/* ScummVM - Graphic Adventure Engine * * ScummVM is the legal property of its developers, whose names * are too numerous to list here. Please refer to the COPYRIGHT * file distributed with this source distribution. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. * * $URL$ * $Id$ * */ #include "sci/engine/gc.h" namespace Sci { #define WORKLIST_CHUNK_SIZE 32 //#define DEBUG_GC //#define DEBUG_GC_VERBOSE typedef struct _worklist { int used; reg_t entries[WORKLIST_CHUNK_SIZE]; struct _worklist *next; } worklist_t; static worklist_t *fresh_worklist(worklist_t *old) { worklist_t *retval = (worklist_t*)sci_malloc(sizeof(worklist_t)); retval->used = 0; retval->next = old; return retval; } static worklist_t *new_worklist() { return fresh_worklist(NULL); } static void worklist_push(worklist_t **wlp, reg_t_hash_map *hashmap, reg_t reg) { worklist_t *wl = *wlp; if (!reg.segment) // No numbers return; #ifdef DEBUG_GC_VERBOSE sciprintf("[GC] Adding "PREG"\n", PRINT_REG(reg)); #endif if (hashmap->contains(reg)) return; // already dealt with it hashmap->setVal(reg, true); if (!wl || wl->used == WORKLIST_CHUNK_SIZE) *wlp = wl = fresh_worklist(wl); wl->entries[wl->used++] = reg; } static int worklist_has_next(worklist_t *wl) { return (wl && wl->used); } static reg_t worklist_pop(worklist_t **wlp) { worklist_t *wl = *wlp; reg_t retval; if (!wl || !wl->used) { error("Attempt to pop from empty worklist"); exit(1); } retval = wl->entries[--wl->used]; if (!wl->used) { *wlp = wl->next; free(wl); } return retval; } static void free_worklist(worklist_t *wl) { if (wl) { if (wl->next) free_worklist(wl->next); free(wl); } } static reg_t_hash_map * normalise_hashmap_ptrs(reg_t_hash_map *nonnormal_map, seg_interface_t **interfaces, int interfaces_nr) { reg_t_hash_map *normal_map = new reg_t_hash_map(); for (reg_t_hash_map::iterator i = nonnormal_map->begin(); i != nonnormal_map->end(); ++i) { seg_interface_t *interfce; reg_t reg = i->_key; interfce = (reg.segment < interfaces_nr) ? interfaces[reg.segment] : NULL; if (interfce) { reg = interfce->find_canonic_address(interfce, reg); normal_map->setVal(reg, true); } } return normal_map; } typedef struct { reg_t_hash_map *nonnormal_map; worklist_t **worklist_ref; } worklist_manager_t; void add_outgoing_refs(void *pre_wm, reg_t addr) { worklist_manager_t *wm = (worklist_manager_t *) pre_wm; worklist_push(wm->worklist_ref, wm->nonnormal_map, addr); } reg_t_hash_map *find_all_used_references(EngineState *s) { SegManager *sm = &(s->seg_manager); seg_interface_t **interfaces = (seg_interface_t**)sci_calloc(sizeof(seg_interface_t *), sm->heap_size); reg_t_hash_map *nonnormal_map = new reg_t_hash_map(); reg_t_hash_map *normal_map = NULL; worklist_t *worklist = new_worklist(); worklist_manager_t worklist_manager; int i; worklist_manager.worklist_ref = &worklist; worklist_manager.nonnormal_map = nonnormal_map; for (i = 1; i < sm->heap_size; i++) if (sm->heap[i] == NULL) interfaces[i] = NULL; else interfaces[i] = get_seg_interface(sm, i); // Initialise // Init: Registers worklist_push(&worklist, nonnormal_map, s->r_acc); worklist_push(&worklist, nonnormal_map, s->r_prev); // Init: Value Stack // We do this one by hand since the stack doesn't know the current execution stack { exec_stack_t *xs = s->execution_stack + s->execution_stack_pos; reg_t *pos; for (pos = s->stack_base; pos < xs->sp; pos++) worklist_push(&worklist, nonnormal_map, *pos); } #ifdef DEBUG_GC_VERBOSE sciprintf("[GC] -- Finished adding value stack"); #endif // Init: Execution Stack for (i = 0; i <= s->execution_stack_pos; i++) { exec_stack_t *es = s->execution_stack + i; if (es->type != EXEC_STACK_TYPE_KERNEL) { worklist_push(&worklist, nonnormal_map, es->objp); worklist_push(&worklist, nonnormal_map, es->sendp); if (es->type == EXEC_STACK_TYPE_VARSELECTOR) worklist_push(&worklist, nonnormal_map, *(es->addr.varp)); } } #ifdef DEBUG_GC_VERBOSE sciprintf("[GC] -- Finished adding execution stack"); #endif // Init: Explicitly loaded scripts for (i = 1; i < sm->heap_size; i++) if (interfaces[i] && interfaces[i]->type_id == MEM_OBJ_SCRIPT) { script_t *script = &(interfaces[i]->mobj->data.script); if (script->lockers) { // Explicitly loaded? int obj_nr; // Locals, if present worklist_push(&worklist, nonnormal_map, make_reg(script->locals_segment, 0)); // All objects (may be classes, may be indirectly reachable) for (obj_nr = 0; obj_nr < script->objects_nr; obj_nr++) { object_t *obj = script->objects + obj_nr; worklist_push(&worklist, nonnormal_map, obj->pos); } } } #ifdef DEBUG_GC_VERBOSE sciprintf("[GC] -- Finished explicitly loaded scripts, done with root set"); #endif // Run Worklist Algorithm while (worklist_has_next(worklist)) { reg_t reg = worklist_pop(&worklist); if (reg.segment != s->stack_segment) { // No need to repeat this one #ifdef DEBUG_GC_VERBOSE sciprintf("[GC] Checking "PREG"\n", PRINT_REG(reg)); #endif if (reg.segment < sm->heap_size && interfaces[reg.segment]) interfaces[reg.segment]->list_all_outgoing_references(interfaces[reg.segment], s, reg, &worklist_manager, add_outgoing_refs); } } // Normalise normal_map = normalise_hashmap_ptrs(nonnormal_map, interfaces, sm->heap_size); // Cleanup for (i = 1; i < sm->heap_size; i++) if (interfaces[i]) interfaces[i]->deallocate_self(interfaces[i]); free(interfaces); delete nonnormal_map; return normal_map; } typedef struct { seg_interface_t *interfce; #ifdef DEBUG_GC char *segnames[MEM_OBJ_MAX + 1]; int segcount[MEM_OBJ_MAX + 1]; #endif reg_t_hash_map *use_map; } deallocator_t; void free_unless_used(void *pre_use_map, reg_t addr) { deallocator_t *deallocator = (deallocator_t *)pre_use_map; reg_t_hash_map *use_map = deallocator->use_map; if (!use_map->contains(addr)) { // Not found -> we can free it deallocator->interfce->free_at_address(deallocator->interfce, addr); #ifdef DEBUG_GC sciprintf("[GC] Deallocating "PREG"\n", PRINT_REG(addr)); deallocator->segcount[deallocator->interfce->type_id]++; #endif } } void run_gc(EngineState *s) { int seg_nr; deallocator_t deallocator; SegManager *sm = &(s->seg_manager); #ifdef DEBUG_GC c_segtable(s); sciprintf("[GC] Running...\n"); memset(&(deallocator.segcount), 0, sizeof(int) * (MEM_OBJ_MAX + 1)); #endif deallocator.use_map = find_all_used_references(s); for (seg_nr = 1; seg_nr < sm->heap_size; seg_nr++) { if (sm->heap[seg_nr] != NULL) { deallocator.interfce = get_seg_interface(sm, seg_nr); #ifdef DEBUG_GC deallocator.segnames[deallocator.interfce->type_id] = deallocator.interfce->type; #endif deallocator.interfce->list_all_deallocatable(deallocator.interfce, &deallocator, free_unless_used); deallocator.interfce->deallocate_self(deallocator.interfce); } } delete deallocator.use_map; #ifdef DEBUG_GC { int i; sciprintf("[GC] Summary:\n"); for (i = 0; i <= MEM_OBJ_MAX; i++) if (deallocator.segcount[i]) sciprintf("\t%d\t* %s\n", deallocator.segcount[i], deallocator.segnames[i]); } #endif } } // End of namespace Sci