jlapi.c
// This file is a part of Julia. License is MIT: https://julialang.org/license
/*
jlapi.c
miscellaneous functions for users of libjulia.so, to handle initialization
and the style of use where julia is not in control most of the time.
*/
#include "platform.h"
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include "julia.h"
#include "options.h"
#include "julia_assert.h"
#include "julia_internal.h"
#ifdef USE_TRACY
#include "tracy/TracyC.h"
#endif
#ifdef __cplusplus
#include <cfenv>
extern "C" {
#else
#include <fenv.h>
#endif
/**
* @brief Check if Julia is already initialized.
*
* Determine if Julia has been previously initialized
* via `jl_init` or `jl_init_with_image`.
*
* @return Returns 1 if Julia is initialized, 0 otherwise.
*/
JL_DLLEXPORT int jl_is_initialized(void)
{
return jl_main_module != NULL;
}
/**
* @brief Set Julia command line arguments.
*
* Allows setting the command line arguments for Julia,
* similar to arguments passed in the main function of a C program.
*
* @param argc The number of command line arguments.
* @param argv Array of command line arguments.
*/
JL_DLLEXPORT void jl_set_ARGS(int argc, char **argv)
{
if (jl_core_module != NULL) {
jl_array_t *args = (jl_array_t*)jl_get_global(jl_core_module, jl_symbol("ARGS"));
if (args == NULL) {
args = jl_alloc_vec_any(0);
JL_GC_PUSH1(&args);
jl_set_const(jl_core_module, jl_symbol("ARGS"), (jl_value_t*)args);
JL_GC_POP();
}
assert(jl_array_nrows(args) == 0);
jl_array_grow_end(args, argc);
int i;
for (i = 0; i < argc; i++) {
jl_value_t *s = (jl_value_t*)jl_cstr_to_string(argv[i]);
jl_array_ptr_set(args, i, s);
}
}
}
/**
* @brief Initialize Julia with a specified system image file.
*
* Initializes Julia by specifying the usr/bin directory where the Julia binary is
* and the path of a system image file (*.so). If the julia_bindir is NULL, the function
* attempts to guess the directory. The image_path is interpreted as a path to the system image
* file. A non-absolute path for the system image is considered relative to julia_bindir, or
* relative to the default Julia home directory. The default system image is typically
* something like ../lib/julia/sys.so.
*
* @param julia_bindir The usr/bin directory where the Julia binary is located, or NULL to guess.
* @param image_path The path of a system image file (*.so). Interpreted as relative to julia_bindir
* or the default Julia home directory if not an absolute path.
*/
JL_DLLEXPORT void jl_init_with_image(const char *julia_bindir,
const char *image_path)
{
if (jl_is_initialized())
return;
libsupport_init();
jl_options.julia_bindir = julia_bindir;
if (image_path != NULL)
jl_options.image_file = image_path;
else
jl_options.image_file = jl_get_default_sysimg_path();
julia_init(JL_IMAGE_JULIA_HOME);
jl_exception_clear();
}
/**
* @brief Initialize the Julia runtime.
*
* Initializes the Julia runtime without any specific system image.
* It must be called before any other Julia API functions.
*/
JL_DLLEXPORT void jl_init(void)
{
char *libbindir = NULL;
#ifdef _OS_WINDOWS_
libbindir = strdup(jl_get_libdir());
#else
(void)asprintf(&libbindir, "%s" PATHSEPSTRING ".." PATHSEPSTRING "%s", jl_get_libdir(), "bin");
#endif
if (!libbindir) {
printf("jl_init unable to find libjulia!\n");
abort();
}
jl_init_with_image(libbindir, jl_get_default_sysimg_path());
free(libbindir);
}
// HACK: remove this for Julia 1.8 (see <https://github.com/JuliaLang/julia/issues/40730>)
JL_DLLEXPORT void jl_init__threading(void)
{
jl_init();
}
// HACK: remove this for Julia 1.8 (see <https://github.com/JuliaLang/julia/issues/40730>)
JL_DLLEXPORT void jl_init_with_image__threading(const char *julia_bindir,
const char *image_relative_path)
{
jl_init_with_image(julia_bindir, image_relative_path);
}
static void _jl_exception_clear(jl_task_t *ct) JL_NOTSAFEPOINT
{
ct->ptls->previous_exception = NULL;
}
/**
* @brief Evaluate a Julia expression from a string.
*
* @param str A C string containing the Julia expression to be evaluated.
* @return A pointer to `jl_value_t` representing the result of the evaluation.
* Returns `NULL` if an error occurs during parsing or evaluation.
*/
JL_DLLEXPORT jl_value_t *jl_eval_string(const char *str)
{
jl_value_t *r;
jl_task_t *ct = jl_current_task;
JL_TRY {
const char filename[] = "none";
jl_value_t *ast = jl_parse_all(str, strlen(str),
filename, strlen(filename), 1);
JL_GC_PUSH1(&ast);
r = jl_toplevel_eval_in(jl_main_module, ast);
JL_GC_POP();
_jl_exception_clear(ct);
}
JL_CATCH {
ct->ptls->previous_exception = jl_current_exception();
r = NULL;
}
return r;
}
/**
* @brief Get the current exception in the Julia context.
*
* @return A pointer to `jl_value_t` representing the current exception.
* Returns `NULL` if no exception is currently thrown.
*/
JL_DLLEXPORT jl_value_t *jl_current_exception(void) JL_GLOBALLY_ROOTED JL_NOTSAFEPOINT
{
jl_excstack_t *s = jl_current_task->excstack;
return s && s->top != 0 ? jl_excstack_exception(s, s->top) : jl_nothing;
}
/**
* @brief Check if an exception has occurred in the Julia context.
*
* @return A pointer to `jl_value_t` representing the exception that occurred.
* Returns `NULL` if no exception has occurred.
*/
JL_DLLEXPORT jl_value_t *jl_exception_occurred(void)
{
return jl_current_task->ptls->previous_exception;
}
/**
* @brief Clear the current exception in the Julia context.
*
*/
JL_DLLEXPORT void jl_exception_clear(void)
{
_jl_exception_clear(jl_current_task);
}
/**
* @brief Get the type name of a Julia value.
*
* @param v A pointer to `jl_value_t` representing the Julia value.
* @return A C string containing the name of the type.
*/
JL_DLLEXPORT const char *jl_typename_str(jl_value_t *v)
{
if (!jl_is_datatype(v))
return NULL;
return jl_symbol_name(((jl_datatype_t*)v)->name->name);
}
/**
* @brief Get the string representation of a Julia value's type.
*
* @param v A pointer to `jl_value_t` representing the Julia value.
* @return A C string describing the type of the value.
*/
JL_DLLEXPORT const char *jl_typeof_str(jl_value_t *v)
{
return jl_typename_str((jl_value_t*)jl_typeof(v));
}
/**
* @brief Get the element type of a Julia array.
*
* @param a A pointer to `jl_value_t` representing the Julia array.
* @return A pointer to the type of the array elements.
*/
JL_DLLEXPORT void *jl_array_eltype(jl_value_t *a)
{
return jl_tparam0(jl_typeof(a));
}
/**
* @brief Get the number of dimensions of a Julia array.
*
* Returns the rank (number of dimensions) of a Julia array.
*
* @param a A pointer to `jl_value_t` representing the Julia array.
* @return An integer representing the number of dimensions of the array.
*/
JL_DLLEXPORT int jl_array_rank(jl_value_t *a)
{
return jl_array_ndims(a);
}
/**
* @brief Get the size of a specific dimension of a Julia array.
*
* Returns the size (number of elements) of a specific dimension
* of a Julia array.
*
* @param a A pointer to `jl_array_t` representing the Julia array.
* @param d The dimension for which the size is requested.
* @return The size of the specified dimension of the array.
*/
JL_DLLEXPORT size_t jl_array_size(jl_array_t *a, int d)
{
// n.b this functions only use was to violate the vector abstraction, so we have to continue to emulate that
if (d >= jl_array_ndims(a))
return a->ref.mem->length;
return jl_array_dim(a, d);
}
/**
* @brief Get the C string pointer from a Julia string.
*
* @param s A pointer to `jl_value_t` representing the Julia string.
* @return A C string pointer containing the contents of the Julia string.
*/
JL_DLLEXPORT const char *jl_string_ptr(jl_value_t *s)
{
return jl_string_data(s);
}
/**
* @brief Call a Julia function with a specified number of arguments.
*
* @param f A pointer to `jl_function_t` representing the Julia function to call.
* @param args An array of pointers to `jl_value_t` representing the arguments.
* @param nargs The number of arguments in the array.
* @return A pointer to `jl_value_t` representing the result of the function call.
*/
JL_DLLEXPORT jl_value_t *jl_call(jl_function_t *f, jl_value_t **args, uint32_t nargs)
{
jl_value_t *v;
jl_task_t *ct = jl_current_task;
nargs++; // add f to args
JL_TRY {
jl_value_t **argv;
JL_GC_PUSHARGS(argv, nargs);
argv[0] = (jl_value_t*)f;
for (int i = 1; i < nargs; i++)
argv[i] = args[i - 1];
size_t last_age = ct->world_age;
ct->world_age = jl_get_world_counter();
v = jl_apply(argv, nargs);
ct->world_age = last_age;
JL_GC_POP();
_jl_exception_clear(ct);
}
JL_CATCH {
ct->ptls->previous_exception = jl_current_exception();
v = NULL;
}
return v;
}
/**
* @brief Call a Julia function with no arguments.
*
* A specialized case of `jl_call` for simpler scenarios.
*
* @param f A pointer to `jl_function_t` representing the Julia function to call.
* @return A pointer to `jl_value_t` representing the result of the function call.
*/
JL_DLLEXPORT jl_value_t *jl_call0(jl_function_t *f)
{
jl_value_t *v;
jl_task_t *ct = jl_current_task;
JL_TRY {
JL_GC_PUSH1(&f);
size_t last_age = ct->world_age;
ct->world_age = jl_get_world_counter();
v = jl_apply_generic(f, NULL, 0);
ct->world_age = last_age;
JL_GC_POP();
_jl_exception_clear(ct);
}
JL_CATCH {
ct->ptls->previous_exception = jl_current_exception();
v = NULL;
}
return v;
}
/**
* @brief Call a Julia function with one argument.
*
* A specialized case of `jl_call` for simpler scenarios.
*
* @param f A pointer to `jl_function_t` representing the Julia function to call.
* @param a A pointer to `jl_value_t` representing the argument to the function.
* @return A pointer to `jl_value_t` representing the result of the function call.
*/
JL_DLLEXPORT jl_value_t *jl_call1(jl_function_t *f, jl_value_t *a)
{
jl_value_t *v;
jl_task_t *ct = jl_current_task;
JL_TRY {
jl_value_t **argv;
JL_GC_PUSHARGS(argv, 2);
argv[0] = f;
argv[1] = a;
size_t last_age = ct->world_age;
ct->world_age = jl_get_world_counter();
v = jl_apply(argv, 2);
ct->world_age = last_age;
JL_GC_POP();
_jl_exception_clear(ct);
}
JL_CATCH {
ct->ptls->previous_exception = jl_current_exception();
v = NULL;
}
return v;
}
/**
* @brief Call a Julia function with two arguments.
*
* A specialized case of `jl_call` for simpler scenarios.
*
* @param f A pointer to `jl_function_t` representing the Julia function to call.
* @param a A pointer to `jl_value_t` representing the first argument.
* @param b A pointer to `jl_value_t` representing the second argument.
* @return A pointer to `jl_value_t` representing the result of the function call.
*/
JL_DLLEXPORT jl_value_t *jl_call2(jl_function_t *f, jl_value_t *a, jl_value_t *b)
{
jl_value_t *v;
jl_task_t *ct = jl_current_task;
JL_TRY {
jl_value_t **argv;
JL_GC_PUSHARGS(argv, 3);
argv[0] = f;
argv[1] = a;
argv[2] = b;
size_t last_age = ct->world_age;
ct->world_age = jl_get_world_counter();
v = jl_apply(argv, 3);
ct->world_age = last_age;
JL_GC_POP();
_jl_exception_clear(ct);
}
JL_CATCH {
ct->ptls->previous_exception = jl_current_exception();
v = NULL;
}
return v;
}
/**
* @brief Call a Julia function with three arguments.
*
* A specialized case of `jl_call` for simpler scenarios.
*
* @param f A pointer to `jl_function_t` representing the Julia function to call.
* @param a A pointer to `jl_value_t` representing the first argument.
* @param b A pointer to `jl_value_t` representing the second argument.
* @param c A pointer to `jl_value_t` representing the third argument.
* @return A pointer to `jl_value_t` representing the result of the function call.
*/
JL_DLLEXPORT jl_value_t *jl_call3(jl_function_t *f, jl_value_t *a,
jl_value_t *b, jl_value_t *c)
{
jl_value_t *v;
jl_task_t *ct = jl_current_task;
JL_TRY {
jl_value_t **argv;
JL_GC_PUSHARGS(argv, 4);
argv[0] = f;
argv[1] = a;
argv[2] = b;
argv[3] = c;
size_t last_age = ct->world_age;
ct->world_age = jl_get_world_counter();
v = jl_apply(argv, 4);
ct->world_age = last_age;
JL_GC_POP();
_jl_exception_clear(ct);
}
JL_CATCH {
ct->ptls->previous_exception = jl_current_exception();
v = NULL;
}
return v;
}
/**
* @brief Get a field from a Julia object.
*
* @param o A pointer to `jl_value_t` representing the Julia object.
* @param fld A C string representing the name of the field to retrieve.
* @return A pointer to `jl_value_t` representing the value of the field.
*/
JL_DLLEXPORT jl_value_t *jl_get_field(jl_value_t *o, const char *fld)
{
jl_value_t *v;
JL_TRY {
jl_value_t *s = (jl_value_t*)jl_symbol(fld);
int i = jl_field_index((jl_datatype_t*)jl_typeof(o), (jl_sym_t*)s, 1);
v = jl_get_nth_field(o, i);
jl_exception_clear();
}
JL_CATCH {
jl_current_task->ptls->previous_exception = jl_current_exception();
v = NULL;
}
return v;
}
/**
* @brief Begin an atomic signal-protected region.
*
* Marks the start of a region of code that should be protected
* from interruption by asynchronous signals.
*/
JL_DLLEXPORT void jl_sigatomic_begin(void)
{
JL_SIGATOMIC_BEGIN();
}
/**
* @brief End an atomic signal-protected region.
*
* Marks the end of a region of code protected from asynchronous signals.
* It should be used in conjunction with `jl_sigatomic_begin` to define signal-protected regions.
*/
JL_DLLEXPORT void jl_sigatomic_end(void)
{
jl_task_t *ct = jl_current_task;
if (ct->ptls->defer_signal == 0)
jl_error("sigatomic_end called in non-sigatomic region");
JL_SIGATOMIC_END();
}
/**
* @brief Check if Julia is running in debug build mode.
*
* @return Returns 1 if Julia is in debug build mode, 0 otherwise.
*/
JL_DLLEXPORT int jl_is_debugbuild(void) JL_NOTSAFEPOINT
{
#ifdef JL_DEBUG_BUILD
return 1;
#else
return 0;
#endif
}
/**
* @brief Check if Julia has been build with assertions enabled.
*
* @return Returns 1 if assertions are enabled, 0 otherwise.
*/
JL_DLLEXPORT int8_t jl_is_assertsbuild(void) JL_NOTSAFEPOINT {
#ifndef JL_NDEBUG
return 1;
#else
return 0;
#endif
}
/**
* @brief Check if Julia's memory debugging is enabled.
*
* @return Returns 1 if memory debugging is enabled, 0 otherwise.
*/
JL_DLLEXPORT int8_t jl_is_memdebug(void) JL_NOTSAFEPOINT {
#ifdef MEMDEBUG
return 1;
#else
return 0;
#endif
}
/**
* @brief Get the directory path of the Julia binary.
*
* @return A pointer to `jl_value_t` representing the directory path as a Julia string.
*/
JL_DLLEXPORT jl_value_t *jl_get_julia_bindir(void)
{
return jl_cstr_to_string(jl_options.julia_bindir);
}
/**
* @brief Get the path to the Julia binary.
*
* @return A pointer to `jl_value_t` representing the full path as a Julia string.
*/
JL_DLLEXPORT jl_value_t *jl_get_julia_bin(void)
{
return jl_cstr_to_string(jl_options.julia_bin);
}
/**
* @brief Get the path to the Julia system image file.
*
* @return A pointer to `jl_value_t` representing the system image file path as a Julia string.
*/
JL_DLLEXPORT jl_value_t *jl_get_image_file(void)
{
return jl_cstr_to_string(jl_options.image_file);
}
/**
* @brief Get the major version number of Julia.
*
* @return The major version number as an integer.
*/
JL_DLLEXPORT int jl_ver_major(void)
{
return JULIA_VERSION_MAJOR;
}
/**
* @brief Get the minor version number of Julia.
*
* @return The minor version number as an integer.
*/
JL_DLLEXPORT int jl_ver_minor(void)
{
return JULIA_VERSION_MINOR;
}
/**
* @brief Get the patch version number of Julia.
*
* @return The patch version number as an integer.
*/
JL_DLLEXPORT int jl_ver_patch(void)
{
return JULIA_VERSION_PATCH;
}
/**
* @brief Check if the current Julia version is a release version.
*
* @return Returns 1 if it is a release version, 0 otherwise.
*/
JL_DLLEXPORT int jl_ver_is_release(void)
{
return JULIA_VERSION_IS_RELEASE;
}
/**
* @brief Get the Julia version as a string.
*
* @return A C string containing the version information.
*/
JL_DLLEXPORT const char *jl_ver_string(void)
{
return JULIA_VERSION_STRING;
}
/**
* @brief Convert a Julia value to a tagged value.
*
* Converts a Julia value into its corresponding tagged value representation.
* Tagged values include additional metadata used internally by the Julia runtime.
*
* @param v A pointer to `jl_value_t` representing the Julia value.
* @return A pointer to `jl_taggedvalue_t` representing the tagged value.
*/
JL_DLLEXPORT jl_taggedvalue_t *(jl_astaggedvalue)(jl_value_t *v)
{
return jl_astaggedvalue(v);
}
/**
* @brief Convert a tagged value back to a Julia value.
*
* Converts a tagged value back into its original Julia value.
* It's the inverse operation of `jl_astaggedvalue`.
*
* @param v A pointer to `jl_taggedvalue_t` representing the tagged value.
* @return A pointer to `jl_value_t` representing the original Julia value.
*/
JL_DLLEXPORT jl_value_t *(jl_valueof)(jl_taggedvalue_t *v)
{
return jl_valueof(v);
}
/**
* @brief Get the type of a Julia value.
*
* @param v A pointer to `jl_value_t` representing the Julia value.
* @return A pointer to `jl_value_t` representing the type of the value.
*/
JL_DLLEXPORT jl_value_t *(jl_typeof)(jl_value_t *v)
{
return jl_typeof(v);
}
/**
* @brief Get the field types of a Julia value.
*
* @param v A pointer to `jl_value_t` representing the Julia value.
* @return A pointer to `jl_value_t` representing the field types.
*/
JL_DLLEXPORT jl_value_t *(jl_get_fieldtypes)(jl_value_t *v)
{
return (jl_value_t*)jl_get_fieldtypes((jl_datatype_t*)v);
}
/**
* @brief Check equality of two Julia values.
*
* @param a A pointer to `jl_value_t` representing the first Julia value.
* @param b A pointer to `jl_value_t` representing the second Julia value.
* @return Returns 1 if the values are equal, 0 otherwise.
*/
JL_DLLEXPORT int ijl_egal(jl_value_t *a, jl_value_t *b)
{
return jl_egal(a, b);
}
#ifndef __clang_gcanalyzer__
/**
* @brief Enter a state where concurrent garbage collection (GC) is considered unsafe.
*
* Marks the beginning of a code region where garbage collection operations are unsafe.
* Used to make it legal to access GC-managed state (almost anything)
*
* @return An `int8_t` state value representing the previous GC state.
*/
JL_DLLEXPORT int8_t (jl_gc_unsafe_enter)(void)
{
jl_task_t *ct = jl_current_task;
return jl_gc_unsafe_enter(ct->ptls);
}
/**
* @brief Leave the state where garbage collection is considered unsafe.
*
* Ends a code region where garbage collection was marked as unsafe.
* It restores the previous GC state using the state value returned by `jl_gc_unsafe_enter`.
*
* @param state The state value returned by `jl_gc_unsafe_enter` to restore the previous GC state.
*/
JL_DLLEXPORT void (jl_gc_unsafe_leave)(int8_t state)
{
jl_task_t *ct = jl_current_task;
jl_gc_unsafe_leave(ct->ptls, state);
}
/**
* @brief Enter a state where garbage collection (GC) is considered safe.
*
* Marks the beginning of a code region where garbage collection operations are safe.
* Used to enable GC in sections of code where it was previously marked as unsafe.
*
* @return An `int8_t` state value representing the previous GC state.
*/
JL_DLLEXPORT int8_t (jl_gc_safe_enter)(void)
{
jl_task_t *ct = jl_current_task;
return jl_gc_safe_enter(ct->ptls);
}
/**
* @brief Leave the state where garbage collection is considered safe.
*
* Ends a code region where garbage collection was marked as safe.
* It restores the previous GC state using the state value returned by `jl_gc_safe_enter`.
*
* @param state The state value returned by `jl_gc_safe_enter` to restore the previous GC state.
*/
JL_DLLEXPORT void (jl_gc_safe_leave)(int8_t state)
{
jl_task_t *ct = jl_current_task;
jl_gc_safe_leave(ct->ptls, state);
}
#endif
/**
* @brief Trigger a garbage collection safepoint in a GC-unsafe region.
*
* Triggers a safepoint for garbage collection. Used to
* ensure that the garbage collector can run at specific points in the code,
* particularly in long-running operations or loops.
*/
JL_DLLEXPORT void jl_gc_safepoint(void)
{
jl_task_t *ct = jl_current_task;
jl_gc_safepoint_(ct->ptls);
}
/**
* @brief Pause CPU execution for a brief moment.
*
* Used to pause the CPU briefly, typically to reduce power consumption
* or manage CPU resources more effectively in a tight loop or busy wait scenario.
*/
JL_DLLEXPORT void (jl_cpu_pause)(void)
{
jl_cpu_pause();
}
/**
* @brief Suspend CPU execution.
*
* Suspends CPU execution until a specific condition or event occurs.
*/
JL_DLLEXPORT void (jl_cpu_suspend)(void)
{
jl_cpu_suspend();
}
/**
* @brief Wake the CPU from a suspended state.
*
* Used to resume CPU execution after it has been suspended using `jl_cpu_suspend`.
*/
JL_DLLEXPORT void (jl_cpu_wake)(void)
{
jl_cpu_wake();
}
/**
* @brief Enable cumulative compile timing.
*/
JL_DLLEXPORT void jl_cumulative_compile_timing_enable(void)
{
// Increment the flag to allow reentrant callers to `@time`.
jl_atomic_fetch_add(&jl_measure_compile_time_enabled, 1);
}
/**
* @brief Disable cumulative compile timing.
*/
JL_DLLEXPORT void jl_cumulative_compile_timing_disable(void)
{
// Decrement the flag when done measuring, allowing other callers to continue measuring.
jl_atomic_fetch_add(&jl_measure_compile_time_enabled, -1);
}
/**
* @brief Get the cumulative compilation time in nanoseconds.
*
* @return The cumulative compilation time in nanoseconds.
*/
JL_DLLEXPORT uint64_t jl_cumulative_compile_time_ns(void)
{
return jl_atomic_load_relaxed(&jl_cumulative_compile_time);
}
/**
* @brief Get the cumulative recompilation time in nanoseconds.
*
* @return The cumulative recompilation time in nanoseconds.
*/
JL_DLLEXPORT uint64_t jl_cumulative_recompile_time_ns(void)
{
return jl_atomic_load_relaxed(&jl_cumulative_recompile_time);
}
/**
* @brief Retrieve floating-point environment constants.
*
* Populates an array with constants related to the floating-point environment,
* such as rounding modes and exception flags.
*
* @param ret An array of integers to be populated with floating-point environment constants.
*/
JL_DLLEXPORT void jl_get_fenv_consts(int *ret)
{
ret[0] = FE_INEXACT;
ret[1] = FE_UNDERFLOW;
ret[2] = FE_OVERFLOW;
ret[3] = FE_DIVBYZERO;
ret[4] = FE_INVALID;
ret[5] = FE_TONEAREST;
ret[6] = FE_UPWARD;
ret[7] = FE_DOWNWARD;
ret[8] = FE_TOWARDZERO;
}
// TODO: Windows binaries currently load msvcrt which doesn't have these C99 functions.
// the mingw compiler ships additional definitions, but only for use in C code.
// remove this when we switch to ucrt, make the version in openlibm portable,
// or figure out how to reexport the defs from libmingwex (see JuliaLang/julia#38466).
JL_DLLEXPORT int jl_get_fenv_rounding(void)
{
return fegetround();
}
/**
* @brief Set the floating-point rounding mode.
*
* @param i An integer representing the desired floating-point rounding mode.
See also "floating-point rounding" macros in `<fenv.h>`.
* @return An integer indicating the success or failure of setting the rounding mode.
*/
JL_DLLEXPORT int jl_set_fenv_rounding(int i)
{
return fesetround(i);
}
static int exec_program(char *program)
{
JL_TRY {
jl_load(jl_main_module, program);
}
JL_CATCH {
// TODO: It is possible for this output to be mangled due to `jl_print_backtrace`
// printing directly to STDERR_FILENO.
int shown_err = 0;
jl_printf(JL_STDERR, "error during bootstrap:\n");
jl_value_t *exc = jl_current_exception();
jl_value_t *showf = jl_base_module ? jl_get_function(jl_base_module, "show") : NULL;
if (showf) {
jl_value_t *errs = jl_stderr_obj();
if (errs) {
if (jl_call2(showf, errs, exc)) {
jl_printf(JL_STDERR, "\n");
shown_err = 1;
}
}
}
if (!shown_err) {
jl_static_show((JL_STREAM*)STDERR_FILENO, exc);
jl_printf((JL_STREAM*)STDERR_FILENO, "\n");
}
jl_print_backtrace(); // written to STDERR_FILENO
jl_printf((JL_STREAM*)STDERR_FILENO, "\n");
return 1;
}
return 0;
}
static NOINLINE int true_main(int argc, char *argv[])
{
jl_set_ARGS(argc, argv);
jl_function_t *start_client = jl_base_module ?
(jl_function_t*)jl_get_global(jl_base_module, jl_symbol("_start")) : NULL;
if (start_client) {
jl_task_t *ct = jl_current_task;
int ret = 1;
JL_TRY {
size_t last_age = ct->world_age;
ct->world_age = jl_get_world_counter();
jl_value_t *r = jl_apply(&start_client, 1);
if (jl_typeof(r) != (jl_value_t*)jl_int32_type)
jl_type_error("typeassert", (jl_value_t*)jl_int32_type, r);
ret = jl_unbox_int32(r);
ct->world_age = last_age;
}
JL_CATCH {
jl_no_exc_handler(jl_current_exception(), ct);
}
return ret;
}
// run program if specified, otherwise enter REPL
if (argc > 0) {
if (strcmp(argv[0], "-")) {
return exec_program(argv[0]);
}
}
jl_printf(JL_STDOUT, "WARNING: Base._start not defined, falling back to economy mode repl.\n");
if (!jl_errorexception_type)
jl_printf(JL_STDOUT, "WARNING: jl_errorexception_type not defined; any errors will be fatal.\n");
while (!ios_eof(ios_stdin)) {
char *volatile line = NULL;
JL_TRY {
ios_puts("\njulia> ", ios_stdout);
ios_flush(ios_stdout);
line = ios_readline(ios_stdin);
jl_value_t *val = (jl_value_t*)jl_eval_string(line);
JL_GC_PUSH1(&val);
if (jl_exception_occurred()) {
jl_printf(JL_STDERR, "error during run:\n");
jl_static_show(JL_STDERR, jl_exception_occurred());
jl_exception_clear();
}
else if (val) {
jl_static_show(JL_STDOUT, val);
}
JL_GC_POP();
jl_printf(JL_STDOUT, "\n");
free(line);
line = NULL;
jl_process_events();
}
JL_CATCH {
if (line) {
free(line);
line = NULL;
}
jl_printf((JL_STREAM*)STDERR_FILENO, "\nparser error:\n");
jl_static_show((JL_STREAM*)STDERR_FILENO, jl_current_exception());
jl_printf((JL_STREAM*)STDERR_FILENO, "\n");
jl_print_backtrace(); // written to STDERR_FILENO
}
}
return 0;
}
static void lock_low32(void)
{
#if defined(_OS_WINDOWS_) && defined(_P64) && defined(JL_DEBUG_BUILD)
// Prevent usage of the 32-bit address space on Win64, to catch pointer cast errors.
char *const max32addr = (char*)0xffffffffL;
SYSTEM_INFO info;
MEMORY_BASIC_INFORMATION meminfo;
GetNativeSystemInfo(&info);
memset(&meminfo, 0, sizeof(meminfo));
meminfo.BaseAddress = info.lpMinimumApplicationAddress;
while ((char*)meminfo.BaseAddress < max32addr) {
size_t nbytes = VirtualQuery(meminfo.BaseAddress, &meminfo, sizeof(meminfo));
assert(nbytes == sizeof(meminfo));
if (meminfo.State == MEM_FREE) { // reserve all free pages in the first 4GB of memory
char *first = (char*)meminfo.BaseAddress;
char *last = first + meminfo.RegionSize;
if (last > max32addr)
last = max32addr;
// adjust first up to the first allocation granularity boundary
// adjust last down to the last allocation granularity boundary
first = (char*)(((long long)first + info.dwAllocationGranularity - 1) & ~(info.dwAllocationGranularity - 1));
last = (char*)((long long)last & ~(info.dwAllocationGranularity - 1));
if (last != first) {
void *p = VirtualAlloc(first, last - first, MEM_RESERVE, PAGE_NOACCESS); // reserve all memory in between
if ((char*)p != first)
// Wine and Windows10 seem to have issues with reporting memory access information correctly
// so we sometimes end up with unexpected results - this is just ignore those and continue
// this is just a debugging aid to help find accidental pointer truncation anyways,
// so it is not critical
VirtualFree(p, 0, MEM_RELEASE);
}
}
meminfo.BaseAddress = (void*)((char*)meminfo.BaseAddress + meminfo.RegionSize);
}
#endif
return;
}
// Actual definition in `ast.c`
void jl_lisp_prompt(void);
#ifdef _OS_LINUX_
static void rr_detach_teleport(void) {
#define RR_CALL_BASE 1000
#define SYS_rrcall_detach_teleport (RR_CALL_BASE + 9)
int err = syscall(SYS_rrcall_detach_teleport, 0, 0, 0, 0, 0, 0);
if (err < 0 || jl_running_under_rr(1)) {
jl_error("Failed to detach from rr session");
}
}
#endif
/**
* @brief Entry point for the Julia REPL (Read-Eval-Print Loop).
*
* @param argc The number of command-line arguments.
* @param argv Array of command-line arguments.
* @return An integer indicating the exit status of the REPL session.
*/
JL_DLLEXPORT int jl_repl_entrypoint(int argc, char *argv[])
{
#ifdef USE_TRACY
if (getenv("JULIA_WAIT_FOR_TRACY"))
while (!TracyCIsConnected) jl_cpu_pause(); // Wait for connection
#endif
// no-op on Windows, note that the caller must have already converted
// from `wchar_t` to `UTF-8` already if we're running on Windows.
uv_setup_args(argc, argv);
// No-op on non-windows
lock_low32();
libsupport_init();
int lisp_prompt = (argc >= 2 && strcmp((char*)argv[1],"--lisp") == 0);
if (lisp_prompt) {
memmove(&argv[1], &argv[2], (argc-2)*sizeof(void*));
argc--;
}
char **new_argv = argv;
jl_parse_opts(&argc, (char***)&new_argv);
// The parent process requested that we detach from the rr session.
// N.B.: In a perfect world, we would only do this for the portion of
// the execution where we actually need to exclude rr (e.g. because we're
// testing for the absence of a memory-model-dependent bug).
if (jl_options.rr_detach && jl_running_under_rr(0)) {
#ifdef _OS_LINUX_
rr_detach_teleport();
execv("/proc/self/exe", argv);
#endif
jl_error("Failed to self-execute");
}
julia_init(jl_options.image_file_specified ? JL_IMAGE_CWD : JL_IMAGE_JULIA_HOME);
if (lisp_prompt) {
jl_current_task->world_age = jl_get_world_counter();
jl_lisp_prompt();
return 0;
}
int ret = true_main(argc, (char**)new_argv);
jl_atexit_hook(ret);
return ret;
}
#ifdef __cplusplus
}
#endif