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Methodology for HW/SW Co-verification in SystemC

Methodology for HW/SW Co-verification in SystemC. Part of HW/SW Codesign of Embedded Systems Course (CE 40-226). Topics. Introduction Design Flow Processor Models Implementation: 8051 Conclusion. Reference:

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Methodology for HW/SW Co-verification in SystemC

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  1. Methodology for HW/SW Co-verification in SystemC Part of HW/SW Codesign of Embedded Systems Course (CE 40-226) Codesign of Embedded Systems

  2. Topics • Introduction • Design Flow • Processor Models • Implementation: 8051 • Conclusion Reference: L. Semeria & A. Ghosh, “Methodology for Hardware/Software Co-Verification in C/C++”, in ASP-DAC 2000 Codesign of Embedded Systems

  3. Methodology for HW/SWCo-verification in SystemC Introduction Codesign of Embedded Systems

  4. Introduction • Shrinking device sizes => all digital components on a single chip • Software is traditionally fully tested after hardware is fabricated => long TTM • Integrating HW and SW earlier in the design cycle => better TTM • Co-simulation involves • Simulating a processor model along with custom hw (usually described in HDL) Codesign of Embedded Systems

  5. Introduction (cont’d) • Heterogeneous co-simulation environments (C-VHDL or C-Verilog) • RPC or another form of inter-process communication between HW and SW simulators • High overhead due to high data transmission between the simulators Codesign of Embedded Systems

  6. Introduction (cont’d) • Recently HW synthesis techniques from C/C++ are more investigated • Eliminates C to HDL translation for synthesis => higher productivity • Reduces translation time • Eliminated bugs introduced during this translation • Easier verification by • re-using testbenches developed during system validation phase • enabling hw/sw co-verification and performance estimation at very early stages of design Codesign of Embedded Systems

  7. Introduction (cont’d) • In this paper, authors present • How hw/sw co-verification is performed in a C/C++ based environment • hw and sw are both described in C++ (SystemC) • Other C/C++ based approaches: PTOLEMY, and CoWare N2C, Codesign of Embedded Systems

  8. Methodology for HW/SWCo-verification in SystemC Design Flow Codesign of Embedded Systems

  9. Mapping Architectural Specification Refinement of Individual hw and sw blocks Synthesis for hw blocks Compilation for sw blocks Design Flow Functional Specificationof the system Codesign of Embedded Systems

  10. Methodology for HW/SWCo-verification in SystemC Processor Models Codesign of Embedded Systems

  11. Processor Models • Bus Functional Model (BFM) • Instruction-Set Simulator (ISS) Codesign of Embedded Systems

  12. Bus Functional Model (BFM) • Encapsulates the bus functionality of a processor • Can execute bus transactions on the processor bus (with cycle accuracy) • Cannot execute any instructions • Hence, • BFM is an abstract model of processor that can be used to verify how a processor interacts with its peripherals Codesign of Embedded Systems

  13. At early stages of the design C/C++ BFM In the later stages of the design ISS BFM Assembly SW SW SW SW SW SW HW HW HW HW HW HW Bus Functional Model (cont’d) Codesign of Embedded Systems

  14. Design of the BFM • Is a SystemC module • Ports of the module correspond to the pins of the processor • Methods of the module provide a PI (programming interface) to the software/ISS • They depend on the type of communication between hw and sw • BFM functionality is modeled as a set of concurrent FSMs Codesign of Embedded Systems

  15. Memory-mapped IO • Peripherals are located on a portion of CPU address space • BFM provided methods • void bfm_read_mem(sc_address, sc_data *, int) • void bfm_write_mem(sc_address, sc_data, int) • SW (without ISS) calls these functions to access hw • When using ISS, SW calls device drivers. • Device drivers are run in the ISS and at proper time call these functions Codesign of Embedded Systems

  16. Interrupt-driven IO • An interrupt controller is implemented in BFM • It is made sensitive to the CPU interrupt lines • In case of an interrupt, the corresponding ISR is called • ISRs are registered by these BFM methods • void bfm_register_handler(sc_interrupt, void (*handler)(sc_interrupt)) • Interrupts may be masked/change behavior using configuration ports Codesign of Embedded Systems

  17. Configuration ports,Access to internal registers • CPUs often have configuration ports for • Multiple modes of operation • Multiple timers/serial modes • Masked interrupts • etc • BFM methods to access these registers • void bfm_read_reg(sc_register, sc_data*, int nb) • void vfm_write_reg(sc_register, sc_data, int nb) • BFM usually doesn’t model general-purpose registers of the CPU Codesign of Embedded Systems

  18. Timers and Serial Ports • Normally, controllers for these timers and serial ports are implemented within BFM • They are configured using configuration ports and registers • Previously mentioned functions are used • They may issue interrupts to the CPU Codesign of Embedded Systems

  19. Performance Estimation Functions • BFM keeps track of bus transactions • Can report number of clock cycles spent for each bus transaction • Reporting can be taken after each transaction or at the end of simulation • Tracking is enabled using • void bfm_enable_tracing(int level) • level is used to define multiple levels of tracking • Even debug information can be produced by the BFM Codesign of Embedded Systems

  20. HW/SW Synchronization • Normal BFM methods are blocking • SW execution is suspended until the bus transaction is done • This essentially serialized SW and HW execution • A flag can be set in the BFM to make SW execute in parallel with HW • i.e. BFM methods return immediately • SW can wait for a specific number of clock cycles by calling • void bfm_idel_cycle(int) Codesign of Embedded Systems

  21. Processor Model • Bus Functional Model (BFM) • Instruction-Set Simulator (ISS) Codesign of Embedded Systems

  22. Instruction-Set Simulator • ISS: a processor model capable of simulating execution of instructions • Different types of ISS for different purposes • Usage 1: Verification of applications written in assembly-code • For fastest speed: translate target assembly instructions into host processor instructions • Is not cycle-accurate. Specially for pipelined and superscalar architectures Codesign of Embedded Systems

  23. ISS (cont’d) • Different types of ISS … (cont’d) • Usage 2: Verification of timing and interface between system components • Used in conjunction with a BFM • ISS should be timing-accurate in this usage • ISS often works as an emulator • For performance estimation usage, ISS is to provide accurate cycle-counting • To have certain speed improvements, ISS should provide necessary hooks (discussed later) Codesign of Embedded Systems

  24. Integrating an ISS and a BFM • ISS + BFM => complete processor model • Cycle-accurate ISS + (already cycle-accurate) BFM => cycle-accurate processor model • Typical units of an ISS • Fetch, Decode, Execute • Execute unit performs calls to BFM to access memory or configuration registers • Fetch unit performs calls to BFM to read instructions Codesign of Embedded Systems

  25. Integrating an ISS and a BFM (cont’d) • For more complex architectures (pipelined, superscalar) • Other units must be modeled • Cache, prefetch, re-order buffer, issue, … • Many units may need to call BFM functions • ISS may need to provide BFM with certain memory-access functions (discussed later) Codesign of Embedded Systems

  26. Techniques to speedup simulation • Reduce activity on memory bus • Most applications: 95% of memory traffic is attributed to instruction and data fetches • Memory access previously verified? => no need to simulate it again during co-simulation • Put instruction memory (and/or data memory) insideISS • What to do for external devices accessing instr/data memory? • BFM must be configured to recognize them and call corresponding ISS method to access instr/data • ISS must provide the above methods • ISS must implement a memory map, where certain addresses are directly accessed, while others through bus cycles Codesign of Embedded Systems

  27. Techniques to speedup simulation (cont’d) • Turn off clocks on modules • All clocked components activate by clock edge • Most of time the component is not addressed => activation and simulation (even a limited part of each process) is wasteful => turn off clocks when not necessary • How to do it? • BFM generated bus clock, only when devices on the bus are addressed Codesign of Embedded Systems

  28. Methodology for HW/SWCo-verification in SystemC Implementation: 8051 Codesign of Embedded Systems

  29. Implementation: 8051 • Implementation of Synopsys dw8051 BFM and cycle-accurate ISS • Synopsys dw8051: • 8-bit microcontroller • Configurable, fully synthesizable, reusable macrocell • industry standard for simple embedded application • smartcard, cars, toys, … • Many IO modes • SFR (Specific Function Register) bus • interrupt ports (expandable to 12) • up to 2 serial ports, in 4 different modes of operation • up to 2 timers, in 3 different modes of operation Codesign of Embedded Systems

  30. Implementation: 8051 (cont’d) • dw8051 BFM • Fully developed in SystemC • BFM supports • timer 1, mode 0,1,2 • serial port 0, mode 0,1,2,3 • external interrupts • external memory accesses • SFR accesses • dw8051 cycle-accurate model Codesign of Embedded Systems

  31. What we learned today • Ghosh et al co-verification strategy, using SystemC, was presented • C/C++ models are very efficiently compiled on today architectures • No overhead for C-HDL interfacing is introduced • Performance estimates can be obtained from model • C++ allows use of OO techniques to create BFM and ISS, which enables re-use of them for subsequent generations of the processor Codesign of Embedded Systems

  32. Complementary notes:Assignments • Take Assignment 8 • Due Date: Saturday, Khordad 12th Codesign of Embedded Systems

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