github.com/c9s/go@v0.0.0-20180120015821-984e81f64e0c/src/reflect/value.go (about) 1 // Copyright 2009 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 package reflect 6 7 import ( 8 "math" 9 "runtime" 10 "unsafe" 11 ) 12 13 const ptrSize = 4 << (^uintptr(0) >> 63) // unsafe.Sizeof(uintptr(0)) but an ideal const 14 15 // Value is the reflection interface to a Go value. 16 // 17 // Not all methods apply to all kinds of values. Restrictions, 18 // if any, are noted in the documentation for each method. 19 // Use the Kind method to find out the kind of value before 20 // calling kind-specific methods. Calling a method 21 // inappropriate to the kind of type causes a run time panic. 22 // 23 // The zero Value represents no value. 24 // Its IsValid method returns false, its Kind method returns Invalid, 25 // its String method returns "<invalid Value>", and all other methods panic. 26 // Most functions and methods never return an invalid value. 27 // If one does, its documentation states the conditions explicitly. 28 // 29 // A Value can be used concurrently by multiple goroutines provided that 30 // the underlying Go value can be used concurrently for the equivalent 31 // direct operations. 32 // 33 // To compare two Values, compare the results of the Interface method. 34 // Using == on two Values does not compare the underlying values 35 // they represent. 36 type Value struct { 37 // typ holds the type of the value represented by a Value. 38 typ *rtype 39 40 // Pointer-valued data or, if flagIndir is set, pointer to data. 41 // Valid when either flagIndir is set or typ.pointers() is true. 42 ptr unsafe.Pointer 43 44 // flag holds metadata about the value. 45 // The lowest bits are flag bits: 46 // - flagStickyRO: obtained via unexported not embedded field, so read-only 47 // - flagEmbedRO: obtained via unexported embedded field, so read-only 48 // - flagIndir: val holds a pointer to the data 49 // - flagAddr: v.CanAddr is true (implies flagIndir) 50 // - flagMethod: v is a method value. 51 // The next five bits give the Kind of the value. 52 // This repeats typ.Kind() except for method values. 53 // The remaining 23+ bits give a method number for method values. 54 // If flag.kind() != Func, code can assume that flagMethod is unset. 55 // If ifaceIndir(typ), code can assume that flagIndir is set. 56 flag 57 58 // A method value represents a curried method invocation 59 // like r.Read for some receiver r. The typ+val+flag bits describe 60 // the receiver r, but the flag's Kind bits say Func (methods are 61 // functions), and the top bits of the flag give the method number 62 // in r's type's method table. 63 } 64 65 type flag uintptr 66 67 const ( 68 flagKindWidth = 5 // there are 27 kinds 69 flagKindMask flag = 1<<flagKindWidth - 1 70 flagStickyRO flag = 1 << 5 71 flagEmbedRO flag = 1 << 6 72 flagIndir flag = 1 << 7 73 flagAddr flag = 1 << 8 74 flagMethod flag = 1 << 9 75 flagMethodShift = 10 76 flagRO flag = flagStickyRO | flagEmbedRO 77 ) 78 79 func (f flag) kind() Kind { 80 return Kind(f & flagKindMask) 81 } 82 83 func (f flag) ro() flag { 84 if f&flagRO != 0 { 85 return flagStickyRO 86 } 87 return 0 88 } 89 90 // pointer returns the underlying pointer represented by v. 91 // v.Kind() must be Ptr, Map, Chan, Func, or UnsafePointer 92 func (v Value) pointer() unsafe.Pointer { 93 if v.typ.size != ptrSize || !v.typ.pointers() { 94 panic("can't call pointer on a non-pointer Value") 95 } 96 if v.flag&flagIndir != 0 { 97 return *(*unsafe.Pointer)(v.ptr) 98 } 99 return v.ptr 100 } 101 102 // packEface converts v to the empty interface. 103 func packEface(v Value) interface{} { 104 t := v.typ 105 var i interface{} 106 e := (*emptyInterface)(unsafe.Pointer(&i)) 107 // First, fill in the data portion of the interface. 108 switch { 109 case ifaceIndir(t): 110 if v.flag&flagIndir == 0 { 111 panic("bad indir") 112 } 113 // Value is indirect, and so is the interface we're making. 114 ptr := v.ptr 115 if v.flag&flagAddr != 0 { 116 // TODO: pass safe boolean from valueInterface so 117 // we don't need to copy if safe==true? 118 c := unsafe_New(t) 119 typedmemmove(t, c, ptr) 120 ptr = c 121 } 122 e.word = ptr 123 case v.flag&flagIndir != 0: 124 // Value is indirect, but interface is direct. We need 125 // to load the data at v.ptr into the interface data word. 126 e.word = *(*unsafe.Pointer)(v.ptr) 127 default: 128 // Value is direct, and so is the interface. 129 e.word = v.ptr 130 } 131 // Now, fill in the type portion. We're very careful here not 132 // to have any operation between the e.word and e.typ assignments 133 // that would let the garbage collector observe the partially-built 134 // interface value. 135 e.typ = t 136 return i 137 } 138 139 // unpackEface converts the empty interface i to a Value. 140 func unpackEface(i interface{}) Value { 141 e := (*emptyInterface)(unsafe.Pointer(&i)) 142 // NOTE: don't read e.word until we know whether it is really a pointer or not. 143 t := e.typ 144 if t == nil { 145 return Value{} 146 } 147 f := flag(t.Kind()) 148 if ifaceIndir(t) { 149 f |= flagIndir 150 } 151 return Value{t, e.word, f} 152 } 153 154 // A ValueError occurs when a Value method is invoked on 155 // a Value that does not support it. Such cases are documented 156 // in the description of each method. 157 type ValueError struct { 158 Method string 159 Kind Kind 160 } 161 162 func (e *ValueError) Error() string { 163 if e.Kind == 0 { 164 return "reflect: call of " + e.Method + " on zero Value" 165 } 166 return "reflect: call of " + e.Method + " on " + e.Kind.String() + " Value" 167 } 168 169 // methodName returns the name of the calling method, 170 // assumed to be two stack frames above. 171 func methodName() string { 172 pc, _, _, _ := runtime.Caller(2) 173 f := runtime.FuncForPC(pc) 174 if f == nil { 175 return "unknown method" 176 } 177 return f.Name() 178 } 179 180 // emptyInterface is the header for an interface{} value. 181 type emptyInterface struct { 182 typ *rtype 183 word unsafe.Pointer 184 } 185 186 // nonEmptyInterface is the header for an interface value with methods. 187 type nonEmptyInterface struct { 188 // see ../runtime/iface.go:/Itab 189 itab *struct { 190 ityp *rtype // static interface type 191 typ *rtype // dynamic concrete type 192 hash uint32 // copy of typ.hash 193 _ [4]byte 194 fun [100000]unsafe.Pointer // method table 195 } 196 word unsafe.Pointer 197 } 198 199 // mustBe panics if f's kind is not expected. 200 // Making this a method on flag instead of on Value 201 // (and embedding flag in Value) means that we can write 202 // the very clear v.mustBe(Bool) and have it compile into 203 // v.flag.mustBe(Bool), which will only bother to copy the 204 // single important word for the receiver. 205 func (f flag) mustBe(expected Kind) { 206 if f.kind() != expected { 207 panic(&ValueError{methodName(), f.kind()}) 208 } 209 } 210 211 // mustBeExported panics if f records that the value was obtained using 212 // an unexported field. 213 func (f flag) mustBeExported() { 214 if f == 0 { 215 panic(&ValueError{methodName(), 0}) 216 } 217 if f&flagRO != 0 { 218 panic("reflect: " + methodName() + " using value obtained using unexported field") 219 } 220 } 221 222 // mustBeAssignable panics if f records that the value is not assignable, 223 // which is to say that either it was obtained using an unexported field 224 // or it is not addressable. 225 func (f flag) mustBeAssignable() { 226 if f == 0 { 227 panic(&ValueError{methodName(), Invalid}) 228 } 229 // Assignable if addressable and not read-only. 230 if f&flagRO != 0 { 231 panic("reflect: " + methodName() + " using value obtained using unexported field") 232 } 233 if f&flagAddr == 0 { 234 panic("reflect: " + methodName() + " using unaddressable value") 235 } 236 } 237 238 // Addr returns a pointer value representing the address of v. 239 // It panics if CanAddr() returns false. 240 // Addr is typically used to obtain a pointer to a struct field 241 // or slice element in order to call a method that requires a 242 // pointer receiver. 243 func (v Value) Addr() Value { 244 if v.flag&flagAddr == 0 { 245 panic("reflect.Value.Addr of unaddressable value") 246 } 247 return Value{v.typ.ptrTo(), v.ptr, v.flag.ro() | flag(Ptr)} 248 } 249 250 // Bool returns v's underlying value. 251 // It panics if v's kind is not Bool. 252 func (v Value) Bool() bool { 253 v.mustBe(Bool) 254 return *(*bool)(v.ptr) 255 } 256 257 // Bytes returns v's underlying value. 258 // It panics if v's underlying value is not a slice of bytes. 259 func (v Value) Bytes() []byte { 260 v.mustBe(Slice) 261 if v.typ.Elem().Kind() != Uint8 { 262 panic("reflect.Value.Bytes of non-byte slice") 263 } 264 // Slice is always bigger than a word; assume flagIndir. 265 return *(*[]byte)(v.ptr) 266 } 267 268 // runes returns v's underlying value. 269 // It panics if v's underlying value is not a slice of runes (int32s). 270 func (v Value) runes() []rune { 271 v.mustBe(Slice) 272 if v.typ.Elem().Kind() != Int32 { 273 panic("reflect.Value.Bytes of non-rune slice") 274 } 275 // Slice is always bigger than a word; assume flagIndir. 276 return *(*[]rune)(v.ptr) 277 } 278 279 // CanAddr reports whether the value's address can be obtained with Addr. 280 // Such values are called addressable. A value is addressable if it is 281 // an element of a slice, an element of an addressable array, 282 // a field of an addressable struct, or the result of dereferencing a pointer. 283 // If CanAddr returns false, calling Addr will panic. 284 func (v Value) CanAddr() bool { 285 return v.flag&flagAddr != 0 286 } 287 288 // CanSet reports whether the value of v can be changed. 289 // A Value can be changed only if it is addressable and was not 290 // obtained by the use of unexported struct fields. 291 // If CanSet returns false, calling Set or any type-specific 292 // setter (e.g., SetBool, SetInt) will panic. 293 func (v Value) CanSet() bool { 294 return v.flag&(flagAddr|flagRO) == flagAddr 295 } 296 297 // Call calls the function v with the input arguments in. 298 // For example, if len(in) == 3, v.Call(in) represents the Go call v(in[0], in[1], in[2]). 299 // Call panics if v's Kind is not Func. 300 // It returns the output results as Values. 301 // As in Go, each input argument must be assignable to the 302 // type of the function's corresponding input parameter. 303 // If v is a variadic function, Call creates the variadic slice parameter 304 // itself, copying in the corresponding values. 305 func (v Value) Call(in []Value) []Value { 306 v.mustBe(Func) 307 v.mustBeExported() 308 return v.call("Call", in) 309 } 310 311 // CallSlice calls the variadic function v with the input arguments in, 312 // assigning the slice in[len(in)-1] to v's final variadic argument. 313 // For example, if len(in) == 3, v.CallSlice(in) represents the Go call v(in[0], in[1], in[2]...). 314 // CallSlice panics if v's Kind is not Func or if v is not variadic. 315 // It returns the output results as Values. 316 // As in Go, each input argument must be assignable to the 317 // type of the function's corresponding input parameter. 318 func (v Value) CallSlice(in []Value) []Value { 319 v.mustBe(Func) 320 v.mustBeExported() 321 return v.call("CallSlice", in) 322 } 323 324 var callGC bool // for testing; see TestCallMethodJump 325 326 func (v Value) call(op string, in []Value) []Value { 327 // Get function pointer, type. 328 t := v.typ 329 var ( 330 fn unsafe.Pointer 331 rcvr Value 332 rcvrtype *rtype 333 ) 334 if v.flag&flagMethod != 0 { 335 rcvr = v 336 rcvrtype, t, fn = methodReceiver(op, v, int(v.flag)>>flagMethodShift) 337 } else if v.flag&flagIndir != 0 { 338 fn = *(*unsafe.Pointer)(v.ptr) 339 } else { 340 fn = v.ptr 341 } 342 343 if fn == nil { 344 panic("reflect.Value.Call: call of nil function") 345 } 346 347 isSlice := op == "CallSlice" 348 n := t.NumIn() 349 if isSlice { 350 if !t.IsVariadic() { 351 panic("reflect: CallSlice of non-variadic function") 352 } 353 if len(in) < n { 354 panic("reflect: CallSlice with too few input arguments") 355 } 356 if len(in) > n { 357 panic("reflect: CallSlice with too many input arguments") 358 } 359 } else { 360 if t.IsVariadic() { 361 n-- 362 } 363 if len(in) < n { 364 panic("reflect: Call with too few input arguments") 365 } 366 if !t.IsVariadic() && len(in) > n { 367 panic("reflect: Call with too many input arguments") 368 } 369 } 370 for _, x := range in { 371 if x.Kind() == Invalid { 372 panic("reflect: " + op + " using zero Value argument") 373 } 374 } 375 for i := 0; i < n; i++ { 376 if xt, targ := in[i].Type(), t.In(i); !xt.AssignableTo(targ) { 377 panic("reflect: " + op + " using " + xt.String() + " as type " + targ.String()) 378 } 379 } 380 if !isSlice && t.IsVariadic() { 381 // prepare slice for remaining values 382 m := len(in) - n 383 slice := MakeSlice(t.In(n), m, m) 384 elem := t.In(n).Elem() 385 for i := 0; i < m; i++ { 386 x := in[n+i] 387 if xt := x.Type(); !xt.AssignableTo(elem) { 388 panic("reflect: cannot use " + xt.String() + " as type " + elem.String() + " in " + op) 389 } 390 slice.Index(i).Set(x) 391 } 392 origIn := in 393 in = make([]Value, n+1) 394 copy(in[:n], origIn) 395 in[n] = slice 396 } 397 398 nin := len(in) 399 if nin != t.NumIn() { 400 panic("reflect.Value.Call: wrong argument count") 401 } 402 nout := t.NumOut() 403 404 // Compute frame type. 405 frametype, _, retOffset, _, framePool := funcLayout(t, rcvrtype) 406 407 // Allocate a chunk of memory for frame. 408 var args unsafe.Pointer 409 if nout == 0 { 410 args = framePool.Get().(unsafe.Pointer) 411 } else { 412 // Can't use pool if the function has return values. 413 // We will leak pointer to args in ret, so its lifetime is not scoped. 414 args = unsafe_New(frametype) 415 } 416 off := uintptr(0) 417 418 // Copy inputs into args. 419 if rcvrtype != nil { 420 storeRcvr(rcvr, args) 421 off = ptrSize 422 } 423 for i, v := range in { 424 v.mustBeExported() 425 targ := t.In(i).(*rtype) 426 a := uintptr(targ.align) 427 off = (off + a - 1) &^ (a - 1) 428 n := targ.size 429 if n == 0 { 430 // Not safe to compute args+off pointing at 0 bytes, 431 // because that might point beyond the end of the frame, 432 // but we still need to call assignTo to check assignability. 433 v.assignTo("reflect.Value.Call", targ, nil) 434 continue 435 } 436 addr := add(args, off, "n > 0") 437 v = v.assignTo("reflect.Value.Call", targ, addr) 438 if v.flag&flagIndir != 0 { 439 typedmemmove(targ, addr, v.ptr) 440 } else { 441 *(*unsafe.Pointer)(addr) = v.ptr 442 } 443 off += n 444 } 445 446 // Call. 447 call(frametype, fn, args, uint32(frametype.size), uint32(retOffset)) 448 449 // For testing; see TestCallMethodJump. 450 if callGC { 451 runtime.GC() 452 } 453 454 var ret []Value 455 if nout == 0 { 456 // This is untyped because the frame is really a 457 // stack, even though it's a heap object. 458 memclrNoHeapPointers(args, frametype.size) 459 framePool.Put(args) 460 } else { 461 // Zero the now unused input area of args, 462 // because the Values returned by this function contain pointers to the args object, 463 // and will thus keep the args object alive indefinitely. 464 memclrNoHeapPointers(args, retOffset) 465 // Wrap Values around return values in args. 466 ret = make([]Value, nout) 467 off = retOffset 468 for i := 0; i < nout; i++ { 469 tv := t.Out(i) 470 a := uintptr(tv.Align()) 471 off = (off + a - 1) &^ (a - 1) 472 if tv.Size() != 0 { 473 fl := flagIndir | flag(tv.Kind()) 474 ret[i] = Value{tv.common(), add(args, off, "tv.Size() != 0"), fl} 475 } else { 476 // For zero-sized return value, args+off may point to the next object. 477 // In this case, return the zero value instead. 478 ret[i] = Zero(tv) 479 } 480 off += tv.Size() 481 } 482 } 483 484 return ret 485 } 486 487 // callReflect is the call implementation used by a function 488 // returned by MakeFunc. In many ways it is the opposite of the 489 // method Value.call above. The method above converts a call using Values 490 // into a call of a function with a concrete argument frame, while 491 // callReflect converts a call of a function with a concrete argument 492 // frame into a call using Values. 493 // It is in this file so that it can be next to the call method above. 494 // The remainder of the MakeFunc implementation is in makefunc.go. 495 // 496 // NOTE: This function must be marked as a "wrapper" in the generated code, 497 // so that the linker can make it work correctly for panic and recover. 498 // The gc compilers know to do that for the name "reflect.callReflect". 499 func callReflect(ctxt *makeFuncImpl, frame unsafe.Pointer) { 500 ftyp := ctxt.typ 501 f := ctxt.fn 502 503 // Copy argument frame into Values. 504 ptr := frame 505 off := uintptr(0) 506 in := make([]Value, 0, int(ftyp.inCount)) 507 for _, typ := range ftyp.in() { 508 off += -off & uintptr(typ.align-1) 509 v := Value{typ, nil, flag(typ.Kind())} 510 if ifaceIndir(typ) { 511 // value cannot be inlined in interface data. 512 // Must make a copy, because f might keep a reference to it, 513 // and we cannot let f keep a reference to the stack frame 514 // after this function returns, not even a read-only reference. 515 v.ptr = unsafe_New(typ) 516 if typ.size > 0 { 517 typedmemmove(typ, v.ptr, add(ptr, off, "typ.size > 0")) 518 } 519 v.flag |= flagIndir 520 } else { 521 v.ptr = *(*unsafe.Pointer)(add(ptr, off, "1-ptr")) 522 } 523 in = append(in, v) 524 off += typ.size 525 } 526 527 // Call underlying function. 528 out := f(in) 529 numOut := ftyp.NumOut() 530 if len(out) != numOut { 531 panic("reflect: wrong return count from function created by MakeFunc") 532 } 533 534 // Copy results back into argument frame. 535 if numOut > 0 { 536 off += -off & (ptrSize - 1) 537 if runtime.GOARCH == "amd64p32" { 538 off = align(off, 8) 539 } 540 for i, typ := range ftyp.out() { 541 v := out[i] 542 if v.typ != typ { 543 panic("reflect: function created by MakeFunc using " + funcName(f) + 544 " returned wrong type: have " + 545 out[i].typ.String() + " for " + typ.String()) 546 } 547 if v.flag&flagRO != 0 { 548 panic("reflect: function created by MakeFunc using " + funcName(f) + 549 " returned value obtained from unexported field") 550 } 551 off += -off & uintptr(typ.align-1) 552 if typ.size == 0 { 553 continue 554 } 555 addr := add(ptr, off, "typ.size > 0") 556 if v.flag&flagIndir != 0 { 557 typedmemmove(typ, addr, v.ptr) 558 } else { 559 *(*unsafe.Pointer)(addr) = v.ptr 560 } 561 off += typ.size 562 } 563 } 564 565 // runtime.getArgInfo expects to be able to find ctxt on the 566 // stack when it finds our caller, makeFuncStub. Make sure it 567 // doesn't get garbage collected. 568 runtime.KeepAlive(ctxt) 569 } 570 571 // methodReceiver returns information about the receiver 572 // described by v. The Value v may or may not have the 573 // flagMethod bit set, so the kind cached in v.flag should 574 // not be used. 575 // The return value rcvrtype gives the method's actual receiver type. 576 // The return value t gives the method type signature (without the receiver). 577 // The return value fn is a pointer to the method code. 578 func methodReceiver(op string, v Value, methodIndex int) (rcvrtype, t *rtype, fn unsafe.Pointer) { 579 i := methodIndex 580 if v.typ.Kind() == Interface { 581 tt := (*interfaceType)(unsafe.Pointer(v.typ)) 582 if uint(i) >= uint(len(tt.methods)) { 583 panic("reflect: internal error: invalid method index") 584 } 585 m := &tt.methods[i] 586 if !tt.nameOff(m.name).isExported() { 587 panic("reflect: " + op + " of unexported method") 588 } 589 iface := (*nonEmptyInterface)(v.ptr) 590 if iface.itab == nil { 591 panic("reflect: " + op + " of method on nil interface value") 592 } 593 rcvrtype = iface.itab.typ 594 fn = unsafe.Pointer(&iface.itab.fun[i]) 595 t = tt.typeOff(m.typ) 596 } else { 597 rcvrtype = v.typ 598 ms := v.typ.exportedMethods() 599 if uint(i) >= uint(len(ms)) { 600 panic("reflect: internal error: invalid method index") 601 } 602 m := ms[i] 603 if !v.typ.nameOff(m.name).isExported() { 604 panic("reflect: " + op + " of unexported method") 605 } 606 ifn := v.typ.textOff(m.ifn) 607 fn = unsafe.Pointer(&ifn) 608 t = v.typ.typeOff(m.mtyp) 609 } 610 return 611 } 612 613 // v is a method receiver. Store at p the word which is used to 614 // encode that receiver at the start of the argument list. 615 // Reflect uses the "interface" calling convention for 616 // methods, which always uses one word to record the receiver. 617 func storeRcvr(v Value, p unsafe.Pointer) { 618 t := v.typ 619 if t.Kind() == Interface { 620 // the interface data word becomes the receiver word 621 iface := (*nonEmptyInterface)(v.ptr) 622 *(*unsafe.Pointer)(p) = iface.word 623 } else if v.flag&flagIndir != 0 && !ifaceIndir(t) { 624 *(*unsafe.Pointer)(p) = *(*unsafe.Pointer)(v.ptr) 625 } else { 626 *(*unsafe.Pointer)(p) = v.ptr 627 } 628 } 629 630 // align returns the result of rounding x up to a multiple of n. 631 // n must be a power of two. 632 func align(x, n uintptr) uintptr { 633 return (x + n - 1) &^ (n - 1) 634 } 635 636 // callMethod is the call implementation used by a function returned 637 // by makeMethodValue (used by v.Method(i).Interface()). 638 // It is a streamlined version of the usual reflect call: the caller has 639 // already laid out the argument frame for us, so we don't have 640 // to deal with individual Values for each argument. 641 // It is in this file so that it can be next to the two similar functions above. 642 // The remainder of the makeMethodValue implementation is in makefunc.go. 643 // 644 // NOTE: This function must be marked as a "wrapper" in the generated code, 645 // so that the linker can make it work correctly for panic and recover. 646 // The gc compilers know to do that for the name "reflect.callMethod". 647 func callMethod(ctxt *methodValue, frame unsafe.Pointer) { 648 rcvr := ctxt.rcvr 649 rcvrtype, t, fn := methodReceiver("call", rcvr, ctxt.method) 650 frametype, argSize, retOffset, _, framePool := funcLayout(t, rcvrtype) 651 652 // Make a new frame that is one word bigger so we can store the receiver. 653 args := framePool.Get().(unsafe.Pointer) 654 655 // Copy in receiver and rest of args. 656 // Avoid constructing out-of-bounds pointers if there are no args. 657 storeRcvr(rcvr, args) 658 if argSize-ptrSize > 0 { 659 typedmemmovepartial(frametype, add(args, ptrSize, "argSize > ptrSize"), frame, ptrSize, argSize-ptrSize) 660 } 661 662 // Call. 663 call(frametype, fn, args, uint32(frametype.size), uint32(retOffset)) 664 665 // Copy return values. On amd64p32, the beginning of return values 666 // is 64-bit aligned, so the caller's frame layout (which doesn't have 667 // a receiver) is different from the layout of the fn call, which has 668 // a receiver. 669 // Ignore any changes to args and just copy return values. 670 // Avoid constructing out-of-bounds pointers if there are no return values. 671 if frametype.size-retOffset > 0 { 672 callerRetOffset := retOffset - ptrSize 673 if runtime.GOARCH == "amd64p32" { 674 callerRetOffset = align(argSize-ptrSize, 8) 675 } 676 typedmemmovepartial(frametype, 677 add(frame, callerRetOffset, "frametype.size > retOffset"), 678 add(args, retOffset, "frametype.size > retOffset"), 679 retOffset, 680 frametype.size-retOffset) 681 } 682 683 // This is untyped because the frame is really a stack, even 684 // though it's a heap object. 685 memclrNoHeapPointers(args, frametype.size) 686 framePool.Put(args) 687 688 // See the comment in callReflect. 689 runtime.KeepAlive(ctxt) 690 } 691 692 // funcName returns the name of f, for use in error messages. 693 func funcName(f func([]Value) []Value) string { 694 pc := *(*uintptr)(unsafe.Pointer(&f)) 695 rf := runtime.FuncForPC(pc) 696 if rf != nil { 697 return rf.Name() 698 } 699 return "closure" 700 } 701 702 // Cap returns v's capacity. 703 // It panics if v's Kind is not Array, Chan, or Slice. 704 func (v Value) Cap() int { 705 k := v.kind() 706 switch k { 707 case Array: 708 return v.typ.Len() 709 case Chan: 710 return chancap(v.pointer()) 711 case Slice: 712 // Slice is always bigger than a word; assume flagIndir. 713 return (*sliceHeader)(v.ptr).Cap 714 } 715 panic(&ValueError{"reflect.Value.Cap", v.kind()}) 716 } 717 718 // Close closes the channel v. 719 // It panics if v's Kind is not Chan. 720 func (v Value) Close() { 721 v.mustBe(Chan) 722 v.mustBeExported() 723 chanclose(v.pointer()) 724 } 725 726 // Complex returns v's underlying value, as a complex128. 727 // It panics if v's Kind is not Complex64 or Complex128 728 func (v Value) Complex() complex128 { 729 k := v.kind() 730 switch k { 731 case Complex64: 732 return complex128(*(*complex64)(v.ptr)) 733 case Complex128: 734 return *(*complex128)(v.ptr) 735 } 736 panic(&ValueError{"reflect.Value.Complex", v.kind()}) 737 } 738 739 // Elem returns the value that the interface v contains 740 // or that the pointer v points to. 741 // It panics if v's Kind is not Interface or Ptr. 742 // It returns the zero Value if v is nil. 743 func (v Value) Elem() Value { 744 k := v.kind() 745 switch k { 746 case Interface: 747 var eface interface{} 748 if v.typ.NumMethod() == 0 { 749 eface = *(*interface{})(v.ptr) 750 } else { 751 eface = (interface{})(*(*interface { 752 M() 753 })(v.ptr)) 754 } 755 x := unpackEface(eface) 756 if x.flag != 0 { 757 x.flag |= v.flag.ro() 758 } 759 return x 760 case Ptr: 761 ptr := v.ptr 762 if v.flag&flagIndir != 0 { 763 ptr = *(*unsafe.Pointer)(ptr) 764 } 765 // The returned value's address is v's value. 766 if ptr == nil { 767 return Value{} 768 } 769 tt := (*ptrType)(unsafe.Pointer(v.typ)) 770 typ := tt.elem 771 fl := v.flag&flagRO | flagIndir | flagAddr 772 fl |= flag(typ.Kind()) 773 return Value{typ, ptr, fl} 774 } 775 panic(&ValueError{"reflect.Value.Elem", v.kind()}) 776 } 777 778 // Field returns the i'th field of the struct v. 779 // It panics if v's Kind is not Struct or i is out of range. 780 func (v Value) Field(i int) Value { 781 if v.kind() != Struct { 782 panic(&ValueError{"reflect.Value.Field", v.kind()}) 783 } 784 tt := (*structType)(unsafe.Pointer(v.typ)) 785 if uint(i) >= uint(len(tt.fields)) { 786 panic("reflect: Field index out of range") 787 } 788 field := &tt.fields[i] 789 typ := field.typ 790 791 // Inherit permission bits from v, but clear flagEmbedRO. 792 fl := v.flag&(flagStickyRO|flagIndir|flagAddr) | flag(typ.Kind()) 793 // Using an unexported field forces flagRO. 794 if !field.name.isExported() { 795 if field.anon() { 796 fl |= flagEmbedRO 797 } else { 798 fl |= flagStickyRO 799 } 800 } 801 // Either flagIndir is set and v.ptr points at struct, 802 // or flagIndir is not set and v.ptr is the actual struct data. 803 // In the former case, we want v.ptr + offset. 804 // In the latter case, we must have field.offset = 0, 805 // so v.ptr + field.offset is still the correct address. 806 ptr := add(v.ptr, field.offset(), "same as non-reflect &v.field") 807 return Value{typ, ptr, fl} 808 } 809 810 // FieldByIndex returns the nested field corresponding to index. 811 // It panics if v's Kind is not struct. 812 func (v Value) FieldByIndex(index []int) Value { 813 if len(index) == 1 { 814 return v.Field(index[0]) 815 } 816 v.mustBe(Struct) 817 for i, x := range index { 818 if i > 0 { 819 if v.Kind() == Ptr && v.typ.Elem().Kind() == Struct { 820 if v.IsNil() { 821 panic("reflect: indirection through nil pointer to embedded struct") 822 } 823 v = v.Elem() 824 } 825 } 826 v = v.Field(x) 827 } 828 return v 829 } 830 831 // FieldByName returns the struct field with the given name. 832 // It returns the zero Value if no field was found. 833 // It panics if v's Kind is not struct. 834 func (v Value) FieldByName(name string) Value { 835 v.mustBe(Struct) 836 if f, ok := v.typ.FieldByName(name); ok { 837 return v.FieldByIndex(f.Index) 838 } 839 return Value{} 840 } 841 842 // FieldByNameFunc returns the struct field with a name 843 // that satisfies the match function. 844 // It panics if v's Kind is not struct. 845 // It returns the zero Value if no field was found. 846 func (v Value) FieldByNameFunc(match func(string) bool) Value { 847 if f, ok := v.typ.FieldByNameFunc(match); ok { 848 return v.FieldByIndex(f.Index) 849 } 850 return Value{} 851 } 852 853 // Float returns v's underlying value, as a float64. 854 // It panics if v's Kind is not Float32 or Float64 855 func (v Value) Float() float64 { 856 k := v.kind() 857 switch k { 858 case Float32: 859 return float64(*(*float32)(v.ptr)) 860 case Float64: 861 return *(*float64)(v.ptr) 862 } 863 panic(&ValueError{"reflect.Value.Float", v.kind()}) 864 } 865 866 var uint8Type = TypeOf(uint8(0)).(*rtype) 867 868 // Index returns v's i'th element. 869 // It panics if v's Kind is not Array, Slice, or String or i is out of range. 870 func (v Value) Index(i int) Value { 871 switch v.kind() { 872 case Array: 873 tt := (*arrayType)(unsafe.Pointer(v.typ)) 874 if uint(i) >= uint(tt.len) { 875 panic("reflect: array index out of range") 876 } 877 typ := tt.elem 878 offset := uintptr(i) * typ.size 879 880 // Either flagIndir is set and v.ptr points at array, 881 // or flagIndir is not set and v.ptr is the actual array data. 882 // In the former case, we want v.ptr + offset. 883 // In the latter case, we must be doing Index(0), so offset = 0, 884 // so v.ptr + offset is still the correct address. 885 val := add(v.ptr, offset, "same as &v[i], i < tt.len") 886 fl := v.flag&(flagIndir|flagAddr) | v.flag.ro() | flag(typ.Kind()) // bits same as overall array 887 return Value{typ, val, fl} 888 889 case Slice: 890 // Element flag same as Elem of Ptr. 891 // Addressable, indirect, possibly read-only. 892 s := (*sliceHeader)(v.ptr) 893 if uint(i) >= uint(s.Len) { 894 panic("reflect: slice index out of range") 895 } 896 tt := (*sliceType)(unsafe.Pointer(v.typ)) 897 typ := tt.elem 898 val := arrayAt(s.Data, i, typ.size, "i < s.Len") 899 fl := flagAddr | flagIndir | v.flag.ro() | flag(typ.Kind()) 900 return Value{typ, val, fl} 901 902 case String: 903 s := (*stringHeader)(v.ptr) 904 if uint(i) >= uint(s.Len) { 905 panic("reflect: string index out of range") 906 } 907 p := arrayAt(s.Data, i, 1, "i < s.Len") 908 fl := v.flag.ro() | flag(Uint8) | flagIndir 909 return Value{uint8Type, p, fl} 910 } 911 panic(&ValueError{"reflect.Value.Index", v.kind()}) 912 } 913 914 // Int returns v's underlying value, as an int64. 915 // It panics if v's Kind is not Int, Int8, Int16, Int32, or Int64. 916 func (v Value) Int() int64 { 917 k := v.kind() 918 p := v.ptr 919 switch k { 920 case Int: 921 return int64(*(*int)(p)) 922 case Int8: 923 return int64(*(*int8)(p)) 924 case Int16: 925 return int64(*(*int16)(p)) 926 case Int32: 927 return int64(*(*int32)(p)) 928 case Int64: 929 return *(*int64)(p) 930 } 931 panic(&ValueError{"reflect.Value.Int", v.kind()}) 932 } 933 934 // CanInterface reports whether Interface can be used without panicking. 935 func (v Value) CanInterface() bool { 936 if v.flag == 0 { 937 panic(&ValueError{"reflect.Value.CanInterface", Invalid}) 938 } 939 return v.flag&flagRO == 0 940 } 941 942 // Interface returns v's current value as an interface{}. 943 // It is equivalent to: 944 // var i interface{} = (v's underlying value) 945 // It panics if the Value was obtained by accessing 946 // unexported struct fields. 947 func (v Value) Interface() (i interface{}) { 948 return valueInterface(v, true) 949 } 950 951 func valueInterface(v Value, safe bool) interface{} { 952 if v.flag == 0 { 953 panic(&ValueError{"reflect.Value.Interface", 0}) 954 } 955 if safe && v.flag&flagRO != 0 { 956 // Do not allow access to unexported values via Interface, 957 // because they might be pointers that should not be 958 // writable or methods or function that should not be callable. 959 panic("reflect.Value.Interface: cannot return value obtained from unexported field or method") 960 } 961 if v.flag&flagMethod != 0 { 962 v = makeMethodValue("Interface", v) 963 } 964 965 if v.kind() == Interface { 966 // Special case: return the element inside the interface. 967 // Empty interface has one layout, all interfaces with 968 // methods have a second layout. 969 if v.NumMethod() == 0 { 970 return *(*interface{})(v.ptr) 971 } 972 return *(*interface { 973 M() 974 })(v.ptr) 975 } 976 977 // TODO: pass safe to packEface so we don't need to copy if safe==true? 978 return packEface(v) 979 } 980 981 // InterfaceData returns the interface v's value as a uintptr pair. 982 // It panics if v's Kind is not Interface. 983 func (v Value) InterfaceData() [2]uintptr { 984 // TODO: deprecate this 985 v.mustBe(Interface) 986 // We treat this as a read operation, so we allow 987 // it even for unexported data, because the caller 988 // has to import "unsafe" to turn it into something 989 // that can be abused. 990 // Interface value is always bigger than a word; assume flagIndir. 991 return *(*[2]uintptr)(v.ptr) 992 } 993 994 // IsNil reports whether its argument v is nil. The argument must be 995 // a chan, func, interface, map, pointer, or slice value; if it is 996 // not, IsNil panics. Note that IsNil is not always equivalent to a 997 // regular comparison with nil in Go. For example, if v was created 998 // by calling ValueOf with an uninitialized interface variable i, 999 // i==nil will be true but v.IsNil will panic as v will be the zero 1000 // Value. 1001 func (v Value) IsNil() bool { 1002 k := v.kind() 1003 switch k { 1004 case Chan, Func, Map, Ptr: 1005 if v.flag&flagMethod != 0 { 1006 return false 1007 } 1008 ptr := v.ptr 1009 if v.flag&flagIndir != 0 { 1010 ptr = *(*unsafe.Pointer)(ptr) 1011 } 1012 return ptr == nil 1013 case Interface, Slice: 1014 // Both interface and slice are nil if first word is 0. 1015 // Both are always bigger than a word; assume flagIndir. 1016 return *(*unsafe.Pointer)(v.ptr) == nil 1017 } 1018 panic(&ValueError{"reflect.Value.IsNil", v.kind()}) 1019 } 1020 1021 // IsValid reports whether v represents a value. 1022 // It returns false if v is the zero Value. 1023 // If IsValid returns false, all other methods except String panic. 1024 // Most functions and methods never return an invalid value. 1025 // If one does, its documentation states the conditions explicitly. 1026 func (v Value) IsValid() bool { 1027 return v.flag != 0 1028 } 1029 1030 // Kind returns v's Kind. 1031 // If v is the zero Value (IsValid returns false), Kind returns Invalid. 1032 func (v Value) Kind() Kind { 1033 return v.kind() 1034 } 1035 1036 // Len returns v's length. 1037 // It panics if v's Kind is not Array, Chan, Map, Slice, or String. 1038 func (v Value) Len() int { 1039 k := v.kind() 1040 switch k { 1041 case Array: 1042 tt := (*arrayType)(unsafe.Pointer(v.typ)) 1043 return int(tt.len) 1044 case Chan: 1045 return chanlen(v.pointer()) 1046 case Map: 1047 return maplen(v.pointer()) 1048 case Slice: 1049 // Slice is bigger than a word; assume flagIndir. 1050 return (*sliceHeader)(v.ptr).Len 1051 case String: 1052 // String is bigger than a word; assume flagIndir. 1053 return (*stringHeader)(v.ptr).Len 1054 } 1055 panic(&ValueError{"reflect.Value.Len", v.kind()}) 1056 } 1057 1058 // MapIndex returns the value associated with key in the map v. 1059 // It panics if v's Kind is not Map. 1060 // It returns the zero Value if key is not found in the map or if v represents a nil map. 1061 // As in Go, the key's value must be assignable to the map's key type. 1062 func (v Value) MapIndex(key Value) Value { 1063 v.mustBe(Map) 1064 tt := (*mapType)(unsafe.Pointer(v.typ)) 1065 1066 // Do not require key to be exported, so that DeepEqual 1067 // and other programs can use all the keys returned by 1068 // MapKeys as arguments to MapIndex. If either the map 1069 // or the key is unexported, though, the result will be 1070 // considered unexported. This is consistent with the 1071 // behavior for structs, which allow read but not write 1072 // of unexported fields. 1073 key = key.assignTo("reflect.Value.MapIndex", tt.key, nil) 1074 1075 var k unsafe.Pointer 1076 if key.flag&flagIndir != 0 { 1077 k = key.ptr 1078 } else { 1079 k = unsafe.Pointer(&key.ptr) 1080 } 1081 e := mapaccess(v.typ, v.pointer(), k) 1082 if e == nil { 1083 return Value{} 1084 } 1085 typ := tt.elem 1086 fl := (v.flag | key.flag).ro() 1087 fl |= flag(typ.Kind()) 1088 if !ifaceIndir(typ) { 1089 return Value{typ, *(*unsafe.Pointer)(e), fl} 1090 } 1091 // Copy result so future changes to the map 1092 // won't change the underlying value. 1093 c := unsafe_New(typ) 1094 typedmemmove(typ, c, e) 1095 return Value{typ, c, fl | flagIndir} 1096 } 1097 1098 // MapKeys returns a slice containing all the keys present in the map, 1099 // in unspecified order. 1100 // It panics if v's Kind is not Map. 1101 // It returns an empty slice if v represents a nil map. 1102 func (v Value) MapKeys() []Value { 1103 v.mustBe(Map) 1104 tt := (*mapType)(unsafe.Pointer(v.typ)) 1105 keyType := tt.key 1106 1107 fl := v.flag.ro() | flag(keyType.Kind()) 1108 1109 m := v.pointer() 1110 mlen := int(0) 1111 if m != nil { 1112 mlen = maplen(m) 1113 } 1114 it := mapiterinit(v.typ, m) 1115 a := make([]Value, mlen) 1116 var i int 1117 for i = 0; i < len(a); i++ { 1118 key := mapiterkey(it) 1119 if key == nil { 1120 // Someone deleted an entry from the map since we 1121 // called maplen above. It's a data race, but nothing 1122 // we can do about it. 1123 break 1124 } 1125 if ifaceIndir(keyType) { 1126 // Copy result so future changes to the map 1127 // won't change the underlying value. 1128 c := unsafe_New(keyType) 1129 typedmemmove(keyType, c, key) 1130 a[i] = Value{keyType, c, fl | flagIndir} 1131 } else { 1132 a[i] = Value{keyType, *(*unsafe.Pointer)(key), fl} 1133 } 1134 mapiternext(it) 1135 } 1136 return a[:i] 1137 } 1138 1139 // Method returns a function value corresponding to v's i'th method. 1140 // The arguments to a Call on the returned function should not include 1141 // a receiver; the returned function will always use v as the receiver. 1142 // Method panics if i is out of range or if v is a nil interface value. 1143 func (v Value) Method(i int) Value { 1144 if v.typ == nil { 1145 panic(&ValueError{"reflect.Value.Method", Invalid}) 1146 } 1147 if v.flag&flagMethod != 0 || uint(i) >= uint(v.typ.NumMethod()) { 1148 panic("reflect: Method index out of range") 1149 } 1150 if v.typ.Kind() == Interface && v.IsNil() { 1151 panic("reflect: Method on nil interface value") 1152 } 1153 fl := v.flag & (flagStickyRO | flagIndir) // Clear flagEmbedRO 1154 fl |= flag(Func) 1155 fl |= flag(i)<<flagMethodShift | flagMethod 1156 return Value{v.typ, v.ptr, fl} 1157 } 1158 1159 // NumMethod returns the number of exported methods in the value's method set. 1160 func (v Value) NumMethod() int { 1161 if v.typ == nil { 1162 panic(&ValueError{"reflect.Value.NumMethod", Invalid}) 1163 } 1164 if v.flag&flagMethod != 0 { 1165 return 0 1166 } 1167 return v.typ.NumMethod() 1168 } 1169 1170 // MethodByName returns a function value corresponding to the method 1171 // of v with the given name. 1172 // The arguments to a Call on the returned function should not include 1173 // a receiver; the returned function will always use v as the receiver. 1174 // It returns the zero Value if no method was found. 1175 func (v Value) MethodByName(name string) Value { 1176 if v.typ == nil { 1177 panic(&ValueError{"reflect.Value.MethodByName", Invalid}) 1178 } 1179 if v.flag&flagMethod != 0 { 1180 return Value{} 1181 } 1182 m, ok := v.typ.MethodByName(name) 1183 if !ok { 1184 return Value{} 1185 } 1186 return v.Method(m.Index) 1187 } 1188 1189 // NumField returns the number of fields in the struct v. 1190 // It panics if v's Kind is not Struct. 1191 func (v Value) NumField() int { 1192 v.mustBe(Struct) 1193 tt := (*structType)(unsafe.Pointer(v.typ)) 1194 return len(tt.fields) 1195 } 1196 1197 // OverflowComplex reports whether the complex128 x cannot be represented by v's type. 1198 // It panics if v's Kind is not Complex64 or Complex128. 1199 func (v Value) OverflowComplex(x complex128) bool { 1200 k := v.kind() 1201 switch k { 1202 case Complex64: 1203 return overflowFloat32(real(x)) || overflowFloat32(imag(x)) 1204 case Complex128: 1205 return false 1206 } 1207 panic(&ValueError{"reflect.Value.OverflowComplex", v.kind()}) 1208 } 1209 1210 // OverflowFloat reports whether the float64 x cannot be represented by v's type. 1211 // It panics if v's Kind is not Float32 or Float64. 1212 func (v Value) OverflowFloat(x float64) bool { 1213 k := v.kind() 1214 switch k { 1215 case Float32: 1216 return overflowFloat32(x) 1217 case Float64: 1218 return false 1219 } 1220 panic(&ValueError{"reflect.Value.OverflowFloat", v.kind()}) 1221 } 1222 1223 func overflowFloat32(x float64) bool { 1224 if x < 0 { 1225 x = -x 1226 } 1227 return math.MaxFloat32 < x && x <= math.MaxFloat64 1228 } 1229 1230 // OverflowInt reports whether the int64 x cannot be represented by v's type. 1231 // It panics if v's Kind is not Int, Int8, int16, Int32, or Int64. 1232 func (v Value) OverflowInt(x int64) bool { 1233 k := v.kind() 1234 switch k { 1235 case Int, Int8, Int16, Int32, Int64: 1236 bitSize := v.typ.size * 8 1237 trunc := (x << (64 - bitSize)) >> (64 - bitSize) 1238 return x != trunc 1239 } 1240 panic(&ValueError{"reflect.Value.OverflowInt", v.kind()}) 1241 } 1242 1243 // OverflowUint reports whether the uint64 x cannot be represented by v's type. 1244 // It panics if v's Kind is not Uint, Uintptr, Uint8, Uint16, Uint32, or Uint64. 1245 func (v Value) OverflowUint(x uint64) bool { 1246 k := v.kind() 1247 switch k { 1248 case Uint, Uintptr, Uint8, Uint16, Uint32, Uint64: 1249 bitSize := v.typ.size * 8 1250 trunc := (x << (64 - bitSize)) >> (64 - bitSize) 1251 return x != trunc 1252 } 1253 panic(&ValueError{"reflect.Value.OverflowUint", v.kind()}) 1254 } 1255 1256 // Pointer returns v's value as a uintptr. 1257 // It returns uintptr instead of unsafe.Pointer so that 1258 // code using reflect cannot obtain unsafe.Pointers 1259 // without importing the unsafe package explicitly. 1260 // It panics if v's Kind is not Chan, Func, Map, Ptr, Slice, or UnsafePointer. 1261 // 1262 // If v's Kind is Func, the returned pointer is an underlying 1263 // code pointer, but not necessarily enough to identify a 1264 // single function uniquely. The only guarantee is that the 1265 // result is zero if and only if v is a nil func Value. 1266 // 1267 // If v's Kind is Slice, the returned pointer is to the first 1268 // element of the slice. If the slice is nil the returned value 1269 // is 0. If the slice is empty but non-nil the return value is non-zero. 1270 func (v Value) Pointer() uintptr { 1271 // TODO: deprecate 1272 k := v.kind() 1273 switch k { 1274 case Chan, Map, Ptr, UnsafePointer: 1275 return uintptr(v.pointer()) 1276 case Func: 1277 if v.flag&flagMethod != 0 { 1278 // As the doc comment says, the returned pointer is an 1279 // underlying code pointer but not necessarily enough to 1280 // identify a single function uniquely. All method expressions 1281 // created via reflect have the same underlying code pointer, 1282 // so their Pointers are equal. The function used here must 1283 // match the one used in makeMethodValue. 1284 f := methodValueCall 1285 return **(**uintptr)(unsafe.Pointer(&f)) 1286 } 1287 p := v.pointer() 1288 // Non-nil func value points at data block. 1289 // First word of data block is actual code. 1290 if p != nil { 1291 p = *(*unsafe.Pointer)(p) 1292 } 1293 return uintptr(p) 1294 1295 case Slice: 1296 return (*SliceHeader)(v.ptr).Data 1297 } 1298 panic(&ValueError{"reflect.Value.Pointer", v.kind()}) 1299 } 1300 1301 // Recv receives and returns a value from the channel v. 1302 // It panics if v's Kind is not Chan. 1303 // The receive blocks until a value is ready. 1304 // The boolean value ok is true if the value x corresponds to a send 1305 // on the channel, false if it is a zero value received because the channel is closed. 1306 func (v Value) Recv() (x Value, ok bool) { 1307 v.mustBe(Chan) 1308 v.mustBeExported() 1309 return v.recv(false) 1310 } 1311 1312 // internal recv, possibly non-blocking (nb). 1313 // v is known to be a channel. 1314 func (v Value) recv(nb bool) (val Value, ok bool) { 1315 tt := (*chanType)(unsafe.Pointer(v.typ)) 1316 if ChanDir(tt.dir)&RecvDir == 0 { 1317 panic("reflect: recv on send-only channel") 1318 } 1319 t := tt.elem 1320 val = Value{t, nil, flag(t.Kind())} 1321 var p unsafe.Pointer 1322 if ifaceIndir(t) { 1323 p = unsafe_New(t) 1324 val.ptr = p 1325 val.flag |= flagIndir 1326 } else { 1327 p = unsafe.Pointer(&val.ptr) 1328 } 1329 selected, ok := chanrecv(v.pointer(), nb, p) 1330 if !selected { 1331 val = Value{} 1332 } 1333 return 1334 } 1335 1336 // Send sends x on the channel v. 1337 // It panics if v's kind is not Chan or if x's type is not the same type as v's element type. 1338 // As in Go, x's value must be assignable to the channel's element type. 1339 func (v Value) Send(x Value) { 1340 v.mustBe(Chan) 1341 v.mustBeExported() 1342 v.send(x, false) 1343 } 1344 1345 // internal send, possibly non-blocking. 1346 // v is known to be a channel. 1347 func (v Value) send(x Value, nb bool) (selected bool) { 1348 tt := (*chanType)(unsafe.Pointer(v.typ)) 1349 if ChanDir(tt.dir)&SendDir == 0 { 1350 panic("reflect: send on recv-only channel") 1351 } 1352 x.mustBeExported() 1353 x = x.assignTo("reflect.Value.Send", tt.elem, nil) 1354 var p unsafe.Pointer 1355 if x.flag&flagIndir != 0 { 1356 p = x.ptr 1357 } else { 1358 p = unsafe.Pointer(&x.ptr) 1359 } 1360 return chansend(v.pointer(), p, nb) 1361 } 1362 1363 // Set assigns x to the value v. 1364 // It panics if CanSet returns false. 1365 // As in Go, x's value must be assignable to v's type. 1366 func (v Value) Set(x Value) { 1367 v.mustBeAssignable() 1368 x.mustBeExported() // do not let unexported x leak 1369 var target unsafe.Pointer 1370 if v.kind() == Interface { 1371 target = v.ptr 1372 } 1373 x = x.assignTo("reflect.Set", v.typ, target) 1374 if x.flag&flagIndir != 0 { 1375 typedmemmove(v.typ, v.ptr, x.ptr) 1376 } else { 1377 *(*unsafe.Pointer)(v.ptr) = x.ptr 1378 } 1379 } 1380 1381 // SetBool sets v's underlying value. 1382 // It panics if v's Kind is not Bool or if CanSet() is false. 1383 func (v Value) SetBool(x bool) { 1384 v.mustBeAssignable() 1385 v.mustBe(Bool) 1386 *(*bool)(v.ptr) = x 1387 } 1388 1389 // SetBytes sets v's underlying value. 1390 // It panics if v's underlying value is not a slice of bytes. 1391 func (v Value) SetBytes(x []byte) { 1392 v.mustBeAssignable() 1393 v.mustBe(Slice) 1394 if v.typ.Elem().Kind() != Uint8 { 1395 panic("reflect.Value.SetBytes of non-byte slice") 1396 } 1397 *(*[]byte)(v.ptr) = x 1398 } 1399 1400 // setRunes sets v's underlying value. 1401 // It panics if v's underlying value is not a slice of runes (int32s). 1402 func (v Value) setRunes(x []rune) { 1403 v.mustBeAssignable() 1404 v.mustBe(Slice) 1405 if v.typ.Elem().Kind() != Int32 { 1406 panic("reflect.Value.setRunes of non-rune slice") 1407 } 1408 *(*[]rune)(v.ptr) = x 1409 } 1410 1411 // SetComplex sets v's underlying value to x. 1412 // It panics if v's Kind is not Complex64 or Complex128, or if CanSet() is false. 1413 func (v Value) SetComplex(x complex128) { 1414 v.mustBeAssignable() 1415 switch k := v.kind(); k { 1416 default: 1417 panic(&ValueError{"reflect.Value.SetComplex", v.kind()}) 1418 case Complex64: 1419 *(*complex64)(v.ptr) = complex64(x) 1420 case Complex128: 1421 *(*complex128)(v.ptr) = x 1422 } 1423 } 1424 1425 // SetFloat sets v's underlying value to x. 1426 // It panics if v's Kind is not Float32 or Float64, or if CanSet() is false. 1427 func (v Value) SetFloat(x float64) { 1428 v.mustBeAssignable() 1429 switch k := v.kind(); k { 1430 default: 1431 panic(&ValueError{"reflect.Value.SetFloat", v.kind()}) 1432 case Float32: 1433 *(*float32)(v.ptr) = float32(x) 1434 case Float64: 1435 *(*float64)(v.ptr) = x 1436 } 1437 } 1438 1439 // SetInt sets v's underlying value to x. 1440 // It panics if v's Kind is not Int, Int8, Int16, Int32, or Int64, or if CanSet() is false. 1441 func (v Value) SetInt(x int64) { 1442 v.mustBeAssignable() 1443 switch k := v.kind(); k { 1444 default: 1445 panic(&ValueError{"reflect.Value.SetInt", v.kind()}) 1446 case Int: 1447 *(*int)(v.ptr) = int(x) 1448 case Int8: 1449 *(*int8)(v.ptr) = int8(x) 1450 case Int16: 1451 *(*int16)(v.ptr) = int16(x) 1452 case Int32: 1453 *(*int32)(v.ptr) = int32(x) 1454 case Int64: 1455 *(*int64)(v.ptr) = x 1456 } 1457 } 1458 1459 // SetLen sets v's length to n. 1460 // It panics if v's Kind is not Slice or if n is negative or 1461 // greater than the capacity of the slice. 1462 func (v Value) SetLen(n int) { 1463 v.mustBeAssignable() 1464 v.mustBe(Slice) 1465 s := (*sliceHeader)(v.ptr) 1466 if uint(n) > uint(s.Cap) { 1467 panic("reflect: slice length out of range in SetLen") 1468 } 1469 s.Len = n 1470 } 1471 1472 // SetCap sets v's capacity to n. 1473 // It panics if v's Kind is not Slice or if n is smaller than the length or 1474 // greater than the capacity of the slice. 1475 func (v Value) SetCap(n int) { 1476 v.mustBeAssignable() 1477 v.mustBe(Slice) 1478 s := (*sliceHeader)(v.ptr) 1479 if n < s.Len || n > s.Cap { 1480 panic("reflect: slice capacity out of range in SetCap") 1481 } 1482 s.Cap = n 1483 } 1484 1485 // SetMapIndex sets the value associated with key in the map v to val. 1486 // It panics if v's Kind is not Map. 1487 // If val is the zero Value, SetMapIndex deletes the key from the map. 1488 // Otherwise if v holds a nil map, SetMapIndex will panic. 1489 // As in Go, key's value must be assignable to the map's key type, 1490 // and val's value must be assignable to the map's value type. 1491 func (v Value) SetMapIndex(key, val Value) { 1492 v.mustBe(Map) 1493 v.mustBeExported() 1494 key.mustBeExported() 1495 tt := (*mapType)(unsafe.Pointer(v.typ)) 1496 key = key.assignTo("reflect.Value.SetMapIndex", tt.key, nil) 1497 var k unsafe.Pointer 1498 if key.flag&flagIndir != 0 { 1499 k = key.ptr 1500 } else { 1501 k = unsafe.Pointer(&key.ptr) 1502 } 1503 if val.typ == nil { 1504 mapdelete(v.typ, v.pointer(), k) 1505 return 1506 } 1507 val.mustBeExported() 1508 val = val.assignTo("reflect.Value.SetMapIndex", tt.elem, nil) 1509 var e unsafe.Pointer 1510 if val.flag&flagIndir != 0 { 1511 e = val.ptr 1512 } else { 1513 e = unsafe.Pointer(&val.ptr) 1514 } 1515 mapassign(v.typ, v.pointer(), k, e) 1516 } 1517 1518 // SetUint sets v's underlying value to x. 1519 // It panics if v's Kind is not Uint, Uintptr, Uint8, Uint16, Uint32, or Uint64, or if CanSet() is false. 1520 func (v Value) SetUint(x uint64) { 1521 v.mustBeAssignable() 1522 switch k := v.kind(); k { 1523 default: 1524 panic(&ValueError{"reflect.Value.SetUint", v.kind()}) 1525 case Uint: 1526 *(*uint)(v.ptr) = uint(x) 1527 case Uint8: 1528 *(*uint8)(v.ptr) = uint8(x) 1529 case Uint16: 1530 *(*uint16)(v.ptr) = uint16(x) 1531 case Uint32: 1532 *(*uint32)(v.ptr) = uint32(x) 1533 case Uint64: 1534 *(*uint64)(v.ptr) = x 1535 case Uintptr: 1536 *(*uintptr)(v.ptr) = uintptr(x) 1537 } 1538 } 1539 1540 // SetPointer sets the unsafe.Pointer value v to x. 1541 // It panics if v's Kind is not UnsafePointer. 1542 func (v Value) SetPointer(x unsafe.Pointer) { 1543 v.mustBeAssignable() 1544 v.mustBe(UnsafePointer) 1545 *(*unsafe.Pointer)(v.ptr) = x 1546 } 1547 1548 // SetString sets v's underlying value to x. 1549 // It panics if v's Kind is not String or if CanSet() is false. 1550 func (v Value) SetString(x string) { 1551 v.mustBeAssignable() 1552 v.mustBe(String) 1553 *(*string)(v.ptr) = x 1554 } 1555 1556 // Slice returns v[i:j]. 1557 // It panics if v's Kind is not Array, Slice or String, or if v is an unaddressable array, 1558 // or if the indexes are out of bounds. 1559 func (v Value) Slice(i, j int) Value { 1560 var ( 1561 cap int 1562 typ *sliceType 1563 base unsafe.Pointer 1564 ) 1565 switch kind := v.kind(); kind { 1566 default: 1567 panic(&ValueError{"reflect.Value.Slice", v.kind()}) 1568 1569 case Array: 1570 if v.flag&flagAddr == 0 { 1571 panic("reflect.Value.Slice: slice of unaddressable array") 1572 } 1573 tt := (*arrayType)(unsafe.Pointer(v.typ)) 1574 cap = int(tt.len) 1575 typ = (*sliceType)(unsafe.Pointer(tt.slice)) 1576 base = v.ptr 1577 1578 case Slice: 1579 typ = (*sliceType)(unsafe.Pointer(v.typ)) 1580 s := (*sliceHeader)(v.ptr) 1581 base = s.Data 1582 cap = s.Cap 1583 1584 case String: 1585 s := (*stringHeader)(v.ptr) 1586 if i < 0 || j < i || j > s.Len { 1587 panic("reflect.Value.Slice: string slice index out of bounds") 1588 } 1589 var t stringHeader 1590 if i < s.Len { 1591 t = stringHeader{arrayAt(s.Data, i, 1, "i < s.Len"), j - i} 1592 } 1593 return Value{v.typ, unsafe.Pointer(&t), v.flag} 1594 } 1595 1596 if i < 0 || j < i || j > cap { 1597 panic("reflect.Value.Slice: slice index out of bounds") 1598 } 1599 1600 // Declare slice so that gc can see the base pointer in it. 1601 var x []unsafe.Pointer 1602 1603 // Reinterpret as *sliceHeader to edit. 1604 s := (*sliceHeader)(unsafe.Pointer(&x)) 1605 s.Len = j - i 1606 s.Cap = cap - i 1607 if cap-i > 0 { 1608 s.Data = arrayAt(base, i, typ.elem.Size(), "i < cap") 1609 } else { 1610 // do not advance pointer, to avoid pointing beyond end of slice 1611 s.Data = base 1612 } 1613 1614 fl := v.flag.ro() | flagIndir | flag(Slice) 1615 return Value{typ.common(), unsafe.Pointer(&x), fl} 1616 } 1617 1618 // Slice3 is the 3-index form of the slice operation: it returns v[i:j:k]. 1619 // It panics if v's Kind is not Array or Slice, or if v is an unaddressable array, 1620 // or if the indexes are out of bounds. 1621 func (v Value) Slice3(i, j, k int) Value { 1622 var ( 1623 cap int 1624 typ *sliceType 1625 base unsafe.Pointer 1626 ) 1627 switch kind := v.kind(); kind { 1628 default: 1629 panic(&ValueError{"reflect.Value.Slice3", v.kind()}) 1630 1631 case Array: 1632 if v.flag&flagAddr == 0 { 1633 panic("reflect.Value.Slice3: slice of unaddressable array") 1634 } 1635 tt := (*arrayType)(unsafe.Pointer(v.typ)) 1636 cap = int(tt.len) 1637 typ = (*sliceType)(unsafe.Pointer(tt.slice)) 1638 base = v.ptr 1639 1640 case Slice: 1641 typ = (*sliceType)(unsafe.Pointer(v.typ)) 1642 s := (*sliceHeader)(v.ptr) 1643 base = s.Data 1644 cap = s.Cap 1645 } 1646 1647 if i < 0 || j < i || k < j || k > cap { 1648 panic("reflect.Value.Slice3: slice index out of bounds") 1649 } 1650 1651 // Declare slice so that the garbage collector 1652 // can see the base pointer in it. 1653 var x []unsafe.Pointer 1654 1655 // Reinterpret as *sliceHeader to edit. 1656 s := (*sliceHeader)(unsafe.Pointer(&x)) 1657 s.Len = j - i 1658 s.Cap = k - i 1659 if k-i > 0 { 1660 s.Data = arrayAt(base, i, typ.elem.Size(), "i < k <= cap") 1661 } else { 1662 // do not advance pointer, to avoid pointing beyond end of slice 1663 s.Data = base 1664 } 1665 1666 fl := v.flag.ro() | flagIndir | flag(Slice) 1667 return Value{typ.common(), unsafe.Pointer(&x), fl} 1668 } 1669 1670 // String returns the string v's underlying value, as a string. 1671 // String is a special case because of Go's String method convention. 1672 // Unlike the other getters, it does not panic if v's Kind is not String. 1673 // Instead, it returns a string of the form "<T value>" where T is v's type. 1674 // The fmt package treats Values specially. It does not call their String 1675 // method implicitly but instead prints the concrete values they hold. 1676 func (v Value) String() string { 1677 switch k := v.kind(); k { 1678 case Invalid: 1679 return "<invalid Value>" 1680 case String: 1681 return *(*string)(v.ptr) 1682 } 1683 // If you call String on a reflect.Value of other type, it's better to 1684 // print something than to panic. Useful in debugging. 1685 return "<" + v.Type().String() + " Value>" 1686 } 1687 1688 // TryRecv attempts to receive a value from the channel v but will not block. 1689 // It panics if v's Kind is not Chan. 1690 // If the receive delivers a value, x is the transferred value and ok is true. 1691 // If the receive cannot finish without blocking, x is the zero Value and ok is false. 1692 // If the channel is closed, x is the zero value for the channel's element type and ok is false. 1693 func (v Value) TryRecv() (x Value, ok bool) { 1694 v.mustBe(Chan) 1695 v.mustBeExported() 1696 return v.recv(true) 1697 } 1698 1699 // TrySend attempts to send x on the channel v but will not block. 1700 // It panics if v's Kind is not Chan. 1701 // It reports whether the value was sent. 1702 // As in Go, x's value must be assignable to the channel's element type. 1703 func (v Value) TrySend(x Value) bool { 1704 v.mustBe(Chan) 1705 v.mustBeExported() 1706 return v.send(x, true) 1707 } 1708 1709 // Type returns v's type. 1710 func (v Value) Type() Type { 1711 f := v.flag 1712 if f == 0 { 1713 panic(&ValueError{"reflect.Value.Type", Invalid}) 1714 } 1715 if f&flagMethod == 0 { 1716 // Easy case 1717 return v.typ 1718 } 1719 1720 // Method value. 1721 // v.typ describes the receiver, not the method type. 1722 i := int(v.flag) >> flagMethodShift 1723 if v.typ.Kind() == Interface { 1724 // Method on interface. 1725 tt := (*interfaceType)(unsafe.Pointer(v.typ)) 1726 if uint(i) >= uint(len(tt.methods)) { 1727 panic("reflect: internal error: invalid method index") 1728 } 1729 m := &tt.methods[i] 1730 return v.typ.typeOff(m.typ) 1731 } 1732 // Method on concrete type. 1733 ms := v.typ.exportedMethods() 1734 if uint(i) >= uint(len(ms)) { 1735 panic("reflect: internal error: invalid method index") 1736 } 1737 m := ms[i] 1738 return v.typ.typeOff(m.mtyp) 1739 } 1740 1741 // Uint returns v's underlying value, as a uint64. 1742 // It panics if v's Kind is not Uint, Uintptr, Uint8, Uint16, Uint32, or Uint64. 1743 func (v Value) Uint() uint64 { 1744 k := v.kind() 1745 p := v.ptr 1746 switch k { 1747 case Uint: 1748 return uint64(*(*uint)(p)) 1749 case Uint8: 1750 return uint64(*(*uint8)(p)) 1751 case Uint16: 1752 return uint64(*(*uint16)(p)) 1753 case Uint32: 1754 return uint64(*(*uint32)(p)) 1755 case Uint64: 1756 return *(*uint64)(p) 1757 case Uintptr: 1758 return uint64(*(*uintptr)(p)) 1759 } 1760 panic(&ValueError{"reflect.Value.Uint", v.kind()}) 1761 } 1762 1763 // UnsafeAddr returns a pointer to v's data. 1764 // It is for advanced clients that also import the "unsafe" package. 1765 // It panics if v is not addressable. 1766 func (v Value) UnsafeAddr() uintptr { 1767 // TODO: deprecate 1768 if v.typ == nil { 1769 panic(&ValueError{"reflect.Value.UnsafeAddr", Invalid}) 1770 } 1771 if v.flag&flagAddr == 0 { 1772 panic("reflect.Value.UnsafeAddr of unaddressable value") 1773 } 1774 return uintptr(v.ptr) 1775 } 1776 1777 // StringHeader is the runtime representation of a string. 1778 // It cannot be used safely or portably and its representation may 1779 // change in a later release. 1780 // Moreover, the Data field is not sufficient to guarantee the data 1781 // it references will not be garbage collected, so programs must keep 1782 // a separate, correctly typed pointer to the underlying data. 1783 type StringHeader struct { 1784 Data uintptr 1785 Len int 1786 } 1787 1788 // stringHeader is a safe version of StringHeader used within this package. 1789 type stringHeader struct { 1790 Data unsafe.Pointer 1791 Len int 1792 } 1793 1794 // SliceHeader is the runtime representation of a slice. 1795 // It cannot be used safely or portably and its representation may 1796 // change in a later release. 1797 // Moreover, the Data field is not sufficient to guarantee the data 1798 // it references will not be garbage collected, so programs must keep 1799 // a separate, correctly typed pointer to the underlying data. 1800 type SliceHeader struct { 1801 Data uintptr 1802 Len int 1803 Cap int 1804 } 1805 1806 // sliceHeader is a safe version of SliceHeader used within this package. 1807 type sliceHeader struct { 1808 Data unsafe.Pointer 1809 Len int 1810 Cap int 1811 } 1812 1813 func typesMustMatch(what string, t1, t2 Type) { 1814 if t1 != t2 { 1815 panic(what + ": " + t1.String() + " != " + t2.String()) 1816 } 1817 } 1818 1819 // arrayAt returns the i-th element of p, 1820 // an array whose elements are eltSize bytes wide. 1821 // The array pointed at by p must have at least i+1 elements: 1822 // it is invalid (but impossible to check here) to pass i >= len, 1823 // because then the result will point outside the array. 1824 // whySafe must explain why i < len. (Passing "i < len" is fine; 1825 // the benefit is to surface this assumption at the call site.) 1826 func arrayAt(p unsafe.Pointer, i int, eltSize uintptr, whySafe string) unsafe.Pointer { 1827 return add(p, uintptr(i)*eltSize, "i < len") 1828 } 1829 1830 // grow grows the slice s so that it can hold extra more values, allocating 1831 // more capacity if needed. It also returns the old and new slice lengths. 1832 func grow(s Value, extra int) (Value, int, int) { 1833 i0 := s.Len() 1834 i1 := i0 + extra 1835 if i1 < i0 { 1836 panic("reflect.Append: slice overflow") 1837 } 1838 m := s.Cap() 1839 if i1 <= m { 1840 return s.Slice(0, i1), i0, i1 1841 } 1842 if m == 0 { 1843 m = extra 1844 } else { 1845 for m < i1 { 1846 if i0 < 1024 { 1847 m += m 1848 } else { 1849 m += m / 4 1850 } 1851 } 1852 } 1853 t := MakeSlice(s.Type(), i1, m) 1854 Copy(t, s) 1855 return t, i0, i1 1856 } 1857 1858 // Append appends the values x to a slice s and returns the resulting slice. 1859 // As in Go, each x's value must be assignable to the slice's element type. 1860 func Append(s Value, x ...Value) Value { 1861 s.mustBe(Slice) 1862 s, i0, i1 := grow(s, len(x)) 1863 for i, j := i0, 0; i < i1; i, j = i+1, j+1 { 1864 s.Index(i).Set(x[j]) 1865 } 1866 return s 1867 } 1868 1869 // AppendSlice appends a slice t to a slice s and returns the resulting slice. 1870 // The slices s and t must have the same element type. 1871 func AppendSlice(s, t Value) Value { 1872 s.mustBe(Slice) 1873 t.mustBe(Slice) 1874 typesMustMatch("reflect.AppendSlice", s.Type().Elem(), t.Type().Elem()) 1875 s, i0, i1 := grow(s, t.Len()) 1876 Copy(s.Slice(i0, i1), t) 1877 return s 1878 } 1879 1880 // Copy copies the contents of src into dst until either 1881 // dst has been filled or src has been exhausted. 1882 // It returns the number of elements copied. 1883 // Dst and src each must have kind Slice or Array, and 1884 // dst and src must have the same element type. 1885 // 1886 // As a special case, src can have kind String if the element type of dst is kind Uint8. 1887 func Copy(dst, src Value) int { 1888 dk := dst.kind() 1889 if dk != Array && dk != Slice { 1890 panic(&ValueError{"reflect.Copy", dk}) 1891 } 1892 if dk == Array { 1893 dst.mustBeAssignable() 1894 } 1895 dst.mustBeExported() 1896 1897 sk := src.kind() 1898 var stringCopy bool 1899 if sk != Array && sk != Slice { 1900 stringCopy = sk == String && dst.typ.Elem().Kind() == Uint8 1901 if !stringCopy { 1902 panic(&ValueError{"reflect.Copy", sk}) 1903 } 1904 } 1905 src.mustBeExported() 1906 1907 de := dst.typ.Elem() 1908 if !stringCopy { 1909 se := src.typ.Elem() 1910 typesMustMatch("reflect.Copy", de, se) 1911 } 1912 1913 var ds, ss sliceHeader 1914 if dk == Array { 1915 ds.Data = dst.ptr 1916 ds.Len = dst.Len() 1917 ds.Cap = ds.Len 1918 } else { 1919 ds = *(*sliceHeader)(dst.ptr) 1920 } 1921 if sk == Array { 1922 ss.Data = src.ptr 1923 ss.Len = src.Len() 1924 ss.Cap = ss.Len 1925 } else if sk == Slice { 1926 ss = *(*sliceHeader)(src.ptr) 1927 } else { 1928 sh := *(*stringHeader)(src.ptr) 1929 ss.Data = sh.Data 1930 ss.Len = sh.Len 1931 ss.Cap = sh.Len 1932 } 1933 1934 return typedslicecopy(de.common(), ds, ss) 1935 } 1936 1937 // A runtimeSelect is a single case passed to rselect. 1938 // This must match ../runtime/select.go:/runtimeSelect 1939 type runtimeSelect struct { 1940 dir SelectDir // SelectSend, SelectRecv or SelectDefault 1941 typ *rtype // channel type 1942 ch unsafe.Pointer // channel 1943 val unsafe.Pointer // ptr to data (SendDir) or ptr to receive buffer (RecvDir) 1944 } 1945 1946 // rselect runs a select. It returns the index of the chosen case. 1947 // If the case was a receive, val is filled in with the received value. 1948 // The conventional OK bool indicates whether the receive corresponds 1949 // to a sent value. 1950 //go:noescape 1951 func rselect([]runtimeSelect) (chosen int, recvOK bool) 1952 1953 // A SelectDir describes the communication direction of a select case. 1954 type SelectDir int 1955 1956 // NOTE: These values must match ../runtime/select.go:/selectDir. 1957 1958 const ( 1959 _ SelectDir = iota 1960 SelectSend // case Chan <- Send 1961 SelectRecv // case <-Chan: 1962 SelectDefault // default 1963 ) 1964 1965 // A SelectCase describes a single case in a select operation. 1966 // The kind of case depends on Dir, the communication direction. 1967 // 1968 // If Dir is SelectDefault, the case represents a default case. 1969 // Chan and Send must be zero Values. 1970 // 1971 // If Dir is SelectSend, the case represents a send operation. 1972 // Normally Chan's underlying value must be a channel, and Send's underlying value must be 1973 // assignable to the channel's element type. As a special case, if Chan is a zero Value, 1974 // then the case is ignored, and the field Send will also be ignored and may be either zero 1975 // or non-zero. 1976 // 1977 // If Dir is SelectRecv, the case represents a receive operation. 1978 // Normally Chan's underlying value must be a channel and Send must be a zero Value. 1979 // If Chan is a zero Value, then the case is ignored, but Send must still be a zero Value. 1980 // When a receive operation is selected, the received Value is returned by Select. 1981 // 1982 type SelectCase struct { 1983 Dir SelectDir // direction of case 1984 Chan Value // channel to use (for send or receive) 1985 Send Value // value to send (for send) 1986 } 1987 1988 // Select executes a select operation described by the list of cases. 1989 // Like the Go select statement, it blocks until at least one of the cases 1990 // can proceed, makes a uniform pseudo-random choice, 1991 // and then executes that case. It returns the index of the chosen case 1992 // and, if that case was a receive operation, the value received and a 1993 // boolean indicating whether the value corresponds to a send on the channel 1994 // (as opposed to a zero value received because the channel is closed). 1995 func Select(cases []SelectCase) (chosen int, recv Value, recvOK bool) { 1996 // NOTE: Do not trust that caller is not modifying cases data underfoot. 1997 // The range is safe because the caller cannot modify our copy of the len 1998 // and each iteration makes its own copy of the value c. 1999 runcases := make([]runtimeSelect, len(cases)) 2000 haveDefault := false 2001 for i, c := range cases { 2002 rc := &runcases[i] 2003 rc.dir = c.Dir 2004 switch c.Dir { 2005 default: 2006 panic("reflect.Select: invalid Dir") 2007 2008 case SelectDefault: // default 2009 if haveDefault { 2010 panic("reflect.Select: multiple default cases") 2011 } 2012 haveDefault = true 2013 if c.Chan.IsValid() { 2014 panic("reflect.Select: default case has Chan value") 2015 } 2016 if c.Send.IsValid() { 2017 panic("reflect.Select: default case has Send value") 2018 } 2019 2020 case SelectSend: 2021 ch := c.Chan 2022 if !ch.IsValid() { 2023 break 2024 } 2025 ch.mustBe(Chan) 2026 ch.mustBeExported() 2027 tt := (*chanType)(unsafe.Pointer(ch.typ)) 2028 if ChanDir(tt.dir)&SendDir == 0 { 2029 panic("reflect.Select: SendDir case using recv-only channel") 2030 } 2031 rc.ch = ch.pointer() 2032 rc.typ = &tt.rtype 2033 v := c.Send 2034 if !v.IsValid() { 2035 panic("reflect.Select: SendDir case missing Send value") 2036 } 2037 v.mustBeExported() 2038 v = v.assignTo("reflect.Select", tt.elem, nil) 2039 if v.flag&flagIndir != 0 { 2040 rc.val = v.ptr 2041 } else { 2042 rc.val = unsafe.Pointer(&v.ptr) 2043 } 2044 2045 case SelectRecv: 2046 if c.Send.IsValid() { 2047 panic("reflect.Select: RecvDir case has Send value") 2048 } 2049 ch := c.Chan 2050 if !ch.IsValid() { 2051 break 2052 } 2053 ch.mustBe(Chan) 2054 ch.mustBeExported() 2055 tt := (*chanType)(unsafe.Pointer(ch.typ)) 2056 if ChanDir(tt.dir)&RecvDir == 0 { 2057 panic("reflect.Select: RecvDir case using send-only channel") 2058 } 2059 rc.ch = ch.pointer() 2060 rc.typ = &tt.rtype 2061 rc.val = unsafe_New(tt.elem) 2062 } 2063 } 2064 2065 chosen, recvOK = rselect(runcases) 2066 if runcases[chosen].dir == SelectRecv { 2067 tt := (*chanType)(unsafe.Pointer(runcases[chosen].typ)) 2068 t := tt.elem 2069 p := runcases[chosen].val 2070 fl := flag(t.Kind()) 2071 if ifaceIndir(t) { 2072 recv = Value{t, p, fl | flagIndir} 2073 } else { 2074 recv = Value{t, *(*unsafe.Pointer)(p), fl} 2075 } 2076 } 2077 return chosen, recv, recvOK 2078 } 2079 2080 /* 2081 * constructors 2082 */ 2083 2084 // implemented in package runtime 2085 func unsafe_New(*rtype) unsafe.Pointer 2086 func unsafe_NewArray(*rtype, int) unsafe.Pointer 2087 2088 // MakeSlice creates a new zero-initialized slice value 2089 // for the specified slice type, length, and capacity. 2090 func MakeSlice(typ Type, len, cap int) Value { 2091 if typ.Kind() != Slice { 2092 panic("reflect.MakeSlice of non-slice type") 2093 } 2094 if len < 0 { 2095 panic("reflect.MakeSlice: negative len") 2096 } 2097 if cap < 0 { 2098 panic("reflect.MakeSlice: negative cap") 2099 } 2100 if len > cap { 2101 panic("reflect.MakeSlice: len > cap") 2102 } 2103 2104 s := sliceHeader{unsafe_NewArray(typ.Elem().(*rtype), cap), len, cap} 2105 return Value{typ.common(), unsafe.Pointer(&s), flagIndir | flag(Slice)} 2106 } 2107 2108 // MakeChan creates a new channel with the specified type and buffer size. 2109 func MakeChan(typ Type, buffer int) Value { 2110 if typ.Kind() != Chan { 2111 panic("reflect.MakeChan of non-chan type") 2112 } 2113 if buffer < 0 { 2114 panic("reflect.MakeChan: negative buffer size") 2115 } 2116 if typ.ChanDir() != BothDir { 2117 panic("reflect.MakeChan: unidirectional channel type") 2118 } 2119 ch := makechan(typ.(*rtype), buffer) 2120 return Value{typ.common(), ch, flag(Chan)} 2121 } 2122 2123 // MakeMap creates a new map with the specified type. 2124 func MakeMap(typ Type) Value { 2125 return MakeMapWithSize(typ, 0) 2126 } 2127 2128 // MakeMapWithSize creates a new map with the specified type 2129 // and initial space for approximately n elements. 2130 func MakeMapWithSize(typ Type, n int) Value { 2131 if typ.Kind() != Map { 2132 panic("reflect.MakeMapWithSize of non-map type") 2133 } 2134 m := makemap(typ.(*rtype), n) 2135 return Value{typ.common(), m, flag(Map)} 2136 } 2137 2138 // Indirect returns the value that v points to. 2139 // If v is a nil pointer, Indirect returns a zero Value. 2140 // If v is not a pointer, Indirect returns v. 2141 func Indirect(v Value) Value { 2142 if v.Kind() != Ptr { 2143 return v 2144 } 2145 return v.Elem() 2146 } 2147 2148 // ValueOf returns a new Value initialized to the concrete value 2149 // stored in the interface i. ValueOf(nil) returns the zero Value. 2150 func ValueOf(i interface{}) Value { 2151 if i == nil { 2152 return Value{} 2153 } 2154 2155 // TODO: Maybe allow contents of a Value to live on the stack. 2156 // For now we make the contents always escape to the heap. It 2157 // makes life easier in a few places (see chanrecv/mapassign 2158 // comment below). 2159 escapes(i) 2160 2161 return unpackEface(i) 2162 } 2163 2164 // Zero returns a Value representing the zero value for the specified type. 2165 // The result is different from the zero value of the Value struct, 2166 // which represents no value at all. 2167 // For example, Zero(TypeOf(42)) returns a Value with Kind Int and value 0. 2168 // The returned value is neither addressable nor settable. 2169 func Zero(typ Type) Value { 2170 if typ == nil { 2171 panic("reflect: Zero(nil)") 2172 } 2173 t := typ.common() 2174 fl := flag(t.Kind()) 2175 if ifaceIndir(t) { 2176 return Value{t, unsafe_New(typ.(*rtype)), fl | flagIndir} 2177 } 2178 return Value{t, nil, fl} 2179 } 2180 2181 // New returns a Value representing a pointer to a new zero value 2182 // for the specified type. That is, the returned Value's Type is PtrTo(typ). 2183 func New(typ Type) Value { 2184 if typ == nil { 2185 panic("reflect: New(nil)") 2186 } 2187 ptr := unsafe_New(typ.(*rtype)) 2188 fl := flag(Ptr) 2189 return Value{typ.common().ptrTo(), ptr, fl} 2190 } 2191 2192 // NewAt returns a Value representing a pointer to a value of the 2193 // specified type, using p as that pointer. 2194 func NewAt(typ Type, p unsafe.Pointer) Value { 2195 fl := flag(Ptr) 2196 return Value{typ.common().ptrTo(), p, fl} 2197 } 2198 2199 // assignTo returns a value v that can be assigned directly to typ. 2200 // It panics if v is not assignable to typ. 2201 // For a conversion to an interface type, target is a suggested scratch space to use. 2202 func (v Value) assignTo(context string, dst *rtype, target unsafe.Pointer) Value { 2203 if v.flag&flagMethod != 0 { 2204 v = makeMethodValue(context, v) 2205 } 2206 2207 switch { 2208 case directlyAssignable(dst, v.typ): 2209 // Overwrite type so that they match. 2210 // Same memory layout, so no harm done. 2211 fl := v.flag&(flagAddr|flagIndir) | v.flag.ro() 2212 fl |= flag(dst.Kind()) 2213 return Value{dst, v.ptr, fl} 2214 2215 case implements(dst, v.typ): 2216 if target == nil { 2217 target = unsafe_New(dst) 2218 } 2219 if v.Kind() == Interface && v.IsNil() { 2220 // A nil ReadWriter passed to nil Reader is OK, 2221 // but using ifaceE2I below will panic. 2222 // Avoid the panic by returning a nil dst (e.g., Reader) explicitly. 2223 return Value{dst, nil, flag(Interface)} 2224 } 2225 x := valueInterface(v, false) 2226 if dst.NumMethod() == 0 { 2227 *(*interface{})(target) = x 2228 } else { 2229 ifaceE2I(dst, x, target) 2230 } 2231 return Value{dst, target, flagIndir | flag(Interface)} 2232 } 2233 2234 // Failed. 2235 panic(context + ": value of type " + v.typ.String() + " is not assignable to type " + dst.String()) 2236 } 2237 2238 // Convert returns the value v converted to type t. 2239 // If the usual Go conversion rules do not allow conversion 2240 // of the value v to type t, Convert panics. 2241 func (v Value) Convert(t Type) Value { 2242 if v.flag&flagMethod != 0 { 2243 v = makeMethodValue("Convert", v) 2244 } 2245 op := convertOp(t.common(), v.typ) 2246 if op == nil { 2247 panic("reflect.Value.Convert: value of type " + v.typ.String() + " cannot be converted to type " + t.String()) 2248 } 2249 return op(v, t) 2250 } 2251 2252 // convertOp returns the function to convert a value of type src 2253 // to a value of type dst. If the conversion is illegal, convertOp returns nil. 2254 func convertOp(dst, src *rtype) func(Value, Type) Value { 2255 switch src.Kind() { 2256 case Int, Int8, Int16, Int32, Int64: 2257 switch dst.Kind() { 2258 case Int, Int8, Int16, Int32, Int64, Uint, Uint8, Uint16, Uint32, Uint64, Uintptr: 2259 return cvtInt 2260 case Float32, Float64: 2261 return cvtIntFloat 2262 case String: 2263 return cvtIntString 2264 } 2265 2266 case Uint, Uint8, Uint16, Uint32, Uint64, Uintptr: 2267 switch dst.Kind() { 2268 case Int, Int8, Int16, Int32, Int64, Uint, Uint8, Uint16, Uint32, Uint64, Uintptr: 2269 return cvtUint 2270 case Float32, Float64: 2271 return cvtUintFloat 2272 case String: 2273 return cvtUintString 2274 } 2275 2276 case Float32, Float64: 2277 switch dst.Kind() { 2278 case Int, Int8, Int16, Int32, Int64: 2279 return cvtFloatInt 2280 case Uint, Uint8, Uint16, Uint32, Uint64, Uintptr: 2281 return cvtFloatUint 2282 case Float32, Float64: 2283 return cvtFloat 2284 } 2285 2286 case Complex64, Complex128: 2287 switch dst.Kind() { 2288 case Complex64, Complex128: 2289 return cvtComplex 2290 } 2291 2292 case String: 2293 if dst.Kind() == Slice && dst.Elem().PkgPath() == "" { 2294 switch dst.Elem().Kind() { 2295 case Uint8: 2296 return cvtStringBytes 2297 case Int32: 2298 return cvtStringRunes 2299 } 2300 } 2301 2302 case Slice: 2303 if dst.Kind() == String && src.Elem().PkgPath() == "" { 2304 switch src.Elem().Kind() { 2305 case Uint8: 2306 return cvtBytesString 2307 case Int32: 2308 return cvtRunesString 2309 } 2310 } 2311 } 2312 2313 // dst and src have same underlying type. 2314 if haveIdenticalUnderlyingType(dst, src, false) { 2315 return cvtDirect 2316 } 2317 2318 // dst and src are unnamed pointer types with same underlying base type. 2319 if dst.Kind() == Ptr && dst.Name() == "" && 2320 src.Kind() == Ptr && src.Name() == "" && 2321 haveIdenticalUnderlyingType(dst.Elem().common(), src.Elem().common(), false) { 2322 return cvtDirect 2323 } 2324 2325 if implements(dst, src) { 2326 if src.Kind() == Interface { 2327 return cvtI2I 2328 } 2329 return cvtT2I 2330 } 2331 2332 return nil 2333 } 2334 2335 // makeInt returns a Value of type t equal to bits (possibly truncated), 2336 // where t is a signed or unsigned int type. 2337 func makeInt(f flag, bits uint64, t Type) Value { 2338 typ := t.common() 2339 ptr := unsafe_New(typ) 2340 switch typ.size { 2341 case 1: 2342 *(*uint8)(ptr) = uint8(bits) 2343 case 2: 2344 *(*uint16)(ptr) = uint16(bits) 2345 case 4: 2346 *(*uint32)(ptr) = uint32(bits) 2347 case 8: 2348 *(*uint64)(ptr) = bits 2349 } 2350 return Value{typ, ptr, f | flagIndir | flag(typ.Kind())} 2351 } 2352 2353 // makeFloat returns a Value of type t equal to v (possibly truncated to float32), 2354 // where t is a float32 or float64 type. 2355 func makeFloat(f flag, v float64, t Type) Value { 2356 typ := t.common() 2357 ptr := unsafe_New(typ) 2358 switch typ.size { 2359 case 4: 2360 *(*float32)(ptr) = float32(v) 2361 case 8: 2362 *(*float64)(ptr) = v 2363 } 2364 return Value{typ, ptr, f | flagIndir | flag(typ.Kind())} 2365 } 2366 2367 // makeComplex returns a Value of type t equal to v (possibly truncated to complex64), 2368 // where t is a complex64 or complex128 type. 2369 func makeComplex(f flag, v complex128, t Type) Value { 2370 typ := t.common() 2371 ptr := unsafe_New(typ) 2372 switch typ.size { 2373 case 8: 2374 *(*complex64)(ptr) = complex64(v) 2375 case 16: 2376 *(*complex128)(ptr) = v 2377 } 2378 return Value{typ, ptr, f | flagIndir | flag(typ.Kind())} 2379 } 2380 2381 func makeString(f flag, v string, t Type) Value { 2382 ret := New(t).Elem() 2383 ret.SetString(v) 2384 ret.flag = ret.flag&^flagAddr | f 2385 return ret 2386 } 2387 2388 func makeBytes(f flag, v []byte, t Type) Value { 2389 ret := New(t).Elem() 2390 ret.SetBytes(v) 2391 ret.flag = ret.flag&^flagAddr | f 2392 return ret 2393 } 2394 2395 func makeRunes(f flag, v []rune, t Type) Value { 2396 ret := New(t).Elem() 2397 ret.setRunes(v) 2398 ret.flag = ret.flag&^flagAddr | f 2399 return ret 2400 } 2401 2402 // These conversion functions are returned by convertOp 2403 // for classes of conversions. For example, the first function, cvtInt, 2404 // takes any value v of signed int type and returns the value converted 2405 // to type t, where t is any signed or unsigned int type. 2406 2407 // convertOp: intXX -> [u]intXX 2408 func cvtInt(v Value, t Type) Value { 2409 return makeInt(v.flag.ro(), uint64(v.Int()), t) 2410 } 2411 2412 // convertOp: uintXX -> [u]intXX 2413 func cvtUint(v Value, t Type) Value { 2414 return makeInt(v.flag.ro(), v.Uint(), t) 2415 } 2416 2417 // convertOp: floatXX -> intXX 2418 func cvtFloatInt(v Value, t Type) Value { 2419 return makeInt(v.flag.ro(), uint64(int64(v.Float())), t) 2420 } 2421 2422 // convertOp: floatXX -> uintXX 2423 func cvtFloatUint(v Value, t Type) Value { 2424 return makeInt(v.flag.ro(), uint64(v.Float()), t) 2425 } 2426 2427 // convertOp: intXX -> floatXX 2428 func cvtIntFloat(v Value, t Type) Value { 2429 return makeFloat(v.flag.ro(), float64(v.Int()), t) 2430 } 2431 2432 // convertOp: uintXX -> floatXX 2433 func cvtUintFloat(v Value, t Type) Value { 2434 return makeFloat(v.flag.ro(), float64(v.Uint()), t) 2435 } 2436 2437 // convertOp: floatXX -> floatXX 2438 func cvtFloat(v Value, t Type) Value { 2439 return makeFloat(v.flag.ro(), v.Float(), t) 2440 } 2441 2442 // convertOp: complexXX -> complexXX 2443 func cvtComplex(v Value, t Type) Value { 2444 return makeComplex(v.flag.ro(), v.Complex(), t) 2445 } 2446 2447 // convertOp: intXX -> string 2448 func cvtIntString(v Value, t Type) Value { 2449 return makeString(v.flag.ro(), string(v.Int()), t) 2450 } 2451 2452 // convertOp: uintXX -> string 2453 func cvtUintString(v Value, t Type) Value { 2454 return makeString(v.flag.ro(), string(v.Uint()), t) 2455 } 2456 2457 // convertOp: []byte -> string 2458 func cvtBytesString(v Value, t Type) Value { 2459 return makeString(v.flag.ro(), string(v.Bytes()), t) 2460 } 2461 2462 // convertOp: string -> []byte 2463 func cvtStringBytes(v Value, t Type) Value { 2464 return makeBytes(v.flag.ro(), []byte(v.String()), t) 2465 } 2466 2467 // convertOp: []rune -> string 2468 func cvtRunesString(v Value, t Type) Value { 2469 return makeString(v.flag.ro(), string(v.runes()), t) 2470 } 2471 2472 // convertOp: string -> []rune 2473 func cvtStringRunes(v Value, t Type) Value { 2474 return makeRunes(v.flag.ro(), []rune(v.String()), t) 2475 } 2476 2477 // convertOp: direct copy 2478 func cvtDirect(v Value, typ Type) Value { 2479 f := v.flag 2480 t := typ.common() 2481 ptr := v.ptr 2482 if f&flagAddr != 0 { 2483 // indirect, mutable word - make a copy 2484 c := unsafe_New(t) 2485 typedmemmove(t, c, ptr) 2486 ptr = c 2487 f &^= flagAddr 2488 } 2489 return Value{t, ptr, v.flag.ro() | f} // v.flag.ro()|f == f? 2490 } 2491 2492 // convertOp: concrete -> interface 2493 func cvtT2I(v Value, typ Type) Value { 2494 target := unsafe_New(typ.common()) 2495 x := valueInterface(v, false) 2496 if typ.NumMethod() == 0 { 2497 *(*interface{})(target) = x 2498 } else { 2499 ifaceE2I(typ.(*rtype), x, target) 2500 } 2501 return Value{typ.common(), target, v.flag.ro() | flagIndir | flag(Interface)} 2502 } 2503 2504 // convertOp: interface -> interface 2505 func cvtI2I(v Value, typ Type) Value { 2506 if v.IsNil() { 2507 ret := Zero(typ) 2508 ret.flag |= v.flag.ro() 2509 return ret 2510 } 2511 return cvtT2I(v.Elem(), typ) 2512 } 2513 2514 // implemented in ../runtime 2515 func chancap(ch unsafe.Pointer) int 2516 func chanclose(ch unsafe.Pointer) 2517 func chanlen(ch unsafe.Pointer) int 2518 2519 // Note: some of the noescape annotations below are technically a lie, 2520 // but safe in the context of this package. Functions like chansend 2521 // and mapassign don't escape the referent, but may escape anything 2522 // the referent points to (they do shallow copies of the referent). 2523 // It is safe in this package because the referent may only point 2524 // to something a Value may point to, and that is always in the heap 2525 // (due to the escapes() call in ValueOf). 2526 2527 //go:noescape 2528 func chanrecv(ch unsafe.Pointer, nb bool, val unsafe.Pointer) (selected, received bool) 2529 2530 //go:noescape 2531 func chansend(ch unsafe.Pointer, val unsafe.Pointer, nb bool) bool 2532 2533 func makechan(typ *rtype, size int) (ch unsafe.Pointer) 2534 func makemap(t *rtype, cap int) (m unsafe.Pointer) 2535 2536 //go:noescape 2537 func mapaccess(t *rtype, m unsafe.Pointer, key unsafe.Pointer) (val unsafe.Pointer) 2538 2539 //go:noescape 2540 func mapassign(t *rtype, m unsafe.Pointer, key, val unsafe.Pointer) 2541 2542 //go:noescape 2543 func mapdelete(t *rtype, m unsafe.Pointer, key unsafe.Pointer) 2544 2545 // m escapes into the return value, but the caller of mapiterinit 2546 // doesn't let the return value escape. 2547 //go:noescape 2548 func mapiterinit(t *rtype, m unsafe.Pointer) unsafe.Pointer 2549 2550 //go:noescape 2551 func mapiterkey(it unsafe.Pointer) (key unsafe.Pointer) 2552 2553 //go:noescape 2554 func mapiternext(it unsafe.Pointer) 2555 2556 //go:noescape 2557 func maplen(m unsafe.Pointer) int 2558 2559 // call calls fn with a copy of the n argument bytes pointed at by arg. 2560 // After fn returns, reflectcall copies n-retoffset result bytes 2561 // back into arg+retoffset before returning. If copying result bytes back, 2562 // the caller must pass the argument frame type as argtype, so that 2563 // call can execute appropriate write barriers during the copy. 2564 func call(argtype *rtype, fn, arg unsafe.Pointer, n uint32, retoffset uint32) 2565 2566 func ifaceE2I(t *rtype, src interface{}, dst unsafe.Pointer) 2567 2568 // typedmemmove copies a value of type t to dst from src. 2569 //go:noescape 2570 func typedmemmove(t *rtype, dst, src unsafe.Pointer) 2571 2572 // typedmemmovepartial is like typedmemmove but assumes that 2573 // dst and src point off bytes into the value and only copies size bytes. 2574 //go:noescape 2575 func typedmemmovepartial(t *rtype, dst, src unsafe.Pointer, off, size uintptr) 2576 2577 // typedslicecopy copies a slice of elemType values from src to dst, 2578 // returning the number of elements copied. 2579 //go:noescape 2580 func typedslicecopy(elemType *rtype, dst, src sliceHeader) int 2581 2582 //go:noescape 2583 func memclrNoHeapPointers(ptr unsafe.Pointer, n uintptr) 2584 2585 // Dummy annotation marking that the value x escapes, 2586 // for use in cases where the reflect code is so clever that 2587 // the compiler cannot follow. 2588 func escapes(x interface{}) { 2589 if dummy.b { 2590 dummy.x = x 2591 } 2592 } 2593 2594 var dummy struct { 2595 b bool 2596 x interface{} 2597 }