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ruby--ruby/mjit_compile.c
2021-08-30 09:06:36 +09:00

590 lines
25 KiB
C

/**********************************************************************
mjit_compile.c - MRI method JIT compiler
Copyright (C) 2017 Takashi Kokubun <takashikkbn@gmail.com>.
**********************************************************************/
// NOTE: All functions in this file are executed on MJIT worker. So don't
// call Ruby methods (C functions that may call rb_funcall) or trigger
// GC (using ZALLOC, xmalloc, xfree, etc.) in this file.
#include "ruby/internal/config.h" // defines USE_MJIT
#if USE_MJIT
#include "internal.h"
#include "internal/compile.h"
#include "internal/hash.h"
#include "internal/object.h"
#include "internal/variable.h"
#include "mjit.h"
#include "vm_core.h"
#include "vm_callinfo.h"
#include "vm_exec.h"
#include "vm_insnhelper.h"
#include "builtin.h"
#include "insns.inc"
#include "insns_info.inc"
// Macros to check if a position is already compiled using compile_status.stack_size_for_pos
#define NOT_COMPILED_STACK_SIZE -1
#define ALREADY_COMPILED_P(status, pos) (status->stack_size_for_pos[pos] != NOT_COMPILED_STACK_SIZE)
// For propagating information needed for lazily pushing a frame.
struct inlined_call_context {
int orig_argc; // ci->orig_argc
VALUE me; // vm_cc_cme(cc)
int param_size; // def_iseq_ptr(vm_cc_cme(cc)->def)->body->param.size
int local_size; // def_iseq_ptr(vm_cc_cme(cc)->def)->body->local_table_size
};
// Storage to keep compiler's status. This should have information
// which is global during one `mjit_compile` call. Ones conditional
// in each branch should be stored in `compile_branch`.
struct compile_status {
bool success; // has true if compilation has had no issue
int *stack_size_for_pos; // stack_size_for_pos[pos] has stack size for the position (otherwise -1)
// If true, JIT-ed code will use local variables to store pushed values instead of
// using VM's stack and moving stack pointer.
bool local_stack_p;
// Safely-accessible ivar cache entries copied from main thread.
union iseq_inline_storage_entry *is_entries;
// Index of call cache entries captured to compiled_iseq to be marked on GC
int cc_entries_index;
// A pointer to root (i.e. not inlined) iseq being compiled.
const struct rb_iseq_constant_body *compiled_iseq;
int compiled_id; // Just a copy of compiled_iseq->jit_unit->id
// Mutated optimization levels
struct rb_mjit_compile_info *compile_info;
bool merge_ivar_guards_p; // If true, merge guards of ivar accesses
rb_serial_t ivar_serial; // ic_serial of IVC in is_entries (used only when merge_ivar_guards_p)
size_t max_ivar_index; // Max IVC index in is_entries (used only when merge_ivar_guards_p)
// If `inlined_iseqs[pos]` is not NULL, `mjit_compile_body` tries to inline ISeq there.
const struct rb_iseq_constant_body **inlined_iseqs;
struct inlined_call_context inline_context;
};
// Storage to keep data which is consistent in each conditional branch.
// This is created and used for one `compile_insns` call and its values
// should be copied for extra `compile_insns` call.
struct compile_branch {
unsigned int stack_size; // this simulates sp (stack pointer) of YARV
bool finish_p; // if true, compilation in this branch should stop and let another branch to be compiled
};
struct case_dispatch_var {
FILE *f;
unsigned int base_pos;
VALUE last_value;
};
static size_t
call_data_index(CALL_DATA cd, const struct rb_iseq_constant_body *body)
{
return cd - body->call_data;
}
const struct rb_callcache ** mjit_iseq_cc_entries(const struct rb_iseq_constant_body *const body);
// Using this function to refer to cc_entries allocated by `mjit_capture_cc_entries`
// instead of storing cc_entries in status directly so that we always refer to a new address
// returned by `realloc` inside it.
static const struct rb_callcache **
captured_cc_entries(const struct compile_status *status)
{
VM_ASSERT(status->cc_entries_index != -1);
return mjit_iseq_cc_entries(status->compiled_iseq) + status->cc_entries_index;
}
// Returns true if call cache is still not obsoleted and vm_cc_cme(cc)->def->type is available.
static bool
has_valid_method_type(CALL_CACHE cc)
{
return vm_cc_cme(cc) != NULL;
}
// Returns true if MJIT thinks this cc's opt_* insn may fallback to opt_send_without_block.
static bool
has_cache_for_send(CALL_CACHE cc, int insn)
{
extern bool rb_vm_opt_cfunc_p(CALL_CACHE cc, int insn);
return has_valid_method_type(cc) &&
!(vm_cc_cme(cc)->def->type == VM_METHOD_TYPE_CFUNC && rb_vm_opt_cfunc_p(cc, insn));
}
// Returns true if iseq can use fastpath for setup, otherwise NULL. This becomes true in the same condition
// as CC_SET_FASTPATH (in vm_callee_setup_arg) is called from vm_call_iseq_setup.
static bool
fastpath_applied_iseq_p(const CALL_INFO ci, const CALL_CACHE cc, const rb_iseq_t *iseq)
{
extern bool rb_simple_iseq_p(const rb_iseq_t *iseq);
return iseq != NULL
&& !(vm_ci_flag(ci) & VM_CALL_KW_SPLAT) && rb_simple_iseq_p(iseq) // Top of vm_callee_setup_arg. In this case, opt_pc is 0.
&& vm_ci_argc(ci) == (unsigned int)iseq->body->param.lead_num // exclude argument_arity_error (assumption: `calling->argc == ci->orig_argc` in send insns)
&& vm_call_iseq_optimizable_p(ci, cc); // CC_SET_FASTPATH condition
}
// Return true if an object of the klass may be a special const. See: rb_class_of
static bool
maybe_special_const_class_p(const VALUE klass)
{
return klass == rb_cFalseClass
|| klass == rb_cNilClass
|| klass == rb_cTrueClass
|| klass == rb_cInteger
|| klass == rb_cSymbol
|| klass == rb_cFloat;
}
static int
compile_case_dispatch_each(VALUE key, VALUE value, VALUE arg)
{
struct case_dispatch_var *var = (struct case_dispatch_var *)arg;
unsigned int offset;
if (var->last_value != value) {
offset = FIX2INT(value);
var->last_value = value;
fprintf(var->f, " case %d:\n", offset);
fprintf(var->f, " goto label_%d;\n", var->base_pos + offset);
fprintf(var->f, " break;\n");
}
return ST_CONTINUE;
}
// Calling rb_id2str in MJIT worker causes random SEGV. So this is disabled by default.
static void
comment_id(FILE *f, ID id)
{
#ifdef MJIT_COMMENT_ID
VALUE name = rb_id2str(id);
const char *p, *e;
char c, prev = '\0';
if (!name) return;
p = RSTRING_PTR(name);
e = RSTRING_END(name);
fputs("/* :\"", f);
for (; p < e; ++p) {
switch (c = *p) {
case '*': case '/': if (prev != (c ^ ('/' ^ '*'))) break;
case '\\': case '"': fputc('\\', f);
}
fputc(c, f);
prev = c;
}
fputs("\" */", f);
#endif
}
static void compile_insns(FILE *f, const struct rb_iseq_constant_body *body, unsigned int stack_size,
unsigned int pos, struct compile_status *status);
// Main function of JIT compilation, vm_exec_core counterpart for JIT. Compile one insn to `f`, may modify
// b->stack_size and return next position.
//
// When you add a new instruction to insns.def, it would be nice to have JIT compilation support here but
// it's optional. This JIT compiler just ignores ISeq which includes unknown instruction, and ISeq which
// does not have it can be compiled as usual.
static unsigned int
compile_insn(FILE *f, const struct rb_iseq_constant_body *body, const int insn, const VALUE *operands,
const unsigned int pos, struct compile_status *status, struct compile_branch *b)
{
unsigned int next_pos = pos + insn_len(insn);
/*****************/
#include "mjit_compile.inc"
/*****************/
// If next_pos is already compiled and this branch is not finished yet,
// next instruction won't be compiled in C code next and will need `goto`.
if (!b->finish_p && next_pos < body->iseq_size && ALREADY_COMPILED_P(status, next_pos)) {
fprintf(f, "goto label_%d;\n", next_pos);
// Verify stack size assumption is the same among multiple branches
if ((unsigned int)status->stack_size_for_pos[next_pos] != b->stack_size) {
if (mjit_opts.warnings || mjit_opts.verbose)
fprintf(stderr, "MJIT warning: JIT stack assumption is not the same between branches (%d != %u)\n",
status->stack_size_for_pos[next_pos], b->stack_size);
status->success = false;
}
}
return next_pos;
}
// Compile one conditional branch. If it has branchXXX insn, this should be
// called multiple times for each branch.
static void
compile_insns(FILE *f, const struct rb_iseq_constant_body *body, unsigned int stack_size,
unsigned int pos, struct compile_status *status)
{
struct compile_branch branch;
branch.stack_size = stack_size;
branch.finish_p = false;
while (pos < body->iseq_size && !ALREADY_COMPILED_P(status, pos) && !branch.finish_p) {
int insn = rb_vm_insn_decode(body->iseq_encoded[pos]);
status->stack_size_for_pos[pos] = (int)branch.stack_size;
fprintf(f, "\nlabel_%d: /* %s */\n", pos, insn_name(insn));
pos = compile_insn(f, body, insn, body->iseq_encoded + (pos+1), pos, status, &branch);
if (status->success && branch.stack_size > body->stack_max) {
if (mjit_opts.warnings || mjit_opts.verbose)
fprintf(stderr, "MJIT warning: JIT stack size (%d) exceeded its max size (%d)\n", branch.stack_size, body->stack_max);
status->success = false;
}
if (!status->success)
break;
}
}
// Print the block to cancel inlined method call. It's supporting only `opt_send_without_block` for now.
static void
compile_inlined_cancel_handler(FILE *f, const struct rb_iseq_constant_body *body, struct inlined_call_context *inline_context)
{
fprintf(f, "\ncancel:\n");
fprintf(f, " RB_DEBUG_COUNTER_INC(mjit_cancel);\n");
fprintf(f, " rb_mjit_recompile_inlining(original_iseq);\n");
// Swap pc/sp set on cancel with original pc/sp.
fprintf(f, " const VALUE *current_pc = reg_cfp->pc;\n");
fprintf(f, " VALUE *current_sp = reg_cfp->sp;\n");
fprintf(f, " reg_cfp->pc = orig_pc;\n");
fprintf(f, " reg_cfp->sp = orig_sp;\n\n");
// Lazily push the current call frame.
fprintf(f, " struct rb_calling_info calling;\n");
fprintf(f, " calling.block_handler = VM_BLOCK_HANDLER_NONE;\n"); // assumes `opt_send_without_block`
fprintf(f, " calling.argc = %d;\n", inline_context->orig_argc);
fprintf(f, " calling.recv = reg_cfp->self;\n");
fprintf(f, " reg_cfp->self = orig_self;\n");
fprintf(f, " vm_call_iseq_setup_normal(ec, reg_cfp, &calling, (const rb_callable_method_entry_t *)0x%"PRIxVALUE", 0, %d, %d);\n\n",
inline_context->me, inline_context->param_size, inline_context->local_size); // fastpath_applied_iseq_p checks rb_simple_iseq_p, which ensures has_opt == FALSE
// Start usual cancel from here.
fprintf(f, " reg_cfp = ec->cfp;\n"); // work on the new frame
fprintf(f, " reg_cfp->pc = current_pc;\n");
fprintf(f, " reg_cfp->sp = current_sp;\n");
for (unsigned int i = 0; i < body->stack_max; i++) { // should be always `status->local_stack_p`
fprintf(f, " *(vm_base_ptr(reg_cfp) + %d) = stack[%d];\n", i, i);
}
// We're not just returning Qundef here so that caller's normal cancel handler can
// push back `stack` to `cfp->sp`.
fprintf(f, " return vm_exec(ec, false);\n");
}
// Print the block to cancel JIT execution.
static void
compile_cancel_handler(FILE *f, const struct rb_iseq_constant_body *body, struct compile_status *status)
{
if (status->inlined_iseqs == NULL) { // the current ISeq is being inlined
compile_inlined_cancel_handler(f, body, &status->inline_context);
return;
}
fprintf(f, "\nsend_cancel:\n");
fprintf(f, " RB_DEBUG_COUNTER_INC(mjit_cancel_send_inline);\n");
fprintf(f, " rb_mjit_recompile_send(original_iseq);\n");
fprintf(f, " goto cancel;\n");
fprintf(f, "\nivar_cancel:\n");
fprintf(f, " RB_DEBUG_COUNTER_INC(mjit_cancel_ivar_inline);\n");
fprintf(f, " rb_mjit_recompile_ivar(original_iseq);\n");
fprintf(f, " goto cancel;\n");
fprintf(f, "\nexivar_cancel:\n");
fprintf(f, " RB_DEBUG_COUNTER_INC(mjit_cancel_exivar_inline);\n");
fprintf(f, " rb_mjit_recompile_exivar(original_iseq);\n");
fprintf(f, " goto cancel;\n");
fprintf(f, "\nconst_cancel:\n");
fprintf(f, " rb_mjit_recompile_const(original_iseq);\n");
fprintf(f, " goto cancel;\n");
fprintf(f, "\ncancel:\n");
fprintf(f, " RB_DEBUG_COUNTER_INC(mjit_cancel);\n");
if (status->local_stack_p) {
for (unsigned int i = 0; i < body->stack_max; i++) {
fprintf(f, " *(vm_base_ptr(reg_cfp) + %d) = stack[%d];\n", i, i);
}
}
fprintf(f, " return Qundef;\n");
}
extern int
mjit_capture_cc_entries(const struct rb_iseq_constant_body *compiled_iseq, const struct rb_iseq_constant_body *captured_iseq);
// Copy current is_entries and use it throughout the current compilation consistently.
// While ic->entry has been immutable since https://github.com/ruby/ruby/pull/3662,
// we still need this to avoid a race condition between entries and ivar_serial/max_ivar_index.
static void
mjit_capture_is_entries(const struct rb_iseq_constant_body *body, union iseq_inline_storage_entry *is_entries)
{
if (is_entries == NULL)
return;
memcpy(is_entries, body->is_entries, sizeof(union iseq_inline_storage_entry) * body->is_size);
}
static bool
mjit_compile_body(FILE *f, const rb_iseq_t *iseq, struct compile_status *status)
{
const struct rb_iseq_constant_body *body = iseq->body;
status->success = true;
status->local_stack_p = !body->catch_except_p;
if (status->local_stack_p) {
fprintf(f, " VALUE stack[%d];\n", body->stack_max);
}
else {
fprintf(f, " VALUE *stack = reg_cfp->sp;\n");
}
if (status->inlined_iseqs != NULL) // i.e. compile root
fprintf(f, " static const rb_iseq_t *original_iseq = (const rb_iseq_t *)0x%"PRIxVALUE";\n", (VALUE)iseq);
fprintf(f, " static const VALUE *const original_body_iseq = (VALUE *)0x%"PRIxVALUE";\n",
(VALUE)body->iseq_encoded);
fprintf(f, " VALUE cfp_self = reg_cfp->self;\n"); // cache self across the method
fprintf(f, "#undef GET_SELF\n");
fprintf(f, "#define GET_SELF() cfp_self\n");
// Generate merged ivar guards first if needed
if (!status->compile_info->disable_ivar_cache && status->merge_ivar_guards_p) {
fprintf(f, " if (UNLIKELY(!(RB_TYPE_P(GET_SELF(), T_OBJECT) && (rb_serial_t)%"PRI_SERIALT_PREFIX"u == RCLASS_SERIAL(RBASIC(GET_SELF())->klass) &&", status->ivar_serial);
if (status->max_ivar_index >= ROBJECT_EMBED_LEN_MAX) {
fprintf(f, "%"PRIuSIZE" < ROBJECT_NUMIV(GET_SELF())", status->max_ivar_index); // index < ROBJECT_NUMIV(obj) && !RB_FL_ANY_RAW(obj, ROBJECT_EMBED)
}
else {
fprintf(f, "ROBJECT_EMBED_LEN_MAX == ROBJECT_NUMIV(GET_SELF())"); // index < ROBJECT_NUMIV(obj) && RB_FL_ANY_RAW(obj, ROBJECT_EMBED)
}
fprintf(f, "))) {\n");
fprintf(f, " goto ivar_cancel;\n");
fprintf(f, " }\n");
}
// Simulate `opt_pc` in setup_parameters_complex. Other PCs which may be passed by catch tables
// are not considered since vm_exec doesn't call mjit_exec for catch tables.
if (body->param.flags.has_opt) {
int i;
fprintf(f, "\n");
fprintf(f, " switch (reg_cfp->pc - reg_cfp->iseq->body->iseq_encoded) {\n");
for (i = 0; i <= body->param.opt_num; i++) {
VALUE pc_offset = body->param.opt_table[i];
fprintf(f, " case %"PRIdVALUE":\n", pc_offset);
fprintf(f, " goto label_%"PRIdVALUE";\n", pc_offset);
}
fprintf(f, " }\n");
}
compile_insns(f, body, 0, 0, status);
compile_cancel_handler(f, body, status);
fprintf(f, "#undef GET_SELF");
return status->success;
}
// Return true if the ISeq can be inlined without pushing a new control frame.
static bool
inlinable_iseq_p(const struct rb_iseq_constant_body *body)
{
// 1) If catch_except_p, caller frame should be preserved when callee catches an exception.
// Then we need to wrap `vm_exec()` but then we can't inline the call inside it.
//
// 2) If `body->catch_except_p` is false and `handles_sp?` of an insn is false,
// sp is not moved as we assume `status->local_stack_p = !body->catch_except_p`.
//
// 3) If `body->catch_except_p` is false and `always_leaf?` of an insn is true,
// pc is not moved.
if (body->catch_except_p)
return false;
unsigned int pos = 0;
while (pos < body->iseq_size) {
int insn = rb_vm_insn_decode(body->iseq_encoded[pos]);
// All insns in the ISeq except `leave` (to be overridden in the inlined code)
// should meet following strong assumptions:
// * Do not require `cfp->sp` motion
// * Do not move `cfp->pc`
// * Do not read any `cfp->pc`
if (insn == BIN(invokebuiltin) || insn == BIN(opt_invokebuiltin_delegate) || insn == BIN(opt_invokebuiltin_delegate_leave)) {
// builtin insn's inlinability is handled by `Primitive.attr! 'inline'` per iseq
if (!body->builtin_inline_p)
return false;
}
else if (insn != BIN(leave) && insn_may_depend_on_sp_or_pc(insn, body->iseq_encoded + (pos + 1)))
return false;
// At this moment, `cfp->ep` in an inlined method is not working.
switch (insn) {
case BIN(getlocal):
case BIN(getlocal_WC_0):
case BIN(getlocal_WC_1):
case BIN(setlocal):
case BIN(setlocal_WC_0):
case BIN(setlocal_WC_1):
case BIN(getblockparam):
case BIN(getblockparamproxy):
case BIN(setblockparam):
return false;
}
pos += insn_len(insn);
}
return true;
}
// Return an iseq pointer if cc has inlinable iseq.
const rb_iseq_t *
rb_mjit_inlinable_iseq(const struct rb_callinfo *ci, const struct rb_callcache *cc)
{
const rb_iseq_t *iseq;
if (has_valid_method_type(cc) &&
!(vm_ci_flag(ci) & VM_CALL_TAILCALL) && // inlining only non-tailcall path
vm_cc_cme(cc)->def->type == VM_METHOD_TYPE_ISEQ &&
fastpath_applied_iseq_p(ci, cc, iseq = def_iseq_ptr(vm_cc_cme(cc)->def)) &&
// CC_SET_FASTPATH in vm_callee_setup_arg
inlinable_iseq_p(iseq->body)) {
return iseq;
}
return NULL;
}
static void
init_ivar_compile_status(const struct rb_iseq_constant_body *body, struct compile_status *status)
{
mjit_capture_is_entries(body, status->is_entries);
int num_ivars = 0;
unsigned int pos = 0;
status->max_ivar_index = 0;
status->ivar_serial = 0;
while (pos < body->iseq_size) {
int insn = rb_vm_insn_decode(body->iseq_encoded[pos]);
if (insn == BIN(getinstancevariable) || insn == BIN(setinstancevariable)) {
IVC ic = (IVC)body->iseq_encoded[pos+2];
IVC ic_copy = &(status->is_entries + ((union iseq_inline_storage_entry *)ic - body->is_entries))->iv_cache;
if (ic_copy->entry) { // Only initialized (ic_serial > 0) IVCs are optimized
num_ivars++;
if (status->max_ivar_index < ic_copy->entry->index) {
status->max_ivar_index = ic_copy->entry->index;
}
if (status->ivar_serial == 0) {
status->ivar_serial = ic_copy->entry->class_serial;
}
else if (status->ivar_serial != ic_copy->entry->class_serial) {
// Multiple classes have used this ISeq. Give up assuming one serial.
status->merge_ivar_guards_p = false;
return;
}
}
}
pos += insn_len(insn);
}
status->merge_ivar_guards_p = status->ivar_serial > 0 && num_ivars >= 2;
}
// This needs to be macro instead of a function because it's using `alloca`.
#define INIT_COMPILE_STATUS(status, body, compile_root_p) do { \
status = (struct compile_status){ \
.stack_size_for_pos = (int *)alloca(sizeof(int) * body->iseq_size), \
.inlined_iseqs = compile_root_p ? \
alloca(sizeof(const struct rb_iseq_constant_body *) * body->iseq_size) : NULL, \
.is_entries = (body->is_size > 0) ? \
alloca(sizeof(union iseq_inline_storage_entry) * body->is_size) : NULL, \
.cc_entries_index = (body->ci_size > 0) ? \
mjit_capture_cc_entries(status.compiled_iseq, body) : -1, \
.compiled_id = status.compiled_id, \
.compiled_iseq = status.compiled_iseq, \
.compile_info = compile_root_p ? \
rb_mjit_iseq_compile_info(body) : alloca(sizeof(struct rb_mjit_compile_info)) \
}; \
memset(status.stack_size_for_pos, NOT_COMPILED_STACK_SIZE, sizeof(int) * body->iseq_size); \
if (compile_root_p) \
memset((void *)status.inlined_iseqs, 0, sizeof(const struct rb_iseq_constant_body *) * body->iseq_size); \
else \
memset(status.compile_info, 0, sizeof(struct rb_mjit_compile_info)); \
} while (0)
// Compile inlinable ISeqs to C code in `f`. It returns true if it succeeds to compile them.
static bool
precompile_inlinable_iseqs(FILE *f, const rb_iseq_t *iseq, struct compile_status *status)
{
const struct rb_iseq_constant_body *body = iseq->body;
unsigned int pos = 0;
while (pos < body->iseq_size) {
int insn = rb_vm_insn_decode(body->iseq_encoded[pos]);
if (insn == BIN(opt_send_without_block) || insn == BIN(opt_size)) { // `compile_inlined_cancel_handler` supports only `opt_send_without_block`
CALL_DATA cd = (CALL_DATA)body->iseq_encoded[pos + 1];
const struct rb_callinfo *ci = cd->ci;
const struct rb_callcache *cc = captured_cc_entries(status)[call_data_index(cd, body)]; // use copy to avoid race condition
extern bool rb_mjit_compiling_iseq_p(const rb_iseq_t *iseq);
const rb_iseq_t *child_iseq;
if ((child_iseq = rb_mjit_inlinable_iseq(ci, cc)) != NULL && rb_mjit_compiling_iseq_p(child_iseq)) {
status->inlined_iseqs[pos] = child_iseq->body;
if (mjit_opts.verbose >= 1) // print beforehand because ISeq may be GCed during copy job.
fprintf(stderr, "JIT inline: %s@%s:%d => %s@%s:%d\n",
RSTRING_PTR(child_iseq->body->location.label),
RSTRING_PTR(rb_iseq_path(child_iseq)), FIX2INT(child_iseq->body->location.first_lineno),
RSTRING_PTR(iseq->body->location.label),
RSTRING_PTR(rb_iseq_path(iseq)), FIX2INT(iseq->body->location.first_lineno));
struct compile_status child_status = { .compiled_iseq = status->compiled_iseq, .compiled_id = status->compiled_id };
INIT_COMPILE_STATUS(child_status, child_iseq->body, false);
child_status.inline_context = (struct inlined_call_context){
.orig_argc = vm_ci_argc(ci),
.me = (VALUE)vm_cc_cme(cc),
.param_size = child_iseq->body->param.size,
.local_size = child_iseq->body->local_table_size
};
if (child_iseq->body->ci_size > 0 && child_status.cc_entries_index == -1) {
return false;
}
init_ivar_compile_status(child_iseq->body, &child_status);
fprintf(f, "ALWAYS_INLINE(static VALUE _mjit%d_inlined_%d(rb_execution_context_t *ec, rb_control_frame_t *reg_cfp, const VALUE orig_self, const rb_iseq_t *original_iseq));\n", status->compiled_id, pos);
fprintf(f, "static inline VALUE\n_mjit%d_inlined_%d(rb_execution_context_t *ec, rb_control_frame_t *reg_cfp, const VALUE orig_self, const rb_iseq_t *original_iseq)\n{\n", status->compiled_id, pos);
fprintf(f, " const VALUE *orig_pc = reg_cfp->pc;\n");
fprintf(f, " VALUE *orig_sp = reg_cfp->sp;\n");
bool success = mjit_compile_body(f, child_iseq, &child_status);
fprintf(f, "\n} /* end of _mjit%d_inlined_%d */\n\n", status->compiled_id, pos);
if (!success)
return false;
}
}
pos += insn_len(insn);
}
return true;
}
// Compile ISeq to C code in `f`. It returns true if it succeeds to compile.
bool
mjit_compile(FILE *f, const rb_iseq_t *iseq, const char *funcname, int id)
{
struct compile_status status = { .compiled_iseq = iseq->body, .compiled_id = id };
INIT_COMPILE_STATUS(status, iseq->body, true);
if (iseq->body->ci_size > 0 && status.cc_entries_index == -1) {
return false;
}
init_ivar_compile_status(iseq->body, &status);
if (!status.compile_info->disable_send_cache && !status.compile_info->disable_inlining) {
if (!precompile_inlinable_iseqs(f, iseq, &status))
return false;
}
#ifdef _WIN32
fprintf(f, "__declspec(dllexport)\n");
#endif
fprintf(f, "VALUE\n%s(rb_execution_context_t *ec, rb_control_frame_t *reg_cfp)\n{\n", funcname);
bool success = mjit_compile_body(f, iseq, &status);
fprintf(f, "\n} // end of %s\n", funcname);
return success;
}
#endif // USE_MJIT