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Erythro/src/Types.c

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/*************/
/*GEMWIRE */
/* ERYTHRO*/
/*************/
#include <Defs.h>
#include <Data.h>
/*
* Returns whether the input Type represents a raw integer type.
* It works on the principles outlined in Pointers.c; the lowest
* 4 bits indicate indirection.
*
* @param Type: The DataTypes representation to check
* @return a boolean representing whether the input Type is a raw integer
*/
int TypeIsInt(int Type) {
printf("\tComparing type %s.\n", TypeNames(Type));
return ( ((Type & 0xf) == 0) && (Type >= RET_CHAR && Type <= RET_LONG));
}
/*
* Returns whether the input Type has at least one level of indirection.
* It works on the principles outlined in Pointers.c; the lowest 4 bits
* indicate indirection.
*
* @param Type: The DataTypes representation to check
* @return a boolean representing whether the input Type is a pointer
*
*/
int TypeIsPtr(int Type) {
return ((Type & 0xf) != 0);
}
/*
* Turn a token type into its appropriate
* primitive type.
*
*/
int PrimitiveSize(int Type) {
if (TypeIsPtr(Type)) return 8;
switch (Type) {
case RET_CHAR:
return 1;
case RET_INT:
return 4;
case RET_LONG:
return 8;
default:
ErrorReport("Bad type in PrimitiveSize: %s\n", TypeNames(Type));
}
return 0;
}
/*
* Dynamically calculate the size of an object.
* This was performed with an array previously, but the addition of
* structs and enums makes that irrelevant.
*
*/
int TypeSize(int Type, struct SymbolTableEntry* Composite) {
if (Type == DAT_STRUCT || Type == DAT_UNION) return Composite->Length;
return PrimitiveSize(Type);
}
/*
* A char buffer we can abuse for printing type names.
* It needs to be 7 because that's 4 (long) + 3 (ptr), the longest
* possible name right now.
*/
static char TypeBuffer[7];
/*
* Get the name of the input Type as a string.
*/
char* TypeNames(int Type) {
switch (Type) {
case RET_CHAR:
memcpy(TypeBuffer, "Char", 4);
break;
case RET_INT:
memcpy(TypeBuffer, "Int ", 4);
break;
case RET_LONG:
memcpy(TypeBuffer, "Long", 4);
break;
case RET_VOID:
memcpy(TypeBuffer, "Void", 4);
break;
default:
break;
};
if (TypeIsPtr(Type)) memcpy((void*) ((size_t) TypeBuffer + 4), "Ptr", 3);
else memcpy((void*) ((size_t) TypeBuffer + 4), "\0", 1);
return TypeBuffer;
}
/*
* Determine if two types are compatible.
* A left char and a right int are compatible, as the char will fit into the int.
* The left char will need to be widened for assignment, however.
*
* If strict is set, you can only widen the Left to the Right.
* If strict is false, any widening is valid.
*
*/
int TypesCompatible(int* Left, int* Right, int STRICT) {
int LeftSize, RightSize;
// Same types are compatible. No shrinking required
if (*Left == *Right) {
*Left = *Right = 0;
return 1;
}
LeftSize = PrimitiveSize(*Left);
RightSize = PrimitiveSize(*Right);
// Types of size 0 are incompatible
if ((LeftSize == 0) || (RightSize == 0))
return 0;
/* char x;
* int y;
* y = 15;
*
* x = y;
* x needs to be widened, y copied in, then x shrunk back down
* AKA, the left must be widened.
*/
if (LeftSize < RightSize) {
*Left = OP_WIDEN;
*Right = 0;
return 1;
}
/*
* char x;
* int y;
*
* x = 15;
*
* y = x;
* x must be widened to fit into y.
* if STRICT mode, this is not allowed.
* By default, this is valid.
*
*/
if (LeftSize > RightSize) {
if (STRICT)
return 0; // Not compatible if STRICT
*Left = 0;
*Right = OP_WIDEN;
return 1; // Compatible by default
}
/*
* Any other cases left, by default, are compatible.
*
*/
*Left = *Right = 0;
return 1;
}
/**
* Given an operation on two types, we need to be able to
* determine if the operation is valid for both types,
* as well as modify the types if the operation is
* theoretically valid but requires some changes.
*
* An example of the latter is assigning an int literal into
* a char, or squeezing down the int into the char type.
*
* If the operation is not valid, this will return NULL.
* If the operaton is valid without changes, this will return Tree.
* If the operation is valid with changes, this will perform
* the changes and return the new tree.
*
* This also serves to consolidate some of the gross widening
* code that TypesCompatible led us to.
*/
struct ASTNode* MutateType(struct ASTNode* Tree, int RightType, int Operation) {
int LeftType;
int LeftSize, RightSize;
LeftType = Tree->ExprType;
printf("\tCalculating compatibility between ltype %s and rtype %s\r\n", TypeNames(LeftType), TypeNames(RightType));
if (TypeIsInt(LeftType) && TypeIsInt(RightType)) {
// Short-circuit for valid types
if (LeftType == RightType) {
return Tree;
}
LeftSize = PrimitiveSize(LeftType);
RightSize = PrimitiveSize(RightType);
/**
* LeftSize > RightSize:
* char x = 15000;
*
* (The left branch of the tree contains the current AST)
*
*/
if (LeftSize > RightSize)
return NULL;
/**
* RightSize > LeftSize:
* char x = 5;
* int y = x;
*
* We have to widen x into an int in order for this to be compatible
* BUT it is possible!
*/
if (RightSize > LeftSize)
return ConstructASTBranch(OP_WIDEN, RightType, Tree, NULL, 0);
}
// Left branch pointers are compatible if we're not doing operations
if (TypeIsPtr(LeftType)) {
if (Operation == 0 && LeftType == RightType)
return Tree;
}
// Otherwise, we can perform some scaling for pointer addition & subtraction
if (Operation == OP_ADD || Operation == OP_SUBTRACT) {
/**
* Left int, right pointer:
* int x = 5;
* int* y;
*
* x = *(y + 1);
*/
if (TypeIsInt(LeftType) && TypeIsPtr(RightType)) {
printf("\t\t\tMutateType: Right node needs adjustment\r\n");
RightSize = PrimitiveSize(ValueAt(RightType));
if (RightSize > 1)
return ConstructASTBranch(OP_SCALE, RightType, Tree, NULL, RightSize);
}
}
// If all else fails, we've constructed a combination of types that are not compatible.
// ie. left or right is a void.
// You cannot do pointer arithmetic on void type.
return NULL;
}
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