/* 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. * */ #include "sci/sci.h" #include "sci/engine/seg_manager.h" #include "sci/engine/state.h" #include "sci/engine/script.h" namespace Sci { SegManager::SegManager(ResourceManager *resMan) { _heap.push_back(0); _clonesSegId = 0; _listsSegId = 0; _nodesSegId = 0; _hunksSegId = 0; #ifdef ENABLE_SCI32 _arraysSegId = 0; _stringSegId = 0; #endif _resMan = resMan; createClassTable(); } SegManager::~SegManager() { resetSegMan(); } void SegManager::resetSegMan() { // Free memory for (uint i = 0; i < _heap.size(); i++) { if (_heap[i]) deallocate(i); } _heap.clear(); // And reinitialize _heap.push_back(0); _clonesSegId = 0; _listsSegId = 0; _nodesSegId = 0; _hunksSegId = 0; #ifdef ENABLE_SCI32 _arraysSegId = 0; _stringSegId = 0; #endif // Reinitialize class table _classTable.clear(); createClassTable(); } void SegManager::initSysStrings() { if (getSciVersion() <= SCI_VERSION_1_1) { // We need to allocate system strings in one segment, for compatibility reasons allocDynmem(512, "system strings", &_saveDirPtr); _parserPtr = make_reg(_saveDirPtr.segment, _saveDirPtr.offset + 256); #ifdef ENABLE_SCI32 } else { SciString *saveDirString = allocateString(&_saveDirPtr); saveDirString->setSize(256); saveDirString->setValue(0, 0); _parserPtr = NULL_REG; // no SCI2 game had a parser #endif } } SegmentId SegManager::findFreeSegment() const { // The following is a very crude approach: We find a free segment id by // scanning from the start. This can be slow if the number of segments // becomes large. Optimizations are possible and easy, but I'll refrain // from attempting any until we determine we actually need it. uint seg = 1; while (seg < _heap.size() && _heap[seg]) { ++seg; } assert(seg < 65536); return seg; } SegmentObj *SegManager::allocSegment(SegmentObj *mem, SegmentId *segid) { // Find a free segment SegmentId id = findFreeSegment(); if (segid) *segid = id; if (!mem) error("SegManager: invalid mobj"); // ... and put it into the (formerly) free segment. if (id >= (int)_heap.size()) { assert(id == (int)_heap.size()); _heap.push_back(0); } _heap[id] = mem; return mem; } Script *SegManager::allocateScript(int script_nr, SegmentId *segid) { // Check if the script already has an allocated segment. If it // does, return that segment. *segid = _scriptSegMap.getVal(script_nr, 0); if (*segid > 0) { return (Script *)_heap[*segid]; } // allocate the SegmentObj SegmentObj *mem = allocSegment(new Script(), segid); // Add the script to the "script id -> segment id" hashmap _scriptSegMap[script_nr] = *segid; return (Script *)mem; } void SegManager::deallocate(SegmentId seg) { if (!check(seg)) error("SegManager::deallocate(): invalid segment ID"); SegmentObj *mobj = _heap[seg]; if (mobj->getType() == SEG_TYPE_SCRIPT) { Script *scr = (Script *)mobj; _scriptSegMap.erase(scr->getScriptNumber()); if (scr->getLocalsSegment()) deallocate(scr->getLocalsSegment()); } delete mobj; _heap[seg] = NULL; } bool SegManager::isHeapObject(reg_t pos) const { const Object *obj = getObject(pos); if (obj == NULL || (obj && obj->isFreed())) return false; Script *scr = getScriptIfLoaded(pos.segment); return !(scr && scr->isMarkedAsDeleted()); } void SegManager::deallocateScript(int script_nr) { deallocate(getScriptSegment(script_nr)); } Script *SegManager::getScript(const SegmentId seg) { if (seg < 1 || (uint)seg >= _heap.size()) { error("SegManager::getScript(): seg id %x out of bounds", seg); } if (!_heap[seg]) { error("SegManager::getScript(): seg id %x is not in memory", seg); } if (_heap[seg]->getType() != SEG_TYPE_SCRIPT) { error("SegManager::getScript(): seg id %x refers to type %d != SEG_TYPE_SCRIPT", seg, _heap[seg]->getType()); } return (Script *)_heap[seg]; } Script *SegManager::getScriptIfLoaded(const SegmentId seg) const { if (seg < 1 || (uint)seg >= _heap.size() || !_heap[seg] || _heap[seg]->getType() != SEG_TYPE_SCRIPT) return 0; return (Script *)_heap[seg]; } SegmentId SegManager::findSegmentByType(int type) const { for (uint i = 0; i < _heap.size(); i++) if (_heap[i] && _heap[i]->getType() == type) return i; return 0; } SegmentObj *SegManager::getSegmentObj(SegmentId seg) const { if (seg < 1 || (uint)seg >= _heap.size() || !_heap[seg]) return 0; return _heap[seg]; } SegmentType SegManager::getSegmentType(SegmentId seg) const { if (seg < 1 || (uint)seg >= _heap.size() || !_heap[seg]) return SEG_TYPE_INVALID; return _heap[seg]->getType(); } SegmentObj *SegManager::getSegment(SegmentId seg, SegmentType type) const { return getSegmentType(seg) == type ? _heap[seg] : NULL; } Object *SegManager::getObject(reg_t pos) const { SegmentObj *mobj = getSegmentObj(pos.segment); Object *obj = NULL; if (mobj != NULL) { if (mobj->getType() == SEG_TYPE_CLONES) { CloneTable *ct = (CloneTable *)mobj; if (ct->isValidEntry(pos.offset)) obj = &(ct->_table[pos.offset]); else warning("getObject(): Trying to get an invalid object"); } else if (mobj->getType() == SEG_TYPE_SCRIPT) { Script *scr = (Script *)mobj; if (pos.offset <= scr->getBufSize() && pos.offset >= -SCRIPT_OBJECT_MAGIC_OFFSET && RAW_IS_OBJECT(scr->getBuf(pos.offset))) { obj = scr->getObject(pos.offset); } } } return obj; } const char *SegManager::getObjectName(reg_t pos) { const Object *obj = getObject(pos); if (!obj) return ""; reg_t nameReg = obj->getNameSelector(); if (nameReg.isNull()) return ""; const char *name = 0; if (nameReg.segment) name = derefString(nameReg); if (!name) return ""; return name; } reg_t SegManager::findObjectByName(const Common::String &name, int index) { Common::Array result; uint i; // Now all values are available; iterate over all objects. for (i = 0; i < _heap.size(); i++) { const SegmentObj *mobj = _heap[i]; if (!mobj) continue; reg_t objpos = make_reg(i, 0); if (mobj->getType() == SEG_TYPE_SCRIPT) { // It's a script, scan all objects in it const Script *scr = (const Script *)mobj; ObjMap objects = scr->getObjectMap(); for (ObjMap::const_iterator it = objects.begin(); it != objects.end(); ++it) { objpos.offset = it->_value.getPos().offset; if (name == getObjectName(objpos)) result.push_back(objpos); } } else if (mobj->getType() == SEG_TYPE_CLONES) { // It's clone table, scan all objects in it const CloneTable *ct = (const CloneTable *)mobj; for (uint idx = 0; idx < ct->_table.size(); ++idx) { if (!ct->isValidEntry(idx)) continue; objpos.offset = idx; if (name == getObjectName(objpos)) result.push_back(objpos); } } } if (result.empty()) return NULL_REG; if (result.size() > 1 && index < 0) { debug("findObjectByName(%s): multiple matches:", name.c_str()); for (i = 0; i < result.size(); i++) debug(" %3x: [%04x:%04x]", i, PRINT_REG(result[i])); return NULL_REG; // Ambiguous } if (index < 0) return result[0]; else if (result.size() <= (uint)index) return NULL_REG; // Not found return result[index]; } // validate the seg // return: // false - invalid seg // true - valid seg bool SegManager::check(SegmentId seg) { if (seg < 1 || (uint)seg >= _heap.size()) { return false; } if (!_heap[seg]) { warning("SegManager: seg %x is removed from memory, but not removed from hash_map", seg); return false; } return true; } // return the seg if script_id is valid and in the map, else 0 SegmentId SegManager::getScriptSegment(int script_id) const { return _scriptSegMap.getVal(script_id, 0); } SegmentId SegManager::getScriptSegment(int script_nr, ScriptLoadType load) { SegmentId segment; if ((load & SCRIPT_GET_LOAD) == SCRIPT_GET_LOAD) instantiateScript(script_nr); segment = getScriptSegment(script_nr); if (segment > 0) { if ((load & SCRIPT_GET_LOCK) == SCRIPT_GET_LOCK) getScript(segment)->incrementLockers(); } return segment; } DataStack *SegManager::allocateStack(int size, SegmentId *segid) { SegmentObj *mobj = allocSegment(new DataStack(), segid); DataStack *retval = (DataStack *)mobj; retval->_entries = (reg_t *)calloc(size, sizeof(reg_t)); retval->_capacity = size; // SSCI initializes the stack with "S" characters (uppercase S in SCI0-SCI1, // lowercase s in SCI0 and SCI11) - probably stands for "stack" byte filler = (getSciVersion() >= SCI_VERSION_01 && getSciVersion() <= SCI_VERSION_1_LATE) ? 'S' : 's'; for (int i = 0; i < size; i++) retval->_entries[i] = make_reg(0, filler); return retval; } void SegManager::freeHunkEntry(reg_t addr) { if (addr.isNull()) { warning("Attempt to free a Hunk from a null address"); return; } HunkTable *ht = (HunkTable *)getSegment(addr.segment, SEG_TYPE_HUNK); if (!ht) { warning("Attempt to free Hunk from address %04x:%04x: Invalid segment type", PRINT_REG(addr)); return; } ht->freeEntryContents(addr.offset); } reg_t SegManager::allocateHunkEntry(const char *hunk_type, int size) { HunkTable *table; int offset; if (!_hunksSegId) allocSegment(new HunkTable(), &(_hunksSegId)); table = (HunkTable *)_heap[_hunksSegId]; offset = table->allocEntry(); reg_t addr = make_reg(_hunksSegId, offset); Hunk *h = &(table->_table[offset]); if (!h) return NULL_REG; h->mem = malloc(size); h->size = size; h->type = hunk_type; return addr; } byte *SegManager::getHunkPointer(reg_t addr) { HunkTable *ht = (HunkTable *)getSegment(addr.segment, SEG_TYPE_HUNK); if (!ht || !ht->isValidEntry(addr.offset)) { // Valid SCI behavior, e.g. when loading/quitting return NULL; } return (byte *)ht->_table[addr.offset].mem; } Clone *SegManager::allocateClone(reg_t *addr) { CloneTable *table; int offset; if (!_clonesSegId) table = (CloneTable *)allocSegment(new CloneTable(), &(_clonesSegId)); else table = (CloneTable *)_heap[_clonesSegId]; offset = table->allocEntry(); *addr = make_reg(_clonesSegId, offset); return &(table->_table[offset]); } List *SegManager::allocateList(reg_t *addr) { ListTable *table; int offset; if (!_listsSegId) allocSegment(new ListTable(), &(_listsSegId)); table = (ListTable *)_heap[_listsSegId]; offset = table->allocEntry(); *addr = make_reg(_listsSegId, offset); return &(table->_table[offset]); } Node *SegManager::allocateNode(reg_t *addr) { NodeTable *table; int offset; if (!_nodesSegId) allocSegment(new NodeTable(), &(_nodesSegId)); table = (NodeTable *)_heap[_nodesSegId]; offset = table->allocEntry(); *addr = make_reg(_nodesSegId, offset); return &(table->_table[offset]); } reg_t SegManager::newNode(reg_t value, reg_t key) { reg_t nodeRef; Node *n = allocateNode(&nodeRef); n->pred = n->succ = NULL_REG; n->key = key; n->value = value; return nodeRef; } List *SegManager::lookupList(reg_t addr) { if (getSegmentType(addr.segment) != SEG_TYPE_LISTS) { error("Attempt to use non-list %04x:%04x as list", PRINT_REG(addr)); return NULL; } ListTable *lt = (ListTable *)_heap[addr.segment]; if (!lt->isValidEntry(addr.offset)) { error("Attempt to use non-list %04x:%04x as list", PRINT_REG(addr)); return NULL; } return &(lt->_table[addr.offset]); } Node *SegManager::lookupNode(reg_t addr, bool stopOnDiscarded) { if (addr.isNull()) return NULL; // Non-error null SegmentType type = getSegmentType(addr.segment); if (type != SEG_TYPE_NODES) { error("Attempt to use non-node %04x:%04x (type %d) as list node", PRINT_REG(addr), type); return NULL; } NodeTable *nt = (NodeTable *)_heap[addr.segment]; if (!nt->isValidEntry(addr.offset)) { if (!stopOnDiscarded) return NULL; error("Attempt to use invalid or discarded reference %04x:%04x as list node", PRINT_REG(addr)); return NULL; } return &(nt->_table[addr.offset]); } SegmentRef SegManager::dereference(reg_t pointer) { SegmentRef ret; if (!pointer.segment || (pointer.segment >= _heap.size()) || !_heap[pointer.segment]) { // This occurs in KQ5CD when interacting with certain objects warning("SegManager::dereference(): Attempt to dereference invalid pointer %04x:%04x", PRINT_REG(pointer)); return ret; /* Invalid */ } SegmentObj *mobj = _heap[pointer.segment]; return mobj->dereference(pointer); } static void *derefPtr(SegManager *segMan, reg_t pointer, int entries, bool wantRaw) { SegmentRef ret = segMan->dereference(pointer); if (!ret.isValid()) return NULL; if (ret.isRaw != wantRaw) { warning("Dereferencing pointer %04x:%04x (type %d) which is %s, but expected %s", PRINT_REG(pointer), segMan->getSegmentType(pointer.segment), ret.isRaw ? "raw" : "not raw", wantRaw ? "raw" : "not raw"); } if (!wantRaw && ret.skipByte) { warning("Unaligned pointer read: %04x:%04x expected with word alignment", PRINT_REG(pointer)); return NULL; } if (entries > ret.maxSize) { warning("Trying to dereference pointer %04x:%04x beyond end of segment", PRINT_REG(pointer)); return NULL; } if (ret.isRaw) return ret.raw; else return ret.reg; } byte *SegManager::derefBulkPtr(reg_t pointer, int entries) { return (byte *)derefPtr(this, pointer, entries, true); } reg_t *SegManager::derefRegPtr(reg_t pointer, int entries) { return (reg_t *)derefPtr(this, pointer, 2*entries, false); } char *SegManager::derefString(reg_t pointer, int entries) { return (char *)derefPtr(this, pointer, entries, true); } // Helper functions for getting/setting characters in string fragments static inline char getChar(const SegmentRef &ref, uint offset) { if (ref.skipByte) offset++; reg_t val = ref.reg[offset / 2]; // segment 0xFFFF means that the scripts are using uninitialized temp-variable space // we can safely ignore this, if it isn't one of the first 2 chars. // foreign lsl3 uses kFileIO(readraw) and then immediately uses kReadNumber right at the start if (val.segment != 0) if (!((val.segment == 0xFFFF) && (offset > 1))) warning("Attempt to read character from non-raw data"); bool oddOffset = offset & 1; if (g_sci->isBE()) oddOffset = !oddOffset; return (oddOffset ? val.offset >> 8 : val.offset & 0xff); } static inline void setChar(const SegmentRef &ref, uint offset, byte value) { if (ref.skipByte) offset++; reg_t *val = ref.reg + offset / 2; val->segment = 0; bool oddOffset = offset & 1; if (g_sci->isBE()) oddOffset = !oddOffset; if (oddOffset) val->offset = (val->offset & 0x00ff) | (value << 8); else val->offset = (val->offset & 0xff00) | value; } // TODO: memcpy, strcpy and strncpy could maybe be folded into a single function void SegManager::strncpy(reg_t dest, const char* src, size_t n) { SegmentRef dest_r = dereference(dest); if (!dest_r.isValid()) { warning("Attempt to strncpy to invalid pointer %04x:%04x", PRINT_REG(dest)); return; } if (dest_r.isRaw) { // raw -> raw if (n == 0xFFFFFFFFU) ::strcpy((char *)dest_r.raw, src); else ::strncpy((char *)dest_r.raw, src, n); } else { // raw -> non-raw for (uint i = 0; i < n; i++) { setChar(dest_r, i, src[i]); if (!src[i]) break; } // Put an ending NUL to terminate the string if ((size_t)dest_r.maxSize > n) setChar(dest_r, n, 0); } } void SegManager::strncpy(reg_t dest, reg_t src, size_t n) { if (src.isNull()) { // Clear target string instead. if (n > 0) strcpy(dest, ""); return; // empty text } SegmentRef dest_r = dereference(dest); const SegmentRef src_r = dereference(src); if (!src_r.isValid()) { warning("Attempt to strncpy from invalid pointer %04x:%04x", PRINT_REG(src)); // Clear target string instead. if (n > 0) strcpy(dest, ""); return; } if (!dest_r.isValid()) { warning("Attempt to strncpy to invalid pointer %04x:%04x", PRINT_REG(dest)); return; } if (src_r.isRaw) { // raw -> * strncpy(dest, (const char*)src_r.raw, n); } else if (dest_r.isRaw && !src_r.isRaw) { // non-raw -> raw for (uint i = 0; i < n; i++) { char c = getChar(src_r, i); dest_r.raw[i] = c; if (!c) break; } } else { // non-raw -> non-raw for (uint i = 0; i < n; i++) { char c = getChar(src_r, i); setChar(dest_r, i, c); if (!c) break; } } } void SegManager::strcpy(reg_t dest, const char* src) { strncpy(dest, src, 0xFFFFFFFFU); } void SegManager::strcpy(reg_t dest, reg_t src) { strncpy(dest, src, 0xFFFFFFFFU); } void SegManager::memcpy(reg_t dest, const byte* src, size_t n) { SegmentRef dest_r = dereference(dest); if (!dest_r.isValid()) { warning("Attempt to memcpy to invalid pointer %04x:%04x", PRINT_REG(dest)); return; } if ((int)n > dest_r.maxSize) { warning("Trying to dereference pointer %04x:%04x beyond end of segment", PRINT_REG(dest)); return; } if (dest_r.isRaw) { // raw -> raw ::memcpy((char*)dest_r.raw, src, n); } else { // raw -> non-raw for (uint i = 0; i < n; i++) setChar(dest_r, i, src[i]); } } void SegManager::memcpy(reg_t dest, reg_t src, size_t n) { SegmentRef dest_r = dereference(dest); const SegmentRef src_r = dereference(src); if (!dest_r.isValid()) { warning("Attempt to memcpy to invalid pointer %04x:%04x", PRINT_REG(dest)); return; } if ((int)n > dest_r.maxSize) { warning("Trying to dereference pointer %04x:%04x beyond end of segment", PRINT_REG(dest)); return; } if (!src_r.isValid()) { warning("Attempt to memcpy from invalid pointer %04x:%04x", PRINT_REG(src)); return; } if ((int)n > src_r.maxSize) { warning("Trying to dereference pointer %04x:%04x beyond end of segment", PRINT_REG(src)); return; } if (src_r.isRaw) { // raw -> * memcpy(dest, src_r.raw, n); } else if (dest_r.isRaw) { // * -> raw memcpy(dest_r.raw, src, n); } else { // non-raw -> non-raw for (uint i = 0; i < n; i++) { char c = getChar(src_r, i); setChar(dest_r, i, c); } } } void SegManager::memcpy(byte *dest, reg_t src, size_t n) { const SegmentRef src_r = dereference(src); if (!src_r.isValid()) { warning("Attempt to memcpy from invalid pointer %04x:%04x", PRINT_REG(src)); return; } if ((int)n > src_r.maxSize) { warning("Trying to dereference pointer %04x:%04x beyond end of segment", PRINT_REG(src)); return; } if (src_r.isRaw) { // raw -> raw ::memcpy(dest, src_r.raw, n); } else { // non-raw -> raw for (uint i = 0; i < n; i++) { char c = getChar(src_r, i); dest[i] = c; } } } size_t SegManager::strlen(reg_t str) { if (str.isNull()) return 0; // empty text SegmentRef str_r = dereference(str); if (!str_r.isValid()) { warning("Attempt to call strlen on invalid pointer %04x:%04x", PRINT_REG(str)); return 0; } if (str_r.isRaw) { return ::strlen((const char *)str_r.raw); } else { int i = 0; while (getChar(str_r, i)) i++; return i; } } Common::String SegManager::getString(reg_t pointer, int entries) { Common::String ret; if (pointer.isNull()) return ret; // empty text SegmentRef src_r = dereference(pointer); if (!src_r.isValid()) { warning("SegManager::getString(): Attempt to dereference invalid pointer %04x:%04x", PRINT_REG(pointer)); return ret; } if (entries > src_r.maxSize) { warning("Trying to dereference pointer %04x:%04x beyond end of segment", PRINT_REG(pointer)); return ret; } if (src_r.isRaw) ret = (char *)src_r.raw; else { uint i = 0; for (;;) { char c = getChar(src_r, i); if (!c) break; i++; ret += c; }; } return ret; } byte *SegManager::allocDynmem(int size, const char *descr, reg_t *addr) { SegmentId seg; SegmentObj *mobj = allocSegment(new DynMem(), &seg); *addr = make_reg(seg, 0); DynMem &d = *(DynMem *)mobj; d._size = size; if (size == 0) d._buf = NULL; else d._buf = (byte *)malloc(size); d._description = descr; return (byte *)(d._buf); } bool SegManager::freeDynmem(reg_t addr) { if (addr.segment < 1 || addr.segment >= _heap.size() || !_heap[addr.segment] || _heap[addr.segment]->getType() != SEG_TYPE_DYNMEM) return false; // error deallocate(addr.segment); return true; // OK } #ifdef ENABLE_SCI32 SciArray *SegManager::allocateArray(reg_t *addr) { ArrayTable *table; int offset; if (!_arraysSegId) { table = (ArrayTable *)allocSegment(new ArrayTable(), &(_arraysSegId)); } else table = (ArrayTable *)_heap[_arraysSegId]; offset = table->allocEntry(); *addr = make_reg(_arraysSegId, offset); return &(table->_table[offset]); } SciArray *SegManager::lookupArray(reg_t addr) { if (_heap[addr.segment]->getType() != SEG_TYPE_ARRAY) error("Attempt to use non-array %04x:%04x as array", PRINT_REG(addr)); ArrayTable *arrayTable = (ArrayTable *)_heap[addr.segment]; if (!arrayTable->isValidEntry(addr.offset)) error("Attempt to use non-array %04x:%04x as array", PRINT_REG(addr)); return &(arrayTable->_table[addr.offset]); } void SegManager::freeArray(reg_t addr) { if (_heap[addr.segment]->getType() != SEG_TYPE_ARRAY) error("Attempt to use non-array %04x:%04x as array", PRINT_REG(addr)); ArrayTable *arrayTable = (ArrayTable *)_heap[addr.segment]; if (!arrayTable->isValidEntry(addr.offset)) error("Attempt to use non-array %04x:%04x as array", PRINT_REG(addr)); arrayTable->_table[addr.offset].destroy(); arrayTable->freeEntry(addr.offset); } SciString *SegManager::allocateString(reg_t *addr) { StringTable *table; int offset; if (!_stringSegId) { table = (StringTable *)allocSegment(new StringTable(), &(_stringSegId)); } else table = (StringTable *)_heap[_stringSegId]; offset = table->allocEntry(); *addr = make_reg(_stringSegId, offset); return &(table->_table[offset]); } SciString *SegManager::lookupString(reg_t addr) { if (_heap[addr.segment]->getType() != SEG_TYPE_STRING) error("lookupString: Attempt to use non-string %04x:%04x as string", PRINT_REG(addr)); StringTable *stringTable = (StringTable *)_heap[addr.segment]; if (!stringTable->isValidEntry(addr.offset)) error("lookupString: Attempt to use non-string %04x:%04x as string", PRINT_REG(addr)); return &(stringTable->_table[addr.offset]); } void SegManager::freeString(reg_t addr) { if (_heap[addr.segment]->getType() != SEG_TYPE_STRING) error("freeString: Attempt to use non-string %04x:%04x as string", PRINT_REG(addr)); StringTable *stringTable = (StringTable *)_heap[addr.segment]; if (!stringTable->isValidEntry(addr.offset)) error("freeString: Attempt to use non-string %04x:%04x as string", PRINT_REG(addr)); stringTable->_table[addr.offset].destroy(); stringTable->freeEntry(addr.offset); } #endif void SegManager::createClassTable() { Resource *vocab996 = _resMan->findResource(ResourceId(kResourceTypeVocab, 996), 1); if (!vocab996) error("SegManager: failed to open vocab 996"); int totalClasses = vocab996->size >> 2; _classTable.resize(totalClasses); for (uint16 classNr = 0; classNr < totalClasses; classNr++) { uint16 scriptNr = READ_SCI11ENDIAN_UINT16(vocab996->data + classNr * 4 + 2); _classTable[classNr].reg = NULL_REG; _classTable[classNr].script = scriptNr; } _resMan->unlockResource(vocab996); } reg_t SegManager::getClassAddress(int classnr, ScriptLoadType lock, reg_t caller) { if (classnr == 0xffff) return NULL_REG; if (classnr < 0 || (int)_classTable.size() <= classnr || _classTable[classnr].script < 0) { error("[VM] Attempt to dereference class %x, which doesn't exist (max %x)", classnr, _classTable.size()); return NULL_REG; } else { Class *the_class = &_classTable[classnr]; if (!the_class->reg.segment) { getScriptSegment(the_class->script, lock); if (!the_class->reg.segment) { error("[VM] Trying to instantiate class %x by instantiating script 0x%x (%03d) failed;", classnr, the_class->script, the_class->script); return NULL_REG; } } else if (caller.segment != the_class->reg.segment) getScript(the_class->reg.segment)->incrementLockers(); return the_class->reg; } } int SegManager::instantiateScript(int scriptNum) { SegmentId segmentId = getScriptSegment(scriptNum); Script *scr = getScriptIfLoaded(segmentId); if (scr) { if (!scr->isMarkedAsDeleted()) { scr->incrementLockers(); return segmentId; } else { scr->freeScript(); } } else { scr = allocateScript(scriptNum, &segmentId); } scr->init(scriptNum, _resMan); scr->load(_resMan); scr->initializeLocals(this); scr->initializeClasses(this); scr->initializeObjects(this, segmentId); return segmentId; } void SegManager::uninstantiateScript(int script_nr) { SegmentId segmentId = getScriptSegment(script_nr); Script *scr = getScriptIfLoaded(segmentId); if (!scr || scr->isMarkedAsDeleted()) { // Is it already unloaded? //warning("unloading script 0x%x requested although not loaded", script_nr); // This is perfectly valid SCI behavior return; } scr->decrementLockers(); // One less locker if (scr->getLockers() > 0) return; // Free all classtable references to this script for (uint i = 0; i < classTableSize(); i++) if (getClass(i).reg.segment == segmentId) setClassOffset(i, NULL_REG); if (getSciVersion() < SCI_VERSION_1_1) uninstantiateScriptSci0(script_nr); // FIXME: Add proper script uninstantiation for SCI 1.1 if (!scr->getLockers()) { // The actual script deletion seems to be done by SCI scripts themselves scr->markDeleted(); debugC(kDebugLevelScripts, "Unloaded script 0x%x.", script_nr); } } void SegManager::uninstantiateScriptSci0(int script_nr) { bool oldScriptHeader = (getSciVersion() == SCI_VERSION_0_EARLY); SegmentId segmentId = getScriptSegment(script_nr); Script *scr = getScript(segmentId); reg_t reg = make_reg(segmentId, oldScriptHeader ? 2 : 0); int objType, objLength = 0; // Make a pass over the object in order to uninstantiate all superclasses do { reg.offset += objLength; // Step over the last checked object objType = READ_SCI11ENDIAN_UINT16(scr->getBuf(reg.offset)); if (!objType) break; objLength = READ_SCI11ENDIAN_UINT16(scr->getBuf(reg.offset + 2)); reg.offset += 4; // Step over header if ((objType == SCI_OBJ_OBJECT) || (objType == SCI_OBJ_CLASS)) { // object or class? reg.offset += 8; // magic offset (SCRIPT_OBJECT_MAGIC_OFFSET) int16 superclass = READ_SCI11ENDIAN_UINT16(scr->getBuf(reg.offset + 2)); if (superclass >= 0) { int superclass_script = getClass(superclass).script; if (superclass_script == script_nr) { if (scr->getLockers()) scr->decrementLockers(); // Decrease lockers if this is us ourselves } else { uninstantiateScript(superclass_script); } // Recurse to assure that the superclass lockers number gets decreased } reg.offset += SCRIPT_OBJECT_MAGIC_OFFSET; } // if object or class reg.offset -= 4; // Step back on header } while (objType != 0); } } // End of namespace Sci