thread_arch.c
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/*
* Copyright (C) 2014-2015 Freie Universität Berlin
*
* This file is subject to the terms and conditions of the GNU Lesser
* General Public License v2.1. See the file LICENSE in the top level
* directory for more details.
*/
/**
* @ingroup cpu_cortexm_common
* @{
*
* @file
* @brief Implementation of the kernel's architecture dependent thread
* interface
*
* Members of the Cortex-M family know stacks and are able to handle register
* backups partly, so we make use of that.
*
* Cortex-M3 and Cortex-M4 use the
* following register layout when saving their context onto the stack:
*
* -------- highest address (bottom of stack)
* | xPSR |
* --------
* | PC |
* --------
* | LR |
* --------
* | R12 |
* --------
* | R3 |
* --------
* | R2 |
* --------
* | R1 |
* --------
* | R0 | <- the registers from xPSR to R0 are handled by hardware
* --------
* | R11 |
* --------
* | R10 |
* --------
* | R9 |
* --------
* | R8 |
* --------
* | R7 |
* --------
* | R6 |
* --------
* | R5 |
* --------
* | R4 |
* --------
* | RET | <- exception return code
* -------- lowest address (top of stack)
*
* For the Cortex-M0 and Cortex-M0plus we use a slightly different layout by
* switching the blocks R11-R8 and R7-R4. This allows more efficient code when
* saving/restoring the context:
*
* ------------- highest address (bottom of stack)
* | xPSR - R0 | <- same as for Cortex-M3/4
* -------------
* | R7 |
* --------
* | R6 |
* --------
* | R5 |
* --------
* | R4 |
* --------
* | R11 |
* --------
* | R10 |
* --------
* | R9 |
* --------
* | R8 |
* --------
* | RET | <- exception return code
* -------- lowest address (top of stack)
*
* TODO: Implement handling of FPU registers for Cortex-M4 CPUs
*
*
* @author Stefan Pfeiffer <stefan.pfeiffer@fu-berlin.de>
* @author Hauke Petersen <hauke.petersen@fu-berlin.de>
* @author Joakim Nohlgård <joakim.nohlgard@eistec.se>
*
* @}
*/
#include <stdio.h>
#include "arch/thread_arch.h"
#include "sched.h"
#include "thread.h"
#include "irq.h"
#include "cpu.h"
extern uint32_t _estack;
extern uint32_t _sstack;
/**
* @brief Noticeable marker marking the beginning of a stack segment
*
* This marker is used e.g. by *thread_arch_start_threading* to identify the
* stacks beginning.
*/
#define STACK_MARKER (0x77777777)
/**
* @brief Initial program status register value for a newly created thread
*
* In the initial state, only the Thumb mode-bit is set
*/
#define INITIAL_XPSR (0x01000000)
/**
* @brief ARM Cortex-M specific exception return value, that triggers the
* return to the task mode stack pointer
*/
#define EXCEPT_RET_TASK_MODE (0xfffffffd)
char *thread_arch_stack_init(thread_task_func_t task_func,
void *arg,
void *stack_start,
int stack_size)
{
uint32_t *stk;
stk = (uint32_t *)((uintptr_t)stack_start + stack_size);
/* adjust to 32 bit boundary by clearing the last two bits in the address */
stk = (uint32_t *)(((uint32_t)stk) & ~((uint32_t)0x3));
/* stack start marker */
stk--;
*stk = STACK_MARKER;
/* make sure the stack is double word aligned (8 bytes) */
/* This is required in order to conform with Procedure Call Standard for the
* ARM® Architecture (AAPCS) */
/* http://infocenter.arm.com/help/topic/com.arm.doc.ihi0042e/IHI0042E_aapcs.pdf */
if (((uint32_t) stk & 0x7) != 0) {
/* add a single word padding */
--stk;
*stk = ~((uint32_t)STACK_MARKER);
}
#if defined(CPU_ARCH_CORTEX_M4F) || (CPU_ARCH_CORTEX_M7)
/* TODO: fix FPU handling for Cortex-M4f */
/*
stk--;
*stk = (unsigned int) 0;
*/
/* S0 - S15 */
/*
for (int i = 15; i >= 0; i--) {
stk--;
*stk = i;
}
*/
#endif
/* ****************************** */
/* Automatically popped registers */
/* ****************************** */
/* The following eight stacked registers are popped by the hardware upon
* return from exception. (bx instruction in context_restore) */
/* xPSR - initial status register */
stk--;
*stk = (uint32_t)INITIAL_XPSR;
/* pc - initial program counter value := thread entry function */
stk--;
*stk = (uint32_t)task_func;
/* lr - contains the return address when the thread exits */
stk--;
*stk = (uint32_t)sched_task_exit;
/* r12 */
stk--;
*stk = 0;
/* r3 - r1 */
for (int i = 3; i >= 1; i--) {
stk--;
*stk = i;
}
/* r0 - contains the thread function parameter */
stk--;
*stk = (uint32_t)arg;
/* ************************* */
/* Manually popped registers */
/* ************************* */
/* The following registers are not handled by hardware in return from
* exception, but manually by context_restore.
* For the Cortex-M0(plus) we write registers R11-R4 in two groups to allow
* for more efficient context save/restore code.
* For the Cortex-M3 and Cortex-M4 we write them continuously onto the stack
* as they can be read/written continuously by stack instructions. */
#if defined(CPU_ARCH_CORTEX_M0) || defined(CPU_ARCH_CORTEX_M0PLUS)
/* start with r7 - r4 */
for (int i = 7; i >= 4; i--) {
stk--;
*stk = i;
}
/* and put r11 - r8 on top of them */
for (int i = 11; i >= 8; i--) {
stk--;
*stk = i;
}
#else
/* r11 - r4 */
for (int i = 11; i >= 4; i--) {
stk--;
*stk = i;
}
#endif
/* exception return code - return to task-mode process stack pointer */
stk--;
*stk = (uint32_t)EXCEPT_RET_TASK_MODE;
/* The returned stack pointer will be aligned on a 32 bit boundary not on a
* 64 bit boundary because of the odd number of registers above (8+9).
* This is not a problem since the initial stack pointer upon process entry
* _will_ be 64 bit aligned (because of the cleared bit 9 in the stacked
* xPSR and aligned stacking of the hardware-handled registers). */
return (char*) stk;
}
void thread_arch_stack_print(void)
{
int count = 0;
uint32_t *sp = (uint32_t *)sched_active_thread->sp;
printf("printing the current stack of thread %" PRIkernel_pid "\n",
thread_getpid());
printf(" address: data:\n");
do {
printf(" 0x%08x: 0x%08x\n", (unsigned int)sp, (unsigned int)*sp);
sp++;
count++;
} while (*sp != STACK_MARKER);
printf("current stack size: %i byte\n", count);
}
/* This function returns the number of bytes used on the ISR stack */
int thread_arch_isr_stack_usage(void)
{
uint32_t *ptr = &_sstack;
while(((*ptr) == STACK_CANARY_WORD) && (ptr < &_estack)) {
++ptr;
}
ptrdiff_t num_used_words = &_estack - ptr;
return num_used_words * sizeof(*ptr);
}
void *thread_arch_isr_stack_pointer(void)
{
void *msp = (void *)__get_MSP();
return msp;
}
void *thread_arch_isr_stack_start(void)
{
return (void *)&_sstack;
}
__attribute__((naked)) void NORETURN thread_arch_start_threading(void)
{
__asm__ volatile (
"bl irq_arch_enable \n" /* enable IRQs to make the SVC
* interrupt is reachable */
"svc #1 \n" /* trigger the SVC interrupt */
"unreachable%=: \n" /* this loop is unreachable */
"b unreachable%= \n" /* loop indefinitely */
:::);
}
void thread_arch_yield(void)
{
/* trigger the PENDSV interrupt to run scheduler and schedule new thread if
* applicable */
SCB->ICSR |= SCB_ICSR_PENDSVSET_Msk;
}
void __attribute__((naked)) __attribute__((used)) isr_pendsv(void) {
__asm__ volatile (
/* PendSV handler entry point */
/* save context by pushing unsaved registers to the stack */
/* {r0-r3,r12,LR,PC,xPSR} are saved automatically on exception entry */
".thumb_func \n"
"mrs r0, psp \n" /* get stack pointer from user mode */
#if defined(CPU_ARCH_CORTEX_M0) || defined(CPU_ARCH_CORTEX_M0PLUS)
"mov r12, sp \n" /* remember the exception SP */
"mov sp, r0 \n" /* set user mode SP as active SP */
/* we can not push high registers directly, so we move R11-R8 into
* R4-R0, as these are already saved */
"mov r0, r8 \n" /* move R11-R8 into R3-R0 */
"mov r1, r9 \n"
"mov r2, r10 \n"
"mov r3, r11 \n"
"push {r0-r7} \n" /* now push them onto the stack */
"mov r0, lr \n" /* next we save the link register */
"push {r0} \n"
"mov r0, sp \n" /* switch back to the exception SP */
"mov sp, r12 \n"
#else
"stmdb r0!,{r4-r11} \n" /* save regs */
"stmdb r0!,{lr} \n" /* exception return value */
#if defined(CPU_ARCH_CORTEX_M4F) || defined(CPU_ARCH_CORTEX_M7)
/* "vstmdb sp!, {s16-s31} \n" */ /* TODO save FPU registers */
#endif
#endif
"ldr r1, =sched_active_thread \n" /* load address of current tcb */
"ldr r1, [r1] \n" /* dereference pdc */
"str r0, [r1] \n" /* write r0 to pdc->sp */
"bl isr_svc \n" /* continue with svc */
);
}
void __attribute__((naked)) __attribute__((used)) isr_svc(void) {
__asm__ volatile (
/* SVC handler entry point */
/* PendSV will continue here as well (via jump) */
".thumb_func \n"
/* perform scheduling */
"bl sched_run \n"
/* restore context and return from exception */
".thumb_func \n"
"context_restore: \n"
#if defined(CPU_ARCH_CORTEX_M0) || defined(CPU_ARCH_CORTEX_M0PLUS)
"mov lr, sp \n" /* save MSR stack pointer for later */
"ldr r0, =sched_active_thread \n" /* load address of current TCB */
"ldr r0, [r0] \n" /* dereference TCB */
"ldr r0, [r0] \n" /* load tcb-sp to R0 */
"mov sp, r0 \n" /* make user mode SP active SP */
"pop {r0} \n" /* restore LR from stack */
"mov r12, r0 \n" /* remember LR by parking it in R12 */
"pop {r0-r7} \n" /* get R11-R8 and R7-R4 from stack */
"mov r8, r0 \n" /* move R11-R8 to correct registers */
"mov r9, r1 \n"
"mov r10, r2 \n"
"mov r11, r3 \n"
/* restore the application mode stack pointer PSP */
"mov r0, sp \n" /* restore the user mode SP */
"msr psp, r0 \n" /* for this write it to the PSP reg */
"mov sp, lr \n" /* and get the parked MSR SP back */
/* return from exception mode to application mode */
"bx r12 \n" /* return from exception mode */
#else
"ldr r0, =sched_active_thread \n" /* load address of current TCB */
"ldr r0, [r0] \n" /* dereference TCB */
"ldr r1, [r0] \n" /* load tcb->sp to register 1 */
"ldmia r1!, {r0} \n" /* restore exception return value */
#if defined(CPU_ARCH_CORTEX_M4F) || defined(CPU_ARCH_CORTEX_M7)
/* "pop {s16-s31} \n" */ /* TODO load FPU registers */
#endif
"ldmia r1!, {r4-r11} \n" /* restore other registers */
"msr psp, r1 \n" /* restore user mode SP to PSP reg */
"bx r0 \n" /* load exception return value to PC,
* causes end of exception*/
#endif
/* {r0-r3,r12,LR,PC,xPSR} are restored automatically on exception return */
);
}