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[/] [eco32/] [trunk/] [lcc/] [src/] [simp.c] - Blame information for rev 73

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Line No.	Rev	Author	Line
1	4	hellwig	`#include "c.h"`
2			`#include <float.h>`
3
4			`static char rcsid[] = "$Id: simp.c,v 1.1 2002/08/28 23:12:45 drh Exp $";`
5
6			`#define foldcnst(TYPE,VAR,OP) \`
7			`if (l->op == CNST+TYPE && r->op == CNST+TYPE) \`
8			`return cnsttree(ty, l->u.v.VAR OP r->u.v.VAR)`
9			`#define commute(L,R) \`
10			`if (generic(R->op) == CNST && generic(L->op) != CNST) \`
11			`do { Tree t = L; L = R; R = t; } while(0)`
12			`#define xfoldcnst(TYPE,VAR,OP,FUNC)\`
13			`if (l->op == CNST+TYPE && r->op == CNST+TYPE\`
14			`&& FUNC(l->u.v.VAR,r->u.v.VAR,\`
15			`ty->u.sym->u.limits.min.VAR,\`
16			`ty->u.sym->u.limits.max.VAR, needconst)) \`
17			`return cnsttree(ty, l->u.v.VAR OP r->u.v.VAR)`
18			`#define xcvtcnst(FTYPE,SRC,DST,VAR,EXPR) \`
19			`if (l->op == CNST+FTYPE) do {\`
20			`if (!explicitCast\`
21			`&& ((SRC) < DST->u.sym->u.limits.min.VAR \|\| (SRC) > DST->u.sym->u.limits.max.VAR))\`
22			warning("overflow in converting constant expression from `%t' to `%t'\n", l->type, DST);\
23			`if (needconst\`
24			`\|\| !((SRC) < DST->u.sym->u.limits.min.VAR \|\| (SRC) > DST->u.sym->u.limits.max.VAR))\`
25			`return cnsttree(ty, (EXPR)); } while(0)`
26			`#define identity(X,Y,TYPE,VAR,VAL) \`
27			`if (X->op == CNST+TYPE && X->u.v.VAR == VAL) return Y`
28			`#define zerofield(OP,TYPE,VAR) \`
29			`if (l->op == FIELD \`
30			`&& r->op == CNST+TYPE && r->u.v.VAR == 0)\`
31			`return eqtree(OP, bittree(BAND, l->kids[0],\`
32			`cnsttree(unsignedtype, \`
33			`(unsigned long)fieldmask(l->u.field)<<fieldright(l->u.field))), r)`
34			`#define cfoldcnst(TYPE,VAR,OP) \`
35			`if (l->op == CNST+TYPE && r->op == CNST+TYPE) \`
36			`return cnsttree(inttype, (long)(l->u.v.VAR OP r->u.v.VAR))`
37			`#define foldaddp(L,R,RTYPE,VAR) \`
38			`if (L->op == CNST+P && R->op == CNST+RTYPE) { \`
39			`Tree e = tree(CNST+P, ty, NULL, NULL);\`
40			`e->u.v.p = (char *)L->u.v.p + R->u.v.VAR;\`
41			`return e; }`
42			`#define ufoldcnst(TYPE,EXP) if (l->op == CNST+TYPE) return EXP`
43			`#define sfoldcnst(OP) \`
44			`if (l->op == CNST+U && r->op == CNST+I \`
45			`&& r->u.v.i >= 0 && r->u.v.i < 8*l->type->size) \`
46			`return cnsttree(ty, (unsigned long)(l->u.v.u OP r->u.v.i))`
47			`#define geu(L,R,V) \`
48			`if (R->op == CNST+U && R->u.v.u == 0) do { \`
49			`warning("result of unsigned comparison is constant\n"); \`
50			`return tree(RIGHT, inttype, root(L), cnsttree(inttype, (long)(V))); } while(0)`
51			`#define idempotent(OP) if (l->op == OP) return l->kids[0]`
52
53			`int needconst;`
54			`int explicitCast;`
55			`static int addi(long x, long y, long min, long max, int needconst) {`
56			`int cond = x == 0 \|\| y == 0`
57			`\|\| x < 0 && y < 0 && x >= min - y`
58			`\|\| x < 0 && y > 0`
59			`\|\| x > 0 && y < 0`
60			`\|\| x > 0 && y > 0 && x <= max - y;`
61			`if (!cond && needconst) {`
62			`warning("overflow in constant expression\n");`
63			`cond = 1;`
64			`}`
65			`return cond;`
66
67
68			`}`
69
70			`static int addd(double x, double y, double min, double max, int needconst) {`
71			`int cond = x == 0 \|\| y == 0`
72			`\|\| x < 0 && y < 0 && x >= min - y`
73			`\|\| x < 0 && y > 0`
74			`\|\| x > 0 && y < 0`
75			`\|\| x > 0 && y > 0 && x <= max - y;`
76			`if (!cond && needconst) {`
77			`warning("overflow in constant expression\n");`
78			`cond = 1;`
79			`}`
80			`return cond;`
81
82
83			`}`
84
85			`static Tree addrtree(Tree e, long n, Type ty) {`
86			`Symbol p = e->u.sym, q;`
87
88			`if (p->scope == GLOBAL`
89			`\|\| p->sclass == STATIC \|\| p->sclass == EXTERN)`
90			`NEW0(q, PERM);`
91			`else`
92			`NEW0(q, FUNC);`
93			`q->name = stringd(genlabel(1));`
94			`q->sclass = p->sclass;`
95			`q->scope = p->scope;`
96			`assert(isptr(ty) \|\| isarray(ty));`
97			`q->type = isptr(ty) ? ty->type : ty;`
98			`q->temporary = p->temporary;`
99			`q->generated = p->generated;`
100			`q->addressed = p->addressed;`
101			`q->computed = 1;`
102			`q->defined = 1;`
103			`q->ref = 1;`
104			`assert(IR->address);`
105			`if (p->scope == GLOBAL`
106			`\|\| p->sclass == STATIC \|\| p->sclass == EXTERN) {`
107			`if (p->sclass == AUTO)`
108			`q->sclass = STATIC;`
109			`(*IR->address)(q, p, n);`
110			`} else {`
111			`Code cp;`
112			`addlocal(p);`
113			`cp = code(Address);`
114			`cp->u.addr.sym = q;`
115			`cp->u.addr.base = p;`
116			`cp->u.addr.offset = n;`
117			`}`
118			`e = tree(e->op, ty, NULL, NULL);`
119			`e->u.sym = q;`
120			`return e;`
121			`}`
122
123			`/* div[id] - return 1 if min <= x/y <= max, 0 otherwise */`
124			`static int divi(long x, long y, long min, long max, int needconst) {`
125			`int cond = y != 0 && !(x == min && y == -1);`
126			`if (!cond && needconst) {`
127			`warning("overflow in constant expression\n");`
128			`cond = 1;`
129			`}`
130			`return cond;`
131
132
133			`}`
134
135			`static int divd(double x, double y, double min, double max, int needconst) {`
136			`int cond;`
137
138			`if (x < 0) x = -x;`
139			`if (y < 0) y = -y;`
140			`cond = y != 0 && !(y < 1 && x > max*y);`
141			`if (!cond && needconst) {`
142			`warning("overflow in constant expression\n");`
143			`cond = 1;`
144			`}`
145			`return cond;`
146
147			`}`
148
149			`/* mul[id] - return 1 if min <= xy <= max, 0 otherwise /`
150			`static int muli(long x, long y, long min, long max, int needconst) {`
151			`int cond = x > -1 && x <= 1 \|\| y > -1 && y <= 1`
152			`\|\| x < 0 && y < 0 && -x <= max/-y`
153			`\|\| x < 0 && y > 0 && x >= min/y`
154			`\|\| x > 0 && y < 0 && y >= min/x`
155			`\|\| x > 0 && y > 0 && x <= max/y;`
156			`if (!cond && needconst) {`
157			`warning("overflow in constant expression\n");`
158			`cond = 1;`
159			`}`
160			`return cond;`
161
162
163			`}`
164
165			`static int muld(double x, double y, double min, double max, int needconst) {`
166			`int cond = x >= -1 && x <= 1 \|\| y >= -1 && y <= 1`
167			`\|\| x < 0 && y < 0 && -x <= max/-y`
168			`\|\| x < 0 && y > 0 && x >= min/y`
169			`\|\| x > 0 && y < 0 && y >= min/x`
170			`\|\| x > 0 && y > 0 && x <= max/y;`
171			`if (!cond && needconst) {`
172			`warning("overflow in constant expression\n");`
173			`cond = 1;`
174			`}`
175			`return cond;`
176
177
178			`}`
179			`/* sub[id] - return 1 if min <= x-y <= max, 0 otherwise */`
180			`static int subi(long x, long y, long min, long max, int needconst) {`
181			`return addi(x, -y, min, max, needconst);`
182			`}`
183
184			`static int subd(double x, double y, double min, double max, int needconst) {`
185			`return addd(x, -y, min, max, needconst);`
186			`}`
187			`Tree constexpr(int tok) {`
188			`Tree p;`
189
190			`needconst++;`
191			`p = expr1(tok);`
192			`needconst--;`
193			`return p;`
194			`}`
195
196			`int intexpr(int tok, int n) {`
197			`Tree p = constexpr(tok);`
198
199			`needconst++;`
200			`if (p->op == CNST+I \|\| p->op == CNST+U)`
201			`n = cast(p, inttype)->u.v.i;`
202			`else`
203			`error("integer expression must be constant\n");`
204			`needconst--;`
205			`return n;`
206			`}`
207			`Tree simplify(int op, Type ty, Tree l, Tree r) {`
208			`int n;`
209			`Tree p;`
210
211			`if (optype(op) == 0)`
212			`op = mkop(op, ty);`
213			`switch (op) {`
214			`case ADD+U:`
215			`foldcnst(U,u,+);`
216			`commute(r,l);`
217			`identity(r,l,U,u,0);`
218			`break;`
219			`case ADD+I:`
220			`xfoldcnst(I,i,+,addi);`
221			`commute(r,l);`
222			`identity(r,l,I,i,0);`
223			`break;`
224			`case CVI+I:`
225			`xcvtcnst(I,l->u.v.i,ty,i,(long)extend(l->u.v.i,ty));`
226			`break;`
227			`case CVU+I:`
228			`if (l->op == CNST+U) {`
229			`if (!explicitCast && l->u.v.u > ty->u.sym->u.limits.max.i)`
230			warning("overflow in converting constant expression from `%t' to `%t'\n", l->type, ty);
231			`if (needconst \|\| !(l->u.v.u > ty->u.sym->u.limits.max.i))`
232			`return cnsttree(ty, (long)extend(l->u.v.u,ty));`
233			`}`
234			`break;`
235			`case CVP+U:`
236			`xcvtcnst(P,(unsigned long)l->u.v.p,ty,u,(unsigned long)l->u.v.p);`
237			`break;`
238			`case CVU+P:`
239			`xcvtcnst(U,(void)l->u.v.u,ty,p,(void)l->u.v.u);`
240			`break;`
241			`case CVP+P:`
242			`xcvtcnst(P,l->u.v.p,ty,p,l->u.v.p);`
243			`break;`
244			`case CVI+U:`
245			`xcvtcnst(I,l->u.v.i,ty,u,((unsigned long)l->u.v.i)&ones(8*ty->size));`
246			`break;`
247			`case CVU+U:`
248			`xcvtcnst(U,l->u.v.u,ty,u,l->u.v.u&ones(8*ty->size));`
249			`break;`
250
251			`case CVI+F:`
252			`xcvtcnst(I,l->u.v.i,ty,d,(long double)l->u.v.i);`
253			`case CVU+F:`
254			`xcvtcnst(U,l->u.v.u,ty,d,(long double)l->u.v.u);`
255			`break;`
256			`case CVF+I:`
257			`xcvtcnst(F,l->u.v.d,ty,i,(long)l->u.v.d);`
258			`break;`
259			`case CVF+F: {`
260			`float d;`
261			`if (l->op == CNST+F)`
262			`if (l->u.v.d < ty->u.sym->u.limits.min.d)`
263			`d = ty->u.sym->u.limits.min.d;`
264			`else if (l->u.v.d > ty->u.sym->u.limits.max.d)`
265			`d = ty->u.sym->u.limits.max.d;`
266			`else`
267			`d = l->u.v.d;`
268			`xcvtcnst(F,l->u.v.d,ty,d,(long double)d);`
269			`break;`
270			`}`
271			`case BAND+U:`
272			`foldcnst(U,u,&);`
273			`commute(r,l);`
274			`identity(r,l,U,u,ones(8*ty->size));`
275			`if (r->op == CNST+U && r->u.v.u == 0)`
276			`return tree(RIGHT, ty, root(l), cnsttree(ty, 0UL));`
277			`break;`
278			`case BAND+I:`
279			`foldcnst(I,i,&);`
280			`commute(r,l);`
281			`identity(r,l,I,i,ones(8*ty->size));`
282			`if (r->op == CNST+I && r->u.v.u == 0)`
283			`return tree(RIGHT, ty, root(l), cnsttree(ty, 0L));`
284			`break;`
285
286			`case MUL+U:`
287			`commute(l,r);`
288			`if (l->op == CNST+U && (n = ispow2(l->u.v.u)) != 0)`
289			`return simplify(LSH, ty, r, cnsttree(inttype, (long)n));`
290			`foldcnst(U,u,*);`
291			`identity(r,l,U,u,1);`
292			`break;`
293			`case NE+I:`
294			`cfoldcnst(I,i,!=);`
295			`commute(r,l);`
296			`zerofield(NE,I,i);`
297			`break;`
298
299			`case EQ+I:`
300			`cfoldcnst(I,i,==);`
301			`commute(r,l);`
302			`zerofield(EQ,I,i);`
303			`break;`
304			`case ADD+P:`
305			`foldaddp(l,r,I,i);`
306			`foldaddp(l,r,U,u);`
307			`foldaddp(r,l,I,i);`
308			`foldaddp(r,l,U,u);`
309			`commute(r,l);`
310			`identity(r,retype(l,ty),I,i,0);`
311			`identity(r,retype(l,ty),U,u,0);`
312			`/*`
313			`Some assemblers, e.g., the MIPS, can't handle offsets`
314			`larger than 16 bits. A better solution would be to change`
315			`the interface so that address() could fail.`
316			`*/`
317			`if (l->op == ADDRG+P && l->u.sym->generated`
318			`&& (r->op == CNST+I && (r->u.v.i > 32767 \|\| r->u.v.i < -32768)`
319			`\|\| r->op == CNST+U && r->u.v.u > 65536))`
320			`break;`
321			`if (IR->address`
322			`&& isaddrop(l->op)`
323			`&& (r->op == CNST+I && r->u.v.i <= longtype->u.sym->u.limits.max.i`
324			`&& r->u.v.i >= longtype->u.sym->u.limits.min.i`
325			`\|\| r->op == CNST+U && r->u.v.u <= longtype->u.sym->u.limits.max.i))`
326			`return addrtree(l, cast(r, longtype)->u.v.i, ty);`
327			`if (IR->address`
328			`&& l->op == ADD+P && isaddrop(l->kids[1]->op)`
329			`&& (r->op == CNST+I && r->u.v.i <= longtype->u.sym->u.limits.max.i`
330			`&& r->u.v.i >= longtype->u.sym->u.limits.min.i`
331			`\|\| r->op == CNST+U && r->u.v.u <= longtype->u.sym->u.limits.max.i))`
332			`return simplify(ADD+P, ty, l->kids[0],`
333			`addrtree(l->kids[1], cast(r, longtype)->u.v.i, ty));`
334			`if ((l->op == ADD+I \|\| l->op == SUB+I)`
335			`&& l->kids[1]->op == CNST+I && isaddrop(r->op))`
336			`return simplify(ADD+P, ty, l->kids[0],`
337			`simplify(generic(l->op)+P, ty, r, l->kids[1]));`
338			`if (l->op == ADD+P && generic(l->kids[1]->op) == CNST`
339			`&& generic(r->op) == CNST)`
340			`return simplify(ADD+P, ty, l->kids[0],`
341			`simplify(ADD, l->kids[1]->type, l->kids[1], r));`
342			`if (l->op == ADD+I && generic(l->kids[1]->op) == CNST`
343			`&& r->op == ADD+P && generic(r->kids[1]->op) == CNST)`
344			`return simplify(ADD+P, ty, l->kids[0],`
345			`simplify(ADD+P, ty, r->kids[0],`
346			`simplify(ADD, r->kids[1]->type, l->kids[1], r->kids[1])));`
347			`if (l->op == RIGHT && l->kids[1])`
348			`return tree(RIGHT, ty, l->kids[0],`
349			`simplify(ADD+P, ty, l->kids[1], r));`
350			`else if (l->op == RIGHT && l->kids[0])`
351			`return tree(RIGHT, ty,`
352			`simplify(ADD+P, ty, l->kids[0], r), NULL);`
353			`break;`
354
355			`case ADD+F:`
356			`xfoldcnst(F,d,+,addd);`
357			`commute(r,l);`
358			`break;`
359			`case AND+I:`
360			`op = AND;`
361			`ufoldcnst(I,l->u.v.i ? cond(r) : l); /* 0&&r => 0, 1&&r => r */`
362			`break;`
363			`case OR+I:`
364			`op = OR;`
365			`/* 0\|\|r => r, 1\|\|r => 1 */`
366			`ufoldcnst(I,l->u.v.i ? cnsttree(ty, 1L) : cond(r));`
367			`break;`
368			`case BCOM+I:`
369			`ufoldcnst(I,cnsttree(ty, (long)extend((~l->u.v.i)&ones(8*ty->size), ty)));`
370			`idempotent(BCOM+U);`
371			`break;`
372			`case BCOM+U:`
373			`ufoldcnst(U,cnsttree(ty, (unsigned long)((~l->u.v.u)&ones(8*ty->size))));`
374			`idempotent(BCOM+U);`
375			`break;`
376			`case BOR+U:`
377			`foldcnst(U,u,\|);`
378			`commute(r,l);`
379			`identity(r,l,U,u,0);`
380			`break;`
381			`case BOR+I:`
382			`foldcnst(I,i,\|);`
383			`commute(r,l);`
384			`identity(r,l,I,i,0);`
385			`break;`
386			`case BXOR+U:`
387			`foldcnst(U,u,^);`
388			`commute(r,l);`
389			`identity(r,l,U,u,0);`
390			`break;`
391			`case BXOR+I:`
392			`foldcnst(I,i,^);`
393			`commute(r,l);`
394			`identity(r,l,I,i,0);`
395			`break;`
396			`case DIV+F:`
397			`xfoldcnst(F,d,/,divd);`
398			`break;`
399			`case DIV+I:`
400			`identity(r,l,I,i,1);`
401			`if (r->op == CNST+I && r->u.v.i == 0`
402			`\|\| l->op == CNST+I && l->u.v.i == ty->u.sym->u.limits.min.i`
403			`&& r->op == CNST+I && r->u.v.i == -1)`
404			`break;`
405			`xfoldcnst(I,i,/,divi);`
406			`break;`
407			`case DIV+U:`
408			`identity(r,l,U,u,1);`
409			`if (r->op == CNST+U && r->u.v.u == 0)`
410			`break;`
411			`if (r->op == CNST+U && (n = ispow2(r->u.v.u)) != 0)`
412			`return simplify(RSH, ty, l, cnsttree(inttype, (long)n));`
413			`foldcnst(U,u,/);`
414			`break;`
415			`case EQ+F:`
416			`cfoldcnst(F,d,==);`
417			`commute(r,l);`
418			`break;`
419			`case EQ+U:`
420			`cfoldcnst(U,u,==);`
421			`commute(r,l);`
422			`zerofield(EQ,U,u);`
423			`break;`
424			`case GE+F: cfoldcnst(F,d,>=); break;`
425			`case GE+I: cfoldcnst(I,i,>=); break;`
426			`case GE+U:`
427			`geu(l,r,1); /* l >= 0 => (l,1) */`
428			`cfoldcnst(U,u,>=);`
429			`if (l->op == CNST+U && l->u.v.u == 0) /* 0 >= r => r == 0 */`
430			`return eqtree(EQ, r, l);`
431			`break;`
432			`case GT+F: cfoldcnst(F,d, >); break;`
433			`case GT+I: cfoldcnst(I,i, >); break;`
434			`case GT+U:`
435			`geu(r,l,0); /* 0 > r => (r,0) */`
436			`cfoldcnst(U,u, >);`
437			`if (r->op == CNST+U && r->u.v.u == 0) /* l > 0 => l != 0 */`
438			`return eqtree(NE, l, r);`
439			`break;`
440			`case LE+F: cfoldcnst(F,d,<=); break;`
441			`case LE+I: cfoldcnst(I,i,<=); break;`
442			`case LE+U:`
443			`geu(r,l,1); /* 0 <= r => (r,1) */`
444			`cfoldcnst(U,u,<=);`
445			`if (r->op == CNST+U && r->u.v.u == 0) /* l <= 0 => l == 0 */`
446			`return eqtree(EQ, l, r);`
447			`break;`
448			`case LSH+I:`
449			`identity(r,l,I,i,0);`
450			`if (l->op == CNST+I && r->op == CNST+I`
451			`&& r->u.v.i >= 0 && r->u.v.i < 8*l->type->size`
452			`&& muli(l->u.v.i, 1<<r->u.v.i, ty->u.sym->u.limits.min.i, ty->u.sym->u.limits.max.i, needconst))`
453			`return cnsttree(ty, (long)(l->u.v.i<<r->u.v.i));`
454			`if (r->op == CNST+I && (r->u.v.i >= 8*ty->size \|\| r->u.v.i < 0)) {`
455			warning("shifting an `%t' by %d bits is undefined\n", ty, r->u.v.i);
456			`break;`
457			`}`
458
459			`break;`
460			`case LSH+U:`
461			`identity(r,l,I,i,0);`
462			`sfoldcnst(<<);`
463			`if (r->op == CNST+I && (r->u.v.i >= 8*ty->size \|\| r->u.v.i < 0)) {`
464			warning("shifting an `%t' by %d bits is undefined\n", ty, r->u.v.i);
465			`break;`
466			`}`
467
468			`break;`
469
470			`case LT+F: cfoldcnst(F,d, <); break;`
471			`case LT+I: cfoldcnst(I,i, <); break;`
472			`case LT+U:`
473			`geu(l,r,0); /* l < 0 => (l,0) */`
474			`cfoldcnst(U,u, <);`
475			`if (l->op == CNST+U && l->u.v.u == 0) /* 0 < r => r != 0 */`
476			`return eqtree(NE, r, l);`
477			`break;`
478			`case MOD+I:`
479			`if (r->op == CNST+I && r->u.v.i == 0`
480			`\|\| l->op == CNST+I && l->u.v.i == ty->u.sym->u.limits.min.i`
481			`&& r->op == CNST+I && r->u.v.i == -1)`
482			`break;`
483			`xfoldcnst(I,i,%,divi);`
484			`if (r->op == CNST+I && r->u.v.i == 1) /* l%1 => (l,0) */`
485			`return tree(RIGHT, ty, root(l), cnsttree(ty, 0L));`
486			`break;`
487			`case MOD+U:`
488			`if (r->op == CNST+U && ispow2(r->u.v.u)) /* l%2^n => l&(2^n-1) */`
489			`return bittree(BAND, l, cnsttree(ty, r->u.v.u - 1));`
490			`if (r->op == CNST+U && r->u.v.u == 0)`
491			`break;`
492			`foldcnst(U,u,%);`
493			`break;`
494			`case MUL+F:`
495			`xfoldcnst(F,d,*,muld);`
496			`commute(l,r);`
497			`break;`
498			`case MUL+I:`
499			`commute(l,r);`
500			`xfoldcnst(I,i,*,muli);`
501			`if (l->op == CNST+I && r->op == ADD+I && r->kids[1]->op == CNST+I)`
502			`/* c1(x + c2) => c1x + c1c2 /`
503			`return simplify(ADD, ty, simplify(MUL, ty, l, r->kids[0]),`
504			`simplify(MUL, ty, l, r->kids[1]));`
505			`if (l->op == CNST+I && r->op == SUB+I && r->kids[1]->op == CNST+I)`
506			`/* c1(x - c2) => c1x - c1c2 /`
507			`return simplify(SUB, ty, simplify(MUL, ty, l, r->kids[0]),`
508			`simplify(MUL, ty, l, r->kids[1]));`
509			`if (l->op == CNST+I && l->u.v.i > 0 && (n = ispow2(l->u.v.i)) != 0)`
510			`/* 2^n * r => r<<n */`
511			`return simplify(LSH, ty, r, cnsttree(inttype, (long)n));`
512			`identity(r,l,I,i,1);`
513			`break;`
514			`case NE+F:`
515			`cfoldcnst(F,d,!=);`
516			`commute(r,l);`
517			`break;`
518			`case NE+U:`
519			`cfoldcnst(U,u,!=);`
520			`commute(r,l);`
521			`zerofield(NE,U,u);`
522			`break;`
523			`case NEG+F:`
524			`ufoldcnst(F,cnsttree(ty, -l->u.v.d));`
525			`idempotent(NEG+F);`
526			`break;`
527			`case NEG+I:`
528			`if (l->op == CNST+I) {`
529			`if (needconst && l->u.v.i == ty->u.sym->u.limits.min.i)`
530			`warning("overflow in constant expression\n");`
531			`if (needconst \|\| l->u.v.i != ty->u.sym->u.limits.min.i)`
532			`return cnsttree(ty, -l->u.v.i);`
533			`}`
534			`idempotent(NEG+I);`
535			`break;`
536			`case NOT+I:`
537			`op = NOT;`
538			`ufoldcnst(I,cnsttree(ty, !l->u.v.i));`
539			`break;`
540			`case RSH+I:`
541			`identity(r,l,I,i,0);`
542			`if (l->op == CNST+I && r->op == CNST+I`
543			`&& r->u.v.i >= 0 && r->u.v.i < 8*l->type->size) {`
544			`long n = l->u.v.i>>r->u.v.i;`
545			`if (l->u.v.i < 0)`
546			`n \|= ~0UL<<(8*l->type->size - r->u.v.i);`
547			`return cnsttree(ty, n);`
548			`}`
549			`if (r->op == CNST+I && (r->u.v.i >= 8*ty->size \|\| r->u.v.i < 0)) {`
550			warning("shifting an `%t' by %d bits is undefined\n", ty, r->u.v.i);
551			`break;`
552			`}`
553
554			`break;`
555			`case RSH+U:`
556			`identity(r,l,I,i,0);`
557			`sfoldcnst(>>);`
558			`if (r->op == CNST+I && (r->u.v.i >= 8*ty->size \|\| r->u.v.i < 0)) {`
559			warning("shifting an `%t' by %d bits is undefined\n", ty, r->u.v.i);
560			`break;`
561			`}`
562
563			`break;`
564			`case SUB+F:`
565			`xfoldcnst(F,d,-,subd);`
566			`break;`
567			`case SUB+I:`
568			`xfoldcnst(I,i,-,subi);`
569			`identity(r,l,I,i,0);`
570			`break;`
571			`case SUB+U:`
572			`foldcnst(U,u,-);`
573			`identity(r,l,U,u,0);`
574			`break;`
575			`case SUB+P:`
576			`if (l->op == CNST+P && r->op == CNST+P)`
577			`return cnsttree(ty, (long)((char )l->u.v.p - (char )r->u.v.p));`
578			`if (r->op == CNST+I \|\| r->op == CNST+U)`
579			`return simplify(ADD, ty, l,`
580			`cnsttree(inttype, r->op == CNST+I ? -r->u.v.i : -(long)r->u.v.u));`
581			`if (isaddrop(l->op) && r->op == ADD+I && r->kids[1]->op == CNST+I)`
582			`/* l - (x + c) => l-c - x */`
583			`return simplify(SUB, ty,`
584			`simplify(SUB, ty, l, r->kids[1]), r->kids[0]);`
585			`break;`
586			`default:assert(0);`
587			`}`
588			`return tree(op, ty, l, r);`
589			`}`
590			`/* ispow2 - if u > 1 && u == 2^n, return n, otherwise return 0 */`
591			`int ispow2(unsigned long u) {`
592			`int n;`
593
594			`if (u > 1 && (u&(u-1)) == 0)`
595			`for (n = 0; u; u >>= 1, n++)`
596			`if (u&1)`
597			`return n;`
598			`return 0;`
599			`}`
600

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