include/arch/x86/segmentation.h - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2016 Intel Corporation
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #ifndef _SEGMENTATION_H
 #define _SEGMENTATION_H

 #include <zephyr/types.h>

 /* Host gen_idt uses this header as well, don't depend on toolchain.h */
 #ifndef __packed
 #define __packed __attribute__((packed))
 #endif

 #ifdef __cplusplus
 extern "C" {
 #endif

 /*
  * Bitmask used to determine which exceptions result in an error code being
  * pushed onto the stack.  The following exception vectors push an error code:
  *
  *  Vector    Mnemonic    Description
  *  ------    -------     ----------------------
  *    8       #DF         Double Fault
  *    10      #TS         Invalid TSS
  *    11      #NP         Segment Not Present
  *    12      #SS         Stack Segment Fault
  *    13      #GP         General Protection Fault
  *    14      #PF         Page Fault
  *    17      #AC         Alignment Check
  */
 #define _EXC_ERROR_CODE_FAULTS	0x27d00


 /* NOTE: We currently do not have definitions for 16-bit segment, currently
  * assume everything we are working with is 32-bit
  */

 #define SEG_TYPE_LDT		0x2
 #define SEG_TYPE_TASK_GATE	0x5
 #define SEG_TYPE_TSS		0x9
 #define SEG_TYPE_TSS_BUSY	0xB
 #define SEG_TYPE_CALL_GATE	0xC
 #define SEG_TYPE_IRQ_GATE	0xE
 #define SEG_TYPE_TRAP_GATE	0xF

 #define DT_GRAN_BYTE	0
 #define DT_GRAN_PAGE	1

 #define DT_READABLE	1
 #define DT_NON_READABLE	0

 #define DT_WRITABLE	1
 #define DT_NON_WRITABLE	0

 #define DT_EXPAND_DOWN	1
 #define DT_EXPAND_UP	0

 #define DT_CONFORM	1
 #define DT_NONCONFORM	0

 #define DT_TYPE_SYSTEM		0
 #define DT_TYPE_CODEDATA	1

 #ifndef _ASMLANGUAGE

 /* Section 7.2.1 of IA architecture SW developer manual, Vol 3. */
 struct __packed task_state_segment {
 	u16_t backlink;
 	u16_t reserved_1;
 	u32_t esp0;
 	u16_t ss0;
 	u16_t reserved_2;
 	u32_t esp1;
 	u16_t ss1;
 	u16_t reserved_3;
 	u32_t esp2;
 	u16_t ss2;
 	u16_t reserved_4;
 	u32_t cr3;
 	u32_t eip;
 	u32_t eflags;
 	u32_t eax;
 	u32_t ecx;
 	u32_t edx;
 	u32_t ebx;
 	u32_t esp;
 	u32_t ebp;
 	u32_t esi;
 	u32_t edi;
 	u16_t es;
 	u16_t reserved_5;
 	u16_t cs;
 	u16_t reserved_6;
 	u16_t ss;
 	u16_t reserved_7;
 	u16_t ds;
 	u16_t reserved_8;
 	u16_t fs;
 	u16_t reserved_9;
 	u16_t gs;
 	u16_t reserved_10;
 	u16_t ldt_ss;
 	u16_t reserved_11;
 	u8_t t:1;		/* Trap bit */
 	u16_t reserved_12:15;
 	u16_t iomap;
 };

 /* Section 3.4.2 of IA architecture SW developer manual, Vol 3. */
 struct __packed segment_selector {
 	union {
 		struct {
 			u8_t rpl:2;
 			u8_t table:1; /* 0=gdt 1=ldt */
 			u16_t index:13;
 		};
 		u16_t val;
 	};
 };

 #define SEG_SELECTOR(index, table, dpl) (index << 3 | table << 2 | dpl)

 /* References
  *
  * Section 5.8.3 (Call gates)
  * Section 7.2.2 (TSS Descriptor)
  * Section 3.4.5 (Segment descriptors)
  * Section 6.11 (IDT Descriptors)
  *
  * IA architecture SW developer manual, Vol 3.
  */
 struct __packed segment_descriptor {

 	/* First DWORD: 0-15 */
 	union {
 		/* IRQ, call, trap gates */
 		u16_t limit_low;

 		/* Task gates */
 		u16_t reserved_task_gate_0;

 		/* Everything else */
 		u16_t offset_low;
 	};

 	/* First DWORD: 16-31 */
 	union {
 		/* Call/Task/Interrupt/Trap gates */
 		u16_t segment_selector;

 		/* TSS/LDT/Segments */
 		u16_t base_low;	/* Bits 0-15 */
 	};

 	/* Second DWORD: 0-7 */
 	union {
 		/* TSS/LDT/Segments */
 		u8_t base_mid;	/* Bits 16-23 */

 		/* Task gates */
 		u8_t reserved_task_gate_1;

 		/* IRQ/Trap/Call Gates */
 		struct {
 			/* Reserved except in case of call gates */
 			u8_t reserved_or_param:5;

 			/* Bits 5-7 0 0 0 per CPU manual */
 			u8_t always_0_0:3;
 		};
 	};

 	/* Second DWORD: 8-15 */
 	union {
 		/* Code or data Segments */
 		struct {
 			/* Set by the processor, init to 0 */
 			u8_t accessed:1;

 			/* executable ? readable : writable */
 			u8_t rw:1;
 			/* executable ? conforming : direction */
 			u8_t cd:1;
 			/* 1=code 0=data */
 			u8_t executable:1;

 			/* Next 3 fields actually common to all */

 			/* 1=code or data, 0=system type */
 			u8_t descriptor_type:1;

 			u8_t dpl:2;
 			u8_t present:1;
 		};

 		/* System types */
 		struct {
 			/* One of the SEG_TYPE_* macros above */
 			u8_t type:4;

 			/* Alas, C doesn't let you do a union of the first
 			 * 4 bits of a bitfield and put the rest outside of it,
 			 * it ends up getting padded.
 			 */
 			u8_t use_other_union:4;
 		};
 	};

 	/* Second DWORD: 16-31 */
 	union {
 		/* Call/IRQ/trap gates */
 		u16_t offset_hi;

 		/* Task Gates */
 		u16_t reserved_task_gate_2;

 		/* segment/LDT/TSS */
 		struct {
 			u8_t limit_hi:4;

 			/* flags */
 			u8_t avl:1;		/* CPU ignores this */

 			/* 1=Indicates 64-bit code segment in IA-32e mode */
 			u8_t flags_l:1; /* L field */

 			u8_t db:1; /* D/B field 1=32-bit 0=16-bit*/
 			u8_t granularity:1;

 			u8_t base_hi;	/* Bits 24-31 */
 		};
 	};

 };


 /* Address of this passed to lidt/lgdt.
  * IA manual calls this a 'pseudo descriptor'.
  */
 struct __packed pseudo_descriptor {
 	u16_t size;
 	struct segment_descriptor *entries;
 };


 /*
  * Full linear address (segment selector+offset), for far jumps/calls
  */
 struct __packed far_ptr {
 	/** Far pointer offset, unused when invoking a task. */
 	void *offset;
 	/** Far pointer segment/gate selector. */
 	u16_t sel;
 };


 #define DT_ZERO_ENTRY { { 0 } }

 /* NOTE: the below macros only work for fixed addresses provided at build time.
  * Base addresses or offsets cannot be &some_variable, as pointer values are not
  * known until link time and the compiler has to split the address into various
  * fields in the segment selector well before that.
  *
  * If you really need to put &some_variable as the base address in some
  * segment descriptor, you will either need to do the assignment at runtime
  * or implement some tool to populate values post-link like gen_idt does.
  */
 #define _LIMIT_AND_BASE(base_p, limit_p, granularity_p) \
 	.base_low = (((u32_t)base_p) & 0xFFFF), \
 	.base_mid = (((base_p) >> 16) & 0xFF), \
 	.base_hi = (((base_p) >> 24) & 0xFF), \
 	.limit_low = ((limit_p) & 0xFFFF), \
 	.limit_hi = (((limit_p) >> 16) & 0xF), \
 	.granularity = (granularity_p), \
 	.flags_l = 0, \
 	.db = 1, \
 	.avl = 0

 #define _SEGMENT_AND_OFFSET(segment_p, offset_p) \
 	.segment_selector = (segment_p), \
 	.offset_low = ((offset_p) & 0xFFFF), \
 	.offset_hi = ((offset_p) >> 16)

 #define _DESC_COMMON(dpl_p) \
 	.dpl = (dpl_p), \
 	.present = 1

 #define _SYS_DESC(type_p) \
 	.type = type_p, \
 	.descriptor_type = 0

 #define DT_CODE_SEG_ENTRY(base_p, limit_p, granularity_p, dpl_p, readable_p, \
 		       conforming_p) \
 	{ \
 		_DESC_COMMON(dpl_p), \
 		_LIMIT_AND_BASE(base_p, limit_p, granularity_p), \
 		.accessed = 0, \
 		.rw = (readable_p), \
 		.cd = (conforming_p), \
 		.executable = 1, \
 		.descriptor_type = 1 \
 	}

 #define DT_DATA_SEG_ENTRY(base_p, limit_p, granularity_p, dpl_p, writable_p, \
 		       direction_p) \
 	{ \
 		_DESC_COMMON(dpl_p), \
 		_LIMIT_AND_BASE(base_p, limit_p, granularity_p), \
 		.accessed = 0, \
 		.rw = (writable_p), \
 		.cd = (direction_p), \
 		.executable = 0, \
 		.descriptor_type = 1 \
 	}

 #define DT_LDT_ENTRY(base_p, limit_p, granularity_p, dpl_p) \
 	{ \
 		_DESC_COMMON(dpl_p), \
 		_LIMIT_AND_BASE(base_p, limit_p, granularity_p), \
 		_SYS_DESC(SEG_TYPE_LDT) \
 	}

 #define DT_TSS_ENTRY(base_p, limit_p, granularity_p, dpl_p) \
 	{ \
 		_DESC_COMMON(dpl_p), \
 		_LIMIT_AND_BASE(base_p, limit_p, granularity_p), \
 		_SYS_DESC(SEG_TYPE_TSS) \
 	}

 /* "standard" TSS segments that don't stuff extra data past the end of the
  * TSS struct
  */
 #define DT_TSS_STD_ENTRY(base_p, dpl_p) \
 	DT_TSS_ENTRY(base_p, sizeof(struct task_state_segment), DT_GRAN_BYTE, \
 		     dpl_p)

 #define DT_TASK_GATE_ENTRY(segment_p, dpl_p) \
 	{ \
 		_DESC_COMMON(dpl_p), \
 		_SYS_DESC(SEG_TYPE_TASK_GATE), \
 		.segment_selector = (segment_p) \
 	}

 #define DT_IRQ_GATE_ENTRY(segment_p, offset_p, dpl_p) \
 	{ \
 		_DESC_COMMON(dpl_p), \
 		_SEGMENT_AND_OFFSET(segment_p, offset_p), \
 		_SYS_DESC(SEG_TYPE_IRQ_GATE), \
 		.always_0_0 = 0 \
 	}

 #define DT_TRAP_GATE_ENTRY(segment_p, offset_p, dpl_p) \
 	{ \
 		_DESC_COMMON(dpl_p), \
 		_SEGMENT_AND_OFFSET(segment_p, offset_p), \
 		_SYS_DESC(SEG_TYPE_TRAP_GATE), \
 		.always_0_0 = 0 \
 	}

 #define DT_CALL_GATE_ENTRY(segment_p, offset_p, dpl_p, param_count_p) \
 	{ \
 		_DESC_COMMON(dpl_p), \
 		_SEGMENT_AND_OFFSET(segment_p, offset_p), \
 		_SYS_DESC(SEG_TYPE_TRAP_GATE), \
 		.reserved_or_param = (param_count_p), \
 		.always_0_0 = 0 \
 	}

 #define DTE_BASE(dt_entry) ((dt_entry)->base_low | \
 			    ((dt_entry)->base_mid << 16) | \
 			    ((dt_entry)->base_hi << 24))

 #define DTE_LIMIT(dt_entry) ((dt_entry)->limit_low | \
 			     ((dt_entry)->limit_hi << 16))

 #define DTE_OFFSET(dt_entry) ((dt_entry)->offset_low | \
 			      ((dt_entry)->offset_hi << 16))

 #define DT_INIT(entries) { sizeof(entries) - 1, &entries[0] }

 #ifdef CONFIG_SET_GDT
 /* This is either the ROM-based GDT in crt0.S or generated by gen_gdt.py,
  * depending on CONFIG_GDT_DYNAMIC
  */
 extern struct pseudo_descriptor _gdt;
 #endif

 /**
  * Properly set the segment descriptor segment and offset
  *
  * Used for call/interrupt/trap gates
  *
  * @param sd Segment descriptor
  * @param offset Offset within segment
  * @param segment_selector Segment selector
  */
 static inline void _sd_set_seg_offset(struct segment_descriptor *sd,
 				      u16_t segment_selector,
 				      u32_t offset)
 {
 	sd->offset_low = offset & 0xFFFF;
 	sd->offset_hi = offset >> 16;
 	sd->segment_selector = segment_selector;
 	sd->always_0_0 = 0;
 }


 /**
  * Initialize an segment descriptor to be a 32-bit IRQ gate
  *
  * @param sd Segment descriptor memory
  * @param seg_selector Segment selector of handler
  * @param offset offset of handler
  * @param dpl descriptor privilege level
  */
 static inline void _init_irq_gate(struct segment_descriptor *sd,
 				  u16_t seg_selector, u32_t offset,
 				  u32_t dpl)
 {
 	_sd_set_seg_offset(sd, seg_selector, offset);
 	sd->dpl = dpl;
 	sd->descriptor_type = DT_TYPE_SYSTEM;
 	sd->present = 1;
 	sd->type = SEG_TYPE_IRQ_GATE;
 }

 /**
  * Perform an IA far jump to code within another code segment
  *
  * @param sel Segment selector
  * @param offset Offset within that selector
  */
 static inline void _far_jump(u16_t sel, void *offset)
 {
 	struct far_ptr ptr = {
 		.offset = offset,
 		.sel = sel
 	};

 	__asm__ __volatile__ ("ljmp *%0" :: "m" (ptr));
 }


 /**
  * Perform an IA far call to code within another code segment
  *
  * @param sel Segment selector
  * @param offset Offset within that selector
  */
 static inline void _far_call(u16_t sel, void *offset)
 {
 	struct far_ptr ptr = {
 		.offset = offset,
 		.sel = sel
 	};

 	__asm__ __volatile__ ("lcall *%0" :: "m" (ptr));
 }


 /**
  * Set current IA task TSS
  *
  * @param sel Segment selector in GDT for desired TSS
  */
 static inline void _set_tss(u16_t sel)
 {
 	__asm__ __volatile__ ("ltr %0" :: "r" (sel));
 }


 /**
  * Get the TSS segment selector in the GDT for the current IA task
  *
  * @return Segment selector for current IA task
  */
 static inline u16_t _get_tss(void)
 {
 	u16_t sel;

 	__asm__ __volatile__ ("str %0" : "=r" (sel));
 	return sel;
 }


 /**
  * Get the current global descriptor table
  *
  * @param gdt Pointer to memory to receive GDT pseudo descriptor information
  */
 static inline void _get_gdt(struct pseudo_descriptor *gdt)
 {
 	__asm__ __volatile__ ("sgdt %0" : "=m" (*gdt));
 }


 /**
  * Get the current interrupt descriptor table
  *
  * @param idt Pointer to memory to receive IDT pseudo descriptor information
  */
 static inline void _get_idt(struct pseudo_descriptor *idt)
 {
 	__asm__ __volatile__ ("sidt %0" : "=m" (*idt));
 }


 /**
  * Get the current local descriptor table (LDT)
  *
  * @return Segment selector in the GDT for the current LDT
  */
 static inline u16_t _get_ldt(void)
 {
 	u16_t ret;

 	__asm__ __volatile__ ("sldt %0" : "=m" (ret));
 	return ret;
 }


 /**
  * Set the local descriptor table for the current IA Task
  *
  * @param ldt Segment selector in the GDT for an LDT
  */
 static inline void _set_ldt(u16_t ldt)
 {
 	__asm__ __volatile__ ("lldt %0" :: "m" (ldt));

 }

 /**
  * Set the global descriptor table
  *
  * You will most likely need to update all the data segment registers
  * and do a far call to the code segment.
  *
  * @param gdt Pointer to GDT pseudo descriptor.
  */
 static inline void _set_gdt(const struct pseudo_descriptor *gdt)
 {
 	__asm__ __volatile__ ("lgdt %0" :: "m" (*gdt));
 }


 /**
  * Set the interrupt descriptor table
  *
  * @param idt Pointer to IDT pseudo descriptor.
  */
 static inline void _set_idt(const struct pseudo_descriptor *idt)
 {
 	__asm__ __volatile__ ("lidt %0" :: "m" (*idt));
 }


 /**
  * Get the segment selector for the current code segment
  *
  * @return Segment selector
  */
 static inline u16_t _get_cs(void)
 {
 	u16_t cs = 0;

 	__asm__ __volatile__ ("mov %%cs, %0" : "=r" (cs));
 	return cs;
 }


 /**
  * Get the segment selector for the current data segment
  *
  * @return Segment selector
  */
 static inline u16_t _get_ds(void)
 {
 	u16_t ds = 0;

 	__asm__ __volatile__ ("mov %%ds, %0" : "=r" (ds));
 	return ds;
 }


 #endif /* _ASMLANGUAGE */

 #ifdef __cplusplus
 }
 #endif

 #endif /* _SEGMENTATION_H */
	/*
	* Copyright (c) 2016 Intel Corporation
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#ifndef _SEGMENTATION_H
	#define _SEGMENTATION_H

	#include <zephyr/types.h>

	/* Host gen_idt uses this header as well, don't depend on toolchain.h */
	#ifndef __packed
	#define __packed __attribute__((packed))
	#endif

	#ifdef __cplusplus
	extern "C" {
	#endif

	/*
	* Bitmask used to determine which exceptions result in an error code being
	* pushed onto the stack. The following exception vectors push an error code:
	*
	* Vector Mnemonic Description
	* ------ ------- ----------------------
	* 8 #DF Double Fault
	* 10 #TS Invalid TSS
	* 11 #NP Segment Not Present
	* 12 #SS Stack Segment Fault
	* 13 #GP General Protection Fault
	* 14 #PF Page Fault
	* 17 #AC Alignment Check
	*/
	#define _EXC_ERROR_CODE_FAULTS 0x27d00


	/* NOTE: We currently do not have definitions for 16-bit segment, currently
	* assume everything we are working with is 32-bit
	*/

	#define SEG_TYPE_LDT 0x2
	#define SEG_TYPE_TASK_GATE 0x5
	#define SEG_TYPE_TSS 0x9
	#define SEG_TYPE_TSS_BUSY 0xB
	#define SEG_TYPE_CALL_GATE 0xC
	#define SEG_TYPE_IRQ_GATE 0xE
	#define SEG_TYPE_TRAP_GATE 0xF

	#define DT_GRAN_BYTE 0
	#define DT_GRAN_PAGE 1

	#define DT_READABLE 1
	#define DT_NON_READABLE 0

	#define DT_WRITABLE 1
	#define DT_NON_WRITABLE 0

	#define DT_EXPAND_DOWN 1
	#define DT_EXPAND_UP 0

	#define DT_CONFORM 1
	#define DT_NONCONFORM 0

	#define DT_TYPE_SYSTEM 0
	#define DT_TYPE_CODEDATA 1

	#ifndef _ASMLANGUAGE

	/* Section 7.2.1 of IA architecture SW developer manual, Vol 3. */
	struct __packed task_state_segment {
	u16_t backlink;
	u16_t reserved_1;
	u32_t esp0;
	u16_t ss0;
	u16_t reserved_2;
	u32_t esp1;
	u16_t ss1;
	u16_t reserved_3;
	u32_t esp2;
	u16_t ss2;
	u16_t reserved_4;
	u32_t cr3;
	u32_t eip;
	u32_t eflags;
	u32_t eax;
	u32_t ecx;
	u32_t edx;
	u32_t ebx;
	u32_t esp;
	u32_t ebp;
	u32_t esi;
	u32_t edi;
	u16_t es;
	u16_t reserved_5;
	u16_t cs;
	u16_t reserved_6;
	u16_t ss;
	u16_t reserved_7;
	u16_t ds;
	u16_t reserved_8;
	u16_t fs;
	u16_t reserved_9;
	u16_t gs;
	u16_t reserved_10;
	u16_t ldt_ss;
	u16_t reserved_11;
	u8_t t:1; /* Trap bit */
	u16_t reserved_12:15;
	u16_t iomap;
	};

	/* Section 3.4.2 of IA architecture SW developer manual, Vol 3. */
	struct __packed segment_selector {
	union {
	struct {
	u8_t rpl:2;
	u8_t table:1; /* 0=gdt 1=ldt */
	u16_t index:13;
	};
	u16_t val;
	};
	};

	#define SEG_SELECTOR(index, table, dpl) (index << 3 \| table << 2 \| dpl)

	/* References
	*
	* Section 5.8.3 (Call gates)
	* Section 7.2.2 (TSS Descriptor)
	* Section 3.4.5 (Segment descriptors)
	* Section 6.11 (IDT Descriptors)
	*
	* IA architecture SW developer manual, Vol 3.
	*/
	struct __packed segment_descriptor {

	/* First DWORD: 0-15 */
	union {
	/* IRQ, call, trap gates */
	u16_t limit_low;

	/* Task gates */
	u16_t reserved_task_gate_0;

	/* Everything else */
	u16_t offset_low;
	};

	/* First DWORD: 16-31 */
	union {
	/* Call/Task/Interrupt/Trap gates */
	u16_t segment_selector;

	/* TSS/LDT/Segments */
	u16_t base_low; /* Bits 0-15 */
	};

	/* Second DWORD: 0-7 */
	union {
	/* TSS/LDT/Segments */
	u8_t base_mid; /* Bits 16-23 */

	/* Task gates */
	u8_t reserved_task_gate_1;

	/* IRQ/Trap/Call Gates */
	struct {
	/* Reserved except in case of call gates */
	u8_t reserved_or_param:5;

	/* Bits 5-7 0 0 0 per CPU manual */
	u8_t always_0_0:3;
	};
	};

	/* Second DWORD: 8-15 */
	union {
	/* Code or data Segments */
	struct {
	/* Set by the processor, init to 0 */
	u8_t accessed:1;

	/* executable ? readable : writable */
	u8_t rw:1;
	/* executable ? conforming : direction */
	u8_t cd:1;
	/* 1=code 0=data */
	u8_t executable:1;

	/* Next 3 fields actually common to all */

	/* 1=code or data, 0=system type */
	u8_t descriptor_type:1;

	u8_t dpl:2;
	u8_t present:1;
	};

	/* System types */
	struct {
	/* One of the SEG_TYPE_* macros above */
	u8_t type:4;

	/* Alas, C doesn't let you do a union of the first
	* 4 bits of a bitfield and put the rest outside of it,
	* it ends up getting padded.
	*/
	u8_t use_other_union:4;
	};
	};

	/* Second DWORD: 16-31 */
	union {
	/* Call/IRQ/trap gates */
	u16_t offset_hi;

	/* Task Gates */
	u16_t reserved_task_gate_2;

	/* segment/LDT/TSS */
	struct {
	u8_t limit_hi:4;

	/* flags */
	u8_t avl:1; /* CPU ignores this */

	/* 1=Indicates 64-bit code segment in IA-32e mode */
	u8_t flags_l:1; /* L field */

	u8_t db:1; /* D/B field 1=32-bit 0=16-bit*/
	u8_t granularity:1;

	u8_t base_hi; /* Bits 24-31 */
	};
	};

	};


	/* Address of this passed to lidt/lgdt.
	* IA manual calls this a 'pseudo descriptor'.
	*/
	struct __packed pseudo_descriptor {
	u16_t size;
	struct segment_descriptor *entries;
	};


	/*
	* Full linear address (segment selector+offset), for far jumps/calls
	*/
	struct __packed far_ptr {
	/** Far pointer offset, unused when invoking a task. */
	void *offset;
	/** Far pointer segment/gate selector. */
	u16_t sel;
	};


	#define DT_ZERO_ENTRY { { 0 } }

	/* NOTE: the below macros only work for fixed addresses provided at build time.
	* Base addresses or offsets cannot be &some_variable, as pointer values are not
	* known until link time and the compiler has to split the address into various
	* fields in the segment selector well before that.
	*
	* If you really need to put &some_variable as the base address in some
	* segment descriptor, you will either need to do the assignment at runtime
	* or implement some tool to populate values post-link like gen_idt does.
	*/
	#define _LIMIT_AND_BASE(base_p, limit_p, granularity_p) \
	.base_low = (((u32_t)base_p) & 0xFFFF), \
	.base_mid = (((base_p) >> 16) & 0xFF), \
	.base_hi = (((base_p) >> 24) & 0xFF), \
	.limit_low = ((limit_p) & 0xFFFF), \
	.limit_hi = (((limit_p) >> 16) & 0xF), \
	.granularity = (granularity_p), \
	.flags_l = 0, \
	.db = 1, \
	.avl = 0

	#define _SEGMENT_AND_OFFSET(segment_p, offset_p) \
	.segment_selector = (segment_p), \
	.offset_low = ((offset_p) & 0xFFFF), \
	.offset_hi = ((offset_p) >> 16)

	#define _DESC_COMMON(dpl_p) \
	.dpl = (dpl_p), \
	.present = 1

	#define _SYS_DESC(type_p) \
	.type = type_p, \
	.descriptor_type = 0

	#define DT_CODE_SEG_ENTRY(base_p, limit_p, granularity_p, dpl_p, readable_p, \
	conforming_p) \
	{ \
	_DESC_COMMON(dpl_p), \
	_LIMIT_AND_BASE(base_p, limit_p, granularity_p), \
	.accessed = 0, \
	.rw = (readable_p), \
	.cd = (conforming_p), \
	.executable = 1, \
	.descriptor_type = 1 \
	}

	#define DT_DATA_SEG_ENTRY(base_p, limit_p, granularity_p, dpl_p, writable_p, \
	direction_p) \
	{ \
	_DESC_COMMON(dpl_p), \
	_LIMIT_AND_BASE(base_p, limit_p, granularity_p), \
	.accessed = 0, \
	.rw = (writable_p), \
	.cd = (direction_p), \
	.executable = 0, \
	.descriptor_type = 1 \
	}

	#define DT_LDT_ENTRY(base_p, limit_p, granularity_p, dpl_p) \
	{ \
	_DESC_COMMON(dpl_p), \
	_LIMIT_AND_BASE(base_p, limit_p, granularity_p), \
	_SYS_DESC(SEG_TYPE_LDT) \
	}

	#define DT_TSS_ENTRY(base_p, limit_p, granularity_p, dpl_p) \
	{ \
	_DESC_COMMON(dpl_p), \
	_LIMIT_AND_BASE(base_p, limit_p, granularity_p), \
	_SYS_DESC(SEG_TYPE_TSS) \
	}

	/* "standard" TSS segments that don't stuff extra data past the end of the
	* TSS struct
	*/
	#define DT_TSS_STD_ENTRY(base_p, dpl_p) \
	DT_TSS_ENTRY(base_p, sizeof(struct task_state_segment), DT_GRAN_BYTE, \
	dpl_p)

	#define DT_TASK_GATE_ENTRY(segment_p, dpl_p) \
	{ \
	_DESC_COMMON(dpl_p), \
	_SYS_DESC(SEG_TYPE_TASK_GATE), \
	.segment_selector = (segment_p) \
	}

	#define DT_IRQ_GATE_ENTRY(segment_p, offset_p, dpl_p) \
	{ \
	_DESC_COMMON(dpl_p), \
	_SEGMENT_AND_OFFSET(segment_p, offset_p), \
	_SYS_DESC(SEG_TYPE_IRQ_GATE), \
	.always_0_0 = 0 \
	}

	#define DT_TRAP_GATE_ENTRY(segment_p, offset_p, dpl_p) \
	{ \
	_DESC_COMMON(dpl_p), \
	_SEGMENT_AND_OFFSET(segment_p, offset_p), \
	_SYS_DESC(SEG_TYPE_TRAP_GATE), \
	.always_0_0 = 0 \
	}

	#define DT_CALL_GATE_ENTRY(segment_p, offset_p, dpl_p, param_count_p) \
	{ \
	_DESC_COMMON(dpl_p), \
	_SEGMENT_AND_OFFSET(segment_p, offset_p), \
	_SYS_DESC(SEG_TYPE_TRAP_GATE), \
	.reserved_or_param = (param_count_p), \
	.always_0_0 = 0 \
	}

	#define DTE_BASE(dt_entry) ((dt_entry)->base_low \| \
	((dt_entry)->base_mid << 16) \| \
	((dt_entry)->base_hi << 24))

	#define DTE_LIMIT(dt_entry) ((dt_entry)->limit_low \| \
	((dt_entry)->limit_hi << 16))

	#define DTE_OFFSET(dt_entry) ((dt_entry)->offset_low \| \
	((dt_entry)->offset_hi << 16))

	#define DT_INIT(entries) { sizeof(entries) - 1, &entries[0] }

	#ifdef CONFIG_SET_GDT
	/* This is either the ROM-based GDT in crt0.S or generated by gen_gdt.py,
	* depending on CONFIG_GDT_DYNAMIC
	*/
	extern struct pseudo_descriptor _gdt;
	#endif

	/**
	* Properly set the segment descriptor segment and offset
	*
	* Used for call/interrupt/trap gates
	*
	* @param sd Segment descriptor
	* @param offset Offset within segment
	* @param segment_selector Segment selector
	*/
	static inline void _sd_set_seg_offset(struct segment_descriptor *sd,
	u16_t segment_selector,
	u32_t offset)
	{
	sd->offset_low = offset & 0xFFFF;
	sd->offset_hi = offset >> 16;
	sd->segment_selector = segment_selector;
	sd->always_0_0 = 0;
	}


	/**
	* Initialize an segment descriptor to be a 32-bit IRQ gate
	*
	* @param sd Segment descriptor memory
	* @param seg_selector Segment selector of handler
	* @param offset offset of handler
	* @param dpl descriptor privilege level
	*/
	static inline void _init_irq_gate(struct segment_descriptor *sd,
	u16_t seg_selector, u32_t offset,
	u32_t dpl)
	{
	_sd_set_seg_offset(sd, seg_selector, offset);
	sd->dpl = dpl;
	sd->descriptor_type = DT_TYPE_SYSTEM;
	sd->present = 1;
	sd->type = SEG_TYPE_IRQ_GATE;
	}

	/**
	* Perform an IA far jump to code within another code segment
	*
	* @param sel Segment selector
	* @param offset Offset within that selector
	*/
	static inline void _far_jump(u16_t sel, void *offset)
	{
	struct far_ptr ptr = {
	.offset = offset,
	.sel = sel
	};

	__asm__ __volatile__ ("ljmp *%0" :: "m" (ptr));
	}


	/**
	* Perform an IA far call to code within another code segment
	*
	* @param sel Segment selector
	* @param offset Offset within that selector
	*/
	static inline void _far_call(u16_t sel, void *offset)
	{
	struct far_ptr ptr = {
	.offset = offset,
	.sel = sel
	};

	__asm__ __volatile__ ("lcall *%0" :: "m" (ptr));
	}


	/**
	* Set current IA task TSS
	*
	* @param sel Segment selector in GDT for desired TSS
	*/
	static inline void _set_tss(u16_t sel)
	{
	__asm__ __volatile__ ("ltr %0" :: "r" (sel));
	}


	/**
	* Get the TSS segment selector in the GDT for the current IA task
	*
	* @return Segment selector for current IA task
	*/
	static inline u16_t _get_tss(void)
	{
	u16_t sel;

	__asm__ __volatile__ ("str %0" : "=r" (sel));
	return sel;
	}


	/**
	* Get the current global descriptor table
	*
	* @param gdt Pointer to memory to receive GDT pseudo descriptor information
	*/
	static inline void _get_gdt(struct pseudo_descriptor *gdt)
	{
	__asm__ __volatile__ ("sgdt %0" : "=m" (*gdt));
	}


	/**
	* Get the current interrupt descriptor table
	*
	* @param idt Pointer to memory to receive IDT pseudo descriptor information
	*/
	static inline void _get_idt(struct pseudo_descriptor *idt)
	{
	__asm__ __volatile__ ("sidt %0" : "=m" (*idt));
	}


	/**
	* Get the current local descriptor table (LDT)
	*
	* @return Segment selector in the GDT for the current LDT
	*/
	static inline u16_t _get_ldt(void)
	{
	u16_t ret;

	__asm__ __volatile__ ("sldt %0" : "=m" (ret));
	return ret;
	}


	/**
	* Set the local descriptor table for the current IA Task
	*
	* @param ldt Segment selector in the GDT for an LDT
	*/
	static inline void _set_ldt(u16_t ldt)
	{
	__asm__ __volatile__ ("lldt %0" :: "m" (ldt));

	}

	/**
	* Set the global descriptor table
	*
	* You will most likely need to update all the data segment registers
	* and do a far call to the code segment.
	*
	* @param gdt Pointer to GDT pseudo descriptor.
	*/
	static inline void _set_gdt(const struct pseudo_descriptor *gdt)
	{
	__asm__ __volatile__ ("lgdt %0" :: "m" (*gdt));
	}


	/**
	* Set the interrupt descriptor table
	*
	* @param idt Pointer to IDT pseudo descriptor.
	*/
	static inline void _set_idt(const struct pseudo_descriptor *idt)
	{
	__asm__ __volatile__ ("lidt %0" :: "m" (*idt));
	}


	/**
	* Get the segment selector for the current code segment
	*
	* @return Segment selector
	*/
	static inline u16_t _get_cs(void)
	{
	u16_t cs = 0;

	__asm__ __volatile__ ("mov %%cs, %0" : "=r" (cs));
	return cs;
	}


	/**
	* Get the segment selector for the current data segment
	*
	* @return Segment selector
	*/
	static inline u16_t _get_ds(void)
	{
	u16_t ds = 0;

	__asm__ __volatile__ ("mov %%ds, %0" : "=r" (ds));
	return ds;
	}


	#endif /* _ASMLANGUAGE */

	#ifdef __cplusplus
	}
	#endif

	#endif /* _SEGMENTATION_H */