esp-idf/components/freertos/FreeRTOS-Kernel/portable/riscv/portasm.S

728 lines
27 KiB
ArmAsm
Raw Normal View History

/*
* SPDX-FileCopyrightText: 2015-2024 Espressif Systems (Shanghai) CO LTD
*
* SPDX-License-Identifier: Apache-2.0
*/
#include "sdkconfig.h"
#include "portmacro.h"
#include "freertos/FreeRTOSConfig.h"
#include "soc/soc_caps.h"
#include "riscv/rvruntime-frames.h"
#include "riscv/csr_hwlp.h"
#include "riscv/csr_pie.h"
.extern pxCurrentTCBs
#if CONFIG_ESP_SYSTEM_HW_STACK_GUARD
#include "esp_private/hw_stack_guard.h"
#endif
.global port_uxInterruptNesting
.global port_xSchedulerRunning
.global xIsrStackTop
.global pxCurrentTCBs
.global vTaskSwitchContext
.global xPortSwitchFlag
#if CONFIG_ESP_SYSTEM_HW_STACK_GUARD
.global xIsrStackBottom
.global esp_hw_stack_guard_monitor_stop
.global esp_hw_stack_guard_monitor_start
.global esp_hw_stack_guard_set_bounds
#endif /* CONFIG_ESP_SYSTEM_HW_STACK_GUARD */
.section .text
#if SOC_CPU_COPROC_NUM > 0
/**
* @brief Macro to generate a routine that saves a coprocessor's registers in the previous owner's TCB dedicated save area.
* This routine aborts if the coprocessor is used from an ISR, since this is not allowed in ESP-IDF.
* However it is allowed to use these coprocessors in the init process, so no error will be triggered if the
* current TCB is NULL.
*
* @param name The name of the coprocessor, this will be used to generate the label, so it must not contain special characters
* @param coproc_idx Index of the coprocessor in the coprocessor save area, this value can be found in rvruntime definition
* @param enable_coproc Macro that takes a scratch register as a parameter and enables the coprocessor.
* @param save_coproc_regs Macro that takes a frame as a parameter and saves all the coprocessors' registers in that frame.
* @param restore_coproc_regs Macro that takes a frame as a parameter and restores all the coprocessors' registers from that.
*
* Note: macros given as parameters can freely use temporary registers
*/
.macro generate_coprocessor_routine name, coproc_idx, enable_coproc, save_coproc_regs, restore_coproc_regs
.global rtos_save_\name\()_coproc
.type rtos_save_\name\()_coproc, @function
rtos_save_\name\()_coproc:
/* If we are in an interrupt context, we have to abort. We don't allow using the coprocessors from ISR */
#if ( configNUM_CORES > 1 )
csrr a2, mhartid /* a2 = coreID */
slli a2, a2, 2 /* a2 = coreID * 4 */
la a1, port_uxInterruptNesting /* a1 = &port_uxInterruptNesting */
add a1, a1, a2 /* a1 = &port_uxInterruptNesting[coreID] */
lw a1, 0(a1) /* a1 = port_uxInterruptNesting[coreID] */
#else /* ( configNUM_CORES <= 1 ) */
lw a1, (port_uxInterruptNesting) /* a1 = port_uxInterruptNesting */
#endif /* ( configNUM_CORES > 1 ) */
/* SP still contains the RvExcFrame address */
mv a0, sp
bnez a1, vPortCoprocUsedInISR
/* Enable the coprocessor needed by the current task */
\enable_coproc a1
mv s0, ra
call rtos_current_tcb
/* If the current TCB is NULL, the coprocessor is used during initialization, even before
* the scheduler started. Consider this a valid usage, it will be disabled as soon as the
* scheduler is started anyway */
beqz a0, rtos_save_\name\()_coproc_norestore
mv s1, a0 /* s1 = pxCurrentTCBs */
/* Prepare parameters of pxPortUpdateCoprocOwner */
mv a2, a0
li a1, \coproc_idx
csrr a0, mhartid
call pxPortUpdateCoprocOwner
/* If the save area is NULL, no need to save context */
beqz a0, rtos_save_\name\()_coproc_nosave
/* If the former owner is the current task (new owner), the return value is -1, we can skip restoring the
* coprocessor context and return directly */
li a1, -1
beq a0, a1, rtos_save_\name\()_coproc_norestore
/* Save the coprocessor context in the structure */
lw a0, RV_COPROC_SA+\coproc_idx*4(a0) /* a0 = RvCoprocSaveArea->sa_coprocs[coproc_idx] */
\save_coproc_regs a0
rtos_save_\name\()_coproc_nosave:
#if ( configNUM_CORES > 1 )
/* Pin current task to current core, s1 has pxCurrentTCBs */
mv a0, s1
csrr a1, mhartid
call vPortTaskPinToCore
#endif /* configNUM_CORES > 1 */
/* Check if we have to restore a previous context from the current TCB */
mv a0, s1
/* Do not allocate memory for the coprocessor yet, delay this until another task wants to use it.
* This guarantees that if a stack overflow occurs when allocating the coprocessor context on the stack,
* the current task context is flushed and updated in the TCB, generating a correct backtrace
* from the panic handler. */
li a1, 0
li a2, \coproc_idx
call pxPortGetCoprocArea
/* Get the enable flags from the coprocessor save area */
lw a1, RV_COPROC_ENABLE(a0)
/* To avoid having branches below, set the coprocessor enable flag now */
ori a2, a1, 1 << \coproc_idx
sw a2, RV_COPROC_ENABLE(a0)
/* Check if the former coprocessor enable bit was set */
andi a2, a1, 1 << \coproc_idx
beqz a2, rtos_save_\name\()_coproc_norestore
/* Enable bit was set, restore the coprocessor context */
lw a0, RV_COPROC_SA+\coproc_idx*4(a0) /* a0 = RvCoprocSaveArea->sa_coprocs[\coproc_idx] */
\restore_coproc_regs a0
rtos_save_\name\()_coproc_norestore:
/* Return from routine via s0, instead of ra */
jr s0
.size rtos_save_\name\()_coproc, .-rtos_save_\name\()_coproc
.endm
#if SOC_CPU_HAS_HWLOOP
/**
* @brief Macros to enable and disable the hardware loop feature on the current core
*/
.macro hwlp_enable scratch_reg=a0
li \scratch_reg, 1
csrw CSR_HWLP_STATE_REG, \scratch_reg
.endm
/**
* @brief Disable HW Loop CPU feature while returning the former status in the given register
*/
.macro hwlp_disable reg
csrrw \reg, CSR_HWLP_STATE_REG, zero
/* Only keep the lowest two bits */
andi \reg, \reg, 0b11
/* If register is 0, HWLP was off */
beqz \reg, 1f
/* It was ON, return the enable bit in \reg */
li \reg, 1 << HWLP_COPROC_IDX
1:
.endm
/**
* @brief Macros to save and restore the hardware loop registers to and from the given frame
*/
.macro hwlp_save_regs frame=sp
csrr a1, CSR_LOOP0_START_ADDR
sw a1, RV_HWLOOP_START0(\frame)
csrr a1, CSR_LOOP0_END_ADDR
sw a1, RV_HWLOOP_END0(\frame)
csrr a1, CSR_LOOP0_COUNT
sw a1, RV_HWLOOP_COUNT0(\frame)
csrr a1, CSR_LOOP1_START_ADDR
sw a1, RV_HWLOOP_START1(\frame)
csrr a1, CSR_LOOP1_END_ADDR
sw a1, RV_HWLOOP_END1(\frame)
csrr a1, CSR_LOOP1_COUNT
sw a1, RV_HWLOOP_COUNT1(\frame)
.endm
.macro hwlp_restore_regs frame=sp
lw a1, RV_HWLOOP_START0(\frame)
csrw CSR_LOOP0_START_ADDR, a1
lw a1, RV_HWLOOP_END0(\frame)
csrw CSR_LOOP0_END_ADDR, a1
lw a1, RV_HWLOOP_COUNT0(\frame)
csrw CSR_LOOP0_COUNT, a1
lw a1, RV_HWLOOP_START1(\frame)
csrw CSR_LOOP1_START_ADDR, a1
lw a1, RV_HWLOOP_END1(\frame)
csrw CSR_LOOP1_END_ADDR, a1
lw a1, RV_HWLOOP_COUNT1(\frame)
csrw CSR_LOOP1_COUNT, a1
.endm
/**
* @brief Restore the HWLP registers contained in the dedicated save area if the given task ever used it.
* This routine sets the HWLP context to clean in any case.
*
* @param a0 StaticTask address for the newly scheduled task
*/
hwlp_restore_if_used:
addi sp, sp, -16
sw ra, (sp)
/* Check if the HWLP was in use beforehand */
li a1, 0
li a2, HWLP_COPROC_IDX
call pxPortGetCoprocArea
/* Get the enable flags from the coprocessor save area */
lw a1, RV_COPROC_ENABLE(a0)
/* To avoid having branches below, set the coprocessor enable flag now */
andi a2, a1, 1 << HWLP_COPROC_IDX
beqz a2, _hwlp_restore_never_used
/* Enable bit was set, restore the coprocessor context */
lw a0, RV_COPROC_SA+HWLP_COPROC_IDX*4(a0) /* a0 = RvCoprocSaveArea->sa_coprocs[HWLP_COPROC_IDX] */
hwlp_restore_regs a0
_hwlp_restore_never_used:
/* Clear the context */
csrwi CSR_HWLP_STATE_REG, HWLP_CLEAN_STATE
lw ra, (sp)
addi sp, sp, 16
ret
#endif /* SOC_CPU_HAS_HWLOOP */
#if SOC_CPU_HAS_PIE
/**
* @brief Macros to enable and disable the PIE coprocessor on the current core
*/
.macro pie_enable scratch_reg=a0
li \scratch_reg, 1
csrw CSR_PIE_STATE_REG, \scratch_reg
.endm
/**
* @brief Disable the PIE coprocessor while returning the former status in the given register
*/
.macro pie_disable reg
csrrw \reg, CSR_PIE_STATE_REG, zero
/* Only keep the lowest two bits, if register is 0, PIE was off */
andi \reg, \reg, 0b11
beqz \reg, 1f
/* It was ON, return the enable bit in \reg */
li \reg, 1 << PIE_COPROC_IDX
1:
.endm
/**
* @brief Macros to save and restore the PIE coprocessor registers to and from the given frame
*/
.macro pie_save_regs frame=a0
/* Save the 128-bit Q registers from the frame memory and then frame += 16 */
esp.vst.128.ip q0, \frame, 16
esp.vst.128.ip q1, \frame, 16
esp.vst.128.ip q2, \frame, 16
esp.vst.128.ip q4, \frame, 16
esp.vst.128.ip q5, \frame, 16
esp.vst.128.ip q6, \frame, 16
esp.vst.128.ip q7, \frame, 16
/* Save the QACC_H and QACC_L registers, each being 256 bits big */
esp.st.qacc.l.l.128.ip \frame, 16
esp.st.qacc.l.h.128.ip \frame, 16
esp.st.qacc.h.l.128.ip \frame, 16
esp.st.qacc.h.h.128.ip \frame, 16
/* UA_STATE register (128 bits) */
esp.st.ua.state.ip \frame, 16
/* XACC register (40 bits) */
esp.st.u.xacc.ip \frame, 8
/* The following registers will be stored in the same word */
/* SAR register (6 bits) */
esp.movx.r.sar a1
slli a2, a1, 8
/* SAR_BYTES register (4 bits) */
esp.movx.r.sar.bytes a1
slli a1, a1, 4
or a2, a2, a1
/* FFT_BIT_WIDTH register (4 bits) */
esp.movx.r.fft.bit.width a1
or a2, a2, a1
sw a2, (\frame)
.endm
.macro pie_restore_regs frame=a0
/* Restore the 128-bit Q registers from the frame memory and then frame += 16 */
esp.vld.128.ip q0, \frame, 16
esp.vld.128.ip q1, \frame, 16
esp.vld.128.ip q2, \frame, 16
esp.vld.128.ip q4, \frame, 16
esp.vld.128.ip q5, \frame, 16
esp.vld.128.ip q6, \frame, 16
esp.vld.128.ip q7, \frame, 16
/* Save the QACC_H and QACC_L registers, each being 256 bits big */
esp.ld.qacc.l.l.128.ip \frame, 16
esp.ld.qacc.l.h.128.ip \frame, 16
esp.ld.qacc.h.l.128.ip \frame, 16
esp.ld.qacc.h.h.128.ip \frame, 16
/* UA_STATE register (128 bits) */
esp.ld.ua.state.ip \frame, 16
/* XACC register (40 bits) */
esp.ld.xacc.ip \frame, 8
/* The following registers are stored in the same word */
lw a2, (\frame)
/* FFT_BIT_WIDTH register (4 bits) */
andi a1, a2, 0xf
esp.movx.w.sar a1
/* SAR_BYTES register (4 bits) */
srli a2, a2, 4
andi a1, a2, 0xf
esp.movx.w.sar.bytes a1
/* SAR register (6 bits) */
srli a2, a2, 4
andi a1, a2, 0x3f
esp.movx.w.fft.bit.width a1
.endm
generate_coprocessor_routine pie, PIE_COPROC_IDX, pie_enable, pie_save_regs, pie_restore_regs
#endif /* SOC_CPU_HAS_PIE */
#if SOC_CPU_HAS_FPU
/* Bit to set in mstatus to enable the FPU */
#define CSR_MSTATUS_FPU_ENABLE (1 << 13)
/* Bit to clear in mstatus to disable the FPU */
#define CSR_MSTATUS_FPU_DISABLE (3 << 13)
.macro fpu_save_regs frame=sp
fsw ft0, RV_FPU_FT0(\frame)
fsw ft1, RV_FPU_FT1(\frame)
fsw ft2, RV_FPU_FT2(\frame)
fsw ft3, RV_FPU_FT3(\frame)
fsw ft4, RV_FPU_FT4(\frame)
fsw ft5, RV_FPU_FT5(\frame)
fsw ft6, RV_FPU_FT6(\frame)
fsw ft7, RV_FPU_FT7(\frame)
fsw fs0, RV_FPU_FS0(\frame)
fsw fs1, RV_FPU_FS1(\frame)
fsw fa0, RV_FPU_FA0(\frame)
fsw fa1, RV_FPU_FA1(\frame)
fsw fa2, RV_FPU_FA2(\frame)
fsw fa3, RV_FPU_FA3(\frame)
fsw fa4, RV_FPU_FA4(\frame)
fsw fa5, RV_FPU_FA5(\frame)
fsw fa6, RV_FPU_FA6(\frame)
fsw fa7, RV_FPU_FA7(\frame)
fsw fs2, RV_FPU_FS2(\frame)
fsw fs3, RV_FPU_FS3(\frame)
fsw fs4, RV_FPU_FS4(\frame)
fsw fs5, RV_FPU_FS5(\frame)
fsw fs6, RV_FPU_FS6(\frame)
fsw fs7, RV_FPU_FS7(\frame)
fsw fs8, RV_FPU_FS8(\frame)
fsw fs9, RV_FPU_FS9(\frame)
fsw fs10, RV_FPU_FS10(\frame)
fsw fs11, RV_FPU_FS11(\frame)
fsw ft8, RV_FPU_FT8 (\frame)
fsw ft9, RV_FPU_FT9 (\frame)
fsw ft10, RV_FPU_FT10(\frame)
fsw ft11, RV_FPU_FT11(\frame)
csrr a1, fcsr
sw a1, RV_FPU_FCSR(\frame)
.endm
.macro fpu_restore_regs frame=sp
flw ft0, RV_FPU_FT0(\frame)
flw ft1, RV_FPU_FT1(\frame)
flw ft2, RV_FPU_FT2(\frame)
flw ft3, RV_FPU_FT3(\frame)
flw ft4, RV_FPU_FT4(\frame)
flw ft5, RV_FPU_FT5(\frame)
flw ft6, RV_FPU_FT6(\frame)
flw ft7, RV_FPU_FT7(\frame)
flw fs0, RV_FPU_FS0(\frame)
flw fs1, RV_FPU_FS1(\frame)
flw fa0, RV_FPU_FA0(\frame)
flw fa1, RV_FPU_FA1(\frame)
flw fa2, RV_FPU_FA2(\frame)
flw fa3, RV_FPU_FA3(\frame)
flw fa4, RV_FPU_FA4(\frame)
flw fa5, RV_FPU_FA5(\frame)
flw fa6, RV_FPU_FA6(\frame)
flw fa7, RV_FPU_FA7(\frame)
flw fs2, RV_FPU_FS2(\frame)
flw fs3, RV_FPU_FS3(\frame)
flw fs4, RV_FPU_FS4(\frame)
flw fs5, RV_FPU_FS5(\frame)
flw fs6, RV_FPU_FS6(\frame)
flw fs7, RV_FPU_FS7(\frame)
flw fs8, RV_FPU_FS8(\frame)
flw fs9, RV_FPU_FS9(\frame)
flw fs10, RV_FPU_FS10(\frame)
flw fs11, RV_FPU_FS11(\frame)
flw ft8, RV_FPU_FT8(\frame)
flw ft9, RV_FPU_FT9(\frame)
flw ft10, RV_FPU_FT10(\frame)
flw ft11, RV_FPU_FT11(\frame)
lw a1, RV_FPU_FCSR(\frame)
csrw fcsr, a1
.endm
.macro fpu_read_dirty_bit reg
csrr \reg, mstatus
srli \reg, \reg, 13
andi \reg, \reg, 1
.endm
.macro fpu_clear_dirty_bit reg
li \reg, 1 << 13
csrc mstatus, \reg
.endm
.macro fpu_enable reg
li \reg, CSR_MSTATUS_FPU_ENABLE
csrs mstatus, \reg
.endm
.macro fpu_disable reg
li \reg, CSR_MSTATUS_FPU_DISABLE
csrc mstatus, \reg
.endm
generate_coprocessor_routine fpu, FPU_COPROC_IDX, fpu_enable, fpu_save_regs, fpu_restore_regs
#endif /* SOC_CPU_HAS_FPU */
#endif /* SOC_CPU_COPROC_NUM > 0 */
/**
* @brief Get current TCB on current core
*/
.type rtos_current_tcb, @function
rtos_current_tcb:
#if ( configNUM_CORES > 1 )
csrr a1, mhartid
slli a1, a1, 2
la a0, pxCurrentTCBs /* a0 = &pxCurrentTCBs */
add a0, a0, a1 /* a0 = &pxCurrentTCBs[coreID] */
lw a0, 0(a0) /* a0 = pxCurrentTCBs[coreID] */
#else
/* Recover the stack of next task */
lw a0, pxCurrentTCBs
#endif /* ( configNUM_CORES > 1 ) */
ret
.size, .-rtos_current_tcb
/**
* This function makes the RTOS aware about an ISR entering. It takes the
* current task stack pointer and places it into the pxCurrentTCBs.
* It then loads the ISR stack into sp.
* TODO: ISR nesting code improvements ?
* In the routines below, let's use a0-a5 registers to let the compiler generate
* 16-bit instructions.
* @returns Context that should be given to `rtos_int_exit`. On targets that have coprocessors,
* this value is a bitmap where bit i is 1 if coprocessor i is enable, 0 if it is disabled.
* This routine can use the s registers too since they are not used by the caller (yet)
*/
.global rtos_int_enter
.type rtos_int_enter, @function
rtos_int_enter:
#if ( configNUM_CORES > 1 )
csrr s0, mhartid /* s0 = coreID */
slli s0, s0, 2 /* s0 = coreID * 4 */
la a0, port_xSchedulerRunning /* a0 = &port_xSchedulerRunning */
add a0, a0, s0 /* a0 = &port_xSchedulerRunning[coreID] */
lw a0, (a0) /* a0 = port_xSchedulerRunning[coreID] */
2023-07-18 04:21:15 -04:00
#else
lw a0, port_xSchedulerRunning /* a0 = port_xSchedulerRunning */
#endif /* ( configNUM_CORES > 1 ) */
/* In case we jump, return value (a0) is correct */
beqz a0, rtos_int_enter_end /* if (port_xSchedulerRunning[coreID] == 0) jump to rtos_int_enter_end */
/* Increment the ISR nesting count */
la a0, port_uxInterruptNesting /* a0 = &port_uxInterruptNesting */
#if ( configNUM_CORES > 1 )
add a0, a0, s0 /* a0 = &port_uxInterruptNesting[coreID] // s0 contains coreID * 4 */
#endif /* ( configNUM_CORES > 1 ) */
lw a1, 0(a0) /* a1 = port_uxInterruptNesting[coreID] */
addi a2, a1, 1 /* a2 = a1 + 1 */
sw a2, 0(a0) /* port_uxInterruptNesting[coreID] = a2 */
/* If we reached here from another low-priority ISR, i.e, port_uxInterruptNesting[coreID] > 0, then skip stack pushing to TCB */
li a0, 0 /* return 0 in case we are going to branch */
bnez a1, rtos_int_enter_end /* if (port_uxInterruptNesting[coreID] > 0) jump to rtos_int_enter_end */
li s2, 0
#if SOC_CPU_COPROC_NUM > 0
/* Disable the coprocessors to forbid the ISR from using it */
#if SOC_CPU_HAS_PIE
/* The current PIE coprocessor status will be returned in a0 */
pie_disable a0
or s2, s2, a0
#endif /* SOC_CPU_HAS_PIE */
#if SOC_CPU_HAS_FPU
fpu_disable a0
#endif /* SOC_CPU_HAS_FPU */
#endif /* SOC_CPU_COPROC_NUM > 0 */
#if CONFIG_ESP_SYSTEM_HW_STACK_GUARD
/* esp_hw_stack_guard_monitor_stop(); pass the scratch registers */
ESP_HW_STACK_GUARD_MONITOR_STOP_CUR_CORE a0 a1
#endif /* CONFIG_ESP_SYSTEM_HW_STACK_GUARD */
/* Save the current sp in pxCurrentTCBs[coreID] and load the ISR stack on to sp */
#if ( configNUM_CORES > 1 )
la a0, pxCurrentTCBs /* a0 = &pxCurrentTCBs */
add a0, a0, s0 /* a0 = &pxCurrentTCBs[coreID] // s0 already contains coreID * 4 */
lw a0, (a0) /* a0 = pxCurrentTCBs[coreID] */
sw sp, 0(a0) /* pxCurrentTCBs[coreID] = sp */
/* We may need a0 below to call pxPortGetCoprocArea */
la a1, xIsrStackTop /* a1 = &xIsrStackTop */
add a1, a1, s0 /* a1 = &xIsrStackTop[coreID] // s0 already contains coreID * 4 */
lw sp, (a1) /* sp = xIsrStackTop[coreID] */
2023-07-18 04:21:15 -04:00
#else
lw a0, pxCurrentTCBs /* a0 = pxCurrentTCBs */
sw sp, 0(a0) /* pxCurrentTCBs[0] = sp */
lw sp, xIsrStackTop /* sp = xIsrStackTop */
#endif /* ( configNUM_CORES > 1 ) */
#if SOC_CPU_HAS_HWLOOP
/* Check if the current task used the Hardware loop feature, by reading the state */
csrr a1, CSR_HWLP_STATE_REG
addi a1, a1, -HWLP_DIRTY_STATE
bnez a1, 1f
/* State is dirty! The hardware loop feature was used, save the registers */
li a1, 1 /* Allocate the save area if not already allocated */
li a2, HWLP_COPROC_IDX
mv s1, ra
call pxPortGetCoprocArea
mv ra, s1
/* Set the enable flags from the coprocessor save area */
lw a1, RV_COPROC_ENABLE(a0)
ori a1, a1, 1 << HWLP_COPROC_IDX
sw a1, RV_COPROC_ENABLE(a0)
/* Get the area where we need to save the HWLP registers */
lw a0, RV_COPROC_SA+HWLP_COPROC_IDX*4(a0) /* a0 = RvCoprocSaveArea->sa_coprocs[\coproc_idx] */
hwlp_save_regs a0
/* Disable the HWLP feature so that ISR cannot use them */
csrwi CSR_HWLP_STATE_REG, HWLP_CLEAN_STATE
1:
#endif
#if CONFIG_ESP_SYSTEM_HW_STACK_GUARD
/* Prepare the parameters for esp_hw_stack_guard_set_bounds(xIsrStackBottom, xIsrStackTop); */
#if ( configNUM_CORES > 1 )
/* Load the xIsrStack for the current core and set the new bounds */
la a0, xIsrStackBottom
add a0, a0, s0 /* a0 = &xIsrStackBottom[coreID] */
lw a0, (a0) /* a0 = xIsrStackBottom[coreID] */
#else
lw a0, xIsrStackBottom
#endif /* ( configNUM_CORES > 1 ) */
mv a1, sp
/* esp_hw_stack_guard_set_bounds(xIsrStackBottom[coreID], xIsrStackTop[coreID]);
*/
ESP_HW_STACK_GUARD_SET_BOUNDS_CUR_CORE a2
ESP_HW_STACK_GUARD_MONITOR_START_CUR_CORE a0 a1
#endif /* CONFIG_ESP_SYSTEM_HW_STACK_GUARD */
/* Return the coprocessor context from s2 */
mv a0, s2
rtos_int_enter_end:
ret
/**
* @brief Restore the stack pointer of the next task to run.
*
* @param a0 Former mstatus
* @param a1 Context returned by `rtos_int_enter`. On targets that have coprocessors, this value is a bitmap
* where bit i is 1 if coprocessor i was enable, 0 if it was disabled.
*
* @returns New mstatus (potentially with coprocessors disabled)
*/
.global rtos_int_exit
.type rtos_int_exit, @function
rtos_int_exit:
/* To speed up this routine and because this current routine is only meant to be called from the interrupt
* handler, let's use callee-saved registers instead of stack space. Registers `s5-s11` are not used by
* the caller */
mv s11, a0
#if SOC_CPU_COPROC_NUM > 0
/* Save a1 as it contains the bitmap with the enabled coprocessors */
mv s8, a1
#endif
#if ( configNUM_CORES > 1 )
csrr a1, mhartid /* a1 = coreID */
slli a1, a1, 2 /* a1 = a1 * 4 */
la a0, port_xSchedulerRunning /* a0 = &port_xSchedulerRunning */
add a0, a0, a1 /* a0 = &port_xSchedulerRunning[coreID] */
lw a0, (a0) /* a0 = port_xSchedulerRunning[coreID] */
2023-07-18 04:21:15 -04:00
#else
lw a0, port_xSchedulerRunning /* a0 = port_xSchedulerRunning */
#endif /* ( configNUM_CORES > 1 ) */
beqz a0, rtos_int_exit_end /* if (port_uxSchedulerRunning == 0) jump to rtos_int_exit_end */
/* Update nesting interrupts counter */
la a2, port_uxInterruptNesting /* a2 = &port_uxInterruptNesting */
#if ( configNUM_CORES > 1 )
add a2, a2, a1 /* a2 = &port_uxInterruptNesting[coreID] // a1 already contains coreID * 4 */
#endif /* ( configNUM_CORES > 1 ) */
lw a0, 0(a2) /* a0 = port_uxInterruptNesting[coreID] */
/* Already zero, protect against underflow */
beqz a0, isr_skip_decrement /* if (port_uxInterruptNesting[coreID] == 0) jump to isr_skip_decrement */
addi a0, a0, -1 /* a0 = a0 - 1 */
sw a0, 0(a2) /* port_uxInterruptNesting[coreID] = a0 */
/* May still have interrupts pending, skip section below and exit */
bnez a0, rtos_int_exit_end
isr_skip_decrement:
/* If the CPU reached this label, a2 (uxInterruptNesting) is 0 for sure */
/* Schedule the next task if a yield is pending */
la s7, xPortSwitchFlag /* s7 = &xPortSwitchFlag */
#if ( configNUM_CORES > 1 )
add s7, s7, a1 /* s7 = &xPortSwitchFlag[coreID] // a1 already contains coreID * 4 */
#endif /* ( configNUM_CORES > 1 ) */
lw a0, 0(s7) /* a0 = xPortSwitchFlag[coreID] */
beqz a0, no_switch_restore_coproc /* if (xPortSwitchFlag[coreID] == 0) jump to no_switch_restore_coproc */
/* Preserve return address and schedule next task. To speed up the process, and because this current routine
* is only meant to be called from the interrupt handle, let's save some speed and space by using callee-saved
* registers instead of stack space. Registers `s3-s11` are not used by the caller */
mv s10, ra
#if ( SOC_CPU_COPROC_NUM > 0 )
/* In the cases where the newly scheduled task is different from the previously running one,
* we have to disable the coprocessors to let them trigger an exception on first use.
* Else, if the same task is scheduled, restore the former coprocessors state (before the interrupt) */
call rtos_current_tcb
/* Keep former TCB in s9 */
mv s9, a0
#endif
call vTaskSwitchContext
#if ( SOC_CPU_COPROC_NUM == 0 )
mv ra, s10 /* Restore original return address */
#endif
/* Clears the switch pending flag (stored in s7) */
sw zero, 0(s7) /* xPortSwitchFlag[coreID] = 0; */
#if ( SOC_CPU_COPROC_NUM > 0 )
/* If the Task to schedule is NOT the same as the former one (s9), keep the coprocessors disabled */
call rtos_current_tcb
mv ra, s10 /* Restore original return address */
beq a0, s9, no_switch_restore_coproc
#if SOC_CPU_HAS_HWLOOP
/* We have to restore the context of the HWLP if the newly scheduled task used it before. In all cases, this
* routine will also clean the state and set it to clean */
mv s7, ra
/* a0 contains the current TCB address */
call hwlp_restore_if_used
mv ra, s7
#endif /* SOC_CPU_HAS_HWLOOP */
#if SOC_CPU_HAS_FPU
/* Disable the FPU in the `mstatus` value to return */
li a1, ~CSR_MSTATUS_FPU_DISABLE
and s11, s11, a1
#endif /* SOC_CPU_HAS_FPU */
j no_switch_restored
#endif /* ( SOC_CPU_COPROC_NUM > 0 ) */
no_switch_restore_coproc:
/* We reach here either because there is no switch scheduled or because the TCB that is going to be scheduled
* is the same as the one that has been interrupted. In both cases, we need to restore the coprocessors status */
#if SOC_CPU_HAS_HWLOOP
/* Check if the ISR altered the state of the HWLP */
csrr a1, CSR_HWLP_STATE_REG
addi a1, a1, -HWLP_DIRTY_STATE
bnez a1, 1f
/* ISR used the HWLP, restore the HWLP context! */
mv s7, ra
/* a0 contains the current TCB address */
call hwlp_restore_if_used
mv ra, s7
1:
/* Else, the ISR hasn't touched HWLP registers, we don't need to restore the HWLP registers */
#endif /* SOC_CPU_HAS_HWLOOP */
#if SOC_CPU_HAS_PIE
andi a0, s8, 1 << PIE_COPROC_IDX
beqz a0, 2f
pie_enable a0
2:
#endif /* SOC_CPU_HAS_PIE */
no_switch_restored:
#if CONFIG_ESP_SYSTEM_HW_STACK_GUARD
/* esp_hw_stack_guard_monitor_stop(); pass the scratch registers */
ESP_HW_STACK_GUARD_MONITOR_STOP_CUR_CORE a0 a1
#endif /* CONFIG_ESP_SYSTEM_HW_STACK_GUARD */
#if ( configNUM_CORES > 1 )
/* Recover the stack of next task and prepare to exit */
csrr a1, mhartid
slli a1, a1, 2
la a0, pxCurrentTCBs /* a0 = &pxCurrentTCBs */
add a0, a0, a1 /* a0 = &pxCurrentTCBs[coreID] */
lw a0, 0(a0) /* a0 = pxCurrentTCBs[coreID] */
lw sp, 0(a0) /* sp = previous sp */
#else
/* Recover the stack of next task */
lw a0, pxCurrentTCBs
lw sp, 0(a0)
#endif /* ( configNUM_CORES > 1 ) */
#if CONFIG_ESP_SYSTEM_HW_STACK_GUARD
/* esp_hw_stack_guard_set_bounds(pxCurrentTCBs[0]->pxStack,
* pxCurrentTCBs[0]->pxEndOfStack);
*/
lw a1, PORT_OFFSET_PX_END_OF_STACK(a0)
lw a0, PORT_OFFSET_PX_STACK(a0)
ESP_HW_STACK_GUARD_SET_BOUNDS_CUR_CORE a2
/* esp_hw_stack_guard_monitor_start(); */
ESP_HW_STACK_GUARD_MONITOR_START_CUR_CORE a0 a1
#endif /* CONFIG_ESP_SYSTEM_HW_STACK_GUARD */
rtos_int_exit_end:
mv a0, s11 /* a0 = new mstatus */
ret