1 / 40

Hardware Design

Hardware Design. Objectives. After completing this module, you will be able to: List the functionality that defines an arbiter, a master, and a slave List various buses available for the PowerPC  processor Discuss the JTAG interface in Virtex-II Pro  devices. Outline. Supported Busses

lottied
Download Presentation

Hardware Design

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Hardware Design This material exempt per Department of Commerce license exception TSU

  2. Objectives After completing this module, you will be able to: • List the functionality that defines an arbiter, a master, and a slave • List various buses available for the PowerPC processor • Discuss the JTAG interface in Virtex-II Pro devices

  3. Outline • Supported Busses • Processor Local Bus (PLB) • On-chip Peripheral Bus (OPB) • Device Control Register (DCR) • On-Chip Memory Bus (OCM) • Processor Use Models • PowerPC Processor Programmer’s Model • Reset Logicin PowerPC • JTAG Configurations in Virtex-II Pro

  4. PowerPC Bus Example PLB Bus Data- 64 bits Address- 32 bits OPB Bus Data- 32 bits Address- 32 bits DSOCM Bus Data- 32 bits Address- 32 bits IIC DDR BRAM UART SDRAM DSOCM BRAM GPIO DSPLB ISPLB INTC Ethernet OPB2PLB PLB2OPB LCD PPC405 DCR BRAM ISOCM DCR Bus Data- 32 bits Address- 10 bits INTC BRAM ISOCM Bus Data- 64 bits Address- 32 bits PLB ARB OPB ARB

  5. CoreConnect • The IBM CoreConnect standard provides three buses for interconnecting cores, library macros, and custom logic: • Processor Local Bus (PLB) • On-chip Peripheral Bus (OPB) • Device Control Register (DCR) bus • IBM offers a no-fee, royalty-free CoreConnect architectural license • Licenses receive the PLB arbiter, OPB arbiter, and PLB/OPB bridge designs along with bus-model toolkits and bus-functional compilers for the PLB, OPB, and DCR buses • Required only if you create your own CoreConnect peripheral or you are using Bus Functional Model (BFM)

  6. Outline • Supported Buses • Processor Local Bus (PLB) • On-Chip Peripheral Bus (OPB) • Device Control Register (DCR) • On-Chip Memory (OCM) • Processor Use Models • MicroBlaze Processor Programmer’s Model • MicroBlaze Configurations • PowerPC Processor Programmer’s Model • Reset Logicin PowerPC • JTAG Configurations in Virtex-II Pro

  7. PLB Bus • Connection infrastructure for high-bandwidth master and slave devices • Fully synchronous to one clock • Centralized bus arbitration—PLB arbiter • 64-bit data bus • Addresses high-performance, low-latency, and design-flexibility issues through: • Decoupled address and read and write data buses with split transaction capability • Concurrent read and write transfers yielding a maximum bus utilization of two data transfers per clock • Address pipelining that reduces bus latency by overlapping a new write request with an ongoing write transfer and up to three read requests with an ongoing read transfer • Ability to overlap the bus request and grant protocol with an ongoing transfer

  8. PLB Interconnect / Architecture • One to 16 PLB masters, each connect all of their signals to the PLB arbiter • The PLB arbiter multiplexes signals from masters onto a shared bus to which all the inputs of the slaves are connected • One to n PLB slaves OR together their outputs to drive a shared bus back to the PLB arbiter • The PLB arbiter handles bus arbitration and the movement of data and control signals between masters and slaves

  9. PLB Bridge • The PLB-to-OPB bridge translates PLB transactions into OPB transactions • This bridge functions as a slave on the PLB side and a master on the OPB side • The bridge contains a DCR slave interface to provide access to its bus error status registers • The bridge is necessary in systems where a PLB master device, such as a CPU, requires access to OPB peripherals

  10. Outline • Buses 101: Arbiter, Master, Slave • Processor Local Bus (PLB) • On-Chip Peripheral Bus (OPB) • Device Control Register (DCR) • On-Chip Memory (OCM) • Local Memory Bus (LMB) • Processor Use Models • MicroBlaze Processor Programmer’s Model • MicroBlaze Configurations • PowerPC Processor Programmer’s Model • Reset Logicin PowerPC • JTAG Configurations in Virtex-II Pro

  11. OPB Bus • The OPB bus decouples lower bandwidth devices from the PLB • It is a less complex protocol than PLB • No split transaction or address pipelining capability • Centralized bus arbitration—OPB arbiter • Connection infrastructure for the master and slave peripheral devices • The OPB bus is designed to alleviate system performance bottlenecks by reducing capacitive loading on the PLB • Fully synchronous to one clock • Shared 32-bit address bus, shared 32-bit data bus • Supports single-cycle data transfers between the master and the slaves • Supports multiple masters, determined by arbitration implementation • The bridge function can be the master on the PLB or OPB

  12. OPB Bus • Supports 16 masters and an unlimited number of slaves (limited by the expected performance) • The OPB arbiter receives bus requests from the OPB masters and grants the bus to one of them • Fixed and dynamic (LRU) priorities • Bus logic is implemented with AND-OR logic. Inactive devices drives zeros • Read and write data buses can be separated to reduce loading on the OPB_DBus signal

  13. Outline • Buses 101: Arbiter, Master, Slave • Processor Local Bus (PLB) • On-Chip Peripheral Bus (OPB) • Device Control Register (DCR) • On-Chip Memory (OCM) • Processor Use Models • PowerPC Processor Programmer’s Model • Reset Logicin PowerPC • JTAG Configurations in Virtex-II Pro

  14. DCR Bus • Device-control register bus • IBM CoreConnect standard • Used to talk to control registers (1024 total) • 32-bits-wide dataall cycles word-oriented • Supports read and write only, no burst cycles • Simple acknowledgement termination • CPU supports special privileged instructions for access to the DCR • Normal DCR requires special CPU assembly code to access • There is a “fixed” 1024-word I/O space • Must be privilege mode to access registers • Requires macros or inline assembly

  15. PPC405 DCR Devices dcr_ABus C405DCRABUS dcr_WrData C405DCRDBUSOUT dcr_RdData DCRC405DBUSIN dcr_Read C405DCRREAD C405DCRWRITE dcr_Write dcr_Clk DCRC405ACK dcr_Ack DCR Bus

  16. Memory Mapped DCR • DCR bridges allow memory mapping of DCR space anywhere within the system memory • OPB DCR bridge • Allows DCR devices to exist within 4 KB of contiguous space • Must be accessed on word boundaries and one word at a time • Easier to use, but it requires a PLB and OPB transaction

  17. Outline • Supported Buses • Processor Local Bus (PLB) • On-Chip Peripheral Bus (OPB) • Device Control Register (DCR) • On-Chip Memory (OCM) • Processor Use Models • PowerPC Processor Programmer’s Model • Reset Logicin PowerPC • JTAG Configurations in Virtex-II Pro

  18. OCM Bus • 405 OCM I/Fs • PPC405 has a separate interface used for high-speed access of on-chip memory • PPC405 presents address on both the PLB bus and the OCM bus • Addresses cannot exist in both PLB and OCM space • OCM addresses are non-cacheable, leaving the cache resources for the PLB accesses • The processor block contains the OCM controllers • The processor block contains dedicated controllers to interface between the OCM I/F and FPGA BRAM • There are separate independent controllers for the I-side and D-side to provide higher performance • All signals are in big-endian format

  19. OCM Bus • Features • Independent 16-MB logical space for each of the DSOCM and ISOCM • 16 MB must be reserved regardless of actual memory used • 64-bit ISOCM and 32-bit DSOCM • Up to 128 KB / 64 KB (ISOCM / DSOCM) using programmable BRAM aspect ratios • Programmable processor versus BRAM clock ratio • DSBRAM load: BRAM initialization (Data2MEM), CPU, and FPGA using dual-port BRAM • ISBRAM load: BRAM initialization (Data2MEM) and DCR • CPU DCR-accessible registers

  20. OCM Bus • Benefits • Avoids loads into cache, reducing pollution and thrashing • Has fast-fixed latency of execution • On the D-side, dual-port BRAM enables a bidirectional data connection with the processor • Sample uses • I-side: Interrupt service routines, boot-code storage • D-side: Scratch-pad memory, bidirectional data transfer

  21. Bus Timing • Use timing constraints to determine which ratio to use • *There are two independent clocks for each OCM controller: • BRAMDSOCMCLK • BRAMISOCMCLK

  22. Bus Summary

  23. Bus Summary

  24. Review Questions • What is the advantage of using the memory-mapped DCR component? • What is the disadvantage of using the memory-mapped DCR component? • Which buses are included in the CoreConnect standard?

  25. Answers • What is the advantage of using the memory-mapped DCR component? • Does not require inline ASM instructions to access the bus • What is the disadvantage of using the memory-mapped DCR component? • Requires a PLB and an OPB transaction • Which buses are included in the CoreConnect standard? • PLB, OPB, and DCR

  26. Outline • Supported Busses • PLB • OPB • DCR • OCM • Processor Use Models • PowerPC Processor Programmer’s Model • Reset Logicin PowerPC • JTAG Configurations in Virtex-II Pro

  27. Highest Integration, Extensive Peripherals, RTOS & Bus Structures Networking & Wireless High Performance 1 2 3 Processor Use Models State Machine Microcontroller Custom Embedded • Lowest Cost, No Peripherals, No RTOS & No Bus Structures • VGA & LCD Controllers • Low/High Performance • Medium Cost, Some Peripherals, Possible RTOS & Bus Structures • Control & Instrumentation • Moderate Performance Range of Use Models

  28. Outline • Supported Busses • PLB • OPB • DCR • OCM • Processor Use Models • PowerPC Processor Programmer’s Model • Reset Logicin PowerPC • JTAG Configurations in Virtex-II Pro

  29. PowerPC Processor Note: The OCM bus does not connect to the cache controller

  30. PowerPC Processor • A 32-bit implementation of the PowerPC embedded-environment architecture • Support for embedded-systems applications • Flexible memory management • Multiply and accumulate instructions for computationally intensive applications • Enhanced debug capabilities • 64-bit time base • Programmable interval (PIT), fixed interval (FIT), and watchdog timers • Performance-enhancing features • Static branch prediction • Five-stage pipeline • Hardware multiply/divide for faster integer arithmetic • Enhanced string and multiple-word handling • Minimized interrupt latency

  31. 0xFFFF_FFFC Reset Address PLB/OPB Memory 0xFFFF_0000 PLB/OPB Memory Peripherals 0x0000_0000 PowerPC • Memory and peripherals • PPC405 uses 32-bit addresses • Special addresses • Every PowerPC system should have the boot section starting at 0xFFFFFFFC • The default program space occupies a contiguous address space from 0xFFFF0000 to 0xFFFFFFFF • If interrupt handlers are present, vector table must start at 64K boundary

  32. Outline • Buses 101: Arbiter, Master, Slave • PLB • OPB • DCR • OCM • PowerPC Processor Programmer’s Model • Reset Logic in PowerPC • JTAG Configurations in Virtex-II Pro

  33. 1 2 3 4 5 6 Reset Sequence • Sequencing of reset signals coming out of reset managed by PROC_SYS_RESET: • First — Bus structures come out of reset • PLB and OPB arbiter and bridges for example • Second — Peripherals come out of reset 16 clocks later • UART, SPI, and IIC, for example • Third — The CPUs come out of reset 16 clocks after the peripherals

  34. Outline • Supported Busses • PLB • OPB • DCR • OCM • Processor Use Model • PowerPC Processor Programmer’s Model • Reset Logic in PowerPC • JTAG Configurations in Virtex-II Pro

  35. JTAG TAP Options • At design time, you have control over whether each of the PowerPC JTAG TAP (in case of multiple PowerPCs) is incorporated into the FPGA JTAG TAP chain after FPGA configuration, or whether it remains a separate chain • This is accomplished by instantiating or not instantiating the dedicated JTAGPPC block

  36. User-Defined JTAG Pins on the FPGA TDO PPC 405 TDI CPUJTAG DEBUG PORT Fixed/Dedicated JTAG Pins on the FPGA FPGA JTAG CONFIG PORT Virtex-II ProSplit JTAG Chains • The isolated chain supports embedded development and debug tools • User-defined JTAG pins • Provides a direct and isolated connection to the PPC405 JTAG I/F • JTAGPPC block is not used in this configuration

  37. User-Defined JTAG Pins on the FPGA TDO PPC 405 TDI CPU JTAG DEBUG PORT JTAG PPC Fixed/Dedicated JTAG Pins on the FPGA FPGA JTAG CONFIG PORT Virtex-II ProCombined JTAG Chains • The combined chain supports development and debug tools • ChipScope Pro (PC4) • iMPACT (PC4) • GDB (PC4) • SingleStep XE (visionPROBEII) • Using the JTAGPPC block • Integrates the PPC405 with the FPGA fabric JTAG chain (dedicated JTAG pins)

  38. Review Questions • What connections must be made to debug software on the IBM PowerPC processor? • Where does the reset vector reside in the PowerPC processor?

  39. Answers • What connections must be made in to debug software on the IBM PowerPC processor? • PowerPC JTAG ports connecting either the JTAGPPC component or the external pins • Where does the reset vector reside in the PowerPC processor? • 0xFFFFFFFC

  40. Where Can I Learn More? • Tool documentation • Processor IP Reference Guide • Processor documentation • PowerPC™ Processor Reference Guide • PowerPC 405 Processor Block Reference Guide • MicroBlaze™ Processor Reference Guide • Support Website • EDK Website: www.xilinx.com/edk

More Related