// CONSTRUCTORS
explicit StatsReport(std::ofstream* aofp)
: os(*aofp) {
header();
sumit();
stars();
stages();
}
void NewTableDialog::okClicked()
{
if (teams().size() == 0 || stages().size() == 0) {
QMessageBox::critical(this, "Ошибка", "Вы должны добавить хотя "
"бы одну команду и один конкурс!");
} else {
accept();
}
}
ModelObject CoilHeatingGasMultiStage_Impl::clone(Model model) const {
auto t_clone = StraightComponent_Impl::clone(model).cast<CoilHeatingGasMultiStage>();
auto t_stages = stages();
for( auto stage: t_stages ) {
auto stageClone = stage.clone(model).cast<CoilHeatingGasMultiStageStageData>();
t_clone.addStage(stageClone);
}
return t_clone;
}
ModelObject CoilCoolingDXMultiSpeed_Impl::clone(Model model) const {
auto t_clone = StraightComponent_Impl::clone(model).cast<CoilCoolingDXMultiSpeed>();
auto t_stages = stages();
for( auto stage: t_stages ) {
auto stageClone = stage.clone(model).cast<CoilCoolingDXMultiSpeedStageData>();
t_clone.addStage(stageClone);
}
return t_clone;
}
// splits n into a list of powers 2^a 2^b 2^c 3^d 5^e...
// exponents are limited by available kernels,
// if no kernel for prime is available, exponent will be 0, interpret as 1.
std::vector<pow> factor(size_t n) const {
std::vector<pow> out, factors = prime_factors(n);
for(auto f = factors.begin() ; f != factors.end() ; f++) {
if(std::find(primes.begin(), primes.end(), f->base) != primes.end()) {
// split exponent into reasonable parts.
auto qs = stages(*f);
// use smallest radix first
std::copy(qs.rbegin(), qs.rend(), std::back_inserter(out));
} else {
// unsupported prime.
for(size_t i = 0 ; i != f->exponent ; i++)
out.push_back(pow(f->base, 0));
}
}
return out;
}
int main (int , char** )
{
// const int NB_STAGE = 5;
// const int RANK[] = { 3, 5, 3, 5, 3 };
// const int NR[] = { 5, 5, 5, 5, 8 };
// const int NC = 20;
const unsigned int NB_STAGE = 3;
const int RANK[] = { 3, 4, 3, 5, 3 };
const int RANKLINKED[] = { 0, 0, 0, 0, 0 };
const int NR[] = { 5, 4, 5, 5, 8 };
const unsigned int NC = 12;
/* Initialize J and b. */
std::vector<Eigen::MatrixXd> J(NB_STAGE);
std::vector<soth::VectorBound> b(NB_STAGE);
soth::generateDeficientDataSet( J,b,NB_STAGE,RANK,RANKLINKED,NR,NC );
for( unsigned int i=0;i<NB_STAGE;++i )
{
std::cout << "J"<<i<<" = " << (soth::MATLAB)J[i] << std::endl;
}
/* SOTH structure construction. */
soth::BaseY Y(NC);
typedef boost::shared_ptr<soth::Stage> stage_ptr_t;
typedef std::vector<stage_ptr_t> stage_list_t;
stage_list_t stages(NB_STAGE);
for( unsigned int i=0;i<NB_STAGE;++i )
{
std::cout <<" --- STAGE " <<i<< " --------------------------------- " << std::endl;
/* Compute the initial COD for each stage. */
stages[i] = stage_ptr_t(new soth::Stage( J[i],b[i],Y ));
stages[i]->setInitialActiveSet();
stages[i]->computeInitialCOD(Y);
Eigen::MatrixXd Jrec; stages[i]->recompose(Jrec);
std::cout << "Jrec" <<i<<" = " << (soth::MATLAB)Jrec << std::endl;
}
Eigen::MatrixXd rec;
stages[0]->recompose(rec);
return 0;
}
bool GrGpuGL::programUnitTest(int maxStages) {
GrTextureDesc dummyDesc;
dummyDesc.fFlags = kRenderTarget_GrTextureFlagBit;
dummyDesc.fConfig = kSkia8888_GrPixelConfig;
dummyDesc.fWidth = 34;
dummyDesc.fHeight = 18;
SkAutoTUnref<GrTexture> dummyTexture1(this->createTexture(dummyDesc, NULL, 0));
dummyDesc.fFlags = kNone_GrTextureFlags;
dummyDesc.fConfig = kAlpha_8_GrPixelConfig;
dummyDesc.fWidth = 16;
dummyDesc.fHeight = 22;
SkAutoTUnref<GrTexture> dummyTexture2(this->createTexture(dummyDesc, NULL, 0));
if (!dummyTexture1 || ! dummyTexture2) {
return false;
}
static const int NUM_TESTS = 512;
SkRandom random;
for (int t = 0; t < NUM_TESTS; ++t) {
#if 0
GrPrintf("\nTest Program %d\n-------------\n", t);
static const int stop = -1;
if (t == stop) {
int breakpointhere = 9;
}
#endif
GrGLProgramDesc pdesc;
int currAttribIndex = 1; // we need to always leave room for position
int currTextureCoordSet = 0;
GrTexture* dummyTextures[] = {dummyTexture1.get(), dummyTexture2.get()};
int numStages = random.nextULessThan(maxStages + 1);
int numColorStages = random.nextULessThan(numStages + 1);
int numCoverageStages = numStages - numColorStages;
SkAutoSTMalloc<8, const GrFragmentStage*> stages(numStages);
bool usePathRendering = this->glCaps().pathRenderingSupport() && random.nextBool();
GrGpu::DrawType drawType = usePathRendering ? GrGpu::kDrawPath_DrawType :
GrGpu::kDrawPoints_DrawType;
SkAutoTDelete<GrGeometryStage> geometryProcessor;
bool hasGeometryProcessor = usePathRendering ? false : random.nextBool();
if (hasGeometryProcessor) {
while (true) {
SkAutoTUnref<const GrGeometryProcessor> effect(
GrProcessorTestFactory<GrGeometryProcessor>::CreateStage(&random, this->getContext(), *this->caps(),
dummyTextures));
SkASSERT(effect);
// Only geometryProcessor can use vertex shader
GrGeometryStage* stage = SkNEW_ARGS(GrGeometryStage, (effect.get()));
geometryProcessor.reset(stage);
// we have to set dummy vertex attribs
const GrGeometryProcessor::VertexAttribArray& v = effect->getVertexAttribs();
int numVertexAttribs = v.count();
SkASSERT(GrGeometryProcessor::kMaxVertexAttribs == 2 &&
GrGeometryProcessor::kMaxVertexAttribs >= numVertexAttribs);
size_t runningStride = GrVertexAttribTypeSize(genericVertexAttribs[0].fType);
for (int i = 0; i < numVertexAttribs; i++) {
genericVertexAttribs[i + 1].fOffset = runningStride;
genericVertexAttribs[i + 1].fType =
convert_sltype_to_attribtype(v[i].getType());
runningStride += GrVertexAttribTypeSize(genericVertexAttribs[i + 1].fType);
}
// update the vertex attributes with the ds
GrDrawState* ds = this->drawState();
ds->setVertexAttribs<genericVertexAttribs>(numVertexAttribs + 1, runningStride);
currAttribIndex = numVertexAttribs + 1;
break;
}
}
for (int s = 0; s < numStages;) {
SkAutoTUnref<const GrFragmentProcessor> effect(
GrProcessorTestFactory<GrFragmentProcessor>::CreateStage(
&random,
this->getContext(),
*this->caps(),
dummyTextures));
SkASSERT(effect);
// If adding this effect would exceed the max texture coord set count then generate a
// new random effect.
if (usePathRendering && this->glPathRendering()->texturingMode() ==
GrGLPathRendering::FixedFunction_TexturingMode) {;
int numTransforms = effect->numTransforms();
if (currTextureCoordSet + numTransforms > this->glCaps().maxFixedFunctionTextureCoords()) {
continue;
}
currTextureCoordSet += numTransforms;
}
GrFragmentStage* stage = SkNEW_ARGS(GrFragmentStage, (effect.get()));
stages[s] = stage;
++s;
}
const GrTexture* dstTexture = random.nextBool() ? dummyTextures[0] : dummyTextures[1];
if (!pdesc.setRandom(&random,
this,
dummyTextures[0]->asRenderTarget(),
dstTexture,
geometryProcessor.get(),
stages.get(),
numColorStages,
numCoverageStages,
currAttribIndex,
drawType)) {
return false;
}
SkAutoTUnref<GrOptDrawState> optState(GrOptDrawState::Create(this->getDrawState(),
*this->caps(),
drawType));
SkAutoTUnref<GrGLProgram> program(
GrGLProgramBuilder::CreateProgram(*optState,
pdesc,
drawType,
geometryProcessor,
stages,
stages + numColorStages,
this));
for (int s = 0; s < numStages; ++s) {
SkDELETE(stages[s]);
}
if (NULL == program.get()) {
return false;
}
// We have to reset the drawstate because we might have added a gp
this->drawState()->reset();
}
return true;
}
std::vector<ModelObject> CoilHeatingGasMultiStage_Impl::children() const {
return subsetCastVector<ModelObject>(stages());
}
bool GrGpuGL::programUnitTest(int maxStages) {
GrTextureDesc dummyDesc;
dummyDesc.fFlags = kRenderTarget_GrTextureFlagBit;
dummyDesc.fConfig = kSkia8888_GrPixelConfig;
dummyDesc.fWidth = 34;
dummyDesc.fHeight = 18;
SkAutoTUnref<GrTexture> dummyTexture1(this->createTexture(dummyDesc, NULL, 0));
dummyDesc.fFlags = kNone_GrTextureFlags;
dummyDesc.fConfig = kAlpha_8_GrPixelConfig;
dummyDesc.fWidth = 16;
dummyDesc.fHeight = 22;
SkAutoTUnref<GrTexture> dummyTexture2(this->createTexture(dummyDesc, NULL, 0));
static const int NUM_TESTS = 512;
SkRandom random;
for (int t = 0; t < NUM_TESTS; ++t) {
#if 0
GrPrintf("\nTest Program %d\n-------------\n", t);
static const int stop = -1;
if (t == stop) {
int breakpointhere = 9;
}
#endif
GrGLProgramDesc pdesc;
int currAttribIndex = 1; // we need to always leave room for position
int currTextureCoordSet = 0;
int attribIndices[2] = { 0, 0 };
GrTexture* dummyTextures[] = {dummyTexture1.get(), dummyTexture2.get()};
int numStages = random.nextULessThan(maxStages + 1);
int numColorStages = random.nextULessThan(numStages + 1);
int numCoverageStages = numStages - numColorStages;
SkAutoSTMalloc<8, const GrEffectStage*> stages(numStages);
bool useFixedFunctionTexturing = this->shouldUseFixedFunctionTexturing();
for (int s = 0; s < numStages;) {
SkAutoTUnref<const GrEffectRef> effect(GrEffectTestFactory::CreateStage(
&random,
this->getContext(),
*this->caps(),
dummyTextures));
SkASSERT(effect);
int numAttribs = (*effect)->numVertexAttribs();
// If adding this effect would exceed the max attrib count then generate a
// new random effect.
if (currAttribIndex + numAttribs > GrDrawState::kMaxVertexAttribCnt) {
continue;
}
// If adding this effect would exceed the max texture coord set count then generate a
// new random effect.
if (useFixedFunctionTexturing && !(*effect)->hasVertexCode()) {
int numTransforms = (*effect)->numTransforms();
if (currTextureCoordSet + numTransforms > this->glCaps().maxFixedFunctionTextureCoords()) {
continue;
}
currTextureCoordSet += numTransforms;
}
useFixedFunctionTexturing = useFixedFunctionTexturing && !(*effect)->hasVertexCode();
for (int i = 0; i < numAttribs; ++i) {
attribIndices[i] = currAttribIndex++;
}
GrEffectStage* stage = SkNEW_ARGS(GrEffectStage,
(effect.get(), attribIndices[0], attribIndices[1]));
stages[s] = stage;
++s;
}
const GrTexture* dstTexture = random.nextBool() ? dummyTextures[0] : dummyTextures[1];
pdesc.setRandom(&random,
this,
dummyTextures[0]->asRenderTarget(),
dstTexture,
stages.get(),
numColorStages,
numCoverageStages,
currAttribIndex);
SkAutoTUnref<GrGLProgram> program(GrGLProgram::Create(this,
pdesc,
stages,
stages + numColorStages));
for (int s = 0; s < numStages; ++s) {
SkDELETE(stages[s]);
}
if (NULL == program.get()) {
return false;
}
}
return true;
}
void FrameRenderer::render( Camera& cam, Node& root, const Viewport& vp ) const
{
/* Start time measurement.
*/
Stopwatch stopwatch;
/* Check for errors.
*/
REPORT_GL_ERROR;
/* Reshape render stages' buffers.
*/
for( std::size_t rsIdx = 0; rsIdx < stages(); ++rsIdx )
{
RenderStage& rs = stageAt( rsIdx );
/* Ensure buffers are properly sized.
*/
if( pimpl->reshaped || !rs.isInitialized() )
{
/* This 'const_cast' is okay, because 'RenderStage' objects are clearly
* stated to be components of a 'FrameRenderer', thus "it runs in the
* family" as long as an immutable 'RenderStage' reference not induces a
* mutable 'FrameRenderer' reference.
*/
FrameRenderer& fr = const_cast< FrameRenderer& >( *this );
rs.reshape( fr, pimpl->viewport->width(), pimpl->viewport->height() );
}
/* Notify stages of beginning frame.
*/
rs.prepareFrame( root );
}
/* Mark that all buffer sizes have been established.
*/
pimpl->reshaped = false;
/* Clear buffers.
*/
glClearColor
( pimpl->backgroundColor[ 0 ]
, pimpl->backgroundColor[ 1 ]
, pimpl->backgroundColor[ 2 ]
, pimpl->backgroundColor[ 3 ] );
/* Render frame.
*/
RenderTask task( *this, cam.projection(), cam.viewTransform() );
task.render( vp, GLContext::COLOR_BUFFER_BIT | GLContext::DEPTH_BUFFER_BIT );
/* Check for errors.
*/
REPORT_GL_ERROR;
/* Stop and evaluate time measurement.
*/
const double time = stopwatch.result();
const double fps = 1 / time;
pimpl->fpsData.push( fps );
pimpl->fpsStatistics = math::Statistics< double >( pimpl->fpsData.size(),
[&]( std::size_t idx )->double
{
return pimpl->fpsData[ idx ];
}
);
}
std::vector<ModelObject> CoilCoolingDXMultiSpeed_Impl::children() const {
return subsetCastVector<ModelObject>(stages());
}
