Example #1
0
void TLoopIndexInfo::fillInfo(TIntermLoop *node)
{
    if (node == NULL)
        return;

    // Here we assume all the operations are valid, because the loop node is
    // already validated in ValidateLimitations.
    TIntermSequence *declSeq =
        node->getInit()->getAsAggregate()->getSequence();
    TIntermBinary *declInit = (*declSeq)[0]->getAsBinaryNode();
    TIntermSymbol *symbol = declInit->getLeft()->getAsSymbolNode();

    mId = symbol->getId();
    mType = symbol->getBasicType();

    if (mType == EbtInt)
    {
        TIntermConstantUnion* initNode = declInit->getRight()->getAsConstantUnion();
        mInitValue = EvaluateIntConstant(initNode);
        mCurrentValue = mInitValue;
        mIncrementValue = GetLoopIntIncrement(node);

        TIntermBinary* binOp = node->getCondition()->getAsBinaryNode();
        mStopValue = EvaluateIntConstant(
            binOp->getRight()->getAsConstantUnion());
        mOp = binOp->getOp();
    }
}
Example #2
0
int ValidateLimitations::validateForLoopInit(TIntermLoop *node)
{
    TIntermNode *init = node->getInit();
    if (init == NULL)
    {
        error(node->getLine(), "Missing init declaration", "for");
        return -1;
    }

    //
    // init-declaration has the form:
    //     type-specifier identifier = constant-expression
    //
    TIntermAggregate *decl = init->getAsAggregate();
    if ((decl == NULL) || (decl->getOp() != EOpDeclaration))
    {
        error(init->getLine(), "Invalid init declaration", "for");
        return -1;
    }
    // To keep things simple do not allow declaration list.
    TIntermSequence &declSeq = decl->getSequence();
    if (declSeq.size() != 1)
    {
        error(decl->getLine(), "Invalid init declaration", "for");
        return -1;
    }
    TIntermBinary *declInit = declSeq[0]->getAsBinaryNode();
    if ((declInit == NULL) || (declInit->getOp() != EOpInitialize))
    {
        error(decl->getLine(), "Invalid init declaration", "for");
        return -1;
    }
    TIntermSymbol *symbol = declInit->getLeft()->getAsSymbolNode();
    if (symbol == NULL)
    {
        error(declInit->getLine(), "Invalid init declaration", "for");
        return -1;
    }
    // The loop index has type int or float.
    TBasicType type = symbol->getBasicType();
    if ((type != EbtInt) && (type != EbtFloat))
    {
        error(symbol->getLine(),
              "Invalid type for loop index", getBasicString(type));
        return -1;
    }
    // The loop index is initialized with constant expression.
    if (!isConstExpr(declInit->getRight()))
    {
        error(declInit->getLine(),
              "Loop index cannot be initialized with non-constant expression",
              symbol->getSymbol().c_str());
        return -1;
    }

    return symbol->getId();
}
Example #3
0
bool TGlslOutputTraverser::parseInitializer( TIntermBinary *node )
{
   TIntermTyped *left, *right;

   left = node->getLeft();
   right = node->getRight();

   if (!left->getAsSymbolNode())
      return false; //Something is likely seriously wrong

   TIntermSymbol *symNode = left->getAsSymbolNode();
   

   if (symNode->getBasicType() == EbtStruct)
      return false;

   GlslSymbol * sym = NULL;

   if ( !current->hasSymbol( symNode->getId() ) )
   {
      int array = symNode->getTypePointer()->isArray() ? symNode->getTypePointer()->getArraySize() : 0;
      const char* semantic = "";

      if (symNode->getInfo())
         semantic = symNode->getInfo()->getSemantic().c_str();

      sym = new GlslSymbol( symNode->getSymbol().c_str(), semantic, symNode->getId(),
                            translateType(symNode->getTypePointer()), m_UsePrecision?node->getPrecision():EbpUndefined, translateQualifier(symNode->getQualifier()), array);

      current->addSymbol(sym);
   }
   else
      return false; //can't init already declared variable
	
	if (right->getAsTyped())
	{
		std::stringstream ss;
		std::stringstream* oldOut = &current->getActiveOutput();
		current->pushDepth(0);
		current->setActiveOutput(&ss);
		right->getAsTyped()->traverse(this);
		current->setActiveOutput(oldOut);
		current->popDepth();
		
		sym->setInitializer(ss.str());
	}

   return true;
}
void ForLoopUnroll::FillLoopIndexInfo(TIntermLoop* node, TLoopIndexInfo& info)
{
    ASSERT(node->getType() == ELoopFor);
    ASSERT(node->getUnrollFlag());

    TIntermNode* init = node->getInit();
    ASSERT(init != NULL);
    TIntermAggregate* decl = init->getAsAggregate();
    ASSERT((decl != NULL) && (decl->getOp() == EOpDeclaration));
    TIntermSequence& declSeq = decl->getSequence();
    ASSERT(declSeq.size() == 1);
    TIntermBinary* declInit = declSeq[0]->getAsBinaryNode();
    ASSERT((declInit != NULL) && (declInit->getOp() == EOpInitialize));
    TIntermSymbol* symbol = declInit->getLeft()->getAsSymbolNode();
    ASSERT(symbol != NULL);
    ASSERT(symbol->getBasicType() == EbtInt);

    info.id = symbol->getId();

    ASSERT(declInit->getRight() != NULL);
    TIntermConstantUnion* initNode = declInit->getRight()->getAsConstantUnion();
    ASSERT(initNode != NULL);

    info.initValue = evaluateIntConstant(initNode);
    info.currentValue = info.initValue;

    TIntermNode* cond = node->getCondition();
    ASSERT(cond != NULL);
    TIntermBinary* binOp = cond->getAsBinaryNode();
    ASSERT(binOp != NULL);
    ASSERT(binOp->getRight() != NULL);
    ASSERT(binOp->getRight()->getAsConstantUnion() != NULL);

    info.incrementValue = getLoopIncrement(node);
    info.stopValue = evaluateIntConstant(
        binOp->getRight()->getAsConstantUnion());
    info.op = binOp->getOp();
}
bool ValidateLimitations::visitBinary(Visit, TIntermBinary* node)
{
    // Check if loop index is modified in the loop body.
    validateOperation(node, node->getLeft());

    // Check indexing.
    switch (node->getOp()) {
      case EOpIndexDirect:
        validateIndexing(node);
        break;
      case EOpIndexIndirect:
#if defined(__APPLE__)
        // Loop unrolling is a work-around for a Mac Cg compiler bug where it
        // crashes when a sampler array's index is also the loop index.
        // Once Apple fixes this bug, we should remove the code in this CL.
        // See http://codereview.appspot.com/4331048/.
        if ((node->getLeft() != NULL) && (node->getRight() != NULL) &&
            (node->getLeft()->getAsSymbolNode())) {
            TIntermSymbol* symbol = node->getLeft()->getAsSymbolNode();
            if (IsSampler(symbol->getBasicType()) && symbol->isArray()) {
                ValidateLoopIndexExpr validate(mLoopStack);
                node->getRight()->traverse(&validate);
                if (validate.usesFloatLoopIndex()) {
                    error(node->getLine(),
                          "sampler array index is float loop index",
                          "for");
                }
            }
        }
#endif
        validateIndexing(node);
        break;
      default: break;
    }
    return true;
}
Example #6
0
bool TSamplerTraverser::traverseAggregate( bool preVisit, TIntermAggregate *node, TIntermTraverser *it)
{
   TSamplerTraverser* sit = static_cast<TSamplerTraverser*>(it);
   TInfoSink &infoSink = sit->infoSink;

   if (sit->abort)
      return false;

   if (! (sit->typing) )
   {
      switch (node->getOp())
      {
      
      case EOpFunction:
         // Store the current function name to use to setup the parameters
         sit->currentFunction = node->getName().c_str(); 
         break;

      case EOpParameters:
         // Store the parameters to the function in the map
         sit->functionMap[sit->currentFunction.c_str()] = &(node->getSequence());
         break;

      case EOpFunctionCall:
         {
            // This is a bit tricky.  Find the function in the map.  Loop over the parameters
            // and see if the parameters have been marked as a typed sampler.  If so, propagate
            // the sampler type to the caller
            if ( sit->functionMap.find ( node->getName().c_str() ) != sit->functionMap.end() )
            {
               // Get the sequence of function parameters
               TIntermSequence *funcSequence = sit->functionMap[node->getName().c_str()];
               
               // Get the sequence of parameters being passed to function
               TIntermSequence &sequence = node->getSequence();

               // Grab iterators to both sequences
               TIntermSequence::iterator it = sequence.begin();
               TIntermSequence::iterator funcIt = funcSequence->begin();

               assert ( sequence.size() == funcSequence->size() );
               if ( sequence.size() == funcSequence->size() )
               {
                  while ( it != sequence.end() )
                  {
                     TIntermSymbol *sym = (*it)->getAsSymbolNode();
                     TIntermSymbol *funcSym = (*funcIt)->getAsSymbolNode();
                     
                     if ( sym != NULL && funcSym != NULL)
                     {
                        // If the parameter is generic, and the sampler to which
                        // it is being passed has been marked, propogate its sampler
                        // type to the caller.
                        if ( sym->getBasicType() == EbtSamplerGeneric &&
                             funcSym->getBasicType() != EbtSamplerGeneric )
                        {
                           sit->typeSampler ( sym, funcSym->getBasicType() );
                        }
                     }
                     it++;
                     funcIt++;
                  }
               }
            }
         }
         break;

         //HLSL texture functions
      case EOpTex1D:
      case EOpTex1DProj:
      case EOpTex1DLod:
      case EOpTex1DBias:
      case EOpTex1DGrad:
         {
            TIntermSequence &sequence = node->getSequence();
            assert( sequence.size());
            TIntermTyped *sampArg = sequence[0]->getAsTyped();
            if ( sampArg)
            {
               if (sampArg->getBasicType() == EbtSamplerGeneric)
               {
                  //type the sampler
                  sit->typeSampler( sampArg, EbtSampler1D);
               }
               else if (sampArg->getBasicType() != EbtSampler1D)
               {
                  //We have a sampler mismatch error
                  infoSink.info << "Error: " << node->getLine() << ": Sampler type mismatch, likely using a generic sampler as two types\n";
               }
            }
            else
            {
               assert(0);
            }

         }
         // We need to continue the traverse here, because the calls could be nested 
         break;


      case EOpTex2D:
      case EOpTex2DProj:
      case EOpTex2DLod:
      case EOpTex2DBias:
      case EOpTex2DGrad:
         {
            TIntermSequence &sequence = node->getSequence();
            assert( sequence.size());
            TIntermTyped *sampArg = sequence[0]->getAsTyped();
            if ( sampArg)
            {
               if (sampArg->getBasicType() == EbtSamplerGeneric)
               {
                  //type the sampler
                  sit->typeSampler( sampArg, EbtSampler2D);
               }
               else if (sampArg->getBasicType() != EbtSampler2D)
               {
                  //We have a sampler mismatch error
                  infoSink.info << "Error: " << node->getLine() << ": Sampler type mismatch, likely using a generic sampler as two types\n";
               }
            }
            else
            {
               assert(0);
            }

         }
         // We need to continue the traverse here, because the calls could be nested 
         break;

	  case EOpTexRect:
	  case EOpTexRectProj:
		  {
			  TIntermSequence &sequence = node->getSequence();
			  assert( sequence.size());
			  TIntermTyped *sampArg = sequence[0]->getAsTyped();
			  if ( sampArg)
			  {
				  if (sampArg->getBasicType() == EbtSamplerGeneric)
				  {
					  //type the sampler
					  sit->typeSampler( sampArg, EbtSamplerRect);
				  }
				  else if (sampArg->getBasicType() != EbtSamplerRect)
				  {
					  //We have a sampler mismatch error
					  infoSink.info << "Error: " << node->getLine() << ": Sampler type mismatch, likely using a generic sampler as two types\n";
				  }
			  }
			  else
			  {
				  assert(0);
			  }
			  
		  }
		  // We need to continue the traverse here, because the calls could be nested 
		  break;
			  
			  
      case EOpTex3D:
      case EOpTex3DProj:
      case EOpTex3DLod:
      case EOpTex3DBias:
      case EOpTex3DGrad:
         {
            TIntermSequence &sequence = node->getSequence();
            assert( sequence.size());
            TIntermTyped *sampArg = sequence[0]->getAsTyped();
            if ( sampArg)
            {
               if (sampArg->getBasicType() == EbtSamplerGeneric)
               {
                  //type the sampler
                  sit->typeSampler( sampArg, EbtSampler3D);
               }
               else if (sampArg->getBasicType() != EbtSampler3D)
               {
                  //We have a sampler mismatch error
                  infoSink.info << "Error: " << node->getLine() << ": Sampler type mismatch, likely using a generic sampler as two types\n";
               }
            }
            else
            {
               assert(0);
            }

         }
         // We need to continue the traverse here, because the calls could be nested 
         break;

      case EOpTexCube:
      case EOpTexCubeProj:
      case EOpTexCubeLod:
      case EOpTexCubeBias:
      case EOpTexCubeGrad:
         {
            TIntermSequence &sequence = node->getSequence();
            assert( sequence.size());
            TIntermTyped *sampArg = sequence[0]->getAsTyped();
            if ( sampArg)
            {
               if (sampArg->getBasicType() == EbtSamplerGeneric)
               {
                  //type the sampler
                  sit->typeSampler( sampArg, EbtSamplerCube);
               }
               else if (sampArg->getBasicType() != EbtSamplerCube)
               {
                  //We have a sampler mismatch error
                  infoSink.info << "Error: " << node->getLine() << ": Sampler type mismatch, likely using a generic sampler as two types\n";
               }
            }
            else
            {
               assert(0);
            }

         }
         // We need to continue the traverse here, because the calls could be nested 
         break;

      default: 
         break;
      }
   }


   return !(sit->abort);
}