kc3-lang/angle/src/compiler/BaseTypes.h

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• Hash : 8772b588
  Author :
  Date : 2013-06-24T16:14:19
  

  Support sampler2DArray throughout the compiler.
  
  TRAC #23377
  Signed-off-by: Jamie Madill
  Signed-off-by: Shannon Woods
  Author: Nicolas Capens
  

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• src/compiler/BaseTypes.h

• //
  // Copyright (c) 2002-2013 The ANGLE Project Authors. All rights reserved.
  // Use of this source code is governed by a BSD-style license that can be
  // found in the LICENSE file.
  //
  
  #ifndef _BASICTYPES_INCLUDED_
  #define _BASICTYPES_INCLUDED_
  
  //
  // Precision qualifiers
  //
  enum TPrecision
  {
      // These need to be kept sorted
      EbpUndefined,
      EbpLow,
      EbpMedium,
      EbpHigh
  };
  
  inline const char* getPrecisionString(TPrecision p)
  {
      switch(p)
      {
      case EbpHigh:		return "highp";		break;
      case EbpMedium:		return "mediump";	break;
      case EbpLow:		return "lowp";		break;
      default:			return "mediump";   break;   // Safest fallback
      }
  }
  
  //
  // Basic type.  Arrays, vectors, etc., are orthogonal to this.
  //
  enum TBasicType
  {
      EbtVoid,
      EbtFloat,
      EbtInt,
      EbtUInt,
      EbtBool,
      EbtGuardSamplerBegin,  // non type:  see implementation of IsSampler()
      EbtSampler2D,
      EbtSampler3D,
      EbtSamplerCube,
      EbtSampler2DArray,
      EbtSamplerExternalOES,  // Only valid if OES_EGL_image_external exists.
      EbtSampler2DRect,       // Only valid if GL_ARB_texture_rectangle exists.
      EbtISampler2D,
      EbtISampler3D,
      EbtISamplerCube,
      EbtISampler2DArray,
      EbtUSampler2D,
      EbtUSampler3D,
      EbtUSamplerCube,
      EbtUSampler2DArray,
      EbtGuardSamplerEnd,    // non type:  see implementation of IsSampler()
      EbtStruct,
      EbtInterfaceBlock,
      EbtAddress,            // should be deprecated??
      EbtInvariant          // used as a type when qualifying a previously declared variable as being invariant
  };
  
  inline const char* getBasicString(TBasicType t)
  {
      switch (t)
      {
      case EbtVoid:              return "void";              break;
      case EbtFloat:             return "float";             break;
      case EbtInt:               return "int";               break;
      case EbtUInt:              return "uint";              break;
      case EbtBool:              return "bool";              break;
      case EbtSampler2D:         return "sampler2D";         break;
      case EbtSampler3D:         return "sampler3D";         break;
      case EbtSamplerCube:       return "samplerCube";       break;
      case EbtSamplerExternalOES: return "samplerExternalOES"; break;
      case EbtSampler2DRect:     return "sampler2DRect";     break;
      case EbtSampler2DArray:    return "sampler2DArray";    break;
      case EbtISampler2D:        return "isampler2D";        break;
      case EbtISampler3D:        return "isampler3D";        break;
      case EbtISamplerCube:      return "isamplerCube";      break;
      case EbtISampler2DArray:   return "isampler2DArray";   break;
      case EbtUSampler2D:        return "usampler2D";        break;
      case EbtUSampler3D:        return "usampler3D";        break;
      case EbtUSamplerCube:      return "usamplerCube";      break;
      case EbtUSampler2DArray:   return "usampler2DArray";   break;
      case EbtStruct:            return "structure";         break;
      case EbtInterfaceBlock:    return "interface block";   break;
      default:                   return "unknown type";
      }
  }
  
  inline bool IsSampler(TBasicType type)
  {
      return type > EbtGuardSamplerBegin && type < EbtGuardSamplerEnd;
  }
  
  //
  // Qualifiers and built-ins.  These are mainly used to see what can be read
  // or written, and by the machine dependent translator to know which registers
  // to allocate variables in.  Since built-ins tend to go to different registers
  // than varying or uniform, it makes sense they are peers, not sub-classes.
  //
  enum TQualifier
  {
      EvqTemporary,     // For temporaries (within a function), read/write
      EvqGlobal,        // For globals read/write
      EvqConst,         // User defined constants and non-output parameters in functions
      EvqAttribute,     // Readonly
      EvqVaryingIn,     // readonly, fragment shaders only
      EvqVaryingOut,    // vertex shaders only  read/write
      EvqInvariantVaryingIn,     // readonly, fragment shaders only
      EvqInvariantVaryingOut,    // vertex shaders only  read/write
      EvqUniform,       // Readonly, vertex and fragment
      EvqVertexInput,   // Vertex shader input
      EvqFragmentOutput, // Fragment shader output
  
      // pack/unpack input and output
      EvqInput,
      EvqOutput,
  
      // parameters
      EvqIn,
      EvqOut,
      EvqInOut,
      EvqConstReadOnly,
  
      // built-ins written by vertex shader
      EvqPosition,
      EvqPointSize,
  
      // built-ins read by fragment shader
      EvqFragCoord,
      EvqFrontFacing,
      EvqPointCoord,
  
      // built-ins written by fragment shader
      EvqFragColor,
      EvqFragData,
  
      // GLSL ES 3.0 vertex output and fragment input
      EvqSmooth,        // Incomplete qualifier, smooth is the default
      EvqFlat,          // Incomplete qualifier
      EvqSmoothOut = EvqSmooth,
      EvqFlatOut = EvqFlat,
      EvqCentroidOut,   // Implies smooth
      EvqSmoothIn,
      EvqFlatIn,
      EvqCentroidIn,    // Implies smooth
  
      // end of list
      EvqLast
  };
  
  enum TLayoutMatrixPacking
  {
      EmpUnspecified,
      EmpRowMajor,
      EmpColumnMajor
  };
  
  enum TLayoutBlockStorage
  {
      EbsUnspecified,
      EbsShared,
      EbsPacked,
      EbsStd140
  };
  
  struct TLayoutQualifier
  {
      int location;
      TLayoutMatrixPacking matrixPacking;
      TLayoutBlockStorage blockStorage;
  
      static TLayoutQualifier create()
      {
          TLayoutQualifier layoutQualifier;
  
          layoutQualifier.location = -1;
          layoutQualifier.matrixPacking = EmpUnspecified;
          layoutQualifier.blockStorage = EbsUnspecified;
  
          return layoutQualifier;
      }
  
      bool isEmpty() const
      {
          return location == -1 && matrixPacking == EmpUnspecified && blockStorage == EbsUnspecified;
      }
  };
  
  //
  // This is just for debug print out, carried along with the definitions above.
  //
  inline const char* getQualifierString(TQualifier q)
  {
      switch(q)
      {
      case EvqTemporary:      return "Temporary";      break;
      case EvqGlobal:         return "Global";         break;
      case EvqConst:          return "const";          break;
      case EvqConstReadOnly:  return "const";          break;
      case EvqAttribute:      return "attribute";      break;
      case EvqVaryingIn:      return "varying";        break;
      case EvqVaryingOut:     return "varying";        break;
      case EvqInvariantVaryingIn: return "invariant varying";	break;
      case EvqInvariantVaryingOut:return "invariant varying";	break;
      case EvqUniform:        return "uniform";        break;
      case EvqVertexInput:    return "in";             break;
      case EvqFragmentOutput: return "out";            break;
      case EvqIn:             return "in";             break;
      case EvqOut:            return "out";            break;
      case EvqInOut:          return "inout";          break;
      case EvqInput:          return "input";          break;
      case EvqOutput:         return "output";         break;
      case EvqPosition:       return "Position";       break;
      case EvqPointSize:      return "PointSize";      break;
      case EvqFragCoord:      return "FragCoord";      break;
      case EvqFrontFacing:    return "FrontFacing";    break;
      case EvqFragColor:      return "FragColor";      break;
      case EvqFragData:       return "FragData";       break;
      case EvqSmoothOut:      return "smooth out";     break;
      case EvqCentroidOut:    return "centroid out";   break;
      case EvqFlatOut:        return "flat out";       break;
      case EvqSmoothIn:       return "smooth in";      break;
      case EvqCentroidIn:     return "centroid in";    break;
      case EvqFlatIn:         return "flat in";        break;
      default:                return "unknown qualifier";
      }
  }
  
  inline const char* getMatrixPackingString(TLayoutMatrixPacking mpq)
  {
      switch (mpq)
      {
      case EmpUnspecified:    return "mp_unspecified";
      case EmpRowMajor:       return "row_major";
      case EmpColumnMajor:    return "column_major";
      default:                return "unknown matrix packing";
      }
  }
  
  inline const char* getBlockStorageString(TLayoutBlockStorage bsq)
  {
      switch (bsq)
      {
      case EbsUnspecified:    return "bs_unspecified";
      case EbsShared:         return "shared";
      case EbsPacked:         return "packed";
      case EbsStd140:         return "std140";
      default:                return "unknown block storage";
      }
  }
  
  inline const char* getInterpolationString(TQualifier q)
  {
      switch(q)
      {
      case EvqSmoothOut:      return "smooth";   break;
      case EvqCentroidOut:    return "centroid"; break;
      case EvqFlatOut:        return "flat";     break;
      case EvqSmoothIn:       return "smooth";   break;
      case EvqCentroidIn:     return "centroid"; break;
      case EvqFlatIn:         return "flat";     break;
      default:                return "unknown interpolation";
      }
  }
  
  #endif // _BASICTYPES_INCLUDED_
  

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