Esempio n. 1
0
void TranslatorESSL::translate(TIntermNode *root, int) {
    TInfoSinkBase& sink = getInfoSink().obj;

    int shaderVer = getShaderVersion();
    if (shaderVer > 100)
    {
        sink << "#version " << shaderVer << " es\n";
    }

    writePragma();

    // Write built-in extension behaviors.
    writeExtensionBehavior();

    bool precisionEmulation = getResources().WEBGL_debug_shader_precision && getPragma().debugShaderPrecision;

    if (precisionEmulation)
    {
        EmulatePrecision emulatePrecision(getSymbolTable(), shaderVer);
        root->traverse(&emulatePrecision);
        emulatePrecision.updateTree();
        emulatePrecision.writeEmulationHelpers(sink, SH_ESSL_OUTPUT);
    }

    RecordConstantPrecision(root, getTemporaryIndex());

    // Write emulated built-in functions if needed.
    if (!getBuiltInFunctionEmulator().IsOutputEmpty())
    {
        sink << "// BEGIN: Generated code for built-in function emulation\n\n";
        if (getShaderType() == GL_FRAGMENT_SHADER)
        {
            sink << "#if defined(GL_FRAGMENT_PRECISION_HIGH)\n"
                 << "#define webgl_emu_precision highp\n"
                 << "#else\n"
                 << "#define webgl_emu_precision mediump\n"
                 << "#endif\n\n";
        }
        else
        {
            sink << "#define webgl_emu_precision highp\n";
        }

        getBuiltInFunctionEmulator().OutputEmulatedFunctions(sink);
        sink << "// END: Generated code for built-in function emulation\n\n";
    }

    // Write array bounds clamping emulation if needed.
    getArrayBoundsClamper().OutputClampingFunctionDefinition(sink);

    // Write translated shader.
    TOutputESSL outputESSL(sink, getArrayIndexClampingStrategy(), getHashFunction(), getNameMap(),
                           getSymbolTable(), shaderVer, precisionEmulation);
    root->traverse(&outputESSL);
}
Esempio n. 2
0
TIntermNode *TCompiler::compileTreeImpl(const char *const shaderStrings[],
                                        size_t numStrings,
                                        const int compileOptions)
{
    clearResults();

    ASSERT(numStrings > 0);
    ASSERT(GetGlobalPoolAllocator());

    // Reset the extension behavior for each compilation unit.
    ResetExtensionBehavior(extensionBehavior);

    // First string is path of source file if flag is set. The actual source follows.
    size_t firstSource = 0;
    if (compileOptions & SH_SOURCE_PATH)
    {
        mSourcePath = shaderStrings[0];
        ++firstSource;
    }

    TIntermediate intermediate(infoSink);
    TParseContext parseContext(symbolTable, extensionBehavior, intermediate, shaderType, shaderSpec,
                               compileOptions, true, infoSink, getResources());

    parseContext.setFragmentPrecisionHighOnESSL1(fragmentPrecisionHigh);
    SetGlobalParseContext(&parseContext);

    // We preserve symbols at the built-in level from compile-to-compile.
    // Start pushing the user-defined symbols at global level.
    TScopedSymbolTableLevel scopedSymbolLevel(&symbolTable);

    // Parse shader.
    bool success =
        (PaParseStrings(numStrings - firstSource, &shaderStrings[firstSource], nullptr, &parseContext) == 0) &&
        (parseContext.getTreeRoot() != nullptr);

    shaderVersion = parseContext.getShaderVersion();
    if (success && MapSpecToShaderVersion(shaderSpec) < shaderVersion)
    {
        infoSink.info.prefix(EPrefixError);
        infoSink.info << "unsupported shader version";
        success = false;
    }

    TIntermNode *root = nullptr;

    if (success)
    {
        mPragma = parseContext.pragma();
        if (mPragma.stdgl.invariantAll)
        {
            symbolTable.setGlobalInvariant();
        }

        root = parseContext.getTreeRoot();
        root = intermediate.postProcess(root);

        // Highp might have been auto-enabled based on shader version
        fragmentPrecisionHigh = parseContext.getFragmentPrecisionHigh();

        // Disallow expressions deemed too complex.
        if (success && (compileOptions & SH_LIMIT_EXPRESSION_COMPLEXITY))
            success = limitExpressionComplexity(root);

        // Create the function DAG and check there is no recursion
        if (success)
            success = initCallDag(root);

        if (success && (compileOptions & SH_LIMIT_CALL_STACK_DEPTH))
            success = checkCallDepth();

        // Checks which functions are used and if "main" exists
        if (success)
        {
            functionMetadata.clear();
            functionMetadata.resize(mCallDag.size());
            success = tagUsedFunctions();
        }

        if (success && !(compileOptions & SH_DONT_PRUNE_UNUSED_FUNCTIONS))
            success = pruneUnusedFunctions(root);

        // Prune empty declarations to work around driver bugs and to keep declaration output simple.
        if (success)
            PruneEmptyDeclarations(root);

        if (success && shaderVersion == 300 && shaderType == GL_FRAGMENT_SHADER)
            success = validateOutputs(root);

        if (success && shouldRunLoopAndIndexingValidation(compileOptions))
            success = validateLimitations(root);

        if (success && (compileOptions & SH_TIMING_RESTRICTIONS))
            success = enforceTimingRestrictions(root, (compileOptions & SH_DEPENDENCY_GRAPH) != 0);

        if (success && shaderSpec == SH_CSS_SHADERS_SPEC)
            rewriteCSSShader(root);

        // Unroll for-loop markup needs to happen after validateLimitations pass.
        if (success && (compileOptions & SH_UNROLL_FOR_LOOP_WITH_INTEGER_INDEX))
        {
            ForLoopUnrollMarker marker(ForLoopUnrollMarker::kIntegerIndex,
                                       shouldRunLoopAndIndexingValidation(compileOptions));
            root->traverse(&marker);
        }
        if (success && (compileOptions & SH_UNROLL_FOR_LOOP_WITH_SAMPLER_ARRAY_INDEX))
        {
            ForLoopUnrollMarker marker(ForLoopUnrollMarker::kSamplerArrayIndex,
                                       shouldRunLoopAndIndexingValidation(compileOptions));
            root->traverse(&marker);
            if (marker.samplerArrayIndexIsFloatLoopIndex())
            {
                infoSink.info.prefix(EPrefixError);
                infoSink.info << "sampler array index is float loop index";
                success = false;
            }
        }

        // Built-in function emulation needs to happen after validateLimitations pass.
        if (success)
        {
            initBuiltInFunctionEmulator(&builtInFunctionEmulator, compileOptions);
            builtInFunctionEmulator.MarkBuiltInFunctionsForEmulation(root);
        }

        // Clamping uniform array bounds needs to happen after validateLimitations pass.
        if (success && (compileOptions & SH_CLAMP_INDIRECT_ARRAY_BOUNDS))
            arrayBoundsClamper.MarkIndirectArrayBoundsForClamping(root);

        // gl_Position is always written in compatibility output mode
        if (success && shaderType == GL_VERTEX_SHADER &&
            ((compileOptions & SH_INIT_GL_POSITION) ||
             (outputType == SH_GLSL_COMPATIBILITY_OUTPUT)))
            initializeGLPosition(root);

        // This pass might emit short circuits so keep it before the short circuit unfolding
        if (success && (compileOptions & SH_REWRITE_DO_WHILE_LOOPS))
            RewriteDoWhile(root, getTemporaryIndex());

        if (success && (compileOptions & SH_UNFOLD_SHORT_CIRCUIT))
        {
            UnfoldShortCircuitAST unfoldShortCircuit;
            root->traverse(&unfoldShortCircuit);
            unfoldShortCircuit.updateTree();
        }

        if (success && (compileOptions & SH_REMOVE_POW_WITH_CONSTANT_EXPONENT))
        {
            RemovePow(root);
        }

        if (success && shouldCollectVariables(compileOptions))
        {
            collectVariables(root);
            if (compileOptions & SH_ENFORCE_PACKING_RESTRICTIONS)
            {
                success = enforcePackingRestrictions();
                if (!success)
                {
                    infoSink.info.prefix(EPrefixError);
                    infoSink.info << "too many uniforms";
                }
            }
            if (success && shaderType == GL_VERTEX_SHADER &&
                (compileOptions & SH_INIT_VARYINGS_WITHOUT_STATIC_USE))
                initializeVaryingsWithoutStaticUse(root);
        }

        if (success && (compileOptions & SH_SCALARIZE_VEC_AND_MAT_CONSTRUCTOR_ARGS))
        {
            ScalarizeVecAndMatConstructorArgs scalarizer(
                shaderType, fragmentPrecisionHigh);
            root->traverse(&scalarizer);
        }

        if (success && (compileOptions & SH_REGENERATE_STRUCT_NAMES))
        {
            RegenerateStructNames gen(symbolTable, shaderVersion);
            root->traverse(&gen);
        }
    }

    SetGlobalParseContext(NULL);
    if (success)
        return root;

    return NULL;
}
Esempio n. 3
0
void TranslatorHLSL::translate(TIntermNode *root, int compileOptions)
{
    const ShBuiltInResources &resources = getResources();
    int numRenderTargets = resources.EXT_draw_buffers ? resources.MaxDrawBuffers : 1;

    sh::AddDefaultReturnStatements(root);

    SeparateDeclarations(root);

    // TODO (oetuaho): Sequence operators should also be split in case there is dynamic indexing of
    // a vector or matrix as an l-value inside (RemoveDynamicIndexing transformation step generates
    // statements in this case).
    SplitSequenceOperator(root,
                          IntermNodePatternMatcher::kExpressionReturningArray |
                              IntermNodePatternMatcher::kUnfoldedShortCircuitExpression |
                              IntermNodePatternMatcher::kDynamicIndexingOfVectorOrMatrixInLValue,
                          getTemporaryIndex(), getSymbolTable(), getShaderVersion());

    // Note that SeparateDeclarations needs to be run before UnfoldShortCircuitToIf.
    UnfoldShortCircuitToIf(root, getTemporaryIndex());

    SeparateExpressionsReturningArrays(root, getTemporaryIndex());

    // Note that SeparateDeclarations needs to be run before SeparateArrayInitialization.
    SeparateArrayInitialization(root);

    // HLSL doesn't support arrays as return values, we'll need to make functions that have an array
    // as a return value to use an out parameter to transfer the array data instead.
    ArrayReturnValueToOutParameter(root, getTemporaryIndex());

    if (!shouldRunLoopAndIndexingValidation(compileOptions))
    {
        // HLSL doesn't support dynamic indexing of vectors and matrices.
        RemoveDynamicIndexing(root, getTemporaryIndex(), getSymbolTable(), getShaderVersion());
    }

    // Work around D3D9 bug that would manifest in vertex shaders with selection blocks which
    // use a vertex attribute as a condition, and some related computation in the else block.
    if (getOutputType() == SH_HLSL_3_0_OUTPUT && getShaderType() == GL_VERTEX_SHADER)
    {
        sh::RewriteElseBlocks(root, getTemporaryIndex());
    }

    bool precisionEmulation =
        getResources().WEBGL_debug_shader_precision && getPragma().debugShaderPrecision;

    if (precisionEmulation)
    {
        EmulatePrecision emulatePrecision(getSymbolTable(), getShaderVersion());
        root->traverse(&emulatePrecision);
        emulatePrecision.updateTree();
        emulatePrecision.writeEmulationHelpers(getInfoSink().obj, getShaderVersion(),
                                               getOutputType());
    }

    if ((compileOptions & SH_EXPAND_SELECT_HLSL_INTEGER_POW_EXPRESSIONS) != 0)
    {
        sh::ExpandIntegerPowExpressions(root, getTemporaryIndex());
    }

    sh::OutputHLSL outputHLSL(getShaderType(), getShaderVersion(), getExtensionBehavior(),
        getSourcePath(), getOutputType(), numRenderTargets, getUniforms(), compileOptions);

    outputHLSL.output(root, getInfoSink().obj);

    mInterfaceBlockRegisterMap = outputHLSL.getInterfaceBlockRegisterMap();
    mUniformRegisterMap = outputHLSL.getUniformRegisterMap();
}