ref: 6235cb639285f9ff5a7fc483a1950a8cd42f9aa9
dir: /mi/match.c/
#include <stdlib.h>
#include <stdio.h>
#include <inttypes.h>
#include <stdarg.h>
#include <ctype.h>
#include <string.h>
#include <assert.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <unistd.h>
#include "parse.h"
#include "mi.h"
typedef struct Dtree Dtree;
struct Dtree {
/* If the values are equal, go to 'sub'. If 'val' is null, anything matches. */
Node *patexpr; /* the full pattern for this node */
Node **val; /* pattern values to compare against */
size_t nval;
Node **load; /* expression value being compared */
size_t nload;
Dtree **sub; /* submatch to use if if equal */
size_t nsub;
Dtree *any; /* tree for a wildcard match. */
/* captured variables and action */
Node **cap;
size_t ncap;
Node *act;
int id;
};
static Dtree *addpat(Dtree *t, Node *pat, Node *val, Node ***cap, size_t *ncap);
void dtdump(Dtree *dt, FILE *f);
/* We treat all integer types, boolean types, etc, as having 2^n constructors.
*
* since, of course, we can't represent all of the constructors for 64 bit
* integers using 64 bit values, we just approximate it. We'd have failed (run
* out of memory, etc) long before getting to this code if we actually had that
* many branches of the switch statements anyways.
*/
static size_t nconstructors(Type *t)
{
if (!t)
return 0;
t = tybase(t);
switch (t->type) {
case Tyvoid: return 0; break;
case Tybool: return 2; break;
case Tychar: return 0x10ffff; break;
/* signed ints */
case Tyint8: return 0x100; break;
case Tyint16: return 0x10000; break;
case Tyint32: return 0x100000000; break;
case Tyint: return 0x100000000; break;
case Tyint64: return ~0ull; break;
/* unsigned ints */
case Tybyte: return 0x100; break;
case Tyuint8: return 0x100; break;
case Tyuint16: return 0x10000; break;
case Tyuint32: return 0x100000000; break;
case Tyuint: return 0x100000000; break;
case Tyuint64: return ~0ull; break;
/* floats */
case Tyflt32: return ~0ull; break;
case Tyflt64: return ~0ull; break;
/* complex types */
case Typtr: return 1; break;
case Tyfunc: return 0; break;
case Tyarray: return 1; break;
case Tytuple: return 1; break;
case Tystruct: return 1;
case Tyunion: return t->nmemb; break;
case Tyslice: return ~0ULL; break;
case Tyvar: case Typaram: case Tyunres: case Tyname:
case Tybad: case Tyvalist: case Tygeneric: case Ntypes:
die("Invalid constructor type %s in match", tystr(t));
break;
}
return 0;
}
static int ndt;
static Dtree *mkdtree()
{
Dtree *t;
t = zalloc(sizeof(Dtree));
t->id = ndt++;
return t;
}
static Dtree *addwild(Dtree *t, Node *pat, Node *val, Node ***cap, size_t *ncap)
{
if (t->any)
return t->any;
t->any = mkdtree();
t->any->patexpr = pat;
if (cap && ncap)
lappend(cap, ncap, pat);
return t->any;
}
static Dtree *addunion(Dtree *t, Node *pat, Node *val, Node ***cap, size_t *ncap)
{
Dtree *sub;
size_t i;
if (t->any)
return t->any;
/* if we have the value already... */
sub = NULL;
for (i = 0; i < t->nval; i++) {
if (nameeq(t->val[i], pat->expr.args[0])) {
if (pat->expr.nargs > 1)
return addpat(t->sub[i], pat->expr.args[1], NULL, cap, ncap);
else
return t->sub[i];
}
}
sub = mkdtree();
sub->patexpr = pat;
lappend(&t->val, &t->nval, pat->expr.args[0]);
lappend(&t->sub, &t->nsub, sub);
if (pat->expr.nargs == 2)
sub = addpat(sub, pat->expr.args[1], NULL, cap, ncap);
return sub;
}
static Dtree *addlit(Dtree *t, Node *pat, Node *val, Node ***cap, size_t *ncap)
{
Dtree *sub;
size_t i;
if (t->any)
return t->any;
for (i = 0; i < t->nval; i++) {
if (liteq(t->val[i]->expr.args[0], pat->expr.args[0]))
return t->sub[i];
}
sub = mkdtree();
sub->patexpr = pat;
lappend(&t->val, &t->nval, pat);
lappend(&t->sub, &t->nsub, sub);
return sub;
}
static Dtree *addtup(Dtree *t, Node *pat, Node *val, Node ***cap, size_t *ncap)
{
size_t i;
if (t->any)
return t->any;
for (i = 0; i < pat->expr.nargs; i++)
t = addpat(t, pat->expr.args[i], NULL, cap, ncap);
return t;
}
static Dtree *addarr(Dtree *t, Node *pat, Node *val, Node ***cap, size_t *ncap)
{
size_t i;
if (t->any)
return t->any;
for (i = 0; i < pat->expr.nargs; i++)
t = addpat(t, pat->expr.args[i], NULL, cap, ncap);
return t;
}
static Dtree *addstruct(Dtree *t, Node *pat, Node *val, Node ***cap, size_t *ncap)
{
Node *elt;
size_t i, j;
if (t->any)
return t->any;
for (i = 0; i < pat->expr.nargs; i++) {
elt = pat->expr.args[i];
for (j = 0; j < t->nval; j++) {
if (!strcmp(namestr(elt->expr.idx), namestr(t->val[j]->expr.idx))) {
t = addpat(t, pat->expr.args[i], NULL, cap, ncap);
break;
}
}
}
return t;
}
static Dtree *addpat(Dtree *t, Node *pat, Node *val, Node ***cap, size_t *ncap)
{
Dtree *ret;
Node *dcl;
if (pat == NULL)
return t;
switch (exprop(pat)) {
case Ovar:
dcl = decls[pat->expr.did];
if (dcl->decl.isconst)
ret = addpat(t, dcl->decl.init, val, cap, ncap);
else
ret = addwild(t, pat, val, cap, ncap);
break;
case Oucon:
ret = addunion(t, pat, val, cap, ncap);
break;
case Olit:
ret = addlit(t, pat, val, cap, ncap);
break;
case Otup:
ret = addtup(t, pat, val, cap, ncap);
break;
case Oarr:
ret = addarr(t, pat, val, cap, ncap);
break;
case Ostruct:
ret = addstruct(t, pat, val, cap, ncap);
break;
case Ogap:
ret = addwild(t, pat, val, NULL, NULL);
break;
default:
ret = NULL;
fatal(pat, "unsupported pattern %s of type %s", opstr[exprop(pat)], tystr(exprtype(pat)));
break;
}
return ret;
}
static int isexhaustive(Dtree *dt)
{
Type *subt;
size_t i;
if (dt->any)
return 1;
if (dt->nsub > 0) {
subt = tybase(exprtype(dt->sub[0]->patexpr));
if (dt->nsub != nconstructors(subt))
return 0;
}
switch (exprop(dt->patexpr)) {
case Ovar:
return 1;
case Olit:
return 1;
case Oucon:
for (i = 0; i < dt->nsub; i++)
if (!isexhaustive(dt->sub[i]))
return 0;
return 1;
break;
case Otup:
for (i = 0; i < dt->nsub; i++)
if (!isexhaustive(dt->sub[i]))
return 0;
return 1;
break;
case Oarr:
for (i = 0; i < dt->nsub; i++)
if (!isexhaustive(dt->sub[i]))
return 0;
return 1;
break;
case Ostruct:
for (i = 0; i < dt->nsub; i++)
if (!isexhaustive(dt->sub[i]))
return 0;
return 1;
break;
default:
die("Invalid pattern in exhaustivenes check. BUG.");
break;
}
return 0;
}
static int exhaustivematch(Node *m, Dtree *t, Type *tt)
{
size_t i;
if (t->any)
return 1;
if (t->nsub != nconstructors(tt))
return 0;
for (i = 0; i < t->nsub; i++)
if (!isexhaustive(t->sub[i]))
return 0;
return 1;
}
static Node *genmatch(Dtree *dt)
{
return NULL;
}
Node *gensimpmatch(Node *m)
{
Dtree *t, *leaf;
Node **pat, **cap;
size_t npat, ncap;
size_t i;
pat = m->matchstmt.matches;
npat = m->matchstmt.nmatches;
t = mkdtree();
for (i = 0; i < npat; i++) {
cap = NULL;
ncap = 0;
leaf = addpat(t, pat[i]->match.pat, NULL, &cap, &ncap);
/* TODO: NULL is returned by unsupported patterns. */
if (!leaf)
return NULL;
if (leaf->act)
fatal(pat[i], "pattern matched by earlier case on line %d", leaf->act->loc.line);
leaf->act = pat[i]->match.block;
leaf->cap = cap;
leaf->ncap = ncap;
}
if (!exhaustivematch(m, t, exprtype(m->matchstmt.val)))
fatal(m, "nonexhaustive pattern set in match statement");
return genmatch(t);
}
char *dtnodestr(Node *n)
{
switch (exprop(n)) {
case Ovar:
return namestr(n->expr.args[0]);
case Olit:
return litstr[n->expr.args[0]->lit.littype];
case Oucon:
return namestr(n->expr.args[0]);
case Otup:
return "tuple";
case Oarr:
return "array";
case Ostruct:
return "struct";
default:
die("Invalid pattern in exhaustivenes check. BUG.");
break;
}
return "???";
}
void dtdumpnode(Dtree *dt, FILE *f, int depth, int iswild)
{
Node *e;
size_t i;
char *s;
if (dt->patexpr) {
e = dt->patexpr;
s = tystr(exprtype(e));
indentf(depth, "%s%s %s : %s\n", iswild ? "WILDCARD " : "", opstr[exprop(e)], dtnodestr(e), s);
free(s);
}
if (dt->cap)
for (i = 0; i < dt->ncap; i++)
indentf(depth + 1, "capture %s\n", dtnodestr(dt->cap[i]));
if (dt->act)
indentf(depth + 1, "action\n");
for (i = 0; i < dt->nsub; i++)
dtdumpnode(dt->sub[i], f, depth + 1, 0);
if (dt->any)
dtdumpnode(dt->any, f, depth + 1, 1);
}
void dtdump(Dtree *dt, FILE *f)
{
dtdumpnode(dt, f, 0, 0);
}