/* * Copyright (c) 2010-2015 Wind River Systems, Inc. * * SPDX-License-Identifier: Apache-2.0 */ /** * @file * @brief Thread support primitives * * This module provides core thread related primitives for the IA-32 * processor architecture. */ #ifdef CONFIG_INIT_STACKS #include #endif /* CONFIG_INIT_STACKS */ #include #include #include #include #include #include /* forward declaration */ /* Initial thread stack frame, such that everything is laid out as expected * for when _Swap() switches to it for the first time. */ struct _x86_initial_frame { u32_t swap_retval; u32_t ebp; u32_t ebx; u32_t esi; u32_t edi; void *_thread_entry; u32_t eflags; k_thread_entry_t entry; void *p1; void *p2; void *p3; }; /** * @brief Create a new kernel execution thread * * Initializes the k_thread object and sets up initial stack frame. * * @param thread pointer to thread struct memory, including any space needed * for extra coprocessor context * @param stack the pointer to aligned stack memory * @param stack_size the stack size in bytes * @param entry thread entry point routine * @param parameter1 first param to entry point * @param parameter2 second param to entry point * @param parameter3 third param to entry point * @param priority thread priority * @param options thread options: K_ESSENTIAL, K_FP_REGS, K_SSE_REGS */ void _new_thread(struct k_thread *thread, k_thread_stack_t *stack, size_t stack_size, k_thread_entry_t entry, void *parameter1, void *parameter2, void *parameter3, int priority, unsigned int options) { char *stack_buf; char *stack_high; struct _x86_initial_frame *initial_frame; _ASSERT_VALID_PRIO(priority, entry); stack_buf = K_THREAD_STACK_BUFFER(stack); _new_thread_init(thread, stack_buf, stack_size, priority, options); #if CONFIG_X86_USERSPACE if (!(options & K_USER)) { /* Running in kernel mode, kernel stack region is also a guard * page */ _x86_mmu_set_flags((void *)(stack_buf - MMU_PAGE_SIZE), MMU_PAGE_SIZE, MMU_ENTRY_NOT_PRESENT, MMU_PTE_P_MASK); } #endif /* CONFIG_X86_USERSPACE */ #if CONFIG_X86_STACK_PROTECTION _x86_mmu_set_flags(stack, MMU_PAGE_SIZE, MMU_ENTRY_NOT_PRESENT, MMU_PTE_P_MASK); #endif stack_high = (char *)STACK_ROUND_DOWN(stack_buf + stack_size); /* Create an initial context on the stack expected by _Swap() */ initial_frame = (struct _x86_initial_frame *) (stack_high - sizeof(struct _x86_initial_frame)); /* _thread_entry() arguments */ initial_frame->entry = entry; initial_frame->p1 = parameter1; initial_frame->p2 = parameter2; initial_frame->p3 = parameter3; /* initial EFLAGS; only modify IF and IOPL bits */ initial_frame->eflags = (EflagsGet() & ~EFLAGS_MASK) | EFLAGS_INITIAL; #ifdef CONFIG_X86_USERSPACE if (options & K_USER) { #ifdef _THREAD_WRAPPER_REQUIRED initial_frame->edi = (u32_t)_arch_user_mode_enter; initial_frame->_thread_entry = _x86_thread_entry_wrapper; #else initial_frame->_thread_entry = _arch_user_mode_enter; #endif /* _THREAD_WRAPPER_REQUIRED */ } else #endif /* CONFIG_X86_USERSPACE */ { #ifdef _THREAD_WRAPPER_REQUIRED initial_frame->edi = (u32_t)_thread_entry; initial_frame->_thread_entry = _x86_thread_entry_wrapper; #else initial_frame->_thread_entry = _thread_entry; #endif } /* Remaining _x86_initial_frame members can be garbage, _thread_entry() * doesn't care about their state when execution begins */ thread->callee_saved.esp = (unsigned long)initial_frame; #if defined(CONFIG_FP_SHARING) thread->arch.excNestCount = 0; #endif /* CONFIG_FP_SHARING */ } #ifdef CONFIG_X86_USERSPACE void _x86_swap_update_page_tables(struct k_thread *incoming, struct k_thread *outgoing) { /* Outgoing thread stack no longer accessible */ _x86_mmu_set_flags((void *)outgoing->stack_info.start, ROUND_UP(outgoing->stack_info.size, MMU_PAGE_SIZE), MMU_ENTRY_SUPERVISOR, MMU_PTE_US_MASK); /* Userspace can now access the incoming thread's stack */ _x86_mmu_set_flags((void *)incoming->stack_info.start, ROUND_UP(incoming->stack_info.size, MMU_PAGE_SIZE), MMU_ENTRY_USER, MMU_PTE_US_MASK); /* In case of privilege elevation, use the incoming thread's kernel * stack, the top of the thread stack is the bottom of the kernel stack */ _main_tss.esp0 = incoming->stack_info.start; /* If either thread defines different memory domains, efficiently * switch between them */ if (incoming->mem_domain_info.mem_domain != outgoing->mem_domain_info.mem_domain){ /* Ensure that the outgoing mem domain configuration * is set back to default state. */ _arch_mem_domain_destroy(outgoing->mem_domain_info.mem_domain); _arch_mem_domain_configure(incoming); } } FUNC_NORETURN void _arch_user_mode_enter(k_thread_entry_t user_entry, void *p1, void *p2, void *p3) { u32_t stack_end; /* Transition will reset stack pointer to initial, discarding * any old context since this is a one-way operation */ stack_end = STACK_ROUND_DOWN(_current->stack_info.start + _current->stack_info.size); /* Set up the kernel stack used during privilege elevation */ _x86_mmu_set_flags((void *)(_current->stack_info.start - MMU_PAGE_SIZE), MMU_PAGE_SIZE, (MMU_ENTRY_PRESENT | MMU_ENTRY_WRITE | MMU_ENTRY_SUPERVISOR), (MMU_PTE_P_MASK | MMU_PTE_RW_MASK | MMU_PTE_US_MASK)); _x86_userspace_enter(user_entry, p1, p2, p3, stack_end, _current->stack_info.start); CODE_UNREACHABLE; } /* Implemented in userspace.S */ extern void _x86_syscall_entry_stub(void); /* Syscalls invoked by 'int 0x80'. Installed in the IDT at DPL=3 so that * userspace can invoke it. */ NANO_CPU_INT_REGISTER(_x86_syscall_entry_stub, -1, -1, 0x80, 3); #endif /* CONFIG_X86_USERSPACE */