int main(int argc, const char * argv[]) { char *filePath = NULL; PathInit(argv[0]); PathForFile("w256-001.gp", &filePath); assert(filePath != NULL); CurveRef curve = CurveCreateFromFile(filePath); assert(curve != NULL); PointRef g = curve->g; mpz_t m; mpz_init_set_str(m, "888493310283202167031085660111238327945443791805939712000426466539273165903", 10); PointRef g2 = PointCreateMultiple(g, m, curve); mpz_t xr, yr; mpz_init_set_str(xr, "5441683091496050436439782524673611468679503009264125966279940185557193452058", 10); mpz_init_set_str(yr, "126373273530397135676109694298926901726086297191360274402845796485476517565", 10); assert(mpz_cmp(g2->x, xr) == 0); assert(mpz_cmp(g2->y, yr) == 0); mpz_set_si(m, 0); PointRef g3 = PointCreateMultiple(g, m, curve); assert(PointIsTeta(g3)); mpz_set_si(m, 1); PointRef g4 = PointCreateMultiple(g, m, curve); assert(PointEqual(g4, g)); return 0; }
int main(){ Vector *v = (Vector*) malloc(sizeof(Vector)); VectorRead(v); Path *solution = (Path*) malloc(sizeof(Path)); PathInit(solution, v->size); AllPathsRec(0, v, solution, solution->indexes); PathCheckNoPaths(solution); PathKill(solution); VectorKill(v); }
int main(int argc, const char * argv[]) { char *filePath = NULL; PathInit(EXEC_PATH); PathForFile(FILE_NAME, &filePath); assert(strcmp(DIR_PATH "/" FILE_NAME, filePath) == 0); free(filePath); return 0; }
void MyModuleInit(RTC::Manager* manager) { PathInit(manager); RTC::RtcBase* comp; // Create a component comp = manager->createComponent("Path"); // Example // The following procedure is examples how handle RT-Components. // These should not be in this function. // Get the component's object reference // RTC::RTObject_var rtobj; // rtobj = RTC::RTObject::_narrow(manager->getPOA()->servant_to_reference(comp)); // Get the port list of the component // PortList* portlist; // portlist = rtobj->get_ports(); // getting port profiles // std::cout << "Number of Ports: "; // std::cout << portlist->length() << std::endl << std::endl; // for (CORBA::ULong i(0), n(portlist->length()); i < n; ++i) // { // Port_ptr port; // port = (*portlist)[i]; // std::cout << "Port" << i << " (name): "; // std::cout << port->get_port_profile()->name << std::endl; // // RTC::PortInterfaceProfileList iflist; // iflist = port->get_port_profile()->interfaces; // std::cout << "---interfaces---" << std::endl; // for (CORBA::ULong i(0), n(iflist.length()); i < n; ++i) // { // std::cout << "I/F name: "; // std::cout << iflist[i].instance_name << std::endl; // std::cout << "I/F type: "; // std::cout << iflist[i].type_name << std::endl; // const char* pol; // pol = iflist[i].polarity == 0 ? "PROVIDED" : "REQUIRED"; // std::cout << "Polarity: " << pol << std::endl; // } // std::cout << "---properties---" << std::endl; // NVUtil::dump(port->get_port_profile()->properties); // std::cout << "----------------" << std::endl << std::endl; // } return; }
void DebugInit( void ) { NestedCallLevel = 0; UpdateFlags = 0; _SwitchOn( SW_ERROR_STARTUP ); _SwitchOn( SW_CHECK_SOURCE_EXISTS ); SET_NIL_ADDR( NilAddr ); TxtBuff = &DbgBuffers[0]; *TxtBuff = '\0'; NameBuff = &DbgBuffers[TXT_LEN+1]; *NameBuff = '\0'; CurrRadix = DefRadix = 10; DbgLevel = MIX; ActiveWindowLevel = MIX; _SwitchOn( SW_BELL ); _SwitchOn( SW_FLIP ); _SwitchOn( SW_RECURSE_CHECK ); _SwitchOff( SW_ADDING_SYMFILE ); _SwitchOff( SW_TASK_RUNNING ); RecordInit(); LogInit(); InitMADInfo(); InitMachState(); PathInit(); InitDbgInfo(); InitTrap( TrapParms ); if( !LangSetInit() ) { FiniTrap(); StartupErr( LIT_ENG( STARTUP_Loading_PRS ) ); } if( !InitCmd() ) { FiniTrap(); StartupErr( LIT_ENG( ERR_NO_MEMORY ) ); } InitScan(); InitLook(); InitBPs(); InitSource(); InitDLLList(); DUIInit(); InitHook(); VarDisplayInit(); }
void SkJS::InitializeDisplayables(const SkBitmap& bitmap, JSContext *cx, JSObject *obj, JSObject *proto) { SkJSDisplayable::gCanvas = new SkCanvas(bitmap); SkJSDisplayable::gPaint = new SkPaint(); #if SK_USE_CONDENSED_INFO == 0 GenerateTables(); #else SkASSERT(0); // !!! compressed version hasn't been implemented #endif AddInit(cx, obj, proto); AddCircleInit(cx, obj, proto); AddOvalInit(cx, obj, proto); AddPathInit(cx, obj, proto); AddRectangleInit(cx, obj, proto); AddRoundRectInit(cx, obj, proto); // AfterInit(cx, obj, proto); ApplyInit(cx, obj, proto); // AnimateInit(cx, obj, proto); // AnimateColorInit(cx, obj, proto); AnimateFieldInit(cx, obj, proto); // AnimateRotateInit(cx, obj, proto); // AnimateScaleInit(cx, obj, proto); // AnimateTranslateInit(cx, obj, proto); BitmapInit(cx, obj, proto); // BaseBitmapInit(cx, obj, proto); // BeforeInit(cx, obj, proto); BitmapShaderInit(cx, obj, proto); BlurInit(cx, obj, proto); ClipInit(cx, obj, proto); ColorInit(cx, obj, proto); CubicToInit(cx, obj, proto); DashInit(cx, obj, proto); DataInit(cx, obj, proto); // DimensionsInit(cx, obj, proto); DiscreteInit(cx, obj, proto); DrawToInit(cx, obj, proto); EmbossInit(cx, obj, proto); EventInit(cx, obj, proto); // FontInit(cx, obj, proto); // FocusInit(cx, obj, proto); ImageInit(cx, obj, proto); IncludeInit(cx, obj, proto); // InputInit(cx, obj, proto); LineInit(cx, obj, proto); LinearGradientInit(cx, obj, proto); LineToInit(cx, obj, proto); MatrixInit(cx, obj, proto); MoveInit(cx, obj, proto); MoveToInit(cx, obj, proto); OvalInit(cx, obj, proto); PathInit(cx, obj, proto); PaintInit(cx, obj, proto); DrawPointInit(cx, obj, proto); PolyToPolyInit(cx, obj, proto); PolygonInit(cx, obj, proto); PolylineInit(cx, obj, proto); PostInit(cx, obj, proto); QuadToInit(cx, obj, proto); RadialGradientInit(cx, obj, proto); RandomInit(cx, obj, proto); RectToRectInit(cx, obj, proto); RectangleInit(cx, obj, proto); RemoveInit(cx, obj, proto); ReplaceInit(cx, obj, proto); RotateInit(cx, obj, proto); RoundRectInit(cx, obj, proto); ScaleInit(cx, obj, proto); SetInit(cx, obj, proto); SkewInit(cx, obj, proto); // 3D_CameraInit(cx, obj, proto); // 3D_PatchInit(cx, obj, proto); SnapshotInit(cx, obj, proto); // StrokeInit(cx, obj, proto); TextInit(cx, obj, proto); TextOnPathInit(cx, obj, proto); TextToPathInit(cx, obj, proto); TranslateInit(cx, obj, proto); // UseInit(cx, obj, proto); }
void PathConcat(PathBuffer* buffer, const char* other) { PathBuffer buf; PathInit(&buf, other); PathConcat(buffer, &buf); }
static BuildProgress::Enum RunAction(BuildQueue* queue, ThreadState* thread_state, NodeState* node, Mutex* queue_lock) { const NodeData *node_data = node->m_MmapData; const char *cmd_line = node_data->m_Action; const char *pre_cmd_line = node_data->m_PreAction; if (!cmd_line || cmd_line[0] == '\0') return BuildProgress::kSucceeded; if (node->m_MmapData->m_Flags & NodeData::kFlagExpensive) { if (queue->m_ExpensiveRunning == queue->m_Config.m_MaxExpensiveCount) { ParkExpensiveNode(queue, node); return BuildProgress::kRunAction; } else { ++queue->m_ExpensiveRunning; } } MutexUnlock(queue_lock); StatCache *stat_cache = queue->m_Config.m_StatCache; const char *annotation = node_data->m_Annotation; int job_id = thread_state->m_ThreadIndex; int echo_cmdline = 0 != (queue->m_Config.m_Flags & BuildQueueConfig::kFlagEchoCommandLines); // Repack frozen env to pointers on the stack. int env_count = node_data->m_EnvVars.GetCount(); EnvVariable* env_vars = (EnvVariable*) alloca(env_count * sizeof(EnvVariable)); for (int i = 0; i < env_count; ++i) { env_vars[i].m_Name = node_data->m_EnvVars[i].m_Name; env_vars[i].m_Value = node_data->m_EnvVars[i].m_Value; } for (const FrozenFileAndHash& output_file : node_data->m_OutputFiles) { PathBuffer output; PathInit(&output, output_file.m_Filename); if (!MakeDirectoriesForFile(stat_cache, output)) { Log(kError, "failed to create output directories for %s", output_file.m_Filename.Get()); MutexLock(queue_lock); return BuildProgress::kFailed; } } ExecResult result = { 0, false }; // See if we need to remove the output files before running anything. if (0 == (node_data->m_Flags & NodeData::kFlagOverwriteOutputs)) { for (const FrozenFileAndHash& output : node_data->m_OutputFiles) { Log(kDebug, "Removing output file %s before running action", output.m_Filename.Get()); remove(output.m_Filename); StatCacheMarkDirty(stat_cache, output.m_Filename, output.m_Hash); } } if (pre_cmd_line) { Log(kSpam, "Launching pre-action process"); TimingScope timing_scope(&g_Stats.m_ExecCount, &g_Stats.m_ExecTimeCycles); result = ExecuteProcess(pre_cmd_line, env_count, env_vars, job_id, echo_cmdline, "(pre-build command)"); Log(kSpam, "Process return code %d", result.m_ReturnCode); } if (0 == result.m_ReturnCode) { Log(kSpam, "Launching process"); TimingScope timing_scope(&g_Stats.m_ExecCount, &g_Stats.m_ExecTimeCycles); result = ExecuteProcess(cmd_line, env_count, env_vars, job_id, echo_cmdline, annotation); Log(kSpam, "Process return code %d", result.m_ReturnCode); } for (const FrozenFileAndHash& output : node_data->m_OutputFiles) { StatCacheMarkDirty(stat_cache, output.m_Filename, output.m_Hash); } MutexLock(queue_lock); if (result.m_WasSignalled) { SignalSet("child processes signalled"); } if (0 == result.m_ReturnCode) { return BuildProgress::kSucceeded; } else { // Clean up output files after a failed build unless they are precious. if (0 == (NodeData::kFlagPreciousOutputs & node_data->m_Flags)) { for (const FrozenFileAndHash& output : node_data->m_OutputFiles) { Log(kDebug, "Removing output file %s from failed build", output.m_Filename.Get()); remove(output.m_Filename); StatCacheMarkDirty(stat_cache, output.m_Filename, output.m_Hash); } } return BuildProgress::kFailed; } }