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    1 /*
    2  *    Stack-less Just-In-Time compiler
    3  *
    4  *    Copyright Zoltan Herczeg (hzmester@freemail.hu). All rights reserved.
    5  *
    6  * Redistribution and use in source and binary forms, with or without modification, are
    7  * permitted provided that the following conditions are met:
    8  *
    9  *   1. Redistributions of source code must retain the above copyright notice, this list of
   10  *      conditions and the following disclaimer.
   11  *
   12  *   2. Redistributions in binary form must reproduce the above copyright notice, this list
   13  *      of conditions and the following disclaimer in the documentation and/or other materials
   14  *      provided with the distribution.
   15  *
   16  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDER(S) AND CONTRIBUTORS ``AS IS'' AND ANY
   17  * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
   18  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT
   19  * SHALL THE COPYRIGHT HOLDER(S) OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
   20  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
   21  * TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
   22  * BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
   23  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
   24  * ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
   25  */
   26 
   27 #ifndef _SLJIT_LIR_H_
   28 #define _SLJIT_LIR_H_
   29 
   30 /*
   31    ------------------------------------------------------------------------
   32     Stack-Less JIT compiler for multiple architectures (x86, ARM, PowerPC)
   33    ------------------------------------------------------------------------
   34 
   35    Short description
   36     Advantages:
   37       - The execution can be continued from any LIR instruction. In other
   38         words, it is possible to jump to any label from anywhere, even from
   39         a code fragment, which is compiled later, if both compiled code
   40         shares the same context. See sljit_emit_enter for more details
   41       - Supports self modifying code: target of (conditional) jump and call
   42         instructions and some constant values can be dynamically modified
   43         during runtime
   44         - although it is not suggested to do it frequently
   45         - can be used for inline caching: save an important value once
   46           in the instruction stream
   47         - since this feature limits the optimization possibilities, a
   48           special flag must be passed at compile time when these
   49           instructions are emitted
   50       - A fixed stack space can be allocated for local variables
   51       - The compiler is thread-safe
   52       - The compiler is highly configurable through preprocessor macros.
   53         You can disable unneeded features (multithreading in single
   54         threaded applications), and you can use your own system functions
   55         (including memory allocators). See sljitConfig.h
   56     Disadvantages:
   57       - No automatic register allocation, and temporary results are
   58         not stored on the stack. (hence the name comes)
   59     In practice:
   60       - This approach is very effective for interpreters
   61         - One of the saved registers typically points to a stack interface
   62         - It can jump to any exception handler anytime (even if it belongs
   63           to another function)
   64         - Hot paths can be modified during runtime reflecting the changes
   65           of the fastest execution path of the dynamic language
   66         - SLJIT supports complex memory addressing modes
   67         - mainly position and context independent code (except some cases)
   68 
   69     For valgrind users:
   70       - pass --smc-check=all argument to valgrind, since JIT is a "self-modifying code"
   71 */
   72 
   73 #if !(defined SLJIT_NO_DEFAULT_CONFIG && SLJIT_NO_DEFAULT_CONFIG)
   74 #include "sljitConfig.h"
   75 #endif
   76 
   77 /* The following header file defines useful macros for fine tuning
   78 sljit based code generators. They are listed in the beginning
   79 of sljitConfigInternal.h */
   80 
   81 #include "sljitConfigInternal.h"
   82 
   83 /* --------------------------------------------------------------------- */
   84 /*  Error codes                                                          */
   85 /* --------------------------------------------------------------------- */
   86 
   87 /* Indicates no error. */
   88 #define SLJIT_SUCCESS           0
   89 /* After the call of sljit_generate_code(), the error code of the compiler
   90    is set to this value to avoid future sljit calls (in debug mode at least).
   91    The complier should be freed after sljit_generate_code(). */
   92 #define SLJIT_ERR_COMPILED      1
   93 /* Cannot allocate non executable memory. */
   94 #define SLJIT_ERR_ALLOC_FAILED      2
   95 /* Cannot allocate executable memory.
   96    Only for sljit_generate_code() */
   97 #define SLJIT_ERR_EX_ALLOC_FAILED   3
   98 /* Return value for SLJIT_CONFIG_UNSUPPORTED placeholder architecture. */
   99 #define SLJIT_ERR_UNSUPPORTED       4
  100 /* An ivalid argument is passed to any SLJIT function. */
  101 #define SLJIT_ERR_BAD_ARGUMENT      5
  102 /* Dynamic code modification is not enabled. */
  103 #define SLJIT_ERR_DYN_CODE_MOD      6
  104 
  105 /* --------------------------------------------------------------------- */
  106 /*  Registers                                                            */
  107 /* --------------------------------------------------------------------- */
  108 
  109 /*
  110   Scratch (R) registers: registers whose may not preserve their values
  111   across function calls.
  112 
  113   Saved (S) registers: registers whose preserve their values across
  114   function calls.
  115 
  116   The scratch and saved register sets are overlap. The last scratch register
  117   is the first saved register, the one before the last is the second saved
  118   register, and so on.
  119 
  120   If an architecture provides two scratch and three saved registers,
  121   its scratch and saved register sets are the following:
  122 
  123      R0   |        |   R0 is always a scratch register
  124      R1   |        |   R1 is always a scratch register
  125     [R2]  |   S2   |   R2 and S2 represent the same physical register
  126     [R3]  |   S1   |   R3 and S1 represent the same physical register
  127     [R4]  |   S0   |   R4 and S0 represent the same physical register
  128 
  129   Note: SLJIT_NUMBER_OF_SCRATCH_REGISTERS would be 2 and
  130         SLJIT_NUMBER_OF_SAVED_REGISTERS would be 3 for this architecture.
  131 
  132   Note: On all supported architectures SLJIT_NUMBER_OF_REGISTERS >= 12
  133         and SLJIT_NUMBER_OF_SAVED_REGISTERS >= 6. However, 6 registers
  134         are virtual on x86-32. See below.
  135 
  136   The purpose of this definition is convenience: saved registers can
  137   be used as extra scratch registers. For example four registers can
  138   be specified as scratch registers and the fifth one as saved register
  139   on the CPU above and any user code which requires four scratch
  140   registers can run unmodified. The SLJIT compiler automatically saves
  141   the content of the two extra scratch register on the stack. Scratch
  142   registers can also be preserved by saving their value on the stack
  143   but this needs to be done manually.
  144 
  145   Note: To emphasize that registers assigned to R2-R4 are saved
  146         registers, they are enclosed by square brackets.
  147 
  148   Note: sljit_emit_enter and sljit_set_context defines whether a register
  149         is S or R register. E.g: when 3 scratches and 1 saved is mapped
  150         by sljit_emit_enter, the allowed register set will be: R0-R2 and
  151         S0. Although S2 is mapped to the same position as R2, it does not
  152         available in the current configuration. Furthermore the S1 register
  153         is not available at all.
  154 */
  155 
  156 /* When SLJIT_UNUSED is specified as the destination of sljit_emit_op1
  157    or sljit_emit_op2 operations the result is discarded. If no status
  158    flags are set, no instructions are emitted for these operations. Data
  159    prefetch is a special exception, see SLJIT_MOV operation. Other SLJIT
  160    operations do not support SLJIT_UNUSED as a destination operand. */
  161 #define SLJIT_UNUSED        0
  162 
  163 /* Scratch registers. */
  164 #define SLJIT_R0    1
  165 #define SLJIT_R1    2
  166 #define SLJIT_R2    3
  167 /* Note: on x86-32, R3 - R6 (same as S3 - S6) are emulated (they
  168    are allocated on the stack). These registers are called virtual
  169    and cannot be used for memory addressing (cannot be part of
  170    any SLJIT_MEM1, SLJIT_MEM2 construct). There is no such
  171    limitation on other CPUs. See sljit_get_register_index(). */
  172 #define SLJIT_R3    4
  173 #define SLJIT_R4    5
  174 #define SLJIT_R5    6
  175 #define SLJIT_R6    7
  176 #define SLJIT_R7    8
  177 #define SLJIT_R8    9
  178 #define SLJIT_R9    10
  179 /* All R registers provided by the architecture can be accessed by SLJIT_R(i)
  180    The i parameter must be >= 0 and < SLJIT_NUMBER_OF_REGISTERS. */
  181 #define SLJIT_R(i)  (1 + (i))
  182 
  183 /* Saved registers. */
  184 #define SLJIT_S0    (SLJIT_NUMBER_OF_REGISTERS)
  185 #define SLJIT_S1    (SLJIT_NUMBER_OF_REGISTERS - 1)
  186 #define SLJIT_S2    (SLJIT_NUMBER_OF_REGISTERS - 2)
  187 /* Note: on x86-32, S3 - S6 (same as R3 - R6) are emulated (they
  188    are allocated on the stack). These registers are called virtual
  189    and cannot be used for memory addressing (cannot be part of
  190    any SLJIT_MEM1, SLJIT_MEM2 construct). There is no such
  191    limitation on other CPUs. See sljit_get_register_index(). */
  192 #define SLJIT_S3    (SLJIT_NUMBER_OF_REGISTERS - 3)
  193 #define SLJIT_S4    (SLJIT_NUMBER_OF_REGISTERS - 4)
  194 #define SLJIT_S5    (SLJIT_NUMBER_OF_REGISTERS - 5)
  195 #define SLJIT_S6    (SLJIT_NUMBER_OF_REGISTERS - 6)
  196 #define SLJIT_S7    (SLJIT_NUMBER_OF_REGISTERS - 7)
  197 #define SLJIT_S8    (SLJIT_NUMBER_OF_REGISTERS - 8)
  198 #define SLJIT_S9    (SLJIT_NUMBER_OF_REGISTERS - 9)
  199 /* All S registers provided by the architecture can be accessed by SLJIT_S(i)
  200    The i parameter must be >= 0 and < SLJIT_NUMBER_OF_SAVED_REGISTERS. */
  201 #define SLJIT_S(i)  (SLJIT_NUMBER_OF_REGISTERS - (i))
  202 
  203 /* Registers >= SLJIT_FIRST_SAVED_REG are saved registers. */
  204 #define SLJIT_FIRST_SAVED_REG (SLJIT_S0 - SLJIT_NUMBER_OF_SAVED_REGISTERS + 1)
  205 
  206 /* The SLJIT_SP provides direct access to the linear stack space allocated by
  207    sljit_emit_enter. It can only be used in the following form: SLJIT_MEM1(SLJIT_SP).
  208    The immediate offset is extended by the relative stack offset automatically.
  209    The sljit_get_local_base can be used to obtain the absolute offset. */
  210 #define SLJIT_SP    (SLJIT_NUMBER_OF_REGISTERS + 1)
  211 
  212 /* Return with machine word. */
  213 
  214 #define SLJIT_RETURN_REG    SLJIT_R0
  215 
  216 /* --------------------------------------------------------------------- */
  217 /*  Floating point registers                                             */
  218 /* --------------------------------------------------------------------- */
  219 
  220 /* Each floating point register can store a 32 or a 64 bit precision
  221    value. The FR and FS register sets are overlap in the same way as R
  222    and S register sets. See above. */
  223 
  224 /* Note: SLJIT_UNUSED as destination is not valid for floating point
  225    operations, since they cannot be used for setting flags. */
  226 
  227 /* Floating point scratch registers. */
  228 #define SLJIT_FR0   1
  229 #define SLJIT_FR1   2
  230 #define SLJIT_FR2   3
  231 #define SLJIT_FR3   4
  232 #define SLJIT_FR4   5
  233 #define SLJIT_FR5   6
  234 /* All FR registers provided by the architecture can be accessed by SLJIT_FR(i)
  235    The i parameter must be >= 0 and < SLJIT_NUMBER_OF_FLOAT_REGISTERS. */
  236 #define SLJIT_FR(i) (1 + (i))
  237 
  238 /* Floating point saved registers. */
  239 #define SLJIT_FS0   (SLJIT_NUMBER_OF_FLOAT_REGISTERS)
  240 #define SLJIT_FS1   (SLJIT_NUMBER_OF_FLOAT_REGISTERS - 1)
  241 #define SLJIT_FS2   (SLJIT_NUMBER_OF_FLOAT_REGISTERS - 2)
  242 #define SLJIT_FS3   (SLJIT_NUMBER_OF_FLOAT_REGISTERS - 3)
  243 #define SLJIT_FS4   (SLJIT_NUMBER_OF_FLOAT_REGISTERS - 4)
  244 #define SLJIT_FS5   (SLJIT_NUMBER_OF_FLOAT_REGISTERS - 5)
  245 /* All S registers provided by the architecture can be accessed by SLJIT_FS(i)
  246    The i parameter must be >= 0 and < SLJIT_NUMBER_OF_SAVED_FLOAT_REGISTERS. */
  247 #define SLJIT_FS(i) (SLJIT_NUMBER_OF_FLOAT_REGISTERS - (i))
  248 
  249 /* Float registers >= SLJIT_FIRST_SAVED_FLOAT_REG are saved registers. */
  250 #define SLJIT_FIRST_SAVED_FLOAT_REG (SLJIT_FS0 - SLJIT_NUMBER_OF_SAVED_FLOAT_REGISTERS + 1)
  251 
  252 /* --------------------------------------------------------------------- */
  253 /*  Argument type definitions                                            */
  254 /* --------------------------------------------------------------------- */
  255 
  256 /* Argument type definitions.
  257    Used by SLJIT_[DEF_]ARGx and SLJIT_[DEF]_RET macros. */
  258 
  259 #define SLJIT_ARG_TYPE_VOID 0
  260 #define SLJIT_ARG_TYPE_SW 1
  261 #define SLJIT_ARG_TYPE_UW 2
  262 #define SLJIT_ARG_TYPE_S32 3
  263 #define SLJIT_ARG_TYPE_U32 4
  264 #define SLJIT_ARG_TYPE_F32 5
  265 #define SLJIT_ARG_TYPE_F64 6
  266 
  267 /* The following argument type definitions are used by sljit_emit_enter,
  268    sljit_set_context, sljit_emit_call, and sljit_emit_icall functions.
  269    The following return type definitions are used by sljit_emit_call
  270    and sljit_emit_icall functions.
  271 
  272    When a function is called, the first integer argument must be placed
  273    in SLJIT_R0, the second in SLJIT_R1, and so on. Similarly the first
  274    floating point argument must be placed in SLJIT_FR0, the second in
  275    SLJIT_FR1, and so on.
  276 
  277    Example function definition:
  278      sljit_f32 SLJIT_FUNC example_c_callback(sljit_sw arg_a,
  279          sljit_f64 arg_b, sljit_u32 arg_c, sljit_f32 arg_d);
  280 
  281    Argument type definition:
  282      SLJIT_DEF_RET(SLJIT_ARG_TYPE_F32)
  283         | SLJIT_DEF_ARG1(SLJIT_ARG_TYPE_SW) | SLJIT_DEF_ARG2(SLJIT_ARG_TYPE_F64)
  284         | SLJIT_DEF_ARG3(SLJIT_ARG_TYPE_U32) | SLJIT_DEF_ARG2(SLJIT_ARG_TYPE_F32)
  285 
  286    Short form of argument type definition:
  287      SLJIT_RET(F32) | SLJIT_ARG1(SW) | SLJIT_ARG2(F64)
  288         | SLJIT_ARG3(S32) | SLJIT_ARG4(F32)
  289 
  290    Argument passing:
  291      arg_a must be placed in SLJIT_R0
  292      arg_c must be placed in SLJIT_R1
  293      arg_b must be placed in SLJIT_FR0
  294      arg_d must be placed in SLJIT_FR1
  295 
  296 Note:
  297    The SLJIT_ARG_TYPE_VOID type is only supported by
  298    SLJIT_DEF_RET, and SLJIT_ARG_TYPE_VOID is also the
  299    default value when SLJIT_DEF_RET is not specified. */
  300 #define SLJIT_DEF_SHIFT 4
  301 #define SLJIT_DEF_RET(type) (type)
  302 #define SLJIT_DEF_ARG1(type) ((type) << SLJIT_DEF_SHIFT)
  303 #define SLJIT_DEF_ARG2(type) ((type) << (2 * SLJIT_DEF_SHIFT))
  304 #define SLJIT_DEF_ARG3(type) ((type) << (3 * SLJIT_DEF_SHIFT))
  305 #define SLJIT_DEF_ARG4(type) ((type) << (4 * SLJIT_DEF_SHIFT))
  306 
  307 /* Short form of the macros above.
  308 
  309    For example the following definition:
  310    SLJIT_DEF_RET(SLJIT_ARG_TYPE_SW) | SLJIT_DEF_ARG1(SLJIT_ARG_TYPE_F32)
  311 
  312    can be shortened to:
  313    SLJIT_RET(SW) | SLJIT_ARG1(F32)
  314 
  315 Note:
  316    The VOID type is only supported by SLJIT_RET, and
  317    VOID is also the default value when SLJIT_RET is
  318    not specified. */
  319 #define SLJIT_RET(type) SLJIT_DEF_RET(SLJIT_ARG_TYPE_ ## type)
  320 #define SLJIT_ARG1(type) SLJIT_DEF_ARG1(SLJIT_ARG_TYPE_ ## type)
  321 #define SLJIT_ARG2(type) SLJIT_DEF_ARG2(SLJIT_ARG_TYPE_ ## type)
  322 #define SLJIT_ARG3(type) SLJIT_DEF_ARG3(SLJIT_ARG_TYPE_ ## type)
  323 #define SLJIT_ARG4(type) SLJIT_DEF_ARG4(SLJIT_ARG_TYPE_ ## type)
  324 
  325 /* --------------------------------------------------------------------- */
  326 /*  Main structures and functions                                        */
  327 /* --------------------------------------------------------------------- */
  328 
  329 /*
  330     The following structures are private, and can be changed in the
  331     future. Keeping them here allows code inlining.
  332 */
  333 
  334 struct sljit_memory_fragment {
  335     struct sljit_memory_fragment *next;
  336     sljit_uw used_size;
  337     /* Must be aligned to sljit_sw. */
  338     sljit_u8 memory[1];
  339 };
  340 
  341 struct sljit_label {
  342     struct sljit_label *next;
  343     sljit_uw addr;
  344     /* The maximum size difference. */
  345     sljit_uw size;
  346 };
  347 
  348 struct sljit_jump {
  349     struct sljit_jump *next;
  350     sljit_uw addr;
  351     sljit_uw flags;
  352     union {
  353         sljit_uw target;
  354         struct sljit_label *label;
  355     } u;
  356 };
  357 
  358 struct sljit_put_label {
  359     struct sljit_put_label *next;
  360     struct sljit_label *label;
  361     sljit_uw addr;
  362     sljit_uw flags;
  363 };
  364 
  365 struct sljit_const {
  366     struct sljit_const *next;
  367     sljit_uw addr;
  368 };
  369 
  370 struct sljit_compiler {
  371     sljit_s32 error;
  372     sljit_s32 options;
  373 
  374     struct sljit_label *labels;
  375     struct sljit_jump *jumps;
  376     struct sljit_put_label *put_labels;
  377     struct sljit_const *consts;
  378     struct sljit_label *last_label;
  379     struct sljit_jump *last_jump;
  380     struct sljit_const *last_const;
  381     struct sljit_put_label *last_put_label;
  382 
  383     void *allocator_data;
  384     struct sljit_memory_fragment *buf;
  385     struct sljit_memory_fragment *abuf;
  386 
  387     /* Used scratch registers. */
  388     sljit_s32 scratches;
  389     /* Used saved registers. */
  390     sljit_s32 saveds;
  391     /* Used float scratch registers. */
  392     sljit_s32 fscratches;
  393     /* Used float saved registers. */
  394     sljit_s32 fsaveds;
  395     /* Local stack size. */
  396     sljit_s32 local_size;
  397     /* Code size. */
  398     sljit_uw size;
  399     /* Relative offset of the executable mapping from the writable mapping. */
  400     sljit_uw executable_offset;
  401     /* Executable size for statistical purposes. */
  402     sljit_uw executable_size;
  403 
  404 #if (defined SLJIT_CONFIG_X86_32 && SLJIT_CONFIG_X86_32)
  405     sljit_s32 args;
  406     sljit_s32 locals_offset;
  407     sljit_s32 saveds_offset;
  408     sljit_s32 stack_tmp_size;
  409 #endif
  410 
  411 #if (defined SLJIT_CONFIG_X86_64 && SLJIT_CONFIG_X86_64)
  412     sljit_s32 mode32;
  413 #ifdef _WIN64
  414     sljit_s32 locals_offset;
  415 #endif
  416 #endif
  417 
  418 #if (defined SLJIT_CONFIG_ARM_V5 && SLJIT_CONFIG_ARM_V5)
  419     /* Constant pool handling. */
  420     sljit_uw *cpool;
  421     sljit_u8 *cpool_unique;
  422     sljit_uw cpool_diff;
  423     sljit_uw cpool_fill;
  424     /* Other members. */
  425     /* Contains pointer, "ldr pc, [...]" pairs. */
  426     sljit_uw patches;
  427 #endif
  428 
  429 #if (defined SLJIT_CONFIG_ARM_V5 && SLJIT_CONFIG_ARM_V5) || (defined SLJIT_CONFIG_ARM_V7 && SLJIT_CONFIG_ARM_V7)
  430     /* Temporary fields. */
  431     sljit_uw shift_imm;
  432 #endif
  433 
  434 #if (defined SLJIT_CONFIG_PPC && SLJIT_CONFIG_PPC)
  435     sljit_sw imm;
  436 #endif
  437 
  438 #if (defined SLJIT_CONFIG_MIPS && SLJIT_CONFIG_MIPS)
  439     sljit_s32 delay_slot;
  440     sljit_s32 cache_arg;
  441     sljit_sw cache_argw;
  442 #endif
  443 
  444 #if (defined SLJIT_CONFIG_SPARC_32 && SLJIT_CONFIG_SPARC_32)
  445     sljit_s32 delay_slot;
  446     sljit_s32 cache_arg;
  447     sljit_sw cache_argw;
  448 #endif
  449 
  450 #if (defined SLJIT_CONFIG_TILEGX && SLJIT_CONFIG_TILEGX)
  451     sljit_s32 cache_arg;
  452     sljit_sw cache_argw;
  453 #endif
  454 
  455 #if (defined SLJIT_VERBOSE && SLJIT_VERBOSE)
  456     FILE* verbose;
  457 #endif
  458 
  459 #if (defined SLJIT_ARGUMENT_CHECKS && SLJIT_ARGUMENT_CHECKS) \
  460         || (defined SLJIT_DEBUG && SLJIT_DEBUG)
  461     /* Flags specified by the last arithmetic instruction.
  462        It contains the type of the variable flag. */
  463     sljit_s32 last_flags;
  464     /* Local size passed to the functions. */
  465     sljit_s32 logical_local_size;
  466 #endif
  467 
  468 #if (defined SLJIT_ARGUMENT_CHECKS && SLJIT_ARGUMENT_CHECKS) \
  469         || (defined SLJIT_DEBUG && SLJIT_DEBUG) \
  470         || (defined SLJIT_VERBOSE && SLJIT_VERBOSE)
  471     /* Trust arguments when the API function is called. */
  472     sljit_s32 skip_checks;
  473 #endif
  474 };
  475 
  476 /* --------------------------------------------------------------------- */
  477 /*  Main functions                                                       */
  478 /* --------------------------------------------------------------------- */
  479 
  480 /* Creates an sljit compiler. The allocator_data is required by some
  481    custom memory managers. This pointer is passed to SLJIT_MALLOC
  482    and SLJIT_FREE macros. Most allocators (including the default
  483    one) ignores this value, and it is recommended to pass NULL
  484    as a dummy value for allocator_data.
  485 
  486    Returns NULL if failed. */
  487 SLJIT_API_FUNC_ATTRIBUTE struct sljit_compiler* sljit_create_compiler(void *allocator_data);
  488 
  489 /* Frees everything except the compiled machine code. */
  490 SLJIT_API_FUNC_ATTRIBUTE void sljit_free_compiler(struct sljit_compiler *compiler);
  491 
  492 /* Returns the current error code. If an error is occurred, future sljit
  493    calls which uses the same compiler argument returns early with the same
  494    error code. Thus there is no need for checking the error after every
  495    call, it is enough to do it before the code is compiled. Removing
  496    these checks increases the performance of the compiling process. */
  497 static SLJIT_INLINE sljit_s32 sljit_get_compiler_error(struct sljit_compiler *compiler) { return compiler->error; }
  498 
  499 /* Sets the compiler error code to SLJIT_ERR_ALLOC_FAILED except
  500    if an error was detected before. After the error code is set
  501    the compiler behaves as if the allocation failure happened
  502    during an sljit function call. This can greatly simplify error
  503    checking, since only the compiler status needs to be checked
  504    after the compilation. */
  505 SLJIT_API_FUNC_ATTRIBUTE void sljit_set_compiler_memory_error(struct sljit_compiler *compiler);
  506 
  507 /*
  508    Allocate a small amount of memory. The size must be <= 64 bytes on 32 bit,
  509    and <= 128 bytes on 64 bit architectures. The memory area is owned by the
  510    compiler, and freed by sljit_free_compiler. The returned pointer is
  511    sizeof(sljit_sw) aligned. Excellent for allocating small blocks during
  512    the compiling, and no need to worry about freeing them. The size is
  513    enough to contain at most 16 pointers. If the size is outside of the range,
  514    the function will return with NULL. However, this return value does not
  515    indicate that there is no more memory (does not set the current error code
  516    of the compiler to out-of-memory status).
  517 */
  518 SLJIT_API_FUNC_ATTRIBUTE void* sljit_alloc_memory(struct sljit_compiler *compiler, sljit_s32 size);
  519 
  520 #if (defined SLJIT_VERBOSE && SLJIT_VERBOSE)
  521 /* Passing NULL disables verbose. */
  522 SLJIT_API_FUNC_ATTRIBUTE void sljit_compiler_verbose(struct sljit_compiler *compiler, FILE* verbose);
  523 #endif
  524 
  525 /*
  526    Create executable code from the sljit instruction stream. This is the final step
  527    of the code generation so no more instructions can be added after this call.
  528 */
  529 
  530 SLJIT_API_FUNC_ATTRIBUTE void* sljit_generate_code(struct sljit_compiler *compiler);
  531 
  532 /* Free executable code. */
  533 
  534 SLJIT_API_FUNC_ATTRIBUTE void sljit_free_code(void* code);
  535 
  536 /*
  537    When the protected executable allocator is used the JIT code is mapped
  538    twice. The first mapping has read/write and the second mapping has read/exec
  539    permissions. This function returns with the relative offset of the executable
  540    mapping using the writable mapping as the base after the machine code is
  541    successfully generated. The returned value is always 0 for the normal executable
  542    allocator, since it uses only one mapping with read/write/exec permissions.
  543    Dynamic code modifications requires this value.
  544 
  545    Before a successful code generation, this function returns with 0.
  546 */
  547 static SLJIT_INLINE sljit_sw sljit_get_executable_offset(struct sljit_compiler *compiler) { return compiler->executable_offset; }
  548 
  549 /*
  550    The executable memory consumption of the generated code can be retrieved by
  551    this function. The returned value can be used for statistical purposes.
  552 
  553    Before a successful code generation, this function returns with 0.
  554 */
  555 static SLJIT_INLINE sljit_uw sljit_get_generated_code_size(struct sljit_compiler *compiler) { return compiler->executable_size; }
  556 
  557 /* Returns with non-zero if the feature or limitation type passed as its
  558    argument is present on the current CPU.
  559 
  560    Some features (e.g. floating point operations) require hardware (CPU)
  561    support while others (e.g. move with update) are emulated if not available.
  562    However even if a feature is emulated, specialized code paths can be faster
  563    than the emulation. Some limitations are emulated as well so their general
  564    case is supported but it has extra performance costs. */
  565 
  566 /* [Not emulated] Floating-point support is available. */
  567 #define SLJIT_HAS_FPU           0
  568 /* [Limitation] Some registers are virtual registers. */
  569 #define SLJIT_HAS_VIRTUAL_REGISTERS 1
  570 /* [Emulated] Count leading zero is supported. */
  571 #define SLJIT_HAS_CLZ           2
  572 /* [Emulated] Conditional move is supported. */
  573 #define SLJIT_HAS_CMOV          3
  574 
  575 #if (defined SLJIT_CONFIG_X86 && SLJIT_CONFIG_X86)
  576 /* [Not emulated] SSE2 support is available on x86. */
  577 #define SLJIT_HAS_SSE2          100
  578 #endif
  579 
  580 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_has_cpu_feature(sljit_s32 feature_type);
  581 
  582 /* Instruction generation. Returns with any error code. If there is no
  583    error, they return with SLJIT_SUCCESS. */
  584 
  585 /*
  586    The executable code is a function from the viewpoint of the C
  587    language. The function calls must obey to the ABI (Application
  588    Binary Interface) of the platform, which specify the purpose of
  589    machine registers and stack handling among other things. The
  590    sljit_emit_enter function emits the necessary instructions for
  591    setting up a new context for the executable code and moves function
  592    arguments to the saved registers. Furthermore the options argument
  593    can be used to pass configuration options to the compiler. The
  594    available options are listed before sljit_emit_enter.
  595 
  596    The function argument list is the combination of SLJIT_ARGx
  597    (SLJIT_DEF_ARG1) macros. Currently maximum 3 SW / UW
  598    (SLJIT_ARG_TYPE_SW / LJIT_ARG_TYPE_UW) arguments are supported.
  599    The first argument goes to SLJIT_S0, the second goes to SLJIT_S1
  600    and so on. The register set used by the function must be declared
  601    as well. The number of scratch and saved registers used by the
  602    function must be passed to sljit_emit_enter. Only R registers
  603    between R0 and "scratches" argument can be used later. E.g. if
  604    "scratches" is set to 2, the scratch register set will be limited
  605    to SLJIT_R0 and SLJIT_R1. The S registers and the floating point
  606    registers ("fscratches" and "fsaveds") are specified in a similar
  607    manner. The sljit_emit_enter is also capable of allocating a stack
  608    space for local variables. The "local_size" argument contains the
  609    size in bytes of this local area and its staring address is stored
  610    in SLJIT_SP. The memory area between SLJIT_SP (inclusive) and
  611    SLJIT_SP + local_size (exclusive) can be modified freely until
  612    the function returns. The stack space is not initialized.
  613 
  614    Note: the following conditions must met:
  615          0 <= scratches <= SLJIT_NUMBER_OF_REGISTERS
  616          0 <= saveds <= SLJIT_NUMBER_OF_REGISTERS
  617          scratches + saveds <= SLJIT_NUMBER_OF_REGISTERS
  618          0 <= fscratches <= SLJIT_NUMBER_OF_FLOAT_REGISTERS
  619          0 <= fsaveds <= SLJIT_NUMBER_OF_FLOAT_REGISTERS
  620          fscratches + fsaveds <= SLJIT_NUMBER_OF_FLOAT_REGISTERS
  621 
  622    Note: every call of sljit_emit_enter and sljit_set_context
  623          overwrites the previous context.
  624 */
  625 
  626 /* The absolute address returned by sljit_get_local_base with
  627 offset 0 is aligned to sljit_f64. Otherwise it is aligned to sljit_sw. */
  628 #define SLJIT_F64_ALIGNMENT 0x00000001
  629 
  630 /* The local_size must be >= 0 and <= SLJIT_MAX_LOCAL_SIZE. */
  631 #define SLJIT_MAX_LOCAL_SIZE    65536
  632 
  633 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_emit_enter(struct sljit_compiler *compiler,
  634     sljit_s32 options, sljit_s32 arg_types, sljit_s32 scratches, sljit_s32 saveds,
  635     sljit_s32 fscratches, sljit_s32 fsaveds, sljit_s32 local_size);
  636 
  637 /* The machine code has a context (which contains the local stack space size,
  638    number of used registers, etc.) which initialized by sljit_emit_enter. Several
  639    functions (like sljit_emit_return) requres this context to be able to generate
  640    the appropriate code. However, some code fragments (like inline cache) may have
  641    no normal entry point so their context is unknown for the compiler. Their context
  642    can be provided to the compiler by the sljit_set_context function.
  643 
  644    Note: every call of sljit_emit_enter and sljit_set_context overwrites
  645          the previous context. */
  646 
  647 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_set_context(struct sljit_compiler *compiler,
  648     sljit_s32 options, sljit_s32 arg_types, sljit_s32 scratches, sljit_s32 saveds,
  649     sljit_s32 fscratches, sljit_s32 fsaveds, sljit_s32 local_size);
  650 
  651 /* Return from machine code.  The op argument can be SLJIT_UNUSED which means the
  652    function does not return with anything or any opcode between SLJIT_MOV and
  653    SLJIT_MOV_P (see sljit_emit_op1). As for src and srcw they must be 0 if op
  654    is SLJIT_UNUSED, otherwise see below the description about source and
  655    destination arguments. */
  656 
  657 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_emit_return(struct sljit_compiler *compiler, sljit_s32 op,
  658     sljit_s32 src, sljit_sw srcw);
  659 
  660 /* Generating entry and exit points for fast call functions (see SLJIT_FAST_CALL).
  661    Both sljit_emit_fast_enter and sljit_emit_fast_return functions preserve the
  662    values of all registers and stack frame. The return address is stored in the
  663    dst argument of sljit_emit_fast_enter, and this return address can be passed
  664    to sljit_emit_fast_return to continue the execution after the fast call.
  665 
  666    Fast calls are cheap operations (usually only a single call instruction is
  667    emitted) but they do not preserve any registers. However the callee function
  668    can freely use / update any registers and stack values which can be
  669    efficiently exploited by various optimizations. Registers can be saved
  670    manually by the callee function if needed.
  671 
  672    Although returning to different address by sljit_emit_fast_return is possible,
  673    this address usually cannot be predicted by the return address predictor of
  674    modern CPUs which may reduce performance. Furthermore using sljit_emit_ijump
  675    to return is also inefficient since return address prediction is usually
  676    triggered by a specific form of ijump.
  677 
  678    Flags: - (does not modify flags). */
  679 
  680 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_emit_fast_enter(struct sljit_compiler *compiler, sljit_s32 dst, sljit_sw dstw);
  681 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_emit_fast_return(struct sljit_compiler *compiler, sljit_s32 src, sljit_sw srcw);
  682 
  683 /*
  684    Source and destination operands for arithmetical instructions
  685     imm              - a simple immediate value (cannot be used as a destination)
  686     reg              - any of the registers (immediate argument must be 0)
  687     [imm]            - absolute immediate memory address
  688     [reg+imm]        - indirect memory address
  689     [reg+(reg<<imm)] - indirect indexed memory address (shift must be between 0 and 3)
  690                        useful for (byte, half, int, sljit_sw) array access
  691                        (fully supported by both x86 and ARM architectures, and cheap operation on others)
  692 */
  693 
  694 /*
  695    IMPORATNT NOTE: memory access MUST be naturally aligned except
  696                    SLJIT_UNALIGNED macro is defined and its value is 1.
  697 
  698      length | alignment
  699    ---------+-----------
  700      byte   | 1 byte (any physical_address is accepted)
  701      half   | 2 byte (physical_address & 0x1 == 0)
  702      int    | 4 byte (physical_address & 0x3 == 0)
  703      word   | 4 byte if SLJIT_32BIT_ARCHITECTURE is defined and its value is 1
  704             | 8 byte if SLJIT_64BIT_ARCHITECTURE is defined and its value is 1
  705     pointer | size of sljit_p type (4 byte on 32 bit machines, 4 or 8 byte
  706             | on 64 bit machines)
  707 
  708    Note:   Different architectures have different addressing limitations.
  709            A single instruction is enough for the following addressing
  710            modes. Other adrressing modes are emulated by instruction
  711            sequences. This information could help to improve those code
  712            generators which focuses only a few architectures.
  713 
  714    x86:    [reg+imm], -2^32+1 <= imm <= 2^32-1 (full address space on x86-32)
  715            [reg+(reg<<imm)] is supported
  716            [imm], -2^32+1 <= imm <= 2^32-1 is supported
  717            Write-back is not supported
  718    arm:    [reg+imm], -4095 <= imm <= 4095 or -255 <= imm <= 255 for signed
  719                 bytes, any halfs or floating point values)
  720            [reg+(reg<<imm)] is supported
  721            Write-back is supported
  722    arm-t2: [reg+imm], -255 <= imm <= 4095
  723            [reg+(reg<<imm)] is supported
  724            Write back is supported only for [reg+imm], where -255 <= imm <= 255
  725    arm64:  [reg+imm], -256 <= imm <= 255, 0 <= aligned imm <= 4095 * alignment
  726            [reg+(reg<<imm)] is supported
  727            Write back is supported only for [reg+imm], where -256 <= imm <= 255
  728    ppc:    [reg+imm], -65536 <= imm <= 65535. 64 bit loads/stores and 32 bit
  729                 signed load on 64 bit requires immediates divisible by 4.
  730                 [reg+imm] is not supported for signed 8 bit values.
  731            [reg+reg] is supported
  732            Write-back is supported except for one instruction: 32 bit signed
  733                 load with [reg+imm] addressing mode on 64 bit.
  734    mips:   [reg+imm], -65536 <= imm <= 65535
  735    sparc:  [reg+imm], -4096 <= imm <= 4095
  736            [reg+reg] is supported
  737 */
  738 
  739 /* Macros for specifying operand types. */
  740 #define SLJIT_MEM       0x80
  741 #define SLJIT_MEM0()        (SLJIT_MEM)
  742 #define SLJIT_MEM1(r1)      (SLJIT_MEM | (r1))
  743 #define SLJIT_MEM2(r1, r2)  (SLJIT_MEM | (r1) | ((r2) << 8))
  744 #define SLJIT_IMM       0x40
  745 
  746 /* Set 32 bit operation mode (I) on 64 bit CPUs. This option is ignored on
  747    32 bit CPUs. When this option is set for an arithmetic operation, only
  748    the lower 32 bit of the input registers are used, and the CPU status
  749    flags are set according to the 32 bit result. Although the higher 32 bit
  750    of the input and the result registers are not defined by SLJIT, it might
  751    be defined by the CPU architecture (e.g. MIPS). To satisfy these CPU
  752    requirements all source registers must be the result of those operations
  753    where this option was also set. Memory loads read 32 bit values rather
  754    than 64 bit ones. In other words 32 bit and 64 bit operations cannot
  755    be mixed. The only exception is SLJIT_MOV32 and SLJIT_MOVU32 whose source
  756    register can hold any 32 or 64 bit value, and it is converted to a 32 bit
  757    compatible format first. This conversion is free (no instructions are
  758    emitted) on most CPUs. A 32 bit value can also be converted to a 64 bit
  759    value by SLJIT_MOV_S32 (sign extension) or SLJIT_MOV_U32 (zero extension).
  760 
  761    Note: memory addressing always uses 64 bit values on 64 bit systems so
  762          the result of a 32 bit operation must not be used with SLJIT_MEMx
  763          macros.
  764 
  765    This option is part of the instruction name, so there is no need to
  766    manually set it. E.g:
  767 
  768      SLJIT_ADD32 == (SLJIT_ADD | SLJIT_I32_OP) */
  769 #define SLJIT_I32_OP        0x100
  770 
  771 /* Set F32 (single) precision mode for floating-point computation. This
  772    option is similar to SLJIT_I32_OP, it just applies to floating point
  773    registers. When this option is passed, the CPU performs 32 bit floating
  774    point operations, rather than 64 bit one. Similar to SLJIT_I32_OP, all
  775    register arguments must be the result of those operations where this
  776    option was also set.
  777 
  778    This option is part of the instruction name, so there is no need to
  779    manually set it. E.g:
  780 
  781      SLJIT_MOV_F32 = (SLJIT_MOV_F64 | SLJIT_F32_OP)
  782  */
  783 #define SLJIT_F32_OP        SLJIT_I32_OP
  784 
  785 /* Many CPUs (x86, ARM, PPC) have status flags which can be set according
  786    to the result of an operation. Other CPUs (MIPS) do not have status
  787    flags, and results must be stored in registers. To cover both architecture
  788    types efficiently only two flags are defined by SLJIT:
  789 
  790     * Zero (equal) flag: it is set if the result is zero
  791     * Variable flag: its value is defined by the last arithmetic operation
  792 
  793    SLJIT instructions can set any or both of these flags. The value of
  794    these flags is undefined if the instruction does not specify their value.
  795    The description of each instruction contains the list of allowed flag
  796    types.
  797 
  798    Example: SLJIT_ADD can set the Z, OVERFLOW, CARRY flags hence
  799 
  800      sljit_op2(..., SLJIT_ADD, ...)
  801        Both the zero and variable flags are undefined so they can
  802        have any value after the operation is completed.
  803 
  804      sljit_op2(..., SLJIT_ADD | SLJIT_SET_Z, ...)
  805        Sets the zero flag if the result is zero, clears it otherwise.
  806        The variable flag is undefined.
  807 
  808      sljit_op2(..., SLJIT_ADD | SLJIT_SET_OVERFLOW, ...)
  809        Sets the variable flag if an integer overflow occurs, clears
  810        it otherwise. The zero flag is undefined.
  811 
  812      sljit_op2(..., SLJIT_ADD | SLJIT_SET_Z | SLJIT_SET_CARRY, ...)
  813        Sets the zero flag if the result is zero, clears it otherwise.
  814        Sets the variable flag if unsigned overflow (carry) occurs,
  815        clears it otherwise.
  816 
  817    If an instruction (e.g. SLJIT_MOV) does not modify flags the flags are
  818    unchanged.
  819 
  820    Using these flags can reduce the number of emitted instructions. E.g. a
  821    fast loop can be implemented by decreasing a counter register and set the
  822    zero flag to jump back if the counter register has not reached zero.
  823 
  824    Motivation: although CPUs can set a large number of flags, usually their
  825    values are ignored or only one of them is used. Emulating a large number
  826    of flags on systems without flag register is complicated so SLJIT
  827    instructions must specify the flag they want to use and only that flag
  828    will be emulated. The last arithmetic instruction can be repeated if
  829    multiple flags need to be checked.
  830 */
  831 
  832 /* Set Zero status flag. */
  833 #define SLJIT_SET_Z         0x0200
  834 /* Set the variable status flag if condition is true.
  835    See comparison types. */
  836 #define SLJIT_SET(condition)            ((condition) << 10)
  837 
  838 /* Notes:
  839      - you cannot postpone conditional jump instructions except if noted that
  840        the instruction does not set flags (See: SLJIT_KEEP_FLAGS).
  841      - flag combinations: '|' means 'logical or'. */
  842 
  843 /* Starting index of opcodes for sljit_emit_op0. */
  844 #define SLJIT_OP0_BASE          0
  845 
  846 /* Flags: - (does not modify flags)
  847    Note: breakpoint instruction is not supported by all architectures (e.g. ppc)
  848          It falls back to SLJIT_NOP in those cases. */
  849 #define SLJIT_BREAKPOINT        (SLJIT_OP0_BASE + 0)
  850 /* Flags: - (does not modify flags)
  851    Note: may or may not cause an extra cycle wait
  852          it can even decrease the runtime in a few cases. */
  853 #define SLJIT_NOP           (SLJIT_OP0_BASE + 1)
  854 /* Flags: - (may destroy flags)
  855    Unsigned multiplication of SLJIT_R0 and SLJIT_R1.
  856    Result is placed into SLJIT_R1:SLJIT_R0 (high:low) word */
  857 #define SLJIT_LMUL_UW           (SLJIT_OP0_BASE + 2)
  858 /* Flags: - (may destroy flags)
  859    Signed multiplication of SLJIT_R0 and SLJIT_R1.
  860    Result is placed into SLJIT_R1:SLJIT_R0 (high:low) word */
  861 #define SLJIT_LMUL_SW           (SLJIT_OP0_BASE + 3)
  862 /* Flags: - (may destroy flags)
  863    Unsigned divide of the value in SLJIT_R0 by the value in SLJIT_R1.
  864    The result is placed into SLJIT_R0 and the remainder into SLJIT_R1.
  865    Note: if SLJIT_R1 is 0, the behaviour is undefined. */
  866 #define SLJIT_DIVMOD_UW         (SLJIT_OP0_BASE + 4)
  867 #define SLJIT_DIVMOD_U32        (SLJIT_DIVMOD_UW | SLJIT_I32_OP)
  868 /* Flags: - (may destroy flags)
  869    Signed divide of the value in SLJIT_R0 by the value in SLJIT_R1.
  870    The result is placed into SLJIT_R0 and the remainder into SLJIT_R1.
  871    Note: if SLJIT_R1 is 0, the behaviour is undefined.
  872    Note: if SLJIT_R1 is -1 and SLJIT_R0 is integer min (0x800..00),
  873          the behaviour is undefined. */
  874 #define SLJIT_DIVMOD_SW         (SLJIT_OP0_BASE + 5)
  875 #define SLJIT_DIVMOD_S32        (SLJIT_DIVMOD_SW | SLJIT_I32_OP)
  876 /* Flags: - (may destroy flags)
  877    Unsigned divide of the value in SLJIT_R0 by the value in SLJIT_R1.
  878    The result is placed into SLJIT_R0. SLJIT_R1 preserves its value.
  879    Note: if SLJIT_R1 is 0, the behaviour is undefined. */
  880 #define SLJIT_DIV_UW            (SLJIT_OP0_BASE + 6)
  881 #define SLJIT_DIV_U32           (SLJIT_DIV_UW | SLJIT_I32_OP)
  882 /* Flags: - (may destroy flags)
  883    Signed divide of the value in SLJIT_R0 by the value in SLJIT_R1.
  884    The result is placed into SLJIT_R0. SLJIT_R1 preserves its value.
  885    Note: if SLJIT_R1 is 0, the behaviour is undefined.
  886    Note: if SLJIT_R1 is -1 and SLJIT_R0 is integer min (0x800..00),
  887          the behaviour is undefined. */
  888 #define SLJIT_DIV_SW            (SLJIT_OP0_BASE + 7)
  889 #define SLJIT_DIV_S32           (SLJIT_DIV_SW | SLJIT_I32_OP)
  890 
  891 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_emit_op0(struct sljit_compiler *compiler, sljit_s32 op);
  892 
  893 /* Starting index of opcodes for sljit_emit_op1. */
  894 #define SLJIT_OP1_BASE          32
  895 
  896 /* The MOV instruction transfers data from source to destination.
  897 
  898    MOV instruction suffixes:
  899 
  900    U8  - unsigned 8 bit data transfer
  901    S8  - signed 8 bit data transfer
  902    U16 - unsigned 16 bit data transfer
  903    S16 - signed 16 bit data transfer
  904    U32 - unsigned int (32 bit) data transfer
  905    S32 - signed int (32 bit) data transfer
  906    P   - pointer (sljit_p) data transfer
  907 
  908    If the destination of a MOV instruction is SLJIT_UNUSED and the source
  909    operand is a memory address the compiler emits a prefetch instruction
  910    if this instruction is supported by the current CPU. Higher data sizes
  911    bring the data closer to the core: a MOV with word size loads the data
  912    into a higher level cache than a byte size. Otherwise the type does not
  913    affect the prefetch instruction. Furthermore a prefetch instruction
  914    never fails, so it can be used to prefetch a data from an address and
  915    check whether that address is NULL afterwards.
  916 */
  917 
  918 /* Flags: - (does not modify flags) */
  919 #define SLJIT_MOV           (SLJIT_OP1_BASE + 0)
  920 /* Flags: - (does not modify flags) */
  921 #define SLJIT_MOV_U8            (SLJIT_OP1_BASE + 1)
  922 #define SLJIT_MOV32_U8          (SLJIT_MOV_U8 | SLJIT_I32_OP)
  923 /* Flags: - (does not modify flags) */
  924 #define SLJIT_MOV_S8            (SLJIT_OP1_BASE + 2)
  925 #define SLJIT_MOV32_S8          (SLJIT_MOV_S8 | SLJIT_I32_OP)
  926 /* Flags: - (does not modify flags) */
  927 #define SLJIT_MOV_U16           (SLJIT_OP1_BASE + 3)
  928 #define SLJIT_MOV32_U16         (SLJIT_MOV_U16 | SLJIT_I32_OP)
  929 /* Flags: - (does not modify flags) */
  930 #define SLJIT_MOV_S16           (SLJIT_OP1_BASE + 4)
  931 #define SLJIT_MOV32_S16         (SLJIT_MOV_S16 | SLJIT_I32_OP)
  932 /* Flags: - (does not modify flags)
  933    Note: no SLJIT_MOV32_U32 form, since it is the same as SLJIT_MOV32 */
  934 #define SLJIT_MOV_U32           (SLJIT_OP1_BASE + 5)
  935 /* Flags: - (does not modify flags)
  936    Note: no SLJIT_MOV32_S32 form, since it is the same as SLJIT_MOV32 */
  937 #define SLJIT_MOV_S32           (SLJIT_OP1_BASE + 6)
  938 /* Flags: - (does not modify flags) */
  939 #define SLJIT_MOV32         (SLJIT_MOV_S32 | SLJIT_I32_OP)
  940 /* Flags: - (does not modify flags)
  941    Note: load a pointer sized data, useful on x32 (a 32 bit mode on x86-64
  942          where all x64 features are available, e.g. 16 register) or similar
  943          compiling modes */
  944 #define SLJIT_MOV_P         (SLJIT_OP1_BASE + 7)
  945 /* Flags: Z
  946    Note: immediate source argument is not supported */
  947 #define SLJIT_NOT           (SLJIT_OP1_BASE + 8)
  948 #define SLJIT_NOT32         (SLJIT_NOT | SLJIT_I32_OP)
  949 /* Flags: Z | OVERFLOW
  950    Note: immediate source argument is not supported */
  951 #define SLJIT_NEG           (SLJIT_OP1_BASE + 9)
  952 #define SLJIT_NEG32         (SLJIT_NEG | SLJIT_I32_OP)
  953 /* Count leading zeroes
  954    Flags: - (may destroy flags)
  955    Note: immediate source argument is not supported */
  956 #define SLJIT_CLZ           (SLJIT_OP1_BASE + 10)
  957 #define SLJIT_CLZ32         (SLJIT_CLZ | SLJIT_I32_OP)
  958 
  959 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_emit_op1(struct sljit_compiler *compiler, sljit_s32 op,
  960     sljit_s32 dst, sljit_sw dstw,
  961     sljit_s32 src, sljit_sw srcw);
  962 
  963 /* Starting index of opcodes for sljit_emit_op2. */
  964 #define SLJIT_OP2_BASE          96
  965 
  966 /* Flags: Z | OVERFLOW | CARRY */
  967 #define SLJIT_ADD           (SLJIT_OP2_BASE + 0)
  968 #define SLJIT_ADD32         (SLJIT_ADD | SLJIT_I32_OP)
  969 /* Flags: CARRY */
  970 #define SLJIT_ADDC          (SLJIT_OP2_BASE + 1)
  971 #define SLJIT_ADDC32            (SLJIT_ADDC | SLJIT_I32_OP)
  972 /* Flags: Z | LESS | GREATER_EQUAL | GREATER | LESS_EQUAL
  973           SIG_LESS | SIG_GREATER_EQUAL | SIG_GREATER
  974           SIG_LESS_EQUAL | CARRY */
  975 #define SLJIT_SUB           (SLJIT_OP2_BASE + 2)
  976 #define SLJIT_SUB32         (SLJIT_SUB | SLJIT_I32_OP)
  977 /* Flags: CARRY */
  978 #define SLJIT_SUBC          (SLJIT_OP2_BASE + 3)
  979 #define SLJIT_SUBC32            (SLJIT_SUBC | SLJIT_I32_OP)
  980 /* Note: integer mul
  981    Flags: MUL_OVERFLOW */
  982 #define SLJIT_MUL           (SLJIT_OP2_BASE + 4)
  983 #define SLJIT_MUL32         (SLJIT_MUL | SLJIT_I32_OP)
  984 /* Flags: Z */
  985 #define SLJIT_AND           (SLJIT_OP2_BASE + 5)
  986 #define SLJIT_AND32         (SLJIT_AND | SLJIT_I32_OP)
  987 /* Flags: Z */
  988 #define SLJIT_OR            (SLJIT_OP2_BASE + 6)
  989 #define SLJIT_OR32          (SLJIT_OR | SLJIT_I32_OP)
  990 /* Flags: Z */
  991 #define SLJIT_XOR           (SLJIT_OP2_BASE + 7)
  992 #define SLJIT_XOR32         (SLJIT_XOR | SLJIT_I32_OP)
  993 /* Flags: Z
  994    Let bit_length be the length of the shift operation: 32 or 64.
  995    If src2 is immediate, src2w is masked by (bit_length - 1).
  996    Otherwise, if the content of src2 is outside the range from 0
  997    to bit_length - 1, the result is undefined. */
  998 #define SLJIT_SHL           (SLJIT_OP2_BASE + 8)
  999 #define SLJIT_SHL32         (SLJIT_SHL | SLJIT_I32_OP)
 1000 /* Flags: Z
 1001    Let bit_length be the length of the shift operation: 32 or 64.
 1002    If src2 is immediate, src2w is masked by (bit_length - 1).
 1003    Otherwise, if the content of src2 is outside the range from 0
 1004    to bit_length - 1, the result is undefined. */
 1005 #define SLJIT_LSHR          (SLJIT_OP2_BASE + 9)
 1006 #define SLJIT_LSHR32            (SLJIT_LSHR | SLJIT_I32_OP)
 1007 /* Flags: Z
 1008    Let bit_length be the length of the shift operation: 32 or 64.
 1009    If src2 is immediate, src2w is masked by (bit_length - 1).
 1010    Otherwise, if the content of src2 is outside the range from 0
 1011    to bit_length - 1, the result is undefined. */
 1012 #define SLJIT_ASHR          (SLJIT_OP2_BASE + 10)
 1013 #define SLJIT_ASHR32            (SLJIT_ASHR | SLJIT_I32_OP)
 1014 
 1015 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_emit_op2(struct sljit_compiler *compiler, sljit_s32 op,
 1016     sljit_s32 dst, sljit_sw dstw,
 1017     sljit_s32 src1, sljit_sw src1w,
 1018     sljit_s32 src2, sljit_sw src2w);
 1019 
 1020 /* Starting index of opcodes for sljit_emit_fop1. */
 1021 #define SLJIT_FOP1_BASE         128
 1022 
 1023 /* Flags: - (does not modify flags) */
 1024 #define SLJIT_MOV_F64           (SLJIT_FOP1_BASE + 0)
 1025 #define SLJIT_MOV_F32           (SLJIT_MOV_F64 | SLJIT_F32_OP)
 1026 /* Convert opcodes: CONV[DST_TYPE].FROM[SRC_TYPE]
 1027    SRC/DST TYPE can be: D - double, S - single, W - signed word, I - signed int
 1028    Rounding mode when the destination is W or I: round towards zero. */
 1029 /* Flags: - (does not modify flags) */
 1030 #define SLJIT_CONV_F64_FROM_F32     (SLJIT_FOP1_BASE + 1)
 1031 #define SLJIT_CONV_F32_FROM_F64     (SLJIT_CONV_F64_FROM_F32 | SLJIT_F32_OP)
 1032 /* Flags: - (does not modify flags) */
 1033 #define SLJIT_CONV_SW_FROM_F64      (SLJIT_FOP1_BASE + 2)
 1034 #define SLJIT_CONV_SW_FROM_F32      (SLJIT_CONV_SW_FROM_F64 | SLJIT_F32_OP)
 1035 /* Flags: - (does not modify flags) */
 1036 #define SLJIT_CONV_S32_FROM_F64     (SLJIT_FOP1_BASE + 3)
 1037 #define SLJIT_CONV_S32_FROM_F32     (SLJIT_CONV_S32_FROM_F64 | SLJIT_F32_OP)
 1038 /* Flags: - (does not modify flags) */
 1039 #define SLJIT_CONV_F64_FROM_SW      (SLJIT_FOP1_BASE + 4)
 1040 #define SLJIT_CONV_F32_FROM_SW      (SLJIT_CONV_F64_FROM_SW | SLJIT_F32_OP)
 1041 /* Flags: - (does not modify flags) */
 1042 #define SLJIT_CONV_F64_FROM_S32     (SLJIT_FOP1_BASE + 5)
 1043 #define SLJIT_CONV_F32_FROM_S32     (SLJIT_CONV_F64_FROM_S32 | SLJIT_F32_OP)
 1044 /* Note: dst is the left and src is the right operand for SLJIT_CMPD.
 1045    Flags: EQUAL_F | LESS_F | GREATER_EQUAL_F | GREATER_F | LESS_EQUAL_F */
 1046 #define SLJIT_CMP_F64           (SLJIT_FOP1_BASE + 6)
 1047 #define SLJIT_CMP_F32           (SLJIT_CMP_F64 | SLJIT_F32_OP)
 1048 /* Flags: - (does not modify flags) */
 1049 #define SLJIT_NEG_F64           (SLJIT_FOP1_BASE + 7)
 1050 #define SLJIT_NEG_F32           (SLJIT_NEG_F64 | SLJIT_F32_OP)
 1051 /* Flags: - (does not modify flags) */
 1052 #define SLJIT_ABS_F64           (SLJIT_FOP1_BASE + 8)
 1053 #define SLJIT_ABS_F32           (SLJIT_ABS_F64 | SLJIT_F32_OP)
 1054 
 1055 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_emit_fop1(struct sljit_compiler *compiler, sljit_s32 op,
 1056     sljit_s32 dst, sljit_sw dstw,
 1057     sljit_s32 src, sljit_sw srcw);
 1058 
 1059 /* Starting index of opcodes for sljit_emit_fop2. */
 1060 #define SLJIT_FOP2_BASE         160
 1061 
 1062 /* Flags: - (does not modify flags) */
 1063 #define SLJIT_ADD_F64           (SLJIT_FOP2_BASE + 0)
 1064 #define SLJIT_ADD_F32           (SLJIT_ADD_F64 | SLJIT_F32_OP)
 1065 /* Flags: - (does not modify flags) */
 1066 #define SLJIT_SUB_F64           (SLJIT_FOP2_BASE + 1)
 1067 #define SLJIT_SUB_F32           (SLJIT_SUB_F64 | SLJIT_F32_OP)
 1068 /* Flags: - (does not modify flags) */
 1069 #define SLJIT_MUL_F64           (SLJIT_FOP2_BASE + 2)
 1070 #define SLJIT_MUL_F32           (SLJIT_MUL_F64 | SLJIT_F32_OP)
 1071 /* Flags: - (does not modify flags) */
 1072 #define SLJIT_DIV_F64           (SLJIT_FOP2_BASE + 3)
 1073 #define SLJIT_DIV_F32           (SLJIT_DIV_F64 | SLJIT_F32_OP)
 1074 
 1075 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_emit_fop2(struct sljit_compiler *compiler, sljit_s32 op,
 1076     sljit_s32 dst, sljit_sw dstw,
 1077     sljit_s32 src1, sljit_sw src1w,
 1078     sljit_s32 src2, sljit_sw src2w);
 1079 
 1080 /* Label and jump instructions. */
 1081 
 1082 SLJIT_API_FUNC_ATTRIBUTE struct sljit_label* sljit_emit_label(struct sljit_compiler *compiler);
 1083 
 1084 /* Invert (negate) conditional type: xor (^) with 0x1 */
 1085 
 1086 /* Integer comparison types. */
 1087 #define SLJIT_EQUAL         0
 1088 #define SLJIT_EQUAL32           (SLJIT_EQUAL | SLJIT_I32_OP)
 1089 #define SLJIT_ZERO          0
 1090 #define SLJIT_ZERO32            (SLJIT_ZERO | SLJIT_I32_OP)
 1091 #define SLJIT_NOT_EQUAL         1
 1092 #define SLJIT_NOT_EQUAL32       (SLJIT_NOT_EQUAL | SLJIT_I32_OP)
 1093 #define SLJIT_NOT_ZERO          1
 1094 #define SLJIT_NOT_ZERO32        (SLJIT_NOT_ZERO | SLJIT_I32_OP)
 1095 
 1096 #define SLJIT_LESS          2
 1097 #define SLJIT_LESS32            (SLJIT_LESS | SLJIT_I32_OP)
 1098 #define SLJIT_SET_LESS          SLJIT_SET(SLJIT_LESS)
 1099 #define SLJIT_GREATER_EQUAL     3
 1100 #define SLJIT_GREATER_EQUAL32       (SLJIT_GREATER_EQUAL | SLJIT_I32_OP)
 1101 #define SLJIT_SET_GREATER_EQUAL     SLJIT_SET(SLJIT_GREATER_EQUAL)
 1102 #define SLJIT_GREATER           4
 1103 #define SLJIT_GREATER32         (SLJIT_GREATER | SLJIT_I32_OP)
 1104 #define SLJIT_SET_GREATER       SLJIT_SET(SLJIT_GREATER)
 1105 #define SLJIT_LESS_EQUAL        5
 1106 #define SLJIT_LESS_EQUAL32      (SLJIT_LESS_EQUAL | SLJIT_I32_OP)
 1107 #define SLJIT_SET_LESS_EQUAL        SLJIT_SET(SLJIT_LESS_EQUAL)
 1108 #define SLJIT_SIG_LESS          6
 1109 #define SLJIT_SIG_LESS32        (SLJIT_SIG_LESS | SLJIT_I32_OP)
 1110 #define SLJIT_SET_SIG_LESS      SLJIT_SET(SLJIT_SIG_LESS)
 1111 #define SLJIT_SIG_GREATER_EQUAL     7
 1112 #define SLJIT_SIG_GREATER_EQUAL32   (SLJIT_SIG_GREATER_EQUAL | SLJIT_I32_OP)
 1113 #define SLJIT_SET_SIG_GREATER_EQUAL SLJIT_SET(SLJIT_SIG_GREATER_EQUAL)
 1114 #define SLJIT_SIG_GREATER       8
 1115 #define SLJIT_SIG_GREATER32     (SLJIT_SIG_GREATER | SLJIT_I32_OP)
 1116 #define SLJIT_SET_SIG_GREATER       SLJIT_SET(SLJIT_SIG_GREATER)
 1117 #define SLJIT_SIG_LESS_EQUAL        9
 1118 #define SLJIT_SIG_LESS_EQUAL32      (SLJIT_SIG_LESS_EQUAL | SLJIT_I32_OP)
 1119 #define SLJIT_SET_SIG_LESS_EQUAL    SLJIT_SET(SLJIT_SIG_LESS_EQUAL)
 1120 
 1121 #define SLJIT_OVERFLOW          10
 1122 #define SLJIT_OVERFLOW32        (SLJIT_OVERFLOW | SLJIT_I32_OP)
 1123 #define SLJIT_SET_OVERFLOW      SLJIT_SET(SLJIT_OVERFLOW)
 1124 #define SLJIT_NOT_OVERFLOW      11
 1125 #define SLJIT_NOT_OVERFLOW32        (SLJIT_NOT_OVERFLOW | SLJIT_I32_OP)
 1126 
 1127 #define SLJIT_MUL_OVERFLOW      12
 1128 #define SLJIT_MUL_OVERFLOW32        (SLJIT_MUL_OVERFLOW | SLJIT_I32_OP)
 1129 #define SLJIT_SET_MUL_OVERFLOW      SLJIT_SET(SLJIT_MUL_OVERFLOW)
 1130 #define SLJIT_MUL_NOT_OVERFLOW      13
 1131 #define SLJIT_MUL_NOT_OVERFLOW32    (SLJIT_MUL_NOT_OVERFLOW | SLJIT_I32_OP)
 1132 
 1133 /* There is no SLJIT_CARRY or SLJIT_NOT_CARRY. */
 1134 #define SLJIT_SET_CARRY         SLJIT_SET(14)
 1135 
 1136 /* Floating point comparison types. */
 1137 #define SLJIT_EQUAL_F64         16
 1138 #define SLJIT_EQUAL_F32         (SLJIT_EQUAL_F64 | SLJIT_F32_OP)
 1139 #define SLJIT_SET_EQUAL_F       SLJIT_SET(SLJIT_EQUAL_F64)
 1140 #define SLJIT_NOT_EQUAL_F64     17
 1141 #define SLJIT_NOT_EQUAL_F32     (SLJIT_NOT_EQUAL_F64 | SLJIT_F32_OP)
 1142 #define SLJIT_SET_NOT_EQUAL_F       SLJIT_SET(SLJIT_NOT_EQUAL_F64)
 1143 #define SLJIT_LESS_F64          18
 1144 #define SLJIT_LESS_F32          (SLJIT_LESS_F64 | SLJIT_F32_OP)
 1145 #define SLJIT_SET_LESS_F        SLJIT_SET(SLJIT_LESS_F64)
 1146 #define SLJIT_GREATER_EQUAL_F64     19
 1147 #define SLJIT_GREATER_EQUAL_F32     (SLJIT_GREATER_EQUAL_F64 | SLJIT_F32_OP)
 1148 #define SLJIT_SET_GREATER_EQUAL_F   SLJIT_SET(SLJIT_GREATER_EQUAL_F64)
 1149 #define SLJIT_GREATER_F64       20
 1150 #define SLJIT_GREATER_F32       (SLJIT_GREATER_F64 | SLJIT_F32_OP)
 1151 #define SLJIT_SET_GREATER_F     SLJIT_SET(SLJIT_GREATER_F64)
 1152 #define SLJIT_LESS_EQUAL_F64        21
 1153 #define SLJIT_LESS_EQUAL_F32        (SLJIT_LESS_EQUAL_F64 | SLJIT_F32_OP)
 1154 #define SLJIT_SET_LESS_EQUAL_F      SLJIT_SET(SLJIT_LESS_EQUAL_F64)
 1155 #define SLJIT_UNORDERED_F64     22
 1156 #define SLJIT_UNORDERED_F32     (SLJIT_UNORDERED_F64 | SLJIT_F32_OP)
 1157 #define SLJIT_SET_UNORDERED_F       SLJIT_SET(SLJIT_UNORDERED_F64)
 1158 #define SLJIT_ORDERED_F64       23
 1159 #define SLJIT_ORDERED_F32       (SLJIT_ORDERED_F64 | SLJIT_F32_OP)
 1160 #define SLJIT_SET_ORDERED_F     SLJIT_SET(SLJIT_ORDERED_F64)
 1161 
 1162 /* Unconditional jump types. */
 1163 #define SLJIT_JUMP          24
 1164     /* Fast calling method. See sljit_emit_fast_enter / sljit_emit_fast_return. */
 1165 #define SLJIT_FAST_CALL         25
 1166     /* Called function must be declared with the SLJIT_FUNC attribute. */
 1167 #define SLJIT_CALL          26
 1168     /* Called function must be declared with cdecl attribute.
 1169        This is the default attribute for C functions. */
 1170 #define SLJIT_CALL_CDECL        27
 1171 
 1172 /* The target can be changed during runtime (see: sljit_set_jump_addr). */
 1173 #define SLJIT_REWRITABLE_JUMP       0x1000
 1174 
 1175 /* Emit a jump instruction. The destination is not set, only the type of the jump.
 1176     type must be between SLJIT_EQUAL and SLJIT_FAST_CALL
 1177     type can be combined (or'ed) with SLJIT_REWRITABLE_JUMP
 1178 
 1179    Flags: does not modify flags. */
 1180 SLJIT_API_FUNC_ATTRIBUTE struct sljit_jump* sljit_emit_jump(struct sljit_compiler *compiler, sljit_s32 type);
 1181 
 1182 /* Emit a C compiler (ABI) compatible function call.
 1183     type must be SLJIT_CALL or SLJIT_CALL_CDECL
 1184     type can be combined (or'ed) with SLJIT_REWRITABLE_JUMP
 1185     arg_types is the combination of SLJIT_RET / SLJIT_ARGx (SLJIT_DEF_RET / SLJIT_DEF_ARGx) macros
 1186 
 1187    Flags: destroy all flags. */
 1188 SLJIT_API_FUNC_ATTRIBUTE struct sljit_jump* sljit_emit_call(struct sljit_compiler *compiler, sljit_s32 type, sljit_s32 arg_types);
 1189 
 1190 /* Basic arithmetic comparison. In most architectures it is implemented as
 1191    an SLJIT_SUB operation (with SLJIT_UNUSED destination and setting
 1192    appropriate flags) followed by a sljit_emit_jump. However some
 1193    architectures (i.e: ARM64 or MIPS) may employ special optimizations here.
 1194    It is suggested to use this comparison form when appropriate.
 1195     type must be between SLJIT_EQUAL and SLJIT_I_SIG_LESS_EQUAL
 1196     type can be combined (or'ed) with SLJIT_REWRITABLE_JUMP
 1197 
 1198    Flags: may destroy flags. */
 1199 SLJIT_API_FUNC_ATTRIBUTE struct sljit_jump* sljit_emit_cmp(struct sljit_compiler *compiler, sljit_s32 type,
 1200     sljit_s32 src1, sljit_sw src1w,
 1201     sljit_s32 src2, sljit_sw src2w);
 1202 
 1203 /* Basic floating point comparison. In most architectures it is implemented as
 1204    an SLJIT_FCMP operation (setting appropriate flags) followed by a
 1205    sljit_emit_jump. However some architectures (i.e: MIPS) may employ
 1206    special optimizations here. It is suggested to use this comparison form
 1207    when appropriate.
 1208     type must be between SLJIT_EQUAL_F64 and SLJIT_ORDERED_F32
 1209     type can be combined (or'ed) with SLJIT_REWRITABLE_JUMP
 1210    Flags: destroy flags.
 1211    Note: if either operand is NaN, the behaviour is undefined for
 1212          types up to SLJIT_S_LESS_EQUAL. */
 1213 SLJIT_API_FUNC_ATTRIBUTE struct sljit_jump* sljit_emit_fcmp(struct sljit_compiler *compiler, sljit_s32 type,
 1214     sljit_s32 src1, sljit_sw src1w,
 1215     sljit_s32 src2, sljit_sw src2w);
 1216 
 1217 /* Set the destination of the jump to this label. */
 1218 SLJIT_API_FUNC_ATTRIBUTE void sljit_set_label(struct sljit_jump *jump, struct sljit_label* label);
 1219 /* Set the destination address of the jump to this label. */
 1220 SLJIT_API_FUNC_ATTRIBUTE void sljit_set_target(struct sljit_jump *jump, sljit_uw target);
 1221 
 1222 /* Emit an indirect jump or fast call.
 1223    Direct form: set src to SLJIT_IMM() and srcw to the address
 1224    Indirect form: any other valid addressing mode
 1225     type must be between SLJIT_JUMP and SLJIT_FAST_CALL
 1226 
 1227    Flags: does not modify flags. */
 1228 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_emit_ijump(struct sljit_compiler *compiler, sljit_s32 type, sljit_s32 src, sljit_sw srcw);
 1229 
 1230 /* Emit a C compiler (ABI) compatible function call.
 1231    Direct form: set src to SLJIT_IMM() and srcw to the address
 1232    Indirect form: any other valid addressing mode
 1233     type must be SLJIT_CALL or SLJIT_CALL_CDECL
 1234     arg_types is the combination of SLJIT_RET / SLJIT_ARGx (SLJIT_DEF_RET / SLJIT_DEF_ARGx) macros
 1235 
 1236    Flags: destroy all flags. */
 1237 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_emit_icall(struct sljit_compiler *compiler, sljit_s32 type, sljit_s32 arg_types, sljit_s32 src, sljit_sw srcw);
 1238 
 1239 /* Perform the operation using the conditional flags as the second argument.
 1240    Type must always be between SLJIT_EQUAL and SLJIT_ORDERED_F64. The value
 1241    represented by the type is 1, if the condition represented by the type
 1242    is fulfilled, and 0 otherwise.
 1243 
 1244    If op == SLJIT_MOV, SLJIT_MOV32:
 1245      Set dst to the value represented by the type (0 or 1).
 1246      Flags: - (does not modify flags)
 1247    If op == SLJIT_OR, op == SLJIT_AND, op == SLJIT_XOR
 1248      Performs the binary operation using dst as the first, and the value
 1249      represented by type as the second argument. Result is written into dst.
 1250      Flags: Z (may destroy flags) */
 1251 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_emit_op_flags(struct sljit_compiler *compiler, sljit_s32 op,
 1252     sljit_s32 dst, sljit_sw dstw,
 1253     sljit_s32 type);
 1254 
 1255 /* Emit a conditional mov instruction which moves source to destination,
 1256    if the condition is satisfied. Unlike other arithmetic operations this
 1257    instruction does not support memory access.
 1258 
 1259    type must be between SLJIT_EQUAL and SLJIT_ORDERED_F64
 1260    dst_reg must be a valid register and it can be combined
 1261       with SLJIT_I32_OP to perform a 32 bit arithmetic operation
 1262    src must be register or immediate (SLJIT_IMM)
 1263 
 1264    Flags: - (does not modify flags) */
 1265 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_emit_cmov(struct sljit_compiler *compiler, sljit_s32 type,
 1266     sljit_s32 dst_reg,
 1267     sljit_s32 src, sljit_sw srcw);
 1268 
 1269 /* The following flags are used by sljit_emit_mem() and sljit_emit_fmem(). */
 1270 
 1271 /* When SLJIT_MEM_SUPP is passed, no instructions are emitted.
 1272    Instead the function returns with SLJIT_SUCCESS if the instruction
 1273    form is supported and SLJIT_ERR_UNSUPPORTED otherwise. This flag
 1274    allows runtime checking of available instruction forms. */
 1275 #define SLJIT_MEM_SUPP      0x0200
 1276 /* Memory load operation. This is the default. */
 1277 #define SLJIT_MEM_LOAD      0x0000
 1278 /* Memory store operation. */
 1279 #define SLJIT_MEM_STORE     0x0400
 1280 /* Base register is updated before the memory access. */
 1281 #define SLJIT_MEM_PRE       0x0800
 1282 /* Base register is updated after the memory access. */
 1283 #define SLJIT_MEM_POST      0x1000
 1284 
 1285 /* Emit a single memory load or store with update instruction. When the
 1286    requested instruction form is not supported by the CPU, it returns
 1287    with SLJIT_ERR_UNSUPPORTED instead of emulating the instruction. This
 1288    allows specializing tight loops based on the supported instruction
 1289    forms (see SLJIT_MEM_SUPP flag).
 1290 
 1291    type must be between SLJIT_MOV and SLJIT_MOV_P and can be
 1292      combined with SLJIT_MEM_* flags. Either SLJIT_MEM_PRE
 1293      or SLJIT_MEM_POST must be specified.
 1294    reg is the source or destination register, and must be
 1295      different from the base register of the mem operand
 1296    mem must be a SLJIT_MEM1() or SLJIT_MEM2() operand
 1297 
 1298    Flags: - (does not modify flags) */
 1299 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_emit_mem(struct sljit_compiler *compiler, sljit_s32 type,
 1300     sljit_s32 reg,
 1301     sljit_s32 mem, sljit_sw memw);
 1302 
 1303 /* Same as sljit_emit_mem except the followings:
 1304 
 1305    type must be SLJIT_MOV_F64 or SLJIT_MOV_F32 and can be
 1306      combined with SLJIT_MEM_* flags. Either SLJIT_MEM_PRE
 1307      or SLJIT_MEM_POST must be specified.
 1308    freg is the source or destination floating point register */
 1309 
 1310 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_emit_fmem(struct sljit_compiler *compiler, sljit_s32 type,
 1311     sljit_s32 freg,
 1312     sljit_s32 mem, sljit_sw memw);
 1313 
 1314 /* Copies the base address of SLJIT_SP + offset to dst. The offset can be
 1315    anything to negate the effect of relative addressing. For example if an
 1316    array of sljit_sw values is stored on the stack from offset 0x40, and R0
 1317    contains the offset of an array item plus 0x120, this item can be
 1318    overwritten by two SLJIT instructions:
 1319 
 1320    sljit_get_local_base(compiler, SLJIT_R1, 0, 0x40 - 0x120);
 1321    sljit_emit_op1(compiler, SLJIT_MOV, SLJIT_MEM2(SLJIT_R1, SLJIT_R0), 0, SLJIT_IMM, 0x5);
 1322 
 1323    Flags: - (may destroy flags) */
 1324 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_get_local_base(struct sljit_compiler *compiler, sljit_s32 dst, sljit_sw dstw, sljit_sw offset);
 1325 
 1326 /* Store a value that can be changed runtime (see: sljit_get_const_addr / sljit_set_const)
 1327    Flags: - (does not modify flags) */
 1328 SLJIT_API_FUNC_ATTRIBUTE struct sljit_const* sljit_emit_const(struct sljit_compiler *compiler, sljit_s32 dst, sljit_sw dstw, sljit_sw init_value);
 1329 
 1330 /* Store the value of a label (see: sljit_set_put_label)
 1331    Flags: - (does not modify flags) */
 1332 SLJIT_API_FUNC_ATTRIBUTE struct sljit_put_label* sljit_emit_put_label(struct sljit_compiler *compiler, sljit_s32 dst, sljit_sw dstw);
 1333 
 1334 /* Set the value stored by put_label to this label. */
 1335 SLJIT_API_FUNC_ATTRIBUTE void sljit_set_put_label(struct sljit_put_label *put_label, struct sljit_label *label);
 1336 
 1337 /* After the code generation the address for label, jump and const instructions
 1338    are computed. Since these structures are freed by sljit_free_compiler, the
 1339    addresses must be preserved by the user program elsewere. */
 1340 static SLJIT_INLINE sljit_uw sljit_get_label_addr(struct sljit_label *label) { return label->addr; }
 1341 static SLJIT_INLINE sljit_uw sljit_get_jump_addr(struct sljit_jump *jump) { return jump->addr; }
 1342 static SLJIT_INLINE sljit_uw sljit_get_const_addr(struct sljit_const *const_) { return const_->addr; }
 1343 
 1344 /* Only the address and executable offset are required to perform dynamic
 1345    code modifications. See sljit_get_executable_offset function. */
 1346 SLJIT_API_FUNC_ATTRIBUTE void sljit_set_jump_addr(sljit_uw addr, sljit_uw new_target, sljit_sw executable_offset);
 1347 SLJIT_API_FUNC_ATTRIBUTE void sljit_set_const(sljit_uw addr, sljit_sw new_constant, sljit_sw executable_offset);
 1348 
 1349 /* --------------------------------------------------------------------- */
 1350 /*  Miscellaneous utility functions                                      */
 1351 /* --------------------------------------------------------------------- */
 1352 
 1353 #define SLJIT_MAJOR_VERSION 0
 1354 #define SLJIT_MINOR_VERSION 94
 1355 
 1356 /* Get the human readable name of the platform. Can be useful on platforms
 1357    like ARM, where ARM and Thumb2 functions can be mixed, and
 1358    it is useful to know the type of the code generator. */
 1359 SLJIT_API_FUNC_ATTRIBUTE const char* sljit_get_platform_name(void);
 1360 
 1361 /* Portable helper function to get an offset of a member. */
 1362 #define SLJIT_OFFSETOF(base, member) ((sljit_sw)(&((base*)0x10)->member) - 0x10)
 1363 
 1364 #if (defined SLJIT_UTIL_GLOBAL_LOCK && SLJIT_UTIL_GLOBAL_LOCK)
 1365 /* This global lock is useful to compile common functions. */
 1366 SLJIT_API_FUNC_ATTRIBUTE void SLJIT_FUNC sljit_grab_lock(void);
 1367 SLJIT_API_FUNC_ATTRIBUTE void SLJIT_FUNC sljit_release_lock(void);
 1368 #endif
 1369 
 1370 #if (defined SLJIT_UTIL_STACK && SLJIT_UTIL_STACK)
 1371 
 1372 /* The sljit_stack structure and its manipulation functions provides
 1373    an implementation for a top-down stack. The stack top is stored
 1374    in the end field of the sljit_stack structure and the stack goes
 1375    down to the min_start field, so the memory region reserved for
 1376    this stack is between min_start (inclusive) and end (exclusive)
 1377    fields. However the application can only use the region between
 1378    start (inclusive) and end (exclusive) fields. The sljit_stack_resize
 1379    function can be used to extend this region up to min_start.
 1380 
 1381    This feature uses the "address space reserve" feature of modern
 1382    operating systems. Instead of allocating a large memory block
 1383    applications can allocate a small memory region and extend it
 1384    later without moving the content of the memory area. Therefore
 1385    after a successful resize by sljit_stack_resize all pointers into
 1386    this region are still valid.
 1387 
 1388    Note:
 1389      this structure may not be supported by all operating systems.
 1390      end and max_limit fields are aligned to PAGE_SIZE bytes (usually
 1391          4 Kbyte or more).
 1392      stack should grow in larger steps, e.g. 4Kbyte, 16Kbyte or more. */
 1393 
 1394 struct sljit_stack {
 1395     /* User data, anything can be stored here.
 1396        Initialized to the same value as the end field. */
 1397     sljit_u8 *top;
 1398 /* These members are read only. */
 1399     /* End address of the stack */
 1400     sljit_u8 *end;
 1401     /* Current start address of the stack. */
 1402     sljit_u8 *start;
 1403     /* Lowest start address of the stack. */
 1404     sljit_u8 *min_start;
 1405 };
 1406 
 1407 /* Allocates a new stack. Returns NULL if unsuccessful.
 1408    Note: see sljit_create_compiler for the explanation of allocator_data. */
 1409 SLJIT_API_FUNC_ATTRIBUTE struct sljit_stack* SLJIT_FUNC sljit_allocate_stack(sljit_uw start_size, sljit_uw max_size, void *allocator_data);
 1410 SLJIT_API_FUNC_ATTRIBUTE void SLJIT_FUNC sljit_free_stack(struct sljit_stack *stack, void *allocator_data);
 1411 
 1412 /* Can be used to increase (extend) or decrease (shrink) the stack
 1413    memory area. Returns with new_start if successful and NULL otherwise.
 1414    It always fails if new_start is less than min_start or greater or equal
 1415    than end fields. The fields of the stack are not changed if the returned
 1416    value is NULL (the current memory content is never lost). */
 1417 SLJIT_API_FUNC_ATTRIBUTE sljit_u8 *SLJIT_FUNC sljit_stack_resize(struct sljit_stack *stack, sljit_u8 *new_start);
 1418 
 1419 #endif /* (defined SLJIT_UTIL_STACK && SLJIT_UTIL_STACK) */
 1420 
 1421 #if !(defined SLJIT_INDIRECT_CALL && SLJIT_INDIRECT_CALL)
 1422 
 1423 /* Get the entry address of a given function. */
 1424 #define SLJIT_FUNC_OFFSET(func_name)    ((sljit_sw)func_name)
 1425 
 1426 #else /* !(defined SLJIT_INDIRECT_CALL && SLJIT_INDIRECT_CALL) */
 1427 
 1428 /* All JIT related code should be placed in the same context (library, binary, etc.). */
 1429 
 1430 #define SLJIT_FUNC_OFFSET(func_name)    (*(sljit_sw*)(void*)func_name)
 1431 
 1432 /* For powerpc64, the function pointers point to a context descriptor. */
 1433 struct sljit_function_context {
 1434     sljit_sw addr;
 1435     sljit_sw r2;
 1436     sljit_sw r11;
 1437 };
 1438 
 1439 /* Fill the context arguments using the addr and the function.
 1440    If func_ptr is NULL, it will not be set to the address of context
 1441    If addr is NULL, the function address also comes from the func pointer. */
 1442 SLJIT_API_FUNC_ATTRIBUTE void sljit_set_function_context(void** func_ptr, struct sljit_function_context* context, sljit_sw addr, void* func);
 1443 
 1444 #endif /* !(defined SLJIT_INDIRECT_CALL && SLJIT_INDIRECT_CALL) */
 1445 
 1446 #if (defined SLJIT_EXECUTABLE_ALLOCATOR && SLJIT_EXECUTABLE_ALLOCATOR)
 1447 /* Free unused executable memory. The allocator keeps some free memory
 1448    around to reduce the number of OS executable memory allocations.
 1449    This improves performance since these calls are costly. However
 1450    it is sometimes desired to free all unused memory regions, e.g.
 1451    before the application terminates. */
 1452 SLJIT_API_FUNC_ATTRIBUTE void sljit_free_unused_memory_exec(void);
 1453 #endif
 1454 
 1455 /* --------------------------------------------------------------------- */
 1456 /*  CPU specific functions                                               */
 1457 /* --------------------------------------------------------------------- */
 1458 
 1459 /* The following function is a helper function for sljit_emit_op_custom.
 1460    It returns with the real machine register index ( >=0 ) of any SLJIT_R,
 1461    SLJIT_S and SLJIT_SP registers.
 1462 
 1463    Note: it returns with -1 for virtual registers (only on x86-32). */
 1464 
 1465 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_get_register_index(sljit_s32 reg);
 1466 
 1467 /* The following function is a helper function for sljit_emit_op_custom.
 1468    It returns with the real machine register index of any SLJIT_FLOAT register.
 1469 
 1470    Note: the index is always an even number on ARM (except ARM-64), MIPS, and SPARC. */
 1471 
 1472 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_get_float_register_index(sljit_s32 reg);
 1473 
 1474 /* Any instruction can be inserted into the instruction stream by
 1475    sljit_emit_op_custom. It has a similar purpose as inline assembly.
 1476    The size parameter must match to the instruction size of the target
 1477    architecture:
 1478 
 1479          x86: 0 < size <= 15. The instruction argument can be byte aligned.
 1480       Thumb2: if size == 2, the instruction argument must be 2 byte aligned.
 1481               if size == 4, the instruction argument must be 4 byte aligned.
 1482    Otherwise: size must be 4 and instruction argument must be 4 byte aligned. */
 1483 
 1484 SLJIT_API_FUNC_ATTRIBUTE sljit_s32 sljit_emit_op_custom(struct sljit_compiler *compiler,
 1485     void *instruction, sljit_s32 size);
 1486 
 1487 /* Define the currently available CPU status flags. It is usually used after an
 1488    sljit_emit_op_custom call to define which flags are set. */
 1489 
 1490 SLJIT_API_FUNC_ATTRIBUTE void sljit_set_current_flags(struct sljit_compiler *compiler,
 1491     sljit_s32 current_flags);
 1492 
 1493 #endif /* _SLJIT_LIR_H_ */