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ruby--ruby/yjit.c
Alan Wu 9f09397bfe
YJIT: On-demand executable memory allocation; faster boot (#5944)
This commit makes YJIT allocate memory for generated code gradually as
needed. Previously, YJIT allocates all the memory it needs on boot in
one go, leading to higher than necessary resident set size (RSS) and
time spent on boot initializing the memory with a large memset().

Users should no longer need to search for a magic number to pass to
`--yjit-exec-mem` since physical memory consumption should now more
accurately reflect the requirement of the workload.

YJIT now reserves a range of addresses on boot. This region start out
with no access permission at all so buggy attempts to jump to the region
crashes like before this change. To get this hardening at finer
granularity than the page size, we fill each page with trapping
instructions when we first allocate physical memory for the page.

Most of the time applications don't need 256 MiB of executable code, so
allocating on-demand ends up doing less total work than before. Case in
point, a simple `ruby --yjit-call-threshold=1 -eitself` takes about
half as long after this change. In terms of memory consumption, here is
a table to give a rough summary of the impact:

    | Peak RSS in MiB | -eitself example | railsbench once |
    | :-------------: | ---------------: | --------------: |
    |     before      |              265 |             377 |
    |      after      |               11 |             143 |
    |     no YJIT     |               10 |             101 |

A new module is introduced to handle allocation bookkeeping.
`CodePtr` is moved into the module since it has a close relationship
with the new `VirtualMemory` struct. This new interface has a slightly
smaller surface than before in that marking a region as writable is no
longer a public operation.
2022-06-14 10:23:13 -04:00

972 lines
26 KiB
C

// This part of YJIT helps interfacing with the rest of CRuby and with the OS.
// Sometimes our FFI binding generation tool gives undesirable outputs when it
// sees C features that Rust doesn't support well. We mitigate that by binding
// functions which have simple parameter types. The boilerplate C functions for
// that purpose are in this file.
// Similarly, we wrap OS facilities we need in simple functions to help with
// FFI and to avoid the need to use external crates.io Rust libraries.
#include "internal.h"
#include "internal/sanitizers.h"
#include "internal/string.h"
#include "internal/hash.h"
#include "internal/variable.h"
#include "internal/compile.h"
#include "internal/class.h"
#include "gc.h"
#include "vm_core.h"
#include "vm_callinfo.h"
#include "builtin.h"
#include "insns.inc"
#include "insns_info.inc"
#include "vm_sync.h"
#include "yjit.h"
#include "vm_insnhelper.h"
#include "probes.h"
#include "probes_helper.h"
#include "iseq.h"
#include "ruby/debug.h"
// For mmapp(), sysconf()
#ifndef _WIN32
#include <unistd.h>
#include <sys/mman.h>
#endif
#include <errno.h>
// We need size_t to have a known size to simplify code generation and FFI.
// TODO(alan): check this in configure.ac to fail fast on 32 bit platforms.
STATIC_ASSERT(64b_size_t, SIZE_MAX == UINT64_MAX);
// I don't know any C implementation that has uint64_t and puts padding bits
// into size_t but the standard seems to allow it.
STATIC_ASSERT(size_t_no_padding_bits, sizeof(size_t) == sizeof(uint64_t));
// This build config impacts the pointer tagging scheme and we only want to
// support one scheme for simplicity.
STATIC_ASSERT(pointer_tagging_scheme, USE_FLONUM);
// NOTE: We can trust that uint8_t has no "padding bits" since the C spec
// guarantees it. Wording about padding bits is more explicit in C11 compared
// to C99. See C11 7.20.1.1p2. All this is to say we have _some_ standards backing to
// use a Rust `*mut u8` to represent a C `uint8_t *`.
//
// If we don't want to trust that we can interpreter the C standard correctly, we
// could outsource that work to the Rust standard library by sticking to fundamental
// types in C such as int, long, etc. and use `std::os::raw::c_long` and friends on
// the Rust side.
//
// What's up with the long prefix? The "rb_" part is to appease `make leaked-globals`
// which runs on upstream CI. The rationale for the check is unclear to Alan as
// we build with `-fvisibility=hidden` so only explicitly marked functions end
// up as public symbols in libruby.so. Perhaps the check is for the static
// libruby and or general namspacing hygiene? Alan admits his bias towards ELF
// platforms and newer compilers.
//
// The "_yjit_" part is for trying to be informative. We might want different
// suffixes for symbols meant for Rust and symbols meant for broader CRuby.
bool
rb_yjit_mark_writable(void *mem_block, uint32_t mem_size)
{
if (mprotect(mem_block, mem_size, PROT_READ | PROT_WRITE)) {
return false;
}
return true;
}
void
rb_yjit_mark_executable(void *mem_block, uint32_t mem_size)
{
if (mprotect(mem_block, mem_size, PROT_READ | PROT_EXEC)) {
rb_bug("Couldn't make JIT page (%p, %lu bytes) executable, errno: %s\n",
mem_block, (unsigned long)mem_size, strerror(errno));
}
}
# define PTR2NUM(x) (rb_int2inum((intptr_t)(void *)(x)))
// For a given raw_sample (frame), set the hash with the caller's
// name, file, and line number. Return the hash with collected frame_info.
static void
rb_yjit_add_frame(VALUE hash, VALUE frame)
{
VALUE frame_id = PTR2NUM(frame);
if (RTEST(rb_hash_aref(hash, frame_id))) {
return;
} else {
VALUE frame_info = rb_hash_new();
// Full label for the frame
VALUE name = rb_profile_frame_full_label(frame);
// Absolute path of the frame from rb_iseq_realpath
VALUE file = rb_profile_frame_absolute_path(frame);
// Line number of the frame
VALUE line = rb_profile_frame_first_lineno(frame);
// If absolute path isn't available use the rb_iseq_path
if (NIL_P(file)) {
file = rb_profile_frame_path(frame);
}
rb_hash_aset(frame_info, ID2SYM(rb_intern("name")), name);
rb_hash_aset(frame_info, ID2SYM(rb_intern("file")), file);
if (line != INT2FIX(0)) {
rb_hash_aset(frame_info, ID2SYM(rb_intern("line")), line);
}
rb_hash_aset(hash, frame_id, frame_info);
}
}
// Parses the YjitExitLocations raw_samples and line_samples collected by
// rb_yjit_record_exit_stack and turns them into 3 hashes (raw, lines, and frames) to
// be used by RubyVM::YJIT.exit_locations. yjit_raw_samples represents the raw frames information
// (without name, file, and line), and yjit_line_samples represents the line information
// of the iseq caller.
VALUE
rb_yjit_exit_locations_dict(VALUE *yjit_raw_samples, int *yjit_line_samples, int samples_len)
{
VALUE result = rb_hash_new();
VALUE raw_samples = rb_ary_new_capa(samples_len);
VALUE line_samples = rb_ary_new_capa(samples_len);
VALUE frames = rb_hash_new();
int idx = 0;
// While the index is less than samples_len, parse yjit_raw_samples and
// yjit_line_samples, then add casted values to raw_samples and line_samples array.
while (idx < samples_len) {
int num = (int)yjit_raw_samples[idx];
int line_num = (int)yjit_line_samples[idx];
idx++;
rb_ary_push(raw_samples, SIZET2NUM(num));
rb_ary_push(line_samples, INT2NUM(line_num));
// Loop through the length of samples_len and add data to the
// frames hash. Also push the current value onto the raw_samples
// and line_samples array respectively.
for (int o = 0; o < num; o++) {
rb_yjit_add_frame(frames, yjit_raw_samples[idx]);
rb_ary_push(raw_samples, SIZET2NUM(yjit_raw_samples[idx]));
rb_ary_push(line_samples, INT2NUM(yjit_line_samples[idx]));
idx++;
}
rb_ary_push(raw_samples, SIZET2NUM(yjit_raw_samples[idx]));
rb_ary_push(line_samples, INT2NUM(yjit_line_samples[idx]));
idx++;
rb_ary_push(raw_samples, SIZET2NUM(yjit_raw_samples[idx]));
rb_ary_push(line_samples, INT2NUM(yjit_line_samples[idx]));
idx++;
}
// Set add the raw_samples, line_samples, and frames to the results
// hash.
rb_hash_aset(result, ID2SYM(rb_intern("raw")), raw_samples);
rb_hash_aset(result, ID2SYM(rb_intern("lines")), line_samples);
rb_hash_aset(result, ID2SYM(rb_intern("frames")), frames);
return result;
}
uint32_t
rb_yjit_get_page_size(void)
{
#if defined(_SC_PAGESIZE)
long page_size = sysconf(_SC_PAGESIZE);
if (page_size <= 0) rb_bug("yjit: failed to get page size");
// 1 GiB limit. x86 CPUs with PDPE1GB can do this and anything larger is unexpected.
// Though our design sort of assume we have fine grained control over memory protection
// which require small page sizes.
if (page_size > 0x40000000l) rb_bug("yjit page size too large");
return (uint32_t)page_size;
#else
#error "YJIT supports POSIX only for now"
#endif
}
#if defined(MAP_FIXED_NOREPLACE) && defined(_SC_PAGESIZE)
// Align the current write position to a multiple of bytes
static uint8_t *
align_ptr(uint8_t *ptr, uint32_t multiple)
{
// Compute the pointer modulo the given alignment boundary
uint32_t rem = ((uint32_t)(uintptr_t)ptr) % multiple;
// If the pointer is already aligned, stop
if (rem == 0)
return ptr;
// Pad the pointer by the necessary amount to align it
uint32_t pad = multiple - rem;
return ptr + pad;
}
#endif
// Address space reservation. Memory pages are mapped on an as needed basis.
// See the Rust mm module for details.
uint8_t *
rb_yjit_reserve_addr_space(uint32_t mem_size)
{
#ifndef _WIN32
uint8_t *mem_block;
// On Linux
#if defined(MAP_FIXED_NOREPLACE) && defined(_SC_PAGESIZE)
uint32_t const page_size = (uint32_t)sysconf(_SC_PAGESIZE);
uint8_t *const cfunc_sample_addr = (void *)&rb_yjit_reserve_addr_space;
uint8_t *const probe_region_end = cfunc_sample_addr + INT32_MAX;
// Align the requested address to page size
uint8_t *req_addr = align_ptr(cfunc_sample_addr, page_size);
// Probe for addresses close to this function using MAP_FIXED_NOREPLACE
// to improve odds of being in range for 32-bit relative call instructions.
do {
mem_block = mmap(
req_addr,
mem_size,
PROT_NONE,
MAP_PRIVATE | MAP_ANONYMOUS | MAP_FIXED_NOREPLACE,
-1,
0
);
// If we succeeded, stop
if (mem_block != MAP_FAILED) {
break;
}
// +4MB
req_addr += 4 * 1024 * 1024;
} while (req_addr < probe_region_end);
// On MacOS and other platforms
#else
// Try to map a chunk of memory as executable
mem_block = mmap(
(void *)rb_yjit_reserve_addr_space,
mem_size,
PROT_NONE,
MAP_PRIVATE | MAP_ANONYMOUS,
-1,
0
);
#endif
// Fallback
if (mem_block == MAP_FAILED) {
// Try again without the address hint (e.g., valgrind)
mem_block = mmap(
NULL,
mem_size,
PROT_NONE,
MAP_PRIVATE | MAP_ANONYMOUS,
-1,
0
);
}
// Check that the memory mapping was successful
if (mem_block == MAP_FAILED) {
perror("ruby: yjit: mmap:");
rb_bug("mmap failed");
}
return mem_block;
#else
// Windows not supported for now
return NULL;
#endif
}
// Is anyone listening for :c_call and :c_return event currently?
bool
rb_c_method_tracing_currently_enabled(rb_execution_context_t *ec)
{
rb_event_flag_t tracing_events;
if (rb_multi_ractor_p()) {
tracing_events = ruby_vm_event_enabled_global_flags;
}
else {
// At the time of writing, events are never removed from
// ruby_vm_event_enabled_global_flags so always checking using it would
// mean we don't compile even after tracing is disabled.
tracing_events = rb_ec_ractor_hooks(ec)->events;
}
return tracing_events & (RUBY_EVENT_C_CALL | RUBY_EVENT_C_RETURN);
}
// The code we generate in gen_send_cfunc() doesn't fire the c_return TracePoint event
// like the interpreter. When tracing for c_return is enabled, we patch the code after
// the C method return to call into this to fire the event.
void
rb_full_cfunc_return(rb_execution_context_t *ec, VALUE return_value)
{
rb_control_frame_t *cfp = ec->cfp;
RUBY_ASSERT_ALWAYS(cfp == GET_EC()->cfp);
const rb_callable_method_entry_t *me = rb_vm_frame_method_entry(cfp);
RUBY_ASSERT_ALWAYS(RUBYVM_CFUNC_FRAME_P(cfp));
RUBY_ASSERT_ALWAYS(me->def->type == VM_METHOD_TYPE_CFUNC);
// CHECK_CFP_CONSISTENCY("full_cfunc_return"); TODO revive this
// Pop the C func's frame and fire the c_return TracePoint event
// Note that this is the same order as vm_call_cfunc_with_frame().
rb_vm_pop_frame(ec);
EXEC_EVENT_HOOK(ec, RUBY_EVENT_C_RETURN, cfp->self, me->def->original_id, me->called_id, me->owner, return_value);
// Note, this deviates from the interpreter in that users need to enable
// a c_return TracePoint for this DTrace hook to work. A reasonable change
// since the Ruby return event works this way as well.
RUBY_DTRACE_CMETHOD_RETURN_HOOK(ec, me->owner, me->def->original_id);
// Push return value into the caller's stack. We know that it's a frame that
// uses cfp->sp because we are patching a call done with gen_send_cfunc().
ec->cfp->sp[0] = return_value;
ec->cfp->sp++;
}
unsigned int
rb_iseq_encoded_size(const rb_iseq_t *iseq)
{
return iseq->body->iseq_size;
}
// TODO(alan): consider using an opaque pointer for the payload rather than a void pointer
void *
rb_iseq_get_yjit_payload(const rb_iseq_t *iseq)
{
RUBY_ASSERT_ALWAYS(IMEMO_TYPE_P(iseq, imemo_iseq));
if (iseq->body) {
return iseq->body->yjit_payload;
}
else {
// Body is NULL when constructing the iseq.
return NULL;
}
}
void
rb_iseq_set_yjit_payload(const rb_iseq_t *iseq, void *payload)
{
RUBY_ASSERT_ALWAYS(IMEMO_TYPE_P(iseq, imemo_iseq));
RUBY_ASSERT_ALWAYS(iseq->body);
RUBY_ASSERT_ALWAYS(NULL == iseq->body->yjit_payload);
iseq->body->yjit_payload = payload;
}
void
rb_iseq_reset_jit_func(const rb_iseq_t *iseq)
{
RUBY_ASSERT_ALWAYS(IMEMO_TYPE_P(iseq, imemo_iseq));
iseq->body->jit_func = NULL;
}
// Get the PC for a given index in an iseq
VALUE *
rb_iseq_pc_at_idx(const rb_iseq_t *iseq, uint32_t insn_idx)
{
RUBY_ASSERT_ALWAYS(IMEMO_TYPE_P(iseq, imemo_iseq));
RUBY_ASSERT_ALWAYS(insn_idx < iseq->body->iseq_size);
VALUE *encoded = iseq->body->iseq_encoded;
VALUE *pc = &encoded[insn_idx];
return pc;
}
// Get the opcode given a program counter. Can return trace opcode variants.
int
rb_iseq_opcode_at_pc(const rb_iseq_t *iseq, const VALUE *pc)
{
// YJIT should only use iseqs after AST to bytecode compilation
RUBY_ASSERT_ALWAYS(FL_TEST_RAW((VALUE)iseq, ISEQ_TRANSLATED));
const VALUE at_pc = *pc;
return rb_vm_insn_addr2opcode((const void *)at_pc);
}
// used by jit_rb_str_bytesize in codegen.rs
VALUE
rb_str_bytesize(VALUE str)
{
return LONG2NUM(RSTRING_LEN(str));
}
// This is defined only as a named struct inside rb_iseq_constant_body.
// By giving it a separate typedef, we make it nameable by rust-bindgen.
// Bindgen's temp/anon name isn't guaranteed stable.
typedef struct rb_iseq_param_keyword rb_seq_param_keyword_struct;
const char *
rb_insn_name(VALUE insn)
{
return insn_name(insn);
}
// Query the instruction length in bytes for YARV opcode insn
int
rb_insn_len(VALUE insn)
{
return insn_len(insn);
}
unsigned int
rb_vm_ci_argc(const struct rb_callinfo *ci)
{
return vm_ci_argc(ci);
}
ID
rb_vm_ci_mid(const struct rb_callinfo *ci)
{
return vm_ci_mid(ci);
}
unsigned int
rb_vm_ci_flag(const struct rb_callinfo *ci)
{
return vm_ci_flag(ci);
}
const struct rb_callinfo_kwarg *
rb_vm_ci_kwarg(const struct rb_callinfo *ci)
{
return vm_ci_kwarg(ci);
}
int
rb_get_cikw_keyword_len(const struct rb_callinfo_kwarg *cikw)
{
return cikw->keyword_len;
}
VALUE
rb_get_cikw_keywords_idx(const struct rb_callinfo_kwarg *cikw, int idx)
{
return cikw->keywords[idx];
}
rb_method_visibility_t
rb_METHOD_ENTRY_VISI(rb_callable_method_entry_t *me)
{
return METHOD_ENTRY_VISI(me);
}
rb_method_type_t
rb_get_cme_def_type(rb_callable_method_entry_t *cme)
{
return cme->def->type;
}
ID
rb_get_cme_def_body_attr_id(rb_callable_method_entry_t *cme)
{
return cme->def->body.attr.id;
}
enum method_optimized_type
rb_get_cme_def_body_optimized_type(rb_callable_method_entry_t *cme)
{
return cme->def->body.optimized.type;
}
unsigned int
rb_get_cme_def_body_optimized_index(rb_callable_method_entry_t *cme)
{
return cme->def->body.optimized.index;
}
rb_method_cfunc_t *
rb_get_cme_def_body_cfunc(rb_callable_method_entry_t *cme)
{
return UNALIGNED_MEMBER_PTR(cme->def, body.cfunc);
}
uintptr_t
rb_get_def_method_serial(rb_method_definition_t *def)
{
return def->method_serial;
}
ID
rb_get_def_original_id(rb_method_definition_t *def)
{
return def->original_id;
}
int
rb_get_mct_argc(rb_method_cfunc_t *mct)
{
return mct->argc;
}
void *
rb_get_mct_func(rb_method_cfunc_t *mct)
{
return (void*)mct->func; // this field is defined as type VALUE (*func)(ANYARGS)
}
const rb_iseq_t *
rb_get_def_iseq_ptr(rb_method_definition_t *def)
{
return def_iseq_ptr(def);
}
rb_iseq_t *
rb_get_iseq_body_local_iseq(rb_iseq_t *iseq)
{
return iseq->body->local_iseq;
}
unsigned int
rb_get_iseq_body_local_table_size(rb_iseq_t *iseq)
{
return iseq->body->local_table_size;
}
VALUE *
rb_get_iseq_body_iseq_encoded(rb_iseq_t *iseq)
{
return iseq->body->iseq_encoded;
}
bool
rb_get_iseq_body_builtin_inline_p(rb_iseq_t *iseq)
{
return iseq->body->builtin_inline_p;
}
unsigned
rb_get_iseq_body_stack_max(rb_iseq_t *iseq)
{
return iseq->body->stack_max;
}
bool
rb_get_iseq_flags_has_opt(rb_iseq_t *iseq)
{
return iseq->body->param.flags.has_opt;
}
bool
rb_get_iseq_flags_has_kw(rb_iseq_t *iseq)
{
return iseq->body->param.flags.has_kw;
}
bool
rb_get_iseq_flags_has_post(rb_iseq_t *iseq)
{
return iseq->body->param.flags.has_post;
}
bool
rb_get_iseq_flags_has_kwrest(rb_iseq_t *iseq)
{
return iseq->body->param.flags.has_kwrest;
}
bool
rb_get_iseq_flags_has_rest(rb_iseq_t *iseq)
{
return iseq->body->param.flags.has_rest;
}
bool
rb_get_iseq_flags_has_block(rb_iseq_t *iseq)
{
return iseq->body->param.flags.has_block;
}
bool
rb_get_iseq_flags_has_accepts_no_kwarg(rb_iseq_t *iseq)
{
return iseq->body->param.flags.accepts_no_kwarg;
}
const rb_seq_param_keyword_struct *
rb_get_iseq_body_param_keyword(rb_iseq_t *iseq)
{
return iseq->body->param.keyword;
}
unsigned
rb_get_iseq_body_param_size(rb_iseq_t *iseq)
{
return iseq->body->param.size;
}
int
rb_get_iseq_body_param_lead_num(rb_iseq_t *iseq)
{
return iseq->body->param.lead_num;
}
int
rb_get_iseq_body_param_opt_num(rb_iseq_t *iseq)
{
return iseq->body->param.opt_num;
}
const VALUE *
rb_get_iseq_body_param_opt_table(rb_iseq_t *iseq)
{
return iseq->body->param.opt_table;
}
// If true, the iseq is leaf and it can be replaced by a single C call.
bool
rb_leaf_invokebuiltin_iseq_p(const rb_iseq_t *iseq)
{
unsigned int invokebuiltin_len = insn_len(BIN(opt_invokebuiltin_delegate_leave));
unsigned int leave_len = insn_len(BIN(leave));
return (iseq->body->iseq_size == (invokebuiltin_len + leave_len) &&
rb_vm_insn_addr2opcode((void *)iseq->body->iseq_encoded[0]) == BIN(opt_invokebuiltin_delegate_leave) &&
rb_vm_insn_addr2opcode((void *)iseq->body->iseq_encoded[invokebuiltin_len]) == BIN(leave) &&
iseq->body->builtin_inline_p
);
}
// Return an rb_builtin_function if the iseq contains only that leaf builtin function.
const struct rb_builtin_function *
rb_leaf_builtin_function(const rb_iseq_t *iseq)
{
if (!rb_leaf_invokebuiltin_iseq_p(iseq))
return NULL;
return (const struct rb_builtin_function *)iseq->body->iseq_encoded[1];
}
VALUE
rb_yjit_str_simple_append(VALUE str1, VALUE str2)
{
return rb_str_cat(str1, RSTRING_PTR(str2), RSTRING_LEN(str2));
}
struct rb_control_frame_struct *
rb_get_ec_cfp(rb_execution_context_t *ec)
{
return ec->cfp;
}
VALUE *
rb_get_cfp_pc(struct rb_control_frame_struct *cfp)
{
return (VALUE*)cfp->pc;
}
VALUE *
rb_get_cfp_sp(struct rb_control_frame_struct *cfp)
{
return cfp->sp;
}
void
rb_set_cfp_pc(struct rb_control_frame_struct *cfp, const VALUE *pc)
{
cfp->pc = pc;
}
void
rb_set_cfp_sp(struct rb_control_frame_struct *cfp, VALUE *sp)
{
cfp->sp = sp;
}
rb_iseq_t *
rb_cfp_get_iseq(struct rb_control_frame_struct *cfp)
{
// TODO(alan) could assert frame type here to make sure that it's a ruby frame with an iseq.
return (rb_iseq_t*)cfp->iseq;
}
VALUE
rb_get_cfp_self(struct rb_control_frame_struct *cfp)
{
return cfp->self;
}
VALUE *
rb_get_cfp_ep(struct rb_control_frame_struct *cfp)
{
return (VALUE*)cfp->ep;
}
VALUE
rb_yarv_class_of(VALUE obj)
{
return rb_class_of(obj);
}
// YJIT needs this function to never allocate and never raise
VALUE
rb_yarv_str_eql_internal(VALUE str1, VALUE str2)
{
// We wrap this since it's static inline
return rb_str_eql_internal(str1, str2);
}
// YJIT needs this function to never allocate and never raise
VALUE
rb_yarv_ary_entry_internal(VALUE ary, long offset)
{
return rb_ary_entry_internal(ary, offset);
}
// Print the Ruby source location of some ISEQ for debugging purposes
void
rb_yjit_dump_iseq_loc(const rb_iseq_t *iseq, uint32_t insn_idx)
{
char *ptr;
long len;
VALUE path = rb_iseq_path(iseq);
RSTRING_GETMEM(path, ptr, len);
fprintf(stderr, "%s %.*s:%u\n", __func__, (int)len, ptr, rb_iseq_line_no(iseq, insn_idx));
}
// The FL_TEST() macro
VALUE
rb_FL_TEST(VALUE obj, VALUE flags)
{
return RB_FL_TEST(obj, flags);
}
// The FL_TEST_RAW() macro, normally an internal implementation detail
VALUE
rb_FL_TEST_RAW(VALUE obj, VALUE flags)
{
return FL_TEST_RAW(obj, flags);
}
// The RB_TYPE_P macro
bool
rb_RB_TYPE_P(VALUE obj, enum ruby_value_type t)
{
return RB_TYPE_P(obj, t);
}
long
rb_RSTRUCT_LEN(VALUE st)
{
return RSTRUCT_LEN(st);
}
// There are RSTRUCT_SETs in ruby/internal/core/rstruct.h and internal/struct.h
// with different types (int vs long) for k. Here we use the one from ruby/internal/core/rstruct.h,
// which takes an int.
void
rb_RSTRUCT_SET(VALUE st, int k, VALUE v)
{
RSTRUCT_SET(st, k, v);
}
const struct rb_callinfo *
rb_get_call_data_ci(struct rb_call_data *cd)
{
return cd->ci;
}
bool
rb_BASIC_OP_UNREDEFINED_P(enum ruby_basic_operators bop, uint32_t klass)
{
return BASIC_OP_UNREDEFINED_P(bop, klass);
}
VALUE
rb_RCLASS_ORIGIN(VALUE c)
{
return RCLASS_ORIGIN(c);
}
// Return the string encoding index
int
rb_ENCODING_GET(VALUE obj)
{
return RB_ENCODING_GET(obj);
}
bool
rb_yjit_multi_ractor_p(void)
{
return rb_multi_ractor_p();
}
// For debug builds
void
rb_assert_iseq_handle(VALUE handle)
{
RUBY_ASSERT_ALWAYS(rb_objspace_markable_object_p(handle));
RUBY_ASSERT_ALWAYS(IMEMO_TYPE_P(handle, imemo_iseq));
}
int
rb_IMEMO_TYPE_P(VALUE imemo, enum imemo_type imemo_type)
{
return IMEMO_TYPE_P(imemo, imemo_type);
}
void
rb_assert_cme_handle(VALUE handle)
{
RUBY_ASSERT_ALWAYS(rb_objspace_markable_object_p(handle));
RUBY_ASSERT_ALWAYS(IMEMO_TYPE_P(handle, imemo_ment));
}
typedef void (*iseq_callback)(const rb_iseq_t *);
// Heap-walking callback for rb_yjit_for_each_iseq().
static int
for_each_iseq_i(void *vstart, void *vend, size_t stride, void *data)
{
const iseq_callback callback = (iseq_callback)data;
VALUE v = (VALUE)vstart;
for (; v != (VALUE)vend; v += stride) {
void *ptr = asan_poisoned_object_p(v);
asan_unpoison_object(v, false);
if (rb_obj_is_iseq(v)) {
rb_iseq_t *iseq = (rb_iseq_t *)v;
callback(iseq);
}
asan_poison_object_if(ptr, v);
}
return 0;
}
// Iterate through the whole GC heap and invoke a callback for each iseq.
// Used for global code invalidation.
void
rb_yjit_for_each_iseq(iseq_callback callback)
{
rb_objspace_each_objects(for_each_iseq_i, (void *)callback);
}
// For running write barriers from Rust. Required when we add a new edge in the
// object graph from `old` to `young`.
void
rb_yjit_obj_written(VALUE old, VALUE young, const char *file, int line)
{
rb_obj_written(old, Qundef, young, file, line);
}
// Acquire the VM lock and then signal all other Ruby threads (ractors) to
// contend for the VM lock, putting them to sleep. YJIT uses this to evict
// threads running inside generated code so among other things, it can
// safely change memory protection of regions housing generated code.
void
rb_yjit_vm_lock_then_barrier(unsigned int *recursive_lock_level, const char *file, int line)
{
rb_vm_lock_enter(recursive_lock_level, file, line);
rb_vm_barrier();
}
// Release the VM lock. The lock level must point to the same integer used to
// acquire the lock.
void
rb_yjit_vm_unlock(unsigned int *recursive_lock_level, const char *file, int line)
{
rb_vm_lock_leave(recursive_lock_level, file, line);
}
// Pointer to a YJIT entry point (machine code generated by YJIT)
typedef VALUE (*yjit_func_t)(rb_execution_context_t *, rb_control_frame_t *);
bool
rb_yjit_compile_iseq(const rb_iseq_t *iseq, rb_execution_context_t *ec)
{
bool success = true;
RB_VM_LOCK_ENTER();
rb_vm_barrier();
// Compile a block version starting at the first instruction
uint8_t *rb_yjit_iseq_gen_entry_point(const rb_iseq_t *iseq, rb_execution_context_t *ec); // defined in Rust
uint8_t *code_ptr = rb_yjit_iseq_gen_entry_point(iseq, ec);
if (code_ptr) {
iseq->body->jit_func = (yjit_func_t)code_ptr;
}
else {
iseq->body->jit_func = 0;
success = false;
}
RB_VM_LOCK_LEAVE();
return success;
}
// GC root for interacting with the GC
struct yjit_root_struct {
bool unused; // empty structs are not legal in C99
};
static void
yjit_root_free(void *ptr)
{
// Do nothing. The root lives as long as the process.
}
static size_t
yjit_root_memsize(const void *ptr)
{
// Count off-gc-heap allocation size of the dependency table
return 0; // TODO: more accurate accounting
}
// GC callback during compaction
static void
yjit_root_update_references(void *ptr)
{
// Do nothing since we use rb_gc_mark(), which pins.
}
void rb_yjit_root_mark(void *ptr); // in Rust
// Custom type for interacting with the GC
// TODO: make this write barrier protected
static const rb_data_type_t yjit_root_type = {
"yjit_root",
{rb_yjit_root_mark, yjit_root_free, yjit_root_memsize, yjit_root_update_references},
0, 0, RUBY_TYPED_FREE_IMMEDIATELY
};
// For dealing with refinements
void
rb_yjit_invalidate_all_method_lookup_assumptions(void)
{
// It looks like Module#using actually doesn't need to invalidate all the
// method caches, so we do nothing here for now.
}
// Primitives used by yjit.rb
VALUE rb_yjit_stats_enabled_p(rb_execution_context_t *ec, VALUE self);
VALUE rb_yjit_trace_exit_locations_enabled_p(rb_execution_context_t *ec, VALUE self);
VALUE rb_yjit_get_stats(rb_execution_context_t *ec, VALUE self);
VALUE rb_yjit_reset_stats_bang(rb_execution_context_t *ec, VALUE self);
VALUE rb_yjit_disasm_iseq(rb_execution_context_t *ec, VALUE self, VALUE iseq);
VALUE rb_yjit_insns_compiled(rb_execution_context_t *ec, VALUE self, VALUE iseq);
VALUE rb_yjit_simulate_oom_bang(rb_execution_context_t *ec, VALUE self);
VALUE rb_yjit_get_exit_locations(rb_execution_context_t *ec, VALUE self);
// Preprocessed yjit.rb generated during build
#include "yjit.rbinc"
// Can raise RuntimeError
void
rb_yjit_init(void)
{
// Call the Rust initialization code
void rb_yjit_init_rust(void);
rb_yjit_init_rust();
// Initialize the GC hooks. Do this second as some code depend on Rust initialization.
struct yjit_root_struct *root;
VALUE yjit_root = TypedData_Make_Struct(0, struct yjit_root_struct, &yjit_root_type, root);
rb_gc_register_mark_object(yjit_root);
}