github.com/bir3/gocompiler@v0.9.2202/src/go/types/typexpr.go (about) 1 // Copyright 2013 The Go Authors. All rights reserved. 2 // Use of this source code is governed by a BSD-style 3 // license that can be found in the LICENSE file. 4 5 // This file implements type-checking of identifiers and type expressions. 6 7 package types 8 9 import ( 10 "fmt" 11 "github.com/bir3/gocompiler/src/go/ast" 12 "github.com/bir3/gocompiler/src/go/constant" 13 "github.com/bir3/gocompiler/src/go/internal/typeparams" 14 . "github.com/bir3/gocompiler/src/internal/types/errors" 15 "strings" 16 ) 17 18 // ident type-checks identifier e and initializes x with the value or type of e. 19 // If an error occurred, x.mode is set to invalid. 20 // For the meaning of def, see Checker.definedType, below. 21 // If wantType is set, the identifier e is expected to denote a type. 22 func (check *Checker) ident(x *operand, e *ast.Ident, def *TypeName, wantType bool) { 23 x.mode = invalid 24 x.expr = e 25 26 // Note that we cannot use check.lookup here because the returned scope 27 // may be different from obj.Parent(). See also Scope.LookupParent doc. 28 scope, obj := check.scope.LookupParent(e.Name, check.pos) 29 switch obj { 30 case nil: 31 if e.Name == "_" { 32 // Blank identifiers are never declared, but the current identifier may 33 // be a placeholder for a receiver type parameter. In this case we can 34 // resolve its type and object from Checker.recvTParamMap. 35 if tpar := check.recvTParamMap[e]; tpar != nil { 36 x.mode = typexpr 37 x.typ = tpar 38 } else { 39 check.error(e, InvalidBlank, "cannot use _ as value or type") 40 } 41 } else { 42 check.errorf(e, UndeclaredName, "undefined: %s", e.Name) 43 } 44 return 45 case universeAny, universeComparable: 46 if !check.verifyVersionf(e, go1_18, "predeclared %s", e.Name) { 47 return // avoid follow-on errors 48 } 49 } 50 check.recordUse(e, obj) 51 52 // Type-check the object. 53 // Only call Checker.objDecl if the object doesn't have a type yet 54 // (in which case we must actually determine it) or the object is a 55 // TypeName and we also want a type (in which case we might detect 56 // a cycle which needs to be reported). Otherwise we can skip the 57 // call and avoid a possible cycle error in favor of the more 58 // informative "not a type/value" error that this function's caller 59 // will issue (see go.dev/issue/25790). 60 typ := obj.Type() 61 if _, gotType := obj.(*TypeName); typ == nil || gotType && wantType { 62 check.objDecl(obj, def) 63 typ = obj.Type() // type must have been assigned by Checker.objDecl 64 } 65 assert(typ != nil) 66 67 // The object may have been dot-imported. 68 // If so, mark the respective package as used. 69 // (This code is only needed for dot-imports. Without them, 70 // we only have to mark variables, see *Var case below). 71 if pkgName := check.dotImportMap[dotImportKey{scope, obj.Name()}]; pkgName != nil { 72 pkgName.used = true 73 } 74 75 switch obj := obj.(type) { 76 case *PkgName: 77 check.errorf(e, InvalidPkgUse, "use of package %s not in selector", obj.name) 78 return 79 80 case *Const: 81 check.addDeclDep(obj) 82 if !isValid(typ) { 83 return 84 } 85 if obj == universeIota { 86 if check.iota == nil { 87 check.error(e, InvalidIota, "cannot use iota outside constant declaration") 88 return 89 } 90 x.val = check.iota 91 } else { 92 x.val = obj.val 93 } 94 assert(x.val != nil) 95 x.mode = constant_ 96 97 case *TypeName: 98 if !check.enableAlias && check.isBrokenAlias(obj) { 99 check.errorf(e, InvalidDeclCycle, "invalid use of type alias %s in recursive type (see go.dev/issue/50729)", obj.name) 100 return 101 } 102 x.mode = typexpr 103 104 case *Var: 105 // It's ok to mark non-local variables, but ignore variables 106 // from other packages to avoid potential race conditions with 107 // dot-imported variables. 108 if obj.pkg == check.pkg { 109 obj.used = true 110 } 111 check.addDeclDep(obj) 112 if !isValid(typ) { 113 return 114 } 115 x.mode = variable 116 117 case *Func: 118 check.addDeclDep(obj) 119 x.mode = value 120 121 case *Builtin: 122 x.id = obj.id 123 x.mode = builtin 124 125 case *Nil: 126 x.mode = value 127 128 default: 129 unreachable() 130 } 131 132 x.typ = typ 133 } 134 135 // typ type-checks the type expression e and returns its type, or Typ[Invalid]. 136 // The type must not be an (uninstantiated) generic type. 137 func (check *Checker) typ(e ast.Expr) Type { 138 return check.definedType(e, nil) 139 } 140 141 // varType type-checks the type expression e and returns its type, or Typ[Invalid]. 142 // The type must not be an (uninstantiated) generic type and it must not be a 143 // constraint interface. 144 func (check *Checker) varType(e ast.Expr) Type { 145 typ := check.definedType(e, nil) 146 check.validVarType(e, typ) 147 return typ 148 } 149 150 // validVarType reports an error if typ is a constraint interface. 151 // The expression e is used for error reporting, if any. 152 func (check *Checker) validVarType(e ast.Expr, typ Type) { 153 // If we have a type parameter there's nothing to do. 154 if isTypeParam(typ) { 155 return 156 } 157 158 // We don't want to call under() or complete interfaces while we are in 159 // the middle of type-checking parameter declarations that might belong 160 // to interface methods. Delay this check to the end of type-checking. 161 check.later(func() { 162 if t, _ := under(typ).(*Interface); t != nil { 163 tset := computeInterfaceTypeSet(check, e.Pos(), t) // TODO(gri) is this the correct position? 164 if !tset.IsMethodSet() { 165 if tset.comparable { 166 check.softErrorf(e, MisplacedConstraintIface, "cannot use type %s outside a type constraint: interface is (or embeds) comparable", typ) 167 } else { 168 check.softErrorf(e, MisplacedConstraintIface, "cannot use type %s outside a type constraint: interface contains type constraints", typ) 169 } 170 } 171 } 172 }).describef(e, "check var type %s", typ) 173 } 174 175 // definedType is like typ but also accepts a type name def. 176 // If def != nil, e is the type specification for the type named def, declared 177 // in a type declaration, and def.typ.underlying will be set to the type of e 178 // before any components of e are type-checked. 179 func (check *Checker) definedType(e ast.Expr, def *TypeName) Type { 180 typ := check.typInternal(e, def) 181 assert(isTyped(typ)) 182 if isGeneric(typ) { 183 check.errorf(e, WrongTypeArgCount, "cannot use generic type %s without instantiation", typ) 184 typ = Typ[Invalid] 185 } 186 check.recordTypeAndValue(e, typexpr, typ, nil) 187 return typ 188 } 189 190 // genericType is like typ but the type must be an (uninstantiated) generic 191 // type. If cause is non-nil and the type expression was a valid type but not 192 // generic, cause will be populated with a message describing the error. 193 func (check *Checker) genericType(e ast.Expr, cause *string) Type { 194 typ := check.typInternal(e, nil) 195 assert(isTyped(typ)) 196 if isValid(typ) && !isGeneric(typ) { 197 if cause != nil { 198 *cause = check.sprintf("%s is not a generic type", typ) 199 } 200 typ = Typ[Invalid] 201 } 202 // TODO(gri) what is the correct call below? 203 check.recordTypeAndValue(e, typexpr, typ, nil) 204 return typ 205 } 206 207 // goTypeName returns the Go type name for typ and 208 // removes any occurrences of "types." from that name. 209 func goTypeName(typ Type) string { 210 return strings.ReplaceAll(fmt.Sprintf("%T", typ), "types.", "") 211 } 212 213 // typInternal drives type checking of types. 214 // Must only be called by definedType or genericType. 215 func (check *Checker) typInternal(e0 ast.Expr, def *TypeName) (T Type) { 216 if check.conf._Trace { 217 check.trace(e0.Pos(), "-- type %s", e0) 218 check.indent++ 219 defer func() { 220 check.indent-- 221 var under Type 222 if T != nil { 223 // Calling under() here may lead to endless instantiations. 224 // Test case: type T[P any] *T[P] 225 under = safeUnderlying(T) 226 } 227 if T == under { 228 check.trace(e0.Pos(), "=> %s // %s", T, goTypeName(T)) 229 } else { 230 check.trace(e0.Pos(), "=> %s (under = %s) // %s", T, under, goTypeName(T)) 231 } 232 }() 233 } 234 235 switch e := e0.(type) { 236 case *ast.BadExpr: 237 // ignore - error reported before 238 239 case *ast.Ident: 240 var x operand 241 check.ident(&x, e, def, true) 242 243 switch x.mode { 244 case typexpr: 245 typ := x.typ 246 setDefType(def, typ) 247 return typ 248 case invalid: 249 // ignore - error reported before 250 case novalue: 251 check.errorf(&x, NotAType, "%s used as type", &x) 252 default: 253 check.errorf(&x, NotAType, "%s is not a type", &x) 254 } 255 256 case *ast.SelectorExpr: 257 var x operand 258 check.selector(&x, e, def, true) 259 260 switch x.mode { 261 case typexpr: 262 typ := x.typ 263 setDefType(def, typ) 264 return typ 265 case invalid: 266 // ignore - error reported before 267 case novalue: 268 check.errorf(&x, NotAType, "%s used as type", &x) 269 default: 270 check.errorf(&x, NotAType, "%s is not a type", &x) 271 } 272 273 case *ast.IndexExpr, *ast.IndexListExpr: 274 ix := typeparams.UnpackIndexExpr(e) 275 check.verifyVersionf(inNode(e, ix.Lbrack), go1_18, "type instantiation") 276 return check.instantiatedType(ix, def) 277 278 case *ast.ParenExpr: 279 // Generic types must be instantiated before they can be used in any form. 280 // Consequently, generic types cannot be parenthesized. 281 return check.definedType(e.X, def) 282 283 case *ast.ArrayType: 284 if e.Len == nil { 285 typ := new(Slice) 286 setDefType(def, typ) 287 typ.elem = check.varType(e.Elt) 288 return typ 289 } 290 291 typ := new(Array) 292 setDefType(def, typ) 293 // Provide a more specific error when encountering a [...] array 294 // rather than leaving it to the handling of the ... expression. 295 if _, ok := e.Len.(*ast.Ellipsis); ok { 296 check.error(e.Len, BadDotDotDotSyntax, "invalid use of [...] array (outside a composite literal)") 297 typ.len = -1 298 } else { 299 typ.len = check.arrayLength(e.Len) 300 } 301 typ.elem = check.varType(e.Elt) 302 if typ.len >= 0 { 303 return typ 304 } 305 // report error if we encountered [...] 306 307 case *ast.Ellipsis: 308 // dots are handled explicitly where they are legal 309 // (array composite literals and parameter lists) 310 check.error(e, InvalidDotDotDot, "invalid use of '...'") 311 check.use(e.Elt) 312 313 case *ast.StructType: 314 typ := new(Struct) 315 setDefType(def, typ) 316 check.structType(typ, e) 317 return typ 318 319 case *ast.StarExpr: 320 typ := new(Pointer) 321 typ.base = Typ[Invalid] // avoid nil base in invalid recursive type declaration 322 setDefType(def, typ) 323 typ.base = check.varType(e.X) 324 return typ 325 326 case *ast.FuncType: 327 typ := new(Signature) 328 setDefType(def, typ) 329 check.funcType(typ, nil, e) 330 return typ 331 332 case *ast.InterfaceType: 333 typ := check.newInterface() 334 setDefType(def, typ) 335 check.interfaceType(typ, e, def) 336 return typ 337 338 case *ast.MapType: 339 typ := new(Map) 340 setDefType(def, typ) 341 342 typ.key = check.varType(e.Key) 343 typ.elem = check.varType(e.Value) 344 345 // spec: "The comparison operators == and != must be fully defined 346 // for operands of the key type; thus the key type must not be a 347 // function, map, or slice." 348 // 349 // Delay this check because it requires fully setup types; 350 // it is safe to continue in any case (was go.dev/issue/6667). 351 check.later(func() { 352 if !Comparable(typ.key) { 353 var why string 354 if isTypeParam(typ.key) { 355 why = " (missing comparable constraint)" 356 } 357 check.errorf(e.Key, IncomparableMapKey, "invalid map key type %s%s", typ.key, why) 358 } 359 }).describef(e.Key, "check map key %s", typ.key) 360 361 return typ 362 363 case *ast.ChanType: 364 typ := new(Chan) 365 setDefType(def, typ) 366 367 dir := SendRecv 368 switch e.Dir { 369 case ast.SEND | ast.RECV: 370 // nothing to do 371 case ast.SEND: 372 dir = SendOnly 373 case ast.RECV: 374 dir = RecvOnly 375 default: 376 check.errorf(e, InvalidSyntaxTree, "unknown channel direction %d", e.Dir) 377 // ok to continue 378 } 379 380 typ.dir = dir 381 typ.elem = check.varType(e.Value) 382 return typ 383 384 default: 385 check.errorf(e0, NotAType, "%s is not a type", e0) 386 check.use(e0) 387 } 388 389 typ := Typ[Invalid] 390 setDefType(def, typ) 391 return typ 392 } 393 394 func setDefType(def *TypeName, typ Type) { 395 if def != nil { 396 switch t := def.typ.(type) { 397 case *Alias: 398 // t.fromRHS should always be set, either to an invalid type 399 // in the beginning, or to typ in certain cyclic declarations. 400 if t.fromRHS != Typ[Invalid] && t.fromRHS != typ { 401 panic(sprintf(nil, nil, true, "t.fromRHS = %s, typ = %s\n", t.fromRHS, typ)) 402 } 403 t.fromRHS = typ 404 case *Basic: 405 assert(t == Typ[Invalid]) 406 case *Named: 407 t.underlying = typ 408 default: 409 panic(fmt.Sprintf("unexpected type %T", t)) 410 } 411 } 412 } 413 414 func (check *Checker) instantiatedType(ix *typeparams.IndexExpr, def *TypeName) (res Type) { 415 if check.conf._Trace { 416 check.trace(ix.Pos(), "-- instantiating type %s with %s", ix.X, ix.Indices) 417 check.indent++ 418 defer func() { 419 check.indent-- 420 // Don't format the underlying here. It will always be nil. 421 check.trace(ix.Pos(), "=> %s", res) 422 }() 423 } 424 425 var cause string 426 gtyp := check.genericType(ix.X, &cause) 427 if cause != "" { 428 check.errorf(ix.Orig, NotAGenericType, invalidOp+"%s (%s)", ix.Orig, cause) 429 } 430 if !isValid(gtyp) { 431 return gtyp // error already reported 432 } 433 434 orig := asNamed(gtyp) 435 if orig == nil { 436 panic(fmt.Sprintf("%v: cannot instantiate %v", ix.Pos(), gtyp)) 437 } 438 439 // evaluate arguments 440 targs := check.typeList(ix.Indices) 441 if targs == nil { 442 setDefType(def, Typ[Invalid]) // avoid errors later due to lazy instantiation 443 return Typ[Invalid] 444 } 445 446 // create the instance 447 inst := asNamed(check.instance(ix.Pos(), orig, targs, nil, check.context())) 448 setDefType(def, inst) 449 450 // orig.tparams may not be set up, so we need to do expansion later. 451 check.later(func() { 452 // This is an instance from the source, not from recursive substitution, 453 // and so it must be resolved during type-checking so that we can report 454 // errors. 455 check.recordInstance(ix.Orig, inst.TypeArgs().list(), inst) 456 457 if check.validateTArgLen(ix.Pos(), inst.obj.name, inst.TypeParams().Len(), inst.TypeArgs().Len()) { 458 if i, err := check.verify(ix.Pos(), inst.TypeParams().list(), inst.TypeArgs().list(), check.context()); err != nil { 459 // best position for error reporting 460 pos := ix.Pos() 461 if i < len(ix.Indices) { 462 pos = ix.Indices[i].Pos() 463 } 464 check.softErrorf(atPos(pos), InvalidTypeArg, err.Error()) 465 } else { 466 check.mono.recordInstance(check.pkg, ix.Pos(), inst.TypeParams().list(), inst.TypeArgs().list(), ix.Indices) 467 } 468 } 469 470 // TODO(rfindley): remove this call: we don't need to call validType here, 471 // as cycles can only occur for types used inside a Named type declaration, 472 // and so it suffices to call validType from declared types. 473 check.validType(inst) 474 }).describef(ix, "resolve instance %s", inst) 475 476 return inst 477 } 478 479 // arrayLength type-checks the array length expression e 480 // and returns the constant length >= 0, or a value < 0 481 // to indicate an error (and thus an unknown length). 482 func (check *Checker) arrayLength(e ast.Expr) int64 { 483 // If e is an identifier, the array declaration might be an 484 // attempt at a parameterized type declaration with missing 485 // constraint. Provide an error message that mentions array 486 // length. 487 if name, _ := e.(*ast.Ident); name != nil { 488 obj := check.lookup(name.Name) 489 if obj == nil { 490 check.errorf(name, InvalidArrayLen, "undefined array length %s or missing type constraint", name.Name) 491 return -1 492 } 493 if _, ok := obj.(*Const); !ok { 494 check.errorf(name, InvalidArrayLen, "invalid array length %s", name.Name) 495 return -1 496 } 497 } 498 499 var x operand 500 check.expr(nil, &x, e) 501 if x.mode != constant_ { 502 if x.mode != invalid { 503 check.errorf(&x, InvalidArrayLen, "array length %s must be constant", &x) 504 } 505 return -1 506 } 507 508 if isUntyped(x.typ) || isInteger(x.typ) { 509 if val := constant.ToInt(x.val); val.Kind() == constant.Int { 510 if representableConst(val, check, Typ[Int], nil) { 511 if n, ok := constant.Int64Val(val); ok && n >= 0 { 512 return n 513 } 514 } 515 } 516 } 517 518 var msg string 519 if isInteger(x.typ) { 520 msg = "invalid array length %s" 521 } else { 522 msg = "array length %s must be integer" 523 } 524 check.errorf(&x, InvalidArrayLen, msg, &x) 525 return -1 526 } 527 528 // typeList provides the list of types corresponding to the incoming expression list. 529 // If an error occurred, the result is nil, but all list elements were type-checked. 530 func (check *Checker) typeList(list []ast.Expr) []Type { 531 res := make([]Type, len(list)) // res != nil even if len(list) == 0 532 for i, x := range list { 533 t := check.varType(x) 534 if !isValid(t) { 535 res = nil 536 } 537 if res != nil { 538 res[i] = t 539 } 540 } 541 return res 542 }