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

• Show log

  Commit

• Hash : 3ca980a3
  Author :
  Date : 2012-12-20T21:11:52
  

  Add utility methods for determining register count.
  
  TRAC #22293
  Signed-off-by: Daniel Koch
  Signed-off-by: Shannon Woods
  Author: Nicolas Capens
  
  git-svn-id: https://angleproject.googlecode.com/svn/branches/dx11proto@1621 736b8ea6-26fd-11df-bfd4-992fa37f6226
  

Download

• src/compiler/Types.h

• //
  // Copyright (c) 2002-2012 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 _TYPES_INCLUDED
  #define _TYPES_INCLUDED
  
  #include "compiler/BaseTypes.h"
  #include "compiler/Common.h"
  #include "compiler/debug.h"
  
  class TType;
  struct TPublicType;
  
  //
  // Need to have association of line numbers to types in a list for building structs.
  //
  struct TTypeLine {
      TType* type;
      int line;
  };
  typedef TVector<TTypeLine> TTypeList;
  
  inline TTypeList* NewPoolTTypeList()
  {
      void* memory = GlobalPoolAllocator.allocate(sizeof(TTypeList));
      return new(memory) TTypeList;
  }
  
  typedef TMap<TTypeList*, TTypeList*> TStructureMap;
  typedef TMap<TTypeList*, TTypeList*>::iterator TStructureMapIterator;
  
  //
  // Base class for things that have a type.
  //
  class TType
  {
  public:
      POOL_ALLOCATOR_NEW_DELETE(GlobalPoolAllocator)
      TType() {}
      TType(TBasicType t, TPrecision p, TQualifier q = EvqTemporary, int s = 1, bool m = false, bool a = false) :
              type(t), precision(p), qualifier(q), size(s), matrix(m), array(a), arraySize(0),
              maxArraySize(0), arrayInformationType(0), structure(0), structureSize(0), deepestStructNesting(0), fieldName(0), mangled(0), typeName(0)
      {
      }
      explicit TType(const TPublicType &p);
      TType(TTypeList* userDef, const TString& n, TPrecision p = EbpUndefined) :
              type(EbtStruct), precision(p), qualifier(EvqTemporary), size(1), matrix(false), array(false), arraySize(0),
              maxArraySize(0), arrayInformationType(0), structure(userDef), structureSize(0), deepestStructNesting(0), fieldName(0), mangled(0)
      {
          typeName = NewPoolTString(n.c_str());
      }
  
      void copyType(const TType& copyOf, TStructureMap& remapper)
      {
          type = copyOf.type;
          precision = copyOf.precision;
          qualifier = copyOf.qualifier;
          size = copyOf.size;
          matrix = copyOf.matrix;
          array = copyOf.array;
          arraySize = copyOf.arraySize;
  
          TStructureMapIterator iter;
          if (copyOf.structure) {
              if ((iter = remapper.find(structure)) == remapper.end()) {
                  // create the new structure here
                  structure = NewPoolTTypeList();
                  for (unsigned int i = 0; i < copyOf.structure->size(); ++i) {
                      TTypeLine typeLine;
                      typeLine.line = (*copyOf.structure)[i].line;
                      typeLine.type = (*copyOf.structure)[i].type->clone(remapper);
                      structure->push_back(typeLine);
                  }
              } else {
                  structure = iter->second;
              }
          } else
              structure = 0;
  
          fieldName = 0;
          if (copyOf.fieldName)
              fieldName = NewPoolTString(copyOf.fieldName->c_str());
          typeName = 0;
          if (copyOf.typeName)
              typeName = NewPoolTString(copyOf.typeName->c_str());
  
          mangled = 0;
          if (copyOf.mangled)
              mangled = NewPoolTString(copyOf.mangled->c_str());
  
          structureSize = copyOf.structureSize;
          maxArraySize = copyOf.maxArraySize;
          deepestStructNesting = copyOf.deepestStructNesting;
          assert(copyOf.arrayInformationType == 0);
          arrayInformationType = 0; // arrayInformationType should not be set for builtIn symbol table level
      }
  
      TType* clone(TStructureMap& remapper)
      {
          TType *newType = new TType();
          newType->copyType(*this, remapper);
  
          return newType;
      }
  
      TBasicType getBasicType() const { return type; }
      void setBasicType(TBasicType t) { type = t; }
  
      TPrecision getPrecision() const { return precision; }
      void setPrecision(TPrecision p) { precision = p; }
  
      TQualifier getQualifier() const { return qualifier; }
      void setQualifier(TQualifier q) { qualifier = q; }
  
      // One-dimensional size of single instance type
      int getNominalSize() const { return size; }
      void setNominalSize(int s) { size = s; }
      // Full size of single instance of type
      int getObjectSize() const
      {
          int totalSize;
  
          if (getBasicType() == EbtStruct)
              totalSize = getStructSize();
          else if (matrix)
              totalSize = size * size;
          else
              totalSize = size;
  
          if (isArray())
              totalSize *= std::max(getArraySize(), getMaxArraySize());
  
          return totalSize;
      }
  
      int elementRegisterCount() const
      {
          TTypeList *structure = getStruct();
  
          if (structure)
          {
              int registerCount = 0;
  
              for (size_t i = 0; i < structure->size(); i++)
              {
                  registerCount += (*structure)[i].type->totalRegisterCount();
              }
  
              return registerCount;
          }
          else if (isMatrix())
          {
              return getNominalSize();
          }
          else
          {
              return 1;
          }
      }
  
      int totalRegisterCount() const
      {
          if (array)
          {
              return arraySize * elementRegisterCount();
          }
          else
          {
              return elementRegisterCount();
          }
      }
  
      bool isMatrix() const { return matrix ? true : false; }
      void setMatrix(bool m) { matrix = m; }
  
      bool isArray() const  { return array ? true : false; }
      int getArraySize() const { return arraySize; }
      void setArraySize(int s) { array = true; arraySize = s; }
      int getMaxArraySize () const { return maxArraySize; }
      void setMaxArraySize (int s) { maxArraySize = s; }
      void clearArrayness() { array = false; arraySize = 0; maxArraySize = 0; }
      void setArrayInformationType(TType* t) { arrayInformationType = t; }
      TType* getArrayInformationType() const { return arrayInformationType; }
  
      bool isVector() const { return size > 1 && !matrix; }
      bool isScalar() const { return size == 1 && !matrix && !structure; }
  
      TTypeList* getStruct() const { return structure; }
      void setStruct(TTypeList* s) { structure = s; computeDeepestStructNesting(); }
  
      const TString& getTypeName() const
      {
          assert(typeName);
          return *typeName;
      }
      void setTypeName(const TString& n)
      {
          typeName = NewPoolTString(n.c_str());
      }
  
      bool isField() const { return fieldName != 0; }
      const TString& getFieldName() const
      {
          assert(fieldName);
          return *fieldName;
      }
      void setFieldName(const TString& n)
      {
          fieldName = NewPoolTString(n.c_str());
      }
  
      TString& getMangledName() {
          if (!mangled) {
              mangled = NewPoolTString("");
              buildMangledName(*mangled);
              *mangled += ';' ;
          }
  
          return *mangled;
      }
  
      bool sameElementType(const TType& right) const {
          return      type == right.type   &&
                      size == right.size   &&
                    matrix == right.matrix &&
                 structure == right.structure;
      }
      bool operator==(const TType& right) const {
          return      type == right.type   &&
                      size == right.size   &&
                    matrix == right.matrix &&
                     array == right.array  && (!array || arraySize == right.arraySize) &&
                 structure == right.structure;
          // don't check the qualifier, it's not ever what's being sought after
      }
      bool operator!=(const TType& right) const {
          return !operator==(right);
      }
      bool operator<(const TType& right) const {
          if (type != right.type) return type < right.type;
          if (size != right.size) return size < right.size;
          if (matrix != right.matrix) return matrix < right.matrix;
          if (array != right.array) return array < right.array;
          if (arraySize != right.arraySize) return arraySize < right.arraySize;
          if (structure != right.structure) return structure < right.structure;
  
          return false;
      }
  
      const char* getBasicString() const { return ::getBasicString(type); }
      const char* getPrecisionString() const { return ::getPrecisionString(precision); }
      const char* getQualifierString() const { return ::getQualifierString(qualifier); }
      TString getCompleteString() const;
  
      // If this type is a struct, returns the deepest struct nesting of
      // any field in the struct. For example:
      //   struct nesting1 {
      //     vec4 position;
      //   };
      //   struct nesting2 {
      //     nesting1 field1;
      //     vec4 field2;
      //   };
      // For type "nesting2", this method would return 2 -- the number
      // of structures through which indirection must occur to reach the
      // deepest field (nesting2.field1.position).
      int getDeepestStructNesting() const { return deepestStructNesting; }
  
      bool isStructureContainingArrays() const;
  
  protected:
      void buildMangledName(TString&);
      int getStructSize() const;
      void computeDeepestStructNesting();
  
      TBasicType type      : 6;
      TPrecision precision;
      TQualifier qualifier : 7;
      int size             : 8; // size of vector or matrix, not size of array
      unsigned int matrix  : 1;
      unsigned int array   : 1;
      int arraySize;
      int maxArraySize;
      TType* arrayInformationType;
  
      TTypeList* structure;      // 0 unless this is a struct
      mutable int structureSize;
      int deepestStructNesting;
  
      TString *fieldName;         // for structure field names
      TString *mangled;
      TString *typeName;          // for structure field type name
  };
  
  //
  // This is a workaround for a problem with the yacc stack,  It can't have
  // types that it thinks have non-trivial constructors.  It should
  // just be used while recognizing the grammar, not anything else.  Pointers
  // could be used, but also trying to avoid lots of memory management overhead.
  //
  // Not as bad as it looks, there is no actual assumption that the fields
  // match up or are name the same or anything like that.
  //
  struct TPublicType
  {
      TBasicType type;
      TQualifier qualifier;
      TPrecision precision;
      int size;          // size of vector or matrix, not size of array
      bool matrix;
      bool array;
      int arraySize;
      TType* userDef;
      int line;
  
      void setBasic(TBasicType bt, TQualifier q, int ln = 0)
      {
          type = bt;
          qualifier = q;
          precision = EbpUndefined;
          size = 1;
          matrix = false;
          array = false;
          arraySize = 0;
          userDef = 0;
          line = ln;
      }
  
      void setAggregate(int s, bool m = false)
      {
          size = s;
          matrix = m;
      }
  
      void setArray(bool a, int s = 0)
      {
          array = a;
          arraySize = s;
      }
  
      bool isStructureContainingArrays() const
      {
          if (!userDef)
          {
              return false;
          }
  
          return userDef->isStructureContainingArrays();
      }
  };
  
  #endif // _TYPES_INCLUDED_
  

Download