initsem.d revision 1.1 1 1.1 mrg /**
2 1.1 mrg * Semantic analysis of initializers.
3 1.1 mrg *
4 1.1 mrg * Copyright: Copyright (C) 1999-2022 by The D Language Foundation, All Rights Reserved
5 1.1 mrg * Authors: $(LINK2 https://www.digitalmars.com, Walter Bright)
6 1.1 mrg * License: $(LINK2 https://www.boost.org/LICENSE_1_0.txt, Boost License 1.0)
7 1.1 mrg * Source: $(LINK2 https://github.com/dlang/dmd/blob/master/src/dmd/initsem.d, _initsem.d)
8 1.1 mrg * Documentation: https://dlang.org/phobos/dmd_initsem.html
9 1.1 mrg * Coverage: https://codecov.io/gh/dlang/dmd/src/master/src/dmd/initsem.d
10 1.1 mrg */
11 1.1 mrg
12 1.1 mrg module dmd.initsem;
13 1.1 mrg
14 1.1 mrg import core.stdc.stdio;
15 1.1 mrg import core.checkedint;
16 1.1 mrg
17 1.1 mrg import dmd.aggregate;
18 1.1 mrg import dmd.aliasthis;
19 1.1 mrg import dmd.arraytypes;
20 1.1 mrg import dmd.astenums;
21 1.1 mrg import dmd.dcast;
22 1.1 mrg import dmd.declaration;
23 1.1 mrg import dmd.dscope;
24 1.1 mrg import dmd.dstruct;
25 1.1 mrg import dmd.dsymbol;
26 1.1 mrg import dmd.dtemplate;
27 1.1 mrg import dmd.errors;
28 1.1 mrg import dmd.expression;
29 1.1 mrg import dmd.expressionsem;
30 1.1 mrg import dmd.func;
31 1.1 mrg import dmd.globals;
32 1.1 mrg import dmd.id;
33 1.1 mrg import dmd.identifier;
34 1.1 mrg import dmd.importc;
35 1.1 mrg import dmd.init;
36 1.1 mrg import dmd.mtype;
37 1.1 mrg import dmd.opover;
38 1.1 mrg import dmd.statement;
39 1.1 mrg import dmd.target;
40 1.1 mrg import dmd.tokens;
41 1.1 mrg import dmd.typesem;
42 1.1 mrg
43 1.1 mrg /********************************
44 1.1 mrg * If possible, convert array initializer to associative array initializer.
45 1.1 mrg *
46 1.1 mrg * Params:
47 1.1 mrg * ai = array initializer to be converted
48 1.1 mrg *
49 1.1 mrg * Returns:
50 1.1 mrg * The converted associative array initializer or ErrorExp if `ai`
51 1.1 mrg * is not an associative array initializer.
52 1.1 mrg */
53 1.1 mrg Expression toAssocArrayLiteral(ArrayInitializer ai)
54 1.1 mrg {
55 1.1 mrg Expression e;
56 1.1 mrg //printf("ArrayInitializer::toAssocArrayInitializer()\n");
57 1.1 mrg //static int i; if (++i == 2) assert(0);
58 1.1 mrg const dim = ai.value.dim;
59 1.1 mrg auto keys = new Expressions(dim);
60 1.1 mrg auto values = new Expressions(dim);
61 1.1 mrg for (size_t i = 0; i < dim; i++)
62 1.1 mrg {
63 1.1 mrg e = ai.index[i];
64 1.1 mrg if (!e)
65 1.1 mrg goto Lno;
66 1.1 mrg (*keys)[i] = e;
67 1.1 mrg Initializer iz = ai.value[i];
68 1.1 mrg if (!iz)
69 1.1 mrg goto Lno;
70 1.1 mrg e = iz.initializerToExpression();
71 1.1 mrg if (!e)
72 1.1 mrg goto Lno;
73 1.1 mrg (*values)[i] = e;
74 1.1 mrg }
75 1.1 mrg e = new AssocArrayLiteralExp(ai.loc, keys, values);
76 1.1 mrg return e;
77 1.1 mrg Lno:
78 1.1 mrg error(ai.loc, "not an associative array initializer");
79 1.1 mrg return ErrorExp.get();
80 1.1 mrg }
81 1.1 mrg
82 1.1 mrg /******************************************
83 1.1 mrg * Perform semantic analysis on init.
84 1.1 mrg * Params:
85 1.1 mrg * init = Initializer AST node
86 1.1 mrg * sc = context
87 1.1 mrg * tx = type that the initializer needs to become. If tx is an incomplete
88 1.1 mrg * type and the initializer completes it, it is updated to be the
89 1.1 mrg * complete type. ImportC has incomplete types
90 1.1 mrg * needInterpret = if CTFE needs to be run on this,
91 1.1 mrg * such as if it is the initializer for a const declaration
92 1.1 mrg * Returns:
93 1.1 mrg * `Initializer` with completed semantic analysis, `ErrorInitializer` if errors
94 1.1 mrg * were encountered
95 1.1 mrg */
96 1.1 mrg extern(C++) Initializer initializerSemantic(Initializer init, Scope* sc, ref Type tx, NeedInterpret needInterpret)
97 1.1 mrg {
98 1.1 mrg Type t = tx;
99 1.1 mrg
100 1.1 mrg static Initializer err()
101 1.1 mrg {
102 1.1 mrg return new ErrorInitializer();
103 1.1 mrg }
104 1.1 mrg
105 1.1 mrg Initializer visitVoid(VoidInitializer i)
106 1.1 mrg {
107 1.1 mrg i.type = t;
108 1.1 mrg return i;
109 1.1 mrg }
110 1.1 mrg
111 1.1 mrg Initializer visitError(ErrorInitializer i)
112 1.1 mrg {
113 1.1 mrg return i;
114 1.1 mrg }
115 1.1 mrg
116 1.1 mrg Initializer visitStruct(StructInitializer i)
117 1.1 mrg {
118 1.1 mrg //printf("StructInitializer::semantic(t = %s) %s\n", t.toChars(), i.toChars());
119 1.1 mrg /* This works by replacing the StructInitializer with an ExpInitializer.
120 1.1 mrg */
121 1.1 mrg t = t.toBasetype();
122 1.1 mrg if (t.ty == Tsarray && t.nextOf().toBasetype().ty == Tstruct)
123 1.1 mrg t = t.nextOf().toBasetype();
124 1.1 mrg if (auto ts = t.isTypeStruct())
125 1.1 mrg {
126 1.1 mrg StructDeclaration sd = ts.sym;
127 1.1 mrg // check if the sd has a regular ctor (user defined non-copy ctor)
128 1.1 mrg // that is not disabled.
129 1.1 mrg if (sd.hasRegularCtor(true))
130 1.1 mrg {
131 1.1 mrg error(i.loc, "%s `%s` has constructors, cannot use `{ initializers }`, use `%s( initializers )` instead", sd.kind(), sd.toChars(), sd.toChars());
132 1.1 mrg return err();
133 1.1 mrg }
134 1.1 mrg sd.size(i.loc);
135 1.1 mrg if (sd.sizeok != Sizeok.done)
136 1.1 mrg return err();
137 1.1 mrg const nfields = sd.nonHiddenFields();
138 1.1 mrg //expandTuples for non-identity arguments?
139 1.1 mrg auto elements = new Expressions(nfields);
140 1.1 mrg auto elems = (*elements)[];
141 1.1 mrg foreach (ref elem; elems)
142 1.1 mrg elem = null;
143 1.1 mrg
144 1.1 mrg // Run semantic for explicitly given initializers
145 1.1 mrg // TODO: this part is slightly different from StructLiteralExp::semantic.
146 1.1 mrg bool errors = false;
147 1.1 mrg size_t fieldi = 0;
148 1.1 mrg foreach (j, id; i.field[])
149 1.1 mrg {
150 1.1 mrg if (id)
151 1.1 mrg {
152 1.1 mrg /* Determine `fieldi` that `id` matches
153 1.1 mrg */
154 1.1 mrg Dsymbol s = sd.search(i.loc, id);
155 1.1 mrg if (!s)
156 1.1 mrg {
157 1.1 mrg s = sd.search_correct(id);
158 1.1 mrg const initLoc = i.value[j].loc;
159 1.1 mrg if (s)
160 1.1 mrg error(initLoc, "`%s` is not a member of `%s`, did you mean %s `%s`?", id.toChars(), sd.toChars(), s.kind(), s.toChars());
161 1.1 mrg else
162 1.1 mrg error(initLoc, "`%s` is not a member of `%s`", id.toChars(), sd.toChars());
163 1.1 mrg return err();
164 1.1 mrg }
165 1.1 mrg s.checkDeprecated(i.loc, sc);
166 1.1 mrg s = s.toAlias();
167 1.1 mrg
168 1.1 mrg // Find out which field index `s` is
169 1.1 mrg for (fieldi = 0; 1; fieldi++)
170 1.1 mrg {
171 1.1 mrg if (fieldi >= nfields)
172 1.1 mrg {
173 1.1 mrg error(i.loc, "`%s.%s` is not a per-instance initializable field", sd.toChars(), s.toChars());
174 1.1 mrg return err();
175 1.1 mrg }
176 1.1 mrg if (s == sd.fields[fieldi])
177 1.1 mrg break;
178 1.1 mrg }
179 1.1 mrg }
180 1.1 mrg if (j >= nfields)
181 1.1 mrg {
182 1.1 mrg error(i.value[j].loc, "too many initializers for `%s`", sd.toChars());
183 1.1 mrg return err();
184 1.1 mrg }
185 1.1 mrg
186 1.1 mrg VarDeclaration vd = sd.fields[fieldi];
187 1.1 mrg if (elems[fieldi])
188 1.1 mrg {
189 1.1 mrg error(i.value[j].loc, "duplicate initializer for field `%s`", vd.toChars());
190 1.1 mrg errors = true;
191 1.1 mrg elems[fieldi] = ErrorExp.get(); // for better diagnostics on multiple errors
192 1.1 mrg ++fieldi;
193 1.1 mrg continue;
194 1.1 mrg }
195 1.1 mrg
196 1.1 mrg // Check for @safe violations
197 1.1 mrg if (vd.type.hasPointers)
198 1.1 mrg {
199 1.1 mrg if ((!t.alignment.isDefault() && t.alignment.get() < target.ptrsize ||
200 1.1 mrg (vd.offset & (target.ptrsize - 1))) &&
201 1.1 mrg sc.func && sc.func.setUnsafe())
202 1.1 mrg {
203 1.1 mrg error(i.value[j].loc, "field `%s.%s` cannot assign to misaligned pointers in `@safe` code",
204 1.1 mrg sd.toChars(), vd.toChars());
205 1.1 mrg errors = true;
206 1.1 mrg elems[fieldi] = ErrorExp.get(); // for better diagnostics on multiple errors
207 1.1 mrg ++fieldi;
208 1.1 mrg continue;
209 1.1 mrg }
210 1.1 mrg }
211 1.1 mrg
212 1.1 mrg // Check for overlapping initializations (can happen with unions)
213 1.1 mrg foreach (k, v2; sd.fields[0 .. nfields])
214 1.1 mrg {
215 1.1 mrg if (vd.isOverlappedWith(v2) && elems[k])
216 1.1 mrg {
217 1.1 mrg error(elems[k].loc, "overlapping initialization for field `%s` and `%s`", v2.toChars(), vd.toChars());
218 1.1 mrg errors = true;
219 1.1 mrg continue;
220 1.1 mrg }
221 1.1 mrg }
222 1.1 mrg
223 1.1 mrg // Convert initializer to Expression `ex`
224 1.1 mrg assert(sc);
225 1.1 mrg auto tm = vd.type.addMod(t.mod);
226 1.1 mrg auto iz = i.value[j].initializerSemantic(sc, tm, needInterpret);
227 1.1 mrg auto ex = iz.initializerToExpression();
228 1.1 mrg if (ex.op == EXP.error)
229 1.1 mrg {
230 1.1 mrg errors = true;
231 1.1 mrg elems[fieldi] = ErrorExp.get(); // for better diagnostics on multiple errors
232 1.1 mrg ++fieldi;
233 1.1 mrg continue;
234 1.1 mrg }
235 1.1 mrg
236 1.1 mrg i.value[j] = iz;
237 1.1 mrg elems[fieldi] = doCopyOrMove(sc, ex);
238 1.1 mrg ++fieldi;
239 1.1 mrg }
240 1.1 mrg if (errors)
241 1.1 mrg return err();
242 1.1 mrg
243 1.1 mrg // Make a StructLiteralExp out of elements[]
244 1.1 mrg auto sle = new StructLiteralExp(i.loc, sd, elements, t);
245 1.1 mrg if (!sd.fill(i.loc, elements, false))
246 1.1 mrg return err();
247 1.1 mrg sle.type = t;
248 1.1 mrg auto ie = new ExpInitializer(i.loc, sle);
249 1.1 mrg return ie.initializerSemantic(sc, t, needInterpret);
250 1.1 mrg }
251 1.1 mrg else if ((t.ty == Tdelegate || t.isPtrToFunction()) && i.value.dim == 0)
252 1.1 mrg {
253 1.1 mrg const tok = (t.ty == Tdelegate) ? TOK.delegate_ : TOK.function_;
254 1.1 mrg /* Rewrite as empty delegate literal { }
255 1.1 mrg */
256 1.1 mrg Type tf = new TypeFunction(ParameterList(), null, LINK.d);
257 1.1 mrg auto fd = new FuncLiteralDeclaration(i.loc, Loc.initial, tf, tok, null);
258 1.1 mrg fd.fbody = new CompoundStatement(i.loc, new Statements());
259 1.1 mrg fd.endloc = i.loc;
260 1.1 mrg Expression e = new FuncExp(i.loc, fd);
261 1.1 mrg auto ie = new ExpInitializer(i.loc, e);
262 1.1 mrg return ie.initializerSemantic(sc, t, needInterpret);
263 1.1 mrg }
264 1.1 mrg if (t.ty != Terror)
265 1.1 mrg error(i.loc, "a struct is not a valid initializer for a `%s`", t.toChars());
266 1.1 mrg return err();
267 1.1 mrg }
268 1.1 mrg
269 1.1 mrg Initializer visitArray(ArrayInitializer i)
270 1.1 mrg {
271 1.1 mrg uint length;
272 1.1 mrg const(uint) amax = 0x80000000;
273 1.1 mrg bool errors = false;
274 1.1 mrg //printf("ArrayInitializer::semantic(%s)\n", t.toChars());
275 1.1 mrg if (i.sem) // if semantic() already run
276 1.1 mrg {
277 1.1 mrg return i;
278 1.1 mrg }
279 1.1 mrg i.sem = true;
280 1.1 mrg t = t.toBasetype();
281 1.1 mrg switch (t.ty)
282 1.1 mrg {
283 1.1 mrg case Tsarray:
284 1.1 mrg case Tarray:
285 1.1 mrg break;
286 1.1 mrg case Tvector:
287 1.1 mrg t = t.isTypeVector().basetype;
288 1.1 mrg break;
289 1.1 mrg case Taarray:
290 1.1 mrg case Tstruct: // consider implicit constructor call
291 1.1 mrg {
292 1.1 mrg Expression e;
293 1.1 mrg // note: MyStruct foo = [1:2, 3:4] is correct code if MyStruct has a this(int[int])
294 1.1 mrg if (t.ty == Taarray || i.isAssociativeArray())
295 1.1 mrg e = i.toAssocArrayLiteral();
296 1.1 mrg else
297 1.1 mrg e = i.initializerToExpression();
298 1.1 mrg // Bugzilla 13987
299 1.1 mrg if (!e)
300 1.1 mrg {
301 1.1 mrg error(i.loc, "cannot use array to initialize `%s`", t.toChars());
302 1.1 mrg return err();
303 1.1 mrg }
304 1.1 mrg auto ei = new ExpInitializer(e.loc, e);
305 1.1 mrg return ei.initializerSemantic(sc, t, needInterpret);
306 1.1 mrg }
307 1.1 mrg case Tpointer:
308 1.1 mrg if (t.nextOf().ty != Tfunction)
309 1.1 mrg break;
310 1.1 mrg goto default;
311 1.1 mrg default:
312 1.1 mrg error(i.loc, "cannot use array to initialize `%s`", t.toChars());
313 1.1 mrg return err();
314 1.1 mrg }
315 1.1 mrg i.type = t;
316 1.1 mrg length = 0;
317 1.1 mrg for (size_t j = 0; j < i.index.dim; j++)
318 1.1 mrg {
319 1.1 mrg Expression idx = i.index[j];
320 1.1 mrg if (idx)
321 1.1 mrg {
322 1.1 mrg sc = sc.startCTFE();
323 1.1 mrg idx = idx.expressionSemantic(sc);
324 1.1 mrg sc = sc.endCTFE();
325 1.1 mrg idx = idx.ctfeInterpret();
326 1.1 mrg i.index[j] = idx;
327 1.1 mrg const uinteger_t idxvalue = idx.toInteger();
328 1.1 mrg if (idxvalue >= amax)
329 1.1 mrg {
330 1.1 mrg error(i.loc, "array index %llu overflow", idxvalue);
331 1.1 mrg errors = true;
332 1.1 mrg }
333 1.1 mrg length = cast(uint)idxvalue;
334 1.1 mrg if (idx.op == EXP.error)
335 1.1 mrg errors = true;
336 1.1 mrg }
337 1.1 mrg Initializer val = i.value[j];
338 1.1 mrg ExpInitializer ei = val.isExpInitializer();
339 1.1 mrg if (ei && !idx)
340 1.1 mrg ei.expandTuples = true;
341 1.1 mrg auto tn = t.nextOf();
342 1.1 mrg val = val.initializerSemantic(sc, tn, needInterpret);
343 1.1 mrg if (val.isErrorInitializer())
344 1.1 mrg errors = true;
345 1.1 mrg ei = val.isExpInitializer();
346 1.1 mrg // found a tuple, expand it
347 1.1 mrg if (ei && ei.exp.op == EXP.tuple)
348 1.1 mrg {
349 1.1 mrg TupleExp te = ei.exp.isTupleExp();
350 1.1 mrg i.index.remove(j);
351 1.1 mrg i.value.remove(j);
352 1.1 mrg for (size_t k = 0; k < te.exps.dim; ++k)
353 1.1 mrg {
354 1.1 mrg Expression e = (*te.exps)[k];
355 1.1 mrg i.index.insert(j + k, cast(Expression)null);
356 1.1 mrg i.value.insert(j + k, new ExpInitializer(e.loc, e));
357 1.1 mrg }
358 1.1 mrg j--;
359 1.1 mrg continue;
360 1.1 mrg }
361 1.1 mrg else
362 1.1 mrg {
363 1.1 mrg i.value[j] = val;
364 1.1 mrg }
365 1.1 mrg length++;
366 1.1 mrg if (length == 0)
367 1.1 mrg {
368 1.1 mrg error(i.loc, "array dimension overflow");
369 1.1 mrg return err();
370 1.1 mrg }
371 1.1 mrg if (length > i.dim)
372 1.1 mrg i.dim = length;
373 1.1 mrg }
374 1.1 mrg if (auto tsa = t.isTypeSArray())
375 1.1 mrg {
376 1.1 mrg uinteger_t edim = tsa.dim.toInteger();
377 1.1 mrg if (i.dim > edim && !(tsa.isIncomplete() && (sc.flags & SCOPE.Cfile)))
378 1.1 mrg {
379 1.1 mrg error(i.loc, "array initializer has %u elements, but array length is %llu", i.dim, edim);
380 1.1 mrg return err();
381 1.1 mrg }
382 1.1 mrg }
383 1.1 mrg if (errors)
384 1.1 mrg return err();
385 1.1 mrg
386 1.1 mrg const sz = t.nextOf().size();
387 1.1 mrg if (sz == SIZE_INVALID)
388 1.1 mrg return err();
389 1.1 mrg bool overflow;
390 1.1 mrg const max = mulu(i.dim, sz, overflow);
391 1.1 mrg if (overflow || max >= amax)
392 1.1 mrg {
393 1.1 mrg error(i.loc, "array dimension %llu exceeds max of %llu", ulong(i.dim), ulong(amax / sz));
394 1.1 mrg return err();
395 1.1 mrg }
396 1.1 mrg return i;
397 1.1 mrg }
398 1.1 mrg
399 1.1 mrg Initializer visitExp(ExpInitializer i)
400 1.1 mrg {
401 1.1 mrg //printf("ExpInitializer::semantic(%s), type = %s\n", i.exp.toChars(), t.toChars());
402 1.1 mrg if (needInterpret)
403 1.1 mrg sc = sc.startCTFE();
404 1.1 mrg i.exp = i.exp.expressionSemantic(sc);
405 1.1 mrg i.exp = resolveProperties(sc, i.exp);
406 1.1 mrg if (needInterpret)
407 1.1 mrg sc = sc.endCTFE();
408 1.1 mrg if (i.exp.op == EXP.error)
409 1.1 mrg return err();
410 1.1 mrg uint olderrors = global.errors;
411 1.1 mrg
412 1.1 mrg /* ImportC: convert arrays to pointers, functions to pointers to functions
413 1.1 mrg */
414 1.1 mrg Type tb = t.toBasetype();
415 1.1 mrg if (tb.isTypePointer())
416 1.1 mrg i.exp = i.exp.arrayFuncConv(sc);
417 1.1 mrg
418 1.1 mrg /* Save the expression before ctfe
419 1.1 mrg * Otherwise the error message would contain for example "&[0][0]" instead of "new int"
420 1.1 mrg * Regression: https://issues.dlang.org/show_bug.cgi?id=21687
421 1.1 mrg */
422 1.1 mrg Expression currExp = i.exp;
423 1.1 mrg if (needInterpret)
424 1.1 mrg {
425 1.1 mrg // If the result will be implicitly cast, move the cast into CTFE
426 1.1 mrg // to avoid premature truncation of polysemous types.
427 1.1 mrg // eg real [] x = [1.1, 2.2]; should use real precision.
428 1.1 mrg if (i.exp.implicitConvTo(t) && !(sc.flags & SCOPE.Cfile))
429 1.1 mrg {
430 1.1 mrg i.exp = i.exp.implicitCastTo(sc, t);
431 1.1 mrg }
432 1.1 mrg if (!global.gag && olderrors != global.errors)
433 1.1 mrg {
434 1.1 mrg return i;
435 1.1 mrg }
436 1.1 mrg if (sc.flags & SCOPE.Cfile)
437 1.1 mrg {
438 1.1 mrg /* the interpreter turns (char*)"string" into &"string"[0] which then
439 1.1 mrg * it cannot interpret. Resolve that case by doing optimize() first
440 1.1 mrg */
441 1.1 mrg i.exp = i.exp.optimize(WANTvalue);
442 1.1 mrg if (i.exp.isSymOffExp())
443 1.1 mrg {
444 1.1 mrg /* `static variable cannot be read at compile time`
445 1.1 mrg * https://issues.dlang.org/show_bug.cgi?id=22513
446 1.1 mrg * Maybe this would be better addressed in ctfeInterpret()?
447 1.1 mrg */
448 1.1 mrg needInterpret = NeedInterpret.INITnointerpret;
449 1.1 mrg }
450 1.1 mrg }
451 1.1 mrg if (needInterpret)
452 1.1 mrg i.exp = i.exp.ctfeInterpret();
453 1.1 mrg if (i.exp.op == EXP.voidExpression)
454 1.1 mrg error(i.loc, "variables cannot be initialized with an expression of type `void`. Use `void` initialization instead.");
455 1.1 mrg }
456 1.1 mrg else
457 1.1 mrg {
458 1.1 mrg i.exp = i.exp.optimize(WANTvalue);
459 1.1 mrg }
460 1.1 mrg
461 1.1 mrg if (!global.gag && olderrors != global.errors)
462 1.1 mrg {
463 1.1 mrg return i; // Failed, suppress duplicate error messages
464 1.1 mrg }
465 1.1 mrg if (i.exp.type.isTypeTuple() && i.exp.type.isTypeTuple().arguments.dim == 0)
466 1.1 mrg {
467 1.1 mrg Type et = i.exp.type;
468 1.1 mrg i.exp = new TupleExp(i.exp.loc, new Expressions());
469 1.1 mrg i.exp.type = et;
470 1.1 mrg }
471 1.1 mrg if (i.exp.op == EXP.type)
472 1.1 mrg {
473 1.1 mrg i.exp.error("initializer must be an expression, not `%s`", i.exp.toChars());
474 1.1 mrg return err();
475 1.1 mrg }
476 1.1 mrg // Make sure all pointers are constants
477 1.1 mrg if (needInterpret && hasNonConstPointers(i.exp))
478 1.1 mrg {
479 1.1 mrg i.exp.error("cannot use non-constant CTFE pointer in an initializer `%s`", currExp.toChars());
480 1.1 mrg return err();
481 1.1 mrg }
482 1.1 mrg Type ti = i.exp.type.toBasetype();
483 1.1 mrg if (i.exp.op == EXP.tuple && i.expandTuples && !i.exp.implicitConvTo(t))
484 1.1 mrg {
485 1.1 mrg return new ExpInitializer(i.loc, i.exp);
486 1.1 mrg }
487 1.1 mrg /* Look for case of initializing a static array with a too-short
488 1.1 mrg * string literal, such as:
489 1.1 mrg * char[5] foo = "abc";
490 1.1 mrg * Allow this by doing an explicit cast, which will lengthen the string
491 1.1 mrg * literal.
492 1.1 mrg */
493 1.1 mrg if (i.exp.op == EXP.string_ && tb.ty == Tsarray)
494 1.1 mrg {
495 1.1 mrg StringExp se = i.exp.isStringExp();
496 1.1 mrg Type typeb = se.type.toBasetype();
497 1.1 mrg TY tynto = tb.nextOf().ty;
498 1.1 mrg if (!se.committed &&
499 1.1 mrg (typeb.ty == Tarray || typeb.ty == Tsarray) && tynto.isSomeChar &&
500 1.1 mrg se.numberOfCodeUnits(tynto) < tb.isTypeSArray().dim.toInteger())
501 1.1 mrg {
502 1.1 mrg i.exp = se.castTo(sc, t);
503 1.1 mrg goto L1;
504 1.1 mrg }
505 1.1 mrg
506 1.1 mrg /* Lop off terminating 0 of initializer for:
507 1.1 mrg * static char s[5] = "hello";
508 1.1 mrg */
509 1.1 mrg if (sc.flags & SCOPE.Cfile &&
510 1.1 mrg typeb.ty == Tsarray &&
511 1.1 mrg tynto.isSomeChar &&
512 1.1 mrg tb.isTypeSArray().dim.toInteger() + 1 == typeb.isTypeSArray().dim.toInteger())
513 1.1 mrg {
514 1.1 mrg i.exp = se.castTo(sc, t);
515 1.1 mrg goto L1;
516 1.1 mrg }
517 1.1 mrg }
518 1.1 mrg /* C11 6.7.9-14..15
519 1.1 mrg * Initialize an array of unknown size with a string.
520 1.1 mrg * Change to static array of known size
521 1.1 mrg */
522 1.1 mrg if (sc.flags & SCOPE.Cfile && i.exp.isStringExp() &&
523 1.1 mrg tb.isTypeSArray() && tb.isTypeSArray().isIncomplete())
524 1.1 mrg {
525 1.1 mrg StringExp se = i.exp.isStringExp();
526 1.1 mrg auto ts = new TypeSArray(tb.nextOf(), new IntegerExp(Loc.initial, se.len + 1, Type.tsize_t));
527 1.1 mrg t = typeSemantic(ts, Loc.initial, sc);
528 1.1 mrg i.exp.type = t;
529 1.1 mrg tx = t;
530 1.1 mrg }
531 1.1 mrg
532 1.1 mrg // Look for implicit constructor call
533 1.1 mrg if (tb.ty == Tstruct && !(ti.ty == Tstruct && tb.toDsymbol(sc) == ti.toDsymbol(sc)) && !i.exp.implicitConvTo(t))
534 1.1 mrg {
535 1.1 mrg StructDeclaration sd = tb.isTypeStruct().sym;
536 1.1 mrg if (sd.ctor)
537 1.1 mrg {
538 1.1 mrg // Rewrite as S().ctor(exp)
539 1.1 mrg Expression e;
540 1.1 mrg e = new StructLiteralExp(i.loc, sd, null);
541 1.1 mrg e = new DotIdExp(i.loc, e, Id.ctor);
542 1.1 mrg e = new CallExp(i.loc, e, i.exp);
543 1.1 mrg e = e.expressionSemantic(sc);
544 1.1 mrg if (needInterpret)
545 1.1 mrg i.exp = e.ctfeInterpret();
546 1.1 mrg else
547 1.1 mrg i.exp = e.optimize(WANTvalue);
548 1.1 mrg }
549 1.1 mrg else if (search_function(sd, Id.call))
550 1.1 mrg {
551 1.1 mrg /* https://issues.dlang.org/show_bug.cgi?id=1547
552 1.1 mrg *
553 1.1 mrg * Look for static opCall
554 1.1 mrg *
555 1.1 mrg * Rewrite as:
556 1.1 mrg * i.exp = typeof(sd).opCall(arguments)
557 1.1 mrg */
558 1.1 mrg
559 1.1 mrg Expression e = typeDotIdExp(i.loc, sd.type, Id.call);
560 1.1 mrg e = new CallExp(i.loc, e, i.exp);
561 1.1 mrg e = e.expressionSemantic(sc);
562 1.1 mrg e = resolveProperties(sc, e);
563 1.1 mrg if (needInterpret)
564 1.1 mrg i.exp = e.ctfeInterpret();
565 1.1 mrg else
566 1.1 mrg i.exp = e.optimize(WANTvalue);
567 1.1 mrg }
568 1.1 mrg }
569 1.1 mrg {
570 1.1 mrg // Look for the case of statically initializing an array
571 1.1 mrg // with a single member.
572 1.1 mrg auto tba = tb.isTypeSArray();
573 1.1 mrg if (tba && !tba.next.equals(ti.toBasetype().nextOf()) && i.exp.implicitConvTo(tba.next))
574 1.1 mrg {
575 1.1 mrg /* If the variable is not actually used in compile time, array creation is
576 1.1 mrg * redundant. So delay it until invocation of toExpression() or toDt().
577 1.1 mrg */
578 1.1 mrg t = tb.nextOf();
579 1.1 mrg }
580 1.1 mrg
581 1.1 mrg auto tta = t.isTypeSArray();
582 1.1 mrg if (i.exp.implicitConvTo(t))
583 1.1 mrg {
584 1.1 mrg i.exp = i.exp.implicitCastTo(sc, t);
585 1.1 mrg }
586 1.1 mrg else if (sc.flags & SCOPE.Cfile && i.exp.isStringExp() &&
587 1.1 mrg tta && (tta.next.ty == Tint8 || tta.next.ty == Tuns8) &&
588 1.1 mrg ti.ty == Tpointer && ti.nextOf().ty == Tchar)
589 1.1 mrg {
590 1.1 mrg /* unsigned char bbb[1] = "";
591 1.1 mrg * signed char ccc[1] = "";
592 1.1 mrg */
593 1.1 mrg i.exp = i.exp.castTo(sc, t);
594 1.1 mrg }
595 1.1 mrg else
596 1.1 mrg {
597 1.1 mrg // Look for mismatch of compile-time known length to emit
598 1.1 mrg // better diagnostic message, as same as AssignExp::semantic.
599 1.1 mrg if (tba && i.exp.implicitConvTo(tba.next.arrayOf()) > MATCH.nomatch)
600 1.1 mrg {
601 1.1 mrg uinteger_t dim1 = tba.dim.toInteger();
602 1.1 mrg uinteger_t dim2 = dim1;
603 1.1 mrg if (auto ale = i.exp.isArrayLiteralExp())
604 1.1 mrg {
605 1.1 mrg dim2 = ale.elements ? ale.elements.dim : 0;
606 1.1 mrg }
607 1.1 mrg else if (auto se = i.exp.isSliceExp())
608 1.1 mrg {
609 1.1 mrg if (Type tx = toStaticArrayType(se))
610 1.1 mrg dim2 = tx.isTypeSArray().dim.toInteger();
611 1.1 mrg }
612 1.1 mrg if (dim1 != dim2)
613 1.1 mrg {
614 1.1 mrg i.exp.error("mismatched array lengths, %d and %d", cast(int)dim1, cast(int)dim2);
615 1.1 mrg i.exp = ErrorExp.get();
616 1.1 mrg }
617 1.1 mrg }
618 1.1 mrg Type et = i.exp.type;
619 1.1 mrg const errors = global.startGagging();
620 1.1 mrg i.exp = i.exp.implicitCastTo(sc, t);
621 1.1 mrg if (global.endGagging(errors))
622 1.1 mrg currExp.error("cannot implicitly convert expression `%s` of type `%s` to `%s`", currExp.toChars(), et.toChars(), t.toChars());
623 1.1 mrg }
624 1.1 mrg }
625 1.1 mrg L1:
626 1.1 mrg if (i.exp.op == EXP.error)
627 1.1 mrg {
628 1.1 mrg return i;
629 1.1 mrg }
630 1.1 mrg if (needInterpret)
631 1.1 mrg i.exp = i.exp.ctfeInterpret();
632 1.1 mrg else
633 1.1 mrg i.exp = i.exp.optimize(WANTvalue);
634 1.1 mrg //printf("-ExpInitializer::semantic(): "); i.exp.print();
635 1.1 mrg return i;
636 1.1 mrg }
637 1.1 mrg
638 1.1 mrg Initializer visitC(CInitializer ci)
639 1.1 mrg {
640 1.1 mrg if (ci.sem) // if semantic() already run
641 1.1 mrg return ci;
642 1.1 mrg //printf("CInitializer::semantic() (%s) %s\n", t.toChars(), ci.toChars());
643 1.1 mrg ci.sem = true;
644 1.1 mrg t = t.toBasetype();
645 1.1 mrg ci.type = t; // later passes will need this
646 1.1 mrg
647 1.1 mrg auto dil = ci.initializerList[];
648 1.1 mrg size_t i = 0; // index into dil[]
649 1.1 mrg const uint amax = 0x8000_0000;
650 1.1 mrg bool errors;
651 1.1 mrg
652 1.1 mrg /* If `{ expression }` return the expression initializer
653 1.1 mrg */
654 1.1 mrg ExpInitializer isBraceExpression()
655 1.1 mrg {
656 1.1 mrg return (dil.length == 1 && !dil[0].designatorList)
657 1.1 mrg ? dil[0].initializer.isExpInitializer()
658 1.1 mrg : null;
659 1.1 mrg }
660 1.1 mrg
661 1.1 mrg /* Convert struct initializer into ExpInitializer
662 1.1 mrg */
663 1.1 mrg Initializer structs(TypeStruct ts)
664 1.1 mrg {
665 1.1 mrg //printf("structs %s\n", ts.toChars());
666 1.1 mrg StructDeclaration sd = ts.sym;
667 1.1 mrg sd.size(ci.loc);
668 1.1 mrg if (sd.sizeok != Sizeok.done)
669 1.1 mrg {
670 1.1 mrg errors = true;
671 1.1 mrg return err();
672 1.1 mrg }
673 1.1 mrg const nfields = sd.nonHiddenFields();
674 1.1 mrg auto elements = new Expressions(nfields);
675 1.1 mrg auto elems = (*elements)[];
676 1.1 mrg foreach (ref elem; elems)
677 1.1 mrg elem = null;
678 1.1 mrg
679 1.1 mrg FieldLoop:
680 1.1 mrg for (size_t fieldi = 0; fieldi < nfields; ++fieldi)
681 1.1 mrg {
682 1.1 mrg if (i == dil.length)
683 1.1 mrg break;
684 1.1 mrg
685 1.1 mrg auto di = dil[i];
686 1.1 mrg if (di.designatorList)
687 1.1 mrg {
688 1.1 mrg error(ci.loc, "C designator-list not supported yet");
689 1.1 mrg errors = true;
690 1.1 mrg break;
691 1.1 mrg }
692 1.1 mrg
693 1.1 mrg VarDeclaration vd = sd.fields[fieldi];
694 1.1 mrg
695 1.1 mrg // Check for overlapping initializations (can happen with unions)
696 1.1 mrg foreach (k, v2; sd.fields[0 .. nfields])
697 1.1 mrg {
698 1.1 mrg if (vd.isOverlappedWith(v2) && elems[k])
699 1.1 mrg {
700 1.1 mrg continue FieldLoop; // skip it
701 1.1 mrg }
702 1.1 mrg }
703 1.1 mrg
704 1.1 mrg ++i;
705 1.1 mrg
706 1.1 mrg // Convert initializer to Expression `ex`
707 1.1 mrg assert(sc);
708 1.1 mrg auto tm = vd.type.addMod(ts.mod);
709 1.1 mrg auto iz = di.initializer.initializerSemantic(sc, tm, needInterpret);
710 1.1 mrg auto ex = iz.initializerToExpression(null, true);
711 1.1 mrg if (ex.op == EXP.error)
712 1.1 mrg {
713 1.1 mrg errors = true;
714 1.1 mrg continue;
715 1.1 mrg }
716 1.1 mrg
717 1.1 mrg elems[fieldi] = ex;
718 1.1 mrg }
719 1.1 mrg if (errors)
720 1.1 mrg return err();
721 1.1 mrg
722 1.1 mrg // Make a StructLiteralExp out of elements[]
723 1.1 mrg Type tx = ts;
724 1.1 mrg auto sle = new StructLiteralExp(ci.loc, sd, elements, tx);
725 1.1 mrg if (!sd.fill(ci.loc, elements, false))
726 1.1 mrg return err();
727 1.1 mrg sle.type = tx;
728 1.1 mrg auto ie = new ExpInitializer(ci.loc, sle);
729 1.1 mrg return ie.initializerSemantic(sc, tx, needInterpret);
730 1.1 mrg }
731 1.1 mrg
732 1.1 mrg if (auto ts = t.isTypeStruct())
733 1.1 mrg {
734 1.1 mrg auto ei = structs(ts);
735 1.1 mrg if (errors)
736 1.1 mrg return err();
737 1.1 mrg if (i < dil.length)
738 1.1 mrg {
739 1.1 mrg error(ci.loc, "%d extra initializer(s) for `struct %s`", cast(int)(dil.length - i), ts.toChars());
740 1.1 mrg return err();
741 1.1 mrg }
742 1.1 mrg return ei;
743 1.1 mrg }
744 1.1 mrg
745 1.1 mrg auto tsa = t.isTypeSArray();
746 1.1 mrg if (!tsa)
747 1.1 mrg {
748 1.1 mrg /* Not an array. See if it is `{ exp }` which can be
749 1.1 mrg * converted to an ExpInitializer
750 1.1 mrg */
751 1.1 mrg if (ExpInitializer ei = isBraceExpression())
752 1.1 mrg {
753 1.1 mrg return ei.initializerSemantic(sc, t, needInterpret);
754 1.1 mrg }
755 1.1 mrg
756 1.1 mrg error(ci.loc, "C non-array initializer (%s) %s not supported yet", t.toChars(), ci.toChars());
757 1.1 mrg return err();
758 1.1 mrg }
759 1.1 mrg
760 1.1 mrg /* If it's an array of integral being initialized by `{ string }`
761 1.1 mrg * replace with `string`
762 1.1 mrg */
763 1.1 mrg auto tn = t.nextOf();
764 1.1 mrg if (tn.isintegral())
765 1.1 mrg {
766 1.1 mrg if (ExpInitializer ei = isBraceExpression())
767 1.1 mrg {
768 1.1 mrg if (ei.exp.isStringExp())
769 1.1 mrg return ei.initializerSemantic(sc, t, needInterpret);
770 1.1 mrg }
771 1.1 mrg }
772 1.1 mrg
773 1.1 mrg /* Support recursion to handle un-braced array initializers
774 1.1 mrg * Params:
775 1.1 mrg * t = element type
776 1.1 mrg * dim = max number of elements
777 1.1 mrg * simple = true if array of simple elements
778 1.1 mrg * Returns:
779 1.1 mrg * # of elements in array
780 1.1 mrg */
781 1.1 mrg size_t array(Type t, size_t dim, ref bool simple)
782 1.1 mrg {
783 1.1 mrg //printf(" type %s i %d dim %d dil.length = %d\n", t.toChars(), cast(int)i, cast(int)dim, cast(int)dil.length);
784 1.1 mrg auto tn = t.nextOf().toBasetype();
785 1.1 mrg auto tnsa = tn.isTypeSArray();
786 1.1 mrg if (tnsa && tnsa.isIncomplete())
787 1.1 mrg {
788 1.1 mrg // C11 6.2.5-20 "element type shall be complete whenever the array type is specified"
789 1.1 mrg error(ci.loc, "incomplete element type `%s` not allowed", tnsa.toChars());
790 1.1 mrg errors = true;
791 1.1 mrg return 1;
792 1.1 mrg }
793 1.1 mrg if (i == dil.length)
794 1.1 mrg return 0;
795 1.1 mrg size_t n;
796 1.1 mrg const nelems = tnsa ? cast(size_t)tnsa.dim.toInteger() : 0;
797 1.1 mrg
798 1.1 mrg /* Run initializerSemantic on a single element.
799 1.1 mrg */
800 1.1 mrg Initializer elem(Initializer ie)
801 1.1 mrg {
802 1.1 mrg ++i;
803 1.1 mrg auto tnx = tn; // in case initializerSemantic tries to change it
804 1.1 mrg ie = ie.initializerSemantic(sc, tnx, needInterpret);
805 1.1 mrg if (ie.isErrorInitializer())
806 1.1 mrg errors = true;
807 1.1 mrg assert(tnx == tn); // sub-types should not be modified
808 1.1 mrg return ie;
809 1.1 mrg }
810 1.1 mrg
811 1.1 mrg foreach (j; 0 .. dim)
812 1.1 mrg {
813 1.1 mrg auto di = dil[i];
814 1.1 mrg if (di.designatorList)
815 1.1 mrg {
816 1.1 mrg error(ci.loc, "C designator-list not supported yet");
817 1.1 mrg errors = true;
818 1.1 mrg break;
819 1.1 mrg }
820 1.1 mrg if (tnsa && di.initializer.isExpInitializer())
821 1.1 mrg {
822 1.1 mrg // no braces enclosing array initializer, so recurse
823 1.1 mrg array(tnsa, nelems, simple);
824 1.1 mrg }
825 1.1 mrg else if (auto tns = tn.isTypeStruct())
826 1.1 mrg {
827 1.1 mrg if (auto ei = di.initializer.isExpInitializer())
828 1.1 mrg {
829 1.1 mrg // no braces enclosing struct initializer
830 1.1 mrg
831 1.1 mrg /* Disambiguate between an exp representing the entire
832 1.1 mrg * struct, and an exp representing the first field of the struct
833 1.1 mrg */
834 1.1 mrg if (needInterpret)
835 1.1 mrg sc = sc.startCTFE();
836 1.1 mrg ei.exp = ei.exp.expressionSemantic(sc);
837 1.1 mrg ei.exp = resolveProperties(sc, ei.exp);
838 1.1 mrg if (needInterpret)
839 1.1 mrg sc = sc.endCTFE();
840 1.1 mrg if (ei.exp.implicitConvTo(tn))
841 1.1 mrg di.initializer = elem(di.initializer); // the whole struct
842 1.1 mrg else
843 1.1 mrg {
844 1.1 mrg simple = false;
845 1.1 mrg dil[n].initializer = structs(tns); // the first field
846 1.1 mrg }
847 1.1 mrg }
848 1.1 mrg else
849 1.1 mrg dil[n].initializer = elem(di.initializer);
850 1.1 mrg }
851 1.1 mrg else
852 1.1 mrg {
853 1.1 mrg di.initializer = elem(di.initializer);
854 1.1 mrg }
855 1.1 mrg ++n;
856 1.1 mrg if (i == dil.length)
857 1.1 mrg break;
858 1.1 mrg }
859 1.1 mrg //printf(" n: %d i: %d\n", cast(int)n, cast(int)i);
860 1.1 mrg return n;
861 1.1 mrg }
862 1.1 mrg
863 1.1 mrg size_t dim = tsa.isIncomplete() ? dil.length : cast(size_t)tsa.dim.toInteger();
864 1.1 mrg bool simple = true;
865 1.1 mrg auto newdim = array(t, dim, simple);
866 1.1 mrg
867 1.1 mrg if (errors)
868 1.1 mrg return err();
869 1.1 mrg
870 1.1 mrg if (tsa.isIncomplete()) // array of unknown length
871 1.1 mrg {
872 1.1 mrg // Change to array of known length
873 1.1 mrg tsa = new TypeSArray(tn, new IntegerExp(Loc.initial, newdim, Type.tsize_t));
874 1.1 mrg tx = tsa; // rewrite caller's type
875 1.1 mrg ci.type = tsa; // remember for later passes
876 1.1 mrg }
877 1.1 mrg const uinteger_t edim = tsa.dim.toInteger();
878 1.1 mrg if (i < dil.length)
879 1.1 mrg {
880 1.1 mrg error(ci.loc, "%d extra initializer(s) for static array length of %d", cast(int)(dil.length - i), cast(int)edim);
881 1.1 mrg return err();
882 1.1 mrg }
883 1.1 mrg
884 1.1 mrg const sz = tn.size(); // element size
885 1.1 mrg if (sz == SIZE_INVALID)
886 1.1 mrg return err();
887 1.1 mrg bool overflow;
888 1.1 mrg const max = mulu(edim, sz, overflow);
889 1.1 mrg if (overflow || max >= amax)
890 1.1 mrg {
891 1.1 mrg error(ci.loc, "array dimension %llu exceeds max of %llu", ulong(edim), ulong(amax / sz));
892 1.1 mrg return err();
893 1.1 mrg }
894 1.1 mrg
895 1.1 mrg /* If an array of simple elements, replace with an ArrayInitializer
896 1.1 mrg */
897 1.1 mrg auto tnb = tn.toBasetype();
898 1.1 mrg if (!tnb.isTypeSArray() && (!tnb.isTypeStruct() || simple))
899 1.1 mrg {
900 1.1 mrg auto ai = new ArrayInitializer(ci.loc);
901 1.1 mrg ai.dim = cast(uint) dil.length;
902 1.1 mrg ai.index.setDim(dil.length);
903 1.1 mrg ai.value.setDim(dil.length);
904 1.1 mrg foreach (const j; 0 .. dil.length)
905 1.1 mrg {
906 1.1 mrg ai.index[j] = null;
907 1.1 mrg ai.value[j] = dil[j].initializer;
908 1.1 mrg }
909 1.1 mrg auto ty = tx;
910 1.1 mrg return ai.initializerSemantic(sc, ty, needInterpret);
911 1.1 mrg }
912 1.1 mrg
913 1.1 mrg if (newdim < ci.initializerList.length && tnb.isTypeStruct())
914 1.1 mrg {
915 1.1 mrg // https://issues.dlang.org/show_bug.cgi?id=22375
916 1.1 mrg // initializerList can be bigger than the number of actual elements
917 1.1 mrg // to initialize for array of structs because it is not required
918 1.1 mrg // for values to have proper bracing.
919 1.1 mrg // i.e: These are all valid initializers for `struct{int a,b;}[3]`:
920 1.1 mrg // {1,2,3,4}, {{1,2},3,4}, {1,2,{3,4}}, {{1,2},{3,4}}
921 1.1 mrg // In all examples above, the new length of the initializer list
922 1.1 mrg // has been shortened from four elements to two. This is important,
923 1.1 mrg // because `dil` is written back to directly, making the lowered
924 1.1 mrg // initializer `{{1,2},{3,4}}` and not `{{1,2},{3,4},3,4}`.
925 1.1 mrg ci.initializerList.length = newdim;
926 1.1 mrg }
927 1.1 mrg
928 1.1 mrg return ci;
929 1.1 mrg }
930 1.1 mrg
931 1.1 mrg final switch (init.kind)
932 1.1 mrg {
933 1.1 mrg case InitKind.void_: return visitVoid (init.isVoidInitializer());
934 1.1 mrg case InitKind.error: return visitError (init.isErrorInitializer());
935 1.1 mrg case InitKind.struct_: return visitStruct(init.isStructInitializer());
936 1.1 mrg case InitKind.array: return visitArray (init.isArrayInitializer());
937 1.1 mrg case InitKind.exp: return visitExp (init.isExpInitializer());
938 1.1 mrg case InitKind.C_: return visitC (init.isCInitializer());
939 1.1 mrg }
940 1.1 mrg }
941 1.1 mrg
942 1.1 mrg /***********************
943 1.1 mrg * Translate init to an `Expression` in order to infer the type.
944 1.1 mrg * Params:
945 1.1 mrg * init = `Initializer` AST node
946 1.1 mrg * sc = context
947 1.1 mrg * Returns:
948 1.1 mrg * an equivalent `ExpInitializer` if successful, or `ErrorInitializer` if it cannot be translated
949 1.1 mrg */
950 1.1 mrg Initializer inferType(Initializer init, Scope* sc)
951 1.1 mrg {
952 1.1 mrg Initializer visitVoid(VoidInitializer i)
953 1.1 mrg {
954 1.1 mrg error(i.loc, "cannot infer type from void initializer");
955 1.1 mrg return new ErrorInitializer();
956 1.1 mrg }
957 1.1 mrg
958 1.1 mrg Initializer visitError(ErrorInitializer i)
959 1.1 mrg {
960 1.1 mrg return i;
961 1.1 mrg }
962 1.1 mrg
963 1.1 mrg Initializer visitStruct(StructInitializer i)
964 1.1 mrg {
965 1.1 mrg error(i.loc, "cannot infer type from struct initializer");
966 1.1 mrg return new ErrorInitializer();
967 1.1 mrg }
968 1.1 mrg
969 1.1 mrg Initializer visitArray(ArrayInitializer init)
970 1.1 mrg {
971 1.1 mrg //printf("ArrayInitializer::inferType() %s\n", toChars());
972 1.1 mrg Expressions* keys = null;
973 1.1 mrg Expressions* values;
974 1.1 mrg if (init.isAssociativeArray())
975 1.1 mrg {
976 1.1 mrg keys = new Expressions(init.value.dim);
977 1.1 mrg values = new Expressions(init.value.dim);
978 1.1 mrg for (size_t i = 0; i < init.value.dim; i++)
979 1.1 mrg {
980 1.1 mrg Expression e = init.index[i];
981 1.1 mrg if (!e)
982 1.1 mrg goto Lno;
983 1.1 mrg (*keys)[i] = e;
984 1.1 mrg Initializer iz = init.value[i];
985 1.1 mrg if (!iz)
986 1.1 mrg goto Lno;
987 1.1 mrg iz = iz.inferType(sc);
988 1.1 mrg if (iz.isErrorInitializer())
989 1.1 mrg {
990 1.1 mrg return iz;
991 1.1 mrg }
992 1.1 mrg (*values)[i] = iz.isExpInitializer().exp;
993 1.1 mrg assert(!(*values)[i].isErrorExp());
994 1.1 mrg }
995 1.1 mrg Expression e = new AssocArrayLiteralExp(init.loc, keys, values);
996 1.1 mrg auto ei = new ExpInitializer(init.loc, e);
997 1.1 mrg return ei.inferType(sc);
998 1.1 mrg }
999 1.1 mrg else
1000 1.1 mrg {
1001 1.1 mrg auto elements = new Expressions(init.value.dim);
1002 1.1 mrg elements.zero();
1003 1.1 mrg for (size_t i = 0; i < init.value.dim; i++)
1004 1.1 mrg {
1005 1.1 mrg assert(!init.index[i]); // already asserted by isAssociativeArray()
1006 1.1 mrg Initializer iz = init.value[i];
1007 1.1 mrg if (!iz)
1008 1.1 mrg goto Lno;
1009 1.1 mrg iz = iz.inferType(sc);
1010 1.1 mrg if (iz.isErrorInitializer())
1011 1.1 mrg {
1012 1.1 mrg return iz;
1013 1.1 mrg }
1014 1.1 mrg (*elements)[i] = iz.isExpInitializer().exp;
1015 1.1 mrg assert(!(*elements)[i].isErrorExp());
1016 1.1 mrg }
1017 1.1 mrg Expression e = new ArrayLiteralExp(init.loc, null, elements);
1018 1.1 mrg auto ei = new ExpInitializer(init.loc, e);
1019 1.1 mrg return ei.inferType(sc);
1020 1.1 mrg }
1021 1.1 mrg Lno:
1022 1.1 mrg if (keys)
1023 1.1 mrg {
1024 1.1 mrg error(init.loc, "not an associative array initializer");
1025 1.1 mrg }
1026 1.1 mrg else
1027 1.1 mrg {
1028 1.1 mrg error(init.loc, "cannot infer type from array initializer");
1029 1.1 mrg }
1030 1.1 mrg return new ErrorInitializer();
1031 1.1 mrg }
1032 1.1 mrg
1033 1.1 mrg Initializer visitExp(ExpInitializer init)
1034 1.1 mrg {
1035 1.1 mrg //printf("ExpInitializer::inferType() %s\n", init.toChars());
1036 1.1 mrg init.exp = init.exp.expressionSemantic(sc);
1037 1.1 mrg
1038 1.1 mrg // for static alias this: https://issues.dlang.org/show_bug.cgi?id=17684
1039 1.1 mrg if (init.exp.op == EXP.type)
1040 1.1 mrg init.exp = resolveAliasThis(sc, init.exp);
1041 1.1 mrg
1042 1.1 mrg init.exp = resolveProperties(sc, init.exp);
1043 1.1 mrg if (auto se = init.exp.isScopeExp())
1044 1.1 mrg {
1045 1.1 mrg TemplateInstance ti = se.sds.isTemplateInstance();
1046 1.1 mrg if (ti && ti.semanticRun == PASS.semantic && !ti.aliasdecl)
1047 1.1 mrg se.error("cannot infer type from %s `%s`, possible circular dependency", se.sds.kind(), se.toChars());
1048 1.1 mrg else
1049 1.1 mrg se.error("cannot infer type from %s `%s`", se.sds.kind(), se.toChars());
1050 1.1 mrg return new ErrorInitializer();
1051 1.1 mrg }
1052 1.1 mrg
1053 1.1 mrg // Give error for overloaded function addresses
1054 1.1 mrg bool hasOverloads;
1055 1.1 mrg if (auto f = isFuncAddress(init.exp, &hasOverloads))
1056 1.1 mrg {
1057 1.1 mrg if (f.checkForwardRef(init.loc))
1058 1.1 mrg {
1059 1.1 mrg return new ErrorInitializer();
1060 1.1 mrg }
1061 1.1 mrg if (hasOverloads && !f.isUnique())
1062 1.1 mrg {
1063 1.1 mrg init.exp.error("cannot infer type from overloaded function symbol `%s`", init.exp.toChars());
1064 1.1 mrg return new ErrorInitializer();
1065 1.1 mrg }
1066 1.1 mrg }
1067 1.1 mrg if (auto ae = init.exp.isAddrExp())
1068 1.1 mrg {
1069 1.1 mrg if (ae.e1.op == EXP.overloadSet)
1070 1.1 mrg {
1071 1.1 mrg init.exp.error("cannot infer type from overloaded function symbol `%s`", init.exp.toChars());
1072 1.1 mrg return new ErrorInitializer();
1073 1.1 mrg }
1074 1.1 mrg }
1075 1.1 mrg if (init.exp.isErrorExp())
1076 1.1 mrg {
1077 1.1 mrg return new ErrorInitializer();
1078 1.1 mrg }
1079 1.1 mrg if (!init.exp.type)
1080 1.1 mrg {
1081 1.1 mrg return new ErrorInitializer();
1082 1.1 mrg }
1083 1.1 mrg return init;
1084 1.1 mrg }
1085 1.1 mrg
1086 1.1 mrg Initializer visitC(CInitializer i)
1087 1.1 mrg {
1088 1.1 mrg //printf("CInitializer.inferType()\n");
1089 1.1 mrg error(i.loc, "TODO C inferType initializers not supported yet");
1090 1.1 mrg return new ErrorInitializer();
1091 1.1 mrg }
1092 1.1 mrg
1093 1.1 mrg final switch (init.kind)
1094 1.1 mrg {
1095 1.1 mrg case InitKind.void_: return visitVoid (init.isVoidInitializer());
1096 1.1 mrg case InitKind.error: return visitError (init.isErrorInitializer());
1097 1.1 mrg case InitKind.struct_: return visitStruct(init.isStructInitializer());
1098 1.1 mrg case InitKind.array: return visitArray (init.isArrayInitializer());
1099 1.1 mrg case InitKind.exp: return visitExp (init.isExpInitializer());
1100 1.1 mrg case InitKind.C_: return visitC (init.isCInitializer());
1101 1.1 mrg }
1102 1.1 mrg }
1103 1.1 mrg
1104 1.1 mrg /***********************
1105 1.1 mrg * Translate init to an `Expression`.
1106 1.1 mrg * Params:
1107 1.1 mrg * init = `Initializer` AST node
1108 1.1 mrg * itype = if not `null`, type to coerce expression to
1109 1.1 mrg * isCfile = default initializers are different with C
1110 1.1 mrg * Returns:
1111 1.1 mrg * `Expression` created, `null` if cannot, `ErrorExp` for other errors
1112 1.1 mrg */
1113 1.1 mrg extern (C++) Expression initializerToExpression(Initializer init, Type itype = null, const bool isCfile = false)
1114 1.1 mrg {
1115 1.1 mrg //printf("initializerToExpression() isCfile: %d\n", isCfile);
1116 1.1 mrg
1117 1.1 mrg Expression visitVoid(VoidInitializer)
1118 1.1 mrg {
1119 1.1 mrg return null;
1120 1.1 mrg }
1121 1.1 mrg
1122 1.1 mrg Expression visitError(ErrorInitializer)
1123 1.1 mrg {
1124 1.1 mrg return ErrorExp.get();
1125 1.1 mrg }
1126 1.1 mrg
1127 1.1 mrg /***************************************
1128 1.1 mrg * This works by transforming a struct initializer into
1129 1.1 mrg * a struct literal. In the future, the two should be the
1130 1.1 mrg * same thing.
1131 1.1 mrg */
1132 1.1 mrg Expression visitStruct(StructInitializer)
1133 1.1 mrg {
1134 1.1 mrg // cannot convert to an expression without target 'ad'
1135 1.1 mrg return null;
1136 1.1 mrg }
1137 1.1 mrg
1138 1.1 mrg /********************************
1139 1.1 mrg * If possible, convert array initializer to array literal.
1140 1.1 mrg * Otherwise return NULL.
1141 1.1 mrg */
1142 1.1 mrg Expression visitArray(ArrayInitializer init)
1143 1.1 mrg {
1144 1.1 mrg //printf("ArrayInitializer::toExpression(), dim = %d\n", dim);
1145 1.1 mrg //static int i; if (++i == 2) assert(0);
1146 1.1 mrg uint edim; // the length of the resulting array literal
1147 1.1 mrg const(uint) amax = 0x80000000;
1148 1.1 mrg Type t = null; // type of the array literal being initialized
1149 1.1 mrg if (init.type)
1150 1.1 mrg {
1151 1.1 mrg if (init.type == Type.terror)
1152 1.1 mrg {
1153 1.1 mrg return ErrorExp.get();
1154 1.1 mrg }
1155 1.1 mrg t = init.type.toBasetype();
1156 1.1 mrg switch (t.ty)
1157 1.1 mrg {
1158 1.1 mrg case Tvector:
1159 1.1 mrg t = t.isTypeVector().basetype;
1160 1.1 mrg goto case Tsarray;
1161 1.1 mrg
1162 1.1 mrg case Tsarray:
1163 1.1 mrg uinteger_t adim = t.isTypeSArray().dim.toInteger();
1164 1.1 mrg if (adim >= amax)
1165 1.1 mrg return null;
1166 1.1 mrg edim = cast(uint)adim;
1167 1.1 mrg break;
1168 1.1 mrg
1169 1.1 mrg case Tpointer:
1170 1.1 mrg case Tarray:
1171 1.1 mrg edim = init.dim;
1172 1.1 mrg break;
1173 1.1 mrg
1174 1.1 mrg default:
1175 1.1 mrg assert(0);
1176 1.1 mrg }
1177 1.1 mrg }
1178 1.1 mrg else
1179 1.1 mrg {
1180 1.1 mrg /* Calculate the length of the array literal
1181 1.1 mrg */
1182 1.1 mrg edim = cast(uint)init.value.dim;
1183 1.1 mrg size_t j = 0;
1184 1.1 mrg foreach (i; 0 .. init.value.dim)
1185 1.1 mrg {
1186 1.1 mrg if (auto e = init.index[i])
1187 1.1 mrg {
1188 1.1 mrg if (e.op == EXP.int64)
1189 1.1 mrg {
1190 1.1 mrg const uinteger_t idxval = e.toInteger();
1191 1.1 mrg if (idxval >= amax)
1192 1.1 mrg return null;
1193 1.1 mrg j = cast(size_t)idxval;
1194 1.1 mrg }
1195 1.1 mrg else
1196 1.1 mrg return null;
1197 1.1 mrg }
1198 1.1 mrg ++j;
1199 1.1 mrg if (j > edim)
1200 1.1 mrg edim = cast(uint)j;
1201 1.1 mrg }
1202 1.1 mrg }
1203 1.1 mrg
1204 1.1 mrg auto elements = new Expressions(edim);
1205 1.1 mrg elements.zero();
1206 1.1 mrg size_t j = 0;
1207 1.1 mrg foreach (i; 0 .. init.value.dim)
1208 1.1 mrg {
1209 1.1 mrg if (auto e = init.index[i])
1210 1.1 mrg j = cast(size_t)e.toInteger();
1211 1.1 mrg assert(j < edim);
1212 1.1 mrg if (Initializer iz = init.value[i])
1213 1.1 mrg {
1214 1.1 mrg if (Expression ex = iz.initializerToExpression(null, isCfile))
1215 1.1 mrg {
1216 1.1 mrg (*elements)[j] = ex;
1217 1.1 mrg ++j;
1218 1.1 mrg }
1219 1.1 mrg else
1220 1.1 mrg return null;
1221 1.1 mrg }
1222 1.1 mrg else
1223 1.1 mrg return null;
1224 1.1 mrg }
1225 1.1 mrg
1226 1.1 mrg /* Fill in any missing elements with the default initializer
1227 1.1 mrg */
1228 1.1 mrg Expression defaultInit = null; // lazily create it
1229 1.1 mrg foreach (ref element; (*elements)[0 .. edim])
1230 1.1 mrg {
1231 1.1 mrg if (!element)
1232 1.1 mrg {
1233 1.1 mrg if (!init.type) // don't know what type to use
1234 1.1 mrg return null;
1235 1.1 mrg if (!defaultInit)
1236 1.1 mrg defaultInit = (cast(TypeNext)t).next.defaultInit(Loc.initial, isCfile);
1237 1.1 mrg element = defaultInit;
1238 1.1 mrg }
1239 1.1 mrg }
1240 1.1 mrg
1241 1.1 mrg /* Expand any static array initializers that are a single expression
1242 1.1 mrg * into an array of them
1243 1.1 mrg * e => [e, e, ..., e, e]
1244 1.1 mrg */
1245 1.1 mrg if (t)
1246 1.1 mrg {
1247 1.1 mrg Type tn = t.nextOf().toBasetype();
1248 1.1 mrg if (tn.ty == Tsarray)
1249 1.1 mrg {
1250 1.1 mrg const dim = cast(size_t)(cast(TypeSArray)tn).dim.toInteger();
1251 1.1 mrg Type te = tn.nextOf().toBasetype();
1252 1.1 mrg foreach (ref e; *elements)
1253 1.1 mrg {
1254 1.1 mrg if (te.equals(e.type))
1255 1.1 mrg {
1256 1.1 mrg auto elements2 = new Expressions(dim);
1257 1.1 mrg foreach (ref e2; *elements2)
1258 1.1 mrg e2 = e;
1259 1.1 mrg e = new ArrayLiteralExp(e.loc, tn, elements2);
1260 1.1 mrg }
1261 1.1 mrg }
1262 1.1 mrg }
1263 1.1 mrg }
1264 1.1 mrg
1265 1.1 mrg /* If any elements are errors, then the whole thing is an error
1266 1.1 mrg */
1267 1.1 mrg foreach (e; (*elements)[0 .. edim])
1268 1.1 mrg {
1269 1.1 mrg if (e.op == EXP.error)
1270 1.1 mrg {
1271 1.1 mrg return e;
1272 1.1 mrg }
1273 1.1 mrg }
1274 1.1 mrg
1275 1.1 mrg Expression e = new ArrayLiteralExp(init.loc, init.type, elements);
1276 1.1 mrg return e;
1277 1.1 mrg }
1278 1.1 mrg
1279 1.1 mrg Expression visitExp(ExpInitializer i)
1280 1.1 mrg {
1281 1.1 mrg if (itype)
1282 1.1 mrg {
1283 1.1 mrg //printf("ExpInitializer::toExpression(t = %s) exp = %s\n", itype.toChars(), i.exp.toChars());
1284 1.1 mrg Type tb = itype.toBasetype();
1285 1.1 mrg Expression e = (i.exp.op == EXP.construct || i.exp.op == EXP.blit) ? (cast(AssignExp)i.exp).e2 : i.exp;
1286 1.1 mrg if (tb.ty == Tsarray && e.implicitConvTo(tb.nextOf()))
1287 1.1 mrg {
1288 1.1 mrg TypeSArray tsa = cast(TypeSArray)tb;
1289 1.1 mrg size_t d = cast(size_t)tsa.dim.toInteger();
1290 1.1 mrg auto elements = new Expressions(d);
1291 1.1 mrg for (size_t j = 0; j < d; j++)
1292 1.1 mrg (*elements)[j] = e;
1293 1.1 mrg auto ae = new ArrayLiteralExp(e.loc, itype, elements);
1294 1.1 mrg return ae;
1295 1.1 mrg }
1296 1.1 mrg }
1297 1.1 mrg return i.exp;
1298 1.1 mrg }
1299 1.1 mrg
1300 1.1 mrg Expression visitC(CInitializer i)
1301 1.1 mrg {
1302 1.1 mrg //printf("CInitializer.initializerToExpression(null, true)\n");
1303 1.1 mrg return null;
1304 1.1 mrg }
1305 1.1 mrg
1306 1.1 mrg final switch (init.kind)
1307 1.1 mrg {
1308 1.1 mrg case InitKind.void_: return visitVoid (init.isVoidInitializer());
1309 1.1 mrg case InitKind.error: return visitError (init.isErrorInitializer());
1310 1.1 mrg case InitKind.struct_: return visitStruct(init.isStructInitializer());
1311 1.1 mrg case InitKind.array: return visitArray (init.isArrayInitializer());
1312 1.1 mrg case InitKind.exp: return visitExp (init.isExpInitializer());
1313 1.1 mrg case InitKind.C_: return visitC (init.isCInitializer());
1314 1.1 mrg }
1315 1.1 mrg }
1316 1.1 mrg
1317 1.1 mrg
1318 1.1 mrg /**************************************
1319 1.1 mrg * Determine if expression has non-constant pointers, or more precisely,
1320 1.1 mrg * a pointer that CTFE cannot handle.
1321 1.1 mrg * Params:
1322 1.1 mrg * e = expression to check
1323 1.1 mrg * Returns:
1324 1.1 mrg * true if it has non-constant pointers
1325 1.1 mrg */
1326 1.1 mrg private bool hasNonConstPointers(Expression e)
1327 1.1 mrg {
1328 1.1 mrg static bool checkArray(Expressions* elems)
1329 1.1 mrg {
1330 1.1 mrg foreach (e; *elems)
1331 1.1 mrg {
1332 1.1 mrg if (e && hasNonConstPointers(e))
1333 1.1 mrg return true;
1334 1.1 mrg }
1335 1.1 mrg return false;
1336 1.1 mrg }
1337 1.1 mrg
1338 1.1 mrg if (e.type.ty == Terror)
1339 1.1 mrg return false;
1340 1.1 mrg if (e.op == EXP.null_)
1341 1.1 mrg return false;
1342 1.1 mrg if (auto se = e.isStructLiteralExp())
1343 1.1 mrg {
1344 1.1 mrg return checkArray(se.elements);
1345 1.1 mrg }
1346 1.1 mrg if (auto ae = e.isArrayLiteralExp())
1347 1.1 mrg {
1348 1.1 mrg if (!ae.type.nextOf().hasPointers())
1349 1.1 mrg return false;
1350 1.1 mrg return checkArray(ae.elements);
1351 1.1 mrg }
1352 1.1 mrg if (auto ae = e.isAssocArrayLiteralExp())
1353 1.1 mrg {
1354 1.1 mrg if (ae.type.nextOf().hasPointers() && checkArray(ae.values))
1355 1.1 mrg return true;
1356 1.1 mrg if (ae.type.isTypeAArray().index.hasPointers())
1357 1.1 mrg return checkArray(ae.keys);
1358 1.1 mrg return false;
1359 1.1 mrg }
1360 1.1 mrg if (auto ae = e.isAddrExp())
1361 1.1 mrg {
1362 1.1 mrg if (ae.type.nextOf().isImmutable() || ae.type.nextOf().isConst())
1363 1.1 mrg {
1364 1.1 mrg return false;
1365 1.1 mrg }
1366 1.1 mrg if (auto se = ae.e1.isStructLiteralExp())
1367 1.1 mrg {
1368 1.1 mrg if (!(se.stageflags & stageSearchPointers))
1369 1.1 mrg {
1370 1.1 mrg const old = se.stageflags;
1371 1.1 mrg se.stageflags |= stageSearchPointers;
1372 1.1 mrg bool ret = checkArray(se.elements);
1373 1.1 mrg se.stageflags = old;
1374 1.1 mrg return ret;
1375 1.1 mrg }
1376 1.1 mrg else
1377 1.1 mrg {
1378 1.1 mrg return false;
1379 1.1 mrg }
1380 1.1 mrg }
1381 1.1 mrg return true;
1382 1.1 mrg }
1383 1.1 mrg if (e.type.ty == Tpointer && !e.type.isPtrToFunction())
1384 1.1 mrg {
1385 1.1 mrg if (e.op == EXP.symbolOffset) // address of a global is OK
1386 1.1 mrg return false;
1387 1.1 mrg if (e.op == EXP.int64) // cast(void *)int is OK
1388 1.1 mrg return false;
1389 1.1 mrg if (e.op == EXP.string_) // "abc".ptr is OK
1390 1.1 mrg return false;
1391 1.1 mrg return true;
1392 1.1 mrg }
1393 1.1 mrg return false;
1394 1.1 mrg }
1395