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* Copyright (c) 2010-2014 Wind River Systems, Inc.
*
* SPDX-License-Identifier: Apache-2.0
*/
/**
* @file
* @brief IA-32 specific kernel interface header
* This header contains the IA-32 specific kernel interface. It is included
* by the generic kernel interface header (include/arch/cpu.h)
*/
#ifndef ZEPHYR_INCLUDE_ARCH_X86_IA32_ARCH_H_
#define ZEPHYR_INCLUDE_ARCH_X86_IA32_ARCH_H_
#include "sys_io.h"
#include <stdbool.h>
#include <kernel_structs.h>
#include <arch/common/ffs.h>
#include <sys/util.h>
#include <arch/x86/ia32/gdbstub.h>
#include <arch/x86/ia32/thread.h>
#include <arch/x86/ia32/syscall.h>
#ifndef _ASMLANGUAGE
#include <stddef.h> /* for size_t */
#include <arch/common/addr_types.h>
#include <arch/x86/ia32/segmentation.h>
#include <pm/pm.h>
#endif /* _ASMLANGUAGE */
/* GDT layout */
#define CODE_SEG 0x08
#define DATA_SEG 0x10
#define MAIN_TSS 0x18
#define DF_TSS 0x20
/*
* Use for thread local storage.
* Match these to gen_gdt.py.
* The 0x03 is added to limit privilege.
*/
#if defined(CONFIG_USERSPACE)
#define GS_TLS_SEG (0x38 | 0x03)
#elif defined(CONFIG_HW_STACK_PROTECTION)
#define GS_TLS_SEG (0x28 | 0x03)
#else
#define GS_TLS_SEG (0x18 | 0x03)
#endif
/**
* Macro used internally by NANO_CPU_INT_REGISTER and NANO_CPU_INT_REGISTER_ASM.
* Not meant to be used explicitly by platform, driver or application code.
*/
#define MK_ISR_NAME(x) __isr__##x
#define Z_DYN_STUB_SIZE 4
#define Z_DYN_STUB_OFFSET 0
#define Z_DYN_STUB_LONG_JMP_EXTRA_SIZE 3
#define Z_DYN_STUB_PER_BLOCK 32
#ifndef _ASMLANGUAGE
#ifdef __cplusplus
extern "C" {
#endif
/* interrupt/exception/error related definitions */
typedef struct s_isrList {
/** Address of ISR/stub */
void *fnc;
/** IRQ associated with the ISR/stub, or -1 if this is not
* associated with a real interrupt; in this case vec must
* not be -1
*/
unsigned int irq;
/** Priority associated with the IRQ. Ignored if vec is not -1 */
unsigned int priority;
/** Vector number associated with ISR/stub, or -1 to assign based
* on priority
*/
unsigned int vec;
/** Privilege level associated with ISR/stub */
unsigned int dpl;
/** If nonzero, specifies a TSS segment selector. Will configure
* a task gate instead of an interrupt gate. fnc parameter will be
* ignored
*/
unsigned int tss;
} ISR_LIST;
/**
* @brief Connect a routine to an interrupt vector
*
* This macro "connects" the specified routine, @a r, to the specified interrupt
* vector, @a v using the descriptor privilege level @a d. On the IA-32
* architecture, an interrupt vector is a value from 0 to 255. This macro
* populates the special intList section with the address of the routine, the
* vector number and the descriptor privilege level. The genIdt tool then picks
* up this information and generates an actual IDT entry with this information
* properly encoded.
*
* The @a d argument specifies the privilege level for the interrupt-gate
* descriptor; (hardware) interrupts and exceptions should specify a level of 0,
* whereas handlers for user-mode software generated interrupts should specify 3.
* @param r Routine to be connected
* @param n IRQ number
* @param p IRQ priority
* @param v Interrupt Vector
* @param d Descriptor Privilege Level
*/
#define NANO_CPU_INT_REGISTER(r, n, p, v, d) \
static ISR_LIST __attribute__((section(".intList"))) \
__attribute__((used)) MK_ISR_NAME(r) = \
{ \
.fnc = &(r), \
.irq = (n), \
.priority = (p), \
.vec = (v), \
.dpl = (d), \
.tss = 0 \
}
/**
* @brief Connect an IA hardware task to an interrupt vector
*
* This is very similar to NANO_CPU_INT_REGISTER but instead of connecting
* a handler function, the interrupt will induce an IA hardware task
* switch to another hardware task instead.
*
* @param tss_p GDT/LDT segment selector for the TSS representing the task
* @param irq_p IRQ number
* @param priority_p IRQ priority
* @param vec_p Interrupt vector
* @param dpl_p Descriptor privilege level
*/
#define _X86_IDT_TSS_REGISTER(tss_p, irq_p, priority_p, vec_p, dpl_p) \
static ISR_LIST __attribute__((section(".intList"))) \
__attribute__((used)) MK_ISR_NAME(r) = \
{ \
.fnc = NULL, \
.irq = (irq_p), \
.priority = (priority_p), \
.vec = (vec_p), \
.dpl = (dpl_p), \
.tss = (tss_p) \
}
/**
* Code snippets for populating the vector ID and priority into the intList
*
* The 'magic' of static interrupts is accomplished by building up an array
* 'intList' at compile time, and the gen_idt tool uses this to create the
* actual IDT data structure.
*
* For controllers like APIC, the vectors in the IDT are not normally assigned
* at build time; instead the sentinel value -1 is saved, and gen_idt figures
* out the right vector to use based on our priority scheme. Groups of 16
* vectors starting at 32 correspond to each priority level.
*
* These macros are only intended to be used by IRQ_CONNECT() macro.
*/
#define _VECTOR_ARG(irq_p) (-1)
#ifdef CONFIG_LINKER_USE_PINNED_SECTION
#define IRQSTUBS_TEXT_SECTION ".pinned_text.irqstubs"
#else
#define IRQSTUBS_TEXT_SECTION ".text.irqstubs"
#endif
/* Internally this function does a few things:
*
* 1. There is a declaration of the interrupt parameters in the .intList
* section, used by gen_idt to create the IDT. This does the same thing
* as the NANO_CPU_INT_REGISTER() macro, but is done in assembly as we
* need to populate the .fnc member with the address of the assembly
* IRQ stub that we generate immediately afterwards.
*
* 2. The IRQ stub itself is declared. The code will go in its own named
* section .text.irqstubs section (which eventually gets linked into 'text')
* and the stub shall be named (isr_name)_irq(irq_line)_stub
*
* 3. The IRQ stub pushes the ISR routine and its argument onto the stack
* and then jumps to the common interrupt handling code in _interrupt_enter().
*
* 4. z_irq_controller_irq_config() is called at runtime to set the mapping
* between the vector and the IRQ line as well as triggering flags
*/
#define ARCH_IRQ_CONNECT(irq_p, priority_p, isr_p, isr_param_p, flags_p) \
{ \
__asm__ __volatile__( \
".pushsection .intList\n\t" \
".long %c[isr]_irq%c[irq]_stub\n\t" /* ISR_LIST.fnc */ \
".long %c[irq]\n\t" /* ISR_LIST.irq */ \
".long %c[priority]\n\t" /* ISR_LIST.priority */ \
".long %c[vector]\n\t" /* ISR_LIST.vec */ \
".long 0\n\t" /* ISR_LIST.dpl */ \
".long 0\n\t" /* ISR_LIST.tss */ \
".popsection\n\t" \
".pushsection " IRQSTUBS_TEXT_SECTION "\n\t" \
".global %c[isr]_irq%c[irq]_stub\n\t" \
"%c[isr]_irq%c[irq]_stub:\n\t" \
"pushl %[isr_param]\n\t" \
"pushl %[isr]\n\t" \
"jmp _interrupt_enter\n\t" \
".popsection\n\t" \
: \
: [isr] "i" (isr_p), \
[isr_param] "i" (isr_param_p), \
[priority] "i" (priority_p), \
[vector] "i" _VECTOR_ARG(irq_p), \
[irq] "i" (irq_p)); \
z_irq_controller_irq_config(Z_IRQ_TO_INTERRUPT_VECTOR(irq_p), (irq_p), \
(flags_p)); \
}
#ifdef CONFIG_PCIE
#define ARCH_PCIE_IRQ_CONNECT(bdf_p, irq_p, priority_p, \
isr_p, isr_param_p, flags_p) \
ARCH_IRQ_CONNECT(irq_p, priority_p, isr_p, isr_param_p, flags_p)
#endif /* CONFIG_PCIE */
/* Direct interrupts won't work as expected with KPTI turned on, because
* all non-user accessible pages in the page table are marked non-present.
* It's likely possible to add logic to ARCH_ISR_DIRECT_HEADER/FOOTER to do
* the necessary trampolining to switch page tables / stacks, but this
* probably loses all the latency benefits that direct interrupts provide
* and one might as well use a regular interrupt anyway.
*/
#ifndef CONFIG_X86_KPTI
#define ARCH_IRQ_DIRECT_CONNECT(irq_p, priority_p, isr_p, flags_p) \
{ \
NANO_CPU_INT_REGISTER(isr_p, irq_p, priority_p, -1, 0); \
z_irq_controller_irq_config(Z_IRQ_TO_INTERRUPT_VECTOR(irq_p), (irq_p), \
(flags_p)); \
}
#ifdef CONFIG_PM
static inline void arch_irq_direct_pm(void)
{
if (_kernel.idle) {
_kernel.idle = 0;
z_pm_save_idle_exit();
}
}
#define ARCH_ISR_DIRECT_PM() arch_irq_direct_pm()
#else
#define ARCH_ISR_DIRECT_PM() do { } while (false)
#endif
#define ARCH_ISR_DIRECT_HEADER() arch_isr_direct_header()
#define ARCH_ISR_DIRECT_FOOTER(swap) arch_isr_direct_footer(swap)
/* FIXME:
* tracing/tracing.h cannot be included here due to circular dependency
*/
#if defined(CONFIG_TRACING)
extern void sys_trace_isr_enter(void);
extern void sys_trace_isr_exit(void);
#endif
static inline void arch_isr_direct_header(void)
{
#if defined(CONFIG_TRACING)
sys_trace_isr_enter();
#endif
/* We're not going to unlock IRQs, but we still need to increment this
* so that arch_is_in_isr() works
*/
++_kernel.cpus[0].nested;
}
/*
* FIXME: z_swap_irqlock is an inline function declared in a private header and
* cannot be referenced from a public header, so we move it to an
* external function.
*/
extern void arch_isr_direct_footer_swap(unsigned int key);
static inline void arch_isr_direct_footer(int swap)
{
z_irq_controller_eoi();
#if defined(CONFIG_TRACING)
sys_trace_isr_exit();
#endif
--_kernel.cpus[0].nested;
/* Call swap if all the following is true:
*
* 1) swap argument was enabled to this function
* 2) We are not in a nested interrupt
* 3) Next thread to run in the ready queue is not this thread
*/
if (swap != 0 && _kernel.cpus[0].nested == 0 &&
_kernel.ready_q.cache != _current) {
unsigned int flags;
/* Fetch EFLAGS argument to z_swap() */
__asm__ volatile (
"pushfl\n\t"
"popl %0\n\t"
: "=g" (flags)
:
: "memory"
);
arch_isr_direct_footer_swap(flags);
}
}
#define ARCH_ISR_DIRECT_DECLARE(name) \
static inline int name##_body(void); \
__attribute__ ((interrupt)) void name(void *stack_frame) \
{ \
ARG_UNUSED(stack_frame); \
int check_reschedule; \
ISR_DIRECT_HEADER(); \
check_reschedule = name##_body(); \
ISR_DIRECT_FOOTER(check_reschedule); \
} \
static inline int name##_body(void)
#endif /* !CONFIG_X86_KPTI */
/**
* @brief Exception Stack Frame
*
* A pointer to an "exception stack frame" (ESF) is passed as an argument
* to exception handlers registered via nanoCpuExcConnect(). As the system
* always operates at ring 0, only the EIP, CS and EFLAGS registers are pushed
* onto the stack when an exception occurs.
*
* The exception stack frame includes the volatile registers (EAX, ECX, and
* EDX) as well as the 5 non-volatile registers (EDI, ESI, EBX, EBP and ESP).
* Those registers are pushed onto the stack by _ExcEnt().
*/
typedef struct nanoEsf {
#ifdef CONFIG_GDBSTUB
unsigned int ss;
unsigned int gs;
unsigned int fs;
unsigned int es;
unsigned int ds;
#endif
unsigned int esp;
unsigned int ebp;
unsigned int ebx;
unsigned int esi;
unsigned int edi;
unsigned int edx;
unsigned int eax;
unsigned int ecx;
unsigned int errorCode;
unsigned int eip;
unsigned int cs;
unsigned int eflags;
} z_arch_esf_t;
extern unsigned int z_x86_exception_vector;
struct _x86_syscall_stack_frame {
uint32_t eip;
uint32_t cs;
uint32_t eflags;
/* These are only present if cs = USER_CODE_SEG */
uint32_t esp;
uint32_t ss;
};
static ALWAYS_INLINE unsigned int arch_irq_lock(void)
{
unsigned int key;
__asm__ volatile ("pushfl; cli; popl %0" : "=g" (key) :: "memory");
return key;
}
/**
* The NANO_SOFT_IRQ macro must be used as the value for the @a irq parameter
* to NANO_CPU_INT_REGISTER when connecting to an interrupt that does not
* correspond to any IRQ line (such as spurious vector or SW IRQ)
*/
#define NANO_SOFT_IRQ ((unsigned int) (-1))
/**
* @defgroup float_apis Floating Point APIs
* @ingroup kernel_apis
* @{
*/
struct k_thread;
/**
* @}
*/
#ifdef CONFIG_X86_ENABLE_TSS
extern struct task_state_segment _main_tss;
#endif
#define ARCH_EXCEPT(reason_p) do { \
__asm__ volatile( \
"push %[reason]\n\t" \
"int %[vector]\n\t" \
: \
: [vector] "i" (Z_X86_OOPS_VECTOR), \
[reason] "i" (reason_p)); \
CODE_UNREACHABLE; /* LCOV_EXCL_LINE */ \
} while (false)
/*
* Dynamic thread object memory alignment.
*
* If support for SSEx extensions is enabled a 16 byte boundary is required,
* since the 'fxsave' and 'fxrstor' instructions require this. In all other
* cases a 4 byte boundary is sufficient.
*/
#if defined(CONFIG_EAGER_FPU_SHARING) || defined(CONFIG_LAZY_FPU_SHARING)
#ifdef CONFIG_SSE
#define ARCH_DYNAMIC_OBJ_K_THREAD_ALIGNMENT 16
#else
#define ARCH_DYNAMIC_OBJ_K_THREAD_ALIGNMENT (sizeof(void *))
#endif
#else
/* No special alignment requirements, simply align on pointer size. */
#define ARCH_DYNAMIC_OBJ_K_THREAD_ALIGNMENT (sizeof(void *))
#endif /* CONFIG_*_FP_SHARING */
#ifdef __cplusplus
}
#endif
#endif /* !_ASMLANGUAGE */
#endif /* ZEPHYR_INCLUDE_ARCH_X86_IA32_ARCH_H_ */
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