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ir.h
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ir.h
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/*
* IR - Lightweight JIT Compilation Framework
* (Public API)
* Copyright (C) 2022 Zend by Perforce.
* Authors: Dmitry Stogov <[email protected]>
*/
#ifndef IR_H
#define IR_H
#ifdef __cplusplus
extern "C" {
#endif
#include <inttypes.h>
#include <stdint.h>
#include <stdbool.h>
#include <stdio.h>
#include <stdlib.h>
#define IR_VERSION "0.0.1"
#ifdef _WIN32
/* TODO Handle ARM, too. */
# if defined(_M_X64) || defined(_M_ARM64)
# define __SIZEOF_SIZE_T__ 8
# elif defined(_M_IX86)
# define __SIZEOF_SIZE_T__ 4
# endif
/* Only supported is little endian for any arch on Windows,
so just fake the same for all. */
# define __ORDER_LITTLE_ENDIAN__ 1
# define __BYTE_ORDER__ __ORDER_LITTLE_ENDIAN__
# ifndef __has_builtin
# define __has_builtin(arg) (0)
# endif
#endif
/* target auto detection */
#if !defined(IR_TARGET_X86) && !defined(IR_TARGET_X64) && !defined(IR_TARGET_AARCH64)
# if defined(__x86_64__) || defined(__x86_64) || defined(_M_X64) || defined(_M_AMD64)
# define IR_TARGET_X64
# elif defined(i386) || defined(__i386) || defined(__i386__) || defined(_M_IX86)
# define IR_TARGET_X86
# elif defined(__aarch64__) || defined(_M_ARM64)
# define IR_TARGET_AARCH64
# elif defined (_WIN64)
# define IR_TARGET_X64
# elif defined (_WIN32)
# define IR_TARGET_X86
# endif
#endif
#if defined(IR_TARGET_X86)
# define IR_TARGET "x86"
#elif defined(IR_TARGET_X64)
# ifdef _WIN64
# define IR_TARGET "Windows-x86_64" /* 64-bit Windows use different ABI and calling convention */
# else
# define IR_TARGET "x86_64"
# endif
#elif defined(IR_TARGET_AARCH64)
# define IR_TARGET "aarch64"
#else
# error "Unknown IR target"
#endif
#if defined(__SIZEOF_SIZE_T__)
# if __SIZEOF_SIZE_T__ == 8
# define IR_64 1
# elif __SIZEOF_SIZE_T__ != 4
# error "Unknown addr size"
# endif
#else
# error "Unknown addr size"
#endif
#if defined(__BYTE_ORDER__)
# if defined(__ORDER_LITTLE_ENDIAN__)
# if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__
# define IR_STRUCT_LOHI(lo, hi) struct {lo; hi;}
# endif
# endif
# if defined(__ORDER_BIG_ENDIAN__)
# if __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__
# define IR_STRUCT_LOHI(lo, hi) struct {hi; lo;}
# endif
# endif
#endif
#ifndef IR_STRUCT_LOHI
# error "Unknown byte order"
#endif
#ifdef __has_attribute
# if __has_attribute(always_inline)
# define IR_ALWAYS_INLINE static inline __attribute__((always_inline))
# endif
# if __has_attribute(noinline)
# define IR_NEVER_INLINE __attribute__((noinline))
# endif
#else
# define __has_attribute(x) 0
#endif
#ifndef IR_ALWAYS_INLINE
# define IR_ALWAYS_INLINE static inline
#endif
#ifndef IR_NEVER_INLINE
# define IR_NEVER_INLINE
#endif
#ifdef IR_PHP
# include "ir_php.h"
#endif
/* IR Type flags (low 4 bits are used for type size) */
#define IR_TYPE_SIGNED (1<<4)
#define IR_TYPE_UNSIGNED (1<<5)
#define IR_TYPE_FP (1<<6)
#define IR_TYPE_SPECIAL (1<<7)
#define IR_TYPE_BOOL (IR_TYPE_SPECIAL|IR_TYPE_UNSIGNED)
#define IR_TYPE_ADDR (IR_TYPE_SPECIAL|IR_TYPE_UNSIGNED)
#define IR_TYPE_CHAR (IR_TYPE_SPECIAL|IR_TYPE_SIGNED)
/* List of IR types */
#define IR_TYPES(_) \
_(BOOL, bool, b, IR_TYPE_BOOL) \
_(U8, uint8_t, u8, IR_TYPE_UNSIGNED) \
_(U16, uint16_t, u16, IR_TYPE_UNSIGNED) \
_(U32, uint32_t, u32, IR_TYPE_UNSIGNED) \
_(U64, uint64_t, u64, IR_TYPE_UNSIGNED) \
_(ADDR, uintptr_t, addr, IR_TYPE_ADDR) \
_(CHAR, char, c, IR_TYPE_CHAR) \
_(I8, int8_t, i8, IR_TYPE_SIGNED) \
_(I16, int16_t, i16, IR_TYPE_SIGNED) \
_(I32, int32_t, i32, IR_TYPE_SIGNED) \
_(I64, int64_t, i64, IR_TYPE_SIGNED) \
_(DOUBLE, double, d, IR_TYPE_FP) \
_(FLOAT, float, f, IR_TYPE_FP) \
#define IR_IS_TYPE_UNSIGNED(t) ((t) < IR_CHAR)
#define IR_IS_TYPE_SIGNED(t) ((t) >= IR_CHAR && (t) < IR_DOUBLE)
#define IR_IS_TYPE_INT(t) ((t) < IR_DOUBLE)
#define IR_IS_TYPE_FP(t) ((t) >= IR_DOUBLE)
#define IR_TYPE_ENUM(name, type, field, flags) IR_ ## name,
typedef enum _ir_type {
IR_VOID,
IR_TYPES(IR_TYPE_ENUM)
IR_LAST_TYPE
} ir_type;
#ifdef IR_64
# define IR_SIZE_T IR_U64
# define IR_SSIZE_T IR_I64
# define IR_UINTPTR_T IR_U64
# define IR_INTPTR_T IR_I64
# define IR_C_UINTPTR IR_U64
# define IR_C_INTPTR IR_I64
#else
# define IR_SIZE_T IR_U32
# define IR_SSIZE_T IR_I32
# define IR_UINTPTR_T IR_U32
# define IR_INTPTR_T IR_I32
# define IR_C_UINTPTR IR_U32
# define IR_C_INTPTR IR_I32
#endif
/* List of IR opcodes
* ==================
*
* Each instruction is described by a type (opcode, flags, op1_type, op2_type, op3_type)
*
* flags
* -----
* v - void
* d - data IR_OP_FLAG_DATA
* r - ref IR_OP_FLAG_DATA alias
* p - pinned IR_OP_FLAG_DATA + IR_OP_FLAG_PINNED
* c - control IR_OP_FLAG_CONTROL
* S - control IR_OP_FLAG_CONTROL + IR_OP_FLAG_BB_START
* E - control IR_OP_FLAG_CONTROL + IR_OP_FLAG_BB_END
* T - control IR_OP_FLAG_CONTROL + IR_OP_FLAG_BB_END + IR_OP_FLAG_TERMINATOR
* l - load IR_OP_FLAG_MEM + IR_OP_FLAG_MEM_LOAD
* s - store IR_OP_FLAG_MEM + IR_OP_FLAG_STORE
* x - call IR_OP_FLAG_MEM + IR_OP_FLAG_CALL
* a - alloc IR_OP_FLAG_MEM + IR_OP_FLAG_ALLOC
* 0-3 - number of input edges
* N - number of arguments is defined in the insn->inputs_count (MERGE, PHI, CALL)
* X1-X3 - number of extra data ops
* C - commutative operation ("d2C" => IR_OP_FLAG_DATA + IR_OP_FLAG_COMMUTATIVE)
*
* operand types
* -------------
* ___ - unused
* def - reference to a definition op (data-flow use-def dependency edge)
* ref - memory reference (data-flow use-def dependency edge)
* var - variable reference (data-flow use-def dependency edge)
* arg - argument reference CALL/TAILCALL/CARG->CARG
* src - reference to a previous control region (IF, IF_TRUE, IF_FALSE, MERGE, LOOP_BEGIN, LOOP_END, RETURN)
* reg - data-control dependency on region (PHI, VAR, PARAM)
* ret - reference to a previous RETURN instruction (RETURN)
* str - string: variable/argument name (VAR, PARAM, CALL, TAILCALL)
* num - number: argument number (PARAM)
* prb - branch probability 1-99 (0 - unspecified): (IF_TRUE, IF_FALSE, CASE_VAL, CASE_DEFAULT)
* opt - optional number
* pro - function prototype
*
* The order of IR opcodes is carefully selected for efficient folding.
* - foldable instruction go first
* - NOP is never used (code 0 is used as ANY pattern)
* - CONST is the most often used instruction (encode with 1 bit)
* - equality inversion: EQ <-> NE => op =^ 1
* - comparison inversion: [U]LT <-> [U]GT, [U]LE <-> [U]GE => op =^ 3
*/
#define IR_OPS(_) \
/* special op (must be the first !!!) */ \
_(NOP, v, ___, ___, ___) /* empty instruction */ \
\
/* constants reference */ \
_(C_BOOL, r0, ___, ___, ___) /* constant */ \
_(C_U8, r0, ___, ___, ___) /* constant */ \
_(C_U16, r0, ___, ___, ___) /* constant */ \
_(C_U32, r0, ___, ___, ___) /* constant */ \
_(C_U64, r0, ___, ___, ___) /* constant */ \
_(C_ADDR, r0, ___, ___, ___) /* constant */ \
_(C_CHAR, r0, ___, ___, ___) /* constant */ \
_(C_I8, r0, ___, ___, ___) /* constant */ \
_(C_I16, r0, ___, ___, ___) /* constant */ \
_(C_I32, r0, ___, ___, ___) /* constant */ \
_(C_I64, r0, ___, ___, ___) /* constant */ \
_(C_DOUBLE, r0, ___, ___, ___) /* constant */ \
_(C_FLOAT, r0, ___, ___, ___) /* constant */ \
\
/* equality ops */ \
_(EQ, d2C, def, def, ___) /* equal */ \
_(NE, d2C, def, def, ___) /* not equal */ \
\
/* comparison ops (order matters, LT must be a modulo of 4 !!!) */ \
_(LT, d2, def, def, ___) /* less */ \
_(GE, d2, def, def, ___) /* greater or equal */ \
_(LE, d2, def, def, ___) /* less or equal */ \
_(GT, d2, def, def, ___) /* greater */ \
_(ULT, d2, def, def, ___) /* unsigned less */ \
_(UGE, d2, def, def, ___) /* unsigned greater or equal */ \
_(ULE, d2, def, def, ___) /* unsigned less or equal */ \
_(UGT, d2, def, def, ___) /* unsigned greater */ \
\
/* arithmetic ops */ \
_(ADD, d2C, def, def, ___) /* addition */ \
_(SUB, d2, def, def, ___) /* subtraction (must be ADD+1) */ \
_(MUL, d2C, def, def, ___) /* multiplication */ \
_(DIV, d2, def, def, ___) /* division */ \
_(MOD, d2, def, def, ___) /* modulo */ \
_(NEG, d1, def, ___, ___) /* change sign */ \
_(ABS, d1, def, ___, ___) /* absolute value */ \
/* (LDEXP, MIN, MAX, FPMATH) */ \
\
/* type conversion ops */ \
_(SEXT, d1, def, ___, ___) /* sign extension */ \
_(ZEXT, d1, def, ___, ___) /* zero extension */ \
_(TRUNC, d1, def, ___, ___) /* truncates to int type */ \
_(BITCAST, d1, def, ___, ___) /* binary representation */ \
_(INT2FP, d1, def, ___, ___) /* int to float conversion */ \
_(FP2INT, d1, def, ___, ___) /* float to int conversion */ \
_(FP2FP, d1, def, ___, ___) /* float to float conversion */ \
_(PROTO, d1X1, def, pro, ___) /* apply function prototype */ \
\
/* overflow-check */ \
_(ADD_OV, d2C, def, def, ___) /* addition */ \
_(SUB_OV, d2, def, def, ___) /* subtraction */ \
_(MUL_OV, d2C, def, def, ___) /* multiplication */ \
_(OVERFLOW, d1, def, ___, ___) /* overflow check add/sub/mul */ \
\
/* bitwise and shift ops */ \
_(NOT, d1, def, ___, ___) /* bitwise NOT */ \
_(OR, d2C, def, def, ___) /* bitwise OR */ \
_(AND, d2C, def, def, ___) /* bitwise AND */ \
_(XOR, d2C, def, def, ___) /* bitwise XOR */ \
_(SHL, d2, def, def, ___) /* logic shift left */ \
_(SHR, d2, def, def, ___) /* logic shift right */ \
_(SAR, d2, def, def, ___) /* arithmetic shift right */ \
_(ROL, d2, def, def, ___) /* rotate left */ \
_(ROR, d2, def, def, ___) /* rotate right */ \
_(BSWAP, d1, def, ___, ___) /* byte swap */ \
_(CTPOP, d1, def, ___, ___) /* count population */ \
_(CTLZ, d1, def, ___, ___) /* count leading zeros */ \
_(CTTZ, d1, def, ___, ___) /* count trailing zeros */ \
\
/* branch-less conditional ops */ \
_(MIN, d2C, def, def, ___) /* min(op1, op2) */ \
_(MAX, d2C, def, def, ___) /* max(op1, op2) */ \
_(COND, d3, def, def, def) /* op1 ? op2 : op3 */ \
\
/* data-flow and miscellaneous ops */ \
_(PHI, pN, reg, def, def) /* SSA Phi function */ \
_(COPY, d1X1, def, opt, ___) /* COPY (last foldable op) */ \
_(PI, p2, reg, def, ___) /* e-SSA Pi constraint ??? */ \
_(FRAME_ADDR, d0, ___, ___, ___) /* function frame address */ \
/* (USE, RENAME) */ \
\
/* data ops */ \
_(PARAM, p1X2, reg, str, num) /* incoming parameter proj. */ \
_(VAR, p1X1, reg, str, ___) /* local variable */ \
_(FUNC_ADDR, r0, ___, ___, ___) /* constant func ref */ \
_(FUNC, r0, ___, ___, ___) /* constant func ref */ \
_(SYM, r0, ___, ___, ___) /* constant symbol ref */ \
_(STR, r0, ___, ___, ___) /* constant str ref */ \
\
/* call ops */ \
_(CALL, xN, src, def, def) /* CALL(src, func, args...) */ \
_(TAILCALL, xN, src, def, def) /* CALL+RETURN */ \
\
/* memory reference and load/store ops */ \
_(ALLOCA, a2, src, def, ___) /* alloca(def) */ \
_(AFREE, a2, src, def, ___) /* revert alloca(def) */ \
_(BLOCK_BEGIN, a1, src, ___, ___) /* stacksave */ \
_(BLOCK_END, a2, src, def, ___) /* stackrestore */ \
_(VADDR, d1, var, ___, ___) /* load address of local var */ \
_(VLOAD, l2, src, var, ___) /* load value of local var */ \
_(VSTORE, s3, src, var, def) /* store value to local var */ \
_(RLOAD, l1X2, src, num, opt) /* load value from register */ \
_(RSTORE, s2X1, src, def, num) /* store value into register */ \
_(LOAD, l2, src, ref, ___) /* load from memory */ \
_(STORE, s3, src, ref, def) /* store to memory */ \
_(TLS, l1X2, src, num, num) /* thread local variable */ \
_(TRAP, x1, src, ___, ___) /* DebugBreak */ \
/* memory reference ops (A, H, U, S, TMP, STR, NEW, X, V) ??? */ \
\
/* va_args */ \
_(VA_START, x2, src, def, ___) /* va_start(va_list) */ \
_(VA_END, x2, src, def, ___) /* va_end(va_list) */ \
_(VA_COPY, x3, src, def, def) /* va_copy(dst, stc) */ \
_(VA_ARG, x2, src, def, ___) /* va_arg(va_list) */ \
\
/* guards */ \
_(GUARD, c3, src, def, def) /* IF without second successor */ \
_(GUARD_NOT , c3, src, def, def) /* IF without second successor */ \
\
/* deoptimization */ \
_(SNAPSHOT, xN, src, def, def) /* SNAPSHOT(src, args...) */ \
\
/* control-flow nodes */ \
_(START, S0X1, ret, ___, ___) /* function start */ \
_(ENTRY, S1X1, src, num, ___) /* entry with a fake src edge */ \
_(BEGIN, S1, src, ___, ___) /* block start */ \
_(IF_TRUE, S1X1, src, prb, ___) /* IF TRUE proj. */ \
_(IF_FALSE, S1X1, src, prb, ___) /* IF FALSE proj. */ \
_(CASE_VAL, S2X1, src, def, prb) /* switch proj. */ \
_(CASE_DEFAULT, S1X1, src, prb, ___) /* switch proj. */ \
_(MERGE, SN, src, src, src) /* control merge */ \
_(LOOP_BEGIN, SN, src, src, src) /* loop start */ \
_(END, E1, src, ___, ___) /* block end */ \
_(LOOP_END, E1, src, ___, ___) /* loop end */ \
_(IF, E2, src, def, ___) /* conditional control split */ \
_(SWITCH, E2, src, def, ___) /* multi-way control split */ \
_(RETURN, T2X1, src, def, ret) /* function return */ \
_(IJMP, T2X1, src, def, ret) /* computed goto */ \
_(UNREACHABLE, T1X2, src, ___, ret) /* unreachable (tailcall, etc) */ \
\
/* deoptimization helper */ \
_(EXITCALL, x2, src, def, ___) /* save CPU regs and call op2 */ \
#define IR_OP_ENUM(name, flags, op1, op2, op3) IR_ ## name,
typedef enum _ir_op {
IR_OPS(IR_OP_ENUM)
#ifdef IR_PHP
IR_PHP_OPS(IR_OP_ENUM)
#endif
IR_LAST_OP
} ir_op;
/* IR Opcode and Type Union */
#define IR_OPT_OP_MASK 0x00ff
#define IR_OPT_TYPE_MASK 0xff00
#define IR_OPT_TYPE_SHIFT 8
#define IR_OPT_INPUTS_SHIFT 16
#define IR_OPT(op, type) ((uint16_t)(op) | ((uint16_t)(type) << IR_OPT_TYPE_SHIFT))
#define IR_OPTX(op, type, n) ((uint32_t)(op) | ((uint32_t)(type) << IR_OPT_TYPE_SHIFT) | ((uint32_t)(n) << IR_OPT_INPUTS_SHIFT))
#define IR_OPT_TYPE(opt) (((opt) & IR_OPT_TYPE_MASK) >> IR_OPT_TYPE_SHIFT)
/* IR References */
typedef int32_t ir_ref;
#define IR_IS_CONST_REF(ref) ((ref) < 0)
/* IR Constant Value */
#define IR_UNUSED 0
#define IR_NULL (-1)
#define IR_FALSE (-2)
#define IR_TRUE (-3)
#define IR_LAST_FOLDABLE_OP IR_COPY
#define IR_CONSTS_LIMIT_MIN (-(IR_TRUE - 1))
#define IR_INSNS_LIMIT_MIN (IR_UNUSED + 1)
#ifndef IR_64
# define ADDR_MEMBER uintptr_t addr;
#else
# define ADDR_MEMBER
#endif
typedef union _ir_val {
double d;
uint64_t u64;
int64_t i64;
#ifdef IR_64
uintptr_t addr;
#endif
IR_STRUCT_LOHI(
union {
uint32_t u32;
int32_t i32;
float f;
ADDR_MEMBER
ir_ref name;
ir_ref str;
IR_STRUCT_LOHI(
union {
uint16_t u16;
int16_t i16;
IR_STRUCT_LOHI(
union {
uint8_t u8;
int8_t i8;
bool b;
char c;
},
uint8_t u8_hi
);
},
uint16_t u16_hi
);
},
uint32_t u32_hi
);
} ir_val;
#undef ADDR_MEMBER
/* IR Instruction */
typedef struct _ir_insn {
IR_STRUCT_LOHI(
union {
IR_STRUCT_LOHI(
union {
IR_STRUCT_LOHI(
uint8_t op,
uint8_t type
);
uint16_t opt;
},
union {
uint16_t inputs_count; /* number of input control edges for MERGE, PHI, CALL, TAILCALL */
uint16_t prev_insn_offset; /* 16-bit backward offset from current instruction for CSE */
uint16_t proto;
}
);
uint32_t optx;
ir_ref ops[1];
},
union {
ir_ref op1;
ir_ref prev_const;
}
);
union {
IR_STRUCT_LOHI(
ir_ref op2,
ir_ref op3
);
ir_val val;
};
} ir_insn;
/* IR Hash Tables API (private) */
typedef struct _ir_hashtab ir_hashtab;
/* IR String Tables API (implementation in ir_strtab.c) */
typedef struct _ir_strtab {
void *data;
uint32_t mask;
uint32_t size;
uint32_t count;
uint32_t pos;
char *buf;
uint32_t buf_size;
uint32_t buf_top;
} ir_strtab;
#define ir_strtab_count(strtab) (strtab)->count
typedef void (*ir_strtab_apply_t)(const char *str, uint32_t len, ir_ref val);
void ir_strtab_init(ir_strtab *strtab, uint32_t count, uint32_t buf_size);
ir_ref ir_strtab_lookup(ir_strtab *strtab, const char *str, uint32_t len, ir_ref val);
ir_ref ir_strtab_find(const ir_strtab *strtab, const char *str, uint32_t len);
ir_ref ir_strtab_update(ir_strtab *strtab, const char *str, uint32_t len, ir_ref val);
const char *ir_strtab_str(const ir_strtab *strtab, ir_ref idx);
const char *ir_strtab_strl(const ir_strtab *strtab, ir_ref idx, size_t *len);
void ir_strtab_apply(const ir_strtab *strtab, ir_strtab_apply_t func);
void ir_strtab_free(ir_strtab *strtab);
/* IR Context Flags */
#define IR_FUNCTION (1<<0) /* Generate a function. */
#define IR_FASTCALL_FUNC (1<<1) /* Generate a function with fastcall calling convention, x86 32-bit only. */
#define IR_VARARG_FUNC (1<<2)
#define IR_BUILTIN_FUNC (1<<3)
#define IR_STATIC (1<<4)
#define IR_EXTERN (1<<5)
#define IR_CONST (1<<6)
#define IR_INITIALIZED (1<<7) /* sym data flag: constant or an initialized variable */
#define IR_CONST_STRING (1<<8) /* sym data flag: constant string */
#define IR_SKIP_PROLOGUE (1<<8) /* Don't generate function prologue. */
#define IR_USE_FRAME_POINTER (1<<9)
#define IR_PREALLOCATED_STACK (1<<10)
#define IR_NO_STACK_COMBINE (1<<11)
#define IR_START_BR_TARGET (1<<12)
#define IR_ENTRY_BR_TARGET (1<<13)
#define IR_GEN_ENDBR (1<<14)
#define IR_MERGE_EMPTY_ENTRIES (1<<15)
#define IR_OPT_INLINE (1<<16)
#define IR_OPT_FOLDING (1<<17)
#define IR_OPT_CFG (1<<18) /* merge BBs, by remove END->BEGIN nodes during CFG construction */
#define IR_OPT_CODEGEN (1<<19)
#define IR_GEN_NATIVE (1<<20)
#define IR_GEN_CODE (1<<21) /* C or LLVM */
#define IR_GEN_CACHE_DEMOTE (1<<22) /* Demote the generated code from closest CPU caches */
/* debug related */
#ifdef IR_DEBUG
# define IR_DEBUG_SCCP (1<<26)
# define IR_DEBUG_GCM (1<<27)
# define IR_DEBUG_GCM_SPLIT (1<<28)
# define IR_DEBUG_SCHEDULE (1<<29)
# define IR_DEBUG_RA (1<<30)
# define IR_DEBUG_BB_SCHEDULE (1U<<31)
#endif
typedef struct _ir_ctx ir_ctx;
typedef struct _ir_use_list ir_use_list;
typedef struct _ir_block ir_block;
typedef struct _ir_arena ir_arena;
typedef struct _ir_live_interval ir_live_interval;
typedef struct _ir_live_range ir_live_range;
typedef struct _ir_loader ir_loader;
typedef int8_t ir_regs[4];
typedef void (*ir_snapshot_create_t)(ir_ctx *ctx, ir_ref addr);
#if defined(IR_TARGET_AARCH64)
typedef const void *(*ir_get_exit_addr_t)(uint32_t exit_num);
typedef const void *(*ir_get_veneer_t)(ir_ctx *ctx, const void *addr);
typedef bool (*ir_set_veneer_t)(ir_ctx *ctx, const void *addr, const void *veneer);
#endif
typedef struct _ir_code_buffer {
void *start;
void *end;
void *pos;
} ir_code_buffer;
struct _ir_ctx {
ir_insn *ir_base; /* two directional array - instructions grow down, constants grow up */
ir_ref insns_count; /* number of instructions stored in instructions buffer */
ir_ref insns_limit; /* size of allocated instructions buffer (it's extended when overflow) */
ir_ref consts_count; /* number of constants stored in constants buffer */
ir_ref consts_limit; /* size of allocated constants buffer (it's extended when overflow) */
uint32_t flags; /* IR context flags (see IR_* defines above) */
uint32_t flags2; /* IR context private flags (see IR_* defines in ir_private.h) */
ir_type ret_type; /* Function return type */
uint32_t mflags; /* CPU specific flags (see IR_X86_... macros below) */
int32_t status; /* non-zero error code (see IR_ERROR_... macros), app may use negative codes */
ir_ref fold_cse_limit; /* CSE finds identical insns backward from "insn_count" to "fold_cse_limit" */
ir_insn fold_insn; /* temporary storage for folding engine */
ir_hashtab *binding;
ir_use_list *use_lists; /* def->use lists for each instruction */
ir_ref *use_edges; /* the actual uses: use = ctx->use_edges[ctx->use_lists[def].refs + n] */
ir_ref use_edges_count; /* number of elements in use_edges[] array */
uint32_t cfg_blocks_count; /* number of elements in cfg_blocks[] array */
uint32_t cfg_edges_count; /* number of elements in cfg_edges[] array */
ir_block *cfg_blocks; /* list of basic blocks (starts from 1) */
uint32_t *cfg_edges; /* the actual basic blocks predecessors and successors edges */
uint32_t *cfg_map; /* map of instructions to basic block number */
uint32_t *cfg_schedule; /* BB order for code generation */
uint32_t *rules; /* array of target specific code-generation rules (for each instruction) */
uint32_t *vregs;
ir_ref vregs_count;
int32_t spill_base; /* base register for special spill area (e.g. PHP VM frame pointer) */
uint64_t fixed_regset; /* fixed registers, excluded for regular register allocation */
int32_t fixed_stack_red_zone; /* reusable stack allocated by caller (default 0) */
int32_t fixed_stack_frame_size; /* fixed stack allocated by generated code for spills and registers save/restore */
int32_t fixed_call_stack_size; /* fixed preallocated stack for parameter passing (default 0) */
uint64_t fixed_save_regset; /* registers that always saved/restored in prologue/epilogue */
uint32_t locals_area_size;
uint32_t gp_reg_params;
uint32_t fp_reg_params;
int32_t param_stack_size;
ir_live_interval **live_intervals;
ir_arena *arena;
ir_live_range *unused_ranges;
ir_regs *regs;
ir_strtab *fused_regs;
ir_ref *prev_ref;
union {
void *data;
ir_ref control; /* used by IR construction API (see ir_builder.h) */
ir_ref bb_start; /* used by target CPU instruction matcher */
ir_ref vars; /* list of VARs (used by register allocator) */
};
ir_snapshot_create_t snapshot_create;
int32_t stack_frame_alignment;
int32_t stack_frame_size; /* spill stack frame size (used by register allocator and code generator) */
int32_t call_stack_size; /* stack for parameter passing (used by register allocator and code generator) */
uint64_t used_preserved_regs;
#ifdef IR_TARGET_X86
int32_t ret_slot;
#endif
uint32_t rodata_offset;
uint32_t jmp_table_offset;
uint32_t entries_count;
uint32_t *entries; /* array of ENTRY blocks */
void *osr_entry_loads;
ir_code_buffer *code_buffer;
#if defined(IR_TARGET_AARCH64)
int32_t deoptimization_exits;
const void *deoptimization_exits_base;
ir_get_exit_addr_t get_exit_addr;
ir_get_veneer_t get_veneer;
ir_set_veneer_t set_veneer;
#endif
ir_loader *loader;
ir_strtab strtab;
ir_ref prev_insn_chain[IR_LAST_FOLDABLE_OP + 1];
ir_ref prev_const_chain[IR_LAST_TYPE];
};
/* Basic IR Construction API (implementation in ir.c) */
void ir_init(ir_ctx *ctx, uint32_t flags, ir_ref consts_limit, ir_ref insns_limit);
void ir_free(ir_ctx *ctx);
void ir_truncate(ir_ctx *ctx);
ir_ref ir_const(ir_ctx *ctx, ir_val val, uint8_t type);
ir_ref ir_const_i8(ir_ctx *ctx, int8_t c);
ir_ref ir_const_i16(ir_ctx *ctx, int16_t c);
ir_ref ir_const_i32(ir_ctx *ctx, int32_t c);
ir_ref ir_const_i64(ir_ctx *ctx, int64_t c);
ir_ref ir_const_u8(ir_ctx *ctx, uint8_t c);
ir_ref ir_const_u16(ir_ctx *ctx, uint16_t c);
ir_ref ir_const_u32(ir_ctx *ctx, uint32_t c);
ir_ref ir_const_u64(ir_ctx *ctx, uint64_t c);
ir_ref ir_const_bool(ir_ctx *ctx, bool c);
ir_ref ir_const_char(ir_ctx *ctx, char c);
ir_ref ir_const_float(ir_ctx *ctx, float c);
ir_ref ir_const_double(ir_ctx *ctx, double c);
ir_ref ir_const_addr(ir_ctx *ctx, uintptr_t c);
ir_ref ir_const_func_addr(ir_ctx *ctx, uintptr_t c, ir_ref proto);
ir_ref ir_const_func(ir_ctx *ctx, ir_ref str, ir_ref proto);
ir_ref ir_const_sym(ir_ctx *ctx, ir_ref str);
ir_ref ir_const_str(ir_ctx *ctx, ir_ref str);
ir_ref ir_unique_const_addr(ir_ctx *ctx, uintptr_t c);
void ir_print_const(const ir_ctx *ctx, const ir_insn *insn, FILE *f, bool quoted);
ir_ref ir_str(ir_ctx *ctx, const char *s);
ir_ref ir_strl(ir_ctx *ctx, const char *s, size_t len);
const char *ir_get_str(const ir_ctx *ctx, ir_ref idx);
const char *ir_get_strl(const ir_ctx *ctx, ir_ref idx, size_t *len);
#define IR_MAX_PROTO_PARAMS 255
typedef struct _ir_proto_t {
uint8_t flags;
uint8_t ret_type;
uint8_t params_count;
uint8_t param_types[5];
} ir_proto_t;
ir_ref ir_proto_0(ir_ctx *ctx, uint8_t flags, ir_type ret_type);
ir_ref ir_proto_1(ir_ctx *ctx, uint8_t flags, ir_type ret_type, ir_type t1);
ir_ref ir_proto_2(ir_ctx *ctx, uint8_t flags, ir_type ret_type, ir_type t1, ir_type t2);
ir_ref ir_proto_3(ir_ctx *ctx, uint8_t flags, ir_type ret_type, ir_type t1, ir_type t2, ir_type t3);
ir_ref ir_proto_4(ir_ctx *ctx, uint8_t flags, ir_type ret_type, ir_type t1, ir_type t2, ir_type t3,
ir_type t4);
ir_ref ir_proto_5(ir_ctx *ctx, uint8_t flags, ir_type ret_type, ir_type t1, ir_type t2, ir_type t3,
ir_type t4, ir_type t5);
ir_ref ir_proto(ir_ctx *ctx, uint8_t flags, ir_type ret_type, uint32_t params_counts, uint8_t *param_types);
ir_ref ir_emit(ir_ctx *ctx, uint32_t opt, ir_ref op1, ir_ref op2, ir_ref op3);
ir_ref ir_emit0(ir_ctx *ctx, uint32_t opt);
ir_ref ir_emit1(ir_ctx *ctx, uint32_t opt, ir_ref op1);
ir_ref ir_emit2(ir_ctx *ctx, uint32_t opt, ir_ref op1, ir_ref op2);
ir_ref ir_emit3(ir_ctx *ctx, uint32_t opt, ir_ref op1, ir_ref op2, ir_ref op3);
ir_ref ir_emit_N(ir_ctx *ctx, uint32_t opt, int32_t count);
void ir_set_op(ir_ctx *ctx, ir_ref ref, int32_t n, ir_ref val);
IR_ALWAYS_INLINE void ir_set_op1(ir_ctx *ctx, ir_ref ref, ir_ref val)
{
ctx->ir_base[ref].op1 = val;
}
IR_ALWAYS_INLINE void ir_set_op2(ir_ctx *ctx, ir_ref ref, ir_ref val)
{
ctx->ir_base[ref].op2 = val;
}
IR_ALWAYS_INLINE void ir_set_op3(ir_ctx *ctx, ir_ref ref, ir_ref val)
{
ctx->ir_base[ref].op3 = val;
}
ir_ref ir_get_op(ir_ctx *ctx, ir_ref ref, int32_t n);
IR_ALWAYS_INLINE ir_ref ir_insn_op(const ir_insn *insn, int32_t n)
{
const ir_ref *p = insn->ops + n;
return *p;
}
IR_ALWAYS_INLINE void ir_insn_set_op(ir_insn *insn, int32_t n, ir_ref val)
{
ir_ref *p = insn->ops + n;
*p = val;
}
ir_ref ir_fold(ir_ctx *ctx, uint32_t opt, ir_ref op1, ir_ref op2, ir_ref op3);
ir_ref ir_fold0(ir_ctx *ctx, uint32_t opt);
ir_ref ir_fold1(ir_ctx *ctx, uint32_t opt, ir_ref op1);
ir_ref ir_fold2(ir_ctx *ctx, uint32_t opt, ir_ref op1, ir_ref op2);
ir_ref ir_fold3(ir_ctx *ctx, uint32_t opt, ir_ref op1, ir_ref op2, ir_ref op3);
ir_ref ir_param(ir_ctx *ctx, ir_type type, ir_ref region, const char *name, int pos);
ir_ref ir_var(ir_ctx *ctx, ir_type type, ir_ref region, const char *name);
ir_ref ir_bind(ir_ctx *ctx, ir_ref var, ir_ref def);
/* Def -> Use lists */
void ir_build_def_use_lists(ir_ctx *ctx);
/* CFG - Control Flow Graph (implementation in ir_cfg.c) */
int ir_build_cfg(ir_ctx *ctx);
int ir_remove_unreachable_blocks(ir_ctx *ctx);
int ir_build_dominators_tree(ir_ctx *ctx);
int ir_find_loops(ir_ctx *ctx);
int ir_schedule_blocks(ir_ctx *ctx);
void ir_build_prev_refs(ir_ctx *ctx);
/* SCCP - Sparse Conditional Constant Propagation (implementation in ir_sccp.c) */
int ir_sccp(ir_ctx *ctx);
/* GCM - Global Code Motion and scheduling (implementation in ir_gcm.c) */
int ir_gcm(ir_ctx *ctx);
int ir_schedule(ir_ctx *ctx);
/* Liveness & Register Allocation (implementation in ir_ra.c) */
#define IR_REG_NONE -1
#define IR_REG_SPILL_LOAD (1<<6)
#define IR_REG_SPILL_STORE (1<<6)
#define IR_REG_SPILL_SPECIAL (1<<7)
#define IR_REG_SPILLED(r) \
((r) & (IR_REG_SPILL_LOAD|IR_REG_SPILL_STORE|IR_REG_SPILL_SPECIAL))
#define IR_REG_NUM(r) \
((int8_t)((r) == IR_REG_NONE ? IR_REG_NONE : ((r) & ~(IR_REG_SPILL_LOAD|IR_REG_SPILL_STORE|IR_REG_SPILL_SPECIAL))))
int ir_assign_virtual_registers(ir_ctx *ctx);
int ir_compute_live_ranges(ir_ctx *ctx);
int ir_coalesce(ir_ctx *ctx);
int ir_compute_dessa_moves(ir_ctx *ctx);
int ir_reg_alloc(ir_ctx *ctx);
int ir_regs_number(void);
bool ir_reg_is_int(int32_t reg);
const char *ir_reg_name(int8_t reg, ir_type type);
int32_t ir_get_spill_slot_offset(ir_ctx *ctx, ir_ref ref);
/* Target CPU instruction selection and code generation (see ir_x86.c) */
int ir_match(ir_ctx *ctx);
void *ir_emit_code(ir_ctx *ctx, size_t *size);
bool ir_needs_thunk(ir_code_buffer *code_buffer, void *addr);
void *ir_emit_thunk(ir_code_buffer *code_buffer, void *addr, size_t *size_ptr);
void ir_fix_thunk(void *thunk_entry, void *addr);
/* Target address resolution (implementation in ir_emit.c) */
void *ir_resolve_sym_name(const char *name);
/* Target CPU disassembler (implementation in ir_disasm.c) */
int ir_disasm_init(void);
void ir_disasm_free(void);
void ir_disasm_add_symbol(const char *name, uint64_t addr, uint64_t size);
const char* ir_disasm_find_symbol(uint64_t addr, int64_t *offset);
int ir_disasm(const char *name,
const void *start,
size_t size,
bool asm_addr,
ir_ctx *ctx,
FILE *f);
/* Linux perf interface (implementation in ir_perf.c) */
int ir_perf_jitdump_open(void);
int ir_perf_jitdump_close(void);
int ir_perf_jitdump_register(const char *name, const void *start, size_t size);
void ir_perf_map_register(const char *name, const void *start, size_t size);
/* GDB JIT interface (implementation in ir_gdb.c) */
int ir_gdb_register(const char *name,
const void *start,
size_t size,
uint32_t sp_offset,
uint32_t sp_adjustment);
void ir_gdb_unregister_all(void);
bool ir_gdb_present(void);
/* IR load API (implementation in ir_load.c) */
struct _ir_loader {
uint32_t default_func_flags;
bool (*init_module) (ir_loader *loader, const char *name, const char *filename, const char *target);
bool (*external_sym_dcl) (ir_loader *loader, const char *name, uint32_t flags);
bool (*external_func_dcl) (ir_loader *loader, const char *name,
uint32_t flags, ir_type ret_type, uint32_t params_count, const uint8_t *param_types);
bool (*forward_func_dcl) (ir_loader *loader, const char *name,
uint32_t flags, ir_type ret_type, uint32_t params_count, const uint8_t *param_types);
bool (*sym_dcl) (ir_loader *loader, const char *name, uint32_t flags, size_t size);
bool (*sym_data) (ir_loader *loader, ir_type type, uint32_t count, const void *data);
bool (*sym_data_str) (ir_loader *loader, const char *str, size_t len);
bool (*sym_data_pad) (ir_loader *loader, size_t offset);
bool (*sym_data_ref) (ir_loader *loader, ir_op op, const char *ref, uintptr_t offset);
bool (*sym_data_end) (ir_loader *loader, uint32_t flags);
bool (*func_init) (ir_loader *loader, ir_ctx *ctx, const char *name);
bool (*func_process) (ir_loader *loader, ir_ctx *ctx, const char *name);
void*(*resolve_sym_name) (ir_loader *loader, const char *name, bool add_thunk);
bool (*has_sym) (ir_loader *loader, const char *name);
bool (*add_sym) (ir_loader *loader, const char *name, void *addr);
};
void ir_loader_init(void);
void ir_loader_free(void);
int ir_load(ir_loader *loader, FILE *f);
/* IR LLVM load API (implementation in ir_load_llvm.c) */
int ir_load_llvm_bitcode(ir_loader *loader, const char *filename);
int ir_load_llvm_asm(ir_loader *loader, const char *filename);
/* IR save API (implementation in ir_save.c) */
#define IR_SAVE_CFG (1<<0) /* add info about CFG */
#define IR_SAVE_CFG_MAP (1<<1) /* add info about CFG block assignment */
#define IR_SAVE_USE_LISTS (1<<2) /* add info about def->use lists */
#define IR_SAVE_RULES (1<<3) /* add info about selected code-generation rules */
#define IR_SAVE_REGS (1<<4) /* add info about selected registers */
void ir_print_proto(const ir_ctx *ctx, ir_ref proto, FILE *f);
void ir_save(const ir_ctx *ctx, uint32_t save_flags, FILE *f);
/* IR debug dump API (implementation in ir_dump.c) */
void ir_dump(const ir_ctx *ctx, FILE *f);
void ir_dump_dot(const ir_ctx *ctx, const char *name, FILE *f);
void ir_dump_use_lists(const ir_ctx *ctx, FILE *f);
void ir_dump_cfg(ir_ctx *ctx, FILE *f);
void ir_dump_cfg_map(const ir_ctx *ctx, FILE *f);
void ir_dump_live_ranges(const ir_ctx *ctx, FILE *f);
void ir_dump_codegen(const ir_ctx *ctx, FILE *f);
/* IR to C conversion (implementation in ir_emit_c.c) */
int ir_emit_c(ir_ctx *ctx, const char *name, FILE *f);
void ir_emit_c_func_decl(const char *name, uint32_t flags, ir_type ret_type, uint32_t params_count, const uint8_t *param_types, FILE *f);
void ir_emit_c_sym_decl(const char *name, uint32_t flags, FILE *f);
/* IR to LLVM conversion (implementation in ir_emit_llvm.c) */
int ir_emit_llvm(ir_ctx *ctx, const char *name, FILE *f);
void ir_emit_llvm_func_decl(const char *name, uint32_t flags, ir_type ret_type, uint32_t params_count, const uint8_t *param_types, FILE *f);
void ir_emit_llvm_sym_decl(const char *name, uint32_t flags, FILE *f);
/* IR verification API (implementation in ir_check.c) */
bool ir_check(const ir_ctx *ctx);
void ir_consistency_check(void);
/* Code patching (implementation in ir_patch.c) */
int ir_patch(const void *code, size_t size, uint32_t jmp_table_size, const void *from_addr, const void *to_addr);
/* CPU information (implementation in ir_cpuinfo.c) */
#if defined(IR_TARGET_X86) || defined(IR_TARGET_X64)
# define IR_X86_SSE2 (1<<0)
# define IR_X86_SSE3 (1<<1)
# define IR_X86_SSSE3 (1<<2)
# define IR_X86_SSE41 (1<<3)
# define IR_X86_SSE42 (1<<4)
# define IR_X86_AVX (1<<5)
# define IR_X86_AVX2 (1<<6)
# define IR_X86_BMI1 (1<<7)
# define IR_X86_CLDEMOTE (1<<8)
#endif
uint32_t ir_cpuinfo(void);
/* Deoptimization helpers */
const void *ir_emit_exitgroup(uint32_t first_exit_point, uint32_t exit_points_per_group, const void *exit_addr, ir_code_buffer *code_buffer, size_t *size_ptr);
/* A reference IR JIT compiler */
IR_ALWAYS_INLINE void *ir_jit_compile(ir_ctx *ctx, int opt_level, size_t *size)
{
if (opt_level == 0) {
if (ctx->flags & IR_OPT_FOLDING) {
// IR_ASSERT(0 && "IR_OPT_FOLDING is incompatible with -O0");
return NULL;
}
ctx->flags &= ~(IR_OPT_CFG | IR_OPT_CODEGEN);
ir_build_def_use_lists(ctx);
if (!ir_build_cfg(ctx)
|| !ir_match(ctx)
|| !ir_assign_virtual_registers(ctx)
|| !ir_compute_dessa_moves(ctx)) {
return NULL;
}
return ir_emit_code(ctx, size);
} else if (opt_level == 1 || opt_level == 2) {
if (!(ctx->flags & IR_OPT_FOLDING)) {
// IR_ASSERT(0 && "IR_OPT_FOLDING must be set in ir_init() for -O1 and -O2");
return NULL;
}
ctx->flags |= IR_OPT_CFG | IR_OPT_CODEGEN;
ir_build_def_use_lists(ctx);
if (opt_level == 2
&& !ir_sccp(ctx)) {
return NULL;
}
if (!ir_build_cfg(ctx)
|| !ir_build_dominators_tree(ctx)
|| !ir_find_loops(ctx)
|| !ir_gcm(ctx)
|| !ir_schedule(ctx)
|| !ir_match(ctx)
|| !ir_assign_virtual_registers(ctx)
|| !ir_compute_live_ranges(ctx)
|| !ir_coalesce(ctx)
|| !ir_reg_alloc(ctx)
|| !ir_schedule_blocks(ctx)) {
return NULL;
}
return ir_emit_code(ctx, size);
} else {
// IR_ASSERT(0 && "wrong optimization level");
return NULL;
}
}
#define IR_ERROR_CODE_MEM_OVERFLOW 1
#define IR_ERROR_FIXED_STACK_FRAME_OVERFLOW 2
#define IR_ERROR_UNSUPPORTED_CODE_RULE 3
#define IR_ERROR_LINK 4
#define IR_ERROR_ENCODE 5
/* IR Memmory Allocation */
#ifndef ir_mem_malloc
# define ir_mem_malloc malloc
#endif
#ifndef ir_mem_calloc
# define ir_mem_calloc calloc
#endif
#ifndef ir_mem_realloc
# define ir_mem_realloc realloc
#endif
#ifndef ir_mem_free
# define ir_mem_free free
#endif
#ifndef ir_mem_pmalloc
# define ir_mem_pmalloc malloc
#endif
#ifndef ir_mem_pcalloc
# define ir_mem_pcalloc calloc
#endif
#ifndef ir_mem_prealloc
# define ir_mem_prealloc realloc
#endif
#ifndef ir_mem_pfree
# define ir_mem_pfree free
#endif
void *ir_mem_mmap(size_t size);
int ir_mem_unmap(void *ptr, size_t size);
int ir_mem_protect(void *ptr, size_t size);
int ir_mem_unprotect(void *ptr, size_t size);