Co-verification of hardware and software for ARM SoC design

Hardware/software co-verification is how to make sure that embedded system software works correctly with the hardware, and that the hardware has been properly designed to run the software successfully -before large sums are spent on prototypes or manufacturing. This is the first book to apply this verification technique to the rapidly growing field of embedded systems-on-a-chip(SoC). As traditional embedded system design evolves into single-chip design, embedded engineers must be armed with the necessary information to make educated decisions about which tools and methodology to deploy. SoC verification requires a mix of expertise from the disciplines of microprocessor and computer architecture, logic design and simulation, and C and Assembly language embedded software. Until now, the relevant information on how it all fits together has not been available. Andrews, a recognized expert, provides in-depth information about how co-verification really works, how to be successful using it, and pitfalls to avoid. He illustrates these concepts using concrete examples with the ARM core - a technology that has the dominant market share in embedded system product design. The companion CD-ROM contains all source code used in the design examples, a searchable e-book version, and useful design tools.

• 1. Embedded System Verification2. Hardware and Software Design Process: System initialization software and hardware abstraction layer (HAL), Hardware diagnostic test suite, Real-time operating system (RTOS), RTOS device drivers, Application software, C simulation, Logic simulation, Simulation acceleration, Emulation, Prototype
• 3. SoC Verification Topics for the ARM Architecture
• 4. Hardware/Software Co-Verification: Host-code execution - implicit access, ISS + BIM, CCM, RTL, Hardware model,Emulation board, FPGA Prototype
• 5. Advanced Hardware/Software Co-Verification: Direct access to simulation memories without advancing simulation time, Memory and time optimizations - understanding synchronization, Cross network connections versus using a single workstation, C modeling for some of the hardware, Implicit Access,Post-processing techniques for software debugging, Synchronized software and hardware views for debugging, Post-processing software trace, Save/restore, How to deal with peripherals, How to deal with an RTOS
• 6. Hardware Verification Environment and Co-Verification: Testbench, The use of testbench tools, Random test generation based on CPU address map, CPU bus protocol checking, Functional/ Transaction coverage, Memory coverage, Property checking - did a specific scenario ever happen? Use of a design signoff model
• 7. Methodology for an Example ARM SoC.