/*
* Stack-less Just-In-Time compiler
*
* Copyright 2009-2012 Zoltan Herczeg (hzmester@freemail.hu). All rights reserved.
*
* Redistribution and use in source and binary forms, with or without modification, are
* permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this list of
* conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice, this list
* of conditions and the following disclaimer in the documentation and/or other materials
* provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDER(S) AND CONTRIBUTORS ``AS IS'' AND ANY
* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT
* SHALL THE COPYRIGHT HOLDER(S) OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
* TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
* BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
* ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef _SLJIT_LIR_H_
#define _SLJIT_LIR_H_
/*
------------------------------------------------------------------------
Stack-Less JIT compiler for multiple architectures (x86, ARM, PowerPC)
------------------------------------------------------------------------
Short description
Advantages:
- The execution can be continued from any LIR instruction. In other
words, it is possible to jump to any label from anywhere, even from
a code fragment, which is compiled later, if both compiled code
shares the same context. See sljit_emit_enter for more details
- Supports self modifying code: target of (conditional) jump and call
instructions and some constant values can be dynamically modified
during runtime
- although it is not suggested to do it frequently
- can be used for inline caching: save an important value once
in the instruction stream
- since this feature limits the optimization possibilities, a
special flag must be passed at compile time when these
instructions are emitted
- A fixed stack space can be allocated for local variables
- The compiler is thread-safe
- The compiler is highly configurable through preprocessor macros.
You can disable unneeded features (multithreading in single
threaded applications), and you can use your own system functions
(including memory allocators). See sljitConfig.h
Disadvantages:
- No automatic register allocation, and temporary results are
not stored on the stack. (hence the name comes)
- Limited number of registers (only 6+4 integer registers, max 3+2
scratch, max 3+2 saved and 6 floating point registers)
In practice:
- This approach is very effective for interpreters
- One of the saved registers typically points to a stack interface
- It can jump to any exception handler anytime (even if it belongs
to another function)
- Hot paths can be modified during runtime reflecting the changes
of the fastest execution path of the dynamic language
- SLJIT supports complex memory addressing modes
- mainly position and context independent code (except some cases)
For valgrind users:
- pass --smc-check=all argument to valgrind, since JIT is a "self-modifying code"
*/
#if !(defined SLJIT_NO_DEFAULT_CONFIG && SLJIT_NO_DEFAULT_CONFIG)
#include "sljitConfig.h"
#endif
/* The following header file defines useful macros for fine tuning
sljit based code generators. They are listed in the beginning
of sljitConfigInternal.h */
#include "sljitConfigInternal.h"
/* --------------------------------------------------------------------- */
/* Error codes */
/* --------------------------------------------------------------------- */
/* Indicates no error. */
#define SLJIT_SUCCESS 0
/* After the call of sljit_generate_code(), the error code of the compiler
is set to this value to avoid future sljit calls (in debug mode at least).
The complier should be freed after sljit_generate_code(). */
#define SLJIT_ERR_COMPILED 1
/* Cannot allocate non executable memory. */
#define SLJIT_ERR_ALLOC_FAILED 2
/* Cannot allocate executable memory.
Only for sljit_generate_code() */
#define SLJIT_ERR_EX_ALLOC_FAILED 3
/* return value for SLJIT_CONFIG_UNSUPPORTED empty architecture. */
#define SLJIT_ERR_UNSUPPORTED 4
/* --------------------------------------------------------------------- */
/* Registers */
/* --------------------------------------------------------------------- */
#define SLJIT_UNUSED 0
/* Scratch (temporary) registers whose may not preserve their values
across function calls. */
#define SLJIT_SCRATCH_REG1 1
#define SLJIT_SCRATCH_REG2 2
#define SLJIT_SCRATCH_REG3 3
/* Note: extra registers cannot be used for memory addressing. */
/* Note: on x86-32, these registers are emulated (using stack
loads & stores). */
#define SLJIT_TEMPORARY_EREG1 4
#define SLJIT_TEMPORARY_EREG2 5
/* Saved registers whose preserve their values across function calls. */
#define SLJIT_SAVED_REG1 6
#define SLJIT_SAVED_REG2 7
#define SLJIT_SAVED_REG3 8
/* Note: extra registers cannot be used for memory addressing. */
/* Note: on x86-32, these registers are emulated (using stack
loads & stores). */
#define SLJIT_SAVED_EREG1 9
#define SLJIT_SAVED_EREG2 10
/* Read-only register (cannot be the destination of an operation).
Only SLJIT_MEM1(SLJIT_LOCALS_REG) addressing mode is allowed since
several ABIs has certain limitations about the stack layout. However
sljit_get_local_base() can be used to obtain the offset of a value
on the stack. */
#define SLJIT_LOCALS_REG 11
/* Number of registers. */
#define SLJIT_NO_TMP_REGISTERS 5
#define SLJIT_NO_GEN_REGISTERS 5
#define SLJIT_NO_REGISTERS 11
/* Return with machine word. */
#define SLJIT_RETURN_REG SLJIT_SCRATCH_REG1
/* x86 prefers specific registers for special purposes. In case of shift
by register it supports only SLJIT_SCRATCH_REG3 for shift argument
(which is the src2 argument of sljit_emit_op2). If another register is
used, sljit must exchange data between registers which cause a minor
slowdown. Other architectures has no such limitation. */
#define SLJIT_PREF_SHIFT_REG SLJIT_SCRATCH_REG3
/* --------------------------------------------------------------------- */
/* Floating point registers */
/* --------------------------------------------------------------------- */
/* Note: SLJIT_UNUSED as destination is not valid for floating point
operations, since they cannot be used for setting flags. */
/* Floating point operations are performed on double or
single precision values. */
#define SLJIT_FLOAT_REG1 1
#define SLJIT_FLOAT_REG2 2
#define SLJIT_FLOAT_REG3 3
#define SLJIT_FLOAT_REG4 4
#define SLJIT_FLOAT_REG5 5
#define SLJIT_FLOAT_REG6 6
#define SLJIT_NO_FLOAT_REGISTERS 6
/* --------------------------------------------------------------------- */
/* Main structures and functions */
/* --------------------------------------------------------------------- */
struct sljit_memory_fragment {
struct sljit_memory_fragment *next;
sljit_uw used_size;
/* Must be aligned to sljit_sw. */
sljit_ub memory[1];
};
struct sljit_label {
struct sljit_label *next;
sljit_uw addr;
/* The maximum size difference. */
sljit_uw size;
};
struct sljit_jump {
struct sljit_jump *next;
sljit_uw addr;
sljit_sw flags;
union {
sljit_uw target;
struct sljit_label* label;
} u;
};
struct sljit_const {
struct sljit_const *next;
sljit_uw addr;
};
struct sljit_compiler {
sljit_si error;
struct sljit_label *labels;
struct sljit_jump *jumps;
struct sljit_const *consts;
struct sljit_label *last_label;
struct sljit_jump *last_jump;
struct sljit_const *last_const;
struct sljit_memory_fragment *buf;
struct sljit_memory_fragment *abuf;
/* Used local registers. */
sljit_si scratches;
/* Used saved registers. */
sljit_si saveds;
/* Local stack size. */
sljit_si local_size;
/* Code size. */
sljit_uw size;
/* For statistical purposes. */
sljit_uw executable_size;
#if (defined SLJIT_CONFIG_X86_32 && SLJIT_CONFIG_X86_32)
sljit_si args;
sljit_si locals_offset;
sljit_si scratches_start;
sljit_si saveds_start;
#endif
#if (defined SLJIT_CONFIG_X86_64 && SLJIT_CONFIG_X86_64)
sljit_si mode32;
#endif
#if (defined SLJIT_CONFIG_X86_32 && SLJIT_CONFIG_X86_32) || (defined SLJIT_CONFIG_X86_64 && SLJIT_CONFIG_X86_64)
sljit_si flags_saved;
#endif
#if (defined SLJIT_CONFIG_ARM_V5 && SLJIT_CONFIG_ARM_V5)
/* Constant pool handling. */
sljit_uw *cpool;
sljit_ub *cpool_unique;
sljit_uw cpool_diff;
sljit_uw cpool_fill;
/* Other members. */
/* Contains pointer, "ldr pc, [...]" pairs. */
sljit_uw patches;
#endif
#if (defined SLJIT_CONFIG_ARM_V5 && SLJIT_CONFIG_ARM_V5) || (defined SLJIT_CONFIG_ARM_V7 && SLJIT_CONFIG_ARM_V7)
/* Temporary fields. */
sljit_uw shift_imm;
sljit_si cache_arg;
sljit_sw cache_argw;
#endif
#if (defined SLJIT_CONFIG_ARM_THUMB2 && SLJIT_CONFIG_ARM_THUMB2)
sljit_si cache_arg;
sljit_sw cache_argw;
#endif
#if (defined SLJIT_CONFIG_PPC_32 && SLJIT_CONFIG_PPC_32) || (defined SLJIT_CONFIG_PPC_64 && SLJIT_CONFIG_PPC_64)
sljit_sw imm;
sljit_si cache_arg;
sljit_sw cache_argw;
#endif
#if (defined SLJIT_CONFIG_MIPS_32 && SLJIT_CONFIG_MIPS_32)
sljit_si delay_slot;
sljit_si cache_arg;
sljit_sw cache_argw;
#endif
#if (defined SLJIT_CONFIG_SPARC_32 && SLJIT_CONFIG_SPARC_32)
sljit_si delay_slot;
sljit_si cache_arg;
sljit_sw cache_argw;
#endif
#if (defined SLJIT_CONFIG_TILEGX && SLJIT_CONFIG_TILEGX)
sljit_si cache_arg;
sljit_sw cache_argw;
#endif
#if (defined SLJIT_VERBOSE && SLJIT_VERBOSE)
FILE* verbose;
#endif
#if (defined SLJIT_DEBUG && SLJIT_DEBUG)
/* Local size passed to the functions. */
sljit_si logical_local_size;
#endif
#if (defined SLJIT_VERBOSE && SLJIT_VERBOSE) || (defined SLJIT_DEBUG && SLJIT_DEBUG)
sljit_si skip_checks;
#endif
};
/* --------------------------------------------------------------------- */
/* Main functions */
/* --------------------------------------------------------------------- */
/* Creates an sljit compiler.
Returns NULL if failed. */
SLJIT_API_FUNC_ATTRIBUTE struct sljit_compiler* sljit_create_compiler(void);
/* Free everything except the compiled machine code. */
SLJIT_API_FUNC_ATTRIBUTE void sljit_free_compiler(struct sljit_compiler *compiler);
/* Returns the current error code. If an error is occurred, future sljit
calls which uses the same compiler argument returns early with the same
error code. Thus there is no need for checking the error after every
call, it is enough to do it before the code is compiled. Removing
these checks increases the performance of the compiling process. */
static SLJIT_INLINE sljit_si sljit_get_compiler_error(struct sljit_compiler *compiler) { return compiler->error; }
/*
Allocate a small amount of memory. The size must be <= 64 bytes on 32 bit,
and <= 128 bytes on 64 bit architectures. The memory area is owned by the
compiler, and freed by sljit_free_compiler. The returned pointer is
sizeof(sljit_sw) aligned. Excellent for allocating small blocks during
the compiling, and no need to worry about freeing them. The size is
enough to contain at most 16 pointers. If the size is outside of the range,
the function will return with NULL. However, this return value does not
indicate that there is no more memory (does not set the current error code
of the compiler to out-of-memory status).
*/
SLJIT_API_FUNC_ATTRIBUTE void* sljit_alloc_memory(struct sljit_compiler *compiler, sljit_si size);
#if (defined SLJIT_VERBOSE && SLJIT_VERBOSE)
/* Passing NULL disables verbose. */
SLJIT_API_FUNC_ATTRIBUTE void sljit_compiler_verbose(struct sljit_compiler *compiler, FILE* verbose);
#endif
SLJIT_API_FUNC_ATTRIBUTE void* sljit_generate_code(struct sljit_compiler *compiler);
SLJIT_API_FUNC_ATTRIBUTE void sljit_free_code(void* code);
/*
After the machine code generation is finished we can retrieve the allocated
executable memory size, although this area may not be fully filled with
instructions depending on some optimizations. This function is useful only
for statistical purposes.
Before a successful code generation, this function returns with 0.
*/
static SLJIT_INLINE sljit_uw sljit_get_generated_code_size(struct sljit_compiler *compiler) { return compiler->executable_size; }
/* Instruction generation. Returns with any error code. If there is no
error, they return with SLJIT_SUCCESS. */
/*
The executable code is basically a function call from the viewpoint of
the C language. The function calls must obey to the ABI (Application
Binary Interface) of the platform, which specify the purpose of machine
registers and stack handling among other things. The sljit_emit_enter
function emits the necessary instructions for setting up a new context
for the executable code and moves function arguments to the saved
registers. The number of arguments are specified in the "args"
parameter and the first argument goes to SLJIT_SAVED_REG1, the second
goes to SLJIT_SAVED_REG2 and so on. The number of scratch and
saved registers are passed in "scratches" and "saveds" arguments
respectively. Since the saved registers contains the arguments,
"args" must be less or equal than "saveds". The sljit_emit_enter
is also capable of allocating a stack space for local variables. The
"local_size" argument contains the size in bytes of this local area
and its staring address is stored in SLJIT_LOCALS_REG. However
the SLJIT_LOCALS_REG is not necessary the machine stack pointer.
The memory bytes between SLJIT_LOCALS_REG (inclusive) and
SLJIT_LOCALS_REG + local_size (exclusive) can be modified freely
until the function returns. The stack space is uninitialized.
Note: every call of sljit_emit_enter and sljit_set_context
overwrites the previous context. */
#define SLJIT_MAX_LOCAL_SIZE 65536
SLJIT_API_FUNC_ATTRIBUTE sljit_si sljit_emit_enter(struct sljit_compiler *compiler,
sljit_si args, sljit_si scratches, sljit_si saveds, sljit_si local_size);
/* The machine code has a context (which contains the local stack space size,
number of used registers, etc.) which initialized by sljit_emit_enter. Several
functions (like sljit_emit_return) requres this context to be able to generate
the appropriate code. However, some code fragments (like inline cache) may have
no normal entry point so their context is unknown for the compiler. Using the
function below we can specify their context.
Note: every call of sljit_emit_enter and sljit_set_context overwrites
the previous context. */
SLJIT_API_FUNC_ATTRIBUTE void sljit_set_context(struct sljit_compiler *compiler,
sljit_si args, sljit_si scratches, sljit_si saveds, sljit_si local_size);
/* Return from machine code. The op argument can be SLJIT_UNUSED which means the
function does not return with anything or any opcode between SLJIT_MOV and
SLJIT_MOV_P (see sljit_emit_op1). As for src and srcw they must be 0 if op
is SLJIT_UNUSED, otherwise see below the description about source and
destination arguments. */
SLJIT_API_FUNC_ATTRIBUTE sljit_si sljit_emit_return(struct sljit_compiler *compiler, sljit_si op,
sljit_si src, sljit_sw srcw);
/* Fast calling mechanism for utility functions (see SLJIT_FAST_CALL). All registers and
even the stack frame is passed to the callee. The return address is preserved in
dst/dstw by sljit_emit_fast_enter (the type of the value stored by this function
is sljit_p), and sljit_emit_fast_return can use this as a return value later. */
/* Note: only for sljit specific, non ABI compilant calls. Fast, since only a few machine
instructions are needed. Excellent for small uility functions, where saving registers
and setting up a new stack frame would cost too much performance. However, it is still
possible to return to the address of the caller (or anywhere else). */
/* Note: flags are not changed (unlike sljit_emit_enter / sljit_emit_return). */
/* Note: although sljit_emit_fast_return could be replaced by an ijump, it is not suggested,
since many architectures do clever branch prediction on call / return instruction pairs. */
SLJIT_API_FUNC_ATTRIBUTE sljit_si sljit_emit_fast_enter(struct sljit_compiler *compiler, sljit_si dst, sljit_sw dstw);
SLJIT_API_FUNC_ATTRIBUTE sljit_si sljit_emit_fast_return(struct sljit_compiler *compiler, sljit_si src, sljit_sw srcw);
/*
Source and destination values for arithmetical instructions
imm - a simple immediate value (cannot be used as a destination)
reg - any of the registers (immediate argument must be 0)
[imm] - absolute immediate memory address
[reg+imm] - indirect memory address
[reg+(reg<<imm)] - indirect indexed memory address (shift must be between 0 and 3)
useful for (byte, half, int, sljit_sw) array access
(fully supported by both x86 and ARM architectures, and cheap operation on others)
*/
/*
IMPORATNT NOTE: memory access MUST be naturally aligned except
SLJIT_UNALIGNED macro is defined and its value is 1.
length | alignment
---------+-----------
byte | 1 byte (any physical_address is accepted)
half | 2 byte (physical_address & 0x1 == 0)
int | 4 byte (physical_address & 0x3 == 0)
word | 4 byte if SLJIT_32BIT_ARCHITECTURE is defined and its value is 1
| 8 byte if SLJIT_64BIT_ARCHITECTURE is defined and its value is 1
pointer | size of sljit_p type (4 byte on 32 bit machines, 4 or 8 byte
| on 64 bit machines)
Note: Different architectures have different addressing limitations.
A single instruction is enough for the following addressing
modes. Other adrressing modes are emulated by instruction
sequences. This information could help to improve those code
generators which focuses only a few architectures.
x86: [reg+imm], -2^32+1 <= imm <= 2^32-1 (full address space on x86-32)
[reg+(reg<<imm)] is supported
[imm], -2^32+1 <= imm <= 2^32-1 is supported
Write-back is not supported
arm: [reg+imm], -4095 <= imm <= 4095 or -255 <= imm <= 255 for signed
bytes, any halfs or floating point values)
[reg+(reg<<imm)] is supported
Write-back is supported
arm-t2: [reg+imm], -255 <= imm <= 4095
[reg+(reg<<imm)] is supported
Write back is supported only for [reg+imm], where -255 <= imm <= 255
ppc: [reg+imm], -65536 <= imm <= 65535. 64 bit loads/stores and 32 bit
signed load on 64 bit requires immediates divisible by 4.
[reg+imm] is not supported for signed 8 bit values.
[reg+reg] is supported
Write-back is supported except for one instruction: 32 bit signed
load with [reg+imm] addressing mode on 64 bit.
mips: [reg+imm], -65536 <= imm <= 65535
sparc: [reg+imm], -4096 <= imm <= 4095
[reg+reg] is supported
*/
/* Register output: simply the name of the register.
For destination, you can use SLJIT_UNUSED as well. */
#define SLJIT_MEM 0x100
#define SLJIT_MEM0() (SLJIT_MEM)
#define SLJIT_MEM1(r1) (SLJIT_MEM | (r1))
#define SLJIT_MEM2(r1, r2) (SLJIT_MEM | (r1) | ((r2) << 4))
#define SLJIT_IMM 0x200
/* Set 32 bit operation mode (I) on 64 bit CPUs. The flag is totally ignored on
32 bit CPUs. If this flag is set for an arithmetic operation, it uses only the
lower 32 bit of the input register(s), and set the CPU status flags according
to the 32 bit result. The higher 32 bits are undefined for both the input and
output. However, the CPU might not ignore those higher 32 bits, like MIPS, which
expects it to be the sign extension of the lower 32 bit. All 32 bit operations
are undefined, if this condition is not fulfilled. Therefore, when SLJIT_INT_OP
is specified, all register arguments must be the result of other operations with
the same SLJIT_INT_OP flag. In other words, although a register can hold either
a 64 or 32 bit value, these values cannot be mixed. The only exceptions are
SLJIT_IMOV and SLJIT_IMOVU (SLJIT_MOV_SI/SLJIT_MOV_UI/SLJIT_MOVU_SI/SLJIT_MOV_UI
with SLJIT_INT_OP flag) which can convert any source argument to SLJIT_INT_OP
compatible result. This conversion might be unnecessary on some CPUs like x86-64,
since the upper 32 bit is always ignored. In this case SLJIT is clever enough
to not generate any instructions if the source and destination operands are the
same registers. Affects sljit_emit_op0, sljit_emit_op1 and sljit_emit_op2. */
#define SLJIT_INT_OP 0x100
/* Single precision mode (SP). This flag is similar to SLJIT_INT_OP, just
it applies to floating point registers (it is even the same bit). When
this flag is passed, the CPU performs single precision floating point
operations. Similar to SLJIT_INT_OP, all register arguments must be the
result of other floating point operations with this flag. Affects
sljit_emit_fop1, sljit_emit_fop2 and sljit_emit_fcmp. */
#define SLJIT_SINGLE_OP 0x100
/* Common CPU status flags for all architectures (x86, ARM, PPC)
- carry flag
- overflow flag
- zero flag
- negative/positive flag (depends on arc)
On mips, these flags are emulated by software. */
/* By default, the instructions may, or may not set the CPU status flags.
Forcing to set or keep status flags can be done with the following flags: */
/* Note: sljit tries to emit the minimum number of instructions. Using these
flags can increase them, so use them wisely to avoid unnecessary code generation. */
/* Set Equal (Zero) status flag (E). */
#define SLJIT_SET_E 0x0200
/* Set signed status flag (S). */
#define SLJIT_SET_S 0x0400
/* Set unsgined status flag (U). */
#define SLJIT_SET_U 0x0800
/* Set signed overflow flag (O). */
#define SLJIT_SET_O 0x1000
/* Set carry flag (C).
Note: Kinda unsigned overflow, but behaves differently on various cpus. */
#define SLJIT_SET_C 0x2000
/* Do not modify the flags (K).
Note: This flag cannot be combined with any other SLJIT_SET_* flag. */
#define SLJIT_KEEP_FLAGS 0x4000
/* Notes:
- you cannot postpone conditional jump instructions except if noted that
the instruction does not set flags (See: SLJIT_KEEP_FLAGS).
- flag combinations: '|' means 'logical or'. */
/* Flags: - (never set any flags)
Note: breakpoint instruction is not supported by all architectures (namely ppc)
It falls back to SLJIT_NOP in those cases. */
#define SLJIT_BREAKPOINT 0
/* Flags: - (never set any flags)
Note: may or may not cause an extra cycle wait
it can even decrease the runtime in a few cases. */
#define SLJIT_NOP 1
/* Flags: - (may destroy flags)
Unsigned multiplication of SLJIT_SCRATCH_REG1 and SLJIT_SCRATCH_REG2.
Result goes to SLJIT_SCRATCH_REG2:SLJIT_SCRATCH_REG1 (high:low) word */
#define SLJIT_UMUL 2
/* Flags: - (may destroy flags)
Signed multiplication of SLJIT_SCRATCH_REG1 and SLJIT_SCRATCH_REG2.
Result goes to SLJIT_SCRATCH_REG2:SLJIT_SCRATCH_REG1 (high:low) word */
#define SLJIT_SMUL 3
/* Flags: I - (may destroy flags)
Unsigned divide of the value in SLJIT_SCRATCH_REG1 by the value in SLJIT_SCRATCH_REG2.
The result is placed in SLJIT_SCRATCH_REG1 and the remainder goes to SLJIT_SCRATCH_REG2.
Note: if SLJIT_SCRATCH_REG2 contains 0, the behaviour is undefined. */
#define SLJIT_UDIV 4
#define SLJIT_IUDIV (SLJIT_UDIV | SLJIT_INT_OP)
/* Flags: I - (may destroy flags)
Signed divide of the value in SLJIT_SCRATCH_REG1 by the value in SLJIT_SCRATCH_REG2.
The result is placed in SLJIT_SCRATCH_REG1 and the remainder goes to SLJIT_SCRATCH_REG2.
Note: if SLJIT_SCRATCH_REG2 contains 0, the behaviour is undefined. */
#define SLJIT_SDIV 5
#define SLJIT_ISDIV (SLJIT_SDIV | SLJIT_INT_OP)
SLJIT_API_FUNC_ATTRIBUTE sljit_si sljit_emit_op0(struct sljit_compiler *compiler, sljit_si op);
/* Notes for MOV instructions:
U = Mov with update (post form). If source or destination defined as SLJIT_MEM1(r1)
or SLJIT_MEM2(r1, r2), r1 is increased by the sum of r2 and the constant argument
UB = unsigned byte (8 bit)
SB = signed byte (8 bit)
UH = unsigned half (16 bit)
SH = signed half (16 bit)
UI = unsigned int (32 bit)
SI = signed int (32 bit)
P = pointer (sljit_p) size */
/* Flags: - (never set any flags) */
#define SLJIT_MOV 6
/* Flags: I - (never set any flags) */
#define SLJIT_MOV_UB 7
#define SLJIT_IMOV_UB (SLJIT_MOV_UB | SLJIT_INT_OP)
/* Flags: I - (never set any flags) */
#define SLJIT_MOV_SB 8
#define SLJIT_IMOV_SB (SLJIT_MOV_SB | SLJIT_INT_OP)
/* Flags: I - (never set any flags) */
#define SLJIT_MOV_UH 9
#define SLJIT_IMOV_UH (SLJIT_MOV_UH | SLJIT_INT_OP)
/* Flags: I - (never set any flags) */
#define SLJIT_MOV_SH 10
#define SLJIT_IMOV_SH (SLJIT_MOV_SH | SLJIT_INT_OP)
/* Flags: I - (never set any flags)
Note: see SLJIT_INT_OP for further details. */
#define SLJIT_MOV_UI 11
/* No SLJIT_INT_OP form, since it the same as SLJIT_IMOVU. */
/* Flags: I - (never set any flags)
Note: see SLJIT_INT_OP for further details. */
#define SLJIT_MOV_SI 12
#define SLJIT_IMOV (SLJIT_MOV_SI | SLJIT_INT_OP)
/* Flags: - (never set any flags) */
#define SLJIT_MOV_P 13
/* Flags: - (never set any flags) */
#define SLJIT_MOVU 14
/* Flags: I - (never set any flags) */
#define SLJIT_MOVU_UB 15
#define SLJIT_IMOVU_UB (SLJIT_MOVU_UB | SLJIT_INT_OP)
/* Flags: I - (never set any flags) */
#define SLJIT_MOVU_SB 16
#define SLJIT_IMOVU_SB (SLJIT_MOVU_SB | SLJIT_INT_OP)
/* Flags: I - (never set any flags) */
#define SLJIT_MOVU_UH 17
#define SLJIT_IMOVU_UH (SLJIT_MOVU_UH | SLJIT_INT_OP)
/* Flags: I - (never set any flags) */
#define SLJIT_MOVU_SH 18
#define SLJIT_IMOVU_SH (SLJIT_MOVU_SH | SLJIT_INT_OP)
/* Flags: I - (never set any flags)
Note: see SLJIT_INT_OP for further details. */
#define SLJIT_MOVU_UI 19
/* No SLJIT_INT_OP form, since it the same as SLJIT_IMOVU. */
/* Flags: I - (never set any flags)
Note: see SLJIT_INT_OP for further details. */
#define SLJIT_MOVU_SI 20
#define SLJIT_IMOVU (SLJIT_MOVU_SI | SLJIT_INT_OP)
/* Flags: - (never set any flags) */
#define SLJIT_MOVU_P 21
/* Flags: I | E | K */
#define SLJIT_NOT 22
#define SLJIT_INOT (SLJIT_NOT | SLJIT_INT_OP)
/* Flags: I | E | O | K */
#define SLJIT_NEG 23
#define SLJIT_INEG (SLJIT_NEG | SLJIT_INT_OP)
/* Count leading zeroes
Flags: I | E | K
Important note! Sparc 32 does not support K flag, since
the required popc instruction is introduced only in sparc 64. */
#define SLJIT_CLZ 24
#define SLJIT_ICLZ (SLJIT_CLZ | SLJIT_INT_OP)
SLJIT_API_FUNC_ATTRIBUTE sljit_si sljit_emit_op1(struct sljit_compiler *compiler, sljit_si op,
sljit_si dst, sljit_sw dstw,
sljit_si src, sljit_sw srcw);
/* Flags: I | E | O | C | K */
#define SLJIT_ADD 25
#define SLJIT_IADD (SLJIT_ADD | SLJIT_INT_OP)
/* Flags: I | C | K */
#define SLJIT_ADDC 26
#define SLJIT_IADDC (SLJIT_ADDC | SLJIT_INT_OP)
/* Flags: I | E | S | U | O | C | K */
#define SLJIT_SUB 27
#define SLJIT_ISUB (SLJIT_SUB | SLJIT_INT_OP)
/* Flags: I | C | K */
#define SLJIT_SUBC 28
#define SLJIT_ISUBC (SLJIT_SUBC | SLJIT_INT_OP)
/* Note: integer mul
Flags: I | O (see SLJIT_C_MUL_*) | K */
#define SLJIT_MUL 29
#define SLJIT_IMUL (SLJIT_MUL | SLJIT_INT_OP)
/* Flags: I | E | K */
#define SLJIT_AND 30
#define SLJIT_IAND (SLJIT_AND | SLJIT_INT_OP)
/* Flags: I | E | K */
#define SLJIT_OR 31
#define SLJIT_IOR (SLJIT_OR | SLJIT_INT_OP)
/* Flags: I | E | K */
#define SLJIT_XOR 32
#define SLJIT_IXOR (SLJIT_XOR | SLJIT_INT_OP)
/* Flags: I | E | K
Let bit_length be the length of the shift operation: 32 or 64.
If src2 is immediate, src2w is masked by (bit_length - 1).
Otherwise, if the content of src2 is outside the range from 0
to bit_length - 1, the operation is undefined. */
#define SLJIT_SHL 33
#define SLJIT_ISHL (SLJIT_SHL | SLJIT_INT_OP)
/* Flags: I | E | K
Let bit_length be the length of the shift operation: 32 or 64.
If src2 is immediate, src2w is masked by (bit_length - 1).
Otherwise, if the content of src2 is outside the range from 0
to bit_length - 1, the operation is undefined. */
#define SLJIT_LSHR 34
#define SLJIT_ILSHR (SLJIT_LSHR | SLJIT_INT_OP)
/* Flags: I | E | K
Let bit_length be the length of the shift operation: 32 or 64.
If src2 is immediate, src2w is masked by (bit_length - 1).
Otherwise, if the content of src2 is outside the range from 0
to bit_length - 1, the operation is undefined. */
#define SLJIT_ASHR 35
#define SLJIT_IASHR (SLJIT_ASHR | SLJIT_INT_OP)
SLJIT_API_FUNC_ATTRIBUTE sljit_si sljit_emit_op2(struct sljit_compiler *compiler, sljit_si op,
sljit_si dst, sljit_sw dstw,
sljit_si src1, sljit_sw src1w,
sljit_si src2, sljit_sw src2w);
/* The following function is a helper function for sljit_emit_op_custom.
It returns with the real machine register index of any SLJIT_SCRATCH
SLJIT_SAVED or SLJIT_LOCALS register.
Note: it returns with -1 for virtual registers (all EREGs on x86-32). */
SLJIT_API_FUNC_ATTRIBUTE sljit_si sljit_get_register_index(sljit_si reg);
/* The following function is a helper function for sljit_emit_op_custom.
It returns with the real machine register index of any SLJIT_FLOAT register.
Note: the index is divided by 2 on ARM 32 bit architectures. */
SLJIT_API_FUNC_ATTRIBUTE sljit_si sljit_get_float_register_index(sljit_si reg);
/* Any instruction can be inserted into the instruction stream by
sljit_emit_op_custom. It has a similar purpose as inline assembly.
The size parameter must match to the instruction size of the target
architecture:
x86: 0 < size <= 15. The instruction argument can be byte aligned.
Thumb2: if size == 2, the instruction argument must be 2 byte aligned.
if size == 4, the instruction argument must be 4 byte aligned.
Otherwise: size must be 4 and instruction argument must be 4 byte aligned. */
SLJIT_API_FUNC_ATTRIBUTE sljit_si sljit_emit_op_custom(struct sljit_compiler *compiler,
void *instruction, sljit_si size);
/* Returns with non-zero if fpu is available. */
SLJIT_API_FUNC_ATTRIBUTE sljit_si sljit_is_fpu_available(void);
/* Note: dst is the left and src is the right operand for SLJIT_FCMP.
Note: NaN check is always performed. If SLJIT_C_FLOAT_UNORDERED is set,
the comparison result is unpredictable.
Flags: SP | E | S (see SLJIT_C_FLOAT_*) */
#define SLJIT_CMPD 36
#define SLJIT_CMPS (SLJIT_CMPD | SLJIT_SINGLE_OP)
/* Flags: SP - (never set any flags) */
#define SLJIT_MOVD 37
#define SLJIT_MOVS (SLJIT_MOVD | SLJIT_SINGLE_OP)
/* Flags: SP - (never set any flags) */
#define SLJIT_NEGD 38
#define SLJIT_NEGS (SLJIT_NEGD | SLJIT_SINGLE_OP)
/* Flags: SP - (never set any flags) */
#define SLJIT_ABSD 39
#define SLJIT_ABSS (SLJIT_ABSD | SLJIT_SINGLE_OP)
SLJIT_API_FUNC_ATTRIBUTE sljit_si sljit_emit_fop1(struct sljit_compiler *compiler, sljit_si op,
sljit_si dst, sljit_sw dstw,
sljit_si src, sljit_sw srcw);
/* Flags: SP - (never set any flags) */
#define SLJIT_ADDD 40
#define SLJIT_ADDS (SLJIT_ADDD | SLJIT_SINGLE_OP)
/* Flags: SP - (never set any flags) */
#define SLJIT_SUBD 41
#define SLJIT_SUBS (SLJIT_SUBD | SLJIT_SINGLE_OP)
/* Flags: SP - (never set any flags) */
#define SLJIT_MULD 42
#define SLJIT_MULS (SLJIT_MULD | SLJIT_SINGLE_OP)
/* Flags: SP - (never set any flags) */
#define SLJIT_DIVD 43
#define SLJIT_DIVS (SLJIT_DIVD | SLJIT_SINGLE_OP)
SLJIT_API_FUNC_ATTRIBUTE sljit_si sljit_emit_fop2(struct sljit_compiler *compiler, sljit_si op,
sljit_si dst, sljit_sw dstw,
sljit_si src1, sljit_sw src1w,
sljit_si src2, sljit_sw src2w);
/* Label and jump instructions. */
SLJIT_API_FUNC_ATTRIBUTE struct sljit_label* sljit_emit_label(struct sljit_compiler *compiler);
/* Invert conditional instruction: xor (^) with 0x1 */
#define SLJIT_C_EQUAL 0
#define SLJIT_C_ZERO 0
#define SLJIT_C_NOT_EQUAL 1
#define SLJIT_C_NOT_ZERO 1
#define SLJIT_C_LESS 2
#define SLJIT_C_GREATER_EQUAL 3
#define SLJIT_C_GREATER 4
#define SLJIT_C_LESS_EQUAL 5
#define SLJIT_C_SIG_LESS 6
#define SLJIT_C_SIG_GREATER_EQUAL 7
#define SLJIT_C_SIG_GREATER 8
#define SLJIT_C_SIG_LESS_EQUAL 9
#define SLJIT_C_OVERFLOW 10
#define SLJIT_C_NOT_OVERFLOW 11
#define SLJIT_C_MUL_OVERFLOW 12
#define SLJIT_C_MUL_NOT_OVERFLOW 13
#define SLJIT_C_FLOAT_EQUAL 14
#define SLJIT_C_FLOAT_NOT_EQUAL 15
#define SLJIT_C_FLOAT_LESS 16
#define SLJIT_C_FLOAT_GREATER_EQUAL 17
#define SLJIT_C_FLOAT_GREATER 18
#define SLJIT_C_FLOAT_LESS_EQUAL 19
#define SLJIT_C_FLOAT_UNORDERED 20
#define SLJIT_C_FLOAT_ORDERED 21
#define SLJIT_JUMP 22
#define SLJIT_FAST_CALL 23
#define SLJIT_CALL0 24
#define SLJIT_CALL1 25
#define SLJIT_CALL2 26
#define SLJIT_CALL3 27
/* Fast calling method. See sljit_emit_fast_enter / sljit_emit_fast_return. */
/* The target can be changed during runtime (see: sljit_set_jump_addr). */
#define SLJIT_REWRITABLE_JUMP 0x1000
/* Emit a jump instruction. The destination is not set, only the type of the jump.
type must be between SLJIT_C_EQUAL and SLJIT_CALL3
type can be combined (or'ed) with SLJIT_REWRITABLE_JUMP
Flags: - (never set any flags) for both conditional and unconditional jumps.
Flags: destroy all flags for calls. */
SLJIT_API_FUNC_ATTRIBUTE struct sljit_jump* sljit_emit_jump(struct sljit_compiler *compiler, sljit_si type);
/* Basic arithmetic comparison. In most architectures it is implemented as
an SLJIT_SUB operation (with SLJIT_UNUSED destination and setting
appropriate flags) followed by a sljit_emit_jump. However some
architectures (i.e: MIPS) may employ special optimizations here. It is
suggested to use this comparison form when appropriate.
type must be between SLJIT_C_EQUAL and SLJIT_C_SIG_LESS_EQUAL
type can be combined (or'ed) with SLJIT_REWRITABLE_JUMP or SLJIT_INT_OP
Flags: destroy flags. */
SLJIT_API_FUNC_ATTRIBUTE struct sljit_jump* sljit_emit_cmp(struct sljit_compiler *compiler, sljit_si type,
sljit_si src1, sljit_sw src1w,
sljit_si src2, sljit_sw src2w);
/* Basic floating point comparison. In most architectures it is implemented as
an SLJIT_FCMP operation (setting appropriate flags) followed by a
sljit_emit_jump. However some architectures (i.e: MIPS) may employ
special optimizations here. It is suggested to use this comparison form
when appropriate.
type must be between SLJIT_C_FLOAT_EQUAL and SLJIT_C_FLOAT_ORDERED
type can be combined (or'ed) with SLJIT_REWRITABLE_JUMP and SLJIT_SINGLE_OP
Flags: destroy flags.
Note: if either operand is NaN, the behaviour is undefined for
type <= SLJIT_C_FLOAT_LESS_EQUAL. */
SLJIT_API_FUNC_ATTRIBUTE struct sljit_jump* sljit_emit_fcmp(struct sljit_compiler *compiler, sljit_si type,
sljit_si src1, sljit_sw src1w,
sljit_si src2, sljit_sw src2w);
/* Set the destination of the jump to this label. */
SLJIT_API_FUNC_ATTRIBUTE void sljit_set_label(struct sljit_jump *jump, struct sljit_label* label);
/* Only for jumps defined with SLJIT_REWRITABLE_JUMP flag.
Note: use sljit_emit_ijump for fixed jumps. */
SLJIT_API_FUNC_ATTRIBUTE void sljit_set_target(struct sljit_jump *jump, sljit_uw target);
/* Call function or jump anywhere. Both direct and indirect form
type must be between SLJIT_JUMP and SLJIT_CALL3
Direct form: set src to SLJIT_IMM() and srcw to the address
Indirect form: any other valid addressing mode
Flags: - (never set any flags) for unconditional jumps.
Flags: destroy all flags for calls. */
SLJIT_API_FUNC_ATTRIBUTE sljit_si sljit_emit_ijump(struct sljit_compiler *compiler, sljit_si type, sljit_si src, sljit_sw srcw);
/* Perform the operation using the conditional flags as the second argument.
Type must always be between SLJIT_C_EQUAL and SLJIT_C_FLOAT_ORDERED. The
value represented by the type is 1, if the condition represented by the type
is fulfilled, and 0 otherwise.
If op == SLJIT_MOV, SLJIT_MOV_SI, SLJIT_MOV_UI:
Set dst to the value represented by the type (0 or 1).
Src must be SLJIT_UNUSED, and srcw must be 0
Flags: - (never set any flags)
If op == SLJIT_OR, op == SLJIT_AND, op == SLJIT_XOR
Performs the binary operation using src as the first, and the value
represented by type as the second argument.
Important note: only dst=src and dstw=srcw is supported at the moment!
Flags: I | E | K
Note: sljit_emit_op_flags does nothing, if dst is SLJIT_UNUSED (regardless of op). */
SLJIT_API_FUNC_ATTRIBUTE sljit_si sljit_emit_op_flags(struct sljit_compiler *compiler, sljit_si op,
sljit_si dst, sljit_sw dstw,
sljit_si src, sljit_sw srcw,
sljit_si type);
/* Copies the base address of SLJIT_LOCALS_REG+offset to dst.
Flags: - (never set any flags) */
SLJIT_API_FUNC_ATTRIBUTE sljit_si sljit_get_local_base(struct sljit_compiler *compiler, sljit_si dst, sljit_sw dstw, sljit_sw offset);
/* The constant can be changed runtime (see: sljit_set_const)
Flags: - (never set any flags) */
SLJIT_API_FUNC_ATTRIBUTE struct sljit_const* sljit_emit_const(struct sljit_compiler *compiler, sljit_si dst, sljit_sw dstw, sljit_sw init_value);
/* After the code generation the address for label, jump and const instructions
are computed. Since these structures are freed by sljit_free_compiler, the
addresses must be preserved by the user program elsewere. */
static SLJIT_INLINE sljit_uw sljit_get_label_addr(struct sljit_label *label) { return label->addr; }
static SLJIT_INLINE sljit_uw sljit_get_jump_addr(struct sljit_jump *jump) { return jump->addr; }
static SLJIT_INLINE sljit_uw sljit_get_const_addr(struct sljit_const *const_) { return const_->addr; }
/* Only the address is required to rewrite the code. */
SLJIT_API_FUNC_ATTRIBUTE void sljit_set_jump_addr(sljit_uw addr, sljit_uw new_addr);
SLJIT_API_FUNC_ATTRIBUTE void sljit_set_const(sljit_uw addr, sljit_sw new_constant);
/* --------------------------------------------------------------------- */
/* Miscellaneous utility functions */
/* --------------------------------------------------------------------- */
#define SLJIT_MAJOR_VERSION 0
#define SLJIT_MINOR_VERSION 91
/* Get the human readable name of the platform. Can be useful on platforms
like ARM, where ARM and Thumb2 functions can be mixed, and
it is useful to know the type of the code generator. */
SLJIT_API_FUNC_ATTRIBUTE SLJIT_CONST char* sljit_get_platform_name(void);
/* Portable helper function to get an offset of a member. */
#define SLJIT_OFFSETOF(base, member) ((sljit_sw)(&((base*)0x10)->member) - 0x10)
#if (defined SLJIT_UTIL_GLOBAL_LOCK && SLJIT_UTIL_GLOBAL_LOCK)
/* This global lock is useful to compile common functions. */
SLJIT_API_FUNC_ATTRIBUTE void SLJIT_CALL sljit_grab_lock(void);
SLJIT_API_FUNC_ATTRIBUTE void SLJIT_CALL sljit_release_lock(void);
#endif
#if (defined SLJIT_UTIL_STACK && SLJIT_UTIL_STACK)
/* The sljit_stack is a utiliy feature of sljit, which allocates a
writable memory region between base (inclusive) and limit (exclusive).
Both base and limit is a pointer, and base is always <= than limit.
This feature uses the "address space reserve" feature
of modern operating systems. Basically we don't need to allocate a
huge memory block in one step for the worst case, we can start with
a smaller chunk and extend it later. Since the address space is
reserved, the data never copied to other regions, thus it is safe
to store pointers here. */
/* Note: The base field is aligned to PAGE_SIZE bytes (usually 4k or more).
Note: stack growing should not happen in small steps: 4k, 16k or even
bigger growth is better.
Note: this structure may not be supported by all operating systems.
Some kind of fallback mechanism is suggested when SLJIT_UTIL_STACK
is not defined. */
struct sljit_stack {
/* User data, anything can be stored here.
Starting with the same value as base. */
sljit_uw top;
/* These members are read only. */
sljit_uw base;
sljit_uw limit;
sljit_uw max_limit;
};
/* Returns NULL if unsuccessful.
Note: limit and max_limit contains the size for stack allocation
Note: the top field is initialized to base. */
SLJIT_API_FUNC_ATTRIBUTE struct sljit_stack* SLJIT_CALL sljit_allocate_stack(sljit_uw limit, sljit_uw max_limit);
SLJIT_API_FUNC_ATTRIBUTE void SLJIT_CALL sljit_free_stack(struct sljit_stack* stack);
/* Can be used to increase (allocate) or decrease (free) the memory area.
Returns with a non-zero value if unsuccessful. If new_limit is greater than
max_limit, it will fail. It is very easy to implement a stack data structure,
since the growth ratio can be added to the current limit, and sljit_stack_resize
will do all the necessary checks. The fields of the stack are not changed if
sljit_stack_resize fails. */
SLJIT_API_FUNC_ATTRIBUTE sljit_sw SLJIT_CALL sljit_stack_resize(struct sljit_stack* stack, sljit_uw new_limit);
#endif /* (defined SLJIT_UTIL_STACK && SLJIT_UTIL_STACK) */
#if !(defined SLJIT_INDIRECT_CALL && SLJIT_INDIRECT_CALL)
/* Get the entry address of a given function. */
#define SLJIT_FUNC_OFFSET(func_name) ((sljit_sw)func_name)
#else /* !(defined SLJIT_INDIRECT_CALL && SLJIT_INDIRECT_CALL) */
/* All JIT related code should be placed in the same context (library, binary, etc.). */
#define SLJIT_FUNC_OFFSET(func_name) (*(sljit_sw*)(void*)func_name)
/* For powerpc64, the function pointers point to a context descriptor. */
struct sljit_function_context {
sljit_sw addr;
sljit_sw r2;
sljit_sw r11;
};
/* Fill the context arguments using the addr and the function.
If func_ptr is NULL, it will not be set to the address of context
If addr is NULL, the function address also comes from the func pointer. */
SLJIT_API_FUNC_ATTRIBUTE void sljit_set_function_context(void** func_ptr, struct sljit_function_context* context, sljit_sw addr, void* func);
#endif /* !(defined SLJIT_INDIRECT_CALL && SLJIT_INDIRECT_CALL) */
#endif /* _SLJIT_LIR_H_ */
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