/* * Copyright (c) 2013-2014 Wind River Systems, Inc. * * SPDX-License-Identifier: Apache-2.0 */ /** * @file * @brief New thread creation for ARM Cortex-M * * Core thread related primitives for the ARM Cortex-M processor architecture. */ #include #include #include #include #ifdef CONFIG_INIT_STACKS #include #endif /* CONFIG_INIT_STACKS */ #ifdef CONFIG_USERSPACE extern u8_t *_k_priv_stack_find(void *obj); #endif /** * * @brief Initialize a new thread from its stack space * * The control structure (thread) is put at the lower address of the stack. An * initial context, to be "restored" by __pendsv(), is put at the other end of * the stack, and thus reusable by the stack when not needed anymore. * * The initial context is an exception stack frame (ESF) since exiting the * PendSV exception will want to pop an ESF. Interestingly, even if the lsb of * an instruction address to jump to must always be set since the CPU always * runs in thumb mode, the ESF expects the real address of the instruction, * with the lsb *not* set (instructions are always aligned on 16 bit halfwords). * Since the compiler automatically sets the lsb of function addresses, we have * to unset it manually before storing it in the 'pc' field of the ESF. * * is currently unused. * * @param pStackMem the aligned stack memory * @param stackSize stack size in bytes * @param pEntry the entry point * @param parameter1 entry point to the first param * @param parameter2 entry point to the second param * @param parameter3 entry point to the third param * @param priority thread priority * @param options thread options: K_ESSENTIAL, K_FP_REGS * * @return N/A */ void _new_thread(struct k_thread *thread, k_thread_stack_t *stack, size_t stackSize, k_thread_entry_t pEntry, void *parameter1, void *parameter2, void *parameter3, int priority, unsigned int options) { char *pStackMem = K_THREAD_STACK_BUFFER(stack); _ASSERT_VALID_PRIO(priority, pEntry); #if CONFIG_MPU_REQUIRES_POWER_OF_TWO_ALIGNMENT char *stackEnd = pStackMem + stackSize - MPU_GUARD_ALIGN_AND_SIZE; #else char *stackEnd = pStackMem + stackSize; #endif struct __esf *pInitCtx; _new_thread_init(thread, pStackMem, stackEnd - pStackMem, priority, options); /* carve the thread entry struct from the "base" of the stack */ pInitCtx = (struct __esf *)(STACK_ROUND_DOWN(stackEnd - sizeof(struct __esf))); #if CONFIG_USERSPACE if (options & K_USER) { pInitCtx->pc = (u32_t)_arch_user_mode_enter; } else { pInitCtx->pc = (u32_t)_thread_entry; } #else pInitCtx->pc = (u32_t)_thread_entry; #endif /* force ARM mode by clearing LSB of address */ pInitCtx->pc &= 0xfffffffe; pInitCtx->a1 = (u32_t)pEntry; pInitCtx->a2 = (u32_t)parameter1; pInitCtx->a3 = (u32_t)parameter2; pInitCtx->a4 = (u32_t)parameter3; pInitCtx->xpsr = 0x01000000UL; /* clear all, thumb bit is 1, even if RO */ thread->callee_saved.psp = (u32_t)pInitCtx; thread->arch.basepri = 0; #if CONFIG_USERSPACE thread->arch.mode = 0; thread->arch.priv_stack_start = 0; thread->arch.priv_stack_size = 0; #endif /* swap_return_value can contain garbage */ /* * initial values in all other registers/thread entries are * irrelevant. */ #ifdef CONFIG_THREAD_MONITOR /* * In debug mode thread->entry give direct access to the thread entry * and the corresponding parameters. */ thread->entry = (struct __thread_entry *)(pInitCtx); thread_monitor_init(thread); #endif } #ifdef CONFIG_USERSPACE FUNC_NORETURN void _arch_user_mode_enter(k_thread_entry_t user_entry, void *p1, void *p2, void *p3) { /* Set up privileged stack before entering user mode */ _current->arch.priv_stack_start = (u32_t)_k_priv_stack_find(_current->stack_obj); _current->arch.priv_stack_size = (u32_t)CONFIG_PRIVILEGED_STACK_SIZE; _arm_userspace_enter(user_entry, p1, p2, p3, (u32_t)_current->stack_info.start, _current->stack_info.size); CODE_UNREACHABLE; } #endif