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ruby--ruby/mjit_worker.c
k0kubun fe6974a8fc mjit_worker.c: support MJIT in forked Ruby process
by launching MJIT worker thread in child Ruby process.

See the comment before `mjit_child_after_fork` for details.

git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@65785 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2018-11-18 08:25:48 +00:00

1238 lines
41 KiB
C

/**********************************************************************
mjit_worker.c - Worker for MRI method JIT compiler
Copyright (C) 2017 Vladimir Makarov <vmakarov@redhat.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. */
/* We utilize widely used C compilers (GCC and LLVM Clang) to
implement MJIT. We feed them a C code generated from ISEQ. The
industrial C compilers are slower than regular JIT engines.
Generated code performance of the used C compilers has a higher
priority over the compilation speed.
So our major goal is to minimize the ISEQ compilation time when we
use widely optimization level (-O2). It is achieved by
o Using a precompiled version of the header
o Keeping all files in `/tmp`. On modern Linux `/tmp` is a file
system in memory. So it is pretty fast
o Implementing MJIT as a multi-threaded code because we want to
compile ISEQs in parallel with iseq execution to speed up Ruby
code execution. MJIT has one thread (*worker*) to do
parallel compilations:
o It prepares a precompiled code of the minimized header.
It starts at the MRI execution start
o It generates PIC object files of ISEQs
o It takes one JIT unit from a priority queue unless it is empty.
o It translates the JIT unit ISEQ into C-code using the precompiled
header, calls CC and load PIC code when it is ready
o Currently MJIT put ISEQ in the queue when ISEQ is called
o MJIT can reorder ISEQs in the queue if some ISEQ has been called
many times and its compilation did not start yet
o MRI reuses the machine code if it already exists for ISEQ
o The machine code we generate can stop and switch to the ISEQ
interpretation if some condition is not satisfied as the machine
code can be speculative or some exception raises
o Speculative machine code can be canceled.
Here is a diagram showing the MJIT organization:
_______
|header |
|_______|
| MRI building
--------------|----------------------------------------
| MRI execution
|
_____________|_____
| | |
| ___V__ | CC ____________________
| | |----------->| precompiled header |
| | | | |____________________|
| | | | |
| | MJIT | | |
| | | | |
| | | | ____V___ CC __________
| |______|----------->| C code |--->| .so file |
| | |________| |__________|
| | |
| | |
| MRI machine code |<-----------------------------
|___________________| loading
*/
#ifdef __sun
#define __EXTENSIONS__ 1
#endif
#include "vm_core.h"
#include "mjit.h"
#include "gc.h"
#include "ruby_assert.h"
#include "ruby/debug.h"
#include "ruby/thread.h"
#ifdef _WIN32
#include <winsock2.h>
#include <windows.h>
#else
#include <sys/wait.h>
#include <sys/time.h>
#include <dlfcn.h>
#endif
#include <errno.h>
#ifdef HAVE_FCNTL_H
#include <fcntl.h>
#endif
#ifdef HAVE_SYS_PARAM_H
# include <sys/param.h>
#endif
#include "dln.h"
#include "ruby/util.h"
#undef strdup /* ruby_strdup may trigger GC */
#ifndef MAXPATHLEN
# define MAXPATHLEN 1024
#endif
#ifdef _WIN32
#define dlopen(name,flag) ((void*)LoadLibrary(name))
#define dlerror() strerror(rb_w32_map_errno(GetLastError()))
#define dlsym(handle,name) ((void*)GetProcAddress((handle),(name)))
#define dlclose(handle) (!FreeLibrary(handle))
#define RTLD_NOW -1
#define waitpid(pid,stat_loc,options) (WaitForSingleObject((HANDLE)(pid), INFINITE), GetExitCodeProcess((HANDLE)(pid), (LPDWORD)(stat_loc)), CloseHandle((HANDLE)pid), (pid))
#define WIFEXITED(S) ((S) != STILL_ACTIVE)
#define WEXITSTATUS(S) (S)
#define WIFSIGNALED(S) (0)
typedef intptr_t pid_t;
#endif
/* Atomically set function pointer if possible. */
#define MJIT_ATOMIC_SET(var, val) (void)ATOMIC_PTR_EXCHANGE(var, val)
#define MJIT_TMP_PREFIX "_ruby_mjit_"
/* The unit structure that holds metadata of ISeq for MJIT. */
struct rb_mjit_unit {
/* Unique order number of unit. */
int id;
/* Dlopen handle of the loaded object file. */
void *handle;
const rb_iseq_t *iseq;
#ifndef _MSC_VER
/* This value is always set for `compact_all_jit_code`. Also used for lazy deletion. */
char *o_file;
/* TRUE if it's inherited from parent Ruby process and lazy deletion should be skipped.
`o_file = NULL` can't be used to skip lazy deletion because `o_file` could be used
by child for `compact_all_jit_code`. */
int o_file_inherited_p;
#endif
#if defined(_WIN32)
/* DLL cannot be removed while loaded on Windows. If this is set, it'll be lazily deleted. */
char *so_file;
#endif
/* Only used by unload_units. Flag to check this unit is currently on stack or not. */
char used_code_p;
struct list_node unode;
};
/* Linked list of struct rb_mjit_unit. */
struct rb_mjit_unit_list {
struct list_head head;
int length; /* the list length */
};
extern void rb_native_mutex_lock(rb_nativethread_lock_t *lock);
extern void rb_native_mutex_unlock(rb_nativethread_lock_t *lock);
extern void rb_native_mutex_initialize(rb_nativethread_lock_t *lock);
extern void rb_native_mutex_destroy(rb_nativethread_lock_t *lock);
extern void rb_native_cond_initialize(rb_nativethread_cond_t *cond);
extern void rb_native_cond_destroy(rb_nativethread_cond_t *cond);
extern void rb_native_cond_signal(rb_nativethread_cond_t *cond);
extern void rb_native_cond_broadcast(rb_nativethread_cond_t *cond);
extern void rb_native_cond_wait(rb_nativethread_cond_t *cond, rb_nativethread_lock_t *mutex);
/* process.c */
extern rb_pid_t ruby_waitpid_locked(rb_vm_t *, rb_pid_t, int *status, int options, rb_nativethread_cond_t *cond);
/* A copy of MJIT portion of MRI options since MJIT initialization. We
need them as MJIT threads still can work when the most MRI data were
freed. */
struct mjit_options mjit_opts;
/* TRUE if MJIT is enabled. */
int mjit_enabled = FALSE;
/* TRUE if JIT-ed code should be called. When `ruby_vm_event_enabled_flags & ISEQ_TRACE_EVENTS`
and `mjit_call_p == FALSE`, any JIT-ed code execution is cancelled as soon as possible. */
int mjit_call_p = FALSE;
/* Priority queue of iseqs waiting for JIT compilation.
This variable is a pointer to head unit of the queue. */
static struct rb_mjit_unit_list unit_queue = { LIST_HEAD_INIT(unit_queue.head) };
/* List of units which are successfully compiled. */
static struct rb_mjit_unit_list active_units = { LIST_HEAD_INIT(active_units.head) };
/* List of compacted so files which will be cleaned up by `free_list()` in `mjit_finish()`. */
static struct rb_mjit_unit_list compact_units = { LIST_HEAD_INIT(compact_units.head) };
/* The number of so far processed ISEQs, used to generate unique id. */
static int current_unit_num;
/* A mutex for conitionals and critical sections. */
static rb_nativethread_lock_t mjit_engine_mutex;
/* A thread conditional to wake up `mjit_finish` at the end of PCH thread. */
static rb_nativethread_cond_t mjit_pch_wakeup;
/* A thread conditional to wake up the client if there is a change in
executed unit status. */
static rb_nativethread_cond_t mjit_client_wakeup;
/* A thread conditional to wake up a worker if there we have something
to add or we need to stop MJIT engine. */
static rb_nativethread_cond_t mjit_worker_wakeup;
/* A thread conditional to wake up workers if at the end of GC. */
static rb_nativethread_cond_t mjit_gc_wakeup;
/* True when GC is working. */
static int in_gc;
/* True when JIT is working. */
static int in_jit;
/* Set to TRUE to stop worker. */
static int stop_worker_p;
/* Set to TRUE if worker is stopped. */
static int worker_stopped;
/* Path of "/tmp", which can be changed to $TMP in MinGW. */
static char *tmp_dir;
/* Hash like { 1 => true, 2 => true, ... } whose keys are valid `class_serial`s.
This is used to invalidate obsoleted CALL_CACHE. */
static VALUE valid_class_serials;
/* Used C compiler path. */
static const char *cc_path;
/* Name of the precompiled header file. */
static char *pch_file;
/* The process id which should delete the pch_file on mjit_finish. */
static rb_pid_t pch_owner_pid;
/* Status of the precompiled header creation. The status is
shared by the workers and the pch thread. */
static enum {PCH_NOT_READY, PCH_FAILED, PCH_SUCCESS} pch_status;
#ifndef _MSC_VER
/* Name of the header file. */
static char *header_file;
#endif
#ifdef _WIN32
/* Linker option to enable libruby. */
static char *libruby_pathflag;
#endif
#include "mjit_config.h"
#if defined(__GNUC__) && \
(!defined(__clang__) || \
(defined(__clang__) && (defined(__FreeBSD__) || defined(__GLIBC__))))
#define GCC_PIC_FLAGS "-Wfatal-errors", "-fPIC", "-shared", "-w", \
"-pipe",
#else
#define GCC_PIC_FLAGS /* empty */
#endif
static const char *const CC_COMMON_ARGS[] = {
MJIT_CC_COMMON MJIT_CFLAGS GCC_PIC_FLAGS
NULL
};
/* GCC and CLANG executable paths. TODO: The paths should absolute
ones to prevent changing C compiler for security reasons. */
#define CC_PATH CC_COMMON_ARGS[0]
static const char *const CC_DEBUG_ARGS[] = {MJIT_DEBUGFLAGS NULL};
static const char *const CC_OPTIMIZE_ARGS[] = {MJIT_OPTFLAGS NULL};
static const char *const CC_LDSHARED_ARGS[] = {MJIT_LDSHARED GCC_PIC_FLAGS NULL};
static const char *const CC_DLDFLAGS_ARGS[] = {
MJIT_DLDFLAGS
#if defined __GNUC__ && !defined __clang__
"-nostartfiles",
# if !defined(_WIN32) && !defined(__CYGWIN__)
"-nodefaultlibs", "-nostdlib",
# endif
#endif
NULL
};
static const char *const CC_LIBS[] = {
#if defined(_WIN32) || defined(__CYGWIN__)
MJIT_LIBS
# if defined __GNUC__ && !defined __clang__
# if defined(_WIN32)
"-lmsvcrt",
# endif
"-lgcc",
# endif
#endif
NULL
};
#define CC_CODEFLAG_ARGS (mjit_opts.debug ? CC_DEBUG_ARGS : CC_OPTIMIZE_ARGS)
/* Print the arguments according to FORMAT to stderr only if MJIT
verbose option value is more or equal to LEVEL. */
PRINTF_ARGS(static void, 2, 3)
verbose(int level, const char *format, ...)
{
if (mjit_opts.verbose >= level) {
va_list args;
size_t len = strlen(format);
char *full_format = alloca(sizeof(char) * (len + 2));
/* Creating `format + '\n'` to atomically print format and '\n'. */
memcpy(full_format, format, len);
full_format[len] = '\n';
full_format[len+1] = '\0';
va_start(args, format);
vfprintf(stderr, full_format, args);
va_end(args);
}
}
PRINTF_ARGS(static void, 1, 2)
mjit_warning(const char *format, ...)
{
if (mjit_opts.warnings || mjit_opts.verbose) {
va_list args;
fprintf(stderr, "MJIT warning: ");
va_start(args, format);
vfprintf(stderr, format, args);
va_end(args);
fprintf(stderr, "\n");
}
}
/* Add unit node to the tail of doubly linked LIST. It should be not in
the list before. */
static void
add_to_list(struct rb_mjit_unit *unit, struct rb_mjit_unit_list *list)
{
list_add_tail(&list->head, &unit->unode);
list->length++;
}
static void
remove_from_list(struct rb_mjit_unit *unit, struct rb_mjit_unit_list *list)
{
list_del(&unit->unode);
list->length--;
}
static void
remove_file(const char *filename)
{
if (remove(filename)) {
mjit_warning("failed to remove \"%s\": %s", filename, strerror(errno));
}
}
/* Lazily delete .o and/or .so files. */
static void
clean_object_files(struct rb_mjit_unit *unit)
{
#ifndef _MSC_VER
if (unit->o_file) {
char *o_file = unit->o_file;
unit->o_file = NULL;
/* For compaction, unit->o_file is always set when compilation succeeds.
So save_temps needs to be checked here. */
if (!mjit_opts.save_temps && !unit->o_file_inherited_p)
remove_file(o_file);
free(o_file);
}
#endif
#if defined(_WIN32)
if (unit->so_file) {
char *so_file = unit->so_file;
unit->so_file = NULL;
/* unit->so_file is set only when mjit_opts.save_temps is FALSE. */
remove_file(so_file);
free(so_file);
}
#endif
}
/* This is called in the following situations:
1) On dequeue or `unload_units()`, associated ISeq is already GCed.
2) The unit is not called often and unloaded by `unload_units()`.
3) Freeing lists on `mjit_finish()`.
`jit_func` value does not matter for 1 and 3 since the unit won't be used anymore.
For the situation 2, this sets the ISeq's JIT state to NOT_COMPILED_JIT_ISEQ_FUNC
to prevent the situation that the same methods are continously compiled. */
static void
free_unit(struct rb_mjit_unit *unit)
{
if (unit->iseq) { /* ISeq is not GCed */
unit->iseq->body->jit_func = (mjit_func_t)NOT_COMPILED_JIT_ISEQ_FUNC;
unit->iseq->body->jit_unit = NULL;
}
if (unit->handle && dlclose(unit->handle)) { /* handle is NULL if it's in queue */
mjit_warning("failed to close handle for u%d: %s", unit->id, dlerror());
}
clean_object_files(unit);
free(unit);
}
/* Start a critical section. Use message MSG to print debug info at
LEVEL. */
static inline void
CRITICAL_SECTION_START(int level, const char *msg)
{
verbose(level, "Locking %s", msg);
rb_native_mutex_lock(&mjit_engine_mutex);
verbose(level, "Locked %s", msg);
}
/* Finish the current critical section. Use message MSG to print
debug info at LEVEL. */
static inline void
CRITICAL_SECTION_FINISH(int level, const char *msg)
{
verbose(level, "Unlocked %s", msg);
rb_native_mutex_unlock(&mjit_engine_mutex);
}
static int
sprint_uniq_filename(char *str, size_t size, unsigned long id, const char *prefix, const char *suffix)
{
return snprintf(str, size, "%s/%sp%"PRI_PIDT_PREFIX"uu%lu%s", tmp_dir, prefix, getpid(), id, suffix);
}
/* Return time in milliseconds as a double. */
#ifdef __APPLE__
double ruby_real_ms_time(void);
# define real_ms_time() ruby_real_ms_time()
#else
static double
real_ms_time(void)
{
# ifdef HAVE_CLOCK_GETTIME
struct timespec tv;
# ifdef CLOCK_MONOTONIC
const clockid_t c = CLOCK_MONOTONIC;
# else
const clockid_t c = CLOCK_REALTIME;
# endif
clock_gettime(c, &tv);
return tv.tv_nsec / 1000000.0 + tv.tv_sec * 1000.0;
# else
struct timeval tv;
gettimeofday(&tv, NULL);
return tv.tv_usec / 1000.0 + tv.tv_sec * 1000.0;
# endif
}
#endif
/* Return TRUE if class_serial is not obsoleted. This is used by mjit_compile.c. */
int
mjit_valid_class_serial_p(rb_serial_t class_serial)
{
int found_p;
CRITICAL_SECTION_START(3, "in valid_class_serial_p");
found_p = rb_hash_stlike_lookup(valid_class_serials, LONG2FIX(class_serial), NULL);
CRITICAL_SECTION_FINISH(3, "in valid_class_serial_p");
return found_p;
}
/* Return the best unit from list. The best is the first
high priority unit or the unit whose iseq has the biggest number
of calls so far. */
static struct rb_mjit_unit *
get_from_list(struct rb_mjit_unit_list *list)
{
struct rb_mjit_unit *unit = NULL, *next, *best = NULL;
/* Find iseq with max total_calls */
list_for_each_safe(&list->head, unit, next, unode) {
if (unit->iseq == NULL) { /* ISeq is GCed. */
remove_from_list(unit, list);
free_unit(unit);
continue;
}
if (best == NULL || best->iseq->body->total_calls < unit->iseq->body->total_calls) {
best = unit;
}
}
if (best) {
remove_from_list(best, list);
}
return best;
}
/* Return length of NULL-terminated array ARGS excluding the NULL
marker. */
static size_t
args_len(char *const *args)
{
size_t i;
for (i = 0; (args[i]) != NULL;i++)
;
return i;
}
/* Concatenate NUM passed NULL-terminated arrays of strings, put the
result (with NULL end marker) into the heap, and return the
result. */
static char **
form_args(int num, ...)
{
va_list argp;
size_t len, n;
int i;
char **args, **res, **tmp;
va_start(argp, num);
res = NULL;
for (i = len = 0; i < num; i++) {
args = va_arg(argp, char **);
n = args_len(args);
if ((tmp = (char **)realloc(res, sizeof(char *) * (len + n + 1))) == NULL) {
free(res);
return NULL;
}
res = tmp;
MEMCPY(res + len, args, char *, n + 1);
len += n;
}
va_end(argp);
return res;
}
COMPILER_WARNING_PUSH
#ifdef __GNUC__
COMPILER_WARNING_IGNORED(-Wdeprecated-declarations)
#endif
/* Start an OS process of absolute executable path with arguments ARGV.
Return PID of the process. */
static pid_t
start_process(const char *abspath, char *const *argv)
{
pid_t pid;
/*
* Not calling non-async-signal-safe functions between vfork
* and execv for safety
*/
int dev_null = rb_cloexec_open(ruby_null_device, O_WRONLY, 0);
if (mjit_opts.verbose >= 2) {
int i;
const char *arg;
fprintf(stderr, "Starting process: %s", abspath);
for (i = 0; (arg = argv[i]) != NULL; i++)
fprintf(stderr, " %s", arg);
fprintf(stderr, "\n");
}
#ifdef _WIN32
{
extern HANDLE rb_w32_start_process(const char *abspath, char *const *argv, int out_fd);
int out_fd = 0;
if (mjit_opts.verbose <= 1) {
/* Discard cl.exe's outputs like:
_ruby_mjit_p12u3.c
Creating library C:.../_ruby_mjit_p12u3.lib and object C:.../_ruby_mjit_p12u3.exp */
out_fd = dev_null;
}
pid = (pid_t)rb_w32_start_process(abspath, argv, out_fd);
if (pid == 0) {
verbose(1, "MJIT: Failed to create process: %s", dlerror());
return -1;
}
}
#else
if ((pid = vfork()) == 0) { /* TODO: reuse some function in process.c */
umask(0077);
if (mjit_opts.verbose == 0) {
/* CC can be started in a thread using a file which has been
already removed while MJIT is finishing. Discard the
messages about missing files. */
dup2(dev_null, STDERR_FILENO);
dup2(dev_null, STDOUT_FILENO);
}
(void)close(dev_null);
pid = execv(abspath, argv); /* Pid will be negative on an error */
/* Even if we successfully found CC to compile PCH we still can
fail with loading the CC in very rare cases for some reasons.
Stop the forked process in this case. */
verbose(1, "MJIT: Error in execv: %s", abspath);
_exit(1);
}
#endif
(void)close(dev_null);
return pid;
}
COMPILER_WARNING_POP
/* Execute an OS process of executable PATH with arguments ARGV.
Return -1 or -2 if failed to execute, otherwise exit code of the process.
TODO: Use a similar function in process.c */
static int
exec_process(const char *path, char *const argv[])
{
int stat, exit_code = -2;
pid_t pid;
rb_vm_t *vm = WAITPID_USE_SIGCHLD ? GET_VM() : 0;
rb_nativethread_cond_t cond;
if (vm) {
rb_native_cond_initialize(&cond);
rb_native_mutex_lock(&vm->waitpid_lock);
}
pid = start_process(path, argv);
for (;pid > 0;) {
pid_t r = vm ? ruby_waitpid_locked(vm, pid, &stat, 0, &cond)
: waitpid(pid, &stat, 0);
if (r == -1) {
if (errno == EINTR) continue;
fprintf(stderr, "[%"PRI_PIDT_PREFIX"d] waitpid(%lu): %s (SIGCHLD=%d,%u)\n",
getpid(), (unsigned long)pid, strerror(errno),
RUBY_SIGCHLD, SIGCHLD_LOSSY);
break;
}
else if (r == pid) {
if (WIFEXITED(stat)) {
exit_code = WEXITSTATUS(stat);
break;
} else if (WIFSIGNALED(stat)) {
exit_code = -1;
break;
}
}
}
if (vm) {
rb_native_mutex_unlock(&vm->waitpid_lock);
rb_native_cond_destroy(&cond);
}
return exit_code;
}
static void
remove_so_file(const char *so_file, struct rb_mjit_unit *unit)
{
#if defined(_WIN32)
/* Windows can't remove files while it's used. */
unit->so_file = strdup(so_file); /* lazily delete on `clean_object_files()` */
if (unit->so_file == NULL)
mjit_warning("failed to allocate memory to lazily remove '%s': %s", so_file, strerror(errno));
#else
remove_file(so_file);
#endif
}
#define append_str2(p, str, len) ((char *)memcpy((p), str, (len))+(len))
#define append_str(p, str) append_str2(p, str, sizeof(str)-1)
#define append_lit(p, str) append_str2(p, str, rb_strlen_lit(str))
#ifdef _MSC_VER
/* Compile C file to so. It returns 1 if it succeeds. (mswin) */
static int
compile_c_to_so(const char *c_file, const char *so_file)
{
int exit_code;
const char *files[] = { NULL, NULL, NULL, NULL, NULL, NULL, "-link", libruby_pathflag, NULL };
char **args;
char *p, *obj_file;
/* files[0] = "-Fe*.dll" */
files[0] = p = alloca(sizeof(char) * (rb_strlen_lit("-Fe") + strlen(so_file) + 1));
p = append_lit(p, "-Fe");
p = append_str2(p, so_file, strlen(so_file));
*p = '\0';
/* files[1] = "-Fo*.obj" */
/* We don't need .obj file, but it's somehow created to cwd without -Fo and we want to control the output directory. */
files[1] = p = alloca(sizeof(char) * (rb_strlen_lit("-Fo") + strlen(so_file) - rb_strlen_lit(DLEXT) + rb_strlen_lit(".obj") + 1));
obj_file = p = append_lit(p, "-Fo");
p = append_str2(p, so_file, strlen(so_file) - rb_strlen_lit(DLEXT));
p = append_lit(p, ".obj");
*p = '\0';
/* files[2] = "-Yu*.pch" */
files[2] = p = alloca(sizeof(char) * (rb_strlen_lit("-Yu") + strlen(pch_file) + 1));
p = append_lit(p, "-Yu");
p = append_str2(p, pch_file, strlen(pch_file));
*p = '\0';
/* files[3] = "C:/.../rb_mjit_header-*.obj" */
files[3] = p = alloca(sizeof(char) * (strlen(pch_file) + 1));
p = append_str2(p, pch_file, strlen(pch_file) - strlen(".pch"));
p = append_lit(p, ".obj");
*p = '\0';
/* files[4] = "-Tc*.c" */
files[4] = p = alloca(sizeof(char) * (rb_strlen_lit("-Tc") + strlen(c_file) + 1));
p = append_lit(p, "-Tc");
p = append_str2(p, c_file, strlen(c_file));
*p = '\0';
/* files[5] = "-Fd*.pdb" */
files[5] = p = alloca(sizeof(char) * (rb_strlen_lit("-Fd") + strlen(pch_file) + 1));
p = append_lit(p, "-Fd");
p = append_str2(p, pch_file, strlen(pch_file) - rb_strlen_lit(".pch"));
p = append_lit(p, ".pdb");
*p = '\0';
args = form_args(5, CC_LDSHARED_ARGS, CC_CODEFLAG_ARGS,
files, CC_LIBS, CC_DLDFLAGS_ARGS);
if (args == NULL)
return FALSE;
exit_code = exec_process(cc_path, args);
free(args);
if (exit_code == 0) {
/* remove never-used files (.obj, .lib, .exp, .pdb). XXX: Is there any way not to generate this? */
if (!mjit_opts.save_temps) {
char *before_dot;
remove_file(obj_file);
before_dot = obj_file + strlen(obj_file) - rb_strlen_lit(".obj");
append_lit(before_dot, ".lib"); remove_file(obj_file);
append_lit(before_dot, ".exp"); remove_file(obj_file);
append_lit(before_dot, ".pdb"); remove_file(obj_file);
}
}
else {
verbose(2, "compile_c_to_so: compile error: %d", exit_code);
}
return exit_code == 0;
}
#else /* _MSC_VER */
/* The function producing the pre-compiled header. */
static void
make_pch(void)
{
int exit_code;
const char *rest_args[] = {
# ifdef __clang__
"-emit-pch",
# endif
"-o", NULL, NULL,
NULL,
};
char **args;
int len = sizeof(rest_args) / sizeof(const char *);
rest_args[len - 2] = header_file;
rest_args[len - 3] = pch_file;
verbose(2, "Creating precompiled header");
args = form_args(3, CC_COMMON_ARGS, CC_CODEFLAG_ARGS, rest_args);
if (args == NULL) {
mjit_warning("making precompiled header failed on forming args");
CRITICAL_SECTION_START(3, "in make_pch");
pch_status = PCH_FAILED;
CRITICAL_SECTION_FINISH(3, "in make_pch");
return;
}
exit_code = exec_process(cc_path, args);
free(args);
CRITICAL_SECTION_START(3, "in make_pch");
if (exit_code == 0) {
pch_status = PCH_SUCCESS;
}
else {
mjit_warning("Making precompiled header failed on compilation. Stopping MJIT worker...");
pch_status = PCH_FAILED;
}
/* wakeup `mjit_finish` */
rb_native_cond_broadcast(&mjit_pch_wakeup);
CRITICAL_SECTION_FINISH(3, "in make_pch");
}
/* Compile .c file to .o file. It returns 1 if it succeeds. (non-mswin) */
static int
compile_c_to_o(const char *c_file, const char *o_file)
{
int exit_code;
const char *files[] = {
"-o", NULL, NULL,
# ifdef __clang__
"-include-pch", NULL,
# endif
"-c", NULL
};
char **args;
files[1] = o_file;
files[2] = c_file;
# ifdef __clang__
files[4] = pch_file;
# endif
args = form_args(5, CC_COMMON_ARGS, CC_CODEFLAG_ARGS, files, CC_LIBS, CC_DLDFLAGS_ARGS);
if (args == NULL)
return FALSE;
exit_code = exec_process(cc_path, args);
free(args);
if (exit_code != 0)
verbose(2, "compile_c_to_o: compile error: %d", exit_code);
return exit_code == 0;
}
/* Link .o files to .so file. It returns 1 if it succeeds. (non-mswin) */
static int
link_o_to_so(const char **o_files, const char *so_file)
{
int exit_code;
const char *options[] = {
"-o", NULL,
# ifdef _WIN32
libruby_pathflag,
# endif
NULL
};
char **args;
options[1] = so_file;
args = form_args(6, CC_LDSHARED_ARGS, CC_CODEFLAG_ARGS,
options, o_files, CC_LIBS, CC_DLDFLAGS_ARGS);
if (args == NULL)
return FALSE;
exit_code = exec_process(cc_path, args);
free(args);
if (exit_code != 0)
verbose(2, "link_o_to_so: link error: %d", exit_code);
return exit_code == 0;
}
/* Link all cached .o files and build a .so file. Reload all JIT func from it. This
allows to avoid JIT code fragmentation and improve performance to call JIT-ed code. */
static void
compact_all_jit_code(void)
{
# ifndef _WIN32 /* This requires header transformation but we don't transform header on Windows for now */
struct rb_mjit_unit *unit, *cur = 0;
double start_time, end_time;
static const char so_ext[] = DLEXT;
char so_file[MAXPATHLEN];
const char **o_files;
int i = 0, success;
/* Abnormal use case of rb_mjit_unit that doesn't have ISeq */
unit = calloc(1, sizeof(struct rb_mjit_unit)); /* To prevent GC, don't use ZALLOC */
if (unit == NULL) return;
unit->id = current_unit_num++;
sprint_uniq_filename(so_file, (int)sizeof(so_file), unit->id, MJIT_TMP_PREFIX, so_ext);
/* NULL-ending for form_args */
o_files = alloca(sizeof(char *) * (active_units.length + 1));
o_files[active_units.length] = NULL;
CRITICAL_SECTION_START(3, "in compact_all_jit_code to keep .o files");
list_for_each(&active_units.head, cur, unode) {
o_files[i] = cur->o_file;
i++;
}
start_time = real_ms_time();
success = link_o_to_so(o_files, so_file);
end_time = real_ms_time();
/* TODO: Shrink this big critical section. For now, this is needed to prevent failure by missing .o files.
This assumes that o -> so link doesn't take long time because the bottleneck, which is compiler optimization,
is already done. But actually it takes about 500ms for 5,000 methods on my Linux machine, so it's better to
finish this critical section before link_o_to_so by disabling unload_units. */
CRITICAL_SECTION_FINISH(3, "in compact_all_jit_code to keep .o files");
if (success) {
void *handle = dlopen(so_file, RTLD_NOW);
if (handle == NULL) {
mjit_warning("failure in loading code from compacted '%s': %s", so_file, dlerror());
free(unit);
return;
}
unit->handle = handle;
/* lazily dlclose handle (and .so file for win32) on `mjit_finish()`. */
add_to_list(unit, &compact_units);
if (!mjit_opts.save_temps)
remove_so_file(so_file, unit);
CRITICAL_SECTION_START(3, "in compact_all_jit_code to read list");
list_for_each(&active_units.head, cur, unode) {
void *func;
char funcname[35]; /* TODO: reconsider `35` */
sprintf(funcname, "_mjit%d", cur->id);
if ((func = dlsym(handle, funcname)) == NULL) {
mjit_warning("skipping to reload '%s' from '%s': %s", funcname, so_file, dlerror());
continue;
}
if (cur->iseq) { /* Check whether GCed or not */
/* Usage of jit_code might be not in a critical section. */
MJIT_ATOMIC_SET(cur->iseq->body->jit_func, (mjit_func_t)func);
}
}
CRITICAL_SECTION_FINISH(3, "in compact_all_jit_code to read list");
verbose(1, "JIT compaction (%.1fms): Compacted %d methods -> %s", end_time - start_time, active_units.length, so_file);
}
else {
free(unit);
verbose(1, "JIT compaction failure (%.1fms): Failed to compact methods", end_time - start_time);
}
# endif /* _WIN32 */
}
#endif /* _MSC_VER */
static void *
load_func_from_so(const char *so_file, const char *funcname, struct rb_mjit_unit *unit)
{
void *handle, *func;
handle = dlopen(so_file, RTLD_NOW);
if (handle == NULL) {
mjit_warning("failure in loading code from '%s': %s", so_file, dlerror());
return (void *)NOT_ADDED_JIT_ISEQ_FUNC;
}
func = dlsym(handle, funcname);
unit->handle = handle;
return func;
}
static void
print_jit_result(const char *result, const struct rb_mjit_unit *unit, const double duration, const char *c_file)
{
verbose(1, "JIT %s (%.1fms): %s@%s:%d -> %s", result,
duration, RSTRING_PTR(unit->iseq->body->location.label),
RSTRING_PTR(rb_iseq_path(unit->iseq)), FIX2INT(unit->iseq->body->location.first_lineno), c_file);
}
#ifndef __clang__
static const char *
header_name_end(const char *s)
{
const char *e = s + strlen(s);
# ifdef __GNUC__ /* don't chomp .pch for mswin */
static const char suffix[] = ".gch";
/* chomp .gch suffix */
if (e > s+sizeof(suffix)-1 && strcmp(e-sizeof(suffix)+1, suffix) == 0) {
e -= sizeof(suffix)-1;
}
# endif
return e;
}
#endif
/* Print platform-specific prerequisites in generated code. */
static void
compile_prelude(FILE *f)
{
#ifndef __clang__ /* -include-pch is used for Clang */
const char *s = pch_file;
const char *e = header_name_end(s);
fprintf(f, "#include \"");
/* print pch_file except .gch for gcc, but keep .pch for mswin */
for (; s < e; s++) {
switch(*s) {
case '\\': case '"':
fputc('\\', f);
}
fputc(*s, f);
}
fprintf(f, "\"\n");
#endif
#ifdef _WIN32
fprintf(f, "void _pei386_runtime_relocator(void){}\n");
fprintf(f, "int __stdcall DllMainCRTStartup(void* hinstDLL, unsigned int fdwReason, void* lpvReserved) { return 1; }\n");
#endif
}
/* Compile ISeq in UNIT and return function pointer of JIT-ed code.
It may return NOT_COMPILED_JIT_ISEQ_FUNC if something went wrong. */
static mjit_func_t
convert_unit_to_func(struct rb_mjit_unit *unit, struct rb_call_cache *cc_entries, union iseq_inline_storage_entry *is_entries)
{
char c_file_buff[MAXPATHLEN], *c_file = c_file_buff, *so_file, funcname[35]; /* TODO: reconsider `35` */
int success;
int fd;
FILE *f;
void *func;
double start_time, end_time;
int c_file_len = (int)sizeof(c_file_buff);
static const char c_ext[] = ".c";
static const char so_ext[] = DLEXT;
const int access_mode =
#ifdef O_BINARY
O_BINARY|
#endif
O_WRONLY|O_EXCL|O_CREAT;
#ifndef _MSC_VER
static const char o_ext[] = ".o";
char *o_file;
#endif
c_file_len = sprint_uniq_filename(c_file_buff, c_file_len, unit->id, MJIT_TMP_PREFIX, c_ext);
if (c_file_len >= (int)sizeof(c_file_buff)) {
++c_file_len;
c_file = alloca(c_file_len);
c_file_len = sprint_uniq_filename(c_file, c_file_len, unit->id, MJIT_TMP_PREFIX, c_ext);
}
++c_file_len;
#ifndef _MSC_VER
o_file = alloca(c_file_len - sizeof(c_ext) + sizeof(o_ext));
memcpy(o_file, c_file, c_file_len - sizeof(c_ext));
memcpy(&o_file[c_file_len - sizeof(c_ext)], o_ext, sizeof(o_ext));
#endif
so_file = alloca(c_file_len - sizeof(c_ext) + sizeof(so_ext));
memcpy(so_file, c_file, c_file_len - sizeof(c_ext));
memcpy(&so_file[c_file_len - sizeof(c_ext)], so_ext, sizeof(so_ext));
sprintf(funcname, "_mjit%d", unit->id);
fd = rb_cloexec_open(c_file, access_mode, 0600);
if (fd < 0 || (f = fdopen(fd, "w")) == NULL) {
int e = errno;
if (fd >= 0) (void)close(fd);
verbose(1, "Failed to fopen '%s', giving up JIT for it (%s)", c_file, strerror(e));
return (mjit_func_t)NOT_COMPILED_JIT_ISEQ_FUNC;
}
/* print #include of MJIT header, etc. */
compile_prelude(f);
/* wait until mjit_gc_finish_hook is called */
CRITICAL_SECTION_START(3, "before mjit_compile to wait GC finish");
while (in_gc) {
verbose(3, "Waiting wakeup from GC");
rb_native_cond_wait(&mjit_gc_wakeup, &mjit_engine_mutex);
}
/* We need to check again here because we could've waited on GC above */
if (unit->iseq == NULL) {
fclose(f);
if (!mjit_opts.save_temps)
remove_file(c_file);
free_unit(unit);
in_jit = FALSE; /* just being explicit for return */
}
else {
in_jit = TRUE;
}
CRITICAL_SECTION_FINISH(3, "before mjit_compile to wait GC finish");
if (!in_jit) {
return (mjit_func_t)NOT_COMPILED_JIT_ISEQ_FUNC;
}
{
VALUE s = rb_iseq_path(unit->iseq);
const char *label = RSTRING_PTR(unit->iseq->body->location.label);
const char *path = RSTRING_PTR(s);
int lineno = FIX2INT(unit->iseq->body->location.first_lineno);
verbose(2, "start compilation: %s@%s:%d -> %s", label, path, lineno, c_file);
fprintf(f, "/* %s@%s:%d */\n\n", label, path, lineno);
}
success = mjit_compile(f, unit->iseq->body, funcname, cc_entries, is_entries);
/* release blocking mjit_gc_start_hook */
CRITICAL_SECTION_START(3, "after mjit_compile to wakeup client for GC");
in_jit = FALSE;
verbose(3, "Sending wakeup signal to client in a mjit-worker for GC");
rb_native_cond_signal(&mjit_client_wakeup);
CRITICAL_SECTION_FINISH(3, "in worker to wakeup client for GC");
fclose(f);
if (!success) {
if (!mjit_opts.save_temps)
remove_file(c_file);
print_jit_result("failure", unit, 0, c_file);
return (mjit_func_t)NOT_COMPILED_JIT_ISEQ_FUNC;
}
start_time = real_ms_time();
#ifdef _MSC_VER
success = compile_c_to_so(c_file, so_file);
#else
/* splitting .c -> .o step and .o -> .so step, to cache .o files in the future */
if ((success = compile_c_to_o(c_file, o_file)) != 0) {
const char *o_files[2] = { NULL, NULL };
o_files[0] = o_file;
success = link_o_to_so(o_files, so_file);
/* Always set o_file for compaction. The value is also used for lazy deletion. */
unit->o_file = strdup(o_file);
if (unit->o_file == NULL) {
mjit_warning("failed to allocate memory to remember '%s' (%s), removing it...", o_file, strerror(errno));
remove_file(o_file);
}
}
#endif
end_time = real_ms_time();
if (!mjit_opts.save_temps)
remove_file(c_file);
if (!success) {
verbose(2, "Failed to generate so: %s", so_file);
return (mjit_func_t)NOT_COMPILED_JIT_ISEQ_FUNC;
}
func = load_func_from_so(so_file, funcname, unit);
if (!mjit_opts.save_temps)
remove_so_file(so_file, unit);
if ((uintptr_t)func > (uintptr_t)LAST_JIT_ISEQ_FUNC) {
CRITICAL_SECTION_START(3, "end of jit");
add_to_list(unit, &active_units);
if (unit->iseq)
print_jit_result("success", unit, end_time - start_time, c_file);
CRITICAL_SECTION_FINISH(3, "end of jit");
}
return (mjit_func_t)func;
}
struct mjit_copy_job {
const struct rb_iseq_constant_body *body;
struct rb_call_cache *cc_entries;
union iseq_inline_storage_entry *is_entries;
int finish_p;
};
static void mjit_copy_job_handler(void *data);
/* We're lazily copying cache values from main thread because these cache values
could be different between ones on enqueue timing and ones on dequeue timing.
Return TRUE if copy succeeds. */
static int
copy_cache_from_main_thread(struct mjit_copy_job *job)
{
CRITICAL_SECTION_START(3, "in copy_cache_from_main_thread");
job->finish_p = FALSE; /* allow dispatching this job in mjit_copy_job_handler */
CRITICAL_SECTION_FINISH(3, "in copy_cache_from_main_thread");
if (UNLIKELY(mjit_opts.wait)) {
mjit_copy_job_handler((void *)job);
return job->finish_p;
}
if (!rb_postponed_job_register(0, mjit_copy_job_handler, (void *)job))
return FALSE;
CRITICAL_SECTION_START(3, "in MJIT copy job wait");
/* checking `stop_worker_p` too because `RUBY_VM_CHECK_INTS(ec)` may not
lush mjit_copy_job_handler when EC_EXEC_TAG() is not TAG_NONE, and then
`stop_worker()` could dead lock with this function. */
while (!job->finish_p && !stop_worker_p) {
rb_native_cond_wait(&mjit_worker_wakeup, &mjit_engine_mutex);
verbose(3, "Getting wakeup from client");
}
CRITICAL_SECTION_FINISH(3, "in MJIT copy job wait");
return job->finish_p;
}
/* The function implementing a worker. It is executed in a separate
thread by rb_thread_create_mjit_thread. It compiles precompiled header
and then compiles requested ISeqs. */
void
mjit_worker(void)
{
struct mjit_copy_job job;
#ifndef _MSC_VER
if (pch_status == PCH_NOT_READY) {
make_pch();
}
#endif
if (pch_status == PCH_FAILED) {
mjit_enabled = FALSE;
CRITICAL_SECTION_START(3, "in worker to update worker_stopped");
worker_stopped = TRUE;
verbose(3, "Sending wakeup signal to client in a mjit-worker");
rb_native_cond_signal(&mjit_client_wakeup);
CRITICAL_SECTION_FINISH(3, "in worker to update worker_stopped");
return; /* TODO: do the same thing in the latter half of mjit_finish */
}
/* main worker loop */
while (!stop_worker_p) {
struct rb_mjit_unit *unit;
/* wait until unit is available */
CRITICAL_SECTION_START(3, "in worker dequeue");
while ((list_empty(&unit_queue.head) || active_units.length >= mjit_opts.max_cache_size) && !stop_worker_p) {
rb_native_cond_wait(&mjit_worker_wakeup, &mjit_engine_mutex);
verbose(3, "Getting wakeup from client");
}
unit = get_from_list(&unit_queue);
job.finish_p = TRUE; /* disable dispatching this job in mjit_copy_job_handler while it's being modified */
CRITICAL_SECTION_FINISH(3, "in worker dequeue");
if (unit) {
mjit_func_t func;
job.body = unit->iseq->body;
job.cc_entries = NULL;
if (job.body->ci_size > 0 || job.body->ci_kw_size > 0)
job.cc_entries = alloca(sizeof(struct rb_call_cache) * (job.body->ci_size + job.body->ci_kw_size));
job.is_entries = NULL;
if (job.body->is_size > 0)
job.is_entries = alloca(sizeof(union iseq_inline_storage_entry) * job.body->is_size);
/* Copy ISeq's inline caches values to avoid race condition. */
if (job.cc_entries != NULL || job.is_entries != NULL) {
if (copy_cache_from_main_thread(&job) == FALSE) {
continue; /* retry postponed_job failure, or stop worker */
}
}
/* JIT compile */
func = convert_unit_to_func(unit, job.cc_entries, job.is_entries);
CRITICAL_SECTION_START(3, "in jit func replace");
if (unit->iseq) { /* Check whether GCed or not */
/* Usage of jit_code might be not in a critical section. */
MJIT_ATOMIC_SET(unit->iseq->body->jit_func, func);
}
CRITICAL_SECTION_FINISH(3, "in jit func replace");
#ifndef _MSC_VER
/* Combine .o files to one .so and reload all jit_func to improve memory locality */
if ((!mjit_opts.wait && unit_queue.length == 0 && active_units.length > 1)
|| active_units.length == mjit_opts.max_cache_size) {
compact_all_jit_code();
}
#endif
}
}
/* To keep mutex unlocked when it is destroyed by mjit_finish, don't wrap CRITICAL_SECTION here. */
worker_stopped = TRUE;
}