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ruby--ruby/yjit_asm.c
Alan Wu 26063d3954 YJIT: Initialize code buffer with PUSH DS
PUSH DS triggers the #UD processor exception in 64-bit mode, which the
OS translates to a SIGILL. Unlike INT3, this triggers the usual crash
reporter, which makes failures easier to notice. When there is a
debugger attached, the PUSH DS pauses execution just like INT3.
2021-12-05 10:26:35 -05:00

1832 lines
52 KiB
C

// This file is a fragment of the yjit.o compilation unit. See yjit.c.
//
// Note that the definition for some of these functions don't specify
// static inline, but their declaration in yjit_asm.h do. The resulting
// linkage is the same as if they both specify. The relevant sections in
// N1256 is 6.2.2p4, 6.2.2p5, and 6.7.4p5.
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <stdarg.h>
#include <stdint.h>
#include <assert.h>
#include <errno.h>
// For mmapp(), sysconf()
#ifndef _WIN32
#include <unistd.h>
#include <sys/mman.h>
#endif
#include "yjit_asm.h"
// Compute the number of bits needed to encode a signed value
uint32_t sig_imm_size(int64_t imm)
{
// Compute the smallest size this immediate fits in
if (imm >= INT8_MIN && imm <= INT8_MAX)
return 8;
if (imm >= INT16_MIN && imm <= INT16_MAX)
return 16;
if (imm >= INT32_MIN && imm <= INT32_MAX)
return 32;
return 64;
}
// Compute the number of bits needed to encode an unsigned value
uint32_t unsig_imm_size(uint64_t imm)
{
// Compute the smallest size this immediate fits in
if (imm <= UINT8_MAX)
return 8;
else if (imm <= UINT16_MAX)
return 16;
else if (imm <= UINT32_MAX)
return 32;
return 64;
}
x86opnd_t mem_opnd(uint32_t num_bits, x86opnd_t base_reg, int32_t disp)
{
bool is_iprel = base_reg.as.reg.reg_type == REG_IP;
x86opnd_t opnd = {
OPND_MEM,
num_bits,
.as.mem = { base_reg.as.reg.reg_no, 0, 0, false, is_iprel, disp }
};
return opnd;
}
x86opnd_t mem_opnd_sib(uint32_t num_bits, x86opnd_t base_reg, x86opnd_t index_reg, int32_t scale, int32_t disp)
{
uint8_t scale_exp;
switch (scale) {
case 8:
scale_exp = 3;
break;
case 4:
scale_exp = 2;
break;
case 2:
scale_exp = 1;
break;
case 1:
scale_exp = 0;
break;
default:
rb_bug("yjit: scale not one of 1,2,4,8");
break;
}
bool is_iprel = base_reg.as.reg.reg_type == REG_IP;
x86opnd_t opnd = {
OPND_MEM,
num_bits,
.as.mem = {
.base_reg_no = base_reg.as.reg.reg_no,
.idx_reg_no = index_reg.as.reg.reg_no,
.has_idx = 1,
.scale_exp = scale_exp,
.is_iprel = is_iprel,
.disp = disp
}
};
return opnd;
}
static x86opnd_t resize_opnd(x86opnd_t opnd, uint32_t num_bits)
{
assert (num_bits % 8 == 0);
x86opnd_t sub = opnd;
sub.num_bits = num_bits;
return sub;
}
x86opnd_t imm_opnd(int64_t imm)
{
x86opnd_t opnd = {
OPND_IMM,
sig_imm_size(imm),
.as.imm = imm
};
return opnd;
}
x86opnd_t const_ptr_opnd(const void *ptr)
{
x86opnd_t opnd = {
OPND_IMM,
64,
.as.unsig_imm = (uint64_t)ptr
};
return opnd;
}
// Align the current write position to a multiple of bytes
static uint8_t *align_ptr(uint8_t *ptr, uint32_t multiple)
{
// Compute the pointer modulo the given alignment boundary
uint32_t rem = ((uint32_t)(uintptr_t)ptr) % multiple;
// If the pointer is already aligned, stop
if (rem == 0)
return ptr;
// Pad the pointer by the necessary amount to align it
uint32_t pad = multiple - rem;
return ptr + pad;
}
// Allocate a block of executable memory
static uint8_t *alloc_exec_mem(uint32_t mem_size)
{
#ifndef _WIN32
uint8_t *mem_block;
// On Linux
#if defined(MAP_FIXED_NOREPLACE) && defined(_SC_PAGESIZE)
// Align the requested address to page size
uint32_t page_size = (uint32_t)sysconf(_SC_PAGESIZE);
uint8_t *req_addr = align_ptr((uint8_t*)&alloc_exec_mem, page_size);
do {
// Try to map a chunk of memory as executable
mem_block = (uint8_t*)mmap(
(void*)req_addr,
mem_size,
PROT_READ | PROT_EXEC,
MAP_PRIVATE | MAP_ANONYMOUS | MAP_FIXED_NOREPLACE,
-1,
0
);
// If we succeeded, stop
if (mem_block != MAP_FAILED) {
break;
}
// +4MB
req_addr += 4 * 1024 * 1024;
} while (req_addr < (uint8_t*)&alloc_exec_mem + INT32_MAX);
// On MacOS and other platforms
#else
// Try to map a chunk of memory as executable
mem_block = (uint8_t*)mmap(
(void*)alloc_exec_mem,
mem_size,
PROT_READ | PROT_EXEC,
MAP_PRIVATE | MAP_ANONYMOUS,
-1,
0
);
#endif
// Fallback
if (mem_block == MAP_FAILED) {
// Try again without the address hint (e.g., valgrind)
mem_block = (uint8_t*)mmap(
NULL,
mem_size,
PROT_READ | PROT_EXEC,
MAP_PRIVATE | MAP_ANONYMOUS,
-1,
0
);
}
// Check that the memory mapping was successful
if (mem_block == MAP_FAILED) {
perror("mmap call failed");
exit(-1);
}
codeblock_t block;
codeblock_t *cb = &block;
cb_init(cb, mem_block, mem_size);
// Fill the executable memory with PUSH DS (0x1E) so that
// executing uninitialized memory will fault with #UD in
// 64-bit mode.
cb_mark_all_writeable(cb);
memset(mem_block, 0x1E, mem_size);
cb_mark_all_executable(cb);
return mem_block;
#else
// Windows not supported for now
return NULL;
#endif
}
// Initialize a code block object
void cb_init(codeblock_t *cb, uint8_t *mem_block, uint32_t mem_size)
{
assert (mem_block);
cb->mem_block_ = mem_block;
cb->mem_size = mem_size;
cb->write_pos = 0;
cb->num_labels = 0;
cb->num_refs = 0;
cb->current_aligned_write_pos = ALIGNED_WRITE_POSITION_NONE;
}
// Set the current write position
void cb_set_pos(codeblock_t *cb, uint32_t pos)
{
// Assert here since while assembler functions do bounds checking, there is
// nothing stopping users from taking out an out-of-bounds pointer and
// doing bad accesses with it.
assert (pos < cb->mem_size);
cb->write_pos = pos;
}
// Align the current write position to a multiple of bytes
void cb_align_pos(codeblock_t *cb, uint32_t multiple)
{
// Compute the pointer modulo the given alignment boundary
uint8_t *ptr = cb_get_write_ptr(cb);
uint8_t *aligned_ptr = align_ptr(ptr, multiple);
const uint32_t write_pos = cb->write_pos;
// Pad the pointer by the necessary amount to align it
ptrdiff_t pad = aligned_ptr - ptr;
cb_set_pos(cb, write_pos + (int32_t)pad);
}
// Set the current write position from a pointer
void cb_set_write_ptr(codeblock_t *cb, uint8_t *code_ptr)
{
intptr_t pos = code_ptr - cb->mem_block_;
assert (pos < cb->mem_size);
cb_set_pos(cb, (uint32_t)pos);
}
// Get a direct pointer into the executable memory block
uint8_t *cb_get_ptr(const codeblock_t *cb, uint32_t index)
{
if (index < cb->mem_size) {
return &cb->mem_block_[index];
}
else {
return NULL;
}
}
// Get a direct pointer to the current write position
uint8_t *cb_get_write_ptr(const codeblock_t *cb)
{
return cb_get_ptr(cb, cb->write_pos);
}
// Write a byte at the current position
void cb_write_byte(codeblock_t *cb, uint8_t byte)
{
assert (cb->mem_block_);
if (cb->write_pos < cb->mem_size) {
cb_mark_position_writeable(cb, cb->write_pos);
cb->mem_block_[cb->write_pos] = byte;
cb->write_pos++;
}
else {
cb->dropped_bytes = true;
}
}
// Write multiple bytes starting from the current position
void cb_write_bytes(codeblock_t *cb, uint32_t num_bytes, ...)
{
va_list va;
va_start(va, num_bytes);
for (uint32_t i = 0; i < num_bytes; ++i)
{
uint8_t byte = va_arg(va, int);
cb_write_byte(cb, byte);
}
va_end(va);
}
// Write a signed integer over a given number of bits at the current position
void cb_write_int(codeblock_t *cb, uint64_t val, uint32_t num_bits)
{
assert (num_bits > 0);
assert (num_bits % 8 == 0);
// Switch on the number of bits
switch (num_bits) {
case 8:
cb_write_byte(cb, (uint8_t)val);
break;
case 16:
cb_write_bytes(
cb,
2,
(uint8_t)((val >> 0) & 0xFF),
(uint8_t)((val >> 8) & 0xFF)
);
break;
case 32:
cb_write_bytes(
cb,
4,
(uint8_t)((val >> 0) & 0xFF),
(uint8_t)((val >> 8) & 0xFF),
(uint8_t)((val >> 16) & 0xFF),
(uint8_t)((val >> 24) & 0xFF)
);
break;
default:
{
// Compute the size in bytes
uint32_t num_bytes = num_bits / 8;
// Write out the bytes
for (uint32_t i = 0; i < num_bytes; ++i)
{
uint8_t byte_val = (uint8_t)(val & 0xFF);
cb_write_byte(cb, byte_val);
val >>= 8;
}
}
}
}
// Allocate a new label with a given name
uint32_t cb_new_label(codeblock_t *cb, const char *name)
{
//if (hasASM)
// writeString(to!string(label) ~ ":");
assert (cb->num_labels < MAX_LABELS);
// Allocate the new label
uint32_t label_idx = cb->num_labels++;
// This label doesn't have an address yet
cb->label_addrs[label_idx] = 0;
cb->label_names[label_idx] = name;
return label_idx;
}
// Write a label at the current address
void cb_write_label(codeblock_t *cb, uint32_t label_idx)
{
assert (label_idx < MAX_LABELS);
cb->label_addrs[label_idx] = cb->write_pos;
}
// Add a label reference at the current write position
void cb_label_ref(codeblock_t *cb, uint32_t label_idx)
{
assert (label_idx < MAX_LABELS);
assert (cb->num_refs < MAX_LABEL_REFS);
// Keep track of the reference
cb->label_refs[cb->num_refs] = (labelref_t){ cb->write_pos, label_idx };
cb->num_refs++;
}
// Link internal label references
void cb_link_labels(codeblock_t *cb)
{
uint32_t orig_pos = cb->write_pos;
// For each label reference
for (uint32_t i = 0; i < cb->num_refs; ++i)
{
uint32_t ref_pos = cb->label_refs[i].pos;
uint32_t label_idx = cb->label_refs[i].label_idx;
assert (ref_pos < cb->mem_size);
assert (label_idx < MAX_LABELS);
uint32_t label_addr = cb->label_addrs[label_idx];
assert (label_addr < cb->mem_size);
// Compute the offset from the reference's end to the label
int64_t offset = (int64_t)label_addr - (int64_t)(ref_pos + 4);
cb_set_pos(cb, ref_pos);
cb_write_int(cb, offset, 32);
}
cb->write_pos = orig_pos;
// Clear the label positions and references
cb->num_labels = 0;
cb->num_refs = 0;
}
// Check if an operand needs a REX byte to be encoded
static bool rex_needed(x86opnd_t opnd)
{
if (opnd.type == OPND_NONE || opnd.type == OPND_IMM)
{
return false;
}
if (opnd.type == OPND_REG)
{
return (
opnd.as.reg.reg_no > 7 ||
(opnd.num_bits == 8 && opnd.as.reg.reg_no >= 4 && opnd.as.reg.reg_no <= 7)
);
}
if (opnd.type == OPND_MEM)
{
return (opnd.as.mem.base_reg_no > 7) || (opnd.as.mem.has_idx && opnd.as.mem.idx_reg_no > 7);
}
rb_bug("unreachable");
}
// Check if an SIB byte is needed to encode this operand
static bool sib_needed(x86opnd_t opnd)
{
if (opnd.type != OPND_MEM)
return false;
return (
opnd.as.mem.has_idx ||
opnd.as.mem.base_reg_no == RSP.as.reg.reg_no ||
opnd.as.mem.base_reg_no == R12.as.reg.reg_no
);
}
// Compute the size of the displacement field needed for a memory operand
static uint32_t disp_size(x86opnd_t opnd)
{
assert (opnd.type == OPND_MEM);
// If using RIP as the base, use disp32
if (opnd.as.mem.is_iprel)
{
return 32;
}
// Compute the required displacement size
if (opnd.as.mem.disp != 0)
{
uint32_t num_bits = sig_imm_size(opnd.as.mem.disp);
assert (num_bits <= 32 && "displacement does not fit in 32 bits");
// x86 can only encode 8-bit and 32-bit displacements
if (num_bits == 16)
num_bits = 32;;
return num_bits;
}
// If EBP or RBP or R13 is used as the base, displacement must be encoded
if (opnd.as.mem.base_reg_no == RBP.as.reg.reg_no ||
opnd.as.mem.base_reg_no == R13.as.reg.reg_no)
{
return 8;
}
return 0;
}
// Write the REX byte
static void cb_write_rex(
codeblock_t *cb,
bool w_flag,
uint8_t reg_no,
uint8_t idx_reg_no,
uint8_t rm_reg_no
)
{
// 0 1 0 0 w r x b
// w - 64-bit operand size flag
// r - MODRM.reg extension
// x - SIB.index extension
// b - MODRM.rm or SIB.base extension
uint8_t w = w_flag? 1:0;
uint8_t r = (reg_no & 8)? 1:0;
uint8_t x = (idx_reg_no & 8)? 1:0;
uint8_t b = (rm_reg_no & 8)? 1:0;
// Encode and write the REX byte
uint8_t rexByte = 0x40 + (w << 3) + (r << 2) + (x << 1) + (b);
cb_write_byte(cb, rexByte);
}
// Write an opcode byte with an embedded register operand
static void cb_write_opcode(codeblock_t *cb, uint8_t opcode, x86opnd_t reg)
{
// Write the reg field into the opcode byte
uint8_t op_byte = opcode | (reg.as.reg.reg_no & 7);
cb_write_byte(cb, op_byte);
}
// Encode an RM instruction
static void cb_write_rm(
codeblock_t *cb,
bool szPref,
bool rexW,
x86opnd_t r_opnd,
x86opnd_t rm_opnd,
uint8_t opExt,
uint32_t op_len,
...)
{
assert (op_len > 0 && op_len <= 3);
assert (r_opnd.type == OPND_REG || r_opnd.type == OPND_NONE);
// Flag to indicate the REX prefix is needed
bool need_rex = rexW || rex_needed(r_opnd) || rex_needed(rm_opnd);
// Flag to indicate SIB byte is needed
bool need_sib = sib_needed(r_opnd) || sib_needed(rm_opnd);
// Add the operand-size prefix, if needed
if (szPref == true)
cb_write_byte(cb, 0x66);
// Add the REX prefix, if needed
if (need_rex)
{
// 0 1 0 0 w r x b
// w - 64-bit operand size flag
// r - MODRM.reg extension
// x - SIB.index extension
// b - MODRM.rm or SIB.base extension
uint8_t w = rexW? 1:0;
uint8_t r;
if (r_opnd.type != OPND_NONE)
r = (r_opnd.as.reg.reg_no & 8)? 1:0;
else
r = 0;
uint8_t x;
if (need_sib && rm_opnd.as.mem.has_idx)
x = (rm_opnd.as.mem.idx_reg_no & 8)? 1:0;
else
x = 0;
uint8_t b;
if (rm_opnd.type == OPND_REG)
b = (rm_opnd.as.reg.reg_no & 8)? 1:0;
else if (rm_opnd.type == OPND_MEM)
b = (rm_opnd.as.mem.base_reg_no & 8)? 1:0;
else
b = 0;
// Encode and write the REX byte
uint8_t rex_byte = 0x40 + (w << 3) + (r << 2) + (x << 1) + (b);
cb_write_byte(cb, rex_byte);
}
// Write the opcode bytes to the code block
va_list va;
va_start(va, op_len);
for (uint32_t i = 0; i < op_len; ++i)
{
uint8_t byte = va_arg(va, int);
cb_write_byte(cb, byte);
}
va_end(va);
// MODRM.mod (2 bits)
// MODRM.reg (3 bits)
// MODRM.rm (3 bits)
assert (
!(opExt != 0xFF && r_opnd.type != OPND_NONE) &&
"opcode extension and register operand present"
);
// Encode the mod field
uint8_t mod;
if (rm_opnd.type == OPND_REG)
{
mod = 3;
}
else
{
uint32_t dsize = disp_size(rm_opnd);
if (dsize == 0 || rm_opnd.as.mem.is_iprel)
mod = 0;
else if (dsize == 8)
mod = 1;
else if (dsize == 32)
mod = 2;
else
rb_bug("unreachable");
}
// Encode the reg field
uint8_t reg;
if (opExt != 0xFF)
reg = opExt;
else if (r_opnd.type == OPND_REG)
reg = r_opnd.as.reg.reg_no & 7;
else
reg = 0;
// Encode the rm field
uint8_t rm;
if (rm_opnd.type == OPND_REG)
{
rm = rm_opnd.as.reg.reg_no & 7;
}
else
{
if (need_sib)
rm = 4;
else
rm = rm_opnd.as.mem.base_reg_no & 7;
}
// Encode and write the ModR/M byte
uint8_t rm_byte = (mod << 6) + (reg << 3) + (rm);
cb_write_byte(cb, rm_byte);
// Add the SIB byte, if needed
if (need_sib)
{
// SIB.scale (2 bits)
// SIB.index (3 bits)
// SIB.base (3 bits)
assert (rm_opnd.type == OPND_MEM);
// Encode the scale value
uint8_t scale = rm_opnd.as.mem.scale_exp;
// Encode the index value
uint8_t index;
if (!rm_opnd.as.mem.has_idx)
index = 4;
else
index = rm_opnd.as.mem.idx_reg_no & 7;
// Encode the base register
uint8_t base = rm_opnd.as.mem.base_reg_no & 7;
// Encode and write the SIB byte
uint8_t sib_byte = (scale << 6) + (index << 3) + (base);
cb_write_byte(cb, sib_byte);
}
// Add the displacement
if (rm_opnd.type == OPND_MEM)
{
uint32_t dsize = disp_size(rm_opnd);
if (dsize > 0)
cb_write_int(cb, rm_opnd.as.mem.disp, dsize);
}
}
// Encode a mul-like single-operand RM instruction
static void write_rm_unary(
codeblock_t *cb,
const char *mnem,
uint8_t opMemReg8,
uint8_t opMemRegPref,
uint8_t opExt,
x86opnd_t opnd)
{
// Write a disassembly string
//cb.writeASM(mnem, opnd);
// Check the size of opnd0
uint32_t opndSize;
if (opnd.type == OPND_REG || opnd.type == OPND_MEM)
opndSize = opnd.num_bits;
else
rb_bug("yjit: invalid operand");
assert (opndSize == 8 || opndSize == 16 || opndSize == 32 || opndSize == 64);
bool szPref = opndSize == 16;
bool rexW = opndSize == 64;
if (opndSize == 8)
cb_write_rm(cb, false, false, NO_OPND, opnd, opExt, 1, opMemReg8);
else
cb_write_rm(cb, szPref, rexW, NO_OPND, opnd, opExt, 1, opMemRegPref);
}
// Encode an add-like RM instruction with multiple possible encodings
static void cb_write_rm_multi(
codeblock_t *cb,
const char *mnem,
uint8_t opMemReg8,
uint8_t opMemRegPref,
uint8_t opRegMem8,
uint8_t opRegMemPref,
uint8_t opMemImm8,
uint8_t opMemImmSml,
uint8_t opMemImmLrg,
uint8_t opExtImm,
x86opnd_t opnd0,
x86opnd_t opnd1)
{
assert (opnd0.type == OPND_REG || opnd0.type == OPND_MEM);
/*
// Write disassembly string
if (!opnd1.isNone)
cb.writeASM(mnem, opnd0, opnd1);
else
cb.writeASM(mnem, opnd0);
*/
// Check the size of opnd0
uint32_t opndSize = opnd0.num_bits;
// Check the size of opnd1
if (opnd1.type == OPND_REG || opnd1.type == OPND_MEM)
{
assert (opnd1.num_bits == opndSize && "operand size mismatch");
}
else if (opnd1.type == OPND_IMM)
{
assert (opnd1.num_bits <= opndSize);
}
assert (opndSize == 8 || opndSize == 16 || opndSize == 32 || opndSize == 64);
bool szPref = opndSize == 16;
bool rexW = opndSize == 64;
// R/M + Reg
if ((opnd0.type == OPND_MEM && opnd1.type == OPND_REG) ||
(opnd0.type == OPND_REG && opnd1.type == OPND_REG))
{
// R/M is opnd0
if (opndSize == 8)
cb_write_rm(cb, false, false, opnd1, opnd0, 0xFF, 1, opMemReg8);
else
cb_write_rm(cb, szPref, rexW, opnd1, opnd0, 0xFF, 1, opMemRegPref);
}
// Reg + R/M
else if (opnd0.type == OPND_REG && opnd1.type == OPND_MEM)
{
// R/M is opnd1
if (opndSize == 8)
cb_write_rm(cb, false, false, opnd0, opnd1, 0xFF, 1, opRegMem8);
else
cb_write_rm(cb, szPref, rexW, opnd0, opnd1, 0xFF, 1, opRegMemPref);
}
// R/M + Imm
else if (opnd1.type == OPND_IMM)
{
// 8-bit immediate
if (opnd1.num_bits <= 8)
{
if (opndSize == 8)
cb_write_rm(cb, false, false, NO_OPND, opnd0, opExtImm, 1, opMemImm8);
else
cb_write_rm(cb, szPref, rexW, NO_OPND, opnd0, opExtImm, 1, opMemImmSml);
cb_write_int(cb, opnd1.as.imm, 8);
}
// 32-bit immediate
else if (opnd1.num_bits <= 32)
{
assert (opnd1.num_bits <= opndSize && "immediate too large for dst");
cb_write_rm(cb, szPref, rexW, NO_OPND, opnd0, opExtImm, 1, opMemImmLrg);
cb_write_int(cb, opnd1.as.imm, (opndSize > 32)? 32:opndSize);
}
// Immediate too large
else
{
assert (false && "immediate value too large");
}
}
// Invalid operands
else
{
assert (false && "invalid operand combination");
}
}
// Encode a single-operand shift instruction
static void cb_write_shift(
codeblock_t *cb,
const char *mnem,
uint8_t opMemOnePref,
uint8_t opMemClPref,
uint8_t opMemImmPref,
uint8_t opExt,
x86opnd_t opnd0,
x86opnd_t opnd1)
{
// Write a disassembly string
//cb.writeASM(mnem, opnd0, opnd1);
// Check the size of opnd0
uint32_t opndSize;
if (opnd0.type == OPND_REG || opnd0.type == OPND_MEM)
opndSize = opnd0.num_bits;
else
rb_bug("yjit: shift: invalid first operand");
assert (opndSize == 16 || opndSize == 32 || opndSize == 64);
bool szPref = opndSize == 16;
bool rexW = opndSize == 64;
if (opnd1.type == OPND_IMM)
{
if (opnd1.as.imm == 1)
{
cb_write_rm(cb, szPref, rexW, NO_OPND, opnd0, opExt, 1, opMemOnePref);
}
else
{
assert (opnd1.num_bits <= 8);
cb_write_rm(cb, szPref, rexW, NO_OPND, opnd0, opExt, 1, opMemImmPref);
cb_write_byte(cb, (uint8_t)opnd1.as.imm);
}
}
/*
else if (opnd1.isReg && opnd1.reg == CL)
{
cb.writeRMInstr!('l', opExt, opMemClPref)(szPref, rexW, opnd0, X86Opnd.NONE);
}
*/
else
{
assert (false);
}
}
// Encode a relative jump to a label (direct or conditional)
// Note: this always encodes a 32-bit offset
static void cb_write_jcc(codeblock_t *cb, const char *mnem, uint8_t op0, uint8_t op1, uint32_t label_idx)
{
//cb.writeASM(mnem, label);
// Write the opcode
if (op0 != 0xFF)
cb_write_byte(cb, op0);
cb_write_byte(cb, op1);
// Add a reference to the label
cb_label_ref(cb, label_idx);
// Relative 32-bit offset to be patched
cb_write_int(cb, 0, 32);
}
// Encode a relative jump to a pointer at a 32-bit offset (direct or conditional)
static void cb_write_jcc_ptr(codeblock_t *cb, const char *mnem, uint8_t op0, uint8_t op1, uint8_t *dst_ptr)
{
//cb.writeASM(mnem, label);
// Write the opcode
if (op0 != 0xFF)
cb_write_byte(cb, op0);
cb_write_byte(cb, op1);
// Pointer to the end of this jump instruction
uint8_t *end_ptr = cb_get_ptr(cb, cb->write_pos + 4);
// Compute the jump offset
int64_t rel64 = (int64_t)(dst_ptr - end_ptr);
if (rel64 >= INT32_MIN && rel64 <= INT32_MAX) {
// Write the relative 32-bit jump offset
cb_write_int(cb, (int32_t)rel64, 32);
}
else {
// Offset doesn't fit in 4 bytes. Report error.
cb->dropped_bytes = true;
}
}
// Encode a conditional move instruction
static void cb_write_cmov(codeblock_t *cb, const char *mnem, uint8_t opcode1, x86opnd_t dst, x86opnd_t src)
{
//cb.writeASM(mnem, dst, src);
assert (dst.type == OPND_REG);
assert (src.type == OPND_REG || src.type == OPND_MEM);
assert (dst.num_bits >= 16 && "invalid dst reg size in cmov");
bool szPref = dst.num_bits == 16;
bool rexW = dst.num_bits == 64;
cb_write_rm(cb, szPref, rexW, dst, src, 0xFF, 2, 0x0F, opcode1);
}
// add - Integer addition
void add(codeblock_t *cb, x86opnd_t opnd0, x86opnd_t opnd1)
{
cb_write_rm_multi(
cb,
"add",
0x00, // opMemReg8
0x01, // opMemRegPref
0x02, // opRegMem8
0x03, // opRegMemPref
0x80, // opMemImm8
0x83, // opMemImmSml
0x81, // opMemImmLrg
0x00, // opExtImm
opnd0,
opnd1
);
}
/// and - Bitwise AND
void and(codeblock_t *cb, x86opnd_t opnd0, x86opnd_t opnd1)
{
cb_write_rm_multi(
cb,
"and",
0x20, // opMemReg8
0x21, // opMemRegPref
0x22, // opRegMem8
0x23, // opRegMemPref
0x80, // opMemImm8
0x83, // opMemImmSml
0x81, // opMemImmLrg
0x04, // opExtImm
opnd0,
opnd1
);
}
// call - Call to a pointer with a 32-bit displacement offset
static void call_rel32(codeblock_t *cb, int32_t rel32)
{
//cb.writeASM("call", rel32);
// Write the opcode
cb_write_byte(cb, 0xE8);
// Write the relative 32-bit jump offset
cb_write_int(cb, (int32_t)rel32, 32);
}
// call - Call a pointer, encode with a 32-bit offset if possible
void call_ptr(codeblock_t *cb, x86opnd_t scratch_reg, uint8_t *dst_ptr)
{
assert (scratch_reg.type == OPND_REG);
// Pointer to the end of this call instruction
uint8_t *end_ptr = cb_get_ptr(cb, cb->write_pos + 5);
// Compute the jump offset
int64_t rel64 = (int64_t)(dst_ptr - end_ptr);
// If the offset fits in 32-bit
if (rel64 >= INT32_MIN && rel64 <= INT32_MAX) {
call_rel32(cb, (int32_t)rel64);
return;
}
// Move the pointer into the scratch register and call
mov(cb, scratch_reg, const_ptr_opnd(dst_ptr));
call(cb, scratch_reg);
}
/// call - Call to label with 32-bit offset
void call_label(codeblock_t *cb, uint32_t label_idx)
{
//cb.writeASM("call", label);
// Write the opcode
cb_write_byte(cb, 0xE8);
// Add a reference to the label
cb_label_ref(cb, label_idx);
// Relative 32-bit offset to be patched
cb_write_int(cb, 0, 32);
}
/// call - Indirect call with an R/M operand
void call(codeblock_t *cb, x86opnd_t opnd)
{
//cb.writeASM("call", opnd);
cb_write_rm(cb, false, false, NO_OPND, opnd, 2, 1, 0xFF);
}
/// cmovcc - Conditional move
void cmova(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmova", 0x47, dst, src); }
void cmovae(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovae", 0x43, dst, src); }
void cmovb(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovb", 0x42, dst, src); }
void cmovbe(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovbe", 0x46, dst, src); }
void cmovc(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovc", 0x42, dst, src); }
void cmove(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmove", 0x44, dst, src); }
void cmovg(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovg", 0x4F, dst, src); }
void cmovge(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovge", 0x4D, dst, src); }
void cmovl(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovl", 0x4C, dst, src); }
void cmovle(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovle", 0x4E, dst, src); }
void cmovna(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovna", 0x46, dst, src); }
void cmovnae(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovnae", 0x42, dst, src); }
void cmovnb(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovnb", 0x43, dst, src); }
void cmovnbe(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovnbe", 0x47, dst, src); }
void cmovnc(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovnc", 0x43, dst, src); }
void cmovne(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovne", 0x45, dst, src); }
void cmovng(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovng", 0x4E, dst, src); }
void cmovnge(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovnge", 0x4C, dst, src); }
void cmovnl(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovnl" , 0x4D, dst, src); }
void cmovnle(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovnle", 0x4F, dst, src); }
void cmovno(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovno", 0x41, dst, src); }
void cmovnp(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovnp", 0x4B, dst, src); }
void cmovns(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovns", 0x49, dst, src); }
void cmovnz(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovnz", 0x45, dst, src); }
void cmovo(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovo", 0x40, dst, src); }
void cmovp(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovp", 0x4A, dst, src); }
void cmovpe(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovpe", 0x4A, dst, src); }
void cmovpo(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovpo", 0x4B, dst, src); }
void cmovs(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovs", 0x48, dst, src); }
void cmovz(codeblock_t *cb, x86opnd_t dst, x86opnd_t src) { cb_write_cmov(cb, "cmovz", 0x44, dst, src); }
/// cmp - Compare and set flags
void cmp(codeblock_t *cb, x86opnd_t opnd0, x86opnd_t opnd1)
{
cb_write_rm_multi(
cb,
"cmp",
0x38, // opMemReg8
0x39, // opMemRegPref
0x3A, // opRegMem8
0x3B, // opRegMemPref
0x80, // opMemImm8
0x83, // opMemImmSml
0x81, // opMemImmLrg
0x07, // opExtImm
opnd0,
opnd1
);
}
/// cdq - Convert doubleword to quadword
void cdq(codeblock_t *cb)
{
//cb.writeASM("cdq");
cb_write_byte(cb, 0x99);
}
/// cqo - Convert quadword to octaword
void cqo(codeblock_t *cb)
{
//cb.writeASM("cqo");
cb_write_bytes(cb, 2, 0x48, 0x99);
}
/// Interrupt 3 - trap to debugger
void int3(codeblock_t *cb)
{
//cb.writeASM("INT 3");
cb_write_byte(cb, 0xCC);
}
/*
// div - Unsigned integer division
alias div = writeRMUnary!(
"div",
0xF6, // opMemReg8
0xF7, // opMemRegPref
0x06 // opExt
);
*/
/*
/// divsd - Divide scalar double
alias divsd = writeXMM64!(
"divsd",
0xF2, // prefix
0x0F, // opRegMem0
0x5E // opRegMem1
);
*/
/*
// idiv - Signed integer division
alias idiv = writeRMUnary!(
"idiv",
0xF6, // opMemReg8
0xF7, // opMemRegPref
0x07 // opExt
);
*/
/*
/// imul - Signed integer multiplication with two operands
void imul(CodeBlock cb, X86Opnd opnd0, X86Opnd opnd1)
{
cb.writeASM("imul", opnd0, opnd1);
assert (opnd0.isReg, "invalid first operand");
auto opndSize = opnd0.reg.size;
// Check the size of opnd1
if (opnd1.isReg)
assert (opnd1.reg.size is opndSize, "operand size mismatch");
else if (opnd1.isMem)
assert (opnd1.mem.size is opndSize, "operand size mismatch");
assert (opndSize is 16 || opndSize is 32 || opndSize is 64);
auto szPref = opndSize is 16;
auto rexW = opndSize is 64;
cb.writeRMInstr!('r', 0xFF, 0x0F, 0xAF)(szPref, rexW, opnd0, opnd1);
}
*/
/*
/// imul - Signed integer multiplication with three operands (one immediate)
void imul(CodeBlock cb, X86Opnd opnd0, X86Opnd opnd1, X86Opnd opnd2)
{
cb.writeASM("imul", opnd0, opnd1, opnd2);
assert (opnd0.isReg, "invalid first operand");
auto opndSize = opnd0.reg.size;
// Check the size of opnd1
if (opnd1.isReg)
assert (opnd1.reg.size is opndSize, "operand size mismatch");
else if (opnd1.isMem)
assert (opnd1.mem.size is opndSize, "operand size mismatch");
assert (opndSize is 16 || opndSize is 32 || opndSize is 64);
auto szPref = opndSize is 16;
auto rexW = opndSize is 64;
assert (opnd2.isImm, "invalid third operand");
auto imm = opnd2.imm;
// 8-bit immediate
if (imm.immSize <= 8)
{
cb.writeRMInstr!('r', 0xFF, 0x6B)(szPref, rexW, opnd0, opnd1);
cb.writeInt(imm.imm, 8);
}
// 32-bit immediate
else if (imm.immSize <= 32)
{
assert (imm.immSize <= opndSize, "immediate too large for dst");
cb.writeRMInstr!('r', 0xFF, 0x69)(szPref, rexW, opnd0, opnd1);
cb.writeInt(imm.imm, min(opndSize, 32));
}
// Immediate too large
else
{
assert (false, "immediate value too large");
}
}
*/
/// jcc - relative jumps to a label
void ja_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "ja" , 0x0F, 0x87, label_idx); }
void jae_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jae" , 0x0F, 0x83, label_idx); }
void jb_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jb" , 0x0F, 0x82, label_idx); }
void jbe_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jbe" , 0x0F, 0x86, label_idx); }
void jc_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jc" , 0x0F, 0x82, label_idx); }
void je_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "je" , 0x0F, 0x84, label_idx); }
void jg_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jg" , 0x0F, 0x8F, label_idx); }
void jge_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jge" , 0x0F, 0x8D, label_idx); }
void jl_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jl" , 0x0F, 0x8C, label_idx); }
void jle_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jle" , 0x0F, 0x8E, label_idx); }
void jna_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jna" , 0x0F, 0x86, label_idx); }
void jnae_label(codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jnae", 0x0F, 0x82, label_idx); }
void jnb_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jnb" , 0x0F, 0x83, label_idx); }
void jnbe_label(codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jnbe", 0x0F, 0x87, label_idx); }
void jnc_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jnc" , 0x0F, 0x83, label_idx); }
void jne_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jne" , 0x0F, 0x85, label_idx); }
void jng_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jng" , 0x0F, 0x8E, label_idx); }
void jnge_label(codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jnge", 0x0F, 0x8C, label_idx); }
void jnl_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jnl" , 0x0F, 0x8D, label_idx); }
void jnle_label(codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jnle", 0x0F, 0x8F, label_idx); }
void jno_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jno" , 0x0F, 0x81, label_idx); }
void jnp_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jnp" , 0x0F, 0x8b, label_idx); }
void jns_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jns" , 0x0F, 0x89, label_idx); }
void jnz_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jnz" , 0x0F, 0x85, label_idx); }
void jo_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jo" , 0x0F, 0x80, label_idx); }
void jp_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jp" , 0x0F, 0x8A, label_idx); }
void jpe_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jpe" , 0x0F, 0x8A, label_idx); }
void jpo_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jpo" , 0x0F, 0x8B, label_idx); }
void js_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "js" , 0x0F, 0x88, label_idx); }
void jz_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jz" , 0x0F, 0x84, label_idx); }
void jmp_label (codeblock_t *cb, uint32_t label_idx) { cb_write_jcc(cb, "jmp" , 0xFF, 0xE9, label_idx); }
/// jcc - relative jumps to a pointer (32-bit offset)
void ja_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "ja" , 0x0F, 0x87, ptr); }
void jae_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jae" , 0x0F, 0x83, ptr); }
void jb_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jb" , 0x0F, 0x82, ptr); }
void jbe_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jbe" , 0x0F, 0x86, ptr); }
void jc_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jc" , 0x0F, 0x82, ptr); }
void je_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "je" , 0x0F, 0x84, ptr); }
void jg_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jg" , 0x0F, 0x8F, ptr); }
void jge_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jge" , 0x0F, 0x8D, ptr); }
void jl_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jl" , 0x0F, 0x8C, ptr); }
void jle_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jle" , 0x0F, 0x8E, ptr); }
void jna_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jna" , 0x0F, 0x86, ptr); }
void jnae_ptr(codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jnae", 0x0F, 0x82, ptr); }
void jnb_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jnb" , 0x0F, 0x83, ptr); }
void jnbe_ptr(codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jnbe", 0x0F, 0x87, ptr); }
void jnc_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jnc" , 0x0F, 0x83, ptr); }
void jne_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jne" , 0x0F, 0x85, ptr); }
void jng_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jng" , 0x0F, 0x8E, ptr); }
void jnge_ptr(codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jnge", 0x0F, 0x8C, ptr); }
void jnl_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jnl" , 0x0F, 0x8D, ptr); }
void jnle_ptr(codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jnle", 0x0F, 0x8F, ptr); }
void jno_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jno" , 0x0F, 0x81, ptr); }
void jnp_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jnp" , 0x0F, 0x8b, ptr); }
void jns_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jns" , 0x0F, 0x89, ptr); }
void jnz_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jnz" , 0x0F, 0x85, ptr); }
void jo_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jo" , 0x0F, 0x80, ptr); }
void jp_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jp" , 0x0F, 0x8A, ptr); }
void jpe_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jpe" , 0x0F, 0x8A, ptr); }
void jpo_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jpo" , 0x0F, 0x8B, ptr); }
void js_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "js" , 0x0F, 0x88, ptr); }
void jz_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jz" , 0x0F, 0x84, ptr); }
void jmp_ptr (codeblock_t *cb, uint8_t *ptr) { cb_write_jcc_ptr(cb, "jmp" , 0xFF, 0xE9, ptr); }
/// jmp - Indirect jump near to an R/M operand
void jmp_rm(codeblock_t *cb, x86opnd_t opnd)
{
//cb.writeASM("jmp", opnd);
cb_write_rm(cb, false, false, NO_OPND, opnd, 4, 1, 0xFF);
}
// jmp - Jump with relative 32-bit offset
void jmp32(codeblock_t *cb, int32_t offset)
{
//cb.writeASM("jmp", ((offset > 0)? "+":"-") ~ to!string(offset));
cb_write_byte(cb, 0xE9);
cb_write_int(cb, offset, 32);
}
/// lea - Load Effective Address
void lea(codeblock_t *cb, x86opnd_t dst, x86opnd_t src)
{
//cb.writeASM("lea", dst, src);
assert (dst.num_bits == 64);
cb_write_rm(cb, false, true, dst, src, 0xFF, 1, 0x8D);
}
// Does this number fit in 32 bits and stays the same if you zero extend it to 64 bit?
// If the sign bit is clear, sign extension and zero extension yield the same
// result.
static bool
zero_extendable_32bit(uint64_t number)
{
return number <= UINT32_MAX && (number & (1ull << 31ull)) == 0;
}
/// mov - Data move operation
void mov(codeblock_t *cb, x86opnd_t dst, x86opnd_t src)
{
// R/M + Imm
if (src.type == OPND_IMM)
{
//cb.writeASM("mov", dst, src);
// R + Imm
if (dst.type == OPND_REG)
{
assert (
src.num_bits <= dst.num_bits ||
unsig_imm_size(src.as.imm) <= dst.num_bits
);
// In case the source immediate could be zero extended to be 64
// bit, we can use the 32-bit operands version of the instruction.
// For example, we can turn mov(rax, 0x34) into the equivalent
// mov(eax, 0x34).
if (dst.num_bits == 64 && zero_extendable_32bit(src.as.unsig_imm)) {
if (rex_needed(dst))
cb_write_rex(cb, false, 0, 0, dst.as.reg.reg_no);
cb_write_opcode(cb, 0xB8, dst);
cb_write_int(cb, src.as.imm, 32);
}
else {
if (dst.num_bits == 16)
cb_write_byte(cb, 0x66);
if (rex_needed(dst) || dst.num_bits == 64)
cb_write_rex(cb, dst.num_bits == 64, 0, 0, dst.as.reg.reg_no);
cb_write_opcode(cb, (dst.num_bits == 8)? 0xB0:0xB8, dst);
cb_write_int(cb, src.as.imm, dst.num_bits);
}
}
// M + Imm
else if (dst.type == OPND_MEM)
{
assert (src.num_bits <= dst.num_bits);
if (dst.num_bits == 8)
cb_write_rm(cb, false, false, NO_OPND, dst, 0xFF, 1, 0xC6);
else
cb_write_rm(cb, dst.num_bits == 16, dst.num_bits == 64, NO_OPND, dst, 0, 1, 0xC7);
cb_write_int(cb, src.as.imm, (dst.num_bits > 32)? 32:dst.num_bits);
}
else
{
assert (false);
}
}
else
{
cb_write_rm_multi(
cb,
"mov",
0x88, // opMemReg8
0x89, // opMemRegPref
0x8A, // opRegMem8
0x8B, // opRegMemPref
0xC6, // opMemImm8
0xFF, // opMemImmSml (not available)
0xFF, // opMemImmLrg
0xFF, // opExtImm
dst,
src
);
}
}
/// movsx - Move with sign extension (signed integers)
void movsx(codeblock_t *cb, x86opnd_t dst, x86opnd_t src)
{
assert (dst.type == OPND_REG);
assert (src.type == OPND_REG || src.type == OPND_MEM);
assert (src.num_bits < dst.num_bits);
//cb.writeASM("movsx", dst, src);
if (src.num_bits == 8)
{
cb_write_rm(cb, dst.num_bits == 16, dst.num_bits == 64, dst, src, 0xFF, 2, 0x0F, 0xBE);
}
else if (src.num_bits == 16)
{
cb_write_rm(cb, dst.num_bits == 16, dst.num_bits == 64, dst, src, 0xFF, 2, 0x0F, 0xBF);
}
else if (src.num_bits == 32)
{
cb_write_rm(cb, false, true, dst, src, 0xFF, 1, 0x63);
}
else
{
assert (false);
}
}
/*
/// movzx - Move with zero extension (unsigned values)
void movzx(codeblock_t *cb, x86opnd_t dst, x86opnd_t src)
{
cb.writeASM("movzx", dst, src);
uint32_t dstSize;
if (dst.isReg)
dstSize = dst.reg.size;
else
assert (false, "movzx dst must be a register");
uint32_t srcSize;
if (src.isReg)
srcSize = src.reg.size;
else if (src.isMem)
srcSize = src.mem.size;
else
assert (false);
assert (
srcSize < dstSize,
"movzx: srcSize >= dstSize"
);
if (srcSize is 8)
{
cb.writeRMInstr!('r', 0xFF, 0x0F, 0xB6)(dstSize is 16, dstSize is 64, dst, src);
}
else if (srcSize is 16)
{
cb.writeRMInstr!('r', 0xFF, 0x0F, 0xB7)(dstSize is 16, dstSize is 64, dst, src);
}
else
{
assert (false, "invalid src operand size for movxz");
}
}
*/
// neg - Integer negation (multiplication by -1)
void neg(codeblock_t *cb, x86opnd_t opnd)
{
write_rm_unary(
cb,
"neg",
0xF6, // opMemReg8
0xF7, // opMemRegPref
0x03, // opExt
opnd
);
}
// nop - Noop, one or multiple bytes long
void nop(codeblock_t *cb, uint32_t length)
{
switch (length) {
case 0:
break;
case 1:
//cb.writeASM("nop1");
cb_write_byte(cb, 0x90);
break;
case 2:
//cb.writeASM("nop2");
cb_write_bytes(cb, 2, 0x66,0x90);
break;
case 3:
//cb.writeASM("nop3");
cb_write_bytes(cb, 3, 0x0F,0x1F,0x00);
break;
case 4:
//cb.writeASM("nop4");
cb_write_bytes(cb, 4, 0x0F,0x1F,0x40,0x00);
break;
case 5:
//cb.writeASM("nop5");
cb_write_bytes(cb, 5, 0x0F,0x1F,0x44,0x00,0x00);
break;
case 6:
//cb.writeASM("nop6");
cb_write_bytes(cb, 6, 0x66,0x0F,0x1F,0x44,0x00,0x00);
break;
case 7:
//cb.writeASM("nop7");
cb_write_bytes(cb, 7, 0x0F,0x1F,0x80,0x00,0x00,0x00,0x00);
break;
case 8:
//cb.writeASM("nop8");
cb_write_bytes(cb, 8, 0x0F,0x1F,0x84,0x00,0x00,0x00,0x00,0x00);
break;
case 9:
//cb.writeASM("nop9");
cb_write_bytes(cb, 9, 0x66,0x0F,0x1F,0x84,0x00,0x00,0x00,0x00,0x00);
break;
default:
{
uint32_t written = 0;
while (written + 9 <= length)
{
nop(cb, 9);
written += 9;
}
nop(cb, length - written);
}
break;
}
}
// not - Bitwise NOT
void not(codeblock_t *cb, x86opnd_t opnd)
{
write_rm_unary(
cb,
"not",
0xF6, // opMemReg8
0xF7, // opMemRegPref
0x02, // opExt
opnd
);
}
/// or - Bitwise OR
void or(codeblock_t *cb, x86opnd_t opnd0, x86opnd_t opnd1)
{
cb_write_rm_multi(
cb,
"or",
0x08, // opMemReg8
0x09, // opMemRegPref
0x0A, // opRegMem8
0x0B, // opRegMemPref
0x80, // opMemImm8
0x83, // opMemImmSml
0x81, // opMemImmLrg
0x01, // opExtImm
opnd0,
opnd1
);
}
/// pop - Pop a register off the stack
void pop(codeblock_t *cb, x86opnd_t opnd)
{
assert (opnd.num_bits == 64);
//cb.writeASM("pop", opnd);
if (opnd.type == OPND_REG) {
if (rex_needed(opnd))
cb_write_rex(cb, false, 0, 0, opnd.as.reg.reg_no);
cb_write_opcode(cb, 0x58, opnd);
}
else if (opnd.type == OPND_MEM) {
cb_write_rm(cb, false, false, NO_OPND, opnd, 0, 1, 0x8F);
}
else {
assert(false && "unexpected operand type");
}
}
/// popfq - Pop the flags register (64-bit)
void popfq(codeblock_t *cb)
{
//cb.writeASM("popfq");
// REX.W + 0x9D
cb_write_bytes(cb, 2, 0x48, 0x9D);
}
/// push - Push an operand on the stack
void push(codeblock_t *cb, x86opnd_t opnd)
{
assert (opnd.num_bits == 64);
//cb.writeASM("push", opnd);
if (opnd.type == OPND_REG) {
if (rex_needed(opnd))
cb_write_rex(cb, false, 0, 0, opnd.as.reg.reg_no);
cb_write_opcode(cb, 0x50, opnd);
}
else if (opnd.type == OPND_MEM) {
cb_write_rm(cb, false, false, NO_OPND, opnd, 6, 1, 0xFF);
}
else {
assert(false && "unexpected operand type");
}
}
/// pushfq - Push the flags register (64-bit)
void pushfq(codeblock_t *cb)
{
//cb.writeASM("pushfq");
cb_write_byte(cb, 0x9C);
}
/// ret - Return from call, popping only the return address
void ret(codeblock_t *cb)
{
//cb.writeASM("ret");
cb_write_byte(cb, 0xC3);
}
// sal - Shift arithmetic left
void sal(codeblock_t *cb, x86opnd_t opnd0, x86opnd_t opnd1)
{
cb_write_shift(
cb,
"sal",
0xD1, // opMemOnePref,
0xD3, // opMemClPref,
0xC1, // opMemImmPref,
0x04,
opnd0,
opnd1
);
}
/// sar - Shift arithmetic right (signed)
void sar(codeblock_t *cb, x86opnd_t opnd0, x86opnd_t opnd1)
{
cb_write_shift(
cb,
"sar",
0xD1, // opMemOnePref,
0xD3, // opMemClPref,
0xC1, // opMemImmPref,
0x07,
opnd0,
opnd1
);
}
// shl - Shift logical left
void shl(codeblock_t *cb, x86opnd_t opnd0, x86opnd_t opnd1)
{
cb_write_shift(
cb,
"shl",
0xD1, // opMemOnePref,
0xD3, // opMemClPref,
0xC1, // opMemImmPref,
0x04,
opnd0,
opnd1
);
}
/// shr - Shift logical right (unsigned)
void shr(codeblock_t *cb, x86opnd_t opnd0, x86opnd_t opnd1)
{
cb_write_shift(
cb,
"shr",
0xD1, // opMemOnePref,
0xD3, // opMemClPref,
0xC1, // opMemImmPref,
0x05,
opnd0,
opnd1
);
}
/// sub - Integer subtraction
void sub(codeblock_t *cb, x86opnd_t opnd0, x86opnd_t opnd1)
{
cb_write_rm_multi(
cb,
"sub",
0x28, // opMemReg8
0x29, // opMemRegPref
0x2A, // opRegMem8
0x2B, // opRegMemPref
0x80, // opMemImm8
0x83, // opMemImmSml
0x81, // opMemImmLrg
0x05, // opExtImm
opnd0,
opnd1
);
}
/// test - Logical Compare
void test(codeblock_t *cb, x86opnd_t rm_opnd, x86opnd_t test_opnd)
{
assert (rm_opnd.type == OPND_REG || rm_opnd.type == OPND_MEM);
assert (test_opnd.type == OPND_REG || test_opnd.type == OPND_IMM);
// If the second operand is an immediate
if (test_opnd.type == OPND_IMM)
{
x86opnd_t imm_opnd = test_opnd;
if (imm_opnd.as.imm >= 0)
{
assert (unsig_imm_size(imm_opnd.as.unsig_imm) <= 32);
assert (unsig_imm_size(imm_opnd.as.unsig_imm) <= rm_opnd.num_bits);
// Use the smallest operand size possible
rm_opnd = resize_opnd(rm_opnd, unsig_imm_size(imm_opnd.as.unsig_imm));
if (rm_opnd.num_bits == 8)
{
cb_write_rm(cb, false, false, NO_OPND, rm_opnd, 0x00, 1, 0xF6);
cb_write_int(cb, imm_opnd.as.imm, rm_opnd.num_bits);
}
else
{
cb_write_rm(cb, rm_opnd.num_bits == 16, false, NO_OPND, rm_opnd, 0x00, 1, 0xF7);
cb_write_int(cb, imm_opnd.as.imm, rm_opnd.num_bits);
}
}
else
{
// This mode only applies to 64-bit R/M operands with 32-bit signed immediates
assert (imm_opnd.as.imm < 0);
assert (sig_imm_size(imm_opnd.as.imm) <= 32);
assert (rm_opnd.num_bits == 64);
cb_write_rm(cb, false, true, NO_OPND, rm_opnd, 0x00, 1, 0xF7);
cb_write_int(cb, imm_opnd.as.imm, 32);
}
}
else
{
assert (test_opnd.num_bits == rm_opnd.num_bits);
if (rm_opnd.num_bits == 8)
{
cb_write_rm(cb, false, false, test_opnd, rm_opnd, 0xFF, 1, 0x84);
}
else
{
cb_write_rm(cb, rm_opnd.num_bits == 16, rm_opnd.num_bits == 64, test_opnd, rm_opnd, 0xFF, 1, 0x85);
}
}
}
/// Undefined opcode
void ud2(codeblock_t *cb)
{
cb_write_bytes(cb, 2, 0x0F, 0x0B);
}
/// xchg - Exchange Register/Memory with Register
void xchg(codeblock_t *cb, x86opnd_t rm_opnd, x86opnd_t r_opnd)
{
assert (rm_opnd.num_bits == 64);
assert (r_opnd.num_bits == 64);
assert (rm_opnd.type == OPND_REG);
assert (r_opnd.type == OPND_REG);
// If we're exchanging with RAX
if (rm_opnd.type == OPND_REG && rm_opnd.as.reg.reg_no == RAX.as.reg.reg_no)
{
// Write the REX byte
cb_write_rex(cb, rm_opnd.num_bits == 64, 0, 0, r_opnd.as.reg.reg_no);
// Write the opcode and register number
cb_write_byte(cb, 0x90 + (r_opnd.as.reg.reg_no & 7));
}
else
{
cb_write_rm(cb, rm_opnd.num_bits == 16, rm_opnd.num_bits == 64, r_opnd, rm_opnd, 0xFF, 1, 0x87);
}
}
/// xor - Exclusive bitwise OR
void xor(codeblock_t *cb, x86opnd_t opnd0, x86opnd_t opnd1)
{
cb_write_rm_multi(
cb,
"xor",
0x30, // opMemReg8
0x31, // opMemRegPref
0x32, // opRegMem8
0x33, // opRegMemPref
0x80, // opMemImm8
0x83, // opMemImmSml
0x81, // opMemImmLrg
0x06, // opExtImm
opnd0,
opnd1
);
}
// LOCK - lock prefix for atomic shared memory operations
void cb_write_lock_prefix(codeblock_t *cb)
{
cb_write_byte(cb, 0xF0);
}
void cb_mark_all_writeable(codeblock_t * cb)
{
if (mprotect(cb->mem_block_, cb->mem_size, PROT_READ | PROT_WRITE)) {
fprintf(stderr, "Couldn't make JIT page (%p) writeable, errno: %s", (void *)cb->mem_block_, strerror(errno));
abort();
}
}
void cb_mark_position_writeable(codeblock_t * cb, uint32_t write_pos)
{
uint32_t pagesize = (uint32_t)sysconf(_SC_PAGESIZE);
uint32_t aligned_position = (write_pos / pagesize) * pagesize;
if (cb->current_aligned_write_pos != aligned_position) {
cb->current_aligned_write_pos = aligned_position;
void *const page_addr = cb_get_ptr(cb, aligned_position);
if (mprotect(page_addr, pagesize, PROT_READ | PROT_WRITE)) {
fprintf(stderr, "Couldn't make JIT page (%p) writeable, errno: %s", page_addr, strerror(errno));
abort();
}
}
}
void cb_mark_all_executable(codeblock_t * cb)
{
cb->current_aligned_write_pos = ALIGNED_WRITE_POSITION_NONE;
if (mprotect(cb->mem_block_, cb->mem_size, PROT_READ | PROT_EXEC)) {
fprintf(stderr, "Couldn't make JIT page (%p) executable, errno: %s", (void *)cb->mem_block_, strerror(errno));
abort();
}
}