// $G $F.go && $L $F.$A && ./$A.out // Copyright 2009 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package main import ( "fmt"; "strconv"; ) const arraylen = 2; // BUG: shouldn't need this func P(a []string) string { s := "{"; for i := 0; i < len(a); i++ { if i > 0 { s += "," } s += `"` + a[i] + `"`; } s +="}"; return s; } func main() { // Test a map literal. mlit := map[string] int { "0":0, "1":1, "2":2, "3":3, "4":4 }; for i := 0; i < len(mlit); i++ { s := string([]byte{byte(i)+'0'}); if mlit[s] != i { fmt.Printf("mlit[%s] = %d\n", s, mlit[s]) } } mib := make(map[int] bool); mii := make(map[int] int); mfi := make(map[float] int); mif := make(map[int] float); msi := make(map[string] int); mis := make(map[int] string); mss := make(map[string] string); mspa := make(map[string] []string); // BUG need an interface map both ways too type T struct { i int64; // can't use string here; struct values are only compared at the top level f float; }; mipT := make(map[int] *T); mpTi := make(map[*T] int); mit := make(map[int] T); // mti := make(map[T] int); type M map[int] int; mipM := make(map[int] M); const count = 1000; var apT [2*count]*T; for i := 0; i < count; i++ { s := strconv.Itoa(i); s10 := strconv.Itoa(i*10); f := float(i); t := T{int64(i),f}; apT[i] = new(T); apT[i].i = int64(i); apT[i].f = f; apT[2*i] = new(T); // need twice as many entries as we use, for the nonexistence check apT[2*i].i = int64(i); apT[2*i].f = f; m := M{i: i+1}; mib[i] = (i != 0); mii[i] = 10*i; mfi[float(i)] = 10*i; mif[i] = 10.0*f; mis[i] = s; msi[s] = i; mss[s] = s10; mss[s] = s10; as := make([]string, arraylen); as[0] = s10; as[1] = s10; mspa[s] = as; mipT[i] = apT[i]; mpTi[apT[i]] = i; mipM[i] = m; mit[i] = t; // mti[t] = i; } // test len if len(mib) != count { fmt.Printf("len(mib) = %d\n", len(mib)); } if len(mii) != count { fmt.Printf("len(mii) = %d\n", len(mii)); } if len(mfi) != count { fmt.Printf("len(mfi) = %d\n", len(mfi)); } if len(mif) != count { fmt.Printf("len(mif) = %d\n", len(mif)); } if len(msi) != count { fmt.Printf("len(msi) = %d\n", len(msi)); } if len(mis) != count { fmt.Printf("len(mis) = %d\n", len(mis)); } if len(mss) != count { fmt.Printf("len(mss) = %d\n", len(mss)); } if len(mspa) != count { fmt.Printf("len(mspa) = %d\n", len(mspa)); } if len(mipT) != count { fmt.Printf("len(mipT) = %d\n", len(mipT)); } if len(mpTi) != count { fmt.Printf("len(mpTi) = %d\n", len(mpTi)); } // if len(mti) != count { // fmt.Printf("len(mti) = %d\n", len(mti)); // } if len(mipM) != count { fmt.Printf("len(mipM) = %d\n", len(mipM)); } // if len(mti) != count { // fmt.Printf("len(mti) = %d\n", len(mti)); // } if len(mit) != count { fmt.Printf("len(mit) = %d\n", len(mit)); } // test construction directly for i := 0; i < count; i++ { s := strconv.Itoa(i); s10 := strconv.Itoa(i*10); f := float(i); t := T{int64(i), f}; // BUG m := M(i, i+1); if mib[i] != (i != 0) { fmt.Printf("mib[%d] = %t\n", i, mib[i]); } if(mii[i] != 10*i) { fmt.Printf("mii[%d] = %d\n", i, mii[i]); } if(mfi[f] != 10*i) { fmt.Printf("mfi[%d] = %d\n", i, mfi[f]); } if(mif[i] != 10.0*f) { fmt.Printf("mif[%d] = %g\n", i, mif[i]); } if(mis[i] != s) { fmt.Printf("mis[%d] = %s\n", i, mis[i]); } if(msi[s] != i) { fmt.Printf("msi[%s] = %d\n", s, msi[s]); } if mss[s] != s10 { fmt.Printf("mss[%s] = %g\n", s, mss[s]); } for j := 0; j < arraylen; j++ { if mspa[s][j] != s10 { fmt.Printf("mspa[%s][%d] = %s\n", s, j, mspa[s][j]); } } if(mipT[i].i != int64(i) || mipT[i].f != f) { fmt.Printf("mipT[%d] = %v\n", i, mipT[i]); } if(mpTi[apT[i]] != i) { fmt.Printf("mpTi[apT[%d]] = %d\n", i, mpTi[apT[i]]); } // if(mti[t] != i) { // fmt.Printf("mti[%s] = %s\n", s, mti[t]); // } if (mipM[i][i] != i + 1) { fmt.Printf("mipM[%d][%d] = %d\n", i, i, mipM[i][i]); } // if(mti[t] != i) { // fmt.Printf("mti[%v] = %d\n", t, mti[t]); // } if(mit[i].i != int64(i) || mit[i].f != f) { fmt.Printf("mit[%d] = {%d %g}\n", i, mit[i].i, mit[i].f); } } // test existence with tuple check // failed lookups yield a false value for the boolean. for i := 0; i < count; i++ { s := strconv.Itoa(i); f := float(i); t := T{int64(i), f}; { a, b := mib[i]; if !b { fmt.Printf("tuple existence decl: mib[%d]\n", i); } a, b = mib[i]; if !b { fmt.Printf("tuple existence assign: mib[%d]\n", i); } } { a, b := mii[i]; if !b { fmt.Printf("tuple existence decl: mii[%d]\n", i); } a, b = mii[i]; if !b { fmt.Printf("tuple existence assign: mii[%d]\n", i); } } { a, b := mfi[f]; if !b { fmt.Printf("tuple existence decl: mfi[%d]\n", i); } a, b = mfi[f]; if !b { fmt.Printf("tuple existence assign: mfi[%d]\n", i); } } { a, b := mif[i]; if !b { fmt.Printf("tuple existence decl: mif[%d]\n", i); } a, b = mif[i]; if !b { fmt.Printf("tuple existence assign: mif[%d]\n", i); } } { a, b := mis[i]; if !b { fmt.Printf("tuple existence decl: mis[%d]\n", i); } a, b = mis[i]; if !b { fmt.Printf("tuple existence assign: mis[%d]\n", i); } } { a, b := msi[s]; if !b { fmt.Printf("tuple existence decl: msi[%d]\n", i); } a, b = msi[s]; if !b { fmt.Printf("tuple existence assign: msi[%d]\n", i); } } { a, b := mss[s]; if !b { fmt.Printf("tuple existence decl: mss[%d]\n", i); } a, b = mss[s]; if !b { fmt.Printf("tuple existence assign: mss[%d]\n", i); } } { a, b := mspa[s]; if !b { fmt.Printf("tuple existence decl: mspa[%d]\n", i); } a, b = mspa[s]; if !b { fmt.Printf("tuple existence assign: mspa[%d]\n", i); } } { a, b := mipT[i]; if !b { fmt.Printf("tuple existence decl: mipT[%d]\n", i); } a, b = mipT[i]; if !b { fmt.Printf("tuple existence assign: mipT[%d]\n", i); } } { a, b := mpTi[apT[i]]; if !b { fmt.Printf("tuple existence decl: mpTi[apT[%d]]\n", i); } a, b = mpTi[apT[i]]; if !b { fmt.Printf("tuple existence assign: mpTi[apT[%d]]\n", i); } } { a, b := mipM[i]; if !b { fmt.Printf("tuple existence decl: mipM[%d]\n", i); } a, b = mipM[i]; if !b { fmt.Printf("tuple existence assign: mipM[%d]\n", i); } } { a, b := mit[i]; if !b { fmt.Printf("tuple existence decl: mit[%d]\n", i); } a, b = mit[i]; if !b { fmt.Printf("tuple existence assign: mit[%d]\n", i); } } // { // a, b := mti[t]; // if !b { // fmt.Printf("tuple existence decl: mti[%d]\n", i); // } // a, b = mti[t]; // if !b { // fmt.Printf("tuple existence assign: mti[%d]\n", i); // } // } } // test nonexistence with tuple check // failed lookups yield a false value for the boolean. for i := count; i < 2*count; i++ { s := strconv.Itoa(i); f := float(i); t := T{int64(i),f}; { a, b := mib[i]; if b { fmt.Printf("tuple nonexistence decl: mib[%d]", i); } a, b = mib[i]; if b { fmt.Printf("tuple nonexistence assign: mib[%d]", i); } } { a, b := mii[i]; if b { fmt.Printf("tuple nonexistence decl: mii[%d]", i); } a, b = mii[i]; if b { fmt.Printf("tuple nonexistence assign: mii[%d]", i); } } { a, b := mfi[f]; if b { fmt.Printf("tuple nonexistence decl: mfi[%d]", i); } a, b = mfi[f]; if b { fmt.Printf("tuple nonexistence assign: mfi[%d]", i); } } { a, b := mif[i]; if b { fmt.Printf("tuple nonexistence decl: mif[%d]", i); } a, b = mif[i]; if b { fmt.Printf("tuple nonexistence assign: mif[%d]", i); } } { a, b := mis[i]; if b { fmt.Printf("tuple nonexistence decl: mis[%d]", i); } a, b = mis[i]; if b { fmt.Printf("tuple nonexistence assign: mis[%d]", i); } } { a, b := msi[s]; if b { fmt.Printf("tuple nonexistence decl: msi[%d]", i); } a, b = msi[s]; if b { fmt.Printf("tuple nonexistence assign: msi[%d]", i); } } { a, b := mss[s]; if b { fmt.Printf("tuple nonexistence decl: mss[%d]", i); } a, b = mss[s]; if b { fmt.Printf("tuple nonexistence assign: mss[%d]", i); } } { a, b := mspa[s]; if b { fmt.Printf("tuple nonexistence decl: mspa[%d]", i); } a, b = mspa[s]; if b { fmt.Printf("tuple nonexistence assign: mspa[%d]", i); } } { a, b := mipT[i]; if b { fmt.Printf("tuple nonexistence decl: mipT[%d]", i); } a, b = mipT[i]; if b { fmt.Printf("tuple nonexistence assign: mipT[%d]", i); } } { a, b := mpTi[apT[i]]; if b { fmt.Printf("tuple nonexistence decl: mpTi[apt[%d]]", i); } a, b = mpTi[apT[i]]; if b { fmt.Printf("tuple nonexistence assign: mpTi[apT[%d]]", i); } } { a, b := mipM[i]; if b { fmt.Printf("tuple nonexistence decl: mipM[%d]", i); } a, b = mipM[i]; if b { fmt.Printf("tuple nonexistence assign: mipM[%d]", i); } } // { // a, b := mti[t]; // if b { // fmt.Printf("tuple nonexistence decl: mti[%d]", i); // } // a, b = mti[t]; // if b { // fmt.Printf("tuple nonexistence assign: mti[%d]", i); // } // } { a, b := mit[i]; if b { fmt.Printf("tuple nonexistence decl: mit[%d]", i); } a, b = mit[i]; if b { fmt.Printf("tuple nonexistence assign: mit[%d]", i); } } } // tests for structured map element updates for i := 0; i < count; i++ { s := strconv.Itoa(i); mspa[s][i % 2] = "deleted"; if mspa[s][i % 2] != "deleted" { fmt.Printf("update mspa[%s][%d] = %s\n", s, i %2, mspa[s][i % 2]); } mipT[i].i += 1; if mipT[i].i != int64(i)+1 { fmt.Printf("update mipT[%d].i = %d\n", i, mipT[i].i); } mipT[i].f = float(i + 1); if (mipT[i].f != float(i + 1)) { fmt.Printf("update mipT[%d].f = %g\n", i, mipT[i].f); } mipM[i][i]++; if mipM[i][i] != (i + 1) + 1 { fmt.Printf("update mipM[%d][%d] = %i\n", i, i, mipM[i][i]); } } }