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Elixir Cross Referencer

 * Copyright (c) 2019 Intel Corporation
 * SPDX-License-Identifier: Apache-2.0


#include <kernel_arch_data.h>
#include <zephyr/arch/x86/mmustructs.h>

#ifdef CONFIG_X86_64
#include <intel64/kernel_arch_func.h>
#include <ia32/kernel_arch_func.h>

static inline bool arch_is_in_isr(void)
	/* On SMP, there is a race vs. the current CPU changing if we
	 * are preempted.  Need to mask interrupts while inspecting
	 * (note deliberate lack of gcc size suffix on the
	 * instructions, we need to work with both architectures here)
	bool ret;

	__asm__ volatile ("pushf; cli");
	ret = arch_curr_cpu()->nested != 0;
	__asm__ volatile ("popf");
	return ret;
	return _kernel.cpus[0].nested != 0U;

struct multiboot_info;

extern FUNC_NORETURN void z_x86_prep_c(void *arg);

/* Setup ultra-minimal serial driver for printk() */
void z_x86_early_serial_init(void);

/* Called upon CPU exception that is unhandled and hence fatal; dump
 * interesting info and call z_x86_fatal_error()
FUNC_NORETURN void z_x86_unhandled_cpu_exception(uintptr_t vector,
						 const z_arch_esf_t *esf);

/* Called upon unrecoverable error; dump registers and transfer control to
 * kernel via z_fatal_error()
FUNC_NORETURN void z_x86_fatal_error(unsigned int reason,
				     const z_arch_esf_t *esf);

/* Common handling for page fault exceptions */
void z_x86_page_fault_handler(z_arch_esf_t *esf);

 * @brief Check if a memory address range falls within the stack
 * Given a memory address range, ensure that it falls within the bounds
 * of the faulting context's stack.
 * @param addr Starting address
 * @param size Size of the region, or 0 if we just want to see if addr is
 *             in bounds
 * @param cs Code segment of faulting context
 * @return true if addr/size region is not within the thread stack
bool z_x86_check_stack_bounds(uintptr_t addr, size_t size, uint16_t cs);

extern FUNC_NORETURN void z_x86_userspace_enter(k_thread_entry_t user_entry,
					       void *p1, void *p2, void *p3,
					       uintptr_t stack_end,
					       uintptr_t stack_start);

/* Preparation steps needed for all threads if user mode is turned on.
 * Returns the initial entry point to swap into.
void *z_x86_userspace_prepare_thread(struct k_thread *thread);


void z_x86_do_kernel_oops(const z_arch_esf_t *esf);

 * Find a free IRQ vector at the specified priority, or return -1 if none left.
 * For multiple vector allocated one after another, prev_vector can be used to
 * speed up the allocation: it only needs to be filled with the previous
 * allocated vector, or -1 to start over.
int z_x86_allocate_vector(unsigned int priority, int prev_vector);

 * Connect a vector
void z_x86_irq_connect_on_vector(unsigned int irq,
				 uint8_t vector,
				 void (*func)(const void *arg),
				 const void *arg);

#endif /* !_ASMLANGUAGE */