ref: 5d1501e35338badd9a2958f1c1c68ad52ea2b020
dir: /cc1/types.c/
static char sccsid[] = "@(#) ./cc1/types.c";
#include <assert.h>
#include <inttypes.h>
#include <stdlib.h>
#include <string.h>
#include <cstd.h>
#include "../inc/scc.h"
#include "cc1.h"
#define NR_TYPE_HASH 16
#define HASH(t) (((t)->op ^ (uintptr_t) (t)->type>>3) & NR_TYPE_HASH-1)
static Type *typetab[NR_TYPE_HASH], *localtypes;
/* 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 = 0xff
},
{ /* 1 = unsigned 2 bytes */
.min.i = 0,
.max.i = 0xffff
},
{ /* 2 = unsigned 4 bytes */
.min.i = 0,
.max.i = 0xffffffff
},
{ /* 3 = unsigned 8 bytes */
.min.i = 0,
.max.i = 0xffffffffffffffff
}
},
{
{ /* 0 = signed 1 byte */
.min.i = -0x7f-1,
.max.i = 0x7f
},
{ /* 1 = signed 2 byte */
.min.i = -0x7fff-1,
.max.i = 0x7fff
},
{ /* 2 = signed 4 byte */
.min.i = -0x7fffffff-1,
.max.i = 0x7fffffff
},
{ /* 3 = signed 8 byte */
.min.i = -0x7fffffffffffffff-1,
.max.i = 0x7fffffffffffffff,
}
},
{
{
/* 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;
default:
abort();
}
return &limits[ntable][ntype];
}
Type *
ctype(int type, int sign, int 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 VA_LIST:
if (size || sign)
goto invalid_type;
return va_list_type;
case VOID:
if (size || sign)
goto invalid_type;
return voidtype;
case BOOL:
if (size || sign)
goto invalid_type;
return booltype;
case 0:
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;
if (size == LONG)
size = LLONG;
else
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 *type;
unsigned long size, offset;
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.
*/
offset = align = size = 0;
n = tp->n.elem;
for (sp = tp->p.fields; n--; ++sp) {
(*sp)->u.i = offset;
type = (*sp)->type;
a = type->align;
if (a > align)
align = a;
if (tp->op == STRUCT) {
if (--a != 0)
size = (size + a) & ~a;
size += type->size;
offset = size;
} else {
if (type->size > size)
size = type->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 *
deftype(Type *tp)
{
tp->prop |= TDEFINED;
typesize(tp);
emit(OTYP, tp);
return tp;
}
static Type *
newtype(Type *base)
{
Type *tp;
size_t siz;
tp = xmalloc(sizeof(*tp));
*tp = *base;
tp->id = newid();
if (tp->op == FTN) {
siz = tp->n.elem * sizeof(Type *);
tp->p.pars = memcpy(xmalloc(siz), tp->p.pars, siz);
}
if (curfun) {
/* it is a type defined in the body of a function */
tp->next = localtypes;
localtypes = tp;
}
if (tp->prop & TDEFINED)
deftype(tp);
return tp;
}
Type *
mktype(Type *tp, int op, TINT nelem, Type *pars[])
{
Type **tbl, type;
Type *bp;
if (op == PTR && tp == voidtype)
return pvoidtype;
memset(&type, 0, sizeof(type));
type.type = tp;
type.op = op;
type.p.pars = pars;
type.n.elem = nelem;
switch (op) {
case ARY:
if (tp == voidtype) {
errorp("declaration of array of voids type");
tp = inttype;
}
type.letter = L_ARRAY;
if (nelem != 0)
type.prop |= TDEFINED;
break;
case KRFTN:
type.prop |= TDEFINED | TK_R;
type.op = FTN;
type.letter = L_FUNCTION;
break;
case FTN:
if (nelem > 0 && pars[nelem-1] == ellipsistype)
type.prop |= TELLIPSIS;
type.letter = L_FUNCTION;
type.prop |= TDEFINED;
break;
case PTR:
type.letter = L_POINTER;
type.prop |= TDEFINED;
break;
case ENUM:
type.letter = inttype->letter;
type.prop |= TINTEGER | TARITH;
type.n.rank = inttype->n.rank;
goto create_type;
case STRUCT:
type.letter = L_STRUCT;
type.prop |= TAGGREG;
goto create_type;
case UNION:
type.letter = L_UNION;
type.prop |= TAGGREG;
create_type:
return newtype(&type);
default:
abort();
}
tbl = &typetab[HASH(&type)];
for (bp = *tbl; bp; bp = bp->h_next) {
if (eqtype(bp, &type, 0))
return bp;
}
bp = newtype(&type);
bp->h_next = *tbl;
*tbl = bp;
return bp;
}
int
eqtype(Type *tp1, Type *tp2, int equiv)
{
TINT n;
Type **p1, **p2;
Symbol **s1, **s2;
if (tp1 == tp2)
return 1;
if (!tp1 || !tp2)
return 0;
if (tp1->op != tp2->op)
return 0;
switch (tp1->op) {
case UNION:
case STRUCT:
if (tp1->letter != tp2->letter)
return 0;
if (tp1->tag->name || tp2->tag->name)
return tp1->tag == tp2->tag;
if (tp1->n.elem != tp2->n.elem)
return 0;
s1 = tp1->p.fields, s2 = tp2->p.fields;
for (n = tp1->n.elem; n > 0; --n, ++s1, ++s2) {
if (strcmp((*s1)->name, (*s2)->name))
return 0;
if (!eqtype((*s1)->type, (*s2)->type, equiv))
return 0;
}
return 1;
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++, equiv))
return 0;
}
goto check_base;
case ARY:
if (equiv && (tp1->n.elem == 0 || tp2->n.elem == 0))
goto check_base;
if (tp1->n.elem != tp2->n.elem)
return 0;
case PTR:
check_base:
return eqtype(tp1->type, tp2->type, equiv);
case VOID:
case ENUM:
return 0;
case INT:
case FLOAT:
return tp1->letter == tp2->letter;
default:
abort();
}
}
void
flushtypes(void)
{
Type *tp, *next, **h;
for (tp = localtypes; tp; tp = next) {
next = tp->next;
switch (tp->op) {
default:
/*
* All the local types are linked after
* global types, and since we are
* unlinking them in the inverse order
* we do know that tp is always the head
* of the collision list
*/
h = &typetab[HASH(tp)];
assert(*h == tp);
*h = tp->h_next;
case STRUCT:
case UNION:
case ENUM:
free(tp);
break;
}
}
localtypes = NULL;
}