TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 1 Features • • • • • • • High-Performance Fixed-Point DSP (C6455) – 1.39-, 1.17, 1-, and 0.83-ns Instruction Cycle Time – 720-MHz, 850-MHz, 1-GHz, and 1.2-GHz Clock Rate – Eight 32-Bit Instructions/Cycle – 9600 MIPS/MMACS (16-Bits) – Commercial Temperature [0°C to 90°C] – Extended Temperature [-40°C to 105°C] TMS320C64x+™ DSP Core – Dedicated SPLOOP Instruction – Compact Instructions (16-Bit) – Instruction Set Enhancements – Exception Handling TMS320C64x+ Megamodule L1/L2 Memory Architecture: – 256K-Bit (32K-Byte) L1P Program Cache [Direct Mapped] – 256K-Bit (32K-Byte) L1D Data Cache [2-Way Set-Associative] – 16M-Bit (2096K-Byte) L2 Unified Mapped RAM/Cache [Flexible Allocation] – 256K-Bit (32K-Byte) L2 ROM – Time Stamp Counter Enhanced VCP2 – Supports Over 694 7.95-Kbps AMR – Programmable Code Parameters Enhanced Turbo Decoder Coprocessor (TCP2) – Supports up to Eight 2-Mbps 3GPP (6 Iterations) – Programmable Turbo Code and Decoding Parameters Endianess: Little Endian, Big Endian 64-Bit External Memory Interface (EMIFA) – Glueless Interface to Asynchronous Memories (SRAM, Flash, and EEPROM) and Synchronous Memories (SBSRAM, ZBT SRAM) – Supports Interface to Standard Sync Devices and Custom Logic (FPGA, CPLD, ASICs, etc.) – 32M-Byte Total Addressable External Memory Space • • • • • • • • • • • • • • • • • • • Four 1x Serial RapidIO® Links (or One 4x), v1.2 Compliant – 1.25-, 2.5-, 3.125-Gbps Link Rates – Message Passing, DirectIO Support, Error Management Extensions, and Congestion Control – IEEE 1149.6 Compliant I/Os DDR2 Memory Controller – Interfaces to DDR2-533 SDRAM – 32-Bit/16-Bit, 533-MHz (data rate) Bus – 512M-Byte Total Addressable External Memory Space EDMA3 Controller (64 Independent Channels) 32-/16-Bit Host-Port Interface (HPI) 32-Bit 33-/66-MHz, 3.3-V Peripheral Component Interconnect (PCI) Master/Slave Interface Conforms to PCI Local Bus Specification (version 2.3) One Inter-Integrated Circuit (I2C) Bus Two McBSPs 10/100/1000 Mb/s Ethernet MAC (EMAC) – IEEE 802.3 Compliant – Supports Multiple Media Independent Interfaces (MII, GMII, RMII, and RGMII) – 8 Independent Transmit (TX) and 8 Independent Receive (RX) Channels Two 64-Bit General-Purpose Timers, Configurable as Four 32-Bit Timers UTOPIA – UTOPIA Level 2 Slave ATM Controller – 8-Bit Transmit and Receive Operations up to 50 MHz per Direction – User-Defined Cell Format up to 64 Bytes 16 General-Purpose I/O (GPIO) Pins System PLL and PLL Controller Secondary PLL and PLL Controller, Dedicated to EMAC and DDR2 Memory Controller Advanced Event Triggering (AET) Compatible Trace-Enabled Device IEEE-1149.1 (JTAG™) Boundary-Scan-Compatible 697-Pin Ball Grid Array (BGA) Package (ZTZ or GTZ Suffix), 0.8-mm Ball Pitch 0.09-μm/7-Level Cu Metal Process (CMOS) 3.3-/1.8-/1.5-/1.25-/1.2-V I/Os, 1.25-/1.2-V Internal All trademarks are the property of their respective owners. PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of the Texas Instruments standard warranty. Production processing does not necessarily include testing of all parameters. Copyright © 2005–2007, Texas Instruments Incorporated TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 1.1 ZTZ/GTZ BGA Package (Bottom View) Figure 1-1 shows the TMS320C6455 device 697-pin ball grid array package (bottom view). ZTZ/GTZ 697-PIN BALL GRID ARRAY (BGA) PACKAGE ( BOTTOM VIEW ) AJ AH AF AD AB Y AG AE AC AA W V U T R P M N L K J H G F E D C B A 1 3 2 5 4 7 6 9 8 11 13 15 17 19 21 23 25 27 29 10 12 14 16 18 20 22 24 26 28 NOTE: The ZTZ mechanical package designator represents the version of the GTZ package with lead-free balls. For more detailed information, see the Mechanical Data section of this document. Figure 1-1. ZTZ/GTZ BGA Package (Bottom View) 1.2 Description The TMS320C64x+™ DSPs (including the TMS320C6455 device) are the highest-performance fixed-point DSP generation in the TMS320C6000™ DSP platform. The C6455 device is based on the third-generation high-performance, advanced VelociTI™ very-long-instruction-word (VLIW) architecture developed by Texas Instruments (TI), making these DSPs an excellent choice for applications including video and telecom infrastructure, imaging/medical, and wireless infrastructure (WI). The C64x+™ devices are upward code-compatible from previous devices that are part of the C6000™ DSP platform. Based on 90-nm process technology and with performance of up to 9600 million instructions per second (MIPS) [or 9600 16-bit MMACs per cycle] at a 1.2-GHz clock rate, the C6455 device offers cost-effective solutions to high-performance DSP programming challenges. The C6455 DSP possesses the operational flexibility of high-speed controllers and the numerical capability of array processors. The C64x+ DSP core employs eight functional units, two register files, and two data paths. Like the earlier C6000 devices, two of these eight functional units are multipliers or .M units. Each C64x+ .M unit doubles the multiply throughput versus the C64x core by performing four 16-bit x 16-bit multiply-accumulates (MACs) every clock cycle. Thus, eight 16-bit x 16-bit MACs can be executed every cycle on the C64x+ core. At a 1.2-GHz clock rate, this means 9600 16-bit MMACs can occur every second. Moreover, each multiplier on the C64x+ core can compute one 32-bit x 32-bit MAC or four 8-bit x 8-bit MACs every clock cycle. The C6455 device includes Serial RapidIO. This high bandwidth peripheral dramatically improves system performance and reduces system cost for applications that include multiple DSPs on a board, such as video and telecom infrastructures and medical/imaging. 2 Features Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 The C6455 DSP integrates a large amount of on-chip memory organized as a two-level memory system. The level-1 (L1) program and data memories on the C6455 device are 32KB each. This memory can be configured as mapped RAM, cache, or some combination of the two. When configured as cache, L1 program (L1P) is a direct mapped cache where as L1 data (L1D) is a two-way set associative cache. The level 2 (L2) memory is shared between program and data space and is 2096KB in size. L2 memory can also be configured as mapped RAM, cache, or some combination of the two. The C64x+ Megamodule also has a 32-bit peripheral configuration (CFG) port, an internal DMA (IDMA) controller, a system component with reset/boot control, interrupt/exception control, a power-down control, and a free-running 32-bit timer for time stamp. The peripheral set includes: an inter-integrated circuit bus module (I2C); two multichannel buffered serial ports (McBSPs); an 8-bit Universal Test and Operations PHY Interface for Asynchronous Transfer Mode (ATM) Slave [UTOPIA Slave] port; two 64-bit general-purpose timers (also configurable as four 32-bit timers); a user-configurable 16-bit or 32-bit host-port interface (HPI16/HPI32); a peripheral component interconnect (PCI); a 16-pin general-purpose input/output port (GPIO) with programmable interrupt/event generation modes; an 10/100/1000 Ethernet media access controller (EMAC), which provides an efficient interface between the C6455 DSP core processor and the network; a management data input/output (MDIO) module (also part of the EMAC) that continuously polls all 32 MDIO addresses in order to enumerate all PHY devices in the system; a glueless external memory interface (64-bit EMIFA), which is capable of interfacing to synchronous and asynchronous peripherals; and a 32-bit DDR2 SDRAM interface. The I2C ports on the C6455 allows the DSP to easily control peripheral devices and communicate with a host processor. In addition, the standard multichannel buffered serial port (McBSP) may be used to communicate with serial peripheral interface (SPI) mode peripheral devices. The C6455 device has two high-performance embedded coprocessors [enhanced Viterbi Decoder Coprocessor (VCP2) and enhanced Turbo Decoder Coprocessor (TCP2)] that significantly speed up channel-decoding operations on-chip. The VCP2 operating at CPU clock divided-by-3 can decode over 694 7.95-Kbps adaptive multi-rate (AMR) [K = 9, R = 1/3] voice channels. The VCP2 supports constraint lengths K = 5, 6, 7, 8, and 9, rates R = 3/4, 1/2, 1/3, 1/4, and 1/5 and flexible polynomials, while generating hard decisions or soft decisions. The TCP2 operating at CPU clock divided-by-3 can decode up to fifty 384-Kbps or eight 2-Mbps turbo encoded channels (assuming 6 iterations). The TCP2 implements the max*log-map algorithm and is designed to support all polynomials and rates required by Third-Generation Partnership Projects (3GPP and 3GPP2), with fully programmable frame length and turbo interleaver. Decoding parameters such as the number of iterations and stopping criteria are also programmable. Communications between the VCP2/TCP2 and the CPU are carried out through the EDMA3 controller. The C6455 has a complete set of development tools which includes: a new C compiler, an assembly optimizer to simplify programming and scheduling, and a Windows debugger interface for visibility into source code execution. Submit Documentation Feedback Features 3 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 1.3 Functional Block Diagram Figure 1-2 shows the functional block diagram of the C6455 device. DDR2 SDRAM 32 C6455 DDR2 Mem Ctlr SBSRAM PLL2 and PLL2 Controller(D) ZBT SRAM 64 SRAM L2 ROM 32K Bytes(E) L1P Cache Direct-Mapped 32K Bytes EMIFA TCP2 ROM/FLASH VCP2 L1P Memory Controller (Memory Protect/Bandwidth Mgmt) I/O Devices McBSP0(A) EMAC 10/100/1000 MII SPLOOP Buffer Instruction Decode In-Circuit Emulation Data Path A A Register File A31−A16 A15−A0 .L1 .S1 .M1 xx .D1 xx Data Path B B Register File B31−B16 B15−B0 .D2 .M2 xx xx .S2 .L2 Internal DMA (IDMA) UTOPIA(B) 16-/32-bit Instruction Dispatch Power Control PCI66(B) M e g a m o d u l e Control Registers L2 Memory Controller (Memory Protect/ Bandwidth Mgmt) HPI (32/16)(B) L2 Cache Memory 2096K Bytes Instruction Fetch System(B) Serial Rapid I/O Primary Switched Central Resource McBSP1(A) Interrupt and Exception Controller C64x+ DSP Core RMII L1D Memory Controller (Memory Protect/Bandwidth Mgmt) GMII RMGII(D) MDIO 16 L1D Cache 2-Way Set-Associative 32K Bytes Total GPIO16(B) I2C Timer1(C) HI LO EDMA 3.0 Timer0(C) Secondary Switched Central Resource HI LO PLL1 and PLL1 Controller Device Configuration Logic Boot Configuration A. McBSPs: Framing Chips - H.100, MVIP, SCSA, T1, E1; AC97 Devices; SPI Devices; Codecs. B. The PCI peripheral pins are muxed with some of the HPI peripheral pins and the UTOPIA address pins. For more detailed information, see Section 3, Device Configuration. C. Each of the TIMER peripherals (TIMER1 and TIMER0) is configurable as a 64-bit general-purpose timer, dual 32-bit general-purpose timers, or a watchdog timer. D. The PLL2 controller also generates clocks for the EMAC. E. When accessing the internal ROM of the DSP, the CPU frequency must always be less than 750 MHz. Figure 1-2. Functional Block Diagram 4 Features Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Contents 1 2 Features 4 5 1 ZTZ/GTZ BGA Package (Bottom View) .............. 2 1.2 Description ............................................ 2 1.3 Functional Block Diagram ............................ 4 6 Device Overview ......................................... 6 2.1 Device Characteristics ................................ 6 2.2 CPU (DSP Core) Description ......................... 7 ............................. 2.4 Boot Sequence ...................................... 2.5 Pin Assignments .................................... 2.6 Signal Groups Description .......................... 2.7 Terminal Functions .................................. 2.8 Development ........................................ Device Configuration .................................. 3.1 Device Configuration at Device Reset .............. 3.2 Peripheral Configuration at Device Reset ........... 3.3 Peripheral Selection After Device Reset ............ 3.4 Device State Control Registers ..................... 3.5 Device Status Register Description ................. 3.6 JTAG ID (JTAGID) Register Description ............ 3.7 Pullup/Pulldown Resistors........................... 3.8 Configuration Examples ............................. System Interconnect ................................... 4.1 Internal Buses, Bridges, and Switch Fabrics ........ 4.2 Data Switch Fabric Connections .................... 4.3 Configuration Switch Fabric ......................... 4.4 Bus Priorities ........................................ C64x+ Megamodule .................................... 5.1 Memory Architecture ................................ 5.2 Memory Protection .................................. 5.3 Bandwidth Management ............................ 5.4 Power-Down Control ................................ 5.5 Megamodule Resets ................................ 5.6 Megamodule Revision............................... 5.7 C64x+ Megamodule Register Description(s) ........ 2.3 3 ................................................... 1.1 Memory Map Summary Submit Documentation Feedback 10 12 15 7 Device Operating Conditions ........................ 96 6.1 Absolute Maximum Ratings Over Operating Case Temperature Range (Unless Otherwise Noted)..... 96 6.2 6.3 Recommended Operating Conditions ............... 96 Electrical Characteristics Over Recommended Ranges of Supply Voltage and Operating Case Temperature (Unless Otherwise Noted) ............ 98 C64x+ Peripheral Information and Electrical Specifications ......................................... 100 7.1 7.2 Parameter Information ............................. 100 Recommended Clock and Control Signal Transition Behavior............................................ 102 7.3 7.4 Power Supplies .................................... 102 Enhanced Direct Memory Access (EDMA3) Controller ........................................... 104 7.5 Interrupts ........................................... 119 7.6 Reset Controller .................................... 123 19 25 50 54 54 56 58 60 70 72 73 74 76 76 77 79 81 82 82 85 85 86 86 87 88 ......................... ......................... 7.9 DDR2 Memory Controller .......................... 7.10 External Memory Interface A (EMIFA) ............. 7.11 I2C Peripheral ...................................... 7.12 Host-Port Interface (HPI) Peripheral ............... 7.13 Multichannel Buffered Serial Port (McBSP)........ 7.14 Ethernet MAC (EMAC) ............................. 7.15 Timers .............................................. 7.16 Enhanced Viterbi-Decoder Coprocessor (VCP2) .. 7.17 Enhanced Turbo Decoder Coprocessor (TCP2) ... 7.18 Peripheral Component Interconnect (PCI) ......... 7.19 UTOPIA ............................................ 7.20 Serial RapidIO (SRIO) Port ........................ 7.21 General-Purpose Input/Output (GPIO)............. 7.22 Emulation Features and Capability ................ Revision History ............................................ 8 Mechanical Data....................................... 8.1 Thermal Data ...................................... 8.2 Packaging Information ............................. 7.7 PLL1 and PLL1 Controller 131 7.8 PLL2 and PLL2 Controller 146 Contents 155 157 168 174 185 195 213 215 216 218 225 229 241 243 245 246 246 246 5 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 2 Device Overview 2.1 Device Characteristics Table 2-1, provides an overview of the C6455 DSP. The tables show significant features of the C6455 device, including the capacity of on-chip RAM, the peripherals, the CPU frequency, and the package type with pin count. Table 2-1. Characteristics of the C6455 Processor HARDWARE FEATURES C6455 EMIFA (64-bit bus width) (clock source = AECLKIN or SYSCLK4) 1 DDR2 Memory Controller (32-bit bus width) [1.8 V I/O] (clock source = CLKIN2) 1 EDMA3 (64 independent channels) [CPU/3 clock rate] 1 High-speed 1x/4x Serial Rapid IO Port 1 Peripherals I2C Not all peripherals pins are available at the same time (For more detail, see the Device Configuration section). HPI (32- or 16-bit user selectable) 1 (HPI16 or HPI32) PCI (32-bit), [66-MHz or 33-MHz] 1 (PCI66 or PCI33) McBSPs (internal CPU/6 or external clock source up to 100 Mbps) 2 UTOPIA (8-bit mode, 50-MHz, Slave-only) 1 10/100/1000 Ethernet MAC (EMAC) 1 Management Data Input/Output (MDIO) 1 64-Bit Timers (Configurable) (internal clock source = CPU/6 clock frequency) Decoder Coprocessors On-Chip Memory 1 2 64-bit or 4 32-bit General-Purpose Input/Output Port (GPIO) 16 VCP2 (clock source = CPU/3 clock frequency) 1 TCP2 (clock source = CPU/3 clock frequency) 1 Size (Bytes) 2192K Organization 32K-Byte (32KB) L1 Program Memory Controller [SRAM/Cache] 32KB Data Memory Controller [SRAM/Cache] 2096KB L2 Unified Memory/Cache 32KB L2 ROM C64x+ Megamodule Revision ID Megamodule Revision ID Register (address location: 0181 2000h) JTAG BSDL_ID JTAGID register (address location: 0x02A80008) See Section 3.6, JTAG ID (JTAGID) Register Description Frequency MHz 720, 850, 1000 (1 GHz), and 1200 (1.2 GHz) Cycle Time ns 1.39 ns (C6455-720), 1.17 ns (C6455-850), 1 ns (C6455 A-1000, -1000) [1-GHz CPU] (1) 0.83 ns (C6455-1200) [1.2-GHz CPU] Core (V) Voltage I/O (V) PLL1 and PLL1 Controller Options CLKIN1 frequency multiplier PLL2 CLKIN2 frequency multiplier [DDR2 Memory Controller and EMAC support only] BGA Package 24 x 24 mm (1) 6 See Section 5.6, Megamodule Revision 1.25 V (A-1000/-1000/-1200) 1.2 V (-850/-720) 1.25/1.2 [RapidIO], 1.5/1.8 [EMAC RGMII], and 1.8 and 3.3 V [I/O Supply Voltage] Bypass (x1), x15, x20, x25, x30, x32 x20 697-Pin Flip-Chip Plastic BGA (ZTZ) 697-Pin Flip-Chip Plastic BGA (GTZ) The extended temperature device's (A-1000) electrical characteristics and ac timings are the same as those for the corresponding commercial temperature devices (-1000). Device Overview Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-1. Characteristics of the C6455 Processor (continued) HARDWARE FEATURES C6455 Process Technology m 0.09 m Product Status (2) Product Preview (PP), Advance Information (AI), or Production Data (PD) Device Part Numbers (For more details on the C64x+™ DSP part numbering, see Figure 2-13) (2) PD TMS320C6455ZTZ7, TMS320C6455ZTZ8, TMS320C6455ZTZ 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. 2.2 CPU (DSP Core) Description The C64x+ Central Processing Unit (CPU) consists of eight functional units, two register files, and two data paths as shown in Figure 2-1. The two general-purpose register files (A and B) each contain 32 32-bit registers for a total of 64 registers. The general-purpose registers can be used for data or can be data address pointers. The data types supported include packed 8-bit data, packed 16-bit data, 32-bit data, 40-bit data, and 64-bit data. Values larger than 32 bits, such as 40-bit-long or 64-bit-long values are stored in register pairs, with the 32 LSBs of data placed in an even register and the remaining 8 or 32 MSBs in the next upper register (which is always an odd-numbered register). The eight functional units (.M1, .L1, .D1, .S1, .M2, .L2, .D2, and .S2) are each capable of executing one instruction every clock cycle. The .M functional units perform all multiply operations. The .S and .L units perform a general set of arithmetic, logical, and branch functions. The .D units primarily load data from memory to the register file and store results from the register file into memory. The C64x+ CPU extends the performance of the C64x core through enhancements and new features. Each C64x+ .M unit can perform one of the following each clock cycle: one 32 x 32 bit multiply, two 16 x 16 bit multiplies, two 16 x 32 bit multiplies, four 8 x 8 bit multiplies, four 8 x 8 bit multiplies with add operations, and four 16 x 16 multiplies with add/subtract capabilities (including a complex multiply). There is also support for Galois field multiplication for 8-bit and 32-bit data. Many communications algorithms such as FFTs and modems require complex multiplication. The complex multiply (CMPY) instruction takes for 16-bit inputs and produces a 32-bit real and a 32-bit imaginary output. There are also complex multiplies with rounding capability that produces one 32-bit packed output that contain 16-bit real and 16-bit imaginary values. The 32 x 32 bit multiply instructions provide the extended precision necessary for audio and other high-precision algorithms on a variety of signed and unsigned 32-bit data types. The .L or (Arithmetic Logic Unit) now incorporates the ability to do parallel add/subtract operations on a pair of common inputs. Versions of this instruction exist to work on 32-bit data or on pairs of 16-bit data performing dual 16-bit add and subtracts in parallel. There are also saturated forms of these instructions. The C64x+ core enhances the .S unit in several ways. In the C64x core, dual 16-bit MIN2 and MAX2 comparisons were only available on the .L units. On the C64x+ core they are also available on the .S unit which increases the performance of algorithms that do searching and sorting. Finally, to increase data packing and unpacking throughput, the .S unit allows sustained high performance for the quad 8-bit/16-bit and dual 16-bit instructions. Unpack instructions prepare 8-bit data for parallel 16-bit operations. Pack instructions return parallel results to output precision including saturation support. Submit Documentation Feedback Device Overview 7 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Other new features include: • SPLOOP - A small instruction buffer in the CPU that aids in creation of software pipelining loops where multiple iterations of a loop are executed in parallel. The SPLOOP buffer reduces the code size associated with software pipelining. Furthermore, loops in the SPLOOP buffer are fully interruptible. • Compact Instructions - The native instruction size for the C6000 devices is 32 bits. Many common instructions such as MPY, AND, OR, ADD, and SUB can be expressed as 16 bits if the C64x+ compiler can restrict the code to use certain registers in the register file. This compression is performed by the code generation tools. • Instruction Set Enhancements - As noted above, there are new instructions such as 32-bit multiplications, complex multiplications, packing, sorting, bit manipulation, and 32-bit Galois field multiplication. • Exception Handling - Intended to aid the programmer in isolating bugs. The C64x+ CPU is able to detect and respond to exceptions, both from internally detected sources (such as illegal op-codes) and from system events (such as a watchdog time expiration). • Privilege - Defines user and supervisor modes of operation, allowing the operating system to give a basic level of protection to sensitive resources. Local memory is divided into multiple pages, each with read, write, and execute permissions. • Time-Stamp Counter - Primarily targeted for Real-Time Operating System (RTOS) robustness, a free-running time-stamp counter is implemented in the CPU which is not sensitive to system stalls. For more details on the C64x+ CPU and its enhancements over the C64x architecture, see the following documents: • TMS320C64x/C64x+ DSP CPU and Instruction Set Reference Guide (literature number SPRU732) • TMS320C64x+ DSP Cache User's Guide (literature number SPRU862) • TMS320C64x+ Megamodule Reference Guide (literature number SPRU871) • TMS320C6455 Technical Reference (literature number SPRU965) • TMS320C64x to TMS320C64x+ CPU Migration Guide (literature number SPRAA84) 8 Device Overview Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor ÁÁ ÁÁ ÁÁ Á ÁÁ Á ÁÁ Á Á Á Á Á Á Á Á Á Á Á Á Á Á Á Á Á Á Á Á Á Á Á Á Á Á Á Á Á Á Á Á Á SPRS276H – MAY 2005 – REVISED OCTOBER 2007 src1 Odd register file A (A1, A3, A5...A31) src2 .L1 odd dst Even register file A (A0, A2, A4...A30) (D) even dst long src ST1b ST1a 32 MSB 32 LSB long src Data path A .S1 8 8 even dst odd dst src1 (D) src2 LD1b LD1a 32 LSB DA2 32 32 src2 32 MSB DA1 LD2a LD2b Á Á Á Á Á Á .M1 dst2 dst1 src1 (A) (B) (C) dst .D1 src1 src2 2x 1x Odd register file B (B1, B3, B5...B31) src2 .D2 32 LSB 32 MSB src1 dst src2 .M2 Even register file B (B0, B2, B4...B30) (C) src1 dst2 32 (B) dst1 32 (A) src2 src1 .S2 odd dst even dst long src Data path B ST2a ST2b 32 MSB 32 LSB long src even dst .L2 (D) 8 8 (D) odd dst src2 src1 Control Register A. B. C. D. On .M unit, dst2 is 32 MSB. On .M unit, dst1 is 32 LSB. On C64x CPU .M unit, src2 is 32 bits; on C64x+ CPU .M unit, src2 is 64 bits. On .L and .S units, odd dst connects to odd register files and even dst connects to even register files. Figure 2-1. TMS320C64x+™ CPU (DSP Core) Data Paths Submit Documentation Feedback Device Overview 9 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 2.3 Memory Map Summary Table 2-2 shows the memory map address ranges of the C6455 device. The external memory configuration register address ranges in the C6455 device begin at the hex address location 0x7000 0000 for EMIFA and hex address location 0x7800 0000 for DDR2 Memory Controller. Table 2-2. C6455 Memory Map Summary MEMORY BLOCK DESCRIPTION Reserved Internal ROM BLOCK SIZE (BYTES) HEX ADDRESS RANGE 1024K 0000 0000 - 000F FFFF 32K 0010 0000 - 0010 7FFF 7M - 32K 0010 8000 - 007F FFFF 2M 0080 0000 - 009F FFFF Reserved 4M 00A0 0000 - 00DF FFFF L1P SRAM 32K 00E0 0000 - 00E0 7FFF 1M - 32K 00E0 8000 - 00EF FFFF Reserved Internal RAM (L2) [L2 SRAM] Reserved L1D SRAM 32K 00F0 0000 - 00F0 7FFF Reserved 1M - 32K 00F0 8000 - 00FF FFFF Reserved 8M 0100 0000 - 017F FFFF C64x+ Megamodule Registers 4M 0180 0000 - 01BF FFFF Reserved 12.5M 01C0 0000 - 0287 FFFF HPI Control Registers 256K 0288 0000 - 028B FFFF McBSP 0 Registers 256K 028C 0000 - 028F FFFF McBSP 1 Registers 256K 0290 0000 - 0293 FFFF Timer 0 Registers 256K 0294 0000 - 0297 FFFF Timer 1 Registers 128K 0298 0000 - 0299 FFFF PLL1 Controller (including Reset Controller) Registers 512 029A 0000 - 029A 01FF 256K - 512 029A 0200 - 029B FFFF PLL2 Controller Registers 512 029C 0000 - 029C 01FF Reserved 64K 029C 0200 - 029C FFFF EDMA3 Channel Controller Registers 32K 02A0 0000 - 02A0 7FFF Reserved 96K 02A0 8000 - 02A1 FFFF EDMA3 Transfer Controller 0 Registers 32K 02A2 0000 - 02A2 7FFF EDMA3 Transfer Controller 1 Registers 32K 02A2 8000 - 02A2 FFFF EDMA3 Transfer Controller 2 Registers 32K 02A3 0000 - 02A3 7FFF EDMA3 Transfer Controller 3 Registers 32K 02A3 8000 - 02A3 FFFF Reserved 256K 02A4 0000 - 02A7 FFFF Chip-Level Registers 256K 02A8 0000 - 02AB FFFF Device State Control Registers 256K 02AC 0000 - 02AF FFFF Reserved GPIO Registers 16K 02B0 0000 - 02B0 3FFF I2C Data and Control Registers 256K 02B0 4000 - 02B3 FFFF UTOPIA Control Registers Reserved 512 02B4 0000 - 02B4 01FF 256K - 512 02B4 0200 - 02B7 FFFF VCP2 Control Registers 128K 02B8 0000 - 02B9 FFFF TCP2 Control Registers 128K 02BA 0000 - 02BB FFFF Reserved 256K 02BC 0000 - 02BF FFFF PCI Control Registers 256K 02C0 0000 - 02C3 FFFF Reserved 256K 02C4 0000 - 02C7 FFFF EMAC Control 4K 02C8 0000 - 02C8 0FFF EMAC Control Module Registers 2K 02C8 1000 - 02C8 17FF MDIO Control Registers 2K 02C8 1800 - 02C8 1FFF 10 Device Overview Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-2. C6455 Memory Map Summary (continued) MEMORY BLOCK DESCRIPTION EMAC Descriptor Memory BLOCK SIZE (BYTES) HEX ADDRESS RANGE 8K 02C8 2000 - 02C8 3FFF Reserved 496K 02C8 4000 - 02CF FFFF RapidIO Control Registers 256K 02D0 0000 - 02D3 FFFF Reserved 768K 02D4 0000 - 02DF FFFF RapidIO CPPI RAM 16K 02E0 0000 - 02E0 3FFF Reserved 2M - 16K 02E0 4000 - 02FF FFFF Reserved 16M 0300 0000 - 03FF FFFF Reserved 192M 0400 0000 - 0FFF FFFF Reserved 256M 1000 0000 - 1FFF FFFF Reserved 256M 2000 0000 - 2FFF FFFF McBSP 0 Data Reserved McBSP 1 Data Reserved UTOPIA Receive (Rx) Data Queue UTOPIA Transmit (Tx) Data Queue 256 3000 0000 - 3000 00FF 64M - 256 3000 0100 - 33FF FFFF 256 3400 0000 - 3400 00FF 64M - 256 3400 0100 - 37FF FFFF 1K 3C00 0000 - 3C00 03FF 1K 3C00 0400 - 3C00 07FF 16M - 2K 3C00 0800 - 3CFF FFFF Reserved 48M 3D00 0000 - 3FFF FFFF PCI External Memory Space 256M 4000 0000 - 4FFF FFFF TCP2 Data Registers 128M 5000 0000 - 57FF FFFF VCP2 Data Registers 128M 5800 0000 - 5FFF FFFF Reserved 256M 6000 0000 - 6FFF FFFF EMIFA (EMIF64) Configuration Registers 128M 7000 0000 - 77FF FFFF DDR2 Memory Controller Configuration Registers 128M 7800 0000 - 7FFF FFFF Reserved 256M 8000 0000 - 8FFF FFFF Reserved 256M 9000 0000 - 9FFF FFFF 8M A000 0000 - A07F FFFF 256M - 8M A080 0000 - AFFF FFFF 8M B000 0000 - B07F FFFF 256M - 8M B080 0000 - BFFF FFFF Reserved EMIFA CE2 - SBSRAM/Async (1) Reserved EMIFA CE3 - SBSRAM/Async (1) Reserved EMIFA CE4 - SBSRAM/Async (1) Reserved EMIFA CE5 - SBSRAM/Async (1) Reserved DDR2 Memory Controller CE0 - DDR2 SDRAM (1) 8M C000 0000 - C07F FFFF 256M - 8M C080 0000 - CFFF FFFF 8M D000 0000 - D07F FFFF 256M - 8M D080 0000 - DFFF FFFF 512M E000 0000 - FFFF FFFF The EMIFA CE0 and CE1 are not functionally supported on the C6455 device, and therefore, are not pinned out. Submit Documentation Feedback Device Overview 11 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 2.4 Boot Sequence The boot sequence is a process by which the DSP's internal memory is loaded with program and data sections and the DSP's internal registers are programmed with predetermined values. The boot sequence is started automatically after each power-on reset, warm reset, max reset, and system reset. For more details on the initiators of these resets, see Section 7.6, Reset Controller. There are several methods by which the memory and register initialization can take place. Each of these methods is referred to as a boot mode. The boot mode to be used is selected at reset through the BOOTMODE[3:0] pins. Each boot mode can be classified as a hardware boot mode or as a software boot mode. Software boot modes require the use of the on-chip bootloader. The bootloader is DSP code that transfers application code from an external source into internal or external program memory after the DSP is taken out of reset. The bootloader is permanently stored in the internal ROM of the DSP starting at byte address 0010 0000h. Hardware boot modes are carried out by the boot configuration logic. The boot configuration logic is actual hardware that does not require the execution of DSP code. Section 2.4.1, Boot Modes Supported, describes each boot mode in more detail. When accessing the internal ROM of the DSP, the CPU frequency must always be less than 750 MHz. Therefore, when using a software boot mode, care must be taken such that the CPU frequency does not exceed 750 MHz at any point during the boot sequence. After the boot sequence has completed, the CPU frequency can be programmed to the frequency required by the application. 2.4.1 Boot Modes Supported The C6455 has six boot modes: • No boot (BOOTMODE[3:0] = 0000b) With no boot, the CPU executes directly from the internal L2 SRAM located at address 0x80 0000. Note: device operations is undefined if invalid code is located at address 0x80 0000. This boot mode is a hardware boot mode. • Host boot (BOOTMODE[3:0] = 0001b and BOOTMODE[3:0] = 0111b) If host boot is selected, after reset, the CPU is internally "stalled" while the remainder of the device is released. During this period, an external host can initialize the CPU's memory space as necessary through Host Port Interface (HPI) or the Peripheral Component Interconnect (PCI) interface. Internal configuration registers, such as those that control the EMIF can also be initialized by the host with two exceptions: Device State Control registers (Section 3.4), PLL1 and PLL2 Controller registers (Section 7.7 and Section 7.8) cannot be accessed through any host interface, including HPI and PCI. Once the host is finished with all necessary initialization, it must generate a DSP interrupt (DSPINT) to complete the boot process. This transition causes boot configuration logic to bring the CPU out of the "stalled" state. The CPU then begins execution from the internal L2 SRAM located at 0x80 0000. Note that the DSP interrupt is registered in bit 0 (channel 0) of the EDMA Event Register (ER). This event must be cleared by software before triggering transfers on DMA channel 0. All memory, with the exceptions previously described, may be written to and read by the host. This allows for the host to verify what it sends to the DSP if required. After the CPU is out of the "stalled" state, the CPU needs to clear the DSPINT, otherwise, no more DSPINTs can be received. As previously mentioned, for the C6455 device, the Host Port Interface (HPI) and the Peripheral Component Interconnect (PCI) interface can be used for host boot. To use the HPI for host boot, the PCI_EN pin (Y29) must be low [default] (enabling the HPI peripheral) and BOOTMODE[3:0] must be set to 0001b at device reset. Conversely, to use the PCI interface for host boot, the PCI_EN pin (Y29) must be high (enabling the PCI peripheral) and BOOTMODE[3:0] must be set to 0111b at device reset. For the HPI host boot, the DSP interrupt can be generated through the use of the DSPINT bit in the HPI Control (HPIC) register. For the HPI host boot, the CPU is actually held in reset until a DSP interrupt is generated by the host. The DSP interrupt can be generated through the use of the DSPINT bit in the HPI Control (HPIC) register. Since the CPU is held in reset during HPI host boot, it will not respond to emulation software 12 Device Overview Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 • • • • such as Code Composer Studio. For the PCI host boot, the CPU is out of reset, but it executes an IDLE instruction until a DSP interrupt is generated by the host. The host can generate a DSP interrupt through the PCI peripheral by setting the DSPINT bit in the Back-End Application Interrupt Enable Set Register (PCIBINTSET) and the Status Set Register (PCISTATSET). Note that the HPI host boot is a hardware boot mode while the PCI host boot is a software boot mode. If PCI boot is selected, the on-chip bootloader configures the PLL1 Controller such that CLKIN1 is multiplied by 15. More specifically, PLLM is set to 0Eh (x15) and RATIO is set to 0 (÷1) in the PLL1 Multiplier Control Register (PLLM) and PLL1 Pre-Divider Register (PREDIV), respectively. The CLKIN1 frequency must not be greater than 50 MHz so that the maximum speed of the internal ROM, 750 MHz, is not violated. The CFGGP[2:0] pins must be set to 000b during reset for proper operation of the PCI boot mode. As mentioned previously, a DSP interrupt must be generated at the end of the host boot process to begin execution of the loaded application. Since the DSP interrupt generated by the HPI and PCI is mapped to the EDMA event DSP_EVT (DMA channel 0), it will get recorded in bit 0 of the EDMA Event Register (ER). This event must be cleared by software before triggering transfers on DMA channel 0. EMIFA 8-bit ROM boot (BOOTMODE[3:0] = 0100b) After reset, the device will begin executing software out of an Asynchronous 8-bit ROM located in EMIFA CE3 space using the default settings in the EMIFA registers. This boot mode is a hardware boot mode. Master I2C boot (BOOTMODE[3:0] = 0101b) After reset, the DSP can act as a master to the I2C bus and copy data from an I2C EEPROM or a device acting as an I2C slave to the DSP using a predefined boot table format. The destination address and length are contained within the boot table. This boot mode is a software boot mode. Slave I2C boot (BOOTMODE[3:0] = 0110b) A Slave I2C boot is also implemented, which programs the DSP as an I2C Slave and simply waits for a Master to send data using a standard boot table format. Using the Slave I2C boot, a single DSP or a device acting as an I2C Master can simultaneously boot multiple slave DSPs connected to the same I2C bus. Note that the Master DSP may require booting via an I2C EEPROM before acting as a Master and booting other DSPs. The Slave I2C boot is a software boot mode. Serial RapidIO boot (BOOTMODE[3:0] = 1000b through 1111b) After reset, the following sequence of events occur: – The on-chip bootloader configures device registers, including SerDes, and EDMA3 – The on-chip bootloader resets the peripheral's state machines and registers – RapidIO ports send idle control symbols to initialize SerDes ports – The host explores the system with RapidIO maintenance packets – The host identifies, enumerates, and initializes the RapidIO device – The host controller configures DSP peripherals through maintenance packets – The application software is sent from the host controller to DSP memory – The DSP CPU is awakened by interrupt such as a RapidIO DOORBELL packet – The application software is executed and normal operation follows For Serial RapidIO boot, BOOTMODE2 (L26 pin) is used in conjunction with CFGGP[2:0] (T26, U26, and U25 pins, respectively) to determine the device address within the RapidIO network. BOOTMODE2 is the MSB of the address, while CFGGP[2:0] are used as the three LSBs–giving the user the opportunity to have up to 16 unique device IDs. BOOTMODE[1:0] (L25 and P26, respectively) denote the configuration of the RapidIO peripheral; i.e., "00b" refers to RapidIO Configuration 0. For exact device RapidIO Configurations, see the TMS320C645x Bootloader User's Guide (literature number SPRUEC6). Submit Documentation Feedback Device Overview 13 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 The SRIO boot is a software boot mode. 2.4.2 2nd-Level Bootloaders Any of the boot modes can be used to download a 2nd-level bootloader. A 2nd-level bootloader allows for any level of customization to current boot methods as well as definition of a completely customized boot. TI offers a few 2nd-level bootloaders, such as an EMAC bootloader and a UTOPIA bootloader, which can be loaded using the Master I2C boot. 14 Device Overview Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 2.5 Pin Assignments 2.5.1 Pin Map Figure 2-2 through Figure 2-5 show the C6455 pin assigments in four quadrants (A, B, C, and D). 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 AJ DVDD33 GP[5] FSX0 CLKS DR0 TINPL1 DVDD33 VSS TCK TMS RSV26 RSV40 SYSCLK4/ GP[1] VSS DVDD33 AJ AH VSS GP[4] FSR0 NMI DR1/ GP[8] TINPL0 TRST TDO TDI EMU17 RSV27 EMU16 EMU9 DVDD33 VSS AH AG CLKR0 GP[7] GP[6] FSX1/ GP[11] DX1/ GP[9] CLKX0 TOUTL1 EMU6 EMU2 RSV38 RSV39 DVDD33 VSS RESET RIOCLK AG AF DVDD33 VSS HD11/ AD11 CLKR1/ GP[0] CLKX1/ GP[3] DX0 EMU0 TOUTL0 EMU4 EMU3 EMU8 EMU7 EMU14 POR RIOCLK AF AE HD22/ AD22 HD0/ AD0 HD10/ AD10 VSS FSR1/ GP[10] DVDD33 VSS DVDD33 EMU15 EMU12 EMU1 EMU5 EMU18 RESETSTAT DVDD33 AE AD HD21/ AD21 HD25/ AD25 HD5/ AD5 HD3/ AD3 DVDD33 VSS DVDD33 EMU13 RSV37 EMU10 RSV36 EMU11 VSS DVDD33 VSS AD AC HD19/ AD19 HD13/ AD13 HD23/ AD23 HD29/ AD29 HD27/ AD27 DVDD33 VSS VSS DVDD33 VSS DVDD33 VSS DVDD33 VSS AVDDA AC AB HD17/ AD17 HD15/ AD15 HD9/ AD9 HD7/ AD7 HD1/ AD1 VSS DVDD33 AB AA DVDD33 VSS HD31/ AD31 HD28/ AD28 HD30/ AD30 DVDD33 VSS AA Y HD26/ AD26 HD18/ AD18 HD16/ AD16 HD6/ AD6 HD4/ AD4 VSS DVDD33 W HD24/ AD24 HD20/ AD20 RSV03 HD14/ AD14 HD8/ AD8 HD2/ AD2 VSS VSS CVDD VSS CVDD VSS W V DVDD33 VSS HHWIL/ PCLK HD12/ AD12 RSV02 VSS DVDD33 CVDD VSS CVDD VSS DVDDRM V U HDS2/ PCBE1 HDS1/ PSERR HINT/ PFRAME HCNTL1/ PDEVSEL HCNTL0/ PSTOP HCS/ PPERR VSS VSS CVDD VSS CVDD VSS U T RSV15 RSV16 HAS/ PPAR HRDY/ PIRDY HR/W/ PCBE2 VSS DVDD33 CVDD VSS CVDD VSS CVDD T R DVDD33 VSS UXADDR1/ PIDSEL URADDR0/ PGNT/ GP[12] URADDR1/ PRST/ GP[13] DVDD33 VSS VSS CVDD VSS CVDD VSS R 1 2 3 4 5 6 7 11 12 13 14 Y 8 9 10 15 Figure 2-2. C6455 Pin Map (Bottom View) [Quadrant A] Submit Documentation Feedback Device Overview 15 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 16 17 18 19 20 21 22 23 24 25 26 27 28 29 AJ VSS AVDDT RIORX2 RIORX2 VSS RIORX1 RIORX1 AVDDT VSS DVDD33 AED5 AED6 AED20 DVDD33 AJ AH DVDD33 RIORX3 RIORX3 VSS AVDDT VSS RIORX0 RIORX0 DVDD33 VSS AED14 AED2 AED18 VSS AH AG VSS DVDD33 RIOTX2 RIOTX2 VSS RIOTX1 RIOTX1 DVDD33 VSS AED3 SCL AED9 AED16 AED30 AG AF DVDD33 RIOTX3 RIOTX3 VSS AVDDT VSS RIOTX0 RIOTX0 DVDD33 AED1 SDA AED10 AED15 AED19 AF AE VSS AVDDT VSS AVDDT VSS RSV17 VSS AVDDT VSS AED7 AED12 AED4 AED13 AED17 AE AD AVDDA VSS DVDD33 VSS DVDDR VSS DVDD33 VSS DVDD33 AED0 AED11 AED8 AED22 AED21 AD AC VSS AVDDA VSS DVDD33 VSS DVDD33 VSS DVDD33 VSS AED24 AED26 AED28 VSS DVDD33 AC AB VSS DVDD33 AAWE/ ASWE AED23 AED25 AED27 AED29 AB AA DVDD33 VSS ABE1 ABE0 AED31 ABE2 ABE3 AA VSS DVDD33 RSV43 RSV42 RSV44 AAOE/ ASOE PCI_EN Y ABE7 W Y W DVDD12 VSS DVDD12 VSS DVDD33 VSS AR/W ACE3 ACE2 RSV41 V VSS DVDDRM VSS CVDD VSS DVDD33 ABA1/ EMIFA_EN ABA0/ DDR2_EN ACE5 ACE4 U DVDDRM VSS CVDD VSS DVDD33 VSS AEA0/ CFGGP0 AEA1/ CFGGP1 AEA6/ PCI66 AEA5/ MCBSP1 _EN RSV20 U T VSS CVDD VSS CVDD VSS DVDD33 AEA11 AEA2/ CFGGP2 AEA3 AEA4/ SYSCLKOUT _EN PLLV1 T R CVDD VSS CVDD VSS DVDD33 VSS AEA14/ HPI_ WIDTH ASADS/ ASRE AEA13/ LENDIAN AEA12/ UTOPIA_EN AHOLD R 16 17 18 19 23 24 25 26 27 28 29 20 21 22 AECLKOUT V Figure 2-3. C6455 Pin Map (Bottom View) [Quadrant B] 16 Device Overview Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 16 17 18 19 P VSS CVDD VSS N CVDD VSS M VSS L CVDD 20 21 22 23 24 25 CVDD RSV30 RSV31 AEA8/ PCI_EEAI CVDD VSS VSS DVDD33 CVDD VSS CVDD DVDD33 VSS CVDD VSS 26 27 28 29 AEA16/ BOOT MODE0 AEA15/ AECLKIN _SEL DVDD33 VSS P AEA19/ BOOT MODE3 AHOLDA AEA7 CLKIN1 AECLKIN N VSS AEA10/ MACSEL1 VSS AEA9/ MACSEL0 DVDD33 VSS M VSS DVDD33 AEA17/ BOOT MODE1 AEA18/ BOOT MODE2 ABUSREQ ABE4 ABE5 L K DVDD33 VSS AED33 ABE6 AED32 AED34 AARDY K J VSS DVDD33 AED38 AED46 AED44 AED42 AED40 J H DVDD33 VSS AED47 AED45 AED43 DVDD33 VSS H G DVDD18 VSS DVDD18 VSS DVDD18 VSS DVDD18 VSS DVDD18 AED55 AED54 AED50 AED48 AED35 G F VSS DVDD18 RSV19 DVDD18 VSS DSDDQ GATE3 VSS DVDD18 VSS AED63 AED36 AED56 AED52 AED37 F E DEODT0 DEA4 AVDLL2 VSS DSDDQS2 DSDDQ GATE2 DVDD18 DSDDQS3 DVDD18 VSS DVDD33 AED59 DVDD33 VSS E D DEA8 DEA5 DEA0 DED19 DSDDQS2 DED23 DED27 DSDDQS3 RSV11 RSV32 RSV09 AED57 AED58 AED39 D C DEA9 DEA6 DEA1 DED18 DSDDQM2 DED22 DED26 DSDDQM3 RSV12 RSV33 RSV23 AED61 AED60 AED41 C B DEA10 DEA7 DEA2 DED16 DVDD18 DED21 DED25 DVDD18 DED29 DED31 RSV22 AED49 AED51 VSS B A DEA11 DEODT1 DEA3 DED17 VSS DED20 DED24 VSS DED28 DED30 DVDD18MON AED62 AED53 DVDD33 A 16 17 18 19 20 21 22 23 24 25 26 27 28 29 Figure 2-4. C6455 Pin Map (Bottom View) [Quadrant C] Submit Documentation Feedback Device Overview 17 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 P URADDR4/ PCBE0/ GP[2] URADDR3/ PREQ/ GP[15] URADDR2/ PINTA/ GP[14] UXADDR0/ PTRDY UXADDR2/ PCBE3 DVDD33 VSS RSV05 VSS CVDD VSS CVDD P N CVDDMON VSS UXADDR3/ MDIO UXCLK/ MTCLK/ RMREFCLK UXDATA7/ MTXD7 RSV29 RSV28 RSV04 CVDD VSS CVDD VSS N M UXDATA0/ MTXD0/ RMTXD0 URDATA7/ MRXD7 UXDATA6/ MTXD6 UXDATA2/ MTXD2 UXADDR4/ MDCLK VSS DVDD33 CVDD VSS CVDD VSS CVDD M L URDATA4/ MRXD4 URDATA5/ MRXD5 UXDATA4/ MTXD4 UXDATA1/ MTXD1/ RMTXD1 UXDATA5/ MTXD5 DVDD33MON VSS VSS CVDD VSS CVDD VSS L K DVDD33 VSS UXSOC/ MCOL UXDATA3/ MTXD3 UXCLAV/ GMTCLK VSS DVDD33 K J URDATA2/ MRXD2 URDATA0/ MRXD0/ RMRXD0 URDATA3/ MRXD3 URCLAV/ MCRS/ RMCRSDV UXENB/ MTXEN/ RMTXEN DVDD33 VSS J H URCLK/ MRCLK URDATA6/ MRXD6 URDATA1/ MRXD1/ RMRXD1 URSOC/ MRXER/ RMRXER URENB/ MRXDV VSS DVDD15 H G VSS DVDD33 CLKIN2 RSV07 VSS DVDD15 VSS DVDD18 VSS DVDD18 VSS DVDD18 VSS DVDD18 VSS G F RSV14 RSV13 DVDD15MON VSS DVDD15 VSS DVDD18 VSS DED11 VSS DVDD18 VSS DVDD18 VSS DVDD18 F E RGRXD0 RGRXD1 RGRXC RGRXD2 VSS RSV34 VSS DSDDQS1 DED10 DVDD18 DSDDQS0 DVDD18 RSV18 DCE0 DBA2 E D VSS DVDD15 RGTXCTL RGTXC DVDD15 RSV35 DED14 DSDDQS1 DED9 DED7 DSDDQS0 DED3 DSDCAS DSDCKE DBA1 D C RGRXD3 RGRXCTL RGTXD2 RGREFCLK VSS RSV25 DED15 DSDDQM1 DED8 DED6 DSDDQM0 DED2 DSDRAS VREFSSTL DBA0 C B VSS VREFHSTL RGTXD1 RGMDCLK DVDD15 RSV24 DED12 DVDD18 DSDDQ GATE1 DED5 DVDD18 DED1 DSDWE DDR2 CLKOUT DEA13 B A DVDD15 RGTXD3 RGTXD0 RGMDIO PLLV2 RSV21 DED13 VSS DSDDQ GATE0 DED4 VSS DED0 AVDLL1 DDR2 CLKOUT DEA12 A 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Figure 2-5. C6455 Pin Map (Bottom View) [Quadrant D] 18 Device Overview Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 2.6 Signal Groups Description CLKIN1 SYSCLK4/GP[1] (A) PLLV1 Clock/PLL1 and PLL Controller Reset and Interrupts RESETSTAT RESET NMI POR CLKIN2 PLLV2 Clock/PLL2 RSV02 RSV03 RSV04 RSV05 RSV07 RSV09 TMS TDO TDI TCK TRST Reserved EMU0 EMU1 • • • EMU14 EMU15 EMU16 EMU17 EMU18 IEEE Standard 1149.1 (JTAG) Emulation • • • RSV42 RSV43 RSV44 Peripheral Enable/Disable PCI_EN Control/Status A. This pin functions as GP[1] by default. For more details, see the Device Configuration section of this document. Figure 2-6. CPU and Peripheral Signals Submit Documentation Feedback Device Overview 19 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 TINPL1 Timer 1 Timer 0 TOUTL1 TOUTL0 TINPL0 Timers (64-Bit) URADDR3/PREQ/GP[15](C) URADDR2/PINTA/GP[14](C) URADDR1/PRST/GP[13](C) URADDR0/PGNT/GP[12](C) FSX1/GP[11](B) FSR1/GP[10](B) DX1/GP[9](B) DR1/GP[8](B) GP[7] GP[6] GP[5] GP[4] CLKX1/GP[3](B) URADDR4/PCBE0/GP[2](C) SYSCLK4/GP[1](A) CLKR1/GP[0](B) GPIO General-Purpose Input/Output 0 (GPIO) Port 4 RIOTX[3:0] RIOTX[3:0] Transmit RIOCLK RIOCLK 4 RIORX[3:0] RIORX[3:0] Clock 4 Receive 4 RAPID IO A. B. This pin functions as GP[1] by default. For more details, see the Device Configuration section of this document. These McBSP1 peripheral pins are muxed with the GPIO peripheral pins and by default these signals function as GPIO peripheral pins. For more details, see the Device Configuration section of this document. C. These UTOPIA and PCI peripheral pins are muxed with the GPIO peripheral pins and by default these signals function as GPIO peripheral pins. For more details, see the Device Configuration section of this document. Figure 2-7. Timers/GPIO/RapidIO Peripheral Signals 20 Device Overview Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 64 Data AED[63:0] AECLKIN ACE5(A) ACE4(A) ACE3(A) AECLKOUT Memory Map Space Select ACE2(A) 20 AEA[19:0] Address External Memory I/F Control ABE7 ABE6 ASWE/AAWE AARDY AR/W ABE5 ABE4 ABE3 ABE2 AAOE/ASOE ASADS/ASRE Byte Enables ABE1 ABE0 Bus Arbitration AHOLD AHOLDA ABUSREQ Bank Address ABA[1:0] EMIFA (64-bit Data Bus) 32 DDR2CLKOUT DDR2CLKOUT DSDCKE DSDCAS Data DED[31:0] Memory Map Space Select DCE0 14 DEA[13:0] DSDDQM3 DSDDQM2 DSDDQM1 DSDDQM0 Address External Memory I/F Control DSDRAS DSDWE DSDDQS[3:0] DSDDQS[3:0] DSDDQGATE[0] DSDDQGATE[1] DSDDQGATE[2] DSDDQGATE[3] DEODT[1:0] Byte Enables Bank Address DBA[2:0] DDR2 Memoty Controller (32-bit Data Bus) A. The EMIFA ACE0 and ACE1 are not functionally supported on the C6455 device. Figure 2-8. EMIFA/DDR2 Memory Controller Peripheral Signals Submit Documentation Feedback Device Overview 21 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 HD[15:0]/AD[15:0] HD[31:16]/AD[31:16] HCNTL0/PSTOP HCNTL1/PDEVSEL 32 HPI(A) (Host-Port Interface) Data HAS/PPAR HR/W/PCBE2 HCS/PPERR HDS1/PSERR HDS2/PCBE1 HRDY/PIRDY HINT/PFRAME Register Select Control HHWIL/PCLK (HPI16 ONLY) Half-Word Select McBSP1 McBSP0 CLKX1/GP[3] FSX1/GP[11] DX1/GP[9] Transmit Transmit CLKR1/GP[0] FSR1/GP[10] DR1/GP[8] Receive Receive Clock McBSPs (Multichannel Buffered Serial Ports)(B) I2C A. B. CLKR0 FSR0 DR0 Clock CLKS (SHARED) CLKX0 FSX0 DX0 SCL SDA These HPI pins are muxed with the PCI peripheral. By default, these pins function as HPI. When the HPI is enabled, the number of HPI pins used depends on the HPI configuration (HPI16 or HPI32). For more details on these muxed pins, see the Device Configuration section of this document. These McBSP1 peripheral pins are muxed with the GPIO peripheral pins and by default these signals function as GPIO peripheral pins. For more details, see the Device Configuration section of this document. Figure 2-9. HPI/McBSP/I2C Peripheral Signals 22 Device Overview Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Ethernet MAC (EMAC) Transmit MII UXDATA[7:2]/MTXD[7:2], UXDATA[1:0]/MTXD[1:0]/RMTXD[1:0] RMII GMII RGTXD[3:0] RGMII(A) MDIO Input/Output MII Receive RMII MII URDATA[7:2]/MRXD[7:2], URDATA[1:0]/MRXD[1:0]/RMRXD[1:0] RMII UXADDR3/MDIO GMII RGMII(A) RGMDIO GMII RGRXD[3:0] RGMII(A) Error Detect and Control URSOC/MRXER/RMRXER, URENB/MRXDV, URCLAV/MCRS/RMCRSDV, UXSOC/MCOL, UXENB/MTXEN/RMTXEN RGTXCTL, RGRXCTL MII RMII Clock MII RMII UXADDR4/MDCLK GMII RGMII(A) RGMDCLK GMII RGMII(A) Clocks MII UXCLK/MTCLK/RMREFCLK, URCLK/MRCLK, UXCLAV/GMTCLK RMII GMII RGTXC, RGRXC, RGREFCLK RGMII(A) Ethernet MAC (EMAC) and MDIO(B) A. B. RGMII signals are mutually exclusive to all other EMAC signals. These EMAC pins are muxed with the UTOPIA peripheral. By default, these signals function as EMAC. For more details on these muxed pins, see the Device Configuration section of this document. Figure 2-10. EMAC/MDIO [MII/RMII/GMII/RGMII] Peripheral Signals Submit Documentation Feedback Device Overview 23 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 UTOPIA (SLAVE)(A) URDATA7/MRXD7 URDATA6/MRXD6 URDATA5/MRXD5 URDATA4/MRXD4 URDATA3/MRXD3 URDATA2/MRXD2 URDATA1/MRXD1/RMRXD1 URDATA0/MRXD0/RMRXD0 Transmit UXDATA7/MTXD7 UXDATA6/MTXD6 UXDATA5/MTXD5 UXDATA4/MTXD4 UXDATA3/MTXD3 UXDATA2/MTXD2 UXDATA1/MTXD1/RMTXD1 UXDATA0/MTXD0/RMTXD0 Control/Status Control/Status UXENB/MTXEN/RMTXEN UXADDR4/GMDCLK UXADDR3/GMDIO UXADDR2/PCBE3 UXADDR1/PIDSEL UXADDR0/PTRDY UXCLAV/GMTCLK UXSOC/MCOL/TCLKRISE Clock Clock UXCLK/MTCLK/REFCLK Receive URENB/MRXDV URADDR4/PCLK/GP[2] URADDR3/PREQ/GP[15] URADDR2/PINTA/GP[14] URADDR1/PRST/GP[13] URADDR0/PGNT/GP[12] URCLAV/MCRS/RMCRSDV URSOC/MRXER/RMRXER URCLK/MRCLK A. These UTOPIA pins are muxed with the PCI or EMAC or GPIO peripherals. By default, these signals function as GPIO or EMAC peripheral pins or have no function. For more details on these muxed pins, see the Device Configuration section of this data sheet. Figure 2-11. UTOPIA Peripheral Signals 32 HD[15:0]/AD[15:0] HD[31:16]/AD[31:16] UXADDR2/PCBE3 HR/W/PCBE2 HDS2/PCBE1 UXADDR4/PCBE0/GP[2] Data/Address Command Byte Enable Clock Control HHWIL/PCLK UXADDR1/PIDSEL HCNTL1/PDEVSEL HINT/PFRAME URADDR2/PINTA/GP[14] HAS/PPAR URADDR1/PRST/GP[13] HRDY/PIRDY HCNTL0/PSTOP UXADDR0/PTRDY URADDR0/PGNT/GP[12] Arbitration Error URADDR3/PREQ/GP[15] HDS1/PSERR HCS/PPERR PCI Interface(A) A. These PCI pins are muxed with the HPI or UTOPIA or GPIO peripherals. By default, these signals function as HPI or GPIO or EMAC. For more details on these muxed pins, see the Device Configuration section of this document. Figure 2-12. PCI Peripheral Signals 24 Device Overview Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 2.7 Terminal Functions The terminal functions table (Table 2-3) identifies the external signal names, the associated pin (ball) numbers along with the mechanical package designator, the pin type (I, O/Z, or I/O/Z), whether the pin has any internal pullup/pulldown resistors, and a functional pin description. For more detailed information on device configuration, peripheral selection, multiplexed/shared pins, and pullup/pulldown resistors, see Section 3, Device Configuration. Table 2-3. Terminal Functions SIGNAL NAME NO. TYPE (1) IPD/IPU (2) DESCRIPTION CLOCK/PLL CONFIGURATIONS CLKIN1 N28 I IPD Clock Input for PLL1. CLKIN2 G3 I IPD Clock Input for PLL2. PLLV1 T29 A 1.8-V I/O supply voltage for PLL1 PLLV2 A5 A 1.8-V I/O supply voltage for PLL2 SYSCLK4/GP[1] (3) AJ13 I/O/Z IPD TMS AJ10 I IPU JTAG test-port mode select TDO AH8 O/Z IPU JTAG test-port data out TDI AH9 I IPU JTAG test-port data in TCK AJ9 I IPU JTAG test-port clock TRST AH7 I IPD JTAG test-port reset. For IEEE 1149.1 JTAG compatibility, see the IEEE 1149.1 JTAG compatibility statement portion of this document. EMU0 (4) AF7 I/O/Z IPU Emulation pin 0 EMU1 (4) AE11 I/O/Z IPU Emulation pin 1 EMU2 AG9 I/O/Z IPU Emulation pin 2 EMU3 AF10 I/O/Z IPU Emulation pin 3 EMU4 AF9 I/O/Z IPU Emulation pin 4 EMU5 AE12 I/O/Z IPU Emulation pin 5 EMU6 AG8 I/O/Z IPU Emulation pin 6 EMU7 AF12 I/O/Z IPU Emulation pin 7 EMU8 AF11 I/O/Z IPU Emulation pin 8 EMU9 AH13 I/O/Z IPU Emulation pin 9 EMU10 AD10 I/O/Z IPU Emulation pin 10 EMU11 AD12 I/O/Z IPU Emulation pin 11 EMU12 AE10 I/O/Z IPU Emulation pin 12 EMU13 AD8 I/O/Z IPU Emulation pin 13 EMU14 AF13 I/O/Z IPU Emulation pin 14 EMU15 AE9 I/O/Z IPU Emulation pin 15 EMU16 AH12 I/O/Z IPU Emulation pin 16 EMU17 AH10 I/O/Z IPU Emulation pin 17 EMU18 AE13 I/O/Z IPU Emulation pin 18 SYSCLK4 is the clock output at 1/8 of the device speed (O/Z) or this pin can be programmed as the GP1 pin (I/O/Z) [default]. JTAG EMULATION (1) (2) (3) (4) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal IPD = Internal pulldown, IPU = Internal pullup. For most systems, a 1-kΩ resistor can be used to oppose the IPU/IPD. For more detailed information on pullup/pulldown resistors and situations where external pullup/pulldown resistors are required, see Section 3.7, Pullup/Pulldown Resistors. These pins are multiplexed pins. For more details, see Section 3, Device Configuration. The C6455 DSP does not require external pulldown resistors on the EMU0 and EMU1 pins for normal or boundary-scan operation. Submit Documentation Feedback Device Overview 25 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. TYPE (1) IPD/IPU (2) DESCRIPTION RESETS, INTERRUPTS, AND GENERAL-PURPOSE INPUT/OUTPUTS RESET AG14 I Device reset NMI AH4 I RESETSTAT AE14 O Reset Status pin. The RESETSTAT pin indicates when the device is in reset POR AF14 I Power on reset. GP[7] AG2 I/O/Z IPD GP[6] AG3 I/O/Z IPD GP[5] AJ2 I/O/Z IPD GP[4] IPD IPD AH2 I/O/Z URADDR3/PREQ/ GP[15] P2 I/O/Z URADDR2/PINTA (5)/ GP[14] P3 I/O/Z URADDR1/PRST/ GP[13] R5 I/O/Z URADDR0/PGNT/ GP[12] R4 I/O/Z FSX1/GP[11] AG4 I/O/Z IPD FSR1/GP[10] AE5 I/O/Z IPD DX1/GP[9] AG5 I/O/Z IPD DR1/GP[8] AH5 I/O/Z IPD CLKX1/GP[3] AF5 I/O/Z IPD P1 I/O/Z URADDR4/PCBE0/ GP[2] Nonmaskable interrupt, edge-driven (rising edge) Any noise on the NMI pin may trigger an NMI interrupt; therefore, if the NMI pin is not used, it is recommended that the NMI pin be grounded versus relying on the IPD. General-purpose input/output (GPIO) pins (I/O/Z). UTOPIA received address pins or PCI peripheral pins or General-purpose input/output (GPIO) [15:12, 2] pins (I/O/Z) [default] SYSCLK4/GP[1] AJ13 O/Z IPD CLKR1/GP[0] AF4 I/O/Z IPD PCI bus request (O/Z) or GP[15] (I/O/Z) [default] PCI interrupt A (O/Z) or GP[14] (I/O/Z) [default] PCI reset (I) or GP[13] (I/O/Z) [default] PCI bus grant (I) or GP[12] (I/O/Z) [default] PCI command/byte enable 0 (I/O/Z) or GP[2] (I/O/Z) [default] McBSP1 transmit clock (I/O/Z) or GP[3] (I/O/Z) [default] McBSP1 receive clock (I/O/Z) or GP[0] (I/O/Z) [default] GP[1] pin (I/O/Z). SYSCLK4 is the clock output at 1/8 of the device speed (O/Z) or this pin can be programmed as a GP[1] pin (I/O/Z) [default]. HOST-PORT INTERFACE (HPI) or PERIPHERAL COMPONENT INTERCONNECT (PCI) Y29 I HINT/PFRAME U3 I/O/Z Host interrupt from DSP to host (O/Z) or PCI frame (I/O/Z) HCNTL1/PDEVSEL U4 I/O/Z Host control - selects between control, address, or data registers (I) [default] or PCI device select (I/O/Z) HCNTL0/PSTOP U5 I/O/Z Host control - selects between control, address, or data registers (I) [default] or PCI stop (I/O/Z) HHWIL/PCLK V3 I/O/Z Host half-word select - first or second half-word (not necessarily high or low order) [For HPI16 bus width selection only] (I) [default] or PCI clock (I) HR/W/PCBE2 T5 I/O/Z Host read or write select (I) [default] or PCI command/byte enable 2 (I/O/Z) HAS/PPAR T3 I/O/Z Host address strobe (I) [default] or PCI parity (I/O/Z) HCS/PPERR U6 I/O/Z Host chip select (I) [default] or PCI parity error (I/O/Z) HDS1/PSERR (5) U2 I/O/Z Host data strobe 1 (I) [default] or PCI system error (I/O/Z) HDS2/PCBE1 U1 I/O/Z Host data strobe 2 (I) [default] or PCI command/byte enable 1 (I/O/Z) HRDY/PIRDY T4 I/O/Z Host ready from DSP to host (O/Z) [default] or PCI initiator ready (I/O/Z) URADDR3/PREQ/ GP[15] P2 I/O/Z UTOPIA received address pin 3 (URADDR3) (I) or PCI bus request (O/Z) or GP[15] (I/O/Z) [default] (5) 26 IPD PCI enable pin. This pin controls the selection (enable/disable) of the HPI and GP[15:8], or PCI peripherals. This pin works in conjunction with the MCBSP1_EN (AEA5 pin) to enable/disable other peripherals (for more details, see Section 3, Device Configuration). PCI_EN These pins function as open-drain outputs when configured as PCI pins. Device Overview Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. TYPE (1) IPD/IPU (2) DESCRIPTION URADDR2/PINTA (5)/ GP[14] P3 I/O/Z UTOPIA received address pin 2 (URADDR2) (I) or PCI interrupt A (O/Z) or GP[14] (I/O/Z) default] URADDR1/PRST/ GP[13] R5 I/O/Z UTOPIA received address pin 1 (URADDR1) (I) or PCI reset (I) or GP[13] (I/O/Z) [default] URADDR0/PGNT/ GP[12] R4 I/O/Z UTOPIA received address pin 0 (URADDR0) (I) or PCI bus grant (I) or GP[12] (I/O/Z)[default] URADDR4/PCBE0/ GP[2] P1 I/O/Z UTOPIA received address pin 4 (URADDR4) (I) or PCI command/byte enable 0 (I/O/Z) or GP[2] (I/O/Z)[default] UXADDR2/PCBE3 P5 I/O/Z UTOPIA transmit address pin 2 (UXADDR2) (I) or PCI command/byte enable 3 (I/O/Z). By default, this pin has no function. UXADDR1/PIDSEL R3 I UXADDR0/PTRDY P4 I/O/Z UTOPIA transmit address pin 0 (UXADDR0) (I) or PCI target ready (PRTDY) (I/O/Z). By default, this pin has no function. I/O/Z Host-port data [31:16] pin (I/O/Z) [default] or PCI data-address bus [31:16] (I/O/Z) I/O/Z Host-port data [15:0] pin (I/O/Z) [default] or PCI data-address bus [15:0] (I/O/Z) HD31/AD31 UTOPIA transmit address pin 1 (UXADDR1) (I) or PCI initialization device select (I). By default, this pin has no function. AA3 HD30/AD30 AA5 HD29/AD29 AC4 HD28/AD28 AA4 HD27/AD27 AC5 HD26/AD26 Y1 HD25/AD25 AD2 HD24/AD24 W1 HD23/AD23 AC3 HD22/AD22 AE1 HD21/AD21 AD1 HD20/AD20 W2 HD19/AD19 AC1 HD18/AD18 Y2 HD17/AD17 AB1 HD16/AD16 Y3 HD15/AD15 AB2 HD14/AD14 W4 HD13/AD13 AC2 HD12/AD12 V4 HD11/AD11 AF3 HD10/AD10 AE3 HD9/AD9 AB3 HD8/AD8 W5 HD7/AD7 AB4 HD6/AD6 Y4 HD5/AD5 AD3 HD4/AD4 Y5 HD3/AD3 AD4 HD2/AD2 W6 HD1/AD1 AB5 HD0/AD0 AE2 Submit Documentation Feedback Device Overview 27 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. TYPE (1) IPD/IPU (2) DESCRIPTION EMIFA (64-BIT) - CONTROL SIGNALS COMMON TO ALL TYPES OF MEMORY ABA1/EMIFA_EN V25 O/Z IPD EMIFA bank address control (ABA[1:0]) • Active-low bank selects for the 64-bit EMIFA. When interfacing to 16-bit Asynchronous devices, ABA1 carries bit 1 of the byte address. For an 8-bit Asynchronous interface, ABA[1:0] are used to carry bits 1 and 0 of the byte address ABA0/DDR2_EN V26 O/Z IPD DDR2 Memory Controller enable (DDR2_EN) [ABA0] 0 - DDR2 Memory Controller peripheral pins are disabled (default) 1 - DDR2 Memory Controller peripheral pins are enabled EMIFA enable (EMIFA_EN) [ABA1] 0 - EMIFA peripheral pins are disabled (default) 1 - EMIFA peripheral pins are enabled ACE5 V27 O/Z IPU ACE4 V28 O/Z IPU ACE3 W26 O/Z IPU ACE2 W27 O/Z IPU ABE7 W29 O/Z IPU ABE6 K26 O/Z IPU ABE5 L29 O/Z IPU ABE4 L28 O/Z IPU ABE3 AA29 O/Z IPU ABE2 AA28 O/Z IPU ABE1 AA25 O/Z IPU ABE0 AA26 O/Z IPU AHOLDA N26 O IPU EMIFA hold-request-acknowledge to the host AHOLD R29 I IPU EMIFA hold request from the host ABUSREQ L27 O IPU EMIFA bus request output EMIFA memory space enables • Enabled by bits 28 through 31 of the word address • Only one pin is asserted during any external data access Note: The C6455 device does not have ACE0 and ACE1 pins EMIFA byte-enable control • Decoded from the low-order address bits. The number of address bits or byte enables used depends on the width of external memory. • Byte-write enables for most types of memory. EMIFA (64-BIT) - BUS ARBITRATION EMIFA (64-BIT) - ASYNCHRONOUS/SYNCHRONOUS MEMORY CONTROL AECLKIN N29 I IPD EMIFA external input clock. The EMIFA input clock (AECLKIN or SYSCLK4 clock) is selected at reset via the pullup/pulldown resistor on the AEA[15] pin. Note: AECLKIN is the default for the EMIFA input clock. AECLKOUT V29 O/Z IPD EMIFA output clock [at EMIFA input clock (AECLKIN or SYSCLK4) frequency] AB25 O/Z IPU Asynchronous memory write-enable/Programmable synchronous interface write-enable AAWE/ASWE AARDY K29 I IPU Asynchronous memory ready input AR/W W25 O/Z IPU Asynchronous memory read/write AAOE/ASOE Y28 O/Z IPU Asynchronous/Programmable synchronous memory output-enable IPU Programmable synchronous address strobe or read-enable • For programmable synchronous interface, the R_ENABLE field in the Chip Select x Configuration Register selects between ASADS and ASRE: – If R_ENABLE = 0, then the ASADS/ASRE signal functions as the ASADS signal. – If R_ENABLE = 1, then the ASADS/ASRE signal functions as the ASRE signal. ASADS/ASRE 28 Device Overview R26 O/Z Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. TYPE (1) IPD/IPU (2) DESCRIPTION EMIFA (64-BIT) - ADDRESS AEA19/BOOTMODE3 N25 AEA18/BOOTMODE2 L26 AEA17/BOOTMODE1 L25 AEA16/BOOTMODE0 P26 AEA15/AECLKIN_SEL P27 AEA14/HPI_WIDTH R25 AEA13/LENDIAN R27 AEA12/UTOPIA_EN R28 O/Z IPD O/Z IPU EMIFA external address (word address) (O/Z) Controls initialization of the DSP modes at reset (I) via pullup/pulldown resistors [For more detailed information, see Section 3, Device Configuration.] Note: If a configuration pin must be routed out from the device and 3-stated (not driven), the internal pullup/pulldown (IPU/IPD) resistor should not be relied upon; TI recommends the use of an external pullup/pulldown resistor. For more detailed information on pullup/pulldown resistors and situations where external pullup/pulldown resistors are required, see Section 3.7, Pullup/Pulldown Resistors. • • AEA11 T25 O/Z IPD • • • Submit Documentation Feedback Boot mode - device boot mode configurations (BOOTMODE[3:0]) [Note: the peripheral must be enabled to use the particular boot mode.] AEA[19:16]: 0000 - No boot (default mode) 0001 - Host boot (HPI) 0010 -Reserved 0011 - Reserved 0100 - EMIFA 8-bit ROM boot 0101 - Master I2C boot 0110 - Slave I2C boot 0111 - Host boot (PCI) 1000 thru 1111 - Serial Rapid I/O boot configurations For more detailed information on the boot modes, see Section 2.4, Boot Sequence. CFGGP[2:0] pins must be set to 000b during reset for proper operation of the PCI boot mode. EMIFA input clock source select Clock mode select for EMIFA (AECLKIN_SEL) AEA15: 0 - AECLKIN (default mode) 1 - SYSCLK4 (CPU/x) Clock Rate. The SYSCLK4 clock rate is software selectable via the Software PLL1 Controller. By default, SYSCLK4 is selected as CPU/8 clock rate. HPI peripheral bus width (HPI_WIDTH) select [Applies only when HPI is enabled; PCI_EN pin = 0] AEA14: 0 - HPI operates as an HPI16 (default). (HPI bus is 16 bits wide. HD[15:0] pins are used and the remaining HD[31:16] pins are reserved pins in the Hi-Z state.) 1 - HPI operates as an HPI32. Device Endian mode (LENDIAN) AEA13: 0 - System operates in Big Endian mode 1 - System operates in Little Endian mode(default) UTOPIA Enable bit (UTOPIA_EN) AEA12: UTOPIA peripheral enable(functional) 0 - UTOPIA disabled; Ethernet MAC (EMAC) and MDIO enable(default). This means all multiplexed EMAC/UTOPIA and MDIO/UTOPIA pins function as EMAC and MDIO. Which EMAC/MDIO configuration (interface) [MII, RMII, GMII or the standalone RGMII] is controlled by the MACSEL[1:0] bits. 1 - UTOPIA enabled; EMAC and MDIO disabled [except when the MACSEL[1:0] bits = 11 then, the EMAC/MDIO RGMII interface is still functional]. This means all multiplexed EMAC/UTOPIA and MDIO/UTOPIA pins now function as UTOPIA. And if MACSEL[1:0] = 11, the RGMII standalone pin functions can be used. Device Overview 29 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. AEA10/MACSEL1 M25 AEA9/MACSEL0 M27 AEA8/PCI_EEAI P25 AEA7 N27 AEA6/PCI66 U27 AEA5/MCBSP1_EN U28 AEA4/ SYSCLKOUT_EN T28 AEA3 T27 AEA2/CFGGP2 T26 AEA1/CFGGP1 U26 TYPE (1) IPD/IPU (2) DESCRIPTION • • • O/Z IPD • AEA0/CFGGP0 U25 • • EMAC/MDIO interface select bits (MACSEL[1:0]) If the EMAC and MDIO peripherals are enabled, AEA12 pin (UTOPIA_EN = 0) , there are two additional configuration pins — MACSEL[1:0] — to select the EMAC/MDIO interface. AEA[10:9]: MACSEL[1:0] with AEA12 =0. 00 - 10/100 EMAC/MDIO MII Mode Interface (default) 01 - 10/100 EMAC/MDIO RMII Mode Interface 10 - 10/100/1000 EMAC/MDIO GMII Mode Interface 11 - 10/100/1000 with RGMII Mode Interface [RGMII interface requires a 1.8 V or 1.5 V I/O supply] When UTOPIA is enabled (AEA12 = 1), if the MACSEL[1:0] bits = 11 then, the EMAC/MDIO RGMII interface is still functional. For more detailed information, see Section 3, Device Configuration. PCI I2C EEPROM Auto-Initialization (PCI_EEAI) AEA8: PCI auto-initialization via external I2C EEPROM If the PCI peripheral is disabled (PCI_EN pin = 0), this pin must not be pulled up. 0 - PCI auto-initialization through I2C EEPROM is disabled (default). 1 - PCI auto-initialization through I2C EEPROM is enabled. PCI Frequency Selection (PCI66) [The PCI peripheral needs be enabled (PCI_EN = 1) to use this function] Selects the PCI operating frequency of 66 MHz or 33 MHz PCI operating frequency is selected at reset via the pullup/pulldown resistor on the PCI66 pin: AEA6: 0 - PCI operates at 33 MHz (default). 1 - PCI operates at 66 MHz. Note: If the PCI peripheral is disabled (PCI_EN = 0), this pin must not be pulled up. McBSP1 Enable bit (MCBSP1_EN) Selects which function is enabled on the McBSP1/GPIO muxed pins AEA5: 0 - GPIO pin functions enabled (default). 1 - McBSP1 pin functions enabled. SYSCLKOUT Enable pin (SYSCLKOUT_EN) Selects which function is enabled on the SYSCLK4/GP[1] muxed pin AEA4: 0 - GP[1] pin function of the SYSCLK4/GP[1] pin enabled (default). 1 - SYSCLK4 pin function of the SYSCLK4/GP[1] pin enabled. Configuration GPI (CFGGP[2:0]) (AEA[2:0]) These pins are latched during reset and their values are shown in the DEVSTAT register. These values can be used by software routines for boot operations. Note: For proper C6455 device operation, the AEA11 pin must be externally pulled up at device reset with a 1-kΩ resistor. The AEA3 pin must be pulled up at device reset using a 1-kΩ resistor if power is applied to the SRIO supply pins. If the SRIO peripheral is not used and the SRIO supply pins are connected to VSS, the AEA3 pin must be pulled down to VSS using a 1-kΩ resistor. 30 Device Overview Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. TYPE (1) IPD/IPU (2) DESCRIPTION EMIFA (64-BIT) - DATA AED63 F25 AED62 A27 AED61 C27 AED60 C28 AED59 E27 AED58 D28 AED57 D27 AED56 F27 AED55 G25 AED54 G26 AED53 A28 AED52 F28 AED51 B28 AED50 G27 AED49 B27 AED48 G28 AED47 H25 AED46 J26 AED45 H26 AED44 J27 AED43 H27 AED42 J28 AED41 C29 AED40 J29 AED39 D29 AED38 J25 AED37 F29 AED36 F26 AED35 G29 AED34 K28 AED33 K25 AED32 K27 AED31 AA27 AED30 AG29 AED29 AB29 AED28 AC27 AED27 AB28 AED26 AC26 AED25 AB27 AED24 AC25 AED23 AB26 AED22 AD28 Submit Documentation Feedback I/O/Z IPU EMIFA external data Device Overview 31 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. AED21 TYPE (1) IPD/IPU (2) I/O/Z IPU DESCRIPTION AD29 AED20 AJ28 AED19 AF29 AED18 AH28 AED17 AE29 AED16 AG28 AED15 AF28 AED14 AH26 AED13 AE28 AED12 AE26 AED11 AD26 AED10 AF27 AED9 AG27 AED8 AD27 AED7 AE25 AED6 AJ27 AED5 AJ26 AED4 AE27 AED3 AG25 AED2 AH27 AED1 AF25 AED0 EMIFA external data AD25 DDR2 MEMORY CONTROLLER (32-BIT) - CONTROL SIGNALS COMMON TO ALL TYPES OF MEMORY DCE0 DDR2 Memory Controller memory space enable. When the DDR2 Memory Controller is enabled, it always keeps this pin low. E14 O/Z DBA2 E15 O/Z DBA1 D15 O/Z DBA0 C15 O/Z DDR2CLKOUT B14 O/Z DDR2 Memory Controller output clock (CLKIN2 frequency נ10) DDR2CLKOUT A14 O/Z Negative DDR2 Memory Controller output clock (CLKIN2 frequency נ10) DSDCAS D13 O/Z DDR2 Memory Controller SDRAM column-address strobe DSDRAS C13 O/Z DDR2 Memory Controller SDRAM row-address strobe DSDWE B13 O/Z DDR2 Memory Controller SDRAM write-enable DSDCKE D14 O/Z DDR2 Memory Controller SDRAM clock-enable (used for self-refresh mode) DEODT1 A17 O/Z DEODT0 E16 O/Z On-die termination signals to external DDR2 SDRAM. These pins should not be connected to the DDR2 SDRAM. Note: There are no on-die termination resistors implemented on the C6455 DSP die. DSDDQGATE3 F21 I DSDDQGATE2 E21 O/Z DSDDQGATE1 B9 I DSDDQGATE0 A9 O/Z DSDDQM3 C23 O/Z DSDDQM2 C20 O/Z DSDDQM1 C8 O/Z DSDDQM0 C11 O/Z 32 Device Overview DDR2 Memory Controller bank address control DDR2 Memory Controller data strobe gate [3:0] For hookup of these signals, please refer to the Implementing DDR2 PCB Layout on the TMS320C6455 application report (literature number SPRAAA7). DDR2 Memory Controller byte-enable controls • Decoded from the low-order address bits. The number of address bits or byte enables used depends on the width of external memory. • Byte-write enables for most types of memory. • Can be directly connected to SDRAM read and write mask signal (SDQM). Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. TYPE (1) DSDDQS3 E23 I/O/Z DSDDQS2 E20 I/O/Z DSDDQS1 E8 I/O/Z DSDDQS0 E11 I/O/Z DSDDQS3 D23 I/O/Z DSDDQS2 D20 I/O/Z DSDDQS1 D8 I/O/Z DSDDQS0 D11 I/O/Z DEA13 B15 DEA12 A15 DEA11 A16 IPD/IPU (2) DESCRIPTION DDR2 Memory Controller data strobe [3:0] positive DDR2 data strobe [3:0] negative Note: These pins are used to meet AC timings. For more detailed information, see the Implementing DDR2 PCB Layout on the TMS320C6455 application report (literature number SPRAAA7). DDR2 MEMORY CONTROLLER (32-BIT) - ADDRESS DEA10 B16 DEA9 C16 DEA8 D16 DEA7 B17 DEA6 C17 DEA5 D17 DEA4 E17 DEA3 A18 DEA2 B18 DEA1 C18 DEA0 D18 Submit Documentation Feedback O/Z DDR2 Memory Controller external address Device Overview 33 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. TYPE (1) IPD/IPU (2) DESCRIPTION DDR2 MEMORY CONTROLLER (32-BIT) - DATA DED31 B25 DED30 A25 DED29 B24 DED28 A24 DED27 D22 DED26 C22 DED25 B22 DED24 A22 DED23 D21 DED22 C21 DED21 B21 DED20 A21 DED19 D19 DED18 C19 DED17 A19 DED16 B19 DED15 C7 DED14 D7 DED13 A7 DED12 B7 DED11 F9 DED10 E9 DED9 D9 DED8 C9 DED7 D10 DED6 C10 DED5 B10 DED4 A10 DED3 D12 DED2 C12 DED1 B12 DED0 A12 I/O/Z DDR2 Memory Controller external data TIMER 1 TOUTL1 AG7 O/Z IPD Timer 1 output pin for lower 32-bit counter TINPL1 AJ6 I IPD Timer 1 input pin for lower 32-bit counter TOUTL0 AF8 O/Z IPD Timer 0 output pin for lower 32-bit counter TINPL0 AH6 I IPD Timer 0 input pin for lower 32-bit counter TIMER 0 INTER-INTEGRATED CIRCUIT (I2C) SCL AG26 I/O/Z I2C clock. When the I2C module is used, use an external pullup resistor. SDA AF26 I/O/Z I2C data. When I2C is used, ensure there is an external pullup resistor. 34 Device Overview Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. TYPE (1) IPD/IPU (2) DESCRIPTION MULTICHANNEL BUFFERED SERIAL PORT 1 AND MULTICHANNEL BUFFERED SERIAL PORT 0 (McBSP1 and McBSP0) CLKS AJ4 I IPD McBSP external clock source (as opposed to internal) (I) [shared by McBSP1 and McBSP0] MULTICHANNEL BUFFERED SERIAL PORT 1 (McBSP1) CLKR1/GP[0] AF4 I/O/Z IPD McBSP1 receive clock (I/O/Z) or GP[0] (I/O/Z) [default] FSR1/GP[10] AE5 I/O/Z IPD McBSP1 receive frame sync (I/O/Z) or GP[10] (I/O/Z)[default] DR1/GP[8] AH5 I/O/Z IPD McBSP1 receive data (I) or GP[8] (I/O/Z) [default] DX1/GP[9] AG5 I/O/Z IPD McBSP1 transmit data (O/Z) or GP[9] (I/O/Z) [default] FSX1/GP[11] AG4 I/O/Z IPD McBSP1 transmit frame sync (I/O/Z) or GP[11] (I/O/Z) [default] CLKX1/GP[3] AF5 I/O/Z IPD McBSP1 transmit clock (I/O/Z) or GP[3] (I/O/Z) [default] MULTICHANNEL BUFFERED SERIAL PORT 0 (McBSP0) CLKR0 AG1 I/O/Z IPU McBSP0 receive clock (I/O/Z) FSR0 AH3 I/O/Z IPD McBSP0 receive frame sync (I/O/Z) DR0 AJ5 I IPD McBSP0 receive data (I) DX0 AF6 I/O/Z IPD McBSP0 transmit data (O/Z) FSX0 AJ3 I/O/Z IPD McBSP0 transmit frame sync (I/O/Z) CLKX0 AG6 I/O/Z IPU McBSP0 transmit clock (I/O/Z) UNIVERSAL TEST AND OPERATIONS PHY INTERFACE for ASYNCHRONOUS TRANSFER MODE (ATM) [UTOPIA SLAVE] UTOPIA SLAVE (ATM CONTROLLER) - TRANSMIT INTERFACE UXCLK/MTCLK/ RMREFCLK UXCLAV/GMTCLK UXENB/MTXEN/ RMTXEN N4 K5 J5 I/O/Z Source clock for UTOPIA transmit driven by Master ATM Controller. When the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0), this pin is either EMAC MII transmit clock (MTCLK) or the EMAC RMII reference clock. The EMAC function is controlled by the MACSEL[1:0] (AEA[10:9] pins). For more detailed information, see Section 3, Device Configuration. I/O/Z Transmit cell available status output signal from UTOPIA Slave. 0 indicates a complete cell is NOT available for transmit 1 indicates a complete cell is available for transmit When the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0), this pin is EMAC GMII transmit clock. MACSEL[1:0] dependent. I/O/Z UTOPIA transmit interface enable input signal. Asserted by the Master ATM Controller to indicate that the UTOPIA Slave should put out on the Transmit Data Bus the first byte of valid data and the UXSOC signal in the next clock cycle. When the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0), this pin is either the EMAC MII transmit enable [default] or EMAC RMII transmit enable or EMAC GMII transmit enable. MACSEL[1:0] dependent. Transmit Start-of-Cell signal. This signal is output by the UTOPIA Slave on the rising edge of the UXCLK, indicating that the first valid byte of the cell is available on the 8-bit Transmit Data Bus (UXDATA[7:0]). When the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0), this pin is either the EMAC MII collision sense or EMAC GMII collision sense. MACSEL[1:0] dependent. UXSOC/MCOL K3 I/O/Z UXADDR4/MDCLK M5 I UXADDR3/MDIO N3 I UXADDR2/PCBE3 P5 I UXADDR1/PIDSEL R3 I UXADDR0/PTRDY P4 Submit Documentation Feedback I UTOPIA transmit address pins (UXADDR[4:0]) (I) As UTOPIA transmit address pins, UTOPIA_EN (AEA12 pin) = 1: • 5-bit Slave transmit address input pins driven by the Master ATM Controller to identify and select one of the Slave devices (up to 31 possible) in the ATM System. When the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0) and if the PCI_EN pin = 1, these pins are PCI peripheral pins: PCI command/byte enable 3(PCBE3) [I/O/Z], PCI initialization device select (PIDSEL) [I], and PCI target ready (PTRDY) [I/O/Z]. Device Overview 35 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. UXDATA7/MTXD7 N5 UXDATA6/MTXD6 M3 UXDATA5/MTXD5 L5 UXDATA4/MTXD4 L3 UXDATA3/MTXD3 K4 UXDATA2/MTXD2 M4 UXDATA1/MTXD1/ RMTXD1 L4 UXDATA0/MTXD0/ RMTXD0 M1 TYPE (1) IPD/IPU (2) DESCRIPTION UTOPIA 8-bit transmit data bus (I/O/Z) [default] or EMAC MII 4-bit transmit data bus (I/O/Z) [default] or EMAC GMII 8-bit transmit data bus or EMAC RMII 2-bit transmit data bus (I/O/Z) O/Z Using the Transmit Data Bus, the UTOPIA Slave (on the rising edge of the UXCLK) transmits the 8-bit ATM cells to the Master ATM Controller. When the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0), these pins function as EMAC pins and are controlled by the MACSEL[1:0] (AEA[10:9] pins) to select the MII, RMII, GMII or RGMII EMAC interface. (For more details, see Section 3, Device Configuration). UTOPIA SLAVE (ATM CONTROLLER) - RECEIVE INTERFACE URCLK/MRCLK URCLAV/MCRS/ RMCRSDV URENB/MRXDV H1 J4 H5 I/O/Z Source clock for UTOPIA receive driven by Master ATM Controller. When the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0), this pin is EMAC MII [default] or GMII receive clock. MACSEL[1:0] dependent. I/O/Z Receive cell available status output signal from UTOPIA Slave. 0 indicates NO space is available to receive a cell from Master ATM Controller 1 indicates space is available to receive a cell from Master ATM Controller When the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0), this pin is EMAC MII carrier sense [default] or RMII carrier sense/data valid or GMII carrier sense. MACSEL[1:0] dependent. MACSEL[1:0] dependent. I/O/Z UTOPIA receive interface enable input signal. Asserted by the Master ATM Controller to indicate to the UTOPIA Slave to sample the Receive Data Bus (URDATA[7:0]) and URSOC signal in the next clock cycle or thereafter. When the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0), this pin is EMAC MII [default] or GMII receive data valid. MACSEL[1:0] dependent. Receive Start-of-Cell signal. This signal is output by the Master ATM Controller to indicate to the UTOPIA Slave that the first valid byte of the cell is available to sample on the 8-bit Receive Data Bus (URDATA[7:0]). When the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0), this pin is EMAC MII [default] or RMII or GMII receive error. MACSEL[1:0] dependent. URSOC/MRXER/ RMRXER H4 I/O/Z URADDR4/PCBE0/ GP[2] P1 I URADDR3/PREQ/ GP[15] P2 I URADDR2/PINTA (1)/ GP[14] P3 I URADDR1/PRST/ GP[13] R5 I URADDR0/PGNT/ GP[12] R4 URDATA7/MRXD7 M2 URDATA6/MRXD6 H2 URDATA5/MRXD5 L2 URDATA4/MRXD4 L1 URDATA3/MRXD3 J3 URDATA2/MRXD2 J1 URDATA1/MRXD1/ RMRXD1 H3 URDATA0/MRXD0/ RMRXD0 J2 (1) 36 I UTOPIA receive address pins [URADDR[4:0] (I)]: As UTOPIA receive address pins, UTOPIA_EN (AEA12 pin) = 1: • 5-bit Slave receive address input pins driven by the Master ATM Controller to identify and select one of the Slave devices (up to 31 possible) in the ATM System. • When the UTOPIA peripheral is disabled [UTOPIA_EN (AEA12 pin) = 0], these pins are PCI (if PCI_EN = 1) or GPIO (if PCI_EN = 0) pins (GP[15:12, 2]). As PCI peripheral pins: PCI command/byte enable 0 (PCBE0) [I/O/Z] PCI bus request (PREQ) [O/Z], PCI interrupt A (PINTA) [O/Z], PCI reset (PRST) [I], and PCI bus grant (PGNT) [I/O/Z]. UTOPIA 8-bit Receive Data Bus (I/O/Z) [default] or EMAC receive data bus [MII] [default] (I/O/Z) or [GMII] (I/O/Z) or [RMII] (I/O/Z) Using the Receive Data Bus, the UTOPIA Slave (on the rising edge of the URCLK) can receive the 8-bit ATM cell data from the Master ATM Controller. I/O/Z When the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0), these pins function as EMAC pins and are controlled by the MACSEL[1:0] (AEA[10:9] pins) to select the MII, RMII, GMII, or RGMII EMAC interface. (For more details, see Section 3, Device Configuration). These pins function as open-drain outputs when configured as PCI pins. Device Overview Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. TYPE (1) IPD/IPU (2) DESCRIPTION RAPIDIO SERIAL PORT RIOCLK AF15 I RapidIO serial port source (reference) clock RIOCLK AG15 I Negative RapidIO serial port source (reference) clock RIOTX3 AF17 RIOTX2 AG18 RIOTX1 AG22 RIOTX0 AF23 RIOTX3 AF18 RIOTX2 AG19 RIOTX1 AG21 RIOTX0 AF22 RIORX3 AH18 RIORX2 AJ18 RIORX1 AJ22 RIORX0 AH22 RIORX3 AH17 RIORX2 AJ19 RIORX1 AJ21 RIORX0 AH23 O/Z RapidIO transmit data bus bits [3:0] (differential) O/Z RapidIO negative transmit data bus bits [3:0] (differential) I RapidIO receive data bus bits [3:0] (differential) I RapidIO negative receive data bus bits [3:0] (differential) MANAGEMENT DATA INPUT/OUTPUT (MDIO) FOR MII/RMII/GMII UXADDR4/MDCLK M5 I/O/Z IPD UTOPIA transmit address pin (UXADDR4) (I) 4 or MDIO serial clock (MDCLK) for MII/RMII/RGMII mode (O) UXADDR3/MDIO N3 I/O/Z IPU UTOPIA transmit address pin 3 (UXADDR3) (I) or MDIO serial data (MDIO) for MII/RMII/RGMII mode (I/O) MANAGEMENT DATA INPUT/OUTPUT (MDIO) FOR RGMII RGMDCLK B4 O/Z RGMDIO A4 I/O/Z MDIO serial clock (RGMII mode) (RGMDCLK) (O) MDIO serial data (RGMII mode) (RGMDIO) (I/O) ETHERNET MAC (EMAC) [MII/RMII/GMII] If the Ethernet MAC (EMAC) and MDIO are enabled (AEA12 driven low [UTOPIA_EN = 0]), there are two additional configuration pins — the MAC_SEL[1:0] (AEA[10:9] pins) that select one of the four interface modes (MII, RMII, GMII, or RGMII) for the EMAC/MDIO interface. For more detailed information on the EMAC configuration pins, see Section 3, Device Configuration. URCLK/MRCLK H1 I URCLAV/MCRS/ RMCRSDV J4 I/O/Z URSOC/MRXER/ RMRXER H4 I UTOPIA receive clock (URCLK) driven by Master ATM Controller (I) or when the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0), this pin is EMAC receive clock (MRCLK) for MII [default] or GMII. MACSEL[1:0] dependent. UTOPIA receive cell available status output signal from UTOPIA Slave (O) or when the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0), this pin is EMAC carrier sense (MCRS) (I) for MII [default] or GMII, or EMAC carrier sense/receive data valid (RMCRSDV) (I) for RMII. MACSEL[1:0] dependent. UTOPIA receive Start-of-Cell signal (I) or when the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0), this pin is EMAC receive error (MRXIR) (I) for MII [default], RMII, or GMII. MACSEL[1:0] dependent. UTOPIA receive interface enable input signal (I). Asserted by the Master ATM Controller to indicate to the UTOPIA Slave to sample the Receive Data Bus (URDATA[7:0]) and URSOC signal in the next clock cycle or thereafter. URENB/MRXDV H5 I When the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0), this pin is EMAC MII [default] or GMII receive data valid (MRXDV) (I). MACSEL[1:0] dependent. Submit Documentation Feedback Device Overview 37 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. URDATA7/MRXD7 M2 URDATA6/MRXD6 H2 URDATA5/MRXD5 L2 URDATA4/MRXD4 L1 URDATA3/MRXD3 J3 URDATA2/MRXD2 J1 URDATA1/MRXD1/ RMRXD1 H3 URDATA0/MRXD0/ RMRXD0 J2 UXCLAV/GMTCLK K5 TYPE (1) I IPD/IPU (2) DESCRIPTION UTOPIA 8-bit Receive Data Bus (I) [default] or EMAC receive data bus for MII [default], RMII, or GMII Using the Receive Data Bus, the UTOPIA Slave (on the rising edge of the URCLK) can receive the 8-bit ATM cell data from the Master ATM Controller. When the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0), these pins function as EMAC receive data pins for MII [default], RMII, or GMII (MRXD[x:0]) (I). MACSEL[1:0] dependent. O/Z Transmit cell available status output signal from UTOPIA slave (O). • 0 indicates a complete cell is NOT available for transmit • 1 indicates a complete cell is available for transmit When the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0), this pin is EMAC GMII transmit clock (GMTCLK) (O). MACSEL[1:0] dependent. UXCLK/MTCLK/ RMREFCLK N4 I UTOPIA transmit source clock (UXCLK) driven by Master ATM Controller (I) or when the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0), this pin is either EMAC MII [default] or GMII transmit clock (MTCLK) (I) or the EMAC RMII reference clock (RMREFCLK) (I). The EMAC function is controlled by the MACSEL[1:0] (AEA[10:9] pins). For more detailed information, see Section 3, Device Configuration. UTOPIA transmit Start-of-Cell signal (O). This signal is output by the UTOPIA Slave on the rising edge of the UXCLK, indicating that the first valid byte of the cell is available on the 8-bit Transmit Data Bus (UXDATA[7:0]). UXSOC/MCOL K3 I/O/Z When the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0), this pin is the EMAC collision sense (MCDL) (I) for MII [default] or GMII. MACSEL[1:0] dependent. UXENB/MTXEN/ RMTXEN J5 UXDATA7/MTXD7 N5 UXDATA6/MTXD6 M3 UXDATA5/MTXD5 L5 UXDATA4/MTXD4 L3 UXDATA3/MTXD3 K4 UXDATA2/MTXD2 M4 UXDATA1/MTXD1/ RMTXD1 L4 UXDATA0/MTXD0/ RMTXD0 M1 38 Device Overview I/O/Z UTOPIA transmit interface enable input signal [default] (I) or when the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0), this pin is either the EMAC transmit enable (MTXEN) (O) for MII [default], RMII, or GMII. MACSEL[1:0] dependent. UTOPIA 8-bit transmit data bus (O) [default] or EMAC transmit data bus for MII [default], RMII, or GMII. O/Z Using the Transmit Data Bus, the UTOPIA Slave (on the rising edge of the UXCLK) transmits the 8-bit ATM cells to the Master ATM Controller. When the UTOPIA peripheral is disabled (UTOPIA_EN [AEA12 pin] = 0), these pins function as EMAC transmit data pins (MTXD[x:0]) (O) for MII, RMII, or GMII. MACSEL[1:0] dependent. Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. TYPE (1) IPD/IPU (2) DESCRIPTION ETHERNET MAC (EMAC) [RGMII] If the Ethernet MAC (EMAC) and MDIO are enabled (AEA12 driven low [UTOPIA_EN = 0]), there are two additional configuration pins — the MAC_SEL[1:0] (AEA[10:9] pins) that select one of the four interface modes (MII, RMII, GMII, or RGMII) for the EMAC/MDIO interface. For more detailed information on the EMAC configuration pins, see Section 3, Device Configuration. RGREFCLK C4 O/Z RGMII reference clock (O). This 125-MHz reference clock is provided as a convenience. It can be used as a clock source to a PHY, so that the PHY may generate RXC clock to communicate with the EMAC. This clock is stopped while the device is in reset. This pin is available only when RGMII mode is selected ( MACSEL[1:0] =11). RGTXC D4 O/Z RGMII transmit clock (O). This pin is available only when RGMII mode is selected (MACSEL[1:0] =11). RGTXD3 A2 RGTXD2 C3 RGTXD1 B3 O/Z RGMII transmit data [3:0] (O). This pin is available only when RGMII mode is selected (MACSEL[1:0] =11). RGTXD0 A3 RGTXCTL D3 O/Z RGMII transmit enable (O). This pin is available only when RGMII mode is selected (MACSEL[1:0] =11). RGRXC E3 I RGRXD3 C1 I RGRXD2 E4 I RGRXD1 E2 I RGRXD0 E1 I RGRXCTL C2 I RGMII receive clock (I). This pin is available only when RGMII mode is selected (MACSEL[1:0] =11). RGMII receive data [3:0] (I). This pin is available only when RGMII mode is selected (MACSEL[1:0] =11). RGMII receive control (I). This pin is available only when RGMII mode is selected (MACSEL[1:0] =11). RESERVED FOR TEST RSV02 V5 RSV03 W3 RSV04 N11 RSV05 P11 RSV07 G4 I RSV09 D26 I RSV11 RSV12 Reserved. These pins must be connected directly to core supply (CVDD) for proper device operation. Reserved. These pins must be connected directly to 1.5-/1.8-V I/O supply (DVDD15) for proper device operation. NOTE: If the EMAC RGMII is not used, these pins can be connected directly to ground (VSS). D24 Reserved. This pin must be connected to ground (VSS) via a 200-Ω resistor for proper device operation. NOTE: If the DDR2 Memory Controller is not used, the VREFSSTL, RSV11, and RSV12 pins can be connected directly to ground (VSS) to save power. However, connecting these pins directly to ground will prevent boundary-scan from functioning on the DDR2 Memory Controller pins. To preserve boundary-scan functionality on the DDR2 Memory Controller pins, see Section 7.3.4. C24 Reserved. This pin must be connected to the 1.8-V I/O supply (DVDD18) via a 200-Ω resistor for proper device operation. NOTE: If the DDR2 Memory Controller is not used, the VREFSSTL, RSV11, and RSV12 pins can be connected directly to ground (VSS) to save power. However, connecting these pins directly to ground will prevent boundary-scan from functioning on the DDR2 Memory Controller pins. To preserve boundary-scan functionality on the DDR2 Memory Controller pins, see Section 7.3.4. Submit Documentation Feedback Device Overview 39 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. TYPE (1) IPD/IPU (2) DESCRIPTION F2 Reserved. This pin must be connected to ground (VSS) via a 200-Ω resistor for proper device operation. NOTE: If the RGMII mode of the EMAC is not used, the DVDD15, VREFHSTL, RSV13, and RSV14 pins can be connected to directly ground (VSS) to save power. However, connecting these pins directly to ground will prevent boundary-scan from functioning on the RGMII pins of the EMAC. To preserve boundary-scan functionality on the RGMII pins, see Section 7.3.4. RSV14 F1 Reserved. This pin must be connected to the 1.5/1.8-V I/O supply (DVDD15) via a 200-Ω resistor for proper device operation. NOTE: If the RGMII mode of the EMAC is not used, the DVDD15, VREFHSTL, RSV13, and RSV14 pins can be connected to directly ground (VSS) to save power. However, connecting these pins directly to ground will prevent boundary-scan from functioning on the RGMII pins of the EMAC. To preserve boundary-scan functionality on the RGMII pins, see Section 7.3.4. RSV15 T1 Reserved. This pin must be connected via a 39-Ω resistor directly to ground (VSS) for proper device operation. The resistor used should have a minimal rating of 1/10 W. RSV16 T2 Reserved. This pin must be connected via a 20-Ω resistor directly to 3.3-V I/O Supply (DVDD33) for proper device operation. The resistor used should have a minimal rating of 1/10 W. RSV17 AE21 A RSV18 E13 A RSV19 F18 A RSV20 U29 A RSV13 RSV21 A6 A RSV22 B26 O RSV23 C26 O RSV24 B6 O RSV25 C6 O RSV26 AJ11 A RSV27 AH11 A RSV36 AD11 I/O/Z IPU RSV37 AD9 I/O/Z IPU RSV38 AG10 I/O/Z IPU RSV39 AG11 I/O/Z IPU RSV40 AJ12 I/O/Z IPU RSV41 W28 O/Z IPU RSV42 Y26 O/Z IPU RSV43 Y25 O/Z IPU RSV44 Y27 O/Z RSV28 N7 A RSV29 N6 A RSV30 P23 A RSV31 P24 A RSV32 D25 Reserved. This pin must be connected to the 1.8-V I/O supply (DVDD18) via a 1-kΩ resistor for proper device operation. RSV33 C25 Reserved. This pin must be connected directly to ground for proper device operation. RSV34 E6 Reserved. This pin must be connected to the 1.8-V I/O supply (DVDD18) via a 1-kΩ resistor for proper device operation. RSV35 D6 Reserved. This pin must be connected directly to ground for proper device operation. 40 Device Overview Reserved. (Leave unconnected, do not connect to power or ground.) Reserved. These pins must be connected directly to VSS for proper device operation. Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. TYPE (1) IPD/IPU (2) DESCRIPTION SUPPLY VOLTAGE MONITOR PINS CVDDMON DVDD33MON DVDD15MON DVDD18MON N1 Die-side 1.2-V core supply (CVDD) voltage monitor pin. The monitor pins indicate the voltage on the die and, therefore, provide the best probe point for voltage monitoring purposes. For more information regarding the use of this and other voltage monitoring pins, see the TMS320C6455 Design Guide and Comparisons to TMS320TC6416T application report (literature number SPRAA89). If the CVDDMON pin is not used, it should be connected directly to the 1.2-V core supply (CVDD). L6 Die-side 3.3-V I/O supply (DVDD33) voltage monitor pin. The monitor pins indicate the voltage on the die and, therefore, provide the best probe point for voltage monitoring purposes. For more information regarding the use of this and other voltage monitoring pins, see the TMS320C6455 Design Guide and Comparisons to TMS320TC6416T application report (literature number SPRAA89). If the DVDD33MON pin is not used, it should be connected directly to the 3.3-V I/O supply (DVDD33). F3 Die-side 1.5-/1.8-V I/O supply (DVDD15) voltage monitor pin. The monitor pins indicate the voltage on the die and, therefore, provide the best probe point for voltage monitoring purposes. For more information regarding the use of this and other voltage monitoring pins, see the TMS320C6455 Design Guide and Comparisons to TMS320TC6416T application report (literature number SPRAA89). If the DVDD15MON pin is not used, it should be connected directly to the 1.5-/1.8-V I/O supply (DVDD15). NOTE: If the RGMII mode of the EMAC is not used, the DVDD15, DVDD15MON, VREFHSTL, RSV13, and RSV14 pins can be connected directly to ground (VSS) to save power. However, connecting these pins directly to ground will prevent boundary-scan from functioning on the RGMII pins of the EMAC. To preserve boundary-scan functionality on the RGMII pins, see Section 7.3.4. I Die-side 1.8-V I/O supply (DVDD18) voltage monitor pin. The monitor pins indicate the voltage on the die and, therefore, provide the best probe point for voltage monitoring purposes. For more information regarding the use of this and other voltage monitoring pins, see the TMS320C6455 Design Guide and Comparisons to TMS320TC6416T application report (literature number SPRAA89). If the DVDD18MON pin is not used, it should be connected directly to the 1.8-V I/O supply (DVDD18). A26 SUPPLY VOLTAGE PINS VREFSSTL VREFHSTL DVDDR A (DVDD18/2)-V reference for SSTL buffer (DDR2 Memory Controller). This input voltage can be generated directly from DVDD18 using two 1-kΩ resistors to form a resistor divider circuit. NOTE: The DDR2 Memory Controller is not used, the VREFSSTL, RSV11, and RSV12 pins can be connected directly to ground (VSS) to save power. However, connecting these pins directly to ground will prevent boundary-scan from functioning on the DDR2 Memory Controller pins. To preserve boundary-scan functionality on the DDR2 Memory Controller pins, see Section 7.3.4. B2 A (DVDD15/2)-V reference for HSTL buffer (EMAC RGMII). VREFHSTL can be generated directly from DVDD15 using two 1-kΩ resistors to form a resistor divider circuit. NOTE: If the RGMII mode of the EMAC is not used, the DVDD15, VREFHSTL, RSV13, and RSV14 pins can be connected to directly ground (VSS) to save power. However, connecting these pins directly to ground will prevent boundary-scan from functioning on the RGMII pins of the EMAC. To preserve boundary-scan functionality on the RGMII pins, see Section 7.3.4. AD20 S 1.8-V I/O supply voltage (SRIO regulator supply). NOTE: If Rapid I/O is not used, this pin can be connected directly to VSS. A SRIO analog supply: 1.25-V I/O supply voltage (-1000 and -1200 devices) 1.2-V I/O supply voltage (-850 and -720 devices). Do not use core supply. NOTE: If Rapid I/O is not used, these pins can be connected directly to VSS. A 1.8-V I/O supply voltage. C14 AC15 AVDDA AC17 AD16 AVDLL1 A13 AVDLL2 E18 Submit Documentation Feedback Device Overview 41 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. TYPE (1) U16 DVDDRM V15 S S Main SRIO supply: 1.25-V I/O supply voltage (-1000 and -1200 devices) 1.2-V I/O supply voltage (-850 and -720 devices). Do not use core supply. NOTE: If RapidIO is not used, these pins can be connected directly to VSS. A SRIO termination supply: 1.25-V I/O supply voltage (-1000 and -1200 devices) 1.2-V I/O supply voltage (-850 and -720 devices). Do not use core supply. NOTE: If RapidIO is not used, these pins can be connected directly to VSS. S 1.8-V or 1.5-V I/O supply voltage for the RGMII function of the EMAC. NOTE: If the RGMII mode of the EMAC is not used, the DVDD15, VREFHSTL, RSV13, and RSV14 pins can be connected to directly ground (VSS) to save power. However, connecting these pins directly to ground will prevent boundary-scan from functioning on the RGMII pins of the EMAC. To preserve boundary-scan functionality on the RGMII pins, see Section 7.3.4. S 1.8-V I/O supply voltage (DDR2 Memory Controller) W16 W18 DESCRIPTION SRIO interface supply: 1.25-V core supply voltage (-1000 and -1200 devices) 1.2-V core supply voltage (-850 and -720 devices). The source for this supply voltage must be the same as that of CVDD. NOTE: If RapidIO is not used, these pins can be connected directly to VSS. V17 DVDD12 IPD/IPU (2) AE17 AE19 AE23 AVDDT AF20 AH20 AJ17 AJ23 A1 B5 D2 DVDD15 D5 F5 G6 H7 B8 B11 B20 B23 E10 E12 E22 E24 F7 F11 F13 F15 DVDD18 F17 F19 F23 G8 G10 G12 G14 G16 G18 G20 G22 G24 42 Device Overview Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. TYPE (1) IPD/IPU (2) DESCRIPTION A29 E26 E28 G2 H23 H28 J6 J24 K1 K7 K23 L24 M7 M23 M28 N24 P6 P28 R1 R6 R23 DVDD33 T7 S 3.3-V I/O supply voltage T24 U23 V1 V7 V24 W23 Y7 Y24 AA1 AA6 AA23 AB7 AB24 AC6 AC9 AC11 AC13 AC19 AC21 AC23 AC29 Submit Documentation Feedback Device Overview 43 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. TYPE (1) IPD/IPU (2) DESCRIPTION AD5 AD7 AD14 AD18 AD22 AD24 AE6 AE8 AE15 AF1 AF16 DVDD33 AF24 S 3.3-V I/O supply voltage S 1.25-V core supply voltage (-1000 and -1200 devices) 1.2-V core supply voltage (-850 and -720 devices) AG12 AG17 AG23 AH14 AH16 AH24 AJ1 AJ7 AJ15 AJ25 AJ29 L12 L14 L16 L18 M11 M13 M15 M17 M19 N12 CVDD N14 N16 N18 P13 P15 P17 P19 R12 R14 R16 44 Device Overview Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. TYPE (1) IPD/IPU (2) DESCRIPTION R18 T11 T13 T15 T17 T19 CVDD U12 U14 S 1.25-V core supply voltage (-1000 and -1200 devices) 1.2-V core supply voltage (-850 and -720 devices) U18 V11 V13 V19 W12 W14 GROUND PINS A8 A11 A20 A23 B1 B29 C5 D1 E5 VSS E7 E19 GND Ground pins E25 E29 F4 F6 F8 F10 F12 F14 F16 Submit Documentation Feedback Device Overview 45 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. TYPE (1) IPD/IPU (2) DESCRIPTION F20 F22 F24 G1 G5 G7 G9 G11 G13 G15 G17 G19 G21 G23 H6 H24 VSS H29 GND Ground pins J7 J23 K2 K6 K24 L7 L11 L13 L15 L17 L19 L23 M6 M12 M14 46 Device Overview Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. TYPE (1) IPD/IPU (2) DESCRIPTION M16 M18 M24 M26 M29 N2 N13 N15 N17 N19 N23 P7 P12 P14 P16 P18 VSS P29 R2 GND Ground pins R7 R11 R13 R15 R17 R19 R24 T6 T12 T14 T16 T18 T23 U7 U11 U13 Submit Documentation Feedback Device Overview 47 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. TYPE (1) IPD/IPU (2) DESCRIPTION U15 U17 U19 U24 V2 V6 V12 V14 V16 V18 V23 W7 W11 W13 W15 W17 VSS W19 GND Ground pins W24 Y6 Y23 AA2 AA7 AA24 AB6 AB23 AC7 AC8 AC10 AC12 AC14 AC16 AC18 48 Device Overview Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 2-3. Terminal Functions (continued) SIGNAL NAME NO. TYPE (1) IPD/IPU (2) DESCRIPTION AC20 AC22 AC24 AC28 AD6 AD13 AD15 AD17 AD19 AD21 AD23 AE4 AE7 AE16 AE18 AE20 AE22 VSS AE24 AF2 GND Ground pins AF19 AF21 AG13 AG16 AG20 AG24 AH1 AH15 AH19 AH21 AH25 AH29 AJ8 AJ14 AJ16 AJ20 AJ24 Submit Documentation Feedback Device Overview 49 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 2.8 Development 2.8.1 Development Support In case the customer would like to develop their own features and software on the C6455 device, TI offers an extensive line of development tools for the TMS320C6000™ DSP platform, including tools to evaluate the performance of the processors, generate code, develop algorithm implementations, and fully integrate and debug software and hardware modules. The tool's support documentation is electronically available within the Code Composer Studio™ Integrated Development Environment (IDE). The following products support development of C6000™ DSP-based applications: Software Development Tools: Code Composer Studio™ Integrated Development Environment (IDE): including Editor C/C++/Assembly Code Generation, and Debug plus additional development tools Scalable, Real-Time Foundation Software (DSP/BIOS™), which provides the basic run-time target software needed to support any DSP application. Hardware Development Tools: Extended Development System (XDS™) Emulator (supports C6000™ DSP multiprocessor system debug) EVM (Evaluation Module) 2.8.2 Device Support 2.8.2.1 Device and Development-Support Tool Nomenclature To designate the stages in the product development cycle, TI assigns prefixes to the part numbers of all DSP devices and support tools. Each DSP commercial family member has one of three prefixes: TMX, TMP, or TMS (e.g., TMS320C6455ZTZ). Texas Instruments recommends two of three possible prefix designators for its support tools: TMDX and TMDS. These prefixes represent evolutionary stages of product development from engineering prototypes (TMX/TMDX) through fully qualified production devices/tools (TMS/TMDS). Device development evolutionary flow: TMX Experimental device that is not necessarily representative of the final device's electrical specifications TMP Final silicon die that conforms to the device's electrical specifications but has not completed quality and reliability verification TMS Fully qualified production device Support tool development evolutionary flow: TMDX Development-support product that has not yet completed Texas Instruments internal qualification testing. TMDS Fully qualified development-support product TMX and TMP devices and TMDX development-support tools are shipped with against the following disclaimer: "Developmental product is intended for internal evaluation purposes." TMS devices and TMDS development-support tools have been characterized fully, and the quality and reliability of the device have been demonstrated fully. TI's standard warranty applies. Predictions show that prototype devices (TMX or TMP) have a greater failure rate than the standard production devices. Texas Instruments recommends that these devices not be used in any production system because their expected end-use failure rate still is undefined. Only qualified production devices are to be used. 50 Device Overview Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 TI device nomenclature also includes a suffix with the device family name. This suffix indicates the package type (for example, ZTZ), the temperature range (for example, blank is the default commercial temperature range), and the device speed range, in megahertz (for example, blank is 1000 MHz [1 GHz]). Figure 2-13 provides a legend for reading the complete device name for any TMS320C64x+™ DSP generation member. For device part numbers and further ordering information for TMS320C6455 in the ZTZ/GTZ package type, see the TI website (www.ti.com) or contact your TI sales representative. TMS 320 PREFIX TMX = Experimental device TMS = Qualified device DEVICE FAMILY 320 = TMS320 DSP family C6455 B ZTZ ( ) 2 DEVICE SPEED RANGE 7 = 720 MHz 8 = 850 MHz Blank = 1 GHz 2 = 1.2 GHz (A) TEMPERATURE RANGE Blank = 0°C to 90°C (default commercial temperature) A = -40°C to 105°C (extended temperature) (B) DEVICE C64x+ DSP: C6455 PACKAGE TYPE ZTZ = 697-pin plastic BGA, with Pb-Free solder balls GTZ = 697-pin plastic BGA with Pb-ed solder balls SILICON REVISION Blank = Initial Silicon 1.1 B = Silicon 2.0 A. The extended temperature "A version" devices may have different operating conditions than the commercial temperature devices. For more details, see the Recommended Operating Conditions section of this document. B. BGA = Ball Grid Array Figure 2-13. TMS320C64x+™ DSP Device Nomenclature (including the TMS320C6455 DSP) 2.8.2.2 Documentation Support The following documents describe the TMS320C6455 Fixed-Point Digital Signal Processor. Copies of these documents are available on the Internet at www.ti.com. Tip: Enter the literature number in the search box provided at www.ti.com. The current documentation that describes the TMS320C6455, related peripherals, and other technical collateral, is available in the C6000 DSP product folder at: www.ti.com/c6000. SPRU732 TMS320C64x/C64x+ DSP CPU and Instruction Set Reference Guide. Describes the CPU architecture, pipeline, instruction set, and interrupts for the TMS320C64x and TMS320C64x+ digital signal processors (DSPs) of the TMS320C6000 DSP family. The C64x/C64x+ DSP generation comprises fixed-point devices in the C6000 DSP platform. The C64x+ DSP is an enhancement of the C64x DSP with added functionality and an expanded instruction set. SPRU871 TMS320C64x+ DSP Megamodule Reference Guide. Describes the TMS320C64x+ digital signal processor (DSP) megamodule. Included is a discussion on the internal direct memory access (IDMA) controller, the interrupt controller, the power-down controller, memory protection, bandwidth management, and the memory and cache. SPRU965 TMS320C6455 Technical Reference. An introduction to the TMS320C6455 DSP and discusses the application areas that are enhanced. SPRAA84 TMS320C64x to TMS320C64x+ CPU Migration Guide. Describes migrating from the Texas Instruments TMS320C64x digital signal processor (DSP) to the TMS320C64x+ DSP. The objective of this document is to indicate differences between the two cores. Functionality in the devices that is identical is not included. SPRU889 High-Speed DSP Systems Design Reference Guide. Provides recommendations for meeting the many challenges of high-speed DSP system design. These recommendations include information about DSP audio, video, and communications systems for the C5000 and Submit Documentation Feedback Device Overview 51 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 C6000 DSP platforms. 52 SPRU970 TMS320C645x DSP DDR2 Memory Controller User's Guide. This document describes the DDR2 memory controller in the TMS320C645x digital-signal processors (DSPs). SPRU966 TMS320C645x DSP Enhanced DMA (EDMA3) Controller User's Guide. This document describes the Enhanced DMA (EDMA3) Controller on the TMS320C645x device. SPRU975 TMS320C645x DSP EMAC/MDIO Module User's Guide. This document provides a functional description of the Ethernet Media Access Controller (EMAC) and Physical layer (PHY) device Management Data Input/Output (MDIO) module integrated with the devices of the TMS320C645x family. SPRU971 TMS320C645x DSP External Memory Interface (EMIF) User's Guide. This document describes the operation of the external memory interface (EMIF) in the digital signal processors (DSPs) of the TMS320C645x DSP family. SPRU724 TMS320C645x DSP General-Purpose Input/Output (GPIO) User's Guide. This document describes the general-purpose input/output (GPIO) peripheral in the digital signal processors (DSPs) of the TMS320C645x DSP family. The GPIO peripheral provides dedicated general-purpose pins that can be configured as either inputs or outputs. When configured as an input, you can detect the state of the input by reading the state of an internal register. When configured as an output, you can write to an internal register to control the state driven on the output pin. SPRU969 TMS320C645x DSP Host Port Interface (HPI) User's Guide. This guide describes the host port interface (HPI) on the TMS320C645x digital signal processors (DSPs). The HPI enables an external host processor (host) to directly access DSP resources (including internal and external memory) using a 16-bit (HPI16) or 32-bit (HPI32) interface. SPRU974 TMS320C645x DSP Inter-Integrated Circuit (I2C) Module User's Guide. This document describes the inter-integrated circuit (I2C) module in the TMS320C645x Digital Signal Processor (DSP). The I2C provides an interface between the TMS320C645x device and other devices compliant with Philips Semiconductors Inter-IC bus (I2C-bus) specification version 2.1 and connected by way of an I2C-bus. This document assumes the reader is familiar with the I2C-bus specification. SPRUE60 TMS320C645x DSP Peripheral Component Interconnect (PCI) User's Guide. This document describes the peripheral component interconnect (PCI) port in TMS320C645x devices. See the PCI Specification revision 2.3 for details on the PCI interface. SPRU976 TMS320C645x DSP Serial Rapid I/O User's Guide. This document describes the Serial Rapid IO (SRIO) on the TMS320C645x devices. SPRUE56 TMS320C645x DSP Software-Programmable Phase-Locked Loop (PLL) Controller User's Guide. This document describes the operation of the software-programmable phase-locked loop (PLL) controller in the TMS320C645x digital signal processors (DSPs). The PLL controller offers flexibility and convenience by way of software-configurable multipliers and dividers to modify the input signal internally. The resulting clock outputs are passed to the TMS320C645x DSP core, peripherals, and other modules inside the TMS320C645x DSP. SPRU968 TMS320C645x DSP 64-Bit Timer User's Guide. This document provides an overview of the 64-bit timer in the TMS320C645x DSP. The timer can be configured as a general-purpose 64-bit timer, dual general-purpose 32-bit timers, or a watchdog timer. When configured as a dual 32-bit timers, each half can operate in conjunction (chain mode) or independently (unchained mode) of each other. SPRU973 TMS320C645x DSP Turbo-Decoder Coprocessor (TCP) User's Guide. Channel decoding of high bit-rate data channels found in third generation (3G) cellular standards requires Device Overview Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 decoding of turbo-encoded data. The turbo-decoder coprocessor (TCP) in some of the digital signal processor (DSPs) of the TMS320C6000™ DSP family has been designed to perform this operation for IS2000 and 3GPP wireless standards. This document describes the operation and programming of the TCP. SPRUE48 TMS320C645x DSP Universal Test & Operations PHY Interface for ATM 2 (UTOPIA2) User's Guide. This document describes the universal test and operations PHY interface for asynchronous transfer mode (ATM) 2 (UTOPIA2) in the TMS320C645x digital signal processors (DSPs) of the TMS320C6000™ DSP family. SPRU972 TMS320C645x DSP Viterbi-Decoder Coprocessor (VCP) User's Guide. Channel decoding of voice and low bit-rate data channels found in third generation (3G) cellular standards requires decoding of convolutional encoded data. The Viterbi-decoder coprocessor 2 (VCP2) provided in C645x devices has been designed to perform Viterbi-Decoding for IS2000 and 3GPP wireless standards. The VCP2 coprocessor has been designed to perform forward error correction for 2G and 3G wireless systems. The VCP2 coprocessor offers a very cost effective and synergistic solution when combined with Texas Instruments (TI) DSPs. The VCP2 can support 1941 12.2 Kbps class A 3G voice channels running at 333 MHZ. This document describes the operation and programming of the VCP2. Submit Documentation Feedback Device Overview 53 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 3 Device Configuration On the C6455 device, certain device configurations like boot mode, pin multiplexing, and endianess, are selected at device reset. The status of the peripherals (enabled/disabled) is determined after device reset. By default, the peripherals on the C6455 device are disabled and need to be enabled by software before being used. 3.1 Device Configuration at Device Reset Table 3-1 describes the C6455 device configuration pins. The logic level of the AEA[19:0], ABA[1:0], and PCI_EN pins is latched at reset to determine the device configuration. The logic level on the device configuration pins can be set by using external pullup/pulldown resistors or by using some control device (e.g., FPGA/CPLD) to intelligently drive these pins. When using a control device, care should be taken to ensure there is no contention on the lines when the device is out of reset. The device configuration pins are sampled during reset and are driven after the reset is removed. To avoid contention, the control device should only drive the EMIFA pins when RESETSTAT is low. NOTE If a configuration pin must be routed out from the device and 3-stated (not driven), internal pullup/pulldown (IPU/IPD) resistor should not be relied upon; TI recommends use of an external pullup/pulldown resistor. For more detailed information pullup/pulldown resistors and situations where external pullup/pulldown resistors required, see Section 3.7, Pullup/Pulldown Resistors. the the on are Table 3-1. C6455 Device Configuration Pins (AEA[19:0], ABA[1:0], and PCI_EN) CONFIGURATION PIN NO. IPD/ IPU (1) FUNCTIONAL DESCRIPTION Boot Mode Selections (BOOTMODE [3:0]). These pins select the boot mode for the device. AEA[19:16] [N25, L26, L25, P26] IPD 0000 No boot (default mode) 0001 Host boot (HPI) 0010 Reserved 0011 Reserved 0100 EMIFA 8-bit ROM boot 0101 Master I2C boot 0110 Slave I2C boot 0111 Host boot (PCI) 1000 thru Serial Rapid I/O boot configurations 1111 If selected for boot, the corresponding peripheral is automatically enabled after device reset. For more detailed information on boot modes, see Section 2.4, Boot Sequence. CFGGP[2:0] pins must be set to 000b during reset for proper operation of the PCI boot mode. EMIFA input clock source select (AECLKIN_SEL). AEA15 (1) 54 P27 IPD 0 AECLKIN (default mode) 1 SYSCLK4 (CPU/x) Clock Rate. The SYSCLK4 clock rate is software selectable via the Software PLL1 Controller. By default, SYSCLK4 is selected as CPU/8 clock rate. IPD = Internal pulldown, IPU = Internal pullup. For most systems, a 1-kΩ resistor can be used to oppose the IPU/IPD. For more detailed information on pullup/pulldown resistors and situations where external pullup/pulldown resistors are required, see Section 3.7, Pullup/Pulldown Resistors. Device Configuration Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 3-1. C6455 Device Configuration Pins (AEA[19:0], ABA[1:0], and PCI_EN) (continued) CONFIGURATION PIN NO. IPD/ IPU (1) FUNCTIONAL DESCRIPTION HPI peripheral bus width select (HPI_WIDTH). AEA14 R25 0 HPI operates in HPI16 mode (default). HPI bus is 16 bits wide; HD[15:0] pins are used and the remaining HD[31:16] pins are reserved pins in the Hi-Z state. 1 HPI operates in HPI32 mode. HPI bus is 32 bits wide; HD[31:0] pins are used. IPD Applies only when HPI function of HPI/PCI multiplexed pins is selected (PCI_EN pin = 0). Device Endian mode (LENDIAN). AEA13 R27 IPU 0 System operates in Big Endian mode. 1 System operates in Little Endian mode (default). UTOPIA pin function enable bit (UTOPIA_EN). This pin selects the function of the UTOPIA/EMAC and UTOPIA/MDIO multiplexed pins. AEA12 AEA11 R28 T25 0 UTOPIA pin function disabled; EMAC and MDIO pin function enabled (default). This means all multiplexed UTOPIA/EMAC and UTOPIA/MDIO pins function as EMAC and MDIO pins. The interface used by EMAC/MDIO (MII, RMII, GMII or the standalone RGMII) is controlled by the MACSEL[1:0] pins (AEA[10:9]). 1 UTOPIA pin function enabled; EMAC and MDIO pin function disabled. This means all multiplexed UTOPIA/EMAC and UTOPIA/MDIO pins now function as UTOPIA. The EMAC/MDIO peripheral can still be used with RGMII (MACSEL[1:0] = 11). IPD IPD For proper C6455 device operation, this pin must be externally pulled up with a 1-kΩ resistor at device reset. EMAC Interface Selects (MACSEL[1:0]). These pins select the interface used by the EMAC/MDIO peripheral. AEA[10:9] [M25, M27] IPD 00 10/100 EMAC/MDIO with MII Interface [default] 01 10/100 EMAC/MDIO with RMII Interface 10 10/100/1000 EMAC/MDIO with GMII Interface 11 10/100/1000 EMAC/MDIO with RGMII Interface If the UTOPIA pin function is selected [UTOPIA_EN (AEA12 pin) = 1] for multiplexed UTOPIA/EMAC and UTOPIA/MDIO pins, the EMAC/MDIO peripheral can only be used with RGMII. For more detailed information on the UTOPIA_EN and MAC_SEL[1:0] control pin selections, see Table 3-3. PCI I2C EEPROM Auto-Initialization (PCI_EEAI). PCI auto-initialization via external I2C EEPROM AEA8 P25 IPD 0 PCI auto-initialization through external I2C EEPROM is disabled. The PCI peripheral uses the specified PCI default values (default). 1 PCI auto-initialization through external I2C EEPROM is enabled. The PCI peripheral is configured through external I2C EEPROM provided the PCI peripheral pins are enabled (PCI_EN = 1). Note: If the PCI pin function is disabled (PCI_EN pin = 0), this pin must not be pulled up. AEA7 N27 IPD For proper C6455 device operation, do not oppose the IPD on this pin. PCI Frequency Selection (PCI66). Selects the operating frequency of the PCI (either 33 MHz or 66 MHz). AEA6 U27 IPD 0 PCI operates at 33 MHz (default) 1 PCI operates at 66 MHz Note: If the PCI pin function is disabled (PCI_EN pin = 0), this pin must not be pulled up. McBSP1 pin function enable bit (MCBSP1_EN). Selects which function is enabled on the McBSP1/GPIO multiplexed pins. AEA5 U28 Submit Documentation Feedback IPD 0 GPIO pin function enabled (default). This means all multiplexed McBSP1/GPIO pins function as GPIO pins. 1 McBSP1 pin function enabled. This means all multiplexed McBSP1/GPIO pins function as McBSP1 pins. Device Configuration 55 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 3-1. C6455 Device Configuration Pins (AEA[19:0], ABA[1:0], and PCI_EN) (continued) CONFIGURATION PIN NO. IPD/ IPU (1) FUNCTIONAL DESCRIPTION SYSCLKOUT Enable bit (SYSCLKOUT_EN). Selects which function is enabled on the SYSCLK4/GP[1] muxed pin. AEA4 T28 IPD 0 GP[1] pin function is enabled (default) 1 SYSCLK4 pin function is enabled AEA3 T27 IPD For proper C6455 device operation, the AEA3 pin must be pulled up at device reset using a 1-kΩ resistor if power is applied to the SRIO supply pins. If the SRIO peripheral is not used and the SRIO supply pins are connected to VSS, the AEA3 pin must be pulled down to VSS using a 1-kΩ resistor. AEA[2:0] [T26, U26, U25] IPD Configuration General-Purpose Inputs (CFGGP[2:0]) The value of these pins is latched to the Device Status Register following device reset and is used by the on-chip bootloader for some boot modes. For more information on the boot modes, see Section 2.4, Boot Sequence. PCI pin function enable bit (PCI_EN). Selects which function is enabled on the HPI/PCI and the PCI/UTOPIA multiplexed pins. PCI_EN Y29 0 HPI and UTOPIA pin function enabled (default) This means all multiplexed HPI/PCI and PCI/UTOPIA pins function as HPI and UTOPIA pins, respectively. 1 PCI pin function enabled This means all multiplexed HPI/PCI and PCI/UTOPIA pins function as PCI pins. IPD DDR2 Memory Controller enable (DDR2_EN). ABA0 V26 IPD 0 DDR2 Memory Controller peripheral pins are disabled (default) 1 DDR2 Memory Controller peripheral pins are enabled EMIFA enable (EMIFA_EN). ABA1 V25 IPD 0 EMIFA peripheral pins are disabled (default) 1 EMIFA peripheral pins are enabled 3.2 Peripheral Configuration at Device Reset Some C6455 peripherals share the same pins (internally multiplexed) and are mutually exclusive. Therefore, not all peripherals may be used at the same time. The device configuration pins described in Section 3.1, Device Configuration at Device Reset, determine which function is enabled for the multiplexed pins. Note that when the pin function of a peripheral is disabled at device reset, the peripheral is permanently disabled and cannot be enabled until its pin function is enabled and another device reset is executed. Also, note that enabling the pin function of a peripheral does not enable the corresponding peripheral. All peripherals on the C6455 device are disabled by default, except when used for boot, and must be enabled through software before being used. Other peripheral options like PCI clock speed and EMAC/MDIO interface mode can also be selected at device reset through the device configuration pins. The configuration selected is also fixed at device reset and cannot be changed until another device reset is executed with a different configuration selected. The multiply factor of the PLL1 Controller is not selected through the configuration pins. The PLL1 multiply factor is set in software through the PLL1 controller registers after device reset. The PLL2 multiply factor is fixed. For more information, see Section 7.7, PLL1 and PLL1 Controller, and Section 7.8, PLL2 and PLL2 Controller. On the C6455 device, the PCI peripheral pins are multiplexed with the HPI pins and partially multiplexed with the UTOPIA pins. The PCI_EN pin selects the function for the HPI/PCI multiplexed pins. The PCI66, PCI_EEAI, and HPI_WIDTH control other functions of the PCI and HPI peripherals. Table 3-2 describes the effect of the PCI_EN, PCI66, PCI_EEAI, and HPI_WIDTH configuration pins. 56 Device Configuration Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 3-2. PCI_EN, PCI66, PCI_EEAI, and HPI_WIDTH Peripheral Selection (HPI and PCI) CONFIGURATION PIN SETTING (1) PERIPHERAL FUNCTION SELECTED PCI_EN PIN [Y29] PCI66 AEA6 PIN [U27] PCI_EEAI AEA8 PIN [P25] (1) HPI_WIDTH AEA14 PIN [R25] HPI DATA LOWER 0 0 0 0 0 0 0 1 1 1 1 X Disabled 1 1 0 X Disabled Disabled 1 0 0 X Disabled Disabled (default values) 1 (1) 0 1 HPI DATA UPPER 32-BIT PCI (66-/33-MHz) PCI AUTO-INIT Enabled Hi-Z Disabled N/A Enabled Enabled Disabled N/A Enabled (66 MHz) Enabled (via External I2C EEPROM) X Disabled Enabled (33 MHz) Enabled (via External I2C EEPROM) PCI_EEAI is latched at reset as a configuration input. If PCI_EEAI is set as one, then default values are loaded from an external I2C EEPROM. The UTOPIA and EMAC/MDIO pins are also multiplexed on the C6455 device. The UTOPIA_EN function (AEA12 pin) controls the function of these multiplexed pins. The MAC_SEL[1:0] configuration pins (AEA[10:9) control which interface is used by the EMAC/MDIO. Note that since the PCI shares some pins with the UTOPIA peripheral, its state also affects the operation of the UTOPIA. Table 3-3 describes the effect of the UTOPIA_EN, PCI_EN, and MACSEL[1:0] configuration pins. Table 3-3. UTOPIA_EN, and MAC_SEL[1:0] Peripheral Selection (UTOPIA and EMAC) CONFIGURATION PIN SETTING PERIPHERAL FUNCTION SELECTED UTOPIA_EN AEA12 PIN [R28] PCI_EN PIN [Y29] MAC_SEL[1:0] AEA[10:9] PINS [M25, M27] 0 x 00b 10/100 EMAC/MDIO with MII Interface [default] Disabled 0 x 01b 10/100 EMAC/MDIO with RMII Interface Disabled 0 x 10b 10/100/1000 EMAC/MDIO with GMII Interface Disabled 0 x 11b 10/100/1000 EMAC/MDIO with RGMII Interface (1) Disabled 1 0 00b, 01b, or 10b Disabled UTOPIA Slave with Full Functionality 1 0 11b 10/100/1000 EMAC/MDIO with RGMII Interface (1) UTOPIA Slave with Full Functionality 1 1 00b, 01b, or 10b Disabled UTOPIA Slave with Single PHY Mode Only 1 1 11b 10/100/1000 EMAC/MDIO with RGMII Interface (1) UTOPIA Slave with Single PHY Mode Only (1) EMAC/MDIO UTOPIA RGMII interface requires a 1.5-/1.8-V I/O supply. Submit Documentation Feedback Device Configuration 57 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 3.3 Peripheral Selection After Device Reset On the C6455 device, peripherals can be in one of several states. These states are listed in Table 3-4. Table 3-4. Peripheral States STATE DESCRIPTION PERIPHERALS THAT CAN BE IN THIS STATE Peripheral pin function has been completely disabled through the device configuration pins. Peripheral is held in reset and clock is turned off. HPI PCI McBSP1 UTOPIA EMAC/MDIO EMIFA DDR2 Memory Controller Peripheral is held in reset and clock is turned off. Default state for all peripherals not in static powerdown mode. TCP VCP I2C Timer 0 Timer 1 GPIO EMAC/MDIO McBSP0 McBSP1 HPI PCI UTOPIA Enabled Clock to the peripheral is turned on and the peripheral is taken out of reset. TCP VCP I2C Timer 0 Timer 1 GPIO MDIO EMAC/MDIO McBSP0 McBSP1 HPI PCI UTOPIA EMIFA DDR2 Memory Controller Enable in progress Not a user-programmable state. This is an intermediate state when transitioning from an disabled state to an enabled state. All peripherals that can be in an enabled state. Static powerdown Disabled Following device reset, all peripherals that are not in the static powerdown state are in the disabled state by default. Peripherals used for boot such as HPI and PCI are enabled automatically following a device reset. Peripherals are only allowed certain transitions between states (see Figure 3-1). 58 Device Configuration Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Static Powerdown Reset Enable In Progress Disabled Enabled Figure 3-1. Peripheral Transitions Between States Figure 3-2 shows the flow needed to change the state of a given peripheral on the C6455 device. Unlock the PERCFG0 register by using the PERLOCK register. Write to the PERCFG0 register within 16 SYSCLK3 clock cycles to change the state of the peripherals. Poll the PERSTAT registers to verify state change. Figure 3-2. Peripheral State Change Flow A 32-bit key (value = 0x0F0A 0B00) must be written to the Peripheral Lock register (PERLOCK) in order to allow access to the PERCFG0 register. Writes to the PERCFG1 register can be done directly without going through the PERLOCK register. NOTE The instructions that write to the PERLOCK and PERCFG0 registers must be in the same fetch packet if code is being executed from external memory. If the instructions are in different fetch packets, fetching the second instruction from external memory may stall the instruction long enough such that PERCFG0 register will be locked before the instruction is executed. Submit Documentation Feedback Device Configuration 59 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 3.4 Device State Control Registers The C6455 device has a set of registers that are used to control the status of its peripherals. These registers are shown in Table 3-5 and described in the next sections. NOTE The device state control registers can only be accessed using the CPU or the emulator. Table 3-5. Device State Control Registers 60 HEX ADDRESS RANGE ACRONYM 02AC 0000 - REGISTER NAME 02AC 0004 PERLOCK Peripheral Lock Register Peripheral Configuration Register 0 Reserved 02AC 0008 PERCFG0 02AC 000C - Reserved 02AC 0010 - Reserved 02AC 0014 PERSTAT0 Peripheral Status Register 0 02AC 0018 PERSTAT1 Peripheral Status Register 1 02AC 001C - 02AC 001F - 02AC 0020 EMACCFG 02AC 0024 - 02AC 002B - 02AC 002C PERCFG1 02AC 0030 - 02AC 0053 - 02AC 0054 EMUBUFPD 02AC 0058 - Device Configuration Reserved EMAC Configuration Register Reserved Peripheral Configuration Register 1 Reserved Emulator Buffer Powerdown Register Reserved Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 3.4.1 Peripheral Lock Register Description When written with correct 32-bit key (0x0F0A0B00), the Peripheral Lock Register (PERLOCK) allows one write to the PERCFG0 register within 16 SYSCLK3 cycles. NOTE The instructions that write to the PERLOCK and PERCFG0 registers must be in the same fetch packet if code is being executed from external memory. If the instructions are in different fetch packets, fetching the second instruction from external memory may stall the instruction long enough such that PERCFG0 register will be locked before the instruction is executed. 31 0 LOCKVAL R/W-F0F0 F0F0 LEGEND: R/W = Read/Write; -n = value after reset Figure 3-3. Peripheral Lock Register (PERLOCK) - 0x02AC 0004 Table 3-6. Peripheral Lock Register (PERLOCK) Field Descriptions Bit 31:0 Field Value LOCKVAL Submit Documentation Feedback Description When programmed with 0x0F0A 0B00 allows one write to the PERCFG0 register within 16 SYSCLK3 clock cycles. Device Configuration 61 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 3.4.2 Peripheral Configuration Register 0 Description The Peripheral Configuration Register (PERCFG0) is used to change the state of the peripherals. One write is allowed to this register within 16 SYSCLK3 cycles after the correct key is written to the PERLOCK register. NOTE The instructions that write to the PERLOCK and PERCFG0 registers must be in the same fetch packet if code is being executed from external memory. If the instructions are in different fetch packets, fetching the second instruction from external memory may stall the instruction long enough such that PERCFG0 register will be locked before the instruction is executed. 31 30 29 24 SRIOCTL Reserved R/W-0 R/W-0 23 22 21 20 19 18 17 16 Reserved UTOPIACTL Reserved PCICTL Reserved HPICTL Reserved McBSP1CTL 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 Reserved McBSP0CTL Reserved I2CCTL Reserved GPIOCTL Reserved TIMER1CTL 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 Reserved TIMER0CTL Reserved EMACCTL Reserved VCPCTL Reserved TCPCTL R/W-0 R/W-0 R/W-0 R/W-0 R/W-0 R/W-0 R/W-0 R/W-0 LEGEND: R/W = Read/Write only; -n = value after reset Figure 3-4. Peripheral Configuration Register 0 (PERCFG0) - 0x02AC 0008 Table 3-7. Peripheral Configuration Register 0 (PERCFG0) Field Descriptions Bit 31-30 29:23 22 Value SRIOCTL Description Mode control for SRIO. SRIO does not have a corresponding status bit in the Peripheral Status Registers. Once SRIOCTL is set to 11b, the SRIO peripheral can be used within 16 SYSCLK3 cycles. 00b Set SRIO to disabled mode 11b Set SRIO to enabled mode Reserved Reserved. UTOPIACTL Mode control for UTOPIA 0 Set UTOPIA to disabled mode 1 Set UTOPIA to enabled mode 21 Reserved Reserved. 20 PCICTL Mode control for PCI. This bit defaults to 1 when Host boot is used (BOOTMODE[3:0] = 0111b). 19 Reserved 18 HPICTL 17 62 Field Reserved Device Configuration 0 Set PCI to disabled mode 1 Set PCI to enabled mode Reserved. Mode control for HPI. This bit defaults to 1 when Host boot is used (BOOTMODE[3:0] = 0001b). 0 Set HPI to disabled mode 1 Set HPI to enabled mode 1 Reserved. Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 3-7. Peripheral Configuration Register 0 (PERCFG0) Field Descriptions (continued) Bit Field 16 McBSP1CTL Value Description Mode control for McBSP1 0 Set McBSP1 to disabled mode 1 Set McBSP1 to enabled mode 15 Reserved Reserved. 14 McBSP0CTL Mode control for McBSP0 0 Set McBSP0 to disabled mode 1 Set McBSP0 to enabled mode 13 Reserved Reserved. 12 I2CCTL Mode control for I2C 11 Reserved 10 GPIOCTL 9 Reserved 8 TIMER1CTL 7 Reserved 6 TIMER0CTL 0 Set I2C to disabled mode 1 Set I2C to enabled mode Reserved. Mode control for GPIO 0 Set GPIO to disabled mode 1 Set GPIO to enabled mode Reserved. Mode control for Timer 1 0 Set Timer 1 to disabled mode 1 Set Timer 1 to enabled mode Reserved. Mode control for Timer 0 0 Set Timer 0 to disabled mode 1 Set Timer 0 to enabled mode 5 Reserved Reserved. 4 EMACCTL Mode control for EMAC/MDIO 0 Set EMAC/MDIO to disabled mode 1 Set EMAC/MDIO to enabled mode 3 Reserved Reserved. 2 VCPCTL Mode control for VCP 1 Reserved 0 TCPCTL Submit Documentation Feedback 0 Set VCP to disabled mode 1 Set VCP to enabled mode Reserved. Mode control for TCP 0 Set TCP to disabled mode 1 Set TCP to enabled mode Device Configuration 63 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 3.4.3 Peripheral Configuration Register 1 Description The Peripheral Configuration Register (PERCFG1) is used to enable the EMIFA and DDR2 Memory Controller. EMIFA and the DDR2 Memory Controller do not have corresponding status bits in the Peripheral Status Registers. The EMIFA and DDR2 Memory Controller peripherals can be used within 16 SYSCLK3 cycles after EMIFACTL and DDR2CTL are set to 1. Once EMIFACTL and DDR2CTL are set to 1, they cannot be set to 0. Note that if the DDR2 Memory Controller and EMIFA are disabled at reset through the device configuration pins (DDR2.EN[ABA0] and EMIFA[ABA1]), they cannot be enabled through the PERCFG1 register. 31 8 Reserved R-0x00 7 2 1 0 Reserved DDR2CTL EMIFACTL R-0x00 R/W-0 R/W-0 LEGEND: R/W = Read/Write; R = Read only; -n = value after reset Figure 3-5. Peripheral Configuration Register 1 (PERCFG1) - 0x02AC 002C Table 3-8. Peripheral Configuration Register 1 (PERCFG1) Field Descriptions Bit Value Description Reserved Reserved. 1 DDR2CTL Mode Control for DDR2 Memory Controller. Once this bit is set to 1, it cannot be changed to 0. 0 64 Field 31:2 0 Set DDR2 to disabled 1 Set DDR2 to enabled EMIFACTL Device Configuration Mode control for EMIFA. Once this bit is set to 1, it cannot be changed to 0. This bit defaults to 1 if EMIFA 8-bit ROM boot is used (BOOTMODE[3:0] = 0100b). 0 Set EMIFA to disabled 1 Set EMIFA to enabled Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 3.4.4 Peripheral Status Registers Description The Peripheral Status Registers (PERSTAT0 and PERSTAT1) show the status of the C6455 peripherals. 31 30 29 27 26 24 Reserved HPISTAT McBSP1STAT R-0 R-0 R-0 23 21 20 18 17 16 McBSP0STAT I2CSTAT GPIOSTAT R-0 R-0 R-0 15 14 12 11 9 8 GPIOSTAT TIMER1STAT TIMER0STAT EMACSTAT R-0 R-0 R-0 R-0 2 0 7 6 5 3 EMACSTAT VCPSTAT TCPSTAT R-0 R-0 R-0 LEGEND: R = Read only; -n = value after reset Figure 3-6. Peripheral Status Register 0 (PERSTAT0) - 0x02AC 0014 Table 3-9. Peripheral Status Register 0 (PERSTAT0) Field Descriptions Bit Field Value Description 31:30 Reserved Reserved. 29:27 HPISTAT HPI status 000 HPI is in the disabled state 001 HPI is in the enabled state 011 HPI is in the static powerdown state 101 HPI is in the enable in progress state Others 26:24 McBSP1STAT McBSP1 status 000 McBSP1 is in the disabled state 001 McBSP1 is in the enabled state 011 McBSP1 is in the static powerdown state 101 McBSP1 is in the enable in progress state Others 23:21 McBSP0STAT Reserved McBSP0 status 000 McBSP0 is in the disabled state 001 McBSP0 is in the enabled state 011 McBSP0 is in the static powerdown state 101 McBSP0 is in the enable in progress state Others 20:18 Reserved I2CSTAT Reserved I2C status 000 I2C is in the disabled state 001 I2C is in the enabled state 011 I2C is in the static powerdown state 101 I2C is in the enable in progress state Others Submit Documentation Feedback Reserved Device Configuration 65 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 3-9. Peripheral Status Register 0 (PERSTAT0) Field Descriptions (continued) Bit 17:15 Field Value GPIOSTAT GPIO status 000 GPIO is in the disabled state 001 GPIO is in the enabled state 011 GPIO is in the static powerdown state 101 GPIO is in the enable in progress state Others 14:12 TIMER1STAT Timer1 status Timer1 is in the disabled state 001 Timer1 is in the enabled state 011 Timer1 is in the static powerdown state 101 Timer1 is in the enable in progress state TIMER0STAT Timer0 status Timer0 is in the disabled state 001 Timer0 is in the enabled state 011 Timer0 is in the static powerdown state 101 Timer0 is in the enable in progress state EMACSTAT 000 EMAC/MDIO is in the disabled state 001 EMAC/MDIO is in the enabled state 011 EMAC/MDIO is in the static powerdown state 101 EMAC/MDIO is in the enable in progress state VCPSTAT 000 VCP is in the disabled state 001 VCP is in the enabled state 011 VCP is in the static powerdown state 101 VCP is in the enable in progress state TCPSTAT Device Configuration Reserved TCP status 000 TCP is in the disabled state 001 TCP is in the enabled state 011 TCP is in the static powerdown state 101 TCP is in the enable in progress state Others 66 Reserved VCP status Others 2:0 Reserved EMAC/MDIO status Others 5:3 Reserved 000 Others 8:6 Reserved 000 Others 11:9 Description Reserved Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 31 16 Reserved R-0 15 6 5 3 2 0 Reserved UTOPIASTAT PCISTAT R-0 R-0 R-0 LEGEND: R = Read only; -n = value after reset Figure 3-7. Peripheral Status Register 1 (PERSTAT1) - 0x02AC 0018 Table 3-10. Peripheral Status Register 1 (PERSTAT1) Field Descriptions Bit Field Value Description 31:6 Reserved Reserved. 5:3 UTOPIASTAT UTOPIA status 000 UTOPIA is in the disabled state 001 UTOPIA is in the enabled state 011 UTOPIA is in the static powerdown state 101 UTOPIA is in the enable in progress state Others 2:0 PCISTAT Reserved PCI status 000 PCI is in the disabled state 001 PCI is in the enabled state 011 PCI is in the static powerdown state 101 PCI is in the enable in progress state Others Submit Documentation Feedback Reserved Device Configuration 67 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 3.4.5 EMAC Configuration Register (EMACCFG) Description The EMAC Configuration Register (EMACCFG) is used to assert and deassert the reset of the Reduced Media Independent Interface (RMII) logic of the EMAC. For more details on how to use this register, see Section 7.14, Ethernet MAC (EMAC). 31 24 Reserved R/W-0 23 19 18 17 16 Reserved RMII_RST Reserved R/W-0001b R/W-1 R/W-0 15 0 Reserved R/W-0 LEGEND: R/W = Read/Write; R = Read only; -n = value after reset Figure 3-8. EMAC Configuration Register (EMACCFG) - 0x02AC 0020 Table 3-11. EMAC Configuration Register (EMACCFG) Field Descriptions Bit Field Value Description 31:19 Reserved Reserved. Writes to this register must keep the default values of these bits. 18 RMII_RST RMII reset bit. This bit is used to reset the RMII logic of the EMAC. 17:0 68 Reserved Device Configuration 0 RMII logic reset is released. 1 RMII logic reset is asserted. Reserved. Writes to this register must keep this bit as 0. Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 3.4.6 Emulator Buffer Powerdown Register (EMUBUFPD) Description The Emulator Buffer Powerdown Register (EMUBUFPD) is used to control the state of the pin buffers of emulator pins EMU[18:2]. These buffers can be powered down if the device trace feature is not needed. 31 8 Reserved R-0 7 1 0 Reserved EMUCTL R-0 R/W-0 LEGEND: R/W = Read/Write; R = Read only; -n = value after reset Figure 3-9. Emulator Buffer Powerdown Register (EMUBUFPD) - 0x02AC 0054 Table 3-12. Emulator Buffer Powerdown Register (EMUBUFPD) Field Descriptions Bit Field Value Description 31:1 Reserved Reserved 0 EMUCTL Buffer powerdown for EMU[18:2] pins Submit Documentation Feedback 0 Power-up buffers 1 Power-down buffers Device Configuration 69 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 3.5 Device Status Register Description The device status register depicts the device configuration selected upon device reset. Once set, these bits will remain set until a device reset. For the actual register bit names and their associated bit field descriptions, see Figure 3-10 and Table 3-13. Note that enabling or disabling peripherals through the Peripheral Configuration Registers (PERCFG0 and PERCFG1) does not affect the DEVSTAT register. To determine the status of peripherals following writes to the PERCFG0 and PERCFG1 registers, read the Peripherals Status Registers (PERSTAT0 and PERSTAT1). 31 24 Reserved R-0000 0000 23 22 21 20 19 18 17 16 Reserved EMIFA_EN DDR2_EN PCI_EN CFGGP2 CFGGP1 CFGGP0 Reserved R-0 R-0 R-0 R-0 R-0 R-0 R-0 R-1 15 14 13 12 11 10 9 8 SYSCLKOUT_ EN MCBSP1_EN PCI66 Reserved PCI_EEAI MAC_SEL1 MAC_SEL0 Reserved R-0 R-0 R-0 R-0 R-0 R-0 R-0 R-1 7 6 5 4 3 2 1 0 UTOPIA_EN LENDIAN HPI_WIDTH AECLKINSEL BOOTMODE3 BOOTMODE2 BOOTMODE1 BOOTMODE0 R-0 R-1 R-0 R-0 R-0 R-0 R-0 R-0 LEGEND: R/W = Read/Write; R = Read only; -x = value after reset Note: The default values of the fields in the DEVSTAT register are latched from device configuration pins, as described in Section 3.1, Device Configuration at Device Reset. The default values shown here correspond to the setting dictated by the internal pullup or pulldown resistor. Figure 3-10. Device Status Register (DEVSTAT) - 0x02A8 0000 Table 3-13. Device Status Register (DEVSTAT) Field Descriptions Bit 31:23 22 21 20 19:17 16 70 Field Value Description Reserved Reserved. Read-only, writes have no effect. EMIFA_EN EMIFA Enable (EMIFA_EN) status bit Shows the status of whether the EMIFA peripheral pins are enabled/disabled. 0 EMIFA peripheral pins are disabled (default) 1 EMIFA peripheral pins are enabled DDR2_EN DDR2 Memory Controller Enable (DDR2_EN) status bit Shows the status of whether the DDR2 Memory Controller peripheral pins are enabled/disabled. 0 DDR2 Memory Controller peripheral pins are disabled (default) 1 DDR2 Memory Controller peripheral pins are enabled PCI_EN PCI Enable (PCI_EN) status bit Shows the status of which function is enabled on the HPI/PCI and PCI/UTOPIA multiplexed pins. 0 HPI and UTOPIA pin functions are enabled (default) 1 PCI pin functions are enabled CFGGP[2:0] Used as General-Purpose inputs for configuration purposes. These pins are latched at reset. These values can be used by S/W routines for boot operations. Reserved Reserved. Read-only, writes have no effect. Device Configuration Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 3-13. Device Status Register (DEVSTAT) Field Descriptions (continued) Bit Field 15 SYSCLKOUT_EN 14 13 Value Description SYSCLKOUT Enable (SYSCLKOUT_EN) status bit Shows the status of which function is enabled on the SYSCLK4/GP[1] muxed pin. 0 GP[1] pin function of the SYSCLK4/GP[1] pin enabled (default) 1 SYSCLK4 pin function of the SYSCLK4/GP[1] pin enabled MCBSP1_EN McBSP1 Enable (MCBSP1_EN) status bit Shows the status of which function is enabled on the McBSP1/GPIO muxed pins. 0 GPIO pin functions enabled (default) 1 McBSP1 pin functions enabled PCI66 PCI Frequency Selection (PCI66) status bit Shows the PCI operating frequency selected at reset. 0 PCI operates at 33 MHz (default) 1 PCI operates at 66 MHz 12 Reserved Reserved. Read-only, writes have no effect. 11 PCI_EEAI PCI I2C EEPROM Auto-Initialization (PCI_EEAI) status bit Shows whether the PCI auto-initialization via external I2C EEPROM is enabled/disabled. 10:9 0 PCI auto-initialization through external I2C EEPROM is disabled; the PCI peripheral uses the specified PCI default values (default). 1 PCI auto-initialization through external I2C EEPROM is enabled; the PCI peripheral is configured through external I2C EEPROM provided the PCI peripheral pin is enabled (PCI_EN = 1). MACSEL[1:0] EMAC Interface Select (MACSEL[1:0]) status bits Shows which EMAC interface mode has been selected. 00 10/100 EMAC/MDIO with MII Interface (default) 01 10/100 EMAC/MDIO with RMII Interface 10 10/100/1000 EMAC/MDIO with GMII Interface 11 10/100/1000 EMAC/MDIO with RGMII Mode Interface [RGMII interface requires a 1.8 V or 1.5 V I/O supply] 8 Reserved Reserved. Read-only, writes have no effect. 7 UTOPIA_EN UTOPIA enable (UTOPIA_EN) status bit Shows the status of which function is enabled on the UTOPIA/EMAC and UTOPIA/MDIO multiplexed pins. 6 5 4 0 EMAC and MDIO pin functions are enabled (default) 1 UTOPIA pin functions are enabled LENDIAN Device Endian mode (LENDIAN) Shows the status of whether the system is operating in Big Endian mode or Little Endian mode (default). 0 System is operating in Big Endian mode 1 System is operating in Little Endian mode (default) HPI_WIDTH HPI bus width control bit. Shows the status of whether the HPI bus operates in 32-bit mode or in 16-bit mode (default). 0 HPI operates in 16-bit mode. (default) 1 HPI operates in 32-bit mode AECLKINSEL Submit Documentation Feedback EMIFA input clock select Shows the status of what clock mode is enabled or disabled for EMIFA. 0 AECLKIN (default mode) 1 SYSCLK4 (CPU/x) Clock Rate. The SYSCLK4 clock rate is software selectable via the PLL1 Controller. By default, SYSCLK4 is selected as CPU/8 clock rate. Device Configuration 71 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 3-13. Device Status Register (DEVSTAT) Field Descriptions (continued) Bit Field 3:0 BOOTMODE[3:0] Value Description Boot mode configuration bits Shows the status of what device boot mode configuration is operational. BOOTMODE[3:0] [Note: if selected for boot, the corresponding peripheral is automatically enabled after device reset.] 0000 No boot (default mode) 0001 Host boot (HPI) 0010 Reserved 0011 Reserved 0100 EMIFA 8-bit ROM boot 0101 Master I2C boot 0110 Slave I2C boot 0111 Host boot (PCI) 1000 thru 1111 Serial Rapid I/O boot For more detailed information on the boot modes, see Section 2.4, Boot Sequence, of this document. 3.6 JTAG ID (JTAGID) Register Description The JTAG ID register is a read-only register that identifies to the customer the JTAG/Device ID. For the C6455 device, the JTAG ID register resides at address location 0x02A8 0008. For the actual register bit names and their associated bit field descriptions, see Figure 3-11 and Table 3-14. 31 28 27 12 11 1 0 VARIANT (4-bit) PART NUMBER (16-bit) MANUFACTURER (11-bit) LSB R-n R-0000 0000 1000 1010b 0000 0010 111b R-1 LEGEND: R = Read only; -n = value after reset Figure 3-11. JTAG ID (JTAGID) Register - 0x02A8 0008 Table 3-14. JTAG ID (JTAGID) Register Field Descriptions Bit Field 31:28 VARIANT Value Description Variant (4-Bit) value. The value of this field depends on the silicon revision being used. For more information, see the TMS320C6455 Digital Signal Processor Silicon Errata (literature number SPRZ234). Note: the VARIANT field may be invalid if no CLKIN1 signal is applied. 27:12 PART NUMBER Part Number (16-Bit) value. C6455 value: 0000 0000 1000 1010b. 11:1 MANUFACTURER Manufacturer (11-Bit) value. C6455 value: 0000 0010 111b. LSB LSB. This bit is read as a "1" for C6455. 0 72 Device Configuration Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 3.7 Pullup/Pulldown Resistors Proper board design should ensure that input pins to the C6455 device always be at a valid logic level and not floating. This may be achieved via pullup/pulldown resistors. The C6455 device features internal pullup (IPU) and internal pulldown (IPD) resistors on most pins to eliminate the need, unless otherwise noted, for external pullup/pulldown resistors. An external pullup/pulldown resistor needs to be used in the following situations: • Device Configuration Pins: If the pin is both routed out and 3-stated (not driven), an external pullup/pulldown resistor must be used, even if the IPU/IPD matches the desired value/state. • Other Input Pins: If the IPU/IPD does not match the desired value/state, use an external pullup/pulldown resistor to pull the signal to the opposite rail. For the device configuration pins (listed in Table 3-1), if they are both routed out and 3-stated (not driven), it is strongly recommended that an external pullup/pulldown resistor be implemented. Although, internal pullup/pulldown resistors exist on these pins and they may match the desired configuration value, providing external connectivity can help ensure that valid logic levels are latched on these device configuration pins. In addition, applying external pullup/pulldown resistors on the device configuration pins adds convenience to the user in debugging and flexibility in switching operating modes. Tips for choosing an external pullup/pulldown resistor: • Consider the total amount of current that may pass through the pullup or pulldown resistor. Make sure to include the leakage currents of all the devices connected to the net, as well as any internal pullup or pulldown resistors. • Decide a target value for the net. For a pulldown resistor, this should be below the lowest VIL level of all inputs connected to the net. For a pullup resistor, this should be above the highest VIH level of all inputs on the net. A reasonable choice would be to target the VOL or VOH levels for the logic family of the limiting device; which, by definition, have margin to the VIL and VIH levels. • Select a pullup/pulldown resistor with the largest possible value; but, which can still ensure that the net will reach the target pulled value when maximum current from all devices on the net is flowing through the resistor. The current to be considered includes leakage current plus, any other internal and external pullup/pulldown resistors on the net. • For bidirectional nets, there is an additional consideration which sets a lower limit on the resistance value of the external resistor. Verify that the resistance is small enough that the weakest output buffer can drive the net to the opposite logic level (including margin). • Remember to include tolerances when selecting the resistor value. • For pullup resistors, also remember to include tolerances on the DVDD rail. For most systems, a 1-kΩ resistor can be used to oppose the IPU/IPD while meeting the above criteria. Users should confirm this resistor value is correct for their specific application. For most systems, a 20-kΩ resistor can be used to compliment the IPU/IPD on the device configuration pins while meeting the above criteria. Users should confirm this resistor value is correct for their specific application. For more detailed information on input current (II), and the low-/high-level input voltages (VIL and VIH) for the C6455 device, see Section 6.3, Electrical Characteristics Over Recommended Ranges of Supply Voltage and Operating Case Temperature. To determine which pins on the C6455 device include internal pullup/pulldown resistors, see Table 2-3, Terminal Functions. Submit Documentation Feedback Device Configuration 73 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 3.8 Configuration Examples Figure 3-12 and Figure 3-13 illustrate examples of peripheral selections/options that are configurable on the C6455 device. 32 HD[31:0] HRDY, HINT HPI (32-Bit) VCP2 PCI TCP2 HCNTL0, HCNTL1, HHWIL, HAS, HR/W, HCS, HDS1, HDS2 64 AED[63:0] UTOPIA GP[15:12,2,1] EMIFA AECLKIN, AARDY, AHOLD AEA[22:3], ACE[3:0], ABE[7:0], AECLKOUT, ASDCKE, AHOLDA, ABUSREQ, ASADS/ASRE, AAOE/ASOE, AAWE/ASWE GPIO 32 DDR2 EMIF CLKIN1, PLLV1 SYSCLK4 PLL1 and PLL1 Controller PLL2 and PLL2 Controller McBSP1 TIMER1 ED[31:0] DEA[21:2], DCE[1:0], DBE[3:0], DDRCLK, DDRCLK, DSDCKE, DDQS, DDQS, DSDCAS, DSDRAS, DSDWE CLKIN2, PLLV2 TINP1L TOUT1L CLKR0, FSR0, DR0, CLKS0, DX0, FSX0, CLKX0 TINP0 McBSP0 TIMER0 MRXD[7:0], MRXER, MRXDV, MCOL, MCRS, MTCLK, MRCLK EMAC RapidIO MTXD[7:0], MTXEN, MDIO, MDCLK MDIO I2C TOUT0 RIOCLK, RIOCLK, RIOTX[3:0], RIOTX[3:0], RIORX[3:0], RIORX[3:0] SCL SDA Shading denotes a peripheral module not available for this configuration. DEVSTAT Register: 0x0061 8161 PCI_EN = 0 (PCI disabled, default) ABA1 (EMIFA_EN) = 1(EMIFA enabled) ABA0 (DDR2_EN) = 1 (DDR2 Memory Controller enabled) AEA[19:16] (BOOTMODE[3:0]) = 0001, (HPI Boot) AEA[15] (AECLKIN_SEL) = 0, (AECLKIN, default) AEA[14] (HPI_WIDTH) = 1, (HPI, 32-bit Operation) AEA[13] (LENDIAN) = IPU, (Little Endian Mode, default) AEA[12] (UTOPIA_EN) = 0, (UTOPIA disabled, default) AEA[11] = 1 (must oppose IPD) AEA[10:9] (MACSEL[1:0]) = 00, (10/100 MII Mode) AEA[8] (PCI_EEAI) = 0, (PCI I2C EEPROM Auto-Init disabled, default) AEA[7] = 0, (do not oppose IPD) AEA[6] (PCI66) = 0, (PCI 33 MHz [default, don’t care]) AEA[5] (MCBSP1_EN) = 0, (McBSP1 disabled, default) AEA[4] (SYSCLKOUT_EN) = 1, (SYSCLK4 pin function) AEA[3] = 1 (must oppose IPD) AEA[2:0] (CFGGP[2:0]) = 000 (default) Figure 3-12. Configuration Example A (McBSP + HPI32 + I2C + EMIFA + DDR2 Memory Controller + TIMERS + RapidIO + EMAC (MII) + MDIO) 74 Device Configuration Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 32 HD[31:0] HRDY, HINT HPI (32-Bit) VCP2 PCI TCP2 HCNTL0, HCNTL1, HHWIL, HAS, HR/W, HCS, HDS1, HDS2 64 AED[63:0] UTOPIA GP[15:12,2,1] EMIFA AECLKIN, AARDY, AHOLD AEA[22:3], ACE[3:0], ABE[7:0], AECLKOUT, ASDCKE, AHOLDA, ABUSREQ, ASADS/ASRE, AAOE/ASOE, AAWE/ASWE GPIO 32 DDR2 EMIF PLL1 and PLL1 Controller PLL2 and PLL2 Controller CLKR1, FSR1, DR1, CLKS1, DX1, FSX1, CLKX1 McBSP1 TIMER1 CLKR0, FSR0, DR0, CLKS0, DX0, FSX0, CLKX0 McBSP0 CLKIN1, PLLV1 SYSCLK4 ED[31:0] DEA[21:2], DCE[1:0], DBE[3:0], DDRCLK, DDRCLK, DSDCKE, DDQS, DDQS, DSDCAS, DSDRAS, DSDWE CLKIN2, PLLV2 TINP1L TOUT1L TINP0 TIMER0 MRXD[7:0], MRXER, MRXDV, MCOL, MCRS, MTCLK, MRCLK EMAC RapidIO MTXD[7:0], MTXEN, MDIO, MDCLK MDIO I2C TOUT0 RIOCLK, RIOCLK, RIOTX[3:0], RIOTX[3:0], RIORX[3:0], RIORX[3:0] SCL SDA Shading denotes a peripheral module not available for this configuration. DEVSTAT Register: 0x0061 C161 PCI_EN = 0 (PCI disabled, default) ABA1 (EMIFA_EN) = 1(EMIFA enabled) ABA0 (DDR2_EN) = 1 (DDR2 Memory Controller enabled) AEA[19:16] (BOOTMODE[3:0]) = 0001, (HPI Boot) AEA[15] (AECLKIN_SEL) = 0, (AECLKIN, default) AEA[14] (HPI_WIDTH) = 1, (HPI, 32-bit Operation) AEA[13] (LENDIAN) = IPU, (Little Endian Mode, default) AEA[12] (UTOPIA_EN) = 0, (UTOPIA disabled, default) AEA[11] = 1 (must oppose IPD) AEA[10:9] (MACSEL[1:0]) = 00, (10/100 MII Mode) AEA[8] (PCI_EEAI) = 0, (PCI I2C EEPROM Auto-Init disabled, default) AEA[7] = 0, (do not oppose IPD) AEA[6] (PCI66) = 0, (PCI 33 MHz [default, don’t care]) AEA[5] (MCBSP1_EN) = 1, (McBSP1 enabled) AEA[4] (SYSCLKOUT_EN) = 1, (SYSCLK4 pin function) AEA[3] = 1 (must oppose IPD) AEA[2:0] (CFGGP[2:0]) = 000 (default) Figure 3-13. Configuration Example B (2 McBSPs + HPI32 + I2C + EMIFA + DDR2 Memory Controller + TIMERS + RapidIO + EMAC (GMII) + MDIO Submit Documentation Feedback Device Configuration 75 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 4 System Interconnect On the C6455 device, the C64x+ Megamodule, the EDMA3 transfer controllers, and the system peripherals are interconnected through two switch fabrics. The switch fabrics allow for low-latency, concurrent data transfers between master peripherals and slave peripherals. Through a switch fabric the CPU can send data to the Viterbi co-processor (VCP2) without affecting a data transfer between the PCI and the DDR2 memory controller. The switch fabrics also allow for seamless arbitration between the system masters when accessing system slaves. 4.1 Internal Buses, Bridges, and Switch Fabrics Two types of buses exist in the C6455 device: data buses and configuration buses. Some C6455 peripherals have both a data bus and a configuration bus interface, while others only have one type of interface. Furthermore, the bus interface width and speed varies from peripheral to peripheral. Configuration buses are mainly used to access the register space of a peripheral and the data buses are used mainly for data transfers. However, in some cases, the configuration bus is also used to transfer data. For example, data is transferred to the VCP2 and TCP2 configuration bus. Similarly, the data bus can also be used to access the register space of a peripheral. For example, the EMIFA and DDR2 memory controller registers are accessed through their data bus interface. The C64x+ Megamodule, the EDMA3 traffic controllers, and the various system peripherals can be classified into two categories: masters and slaves. Masters are capable of initiating read and write transfers in the system and do not rely on the EDMA3 for their data transfers. Slaves on the other hand rely on the EDMA3 to perform transfers to and from them. Masters include the EDMA3 traffic controllers, SRIO, and PCI. Slaves include the McBSP, UTOPIA, and I2C. The C6455 device contains two switch fabrics through which masters and slaves communicate. The data switch fabric, known as the data switched central resource (SCR), is a high-throughput interconnect mainly used to move data across the system (for more information, see Section 4.2). The data SCR connects masters to slaves via 128-bit data buses running at a SYSCLK2 frequency (SYSCLK2 is generated from PLL1 controller). Peripherals that have a 128-bit data bus interface running at this speed can connect directly to the data SCR; other peripherals require a bridge. The configuration switch fabric, also known as the configuration switch central resource (SCR) is mainly used by the C64x+ Megamodule to access peripheral registers (for more information, see Section 4.3). The configuration SCR connects C64x+ Megamodule to slaves via 32-bit configuration buses running at a SYSCLK2 frequency (SYSCLK2 is generated from PLL1 controller). As with the data SCR, some peripherals require the use of a bridge to interface to the configuration SCR. Note that the data SCR also connects to the configuration SCR. Bridges perform a variety of functions: • Conversion between configuration bus and data bus. • Width conversion between peripheral bus width and SCR bus width. • Frequency conversion between peripheral bus frequency and SCR bus frequency. For example, the EMIFA and DDR2 memory controller require a bridge to convert their 64-bit data bus interface into a 128-bit interface so that they can connect to the data SCR. In the case of the TCP2 and VCP2, a bridge is required to connect the data SCR to the 64-bit configuration bus interface. Note that some peripherals can be accessed through the data SCR and also through the configuration SCR. 76 System Interconnect Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 4.2 Data Switch Fabric Connections Figure 4-1 shows the connection between slaves and masters through the data switched central resource (SCR). Masters are shown on the right and slaves on the left. The data SCR connects masters to slaves via 128-bit data buses running at a SYSCLK2 frequency. SYSCLK2 is supplied by the PLL1 controller and is fixed at a frequency equal to the CPU frequency divided by 3. Some peripherals, like PCI and the C64x+ Megamodule, have both slave and master ports. Note that each EDMA3 transfer controller has an independent connection to the data SCR. The Serial RapidIO (SRIO) peripheral has two connections to the data SCR. The first connection is used when descriptors are being fetched from system memory. The other connection is used for all other data transfers. Note that masters can access the configuration SCR through the data SCR. The configuration SCR is described in Section 4.3. Not all masters on the C6455 DSP may connect to all slaves. Allowed connections are summarized in Table 4-1. Submit Documentation Feedback System Interconnect 77 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 EDMA3 Channel Controller Events MASTER SLAVE Data SCR 128 (SYSCLK2) 128 (SYSCLK2) M0 EDMA3 Transfer Controllers 128 (SYSCLK2) M1 M M 128-bit (SYSCLK2) 32 (SYSCLK3) 32 (SYSCLK3) M PCI M S VCP2 S CFG SCR S McBSPs S UTOPIA S PCI S DDR2 Memory Controller S EMIFA S Megamodule 32 (SYSCLK2) Bridge 32 128 (SYSCLK3) (SYSCLK3) M HPI TCP2 64 (SYSCLK2) Bridge 128 (SYSCLK2) S3 32 (SYSCLK3) EMAC S S2 128 (SYSCLK2) M3 64 (SYSCLK2) Bridge 128 (SYSCLK2) S1 128 (SYSCLK2) M2 M S0 M Bridge 32 (SYSCLK3) 32 (SYSCLK3) Bridge S 128 (SYSCLK2) 32 (SYSCLK3) 32 (SYSCLK3) M Serial RapidIO (Descriptor) M Serial RapidIO (Data) M Megamodule M 32 (SYSCLK3) 32 (SYSCLK3) Bridge S M 128 (SYSCLK2) 128 (SYSCLK2) S M 128 (SYSCLK2) 128 (SYSCLK2) Bridge Bridge 64 (SYSCLK2) 64 (SYSCLK2) 128 (SYSCLK2) S Configuration Bus Data Bus Figure 4-1. Switched Central Resource Block Diagram 78 System Interconnect Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 4-1. SCR Connection Matrix TCP2 VCP2 McBSPs UTOPIA2 CONFIGURATION SCR PCI DDR2 MEMORY CONTROLLER EMIFA MEGAMODULE TC0 Y Y N N N N Y Y Y TC1 N N Y Y Y Y Y Y Y TC2 N N N N N Y Y Y Y TC3 N N N N N Y Y Y Y EMAC N N N N N N Y Y Y HPI N N N N Y N Y Y Y PCI N N N N Y N Y Y Y SRIO (1) N N N N Y N Y Y Y Megamodule Y Y Y Y Y Y Y Y N (1) Applies to both descriptor and data accesses by the SRIO peripheral. 4.3 Configuration Switch Fabric Figure 4-2 shows the connection between the C64x+ Megamodule and the configuration switched central resource (SCR). The configuration SCR is mainly used by the C64x+ Megamodule to access peripheral registers. The data SCR also has a connection to the configuration SCR which allows masters to access most peripheral registers. The only registers not accessible by the data SCR through the configuration SCR are the device configuration registers and the PLL1 and PLL2 controller registers; these can only be accessed by the C64x+ Megamodule. The configuration SCR uses 32-bit configuration buses running at SYSCLK2 frequency. SYSCLK2 is supplied by the PLL1 controller and is fixed at a frequency equal to the CPU frequency divided by 3. Submit Documentation Feedback System Interconnect 79 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 CFG SCR 32 (SYSCLK2) M S TCP2 S VCP2 S GPIO S McBSPs S UTOPIA S PCI S I2C S Timers S HPI S EMAC/MDIO S PLL Controllers (A) MUX 32 (SYSCLK2) 32 (SYSCLK3) 32 (SYSCLK2) 32 (SYSCLK3) 32 (SYSCLK3) 32 (SYSCLK3) 32 (SYSCLK3) 32-bit (SYSCLK2) M Bridge 7 MUX 32 (SYSCLK2) Megamodule Data SCR M M S 32 (SYSCLK3) 32 (SYSCLK2) 32 (SYSCLK3) 32 (SYSCLK3) 32 (SYSCLK3) 32 (SYSCLK2) S 32 (SYSCLK3) 32 (SYSCLK3) M 32 (SYSCLK2) S Device Configuration Registers (A) S Serial RapidIO S EDMA3 CC S EDMA3 TC0 S EDMA3 TC1 S EDMA3 TC2 S EDMA3 TC3 32 (SYSCLK2) 32 (SYSCLK2) M 32 (SYSCLK2) MUX 32 (SYSCLK2) 32 (SYSCLK2) 32 (SYSCLK2) Configuration Bus Data Bus A. Only accessible by the C64x+ Megamodule. B. All clocks in this figure are generated by the PLL1 controller. Figure 4-2. C64x+ Megamodule - SCR Connection 80 System Interconnect Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 4.4 Bus Priorities On the C6455 device, bus priority is programmable for each master. The register bit fields and default priority levels for C6455 bus masters are shown in Table 4-2. The priority levels should be tuned to obtain the best system performance for a particular application. Lower values indicate higher priorities. For some masters, the priority values are programmed at the system level by configuring the PRI_ALLOC register. Details on the PRI_ALLOC register are shown in Figure 4-3. The C64x+ megamodule, SRIO, and EDMA masters contain registers that control their own priority values. The priority is enforced when several masters in the system are vying for the same endpoint. Note that the configuration SCR port on the data SCR is considered a single endpoint meaning priority will be enforced when multiple masters try to access the configuration SCR. Priority is also enforced on the configuration SCR side when a master (through the data SCR) tries to access the same endpoint as the C64x+ megamodule. In the PRI_ALLOC register, the HOST field applies to the priority of the HPI and PCI peripherals. The EMAC field specifies the priority of the EMAC peripheral. The SRIO field is used to specify the priority of the Serial RapidIO when accessing descriptors from system memory. The priority for Serial RapidIO data accesses is set in the peripheral itself. Table 4-2. C6455 Default Bus Master Priorities DEFAULT PRIORITY LEVEL BUS MASTER PRIORITY CONTROL EDMA3TC0 0 QUEPRI.PRIQ0 (EDMA3 register) EDMA3TC1 0 QUEPRI.PRIQ1 (EDMA3 register) EDMA3TC2 0 QUEPRI.PRIQ2 (EDMA3 register) EDMA3TC3 0 QUEPRI.PRIQ3 (EDMA3 register) SRIO (Data Access) 0 PER_SET_CNTL.CBA_TRANS_PRI (SRIO register) SRIO (Descriptor Access) 0 PRI_ALLOC.SRIO EMAC 1 PRI_ALLOC.EMAC PCI 2 PRI_ALLOC.HOST HPI 2 PRI_ALLOC.HOST C64x+ Megamodule (MDMA port) 7 MDMAARBE.PRI (C64x+ Megamodule Register) 31 16 Reserved R-0000 0000 0000 0000 15 12 11 9 8 6 5 3 2 0 Reserved SRIO Reserved HOST EMAC R-000 0 R/W-001 R-100 R/W-010 R/W-001 LEGEND: R/W = Read/Write; R = Read only; -n = value at reset Figure 4-3. Priority Allocation Register (PRI_ALLOC) Submit Documentation Feedback System Interconnect 81 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 5 C64x+ Megamodule The C64x+ Megamodule consists of several components — the C64x+ CPU, the L1 program and data memory controllers, the L2 memory controller, the internal DMA (IDMA), the interrupt controller, power-down controller, and external memory controller. The C64x+ Megamodule also provides support for memory protection (for L1P, L1D, and L2 memories) and bandwidth management (for resources local to the C64x+ Megamodule). Figure 5-1 shows a block diagram of the C64x+ Megamodule. L1P cache/SRAM 256 L1 program memory controller 256 L2 cache/ SRAM Internal ROM(A) 256 Cache control 256 Cache control Bandwidth management Memory protection L2 memory controller 256 256 C64x+ CPU Instruction fetch SPLOOP buffer 16/32−bit instruction dispatch Instruction decode Data path 1 Data path 2 Bandwidth management Memory protection 256 IDMA 128 L1 External memory controller To Chip registers 32 256 Slave DMA 128 Master DMA S1 M1 xx xx D1 D2 M2 xx xx A register file Configuration Registers 128 To primary switch fabric Advanced event triggering (AET) 256 S2 L2 B register file 64 64 L1 data memory controller Cache control Bandwidth management Memory protection Interrupt and exception controller Power control 32 L1D cache/SRAM A. When accessing the internal ROM of the DSP, the CPU frequency must always be less than 750 MHz. Figure 5-1. 64x+ Megamodule Block Diagram For more detailed information on the TMS320C64x+ Megamodule on the C6455 device, see the TMS320C64x+ Megamodule Reference Guide (literature number SPRU871). 5.1 Memory Architecture The TMS320C6455 device contains a 2096KB level-2 memory (L2), a 32KB level-1 program memory (L1P), and a 32KB level-1 data memory (L1D). The L1P memory configuration for the C6455 device is as follows: • Region 0 size is 0K bytes (disabled). • Region 1 size is 32K bytes with no wait states. The L1D memory configuration for the C6455 device is as follows: • Region 0 size is 0K bytes (disabled). 82 C64x+ Megamodule Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 • Region 1 size is 32K bytes with no wait states. L1D is a two-way set-associative cache while L1P is a direct-mapped cache. The L1P and L1D cache can be reconfigured via software through the L1PMODE field of the L1P Configuration Register (L1PMODE) and the L1DMODE field of the L1D Configuration Register (L1DCFG) of the C64x+ Megamodule. After device reset, L1P and L1D cache are configured as all cache or all SRAM. The on-chip Bootloader changes the reset configuration for L1P and L1D. For more information, see the TMS320C645x Bootloader User's Guide (literature number SPRUEC6). Figure 5-2 and Figure 5-3 show the available SRAM/cache configurations for L1P and L1D, respectively. L1P mode bits 000 001 010 011 100 1/2 SRAM All SRAM 7/8 SRAM L1P memory Block base address 00E0 0000h 16K bytes 3/4 SRAM direct mapped cache 00E0 4000h 8K bytes dm cache direct mapped cache direct mapped cache 00E0 6000h 4K bytes 00E0 7000h 4K bytes 00E0 8000h Figure 5-2. TMS320C6455 L1P Memory Configurations L1D mode bits 000 001 010 011 100 1/2 SRAM All SRAM 7/8 SRAM L1D memory Block base address 00F0 0000h 16K bytes 3/4 SRAM 2-way cache 00F0 4000h 8K bytes 2-way cache 00F0 6000h 4K bytes 2-way cache 2-way cache 00F0 7000h 4K bytes 00F0 8000h Figure 5-3. TMS320C6455 L1D Memory Configurations Submit Documentation Feedback C64x+ Megamodule 83 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 The L2 memory configuration for the C6455 device is as follows: • Port 0 configuration: – Memory size is 2096KB – Starting address is 0080 0000h – 2-cycle latency – 4 נ128-bit bank configuration • Port 1 configuration: – Memory size is 32K bytes (this corresponds to the internal ROM) – Starting address is 0010 0000h – 1-cycle latency – 1 נ256-bit bank configuration L2 memory can be configured as all SRAM or as part 4-way set-associative cache. The amount of L2 memory that is configured as cache is controlled through the L2MODE field of the L2 Configuration Register (L2CFG) of the C64x+ Megamodule. Figure 5-4 shows the available SRAM/cache configurations for L2. By default, L2 is configured as all SRAM after device reset. L2 mode bits 000 001 010 011 111 L2 memory 7/8 SRAM 1840K bytes Block base address 0080 0000h 15/16 SRAM All SRAM 63/64 SRAM 31/32 SRAM 009C 0000h 4-way cache 128K bytes 009E 0000h 4-way 4-way cache 4-way cache 64K bytes 32K bytes 32K bytes 009F 0000h 009F 8000h 00A0 0000h Figure 5-4. TMS320C6455 L2 Memory Configurations For more information on the operation L1 and L2 caches, see the TMS320C64x+ DSP Cache User's Guide (literature number SPRU862). All memory on the C6455 has a unique location in the memory map (see Table 2-2, C6455 Memory Map Summary). When accessing the internal ROM of the DSP, the CPU frequency must always be less than 750 MHz. Therefore, when using a software boot mode, care must be taken such that the CPU frequency does not exceed 750 MHz at any point during the boot sequence. After the boot sequence has completed, the CPU frequency can be programmed to the frequency required by the application. For more detailed information ont he boot modes, see Section 2.4, Boot Sequence. 84 C64x+ Megamodule Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 5.2 Memory Protection Memory protection allows an operating system to define who or what is authorized to access L1D, L1P, and L2 memory. To accomplish this, the L1D, L1P, and L2 memories are divided into pages. There are 16 pages of L1P (2KB each), 16 pages of L1D (2KB each), and 32 pages of L2 (64KB each). The L1D, L1P, and L2 memory controllers in the C64x+ Megamodule are equipped with a set of registers that specify the permissions for each memory page. Each page may be assigned with fully orthogonal user and supervisor read, write, and execute permissions. Additionally, a page may be marked as either (or both) locally or globally accessible. A local access is a direct CPU access to L1D, L1P, and L2, while a global access is initiated by a DMA (either IDMA or the EDMA3) or by other system masters. Note that EDMA or IDMA transfers programmed by the CPU count as global accesses. The CPU and the system masters on the C6455 device are all assigned a privilege ID of 0. Therefore it is only possible to specify whether memory pages are locally or globally accessible. The AID0 and LOCAL bits of the memory protection page attribute registers specify the memory page protection scheme, see Table 5-1. Table 5-1. Available Memory Page Protection Schemes AID0 Bit LOCAL Bit Description 0 0 No access to memory page is permitted. 0 1 Only direct access by CPU is permitted. 1 0 Only accesses by system masters and IDMA are permitted (includes EDMA and IDMA accesses initiated by the CPU). 1 1 All accesses permitted For more information on memory protection for L1D, L1P, and L2, see the TMS320C64x+ Megamodule Reference Guide (literature number SPRU871). 5.3 Bandwidth Management When multiple requestors contend for a single C64x+ Megamodule resource, the conflict is solved by granting access to the highest priority requestor. The following four resources are managed by the Bandwidth Management control hardware: • Level 1 Program (L1P) SRAM/Cache • Level 1 Data (L1D) SRAM/Cache • Level 2 (L2) SRAM/Cache • Memory-mapped registers configuration bus The priority level for operations initiated within the C64x+ Megamodule; e.g., CPU-initiated transfers, user-programmed cache coherency operations, and IDMA-initiated transfers, are declared through registers in the C64x+ Megamodule. The priority level for operations initiated outside the C64x+ Megamodule by system peripherals is declared through the Priority Allocation Register (PRI_ALLOC), see Section 4.4. System peripherals with no fields in PRI_ALLOC have their own registers to program their priorities. More information on the bandwidth management features of the C64x+ Megamodule can be found in the TMS320C64x+ Megamodule Reference Guide (literature number SPRU871). Submit Documentation Feedback C64x+ Megamodule 85 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 5.4 Power-Down Control The C64x+ Megamodule supports the ability to power-down various parts of the C64x+ Megamodule. The power-down controller (PDC) of the C64x+ Megamodule can be used to power down L1P, the cache control hardware, the CPU, and the entire C64x+ Megamodule. These power-down features can be used to design systems for lower overall system power requirements. NOTE The C6455 does not support power-down modes for the L2 memory at this time. More information on the power-down features of the C64x+ Megamodule can be found in the TMS320C64x+ Megamodule Reference Guide (literature number SPRU871). 5.5 Megamodule Resets Table 5-2 shows the reset types supported on the C6455 device and they affect the resetting of the Megamodule, either both globally or just locally. Table 5-2. Megamodule Reset (Global or Local) GLOBAL MEGAMODULE RESET LOCAL MEGAMODULE RESET Power-On Reset Y Y Warm Reset Y Y Max Reset Y Y System Reset Y Y CPU Reset N Y RESET TYPE For more detailed information on the global and local Megamodule resets, see the TMS320C64x+ Megamodule Reference Guide (literature number SPRU871). And for more detailed information on device resets, see Section 7.6, Reset Controller. 86 C64x+ Megamodule Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 5.6 Megamodule Revision The version and revision of the C64x+ Megamodule can be read from the Megamodule Revision ID Register (MM_REVID) located at address 0181 2000h. The MM_REVID register is shown in Figure 5-5 and described in Table 5-3. The C64x+ Megamodule revision is dependant on the silicon revision being used. For more information, see the TMS320C6455 Digital Signal Processor Silicon Errata (literature number SPRZ234). 31 16 15 0 (A) VERSION REVISION R-1h R-n LEGEND: R = Read only; -n = value after reset A. The C64x+ Megamodule revision is dependant on the silicon revision being used. For more information, see the TMS320C6455 Digital Signal Processor Silicon Errata (literature number SPRZ234). Figure 5-5. Megamodule Revision ID Register (MM_REVID) [Hex Address: 0181 2000h] Table 5-3. Megamodule Revision ID Register (MM_REVID) Field Descriptions Bit Field 31:16 VERSION 15:0 REVISION Value Submit Documentation Feedback 1h Description Version of the C64x+ Megamodule implemented on the device. This field is always read as 1h. Revision of the C64x+ Megamodule version implemented on the device. The C64x+ Megamodule revision is dependant on the silicon revision being used. For more information, see the TMS320C6455 Digital Signal Processor Silicon Errata (literature number SPRZ234). C64x+ Megamodule 87 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 5.7 C64x+ Megamodule Register Description(s) Table 5-4. Megamodule Interrupt Registers 88 HEX ADDRESS RANGE ACRONYM 0180 0000 EVTFLAG0 Event Flag Register 0 (Events [31:0]) REGISTER NAME 0180 0004 EVTFLAG1 Event Flag Register 1 0180 0008 EVTFLAG2 Event Flag Register 2 0180 000C EVTFLAG3 Event Flag Register 3 0180 0010 - 0180 001C - 0180 0020 EVTSET0 Event Set Register 0 (Events [31:0]) 0180 0024 EVTSET1 Event Set Register 1 0180 0028 EVTSET2 Event Set Register 2 0180 002C EVTSET3 Event Set Register 3 Reserved 0180 0030 - 0180 003C - 0180 0040 EVTCLR0 Reserved Event Clear Register 0 (Events [31:0]) 0180 0044 EVTCLR1 Event Clear Register 1 0180 0048 EVTCLR2 Event Clear Register 2 0180 004C EVTCLR3 Event Clear Register 3 0180 0050 - 0180 007C - 0180 0080 EVTMASK0 Event Mask Register 0 (Events [31:0]) 0180 0084 EVTMASK1 Event Mask Register 1 0180 0088 EVTMASK2 Event Mask Register 2 0180 008C EVTMASK3 Event Mask Register 3 Reserved 0180 0090 - 0180 009C - 0180 00A0 MEVTFLAG0 Reserved Masked Event Flag Status Register 0 (Events [31:0]) 0180 00A4 MEVTFLAG1 Masked Event Flag Status Register 1 0180 00A8 MEVTFLAG2 Masked Event Flag Status Register 2 0180 00AC MEVTFLAG3 Masked Event Flag Status Register 3 0180 00B0 - 0180 00BC - 0180 00C0 EXPMASK0 Exception Mask Register 0 (Events [31:0]) 0180 00C4 EXPMASK1 Exception Mask Register 1 0180 00C8 EXPMASK2 Exception Mask Register 2 0180 00CC EXPMASK3 Exception Mask Register 3 Reserved 0180 00D0 - 0180 00DC - 0180 00E0 MEXPFLAG0 Reserved Masked Exception Flag Register 0 0180 00E4 MEXPFLAG1 Masked Exception Flag Register 1 0180 00E8 MEXPFLAG2 Masked Exception Flag Register 2 0180 00EC MEXPFLAG3 Masked Exception Flag Register 3 0180 00F0 - 0180 00FC - Reserved 0180 0100 - Reserved 0180 0104 INTMUX1 Interrupt Multiplexor Register 1 0180 0108 INTMUX2 Interrupt Multiplexor Register 2 0180 010C INTMUX3 Interrupt Multiplexor Register 3 0180 0110 - 0180 013C - 0180 0140 AEGMUX0 Reserved Advanced Event Generator Mux Register 0 0180 0144 AEGMUX1 Advanced Event Generator Mux Register 1 0180 0148 - 0180 017C - 0180 0180 INTXSTAT Interrupt Exception Status Register 0180 0184 INTXCLR Interrupt Exception Clear Register C64x+ Megamodule Reserved Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 5-4. Megamodule Interrupt Registers (continued) HEX ADDRESS RANGE ACRONYM 0180 0188 INTDMASK 0180 0188 - 0180 01BC - 0180 01C0 EVTASRT 0180 01C4 - 0180 FFFF - REGISTER NAME Dropped Interrupt Mask Register Reserved Event Asserting Register Reserved Table 5-5. Megamodule Powerdown Control Registers HEX ADDRESS RANGE ACRONYM 0181 0000 PDCCMD 0181 0004 - 0181 1FFF - REGISTER NAME Power-down controller command register Reserved Table 5-6. Megamodule Revision Register HEX ADDRESS RANGE ACRONYM 0181 2000 MM_REVID 0181 2004 – 0181 2FFF - REGISTER NAME Megamodule Revision ID Register Reserved Table 5-7. Megamodule IDMA Registers HEX ADDRESS RANGE ACRONYM 0182 0000 IDMA0STAT IDMA Channel 0 Status Register 0182 0004 IDMA0MASK IDMA Channel 0 Mask Register 0182 0008 IMDA0SRC IDMA Channel 0 Source Address Register 0182 000C IDMA0DST IDMA Channel 0 Destination Address Register 0182 0010 IDMA0CNT IDMA Channel 0 Count Register 0182 0014 - 0182 00FC - 0182 0100 IDMA1STAT 0182 0104 - 0182 0108 IMDA1SRC IDMA Channel 1 Source Address Register 0182 010C IDMA1DST IDMA Channel 1 Destination Address Register 0182 0110 IDMA1CNT IDMA Channel 1 Count Register 0182 0114 - 0182 017C - Reserved 0182 0180 - Reserved 0182 0184 - 0182 01FF - Reserved Submit Documentation Feedback REGISTER NAME Reserved IDMA Channel 1 Status Register Reserved C64x+ Megamodule 89 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 5-8. Megamodule Cache Configuration Registers 90 HEX ADDRESS RANGE ACRONYM 0184 0000 L2CFG REGISTER NAME L2 Cache Configuration Register 0184 0004 - 0184 001F - 0184 0020 L1PCFG Reserved L1P Configuration Register 0184 0024 L1PCC L1P Cache Control Register 0184 0028 - 0184 003F - 0184 0040 L1DCFG Reserved L1D Configuration Register 0184 0044 L1DCC L1D Cache Control Register 0184 0048 - 0184 0FFF - Reserved 0184 1000 - 0184 104F - See Table 5-10, CPU Megamodule Bandwidth Management Registers 0184 1050 - 0184 3FFF - Reserved 0184 4000 L2WBAR L2 Writeback Base Address Register - for Block Writebacks L2 Writeback Word Count Register 0184 4004 L2WWC 0184 4008 - 0184 400C - 0184 4010 L2WIBAR L2 Writeback and Invalidate Base Address Register - for Block Writebacks 0184 4014 L2WIWC L2 Writeback and Invalidate word count register 0184 4018 L2IBAR L2 Invalidate Base Address Register 0184 401C L2IWC L2 Invalidate Word Count Register 0184 4020 L1PIBAR L1P Invalidate Base Address Register 0184 4024 L1PIWC L1P Invalidate Word Count Register 0184 4030 L1DWIBAR L1D Writeback and Invalidate Base Address Register 0184 4034 L1DWIWC L1D Writeback and Invalidate Word Count Register Reserved 0184 4038 - 0184 4040 L1DWBAR Reserved L1D Writeback Base Address Register - for Block Writebacks 0184 4044 L1DWWC L1D Writeback Word Count Register 0184 4048 L1DIBAR L1D Invalidate Base Address Register 0184 404C L1DIWC L1D Invalidate Word Count Register 0184 4050 - 0184 4FFF - 0184 5000 L2WB 0184 5004 L2WBINV 0184 5008 L2INV 0184 500C - 0184 5024 - Reserved L2 Global Writeback Register L2 Global Writeback and Invalidate Register L2 Global Invalidate Register Reserved 0184 5028 L1PINV 0184 502C - 0184 503C - 0184 5040 L1DWB 0184 5044 L1DWBINV 0184 5048 L1DINV L1D Global Invalidate Register 0184 8000 - 0184 81FC MAR0 to MAR127 Reserved 0184 8200 - 0184 823C MAR128 to MAR143 Reserved 0184 8240 - 0184 827C MAR144 to MAR159 Reserved 0184 8280 MAR160 Controls EMIFA CE2 Range A000 0000 - A0FF FFFF 0184 8284 MAR161 Controls EMIFA CE2 Range A100 0000 - A1FF FFFF 0184 8288 MAR162 Controls EMIFA CE2 Range A200 0000 - A2FF FFFF 0184 828C MAR163 Controls EMIFA CE2 Range A300 0000 - A3FF FFFF 0184 8290 MAR164 Controls EMIFA CE2 Range A400 0000 - A4FF FFFF 0184 8294 MAR165 Controls EMIFA CE2 Range A500 0000 - A5FF FFFF C64x+ Megamodule L1P Global Invalidate Register Reserved L1D Global Writeback Register L1D Global Writeback and Invalidate Register Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 5-8. Megamodule Cache Configuration Registers (continued) HEX ADDRESS RANGE ACRONYM 0184 8298 MAR166 Controls EMIFA CE2 Range A600 0000 - A6FF FFFF REGISTER NAME 0184 829C MAR167 Controls EMIFA CE2 Range A700 0000 - A7FF FFFF 0184 82A0 MAR168 Controls EMIFA CE2 Range A800 0000 - A8FF FFFF 0184 82A4 MAR169 Controls EMIFA CE2 Range A900 0000 - A9FF FFFF 0184 82A8 MAR170 Controls EMIFA CE2 Range AA00 0000 - AAFF FFFF 0184 82AC MAR171 Controls EMIFA CE2 Range AB00 0000 - ABFF FFFF 0184 82B0 MAR172 Controls EMIFA CE2 Range AC00 0000 - ACFF FFFF 0184 82B4 MAR173 Controls EMIFA CE2 Range AD00 0000 - ADFF FFFF 0184 82B8 MAR174 Controls EMIFA CE2 Range AE00 0000 - AEFF FFFF 0184 82BC MAR175 Controls EMIFA CE2 Range AF00 0000 - AFFF FFFF 0184 82C0 MAR176 Controls EMIFA CE3 Range B000 0000 - B0FF FFFF 0184 82C4 MAR177 Controls EMIFA CE3 Range B100 0000 - B1FF FFFF 0184 82C8 MAR178 Controls EMIFA CE3 Range B200 0000 - B2FF FFFF 0184 82CC MAR179 Controls EMIFA CE3 Range B300 0000 - B3FF FFFF 0184 82D0 MAR180 Controls EMIFA CE3 Range B400 0000 - B4FF FFFF 0184 82D4 MAR181 Controls EMIFA CE3 Range B500 0000 - B5FF FFFF 0184 82D8 MAR182 Controls EMIFA CE3 Range B600 0000 - B6FF FFFF 0184 82DC MAR183 Controls EMIFA CE3 Range B700 0000 - B7FF FFFF 0184 82E0 MAR184 Controls EMIFA CE3 Range B800 0000 - B8FF FFFF 0184 82E4 MAR185 Controls EMIFA CE3 Range B900 0000 - B9FF FFFF 0184 82E8 MAR186 Controls EMIFA CE3 Range BA00 0000 - BAFF FFFF 0184 82EC MAR187 Controls EMIFA CE3 Range BB00 0000 - BBFF FFFF 0184 82F0 MAR188 Controls EMIFA CE3 Range BC00 0000 - BCFF FFFF 0184 82F4 MAR189 Controls EMIFA CE3 Range BD00 0000 - BDFF FFFF 0184 82F8 MAR190 Controls EMIFA CE3 Range BE00 0000 - BEFF FFFF 0184 82FC MAR191 Controls EMIFA CE3 Range BF00 0000 - BFFF FFFF 0184 8300 MAR192 Controls EMIFA CE4 Range C000 0000 - C0FF FFFF 0184 8304 MAR193 Controls EMIFA CE4 Range C100 0000 - C1FF FFFF 0184 8308 MAR194 Controls EMIFA CE4 Range C200 0000 - C2FF FFFF 0184 830C MAR195 Controls EMIFA CE4 Range C300 0000 - C3FF FFFF 0184 8310 MAR196 Controls EMIFA CE4 Range C400 0000 - C4FF FFFF 0184 8314 MAR197 Controls EMIFA CE4 Range C500 0000 - C5FF FFFF 0184 8318 MAR198 Controls EMIFA CE4 Range C600 0000 - C6FF FFFF 0184 831C MAR199 Controls EMIFA CE4 Range C700 0000 - C7FF FFFF 0184 8320 MAR200 Controls EMIFA CE4 Range C800 0000 - C8FF FFFF 0184 8324 MAR201 Controls EMIFA CE4 Range C900 0000 - C9FF FFFF 0184 8328 MAR202 Controls EMIFA CE4 Range CA00 0000 - CAFF FFFF 0184 832C MAR203 Controls EMIFA CE4 Range CB00 0000 - CBFF FFFF 0184 8330 MAR204 Controls EMIFA CE4 Range CC00 0000 - CCFF FFFF 0184 8334 MAR205 Controls EMIFA CE4 Range CD00 0000 - CDFF FFFF 0184 8338 MAR206 Controls EMIFA CE4 Range CE00 0000 - CEFF FFFF 0184 833C MAR207 Controls EMIFA CE4 Range CF00 0000 - CFFF FFFF 0184 8340 MAR208 Controls EMIFA CE5 Range D000 0000 - D0FF FFFF 0184 8344 MAR209 Controls EMIFA CE5 Range D100 0000 - D1FF FFFF 0184 8348 MAR210 Controls EMIFA CE5 Range D200 0000 - D2FF FFFF 0184 834C MAR211 Controls EMIFA CE5 Range D300 0000 - D3FF FFFF 0184 8350 MAR212 Controls EMIFA CE5 Range D400 0000 - D4FF FFFF Submit Documentation Feedback C64x+ Megamodule 91 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 5-8. Megamodule Cache Configuration Registers (continued) HEX ADDRESS RANGE ACRONYM 0184 8354 MAR213 Controls EMIFA CE5 Range D500 0000 - D5FF FFFF REGISTER NAME 0184 8358 MAR214 Controls EMIFA CE5 Range D600 0000 - D6FF FFFF 0184 835C MAR215 Controls EMIFA CE5 Range D700 0000 - D7FF FFFF 0184 8360 MAR216 Controls EMIFA CE5 Range D800 0000 - D8FF FFFF 0184 8364 MAR217 Controls EMIFA CE5 Range D900 0000 - D9FF FFFF 0184 8368 MAR218 Controls EMIFA CE5 Range DA00 0000 - DAFF FFFF 0184 836C MAR219 Controls EMIFA CE5 Range DB00 0000 - DBFF FFFF 0184 8370 MAR220 Controls EMIFA CE5 Range DC00 0000 - DCFF FFFF 0184 8374 MAR221 Controls EMIFA CE5 Range DD00 0000 - DDFF FFFF 0184 8378 MAR222 Controls EMIFA CE5 Range DE00 0000 - DEFF FFFF 0184 837C MAR223 Controls EMIFA CE5 Range DF00 0000 - DFFF FFFF 0184 8380 MAR224 Controls DDR2 CE0 Range E000 0000 - E0FF FFFF 0184 8384 MAR225 Controls DDR2 CE0 Range E100 0000 - E1FF FFFF 0184 8388 MAR226 Controls DDR2 CE0 Range E200 0000 - E2FF FFFF 0184 838C MAR227 Controls DDR2 CE0 Range E300 0000 - E3FF FFFF 0184 8390 MAR228 Controls DDR2 CE0 Range E400 0000 - E4FF FFFF 0184 8394 MAR229 Controls DDR2 CE0 Range E500 0000 - E5FF FFFF 0184 8398 MAR230 Controls DDR2 CE0 Range E600 0000 - E6FF FFFF 0184 839C MAR231 Controls DDR2 CE0 Range E700 0000 - E7FF FFFF 0184 83A0 MAR232 Controls DDR2 CE0 Range E800 0000 - E8FF FFFF 0184 83A4 MAR233 Controls DDR2 CE0 Range E900 0000 - E9FF FFFF 0184 83A8 MAR234 Controls DDR2 CE0 Range EA00 0000 - EAFF FFFF 0184 83AC MAR235 Controls DDR2 CE0 Range EB00 0000 - EBFF FFFF 0184 83B0 MAR236 Controls DDR2 CE0 Range EC00 0000 - ECFF FFFF 0184 83B4 MAR237 Controls DDR2 CE0 Range ED00 0000 - EDFF FFFF 0184 83B8 MAR238 Controls DDR2 CE0 Range EE00 0000 - EEFF FFFF 0184 83BC MAR239 Controls DDR2 CE0 Range EF00 0000 - EFFF FFFF 0184 83C0 -0184 83FC MAR240 to MAR255 Reserved Table 5-9. Megamodule L1/L2 Memory Protection Registers 92 HEX ADDRESS RANGE ACRONYM REGISTER NAME 0184 A000 L2MPFAR L2 memory protection fault address register 0184 A004 L2MPFSR L2 memory protection fault status register 0184 A008 L2MPFCR L2 memory protection fault command register 0184 A00C - 0184 A0FF - 0184 A100 L2MPLK0 L2 memory protection lock key bits [31:0] 0184 A104 L2MPLK1 L2 memory protection lock key bits [63:32] 0184 A108 L2MPLK2 L2 memory protection lock key bits [95:64] 0184 A10C L2MPLK3 L2 memory protection lock key bits [127:96] 0184 A110 L2MPLKCMD L2 memory protection lock key command register 0184 A114 L2MPLKSTAT L2 memory protection lock key status register Reserved 0184 A118 - 0184 A1FF - 0184 A200 L2MPPA0 L2 memory protection page attribute register 0 0184 A204 L2MPPA1 L2 memory protection page attribute register 1 0184 A208 L2MPPA2 L2 memory protection page attribute register 2 0184 A20C L2MPPA3 L2 memory protection page attribute register 3 C64x+ Megamodule Reserved Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 5-9. Megamodule L1/L2 Memory Protection Registers (continued) (1) (2) HEX ADDRESS RANGE ACRONYM 0184 A210 L2MPPA4 L2 memory protection page attribute register 4 REGISTER NAME 0184 A214 L2MPPA5 L2 memory protection page attribute register 5 0184 A218 L2MPPA6 L2 memory protection page attribute register 6 0184 A21C L2MPPA7 L2 memory protection page attribute register 7 0184 A220 L2MPPA8 L2 memory protection page attribute register 8 0184 A224 L2MPPA9 L2 memory protection page attribute register 9 0184 A228 L2MPPA10 L2 memory protection page attribute register 10 0184 A22C L2MPPA11 L2 memory protection page attribute register 11 0184 A230 L2MPPA12 L2 memory protection page attribute register 12 0184 A234 L2MPPA13 L2 memory protection page attribute register 13 0184 A238 L2MPPA14 L2 memory protection page attribute register 14 0184 A23C L2MPPA15 L2 memory protection page attribute register 15 0184 A240 L2MPPA16 L2 memory protection page attribute register 16 0184 A244 L2MPPA17 L2 memory protection page attribute register 17 0184 A248 L2MPPA18 L2 memory protection page attribute register 18 0184 A24C L2MPPA19 L2 memory protection page attribute register 19 0184 A250 L2MPPA20 L2 memory protection page attribute register 20 0184 A254 L2MPPA21 L2 memory protection page attribute register 21 0184 A258 L2MPPA22 L2 memory protection page attribute register 22 0184 A25C L2MPPA23 L2 memory protection page attribute register 23 0184 A260 L2MPPA24 L2 memory protection page attribute register 24 0184 A264 L2MPPA25 L2 memory protection page attribute register 25 0184 A268 L2MPPA26 L2 memory protection page attribute register 26 0184 A26C L2MPPA27 L2 memory protection page attribute register 27 0184 A270 L2MPPA28 L2 memory protection page attribute register 28 0184 A274 L2MPPA29 L2 memory protection page attribute register 29 0184 A278 L2MPPA30 L2 memory protection page attribute register 30 0184 A27C L2MPPA31 L2 memory protection page attribute register 31 0184 A280 - 0184 A2FC (1) - Reserved 0184 0300 - 0184 A3FF - Reserved 0184 A400 L1PMPFAR L1 program (L1P) memory protection fault address register 0184 A404 L1PMPFSR L1P memory protection fault status register L1P memory protection fault command register 0184 A408 L1PMPFCR 0184 A40C - 0184 A4FF - 0184 A500 L1PMPLK0 L1P memory protection lock key bits [31:0] 0184 A504 L1PMPLK1 L1P memory protection lock key bits [63:32] 0184 A508 L1PMPLK2 L1P memory protection lock key bits [95:64] 0184 A50C L1PMPLK3 L1P memory protection lock key bits [127:96] 0184 A510 L1PMPLKCMD L1P memory protection lock key command register L1P memory protection lock key status register Reserved 0184 A514 L1PMPLKSTAT 0184 A518 - 0184 A5FF - Reserved 0184 A600 - 0184 A63C (2) - Reserved 0184 A640 L1PMPPA16 L1P memory protection page attribute register 16 0184 A644 L1PMPPA17 L1P memory protection page attribute register 17 These addresses correspond to the L2 memory protection page attribute registers 32-63 (L2MPPA32-L2MPPA63) of the C64x+ megamaodule. These registers are not supported for the C6455 device. These addresses correspond to the L1P memory protection page attribute registers 0-15 (L1PMPPA0-L1PMPPA15) of the C64x+ megamaodule. These registers are not supported for the C6455 device. Submit Documentation Feedback C64x+ Megamodule 93 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 5-9. Megamodule L1/L2 Memory Protection Registers (continued) (3) 94 HEX ADDRESS RANGE ACRONYM REGISTER NAME 0184 A648 L1PMPPA18 L1P memory protection page attribute register 18 0184 A64C L1PMPPA19 L1P memory protection page attribute register 19 0184 A650 L1PMPPA20 L1P memory protection page attribute register 20 0184 A654 L1PMPPA21 L1P memory protection page attribute register 21 0184 A658 L1PMPPA22 L1P memory protection page attribute register 22 0184 A65C L1PMPPA23 L1P memory protection page attribute register 23 0184 A660 L1PMPPA24 L1P memory protection page attribute register 24 0184 A664 L1PMPPA25 L1P memory protection page attribute register 25 0184 A668 L1PMPPA26 L1P memory protection page attribute register 26 0184 A66C L1PMPPA27 L1P memory protection page attribute register 27 0184 A670 L1PMPPA28 L1P memory protection page attribute register 28 0184 A674 L1PMPPA29 L1P memory protection page attribute register 29 0184 A678 L1PMPPA30 L1P memory protection page attribute register 30 0184 A67C L1PMPPA31 L1P memory protection page attribute register 31 0184 A680 - 0184 ABFF - 0184 AC00 L1DMPFAR L1 data (L1D) memory protection fault address register 0184 AC04 L1DMPFSR L1D memory protection fault status register 0184 AC08 L1DMPFCR L1D memory protection fault command register 0184 AC0C - 0184 ACFF - 0184 AD00 L1DMPLK0 L1D memory protection lock key bits [31:0] 0184 AD04 L1DMPLK1 L1D memory protection lock key bits [63:32] 0184 AD08 L1DMPLK2 L1D memory protection lock key bits [95:64] 0184 AD0C L1DMPLK3 L1D memory protection lock key bits [127:96] 0184 AD10 L1DMPLKCMD L1D memory protection lock key command register 0184 AD14 L1DMPLKSTAT L1D memory protection lock key status register Reserved Reserved 0184 AD18 - 0184 ADFF - Reserved 0184 AE00 - 0184 AE3C (3) - Reserved 0184 AE40 L1DMPPA16 L1D memory protection page attribute register 16 0184 AE44 L1DMPPA17 L1D memory protection page attribute register 17 0184 AE48 L1DMPPA18 L1D memory protection page attribute register 18 0184 AE4C L1DMPPA19 L1D memory protection page attribute register 19 0184 AE50 L1DMPPA20 L1D memory protection page attribute register 20 0184 AE54 L1DMPPA21 L1D memory protection page attribute register 21 0184 AE58 L1DMPPA22 L1D memory protection page attribute register 22 0184 AE5C L1DMPPA23 L1D memory protection page attribute register 23 0184 AE60 L1DMPPA24 L1D memory protection page attribute register 24 0184 AE64 L1DMPPA25 L1D memory protection page attribute register 25 0184 AE68 L1DMPPA26 L1D memory protection page attribute register 26 0184 AE6C L1DMPPA27 L1D memory protection page attribute register 27 0184 AE70 L1DMPPA28 L1D memory protection page attribute register 28 0184 AE74 L1DMPPA29 L1D memory protection page attribute register 29 0184 AE78 L1DMPPA30 L1D memory protection page attribute register 30 0184 AE7C L1DMPPA31 L1D memory protection page attribute register 31 0184 AE80 - 0185 FFFF - Reserved These addresses correspond to the L1D memory protection page attribute registers 0-15 (L1DMPPA0-L1DMPPA15) of the C64x+ megamaodule. These registers are not supported for the C6455 device. C64x+ Megamodule Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 5-10. CPU Megamodule Bandwidth Management Registers HEX ADDRESS RANGE ACRONYM 0182 0200 EMCCPUARBE EMC CPU Arbitration Control Register REGISTER NAME 0182 0204 EMCIDMAARBE EMC IDMA Arbitration Control Register 0182 0208 EMCSDMAARBE EMC Slave DMA Arbitration Control Register 0182 020C EMCMDMAARBE EMC Master DMA Arbitration Control Resgiter 0182 0210 - 0182 02FF - 0184 1000 L2DCPUARBU Reserved L2D CPU Arbitration Control Register 0184 1004 L2DIDMAARBU L2D IDMA Arbitration Control Register 0184 1008 L2DSDMAARBU L2D Slave DMA Arbitration Control Register 0184 100C L2DUCARBU 0184 1010 - 0184 103F - L2D User Coherence Arbitration Control Resgiter 0184 1040 L1DCPUARBD L1D CPU Arbitration Control Register 0184 1044 L1DIDMAARBD L1D IDMA Arbitration Control Register 0184 1048 L1DSDMAARBD L1D Slave DMA Arbitration Control Register 0184 104C L1DUCARBD Reserved L1D User Coherence Arbitration Control Resgiter Table 5-11. Device Configuration Registers (Chip-Level Registers) HEX ADDRESS RANGE ACRONYM 02A8 0000 DEVSTAT 02A8 0004 PRI_ALLOC REGISTER NAME Device Status Register Priority Allocation Register Sets priority for Master peripherals JTAG and BSDL Identification Register Read-only. Provides 32-bit JTAG ID of the device. 02A8 0008 JTAGID 02A8 000C - 02AB FFFF - Reserved 02AC 0000 - Reserved 02AC 0004 PERLOCK Peripheral Lock Register Peripheral Configuration Register 0 02AC 0008 PERCFG0 02AC 000C - Reserved 02AC 0010 - Reserved 02AC 0014 PERSTAT0 Peripheral Status Register 0 02AC 0018 PERSTAT1 Peripheral Status Register 1 02AC 001C - 02AC 001F - 02AC 0020 EMACCFG 02AC 0024 - 02AC 002B - 02AC 002C PERCFG1 02AC 0030 - 02AC 0053 - 02AC 0054 EMUBUFPD 02AC 0058 - Submit Documentation Feedback COMMENTS Read-only. Provides status of the user's device configuration on reset. Reserved EMAC Configuration Register Reserved Peripheral Configuration Register 1 Reserved Emulator Buffer Powerdown Register Reserved C64x+ Megamodule 95 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 6 Device Operating Conditions 6.1 Absolute Maximum Ratings Over Operating Case Temperature Range (Unless Otherwise Noted) (1) Supply voltage range: CVDD (2) DVDD33 -0.5 V to 1.5 V (2) -0.5 V to 4.2 V DVDDR, DVDD18, AVDLL1, AVDLL2 (2) DVDD15 -0.5 V to 2.5 V (2) -0.5 V to 2.5 V DVDD12, DVDDRM, AVDDT, AVDDA (2) PLLV1, PLLV2 Input voltage (VI) range: -0.5 V to 1.5 V (2) -0.5 V to 2.5 V 3.3-V pins (except PCI-capable pins) -0.5 V to DVDD33 + 0.5 V PCI-capable pins -0.5 V to DVDD33 + 0.5 V RGMII pins -0.5 V to 2.5 V DDR2 memory controller pins Output voltage (VO) range: Operating case temperature range, TC: -0.5 V to 2.5 V 3.3-V pins (except PCI-capable pins) -0.5 V to DVDD33 + 0.5 V PCI-capable pins -0.5 V to DVDD33 + 0.5 V RGMII pins -0.5 V to 2.5 V DDR2 memory controller pins -0.5 V to 2.5 V (default) 0C to 90C (A version) [A-1000 device] -40°C to105°C Storage temperature range, Tstg (1) (2) -65C to 150C Stresses beyond those listed under "absolute maximum ratings" may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated under "recommended operating conditions" is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability. All voltage values are with respect to VSS. 6.2 Recommended Operating Conditions CVDD Supply voltage, Core DVDDRM Supply voltage, Core [required only for RapidIO] MIN NOM A-1000/-1000 -1200 MAX UNIT 1.2125 1.25 1.2875 V -850 -720 1.1640 1.20 1.2360 V A-1000/-1000 -1200 1.2125 1.25 1.2875 V -850 -720 1.1640 1.20 1.2360 V A-1000/-1000 -1200 1.1875 1.25 1.3125 V 1.14 1.20 1.26 V DVDD12, AVDDA, AVDDT Supply voltage, I/O [required only for RapidIO] DVDD33 Supply voltage, I/O 3.14 3.3 3.46 V DVDD18 Supply voltage, I/O 1.71 1.8 1.89 V AVDLL1 Supply voltage, I/O 1.71 1.8 1.89 V AVDLL2 Supply voltage, I/O VREFSSTL Reference voltage Supply voltage, I/O [required only for EMAC RGMII] DVDD15 VREFHSTL 96 Reference voltage Device Operating Conditions -850 -720 1.71 1.8 1.89 V 0.49DVDD18 0.50DVDD18 0.51DVDD18 V 1.71 1.8 1.89 V 1.5-V operation 1.43 1.5 1.57 V 1.8-V operation 0.855 0.9 0.945 V 1.5-V operation 0.713 0.75 0.787 V 1.8-V operation Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Recommended Operating Conditions (continued) PLLV1, PLLV2 Supply voltage, PLL VSS Supply ground 3.3 V pins (except PCI-capable and I2C pins) PCI-capable pins (1) VIH High-level input voltage I2C pins RGMII pins DDR2 memory controller pins (DC) 3.3 V pins (except PCI-capable and I2C pins) PCI-capable pins (1) VIL VOS TC (1) (2) Low-level input voltage I2C pins NOM MAX UNIT 1.71 1.8 1.89 V 0 0 0 V 2 0.5DVDD33 V DVDD33 + 0.5 0.7DVDD33 V V VREFHSTL + 0.10 DVDD15 + 0.30 V VREFSSTL + 0.125 DVDD18 + 0.3 V 0 0.8 V -0.5 0.3DVDD33 V 0 0.3DVDD33 V RGMII pins -0.3 VREFHSTL - 0.1 V DDR2 memory controller pins (DC) -0.3 VREFSSTL - 0.125 V -3.5 7.1 V commercial temperature 0 90 extended temperature -40 105 Maximum voltage during overshoot/undershoot (PCI-capable pins) (2) Operating case temperature MIN C These rated numbers are from the PCI Local Bus Specification (version 2.3). The DC specifications and AC specifications are defined in Table 4-3 and Table 4-4, respectively, of the PCI Local Bus Specification. PCI-capable pins can withstand a maximum overshoot/undershoot for up to 11 ns as required by the PCI Local Bus Specification (version 2.3). Submit Documentation Feedback Device Operating Conditions 97 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 6.3 Electrical Characteristics Over Recommended Ranges of Supply Voltage and Operating Case Temperature (Unless Otherwise Noted) PARAMETER VOH High-level output voltage TEST CONDITIONS (1) II (3) Input current [DC] PCI-capable pins (2) IOH = -0.5 mA, DVDD33 = 3.3 V 0.9DVDD33 V DVDD15 - 0.4 V 1.4 V 3.3-V pins (except PCI-capable and I2C pins) DVDD33 = MIN, IOL = MAX 0.22DVDD33 V PCI-capable pins (2) IOL = 1.5 mA, DVDD33 = 3.3 V 0.1DVDD33 V I2C pins Pulled up to 3.3 V, 3 mA sink current 0.4 V RGMII pins 0.4 V DDR2 memory controller pins 0.4 V 1 uA VI = VSS to DVDD33, pins without internal pullup or pulldown resistor -1 VI = VSS to DVDD33, pins with internal pullup resistor 50 100 400 uA VI = VSS to DVDD33, pins with internal pulldown resistor -400 -100 -50 uA -10 10 uA -1000 1000 uA 0.4 V AECLKOUT, CLKR1/GP[0], CLKX1/GP[3], SYSCLK4/GP[1], EMU[18:0], CLKR0, CLKX0 -8 mA EMIF pins (except AECLKOUT), NMI, TOUT0L, TINP0L, TOUT1L, TINP1L, PCI_EN, EMAC-capable pins (except RGMII pins), RESETSTAT, McBSP-capable pins (except CLKR1/GP[0], CLKX1/GP[3], CLKR0, CLKX0), GP[7:4], and TDO -4 mA -0.5 mA -8 mA 4 mA 3.3-V pins (except PCI-capable and I2C pins) PCI-capable pins (4) RGMII pins High-level output current [DC] PCI-capable pins (2) RGMII pins DDR2 memory controller pins (1) (2) (3) (4) 98 UNIT V I2C pins IOH MAX 0.8DVDD33 DDR2 memory controller pins VOL TYP DVDD33 = MIN, IOH = MAX RGMII pins Low-level output voltage MIN 3.3-V pins (except PCI-capable and I2C pins) 0.1DVDD33 ≤ VI ≤ 0.9DVDD33 For test conditions shown as MIN, MAX, or NOM, use the appropriate value specified in the recommended operating conditions table. These rated numbers are from the PCI Local Bus Specification (version 2.3). The DC specification and AC specifications are defined in Table 4-3 and Table 4-4, respectively, of the PCI Local Bus Specification. II applies to input-only pins and bi-directional pins. For input-only pins, II indicates the input leakage current. For bi-directional pins, II includes input leakage current and off-state (hi-Z) output leakage current. PCI input leakage currents include Hi-Z output leakage for all bidirectional buffers with 3-state outputs. Device Operating Conditions Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Electrical Characteristics Over Recommended Ranges of Supply Voltage and Operating Case Temperature (Unless Otherwise Noted) (continued) PARAMETER TEST CONDITIONS (1) MIN TYP AECLKOUT, CLKR1/GP[0], CLKX1/GP[3], SYSCLK4/GP[1], EMU[18:0], CLKR0, CLKX0 EMIF pins (except AECLKOUT), NMI, TOUT0L, TINP0L, TOUTP1L, TINP1L, PCI_EN, Low-level output EMAC-capable pins current [DC] (except RGMII pins), RESETSTAT, McBSP-capable pins (except CLKR1/GP[0], CLKX1/GP[3], CLKR0, CLKX0), GP[7:4], and TDO IOL PCI-capable pins (2) RGMII pins DDR2 memory controller pins IOZ (5) PCDD PDDD Ci Co (5) (6) Off-state output current [DC] 3.3-V pins Core supply power (6) I/O supply power (6) VO = DVDD33 or 0 V -20 MAX UNIT 8 mA 4 mA 1.5 mA 8 mA -4 mA 20 uA CVDD = 1.25 V, CPU frequency = 1200 MHz 1.76 W CVDD = 1.25 V, CPU frequency = 1000 MHz 1.66 W CVDD = 1.2 V, CPU frequency = 850 MHz 1.41 W CVDD = 1.2 V, CPU frequency = 720 MHz 1.29 W DVDD33 = 3.3 V, DVDD18 = DVDDR = 1.8 V, PLLV1 = PLLV2 = AVDLL1 = AVDLL2 = 1.8 V, CPU frequency = 1200 MHz 0.54 W DVDD33 = 3.3 V, DVDD18 = DVDDR = 1.8 V, PLLV1 = PLLV2 = AVDLL1 = AVDLL2 = 1.8 V, CPU frequency = 1000 MHz 0.53 W DVDD33 = 3.3 V, DVDD18 = DVDDR = 1.8 V, PLLV1 = PLLV2 = AVDLL1 = AVDLL2 = 1.8 V, CPU frequency = 850 MHz 0.53 W DVDD33 = 3.3 V, DVDD18 = DVDDR = 1.8 V, PLLV1 = PLLV2 = AVDLL1 = AVDLL2 = 1.8 V, CPU frequency = 720 MHz 0.52 W Input capacitance 10 pF Output capacitance 10 pF IOZ applies to output-only pins, indicating off-state (hi-Z) output leakage current. Assumes the following conditions: 60% CPU utilization; DDR2 at 50% utilization (250 MHz), 50% writes, 32 bits, 50% bit switching; two 2-MHz McBSPs at 100% utilization, 50% switching; two 75-MHz Timers at 100% utilization; device configured for HPI32 mode with pull-up resistors on HPI pins; room temperature (25°C). The actual current draw is highly application-dependent. For more details on core and I/O activity, see the TMS320C6455/54 Power Consumption Summary application report (literature number SPRAAE8). Submit Documentation Feedback Device Operating Conditions 99 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7 C64x+ Peripheral Information and Electrical Specifications 7.1 Parameter Information Tester Pin Electronics 42 Ω Data Sheet Timing Reference Point Output Under Test 3.5 nH Transmission Line Z0 = 50 Ω (see Note) 4.0 pF Device Pin (see Note) 1.85 pF NOTE: The data sheet provides timing at the device pin. For output timing analysis, the tester pin electronics and its transmission line effects must be taken into account. A transmission line with a delay of 2 ns can be used to produce the desired transmission line effect. The transmission line is intended as a load only. It is not necessary to add or subtract the transmission line delay (2 ns) from the data sheet timings. Input requirements in this data sheet are tested with an input slew rate of < 4 Volts per nanosecond (4 V/ns) at the device pin. Figure 7-1. Test Load Circuit for AC Timing Measurements The load capacitance value stated is only for characterization and measurement of AC timing signals. This load capacitance value does not indicate the maximum load the device is capable of driving. 7.1.1 3.3-V Signal Transition Levels All input and output timing parameters are referenced to 1.5 V for both "0" and "1" logic levels. Vref = 1.5 V Figure 7-2. Input and Output Voltage Reference Levels for AC Timing Measurements All rise and fall transition timing parameters are referenced to VIL MAX and VIH MIN for input clocks, VOLMAX and VOH MIN for output clocks. Vref = VIH MIN (or VOH MIN) Vref = VIL MAX (or VOL MAX) Figure 7-3. Rise and Fall Transition Time Voltage Reference Levels 7.1.2 3.3-V Signal Transition Rates All timings are tested with an input edge rate of 4 volts per nanosecond (4 V/ns). 100 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.1.3 Timing Parameters and Board Routing Analysis The timing parameter values specified in this data sheet do not include delays by board routings. As a good board design practice, such delays must always be taken into account. Timing values may be adjusted by increasing/decreasing such delays. TI recommends utilizing the available I/O buffer information specification (IBIS) models to analyze the timing characteristics correctly. To properly use IBIS models to attain accurate timing analysis for a given system, see the Using IBIS Models for Timing Analysis application report (literature number SPRA839). If needed, external logic hardware such as buffers may be used to compensate any timing differences. For inputs, timing is most impacted by the round-trip propagation delay from the DSP to the external device and from the external device to the DSP. This round-trip delay tends to negatively impact the input setup time margin, but also tends to improve the input hold time margins (see Table 7-1 and Figure 7-4). Figure 7-4 represents a general transfer between the DSP and an external device. The figure also represents board route delays and how they are perceived by the DSP and the external device. Table 7-1. Board-Level Timing Example (see Figure 7-4) NO. DESCRIPTION 1 Clock route delay 2 Minimum DSP hold time 3 Minimum DSP setup time 4 External device hold time requirement 5 External device setup time requirement 6 Control signal route delay 7 External device hold time 8 External device access time 9 DSP hold time requirement 10 DSP setup time requirement 11 Data route delay AECLKOUT (Output from DSP) 1 AECLKOUT (Input to External Device) Control Signals (A) (Output from DSP) 2 3 4 5 Control Signals (Input to External Device) 6 7 Data Signals (B) (Output from External Device) 8 10 Data Signals (B) (Input to DSP) 9 11 A. Control signals include data for Writes. B. Data signals are generated during Reads from an external device. Figure 7-4. Board-Level Input/Output Timings Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 101 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.2 Recommended Clock and Control Signal Transition Behavior All clocks and control signals must transition between VIH and VIL (or between VIL and VIH) in a monotonic manner. 7.3 Power Supplies 7.3.1 Power-Supply Sequencing TI recommends the power-supply sequence shown in Figure 7-5. After the DVDD33 supply is stable, the remaining power supplies can be powered up at the same time as CVDD as long as their supply voltage never exceeds the CVDD voltage during powerup. Some TI power-supply devices include features that facilitate power sequencing; for example, Auto-Track or Slow-Start/Enable features. For more information, visit www.ti.com/dsppower. DVDD33 1 CVDD12 2 All other power supplies Figure 7-5. Power-Supply Sequence Table 7-2. Timing Requirements for Power-Supply Sequence -720 -850 A-1000/-1000 -1200 NO. 1 tsu(DVDD33-CVDD12) Setup time, DVDD33 supply stable before CVDD12 supply stable 2 tsu(CVDD12-ALLSUP) 7.3.2 Setup time, CVDD12 supply stable before all other supplies stable UNIT MIN MAX 0.5 200 ms 0 200 ms Power-Supply Decoupling In order to properly decouple the supply planes from system noise, place as many capacitors (caps) as possible close to the DSP. These caps need to be close to the DSP, no more than 1.25 cm maximum distance to be effective. Physically smaller caps are better, such as 0402, but need to be evaluated from a yield/manufacturing point-of-view. Parasitic inductance limits the effectiveness of the decoupling capacitors, therefore physically smaller capacitors should be used while maintaining the largest available capacitance value. As with the selection of any component, verification of capacitor availability over the product's production lifetime should be considered. 7.3.3 Power-Down Operation One of the power goals for the C6455 is to reduce power dissipation due to unused peripherals. There are different ways to power down peripherals on the C6455 device. Some peripherals can be statically powered down at device reset through the device configuration pins (see Section 3.1, Device Configuration at Device Reset). Once in a static power-down state, the peripheral is held in reset and its clock is turned off. Peripherals cannot be enabled once they are in a static power-down state. To take a peripheral out of the static power-down state, a device reset must be executed with a different configuration pin setting. After device reset, all peripherals on the C6455 device are in a disabled state and must be enabled by software before being used. It is possible to enable only the peripherals needed by the application while keeping the rest disabled. Note that peripherals in a disabled state are held in reset with their clocks gated. For more information on how to enable peripherals, see Section 3.3, Peripheral Selection After Device Reset. 102 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Peripherals used for booting, like I2C and HPI, are automatically enabled after device reset. It is not possible to disable these peripherals after the boot process is complete. The C64x+ Megamodule also allows for software-driven power-down management for all of the C64x+ megamodule components through its Power-Down Controller (PDC). The CPU can power-down part or the entire C64x+ megamodule through the power-down controller based on its own execution thread or in response to an external stimulus from a host or global controller. More information on the power-down features of the C64x+ Megamodule can be found in the TMS320C64x+ Megamodule Reference Guide (literature number SPRU871). 7.3.4 Preserving Boundary-Scan Functionality on RGMII and DDR2 Memory Pins When the RGMII mode of the EMAC is not used, the DVDD15, DVDD15MON, VREFHSTL, RSV13, and RSV14 pins can be connected directly to ground (VSS) to save power. However, this will prevent boundary-scan from functioning on the RGMII pins of the EMAC. To preserve boundary-scan functionality on the RGMII pins, DVDD15, VREFHSTL, RSV14, and RSV13 should be connected as follows: • DVDD15 and DVDD15MON - connect these pins to the 1.8-V I/O supply (DVDD18). • VREFHSTL - connect to a voltage of DVDD18/2. The DVDD18/2 voltage can be generated directly from the DVDD18 supply using two 1-kΩ resistors to form a resistor divider circuit. • RSV13 - connect this pin to ground (VSS) via a 200-Ω resistor. • RSV14 - connect this pin to the 1.8-V I/O supply (DVDD18) via a 200-Ω resistor. Similarly, when the DDR2 Memory Controller is not used, the VREFSSTL, RSV11, and RSV12 pins can be connected directly to ground (VSS) to save power. However, this will prevent boundary-scan from functioning on the DDR2 Memory Controller pins. To preserve boundary-scan functionality on the DDR2 Memory Controller pins, VREFSSTL, RSV11, and RSV12 should be connected as follows: • VREFSSTL - connect to a voltage of DVDD18/2. The DVDD18/2 voltage can be generated directly from the DVDD18 supply using two 1-kΩ resistors to form a resistor divider circuit. • RSV11 - connect this pin to ground (VSS) via a 200-Ω resistor. • RSV12 - connect this pin to the 1.8-V I/O supply (DVDD18) via a 200-Ω resistor. Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 103 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.4 Enhanced Direct Memory Access (EDMA3) Controller The primary purpose of the EDMA3 is to service user-programmed data transfers between two memory-mapped slave endpoints on the device. The EDMA3 services software-driven paging transfers (e.g., data movement between external memory and internal memory), performs sorting or subframe extraction of various data structures, services event driven peripherals such as a McBSP or the UTOPIA port, and offloads data transfers from the device CPU. The EDMA3 includes the following features: • Fully orthogonal transfer description – 3 transfer dimensions: array (multiple bytes), frame (multiple arrays), and block (multiple frames) – Single event can trigger transfer of array, frame, or entire block – Independent indexes on source and destination • Flexible transfer definition: – Increment or FIFO transfer addressing modes – Linking mechanism allows for ping-pong buffering, circular buffering, and repetitive/continuous transfers, all with no CPU intervention – Chaining allows multiple transfers to execute with one event • 256 PaRAM entries – Used to define transfer context for channels – Each PaRAM entry can be used as a DMA entry, QDMA entry, or link entry • 64 DMA channels – Manually triggered (CPU writes to channel controller register), external event triggered, and chain triggered (completion of one transfer triggers another) • 4 Quick DMA (QDMA) channels – Used for software-driven transfers – Triggered upon writing to a single PaRAM set entry • 4 transfer controllers/event queues with programmable system-level priority • Interrupt generation for transfer completion and error conditions • Memory protection support – Active memory protection for accesses to PaRAM and registers • Debug visibility – Queue watermarking/threshold allows detection of maximum usage of event queues – Error and status recording to facilitate debug Each of the transfer controllers has a direct connection to the switched central resource (SCR). NOTE Although the transfer controllers are directly connected to the SCR, they can only access certain device resources. For example, only transfer controller 1 (TC1) can access the McBSPs. Table 4-1 lists the device resources that can be accessed by each of the transfer controllers. 104 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.4.1 EDMA3 Device-Specific Information The EDMA supports two addressing modes: constant addressing and increment addressing mode. Constant addressing mode is applicable to a very limited set of use cases; for most applications increment mode can be used. On the C6455 DSP, the EDMA can use constant addressing mode only with the Enhanced Viterbi-Decoder Coprocessor (VCP2) and the Enhanced Turbo Decoder Coprocessor (TCP2). Constant addressing mode is not supported by any other peripheral or internal memory in the C6455 DSP. Note that increment mode is supported by all C6455 peripherals, including VCP2 and TCP2. For more information on these two addressing modes, see the TMS320C645x DSP Enhanced DMA (EDMA3) Controller User's Guide (literature number SPRU966). A DSP interrupt must be generated at the end of an HPI or PCI boot operation to begin execution of the loaded application. Since the DSP interrupt generated by the HPI and PCI is mapped to the EDMA event DSP_EVT (DMA channel 0), it will get recorded in bit 0 of the EDMA Event Register (ER). This event must be cleared by software before triggering transfers on DMA channel 0. The EDMA3 on the C6455 DSP supports active memory protection, but it does not support proxied memory protection. 7.4.2 EDMA3 Channel Synchronization Events The EDMA3 supports up to 64 DMA channels that can be used to service system peripherals and to move data between system memories. DMA channels can be triggered by synchronization events generated by system peripherals. Table 7-3 lists the source of the synchronization event associated with each of the DMA channels. On the C6455, the association of each synchronization event and DMA channel is fixed and cannot be reprogrammed. For more detailed information on the EDMA3 module and how EDMA3 events are enabled, captured, processed, prioritized, linked, chained, and cleared, etc., see the TMS320C645x DSP Enhanced DMA (EDMA3) Controller User's Guide (literature number SPRU966). Table 7-3. C6455 EDMA3 Channel Synchronization Events (1) (1) (2) EDMA CHANNEL BINARY EVENT NAME 0 (2) 000 0000 DSP_EVT HPI/PCI-to-DSP event 1 000 0001 TEVTLO0 Timer 0 lower counter event 2 000 0010 TEVTHI0 Timer 0 high counter event 3 000 0011 - None 4 000 0100 - None 5 000 0101 - None 6 000 0110 - None 7 000 0111 - None 8 000 1000 - None 9 000 1001 - None 10 000 1010 - None 11 000 1011 - None 12 000 1100 XEVT0 McBSP0 transmit event 13 000 1101 REVT0 McBSP0 receive event 14 000 1110 XEVT1 McBSP1 transmit event 15 000 1111 REVT1 McBSP1 receive event 16 001 0000 TEVTLO1 Timer 1 lower counter event 17 001 0001 TEVTHI1 Timer 1 high counter event EVENT DESCRIPTION In addition to the events shown in this table, each of the 64 channels can also be synchronized with the transfer completion or alternate transfer completion events. For more detailed information on EDMA event-transfer chaining, see the TMS320C645x DSP Enhanced DMA (EDMA3) Controller User's Guide (literature number SPRU966). HPI boot and PCI boot are terminated using a DSP interrupt. The DSP interrupt is registered in bit 0 (channel 0) of the EDMA Event Register (ER). This event must be cleared by software before triggering transfers on DMA channel 0. Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 105 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-3. C6455 EDMA3 Channel Synchronization Events (continued) EDMA CHANNEL BINARY EVENT NAME 18-19 - - EVENT DESCRIPTION None 20 001 0100 INTDST1 21-27 - - RapidIO Interrupt 1 28 001 1100 VCP2REVT VCP2 receive event 29 001 1101 VCP2XEVT VCP2 transmit event 30 001 1110 TCP2REVT TCP2 receive event 31 001 1111 TCP2XEVT TCP2 transmit event 32 010 0000 UREVT None UTOPIA receive event 33-39 - - 40 010 1000 UXEVT 41-43 - - 44 010 1100 ICREVT I2C receive event 45 010 1101 ICXEVT I2C transmit event 46-47 - - 48 011 0000 GPINT0 GPIO event 0 49 011 0001 GPINT1 GPIO event 1 50 011 0010 GPINT2 GPIO event 2 51 011 0011 GPINT3 GPIO event 3 52 011 0100 GPINT4 GPIO event 4 53 011 0101 GPINT5 GPIO event 5 54 011 0110 GPINT6 GPIO event 6 55 011 0111 GPINT7 GPIO event 7 56 011 1000 GPINT8 GPIO event 8 57 011 1001 GPINT9 GPIO event 9 58 011 1010 GPINT10 GPIO event 10 59 011 1011 GPINT11 GPIO event 11 60 011 1100 GPINT12 GPIO event 12 61 011 1101 GPINT13 GPIO event 13 62 011 1110 GPINT14 GPIO event 14 63 011 1111 GPINT15 GPIO event 15 7.4.3 None UTOPIA transmit event None None EDMA3 Peripheral Register Description(s) Table 7-4. EDMA3 Channel Controller Registers 106 HEX ADDRESS RANGE ACRONYM 02A0 0000 PID 02A0 0004 CCCFG REGISTER NAME Peripheral ID Register EDMA3CC Configuration Register 02A0 0008 - 02A0 00FC - 02A0 0100 DCHMAP0 Reserved DMA Channel 0 Mapping Register 02A0 0104 DCHMAP1 DMA Channel 1 Mapping Register 02A0 0108 DCHMAP2 DMA Channel 2 Mapping Register 02A0 010C DCHMAP3 DMA Channel 3 Mapping Register 02A0 0110 DCHMAP4 DMA Channel 4 Mapping Register 02A0 0114 DCHMAP5 DMA Channel 5 Mapping Register 02A0 0118 DCHMAP6 DMA Channel 6 Mapping Register 02A0 011C DCHMAP7 DMA Channel 7 Mapping Register C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-4. EDMA3 Channel Controller Registers (continued) HEX ADDRESS RANGE ACRONYM 02A0 0120 DCHMAP8 DMA Channel 8 Mapping Register REGISTER NAME 02A0 0124 DCHMAP9 DMA Channel 9 Mapping Register 02A0 0128 DCHMAP10 DMA Channel 10 Mapping Register 02A0 012C DCHMAP11 DMA Channel 11 Mapping Register 02A0 0130 DCHMAP12 DMA Channel 12 Mapping Register 02A0 0134 DCHMAP13 DMA Channel 13 Mapping Register 02A0 0138 DCHMAP14 DMA Channel 14 Mapping Register 02A0 013C DCHMAP15 DMA Channel 15 Mapping Register 02A0 0140 DCHMAP16 DMA Channel 16 Mapping Register 02A0 0144 DCHMAP17 DMA Channel 17 Mapping Register 02A0 0148 DCHMAP18 DMA Channel 18 Mapping Register 02A0 014C DCHMAP19 DMA Channel 19 Mapping Register 02A0 0150 DCHMAP20 DMA Channel 20 Mapping Register 02A0 0154 DCHMAP21 DMA Channel 21 Mapping Register 02A0 0158 DCHMAP22 DMA Channel 22 Mapping Register 02A0 015C DCHMAP23 DMA Channel 23 Mapping Register 02A0 0160 DCHMAP24 DMA Channel 24 Mapping Register 02A0 0164 DCHMAP25 DMA Channel 25 Mapping Register 02A0 0168 DCHMAP26 DMA Channel 26 Mapping Register 02A0 016C DCHMAP27 DMA Channel 27 Mapping Register 02A0 0170 DCHMAP28 DMA Channel 28 Mapping Register 02A0 0174 DCHMAP29 DMA Channel 29 Mapping Register 02A0 0178 DCHMAP30 DMA Channel 30 Mapping Register 02A0 017C DCHMAP31 DMA Channel 31 Mapping Register 02A0 0180 DCHMAP32 DMA Channel 32 Mapping Register 02A0 0184 DCHMAP33 DMA Channel 33 Mapping Register 02A0 0188 DCHMAP34 DMA Channel 34 Mapping Register 02A0 018C DCHMAP35 DMA Channel 35 Mapping Register 02A0 0190 DCHMAP36 DMA Channel 36 Mapping Register 02A0 0194 DCHMAP37 DMA Channel 37 Mapping Register 02A0 0198 DCHMAP38 DMA Channel 38 Mapping Register 02A0 019C DCHMAP39 DMA Channel 39 Mapping Register 02A0 01A0 DCHMAP40 DMA Channel 40 Mapping Register 02A0 01A4 DCHMAP41 DMA Channel 41 Mapping Register 02A0 01A8 DCHMAP42 DMA Channel 42 Mapping Register 02A0 01AC DCHMAP43 DMA Channel 43 Mapping Register 02A0 01B0 DCHMAP44 DMA Channel 44 Mapping Register 02A0 01B4 DCHMAP45 DMA Channel 45 Mapping Register 02A0 01B8 DCHMAP46 DMA Channel 46 Mapping Register 02A0 01BC DCHMAP47 DMA Channel 47 Mapping Register 02A0 01C0 DCHMAP48 DMA Channel 48 Mapping Register 02A0 01C4 DCHMAP49 DMA Channel 49 Mapping Register 02A0 01C8 DCHMAP50 DMA Channel 50 Mapping Register 02A0 01CC DCHMAP51 DMA Channel 51 Mapping Register 02A0 01D0 DCHMAP52 DMA Channel 52 Mapping Register 02A0 01D4 DCHMAP53 DMA Channel 53 Mapping Register 02A0 01D8 DCHMAP54 DMA Channel 54 Mapping Register Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 107 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-4. EDMA3 Channel Controller Registers (continued) 108 HEX ADDRESS RANGE ACRONYM 02A0 01DC DCHMAP55 DMA Channel 55 Mapping Register REGISTER NAME 02A0 01E0 DCHMAP56 DMA Channel 56 Mapping Register 02A0 01E4 DCHMAP57 DMA Channel 57 Mapping Register 02A0 01E8 DCHMAP58 DMA Channel 58 Mapping Register 02A0 01EC DCHMAP59 DMA Channel 59 Mapping Register 02A0 01F0 DCHMAP60 DMA Channel 60 Mapping Register 02A0 01F4 DCHMAP61 DMA Channel 61 Mapping Register 02A0 01F8 DCHMAP62 DMA Channel 62 Mapping Register 02A0 01FC DCHMAP63 DMA Channel 63 Mapping Register 02A0 0200 QCHMAP0 QDMA Channel 0 Mapping Register 02A0 0204 QCHMAP1 QDMA Channel 1 Mapping Register 02A0 0208 QCHMAP2 QDMA Channel 2 Mapping Register QDMA Channel 3 Mapping Register 02A0 020C QCHMAP3 02A0 0210 - 02A0 021C - Reserved 02A0 0220 - 02A0 023C - Reserved 02A0 0240 DMAQNUM0 DMA Queue Number Register 0 02A0 0244 DMAQNUM1 DMA Queue Number Register 1 02A0 0248 DMAQNUM2 DMA Queue Number Register 2 02A0 024C DMAQNUM3 DMA Queue Number Register 3 02A0 0250 DMAQNUM4 DMA Queue Number Register 4 02A0 0254 DMAQNUM5 DMA Queue Number Register 5 02A0 0258 DMAQNUM6 DMA Queue Number Register 6 02A0 025C DMAQNUM7 DMA Queue Number Register 7 02A0 0260 QDMAQNUM QDMA Queue Number Register 02A0 0264 - 02A0 0280 - Reserved 02A0 0284 QUEPRI 02A0 0288 - 02A0 02FC - Queue Priority Register 02A0 0300 EMR 02A0 0304 EMRH Event MissedRegister High Event Missed Clear Register Reserved Event Missed Register 02A0 0308 EMCR 02A0 030C EMCRH 02A0 0310 QEMR 02A0 0314 QEMCR QDMA Event Missed Clear Register 02A0 0318 CCERR EDMA3CC Error Register 02A0 031C CCERRCLR 02A0 0320 EEVAL 02A0 0324 - 02A0 033C - 02A0 0340 DRAE0 02A0 0344 DRAEH0 02A0 0348 DRAE1 02A0 034C DRAEH1 02A0 0350 DRAE2 02A0 0354 DRAEH2 02A0 0358 DRAE3 02A0 035C DRAEH3 02A0 0360 DRAE4 02A0 0364 DRAEH4 Event Missed Clear Register High QDMA Event Missed Register EDMA3CC Error Clear Register Error Evaluate Register Reserved DMA Region Access Enable Register for Region 0 DMA Region Access Enable Register High for Region 0 DMA Region Access Enable Register for Region 1 DMA Region Access Enable Register High for Region 1 DMA Region Access Enable Register for Region 2 DMA Region Access Enable Register High for Region 2 DMA Region Access Enable Register for Region 3 DMA Region Access Enable Register High for Region 3 DMA Region Access Enable Register for Region 4 DMA Region Access Enable Register High for Region 4 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-4. EDMA3 Channel Controller Registers (continued) HEX ADDRESS RANGE ACRONYM 02A0 0368 DRAE5 02A0 036C DRAEH5 REGISTER NAME DMA Region Access Enable Register for Region 5 DMA Region Access Enable Register High for Region 5 02A0 0370 DRAE6 02A0 0374 DRAEH6 DMA Region Access Enable Register for Region 6 02A0 0378 DRAE7 02A0 037C DRAEH7 02A0 0380 QRAE0 QDMA Region Access Enable Register for Region 0 02A0 0384 QRAE1 QDMA Region Access Enable Register for Region 1 02A0 0388 QRAE2 QDMA Region Access Enable Register for Region 2 QDMA Region Access Enable Register for Region 3 DMA Region Access Enable Register High for Region 6 DMA Region Access Enable Register for Region 7 DMA Region Access Enable Register High for Region 7 02A0 038C QRAE3 02A0 0390 - 02A0 039C - 02A0 0400 Q0E0 Event Queue 0 Entry Register 0 02A0 0404 Q0E1 Event Queue 0 Entry Register 1 02A0 0408 Q0E2 Event Queue 0 Entry Register 2 02A0 040C Q0E3 Event Queue 0 Entry Register 3 02A0 0410 Q0E4 Event Queue 0 Entry Register 4 02A0 0414 Q0E5 Event Queue 0 Entry Register 5 02A0 0418 Q0E6 Event Queue 0 Entry Register 6 02A0 041C Q0E7 Event Queue 0 Entry Register 7 02A0 0420 Q0E8 Event Queue 0 Entry Register 8 02A0 0424 Q0E9 Event Queue 0 Entry Register 9 02A0 0428 Q0E10 Event Queue 0 Entry Register 10 02A0 042C Q0E11 Event Queue 0 Entry Register 11 02A0 0430 Q0E12 Event Queue 0 Entry Register 12 02A0 0434 Q0E13 Event Queue 0 Entry Register 13 Reserved 02A0 0438 Q0E14 Event Queue 0 Entry Register 14 02A0 043C Q0E15 Event Queue 0 Entry Register 15 02A0 0440 Q1E0 Event Queue 1 Entry Register 0 02A0 0444 Q1E1 Event Queue 1 Entry Register 1 02A0 0448 Q1E2 Event Queue 1 Entry Register 2 02A0 044C Q1E3 Event Queue 1 Entry Register 3 02A0 0450 Q1E4 Event Queue 1 Entry Register 4 02A0 0454 Q1E5 Event Queue 1 Entry Register 5 02A0 0458 Q1E6 Event Queue 1 Entry Register 6 02A0 045C Q1E7 Event Queue 1 Entry Register 7 02A0 0460 Q1E8 Event Queue 1 Entry Register 8 02A0 0464 Q1E9 Event Queue 1 Entry Register 9 02A0 0468 Q1E10 Event Queue 1 Entry Register 10 02A0 046C Q1E11 Event Queue 1 Entry Register 11 02A0 0470 Q1E12 Event Queue 1 Entry Register 12 02A0 0474 Q1E13 Event Queue 1 Entry Register 13 02A0 0478 Q1E14 Event Queue 1 Entry Register 14 02A0 047C Q1E15 Event Queue 1 Entry Register 15 02A0 0480 Q2E0 Event Queue 2 Entry Register 0 02A0 0484 Q2E1 Event Queue 2 Entry Register 1 02A0 0488 Q2E2 Event Queue 2 Entry Register 2 02A0 048C Q2E3 Event Queue 2 Entry Register 3 Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 109 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-4. EDMA3 Channel Controller Registers (continued) 110 HEX ADDRESS RANGE ACRONYM 02A0 0490 Q2E4 Event Queue 2 Entry Register 4 REGISTER NAME 02A0 0494 Q2E5 Event Queue 2 Entry Register 5 02A0 0498 Q2E6 Event Queue 2 Entry Register 6 02A0 049C Q2E7 Event Queue 2 Entry Register 7 02A0 04A0 Q2E8 Event Queue 2 Entry Register 8 02A0 04A4 Q2E9 Event Queue 2 Entry Register 9 02A0 04A8 Q2E10 Event Queue 2 Entry Register 10 02A0 04AC Q2E11 Event Queue 2 Entry Register 11 02A0 04B0 Q2E12 Event Queue 2 Entry Register 12 02A0 04B4 Q2E13 Event Queue 2 Entry Register 13 02A0 04B8 Q2E14 Event Queue 2 Entry Register 14 02A0 04BC Q2E15 Event Queue 2 Entry Register 15 02A0 04C0 Q3E0 Event Queue 3 Entry Register 0 02A0 04C4 Q3E1 Event Queue 3 Entry Register 1 02A0 04C8 Q3E2 Event Queue 3 Entry Register 2 02A0 04CC Q3E3 Event Queue 3 Entry Register 3 02A0 04D0 Q3E4 Event Queue 3 Entry Register 4 02A0 04D4 Q3E5 Event Queue 3 Entry Register 5 02A0 04D8 Q3E6 Event Queue 3 Entry Register 6 02A0 04DC Q3E7 Event Queue 3 Entry Register 7 02A0 04E0 Q3E8 Event Queue 3 Entry Register 8 02A0 04E4 Q3E9 Event Queue 3 Entry Register 9 02A0 04E8 Q3E10 Event Queue 3 Entry Register 10 02A0 04EC Q3E11 Event Queue 3 Entry Register 11 02A0 04F0 Q3E12 Event Queue 3 Entry Register 12 02A0 04F4 Q3E13 Event Queue 3 Entry Register 13 02A0 04F8 Q3E14 Event Queue 3 Entry Register 14 02A0 04FC Q3E15 Event Queue 3 Entry Register 15 02A0 0500 - 02A0 051C - Reserved 02A0 0520 - 02A0 05FC - Reserved 02A0 0600 QSTAT0 Queue Status Register 0 02A0 0604 QSTAT1 Queue Status Register 1 02A0 0608 QSTAT2 Queue Status Register 2 02A0 060C QSTAT3 Queue Status Register 3 02A0 0610 - 02A0 061C - Reserved 02A0 0620 QWMTHRA 02A0 0624 - 02A0 063C - Queue Watermark Threshold A Register 02A0 0640 CCSTAT 02A0 0644 - 02A0 06FC - Reserved 02A0 0700 - 02A0 07FC - Reserved 02A0 0800 MPFAR Memory Protection Fault Address Register 02A0 0804 MPFSR Memory Protection Fault Status Register Reserved EDMA3CC Status Register 02A0 0808 MPFCR Memory Protection Fault Command Register 02A0 080C MPPA0 Memory Protection Page Attribute Register 0 02A0 0810 MPPA1 Memory Protection Page Attribute Register 1 02A0 0814 MPPA2 Memory Protection Page Attribute Register 2 02A0 0818 MPPA3 Memory Protection Page Attribute Register 3 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-4. EDMA3 Channel Controller Registers (continued) HEX ADDRESS RANGE ACRONYM 02A0 081C MPPA4 Memory Protection Page Attribute Register 4 REGISTER NAME 02A0 0820 MPPA5 Memory Protection Page Attribute Register 5 02A0 0824 MPPA6 Memory Protection Page Attribute Register 6 02A0 0828 MPPA7 Memory Protection Page Attribute Register 7 02A0 082C - 02A0 0FFC - Reserved 02A0 1000 ER 02A0 1004 ERH Event Register Event Register High 02A0 1008 ECR Event Clear Register 02A0 100C ECRH Event Clear Register High 02A0 1010 ESR 02A0 1014 ESRH Event Set Register High 02A0 1018 CER Chained Event Register 02A0 101C CERH 02A0 1020 EER 02A0 1024 EERH Event Enable Register High Event Enable Clear Register 02A0 1028 EECR 02A0 102C EECRH 02A0 1030 EESR 02A0 1034 EESRH Event Set Register Chained Event Register High Event Enable Register Event Enable Clear Register High Event Enable Set Register Event Enable Set Register High 02A0 1038 SER 02A0 103C SERH Secondary Event Register Secondary Event Register High 02A0 1040 SECR Secondary Event Clear Register 02A0 1044 SECRH 02A0 1048 - 02A0 104C - Secondary Event Clear Register High 02A0 1050 IER 02A0 1054 IERH Interrupt Enable High Register 02A0 1058 IECR Interrupt Enable Clear Register 02A0 105C IECRH 02A0 1060 IESR 02A0 1064 IESRH 02A0 1068 IPR 02A0 106C IPRH Reserved Interrupt Enable Register Interrupt Enable Clear High Register Interrupt Enable Set Register Interrupt Enable Set High Register Interrupt Pending Register Interrupt Pending High Register 02A0 1070 ICR 02A0 1074 ICRH Interrupt Clear Register Interrupt Clear High Register 02A0 1078 IEVAL Interrupt Evaluate Register 02A0 107C - 02A0 1080 QER Reserved 02A0 1084 QEER 02A0 1088 QEECR QDMA Event Enable Clear Register 02A0 108C QEESR QDMA Event Enable Set Register 02A0 1090 QSER QDMA Secondary Event Register 02A0 1094 QSECR 02A0 1098 - 02A0 1FFF - QDMA Event Register QDMA Event Enable Register QDMA Secondary Event Clear Register Reserved Shadow Region 0 Channel Registers 02A0 2000 ER 02A0 2004 ERH Event Register High 02A0 2008 ECR Event Clear Register Submit Documentation Feedback Event Register C64x+ Peripheral Information and Electrical Specifications 111 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-4. EDMA3 Channel Controller Registers (continued) 112 HEX ADDRESS RANGE ACRONYM 02A0 200C ECRH REGISTER NAME 02A0 2010 ESR 02A0 2014 ESRH Event Set Register High 02A0 2018 CER Chained Event Register 02A0 201C CERH Event Clear Register High Event Set Register Chained Event Register Hig 02A0 2020 EER 02A0 2024 EERH Event Enable Register Event Enable Register High 02A0 2028 EECR Event Enable Clear Register 02A0 202C EECRH Event Enable Clear Register High 02A0 2030 EESR 02A0 2034 EESRH Event Enable Set Register 02A0 2038 SER 02A0 203C SERH Secondary Event Register High 02A0 2040 SECR Secondary Event Clear Register 02A0 2044 SECRH Event Enable Set Register High Secondary Event Register Secondary Event Clear Register High 02A0 2048 - 02A0 204C - 02A0 2050 IER 02A0 2054 IERH Interrupt Enable Register High 02A0 2058 IECR Interrupt Enable Clear Register 02A0 205C IECRH 02A0 2060 IESR 02A0 2064 IESRH 02A0 2068 IPR 02A0 206C IPRH 02A0 2070 ICR Reserved Interrupt Enable Register Interrupt Enable Clear Register High Interrupt Enable Set Register Interrupt Enable Set Register High Interrupt Pending Register Interrupt Pending Register High Interrupt Clear Register 02A0 2074 ICRH Interrupt Clear Register High 02A0 2078 IEVAL Interrupt Evaluate Register 02A0 207C - 02A0 2080 QER Reserved QDMA Event Register 02A0 2084 QEER 02A0 2088 QEECR QDMA Event Enable Register QDMA Event Enable Clear Register 02A0 208C QEESR QDMA Event Enable Set Register 02A0 2090 QSER QDMA Secondary Event Register 02A0 2094 QSECR 02A0 2098 - 02A0 23FF - Reserved QDMA Secondary Event Clear Register 02A0 2400 - 02A0 2497 - Shadow Region 2 Channel Registers 02A0 2498 - 02A0 25FF - Reserved 02A0 2600 - 02A0 2697 - Shadow Region 3 Channel Registers 02A0 2698 - 02A0 27FF - Reserved 02A0 2800 - 02A0 2897 - Shadow Region 4 Channel Registers 02A0 2898 - 02A0 29FF - Reserved 02A0 2A00 - 02A0 2A97 - Shadow Region 5 Channel Registers 02A0 2A98 - 02A0 2BFF - Reserved 02A0 2C00 - 02A0 2C97 - Shadow Region 6 Channel Registers 02A0 2C98 - 02A0 2DFF - Reserved 02A0 2E00 - 02A0 2E97 - Shadow Region 7 Channel Registers 02A0 2E98 - 02A0 2FFF - Reserved C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-5. EDMA3 Parameter RAM (1) HEX ADDRESS RANGE ACRONYM 02A0 4000 - 02A0 401F - Parameter Set 0 02A0 4020 - 02A0 403F - Parameter Set 1 02A0 4040 - 02A0 405F - Parameter Set 2 02A0 4060 - 02A0 407F - Parameter Set 3 02A0 4080 - 02A0 409F - Parameter Set 4 02A0 40A0 - 02A0 40BF - Parameter Set 5 02A0 40C0 - 02A0 40DF - Parameter Set 6 02A0 40E0 - 02A0 40FF - Parameter Set 7 02A0 4100 - 02A0 411F - Parameter Set 8 02A0 4120 - 02A0 413F - Parameter Set 9 ... ... 02A0 47E0 - 02A0 47FF - Parameter Set 63 02A0 4800 - 02A0 481F - Parameter Set 64 02A0 4820 - 02A0 483F - Parameter Set 65 ... (1) REGISTER NAME ... 02A0 5FC0 - 02A0 5FDF - Parameter Set 254 02A0 5FE0 - 02A0 5FFF - Parameter Set 255 The C6455 device has 256 EDMA3 parameter sets total. Each parameter set can be used as a DMA entry, a QDMA entry, or a link entry. Table 7-6. EDMA3 Transfer Controller 0 Registers HEX ADDRESS RANGE ACRONYM 02A2 0000 PID REGISTER NAME Peripheral Identification Register EDMA3TC Configuration Register 02A2 0004 TCCFG 02A2 0008 - 02A2 00FC - 02A2 0100 TCSTAT 02A2 0104 - 02A2 011C - 02A2 0120 ERRSTAT 02A2 0124 ERREN 02A2 0128 ERRCLR Error Clear Register 02A2 012C ERRDET Error Details Register 02A2 0130 ERRCMD Error Interrupt Command Register 02A2 0134 - 02A2 013C - Reserved EDMA3TC Channel Status Register Reserved Error Register Error Enable Register Reserved 02A2 0140 RDRATE 02A2 0144 - 02A2 023C - Read Rate Register 02A2 0240 SAOPT Source Active Options Register 02A2 0244 SASRC Source Active Source Address Register Reserved 02A2 0248 SACNT Source Active Count Register 02A2 024C SADST Source Active Destination Address Register 02A2 0250 SABIDX Source Active Source B-Index Register 02A2 0254 SAMPPRXY Source Active Memory Protection Proxy Register 02A2 0258 SACNTRLD Source Active Count Reload Register 02A2 025C SASRCBREF Source Active Source Address B-Reference Register Source Active Destination Address B-Reference Register 02A2 0260 SADSTBREF 02A2 0264 - 02A2 027C - 02A2 0280 DFCNTRLD Submit Documentation Feedback Reserved Destination FIFO Set Count Reload C64x+ Peripheral Information and Electrical Specifications 113 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-6. EDMA3 Transfer Controller 0 Registers (continued) HEX ADDRESS RANGE ACRONYM 02A2 0284 DFSRCBREF REGISTER NAME Destination FIFO Set Destination Address B Reference Register 02A2 0288 DFDSTBREF Destination FIFO Set Destination Address B Reference Register 02A2 028C - 02A2 02FC - 02A2 0300 DFOPT0 Reserved Destination FIFO Options Register 0 02A2 0304 DFSRC0 Destination FIFO Source Address Register 0 02A2 0308 DFCNT0 Destination FIFO Count Register 0 02A2 030C DFDST0 Destination FIFO Destination Address Register 0 02A2 0310 DFBIDX0 Destination FIFO BIDX Register 0 02A2 0314 DFMPPRXY0 Destination FIFO Memory Protection Proxy Register 0 02A2 0318 - 02A2 033C - 02A2 0340 DFOPT1 Reserved Destination FIFO Options Register 1 02A2 0344 DFSRC1 Destination FIFO Source Address Register 1 02A2 0348 DFCNT1 Destination FIFO Count Register 1 02A2 034C DFDST1 Destination FIFO Destination Address Register 1 02A2 0350 DFBIDX1 Destination FIFO BIDX Register 1 02A2 0354 DFMPPRXY1 02A2 0358 - 02A2 037C - Destination FIFO Memory Protection Proxy Register 1 02A2 0380 DFOPT2 Destination FIFO Options Register 2 02A2 0384 DFSRC2 Destination FIFO Source Address Register 2 Reserved 02A2 0388 DFCNT2 Destination FIFO Count Register 2 02A2 038C DFDST2 Destination FIFO Destination Address Register 2 02A2 0390 DFBIDX2 Destination FIFO BIDX Register 2 02A2 0394 DFMPPRXY2 02A2 0398 - 02A2 03BC - Destination FIFO Memory Protection Proxy Register 2 02A2 03C0 DFOPT3 Destination FIFO Options Register 3 02A2 03C4 DFSRC3 Destination FIFO Source Address Register 3 02A2 03C8 DFCNT3 Destination FIFO Count Register 3 02A2 03CC DFDST3 Destination FIFO Destination Address Register 3 02A2 03D0 DFBIDX3 Destination FIFO BIDX Register 3 02A2 03D4 DFMPPRXY3 02A2 03D8 - 02A2 7FFF - Reserved Destination FIFO Memory Protection Proxy Register 3 Reserved Table 7-7. EDMA3 Transfer Controller 1 Registers 114 HEX ADDRESS RANGE ACRONYM 02A2 8000 PID REGISTER NAME Peripheral Identification Register 02A2 8004 TCCFG EDMA3TC Configuration Register 02A2 8008 - 02A2 80FC - 02A2 8100 TCSTAT Reserved 02A2 8104 - 02A2 811C - 02A2 8120 ERRSTAT 02A2 8124 ERREN 02A2 8128 ERRCLR Error Clear Register 02A2 812C ERRDET Error Details Register 02A2 8130 ERRCMD Error Interrupt Command Register 02A2 8134 - 02A2 813C - 02A2 8140 RDRATE 02A2 8144 - 02A2 823C - EDMA3TC Channel Status Register Reserved Error Register Error Enable Register Reserved Read Rate Register Reserved C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-7. EDMA3 Transfer Controller 1 Registers (continued) HEX ADDRESS RANGE ACRONYM 02A2 8240 SAOPT REGISTER NAME Source Active Options Register 02A2 8244 SASRC Source Active Source Address Register 02A2 8248 SACNT Source Active Count Register 02A2 824C SADST Source Active Destination Address Register 02A2 8250 SABIDX Source Active Source B-Index Register 02A2 8254 SAMPPRXY Source Active Memory Protection Proxy Register 02A2 8258 SACNTRLD Source Active Count Reload Register 02A2 825C SASRCBREF Source Active Source Address B-Reference Register 02A2 8260 SADSTBREF Source Active Destination Address B-Reference Register 02A2 8264 - 02A2 827C - 02A2 8280 DFCNTRLD Reserved 02A2 8284 DFSRCBREF Destination FIFO Set Destination Address B Reference Register Destination FIFO Set Destination Address B Reference Register Destination FIFO Set Count Reload 02A2 8288 DFDSTBREF 02A2 828C - 02A2 82FC - 02A2 8300 DFOPT0 Destination FIFO Options Register 0 02A2 8304 DFSRC0 Destination FIFO Source Address Register 0 02A2 8308 DFCNT0 Destination FIFO Count Register 0 02A2 830C DFDST0 Destination FIFO Destination Address Register 0 02A2 8310 DFBIDX0 Destination FIFO BIDX Register 0 Reserved 02A2 8314 DFMPPRXY0 02A2 8318 - 02A2 833C - Destination FIFO Memory Protection Proxy Register 0 02A2 8340 DFOPT1 Destination FIFO Options Register 1 02A2 8344 DFSRC1 Destination FIFO Source Address Register 1 02A2 8348 DFCNT1 Destination FIFO Count Register 1 02A2 834C DFDST1 Destination FIFO Destination Address Register 1 02A2 8350 DFBIDX1 Destination FIFO BIDX Register 1 02A2 8354 DFMPPRXY1 02A2 8358 - 02A2 837C - 02A2 8380 DFOPT2 Destination FIFO Options Register 2 02A2 8384 DFSRC2 Destination FIFO Source Address Register 2 02A2 8388 DFCNT2 Destination FIFO Count Register 2 02A2 838C DFDST2 Destination FIFO Destination Address Register 2 02A2 8390 DFBIDX2 Destination FIFO BIDX Register 2 02A2 8394 DFMPPRXY2 02A2 8398 - 02A2 83BC - Reserved Destination FIFO Memory Protection Proxy Register 1 Reserved Destination FIFO Memory Protection Proxy Register 2 Reserved 02A2 83C0 DFOPT3 Destination FIFO Options Register 3 02A2 83C4 DFSRC3 Destination FIFO Source Address Register 3 02A2 83C8 DFCNT3 Destination FIFO Count Register 3 02A2 83CC DFDST3 Destination FIFO Destination Address Register 3 02A2 83D0 DFBIDX3 Destination FIFO BIDX Register 3 02A2 83D4 DFMPPRXY3 02A2 83D8 - 02A2 FFFF - Destination FIFO Memory Protection Proxy Register 3 Reserved Table 7-8. EDMA3 Transfer Controller 2 Registers HEX ADDRESS RANGE ACRONYM 02A3 0000 PID Peripheral Identification Register 02A3 0004 TCCFG EDMA3TC Configuration Register Submit Documentation Feedback REGISTER NAME C64x+ Peripheral Information and Electrical Specifications 115 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-8. EDMA3 Transfer Controller 2 Registers (continued) 116 HEX ADDRESS RANGE ACRONYM 02A3 0008 - 02A3 00FC - 02A3 0100 TCSTAT 02A3 0104 - 02A3 011C - 02A3 0120 ERRSTAT 02A3 0124 ERREN REGISTER NAME Reserved EDMA3TC Channel Status Register Reserved Error Register Error Enable Register 02A3 0128 ERRCLR Error Clear Register 02A3 012C ERRDET Error Details Register 02A3 0130 ERRCMD Error Interrupt Command Register 02A3 0134 - 02A3 013C - Reserved 02A3 0140 RDRATE 02A3 0144 - 02A3 023C - Read Rate Register 02A3 0240 SAOPT Source Active Options Register 02A3 0244 SASRC Source Active Source Address Register 02A3 0248 SACNT Source Active Count Register 02A3 024C SADST Source Active Destination Address Register 02A3 0250 SABIDX Source Active Source B-Index Register 02A3 0254 SAMPPRXY Source Active Memory Protection Proxy Register 02A3 0258 SACNTRLD Source Active Count Reload Register 02A3 025C SASRCBREF Source Active Source Address B-Reference Register Source Active Destination Address B-Reference Register Reserved 02A3 0260 SADSTBREF 02A3 0264 - 02A3 027C - 02A3 0280 DFCNTRLD 02A3 0284 DFSRCBREF Destination FIFO Set Destination Address B Reference Register 02A3 0288 DFDSTBREF Destination FIFO Set Destination Address B Reference Register 02A3 028C - 02A3 02FC - Reserved Destination FIFO Set Count Reload Reserved 02A3 0300 DFOPT0 Destination FIFO Options Register 0 02A3 0304 DFSRC0 Destination FIFO Source Address Register 0 02A3 0308 DFCNT0 Destination FIFO Count Register 0 02A3 030C DFDST0 Destination FIFO Destination Address Register 0 02A3 0310 DFBIDX0 Destination FIFO BIDX Register 0 02A3 0314 DFMPPRXY0 02A3 0318 - 02A3 033C - Destination FIFO Memory Protection Proxy Register 0 Reserved 02A3 0340 DFOPT1 Destination FIFO Options Register 1 02A3 0344 DFSRC1 Destination FIFO Source Address Register 1 02A3 0348 DFCNT1 Destination FIFO Count Register 1 02A3 034C DFDST1 Destination FIFO Destination Address Register 1 02A3 0350 DFBIDX1 Destination FIFO BIDX Register 1 02A3 0354 DFMPPRXY1 02A3 0358 - 02A3 037C - Destination FIFO Memory Protection Proxy Register 1 Reserved 02A3 0380 DFOPT2 Destination FIFO Options Register 2 02A3 0384 DFSRC2 Destination FIFO Source Address Register 2 02A3 0388 DFCNT2 Destination FIFO Count Register 2 02A3 038C DFDST2 Destination FIFO Destination Address Register 2 02A3 0390 DFBIDX2 Destination FIFO BIDX Register 2 02A3 0394 DFMPPRXY2 02A3 0398 - 02A3 03BC - 02A3 03C0 DFOPT3 Destination FIFO Memory Protection Proxy Register 2 Reserved Destination FIFO Options Register 3 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-8. EDMA3 Transfer Controller 2 Registers (continued) HEX ADDRESS RANGE ACRONYM 02A3 03C4 DFSRC3 REGISTER NAME Destination FIFO Source Address Register 3 02A3 03C8 DFCNT3 Destination FIFO Count Register 3 02A3 03CC DFDST3 Destination FIFO Destination Address Register 3 02A3 03D0 DFBIDX3 Destination FIFO BIDX Register 3 02A3 03D4 DFMPPRXY3 02A3 03D8 - 02A3 7FFF - Destination FIFO Memory Protection Proxy Register 3 Reserved Table 7-9. EDMA3 Transfer Controller 3 Registers HEX ADDRESS RANGE ACRONYM REGISTER NAME 02A3 8000 PID Peripheral Identification Register 02A3 8004 TCCFG EDMA3TC Configuration Register 02A3 8008 - 02A3 80FC - 02A3 8100 TCSTAT 02A3 8104 - 02A3 811C - 02A3 8120 ERRSTAT 02A3 8124 ERREN Reserved EDMA3TC Channel Status Register Reserved Error Register Error Enable Register 02A3 8128 ERRCLR Error Clear Register 02A3 812C ERRDET Error Details Register 02A3 8130 ERRCMD Error Interrupt Command Register 02A3 8134 - 02A3 813C - 02A3 8140 RDRATE 02A3 8144 - 02A3 823C - Reserved Read Rate Register Reserved 02A3 8240 SAOPT Source Active Options Register 02A3 8244 SASRC Source Active Source Address Register 02A3 8248 SACNT Source Active Count Register 02A3 824C SADST Source Active Destination Address Register 02A3 8250 SABIDX Source Active Source B-Index Register 02A3 8254 SAMPPRXY Source Active Memory Protection Proxy Register 02A3 8258 SACNTRLD Source Active Count Reload Register 02A3 825C SASRCBREF Source Active Source Address B-Reference Register 02A3 8260 SADSTBREF Source Active Destination Address B-Reference Register 02A3 8264 - 02A3 827C - Reserved 02A3 8280 DFCNTRLD 02A3 8284 DFSRCBREF Destination FIFO Set Count Reload Destination FIFO Set Destination Address B Reference Register 02A3 8288 DFDSTBREF Destination FIFO Set Destination Address B Reference Register 02A3 828C - 02A3 82FC - Reserved 02A3 8300 DFOPT0 Destination FIFO Options Register 0 02A3 8304 DFSRC0 Destination FIFO Source Address Register 0 02A3 8308 DFCNT0 Destination FIFO Count Register 0 02A3 830C DFDST0 Destination FIFO Destination Address Register 0 02A3 8310 DFBIDX0 Destination FIFO BIDX Register 0 02A3 8314 DFMPPRXY0 Destination FIFO Memory Protection Proxy Register 0 02A3 8318 - 02A3 833C - 02A3 8340 DFOPT1 Destination FIFO Options Register 1 02A3 8344 DFSRC1 Destination FIFO Source Address Register 1 02A3 8348 DFCNT1 Destination FIFO Count Register 1 02A3 834C DFDST1 Destination FIFO Destination Address Register 1 Submit Documentation Feedback Reserved C64x+ Peripheral Information and Electrical Specifications 117 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-9. EDMA3 Transfer Controller 3 Registers (continued) 118 HEX ADDRESS RANGE ACRONYM 02A3 8350 DFBIDX1 02A3 8354 DFMPPRXY1 REGISTER NAME Destination FIFO BIDX Register 1 Destination FIFO Memory Protection Proxy Register 1 02A3 8358 - 02A3 837C - 02A3 8380 DFOPT2 Reserved Destination FIFO Options Register 2 02A3 8384 DFSRC2 Destination FIFO Source Address Register 2 02A3 8388 DFCNT2 Destination FIFO Count Register 2 02A3 838C DFDST2 Destination FIFO Destination Address Register 2 02A3 8390 DFBIDX2 Destination FIFO BIDX Register 2 02A3 8394 DFMPPRXY2 Destination FIFO Memory Protection Proxy Register 2 02A3 8398 - 02A3 83BC - 02A3 83C0 DFOPT3 Reserved Destination FIFO Options Register 3 02A3 83C4 DFSRC3 Destination FIFO Source Address Register 3 02A3 83C8 DFCNT3 Destination FIFO Count Register 3 02A3 83CC DFDST3 Destination FIFO Destination Address Register 3 02A3 83D0 DFBIDX3 Destination FIFO BIDX Register 3 02A3 83D4 DFMPPRXY3 02A3 83D8 - 02A3 FFFF - Destination FIFO Memory Protection Proxy Register 3 Reserved C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.5 Interrupts 7.5.1 Interrupt Sources and Interrupt Controller The CPU interrupts on the C6455 device are configured through the C64x+ Megamodule Interrupt Controller. The interrupt controller allows for up to 128 system events to be programmed to any of the twelve CPU interrupt inputs (CPUINT4 - CPUINT15), the CPU exception input (EXCEP), or the advanced emulation logic. The 128 system events consist of both internally-generated events (within the megamodule) and chip-level events. Table 7-10 shows the mapping of system events. For more information on the Interrupt Controller, see the TMS320C64x+ Megamodule Reference Guide (literature number SPRU871). Table 7-10. C6455 System Event Mapping EVENT NUMBER INTERRUPT EVENT 0 (1) EVT0 Output of event combiner 0 in interrupt controller, for events 1 - 31. 1 (1) EVT1 Output of event combiner 1 in interrupt controller, for events 32 - 63. 2 (1) EVT2 Output of event combiner 2 in interrupt controller, for events 64 - 95. 3 (1) EVT3 Output of event combiner 3 in interrupt controller, for events 96 127. 4-8 Reserved 9 (1) Reserved. These system events are not connected and, therefore, not used. EMU interrupt for: 1. Host scan access 2. DTDMA transfer complete 3. AET interrupt 10 None 11 (1) EMU_RTDXRX EMU real-time data exchange (RTDX) receive complete 12 (1) EMU_RTDXTX This system event is not connected and, therefore, not used. EMU RTDX transmit complete (1) IDMA0 IDMA channel 0 interrupt 14 (1) IDMA1 IDMA channel 1 interrupt 15 DSPINT HPI/PCI-to-DSP interrupt 16 I2CINT I2C interrupt 17 MACINT 18 AEASYNCERR 19 Reserved Reserved. This system event is not connected and, therefore, not used. 20 INTDST0 RapidIO interrupt 0 21 INTDST1 RapidIO interrupt 1 22 INTDST4 RapidIO interrupt 4 23 Reserved Reserved. This system event is not connected and, therefore, not used. 24 EDMA3CC_GINT 25 - 31 Reserved Reserved. These system events are not connected and, therefore, not used. 32 VCP2_INT VCP2 error interrupt 33 TCP2_INT TCP2 error interrupt 34 - 35 Reserved Reserved. These system events are not connected and, therefore, not used. 36 UINT 37 - 39 Reserved 40 RINT0 13 (1) EMU_DTDMA DESCRIPTION Ethernet MAC interrupt EMIFA error interrupt EDMA3 channel global completion interrupt UTOPIA interrupt Reserved. These system events are not connected and, therefore, not used. McBSP0 receive interrupt This system event is generated from within the C64x+ megamodule. Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 119 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-10. C6455 System Event Mapping (continued) EVENT NUMBER INTERRUPT EVENT 41 XINT0 McBSP0 transmit interrupt 42 RINT1 McBSP1 receive interrupt McBSP1 transmit interrupt 43 XINT1 44 - 50 Reserved 51 GPINT0 GPIO interrupt 52 GPINT1 GPIO interrupt 53 GPINT2 GPIO interrupt 54 GPINT3 GPIO interrupt 55 GPINT4 GPIO interrupt 56 GPINT5 GPIO interrupt 57 GPINT6 GPIO interrupt 58 GPINT7 GPIO interrupt 59 GPINT8 GPIO interrupt 60 GPINT9 GPIO interrupt 61 GPINT10 GPIO interrupt 62 GPINT11 GPIO interrupt 63 GPINT12 GPIO interrupt 64 GPINT13 GPIO interrupt 65 GPINT14 GPIO interrupt 66 GPINT15 GPIO interrupt 67 TINTLO0 Timer 0 lower counter interrupt 68 TINTHI0 Timer 0 higher counter interrupt 69 TINTLO1 Timer 1 lower counter interrupt 70 TINTHI1 Timer 1 higher counter interrupt 71 EDMA3CC_INT0 EDMA3CC completion interrupt - Mask0 72 EDMA3CC_INT1 EDMA3CC completion interrupt - Mask1 73 EDMA3CC_INT2 EDMA3CC completion interrupt - Mask2 74 EDMA3CC_INT3 EDMA3CC completion interrupt - Mask3 75 EDMA3CC_INT4 EDMA3CC completion interrupt - Mask4 76 EDMA3CC_INT5 EDMA3CC completion interrupt - Mask5 77 EDMA3CC_INT6 EDMA3CC completion interrupt - Mask6 78 EDMA3CC_INT7 EDMA3CC completion interrupt - Mask7 79 EDMA3CC_ERRINT 80 Reserved 81 EDMA3TC0_ERRINT EDMA3TC0 error interrupt 82 EDMA3TC1_ERRINT EDMA3TC1 error interrupt 83 EDMA3TC2_ERRINT EDMA3TC2 error interrupt 84 EDMA3TC3_ERRINT EDMA3TC3 error interrupt 85 - 95 Reserved Reserved. These system events are not connected and, therefore, not used. 96 (1) INTERR Interrupt Controller dropped CPU interrupt event 97 (1) EMC_IDMAERR Reserved. Do not use. EDMA3CC error interrupt Reserved. This system event is not connected and, therefore, not used. EMC invalid IDMA parameters 98 - 99 Reserved Reserved. These system events are not connected and, therefore, not used. 100 (1) EFIINTA EFI interrupt from side A (1) EFIINTB EFI interrupt from side B 101 120 DESCRIPTION C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-10. C6455 System Event Mapping (continued) EVENT NUMBER INTERRUPT EVENT DESCRIPTION 102 - 112 Reserved Reserved. These system events are not connected and, therefore, not used. 113 (1) L1P_ED1 L1P single bit error detected during DMA read 114 - 115 Reserved Reserved. These system events are not connected and, therefore, not used. 116 (1) L2_ED1 L2 single bit error detected L2_ED2 L2 two bit error detected 117 (1) 118 (1) PDC_INT Powerdown sleep interrupt 119 Reserved Reserved. These system events are not connected and, therefore, not used. 120 (1) L1P_CMPA L1P CPU memory protection fault 121 (1) L1P_DMPA L1P DMA memory protection fault (1) L1D_CMPA L1D CPU memory protection fault 123 (1) L1D_DMPA L1D DMA memory protection fault 124 (1) L2_CMPA L2 CPU memory protection fault 125 (1) L2_DMPA L2 DMA memory protection fault 122 126 (1) 127 (1) Submit Documentation Feedback IDMA_CMPA IDMA_BUSERR IDMA CPU memory protection fault IDMA bus error interrupt C64x+ Peripheral Information and Electrical Specifications 121 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.5.2 External Interrupts Electrical Data/Timing Table 7-11. Timing Requirements for External Interrupts (1) (see Figure 7-6) -720 -850 A-1000/-1000 -1200 NO. MIN (1) UNIT MAX 1 tw(NMIL) Width of the NMI interrupt pulse low 6P ns 2 tw(NMIH) Width of the NMI interrupt pulse high 6P ns P = 1/CPU clock frequency in ns. For example, when running parts at 1000 MHz, use P = 1 ns. 1 2 NMI Figure 7-6. NMI Interrupt Timing 122 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.6 Reset Controller The reset controller detects the different type of resets supported on the C6455 device and manages the distribution of those resets throughout the device. The C6455 device has several types of resets: power-on reset, warm reset, max reset, system reset, and CPU reset. Table 7-12 explains further the types of reset, the reset initiator, and the effects of each reset on the chip. For more information on the effects of each reset on the PLL controllers and their clocks, see Section 7.6.8, Reset Electrical Data/Timing. Table 7-12. Reset Types TYPE INITIATOR EFFECT(s) Power-on Reset POR pin Resets the entire chip including the test and emulation logic. Warm Reset RESET pin Resets everything except for the test and emulation logic and PLL2. Emulator stays alive during Warm Reset. Max Reset RapidIO [through INTDST5 (1)] Same as Warm Reset. System Reset Emulator A system reset maintains memory contents and does not reset the test and emulation circuitry. The device configuration pins are also not re-latched and the state of the peripherals is also not affected. (2) CPU Local Reset HPI/PCI CPU local reset. (1) (2) INTDST5 is used generate a MAX reset only. It is not connected to the device interrupt controller. For more detailed information on the INTDST5, see the TMS320C645x DSP Serial Rapid I/O User's Guide (literature number SPRU976). On the C6455 device, peripherals can be in one of several states. These states are listed in Table 3-4. 7.6.1 Power-on Reset (POR Pin) Power-on Reset is initiated by the POR pin and is used to reset the entire chip, including the test and emulation logic. Power-on Reset is also referred to as a cold reset since the device usually goes through a power-up cycle. During power-up, the POR pin must be asserted (driven low) until the power supplies have reached their normal operating conditions. Note that a device power-up cycle is not required to initiate a Power-on Reset. The following sequence must be followed during a Power-on Reset: 1. Wait for all power supplies to reach normal operating conditions while keeping the POR pin asserted (driven low). While POR is asserted, all pins will be set to high-impedance. After the POR pin is deasserted (driven high), all Z group pins, low group pins, and high group pins are set to their reset state and will remain at their reset state until the otherwise configured by their respective peripheral. All peripherals, except those selected for boot purposes, are disabled after a Power-on Reset and must be enabled through the Device State Control registers; for more details, see Section 3.3, Peripheral Selection After Device Reset. 2. Once all the power supplies are within valid operating conditions, the POR pin must remain asserted (low) for a minimum of 256 CLKIN2 cycles. The PLL1 controller input clock, CLKIN1, and the PCI input clock, PCLK, must also be valid during this time. PCLK is only needed if the PCI module is being used. If the DDR2 memory controller and the EMAC peripheral are not needed, CLKIN2 can be tied low and, in this case, the POR pin must remain asserted (low) for a minimum of 256 CLKIN1 cycles after all power supplies have reached valid operating conditions. Within the low period of the POR pin, the following happens: – The reset signals flow to the entire chip (including the test and emulation logic), resetting modules that use reset asynchronously. – The PLL1 controller clocks are started at the frequency of the system reference clock. The clocks are propagated throughout the chip to reset modules that use reset synchronously. By default, PLL1 is in reset and unlocked. – The PLL2 controller clocks are started at the frequency of the system reference clock. PLL2 is held in reset. Since the PLL2 controller always operates in PLL mode, the system reference clock and Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 123 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 all the system clocks are invalid at this point. – The RESETSTAT pin stays asserted (low), indicating the device is in reset. 3. The POR pin may now be deasserted (driven high). When the POR pin is deasserted, the configuration pin values are latched and the PLL controllers change their system clocks to their default divide-down values. PLL2 is taken out of reset and automatically starts its locking sequence. Other device initialization is also started. 4. After device initialization is complete, the RESETSTAT pin is deasserted (driven high). By this time, PLL2 has already completed its locking sequence and is outputting a valid clock. The system clocks of both PLL controllers are allowed to finish their current cycles and then paused for 10 cycles of their respective system reference clocks. After the pause the system clocks are restarted at their default divide-by settings. 5. The device is now out of reset, device execution begins as dictated by the selected boot mode (see Section 2.4, Boot Sequence). NOTE To most of the device, reset is de-asserted only when the POR and RESET pins are both de-asserted (driven high). Therefore, in the sequence described above, if the RESET pin is held low past the low period of the POR pin, most of the device will remain in reset. The only exception being that PLL2 is taken out of reset as soon as POR is de-asserted (driven high), regardless of the state of the RESET pin. The RESET pin should not be tied together with the POR pin. 7.6.2 Warm Reset (RESET Pin) A Warm Reset has the same effects as a Power-on Reset, except that in this case, the test and emulation logic and PLL2 are not reset. The following sequence must be followed during a Warm Reset: 1. Hold the RESET pin low for a minimum of 24 CLKIN1 cycles. Within the minimum 24 CLKIN1 cycles. Within the low period of the RESET pin, the following happens: – The Z group pins, low group pins, and the high group pins are set to their reset state with one exception: The PCI pins are not affected by warm reset if the PCI module was enabled before RESET went low. In this case, PCI pins stay at whatever their value was before RESET went low. – The reset signals flow to the entire chip (excluding the test and emulation logic), resetting modules that use reset asynchronously. – The PLL1 controller is reset thereby switching back to bypass mode and resetting all its registers to their default values. PLL1 is placed in reset and loses lock. The PLL1 controller clocks start running at the frequency of the system reference clock. The clocks are propagated throughout the chip to reset modules that use reset synchronously. – The PLL2 controller is reset thereby resetting all its registers to their default values. The PLL2 controller clocks start running at the frequency of the system reference clock. PLL2 is not reset, therefore it remains locked. – The RESETSTAT pin becomes active (low), indicating the device is in reset. 2. The RESET pin may now be released (driven inactive high). When the RESET pin is released, the configuration pin values are latched and the PLL controllers immediately change their system clocks to their default divide-down values. Other device initialization is also started. 3. After device initialization is complete, the RESETSTAT pin goes inactive (high). All system clocks are allowed to finish their current cycles and then paused for 10 cycles of their respective system reference clocks. After the pause the system clocks are restarted at their default divide-by settings. 4. The device is now out of reset, device execution begins as dictated by the selected boot mode (see 124 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Section 2.4, Boot Sequence). NOTE The POR pin should be held inactive (high) throughout the Warm Reset sequence. Otherwise, if POR is activated (brought low), the minimum POR pulse width must be met. The RESET pin should not be tied together with the POR pin. 7.6.3 Max Reset A Max Reset is initiated by the RapidIO peripheral and has the same affect as a Warm Reset. 7.6.4 System Reset The emulator initiates a System Reset via the ICEPick module. This ICEPick-initiated reset is non-maskable. To invoke the maximum reset via the ICEPick module, the user can perform the following from the Code Composer Studio™ menu: Debug → Advanced Resets → System Reset. The following memory contents are maintained during a System Reset: • DDR2 Memory Controller: The DDR2 Memory Controller registers are not reset. In addition, the DDR2 SDRAM memory content is retained if the user places the DDR2 SDRAM in self-refresh mode before invoking the System Reset. • EMIFA: The contents of the memory connected to the EMIFA are retained. The EMIFA registers are not reset. Test, emulation, and clock logic are unaffected. The device configuration pins are also not re-latched and the state of the peripherals (see Table 3-4) is not affected. During a System Reset, the following happens: 1. The System Reset is initiated by the emulator. During this time, the following happens: – The reset signals flow to the entire chip resetting all the modules on chip except the test and emulation logic. – The PLL controllers are not reset. Internal system clocks are unaffected. If PLL1/PLL2 were locked before the System Reset, they remain locked. – The RESETSTAT pin goes low to indicate an internal reset is being generated. 2. After device initialization is complete, the RESETSTAT pin is deasserted (driven high). In addition, the PLL controllers pause their system clocks for about 10 cycles. At this point: – The state of the peripherals before the System Reset is not changed. For example, if McBSP0 was in the enabled state before System Reset, it will remain in the enabled state after System Reset. – The I/O pins are controlled as dictated by the DEVSTAT register. – The DDR2 Memory Controller and EMIFA registers retain their previous values. Only the DDR2 Memory Controller and EMIFA state machines are reset by the System Reset. – The PLL controllers are operating in the mode prior to System Reset. System clocks are unaffected. The boot sequence is started after the system clocks are restarted. Since the configuration pins (including the BOOTMODE[3:0] pins) are not latched with a System Reset, the previous values, as shown in the DEVSTAT register, are used to select the boot mode. 7.6.5 CPU Reset A CPU Reset is initiated by the HPI or PCI peripheral. This reset only affects the CPU. During a PCI-initiated CPU Reset, the PCI pins are set to their reset state. With the exception of the HRDY/PIRDY pin, the PCI pins have a reset state of high-impedance; the HRDY/PIRDY pin goes high during reset. Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 125 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.6.6 Reset Priority If any of the above reset sources occur simultaneously, the PLLCTRL only processes the highest priority reset request. The rest request priorities are as follows (high to low): • Power-on Reset • Maximum Reset • Warm Reset • System Reset • CPU Reset 126 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.6.7 Reset Controller Register The reset type status (RSTYPE) register (029A 00E4) is the only register for the reset controller. This register falls in the same memory range as the PLL1 controller registers [029A 0000 - 029A 01FF] (see Table 7-18). 7.6.7.1 Reset Type Status Register Description The rest type status (RSTYPE) register latches the cause of the last reset. If multiple reset sources occur simultaneously, this register latches the highest priority reset source. The reset type status register is shown in Figure 7-7 and described in Table 7-13. 31 16 Reserved R-0 15 4 3 2 1 0 Reserved SRST MRST WRST POR R-0 R-0 R-0 R-0 R-0 LEGEND: R/W = Read/Write; R = Read only; -n = value after reset Figure 7-7. Reset Type Status Register (RSTYPE) [Hex Address: 029A 00E4] Table 7-13. Reset Type Status Register (RSTYPE) Field Descriptions Bit 31:4 3 2 1 0 Field Value Reserved Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. SRST System reset. 0 System Reset was not the last reset to occur. 1 System Reset was the last reset to occur. MRST Max reset. 0 Max Reset was not the last reset to occur. 1 Max Reset was the last reset to occur. WRST Warm reset. 0 Warm Reset was not the last reset to occur. 1 Warm Reset was the last reset to occur. POR Submit Documentation Feedback Description Power-on reset. 0 Power-on Reset was not the last reset to occur. 1 Power-on Reset was the last reset to occur. C64x+ Peripheral Information and Electrical Specifications 127 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.6.8 Reset Electrical Data/Timing Table 7-14. Timing Requirements for Reset (1) (2) (3) (see Figure 7-8 and Figure 7-9) -720 -850 A-1000/-1000 -1200 NO. MIN (1) (2) (3) UNIT MAX 256D (4) ns 24C ns Setup time, boot mode and configuration pins valid before POR high or RESET high (5) 6P ns Hold time, boot mode and configuration pins valid after POR high or RESET high (5) 6P ns 5 tw(POR) Pulse duration, POR low 6 tw(RESET) Pulse duration, RESET low 7 tsu(boot) 8 th(boot) C = 1/CLKIN1 clock frequency in ns. D = 1/CLKIN2 clock frequency in ns. P = 1/CPU clock frequency in nanoseconds (ns). Note that after power-on reset, warm reset, and max reset the CPU frequency is equal to the CLKIN1 frequency divided by three due to the PLL1 controller being reset (see Section 7.6, Reset Controller). If CLKIN2 is not used, tw(POR) must be measured in terms of CLKIN1 cycles; otherwise, use CLKIN2 cycles. AEA[19:0], ABA[1:0], and PCI_EN are the boot configuration pins during device reset. Note: If a configuration pin must be routed out from the device and 3-stated (not driven), the internal pullup/pulldown (IPU/IPD) resistor should not be relied upon; TI recommends the use of an external pullup/pulldown resistor. For more detailed information on pullup/pulldown resistors and situations where external pullup/pulldown resistors are required, see Section 3.7, Pullup/Pulldown Resistors. (4) (5) Table 7-15. Switching Characteristics Over Recommended Operating Conditions During Reset (1) (see Figure 7-9) NO. PARAMETER -720 -850 A-1000/-1000 -1200 MIN 9 (1) td(PORH-RSTATH) Delay time, POR high AND RESET high to RESETSTAT high UNIT MAX 15000C ns C = 1/CLKIN1 clock frequency in ns. For Figure 7-8, note the following: • Z group consists of: all I/O/Z and O/Z pins, except for Low and High group pins. Pins become high impedance as soon as their respective power supply has reached normal operating coditions. Pins remain in high impedance until configured otherwise by their respective peripheral. • Low group consists of: UXDATA0/MTXD0/RMTXD0, UXDATA1/MTXD1/RMTXD1, UXDATA2/MTXD2/RMTXD2, UXDATA3/MTXD3/RMTXD3, UXDATA4/MTXD4/RMTXD4, and UXENB/MTXEN/RMTXEN. Pins become low as soon as their respective power supply has reached normal operating conditions. Pins remain low until configured otherwise by their respective peripheral. • High group consists of: AHOLD, ABUSREQ, and HRDY/PIRDY. Pins become high as soon as their respective power supply has reached normal operating conditions. Pins remain high until configured otherwise by their respective peripheral. The ABUSREQ pin remains high until the EMIFA is enabled through the PERCFG1 register. Once the EMIFA is enabled, the ABUSREQ pin is driven to its inactive state (driven low). • All peripherals must be enable through software following a Power-on Reset; for more details, see Section 7.6.1, Power-on Reset. • For power-supply sequence requirements, see Section 7.3.1, Power-Supply Sequencing. 128 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Power Supplies Ramping Power Supplies Stable CLKIN1 PCLK 5 POR RESET 9 RESETSTAT SYSREFCLK (PLL1C) SYSCLK2 SYSCLK3 SYSCLK4 SYSCLK5 AECLKOUT (Internal) 7 Boot and Device Configuration Pins 8 Z Group Undefined Low Group Undefined High-Z Low High High Group Undefined CLKIN2 Internal Reset PLL2C Undefined SYSREFCLK (PLL2C) Undefined PLL2 Unlocked SYSCLK1 (PLL2C) Undefined PLL2 Unlocked PLL2 Locked(A) Clock Valid A. SYSREFCLK of the PLL2 controller runs at CLKIN2 ױ0. B. SYSCLK1 of PLL2 controller runs at SYSREFCLK/2 (default). C. Power supplies, CLKIN1, CLKIN2 (if used), and PCLK (if used) must be stable before the start of tw(POR). Clock Valid (B) D. Do not tie the RESET and POR pins together. E. The RESET pin can be brought high after the POR pin has been brought high. In this case, the RESET pin must be held low for a minimum of tw(RESET) after the POR pin has been brought high. Figure 7-8. Power-Up Timing Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 129 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 CLKIN1 CLKIN2 POR 6 RESET(A)(B) 9 RESETSTAT 7 8 Boot and Device Configuration Pins(C) A. RESET should only be used after device has been powered up. For more details on the use of the RESET pin, see Section 7.6, Reset Controller. B. A reset signal is generated internally during a Warm Reset. This internal reset signal has the same effect as the RESET pin during a Warm Reset. C. Boot and Device Configurations Inputs (during reset) include: AEA[19:0], ABA[1:0], and PCI_EN. Figure 7-9. Warm Reset and Max Reset Timing 130 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.7 PLL1 and PLL1 Controller The primary PLL controller generates the input clock to the C64x+ megamodule (including the CPU) as well as most of the system peripherals such as the multichannel buffered serial ports (McBSPs) and the external memory interface (EMIF). As shown in Figure 7-10, the PLL1 controller features a software-programmable PLL multiplier controller (PLLM) and five dividers (PREDIV, D2, D3, D4, and D5). The PLL1 controller uses the device input clock CLKIN1 to generate a system reference clock (SYSREFCLK) and four system clocks (SYSCLK2, SYSCLK3, SYSCLK4, and SYSCLK5). PLL1 power is supplied externally via the PLL1 power-supply pin (PLLV1). An external EMI filter circuit must be added to PLLV1, as shown in Figure 7-10. The 1.8-V supply of the EMI filter must be from the same 1.8-V power plane supplying the I/O power-supply pin, DVDD18. TI requires EMI filter manufacturer Murata, part number NFM18CC222R1C3 or NFM18CC223R1C3. All PLL external components (C1, C2, and the EMI Filter) must be placed as close to the C64x+ DSP device as possible. For the best performance, TI recommends that all the PLL external components be on a single side of the board without jumpers, switches, or components other than the ones shown. For reduced PLL jitter, maximize the spacing between switching signals and the PLL external components (C1, C2, and the EMI Filter). The minimum CLKIN1 rise and fall times should also be observed. For the input clock timing requirements, see Section 7.7.4, PLL1 Controller Input and Output Clock Electrical Data/Timing. CAUTION The PLL controller module as described in the TMS320C645x DSP Software-Programmable Phase-Locked Loop (PLL) Controller User's Guide (literature number SPRUE56) includes a superset of features, some of which are not supported on the C6455 DSP. The following sections describe the features that are supported; it should be assumed that any feature not included in these sections is not supported by the C6455 DSP. Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 131 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 TMS320C6455 DSP +1.8 V PLLV1 C1 EMI Filter C2 560 pF 0.1 mF CLKIN1 (B) PLL1 PLLOUT PLLREF PLL1 Controller PLLEN (PLLCTL.[0]) DIVIDER PREDIV /1, /2, /3 ENA SYSREFCLK (C64x+ MegaModule) PLLM x1, x15, x20, x25, x30, x32 DIVIDER D2(A) 1 0 PREDEN (PREDIV.[15]) SYSCLK2 /3 DIVIDER D3(A) SYSCLK3 /6 DIVIDER D4 D4EN (PLLDIV4.[15]) /2, /4, ..., /16 ENA SYSCLK4 (Internal EMIF Clock Input) DIVIDER D5 D5EN (PLLDIV5.[15]) /1, /2, ..., /8 ENA SYSCLK5 (Emulation and Trace) AECLKIN (External EMIF Clock Input) /1, /2, ..., /8 GP0 CLKDIV (CTRL.[18:16]) (EMIF Input Clock) 0 1 DIVIDER D2 and DIVIDER D3 are always enabled. B. CLKIN1 is a 3.3-V signal. 1 0 SYSCLKOUT_EN (AEA[4] pin) EMIFA AECLKOUT A. AECLKINSEL (AEA[15] pin) GP1/SYSCLK4 Figure 7-10. PLL1 and PLL1 Controller 7.7.1 PLL1 Controller Device-Specific Information 7.7.1.1 Internal Clocks and Maximum Operating Frequencies As shown in Figure 7-10, the PLL1 controller generates several internal clocks including the system reference clock (SYSREFCLK), and the system clocks (SYSCLK2/3/4/5). The high-frequency clock signal SYSREFCLK is directly used to clock the C64x+ megamodule (including the CPU) and also serves as a reference clock for the rest of the DSP system. Dividers D2, D3, D4, and D5 divide the high-frequency clock SYSREFCLK to generate SYSCLK2, SYSCLK3, SYSCLK4, and SYSCLK5, respectively. The system clocks are used to clock different portions of the DSP: • SYSCLK2 is used to clock the switched central resources (SCRs), EDMA3, VCP2, TCP2, and RapidIO, as well as the data bus interfaces of the EMIFA and DDR2 Memory Controller. • SYSCLK3 clocks the PCI, HPI, UTOPIA, McBSP, GPIO, TIMER, and I2C peripherals, as well as the configuration bus of the PLL2 Controller. 132 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 • • SYSCLK4 is used as the internal clock for the EMIFA. It is also used to clock other logic within the DSP. SYSCLK5 clocks the emulation and trace logic of the DSP. The divider ratio bits of dividers D2 and D3 are fixed at ÷3 and ÷6, respectively. The divider ratio bits of dividers D4 and D5 are programmable through the PLL controller divider registers PLLDIV4 and PLLDIV5, respectively. The PLL multiplier controller (PLLM) and the dividers (D4 and D5) must be programmed after reset. There is no hardware CLKMODE selection on the C6455 device. Since the divider ratio bits for dividers D2 and D3 are fixed, the frequency of SYSCLK2 and SYSCLK3 is tied to the frequency of SYSREFCLK. However, the frequency of SYSCLK4 and SYSCLK5 depends on the configuration of dividers D4 and D5. For example, with PLLM in the PLL1 multiply control register set to 10011b (x20 mode) and a 50 MHz CLKIN1 input, the PLL output PLLOUT is set to 1200 MHz and SYSCLK2 and SYSCLK3 run at 333 MHz and 166 MHz, respectively. Divider D4 can be programmed through the PLLDIV4 register to divide SYSREFCLK by 10 such that SYSCLK4, and hence the EMIF internal clock, runs at 100 MHz. All hosts (HPI, PCI, etc.) must hold off accesses to the DSP while the frequency of its internal clocks is changing. A mechanism must be in place such that the DSP notifies the host when the PLL configuration has completed. Note that there is a minimum and maximum operating frequency for PLLREF, PLLOUT, SYSCLK4, and SYSCLK5. The PLL1 Controller must not be configured to exceed any of these constraints (certain combinations of external clock input, internal dividers, and PLL multiply ratios might not be supported). For the PLL clocks input and output frequency ranges, see Table 7-16. Table 7-16. PLL1 Clock Frequency Ranges CLOCK SIGNAL MIN CLKIN1 PLLREF (PLLEN = 1) (1) MAX UNIT 66.6 MHz 33.3 66.6 MHz PLLOUT (1) 400 1200 MHz SYSCLK4 25 166 MHz 333 MHz SYSCLK5 (1) Only applies when the PLL1 Controller is set to PLL mode (PLLEN = 1 in the PLLCTL register). 7.7.1.2 PLL1 Controller Operating Modes The PLL1 controller has two modes of operation: bypass mode and PLL mode. The mode of operation is determined by the PLLEN bit of the PLL control register (PLLCTL). In PLL mode, SYSREFCLK is generated from the device input clock CLKIN1 using the divider PREDIV and the PLL multiplier PLLM. In bypass mode, CLKIN1 is fed directly to SYSREFCLK. All hosts (HPI, PCI, etc.) must hold off accesses to the DSP while the frequency of its internal clocks is changing. A mechanism must be in place such that the DSP notifies the host when the PLL configuration has completed. 7.7.1.3 PLL1 Stabilization, Lock, and Reset Times The PLL stabilization time is the amount of time that must be allotted for the internal PLL regulators to become stable after device powerup. The PLL should not be operated until this stabilization time has expired. The PLL reset time is the amount of wait time needed when resetting the PLL (writing PLLRST = 1), in order for the PLL to properly reset, before bringing the PLL out of reset (writing PLLRST = 0). For the PLL1 reset time value, see Table 7-17. Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 133 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 The PLL lock time is the amount of time needed from when the PLL is taken out of reset (PLLRST = 1 with PLLEN = 0) to when to when the PLL controller can be switched to PLL mode (PLLEN = 1). The PLL1 lock time is given in Table 7-17. Table 7-17. PLL1 Stabilization, Lock, and Reset Times MIN PLL stabilization time TYP MAX μs PLL lock time 2000*C 128*C (1) PLL reset time (1) UNIT 150 (1) ns ns C = CLKIN1 cycle time in ns. For example, when CLKIN1 frequency is 50 MHz, use C = 20 ns. 7.7.2 PLL1 Controller Memory Map The memory map of the PLL1 controller is shown in Table 7-18. Note that only registers documented here are accessible on the TMS320C6455. Other addresses in the PLL1 controller memory map should not be modified. Table 7-18. PLL1 Controller Registers (Including Reset Controller) 134 HEX ADDRESS RANGE ACRONYM 029A 0000 - 029A 00E3 - REGISTER NAME Reserved 029A 00E4 RSTYPE 029A 00E8 - 029A 00FF - Reset Type Status Register (Reset Controller) 029A 0100 PLLCTL 029A 0104 - Reserved Reserved PLL Control Register 029A 0108 - Reserved 029A 010C - Reserved 029A 0110 PLLM 029A 0114 PREDIV 029A 0118 - Reserved 029A 011C - Reserved 029A 0120 - Reserved 029A 0124 - Reserved 029A 0128 - Reserved 029A 012C - Reserved 029A 0130 - Reserved 029A 0134 - Reserved 029A 0138 PLLCMD PLL Controller Command Register 029A 013C PLLSTAT PLL Controller Status Register 029A 0140 ALNCTL PLL Controller Clock Align Control Register 029A 0144 DCHANGE PLL Multiplier Control Register PLL Pre-Divider Control Register PLLDIV Ratio Change Status Register 029A 0148 - Reserved 029A 014C - Reserved 029A 0150 SYSTAT 029A 0154 - Reserved SYSCLK Status Register 029A 0158 - Reserved 029A 015C - Reserved 029A 0160 PLLDIV4 PLL Controller Divider 4 Register 029A 0164 PLLDIV5 PLL Controller Divider 5 Register 029A 0168 - 029B FFFF - Reserved C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.7.3 PLL1 Controller Register Descriptions This section provides a description of the PLL1 controller registers. For details on the operation of the PLL controller module, see the TMS320C645x DSP Software-Programmable Phase-Locked Loop (PLL) Controller User's Guide (literature number SPRUE56). NOTE: The PLL1 controller registers can only be accessed using the CPU or the emulator. Not all of the registers documented in the TMS320C645x DSP Software-Programmable Phase-Locked Loop (PLL) Controller User's Guide (literature number SPRUE56) are supported on the TMS320C6455. Only those registers documented in this section are supported. Furthermore, only the bits within the registers described here are supported. You should not write to any reserved memory location or change the value of reserved bits. 7.7.3.1 PLL1 Control Register The PLL control register (PLLCTL) is shown in Figure 7-11 and described in Table 7-19. 31 16 Reserved R-0 15 8 7 6 Reserved Rsvd Rsvd R-0 R/W-0 R-1 5 4 3 2 1 0 Reserved PLLRST Rsvd PLL PWRDN PLLEN R/W-0 R/W-1 R-0 R/W-0 R/W-0 LEGEND: R/W = Read/Write; R = Read only; -n = value after reset Figure 7-11. PLL1 Control Register (PLLCTL) [Hex Address: 029A 0100] Table 7-19. PLL1 Control Register (PLLCTL) Field Descriptions Bit Field Value Description 31:8 Reserved Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. 7 Reserved Reserved. Writes to this register must keep this bit as 0. 6 Reserved Reserved. The reserved bit location is always read as 1. A value written to this field has no effect. 5:4 Reserved Reserved. Writes to this register must keep this bit as 0. 3 PLLRST 2 Reserved 1 PLLPWRDN 0 PLL reset bit 0 PLL reset is released 1 PLL reset is asserted Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. PLL power-down mode select bit 0 PLL is operational 1 PLL is placed in power-down state, i.e., all analog circuitry in the PLL is turned-off PLLEN Submit Documentation Feedback PLL enable bit 0 Bypass mode. Divider PREDIV and PLL are bypassed. All the system clocks (SYSCLKn) are divided down directly from input reference clock. 1 PLL mode. Divider PREDIV and PLL are not bypassed. PLL output path is enabled. All the system clocks (SYSCLKn) are divided down from PLL output. C64x+ Peripheral Information and Electrical Specifications 135 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.7.3.2 PLL Multiplier Control Register The PLL multiplier control register (PLLM) is shown in Figure 7-12 and described in Table 7-20. The PLLM register defines the input reference clock frequency multiplier in conjunction with the PLL divider ratio bits (RATIO) in the PLL controller pre-divider register (PREDIV). 31 16 Reserved R-0 15 5 4 0 Reserved PLLM R-0 R/W-0h LEGEND: R/W = Read/Write; R = Read only; -n = value after reset Figure 7-12. PLL Multiplier Control Register (PLLM) [Hex Address: 029A 0110] Table 7-20. PLL Multiplier Control Register (PLLM) Field Descriptions Bit Field 31:5 Reserved 4:0 PLLM 136 Value 0 Description Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. PLL multiplier bits. Defines the frequency multiplier of the input reference clock in conjunction with the PLL divider ratio bits (RATIO) in PREDIV. 0h x1 multiplier rate Eh x15 multiplier rate 13h x20 multiplier rate 18h x25 multiplier rate 1Dh x30 multiplier rate 1Fh x32 multiplier rate C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.7.3.3 PLL Pre-Divider Control Register The PLL pre-divider control register (PREDIV) is shown in Figure 7-13 and described in Table 7-21. 31 16 Reserved R-0 15 14 5 4 0 PREDEN Reserved RATIO R/W-1 R-0 R/W-2h LEGEND: R/W = Read/Write; R = Read only; -n = value after reset Figure 7-13. PLL Pre-Divider Control Register (PREDIV) [Hex Address: 029A 0114] Table 7-21. PLL Pre-Divider Control Register (PREDIV) Field Descriptions Bit Field 31:16 Reserved 15 PREDEN 14:5 Reserved 4:0 RATIO Value 0 Description Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. Pre-divider enable bit. 0 Pre-divider is disabled. No clock output. 1 Pre-divider is enabled. 0 Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. 0-1Fh 0 ÷1. Divide frequency by 1. 1h ÷2. Divide frequency by 2. 2h ÷3. Divide frequency by 3. 3h-1Fh Submit Documentation Feedback Divider ratio bits. Reserved, do not use. C64x+ Peripheral Information and Electrical Specifications 137 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.7.3.4 PLL Controller Divider 4 Register The PLL controller divider 4 register (PLLDIV4) is shown in Figure 7-14 and described in Table 7-22. Besides being used as the EMIFA internal clock, SYSCLK4 is also used in other parts of the system. Disabling this clock will cause unpredictable system behavior. Therefore, the PLLDIV4 register should never be used to disable SYSCLK4. 31 16 Reserved R-0 15 14 5 4 0 D4EN Reserved RATIO R/W-1 R-0 R/W-3 LEGEND: R/W = Read/Write; R = Read only; -n = value after reset Figure 7-14. PLL Controller Divider 4 Register (PLLDIV4) [Hex Address: 029A 0160] Table 7-22. PLL Controller Divider 4 Register (PLLDIV4) Field Descriptions Bit 31:16 15 Field Reserved Value 0 D4EN 14:5 Reserved 4:0 RATIO Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. Divider 4 enable bit. 0 Divider 4 is disabled. No clock output. 1 Divider 4 is enabled. 0 Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. 0-1Fh Divider ratio bits. 0 ÷2. Divide frequency by 2. 1h ÷4. Divide frequency by 4. 2h ÷6. Divide frequency by 6. 3h ÷8. Divide frequency by 8. 4h-7h 8h-1Fh 138 Description ÷10 to ÷16. Divide frequency by 10 to divide frequency by 16. Reserved, do not use. C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.7.3.5 PLL Controller Divider 5 Register The PLL controller divider 5 register (PLLDIV5) is shown in Figure 7-15 and described in Table 7-23. 31 16 Reserved R-0 15 14 5 4 0 D5EN Reserved RATIO R/W-1 R-0 R/W-3 LEGEND: R/W = Read/Write; R = Read only; -n = value after reset Figure 7-15. PLL Controller Divider 5 Register (PLLDIV5) [Hex Address: 029A 0164] Table 7-23. PLL Controller Divider 5 Register (PLLDIV5) Field Descriptions Bit 31:16 15 Field Value Reserved 0 D5EN 14:5 Reserved 4:0 RATIO Description Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. Divider 5 enable bit. 0 Divider 5 is disabled. No clock output. 1 Divider 5 is enabled. 0 Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. 0-1Fh 0 ÷1. Divide frequency by 1. 1h ÷2. Divide frequency by 2. 2h ÷3. Divide frequency by 3. 3h ÷4. Divide frequency by 4. 4h-7h 8h-1Fh Submit Documentation Feedback Divider ratio bits. ÷5 to ÷8. Divide frequency by 5 to divide frequency by 8. Reserved, do not use. C64x+ Peripheral Information and Electrical Specifications 139 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.7.3.6 PLL Controller Command Register The PLL controller command register (PLLCMD) contains the command bit for GO operation. PLLCMD is shown in Figure 7-16 and described in Table 7-24. 31 16 Reserved R-0 15 2 1 0 Reserved Rsvd GOSET R-0 R/W-0 R/W-0 LEGEND: R/W = Read/Write; R = Read only; -n = value after reset Figure 7-16. PLL Controller Command Register (PLLCMD) [Hex Address: 029A 0138] Table 7-24. PLL Controller Command Register (PLLCMD) Field Descriptions Bit Field Value Reserved 1 Reserved Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. 0 GOSET GO operation command for SYSCLK rate change and phase alignment. Before setting this bit to 1 to initiate a GO operation, check the GOSTAT bit in the PLLSTAT register to ensure all previous GO operations have completed. 140 0 Description 31:2 Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. 0 No effect. Write of 0 clears bit to 0. 1 Initiates GO operation. Write of 1 initiates GO operation. Once set, GOSET remains set but further writes of 1 can initiate the GO operation. C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.7.3.7 PLL Controller Status Register The PLL controller status register (PLLSTAT) shows the PLL controller status. PLLSTAT is shown in Figure 7-17 and described in Table 7-25. 31 16 Reserved R-0 15 1 0 Reserved GOSTAT R-0 R-0 LEGEND: R/W = Read/Write; R = Read only; -n = value after reset Figure 7-17. PLL Controller Status Register (PLLSTAT) [Hex Address: 029A 013C] Table 7-25. PLL Controller Status Register (PLLSTAT) Field Descriptions Bit Field 31:1 Reserved 0 GOSTAT Value Submit Documentation Feedback 0 Description Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. GO operation status. 0 GO operation is not in progress. SYSCLK divide ratios are not being changed. 1 GO operation is in progress. SYSCLK divide ratios are being changed. C64x+ Peripheral Information and Electrical Specifications 141 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.7.3.8 PLL Controller Clock Align Control Register The PLL controller clock align control register (ALNCTL) is shown in Figure 7-18 and described in Table 7-26. 31 16 Reserved R-0 15 5 4 3 2 0 Reserved ALN5 ALN4 Reserved R-0 R-1 R-1 R-1 LEGEND: R/W = Read/Write; R = Read only; -n = value after reset Figure 7-18. PLL Controller Clock Align Control Register (ALNCTL) [Hex Address: 029A 0140] Table 7-26. PLL Controller Clock Align Control Register (ALNCTL) Field Descriptions Bit Field 31:5 Reserved 4:3 ALNn 2:0 142 Reserved Value 0 Description Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. SYSCLKn alignment. Do not change the default values of these fields. 0 Do not align SYSCLKn to other SYSCLKs during GO operation. If SYSn in DCHANGE is set to 1, SYSCLKn switches to the new ratio immediately after the GOSET bit in PLLCMD is set. 1 Align SYSCLKn to other SYSCLKs selected in ALNCTL when the GOSET bit in PLLCMD is set. The SYSCLKn ratio is set to the ratio programmed in the RATIO bit in PLLDIVn. 0 Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.7.3.9 PLLDIV Ratio Change Status Register Whenever a different ratio is written to the PLLDIVn registers, the PLLCTRL flags the change in the PLLDIV ratio change status registers (DCHANGE). During the GO operation, the PLL controller will only change the divide ratio of the SYSCLKs with the bit set in DCHANGE. Note that changed clocks will be automatically aligned to other clocks. The PLLDIV divider ratio change status register is shown in Figure 7-19 and described in Table 7-27. 31 16 Reserved R-0 15 5 4 3 2 0 Reserved SYS5 SYS4 Reserved R-0 R-0 R-0 R-0 LEGEND: R/W = Read/Write; R = Read only; -n = value after reset Figure 7-19. PLLDIV Divider Ratio Change Status Register (DCHANGE) [Hex Address: 029A 0144] Table 7-27. PLLDIV Divider Ratio Change Status Register (DCHANGE) Field Descriptions Bit 31:5 4 3 2:0 Field Value Reserved 0 SYS5 Submit Documentation Feedback Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. Identifies when the SYSCLK5 divide ratio has been modified. 0 SYSCLK5 ratio has not been modified. When GOSET is set, SYSCLK5 will not be affected. 1 SYSCLK5 ratio has been modified. When GOSET is set, SYSCLK5 will change to the new ratio. SYS4 Reserved Description Identifies when the SYSCLK4 divide ratio has been modified. 0 SYSCLK4 ratio has not been modified. When GOSET is set, SYSCLK4 will not be affected. 1 SYSCLK4 ratio has been modified. When GOSET is set, SYSCLK4 will change to the new ratio. 0 Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. C64x+ Peripheral Information and Electrical Specifications 143 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.7.3.10 SYSCLK Status Register The SYSCLK status register (SYSTAT) shows the status of the system clocks (SYSCLKn). SYSTAT is shown in Figure 7-20 and described in Table 7-28. 31 16 Reserved R-0 15 8 Reserved R-0 7 5 4 3 2 1 0 Reserved SYS5ON SYS4ON SYS3ON SYS2ON Reserved R-0 R-1 R-1 R-1 R-1 R-1 LEGEND: R = Read only; -n = value after reset Figure 7-20. SYSCLK Status Register (SYSTAT) [Hex Address: 029A 0150] Table 7-28. SYSCLK Status Register (SYSTAT) Field Descriptions Bit Field 31:4 Reserved 4:1 SYSnON 0 144 Reserved Value 0 Description Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. SYSCLKn on status. 0 SYSCLKn is gated. 1 SYSCLKn is on. 1 Reserved. The reserved bit location is always read as 1. A value written to this field has no effect. C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.7.4 PLL1 Controller Input and Output Clock Electrical Data/Timing Table 7-29. Timing Requirements for CLKIN1 Devices (1) (2) (3) (see Figure 7-21) -720 -850 A-1000/-1000 -1200 NO. (1) (2) (3) (4) PLL MODES x1 (Bypass), x15, x20, x25, x30, x32 MIN MAX 15 30.3 UNIT 1 tc(CLKIN1) Cycle time, CLKIN1 (4) 2 tw(CLKIN1H) Pulse duration, CLKIN1 high 0.4C ns 3 tw(CLKIN1L) Pulse duration, CLKIN1 low 0.4C ns 4 tt(CLKIN1) Transition time, CLKIN1 1.2 ns 5 tJ(CLKIN1) Period jitter (peak-to-peak), CLKIN1 100 ps ns The reference points for the rise and fall transitions are measured at 3.3 V VIL MAX and VIH MIN. For more details on the PLL multiplier factors (x1 [BYPASS], x 15, x20, x25, x30, x32), see Section 7.7.1.2, PLL1 Controller Operating Modes. C = CLKIN1 cycle time in ns. For example, when CLKIN1 frequency is 50 MHz, use C = 20 ns. The PLL1 multiplier factors (x1 [BYPASS], x 15, x20, x25, x30, x32) further limit the MIN and MAX values for tc(CLKIN1). For more detailed information on these limitations, see Section 7.7.1.1, Internal Clocks and Maximum Operating Frequencies. 1 5 4 2 CLKIN1 3 4 Figure 7-21. CLKIN1 Timing Table 7-30. Switching Characteristics Over Recommended Operating Conditions for SYSCLK4 [CPU/8 - CPU/12] (1) (2) (see Figure 7-22) NO. (1) (2) -720 -850 A-1000/-1000 -1200 PARAMETER MIN MAX UNIT 2 tw(CKO3H) Pulse duration, SYSCLK4 high 4P – 0.7 6P + 0.7 ns 3 tw(CKO3L) Pulse duration, SYSCLK4 low 4P – 0.7 6P + 0.7 ns 4 tt(CKO3) Transition time, SYSCLK4 1 ns The reference points for the rise and fall transitions are measured at 3.3 V VOL MAX and VOH MIN. P = 1/CPU clock frequency in nanoseconds (ns) 4 2 SYSCLK4 3 4 Figure 7-22. SYSCLK4 Timing Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 145 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.8 PLL2 and PLL2 Controller The secondary PLL controller generates interface clocks for the Ethernet media access controller (EMAC) and the DDR2 memory controller. As shown in Figure 7-23, the PLL2 controller features a PLL multiplier controller and one divider (D1). The PLL multiplier is fixed to a x20 multiplier rate and the divider D1 can be programmed to a ÷2 or ÷5 mode. PLL2 power is supplied externally via the PLL2 power supply (PLLV2). An external PLL filter circuit must be added to PLLV2 as shown in Figure 7-23. The 1.8-V supply for the EMI filter must be from the same 1.8-V power plane supplying the I/O power-supply pin, DVDD18. TI requires EMI filter manufacturer Murata, part number NFM18CC222R1C3 or NFM18CC223R1C3. All PLL external components (C161, C162, and the EMI Filter) should be placed as close to the C64x+ DSP device as possible. For the best performance, TI requires that all the PLL external components be on a single side of the board without jumpers, switches, or components other than the ones shown. For reduced PLL jitter, maximize the spacing between switching signals and the PLL external components (C161, C162, and the EMI Filter). The minimum CLKIN2 rise and fall times should also be observed. For the input clock timing requirements, see Section 7.8.4, PLL2 Controller Input Clock Electrical Data/Timing. CAUTION The PLL controller module as described in the TMS320C645x DSP Software-Programmable Phase-Locked Loop (PLL) Controller User's Guide (literature number SPRUE56) includes a superset of features, some of which are not supported on the C6455 DSP. The following sections describe the features that are supported; it should be assumed that any feature not included in these sections is not supported by the C6455 DSP. TMS320C6455 DSP SYSCLK3 (From PLL1 Controller) PLLV2 +1.8 V SYSCLK2 (From PLL1 Controller) 560 pF 0.1 mF EMI Filter C161 C162 PLLREF CLKIN2 PLL2 PLLOUT DDR2 Memory Controller /2 (B)(C) PLLM x20 DIVIDER D1 1 0 SYSREFCLK /x (A) SYSCLK1 EMAC 1 PLL2 Controller A. /x must be programmed to /2 for GMII (default) and to /5 for RGMII. B. If EMAC is enabled with RGMII, or GMII, CLKIN2 frequency must be 25 MHz. C. CLKIN2 is a 3.3-V signal. Figure 7-23. PLL2 Block Diagram 146 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.8.1 PLL2 Controller Device-Specific Information 7.8.1.1 Internal Clocks and Maximum Operating Frequencies As shown in Figure 7-23, the output of PLL2, PLLOUT, is divided by 2 and directly fed to the DDR2 memory controller. This clock is used by the DDR2 memory controller to generate DDR2CLKOUT and DDR2CLKOUT. Note that, internally, the data bus interface of the DDR2 memory controller is clocked by SYSCLK2 of the PLL1 controller. The PLLOUT/2 clock is also fed back into the PLL2 controller where it becomes SYSREFCLK. Divider D1 of the PLL2 controller generates SYSCLK1 for the Ethernet media access controller (EMAC). The EMAC uses SYSCLK1 to generate the necessary clock for each of its interfaces. Divider D1 should be programmed to ÷2 mode [default] when using the Gigabit Media Independent Interface (GMII) mode and to ÷5 mode when using the Reduce Gigabit Media Independent Interface (RGMII). Divider D1 is software programmable and, if necessary, must be programmed after device reset to ÷5 when the RGMII mode of the EMAC is used. Note that, internally, the data bus interface of the EMAC is clocked by SYSCLK3 of the PLL2 controller. Note that there is a minimum and maximum operating frequency for PLLREF, PLLOUT, and SYSCLK1. The clock generator must not be configured to exceed any of these constraints. For the PLL clocks input and output frequency ranges, see Table 7-31. Also, when EMAC is enabled with RGMII or GMII, CLKIN2 must be 25 MHz. Table 7-31. PLL2 Clock Frequency Ranges MIN MAX UNIT PLLREF (PLLEN = 1) CLOCK SIGNAL 12.5 26.7 MHz PLLOUT 250 533 MHz SYSCLK1 (1) 50 125 MHz (1) SYSCLK1 restriction applies only when the EMAC is enabled and the RGMII or GMII modes are used. SYSCLK1 must be programmed to 125 MHz when the GMII mode is used and to 50 MHz when the RGMII mode is used. 7.8.1.2 PLL2 Controller Operating Modes Unlike the PLL1 controller which can operate in bypass and a PLL mode, the PLL2 controller only operates in PLL mode. In this mode, SYSREFCLK is generated outside the PLL2 controller by dividing the output of PLL2 by two. The PLL2 controller is affected by power-on reset, warm reset, and max reset. During these resets the PLL2 controller registers get reset to their default values. The internal clocks of the PLL2 controller are also affected as described in Section 7.6, Reset Controller. PLL2 is only unlocked during the power-up sequence (see Section 7.6, Reset Controller ) and is locked by the time the RESETSTAT pin goes high. It does not lose lock during any of the other resets. Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 147 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.8.2 PLL2 Controller Memory Map The memory map of the PLL2 controller is shown in Table 7-32. Note that only registers documented here are accessible on the TMS320C6455. Other addresses in the PLL2 controller memory map should not be modified. Table 7-32. PLL2 Controller Registers HEX ADDRESS RANGE 7.8.3 ACRONYM DESCRIPTION 029C 0000 - 029C 0114 - 029C 0118 PLLDIV1 Reserved 029C 011C - 029C 0134 - 029C 0138 PLLCMD PLL Controller Command Register 029C 013C PLLSTAT PLL Controller Status Register 029C 0140 ALNCTL PLL Controller Clock Align Control Register 029C 0144 DCHANGE PLL Controller Divider 1 Register Reserved PLLDIV Ratio Change Status Register 029C 0148 - Reserved 029C 014C - Reserved 029C 0150 SYSTAT SYSCLK Status Register 029C 0154 - 029C 0190 - Reserved 029C 0194 - 029C 01FF - Reserved 029C 0200 - 029C FFFF - Reserved PLL2 Controller Register Descriptions This section provides a description of the PLL2 controller registers. For details on the operation of the PLL controller module, see the TMS320C645x DSP Software-Programmable Phase-Locked Loop (PLL) Controller User's Guide (literature number SPRUE56). NOTE: The PLL2 controller registers can only be accessed using the CPU or the emulator. Not all of the registers documented in the TMS320C645x DSP Software-Programmable Phase-Locked Loop (PLL) Controller User's Guide (literature number SPRUE56) are supported on the TMS320C6455. Only those registers documented in this section are supported. Furthermore, only the bits within the registers described here are supported. You should not write to any reserved memory location or change the value of reserved bits. 148 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.8.3.1 PLL Controller Divider 1 Register The PLL controller divider 1 register (PLLDIV1) is shown in Figure 7-24 and described in Table 7-33. 31 16 Reserved R-0 15 14 5 4 0 D1EN Reserved RATIO R/W-1 R-0 R/W-1 LEGEND: R/W = Read/Write; R = Read only; -n = value after reset Figure 7-24. PLL Controller Divider 1 Register (PLLDIV1) [Hex Address: 029C 0118] Table 7-33. PLL Controller Divider 1 Register (PLLDIV1) Field Descriptions Bit 31:16 15 Field Value Reserved 0 D1EN 14:5 Reserved 4:0 RATIO Description Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. Divider D1 enable bit. 0 Divider D1 is disabled. No clock output. 1 Divider D1 is enabled. 0 Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. 0-1Fh 1h ÷2. Divide frequency by 2. 4h ÷5. Divide frequency by 5. Others Submit Documentation Feedback Divider ratio bits. Reserved C64x+ Peripheral Information and Electrical Specifications 149 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.8.3.2 PLL Controller Command Register The PLL controller command register (PLLCMD) contains the command bit for GO operation. PLLCMD is shown in Figure 7-25 and described in Table 7-34. 31 16 Reserved R-0 15 2 1 0 Reserved Rsvd GOSET R-0 R/W-0 R/W-0 LEGEND: R/W = Read/Write; R = Read only; -n = value after reset Figure 7-25. PLL Controller Command Register (PLLCMD) [Hex Address: 029C 0138] Table 7-34. PLL Controller Command Register (PLLCMD) Field Descriptions Bit Field Value Reserved 1 Reserved Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. 0 GOSET GO operation command for SYSCLK rate change and phase alignment. Before setting this bit to 1 to initiate a GO operation, check the GOSTAT bit in the PLLSTAT register to ensure all previous GO operations have completed. 150 0 Description 31:2 Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. 0 No effect. Write of 0 clears bit to 0. 1 Initiates GO operation. Write of 1 initiates GO operation. Once set, GOSET remains set but further writes of 1 can initiate the GO operation. C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.8.3.3 PLL Controller Status Register The PLL controller status register (PLLSTAT) shows the PLL controller status. PLLSTAT is shown in Figure 7-26 and described in Table 7-35. 31 16 Reserved R-0 15 1 0 Reserved GOSTAT R-0 R-0 LEGEND: R/W = Read/Write; R = Read only; -n = value after reset Figure 7-26. PLL Controller Status Register (PLLSTAT) [Hex Address: 029C 013C] Table 7-35. PLL Controller Status Register (PLLSTAT) Field Descriptions Bit Field 31:1 Reserved 0 GOSTAT Value 0 Description Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. GO operation status. 0 Go operation is not in progress. SYSCLK divide ratios are not being changed. 1 GO operation is in progress. SYSCLK divide ratios are being changed. 7.8.3.4 PLL Controller Clock Align Control Register The PLL controller clock align control register (ALNCTL) is shown in Figure 7-27 and described in Table 7-36. 31 16 Reserved R-0 15 1 0 Reserved ALN1 R-0 R/W-1 LEGEND: R/W = Read/Write; R = Read only; -n = value after reset Figure 7-27. PLL Controller Clock Align Control Register (ALNCTL) [Hex Address: 029C 0140] Table 7-36. PLL Controller Clock Align Control Register (ALNCTL) Field Descriptions Bit 31:1 0 Field Value Reserved 0 ALN1 Submit Documentation Feedback Description Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. SYSCLK1 alignment. Do not change the default values of these fields. 0 Do not align SYSCLK1 during GO operation. If SYS1 in DCHANGE is set to 1, SYSCLK1 switches to the new ratio immediately after the GOSET bit in PLLCMD is set. 1 Align SYSCLK1 when the GOSET bit in PLLCMD is set. The SYSCLK1 ratio is set to the ratio programmed in the RATIO bit in PLLDIV1. C64x+ Peripheral Information and Electrical Specifications 151 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.8.3.5 PLLDIV Ratio Change Status Register Whenever a different ratio is written to the PLLDIV1 register, the PLLCTRL flags the change in the DCHANGE status register. During the GO operation, the PLL controller will only change the divide ratio SYSCLK1 if SYS1 in DCHANGE is 1. The PLLDIV divider ratio change status register is shown in Figure 7-28 and described in Table 7-37. 31 16 Reserved R-0 15 1 0 Reserved SYS1 R-0 R-0 LEGEND: R/W = Read/Write; R = Read only; -n = value after reset Figure 7-28. PLLDIV Divider Ratio Change Status Register (DCHANGE) [Hex Address: 029C 0144] Table 7-37. PLLDIV Divider Ratio Change Status Register (DCHANGE) Field Descriptions Bit 31:1 0 152 Field Reserved Value 0 SYS1 Description Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. SYSCLK1 divide ratio has been modified. SYSCLK1 ratio will be modified during GO operation. 0 SYSCLK1 ratio has not been modified. When GOSET is set, SYSCLK1 will not be affected. 1 SYSCLK1 ratio has been modified. When GOSET is set, SYSCLK1 will change to the new ratio. C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.8.3.6 SYSCLK Status Register The SYSCLK status register (SYSTAT) shows the status of the system clock (SYSCLK1). SYSTAT is shown in Figure 7-29 and described in Table 7-38. 31 16 Reserved R-0 15 1 0 Reserved SYS1ON R-0 R-1 LEGEND: R/W = Read/Write; R = Read only; -n = value after reset Figure 7-29. SYSCLK Status Register [Hex Address: 029C 0150] Table 7-38. SYSCLK Status Register Field Descriptions Bit Field 31:1 Reserved 0 SYS1ON Value Submit Documentation Feedback 0 Description Reserved. The reserved bit location is always read as 0. A value written to this field has no effect. SYSCLK1 on status. 0 SYSCLK1 is gated. 1 SYSCLK1 is on. C64x+ Peripheral Information and Electrical Specifications 153 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.8.4 PLL2 Controller Input Clock Electrical Data/Timing Table 7-39. Timing Requirements for CLKIN2 (1) (2) (3) (see Figure 7-30) -720 -850 A-1000/-1000 -1200 NO. (1) (2) (3) UNIT MIN MAX 1 tc(CLKIN2) Cycle time, CLKIN2 37.5 80 2 tw(CLKIN2H) Pulse duration, CLKIN2 high 0.4C 3 tw(CLKIN2L) Pulse duration, CLKIN2 low 0.4C 4 tt(CLKIN2) Transition time, CLKIN2 1.2 ns 5 tJ(CLKIN2) Period jitter (peak-to-peak), CLKIN2 100 ps ns ns ns The reference points for the rise and fall transitions are measured at 3.3 V VIL MAX and VIH MIN. C = CLKIN2 cycle time in ns. For example, when CLKIN2 frequency is 25 MHz, use C = 40 ns. If EMAC is enabled with RGMII or GMII, CLKIN2 cycle time must be 40 ns (25 MHz). 1 5 4 2 CLKIN2 3 4 Figure 7-30. CLKIN2 Timing 154 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.9 DDR2 Memory Controller The 32-bit, 533-MHz (data rate) DDR2 Memory Controller bus of the C6455 is used to interface to JESD79D-2A standard-compliant DDR2 SDRAM devices. The DDR2 external bus only interfaces to DDR2 SDRAM devices (up to 512 MB); it does not share the bus with any other types of peripherals. The decoupling of DDR2 memories from other devices both simplifies board design and provides I/O concurrency from a second external memory interface, EMIFA. The internal data bus clock frequency and DDR2 bus clock frequency directly affect the maximum throughput of the DDR2 bus. The clock frequency of the DDR2 bus is equal to the CLKIN2 frequency multiplied by 10. The internal data bus clock frequency of the DDR2 Memory Controller is fixed at a divide-by-three ratio of the CPU frequency. The maximum DDR2 throughput is determined by the smaller of the two bus frequencies. For example, if the internal data bus frequency is 333 MHz (CPU frequency is 1 GHz) and the DDR2 bus frequency is 267 MHz (CLKIN2 frequency is 26.7 MHz), the maximum data rate achievable by the DDR2 memory controller is 2.1 Gbytes/sec. The DDR2 bus is designed to sustain a maximum throughput of up to 2.1 Gbytes/sec at a 533-MHz data rate (267-MHz clock rate), as long as data requests are pending in the DDR2 Memory Controller. 7.9.1 DDR2 Memory Controller Device-Specific Information The approach to specifying interface timing for the DDR2 memory bus is different than on other interfaces such as EMIF, HPI, and McBSP. For these other interfaces the device timing was specified in terms of data manual specifications and I/O buffer information specification (IBIS) models. For the C6455 DDR2 memory bus, the approach is to specify compatible DDR2 devices and provide the printed circuit board (PCB) solution and guidelines directly to the user. Texas Instruments (TI) has performed the simulation and system characterization to ensure all DDR2 interface timings in this solution are met. The complete DDR2 system solution is documented in the Implementing DDR2 PCB Layout on the TMS320C6455 application report (literature number SPRAAA7). TI only supports designs that follow the board design guidelines outlined in the SPRAAA7 application report. The DDR2 Memory Controller pins must be enabled by setting the DDR2_EN configuration pin (ABA0) high during device reset. For more details, see Section 3.1, Device Configuration at Device Reset. The ODT[1:0] pins of the memory controller must be left unconnected. The ODT pins on the DDR2 memory device(s) must be connected to ground. The DDR2 memory controller on the C6455 device supports the following memory topologies: • A 32-bit wide configuration interfacing to two 16-bit wide DDR2 SDRAM devices. • A 16-bit wide configuration interfacing to a single 16-bit wide DDR2 SDRAM device. A race condition may exist when certain masters write data to the DDR2 memory controller. For example, if master A passes a software message via a buffer in external memory and does not wait for indication that the write completes, when master B attempts to read the software message, then the master B read may bypass the master A write and, thus, master B may read stale data and, therefore, receive an incorrect message. Some master peripherals (e.g., EDMA3 transfer controllers) will always wait for the write to complete before signaling an interrupt to the system, thus avoiding this race condition. For masters that do not have hardware guarantee of write-read ordering, it may be necessary to guarantee data ordering via software. If master A does not wait for indication that a write is complete, it must perform the following workaround: 1. Perform the required write. 2. Perform a dummy write to the DDR2 memory controller module ID and revision register. 3. Perform a dummy read to the DDR2 memory controller module ID and revision register. 4. Indicate to master B that the data is ready to be read after completion of the read in step 3. The completion of the read in step 3 ensures that the previous write was done. Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 155 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.9.2 DDR2 Memory Controller Peripheral Register Description(s) Table 7-40. DDR2 Memory Controller Registers 7.9.3 HEX ADDRESS RANGE ACRONYM 7800 0000 MIDR REGISTER NAME 7800 0004 DMCSTAT 7800 0008 SDCFG DDR2 Memory Controller SDRAM Configuration Register 7800 000C SDRFC DDR2 Memory Controller SDRAM Refresh Control Register 7800 0010 SDTIM1 DDR2 Memory Controller SDRAM Timing 1 Register 7800 0014 SDTIM2 DDR2 Memory Controller SDRAM Timing 2 Register 7800 0018 - 7800 0020 BPRIO 7800 0024 - 7800 004C - Reserved 7800 0050 - 7800 0078 - Reserved 7800 007C - 7800 00BC - Reserved 7800 00C0 - 7800 00E0 - Reserved 7800 00E4 DMCCTL 7800 00E8 - 7800 00FC - Reserved 7800 0100 - 7FFF FFFF - Reserved DDR2 Memory Controller Module and Revision Register DDR2 Memory Controller Status Register Reserved DDR2 Memory Controller Burst Priority Register DDR2 Memory Controller Control Register DDR2 Memory Controller Electrical Data/Timing The Implementing DDR2 PCB Layout on the TMS320C6455 application report (literature number SPRAAA7) specifies a complete DDR2 interface solution for the C6455 as well as a list of compatible DDR2 devices. TI has performed the simulation and system characterization to ensure all DDR2 interface timings in this solution are met; therefore, no electrical data/timing information is supplied here for this interface. TI only supports designs that follow the board design guidelines outlined in the SPRAAA7 application report. 156 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.10 External Memory Interface A (EMIFA) The EMIFA can interface to a variety of external devices or ASICs, including: • Pipelined and flow-through Synchronous-Burst SRAM (SBSRAM) • ZBT (Zero Bus Turnaround) SRAM and Late Write SRAM • Synchronous FIFOs • Asynchronous memory, including SRAM, ROM, and Flash 7.10.1 EMIFA Device-Specific Information Timing analysis must be done to verify all AC timings are met. TI recommends utilizing I/O buffer information specification (IBIS) to analyze all AC timings. To properly use IBIS models to attain accurate timing analysis for a given system, see the Using IBIS Models for Timing Analysis application report (literature number SPRA839). To maintain signal integrity, serial termination resistors should be inserted into all EMIF output signal lines (for the EMIF output signals, see Table 2-3, Terminal Functions). A race condition may exist when certain masters write data to the EMIFA. For example, if master A passes a software message via a buffer in external memory and does not wait for indication that the write completes, when master B attempts to read the software message, then the master B read may bypass the master A write and, thus, master B may read stale data and, therefore, receive an incorrect message. Some master peripherals (e.g., EDMA3 transfer controllers) will always wait for the write to complete before signaling an interrupt to the system, thus avoiding this race condition. For masters that do not have hardware guarantee of write-read ordering, it may be necessary to guarantee data ordering via software. If master A does not wait for indication that a write is complete, it must perform the following workaround: 1. Perform the required write. 2. Perform a dummy write to the EMIFA module ID and revision register. 3. Perform a dummy read to the EMIFA module ID and revision register. 4. Indicate to master B that the data is ready to be read after completion of the read in step 3. The completion of the read in step 3 ensures that the previous write was done. Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 157 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.10.2 EMIFA Peripheral Register Description(s) Table 7-41. EMIFA Registers 158 HEX ADDRESS RANGE ACRONYM 7000 0000 MIDR Module ID and Revision Register REGISTER NAME 7000 0004 STAT Status Register 7000 0008 - Reserved 7000 000C - 7000 001C - Reserved 7000 0020 BURST_PRIO 7000 0024 - 7000 004C - Reserved 7000 0050 - 7000 007C - Reserved 7000 0080 CE2CFG EMIFA CE2 Configuration Register 7000 0084 CE3CFG EMIFA CE3 Configuration Register Burst Priority Register 7000 0088 CE4CFG EMIFA CE4 Configuration Register 7000 008C CE5CFG EMIFA CE5 Configuration Register 7000 0090 - 7000 009C - Reserved 7000 00A0 AWCC 7000 00A4 - 7000 00BC - EMIFA Async Wait Cycle Configuration Register 7000 00C0 INTRAW EMIFA Interrupt RAW Register 7000 00C4 INTMSK EMIFA Interrupt Masked Register Reserved 7000 00C8 INTMSKSET EMIFA Interrupt Mask Set Register 7000 00CC INTMSKCLR EMIFA Interrupt Mask Clear Register 7000 00D0 - 7000 00DC - Reserved 7000 00E0 - 77FF FFFF - Reserved C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.10.3 EMIFA Electrical Data/Timing Table 7-42. Timing Requirements for AECLKIN for EMIFA (1) (2) (see Figure 7-31) -720 -850 A-1000/-1000 -1200 NO. (1) (2) (3) (4) UNIT MIN MAX 1 tc(EKI) Cycle time, AECLKIN 6 (3) 40 2 tw(EKIH) Pulse duration, AECLKIN high 2.7 3 tw(EKIL) Pulse duration, AECLKIN low 2.7 4 tt(EKI) Transition time, AECLKIN 5 tJ(EKI) Period Jitter, AECLKIN ns ns ns 2 ns 0.02E (4) ns The reference points for the rise and fall transitions are measured at VIL MAX and VIH MIN. E = the EMIF input clock (AECLKIN or SYSCLK4) period in ns for EMIFA. Minimum AECLKIN cycle times must be met, even when AECLKIN is generated by an internal clock source. Minimum AECLKIN times are based on internal logic speed; the maximum useable speed of the EMIF may be lower due to AC timing requirements. This timing only applies when AECLKIN is used for EMIFA. 1 5 4 2 AECLKIN 3 4 Figure 7-31. AECLKIN Timing for EMIFA Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 159 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-43. Switching Characteristics Over Recommended Operating Conditions for AECLKOUT for the EMIFA Module (1) (2) (3) (see Figure 7-32) NO. (1) (2) (3) -720 -850 A-1000/-1000 -1200 PARAMETER UNIT MIN MAX E - 0.7 E + 0.7 ns Pulse duration, AECLKOUT high EH - 0.7 EH + 0.7 ns Pulse duration, AECLKOUT low EL - 0.7 EL + 0.7 ns 1 ns 1 8 ns 1 8 ns 1 tc(EKO) Cycle time, AECLKOUT 2 tw(EKOH) 3 tw(EKOL) 4 tt(EKO) Transition time, AECLKOUT 5 td(EKIH-EKOH) Delay time, AECLKIN high to AECLKOUT high 6 td(EKIL-EKOL) Delay time, AECLKIN low to AECLKOUT low E = the EMIF input clock (AECLKIN or SYSCLK4) period in ns for EMIFA. The reference points for the rise and fall transitions are measured at VOL MAX and VOH MIN. EH is the high period of E (EMIF input clock period) in ns and EL is the low period of E (EMIF input clock period) in ns for EMIFA. AECLKIN 1 6 5 3 2 4 4 AECLKOUT1 Figure 7-32. AECLKOUT Timing for the EMIFA Module 7.10.3.1 Asynchronous Memory Timing Table 7-44. Timing Requirements for Asynchronous Memory Cycles for EMIFA Module (1) (2) (3) (see Figure 7-33 and Figure 7-34) -720 -850 A-1000/-1000 -1200 NO. MIN (1) (2) (3) 160 3 tsu(EDV-AOEH) Setup time, AEDx valid before AAOE high 4 th(AOEH-EDV) 5 tsu(ARDY-EKOH) 6 7 UNIT MAX 6.5 ns Hold time, AEDx valid after AAOE high 0 ns Setup time, AARDY valid before AECLKOUT low 1 ns th(EKOH-ARDY) Hold time, AARDY valid after AECLKOUT low 2 ns tw(ARDY) Pulse width, AARDY assertion and deassertion 2E + 5 ns 8 td(ARDY-HOLD) Delay time, from AARDY sampled deasserted on AECLKOUT falling to beginning of programmed hold period 9 tsu(ARDY-HOLD) Setup time, before end of programmed strobe period by which AARDY should be asserted in order to insert extended strobe wait states. 4E 2E ns ns E = AECLKOUT period in ns for EMIFA To ensure data setup time, simply program the strobe width wide enough. AARDY is internally synchronized. To use AARDY as an asynchronous input, the pulse width of the AARDY signal should be at least 2E to ensure setup and hold time is met. C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-45. Switching Characteristics Over Recommended Operating Conditions for Asynchronous Memory Cycles for EMIFA Module (1) (2) (3) (see Figure 7-33 and Figure 7-34) NO. -720 -850 A-1000/-1000 -1200 PARAMETER MIN (1) (2) (3) 1 tosu(SELV-AOEL) Output setup time, select signals valid to AAOE low RS * E – 1.5 RS * E – 1.9 2 toh(AOEH-SELIV) Output hold time, AAOE high to select signals invalid 10 td(EKOH-AOEV) Delay time, AECLKOUT high to AAOE valid 11 tosu(SELV-AWEL) Output setup time, select signals valid to AAWE low WS * E – 1.7 12 toh(AWEH-SELIV) Output hold time, AAWE high to select signals invalid WH * E – 1.8 13 td(EKOH-AWEV) Delay time, AECLKOUT high to AAWE valid UNIT MAX ns ns 1 7 ns ns ns 1.3 7.1 ns E = AECLKOUT period in ns for EMIFA RS = Read setup, RST = Read strobe, RH = Read hold, WS = Write setup, WST = Write strobe, WH = Write hold. These parameters are programmed via the EMIFA CE Configuration registers (CEnCFG). Select signals for EMIFA include: ACEx, ABE[7:0], AEA[19:0], ABA[1:0]; and for EMIFA writes, also include AR/W, AED[63:0]. Strobe = 4 Setup = 1 Hold = 1 AECLKOUT 2 1 ACEx 1 2 Byte Enables ABE[7:0] 2 1 AEA[19:0]/ ABA[1:0] Address 3 4 Read Data AED[63:0] 10 10 AAOE/ASOE(A) AAWE/ASWE(A) AR/W DEASSERTED AARDY(B) A AAOE/ASOE and AAWE/ASWE operate as AAOE (identified under select signals) and AAWE, respectively, during asynchronous memory accesses. B Polarity of the AARDY signal is programmable through the AP field of the EMIFA Async Wait Cycle Configuration register (AWCC). Figure 7-33. Asynchronous Memory Read Timing for EMIFA Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 161 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Strobe = 4 Hold = 1 Setup = 1 AECLKOUT 12 11 ACEx 11 12 Byte Enables ABE[7:0] 11 AEA[19:0]/ ABA[1:0] 12 Address 11 12 Write Data AED[63:0] AAOE/ASOE(A) 13 13 AAWE/ASWE(A) 11 12 AR/W DEASSERTED AARDY(B) A AAOE/ASOE and AAWE/ASWE operate as AAOE (identified under select signals) and AAWE, respectively, during asynchronous memory accesses. B Polarity of the AARDY signal is programmable through the AP field of the EMIFA Async Wait Cycle Configuration register (AWCC). Figure 7-34. Asynchronous Memory Write Timing for EMIFA Strobe Strobe Setup = 2 Extended Strobe Hold = 2 8 9 AECLKOUT 6 5 7 7 AARDY(A) ASSERTED DEASSERTED A Polarity of the AARDY signal is programmable through the AP field of the EMIFA Async Wait Cycle Configuration register (AWCC). Figure 7-35. AARDY Timing 162 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.10.3.2 Programmable Synchronous Interface Timing Table 7-46. Timing Requirements for Programmable Synchronous Interface Cycles for EMIFA Module (see Figure 7-36) -720 -850 A-1000/-1000 -1200 NO. MIN 6 tsu(EDV-EKOH) Setup time, read AEDx valid before AECLKOUT high 7 th(EKOH-EDV) Hold time, read AEDx valid after AECLKOUT high UNIT MAX 2 ns 1.5 ns Table 7-47. Switching Characteristics Over Recommended Operating Conditions for Programmable Synchronous Interface Cycles for EMIFA Module (1) (see Figure 7-36–Figure 7-38) NO. (1) -720 -850 A-1000/-1000 -1200 PARAMETER UNIT MIN MAX 1.3 4.9 ns 4.9 ns 1 td(EKOH-CEV) Delay time, AECLKOUT high to ACEx valid 2 td(EKOH-BEV) Delay time, AECLKOUT high to ABEx valid 3 td(EKOH-BEIV) Delay time, AECLKOUT high to ABEx invalid 4 td(EKOH-EAV) Delay time, AECLKOUT high to AEAx valid 5 td(EKOH-EAIV) Delay time, AECLKOUT high to AEAx invalid 1.3 8 td(EKOH-ADSV) Delay time, AECLKOUT high to ASADS/ASRE valid 1.3 4.9 ns 9 td(EKOH-OEV) Delay time, AECLKOUT high to ASOE valid 1.3 4.9 ns 10 td(EKOH-EDV) Delay time, AECLKOUT high to AEDx valid 4.9 ns 11 td(EKOH-EDIV) Delay time, AECLKOUT high to AEDx invalid 1.3 12 td(EKOH-WEV) Delay time, AECLKOUT high to ASWE valid 1.3 1.3 ns 4.9 ns ns ns 4.9 ns The following parameters are programmable via the EMIFA CE Configuration registers (CEnCFG): • Read latency (R_LTNCY): 0-, 1-, 2-, or 3-cycle read latency • Write latency (W_LTNCY): 0-, 1-, 2-, or 3-cycle write latency • ACEx assertion length (CE_EXT): For standard SBSRAM or ZBT SRAM interface, ACEx goes inactive after the final command has been issued (CE_EXT = 0). For synchronous FIFO interface with glue, ACEx is active when ASOE is active (CE_EXT = 1). • Function of ASADS/ASRE (R_ENABLE): For standard SBSRAM or ZBT SRAM interface, ASADS/ASRE acts as ASADS with deselect cycles (R_ENABLE = 0). For FIFO interface, ASADS/ASRE acts as ASRE with NO deselect cycles (R_ENABLE = 1). Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 163 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 READ latency = 2 AECLKOUT 1 1 ACEx 2 BE1 ABE[7:0] 3 BE2 BE3 BE4 4 AEA[19:0]/ABA[1:0] 5 EA1 EA2 EA3 EA4 6 AED[63:0] 7 Q1 Q2 Q3 Q4 8 8 ASADS/ASRE(B) 9 9 AAOE/ASOE(B) AAWE/ASWE(B) A The following parameters are programmable via the EMIFA Chip Select n Configuration Register (CESECn): −Read latency (R_LTNCY): 1-, 2-, or 3-cycle read latency −Write latency (W_LTNCY): 0-, 1-, 2-, or 3-cycle write latency −ACEx assertion length (CE_EXT): For standard SBSRAM or ZBT SRAM interface, ACEx goes inactive after the final command has been issued (CE_EXT = 0). For synchronous FIFO interface, ACEx is active when ASOE is active (CE_EXT = 1). −Function of ASADS/ASRE (R_ENABLE): For standard SBSRAM or ZBT SRAM interface, ASADS/ASRE acts as ASADS with deselect cycles (R_ENABLE = 0). For FIFO interface, ASADS/ASRE acts as SRE with NO deselect cycles (R_ENABLE = 1). −In this figure R_LTNCY = 2, CE_EXT = 0, R_ENABLE = 0, and SSEL = 1. B AAOE/ASOE, and AAWE/ASWE operate as ASOE, and ASWE, respectively, during programmable synchronous interface accesses. Figure 7-36. Programmable Synchronous Interface Read Timing for EMIFA (With Read Latency = 2)(A) AECLKOUT 1 1 ACEx ABE[7:0] 2 BE1 AEA[19:0]/ABA[1:0] 4 EA1 EA2 EA3 EA4 10 Q1 Q2 Q3 Q4 10 AED[63:0] ASADS/ASRE(B) 8 3 BE2 BE3 BE4 5 11 8 AAOE/ASOE(B) 12 12 AAWE/ASWE(B) A The following parameters are programmable via the EMIFA Chip Select n Configuration Register (CESECn): − Read latency (R_LTNCY): 1-, 2-, or 3-cycle read latency − Write latency (W_LTNCY): 0-, 1-, 2-, or 3-cycle write latency − ACEx assertion length (CE_EXT): For standard SBSRAM or ZBT SRAM interface, ACEx goes inactive after the final command has been issued (CE_EXT = 0). For synchronous FIFO interface, ACEx is active when ASOE is active (CE_EXT = 1). − Function of ASADS/ASRE (R_ENABLE): For standard SBSRAM or ZBT SRAM interface, ASADS/ASRE acts as ASADS with deselect cycles (R_ENABLE = 0). For FIFO interface, ASADS/ASRE acts as SRE with NO deselect cycles (R_ENABLE = 1). − In this figure W_LTNCY = 0, CE_EXT = 0, R_ENABLE = 0, and SSEL = 1. B AAOE/ASOE, and AAWE/ASWE operate as ASOE, and ASWE, respectively, during programmable synchronous interface accesses. Figure 7-37. Programmable Synchronous Interface Write Timing for EMIFA (With Write Latency = 0)(A) 164 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Write Latency = 1 (B) AECLKOUT 1 1 ACEx ABE[7:0] 2 BE1 AEA[19:0]/ABA[1:0] 4 EA1 10 AED[63:0] 3 BE2 BE3 BE4 EA2 10 EA3 EA4 Q1 Q2 Q3 5 11 Q4 8 8 ASADS/ASRE (B) AAOE/ASOE (B) 12 12 AAWE/ASWE (B) A The following parameters are programmable via the EMIFA Chip Select n Configuration Register (CESECn): − Read latency (R_LTNCY): 1-, 2-, or 3-cycle read latency − Write latency (W_LTNCY): 0-, 1-, 2-, or 3-cycle write latency − ACEx assertion length (CE_EXT): For standard SBSRAM or ZBT SRAM interface, ACEx goes inactive after the final command has been issued (CE_EXT = 0). For synchronous FIFO interface, ACEx is active when ASOE is active (CE_EXT = 1). − Function of ASADS/ASRE (R_ENABLE): For standard SBSRAM or ZBT SRAM interface, ASADS/ASRE acts as ASADS with deselect cycles (R_ENABLE = 0). For FIFO interface, ASADS/ASRE acts as SRE with NO deselect cycles (R_ENABLE = 1). − In this figure W_LTNCY = 1, CE_EXT = 0, R_ENABLE = 0, and SSEL = 1. B AAOE/ASOE, and AAWE/ASWE operate as ASOE, and ASWE, respectively, during programmable synchronous interface accesses. Figure 7-38. Programmable Synchronous Interface Write Timing for EMIFA (With Write Latency = 1) (A) Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 165 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.10.4 HOLD/HOLDA Timing Table 7-48. Timing Requirements for the HOLD/HOLDA Cycles for EMIFA Module (1) (see Figure 7-39) -720 -850 A-1000/-1000 -1200 NO. MIN 3 (1) th(HOLDAL-HOLDL) Hold time, HOLD low after HOLDA low UNIT MAX E ns E = the EMIF input clock (ECLKIN) period in ns for EMIFA. Table 7-49. Switching Characteristics Over Recommended Operating Conditions for the HOLD/HOLDA Cycles for EMIFA Module (1) (2) (see Figure 7-39) NO. (1) (2) (3) -720 -850 A-1000/-1000 -1200 PARAMETER UNIT MIN MAX 1 td(HOLDL-EMHZ) Delay time, HOLD low to EMIFA Bus high impedance 2E (3) ns 2 td(EMHZ-HOLDAL) Delay time, EMIF Bus high impedance to HOLDA low 0 2E ns 4 td(HOLDH-EMLZ) Delay time, HOLD high to EMIF Bus low impedance 2E 7E ns 5 td(EMLZ-HOLDAH) Delay time, EMIFA Bus low impedance to HOLDA high 0 2E ns E = the EMIF input clock (ECLKIN) period in ns for EMIFA. EMIFA Bus consists of: ACE[5:2], ABE[7:0], AED[63:0], AEA[19:0], ABA[1:0], AR/W, ASADS/ASRE, AAOE/ASOE, and AAWE/ASWE. All pending EMIF transactions are allowed to complete before HOLDA is asserted. If no bus transactions are occurring, then the minimum delay time can be achieved. External Requestor Owns Bus DSP Owns Bus DSP Owns Bus 3 HOLD 2 5 HOLDA 1 EMIF Bus (A) 4 DSP DSP AECLKOUT A. EMIFA Bus consists of: ACE[5:2], ABE[7:0], AED[63:0], AEA[19:0], ABA[1:0], AR/W, ASADS/ASRE, AAOE/ASOE, and AAWE/ASWE. Figure 7-39. HOLD/HOLDA Timing for EMIFA 166 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.10.5 BUSREQ Timing Table 7-50. Switching Characteristics Over Recommended Operating Conditions for the BUSREQ Cycles for EMIFA Module (see Figure 7-40) NO. 1 -720 -850 A-1000/-1000 -1200 PARAMETER td(AEKOH-ABUSRV) Delay time, AECLKOUT high to ABUSREQ valid MIN MAX 1 5.5 UNIT ns AECLKOUTx 1 1 ABUSREQ Figure 7-40. BUSREQ Timing for EMIFA Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 167 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.11 I2C Peripheral The inter-integrated circuit (I2C) module provides an interface between a C64x+ DSP and other devices compliant with Philips Semiconductors Inter-IC bus (I2C bus) specification version 2.1 and connected by way of an I2C-bus. External components attached to this 2-wire serial bus can transmit/receive up to 8-bit data to/from the DSP through the I2C module. 7.11.1 I2C Device-Specific Information The C6455 device includes an I2C peripheral module (I2C). NOTE: when using the I2C module, ensure there are external pullup resistors on the SDA and SCL pins. The I2C modules on the C6455 may be used by the DSP to control local peripherals ICs (DACs, ADCs, etc.) or may be used to communicate with other controllers in a system or to implement a user interface. The I2C port supports: • Compatible with Philips I2C Specification Revision 2.1 (January 2000) • Fast Mode up to 400 Kbps (no fail-safe I/O buffers) • Noise Filter to remove noise 50 ns or less • 7- and 10-Bit Device Addressing Modes • Multi-Master (Transmit/Receive) and Slave (Transmit/Receive) Functionality • Events: DMA, Interrupt, or Polling • Slew-Rate Limited Open-Drain Output Buffers Figure 7-41 is a block diagram of the I2C module. 168 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 I2C Module Clock Prescale Peripheral Clock (CPU/6) I2CPSC Control Bit Clock Generator SCL Noise Filter I2C Clock I2CCLKH I2COAR Own Address I2CSAR Slave Address I2CMDR Mode I2CCNT Data Count I2CCLKL Transmit I2CXSR Transmit Shift I2CDXR Transmit Buffer SDA I2C Data I2CEMDR Extended Mode Interrupt/DMA Noise Filter Receive I2CIMR Interrupt Mask/Status I2CDRR Receive Buffer I2CSTR Interrupt Status I2CRSR Receive Shift I2CIVR Interrupt Vector Shading denotes control/status registers. Figure 7-41. I2C Module Block Diagram Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 169 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.11.2 I2C Peripheral Register Description(s) Table 7-51. I2C Registers 170 HEX ADDRESS RANGE ACRONYM 02B0 4000 ICOAR I2C own address register REGISTER NAME 02B0 4004 ICIMR I2C interrupt mask/status register 02B0 4008 ICSTR I2C interrupt status register 02B0 400C ICCLKL I2C clock low-time divider register 02B0 4010 ICCLKH I2C clock high-time divider register 02B0 4014 ICCNT I2C data count register 02B0 4018 ICDRR I2C data receive register 02B0 401C ICSAR I2C slave address register 02B0 4020 ICDXR I2C data transmit register 02B0 4024 ICMDR I2C mode register 02B0 4028 ICIVR I2C interrupt vector register 02B0 402C ICEMDR I2C extended mode register 02B0 4030 ICPSC I2C prescaler register 02B0 4034 ICPID1 I2C peripheral identification register 1 [Value: 0x0000 0105] 02B0 4038 ICPID2 I2C peripheral identification register 2 [Value: 0x0000 0005] 02B0 403C - 02B0 405C - Reserved 02B0 4060 - 02B3 407F - Reserved 02B0 4080 - 02B3 FFFF - Reserved C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.11.3 I2C Electrical Data/Timing 7.11.3.1 Inter-Integrated Circuits (I2C) Timing Table 7-52. Timing Requirements for I2C Timings (1) (see Figure 7-42) -720 -850 A-1000/-1000 -1200 NO. STANDARD MODE MIN (3) (4) (5) MAX tc(SCL) Cycle time, SCL 10 2.5 μs 2 tsu(SCLH-SDAL) Setup time, SCL high before SDA low (for a repeated START condition) 4.7 0.6 μs 3 th(SCLL-SDAL) Hold time, SCL low after SDA low (for a START and a repeated START condition) 4 0.6 μs 4 tw(SCLL) Pulse duration, SCL low 4.7 1.3 μs 5 tw(SCLH) Pulse duration, SCL high 4 0.6 μs 6 tsu(SDAV-SDLH) Setup time, SDA valid before SCL high 250 100 (2) ns 7 th(SDA-SDLL) Hold time, SDA valid after SCL low (For I C bus™ devices) 0 (3) 0 (3) 8 tw(SDAH) Pulse duration, SDA high between STOP and START conditions 4.7 1.3 9 tr(SDA) Rise time, SDA 1000 20 + 0.1Cb (5) 300 ns 10 tr(SCL) Rise time, SCL 1000 20 + 0.1Cb (5) 300 ns 11 tf(SDA) Fall time, SDA 300 20 + 0.1Cb (5) 300 ns 300 (5) 300 ns 12 (2) FAST MODE MIN 1 2 (1) MAX UNIT tf(SCL) Fall time, SCL 13 tsu(SCLH-SDAH) Setup time, SCL high before SDA high (for STOP condition) 14 tw(SP) Pulse duration, spike (must be suppressed) 15 Cb (5) Capacitive load for each bus line 4 20 + 0.1Cb 0.9 (4) μs μs 0.6 0 400 μs 50 ns 400 pF The I2C pins SDA and SCL do not feature fail-safe I/O buffers. These pins could potentially draw current when the device is powered down. A Fast-mode I2C-bus™ device can be used in a Standard-mode I2C-bus™ system, but the requirement tsu(SDA-SCLH) ≥250 ns must then be met. This will automatically be the case if the device does not stretch the LOW period of the SCL signal. If such a device does stretch the LOW period of the SCL signal, it must output the next data bit to the SDA line tr max + tsu(SDA-SCLH) = 1000 + 250 = 1250 ns (according to the Standard-mode I2C-Bus Specification) before the SCL line is released. A device must internally provide a hold time of at least 300 ns for the SDA signal (referred to the VIHmin of the SCL signal) to bridge the undefined region of the falling edge of SCL. The maximum th(SDA-SCLL) has only to be met if the device does not stretch the low period [tw(SCLL)] of the SCL signal. Cb = total capacitance of one bus line in pF. If mixed with HS-mode devices, faster fall-times are allowed. Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 171 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 11 9 SDA 6 8 14 4 13 5 10 SCL 1 12 3 2 7 3 Stop Start Repeated Start Stop Figure 7-42. I2C Receive Timings Table 7-53. Switching Characteristics for I2C Timings (1) (see Figure 7-43) NO. -720 -850 A-1000/-1000 -1200 PARAMETER STANDARD MODE MIN MAX UNIT FAST MODE MIN MAX 16 tc(SCL) Cycle time, SCL 10 2.5 μs 17 td(SCLH-SDAL) Delay time, SCL high to SDA low (for a repeated START condition) 4.7 0.6 μs 18 td(SDAL-SCLL) Delay time, SDA low to SCL low (for a START and a repeated START condition) 4 0.6 μs 19 tw(SCLL) Pulse duration, SCL low 4.7 1.3 μs 20 tw(SCLH) Pulse duration, SCL high 4 0.6 μs 21 td(SDAV-SDLH) Delay time, SDA valid to SCL high 250 100 ns 0 0 4.7 1.3 2 22 tv(SDLL-SDAV) Valid time, SDA valid after SCL low (For I C bus™ devices) 23 tw(SDAH) Pulse duration, SDA high between STOP and START conditions 24 tr(SDA) Rise time, SDA 1000 20 + 0.1Cb (1) 300 ns 25 tr(SCL) Rise time, SCL 1000 20 + 0.1Cb (1) 300 ns 26 tf(SDA) Fall time, SDA 300 20 + 0.1Cb (1) 300 ns 300 (1) 300 ns 27 tf(SCL) Fall time, SCL 28 td(SCLH-SDAH) Delay time, SCL high to SDA high (for STOP condition) 29 Cp Capacitance for each I2C pin (1) 172 20 + 0.1Cb 4 0.9 μs μs 0.6 10 μs 10 pF Cb = total capacitance of one bus line in pF. If mixed with HS-mode devices, faster fall-times are allowed. C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 26 24 SDA 21 23 19 28 20 25 SCL 16 27 18 17 22 18 Stop Start Repeated Start Stop Figure 7-43. I2C Transmit Timings Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 173 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.12 Host-Port Interface (HPI) Peripheral 7.12.1 HPI Device-Specific Information The C6455 device includes a user-configurable 16-bit or 32-bit Host-port interface (HPI16/HPI32). The AEA14 pin controls the HPI_WIDTH, allowing the user to configure the HPI as a 16-bit or 32-bit peripheral. Software handshaking via the HRDY bit of the Host Port Control Register (HPIC) is not supported on the C6455. An HPI boot is terminated using a DSP interrupt. The DSP interrupt is registered in bit 0 (channel 0) of the EDMA Event Register (ER). This event must be cleared by software before triggering transfers on DMA channel 0. 7.12.2 HPI Peripheral Register Description(s) Table 7-54. HPI Control Registers HEX ADDRESS RANGE ACRONYM 0288 0000 - REGISTER NAME 0288 0004 PWREMU_MGMT 0288 0008 - 0288 0024 - Reserved 0288 0028 - Reserved 0288 002C - Reserved 0288 0030 HPIC HPI control register 0288 0034 HPIA (HPIAW) (2) HPI address register (Write) 0288 0038 HPIA (HPIAR) (2) HPI address register (Read) 0288 000C - 028B 007F - Reserved 0288 0080 - 028B FFFF - Reserved (1) (2) 174 COMMENTS Reserved HPI power and emulation management register The CPU has read/write access to the PWREMU_MGMT register; the Host does not have any access to this register. The Host and the CPU have read/write access to the HPIC register. (1) The Host has read/write access to the HPIA registers. The CPU has only read access to the HPIA registers. The CPU can write 1 to the HINT bit to generate an interrupt to the host and it can write 1 to the DSPINT bit to clear/acknowledge an interrupt from the host. There are two 32-bit HPIA registers: HPIAR for read operations and HPIAW for write operations. The HPI can be configured such that HPIAR and HPIAW act as a single 32-bit HPIA (single-HPIA mode) or as two separate 32-bit HPIAs (dual-HPIA mode) from the perspective of the host. The CPU can access HPIAW and HPIAR independently. For details about the HPIA registers and their modes, see the TMS320C645x DSP Host Port Interface (HPI) User's Guide (literature number SPRU969). C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.12.3 HPI Electrical Data/Timing Table 7-55. Timing Requirements for Host-Port Interface Cycles (1) (2) (see Table 7-56 through Figure 7-51) -720 -850 A-1000/-1000 -1200 NO. MIN MAX 9 tsu(HASL-HSTBL) Setup time, HAS low before HSTROBE low 5 ns 10 th(HSTBL-HASL) Hold time, HAS low after HSTROBE low 2 ns 5 ns 5 ns (3) 11 tsu(SELV-HASL) Setup time, select signals 12 th(HASL-SELV) Hold time, select signals (3) valid after HAS low 13 tw(HSTBL) Pulse duration, HSTROBE low 15 ns 14 tw(HSTBH) Pulse duration, HSTROBE high between consecutive accesses 2M ns 15 tsu(SELV-HSTBL) Setup time, select signals (3) valid before HSTROBE low 5 ns 16 th(HSTBL-SELV) Hold time, select signals (3) valid after HSTROBE low 5 ns 17 tsu(HDV-HSTBH) Setup time, host data valid before HSTROBE high 5 ns 18 th(HSTBH-HDV) Hold time, host data valid after HSTROBE high 1 ns 37 tsu(HCSL-HSTBL) Setup time, HCS low before HSTROBE low 0 ns th(HRDYL-HSTBL) Hold time, HSTROBE low after HRDY low. HSTROBE should not be inactivated until HRDY is active (low); otherwise, HPI writes will not complete properly. 1.1 ns 38 (1) (2) (3) UNIT valid before HAS low HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS. M = SYSCLK3 period = 6/CPU clock frequency in ns. For example, when running parts at 1000 MHz, use M = 6 ns. Select signals include: HCNTL[1:0] and HR/W. For HPI16 mode only, select signals also include HHWIL. Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 175 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-56. Switching Characteristics for Host-Port Interface Cycles (1) (2) (see Table 7-56 through Figure 7-51) NO. PARAMETER -720 -850 A-1000/-1000 -1200 MIN Case 1. HPIC or HPIA read 1 td(HSTBL-HDV) Delay time, HSTROBE low to DSP data valid 15 9 * M + 20 Case 3. HPID read with auto-increment and read FIFO initially empty (3) 9 * M + 20 5 ns 15 2 tdis(HSTBH-HDV) Disable time, HD high-impedance from HSTROBE high 1 4 ns 3 ten(HSTBL-HD) Enable time, HD driven from HSTROBE low 3 15 ns 4 td(HSTBL-HRDYH) Delay time, HSTROBE low to HRDY high 12 ns 5 td(HSTBH-HRDYH) Delay time, HSTROBE high to HRDY high 12 ns td(HSTBL-HRDYL) Delay time, HSTROBE low to HRDY low 6 7 td(HDV-HRDYL) Case 1. HPID read with no auto-increment (3) 10 * M + 20 Case 2. HPID read with auto-increment and read FIFO initially empty (3) 10 * M + 20 Delay time, HD valid to HRDY low Case 1. HPIA write (3) 34 td(DSH-HRDYL) Delay time, HSTROBE high to Case 2. HPID write with no HRDY low auto-increment (3) 35 td(HSTBL-HRDYL) Delay time, HSTROBE low to HRDY low for HPIA write and FIFO not empty (3) 36 td(HASL-HRDYH) Delay time, HAS low to HRDY high 176 MAX 5 Case 2. HPID read with no auto-increment (3) Case 4. HPID read with auto-increment and data previously prefetched into the read FIFO (1) (2) (3) UNIT ns 0 ns 5 * M + 20 5 * M + 20 ns 40 * M + 20 ns 12 ns M = SYSCLK3 period = 6/CPU clock frequency in ns. For example, when running parts at 1000 MHz, use M = 6 ns. HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS. Assumes the HPI is accessing L2/L1 memory and no other master is accessing the same memory location. C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 HCS HAS HCNTL[1:0] HR/W HHWIL 13 16 16 15 15 37 37 14 13 HSTROBE(A) 3 3 1 2 1 2 HD[15:0] 38 4 7 6 HRDY(B) A. HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS. B. Depending on the type of write or read operation (HPID without auto-incrementing; HPIA, HPIC, or HPID with auto-incrementing) and the state of the FIFO, transitions on HRDY may or may not occur. For more detailed information on the HPI peripheral, see the TMS320C645x DSP Host Port Interface (HPI) User's Guide (literature number SPRU969). Figure 7-44. HPI16 Read Timing (HAS Not Used, Tied High) Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 177 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 HCS HAS 12 11 12 11 HCNTL[1:0] 12 11 12 11 12 11 12 11 HR/W HHWIL 10 9 10 9 37 13 37 13 14 HSTROBE(A) 1 3 2 1 3 2 HD[15:0] 7 36 6 38 HRDY(B) A. HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS. B. Depending on the type of write or read operation (HPID without auto-incrementing; HPIA, HPIC, or HPID with auto-incrementing) and the state of the FIFO, transitions on HRDY may or may not occur. For more detailed information on the HPI peripheral, see the TMS320C645x DSP Host Port Interface (HPI) User's Guide (literature number SPRU969). Figure 7-45. HPI16 Read Timing (HAS Used) 178 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 HCS HAS HCNTL[1:0] HR/W HHWIL 16 13 16 15 37 15 37 13 14 HSTROBE(A) 18 18 17 17 HD[15:0] 4 35 38 34 5 34 5 HRDY(B) A. HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS. B. Depending on the type of write or read operation (HPID without auto-incrementing; HPIA, HPIC, or HPID with auto-incrementing) and the state of the FIFO, transitions on HRDY may or may not occur. For more detailed information on the HPI peripheral, see the TMS320C645x DSP Host Port Interface (HPI) User's Guide (literature number SPRU969). Figure 7-46. HPI16 Write Timing (HAS Not Used, Tied High) Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 179 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 HCS HAS 12 11 12 11 HCNTL[1:0] 12 11 11 12 11 11 12 HR/W 12 HHWIL 9 10 9 14 37 HSTROBE(A) 10 37 13 13 18 18 17 17 HD[15:0] 34 35 34 5 36 38 5 HRDY(B) A. HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS. B. Depending on the type of write or read operation (HPID without auto-incrementing; HPIA, HPIC, or HPID with auto-incrementing) and the state of the FIFO, transitions on HRDY may or may not occur. For more detailed information on the HPI peripheral, see the TMS320C645x DSP Host Port Interface (HPI) User's Guide (literature number SPRU969). Figure 7-47. HPI16 Write Timing (HAS Used) 180 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 HAS (input) 16 15 HCNTL[1:0] (input) HR/W (input) 13 HSTROBE(A) (input) 37 HCS (input) 1 2 3 HD[31:0] (output) 38 7 6 4 HRDY(B) (output) A. HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS. B. Depending on the type of write or read operation (HPID without auto-incrementing; HPIA, HPIC, or HPID with auto-incrementing) and the state of the FIFO, transitions on HRDY may or may not occur. For more detailed information on the HPI peripheral, see the TMS320C645x DSP Host Port Interface (HPI) User's Guide (literature number SPRU969). C. The timing tw(HSTBH), HSTROBE high pulse duration, must be met between consecutive HPI accesses in HPI32 mode. Figure 7-48. HPI32 Read Timing (HAS Not Used, Tied High) Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 181 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 10 HAS (input) 12 11 HCNTL[1:0] (input) HR/W (input) 9 13 HSTROBE(A) (input) 37 HCS (input) 1 2 3 HD[31:0] (output) 7 38 6 36 HRDY(B) (output) A. HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS. B. Depending on the type of write or read operation (HPID without auto-incrementing; HPIA, HPIC, or HPID with auto-incrementing) and the state of the FIFO, transitions on HRDY may or may not occur. For more detailed information on the HPI peripheral, see the TMS320C645x DSP Host Port Interface (HPI) User's Guide (literature number SPRU969). C. The timing tw(HSTBH), HSTROBE high pulse duration, must be met between consecutive HPI accesses in HPI32 mode. Figure 7-49. HPI32 Read Timing (HAS Used) 182 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 HAS (input) 16 15 HCNTL[1:0] (input) HR/W (input) 13 HSTROBE(A) (input) 37 HCS (input) 18 17 HD[31:0] (input) 38 34 35 5 4 HRDY(B) (output) A. HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS. B. Depending on the type of write or read operation (HPID without auto-incrementing; HPIA, HPIC, or HPID with auto-incrementing) and the state of the FIFO, transitions on HRDY may or may not occur. For more detailed information on the HPI peripheral, see the TMS320C645x DSP Host Port Interface (HPI) User's Guide (literature number SPRU969). C. The timing tw(HSTBH), HSTROBE high pulse duration, must be met between consecutive HPI accesses in HPI32 mode. Figure 7-50. HPI32 Write Timing (HAS Not Used, Tied High) Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 183 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 10 HAS (input) 12 11 HCNTL[1:0] (input) HR/W (input) 9 13 HSTROBE(A) (input) 37 HCS (input) 17 18 HD[31:0] (input) 35 36 34 38 5 HRDY(B) (output) A. HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS. B. Depending on the type of write or read operation (HPID without auto-incrementing; HPIA, HPIC, or HPID with auto-incrementing) and the state of the FIFO, transitions on HRDY may or may not occur. For more detailed information on the HPI peripheral, see the TMS320C645x DSP Host Port Interface (HPI) User's Guide (literature number SPRU969). C. The timing tw(HSTBH), HSTROBE high pulse duration, must be met between consecutive HPI accesses in HPI32 mode. Figure 7-51. HPI32 Write Timing (HAS Used) 184 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.13 Multichannel Buffered Serial Port (McBSP) The McBSP provides these functions: • Full-duplex communication • Double-buffered data registers, which allow a continuous data stream • Independent framing and clocking for receive and transmit • Direct interface to industry-standard codecs, analog interface chips (AICs), and other serially connected analog-to-digital (A/D) and digital-to-analog (D/A) devices • External shift clock or an internal, programmable frequency shift clock for data transfer For more detailed information on the McBSP peripheral, see the TMS320C6000 DSP Multichannel Buffered Serial Port ( McBSP) Reference Guide (literature number SPRU580, rev. E or later). Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 185 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.13.1 McBSP Device-Specific Information The CLKS signal is shared by both McBSP0 and McBSP1 on this device. Also, the CLKGDV field of the Sample Rate Generator Register (SRGR) must always be set to a value of 1 or greater. The McBSP Data Receive Register (DRR) and Data Transmit Register (DXR) can be accessed through two separate busses: a configuration bus and a data bus. Both paths can be used by the CPU and the EDMA. The data bus should be used to service the McBSP as this path provides better performance. However, since the data path shares a bridge with the PCI and UTOPIA peripherals (see Figure 4-1), the configuration path should be used in cases where these peripherals are being used to avoid any performance degradation. Note that the PCI peripheral consists of an independent master and slave. Performance degradation is only a concern when this peripheral is used to initiate transactions on the external bus. 7.13.1.1 McBSP Peripheral Register Description(s) Table 7-57. McBSP 0 Registers HEX ADDRESS RANGE 186 ACRONYM REGISTER NAME COMMENTS 028C 0000 DRR0 McBSP0 Data Receive Register via Configuration Bus 3000 0000 DRR0 McBSP0 Data Receive Register via EDMA3 Bus 028C 0004 DXR0 McBSP0 Data Transmit Register via Configuration Bus McBSP0 Data Transmit Register via EDMA Bus 3000 0010 DXR0 028C 0008 SPCR0 028C 000C RCR0 McBSP0 Receive Control Register 028C 0010 XCR0 McBSP0 Transmit Control Register 028C 0014 SRGR0 028C 0018 MCR0 028C 001C RCERE00 McBSP0 Enhanced Receive Channel Enable Register 0 Partition A/B 028C 0020 XCERE00 McBSP0 Enhanced Transmit Channel Enable Register 0 Partition A/B 028C 0024 PCR0 028C 0028 RCERE10 McBSP0 Enhanced Receive Channel Enable Register 1 Partition C/D 028C 002C XCERE10 McBSP0 Enhanced Transmit Channel Enable Register 1 Partition C/D 028C 0030 RCERE20 McBSP0 Enhanced Receive Channel Enable Register 2 Partition E/F 028C 0034 XCERE20 McBSP0 Enhanced Transmit Channel Enable Register 2 Partition E/F 028C 0038 RCERE30 McBSP0 Enhanced Receive Channel Enable Register 3 Partition G/H 028C 003C XCERE30 McBSP0 Enhanced Transmit Channel Enable Register 3 Partition G/H 028C 0040 - 028F FFFF - The CPU and EDMA3 controller can only read this register; they cannot write to it. McBSP0 Serial Port Control Register McBSP0 Sample Rate Generator register McBSP0 Multichannel Control Register McBSP0 Pin Control Register Reserved C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-58. McBSP 1 Registers HEX ADDRESS RANGE ACRONYM REGISTER NAME 0290 0000 DRR1 McBSP1 Data Receive Register via Configuration Bus 3400 0000 DRR1 McBSP1 Data Receive Register via EDMA bus 0290 0004 DXR1 McBSP1 Data Transmit Register via configuration bus 3400 0010 DXR1 McBSP1 Data Transmit Register via EDMA bus 0290 0008 SPCR1 McBSP1 serial port control register 0290 000C RCR1 McBSP1 Receive Control Register 0290 0010 XCR1 McBSP1 Transmit Control Register 0290 0014 SRGR1 0290 0018 MCR1 0290 001C RCERE01 McBSP1 Enhanced Receive Channel Enable Register 0 Partition A/B 0290 0020 XCERE01 McBSP1 Enhanced Transmit Channel Enable Register 0 Partition A/B 0290 0024 PCR1 0290 0028 RCERE11 McBSP1 Enhanced Receive Channel Enable Register 1 Partition C/D 0290 002C XCERE11 McBSP1 Enhanced Transmit Channel Enable Register 1 Partition C/D 0290 0030 RCERE21 McBSP1 Enhanced Receive Channel Enable Register 2 Partition E/F 0290 0034 XCERE21 McBSP1 Enhanced Transmit Channel Enable Register 2 Partition E/F 0290 0038 RCERE31 McBSP1 Enhanced Receive Channel Enable Register 3 Partition G/H 0290 003C XCERE31 McBSP1 Enhanced Transmit Channel Enable Register 3 Partition G/H 0290 0040 - 0293 FFFF - Submit Documentation Feedback COMMENTS The CPU and EDMA controller can only read this register; they cannot write to it. McBSP1 sample rate generator register McBSP1 multichannel control register McBSP1 Pin Control Register Reserved C64x+ Peripheral Information and Electrical Specifications 187 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.13.2 McBSP Electrical Data/Timing 7.13.2.1 Multichannel Buffered Serial Port (McBSP) Timing Table 7-59. Timing Requirements for McBSP (1) (see Figure 7-52) -720 -850 A-1000/-1000 -1200 NO. MIN UNIT MAX 2 tc(CKRX) Cycle time, CLKR/X CLKR/X ext 6P or 10 (2) (3) ns 3 tw(CKRX) Pulse duration, CLKR/X high or CLKR/X low CLKR/X ext 0.5tc(CKRX) –1 (4) ns 5 tsu(FRH-CKRL) Setup time, external FSR high before CLKR low 6 th(CKRL-FRH) Hold time, external FSR high after CLKR low 7 tsu(DRV-CKRL) Setup time, DR valid before CLKR low 8 th(CKRL-DRV) Hold time, DR valid after CLKR low 10 tsu(FXH-CKXL) Setup time, external FSX high before CLKX low 11 th(CKXL-FXH) Hold time, external FSX high after CLKX low (1) CLKR int 9 CLKR ext 1.3 CLKR int 6 CLKR ext 3 CLKR int 8 CLKR ext 0.9 CLKR int 3 CLKR ext 3.1 CLKX int 9 CLKX ext 1.3 CLKX int 6 CLKX ext 3 ns ns ns ns ns ns CLKRP = CLKXP = FSRP = FSXP = 0. If polarity of any of the signals is inverted, then the timing references of that signal are also inverted. P = 1/CPU clock frequency in ns. For example, when running parts at 1000 MHz, use P = 1 ns. Use whichever value is greater. Minimum CLKR/X cycle times must be met, even when CLKR/X is generated by an internal clock source. The minimum CLKR/X cycle times are based on internal logic speed; the maximum usable speed may be lower due to EDMA limitations and AC timing requirements. This parameter applies to the maximum McBSP frequency. Operate serial clocks (CLKR/X) in the reasonable range of 40/60 duty cycle. (2) (3) (4) Table 7-60. Switching Characteristics Over Recommended Operating Conditions for McBSP (1) (2) (see Figure 7-52) NO. -720 -850 A-1000/-1000 -1200 PARAMETER MIN (1) (2) (3) (4) (5) (6) 188 1 td(CKSH-CKRXH) Delay time, CLKS high to CLKR/X high for internal CLKR/X generated from CLKS input (3) 2 tc(CKRX) Cycle time, CLKR/X CLKR/X int UNIT MAX 1.4 6P or 10 (4) (5) (6) 10 ns ns CLKRP = CLKXP = FSRP = FSXP = 0. If polarity of any of the signals is inverted, then the timing references of that signal are also inverted. Minimum delay times also represent minimum output hold times. The CLKS signal is shared by both McBSP0 and McBSP1 on this device. Minimum CLKR/X cycle times must be met, even when CLKR/X is generated by an internal clock source. Minimum CLKR/X cycle times are based on internal logic speed; the maximum usable speed may be lower due to EDMA limitations and AC timing requirements. P = 1/CPU clock frequency in ns. For example, when running parts at 1000 MHz, use P = 1 ns. Use whichever value is greater. C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-60. Switching Characteristics Over Recommended Operating Conditions for McBSP (see Figure 7-52) (continued) NO. -720 -850 A-1000/-1000 -1200 PARAMETER MIN (8) (9) ns CLKR int –2.1 3.3 ns CLKX int –1.7 3 CLKX ext 1.7 9 CLKX int –3.9 4 CLKX ext 2.1 9 CLKX int –3.9 + D1 (8) 4 + D2 (8) (8) 9 + D2 (8) Pulse duration, CLKR/X high or CLKR/X low CLKR/X int 4 td(CKRH-FRV) Delay time, CLKR high to internal FSR valid Delay time, CLKX high to internal FSX valid 12 tdis(CKXH-DXHZ) Disable time, DX high impedance following last data bit from CLKX high 13 td(CKXH-DXV) Delay time, CLKX high to DX valid 14 (7) C + 1 (7) tw(CKRX) td(CKXH-FXV) td(FXH-DXV) MAX C – 1 (7) 3 9 UNIT CLKX ext 2.1 + D1 Delay time, FSX high to DX valid FSX int –2.3 + D1 (9) 5.6 + D2 (9) ONLY applies when in data delay 0 (XDATDLY = 00b) mode FSX ext 1.9 + D1 (9) 9 + D2 (9) ns ns ns ns C = H or L S = sample rate generator input clock = 6P if CLKSM = 1 (P = 1/CPU clock frequency) S = sample rate generator input clock = P_clks if CLKSM = 0 (P_clks = CLKS period) H = CLKX high pulse width = (CLKGDV/2 + 1) * S if CLKGDV is even H = (CLKGDV + 1)/2 * S if CLKGDV is odd L = CLKX low pulse width = (CLKGDV/2) * S if CLKGDV is even L = (CLKGDV + 1)/2 * S if CLKGDV is odd CLKGDV should be set appropriately to ensure the McBSP bit rate does not exceed the maximum limit (see (4) above). Extra delay from CLKX high to DX valid applies only to the first data bit of a device, if and only if DXENA = 1 in SPCR. if DXENA = 0, then D1 = D2 = 0 if DXENA = 1, then D1 = 6P, D2 = 12P Extra delay from FSX high to DX valid applies only to the first data bit of a device, if and only if DXENA = 1 in SPCR. if DXENA = 0, then D1 = D2 = 0 if DXENA = 1, then D1 = 6P, D2 = 12P Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 189 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 CLKS 1 2 3 3 CLKR 4 4 FSR (int) 5 6 FSR (ext) 7 DR 8 Bit(n-1) (n-2) (n-3) 2 3 3 CLKX 9 FSX (int) 11 10 FSX (ext) FSX (XDATDLY=00b) 14 13 (A) Bit(n-1) 12 DX Bit 0 A. Parameter No. 13 applies to the first data bit only when XDATDLY ≠ 0. B. The CLKS signal is shared by both McBSP0 and McBSP1 on this device. 13 (A) (n-2) (n-3) Figure 7-52. McBSP Timing(B) Table 7-61. Timing Requirements for FSR When GSYNC = 1 (see Figure 7-53) -720 -850 A-1000/-1000 -1200 NO. MIN UNIT MAX 1 tsu(FRH-CKSH) Setup time, FSR high before CLKS high 4 ns 2 th(CKSH-FRH) Hold time, FSR high after CLKS high 4 ns CLKS 1 2 FSR external CLKR/X (no need to resync) CLKR/X (needs resync) Figure 7-53. FSR Timing When GSYNC = 1 190 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-62. Timing Requirements for McBSP as SPI Master or Slave: CLKSTP = 10b, CLKXP = 0 (1) (2) (see Figure 7-54) -720 -850 A-1000/-1000 -1200 NO. MASTER MIN (1) (2) 4 tsu(DRV-CKXL) Setup time, DR valid before CLKX low 5 th(CKXL-DRV) Hold time, DR valid after CLKX low UNIT SLAVE MAX MIN MAX 12 2 – 18P ns 4 5 + 36P ns P = 1/CPU clock frequency in ns. For example, when running parts at 1000 MHz, use P = 1 ns. For all SPI Slave modes, CLKG is programmed as 1/6 of the CPU clock by setting CLKSM = CLKGDV = 1. Table 7-63. Switching Characteristics Over Recommended Operating Conditions for McBSP as SPI Master or Slave: CLKSTP = 10b, CLKXP = 0 (1) (2) (see Figure 7-54) NO. -720 -850 A-1000/-1000 -1200 PARAMETER MASTER 1 (1) (2) (3) (4) (5) Hold time, FSX low after CLKX low (4) th(CKXL-FXL) (5) 2 td(FXL-CKXH) Delay time, FSX low to CLKX high 3 td(CKXH-DXV) Delay time, CLKX high to DX valid 6 tdis(CKXL-DXHZ) Disable time, DX high impedance following last data bit from CLKX low 7 tdis(FXH-DXHZ) Disable time, DX high impedance following last data bit from FSX high 8 td(FXL-DXV) Delay time, FSX low to DX valid (3) UNIT SLAVE MIN MAX T–2 T+3 L–2 L+3 –2 4 L–2 L+3 MIN MAX ns ns 18P + 2.8 30P + 17 ns ns 6P + 3 18P + 17 ns 12P + 2 24P + 17 ns P = 1/CPU clock frequency in ns. For example, when running parts at 1000 MHz, use P = 1 ns. For all SPI Slave modes, CLKG is programmed as 1/6 of the CPU clock by setting CLKSM = CLKGDV = 1. S = Sample rate generator input clock = 6P if CLKSM = 1 (P = 1/CPU clock frequency) S = Sample rate generator input clock = P_clks if CLKSM = 0 (P_clks = CLKS period) T = CLKX period = (1 + CLKGDV) * S H = CLKX high pulse width = (CLKGDV/2 + 1) * S if CLKGDV is even H = (CLKGDV + 1)/2 * S if CLKGDV is odd L = CLKX low pulse width = (CLKGDV/2) * S if CLKGDV is even L = (CLKGDV + 1)/2 * S if CLKGDV is odd FSRP = FSXP = 1. As a SPI Master, FSX is inverted to provide active-low slave-enable output. As a Slave, the active-low signal input on FSX and FSR is inverted before being used internally. CLKXM = FSXM = 1, CLKRM = FSRM = 0 for Master McBSP CLKXM = CLKRM = FSXM = FSRM = 0 for Slave McBSP FSX should be low before the rising edge of clock to enable Slave devices and then begin a SPI transfer at the rising edge of the Master clock (CLKX). CLKX 1 2 FSX 7 6 DX 8 3 Bit 0 Bit(n-1) 4 DR Bit 0 (n-2) (n-3) (n-4) 5 Bit(n-1) (n-2) (n-3) (n-4) Figure 7-54. McBSP Timing as SPI Master or Slave: CLKSTP = 10b, CLKXP = 0 Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 191 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-64. Timing Requirements for McBSP as SPI Master or Slave: CLKSTP = 11b, CLKXP = 0 (1) (2) (see Figure 7-55) -720 -850 A-1000/-1000 -1200 NO. UNIT MASTER MIN (1) (2) 4 tsu(DRV-CKXH) Setup time, DR valid before CLKX high 5 th(CKXH-DRV) Hold time, DR valid after CLKX high SLAVE MAX MIN MAX 12 2 – 18P ns 4 5 + 36P ns P = 1/CPU clock frequency in ns. For example, when running parts at 1000 MHz, use P = 1 ns. For all SPI Slave modes, CLKG is programmed as 1/6 of the CPU clock by setting CLKSM = CLKGDV = 1. Table 7-65. Switching Characteristics Over Recommended Operating Conditions for McBSP as SPI Master or Slave: CLKSTP = 11b, CLKXP = 0 (1) (2) (see Figure 7-55) NO. -720 -850 A-1000/-1000 -1200 PARAMETER MASTER 1 (1) (2) (3) (4) (5) Hold time, FSX low after CLKX low (4) th(CKXL-FXL) (5) (3) UNIT SLAVE MIN MAX L–2 L+3 MIN MAX ns 2 td(FXL-CKXH) Delay time, FSX low to CLKX high T–2 T+3 3 td(CKXL-DXV) Delay time, CLKX low to DX valid –2 4 18P + 2.8 30P + 17 ns ns 6 tdis(CKXL-DXHZ) Disable time, DX high impedance following last data bit from CLKX low –2 4 18P + 3 30P + 17 ns 7 td(FXL-DXV) Delay time, FSX low to DX valid H–2 H+4 12P + 2 24P + 17 ns P = 1/CPU clock frequency in ns. For example, when running parts at 1000 MHz, use P = 1 ns. For all SPI Slave modes, CLKG is programmed as 1/6 of the CPU clock by setting CLKSM = CLKGDV = 1. S = Sample rate generator input clock = 6P if CLKSM = 1 (P = 1/CPU clock frequency) S = Sample rate generator input clock = P_clks if CLKSM = 0 (P_clks = CLKS period) T = CLKX period = (1 + CLKGDV) * S H = CLKX high pulse width = (CLKGDV/2 + 1) * S if CLKGDV is even H = (CLKGDV + 1)/2 * S if CLKGDV is odd L = CLKX low pulse width = (CLKGDV/2) * S if CLKGDV is even L = (CLKGDV + 1)/2 * S if CLKGDV is odd FSRP = FSXP = 1. As a SPI Master, FSX is inverted to provide active-low slave-enable output. As a Slave, the active-low signal input on FSX and FSR is inverted before being used internally. CLKXM = FSXM = 1, CLKRM = FSRM = 0 for Master McBSP CLKXM = CLKRM = FSXM = FSRM = 0 for Slave McBSP FSX should be low before the rising edge of clock to enable Slave devices and then begin a SPI transfer at the rising edge of the Master clock (CLKX). CLKX 1 2 6 Bit 0 7 FSX DX 3 Bit(n-1) 4 DR Bit 0 (n-2) (n-3) (n-4) 5 Bit(n-1) (n-2) (n-3) (n-4) Figure 7-55. McBSP Timing as SPI Master or Slave: CLKSTP = 11b, CLKXP = 0 192 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-66. Timing Requirements for McBSP as SPI Master or Slave: CLKSTP = 10b, CLKXP = 1 (1) (2) (see Figure 7-56) -720 -850 A-1000/-1000 -1200 NO. MASTER MIN (1) (2) 4 tsu(DRV-CKXH) Setup time, DR valid before CLKX high 5 th(CKXH-DRV) Hold time, DR valid after CLKX high UNIT SLAVE MAX MIN MAX 12 2 – 18P ns 4 5 + 36P ns P = 1/CPU clock frequency in ns. For example, when running parts at 1000 MHz, use P = 1 ns. For all SPI Slave modes, CLKG is programmed as 1/6 of the CPU clock by setting CLKSM = CLKGDV = 1. Table 7-67. Switching Characteristics Over Recommended Operating Conditions for McBSP as SPI Master or Slave: CLKSTP = 10b, CLKXP = 1 (1) (2) (see Figure 7-56) NO. -720 -850 A-1000/-1000 -1200 PARAMETER MASTER 1 (1) (2) (3) (4) (5) Hold time, FSX low after CLKX high (4) th(CKXH-FXL) (5) 2 td(FXL-CKXL) Delay time, FSX low to CLKX low 3 td(CKXL-DXV) Delay time, CLKX low to DX valid 6 tdis(CKXH-DXHZ) Disable time, DX high impedance following last data bit from CLKX high 7 tdis(FXH-DXHZ) Disable time, DX high impedance following last data bit from FSX high 8 td(FXL-DXV) Delay time, FSX low to DX valid (3) UNIT SLAVE MIN MAX T–2 T+3 H–2 H+3 –2 4 H–2 H+3 MIN MAX ns ns 18P + 2.8 30P + 17 ns ns 6P + 3 18P + 17 ns 12P + 2 24P + 17 ns P = 1/CPU clock frequency in ns. For example, when running parts at 1000 MHz, use P = 1 ns. For all SPI Slave modes, CLKG is programmed as 1/6 of the CPU clock by setting CLKSM = CLKGDV = 1. S = Sample rate generator input clock = 6P if CLKSM = 1 (P = 1/CPU clock frequency) S = Sample rate generator input clock = P_clks if CLKSM = 0 (P_clks = CLKS period) T = CLKX period = (1 + CLKGDV) * S H = CLKX high pulse width = (CLKGDV/2 + 1) * S if CLKGDV is even H = (CLKGDV + 1)/2 * S if CLKGDV is odd L = CLKX low pulse width = (CLKGDV/2) * S if CLKGDV is even L = (CLKGDV + 1)/2 * S if CLKGDV is odd FSRP = FSXP = 1. As a SPI Master, FSX is inverted to provide active-low slave-enable output. As a Slave, the active-low signal input on FSX and FSR is inverted before being used internally. CLKXM = FSXM = 1, CLKRM = FSRM = 0 for Master McBSP CLKXM = CLKRM = FSXM = FSRM = 0 for Slave McBSP FSX should be low before the rising edge of clock to enable Slave devices and then begin a SPI transfer at the rising edge of the Master clock (CLKX). CLKX 1 2 FSX 7 6 DX 8 3 Bit 0 Bit(n-1) 4 DR Bit 0 (n-2) (n-3) (n-4) 5 Bit(n-1) (n-2) (n-3) (n-4) Figure 7-56. McBSP Timing as SPI Master or Slave: CLKSTP = 10b, CLKXP = 1 Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 193 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-68. Timing Requirements for McBSP as SPI Master or Slave: CLKSTP = 11b, CLKXP = 1 (1) (2) (see Figure 7-57) -720 -850 A-1000/-1000 -1200 NO. MASTER MIN (1) (2) 4 tsu(DRV-CKXH) Setup time, DR valid before CLKX high 5 th(CKXH-DRV) Hold time, DR valid after CLKX high UNIT SLAVE MAX MIN MAX 12 2 – 18P ns 4 5 + 36P ns P = 1/CPU clock frequency in ns. For example, when running parts at 1000 MHz, use P = 1 ns. For all SPI Slave modes, CLKG is programmed as 1/6 of the CPU clock by setting CLKSM = CLKGDV = 1. Table 7-69. Switching Characteristics Over Recommended Operating Conditions for McBSP as SPI Master or Slave: CLKSTP = 11b, CLKXP = 1 (1) (2) (see Figure 7-57) NO. -720 -850 A-1000/-1000 -1200 PARAMETER MASTER 1 (1) (2) (3) (4) (5) Hold time, FSX low after CLKX high (4) th(CKXH-FXL) (5) (3) UNIT SLAVE MIN MAX H–2 H+3 MIN MAX ns 2 td(FXL-CKXL) Delay time, FSX low to CLKX low T–2 T+1 3 td(CKXH-DXV) Delay time, CLKX high to DX valid –2 4 18P + 2.8 30P + 17 ns ns 6 tdis(CKXH-DXHZ) Disable time, DX high impedance following last data bit from CLKX high –2 4 18P + 3 30P + 17 ns 7 td(FXL-DXV) Delay time, FSX low to DX valid L–2 L+4 12P + 2 24P + 17 ns P = 1/CPU clock frequency in ns. For example, when running parts at 1000 MHz, use P = 1 ns. For all SPI Slave modes, CLKG is programmed as 1/6 of the CPU clock by setting CLKSM = CLKGDV = 1. S = Sample rate generator input clock = 6P if CLKSM = 1 (P = 1/CPU clock frequency) S = Sample rate generator input clock = P_clks if CLKSM = 0 (P_clks = CLKS period) T = CLKX period = (1 + CLKGDV) * S H = CLKX high pulse width = (CLKGDV/2 + 1) * S if CLKGDV is even H = (CLKGDV + 1)/2 * S if CLKGDV is odd L = CLKX low pulse width = (CLKGDV/2) * S if CLKGDV is even L = (CLKGDV + 1)/2 * S if CLKGDV is odd FSRP = FSXP = 1. As a SPI Master, FSX is inverted to provide active-low slave-enable output. As a Slave, the active-low signal input on FSX and FSR is inverted before being used internally. CLKXM = FSXM = 1, CLKRM = FSRM = 0 for Master McBSP CLKXM = CLKRM = FSXM = FSRM = 0 for Slave McBSP FSX should be low before the rising edge of clock to enable Slave devices and then begin a SPI transfer at the rising edge of the Master clock (CLKX). CLKX 1 2 FSX 6 DX 7 3 Bit 0 Bit(n-1) 4 DR Bit 0 (n-2) (n-3) (n-4) 5 Bit(n-1) (n-2) (n-3) (n-4) Figure 7-57. McBSP Timing as SPI Master or Slave: CLKSTP = 11b, CLKXP = 1 194 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.14 Ethernet MAC (EMAC) The Ethernet Media Access Controller (EMAC) module provides an efficient interface between the C6455 DSP core processor and the networked community. The EMAC supports 10Base-T (10 Mbits/second [Mbps]), and 100BaseTX (100 Mbps), in either half- or full-duplex mode, and 1000BaseT (1000 Mbps) in full-duplex mode, with hardware flow control and quality-of-service (QOS) support. The EMAC module conforms to the IEEE 802.3-2002 standard, describing the “Carrier Sense Multiple Access with Collision Detection (CSMA/CD) Access Method and Physical Layer” specifications. The IEEE 802.3 standard has also been adopted by ISO/IEC and re-designated as ISO/IEC 8802-3:2000(E). Deviation from this standard, the EMAC module does not use the Transmit Coding Error signal MTXER. Instead of driving the error pin when an underflow condition occurs on a transmitted frame, the EMAC will intentionally generate an incorrect checksum by inverting the frame CRC, so that the transmitted frame will be detected as an error by the network. The EMAC control module is the main interface between the device core processor, the MDIO module, and the EMAC module. The relationship between these three components is shown in Figure 7-58. The EMAC control module contains the necessary components to allow the EMAC to make efficient use of device memory, plus it controls device interrupts. The EMAC control module incorporates 8K-bytes of internal RAM to hold EMAC buffer descriptors. The relationship between these three components is shown in Figure 7-58. Interrupt Controller Configuration Bus DMA Memory Transfer Controller Peripheral Bus EMAC Control Module EMAC/MDIO Interrupt EMAC Module MDIO Module Ethernet Bus MDIO Bus Figure 7-58. EMAC, MDIO, and EMAC Control Modules For more detailed information on the EMAC/MDIO, see the TMS320C645x DSP EMAC/MDIO Module Reference Guide (literature number SPRU975). Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 195 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.14.1 EMAC Device-Specific Information Interface Modes The EMAC module on the TMS320C6455 supports four interface modes: Media Independent Interface (MII), Reduced Media Independent Interface (RMII), Gigabit Media Independent Interface (GMII), and Reduced Gigabit Media Independent Interface (RGMII). The MII and GMII interface modes are defined in the IEEE 802.3-2002 standard. The RGMII mode of the EMAC conforms to the Reduced Gigabit Media Independent Interface (RGMII) Specification (version 2.0). The RGMII mode implements the same functionality as the GMII mode, but with a reduced number of pins. Data and control information is transmitted and received using both edges of the transmit and receive clocks (TXC and RXC). Note: The EMAC internally delays the transmit clock (TXC) with respect to the transmit data and control pins. Therefore, the EMAC conforms to the RGMII-ID operation of the RGMII specification. However, the EMAC does not delay the receive clock (RXC); this signal must be delayed with respect to the receive data and control pins outside of the DSP. The RMII mode of the EMAC conforms to the RMII Specification (revision 1.2), as written by the RMII Consortium. As the name implies, the Reduced Media Independent Interface (RMII) mode is a reduced pin count version of the MII mode. Interface Mode Select The EMAC uses the same pins for the MII, GMII, and RMII modes. Standalone pins are included for the RGMII mode due to specific voltage requirements. Only one mode can be used at a time. The mode used is selected at device reset based on the MACSEL[1:0] configuration pins (for more detailed information, see Section 3, Device Configuration). Table 7-70 shows which multiplexed pins are used in the MII, GMII, and RMII modes on the EMAC. For a detailed description of these pin functions, see Table 2-3, Terminal Functions. 196 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-70. EMAC/MDIO Multiplexed Pins (MII, RMII, and GMII Modes) BALL NUMBER DEVICE PIN NAME MII (MAC_SEL = 00b) RMII (MAC_SEL = 01b) GMII (MAC_SEL = 10b) J2 URDATA0/MRXD0/RMRXD0 MRXD0 RMRXD0 MRXD0 H3 URDATA1/MRXD1/RMRXD1 MRXD1 RMRXD1 MRXD1 J1 URDATA2/MRXD2 MRXD2 MRXD2 J3 URDATA3/MRXD3 MRXD3 MRXD3 L1 URDATA4/MRXD4 MRXD4 L2 URDATA5/MRXD5 MRXD5 H2 URDATA6/MRXD6 MRXD6 M2 URDATA7/MRXD7 MRXD7 M1 UXDATA0/MTXD0/RMTXD0 MTXD0 RMTXD0 MTXD0 RMTXD1 MTXD1 L4 UXDATA1/MTXD1/RMTXD1 MTXD1 M4 UXDATA2/MTXD2 MTXD2 MTXD2 K4 UXDATA3/MTXD3 MTXD3 MTXD3 L3 UXDATA4/MTXD4 MTXD4 L5 UXDATA5/MTXD5 MTXD5 M3 UXDATA6/MTXD6 MTXD6 N5 UXDATA7/MTXD7 MTXD7 H4 URSOC/MRXER/RMRXER MRXER H5 URENB/MRXDV MRXDV J5 UXENB/MTXEN/RMTXEN MTXEN RMTXEN MTXEN RMCRSDV MCRS RMRXER MRXER MRXDV J4 URCLAV/MCRS/RMCRSDV MCRS K3 UXSOC/MCOL MCOL K5 UXCLAV/GMTCLK H1 URCLK/MRCLK MRCLK N4 UXCLK/MTCLK/REFCLK MTCLK RMREFCLK MTCLK N3 UXADDR3/GMDIO MDIO MDIO MDIO M5 UXADDR4/GMDCLK MDCLK MDCLK MDCLK MCOL GMTCLK MRCLK Using the RMII Mode of the EMAC The Ethernet Media Access Controller (EMAC) contains logic that allows it to communicate using the Reduced Media Independent Interface (RMII) protocol. This logic must be taken out of reset before being used. To use the RMII mode of the EMAC follow these steps: 1. Enable the EMAC/MDIO through the Device State Control Registers. – Unlock the PERCFG0 register by writing 0x0F0A 0B00 to the PERLOCK register. – Set bit 4 in the PERCFG0 register within 16 SYSCLK3 clock cycles to enable the EMAC/MDIO. – Poll the PERSTAT0 register to verify state change. 2. Initialize the EMAC/MDIO as needed. 3. Release the RMII logic from reset by clearing the RMII_RST bit of the EMAC Configuration Register (see Section 3.4.5). As described in the previous section, the RMII mode of the EMAC must be selected by setting MACSEL[1:0] = 01b at device reset. Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 197 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Interface Mode Clocking The on-chip PLL2 and PLL2 Controller generate the clocks to the EMAC module in RGMII or GMII mode. When the EMAC is enabled with these modes, the input clock to the PLL2 Controller (CLKIN2) must have a 25-MHz frequency. For more information, see Section 7.8, PLL2 and PLL2 Controller. The EMAC uses SYSCLK1 of the PLL2 Controller to generate the necessary clocks for the GMII and RGMII modes. When these modes are used, the frequency of CLKIN2 must be 25 MHz. Also, divider D1 should be programmed to ÷2 mode [default] when using the GMII mode and to ÷5 mode when using the RGMII mode. Divider D1 is software programmable and, if necessary, must be programmed after device reset to ÷5 when the RGMII mode of the EMAC is used. 198 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.14.2 EMAC Peripheral Register Description(s) Table 7-71. Ethernet MAC (EMAC) Control Registers HEX ADDRESS RANGE ACRONYM 02C8 0000 TXIDVER 02C8 0004 TXCONTROL 02C8 0008 TXTEARDOWN 02C8 000F - 02C8 0010 RXIDVER 02C8 0014 RXCONTROL REGISTER NAME Transmit Identification and Version Register Transmit Control Register Transmit Teardown Register Reserved Receive Identification and Version Register Receive Control Register 02C8 0018 RXTEARDOWN 02C8 001C - Receive Teardown Register Reserved 02C8 0020 - 02C8 007C - Reserved 02C8 0080 TXINTSTATRAW 02C8 0084 TXINTSTATMASKED Transmit Interrupt Status (Unmasked) Register 02C8 0088 TXINTMASKSET 02C8 008C TXINTMASKCLEAR 02C8 0090 MACINVECTOR 02C8 0194 - 02C8 019C - 02C8 01A0 RXINTSTATRAW 01C8 01A4 RXINTSTATMASKED 01C8 01A8 RXINTMASKSET 01C8 01AC RXINTMASKCLEAR Receive Interrupt Mask Clear Register 01C8 01B0 MACINTSTATRAW MAC Interrupt Status (Unmasked) Register 01C8 01B4 MACINTSTATMASKED 01C8 01B8 MACINTMASKSET Transmit Interrupt Status (Masked) Register Transmit Interrupt Mask Set Register Transmit Interrupt Mask Clear Register MAC Input Vector Register Reserved Receive Interrupt Status (Unmasked) Register Receive Interrupt Status (Masked) Register Receive Interrupt Mask Set Register MAC Interrupt Status (Masked) Register MAC Interrupt Mask Set Register 01C8 01BC MACINTMASKCLEAR 02C8 00C0 - 02C8 00FC - 02C8 0100 RXMBPENABLE Receive Multicast/Broadcast/Promiscuous Channel Enable Register 02C8 0104 RXUNICASTSET Receive Unicast Enable Set Register 02C8 0108 RXUNICASTCLEAR 02C8 010C RXMAXLEN 02C8 0110 RXBUFFEROFFSET MAC Interrupt Mask Clear Register Reserved Receive Unicast Clear Register Receive Maximum Length Register Receive Buffer Offset Register 02C8 0114 RXFILTERLOWTHRESH 02C8 0118 - 02C8 011C - 02C8 0120 RX0FLOWTHRESH Receive Channel 0 Flow Control Threshold Register 02C8 0124 RX1FLOWTHRESH Receive Channel 1 Flow Control Threshold Register 02C8 0128 RX2FLOWTHRESH Receive Channel 2 Flow Control Threshold Register 02C8 012C RX3FLOWTHRESH Receive Channel 3 Flow Control Threshold Register 02C8 0130 RX4FLOWTHRESH Receive Channel 4 Flow Control Threshold Register 02C8 0134 RX5FLOWTHRESH Receive Channel 5 Flow Control Threshold Register 02C8 0138 RX6FLOWTHRESH Receive Channel 6 Flow Control Threshold Register 02C8 013C RX7FLOWTHRESH Receive Channel 7 Flow Control Threshold Register 02C8 0140 RX0FREEBUFFER Receive Channel 0 Free Buffer Count Register 02C8 0144 RX1FREEBUFFER Receive Channel 1 Free Buffer Count Register 02C8 0148 RX2FREEBUFFER Receive Channel 2 Free Buffer Count Register 02C8 014C RX3FREEBUFFER Receive Channel 3 Free Buffer Count Register 02C8 0150 RX4FREEBUFFER Receive Channel 4 Free Buffer Count Register 02C8 0154 RX5FREEBUFFER Receive Channel 5 Free Buffer Count Register Submit Documentation Feedback Receive Filter Low Priority Frame Threshold Register Reserved C64x+ Peripheral Information and Electrical Specifications 199 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-71. Ethernet MAC (EMAC) Control Registers (continued) 200 HEX ADDRESS RANGE ACRONYM 02C8 0158 RX6FREEBUFFER REGISTER NAME Receive Channel 6 Free Buffer Count Register 02C8 015C RX7FREEBUFFER Receive Channel 7 Free Buffer Count Register 02C8 0160 MACCONTROL MAC Control Register 02C8 0164 MACSTATUS MAC Status Register 02C8 0168 EMCONTROL Emulation Control Register 02C8 016C FIFOCONTROL 02C8 0170 MACCONFIG MAC Configuration Register 02C8 0174 SOFTRESET Soft Reset Register 02C8 0178 - 02C8 01CC - 02C8 01D0 MACSRCADDRLO MAC Source Address Low Bytes Register (Lower 32-bits) 02C8 01D4 MACSRCADDRHI MAC Source Address High Bytes Register (Upper 32-bits) 02C8 01D8 MACHASH1 MAC Hash Address Register 1 02C8 01DC MACHASH2 MAC Hash Address Register 2 02C8 01E0 BOFFTEST Back Off Test Register 02C8 01E4 TPACETEST FIFO Control Register (Transmit and Receive) Reserved Transmit Pacing Algorithm Test Register 02C8 01E8 RXPAUSE Receive Pause Timer Register 02C8 01EC TXPAUSE Transmit Pause Timer Register 02C8 01F0 - 02C8 01FC - 02C8 0200 - 02C8 02FC (see Table 7-72) 02C8 0300 - 02C8 03FC - Reserved 02C8 0400 - 02C8 04FC - Reserved 02C8 0500 MACADDRLO MAC Address Low Bytes Register (used in receive address matching) 02C8 0504 MACADDRHI MAC Address High Bytes Register (used in receive address matching) 02C8 0508 MACINDEX Reserved EMAC Statistics Registers MAC Index Register 02C8 050C - 02C8 05FC - 02C8 0600 TX0HDP Reserved Transmit Channel 0 DMA Head Descriptor Pointer Register 02C8 0604 TX1HDP Transmit Channel 1 DMA Head Descriptor Pointer Register 02C8 0608 TX2HDP Transmit Channel 2 DMA Head Descriptor Pointer Register 02C8 060C TX3HDP Transmit Channel 3 DMA Head Descriptor Pointer Register 02C8 0610 TX4HDP Transmit Channel 4 DMA Head Descriptor Pointer Register 02C8 0614 TX5HDP Transmit Channel 5 DMA Head Descriptor Pointer Register 02C8 0618 TX6HDP Transmit Channel 6 DMA Head Descriptor Pointer Register 02C8 061C TX7HDP Transmit Channel 7 DMA Head Descriptor Pointer Register 02C8 0620 RX0HDP Receive Channel 0 DMA Head Descriptor Pointer Register 02C8 0624 RX1HDP Receive Channel 1 DMA Head Descriptor Pointer Register 02C8 0628 RX2HDP Receive Channel 2 DMA Head Descriptor Pointer Register 02C8 062C RX3HDP Receive Channel 3 DMA Head Descriptor Pointer Register 02C8 0630 RX4HDP Receive Channel 4 DMA Head Descriptor Pointer Register 02C8 0634 RX5HDP Receive Channel 5 DMA Head Descriptor Pointer Register 02C8 0638 RX6HDP Receive Channel 6 DMA Head Descriptor Pointer Register 02C8 063C RX7HDP Receive Channel 7 DMA Head Descriptor Pointer Register 02C8 0640 TX0CP Transmit Channel 0 Completion Pointer (Interrupt Acknowledge) Register 02C8 0644 TX1CP Transmit Channel 1 Completion Pointer (Interrupt Acknowledge) Register 02C8 0648 TX2CP Transmit Channel 2 Completion Pointer (Interrupt Acknowledge) Register C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-71. Ethernet MAC (EMAC) Control Registers (continued) HEX ADDRESS RANGE ACRONYM REGISTER NAME 02C8 064C TX3CP Transmit Channel 3 Completion Pointer (Interrupt Acknowledge) Register 02C8 0650 TX4CP Transmit Channel 4 Completion Pointer (Interrupt Acknowledge) Register 02C8 0654 TX5CP Transmit Channel 5 Completion Pointer (Interrupt Acknowledge) Register 02C8 0658 TX6CP Transmit Channel 6 Completion Pointer (Interrupt Acknowledge) Register 02C8 065C TX7CP Transmit Channel 7 Completion Pointer (Interrupt Acknowledge) Register 02C8 0660 RX0CP Receive Channel 0 Completion Pointer (Interrupt Acknowledge) Register 02C8 0664 RX1CP Receive Channel 1 Completion Pointer (Interrupt Acknowledge) Register 02C8 0668 RX2CP Receive Channel 2 Completion Pointer (Interrupt Acknowledge) Register 02C8 066C RX3CP Receive Channel 3 Completion Pointer (Interrupt Acknowledge) Register 02C8 0670 RX4CP Receive Channel 4 Completion Pointer (Interrupt Acknowledge) Register 02C8 0674 RX5CP Receive Channel 5 Completion Pointer (Interrupt Acknowledge) Register 02C8 0678 RX6CP Receive Channel 6 Completion Pointer (Interrupt Acknowledge) Register 02C8 067C RX7CP Receive Channel 7 Completion Pointer (Interrupt Acknowledge) Register 02C8 0680 - 02C8 06FC - Reserved 02C8 0700 - 02C8 077C - Reserved was State RAM Test Access Registers Processor Read and Write Access to Head Descriptor Pointers and Interrupt Acknowledge Registers 02C8 0780 - 02C8 0FFF - Reserved Table 7-72. EMAC Statistics Registers HEX ADDRESS RANGE ACRONYM 02C8 0200 RXGOODFRAMES Good Receive Frames Register 02C8 0204 RXBCASTFRAMES Broadcast Receive Frames Register (Total number of good broadcast frames received) 02C8 0208 RXMCASTFRAMES Multicast Receive Frames Register (Total number of good multicast frames received) 02C8 020C RXPAUSEFRAMES Pause Receive Frames Register 02C8 0210 RXCRCERRORS 02C8 0214 RXALIGNCODEERRORS 02C8 0218 RXOVERSIZED 02C8 021C RXJABBER 02C8 0220 RXUNDERSIZED Receive Undersized Frames Register (Total number of undersized frames received) 02C8 0224 RXFRAGMENTS Receive Frame Fragments Register 02C8 0228 RXFILTERED 02C8 022C RXQOSFILTERED Submit Documentation Feedback REGISTER NAME Receive CRC Errors Register (Total number of frames received with CRC errors) Receive Alignment/Code Errors Register (Total number of frames received with alignment/code errors) Receive Oversized Frames Register (Total number of oversized frames received) Receive Jabber Frames Register (Total number of jabber frames received) Filtered Receive Frames Register Received QOS Filtered Frames Register C64x+ Peripheral Information and Electrical Specifications 201 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-72. EMAC Statistics Registers (continued) HEX ADDRESS RANGE ACRONYM REGISTER NAME 02C8 0230 RXOCTETS Receive Octet Frames Register (Total number of received bytes in good frames) 02C8 0234 TXGOODFRAMES Good Transmit Frames Register (Total number of good frames transmitted) 02C8 0238 TXBCASTFRAMES Broadcast Transmit Frames Register 02C8 023C TXMCASTFRAMES Multicast Transmit Frames Register 02C8 0240 TXPAUSEFRAMES Pause Transmit Frames Register 02C8 0244 TXDEFERRED Deferred Transmit Frames Register 02C8 0248 TXCOLLISION Transmit Collision Frames Register 02C8 024C TXSINGLECOLL 02C8 0250 TXMULTICOLL 02C8 0254 TXEXCESSIVECOLL Transmit Single Collision Frames Register Transmit Multiple Collision Frames Register 02C8 0258 TXLATECOLL 02C8 025C TXUNDERRUN 02C8 0260 TXCARRIERSENSE 02C8 0264 TXOCTETS Transmit Excessive Collision Frames Register Transmit Late Collision Frames Register Transmit Underrun Error Register Transmit Carrier Sense Errors Register Transmit Octet Frames Register 02C8 0268 FRAME64 02C8 026C FRAME65T127 Transmit and Receive 64 Octet Frames Register Transmit and Receive 65 to 127 Octet Frames Register 02C8 0270 FRAME128T255 Transmit and Receive 128 to 255 Octet Frames Register 02C8 0274 FRAME256T511 Transmit and Receive 256 to 511 Octet Frames Register 02C8 0278 FRAME512T1023 Transmit and Receive 512 to 1023 Octet Frames Register 02C8 027C FRAME1024TUP Transmit and Receive 1024 to 1518 Octet Frames Register 02C8 0280 NETOCTETS 02C8 0284 RXSOFOVERRUNS Network Octet Frames Register Receive FIFO or DMA Start of Frame Overruns Register 02C8 0288 RXMOFOVERRUNS Receive FIFO or DMA Middle of Frame Overruns Register 02C8 028C RXDMAOVERRUNS Receive DMA Start of Frame and Middle of Frame Overruns Register 02C8 0290 - 02C8 02FC - Reserved Table 7-73. EMAC Control Module Registers HEX ADDRESS RANGE ACRONYM 02C8 1000 - 02C8 1004 EWCTL 02C8 1008 EWINTTCNT 02C8 100C - 02C8 17FF - REGISTER NAME Reserved EMAC Control Module Interrupt Control Register EMAC Control Module Interrupt Timer Count Register Reserved Table 7-74. EMAC Descriptor Memory 202 HEX ADDRESS RANGE ACRONYM 02C8 2000 - 02C8 3FFF - DESCRIPTION EMAC Descriptor Memory C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.14.3 EMAC Electrical Data/Timing 7.14.3.1 EMAC MII and GMII Electrical Data/Timing Table 7-75. Timing Requirements for MRCLK - MII and GMII Operation (see Figure 7-59) -720 -850 A-1000/-1000 -1200 NO. 1000 Mbps (GMII Only) MIN 1 tc(MRCLK) Cycle time, MRCLK 2 tw(MRCLKH) 3 tw(MRCLKL) 4 tt(MRCLK) Transition time, MRCLK MAX UNIT 100 Mbps 10 Mbps MIN MIN MAX MAX 8 40 400 ns Pulse duration, MRCLK high 2.8 14 140 ns Pulse duration, MRCLK low 2.8 14 140 1 ns 3 3 ns 4 1 2 4 3 MRCLK (Input) Figure 7-59. MRCLK Timing (EMAC – Receive) [MII and GMII Operation] Table 7-76. Timing Requirements for MTCLK - MII and GMII Operation (see Figure 7-60) -720 -850 A-1000/-1000 -1200 NO. 100 Mbps MIN UNIT 10 Mbps MAX MIN MAX 1 tc(MTCLK) Cycle time, MTCLK 40 400 ns 2 tw(MTCLKH) Pulse duration, MTCLK high 14 140 ns 3 tw(MTCLKL) Pulse duration, MTCLK low 14 140 ns 4 tt(MTCLK) Transition time, MTCLK 3 3 ns 4 1 2 3 4 MTCLK (Input) Figure 7-60. MTCLK Timing (EMAC – Transmit) [MII and GMII Operation] Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 203 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-77. Switching Characteristics Over Recommended Operating Conditions for GMTCLK - GMII Operation (see Figure 7-61) -720 -850 A-1000/-1000 -1200 NO. UNIT 1000 Mbps MIN MAX 1 tc(GMTCLK) Cycle time, GMTCLK 8 ns 2 tw(GMTCLKH) Pulse duration, GMTCLK high 2.8 ns 3 tw(GMTCLKL) Pulse duration, GMTCLK low 2.8 ns 4 tt(GMTCLK) Transition time, GMTCLK 1 ns 4 1 2 4 3 GMTCLK (Output) Figure 7-61. GMTCLK Timing (EMAC – Transmit) [GMII Operation] Table 7-78. Timing Requirements for EMAC MII and GMII Receive 10/100/1000 Mbit/s (1) (see Figure 7-62) -720 -850 A-1000/-1000 -1200 NO. 1000 Mbps MIN (1) 1 tsu(MRXD-MRCLKH) Setup time, receive selected signals valid before MRCLK high 2 th(MRCLKH-MRXD) Hold time, receive selected signals valid after MRCLK high UNIT 100/10 Mbps MAX MIN MAX 2 8 ns 0 8 ns For MII, Receive selected signals include: MRXD[3:0], MRXDV, and MRXER. For GMII, Receive selected signals include: MRXD[7:0], MRXDV, and MRXER. 1 2 MRCLK (Input) MRXD7−MRXD4(GMII only), MRXD3−MRXD0, MRXDV, MRXER (Inputs) Figure 7-62. EMAC Receive Interface Timing [MII and GMII Operation] 204 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-79. Switching Characteristics Over Recommended Operating Conditions for EMAC MII and GMII Transmit 10/100 Mbit/s (1) (see Figure 7-63) NO. -720 -850 A-1000/-1000 -1200 PARAMETER UNIT 100/10 Mbps 1 (1) td(MTCLKH-MTXD) Delay time, MTCLK high to transmit selected signals valid MIN MAX 5 25 ns For MII, Transmit selected signals include: MTXD[3:0] and MTXEN. For GMII, Transmit selected signals include: GMTXD[7:0] and MTXEN. 1 MTCLK (Input) MTXD7−MTXD4(GMII only), MTXD3−MTXD0, MTXEN (Outputs) Figure 7-63. EMAC Transmit Interface Timing [MII and GMII Operation] Table 7-80. Switching Characteristics Over Recommended Operating Conditions for EMAC GMII Transmit 1000 Mbit/s (1) (see Figure 7-64) NO. -720 -850 A-1000/-1000 -1200 PARAMETER UNIT 1000 Mbps 1 (1) td(GMTCLKH-MTXD) Delay time, GMTCLK high to transmit selected signals valid MIN MAX 0.5 5 ns For GMII, Transmit selected signals include: GMTXD[7:0] and MTXEN. 1 GMTCLK (Output) MTXD7−MTXD0, MTXEN (Outputs) Figure 7-64. EMAC Transmit Interface Timing [GMII Operation] Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 205 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.14.3.2 EMAC RMII Electrical Data/Timing The RMREFCLK pin is used to source a clock to the EMAC when it is configured for RMII operation. The RMREFCLK frequency should be 50 MHz 50 PPM with a duty cycle between 35% and 65%, inclusive. Table 7-81. Timing Requirements for RMREFCLK - RMII Operation (see Figure 7-65) NO. -720 -850 A-1000/-1000 -1200 PARAMETER UNIT MIN MAX 1 tw(RMREFCLKH) Pulse duration, RMREFCLK high 7 13 ns 2 tw(RMREFCLKL) Pulse duration, RMREFCLK low 7 13 ns 3 tt(RMREFCLK) Transition time, RMREFCLK 2 ns 3 1 RMREFCLK (Input) 2 3 Figure 7-65. RMREFCLK Timing Table 7-82. Switching Characteristics Over Recommended Operating Conditions for EMAC RMII Transmit 10/100 Mbit/s (1) (see Figure 7-66) NO. -720 -850 A-1000/-1000 -1200 PARAMETER UNIT 1000 Mbps 1 (1) td(RMREFCLKH-MTXD) Delay time, RMREFCLK high to transmit selected signals valid MIN MAX 3 10 ns For RMII, transmit selected signals include: MTXD[1:0] and MTXEN. 1 RMREFCLK (Input) MTXD1-MTXD0, MTXEN (Outputs) Figure 7-66. EMAC Transmit Interface Timing [RMII Operation] 206 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-83. Timing Requirements for EMAC RMII Input Receive for 100 Mbps (1) (see Figure 7-67) -720 -850 A-1000/-1000 -1200 NO. MIN (1) 1 tsu(MRXD-MREFCLK) Setup time, receive selected signals valid before MREFCLK (at DSP) high/low 2 th(MREFCLK-MRXD) Hold time, receive selected signals valid after MREFCLK (at DSP) high/low UNIT MAX 4.0 ns 2.0 ns For RMII, receive selected signals include: MRXD[1:0], MRXER, and MCRSDV. 3 1 RMREFCLK (Input) 2 4 3 5 MRXD1-MRXD0, MCRSDV, MRXER (Inputs) Figure 7-67. EMAC Receive Interface Timing [RMII Operation] Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 207 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.14.3.3 EMAC RGMII Electrical Data/Timing An extra clock signal, RGREFCLK, running at 125 MHz is included as a convenience to the user. Note that this reference clock is not a free-running clock. This should only be used by an external device if it does not expect a valid clock during device reset. Table 7-84. Switching Characteristics Over Recommended Operating Conditions for EMAC RGREFCLK RGMII Operation (see Figure 7-68) NO. -720 -850 A-1000/-1000 -1200 PARAMETER UNIT MIN MAX 8 - 0.8 8 + 0.8 ns Pulse duration, RGREFCLK high 3.2 4.8 ns Pulse duration, RGREFCLK low 3.2 4.8 ns 0.75 ns 1 tc(RGFCLK) Cycle time, RGREFCLK 2 tw(RGFCLKH) 3 tw(RGFCLKL) 4 tt(RGFCLK) Transition time, RGREFCLK 1 4 2 RGREFCLK (Output) 3 4 Figure 7-68. RGREFCLK Timing Table 7-85. Timing Requirements for RXC - RGMII Operation (see Figure 7-69) -720 -850 A-1000/-1000 -1200 NO. MIN 1 tc(RXC) Cycle time, RXC 3 4 208 tw(RXCH) tw(RXCL) tt(RXC) Pulse duration, RXC high Pulse duration, RXC low Transition time, RXC C64x+ Peripheral Information and Electrical Specifications MAX 10 Mbps 360 440 100 Mbps 36 44 1000 Mbps 2 UNIT 7.2 8.8 10 Mbps 0.40*tc(RXC) 0.60*tc(RXC) 100 Mbps 0.40*tc(RXC) 0.60*tc(RXC) 1000 Mbps 0.45*tc(RXC) 0.55*tc(RXC) 10 Mbps 0.40*tc(RXC) 0.60*tc(RXC) 100 Mbps 0.40*tc(RXC) 0.60*tc(RXC) 1000 Mbps 0.45*tc(RXC) 0.55*tc(RXC) 10 Mbps 0.75 100 Mbps 0.75 1000 Mbps 0.75 ns ns ns ns Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-86. Timing Requirements for EMAC RGMII Input Receive for 10/100/1000 Mbps (1) (see Figure 7-69) -720 -850 A-1000/-1000 -1200 NO. MIN (1) UNIT MAX 5 tsu(RXD-RXCH) Setup time, receive selected signals valid before RXC (at DSP) high/low 1.0 ns 6 th(RXCH-RXD) Hold time, receive selected signals valid after RXC (at DSP) high/low 1.0 ns For RGMII, receive selected signals include: RXD[3:0] and RXCTL. 1 4 2 4 3 RXC (at DSP)(B) 5 1st Half-byte 2nd Half-byte RXD[3:0](A) RXD[3:0] RXD[7:4] RXDV RXERR RXCTL(A) 6 A. Data and control information is received using both edges of the clocks. RXD[3:0] carries data bits 3-0 on the rising edge of RXC and data bits 7-4 on the falling edge of RXC. Similarly, RXCTL carries RXDV on rising edge of RXC and RXERR on falling edge B. RXC must be externally delayed relative to the data and control pins. Figure 7-69. EMAC Receive Interface Timing [RGMII Operation](A)(B) Table 7-87. Switching Characteristics Over Recommended Operating Conditions for TXC - RGMII Operation for 10/100/1000 Mbit/s (see Figure 7-70) -720 -850 A-1000/-1000 -1200 NO. MIN 10 Mbps 1 2 3 4 tc(TXC) tw(TXCH) tw(TXCL) tt(TXC) Cycle time, TXC Pulse duration, TXC high Pulse duration, TXC low Transition time, TXC Submit Documentation Feedback UNIT MAX 360 440 100 Mbps 36 44 1000 Mbps 7.2 8.8 10 Mbps 0.40*tc(TXC) 0.60*tc(TXC) 100 Mbps 0.40*tc(TXC) 0.60*tc(TXC) 1000 Mbps 0.45*tc(TXC) 0.55*tc(TXC) 10 Mbps 0.40*tc(TXC) 0.60*tc(TXC) 100 Mbps 0.40*tc(TXC) 0.60*tc(TXC) 1000 Mbps 0.45*tc(TXC) 0.55*tc(TXC) 10 Mbps 0.75 100 Mbps 0.75 1000 Mbps 0.75 C64x+ Peripheral Information and Electrical Specifications ns ns ns ns 209 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-88. Switching Characteristics Over Recommended Operating Conditions for EMAC RGMII Transmit (1)(see Figure 7-70) NO. -720 -850 A-1000/-1000 -1200 PARAMETER MIN (1) 5 tsu(TXD-TXCH) Setup time, transmit selected signals valid before TXC (at DSP) high/low 1.2 6 th(TXCH-TXD) Hold time, transmit selected signals valid after TXC (at DSP) high/low 1.2 UNIT MAX ns For RGMII, transmit selected signals include: TXD[3:0] and TXCTL. TXC at DSP pins 1 4 Internal TXC 2 3 4 TXC (at DSP)(B) 1 5 TXD[3:0](A) 1st Half-byte 2nd Half-byte 6 2 TXCTL(A) TXEN TXERR A. Data and control information is transmitted using both edges of the clocks. TXD[3:0] carries data bits 3-0 on the rising edge of TXC and data bits 7-4 on the falling edge of TXC. Similarly, TX_CTL carries TXEN on rising edge of TXC and TXERR of falling edge. B. TXC is delayed internally before being driven to the TXC pin. Figure 7-70. EMAC Transmit Interface Timing [RGMII Operation](A)(B) 210 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.14.4 Management Data Input/Output (MDIO) The Management Data Input/Output (MDIO) module implements the 802.3 serial management interface to interrogate and controls up to 32 Ethernet PHY(s) connected to the device, using a shared two-wire bus. Application software uses the MDIO module to configure the auto-negotiation parameters of each PHY attached to the EMAC, retrieve the negotiation results, and configure required parameters in the EMAC module for correct operation. The module is designed to allow almost transparent operation of the MDIO interface, with very little maintenance from the core processor. The EMAC control module is the main interface between the device core processor, the MDIO module, and the EMAC module. The relationship between these three components is shown in Figure 7-58. The MDIO uses the same pins for the MII, GMII, and RMII modes. Standalone pins are included for the RGMII mode due to specific voltage requirements. Only one mode can be used at a time. The mode used is selected at device reset based on the MACSEL[1:0] configuration pins (for more detailed information, see Section 3, Device Configuration). Table 7-70 above shows which multiplexed pin are used in the MII, GMII, and RMII modes on the MDIO. For more detailed information on the EMAC/MDIO, see the TMS320C645x DSP EMAC/MDIO Module Reference Guide (literature number SPRU975). 7.14.4.1 MDIO Device-Specific Information Clocking Information The MDIO clock is based on a divide-down of the SYSCLK3 (from the PLL1 controller) and is specified to run up to 2.5 MHz, although typical operation is 1.0 MHz. Since the peripheral clock frequency is variable, the application software or driver controls the divide-down amount. 7.14.4.2 MDIO Peripheral Register Description(s) Table 7-89. MDIO Registers HEX ADDRESS RANGE ACRONYM 02C8 1800 VERSION MDIO Version Register REGISTER NAME 02C8 1804 CONTROL MDIO Control Register 02C8 1808 ALIVE MDIO PHY Alive Status Register 02C8 180C LINK MDIO PHY Link Status Register 02C8 1810 LINKINTRAW 02C8 1814 LINKINTMASKED MDIO Link Status Change Interrupt (Unmasked) Register MDIO Link Status Change Interrupt (Masked) Register 02C8 1818 - 02C8 181C - 02C8 1820 USERINTRAW Reserved 02C8 1824 USERINTMASKED MDIO User Command Complete Interrupt (Masked) Register MDIO User Command Complete Interrupt Mask Set Register MDIO User Command Complete Interrupt (Unmasked) Register 02C8 1828 USERINTMASKSET 02C8 182C USERINTMASKCLEAR 02C8 1830 - 02C8 187C - 02C8 1880 USERACCESS0 MDIO User Access Register 0 02C8 1884 USERPHYSEL0 MDIO User PHY Select Register 0 02C8 1888 USERACCESS1 MDIO User Access Register 1 02C8 188C USERPHYSEL1 MDIO User PHY Select Register 1 02C8 1890 - 02C8 1FFF - Submit Documentation Feedback MDIO User Command Complete Interrupt Mask Clear Register Reserved Reserved C64x+ Peripheral Information and Electrical Specifications 211 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.14.4.3 MDIO Electrical Data/Timing Table 7-90. Timing Requirements for MDIO Input (R)(G)MII (see Figure 7-71) -720 -850 A-1000/-1000 -1200 NO. MIN UNIT MAX 1 tc(MDCLK) Cycle time, MDCLK 400 ns 2a tw(MDCLK) Pulse duration, MDCLK high 180 ns 2b tw(MDCLK) Pulse duration, MDCLK low 180 ns 3 tt(MDCLK) Transition time, MDCLK 4 tsu(MDIO-MDCLKH) Setup time, MDIO data input valid before MDCLK high 10 ns 5 th(MDCLKH-MDIO) Hold time, MDIO data input valid after MDCLK high 10 ns 5 ns 1 MDCLK 3 4 MDIO (input) Figure 7-71. MDIO Input Timing Table 7-91. Switching Characteristics Over Recommended Operating Conditions for MDIO Output (see Figure 7-72) NO. PARAMETER -720 -850 A-1000/-1000 -1200 MIN 7 td(MDCLKL-MDIO) Delay time, MDCLK low to MDIO data output valid UNIT MAX 100 ns 1 MDCLK 7 MDIO (output) Figure 7-72. MDIO Output Timing 212 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.15 Timers The timers can be used to: time events, count events, generate pulses, interrupt the CPU, and send synchronization events to the EDMA3 channel controller. 7.15.1 Timers Device-Specific Information The C6455 device has two general-purpose timers, Timer0 and Timer1, each of which can be configured as a general-purpose timer or a watchdog timer. When configured as a general-purpose timer, each timer can be programmed as a 64-bit timer or as two separate 32-bit timers. Each timer is made up of two 32-bit counters: a high counter and a low counter. The timer pins, TINPLx and TOUTLx are connected to the low counter. The high counter does not have any external device pins. 7.15.2 Timers Peripheral Register Description(s) Table 7-92. Timer 0 Registers HEX ADDRESS RANGE ACRONYM 0294 0000 - REGISTER NAME 0294 0004 EMUMGT_CLKSPD0 0294 0008 - Reserved 0294 000C - Reserved 0294 0010 CNTLO0 Timer 0 Counter Register Low 0294 0014 CNTHI0 Timer 0 Counter Register High COMMENTS Reserved Timer 0 Emulation Management/Clock Speed Register 0294 0018 PRDLO0 Timer 0 Period Register Low 0294 001C PRDHI0 Timer 0 Period Register High 0294 0020 TCR0 0294 0024 TGCR0 Timer 0 Control Register Timer 0 Global Control Register 0294 0028 WDTCR0 0294 002C - Timer 0 Watchdog Timer Control Register Reserved 0294 0030 - Reserved 0294 0034 - 0297 FFFF - Reserved Table 7-93. Timer 1 Registers HEX ADDRESS RANGE ACRONYM REGISTER NAME 0298 0000 - 0298 0004 EMUMGT_CLKSPD1 0298 0008 - Reserved 0298 000C - Reserved 0298 0010 CNTLO1 Timer 1 Counter Register Low 0298 0014 CNTHI1 Timer 1 Counter Register High Reserved Timer 1 Emulation Management/Clock Speed Register 0298 0018 PRDLO1 Timer 1 Period Register Low 0298 001C PRDHI1 Timer 1 Period Register High 0298 0020 TCR1 0298 0024 TGCR1 Timer 1 Control Register Timer 1 Global Control Register 0298 0028 WDTCR1 0298 002C - Reserved 0298 0030 - Reserved 0298 0034 - 0299 FFFF - Reserved Submit Documentation Feedback COMMENTS Timer 1 Watchdog Timer Control Register C64x+ Peripheral Information and Electrical Specifications 213 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.15.3 Timers Electrical Data/Timing Table 7-94. Timing Requirements for Timer Inputs (1) (see Figure 7-73) -720 -850 A-1000/-1000 -1200 NO. MIN (1) UNIT MAX 1 tw(TINPH) Pulse duration, TINPLx high 12P ns 2 tw(TINPL) Pulse duration, TINPLx low 12P ns P = 1/CPU clock frequency in ns. For example, when running parts at 1000 MHz, use P = 1 ns. Table 7-95. Switching Characteristics Over Recommended Operating Conditions for Timer Outputs (1) (see Figure 7-73) NO. -720 -850 A-1000/-1000 -1200 PARAMETER MIN (1) UNIT MAX 3 tw(TOUTH) Pulse duration, TOUTLx high 12P – 3 ns 4 tw(TOUTL) Pulse duration, TOUTLx low 12P – 3 ns P = 1/CPU clock frequency in ns. For example, when running parts at 1000 MHz, use P = 1 ns. 2 1 TINPLx 4 3 TOUTLx Figure 7-73. Timer Timing 214 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.16 Enhanced Viterbi-Decoder Coprocessor (VCP2) 7.16.1 VCP2 Device-Specific Information The C6455 device has a high-performance embedded coprocessor [Viterbi-Decoder Coprocessor (VCP2) that significantly speeds up channel-decoding operations on-chip. The VCP2 operating at CPU clock divided-by-4 can decode over 694 7.95-Kbps adaptive multi-rate (AMR) [K = 9, R = 1/3] voice channels. The VCP2 supports constraint lengths K = 5, 6, 7, 8, and 9, rates R = 3/4, 1/2, 1/3, 1/4, and 1/5, and flexible polynomials, while generating hard decisions or soft decisions. Communications between the VCP2 and the CPU are carried out through the EDMA3 controller. The VCP2 supports: • Unlimited frame sizes • Code rates 3/4, 1/2, 1/3, 1/4, and 1/5 • Constraint lengths 5, 6, 7, 8, and 9 • Programmable encoder polynomials • Programmable reliability and convergence lengths • Hard and soft decoded decisions • Tail and convergent modes • Yamamoto logic • Tail biting logic • Various input and output FIFO lengths For more detailed information on the VCP2, see the TMS320C645x DSP Viterbi-Decoder Coprocessor 2 (VCP2) Reference Guide (literature number SPRU972). 7.16.2 VCP2 Peripheral Register Description(s) Table 7-96. VCP2 Registers EDMA BUS HEX ADDRESS RANGE CONFIGURATION BUS HEX ADDRESS RANGE ACRONYM 5800 0000 - VCPIC0 VCP2 Input Configuration Register 0 5800 0004 - VCPIC1 VCP2 Input Configuration Register 1 5800 0008 - VCPIC2 VCP2 Input Configuration Register 2 5800 000C - VCPIC3 VCP2 Input Configuration Register 3 5800 0010 - VCPIC4 VCP2 Input Configuration Register 4 5800 0014 - VCPIC5 VCP2 Input Configuration Register 5 5800 0018 - 5800 0044 - REGISTER NAME Reserved 5800 0048 - VCPOUT0 VCP2 Output Register 0 5800 004C - VCPOUT1 VCP2 Output Register 1 5800 0050 - 5800 007C 5800 0080 N/A 5800 0084 - 5800 009C Reserved VCPWBM - VCP2 Branch Metrics Write FIFO Register Reserved 5800 00C0 N/A VCPRDECS N/A 02B8 0018 VCPEXE VCP2 Execution Register N/A 02B8 0020 VCPEND VCP2 Endian Mode Register N/A 02B8 0040 VCPSTAT0 VCP2 Status Register 0 N/A 02B8 0044 VCPSTAT1 VCP2 Status Register 1 N/A 02B8 0050 VCPERR - N/A Submit Documentation Feedback 02B8 0060 VCP2 Decisions Read FIFO Register VCP2 Error Register Reserved VCPEMU VCP2 Emulation Control Register C64x+ Peripheral Information and Electrical Specifications 215 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-96. VCP2 Registers (continued) EDMA BUS HEX ADDRESS RANGE CONFIGURATION BUS HEX ADDRESS RANGE ACRONYM N/A 02B8 0064 - 02B9 FFFF - 5800 1000 - BM Branch Metrics 5800 2000 - SM State Metric 5800 3000 - TBHD Traceback Hard Decision 5800 6000 - TBSD Traceback Soft Decision 5800 F000 - IO REGISTER NAME Reserved Decoded Bits 7.17 Enhanced Turbo Decoder Coprocessor (TCP2) 7.17.1 TCP2 Device-Specific Information The C6455 device has a high-performance embedded coprocessor [Turbo-Decoder Coprocessor (TCP2) that significantly speeds up channel-decoding operations on-chip. With the CPU operating at 1 GHz, the TCP2 can decode up to forty 384-Kbps or eight 2-Mbps turbo-encoded channels (assuming 8 iterations). The TCP2 implements the max*log-map algorithm and is designed to support all polynomials and rates required by Third-Generation Partnership Projects (3GPP and 3GPP2), with fully programmable frame length and turbo interleaver. Decoding parameters such as the number of iterations and stopping criteria are also programmable. Communications between the TCP2 and the CPU are carried out through the EDMA3 controller. The TCP2 supports: • Parallel concatenated convolutional turbo decoding using the MAP algorithm • All turbo code rates greater than or equal to 1/5 • 3GPP and CDMA2000 turbo encoder trellis • 3GPP and CDMA2000 block sizes in standalone mode • Larger block sizes in shared processing mode • Both max log MAP and log MAP decoding • Sliding windows algorithm with variable reliability and prolog lengths • The prolog reduction algorithm • Execution of a minimum and maximum number of iterations • The SNR stopping criteria algorithm • The CRC stopping criteria algorithm For more detailed information on the TCP2, see the TMS320C645x DSP Turbo-Decoder Coprocessor 2 (TCP2) Reference Guide (literature number SPRU973). 216 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.17.2 TCP2 Peripheral Register Description(s) Table 7-97. TCP2 Registers EDMA BUS HEX ADDRESS RANGE CONFIGURATION BUS HEX ADDRESS RANGE ACRONYM 5000 0000 - TCPIC0 TCP2 Input Configuration Register 0 5000 0004 - TCPIC1 TCP2 Input Configuration Register 1 5000 0008 - TCPIC2 TCP2 Input Configuration Register 2 5000 000C - TCPIC3 TCP2 Input Configuration Register 3 5000 0010 - TCPIC4 TCP2 Input Configuration Register 4 5000 0014 - TCPIC5 TCP2 Input Configuration Register 5 5000 0018 - TCPIC6 TCP2 Input Configuration Register 6 5000 001C - TCPIC7 TCP2 Input Configuration Register 7 5000 0020 - TCPIC8 TCP2 Input Configuration Register 8 5000 0024 - TCPIC9 TCP2 Input Configuration Register 9 5000 0028 - TCPIC10 TCP2 Input Configuration Register 10 5000 002C - TCPIC11 TCP2 Input Configuration Register 11 5000 0030 - TCPIC12 TCP2 Input Configuration Register 12 5000 0034 - TCPIC13 TCP2 Input Configuration Register 13 5000 0038 - TCPIC14 TCP2 Input Configuration Register 14 5000 003C - TCPIC15 TCP2 Input Configuration Register 15 5000 0040 - TCPOUT0 TCP2 Output Parameters Register 0 5000 0044 - TCPOUT1 TCP2 Output Parameters Register 1 5000 0048 - TCPOUTP2 TCP2 Output Parameters Register 2 5001 0000 N/A X0 TCP2 Data/Sys and Parity Memory 5003 0000 N/A W0 TCP2 Extrinsic Mem 0 5004 0000 N/A W1 TCP2 Extrinsic Mem 1 5005 0000 N/A I0 TCP2 Interleaver Memory 5006 0000 N/A O0 TCP2 Output/Decision Memory 5007 0000 N/A S0 TCP2 Scratch Pad Memory 5008 0000 N/A T0 TCP2 Beta State Memory 5009 0000 N/A C0 TCP2 CRC Memory 500A 0000 N/A B0 TCP2 Beta Prolog Memory TCP2 Alpha Prolog Memory 500B 0000 REGISTER NAME N/A A0 02BA 0000 TCPPID TCP2 Peripheral Identification Register N/A 02BA 004C TCPEXE TCP2 Execute Register N/A 02BA 0050 TCPEND TCP2 Endianness Register N/A 02BA 0060 TCPERR TCP2 Error Register N/A 02BA 0068 TCPSTAT TCP2 Status Register N/A 02BA 0070 TCPEMU TCP2 Emulation Register N/A 02BA 005C - 02BB FFFF - Submit Documentation Feedback Reserved C64x+ Peripheral Information and Electrical Specifications 217 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.18 Peripheral Component Interconnect (PCI) The C6455 DSP supports connections to a PCI backplane via the integrated PCI master/slave bus interface. The PCI port interfaces to DSP internal resources via the data switched central resource. The data switched central resource is described in more detail in Section 4. For more detailed information on the PCI port peripheral module, see the TMS320C645x DSP Peripheral Component Interconnect (PCI) User's Guide (literature number SPRUE60). 7.18.1 PCI Device-Specific Information The PCI peripheral on the C6455 DSP conforms to the PCI Local Bus Specification (version 2.3). The PCI peripheral can act both as a PCI bus master and as a target. It supports PCI bus operation of speeds up to 66 MHz and uses a 32-bit data/address bus. On the C6455 device, the pins of the PCI peripheral are multiplexed with the pins of the HPI, UTOPIA, and GPIO peripherals. PCI functionality for these pins is controlled (enabled/disabled) by the PCI_EN pin (Y29). The maximum speed of the PCI, 33 MHz or 66 MHz, is controlled through the PCI66 pin (U27). For more detailed information on the peripheral control, see Section 3, Device Configuration. The C6455 device provides an initialization mechanism through which the default values for some of the PCI configuration registers can be read from an I2C EEPROM. Table 7-98 shows the registers which can be initialized through the PCI auto-initialization. Also shown is the default value of these registers when PCI auto-initialization is not used. PCI auto-initialization is controlled (enabled/disabled) through the PCI_EEAI pin (P25). For more information on this feature, see the TMS320C645x DSP Peripheral Component Interconnect (PCI) User's Guide (literature number SPRUE60) and the TMS320C645x Bootloader User's Guide (literature number SPRUEC6). Table 7-98. Default Values for PCI Configuration Registers REGISTER DEFAULT VALUE Vendor ID/Device ID Register (PCIVENDEV) 104C B000h Class Code/Revision ID Register (PCICLREV) 0000 0001h Subsystem Vendor ID/Subsystem ID Register (PCISUBID) 0000 0000h Max Latency/Min Grant/Interrupt Pin/Interrupt Line Register (PCILGINT) 0000 0100h The on-chip Bootloader supports a host boot which allows an external PCI device to load application code into the DSP's memory space. The PCI boot is terminated when the Host generates a DSP interrupt. The Host can generate a DSP interrupt through the PCI peripheral by setting the DSPINT bit in the Back-End Application Interrupt Enable Set Register (PCIBINTSET) and the Status Set Register (PCISTATSET). For more information on the boot sequence of the C6455 DSP, see Section 2.4. NOTE After the host boot is complete, the DSP interrupt is registered in bit 0 (channel 0) of the EDMA Event Register (ER). This event must be cleared by software before triggering transfers on DMA channel 0. 218 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.18.2 PCI Peripheral Register Description(s) Table 7-99. PCI Configuration Registers PCI HOST ACCESS HEX ADDRESS OFFSET ACRONYM 0x00 PCIVENDEV PCI HOST ACCESS REGISTER NAME Vendor ID/Device ID 0x04 PCICSR 0x08 PCICLREV Class Code/Revision ID 0x0C PCICLINE BIST/Header Type/Latency Timer/Cacheline Size 0x10 PCIBAR0 Base Address 0 0x14 PCIBAR1 Base Address 1 0x18 PCIBAR2 Base Address 2 0x1C PCIBAR3 Base Address 3 0x20 PCIBAR4 Base Address 4 0x24 PCIBAR5 Base Address 5 0x28 - 0x2B - 0x2C PCISUBID 0x30 - 0x34 PCICPBPTR 0x38 - 0x3B - 0x3C PCILGINT 0x40 - 0x7F - Submit Documentation Feedback Command/Status Reserved Subsystem Vendor ID/Subsystem ID Reserved Capabilities Pointer Reserved Max Latency/Min Grant/Interrupt Pin/Interrupt Line Reserved C64x+ Peripheral Information and Electrical Specifications 219 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-100. PCI Back End Configuration Registers DSP ACCESS HEX ADDRESS RANGE DSP ACCESS REGISTER NAME 02C0 0000 - 02C0 000F - 02C0 0010 PCISTATSET PCI Status Set Register 02C0 0014 PCISTATCLR PCI Status Clear Register 02C0 0018 - 02C0 001F - Reserved Reserved 02C0 0020 PCIHINTSET PCI Host Interrupt Enable Set Register 02C0 0024 PCIHINTCLR PCI Host Interrupt Enable Clear Register 02C0 0028 - 02C0 002F - Reserved 02C0 0030 PCIBINTSET PCI Back End Application Interrupt Enable Set Register 02C0 0034 PCIBINTCLR PCI Back End Application Interrupt Enable Clear Register 02C0 0038 PCIBCLKMGT PCI Back End Application Clock Management Register 02C0 003C - 02C0 00FF 02C0 0100 220 ACRONYM - Reserved PCIVENDEVMIR PCI Vendor ID/Device ID Mirror Register 02C0 0104 PCICSRMIR 02C0 0108 PCICLREVMIR PCI Command/Status Mirror Register PCI Class Code/Revision ID Mirror Register 02C0 010C PCICLINEMIR PCI BIST/Header Type/Latency Timer/Cacheline Size Mirror Register 02C0 0110 PCIBAR0MSK PCI Base Address Mask Register 0 02C0 0114 PCIBAR1MSK PCI Base Address Mask Register 1 02C0 0118 PCIBAR2MSK PCI Base Address Mask Register 2 02C0 011C PCIBAR3MSK PCI Base Address Mask Register 3 02C0 0120 PCIBAR4MSK PCI Base Address Mask Register 4 PCI Base Address Mask Register 5 02C0 0124 PCIBAR5MSK 02C0 0128 - 02C0 012B - 02C0 012C PCISUBIDMIR 02C0 0130 - 02C0 0134 PCICPBPTRMIR 02C0 0138 - 02C0 013B - 02C0 013C PCILGINTMIR Reserved PCI Subsystem Vendor ID/Subsystem ID Mirror Register Reserved PCI Capabilities Pointer Mirror Register Reserved PCI Max Latency/Min Grant/Interrupt Pin/Interrupt Line Mirror Register 02C0 0140 - 02C0 017F - 02C0 0180 PCISLVCNTL Reserved 02C0 0184 - 02C0 01BF - 02C0 01C0 PCIBAR0TRL PCI Slave Base Address 0 Translation Register 02C0 01C4 PCIBAR1TRL PCI Slave Base Address 1 Translation Register 02C0 01C8 PCIBAR2TRL PCI Slave Base Address 2 Translation Register 02C0 01CC PCIBAR3TRL PCI Slave Base Address 3 Translation Register 02C0 01D0 PCIBAR4TRL PCI Slave Base Address 4 Translation Register 02C0 01D4 PCIBAR5TRL PCI Slave Base Address 5 Translation Register 02C0 01D8 - 02C0 01DF - 02C0 01E0 PCIBAR0MIR PCI Base Address Register 0 Mirror Register 02C0 01E4 PCIBAR1MIR PCI Base Address Register 1 Mirror Register 02C0 01E8 PCIBAR2MIR PCI Base Address Register 2 Mirror Register 02C0 01EC PCIBAR3MIR PCI Base Address Register 3 Mirror Register 02C0 01F0 PCIBAR4MIR PCI Base Address Register 4 Mirror Register 02C0 01F4 PCIBAR5MIR PCI Base Address Register 5 Mirror Register 02C0 01F8 - 02C0 02FF - PCI Slave Control Register Reserved Reserved Reserved 02C0 0300 PCIMCFGDAT PCI Master Configuration/IO Access Data Register 02C0 0304 PCIMCFGADR PCI Master Configuration/IO Access Address Register C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-100. PCI Back End Configuration Registers (continued) DSP ACCESS HEX ADDRESS RANGE ACRONYM 02C0 0308 PCIMCFGCMD 02C0 030C - 02C0 030F - 02C0 0310 PCIMSTCFG DSP ACCESS REGISTER NAME PCI Master Configuration/IO Access Command Register Reserved PCI Master Configuration Register Table 7-101. DSP-to_PCI Address Translation Registers DSP ACCESS HEX ADDRESS RANGE ACRONYM 02C0 0314 PCIADDSUB0 PCI Address Substitute 0 Register DSP ACCESS REGISTER NAME 02C0 0318 PCIADDSUB1 PCI Address Substitute 1 Register 02C0 031C PCIADDSUB2 PCI Address Substitute 2 Register 02C0 0320 PCIADDSUB3 PCI Address Substitute 3 Register 02C0 0324 PCIADDSUB4 PCI Address Substitute 4 Register 02C0 0328 PCIADDSUB5 PCI Address Substitute 5 Register 02C0 032C PCIADDSUB6 PCI Address Substitute 6 Register 02C0 0330 PCIADDSUB7 PCI Address Substitute 7 Register 02C0 0334 PCIADDSUB8 PCI Address Substitute 8 Register 02C0 0338 PCIADDSUB9 PCI Address Substitute 9 Register 02C0 033C PCIADDSUB10 PCI Address Substitute 10 Register 02C0 0340 PCIADDSUB11 PCI Address Substitute 11 Register 02C0 0344 PCIADDSUB12 PCI Address Substitute 12 Register 02C0 0348 PCIADDSUB13 PCI Address Substitute 13 Register 02C0 034C PCIADDSUB14 PCI Address Substitute 14 Register 02C0 0350 PCIADDSUB15 PCI Address Substitute 15 Register 02C0 0354 PCIADDSUB16 PCI Address Substitute 16 Register 02C0 0358 PCIADDSUB17 PCI Address Substitute 17 Register 02C0 035C PCIADDSUB18 PCI Address Substitute 18 Register 02C0 0360 PCIADDSUB19 PCI Address Substitute 19 Register 02C0 0364 PCIADDSUB20 PCI Address Substitute 20 Register 02C0 0368 PCIADDSUB21 PCI Address Substitute 21 Register 02C0 036C PCIADDSUB22 PCI Address Substitute 22 Register 02C0 0370 PCIADDSUB23 PCI Address Substitute 23 Register 02C0 0374 PCIADDSUB24 PCI Address Substitute 24 Register 02C0 0378 PCIADDSUB25 PCI Address Substitute 25 Register 02C0 037C PCIADDSUB26 PCI Address Substitute 26 Register 02C0 0380 PCIADDSUB27 PCI Address Substitute 27 Register 02C0 0384 PCIADDSUB28 PCI Address Substitute 28 Register 02C0 0388 PCIADDSUB29 PCI Address Substitute 29 Register 02C0 038C PCIADDSUB30 PCI Address Substitute 30 Register 02C0 0390 PCIADDSUB31 PCI Address Substitute 31 Register Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 221 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-102. PCI Hook Configuration Registers DSP ACCESS HEX ADDRESS RANGE 02C0 0394 02C0 0398 ACRONYM PCIVENDEVPRG DSP ACCESS REGISTER NAME PCI Vendor ID and Device ID Program Register PCICMDSTATPRG PCI Command and Status Program Register 02C0 039C PCICLREVPRG PCI Class Code and Revision ID Program Register 02C0 03A0 PCISUBIDPRG PCI Subsystem Vendor ID and Subsystem ID Program Register 02C0 03A4 PCIMAXLGPRG PCI Max Latency and Min Grant Program Register 02C0 03A8 PCILRSTREG PCI LRESET Register 02C0 03AC PCICFGDONE PCI Configuration Done Register 02C0 03B0 PCIBAR0MPRG PCI Base Address Mask Register 0 Program Register 02C0 03B4 PCIBAR1MPRG PCI Base Address Mask Register 1 Program Register 02C0 03B8 PCIBAR2MPRG PCI Base Address Mask Register 2 Program Register 02C0 03BC PCIBAR3MPRG PCI Base Address Mask Register 3 Program Register 02C0 03C0 PCIBAR4MPRG PCI Base Address Mask Register 4 Program Register 02C0 03C4 PCIBAR5MPRG PCI Base Address Mask Register 5 Program Register 02C0 03C8 PCIBAR0PRG PCI Base Address Register 0 Program Register 02C0 03CC PCIBAR1PRG PCI Base Address Register 1 Program Register 02C0 03D0 PCIBAR2PRG PCI Base Address Register 2 Program Register 02C0 03D4 PCIBAR3PRG PCI Base Address Register 3 Program Register 02C0 03D8 PCIBAR4PRG PCI Base Address Register 4 Program Register 02C0 03DC PCIBAR5PRG PCI Base Address Register 5 Program Register 02C0 03E0 PCIBAR0TRLPRG PCI Base Address Translation Register 0 Program Register 02C0 03E4 PCIBAR1TRLPRG PCI Base Address Translation Register 1 Program Register 02C0 03E8 PCIBAR2TRLPRG PCI Base Address Translation Register 2 Program Register 02C0 03EC PCIBAR3TRLPRG PCI Base Address Translation Register 3 Program Register 02C0 03F0 PCIBAR4TRLPRG PCI Base Address Translation Register 4 Program Register 02C0 03F4 PCIBAR5TRLPRG PCI Base Address Translation Register 5 Program Register 02C0 03F8 PCIBASENPRG 02C0 03FC - 02C0 03FF - PCI Base En Prog Register Reserved Table 7-103. PCI External Memory Space 222 HEX ADDRESS OFFSET ACRONYM 4000 0000 - 407F FFFF - PCI Master Window 0 REGISTER NAME 4080 0000 - 40FF FFFF - PCI Master Window 1 4100 0000 - 417F FFFF - PCI Master Window 2 4180 0000 - 41FF FFFF - PCI Master Window 3 4200 0000 - 427F FFFF - PCI Master Window 4 4280 0000 - 42FF FFFF - PCI Master Window 5 4300 0000 - 437F FFFF - PCI Master Window 6 4380 0000 - 43FF FFFF - PCI Master Window 7 4400 0000 - 447F FFFF - PCI Master Window 8 4480 0000 - 44FF FFFF - PCI Master Window 9 4500 0000 - 457F FFFF - PCI Master Window 10 4580 0000 - 45FF FFFF - PCI Master Window 11 4600 0000 - 467F FFFF - PCI Master Window 12 4680 0000 - 46FF FFFF - PCI Master Window 13 4700 0000 - 477F FFFF - PCI Master Window 14 4780 0000 - 47FF FFFF - PCI Master Window 15 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-103. PCI External Memory Space (continued) HEX ADDRESS OFFSET ACRONYM 4800 0000 - 487F FFFF - PCI Master Window 16 REGISTER NAME 4880 0000 - 48FF FFFF - PCI Master Window 17 4900 0000 - 497F FFFF - PCI Master Window 18 4980 0000 - 49FF FFFF - PCI Master Window 19 4A00 0000 - 4A7F FFFF - PCI Master Window 20 4A80 0000 - 4AFF FFFF - PCI Master Window 21 4B00 0000 - 4B7F FFFF - PCI Master Window 22 4B80 0000 - 4BFF FFFF - PCI Master Window 23 4C00 0000 - 4C7F FFFF - PCI Master Window 24 4C80 0000 - 4CFF FFFF - PCI Master Window 25 4D00 0000 - 4D7F FFFF - PCI Master Window 26 4D80 0000 - 4DFF FFFF - PCI Master Window 27 4E00 0000 - 4E7F FFFF - PCI Master Window 28 4E80 0000 - 4EFF FFFF - PCI Master Window 29 4F00 0000 - 4F7F FFFF - PCI Master Window 30 4F80 0000 - 4FFF FFFF - PCI Master Window 31 Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 223 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.18.3 PCI Electrical Data/Timing Texas Instruments (TI) has performed the simulation and system characterization to ensure that the PCI peripheral meets all AC timing specifications as required by the PCI Local Bus Specification (version 2.3). The AC timing specifications are not reproduced here. For more information on the AC timing specifications, see section 4.2.3, Timing Specification (33 MHz timing), and section 7.6.4, Timing Specification (66 MHz timing), of the PCI Local Bus Specification (version 2.3). Note that the C6455 PCI peripheral only supports 3.3-V signaling. 224 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.19 UTOPIA 7.19.1 UTOPIA Device-Specific Information The Universal Test and Operations PHY Interface for ATM (UTOPIA) peripheral is a 50 MHz, 8-Bit Slave-only interface. The UTOPIA is more simplistic than the Ethernet MAC, in that the UTOPIA is serviced directly by the EDMA3 controller. The UTOPIA peripheral contains two, two-cell FIFOs, one for transmit and one for receive, with which to buffer up data sent/received across the pins. There is a transmit and a receive event to the EDMA3 channel controller to enable servicing. For more detailed information on the UTOPIA peripheral, see the TMS320C645x DSP Universal Test and Operations PHY Interface for ATM 2 (UTOPIA2) User's Guide (literature number SPRUE48). 7.19.2 UTOPIA Peripheral Register Description(s) Table 7-104. UTOPIA Registers HEX ADDRESS RANGE ACRONYM 02B4 0000 UCR REGISTER NAME 02B4 0004 - Reserved 02B4 0008 - Reserved 02B4 000C - Reserved 02B4 0010 - Reserved 02B4 0014 CDR Clock Detect Register UTOPIA Control Register 02B4 0018 EIER Error Interrupt Enable Register 02B4 001C EIPR Error Interrupt Pending Register 02B4 0020 - 02B4 01FF - Reserved 02B4 0200 - 02B7 FFFF - Reserved Table 7-105. UTOPIA Data Queues (Receive and Transmit) Registers HEX ADDRESS RANGE ACRONYM 3C00 0000 - 3C00 03FF URQ UTOPIA Receive (Rx) Data Queue 3C00 0400 - 3C00 07FF UXQ UTOPIA Transmit (Tx) Data Queue Submit Documentation Feedback REGISTER NAME C64x+ Peripheral Information and Electrical Specifications 225 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.19.3 UTOPIA Electrical Data/Timing Table 7-106. Timing Requirements for UXCLK (1) (see Figure 7-74) -720 -850 A-1000/-1000 -1200 NO. MIN (1) UNIT MAX 1 tc(UXCK) Cycle time, UXCLK 20 2 tw(UXCKH) Pulse duration, UXCLK high 0.4tc(UXCK) 0.6tc(UXCK) ns ns 3 tw(UXCKL) Pulse duration, UXCLK low 0.4tc(UXCK) 0.6tc(UXCK) ns 4 tt(UXCK) Transition time, UXCLK 2 ns The reference points for the rise and fall transitions are measured at VIL MAX and VIH MIN. 1 4 2 UXCLK 3 4 Figure 7-74. UXCLK Timing Table 7-107. Timing Requirements for URCLK (1) (see Figure 7-75) -720 -850 A-1000/-1000 -1200 NO. MIN (1) UNIT MAX 1 tc(URCK) Cycle time, URCLK 20 2 tw(URCKH) Pulse duration, URCLK high 0.4tc(URCK) 0.6tc(URCK) ns ns 3 tw(URCKL) Pulse duration, URCLK low 0.4tc(URCK) 0.6tc(URCK) ns 4 tt(URCK) Transition time, URCLK 2 ns The reference points for the rise and fall transitions are measured at VIL MAX and VIH MIN. 1 4 2 URCLK 3 4 Figure 7-75. URCLK Timing 226 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-108. Timing Requirements for UTOPIA Slave Transmit (see Figure 7-76) -720 -850 A-1000/-1000 -1200 NO. MIN UNIT MAX 2 tsu(UXAV-UXCH) Setup time, UXADDR valid before UXCLK high 4 ns 3 th(UXCH-UXAV) Hold time, UXADDR valid after UXCLK high 1 ns 8 tsu(UXENBL-UXCH) Setup time, UXENB low before UXCLK high 4 ns 9 th(UXCH-UXENBL) Hold time, UXENB low after UXCLK high 1 ns Table 7-109. Switching Characteristics Over Recommended Operating Conditions for UTOPIA Slave Transmit Cycles (see Figure 7-76) NO. -720 -850 A-1000/-1000 -1200 PARAMETER MIN UNIT MAX 1 td(UXCH-UXDV) Delay time, UXCLK high to UXDATA valid 3 12 ns 4 td(UXCH-UXCLAV) Delay time, UXCLK high to UXCLAV driven active value 3 12 ns 5 td(UXCH-UXCLAVL) Delay time, UXCLK high to UXCLAV driven inactive low 3 12 ns 6 td(UXCH-UXCLAVHZ) Delay time, UXCLK high to UXCLAV going Hi-Z 9 18.5 ns 7 tw(UXCLAVL-UXCLAVHZ) Pulse duration (low), UXCLAV low to UXCLAV Hi-Z 3 10 td(UXCH-UXSV) Delay time, UXCLK high to UXSOC valid 3 ns 12 ns UXCLK 1 UXDATA[7:0] P45 P46 P47 P48 H1 3 2 UXADDR[4:0] 0 x1F N 0x1F N 0x1F N+1 0x1F 6 7 4 UXCLAV 5 N N 9 8 UXENB 10 UXSOC A. The UTOPIA Slave module has signals that are middle-level signals indicating a high-impedance state (i.e., the UXCLAV and UXSOC signals). Figure 7-76. UTOPIA Slave Transmit Timing(A) Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 227 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-110. Timing Requirements for UTOPIA Slave Receive (see Figure 7-77) -720 -850 A-1000/-1000 -1200 NO. MIN UNIT MAX 1 tsu(URDV-URCH) Setup time, URDATA valid before URCLK high 4 ns 2 th(URCH-URDV) Hold time, URADDR valid after URCLK high 1 ns 3 tsu(URAV-URCH) Setup time, URADDR valid before URCLK high 4 ns 4 th(URCH-URAV) Hold time, URADDR valid after URCLK high 1 ns 9 tsu(URENBL-URCH) Setup time, URENB low before URCLK high 4 ns 10 th(URCH-URENBL) Hold time, URENB low after URCLK high 1 ns 11 tsu(URSH-URCH) Setup time, URSOC high before URCLK high 4 ns 12 th(URCH-URSH) Hold time, URSOC high after URCLK high 1 ns Table 7-111. Switching Characteristics Over Recommended Operating Conditions for UTOPIA Slave Receive Cycles (see Figure 7-77) NO. -720 -850 A-1000/-1000 -1200 PARAMETER MIN UNIT MAX 5 td(URCH-URCLAV) Delay time, URCLK high to URCLAV driven active value 3 12 ns 6 td(URCH-URCLAVL) Delay time, URCLK high to URCLAV driven inactive low 3 12 ns 7 td(URCH-URCLAVHZ) Delay time, URCLK high to URCLAV going Hi-Z 9 18.5 ns 8 tw(URCLAVL-URCLAVHZ) Pulse duration (low), URCLAV low to URCLAV Hi-Z 3 ns URCLK 2 1 URDATA[7:0] P48 H1 H2 H3 0x1F N+2 0x1F 4 3 URADDR[4:0] N 0x1F N+1 7 6 5 URCLAV N N+1 10 8 N+2 9 URENB 11 12 URSOC A. The UTOPIA Slave module has signals that are middle-level signals indicating a high-impedance state (i.e., the URCLAV and URSOC signals). Figure 7-77. UTOPIA Slave Receive Timing(A) 228 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.20 Serial RapidIO (SRIO) Port The SRIO port on the C6455 device is a high-performance, low pin-count interconnect aimed for embedded markets. The use of the Rapid I/O interconnect in a baseband board design can create a homogeneous interconnect environment, providing even more connectivity and control among the components. Rapid I/O is based on the memory and device addressing concepts of processor buses where the transaction processing is managed completely by hardware. This enables the Rapid I/O interconnect to lower the system cost by providing lower latency, reduced overhead of packet data processing, and higher system bandwidth, all of which are key for wireless interfaces. The Rapid I/O interconnect offers very low pin-count interfaces with scalable system bandwidth based on 10-Gigabit per second (Gbps) bidirectional links. The PHY part of the RIO consists of the physical layer and includes the input and output buffers (each serial link consists of a differential pair), the 8-bit/10-bit encoder/decoder, the PLL clock recovery, and the parallel-to-serial/serial-to-parallel converters. The RapidIO interface should be designed to operate at a data rate of 3.125 Gbps per differential pair. This equals 12.5 raw GBaud/s for the 4x RapidIO port, or approximately 9 Gbps data throughput rate. 7.20.1 Serial RapidIO Device-Specific Information The approach to specifying interface timing for the SRIO Port is different than on other interfaces such as EMIF, HPI, and McBSP. For these other interfaces the device timing was specified in terms of data manual specifications and I/O buffer information specification (IBIS) models. For the C6455 SRIO Port, Texas Instruments (TI) provides a printed circuit board (PCB) solution showing two DSPs connected via a 4x SRIO link directly to the user. TI has performed the simulation and system characterization to ensure all SRIO interface timings in this solution are met. The complete SRIO system solution is documented in the Implementing Serial Rapid I/O PCB Layout on a TMS320C6455 Hardware Design application report (literature number SPRAAA8). TI only supports designs that follow the board design guidelines outlined in the SPRAAA8 application report. The Serial RapidIO peripheral is a master peripheral in the C6455 DSP. It conforms to the RapidIO™ Interconnect Specification, Part VI: Physical Layer 1x/4x LP-Serial Specification, Revision 1.2. If the SRIO peripheral is not used, the SRIO reference clock inputs and SRIO link pins can be left unconnected. If the SRIO peripheral is enabled but not all links are used, the pins of the unused links can be left unconnected and no terminations are needed. For more information, see the TMS320C6455 Design Guide and Comparisons to TMS320TC6416T (literature number SPRAA89). 7.20.2 Serial RapidIO Peripheral Register Description(s) Table 7-112. RapidIO Control Registers HEX ADDRESS RANGE ACRONYM 02D0 0000 RIO_PID Peripheral Identification Register 02D0 0004 RIO_PCR Peripheral Control Register 02D0 0008 - 02D0 001C - 02D0 0020 RIO_PER_SET_CNTL 02D0 0024 - 02D0 002C - 02D0 0030 RIO_GBL_EN 02D0 0034 RIO_GBL_EN_STAT 02D0 0038 RIO_BLK0_EN 02D0 003C RIO_BLK0_EN_STAT 02D0 0040 RIO_BLK1_EN 02D0 0044 RIO_BLK1_EN_STAT Submit Documentation Feedback REGISTER NAME Reserved Peripheral Settings Control Register Reserved Peripheral Global Enable Register Peripheral Global Enable Status Block Enable 0 Block Enable Status 0 Block Enable 1 Block Enable Status 1 C64x+ Peripheral Information and Electrical Specifications 229 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-112. RapidIO Control Registers (continued) 230 HEX ADDRESS RANGE ACRONYM 02D0 0048 RIO_BLK2_EN 02D0 004C RIO_BLK2_EN_STAT 02D0 0050 RIO_BLK3_EN 02D0 0054 RIO_BLK3_EN_STAT 02D0 0058 RIO_BLK4_EN 02D0 005C RIO_BLK4_EN_STAT 02D0 0060 RIO_BLK5_EN 02D0 0064 RIO_BLK5_EN_STAT 02D0 0068 RIO_BLK6_EN 02D0 006C RIO_BLK6_EN_STAT 02D0 0070 RIO_BLK7_EN 02D0 0074 RIO_BLK7_EN_STAT REGISTER NAME Block Enable 2 Block Enable Status 2 Block Enable 3 Block Enable Status 3 Block Enable 4 Block Enable Status 4 Block Enable 5 Block Enable Status 5 Block Enable 6 Block Enable Status 6 Block Enable 7 Block Enable Status 7 02D0 0078 RIO_BLK8_EN 02D0 007C RIO_BLK8_EN_STAT Block Enable 8 Block Enable Status 8 02D0 0080 RIO_DEVICEID_REG1 RapidIO DEVICEID1 Register RapidIO DEVICEID2 Register 02D0 0084 RIO_DEVICEID_REG2 02D0 0088 - 02D0 008C - 02D0 0090 RIO_PF_16B_CNTL0 Packet Forwarding Register 0 for 16-bit Device IDs 02D0 0094 RIO_PF_8B_CNTL0 Packet Forwarding Register 0 for 8-bit Device IDs Reserved 02D0 0098 RIO_PF_16B_CNTL1 Packet Forwarding Register 1 for 16-bit Device IDs 02D0 009C RIO_PF_8B_CNTL1 Packet Forwarding Register 1 for 8-bit Device IDs 02D0 00A0 RIO_PF_16B_CNTL2 Packet Forwarding Register 2 for 16-bit Device IDs 02D0 00A4 RIO_PF_8B_CNTL2 Packet Forwarding Register 2 for 8-bit Device IDs 02D0 00A8 RIO_PF_16B_CNTL3 Packet Forwarding Register 3 for 16-bit Device IDs 02D0 00AC RIO_PF_8B_CNTL3 Packet Forwarding Register 3 for 8-bit Device IDs 02D0 00B0 - 02D0 00FC - 02D0 0100 RIO_SERDES_CFGRX0_CNTL Reserved SERDES Receive Channel Configuration Register 0 02D0 0104 RIO_SERDES_CFGRX1_CNTL SERDES Receive Channel Configuration Register 1 02D0 0108 RIO_SERDES_CFGRX2_CNTL SERDES Receive Channel Configuration Register 2 02D0 010C RIO_SERDES_CFGRX3_CNTL SERDES Receive Channel Configuration Register 3 02D0 0110 RIO_SERDES_CFGTX0_CNTL SERDES Transmit Channel Configuration Register 0 02D0 0114 RIO_SERDES_CFGTX1_CNTL SERDES Transmit Channel Configuration Register 1 02D0 0118 RIO_SERDES_CFGTX2_CNTL SERDES Transmit Channel Configuration Register 2 02D0 011C RIO_SERDES_CFGTX3_CNTL SERDES Transmit Channel Configuration Register 3 02D0 0120 RIO_SERDES_CFG0_CNTL SERDES Macro Configuration Register 0 02D0 0124 RIO_SERDES_CFG1_CNTL SERDES Macro Configuration Register 1 02D0 0128 RIO_SERDES_CFG2_CNTL SERDES Macro Configuration Register 2 02D0 012C RIO_SERDES_CFG3_CNTL SERDES Macro Configuration Register 3 02D0 0130 - 02D0 01FC - 02D0 0200 RIO_DOORBELL0_ICSR 02D0 0204 - 02D0 0208 RIO_DOORBELL0_ICCR 02D0 020C - 02D0 0210 RIO_DOORBELL1_ICSR 02D0 0214 - 02D0 0218 RIO_DOORBELL1_ICCR 02D0 021C - C64x+ Peripheral Information and Electrical Specifications Reserved DOORBELL Interrupt Condition Status Register 0 Reserved DOORBELL Interrupt Condition Clear Register 0 Reserved DOORBELL Interrupt Condition Status Register 1 Reserved DOORBELL Interrupt Condition Clear Register 1 Reserved Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-112. RapidIO Control Registers (continued) HEX ADDRESS RANGE ACRONYM 02D0 0220 RIO_DOORBELL2_ICSR 02D0 0224 - 02D0 0228 RIO_DOORBELL2_ICCR 02D0 022C - 02D0 0230 RIO_DOORBELL3_ICSR 02D0 0234 - 02D0 0238 RIO_DOORBELL3_ICCR 02D0 023C - 02D0 0240 RIO_RX_CPPI_ICSR 02D0 0244 - 02D0 0248 RIO_RX_CPPI_ICCR 02D0 024c - 02D0 0250 RIO_TX_CPPI_ICSR 02D0 0254 - 02D0 0258 RIO_TX_CPPI_ICCR 02D0 025C - 02D0 0260 RIO_LSU_ICSR 02D0 0264 - 02D0 0268 RIO_LSU_ICCR 02D0 026C - 02D0 0270 RIO_ERR_RST_EVNT_ICSR 02D0 0274 - 02D0 0278 RIO_ERR_RST_EVNT_ICCR 02D0 027C - REGISTER NAME DOORBELL Interrupt Condition Status Register 2 Reserved DOORBELL Interrupt Condition Clear Register 2 Reserved DOORBELL Interrupt Condition Status Register 3 Reserved DOORBELL Interrupt Condition Clear Register 3 Reserved RX CPPI Interrupt Condition Status Register Reserved RX CPPI Interrupt Condition Clear Register Reserved TX CPPI Interrupt Condition Status Register Reserved TX CPPI Interrupt Condition Clear Register Reserved LSU Interrupt Condition Status Register Reserved LSU Interrupt Condition Clear Register Reserved Error, Reset, and Special Event Interrupt Condition Status Register Reserved Error, Reset, and Special Event Interrupt Condition Clear Register Reserved 02D0 0280 RIO_DOORBELL0_ICRR DOORBELL0 Interrupt Condition Routing Register 02D0 0284 RIO_DOORBELL0_ICRR2 DOORBELL 0 Interrupt Condition Routing Register 2 02D0 0288 - 02D0 028C - Reserved 02D0 0290 RIO_DOORBELL1_ICRR DOORBELL1 Interrupt Condition Routing Register 02D0 0294 RIO_DOORBELL1_ICRR2 DOORBELL 1 Interrupt Condition Routing Register 2 02D0 0298 - 02D0 029C - Reserved 02D0 02A0 RIO_DOORBELL2_ICRR DOORBELL2 Interrupt Condition Routing Register 02D0 02A4 RIO_DOORBELL2_ICRR2 DOORBELL 2 Interrupt Condition Routing Register 2 02D0 02A8 - 02D0 02AC - 02D0 02B0 RIO_DOORBELL3_ICRR DOORBELL3 Interrupt Condition Routing Register DOORBELL 3 Interrupt Condition Routing Register 2 Reserved 02D0 02B4 RIO_DOORBELL3_ICRR2 02D0 02B8 - 02D0 02BC - 02D0 02C0 RIO_RX_CPPI_ICRR Receive CPPI Interrupt Condition Routing Register Receive CPPI Interrupt Condition Routing Register 2 Reserved 02D0 02C4 RIO_RX_CPPI_ICRR2 02D0 02C8 - 02D0 02CC - 02D0 02D0 RIO_TX_CPPI_ICRR Transmit CPPI Interrupt Condition Routing Register Transmit CPPI Interrupt Condition Routing Register 2 Reserved 02D0 02D4 RIO_TX_CPPI_ICRR2 02D0 02D8 - 02D0 02DC - 02D0 02E0 RIO_LSU_ICRR0 LSU Interrupt Condition Routing Register 0 02D0 02E4 RIO_LSU_ICRR1 LSU Interrupt Condition Routing Register 1 02D0 02E8 RIO_LSU_ICRR2 LSU Interrupt Condition Routing Register 2 02D0 02EC RIO_LSU_ICRR3 LSU Interrupt Condition Routing Register 3 Submit Documentation Feedback Reserved C64x+ Peripheral Information and Electrical Specifications 231 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-112. RapidIO Control Registers (continued) 232 HEX ADDRESS RANGE ACRONYM 02D0 02F0 RIO_ERR_RST_EVNT_ICRR Error, Reset, and Special Event Interrupt Condition Routing Register REGISTER NAME 02D0 02F4 RIO_ERR_RST_EVNT_ICRR2 Error, Reset, and Special Event Interrupt Condition Routing Register 2 02D0 02F8 RIO_ERR_RST_EVNT_ICRR3 Error, Reset, and Special Event Interrupt Condition Routing Register 3 02D0 02FC - 02D0 0300 RIO_INTDST0_DECODE Reserved INTDST Interrupt Status Decode Register 0 02D0 0304 RIO_INTDST1_DECODE INTDST Interrupt Status Decode Register 1 02D0 0308 RIO_INTDST2_DECODE INTDST Interrupt Status Decode Register 2 02D0 030C RIO_INTDST3_DECODE INTDST Interrupt Status Decode Register 3 02D0 0310 RIO_INTDST4_DECODE INTDST Interrupt Status Decode Register 4 02D0 0314 RIO_INTDST5_DECODE INTDST Interrupt Status Decode Register 5 02D0 0318 RIO_INTDST6_DECODE INTDST Interrupt Status Decode Register 6 02D0 031C RIO_INTDST7_DECODE INTDST Interrupt Status Decode Register 7 02D0 0320 RIO_INTDST0_RATE_CNTL INTDST Interrupt Rate Control Register 0 02D0 0324 RIO_INTDST1_RATE_CNTL INTDST Interrupt Rate Control Register 1 02D0 0328 RIO_INTDST2_RATE_CNTL INTDST Interrupt Rate Control Register 2 02D0 032C RIO_INTDST3_RATE_CNTL INTDST Interrupt Rate Control Register 3 02D0 0330 RIO_INTDST4_RATE_CNTL INTDST Interrupt Rate Control Register 4 02D0 0334 RIO_INTDST5_RATE_CNTL INTDST Interrupt Rate Control Register 5 02D0 0338 RIO_INTDST6_RATE_CNTL INTDST Interrupt Rate Control Register 6 INTDST Interrupt Rate Control Register 7 02D0 033C RIO_INTDST7_RATE_CNTL 02D0 0340 - 02D0 03FC - 02D0 0400 RIO_LSU1_REG0 LSU1 Control Register 0 02D0 0404 RIO_LSU1_REG1 LSU1 Control Register 1 Reserved 02D0 0408 RIO_LSU1_REG2 LSU1 Control Register 2 02D0 040C RIO_LSU1_REG3 LSU1 Control Register 3 02D0 0410 RIO_LSU1_REG4 LSU1 Control Register 4 02D0 0414 RIO_LSU1_REG5 LSU1 Control Register 5 02D0 0418 RIO_LSU1_REG6 LSU1 Control Register 6 02D0 041C RIO_LSU1_FLOW_MASKS 02D0 0420 RIO_LSU2_REG0 LSU2 Control Register 0 02D0 0424 RIO_LSU2_REG1 LSU2 Control Register 1 02D0 0428 RIO_LSU2_REG2 LSU2 Control Register 2 02D0 042C RIO_LSU2_REG3 LSU2 Control Register 3 02D0 0430 RIO_LSU2_REG4 LSU2 Control Register 4 02D0 0434 RIO_LSU2_REG5 LSU2 Control Register 5 02D0 0438 RIO_LSU2_REG6 LSU2 Control Register 6 02D0 043C RIO_LSU2_FLOW_MASKS1 02D0 0440 RIO_LSU3_REG0 LSU3 Control Register 0 02D0 0444 RIO_LSU3_REG1 LSU3 Control Register 1 LSU1 Congestion Control Flow Mask Register LSU2 Congestion Control Flow Mask Register 02D0 0448 RIO_LSU3_REG2 LSU3 Control Register 2 02D0 044C RIO_LSU3_REG3 LSU3 Control Register 3 02D0 0450 RIO_LSU3_REG4 LSU3 Control Register 4 02D0 0454 RIO_LSU3_REG5 LSU3 Control Register 5 02D0 0458 RIO_LSU3_REG6 LSU3 Control Register 6 02D0 045C RIO_LSU3_FLOW_MASKS2 C64x+ Peripheral Information and Electrical Specifications LSU3 Congestion Control Flow Mask Register Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-112. RapidIO Control Registers (continued) HEX ADDRESS RANGE ACRONYM 02D0 0460 RIO_LSU4_REG0 LSU4 Control Register 0 REGISTER NAME 02D0 0464 RIO_LSU4_REG1 LSU4 Control Register 1 02D0 0468 RIO_LSU4_REG2 LSU4 Control Register 2 02D0 046C RIO_LSU4_REG3 LSU4 Control Register 3 02D0 0470 RIO_LSU4_REG4 LSU4 Control Register 4 02D0 0474 RIO_LSU4_REG5 LSU4 Control Register 5 02D0 0478 RIO_LSU4_REG6 LSU4 Control Register 6 02D0 047C RIO_LSU4_FLOW_MASKS3 02D0 0480 - 02D0 04FC - 02D0 0500 RIO_QUEUE0_TXDMA_HDP Queue Transmit DMA Head Descriptor Pointer Register 0 02D0 0504 RIO_QUEUE1_TXDMA_HDP Queue Transmit DMA Head Descriptor Pointer Register 1 02D0 0508 RIO_QUEUE2_TXDMA_HDP Queue Transmit DMA Head Descriptor Pointer Register 2 02D0 050C RIO_QUEUE3_TXDMA_HDP Queue Transmit DMA Head Descriptor Pointer Register 3 02D0 0510 RIO_QUEUE4_TXDMA_HDP Queue Transmit DMA Head Descriptor Pointer Register 4 02D0 0514 RIO_QUEUE5_TXDMA_HDP Queue Transmit DMA Head Descriptor Pointer Register 5 LSU4 Congestion Control Flow Mask Register Reserved 02D0 0518 RIO_QUEUE6_TXDMA_HDP Queue Transmit DMA Head Descriptor Pointer Register 6 02D0 051C RIO_QUEUE7_TXDMA_HDP Queue Transmit DMA Head Descriptor Pointer Register 7 02D0 0520 RIO_QUEUE8_TXDMA_HDP Queue Transmit DMA Head Descriptor Pointer Register 8 02D0 0524 RIO_QUEUE9_TXDMA_HDP Queue Transmit DMA Head Descriptor Pointer Register 9 02D0 0528 RIO_QUEUE10_TXDMA_HDP Queue Transmit DMA Head Descriptor Pointer Register 10 02D0 052C RIO_QUEUE11_TXDMA_HDP Queue Transmit DMA Head Descriptor Pointer Register 11 02D0 0530 RIO_QUEUE12_TXDMA_HDP Queue Transmit DMA Head Descriptor Pointer Register 12 02D0 0534 RIO_QUEUE13_TXDMA_HDP Queue Transmit DMA Head Descriptor Pointer Register 13 02D0 0538 RIO_QUEUE14_TXDMA_HDP Queue Transmit DMA Head Descriptor Pointer Register 14 02D0 053C RIO_QUEUE15_TXDMA_HDP Queue Transmit DMA Head Descriptor Pointer Register 15 02D0 0540 - 02D0 057C - 02D0 0580 RIO_QUEUE0_TXDMA_CP Reserved Queue Transmit DMA Completion Pointer Register 0 02D0 0584 RIO_QUEUE1_TXDMA_CP Queue Transmit DMA Completion Pointer Register 1 02D0 0588 RIO_QUEUE2_TXDMA_CP Queue Transmit DMA Completion Pointer Register 2 02D0 058C RIO_QUEUE3_TXDMA_CP Queue Transmit DMA Completion Pointer Register 3 02D0 0590 RIO_QUEUE4_TXDMA_CP Queue Transmit DMA Completion Pointer Register 4 02D0 0594 RIO_QUEUE5_TXDMA_CP Queue Transmit DMA Completion Pointer Register 5 02D0 0598 RIO_QUEUE6_TXDMA_CP Queue Transmit DMA Completion Pointer Register 6 02D0 059C RIO_QUEUE7_TXDMA_CP Queue Transmit DMA Completion Pointer Register 7 02D0 05A0 RIO_QUEUE8_TXDMA_CP Queue Transmit DMA Completion Pointer Register 8 02D0 05A4 RIO_QUEUE9_TXDMA_CP Queue Transmit DMA Completion Pointer Register 9 02D0 05A8 RIO_QUEUE10_TXDMA_CP Queue Transmit DMA Completion Pointer Register 10 02D0 05AC RIO_QUEUE11_TXDMA_CP Queue Transmit DMA Completion Pointer Register 11 02D0 05B0 RIO_QUEUE12_TXDMA_CP Queue Transmit DMA Completion Pointer Register 12 02D0 05B4 RIO_QUEUE13_TXDMA_CP Queue Transmit DMA Completion Pointer Register 13 02D0 05B8 RIO_QUEUE14_TXDMA_CP Queue Transmit DMA Completion Pointer Register 14 02D0 05BC RIO_QUEUE15_TXDMA_CP Queue Transmit DMA Completion Pointer Register 15 02D0 05D0 - 02D0 05FC - 02D0 0600 RIO_QUEUE0_RXDMA_HDP Queue Receive DMA Head Descriptor Pointer Register 0 02D0 0604 RIO_QUEUE1_RXDMA_HDP Queue Receive DMA Head Descriptor Pointer Register 1 02D0 0608 RIO_QUEUE2_RXDMA_HDP Queue Receive DMA Head Descriptor Pointer Register 2 02D0 060C RIO_QUEUE3_RXDMA_HDP Queue Receive DMA Head Descriptor Pointer Register 3 Submit Documentation Feedback Reserved C64x+ Peripheral Information and Electrical Specifications 233 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-112. RapidIO Control Registers (continued) 234 HEX ADDRESS RANGE ACRONYM 02D0 0610 RIO_QUEUE4_RXDMA_HDP Queue Receive DMA Head Descriptor Pointer Register 4 REGISTER NAME 02D0 0614 RIO_QUEUE5_RXDMA_HDP Queue Receive DMA Head Descriptor Pointer Register 5 02D0 0618 RIO_QUEUE6_RXDMA_HDP Queue Receive DMA Head Descriptor Pointer Register 6 02D0 061C RIO_QUEUE7_RXDMA_HDP Queue Receive DMA Head Descriptor Pointer Register 7 02D0 0620 RIO_QUEUE8_RXDMA_HDP Queue Receive DMA Head Descriptor Pointer Register 8 02D0 0624 RIO_QUEUE9_RXDMA_HDP Queue Receive DMA Head Descriptor Pointer Register 9 02D0 0628 RIO_QUEUE10_RXDMA_HDP Queue Receive DMA Head Descriptor Pointer Register 10 02D0 062C RIO_QUEUE11_RXDMA_HDP Queue Receive DMA Head Descriptor Pointer Register 11 02D0 0630 RIO_QUEUE12_RXDMA_HDP Queue Receive DMA Head Descriptor Pointer Register 12 02D0 0634 RIO_QUEUE13_RXDMA_HDP Queue Receive DMA Head Descriptor Pointer Register 13 02D0 0638 RIO_QUEUE14_RXDMA_HDP Queue Receive DMA Head Descriptor Pointer Register 14 02D0 063C RIO_QUEUE15_RXDMA_HDP Queue Receive DMA Head Descriptor Pointer Register 15 02D0 0640 - 02D0 067C - 02D0 0680 RIO_QUEUE0_RXDMA_CP Reserved Queue Receive DMA Completion Pointer Register 0 02D0 0684 RIO_QUEUE1_RXDMA_CP Queue Receive DMA Completion Pointer Register 1 02D0 0688 RIO_QUEUE2_RXDMA_CP Queue Receive DMA Completion Pointer Register 2 02D0 068C RIO_QUEUE3_RXDMA_CP Queue Receive DMA Completion Pointer Register 3 02D0 0690 RIO_QUEUE4_RXDMA_CP Queue Receive DMA Completion Pointer Register 4 02D0 0694 RIO_QUEUE5_RXDMA_CP Queue Receive DMA Completion Pointer Register 5 02D0 0698 RIO_QUEUE6_RXDMA_CP Queue Receive DMA Completion Pointer Register 6 02D0 069C RIO_QUEUE7_RXDMA_CP Queue Receive DMA Completion Pointer Register 7 02D0 06A0 RIO_QUEUE8_RXDMA_CP Queue Receive DMA Completion Pointer Register 8 02D0 06A4 RIO_QUEUE9_RXDMA_CP Queue Receive DMA Completion Pointer Register 9 02D0 06A8 RIO_QUEUE10_RXDMA_CP Queue Receive DMA Completion Pointer Register 10 02D0 06AC RIO_QUEUE11_RXDMA_CP Queue Receive DMA Completion Pointer Register 11 02D0 06B0 RIO_QUEUE12_RXDMA_CP Queue Receive DMA Completion Pointer Register 12 02D0 06B4 RIO_QUEUE13_RXDMA_CP Queue Receive DMA Completion Pointer Register 13 02D0 06B8 RIO_QUEUE14_RXDMA_CP Queue Receive DMA Completion Pointer Register 14 02D0 06BC RIO_QUEUE15_RXDMA_CP Queue Receive DMA Completion Pointer Register 15 02D0 06C0 - 02D0 006FC - 02D0 0700 RIO_TX_QUEUE_TEAR_DOWN Reserved Transmit Queue Teardown Register 02D0 0704 RIO_TX_CPPI_FLOW_MASKS0 Transmit CPPI Supported Flow Mask Register 0 02D0 0708 RIO_TX_CPPI_FLOW_MASKS1 Transmit CPPI Supported Flow Mask Register 1 02D0 070C RIO_TX_CPPI_FLOW_MASKS2 Transmit CPPI Supported Flow Mask Register 2 02D0 0710 RIO_TX_CPPI_FLOW_MASKS3 Transmit CPPI Supported Flow Mask Register 3 02D0 0714 RIO_TX_CPPI_FLOW_MASKS4 Transmit CPPI Supported Flow Mask Register 4 02D0 0718 RIO_TX_CPPI_FLOW_MASKS5 Transmit CPPI Supported Flow Mask Register 5 02D0 071C RIO_TX_CPPI_FLOW_MASKS6 Transmit CPPI Supported Flow Mask Register 6 02D0 0720 RIO_TX_CPPI_FLOW_MASKS7 Transmit CPPI Supported Flow Mask Register 7 02D0 0724 - 02D0 073C - 02D0 0740 RIO_RX_QUEUE_TEAR_DOWN 02D0 0744 RIO_RX_CPPI_CNTL Reserved Receive Queue Teardown Register Receive CPPI Control Register 02D0 0748 - 02D0 07DC - 02D0 07E0 RIO_TX_QUEUE_CNTL0 Transmit CPPI Weighted Round Robin Control Register 0 02D0 07E4 RIO_TX_QUEUE_CNTL1 Transmit CPPI Weighted Round Robin Control Register 1 02D0 07E8 RIO_TX_QUEUE_CNTL2 Transmit CPPI Weighted Round Robin Control Register 2 02D0 07EC RIO_TX_QUEUE_CNTL3 Transmit CPPI Weighted Round Robin Control Register 3 C64x+ Peripheral Information and Electrical Specifications Reserved Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-112. RapidIO Control Registers (continued) HEX ADDRESS RANGE ACRONYM 02D0 07F0 - 02D0 07FC - REGISTER NAME 02D0 0800 RIO_RXU_MAP_L0 Mailbox-to-Queue Mapping Register L0 02D0 0804 RIO_RXU_MAP_H0 Mailbox-to-Queue Mapping Register H0 02D0 0808 RIO_RXU_MAP_L1 Mailbox-to-Queue Mapping Register L1 02D0 080C RIO_RXU_MAP_H1 Mailbox-to-Queue Mapping Register H1 02D0 0810 RIO_RXU_MAP_L2 Mailbox-to-Queue Mapping Register L2 02D0 0814 RIO_RXU_MAP_H2 Mailbox-to-Queue Mapping Register H2 02D0 0818 RIO_RXU_MAP_L3 Mailbox-to-Queue Mapping Register L3 02D0 081C RIO_RXU_MAP_H3 Mailbox-to-Queue Mapping Register H3 02D0 0820 RIO_RXU_MAP_L4 Mailbox-to-Queue Mapping Register L4 02D0 0824 RIO_RXU_MAP_H4 Mailbox-to-Queue Mapping Register H4 02D0 0828 RIO_RXU_MAP_L5 Mailbox-to-Queue Mapping Register L5 02D0 082C RIO_RXU_MAP_H5 Mailbox-to-Queue Mapping Register H5 02D0 0830 RIO_RXU_MAP_L6 Mailbox-to-Queue Mapping Register L6 02D0 0834 RIO_RXU_MAP_H6 Mailbox-to-Queue Mapping Register H6 Reserved 02D0 0838 RIO_RXU_MAP_L7 Mailbox-to-Queue Mapping Register L7 02D0 083C RIO_RXU_MAP_H7 Mailbox-to-Queue Mapping Register H7 02D0 0840 RIO_RXU_MAP_L8 Mailbox-to-Queue Mapping Register L8 02D0 0844 RIO_RXU_MAP_H8 Mailbox-to-Queue Mapping Register H8 02D0 0848 RIO_RXU_MAP_L9 Mailbox-to-Queue Mapping Register L9 02D0 084C RIO_RXU_MAP_H9 Mailbox-to-Queue Mapping Register H9 02D0 0850 RIO_RXU_MAP_L10 Mailbox-to-Queue Mapping Register L10 02D0 0854 RIO_RXU_MAP_H10 Mailbox-to-Queue Mapping Register H10 02D0 0858 RIO_RXU_MAP_L11 Mailbox-to-Queue Mapping Register L11 02D0 085C RIO_RXU_MAP_H11 Mailbox-to-Queue Mapping Register H11 02D0 0860 RIO_RXU_MAP_L12 Mailbox-to-Queue Mapping Register L12 02D0 0864 RIO_RXU_MAP_H12 Mailbox-to-Queue Mapping Register H12 02D0 0868 RIO_RXU_MAP_L13 Mailbox-to-Queue Mapping Register L13 02D0 086C RIO_RXU_MAP_H13 Mailbox-to-Queue Mapping Register H13 02D0 0870 RIO_RXU_MAP_L14 Mailbox-to-Queue Mapping Register L14 02D0 0874 RIO_RXU_MAP_H14 Mailbox-to-Queue Mapping Register H14 02D0 0878 RIO_RXU_MAP_L15 Mailbox-to-Queue Mapping Register L15 02D0 087C RIO_RXU_MAP_H15 Mailbox-to-Queue Mapping Register H15 02D0 0880 RIO_RXU_MAP_L16 Mailbox-to-Queue Mapping Register L16 02D0 0884 RIO_RXU_MAP_H16 Mailbox-to-Queue Mapping Register H16 02D0 0888 RIO_RXU_MAP_L17 Mailbox-to-Queue Mapping Register L17 02D0 088C RIO_RXU_MAP_H17 Mailbox-to-Queue Mapping Register H17 02D0 0890 RIO_RXU_MAP_L18 Mailbox-to-Queue Mapping Register L18 02D0 0894 RIO_RXU_MAP_H18 Mailbox-to-Queue Mapping Register H18 02D0 0898 RIO_RXU_MAP_L19 Mailbox-to-Queue Mapping Register L19 02D0 089C RIO_RXU_MAP_H19 Mailbox-to-Queue Mapping Register H19 02D0 08A0 RIO_RXU_MAP_L20 Mailbox-to-Queue Mapping Register L20 02D0 08A4 RIO_RXU_MAP_H20 Mailbox-to-Queue Mapping Register H20 02D0 08A8 RIO_RXU_MAP_L21 Mailbox-to-Queue Mapping Register L21 02D0 08AC RIO_RXU_MAP_H21 Mailbox-to-Queue Mapping Register H21 02D0 08B0 RIO_RXU_MAP_L22 Mailbox-to-Queue Mapping Register L22 02D0 08B4 RIO_RXU_MAP_H22 Mailbox-to-Queue Mapping Register H22 Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 235 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-112. RapidIO Control Registers (continued) HEX ADDRESS RANGE ACRONYM 02D0 08B8 RIO_RXU_MAP_L23 Mailbox-to-Queue Mapping Register L23 REGISTER NAME 02D0 08BC RIO_RXU_MAP_H23 Mailbox-to-Queue Mapping Register H23 02D0 08C0 RIO_RXU_MAP_L24 Mailbox-to-Queue Mapping Register L24 02D0 08C4 RIO_RXU_MAP_H24 Mailbox-to-Queue Mapping Register H24 02D0 08C8 RIO_RXU_MAP_L25 Mailbox-to-Queue Mapping Register L25 02D0 08CC RIO_RXU_MAP_H25 Mailbox-to-Queue Mapping Register H25 02D0 08D0 RIO_RXU_MAP_L26 Mailbox-to-Queue Mapping Register L26 02D0 08D4 RIO_RXU_MAP_H26 Mailbox-to-Queue Mapping Register H26 02D0 08D8 RIO_RXU_MAP_L27 Mailbox-to-Queue Mapping Register L27 02D0 08DC RIO_RXU_MAP_H27 Mailbox-to-Queue Mapping Register H27 02D0 08E0 RIO_RXU_MAP_L28 Mailbox-to-Queue Mapping Register L28 02D0 08E4 RIO_RXU_MAP_H28 Mailbox-to-Queue Mapping Register H28 02D0 08E8 RIO_RXU_MAP_L29 Mailbox-to-Queue Mapping Register L29 02D0 08EC RIO_RXU_MAP_H29 Mailbox-to-Queue Mapping Register H29 02D0 08F0 RIO_RXU_MAP_L30 Mailbox-to-Queue Mapping Register L30 02D0 08F4 RIO_RXU_MAP_H30 Mailbox-to-Queue Mapping Register H30 02D0 08F8 RIO_RXU_MAP_L31 Mailbox-to-Queue Mapping Register L31 02D0 08FC RIO_RXU_MAP_H31 Mailbox-to-Queue Mapping Register H31 02D0 0900 RIO_FLOW_CNTL0 Flow Control Table Entry Register 0 02D0 0904 RIO_FLOW_CNTL1 Flow Control Table Entry Register 1 02D0 0908 RIO_FLOW_CNTL2 Flow Control Table Entry Register 2 02D0 090C RIO_FLOW_CNTL3 Flow Control Table Entry Register 3 02D0 0910 RIO_FLOW_CNTL4 Flow Control Table Entry Register 4 02D0 0914 RIO_FLOW_CNTL5 Flow Control Table Entry Register 5 02D0 0918 RIO_FLOW_CNTL6 Flow Control Table Entry Register 6 02D0 091C RIO_FLOW_CNTL7 Flow Control Table Entry Register 7 02D0 0920 RIO_FLOW_CNTL8 Flow Control Table Entry Register 8 02D0 0924 RIO_FLOW_CNTL9 Flow Control Table Entry Register 9 02D0 0928 RIO_FLOW_CNTL10 Flow Control Table Entry Register 10 02D0 092C RIO_FLOW_CNTL11 Flow Control Table Entry Register 11 02D0 0930 RIO_FLOW_CNTL12 Flow Control Table Entry Register 12 02D0 0934 RIO_FLOW_CNTL13 Flow Control Table Entry Register 13 02D0 0938 RIO_FLOW_CNTL14 Flow Control Table Entry Register 14 02D0 093C RIO_FLOW_CNTL15 Flow Control Table Entry Register 15 02D0 0940 - 02D0 09FC - 02D0 1000 RIO_DEV_ID 02D0 1004 RIO_DEV_INFO Device Information CAR 02D0 1008 RIO_ASBLY_ID Assembly Identity CAR 02D0 100C RIO_ASBLY_INFO 02D0 1010 RIO_PE_FEAT 02D0 1014 - Reserved RapidIO Peripheral-Specific Registers 236 Device Identity CAR Assembly Information CAR Processing Element Features CAR Reserved 02D0 1018 RIO_SRC_OP Source Operations CAR 02D0 101C RIO_DEST_OP Destination Operations CAR 02D0 1020 - 02D0 1048 - 02D0 104C RIO_PE_LL_CTL 02D0 1050 - 02D0 1054 - C64x+ Peripheral Information and Electrical Specifications Reserved Processing Element Logical Layer Control CSR Reserved Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-112. RapidIO Control Registers (continued) HEX ADDRESS RANGE ACRONYM 02D0 1058 RIO_LCL_CFG_HBAR Local Configuration Space Base Address 0 CSR REGISTER NAME 02D0 105C RIO_LCL_CFG_BAR Local Configuration Space Base Address 1 CSR 02D0 1060 RIO_BASE_ID 02D0 1064 - 02D0 1068 RIO_HOST_BASE_ID_LOCK 02D0 106C RIO_COMP_TAG 02D0 1070 - 02D0 10FC - Base Device ID CSR Reserved Host Base Device ID Lock CSR Component Tag CSR Reserved RapidIO Extended Features - LP Serial Registers 02D0 1100 RIO_SP_MB_HEAD 1x/4x LP Serial Port Maintenance Block Header 02D0 1104 - 02D0 1118 02D0 1120 RIO_SP_LT_CTL Port Link Time-Out Control CSR 02D0 1124 RIO_SP_RT_CTL Port Response Time-Out Control CSR 02D0 1128 - 02D0 1138 - 02D0 113C RIO_SP_GEN_CTL Reserved Port General Control CSR 02D0 1140 RIO_SP0_LM_REQ Port 0 Link Maintenance Request CSR 02D0 1144 RIO_SP0_LM_RERIO_SP Port 0 Link Maintenance Response CSR 02D0 1148 RIO_SP0_ACKID_STAT Port 0 Local Acknowledge ID Status CSR 02D0 114C - 02D0 1154 - 02D0 1158 RIO_SP0_ERR_STAT Reserved Port 0 Error and Status CSR 02D0 115C RIO_SP0_CTL 02D0 1160 RIO_SP1_LM_REQ 02D0 1164 RIO_SP1_LM_RERIO_SP Port 1 Link Maintenance Response CSR Port 1 Local Acknowledge ID Status CSR 02D0 1168 RIO_SP1_ACKID_STAT 02D0 116C - 02D0 1174 - 02D0 1178 RIO_SP1_ERR_STAT Port 0 Control CSR Port 1 Link Maintenance Request CSR Reserved Port 1 Error and Status CSR 02D0 117C RIO_SP1_CTL 02D0 1180 RIO_SP2_LM_REQ 02D0 1184 RIO_SP2_LM_RERIO_SP Port 2 Link Maintenance Response CSR 02D0 1188 RIO_SP2_ACKID_STAT Port 2 Local Acknowledge ID Status CSR 02D0 118C - 02D0 1194 - 02D0 1198 RIO_SP2_ERR_STAT 02D0 119C RIO_SP2_CTL Port 1 Control CSR Port 2 Link Maintenance Request CSR Reserved Port 2 Error and Status CSR Port 2 Control CSR 02D0 11A0 RIO_SP3_LM_REQ 02D0 11A4 RIO_SP3_LM_RERIO_SP Port 3 Link Maintenance Response CSR 02D0 11A8 RIO_SP3_ACKID_STAT Port 3 Local Acknowledge ID Status CSR 02D0 11AC - 02D0 11B4 - 02D0 11B8 RIO_SP3_ERR_STAT 02D0 11BC RIO_SP3_CTL 02D0 11C0 - 02D0 1FFC - Port 3 Link Maintenance Request CSR Reserved Port 3 Error and Status CSR Port 3 Control CSR Reserved RapidIO Extended Feature - Error Management Registers 02D0 2000 RIO_ERR_RPT_BH 02D0 2004 - Error Reporting Block Header Reserved 02D0 2008 RIO_ERR_DET Logical/Transport Layer Error Detect CSR 02D0 200C RIO_ERR_EN Logical/Transport Layer Error Enable CSR 02D0 2010 RIO_H_ADDR_CAPT 02D0 2014 RIO_ADDR_CAPT 02D0 2018 RIO_ID_CAPT Submit Documentation Feedback Logical/Transport Layer High Address Capture CSR Logical/Transport Layer Address Capture CSR Logical/Transport Layer Device ID Capture CSR C64x+ Peripheral Information and Electrical Specifications 237 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-112. RapidIO Control Registers (continued) HEX ADDRESS RANGE ACRONYM 02D0 201C RIO_CTRL_CAPT 02D0 2020 - 02D0 2024 - Reserved 02D0 2028 RIO_PW_TGT_ID 02D0 202C - 02D0 203C - 02D0 2040 RIO_SP0_ERR_DET Port 0 Error Detect CSR RIO_SP0_RATE_EN Port 0 Error Enable CSR 02D0 2044 02D0 2048 Port-Write Target Device ID CSR Reserved RIO_SP0_ERR_ATTR_CAPT_DBG0 Port 0 Attributes Error Capture CSR 0 02D0 204C RIO_SP0_ERR_CAPT_DBG1 Port 0 Packet/Control Symbol Error Capture CSR 1 02D0 2050 RIO_SP0_ERR_CAPT_DBG2 Port 0 Packet/Control Symbol Error Capture CSR 2 02D0 2054 RIO_SP0_ERR_CAPT_DBG3 Port 0 Packet/Control Symbol Error Capture CSR 3 02D0 2058 RIO_SP0_ERR_CAPT_DBG4 Port 0 Packet/Control Symbol Error Capture CSR 4 02D0 205C - 02D0 2064 - Reserved 02D0 2068 RIO_SP0_ERR_RATE 02D0 206C RIO_SP0_ERR_THRESH 02D0 2070 - 02D0 207C - 02D0 2080 RIO_SP1_ERR_DET Port 1 Error Detect CSR 02D0 2084 RIO_SP1_RATE_EN Port 1 Error Enable CSR 02D0 2088 Port 0 Error Rate CSR 0 Port 0 Error Rate Threshold CSR Reserved RIO_SP1_ERR_ATTR_CAPT_DBG0 Port 1 Attributes Error Capture CSR 0 02D0 208C RIO_SP1_ERR_CAPT_DBG1 Port 1 Packet/Control Symbol Error Capture CSR 1 02D0 2090 RIO_SP1_ERR_CAPT_DBG2 Port 1 Packet/Control Symbol Error Capture CSR 2 02D0 2094 RIO_SP1_ERR_CAPT_DBG3 Port 1 Packet/Control Symbol Error Capture CSR 3 02D0 2098 RIO_SP1_ERR_CAPT_DBG4 Port 1 Packet/Control Symbol Error Capture CSR 4 02D0 209C - 02D0 20A4 - 02D0 20A8 RIO_SP1_ERR_RATE 02D0 20AC RIO_SP1_ERR_THRESH Reserved Port 1 Error Rate CSR Port 1 Error Rate Threshold CSR 02D0 20B0 - 02D0 20BC - 02D0 20C0 RIO_SP2_ERR_DET Port 2 Error Detect CSR 02D0 20C4 RIO_SP2_RATE_EN Port 2 Error Enable CSR 02D0 20C8 Reserved RIO_SP2_ERR_ATTR_CAPT_DBG0 Port 2 Attributes Error Capture CSR 0 02D0 20CC RIO_SP2_ERR_CAPT_DBG1 Port 2 Packet/Control Symbol Error Capture CSR 1 02D0 20D0 RIO_SP2_ERR_CAPT_DBG2 Port 2 Packet/Control Symbol Error Capture CSR 2 02D0 20D4 RIO_SP2_ERR_CAPT_DBG3 Port 2 Packet/Control Symbol Error Capture CSR 3 Port 2 Packet/Control Symbol Error Capture CSR 4 02D0 20D8 RIO_SP2_ERR_CAPT_DBG4 02D0 20DC - 02D0 20E4 - 02D0 20E8 RIO_SP2_ERR_RATE Reserved Port 2 Error Rate CSR 02D0 20EC RIO_SP2_ERR_THRESH 02D0 20F0 - 02D0 20FC - 02D0 2100 RIO_SP3_ERR_DET Port 3 Error Detect CSR 02D0 2104 RIO_SP3_RATE_EN Port 3 Error Enable CSR 02D0 2108 238 REGISTER NAME Logical/Transport Layer Control Capture CSR Port 2 Error Rate Threshold CSR Reserved RIO_SP3_ERR_ATTR_CAPT_DBG0 Port 3 Attributes Error Capture CSR 0 02D0 210C RIO_SP3_ERR_CAPT_DBG1 Port 3 Packet/Control Symbol Error Capture CSR 1 02D0 2110 RIO_SP3_ERR_CAPT_DBG2 Port 3 Packet/Control Symbol Error Capture CSR 2 02D0 2114 RIO_SP3_ERR_CAPT_DBG3 Port 3 Packet/Control Symbol Error Capture CSR 3 02D0 2118 RIO_SP3_ERR_CAPT_DBG4 Port 3 Packet/Control Symbol Error Capture CSR 4 02D0 211C - 02D0 2124 - 02D0 2128 RIO_SP3_ERR_RATE 02D0 212C RIO_SP3_ERR_THRESH C64x+ Peripheral Information and Electrical Specifications Reserved Port 3 Error Rate CSR Port 3 Error Rate Threshold CSR Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Table 7-112. RapidIO Control Registers (continued) HEX ADDRESS RANGE ACRONYM 02D0 2130 - 02D1 0FFC - REGISTER NAME Reserved Implementation Registers 02D1 1000 - 02D1 1FFC - 02D1 2000 RIO_SP_IP_DISCOVERY_TIMER Reserved 02D1 2004 RIO_SP_IP_MODE Port IP Mode CSR Port IP Prescaler Register Port IP Discovery Timer in 4x mode 02D1 2008 RIO_IP_PRESCAL 02D1 200C - 02D1 2010 RIO_SP_IP_PW_IN_CAPT0 Port-Write-In Capture CSR Register 0 02D1 2014 RIO_SP_IP_PW_IN_CAPT1 Port-Write-In Capture CSR Register 1 Reserved 02D1 2018 RIO_SP_IP_PW_IN_CAPT2 Port-Write-In Capture CSR Register 2 02D1 201C RIO_SP_IP_PW_IN_CAPT3 Port-Write-In Capture CSR Register 3 02D1 2020 - 02D1 3FFC - Reserved 02D1 4000 RIO_SP0_RST_OPT 02D1 4004 RIO_SP0_CTL_INDEP Port 0 Reset Option CSR 02D1 4008 RIO_SP0_SILENCE_TIMER Port 0 Silence Timer Register 02D1 400C RIO_SP0_MULT_EVNT_CS Port 0 Multicast-Event Control Symbol Request Register 02D1 4010 - 02D1 4014 RIO_SP0_CS_TX 02D1 4018 - 02D1 40FC - Port 0 Control Independent Register Reserved Port 0 Control Symbol Transmit Register Reserved 02D1 4100 RIO_SP1_RST_OPT 02D1 4104 RIO_SP1_CTL_INDEP Port 1 Reset Option CSR 02D1 4108 RIO_SP1_SILENCE_TIMER Port 1 Silence Timer Register 02D1 410C RIO_SP1_MULT_EVNT_CS Port 1 Multicast-Event Control Symbol Request Register 02D1 4110 - 02D1 4114 RIO_SP1_CS_TX Port 1 Control Independent Register Reserved Port 1 Control Symbol Transmit Register 02D1 4118 - 02D1 41FC - 02D1 4200 RIO_SP2_RST_OPT Reserved 02D1 4204 RIO_SP2_CTL_INDEP 02D1 4208 RIO_SP2_SILENCE_TIMER Port 2 Silence Timer Register 02D1 420C RIO_SP2_MULT_EVNT_CS Port 2 Multicast-Event Control Symbol Request Register 02D1 4214 RIO_SP2_CS_TX 02D1 4218 - 02D1 42FC - Port 2 Reset Option CSR Port 2 Control Independent Register Port 2 Control Symbol Transmit Register Reserved 02D1 4300 RIO_SP3_RST_OPT 02D1 4304 RIO_SP3_CTL_INDEP Port 3 Reset Option CSR 02D1 4308 RIO_SP3_SILENCE_TIMER Port 3 Silence Timer Register 02D1 430C RIO_SP3_MULT_EVNT_CS Port 3 Multicast-Event Control Symbol Request Register 02D1 4310 - 02D1 4314 RIO_SP3_CS_TX 02D1 4318 - 02D2 0FFF - Reserved 02D2 1000 - 02DF FFFF - Reserved Port 3 Control Independent Register Reserved Port 3 Control Symbol Transmit Register 7.20.3 Serial RapidIO Electrical Data/Timing The Implementing Serial Rapid I/O PCB Layout on a TMS320C6455 Hardware Design application report (literature number SPRAAA8) specifies a complete printed circuit board (PCB) solution for the C6455 as well as a list of compatible SRIO devices showing two DSPs connected via a 4x SRIO link. TI has performed the simulation and system characterization to ensure all SRIO interface timings in this solution are met; therefore, no electrical data/timing information is supplied here for this interface. Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 239 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 TI only supports designs that follow the board design guidelines outlined in the SPRAAA8 application report. 240 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.21 General-Purpose Input/Output (GPIO) 7.21.1 GPIO Device-Specific Information On the C6455 the GPIO peripheral pins GP[15:8] and GP[3:0] are muxed with the UTOPIA, PCI, and McBSP1 peripheral pins and the SYSCLK4 signal. For more detailed information on device/peripheral configuration and the C6455 device pin muxing, see Section 3, Device Configuration. 7.21.2 GPIO Peripheral Register Description(s) Table 7-113. GPIO Registers HEX ADDRESS RANGE ACRONYM 02B0 0008 BINTEN REGISTER NAME GPIO interrupt per bank enable register 02B0 000C - 02B0 0010 DIR Reserved 02B0 0014 OUT_DATA GPIO Output Data register GPIO Direction Register 02B0 0018 SET_DATA GPIO Set Data register 02B0 001C CLR_DATA GPIO Clear Data Register 02B0 0020 IN_DATA GPIO Input Data Register 02B0 0024 SET_RIS_TRIG GPIO Set Rising Edge Interrupt Register 02B0 0028 CLR_RIS_TRIG GPIO Clear Rising Edge Interrupt Register 02B0 002C SET_FAL_TRIG GPIO Set Falling Edge Interrupt Register 02B0 0030 CLR_FAL_TRIG GPIO Clear Falling Edge Interrupt Register 02B0 008C - Reserved 02B0 0090 - 02B0 00FF - Reserved 02B0 0100 - 02B0 3FFF - Reserved Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 241 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.21.3 GPIO Electrical Data/Timing Table 7-114. Timing Requirements for GPIO Inputs (1) (2) (see Figure 7-78) -720 -850 A-1000/-1000 -1200 NO. MIN (1) (2) UNIT MAX 1 tw(GPIH) Pulse duration, GPIx high 12P ns 2 tw(GPIL) Pulse duration, GPIx low 12P ns P = 1/CPU clock frequency in ns. For example, when running parts at 1000 MHz, use P = 1 ns. The pulse width given is sufficient to generate a CPU interrupt or an EDMA event. However, if a user wants to have the DSP recognize the GPIx changes through software polling of the GPIO register, the GPIx duration must be extended to at least 24P to allow the DSP enough time to access the GPIO register through the CFGBUS. Table 7-115. Switching Characteristics Over Recommended Operating Conditions for GPIO Outputs (1) (see Figure 7-78) NO. -720 -850 A-1000/-1000 -1200 PARAMETER MIN (1) (2) UNIT MAX 3 tw(GPOH) Pulse duration, GPOx high 36P – 8 (2) ns 4 tw(GPOL) Pulse duration, GPOx low 36P – 8 (2) ns P = 1/CPU clock frequency in ns. For example, when running parts at 1000 MHz, use P = 1 ns. This parameter value should not be used as a maximum performance specification. Actual performance of back-to-back accesses of the GPIO is dependent upon internal bus activity. 2 1 GPIx 4 3 GPOx Figure 7-78. GPIO Port Timing 242 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.22 Emulation Features and Capability 7.22.1 Advanced Event Triggering (AET) The C6455 device supports Advanced Event Triggering (AET). This capability can be used to debug complex problems as well as understand performance characteristics of user applications. AET provides the following capabilities: • Hardware Program Breakpoints: specify addresses or address ranges that can generate events such as halting the processor or triggering the trace capture. • Data Watchpoints: specify data variable addresses, address ranges, or data values that can generate events such as halting the processor or triggering the trace capture. • Counters: count the occurrence of an event or cycles for performance monitoring. • State Sequencing: allows combinations of hardware program breakpoints and data watchpoints to precisely generate events for complex sequences. For more information on AET, see the following documents: Using Advanced Event Triggering to Find and Fix Intermittent Real-Time Bugs application report (literature number SPRA753) Using Advanced Event Triggering to Debug Real-Time Problems in High Speed Embedded Microprocessor Systems application report (literature number SPRA387) 7.22.2 Trace The C6455 device supports Trace. Trace is a debug technology that provides a detailed, historical account of application code execution, timing, and data accesses. Trace collects, compresses, and exports debug information for analysis. Trace works in real-time and does not impact the execution of the system. For more information on board design guidelines for Trace Advanced Emulation, see the 60-Pin Emulation Header Technical Reference (literature number SPRU655). Submit Documentation Feedback C64x+ Peripheral Information and Electrical Specifications 243 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 7.22.3 IEEE 1149.1 JTAG 7.22.3.1 JTAG Device-Specific Information 7.22.3.1.1 IEEE 1149.1 JTAG Compatibility Statement For maximum reliability, the C6455 DSP includes an internal pulldown (IPD) on the TRST pin to ensure that TRST will always be asserted upon power up and the DSP's internal emulation logic will always be properly initialized when this pin is not routed out. JTAG controllers from Texas Instruments actively drive TRST high. However, some third-party JTAG controllers may not drive TRST high but expect the use of an external pullup resistor on TRST. When using this type of JTAG controller, assert TRST to initialize the DSP after powerup and externally drive TRST high before attempting any emulation or boundary scan operations. 7.22.4 JTAG Peripheral Register Description(s) 7.22.5 JTAG Electrical Data/Timing Table 7-116. Timing Requirements for JTAG Test Port (see Figure 7-79) -720 -850 A-1000/-1000 -1200 NO. MIN UNIT MAX 1 tc(TCK) Cycle time, TCK 35 ns 3 tsu(TDIV-TCKH) Setup time, TDI/TMS/TRST valid before TCK high 10 ns 4 th(TCKH-TDIV) Hold time, TDI/TMS/TRST valid after TCK high 9 ns Table 7-117. Switching Characteristics Over Recommended Operating Conditions for JTAG Test Port (see Figure 7-79) NO. 2 -720 -850 A-1000/-1000 -1200 PARAMETER td(TCKL-TDOV) Delay time, TCK low to TDO valid UNIT MIN MAX -3 18 ns 1 TCK 2 2 TDO 4 3 TDI/TMS/TRST Figure 7-79. JTAG Test-Port Timing 244 C64x+ Peripheral Information and Electrical Specifications Submit Documentation Feedback TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 Revision History NOTE: Page numbers for previous revisions may differ from page numbers in the current version. This data sheet revision history highlights the technical changes made to the SPRS276G device-specific data sheet to make it an SPRS276H revision. Scope: Applicable updates to the C64x device family, specifically relating to the TMS320C6455 device, have been incorporated. C6455 Revision History SEE Global Section 1 ADDITIONS/MODIFICATIONS/DELETIONS Added 1.2-GHz device information Features: Added 0.83-ns instruction cycle time Added 1.2-GHz clock rate Section 1.3 Functional Block Diagram: Updated Footnote C in Figure 1-2, Functional Block Diagram Section 2.1 Device Characteristics: Table 2-1, Characteristics of the C6455 Processor: Added 1200 (1.2 GHz) Frequency Added 0.83 ns (C6455-1200) [1.2-GHz CPU] Cycle Time Added -1200 device to 1.25-V Core Voltage Section 2.8.2 Device Support: Added Device Speed Range 2 = 1.2 GHz to Figure 2-13, TMS320C64x+™ DSP Device Nomenclature (including the TMS320C6455 DSP) Section 6.2 Recommended Operating Conditions: Added -1200 device to CVDD, Supply voltage, Core; DVDDRM, Supply voltage, Core; and DVDD12, AVDDA, AVDDT, Supply voltage, I/O Section 6.3 Electrical Characteristics Over Recommended Ranges of Supply Voltage and Operating Case Temperature: Added a row to PCDD Core supply power for CPU frequency = 1200 MHz with a TYP value of 1.76 W and updated TYP values for CPU frequency = 1000, 850, and 720 MHz Added a row to PDDD I/O supply power for CPU frequency = 1200 MHz with a TYP value of 0.54 W and updated TYP values for CPU frequency = 1000, 850, and 720 MHz Section 7 Section 7.7.1 Section 7.8 C64x+ Peripheral Information and Electrical Specifications: Added -1200 to all timing and switching characteristics tables PLL1 Controller Device-Specific Information: Changed third paragraph to ... PLLOUT is set to 1200 MHz ... Changed PLLOUT MAX value to 1200 MHz in Table 7-16, PLL1 Clock Frequency Ranges PLL2 and PLL2 Controller: Changed C162 value to 0.1 μF in Figure 7-23, PLL2 Block Diagram Submit Documentation Feedback Revision History 245 TMS320C6455 Fixed-Point Digital Signal Processor SPRS276H – MAY 2005 – REVISED OCTOBER 2007 8 Mechanical Data 8.1 Thermal Data Table 8-1 shows the thermal resistance characteristics for the PBGA - ZTZ/GTZ mechanical package. Table 8-1. Thermal Resistance Characteristics (S-PBGA Package) [ZTZ/GTZ] NO. AIR FLOW (m/s) (1) N/A 1 RΘJC Junction-to-case 1.45 2 RΘJB Junction-to-board 8.34 N/A 16.1 0.00 13.0 1.0 11.9 2.0 3 4 5 RΘJA Junction-to-free air 6 7 8 (1) °C/W PsiJT PsiJB Junction-to-package top Junction-to-board 10.7 3.0 0.37 0.00 0.89 1.0 1.01 1.5 1.17 3.00 7.6 0.00 6.7 1.0 6.4 1.5 5.8 3.00 m/s = meters per second 8.2 Packaging Information The following packaging information reflects the most current released data available for the designated device(s). This data is subject to change without notice and without revision of this document. 246 Mechanical Data Submit Documentation Feedback PACKAGE OPTION ADDENDUM www.ti.com 3-Oct-2007 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Drawing Pins Package Eco Plan (2) Qty Lead/Ball Finish MSL Peak Temp (3) TMS320C6455BGTZ ACTIVE FCBGA GTZ 697 44 TBD SNPB Level-4-220C-72 HR TMS320C6455BGTZ2 ACTIVE FCBGA GTZ 697 44 TBD SNPB Level-4-220C-72 HR TMS320C6455BGTZ7 ACTIVE FCBGA GTZ 697 44 TBD SNPB Level-4-220C-72 HR TMS320C6455BGTZ8 ACTIVE FCBGA GTZ 697 44 TBD SNPB Level-4-220C-72 HR TMS320C6455BGTZA ACTIVE FCBGA GTZ 697 44 TBD SNPB Level-4-220C-72 HR TMS320C6455BZTZ ACTIVE FCBGA ZTZ 697 44 Pb-Free (RoHS Exempt) SNAGCU Level-4-260C-72HR TMS320C6455BZTZ2 ACTIVE FCBGA ZTZ 697 44 Pb-Free (RoHS Exempt) SNAGCU Level-4-260C-72HR TMS320C6455BZTZ7 ACTIVE FCBGA ZTZ 697 44 Pb-Free (RoHS Exempt) SNAGCU Level-4-260C-72HR TMS320C6455BZTZ8 ACTIVE FCBGA ZTZ 697 44 Pb-Free (RoHS Exempt) SNAGCU Level-4-260C-72HR TMS320C6455BZTZA ACTIVE FCBGA ZTZ 697 44 Pb-Free (RoHS Exempt) SNAGCU Level-4-260C-72HR (1) The marketing status values are defined as follows: ACTIVE: Product device recommended for new designs. LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect. NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design. PREVIEW: Device has been announced but is not in production. Samples may or may not be available. OBSOLETE: TI has discontinued the production of the device. (2) Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability information and additional product content details. TBD: The Pb-Free/Green conversion plan has not been defined. Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes. Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above. Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material) (3) MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature. Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals. TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release. In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis. 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