using namespace std;
namespace factor {
typedef void (*c_to_factor_func_type)(cell quot);
typedef void (*unwind_native_frames_func_type)(cell quot, cell to);
typedef cell (*get_fpu_state_func_type)();
typedef void (*set_fpu_state_func_type)(cell state);
struct growable_array;
struct code_root;
struct factor_vm {
//
// vvvvvv
// THESE FIELDS ARE ACCESSED DIRECTLY FROM FACTOR. See:
// basis/vm/vm.factor
// basis/compiler/constants/constants.factor
// Current context
context* ctx;
// Spare context -- for callbacks
context* spare_ctx;
// New objects are allocated here, use the data->nursery reference
// instead from c++ code.
bump_allocator nursery;
// Add this to a shifted address to compute write barrier offsets
cell cards_offset;
cell decks_offset;
// cdecl signal handler address, used by signal handler subprimitives
cell signal_handler_addr;
// are we handling a memory error? used to detect double faults
cell faulting_p;
// Various special objects, accessed by special-object and
// set-special-object primitives
cell special_objects[special_object_count];
// THESE FIELDS ARE ACCESSED DIRECTLY FROM FACTOR.
// ^^^^^^
//
// Handle to the main thread we run in
THREADHANDLE thread;
// Data stack and retain stack sizes
cell datastack_size, retainstack_size, callstack_size;
// Stack of callback IDs
std::vector<int> callback_ids;
// Next callback ID
int callback_id;
// List of callback function descriptors for PPC
std::list<void**> function_descriptors;
// Pooling unused contexts to make context allocation cheaper
std::list<context*> unused_contexts;
// Active contexts, for tracing by the GC
std::set<context*> active_contexts;
// External entry points
c_to_factor_func_type c_to_factor_func;
// Is profiling enabled?
volatile cell sampling_profiler_p;
fixnum samples_per_second;
// Global variables used to pass fault handler state from signal handler
// to VM
bool signal_resumable;
cell signal_number;
cell signal_fault_addr;
cell signal_fault_pc;
unsigned int signal_fpu_status;
// Pipe used to notify Factor multiplexer of signals
int signal_pipe_input, signal_pipe_output;
// State kept by the sampling profiler
std::vector<profiling_sample> samples;
volatile profiling_sample current_sample;
// GC is off during heap walking
bool gc_off;
// Data heap
data_heap* data;
// Code heap
code_heap* code;
// Pinned callback stubs
callback_heap* callbacks;
// Only set if we're performing a GC
gc_state* current_gc;
volatile cell current_gc_p;
// Set if we're in the jit
volatile fixnum current_jit_count;
// Mark stack used for mark & sweep GC
std::vector<cell> mark_stack;
// If not NULL, we push GC events here
std::vector<gc_event>* gc_events;
// If a runtime function needs to call another function which potentially
// allocates memory, it must wrap any references to the data and code
// heaps with data_root and code_root smart pointers, which register
// themselves here. See data_roots.hpp and code_roots.hpp
std::vector<cell*> data_roots;
std::vector<code_root*> code_roots;
// Debugger
bool fep_p;
bool fep_help_was_shown;
bool fep_disabled;
bool full_output;
// Method dispatch statistics
dispatch_statistics dispatch_stats;
// Number of entries in a polymorphic inline cache
cell max_pic_size;
// Incrementing object counter for identity hashing
cell object_counter;
// Sanity check to ensure that monotonic counter doesn't decrease
uint64_t last_nano_count;
// Stack for signal handlers, only used on Unix
segment* signal_callstack_seg;
// Are we already handling a fault? Used to catch double memory faults
static bool fatal_erroring_p;
// Two fep_p variants, one might be redundant.
volatile cell safepoint_fep_p;
// Allow Ctrl-Break a busy loop in the Listener, only used on Windows
volatile bool stop_on_ctrl_break;
// contexts
context* new_context();
void init_context(context* ctx);
void delete_context();
cell begin_callback(cell quot);
void end_callback();
void primitive_current_callback();
void primitive_context_object();
void primitive_context_object_for();
void primitive_set_context_object();
cell stack_to_array(cell bottom, cell top, vm_error_type error);
cell datastack_to_array(context* ctx);
void primitive_datastack_for();
cell retainstack_to_array(context* ctx);
void primitive_retainstack_for();
void primitive_set_datastack();
void primitive_set_retainstack();
void primitive_check_datastack();
void primitive_load_locals();
// run
void primitive_exit();
void primitive_nano_count();
void primitive_sleep();
void primitive_set_slot();
// objects
void primitive_special_object();
void primitive_set_special_object();
void primitive_identity_hashcode();
void primitive_compute_identity_hashcode();
void primitive_clone();
void primitive_become();
// sampling_profiler
void record_sample(bool prolog_p);
void start_sampling_profiler(fixnum rate);
void end_sampling_profiler();
void set_sampling_profiler(fixnum rate);
void primitive_sampling_profiler();
void primitive_get_samples();
array* allot_growarr();
void growarr_add(array *growarr_, cell value);
// errors
void general_error(vm_error_type error, cell arg1, cell arg2);
void type_error(cell type, cell tagged);
void set_memory_protection_error(cell fault_addr, cell fault_pc);
void divide_by_zero_error();
// bignum
int bignum_equal_p(bignum* x, bignum* y);
enum bignum_comparison bignum_compare(bignum* x, bignum* y);
bignum* bignum_add(bignum* x, bignum* y);
bignum* bignum_subtract(bignum* x, bignum* y);
bignum* bignum_square(bignum* x_);
bignum* bignum_multiply(bignum* x, bignum* y);
void bignum_divide(bignum* numerator, bignum* denominator, bignum** quotient,
bignum** remainder);
bignum* bignum_quotient(bignum* numerator, bignum* denominator);
bignum* bignum_remainder(bignum* numerator, bignum* denominator);
fixnum bignum_to_fixnum_strict(bignum* bn);
bignum* double_to_bignum(double x);
int bignum_equal_p_unsigned(bignum* x, bignum* y);
enum bignum_comparison bignum_compare_unsigned(bignum* x, bignum* y);
bignum* bignum_add_unsigned(bignum* x_, bignum* y_, int negative_p);
bignum* bignum_subtract_unsigned(bignum* x_, bignum* y_);
bignum* bignum_multiply_unsigned(bignum* x_, bignum* y_, int negative_p);
bignum* bignum_multiply_unsigned_small_factor(bignum* x, bignum_digit_type y,
int negative_p);
void bignum_destructive_add(bignum* bn, bignum_digit_type n);
void bignum_destructive_scale_up(bignum* bn, bignum_digit_type factor);
void bignum_divide_unsigned_large_denominator(
bignum* numerator_, bignum* denominator_, bignum** quotient,
bignum** remainder, int q_negative_p, int r_negative_p);
void bignum_divide_unsigned_normalized(bignum* u, bignum* v, bignum* q);
bignum_digit_type bignum_divide_subtract(bignum_digit_type* v_start,
bignum_digit_type* v_end,
bignum_digit_type guess,
bignum_digit_type* u_start);
void bignum_divide_unsigned_medium_denominator(
bignum* numerator_, bignum_digit_type denominator, bignum** quotient,
bignum** remainder, int q_negative_p, int r_negative_p);
void bignum_destructive_normalization(bignum* source, bignum* target,
int shift_left);
void bignum_destructive_unnormalization(bignum* bn, int shift_right);
bignum_digit_type bignum_digit_divide(
bignum_digit_type uh, bignum_digit_type ul, bignum_digit_type v,
bignum_digit_type* q); // return value
bignum_digit_type bignum_digit_divide_subtract(bignum_digit_type v1,
bignum_digit_type v2,
bignum_digit_type guess,
bignum_digit_type* u);
void bignum_divide_unsigned_small_denominator(
bignum* numerator_, bignum_digit_type denominator, bignum** quotient,
bignum** remainder, int q_negative_p, int r_negative_p);
bignum_digit_type bignum_destructive_scale_down(
bignum* bn, bignum_digit_type denominator);
bignum* bignum_remainder_unsigned_small_denominator(bignum* n,
bignum_digit_type d,
int negative_p);
bignum* bignum_digit_to_bignum(bignum_digit_type digit, int negative_p);
bignum* allot_bignum(bignum_length_type length, int negative_p);
bignum* allot_bignum_zeroed(bignum_length_type length, int negative_p);
bignum* bignum_shorten_length(bignum* bn, bignum_length_type length);
bignum* bignum_trim(bignum* bn);
bignum* bignum_new_sign(bignum* x_, int negative_p);
bignum* bignum_maybe_new_sign(bignum* x_, int negative_p);
void bignum_destructive_copy(bignum* source, bignum* target);
bignum* bignum_bitwise_not(bignum* x_);
bignum* bignum_arithmetic_shift(bignum* arg1, fixnum n);
bignum* bignum_bitwise_and(bignum* arg1, bignum* arg2);
bignum* bignum_bitwise_ior(bignum* arg1, bignum* arg2);
bignum* bignum_bitwise_xor(bignum* arg1, bignum* arg2);
bignum* bignum_magnitude_ash(bignum* arg1_, fixnum n);
bignum* bignum_pospos_bitwise_op(int op, bignum* arg1_, bignum* arg2_);
bignum* bignum_posneg_bitwise_op(int op, bignum* arg1_, bignum* arg2_);
bignum* bignum_negneg_bitwise_op(int op, bignum* arg1_, bignum* arg2_);
void bignum_negate_magnitude(bignum* arg);
bignum* bignum_integer_length(bignum* x_);
int bignum_logbitp(int shift, bignum* arg);
int bignum_unsigned_logbitp(int shift, bignum* bn);
bignum* bignum_gcd(bignum* a_, bignum* b_);
//data heap
void set_data_heap(data_heap* data_);
void primitive_size();
data_heap_room data_room();
void primitive_data_room();
cell instances(cell type);
void primitive_all_instances();
template <typename Generation, typename Iterator>
inline void each_object(Generation* gen, Iterator& iterator) {
cell obj = gen->first_object();
while (obj) {
iterator((object*)obj);
obj = gen->next_object_after(obj);
}
}
template <typename Iterator> inline void each_object(Iterator& iterator) {
// The nursery can't be iterated because there may be gaps between
// the objects (see factor_vm::reallot_array) so we require it to
// be empty first.
FACTOR_ASSERT(data->nursery->occupied_space() == 0);
gc_off = true;
each_object(data->tenured, iterator);
each_object(data->aging, iterator);
gc_off = false;
}
template <typename Iterator>
inline void each_object_each_slot(Iterator& iterator) {
auto each_object_func = [&](object* obj) {
auto each_slot_func = [&](cell* slot) {
iterator(obj, slot);
};
obj->each_slot(each_slot_func);
};
each_object(each_object_func);
}
// the write barrier must be called any time we are potentially storing a
// pointer from an older generation to a younger one
inline void write_barrier(cell* slot_ptr) {
*(unsigned char*)(cards_offset + ((cell)slot_ptr >> card_bits)) = card_mark_mask;
*(unsigned char*)(decks_offset + ((cell)slot_ptr >> deck_bits)) = card_mark_mask;
}
inline void write_barrier(object* obj, cell size) {
cell start = (cell)obj & (~card_size + 1);
cell end = ((cell)obj + size + card_size - 1) & (~card_size + 1);
for (cell offset = start; offset < end; offset += card_size)
write_barrier((cell*)offset);
}
// data heap checker
void check_data_heap();
// gc
void set_current_gc_op(gc_op op);
void start_gc_again();
void collect_nursery();
void collect_aging();
void collect_to_tenured();
void update_code_roots_for_compaction();
void collect_mark_impl();
void collect_sweep_impl();
void collect_full();
void collect_compact_impl();
void collect_compact();
void collect_growing_data_heap(cell requested_size);
void gc(gc_op op, cell requested_size);
void primitive_minor_gc();
void primitive_full_gc();
void primitive_compact_gc();
void primitive_enable_gc_events();
void primitive_disable_gc_events();
object* allot_object(cell type, cell size);
object* allot_large_object(cell type, cell size);
// Allocates memory
template <typename Type> Type* allot(cell size) {
return (Type*)allot_object(Type::type_number, size);
}
// generic arrays
template <typename Array> Array* allot_uninitialized_array(cell capacity);
template <typename Array>
bool reallot_array_in_place_p(Array* array, cell capacity);
template <typename Array> Array* reallot_array(Array* array_, cell capacity);
// debug
void print_chars(ostream& out, string* str);
void print_word(ostream& out, word* word, cell nesting);
void print_factor_string(ostream& out, string* str);
void print_array(ostream& out, array* array, cell nesting);
void print_byte_array(ostream& out, byte_array* array, cell nesting);
void print_tuple(ostream& out, tuple* tuple, cell nesting);
void print_alien(ostream& out, alien* alien, cell nesting);
void print_nested_obj(ostream& out, cell obj, fixnum nesting);
void print_obj(ostream& out, cell obj);
void print_objects(ostream& out, cell* start, cell* end);
void print_datastack(ostream& out);
void print_retainstack(ostream& out);
void print_callstack(ostream& out);
void print_callstack_object(ostream& out, callstack* obj);
void dump_cell(ostream& out, cell x);
void dump_memory(ostream& out, cell from, cell to);
void dump_memory_layout(ostream& out);
void dump_objects(ostream& out, cell type);
void dump_edges(ostream& out);
void find_data_references(ostream& out, cell look_for_);
void dump_code_heap(ostream& out);
void factorbug_usage(bool advanced_p);
void factorbug();
void primitive_die();
void primitive_enable_ctrl_break();
void primitive_disable_ctrl_break();
// arrays
inline void set_array_nth(array* array, cell slot, cell value);
array* allot_array(cell capacity, cell fill_);
void primitive_array();
cell allot_array_4(cell v1_, cell v2_, cell v3_, cell v4_);
void primitive_resize_array();
cell std_vector_to_array(std::vector<cell>& elements);
// strings
string* allot_string_internal(cell capacity);
void fill_string(string* str_, cell start, cell capacity, cell fill);
string* allot_string(cell capacity, cell fill);
void primitive_string();
bool reallot_string_in_place_p(string* str, cell capacity);
string* reallot_string(string* str_, cell capacity);
void primitive_resize_string();
void primitive_set_string_nth_fast();
// booleans
cell tag_boolean(cell untagged) {
return untagged ? special_objects[OBJ_CANONICAL_TRUE] : false_object;
}
// byte arrays
byte_array* allot_byte_array(cell size);
void primitive_byte_array();
void primitive_uninitialized_byte_array();
void primitive_resize_byte_array();
template <typename Type> byte_array* byte_array_from_value(Type* value);
// tuples
void primitive_tuple();
void primitive_tuple_boa();
// words
word* allot_word(cell name_, cell vocab_, cell hashcode_);
void primitive_word();
void primitive_word_code();
void primitive_word_optimized_p();
void primitive_wrapper();
void jit_compile_word(cell word_, cell def_, bool relocating);
// math
void primitive_bignum_to_fixnum();
void primitive_bignum_to_fixnum_strict();
void primitive_float_to_fixnum();
void primitive_fixnum_divint();
void primitive_fixnum_divmod();
bignum* fixnum_to_bignum(fixnum);
bignum* cell_to_bignum(cell);
bignum* long_long_to_bignum(int64_t n);
bignum* ulong_long_to_bignum(uint64_t n);
inline fixnum sign_mask(fixnum x);
inline fixnum branchless_max(fixnum x, fixnum y);
inline fixnum branchless_abs(fixnum x);
void primitive_fixnum_shift();
void primitive_fixnum_to_bignum();
void primitive_float_to_bignum();
void primitive_bignum_eq();
void primitive_bignum_add();
void primitive_bignum_subtract();
void primitive_bignum_multiply();
void primitive_bignum_divint();
void primitive_bignum_divmod();
void primitive_bignum_mod();
void primitive_bignum_gcd();
void primitive_bignum_and();
void primitive_bignum_or();
void primitive_bignum_xor();
void primitive_bignum_shift();
void primitive_bignum_less();
void primitive_bignum_lesseq();
void primitive_bignum_greater();
void primitive_bignum_greatereq();
void primitive_bignum_not();
void primitive_bignum_bitp();
void primitive_bignum_log2();
inline cell unbox_array_size();
void primitive_fixnum_to_float();
void primitive_format_float();
void primitive_float_eq();
void primitive_float_add();
void primitive_float_subtract();
void primitive_float_multiply();
void primitive_float_divfloat();
void primitive_float_less();
void primitive_float_lesseq();
void primitive_float_greater();
void primitive_float_greatereq();
void primitive_float_bits();
void primitive_bits_float();
void primitive_double_bits();
void primitive_bits_double();
fixnum to_fixnum(cell tagged);
fixnum to_fixnum_strict(cell tagged);
cell to_cell(cell tagged);
cell from_signed_8(int64_t n);
int64_t to_signed_8(cell obj);
cell from_unsigned_8(uint64_t n);
uint64_t to_unsigned_8(cell obj);
float to_float(cell value);
double to_double(cell value);
inline void overflow_fixnum_add(fixnum x, fixnum y);
inline void overflow_fixnum_subtract(fixnum x, fixnum y);
inline void overflow_fixnum_multiply(fixnum x, fixnum y);
inline cell from_signed_cell(fixnum x);
inline cell from_unsigned_cell(cell x);
inline cell allot_float(double n);
inline bignum* float_to_bignum(cell tagged);
inline double untag_float(cell tagged);
inline double untag_float_check(cell tagged);
inline fixnum float_to_fixnum(cell tagged);
inline double fixnum_to_float(cell tagged);
// tagged
template <typename Type> void check_tagged(tagged<Type> t) {
if (!t.type_p())
type_error(Type::type_number, t.value_);
}
template <typename Type> Type* untag_check(cell value) {
tagged<Type> t(value);
check_tagged(t);
return t.untagged();
}
// io
void io_error_if_not_EINTR();
FILE* safe_fopen(char* filename, const char* mode);
int safe_fgetc(FILE* stream);
size_t safe_fread(void* ptr, size_t size, size_t nitems, FILE* stream);
void safe_fputc(int c, FILE* stream);
size_t safe_fwrite(void* ptr, size_t size, size_t nitems, FILE* stream);
int safe_ftell(FILE* stream);
void safe_fseek(FILE* stream, off_t offset, int whence);
void safe_fflush(FILE* stream);
void primitive_fopen();
FILE* pop_file_handle();
FILE* peek_file_handle();
void primitive_fgetc();
void primitive_fread();
void primitive_fputc();
void primitive_fwrite();
void primitive_ftell();
void primitive_fseek();
void primitive_fflush();
void primitive_fclose();
// code_block
cell compute_entry_point_pic_address(word* w, cell tagged_quot);
cell compute_entry_point_pic_address(cell w_);
cell compute_entry_point_pic_tail_address(cell w_);
cell compute_external_address(instruction_operand op);
void update_word_references(code_block* compiled, bool reset_inline_caches);
void undefined_symbol();
cell compute_dlsym_address(array* literals, cell index, bool toc);
cell lookup_external_address(relocation_type rel_type,
code_block* compiled,
array* parameters,
cell index);
void initialize_code_block(code_block* compiled, cell literals);
void initialize_code_block(code_block* compiled);
void fixup_labels(array* labels, code_block* compiled);
code_block* allot_code_block(cell size, code_block_type type);
code_block* add_code_block(code_block_type type, cell code_, cell labels_,
cell owner_, cell relocation_, cell parameters_,
cell literals_, cell frame_size_untagged);
//code heap
template <typename Iterator> void each_code_block(Iterator& iter) {
code->allocator->iterate(iter, no_fixup());
}
void update_code_heap_words(bool reset_inline_caches);
void primitive_modify_code_heap();
void primitive_code_room();
void primitive_strip_stack_traces();
void primitive_code_blocks();
// callbacks
void primitive_free_callback();
void primitive_callback();
void primitive_callback_room();
// image
void load_data_heap(FILE* file, image_header* h, vm_parameters* p);
void load_code_heap(FILE* file, image_header* h, vm_parameters* p);
bool save_image(const vm_char* saving_filename, const vm_char* filename);
void primitive_save_image();
void fixup_heaps(cell data_offset, cell code_offset);
void load_image(vm_parameters* p);
bool read_embedded_image_footer(FILE* file, embedded_image_footer* footer);
bool embedded_image_p();
template <typename Iterator, typename Fixup>
void iterate_callstack_object(callstack* stack_, Iterator& iterator,
Fixup& fixup);
template <typename Iterator>
void iterate_callstack_object(callstack* stack_, Iterator& iterator);
callstack* allot_callstack(cell size);
cell second_from_top_stack_frame(context* ctx);
cell capture_callstack(context* ctx);
void primitive_callstack_for();
void primitive_callstack_to_array();
void primitive_innermost_stack_frame_executing();
void primitive_innermost_stack_frame_scan();
void primitive_set_innermost_stack_frame_quotation();
template <typename Iterator, typename Fixup>
void iterate_callstack(context* ctx, Iterator& iterator, Fixup& fixup);
template <typename Iterator>
void iterate_callstack(context* ctx, Iterator& iterator);
// cpu-*
void dispatch_signal_handler(cell* sp, cell* pc, cell newpc);
#if defined(FACTOR_X86) || defined(FACTOR_64)
void dispatch_non_resumable_signal(cell* sp, cell* pc,
cell handler,
cell limit);
void dispatch_resumable_signal(cell* sp, cell* pc, cell handler);
#endif
// alien
char* pinned_alien_offset(cell obj);
cell allot_alien(cell delegate_, cell displacement);
cell allot_alien(cell address);
void primitive_displaced_alien();
void primitive_alien_address();
void* alien_pointer();
void primitive_dlopen();
void primitive_dlsym();
void primitive_dlsym_raw();
void primitive_dlclose();
void primitive_dll_validp();
char* alien_offset(cell obj);
// quotations
void primitive_jit_compile();
cell lazy_jit_compile_entry_point();
void primitive_array_to_quotation();
void primitive_quotation_code();
code_block* jit_compile_quotation(cell owner_, cell quot_, bool relocating);
void jit_compile_quotation(cell quot_, bool relocating);
fixnum quot_code_offset_to_scan(cell quot_, cell offset);
cell lazy_jit_compile(cell quot);
bool quotation_compiled_p(quotation* quot);
void primitive_quotation_compiled_p();
// dispatch
cell lookup_tuple_method(cell obj, cell methods);
cell lookup_method(cell obj, cell methods);
void primitive_lookup_method();
cell object_class(cell obj);
void update_method_cache(cell cache, cell klass, cell method);
void primitive_mega_cache_miss();
void primitive_reset_dispatch_stats();
void primitive_dispatch_stats();
// inline cache
void deallocate_inline_cache(cell return_address);
void update_pic_count(cell type);
cell add_inline_cache_entry(cell cache_entries_, cell klass_, cell method_);
void update_pic_transitions(cell pic_size);
cell inline_cache_miss(cell return_address);
// entry points
void c_to_factor(cell quot);
void unwind_native_frames(cell quot, cell to);
cell get_fpu_state();
void set_fpu_state(cell state);
// safepoints
void handle_safepoint(cell pc);
void enqueue_samples(cell samples, cell pc, bool foreign_thread_p);
void enqueue_fep();
// factor
void prepare_boot_image();
void init_factor(vm_parameters* p);
void pass_args_to_factor(int argc, vm_char** argv);
void stop_factor();
void start_standalone_factor(int argc, vm_char** argv);
char* factor_eval_string(char* string);
void factor_eval_free(char* result);
void factor_yield();
void factor_sleep(long us);
// os-*
void primitive_existsp();
void init_ffi();
void ffi_dlopen(dll* dll);
cell ffi_dlsym(dll* dll, symbol_char* symbol);
cell ffi_dlsym_raw(dll* dll, symbol_char* symbol);
void ffi_dlclose(dll* dll);
void c_to_factor_toplevel(cell quot);
void init_signals();
void start_sampling_profiler_timer();
void end_sampling_profiler_timer();
// os-windows
#if defined(WINDOWS)
/* Id of the main thread we run in. Used for Ctrl-Break handling. */
DWORD thread_id;
HANDLE ctrl_break_thread;
HANDLE sampler_thread;
void sampler_thread_loop();
const vm_char* vm_executable_path();
const vm_char* default_image_path();
BOOL windows_stat(vm_char* path);
LONG exception_handler(PEXCEPTION_RECORD e, void* frame, PCONTEXT c,
void* dispatch);
#else // UNIX
void dispatch_signal(void* uap, void(handler)());
void unix_init_signals();
#endif
#ifdef __APPLE__
void call_fault_handler(exception_type_t exception,
exception_data_type_t code,
MACH_EXC_STATE_TYPE* exc_state,
MACH_THREAD_STATE_TYPE* thread_state,
MACH_FLOAT_STATE_TYPE* float_state);
#endif
factor_vm(THREADHANDLE thread_id);
~factor_vm();
};
}