static void
flattencond(Flattenctx *s, Node *n, Node *ltrue, Node *lfalse)
{
Node **args;
Node *v, *lnext;
args = n->expr.args;
switch (exprop(n)) {
case Oland:
lnext = genlbl(n->loc);
flattencond(s, args[0], lnext, lfalse);
append(s, lnext);
flattencond(s, args[1], ltrue, lfalse);
break;
case Olor:
lnext = genlbl(n->loc);
flattencond(s, args[0], ltrue, lnext);
append(s, lnext);
flattencond(s, args[1], ltrue, lfalse);
break;
case Olnot:
flattencond(s, args[0], lfalse, ltrue);
break;
default:
v = rval(s, n);
cjmp(s, v, ltrue, lfalse);
break;
}
}
static Node*
flattentern(Flattenctx *s, Node *n)
{
Node *l1, *l2, *l3;
Node *res, *t;
l1 = genlbl(n->loc);
l2 = genlbl(n->loc);
l3 = genlbl(n->loc);
res = temp(s, n);
flattencond(s, n->expr.args[0], l1, l2);
append(s, l1);
t = assign(s, res, rval(s, n->expr.args[1]));
append(s, t);
jmp(s, l3);
append(s, l2);
t = assign(s, res, rval(s, n->expr.args[2]));
append(s, t);
append(s, l3);
return res;
}
static void simpmatch(Simp *s, Node *n)
{
Node *end, *cur, *next; /* labels */
Node *val, *tmp;
Node *m;
size_t i;
end = genlbl();
val = temp(s, n->matchstmt.val);
tmp = rval(s, n->matchstmt.val, val);
if (val != tmp)
append(s, assign(s, val, tmp));
for (i = 0; i < n->matchstmt.nmatches; i++) {
m = n->matchstmt.matches[i];
/* check pattern */
cur = genlbl();
next = genlbl();
umatch(s, m->match.pat, val, val->expr.type, cur, next);
/* do the action if it matches */
append(s, cur);
simp(s, m->match.block);
jmp(s, end);
append(s, next);
}
append(s, end);
}
static void simpcond(Simp *s, Node *n, Node *ltrue, Node *lfalse)
{
Node **args;
Node *v, *lnext;
args = n->expr.args;
switch (exprop(n)) {
case Oland:
lnext = genlbl();
simpcond(s, args[0], lnext, lfalse);
append(s, lnext);
simpcond(s, args[1], ltrue, lfalse);
break;
case Olor:
lnext = genlbl();
simpcond(s, args[0], ltrue, lnext);
append(s, lnext);
simpcond(s, args[1], ltrue, lfalse);
break;
case Olnot:
simpcond(s, args[0], lfalse, ltrue);
break;
default:
v = rval(s, n, NULL);
cjmp(s, v, ltrue, lfalse);
break;
}
}
/* init; while cond; body;;
* => init
* jmp :cond
* :body
* ...body...
* ...step...
* :cond
* ...cond...
* cjmp (cond) :body :end
* :end
*/
static void simploop(Simp *s, Node *n)
{
Node *lbody;
Node *lend;
Node *lcond;
Node *lstep;
lbody = genlbl();
lcond = genlbl();
lstep = genlbl();
lend = genlbl();
lappend(&s->loopstep, &s->nloopstep, lstep);
lappend(&s->loopexit, &s->nloopexit, lend);
simp(s, n->loopstmt.init); /* init */
jmp(s, lcond); /* goto test */
simp(s, lbody); /* body lbl */
simp(s, n->loopstmt.body); /* body */
simp(s, lstep); /* test lbl */
simp(s, n->loopstmt.step); /* step */
simp(s, lcond); /* test lbl */
simpcond(s, n->loopstmt.cond, lbody, lend); /* repeat? */
simp(s, lend); /* exit */
s->nloopstep--;
s->nloopexit--;
}
/* if foo; bar; else baz;;
* => cjmp (foo) :bar :baz */
static void simpif(Simp *s, Node *n, Node *exit)
{
Node *l1, *l2, *l3;
Node *iftrue, *iffalse;
l1 = genlbl();
l2 = genlbl();
if (exit)
l3 = exit;
else
l3 = genlbl();
iftrue = n->ifstmt.iftrue;
iffalse = n->ifstmt.iffalse;
simpcond(s, n->ifstmt.cond, l1, l2);
simp(s, l1);
simp(s, iftrue);
jmp(s, l3);
simp(s, l2);
/* because lots of bunched up end labels are ugly,
* coalesce them by handling 'elif'-like constructs
* separately */
if (iffalse && iffalse->type == Nifstmt) {
simpif(s, iffalse, exit);
} else {
simp(s, iffalse);
jmp(s, l3);
}
if (!exit)
simp(s, l3);
}
/* simplifies
* a || b
* to
* if a || b
* t = true
* else
* t = false
* ;;
*/
static Node *simplazy(Simp *s, Node *n)
{
Node *r, *t, *u;
Node *ltrue, *lfalse, *ldone;
/* set up temps and labels */
r = temp(s, n);
ltrue = genlbl();
lfalse = genlbl();
ldone = genlbl();
/* simp the conditional */
simpcond(s, n, ltrue, lfalse);
/* if true */
append(s, ltrue);
u = mkexpr(n->line, Olit, mkbool(n->line, 1), NULL);
u->expr.type = mktype(n->line, Tybool);
t = set(r, u);
append(s, t);
jmp(s, ldone);
/* if false */
append(s, lfalse);
u = mkexpr(n->line, Olit, mkbool(n->line, 0), NULL);
u->expr.type = mktype(n->line, Tybool);
t = set(r, u);
append(s, t);
jmp(s, ldone);
/* finish */
append(s, ldone);
return r;
}
/* pat; seq;
* body;;
*
* =>
* .pseudo = seqinit
* jmp :cond
* :body
* ...body...
* :step
* ...step...
* :cond
* ...cond...
* cjmp (cond) :match :end
* :match
* ...match...
* cjmp (match) :body :step
* :end
*/
static void simpiter(Simp *s, Node *n)
{
Node *lbody, *lstep, *lcond, *lmatch, *lend;
Node *idx, *len, *dcl, *seq, *val, *done;
Node *zero;
lbody = genlbl();
lstep = genlbl();
lcond = genlbl();
lmatch = genlbl();
lend = genlbl();
lappend(&s->loopstep, &s->nloopstep, lstep);
lappend(&s->loopexit, &s->nloopexit, lend);
zero = mkintlit(n->line, 0);
zero->expr.type = tyintptr;
seq = rval(s, n->iterstmt.seq, NULL);
idx = gentemp(s, n, tyintptr, &dcl);
declarelocal(s, dcl);
/* setup */
append(s, assign(s, idx, zero));
jmp(s, lcond);
simp(s, lbody);
/* body */
simp(s, n->iterstmt.body);
/* step */
simp(s, lstep);
simp(s, assign(s, idx, addk(idx, 1)));
/* condition */
simp(s, lcond);
len = seqlen(s, seq, tyintptr);
done = mkexpr(n->line, Olt, idx, len, NULL);
cjmp(s, done, lmatch, lend);
simp(s, lmatch);
val = load(idxaddr(s, seq, idx));
umatch(s, n->iterstmt.elt, val, val->expr.type, lbody, lstep);
simp(s, lend);
s->nloopstep--;
s->nloopexit--;
}
/* flatten
* a || b
* to
* if a || b
* t = true
* else
* t = false
* ;;
*/
static Node *
flattenlazy(Flattenctx *s, Node *n)
{
Node *r, *t, *u;
Node *ltrue, *lfalse, *ldone;
/* set up temps and labels */
r = temp(s, n);
ltrue = genlbl(n->loc);
lfalse = genlbl(n->loc);
ldone = genlbl(n->loc);
/* flatten the conditional */
flattencond(s, n, ltrue, lfalse);
/* if true */
append(s, ltrue);
u = mkexpr(n->loc, Olit, mkbool(n->loc, 1), NULL);
u->expr.type = mktype(n->loc, Tybool);
t = asn(r, u);
append(s, t);
jmp(s, ldone);
/* if false */
append(s, lfalse);
u = mkexpr(n->loc, Olit, mkbool(n->loc, 0), NULL);
u->expr.type = mktype(n->loc, Tybool);
t = asn(r, u);
append(s, t);
jmp(s, ldone);
/* finish */
append(s, ldone);
return r;
}
static void umatch(Simp *s, Node *pat, Node *val, Type *t, Node *iftrue, Node *iffalse)
{
Node *v, *x, *y;
Node *deeper, *next;
Node **patarg;
Ucon *uc;
size_t i;
size_t off;
assert(pat->type == Nexpr);
t = tybase(t);
if (exprop(pat) == Ovar && !decls[pat->expr.did]->decl.isconst) {
v = assign(s, pat, val);
append(s, v);
jmp(s, iftrue);
return;
}
switch (t->type) {
/* Never supported */
case Tyvoid: case Tybad: case Tyvalist: case Tyvar:
case Typaram: case Tyunres: case Tyname: case Ntypes:
/* Should never show up */
case Tyslice:
die("Unsupported type for compare");
break;
case Tybool: case Tychar: case Tybyte:
case Tyint8: case Tyint16: case Tyint32: case Tyint:
case Tyuint8: case Tyuint16: case Tyuint32: case Tyuint:
case Tyint64: case Tyuint64: case Tylong: case Tyulong:
case Tyfloat32: case Tyfloat64:
case Typtr: case Tyfunc:
v = mkexpr(pat->line, Oeq, pat, val, NULL);
v->expr.type = mktype(pat->line, Tybool);
cjmp(s, v, iftrue, iffalse);
break;
/* We got lucky. The structure of tuple, array, and struct literals
* is the same, so long as we don't inspect the type, so we can
* share the code*/
case Tystruct: case Tytuple: case Tyarray:
patarg = pat->expr.args;
off = 0;
for (i = 0; i < pat->expr.nargs; i++) {
off = tyalign(off, size(patarg[i]));
next = genlbl();
v = load(addk(addr(s, val, exprtype(patarg[i])), off));
umatch(s, patarg[i], v, exprtype(patarg[i]), next, iffalse);
append(s, next);
off += size(patarg[i]);
}
jmp(s, iftrue);
break;
case Tyunion:
uc = finducon(pat);
if (!uc)
uc = finducon(val);
deeper = genlbl();
x = uconid(s, pat);
y = uconid(s, val);
v = mkexpr(pat->line, Oeq, x, y, NULL);
v->expr.type = tyintptr;
cjmp(s, v, deeper, iffalse);
append(s, deeper);
if (uc->etype) {
pat = patval(s, pat, uc->etype);
val = patval(s, val, uc->etype);
umatch(s, pat, val, uc->etype, iftrue, iffalse);
}
break;
}
}
