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概要: 入れ子 | フィールド | コンストラクタ | メソッド | 詳細: フィールド | コンストラクタ | メソッド |
Elem interface Elem class (structure/union element class) interface. See getFirstElem of TypeInterface.
フィールドの概要 |
インタフェース coins.sym.Var から継承したフィールド |
STORAGECLASS, VAR_AUTO, VAR_REGISTER, VAR_STATIC |
インタフェース coins.sym.Sym から継承したフィールド |
KIND_NAME, VISIBILITY |
メソッドの概要 | |
long |
evaluateDisp()
evaluateDisp Get the displacement of this element. |
int |
getBitOffset()
getBitOffset See also setBitFieldOffset method. |
int |
getBitSize()
getBitSize See also setBitFieldOffset method. |
Type |
getUpperType()
getUpperType |
boolean |
isBitField()
isBitField |
boolean |
isDispEvaluable()
isDispEvaluable |
Elem |
searchElem(Type pRecordedIn)
searchElem Get the proper element having the same name as this symbol in pRecordedIn construct (structure or union). |
Elem |
searchElem(Var pVar)
searchElem Get the proper element having the same name as this symbol in the struct/union variable pVar. |
void |
setBitFieldOffset(int pBitOffset)
setBitFieldOffset Set bit field offset of this element if it is a bit field. |
void |
setBitFieldSize(int pBitSize)
Set the size of bit field and set an indication showing that this element is a bit field. |
void |
setDispExp(Exp pDispExp)
setDispExp Set the displacement of this element. |
void |
setDisplacement(long pDisplacement)
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インタフェース coins.sym.Var から継承したメソッド |
evaluateAsObject, getDimension, getInitialValue, getNext, getSize, getStorageClass, getVisibility, isSizeEvaluable, setInitialValue, setNext, setStorageClass, setVisibility |
インタフェース coins.sym.Sym0 から継承したメソッド |
charConst, definedType, defineElem, defineLabel, defineParam, defineSubp, defineVar, enumType, floatConst, getDefinedFile, getDefinedIn, getFlag, getName, getNextSym, getRecordedIn, getSymKind, getSymType, getUniqueName, intConst, isGlobal, namedConst, pointerType, setFlag, stringConst, structType, subpType, unionType, vectorType, vectorTypeUnfixed |
メソッドの詳細 |
public boolean isDispEvaluable()
public long evaluateDisp()
public void setDispExp(Exp pDispExp)
pDispExp
- Expression representing the displacement
of this element in byte.public void setDisplacement(long pDisplacement)
public void setBitFieldSize(int pBitSize)
Set the size of bit field and set an indication showing that this element is a bit field. The size of bit field should not exceed the bit width of long (typeLong.getSizeValue()*8). See also setBitFieldOffset method.
pBitSize
- number of bits in this bit field.public void setBitFieldOffset(int pBitOffset)
Set bit field offset of this element if it is a bit field. Consider bit offset and bit field length of a bit field are represented by bitOffset and bitFieldSize each respectively. In the case of machineParam.isPackedFromLeft() is true, the most significant bit of the 1st field is placed at the most significant bit of "containing object" (which is explained later), and the bit field is placed at bit positions bitOffset through (bitOffset + bitFieldSize - 1) in the containing object, where the most significant bit position of the containing object is zero and the least significant bit position is (bit width of containing object -1). In the case of machineParam.isPackedFromLeft() is false, that is, machineParam.isPackedFromRight() is true, the least significant bit of the 1st field is placed at the least significant bit of containing object, and the bit field is placed at bit positions bitOffset through (bitOffset + bitFieldSize - 1) in the containing object, where the least significant bit position of the containing object is zero and the most significant bit position is (bit width of containing object -1). In both cases, displacement of the containing object within the surrounding structure is shown by evaluateDisp(). Source language analyzer is not requested to set bit field offset but requested to set only the size of bit fields by setBitFieldSize method because the bit offset computation is usually done by finishStructType() of StructType. "containing object" mentioned in the previous paragraph is a hypothetical object that contains bit fields. The alignment/size of the containing object is considered to be the alignment/size of the largest bit field type among the consecutive bit fields (all of which have type int or unsigned int in C). When a bit field is encountered in structure declaration and the total size of preceding elements is lSize, then the displacement of the containing object is computed as (lSize / lElemTypeSize) * lElemTypeSize where lElemTypeSize is the size of the largest bit field type among the consecutive bit fields. If the containing object has space to hold the bit field, then the bit field is placed in the containing object. When there remains no space to hold new bit field after successive allocation of preceding bit fields, a new containing object is placed adjacent to the old one and remaining bit fields are placed in the new containing object. A bit field is contained in one containing object and does not span to multiple containing objects. Multiple bit fields may be contained in one containing object if the containing object can contain them and bit fields continues successively. The structure is supposed to have the alignment greater or equal to the alignment of the containing object and its size is the multiple of the size of the containing object. Consider a C language structure struct st1 { short s1; char c1; unsigned int b1:5; unsigned int b2:1; unsigned int b3:3; char c2; }; on machine having 2 as short size, 4 as int size. Displacements and bit offsets in this case will be as follows: element displacement bit offset s1 0 - c1 2 - b1 0 24 b2 0 29 b3 4 0 c2 5 - and the structure will have alignment 4 and size 8. As for C program struct bitField1 { unsigned a1:1; unsigned b1:1; }; struct bitField2 { struct bitField1 st1; unsigned char cc1; struct bitField1 st2; unsigned char cc2; }; Displacements and bit offsets in this case will be as follows: element displacement bit offset st1.a1 0 0 st1.b1 0 1 cc1 4 - st2.a1 8 0 st2.b1 8 1 cc2 12 - and the structure will have alignment 4 and size 16. A bit field can be loaded to register by loading the corresponding containing object whose displacement can be get be evaluateDisp(). Access methods of a bit field shows evaluateDisp(): displacement of the containing object containing the bit field. getBitSize(): the number of bits in the bit field. getBitOffset(): bit offset position in the containing object (its meaning differs according to the value of isPackedFromLeft() as mentioned before).
pBitOffset
- bit offset of the bit field as explained above.
public int getBitSize()
public int getBitOffset()
public boolean isBitField()
public Elem searchElem(Var pVar)
pVar
- sturcture or union variable.
public Elem searchElem(Type pRecordedIn)
pRecordedIn
- enclosing construct defining the element to be
searched (sturcture type or union type in C).
public Type getUpperType()
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前のクラス 次のクラス | フレームあり フレームなし | |||||||||
概要: 入れ子 | フィールド | コンストラクタ | メソッド | 詳細: フィールド | コンストラクタ | メソッド |