Extending the model =================== Changing the register representation ------------------------------------ One can change the base register representation from an `XLEN`-length bitvector by supplying a different definition of the `regtype` type, and functions that convert between that type and the default `XLEN`-length bitvector. The interface for this is specified in `riscv_reg_type.sail`. An extension can implement a different representation in a file that follows that interface, and use it with the rest of the model. Adding architectural state -------------------------- Adding registers (such as for floating-point) would involve naming them and defining their read and write accessors, as is done for the integer registers in `riscv_types.sail`, `riscv_reg_type.sail` and `riscv_regs.sail`. For modularity, these new definitions should be added in separate files. If any of these registers are control-and-status registers (CSRs), or depend on privilege level (such as hypervisor-mode registers), additional access control checks would need to be provided as is done for the standard CSRs in `riscv_sys_regs.sail` and `riscv_sys_control.sail`. Access to newly added CSRs can be hooked in `riscv_csr_ext.sail`. In addition, the bits `mstatus.XS` and `mstatus.SD` may need to be updated or extended to handle any extended register state. Adding a new privilege level or functionality restricted by privilege level will normally be accompanied by defining new exception causes and their encodings. This will require modifying and extending the existing definitions for privilege levels and exceptions in `riscv_types.sail`, and modifying the exception handling and privilege transition functions in `riscv_sys_control.sail`. Modifying exception handling ---------------------------- An extension that needs to interact closely with exception handling may need to capture additional information at the time of an exception. This is supported using the `ext` field in the `sync_exception` type in `riscv_sync_exception.sail`, which is where the extension can store this information. The addresses involved in exception handling can be modified by following the interface provided in `riscv_sys_exceptions.sail`. New exception codes can be introduced using the `E_Extension` variant of the `ExceptionType` in `riscv_types`. Adding low-level platform functionality --------------------------------------- Adding support for new devices such as interrupt controllers and similar memory-mapped I/O (MMIO) entities strictly falls outside the purview of the formal model itself, and typically is not done directly in the Sail model. However, bindings to this external functionality can be provided to Sail definitions using the `extern` construct of the Sail language. `riscv_platform.sail` can be examined to see how this is done for the SiFive core-local interrupt (CLINT) controller, the HTIF timer and terminal devices. The implementation of the actual functionality provided by these MMIO devices would need to be added to the C and OCaml emulators. If this functionality requires the definition of new interrupt sources, their encodings would need to be added to `riscv_types.sail`, and their delegation and handling added to `riscv_sys_control.sail`. Modifying physical memory access -------------------------------- Physical memory addressing and access is defined in `riscv_mem.sail`. Any new regions of memory that are accessible via physical addresses will require modifying the `mem_read`, `mem_write_value` or their supporting functions `checked_mem_read` and `checked_mem_write`. The model supports storing and retrieving metadata along with memory values at each physical memory address. The default interface for this is defined in `prelude_mem_metadata.sail`. An extension can customize the default implementation there to support its metadata type. The actual content of such memory, and its modification, can be defined in separate Sail files. This functionality will have access to any newly defined architectural state. One can examine how normal physical memory access is implemented in `riscv_mem.sail` with helpers in `prelude_mem.sail` and `prelude_mem_metadata.sail`. Extending virtual memory and address translation ------------------------------------------------ Virtual memory is implemented in `riscv_vmem.sail`, and defining new address translation schemes will require modifying the top-level `translateAddr` function. New types of memory access can be defined using the definitions in `riscv_vmem_types`. Any access control checks on virtual addresses and the specifics of the new address translation can be specified in a separate file. This functionality can access any newly defined architectural state. The RV64 architecture has reserved bits in the PTE that can be utilized for research experimentation. These bits can be accessed and modified using the `ext_pte` argument in functions implementing the page-table walk. The information computed by and used during the page-table can also be varied using the `ext_ptw` argument, which can be defined and used by extensions as needed. Checking and transforming memory addresses ------------------------------------------ An extension may wish to perform validity checks and transformations on addresses generated by an instruction before a memory access is performed with the generated address. This is supported using the types defined in `riscv_addr_checks_common.sail`, with a default implementation in `riscv_addr_checks.sail`. The handling of the memory addresses involved during exception handling can be extending using the interface defined in `riscv_sys_exceptions.sail`. Checking and transforming the program counter --------------------------------------------- An extension might want to similarly check and transform accesses to the program counter. This is supported by supplying implementations of the functions defined in `riscv_pc_access.sail`. In addition, dynamically enabling and disabling the RVC extension has an effect on legal PC alignment; in particular, attempts to disable RVC are ignored if the PC becomes unaligned in the base architecture. Extensions can also veto these attempts by appropriately defining `ext_veto_disable_C`. Adding new instructions ----------------------- This is typically simpler than adding new architectural state or memory interposition. Each new set of instructions can be specified in a separate self-contained file, with their instruction encodings, assembly language specifications and the corresponding encoders and decoders, and execution semantics. `riscv.sail` can be examined for examples on how this can done. These instruction definitions can access any newly defined architectural state and perform virtual or physical memory accesses as is done in `riscv.sail`. Interposing on instruction decode --------------------------------- An extension may wish to check and transform a decoded instruction. This is supported via a post-decode extension hook, the default implementation of which is provided in `riscv_decode_ext.sail`. General guidelines ------------------ For any new extension, it is helpful to factor it out into the above items. When specifying and implementing the extension, it is expected to be easier to implement it in the above listed order. Example ------- As an example, one can examine the implementation of the 'N' extension for user-level interrupt handling. The architectural state to support 'N' is specified in `riscv_next_regs.sail`, added CSR and control functionality is in `riscv_next_control.sail`, and added instructions are in `riscv_insts_next.sail`. Access to the CSRs added by the extension are hooked in `riscv_csr_ext.sail`. In addition, privilege transition and interrupt delegation logic in `riscv_sys_control.sail` has been extended.