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// Derived from Inferno utils/6c/peep.c
// http://code.google.com/p/inferno-os/source/browse/utils/6c/peep.c
//
// Copyright © 1994-1999 Lucent Technologies Inc. All rights reserved.
// Portions Copyright © 1995-1997 C H Forsyth (forsyth@terzarima.net)
// Portions Copyright © 1997-1999 Vita Nuova Limited
// Portions Copyright © 2000-2007 Vita Nuova Holdings Limited (www.vitanuova.com)
// Portions Copyright © 2004,2006 Bruce Ellis
// Portions Copyright © 2005-2007 C H Forsyth (forsyth@terzarima.net)
// Revisions Copyright © 2000-2007 Lucent Technologies Inc. and others
// Portions Copyright © 2009 The Go Authors. All rights reserved.
//
// Permission is hereby granted, free of charge, to any person obtaining a copy
// of this software and associated documentation files (the "Software"), to deal
// in the Software without restriction, including without limitation the rights
// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
// copies of the Software, and to permit persons to whom the Software is
// furnished to do so, subject to the following conditions:
//
// The above copyright notice and this permission notice shall be included in
// all copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
// THE SOFTWARE.
#include <u.h>
#include <libc.h>
#include "gg.h"
#include "opt.h"
static void conprop(Flow *r);
static void elimshortmov(Graph *g);
static int prevl(Flow *r, int reg);
static void pushback(Flow *r);
static int regconsttyp(Adr*);
static int subprop(Flow*);
static int copyprop(Graph*, Flow*);
static int copy1(Adr*, Adr*, Flow*, int);
static int copyas(Adr*, Adr*);
static int copyau(Adr*, Adr*);
static int copysub(Adr*, Adr*, Adr*, int);
static uint32 gactive;
// do we need the carry bit
static int
needc(Prog *p)
{
ProgInfo info;
while(p != P) {
proginfo(&info, p);
if(info.flags & UseCarry)
return 1;
if(info.flags & (SetCarry|KillCarry))
return 0;
p = p->link;
}
return 0;
}
static Flow*
rnops(Flow *r)
{
Prog *p;
Flow *r1;
if(r != nil)
for(;;) {
p = r->prog;
if(p->as != ANOP || p->from.type != D_NONE || p->to.type != D_NONE)
break;
r1 = uniqs(r);
if(r1 == nil)
break;
r = r1;
}
return r;
}
void
peep(Prog *firstp)
{
Flow *r, *r1;
Graph *g;
Prog *p, *p1;
int t;
g = flowstart(firstp, sizeof(Flow));
if(g == nil)
return;
gactive = 0;
// byte, word arithmetic elimination.
elimshortmov(g);
// constant propagation
// find MOV $con,R followed by
// another MOV $con,R without
// setting R in the interim
for(r=g->start; r!=nil; r=r->link) {
p = r->prog;
switch(p->as) {
case ALEAL:
case ALEAQ:
if(regtyp(&p->to))
if(p->from.sym != nil)
if(p->from.index == D_NONE || p->from.index == D_CONST)
conprop(r);
break;
case AMOVB:
case AMOVW:
case AMOVL:
case AMOVQ:
case AMOVSS:
case AMOVSD:
if(regtyp(&p->to))
if(p->from.type == D_CONST)
conprop(r);
break;
}
}
loop1:
if(debug['P'] && debug['v'])
dumpit("loop1", g->start, 0);
t = 0;
for(r=g->start; r!=nil; r=r->link) {
p = r->prog;
switch(p->as) {
case AMOVL:
case AMOVQ:
case AMOVSS:
case AMOVSD:
if(regtyp(&p->to))
if(regtyp(&p->from)) {
if(copyprop(g, r)) {
excise(r);
t++;
} else
if(subprop(r) && copyprop(g, r)) {
excise(r);
t++;
}
}
break;
case AMOVBLZX:
case AMOVWLZX:
case AMOVBLSX:
case AMOVWLSX:
if(regtyp(&p->to)) {
r1 = rnops(uniqs(r));
if(r1 != nil) {
p1 = r1->prog;
if(p->as == p1->as && p->to.type == p1->from.type){
p1->as = AMOVL;
t++;
}
}
}
break;
case AMOVBQSX:
case AMOVBQZX:
case AMOVWQSX:
case AMOVWQZX:
case AMOVLQSX:
case AMOVLQZX:
case AMOVQL:
if(regtyp(&p->to)) {
r1 = rnops(uniqs(r));
if(r1 != nil) {
p1 = r1->prog;
if(p->as == p1->as && p->to.type == p1->from.type){
p1->as = AMOVQ;
t++;
}
}
}
break;
case AADDL:
case AADDQ:
case AADDW:
if(p->from.type != D_CONST || needc(p->link))
break;
if(p->from.offset == -1){
if(p->as == AADDQ)
p->as = ADECQ;
else
if(p->as == AADDL)
p->as = ADECL;
else
p->as = ADECW;
p->from = zprog.from;
break;
}
if(p->from.offset == 1){
if(p->as == AADDQ)
p->as = AINCQ;
else if(p->as == AADDL)
p->as = AINCL;
else
p->as = AINCW;
p->from = zprog.from;
break;
}
break;
case ASUBL:
case ASUBQ:
case ASUBW:
if(p->from.type != D_CONST || needc(p->link))
break;
if(p->from.offset == -1) {
if(p->as == ASUBQ)
p->as = AINCQ;
else
if(p->as == ASUBL)
p->as = AINCL;
else
p->as = AINCW;
p->from = zprog.from;
break;
}
if(p->from.offset == 1){
if(p->as == ASUBQ)
p->as = ADECQ;
else
if(p->as == ASUBL)
p->as = ADECL;
else
p->as = ADECW;
p->from = zprog.from;
break;
}
break;
}
}
if(t)
goto loop1;
// MOVLQZX removal.
// The MOVLQZX exists to avoid being confused for a
// MOVL that is just copying 32-bit data around during
// copyprop. Now that copyprop is done, remov MOVLQZX R1, R2
// if it is dominated by an earlier ADDL/MOVL/etc into R1 that
// will have already cleared the high bits.
//
// MOVSD removal.
// We never use packed registers, so a MOVSD between registers
// can be replaced by MOVAPD, which moves the pair of float64s
// instead of just the lower one. We only use the lower one, but
// the processor can do better if we do moves using both.
for(r=g->start; r!=nil; r=r->link) {
p = r->prog;
if(p->as == AMOVLQZX)
if(regtyp(&p->from))
if(p->from.type == p->to.type)
if(prevl(r, p->from.type))
excise(r);
if(p->as == AMOVSD)
if(regtyp(&p->from))
if(regtyp(&p->to))
p->as = AMOVAPD;
}
// load pipelining
// push any load from memory as early as possible
// to give it time to complete before use.
for(r=g->start; r!=nil; r=r->link) {
p = r->prog;
switch(p->as) {
case AMOVB:
case AMOVW:
case AMOVL:
case AMOVQ:
case AMOVLQZX:
if(regtyp(&p->to) && !regconsttyp(&p->from))
pushback(r);
}
}
flowend(g);
}
static void
pushback(Flow *r0)
{
Flow *r, *b;
Prog *p0, *p, t;
b = nil;
p0 = r0->prog;
for(r=uniqp(r0); r!=nil && uniqs(r)!=nil; r=uniqp(r)) {
p = r->prog;
if(p->as != ANOP) {
if(!regconsttyp(&p->from) || !regtyp(&p->to))
break;
if(copyu(p, &p0->to, nil) || copyu(p0, &p->to, nil))
break;
}
if(p->as == ACALL)
break;
b = r;
}
if(b == nil) {
if(debug['v']) {
print("no pushback: %P\n", r0->prog);
if(r)
print("\t%P [%d]\n", r->prog, uniqs(r)!=nil);
}
return;
}
if(debug['v']) {
print("pushback\n");
for(r=b;; r=r->link) {
print("\t%P\n", r->prog);
if(r == r0)
break;
}
}
t = *r0->prog;
for(r=uniqp(r0);; r=uniqp(r)) {
p0 = r->link->prog;
p = r->prog;
p0->as = p->as;
p0->lineno = p->lineno;
p0->from = p->from;
p0->to = p->to;
if(r == b)
break;
}
p0 = r->prog;
p0->as = t.as;
p0->lineno = t.lineno;
p0->from = t.from;
p0->to = t.to;
if(debug['v']) {
print("\tafter\n");
for(r=b;; r=r->link) {
print("\t%P\n", r->prog);
if(r == r0)
break;
}
}
}
void
excise(Flow *r)
{
Prog *p;
p = r->prog;
if(debug['P'] && debug['v'])
print("%P ===delete===\n", p);
p->as = ANOP;
p->from = zprog.from;
p->to = zprog.to;
ostats.ndelmov++;
}
int
regtyp(Adr *a)
{
int t;
t = a->type;
if(t >= D_AX && t <= D_R15)
return 1;
if(t >= D_X0 && t <= D_X0+15)
return 1;
return 0;
}
// movb elimination.
// movb is simulated by the linker
// when a register other than ax, bx, cx, dx
// is used, so rewrite to other instructions
// when possible. a movb into a register
// can smash the entire 32-bit register without
// causing any trouble.
//
// TODO: Using the Q forms here instead of the L forms
// seems unnecessary, and it makes the instructions longer.
static void
elimshortmov(Graph *g)
{
Prog *p;
Flow *r;
for(r=g->start; r!=nil; r=r->link) {
p = r->prog;
if(regtyp(&p->to)) {
switch(p->as) {
case AINCB:
case AINCW:
p->as = AINCQ;
break;
case ADECB:
case ADECW:
p->as = ADECQ;
break;
case ANEGB:
case ANEGW:
p->as = ANEGQ;
break;
case ANOTB:
case ANOTW:
p->as = ANOTQ;
break;
}
if(regtyp(&p->from) || p->from.type == D_CONST) {
// move or artihmetic into partial register.
// from another register or constant can be movl.
// we don't switch to 64-bit arithmetic if it can
// change how the carry bit is set (and the carry bit is needed).
switch(p->as) {
case AMOVB:
case AMOVW:
p->as = AMOVQ;
break;
case AADDB:
case AADDW:
if(!needc(p->link))
p->as = AADDQ;
break;
case ASUBB:
case ASUBW:
if(!needc(p->link))
p->as = ASUBQ;
break;
case AMULB:
case AMULW:
p->as = AMULQ;
break;
case AIMULB:
case AIMULW:
p->as = AIMULQ;
break;
case AANDB:
case AANDW:
p->as = AANDQ;
break;
case AORB:
case AORW:
p->as = AORQ;
break;
case AXORB:
case AXORW:
p->as = AXORQ;
break;
case ASHLB:
case ASHLW:
p->as = ASHLQ;
break;
}
} else if(p->from.type >= D_NONE) {
// explicit zero extension, but don't
// do that if source is a byte register
// (only AH can occur and it's forbidden).
switch(p->as) {
case AMOVB:
p->as = AMOVBQZX;
break;
case AMOVW:
p->as = AMOVWQZX;
break;
}
}
}
}
}
// is 'a' a register or constant?
static int
regconsttyp(Adr *a)
{
if(regtyp(a))
return 1;
switch(a->type) {
case D_CONST:
case D_FCONST:
case D_SCONST:
case D_ADDR:
return 1;
}
return 0;
}
// is reg guaranteed to be truncated by a previous L instruction?
static int
prevl(Flow *r0, int reg)
{
Prog *p;
Flow *r;
ProgInfo info;
for(r=uniqp(r0); r!=nil; r=uniqp(r)) {
p = r->prog;
if(p->to.type == reg) {
proginfo(&info, p);
if(info.flags & RightWrite) {
if(info.flags & SizeL)
return 1;
return 0;
}
}
}
return 0;
}
/*
* the idea is to substitute
* one register for another
* from one MOV to another
* MOV a, R0
* ADD b, R0 / no use of R1
* MOV R0, R1
* would be converted to
* MOV a, R1
* ADD b, R1
* MOV R1, R0
* hopefully, then the former or latter MOV
* will be eliminated by copy propagation.
*/
static int
subprop(Flow *r0)
{
Prog *p;
ProgInfo info;
Adr *v1, *v2;
Flow *r;
int t;
if(debug['P'] && debug['v'])
print("subprop %P\n", r0->prog);
p = r0->prog;
v1 = &p->from;
if(!regtyp(v1)) {
if(debug['P'] && debug['v'])
print("\tnot regtype %D; return 0\n", v1);
return 0;
}
v2 = &p->to;
if(!regtyp(v2)) {
if(debug['P'] && debug['v'])
print("\tnot regtype %D; return 0\n", v2);
return 0;
}
for(r=uniqp(r0); r!=nil; r=uniqp(r)) {
if(debug['P'] && debug['v'])
print("\t? %P\n", r->prog);
if(uniqs(r) == nil) {
if(debug['P'] && debug['v'])
print("\tno unique successor\n");
break;
}
p = r->prog;
if(p->as == AVARDEF || p->as == AVARKILL)
continue;
proginfo(&info, p);
if(info.flags & Call) {
if(debug['P'] && debug['v'])
print("\tfound %P; return 0\n", p);
return 0;
}
if(info.reguse | info.regset) {
if(debug['P'] && debug['v'])
print("\tfound %P; return 0\n", p);
return 0;
}
if((info.flags & Move) && (info.flags & (SizeL|SizeQ|SizeF|SizeD)) && p->to.type == v1->type)
goto gotit;
if(copyau(&p->from, v2) ||
copyau(&p->to, v2)) {
if(debug['P'] && debug['v'])
print("\tcopyau %D failed\n", v2);
break;
}
if(copysub(&p->from, v1, v2, 0) ||
copysub(&p->to, v1, v2, 0)) {
if(debug['P'] && debug['v'])
print("\tcopysub failed\n");
break;
}
}
if(debug['P'] && debug['v'])
print("\tran off end; return 0\n");
return 0;
gotit:
copysub(&p->to, v1, v2, 1);
if(debug['P']) {
print("gotit: %D->%D\n%P", v1, v2, r->prog);
if(p->from.type == v2->type)
print(" excise");
print("\n");
}
for(r=uniqs(r); r!=r0; r=uniqs(r)) {
p = r->prog;
copysub(&p->from, v1, v2, 1);
copysub(&p->to, v1, v2, 1);
if(debug['P'])
print("%P\n", r->prog);
}
t = v1->type;
v1->type = v2->type;
v2->type = t;
if(debug['P'])
print("%P last\n", r->prog);
return 1;
}
/*
* The idea is to remove redundant copies.
* v1->v2 F=0
* (use v2 s/v2/v1/)*
* set v1 F=1
* use v2 return fail
* -----------------
* v1->v2 F=0
* (use v2 s/v2/v1/)*
* set v1 F=1
* set v2 return success
*/
static int
copyprop(Graph *g, Flow *r0)
{
Prog *p;
Adr *v1, *v2;
USED(g);
if(debug['P'] && debug['v'])
print("copyprop %P\n", r0->prog);
p = r0->prog;
v1 = &p->from;
v2 = &p->to;
if(copyas(v1, v2))
return 1;
gactive++;
return copy1(v1, v2, r0->s1, 0);
}
static int
copy1(Adr *v1, Adr *v2, Flow *r, int f)
{
int t;
Prog *p;
if(r->active == gactive) {
if(debug['P'])
print("act set; return 1\n");
return 1;
}
r->active = gactive;
if(debug['P'])
print("copy %D->%D f=%d\n", v1, v2, f);
for(; r != nil; r = r->s1) {
p = r->prog;
if(debug['P'])
print("%P", p);
if(!f && uniqp(r) == nil) {
f = 1;
if(debug['P'])
print("; merge; f=%d", f);
}
t = copyu(p, v2, nil);
switch(t) {
case 2: /* rar, can't split */
if(debug['P'])
print("; %D rar; return 0\n", v2);
return 0;
case 3: /* set */
if(debug['P'])
print("; %D set; return 1\n", v2);
return 1;
case 1: /* used, substitute */
case 4: /* use and set */
if(f) {
if(!debug['P'])
return 0;
if(t == 4)
print("; %D used+set and f=%d; return 0\n", v2, f);
else
print("; %D used and f=%d; return 0\n", v2, f);
return 0;
}
if(copyu(p, v2, v1)) {
if(debug['P'])
print("; sub fail; return 0\n");
return 0;
}
if(debug['P'])
print("; sub %D/%D", v2, v1);
if(t == 4) {
if(debug['P'])
print("; %D used+set; return 1\n", v2);
return 1;
}
break;
}
if(!f) {
t = copyu(p, v1, nil);
if(!f && (t == 2 || t == 3 || t == 4)) {
f = 1;
if(debug['P'])
print("; %D set and !f; f=%d", v1, f);
}
}
if(debug['P'])
print("\n");
if(r->s2)
if(!copy1(v1, v2, r->s2, f))
return 0;
}
return 1;
}
/*
* return
* 1 if v only used (and substitute),
* 2 if read-alter-rewrite
* 3 if set
* 4 if set and used
* 0 otherwise (not touched)
*/
int
copyu(Prog *p, Adr *v, Adr *s)
{
ProgInfo info;
switch(p->as) {
case AJMP:
if(s != nil) {
if(copysub(&p->to, v, s, 1))
return 1;
return 0;
}
if(copyau(&p->to, v))
return 1;
return 0;
case ARET:
if(s != nil)
return 1;
return 3;
case ACALL:
if(REGEXT && v->type <= REGEXT && v->type > exregoffset)
return 2;
if(REGARG >= 0 && v->type == (uchar)REGARG)
return 2;
if(v->type == p->from.type)
return 2;
if(s != nil) {
if(copysub(&p->to, v, s, 1))
return 1;
return 0;
}
if(copyau(&p->to, v))
return 4;
return 3;
case ATEXT:
if(REGARG >= 0 && v->type == (uchar)REGARG)
return 3;
return 0;
}
if(p->as == AVARDEF || p->as == AVARKILL)
return 0;
proginfo(&info, p);
if((info.reguse|info.regset) & RtoB(v->type))
return 2;
if(info.flags & LeftAddr)
if(copyas(&p->from, v))
return 2;
if((info.flags & (RightRead|RightWrite)) == (RightRead|RightWrite))
if(copyas(&p->to, v))
return 2;
if(info.flags & RightWrite) {
if(copyas(&p->to, v)) {
if(s != nil)
return copysub(&p->from, v, s, 1);
if(copyau(&p->from, v))
return 4;
return 3;
}
}
if(info.flags & (LeftAddr|LeftRead|LeftWrite|RightAddr|RightRead|RightWrite)) {
if(s != nil) {
if(copysub(&p->from, v, s, 1))
return 1;
return copysub(&p->to, v, s, 1);
}
if(copyau(&p->from, v))
return 1;
if(copyau(&p->to, v))
return 1;
}
return 0;
}
/*
* direct reference,
* could be set/use depending on
* semantics
*/
static int
copyas(Adr *a, Adr *v)
{
if(a->type != v->type)
return 0;
if(regtyp(v))
return 1;
if(v->type == D_AUTO || v->type == D_PARAM)
if(v->offset == a->offset)
return 1;
return 0;
}
int
sameaddr(Addr *a, Addr *v)
{
if(a->type != v->type)
return 0;
if(regtyp(v))
return 1;
if(v->type == D_AUTO || v->type == D_PARAM)
if(v->offset == a->offset)
return 1;
return 0;
}
/*
* either direct or indirect
*/
static int
copyau(Adr *a, Adr *v)
{
if(copyas(a, v)) {
if(debug['P'] && debug['v'])
print("\tcopyau: copyas returned 1\n");
return 1;
}
if(regtyp(v)) {
if(a->type-D_INDIR == v->type) {
if(debug['P'] && debug['v'])
print("\tcopyau: found indir use - return 1\n");
return 1;
}
if(a->index == v->type) {
if(debug['P'] && debug['v'])
print("\tcopyau: found index use - return 1\n");
return 1;
}
}
return 0;
}
/*
* substitute s for v in a
* return failure to substitute
*/
static int
copysub(Adr *a, Adr *v, Adr *s, int f)
{
int t;
if(copyas(a, v)) {
t = s->type;
if(t >= D_AX && t <= D_R15 || t >= D_X0 && t <= D_X0+15) {
if(f)
a->type = t;
}
return 0;
}
if(regtyp(v)) {
t = v->type;
if(a->type == t+D_INDIR) {
if((s->type == D_BP || s->type == D_R13) && a->index != D_NONE)
return 1; /* can't use BP-base with index */
if(f)
a->type = s->type+D_INDIR;
// return 0;
}
if(a->index == t) {
if(f)
a->index = s->type;
return 0;
}
return 0;
}
return 0;
}
static void
conprop(Flow *r0)
{
Flow *r;
Prog *p, *p0;
int t;
Adr *v0;
p0 = r0->prog;
v0 = &p0->to;
r = r0;
loop:
r = uniqs(r);
if(r == nil || r == r0)
return;
if(uniqp(r) == nil)
return;
p = r->prog;
t = copyu(p, v0, nil);
switch(t) {
case 0: // miss
case 1: // use
goto loop;
case 2: // rar
case 4: // use and set
break;
case 3: // set
if(p->as == p0->as)
if(p->from.type == p0->from.type)
if(p->from.node == p0->from.node)
if(p->from.offset == p0->from.offset)
if(p->from.scale == p0->from.scale)
if(p->from.type == D_FCONST && p->from.u.dval == p0->from.u.dval)
if(p->from.index == p0->from.index) {
excise(r);
goto loop;
}
break;
}
}
int
smallindir(Addr *a, Addr *reg)
{
return regtyp(reg) &&
a->type == D_INDIR + reg->type &&
a->index == D_NONE &&
0 <= a->offset && a->offset < 4096;
}
int
stackaddr(Addr *a)
{
return regtyp(a) && a->type == D_SP;
}