/* 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 "common/system.h" #include // FIXME: For struct tm #include "sci/sci.h" #include "sci/debug.h" #include "sci/engine/state.h" #include "sci/engine/kernel.h" #include "sci/engine/gc.h" namespace Sci { reg_t kRestartGame(EngineState *s, int funct_nr, int argc, reg_t *argv) { s->restarting_flags |= SCI_GAME_IS_RESTARTING_NOW; s->restarting_flags &= ~SCI_GAME_WAS_RESTARTED_AT_LEAST_ONCE; // This appears to help shrink_execution_stack(s, s->execution_stack_base + 1); script_abort_flag = 1; // Force vm to abort ASAP return NULL_REG; } /* kGameIsRestarting(): ** Returns the restarting_flag in acc */ reg_t kGameIsRestarting(EngineState *s, int funct_nr, int argc, reg_t *argv) { s->r_acc = make_reg(0, (s->restarting_flags & SCI_GAME_WAS_RESTARTED)); if (argc) { // Only happens during replay if (!argv[0].toUint16()) // Set restarting flag s->restarting_flags &= ~SCI_GAME_WAS_RESTARTED; } return s->r_acc; } reg_t kHaveMouse(EngineState *s, int funct_nr, int argc, reg_t *argv) { return make_reg(0, -1); } enum kMemoryInfoFunc { K_MEMORYINFO_LARGEST_HEAP_BLOCK = 0, // Largest heap block available K_MEMORYINFO_FREE_HEAP = 1, // Total free heap memory K_MEMORYINFO_LARGEST_HUNK_BLOCK = 2, // Largest available hunk memory block K_MEMORYINFO_FREE_HUNK = 3, // Amount of free DOS paragraphs K_MEMORYINFO_TOTAL_HUNK = 4 // Total amount of hunk memory (SCI01) }; reg_t kMemoryInfo(EngineState *s, int funct_nr, int argc, reg_t *argv) { uint16 size = 0x7fff; // Must not be 0xffff, or some memory calculations will overflow switch (argv[0].offset) { case K_MEMORYINFO_LARGEST_HEAP_BLOCK: // In order to prevent "Memory fragmented" dialogs from // popping up in some games, we must return FREE_HEAP - 2 here. return make_reg(0, size - 2); case K_MEMORYINFO_FREE_HEAP: case K_MEMORYINFO_LARGEST_HUNK_BLOCK: case K_MEMORYINFO_FREE_HUNK: case K_MEMORYINFO_TOTAL_HUNK: return make_reg(0, size); default: warning("Unknown MemoryInfo operation: %04x", argv[0].offset); } return NULL_REG; } #define SCI_MAPPED_UNKNOWN_KFUNCTIONS_NR 0x75 // kfunct_mappers below doubles for unknown kfunctions reg_t k_Unknown(EngineState *s, int funct_nr, int argc, reg_t *argv) { warning("Unhandled Unknown function %04x", funct_nr); return NULL_REG; } reg_t kFlushResources(EngineState *s, int funct_nr, int argc, reg_t *argv) { run_gc(s); debugC(2, kDebugLevelRoom, "Entering room number %d", argv[0].toUint16()); return s->r_acc; } reg_t kSetDebug(EngineState *s, int funct_nr, int argc, reg_t *argv) { printf("Debug mode activated\n"); scriptState.seeking = kDebugSeekNothing; scriptState.runningStep = 0; return s->r_acc; } enum { _K_NEW_GETTIME_TICKS = 0, _K_NEW_GETTIME_TIME_12HOUR = 1, _K_NEW_GETTIME_TIME_24HOUR = 2, _K_NEW_GETTIME_DATE = 3 }; reg_t kGetTime(EngineState *s, int funct_nr, int argc, reg_t *argv) { tm loc_time; uint32 start_time; int retval = 0; // Avoid spurious warning #if 0 // Reset optimization flags: If this function is called, // the game may be waiting for a timeout s->kernel_opt_flags &= ~(KERNEL_OPT_FLAG_GOT_EVENT | KERNEL_OPT_FLAG_GOT_2NDEVENT); #endif g_system->getTimeAndDate(loc_time); start_time = g_system->getMillis() - s->game_start_time; if ((s->_flags & GF_SCI0_OLDGETTIME) && argc) { // Use old semantics retval = (loc_time.tm_hour % 12) * 3600 + loc_time.tm_min * 60 + loc_time.tm_sec; debugC(2, kDebugLevelTime, "GetTime(timeofday) returns %d", retval); return make_reg(0, retval); } int mode = (argc > 0) ? argv[0].toUint16() : 0; switch (mode) { case _K_NEW_GETTIME_TICKS : retval = start_time * 60 / 1000; debugC(2, kDebugLevelTime, "GetTime(elapsed) returns %d", retval); break; case _K_NEW_GETTIME_TIME_12HOUR : retval = ((loc_time.tm_hour % 12) << 12) | (loc_time.tm_min << 6) | (loc_time.tm_sec); debugC(2, kDebugLevelTime, "GetTime(12h) returns %d", retval); break; case _K_NEW_GETTIME_TIME_24HOUR : retval = (loc_time.tm_hour << 11) | (loc_time.tm_min << 5) | (loc_time.tm_sec >> 1); debugC(2, kDebugLevelTime, "GetTime(24h) returns %d", retval); break; case _K_NEW_GETTIME_DATE : retval = loc_time.tm_mday | ((loc_time.tm_mon + 1) << 5) | (((loc_time.tm_year + 1900) & 0x7f) << 9); debugC(2, kDebugLevelTime, "GetTime(date) returns %d", retval); break; default: warning("Attempt to use unknown GetTime mode %d", mode); break; } return make_reg(0, retval); } enum { K_MEMORY_ALLOCATE_CRITICAL = 1, K_MEMORY_ALLOCATE_NONCRITICAL = 2, K_MEMORY_FREE = 3, K_MEMORY_MEMCPY = 4, K_MEMORY_PEEK = 5, K_MEMORY_POKE = 6 }; reg_t kMemory(EngineState *s, int funct_nr, int argc, reg_t *argv) { switch (argv[0].toUint16()) { case K_MEMORY_ALLOCATE_CRITICAL : if (!s->seg_manager->allocDynmem(argv[1].toUint16(), "kMemory() critical", &s->r_acc)) { error("Critical heap allocation failed"); } return s->r_acc; break; case K_MEMORY_ALLOCATE_NONCRITICAL : s->seg_manager->allocDynmem(argv[1].toUint16(), "kMemory() non-critical", &s->r_acc); break; case K_MEMORY_FREE : if (s->seg_manager->freeDynmem(argv[1])) { error("Attempt to kMemory::free() non-dynmem pointer %04x:%04x", PRINT_REG(argv[1])); } break; case K_MEMORY_MEMCPY : { int size = argv[3].toUint16(); byte *dest = kernel_dereference_bulk_pointer(s, argv[1], size); byte *src = kernel_dereference_bulk_pointer(s, argv[2], size); if (dest && src) memcpy(dest, src, size); else { warning("Could not execute kMemory:memcpy of %d bytes:", size); if (!dest) { warning(" dest ptr (%04x:%04x) invalid/memory region too small", PRINT_REG(argv[1])); } if (!src) { warning(" src ptr (%04x:%04x) invalid/memory region too small", PRINT_REG(argv[2])); } } break; } case K_MEMORY_PEEK : { byte *ref = kernel_dereference_bulk_pointer(s, argv[1], 2); if (!ref) { // This occurs in KQ5CD when interacting with certain objects warning("Attempt to peek invalid memory at %04x:%04x", PRINT_REG(argv[1])); return s->r_acc; } if (s->seg_manager->_heap[argv[1].segment]->getType() == MEM_OBJ_LOCALS) return *((reg_t *) ref); else return make_reg(0, (int16)READ_LE_UINT16(ref)); break; } case K_MEMORY_POKE : { byte *ref = kernel_dereference_bulk_pointer(s, argv[1], 2); if (!ref) { warning("Attempt to poke invalid memory at %04x:%04x", PRINT_REG(argv[1])); return s->r_acc; } if (s->seg_manager->_heap[argv[1].segment]->getType() == MEM_OBJ_LOCALS) *((reg_t *) ref) = argv[2]; else { if (argv[2].segment) { error("Attempt to poke memory reference %04x:%04x to %04x:%04x", PRINT_REG(argv[2]), PRINT_REG(argv[1])); return s->r_acc; WRITE_LE_UINT16(ref, argv[2].offset); // ? } } return s->r_acc; break; } } return s->r_acc; } reg_t kStub(EngineState *s, int funct_nr, int argc, reg_t *argv) { char tmpbuf[200]; sprintf(tmpbuf, "Unimplemented syscall: %s[%x] (", ((SciEngine*)g_engine)->getKernel()->getKernelName(funct_nr).c_str(), funct_nr); for (int i = 0; i < argc; i++) { char tmpbuf2[20]; sprintf(tmpbuf2, "%04x:%04x", PRINT_REG(argv[i])); if (i + 1 < argc) strcat(tmpbuf2, ", "); strcat(tmpbuf, tmpbuf2); } strcat(tmpbuf, ")"); warning("%s", tmpbuf); return NULL_REG; } reg_t kNOP(EngineState *s, int funct_nr, int argc, reg_t *argv) { warning("Kernel function 0x%02x (%s) invoked: unmapped", funct_nr, ((SciEngine*)g_engine)->getKernel()->_kernelFuncs[funct_nr].orig_name.c_str()); return NULL_REG; } } // End of namespace Sci