ref: 3e1d484b33d59c87095ce175ac7fa180bc422132
dir: /cc1/types.c/
/* See LICENSE file for copyright and license details. */ #include <inttypes.h> #include <stdio.h> #include <stdlib.h> #include <string.h> #include "../inc/sizes.h" #include "../inc/cc.h" #include "arch.h" #include "cc1.h" #include "arch.h" #define NR_TYPE_HASH 16 /* FIXME: * Compiler can generate warnings here if the ranges of TINT, * TUINT and TFLOAT are smaller than any of the constants in this * array. Ignore them if you know that the target types are correct */ static struct limits limits[][4] = { { { /* 0 = unsigned 1 byte */ .min.i = 0, .max.i = 255 }, { /* 1 = unsigned 2 bytes */ .min.i = 0, .max.i = 65535u }, { /* 2 = unsigned 4 bytes */ .min.i = 0, .max.i = 4294967295u }, { /* 3 = unsigned 8 bytes */ .min.i = 0, .max.i = 18446744073709551615u } }, { { /* 0 = signed 1 byte */ .min.i = -127, .max.i = 127 }, { /* 1 = signed 2 byte */ .min.i = -32767, .max.i = 32767 }, { /* 2 = signed 4 byte */ .min.i = -2147483647L, .max.i = 2147483647L }, { /* 3 = signed 8 byte */ .min.i = -9223372036854775807LL, .max.i = 9223372036854775807LL, } }, { { /* 0 = float 4 bytes */ .min.f = -1, .max.f = 2 }, { /* 1 = float 8 bytes */ .min.f = -1, .max.f = 2, }, { /* 2 = float 16 bytes */ .min.f = -1, .max.f = 2, } } }; struct limits * getlimits(Type *tp) { int ntable, ntype; switch (tp->op) { case ENUM: case INT: ntable = ((tp->prop & TSIGNED) != 0); switch (tp->size) { case 1: ntype = 0; break; case 2: ntype = 1; break; case 4: ntype = 2; break; case 8: ntype = 3; break; } break; case FLOAT: ntable = 2; switch (tp->size) { case 4: ntype = 0; break; case 8: ntype = 1; break; case 16: ntype = 2; break; } break; } return &limits[ntable][ntype]; } Type * ctype(unsigned type, unsigned sign, unsigned size) { switch (type) { case CHAR: if (size) goto invalid_type; switch (sign) { case 0: return chartype; case SIGNED: return schartype; case UNSIGNED: return uchartype; } break; case VOID: if (size || sign) goto invalid_type; return voidtype; case BOOL: if (size || sign) goto invalid_type; return booltype; case 0: /* fallthrough */ case INT: switch (size) { case 0: return (sign == UNSIGNED) ? uinttype : inttype; case SHORT: return (sign == UNSIGNED) ? ushortype : shortype; case LONG: return (sign == UNSIGNED) ? ulongtype : longtype; case LLONG: return (sign == UNSIGNED) ? ullongtype : llongtype; } break; case DOUBLE: if (size == LLONG) goto invalid_type; size += LONG; goto floating; case FLOAT: if (size == LLONG) goto invalid_type; floating: if (sign) goto invalid_type; switch (size) { case 0: return floattype; case LONG: return doubletype; case LLONG: return ldoubletype; } break; } invalid_type: error("invalid type specification"); } void typesize(Type *tp) { Symbol **sp; Type *aux; unsigned long size; int align, a; TINT n; switch (tp->op) { case ARY: /* FIXME: Control overflow */ tp->size = tp->n.elem * tp->type->size; tp->align = tp->type->align; return; case PTR: tp->size = pvoidtype->size; tp->align = pvoidtype->align; return; case STRUCT: case UNION: /* FIXME: Control overflow */ /* * The alignment of the struct/union is * he alignment of the largest included type. * The size of an union is the size of the largest * field, and the size of a struct is the sum * of the size of every field plus padding bits. */ align = size = 0; n = tp->n.elem; for (sp = tp->p.fields; n--; ++sp) { (*sp)->u.i = size; aux = (*sp)->type; a = aux->align; if (a > align) align = a; if (tp->op == STRUCT) { if (--a != 0) size += (size + a) & ~a; size += aux->size; } else { if (tp->size > size) size = aux->size; } } tp->align = align; /* * We have to add the padding bits to * ensure next struct in an array is well * alignment. */ if (tp->op == STRUCT && align-- > 1) size += size + align & ~align; tp->size = size; return; case ENUM: tp->size = inttype->size; tp->align = inttype->align; return; case FTN: return; default: abort(); } } Type * mktype(Type *tp, int op, TINT nelem, Type *pars[]) { static Type *typetab[NR_TYPE_HASH]; Type **tbl, type; unsigned t; Type *bp; int c, k_r = 0; if (op == PTR && tp == voidtype) return pvoidtype; if (op == KRFTN) { k_r = 1; op = FTN; } switch (op) { case PTR: c = L_POINTER; break; case ARY: c = L_ARRAY; break; case FTN: c = L_FUNCTION; break; case ENUM: c = L_ENUM; break; case STRUCT: c = L_STRUCT; break; case UNION: c = L_UNION; break; } type.type = tp; type.op = op; type.prop = k_r ? TK_R : 0; type.letter = c; type.p.pars = pars; type.n.elem = nelem; type.ns = 0; switch (op) { case ARY: if (nelem == 0) break; /* PASSTROUGH */ case FTN: case PTR: type.prop |= TDEFINED; break; case ENUM: type.prop |= TPRINTED | TINTEGER | TARITH; type.n.rank = RANK_INT; break; case STRUCT: case UNION: type.prop |= TAGGREG; break; default: abort(); } t = (op ^ (uintptr_t) tp >> 3) & NR_TYPE_HASH-1; tbl = &typetab[t]; for (bp = *tbl; bp; bp = bp->next) { if (eqtype(bp, &type) && op != STRUCT && op != UNION) { /* * pars was allocated by the caller * but the type already exists, so * we have to deallocte it */ free(pars); return bp; } } typesize(&type); bp = duptype(&type); bp->next = *tbl; return *tbl = bp; } int eqtype(Type *tp1, Type *tp2) { TINT n; Type **p1, **p2; if (tp1 == tp2) return 1; if (!tp1 || !tp2) return 0; if (tp1->op != tp2->op) return 0; switch (tp1->op) { case UNION: case STRUCT: case FTN: if (tp1->n.elem != tp2->n.elem) return 0; p1 = tp1->p.pars, p2 = tp2->p.pars; for (n = tp1->n.elem; n > 0; --n) { if (!eqtype(*p1++, *p2++)) return 0; } goto check_base; case ARY: if (tp1->n.elem != tp2->n.elem) return 0; case PTR: check_base: return eqtype(tp1->type, tp2->type); case VOID: case ENUM: return 0; case INT: case FLOAT: return tp1->letter == tp2->letter; default: abort(); } }