Mirrors_Framework/nuttx
1
0
Fork 0
mirror of https://github.com/apache/nuttx.git synced 2026-05-20 04:16:35 +08:00
Code Issues Actions 1 Packages Projects Releases Wiki Activity

arch/risc-v: Merge rv32im and rv64gc into common

Browse Source 
Signed-off-by: Huang Qi <huangqi3@xiaomi.com>
This commit is contained in:
Huang Qi
2022-01-07 23:17:23 +08:00
committed by Xiang Xiao
parent efca63e9e3
commit 10bb48b9b4
73 changed files with 701 additions and 2030 deletions
Download Patch File Download Diff File Expand all files Collapse all files
arch/risc-v/Kconfig
-3
View File
@@ -199,9 +199,6 @@ endif
source "arch/risc-v/src/opensbi/Kconfig"
source "arch/risc-v/src/common/Kconfig"
if ARCH_RV32
source "arch/risc-v/src/rv32im/Kconfig"
endif
if ARCH_CHIP_FE310
source "arch/risc-v/src/fe310/Kconfig"
endif
arch/risc-v/include/irq.h
+443 -7
View File
@@ -31,21 +31,457 @@
/* Include chip-specific IRQ definitions (including IRQ numbers) */
#include <nuttx/config.h>
#include <arch/types.h>
#ifndef __ASSEMBLY__
#include <stdint.h>
#include <nuttx/irq.h>
#include <arch/csr.h>
#include <arch/chip/irq.h>
/* Include RISC-V architecture-specific IRQ definitions */
#if defined(CONFIG_ARCH_RV32)
# include <arch/rv32im/irq.h>
#endif
#if defined(CONFIG_ARCH_RV64)
# include <arch/rv64gc/irq.h>
/****************************************************************************
* Pre-processor Definitions
****************************************************************************/
/* Configuration ************************************************************/
/* If this is a kernel build, how many nested system calls should we
* support?
*/
#ifndef CONFIG_SYS_NNEST
# define CONFIG_SYS_NNEST 2
#endif
/* Processor PC */
#define REG_EPC_NDX 0
/* General pupose registers
* $0: Zero register does not need to be saved
* $1: ra (return address)
*/
#define REG_X1_NDX 1
/* $2: Stack POinter
* $3: Global Pointer
* $4: Thread Pointer
*/
#define REG_X2_NDX 2
#define REG_X3_NDX 3
#define REG_X4_NDX 4
/* $5-$7 = t0-t3: Temporary registers */
#define REG_X5_NDX 5
#define REG_X6_NDX 6
#define REG_X7_NDX 7
/* $8: s0 / fp Frame pointer */
#define REG_X8_NDX 8
/* $89 s1 Saved register */
#define REG_X9_NDX 9
/* $10-$17 = a0-a7: Argument registers */
#define REG_X10_NDX 10
#define REG_X11_NDX 11
#define REG_X12_NDX 12
#define REG_X13_NDX 13
#define REG_X14_NDX 14
#define REG_X15_NDX 15
#define REG_X16_NDX 16
#define REG_X17_NDX 17
/* $18-$27 = s2-s11: Saved registers */
#define REG_X18_NDX 18
#define REG_X19_NDX 19
#define REG_X20_NDX 20
#define REG_X21_NDX 21
#define REG_X22_NDX 22
#define REG_X23_NDX 23
#define REG_X24_NDX 24
#define REG_X25_NDX 25
#define REG_X26_NDX 26
#define REG_X27_NDX 27
/* $28-31 = t3-t6: Temporary (Volatile) registers */
#define REG_X28_NDX 28
#define REG_X29_NDX 29
#define REG_X30_NDX 30
#define REG_X31_NDX 31
/* Interrupt Context register */
#define REG_INT_CTX_NDX 32
#ifdef CONFIG_ARCH_RISCV_INTXCPT_EXTREGS
# define INT_XCPT_REGS (33 + CONFIG_ARCH_RISCV_INTXCPT_EXTREGS)
#else
# define INT_XCPT_REGS 33
#endif
#ifdef CONFIG_ARCH_RV32
# define INT_REG_SIZE 4
#else
# define INT_REG_SIZE 8
#endif
#define INT_XCPT_SIZE (INT_REG_SIZE * INT_XCPT_REGS)
#ifdef CONFIG_ARCH_RV32
# if defined(CONFIG_ARCH_DPFPU)
# define FPU_REG_SIZE 2
# elif defined(CONFIG_ARCH_QPFPU)
# define FPU_REG_SIZE 4
# elif defined(CONFIG_ARCH_FPU)
# define FPU_REG_SIZE 1
# endif
#else
# if defined(CONFIG_ARCH_QPFPU)
# define FPU_REG_SIZE 2
# else
# define FPU_REG_SIZE 1
# endif
#endif
#ifdef CONFIG_ARCH_FPU
# define REG_F0_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 0)
# define REG_F1_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 1)
# define REG_F2_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 2)
# define REG_F3_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 3)
# define REG_F4_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 4)
# define REG_F5_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 5)
# define REG_F6_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 6)
# define REG_F7_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 7)
# define REG_F8_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 8)
# define REG_F9_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 9)
# define REG_F10_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 10)
# define REG_F11_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 11)
# define REG_F12_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 12)
# define REG_F13_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 13)
# define REG_F14_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 14)
# define REG_F15_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 15)
# define REG_F16_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 16)
# define REG_F17_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 17)
# define REG_F18_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 18)
# define REG_F19_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 19)
# define REG_F20_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 20)
# define REG_F21_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 21)
# define REG_F22_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 22)
# define REG_F23_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 23)
# define REG_F24_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 24)
# define REG_F25_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 25)
# define REG_F26_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 26)
# define REG_F27_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 27)
# define REG_F28_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 28)
# define REG_F29_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 29)
# define REG_F30_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 30)
# define REG_F31_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 31)
# define REG_FCSR_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 32)
# define FPU_XCPT_REGS (FPU_REG_SIZE * 33)
#else /* !CONFIG_ARCH_FPU */
# define FPU_XCPT_REGS 0
#endif /* CONFIG_ARCH_FPU */
#define XCPTCONTEXT_REGS (INT_XCPT_REGS + FPU_XCPT_REGS)
#define XCPTCONTEXT_SIZE (INT_REG_SIZE * XCPTCONTEXT_REGS)
/* In assembly language, values have to be referenced as byte address
* offsets. But in C, it is more convenient to reference registers as
* register save table offsets.
*/
#ifdef __ASSEMBLY__
# define REG_EPC (INT_REG_SIZE*REG_EPC_NDX)
# define REG_X1 (INT_REG_SIZE*REG_X1_NDX)
# define REG_X2 (INT_REG_SIZE*REG_X2_NDX)
# define REG_X3 (INT_REG_SIZE*REG_X3_NDX)
# define REG_X4 (INT_REG_SIZE*REG_X4_NDX)
# define REG_X5 (INT_REG_SIZE*REG_X5_NDX)
# define REG_X6 (INT_REG_SIZE*REG_X6_NDX)
# define REG_X7 (INT_REG_SIZE*REG_X7_NDX)
# define REG_X8 (INT_REG_SIZE*REG_X8_NDX)
# define REG_X9 (INT_REG_SIZE*REG_X9_NDX)
# define REG_X10 (INT_REG_SIZE*REG_X10_NDX)
# define REG_X11 (INT_REG_SIZE*REG_X11_NDX)
# define REG_X12 (INT_REG_SIZE*REG_X12_NDX)
# define REG_X13 (INT_REG_SIZE*REG_X13_NDX)
# define REG_X14 (INT_REG_SIZE*REG_X14_NDX)
# define REG_X15 (INT_REG_SIZE*REG_X15_NDX)
# define REG_X16 (INT_REG_SIZE*REG_X16_NDX)
# define REG_X17 (INT_REG_SIZE*REG_X17_NDX)
# define REG_X18 (INT_REG_SIZE*REG_X18_NDX)
# define REG_X19 (INT_REG_SIZE*REG_X19_NDX)
# define REG_X20 (INT_REG_SIZE*REG_X20_NDX)
# define REG_X21 (INT_REG_SIZE*REG_X21_NDX)
# define REG_X22 (INT_REG_SIZE*REG_X22_NDX)
# define REG_X23 (INT_REG_SIZE*REG_X23_NDX)
# define REG_X24 (INT_REG_SIZE*REG_X24_NDX)
# define REG_X25 (INT_REG_SIZE*REG_X25_NDX)
# define REG_X26 (INT_REG_SIZE*REG_X26_NDX)
# define REG_X27 (INT_REG_SIZE*REG_X27_NDX)
# define REG_X28 (INT_REG_SIZE*REG_X28_NDX)
# define REG_X29 (INT_REG_SIZE*REG_X29_NDX)
# define REG_X30 (INT_REG_SIZE*REG_X30_NDX)
# define REG_X31 (INT_REG_SIZE*REG_X31_NDX)
# define REG_INT_CTX (INT_REG_SIZE*REG_INT_CTX_NDX)
#ifdef CONFIG_ARCH_FPU
# define REG_F0 (INT_REG_SIZE*REG_F0_NDX)
# define REG_F1 (INT_REG_SIZE*REG_F1_NDX)
# define REG_F2 (INT_REG_SIZE*REG_F2_NDX)
# define REG_F3 (INT_REG_SIZE*REG_F3_NDX)
# define REG_F4 (INT_REG_SIZE*REG_F4_NDX)
# define REG_F5 (INT_REG_SIZE*REG_F5_NDX)
# define REG_F6 (INT_REG_SIZE*REG_F6_NDX)
# define REG_F7 (INT_REG_SIZE*REG_F7_NDX)
# define REG_F8 (INT_REG_SIZE*REG_F8_NDX)
# define REG_F9 (INT_REG_SIZE*REG_F9_NDX)
# define REG_F10 (INT_REG_SIZE*REG_F10_NDX)
# define REG_F11 (INT_REG_SIZE*REG_F11_NDX)
# define REG_F12 (INT_REG_SIZE*REG_F12_NDX)
# define REG_F13 (INT_REG_SIZE*REG_F13_NDX)
# define REG_F14 (INT_REG_SIZE*REG_F14_NDX)
# define REG_F15 (INT_REG_SIZE*REG_F15_NDX)
# define REG_F16 (INT_REG_SIZE*REG_F16_NDX)
# define REG_F17 (INT_REG_SIZE*REG_F17_NDX)
# define REG_F18 (INT_REG_SIZE*REG_F18_NDX)
# define REG_F19 (INT_REG_SIZE*REG_F19_NDX)
# define REG_F20 (INT_REG_SIZE*REG_F20_NDX)
# define REG_F21 (INT_REG_SIZE*REG_F21_NDX)
# define REG_F22 (INT_REG_SIZE*REG_F22_NDX)
# define REG_F23 (INT_REG_SIZE*REG_F23_NDX)
# define REG_F24 (INT_REG_SIZE*REG_F24_NDX)
# define REG_F25 (INT_REG_SIZE*REG_F25_NDX)
# define REG_F26 (INT_REG_SIZE*REG_F26_NDX)
# define REG_F27 (INT_REG_SIZE*REG_F27_NDX)
# define REG_F28 (INT_REG_SIZE*REG_F28_NDX)
# define REG_F29 (INT_REG_SIZE*REG_F29_NDX)
# define REG_F30 (INT_REG_SIZE*REG_F30_NDX)
# define REG_F31 (INT_REG_SIZE*REG_F31_NDX)
# define REG_FCSR (INT_REG_SIZE*REG_FCSR_NDX)
#endif
#else
# define REG_EPC REG_EPC_NDX
# define REG_X1 REG_X1_NDX
# define REG_X2 REG_X2_NDX
# define REG_X3 REG_X3_NDX
# define REG_X4 REG_X4_NDX
# define REG_X5 REG_X5_NDX
# define REG_X6 REG_X6_NDX
# define REG_X7 REG_X7_NDX
# define REG_X8 REG_X8_NDX
# define REG_X9 REG_X9_NDX
# define REG_X10 REG_X10_NDX
# define REG_X11 REG_X11_NDX
# define REG_X12 REG_X12_NDX
# define REG_X13 REG_X13_NDX
# define REG_X14 REG_X14_NDX
# define REG_X15 REG_X15_NDX
# define REG_X16 REG_X16_NDX
# define REG_X17 REG_X17_NDX
# define REG_X18 REG_X18_NDX
# define REG_X19 REG_X19_NDX
# define REG_X20 REG_X20_NDX
# define REG_X21 REG_X21_NDX
# define REG_X22 REG_X22_NDX
# define REG_X23 REG_X23_NDX
# define REG_X24 REG_X24_NDX
# define REG_X25 REG_X25_NDX
# define REG_X26 REG_X26_NDX
# define REG_X27 REG_X27_NDX
# define REG_X28 REG_X28_NDX
# define REG_X29 REG_X29_NDX
# define REG_X30 REG_X30_NDX
# define REG_X31 REG_X31_NDX
# define REG_INT_CTX REG_INT_CTX_NDX
#ifdef CONFIG_ARCH_FPU
# define REG_F0 REG_F0_NDX
# define REG_F1 REG_F1_NDX
# define REG_F2 REG_F2_NDX
# define REG_F3 REG_F3_NDX
# define REG_F4 REG_F4_NDX
# define REG_F5 REG_F5_NDX
# define REG_F6 REG_F6_NDX
# define REG_F7 REG_F7_NDX
# define REG_F8 REG_F8_NDX
# define REG_F9 REG_F9_NDX
# define REG_F10 REG_F10_NDX
# define REG_F11 REG_F11_NDX
# define REG_F12 REG_F12_NDX
# define REG_F13 REG_F13_NDX
# define REG_F14 REG_F14_NDX
# define REG_F15 REG_F15_NDX
# define REG_F16 REG_F16_NDX
# define REG_F17 REG_F17_NDX
# define REG_F18 REG_F18_NDX
# define REG_F19 REG_F19_NDX
# define REG_F20 REG_F20_NDX
# define REG_F21 REG_F21_NDX
# define REG_F22 REG_F22_NDX
# define REG_F23 REG_F23_NDX
# define REG_F24 REG_F24_NDX
# define REG_F25 REG_F25_NDX
# define REG_F26 REG_F26_NDX
# define REG_F27 REG_F27_NDX
# define REG_F28 REG_F28_NDX
# define REG_F29 REG_F29_NDX
# define REG_F30 REG_F30_NDX
# define REG_F31 REG_F31_NDX
# define REG_FCSR REG_FCSR_NDX
#endif
#endif
/* Now define more user friendly alternative name that can be used either
* in assembly or C contexts.
*/
/* $1 = ra: Return address */
#define REG_RA REG_X1
/* $2 = sp: The value of the stack pointer on return from the exception */
#define REG_SP REG_X2
/* $3 = gp: Only needs to be saved under conditions where there are
* multiple, per-thread values for the GP.
*/
#define REG_GP REG_X3
/* $4 = tp: Thread Pointer */
#define REG_TP REG_X4
/* $5-$7 = t0-t2: Caller saved temporary registers */
#define REG_T0 REG_X5
#define REG_T1 REG_X6
#define REG_T2 REG_X7
/* $8 = either s0 or fp: Depends if a frame pointer is used or not */
#define REG_S0 REG_X8
#define REG_FP REG_X8
/* $9 = s1: Caller saved register */
#define REG_S1 REG_X9
/* $10-$17 = a0-a7: Argument registers */
#define REG_A0 REG_X10
#define REG_A1 REG_X11
#define REG_A2 REG_X12
#define REG_A3 REG_X13
#define REG_A4 REG_X14
#define REG_A5 REG_X15
#define REG_A6 REG_X16
#define REG_A7 REG_X17
/* $18-$27 = s2-s11: Callee saved registers */
#define REG_S2 REG_X18
#define REG_S3 REG_X19
#define REG_S4 REG_X20
#define REG_S5 REG_X21
#define REG_S6 REG_X22
#define REG_S7 REG_X23
#define REG_S8 REG_X24
#define REG_S9 REG_X25
#define REG_S10 REG_X26
#define REG_S11 REG_X27
/* $28-$31 = t3-t6: Caller saved temporary registers */
#define REG_T3 REG_X28
#define REG_T4 REG_X29
#define REG_T5 REG_X30
#define REG_T6 REG_X31
/****************************************************************************
* Public Types
****************************************************************************/
#ifndef __ASSEMBLY__
/* This structure represents the return state from a system call */
#ifdef CONFIG_LIB_SYSCALL
struct xcpt_syscall_s
{
uintptr_t sysreturn; /* The return PC */
#ifdef CONFIG_BUILD_PROTECTED
uintptr_t int_ctx; /* Interrupt context (i.e. mstatus) */
#endif
};
#endif
/* The following structure is included in the TCB and defines the complete
* state of the thread.
*/
struct xcptcontext
{
/* The following function pointer is non-NULL if there are pending signals
* to be processed.
*/
void *sigdeliver; /* Actual type is sig_deliver_t */
/* These additional register save locations are used to implement the
* signal delivery trampoline.
*
* REVISIT: Because there is only one copy of these save areas,
* only a single signal handler can be active. This precludes
* queuing of signal actions. As a result, signals received while
* another signal handler is executing will be ignored!
*/
uintptr_t saved_epc; /* Trampoline PC */
uintptr_t saved_int_ctx; /* Interrupt context with interrupts disabled. */
#ifdef CONFIG_BUILD_PROTECTED
/* This is the saved address to use when returning from a user-space
* signal handler.
*/
uintptr_t sigreturn;
#endif
#ifdef CONFIG_LIB_SYSCALL
/* The following array holds information needed to return from each nested
* system call.
*/
uint8_t nsyscalls;
struct xcpt_syscall_s syscall[CONFIG_SYS_NNEST];
#endif
/* Register save area */
uintptr_t regs[XCPTCONTEXT_REGS];
};
#endif /* __ASSEMBLY__ */
/****************************************************************************
* Public Types
****************************************************************************/
arch/risc-v/include/rv32im/mcause.h → arch/risc-v/include/mcause.h
+4 -4
View File
@@ -1,5 +1,5 @@
/****************************************************************************
* arch/risc-v/include/rv32im/mcause.h
* arch/risc-v/include/mcause.h
*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed with
@@ -18,8 +18,8 @@
*
****************************************************************************/
#ifndef __ARCH_RISCV_INCLUDE_RV32IM_MCAUSE_H
#define __ARCH_RISCV_INCLUDE_RV32IM_MCAUSE_H
#ifndef __ARCH_RISCV_INCLUDE_MCAUSE_H
#define __ARCH_RISCV_INCLUDE_MCAUSE_H
/****************************************************************************
* Included Files
@@ -59,5 +59,5 @@
#define MCAUSE_MAX_EXCEPTION (15)
#endif /* __ARCH_RISCV_INCLUDE_RV32IM_MCAUSE_H */
#endif /* __ARCH_RISCV_INCLUDE_MCAUSE_H */
arch/risc-v/include/rv32im/irq.h
-461
View File
@@ -1,461 +0,0 @@
/****************************************************************************
* arch/risc-v/include/rv32im/irq.h
*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership. The
* ASF licenses this file to you under the Apache License, Version 2.0 (the
* "License"); you may not use this file except in compliance with the
* License. You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
* License for the specific language governing permissions and limitations
* under the License.
*
****************************************************************************/
/* This file should never be included directly but, rather, only indirectly
* through nuttx/irq.h
*/
#ifndef __ARCH_RISCV_INCLUDE_RV32IM_IRQ_H
#define __ARCH_RISCV_INCLUDE_RV32IM_IRQ_H
/****************************************************************************
* Included Files
****************************************************************************/
#include <nuttx/config.h>
#include <arch/types.h>
/****************************************************************************
* Pre-processor Definitions
****************************************************************************/
/* Configuration ************************************************************/
/* How many nested system calls should we support? */
#ifndef CONFIG_SYS_NNEST
# define CONFIG_SYS_NNEST 2
#endif
/* Processor PC */
#define REG_EPC_NDX 0
/* General pupose registers */
/* $0: Zero register does not need to be saved
* $1: ra (return address)
*/
#define REG_X1_NDX 1
/* $2: Stack Pointer
* $3: Global Pointer
* $4: Thread Pointer
*/
#define REG_X2_NDX 2
#define REG_X3_NDX 3
#define REG_X4_NDX 4
/* $5-$7 = t0-t3: Temporary registers */
#define REG_X5_NDX 5
#define REG_X6_NDX 6
#define REG_X7_NDX 7
/* $8: s0 / fp Frame pointer */
#define REG_X8_NDX 8
/* $89 s1 Saved register */
#define REG_X9_NDX 9
/* $10-$17 = a0-a7: Argument registers */
#define REG_X10_NDX 10
#define REG_X11_NDX 11
#define REG_X12_NDX 12
#define REG_X13_NDX 13
#define REG_X14_NDX 14
#define REG_X15_NDX 15
#define REG_X16_NDX 16
#define REG_X17_NDX 17
/* $18-$27 = s2-s11: Saved registers */
#define REG_X18_NDX 18
#define REG_X19_NDX 19
#define REG_X20_NDX 20
#define REG_X21_NDX 21
#define REG_X22_NDX 22
#define REG_X23_NDX 23
#define REG_X24_NDX 24
#define REG_X25_NDX 25
#define REG_X26_NDX 26
#define REG_X27_NDX 27
/* $28-31 = t3-t6: Temporary (Volatile) registers */
#define REG_X28_NDX 28
#define REG_X29_NDX 29
#define REG_X30_NDX 30
#define REG_X31_NDX 31
/* Interrupt Context register */
#define REG_INT_CTX_NDX 32
#ifdef CONFIG_ARCH_RISCV_INTXCPT_EXTREGS
#define INT_XCPT_REGS (33 + CONFIG_ARCH_RISCV_INTXCPT_EXTREGS)
#else
#define INT_XCPT_REGS 33
#endif
#define INT_XCPT_SIZE (4 * INT_XCPT_REGS)
#ifdef CONFIG_ARCH_FPU
#if defined(CONFIG_ARCH_DPFPU)
# define FPU_REG_SIZE 2
#elif defined(CONFIG_ARCH_QPFPU)
# define FPU_REG_SIZE 4
#else
# define FPU_REG_SIZE 1
#endif
# define REG_F0_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 0)
# define REG_F1_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 1)
# define REG_F2_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 2)
# define REG_F3_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 3)
# define REG_F4_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 4)
# define REG_F5_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 5)
# define REG_F6_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 6)
# define REG_F7_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 7)
# define REG_F8_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 8)
# define REG_F9_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 9)
# define REG_F10_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 10)
# define REG_F11_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 11)
# define REG_F12_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 12)
# define REG_F13_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 13)
# define REG_F14_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 14)
# define REG_F15_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 15)
# define REG_F16_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 16)
# define REG_F17_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 17)
# define REG_F18_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 18)
# define REG_F19_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 19)
# define REG_F20_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 20)
# define REG_F21_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 21)
# define REG_F22_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 22)
# define REG_F23_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 23)
# define REG_F24_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 24)
# define REG_F25_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 25)
# define REG_F26_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 26)
# define REG_F27_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 27)
# define REG_F28_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 28)
# define REG_F29_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 29)
# define REG_F30_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 30)
# define REG_F31_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 31)
# define REG_FCSR_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 32)
# define FPU_XCPT_REGS (FPU_REG_SIZE * 33)
#else
# define FPU_XCPT_REGS 0
#endif
#define XCPTCONTEXT_REGS (INT_XCPT_REGS + FPU_XCPT_REGS)
#define XCPTCONTEXT_SIZE (4 * XCPTCONTEXT_REGS)
/* In assembly language, values have to be referenced as byte address
* offsets. But in C, it is more convenient to reference registers as
* register save table offsets.
*/
#ifdef __ASSEMBLY__
# define REG_EPC (4*REG_EPC_NDX)
# define REG_X1 (4*REG_X1_NDX)
# define REG_X2 (4*REG_X2_NDX)
# define REG_X3 (4*REG_X3_NDX)
# define REG_X4 (4*REG_X4_NDX)
# define REG_X5 (4*REG_X5_NDX)
# define REG_X6 (4*REG_X6_NDX)
# define REG_X7 (4*REG_X7_NDX)
# define REG_X8 (4*REG_X8_NDX)
# define REG_X9 (4*REG_X9_NDX)
# define REG_X10 (4*REG_X10_NDX)
# define REG_X11 (4*REG_X11_NDX)
# define REG_X12 (4*REG_X12_NDX)
# define REG_X13 (4*REG_X13_NDX)
# define REG_X14 (4*REG_X14_NDX)
# define REG_X15 (4*REG_X15_NDX)
# define REG_X16 (4*REG_X16_NDX)
# define REG_X17 (4*REG_X17_NDX)
# define REG_X18 (4*REG_X18_NDX)
# define REG_X19 (4*REG_X19_NDX)
# define REG_X20 (4*REG_X20_NDX)
# define REG_X21 (4*REG_X21_NDX)
# define REG_X22 (4*REG_X22_NDX)
# define REG_X23 (4*REG_X23_NDX)
# define REG_X24 (4*REG_X24_NDX)
# define REG_X25 (4*REG_X25_NDX)
# define REG_X26 (4*REG_X26_NDX)
# define REG_X27 (4*REG_X27_NDX)
# define REG_X28 (4*REG_X28_NDX)
# define REG_X29 (4*REG_X29_NDX)
# define REG_X30 (4*REG_X30_NDX)
# define REG_X31 (4*REG_X31_NDX)
# define REG_INT_CTX (4*REG_INT_CTX_NDX)
#ifdef CONFIG_ARCH_FPU
# define REG_F0 (4*REG_F0_NDX)
# define REG_F1 (4*REG_F1_NDX)
# define REG_F2 (4*REG_F2_NDX)
# define REG_F3 (4*REG_F3_NDX)
# define REG_F4 (4*REG_F4_NDX)
# define REG_F5 (4*REG_F5_NDX)
# define REG_F6 (4*REG_F6_NDX)
# define REG_F7 (4*REG_F7_NDX)
# define REG_F8 (4*REG_F8_NDX)
# define REG_F9 (4*REG_F9_NDX)
# define REG_F10 (4*REG_F10_NDX)
# define REG_F11 (4*REG_F11_NDX)
# define REG_F12 (4*REG_F12_NDX)
# define REG_F13 (4*REG_F13_NDX)
# define REG_F14 (4*REG_F14_NDX)
# define REG_F15 (4*REG_F15_NDX)
# define REG_F16 (4*REG_F16_NDX)
# define REG_F17 (4*REG_F17_NDX)
# define REG_F18 (4*REG_F18_NDX)
# define REG_F19 (4*REG_F19_NDX)
# define REG_F20 (4*REG_F20_NDX)
# define REG_F21 (4*REG_F21_NDX)
# define REG_F22 (4*REG_F22_NDX)
# define REG_F23 (4*REG_F23_NDX)
# define REG_F24 (4*REG_F24_NDX)
# define REG_F25 (4*REG_F25_NDX)
# define REG_F26 (4*REG_F26_NDX)
# define REG_F27 (4*REG_F27_NDX)
# define REG_F28 (4*REG_F28_NDX)
# define REG_F29 (4*REG_F29_NDX)
# define REG_F30 (4*REG_F30_NDX)
# define REG_F31 (4*REG_F31_NDX)
# define REG_FCSR (4*REG_FCSR_NDX)
#endif
#else
# define REG_EPC REG_EPC_NDX
# define REG_X1 REG_X1_NDX
# define REG_X2 REG_X2_NDX
# define REG_X3 REG_X3_NDX
# define REG_X4 REG_X4_NDX
# define REG_X5 REG_X5_NDX
# define REG_X6 REG_X6_NDX
# define REG_X7 REG_X7_NDX
# define REG_X8 REG_X8_NDX
# define REG_X9 REG_X9_NDX
# define REG_X10 REG_X10_NDX
# define REG_X11 REG_X11_NDX
# define REG_X12 REG_X12_NDX
# define REG_X13 REG_X13_NDX
# define REG_X14 REG_X14_NDX
# define REG_X15 REG_X15_NDX
# define REG_X16 REG_X16_NDX
# define REG_X17 REG_X17_NDX
# define REG_X18 REG_X18_NDX
# define REG_X19 REG_X19_NDX
# define REG_X20 REG_X20_NDX
# define REG_X21 REG_X21_NDX
# define REG_X22 REG_X22_NDX
# define REG_X23 REG_X23_NDX
# define REG_X24 REG_X24_NDX
# define REG_X25 REG_X25_NDX
# define REG_X26 REG_X26_NDX
# define REG_X27 REG_X27_NDX
# define REG_X28 REG_X28_NDX
# define REG_X29 REG_X29_NDX
# define REG_X30 REG_X30_NDX
# define REG_X31 REG_X31_NDX
# define REG_INT_CTX REG_INT_CTX_NDX
#ifdef CONFIG_ARCH_FPU
# define REG_F0 REG_F0_NDX
# define REG_F1 REG_F1_NDX
# define REG_F2 REG_F2_NDX
# define REG_F3 REG_F3_NDX
# define REG_F4 REG_F4_NDX
# define REG_F5 REG_F5_NDX
# define REG_F6 REG_F6_NDX
# define REG_F7 REG_F7_NDX
# define REG_F8 REG_F8_NDX
# define REG_F9 REG_F9_NDX
# define REG_F10 REG_F10_NDX
# define REG_F11 REG_F11_NDX
# define REG_F12 REG_F12_NDX
# define REG_F13 REG_F13_NDX
# define REG_F14 REG_F14_NDX
# define REG_F15 REG_F15_NDX
# define REG_F16 REG_F16_NDX
# define REG_F17 REG_F17_NDX
# define REG_F18 REG_F18_NDX
# define REG_F19 REG_F19_NDX
# define REG_F20 REG_F20_NDX
# define REG_F21 REG_F21_NDX
# define REG_F22 REG_F22_NDX
# define REG_F23 REG_F23_NDX
# define REG_F24 REG_F24_NDX
# define REG_F25 REG_F25_NDX
# define REG_F26 REG_F26_NDX
# define REG_F27 REG_F27_NDX
# define REG_F28 REG_F28_NDX
# define REG_F29 REG_F29_NDX
# define REG_F30 REG_F30_NDX
# define REG_F31 REG_F31_NDX
# define REG_FCSR REG_FCSR_NDX
#endif
#endif
/* Now define more user friendly alternative name that can be used either
* in assembly or C contexts.
*/
/* $1 = ra: Return address */
#define REG_RA REG_X1
/* $2 = sp: The value of the stack pointer on return from the exception */
#define REG_SP REG_X2
/* $3 = gp: Only needs to be saved under conditions where there are
* multiple, per-thread values for the GP.
*/
#define REG_GP REG_X3
/* $4 = tp: Thread Pointer */
#define REG_TP REG_X4
/* $5-$7 = t0-t2: Caller saved temporary registers */
#define REG_T0 REG_X5
#define REG_T1 REG_X6
#define REG_T2 REG_X7
/* $8 = either s0 or fp: Depends if a frame pointer is used or not */
#define REG_S0 REG_X8
#define REG_FP REG_X8
/* $9 = s1: Caller saved register */
#define REG_S1 REG_X9
/* $10-$17 = a0-a7: Argument registers */
#define REG_A0 REG_X10
#define REG_A1 REG_X11
#define REG_A2 REG_X12
#define REG_A3 REG_X13
#define REG_A4 REG_X14
#define REG_A5 REG_X15
#define REG_A6 REG_X16
#define REG_A7 REG_X17
/* $18-$27 = s2-s11: Callee saved registers */
#define REG_S2 REG_X18
#define REG_S3 REG_X19
#define REG_S4 REG_X20
#define REG_S5 REG_X21
#define REG_S6 REG_X22
#define REG_S7 REG_X23
#define REG_S8 REG_X24
#define REG_S9 REG_X25
#define REG_S10 REG_X26
#define REG_S11 REG_X27
/* $28-$31 = t3-t6: Caller saved temporary registers */
#define REG_T3 REG_X28
#define REG_T4 REG_X29
#define REG_T5 REG_X30
#define REG_T6 REG_X31
/****************************************************************************
* Public Types
****************************************************************************/
#ifndef __ASSEMBLY__
/* This structure represents the return state from a system call */
#ifdef CONFIG_BUILD_KERNEL
struct xcpt_syscall_s
{
uint32_t sysreturn; /* The return PC */
};
#endif
/* The following structure is included in the TCB and defines the complete
* state of the thread.
*/
struct xcptcontext
{
/* The following function pointer is non-NULL if there are pending signals
* to be processed.
*/
void *sigdeliver; /* Actual type is sig_deliver_t */
/* These additional register save locations are used to implement the
* signal delivery trampoline.
*
* REVISIT: Because there is only one copy of these save areas,
* only a single signal handler can be active. This precludes
* queuing of signal actions. As a result, signals received while
* another signal handler is executing will be ignored!
*/
uint32_t saved_epc; /* Trampoline PC */
uint32_t saved_int_ctx; /* Interrupt context with interrupts disabled. */
#ifdef CONFIG_BUILD_KERNEL
/* This is the saved address to use when returning from a user-space
* signal handler.
*/
uint32_t sigreturn;
#endif
#ifdef CONFIG_BUILD_KERNEL
/* The following array holds information needed to return from each nested
* system call.
*/
uint8_t nsyscalls;
struct xcpt_syscall_s syscall[CONFIG_SYS_NNEST];
#endif
/* Register save area */
uint32_t regs[XCPTCONTEXT_REGS];
};
#endif /* __ASSEMBLY__ */
/****************************************************************************
* Public Function Prototypes
****************************************************************************/
#endif /* __ARCH_RISCV_INCLUDE_RV32IM_IRQ_H */
arch/risc-v/include/rv32m1/rv32m1ri5cy_irq.h
+1 -1
View File
@@ -25,7 +25,7 @@
* Included Files
****************************************************************************/
#include <arch/rv32im/mcause.h>
#include <arch/mcause.h>
/****************************************************************************
* Pre-processor Definitions
arch/risc-v/include/rv64gc/irq.h
-468
View File
@@ -1,468 +0,0 @@
/****************************************************************************
* arch/risc-v/include/rv64gc/irq.h
*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership. The
* ASF licenses this file to you under the Apache License, Version 2.0 (the
* "License"); you may not use this file except in compliance with the
* License. You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
* License for the specific language governing permissions and limitations
* under the License.
*
****************************************************************************/
/* This file should never be included directly but, rather, only indirectly
* through nuttx/irq.h
*/
#ifndef __ARCH_RISCV_INCLUDE_RV64GC_IRQ_H
#define __ARCH_RISCV_INCLUDE_RV64GC_IRQ_H
/****************************************************************************
* Included Files
****************************************************************************/
#include <nuttx/config.h>
#include <arch/types.h>
/****************************************************************************
* Pre-processor Definitions
****************************************************************************/
/* Configuration ************************************************************/
/* If this is a kernel build, how many nested system calls should we
* support?
*/
#ifndef CONFIG_SYS_NNEST
# define CONFIG_SYS_NNEST 2
#endif
/* Processor PC */
#define REG_EPC_NDX 0
/* General pupose registers
* $0: Zero register does not need to be saved
* $1: ra (return address)
*/
#define REG_X1_NDX 1
/* $2: Stack POinter
* $3: Global Pointer
* $4: Thread Pointer
*/
#define REG_X2_NDX 2
#define REG_X3_NDX 3
#define REG_X4_NDX 4
/* $5-$7 = t0-t3: Temporary registers */
#define REG_X5_NDX 5
#define REG_X6_NDX 6
#define REG_X7_NDX 7
/* $8: s0 / fp Frame pointer */
#define REG_X8_NDX 8
/* $89 s1 Saved register */
#define REG_X9_NDX 9
/* $10-$17 = a0-a7: Argument registers */
#define REG_X10_NDX 10
#define REG_X11_NDX 11
#define REG_X12_NDX 12
#define REG_X13_NDX 13
#define REG_X14_NDX 14
#define REG_X15_NDX 15
#define REG_X16_NDX 16
#define REG_X17_NDX 17
/* $18-$27 = s2-s11: Saved registers */
#define REG_X18_NDX 18
#define REG_X19_NDX 19
#define REG_X20_NDX 20
#define REG_X21_NDX 21
#define REG_X22_NDX 22
#define REG_X23_NDX 23
#define REG_X24_NDX 24
#define REG_X25_NDX 25
#define REG_X26_NDX 26
#define REG_X27_NDX 27
/* $28-31 = t3-t6: Temporary (Volatile) registers */
#define REG_X28_NDX 28
#define REG_X29_NDX 29
#define REG_X30_NDX 30
#define REG_X31_NDX 31
/* Interrupt Context register */
#define REG_INT_CTX_NDX 32
#ifdef CONFIG_ARCH_RISCV_INTXCPT_EXTREGS
#define INT_XCPT_REGS (33 + CONFIG_ARCH_RISCV_INTXCPT_EXTREGS)
#else
#define INT_XCPT_REGS 33
#endif
#define INT_XCPT_SIZE (8 * INT_XCPT_REGS)
/* FPU REG size in uint64_t */
#ifdef CONFIG_ARCH_FPU
#if defined(CONFIG_ARCH_DPFPU)
# define FPU_REG_SIZE 1
#elif defined(CONFIG_ARCH_QPFPU)
# define FPU_REG_SIZE 2
#else
# error not supported !!!
#endif
# define REG_F0_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 0)
# define REG_F1_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 1)
# define REG_F2_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 2)
# define REG_F3_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 3)
# define REG_F4_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 4)
# define REG_F5_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 5)
# define REG_F6_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 6)
# define REG_F7_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 7)
# define REG_F8_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 8)
# define REG_F9_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 9)
# define REG_F10_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 10)
# define REG_F11_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 11)
# define REG_F12_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 12)
# define REG_F13_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 13)
# define REG_F14_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 14)
# define REG_F15_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 15)
# define REG_F16_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 16)
# define REG_F17_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 17)
# define REG_F18_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 18)
# define REG_F19_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 19)
# define REG_F20_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 20)
# define REG_F21_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 21)
# define REG_F22_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 22)
# define REG_F23_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 23)
# define REG_F24_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 24)
# define REG_F25_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 25)
# define REG_F26_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 26)
# define REG_F27_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 27)
# define REG_F28_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 28)
# define REG_F29_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 29)
# define REG_F30_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 30)
# define REG_F31_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 31)
# define REG_FCSR_NDX (INT_XCPT_REGS + FPU_REG_SIZE * 32)
# define FPU_XCPT_REGS (FPU_REG_SIZE * 33)
#else /* !CONFIG_ARCH_FPU */
# define FPU_XCPT_REGS 0
#endif /* CONFIG_ARCH_FPU */
#define XCPTCONTEXT_REGS (INT_XCPT_REGS + FPU_XCPT_REGS)
#define XCPTCONTEXT_SIZE (8 * XCPTCONTEXT_REGS)
/* In assembly language, values have to be referenced as byte address
* offsets. But in C, it is more convenient to reference registers as
* register save table offsets.
*/
#ifdef __ASSEMBLY__
# define REG_EPC (8*REG_EPC_NDX)
# define REG_X1 (8*REG_X1_NDX)
# define REG_X2 (8*REG_X2_NDX)
# define REG_X3 (8*REG_X3_NDX)
# define REG_X4 (8*REG_X4_NDX)
# define REG_X5 (8*REG_X5_NDX)
# define REG_X6 (8*REG_X6_NDX)
# define REG_X7 (8*REG_X7_NDX)
# define REG_X8 (8*REG_X8_NDX)
# define REG_X9 (8*REG_X9_NDX)
# define REG_X10 (8*REG_X10_NDX)
# define REG_X11 (8*REG_X11_NDX)
# define REG_X12 (8*REG_X12_NDX)
# define REG_X13 (8*REG_X13_NDX)
# define REG_X14 (8*REG_X14_NDX)
# define REG_X15 (8*REG_X15_NDX)
# define REG_X16 (8*REG_X16_NDX)
# define REG_X17 (8*REG_X17_NDX)
# define REG_X18 (8*REG_X18_NDX)
# define REG_X19 (8*REG_X19_NDX)
# define REG_X20 (8*REG_X20_NDX)
# define REG_X21 (8*REG_X21_NDX)
# define REG_X22 (8*REG_X22_NDX)
# define REG_X23 (8*REG_X23_NDX)
# define REG_X24 (8*REG_X24_NDX)
# define REG_X25 (8*REG_X25_NDX)
# define REG_X26 (8*REG_X26_NDX)
# define REG_X27 (8*REG_X27_NDX)
# define REG_X28 (8*REG_X28_NDX)
# define REG_X29 (8*REG_X29_NDX)
# define REG_X30 (8*REG_X30_NDX)
# define REG_X31 (8*REG_X31_NDX)
# define REG_INT_CTX (8*REG_INT_CTX_NDX)
#ifdef CONFIG_ARCH_FPU
# define REG_F0 (8*REG_F0_NDX)
# define REG_F1 (8*REG_F1_NDX)
# define REG_F2 (8*REG_F2_NDX)
# define REG_F3 (8*REG_F3_NDX)
# define REG_F4 (8*REG_F4_NDX)
# define REG_F5 (8*REG_F5_NDX)
# define REG_F6 (8*REG_F6_NDX)
# define REG_F7 (8*REG_F7_NDX)
# define REG_F8 (8*REG_F8_NDX)
# define REG_F9 (8*REG_F9_NDX)
# define REG_F10 (8*REG_F10_NDX)
# define REG_F11 (8*REG_F11_NDX)
# define REG_F12 (8*REG_F12_NDX)
# define REG_F13 (8*REG_F13_NDX)
# define REG_F14 (8*REG_F14_NDX)
# define REG_F15 (8*REG_F15_NDX)
# define REG_F16 (8*REG_F16_NDX)
# define REG_F17 (8*REG_F17_NDX)
# define REG_F18 (8*REG_F18_NDX)
# define REG_F19 (8*REG_F19_NDX)
# define REG_F20 (8*REG_F20_NDX)
# define REG_F21 (8*REG_F21_NDX)
# define REG_F22 (8*REG_F22_NDX)
# define REG_F23 (8*REG_F23_NDX)
# define REG_F24 (8*REG_F24_NDX)
# define REG_F25 (8*REG_F25_NDX)
# define REG_F26 (8*REG_F26_NDX)
# define REG_F27 (8*REG_F27_NDX)
# define REG_F28 (8*REG_F28_NDX)
# define REG_F29 (8*REG_F29_NDX)
# define REG_F30 (8*REG_F30_NDX)
# define REG_F31 (8*REG_F31_NDX)
# define REG_FCSR (8*REG_FCSR_NDX)
#endif
#else
# define REG_EPC REG_EPC_NDX
# define REG_X1 REG_X1_NDX
# define REG_X2 REG_X2_NDX
# define REG_X3 REG_X3_NDX
# define REG_X4 REG_X4_NDX
# define REG_X5 REG_X5_NDX
# define REG_X6 REG_X6_NDX
# define REG_X7 REG_X7_NDX
# define REG_X8 REG_X8_NDX
# define REG_X9 REG_X9_NDX
# define REG_X10 REG_X10_NDX
# define REG_X11 REG_X11_NDX
# define REG_X12 REG_X12_NDX
# define REG_X13 REG_X13_NDX
# define REG_X14 REG_X14_NDX
# define REG_X15 REG_X15_NDX
# define REG_X16 REG_X16_NDX
# define REG_X17 REG_X17_NDX
# define REG_X18 REG_X18_NDX
# define REG_X19 REG_X19_NDX
# define REG_X20 REG_X20_NDX
# define REG_X21 REG_X21_NDX
# define REG_X22 REG_X22_NDX
# define REG_X23 REG_X23_NDX
# define REG_X24 REG_X24_NDX
# define REG_X25 REG_X25_NDX
# define REG_X26 REG_X26_NDX
# define REG_X27 REG_X27_NDX
# define REG_X28 REG_X28_NDX
# define REG_X29 REG_X29_NDX
# define REG_X30 REG_X30_NDX
# define REG_X31 REG_X31_NDX
# define REG_INT_CTX REG_INT_CTX_NDX
#ifdef CONFIG_ARCH_FPU
# define REG_F0 REG_F0_NDX
# define REG_F1 REG_F1_NDX
# define REG_F2 REG_F2_NDX
# define REG_F3 REG_F3_NDX
# define REG_F4 REG_F4_NDX
# define REG_F5 REG_F5_NDX
# define REG_F6 REG_F6_NDX
# define REG_F7 REG_F7_NDX
# define REG_F8 REG_F8_NDX
# define REG_F9 REG_F9_NDX
# define REG_F10 REG_F10_NDX
# define REG_F11 REG_F11_NDX
# define REG_F12 REG_F12_NDX
# define REG_F13 REG_F13_NDX
# define REG_F14 REG_F14_NDX
# define REG_F15 REG_F15_NDX
# define REG_F16 REG_F16_NDX
# define REG_F17 REG_F17_NDX
# define REG_F18 REG_F18_NDX
# define REG_F19 REG_F19_NDX
# define REG_F20 REG_F20_NDX
# define REG_F21 REG_F21_NDX
# define REG_F22 REG_F22_NDX
# define REG_F23 REG_F23_NDX
# define REG_F24 REG_F24_NDX
# define REG_F25 REG_F25_NDX
# define REG_F26 REG_F26_NDX
# define REG_F27 REG_F27_NDX
# define REG_F28 REG_F28_NDX
# define REG_F29 REG_F29_NDX
# define REG_F30 REG_F30_NDX
# define REG_F31 REG_F31_NDX
# define REG_FCSR REG_FCSR_NDX
#endif
#endif
/* Now define more user friendly alternative name that can be used either
* in assembly or C contexts.
*/
/* $1 = ra: Return address */
#define REG_RA REG_X1
/* $2 = sp: The value of the stack pointer on return from the exception */
#define REG_SP REG_X2
/* $3 = gp: Only needs to be saved under conditions where there are
* multiple, per-thread values for the GP.
*/
#define REG_GP REG_X3
/* $4 = tp: Thread Pointer */
#define REG_TP REG_X4
/* $5-$7 = t0-t2: Caller saved temporary registers */
#define REG_T0 REG_X5
#define REG_T1 REG_X6
#define REG_T2 REG_X7
/* $8 = either s0 or fp: Depends if a frame pointer is used or not */
#define REG_S0 REG_X8
#define REG_FP REG_X8
/* $9 = s1: Caller saved register */
#define REG_S1 REG_X9
/* $10-$17 = a0-a7: Argument registers */
#define REG_A0 REG_X10
#define REG_A1 REG_X11
#define REG_A2 REG_X12
#define REG_A3 REG_X13
#define REG_A4 REG_X14
#define REG_A5 REG_X15
#define REG_A6 REG_X16
#define REG_A7 REG_X17
/* $18-$27 = s2-s11: Callee saved registers */
#define REG_S2 REG_X18
#define REG_S3 REG_X19
#define REG_S4 REG_X20
#define REG_S5 REG_X21
#define REG_S6 REG_X22
#define REG_S7 REG_X23
#define REG_S8 REG_X24
#define REG_S9 REG_X25
#define REG_S10 REG_X26
#define REG_S11 REG_X27
/* $28-$31 = t3-t6: Caller saved temporary registers */
#define REG_T3 REG_X28
#define REG_T4 REG_X29
#define REG_T5 REG_X30
#define REG_T6 REG_X31
/****************************************************************************
* Public Types
****************************************************************************/
#ifndef __ASSEMBLY__
/* This structure represents the return state from a system call */
#ifdef CONFIG_LIB_SYSCALL
struct xcpt_syscall_s
{
uint64_t sysreturn; /* The return PC */
#ifdef CONFIG_BUILD_PROTECTED
uint64_t int_ctx; /* Interrupt context (i.e. mstatus) */
#endif
};
#endif
/* The following structure is included in the TCB and defines the complete
* state of the thread.
*/
struct xcptcontext
{
/* The following function pointer is non-NULL if there are pending signals
* to be processed.
*/
void *sigdeliver; /* Actual type is sig_deliver_t */
/* These additional register save locations are used to implement the
* signal delivery trampoline.
*
* REVISIT: Because there is only one copy of these save areas,
* only a single signal handler can be active. This precludes
* queuing of signal actions. As a result, signals received while
* another signal handler is executing will be ignored!
*/
uint64_t saved_epc; /* Trampoline PC */
uint64_t saved_int_ctx; /* Interrupt context with interrupts disabled. */
#ifdef CONFIG_BUILD_PROTECTED
/* This is the saved address to use when returning from a user-space
* signal handler.
*/
uint32_t sigreturn;
#endif
#ifdef CONFIG_LIB_SYSCALL
/* The following array holds information needed to return from each nested
* system call.
*/
uint8_t nsyscalls;
struct xcpt_syscall_s syscall[CONFIG_SYS_NNEST];
#endif
/* Register save area */
uint64_t regs[XCPTCONTEXT_REGS];
};
#endif /* __ASSEMBLY__ */
/****************************************************************************
* Public Function Prototypes
****************************************************************************/
#endif /* __ARCH_RISCV_INCLUDE_RV64GC_IRQ_H */
arch/risc-v/src/bl602/bl602_head.S
+1 -1
View File
@@ -23,7 +23,7 @@
****************************************************************************/
#include <nuttx/config.h>
#include <arch/rv32im/irq.h>
#include <arch/irq.h>
/****************************************************************************
* Public Symbols
arch/risc-v/src/bl602/bl602_irq.c
+1 -1
View File
@@ -88,7 +88,7 @@ void up_irqinitialize(void)
/* currents_regs is non-NULL only while processing an interrupt */
g_current_regs = NULL;
CURRENT_REGS = NULL;
/* Attach the ecall interrupt handler */
arch/risc-v/src/bl602/bl602_irq_dispatch.c
+14 -14
View File
@@ -41,7 +41,7 @@
* Public Data
****************************************************************************/
volatile uint32_t *g_current_regs = NULL;
volatile uintptr_t *g_current_regs[1];
/****************************************************************************
* Public Functions
@@ -51,10 +51,10 @@ volatile uint32_t *g_current_regs = NULL;
* bl602_dispatch_irq
****************************************************************************/
void *bl602_dispatch_irq(uint32_t vector, uint32_t *regs)
void *bl602_dispatch_irq(uintptr_t vector, uintptr_t *regs)
{
uint32_t irq = vector & 0x3ff; /* E24 [9:0] */
uint32_t *mepc = regs;
uintptr_t irq = vector & 0x3ff; /* E24 [9:0] */
uintptr_t *mepc = regs;
/* If current is interrupt */
@@ -67,7 +67,7 @@ void *bl602_dispatch_irq(uint32_t vector, uint32_t *regs)
if (BL602_IRQ_ECALLM == irq)
{
*mepc += 2;
*mepc += 4;
}
/* Acknowledge the interrupt */
@@ -78,13 +78,13 @@ void *bl602_dispatch_irq(uint32_t vector, uint32_t *regs)
PANIC();
#else
/* Current regs non-zero indicates that we are processing an interrupt;
* g_current_regs is also used to manage interrupt level context switches.
* CURRENT_REGS is also used to manage interrupt level context switches.
*
* Nested interrupts are not supported
*/
DEBUGASSERT(g_current_regs == NULL);
g_current_regs = regs;
DEBUGASSERT(CURRENT_REGS == NULL);
CURRENT_REGS = regs;
/* Deliver the IRQ */
@@ -92,18 +92,18 @@ void *bl602_dispatch_irq(uint32_t vector, uint32_t *regs)
#if defined(CONFIG_ARCH_FPU) || defined(CONFIG_ARCH_ADDRENV)
/* Check for a context switch. If a context switch occurred, then
* g_current_regs will have a different value than it did on entry. If an
* CURRENT_REGS will have a different value than it did on entry. If an
* interrupt level context switch has occurred, then restore the floating
* point state and the establish the correct address environment before
* returning from the interrupt.
*/
if (regs != g_current_regs)
if (regs != CURRENT_REGS)
{
#ifdef CONFIG_ARCH_FPU
/* Restore floating point registers */
riscv_restorefpu((uint32_t *)g_current_regs);
riscv_restorefpu((uintptr_t *)CURRENT_REGS);
#endif
#ifdef CONFIG_ARCH_ADDRENV
@@ -121,13 +121,13 @@ void *bl602_dispatch_irq(uint32_t vector, uint32_t *regs)
#endif /* CONFIG_SUPPRESS_INTERRUPTS */
/* If a context switch occurred while processing the interrupt then
* g_current_regs may have change value. If we return any value different
* CURRENT_REGS may have change value. If we return any value different
* from the input regs, then the lower level will know that a context
* switch occurred during interrupt processing.
*/
regs = (uint32_t *)g_current_regs;
g_current_regs = NULL;
regs = (uintptr_t *)CURRENT_REGS;
CURRENT_REGS = NULL;
return regs;
}
arch/risc-v/src/bl602/bl602_start.c
+1 -1
View File
@@ -82,7 +82,7 @@ static struct boot2_partition_table_s g_boot2_partition_table unused_data;
* Public Data
****************************************************************************/
uint32_t g_idle_topstack = 0;
uintptr_t g_idle_topstack;
/****************************************************************************
* Public Functions
arch/risc-v/src/c906/c906_head.S
+1 -1
View File
@@ -24,7 +24,7 @@
#include <nuttx/config.h>
#include <arch/csr.h>
#include <arch/rv64gc/irq.h>
#include <arch/irq.h>
#include "chip.h"
#include "c906_memorymap.h"
arch/risc-v/src/common/riscv_assert.c
+27 -35
View File
@@ -57,14 +57,6 @@
# define CONFIG_BOARD_RESET_ON_ASSERT 0
#endif
/* Format output with register width and hex */
#ifdef CONFIG_ARCH_RV32
# define PRIxREG "%08"PRIxPTR
#else
# define PRIxREG "%016"PRIxPTR
#endif
/****************************************************************************
* Private Functions
****************************************************************************/
@@ -106,35 +98,35 @@ static inline void riscv_registerdump(volatile uintptr_t *regs)
{
/* Are user registers available from interrupt processing? */
_alert("EPC:" PRIxREG "\n", regs[REG_EPC]);
_alert("A0:" PRIxREG " A1:" PRIxREG "A2:" PRIxREG
" A3:" PRIxREG "\n",
_alert("EPC: %" PRIxREG "\n", regs[REG_EPC]);
_alert("A0: %" PRIxREG " A1: %" PRIxREG " A2: %" PRIxREG
" A3: %" PRIxREG "\n",
regs[REG_A0], regs[REG_A1], regs[REG_A2], regs[REG_A3]);
_alert("A4:" PRIxREG " A5:" PRIxREG "A6:" PRIxREG
" A7:" PRIxREG "\n",
_alert("A4: %" PRIxREG " A5: %" PRIxREG " A6: %" PRIxREG
" A7: %" PRIxREG "\n",
regs[REG_A4], regs[REG_A5], regs[REG_A6], regs[REG_A7]);
_alert("T0:" PRIxREG " T1:" PRIxREG " T2:" PRIxREG
" T3:" PRIxREG "\n",
_alert("T0: %" PRIxREG " T1: %" PRIxREG " T2: %" PRIxREG
" T3: %" PRIxREG "\n",
regs[REG_T0], regs[REG_T1], regs[REG_T2], regs[REG_T3]);
_alert("T4:" PRIxREG " T5:" PRIxREG " T6:" PRIxREG "\n",
_alert("T4: %" PRIxREG " T5: %" PRIxREG " T6: %" PRIxREG "\n",
regs[REG_T4], regs[REG_T5], regs[REG_T6]);
_alert("S0:" PRIxREG " S1:" PRIxREG " S2:" PRIxREG
" S3:" PRIxREG "\n",
_alert("S0: %" PRIxREG " S1: %" PRIxREG " S2: %" PRIxREG
" S3: %" PRIxREG "\n",
regs[REG_S0], regs[REG_S1], regs[REG_S2], regs[REG_S3]);
_alert("S4:" PRIxREG " S5:" PRIxREG " S6:" PRIxREG
" S7:" PRIxREG "\n",
_alert("S4: %" PRIxREG " S5: %" PRIxREG " S6: %" PRIxREG
" S7: %" PRIxREG "\n",
regs[REG_S4], regs[REG_S5], regs[REG_S6], regs[REG_S7]);
_alert("S8:" PRIxREG " S9:" PRIxREG " S10:" PRIxREG
" S11:" PRIxREG "\n",
_alert("S8: %" PRIxREG " S9: %" PRIxREG " S10: %" PRIxREG
" S11: %" PRIxREG "\n",
regs[REG_S8], regs[REG_S9], regs[REG_S10], regs[REG_S11]);
#ifdef RISCV_SAVE_GP
_alert("GP:" PRIxREG " SP:" PRIxREG " FP:" PRIxREG
" TP:" PRIxREG " RA:" PRIxREG "\n",
_alert("GP: %" PRIxREG " SP: %" PRIxREG " FP: %" PRIxREG
" TP: %" PRIxREG " RA: %" PRIxREG "\n",
regs[REG_GP], regs[REG_SP], regs[REG_FP], regs[REG_TP],
regs[REG_RA]);
#else
_alert("SP:" PRIxREG " FP:" PRIxREG " TP:" PRIxREG
" RA:" PRIxREG "\n",
_alert("SP: %" PRIxREG " FP: %" PRIxREG " TP: %" PRIxREG
" RA: %" PRIxREG "\n",
regs[REG_SP], regs[REG_FP], regs[REG_TP], regs[REG_RA]);
#endif
}
@@ -338,10 +330,10 @@ static void riscv_dumpstate(void)
/* Show interrupt stack info */
_alert("sp: " PRIxREG "\n", sp);
_alert("sp: %" PRIxREG "\n", sp);
_alert("IRQ stack:\n");
_alert(" base: " PRIxREG "\n", istackbase);
_alert(" size: " PRIxREG "\n", istacksize);
_alert(" base: %" PRIxREG "\n", istackbase);
_alert(" size: %" PRIxREG "\n", istacksize);
/* Does the current stack pointer lie within the interrupt
* stack?
@@ -356,7 +348,7 @@ static void riscv_dumpstate(void)
/* Extract the user stack pointer */
sp = CURRENT_REGS[REG_SP];
_alert("sp: " PRIxREG "\n", sp);
_alert("sp: %" PRIxREG "\n", sp);
}
else if (CURRENT_REGS)
{
@@ -367,12 +359,12 @@ static void riscv_dumpstate(void)
/* Show user stack info */
_alert("User stack:\n");
_alert(" base: " PRIxREG "\n", ustackbase);
_alert(" size: " PRIxREG "\n", ustacksize);
_alert(" base: %" PRIxREG "\n", ustackbase);
_alert(" size: %" PRIxREG "\n", ustacksize);
#else
_alert("sp: " PRIxREG "\n", sp);
_alert("stack base: " PRIxREG "\n", ustackbase);
_alert("stack size: " PRIxREG "\n", ustacksize);
_alert("sp: %" PRIxREG "\n", sp);
_alert("stack base: %" PRIxREG "\n", ustackbase);
_alert("stack size: %" PRIxREG "\n", ustacksize);
#endif
/* Dump the user stack if the stack pointer lies within the allocated user
arch/risc-v/src/common/riscv_backtrace.c
+1 -1
View File
@@ -143,7 +143,7 @@ int up_backtrace(struct tcb_s *tcb, void **buffer, int size, int skip)
{
#if CONFIG_ARCH_INTERRUPTSTACK > 15
ret = backtrace((void *)&g_intstackalloc,
(void *)((uint32_t)&g_intstackalloc +
(void *)((uintptr_t)&g_intstackalloc +
CONFIG_ARCH_INTERRUPTSTACK),
(void *)getfp(), NULL, buffer, size, &skip);
#else
arch/risc-v/src/rv32im/riscv_copyfullstate.c → arch/risc-v/src/common/riscv_copyfullstate.c
+2 -2
View File
@@ -1,5 +1,5 @@
/****************************************************************************
* arch/risc-v/src/rv32im/riscv_copyfullstate.c
* arch/risc-v/src/common/riscv_copyfullstate.c
*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed with
@@ -43,7 +43,7 @@
*
****************************************************************************/
void riscv_copyfullstate(uint32_t *dest, uint32_t *src)
void riscv_copyfullstate(uintptr_t *dest, uintptr_t *src)
{
int i;
arch/risc-v/src/rv32im/riscv_copystate.c → arch/risc-v/src/common/riscv_copystate.c
+3 -3
View File
@@ -1,5 +1,5 @@
/****************************************************************************
* arch/risc-v/src/rv32im/riscv_copystate.c
* arch/risc-v/src/common/riscv_copystate.c
*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed with
@@ -51,12 +51,12 @@
/* A little faster than most memcpy's */
void riscv_copystate(uint32_t *dest, uint32_t *src)
void riscv_copystate(uintptr_t *dest, uintptr_t *src)
{
int i;
#ifdef CONFIG_ARCH_FPU
uint32_t *regs = dest;
uintptr_t *regs = dest;
#endif
/* In the RISC-V model, the state is copied from the stack to the TCB,
arch/risc-v/src/rv32im/riscv_doirq.c → arch/risc-v/src/common/riscv_doirq.c
+12 -12
View File
@@ -1,5 +1,5 @@
/****************************************************************************
* arch/risc-v/src/rv32im/riscv_doirq.c
* arch/risc-v/src/common/riscv_doirq.c
*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed with
@@ -57,20 +57,20 @@
* Public Functions
****************************************************************************/
uint32_t *up_doirq(int irq, uint32_t *regs)
uintptr_t *up_doirq(int irq, uintptr_t *regs)
{
board_autoled_on(LED_INIRQ);
#ifdef CONFIG_SUPPRESS_INTERRUPTS
PANIC();
#else
/* Current regs non-zero indicates that we are processing an interrupt;
* g_current_regs is also used to manage interrupt level context switches.
* CURRENT_REGS is also used to manage interrupt level context switches.
*
* Nested interrupts are not supported
*/
DEBUGASSERT(g_current_regs == NULL);
g_current_regs = regs;
DEBUGASSERT(CURRENT_REGS == NULL);
CURRENT_REGS = regs;
/* Disable further occurrences of this interrupt (until the interrupt
* sources have been clear by the driver).
@@ -84,18 +84,18 @@ uint32_t *up_doirq(int irq, uint32_t *regs)
#if defined(CONFIG_ARCH_FPU) || defined(CONFIG_ARCH_ADDRENV)
/* Check for a context switch. If a context switch occurred, then
* g_current_regs will have a different value than it did on entry. If an
* CURRENT_REGS will have a different value than it did on entry. If an
* interrupt level context switch has occurred, then restore the floating
* point state and the establish the correct address environment before
* returning from the interrupt.
*/
if (regs != g_current_regs)
if (regs != CURRENT_REGS)
{
#ifdef CONFIG_ARCH_FPU
/* Restore floating point registers */
riscv_restorefpu((uint32_t *)g_current_regs);
riscv_restorefpu((uintptr_t *)CURRENT_REGS);
#endif
#ifdef CONFIG_ARCH_ADDRENV
@@ -111,18 +111,18 @@ uint32_t *up_doirq(int irq, uint32_t *regs)
#endif
/* If a context switch occurred while processing the interrupt then
* g_current_regs may have change value. If we return any value different
* CURRENT_REGS may have change value. If we return any value different
* from the input regs, then the lower level will know that a context
* switch occurred during interrupt processing.
*/
regs = (uint32_t *)g_current_regs;
regs = (uintptr_t *)CURRENT_REGS;
/* Set g_current_regs to NULL to indicate that we are no longer in an
/* Set CURRENT_REGS to NULL to indicate that we are no longer in an
* interrupt handler.
*/
g_current_regs = NULL;
CURRENT_REGS = NULL;
/* Unmask the last interrupt (global interrupts are still disabled) */
arch/risc-v/src/rv32im/riscv_exception.c → arch/risc-v/src/common/riscv_exception.c
+5 -5
View File
@@ -1,5 +1,5 @@
/****************************************************************************
* arch/risc-v/src/rv32im/riscv_exception.c
* arch/risc-v/src/common/riscv_exception.c
*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed with
@@ -33,7 +33,7 @@
#include <nuttx/arch.h>
#include <nuttx/board.h>
#include <nuttx/syslog/syslog.h>
#include <arch/rv32im/mcause.h>
#include <arch/mcause.h>
#include "riscv_arch.h"
#include "riscv_internal.h"
@@ -72,9 +72,9 @@ static const char *g_reasons_str[MCAUSE_MAX_EXCEPTION + 1] =
*
****************************************************************************/
void riscv_exception(uint32_t mcause, uint32_t *regs)
void riscv_exception(uintptr_t mcause, uintptr_t *regs)
{
uint32_t cause = mcause & MCAUSE_INTERRUPT_MASK;
uintptr_t cause = mcause & MCAUSE_INTERRUPT_MASK;
#ifdef CONFIG_DEBUG_INFO
if (mcause > MCAUSE_MAX_EXCEPTION)
@@ -90,7 +90,7 @@ void riscv_exception(uint32_t mcause, uint32_t *regs)
_alert("PANIC!!! Exception = %08" PRIx32 "\n", cause);
up_irq_save();
g_current_regs = regs;
CURRENT_REGS = regs;
PANIC();
}
arch/risc-v/src/rv64gc/riscv_fault.c → arch/risc-v/src/common/riscv_fault.c
+21 -21
View File
@@ -1,5 +1,5 @@
/****************************************************************************
* arch/risc-v/src/rv64gc/riscv_fault.c
* arch/risc-v/src/common/riscv_fault.c
*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed with
@@ -54,61 +54,61 @@
*
****************************************************************************/
void up_fault(int irq, uint64_t *regs)
void up_fault(int irq, uintptr_t *regs)
{
CURRENT_REGS = regs;
_alert("EPC:%016" PRIx64 "\n",
_alert("EPC: %" PRIxREG "\n",
CURRENT_REGS[REG_EPC]);
_alert("Fault IRQ=%d\n", irq);
/* Dump register info */
_alert("A0:%016" PRIx64 " A1:%016" PRIx64 " A2:%016" PRIx64
" A3:%016" PRIx64 "\n",
_alert("A0: %" PRIxREG " A1: %" PRIxREG " A2: %" PRIxREG
" A3: %" PRIxREG "\n",
CURRENT_REGS[REG_A0], CURRENT_REGS[REG_A1],
CURRENT_REGS[REG_A2], CURRENT_REGS[REG_A3]);
_alert("A4:%016" PRIx64 " A5:%016" PRIx64 " A6:%016" PRIx64
" A7:%016" PRIx64 "\n",
_alert("A4: %" PRIxREG " A5: %" PRIxREG " A6: %" PRIxREG
" A7: %" PRIxREG "\n",
CURRENT_REGS[REG_A4], CURRENT_REGS[REG_A5],
CURRENT_REGS[REG_A6], CURRENT_REGS[REG_A7]);
_alert("T0:%016" PRIx64 " T1:%016" PRIx64 " T2:%016" PRIx64
" T3:%016" PRIx64 "\n",
_alert("T0: %" PRIxREG " T1: %" PRIxREG " T2: %" PRIxREG
" T3: %" PRIxREG "\n",
CURRENT_REGS[REG_T0], CURRENT_REGS[REG_T1],
CURRENT_REGS[REG_T2], CURRENT_REGS[REG_T3]);
_alert("T4:%016" PRIx64 " T5:%016" PRIx64
" T6:%016" PRIx64 "\n",
_alert("T4: %" PRIxREG " T5: %" PRIxREG
" T6: %" PRIxREG "\n",
CURRENT_REGS[REG_T4], CURRENT_REGS[REG_T5],
CURRENT_REGS[REG_T6]);
_alert("S0:%016" PRIx64 " S1:%016" PRIx64 " S2:%016" PRIx64
" S3:%016" PRIx64 "\n",
_alert("S0: %" PRIxREG " S1: %" PRIxREG " S2: %" PRIxREG
" S3: %" PRIxREG "\n",
CURRENT_REGS[REG_S0], CURRENT_REGS[REG_S1],
CURRENT_REGS[REG_S2], CURRENT_REGS[REG_S3]);
_alert("S4:%016" PRIx64 " S5:%016" PRIx64 " S6:%016" PRIx64
" S7:%016" PRIx64 "\n",
_alert("S4: %" PRIxREG " S5: %" PRIxREG " S6: %" PRIxREG
" S7: %" PRIxREG "\n",
CURRENT_REGS[REG_S4], CURRENT_REGS[REG_S5],
CURRENT_REGS[REG_S6], CURRENT_REGS[REG_S7]);
_alert("S8:%016" PRIx64 " S9:%016" PRIx64 " S10:%016" PRIx64
" S11:%016" PRIx64 "\n",
_alert("S8: %" PRIxREG " S9: %" PRIxREG " S10: %" PRIxREG
" S11: %" PRIxREG "\n",
CURRENT_REGS[REG_S8], CURRENT_REGS[REG_S9],
CURRENT_REGS[REG_S10], CURRENT_REGS[REG_S11]);
#ifdef RISCV_SAVE_GP
_alert("GP:%016" PRIx64 " SP:%016" PRIx64 " FP:%016" PRIx64
" TP:%016 " PRIx64 "RA:%016" PRIx64 "\n",
_alert("GP: %" PRIxREG " SP: %" PRIxREG " FP: %" PRIxREG
" TP: %" PRIxREG "RA: %" PRIxREG "\n",
CURRENT_REGS[REG_GP], CURRENT_REGS[REG_SP],
CURRENT_REGS[REG_FP], CURRENT_REGS[REG_TP],
CURRENT_REGS[REG_RA]);
#else
_alert("SP:%016" PRIx64 " FP:%016" PRIx64 " TP:%016" PRIx64
" RA:%016" PRIx64 "\n",
_alert("SP: %" PRIxREG " FP: %" PRIxREG " TP: %" PRIxREG
" RA: %" PRIxREG "\n",
CURRENT_REGS[REG_SP], CURRENT_REGS[REG_FP],
CURRENT_REGS[REG_TP], CURRENT_REGS[REG_RA]);
#endif
arch/risc-v/src/common/riscv_fpu.S
+1 -5
View File
@@ -24,11 +24,7 @@
#include <nuttx/config.h>
#ifdef CONFIG_ARCH_RV32
#include <arch/rv32im/irq.h>
#else
#include <arch/rv64gc/irq.h>
#endif
#include <arch/irq.h>
#ifdef CONFIG_ARCH_FPU
arch/risc-v/src/common/riscv_internal.h
+16 -29
View File
@@ -45,17 +45,20 @@
#define INTSTACK_COLOR 0xdeadbeef
#define HEAP_COLOR 'h'
/* Format output with register width and hex */
#ifdef CONFIG_ARCH_RV32
# define PRIxREG "08" PRIxPTR
#else
# define PRIxREG "016" PRIxPTR
#endif
/* In the RISC_V model, the state is copied from the stack to the TCB, but
* only a referenced is passed to get the state from the TCB.
*/
#ifdef CONFIG_ARCH_RV64
#define riscv_savestate(regs) riscv_copystate(regs, (uint64_t*)CURRENT_REGS)
#define riscv_savestate(regs) riscv_copystate(regs, (uintptr_t*)CURRENT_REGS)
#define riscv_restorestate(regs) (CURRENT_REGS = regs)
#else
#define riscv_savestate(regs) riscv_copystate(regs, (uint32_t*)g_current_regs)
#define riscv_restorestate(regs) (g_current_regs = regs)
#endif
#define _START_TEXT &_stext
#define _END_TEXT &_etext
@@ -101,20 +104,14 @@ extern "C"
#endif
#ifndef __ASSEMBLY__
#ifdef CONFIG_ARCH_RV64
#ifdef CONFIG_SMP
EXTERN volatile uint64_t *g_current_regs[CONFIG_SMP_NCPUS];
EXTERN volatile uintptr_t *g_current_regs[CONFIG_SMP_NCPUS];
# define CURRENT_REGS (g_current_regs[up_cpu_index()])
#else
EXTERN volatile uint64_t *g_current_regs[1];
EXTERN volatile uintptr_t *g_current_regs[1];
# define CURRENT_REGS (g_current_regs[0])
#endif
EXTERN uintptr_t g_idle_topstack;
#else
EXTERN volatile uint32_t *g_current_regs;
# define CURRENT_REGS (g_current_regs)
EXTERN uint32_t g_idle_topstack;
#endif
/* Address of the saved user stack pointer */
@@ -167,26 +164,16 @@ void riscv_addregion(void);
void riscv_ack_irq(int irq);
#ifdef CONFIG_ARCH_RV64
void riscv_copystate(uint64_t *dest, uint64_t *src);
void riscv_copyfullstate(uint64_t *dest, uint64_t *src);
#else
void riscv_copystate(uint32_t *dest, uint32_t *src);
void riscv_copyfullstate(uint32_t *dest, uint32_t *src);
#endif
void riscv_copystate(uintptr_t *dest, uintptr_t *src);
void riscv_copyfullstate(uintptr_t *dest, uintptr_t *src);
void riscv_sigdeliver(void);
int riscv_swint(int irq, void *context, void *arg);
uint32_t riscv_get_newintctx(void);
#ifdef CONFIG_ARCH_FPU
#ifdef CONFIG_ARCH_RV64
void riscv_savefpu(uint64_t *regs);
void riscv_restorefpu(const uint64_t *regs);
#else /* !CONFIG_ARCH_RV64 */
void riscv_savefpu(uint32_t *regs);
void riscv_restorefpu(const uint32_t *regs);
#endif /* CONFIG_ARCH_RV64 */
void riscv_savefpu(uintptr_t *regs);
void riscv_restorefpu(const uintptr_t *regs);
#else
# define riscv_savefpu(regs)
# define riscv_restorefpu(regs)
@@ -224,7 +211,7 @@ void rpmsg_serialinit(void);
/* Exception Handler ********************************************************/
void riscv_exception(uint32_t mcause, uint32_t *regs);
void riscv_exception(uintptr_t mcause, uintptr_t *regs);
/* Debug ********************************************************************/
arch/risc-v/src/common/riscv_interruptcontext.c
+1 -1
View File
@@ -64,6 +64,6 @@ bool up_interrupt_context(void)
return ret;
#else
return g_current_regs != NULL;
return CURRENT_REGS != NULL;
#endif
}
arch/risc-v/src/rv64gc/riscv_schedulesigaction.c → arch/risc-v/src/common/riscv_schedulesigaction.c
+7 -7
View File
@@ -1,5 +1,5 @@
/****************************************************************************
* arch/risc-v/src/rv64gc/riscv_schedulesigaction.c
* arch/risc-v/src/common/riscv_schedulesigaction.c
*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed with
@@ -80,7 +80,7 @@
#ifndef CONFIG_SMP
void up_schedule_sigaction(struct tcb_s *tcb, sig_deliver_t sigdeliver)
{
uint64_t int_ctx;
uintptr_t int_ctx;
sinfo("tcb=0x%p sigdeliver=0x%p\n", tcb, sigdeliver);
@@ -152,8 +152,8 @@ void up_schedule_sigaction(struct tcb_s *tcb, sig_deliver_t sigdeliver)
riscv_savestate(tcb->xcp.regs);
sinfo("PC/STATUS Saved: %016" PRIx64 "/%016" PRIx64
" New: %016" PRIx64 "/%016" PRIx64 "\n",
sinfo("PC/STATUS Saved: %" PRIxREG "/%" PRIxREG
" New: %" PRIxREG "/%" PRIxREG "\n",
tcb->xcp.saved_epc, tcb->xcp.saved_int_ctx,
CURRENT_REGS[REG_EPC], CURRENT_REGS[REG_INT_CTX]);
}
@@ -188,8 +188,8 @@ void up_schedule_sigaction(struct tcb_s *tcb, sig_deliver_t sigdeliver)
tcb->xcp.regs[REG_INT_CTX] = int_ctx;
sinfo("PC/STATUS Saved: %016" PRIx64 "/%016" PRIx64
" New: %016" PRIx64 "/%016" PRIx64 "\n",
sinfo("PC/STATUS Saved: %" PRIxREG "/%" PRIxREG
" New: %" PRIxREG "/%" PRIxREG "\n",
tcb->xcp.saved_epc, tcb->xcp.saved_int_ctx,
tcb->xcp.regs[REG_EPC], tcb->xcp.regs[REG_INT_CTX]);
}
@@ -200,7 +200,7 @@ void up_schedule_sigaction(struct tcb_s *tcb, sig_deliver_t sigdeliver)
#ifdef CONFIG_SMP
void up_schedule_sigaction(struct tcb_s *tcb, sig_deliver_t sigdeliver)
{
uint64_t int_ctx;
uintptr_t int_ctx;
int cpu;
int me;
arch/risc-v/src/rv64gc/riscv_sigdeliver.c → arch/risc-v/src/common/riscv_sigdeliver.c
+3 -3
View File
@@ -1,5 +1,5 @@
/****************************************************************************
* arch/risc-v/src/rv64gc/riscv_sigdeliver.c
* arch/risc-v/src/common/riscv_sigdeliver.c
*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed with
@@ -57,7 +57,7 @@
void riscv_sigdeliver(void)
{
struct tcb_s *rtcb = this_task();
uint64_t regs[XCPTCONTEXT_REGS];
uintptr_t regs[XCPTCONTEXT_REGS];
#ifdef CONFIG_SMP
/* In the SMP case, we must terminate the critical section while the signal
@@ -115,7 +115,7 @@ void riscv_sigdeliver(void)
* errno that is needed by the user logic (it is probably EINTR).
*/
sinfo("Resuming EPC: %016" PRIx64 " INT_CTX: %016" PRIx64 "\n",
sinfo("Resuming EPC: %" PRIxREG " INT_CTX: %" PRIxREG "\n",
regs[REG_EPC], regs[REG_INT_CTX]);
#ifdef CONFIG_SMP
arch/risc-v/src/rv64gc/riscv_signal_dispatch.c → arch/risc-v/src/common/riscv_signal_dispatch.c
View File
arch/risc-v/src/rv64gc/riscv_signal_handler.S → arch/risc-v/src/common/riscv_signal_handler.S
View File
arch/risc-v/src/rv64gc/riscv_swint.c → arch/risc-v/src/common/riscv_swint.c
+48 -17
View File
@@ -1,5 +1,5 @@
/****************************************************************************
* arch/risc-v/src/rv64gc/riscv_swint.c
* arch/risc-v/src/common/riscv_swint.c
*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed with
@@ -42,6 +42,10 @@
#include "svcall.h"
#include "riscv_internal.h"
/****************************************************************************
* Pre-processor Definitions
****************************************************************************/
/****************************************************************************
* Private Functions
****************************************************************************/
@@ -51,29 +55,35 @@
****************************************************************************/
#ifdef CONFIG_DEBUG_SYSCALL_INFO
static void riscv_registerdump(const uint64_t *regs)
static void riscv_registerdump(const uintptr_t *regs)
{
svcinfo("EPC:%08x\n",
svcinfo("EPC: %" PRIxREG "\n",
regs[REG_EPC]);
svcinfo("A0:%08x A1:%08x A2:%08x A3:%08x A4:%08x A5:%08x "
"A6:%08x A7:%08x\n",
svcinfo("A0: %" PRIxREG " A1: %" PRIxREG " A2: %" PRIxREG " A3: %" PRIxREG
" A4: %" PRIxREG " A5: %" PRIxREG " A6: %" PRIxREG " A7: %" PRIxREG
"\n",
regs[REG_A0], regs[REG_A1], regs[REG_A2], regs[REG_A3],
regs[REG_A4], regs[REG_A5], regs[REG_A6], regs[REG_A7]);
svcinfo("T0:%08x T1:%08x T2:%08x T3:%08x T4:%08x T5:%08x T6:%08x\n",
svcinfo("T0: %" PRIxREG " T1: %" PRIxREG " T2: %" PRIxREG " T3: %" PRIxREG
" T4: %" PRIxREG " T5: %" PRIxREG " T6: %" PRIxREG "\n",
regs[REG_T0], regs[REG_T1], regs[REG_T2], regs[REG_T3],
regs[REG_T4], regs[REG_T5], regs[REG_T6]);
svcinfo("S0:%08x S1:%08x S2:%08x S3:%08x S4:%08x S5:%08x "
"S6:%08x S7:%08x\n",
svcinfo("S0: %" PRIxREG " S1: %" PRIxREG " S2: %" PRIxREG " S3: %" PRIxREG
" S4: %" PRIxREG " S5: %" PRIxREG " S6: %" PRIxREG " S7: %" PRIxREG
"\n",
regs[REG_S0], regs[REG_S1], regs[REG_S2], regs[REG_S3],
regs[REG_S4], regs[REG_S5], regs[REG_S6], regs[REG_S7]);
svcinfo("S8:%08x S9:%08x S10:%08x S11:%08x\n",
svcinfo("S8: %" PRIxREG " S9: %" PRIxREG " S10: %"PRIxREG
" S11: %" PRIxREG "\n",
regs[REG_S8], regs[REG_S9], regs[REG_S10], regs[REG_S11]);
#ifdef RISCV_SAVE_GP
svcinfo("GP:%08x SP:%08x FP:%08x TP:%08x RA:%08x\n",
svcinfo("GP: %" PRIxREG " SP: %" PRIxREG " FP: %" PRIxREG
" TP: %" PRIxREG " RA: %" PRIxREG "\n",
regs[REG_GP], regs[REG_SP], regs[REG_FP], regs[REG_TP],
regs[REG_RA]);
#else
svcinfo("SP:%08x FP:%08x TP:%08x RA:%08x\n",
svcinfo("SP: %" PRIxREG " FP: %" PRIxREG " TP: %" PRIxREG " RA: %" PRIxREG
"\n",
regs[REG_SP], regs[REG_FP], regs[REG_TP], regs[REG_RA]);
#endif
}
@@ -98,6 +108,7 @@ static void riscv_registerdump(const uint64_t *regs)
#ifdef CONFIG_LIB_SYSCALL
static void dispatch_syscall(void) naked_function;
#ifdef CONFIG_ARCH_RV64
static void dispatch_syscall(void)
{
asm volatile
@@ -116,6 +127,26 @@ static void dispatch_syscall(void)
" ecall" /* Return from the syscall */
);
}
#else
static void dispatch_syscall(void)
{
asm volatile
(
" addi sp, sp, -4\n" /* Create a stack frame to hold ra */
" sw ra, 0(sp)\n" /* Save ra in the stack frame */
" la t0, g_stublookup\n" /* t0=The base of the stub lookup table */
" slli a0, a0, 3\n" /* a0=Offset for the stub lookup table */
" add t0, t0, a0\n" /* t0=The address in the table */
" lw t0, 0(t0)\n" /* t0=The address of the stub for this syscall */
" jalr ra, t0\n" /* Call the stub (modifies ra) */
" lw ra, 0(sp)\n" /* Restore ra */
" addi sp, sp, 4\n" /* Destroy the stack frame */
" mv a2, a0\n" /* a2=Save return value in a0 */
" li a0, 3\n" /* a0=SYS_syscall_return (3) */
" ecall" /* Return from the syscall */
);
}
#endif
#endif
/****************************************************************************
@@ -133,7 +164,7 @@ static void dispatch_syscall(void)
int riscv_swint(int irq, void *context, void *arg)
{
uint64_t *regs = (uint64_t *)context;
uintptr_t *regs = (uintptr_t *)context;
DEBUGASSERT(regs && regs == CURRENT_REGS);
@@ -170,7 +201,7 @@ int riscv_swint(int irq, void *context, void *arg)
case SYS_restore_context:
{
DEBUGASSERT(regs[REG_A1] != 0);
CURRENT_REGS = (uint64_t *)regs[REG_A1];
CURRENT_REGS = (uintptr_t *)regs[REG_A1];
}
break;
@@ -193,8 +224,8 @@ int riscv_swint(int irq, void *context, void *arg)
case SYS_switch_context:
{
DEBUGASSERT(regs[REG_A1] != 0 && regs[REG_A2] != 0);
riscv_copystate((uint64_t *)regs[REG_A1], regs);
CURRENT_REGS = (uint64_t *)regs[REG_A2];
riscv_copystate((uintptr_t *)regs[REG_A1], regs);
CURRENT_REGS = (uintptr_t *)regs[REG_A2];
}
break;
@@ -455,7 +486,7 @@ int riscv_swint(int irq, void *context, void *arg)
rtcb->flags |= TCB_FLAG_SYSCALL;
#else
svcerr("ERROR: Bad SYS call: %" PRId64 "\n", regs[REG_A0]);
svcerr("ERROR: Bad SYS call: %" PRIdPTR "\n", regs[REG_A0]);
#endif
}
break;
@@ -469,7 +500,7 @@ int riscv_swint(int irq, void *context, void *arg)
if (regs != CURRENT_REGS)
{
svcinfo("SWInt Return: Context switch!\n");
riscv_registerdump((const uint32_t *)CURRENT_REGS);
riscv_registerdump((const uintptr_t *)CURRENT_REGS);
}
else
{
arch/risc-v/src/rv32im/riscv_vfork.c → arch/risc-v/src/common/riscv_vfork.c
View File
arch/risc-v/src/rv32im/riscv_vfork.h → arch/risc-v/src/common/riscv_vfork.h
View File
arch/risc-v/src/rv64gc/svcall.h → arch/risc-v/src/common/svcall.h
View File
arch/risc-v/src/esp32c3/esp32c3_head.S
+1 -1
View File
@@ -23,7 +23,7 @@
****************************************************************************/
#include <nuttx/config.h>
#include <arch/rv32im/irq.h>
#include <arch/irq.h>
#include "chip.h"
arch/risc-v/src/esp32c3/esp32c3_interrupt.S
+1 -1
View File
@@ -23,7 +23,7 @@
****************************************************************************/
#include <nuttx/config.h>
#include <arch/rv32im/irq.h>
#include <arch/irq.h>
#include "chip.h"
arch/risc-v/src/esp32c3/esp32c3_irq.c
+9 -9
View File
@@ -34,7 +34,7 @@
#include <arch/board/board.h>
#include <arch/irq.h>
#include <arch/rv32im/mcause.h>
#include <arch/mcause.h>
#include "riscv_internal.h"
#include "hardware/esp32c3_interrupt.h"
@@ -60,7 +60,7 @@
* Public Data
****************************************************************************/
volatile uint32_t *g_current_regs;
volatile uintptr_t *g_current_regs[1];
/****************************************************************************
* Private Data
@@ -373,7 +373,7 @@ void esp32c3_free_cpuint(uint8_t periphid)
*
****************************************************************************/
IRAM_ATTR uint32_t *esp32c3_dispatch_irq(uint32_t mcause, uint32_t *regs)
IRAM_ATTR uintptr_t *esp32c3_dispatch_irq(uintptr_t mcause, uintptr_t *regs)
{
int irq;
@@ -390,14 +390,14 @@ IRAM_ATTR uint32_t *esp32c3_dispatch_irq(uint32_t mcause, uint32_t *regs)
}
else
{
/* Check "g_current_regs" only in interrupt or ecall */
/* Check "CURRENT_REGS" only in interrupt or ecall */
DEBUGASSERT(g_current_regs == NULL);
DEBUGASSERT(CURRENT_REGS == NULL);
}
g_current_regs = regs;
CURRENT_REGS = regs;
irqinfo("INFO: mcause=%08" PRIX32 "\n", mcause);
irqinfo("INFO: mcause=%08" PRIXPTR "\n", mcause);
/* If the board supports LEDs, turn on an LED now to indicate that we are
* processing an interrupt.
@@ -436,8 +436,8 @@ IRAM_ATTR uint32_t *esp32c3_dispatch_irq(uint32_t mcause, uint32_t *regs)
}
}
regs = (uint32_t *)g_current_regs;
g_current_regs = NULL;
regs = (uintptr_t *)CURRENT_REGS;
CURRENT_REGS = NULL;
board_autoled_off(LED_INIRQ);
arch/risc-v/src/esp32c3/esp32c3_irq.h
+1 -1
View File
@@ -116,6 +116,6 @@ void esp32c3_free_cpuint(uint8_t periphid);
*
****************************************************************************/
uint32_t *esp32c3_dispatch_irq(uint32_t mcause, uint32_t *regs);
uintptr_t *esp32c3_dispatch_irq(uintptr_t mcause, uintptr_t *regs);
#endif /* __ARCH_RISCV_SRC_ESP32C3_ESP32C3_IRQ_H */
arch/risc-v/src/esp32c3/esp32c3_start.c
+1 -1
View File
@@ -125,7 +125,7 @@ HDR_ATTR static void (*_entry_point)(void) = &__start;
uint8_t g_idlestack[CONFIG_IDLETHREAD_STACKSIZE]
aligned_data(16) locate_data(".noinit");
uint32_t g_idle_topstack = ESP32C3_IDLESTACK_TOP;
uintptr_t g_idle_topstack = ESP32C3_IDLESTACK_TOP;
/****************************************************************************
* Private Functions
arch/risc-v/src/esp32c3/esp32c3_vectors.S
+1 -1
View File
@@ -23,7 +23,7 @@
****************************************************************************/
#include <nuttx/config.h>
#include <arch/rv32im/irq.h>
#include <arch/irq.h>
#include <arch/esp32c3/irq.h>
#include "chip.h"
arch/risc-v/src/fe310/fe310_head.S
+1 -1
View File
@@ -23,7 +23,7 @@
****************************************************************************/
#include <nuttx/config.h>
#include <arch/rv32im/irq.h>
#include <arch/irq.h>
#include "chip.h"
#include "fe310_memorymap.h"
arch/risc-v/src/fe310/fe310_irq.c
+1 -1
View File
@@ -80,7 +80,7 @@ void up_irqinitialize(void)
/* currents_regs is non-NULL only while processing an interrupt */
g_current_regs = NULL;
CURRENT_REGS = NULL;
/* Attach the ecall interrupt handler */
arch/risc-v/src/fe310/fe310_irq_dispatch.c
+11 -11
View File
@@ -42,7 +42,7 @@
* Public Data
****************************************************************************/
volatile uint32_t * g_current_regs;
volatile uintptr_t *g_current_regs[1];
/****************************************************************************
* Public Functions
@@ -52,10 +52,10 @@ volatile uint32_t * g_current_regs;
* fe310_dispatch_irq
****************************************************************************/
void *fe310_dispatch_irq(uint32_t vector, uint32_t *regs)
void *fe310_dispatch_irq(uintptr_t vector, uintptr_t *regs)
{
uint32_t irq = (vector >> 27) | (vector & 0xf);
uint32_t *mepc = regs;
uintptr_t irq = (vector >> 27) | (vector & 0xf);
uintptr_t *mepc = regs;
/* Firstly, check if the irq is machine external interrupt */
@@ -72,7 +72,7 @@ void *fe310_dispatch_irq(uint32_t vector, uint32_t *regs)
if (FE310_IRQ_ECALLM == irq)
{
*mepc += 2;
*mepc += 4;
}
/* Acknowledge the interrupt */
@@ -83,13 +83,13 @@ void *fe310_dispatch_irq(uint32_t vector, uint32_t *regs)
PANIC();
#else
/* Current regs non-zero indicates that we are processing an interrupt;
* g_current_regs is also used to manage interrupt level context switches.
* CURRENT_REGS is also used to manage interrupt level context switches.
*
* Nested interrupts are not supported
*/
DEBUGASSERT(g_current_regs == NULL);
g_current_regs = regs;
DEBUGASSERT(CURRENT_REGS == NULL);
CURRENT_REGS = regs;
/* Deliver the IRQ */
@@ -111,13 +111,13 @@ void *fe310_dispatch_irq(uint32_t vector, uint32_t *regs)
#endif
/* If a context switch occurred while processing the interrupt then
* g_current_regs may have change value. If we return any value different
* CURRENT_REGS may have change value. If we return any value different
* from the input regs, then the lower level will know that a context
* switch occurred during interrupt processing.
*/
regs = (uint32_t *)g_current_regs;
g_current_regs = NULL;
regs = (uintptr_t *)CURRENT_REGS;
CURRENT_REGS = NULL;
return regs;
}
arch/risc-v/src/fe310/fe310_start.c
+1 -1
View File
@@ -57,7 +57,7 @@
* address.
*/
uint32_t g_idle_topstack = FE310_IDLESTACK_TOP;
uintptr_t g_idle_topstack = FE310_IDLESTACK_TOP;
/****************************************************************************
* Public Functions
arch/risc-v/src/k210/k210_head.S
+1 -1
View File
@@ -23,7 +23,7 @@
****************************************************************************/
#include <nuttx/config.h>
#include <arch/rv64gc/irq.h>
#include <arch/irq.h>
#include "chip.h"
#include "k210_memorymap.h"
arch/risc-v/src/k210/k210_irq.c
+2 -2
View File
@@ -46,9 +46,9 @@
* such value for each processor that can receive an interrupt.
*/
volatile uint64_t *g_current_regs[CONFIG_SMP_NCPUS];
volatile uintptr_t *g_current_regs[CONFIG_SMP_NCPUS];
#else
volatile uint64_t *g_current_regs[1];
volatile uintptr_t *g_current_regs[1];
#endif
#ifdef CONFIG_SMP
arch/risc-v/src/k210/k210_irq_dispatch.c
+5 -5
View File
@@ -41,7 +41,7 @@
* Public Data
****************************************************************************/
extern void up_fault(int irq, uint64_t *regs);
extern void up_fault(int irq, uintptr_t *regs);
/****************************************************************************
* Public Functions
@@ -51,10 +51,10 @@ extern void up_fault(int irq, uint64_t *regs);
* k210_dispatch_irq
****************************************************************************/
void *k210_dispatch_irq(uint64_t vector, uint64_t *regs)
void *k210_dispatch_irq(uintptr_t vector, uintptr_t *regs)
{
uint32_t irq = (vector >> (27 + 32)) | (vector & 0xf);
uint64_t *mepc = regs;
uintptr_t irq = (vector >> (27 + 32)) | (vector & 0xf);
uintptr_t *mepc = regs;
/* Check if fault happened */
@@ -120,7 +120,7 @@ void *k210_dispatch_irq(uint64_t vector, uint64_t *regs)
* switch occurred during interrupt processing.
*/
regs = (uint64_t *)CURRENT_REGS;
regs = (uintptr_t *)CURRENT_REGS;
CURRENT_REGS = NULL;
return regs;
arch/risc-v/src/litex/litex_head.S
+1 -1
View File
@@ -23,7 +23,7 @@
****************************************************************************/
#include <nuttx/config.h>
#include <arch/rv32im/irq.h>
#include <arch/irq.h>
#include "chip.h"
arch/risc-v/src/litex/litex_irq.c
+1 -1
View File
@@ -68,7 +68,7 @@ void up_irqinitialize(void)
/* currents_regs is non-NULL only while processing an interrupt */
g_current_regs = NULL;
CURRENT_REGS = NULL;
/* Attach the ecall interrupt handler */
arch/risc-v/src/litex/litex_irq_dispatch.c
+10 -10
View File
@@ -41,7 +41,7 @@
* Public Data
****************************************************************************/
volatile uint32_t * g_current_regs;
volatile uintptr_t *g_current_regs[1];
/****************************************************************************
* Public Functions
@@ -51,10 +51,10 @@ volatile uint32_t * g_current_regs;
* litex_dispatch_irq
****************************************************************************/
void *litex_dispatch_irq(uint32_t vector, uint32_t *regs)
void *litex_dispatch_irq(uintptr_t vector, uintptr_t *regs)
{
uint32_t irq = (vector >> 27) | (vector & 0xf);
uint32_t *mepc = regs;
uintptr_t irq = (vector >> 27) | (vector & 0xf);
uintptr_t *mepc = regs;
int i;
/* Firstly, check if the irq is machine external interrupt */
@@ -99,13 +99,13 @@ void *litex_dispatch_irq(uint32_t vector, uint32_t *regs)
PANIC();
#else
/* Current regs non-zero indicates that we are processing an interrupt;
* g_current_regs is also used to manage interrupt level context switches.
* CURRENT_REGS is also used to manage interrupt level context switches.
*
* Nested interrupts are not supported
*/
DEBUGASSERT(g_current_regs == NULL);
g_current_regs = regs;
DEBUGASSERT(CURRENT_REGS == NULL);
CURRENT_REGS = regs;
/* Deliver the IRQ */
@@ -114,13 +114,13 @@ void *litex_dispatch_irq(uint32_t vector, uint32_t *regs)
#endif
/* If a context switch occurred while processing the interrupt then
* g_current_regs may have change value. If we return any value different
* CURRENT_REGS may have change value. If we return any value different
* from the input regs, then the lower level will know that a context
* switch occurred during interrupt processing.
*/
regs = (uint32_t *)g_current_regs;
g_current_regs = NULL;
regs = (uintptr_t *)CURRENT_REGS;
CURRENT_REGS = NULL;
return regs;
}
arch/risc-v/src/litex/litex_start.c
+1 -1
View File
@@ -57,7 +57,7 @@
* address.
*/
uint32_t g_idle_topstack = LITEX_IDLESTACK_TOP;
uintptr_t g_idle_topstack = LITEX_IDLESTACK_TOP;
/****************************************************************************
* Public Functions
arch/risc-v/src/mpfs/mpfs_head.S
+1 -1
View File
@@ -24,7 +24,7 @@
#include <nuttx/config.h>
#include <arch/csr.h>
#include <arch/rv64gc/irq.h>
#include <arch/irq.h>
#include "chip.h"
#include "mpfs_memorymap.h"
arch/risc-v/src/mpfs/mpfs_irq.c
+1 -1
View File
@@ -41,7 +41,7 @@
* Public Data
****************************************************************************/
volatile uint64_t *g_current_regs[1];
volatile uintptr_t *g_current_regs[1];
/****************************************************************************
* Public Functions
arch/risc-v/src/qemu-rv32/qemu_rv32_head.S
+3 -33
View File
@@ -23,7 +23,7 @@
****************************************************************************/
#include <nuttx/config.h>
#include <arch/rv32im/irq.h>
#include <arch/irq.h>
#include "chip.h"
@@ -105,26 +105,11 @@ exception_common:
sw x30, 30*4(sp) /* t5 */
sw x31, 31*4(sp) /* t6 */
#if defined(INT_XCPT_REGS) && INT_XCPT_REGS >= 39
csrr x28, 0x7b0
csrr x29, 0x7b1
csrr x30, 0x7b2
sw x28, 33*4(sp)
sw x29, 34*4(sp)
sw x30, 35*4(sp)
csrr x28, 0x7b4
csrr x29, 0x7b5
csrr x30, 0x7b6
sw x28, 36*4(sp)
sw x29, 37*4(sp)
sw x30, 38*4(sp)
#endif
csrr s0, mstatus
sw s0, 32*4(sp) /* mstatus */
sw s0, 32*4(sp) /* mstatus */
addi s0, sp, XCPTCONTEXT_SIZE
sw s0, 2*4(sp) /* original SP */
sw s0, 2*4(sp) /* original SP */
/* Setup arg0(exception cause), arg1(context) */
@@ -154,21 +139,6 @@ exception_common:
lw s0, 32*4(sp) /* restore mstatus */
csrw mstatus, s0
#if defined(INT_XCPT_REGS) && INT_XCPT_REGS >= 39
lw x28, 36*4(sp)
lw x29, 37*4(sp)
lw x30, 38*4(sp)
csrrw x0, 0x7b4, x28
csrrw x0, 0x7b5, x29
csrrw x0, 0x7b6, x30
lw x28, 33*4(sp)
lw x29, 34*4(sp)
lw x30, 35*4(sp)
csrrw x0, 0x7b0, x28
csrrw x0, 0x7b1, x29
csrrw x0, 0x7b2, x30
#endif
lw x3, 3*4(sp) /* gp */
lw x4, 4*4(sp) /* tp */
lw x5, 5*4(sp) /* t0 */
arch/risc-v/src/qemu-rv32/qemu_rv32_irq.c
+1 -1
View File
@@ -81,7 +81,7 @@ void up_irqinitialize(void)
/* currents_regs is non-NULL only while processing an interrupt */
g_current_regs = NULL;
CURRENT_REGS = NULL;
/* Attach the ecall interrupt handler */

Some files were not shown because too many files have changed in this diff Show More