mirror of
https://github.com/DarkFlippers/unleashed-firmware.git
synced 2024-12-25 14:22:27 +03:00
0154018363
* FBT: cdefines to env, libs order * API: strtod, modf, itoa, calloc * Apps: elk js * Apps: mjs * JS: scripts as assets * mjs: composite resolver * mjs: stack trace * ELK JS example removed * MJS thread, MJS lib modified to support script interruption * JS console UI * Module system, BadUSB bindings rework * JS notifications, simple dialog, BadUSB demo * Custom dialogs, dialog demo * MJS as system library, some dirty hacks to make it compile * Plugin-based js modules * js_uart(BadUART) module * js_uart: support for byte array arguments * Script icon and various fixes * File browser: multiple extensions filter, running js scripts from app loader * Running js scripts from archive browser * JS Runner as system app * Example scripts moved to /ext/apps/Scripts * JS bytecode listing generation * MJS builtin printf cleanup * JS examples cleanup * mbedtls version fix * Unused lib cleanup * Making PVS happy & TODOs cleanup * TODOs cleanup #2 * MJS: initial typed arrays support * JS: fix mem leak in uart destructor Co-authored-by: SG <who.just.the.doctor@gmail.com> Co-authored-by: Aleksandr Kutuzov <alleteam@gmail.com>
536 lines
15 KiB
C
536 lines
15 KiB
C
/*
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* Copyright (c) 2014 Cesanta Software Limited
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* All rights reserved
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*/
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#include <stdio.h>
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#include "common/cs_varint.h"
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#include "common/mbuf.h"
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#include "mjs_core.h"
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#include "mjs_ffi.h"
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#include "mjs_gc.h"
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#include "mjs_internal.h"
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#include "mjs_object.h"
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#include "mjs_primitive.h"
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#include "mjs_string.h"
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/*
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* Macros for marking reachable things: use bit 0.
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*/
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#define MARK(p) (((struct gc_cell*)(p))->head.word |= 1)
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#define UNMARK(p) (((struct gc_cell*)(p))->head.word &= ~1)
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#define MARKED(p) (((struct gc_cell*)(p))->head.word & 1)
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/*
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* Similar to `MARK()` / `UNMARK()` / `MARKED()`, but `.._FREE` counterparts
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* are intended to mark free cells (as opposed to used ones), so they use
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* bit 1.
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*/
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#define MARK_FREE(p) (((struct gc_cell*)(p))->head.word |= 2)
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#define UNMARK_FREE(p) (((struct gc_cell*)(p))->head.word &= ~2)
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#define MARKED_FREE(p) (((struct gc_cell*)(p))->head.word & 2)
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/*
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* When each arena has that or less free cells, GC will be scheduled
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*/
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#define GC_ARENA_CELLS_RESERVE 2
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static struct gc_block* gc_new_block(struct gc_arena* a, size_t size);
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static void gc_free_block(struct gc_block* b);
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static void gc_mark_mbuf_pt(struct mjs* mjs, const struct mbuf* mbuf);
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MJS_PRIVATE struct mjs_object* new_object(struct mjs* mjs) {
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return (struct mjs_object*)gc_alloc_cell(mjs, &mjs->object_arena);
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}
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MJS_PRIVATE struct mjs_property* new_property(struct mjs* mjs) {
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return (struct mjs_property*)gc_alloc_cell(mjs, &mjs->property_arena);
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}
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MJS_PRIVATE struct mjs_ffi_sig* new_ffi_sig(struct mjs* mjs) {
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return (struct mjs_ffi_sig*)gc_alloc_cell(mjs, &mjs->ffi_sig_arena);
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}
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/* Initializes a new arena. */
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MJS_PRIVATE void gc_arena_init(
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struct gc_arena* a,
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size_t cell_size,
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size_t initial_size,
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size_t size_increment) {
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assert(cell_size >= sizeof(uintptr_t));
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memset(a, 0, sizeof(*a));
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a->cell_size = cell_size;
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a->size_increment = size_increment;
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a->blocks = gc_new_block(a, initial_size);
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}
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MJS_PRIVATE void gc_arena_destroy(struct mjs* mjs, struct gc_arena* a) {
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struct gc_block* b;
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if(a->blocks != NULL) {
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gc_sweep(mjs, a, 0);
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for(b = a->blocks; b != NULL;) {
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struct gc_block* tmp;
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tmp = b;
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b = b->next;
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gc_free_block(tmp);
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}
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}
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}
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static void gc_free_block(struct gc_block* b) {
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free(b->base);
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free(b);
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}
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static struct gc_block* gc_new_block(struct gc_arena* a, size_t size) {
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struct gc_cell* cur;
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struct gc_block* b;
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b = (struct gc_block*)calloc(1, sizeof(*b));
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if(b == NULL) abort();
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b->size = size;
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b->base = (struct gc_cell*)calloc(a->cell_size, b->size);
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if(b->base == NULL) abort();
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for(cur = GC_CELL_OP(a, b->base, +, 0); cur < GC_CELL_OP(a, b->base, +, b->size);
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cur = GC_CELL_OP(a, cur, +, 1)) {
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cur->head.link = a->free;
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a->free = cur;
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}
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return b;
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}
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/*
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* Returns whether the given arena has GC_ARENA_CELLS_RESERVE or less free
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* cells
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*/
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static int gc_arena_is_gc_needed(struct gc_arena* a) {
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struct gc_cell* r = a->free;
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int i;
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for(i = 0; i <= GC_ARENA_CELLS_RESERVE; i++, r = r->head.link) {
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if(r == NULL) {
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return 1;
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}
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}
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return 0;
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}
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MJS_PRIVATE int gc_strings_is_gc_needed(struct mjs* mjs) {
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struct mbuf* m = &mjs->owned_strings;
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return (double)m->len / (double)m->size > (double)0.9;
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}
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MJS_PRIVATE void* gc_alloc_cell(struct mjs* mjs, struct gc_arena* a) {
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struct gc_cell* r;
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if(a->free == NULL) {
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struct gc_block* b = gc_new_block(a, a->size_increment);
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b->next = a->blocks;
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a->blocks = b;
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}
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r = a->free;
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UNMARK(r);
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a->free = r->head.link;
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#if MJS_MEMORY_STATS
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a->allocations++;
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a->alive++;
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#endif
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/* Schedule GC if needed */
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if(gc_arena_is_gc_needed(a)) {
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mjs->need_gc = 1;
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}
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/*
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* TODO(mkm): minor opt possible since most of the fields
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* are overwritten downstream, but not worth the yak shave time
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* when fields are added to GC-able structures */
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memset(r, 0, a->cell_size);
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return (void*)r;
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}
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/*
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* Scans the arena and add all unmarked cells to the free list.
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*
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* Empty blocks get deallocated. The head of the free list will contais cells
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* from the last (oldest) block. Cells will thus be allocated in block order.
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*/
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void gc_sweep(struct mjs* mjs, struct gc_arena* a, size_t start) {
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struct gc_block* b;
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struct gc_cell* cur;
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struct gc_block** prevp = &a->blocks;
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#if MJS_MEMORY_STATS
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a->alive = 0;
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#endif
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/*
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* Before we sweep, we should mark all free cells in a way that is
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* distinguishable from marked used cells.
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*/
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{
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struct gc_cell* next;
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for(cur = a->free; cur != NULL; cur = next) {
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next = cur->head.link;
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MARK_FREE(cur);
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}
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}
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/*
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* We'll rebuild the whole `free` list, so initially we just reset it
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*/
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a->free = NULL;
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for(b = a->blocks; b != NULL;) {
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size_t freed_in_block = 0;
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/*
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* if it turns out that this block is 100% garbage
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* we can release the whole block, but the addition
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* of it's cells to the free list has to be undone.
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*/
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struct gc_cell* prev_free = a->free;
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for(cur = GC_CELL_OP(a, b->base, +, start); cur < GC_CELL_OP(a, b->base, +, b->size);
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cur = GC_CELL_OP(a, cur, +, 1)) {
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if(MARKED(cur)) {
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/* The cell is used and marked */
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UNMARK(cur);
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#if MJS_MEMORY_STATS
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a->alive++;
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#endif
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} else {
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/*
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* The cell is either:
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* - free
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* - garbage that's about to be freed
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*/
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if(MARKED_FREE(cur)) {
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/* The cell is free, so, just unmark it */
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UNMARK_FREE(cur);
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} else {
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/*
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* The cell is used and should be freed: call the destructor and
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* reset the memory
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*/
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if(a->destructor != NULL) {
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a->destructor(mjs, cur);
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}
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memset(cur, 0, a->cell_size);
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}
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/* Add this cell to the `free` list */
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cur->head.link = a->free;
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a->free = cur;
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freed_in_block++;
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#if MJS_MEMORY_STATS
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a->garbage++;
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#endif
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}
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}
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/*
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* don't free the initial block, which is at the tail
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* because it has a special size aimed at reducing waste
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* and simplifying initial startup. TODO(mkm): improve
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* */
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if(b->next != NULL && freed_in_block == b->size) {
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*prevp = b->next;
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gc_free_block(b);
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b = *prevp;
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a->free = prev_free;
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} else {
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prevp = &b->next;
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b = b->next;
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}
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}
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}
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/* Mark an FFI signature */
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static void gc_mark_ffi_sig(struct mjs* mjs, mjs_val_t* v) {
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struct mjs_ffi_sig* psig;
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assert(mjs_is_ffi_sig(*v));
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psig = mjs_get_ffi_sig_struct(*v);
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/*
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* we treat all object like things like objects but they might be functions,
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* gc_check_val checks the appropriate arena per actual value type.
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*/
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if(!gc_check_val(mjs, *v)) {
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abort();
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}
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if(MARKED(psig)) return;
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MARK(psig);
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}
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/* Mark an object */
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static void gc_mark_object(struct mjs* mjs, mjs_val_t* v) {
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struct mjs_object* obj_base;
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struct mjs_property* prop;
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struct mjs_property* next;
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assert(mjs_is_object_based(*v));
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obj_base = get_object_struct(*v);
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/*
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* we treat all object like things like objects but they might be functions,
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* gc_check_val checks the appropriate arena per actual value type.
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*/
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if(!gc_check_val(mjs, *v)) {
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abort();
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}
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if(MARKED(obj_base)) return;
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/* mark object itself, and its properties */
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for((prop = obj_base->properties), MARK(obj_base); prop != NULL; prop = next) {
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if(!gc_check_ptr(&mjs->property_arena, prop)) {
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abort();
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}
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gc_mark(mjs, &prop->name);
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gc_mark(mjs, &prop->value);
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next = prop->next;
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MARK(prop);
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}
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/* mark object's prototype */
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/*
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* We dropped support for object prototypes in MJS.
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* If we ever bring it back, don't forget to mark it
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*/
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/* gc_mark(mjs, mjs_get_proto(mjs, v)); */
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}
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/* Mark a string value */
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static void gc_mark_string(struct mjs* mjs, mjs_val_t* v) {
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mjs_val_t h, tmp = 0;
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char* s;
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/* clang-format off */
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/*
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* If a value points to an unmarked string we shall:
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* 1. save the first 6 bytes of the string
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* since we need to be able to distinguish real values from
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* the saved first 6 bytes of the string, we need to tag the chunk
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* as MJS_TAG_STRING_C
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* 2. encode value's address (v) into the first 6 bytes of the string.
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* 3. put the saved 8 bytes (tag + chunk) back into the value.
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* 4. mark the string by putting '\1' in the NUL terminator of the previous
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* string chunk.
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*
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* If a value points to an already marked string we shall:
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* (0, <6 bytes of a pointer to a mjs_val_t>), hence we have to skip
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* the first byte. We tag the value pointer as a MJS_TAG_FOREIGN
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* so that it won't be followed during recursive mark.
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*
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* ... the rest is the same
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*
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* Note: 64-bit pointers can be represented with 48-bits
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*/
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/* clang-format on */
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assert((*v & MJS_TAG_MASK) == MJS_TAG_STRING_O);
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s = mjs->owned_strings.buf + gc_string_mjs_val_to_offset(*v);
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assert(s < mjs->owned_strings.buf + mjs->owned_strings.len);
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if(s[-1] == '\0') {
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memcpy(&tmp, s, sizeof(tmp) - 2);
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tmp |= MJS_TAG_STRING_C;
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} else {
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memcpy(&tmp, s, sizeof(tmp) - 2);
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tmp |= MJS_TAG_FOREIGN;
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}
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h = (mjs_val_t)(uintptr_t)v;
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s[-1] = 1;
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memcpy(s, &h, sizeof(h) - 2);
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memcpy(v, &tmp, sizeof(tmp));
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}
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MJS_PRIVATE void gc_mark(struct mjs* mjs, mjs_val_t* v) {
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if(mjs_is_object_based(*v)) {
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gc_mark_object(mjs, v);
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}
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if(mjs_is_ffi_sig(*v)) {
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gc_mark_ffi_sig(mjs, v);
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}
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if((*v & MJS_TAG_MASK) == MJS_TAG_STRING_O) {
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gc_mark_string(mjs, v);
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}
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}
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MJS_PRIVATE uint64_t gc_string_mjs_val_to_offset(mjs_val_t v) {
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return (((uint64_t)(uintptr_t)get_ptr(v)) & ~MJS_TAG_MASK);
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}
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MJS_PRIVATE mjs_val_t gc_string_val_from_offset(uint64_t s) {
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return s | MJS_TAG_STRING_O;
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}
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void gc_compact_strings(struct mjs* mjs) {
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char* p = mjs->owned_strings.buf + 1;
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uint64_t h, next, head = 1;
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int len, llen;
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while(p < mjs->owned_strings.buf + mjs->owned_strings.len) {
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if(p[-1] == '\1') {
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/* relocate and update ptrs */
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h = 0;
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memcpy(&h, p, sizeof(h) - 2);
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/*
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* relocate pointers until we find the tail.
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* The tail is marked with MJS_TAG_STRING_C,
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* while mjs_val_t link pointers are tagged with MJS_TAG_FOREIGN
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*/
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for(; (h & MJS_TAG_MASK) != MJS_TAG_STRING_C; h = next) {
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h &= ~MJS_TAG_MASK;
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memcpy(&next, (char*)(uintptr_t)h, sizeof(h));
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*(mjs_val_t*)(uintptr_t)h = gc_string_val_from_offset(head);
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}
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h &= ~MJS_TAG_MASK;
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/*
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* the tail contains the first 6 bytes we stole from
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* the actual string.
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*/
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len = cs_varint_decode_unsafe((unsigned char*)&h, &llen);
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len += llen + 1;
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/*
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* restore the saved 6 bytes
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* TODO(mkm): think about endianness
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*/
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memcpy(p, &h, sizeof(h) - 2);
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/*
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* and relocate the string data by packing it to the left.
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*/
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memmove(mjs->owned_strings.buf + head, p, len);
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mjs->owned_strings.buf[head - 1] = 0x0;
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p += len;
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head += len;
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} else {
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len = cs_varint_decode_unsafe((unsigned char*)p, &llen);
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len += llen + 1;
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p += len;
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}
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}
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mjs->owned_strings.len = head;
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}
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MJS_PRIVATE int maybe_gc(struct mjs* mjs) {
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if(!mjs->inhibit_gc) {
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mjs_gc(mjs, 0);
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return 1;
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}
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return 0;
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}
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/*
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* mark an array of `mjs_val_t` values (*not pointers* to them)
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*/
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static void gc_mark_val_array(struct mjs* mjs, mjs_val_t* vals, size_t len) {
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mjs_val_t* vp;
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for(vp = vals; vp < vals + len; vp++) {
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gc_mark(mjs, vp);
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}
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}
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/*
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* mark an mbuf containing *pointers* to `mjs_val_t` values
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*/
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static void gc_mark_mbuf_pt(struct mjs* mjs, const struct mbuf* mbuf) {
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mjs_val_t** vp;
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for(vp = (mjs_val_t**)mbuf->buf; (char*)vp < mbuf->buf + mbuf->len; vp++) {
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gc_mark(mjs, *vp);
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}
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}
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/*
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* mark an mbuf containing `mjs_val_t` values (*not pointers* to them)
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*/
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static void gc_mark_mbuf_val(struct mjs* mjs, const struct mbuf* mbuf) {
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gc_mark_val_array(mjs, (mjs_val_t*)mbuf->buf, mbuf->len / sizeof(mjs_val_t));
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}
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static void gc_mark_ffi_cbargs_list(struct mjs* mjs, ffi_cb_args_t* cbargs) {
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for(; cbargs != NULL; cbargs = cbargs->next) {
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gc_mark(mjs, &cbargs->func);
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gc_mark(mjs, &cbargs->userdata);
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}
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}
|
|
|
|
/* Perform garbage collection */
|
|
void mjs_gc(struct mjs* mjs, int full) {
|
|
gc_mark_val_array(mjs, (mjs_val_t*)&mjs->vals, sizeof(mjs->vals) / sizeof(mjs_val_t));
|
|
|
|
gc_mark_mbuf_pt(mjs, &mjs->owned_values);
|
|
gc_mark_mbuf_val(mjs, &mjs->scopes);
|
|
gc_mark_mbuf_val(mjs, &mjs->stack);
|
|
gc_mark_mbuf_val(mjs, &mjs->call_stack);
|
|
|
|
gc_mark_ffi_cbargs_list(mjs, mjs->ffi_cb_args);
|
|
|
|
gc_compact_strings(mjs);
|
|
|
|
gc_sweep(mjs, &mjs->object_arena, 0);
|
|
gc_sweep(mjs, &mjs->property_arena, 0);
|
|
gc_sweep(mjs, &mjs->ffi_sig_arena, 0);
|
|
|
|
if(full) {
|
|
/*
|
|
* In case of full GC, we also resize strings buffer, but we still leave
|
|
* some extra space (at most, `_MJS_STRING_BUF_RESERVE`) in order to avoid
|
|
* frequent reallocations
|
|
*/
|
|
size_t trimmed_size = mjs->owned_strings.len + _MJS_STRING_BUF_RESERVE;
|
|
if(trimmed_size < mjs->owned_strings.size) {
|
|
mbuf_resize(&mjs->owned_strings, trimmed_size);
|
|
}
|
|
}
|
|
}
|
|
|
|
MJS_PRIVATE int gc_check_val(struct mjs* mjs, mjs_val_t v) {
|
|
if(mjs_is_object_based(v)) {
|
|
return gc_check_ptr(&mjs->object_arena, get_object_struct(v));
|
|
}
|
|
if(mjs_is_ffi_sig(v)) {
|
|
return gc_check_ptr(&mjs->ffi_sig_arena, mjs_get_ffi_sig_struct(v));
|
|
}
|
|
return 1;
|
|
}
|
|
|
|
MJS_PRIVATE int gc_check_ptr(const struct gc_arena* a, const void* ptr) {
|
|
const struct gc_cell* p = (const struct gc_cell*)ptr;
|
|
struct gc_block* b;
|
|
for(b = a->blocks; b != NULL; b = b->next) {
|
|
if(p >= b->base && p < GC_CELL_OP(a, b->base, +, b->size)) {
|
|
return 1;
|
|
}
|
|
}
|
|
return 0;
|
|
}
|