zdray/thirdparty/ShaderCompiler/glslang/MachineIndependent/intermOut.cpp

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2021-10-28 21:26:53 +00:00
//
// Copyright (C) 2002-2005 3Dlabs Inc. Ltd.
// Copyright (C) 2012-2016 LunarG, Inc.
// Copyright (C) 2017 ARM Limited.
//
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions
// are met:
//
// Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
//
// Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following
// disclaimer in the documentation and/or other materials provided
// with the distribution.
//
// Neither the name of 3Dlabs Inc. Ltd. nor the names of its
// contributors may be used to endorse or promote products derived
// from this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
// FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
// COPYRIGHT HOLDERS OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
// INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
// BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
// LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
// CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
// LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
// ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
#include "localintermediate.h"
#include "../Include/InfoSink.h"
#ifdef _MSC_VER
#include <cfloat>
#else
#include <cmath>
#endif
namespace {
bool IsInfinity(double x) {
#ifdef _MSC_VER
switch (_fpclass(x)) {
case _FPCLASS_NINF:
case _FPCLASS_PINF:
return true;
default:
return false;
}
#else
return std::isinf(x);
#endif
}
bool IsNan(double x) {
#ifdef _MSC_VER
switch (_fpclass(x)) {
case _FPCLASS_SNAN:
case _FPCLASS_QNAN:
return true;
default:
return false;
}
#else
return std::isnan(x);
#endif
}
}
namespace glslang {
//
// Two purposes:
// 1. Show an example of how to iterate tree. Functions can
// also directly call Traverse() on children themselves to
// have finer grained control over the process than shown here.
// See the last function for how to get started.
// 2. Print out a text based description of the tree.
//
//
// Use this class to carry along data from node to node in
// the traversal
//
class TOutputTraverser : public TIntermTraverser {
public:
TOutputTraverser(TInfoSink& i) : infoSink(i), extraOutput(NoExtraOutput) { }
enum EExtraOutput {
NoExtraOutput,
BinaryDoubleOutput
};
void setDoubleOutput(EExtraOutput extra) { extraOutput = extra; }
virtual bool visitBinary(TVisit, TIntermBinary* node);
virtual bool visitUnary(TVisit, TIntermUnary* node);
virtual bool visitAggregate(TVisit, TIntermAggregate* node);
virtual bool visitSelection(TVisit, TIntermSelection* node);
virtual void visitConstantUnion(TIntermConstantUnion* node);
virtual void visitSymbol(TIntermSymbol* node);
virtual bool visitLoop(TVisit, TIntermLoop* node);
virtual bool visitBranch(TVisit, TIntermBranch* node);
virtual bool visitSwitch(TVisit, TIntermSwitch* node);
TInfoSink& infoSink;
protected:
TOutputTraverser(TOutputTraverser&);
TOutputTraverser& operator=(TOutputTraverser&);
EExtraOutput extraOutput;
};
//
// Helper functions for printing, not part of traversing.
//
static void OutputTreeText(TInfoSink& infoSink, const TIntermNode* node, const int depth)
{
int i;
infoSink.debug << node->getLoc().string << ":";
if (node->getLoc().line)
infoSink.debug << node->getLoc().line;
else
infoSink.debug << "? ";
for (i = 0; i < depth; ++i)
infoSink.debug << " ";
}
//
// The rest of the file are the traversal functions. The last one
// is the one that starts the traversal.
//
// Return true from interior nodes to have the external traversal
// continue on to children. If you process children yourself,
// return false.
//
bool TOutputTraverser::visitBinary(TVisit /* visit */, TIntermBinary* node)
{
TInfoSink& out = infoSink;
OutputTreeText(out, node, depth);
switch (node->getOp()) {
case EOpAssign: out.debug << "move second child to first child"; break;
case EOpAddAssign: out.debug << "add second child into first child"; break;
case EOpSubAssign: out.debug << "subtract second child into first child"; break;
case EOpMulAssign: out.debug << "multiply second child into first child"; break;
case EOpVectorTimesMatrixAssign: out.debug << "matrix mult second child into first child"; break;
case EOpVectorTimesScalarAssign: out.debug << "vector scale second child into first child"; break;
case EOpMatrixTimesScalarAssign: out.debug << "matrix scale second child into first child"; break;
case EOpMatrixTimesMatrixAssign: out.debug << "matrix mult second child into first child"; break;
case EOpDivAssign: out.debug << "divide second child into first child"; break;
case EOpModAssign: out.debug << "mod second child into first child"; break;
case EOpAndAssign: out.debug << "and second child into first child"; break;
case EOpInclusiveOrAssign: out.debug << "or second child into first child"; break;
case EOpExclusiveOrAssign: out.debug << "exclusive or second child into first child"; break;
case EOpLeftShiftAssign: out.debug << "left shift second child into first child"; break;
case EOpRightShiftAssign: out.debug << "right shift second child into first child"; break;
case EOpIndexDirect: out.debug << "direct index"; break;
case EOpIndexIndirect: out.debug << "indirect index"; break;
case EOpIndexDirectStruct:
{
bool reference = node->getLeft()->getType().getBasicType() == EbtReference;
const TTypeList *members = reference ? node->getLeft()->getType().getReferentType()->getStruct() : node->getLeft()->getType().getStruct();
out.debug << (*members)[node->getRight()->getAsConstantUnion()->getConstArray()[0].getIConst()].type->getFieldName();
out.debug << ": direct index for structure"; break;
}
case EOpVectorSwizzle: out.debug << "vector swizzle"; break;
case EOpMatrixSwizzle: out.debug << "matrix swizzle"; break;
case EOpAdd: out.debug << "add"; break;
case EOpSub: out.debug << "subtract"; break;
case EOpMul: out.debug << "component-wise multiply"; break;
case EOpDiv: out.debug << "divide"; break;
case EOpMod: out.debug << "mod"; break;
case EOpRightShift: out.debug << "right-shift"; break;
case EOpLeftShift: out.debug << "left-shift"; break;
case EOpAnd: out.debug << "bitwise and"; break;
case EOpInclusiveOr: out.debug << "inclusive-or"; break;
case EOpExclusiveOr: out.debug << "exclusive-or"; break;
case EOpEqual: out.debug << "Compare Equal"; break;
case EOpNotEqual: out.debug << "Compare Not Equal"; break;
case EOpLessThan: out.debug << "Compare Less Than"; break;
case EOpGreaterThan: out.debug << "Compare Greater Than"; break;
case EOpLessThanEqual: out.debug << "Compare Less Than or Equal"; break;
case EOpGreaterThanEqual: out.debug << "Compare Greater Than or Equal"; break;
case EOpVectorEqual: out.debug << "Equal"; break;
case EOpVectorNotEqual: out.debug << "NotEqual"; break;
case EOpVectorTimesScalar: out.debug << "vector-scale"; break;
case EOpVectorTimesMatrix: out.debug << "vector-times-matrix"; break;
case EOpMatrixTimesVector: out.debug << "matrix-times-vector"; break;
case EOpMatrixTimesScalar: out.debug << "matrix-scale"; break;
case EOpMatrixTimesMatrix: out.debug << "matrix-multiply"; break;
case EOpLogicalOr: out.debug << "logical-or"; break;
case EOpLogicalXor: out.debug << "logical-xor"; break;
case EOpLogicalAnd: out.debug << "logical-and"; break;
default: out.debug << "<unknown op>";
}
out.debug << " (" << node->getCompleteString() << ")";
out.debug << "\n";
return true;
}
bool TOutputTraverser::visitUnary(TVisit /* visit */, TIntermUnary* node)
{
TInfoSink& out = infoSink;
OutputTreeText(out, node, depth);
switch (node->getOp()) {
case EOpNegative: out.debug << "Negate value"; break;
case EOpVectorLogicalNot:
case EOpLogicalNot: out.debug << "Negate conditional"; break;
case EOpBitwiseNot: out.debug << "Bitwise not"; break;
case EOpPostIncrement: out.debug << "Post-Increment"; break;
case EOpPostDecrement: out.debug << "Post-Decrement"; break;
case EOpPreIncrement: out.debug << "Pre-Increment"; break;
case EOpPreDecrement: out.debug << "Pre-Decrement"; break;
// * -> bool
case EOpConvInt8ToBool: out.debug << "Convert int8_t to bool"; break;
case EOpConvUint8ToBool: out.debug << "Convert uint8_t to bool"; break;
case EOpConvInt16ToBool: out.debug << "Convert int16_t to bool"; break;
case EOpConvUint16ToBool: out.debug << "Convert uint16_t to bool";break;
case EOpConvIntToBool: out.debug << "Convert int to bool"; break;
case EOpConvUintToBool: out.debug << "Convert uint to bool"; break;
case EOpConvInt64ToBool: out.debug << "Convert int64 to bool"; break;
case EOpConvUint64ToBool: out.debug << "Convert uint64 to bool"; break;
case EOpConvFloat16ToBool: out.debug << "Convert float16_t to bool"; break;
case EOpConvFloatToBool: out.debug << "Convert float to bool"; break;
case EOpConvDoubleToBool: out.debug << "Convert double to bool"; break;
// bool -> *
case EOpConvBoolToInt8: out.debug << "Convert bool to int8_t"; break;
case EOpConvBoolToUint8: out.debug << "Convert bool to uint8_t"; break;
case EOpConvBoolToInt16: out.debug << "Convert bool to in16t_t"; break;
case EOpConvBoolToUint16: out.debug << "Convert bool to uint16_t";break;
case EOpConvBoolToInt: out.debug << "Convert bool to int" ; break;
case EOpConvBoolToUint: out.debug << "Convert bool to uint"; break;
case EOpConvBoolToInt64: out.debug << "Convert bool to int64"; break;
case EOpConvBoolToUint64: out.debug << "Convert bool to uint64";break;
case EOpConvBoolToFloat16: out.debug << "Convert bool to float16_t"; break;
case EOpConvBoolToFloat: out.debug << "Convert bool to float"; break;
case EOpConvBoolToDouble: out.debug << "Convert bool to double"; break;
// int8_t -> (u)int*
case EOpConvInt8ToInt16: out.debug << "Convert int8_t to int16_t";break;
case EOpConvInt8ToInt: out.debug << "Convert int8_t to int"; break;
case EOpConvInt8ToInt64: out.debug << "Convert int8_t to int64"; break;
case EOpConvInt8ToUint8: out.debug << "Convert int8_t to uint8_t";break;
case EOpConvInt8ToUint16: out.debug << "Convert int8_t to uint16_t";break;
case EOpConvInt8ToUint: out.debug << "Convert int8_t to uint"; break;
case EOpConvInt8ToUint64: out.debug << "Convert int8_t to uint64"; break;
// uint8_t -> (u)int*
case EOpConvUint8ToInt8: out.debug << "Convert uint8_t to int8_t";break;
case EOpConvUint8ToInt16: out.debug << "Convert uint8_t to int16_t";break;
case EOpConvUint8ToInt: out.debug << "Convert uint8_t to int"; break;
case EOpConvUint8ToInt64: out.debug << "Convert uint8_t to int64"; break;
case EOpConvUint8ToUint16: out.debug << "Convert uint8_t to uint16_t";break;
case EOpConvUint8ToUint: out.debug << "Convert uint8_t to uint"; break;
case EOpConvUint8ToUint64: out.debug << "Convert uint8_t to uint64"; break;
// int8_t -> float*
case EOpConvInt8ToFloat16: out.debug << "Convert int8_t to float16_t";break;
case EOpConvInt8ToFloat: out.debug << "Convert int8_t to float"; break;
case EOpConvInt8ToDouble: out.debug << "Convert int8_t to double"; break;
// uint8_t -> float*
case EOpConvUint8ToFloat16: out.debug << "Convert uint8_t to float16_t";break;
case EOpConvUint8ToFloat: out.debug << "Convert uint8_t to float"; break;
case EOpConvUint8ToDouble: out.debug << "Convert uint8_t to double"; break;
// int16_t -> (u)int*
case EOpConvInt16ToInt8: out.debug << "Convert int16_t to int8_t";break;
case EOpConvInt16ToInt: out.debug << "Convert int16_t to int"; break;
case EOpConvInt16ToInt64: out.debug << "Convert int16_t to int64"; break;
case EOpConvInt16ToUint8: out.debug << "Convert int16_t to uint8_t";break;
case EOpConvInt16ToUint16: out.debug << "Convert int16_t to uint16_t";break;
case EOpConvInt16ToUint: out.debug << "Convert int16_t to uint"; break;
case EOpConvInt16ToUint64: out.debug << "Convert int16_t to uint64"; break;
// int16_t -> float*
case EOpConvInt16ToFloat16: out.debug << "Convert int16_t to float16_t";break;
case EOpConvInt16ToFloat: out.debug << "Convert int16_t to float"; break;
case EOpConvInt16ToDouble: out.debug << "Convert int16_t to double"; break;
// uint16_t -> (u)int*
case EOpConvUint16ToInt8: out.debug << "Convert uint16_t to int8_t";break;
case EOpConvUint16ToInt16: out.debug << "Convert uint16_t to int16_t";break;
case EOpConvUint16ToInt: out.debug << "Convert uint16_t to int"; break;
case EOpConvUint16ToInt64: out.debug << "Convert uint16_t to int64"; break;
case EOpConvUint16ToUint8: out.debug << "Convert uint16_t to uint8_t";break;
case EOpConvUint16ToUint: out.debug << "Convert uint16_t to uint"; break;
case EOpConvUint16ToUint64: out.debug << "Convert uint16_t to uint64"; break;
// uint16_t -> float*
case EOpConvUint16ToFloat16: out.debug << "Convert uint16_t to float16_t";break;
case EOpConvUint16ToFloat: out.debug << "Convert uint16_t to float"; break;
case EOpConvUint16ToDouble: out.debug << "Convert uint16_t to double"; break;
// int32_t -> (u)int*
case EOpConvIntToInt8: out.debug << "Convert int to int8_t";break;
case EOpConvIntToInt16: out.debug << "Convert int to int16_t";break;
case EOpConvIntToInt64: out.debug << "Convert int to int64"; break;
case EOpConvIntToUint8: out.debug << "Convert int to uint8_t";break;
case EOpConvIntToUint16: out.debug << "Convert int to uint16_t";break;
case EOpConvIntToUint: out.debug << "Convert int to uint"; break;
case EOpConvIntToUint64: out.debug << "Convert int to uint64"; break;
// int32_t -> float*
case EOpConvIntToFloat16: out.debug << "Convert int to float16_t";break;
case EOpConvIntToFloat: out.debug << "Convert int to float"; break;
case EOpConvIntToDouble: out.debug << "Convert int to double"; break;
// uint32_t -> (u)int*
case EOpConvUintToInt8: out.debug << "Convert uint to int8_t";break;
case EOpConvUintToInt16: out.debug << "Convert uint to int16_t";break;
case EOpConvUintToInt: out.debug << "Convert uint to int";break;
case EOpConvUintToInt64: out.debug << "Convert uint to int64"; break;
case EOpConvUintToUint8: out.debug << "Convert uint to uint8_t";break;
case EOpConvUintToUint16: out.debug << "Convert uint to uint16_t";break;
case EOpConvUintToUint64: out.debug << "Convert uint to uint64"; break;
// uint32_t -> float*
case EOpConvUintToFloat16: out.debug << "Convert uint to float16_t";break;
case EOpConvUintToFloat: out.debug << "Convert uint to float"; break;
case EOpConvUintToDouble: out.debug << "Convert uint to double"; break;
// int64 -> (u)int*
case EOpConvInt64ToInt8: out.debug << "Convert int64 to int8_t"; break;
case EOpConvInt64ToInt16: out.debug << "Convert int64 to int16_t"; break;
case EOpConvInt64ToInt: out.debug << "Convert int64 to int"; break;
case EOpConvInt64ToUint8: out.debug << "Convert int64 to uint8_t";break;
case EOpConvInt64ToUint16: out.debug << "Convert int64 to uint16_t";break;
case EOpConvInt64ToUint: out.debug << "Convert int64 to uint"; break;
case EOpConvInt64ToUint64: out.debug << "Convert int64 to uint64"; break;
// int64 -> float*
case EOpConvInt64ToFloat16: out.debug << "Convert int64 to float16_t";break;
case EOpConvInt64ToFloat: out.debug << "Convert int64 to float"; break;
case EOpConvInt64ToDouble: out.debug << "Convert int64 to double"; break;
// uint64 -> (u)int*
case EOpConvUint64ToInt8: out.debug << "Convert uint64 to int8_t";break;
case EOpConvUint64ToInt16: out.debug << "Convert uint64 to int16_t";break;
case EOpConvUint64ToInt: out.debug << "Convert uint64 to int"; break;
case EOpConvUint64ToInt64: out.debug << "Convert uint64 to int64"; break;
case EOpConvUint64ToUint8: out.debug << "Convert uint64 to uint8_t";break;
case EOpConvUint64ToUint16: out.debug << "Convert uint64 to uint16"; break;
case EOpConvUint64ToUint: out.debug << "Convert uint64 to uint"; break;
// uint64 -> float*
case EOpConvUint64ToFloat16: out.debug << "Convert uint64 to float16_t";break;
case EOpConvUint64ToFloat: out.debug << "Convert uint64 to float"; break;
case EOpConvUint64ToDouble: out.debug << "Convert uint64 to double"; break;
// float16_t -> int*
case EOpConvFloat16ToInt8: out.debug << "Convert float16_t to int8_t"; break;
case EOpConvFloat16ToInt16: out.debug << "Convert float16_t to int16_t"; break;
case EOpConvFloat16ToInt: out.debug << "Convert float16_t to int"; break;
case EOpConvFloat16ToInt64: out.debug << "Convert float16_t to int64"; break;
// float16_t -> uint*
case EOpConvFloat16ToUint8: out.debug << "Convert float16_t to uint8_t"; break;
case EOpConvFloat16ToUint16: out.debug << "Convert float16_t to uint16_t"; break;
case EOpConvFloat16ToUint: out.debug << "Convert float16_t to uint"; break;
case EOpConvFloat16ToUint64: out.debug << "Convert float16_t to uint64"; break;
// float16_t -> float*
case EOpConvFloat16ToFloat: out.debug << "Convert float16_t to float"; break;
case EOpConvFloat16ToDouble: out.debug << "Convert float16_t to double"; break;
// float32 -> float*
case EOpConvFloatToFloat16: out.debug << "Convert float to float16_t"; break;
case EOpConvFloatToDouble: out.debug << "Convert float to double"; break;
// float32_t -> int*
case EOpConvFloatToInt8: out.debug << "Convert float to int8_t"; break;
case EOpConvFloatToInt16: out.debug << "Convert float to int16_t"; break;
case EOpConvFloatToInt: out.debug << "Convert float to int"; break;
case EOpConvFloatToInt64: out.debug << "Convert float to int64"; break;
// float32_t -> uint*
case EOpConvFloatToUint8: out.debug << "Convert float to uint8_t"; break;
case EOpConvFloatToUint16: out.debug << "Convert float to uint16_t"; break;
case EOpConvFloatToUint: out.debug << "Convert float to uint"; break;
case EOpConvFloatToUint64: out.debug << "Convert float to uint64"; break;
// double -> float*
case EOpConvDoubleToFloat16: out.debug << "Convert double to float16_t"; break;
case EOpConvDoubleToFloat: out.debug << "Convert double to float"; break;
// double -> int*
case EOpConvDoubleToInt8: out.debug << "Convert double to int8_t"; break;
case EOpConvDoubleToInt16: out.debug << "Convert double to int16_t"; break;
case EOpConvDoubleToInt: out.debug << "Convert double to int"; break;
case EOpConvDoubleToInt64: out.debug << "Convert double to int64"; break;
// float32_t -> uint*
case EOpConvDoubleToUint8: out.debug << "Convert double to uint8_t"; break;
case EOpConvDoubleToUint16: out.debug << "Convert double to uint16_t"; break;
case EOpConvDoubleToUint: out.debug << "Convert double to uint"; break;
case EOpConvDoubleToUint64: out.debug << "Convert double to uint64"; break;
case EOpConvUint64ToPtr: out.debug << "Convert uint64_t to pointer"; break;
case EOpConvPtrToUint64: out.debug << "Convert pointer to uint64_t"; break;
case EOpRadians: out.debug << "radians"; break;
case EOpDegrees: out.debug << "degrees"; break;
case EOpSin: out.debug << "sine"; break;
case EOpCos: out.debug << "cosine"; break;
case EOpTan: out.debug << "tangent"; break;
case EOpAsin: out.debug << "arc sine"; break;
case EOpAcos: out.debug << "arc cosine"; break;
case EOpAtan: out.debug << "arc tangent"; break;
case EOpSinh: out.debug << "hyp. sine"; break;
case EOpCosh: out.debug << "hyp. cosine"; break;
case EOpTanh: out.debug << "hyp. tangent"; break;
case EOpAsinh: out.debug << "arc hyp. sine"; break;
case EOpAcosh: out.debug << "arc hyp. cosine"; break;
case EOpAtanh: out.debug << "arc hyp. tangent"; break;
case EOpExp: out.debug << "exp"; break;
case EOpLog: out.debug << "log"; break;
case EOpExp2: out.debug << "exp2"; break;
case EOpLog2: out.debug << "log2"; break;
case EOpSqrt: out.debug << "sqrt"; break;
case EOpInverseSqrt: out.debug << "inverse sqrt"; break;
case EOpAbs: out.debug << "Absolute value"; break;
case EOpSign: out.debug << "Sign"; break;
case EOpFloor: out.debug << "Floor"; break;
case EOpTrunc: out.debug << "trunc"; break;
case EOpRound: out.debug << "round"; break;
case EOpRoundEven: out.debug << "roundEven"; break;
case EOpCeil: out.debug << "Ceiling"; break;
case EOpFract: out.debug << "Fraction"; break;
case EOpIsNan: out.debug << "isnan"; break;
case EOpIsInf: out.debug << "isinf"; break;
case EOpFloatBitsToInt: out.debug << "floatBitsToInt"; break;
case EOpFloatBitsToUint:out.debug << "floatBitsToUint"; break;
case EOpIntBitsToFloat: out.debug << "intBitsToFloat"; break;
case EOpUintBitsToFloat:out.debug << "uintBitsToFloat"; break;
case EOpDoubleBitsToInt64: out.debug << "doubleBitsToInt64"; break;
case EOpDoubleBitsToUint64: out.debug << "doubleBitsToUint64"; break;
case EOpInt64BitsToDouble: out.debug << "int64BitsToDouble"; break;
case EOpUint64BitsToDouble: out.debug << "uint64BitsToDouble"; break;
case EOpFloat16BitsToInt16: out.debug << "float16BitsToInt16"; break;
case EOpFloat16BitsToUint16: out.debug << "float16BitsToUint16"; break;
case EOpInt16BitsToFloat16: out.debug << "int16BitsToFloat16"; break;
case EOpUint16BitsToFloat16: out.debug << "uint16BitsToFloat16"; break;
case EOpPackSnorm2x16: out.debug << "packSnorm2x16"; break;
case EOpUnpackSnorm2x16:out.debug << "unpackSnorm2x16"; break;
case EOpPackUnorm2x16: out.debug << "packUnorm2x16"; break;
case EOpUnpackUnorm2x16:out.debug << "unpackUnorm2x16"; break;
case EOpPackHalf2x16: out.debug << "packHalf2x16"; break;
case EOpUnpackHalf2x16: out.debug << "unpackHalf2x16"; break;
case EOpPack16: out.debug << "pack16"; break;
case EOpPack32: out.debug << "pack32"; break;
case EOpPack64: out.debug << "pack64"; break;
case EOpUnpack32: out.debug << "unpack32"; break;
case EOpUnpack16: out.debug << "unpack16"; break;
case EOpUnpack8: out.debug << "unpack8"; break;
case EOpPackSnorm4x8: out.debug << "PackSnorm4x8"; break;
case EOpUnpackSnorm4x8: out.debug << "UnpackSnorm4x8"; break;
case EOpPackUnorm4x8: out.debug << "PackUnorm4x8"; break;
case EOpUnpackUnorm4x8: out.debug << "UnpackUnorm4x8"; break;
case EOpPackDouble2x32: out.debug << "PackDouble2x32"; break;
case EOpUnpackDouble2x32: out.debug << "UnpackDouble2x32"; break;
case EOpPackInt2x32: out.debug << "packInt2x32"; break;
case EOpUnpackInt2x32: out.debug << "unpackInt2x32"; break;
case EOpPackUint2x32: out.debug << "packUint2x32"; break;
case EOpUnpackUint2x32: out.debug << "unpackUint2x32"; break;
case EOpPackInt2x16: out.debug << "packInt2x16"; break;
case EOpUnpackInt2x16: out.debug << "unpackInt2x16"; break;
case EOpPackUint2x16: out.debug << "packUint2x16"; break;
case EOpUnpackUint2x16: out.debug << "unpackUint2x16"; break;
case EOpPackInt4x16: out.debug << "packInt4x16"; break;
case EOpUnpackInt4x16: out.debug << "unpackInt4x16"; break;
case EOpPackUint4x16: out.debug << "packUint4x16"; break;
case EOpUnpackUint4x16: out.debug << "unpackUint4x16"; break;
case EOpPackFloat2x16: out.debug << "packFloat2x16"; break;
case EOpUnpackFloat2x16: out.debug << "unpackFloat2x16"; break;
case EOpLength: out.debug << "length"; break;
case EOpNormalize: out.debug << "normalize"; break;
case EOpDPdx: out.debug << "dPdx"; break;
case EOpDPdy: out.debug << "dPdy"; break;
case EOpFwidth: out.debug << "fwidth"; break;
case EOpDPdxFine: out.debug << "dPdxFine"; break;
case EOpDPdyFine: out.debug << "dPdyFine"; break;
case EOpFwidthFine: out.debug << "fwidthFine"; break;
case EOpDPdxCoarse: out.debug << "dPdxCoarse"; break;
case EOpDPdyCoarse: out.debug << "dPdyCoarse"; break;
case EOpFwidthCoarse: out.debug << "fwidthCoarse"; break;
case EOpInterpolateAtCentroid: out.debug << "interpolateAtCentroid"; break;
case EOpDeterminant: out.debug << "determinant"; break;
case EOpMatrixInverse: out.debug << "inverse"; break;
case EOpTranspose: out.debug << "transpose"; break;
case EOpAny: out.debug << "any"; break;
case EOpAll: out.debug << "all"; break;
case EOpArrayLength: out.debug << "array length"; break;
case EOpEmitStreamVertex: out.debug << "EmitStreamVertex"; break;
case EOpEndStreamPrimitive: out.debug << "EndStreamPrimitive"; break;
case EOpAtomicCounterIncrement: out.debug << "AtomicCounterIncrement";break;
case EOpAtomicCounterDecrement: out.debug << "AtomicCounterDecrement";break;
case EOpAtomicCounter: out.debug << "AtomicCounter"; break;
case EOpTextureQuerySize: out.debug << "textureSize"; break;
case EOpTextureQueryLod: out.debug << "textureQueryLod"; break;
case EOpTextureQueryLevels: out.debug << "textureQueryLevels"; break;
case EOpTextureQuerySamples: out.debug << "textureSamples"; break;
case EOpImageQuerySize: out.debug << "imageQuerySize"; break;
case EOpImageQuerySamples: out.debug << "imageQuerySamples"; break;
case EOpImageLoad: out.debug << "imageLoad"; break;
case EOpBitFieldReverse: out.debug << "bitFieldReverse"; break;
case EOpBitCount: out.debug << "bitCount"; break;
case EOpFindLSB: out.debug << "findLSB"; break;
case EOpFindMSB: out.debug << "findMSB"; break;
case EOpNoise: out.debug << "noise"; break;
case EOpBallot: out.debug << "ballot"; break;
case EOpReadFirstInvocation: out.debug << "readFirstInvocation"; break;
case EOpAnyInvocation: out.debug << "anyInvocation"; break;
case EOpAllInvocations: out.debug << "allInvocations"; break;
case EOpAllInvocationsEqual: out.debug << "allInvocationsEqual"; break;
case EOpSubgroupElect: out.debug << "subgroupElect"; break;
case EOpSubgroupAll: out.debug << "subgroupAll"; break;
case EOpSubgroupAny: out.debug << "subgroupAny"; break;
case EOpSubgroupAllEqual: out.debug << "subgroupAllEqual"; break;
case EOpSubgroupBroadcast: out.debug << "subgroupBroadcast"; break;
case EOpSubgroupBroadcastFirst: out.debug << "subgroupBroadcastFirst"; break;
case EOpSubgroupBallot: out.debug << "subgroupBallot"; break;
case EOpSubgroupInverseBallot: out.debug << "subgroupInverseBallot"; break;
case EOpSubgroupBallotBitExtract: out.debug << "subgroupBallotBitExtract"; break;
case EOpSubgroupBallotBitCount: out.debug << "subgroupBallotBitCount"; break;
case EOpSubgroupBallotInclusiveBitCount: out.debug << "subgroupBallotInclusiveBitCount"; break;
case EOpSubgroupBallotExclusiveBitCount: out.debug << "subgroupBallotExclusiveBitCount"; break;
case EOpSubgroupBallotFindLSB: out.debug << "subgroupBallotFindLSB"; break;
case EOpSubgroupBallotFindMSB: out.debug << "subgroupBallotFindMSB"; break;
case EOpSubgroupShuffle: out.debug << "subgroupShuffle"; break;
case EOpSubgroupShuffleXor: out.debug << "subgroupShuffleXor"; break;
case EOpSubgroupShuffleUp: out.debug << "subgroupShuffleUp"; break;
case EOpSubgroupShuffleDown: out.debug << "subgroupShuffleDown"; break;
case EOpSubgroupAdd: out.debug << "subgroupAdd"; break;
case EOpSubgroupMul: out.debug << "subgroupMul"; break;
case EOpSubgroupMin: out.debug << "subgroupMin"; break;
case EOpSubgroupMax: out.debug << "subgroupMax"; break;
case EOpSubgroupAnd: out.debug << "subgroupAnd"; break;
case EOpSubgroupOr: out.debug << "subgroupOr"; break;
case EOpSubgroupXor: out.debug << "subgroupXor"; break;
case EOpSubgroupInclusiveAdd: out.debug << "subgroupInclusiveAdd"; break;
case EOpSubgroupInclusiveMul: out.debug << "subgroupInclusiveMul"; break;
case EOpSubgroupInclusiveMin: out.debug << "subgroupInclusiveMin"; break;
case EOpSubgroupInclusiveMax: out.debug << "subgroupInclusiveMax"; break;
case EOpSubgroupInclusiveAnd: out.debug << "subgroupInclusiveAnd"; break;
case EOpSubgroupInclusiveOr: out.debug << "subgroupInclusiveOr"; break;
case EOpSubgroupInclusiveXor: out.debug << "subgroupInclusiveXor"; break;
case EOpSubgroupExclusiveAdd: out.debug << "subgroupExclusiveAdd"; break;
case EOpSubgroupExclusiveMul: out.debug << "subgroupExclusiveMul"; break;
case EOpSubgroupExclusiveMin: out.debug << "subgroupExclusiveMin"; break;
case EOpSubgroupExclusiveMax: out.debug << "subgroupExclusiveMax"; break;
case EOpSubgroupExclusiveAnd: out.debug << "subgroupExclusiveAnd"; break;
case EOpSubgroupExclusiveOr: out.debug << "subgroupExclusiveOr"; break;
case EOpSubgroupExclusiveXor: out.debug << "subgroupExclusiveXor"; break;
case EOpSubgroupClusteredAdd: out.debug << "subgroupClusteredAdd"; break;
case EOpSubgroupClusteredMul: out.debug << "subgroupClusteredMul"; break;
case EOpSubgroupClusteredMin: out.debug << "subgroupClusteredMin"; break;
case EOpSubgroupClusteredMax: out.debug << "subgroupClusteredMax"; break;
case EOpSubgroupClusteredAnd: out.debug << "subgroupClusteredAnd"; break;
case EOpSubgroupClusteredOr: out.debug << "subgroupClusteredOr"; break;
case EOpSubgroupClusteredXor: out.debug << "subgroupClusteredXor"; break;
case EOpSubgroupQuadBroadcast: out.debug << "subgroupQuadBroadcast"; break;
case EOpSubgroupQuadSwapHorizontal: out.debug << "subgroupQuadSwapHorizontal"; break;
case EOpSubgroupQuadSwapVertical: out.debug << "subgroupQuadSwapVertical"; break;
case EOpSubgroupQuadSwapDiagonal: out.debug << "subgroupQuadSwapDiagonal"; break;
#ifdef NV_EXTENSIONS
case EOpSubgroupPartition: out.debug << "subgroupPartitionNV"; break;
case EOpSubgroupPartitionedAdd: out.debug << "subgroupPartitionedAddNV"; break;
case EOpSubgroupPartitionedMul: out.debug << "subgroupPartitionedMulNV"; break;
case EOpSubgroupPartitionedMin: out.debug << "subgroupPartitionedMinNV"; break;
case EOpSubgroupPartitionedMax: out.debug << "subgroupPartitionedMaxNV"; break;
case EOpSubgroupPartitionedAnd: out.debug << "subgroupPartitionedAndNV"; break;
case EOpSubgroupPartitionedOr: out.debug << "subgroupPartitionedOrNV"; break;
case EOpSubgroupPartitionedXor: out.debug << "subgroupPartitionedXorNV"; break;
case EOpSubgroupPartitionedInclusiveAdd: out.debug << "subgroupPartitionedInclusiveAddNV"; break;
case EOpSubgroupPartitionedInclusiveMul: out.debug << "subgroupPartitionedInclusiveMulNV"; break;
case EOpSubgroupPartitionedInclusiveMin: out.debug << "subgroupPartitionedInclusiveMinNV"; break;
case EOpSubgroupPartitionedInclusiveMax: out.debug << "subgroupPartitionedInclusiveMaxNV"; break;
case EOpSubgroupPartitionedInclusiveAnd: out.debug << "subgroupPartitionedInclusiveAndNV"; break;
case EOpSubgroupPartitionedInclusiveOr: out.debug << "subgroupPartitionedInclusiveOrNV"; break;
case EOpSubgroupPartitionedInclusiveXor: out.debug << "subgroupPartitionedInclusiveXorNV"; break;
case EOpSubgroupPartitionedExclusiveAdd: out.debug << "subgroupPartitionedExclusiveAddNV"; break;
case EOpSubgroupPartitionedExclusiveMul: out.debug << "subgroupPartitionedExclusiveMulNV"; break;
case EOpSubgroupPartitionedExclusiveMin: out.debug << "subgroupPartitionedExclusiveMinNV"; break;
case EOpSubgroupPartitionedExclusiveMax: out.debug << "subgroupPartitionedExclusiveMaxNV"; break;
case EOpSubgroupPartitionedExclusiveAnd: out.debug << "subgroupPartitionedExclusiveAndNV"; break;
case EOpSubgroupPartitionedExclusiveOr: out.debug << "subgroupPartitionedExclusiveOrNV"; break;
case EOpSubgroupPartitionedExclusiveXor: out.debug << "subgroupPartitionedExclusiveXorNV"; break;
#endif
case EOpClip: out.debug << "clip"; break;
case EOpIsFinite: out.debug << "isfinite"; break;
case EOpLog10: out.debug << "log10"; break;
case EOpRcp: out.debug << "rcp"; break;
case EOpSaturate: out.debug << "saturate"; break;
case EOpSparseTexelsResident: out.debug << "sparseTexelsResident"; break;
#ifdef AMD_EXTENSIONS
case EOpMinInvocations: out.debug << "minInvocations"; break;
case EOpMaxInvocations: out.debug << "maxInvocations"; break;
case EOpAddInvocations: out.debug << "addInvocations"; break;
case EOpMinInvocationsNonUniform: out.debug << "minInvocationsNonUniform"; break;
case EOpMaxInvocationsNonUniform: out.debug << "maxInvocationsNonUniform"; break;
case EOpAddInvocationsNonUniform: out.debug << "addInvocationsNonUniform"; break;
case EOpMinInvocationsInclusiveScan: out.debug << "minInvocationsInclusiveScan"; break;
case EOpMaxInvocationsInclusiveScan: out.debug << "maxInvocationsInclusiveScan"; break;
case EOpAddInvocationsInclusiveScan: out.debug << "addInvocationsInclusiveScan"; break;
case EOpMinInvocationsInclusiveScanNonUniform: out.debug << "minInvocationsInclusiveScanNonUniform"; break;
case EOpMaxInvocationsInclusiveScanNonUniform: out.debug << "maxInvocationsInclusiveScanNonUniform"; break;
case EOpAddInvocationsInclusiveScanNonUniform: out.debug << "addInvocationsInclusiveScanNonUniform"; break;
case EOpMinInvocationsExclusiveScan: out.debug << "minInvocationsExclusiveScan"; break;
case EOpMaxInvocationsExclusiveScan: out.debug << "maxInvocationsExclusiveScan"; break;
case EOpAddInvocationsExclusiveScan: out.debug << "addInvocationsExclusiveScan"; break;
case EOpMinInvocationsExclusiveScanNonUniform: out.debug << "minInvocationsExclusiveScanNonUniform"; break;
case EOpMaxInvocationsExclusiveScanNonUniform: out.debug << "maxInvocationsExclusiveScanNonUniform"; break;
case EOpAddInvocationsExclusiveScanNonUniform: out.debug << "addInvocationsExclusiveScanNonUniform"; break;
case EOpMbcnt: out.debug << "mbcnt"; break;
case EOpFragmentMaskFetch: out.debug << "fragmentMaskFetchAMD"; break;
case EOpFragmentFetch: out.debug << "fragmentFetchAMD"; break;
case EOpCubeFaceIndex: out.debug << "cubeFaceIndex"; break;
case EOpCubeFaceCoord: out.debug << "cubeFaceCoord"; break;
#endif
case EOpSubpassLoad: out.debug << "subpassLoad"; break;
case EOpSubpassLoadMS: out.debug << "subpassLoadMS"; break;
case EOpConstructReference: out.debug << "Construct reference type"; break;
default: out.debug.message(EPrefixError, "Bad unary op");
}
out.debug << " (" << node->getCompleteString() << ")";
out.debug << "\n";
return true;
}
bool TOutputTraverser::visitAggregate(TVisit /* visit */, TIntermAggregate* node)
{
TInfoSink& out = infoSink;
if (node->getOp() == EOpNull) {
out.debug.message(EPrefixError, "node is still EOpNull!");
return true;
}
OutputTreeText(out, node, depth);
switch (node->getOp()) {
case EOpSequence: out.debug << "Sequence\n"; return true;
case EOpLinkerObjects: out.debug << "Linker Objects\n"; return true;
case EOpComma: out.debug << "Comma"; break;
case EOpFunction: out.debug << "Function Definition: " << node->getName(); break;
case EOpFunctionCall: out.debug << "Function Call: " << node->getName(); break;
case EOpParameters: out.debug << "Function Parameters: "; break;
case EOpConstructFloat: out.debug << "Construct float"; break;
case EOpConstructDouble:out.debug << "Construct double"; break;
case EOpConstructVec2: out.debug << "Construct vec2"; break;
case EOpConstructVec3: out.debug << "Construct vec3"; break;
case EOpConstructVec4: out.debug << "Construct vec4"; break;
case EOpConstructDVec2: out.debug << "Construct dvec2"; break;
case EOpConstructDVec3: out.debug << "Construct dvec3"; break;
case EOpConstructDVec4: out.debug << "Construct dvec4"; break;
case EOpConstructBool: out.debug << "Construct bool"; break;
case EOpConstructBVec2: out.debug << "Construct bvec2"; break;
case EOpConstructBVec3: out.debug << "Construct bvec3"; break;
case EOpConstructBVec4: out.debug << "Construct bvec4"; break;
case EOpConstructInt8: out.debug << "Construct int8_t"; break;
case EOpConstructI8Vec2: out.debug << "Construct i8vec2"; break;
case EOpConstructI8Vec3: out.debug << "Construct i8vec3"; break;
case EOpConstructI8Vec4: out.debug << "Construct i8vec4"; break;
case EOpConstructInt: out.debug << "Construct int"; break;
case EOpConstructIVec2: out.debug << "Construct ivec2"; break;
case EOpConstructIVec3: out.debug << "Construct ivec3"; break;
case EOpConstructIVec4: out.debug << "Construct ivec4"; break;
case EOpConstructUint8: out.debug << "Construct uint8_t"; break;
case EOpConstructU8Vec2: out.debug << "Construct u8vec2"; break;
case EOpConstructU8Vec3: out.debug << "Construct u8vec3"; break;
case EOpConstructU8Vec4: out.debug << "Construct u8vec4"; break;
case EOpConstructUint: out.debug << "Construct uint"; break;
case EOpConstructUVec2: out.debug << "Construct uvec2"; break;
case EOpConstructUVec3: out.debug << "Construct uvec3"; break;
case EOpConstructUVec4: out.debug << "Construct uvec4"; break;
case EOpConstructInt64: out.debug << "Construct int64"; break;
case EOpConstructI64Vec2: out.debug << "Construct i64vec2"; break;
case EOpConstructI64Vec3: out.debug << "Construct i64vec3"; break;
case EOpConstructI64Vec4: out.debug << "Construct i64vec4"; break;
case EOpConstructUint64: out.debug << "Construct uint64"; break;
case EOpConstructU64Vec2: out.debug << "Construct u64vec2"; break;
case EOpConstructU64Vec3: out.debug << "Construct u64vec3"; break;
case EOpConstructU64Vec4: out.debug << "Construct u64vec4"; break;
case EOpConstructInt16: out.debug << "Construct int16_t"; break;
case EOpConstructI16Vec2: out.debug << "Construct i16vec2"; break;
case EOpConstructI16Vec3: out.debug << "Construct i16vec3"; break;
case EOpConstructI16Vec4: out.debug << "Construct i16vec4"; break;
case EOpConstructUint16: out.debug << "Construct uint16_t"; break;
case EOpConstructU16Vec2: out.debug << "Construct u16vec2"; break;
case EOpConstructU16Vec3: out.debug << "Construct u16vec3"; break;
case EOpConstructU16Vec4: out.debug << "Construct u16vec4"; break;
case EOpConstructMat2x2: out.debug << "Construct mat2"; break;
case EOpConstructMat2x3: out.debug << "Construct mat2x3"; break;
case EOpConstructMat2x4: out.debug << "Construct mat2x4"; break;
case EOpConstructMat3x2: out.debug << "Construct mat3x2"; break;
case EOpConstructMat3x3: out.debug << "Construct mat3"; break;
case EOpConstructMat3x4: out.debug << "Construct mat3x4"; break;
case EOpConstructMat4x2: out.debug << "Construct mat4x2"; break;
case EOpConstructMat4x3: out.debug << "Construct mat4x3"; break;
case EOpConstructMat4x4: out.debug << "Construct mat4"; break;
case EOpConstructDMat2x2: out.debug << "Construct dmat2"; break;
case EOpConstructDMat2x3: out.debug << "Construct dmat2x3"; break;
case EOpConstructDMat2x4: out.debug << "Construct dmat2x4"; break;
case EOpConstructDMat3x2: out.debug << "Construct dmat3x2"; break;
case EOpConstructDMat3x3: out.debug << "Construct dmat3"; break;
case EOpConstructDMat3x4: out.debug << "Construct dmat3x4"; break;
case EOpConstructDMat4x2: out.debug << "Construct dmat4x2"; break;
case EOpConstructDMat4x3: out.debug << "Construct dmat4x3"; break;
case EOpConstructDMat4x4: out.debug << "Construct dmat4"; break;
case EOpConstructIMat2x2: out.debug << "Construct imat2"; break;
case EOpConstructIMat2x3: out.debug << "Construct imat2x3"; break;
case EOpConstructIMat2x4: out.debug << "Construct imat2x4"; break;
case EOpConstructIMat3x2: out.debug << "Construct imat3x2"; break;
case EOpConstructIMat3x3: out.debug << "Construct imat3"; break;
case EOpConstructIMat3x4: out.debug << "Construct imat3x4"; break;
case EOpConstructIMat4x2: out.debug << "Construct imat4x2"; break;
case EOpConstructIMat4x3: out.debug << "Construct imat4x3"; break;
case EOpConstructIMat4x4: out.debug << "Construct imat4"; break;
case EOpConstructUMat2x2: out.debug << "Construct umat2"; break;
case EOpConstructUMat2x3: out.debug << "Construct umat2x3"; break;
case EOpConstructUMat2x4: out.debug << "Construct umat2x4"; break;
case EOpConstructUMat3x2: out.debug << "Construct umat3x2"; break;
case EOpConstructUMat3x3: out.debug << "Construct umat3"; break;
case EOpConstructUMat3x4: out.debug << "Construct umat3x4"; break;
case EOpConstructUMat4x2: out.debug << "Construct umat4x2"; break;
case EOpConstructUMat4x3: out.debug << "Construct umat4x3"; break;
case EOpConstructUMat4x4: out.debug << "Construct umat4"; break;
case EOpConstructBMat2x2: out.debug << "Construct bmat2"; break;
case EOpConstructBMat2x3: out.debug << "Construct bmat2x3"; break;
case EOpConstructBMat2x4: out.debug << "Construct bmat2x4"; break;
case EOpConstructBMat3x2: out.debug << "Construct bmat3x2"; break;
case EOpConstructBMat3x3: out.debug << "Construct bmat3"; break;
case EOpConstructBMat3x4: out.debug << "Construct bmat3x4"; break;
case EOpConstructBMat4x2: out.debug << "Construct bmat4x2"; break;
case EOpConstructBMat4x3: out.debug << "Construct bmat4x3"; break;
case EOpConstructBMat4x4: out.debug << "Construct bmat4"; break;
case EOpConstructFloat16: out.debug << "Construct float16_t"; break;
case EOpConstructF16Vec2: out.debug << "Construct f16vec2"; break;
case EOpConstructF16Vec3: out.debug << "Construct f16vec3"; break;
case EOpConstructF16Vec4: out.debug << "Construct f16vec4"; break;
case EOpConstructF16Mat2x2: out.debug << "Construct f16mat2"; break;
case EOpConstructF16Mat2x3: out.debug << "Construct f16mat2x3"; break;
case EOpConstructF16Mat2x4: out.debug << "Construct f16mat2x4"; break;
case EOpConstructF16Mat3x2: out.debug << "Construct f16mat3x2"; break;
case EOpConstructF16Mat3x3: out.debug << "Construct f16mat3"; break;
case EOpConstructF16Mat3x4: out.debug << "Construct f16mat3x4"; break;
case EOpConstructF16Mat4x2: out.debug << "Construct f16mat4x2"; break;
case EOpConstructF16Mat4x3: out.debug << "Construct f16mat4x3"; break;
case EOpConstructF16Mat4x4: out.debug << "Construct f16mat4"; break;
case EOpConstructStruct: out.debug << "Construct structure"; break;
case EOpConstructTextureSampler: out.debug << "Construct combined texture-sampler"; break;
case EOpConstructReference: out.debug << "Construct reference"; break;
case EOpLessThan: out.debug << "Compare Less Than"; break;
case EOpGreaterThan: out.debug << "Compare Greater Than"; break;
case EOpLessThanEqual: out.debug << "Compare Less Than or Equal"; break;
case EOpGreaterThanEqual: out.debug << "Compare Greater Than or Equal"; break;
case EOpVectorEqual: out.debug << "Equal"; break;
case EOpVectorNotEqual: out.debug << "NotEqual"; break;
case EOpMod: out.debug << "mod"; break;
case EOpModf: out.debug << "modf"; break;
case EOpPow: out.debug << "pow"; break;
case EOpAtan: out.debug << "arc tangent"; break;
case EOpMin: out.debug << "min"; break;
case EOpMax: out.debug << "max"; break;
case EOpClamp: out.debug << "clamp"; break;
case EOpMix: out.debug << "mix"; break;
case EOpStep: out.debug << "step"; break;
case EOpSmoothStep: out.debug << "smoothstep"; break;
case EOpDistance: out.debug << "distance"; break;
case EOpDot: out.debug << "dot-product"; break;
case EOpCross: out.debug << "cross-product"; break;
case EOpFaceForward: out.debug << "face-forward"; break;
case EOpReflect: out.debug << "reflect"; break;
case EOpRefract: out.debug << "refract"; break;
case EOpMul: out.debug << "component-wise multiply"; break;
case EOpOuterProduct: out.debug << "outer product"; break;
case EOpEmitVertex: out.debug << "EmitVertex"; break;
case EOpEndPrimitive: out.debug << "EndPrimitive"; break;
case EOpBarrier: out.debug << "Barrier"; break;
case EOpMemoryBarrier: out.debug << "MemoryBarrier"; break;
case EOpMemoryBarrierAtomicCounter: out.debug << "MemoryBarrierAtomicCounter"; break;
case EOpMemoryBarrierBuffer: out.debug << "MemoryBarrierBuffer"; break;
case EOpMemoryBarrierImage: out.debug << "MemoryBarrierImage"; break;
case EOpMemoryBarrierShared: out.debug << "MemoryBarrierShared"; break;
case EOpGroupMemoryBarrier: out.debug << "GroupMemoryBarrier"; break;
case EOpReadInvocation: out.debug << "readInvocation"; break;
#ifdef AMD_EXTENSIONS
case EOpSwizzleInvocations: out.debug << "swizzleInvocations"; break;
case EOpSwizzleInvocationsMasked: out.debug << "swizzleInvocationsMasked"; break;
case EOpWriteInvocation: out.debug << "writeInvocation"; break;
case EOpMin3: out.debug << "min3"; break;
case EOpMax3: out.debug << "max3"; break;
case EOpMid3: out.debug << "mid3"; break;
case EOpTime: out.debug << "time"; break;
#endif
case EOpAtomicAdd: out.debug << "AtomicAdd"; break;
case EOpAtomicMin: out.debug << "AtomicMin"; break;
case EOpAtomicMax: out.debug << "AtomicMax"; break;
case EOpAtomicAnd: out.debug << "AtomicAnd"; break;
case EOpAtomicOr: out.debug << "AtomicOr"; break;
case EOpAtomicXor: out.debug << "AtomicXor"; break;
case EOpAtomicExchange: out.debug << "AtomicExchange"; break;
case EOpAtomicCompSwap: out.debug << "AtomicCompSwap"; break;
case EOpAtomicLoad: out.debug << "AtomicLoad"; break;
case EOpAtomicStore: out.debug << "AtomicStore"; break;
case EOpAtomicCounterAdd: out.debug << "AtomicCounterAdd"; break;
case EOpAtomicCounterSubtract: out.debug << "AtomicCounterSubtract"; break;
case EOpAtomicCounterMin: out.debug << "AtomicCounterMin"; break;
case EOpAtomicCounterMax: out.debug << "AtomicCounterMax"; break;
case EOpAtomicCounterAnd: out.debug << "AtomicCounterAnd"; break;
case EOpAtomicCounterOr: out.debug << "AtomicCounterOr"; break;
case EOpAtomicCounterXor: out.debug << "AtomicCounterXor"; break;
case EOpAtomicCounterExchange: out.debug << "AtomicCounterExchange"; break;
case EOpAtomicCounterCompSwap: out.debug << "AtomicCounterCompSwap"; break;
case EOpImageQuerySize: out.debug << "imageQuerySize"; break;
case EOpImageQuerySamples: out.debug << "imageQuerySamples"; break;
case EOpImageLoad: out.debug << "imageLoad"; break;
case EOpImageStore: out.debug << "imageStore"; break;
case EOpImageAtomicAdd: out.debug << "imageAtomicAdd"; break;
case EOpImageAtomicMin: out.debug << "imageAtomicMin"; break;
case EOpImageAtomicMax: out.debug << "imageAtomicMax"; break;
case EOpImageAtomicAnd: out.debug << "imageAtomicAnd"; break;
case EOpImageAtomicOr: out.debug << "imageAtomicOr"; break;
case EOpImageAtomicXor: out.debug << "imageAtomicXor"; break;
case EOpImageAtomicExchange: out.debug << "imageAtomicExchange"; break;
case EOpImageAtomicCompSwap: out.debug << "imageAtomicCompSwap"; break;
case EOpImageAtomicLoad: out.debug << "imageAtomicLoad"; break;
case EOpImageAtomicStore: out.debug << "imageAtomicStore"; break;
#ifdef AMD_EXTENSIONS
case EOpImageLoadLod: out.debug << "imageLoadLod"; break;
case EOpImageStoreLod: out.debug << "imageStoreLod"; break;
#endif
case EOpTextureQuerySize: out.debug << "textureSize"; break;
case EOpTextureQueryLod: out.debug << "textureQueryLod"; break;
case EOpTextureQueryLevels: out.debug << "textureQueryLevels"; break;
case EOpTextureQuerySamples: out.debug << "textureSamples"; break;
case EOpTexture: out.debug << "texture"; break;
case EOpTextureProj: out.debug << "textureProj"; break;
case EOpTextureLod: out.debug << "textureLod"; break;
case EOpTextureOffset: out.debug << "textureOffset"; break;
case EOpTextureFetch: out.debug << "textureFetch"; break;
case EOpTextureFetchOffset: out.debug << "textureFetchOffset"; break;
case EOpTextureProjOffset: out.debug << "textureProjOffset"; break;
case EOpTextureLodOffset: out.debug << "textureLodOffset"; break;
case EOpTextureProjLod: out.debug << "textureProjLod"; break;
case EOpTextureProjLodOffset: out.debug << "textureProjLodOffset"; break;
case EOpTextureGrad: out.debug << "textureGrad"; break;
case EOpTextureGradOffset: out.debug << "textureGradOffset"; break;
case EOpTextureProjGrad: out.debug << "textureProjGrad"; break;
case EOpTextureProjGradOffset: out.debug << "textureProjGradOffset"; break;
case EOpTextureGather: out.debug << "textureGather"; break;
case EOpTextureGatherOffset: out.debug << "textureGatherOffset"; break;
case EOpTextureGatherOffsets: out.debug << "textureGatherOffsets"; break;
case EOpTextureClamp: out.debug << "textureClamp"; break;
case EOpTextureOffsetClamp: out.debug << "textureOffsetClamp"; break;
case EOpTextureGradClamp: out.debug << "textureGradClamp"; break;
case EOpTextureGradOffsetClamp: out.debug << "textureGradOffsetClamp"; break;
#ifdef AMD_EXTENSIONS
case EOpTextureGatherLod: out.debug << "textureGatherLod"; break;
case EOpTextureGatherLodOffset: out.debug << "textureGatherLodOffset"; break;
case EOpTextureGatherLodOffsets: out.debug << "textureGatherLodOffsets"; break;
#endif
case EOpSparseTexture: out.debug << "sparseTexture"; break;
case EOpSparseTextureOffset: out.debug << "sparseTextureOffset"; break;
case EOpSparseTextureLod: out.debug << "sparseTextureLod"; break;
case EOpSparseTextureLodOffset: out.debug << "sparseTextureLodOffset"; break;
case EOpSparseTextureFetch: out.debug << "sparseTexelFetch"; break;
case EOpSparseTextureFetchOffset: out.debug << "sparseTexelFetchOffset"; break;
case EOpSparseTextureGrad: out.debug << "sparseTextureGrad"; break;
case EOpSparseTextureGradOffset: out.debug << "sparseTextureGradOffset"; break;
case EOpSparseTextureGather: out.debug << "sparseTextureGather"; break;
case EOpSparseTextureGatherOffset: out.debug << "sparseTextureGatherOffset"; break;
case EOpSparseTextureGatherOffsets: out.debug << "sparseTextureGatherOffsets"; break;
case EOpSparseImageLoad: out.debug << "sparseImageLoad"; break;
case EOpSparseTextureClamp: out.debug << "sparseTextureClamp"; break;
case EOpSparseTextureOffsetClamp: out.debug << "sparseTextureOffsetClamp"; break;
case EOpSparseTextureGradClamp: out.debug << "sparseTextureGradClamp"; break;
case EOpSparseTextureGradOffsetClamp: out.debug << "sparseTextureGradOffsetClam"; break;
#ifdef AMD_EXTENSIONS
case EOpSparseTextureGatherLod: out.debug << "sparseTextureGatherLod"; break;
case EOpSparseTextureGatherLodOffset: out.debug << "sparseTextureGatherLodOffset"; break;
case EOpSparseTextureGatherLodOffsets: out.debug << "sparseTextureGatherLodOffsets"; break;
case EOpSparseImageLoadLod: out.debug << "sparseImageLoadLod"; break;
#endif
#ifdef NV_EXTENSIONS
case EOpImageSampleFootprintNV: out.debug << "imageSampleFootprintNV"; break;
case EOpImageSampleFootprintClampNV: out.debug << "imageSampleFootprintClampNV"; break;
case EOpImageSampleFootprintLodNV: out.debug << "imageSampleFootprintLodNV"; break;
case EOpImageSampleFootprintGradNV: out.debug << "imageSampleFootprintGradNV"; break;
case EOpImageSampleFootprintGradClampNV: out.debug << "mageSampleFootprintGradClampNV"; break;
#endif
case EOpAddCarry: out.debug << "addCarry"; break;
case EOpSubBorrow: out.debug << "subBorrow"; break;
case EOpUMulExtended: out.debug << "uMulExtended"; break;
case EOpIMulExtended: out.debug << "iMulExtended"; break;
case EOpBitfieldExtract: out.debug << "bitfieldExtract"; break;
case EOpBitfieldInsert: out.debug << "bitfieldInsert"; break;
case EOpFma: out.debug << "fma"; break;
case EOpFrexp: out.debug << "frexp"; break;
case EOpLdexp: out.debug << "ldexp"; break;
case EOpInterpolateAtSample: out.debug << "interpolateAtSample"; break;
case EOpInterpolateAtOffset: out.debug << "interpolateAtOffset"; break;
#ifdef AMD_EXTENSIONS
case EOpInterpolateAtVertex: out.debug << "interpolateAtVertex"; break;
#endif
case EOpSinCos: out.debug << "sincos"; break;
case EOpGenMul: out.debug << "mul"; break;
case EOpAllMemoryBarrierWithGroupSync: out.debug << "AllMemoryBarrierWithGroupSync"; break;
case EOpDeviceMemoryBarrier: out.debug << "DeviceMemoryBarrier"; break;
case EOpDeviceMemoryBarrierWithGroupSync: out.debug << "DeviceMemoryBarrierWithGroupSync"; break;
case EOpWorkgroupMemoryBarrier: out.debug << "WorkgroupMemoryBarrier"; break;
case EOpWorkgroupMemoryBarrierWithGroupSync: out.debug << "WorkgroupMemoryBarrierWithGroupSync"; break;
case EOpSubgroupBarrier: out.debug << "subgroupBarrier"; break;
case EOpSubgroupMemoryBarrier: out.debug << "subgroupMemoryBarrier"; break;
case EOpSubgroupMemoryBarrierBuffer: out.debug << "subgroupMemoryBarrierBuffer"; break;
case EOpSubgroupMemoryBarrierImage: out.debug << "subgroupMemoryBarrierImage"; break;
case EOpSubgroupMemoryBarrierShared: out.debug << "subgroupMemoryBarrierShared"; break;
case EOpSubgroupElect: out.debug << "subgroupElect"; break;
case EOpSubgroupAll: out.debug << "subgroupAll"; break;
case EOpSubgroupAny: out.debug << "subgroupAny"; break;
case EOpSubgroupAllEqual: out.debug << "subgroupAllEqual"; break;
case EOpSubgroupBroadcast: out.debug << "subgroupBroadcast"; break;
case EOpSubgroupBroadcastFirst: out.debug << "subgroupBroadcastFirst"; break;
case EOpSubgroupBallot: out.debug << "subgroupBallot"; break;
case EOpSubgroupInverseBallot: out.debug << "subgroupInverseBallot"; break;
case EOpSubgroupBallotBitExtract: out.debug << "subgroupBallotBitExtract"; break;
case EOpSubgroupBallotBitCount: out.debug << "subgroupBallotBitCount"; break;
case EOpSubgroupBallotInclusiveBitCount: out.debug << "subgroupBallotInclusiveBitCount"; break;
case EOpSubgroupBallotExclusiveBitCount: out.debug << "subgroupBallotExclusiveBitCount"; break;
case EOpSubgroupBallotFindLSB: out.debug << "subgroupBallotFindLSB"; break;
case EOpSubgroupBallotFindMSB: out.debug << "subgroupBallotFindMSB"; break;
case EOpSubgroupShuffle: out.debug << "subgroupShuffle"; break;
case EOpSubgroupShuffleXor: out.debug << "subgroupShuffleXor"; break;
case EOpSubgroupShuffleUp: out.debug << "subgroupShuffleUp"; break;
case EOpSubgroupShuffleDown: out.debug << "subgroupShuffleDown"; break;
case EOpSubgroupAdd: out.debug << "subgroupAdd"; break;
case EOpSubgroupMul: out.debug << "subgroupMul"; break;
case EOpSubgroupMin: out.debug << "subgroupMin"; break;
case EOpSubgroupMax: out.debug << "subgroupMax"; break;
case EOpSubgroupAnd: out.debug << "subgroupAnd"; break;
case EOpSubgroupOr: out.debug << "subgroupOr"; break;
case EOpSubgroupXor: out.debug << "subgroupXor"; break;
case EOpSubgroupInclusiveAdd: out.debug << "subgroupInclusiveAdd"; break;
case EOpSubgroupInclusiveMul: out.debug << "subgroupInclusiveMul"; break;
case EOpSubgroupInclusiveMin: out.debug << "subgroupInclusiveMin"; break;
case EOpSubgroupInclusiveMax: out.debug << "subgroupInclusiveMax"; break;
case EOpSubgroupInclusiveAnd: out.debug << "subgroupInclusiveAnd"; break;
case EOpSubgroupInclusiveOr: out.debug << "subgroupInclusiveOr"; break;
case EOpSubgroupInclusiveXor: out.debug << "subgroupInclusiveXor"; break;
case EOpSubgroupExclusiveAdd: out.debug << "subgroupExclusiveAdd"; break;
case EOpSubgroupExclusiveMul: out.debug << "subgroupExclusiveMul"; break;
case EOpSubgroupExclusiveMin: out.debug << "subgroupExclusiveMin"; break;
case EOpSubgroupExclusiveMax: out.debug << "subgroupExclusiveMax"; break;
case EOpSubgroupExclusiveAnd: out.debug << "subgroupExclusiveAnd"; break;
case EOpSubgroupExclusiveOr: out.debug << "subgroupExclusiveOr"; break;
case EOpSubgroupExclusiveXor: out.debug << "subgroupExclusiveXor"; break;
case EOpSubgroupClusteredAdd: out.debug << "subgroupClusteredAdd"; break;
case EOpSubgroupClusteredMul: out.debug << "subgroupClusteredMul"; break;
case EOpSubgroupClusteredMin: out.debug << "subgroupClusteredMin"; break;
case EOpSubgroupClusteredMax: out.debug << "subgroupClusteredMax"; break;
case EOpSubgroupClusteredAnd: out.debug << "subgroupClusteredAnd"; break;
case EOpSubgroupClusteredOr: out.debug << "subgroupClusteredOr"; break;
case EOpSubgroupClusteredXor: out.debug << "subgroupClusteredXor"; break;
case EOpSubgroupQuadBroadcast: out.debug << "subgroupQuadBroadcast"; break;
case EOpSubgroupQuadSwapHorizontal: out.debug << "subgroupQuadSwapHorizontal"; break;
case EOpSubgroupQuadSwapVertical: out.debug << "subgroupQuadSwapVertical"; break;
case EOpSubgroupQuadSwapDiagonal: out.debug << "subgroupQuadSwapDiagonal"; break;
case EOpSubpassLoad: out.debug << "subpassLoad"; break;
case EOpSubpassLoadMS: out.debug << "subpassLoadMS"; break;
#ifdef NV_EXTENSIONS
case EOpTraceNV: out.debug << "traceNV"; break;
case EOpReportIntersectionNV: out.debug << "reportIntersectionNV"; break;
case EOpIgnoreIntersectionNV: out.debug << "ignoreIntersectionNV"; break;
case EOpTerminateRayNV: out.debug << "terminateRayNV"; break;
case EOpExecuteCallableNV: out.debug << "executeCallableNV"; break;
case EOpWritePackedPrimitiveIndices4x8NV: out.debug << "writePackedPrimitiveIndices4x8NV"; break;
#endif
default: out.debug.message(EPrefixError, "Bad aggregation op");
}
if (node->getOp() != EOpSequence && node->getOp() != EOpParameters)
out.debug << " (" << node->getCompleteString() << ")";
out.debug << "\n";
return true;
}
bool TOutputTraverser::visitSelection(TVisit /* visit */, TIntermSelection* node)
{
TInfoSink& out = infoSink;
OutputTreeText(out, node, depth);
out.debug << "Test condition and select";
out.debug << " (" << node->getCompleteString() << ")";
if (node->getShortCircuit() == false)
out.debug << ": no shortcircuit";
if (node->getFlatten())
out.debug << ": Flatten";
if (node->getDontFlatten())
out.debug << ": DontFlatten";
out.debug << "\n";
++depth;
OutputTreeText(out, node, depth);
out.debug << "Condition\n";
node->getCondition()->traverse(this);
OutputTreeText(out, node, depth);
if (node->getTrueBlock()) {
out.debug << "true case\n";
node->getTrueBlock()->traverse(this);
} else
out.debug << "true case is null\n";
if (node->getFalseBlock()) {
OutputTreeText(out, node, depth);
out.debug << "false case\n";
node->getFalseBlock()->traverse(this);
}
--depth;
return false;
}
// Print infinities and NaNs, and numbers in a portable way.
// Goals:
// - portable (across IEEE 754 platforms)
// - shows all possible IEEE values
// - shows simple numbers in a simple way, e.g., no leading/trailing 0s
// - shows all digits, no premature rounding
static void OutputDouble(TInfoSink& out, double value, TOutputTraverser::EExtraOutput extra)
{
if (IsInfinity(value)) {
if (value < 0)
out.debug << "-1.#INF";
else
out.debug << "+1.#INF";
} else if (IsNan(value))
out.debug << "1.#IND";
else {
const int maxSize = 340;
char buf[maxSize];
const char* format = "%f";
if (fabs(value) > 0.0 && (fabs(value) < 1e-5 || fabs(value) > 1e12))
format = "%-.13e";
int len = snprintf(buf, maxSize, format, value);
assert(len < maxSize);
// remove a leading zero in the 100s slot in exponent; it is not portable
// pattern: XX...XXXe+0XX or XX...XXXe-0XX
if (len > 5) {
if (buf[len-5] == 'e' && (buf[len-4] == '+' || buf[len-4] == '-') && buf[len-3] == '0') {
buf[len-3] = buf[len-2];
buf[len-2] = buf[len-1];
buf[len-1] = '\0';
}
}
out.debug << buf;
switch (extra) {
case TOutputTraverser::BinaryDoubleOutput:
{
out.debug << " : ";
long long b = *reinterpret_cast<long long*>(&value);
for (size_t i = 0; i < 8 * sizeof(value); ++i, ++b) {
out.debug << ((b & 0x8000000000000000) != 0 ? "1" : "0");
b <<= 1;
}
break;
}
default:
break;
}
}
}
static void OutputConstantUnion(TInfoSink& out, const TIntermTyped* node, const TConstUnionArray& constUnion,
TOutputTraverser::EExtraOutput extra, int depth)
{
int size = node->getType().computeNumComponents();
for (int i = 0; i < size; i++) {
OutputTreeText(out, node, depth);
switch (constUnion[i].getType()) {
case EbtBool:
if (constUnion[i].getBConst())
out.debug << "true";
else
out.debug << "false";
out.debug << " (" << "const bool" << ")";
out.debug << "\n";
break;
case EbtFloat:
case EbtDouble:
case EbtFloat16:
OutputDouble(out, constUnion[i].getDConst(), extra);
out.debug << "\n";
break;
case EbtInt8:
{
const int maxSize = 300;
char buf[maxSize];
snprintf(buf, maxSize, "%d (%s)", constUnion[i].getI8Const(), "const int8_t");
out.debug << buf << "\n";
}
break;
case EbtUint8:
{
const int maxSize = 300;
char buf[maxSize];
snprintf(buf, maxSize, "%u (%s)", constUnion[i].getU8Const(), "const uint8_t");
out.debug << buf << "\n";
}
break;
case EbtInt16:
{
const int maxSize = 300;
char buf[maxSize];
snprintf(buf, maxSize, "%d (%s)", constUnion[i].getI16Const(), "const int16_t");
out.debug << buf << "\n";
}
break;
case EbtUint16:
{
const int maxSize = 300;
char buf[maxSize];
snprintf(buf, maxSize, "%u (%s)", constUnion[i].getU16Const(), "const uint16_t");
out.debug << buf << "\n";
}
break;
case EbtInt:
{
const int maxSize = 300;
char buf[maxSize];
snprintf(buf, maxSize, "%d (%s)", constUnion[i].getIConst(), "const int");
out.debug << buf << "\n";
}
break;
case EbtUint:
{
const int maxSize = 300;
char buf[maxSize];
snprintf(buf, maxSize, "%u (%s)", constUnion[i].getUConst(), "const uint");
out.debug << buf << "\n";
}
break;
case EbtInt64:
{
const int maxSize = 300;
char buf[maxSize];
snprintf(buf, maxSize, "%lld (%s)", constUnion[i].getI64Const(), "const int64_t");
out.debug << buf << "\n";
}
break;
case EbtUint64:
{
const int maxSize = 300;
char buf[maxSize];
snprintf(buf, maxSize, "%llu (%s)", constUnion[i].getU64Const(), "const uint64_t");
out.debug << buf << "\n";
}
break;
default:
out.info.message(EPrefixInternalError, "Unknown constant", node->getLoc());
break;
}
}
}
void TOutputTraverser::visitConstantUnion(TIntermConstantUnion* node)
{
OutputTreeText(infoSink, node, depth);
infoSink.debug << "Constant:\n";
OutputConstantUnion(infoSink, node, node->getConstArray(), extraOutput, depth + 1);
}
void TOutputTraverser::visitSymbol(TIntermSymbol* node)
{
OutputTreeText(infoSink, node, depth);
infoSink.debug << "'" << node->getName() << "' (" << node->getCompleteString() << ")\n";
if (! node->getConstArray().empty())
OutputConstantUnion(infoSink, node, node->getConstArray(), extraOutput, depth + 1);
else if (node->getConstSubtree()) {
incrementDepth(node);
node->getConstSubtree()->traverse(this);
decrementDepth();
}
}
bool TOutputTraverser::visitLoop(TVisit /* visit */, TIntermLoop* node)
{
TInfoSink& out = infoSink;
OutputTreeText(out, node, depth);
out.debug << "Loop with condition ";
if (! node->testFirst())
out.debug << "not ";
out.debug << "tested first";
if (node->getUnroll())
out.debug << ": Unroll";
if (node->getDontUnroll())
out.debug << ": DontUnroll";
if (node->getLoopDependency()) {
out.debug << ": Dependency ";
out.debug << node->getLoopDependency();
}
out.debug << "\n";
++depth;
OutputTreeText(infoSink, node, depth);
if (node->getTest()) {
out.debug << "Loop Condition\n";
node->getTest()->traverse(this);
} else
out.debug << "No loop condition\n";
OutputTreeText(infoSink, node, depth);
if (node->getBody()) {
out.debug << "Loop Body\n";
node->getBody()->traverse(this);
} else
out.debug << "No loop body\n";
if (node->getTerminal()) {
OutputTreeText(infoSink, node, depth);
out.debug << "Loop Terminal Expression\n";
node->getTerminal()->traverse(this);
}
--depth;
return false;
}
bool TOutputTraverser::visitBranch(TVisit /* visit*/, TIntermBranch* node)
{
TInfoSink& out = infoSink;
OutputTreeText(out, node, depth);
switch (node->getFlowOp()) {
case EOpKill: out.debug << "Branch: Kill"; break;
case EOpBreak: out.debug << "Branch: Break"; break;
case EOpContinue: out.debug << "Branch: Continue"; break;
case EOpReturn: out.debug << "Branch: Return"; break;
case EOpCase: out.debug << "case: "; break;
case EOpDefault: out.debug << "default: "; break;
default: out.debug << "Branch: Unknown Branch"; break;
}
if (node->getExpression()) {
out.debug << " with expression\n";
++depth;
node->getExpression()->traverse(this);
--depth;
} else
out.debug << "\n";
return false;
}
bool TOutputTraverser::visitSwitch(TVisit /* visit */, TIntermSwitch* node)
{
TInfoSink& out = infoSink;
OutputTreeText(out, node, depth);
out.debug << "switch";
if (node->getFlatten())
out.debug << ": Flatten";
if (node->getDontFlatten())
out.debug << ": DontFlatten";
out.debug << "\n";
OutputTreeText(out, node, depth);
out.debug << "condition\n";
++depth;
node->getCondition()->traverse(this);
--depth;
OutputTreeText(out, node, depth);
out.debug << "body\n";
++depth;
node->getBody()->traverse(this);
--depth;
return false;
}
//
// This function is the one to call externally to start the traversal.
// Individual functions can be initialized to 0 to skip processing of that
// type of node. It's children will still be processed.
//
void TIntermediate::output(TInfoSink& infoSink, bool tree)
{
infoSink.debug << "Shader version: " << version << "\n";
if (requestedExtensions.size() > 0) {
for (auto extIt = requestedExtensions.begin(); extIt != requestedExtensions.end(); ++extIt)
infoSink.debug << "Requested " << *extIt << "\n";
}
if (xfbMode)
infoSink.debug << "in xfb mode\n";
switch (language) {
case EShLangVertex:
break;
case EShLangTessControl:
infoSink.debug << "vertices = " << vertices << "\n";
if (inputPrimitive != ElgNone)
infoSink.debug << "input primitive = " << TQualifier::getGeometryString(inputPrimitive) << "\n";
if (vertexSpacing != EvsNone)
infoSink.debug << "vertex spacing = " << TQualifier::getVertexSpacingString(vertexSpacing) << "\n";
if (vertexOrder != EvoNone)
infoSink.debug << "triangle order = " << TQualifier::getVertexOrderString(vertexOrder) << "\n";
break;
case EShLangTessEvaluation:
infoSink.debug << "input primitive = " << TQualifier::getGeometryString(inputPrimitive) << "\n";
infoSink.debug << "vertex spacing = " << TQualifier::getVertexSpacingString(vertexSpacing) << "\n";
infoSink.debug << "triangle order = " << TQualifier::getVertexOrderString(vertexOrder) << "\n";
if (pointMode)
infoSink.debug << "using point mode\n";
break;
case EShLangGeometry:
infoSink.debug << "invocations = " << invocations << "\n";
infoSink.debug << "max_vertices = " << vertices << "\n";
infoSink.debug << "input primitive = " << TQualifier::getGeometryString(inputPrimitive) << "\n";
infoSink.debug << "output primitive = " << TQualifier::getGeometryString(outputPrimitive) << "\n";
break;
case EShLangFragment:
if (pixelCenterInteger)
infoSink.debug << "gl_FragCoord pixel center is integer\n";
if (originUpperLeft)
infoSink.debug << "gl_FragCoord origin is upper left\n";
if (earlyFragmentTests)
infoSink.debug << "using early_fragment_tests\n";
if (postDepthCoverage)
infoSink.debug << "using post_depth_coverage\n";
if (depthLayout != EldNone)
infoSink.debug << "using " << TQualifier::getLayoutDepthString(depthLayout) << "\n";
if (blendEquations != 0) {
infoSink.debug << "using";
// blendEquations is a mask, decode it
for (TBlendEquationShift be = (TBlendEquationShift)0; be < EBlendCount; be = (TBlendEquationShift)(be + 1)) {
if (blendEquations & (1 << be))
infoSink.debug << " " << TQualifier::getBlendEquationString(be);
}
infoSink.debug << "\n";
}
break;
#ifdef NV_EXTENSIONS
case EShLangMeshNV:
infoSink.debug << "max_vertices = " << vertices << "\n";
infoSink.debug << "max_primitives = " << primitives << "\n";
infoSink.debug << "output primitive = " << TQualifier::getGeometryString(outputPrimitive) << "\n";
// Fall through
case EShLangTaskNV:
// Fall through
#endif
case EShLangCompute:
infoSink.debug << "local_size = (" << localSize[0] << ", " << localSize[1] << ", " << localSize[2] << ")\n";
{
if (localSizeSpecId[0] != TQualifier::layoutNotSet ||
localSizeSpecId[1] != TQualifier::layoutNotSet ||
localSizeSpecId[2] != TQualifier::layoutNotSet) {
infoSink.debug << "local_size ids = (" <<
localSizeSpecId[0] << ", " <<
localSizeSpecId[1] << ", " <<
localSizeSpecId[2] << ")\n";
}
}
break;
default:
break;
}
if (treeRoot == 0 || ! tree)
return;
TOutputTraverser it(infoSink);
if (getBinaryDoubleOutput())
it.setDoubleOutput(TOutputTraverser::BinaryDoubleOutput);
treeRoot->traverse(&it);
}
} // end namespace glslang