33BF
31
30
29
28
27
26
25
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
1
RO
0
24
23
22
21
20
19
18
17
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
1
8
7
6
5
4
3
2
1
0
MPU
reserved
TEMPSNS
PLL
WDT
SWO
SWD
JTAG
RO
1
RO
0
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
reserved
Type
Reset
MINSYSDIV
Type
Reset
RO
1
reserved
RO
0
MAXADCSPD
RO
1
RO
1
16
ADC
Bit/Field
Name
Type
Reset
Description
31:17
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
16
ADC
RO
1
ADC Module Present
When set, indicates that the ADC module is present.
15:12
MINSYSDIV
RO
0x3
System Clock Divider
Minimum 4-bit divider value for system clock. The reset value is
hardware-dependent. See the RCC register for how to change the
system clock divisor using the SYSDIV bit.
Value Description
0x3
11:10
reserved
RO
0
9:8
MAXADCSPD
RO
0x3
Specifies a 50-MHz CPU clock with a PLL divider of 4.
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Max ADC Speed
Indicates the maximum rate at which the ADC samples data.
Value Description
0x3
7
MPU
RO
1
1M samples/second
MPU Present
When set, indicates that the Cortex-M3 Memory Protection Unit (MPU)
module is present. See the "Cortex-M3 Peripherals" chapter in the
Stellaris Data Sheet for details on the MPU.
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Bit/Field
Name
Type
Reset
Description
6
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
5
TEMPSNS
RO
1
Temp Sensor Present
When set, indicates that the on-chip temperature sensor is present.
4
PLL
RO
1
PLL Present
When set, indicates that the on-chip Phase Locked Loop (PLL) is
present.
3
WDT
RO
1
Watchdog Timer Present
When set, indicates that a watchdog timer is present.
2
SWO
RO
1
SWO Trace Port Present
When set, indicates that the Serial Wire Output (SWO) trace port is
present.
1
SWD
RO
1
SWD Present
When set, indicates that the Serial Wire Debugger (SWD) is present.
0
JTAG
RO
1
JTAG Present
When set, indicates that the JTAG debugger interface is present.
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Register 16: Device Capabilities 2 (DC2), offset 0x014
This register provides a list of features available in the system. The Stellaris family uses this register
format to indicate the availability of the following family features in the specific device: Analog
Comparators, General-Purpose Timers, I2Cs, QEIs, SSIs, and UARTs. The format of this register
is consistent with the RCGC1, SCGC1, and DCGC1 clock control registers and the SRCR1 software
reset control register.
Device Capabilities 2 (DC2)
Base 0x400F.E000
Offset 0x014
Type RO, reset 0x0007.1013
31
30
29
28
27
26
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
RO
0
25
24
23
22
21
20
19
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
10
9
8
7
6
5
4
3
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
RO
0
I2C0
RO
0
RO
1
reserved
RO
0
SSI0
RO
1
18
17
16
TIMER2
TIMER1
TIMER0
RO
1
RO
1
RO
1
2
1
0
UART1
UART0
RO
1
RO
1
reserved
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:19
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
18
TIMER2
RO
1
Timer 2 Present
When set, indicates that General-Purpose Timer module 2 is present.
17
TIMER1
RO
1
Timer 1 Present
When set, indicates that General-Purpose Timer module 1 is present.
16
TIMER0
RO
1
Timer 0 Present
When set, indicates that General-Purpose Timer module 0 is present.
15:13
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
12
I2C0
RO
1
I2C Module 0 Present
When set, indicates that I2C module 0 is present.
11:5
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
4
SSI0
RO
1
SSI0 Present
When set, indicates that SSI module 0 is present.
3:2
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
1
UART1
RO
1
UART1 Present
When set, indicates that UART module 1 is present.
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Bit/Field
Name
Type
Reset
0
UART0
RO
1
Description
UART0 Present
When set, indicates that UART module 0 is present.
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Register 17: Device Capabilities 3 (DC3), offset 0x018
This register provides a list of features available in the system. The Stellaris family uses this register
format to indicate the availability of the following family features in the specific device: Analog
Comparator I/Os, CCP I/Os, ADC I/Os, and PWM I/Os.
Device Capabilities 3 (DC3)
Base 0x400F.E000
Offset 0x018
Type RO, reset 0xBFFF.0000
Type
Reset
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
32KHZ
reserved
CCP5
CCP4
CCP3
CCP2
CCP1
CCP0
ADC7
ADC6
ADC5
ADC4
ADC3
ADC2
ADC1
ADC0
RO
1
RO
0
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
Bit/Field
Name
Type
Reset
31
32KHZ
RO
1
Description
32KHz Input Clock Available
When set, indicates the 32KHz pin or an even CCP pin is present and
can be used as a 32-KHz input clock.
30
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
29
CCP5
RO
1
CCP5 Pin Present
When set, indicates that Capture/Compare/PWM pin 5 is present.
28
CCP4
RO
1
CCP4 Pin Present
When set, indicates that Capture/Compare/PWM pin 4 is present.
27
CCP3
RO
1
CCP3 Pin Present
When set, indicates that Capture/Compare/PWM pin 3 is present.
26
CCP2
RO
1
CCP2 Pin Present
When set, indicates that Capture/Compare/PWM pin 2 is present.
25
CCP1
RO
1
CCP1 Pin Present
When set, indicates that Capture/Compare/PWM pin 1 is present.
24
CCP0
RO
1
CCP0 Pin Present
When set, indicates that Capture/Compare/PWM pin 0 is present.
23
ADC7
RO
1
ADC7 Pin Present
When set, indicates that ADC pin 7 is present.
22
ADC6
RO
1
ADC6 Pin Present
When set, indicates that ADC pin 6 is present.
21
ADC5
RO
1
ADC5 Pin Present
When set, indicates that ADC pin 5 is present.
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Bit/Field
Name
Type
Reset
20
ADC4
RO
1
Description
ADC4 Pin Present
When set, indicates that ADC pin 4 is present.
19
ADC3
RO
1
ADC3 Pin Present
When set, indicates that ADC pin 3 is present.
18
ADC2
RO
1
ADC2 Pin Present
When set, indicates that ADC pin 2 is present.
17
ADC1
RO
1
ADC1 Pin Present
When set, indicates that ADC pin 1 is present.
16
ADC0
RO
1
ADC0 Pin Present
When set, indicates that ADC pin 0 is present.
15:0
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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System Control
Register 18: Device Capabilities 4 (DC4), offset 0x01C
This register provides a list of features available in the system. The Stellaris family uses this register
format to indicate the availability of GPIOs in the specific device. The format of this register is
consistent with the RCGC2, SCGC2, and DCGC2 clock control registers and the SRCR2 software
reset control register.
Device Capabilities 4 (DC4)
Base 0x400F.E000
Offset 0x01C
Type RO, reset 0x0000.001F
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
GPIOE
GPIOD
GPIOC
GPIOB
GPIOA
RO
0
RO
0
RO
0
RO
0
RO
1
RO
1
RO
1
RO
1
RO
1
reserved
Type
Reset
reserved
Type
Reset
RO
0
Bit/Field
Name
Type
Reset
Description
31:5
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
4
GPIOE
RO
1
GPIO Port E Present
When set, indicates that GPIO Port E is present.
3
GPIOD
RO
1
GPIO Port D Present
When set, indicates that GPIO Port D is present.
2
GPIOC
RO
1
GPIO Port C Present
When set, indicates that GPIO Port C is present.
1
GPIOB
RO
1
GPIO Port B Present
When set, indicates that GPIO Port B is present.
0
GPIOA
RO
1
GPIO Port A Present
When set, indicates that GPIO Port A is present.
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Register 19: Run Mode Clock Gating Control Register 0 (RCGC0), offset 0x100
This register controls the clock gating logic. Each bit controls a clock enable for a given interface,
function, or unit. If set, the unit receives a clock and functions. Otherwise, the unit is unclocked and
disabled (saving power). If the unit is unclocked, reads or writes to the unit will generate a bus fault.
The reset state of these bits is 0 (unclocked) unless otherwise noted, so that all functional units are
disabled. It is the responsibility of software to enable the ports necessary for the application. Note
that these registers may contain more bits than there are interfaces, functions, or units to control.
This is to assure reasonable code compatibility with other family and future parts. RCGC0 is the
clock configuration register for running operation, SCGC0 for Sleep operation, and DCGC0 for
Deep-Sleep operation. Setting the ACG bit in the Run-Mode Clock Configuration (RCC) register
specifies that the system uses sleep modes.
Run Mode Clock Gating Control Register 0 (RCGC0)
Base 0x400F.E000
Offset 0x100
Type R/W, reset 0x00000040
31
30
29
28
27
26
25
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
24
23
22
21
20
19
18
17
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
ADC
MAXADCSPD
R/W
0
16
reserved
WDT
R/W
0
reserved
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:17
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
16
ADC
R/W
0
ADC0 Clock Gating Control
This bit controls the clock gating for SAR ADC module 0. If set, the unit
receives a clock and functions. Otherwise, the unit is unclocked and
disabled. If the unit is unclocked, a read or write to the unit generates
a bus fault.
15:10
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
9:8
MAXADCSPD
R/W
0
ADC Sample Speed
This field sets the rate at which the ADC samples data. You cannot set
the rate higher than the maximum rate. You can set the sample rate by
setting the MAXADCSPD bit as follows:
Value Description
0x3
1M samples/second
0x2
500K samples/second
0x1
250K samples/second
0x0
125K samples/second
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Bit/Field
Name
Type
Reset
Description
7:4
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
3
WDT
R/W
0
WDT Clock Gating Control
This bit controls the clock gating for the WDT module. If set, the unit
receives a clock and functions. Otherwise, the unit is unclocked and
disabled. If the unit is unclocked, a read or write to the unit generates
a bus fault.
2:0
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
188
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Stellaris LM3S828 Microcontroller
Register 20: Sleep Mode Clock Gating Control Register 0 (SCGC0), offset
0x110
This register controls the clock gating logic. Each bit controls a clock enable for a given interface,
function, or unit. If set, the unit receives a clock and functions. Otherwise, the unit is unclocked and
disabled (saving power). If the unit is unclocked, reads or writes to the unit will generate a bus fault.
The reset state of these bits is 0 (unclocked) unless otherwise noted, so that all functional units are
disabled. It is the responsibility of software to enable the ports necessary for the application. Note
that these registers may contain more bits than there are interfaces, functions, or units to control.
This is to assure reasonable code compatibility with other family and future parts. RCGC0 is the
clock configuration register for running operation, SCGC0 for Sleep operation, and DCGC0 for
Deep-Sleep operation. Setting the ACG bit in the Run-Mode Clock Configuration (RCC) register
specifies that the system uses sleep modes.
Sleep Mode Clock Gating Control Register 0 (SCGC0)
Base 0x400F.E000
Offset 0x110
Type R/W, reset 0x00000040
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
9
8
7
6
5
4
MAXADCSPD
RO
0
RO
0
R/W
0
R/W
0
16
ADC
reserved
RO
0
RO
0
RO
0
RO
0
RO
0
3
2
WDT
RO
0
R/W
0
RO
0
R/W
0
1
0
reserved
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:17
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
16
ADC
R/W
0
ADC0 Clock Gating Control
This bit controls the clock gating for SAR ADC module 0. If set, the unit
receives a clock and functions. Otherwise, the unit is unclocked and
disabled. If the unit is unclocked, a read or write to the unit generates
a bus fault.
15:10
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
9:8
MAXADCSPD
R/W
0
ADC Sample Speed
This field sets the rate at which the ADC samples data. You cannot set
the rate higher than the maximum rate. You can set the sample rate by
setting the MAXADCSPD bit as follows:
Value Description
0x3
1M samples/second
0x2
500K samples/second
0x1
250K samples/second
0x0
125K samples/second
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Bit/Field
Name
Type
Reset
Description
7:4
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
3
WDT
R/W
0
WDT Clock Gating Control
This bit controls the clock gating for the WDT module. If set, the unit
receives a clock and functions. Otherwise, the unit is unclocked and
disabled. If the unit is unclocked, a read or write to the unit generates
a bus fault.
2:0
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
190
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Register 21: Deep Sleep Mode Clock Gating Control Register 0 (DCGC0),
offset 0x120
This register controls the clock gating logic. Each bit controls a clock enable for a given interface,
function, or unit. If set, the unit receives a clock and functions. Otherwise, the unit is unclocked and
disabled (saving power). If the unit is unclocked, reads or writes to the unit will generate a bus fault.
The reset state of these bits is 0 (unclocked) unless otherwise noted, so that all functional units are
disabled. It is the responsibility of software to enable the ports necessary for the application. Note
that these registers may contain more bits than there are interfaces, functions, or units to control.
This is to assure reasonable code compatibility with other family and future parts. RCGC0 is the
clock configuration register for running operation, SCGC0 for Sleep operation, and DCGC0 for
Deep-Sleep operation. Setting the ACG bit in the Run-Mode Clock Configuration (RCC) register
specifies that the system uses sleep modes.
Deep Sleep Mode Clock Gating Control Register 0 (DCGC0)
Base 0x400F.E000
Offset 0x120
Type R/W, reset 0x00000040
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
3
2
WDT
RO
0
RO
0
16
ADC
RO
0
RO
0
RO
0
RO
0
R/W
0
RO
0
R/W
0
1
0
reserved
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:17
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
16
ADC
R/W
0
ADC0 Clock Gating Control
This bit controls the clock gating for SAR ADC module 0. If set, the unit
receives a clock and functions. Otherwise, the unit is unclocked and
disabled. If the unit is unclocked, a read or write to the unit generates
a bus fault.
15:4
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
3
WDT
R/W
0
WDT Clock Gating Control
This bit controls the clock gating for the WDT module. If set, the unit
receives a clock and functions. Otherwise, the unit is unclocked and
disabled. If the unit is unclocked, a read or write to the unit generates
a bus fault.
2:0
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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191
Texas Instruments-Production Data
System Control
Register 22: Run Mode Clock Gating Control Register 1 (RCGC1), offset 0x104
This register controls the clock gating logic. Each bit controls a clock enable for a given interface,
function, or unit. If set, the unit receives a clock and functions. Otherwise, the unit is unclocked and
disabled (saving power). If the unit is unclocked, reads or writes to the unit will generate a bus fault.
The reset state of these bits is 0 (unclocked) unless otherwise noted, so that all functional units are
disabled. It is the responsibility of software to enable the ports necessary for the application. Note
that these registers may contain more bits than there are interfaces, functions, or units to control.
This is to assure reasonable code compatibility with other family and future parts. RCGC1 is the
clock configuration register for running operation, SCGC1 for Sleep operation, and DCGC1 for
Deep-Sleep operation. Setting the ACG bit in the Run-Mode Clock Configuration (RCC) register
specifies that the system uses sleep modes.
Run Mode Clock Gating Control Register 1 (RCGC1)
Base 0x400F.E000
Offset 0x104
Type R/W, reset 0x00000000
31
30
29
28
27
26
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
RO
0
25
24
23
22
21
20
19
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
10
9
8
7
6
5
4
3
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
RO
0
I2C0
RO
0
R/W
0
reserved
RO
0
SSI0
R/W
0
18
17
16
TIMER2
TIMER1
TIMER0
R/W
0
R/W
0
R/W
0
2
1
0
UART1
UART0
R/W
0
R/W
0
reserved
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:19
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
18
TIMER2
R/W
0
Timer 2 Clock Gating Control
This bit controls the clock gating for General-Purpose Timer module 2.
If set, the unit receives a clock and functions. Otherwise, the unit is
unclocked and disabled. If the unit is unclocked, reads or writes to the
unit will generate a bus fault.
17
TIMER1
R/W
0
Timer 1 Clock Gating Control
This bit controls the clock gating for General-Purpose Timer module 1.
If set, the unit receives a clock and functions. Otherwise, the unit is
unclocked and disabled. If the unit is unclocked, reads or writes to the
unit will generate a bus fault.
16
TIMER0
R/W
0
Timer 0 Clock Gating Control
This bit controls the clock gating for General-Purpose Timer module 0.
If set, the unit receives a clock and functions. Otherwise, the unit is
unclocked and disabled. If the unit is unclocked, reads or writes to the
unit will generate a bus fault.
15:13
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Bit/Field
Name
Type
Reset
12
I2C0
R/W
0
Description
I2C0 Clock Gating Control
This bit controls the clock gating for I2C module 0. If set, the unit receives
a clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
11:5
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
4
SSI0
R/W
0
SSI0 Clock Gating Control
This bit controls the clock gating for SSI module 0. If set, the unit receives
a clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
3:2
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
1
UART1
R/W
0
UART1 Clock Gating Control
This bit controls the clock gating for UART module 1. If set, the unit
receives a clock and functions. Otherwise, the unit is unclocked and
disabled. If the unit is unclocked, reads or writes to the unit will generate
a bus fault.
0
UART0
R/W
0
UART0 Clock Gating Control
This bit controls the clock gating for UART module 0. If set, the unit
receives a clock and functions. Otherwise, the unit is unclocked and
disabled. If the unit is unclocked, reads or writes to the unit will generate
a bus fault.
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System Control
Register 23: Sleep Mode Clock Gating Control Register 1 (SCGC1), offset
0x114
This register controls the clock gating logic. Each bit controls a clock enable for a given interface,
function, or unit. If set, the unit receives a clock and functions. Otherwise, the unit is unclocked and
disabled (saving power). If the unit is unclocked, reads or writes to the unit will generate a bus fault.
The reset state of these bits is 0 (unclocked) unless otherwise noted, so that all functional units are
disabled. It is the responsibility of software to enable the ports necessary for the application. Note
that these registers may contain more bits than there are interfaces, functions, or units to control.
This is to assure reasonable code compatibility with other family and future parts. RCGC1 is the
clock configuration register for running operation, SCGC1 for Sleep operation, and DCGC1 for
Deep-Sleep operation. Setting the ACG bit in the Run-Mode Clock Configuration (RCC) register
specifies that the system uses sleep modes.
Sleep Mode Clock Gating Control Register 1 (SCGC1)
Base 0x400F.E000
Offset 0x114
Type R/W, reset 0x00000000
31
30
29
28
27
26
25
24
23
22
21
20
19
reserved
Type
Reset
RO
0
15
RO
0
RO
0
14
13
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
12
11
10
9
I2C0
RO
0
R/W
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
reserved
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
17
16
TIMER1
TIMER0
R/W
0
R/W
0
RO
0
RO
0
R/W
0
4
3
2
SSI0
RO
0
18
TIMER2
R/W
0
reserved
RO
0
RO
0
1
0
UART1
UART0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:19
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
18
TIMER2
R/W
0
Timer 2 Clock Gating Control
This bit controls the clock gating for General-Purpose Timer module 2.
If set, the unit receives a clock and functions. Otherwise, the unit is
unclocked and disabled. If the unit is unclocked, reads or writes to the
unit will generate a bus fault.
17
TIMER1
R/W
0
Timer 1 Clock Gating Control
This bit controls the clock gating for General-Purpose Timer module 1.
If set, the unit receives a clock and functions. Otherwise, the unit is
unclocked and disabled. If the unit is unclocked, reads or writes to the
unit will generate a bus fault.
16
TIMER0
R/W
0
Timer 0 Clock Gating Control
This bit controls the clock gating for General-Purpose Timer module 0.
If set, the unit receives a clock and functions. Otherwise, the unit is
unclocked and disabled. If the unit is unclocked, reads or writes to the
unit will generate a bus fault.
15:13
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Bit/Field
Name
Type
Reset
12
I2C0
R/W
0
Description
I2C0 Clock Gating Control
This bit controls the clock gating for I2C module 0. If set, the unit receives
a clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
11:5
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
4
SSI0
R/W
0
SSI0 Clock Gating Control
This bit controls the clock gating for SSI module 0. If set, the unit receives
a clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
3:2
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
1
UART1
R/W
0
UART1 Clock Gating Control
This bit controls the clock gating for UART module 1. If set, the unit
receives a clock and functions. Otherwise, the unit is unclocked and
disabled. If the unit is unclocked, reads or writes to the unit will generate
a bus fault.
0
UART0
R/W
0
UART0 Clock Gating Control
This bit controls the clock gating for UART module 0. If set, the unit
receives a clock and functions. Otherwise, the unit is unclocked and
disabled. If the unit is unclocked, reads or writes to the unit will generate
a bus fault.
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System Control
Register 24: Deep Sleep Mode Clock Gating Control Register 1 (DCGC1),
offset 0x124
This register controls the clock gating logic. Each bit controls a clock enable for a given interface,
function, or unit. If set, the unit receives a clock and functions. Otherwise, the unit is unclocked and
disabled (saving power). If the unit is unclocked, reads or writes to the unit will generate a bus fault.
The reset state of these bits is 0 (unclocked) unless otherwise noted, so that all functional units are
disabled. It is the responsibility of software to enable the ports necessary for the application. Note
that these registers may contain more bits than there are interfaces, functions, or units to control.
This is to assure reasonable code compatibility with other family and future parts. RCGC1 is the
clock configuration register for running operation, SCGC1 for Sleep operation, and DCGC1 for
Deep-Sleep operation. Setting the ACG bit in the Run-Mode Clock Configuration (RCC) register
specifies that the system uses sleep modes.
Deep Sleep Mode Clock Gating Control Register 1 (DCGC1)
Base 0x400F.E000
Offset 0x124
Type R/W, reset 0x00000000
31
30
29
28
27
26
25
24
23
22
21
20
19
reserved
Type
Reset
RO
0
15
RO
0
RO
0
14
13
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
12
11
10
9
I2C0
RO
0
R/W
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
reserved
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
17
16
TIMER1
TIMER0
R/W
0
R/W
0
RO
0
RO
0
R/W
0
4
3
2
SSI0
RO
0
18
TIMER2
R/W
0
reserved
RO
0
RO
0
1
0
UART1
UART0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:19
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
18
TIMER2
R/W
0
Timer 2 Clock Gating Control
This bit controls the clock gating for General-Purpose Timer module 2.
If set, the unit receives a clock and functions. Otherwise, the unit is
unclocked and disabled. If the unit is unclocked, reads or writes to the
unit will generate a bus fault.
17
TIMER1
R/W
0
Timer 1 Clock Gating Control
This bit controls the clock gating for General-Purpose Timer module 1.
If set, the unit receives a clock and functions. Otherwise, the unit is
unclocked and disabled. If the unit is unclocked, reads or writes to the
unit will generate a bus fault.
16
TIMER0
R/W
0
Timer 0 Clock Gating Control
This bit controls the clock gating for General-Purpose Timer module 0.
If set, the unit receives a clock and functions. Otherwise, the unit is
unclocked and disabled. If the unit is unclocked, reads or writes to the
unit will generate a bus fault.
15:13
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Bit/Field
Name
Type
Reset
12
I2C0
R/W
0
Description
I2C0 Clock Gating Control
This bit controls the clock gating for I2C module 0. If set, the unit receives
a clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
11:5
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
4
SSI0
R/W
0
SSI0 Clock Gating Control
This bit controls the clock gating for SSI module 0. If set, the unit receives
a clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
3:2
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
1
UART1
R/W
0
UART1 Clock Gating Control
This bit controls the clock gating for UART module 1. If set, the unit
receives a clock and functions. Otherwise, the unit is unclocked and
disabled. If the unit is unclocked, reads or writes to the unit will generate
a bus fault.
0
UART0
R/W
0
UART0 Clock Gating Control
This bit controls the clock gating for UART module 0. If set, the unit
receives a clock and functions. Otherwise, the unit is unclocked and
disabled. If the unit is unclocked, reads or writes to the unit will generate
a bus fault.
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System Control
Register 25: Run Mode Clock Gating Control Register 2 (RCGC2), offset 0x108
This register controls the clock gating logic. Each bit controls a clock enable for a given interface,
function, or unit. If set, the unit receives a clock and functions. Otherwise, the unit is unclocked and
disabled (saving power). If the unit is unclocked, reads or writes to the unit will generate a bus fault.
The reset state of these bits is 0 (unclocked) unless otherwise noted, so that all functional units are
disabled. It is the responsibility of software to enable the ports necessary for the application. Note
that these registers may contain more bits than there are interfaces, functions, or units to control.
This is to assure reasonable code compatibility with other family and future parts. RCGC2 is the
clock configuration register for running operation, SCGC2 for Sleep operation, and DCGC2 for
Deep-Sleep operation. Setting the ACG bit in the Run-Mode Clock Configuration (RCC) register
specifies that the system uses sleep modes.
Run Mode Clock Gating Control Register 2 (RCGC2)
Base 0x400F.E000
Offset 0x108
Type R/W, reset 0x00000000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
GPIOE
GPIOD
GPIOC
GPIOB
GPIOA
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
Bit/Field
Name
Type
Reset
Description
31:5
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
4
GPIOE
R/W
0
Port E Clock Gating Control
This bit controls the clock gating for Port E. If set, the unit receives a
clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
3
GPIOD
R/W
0
Port D Clock Gating Control
This bit controls the clock gating for Port D. If set, the unit receives a
clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
2
GPIOC
R/W
0
Port C Clock Gating Control
This bit controls the clock gating for Port C. If set, the unit receives a
clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
1
GPIOB
R/W
0
Port B Clock Gating Control
This bit controls the clock gating for Port B. If set, the unit receives a
clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
0
GPIOA
R/W
0
Port A Clock Gating Control
This bit controls the clock gating for Port A. If set, the unit receives a
clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
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Register 26: Sleep Mode Clock Gating Control Register 2 (SCGC2), offset
0x118
This register controls the clock gating logic. Each bit controls a clock enable for a given interface,
function, or unit. If set, the unit receives a clock and functions. Otherwise, the unit is unclocked and
disabled (saving power). If the unit is unclocked, reads or writes to the unit will generate a bus fault.
The reset state of these bits is 0 (unclocked) unless otherwise noted, so that all functional units are
disabled. It is the responsibility of software to enable the ports necessary for the application. Note
that these registers may contain more bits than there are interfaces, functions, or units to control.
This is to assure reasonable code compatibility with other family and future parts. RCGC2 is the
clock configuration register for running operation, SCGC2 for Sleep operation, and DCGC2 for
Deep-Sleep operation. Setting the ACG bit in the Run-Mode Clock Configuration (RCC) register
specifies that the system uses sleep modes.
Sleep Mode Clock Gating Control Register 2 (SCGC2)
Base 0x400F.E000
Offset 0x118
Type R/W, reset 0x00000000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
10
9
8
7
6
5
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
4
3
2
1
0
GPIOE
GPIOD
GPIOC
GPIOB
GPIOA
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:5
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
4
GPIOE
R/W
0
Port E Clock Gating Control
This bit controls the clock gating for Port E. If set, the unit receives a
clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
3
GPIOD
R/W
0
Port D Clock Gating Control
This bit controls the clock gating for Port D. If set, the unit receives a
clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
2
GPIOC
R/W
0
Port C Clock Gating Control
This bit controls the clock gating for Port C. If set, the unit receives a
clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
1
GPIOB
R/W
0
Port B Clock Gating Control
This bit controls the clock gating for Port B. If set, the unit receives a
clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
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Bit/Field
Name
Type
Reset
0
GPIOA
R/W
0
Description
Port A Clock Gating Control
This bit controls the clock gating for Port A. If set, the unit receives a
clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
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Register 27: Deep Sleep Mode Clock Gating Control Register 2 (DCGC2),
offset 0x128
This register controls the clock gating logic. Each bit controls a clock enable for a given interface,
function, or unit. If set, the unit receives a clock and functions. Otherwise, the unit is unclocked and
disabled (saving power). If the unit is unclocked, reads or writes to the unit will generate a bus fault.
The reset state of these bits is 0 (unclocked) unless otherwise noted, so that all functional units are
disabled. It is the responsibility of software to enable the ports necessary for the application. Note
that these registers may contain more bits than there are interfaces, functions, or units to control.
This is to assure reasonable code compatibility with other family and future parts. RCGC2 is the
clock configuration register for running operation, SCGC2 for Sleep operation, and DCGC2 for
Deep-Sleep operation. Setting the ACG bit in the Run-Mode Clock Configuration (RCC) register
specifies that the system uses sleep modes.
Deep Sleep Mode Clock Gating Control Register 2 (DCGC2)
Base 0x400F.E000
Offset 0x128
Type R/W, reset 0x00000000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
10
9
8
7
6
5
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
4
3
2
1
0
GPIOE
GPIOD
GPIOC
GPIOB
GPIOA
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:5
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
4
GPIOE
R/W
0
Port E Clock Gating Control
This bit controls the clock gating for Port E. If set, the unit receives a
clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
3
GPIOD
R/W
0
Port D Clock Gating Control
This bit controls the clock gating for Port D. If set, the unit receives a
clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
2
GPIOC
R/W
0
Port C Clock Gating Control
This bit controls the clock gating for Port C. If set, the unit receives a
clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
1
GPIOB
R/W
0
Port B Clock Gating Control
This bit controls the clock gating for Port B. If set, the unit receives a
clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
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System Control
Bit/Field
Name
Type
Reset
0
GPIOA
R/W
0
Description
Port A Clock Gating Control
This bit controls the clock gating for Port A. If set, the unit receives a
clock and functions. Otherwise, the unit is unclocked and disabled. If
the unit is unclocked, reads or writes to the unit will generate a bus fault.
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Register 28: Software Reset Control 0 (SRCR0), offset 0x040
Writes to this register are masked by the bits in the Device Capabilities 1 (DC1) register.
Software Reset Control 0 (SRCR0)
Base 0x400F.E000
Offset 0x040
Type R/W, reset 0x00000000
31
30
29
28
27
26
25
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
24
23
22
21
20
19
18
17
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
9
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
ADC
reserved
Type
Reset
16
WDT
R/W
0
reserved
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:17
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
16
ADC
R/W
0
ADC0 Reset Control
Reset control for SAR ADC module 0.
15:4
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
3
WDT
R/W
0
WDT Reset Control
Reset control for Watchdog unit.
2:0
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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System Control
Register 29: Software Reset Control 1 (SRCR1), offset 0x044
Writes to this register are masked by the bits in the Device Capabilities 2 (DC2) register.
Software Reset Control 1 (SRCR1)
Base 0x400F.E000
Offset 0x044
Type R/W, reset 0x00000000
31
30
29
28
27
26
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
RO
0
25
24
23
22
21
20
19
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
10
9
8
7
6
5
4
3
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
RO
0
I2C0
RO
0
R/W
0
reserved
RO
0
SSI0
R/W
0
18
17
16
TIMER2
TIMER1
TIMER0
R/W
0
R/W
0
R/W
0
2
1
0
UART1
UART0
R/W
0
R/W
0
reserved
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:19
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
18
TIMER2
R/W
0
Timer 2 Reset Control
Reset control for General-Purpose Timer module 2.
17
TIMER1
R/W
0
Timer 1 Reset Control
Reset control for General-Purpose Timer module 1.
16
TIMER0
R/W
0
Timer 0 Reset Control
Reset control for General-Purpose Timer module 0.
15:13
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
12
I2C0
R/W
0
I2C0 Reset Control
Reset control for I2C unit 0.
11:5
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
4
SSI0
R/W
0
SSI0 Reset Control
Reset control for SSI unit 0.
3:2
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
1
UART1
R/W
0
UART1 Reset Control
Reset control for UART unit 1.
0
UART0
R/W
0
UART0 Reset Control
Reset control for UART unit 0.
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Register 30: Software Reset Control 2 (SRCR2), offset 0x048
Writes to this register are masked by the bits in the Device Capabilities 4 (DC4) register.
Software Reset Control 2 (SRCR2)
Base 0x400F.E000
Offset 0x048
Type R/W, reset 0x00000000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
GPIOE
GPIOD
GPIOC
GPIOB
GPIOA
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
Bit/Field
Name
Type
Reset
Description
31:5
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
4
GPIOE
R/W
0
Port E Reset Control
Reset control for GPIO Port E.
3
GPIOD
R/W
0
Port D Reset Control
Reset control for GPIO Port D.
2
GPIOC
R/W
0
Port C Reset Control
Reset control for GPIO Port C.
1
GPIOB
R/W
0
Port B Reset Control
Reset control for GPIO Port B.
0
GPIOA
R/W
0
Port A Reset Control
Reset control for GPIO Port A.
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Internal Memory
6
Internal Memory
The LM3S828 microcontroller comes with 8 KB of bit-banded SRAM and 64 KB of flash memory.
The flash controller provides a user-friendly interface, making flash programming a simple task.
Flash protection can be applied to the flash memory on a 2-KB block basis.
6.1
Block Diagram
Figure 6-1 on page 206 illustrates the Flash functions. The dashed boxes in the figure indicate
registers residing in the System Control module rather than the Flash Control module.
Figure 6-1. Flash Block Diagram
Flash Control
Icode Bus
Cortex-M3
System
Bus
Dcode Bus
FMA
FMD
FMC
FCRIS
FCIM
FCMISC
Flash Array
Flash Protection
Bridge
FMPRE
FMPPE
Flash Timing
USECRL
SRAM Array
6.2
Functional Description
This section describes the functionality of the SRAM and Flash memories.
6.2.1
SRAM Memory
®
The internal SRAM of the Stellaris devices is located at address 0x2000.0000 of the device memory
map. To reduce the number of time consuming read-modify-write (RMW) operations, ARM has
introduced bit-banding technology in the Cortex-M3 processor. With a bit-band-enabled processor,
certain regions in the memory map (SRAM and peripheral space) can use address aliases to access
individual bits in a single, atomic operation.
The bit-band alias is calculated by using the formula:
bit-band alias = bit-band base + (byte offset * 32) + (bit number * 4)
For example, if bit 3 at address 0x2000.1000 is to be modified, the bit-band alias is calculated as:
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0x2200.0000 + (0x1000 * 32) + (3 * 4) = 0x2202.000C
With the alias address calculated, an instruction performing a read/write to address 0x2202.000C
allows direct access to only bit 3 of the byte at address 0x2000.1000.
For details about bit-banding, see “Bit-Banding” on page 63.
6.2.2
Flash Memory
The flash is organized as a set of 1-KB blocks that can be individually erased. Erasing a block
causes the entire contents of the block to be reset to all 1s. An individual 32-bit word can be
programmed to change bits that are currently 1 to a 0. These blocks are paired into a set of 2-KB
blocks that can be individually protected. The protection allows blocks to be marked as read-only
or execute-only, providing different levels of code protection. Read-only blocks cannot be erased
or programmed, protecting the contents of those blocks from being modified. Execute-only blocks
cannot be erased or programmed, and can only be read by the controller instruction fetch mechanism,
protecting the contents of those blocks from being read by either the controller or by a debugger.
See also “Serial Flash Loader” on page 497 for a preprogrammed flash-resident utility used to
download code to the flash memory of a device without the use of a debug interface.
6.2.2.1
Flash Memory Timing
The timing for the flash is automatically handled by the flash controller. However, in order to do so,
it must know the clock rate of the system in order to time its internal signals properly. The number
of clock cycles per microsecond must be provided to the flash controller for it to accomplish this
timing. It is software's responsibility to keep the flash controller updated with this information via the
USec Reload (USECRL) register.
On reset, the USECRL register is loaded with a value that configures the flash timing so that it works
with the maximum clock rate of the part. If software changes the system operating frequency, the
new operating frequency minus 1 (in MHz) must be loaded into USECRL before any flash
modifications are attempted. For example, if the device is operating at a speed of 20 MHz, a value
of 0x13 (20-1) must be written to the USECRL register.
6.2.2.2
Flash Memory Protection
The user is provided two forms of flash protection per 2-KB flash blocks in two 32-bit wide
registers.The protection policy for each form is controlled by individual bits (per policy per block) in
the FMPPEn and FMPREn registers.
■ Flash Memory Protection Program Enable (FMPPEn): If set, the block may be programmed
(written) or erased. If cleared, the block may not be changed.
■ Flash Memory Protection Read Enable (FMPREn): If a bit is set, the corresponding block may
be executed or read by software or debuggers. If a bit is cleared, the corresponding block may
only be executed, and contents of the memory block are prohibited from being read as data.
The policies may be combined as shown in Table 6-1 on page 207.
Table 6-1. Flash Protection Policy Combinations
FMPPEn
FMPREn
0
0
Protection
Execute-only protection. The block may only be executed and may not be written or erased.
This mode is used to protect code.
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Internal Memory
Table 6-1. Flash Protection Policy Combinations (continued)
FMPPEn
FMPREn
Protection
1
0
The block may be written, erased or executed, but not read. This combination is unlikely to
be used.
0
1
Read-only protection. The block may be read or executed but may not be written or erased.
This mode is used to lock the block from further modification while allowing any read or
execute access.
1
1
No protection. The block may be written, erased, executed or read.
A Flash memory access that attempts to read a read-protected block (FMPREn bit is set) is prohibited
and generates a bus fault. A Flash memory access that attempts to program or erase a
program-protected block (FMPPEn bit is set) is prohibited and can optionally generate an interrupt
(by setting the AMASK bit in the Flash Controller Interrupt Mask (FCIM) register) to alert software
developers of poorly behaving software during the development and debug phases.
The factory settings for the FMPREn and FMPPEn registers are a value of 1 for all implemented
banks. These settings create a policy of open access and programmability. The register bits may
be changed by clearing the specific register bit. The changes are not permanent until the register
is committed (saved), at which point the bit change is permanent. If a bit is changed from a 1 to a
0 and not committed, it may be restored by executing a power-on reset sequence. The changes
are committed using the Flash Memory Control (FMC) register.
6.2.2.3
Interrupts
The Flash memory controller can generate interrupts when the following conditions are observed:
■ Programming Interrupt - signals when a program or erase action is complete.
■ Access Interrupt - signals when a program or erase action has been attempted on a 2-kB block
of memory that is protected by its corresponding FMPPEn bit.
The interrupt events that can trigger a controller-level interrupt are defined in the Flash Controller
Masked Interrupt Status (FCMIS) register (see page 217) by setting the corresponding MASK bits.
If interrupts are not used, the raw interrupt status is always visible via the Flash Controller Raw
Interrupt Status (FCRIS) register (see page 216).
Interrupts are always cleared (for both the FCMIS and FCRIS registers) by writing a 1 to the
corresponding bit in the Flash Controller Masked Interrupt Status and Clear (FCMISC) register
(see page 218).
6.2.2.4
Flash Memory Protection by Disabling Debug Access
Flash memory may also be protected by permanently disabling access to the Debug Access Port
(DAP) through the JTAG and SWD interfaces. Access is disabled by clearing the DBG field of the
FMPRE register.
If the DBG field in the Flash Memory Protection Read Enable (FMPRE) register is programmed
to 0x2, access to the DAP is enabled through the JTAG and SWD interfaces. If clear, access to the
DAP is disabled. The DBG field programming becomes permanent and irreversible after a commit
sequence is performed.
In the initial state provided from the factory, access is enabled in order to facilitate code development
and debug. Access to the DAP may be disabled at the end of the manufacturing flow, once all tests
have passed and software has been loaded. This change does not take effect until the next power-up
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of the device. Note that it is recommended that disabling access to the DAP be combined with a
mechanism for providing end-user installable updates (if necessary) such as the Stellaris boot loader.
Important: Once the DBG field is cleared and committed, this field can never be restored to the
factory-programmed value—which means the JTAG/SWD interface to the debug module
can never be re-enabled. This sequence does NOT disable the JTAG controller, it only
disables the access of the DAP through the JTAG or SWD interfaces. The JTAG interface
remains functional and access to the Test Access Port remains enabled, allowing the
user to execute the IEEE JTAG-defined instructions (for example, to perform boundary
scan operations).
When using the FMPRE bits to protect Flash memory from being read as data (to mark sets of 2-KB
blocks of Flash memory as execute-only), these one-time-programmable bits should be written at
the same time that the debug disable bits are programmed. Mechanisms to execute the one-time
code sequence to disable all debug access include:
■ Selecting the debug disable option in the Stellaris boot loader
■ Loading the debug disable sequence into SRAM and running it once from SRAM after
programming the final end application code into Flash memory
6.3
Flash Memory Initialization and Configuration
This section shows examples for using the flash controller to perform various operations on the
contents of the flash memory.
6.3.1
Changing Flash Protection Bits
As discussed in “Flash Memory Protection” on page 207, changes to the protection bits must be
committed before they take effect. The sequence below is used change and commit a block protection
bit in the FMPRE or FMPPE registers. The sequence to change and commit a bit in software is as
follows:
1. The Flash Memory Protection Read Enable (FMPRE) and Flash Memory Protection Program
Enable (FMPPE) registers are written, changing the intended bit(s). The action of these changes
can be tested by software while in this state.
2. The Flash Memory Address (FMA) register (see page 212) bit 0 is set to 1 if the FMPPE register
is to be committed; otherwise, a 0 commits the FMPRE register.
3. The Flash Memory Control (FMC) register (see page 214) is written with the COMT bit set. This
initiates a write sequence and commits the changes.
There is a special sequence to change and commit the DBG bits in the Flash Memory Protection
Read Enable (FMPRE) register. This sequence also sets and commits any changes from 1 to 0 in
the block protection bits (for execute-only) in the FMPRE register.
1. The Flash Memory Protection Read Enable (FMPRE) register is written, changing the intended
bit(s). The action of these changes can be tested by software while in this state.
2. The Flash Memory Address (FMA) register (see page 212) is written with a value of 0x900.
3. The Flash Memory Control (FMC) register (see page 214) is written with the COMT bit set. This
initiates a write sequence and commits the changes.
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Below is an example code sequence to permanently disable the JTAG and SWD interface to the
debug module using DriverLib:
#include "hw_types.h"
#include "hw_flash.h"
void
permanently_disable_jtag_swd(void)
{
//
// Clear the DBG field of the FMPRE register. Note that the value
// used in this instance does not affect the state of the BlockN
// bits, but were the value different, all bits in the FMPRE are
// affected by this function!
//
HWREG(FLASH_FMPRE) &= 0x3fffffff;
//
// The following sequence activates the one-time
// programming of the FMPRE register.
//
HWREG(FLASH_FMA) = 0x900;
HWREG(FLASH_FMC) = (FLASH_FMC_WRKEY | FLASH_FMC_COMT);
//
// Wait until the operation is complete.
//
while (HWREG(FLASH_FMC) & FLASH_FMC_COMT)
{
}
}
6.3.2
Flash Programming
The Stellaris devices provide a user-friendly interface for flash programming. All erase/program
operations are handled via three registers: FMA, FMD, and FMC.
During a Flash memory operation (write, page erase, or mass erase) access to the Flash memory
is inhibited. As a result, instruction and literal fetches are held off until the Flash memory operation
is complete. If instruction execution is required during a Flash memory operation, the code that is
executing must be placed in SRAM and executed from there while the flash operation is in progress.
6.3.2.1
To program a 32-bit word
1. Write source data to the FMD register.
2. Write the target address to the FMA register.
3. Write the flash write key and the WRITE bit (a value of 0xA442.0001) to the FMC register.
4. Poll the FMC register until the WRITE bit is cleared.
6.3.2.2
To perform an erase of a 1-KB page
1. Write the page address to the FMA register.
2. Write the flash write key and the ERASE bit (a value of 0xA442.0002) to the FMC register.
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3. Poll the FMC register until the ERASE bit is cleared.
6.3.2.3
To perform a mass erase of the flash
1. Write the flash write key and the MERASE bit (a value of 0xA442.0004) to the FMC register.
2. Poll the FMC register until the MERASE bit is cleared.
6.4
Register Map
Table 6-2 on page 211 lists the Flash memory and control registers. The offset listed is a hexadecimal
increment to the register's address. The FMA, FMD, FMC, FCRIS, FCIM, and FCMISC register
offsets are relative to the Flash memory control base address of 0x400F.D000. The Flash memory
protection register offsets are relative to the System Control base address of 0x400F.E000.
Table 6-2. Flash Register Map
Offset
Name
Type
Reset
Description
See
page
Flash Memory Control Registers (Flash Control Offset)
0x000
FMA
R/W
0x0000.0000
Flash Memory Address
212
0x004
FMD
R/W
0x0000.0000
Flash Memory Data
213
0x008
FMC
R/W
0x0000.0000
Flash Memory Control
214
0x00C
FCRIS
RO
0x0000.0000
Flash Controller Raw Interrupt Status
216
0x010
FCIM
R/W
0x0000.0000
Flash Controller Interrupt Mask
217
0x014
FCMISC
R/W1C
0x0000.0000
Flash Controller Masked Interrupt Status and Clear
218
Flash Memory Protection Registers (System Control Offset)
0x130
FMPRE
R/W
0xBFFF.FFFF
Flash Memory Protection Read Enable
221
0x134
FMPPE
R/W
0xFFFF.FFFF
Flash Memory Protection Program Enable
222
0x140
USECRL
R/W
0x31
USec Reload
220
6.5
Flash Register Descriptions (Flash Control Offset)
This section lists and describes the Flash Memory registers, in numerical order by address offset.
Registers in this section are relative to the Flash control base address of 0x400F.D000.
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Register 1: Flash Memory Address (FMA), offset 0x000
During a write operation, this register contains a 4-byte-aligned address and specifies where the
data is written. During erase operations, this register contains a 1 KB-aligned address and specifies
which page is erased. Note that the alignment requirements must be met by software or the results
of the operation are unpredictable.
Flash Memory Address (FMA)
Base 0x400F.D000
Offset 0x000
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
OFFSET
Type
Reset
Bit/Field
Name
Type
Reset
Description
31:16
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
15:0
OFFSET
R/W
0x0
Address Offset
Address offset in flash where operation is performed.
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Register 2: Flash Memory Data (FMD), offset 0x004
This register contains the data to be written during the programming cycle or read during the read
cycle. Note that the contents of this register are undefined for a read access of an execute-only
block. This register is not used during the erase cycles.
Flash Memory Data (FMD)
Base 0x400F.D000
Offset 0x004
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
DATA
Type
Reset
DATA
Type
Reset
Bit/Field
Name
Type
Reset
Description
31:0
DATA
R/W
0x0
Data Value
Data value for write operation.
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Register 3: Flash Memory Control (FMC), offset 0x008
When this register is written, the flash controller initiates the appropriate access cycle for the location
specified by the Flash Memory Address (FMA) register (see page 212). If the access is a write
access, the data contained in the Flash Memory Data (FMD) register (see page 213) is written.
This is the final register written and initiates the memory operation. There are four control bits in the
lower byte of this register that, when set, initiate the memory operation. The most used of these
register bits are the ERASE and WRITE bits.
It is a programming error to write multiple control bits and the results of such an operation are
unpredictable.
Flash Memory Control (FMC)
Base 0x400F.D000
Offset 0x008
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
COMT
MERASE
ERASE
WRITE
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
WRKEY
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
31:16
WRKEY
WO
0x0
Description
Flash Write Key
This field contains a write key, which is used to minimize the incidence
of accidental flash writes. The value 0xA442 must be written into this
field for a write to occur. Writes to the FMC register without this WRKEY
value are ignored. A read of this field returns the value 0.
15:4
reserved
RO
0x0
3
COMT
R/W
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Commit Register Value
Commit (write) of register value to nonvolatile storage. A write of 0 has
no effect on the state of this bit.
If read, the state of the previous commit access is provided. If the
previous commit access is complete, a 0 is returned; otherwise, if the
commit access is not complete, a 1 is returned.
This can take up to 50 μs.
2
MERASE
R/W
0
Mass Erase Flash Memory
If this bit is set, the flash main memory of the device is all erased. A
write of 0 has no effect on the state of this bit.
If read, the state of the previous mass erase access is provided. If the
previous mass erase access is complete, a 0 is returned; otherwise, if
the previous mass erase access is not complete, a 1 is returned.
This can take up to 250 ms.
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Bit/Field
Name
Type
Reset
1
ERASE
R/W
0
Description
Erase a Page of Flash Memory
If this bit is set, the page of flash main memory as specified by the
contents of FMA is erased. A write of 0 has no effect on the state of this
bit.
If read, the state of the previous erase access is provided. If the previous
erase access is complete, a 0 is returned; otherwise, if the previous
erase access is not complete, a 1 is returned.
This can take up to 25 ms.
0
WRITE
R/W
0
Write a Word into Flash Memory
If this bit is set, the data stored in FMD is written into the location as
specified by the contents of FMA. A write of 0 has no effect on the state
of this bit.
If read, the state of the previous write update is provided. If the previous
write access is complete, a 0 is returned; otherwise, if the write access
is not complete, a 1 is returned.
This can take up to 50 µs.
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Register 4: Flash Controller Raw Interrupt Status (FCRIS), offset 0x00C
This register indicates that the flash controller has an interrupt condition. An interrupt is only signaled
if the corresponding FCIM register bit is set.
Flash Controller Raw Interrupt Status (FCRIS)
Base 0x400F.D000
Offset 0x00C
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
PRIS
ARIS
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
31:2
reserved
RO
0x0
1
PRIS
RO
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Programming Raw Interrupt Status
This bit provides status on programming cycles which are write or erase
actions generated through the FMC register bits (see page 214).
Value Description
1
The programming cycle has completed.
0
The programming cycle has not completed.
This status is sent to the interrupt controller when the PMASK bit in the
FCIM register is set.
This bit is cleared by writing a 1 to the PMISC bit in the FCMISC register.
0
ARIS
RO
0
Access Raw Interrupt Status
Value Description
1
A program or erase action was attempted on a block of Flash
memory that contradicts the protection policy for that block as
set in the FMPPEn registers.
0
No access has tried to improperly program or erase the Flash
memory.
This status is sent to the interrupt controller when the AMASK bit in the
FCIM register is set.
This bit is cleared by writing a 1 to the AMISC bit in the FCMISC register.
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Register 5: Flash Controller Interrupt Mask (FCIM), offset 0x010
This register controls whether the flash controller generates interrupts to the controller.
Flash Controller Interrupt Mask (FCIM)
Base 0x400F.D000
Offset 0x010
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
PMASK
AMASK
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
31:2
reserved
RO
0x0
1
PMASK
R/W
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Programming Interrupt Mask
This bit controls the reporting of the programming raw interrupt status
to the interrupt controller.
Value Description
0
AMASK
R/W
0
1
An interrupt is sent to the interrupt controller when the PRIS bit
is set.
0
The PRIS interrupt is suppressed and not sent to the interrupt
controller.
Access Interrupt Mask
This bit controls the reporting of the access raw interrupt status to the
interrupt controller.
Value Description
1
An interrupt is sent to the interrupt controller when the ARIS bit
is set.
0
The ARIS interrupt is suppressed and not sent to the interrupt
controller.
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Register 6: Flash Controller Masked Interrupt Status and Clear (FCMISC),
offset 0x014
This register provides two functions. First, it reports the cause of an interrupt by indicating which
interrupt source or sources are signalling the interrupt. Second, it serves as the method to clear the
interrupt reporting.
Flash Controller Masked Interrupt Status and Clear (FCMISC)
Base 0x400F.D000
Offset 0x014
Type R/W1C, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
3
2
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
31:2
reserved
RO
0x0
1
PMISC
R/W1C
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
1
0
PMISC
AMISC
R/W1C
0
R/W1C
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Programming Masked Interrupt Status and Clear
Value Description
1
When read, a 1 indicates that an unmasked interrupt was
signaled because a programming cycle completed.
Writing a 1 to this bit clears PMISC and also the PRIS bit in the
FCRIS register (see page 216).
0
When read, a 0 indicates that a programming cycle complete
interrupt has not occurred.
A write of 0 has no effect on the state of this bit.
0
AMISC
R/W1C
0
Access Masked Interrupt Status and Clear
Value Description
1
When read, a 1 indicates that an unmasked interrupt was
signaled because a program or erase action was attempted on
a block of Flash memory that contradicts the protection policy
for that block as set in the FMPPEn registers.
Writing a 1 to this bit clears AMISC and also the ARIS bit in the
FCRIS register (see page 216).
0
When read, a 0 indicates that no improper accesses have
occurred.
A write of 0 has no effect on the state of this bit.
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6.6
Flash Register Descriptions (System Control Offset)
The remainder of this section lists and describes the Flash Memory registers, in numerical order by
address offset. Registers in this section are relative to the System Control base address of
0x400F.E000.
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Register 7: USec Reload (USECRL), offset 0x140
Note:
Offset is relative to System Control base address of 0x400F.E000
This register is provided as a means of creating a 1-μs tick divider reload value for the flash controller.
The internal flash has specific minimum and maximum requirements on the length of time the high
voltage write pulse can be applied. It is required that this register contain the operating frequency
(in MHz -1) whenever the flash is being erased or programmed. The user is required to change this
value if the clocking conditions are changed for a flash erase/program operation.
USec Reload (USECRL)
Base 0x400F.E000
Offset 0x140
Type R/W, reset 0x31
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
1
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
USEC
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
1
R/W
1
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
USEC
R/W
0x31
Microsecond Reload Value
MHz -1 of the controller clock when the flash is being erased or
programmed.
If the maximum system frequency is being used, USEC should be set to
0x31 (50 MHz) whenever the flash is being erased or programmed.
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Register 8: Flash Memory Protection Read Enable (FMPRE), offset 0x130
Note:
Offset is relative to System Control base address of 0x400FE000.
This register stores the read-only protection bits for each 2-KB flash block (see the FMPPE registers
for the execute-only protection bits). This register is loaded during the power-on reset sequence.
The factory settingsare a value of 1 for all implemented banks. This implements a policy of open
access and programmability. The register bits may be changed by writing the specific register bit.
However, this register is R/W0; the user can only change the protection bit from a 1 to a 0 (and may
NOT change a 0 to a 1). The changes are not permanent until the register is committed (saved), at
which point the bit change is permanent. If a bit is changed from a 1 to a 0 and not committed, it
may be restored by executing a power-on reset sequence. For additional information, see the “Flash
Memory Protection” section.
Flash Memory Protection Read Enable (FMPRE)
Base 0x400F.E000
Offset 0x130
Type R/W, reset 0xBFFF.FFFF
31
30
29
28
27
26
25
24
DBG
Type
Reset
23
22
21
20
19
18
17
16
READ_ENABLE
R/W
1
R/W
0
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
15
14
13
12
11
10
9
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
8
7
6
5
4
3
2
1
0
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
READ_ENABLE
Type
Reset
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
Bit/Field
Name
Type
Reset
31:30
DBG
R/W
0x2
R/W
1
R/W
1
Description
User Controlled Debug Enable
Each bit position maps 2 Kbytes of Flash to be read-enabled.
Value Description
0x2
29:0
READ_ENABLE
R/W
Debug access allowed
0x3FFFFFFF Flash Read Enable
Each bit position maps 2 Kbytes of Flash to be read-enabled.
Value
Description
0x3FFFFFFF Enables 64 KB of flash.
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Register 9: Flash Memory Protection Program Enable (FMPPE), offset 0x134
Note:
Offset is relative to System Control base address of 0x400FE000.
This register stores the execute-only protection bits for each 2-KB flash block (see the FMPRE
registers for the read-only protection bits). This register is loaded during the power-on reset sequence.
The factory settings are a value of 1 for all implemented banks. This implements a policy of open
access and programmability. The register bits may be changed by writing the specific register bit.
However, this register is R/W0; the user can only change the protection bit from a 1 to a 0 (and may
NOT change a 0 to a 1). The changes are not permanent until the register is committed (saved), at
which point the bit change is permanent. If a bit is changed from a 1 to a 0 and not committed, it
may be restored by executing a power-on reset sequence. For additional information, see the “Flash
Memory Protection” section.
Flash Memory Protection Program Enable (FMPPE)
Base 0x400F.E000
Offset 0x134
Type R/W, reset 0xFFFF.FFFF
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
PROG_ENABLE
Type
Reset
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
15
14
13
12
11
10
9
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
8
7
6
5
4
3
2
1
0
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
PROG_ENABLE
Type
Reset
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
Bit/Field
Name
Type
31:0
PROG_ENABLE
R/W
R/W
1
Reset
R/W
1
R/W
1
Description
0xFFFFFFFF Flash Programming Enable
Each bit position maps 2 Kbytes of Flash to be write-enabled.
Value
Description
0xFFFFFFFF Enables 64 KB of flash.
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7
General-Purpose Input/Outputs (GPIOs)
The GPIO module is composed of five physical GPIO blocks, each corresponding to an individual
GPIO port (Port A, Port B, Port C, Port D, Port E). The GPIO module supports 7-28 programmable
input/output pins, depending on the peripherals being used.
The GPIO module has the following features:
■ 7-28 GPIOs, depending on configuration
■ 5-V-tolerant in input configuration
■ Fast toggle capable of a change every two clock cycles
■ Programmable control for GPIO interrupts
– Interrupt generation masking
– Edge-triggered on rising, falling, or both
– Level-sensitive on High or Low values
■ Bit masking in both read and write operations through address lines
■ Can initiate an ADC sample sequence
■ Pins configured as digital inputs are Schmitt-triggered.
■ Programmable control for GPIO pad configuration
– Weak pull-up or pull-down resistors
– 2-mA, 4-mA, and 8-mA pad drive for digital communication
– Slew rate control for the 8-mA drive
– Open drain enables
– Digital input enables
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7.1
Block Diagram
U0Rx
PA1
U0Tx
PA4
SSIClk
SSIFss
U1Rx
U1Tx
UART1
CCP0
Timer0
CCP1
PB1
CCP2
Timer1
CCP3
PB2
I2CSCL
PB4
PB5
GPIO Port B
PB0
PB3
I2CSDA
PE1
SSI
SSIRx
SSITx
PA5
PE0
2
IC
TRST
PD0
GPIO Port D
PA3
UART0
PD1
PD2
PD3
TCK/SWCLK
PC0
TMS/SWDIO
PC1
TDI
PC2
JTAG
GPIO Port C
PA2
GPIO Port A
PA0
GPIO Port E
Figure 7-1. GPIO Module Block Diagram
TDO/SWO
PB6
PC3
PC4
PC5
PB7
PC6
CCP5
7.2
Timer2
CCP4
PC7
Signal Description
GPIO signals have alternate hardware functions. Table 7-3 on page 225 lists the GPIO pins and their
analog and digital alternate functions. The AINx analog signals are not 5-V tolerant and go through
an isolation circuit before reaching their circuitry. These signals are configured by clearing the
corresponding DEN bit in the GPIO Digital Enable (GPIODEN) register and setting the corresponding
AMSEL bit in the GPIO Analog Mode Select (GPIOAMSEL) register. The digital alternate hardware
functions are enabled by setting the appropriate bit in the GPIO Alternate Function Select
(GPIOAFSEL) and GPIODEN registers and configuring the PMCx bit field in the GPIO Port Control
(GPIOPCTL) register to the numeric enoding shown in the table below. Note that each pin must be
programmed individually; no type of grouping is implied by the columns in the table.
Important: All GPIO pins are configured as GPIOs and tri-stated by default (GPIOAFSEL=0,
GPIODEN=0, GPIOPDR=0, GPIOPUR=0, and GPIOPCTL=0, with the exception of the
four JTAG/SWD pins (shown in the table below). A Power-On-Reset (POR) or asserting
RST puts the pins back to their default state.
Table 7-1. GPIO Pins With Non-Zero Reset Values
GPIO Pins
Default State
GPIOAFSEL GPIODEN GPIOPDR GPIOPUR
PA[1:0]
UART0
1
1
0
0
0x1
PA[5:2]
SSI0
1
1
0
0
0x1
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Table 7-1. GPIO Pins With Non-Zero Reset Values (continued)
GPIO Pins
Default State
PB[3:2]
I2C0
GPIOAFSEL GPIODEN GPIOPDR GPIOPUR
1
1
0
0
GPIOPCTL
0x1
PC[3:0]
JTAG/SWD
1
1
0
1
0x3
Table 7-2. GPIO Pins and Alternate Functions (48QFP)
IO
Pin Number
Multiplexed Function
PA0
17
U0Rx
PA1
18
U0Tx
PA2
19
SSIClk
Multiplexed Function
PA3
20
SSIFss
PA4
21
SSIRx
PA5
22
SSITx
PB0
29
CCP0
PB1
30
CCP2
PB2
33
I2CSCL
PB3
34
I2CSDA
PB4
44
PB5
43
PB6
42
PB7
41
TRST
PC0
40
TCK
SWCLK
PC1
39
TMS
SWDIO
PC2
38
TDI
PC3
37
TDO
PC4
14
PC5
13
CCP1
PC6
12
CCP3
CCP4
CCP5
PC7
11
PD0
25
PD1
26
PD2
27
U1Rx
PD3
28
U1Tx
PE0
35
PE1
36
SWO
Table 7-3. GPIO Signals (48QFP)
a
Pin Name
Pin Number
Pin Type
Buffer Type
Description
PA0
17
I/O
TTL
GPIO port A bit 0.
PA1
18
I/O
TTL
GPIO port A bit 1.
PA2
19
I/O
TTL
GPIO port A bit 2.
PA3
20
I/O
TTL
GPIO port A bit 3.
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Table 7-3. GPIO Signals (48QFP) (continued)
a
Pin Name
Pin Number
Pin Type
Buffer Type
Description
PA4
21
I/O
TTL
GPIO port A bit 4.
PA5
22
I/O
TTL
GPIO port A bit 5.
PB0
29
I/O
TTL
GPIO port B bit 0.
PB1
30
I/O
TTL
GPIO port B bit 1.
PB2
33
I/O
TTL
GPIO port B bit 2.
PB3
34
I/O
TTL
GPIO port B bit 3.
PB4
44
I/O
TTL
GPIO port B bit 4.
PB5
43
I/O
TTL
GPIO port B bit 5.
PB6
42
I/O
TTL
GPIO port B bit 6.
PB7
41
I/O
TTL
GPIO port B bit 7.
PC0
40
I/O
TTL
GPIO port C bit 0.
PC1
39
I/O
TTL
GPIO port C bit 1.
PC2
38
I/O
TTL
GPIO port C bit 2.
PC3
37
I/O
TTL
GPIO port C bit 3.
PC4
14
I/O
TTL
GPIO port C bit 4.
PC5
13
I/O
TTL
GPIO port C bit 5.
PC6
12
I/O
TTL
GPIO port C bit 6.
PC7
11
I/O
TTL
GPIO port C bit 7.
PD0
25
I/O
TTL
GPIO port D bit 0.
PD1
26
I/O
TTL
GPIO port D bit 1.
PD2
27
I/O
TTL
GPIO port D bit 2.
PD3
28
I/O
TTL
GPIO port D bit 3.
PE0
35
I/O
TTL
GPIO port E bit 0.
PE1
36
I/O
TTL
GPIO port E bit 1.
a. The TTL designation indicates the pin has TTL-compatible voltage levels.
7.3
Functional Description
Important: All GPIO pins are inputs by default (GPIODIR=0 and GPIOAFSEL=0), with the exception
of the five JTAG pins (PB7 and PC[3:0]). The JTAG pins default to their JTAG
functionality (GPIOAFSEL=1). A Power-On-Reset (POR) or asserting an external reset
(RST) puts both groups of pins back to their default state.
While debugging systems where PB7 is being used as a GPIO, care must be taken to
ensure that a Low value is not applied to the pin when the part is reset. Because PB7
reverts to the TRST function after reset, a Low value on the pin causes the JTAG
controller to be reset, resulting in a loss of JTAG communication.
Each GPIO port is a separate hardware instantiation of the same physical block (see Figure
7-2 on page 227). The LM3S828 microcontroller contains five ports and thus five of these physical
GPIO blocks.
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Figure 7-2. GPIO Port Block Diagram
Mode
Control
GPIOAFSEL
DEMUX
Alternate Input
Alternate Output
Pad Input
Alternate Output Enable
Pad Output
MUX
Pad Output Enable
Digital
I/O Pad
Package I/O Pin
GPIO Output
GPIODATA
GPIODIR
Interrupt
MUX
GPIO Input
Data
Control
GPIO Output Enable
Interrupt
Control
Pad
Control
GPIOIS
GPIOIBE
GPIOIEV
GPIOIM
GPIORIS
GPIOMIS
GPIOICR
GPIODR2R
GPIODR4R
GPIODR8R
GPIOSLR
GPIOPUR
GPIOPDR
GPIOODR
GPIODEN
Identification Registers
GPIOPeriphID0
GPIOPeriphID1
GPIOPeriphID2
GPIOPeriphID3
7.3.1
GPIOPeriphID4
GPIOPeriphID5
GPIOPeriphID6
GPIOPeriphID7
GPIOPCellID0
GPIOPCellID1
GPIOPCellID2
GPIOPCellID3
Data Control
The data control registers allow software to configure the operational modes of the GPIOs. The data
direction register configures the GPIO as an input or an output while the data register either captures
incoming data or drives it out to the pads.
7.3.1.1
Data Direction Operation
The GPIO Direction (GPIODIR) register (see page 234) is used to configure each individual pin as
an input or output. When the data direction bit is set to 0, the GPIO is configured as an input and
the corresponding data register bit will capture and store the value on the GPIO port. When the data
direction bit is set to 1, the GPIO is configured as an output and the corresponding data register bit
will be driven out on the GPIO port.
7.3.1.2
Data Register Operation
To aid in the efficiency of software, the GPIO ports allow for the modification of individual bits in the
GPIO Data (GPIODATA) register (see page 233) by using bits [9:2] of the address bus as a mask.
This allows software drivers to modify individual GPIO pins in a single instruction, without affecting
the state of the other pins. This is in contrast to the "typical" method of doing a read-modify-write
operation to set or clear an individual GPIO pin. To accommodate this feature, the GPIODATA
register covers 256 locations in the memory map.
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During a write, if the address bit associated with that data bit is set to 1, the value of the GPIODATA
register is altered. If it is cleared to 0, it is left unchanged.
For example, writing a value of 0xEB to the address GPIODATA + 0x098 would yield as shown in
Figure 7-3 on page 228, where u is data unchanged by the write.
Figure 7-3. GPIODATA Write Example
ADDR[9:2]
0x098
9
8
7
6
5
4
3
2
1
0
0
0
1
0
0
1
1
0
0
0
0xEB
1
1
1
0
1
0
1
1
GPIODATA
u
u
1
u
u
0
1
u
7
6
5
4
3
2
1
0
During a read, if the address bit associated with the data bit is set to 1, the value is read. If the
address bit associated with the data bit is set to 0, it is read as a zero, regardless of its actual value.
For example, reading address GPIODATA + 0x0C4 yields as shown in Figure 7-4 on page 228.
Figure 7-4. GPIODATA Read Example
7.3.2
ADDR[9:2]
0x0C4
9
8
7
6
5
4
3
2
1
0
0
0
1
1
0
0
0
1
0
0
GPIODATA
1
0
1
1
1
1
1
0
Returned Value
0
0
1
1
0
0
0
0
7
6
5
4
3
2
1
0
Interrupt Control
The interrupt capabilities of each GPIO port are controlled by a set of seven registers. With these
registers, it is possible to select the source of the interrupt, its polarity, and the edge properties.
When one or more GPIO inputs cause an interrupt, a single interrupt output is sent to the interrupt
controller for the entire GPIO port. For edge-triggered interrupts, software must clear the interrupt
to enable any further interrupts. For a level-sensitive interrupt, it is assumed that the external source
holds the level constant for the interrupt to be recognized by the controller.
Three registers are required to define the edge or sense that causes interrupts:
■ GPIO Interrupt Sense (GPIOIS) register (see page 235)
■ GPIO Interrupt Both Edges (GPIOIBE) register (see page 236)
■ GPIO Interrupt Event (GPIOIEV) register (see page 237)
Interrupts are enabled/disabled via the GPIO Interrupt Mask (GPIOIM) register (see page 238).
When an interrupt condition occurs, the state of the interrupt signal can be viewed in two locations:
the GPIO Raw Interrupt Status (GPIORIS) and GPIO Masked Interrupt Status (GPIOMIS) registers
(see page 239 and page 240). As the name implies, the GPIOMIS register only shows interrupt
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conditions that are allowed to be passed to the controller. The GPIORIS register indicates that a
GPIO pin meets the conditions for an interrupt, but has not necessarily been sent to the controller.
In addition to providing GPIO functionality, PB4 can also be used as an external trigger for the ADC.
If PB4 is configured as a non-masked interrupt pin (the appropriate bit of GPIOIM is set to 1), not
only is an interrupt for PortB generated, but an external trigger signal is sent to the ADC. If the ADC
Event Multiplexer Select (ADCEMUX) register is configured to use the external trigger, an ADC
conversion is initiated.
If no other PortB pins are being used to generate interrupts, the Interrupt 0-31 Set Enable (EN0)
register can disable the PortB interrupts, and the ADC interrupt can be used to read back the
converted data. Otherwise, the PortB interrupt handler needs to ignore and clear interrupts on PB4,
and wait for the ADC interrupt or the ADC interrupt must be disabled in the EN0 register and the
PortB interrupt handler must poll the ADC registers until the conversion is completed. See page 96
for more information.
Interrupts are cleared by writing a 1 to the appropriate bit of the GPIO Interrupt Clear (GPIOICR)
register (see page 241).
When programming the following interrupt control registers, the interrupts should be masked (GPIOIM
set to 0). Writing any value to an interrupt control register (GPIOIS, GPIOIBE, or GPIOIEV) can
generate a spurious interrupt if the corresponding bits are enabled.
7.3.3
Mode Control
The GPIO pins can be controlled by either hardware or software. When hardware control is enabled
via the GPIO Alternate Function Select (GPIOAFSEL) register (see page 242), the pin state is
controlled by its alternate function (that is, the peripheral). Software control corresponds to GPIO
mode, where the GPIODATA register is used to read/write the corresponding pins.
7.3.4
Pad Control
The pad control registers allow for GPIO pad configuration by software based on the application
requirements. The pad control registers include the GPIODR2R, GPIODR4R, GPIODR8R, GPIOODR,
GPIOPUR, GPIOPDR, GPIOSLR, and GPIODEN registers. These registers control drive strength,
open-drain configuration, pull-up and pull-down resistors, slew-rate control and digital enable.
7.3.5
Identification
The identification registers configured at reset allow software to detect and identify the module as
a GPIO block. The identification registers include the GPIOPeriphID0-GPIOPeriphID7 registers as
well as the GPIOPCellID0-GPIOPCellID3 registers.
7.4
Initialization and Configuration
To use the GPIO, the peripheral clock must be enabled by setting the appropriate GPIO Port bit
field (GPIOn) in the RCGC2 register.
On reset, all GPIO pins (except for the five JTAG pins) default to general-purpose input mode
(GPIODIR=0 and GPIOAFSEL=0). Table 7-4 on page 230 shows all possible configurations of the
GPIO pads and the control register settings required to achieve them. Table 7-5 on page 230 shows
how a rising edge interrupt would be configured for pin 2 of a GPIO port.
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Table 7-4. GPIO Pad Configuration Examples
a
GPIO Register Bit Value
Configuration
AFSEL
Digital Input (GPIO)
DIR
0
ODR
0
DEN
0
PUR
1
PDR
?
?
DR2R
DR4R
DR8R
X
X
X
SLR
X
Digital Output (GPIO)
0
1
0
1
?
?
?
?
?
?
Open Drain Output
(GPIO)
0
1
1
1
X
X
?
?
?
?
Open Drain
Input/Output (I2C)
1
X
1
1
X
X
?
?
?
?
Digital Input (Timer
CCP)
1
X
0
1
?
?
X
X
X
X
Digital Output (Timer
PWM)
1
X
0
1
?
?
?
?
?
?
Digital Input/Output
(SSI)
1
X
0
1
?
?
?
?
?
?
Digital Input/Output
(UART)
1
X
0
1
?
?
?
?
?
?
a. X=Ignored (don’t care bit)
?=Can be either 0 or 1, depending on the configuration
Table 7-5. GPIO Interrupt Configuration Example
Register
Desired
Interrupt
Event
Trigger
GPIOIS
0=edge
GPIOIBE
0=single
edge
a
Pin 2 Bit Value
7
6
5
4
3
2
1
0
X
X
X
X
X
0
X
X
X
X
X
X
X
0
X
X
X
X
X
X
X
1
X
X
0
0
0
0
0
1
0
0
1=level
1=both
edges
GPIOIEV
0=Low level,
or negative
edge
1=High level,
or positive
edge
GPIOIM
0=masked
1=not
masked
a. X=Ignored (don’t care bit)
7.5
Register Map
Table 7-6 on page 231 lists the GPIO registers. The offset listed is a hexadecimal increment to the
register’s address, relative to that GPIO port’s base address:
■
■
■
■
GPIO Port A: 0x4000.4000
GPIO Port B: 0x4000.5000
GPIO Port C: 0x4000.6000
GPIO Port D: 0x4000.7000
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■ GPIO Port E: 0x4002.4000
Note that the GPIO module clock must be enabled before the registers can be programmed (see
page 198). There must be a delay of 3 system clocks after the GPIO module clock is enabled before
any GPIO module registers are accessed.
Important: The GPIO registers in this chapter are duplicated in each GPIO block; however,
depending on the block, all eight bits may not be connected to a GPIO pad. In those
cases, writing to those unconnected bits has no effect, and reading those unconnected
bits returns no meaningful data.
Note:
The default reset value for the GPIOAFSEL register is 0x0000.0000 for all GPIO pins, with
the exception of the five JTAG pins (PB7 and PC[3:0]). These five pins default to JTAG
functionality. Because of this, the default reset value of GPIOAFSEL for GPIO Port B is
0x0000.0080 while the default reset value for Port C is 0x0000.000F.
Table 7-6. GPIO Register Map
Description
See
page
Offset
Name
Type
Reset
0x000
GPIODATA
R/W
0x0000.0000
GPIO Data
233
0x400
GPIODIR
R/W
0x0000.0000
GPIO Direction
234
0x404
GPIOIS
R/W
0x0000.0000
GPIO Interrupt Sense
235
0x408
GPIOIBE
R/W
0x0000.0000
GPIO Interrupt Both Edges
236
0x40C
GPIOIEV
R/W
0x0000.0000
GPIO Interrupt Event
237
0x410
GPIOIM
R/W
0x0000.0000
GPIO Interrupt Mask
238
0x414
GPIORIS
RO
0x0000.0000
GPIO Raw Interrupt Status
239
0x418
GPIOMIS
RO
0x0000.0000
GPIO Masked Interrupt Status
240
0x41C
GPIOICR
W1C
0x0000.0000
GPIO Interrupt Clear
241
0x420
GPIOAFSEL
R/W
-
GPIO Alternate Function Select
242
0x500
GPIODR2R
R/W
0x0000.00FF
GPIO 2-mA Drive Select
244
0x504
GPIODR4R
R/W
0x0000.0000
GPIO 4-mA Drive Select
245
0x508
GPIODR8R
R/W
0x0000.0000
GPIO 8-mA Drive Select
246
0x50C
GPIOODR
R/W
0x0000.0000
GPIO Open Drain Select
247
0x510
GPIOPUR
R/W
0x0000.00FF
GPIO Pull-Up Select
248
0x514
GPIOPDR
R/W
0x0000.0000
GPIO Pull-Down Select
249
0x518
GPIOSLR
R/W
0x0000.0000
GPIO Slew Rate Control Select
250
0x51C
GPIODEN
R/W
0x0000.00FF
GPIO Digital Enable
251
0xFD0
GPIOPeriphID4
RO
0x0000.0000
GPIO Peripheral Identification 4
252
0xFD4
GPIOPeriphID5
RO
0x0000.0000
GPIO Peripheral Identification 5
253
0xFD8
GPIOPeriphID6
RO
0x0000.0000
GPIO Peripheral Identification 6
254
0xFDC
GPIOPeriphID7
RO
0x0000.0000
GPIO Peripheral Identification 7
255
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Table 7-6. GPIO Register Map (continued)
Offset
Name
0xFE0
Reset
GPIOPeriphID0
RO
0x0000.0061
GPIO Peripheral Identification 0
256
0xFE4
GPIOPeriphID1
RO
0x0000.0000
GPIO Peripheral Identification 1
257
0xFE8
GPIOPeriphID2
RO
0x0000.0018
GPIO Peripheral Identification 2
258
0xFEC
GPIOPeriphID3
RO
0x0000.0001
GPIO Peripheral Identification 3
259
0xFF0
GPIOPCellID0
RO
0x0000.000D
GPIO PrimeCell Identification 0
260
0xFF4
GPIOPCellID1
RO
0x0000.00F0
GPIO PrimeCell Identification 1
261
0xFF8
GPIOPCellID2
RO
0x0000.0005
GPIO PrimeCell Identification 2
262
0xFFC
GPIOPCellID3
RO
0x0000.00B1
GPIO PrimeCell Identification 3
263
7.6
Description
See
page
Type
Register Descriptions
The remainder of this section lists and describes the GPIO registers, in numerical order by address
offset.
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Register 1: GPIO Data (GPIODATA), offset 0x000
The GPIODATA register is the data register. In software control mode, values written in the
GPIODATA register are transferred onto the GPIO port pins if the respective pins have been
configured as outputs through the GPIO Direction (GPIODIR) register (see page 234).
In order to write to GPIODATA, the corresponding bits in the mask, resulting from the address bus
bits [9:2], must be High. Otherwise, the bit values remain unchanged by the write.
Similarly, the values read from this register are determined for each bit by the mask bit derived from
the address used to access the data register, bits [9:2]. Bits that are 1 in the address mask cause
the corresponding bits in GPIODATA to be read, and bits that are 0 in the address mask cause the
corresponding bits in GPIODATA to be read as 0, regardless of their value.
A read from GPIODATA returns the last bit value written if the respective pins are configured as
outputs, or it returns the value on the corresponding input pin when these are configured as inputs.
All bits are cleared by a reset.
GPIO Data (GPIODATA)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0x000
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
DATA
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
DATA
R/W
0x00
GPIO Data
This register is virtually mapped to 256 locations in the address space.
To facilitate the reading and writing of data to these registers by
independent drivers, the data read from and the data written to the
registers are masked by the eight address lines ipaddr[9:2]. Reads
from this register return its current state. Writes to this register only affect
bits that are not masked by ipaddr[9:2] and are configured as
outputs. See “Data Register Operation” on page 227 for examples of
reads and writes.
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General-Purpose Input/Outputs (GPIOs)
Register 2: GPIO Direction (GPIODIR), offset 0x400
The GPIODIR register is the data direction register. Bits set to 1 in the GPIODIR register configure
the corresponding pin to be an output, while bits set to 0 configure the pins to be inputs. All bits are
cleared by a reset, meaning all GPIO pins are inputs by default.
GPIO Direction (GPIODIR)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0x400
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
DIR
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
DIR
R/W
0x00
GPIO Data Direction
The DIR values are defined as follows:
Value Description
0
Pins are inputs.
1
Pins are outputs.
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Register 3: GPIO Interrupt Sense (GPIOIS), offset 0x404
The GPIOIS register is the interrupt sense register. Bits set to 1 in GPIOIS configure the
corresponding pins to detect levels, while bits set to 0 configure the pins to detect edges. All bits
are cleared by a reset.
GPIO Interrupt Sense (GPIOIS)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0x404
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
IS
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
IS
R/W
0x00
GPIO Interrupt Sense
The IS values are defined as follows:
Value Description
0
Edge on corresponding pin is detected (edge-sensitive).
1
Level on corresponding pin is detected (level-sensitive).
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General-Purpose Input/Outputs (GPIOs)
Register 4: GPIO Interrupt Both Edges (GPIOIBE), offset 0x408
The GPIOIBE register is the interrupt both-edges register. When the corresponding bit in the GPIO
Interrupt Sense (GPIOIS) register (see page 235) is set to detect edges, bits set to High in GPIOIBE
configure the corresponding pin to detect both rising and falling edges, regardless of the
corresponding bit in the GPIO Interrupt Event (GPIOIEV) register (see page 237). Clearing a bit
configures the pin to be controlled by GPIOIEV. All bits are cleared by a reset.
GPIO Interrupt Both Edges (GPIOIBE)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0x408
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
IBE
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
IBE
R/W
0x00
GPIO Interrupt Both Edges
The IBE values are defined as follows:
Value Description
0
Interrupt generation is controlled by the GPIO Interrupt Event
(GPIOIEV) register (see page 237).
1
Both edges on the corresponding pin trigger an interrupt.
Note:
Single edge is determined by the corresponding bit
in GPIOIEV.
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Register 5: GPIO Interrupt Event (GPIOIEV), offset 0x40C
The GPIOIEV register is the interrupt event register. Bits set to High in GPIOIEV configure the
corresponding pin to detect rising edges or high levels, depending on the corresponding bit value
in the GPIO Interrupt Sense (GPIOIS) register (see page 235). Clearing a bit configures the pin to
detect falling edges or low levels, depending on the corresponding bit value in GPIOIS. All bits are
cleared by a reset.
GPIO Interrupt Event (GPIOIEV)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0x40C
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
IEV
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
IEV
R/W
0x00
GPIO Interrupt Event
The IEV values are defined as follows:
Value Description
0
Falling edge or Low levels on corresponding pins trigger
interrupts.
1
Rising edge or High levels on corresponding pins trigger
interrupts.
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General-Purpose Input/Outputs (GPIOs)
Register 6: GPIO Interrupt Mask (GPIOIM), offset 0x410
The GPIOIM register is the interrupt mask register. Bits set to High in GPIOIM allow the corresponding
pins to trigger their individual interrupts and the combined GPIOINTR line. Clearing a bit disables
interrupt triggering on that pin. All bits are cleared by a reset.
GPIO Interrupt Mask (GPIOIM)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0x410
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
IME
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
IME
R/W
0x00
GPIO Interrupt Mask Enable
The IME values are defined as follows:
Value Description
0
Corresponding pin interrupt is masked.
1
Corresponding pin interrupt is not masked.
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Register 7: GPIO Raw Interrupt Status (GPIORIS), offset 0x414
The GPIORIS register is the raw interrupt status register. Bits read High in GPIORIS reflect the
status of interrupt trigger conditions detected (raw, prior to masking), indicating that all the
requirements have been met, before they are finally allowed to trigger by the GPIO Interrupt Mask
(GPIOIM) register (see page 238). Bits read as zero indicate that corresponding input pins have not
initiated an interrupt. All bits are cleared by a reset.
GPIO Raw Interrupt Status (GPIORIS)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0x414
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RIS
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
RIS
RO
0x00
GPIO Interrupt Raw Status
Reflects the status of interrupt trigger condition detection on pins (raw,
prior to masking).
The RIS values are defined as follows:
Value Description
0
Corresponding pin interrupt requirements not met.
1
Corresponding pin interrupt has met requirements.
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General-Purpose Input/Outputs (GPIOs)
Register 8: GPIO Masked Interrupt Status (GPIOMIS), offset 0x418
The GPIOMIS register is the masked interrupt status register. Bits read High in GPIOMIS reflect
the status of input lines triggering an interrupt. Bits read as Low indicate that either no interrupt has
been generated, or the interrupt is masked.
In addition to providing GPIO functionality, PB4 can also be used as an external trigger for the ADC.
If PB4 is configured as a non-masked interrupt pin (the appropriate bit of GPIOIM is set to 1), not
only is an interrupt for PortB generated, but an external trigger signal is sent to the ADC. If the ADC
Event Multiplexer Select (ADCEMUX) register is configured to use the external trigger, an ADC
conversion is initiated.
If no other PortB pins are being used to generate interrupts, the Interrupt 0-31 Set Enable (EN0)
register can disable the PortB interrupts, and the ADC interrupt can be used to read back the
converted data. Otherwise, the PortB interrupt handler needs to ignore and clear interrupts on PB4,
and wait for the ADC interrupt or the ADC interrupt must be disabled in the EN0 register and the
PortB interrupt handler must poll the ADC registers until the conversion is completed. See page 96
for more information.
GPIOMIS is the state of the interrupt after masking.
GPIO Masked Interrupt Status (GPIOMIS)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0x418
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
MIS
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
MIS
RO
0x00
GPIO Masked Interrupt Status
Masked value of interrupt due to corresponding pin.
The MIS values are defined as follows:
Value Description
0
Corresponding GPIO line interrupt not active.
1
Corresponding GPIO line asserting interrupt.
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Register 9: GPIO Interrupt Clear (GPIOICR), offset 0x41C
The GPIOICR register is the interrupt clear register. Writing a 1 to a bit in this register clears the
corresponding interrupt edge detection logic register. Writing a 0 has no effect.
GPIO Interrupt Clear (GPIOICR)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0x41C
Type W1C, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
W1C
0
W1C
0
W1C
0
W1C
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
IC
RO
0
RO
0
RO
0
RO
0
W1C
0
W1C
0
W1C
0
W1C
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
IC
W1C
0x00
GPIO Interrupt Clear
The IC values are defined as follows:
Value Description
0
Corresponding interrupt is unaffected.
1
Corresponding interrupt is cleared.
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General-Purpose Input/Outputs (GPIOs)
Register 10: GPIO Alternate Function Select (GPIOAFSEL), offset 0x420
The GPIOAFSEL register is the mode control select register. Writing a 1 to any bit in this register
selects the hardware control for the corresponding GPIO line. All bits are cleared by a reset, therefore
no GPIO line is set to hardware control by default.
Important: All GPIO pins are inputs by default (GPIODIR=0 and GPIOAFSEL=0), with the exception
of the five JTAG pins (PB7 and PC[3:0]). The JTAG pins default to their JTAG
functionality (GPIOAFSEL=1). A Power-On-Reset (POR) or asserting an external reset
(RST) puts both groups of pins back to their default state.
While debugging systems where PB7 is being used as a GPIO, care must be taken to
ensure that a Low value is not applied to the pin when the part is reset. Because PB7
reverts to the TRST function after reset, a Low value on the pin causes the JTAG
controller to be reset, resulting in a loss of JTAG communication.
Caution – If the JTAG pins are used as GPIOs in a design, PB7 and PC2 cannot have external pull-down
resistors connected to both of them at the same time. If both pins are pulled Low during reset, the
controller has unpredictable behavior. If this happens, remove one or both of the pull-down resistors,
and apply RST or power-cycle the part.
It is possible to create a software sequence that prevents the debugger from connecting to the Stellaris®
microcontroller. If the program code loaded into flash immediately changes the JTAG pins to their
GPIO functionality, the debugger may not have enough time to connect and halt the controller before
the JTAG pin functionality switches. This may lock the debugger out of the part. This can be avoided
with a software routine that restores JTAG functionality based on an external or software trigger.
GPIO Alternate Function Select (GPIOAFSEL)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0x420
Type R/W, reset 31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
R/W
-
R/W
-
R/W
-
R/W
-
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
AFSEL
RO
0
RO
0
RO
0
RO
0
R/W
-
R/W
-
R/W
-
R/W
-
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Bit/Field
Name
Type
Reset
7:0
AFSEL
R/W
-
Description
GPIO Alternate Function Select
The AFSEL values are defined as follows:
Value Description
0
Software control of corresponding GPIO line (GPIO mode).
1
Hardware control of corresponding GPIO line (alternate
hardware function).
Note:
The default reset value for the GPIOAFSEL register
is 0x0000.0000 for all GPIO pins, with the exception
of the five JTAG pins (PB7 and PC[3:0]). These five
pins default to JTAG functionality. Because of this,
the default reset value of GPIOAFSEL for GPIO Port
B is 0x0000.0080 while the default reset value for
Port C is 0x0000.000F.
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General-Purpose Input/Outputs (GPIOs)
Register 11: GPIO 2-mA Drive Select (GPIODR2R), offset 0x500
The GPIODR2R register is the 2-mA drive control register. It allows for each GPIO signal in the port
to be individually configured without affecting the other pads. When writing a DRV2 bit for a GPIO
signal, the corresponding DRV4 bit in the GPIODR4R register and the DRV8 bit in the GPIODR8R
register are automatically cleared by hardware.
GPIO 2-mA Drive Select (GPIODR2R)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0x500
Type R/W, reset 0x0000.00FF
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
R/W
1
R/W
1
R/W
1
R/W
1
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
DRV2
RO
0
RO
0
RO
0
RO
0
R/W
1
R/W
1
R/W
1
R/W
1
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
DRV2
R/W
0xFF
Output Pad 2-mA Drive Enable
A write of 1 to either GPIODR4[n] or GPIODR8[n] clears the
corresponding 2-mA enable bit. The change is effective on the second
clock cycle after the write.
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Register 12: GPIO 4-mA Drive Select (GPIODR4R), offset 0x504
The GPIODR4R register is the 4-mA drive control register. It allows for each GPIO signal in the port
to be individually configured without affecting the other pads. When writing the DRV4 bit for a GPIO
signal, the corresponding DRV2 bit in the GPIODR2R register and the DRV8 bit in the GPIODR8R
register are automatically cleared by hardware.
GPIO 4-mA Drive Select (GPIODR4R)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0x504
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
DRV4
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
DRV4
R/W
0x00
Output Pad 4-mA Drive Enable
A write of 1 to either GPIODR2[n] or GPIODR8[n] clears the
corresponding 4-mA enable bit. The change is effective on the second
clock cycle after the write.
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General-Purpose Input/Outputs (GPIOs)
Register 13: GPIO 8-mA Drive Select (GPIODR8R), offset 0x508
The GPIODR8R register is the 8-mA drive control register. It allows for each GPIO signal in the port
to be individually configured without affecting the other pads. When writing the DRV8 bit for a GPIO
signal, the corresponding DRV2 bit in the GPIODR2R register and the DRV4 bit in the GPIODR4R
register are automatically cleared by hardware.
GPIO 8-mA Drive Select (GPIODR8R)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0x508
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
DRV8
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
DRV8
R/W
0x00
Output Pad 8-mA Drive Enable
A write of 1 to either GPIODR2[n] or GPIODR4[n] clears the
corresponding 8-mA enable bit. The change is effective on the second
clock cycle after the write.
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Register 14: GPIO Open Drain Select (GPIOODR), offset 0x50C
The GPIOODR register is the open drain control register. Setting a bit in this register enables the
open drain configuration of the corresponding GPIO pad. When open drain mode is enabled, the
corresponding bit should also be set in the GPIO Digital Enable (GPIODEN) register (see page 251).
Corresponding bits in the drive strength registers (GPIODR2R, GPIODR4R, GPIODR8R, and
GPIOSLR ) can be set to achieve the desired rise and fall times. The GPIO acts as an open-drain
input if the corresponding bit in the GPIODIR register is cleared. If open drain is selected while the
GPIO is configured as an input, the GPIO will remain an input and the open-drain selection has no
effect until the GPIO is changed to an output.
When using the I2C module, in addition to configuring the pin to open drain, the GPIO Alternate
Function Select (GPIOAFSEL) register bits for the I2C clock and data pins should be set to 1 (see
examples in “Initialization and Configuration” on page 229).
GPIO Open Drain Select (GPIOODR)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0x50C
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
ODE
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
ODE
R/W
0x00
Output Pad Open Drain Enable
The ODE values are defined as follows:
Value Description
0
Open drain configuration is disabled.
1
Open drain configuration is enabled.
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General-Purpose Input/Outputs (GPIOs)
Register 15: GPIO Pull-Up Select (GPIOPUR), offset 0x510
The GPIOPUR register is the pull-up control register. When a bit is set to 1, it enables a weak pull-up
resistor on the corresponding GPIO signal. Setting a bit in GPIOPUR automatically clears the
corresponding bit in the GPIO Pull-Down Select (GPIOPDR) register (see page 249).
GPIO Pull-Up Select (GPIOPUR)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0x510
Type R/W, reset 0x0000.00FF
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
R/W
1
R/W
1
R/W
1
R/W
1
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
PUE
RO
0
RO
0
RO
0
RO
0
R/W
1
R/W
1
R/W
1
R/W
1
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PUE
R/W
0xFF
Pad Weak Pull-Up Enable
Value Description
0
The corresponding pin's weak pull-up resistor is disabled.
1
The corresponding pin's weak pull-up resistor is enabled.
A write of 1 to GPIOPDR[n] clears the corresponding GPIOPUR[n]
enables. The change is effective on the second clock cycle after the
write.
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Register 16: GPIO Pull-Down Select (GPIOPDR), offset 0x514
The GPIOPDR register is the pull-down control register. When a bit is set to 1, it enables a weak
pull-down resistor on the corresponding GPIO signal. Setting a bit in GPIOPDR automatically clears
the corresponding bit in the GPIO Pull-Up Select (GPIOPUR) register (see page 248).
GPIO Pull-Down Select (GPIOPDR)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0x514
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
PDE
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PDE
R/W
0x00
Pad Weak Pull-Down Enable
Value Description
0
The corresponding pin's weak pull-down resistor is disabled.
1
The corresponding pin's weak pull-down resistor is enabled.
A write of 1 to GPIOPUR[n] clears the corresponding GPIOPDR[n]
enables. The change is effective on the second clock cycle after the
write.
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General-Purpose Input/Outputs (GPIOs)
Register 17: GPIO Slew Rate Control Select (GPIOSLR), offset 0x518
The GPIOSLR register is the slew rate control register. Slew rate control is only available when
using the 8-mA drive strength option via the GPIO 8-mA Drive Select (GPIODR8R) register (see
page 246).
GPIO Slew Rate Control Select (GPIOSLR)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0x518
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
SRL
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
SRL
R/W
0x00
Slew Rate Limit Enable (8-mA drive only)
The SRL values are defined as follows:
Value Description
0
Slew rate control disabled.
1
Slew rate control enabled.
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Register 18: GPIO Digital Enable (GPIODEN), offset 0x51C
Note:
Pins configured as digital inputs are Schmitt-triggered.
The GPIODEN register is the digital enable register. By default, all GPIO signals are configured as
digital inputs at reset. If a pin is being used as a GPIO or its Alternate Hardware Function, it should
be configured as a digital input.
GPIO Digital Enable (GPIODEN)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0x51C
Type R/W, reset 0x0000.00FF
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
reserved
Type
Reset
reserved
Type
Reset
DEN
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
DEN
R/W
0xFF
Digital Enable
The DEN values are defined as follows:
Value Description
0
Digital functions disabled.
1
Digital functions enabled.
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General-Purpose Input/Outputs (GPIOs)
Register 19: GPIO Peripheral Identification 4 (GPIOPeriphID4), offset 0xFD0
The GPIOPeriphID4, GPIOPeriphID5, GPIOPeriphID6, and GPIOPeriphID7 registers can
conceptually be treated as one 32-bit register; each register contains eight bits of the 32-bit register,
used by software to identify the peripheral.
GPIO Peripheral Identification 4 (GPIOPeriphID4)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0xFD0
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
PID4
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID4
RO
0x00
GPIO Peripheral ID Register[7:0]
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Register 20: GPIO Peripheral Identification 5 (GPIOPeriphID5), offset 0xFD4
The GPIOPeriphID4, GPIOPeriphID5, GPIOPeriphID6, and GPIOPeriphID7 registers can
conceptually be treated as one 32-bit register; each register contains eight bits of the 32-bit register,
used by software to identify the peripheral.
GPIO Peripheral Identification 5 (GPIOPeriphID5)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0xFD4
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
PID5
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID5
RO
0x00
GPIO Peripheral ID Register[15:8]
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General-Purpose Input/Outputs (GPIOs)
Register 21: GPIO Peripheral Identification 6 (GPIOPeriphID6), offset 0xFD8
The GPIOPeriphID4, GPIOPeriphID5, GPIOPeriphID6, and GPIOPeriphID7 registers can
conceptually be treated as one 32-bit register; each register contains eight bits of the 32-bit register,
used by software to identify the peripheral.
GPIO Peripheral Identification 6 (GPIOPeriphID6)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0xFD8
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
PID6
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID6
RO
0x00
GPIO Peripheral ID Register[23:16]
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Register 22: GPIO Peripheral Identification 7 (GPIOPeriphID7), offset 0xFDC
The GPIOPeriphID4, GPIOPeriphID5, GPIOPeriphID6, and GPIOPeriphID7 registers can
conceptually be treated as one 32-bit register; each register contains eight bits of the 32-bit register,
used by software to identify the peripheral.
GPIO Peripheral Identification 7 (GPIOPeriphID7)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0xFDC
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
PID7
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID7
RO
0x00
GPIO Peripheral ID Register[31:24]
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General-Purpose Input/Outputs (GPIOs)
Register 23: GPIO Peripheral Identification 0 (GPIOPeriphID0), offset 0xFE0
The GPIOPeriphID0, GPIOPeriphID1, GPIOPeriphID2, and GPIOPeriphID3 registers can
conceptually be treated as one 32-bit register; each register contains eight bits of the 32-bit register,
used by software to identify the peripheral.
GPIO Peripheral Identification 0 (GPIOPeriphID0)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0xFE0
Type RO, reset 0x0000.0061
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
0
RO
0
RO
0
RO
1
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
PID0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
1
RO
1
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID0
RO
0x61
GPIO Peripheral ID Register[7:0]
Can be used by software to identify the presence of this peripheral.
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Register 24: GPIO Peripheral Identification 1 (GPIOPeriphID1), offset 0xFE4
The GPIOPeriphID0, GPIOPeriphID1, GPIOPeriphID2, and GPIOPeriphID3 registers can
conceptually be treated as one 32-bit register; each register contains eight bits of the 32-bit register,
used by software to identify the peripheral.
GPIO Peripheral Identification 1 (GPIOPeriphID1)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0xFE4
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
PID1
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID1
RO
0x00
GPIO Peripheral ID Register[15:8]
Can be used by software to identify the presence of this peripheral.
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Register 25: GPIO Peripheral Identification 2 (GPIOPeriphID2), offset 0xFE8
The GPIOPeriphID0, GPIOPeriphID1, GPIOPeriphID2, and GPIOPeriphID3 registers can
conceptually be treated as one 32-bit register; each register contains eight bits of the 32-bit register,
used by software to identify the peripheral.
GPIO Peripheral Identification 2 (GPIOPeriphID2)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0xFE8
Type RO, reset 0x0000.0018
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
1
RO
0
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
PID2
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
1
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID2
RO
0x18
GPIO Peripheral ID Register[23:16]
Can be used by software to identify the presence of this peripheral.
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Register 26: GPIO Peripheral Identification 3 (GPIOPeriphID3), offset 0xFEC
The GPIOPeriphID0, GPIOPeriphID1, GPIOPeriphID2, and GPIOPeriphID3 registers can
conceptually be treated as one 32-bit register; each register contains eight bits of the 32-bit register,
used by software to identify the peripheral.
GPIO Peripheral Identification 3 (GPIOPeriphID3)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0xFEC
Type RO, reset 0x0000.0001
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
0
RO
0
RO
0
RO
1
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
PID3
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID3
RO
0x01
GPIO Peripheral ID Register[31:24]
Can be used by software to identify the presence of this peripheral.
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Register 27: GPIO PrimeCell Identification 0 (GPIOPCellID0), offset 0xFF0
The GPIOPCellID0, GPIOPCellID1, GPIOPCellID2, and GPIOPCellID3 registers are four 8-bit wide
registers, that can conceptually be treated as one 32-bit register. The register is used as a standard
cross-peripheral identification system.
GPIO PrimeCell Identification 0 (GPIOPCellID0)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0xFF0
Type RO, reset 0x0000.000D
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
1
RO
1
RO
0
RO
1
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
CID0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
CID0
RO
0x0D
GPIO PrimeCell ID Register[7:0]
Provides software a standard cross-peripheral identification system.
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Register 28: GPIO PrimeCell Identification 1 (GPIOPCellID1), offset 0xFF4
The GPIOPCellID0, GPIOPCellID1, GPIOPCellID2, and GPIOPCellID3 registers are four 8-bit wide
registers, that can conceptually be treated as one 32-bit register. The register is used as a standard
cross-peripheral identification system.
GPIO PrimeCell Identification 1 (GPIOPCellID1)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0xFF4
Type RO, reset 0x0000.00F0
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
CID1
RO
0
RO
0
RO
0
RO
0
RO
1
RO
1
RO
1
RO
1
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
CID1
RO
0xF0
GPIO PrimeCell ID Register[15:8]
Provides software a standard cross-peripheral identification system.
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Register 29: GPIO PrimeCell Identification 2 (GPIOPCellID2), offset 0xFF8
The GPIOPCellID0, GPIOPCellID1, GPIOPCellID2, and GPIOPCellID3 registers are four 8-bit wide
registers, that can conceptually be treated as one 32-bit register. The register is used as a standard
cross-peripheral identification system.
GPIO PrimeCell Identification 2 (GPIOPCellID2)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0xFF8
Type RO, reset 0x0000.0005
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
0
RO
1
RO
0
RO
1
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
CID2
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
CID2
RO
0x05
GPIO PrimeCell ID Register[23:16]
Provides software a standard cross-peripheral identification system.
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Register 30: GPIO PrimeCell Identification 3 (GPIOPCellID3), offset 0xFFC
The GPIOPCellID0, GPIOPCellID1, GPIOPCellID2, and GPIOPCellID3 registers are four 8-bit wide
registers, that can conceptually be treated as one 32-bit register. The register is used as a standard
cross-peripheral identification system.
GPIO PrimeCell Identification 3 (GPIOPCellID3)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
Offset 0xFFC
Type RO, reset 0x0000.00B1
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
0
RO
0
RO
0
RO
1
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
CID3
RO
0
RO
0
RO
0
RO
0
RO
1
RO
0
RO
1
RO
1
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
CID3
RO
0xB1
GPIO PrimeCell ID Register[31:24]
Provides software a standard cross-peripheral identification system.
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8
General-Purpose Timers
Programmable timers can be used to count or time external events that drive the Timer input pins.
®
The Stellaris General-Purpose Timer Module (GPTM) contains three GPTM blocks (Timer0, Timer1,
and Timer 2). Each GPTM block provides two 16-bit timers/counters (referred to as TimerA and
TimerB) that can be configured to operate independently as timers or event counters, or configured
to operate as one 32-bit timer or one 32-bit Real-Time Clock (RTC).
In addition, timers can be used to trigger analog-to-digital conversions (ADC). The ADC trigger
signals from all of the general-purpose timers are ORed together before reaching the ADC module,
so only one timer should be used to trigger ADC events.
The GPT Module is one timing resource available on the Stellaris microcontrollers. Other timer
resources include the System Timer (SysTick) (see 82).
The General-Purpose Timers provide the following features:
■ Three General-Purpose Timer Modules (GPTM), each of which provides two 16-bit
timers/counters. Each GPTM can be configured to operate independently:
– As a single 32-bit timer
– As one 32-bit Real-Time Clock (RTC) to event capture
– For Pulse Width Modulation (PWM)
– To trigger analog-to-digital conversions
■ 32-bit Timer modes
– Programmable one-shot timer
– Programmable periodic timer
– Real-Time Clock when using an external 32.768-KHz clock as the input
– User-enabled stalling when the controller asserts CPU Halt flag during debug
– ADC event trigger
■ 16-bit Timer modes
– General-purpose timer function with an 8-bit prescaler (for one-shot and periodic modes only)
– Programmable one-shot timer
– Programmable periodic timer
– User-enabled stalling when the controller asserts CPU Halt flag during debug
– ADC event trigger
■ 16-bit Input Capture modes
– Input edge count capture
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– Input edge time capture
■ 16-bit PWM mode
– Simple PWM mode with software-programmable output inversion of the PWM signal
8.1
Block Diagram
Note:
In Figure 8-1 on page 265, the specific CCP pins available depend on the Stellaris device.
See Table 8-1 on page 265 for the available CCPs.
Figure 8-1. GPTM Module Block Diagram
0x0000 (Down Counter Modes)
TimerA Control
GPTMTAPMR
TA Comparator
GPTMTAPR
Clock / Edge
Detect
GPTMTAMATCHR
Interrupt / Config
TimerA
Interrupt
GPTMCFG
GPTMTAILR
GPTMAR
En
GPTMTAMR
GPTMCTL
GPTMIMR
TimerB
Interrupt
32 KHz or
Even CCP Pin
RTC Divider
GPTMRIS
GPTMMIS
TimerB Control
GPTMICR
GPTMTBPMR
GPTMTBR En
Clock / Edge
Detect
GPTMTBPR
GPTMTBMATCHR
GPTMTBILR
Odd CCP Pin
TB Comparator
GPTMTBMR
0x0000 (Down Counter Modes)
System
Clock
Table 8-1. Available CCP Pins
Timer
16-Bit Up/Down Counter
Even CCP Pin
Odd CCP Pin
Timer 0
TimerA
CCP0
-
TimerB
-
CCP1
TimerA
CCP2
-
TimerB
-
CCP3
TimerA
CCP4
-
TimerB
-
CCP5
Timer 1
Timer 2
8.2
Signal Description
Table 8-2 on page 266lists the external signals of the GP Timer module and describes the function
of each. The GP Timer signals are alternate functions for some GPIO signals and default to be
GPIO signals at reset. The column in the table below titled "Pin Assignment" lists the possible GPIO
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pin placements for these GP Timer signals. The AFSEL bit in the GPIO Alternate Function Select
(GPIOAFSEL) register (page 242) should be set to choose the GP Timer function. For more information
on configuring GPIOs, see “General-Purpose Input/Outputs (GPIOs)” on page 223.
Table 8-2. General-Purpose Timers Signals (48QFP)
a
Pin Name
Pin Number
Pin Type
Buffer Type
Description
CCP0
29
I/O
TTL
Capture/Compare/PWM 0.
CCP1
13
I/O
TTL
Capture/Compare/PWM 1.
CCP2
30
I/O
TTL
Capture/Compare/PWM 2.
CCP3
12
I/O
TTL
Capture/Compare/PWM 3.
CCP4
11
I/O
TTL
Capture/Compare/PWM 4.
CCP5
43
I/O
TTL
Capture/Compare/PWM 5.
a. The TTL designation indicates the pin has TTL-compatible voltage levels.
8.3
Functional Description
The main components of each GPTM block are two free-running 16-bit up/down counters (referred
to as TimerA and TimerB), two 16-bit match registers, two prescaler match registers, and two 16-bit
load/initialization registers and their associated control functions. The exact functionality of each
GPTM is controlled by software and configured through the register interface.
Software configures the GPTM using the GPTM Configuration (GPTMCFG) register (see page 276),
the GPTM TimerA Mode (GPTMTAMR) register (see page 277), and the GPTM TimerB Mode
(GPTMTBMR) register (see page 279). When in one of the 32-bit modes, the timer can only act as
a 32-bit timer. However, when configured in 16-bit mode, the GPTM can have its two 16-bit timers
configured in any combination of the 16-bit modes.
8.3.1
GPTM Reset Conditions
After reset has been applied to the GPTM module, the module is in an inactive state, and all control
registers are cleared and in their default states. Counters TimerA and TimerB are initialized to
0xFFFF, along with their corresponding load registers: the GPTM TimerA Interval Load
(GPTMTAILR) register (see page 290) and the GPTM TimerB Interval Load (GPTMTBILR) register
(see page 291). The prescale counters are initialized to 0x00: the GPTM TimerA Prescale
(GPTMTAPR) register (see page 294) and the GPTM TimerB Prescale (GPTMTBPR) register (see
page 295).
8.3.2
32-Bit Timer Operating Modes
This section describes the three GPTM 32-bit timer modes (One-Shot, Periodic, and RTC) and their
configuration.
The GPTM is placed into 32-bit mode by writing a 0 (One-Shot/Periodic 32-bit timer mode) or a 1
(RTC mode) to the GPTM Configuration (GPTMCFG) register. In both configurations, certain GPTM
registers are concatenated to form pseudo 32-bit registers. These registers include:
■ GPTM TimerA Interval Load (GPTMTAILR) register [15:0], see page 290
■ GPTM TimerB Interval Load (GPTMTBILR) register [15:0], see page 291
■ GPTM TimerA (GPTMTAR) register [15:0], see page 298
■ GPTM TimerB (GPTMTBR) register [15:0], see page 299
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In the 32-bit modes, the GPTM translates a 32-bit write access to GPTMTAILR into a write access
to both GPTMTAILR and GPTMTBILR. The resulting word ordering for such a write operation is:
GPTMTBILR[15:0]:GPTMTAILR[15:0]
Likewise, a read access to GPTMTAR returns the value:
GPTMTBR[15:0]:GPTMTAR[15:0]
8.3.2.1
32-Bit One-Shot/Periodic Timer Mode
In 32-bit one-shot and periodic timer modes, the concatenated versions of the TimerA and TimerB
registers are configured as a 32-bit down-counter. The selection of one-shot or periodic mode is
determined by the value written to the TAMR field of the GPTM TimerA Mode (GPTMTAMR) register
(see page 277), and there is no need to write to the GPTM TimerB Mode (GPTMTBMR) register.
When software writes the TAEN bit in the GPTM Control (GPTMCTL) register (see page 281), the
timer begins counting down from its preloaded value. Once the 0x0000.0000 state is reached, the
timer reloads its start value from the concatenated GPTMTAILR on the next cycle. If configured to
be a one-shot timer, the timer stops counting and clears the TAEN bit in the GPTMCTL register. If
configured as a periodic timer, it continues counting.
In addition to reloading the count value, the GPTM generates interrupts and triggers when it reaches
the 0x000.0000 state. The GPTM sets the TATORIS bit in the GPTM Raw Interrupt Status
(GPTMRIS) register (see page 286), and holds it until it is cleared by writing the GPTM Interrupt
Clear (GPTMICR) register (see page 288). If the time-out interrupt is enabled in the GPTM Interrupt
Mask (GPTMIMR) register (see page 284), the GPTM also sets the TATOMIS bit in the GPTM Masked
Interrupt Status (GPTMMIS) register (see page 287). The ADC trigger is enabled by setting the
TAOTE bit in GPTMCTL.
If software reloads the GPTMTAILR register while the counter is running, the counter loads the new
value on the next clock cycle and continues counting from the new value.
If the TASTALL bit in the GPTMCTL register is set, the timer freezes counting while the processor
is halted by the debugger. The timer resumes counting when the processor resumes execution.
8.3.2.2
32-Bit Real-Time Clock Timer Mode
In Real-Time Clock (RTC) mode, the concatenated versions of the TimerA and TimerB registers
are configured as a 32-bit up-counter. When RTC mode is selected for the first time, the counter is
loaded with a value of 0x0000.0001. All subsequent load values must be written to the GPTM TimerA
Match (GPTMTAMATCHR) register (see page 292) by the controller.
The input clock on an even CCP input is required to be 32.768 KHz in RTC mode. The clock signal
is then divided down to a 1 Hz rate and is passed along to the input of the 32-bit counter.
When software writes the TAEN bit inthe GPTMCTL register, the counter starts counting up from its
preloaded value of 0x0000.0001. When the current count value matches the preloaded value in the
GPTMTAMATCHR register, it rolls over to a value of 0x0000.0000 and continues counting until
either a hardware reset, or it is disabled by software (clearing the TAEN bit). When a match occurs,
the GPTM asserts the RTCRIS bit in GPTMRIS. If the RTC interrupt is enabled in GPTMIMR, the
GPTM also sets the RTCMIS bit in GPTMMIS and generates a controller interrupt. The status flags
are cleared by writing the RTCCINT bit in GPTMICR.
If the TASTALL and/or TBSTALL bits in the GPTMCTL register are set, the timer does not freeze if
the RTCEN bit is set in GPTMCTL.
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8.3.3
16-Bit Timer Operating Modes
The GPTM is placed into global 16-bit mode by writing a value of 0x4 to the GPTM Configuration
(GPTMCFG) register (see page 276). This section describes each of the GPTM 16-bit modes of
operation. TimerA and TimerB have identical modes, so a single description is given using an n to
reference both.
8.3.3.1
16-Bit One-Shot/Periodic Timer Mode
In 16-bit one-shot and periodic timer modes, the timer is configured as a 16-bit down-counter with
an optional 8-bit prescaler that effectively extends the counting range of the timer to 24 bits. The
selection of one-shot or periodic mode is determined by the value written to the TnMR field of the
GPTMTnMR register. The optional prescaler is loaded into the GPTM Timern Prescale (GPTMTnPR)
register.
When software writes the TnEN bit in the GPTMCTL register, the timer begins counting down from
its preloaded value. Once the 0x0000 state is reached, the timer reloads its start value from
GPTMTnILR and GPTMTnPR on the next cycle. If configured to be a one-shot timer, the timer stops
counting and clears the TnEN bit in the GPTMCTL register. If configured as a periodic timer, it
continues counting.
In addition to reloading the count value, the timer generates interrupts and triggers when it reaches
the 0x0000 state. The GPTM sets the TnTORIS bit in the GPTMRIS register, and holds it until it is
cleared by writing the GPTMICR register. If the time-out interrupt is enabled in GPTMIMR, the GPTM
also sets the TnTOMIS bit in GPTMISR and generates a controller interrupt. The ADC trigger is
enabled by setting the TnOTE bit in the GPTMCTL register.
If software reloads the GPTMTAILR register while the counter is running, the counter loads the new
value on the next clock cycle and continues counting from the new value.
If the TnSTALL bit in the GPTMCTL register is set, the timer freezes counting while the processor
is halted by the debugger. The timer resumes counting when the processor resumes execution.
The following example shows a variety of configurations for a 16-bit free running timer while using
the prescaler. All values assume a 50-MHz clock with Tc=20 ns (clock period).
Table 8-3. 16-Bit Timer With Prescaler Configurations
a
Prescale
#Clock (T c)
Max Time
Units
00000000
1
1.3107
mS
00000001
2
2.6214
mS
00000010
3
3.9322
mS
------------
--
--
--
11111101
254
332.9229
mS
11111110
255
334.2336
mS
11111111
256
335.5443
mS
a. Tc is the clock period.
8.3.3.2
16-Bit Input Edge Count Mode
Note:
For rising-edge detection, the input signal must be High for at least two system clock periods
following the rising edge. Similarly, for falling-edge detection, the input signal must be Low
for at least two system clock periods following the falling edge. Based on this criteria, the
maximum input frequency for edge detection is 1/4 of the system frequency.
Note:
The prescaler is not available in 16-Bit Input Edge Count mode.
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In Edge Count mode, the timer is configured as a down-counter capable of capturing three types
of events: rising edge, falling edge, or both. To place the timer in Edge Count mode, the TnCMR bit
of the GPTMTnMR register must be set to 0. The type of edge that the timer counts is determined
by the TnEVENT fields of the GPTMCTL register. During initialization, the GPTM Timern Match
(GPTMTnMATCHR) register is configured so that the difference between the value in the
GPTMTnILR register and the GPTMTnMATCHR register equals the number of edge events that
must be counted.
When software writes the TnEN bit in the GPTM Control (GPTMCTL) register, the timer is enabled
for event capture. Each input event on the CCP pin decrements the counter by 1 until the event count
matches GPTMTnMATCHR. When the counts match, the GPTM asserts the CnMRIS bit in the
GPTMRIS register (and the CnMMIS bit, if the interrupt is not masked).
The counter is then reloaded using the value in GPTMTnILR, and stopped since the GPTM
automatically clears the TnEN bit in the GPTMCTL register. Once the event count has been reached,
all further events are ignored until TnEN is re-enabled by software.
Figure 8-2 on page 269 shows how input edge count mode works. In this case, the timer start value
is set to GPTMTnILR =0x000A and the match value is set to GPTMTnMATCHR =0x0006 so that
four edge events are counted. The counter is configured to detect both edges of the input signal.
Note that the last two edges are not counted since the timer automatically clears the TnEN bit after
the current count matches the value in the GPTMTnMATCHR register.
Figure 8-2. 16-Bit Input Edge Count Mode Example
Timer stops,
flags
asserted
Count
Timer reload
on next cycle
Ignored
Ignored
0x000A
0x0009
0x0008
0x0007
0x0006
Input Signal
8.3.3.3
16-Bit Input Edge Time Mode
Note:
For rising-edge detection, the input signal must be High for at least two system clock periods
following the rising edge. Similarly, for falling edge detection, the input signal must be Low
for at least two system clock periods following the falling edge. Based on this criteria, the
maximum input frequency for edge detection is 1/4 of the system frequency.
Note:
The prescaler is not available in 16-Bit Input Edge Time mode.
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In Edge Time mode, the timer is configured as a free-running down-counter initialized to the value
loaded in the GPTMTnILR register (or 0xFFFF at reset). The timer is capable of capturing three
types of events: rising edge, falling edge, or both. The timer is placed into Edge Time mode by
setting the TnCMR bit in the GPTMTnMR register, and the type of event that the timer captures is
determined by the TnEVENT fields of the GPTMCTL register.
When software writes the TnEN bit in the GPTMCTL register, the timer is enabled for event capture.
When the selected input event is detected, the current Tn counter value is captured in the GPTMTnR
register and is available to be read by the controller. The GPTM then asserts the CnERIS bit (and
the CnEMIS bit, if the interrupt is not masked).
After an event has been captured, the timer does not stop counting. It continues to count until the
TnEN bit is cleared. When the timer reaches the 0x0000 state, it is reloaded with the value from the
GPTMTnILR register.
Figure 8-3 on page 270 shows how input edge timing mode works. In the diagram, it is assumed that
the start value of the timer is the default value of 0xFFFF, and the timer is configured to capture
rising edge events.
Each time a rising edge event is detected, the current count value is loaded into the GPTMTnR
register, and is held there until another rising edge is detected (at which point the new count value
is loaded into GPTMTnR).
Figure 8-3. 16-Bit Input Edge Time Mode Example
Count
0xFFFF
GPTMTnR=X
GPTMTnR=Y
GPTMTnR=Z
Z
X
Y
Time
Input Signal
8.3.3.4
16-Bit PWM Mode
Note:
The prescaler is not available in 16-Bit PWM mode.
The GPTM supports a simple PWM generation mode. In PWM mode, the timer is configured as a
down-counter with a start value (and thus period) defined by GPTMTnILR. In this mode, the PWM
frequency and period are synchronous events and therefore guaranteed to be glitch free. PWM
mode is enabled with the GPTMTnMR register by setting the TnAMS bit to 0x1, the TnCMR bit to
0x0, and the TnMR field to 0x2.
When software writes the TnEN bit in the GPTMCTL register, the counter begins counting down
until it reaches the 0x0000 state. On the next counter cycle, the counter reloads its start value from
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GPTMTnILR and continues counting until disabled by software clearing the TnEN bit in the GPTMCTL
register. No interrupts or status bits are asserted in PWM mode.
The output PWM signal asserts when the counter is at the value of the GPTMTnILR register (its
start state), and is deasserted when the counter value equals the value in the GPTM Timern Match
Register (GPTMTnMATCHR). Software has the capability of inverting the output PWM signal by
setting the TnPWML bit in the GPTMCTL register.
Figure 8-4 on page 271 shows how to generate an output PWM with a 1-ms period and a 66% duty
cycle assuming a 50-MHz input clock and TnPWML =0 (duty cycle would be 33% for the TnPWML
=1 configuration). For this example, the start value is GPTMTnIRL=0xC350 and the match value is
GPTMTnMATCHR=0x411A.
Figure 8-4. 16-Bit PWM Mode Example
Count
GPTMTnR=GPTMnMR
GPTMTnR=GPTMnMR
0xC350
0x411A
Time
TnEN set
TnPWML = 0
Output
Signal
TnPWML = 1
8.4
Initialization and Configuration
To use the general-purpose timers, the peripheral clock must be enabled by setting the TIMER0,
TIMER1, and TIMER2 bits in the RCGC1 register.
This section shows module initialization and configuration examples for each of the supported timer
modes.
8.4.1
32-Bit One-Shot/Periodic Timer Mode
The GPTM is configured for 32-bit One-Shot and Periodic modes by the following sequence:
1. Ensure the timer is disabled (the TAEN bit in the GPTMCTL register is cleared) before making
any changes.
2. Write the GPTM Configuration Register (GPTMCFG) with a value of 0x0.
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3. Set the TAMR field in the GPTM TimerA Mode Register (GPTMTAMR):
a. Write a value of 0x1 for One-Shot mode.
b. Write a value of 0x2 for Periodic mode.
4. Load the start value into the GPTM TimerA Interval Load Register (GPTMTAILR).
5. If interrupts are required, set the TATOIM bit in the GPTM Interrupt Mask Register (GPTMIMR).
6. Set the TAEN bit in the GPTMCTL register to enable the timer and start counting.
7. Poll the TATORIS bit in the GPTMRIS register or wait for the interrupt to be generated (if enabled).
In both cases, the status flags are cleared by writing a 1 to the TATOCINT bit of the GPTM
Interrupt Clear Register (GPTMICR).
In One-Shot mode, the timer stops counting after step 7 on page 272. To re-enable the timer, repeat
the sequence. A timer configured in Periodic mode does not stop counting after it times out.
8.4.2
32-Bit Real-Time Clock (RTC) Mode
To use the RTC mode, the timer must have a 32.768-KHz input signal on an even CCP input. To
enable the RTC feature, follow these steps:
1. Ensure the timer is disabled (the TAEN bit is cleared) before making any changes.
2. Write the GPTM Configuration Register (GPTMCFG) with a value of 0x1.
3. Write the desired match value to the GPTM TimerA Match Register (GPTMTAMATCHR).
4. Set/clear the RTCEN bit in the GPTM Control Register (GPTMCTL) as desired.
5. If interrupts are required, set the RTCIM bit in the GPTM Interrupt Mask Register (GPTMIMR).
6. Set the TAEN bit in the GPTMCTL register to enable the timer and start counting.
When the timer count equals the value in the GPTMTAMATCHR register, the GPTM asserts the
RTCRIS bit in the GPTMRIS register and continues counting until Timer A is disabled or a hardware
reset. The interrupt is cleared by writing the RTCCINT bit in the GPTMICR register.
8.4.3
16-Bit One-Shot/Periodic Timer Mode
A timer is configured for 16-bit One-Shot and Periodic modes by the following sequence:
1. Ensure the timer is disabled (the TnEN bit is cleared) before making any changes.
2. Write the GPTM Configuration Register (GPTMCFG) with a value of 0x4.
3. Set the TnMR field in the GPTM Timer Mode (GPTMTnMR) register:
a. Write a value of 0x1 for One-Shot mode.
b. Write a value of 0x2 for Periodic mode.
4. If a prescaler is to be used, write the prescale value to the GPTM Timern Prescale Register
(GPTMTnPR).
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5. Load the start value into the GPTM Timer Interval Load Register (GPTMTnILR).
6. If interrupts are required, set the TnTOIM bit in the GPTM Interrupt Mask Register (GPTMIMR).
7. Set the TnEN bit in the GPTM Control Register (GPTMCTL) to enable the timer and start
counting.
8. Poll the TnTORIS bit in the GPTMRIS register or wait for the interrupt to be generated (if enabled).
In both cases, the status flags are cleared by writing a 1 to the TnTOCINT bit of the GPTM
Interrupt Clear Register (GPTMICR).
In One-Shot mode, the timer stops counting after step 8 on page 273. To re-enable the timer, repeat
the sequence. A timer configured in Periodic mode does not stop counting after it times out.
8.4.4
16-Bit Input Edge Count Mode
A timer is configured to Input Edge Count mode by the following sequence:
1. Ensure the timer is disabled (the TnEN bit is cleared) before making any changes.
2. Write the GPTM Configuration (GPTMCFG) register with a value of 0x4.
3. In the GPTM Timer Mode (GPTMTnMR) register, write the TnCMR field to 0x0 and the TnMR
field to 0x3.
4. Configure the type of event(s) that the timer captures by writing the TnEVENT field of the GPTM
Control (GPTMCTL) register.
5. Load the timer start value into the GPTM Timern Interval Load (GPTMTnILR) register.
6. Load the desired event count into the GPTM Timern Match (GPTMTnMATCHR) register.
7. If interrupts are required, set the CnMIM bit in the GPTM Interrupt Mask (GPTMIMR) register.
8. Set the TnEN bit in the GPTMCTL register to enable the timer and begin waiting for edge events.
9. Poll the CnMRIS bit in the GPTMRIS register or wait for the interrupt to be generated (if enabled).
In both cases, the status flags are cleared by writing a 1 to the CnMCINT bit of the GPTM
Interrupt Clear (GPTMICR) register.
In Input Edge Count Mode, the timer stops after the desired number of edge events has been
detected. To re-enable the timer, ensure that the TnEN bit is cleared and repeat step 4 on page 273
through step 9 on page 273.
8.4.5
16-Bit Input Edge Timing Mode
A timer is configured to Input Edge Timing mode by the following sequence:
1. Ensure the timer is disabled (the TnEN bit is cleared) before making any changes.
2. Write the GPTM Configuration (GPTMCFG) register with a value of 0x4.
3. In the GPTM Timer Mode (GPTMTnMR) register, write the TnCMR field to 0x1 and the TnMR
field to 0x3.
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4. Configure the type of event that the timer captures by writing the TnEVENT field of the GPTM
Control (GPTMCTL) register.
5. Load the timer start value into the GPTM Timern Interval Load (GPTMTnILR) register.
6. If interrupts are required, set the CnEIM bit in the GPTM Interrupt Mask (GPTMIMR) register.
7. Set the TnEN bit in the GPTM Control (GPTMCTL) register to enable the timer and start counting.
8. Poll the CnERIS bit in the GPTMRIS register or wait for the interrupt to be generated (if enabled).
In both cases, the status flags are cleared by writing a 1 to the CnECINT bit of the GPTM
Interrupt Clear (GPTMICR) register. The time at which the event happened can be obtained
by reading the GPTM Timern (GPTMTnR) register.
In Input Edge Timing mode, the timer continues running after an edge event has been detected,
but the timer interval can be changed at any time by writing the GPTMTnILR register. The change
takes effect at the next cycle after the write.
8.4.6
16-Bit PWM Mode
A timer is configured to PWM mode using the following sequence:
1. Ensure the timer is disabled (the TnEN bit is cleared) before making any changes.
2. Write the GPTM Configuration (GPTMCFG) register with a value of 0x4.
3. In the GPTM Timer Mode (GPTMTnMR) register, set the TnAMS bit to 0x1, the TnCMR bit to
0x0, and the TnMR field to 0x2.
4. Configure the output state of the PWM signal (whether or not it is inverted) in the TnPWML field
of the GPTM Control (GPTMCTL) register.
5. Load the timer start value into the GPTM Timern Interval Load (GPTMTnILR) register.
6. Load the GPTM Timern Match (GPTMTnMATCHR) register with the desired value.
7. Set the TnEN bit in the GPTM Control (GPTMCTL) register to enable the timer and begin
generation of the output PWM signal.
In PWM Timing mode, the timer continues running after the PWM signal has been generated. The
PWM period can be adjusted at any time by writing the GPTMTnILR register, and the change takes
effect at the next cycle after the write.
8.5
Register Map
Table 8-4 on page 275 lists the GPTM registers. The offset listed is a hexadecimal increment to the
register’s address, relative to that timer’s base address:
■ Timer0: 0x4003.0000
■ Timer1: 0x4003.1000
■ Timer2: 0x4003.2000
Note that the Timer module clock must be enabled before the registers can be programmed (see
page 192). There must be a delay of 3 system clocks after the Timer module clock is enabled before
any Timer module registers are accessed.
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Table 8-4. Timers Register Map
Name
Type
Reset
0x000
GPTMCFG
R/W
0x0000.0000
GPTM Configuration
276
0x004
GPTMTAMR
R/W
0x0000.0000
GPTM TimerA Mode
277
0x008
GPTMTBMR
R/W
0x0000.0000
GPTM TimerB Mode
279
0x00C
GPTMCTL
R/W
0x0000.0000
GPTM Control
281
0x018
GPTMIMR
R/W
0x0000.0000
GPTM Interrupt Mask
284
0x01C
GPTMRIS
RO
0x0000.0000
GPTM Raw Interrupt Status
286
0x020
GPTMMIS
RO
0x0000.0000
GPTM Masked Interrupt Status
287
0x024
GPTMICR
W1C
0x0000.0000
GPTM Interrupt Clear
288
0x028
GPTMTAILR
R/W
0xFFFF.FFFF
GPTM TimerA Interval Load
290
0x02C
GPTMTBILR
R/W
0x0000.FFFF
GPTM TimerB Interval Load
291
0x030
GPTMTAMATCHR
R/W
0xFFFF.FFFF
GPTM TimerA Match
292
0x034
GPTMTBMATCHR
R/W
0x0000.FFFF
GPTM TimerB Match
293
0x038
GPTMTAPR
R/W
0x0000.0000
GPTM TimerA Prescale
294
0x03C
GPTMTBPR
R/W
0x0000.0000
GPTM TimerB Prescale
295
0x040
GPTMTAPMR
R/W
0x0000.0000
GPTM TimerA Prescale Match
296
0x044
GPTMTBPMR
R/W
0x0000.0000
GPTM TimerB Prescale Match
297
0x048
GPTMTAR
RO
0xFFFF.FFFF
GPTM TimerA
298
0x04C
GPTMTBR
RO
0x0000.FFFF
GPTM TimerB
299
8.6
Description
See
page
Offset
Register Descriptions
The remainder of this section lists and describes the GPTM registers, in numerical order by address
offset.
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Register 1: GPTM Configuration (GPTMCFG), offset 0x000
This register configures the global operation of the GPTM module. The value written to this register
determines whether the GPTM is in 32- or 16-bit mode.
GPTM Configuration (GPTMCFG)
Timer0 base: 0x4003.0000
Timer1 base: 0x4003.1000
Timer2 base: 0x4003.2000
Offset 0x000
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
GPTMCFG
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:3
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
2:0
GPTMCFG
R/W
0x0
GPTM Configuration
The GPTMCFG values are defined as follows:
Value
Description
0x0
32-bit timer configuration.
0x1
32-bit real-time clock (RTC) counter configuration.
0x2
Reserved
0x3
Reserved
0x4-0x7 16-bit timer configuration, function is controlled by bits 1:0 of
GPTMTAMR and GPTMTBMR.
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Register 2: GPTM TimerA Mode (GPTMTAMR), offset 0x004
This register configures the GPTM based on the configuration selected in the GPTMCFG register.
When in 16-bit PWM mode, set the TAAMS bit to 0x1, the TACMR bit to 0x0, and the TAMR field to
0x2.
GPTM TimerA Mode (GPTMTAMR)
Timer0 base: 0x4003.0000
Timer1 base: 0x4003.1000
Timer2 base: 0x4003.2000
Offset 0x004
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
TAAMS
TACMR
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
TAMR
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:4
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
3
TAAMS
R/W
0
GPTM TimerA Alternate Mode Select
The TAAMS values are defined as follows:
Value Description
0
Capture mode is enabled.
1
PWM mode is enabled.
Note:
2
TACMR
R/W
0
To enable PWM mode, you must also clear the TACMR
bit and set the TAMR field to 0x2.
GPTM TimerA Capture Mode
The TACMR values are defined as follows:
Value Description
0
Edge-Count mode
1
Edge-Time mode
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Bit/Field
Name
Type
Reset
1:0
TAMR
R/W
0x0
Description
GPTM TimerA Mode
The TAMR values are defined as follows:
Value Description
0x0 Reserved
0x1 One-Shot Timer mode
0x2 Periodic Timer mode
0x3 Capture mode
The Timer mode is based on the timer configuration defined by bits 2:0
in the GPTMCFG register (16-or 32-bit).
In 16-bit timer configuration, TAMR controls the 16-bit timer modes for
TimerA.
In 32-bit timer configuration, this register controls the mode and the
contents of GPTMTBMR are ignored.
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Register 3: GPTM TimerB Mode (GPTMTBMR), offset 0x008
This register configures the GPTM based on the configuration selected in the GPTMCFG register.
When in 16-bit PWM mode, set the TBAMS bit to 0x1, the TBCMR bit to 0x0, and the TBMR field to
0x2.
GPTM TimerB Mode (GPTMTBMR)
Timer0 base: 0x4003.0000
Timer1 base: 0x4003.1000
Timer2 base: 0x4003.2000
Offset 0x008
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
TBAMS
TBCMR
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
TBMR
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:4
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
3
TBAMS
R/W
0
GPTM TimerB Alternate Mode Select
The TBAMS values are defined as follows:
Value Description
0
Capture mode is enabled.
1
PWM mode is enabled.
Note:
2
TBCMR
R/W
0
To enable PWM mode, you must also clear the TBCMR
bit and set the TBMR field to 0x2.
GPTM TimerB Capture Mode
The TBCMR values are defined as follows:
Value Description
0
Edge-Count mode
1
Edge-Time mode
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Bit/Field
Name
Type
Reset
1:0
TBMR
R/W
0x0
Description
GPTM TimerB Mode
The TBMR values are defined as follows:
Value Description
0x0 Reserved
0x1 One-Shot Timer mode
0x2 Periodic Timer mode
0x3 Capture mode
The timer mode is based on the timer configuration defined by bits 2:0
in the GPTMCFG register.
In 16-bit timer configuration, these bits control the 16-bit timer modes
for TimerB.
In 32-bit timer configuration, this register’s contents are ignored and
GPTMTAMR is used.
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Register 4: GPTM Control (GPTMCTL), offset 0x00C
This register is used alongside the GPTMCFG and GMTMTnMR registers to fine-tune the timer
configuration, and to enable other features such as timer stall and the output trigger. The output
trigger can be used to initiate transfers on the ADC module.
GPTM Control (GPTMCTL)
Timer0 base: 0x4003.0000
Timer1 base: 0x4003.1000
Timer2 base: 0x4003.2000
Offset 0x00C
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
11
10
9
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
TBSTALL
TBEN
reserved
TAPWML
TAOTE
RTCEN
TASTALL
TAEN
R/W
0
R/W
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
Type
Reset
15
14
13
12
reserved
TBPWML
TBOTE
reserved
RO
0
R/W
0
R/W
0
RO
0
TBEVENT
R/W
0
R/W
0
TAEVENT
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:15
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
14
TBPWML
R/W
0
GPTM TimerB PWM Output Level
The TBPWML values are defined as follows:
Value Description
13
TBOTE
R/W
0
0
Output is unaffected.
1
Output is inverted.
GPTM TimerB Output Trigger Enable
The TBOTE values are defined as follows:
Value Description
0
The output TimerB ADC trigger is disabled.
1
The output TimerB ADC trigger is enabled.
In addition, the ADC must be enabled and the timer selected as a trigger
source with the EMn bit in the ADCEMUX register (see page 339).
12
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Bit/Field
Name
Type
Reset
11:10
TBEVENT
R/W
0x0
Description
GPTM TimerB Event Mode
The TBEVENT values are defined as follows:
Value Description
0x0 Positive edge
0x1 Negative edge
0x2 Reserved
0x3 Both edges
9
TBSTALL
R/W
0
GPTM Timer B Stall Enable
The TBSTALL values are defined as follows:
Value Description
0
Timer B continues counting while the processor is halted by the
debugger.
1
Timer B freezes counting while the processor is halted by the
debugger.
If the processor is executing normally, the TBSTALL bit is ignored.
8
TBEN
R/W
0
GPTM TimerB Enable
The TBEN values are defined as follows:
Value Description
0
TimerB is disabled.
1
TimerB is enabled and begins counting or the capture logic is
enabled based on the GPTMCFG register.
7
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
6
TAPWML
R/W
0
GPTM TimerA PWM Output Level
The TAPWML values are defined as follows:
Value Description
5
TAOTE
R/W
0
0
Output is unaffected.
1
Output is inverted.
GPTM TimerA Output Trigger Enable
The TAOTE values are defined as follows:
Value Description
0
The output TimerA ADC trigger is disabled.
1
The output TimerA ADC trigger is enabled.
In addition, the ADC must be enabled and the timer selected as a trigger
source with the EMn bit in the ADCEMUX register (see page 339).
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Bit/Field
Name
Type
Reset
4
RTCEN
R/W
0
Description
GPTM RTC Enable
The RTCEN values are defined as follows:
Value Description
3:2
TAEVENT
R/W
0x0
0
RTC counting is disabled.
1
RTC counting is enabled.
GPTM TimerA Event Mode
The TAEVENT values are defined as follows:
Value Description
0x0 Positive edge
0x1 Negative edge
0x2 Reserved
0x3 Both edges
1
TASTALL
R/W
0
GPTM Timer A Stall Enable
The TASTALL values are defined as follows:
Value Description
0
Timer A continues counting while the processor is halted by the
debugger.
1
Timer A freezes counting while the processor is halted by the
debugger.
If the processor is executing normally, the TASTALL bit is ignored.
0
TAEN
R/W
0
GPTM TimerA Enable
The TAEN values are defined as follows:
Value Description
0
TimerA is disabled.
1
TimerA is enabled and begins counting or the capture logic is
enabled based on the GPTMCFG register.
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Register 5: GPTM Interrupt Mask (GPTMIMR), offset 0x018
This register allows software to enable/disable GPTM controller-level interrupts. Writing a 1 enables
the interrupt, while writing a 0 disables it.
GPTM Interrupt Mask (GPTMIMR)
Timer0 base: 0x4003.0000
Timer1 base: 0x4003.1000
Timer2 base: 0x4003.2000
Offset 0x018
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
CBEIM
CBMIM
TBTOIM
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RTCIM
CAEIM
CAMIM
TATOIM
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
reserved
Bit/Field
Name
Type
Reset
Description
31:11
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
10
CBEIM
R/W
0
GPTM CaptureB Event Interrupt Mask
The CBEIM values are defined as follows:
Value Description
9
CBMIM
R/W
0
0
Interrupt is disabled.
1
Interrupt is enabled.
GPTM CaptureB Match Interrupt Mask
The CBMIM values are defined as follows:
Value Description
8
TBTOIM
R/W
0
0
Interrupt is disabled.
1
Interrupt is enabled.
GPTM TimerB Time-Out Interrupt Mask
The TBTOIM values are defined as follows:
Value Description
7:4
reserved
RO
0
0
Interrupt is disabled.
1
Interrupt is enabled.
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Bit/Field
Name
Type
Reset
3
RTCIM
R/W
0
Description
GPTM RTC Interrupt Mask
The RTCIM values are defined as follows:
Value Description
2
CAEIM
R/W
0
0
Interrupt is disabled.
1
Interrupt is enabled.
GPTM CaptureA Event Interrupt Mask
The CAEIM values are defined as follows:
Value Description
1
CAMIM
R/W
0
0
Interrupt is disabled.
1
Interrupt is enabled.
GPTM CaptureA Match Interrupt Mask
The CAMIM values are defined as follows:
Value Description
0
TATOIM
R/W
0
0
Interrupt is disabled.
1
Interrupt is enabled.
GPTM TimerA Time-Out Interrupt Mask
The TATOIM values are defined as follows:
Value Description
0
Interrupt is disabled.
1
Interrupt is enabled.
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Register 6: GPTM Raw Interrupt Status (GPTMRIS), offset 0x01C
This register shows the state of the GPTM's internal interrupt signal. These bits are set whether or
not the interrupt is masked in the GPTMIMR register. Each bit can be cleared by writing a 1 to its
corresponding bit in GPTMICR.
GPTM Raw Interrupt Status (GPTMRIS)
Timer0 base: 0x4003.0000
Timer1 base: 0x4003.1000
Timer2 base: 0x4003.2000
Offset 0x01C
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RTCRIS
CAERIS
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
CBERIS
RO
0
CBMRIS TBTORIS
RO
0
RO
0
reserved
CAMRIS TATORIS
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:11
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
10
CBERIS
RO
0
GPTM CaptureB Event Raw Interrupt
This is the CaptureB Event interrupt status prior to masking.
9
CBMRIS
RO
0
GPTM CaptureB Match Raw Interrupt
This is the CaptureB Match interrupt status prior to masking.
8
TBTORIS
RO
0
GPTM TimerB Time-Out Raw Interrupt
This is the TimerB time-out interrupt status prior to masking.
7:4
reserved
RO
0x0
3
RTCRIS
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
GPTM RTC Raw Interrupt
This is the RTC Event interrupt status prior to masking.
2
CAERIS
RO
0
GPTM CaptureA Event Raw Interrupt
This is the CaptureA Event interrupt status prior to masking.
1
CAMRIS
RO
0
GPTM CaptureA Match Raw Interrupt
This is the CaptureA Match interrupt status prior to masking.
0
TATORIS
RO
0
GPTM TimerA Time-Out Raw Interrupt
This the TimerA time-out interrupt status prior to masking.
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Register 7: GPTM Masked Interrupt Status (GPTMMIS), offset 0x020
This register show the state of the GPTM's controller-level interrupt. If an interrupt is unmasked in
GPTMIMR, and there is an event that causes the interrupt to be asserted, the corresponding bit is
set in this register. All bits are cleared by writing a 1 to the corresponding bit in GPTMICR.
GPTM Masked Interrupt Status (GPTMMIS)
Timer0 base: 0x4003.0000
Timer1 base: 0x4003.1000
Timer2 base: 0x4003.2000
Offset 0x020
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
CBEMIS CBMMIS TBTOMIS
RO
0
RO
0
RO
0
reserved
RTCMIS
RO
0
CAEMIS CAMMIS TATOMIS
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:11
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
10
CBEMIS
RO
0
GPTM CaptureB Event Masked Interrupt
This is the CaptureB event interrupt status after masking.
9
CBMMIS
RO
0
GPTM CaptureB Match Masked Interrupt
This is the CaptureB match interrupt status after masking.
8
TBTOMIS
RO
0
GPTM TimerB Time-Out Masked Interrupt
This is the TimerB time-out interrupt status after masking.
7:4
reserved
RO
0x0
3
RTCMIS
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
GPTM RTC Masked Interrupt
This is the RTC event interrupt status after masking.
2
CAEMIS
RO
0
GPTM CaptureA Event Masked Interrupt
This is the CaptureA event interrupt status after masking.
1
CAMMIS
RO
0
GPTM CaptureA Match Masked Interrupt
This is the CaptureA match interrupt status after masking.
0
TATOMIS
RO
0
GPTM TimerA Time-Out Masked Interrupt
This is the TimerA time-out interrupt status after masking.
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Register 8: GPTM Interrupt Clear (GPTMICR), offset 0x024
This register is used to clear the status bits in the GPTMRIS and GPTMMIS registers. Writing a 1
to a bit clears the corresponding bit in the GPTMRIS and GPTMMIS registers.
GPTM Interrupt Clear (GPTMICR)
Timer0 base: 0x4003.0000
Timer1 base: 0x4003.1000
Timer2 base: 0x4003.2000
Offset 0x024
Type W1C, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
reserved
Type
Reset
reserved
Type
Reset
RO
0
RO
0
RO
0
CBECINT CBMCINT
RO
0
RO
0
W1C
0
W1C
0
reserved
TBTOCINT
W1C
0
RO
0
RO
0
RO
0
RTCCINT CAECINT CAMCINT
RO
0
W1C
0
W1C
0
W1C
0
0
TATOCINT
W1C
0
Bit/Field
Name
Type
Reset
Description
31:11
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
10
CBECINT
W1C
0
GPTM CaptureB Event Interrupt Clear
The CBECINT values are defined as follows:
Value Description
9
CBMCINT
W1C
0
0
The interrupt is unaffected.
1
The interrupt is cleared.
GPTM CaptureB Match Interrupt Clear
The CBMCINT values are defined as follows:
Value Description
8
TBTOCINT
W1C
0
0
The interrupt is unaffected.
1
The interrupt is cleared.
GPTM TimerB Time-Out Interrupt Clear
The TBTOCINT values are defined as follows:
Value Description
7:4
reserved
RO
0x0
0
The interrupt is unaffected.
1
The interrupt is cleared.
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Bit/Field
Name
Type
Reset
3
RTCCINT
W1C
0
Description
GPTM RTC Interrupt Clear
The RTCCINT values are defined as follows:
Value Description
2
CAECINT
W1C
0
0
The interrupt is unaffected.
1
The interrupt is cleared.
GPTM CaptureA Event Interrupt Clear
The CAECINT values are defined as follows:
Value Description
1
CAMCINT
W1C
0
0
The interrupt is unaffected.
1
The interrupt is cleared.
GPTM CaptureA Match Interrupt Clear
The CAMCINT values are defined as follows:
Value Description
0
TATOCINT
W1C
0
0
The interrupt is unaffected.
1
The interrupt is cleared.
GPTM TimerA Time-Out Interrupt Clear
The TATOCINT values are defined as follows:
Value Description
0
The interrupt is unaffected.
1
The interrupt is cleared.
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Register 9: GPTM TimerA Interval Load (GPTMTAILR), offset 0x028
This register is used to load the starting count value into the timer. When GPTM is configured to
one of the 32-bit modes, GPTMTAILR appears as a 32-bit register (the upper 16-bits correspond
to the contents of the GPTM TimerB Interval Load (GPTMTBILR) register). In 16-bit mode, the
upper 16 bits of this register read as 0s and have no effect on the state of GPTMTBILR.
GPTM TimerA Interval Load (GPTMTAILR)
Timer0 base: 0x4003.0000
Timer1 base: 0x4003.1000
Timer2 base: 0x4003.2000
Offset 0x028
Type R/W, reset 0xFFFF.FFFF
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
TAILRH
Type
Reset
TAILRL
Type
Reset
Bit/Field
Name
Type
Reset
31:16
TAILRH
R/W
0xFFFF
Description
GPTM TimerA Interval Load Register High
When configured for 32-bit mode via the GPTMCFG register, the GPTM
TimerB Interval Load (GPTMTBILR) register loads this value on a
write. A read returns the current value of GPTMTBILR.
In 16-bit mode, this field reads as 0 and does not have an effect on the
state of GPTMTBILR.
15:0
TAILRL
R/W
0xFFFF
GPTM TimerA Interval Load Register Low
For both 16- and 32-bit modes, writing this field loads the counter for
TimerA. A read returns the current value of GPTMTAILR.
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Register 10: GPTM TimerB Interval Load (GPTMTBILR), offset 0x02C
This register is used to load the starting count value into TimerB. When the GPTM is configured to
a 32-bit mode, GPTMTBILR returns the current value of TimerB and ignores writes.
GPTM TimerB Interval Load (GPTMTBILR)
Timer0 base: 0x4003.0000
Timer1 base: 0x4003.1000
Timer2 base: 0x4003.2000
Offset 0x02C
Type R/W, reset 0x0000.FFFF
31
30
29
28
27
26
25
24
23
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
reserved
Type
Reset
TBILRL
Type
Reset
Bit/Field
Name
Type
Reset
Description
31:16
reserved
RO
0x0000
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
15:0
TBILRL
R/W
0xFFFF
GPTM TimerB Interval Load Register
When the GPTM is not configured as a 32-bit timer, a write to this field
updates GPTMTBILR. In 32-bit mode, writes are ignored, and reads
return the current value of GPTMTBILR.
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Register 11: GPTM TimerA Match (GPTMTAMATCHR), offset 0x030
This register is used in 32-bit Real-Time Clock mode and 16-bit PWM and Input Edge Count modes.
GPTM TimerA Match (GPTMTAMATCHR)
Timer0 base: 0x4003.0000
Timer1 base: 0x4003.1000
Timer2 base: 0x4003.2000
Offset 0x030
Type R/W, reset 0xFFFF.FFFF
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
TAMRH
Type
Reset
TAMRL
Type
Reset
Bit/Field
Name
Type
Reset
31:16
TAMRH
R/W
0xFFFF
Description
GPTM TimerA Match Register High
When configured for 32-bit Real-Time Clock (RTC) mode via the
GPTMCFG register, this value is compared to the upper half of
GPTMTAR, to determine match events.
In 16-bit mode, this field reads as 0 and does not have an effect on the
state of GPTMTBMATCHR.
15:0
TAMRL
R/W
0xFFFF
GPTM TimerA Match Register Low
When configured for 32-bit Real-Time Clock (RTC) mode via the
GPTMCFG register, this value is compared to the lower half of
GPTMTAR, to determine match events.
When configured for PWM mode, this value along with GPTMTAILR,
determines the duty cycle of the output PWM signal.
When configured for Edge Count mode, this value along with
GPTMTAILR, determines how many edge events are counted. The total
number of edge events counted is equal to the value in GPTMTAILR
minus this value.
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Register 12: GPTM TimerB Match (GPTMTBMATCHR), offset 0x034
This register is used in 16-bit PWM and Input Edge Count modes.
GPTM TimerB Match (GPTMTBMATCHR)
Timer0 base: 0x4003.0000
Timer1 base: 0x4003.1000
Timer2 base: 0x4003.2000
Offset 0x034
Type R/W, reset 0x0000.FFFF
31
30
29
28
27
26
25
24
23
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
reserved
Type
Reset
TBMRL
Type
Reset
Bit/Field
Name
Type
Reset
Description
31:16
reserved
RO
0x0000
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
15:0
TBMRL
R/W
0xFFFF
GPTM TimerB Match Register Low
When configured for PWM mode, this value along with GPTMTBILR,
determines the duty cycle of the output PWM signal.
When configured for Edge Count mode, this value along with
GPTMTBILR, determines how many edge events are counted. The total
number of edge events counted is equal to the value in GPTMTBILR
minus this value.
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Register 13: GPTM TimerA Prescale (GPTMTAPR), offset 0x038
This register allows software to extend the range of the 16-bit timers when operating in one-shot or
periodic mode.
GPTM TimerA Prescale (GPTMTAPR)
Timer0 base: 0x4003.0000
Timer1 base: 0x4003.1000
Timer2 base: 0x4003.2000
Offset 0x038
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
TAPSR
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
TAPSR
R/W
0x00
GPTM TimerA Prescale
The register loads this value on a write. A read returns the current value
of the register.
Refer to Table 8-3 on page 268 for more details and an example.
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Register 14: GPTM TimerB Prescale (GPTMTBPR), offset 0x03C
This register allows software to extend the range of the 16-bit timers when operating in one-shot or
periodic mode.
GPTM TimerB Prescale (GPTMTBPR)
Timer0 base: 0x4003.0000
Timer1 base: 0x4003.1000
Timer2 base: 0x4003.2000
Offset 0x03C
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
TBPSR
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
TBPSR
R/W
0x00
GPTM TimerB Prescale
The register loads this value on a write. A read returns the current value
of this register.
Refer to Table 8-3 on page 268 for more details and an example.
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Register 15: GPTM TimerA Prescale Match (GPTMTAPMR), offset 0x040
This register effectively extends the range of GPTMTAMATCHR to 24 bits when operating in 16-bit
one-shot or periodic mode.
GPTM TimerA Prescale Match (GPTMTAPMR)
Timer0 base: 0x4003.0000
Timer1 base: 0x4003.1000
Timer2 base: 0x4003.2000
Offset 0x040
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
TAPSMR
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
TAPSMR
R/W
0x00
GPTM TimerA Prescale Match
This value is used alongside GPTMTAMATCHR to detect timer match
events while using a prescaler.
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Register 16: GPTM TimerB Prescale Match (GPTMTBPMR), offset 0x044
This register effectively extends the range of GPTMTBMATCHR to 24 bits when operating in 16-bit
one-shot or periodic mode.
GPTM TimerB Prescale Match (GPTMTBPMR)
Timer0 base: 0x4003.0000
Timer1 base: 0x4003.1000
Timer2 base: 0x4003.2000
Offset 0x044
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
TBPSMR
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
TBPSMR
R/W
0x00
GPTM TimerB Prescale Match
This value is used alongside GPTMTBMATCHR to detect timer match
events while using a prescaler.
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General-Purpose Timers
Register 17: GPTM TimerA (GPTMTAR), offset 0x048
This register shows the current value of the TimerA counter in all cases except for Input Edge Count
mode. When in this mode, this register contains the number of edges that have occurred.
GPTM TimerA (GPTMTAR)
Timer0 base: 0x4003.0000
Timer1 base: 0x4003.1000
Timer2 base: 0x4003.2000
Offset 0x048
Type RO, reset 0xFFFF.FFFF
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
TARH
Type
Reset
TARL
Type
Reset
Bit/Field
Name
Type
Reset
31:16
TARH
RO
0xFFFF
Description
GPTM TimerA Register High
If the GPTMCFG is in a 32-bit mode, TimerB value is read. If the
GPTMCFG is in a 16-bit mode, this is read as zero.
15:0
TARL
RO
0xFFFF
GPTM TimerA Register Low
A read returns the current value of the GPTM TimerA Count Register,
except in Input Edge-Count mode, when it returns the number of edges
that have occurred.
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Register 18: GPTM TimerB (GPTMTBR), offset 0x04C
This register shows the current value of the TimerB counter in all cases except for Input Edge Count
mode. When in this mode, this register contains the number of edges that have occurred.
GPTM TimerB (GPTMTBR)
Timer0 base: 0x4003.0000
Timer1 base: 0x4003.1000
Timer2 base: 0x4003.2000
Offset 0x04C
Type RO, reset 0x0000.FFFF
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
reserved
Type
Reset
TBRL
Type
Reset
Bit/Field
Name
Type
Reset
Description
31:16
reserved
RO
0x0000
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
15:0
TBRL
RO
0xFFFF
GPTM TimerB
A read returns the current value of the GPTM TimerB Count Register,
except in Input Edge-Count mode, when it returns the number of edges
that have occurred.
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Watchdog Timer
9
Watchdog Timer
A watchdog timer can generate nonmaskable interrupts (NMIs) or a reset when a time-out value is
reached. The watchdog timer is used to regain control when a system has failed due to a software
error or due to the failure of an external device to respond in the expected way.
®
The Stellaris Watchdog Timer module has the following features:
■ 32-bit down counter with a programmable load register
■ Separate watchdog clock with an enable
■ Programmable interrupt generation logic with interrupt masking
■ Lock register protection from runaway software
■ Reset generation logic with an enable/disable
■ User-enabled stalling when the controller asserts the CPU Halt flag during debug
The Watchdog Timer can be configured to generate an interrupt to the controller on its first time-out,
and to generate a reset signal on its second time-out. Once the Watchdog Timer has been configured,
the lock register can be written to prevent the timer configuration from being inadvertently altered.
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9.1
Block Diagram
Figure 9-1. WDT Module Block Diagram
WDTLOAD
Control / Clock /
Interrupt
Generation
WDTCTL
WDTICR
Interrupt
WDTRIS
32-Bit Down
Counter
WDTMIS
0x00000000
WDTLOCK
System Clock
WDTTEST
Comparator
WDTVALUE
Identification Registers
9.2
WDTPCellID0
WDTPeriphID0
WDTPeriphID4
WDTPCellID1
WDTPeriphID1
WDTPeriphID5
WDTPCellID2
WDTPeriphID2
WDTPeriphID6
WDTPCellID3
WDTPeriphID3
WDTPeriphID7
Functional Description
The Watchdog Timer module generates the first time-out signal when the 32-bit counter reaches
the zero state after being enabled; enabling the counter also enables the watchdog timer interrupt.
After the first time-out event, the 32-bit counter is re-loaded with the value of the Watchdog Timer
Load (WDTLOAD) register, and the timer resumes counting down from that value. Once the
Watchdog Timer has been configured, the Watchdog Timer Lock (WDTLOCK) register is written,
which prevents the timer configuration from being inadvertently altered by software.
If the timer counts down to its zero state again before the first time-out interrupt is cleared, and the
reset signal has been enabled (via the WatchdogResetEnable function), the Watchdog timer
asserts its reset signal to the system. If the interrupt is cleared before the 32-bit counter reaches its
second time-out, the 32-bit counter is loaded with the value in the WDTLOAD register, and counting
resumes from that value.
If WDTLOAD is written with a new value while the Watchdog Timer counter is counting, then the
counter is loaded with the new value and continues counting.
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Watchdog Timer
Writing to WDTLOAD does not clear an active interrupt. An interrupt must be specifically cleared
by writing to the Watchdog Interrupt Clear (WDTICR) register.
The Watchdog module interrupt and reset generation can be enabled or disabled as required. When
the interrupt is re-enabled, the 32-bit counter is preloaded with the load register value and not its
last state.
9.3
Initialization and Configuration
To use the WDT, its peripheral clock must be enabled by setting the WDT bit in the RCGC0 register.
The Watchdog Timer is configured using the following sequence:
1. Load the WDTLOAD register with the desired timer load value.
2. If the Watchdog is configured to trigger system resets, set the RESEN bit in the WDTCTL register.
3. Set the INTEN bit in the WDTCTL register to enable the Watchdog and lock the control register.
If software requires that all of the watchdog registers are locked, the Watchdog Timer module can
be fully locked by writing any value to the WDTLOCK register. To unlock the Watchdog Timer, write
a value of 0x1ACC.E551.
9.4
Register Map
Table 9-1 on page 302 lists the Watchdog registers. The offset listed is a hexadecimal increment to
the register’s address, relative to the Watchdog Timer base address of 0x4000.0000.
Table 9-1. Watchdog Timer Register Map
Description
See
page
Offset
Name
Type
Reset
0x000
WDTLOAD
R/W
0xFFFF.FFFF
Watchdog Load
304
0x004
WDTVALUE
RO
0xFFFF.FFFF
Watchdog Value
305
0x008
WDTCTL
R/W
0x0000.0000
Watchdog Control
306
0x00C
WDTICR
WO
-
Watchdog Interrupt Clear
307
0x010
WDTRIS
RO
0x0000.0000
Watchdog Raw Interrupt Status
308
0x014
WDTMIS
RO
0x0000.0000
Watchdog Masked Interrupt Status
309
0x418
WDTTEST
R/W
0x0000.0000
Watchdog Test
310
0xC00
WDTLOCK
R/W
0x0000.0000
Watchdog Lock
311
0xFD0
WDTPeriphID4
RO
0x0000.0000
Watchdog Peripheral Identification 4
312
0xFD4
WDTPeriphID5
RO
0x0000.0000
Watchdog Peripheral Identification 5
313
0xFD8
WDTPeriphID6
RO
0x0000.0000
Watchdog Peripheral Identification 6
314
0xFDC
WDTPeriphID7
RO
0x0000.0000
Watchdog Peripheral Identification 7
315
0xFE0
WDTPeriphID0
RO
0x0000.0005
Watchdog Peripheral Identification 0
316
0xFE4
WDTPeriphID1
RO
0x0000.0018
Watchdog Peripheral Identification 1
317
0xFE8
WDTPeriphID2
RO
0x0000.0018
Watchdog Peripheral Identification 2
318
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Table 9-1. Watchdog Timer Register Map (continued)
Offset
Name
0xFEC
Reset
WDTPeriphID3
RO
0x0000.0001
Watchdog Peripheral Identification 3
319
0xFF0
WDTPCellID0
RO
0x0000.000D
Watchdog PrimeCell Identification 0
320
0xFF4
WDTPCellID1
RO
0x0000.00F0
Watchdog PrimeCell Identification 1
321
0xFF8
WDTPCellID2
RO
0x0000.0005
Watchdog PrimeCell Identification 2
322
0xFFC
WDTPCellID3
RO
0x0000.00B1
Watchdog PrimeCell Identification 3
323
9.5
Description
See
page
Type
Register Descriptions
The remainder of this section lists and describes the WDT registers, in numerical order by address
offset.
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Watchdog Timer
Register 1: Watchdog Load (WDTLOAD), offset 0x000
This register is the 32-bit interval value used by the 32-bit counter. When this register is written, the
value is immediately loaded and the counter restarts counting down from the new value. If the
WDTLOAD register is loaded with 0x0000.0000, an interrupt is immediately generated.
Watchdog Load (WDTLOAD)
Base 0x4000.0000
Offset 0x000
Type R/W, reset 0xFFFF.FFFF
31
30
29
28
27
26
25
24
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
15
14
13
12
11
10
9
8
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
23
22
21
20
19
18
17
16
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
7
6
5
4
3
2
1
0
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
WDTLoad
Type
Reset
WDTLoad
Type
Reset
Bit/Field
Name
Type
31:0
WDTLoad
R/W
Reset
R/W
1
Description
0xFFFF.FFFF Watchdog Load Value
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Register 2: Watchdog Value (WDTVALUE), offset 0x004
This register contains the current count value of the timer.
Watchdog Value (WDTVALUE)
Base 0x4000.0000
Offset 0x004
Type RO, reset 0xFFFF.FFFF
31
30
29
28
27
26
25
24
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
15
14
13
12
11
10
9
8
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
23
22
21
20
19
18
17
16
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
7
6
5
4
3
2
1
0
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
RO
1
WDTValue
Type
Reset
WDTValue
Type
Reset
Bit/Field
Name
Type
31:0
WDTValue
RO
Reset
RO
1
Description
0xFFFF.FFFF Watchdog Value
Current value of the 32-bit down counter.
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Watchdog Timer
Register 3: Watchdog Control (WDTCTL), offset 0x008
This register is the watchdog control register. The watchdog timer can be configured to generate a
reset signal (on second time-out) or an interrupt on time-out.
When the watchdog interrupt has been enabled, all subsequent writes to the control register are
ignored. The only mechanism that can re-enable writes is a hardware reset.
Watchdog Control (WDTCTL)
Base 0x4000.0000
Offset 0x008
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
3
2
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
1
0
RESEN
INTEN
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:2
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
1
RESEN
R/W
0
Watchdog Reset Enable
The RESEN values are defined as follows:
Value Description
0
INTEN
R/W
0
0
Disabled.
1
Enable the Watchdog module reset output.
Watchdog Interrupt Enable
The INTEN values are defined as follows:
Value Description
0
Interrupt event disabled (once this bit is set, it can only be
cleared by a hardware reset).
1
Interrupt event enabled. Once enabled, all writes are ignored.
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Register 4: Watchdog Interrupt Clear (WDTICR), offset 0x00C
This register is the interrupt clear register. A write of any value to this register clears the Watchdog
interrupt and reloads the 32-bit counter from the WDTLOAD register. Value for a read or reset is
indeterminate.
Watchdog Interrupt Clear (WDTICR)
Base 0x4000.0000
Offset 0x00C
Type WO, reset 31
30
29
28
27
26
25
24
WO
-
WO
-
WO
-
WO
-
WO
-
WO
-
WO
-
WO
-
15
14
13
12
11
10
9
8
WO
-
WO
-
WO
-
WO
-
WO
-
WO
-
WO
-
WO
-
23
22
21
20
19
18
17
16
WO
-
WO
-
WO
-
WO
-
WO
-
WO
-
WO
-
WO
-
7
6
5
4
3
2
1
0
WO
-
WO
-
WO
-
WO
-
WO
-
WO
-
WO
-
WDTIntClr
Type
Reset
WDTIntClr
Type
Reset
Bit/Field
Name
Type
Reset
31:0
WDTIntClr
WO
-
WO
-
Description
Watchdog Interrupt Clear
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Watchdog Timer
Register 5: Watchdog Raw Interrupt Status (WDTRIS), offset 0x010
This register is the raw interrupt status register. Watchdog interrupt events can be monitored via
this register if the controller interrupt is masked.
Watchdog Raw Interrupt Status (WDTRIS)
Base 0x4000.0000
Offset 0x010
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
WDTRIS
RO
0
Bit/Field
Name
Type
Reset
Description
31:1
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
0
WDTRIS
RO
0
Watchdog Raw Interrupt Status
Gives the raw interrupt state (prior to masking) of WDTINTR.
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Stellaris LM3S828 Microcontroller
Register 6: Watchdog Masked Interrupt Status (WDTMIS), offset 0x014
This register is the masked interrupt status register. The value of this register is the logical AND of
the raw interrupt bit and the Watchdog interrupt enable bit.
Watchdog Masked Interrupt Status (WDTMIS)
Base 0x4000.0000
Offset 0x014
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
WDTMIS
RO
0
Bit/Field
Name
Type
Reset
Description
31:1
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
0
WDTMIS
RO
0
Watchdog Masked Interrupt Status
Gives the masked interrupt state (after masking) of the WDTINTR
interrupt.
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Watchdog Timer
Register 7: Watchdog Test (WDTTEST), offset 0x418
This register provides user-enabled stalling when the microcontroller asserts the CPU halt flag
during debug.
Watchdog Test (WDTTEST)
Base 0x4000.0000
Offset 0x418
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
STALL
R/W
0
reserved
Bit/Field
Name
Type
Reset
Description
31:9
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
8
STALL
R/W
0
Watchdog Stall Enable
When set to 1, if the Stellaris microcontroller is stopped with a debugger,
the watchdog timer stops counting. Once the microcontroller is restarted,
the watchdog timer resumes counting.
7:0
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Stellaris LM3S828 Microcontroller
Register 8: Watchdog Lock (WDTLOCK), offset 0xC00
Writing 0x1ACC.E551 to the WDTLOCK register enables write access to all other registers. Writing
any other value to the WDTLOCK register re-enables the locked state for register writes to all the
other registers. Reading the WDTLOCK register returns the lock status rather than the 32-bit value
written. Therefore, when write accesses are disabled, reading the WDTLOCK register returns
0x0000.0001 (when locked; otherwise, the returned value is 0x0000.0000 (unlocked)).
Watchdog Lock (WDTLOCK)
Base 0x4000.0000
Offset 0xC00
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
15
14
13
12
11
10
9
8
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
23
22
21
20
19
18
17
16
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
7
6
5
4
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
WDTLock
Type
Reset
WDTLock
Type
Reset
Bit/Field
Name
Type
Reset
31:0
WDTLock
R/W
0x0000
R/W
0
Description
Watchdog Lock
A write of the value 0x1ACC.E551 unlocks the watchdog registers for
write access. A write of any other value reapplies the lock, preventing
any register updates.
A read of this register returns the following values:
Value
Description
0x0000.0001 Locked
0x0000.0000 Unlocked
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Watchdog Timer
Register 9: Watchdog Peripheral Identification 4 (WDTPeriphID4), offset 0xFD0
The WDTPeriphIDn registers are hard-coded and the fields within the register determine the reset
value.
Watchdog Peripheral Identification 4 (WDTPeriphID4)
Base 0x4000.0000
Offset 0xFD0
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
PID4
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID4
RO
0x00
WDT Peripheral ID Register[7:0]
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Stellaris LM3S828 Microcontroller
Register 10: Watchdog Peripheral Identification 5 (WDTPeriphID5), offset
0xFD4
The WDTPeriphIDn registers are hard-coded and the fields within the register determine the reset
value.
Watchdog Peripheral Identification 5 (WDTPeriphID5)
Base 0x4000.0000
Offset 0xFD4
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
PID5
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID5
RO
0x00
WDT Peripheral ID Register[15:8]
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Watchdog Timer
Register 11: Watchdog Peripheral Identification 6 (WDTPeriphID6), offset
0xFD8
The WDTPeriphIDn registers are hard-coded and the fields within the register determine the reset
value.
Watchdog Peripheral Identification 6 (WDTPeriphID6)
Base 0x4000.0000
Offset 0xFD8
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
PID6
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID6
RO
0x00
WDT Peripheral ID Register[23:16]
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Stellaris LM3S828 Microcontroller
Register 12: Watchdog Peripheral Identification 7 (WDTPeriphID7), offset
0xFDC
The WDTPeriphIDn registers are hard-coded and the fields within the register determine the reset
value.
Watchdog Peripheral Identification 7 (WDTPeriphID7)
Base 0x4000.0000
Offset 0xFDC
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
PID7
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID7
RO
0x00
WDT Peripheral ID Register[31:24]
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Watchdog Timer
Register 13: Watchdog Peripheral Identification 0 (WDTPeriphID0), offset
0xFE0
The WDTPeriphIDn registers are hard-coded and the fields within the register determine the reset
value.
Watchdog Peripheral Identification 0 (WDTPeriphID0)
Base 0x4000.0000
Offset 0xFE0
Type RO, reset 0x0000.0005
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
0
RO
1
RO
0
RO
1
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
PID0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID0
RO
0x05
Watchdog Peripheral ID Register[7:0]
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Stellaris LM3S828 Microcontroller
Register 14: Watchdog Peripheral Identification 1 (WDTPeriphID1), offset
0xFE4
The WDTPeriphIDn registers are hard-coded and the fields within the register determine the reset
value.
Watchdog Peripheral Identification 1 (WDTPeriphID1)
Base 0x4000.0000
Offset 0xFE4
Type RO, reset 0x0000.0018
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
1
RO
0
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
PID1
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
1
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID1
RO
0x18
Watchdog Peripheral ID Register[15:8]
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Watchdog Timer
Register 15: Watchdog Peripheral Identification 2 (WDTPeriphID2), offset
0xFE8
The WDTPeriphIDn registers are hard-coded and the fields within the register determine the reset
value.
Watchdog Peripheral Identification 2 (WDTPeriphID2)
Base 0x4000.0000
Offset 0xFE8
Type RO, reset 0x0000.0018
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
1
RO
0
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
PID2
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
1
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID2
RO
0x18
Watchdog Peripheral ID Register[23:16]
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Stellaris LM3S828 Microcontroller
Register 16: Watchdog Peripheral Identification 3 (WDTPeriphID3), offset
0xFEC
The WDTPeriphIDn registers are hard-coded and the fields within the register determine the reset
value.
Watchdog Peripheral Identification 3 (WDTPeriphID3)
Base 0x4000.0000
Offset 0xFEC
Type RO, reset 0x0000.0001
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
0
RO
0
RO
0
RO
1
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
PID3
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID3
RO
0x01
Watchdog Peripheral ID Register[31:24]
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Watchdog Timer
Register 17: Watchdog PrimeCell Identification 0 (WDTPCellID0), offset 0xFF0
The WDTPCellIDn registers are hard-coded and the fields within the register determine the reset
value.
Watchdog PrimeCell Identification 0 (WDTPCellID0)
Base 0x4000.0000
Offset 0xFF0
Type RO, reset 0x0000.000D
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
1
RO
1
RO
0
RO
1
reserved
Type
Reset
reserved
Type
Reset
CID0
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
CID0
RO
0x0D
Watchdog PrimeCell ID Register[7:0]
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Texas Instruments-Production Data
®
Stellaris LM3S828 Microcontroller
Register 18: Watchdog PrimeCell Identification 1 (WDTPCellID1), offset 0xFF4
The WDTPCellIDn registers are hard-coded and the fields within the register determine the reset
value.
Watchdog PrimeCell Identification 1 (WDTPCellID1)
Base 0x4000.0000
Offset 0xFF4
Type RO, reset 0x0000.00F0
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
1
RO
1
RO
1
RO
1
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
CID1
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
CID1
RO
0xF0
Watchdog PrimeCell ID Register[15:8]
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Watchdog Timer
Register 19: Watchdog PrimeCell Identification 2 (WDTPCellID2), offset 0xFF8
The WDTPCellIDn registers are hard-coded and the fields within the register determine the reset
value.
Watchdog PrimeCell Identification 2 (WDTPCellID2)
Base 0x4000.0000
Offset 0xFF8
Type RO, reset 0x0000.0005
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
1
RO
0
RO
1
reserved
Type
Reset
reserved
Type
Reset
CID2
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
CID2
RO
0x05
Watchdog PrimeCell ID Register[23:16]
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Register 20: Watchdog PrimeCell Identification 3 (WDTPCellID3 ), offset 0xFFC
The WDTPCellIDn registers are hard-coded and the fields within the register determine the reset
value.
Watchdog PrimeCell Identification 3 (WDTPCellID3)
Base 0x4000.0000
Offset 0xFFC
Type RO, reset 0x0000.00B1
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
1
RO
0
RO
1
RO
1
RO
0
RO
0
RO
0
RO
1
reserved
Type
Reset
reserved
Type
Reset
CID3
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
CID3
RO
0xB1
Watchdog PrimeCell ID Register[31:24]
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10
Analog-to-Digital Converter (ADC)
An analog-to-digital converter (ADC) is a peripheral that converts a continuous analog voltage to a
discrete digital number.
®
The Stellaris ADC module features 10-bit conversion resolution and supports eight input channels,
plus an internal temperature sensor. The ADC module contains four programmable sequencer which
allows for the sampling of multiple analog input sources without controller intervention. Each sample
sequence provides flexible programming with fully configurable input source, trigger events, interrupt
generation, and sequence priority.
The Stellaris ADC module provides the following features:
■ Eight analog input channels
■ Single-ended and differential-input configurations
■ On-chip internal temperature sensor
■ Sample rate of one million samples/second
■ Flexible, configurable analog-to-digital conversion
■ Four programmable sample conversion sequences from one to eight entries long, with
corresponding conversion result FIFOs
■ Flexible trigger control
– Controller (software)
– Timers
– GPIO
■ Hardware averaging of up to 64 samples for improved accuracy
■ Converter uses an internal 3-V reference
10.1
Block Diagram
Figure 10-1 on page 325 provides details on the internal configuration of the ADC controls and data
registers.
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Figure 10-1. ADC Module Block Diagram
Trigger Events
Comparator
GPIO (PB4)
Timer
PWM
Analog Inputs
SS3
Comparator
GPIO (PB4)
Timer
PWM
Control/Status
Sample
Sequencer 0
ADCACTSS
ADCSSMUX0
ADCOSTAT
ADCSSCTL0
ADCUSTAT
ADCSSFSTAT0
Analog-to-Digital
Converter
ADCSSPRI
SS2
Sample
Sequencer 1
ADCSSMUX1
Comparator
GPIO (PB4)
Timer
PWM
ADCSSCTL1
SS1
Hardware Averager
ADCSSFSTAT1
ADCSAC
Sample
Sequencer 2
Comparator
GPIO (PB4)
Timer
PWM
SS0
ADCSSMUX2
ADCSSCTL2
FIFO Block
ADCSSFSTAT2
ADCSSFIFO0
ADCEMUX
ADCPSSI
ADCSSFIFO1
Interrupt Control
Sample
Sequencer 3
ADCIM
ADCSSMUX3
SS0 Interrupt
SS1 Interrupt
SS2 Interrupt
SS3 Interrupt
10.2
ADCSSFIFO2
ADCSSFIFO3
ADCRIS
ADCSSCTL3
ADCISC
ADCSSFSTAT3
Signal Description
The signals are analog functions for some GPIO signals. The column in the table below titled "Pin
Assignment" lists the GPIO pin placement for the ADC signals. The AINx analog signals are not
5-V tolerant and go through an isolation circuit before reaching their circuitry. These signals are
configured by clearing the corresponding DEN bit in the GPIO Digital Enable (GPIODEN) register
and setting the corresponding AMSEL bit in the GPIO Analog Mode Select (GPIOAMSEL) register.
For more information on configuring GPIOs, see “General-Purpose Input/Outputs
(GPIOs)” on page 223.
Table 10-1. ADC Signals (48QFP)
a
Pin Name
Pin Number
Pin Type
Buffer Type
ADC0
1
I
Analog
Description
Analog-to-digital converter input 0.
ADC1
2
I
Analog
Analog-to-digital converter input 1.
ADC2
3
I
Analog
Analog-to-digital converter input 2.
ADC3
4
I
Analog
Analog-to-digital converter input 3.
ADC4
48
I
Analog
Analog-to-digital converter input 4.
ADC5
47
I
Analog
Analog-to-digital converter input 5.
ADC6
46
I
Analog
Analog-to-digital converter input 6.
ADC7
45
I
Analog
Analog-to-digital converter input 7.
a. The TTL designation indicates the pin has TTL-compatible voltage levels.
10.3
Functional Description
The Stellaris ADC collects sample data by using a programmable sequence-based approach instead
of the traditional single or double-sampling approaches found on many ADC modules. Each sample
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sequence is a fully programmed series of consecutive (back-to-back) samples, allowing the ADC
to collect data from multiple input sources without having to be re-configured or serviced by the
controller. The programming of each sample in the sample sequence includes parameters such as
the input source and mode (differential versus single-ended input), interrupt generation on sample
completion, and the indicator for the last sample in the sequence.
10.3.1
Sample Sequencers
The sampling control and data capture is handled by the sample sequencers. All of the sequencers
are identical in implementation except for the number of samples that can be captured and the depth
of the FIFO. Table 10-2 on page 326 shows the maximum number of samples that each sequencer
can capture and its corresponding FIFO depth. In this implementation, each FIFO entry is a 32-bit
word, with the lower 10 bits containing the conversion result.
Table 10-2. Samples and FIFO Depth of Sequencers
Sequencer
Number of Samples
Depth of FIFO
SS3
1
1
SS2
4
4
SS1
4
4
SS0
8
8
For a given sample sequence, each sample is defined by two 4-bit nibbles in the ADC Sample
Sequence Input Multiplexer Select (ADCSSMUXn) and ADC Sample Sequence Control
(ADCSSCTLn) registers, where "n" corresponds to the sequence number. The ADCSSMUXn
nibbles select the input pin, while the ADCSSCTLn nibbles contain the sample control bits
corresponding to parameters such as temperature sensor selection, interrupt enable, end of
sequence, and differential input mode. Sample sequencers are enabled by setting the respective
ASENn bit in the ADC Active Sample Sequencer (ADCACTSS) register, and should be configured
before being enabled.
When configuring a sample sequence, multiple uses of the same input pin within the same sequence
is allowed. In the ADCSSCTLn register, the IEn bits can be set for any combination of samples,
allowing interrupts to be generated after every sample in the sequence if necessary. Also, the END
bit can be set at any point within a sample sequence. For example, if Sequencer 0 is used, the END
bit can be set in the nibble associated with the fifth sample, allowing Sequencer 0 to complete
execution of the sample sequence after the fifth sample.
After a sample sequence completes execution, the result data can be retrieved from the ADC
Sample Sequence Result FIFO (ADCSSFIFOn) registers. The FIFOs are simple circular buffers
that read a single address to "pop" result data. For software debug purposes, the positions of the
FIFO head and tail pointers are visible in the ADC Sample Sequence FIFO Status (ADCSSFSTATn)
registers along with FULL and EMPTY status flags. Overflow and underflow conditions are monitored
using the ADCOSTAT and ADCUSTAT registers.
10.3.2
Module Control
Outside of the sample sequencers, the remainder of the control logic is responsible for tasks such
as:
■ Interrupt generation
■ Sequence prioritization
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■ Trigger configuration
Most of the ADC control logic runs at the ADC clock rate of 14-18 MHz. The internal ADC divider
is configured automatically by hardware when the system XTAL is selected. The automatic clock
divider configuration targets 16.667 MHz operation for all Stellaris devices.
10.3.2.1
Interrupts
The register configurations of the sample sequencers dictate which events generate raw interrupts,
but do not have control over whether the interrupt is actually sent to the interrupt controller. The
ADC module's interrupt signals are controlled by the state of the MASK bits in the ADC Interrupt
Mask (ADCIM) register. Interrupt status can be viewed at two locations: the ADC Raw Interrupt
Status (ADCRIS) register, which shows the raw status of the various interrupt signals, and the ADC
Interrupt Status and Clear (ADCISC) register, which shows active interrupts that are enabled by
the ADCIM register. Sequencer interrupts are cleared by writing a 1 to the corresponding IN bit in
ADCISC.
10.3.2.2
Prioritization
When sampling events (triggers) happen concurrently, they are prioritized for processing by the
values in the ADC Sample Sequencer Priority (ADCSSPRI) register. Valid priority values are in
the range of 0-3, with 0 being the highest priority and 3 being the lowest. Multiple active sample
sequencer units with the same priority do not provide consistent results, so software must ensure
that all active sample sequencer units have a unique priority value.
10.3.2.3
Sampling Events
Sample triggering for each sample sequencer is defined in the ADC Event Multiplexer Select
(ADCEMUX) register. The external peripheral triggering sources vary by Stellaris family member,
but all devices share the "Controller" and "Always" triggers. Software can initiate sampling by setting
the SSx bits in the ADC Processor Sample Sequence Initiate (ADCPSSI) register.
Care must be taken when using the "Always" trigger. If a sequence's priority is too high, it is possible
to starve other lower priority sequences.
10.3.3
Hardware Sample Averaging Circuit
Higher precision results can be generated using the hardware averaging circuit, however, the
improved results are at the cost of throughput. Up to 64 samples can be accumulated and averaged
to form a single data entry in the sequencer FIFO. Throughput is decreased proportionally to the
number of samples in the averaging calculation. For example, if the averaging circuit is configured
to average 16 samples, the throughput is decreased by a factor of 16.
By default the averaging circuit is off and all data from the converter passes through to the sequencer
FIFO. The averaging hardware is controlled by the ADC Sample Averaging Control (ADCSAC)
register (see page 346). There is a single averaging circuit and all input channels receive the same
amount of averaging whether they are single-ended or differential.
10.3.4
Analog-to-Digital Converter
The converter itself generates a 10-bit output value for selected analog input. Special analog pads
are used to minimize the distortion on the input. An internal 3 V reference is used by the converter
resulting in sample values ranging from 0x000 at 0 V input to 0x3FF at 3 V input when in single-ended
input mode.
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10.3.5
Differential Sampling
In addition to traditional single-ended sampling, the ADC module supports differential sampling of
two analog input channels. To enable differential sampling, software must set the Dn bit in the
ADCSSCTL0n register in a step's configuration nibble.
When a sequence step is configured for differential sampling, its corresponding value in the
ADCSSMUXn register must be set to one of the four differential pairs, numbered 0-3. Differential
pair 0 samples analog inputs 0 and 1; differential pair 1 samples analog inputs 2 and 3; and so on
(see Table 10-3 on page 328). The ADC does not support other differential pairings such as analog
input 0 with analog input 3. The number of differential pairs supported is dependent on the number
of analog inputs (see Table 10-3 on page 328).
Table 10-3. Differential Sampling Pairs
Differential Pair
Analog Inputs
0
0 and 1
1
2 and 3
2
4 and 5
3
6 and 7
The voltage sampled in differential mode is the difference between the odd and even channels:
∆V (differential voltage) = VIN_EVEN (even channels) – VIN_ODD (odd channels), therefore:
■ If ∆V = 0, then the conversion result = 0x1FF
■ If ∆V > 0, then the conversion result > 0x1FF (range is 0x1FF–0x3FF)
■ If ∆V < 0, then the conversion result < 0x1FF (range is 0–0x1FF)
The differential pairs assign polarities to the analog inputs: the even-numbered input is always
positive, and the odd-numbered input is always negative. In order for a valid conversion result to
appear, the negative input must be in the range of ± 1.5 V of the positive input. If an analog input
is greater than 3 V or less than 0 V (the valid range for analog inputs), the input voltage is clipped,
meaning it appears as either 3 V or 0 V, respectively, to the ADC.
Figure 10-2 on page 329 shows an example of the negative input centered at 1.5 V. In this
configuration, the differential range spans from -1.5 V to 1.5 V. Figure 10-3 on page 329 shows an
example where the negative input is centered at -0.75 V, meaning inputs on the positive input
saturate past a differential voltage of -0.75 V since the input voltage is less than 0 V. Figure
10-4 on page 330 shows an example of the negative input centered at 2.25 V, where inputs on the
positive channel saturate past a differential voltage of 0.75 V since the input voltage would be greater
than 3 V.
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Figure 10-2. Differential Sampling Range, VIN_ODD = 1.5 V
ADC Conversion Result
0x3FF
0x1FF
0V
-1.5 V
1.5 V
0V
3.0 V VIN_EVEN
1.5 V DV
VIN_ODD = 1.5 V
- Input Saturation
Figure 10-3. Differential Sampling Range, VIN_ODD = 0.75 V
ADC Conversion Result
0x3FF
0x1FF
0x0FF
-1.5 V
0V
-0.75 V
+0.75 V
+2.25 V
+1.5 V
VIN_EVEN
DV
- Input Saturation
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Figure 10-4. Differential Sampling Range, VIN_ODD = 2.25 V
ADC Conversion Result
0x3FF
0x2FF
0x1FF
0.75 V
-1.5 V
2.25 V
3.0 V
0.75 V
1.5 V
VIN_EVEN
DV
- Input Saturation
10.3.6
Test Modes
There is a user-available test mode that allows for loopback operation within the digital portion of
the ADC module. This can be useful for debugging software without having to provide actual analog
stimulus. This mode is available through the ADC Test Mode Loopback (ADCTMLB) register (see
page 359).
10.3.7
Internal Temperature Sensor
The temperature sensor does not have a separate enable, since it also contains the bandgap
reference and must always be enabled. The reference is supplied to other analog modules; not just
the ADC.
The internal temperature sensor provides an analog temperature reading as well as a reference
voltage. The voltage at the output terminal SENSO is given by the following equation:
SENSO = 2.7 - ((T + 55) / 75)
This relation is shown in Figure 10-5 on page 331.
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Figure 10-5. Internal Temperature Sensor Characteristic
10.4
Initialization and Configuration
In order for the ADC module to be used, the PLL must be enabled and using a supported crystal
frequency (see the RCC register). Using unsupported frequencies can cause faulty operation in the
ADC module.
10.4.1
Module Initialization
Initialization of the ADC module is a simple process with very few steps. The main steps include
enabling the clock to the ADC and reconfiguring the sample sequencer priorities (if needed).
The initialization sequence for the ADC is as follows:
1. Enable the ADC clock by writing a value of 0x0001.0000 to the RCGC0 register (see page 187).
2. If required by the application, reconfigure the sample sequencer priorities in the ADCSSPRI
register. The default configuration has Sample Sequencer 0 with the highest priority, and Sample
Sequencer 3 as the lowest priority.
10.4.2
Sample Sequencer Configuration
Configuration of the sample sequencers is slightly more complex than the module initialization since
each sample sequence is completely programmable.
The configuration for each sample sequencer should be as follows:
1. Ensure that the sample sequencer is disabled by writing a 0 to the corresponding ASENn bit in
the ADCACTSS register. Programming of the sample sequencers is allowed without having
them enabled. Disabling the sequencer during programming prevents erroneous execution if a
trigger event were to occur during the configuration process.
2. Configure the trigger event for the sample sequencer in the ADCEMUX register.
3. For each sample in the sample sequence, configure the corresponding input source in the
ADCSSMUXn register.
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4. For each sample in the sample sequence, configure the sample control bits in the corresponding
nibble in the ADCSSCTLn register. When programming the last nibble, ensure that the END bit
is set. Failure to set the END bit causes unpredictable behavior.
5. If interrupts are to be used, write a 1 to the corresponding MASK bit in the ADCIM register.
6. Enable the sample sequencer logic by writing a 1 to the corresponding ASENn bit in the
ADCACTSS register.
10.5
Register Map
Table 10-4 on page 332 lists the ADC registers. The offset listed is a hexadecimal increment to the
register’s address, relative to the ADC base address of 0x4003.8000.
Note that the ADC module clock must be enabled before the registers can be programmed (see
page 187). There must be a delay of 3 system clocks after the ADC module clock is enabled before
any ADC module registers are accessed.
Table 10-4. ADC Register Map
Description
See
page
Offset
Name
Type
Reset
0x000
ADCACTSS
R/W
0x0000.0000
ADC Active Sample Sequencer
334
0x004
ADCRIS
RO
0x0000.0000
ADC Raw Interrupt Status
335
0x008
ADCIM
R/W
0x0000.0000
ADC Interrupt Mask
336
0x00C
ADCISC
R/W1C
0x0000.0000
ADC Interrupt Status and Clear
337
0x010
ADCOSTAT
R/W1C
0x0000.0000
ADC Overflow Status
338
0x014
ADCEMUX
R/W
0x0000.0000
ADC Event Multiplexer Select
339
0x018
ADCUSTAT
R/W1C
0x0000.0000
ADC Underflow Status
342
0x020
ADCSSPRI
R/W
0x0000.3210
ADC Sample Sequencer Priority
343
0x028
ADCPSSI
WO
-
ADC Processor Sample Sequence Initiate
345
0x030
ADCSAC
R/W
0x0000.0000
ADC Sample Averaging Control
346
0x040
ADCSSMUX0
R/W
0x0000.0000
ADC Sample Sequence Input Multiplexer Select 0
347
0x044
ADCSSCTL0
R/W
0x0000.0000
ADC Sample Sequence Control 0
349
0x048
ADCSSFIFO0
RO
-
ADC Sample Sequence Result FIFO 0
352
0x04C
ADCSSFSTAT0
RO
0x0000.0100
ADC Sample Sequence FIFO 0 Status
353
0x060
ADCSSMUX1
R/W
0x0000.0000
ADC Sample Sequence Input Multiplexer Select 1
354
0x064
ADCSSCTL1
R/W
0x0000.0000
ADC Sample Sequence Control 1
355
0x068
ADCSSFIFO1
RO
-
ADC Sample Sequence Result FIFO 1
352
0x06C
ADCSSFSTAT1
RO
0x0000.0100
ADC Sample Sequence FIFO 1 Status
353
0x080
ADCSSMUX2
R/W
0x0000.0000
ADC Sample Sequence Input Multiplexer Select 2
354
0x084
ADCSSCTL2
R/W
0x0000.0000
ADC Sample Sequence Control 2
355
0x088
ADCSSFIFO2
RO
-
ADC Sample Sequence Result FIFO 2
352
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Table 10-4. ADC Register Map (continued)
Offset
Name
0x08C
Reset
ADCSSFSTAT2
RO
0x0000.0100
ADC Sample Sequence FIFO 2 Status
353
0x0A0
ADCSSMUX3
R/W
0x0000.0000
ADC Sample Sequence Input Multiplexer Select 3
357
0x0A4
ADCSSCTL3
R/W
0x0000.0002
ADC Sample Sequence Control 3
358
0x0A8
ADCSSFIFO3
RO
-
ADC Sample Sequence Result FIFO 3
352
0x0AC
ADCSSFSTAT3
RO
0x0000.0100
ADC Sample Sequence FIFO 3 Status
353
0x100
ADCTMLB
R/W
0x0000.0000
ADC Test Mode Loopback
359
10.6
Description
See
page
Type
Register Descriptions
The remainder of this section lists and describes the ADC registers, in numerical order by address
offset.
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Register 1: ADC Active Sample Sequencer (ADCACTSS), offset 0x000
This register controls the activation of the sample sequencers. Each sample sequencer can be
enabled or disabled independently.
ADC Active Sample Sequencer (ADCACTSS)
Base 0x4003.8000
Offset 0x000
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
ASEN3
ASEN2
ASEN1
ASEN0
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
31:4
reserved
RO
0x0000.000
3
ASEN3
R/W
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
ADC SS3 Enable
Specifies whether Sample Sequencer 3 is enabled. If set, the sample
sequence logic for Sequencer 3 is active. Otherwise, the sequencer is
inactive.
2
ASEN2
R/W
0
ADC SS2 Enable
Specifies whether Sample Sequencer 2 is enabled. If set, the sample
sequence logic for Sequencer 2 is active. Otherwise, the sequencer is
inactive.
1
ASEN1
R/W
0
ADC SS1 Enable
Specifies whether Sample Sequencer 1 is enabled. If set, the sample
sequence logic for Sequencer 1 is active. Otherwise, the sequencer is
inactive.
0
ASEN0
R/W
0
ADC SS0 Enable
Specifies whether Sample Sequencer 0 is enabled. If set, the sample
sequence logic for Sequencer 0 is active. Otherwise, the sequencer is
inactive.
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Register 2: ADC Raw Interrupt Status (ADCRIS), offset 0x004
This register shows the status of the raw interrupt signal of each sample sequencer. These bits may
be polled by software to look for interrupt conditions without having to generate controller interrupts.
ADC Raw Interrupt Status (ADCRIS)
Base 0x4003.8000
Offset 0x004
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
INR3
INR2
INR1
INR0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
Description
31:4
reserved
RO
0x000
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
3
INR3
RO
0
SS3 Raw Interrupt Status
This bit is set by hardware when a sample with its respective
ADCSSCTL3 IE bit has completed conversion. This bit is cleared by
setting the IN3 bit in the ADCISC register.
2
INR2
RO
0
SS2 Raw Interrupt Status
This bit is set by hardware when a sample with its respective
ADCSSCTL2 IE bit has completed conversion. This bit is cleared by
setting the IN2 bit in the ADCISC register.
1
INR1
RO
0
SS1 Raw Interrupt Status
This bit is set by hardware when a sample with its respective
ADCSSCTL1 IE bit has completed conversion. This bit is cleared by
setting the IN1 bit in the ADCISC register.
0
INR0
RO
0
SS0 Raw Interrupt Status
This bit is set by hardware when a sample with its respective
ADCSSCTL0 IE bit has completed conversion. This bit is cleared by
setting the IN30 bit in the ADCISC register.
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Register 3: ADC Interrupt Mask (ADCIM), offset 0x008
This register controls whether the sample sequencer raw interrupt signals are promoted to controller
interrupts. Each raw interrupt signal can be masked independently.
ADC Interrupt Mask (ADCIM)
Base 0x4003.8000
Offset 0x008
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
MASK3
MASK2
MASK1
MASK0
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
Description
31:4
reserved
RO
0x000
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
3
MASK3
R/W
0
SS3 Interrupt Mask
When set, this bit allows the raw interrupt signal from Sample Sequencer
3 (ADCRIS register INR3 bit) to be promoted to a controller interrupt.
When clear, the status of Sample Sequencer 3 does not affect the SS3
interrupt status.
2
MASK2
R/W
0
SS2 Interrupt Mask
When set, this bit allows the raw interrupt signal from Sample Sequencer
2 (ADCRIS register INR2 bit) to be promoted to a controller interrupt.
When clear, the status of Sample Sequencer 2 does not affect the SS2
interrupt status.
1
MASK1
R/W
0
SS1 Interrupt Mask
When set, this bit allows the raw interrupt signal from Sample Sequencer
1 (ADCRIS register INR1 bit) to be promoted to a controller interrupt.
When clear, the status of Sample Sequencer 1 does not affect the SS1
interrupt status.
0
MASK0
R/W
0
SS0 Interrupt Mask
When set, this bit allows the raw interrupt signal from Sample Sequencer
0 (ADCRIS register INR0 bit) to be promoted to a controller interrupt.
When clear, the status of Sample Sequencer 0 does not affect the SS0
interrupt status.
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Register 4: ADC Interrupt Status and Clear (ADCISC), offset 0x00C
This register provides the mechanism for clearing sample sequence interrupt conditions and shows
the status of controller interrupts generated by the sample sequencers. When read, each bit field
is the logical AND of the respective INR and MASK bits. Sample sequence nterrupts are cleared by
setting the corresponding bit position. If software is polling the ADCRIS instead of generating
interrupts, the sample sequence INR bits are still cleared via the ADCISC register, even if the IN
bit is not set.
ADC Interrupt Status and Clear (ADCISC)
Base 0x4003.8000
Offset 0x00C
Type R/W1C, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
IN3
IN2
IN1
IN0
RO
0
RO
0
RO
0
RO
0
RO
0
R/W1C
0
R/W1C
0
R/W1C
0
R/W1C
0
reserved
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
Description
31:4
reserved
RO
0x000
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
3
IN3
R/W1C
0
SS3 Interrupt Status and Clear
This bit is set when both the INR3 bit in the ADCRIS register and the
MASK3 bit in the ADCIM register are set, providing a level-based interrupt
to the controller.
This bit is cleared by writing a 1. Clearing this bit also clears the INR3
bit.
2
IN2
R/W1C
0
SS2 Interrupt Status and Clear
This bit is set when both the INR2 bit in the ADCRIS register and the
MASK2 bit in the ADCIM register are set, providing a level-based interrupt
to the controller.
This bit is cleared by writing a 1. Clearing this bit also clears the INR2
bit.
1
IN1
R/W1C
0
SS1 Interrupt Status and Clear
This bit is set when both the INR1 bit in the ADCRIS register and the
MASK1 bit in the ADCIM register are set, providing a level-based interrupt
to the controller.
This bit is cleared by writing a 1. Clearing this bit also clears the INR1
bit.
0
IN0
R/W1C
0
SS0 Interrupt Status and Clear
This bit is set when both the INR0 bit in the ADCRIS register and the
MASK0 bit in the ADCIM register are set, providing a level-based interrupt
to the controller.
This bit is cleared by writing a 1. Clearing this bit also clears the INR0
bit.
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Analog-to-Digital Converter (ADC)
Register 5: ADC Overflow Status (ADCOSTAT), offset 0x010
This register indicates overflow conditions in the sample sequencer FIFOs. Once the overflow
condition has been handled by software, the condition can be cleared by writing a 1 to the
corresponding bit position.
ADC Overflow Status (ADCOSTAT)
Base 0x4003.8000
Offset 0x010
Type R/W1C, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
OV3
OV2
OV1
OV0
RO
0
RO
0
RO
0
RO
0
RO
0
R/W1C
0
R/W1C
0
R/W1C
0
R/W1C
0
reserved
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
31:4
reserved
RO
0x0000.000
3
OV3
R/W1C
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
SS3 FIFO Overflow
When set, this bit specifies that the FIFO for Sample Sequencer 3 has
hit an overflow condition where the FIFO is full and a write was
requested. When an overflow is detected, the most recent write is
dropped.
This bit is cleared by writing a 1.
2
OV2
R/W1C
0
SS2 FIFO Overflow
When set, this bit specifies that the FIFO for Sample Sequencer 2 has
hit an overflow condition where the FIFO is full and a write was
requested. When an overflow is detected, the most recent write is
dropped.
This bit is cleared by writing a 1.
1
OV1
R/W1C
0
SS1 FIFO Overflow
When set, this bit specifies that the FIFO for Sample Sequencer 1 has
hit an overflow condition where the FIFO is full and a write was
requested. When an overflow is detected, the most recent write is
dropped.
This bit is cleared by writing a 1.
0
OV0
R/W1C
0
SS0 FIFO Overflow
When set, this bit specifies that the FIFO for Sample Sequencer 0 has
hit an overflow condition where the FIFO is full and a write was
requested. When an overflow is detected, the most recent write is
dropped.
This bit is cleared by writing a 1.
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Register 6: ADC Event Multiplexer Select (ADCEMUX), offset 0x014
The ADCEMUX selects the event (trigger) that initiates sampling for each sample sequencer. Each
sample sequencer can be configured with a unique trigger source.
ADC Event Multiplexer Select (ADCEMUX)
Base 0x4003.8000
Offset 0x014
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
EM3
Type
Reset
EM2
EM1
EM0
Bit/Field
Name
Type
Reset
Description
31:16
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
15:12
EM3
R/W
0x0
SS3 Trigger Select
This field selects the trigger source for Sample Sequencer 3.
The valid configurations for this field are:
Value
Event
0x0
Controller (default)
0x1
Reserved
0x2
Reserved
0x3
Reserved
0x4
External (GPIO PB4)
0x5
Timer
In addition, the trigger must be enabled with the TnOTE bit in
the GPTMCTL register (see page 281).
0x6
reserved
0x7
reserved
0x8
reserved
0x9-0xE reserved
0xF
Always (continuously sample)
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Analog-to-Digital Converter (ADC)
Bit/Field
Name
Type
Reset
11:8
EM2
R/W
0x0
Description
SS2 Trigger Select
This field selects the trigger source for Sample Sequencer 2.
The valid configurations for this field are:
Value
Event
0x0
Controller (default)
0x1
Reserved
0x2
Reserved
0x3
Reserved
0x4
External (GPIO PB4)
0x5
Timer
In addition, the trigger must be enabled with the TnOTE bit in
the GPTMCTL register (see page 281).
0x6
reserved
0x7
reserved
0x8
reserved
0x9-0xE reserved
0xF
7:4
EM1
R/W
0x0
Always (continuously sample)
SS1 Trigger Select
This field selects the trigger source for Sample Sequencer 1.
The valid configurations for this field are:
Value
Event
0x0
Controller (default)
0x1
Reserved
0x2
Reserved
0x3
Reserved
0x4
External (GPIO PB4)
0x5
Timer
In addition, the trigger must be enabled with the TnOTE bit in
the GPTMCTL register (see page 281).
0x6
reserved
0x7
reserved
0x8
reserved
0x9-0xE reserved
0xF
Always (continuously sample)
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Bit/Field
Name
Type
Reset
3:0
EM0
R/W
0x0
Description
SS0 Trigger Select
This field selects the trigger source for Sample Sequencer 0.
The valid configurations for this field are:
Value
Event
0x0
Controller (default)
0x1
Reserved
0x2
Reserved
0x3
Reserved
0x4
External (GPIO PB4)
0x5
Timer
In addition, the trigger must be enabled with the TnOTE bit in
the GPTMCTL register (see page 281).
0x6
reserved
0x7
reserved
0x8
reserved
0x9-0xE reserved
0xF
Always (continuously sample)
June 18, 2012
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Analog-to-Digital Converter (ADC)
Register 7: ADC Underflow Status (ADCUSTAT), offset 0x018
This register indicates underflow conditions in the sample sequencer FIFOs. The corresponding
underflow condition is cleared by writing a 1 to the relevant bit position.
ADC Underflow Status (ADCUSTAT)
Base 0x4003.8000
Offset 0x018
Type R/W1C, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
UV3
UV2
UV1
UV0
RO
0
RO
0
RO
0
RO
0
RO
0
R/W1C
0
R/W1C
0
R/W1C
0
R/W1C
0
reserved
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
31:4
reserved
RO
0x0000.000
3
UV3
R/W1C
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
SS3 FIFO Underflow
When set, this bit specifies that the FIFO for Sample Sequencer 3 has
hit an underflow condition where the FIFO is empty and a read was
requested. The problematic read does not move the FIFO pointers, and
0s are returned.
This bit is cleared by writing a 1.
2
UV2
R/W1C
0
SS2 FIFO Underflow
When set, this bit specifies that the FIFO for Sample Sequencer 2 has
hit an underflow condition where the FIFO is empty and a read was
requested. The problematic read does not move the FIFO pointers, and
0s are returned.
This bit is cleared by writing a 1.
1
UV1
R/W1C
0
SS1 FIFO Underflow
When set, this bit specifies that the FIFO for Sample Sequencer 1 has
hit an underflow condition where the FIFO is empty and a read was
requested. The problematic read does not move the FIFO pointers, and
0s are returned.
This bit is cleared by writing a 1.
0
UV0
R/W1C
0
SS0 FIFO Underflow
When set, this bit specifies that the FIFO for Sample Sequencer 0 has
hit an underflow condition where the FIFO is empty and a read was
requested. The problematic read does not move the FIFO pointers, and
0s are returned.
This bit is cleared by writing a 1.
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Register 8: ADC Sample Sequencer Priority (ADCSSPRI), offset 0x020
This register sets the priority for each of the sample sequencers. Out of reset, Sequencer 0 has the
highest priority, and Sequencer 3 has the lowest priority. When reconfiguring sequence priorities,
each sequence must have a unique priority for the ADC to operate properly.
ADC Sample Sequencer Priority (ADCSSPRI)
Base 0x4003.8000
Offset 0x020
Type R/W, reset 0x0000.3210
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
R/W
1
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
R/W
0
RO
0
RO
0
R/W
0
R/W
1
RO
0
RO
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
RO
0
SS3
R/W
1
reserved
RO
0
SS2
R/W
1
Bit/Field
Name
Type
Reset
31:14
reserved
RO
0x0000.0
13:12
SS3
R/W
0x3
reserved
SS1
reserved
SS0
R/W
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
SS3 Priority
This field contains a binary-encoded value that specifies the priority
encoding of Sample Sequencer 3. A priority encoding of 0 is highest
and 3 is lowest. The priorities assigned to the sequencers must be
uniquely mapped. The ADC may not operate properly if two or more
fields are equal.
11:10
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
9:8
SS2
R/W
0x2
SS2 Priority
This field contains a binary-encoded value that specifies the priority
encoding of Sample Sequencer 2. A priority encoding of 0 is highest
and 3 is lowest. The priorities assigned to the sequencers must be
uniquely mapped. The ADC may not operate properly if two or more
fields are equal.
7:6
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
5:4
SS1
R/W
0x1
SS1 Priority
This field contains a binary-encoded value that specifies the priority
encoding of Sample Sequencer 1. A priority encoding of 0 is highest
and 3 is lowest. The priorities assigned to the sequencers must be
uniquely mapped. The ADC may not operate properly if two or more
fields are equal.
3:2
reserved
RO
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Analog-to-Digital Converter (ADC)
Bit/Field
Name
Type
Reset
Description
1:0
SS0
R/W
0x0
SS0 Priority
This field contains a binary-encoded value that specifies the priority
encoding of Sample Sequencer 0. A priority encoding of 0 is highest
and 3 is lowest. The priorities assigned to the sequencers must be
uniquely mapped. The ADC may not operate properly if two or more
fields are equal.
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Register 9: ADC Processor Sample Sequence Initiate (ADCPSSI), offset 0x028
This register provides a mechanism for application software to initiate sampling in the sample
sequencers. Sample sequences can be initiated individually or in any combination. When multiple
sequences are triggered simultaneously, the priority encodings in ADCSSPRI dictate execution
order.
ADC Processor Sample Sequence Initiate (ADCPSSI)
Base 0x4003.8000
Offset 0x028
Type WO, reset 31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
SS3
SS2
SS1
SS0
RO
0
RO
0
RO
0
RO
0
RO
0
WO
-
WO
-
WO
-
WO
-
reserved
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
Description
31:4
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
3
SS3
WO
-
SS3 Initiate
When set, this bit triggers sampling on Sample Sequencer 3 if the
sequencer is enabled in the ADCACTSS register.
Only a write by software is valid; a read of this register returns no
meaningful data.
2
SS2
WO
-
SS2 Initiate
When set, this bit triggers sampling on Sample Sequencer 2 if the
sequencer is enabled in the ADCACTSS register.
Only a write by software is valid; a read of this register returns no
meaningful data.
1
SS1
WO
-
SS1 Initiate
When set, this bit triggers sampling on Sample Sequencer 1 if the
sequencer is enabled in the ADCACTSS register.
Only a write by software is valid; a read of this register returns no
meaningful data.
0
SS0
WO
-
SS0 Initiate
When set, this bit triggers sampling on Sample Sequencer 0 if the
sequencer is enabled in the ADCACTSS register.
Only a write by software is valid; a read of this register returns no
meaningful data.
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Analog-to-Digital Converter (ADC)
Register 10: ADC Sample Averaging Control (ADCSAC), offset 0x030
This register controls the amount of hardware averaging applied to conversion results. The final
conversion result stored in the FIFO is averaged from 2 AVG consecutive ADC samples at the specified
ADC speed. If AVG is 0, the sample is passed directly through without any averaging. If AVG=6,
then 64 consecutive ADC samples are averaged to generate one result in the sequencer FIFO. An
AVG = 7 provides unpredictable results.
ADC Sample Averaging Control (ADCSAC)
Base 0x4003.8000
Offset 0x030
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
Bit/Field
Name
Type
Reset
31:3
reserved
RO
0x0000.000
2:0
AVG
R/W
0x0
AVG
R/W
0
R/W
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Hardware Averaging Control
Specifies the amount of hardware averaging that will be applied to ADC
samples. The AVG field can be any value between 0 and 6. Entering a
value of 7 creates unpredictable results.
Value Description
0x0
No hardware oversampling
0x1
2x hardware oversampling
0x2
4x hardware oversampling
0x3
8x hardware oversampling
0x4
16x hardware oversampling
0x5
32x hardware oversampling
0x6
64x hardware oversampling
0x7
Reserved
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®
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Register 11: ADC Sample Sequence Input Multiplexer Select 0 (ADCSSMUX0),
offset 0x040
This register defines the analog input configuration for each sample in a sequence executed with
Sample Sequencer 0. This register is 32 bits wide and contains information for eight possible
samples.
ADC Sample Sequence Input Multiplexer Select 0 (ADCSSMUX0)
Base 0x4003.8000
Offset 0x040
Type R/W, reset 0x0000.0000
31
30
Type
Reset
RO
0
R/W
0
15
14
RO
0
28
R/W
0
R/W
0
R/W
0
13
12
R/W
0
27
26
RO
0
R/W
0
11
10
24
RO
0
R/W
0
R/W
0
R/W
0
9
8
R/W
0
Bit/Field
Name
Type
Reset
31
reserved
RO
0
30:28
MUX7
R/W
0x0
23
22
RO
0
R/W
0
7
6
RO
0
20
R/W
0
R/W
0
R/W
0
5
4
R/W
0
19
18
RO
0
R/W
0
3
2
RO
0
16
R/W
0
R/W
0
1
0
MUX0
reserved
R/W
0
17
MUX4
reserved
MUX1
reserved
R/W
0
21
MUX5
reserved
MUX2
reserved
R/W
0
25
MUX6
reserved
MUX3
reserved
Type
Reset
29
MUX7
reserved
R/W
0
R/W
0
R/W
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
8th Sample Input Select
The MUX7 field is used during the eighth sample of a sequence executed
with the sample sequencer. It specifies which of the analog inputs is
sampled for the analog-to-digital conversion. The value set here indicates
the corresponding pin, for example, a value of 1 indicates the input is
ADC1.
27
reserved
RO
0
26:24
MUX6
R/W
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7th Sample Input Select
The MUX6 field is used during the seventh sample of a sequence
executed with the sample sequencer. It specifies which of the analog
inputs is sampled for the analog-to-digital conversion.
23
reserved
RO
0
22:20
MUX5
R/W
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
6th Sample Input Select
The MUX5 field is used during the sixth sample of a sequence executed
with the sample sequencer. It specifies which of the analog inputs is
sampled for the analog-to-digital conversion.
19
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
June 18, 2012
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Texas Instruments-Production Data
Analog-to-Digital Converter (ADC)
Bit/Field
Name
Type
Reset
18:16
MUX4
R/W
0x0
Description
5th Sample Input Select
The MUX4 field is used during the fifth sample of a sequence executed
with the sample sequencer. It specifies which of the analog inputs is
sampled for the analog-to-digital conversion.
15
reserved
RO
0
14:12
MUX3
R/W
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
4th Sample Input Select
The MUX3 field is used during the fourth sample of a sequence executed
with the sample sequencer. It specifies which of the analog inputs is
sampled for the analog-to-digital conversion.
11
reserved
RO
0
10:8
MUX2
R/W
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
3rd Sample Input Select
The MUX72 field is used during the third sample of a sequence executed
with the sample sequencer. It specifies which of the analog inputs is
sampled for the analog-to-digital conversion.
7
reserved
RO
0
6:4
MUX1
R/W
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
2nd Sample Input Select
The MUX1 field is used during the second sample of a sequence
executed with the sample sequencer. It specifies which of the analog
inputs is sampled for the analog-to-digital conversion.
3
reserved
RO
0
2:0
MUX0
R/W
0x0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
1st Sample Input Select
The MUX0 field is used during the first sample of a sequence executed
with the sample sequencer. It specifies which of the analog inputs is
sampled for the analog-to-digital conversion.
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®
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Register 12: ADC Sample Sequence Control 0 (ADCSSCTL0), offset 0x044
This register contains the configuration information for each sample for a sequence executed with
a sample sequencer. When configuring a sample sequence, the END bit must be set at some point,
whether it be after the first sample, last sample, or any sample in between. This register is 32-bits
wide and contains information for eight possible samples.
ADC Sample Sequence Control 0 (ADCSSCTL0)
Base 0x4003.8000
Offset 0x044
Type R/W, reset 0x0000.0000
31
Type
Reset
Type
Reset
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
TS7
IE7
END7
D7
TS6
IE6
END6
D6
TS5
IE5
END5
D5
TS4
IE4
END4
D4
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
TS3
IE3
END3
D3
TS2
IE2
END2
D2
TS1
IE1
END1
D1
TS0
IE0
END0
D0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
31
TS7
R/W
0
Description
8th Sample Temp Sensor Select
This bit is used during the eighth sample of the sample sequence and
and specifies the input source of the sample.
When set, the temperature sensor is read.
When clear, the input pin specified by the ADCSSMUX register is read.
30
IE7
R/W
0
8th Sample Interrupt Enable
This bit is used during the eighth sample of the sample sequence and
specifies whether the raw interrupt signal (INR0 bit) is asserted at the
end of the sample's conversion. If the MASK0 bit in the ADCIM register
is set, the interrupt is promoted to a controller-level interrupt.
When this bit is set, the raw interrupt is asserted.
When this bit is clear, the raw interrupt is not asserted.
It is legal to have multiple samples within a sequence generate interrupts.
29
END7
R/W
0
8th Sample is End of Sequence
The END7 bit indicates that this is the last sample of the sequence. It is
possible to end the sequence on any sample position. Samples defined
after the sample containing a set END are not requested for conversion
even though the fields may be non-zero. It is required that software write
the END bit somewhere within the sequence. (Sample Sequencer 3,
which only has a single sample in the sequence, is hardwired to have
the END0 bit set.)
Setting this bit indicates that this sample is the last in the sequence.
28
D7
R/W
0
8th Sample Diff Input Select
The D7 bit indicates that the analog input is to be differentially sampled.
The corresponding ADCSSMUXx nibble must be set to the pair number
"i", where the paired inputs are "2i and 2i+1". The temperature sensor
does not have a differential option. When set, the analog inputs are
differentially sampled.
27
TS6
R/W
0
7th Sample Temp Sensor Select
Same definition as TS7 but used during the seventh sample.
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Texas Instruments-Production Data
Analog-to-Digital Converter (ADC)
Bit/Field
Name
Type
Reset
26
IE6
R/W
0
Description
7th Sample Interrupt Enable
Same definition as IE7 but used during the seventh sample.
25
END6
R/W
0
7th Sample is End of Sequence
Same definition as END7 but used during the seventh sample.
24
D6
R/W
0
7th Sample Diff Input Select
Same definition as D7 but used during the seventh sample.
23
TS5
R/W
0
6th Sample Temp Sensor Select
Same definition as TS7 but used during the sixth sample.
22
IE5
R/W
0
6th Sample Interrupt Enable
Same definition as IE7 but used during the sixth sample.
21
END5
R/W
0
6th Sample is End of Sequence
Same definition as END7 but used during the sixth sample.
20
D5
R/W
0
6th Sample Diff Input Select
Same definition as D7 but used during the sixth sample.
19
TS4
R/W
0
5th Sample Temp Sensor Select
Same definition as TS7 but used during the fifth sample.
18
IE4
R/W
0
5th Sample Interrupt Enable
Same definition as IE7 but used during the fifth sample.
17
END4
R/W
0
5th Sample is End of Sequence
Same definition as END7 but used during the fifth sample.
16
D4
R/W
0
5th Sample Diff Input Select
Same definition as D7 but used during the fifth sample.
15
TS3
R/W
0
4th Sample Temp Sensor Select
Same definition as TS7 but used during the fourth sample.
14
IE3
R/W
0
4th Sample Interrupt Enable
Same definition as IE7 but used during the fourth sample.
13
END3
R/W
0
4th Sample is End of Sequence
Same definition as END7 but used during the fourth sample.
12
D3
R/W
0
4th Sample Diff Input Select
Same definition as D7 but used during the fourth sample.
11
TS2
R/W
0
3rd Sample Temp Sensor Select
Same definition as TS7 but used during the third sample.
10
IE2
R/W
0
3rd Sample Interrupt Enable
Same definition as IE7 but used during the third sample.
9
END2
R/W
0
3rd Sample is End of Sequence
Same definition as END7 but used during the third sample.
350
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®
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Bit/Field
Name
Type
Reset
8
D2
R/W
0
Description
3rd Sample Diff Input Select
Same definition as D7 but used during the third sample.
7
TS1
R/W
0
2nd Sample Temp Sensor Select
Same definition as TS7 but used during the second sample.
6
IE1
R/W
0
2nd Sample Interrupt Enable
Same definition as IE7 but used during the second sample.
5
END1
R/W
0
2nd Sample is End of Sequence
Same definition as END7 but used during the second sample.
4
D1
R/W
0
2nd Sample Diff Input Select
Same definition as D7 but used during the second sample.
3
TS0
R/W
0
1st Sample Temp Sensor Select
Same definition as TS7 but used during the first sample.
2
IE0
R/W
0
1st Sample Interrupt Enable
Same definition as IE7 but used during the first sample.
1
END0
R/W
0
1st Sample is End of Sequence
Same definition as END7 but used during the first sample.
0
D0
R/W
0
1st Sample Diff Input Select
Same definition as D7 but used during the first sample.
June 18, 2012
351
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Analog-to-Digital Converter (ADC)
Register 13: ADC Sample Sequence Result FIFO 0 (ADCSSFIFO0), offset 0x048
Register 14: ADC Sample Sequence Result FIFO 1 (ADCSSFIFO1), offset 0x068
Register 15: ADC Sample Sequence Result FIFO 2 (ADCSSFIFO2), offset 0x088
Register 16: ADC Sample Sequence Result FIFO 3 (ADCSSFIFO3), offset
0x0A8
Important: This register is read-sensitive. See the register description for details.
This register contains the conversion results for samples collected with the sample sequencer (the
ADCSSFIFO0 register is used for Sample Sequencer 0, ADCSSFIFO1 for Sequencer 1,
ADCSSFIFO2 for Sequencer 2, and ADCSSFIFO3 for Sequencer 3). Reads of this register return
conversion result data in the order sample 0, sample 1, and so on, until the FIFO is empty. If the
FIFO is not properly handled by software, overflow and underflow conditions are registered in the
ADCOSTAT and ADCUSTAT registers.
ADC Sample Sequence Result FIFO 0 (ADCSSFIFO0)
Base 0x4003.8000
Offset 0x048
Type RO, reset 31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
-
RO
-
RO
-
RO
-
RO
-
4
3
2
1
0
RO
-
RO
-
RO
-
RO
-
RO
-
reserved
Type
Reset
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
15
14
13
12
11
10
9
8
7
6
5
reserved
Type
Reset
RO
-
RO
-
RO
-
RO
-
DATA
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
RO
-
Bit/Field
Name
Type
Reset
Description
31:10
reserved
RO
-
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
9:0
DATA
RO
-
Conversion Result Data
352
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Texas Instruments-Production Data
®
Stellaris LM3S828 Microcontroller
Register 17: ADC Sample Sequence FIFO 0 Status (ADCSSFSTAT0), offset
0x04C
Register 18: ADC Sample Sequence FIFO 1 Status (ADCSSFSTAT1), offset
0x06C
Register 19: ADC Sample Sequence FIFO 2 Status (ADCSSFSTAT2), offset
0x08C
Register 20: ADC Sample Sequence FIFO 3 Status (ADCSSFSTAT3), offset
0x0AC
This register provides a window into the sample sequencer, providing full/empty status information
as well as the positions of the head and tail pointers. The reset value of 0x100 indicates an empty
FIFO. The ADCSSFSTAT0 register provides status on FIFO0, ADCSSFSTAT1 on FIFO1,
ADCSSFSTAT2 on FIFO2, and ADCSSFSTAT3 on FIFO3.
ADC Sample Sequence FIFO 0 Status (ADCSSFSTAT0)
Base 0x4003.8000
Offset 0x04C
Type RO, reset 0x0000.0100
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
RO
0
FULL
RO
0
RO
0
reserved
RO
0
RO
0
EMPTY
RO
0
Bit/Field
Name
Type
Reset
31:13
reserved
RO
0x0
12
FULL
RO
0
RO
1
HPTR
TPTR
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
FIFO Full
When set, this bit indicates that the FIFO is currently full.
11:9
reserved
RO
0x0
8
EMPTY
RO
1
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
FIFO Empty
When set, this bit indicates that the FIFO is currently empty.
7:4
HPTR
RO
0x0
FIFO Head Pointer
This field contains the current "head" pointer index for the FIFO, that is,
the next entry to be written.
3:0
TPTR
RO
0x0
FIFO Tail Pointer
This field contains the current "tail" pointer index for the FIFO, that is,
the next entry to be read.
June 18, 2012
353
Texas Instruments-Production Data
Analog-to-Digital Converter (ADC)
Register 21: ADC Sample Sequence Input Multiplexer Select 1 (ADCSSMUX1),
offset 0x060
Register 22: ADC Sample Sequence Input Multiplexer Select 2 (ADCSSMUX2),
offset 0x080
This register defines the analog input configuration for each sample in a sequence executed with
Sample Sequencer 1 or 2. These registers are 16-bits wide and contain information for four possible
samples. See the ADCSSMUX0 register on page 347 for detailed bit descriptions. The ADCSSMUX1
register affects Sample Sequencer 1 and the ADCSSMUX2 register affects Sample Sequencer 2.
ADC Sample Sequence Input Multiplexer Select 1 (ADCSSMUX1)
Base 0x4003.8000
Offset 0x060
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
reserved
Type
Reset
MUX3
reserved
Type
Reset
RO
0
R/W
0
R/W
0
MUX2
reserved
R/W
0
RO
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
31:15
reserved
RO
0x0000
14:12
MUX3
R/W
0x0
11
reserved
RO
0
10:8
MUX2
R/W
0x0
7
reserved
RO
0
6:4
MUX1
R/W
0x0
3
reserved
RO
0
2:0
MUX0
R/W
0x0
MUX1
reserved
R/W
0
RO
0
R/W
0
R/W
0
MUX0
reserved
R/W
0
RO
0
R/W
0
R/W
0
R/W
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
4th Sample Input Select
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
3rd Sample Input Select
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
2nd Sample Input Select
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
1st Sample Input Select
354
June 18, 2012
Texas Instruments-Production Data
®
Stellaris LM3S828 Microcontroller
Register 23: ADC Sample Sequence Control 1 (ADCSSCTL1), offset 0x064
Register 24: ADC Sample Sequence Control 2 (ADCSSCTL2), offset 0x084
These registers contain the configuration information for each sample for a sequence executed with
Sample Sequencer 1 or 2. When configuring a sample sequence, the END bit must be set at some
point, whether it be after the first sample, last sample, or any sample in between. These registers
are 16-bits wide and contain information for four possible samples. See the ADCSSCTL0 register
on page 349 for detailed bit descriptions. The ADCSSCTL1 register configures Sample Sequencer
1 and the ADCSSCTL2 register configures Sample Sequencer 2.
ADC Sample Sequence Control 1 (ADCSSCTL1)
Base 0x4003.8000
Offset 0x064
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
TS3
IE3
END3
D3
TS2
IE2
END2
D2
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
TS1
IE1
END1
D1
TS0
IE0
END0
D0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
Type
Reset
Bit/Field
Name
Type
Reset
31:16
reserved
RO
0x0000
15
TS3
R/W
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
4th Sample Temp Sensor Select
Same definition as TS7 but used during the fourth sample.
14
IE3
R/W
0
4th Sample Interrupt Enable
Same definition as IE7 but used during the fourth sample.
13
END3
R/W
0
4th Sample is End of Sequence
Same definition as END7 but used during the fourth sample.
12
D3
R/W
0
4th Sample Diff Input Select
Same definition as D7 but used during the fourth sample.
11
TS2
R/W
0
3rd Sample Temp Sensor Select
Same definition as TS7 but used during the third sample.
10
IE2
R/W
0
3rd Sample Interrupt Enable
Same definition as IE7 but used during the third sample.
9
END2
R/W
0
3rd Sample is End of Sequence
Same definition as END7 but used during the third sample.
8
D2
R/W
0
3rd Sample Diff Input Select
Same definition as D7 but used during the third sample.
7
TS1
R/W
0
2nd Sample Temp Sensor Select
Same definition as TS7 but used during the second sample.
June 18, 2012
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Texas Instruments-Production Data
Analog-to-Digital Converter (ADC)
Bit/Field
Name
Type
Reset
6
IE1
R/W
0
Description
2nd Sample Interrupt Enable
Same definition as IE7 but used during the second sample.
5
END1
R/W
0
2nd Sample is End of Sequence
Same definition as END7 but used during the second sample.
4
D1
R/W
0
2nd Sample Diff Input Select
Same definition as D7 but used during the second sample.
3
TS0
R/W
0
1st Sample Temp Sensor Select
Same definition as TS7 but used during the first sample.
2
IE0
R/W
0
1st Sample Interrupt Enable
Same definition as IE7 but used during the first sample.
1
END0
R/W
0
1st Sample is End of Sequence
Same definition as END7 but used during the first sample.
0
D0
R/W
0
1st Sample Diff Input Select
Same definition as D7 but used during the first sample.
356
June 18, 2012
Texas Instruments-Production Data
®
Stellaris LM3S828 Microcontroller
Register 25: ADC Sample Sequence Input Multiplexer Select 3 (ADCSSMUX3),
offset 0x0A0
This register defines the analog input configuration for a sample executed with Sample Sequencer
3. This register is 4-bits wide and contains information for one possible sample. See the ADCSSMUX0
register on page 347 for detailed bit descriptions.
ADC Sample Sequence Input Multiplexer Select 3 (ADCSSMUX3)
Base 0x4003.8000
Offset 0x0A0
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
1
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
9
8
7
6
5
4
3
2
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
31:3
reserved
RO
0x0000.000
2:0
MUX0
R/W
0
MUX0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
1st Sample Input Select
June 18, 2012
357
Texas Instruments-Production Data
Analog-to-Digital Converter (ADC)
Register 26: ADC Sample Sequence Control 3 (ADCSSCTL3), offset 0x0A4
This register contains the configuration information for a sample executed with Sample Sequencer
3. The END bit is always set since there is only one sample in this sequencer. This register is 4-bits
wide and contains information for one possible sample. See the ADCSSCTL0 register on page 349
for detailed bit descriptions.
ADC Sample Sequence Control 3 (ADCSSCTL3)
Base 0x4003.8000
Offset 0x0A4
Type R/W, reset 0x0000.0002
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
TS0
IE0
END0
D0
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
1
R/W
0
reserved
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
31:4
reserved
RO
0x0000.000
3
TS0
R/W
0
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
1st Sample Temp Sensor Select
Same definition as TS7 but used during the first sample.
2
IE0
R/W
0
1st Sample Interrupt Enable
Same definition as IE7 but used during the first sample.
1
END0
R/W
1
1st Sample is End of Sequence
Same definition as END7 but used during the first sample.
Since this sequencer has only one entry, this bit must be set.
0
D0
R/W
0
1st Sample Diff Input Select
Same definition as D7 but used during the first sample.
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Register 27: ADC Test Mode Loopback (ADCTMLB), offset 0x100
This register provides loopback operation within the digital logic of the ADC, which can be useful in
debugging software without having to provide actual analog stimulus. This test mode is entered by
writing a value of 0x0000.0001 to this register. When data is read from the FIFO in loopback mode,
the read-only portion of this register is returned.
ADC Test Mode Loopback (ADCTMLB)
Base 0x4003.8000
Offset 0x100
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
31:1
reserved
RO
0x0000.000
0
LB
R/W
0
RO
0
LB
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Loopback Mode Enable
When set, forces a loopback within the digital block to provide information
on input and unique numbering. The ADCSSFIFOn registers do not
provide sample data, but instead provide the 10-bit loopback data as
shown below.
Bit/Field Name
Description
9:6
Continuous Sample Counter
CNT
Continuous sample counter that is initialized to 0
and counts each sample as it processed. This
helps provide a unique value for the data received.
5
CONT
Continuation Sample Indicator
When set, indicates that this is a continuation
sample. For example, if two sequencers were to
run back-to-back, this indicates that the controller
kept continuously sampling at full rate.
4
DIFF
Differential Sample Indicator
When set, indicates that this is a differential
sample.
3
TS
Temp Sensor Sample Indicator
When set, indicates that this is a temperature
sensor sample.
2:0
MUX
Analog Input Indicator
Indicates which analog input is to be sampled.
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11
Universal Asynchronous Receivers/Transmitters
(UARTs)
®
Each Stellaris Universal Asynchronous Receiver/Transmitter (UART) has the following features:
■ Two fully programmable 16C550-type UARTs
■ Separate 16x8 transmit (TX) and receive (RX) FIFOs to reduce CPU interrupt service loading
■ Programmable baud-rate generator allowing speeds up to 3.125 Mbps
■ Programmable FIFO length, including 1-byte deep operation providing conventional
double-buffered interface
■ FIFO trigger levels of 1/8, 1/4, 1/2, 3/4, and 7/8
■ Standard asynchronous communication bits for start, stop, and parity
■ Line-break generation and detection
■ Fully programmable serial interface characteristics
– 5, 6, 7, or 8 data bits
– Even, odd, stick, or no-parity bit generation/detection
– 1 or 2 stop bit generation
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11.1
Block Diagram
Figure 11-1. UART Module Block Diagram
System Clock
Interrupt
Interrupt Control
UARTIFLS
UARTIM
UARTMIS
UARTRIS
UARTICR
Identification
Registers
UARTPCellID0
UARTPCellID1
UARTPCellID2
UARTPCellID3
UARTPeriphID0
UARTPeriphID1
UARTPeriphID2
UARTPeriphID3
UARTPeriphID4
UARTPeriphID5
UARTPeriphID6
UARTPeriphID7
11.2
TxFIFO
16 x 8
.
.
.
Transmitter
UnTx
Baud Rate
Generator
UARTIBRD
UARTFBRD
UARTDR
Receiver
Control/Status
UnRx
RxFIFO
16 x 8
UARTRSR/ECR
UARTFR
UARTLCRH
UARTCTL
UARTILPR
.
.
.
Signal Description
Table 11-1 on page 361 lists the external signals of the UART module and describes the function of
each. The UART signals are alternate functions for some GPIO signals and default to be GPIO
signals at reset, with the exception of the U0Rx and U0Tx pins which default to the UART function.
The column in the table below titled "Pin Assignment" lists the possible GPIO pin placements for
these UART signals. The AFSEL bit in the GPIO Alternate Function Select (GPIOAFSEL) register
(page 242) should be set to choose the UART function. For more information on configuring GPIOs,
see “General-Purpose Input/Outputs (GPIOs)” on page 223.
Table 11-1. UART Signals (48QFP)
a
Pin Name
Pin Number
Pin Type
Buffer Type
U0Rx
17
I
TTL
Description
UART module 0 receive.
U0Tx
18
O
TTL
UART module 0 transmit.
U1Rx
27
I
TTL
UART module 1 receive.
U1Tx
28
O
TTL
UART module 1 transmit.
a. The TTL designation indicates the pin has TTL-compatible voltage levels.
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11.3
Functional Description
Each Stellaris UART performs the functions of parallel-to-serial and serial-to-parallel conversions.
It is similar in functionality to a 16C550 UART, but is not register compatible.
The UART is configured for transmit and/or receive via the TXE and RXE bits of the UART Control
(UARTCTL) register (see page 378). Transmit and receive are both enabled out of reset. Before any
control registers are programmed, the UART must be disabled by clearing the UARTEN bit in
UARTCTL. If the UART is disabled during a TX or RX operation, the current transaction is completed
prior to the UART stopping.
11.3.1
Transmit/Receive Logic
The transmit logic performs parallel-to-serial conversion on the data read from the transmit FIFO.
The control logic outputs the serial bit stream beginning with a start bit, and followed by the data
bits (LSB first), parity bit, and the stop bits according to the programmed configuration in the control
registers. See Figure 11-2 on page 362 for details.
The receive logic performs serial-to-parallel conversion on the received bit stream after a valid start
pulse has been detected. Overrun, parity, frame error checking, and line-break detection are also
performed, and their status accompanies the data that is written to the receive FIFO.
Figure 11-2. UART Character Frame
UnTX
LSB
1
5-8 data bits
0
n
Parity bit
if enabled
Start
11.3.2
1-2
stop bits
MSB
Baud-Rate Generation
The baud-rate divisor is a 22-bit number consisting of a 16-bit integer and a 6-bit fractional part.
The number formed by these two values is used by the baud-rate generator to determine the bit
period. Having a fractional baud-rate divider allows the UART to generate all the standard baud
rates.
The 16-bit integer is loaded through the UART Integer Baud-Rate Divisor (UARTIBRD) register
(see page 374) and the 6-bit fractional part is loaded with the UART Fractional Baud-Rate Divisor
(UARTFBRD) register (see page 375). The baud-rate divisor (BRD) has the following relationship
to the system clock (where BRDI is the integer part of the BRD and BRDF is the fractional part,
separated by a decimal place.)
BRD = BRDI + BRDF = UARTSysClk / (16 * Baud Rate)
where UARTSysClk is the system clock connected to the UART.
The 6-bit fractional number (that is to be loaded into the DIVFRAC bit field in the UARTFBRD register)
can be calculated by taking the fractional part of the baud-rate divisor, multiplying it by 64, and
adding 0.5 to account for rounding errors:
UARTFBRD[DIVFRAC] = integer(BRDF * 64 + 0.5)
The UART generates an internal baud-rate reference clock at 16x the baud-rate (referred to as
Baud16). This reference clock is divided by 16 to generate the transmit clock, and is used for error
detection during receive operations.
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Along with the UART Line Control, High Byte (UARTLCRH) register (see page 376), the UARTIBRD
and UARTFBRD registers form an internal 30-bit register. This internal register is only updated
when a write operation to UARTLCRH is performed, so any changes to the baud-rate divisor must
be followed by a write to the UARTLCRH register for the changes to take effect.
To update the baud-rate registers, there are four possible sequences:
■ UARTIBRD write, UARTFBRD write, and UARTLCRH write
■ UARTFBRD write, UARTIBRD write, and UARTLCRH write
■ UARTIBRD write and UARTLCRH write
■ UARTFBRD write and UARTLCRH write
11.3.3
Data Transmission
Data received or transmitted is stored in two 16-byte FIFOs, though the receive FIFO has an extra
four bits per character for status information. For transmission, data is written into the transmit FIFO.
If the UART is enabled, it causes a data frame to start transmitting with the parameters indicated
in the UARTLCRH register. Data continues to be transmitted until there is no data left in the transmit
FIFO. The BUSY bit in the UART Flag (UARTFR) register (see page 372) is asserted as soon as
data is written to the transmit FIFO (that is, if the FIFO is non-empty) and remains asserted while
data is being transmitted. The BUSY bit is negated only when the transmit FIFO is empty, and the
last character has been transmitted from the shift register, including the stop bits. The UART can
indicate that it is busy even though the UART may no longer be enabled.
When the receiver is idle (the UnRx is continuously 1) and the data input goes Low (a start bit has
been received), the receive counter begins running and data is sampled on the eighth cycle of
Baud16 (described in “Transmit/Receive Logic” on page 362).
The start bit is valid and recognized if UnRx is still low on the eighth cycle of Baud16, otherwise it
is ignored. After a valid start bit is detected, successive data bits are sampled on every 16th cycle
of Baud16 (that is, one bit period later) according to the programmed length of the data characters.
The parity bit is then checked if parity mode was enabled. Data length and parity are defined in the
UARTLCRH register.
Lastly, a valid stop bit is confirmed if UnRx is High, otherwise a framing error has occurred. When
a full word is received, the data is stored in the receive FIFO, with any error bits associated with
that word.
11.3.4
FIFO Operation
The UART has two 16-entry FIFOs; one for transmit and one for receive. Both FIFOs are accessed
via the UART Data (UARTDR) register (see page 368). Read operations of the UARTDR register
return a 12-bit value consisting of 8 data bits and 4 error flags while write operations place 8-bit data
in the transmit FIFO.
Out of reset, both FIFOs are disabled and act as 1-byte-deep holding registers. The FIFOs are
enabled by setting the FEN bit in UARTLCRH (page 376).
FIFO status can be monitored via the UART Flag (UARTFR) register (see page 372) and the UART
Receive Status (UARTRSR) register. Hardware monitors empty, full and overrun conditions. The
UARTFR register contains empty and full flags (TXFE, TXFF, RXFE, and RXFF bits) and the
UARTRSR register shows overrun status via the OE bit.
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The trigger points at which the FIFOs generate interrupts is controlled via the UART Interrupt FIFO
Level Select (UARTIFLS) register (see page 380). Both FIFOs can be individually configured to
trigger interrupts at different levels. Available configurations include 1/8, ¼, ½, ¾, and 7/8. For
example, if the ¼ option is selected for the receive FIFO, the UART generates a receive interrupt
after 4 data bytes are received. Out of reset, both FIFOs are configured to trigger an interrupt at the
½ mark.
11.3.5
Interrupts
The UART can generate interrupts when the following conditions are observed:
■ Overrun Error
■ Break Error
■ Parity Error
■ Framing Error
■ Receive Timeout
■ Transmit (when condition defined in the TXIFLSEL bit in the UARTIFLS register is met)
■ Receive (when condition defined in the RXIFLSEL bit in the UARTIFLS register is met)
All of the interrupt events are ORed together before being sent to the interrupt controller, so the
UART can only generate a single interrupt request to the controller at any given time. Software can
service multiple interrupt events in a single interrupt service routine by reading the UART Masked
Interrupt Status (UARTMIS) register (see page 385).
The interrupt events that can trigger a controller-level interrupt are defined in the UART Interrupt
Mask (UARTIM ) register (see page 382) by setting the corresponding IM bit to 1. If interrupts are
not used, the raw interrupt status is always visible via the UART Raw Interrupt Status (UARTRIS)
register (see page 384).
Interrupts are always cleared (for both the UARTMIS and UARTRIS registers) by setting the
corresponding bit in the UART Interrupt Clear (UARTICR) register (see page 386).
The receive interrupt changes state when one of the following events occurs:
■ If the FIFOs are enabled and the receive FIFO reaches the programmed trigger level, the RXRIS
bit is set. The receive interrupt is cleared by reading data from the receive FIFO until it becomes
less than the trigger level, or by clearing the interrupt by writing a 1 to the RXIC bit.
■ If the FIFOs are disabled (have a depth of one location) and data is received thereby filling the
location, the RXRIS bit is set. The receive interrupt is cleared by performing a single read of the
receive FIFO, or by clearing the interrupt by writing a 1 to the RXIC bit.
The transmit interrupt changes state when one of the following events occurs:
■ If the FIFOs are enabled and the transmit FIFO reaches the programmed trigger level, the TXRIS
bit is set. The transmit interrupt is cleared by writing data to the transmit FIFO until it becomes
greater than the trigger level, or by clearing the interrupt by writing a 1 to the TXIC bit.
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■ If the FIFOs are disabled (have a depth of one location) and there is no data present in the
transmitters single location, the TXRIS bit is set. It is cleared by performing a single write to the
transmit FIFO, or by clearing the interrupt by writing a 1 to the TXIC bit.
11.3.6
Loopback Operation
The UART can be placed into an internal loopback mode for diagnostic or debug work. This is
accomplished by setting the LBE bit in the UARTCTL register (see page 378). In loopback mode,
data transmitted on UnTx is received on the UnRx input.
11.4
Initialization and Configuration
To use the UARTs, the peripheral clock must be enabled by setting the UART0 or UART1 bits in the
RCGC1 register.
This section discusses the steps that are required to use a UART module. For this example, the
UART clock is assumed to be 20 MHz and the desired UART configuration is:
■ 115200 baud rate
■ Data length of 8 bits
■ One stop bit
■ No parity
■ FIFOs disabled
■ No interrupts
The first thing to consider when programming the UART is the baud-rate divisor (BRD), since the
UARTIBRD and UARTFBRD registers must be written before the UARTLCRH register. Using the
equation described in “Baud-Rate Generation” on page 362, the BRD can be calculated:
BRD = 20,000,000 / (16 * 115,200) = 10.8507
which means that the DIVINT field of the UARTIBRD register (see page 374) should be set to 10.
The value to be loaded into the UARTFBRD register (see page 375) is calculated by the equation:
UARTFBRD[DIVFRAC] = integer(0.8507 * 64 + 0.5) = 54
With the BRD values in hand, the UART configuration is written to the module in the following order:
1. Disable the UART by clearing the UARTEN bit in the UARTCTL register.
2. Write the integer portion of the BRD to the UARTIBRD register.
3. Write the fractional portion of the BRD to the UARTFBRD register.
4. Write the desired serial parameters to the UARTLCRH register (in this case, a value of
0x0000.0060).
5. Enable the UART by setting the UARTEN bit in the UARTCTL register.
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11.5
Register Map
Table 11-2 on page 366 lists the UART registers. The offset listed is a hexadecimal increment to the
register’s address, relative to that UART’s base address:
■ UART0: 0x4000.C000
■ UART1: 0x4000.D000
Note that the UART module clock must be enabled before the registers can be programmed (see
page 192). There must be a delay of 3 system clocks after the UART module clock is enabled before
any UART module registers are accessed.
Note:
The UART must be disabled (see the UARTEN bit in the UARTCTL register on page 378)
before any of the control registers are reprogrammed. When the UART is disabled during
a TX or RX operation, the current transaction is completed prior to the UART stopping.
Table 11-2. UART Register Map
Offset
Name
Type
Reset
Description
See
page
0x000
UARTDR
R/W
0x0000.0000
UART Data
368
0x004
UARTRSR/UARTECR
R/W
0x0000.0000
UART Receive Status/Error Clear
370
0x018
UARTFR
RO
0x0000.0090
UART Flag
372
0x024
UARTIBRD
R/W
0x0000.0000
UART Integer Baud-Rate Divisor
374
0x028
UARTFBRD
R/W
0x0000.0000
UART Fractional Baud-Rate Divisor
375
0x02C
UARTLCRH
R/W
0x0000.0000
UART Line Control
376
0x030
UARTCTL
R/W
0x0000.0300
UART Control
378
0x034
UARTIFLS
R/W
0x0000.0012
UART Interrupt FIFO Level Select
380
0x038
UARTIM
R/W
0x0000.0000
UART Interrupt Mask
382
0x03C
UARTRIS
RO
0x0000.000F
UART Raw Interrupt Status
384
0x040
UARTMIS
RO
0x0000.0000
UART Masked Interrupt Status
385
0x044
UARTICR
W1C
0x0000.0000
UART Interrupt Clear
386
0xFD0
UARTPeriphID4
RO
0x0000.0000
UART Peripheral Identification 4
388
0xFD4
UARTPeriphID5
RO
0x0000.0000
UART Peripheral Identification 5
389
0xFD8
UARTPeriphID6
RO
0x0000.0000
UART Peripheral Identification 6
390
0xFDC
UARTPeriphID7
RO
0x0000.0000
UART Peripheral Identification 7
391
0xFE0
UARTPeriphID0
RO
0x0000.0011
UART Peripheral Identification 0
392
0xFE4
UARTPeriphID1
RO
0x0000.0000
UART Peripheral Identification 1
393
0xFE8
UARTPeriphID2
RO
0x0000.0018
UART Peripheral Identification 2
394
0xFEC
UARTPeriphID3
RO
0x0000.0001
UART Peripheral Identification 3
395
0xFF0
UARTPCellID0
RO
0x0000.000D
UART PrimeCell Identification 0
396
0xFF4
UARTPCellID1
RO
0x0000.00F0
UART PrimeCell Identification 1
397
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Table 11-2. UART Register Map (continued)
Offset
Name
0xFF8
0xFFC
11.6
Description
See
page
Type
Reset
UARTPCellID2
RO
0x0000.0005
UART PrimeCell Identification 2
398
UARTPCellID3
RO
0x0000.00B1
UART PrimeCell Identification 3
399
Register Descriptions
The remainder of this section lists and describes the UART registers, in numerical order by address
offset.
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Register 1: UART Data (UARTDR), offset 0x000
Important: This register is read-sensitive. See the register description for details.
This register is the data register (the interface to the FIFOs).
When FIFOs are enabled, data written to this location is pushed onto the transmit FIFO. If FIFOs
are disabled, data is stored in the transmitter holding register (the bottom word of the transmit FIFO).
A write to this register initiates a transmission from the UART.
For received data, if the FIFO is enabled, the data byte and the 4-bit status (break, frame, parity,
and overrun) is pushed onto the 12-bit wide receive FIFO. If FIFOs are disabled, the data byte and
status are stored in the receiving holding register (the bottom word of the receive FIFO). The received
data can be retrieved by reading this register.
UART Data (UARTDR)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0x000
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
OE
BE
PE
FE
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
DATA
Bit/Field
Name
Type
Reset
Description
31:12
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
11
OE
RO
0
UART Overrun Error
The OE values are defined as follows:
Value Description
10
BE
RO
0
0
There has been no data loss due to a FIFO overrun.
1
New data was received when the FIFO was full, resulting in
data loss.
UART Break Error
This bit is set to 1 when a break condition is detected, indicating that
the receive data input was held Low for longer than a full-word
transmission time (defined as start, data, parity, and stop bits).
In FIFO mode, this error is associated with the character at the top of
the FIFO. When a break occurs, only one 0 character is loaded into the
FIFO. The next character is only enabled after the received data input
goes to a 1 (marking state) and the next valid start bit is received.
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Bit/Field
Name
Type
Reset
9
PE
RO
0
Description
UART Parity Error
This bit is set to 1 when the parity of the received data character does
not match the parity defined by bits 2 and 7 of the UARTLCRH register.
In FIFO mode, this error is associated with the character at the top of
the FIFO.
8
FE
RO
0
UART Framing Error
This bit is set to 1 when the received character does not have a valid
stop bit (a valid stop bit is 1).
7:0
DATA
R/W
0
Data Transmitted or Received
When written, the data that is to be transmitted via the UART. When
read, the data that was received by the UART.
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Register 2: UART Receive Status/Error Clear (UARTRSR/UARTECR), offset
0x004
The UARTRSR/UARTECR register is the receive status register/error clear register.
In addition to the UARTDR register, receive status can also be read from the UARTRSR register.
If the status is read from this register, then the status information corresponds to the entry read from
UARTDR prior to reading UARTRSR. The status information for overrun is set immediately when
an overrun condition occurs.
The UARTRSR register cannot be written.
A write of any value to the UARTECR register clears the framing, parity, break, and overrun errors.
All the bits are cleared to 0 on reset.
Reads
UART Receive Status/Error Clear (UARTRSR/UARTECR)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0x004
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
3
2
1
0
OE
BE
PE
FE
RO
0
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:4
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
3
OE
RO
0
UART Overrun Error
When this bit is set to 1, data is received and the FIFO is already full.
This bit is cleared to 0 by a write to UARTECR.
The FIFO contents remain valid since no further data is written when
the FIFO is full, only the contents of the shift register are overwritten.
The CPU must now read the data in order to empty the FIFO.
2
BE
RO
0
UART Break Error
This bit is set to 1 when a break condition is detected, indicating that
the received data input was held Low for longer than a full-word
transmission time (defined as start, data, parity, and stop bits).
This bit is cleared to 0 by a write to UARTECR.
In FIFO mode, this error is associated with the character at the top of
the FIFO. When a break occurs, only one 0 character is loaded into the
FIFO. The next character is only enabled after the receive data input
goes to a 1 (marking state) and the next valid start bit is received.
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Bit/Field
Name
Type
Reset
1
PE
RO
0
Description
UART Parity Error
This bit is set to 1 when the parity of the received data character does
not match the parity defined by bits 2 and 7 of the UARTLCRH register.
This bit is cleared to 0 by a write to UARTECR.
0
FE
RO
0
UART Framing Error
This bit is set to 1 when the received character does not have a valid
stop bit (a valid stop bit is 1).
This bit is cleared to 0 by a write to UARTECR.
In FIFO mode, this error is associated with the character at the top of
the FIFO.
Writes
UART Receive Status/Error Clear (UARTRSR/UARTECR)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0x004
Type WO, reset 0x0000.0000
31
30
29
28
27
26
25
24
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
15
14
13
12
11
10
9
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
23
22
21
20
19
18
17
16
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
8
7
6
5
4
3
2
1
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
reserved
Type
Reset
reserved
Type
Reset
DATA
WO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
WO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
DATA
WO
0
Error Clear
A write to this register of any data clears the framing, parity, break, and
overrun flags.
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Universal Asynchronous Receivers/Transmitters (UARTs)
Register 3: UART Flag (UARTFR), offset 0x018
The UARTFR register is the flag register. After reset, the TXFF, RXFF, and BUSY bits are 0, and
TXFE and RXFE bits are 1.
UART Flag (UARTFR)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0x018
Type RO, reset 0x0000.0090
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
TXFE
RXFF
TXFF
RXFE
BUSY
RO
1
RO
0
RO
0
RO
1
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
reserved
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7
TXFE
RO
1
UART Transmit FIFO Empty
The meaning of this bit depends on the state of the FEN bit in the
UARTLCRH register.
If the FIFO is disabled (FEN is 0), this bit is set when the transmit holding
register is empty.
If the FIFO is enabled (FEN is 1), this bit is set when the transmit FIFO
is empty.
6
RXFF
RO
0
UART Receive FIFO Full
The meaning of this bit depends on the state of the FEN bit in the
UARTLCRH register.
If the FIFO is disabled, this bit is set when the receive holding register
is full.
If the FIFO is enabled, this bit is set when the receive FIFO is full.
5
TXFF
RO
0
UART Transmit FIFO Full
The meaning of this bit depends on the state of the FEN bit in the
UARTLCRH register.
If the FIFO is disabled, this bit is set when the transmit holding register
is full.
If the FIFO is enabled, this bit is set when the transmit FIFO is full.
4
RXFE
RO
1
UART Receive FIFO Empty
The meaning of this bit depends on the state of the FEN bit in the
UARTLCRH register.
If the FIFO is disabled, this bit is set when the receive holding register
is empty.
If the FIFO is enabled, this bit is set when the receive FIFO is empty.
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Bit/Field
Name
Type
Reset
Description
3
BUSY
RO
0
UART Busy
When this bit is 1, the UART is busy transmitting data. This bit remains
set until the complete byte, including all stop bits, has been sent from
the shift register.
This bit is set as soon as the transmit FIFO becomes non-empty
(regardless of whether UART is enabled).
2:0
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
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Texas Instruments-Production Data
Universal Asynchronous Receivers/Transmitters (UARTs)
Register 4: UART Integer Baud-Rate Divisor (UARTIBRD), offset 0x024
The UARTIBRD register is the integer part of the baud-rate divisor value. All the bits are cleared
on reset. The minimum possible divide ratio is 1 (when UARTIBRD=0), in which case the UARTFBRD
register is ignored. When changing the UARTIBRD register, the new value does not take effect until
transmission/reception of the current character is complete. Any changes to the baud-rate divisor
must be followed by a write to the UARTLCRH register. See “Baud-Rate Generation” on page 362
for configuration details.
UART Integer Baud-Rate Divisor (UARTIBRD)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0x024
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
DIVINT
Type
Reset
Bit/Field
Name
Type
Reset
31:16
reserved
RO
0
15:0
DIVINT
R/W
0x0000
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
Integer Baud-Rate Divisor
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Register 5: UART Fractional Baud-Rate Divisor (UARTFBRD), offset 0x028
The UARTFBRD register is the fractional part of the baud-rate divisor value. All the bits are cleared
on reset. When changing the UARTFBRD register, the new value does not take effect until
transmission/reception of the current character is complete. Any changes to the baud-rate divisor
must be followed by a write to the UARTLCRH register. See “Baud-Rate Generation” on page 362
for configuration details.
UART Fractional Baud-Rate Divisor (UARTFBRD)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0x028
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
DIVFRAC
R/W
0
Bit/Field
Name
Type
Reset
Description
31:6
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
5:0
DIVFRAC
R/W
0x000
Fractional Baud-Rate Divisor
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Texas Instruments-Production Data
Universal Asynchronous Receivers/Transmitters (UARTs)
Register 6: UART Line Control (UARTLCRH), offset 0x02C
The UARTLCRH register is the line control register. Serial parameters such as data length, parity,
and stop bit selection are implemented in this register.
When updating the baud-rate divisor (UARTIBRD and/or UARTIFRD), the UARTLCRH register
must also be written. The write strobe for the baud-rate divisor registers is tied to the UARTLCRH
register.
UART Line Control (UARTLCRH)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0x02C
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
SPS
RO
0
RO
0
RO
0
RO
0
R/W
0
5
WLEN
R/W
0
R/W
0
4
3
2
1
0
FEN
STP2
EPS
PEN
BRK
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7
SPS
R/W
0
UART Stick Parity Select
When bits 1, 2, and 7 of UARTLCRH are set, the parity bit is transmitted
and checked as a 0. When bits 1 and 7 are set and 2 is cleared, the
parity bit is transmitted and checked as a 1.
When this bit is cleared, stick parity is disabled.
6:5
WLEN
R/W
0
UART Word Length
The bits indicate the number of data bits transmitted or received in a
frame as follows:
Value Description
0x3 8 bits
0x2 7 bits
0x1 6 bits
0x0 5 bits (default)
4
FEN
R/W
0
UART Enable FIFOs
If this bit is set to 1, transmit and receive FIFO buffers are enabled (FIFO
mode).
When cleared to 0, FIFOs are disabled (Character mode). The FIFOs
become 1-byte-deep holding registers.
3
STP2
R/W
0
UART Two Stop Bits Select
If this bit is set to 1, two stop bits are transmitted at the end of a frame.
The receive logic does not check for two stop bits being received.
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Bit/Field
Name
Type
Reset
2
EPS
R/W
0
Description
UART Even Parity Select
If this bit is set to 1, even parity generation and checking is performed
during transmission and reception, which checks for an even number
of 1s in data and parity bits.
When cleared to 0, then odd parity is performed, which checks for an
odd number of 1s.
This bit has no effect when parity is disabled by the PEN bit.
1
PEN
R/W
0
UART Parity Enable
If this bit is set to 1, parity checking and generation is enabled; otherwise,
parity is disabled and no parity bit is added to the data frame.
0
BRK
R/W
0
UART Send Break
If this bit is set to 1, a Low level is continually output on the UnTX output,
after completing transmission of the current character. For the proper
execution of the break command, the software must set this bit for at
least two frames (character periods). For normal use, this bit must be
cleared to 0.
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Universal Asynchronous Receivers/Transmitters (UARTs)
Register 7: UART Control (UARTCTL), offset 0x030
The UARTCTL register is the control register. All the bits are cleared on reset except for the
Transmit Enable (TXE) and Receive Enable (RXE) bits, which are set to 1.
To enable the UART module, the UARTEN bit must be set to 1. If software requires a configuration
change in the module, the UARTEN bit must be cleared before the configuration changes are written.
If the UART is disabled during a transmit or receive operation, the current transaction is completed
prior to the UART stopping.
Note:
The UARTCTL register should not be changed while the UART is enabled or else the results
are unpredictable. The following sequence is recommended for making changes to the
UARTCTL register.
1. Disable the UART.
2. Wait for the end of transmission or reception of the current character.
3. Flush the transmit FIFO by disabling bit 4 (FEN) in the line control register (UARTLCRH).
4. Reprogram the control register.
5. Enable the UART.
UART Control (UARTCTL)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0x030
Type R/W, reset 0x0000.0300
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
RXE
TXE
LBE
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
1
R/W
1
R/W
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
reserved
UARTEN
R/W
0
Bit/Field
Name
Type
Reset
Description
31:10
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
9
RXE
R/W
1
UART Receive Enable
If this bit is set to 1, the receive section of the UART is enabled. When
the UART is disabled in the middle of a receive, it completes the current
character before stopping.
Note:
8
TXE
R/W
1
To enable reception, the UARTEN bit must also be set.
UART Transmit Enable
If this bit is set to 1, the transmit section of the UART is enabled. When
the UART is disabled in the middle of a transmission, it completes the
current character before stopping.
Note:
To enable transmission, the UARTEN bit must also be set.
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Bit/Field
Name
Type
Reset
7
LBE
R/W
0
Description
UART Loop Back Enable
If this bit is set to 1, the UnTX path is fed through the UnRX path.
6:1
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
0
UARTEN
R/W
0
UART Enable
If this bit is set to 1, the UART is enabled. When the UART is disabled
in the middle of transmission or reception, it completes the current
character before stopping.
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Universal Asynchronous Receivers/Transmitters (UARTs)
Register 8: UART Interrupt FIFO Level Select (UARTIFLS), offset 0x034
The UARTIFLS register is the interrupt FIFO level select register. You can use this register to define
the FIFO level at which the TXRIS and RXRIS bits in the UARTRIS register are triggered.
The interrupts are generated based on a transition through a level rather than being based on the
level. That is, the interrupts are generated when the fill level progresses through the trigger level.
For example, if the receive trigger level is set to the half-way mark, the interrupt is triggered as the
module is receiving the 9th character.
Out of reset, the TXIFLSEL and RXIFLSEL bits are configured so that the FIFOs trigger an interrupt
at the half-way mark.
UART Interrupt FIFO Level Select (UARTIFLS)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0x034
Type R/W, reset 0x0000.0012
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
RXIFLSEL
R/W
1
TXIFLSEL
R/W
1
R/W
0
Bit/Field
Name
Type
Reset
Description
31:6
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
5:3
RXIFLSEL
R/W
0x2
UART Receive Interrupt FIFO Level Select
The trigger points for the receive interrupt are as follows:
Value
Description
0x0
RX FIFO ≥ ⅛ full
0x1
RX FIFO ≥ ¼ full
0x2
RX FIFO ≥ ½ full (default)
0x3
RX FIFO ≥ ¾ full
0x4
RX FIFO ≥ ⅞ full
0x5-0x7 Reserved
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Texas Instruments-Production Data
®
Stellaris LM3S828 Microcontroller
Bit/Field
Name
Type
Reset
2:0
TXIFLSEL
R/W
0x2
Description
UART Transmit Interrupt FIFO Level Select
The trigger points for the transmit interrupt are as follows:
Value
Description
0x0
TX FIFO ≤ ⅞ empty
0x1
TX FIFO ≤ ¾ empty
0x2
TX FIFO ≤ ½ empty (default)
0x3
TX FIFO ≤ ¼ empty
0x4
TX FIFO ≤ ⅛ empty
0x5-0x7 Reserved
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Universal Asynchronous Receivers/Transmitters (UARTs)
Register 9: UART Interrupt Mask (UARTIM), offset 0x038
The UARTIM register is the interrupt mask set/clear register.
On a read, this register gives the current value of the mask on the relevant interrupt. Writing a 1 to
a bit allows the corresponding raw interrupt signal to be routed to the interrupt controller. Writing a
0 prevents the raw interrupt signal from being sent to the interrupt controller.
UART Interrupt Mask (UARTIM)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0x038
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
3
2
1
0
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
15
14
RO
0
RO
0
RO
0
13
12
11
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
10
9
8
7
6
5
4
OEIM
BEIM
PEIM
FEIM
RTIM
TXIM
RXIM
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
RO
0
reserved
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:11
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
10
OEIM
R/W
0
UART Overrun Error Interrupt Mask
On a read, the current mask for the OEIM interrupt is returned.
Setting this bit to 1 promotes the OEIM interrupt to the interrupt controller.
9
BEIM
R/W
0
UART Break Error Interrupt Mask
On a read, the current mask for the BEIM interrupt is returned.
Setting this bit to 1 promotes the BEIM interrupt to the interrupt controller.
8
PEIM
R/W
0
UART Parity Error Interrupt Mask
On a read, the current mask for the PEIM interrupt is returned.
Setting this bit to 1 promotes the PEIM interrupt to the interrupt controller.
7
FEIM
R/W
0
UART Framing Error Interrupt Mask
On a read, the current mask for the FEIM interrupt is returned.
Setting this bit to 1 promotes the FEIM interrupt to the interrupt controller.
6
RTIM
R/W
0
UART Receive Time-Out Interrupt Mask
On a read, the current mask for the RTIM interrupt is returned.
Setting this bit to 1 promotes the RTIM interrupt to the interrupt controller.
5
TXIM
R/W
0
UART Transmit Interrupt Mask
On a read, the current mask for the TXIM interrupt is returned.
Setting this bit to 1 promotes the TXIM interrupt to the interrupt controller.
4
RXIM
R/W
0
UART Receive Interrupt Mask
On a read, the current mask for the RXIM interrupt is returned.
Setting this bit to 1 promotes the RXIM interrupt to the interrupt controller.
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Texas Instruments-Production Data
®
Stellaris LM3S828 Microcontroller
Bit/Field
Name
Type
Reset
Description
3:0
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
June 18, 2012
383
Texas Instruments-Production Data
Universal Asynchronous Receivers/Transmitters (UARTs)
Register 10: UART Raw Interrupt Status (UARTRIS), offset 0x03C
The UARTRIS register is the raw interrupt status register. On a read, this register gives the current
raw status value of the corresponding interrupt. A write has no effect.
UART Raw Interrupt Status (UARTRIS)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0x03C
Type RO, reset 0x0000.000F
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
OERIS
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
BERIS
PERIS
FERIS
RTRIS
TXRIS
RXRIS
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
1
RO
1
RO
1
RO
1
reserved
Type
Reset
reserved
Type
Reset
RO
0
reserved
Bit/Field
Name
Type
Reset
Description
31:11
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
10
OERIS
RO
0
UART Overrun Error Raw Interrupt Status
Gives the raw interrupt state (prior to masking) of this interrupt.
9
BERIS
RO
0
UART Break Error Raw Interrupt Status
Gives the raw interrupt state (prior to masking) of this interrupt.
8
PERIS
RO
0
UART Parity Error Raw Interrupt Status
Gives the raw interrupt state (prior to masking) of this interrupt.
7
FERIS
RO
0
UART Framing Error Raw Interrupt Status
Gives the raw interrupt state (prior to masking) of this interrupt.
6
RTRIS
RO
0
UART Receive Time-Out Raw Interrupt Status
Gives the raw interrupt state (prior to masking) of this interrupt.
5
TXRIS
RO
0
UART Transmit Raw Interrupt Status
Gives the raw interrupt state (prior to masking) of this interrupt.
4
RXRIS
RO
0
UART Receive Raw Interrupt Status
Gives the raw interrupt state (prior to masking) of this interrupt.
3:0
reserved
RO
0xF
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
384
June 18, 2012
Texas Instruments-Production Data
®
Stellaris LM3S828 Microcontroller
Register 11: UART Masked Interrupt Status (UARTMIS), offset 0x040
The UARTMIS register is the masked interrupt status register. On a read, this register gives the
current masked status value of the corresponding interrupt. A write has no effect.
UART Masked Interrupt Status (UARTMIS)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0x040
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
OEMIS
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
BEMIS
PEMIS
FEMIS
RTMIS
TXMIS
RXMIS
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
reserved
Bit/Field
Name
Type
Reset
Description
31:11
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
10
OEMIS
RO
0
UART Overrun Error Masked Interrupt Status
Gives the masked interrupt state of this interrupt.
9
BEMIS
RO
0
UART Break Error Masked Interrupt Status
Gives the masked interrupt state of this interrupt.
8
PEMIS
RO
0
UART Parity Error Masked Interrupt Status
Gives the masked interrupt state of this interrupt.
7
FEMIS
RO
0
UART Framing Error Masked Interrupt Status
Gives the masked interrupt state of this interrupt.
6
RTMIS
RO
0
UART Receive Time-Out Masked Interrupt Status
Gives the masked interrupt state of this interrupt.
5
TXMIS
RO
0
UART Transmit Masked Interrupt Status
Gives the masked interrupt state of this interrupt.
4
RXMIS
RO
0
UART Receive Masked Interrupt Status
Gives the masked interrupt state of this interrupt.
3:0
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
June 18, 2012
385
Texas Instruments-Production Data
Universal Asynchronous Receivers/Transmitters (UARTs)
Register 12: UART Interrupt Clear (UARTICR), offset 0x044
The UARTICR register is the interrupt clear register. On a write of 1, the corresponding interrupt
(both raw interrupt and masked interrupt, if enabled) is cleared. A write of 0 has no effect.
UART Interrupt Clear (UARTICR)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0x044
Type W1C, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
OEIC
RO
0
RO
0
RO
0
RO
0
W1C
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
BEIC
PEIC
FEIC
RTIC
TXIC
RXIC
W1C
0
W1C
0
W1C
0
W1C
0
W1C
0
W1C
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
reserved
Bit/Field
Name
Type
Reset
Description
31:11
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
10
OEIC
W1C
0
Overrun Error Interrupt Clear
The OEIC values are defined as follows:
Value Description
9
BEIC
W1C
0
0
No effect on the interrupt.
1
Clears interrupt.
Break Error Interrupt Clear
The BEIC values are defined as follows:
Value Description
8
PEIC
W1C
0
0
No effect on the interrupt.
1
Clears interrupt.
Parity Error Interrupt Clear
The PEIC values are defined as follows:
Value Description
7
FEIC
W1C
0
0
No effect on the interrupt.
1
Clears interrupt.
Framing Error Interrupt Clear
The FEIC values are defined as follows:
Value Description
0
No effect on the interrupt.
1
Clears interrupt.
386
June 18, 2012
Texas Instruments-Production Data
®
Stellaris LM3S828 Microcontroller
Bit/Field
Name
Type
Reset
6
RTIC
W1C
0
Description
Receive Time-Out Interrupt Clear
The RTIC values are defined as follows:
Value Description
5
TXIC
W1C
0
0
No effect on the interrupt.
1
Clears interrupt.
Transmit Interrupt Clear
The TXIC values are defined as follows:
Value Description
4
RXIC
W1C
0
0
No effect on the interrupt.
1
Clears interrupt.
Receive Interrupt Clear
The RXIC values are defined as follows:
Value Description
3:0
reserved
RO
0x00
0
No effect on the interrupt.
1
Clears interrupt.
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
June 18, 2012
387
Texas Instruments-Production Data
Universal Asynchronous Receivers/Transmitters (UARTs)
Register 13: UART Peripheral Identification 4 (UARTPeriphID4), offset 0xFD0
The UARTPeriphIDn registers are hard-coded and the fields within the registers determine the
reset values.
UART Peripheral Identification 4 (UARTPeriphID4)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0xFD0
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
PID4
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID4
RO
0x0000
UART Peripheral ID Register[7:0]
Can be used by software to identify the presence of this peripheral.
388
June 18, 2012
Texas Instruments-Production Data
®
Stellaris LM3S828 Microcontroller
Register 14: UART Peripheral Identification 5 (UARTPeriphID5), offset 0xFD4
The UARTPeriphIDn registers are hard-coded and the fields within the registers determine the
reset values.
UART Peripheral Identification 5 (UARTPeriphID5)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0xFD4
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
PID5
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID5
RO
0x0000
UART Peripheral ID Register[15:8]
Can be used by software to identify the presence of this peripheral.
June 18, 2012
389
Texas Instruments-Production Data
Universal Asynchronous Receivers/Transmitters (UARTs)
Register 15: UART Peripheral Identification 6 (UARTPeriphID6), offset 0xFD8
The UARTPeriphIDn registers are hard-coded and the fields within the registers determine the
reset values.
UART Peripheral Identification 6 (UARTPeriphID6)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0xFD8
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
PID6
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID6
RO
0x0000
UART Peripheral ID Register[23:16]
Can be used by software to identify the presence of this peripheral.
390
June 18, 2012
Texas Instruments-Production Data
®
Stellaris LM3S828 Microcontroller
Register 16: UART Peripheral Identification 7 (UARTPeriphID7), offset 0xFDC
The UARTPeriphIDn registers are hard-coded and the fields within the registers determine the
reset values.
UART Peripheral Identification 7 (UARTPeriphID7)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0xFDC
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
PID7
RO
0
Bit/Field
Name
Type
Reset
31:8
reserved
RO
0
7:0
PID7
RO
0x0000
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
UART Peripheral ID Register[31:24]
Can be used by software to identify the presence of this peripheral.
June 18, 2012
391
Texas Instruments-Production Data
Universal Asynchronous Receivers/Transmitters (UARTs)
Register 17: UART Peripheral Identification 0 (UARTPeriphID0), offset 0xFE0
The UARTPeriphIDn registers are hard-coded and the fields within the registers determine the
reset values.
UART Peripheral Identification 0 (UARTPeriphID0)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0xFE0
Type RO, reset 0x0000.0011
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
1
RO
0
RO
0
RO
0
RO
1
reserved
Type
Reset
reserved
Type
Reset
PID0
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID0
RO
0x11
UART Peripheral ID Register[7:0]
Can be used by software to identify the presence of this peripheral.
392
June 18, 2012
Texas Instruments-Production Data
®
Stellaris LM3S828 Microcontroller
Register 18: UART Peripheral Identification 1 (UARTPeriphID1), offset 0xFE4
The UARTPeriphIDn registers are hard-coded and the fields within the registers determine the
reset values.
UART Peripheral Identification 1 (UARTPeriphID1)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0xFE4
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
PID1
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID1
RO
0x00
UART Peripheral ID Register[15:8]
Can be used by software to identify the presence of this peripheral.
June 18, 2012
393
Texas Instruments-Production Data
Universal Asynchronous Receivers/Transmitters (UARTs)
Register 19: UART Peripheral Identification 2 (UARTPeriphID2), offset 0xFE8
The UARTPeriphIDn registers are hard-coded and the fields within the registers determine the
reset values.
UART Peripheral Identification 2 (UARTPeriphID2)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0xFE8
Type RO, reset 0x0000.0018
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
1
RO
1
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
PID2
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID2
RO
0x18
UART Peripheral ID Register[23:16]
Can be used by software to identify the presence of this peripheral.
394
June 18, 2012
Texas Instruments-Production Data
®
Stellaris LM3S828 Microcontroller
Register 20: UART Peripheral Identification 3 (UARTPeriphID3), offset 0xFEC
The UARTPeriphIDn registers are hard-coded and the fields within the registers determine the
reset values.
UART Peripheral Identification 3 (UARTPeriphID3)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0xFEC
Type RO, reset 0x0000.0001
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
1
reserved
Type
Reset
reserved
Type
Reset
PID3
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID3
RO
0x01
UART Peripheral ID Register[31:24]
Can be used by software to identify the presence of this peripheral.
June 18, 2012
395
Texas Instruments-Production Data
Universal Asynchronous Receivers/Transmitters (UARTs)
Register 21: UART PrimeCell Identification 0 (UARTPCellID0), offset 0xFF0
The UARTPCellIDn registers are hard-coded and the fields within the registers determine the reset
values.
UART PrimeCell Identification 0 (UARTPCellID0)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0xFF0
Type RO, reset 0x0000.000D
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
1
RO
1
RO
0
RO
1
reserved
Type
Reset
reserved
Type
Reset
CID0
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
CID0
RO
0x0D
UART PrimeCell ID Register[7:0]
Provides software a standard cross-peripheral identification system.
396
June 18, 2012
Texas Instruments-Production Data
®
Stellaris LM3S828 Microcontroller
Register 22: UART PrimeCell Identification 1 (UARTPCellID1), offset 0xFF4
The UARTPCellIDn registers are hard-coded and the fields within the registers determine the reset
values.
UART PrimeCell Identification 1 (UARTPCellID1)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0xFF4
Type RO, reset 0x0000.00F0
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
1
RO
1
RO
1
RO
1
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
CID1
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
CID1
RO
0xF0
UART PrimeCell ID Register[15:8]
Provides software a standard cross-peripheral identification system.
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Register 23: UART PrimeCell Identification 2 (UARTPCellID2), offset 0xFF8
The UARTPCellIDn registers are hard-coded and the fields within the registers determine the reset
values.
UART PrimeCell Identification 2 (UARTPCellID2)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0xFF8
Type RO, reset 0x0000.0005
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
1
RO
0
RO
1
reserved
Type
Reset
reserved
Type
Reset
CID2
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
CID2
RO
0x05
UART PrimeCell ID Register[23:16]
Provides software a standard cross-peripheral identification system.
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Register 24: UART PrimeCell Identification 3 (UARTPCellID3), offset 0xFFC
The UARTPCellIDn registers are hard-coded and the fields within the registers determine the reset
values.
UART PrimeCell Identification 3 (UARTPCellID3)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
Offset 0xFFC
Type RO, reset 0x0000.00B1
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
1
RO
0
RO
1
RO
1
RO
0
RO
0
RO
0
RO
1
reserved
Type
Reset
reserved
Type
Reset
CID3
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
CID3
RO
0xB1
UART PrimeCell ID Register[31:24]
Provides software a standard cross-peripheral identification system.
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Synchronous Serial Interface (SSI)
12
Synchronous Serial Interface (SSI)
®
The Stellaris Synchronous Serial Interface (SSI) is a master or slave interface for synchronous
serial communication with peripheral devices that have either Freescale SPI, MICROWIRE, or Texas
Instruments synchronous serial interfaces.
The Stellaris SSI module has the following features:
■ Master or slave operation
■ Programmable clock bit rate and prescale
■ Separate transmit and receive FIFOs, 16 bits wide, 8 locations deep
■ Programmable interface operation for Freescale SPI, MICROWIRE, or Texas Instruments
synchronous serial interfaces
■ Programmable data frame size from 4 to 16 bits
■ Internal loopback test mode for diagnostic/debug testing
12.1
Block Diagram
Figure 12-1. SSI Module Block Diagram
Interrupt
Interrupt Control
SSIIM
SSIMIS
Control/ Status
SSIRIS
SSIICR
SSICR0
SSICR1
TxFIFO
8 x16
.
.
.
SSITx
SSISR
SSIRx
SSIDR
RxFIFO
8 x16
System Clock
SSIPCellID0
Identification
Registers
SSIPeriphID0 SSIPeriphID 4
SSIPCellID1
SSIPeriphID 1 SSIPeriphID 5
SSIPCellID2
SSIPeriphID 2 SSIPeriphID 6
SSIPCellID3
SSIPeriphID 3 SSIPeriphID7
12.2
Clock
Prescaler
Transmit /
Receive
Logic
SSIClk
SSIFss
.
.
.
SSICPSR
Signal Description
Table 12-1 on page 401 lists the external signals of the SSI module and describes the function of
each. The SSI signals are alternate functions for some GPIO signals and default to be GPIO signals
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at reset., with the exception of the SSI0Clk, SSI0Fss, SSI0Rx, and SSI0Tx pins which default
to the SSI function. The column in the table below titled "Pin Assignment" lists the possible GPIO
pin placements for the SSI signals. The AFSEL bit in the GPIO Alternate Function Select
(GPIOAFSEL) register (page 242) should be set to choose the SSI function. For more information
on configuring GPIOs, see “General-Purpose Input/Outputs (GPIOs)” on page 223.
Table 12-1. SSI Signals (48QFP)
a
Pin Name
Pin Number
Pin Type
Buffer Type
Description
SSIClk
19
I/O
TTL
SSI clock.
SSIFss
20
I/O
TTL
SSI frame.
SSIRx
21
I
TTL
SSI receive.
SSITx
22
O
TTL
SSI transmit.
a. The TTL designation indicates the pin has TTL-compatible voltage levels.
12.3
Functional Description
The SSI performs serial-to-parallel conversion on data received from a peripheral device. The CPU
accesses data, control, and status information. The transmit and receive paths are buffered with
internal FIFO memories allowing up to eight 16-bit values to be stored independently in both transmit
and receive modes.
12.3.1
Bit Rate Generation
The SSI includes a programmable bit rate clock divider and prescaler to generate the serial output
clock. Bit rates are supported to 1.5 MHz and higher, although maximum bit rate is determined by
peripheral devices.
The serial bit rate is derived by dividing down the input clock (FSysClk). The clock is first divided
by an even prescale value CPSDVSR from 2 to 254, which is programmed in the SSI Clock Prescale
(SSICPSR) register (see page 420). The clock is further divided by a value from 1 to 256, which is
1 + SCR, where SCR is the value programmed in the SSI Control0 (SSICR0) register (see page 413).
The frequency of the output clock SSIClk is defined by:
SSIClk = FSysClk / (CPSDVSR * (1 + SCR))
Note:
For master mode, the system clock must be at least two times faster than the SSIClk. For
slave mode, the system clock must be at least 12 times faster than the SSIClk.
See “Synchronous Serial Interface (SSI)” on page 493 to view SSI timing parameters.
12.3.2
FIFO Operation
12.3.2.1
Transmit FIFO
The common transmit FIFO is a 16-bit wide, 8-locations deep, first-in, first-out memory buffer. The
CPU writes data to the FIFO by writing the SSI Data (SSIDR) register (see page 417), and data is
stored in the FIFO until it is read out by the transmission logic.
When configured as a master or a slave, parallel data is written into the transmit FIFO prior to serial
conversion and transmission to the attached slave or master, respectively, through the SSITx pin.
In slave mode, the SSI transmits data each time the master initiates a transaction. If the transmit
FIFO is empty and the master initiates, the slave transmits the 8th most recent value in the transmit
FIFO. If less than 8 values have been written to the transmit FIFO since the SSI module clock was
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enabled using the SSI bit in the RGCG1 register, then 0 is transmitted. Care should be taken to
ensure that valid data is in the FIFO as needed. The SSI can be configured to generate an interrupt
or a µDMA request when the FIFO is empty.
12.3.2.2
Receive FIFO
The common receive FIFO is a 16-bit wide, 8-locations deep, first-in, first-out memory buffer.
Received data from the serial interface is stored in the buffer until read out by the CPU, which
accesses the read FIFO by reading the SSIDR register.
When configured as a master or slave, serial data received through the SSIRx pin is registered
prior to parallel loading into the attached slave or master receive FIFO, respectively.
12.3.3
Interrupts
The SSI can generate interrupts when the following conditions are observed:
■ Transmit FIFO service
■ Receive FIFO service
■ Receive FIFO time-out
■ Receive FIFO overrun
All of the interrupt events are ORed together before being sent to the interrupt controller, so the SSI
can only generate a single interrupt request to the controller at any given time. You can mask each
of the four individual maskable interrupts by setting the appropriate bits in the SSI Interrupt Mask
(SSIIM) register (see page 421). Setting the appropriate mask bit to 1 enables the interrupt.
Provision of the individual outputs, as well as a combined interrupt output, allows use of either a
global interrupt service routine, or modular device drivers to handle interrupts. The transmit and
receive dynamic dataflow interrupts have been separated from the status interrupts so that data
can be read or written in response to the FIFO trigger levels. The status of the individual interrupt
sources can be read from the SSI Raw Interrupt Status (SSIRIS) and SSI Masked Interrupt Status
(SSIMIS) registers (see page 423 and page 424, respectively).
12.3.4
Frame Formats
Each data frame is between 4 and 16 bits long, depending on the size of data programmed, and is
transmitted starting with the MSB. There are three basic frame types that can be selected:
■ Texas Instruments synchronous serial
■ Freescale SPI
■ MICROWIRE
For all three formats, the serial clock (SSIClk) is held inactive while the SSI is idle, and SSIClk
transitions at the programmed frequency only during active transmission or reception of data. The
idle state of SSIClk is utilized to provide a receive timeout indication that occurs when the receive
FIFO still contains data after a timeout period.
For Freescale SPI and MICROWIRE frame formats, the serial frame (SSIFss ) pin is active Low,
and is asserted (pulled down) during the entire transmission of the frame.
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For Texas Instruments synchronous serial frame format, the SSIFss pin is pulsed for one serial
clock period starting at its rising edge, prior to the transmission of each frame. For this frame format,
both the SSI and the off-chip slave device drive their output data on the rising edge of SSIClk, and
latch data from the other device on the falling edge.
Unlike the full-duplex transmission of the other two frame formats, the MICROWIRE format uses a
special master-slave messaging technique, which operates at half-duplex. In this mode, when a
frame begins, an 8-bit control message is transmitted to the off-chip slave. During this transmit, no
incoming data is received by the SSI. After the message has been sent, the off-chip slave decodes
it and, after waiting one serial clock after the last bit of the 8-bit control message has been sent,
responds with the requested data. The returned data can be 4 to 16 bits in length, making the total
frame length anywhere from 13 to 25 bits.
12.3.4.1
Texas Instruments Synchronous Serial Frame Format
Figure 12-2 on page 403 shows the Texas Instruments synchronous serial frame format for a single
transmitted frame.
Figure 12-2. TI Synchronous Serial Frame Format (Single Transfer)
SSIClk
SSIFss
SSITx/SSIRx
MSB
LSB
4 to 16 bits
In this mode, SSIClk and SSIFss are forced Low, and the transmit data line SSITx is tristated
whenever the SSI is idle. Once the bottom entry of the transmit FIFO contains data, SSIFss is
pulsed High for one SSIClk period. The value to be transmitted is also transferred from the transmit
FIFO to the serial shift register of the transmit logic. On the next rising edge of SSIClk, the MSB
of the 4 to 16-bit data frame is shifted out on the SSITx pin. Likewise, the MSB of the received data
is shifted onto the SSIRx pin by the off-chip serial slave device.
Both the SSI and the off-chip serial slave device then clock each data bit into their serial shifter on
the falling edge of each SSIClk. The received data is transferred from the serial shifter to the receive
FIFO on the first rising edge of SSIClk after the LSB has been latched.
Figure 12-3 on page 404 shows the Texas Instruments synchronous serial frame format when
back-to-back frames are transmitted.
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Figure 12-3. TI Synchronous Serial Frame Format (Continuous Transfer)
SSIClk
SSIFss
SSITx/SSIRx
MSB
LSB
4 to 16 bits
12.3.4.2
Freescale SPI Frame Format
The Freescale SPI interface is a four-wire interface where the SSIFss signal behaves as a slave
select. The main feature of the Freescale SPI format is that the inactive state and phase of the
SSIClk signal are programmable through the SPO and SPH bits within the SSISCR0 control register.
SPO Clock Polarity Bit
When the SPO clock polarity control bit is Low, it produces a steady state Low value on the SSIClk
pin. If the SPO bit is High, a steady state High value is placed on the SSIClk pin when data is not
being transferred.
SPH Phase Control Bit
The SPH phase control bit selects the clock edge that captures data and allows it to change state.
It has the most impact on the first bit transmitted by either allowing or not allowing a clock transition
before the first data capture edge. When the SPH phase control bit is Low, data is captured on the
first clock edge transition. If the SPH bit is High, data is captured on the second clock edge transition.
12.3.4.3
Freescale SPI Frame Format with SPO=0 and SPH=0
Single and continuous transmission signal sequences for Freescale SPI format with SPO=0 and
SPH=0 are shown in Figure 12-4 on page 404 and Figure 12-5 on page 405.
Figure 12-4. Freescale SPI Format (Single Transfer) with SPO=0 and SPH=0
SSIClk
SSIFss
SSIRx
LSB
MSB
Q
4 to 16 bits
SSITx
MSB
Note:
LSB
Q is undefined.
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Figure 12-5. Freescale SPI Format (Continuous Transfer) with SPO=0 and SPH=0
SSIClk
SSIFss
SSIRx LSB
LSB
MSB
MSB
4 to16 bits
SSITx LSB
MSB
LSB
MSB
In this configuration, during idle periods:
■ SSIClk is forced Low
■ SSIFss is forced High
■ The transmit data line SSITx is arbitrarily forced Low
■ When the SSI is configured as a master, it enables the SSIClk pad
■ When the SSI is configured as a slave, it disables the SSIClk pad
If the SSI is enabled and there is valid data within the transmit FIFO, the start of transmission is
signified by the SSIFss master signal being driven Low. This causes slave data to be enabled onto
the SSIRx input line of the master. The master SSITx output pad is enabled.
One half SSIClk period later, valid master data is transferred to the SSITx pin. Now that both the
master and slave data have been set, the SSIClk master clock pin goes High after one further half
SSIClk period.
The data is now captured on the rising and propagated on the falling edges of the SSIClk signal.
In the case of a single word transmission, after all bits of the data word have been transferred, the
SSIFss line is returned to its idle High state one SSIClk period after the last bit has been captured.
However, in the case of continuous back-to-back transmissions, the SSIFss signal must be pulsed
High between each data word transfer. This is because the slave select pin freezes the data in its
serial peripheral register and does not allow it to be altered if the SPH bit is logic zero. Therefore,
the master device must raise the SSIFss pin of the slave device between each data transfer to
enable the serial peripheral data write. On completion of the continuous transfer, the SSIFss pin
is returned to its idle state one SSIClk period after the last bit has been captured.
12.3.4.4
Freescale SPI Frame Format with SPO=0 and SPH=1
The transfer signal sequence for Freescale SPI format with SPO=0 and SPH=1 is shown in Figure
12-6 on page 406, which covers both single and continuous transfers.
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Figure 12-6. Freescale SPI Frame Format with SPO=0 and SPH=1
SSIClk
SSIFss
SSIRx
Q
MSB
Q
LSB
Q
4 to 16 bits
SSITx
LSB
MSB
Note:
Q is undefined.
In this configuration, during idle periods:
■ SSIClk is forced Low
■ SSIFss is forced High
■ The transmit data line SSITx is arbitrarily forced Low
■ When the SSI is configured as a master, it enables the SSIClk pad
■ When the SSI is configured as a slave, it disables the SSIClk pad
If the SSI is enabled and there is valid data within the transmit FIFO, the start of transmission is
signified by the SSIFss master signal being driven Low. The master SSITx output is enabled. After
a further one half SSIClk period, both master and slave valid data is enabled onto their respective
transmission lines. At the same time, the SSIClk is enabled with a rising edge transition.
Data is then captured on the falling edges and propagated on the rising edges of the SSIClk signal.
In the case of a single word transfer, after all bits have been transferred, the SSIFss line is returned
to its idle High state one SSIClk period after the last bit has been captured.
For continuous back-to-back transfers, the SSIFss pin is held Low between successive data words
and termination is the same as that of the single word transfer.
12.3.4.5
Freescale SPI Frame Format with SPO=1 and SPH=0
Single and continuous transmission signal sequences for Freescale SPI format with SPO=1 and
SPH=0 are shown in Figure 12-7 on page 406 and Figure 12-8 on page 407.
Figure 12-7. Freescale SPI Frame Format (Single Transfer) with SPO=1 and SPH=0
SSIClk
SSIFss
SSIRx
MSB
LSB
Q
4 to 16 bits
SSITx
LSB
MSB
Note:
Q is undefined.
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Figure 12-8. Freescale SPI Frame Format (Continuous Transfer) with SPO=1 and SPH=0
SSIClk
SSIFss
SSITx/SSIRx
MSB
LSB
LSB
MSB
4 to 16 bits
In this configuration, during idle periods:
■ SSIClk is forced High
■ SSIFss is forced High
■ The transmit data line SSITx is arbitrarily forced Low
■ When the SSI is configured as a master, it enables the SSIClk pad
■ When the SSI is configured as a slave, it disables the SSIClk pad
If the SSI is enabled and there is valid data within the transmit FIFO, the start of transmission is
signified by the SSIFss master signal being driven Low, which causes slave data to be immediately
transferred onto the SSIRx line of the master. The master SSITx output pad is enabled.
One half period later, valid master data is transferred to the SSITx line. Now that both the master
and slave data have been set, the SSIClk master clock pin becomes Low after one further half
SSIClk period. This means that data is captured on the falling edges and propagated on the rising
edges of the SSIClk signal.
In the case of a single word transmission, after all bits of the data word are transferred, the SSIFss
line is returned to its idle High state one SSIClk period after the last bit has been captured.
However, in the case of continuous back-to-back transmissions, the SSIFss signal must be pulsed
High between each data word transfer. This is because the slave select pin freezes the data in its
serial peripheral register and does not allow it to be altered if the SPH bit is logic zero. Therefore,
the master device must raise the SSIFss pin of the slave device between each data transfer to
enable the serial peripheral data write. On completion of the continuous transfer, the SSIFss pin
is returned to its idle state one SSIClk period after the last bit has been captured.
12.3.4.6
Freescale SPI Frame Format with SPO=1 and SPH=1
The transfer signal sequence for Freescale SPI format with SPO=1 and SPH=1 is shown in Figure
12-9 on page 408, which covers both single and continuous transfers.
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Figure 12-9. Freescale SPI Frame Format with SPO=1 and SPH=1
SSIClk
SSIFss
SSIRx
Q
MSB
LSB
Q
4 to 16 bits
MSB
SSITx
Note:
LSB
Q is undefined.
In this configuration, during idle periods:
■ SSIClk is forced High
■ SSIFss is forced High
■ The transmit data line SSITx is arbitrarily forced Low
■ When the SSI is configured as a master, it enables the SSIClk pad
■ When the SSI is configured as a slave, it disables the SSIClk pad
If the SSI is enabled and there is valid data within the transmit FIFO, the start of transmission is
signified by the SSIFss master signal being driven Low. The master SSITx output pad is enabled.
After a further one-half SSIClk period, both master and slave data are enabled onto their respective
transmission lines. At the same time, SSIClk is enabled with a falling edge transition. Data is then
captured on the rising edges and propagated on the falling edges of the SSIClk signal.
After all bits have been transferred, in the case of a single word transmission, the SSIFss line is
returned to its idle high state one SSIClk period after the last bit has been captured.
For continuous back-to-back transmissions, the SSIFss pin remains in its active Low state, until
the final bit of the last word has been captured, and then returns to its idle state as described above.
For continuous back-to-back transfers, the SSIFss pin is held Low between successive data words
and termination is the same as that of the single word transfer.
12.3.4.7
MICROWIRE Frame Format
Figure 12-10 on page 408 shows the MICROWIRE frame format, again for a single frame. Figure
12-11 on page 409 shows the same format when back-to-back frames are transmitted.
Figure 12-10. MICROWIRE Frame Format (Single Frame)
SSIClk
SSIFss
SSITx
LSB
MSB
8-bit control
SSIRx
0
MSB
LSB
4 to 16 bits
output data
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MICROWIRE format is very similar to SPI format, except that transmission is half-duplex instead of
full-duplex, using a master-slave message passing technique. Each serial transmission begins with
an 8-bit control word that is transmitted from the SSI to the off-chip slave device. During this
transmission, no incoming data is received by the SSI. After the message has been sent, the off-chip
slave decodes it and, after waiting one serial clock after the last bit of the 8-bit control message has
been sent, responds with the required data. The returned data is 4 to 16 bits in length, making the
total frame length anywhere from 13 to 25 bits.
In this configuration, during idle periods:
■ SSIClk is forced Low
■ SSIFss is forced High
■ The transmit data line SSITx is arbitrarily forced Low
A transmission is triggered by writing a control byte to the transmit FIFO. The falling edge of SSIFss
causes the value contained in the bottom entry of the transmit FIFO to be transferred to the serial
shift register of the transmit logic, and the MSB of the 8-bit control frame to be shifted out onto the
SSITx pin. SSIFss remains Low for the duration of the frame transmission. The SSIRx pin remains
tristated during this transmission.
The off-chip serial slave device latches each control bit into its serial shifter on the rising edge of
each SSIClk. After the last bit is latched by the slave device, the control byte is decoded during a
one clock wait-state, and the slave responds by transmitting data back to the SSI. Each bit is driven
onto the SSIRx line on the falling edge of SSIClk. The SSI in turn latches each bit on the rising
edge of SSIClk. At the end of the frame, for single transfers, the SSIFss signal is pulled High one
clock period after the last bit has been latched in the receive serial shifter, which causes the data
to be transferred to the receive FIFO.
Note:
The off-chip slave device can tristate the receive line either on the falling edge of SSIClk
after the LSB has been latched by the receive shifter, or when the SSIFss pin goes High.
For continuous transfers, data transmission begins and ends in the same manner as a single transfer.
However, the SSIFss line is continuously asserted (held Low) and transmission of data occurs
back-to-back. The control byte of the next frame follows directly after the LSB of the received data
from the current frame. Each of the received values is transferred from the receive shifter on the
falling edge of SSIClk, after the LSB of the frame has been latched into the SSI.
Figure 12-11. MICROWIRE Frame Format (Continuous Transfer)
SSIClk
SSIFss
SSITx
LSB
MSB
LSB
8-bit control
SSIRx
0
MSB
LSB
MSB
4 to 16 bits
output data
In the MICROWIRE mode, the SSI slave samples the first bit of receive data on the rising edge of
SSIClk after SSIFss has gone Low. Masters that drive a free-running SSIClk must ensure that
the SSIFss signal has sufficient setup and hold margins with respect to the rising edge of SSIClk.
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Figure 12-12 on page 410 illustrates these setup and hold time requirements. With respect to the
SSIClk rising edge on which the first bit of receive data is to be sampled by the SSI slave, SSIFss
must have a setup of at least two times the period of SSIClk on which the SSI operates. With
respect to the SSIClk rising edge previous to this edge, SSIFss must have a hold of at least one
SSIClk period.
Figure 12-12. MICROWIRE Frame Format, SSIFss Input Setup and Hold Requirements
tSetup=(2*tSSIClk)
tHold=tSSIClk
SSIClk
SSIFss
SSIRx
First RX data to be
sampled by SSI slave
12.4
Initialization and Configuration
To use the SSI, its peripheral clock must be enabled by setting the SSI bit in the RCGC1 register.
For each of the frame formats, the SSI is configured using the following steps:
1. Ensure that the SSE bit in the SSICR1 register is disabled before making any configuration
changes.
2. Select whether the SSI is a master or slave:
a. For master operations, set the SSICR1 register to 0x0000.0000.
b. For slave mode (output enabled), set the SSICR1 register to 0x0000.0004.
c. For slave mode (output disabled), set the SSICR1 register to 0x0000.000C.
3. Configure the clock prescale divisor by writing the SSICPSR register.
4. Write the SSICR0 register with the following configuration:
■ Serial clock rate (SCR)
■ Desired clock phase/polarity, if using Freescale SPI mode (SPH and SPO)
■ The protocol mode: Freescale SPI, TI SSF, MICROWIRE (FRF)
■ The data size (DSS)
5. Enable the SSI by setting the SSE bit in the SSICR1 register.
As an example, assume the SSI must be configured to operate with the following parameters:
■ Master operation
■ Freescale SPI mode (SPO=1, SPH=1)
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■ 1 Mbps bit rate
■ 8 data bits
Assuming the system clock is 20 MHz, the bit rate calculation would be:
FSSIClk = FSysClk / (CPSDVSR * (1 + SCR))
1x106 = 20x106 / (CPSDVSR * (1 + SCR))
In this case, if CPSDVSR=2, SCR must be 9.
The configuration sequence would be as follows:
1. Ensure that the SSE bit in the SSICR1 register is disabled.
2. Write the SSICR1 register with a value of 0x0000.0000.
3. Write the SSICPSR register with a value of 0x0000.0002.
4. Write the SSICR0 register with a value of 0x0000.09C7.
5. The SSI is then enabled by setting the SSE bit in the SSICR1 register to 1.
12.5
Register Map
Table 12-2 on page 411 lists the SSI registers. The offset listed is a hexadecimal increment to the
register’s address, relative to that SSI module’s base address:
■ SSI0: 0x4000.8000
Note that the SSI module clock must be enabled before the registers can be programmed (see
page 192). There must be a delay of 3 system clocks after the SSI module clock is enabled before
any SSI module registers are accessed.
Note:
The SSI must be disabled (see the SSE bit in the SSICR1 register) before any of the control
registers are reprogrammed.
Table 12-2. SSI Register Map
Offset
Name
Type
Reset
Description
See
page
0x000
SSICR0
R/W
0x0000.0000
SSI Control 0
413
0x004
SSICR1
R/W
0x0000.0000
SSI Control 1
415
0x008
SSIDR
R/W
0x0000.0000
SSI Data
417
0x00C
SSISR
RO
0x0000.0003
SSI Status
418
0x010
SSICPSR
R/W
0x0000.0000
SSI Clock Prescale
420
0x014
SSIIM
R/W
0x0000.0000
SSI Interrupt Mask
421
0x018
SSIRIS
RO
0x0000.0008
SSI Raw Interrupt Status
423
0x01C
SSIMIS
RO
0x0000.0000
SSI Masked Interrupt Status
424
0x020
SSIICR
W1C
0x0000.0000
SSI Interrupt Clear
425
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Table 12-2. SSI Register Map (continued)
Offset
Name
0xFD0
Reset
SSIPeriphID4
RO
0x0000.0000
SSI Peripheral Identification 4
426
0xFD4
SSIPeriphID5
RO
0x0000.0000
SSI Peripheral Identification 5
427
0xFD8
SSIPeriphID6
RO
0x0000.0000
SSI Peripheral Identification 6
428
0xFDC
SSIPeriphID7
RO
0x0000.0000
SSI Peripheral Identification 7
429
0xFE0
SSIPeriphID0
RO
0x0000.0022
SSI Peripheral Identification 0
430
0xFE4
SSIPeriphID1
RO
0x0000.0000
SSI Peripheral Identification 1
431
0xFE8
SSIPeriphID2
RO
0x0000.0018
SSI Peripheral Identification 2
432
0xFEC
SSIPeriphID3
RO
0x0000.0001
SSI Peripheral Identification 3
433
0xFF0
SSIPCellID0
RO
0x0000.000D
SSI PrimeCell Identification 0
434
0xFF4
SSIPCellID1
RO
0x0000.00F0
SSI PrimeCell Identification 1
435
0xFF8
SSIPCellID2
RO
0x0000.0005
SSI PrimeCell Identification 2
436
0xFFC
SSIPCellID3
RO
0x0000.00B1
SSI PrimeCell Identification 3
437
12.6
Description
See
page
Type
Register Descriptions
The remainder of this section lists and describes the SSI registers, in numerical order by address
offset.
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Register 1: SSI Control 0 (SSICR0), offset 0x000
SSICR0 is control register 0 and contains bit fields that control various functions within the SSI
module. Functionality such as protocol mode, clock rate, and data size are configured in this register.
SSI Control 0 (SSICR0)
SSI0 base: 0x4000.8000
Offset 0x000
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
SPH
SPO
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
SCR
Type
Reset
FRF
R/W
0
DSS
Bit/Field
Name
Type
Reset
Description
31:16
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
15:8
SCR
R/W
0x0000
SSI Serial Clock Rate
The value SCR is used to generate the transmit and receive bit rate of
the SSI. The bit rate is:
BR=FSSIClk/(CPSDVSR * (1 + SCR))
where CPSDVSR is an even value from 2-254 programmed in the
SSICPSR register, and SCR is a value from 0-255.
7
SPH
R/W
0
SSI Serial Clock Phase
This bit is only applicable to the Freescale SPI Format.
The SPH control bit selects the clock edge that captures data and allows
it to change state. It has the most impact on the first bit transmitted by
either allowing or not allowing a clock transition before the first data
capture edge.
When the SPH bit is 0, data is captured on the first clock edge transition.
If SPH is 1, data is captured on the second clock edge transition.
6
SPO
R/W
0
SSI Serial Clock Polarity
This bit is only applicable to the Freescale SPI Format.
When the SPO bit is 0, it produces a steady state Low value on the
SSIClk pin. If SPO is 1, a steady state High value is placed on the
SSIClk pin when data is not being transferred.
5:4
FRF
R/W
0x0
SSI Frame Format Select
The FRF values are defined as follows:
Value Frame Format
0x0 Freescale SPI Frame Format
0x1 Texas Instruments Synchronous Serial Frame Format
0x2 MICROWIRE Frame Format
0x3 Reserved
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Bit/Field
Name
Type
Reset
Description
3:0
DSS
R/W
0x00
SSI Data Size Select
The DSS values are defined as follows:
Value
Data Size
0x0-0x2 Reserved
0x3
4-bit data
0x4
5-bit data
0x5
6-bit data
0x6
7-bit data
0x7
8-bit data
0x8
9-bit data
0x9
10-bit data
0xA
11-bit data
0xB
12-bit data
0xC
13-bit data
0xD
14-bit data
0xE
15-bit data
0xF
16-bit data
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Register 2: SSI Control 1 (SSICR1), offset 0x004
SSICR1 is control register 1 and contains bit fields that control various functions within the SSI
module. Master and slave mode functionality is controlled by this register.
SSI Control 1 (SSICR1)
SSI0 base: 0x4000.8000
Offset 0x004
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
SOD
MS
SSE
LBM
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
Description
31:4
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
3
SOD
R/W
0
SSI Slave Mode Output Disable
This bit is relevant only in the Slave mode (MS=1). In multiple-slave
systems, it is possible for the SSI master to broadcast a message to all
slaves in the system while ensuring that only one slave drives data onto
the serial output line. In such systems, the TXD lines from multiple slaves
could be tied together. To operate in such a system, the SOD bit can be
configured so that the SSI slave does not drive the SSITx pin.
The SOD values are defined as follows:
Value Description
2
MS
R/W
0
0
SSI can drive SSITx output in Slave Output mode.
1
SSI must not drive the SSITx output in Slave mode.
SSI Master/Slave Select
This bit selects Master or Slave mode and can be modified only when
SSI is disabled (SSE=0).
The MS values are defined as follows:
Value Description
0
Device configured as a master.
1
Device configured as a slave.
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Bit/Field
Name
Type
Reset
1
SSE
R/W
0
Description
SSI Synchronous Serial Port Enable
Setting this bit enables SSI operation.
The SSE values are defined as follows:
Value Description
0
SSI operation disabled.
1
SSI operation enabled.
Note:
0
LBM
R/W
0
This bit must be set to 0 before any control registers
are reprogrammed.
SSI Loopback Mode
Setting this bit enables Loopback Test mode.
The LBM values are defined as follows:
Value Description
0
Normal serial port operation enabled.
1
Output of the transmit serial shift register is connected internally
to the input of the receive serial shift register.
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Register 3: SSI Data (SSIDR), offset 0x008
Important: This register is read-sensitive. See the register description for details.
SSIDR is the data register and is 16-bits wide. When SSIDR is read, the entry in the receive FIFO
(pointed to by the current FIFO read pointer) is accessed. As data values are removed by the SSI
receive logic from the incoming data frame, they are placed into the entry in the receive FIFO (pointed
to by the current FIFO write pointer).
When SSIDR is written to, the entry in the transmit FIFO (pointed to by the write pointer) is written
to. Data values are removed from the transmit FIFO one value at a time by the transmit logic. It is
loaded into the transmit serial shifter, then serially shifted out onto the SSITx pin at the programmed
bit rate.
When a data size of less than 16 bits is selected, the user must right-justify data written to the
transmit FIFO. The transmit logic ignores the unused bits. Received data less than 16 bits is
automatically right-justified in the receive buffer.
When the SSI is programmed for MICROWIRE frame format, the default size for transmit data is
eight bits (the most significant byte is ignored). The receive data size is controlled by the programmer.
The transmit FIFO and the receive FIFO are not cleared even when the SSE bit in the SSICR1
register is set to zero. This allows the software to fill the transmit FIFO before enabling the SSI.
SSI Data (SSIDR)
SSI0 base: 0x4000.8000
Offset 0x008
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
DATA
Type
Reset
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:16
reserved
RO
0x0000
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
15:0
DATA
R/W
0x0000
SSI Receive/Transmit Data
A read operation reads the receive FIFO. A write operation writes the
transmit FIFO.
Software must right-justify data when the SSI is programmed for a data
size that is less than 16 bits. Unused bits at the top are ignored by the
transmit logic. The receive logic automatically right-justifies the data.
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Register 4: SSI Status (SSISR), offset 0x00C
SSISR is a status register that contains bits that indicate the FIFO fill status and the SSI busy status.
SSI Status (SSISR)
SSI0 base: 0x4000.8000
Offset 0x00C
Type RO, reset 0x0000.0003
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
BSY
RFF
RNE
TNF
TFE
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
1
R0
1
reserved
Type
Reset
reserved
Type
Reset
RO
0
Bit/Field
Name
Type
Reset
Description
31:5
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
4
BSY
RO
0
SSI Busy Bit
The BSY values are defined as follows:
Value Description
3
RFF
RO
0
0
SSI is idle.
1
SSI is currently transmitting and/or receiving a frame, or the
transmit FIFO is not empty.
SSI Receive FIFO Full
The RFF values are defined as follows:
Value Description
2
RNE
RO
0
0
Receive FIFO is not full.
1
Receive FIFO is full.
SSI Receive FIFO Not Empty
The RNE values are defined as follows:
Value Description
1
TNF
RO
1
0
Receive FIFO is empty.
1
Receive FIFO is not empty.
SSI Transmit FIFO Not Full
The TNF values are defined as follows:
Value Description
0
Transmit FIFO is full.
1
Transmit FIFO is not full.
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Bit/Field
Name
Type
Reset
0
TFE
R0
1
Description
SSI Transmit FIFO Empty
The TFE values are defined as follows:
Value Description
0
Transmit FIFO is not empty.
1
Transmit FIFO is empty.
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Register 5: SSI Clock Prescale (SSICPSR), offset 0x010
SSICPSR is the clock prescale register and specifies the division factor by which the system clock
must be internally divided before further use.
The value programmed into this register must be an even number between 2 and 254. The
least-significant bit of the programmed number is hard-coded to zero. If an odd number is written
to this register, data read back from this register has the least-significant bit as zero.
SSI Clock Prescale (SSICPSR)
SSI0 base: 0x4000.8000
Offset 0x010
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
CPSDVSR
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
CPSDVSR
R/W
0x00
SSI Clock Prescale Divisor
This value must be an even number from 2 to 254, depending on the
frequency of SSIClk. The LSB always returns 0 on reads.
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Register 6: SSI Interrupt Mask (SSIIM), offset 0x014
The SSIIM register is the interrupt mask set or clear register. It is a read/write register and all bits
are cleared to 0 on reset.
On a read, this register gives the current value of the mask on the relevant interrupt. A write of 1 to
the particular bit sets the mask, enabling the interrupt to be read. A write of 0 clears the corresponding
mask.
SSI Interrupt Mask (SSIIM)
SSI0 base: 0x4000.8000
Offset 0x014
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
3
2
1
0
TXIM
RXIM
RTIM
RORIM
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:4
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
3
TXIM
R/W
0
SSI Transmit FIFO Interrupt Mask
The TXIM values are defined as follows:
Value Description
2
RXIM
R/W
0
0
TX FIFO half-empty or less condition interrupt is masked.
1
TX FIFO half-empty or less condition interrupt is not masked.
SSI Receive FIFO Interrupt Mask
The RXIM values are defined as follows:
Value Description
1
RTIM
R/W
0
0
RX FIFO half-full or more condition interrupt is masked.
1
RX FIFO half-full or more condition interrupt is not masked.
SSI Receive Time-Out Interrupt Mask
The RTIM values are defined as follows:
Value Description
0
RX FIFO time-out interrupt is masked.
1
RX FIFO time-out interrupt is not masked.
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Bit/Field
Name
Type
Reset
0
RORIM
R/W
0
Description
SSI Receive Overrun Interrupt Mask
The RORIM values are defined as follows:
Value Description
0
RX FIFO overrun interrupt is masked.
1
RX FIFO overrun interrupt is not masked.
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Register 7: SSI Raw Interrupt Status (SSIRIS), offset 0x018
The SSIRIS register is the raw interrupt status register. On a read, this register gives the current
raw status value of the corresponding interrupt prior to masking. A write has no effect.
SSI Raw Interrupt Status (SSIRIS)
SSI0 base: 0x4000.8000
Offset 0x018
Type RO, reset 0x0000.0008
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
TXRIS
RXRIS
RTRIS
RORRIS
RO
0
RO
0
RO
0
RO
0
RO
0
RO
1
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
Description
31:4
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
3
TXRIS
RO
1
SSI Transmit FIFO Raw Interrupt Status
Indicates that the transmit FIFO is half empty or less, when set.
2
RXRIS
RO
0
SSI Receive FIFO Raw Interrupt Status
Indicates that the receive FIFO is half full or more, when set.
1
RTRIS
RO
0
SSI Receive Time-Out Raw Interrupt Status
Indicates that the receive time-out has occurred, when set.
0
RORRIS
RO
0
SSI Receive Overrun Raw Interrupt Status
Indicates that the receive FIFO has overflowed, when set.
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Register 8: SSI Masked Interrupt Status (SSIMIS), offset 0x01C
The SSIMIS register is the masked interrupt status register. On a read, this register gives the current
masked status value of the corresponding interrupt. A write has no effect.
SSI Masked Interrupt Status (SSIMIS)
SSI0 base: 0x4000.8000
Offset 0x01C
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
TXMIS
RXMIS
RTMIS
RORMIS
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
Description
31:4
reserved
RO
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
3
TXMIS
RO
0
SSI Transmit FIFO Masked Interrupt Status
Indicates that the transmit FIFO is half empty or less, when set.
2
RXMIS
RO
0
SSI Receive FIFO Masked Interrupt Status
Indicates that the receive FIFO is half full or more, when set.
1
RTMIS
RO
0
SSI Receive Time-Out Masked Interrupt Status
Indicates that the receive time-out has occurred, when set.
0
RORMIS
RO
0
SSI Receive Overrun Masked Interrupt Status
Indicates that the receive FIFO has overflowed, when set.
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Stellaris LM3S828 Microcontroller
Register 9: SSI Interrupt Clear (SSIICR), offset 0x020
The SSIICR register is the interrupt clear register. On a write of 1, the corresponding interrupt is
cleared. A write of 0 has no effect.
SSI Interrupt Clear (SSIICR)
SSI0 base: 0x4000.8000
Offset 0x020
Type W1C, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RTIC
RORIC
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
W1C
0
W1C
0
reserved
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
Description
31:2
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
1
RTIC
W1C
0
SSI Receive Time-Out Interrupt Clear
The RTIC values are defined as follows:
Value Description
0
RORIC
W1C
0
0
No effect on interrupt.
1
Clears interrupt.
SSI Receive Overrun Interrupt Clear
The RORIC values are defined as follows:
Value Description
0
No effect on interrupt.
1
Clears interrupt.
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Synchronous Serial Interface (SSI)
Register 10: SSI Peripheral Identification 4 (SSIPeriphID4), offset 0xFD0
The SSIPeriphIDn registers are hard-coded and the fields within the register determine the reset
value.
SSI Peripheral Identification 4 (SSIPeriphID4)
SSI0 base: 0x4000.8000
Offset 0xFD0
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
PID4
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID4
RO
0x00
SSI Peripheral ID Register[7:0]
Can be used by software to identify the presence of this peripheral.
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Texas Instruments-Production Data
®
Stellaris LM3S828 Microcontroller
Register 11: SSI Peripheral Identification 5 (SSIPeriphID5), offset 0xFD4
The SSIPeriphIDn registers are hard-coded and the fields within the register determine the reset
value.
SSI Peripheral Identification 5 (SSIPeriphID5)
SSI0 base: 0x4000.8000
Offset 0xFD4
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
PID5
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID5
RO
0x00
SSI Peripheral ID Register[15:8]
Can be used by software to identify the presence of this peripheral.
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Synchronous Serial Interface (SSI)
Register 12: SSI Peripheral Identification 6 (SSIPeriphID6), offset 0xFD8
The SSIPeriphIDn registers are hard-coded and the fields within the register determine the reset
value.
SSI Peripheral Identification 6 (SSIPeriphID6)
SSI0 base: 0x4000.8000
Offset 0xFD8
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
PID6
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID6
RO
0x00
SSI Peripheral ID Register[23:16]
Can be used by software to identify the presence of this peripheral.
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®
Stellaris LM3S828 Microcontroller
Register 13: SSI Peripheral Identification 7 (SSIPeriphID7), offset 0xFDC
The SSIPeriphIDn registers are hard-coded and the fields within the register determine the reset
value.
SSI Peripheral Identification 7 (SSIPeriphID7)
SSI0 base: 0x4000.8000
Offset 0xFDC
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
PID7
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID7
RO
0x00
SSI Peripheral ID Register[31:24]
Can be used by software to identify the presence of this peripheral.
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Synchronous Serial Interface (SSI)
Register 14: SSI Peripheral Identification 0 (SSIPeriphID0), offset 0xFE0
The SSIPeriphIDn registers are hard-coded and the fields within the register determine the reset
value.
SSI Peripheral Identification 0 (SSIPeriphID0)
SSI0 base: 0x4000.8000
Offset 0xFE0
Type RO, reset 0x0000.0022
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
1
RO
0
RO
0
RO
0
RO
1
RO
0
reserved
Type
Reset
reserved
Type
Reset
PID0
RO
0
Bit/Field
Name
Type
Reset
31:8
reserved
RO
0
7:0
PID0
RO
0x22
Description
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
SSI Peripheral ID Register[7:0]
Can be used by software to identify the presence of this peripheral.
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®
Stellaris LM3S828 Microcontroller
Register 15: SSI Peripheral Identification 1 (SSIPeriphID1), offset 0xFE4
The SSIPeriphIDn registers are hard-coded and the fields within the register determine the reset
value.
SSI Peripheral Identification 1 (SSIPeriphID1)
SSI0 base: 0x4000.8000
Offset 0xFE4
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
PID1
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID1
RO
0x00
SSI Peripheral ID Register [15:8]
Can be used by software to identify the presence of this peripheral.
June 18, 2012
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Synchronous Serial Interface (SSI)
Register 16: SSI Peripheral Identification 2 (SSIPeriphID2), offset 0xFE8
The SSIPeriphIDn registers are hard-coded and the fields within the register determine the reset
value.
SSI Peripheral Identification 2 (SSIPeriphID2)
SSI0 base: 0x4000.8000
Offset 0xFE8
Type RO, reset 0x0000.0018
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
1
RO
1
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
PID2
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID2
RO
0x18
SSI Peripheral ID Register [23:16]
Can be used by software to identify the presence of this peripheral.
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®
Stellaris LM3S828 Microcontroller
Register 17: SSI Peripheral Identification 3 (SSIPeriphID3), offset 0xFEC
The SSIPeriphIDn registers are hard-coded and the fields within the register determine the reset
value.
SSI Peripheral Identification 3 (SSIPeriphID3)
SSI0 base: 0x4000.8000
Offset 0xFEC
Type RO, reset 0x0000.0001
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
1
reserved
Type
Reset
reserved
Type
Reset
PID3
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
PID3
RO
0x01
SSI Peripheral ID Register [31:24]
Can be used by software to identify the presence of this peripheral.
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Synchronous Serial Interface (SSI)
Register 18: SSI PrimeCell Identification 0 (SSIPCellID0), offset 0xFF0
The SSIPCellIDn registers are hard-coded, and the fields within the register determine the reset
value.
SSI PrimeCell Identification 0 (SSIPCellID0)
SSI0 base: 0x4000.8000
Offset 0xFF0
Type RO, reset 0x0000.000D
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
1
RO
1
RO
0
RO
1
reserved
Type
Reset
reserved
Type
Reset
CID0
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
CID0
RO
0x0D
SSI PrimeCell ID Register [7:0]
Provides software a standard cross-peripheral identification system.
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®
Stellaris LM3S828 Microcontroller
Register 19: SSI PrimeCell Identification 1 (SSIPCellID1), offset 0xFF4
The SSIPCellIDn registers are hard-coded, and the fields within the register determine the reset
value.
SSI PrimeCell Identification 1 (SSIPCellID1)
SSI0 base: 0x4000.8000
Offset 0xFF4
Type RO, reset 0x0000.00F0
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
1
RO
1
RO
1
RO
1
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
CID1
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
CID1
RO
0xF0
SSI PrimeCell ID Register [15:8]
Provides software a standard cross-peripheral identification system.
June 18, 2012
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Texas Instruments-Production Data
Synchronous Serial Interface (SSI)
Register 20: SSI PrimeCell Identification 2 (SSIPCellID2), offset 0xFF8
The SSIPCellIDn registers are hard-coded, and the fields within the register determine the reset
value.
SSI PrimeCell Identification 2 (SSIPCellID2)
SSI0 base: 0x4000.8000
Offset 0xFF8
Type RO, reset 0x0000.0005
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
1
RO
0
RO
1
reserved
Type
Reset
reserved
Type
Reset
CID2
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
CID2
RO
0x05
SSI PrimeCell ID Register [23:16]
Provides software a standard cross-peripheral identification system.
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June 18, 2012
Texas Instruments-Production Data
®
Stellaris LM3S828 Microcontroller
Register 21: SSI PrimeCell Identification 3 (SSIPCellID3), offset 0xFFC
The SSIPCellIDn registers are hard-coded, and the fields within the register determine the reset
value.
SSI PrimeCell Identification 3 (SSIPCellID3)
SSI0 base: 0x4000.8000
Offset 0xFFC
Type RO, reset 0x0000.00B1
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
RO
1
RO
0
RO
1
RO
1
RO
0
RO
0
RO
0
RO
1
reserved
Type
Reset
reserved
Type
Reset
CID3
RO
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
CID3
RO
0xB1
SSI PrimeCell ID Register [31:24]
Provides software a standard cross-peripheral identification system.
June 18, 2012
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Texas Instruments-Production Data
Inter-Integrated Circuit (I2C) Interface
13
Inter-Integrated Circuit (I2C) Interface
The Inter-Integrated Circuit (I2C) bus provides bi-directional data transfer through a two-wire design
(a serial data line SDA and a serial clock line SCL), and interfaces to external I2C devices such as
serial memory (RAMs and ROMs), networking devices, LCDs, tone generators, and so on. The I2C
bus may also be used for system testing and diagnostic purposes in product development and
manufacture. The LM3S828 microcontroller includes one I2C module, providing the ability to interact
(both send and receive) with other I2C devices on the bus.
®
The Stellaris I2C interface has the following features:
■ Devices on the I2C bus can be designated as either a master or a slave
– Supports both sending and receiving data as either a master or a slave
– Supports simultaneous master and slave operation
■ Four I2C modes
– Master transmit
– Master receive
– Slave transmit
– Slave receive
■ Two transmission speeds: Standard (100 Kbps) and Fast (400 Kbps)
■ Master and slave interrupt generation
– Master generates interrupts when a transmit or receive operation completes (or aborts due
to an error)
– Slave generates interrupts when data has been sent or requested by a master
■ Master with arbitration and clock synchronization, multimaster support, and 7-bit addressing
mode
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June 18, 2012
Texas Instruments-Production Data
®
Stellaris LM3S828 Microcontroller
13.1
Block Diagram
Figure 13-1. I2C Block Diagram
I2CSCL
I2C Control
Interrupt
I2CMSA
I2CSOAR
I2CMCS
I2CSCSR
I2CMDR
I2CSDR
I2CMTPR
I2CSIM
I2CMIMR
I2CSRIS
I2CMRIS
I2CSMIS
I2CMMIS
I2CSICR
I2C Master Core
I2CSCL
I2C I/O Select
I2CSDA
I2CSCL
I2C Slave Core
I2CMICR
I2CSDA
I2CMCR
13.2
I2CSDA
Signal Description
Table 13-1 on page 439 lists the external signals of the I2C interface and describes the function of
each. The I2C interface signals are alternate functions for some GPIO signals and default to be
GPIO signals at reset., with the exception of the I2C0SCL and I2CSDA pins which default to the
I2C function. The column in the table below titled "Pin Assignment" lists the possible GPIO pin
placements for the I2C signals. The AFSEL bit in the GPIO Alternate Function Select (GPIOAFSEL)
register (page 242) should be set to choose the I2C function. Note that the I2C pins should be set to
open drain using the GPIO Open Drain Select (GPIOODR) register. For more information on
configuring GPIOs, see “General-Purpose Input/Outputs (GPIOs)” on page 223.
Table 13-1. I2C Signals (48QFP)
a
Pin Name
Pin Number
Pin Type
Buffer Type
Description
I2CSCL
33
I/O
OD
I2C clock.
I2CSDA
34
I/O
OD
I2C data.
a. The TTL designation indicates the pin has TTL-compatible voltage levels.
13.3
Functional Description
I2C module is comprised of both master and slave functions which are implemented as separate
peripherals. For proper operation, the SDA and SCL pins must be connected to bi-directional
open-drain pads. A typical I2C bus configuration is shown in Figure 13-2 on page 440.
See “Inter-Integrated Circuit (I2C) Interface” on page 495 for I2C timing diagrams.
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Figure 13-2. I2C Bus Configuration
RPUP
SCL
SDA
I2C Bus
I2CSCL
I2CSDA
StellarisTM
13.3.1
RPUP
SCL
SDA
3rd Party Device
with I2C Interface
SCL
SDA
3rd Party Device
with I2C Interface
I2C Bus Functional Overview
The I2C bus uses only two signals: SDA and SCL, named I2CSDA and I2CSCL on Stellaris
microcontrollers. SDA is the bi-directional serial data line and SCL is the bi-directional serial clock
line. The bus is considered idle when both lines are High.
Every transaction on the I2C bus is nine bits long, consisting of eight data bits and a single
acknowledge bit. The number of bytes per transfer (defined as the time between a valid START
and STOP condition, described in “START and STOP Conditions” on page 440) is unrestricted, but
each byte has to be followed by an acknowledge bit, and data must be transferred MSB first. When
a receiver cannot receive another complete byte, it can hold the clock line SCL Low and force the
transmitter into a wait state. The data transfer continues when the receiver releases the clock SCL.
13.3.1.1
START and STOP Conditions
The protocol of the I2C bus defines two states to begin and end a transaction: START and STOP.
A High-to-Low transition on the SDA line while the SCL is High is defined as a START condition,
and a Low-to-High transition on the SDA line while SCL is High is defined as a STOP condition.
The bus is considered busy after a START condition and free after a STOP condition. See Figure
13-3 on page 440.
Figure 13-3. START and STOP Conditions
SDA
SDA
SCL
SCL
START
condition
13.3.1.2
STOP
condition
Data Format with 7-Bit Address
Data transfers follow the format shown in Figure 13-4 on page 441. After the START condition, a
slave address is sent. This address is 7-bits long followed by an eighth bit, which is a data direction
bit (R/S bit in the I2CMSA register). A zero indicates a transmit operation (send), and a one indicates
a request for data (receive). A data transfer is always terminated by a STOP condition generated
by the master, however, a master can initiate communications with another device on the bus by
generating a repeated START condition and addressing another slave without first generating a
STOP condition. Various combinations of receive/send formats are then possible within a single
transfer.
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Figure 13-4. Complete Data Transfer with a 7-Bit Address
SDA
MSB
SCL
1
2
LSB
R/S
ACK
7
8
9
MSB
1
2
Slave address
7
LSB
ACK
8
9
Data
The first seven bits of the first byte make up the slave address (see Figure 13-5 on page 441). The
eighth bit determines the direction of the message. A zero in the R/S position of the first byte means
that the master will write (send) data to the selected slave, and a one in this position means that
the master will receive data from the slave.
Figure 13-5. R/S Bit in First Byte
MSB
LSB
R/S
Slave address
13.3.1.3
Data Validity
The data on the SDA line must be stable during the high period of the clock, and the data line can
only change when SCL is Low (see Figure 13-6 on page 441).
Figure 13-6. Data Validity During Bit Transfer on the I2C Bus
SDA
SCL
Data line Change
stable
of data
allowed
13.3.1.4
Acknowledge
All bus transactions have a required acknowledge clock cycle that is generated by the master. During
the acknowledge cycle, the transmitter (which can be the master or slave) releases the SDA line.
To acknowledge the transaction, the receiver must pull down SDA during the acknowledge clock
cycle. The data sent out by the receiver during the acknowledge cycle must comply with the data
validity requirements described in “Data Validity” on page 441.
When a slave receiver does not acknowledge the slave address, SDA must be left High by the slave
so that the master can generate a STOP condition and abort the current transfer. If the master
device is acting as a receiver during a transfer, it is responsible for acknowledging each transfer
made by the slave. Since the master controls the number of bytes in the transfer, it signals the end
of data to the slave transmitter by not generating an acknowledge on the last data byte. The slave
transmitter must then release SDA to allow the master to generate the STOP or a repeated START
condition.
13.3.1.5
Arbitration
A master may start a transfer only if the bus is idle. It's possible for two or more masters to generate
a START condition within minimum hold time of the START condition. In these situations, an
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arbitration scheme takes place on the SDA line, while SCL is High. During arbitration, the first of
the competing master devices to place a '1' (High) on SDA while another master transmits a '0'
(Low) will switch off its data output stage and retire until the bus is idle again.
Arbitration can take place over several bits. Its first stage is a comparison of address bits, and if
both masters are trying to address the same device, arbitration continues on to the comparison of
data bits.
13.3.2
Available Speed Modes
The I2C clock rate is determined by the parameters: CLK_PRD, TIMER_PRD, SCL_LP, and SCL_HP.
where:
CLK_PRD is the system clock period
SCL_LP is the low phase of SCL (fixed at 6)
SCL_HP is the high phase of SCL (fixed at 4)
TIMER_PRD is the programmed value in the I2C Master Timer Period (I2CMTPR) register (see
page 460).
The I2C clock period is calculated as follows:
SCL_PERIOD = 2*(1 + TIMER_PRD)*(SCL_LP + SCL_HP)*CLK_PRD
For example:
CLK_PRD = 50 ns
TIMER_PRD = 2
SCL_LP=6
SCL_HP=4
yields a SCL frequency of:
1/T = 333 Khz
Table 13-2 on page 442 gives examples of timer period, system clock, and speed mode (Standard
or Fast).
Table 13-2. Examples of I2C Master Timer Period versus Speed Mode
System Clock
Timer Period
Standard Mode
Timer Period
Fast Mode
4 MHz
0x01
100 Kbps
-
-
6 MHz
0x02
100 Kbps
-
-
12.5 MHz
0x06
89 Kbps
0x01
312 Kbps
16.7 MHz
0x08
93 Kbps
0x02
278 Kbps
20 MHz
0x09
100 Kbps
0x02
333 Kbps
25 MHz
0x0C
96.2 Kbps
0x03
312 Kbps
33 MHz
0x10
97.1 Kbps
0x04
330 Kbps
40 MHz
0x13
100 Kbps
0x04
400 Kbps
50 MHz
0x18
100 Kbps
0x06
357 Kbps
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13.3.3
Interrupts
The I2C can generate interrupts when the following conditions are observed:
■ Master transaction completed
■ Master arbitration lost
■ Master transaction error
■ Slave transaction received
■ Slave transaction requested
There is a separate interrupt signal for the I2C master and I2C slave modules. While both modules
can generate interrupts for multiple conditions, only a single interrupt signal is sent to the interrupt
controller.
13.3.3.1
I2C Master Interrupts
The I2C master module generates an interrupt when a transaction completes (either transmit or
receive), when arbitration is lost, or when an error occurs during a transaction. To enable the I2C
master interrupt, software must set the IM bit in the I2C Master Interrupt Mask (I2CMIMR) register.
When an interrupt condition is met, software must check the ERROR and ARBLST bits in the I2C
Master Control/Status (I2CMCS) register to verify that an error didn't occur during the last transaction
and to ensure that arbitration has not been lost. An error condition is asserted if the last transaction
wasn't acknowledged by the slave. If an error is not detected and the master has not lost arbitration,
the application can proceed with the transfer. The interrupt is cleared by writing a 1 to the IC bit in
the I2C Master Interrupt Clear (I2CMICR) register.
If the application doesn't require the use of interrupts, the raw interrupt status is always visible via
the I2C Master Raw Interrupt Status (I2CMRIS) register.
13.3.3.2
I2C Slave Interrupts
The slave module can generate an interrupt when data has been received or requested. This interrupt
is enabled by writing a 1 to the DATAIM bit in the I2C Slave Interrupt Mask (I2CSIMR) register.
Software determines whether the module should write (transmit) or read (receive) data from the I2C
Slave Data (I2CSDR) register, by checking the RREQ and TREQ bits of the I2C Slave Control/Status
(I2CSCSR) register. If the slave module is in receive mode and the first byte of a transfer is received,
the FBR bit is set along with the RREQ bit. The interrupt is cleared by writing a 1 to the DATAIC bit
in the I2C Slave Interrupt Clear (I2CSICR) register.
If the application doesn't require the use of interrupts, the raw interrupt status is always visible via
the I2C Slave Raw Interrupt Status (I2CSRIS) register.
13.3.4
Loopback Operation
The I2C modules can be placed into an internal loopback mode for diagnostic or debug work. This
is accomplished by setting the LPBK bit in the I2C Master Configuration (I2CMCR) register. In
loopback mode, the SDA and SCL signals from the master and slave modules are tied together.
13.3.5
Command Sequence Flow Charts
This section details the steps required to perform the various I2C transfer types in both master and
slave mode.
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13.3.5.1
I2C Master Command Sequences
The figures that follow show the command sequences available for the I2C master.
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Figure 13-7. Master Single SEND
Idle
Write Slave
Address to
I2CMSA
Sequence
may be
omitted in a
Single Master
system
Write data to
I2CMDR
Read I2CMCS
NO
BUSBSY bit=0?
YES
Write ---0-111 to
I2CMCS
Read I2CMCS
NO
BUSY bit=0?
YES
Error Service
NO
ERROR bit=0?
YES
Idle
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Figure 13-8. Master Single RECEIVE
Idle
Write Slave
Address to
I2CMSA
Sequence may be
omitted in a Single
Master system
Read I2CMCS
NO
BUSBSY bit=0?
YES
Write ---00111 to
I2CMCS
Read I2CMCS
NO
BUSY bit=0?
YES
Error Service
NO
ERROR bit=0?
YES
Read data from
I2CMDR
Idle
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Figure 13-9. Master Burst SEND
Idle
Write Slave
Address to
I2CMSA
Sequence
may be
omitted in a
Single Master
system
Read I2CMCS
Write data to
I2CMDR
BUSY bit=0?
YES
Read I2CMCS
ERROR bit=0?
NO
NO
NO
BUSBSY bit=0?
YES
Write data to
I2CMDR
YES
Write ---0-011 to
I2CMCS
NO
ARBLST bit=1?
YES
Write ---0-001 to
I2CMCS
NO
Index=n?
YES
Write ---0-101 to
I2CMCS
Write ---0-100 to
I2CMCS
Error Service
Idle
Read I2CMCS
NO
BUSY bit=0?
YES
Error Service
NO
ERROR bit=0?
YES
Idle
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Figure 13-10. Master Burst RECEIVE
Idle
Write Slave
Address to
I2CMSA
Sequence
may be
omitted in a
Single Master
system
Read I2CMCS
BUSY bit=0?
Read I2CMCS
NO
YES
NO
BUSBSY bit=0?
ERROR bit=0?
NO
YES
Write ---01011 to
I2CMCS
NO
Read data from
I2CMDR
ARBLST bit=1?
YES
Write ---01001 to
I2CMCS
NO
Write ---0-100 to
I2CMCS
Index=m-1?
Error Service
YES
Write ---00101 to
I2CMCS
Idle
Read I2CMCS
BUSY bit=0?
NO
YES
NO
ERROR bit=0?
YES
Error Service
Read data from
I2CMDR
Idle
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Figure 13-11. Master Burst RECEIVE after Burst SEND
Idle
Master operates in
Master Transmit mode
STOP condition is not
generated
Write Slave
Address to
I2CMSA
Write ---01011 to
I2CMCS
Master operates in
Master Receive mode
Repeated START
condition is generated
with changing data
direction
Idle
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Figure 13-12. Master Burst SEND after Burst RECEIVE
Idle
Master operates in
Master Receive mode
STOP condition is not
generated
Write Slave
Address to
I2CMSA
Write ---0-011 to
I2CMCS
Master operates in
Master Transmit mode
Repeated START
condition is generated
with changing data
direction
Idle
13.3.5.2
I2C Slave Command Sequences
Figure 13-13 on page 451 presents the command sequence available for the I2C slave.
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Figure 13-13. Slave Command Sequence
Idle
Write OWN Slave
Address to
I2CSOAR
Write -------1 to
I2CSCSR
Read I2CSCSR
NO
TREQ bit=1?
YES
Write data to
I2CSDR
13.4
NO
RREQ bit=1?
FBR is
also valid
YES
Read data from
I2CSDR
Initialization and Configuration
The following example shows how to configure the I2C module to send a single byte as a master.
This assumes the system clock is 20 MHz.
1. Enable the I2C clock by writing a value of 0x0000.1000 to the RCGC1 register in the System
Control module.
2. Enable the clock to the appropriate GPIO module via the RCGC2 register in the System Control
module.
3. In the GPIO module, enable the appropriate pins for their alternate function using the
GPIOAFSEL register. Also, be sure to enable the same pins for Open Drain operation.
4. Initialize the I2C Master by writing the I2CMCR register with a value of 0x0000.0020.
5. Set the desired SCL clock speed of 100 Kbps by writing the I2CMTPR register with the correct
value. The value written to the I2CMTPR register represents the number of system clock periods
in one SCL clock period. The TPR value is determined by the following equation:
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TPR = (System Clock / (2 * (SCL_LP + SCL_HP) * SCL_CLK)) - 1;
TPR = (20MHz / (2 * (6 + 4) * 100000)) - 1;
TPR = 9
Write the I2CMTPR register with the value of 0x0000.0009.
6. Specify the slave address of the master and that the next operation will be a Send by writing
the I2CMSA register with a value of 0x0000.0076. This sets the slave address to 0x3B.
7. Place data (byte) to be sent in the data register by writing the I2CMDR register with the desired
data.
8. Initiate a single byte send of the data from Master to Slave by writing the I2CMCS register with
a value of 0x0000.0007 (STOP, START, RUN).
9. Wait until the transmission completes by polling the I2CMCS register’s BUSBSY bit until it has
been cleared.
13.5
Register Map
Table 13-3 on page 452 lists the I2C registers. All addresses given are relative to the I2C base
addresses for the master and slave:
■ I2C 0: 0x4002.0000
Note that the I2C module clock must be enabled before the registers can be programmed (see
page 192). There must be a delay of 3 system clocks after the I2C module clock is enabled before
any I2C module registers are accessed.
®
The hw_i2c.h file in the StellarisWare Driver Library uses a base address of 0x800 for the I2C slave
registers. Be aware when using registers with offsets between 0x800 and 0x818 that StellarisWare
uses an offset between 0x000 and 0x018 with the slave base address.
Table 13-3. Inter-Integrated Circuit (I2C) Interface Register Map
Offset
Description
See
page
Name
Type
Reset
0x000
I2CMSA
R/W
0x0000.0000
I2C Master Slave Address
454
0x004
I2CMCS
R/W
0x0000.0000
I2C Master Control/Status
455
0x008
I2CMDR
R/W
0x0000.0000
I2C Master Data
459
0x00C
I2CMTPR
R/W
0x0000.0001
I2C Master Timer Period
460
0x010
I2CMIMR
R/W
0x0000.0000
I2C Master Interrupt Mask
461
0x014
I2CMRIS
RO
0x0000.0000
I2C Master Raw Interrupt Status
462
0x018
I2CMMIS
RO
0x0000.0000
I2C Master Masked Interrupt Status
463
0x01C
I2CMICR
WO
0x0000.0000
I2C Master Interrupt Clear
464
0x020
I2CMCR
R/W
0x0000.0000
I2C Master Configuration
465
I2C Master
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Table 13-3. Inter-Integrated Circuit (I2C) Interface Register Map (continued)
Offset
Description
See
page
Name
Type
Reset
0x800
I2CSOAR
R/W
0x0000.0000
I2C Slave Own Address
467
0x804
I2CSCSR
RO
0x0000.0000
I2C Slave Control/Status
468
0x808
I2CSDR
R/W
0x0000.0000
I2C Slave Data
470
0x80C
I2CSIMR
R/W
0x0000.0000
I2C Slave Interrupt Mask
471
0x810
I2CSRIS
RO
0x0000.0000
I2C Slave Raw Interrupt Status
472
0x814
I2CSMIS
RO
0x0000.0000
I2C Slave Masked Interrupt Status
473
0x818
I2CSICR
WO
0x0000.0000
I2C Slave Interrupt Clear
474
I2C Slave
13.6
Register Descriptions (I2C Master)
The remainder of this section lists and describes the I2C master registers, in numerical order by
address offset. See also “Register Descriptions (I2C Slave)” on page 466.
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Register 1: I2C Master Slave Address (I2CMSA), offset 0x000
This register consists of eight bits: seven address bits (A6-A0), and a Receive/Send bit, which
determines if the next operation is a Receive (High), or Send (Low).
I2C Master Slave Address (I2CMSA)
I2C 0 base: 0x4002.0000
Offset 0x000
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
SA
RO
0
R/S
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:1
SA
R/W
0
I2C Slave Address
This field specifies bits A6 through A0 of the slave address.
0
R/S
R/W
0
Receive/Send
The R/S bit specifies if the next operation is a Receive (High) or Send
(Low).
Value Description
0
Send.
1
Receive.
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Register 2: I2C Master Control/Status (I2CMCS), offset 0x004
This register accesses four control bits when written, and accesses seven status bits when read.
The status register consists of seven bits, which when read determine the state of the I2C bus
controller.
The control register consists of four bits: the RUN, START, STOP, and ACK bits. The START bit causes
the generation of the START, or REPEATED START condition.
The STOP bit determines if the cycle stops at the end of the data cycle, or continues on to a burst.
To generate a single send cycle, the I2C Master Slave Address (I2CMSA) register is written with
the desired address, the R/S bit is set to 0, and the Control register is written with ACK=X (0 or 1),
STOP=1, START=1, and RUN=1 to perform the operation and stop. When the operation is completed
(or aborted due an error), the interrupt pin becomes active and the data may be read from the
I2CMDR register. When the I2C module operates in Master receiver mode, the ACK bit must be set
normally to logic 1. This causes the I2C bus controller to send an acknowledge automatically after
each byte. This bit must be reset when the I2C bus controller requires no further data to be sent
from the slave transmitter.
Reads
I2C Master Control/Status (I2CMCS)
I2C 0 base: 0x4002.0000
Offset 0x004
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
BUSBSY
IDLE
ARBLST
ERROR
BUSY
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
DATACK ADRACK
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:7
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
6
BUSBSY
RO
0
Bus Busy
This bit specifies the state of the I2C bus. If set, the bus is busy;
otherwise, the bus is idle. The bit changes based on the START and
STOP conditions.
5
IDLE
RO
0
I2C Idle
This bit specifies the I2C controller state. If set, the controller is idle;
otherwise the controller is not idle.
4
ARBLST
RO
0
Arbitration Lost
This bit specifies the result of bus arbitration. If set, the controller lost
arbitration; otherwise, the controller won arbitration.
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Bit/Field
Name
Type
Reset
3
DATACK
RO
0
Description
Acknowledge Data
This bit specifies the result of the last data operation. If set, the
transmitted data was not acknowledged; otherwise, the data was
acknowledged.
2
ADRACK
RO
0
Acknowledge Address
This bit specifies the result of the last address operation. If set, the
transmitted address was not acknowledged; otherwise, the address was
acknowledged.
1
ERROR
RO
0
Error
This bit specifies the result of the last bus operation. If set, an error
occurred on the last operation; otherwise, no error was detected. The
error can be from the slave address not being acknowledged or the
transmit data not being acknowledged.
0
BUSY
RO
0
I2C Busy
This bit specifies the state of the controller. If set, the controller is busy;
otherwise, the controller is idle. When the BUSY bit is set, the other status
bits are not valid.
Writes
I2C Master Control/Status (I2CMCS)
I2C 0 base: 0x4002.0000
Offset 0x004
Type WO, reset 0x0000.0000
31
30
29
28
27
26
25
24
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
15
14
13
12
11
10
9
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
23
22
21
20
19
18
17
16
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
8
7
6
5
4
3
2
1
0
ACK
STOP
START
RUN
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
WO
0
reserved
Type
Reset
reserved
Type
Reset
Bit/Field
Name
Type
Reset
Description
31:4
reserved
WO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
3
ACK
WO
0
Data Acknowledge Enable
When set, causes received data byte to be acknowledged automatically
by the master. See field decoding in Table 13-4 on page 457.
2
STOP
WO
0
Generate STOP
When set, causes the generation of the STOP condition. See field
decoding in Table 13-4 on page 457.
1
START
WO
0
Generate START
When set, causes the generation of a START or repeated START
condition. See field decoding in Table 13-4 on page 457.
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Bit/Field
Name
Type
Reset
0
RUN
WO
0
Description
I2C Master Enable
When set, allows the master to send or receive data. See field decoding
in Table 13-4 on page 457.
Table 13-4. Write Field Decoding for I2CMCS[3:0] Field (Sheet 1 of 3)
Current I2CMSA[0]
State
R/S
Idle
I2CMCS[3:0]
ACK
STOP
START
RUN
1
0
X
a
0
1
0
X
1
1
1
START condition followed by a SEND and STOP
condition (master remains in Idle state).
1
0
0
1
1
START condition followed by RECEIVE operation with
negative ACK (master goes to the Master Receive state).
1
0
1
1
1
START condition followed by RECEIVE and STOP
condition (master remains in Idle state).
1
1
0
1
1
START condition followed by RECEIVE (master goes
to the Master Receive state).
1
1
1
1
1
Illegal.
All other combinations not listed are non-operations.
Master
Transmit
Description
START condition followed by SEND (master goes to the
Master Transmit state).
NOP.
X
X
0
0
1
SEND operation (master remains in Master Transmit
state).
X
X
1
0
0
STOP condition (master goes to Idle state).
X
X
1
0
1
SEND followed by STOP condition (master goes to Idle
state).
0
X
0
1
1
Repeated START condition followed by a SEND (master
remains in Master Transmit state).
0
X
1
1
1
Repeated START condition followed by SEND and STOP
condition (master goes to Idle state).
1
0
0
1
1
Repeated START condition followed by a RECEIVE
operation with a negative ACK (master goes to Master
Receive state).
1
0
1
1
1
Repeated START condition followed by a SEND and
STOP condition (master goes to Idle state).
1
1
0
1
1
Repeated START condition followed by RECEIVE
(master goes to Master Receive state).
1
1
1
1
1
Illegal.
All other combinations not listed are non-operations.
NOP.
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Inter-Integrated Circuit (I2C) Interface
Table 13-4. Write Field Decoding for I2CMCS[3:0] Field (Sheet 1 of 3) (continued)
Current I2CMSA[0]
State
R/S
I2CMCS[3:0]
Description
ACK
STOP
START
RUN
X
0
0
0
1
RECEIVE operation with negative ACK (master remains
in Master Receive state).
X
X
1
0
0
STOP condition (master goes to Idle state).
X
0
1
0
1
RECEIVE followed by STOP condition (master goes to
Idle state).
X
1
0
0
1
RECEIVE operation (master remains in Master Receive
state).
X
1
1
0
1
Illegal.
1
0
0
1
1
Repeated START condition followed by RECEIVE
operation with a negative ACK (master remains in Master
Receive state).
1
0
1
1
1
Repeated START condition followed by RECEIVE and
STOP condition (master goes to Idle state).
1
1
0
1
1
Repeated START condition followed by RECEIVE
(master remains in Master Receive state).
0
X
0
1
1
Repeated START condition followed by SEND (master
goes to Master Transmit state).
0
X
1
1
1
Repeated START condition followed by SEND and STOP
condition (master goes to Idle state).
Master
Receive
All other combinations not listed are non-operations.
b
NOP.
a. An X in a table cell indicates the bit can be 0 or 1.
b. In Master Receive mode, a STOP condition should be generated only after a Data Negative Acknowledge executed by
the master or an Address Negative Acknowledge executed by the slave.
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Register 3: I2C Master Data (I2CMDR), offset 0x008
Important: This register is read-sensitive. See the register description for details.
This register contains the data to be transmitted when in the Master Transmit state, and the data
received when in the Master Receive state.
I2C Master Data (I2CMDR)
I2C 0 base: 0x4002.0000
Offset 0x008
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
DATA
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
DATA
R/W
0x00
Data Transferred
Data transferred during transaction.
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Inter-Integrated Circuit (I2C) Interface
Register 4: I2C Master Timer Period (I2CMTPR), offset 0x00C
This register specifies the period of the SCL clock.
Caution – Take care not to set bit 7 when accessing this register as unpredictable behavior can occur.
I2C Master Timer Period (I2CMTPR)
I2C 0 base: 0x4002.0000
Offset 0x00C
Type R/W, reset 0x0000.0001
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
R/W
0
R/W
0
R/W
1
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
15
14
13
12
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
TPR
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:7
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
6:0
TPR
R/W
0x1
SCL Clock Period
This field specifies the period of the SCL clock.
SCL_PRD = 2*(1 + TPR)*(SCL_LP + SCL_HP)*CLK_PRD
where:
SCL_PRD is the SCL line period (I2C clock).
TPR is the Timer Period register value (range of 1 to 127).
SCL_LP is the SCL Low period (fixed at 6).
SCL_HP is the SCL High period (fixed at 4).
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Register 5: I2C Master Interrupt Mask (I2CMIMR), offset 0x010
This register controls whether a raw interrupt is promoted to a controller interrupt.
I2C Master Interrupt Mask (I2CMIMR)
I2C 0 base: 0x4002.0000
Offset 0x010
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
IM
Bit/Field
Name
Type
Reset
Description
31:1
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
0
IM
R/W
0
Interrupt Mask
This bit controls whether a raw interrupt is promoted to a controller
interrupt. If set, the interrupt is not masked and the interrupt is promoted;
otherwise, the interrupt is masked.
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Inter-Integrated Circuit (I2C) Interface
Register 6: I2C Master Raw Interrupt Status (I2CMRIS), offset 0x014
This register specifies whether an interrupt is pending.
I2C Master Raw Interrupt Status (I2CMRIS)
I2C 0 base: 0x4002.0000
Offset 0x014
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
RIS
RO
0
Bit/Field
Name
Type
Reset
Description
31:1
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
0
RIS
RO
0
Raw Interrupt Status
This bit specifies the raw interrupt state (prior to masking) of the I2C
master block. If set, an interrupt is pending; otherwise, an interrupt is
not pending.
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Register 7: I2C Master Masked Interrupt Status (I2CMMIS), offset 0x018
This register specifies whether an interrupt was signaled.
I2C Master Masked Interrupt Status (I2CMMIS)
I2C 0 base: 0x4002.0000
Offset 0x018
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
MIS
RO
0
Bit/Field
Name
Type
Reset
Description
31:1
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
0
MIS
RO
0
Masked Interrupt Status
This bit specifies the raw interrupt state (after masking) of the I2C master
block. If set, an interrupt was signaled; otherwise, an interrupt has not
been generated since the bit was last cleared.
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Register 8: I2C Master Interrupt Clear (I2CMICR), offset 0x01C
This register clears the raw interrupt.
I2C Master Interrupt Clear (I2CMICR)
I2C 0 base: 0x4002.0000
Offset 0x01C
Type WO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
WO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
IC
Bit/Field
Name
Type
Reset
Description
31:1
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
0
IC
WO
0
Interrupt Clear
This bit controls the clearing of the raw interrupt. A write of 1 clears the
interrupt; otherwise, a write of 0 has no affect on the interrupt state. A
read of this register returns no meaningful data.
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Register 9: I2C Master Configuration (I2CMCR), offset 0x020
This register configures the mode (Master or Slave) and sets the interface for test mode loopback.
I2C Master Configuration (I2CMCR)
I2C 0 base: 0x4002.0000
Offset 0x020
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
8
7
6
5
4
3
2
1
0
SFE
MFE
RO
0
RO
0
RO
0
R/W
0
R/W
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
reserved
RO
0
RO
0
LPBK
RO
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:6
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
5
SFE
R/W
0
I2C Slave Function Enable
This bit specifies whether the interface may operate in Slave mode. If
set, Slave mode is enabled; otherwise, Slave mode is disabled.
4
MFE
R/W
0
I2C Master Function Enable
This bit specifies whether the interface may operate in Master mode. If
set, Master mode is enabled; otherwise, Master mode is disabled and
the interface clock is disabled.
3:1
reserved
RO
0x00
0
LPBK
R/W
0
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
I2C Loopback
This bit specifies whether the interface is operating normally or in
Loopback mode. If set, the device is put in a test mode loopback
configuration; otherwise, the device operates normally.
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13.7
Register Descriptions (I2C Slave)
The remainder of this section lists and describes the I2C slave registers, in numerical order by
address offset. See also “Register Descriptions (I2C Master)” on page 453.
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Register 10: I2C Slave Own Address (I2CSOAR), offset 0x800
This register consists of seven address bits that identify the Stellaris I2C device on the I2C bus.
I2C Slave Own Address (I2CSOAR)
I2C 0 base: 0x4002.0000
Offset 0x800
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
15
14
13
12
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
OAR
RO
0
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:7
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
6:0
OAR
R/W
0x00
I2C Slave Own Address
This field specifies bits A6 through A0 of the slave address.
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Inter-Integrated Circuit (I2C) Interface
Register 11: I2C Slave Control/Status (I2CSCSR), offset 0x804
This register accesses one control bit when written, and three status bits when read.
The read-only Status register consists of three bits: the FBR, RREQ, and TREQ bits. The First
Byte Received (FBR) bit is set only after the Stellaris device detects its own slave address and
receives the first data byte from the I2C master. The Receive Request (RREQ) bit indicates that
the Stellaris I2C device has received a data byte from an I2C master. Read one data byte from the
I2C Slave Data (I2CSDR) register to clear the RREQ bit. The Transmit Request (TREQ) bit
indicates that the Stellaris I2C device is addressed as a Slave Transmitter. Write one data byte into
the I2C Slave Data (I2CSDR) register to clear the TREQ bit.
The write-only Control register consists of one bit: the DA bit. The DA bit enables and disables the
Stellaris I2C slave operation.
Reads
I2C Slave Control/Status (I2CSCSR)
I2C 0 base: 0x4002.0000
Offset 0x804
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
9
8
7
6
5
4
3
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
2
1
0
FBR
TREQ
RREQ
RO
0
RO
0
RO
0
Bit/Field
Name
Type
Reset
Description
31:3
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
2
FBR
RO
0
First Byte Received
Indicates that the first byte following the slave’s own address is received.
This bit is only valid when the RREQ bit is set, and is automatically cleared
when data has been read from the I2CSDR register.
Note:
1
TREQ
RO
0
This bit is not used for slave transmit operations.
Transmit Request
This bit specifies the state of the I2C slave with regards to outstanding
transmit requests. If set, the I2C unit has been addressed as a slave
transmitter and uses clock stretching to delay the master until data has
been written to the I2CSDR register. Otherwise, there is no outstanding
transmit request.
0
RREQ
RO
0
Receive Request
This bit specifies the status of the I2C slave with regards to outstanding
receive requests. If set, the I2C unit has outstanding receive data from
the I2C master and uses clock stretching to delay the master until the
data has been read from the I2CSDR register. Otherwise, no receive
data is outstanding.
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Writes
I2C Slave Control/Status (I2CSCSR)
I2C 0 base: 0x4002.0000
Offset 0x804
Type WO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
WO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
DA
Bit/Field
Name
Type
Reset
Description
31:1
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
0
DA
WO
0
Device Active
Value Description
0
Disables the I2C slave operation.
1
Enables the I2C slave operation.
Once this bit has been set, it should not be set again unless it has been
cleared by writing a 0 or by a reset, otherwise transfer failures may
occur.
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Inter-Integrated Circuit (I2C) Interface
Register 12: I2C Slave Data (I2CSDR), offset 0x808
Important: This register is read-sensitive. See the register description for details.
This register contains the data to be transmitted when in the Slave Transmit state, and the data
received when in the Slave Receive state.
I2C Slave Data (I2CSDR)
I2C 0 base: 0x4002.0000
Offset 0x808
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
3
2
1
0
R/W
0
R/W
0
R/W
0
R/W
0
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
7
6
5
4
reserved
Type
Reset
RO
0
RO
0
RO
0
RO
0
DATA
RO
0
RO
0
RO
0
RO
0
R/W
0
R/W
0
R/W
0
R/W
0
Bit/Field
Name
Type
Reset
Description
31:8
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
7:0
DATA
R/W
0x0
Data for Transfer
This field contains the data for transfer during a slave receive or transmit
operation.
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Register 13: I2C Slave Interrupt Mask (I2CSIMR), offset 0x80C
This register controls whether a raw interrupt is promoted to a controller interrupt.
I2C Slave Interrupt Mask (I2CSIMR)
I2C 0 base: 0x4002.0000
Offset 0x80C
Type R/W, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
DATAIM
R/W
0
Bit/Field
Name
Type
Reset
Description
31:1
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
0
DATAIM
R/W
0
Data Interrupt Mask
This bit controls whether the raw interrupt for data received and data
requested is promoted to a controller interrupt. If set, the interrupt is not
masked and the interrupt is promoted; otherwise, the interrupt is masked.
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Inter-Integrated Circuit (I2C) Interface
Register 14: I2C Slave Raw Interrupt Status (I2CSRIS), offset 0x810
This register specifies whether an interrupt is pending.
I2C Slave Raw Interrupt Status (I2CSRIS)
I2C 0 base: 0x4002.0000
Offset 0x810
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
DATARIS
RO
0
Bit/Field
Name
Type
Reset
Description
31:1
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
0
DATARIS
RO
0
Data Raw Interrupt Status
This bit specifies the raw interrupt state for data received and data
requested (prior to masking) of the I2C slave block. If set, an interrupt
is pending; otherwise, an interrupt is not pending.
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Register 15: I2C Slave Masked Interrupt Status (I2CSMIS), offset 0x814
This register specifies whether an interrupt was signaled.
I2C Slave Masked Interrupt Status (I2CSMIS)
I2C 0 base: 0x4002.0000
Offset 0x814
Type RO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
DATAMIS
RO
0
Bit/Field
Name
Type
Reset
Description
31:1
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
0
DATAMIS
RO
0
Data Masked Interrupt Status
This bit specifies the interrupt state for data received and data requested
(after masking) of the I2C slave block. If set, an interrupt was signaled;
otherwise, an interrupt has not been generated since the bit was last
cleared.
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Inter-Integrated Circuit (I2C) Interface
Register 16: I2C Slave Interrupt Clear (I2CSICR), offset 0x818
This register clears the raw interrupt. A read of this register returns no meaningful data.
I2C Slave Interrupt Clear (I2CSICR)
I2C 0 base: 0x4002.0000
Offset 0x818
Type WO, reset 0x0000.0000
31
30
29
28
27
26
25
24
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
15
14
13
12
11
10
9
8
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
23
22
21
20
19
18
17
16
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
7
6
5
4
3
2
1
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
RO
0
reserved
Type
Reset
reserved
Type
Reset
RO
0
DATAIC
WO
0
Bit/Field
Name
Type
Reset
Description
31:1
reserved
RO
0x00
Software should not rely on the value of a reserved bit. To provide
compatibility with future products, the value of a reserved bit should be
preserved across a read-modify-write operation.
0
DATAIC
WO
0
Data Interrupt Clear
This bit controls the clearing of the raw interrupt for data received and
data requested. When set, it clears the DATARIS interrupt bit; otherwise,
it has no effect on the DATARIS bit value.
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14
Pin Diagram
The LM3S828 microcontroller pin diagrams are shown below.
Figure 14-1. 48-Pin QFP Package Pin Diagram
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Signal Tables
15
Signal Tables
Important: All multiplexed pins are GPIOs by default, with the exception of the five JTAG pins (PB7
and PC[3:0]) which default to the JTAG functionality.
The following tables list the signals available for each pin. Functionality is enabled by software with
the GPIOAFSEL register. All digital inputs are Schmitt triggered.
■
■
■
■
■
15.1
Signals by Pin Number
Signals by Signal Name
Signals by Function, Except for GPIO
GPIO Pins and Alternate Functions
Connections for Unused Signals
Signals by Pin Number
Table 15-1. Signals by Pin Number
a
Pin Number
Pin Name
Pin Type
Buffer Type
1
ADC0
I
Analog
Analog-to-digital converter input 0.
2
ADC1
I
Analog
Analog-to-digital converter input 1.
3
ADC2
I
Analog
Analog-to-digital converter input 2.
4
ADC3
I
Analog
Analog-to-digital converter input 3.
5
RST
I
TTL
LDO
-
Power
Low drop-out regulator output voltage. This pin requires an external
capacitor between the pin and GND of 1 µF or greater.
7
VDD
-
Power
Positive supply for I/O and some logic.
8
GND
-
Power
Ground reference for logic and I/O pins.
9
OSC0
I
Analog
Main oscillator crystal input or an external clock reference input.
OSC1
O
Analog
Main oscillator crystal output. Leave unconnected when using a
single-ended clock source.
6
10
Description
System reset input.
PC7
I/O
TTL
GPIO port C bit 7.
CCP4
I/O
TTL
Capture/Compare/PWM 4.
PC6
I/O
TTL
GPIO port C bit 6.
CCP3
I/O
TTL
Capture/Compare/PWM 3.
PC5
I/O
TTL
GPIO port C bit 5.
11
12
13
CCP1
I/O
TTL
Capture/Compare/PWM 1.
14
PC4
I/O
TTL
GPIO port C bit 4.
15
VDD
-
Power
Positive supply for I/O and some logic.
16
GND
-
Power
Ground reference for logic and I/O pins.
PA0
I/O
TTL
GPIO port A bit 0.
U0Rx
I
TTL
UART module 0 receive.
PA1
I/O
TTL
GPIO port A bit 1.
U0Tx
O
TTL
UART module 0 transmit.
PA2
I/O
TTL
GPIO port A bit 2.
SSIClk
I/O
TTL
SSI clock.
17
18
19
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Table 15-1. Signals by Pin Number (continued)
Pin Number
a
Pin Name
Pin Type
Buffer Type
Description
PA3
I/O
TTL
GPIO port A bit 3.
SSIFss
I/O
TTL
SSI frame.
PA4
I/O
TTL
GPIO port A bit 4.
SSIRx
I
TTL
SSI receive.
PA5
I/O
TTL
GPIO port A bit 5.
SSI transmit.
20
21
22
SSITx
O
TTL
23
VDD
-
Power
Positive supply for I/O and some logic.
24
GND
-
Power
Ground reference for logic and I/O pins.
25
PD0
I/O
TTL
GPIO port D bit 0.
26
PD1
I/O
TTL
GPIO port D bit 1.
PD2
I/O
TTL
GPIO port D bit 2.
U1Rx
I
TTL
UART module 1 receive.
PD3
I/O
TTL
GPIO port D bit 3.
U1Tx
O
TTL
UART module 1 transmit.
PB0
I/O
TTL
GPIO port B bit 0.
CCP0
I/O
TTL
Capture/Compare/PWM 0.
PB1
I/O
TTL
GPIO port B bit 1.
CCP2
I/O
TTL
Capture/Compare/PWM 2.
31
GND
-
Power
Ground reference for logic and I/O pins.
32
VDD
-
Power
Positive supply for I/O and some logic.
PB2
I/O
TTL
GPIO port B bit 2.
I2CSCL
I/O
OD
I2C clock.
PB3
I/O
TTL
GPIO port B bit 3.
I2CSDA
I/O
OD
I2C data.
35
PE0
I/O
TTL
GPIO port E bit 0.
36
PE1
I/O
TTL
GPIO port E bit 1.
PC3
I/O
TTL
GPIO port C bit 3.
SWO
O
TTL
JTAG TDO and SWO.
TDO
O
TTL
JTAG TDO and SWO.
PC2
I/O
TTL
GPIO port C bit 2.
TDI
I
TTL
JTAG TDI.
27
28
29
30
33
34
37
38
39
40
PC1
I/O
TTL
GPIO port C bit 1.
SWDIO
I/O
TTL
JTAG TMS and SWDIO.
TMS
I/O
TTL
JTAG TMS and SWDIO.
PC0
I/O
TTL
GPIO port C bit 0.
SWCLK
I
TTL
JTAG/SWD CLK.
TCK
I
TTL
JTAG/SWD CLK.
PB7
I/O
TTL
GPIO port B bit 7.
TRST
I
TTL
JTAG TRST.
PB6
I/O
TTL
GPIO port B bit 6.
41
42
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Signal Tables
Table 15-1. Signals by Pin Number (continued)
Pin Number
a
Pin Name
Pin Type
Buffer Type
Description
PB5
I/O
TTL
GPIO port B bit 5.
CCP5
I/O
TTL
Capture/Compare/PWM 5.
44
PB4
I/O
TTL
GPIO port B bit 4.
45
ADC7
I
Analog
Analog-to-digital converter input 7.
46
ADC6
I
Analog
Analog-to-digital converter input 6.
47
ADC5
I
Analog
Analog-to-digital converter input 5.
48
ADC4
I
Analog
Analog-to-digital converter input 4.
43
a. The TTL designation indicates the pin has TTL-compatible voltage levels.
15.2
Signals by Signal Name
Table 15-2. Signals by Signal Name
a
Pin Name
Pin Number
Pin Type
Buffer Type
Description
ADC0
1
I
Analog
Analog-to-digital converter input 0.
ADC1
2
I
Analog
Analog-to-digital converter input 1.
ADC2
3
I
Analog
Analog-to-digital converter input 2.
ADC3
4
I
Analog
Analog-to-digital converter input 3.
ADC4
48
I
Analog
Analog-to-digital converter input 4.
ADC5
47
I
Analog
Analog-to-digital converter input 5.
ADC6
46
I
Analog
Analog-to-digital converter input 6.
ADC7
45
I
Analog
Analog-to-digital converter input 7.
CCP0
29
I/O
TTL
Capture/Compare/PWM 0.
CCP1
13
I/O
TTL
Capture/Compare/PWM 1.
CCP2
30
I/O
TTL
Capture/Compare/PWM 2.
CCP3
12
I/O
TTL
Capture/Compare/PWM 3.
CCP4
11
I/O
TTL
Capture/Compare/PWM 4.
CCP5
43
I/O
TTL
Capture/Compare/PWM 5.
GND
8
16
24
31
-
Power
I2CSCL
33
I/O
OD
I2C clock.
I2CSDA
34
I/O
OD
I2C data.
LDO
6
-
Power
Low drop-out regulator output voltage. This pin requires an
external capacitor between the pin and GND of 1 µF or
greater.
OSC0
9
I
Analog
Main oscillator crystal input or an external clock reference
input.
OSC1
10
O
Analog
Main oscillator crystal output. Leave unconnected when using
a single-ended clock source.
PA0
17
I/O
TTL
GPIO port A bit 0.
PA1
18
I/O
TTL
GPIO port A bit 1.
PA2
19
I/O
TTL
GPIO port A bit 2.
PA3
20
I/O
TTL
GPIO port A bit 3.
Ground reference for logic and I/O pins.
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Table 15-2. Signals by Signal Name (continued)
a
Pin Name
Pin Number
Pin Type
Buffer Type
Description
PA4
21
I/O
TTL
GPIO port A bit 4.
PA5
22
I/O
TTL
GPIO port A bit 5.
PB0
29
I/O
TTL
GPIO port B bit 0.
PB1
30
I/O
TTL
GPIO port B bit 1.
PB2
33
I/O
TTL
GPIO port B bit 2.
PB3
34
I/O
TTL
GPIO port B bit 3.
PB4
44
I/O
TTL
GPIO port B bit 4.
PB5
43
I/O
TTL
GPIO port B bit 5.
PB6
42
I/O
TTL
GPIO port B bit 6.
PB7
41
I/O
TTL
GPIO port B bit 7.
PC0
40
I/O
TTL
GPIO port C bit 0.
PC1
39
I/O
TTL
GPIO port C bit 1.
PC2
38
I/O
TTL
GPIO port C bit 2.
PC3
37
I/O
TTL
GPIO port C bit 3.
PC4
14
I/O
TTL
GPIO port C bit 4.
PC5
13
I/O
TTL
GPIO port C bit 5.
PC6
12
I/O
TTL
GPIO port C bit 6.
PC7
11
I/O
TTL
GPIO port C bit 7.
PD0
25
I/O
TTL
GPIO port D bit 0.
PD1
26
I/O
TTL
GPIO port D bit 1.
PD2
27
I/O
TTL
GPIO port D bit 2.
PD3
28
I/O
TTL
GPIO port D bit 3.
PE0
35
I/O
TTL
GPIO port E bit 0.
PE1
36
I/O
TTL
GPIO port E bit 1.
RST
5
I
TTL
System reset input.
SSIClk
19
I/O
TTL
SSI clock.
SSIFss
20
I/O
TTL
SSI frame.
SSIRx
21
I
TTL
SSI receive.
SSITx
22
O
TTL
SSI transmit.
SWCLK
40
I
TTL
JTAG/SWD CLK.
SWDIO
39
I/O
TTL
JTAG TMS and SWDIO.
SWO
37
O
TTL
JTAG TDO and SWO.
TCK
40
I
TTL
JTAG/SWD CLK.
TDI
38
I
TTL
JTAG TDI.
TDO
37
O
TTL
JTAG TDO and SWO.
TMS
39
I/O
TTL
JTAG TMS and SWDIO.
TRST
41
I
TTL
JTAG TRST.
U0Rx
17
I
TTL
UART module 0 receive.
U0Tx
18
O
TTL
UART module 0 transmit.
U1Rx
27
I
TTL
UART module 1 receive.
U1Tx
28
O
TTL
UART module 1 transmit.
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Signal Tables
Table 15-2. Signals by Signal Name (continued)
a
Pin Name
Pin Number
Pin Type
Buffer Type
VDD
7
15
23
32
-
Power
Description
Positive supply for I/O and some logic.
a. The TTL designation indicates the pin has TTL-compatible voltage levels.
15.3
Signals by Function, Except for GPIO
Table 15-3. Signals by Function, Except for GPIO
Function
Pin Name
Pin Type
Buffer Type
ADC0
1
I
Analog
Analog-to-digital converter input 0.
ADC1
2
I
Analog
Analog-to-digital converter input 1.
ADC2
3
I
Analog
Analog-to-digital converter input 2.
ADC3
4
I
Analog
Analog-to-digital converter input 3.
ADC4
48
I
Analog
Analog-to-digital converter input 4.
ADC5
47
I
Analog
Analog-to-digital converter input 5.
ADC6
46
I
Analog
Analog-to-digital converter input 6.
ADC7
45
I
Analog
Analog-to-digital converter input 7.
CCP0
29
I/O
TTL
Capture/Compare/PWM 0.
CCP1
13
I/O
TTL
Capture/Compare/PWM 1.
CCP2
30
I/O
TTL
Capture/Compare/PWM 2.
CCP3
12
I/O
TTL
Capture/Compare/PWM 3.
CCP4
11
I/O
TTL
Capture/Compare/PWM 4.
CCP5
43
I/O
TTL
Capture/Compare/PWM 5.
I2CSCL
33
I/O
OD
I2C clock.
I2CSDA
34
I/O
OD
I2C data.
SWCLK
40
I
TTL
JTAG/SWD CLK.
SWDIO
39
I/O
TTL
JTAG TMS and SWDIO.
SWO
37
O
TTL
JTAG TDO and SWO.
TCK
40
I
TTL
JTAG/SWD CLK.
TDI
38
I
TTL
JTAG TDI.
TDO
37
O
TTL
JTAG TDO and SWO.
TMS
39
I/O
TTL
JTAG TMS and SWDIO.
JTAG TRST.
ADC
General-Purpose
Timers
a
Pin Number
I2C
JTAG/SWD/SWO
Description
TRST
41
I
TTL
GND
8
16
24
31
-
Power
Ground reference for logic and I/O pins.
LDO
6
-
Power
Low drop-out regulator output voltage. This pin
requires an external capacitor between the pin and
GND of 1 µF or greater.
VDD
7
15
23
32
-
Power
Positive supply for I/O and some logic.
Power
480
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Table 15-3. Signals by Function, Except for GPIO (continued)
Function
Pin Name
Pin Type
Buffer Type
SSIClk
19
I/O
TTL
SSI clock.
SSIFss
20
I/O
TTL
SSI frame.
SSIRx
21
I
TTL
SSI receive.
SSITx
22
O
TTL
SSI transmit.
OSC0
9
I
Analog
Main oscillator crystal input or an external clock
reference input.
OSC1
10
O
Analog
Main oscillator crystal output. Leave unconnected
when using a single-ended clock source.
RST
5
I
TTL
System reset input.
U0Rx
17
I
TTL
UART module 0 receive.
U0Tx
18
O
TTL
UART module 0 transmit.
U1Rx
27
I
TTL
UART module 1 receive.
U1Tx
28
O
TTL
UART module 1 transmit.
SSI
System Control &
Clocks
a
Pin Number
UART
Description
a. The TTL designation indicates the pin has TTL-compatible voltage levels.
15.4
GPIO Pins and Alternate Functions
Table 15-4. GPIO Pins and Alternate Functions
IO
Pin Number
Multiplexed Function
PA0
17
U0Rx
PA1
18
U0Tx
PA2
19
SSIClk
Multiplexed Function
PA3
20
SSIFss
PA4
21
SSIRx
PA5
22
SSITx
PB0
29
CCP0
PB1
30
CCP2
PB2
33
I2CSCL
PB3
34
I2CSDA
PB4
44
PB5
43
PB6
42
PB7
41
TRST
PC0
40
TCK
SWCLK
PC1
39
TMS
SWDIO
PC2
38
TDI
PC3
37
TDO
PC4
14
PC5
13
CCP1
PC6
12
CCP3
PC7
11
CCP4
PD0
25
CCP5
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Table 15-4. GPIO Pins and Alternate Functions (continued)
15.5
IO
Pin Number
Multiplexed Function
PD1
26
PD2
27
U1Rx
PD3
28
U1Tx
PE0
35
PE1
36
Multiplexed Function
Connections for Unused Signals
Table 15-5 on page 482 show how to handle signals for functions that are not used in a particular
system implementation. Two options are shown in the table: an acceptable practice and a preferred
practice for reduced power consumption and improved EMC characteristics.
Table 15-5. Connections for Unused Signals
Function
ADC
GPIO
System
Control
Signal Name
Pin Number
Acceptable Practice
Preferred Practice
ADC0
1
NC
GNDA
ADC1
2
ADC2
3
ADC3
4
ADC4
48
ADC5
47
ADC6
46
ADC7
45
All unused GPIOs
-
NC
GND
OSC0
9
NC
GND
OSC1
10
NC
NC
RST
5
Pull up as shown in Figure Connect through a capacitor to
5-1 on page 152
GND as close to pin as possible
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16
Operating Characteristics
Table 16-1. Temperature Characteristics
Characteristic
Symbol
Value
Industrial operating temperature range
TA
-40 to +85
Unit
°C
Unpowered storage temperature range
TS
-65 to +150
°C
Table 16-2. Thermal Characteristics
Characteristic
a
Thermal resistance (junction to ambient)
b
Symbol
Value
ΘJA
50 (48-pin QFP)
Unit
°C/W
Junction temperature
TJ
TA + (P • ΘJA)
°C
Maximum junction temperature
TJMAX
115
°C
c
a. Junction to ambient thermal resistance θJA numbers are determined by a package simulator.
b. Power dissipation is a function of temperature.
c. TJMAX calculation is based on power consumption values and conditions as specified in “Power Specifications”.
a
Table 16-3. ESD Absolute Maximum Ratings
Parameter Name
VESDHBM
Min
Nom
Max
Unit
-
-
2.0
kV
VESDCDM
-
-
1.0
kV
VESDMM
-
-
100
V
a. All Stellaris parts are ESD tested following the JEDEC standard.
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17
Electrical Characteristics
17.1
DC Characteristics
17.1.1
Maximum Ratings
The maximum ratings are the limits to which the device can be subjected without permanently
damaging the device.
Note:
The device is not guaranteed to operate properly at the maximum ratings.
Table 17-1. Maximum Ratings
a
Characteristic
Supply voltage range (VDD)
Input voltage
Symbol
Value
VDD
0.0 to +3.6
V
-0.3 to 5.5
V
VIN
Input voltage for a GPIO configured as an analog input
Unit
-0.3 to VDD + 0.3
V
Maximum current for pins, excluding pins operating as GPIOs
I
100
mA
Maximum current for GPIO pins
I
100
mA
VNON
300
mV
Maximum input voltage on a non-power pin when the
microcontroller is unpowered
a. Voltages are measured with respect to GND.
Important: This device contains circuitry to protect the inputs against damage due to high-static
voltages or electric fields; however, it is advised that normal precautions be taken to
avoid application of any voltage higher than maximum-rated voltages to this
high-impedance circuit. Reliability of operation is enhanced if unused inputs are
connected to an appropriate logic voltage level (for example, either GND or VDD).
17.1.2
Recommended DC Operating Conditions
Table 17-2. Recommended DC Operating Conditions
Parameter Parameter Name
Min
Nom
Max
Unit
3.0
3.3
3.6
V
VDD
Supply voltage
VIH
High-level input voltage
2.0
-
5.0
V
VIL
Low-level input voltage
-0.3
-
1.3
V
VOH
High-level output voltage
2.4
-
-
V
VOL
Low-level output voltage
-
-
0.4
V
2-mA Drive
2.0
-
-
mA
4-mA Drive
4.0
-
-
mA
8-mA Drive
8.0
-
-
mA
2-mA Drive
2.0
-
-
mA
4-mA Drive
4.0
-
-
mA
8-mA Drive
8.0
-
-
mA
High-level source current, VOH=2.4 V
IOH
Low-level sink current, VOL=0.4 V
IOL
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17.1.3
On-Chip Low Drop-Out (LDO) Regulator Characteristics
Table 17-3. LDO Regulator Characteristics
Parameter
Parameter Name
Min
Nom
Max
Unit
Programmable internal (logic) power supply
output value
2.25
-
2.75
V
Output voltage accuracy
-
2%
-
%
tPON
Power-on time
-
-
100
µs
tON
Time on
-
-
200
µs
tOFF
Time off
-
-
100
µs
VSTEP
Step programming incremental voltage
-
50
-
mV
CLDO
External filter capacitor size for internal power
supply
1.0
-
3.0
µF
VLDOOUT
17.1.4
GPIO Module Characteristics
Table 17-4. GPIO Module DC Characteristics
Parameter
Min
Nom
Max
Unit
RGPIOPU
GPIO internal pull-up resistor
50
-
110
kΩ
RGPIOPD
GPIO internal pull-down resistor
55
-
180
kΩ
-
-
2
µA
ILKG
Parameter Name
a
GPIO input leakage current
a. The leakage current is measured with GND or VDD applied to the corresponding pin(s). The leakage of digital port pins is
measured individually. The port pin is configured as an input and the pullup/pulldown resistor is disabled.
17.1.5
Power Specifications
The power measurements specified in the tables that follow are run on the core processor using
SRAM with the following specifications (except as noted):
■ VDD = 3.3 V
■ Temperature = 25°C
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Table 17-5. Detailed Power Specifications
Parameter
Parameter Name
Conditions
Run mode 1 (Flash loop) LDO = 2.50 V
Nom
Max
Unit
95
110
mA
60
75
mA
85
95
mA
50
60
mA
19
22
mA
950
1150
μA
Code = while(1){} executed out of Flash
Peripherals = All clock-gated ON
System Clock = 50 MHz (with PLL)
Run mode 2 (Flash loop) LDO = 2.50 V
Code = while(1){} executed out of Flash
Peripherals = All clock-gated OFF
IDD_RUN
System Clock = 50 MHz (with PLL)
Run mode 1 (SRAM
loop)
LDO = 2.50 V
Code = while(1){} executed in SRAM
Peripherals = All clock-gated ON
System Clock = 50 MHz (with PLL)
Run mode 2 (SRAM
loop)
LDO = 2.50 V
Code = while(1){} executed in SRAM
Peripherals = All clock-gated OFF
System Clock = 50 MHz (with PLL)
IDD_SLEEP
Sleep mode
LDO = 2.50 V
Peripherals = All clock-gated OFF
System Clock = 50 MHz (with PLL)
IDD_DEEPSLEEP Deep-Sleep mode
LDO = 2.25 V
Peripherals = All OFF
System Clock = MOSC/16
17.1.6
Flash Memory Characteristics
Table 17-6. Flash Memory Characteristics
Parameter
Min
Nom
Max
Unit
10,000
100,000
-
cycles
Data retention at average operating
temperature of 85˚C
10
-
-
years
TPROG
Word program time
20
-
-
µs
TERASE
Page erase time
20
-
-
ms
TME
Mass erase time
-
-
250
ms
PECYC
TRET
Parameter Name
Number of guaranteed program/erase cycles
a
before failure
a. A program/erase cycle is defined as switching the bits from 1-> 0 -> 1.
17.2
AC Characteristics
17.2.1
Load Conditions
Unless otherwise specified, the following conditions are true for all timing measurements. Timing
measurements are for 4-mA drive strength.
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Figure 17-1. Load Conditions
CL = 50 pF
pin
GND
17.2.2
Clocks
Table 17-7. Phase Locked Loop (PLL) Characteristics
Min
Nom
Max
Unit
fref_crystal
Parameter
Crystal reference
Parameter Name
3.579545
-
8.192
MHz
fref_ext
External clock referencea
3.579545
-
8.192
MHz
a
b
fpll
PLL frequency
-
200
-
MHz
TREADY
PLL lock time
-
-
0.5
ms
a. The exact value is determined by the crystal value programmed into the XTAL field of the Run-Mode Clock Configuration
(RCC) register.
b. PLL frequency is automatically calculated by the hardware based on the XTAL field of the RCC register.
Table 17-8. Clock Characteristics
Min
Nom
Max
Unit
fIOSC
Parameter
Parameter Name
Internal oscillator frequency
7
12
22
MHz
fMOSC
Main oscillator frequency
1
-
8
MHz
tMOSC_per
Main oscillator period
125
-
1000
ns
fref_crystal_bypass
Crystal reference using the main oscillator
a
(PLL in BYPASS mode)
1
-
8
MHz
fref_ext_bypass
External clock reference (PLL in BYPASS
a
mode)
0
-
50
MHz
fsystem_clock
System clock
0
-
50
MHz
a. The ADC must be clocked from the PLL or directly from a 16.667-MHz clock source to operate properly.
17.2.2.1
System Clock Specifications with ADC Operation
Table 17-9. System Clock Characteristics with ADC Operation
Parameter
fsysadc
17.2.3
Parameter Name
System clock frequency when the ADC module is
operating (when PLL is bypassed)
Min
Nom
Max
Unit
16
-
-
MHz
Min
Nom
Max
Unit
0
-
10
MHz
100
-
-
ns
JTAG and Boundary Scan
Table 17-10. JTAG Characteristics
Parameter
No.
Parameter
Parameter Name
J1
fTCK
TCK operational clock frequency
J2
tTCK
TCK operational clock period
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Table 17-10. JTAG Characteristics (continued)
Parameter
No.
Parameter
J3
tTCK_LOW
J4
tTCK_HIGH
Parameter Name
Min
Nom
Max
Unit
TCK clock Low time
-
tTCK/2
-
ns
TCK clock High time
-
tTCK/2
-
ns
J5
tTCK_R
TCK rise time
0
-
10
ns
J6
tTCK_F
TCK fall time
0
-
10
ns
J7
tTMS_SU
TMS setup time to TCK rise
20
-
-
ns
J8
tTMS_HLD
TMS hold time from TCK rise
20
-
-
ns
J9
tTDI_SU
TDI setup time to TCK rise
25
-
-
ns
J10
tTDI_HLD
TDI hold time from TCK rise
25
-
-
ns
J11
t TDO_ZDV
TCK fall to Data
Valid from High-Z
2-mA drive
23
35
ns
4-mA drive
15
26
ns
-
8-mA drive
8-mA drive with slew rate control
J12
t TDO_DV
J13
TCK fall to Data
Valid from Data
Valid
t TDO_DVZ
TCK fall to High-Z
from Data Valid
J14
tTRST
J15
tTRST_SU
14
25
ns
18
29
ns
2-mA drive
21
35
ns
4-mA drive
14
25
ns
13
24
ns
8-mA drive with slew rate control
18
28
ns
2-mA drive
9
11
ns
7
9
ns
6
8
ns
-
8-mA drive
4-mA drive
-
8-mA drive
7
9
ns
TRST assertion time
8-mA drive with slew rate control
100
-
-
ns
TRST setup time to TCK rise
10
-
-
ns
Figure 17-2. JTAG Test Clock Input Timing
J2
J3
J4
TCK
J6
J5
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Figure 17-3. JTAG Test Access Port (TAP) Timing
TCK
J7
TMS
TDI
J8
J7
TMS Input Valid
TMS Input Valid
J9
J9
J10
TDI Input Valid
J11
TDO
J8
J10
TDI Input Valid
J12
J13
TDO Output Valid
TDO Output Valid
Figure 17-4. JTAG TRST Timing
TCK
J14
J15
TRST
17.2.4
Reset
Table 17-11. Reset Characteristics
Parameter
No.
Parameter
Parameter Name
R1
VTH
Reset threshold
R2
VBTH
Brown-Out threshold
R3
TPOR
R4
TBOR
R5
TIRPOR
Internal reset timeout after POR
R6
TIRBOR
Internal reset timeout after BOR
R7
TIRHWR
Internal reset timeout after hardware reset
(RST pin)
R8
TIRSWR
Internal reset timeout after
software-initiated system reset a
R9
TIRWDR
Internal reset timeout after watchdog reseta
Min
Nom
Max
Unit
-
2.0
-
V
2.85
2.9
2.95
V
Power-On Reset timeout
-
10
-
ms
Brown-Out timeout
-
500
-
µs
15
-
30
ms
2.5
-
20
µs
2.9
-
29
µs
2.5
-
20
µs
2.5
-
20
µs
2.5
-
20
µs
-
-
100
ms
a
reseta
R10
TIRLDOR
Internal reset timeout after LDO
R11
TVDDRISE
Supply voltage (VDD) rise time (0 V-3.3 V)
a. 20 * t MOSC_per
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Figure 17-5. External Reset Timing (RST)
RST
R7
/Reset
(Internal)
Figure 17-6. Power-On Reset Timing
R1
VDD
R3
/POR
(Internal)
R5
/Reset
(Internal)
Figure 17-7. Brown-Out Reset Timing
R2
VDD
R4
/BOR
(Internal)
R6
/Reset
(Internal)
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Figure 17-8. Software Reset Timing
SW Reset
R8
/Reset
(Internal)
Figure 17-9. Watchdog Reset Timing
WDOG
Reset
(Internal)
R9
/Reset
(Internal)
Figure 17-10. LDO Reset Timing
LDO Reset
(Internal)
R10
/Reset
(Internal)
17.2.5
Sleep Modes
a
Table 17-12. Sleep Modes AC Characteristics
Parameter No
Parameter
D1
tWAKE_S
D2
tWAKE_PLL_S
Parameter Name
Min
Nom
Max
Unit
Time to wake from interrupt in sleep or
deep-sleep mode, not using the PLL
-
-
7
system clocks
Time to wake from interrupt in sleep or
deep-sleep mode when using the PLL
-
-
TREADY
ms
a. Values in this table assume the IOSC is the clock source during sleep or deep-sleep mode.
17.2.6
General-Purpose I/O (GPIO)
Note:
All GPIOs are 5 V-tolerant.
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Table 17-13. GPIO Characteristics
Parameter Parameter Name Condition
tGPIOR
tGPIOF
Min
GPIO Rise Time
(from 20% to 80%
of VDD)
Nom
Max
Unit
2-mA drive
17
26
ns
4-mA drive
9
13
ns
-
6
9
ns
8-mA drive with slew rate control
8-mA drive
10
12
ns
2-mA drive
17
25
ns
4-mA drive
8
12
ns
6
10
ns
11
13
ns
GPIO Fall Time
(from 80% to 20%
of VDD)
-
8-mA drive
8-mA drive with slew rate control
17.2.7
Analog-to-Digital Converter
a
Table 17-14. ADC Characteristics
Parameter
VADCIN
N
fADC
Parameter Name
Min
Nom
Max
Unit
Maximum single-ended, full-scale analog input
voltage
-
-
3.0
V
Minimum single-ended, full-scale analog input
voltage
0.0
-
-
V
Maximum differential, full-scale analog input
voltage
-
-
1.5
V
Minimum differential, full-scale analog input
voltage
0.0
-
-
V
Resolution
10
b
ADC internal clock frequency
18
MHz
1
µs
c
1041.667
k samples/s
tADCCONV
Conversion time
Conversion rate
IL
16.667
c
f ADCCONV
tLT
14
bits
Latency from trigger to start of conversion
-
2
-
system clocks
ADC input leakage
-
-
±3.0
µA
RADC
ADC equivalent resistance
-
-
10
kΩ
CADC
ADC equivalent capacitance
0.9
1.0
1.1
pF
-
-
±3
LSB
EL
Integral nonlinearity error
ED
Differential nonlinearity error
-
-
±2
EO
Offset error
-
-
+6
LSB
EG
Full-scale gain error
-
-
±3
LSB
ETS
Temperature sensor accuracy
-
-
±5
°C
d
LSB
a. The ADC reference voltage is 3.0 V. This reference voltage is internally generated from the 3.3 VDDA supply by a band
gap circuit.
b. The ADC must be clocked from the PLL or directly from an external clock source to operate properly.
c. The conversion time and rate scale from the specified number if the ADC internal clock frequency is any value other than
16.667 MHz.
d. The offset error listed above is the conversion result with 0 V applied to the ADC input.
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Figure 17-11. ADC Input Equivalency Diagram
Stellaris® Microcontroller
VDD
RADC
10-bit
converter
IL
VIN
CADC
Sample and hold
ADC converter
Table 17-15. ADC Module Internal Reference Characteristics
Parameter
VREFI
EIR
17.2.8
Parameter Name
Min
Nom
Max
Unit
Internal voltage reference for ADC
-
3.0
-
V
Internal voltage reference error
-
-
±2.5
%
Synchronous Serial Interface (SSI)
Table 17-16. SSI Characteristics
Parameter
No.
Parameter
Parameter Name
Min
S1
tclk_per
SSIClk cycle time
S2
tclk_high
SSIClk high time
S3
tclk_low
SSIClk low time
a
Nom
Max
Unit
2
-
65024
system clocks
-
0.5
-
t clk_per
-
0.5
-
t clk_per
-
6
10
ns
S4
tclkrf
SSIClk rise/fall time
S5
tDMd
Data from master valid delay time
0
-
1
system clocks
S6
tDMs
Data from master setup time
1
-
-
system clocks
S7
tDMh
Data from master hold time
2
-
-
system clocks
S8
tDSs
Data from slave setup time
1
-
-
system clocks
S9
tDSh
Data from slave hold time
2
-
-
system clocks
a. Note that the delays shown are using 8-mA drive strength.
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Figure 17-12. SSI Timing for TI Frame Format (FRF=01), Single Transfer Timing Measurement
S1
S4
S2
SSIClk
S3
SSIFss
SSITx
SSIRx
MSB
LSB
4 to 16 bits
Figure 17-13. SSI Timing for MICROWIRE Frame Format (FRF=10), Single Transfer
S2
S1
SSIClk
S3
SSIFss
SSITx
MSB
LSB
8-bit control
SSIRx
0
MSB
LSB
4 to 16 bits output data
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Figure 17-14. SSI Timing for SPI Frame Format (FRF=00), with SPH=1
S1
S2
S4
SSIClk
(SPO=0)
S3
SSIClk
(SPO=1)
S6
SSITx
(master)
S7
MSB
S5
SSIRx
(slave)
S8
LSB
S9
MSB
LSB
SSIFss
17.2.9
Inter-Integrated Circuit (I2C) Interface
Table 17-17. I2C Characteristics
Parameter
No.
Parameter
Parameter Name
Min
Nom
Max
Unit
a
tSCH
Start condition hold time
36
-
-
system clocks
a
tLP
Clock Low period
36
-
-
system clocks
b
tSRT
I2CSCL/I2CSDA rise time (VIL =0.5 V
to V IH =2.4 V)
-
-
(see note
b)
ns
a
tDH
Data hold time
2
-
-
system clocks
c
tSFT
I2CSCL/I2CSDA fall time (VIH =2.4 V
to V IL =0.5 V)
-
9
10
ns
I1
I2
I3
I4
I5
a
tHT
Clock High time
24
-
-
system clocks
a
tDS
Data setup time
18
-
-
system clocks
a
tSCSR
Start condition setup time (for repeated
start condition only)
36
-
-
system clocks
a
tSCS
Stop condition setup time
24
-
-
system clocks
I6
I7
I8
I9
I2C
a. Values depend on the value programmed into the TPR bit in the
Master Timer Period (I2CMTPR) register; a TPR
programmed for the maximum I2CSCL frequency (TPR=0x2) results in a minimum output timing as shown in the table
above. The I 2C interface is designed to scale the actual data transition time to move it to the middle of the I2CSCL Low
period. The actual position is affected by the value programmed into the TPR; however, the numbers given in the above
values are minimum values.
b. Because I2CSCL and I2CSDA are open-drain-type outputs, which the controller can only actively drive Low, the time
I2CSCL or I2CSDA takes to reach a high level depends on external signal capacitance and pull-up resistor values.
c. Specified at a nominal 50 pF load.
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Figure 17-15. I2C Timing
I2
I6
I5
I2CSCL
I1
I4
I7
I8
I3
I9
I2CSDA
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A
Serial Flash Loader
A.1
Serial Flash Loader
®
The Stellaris serial flash loader is a preprogrammed flash-resident utility used to download code
to the flash memory of a device without the use of a debug interface. The serial flash loader uses
a simple packet interface to provide synchronous communication with the device. The flash loader
runs off the crystal and does not enable the PLL, so its speed is determined by the crystal used.
The two serial interfaces that can be used are the UART0 and SSI0 interfaces. For simplicity, both
the data format and communication protocol are identical for both serial interfaces.
A.2
Interfaces
Once communication with the flash loader is established via one of the serial interfaces, that interface
is used until the flash loader is reset or new code takes over. For example, once you start
communicating using the SSI port, communications with the flash loader via the UART are disabled
until the device is reset.
A.2.1
UART
The Universal Asynchronous Receivers/Transmitters (UART) communication uses a fixed serial
format of 8 bits of data, no parity, and 1 stop bit. The baud rate used for communication is
automatically detected by the flash loader and can be any valid baud rate supported by the host
and the device. The auto detection sequence requires that the baud rate should be no more than
1/32 the crystal frequency of the board that is running the serial flash loader. This is actually the
same as the hardware limitation for the maximum baud rate for any UART on a Stellaris device
which is calculated as follows:
Max Baud Rate = System Clock Frequency / 16
In order to determine the baud rate, the serial flash loader needs to determine the relationship
between its own crystal frequency and the baud rate. This is enough information for the flash loader
to configure its UART to the same baud rate as the host. This automatic baud-rate detection allows
the host to use any valid baud rate that it wants to communicate with the device.
The method used to perform this automatic synchronization relies on the host sending the flash
loader two bytes that are both 0x55. This generates a series of pulses to the flash loader that it can
use to calculate the ratios needed to program the UART to match the host’s baud rate. After the
host sends the pattern, it attempts to read back one byte of data from the UART. The flash loader
returns the value of 0xCC to indicate successful detection of the baud rate. If this byte is not received
after at least twice the time required to transfer the two bytes, the host can resend another pattern
of 0x55, 0x55, and wait for the 0xCC byte again until the flash loader acknowledges that it has
received a synchronization pattern correctly. For example, the time to wait for data back from the
flash loader should be calculated as at least 2*(20(bits/sync)/baud rate (bits/sec)). For a baud rate
of 115200, this time is 2*(20/115200) or 0.35 ms.
A.2.2
SSI
The Synchronous Serial Interface (SSI) port also uses a fixed serial format for communications,
with the framing defined as Motorola format with SPH set to 1 and SPO set to 1. See “Frame
Formats” on page 402 in the SSI chapter for more information on formats for this transfer protocol.
Like the UART, this interface has hardware requirements that limit the maximum speed that the SSI
clock can run. This allows the SSI clock to be at most 1/12 the crystal frequency of the board running
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the flash loader. Since the host device is the master, the SSI on the flash loader device does not
need to determine the clock as it is provided directly by the host.
A.3
Packet Handling
All communications, with the exception of the UART auto-baud, are done via defined packets that
are acknowledged (ACK) or not acknowledged (NAK) by the devices. The packets use the same
format for receiving and sending packets, including the method used to acknowledge successful or
unsuccessful reception of a packet.
A.3.1
Packet Format
All packets sent and received from the device use the following byte-packed format.
struct
{
unsigned char ucSize;
unsigned char ucCheckSum;
unsigned char Data[];
};
A.3.2
ucSize
The first byte received holds the total size of the transfer including
the size and checksum bytes.
ucChecksum
This holds a simple checksum of the bytes in the data buffer only.
The algorithm is Data[0]+Data[1]+…+ Data[ucSize-3].
Data
This is the raw data intended for the device, which is formatted in
some form of command interface. There should be ucSize–2
bytes of data provided in this buffer to or from the device.
Sending Packets
The actual bytes of the packet can be sent individually or all at once; the only limitation is that
commands that cause flash memory access should limit the download sizes to prevent losing bytes
during flash programming. This limitation is discussed further in the section that describes the serial
flash loader command, COMMAND_SEND_DATA (see “COMMAND_SEND_DATA
(0x24)” on page 500).
Once the packet has been formatted correctly by the host, it should be sent out over the UART or
SSI interface. Then the host should poll the UART or SSI interface for the first non-zero data returned
from the device. The first non-zero byte will either be an ACK (0xCC) or a NAK (0x33) byte from
the device indicating the packet was received successfully (ACK) or unsuccessfully (NAK). This
does not indicate that the actual contents of the command issued in the data portion of the packet
were valid, just that the packet was received correctly.
A.3.3
Receiving Packets
The flash loader sends a packet of data in the same format that it receives a packet. The flash loader
may transfer leading zero data before the first actual byte of data is sent out. The first non-zero byte
is the size of the packet followed by a checksum byte, and finally followed by the data itself. There
is no break in the data after the first non-zero byte is sent from the flash loader. Once the device
communicating with the flash loader receives all the bytes, it must either ACK or NAK the packet to
indicate that the transmission was successful. The appropriate response after sending a NAK to
the flash loader is to resend the command that failed and request the data again. If needed, the
host may send leading zeros before sending down the ACK/NAK signal to the flash loader, as the
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flash loader only accepts the first non-zero data as a valid response. This zero padding is needed
by the SSI interface in order to receive data to or from the flash loader.
A.4
Commands
The next section defines the list of commands that can be sent to the flash loader. The first byte of
the data should always be one of the defined commands, followed by data or parameters as
determined by the command that is sent.
A.4.1
COMMAND_PING (0X20)
This command simply accepts the command and sets the global status to success. The format of
the packet is as follows:
Byte[0] = 0x03;
Byte[1] = checksum(Byte[2]);
Byte[2] = COMMAND_PING;
The ping command has 3 bytes and the value for COMMAND_PING is 0x20 and the checksum of one
byte is that same byte, making Byte[1] also 0x20. Since the ping command has no real return status,
the receipt of an ACK can be interpreted as a successful ping to the flash loader.
A.4.2
COMMAND_GET_STATUS (0x23)
This command returns the status of the last command that was issued. Typically, this command
should be sent after every command to ensure that the previous command was successful or to
properly respond to a failure. The command requires one byte in the data of the packet and should
be followed by reading a packet with one byte of data that contains a status code. The last step is
to ACK or NAK the received data so the flash loader knows that the data has been read.
Byte[0] = 0x03
Byte[1] = checksum(Byte[2])
Byte[2] = COMMAND_GET_STATUS
A.4.3
COMMAND_DOWNLOAD (0x21)
This command is sent to the flash loader to indicate where to store data and how many bytes will
be sent by the COMMAND_SEND_DATA commands that follow. The command consists of two 32-bit
values that are both transferred MSB first. The first 32-bit value is the address to start programming
data into, while the second is the 32-bit size of the data that will be sent. This command also triggers
an erase of the full area to be programmed so this command takes longer than other commands.
This results in a longer time to receive the ACK/NAK back from the board. This command should
be followed by a COMMAND_GET_STATUS to ensure that the Program Address and Program size
are valid for the device running the flash loader.
The format of the packet to send this command is a follows:
Byte[0]
Byte[1]
Byte[2]
Byte[3]
Byte[4]
Byte[5]
Byte[6]
Byte[7]
=
=
=
=
=
=
=
=
11
checksum(Bytes[2:10])
COMMAND_DOWNLOAD
Program Address [31:24]
Program Address [23:16]
Program Address [15:8]
Program Address [7:0]
Program Size [31:24]
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Byte[8] = Program Size [23:16]
Byte[9] = Program Size [15:8]
Byte[10] = Program Size [7:0]
A.4.4
COMMAND_SEND_DATA (0x24)
This command should only follow a COMMAND_DOWNLOAD command or another
COMMAND_SEND_DATA command if more data is needed. Consecutive send data commands
automatically increment address and continue programming from the previous location. The caller
should limit transfers of data to a maximum 8 bytes of packet data to allow the flash to program
successfully and not overflow input buffers of the serial interfaces. The command terminates
programming once the number of bytes indicated by the COMMAND_DOWNLOAD command has been
received. Each time this function is called it should be followed by a COMMAND_GET_STATUS to
ensure that the data was successfully programmed into the flash. If the flash loader sends a NAK
to this command, the flash loader does not increment the current address to allow retransmission
of the previous data.
Byte[0] = 11
Byte[1] = checksum(Bytes[2:10])
Byte[2] = COMMAND_SEND_DATA
Byte[3] = Data[0]
Byte[4] = Data[1]
Byte[5] = Data[2]
Byte[6] = Data[3]
Byte[7] = Data[4]
Byte[8] = Data[5]
Byte[9] = Data[6]
Byte[10] = Data[7]
A.4.5
COMMAND_RUN (0x22)
This command is used to tell the flash loader to execute from the address passed as the parameter
in this command. This command consists of a single 32-bit value that is interpreted as the address
to execute. The 32-bit value is transmitted MSB first and the flash loader responds with an ACK
signal back to the host device before actually executing the code at the given address. This allows
the host to know that the command was received successfully and the code is now running.
Byte[0]
Byte[1]
Byte[2]
Byte[3]
Byte[4]
Byte[5]
Byte[6]
A.4.6
=
=
=
=
=
=
=
7
checksum(Bytes[2:6])
COMMAND_RUN
Execute Address[31:24]
Execute Address[23:16]
Execute Address[15:8]
Execute Address[7:0]
COMMAND_RESET (0x25)
This command is used to tell the flash loader device to reset. This is useful when downloading a
new image that overwrote the flash loader and wants to start from a full reset. Unlike the
COMMAND_RUN command, this allows the initial stack pointer to be read by the hardware and set
up for the new code. It can also be used to reset the flash loader if a critical error occurs and the
host device wants to restart communication with the flash loader.
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Byte[0] = 3
Byte[1] = checksum(Byte[2])
Byte[2] = COMMAND_RESET
The flash loader responds with an ACK signal back to the host device before actually executing the
software reset to the device running the flash loader. This allows the host to know that the command
was received successfully and the part will be reset.
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Register Quick Reference
B
Register Quick Reference
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
The Cortex-M3 Processor
R0, type R/W, , reset - (see page 47)
DATA
DATA
R1, type R/W, , reset - (see page 47)
DATA
DATA
R2, type R/W, , reset - (see page 47)
DATA
DATA
R3, type R/W, , reset - (see page 47)
DATA
DATA
R4, type R/W, , reset - (see page 47)
DATA
DATA
R5, type R/W, , reset - (see page 47)
DATA
DATA
R6, type R/W, , reset - (see page 47)
DATA
DATA
R7, type R/W, , reset - (see page 47)
DATA
DATA
R8, type R/W, , reset - (see page 47)
DATA
DATA
R9, type R/W, , reset - (see page 47)
DATA
DATA
R10, type R/W, , reset - (see page 47)
DATA
DATA
R11, type R/W, , reset - (see page 47)
DATA
DATA
R12, type R/W, , reset - (see page 47)
DATA
DATA
SP, type R/W, , reset - (see page 48)
SP
SP
LR, type R/W, , reset 0xFFFF.FFFF (see page 49)
LINK
LINK
PC, type R/W, , reset - (see page 50)
PC
PC
502
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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
PSR, type R/W, , reset 0x0100.0000 (see page 51)
N
Z
C
V
Q
ICI / IT
THUMB
ICI / IT
ISRNUM
PRIMASK, type R/W, , reset 0x0000.0000 (see page 55)
PRIMASK
FAULTMASK, type R/W, , reset 0x0000.0000 (see page 56)
FAULTMASK
BASEPRI, type R/W, , reset 0x0000.0000 (see page 57)
BASEPRI
CONTROL, type R/W, , reset 0x0000.0000 (see page 58)
ASP
TMPL
INTEN
ENABLE
Cortex-M3 Peripherals
System Timer (SysTick) Registers
Base 0xE000.E000
STCTRL, type R/W, offset 0x010, reset 0x0000.0000
COUNT
CLK_SRC
STRELOAD, type R/W, offset 0x014, reset 0x0000.0000
RELOAD
RELOAD
STCURRENT, type R/WC, offset 0x018, reset 0x0000.0000
CURRENT
CURRENT
Cortex-M3 Peripherals
Nested Vectored Interrupt Controller (NVIC) Registers
Base 0xE000.E000
EN0, type R/W, offset 0x100, reset 0x0000.0000
INT
INT
DIS0, type R/W, offset 0x180, reset 0x0000.0000
INT
INT
PEND0, type R/W, offset 0x200, reset 0x0000.0000
INT
INT
UNPEND0, type R/W, offset 0x280, reset 0x0000.0000
INT
INT
ACTIVE0, type RO, offset 0x300, reset 0x0000.0000
INT
INT
PRI0, type R/W, offset 0x400, reset 0x0000.0000
INTD
INTC
INTB
INTA
PRI1, type R/W, offset 0x404, reset 0x0000.0000
INTD
INTC
INTB
INTA
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Register Quick Reference
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
PRI2, type R/W, offset 0x408, reset 0x0000.0000
INTD
INTC
INTB
INTA
PRI3, type R/W, offset 0x40C, reset 0x0000.0000
INTD
INTC
INTB
INTA
PRI4, type R/W, offset 0x410, reset 0x0000.0000
INTD
INTC
INTB
INTA
PRI5, type R/W, offset 0x414, reset 0x0000.0000
INTD
INTC
INTB
INTA
PRI6, type R/W, offset 0x418, reset 0x0000.0000
INTD
INTC
INTB
INTA
PRI7, type R/W, offset 0x41C, reset 0x0000.0000
INTD
INTC
INTB
INTA
SWTRIG, type WO, offset 0xF00, reset 0x0000.0000
INTID
Cortex-M3 Peripherals
System Control Block (SCB) Registers
Base 0xE000.E000
CPUID, type RO, offset 0xD00, reset 0x410F.C231
IMP
VAR
CON
PARTNO
REV
INTCTRL, type R/W, offset 0xD04, reset 0x0000.0000
NMISET
PENDSV UNPENDSV PENDSTSET PENDSTCLR
VECPEND
ISRPRE
ISRPEND
VECPEND
RETBASE
VECACT
VTABLE, type R/W, offset 0xD08, reset 0x0000.0000
BASE
OFFSET
OFFSET
APINT, type R/W, offset 0xD0C, reset 0xFA05.0000
VECTKEY
PRIGROUP
ENDIANESS
SYSRESREQ VECTCLRACT VECTRESET
SYSCTRL, type R/W, offset 0xD10, reset 0x0000.0000
SEVONPEND
SLEEPDEEP SLEEPEXIT
CFGCTRL, type R/W, offset 0xD14, reset 0x0000.0000
DIV0
STKALIGN BFHFNMIGN
UNALIGNED
MAINPEND
BASETHR
SYSPRI1, type R/W, offset 0xD18, reset 0x0000.0000
USAGE
BUS
MEM
SYSPRI2, type R/W, offset 0xD1C, reset 0x0000.0000
SVC
SYSPRI3, type R/W, offset 0xD20, reset 0x0000.0000
TICK
PENDSV
DEBUG
504
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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
MON
SVCA
SYSHNDCTRL, type R/W, offset 0xD24, reset 0x0000.0000
USAGE
SVC
BUSP
MEMP
USAGEP
TICK
PNDSV
USGA
BUS
MEM
BUSA
MEMA
INVSTAT
UNDEF
DERR
IERR
FAULTSTAT, type R/W1C, offset 0xD28, reset 0x0000.0000
BFARV
BSTKE
BUSTKE
IMPRE
DIV0
UNALIGN
PRECISE
IBUS
NOCP
MMARV
MSTKE
INVPC
MUSTKE
HFAULTSTAT, type R/W1C, offset 0xD2C, reset 0x0000.0000
DBG
FORCED
VECT
MMADDR, type R/W, offset 0xD34, reset ADDR
ADDR
FAULTADDR, type R/W, offset 0xD38, reset ADDR
ADDR
Cortex-M3 Peripherals
Memory Protection Unit (MPU) Registers
Base 0xE000.E000
MPUTYPE, type RO, offset 0xD90, reset 0x0000.0800
IREGION
DREGION
SEPARATE
MPUCTRL, type R/W, offset 0xD94, reset 0x0000.0000
PRIVDEFEN HFNMIENA
ENABLE
MPUNUMBER, type R/W, offset 0xD98, reset 0x0000.0000
NUMBER
MPUBASE, type R/W, offset 0xD9C, reset 0x0000.0000
ADDR
ADDR
VALID
REGION
VALID
REGION
VALID
REGION
VALID
REGION
MPUBASE1, type R/W, offset 0xDA4, reset 0x0000.0000
ADDR
ADDR
MPUBASE2, type R/W, offset 0xDAC, reset 0x0000.0000
ADDR
ADDR
MPUBASE3, type R/W, offset 0xDB4, reset 0x0000.0000
ADDR
ADDR
MPUATTR, type R/W, offset 0xDA0, reset 0x0000.0000
XN
AP
TEX
SRD
S
C
SIZE
B
ENABLE
MPUATTR1, type R/W, offset 0xDA8, reset 0x0000.0000
XN
AP
TEX
SRD
S
C
SIZE
B
ENABLE
MPUATTR2, type R/W, offset 0xDB0, reset 0x0000.0000
XN
AP
TEX
SRD
S
C
SIZE
B
ENABLE
MPUATTR3, type R/W, offset 0xDB8, reset 0x0000.0000
XN
AP
SRD
TEX
S
SIZE
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B
ENABLE
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Texas Instruments-Production Data
Register Quick Reference
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
BORIOR
BORWT
System Control
Base 0x400F.E000
DID0, type RO, offset 0x000, reset - (see page 162)
VER
MAJOR
MINOR
PBORCTL, type R/W, offset 0x030, reset 0x0000.7FFD (see page 164)
BORTIM
LDOPCTL, type R/W, offset 0x034, reset 0x0000.0000 (see page 165)
VADJ
RIS, type RO, offset 0x050, reset 0x0000.0000 (see page 166)
PLLLRIS
CLRIS
IOFRIS
MOFRIS
LDORIS
BORRIS
PLLFRIS
PLLLIM
CLIM
IOFIM
MOFIM
LDOIM
BORIM
PLLFIM
PLLLMIS
CLMIS
IOFMIS
MOFMIS
LDOMIS
BORMIS
LDO
SW
WDT
BOR
POR
IMC, type R/W, offset 0x054, reset 0x0000.0000 (see page 167)
MISC, type R/W1C, offset 0x058, reset 0x0000.0000 (see page 168)
RESC, type R/W, offset 0x05C, reset - (see page 169)
EXT
RCC, type R/W, offset 0x060, reset 0x0780.3AC0 (see page 170)
ACG
PWRDN
OEN
BYPASS
SYSDIV
USESYSDIV
PLLVER
XTAL
OSCSRC
IOSCVER MOSCVER IOSCDIS MOSCDIS
PLLCFG, type RO, offset 0x064, reset - (see page 173)
OD
F
R
DSLPCLKCFG, type R/W, offset 0x144, reset 0x0780.0000 (see page 174)
IOSC
CLKVCLR, type R/W, offset 0x150, reset 0x0000.0000 (see page 175)
VERCLR
LDOARST, type R/W, offset 0x160, reset 0x0000.0000 (see page 176)
LDOARST
DID1, type RO, offset 0x004, reset - (see page 177)
VER
FAM
PARTNO
TEMP
PKG
ROHS
QUAL
DC0, type RO, offset 0x008, reset 0x001F.001F (see page 179)
SRAMSZ
FLASHSZ
DC1, type RO, offset 0x010, reset 0x0001.33BF (see page 180)
ADC
MINSYSDIV
MAXADCSPD
MPU
TEMPSNS
PLL
WDT
SWO
SWD
JTAG
TIMER2
TIMER1
TIMER0
UART1
UART0
ADC1
ADC0
DC2, type RO, offset 0x014, reset 0x0007.1013 (see page 182)
I2C0
SSI0
DC3, type RO, offset 0x018, reset 0xBFFF.0000 (see page 184)
32KHZ
CCP5
CCP4
CCP3
CCP2
CCP1
CCP0
ADC7
ADC6
ADC5
506
ADC4
ADC3
ADC2
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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
GPIOE
GPIOD
GPIOC
GPIOB
GPIOA
DC4, type RO, offset 0x01C, reset 0x0000.001F (see page 186)
RCGC0, type R/W, offset 0x100, reset 0x00000040 (see page 187)
ADC
MAXADCSPD
WDT
MAXADCSPD
WDT
SCGC0, type R/W, offset 0x110, reset 0x00000040 (see page 189)
ADC
DCGC0, type R/W, offset 0x120, reset 0x00000040 (see page 191)
ADC
WDT
RCGC1, type R/W, offset 0x104, reset 0x00000000 (see page 192)
TIMER2
I2C0
SSI0
TIMER1
TIMER0
UART1
UART0
TIMER1
TIMER0
UART1
UART0
TIMER1
TIMER0
UART1
UART0
SCGC1, type R/W, offset 0x114, reset 0x00000000 (see page 194)
TIMER2
I2C0
SSI0
DCGC1, type R/W, offset 0x124, reset 0x00000000 (see page 196)
TIMER2
I2C0
SSI0
RCGC2, type R/W, offset 0x108, reset 0x00000000 (see page 198)
GPIOE
GPIOD
GPIOC
GPIOB
GPIOA
GPIOE
GPIOD
GPIOC
GPIOB
GPIOA
GPIOE
GPIOD
GPIOC
GPIOB
GPIOA
SCGC2, type R/W, offset 0x118, reset 0x00000000 (see page 199)
DCGC2, type R/W, offset 0x128, reset 0x00000000 (see page 201)
SRCR0, type R/W, offset 0x040, reset 0x00000000 (see page 203)
ADC
WDT
SRCR1, type R/W, offset 0x044, reset 0x00000000 (see page 204)
TIMER2
I2C0
SSI0
TIMER1
TIMER0
UART1
UART0
SRCR2, type R/W, offset 0x048, reset 0x00000000 (see page 205)
GPIOE
GPIOD
GPIOC
GPIOB
GPIOA
COMT
MERASE
ERASE
WRITE
Internal Memory
Flash Memory Control Registers (Flash Control Offset)
Base 0x400F.D000
FMA, type R/W, offset 0x000, reset 0x0000.0000
OFFSET
FMD, type R/W, offset 0x004, reset 0x0000.0000
DATA
DATA
FMC, type R/W, offset 0x008, reset 0x0000.0000
WRKEY
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Register Quick Reference
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
PRIS
ARIS
PMASK
AMASK
PMISC
AMISC
FCRIS, type RO, offset 0x00C, reset 0x0000.0000
FCIM, type R/W, offset 0x010, reset 0x0000.0000
FCMISC, type R/W1C, offset 0x014, reset 0x0000.0000
Internal Memory
Flash Memory Protection Registers (System Control Offset)
Base 0x400F.E000
USECRL, type R/W, offset 0x140, reset 0x31
USEC
FMPRE, type R/W, offset 0x130, reset 0xBFFF.FFFF
DBG
READ_ENABLE
READ_ENABLE
FMPPE, type R/W, offset 0x134, reset 0xFFFF.FFFF
PROG_ENABLE
PROG_ENABLE
General-Purpose Input/Outputs (GPIOs)
GPIO Port A base: 0x4000.4000
GPIO Port B base: 0x4000.5000
GPIO Port C base: 0x4000.6000
GPIO Port D base: 0x4000.7000
GPIO Port E base: 0x4002.4000
GPIODATA, type R/W, offset 0x000, reset 0x0000.0000 (see page 233)
DATA
GPIODIR, type R/W, offset 0x400, reset 0x0000.0000 (see page 234)
DIR
GPIOIS, type R/W, offset 0x404, reset 0x0000.0000 (see page 235)
IS
GPIOIBE, type R/W, offset 0x408, reset 0x0000.0000 (see page 236)
IBE
GPIOIEV, type R/W, offset 0x40C, reset 0x0000.0000 (see page 237)
IEV
GPIOIM, type R/W, offset 0x410, reset 0x0000.0000 (see page 238)
IME
GPIORIS, type RO, offset 0x414, reset 0x0000.0000 (see page 239)
RIS
GPIOMIS, type RO, offset 0x418, reset 0x0000.0000 (see page 240)
MIS
GPIOICR, type W1C, offset 0x41C, reset 0x0000.0000 (see page 241)
IC
508
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16
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13
12
11
10
9
8
7
6
5
4
3
2
1
0
GPIOAFSEL, type R/W, offset 0x420, reset - (see page 242)
AFSEL
GPIODR2R, type R/W, offset 0x500, reset 0x0000.00FF (see page 244)
DRV2
GPIODR4R, type R/W, offset 0x504, reset 0x0000.0000 (see page 245)
DRV4
GPIODR8R, type R/W, offset 0x508, reset 0x0000.0000 (see page 246)
DRV8
GPIOODR, type R/W, offset 0x50C, reset 0x0000.0000 (see page 247)
ODE
GPIOPUR, type R/W, offset 0x510, reset 0x0000.00FF (see page 248)
PUE
GPIOPDR, type R/W, offset 0x514, reset 0x0000.0000 (see page 249)
PDE
GPIOSLR, type R/W, offset 0x518, reset 0x0000.0000 (see page 250)
SRL
GPIODEN, type R/W, offset 0x51C, reset 0x0000.00FF (see page 251)
DEN
GPIOPeriphID4, type RO, offset 0xFD0, reset 0x0000.0000 (see page 252)
PID4
GPIOPeriphID5, type RO, offset 0xFD4, reset 0x0000.0000 (see page 253)
PID5
GPIOPeriphID6, type RO, offset 0xFD8, reset 0x0000.0000 (see page 254)
PID6
GPIOPeriphID7, type RO, offset 0xFDC, reset 0x0000.0000 (see page 255)
PID7
GPIOPeriphID0, type RO, offset 0xFE0, reset 0x0000.0061 (see page 256)
PID0
GPIOPeriphID1, type RO, offset 0xFE4, reset 0x0000.0000 (see page 257)
PID1
GPIOPeriphID2, type RO, offset 0xFE8, reset 0x0000.0018 (see page 258)
PID2
GPIOPeriphID3, type RO, offset 0xFEC, reset 0x0000.0001 (see page 259)
PID3
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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
GPIOPCellID0, type RO, offset 0xFF0, reset 0x0000.000D (see page 260)
CID0
GPIOPCellID1, type RO, offset 0xFF4, reset 0x0000.00F0 (see page 261)
CID1
GPIOPCellID2, type RO, offset 0xFF8, reset 0x0000.0005 (see page 262)
CID2
GPIOPCellID3, type RO, offset 0xFFC, reset 0x0000.00B1 (see page 263)
CID3
General-Purpose Timers
Timer0 base: 0x4003.0000
Timer1 base: 0x4003.1000
Timer2 base: 0x4003.2000
GPTMCFG, type R/W, offset 0x000, reset 0x0000.0000 (see page 276)
GPTMCFG
GPTMTAMR, type R/W, offset 0x004, reset 0x0000.0000 (see page 277)
TAAMS
TACMR
TAMR
TBAMS
TBCMR
TBMR
GPTMTBMR, type R/W, offset 0x008, reset 0x0000.0000 (see page 279)
GPTMCTL, type R/W, offset 0x00C, reset 0x0000.0000 (see page 281)
TBPWML
TBOTE
TBEVENT
TBSTALL
TBEN
TAPWML
TAOTE
RTCEN
TAEVENT
TASTALL
TAEN
GPTMIMR, type R/W, offset 0x018, reset 0x0000.0000 (see page 284)
CBEIM
CBMIM
TBTOIM
RTCIM
CAEIM
CAMIM
TATOIM
CBMRIS TBTORIS
RTCRIS
CAERIS
CAMRIS
TATORIS
RTCMIS
CAEMIS
CAMMIS TATOMIS
GPTMRIS, type RO, offset 0x01C, reset 0x0000.0000 (see page 286)
CBERIS
GPTMMIS, type RO, offset 0x020, reset 0x0000.0000 (see page 287)
CBEMIS
CBMMIS TBTOMIS
GPTMICR, type W1C, offset 0x024, reset 0x0000.0000 (see page 288)
CBECINT CBMCINT TBTOCINT
RTCCINT CAECINT CAMCINT TATOCINT
GPTMTAILR, type R/W, offset 0x028, reset 0xFFFF.FFFF (see page 290)
TAILRH
TAILRL
GPTMTBILR, type R/W, offset 0x02C, reset 0x0000.FFFF (see page 291)
TBILRL
GPTMTAMATCHR, type R/W, offset 0x030, reset 0xFFFF.FFFF (see page 292)
TAMRH
TAMRL
GPTMTBMATCHR, type R/W, offset 0x034, reset 0x0000.FFFF (see page 293)
TBMRL
510
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18
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16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
RESEN
INTEN
GPTMTAPR, type R/W, offset 0x038, reset 0x0000.0000 (see page 294)
TAPSR
GPTMTBPR, type R/W, offset 0x03C, reset 0x0000.0000 (see page 295)
TBPSR
GPTMTAPMR, type R/W, offset 0x040, reset 0x0000.0000 (see page 296)
TAPSMR
GPTMTBPMR, type R/W, offset 0x044, reset 0x0000.0000 (see page 297)
TBPSMR
GPTMTAR, type RO, offset 0x048, reset 0xFFFF.FFFF (see page 298)
TARH
TARL
GPTMTBR, type RO, offset 0x04C, reset 0x0000.FFFF (see page 299)
TBRL
Watchdog Timer
Base 0x4000.0000
WDTLOAD, type R/W, offset 0x000, reset 0xFFFF.FFFF (see page 304)
WDTLoad
WDTLoad
WDTVALUE, type RO, offset 0x004, reset 0xFFFF.FFFF (see page 305)
WDTValue
WDTValue
WDTCTL, type R/W, offset 0x008, reset 0x0000.0000 (see page 306)
WDTICR, type WO, offset 0x00C, reset - (see page 307)
WDTIntClr
WDTIntClr
WDTRIS, type RO, offset 0x010, reset 0x0000.0000 (see page 308)
WDTRIS
WDTMIS, type RO, offset 0x014, reset 0x0000.0000 (see page 309)
WDTMIS
WDTTEST, type R/W, offset 0x418, reset 0x0000.0000 (see page 310)
STALL
WDTLOCK, type R/W, offset 0xC00, reset 0x0000.0000 (see page 311)
WDTLock
WDTLock
WDTPeriphID4, type RO, offset 0xFD0, reset 0x0000.0000 (see page 312)
PID4
WDTPeriphID5, type RO, offset 0xFD4, reset 0x0000.0000 (see page 313)
PID5
WDTPeriphID6, type RO, offset 0xFD8, reset 0x0000.0000 (see page 314)
PID6
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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
ASEN3
ASEN2
ASEN1
ASEN0
INR3
INR2
INR1
INR0
MASK3
MASK2
MASK1
MASK0
IN3
IN2
IN1
IN0
OV3
OV2
OV1
OV0
UV1
UV0
WDTPeriphID7, type RO, offset 0xFDC, reset 0x0000.0000 (see page 315)
PID7
WDTPeriphID0, type RO, offset 0xFE0, reset 0x0000.0005 (see page 316)
PID0
WDTPeriphID1, type RO, offset 0xFE4, reset 0x0000.0018 (see page 317)
PID1
WDTPeriphID2, type RO, offset 0xFE8, reset 0x0000.0018 (see page 318)
PID2
WDTPeriphID3, type RO, offset 0xFEC, reset 0x0000.0001 (see page 319)
PID3
WDTPCellID0, type RO, offset 0xFF0, reset 0x0000.000D (see page 320)
CID0
WDTPCellID1, type RO, offset 0xFF4, reset 0x0000.00F0 (see page 321)
CID1
WDTPCellID2, type RO, offset 0xFF8, reset 0x0000.0005 (see page 322)
CID2
WDTPCellID3, type RO, offset 0xFFC, reset 0x0000.00B1 (see page 323)
CID3
Analog-to-Digital Converter (ADC)
Base 0x4003.8000
ADCACTSS, type R/W, offset 0x000, reset 0x0000.0000 (see page 334)
ADCRIS, type RO, offset 0x004, reset 0x0000.0000 (see page 335)
ADCIM, type R/W, offset 0x008, reset 0x0000.0000 (see page 336)
ADCISC, type R/W1C, offset 0x00C, reset 0x0000.0000 (see page 337)
ADCOSTAT, type R/W1C, offset 0x010, reset 0x0000.0000 (see page 338)
ADCEMUX, type R/W, offset 0x014, reset 0x0000.0000 (see page 339)
EM3
EM2
EM1
EM0
ADCUSTAT, type R/W1C, offset 0x018, reset 0x0000.0000 (see page 342)
UV3
UV2
ADCSSPRI, type R/W, offset 0x020, reset 0x0000.3210 (see page 343)
SS3
SS2
512
SS1
SS0
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15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
SS3
SS2
SS1
SS0
ADCPSSI, type WO, offset 0x028, reset - (see page 345)
ADCSAC, type R/W, offset 0x030, reset 0x0000.0000 (see page 346)
AVG
ADCSSMUX0, type R/W, offset 0x040, reset 0x0000.0000 (see page 347)
MUX7
MUX6
MUX5
MUX4
MUX3
MUX2
MUX1
MUX0
ADCSSCTL0, type R/W, offset 0x044, reset 0x0000.0000 (see page 349)
TS7
IE7
END7
D7
TS6
IE6
END6
D6
TS5
IE5
END5
D5
TS4
IE4
END4
D4
TS3
IE3
END3
D3
TS2
IE2
END2
D2
TS1
IE1
END1
D1
TS0
IE0
END0
D0
ADCSSFIFO0, type RO, offset 0x048, reset - (see page 352)
DATA
ADCSSFIFO1, type RO, offset 0x068, reset - (see page 352)
DATA
ADCSSFIFO2, type RO, offset 0x088, reset - (see page 352)
DATA
ADCSSFIFO3, type RO, offset 0x0A8, reset - (see page 352)
DATA
ADCSSFSTAT0, type RO, offset 0x04C, reset 0x0000.0100 (see page 353)
FULL
EMPTY
HPTR
TPTR
EMPTY
HPTR
TPTR
EMPTY
HPTR
TPTR
EMPTY
HPTR
TPTR
ADCSSFSTAT1, type RO, offset 0x06C, reset 0x0000.0100 (see page 353)
FULL
ADCSSFSTAT2, type RO, offset 0x08C, reset 0x0000.0100 (see page 353)
FULL
ADCSSFSTAT3, type RO, offset 0x0AC, reset 0x0000.0100 (see page 353)
FULL
ADCSSMUX1, type R/W, offset 0x060, reset 0x0000.0000 (see page 354)
MUX3
MUX2
MUX1
MUX0
MUX1
MUX0
ADCSSMUX2, type R/W, offset 0x080, reset 0x0000.0000 (see page 354)
MUX3
MUX2
ADCSSCTL1, type R/W, offset 0x064, reset 0x0000.0000 (see page 355)
TS3
IE3
END3
D3
TS2
IE2
END2
D2
TS1
IE1
END1
D1
TS0
IE0
END0
D0
D2
TS1
IE1
END1
D1
TS0
IE0
END0
D0
ADCSSCTL2, type R/W, offset 0x084, reset 0x0000.0000 (see page 355)
TS3
IE3
END3
D3
TS2
IE2
END2
ADCSSMUX3, type R/W, offset 0x0A0, reset 0x0000.0000 (see page 357)
MUX0
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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
TS0
IE0
END0
D0
ADCSSCTL3, type R/W, offset 0x0A4, reset 0x0000.0002 (see page 358)
ADCTMLB, type R/W, offset 0x100, reset 0x0000.0000 (see page 359)
LB
Universal Asynchronous Receivers/Transmitters (UARTs)
UART0 base: 0x4000.C000
UART1 base: 0x4000.D000
UARTDR, type R/W, offset 0x000, reset 0x0000.0000 (see page 368)
OE
BE
PE
FE
DATA
UARTRSR/UARTECR, type RO, offset 0x004, reset 0x0000.0000 (Reads) (see page 370)
OE
BE
PE
FE
PEN
BRK
UARTRSR/UARTECR, type WO, offset 0x004, reset 0x0000.0000 (Writes) (see page 370)
DATA
UARTFR, type RO, offset 0x018, reset 0x0000.0090 (see page 372)
TXFE
RXFF
TXFF
RXFE
BUSY
UARTIBRD, type R/W, offset 0x024, reset 0x0000.0000 (see page 374)
DIVINT
UARTFBRD, type R/W, offset 0x028, reset 0x0000.0000 (see page 375)
DIVFRAC
UARTLCRH, type R/W, offset 0x02C, reset 0x0000.0000 (see page 376)
SPS
WLEN
FEN
STP2
EPS
UARTCTL, type R/W, offset 0x030, reset 0x0000.0300 (see page 378)
RXE
TXE
LBE
UARTEN
UARTIFLS, type R/W, offset 0x034, reset 0x0000.0012 (see page 380)
RXIFLSEL
TXIFLSEL
UARTIM, type R/W, offset 0x038, reset 0x0000.0000 (see page 382)
OEIM
BEIM
PEIM
FEIM
RTIM
TXIM
RXIM
PERIS
FERIS
RTRIS
TXRIS
RXRIS
PEMIS
FEMIS
RTMIS
TXMIS
RXMIS
PEIC
FEIC
RTIC
TXIC
RXIC
UARTRIS, type RO, offset 0x03C, reset 0x0000.000F (see page 384)
OERIS
BERIS
UARTMIS, type RO, offset 0x040, reset 0x0000.0000 (see page 385)
OEMIS
BEMIS
UARTICR, type W1C, offset 0x044, reset 0x0000.0000 (see page 386)
OEIC
BEIC
UARTPeriphID4, type RO, offset 0xFD0, reset 0x0000.0000 (see page 388)
PID4
514
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13
12
11
10
9
8
7
6
5
4
3
2
1
0
UARTPeriphID5, type RO, offset 0xFD4, reset 0x0000.0000 (see page 389)
PID5
UARTPeriphID6, type RO, offset 0xFD8, reset 0x0000.0000 (see page 390)
PID6
UARTPeriphID7, type RO, offset 0xFDC, reset 0x0000.0000 (see page 391)
PID7
UARTPeriphID0, type RO, offset 0xFE0, reset 0x0000.0011 (see page 392)
PID0
UARTPeriphID1, type RO, offset 0xFE4, reset 0x0000.0000 (see page 393)
PID1
UARTPeriphID2, type RO, offset 0xFE8, reset 0x0000.0018 (see page 394)
PID2
UARTPeriphID3, type RO, offset 0xFEC, reset 0x0000.0001 (see page 395)
PID3
UARTPCellID0, type RO, offset 0xFF0, reset 0x0000.000D (see page 396)
CID0
UARTPCellID1, type RO, offset 0xFF4, reset 0x0000.00F0 (see page 397)
CID1
UARTPCellID2, type RO, offset 0xFF8, reset 0x0000.0005 (see page 398)
CID2
UARTPCellID3, type RO, offset 0xFFC, reset 0x0000.00B1 (see page 399)
CID3
Synchronous Serial Interface (SSI)
SSI0 base: 0x4000.8000
SSICR0, type R/W, offset 0x000, reset 0x0000.0000 (see page 413)
SCR
SPH
SPO
FRF
DSS
SSICR1, type R/W, offset 0x004, reset 0x0000.0000 (see page 415)
SOD
MS
SSE
LBM
RFF
RNE
TNF
TFE
RXIM
RTIM
RORIM
SSIDR, type R/W, offset 0x008, reset 0x0000.0000 (see page 417)
DATA
SSISR, type RO, offset 0x00C, reset 0x0000.0003 (see page 418)
BSY
SSICPSR, type R/W, offset 0x010, reset 0x0000.0000 (see page 420)
CPSDVSR
SSIIM, type R/W, offset 0x014, reset 0x0000.0000 (see page 421)
TXIM
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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
TXRIS
RXRIS
RTRIS
RORRIS
TXMIS
RXMIS
RTMIS
RORMIS
RTIC
RORIC
SSIRIS, type RO, offset 0x018, reset 0x0000.0008 (see page 423)
SSIMIS, type RO, offset 0x01C, reset 0x0000.0000 (see page 424)
SSIICR, type W1C, offset 0x020, reset 0x0000.0000 (see page 425)
SSIPeriphID4, type RO, offset 0xFD0, reset 0x0000.0000 (see page 426)
PID4
SSIPeriphID5, type RO, offset 0xFD4, reset 0x0000.0000 (see page 427)
PID5
SSIPeriphID6, type RO, offset 0xFD8, reset 0x0000.0000 (see page 428)
PID6
SSIPeriphID7, type RO, offset 0xFDC, reset 0x0000.0000 (see page 429)
PID7
SSIPeriphID0, type RO, offset 0xFE0, reset 0x0000.0022 (see page 430)
PID0
SSIPeriphID1, type RO, offset 0xFE4, reset 0x0000.0000 (see page 431)
PID1
SSIPeriphID2, type RO, offset 0xFE8, reset 0x0000.0018 (see page 432)
PID2
SSIPeriphID3, type RO, offset 0xFEC, reset 0x0000.0001 (see page 433)
PID3
SSIPCellID0, type RO, offset 0xFF0, reset 0x0000.000D (see page 434)
CID0
SSIPCellID1, type RO, offset 0xFF4, reset 0x0000.00F0 (see page 435)
CID1
SSIPCellID2, type RO, offset 0xFF8, reset 0x0000.0005 (see page 436)
CID2
SSIPCellID3, type RO, offset 0xFFC, reset 0x0000.00B1 (see page 437)
CID3
Inter-Integrated Circuit
(I2C)
Interface
I2C Master
I2C 0 base: 0x4002.0000
I2CMSA, type R/W, offset 0x000, reset 0x0000.0000
SA
516
R/S
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13
12
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9
8
7
6
5
4
3
2
1
0
BUSBSY
IDLE
ARBLST
DATACK
ADRACK
ERROR
BUSY
ACK
STOP
START
RUN
I2CMCS, type RO, offset 0x004, reset 0x0000.0000 (Reads)
I2CMCS, type WO, offset 0x004, reset 0x0000.0000 (Writes)
I2CMDR, type R/W, offset 0x008, reset 0x0000.0000
DATA
I2CMTPR, type R/W, offset 0x00C, reset 0x0000.0001
TPR
I2CMIMR, type R/W, offset 0x010, reset 0x0000.0000
IM
I2CMRIS, type RO, offset 0x014, reset 0x0000.0000
RIS
I2CMMIS, type RO, offset 0x018, reset 0x0000.0000
MIS
I2CMICR, type WO, offset 0x01C, reset 0x0000.0000
IC
I2CMCR, type R/W, offset 0x020, reset 0x0000.0000
SFE
MFE
LPBK
Inter-Integrated Circuit (I2C) Interface
I2C Slave
I2C 0 base: 0x4002.0000
I2CSOAR, type R/W, offset 0x800, reset 0x0000.0000
OAR
I2CSCSR, type RO, offset 0x804, reset 0x0000.0000 (Reads)
FBR
TREQ
RREQ
I2CSCSR, type WO, offset 0x804, reset 0x0000.0000 (Writes)
DA
I2CSDR, type R/W, offset 0x808, reset 0x0000.0000
DATA
I2CSIMR, type R/W, offset 0x80C, reset 0x0000.0000
DATAIM
I2CSRIS, type RO, offset 0x810, reset 0x0000.0000
DATARIS
I2CSMIS, type RO, offset 0x814, reset 0x0000.0000
DATAMIS
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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
I2CSICR, type WO, offset 0x818, reset 0x0000.0000
DATAIC
518
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C
Ordering and Contact Information
C.1
Ordering Information
LM3Snnnn–gppss–rrm
Part Number
nnn = Sandstorm-class parts
nnnn = All other Stellaris® parts
Shipping Medium
T = Tape-and-reel
Omitted = Default shipping (tray or tube)
Temperature
E = –40°C to +105°C
I = –40°C to +85°C
Revision
Speed
20 = 20 MHz
25 = 25 MHz
50 = 50 MHz
80 = 80 MHz
Package
BZ = 108-ball BGA
QC = 100-pin LQFP
QN = 48-pin LQFP
QR = 64-pin LQFP
Table C-1. Part Ordering Information
C.2
Orderable Part Number
Description
LM3S828-IQN50-C2
Stellaris LM3S828 Microcontroller Industrial Temperature 48-pin LQFP
LM3S828-IQN50-C2T
Stellaris LM3S828 Microcontroller Industrial Temperature 48-pin LQFP
Tape-and-reel
®
Part Markings
The Stellaris microcontrollers are marked with an identifying number. This code contains the following
information:
■ The first line indicates the part number, for example, LM3S9B90.
■ In the second line, the first eight characters indicate the temperature, package, speed, revision,
and product status. For example in the figure below, IQC80C0X indicates an Industrial temperature
(I), 100-pin LQFP package (QC), 80-MHz (80), revision C0 (C0) device. The letter immediately
following the revision indicates product status. An X indicates experimental and requires a waiver;
an S indicates the part is fully qualified and released to production.
■ The remaining characters contain internal tracking numbers.
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C.3
Kits
The Stellaris Family provides the hardware and software tools that engineers need to begin
development quickly.
■ Reference Design Kits accelerate product development by providing ready-to-run hardware and
comprehensive documentation including hardware design files
■ Evaluation Kits provide a low-cost and effective means of evaluating Stellaris microcontrollers
before purchase
■ Development Kits provide you with all the tools you need to develop and prototype embedded
applications right out of the box
See the website at www.ti.com/stellaris for the latest tools available, or ask your distributor.
C.4
Support Information
For support on Stellaris products, contact the TI Worldwide Product Information Center nearest you:
http://www-k.ext.ti.com/sc/technical-support/product-information-centers.htm.
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Texas Instruments-Production Data
®
Stellaris LM3S828 Microcontroller
D
Package Information
D.1
48-Pin LQFP Package
D.1.1
Package Dimensions
Figure D-1. Stellaris LM3S828 48-Pin LQFP Package
Note:
The following notes apply to the package drawing.
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Texas Instruments-Production Data
Package Information
1. All dimensions are in mm.
2. Dimensions shown are nominal with tolerances indicated.
3. Foot length "L" is measured at gage plane 0.25 mm above seating plane.
4. L/F: Eftec 64T Cu or equivalent, 0.127 mm (0.005") thick.
Package Type
Symbol
48LD LQFP
Note
MIN
MAX
A
-
1.60
A1
0.05
0.15
A2
-
1.40
D
9.00
D1
7.00
E
9.00
E1
7.00
L
0.60
e
0.50
b
0.22
theta
0° - 7°
ddd
0.08
ccc
0.08
JEDEC Reference Drawing
MS-026
Variation Designator
BBC
522
June 18, 2012
Texas Instruments-Production Data
®
Stellaris LM3S828 Microcontroller
D.1.2
Tray Dimensions
Figure D-2. 48-Pin LQFP Tray Dimensions
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Package Information
524
June 18, 2012
Texas Instruments-Production Data
®
Stellaris LM3S828 Microcontroller
D.1.3
Tape and Reel Dimensions
Figure D-3. 48-Pin LQFP Tape and Reel Dimensions
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Texas Instruments-Production Data
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