/** @file RISC-V Exception Handler library implementation. Copyright (c) 2016 - 2022, Hewlett Packard Enterprise Development LP. All rights reserved.
SPDX-License-Identifier: BSD-2-Clause-Patent **/ #include #include #include #include #include #include #include #include "CpuExceptionHandlerLib.h" // // Define the maximum message length // #define MAX_DEBUG_MESSAGE_LENGTH 0x100 STATIC EFI_CPU_INTERRUPT_HANDLER mExceptionHandlers[EXCEPT_RISCV_MAX_EXCEPTIONS + 1]; STATIC EFI_CPU_INTERRUPT_HANDLER mIrqHandlers[EXCEPT_RISCV_MAX_IRQS + 1]; STATIC CONST CHAR8 mExceptionOrIrqUnknown[] = "Unknown"; STATIC CONST CHAR8 *mExceptionNameStr[EXCEPT_RISCV_MAX_EXCEPTIONS + 1] = { "EXCEPT_RISCV_INST_MISALIGNED", "EXCEPT_RISCV_INST_ACCESS_FAULT", "EXCEPT_RISCV_ILLEGAL_INST", "EXCEPT_RISCV_BREAKPOINT", "EXCEPT_RISCV_LOAD_ADDRESS_MISALIGNED", "EXCEPT_RISCV_LOAD_ACCESS_FAULT", "EXCEPT_RISCV_STORE_AMO_ADDRESS_MISALIGNED", "EXCEPT_RISCV_STORE_AMO_ACCESS_FAULT", "EXCEPT_RISCV_ENV_CALL_FROM_UMODE", "EXCEPT_RISCV_ENV_CALL_FROM_SMODE", "EXCEPT_RISCV_ENV_CALL_FROM_VS_MODE", "EXCEPT_RISCV_ENV_CALL_FROM_MMODE", "EXCEPT_RISCV_INST_ACCESS_PAGE_FAULT", "EXCEPT_RISCV_LOAD_ACCESS_PAGE_FAULT", "EXCEPT_RISCV_14", "EXCEPT_RISCV_STORE_ACCESS_PAGE_FAULT", "EXCEPT_RISCV_16", "EXCEPT_RISCV_17", "EXCEPT_RISCV_18", "EXCEPT_RISCV_19", "EXCEPT_RISCV_INST_GUEST_PAGE_FAULT", "EXCEPT_RISCV_LOAD_GUEST_PAGE_FAULT", "EXCEPT_RISCV_VIRTUAL_INSTRUCTION", "EXCEPT_RISCV_STORE_GUEST_PAGE_FAULT" }; STATIC CONST CHAR8 *mIrqNameStr[EXCEPT_RISCV_MAX_IRQS + 1] = { "EXCEPT_RISCV_IRQ_0", "EXCEPT_RISCV_IRQ_SOFT_FROM_SMODE", "EXCEPT_RISCV_IRQ_SOFT_FROM_VSMODE", "EXCEPT_RISCV_IRQ_SOFT_FROM_MMODE", "EXCEPT_RISCV_IRQ_4", "EXCEPT_RISCV_IRQ_TIMER_FROM_SMODE", }; /** Prints a message to the serial port. @param Format Format string for the message to print. @param ... Variable argument list whose contents are accessed based on the format string specified by Format. **/ STATIC VOID EFIAPI InternalPrintMessage ( IN CONST CHAR8 *Format, ... ) { CHAR8 Buffer[MAX_DEBUG_MESSAGE_LENGTH]; VA_LIST Marker; // // Convert the message to an ASCII String // VA_START (Marker, Format); AsciiVSPrint (Buffer, sizeof (Buffer), Format, Marker); VA_END (Marker); // // Send the print string to a Serial Port // SerialPortWrite ((UINT8 *)Buffer, AsciiStrLen (Buffer)); } /** Get ASCII format string exception name by exception type. @param ExceptionType Exception type. @return ASCII format string exception name. **/ STATIC CONST CHAR8 * GetExceptionNameStr ( IN EFI_EXCEPTION_TYPE ExceptionType ) { if (EXCEPT_RISCV_IS_IRQ (ExceptionType)) { if (EXCEPT_RISCV_IRQ_INDEX (ExceptionType) > EXCEPT_RISCV_MAX_IRQS) { return mExceptionOrIrqUnknown; } return mIrqNameStr[EXCEPT_RISCV_IRQ_INDEX (ExceptionType)]; } if (ExceptionType > EXCEPT_RISCV_MAX_EXCEPTIONS) { return mExceptionOrIrqUnknown; } return mExceptionNameStr[ExceptionType]; } /** Display CPU information. This can be called by 3rd-party handlers set by RegisterCpuInterruptHandler. @param ExceptionType Exception type. @param SystemContext Pointer to EFI_SYSTEM_CONTEXT. **/ VOID EFIAPI DumpCpuContext ( IN EFI_EXCEPTION_TYPE ExceptionType, IN EFI_SYSTEM_CONTEXT SystemContext ) { UINTN Printed; SMODE_TRAP_REGISTERS *Regs; Printed = 0; Regs = (SMODE_TRAP_REGISTERS *)SystemContext.SystemContextRiscV64; InternalPrintMessage ( "!!!! RISCV64 Exception Type - %016x(%a) !!!!\n", ExceptionType, GetExceptionNameStr (ExceptionType) ); DEBUG_CODE_BEGIN (); #define REGS() \ REG (t0); REG (t1); REG (t2); REG (t3); REG (t4); REG (t5); REG (t6); \ REG (s0); REG (s1); REG (s2); REG (s3); REG (s4); REG (s5); REG (s6); \ REG (s7); REG (s8); REG (s9); REG (s10); REG (s11); \ REG (a0); REG (a1); REG (a2); REG (a3); REG (a4); REG (a5); REG (a6); \ REG (a7); \ REG (zero); REG (ra); REG (sp); REG (gp); REG (tp); \ REG (sepc); REG (sstatus); REG (stval); #define REG(x) do { \ InternalPrintMessage ("%7a = 0x%017lx%c", #x, Regs->x, \ (++Printed % 2) ? L'\t' : L'\n'); \ } while (0); REGS (); if (Printed % 2 != 0) { InternalPrintMessage ("\n"); } #undef REG #undef REGS DEBUG_CODE_END (); } /** Initializes all CPU exceptions entries and provides the default exception handlers. Caller should try to get an array of interrupt and/or exception vectors that are in use and need to persist by EFI_VECTOR_HANDOFF_INFO defined in PI 1.3 specification. If caller cannot get reserved vector list or it does not exists, set VectorInfo to NULL. If VectorInfo is not NULL, the exception vectors will be initialized per vector attribute accordingly. @param[in] VectorInfo Pointer to reserved vector list. @retval EFI_SUCCESS CPU Exception Entries have been successfully initialized with default exception handlers. @retval EFI_INVALID_PARAMETER VectorInfo includes the invalid content if VectorInfo is not NULL. @retval EFI_UNSUPPORTED This function is not supported. **/ EFI_STATUS EFIAPI InitializeCpuExceptionHandlers ( IN EFI_VECTOR_HANDOFF_INFO *VectorInfo OPTIONAL ) { RiscVSetSupervisorStvec ((UINT64)SupervisorModeTrap); return EFI_SUCCESS; } /** Registers a function to be called from the processor interrupt handler. This function registers and enables the handler specified by InterruptHandler for a processor interrupt or exception type specified by ExceptionType. If InterruptHandler is NULL, then the handler for the processor interrupt or exception type specified by ExceptionType is uninstalled. The installed handler is called once for each processor interrupt or exception. NOTE: This function should be invoked after InitializeCpuExceptionHandlers() or InitializeCpuInterruptHandlers() invoked, otherwise EFI_UNSUPPORTED returned. @param[in] ExceptionType Defines which interrupt or exception to hook. @param[in] InterruptHandler A pointer to a function of type EFI_CPU_INTERRUPT_HANDLER that is called when a processor interrupt occurs. If this parameter is NULL, then the handler will be uninstalled. @retval EFI_SUCCESS The handler for the processor interrupt was successfully installed or uninstalled. @retval EFI_ALREADY_STARTED InterruptHandler is not NULL, and a handler for ExceptionType was previously installed. @retval EFI_INVALID_PARAMETER InterruptHandler is NULL, and a handler for ExceptionType was not previously installed. @retval EFI_UNSUPPORTED The interrupt specified by ExceptionType is not supported, or this function is not supported. **/ EFI_STATUS EFIAPI RegisterCpuInterruptHandler ( IN EFI_EXCEPTION_TYPE ExceptionType, IN EFI_CPU_INTERRUPT_HANDLER InterruptHandler ) { DEBUG ((DEBUG_INFO, "%a: Type:%x Handler: %x\n", __func__, ExceptionType, InterruptHandler)); if (EXCEPT_RISCV_IS_IRQ (ExceptionType)) { if (EXCEPT_RISCV_IRQ_INDEX (ExceptionType) > EXCEPT_RISCV_MAX_IRQS) { return EFI_UNSUPPORTED; } if (mIrqHandlers[EXCEPT_RISCV_IRQ_INDEX (ExceptionType)] != NULL) { return EFI_ALREADY_STARTED; } else if (InterruptHandler == NULL) { return EFI_INVALID_PARAMETER; } mIrqHandlers[EXCEPT_RISCV_IRQ_INDEX (ExceptionType)] = InterruptHandler; } else { if (ExceptionType > EXCEPT_RISCV_MAX_EXCEPTIONS) { return EFI_UNSUPPORTED; } if (mExceptionHandlers[ExceptionType] != NULL) { return EFI_ALREADY_STARTED; } else if (InterruptHandler == NULL) { return EFI_INVALID_PARAMETER; } mExceptionHandlers[ExceptionType] = InterruptHandler; } return EFI_SUCCESS; } /** Setup separate stacks for certain exception handlers. If the input Buffer and BufferSize are both NULL, use global variable if possible. @param[in] Buffer Point to buffer used to separate exception stack. @param[in, out] BufferSize On input, it indicates the byte size of Buffer. If the size is not enough, the return status will be EFI_BUFFER_TOO_SMALL, and output BufferSize will be the size it needs. @retval EFI_SUCCESS The stacks are assigned successfully. @retval EFI_UNSUPPORTED This function is not supported. @retval EFI_BUFFER_TOO_SMALL This BufferSize is too small. **/ EFI_STATUS EFIAPI InitializeSeparateExceptionStacks ( IN VOID *Buffer, IN OUT UINTN *BufferSize ) { return EFI_SUCCESS; } /** Supervisor mode trap handler. @param[in] SmodeTrapReg Registers before trap occurred. **/ VOID RiscVSupervisorModeTrapHandler ( SMODE_TRAP_REGISTERS *SmodeTrapReg ) { EFI_EXCEPTION_TYPE ExceptionType; EFI_SYSTEM_CONTEXT RiscVSystemContext; UINTN IrqIndex; RiscVSystemContext.SystemContextRiscV64 = (EFI_SYSTEM_CONTEXT_RISCV64 *)SmodeTrapReg; ExceptionType = (UINTN)RiscVGetSupervisorTrapCause (); if (EXCEPT_RISCV_IS_IRQ (ExceptionType)) { IrqIndex = EXCEPT_RISCV_IRQ_INDEX (ExceptionType); if ((IrqIndex <= EXCEPT_RISCV_MAX_IRQS) && (mIrqHandlers[IrqIndex] != NULL)) { mIrqHandlers[IrqIndex](ExceptionType, RiscVSystemContext); return; } } else { if ((ExceptionType <= EXCEPT_RISCV_MAX_EXCEPTIONS) && (mExceptionHandlers[ExceptionType] != 0)) { mExceptionHandlers[ExceptionType](ExceptionType, RiscVSystemContext); return; } } DumpCpuContext (ExceptionType, RiscVSystemContext); CpuDeadLoop (); }