func TestDecGobEncoding(t *testing.T) { var medium bytes.Buffer enc := gob.NewEncoder(&medium) dec := gob.NewDecoder(&medium) for i, test := range decGobEncodingTests { for j := 0; j < 2; j++ { for k := inf.Scale(-5); k <= 5; k++ { medium.Reset() // empty buffer for each test case (in case of failures) stest := test if j != 0 { // negative numbers stest = "-" + test } var tx inf.Dec tx.SetString(stest) tx.SetScale(k) // test with positive, negative, and zero scale if err := enc.Encode(&tx); err != nil { t.Errorf("#%d%c: encoding failed: %s", i, 'a'+j, err) } var rx inf.Dec if err := dec.Decode(&rx); err != nil { t.Errorf("#%d%c: decoding failed: %s", i, 'a'+j, err) } if rx.Cmp(&tx) != 0 { t.Errorf("#%d%c: transmission failed: got %s want %s", i, 'a'+j, &rx, &tx) } } } } }
func TestDecAbsZ(t *testing.T) { var zero inf.Dec for _, a := range decSumZZ { var z inf.Dec z.Abs(a.z) var e inf.Dec e.Set(a.z) if e.Cmp(&zero) < 0 { e.Sub(&zero, &e) } if z.Cmp(&e) != 0 { t.Errorf("got z = %v; want %v", z, e) } } }
func TestDecSetString(t *testing.T) { tmp := new(inf.Dec) for i, test := range decStringTests { if test.scale < 0 { // SetString only supports scale >= 0 continue } // initialize to a non-zero value so that issues with parsing // 0 are detected tmp.Set(inf.NewDec(1234567890, 123)) n1, ok1 := new(inf.Dec).SetString(test.in) n2, ok2 := tmp.SetString(test.in) expected := inf.NewDec(test.val, test.scale) if ok1 != test.ok || ok2 != test.ok { t.Errorf("#%d (input '%s') ok incorrect (should be %t)", i, test.in, test.ok) continue } if !ok1 { if n1 != nil { t.Errorf("#%d (input '%s') n1 != nil", i, test.in) } continue } if !ok2 { if n2 != nil { t.Errorf("#%d (input '%s') n2 != nil", i, test.in) } continue } if n1.Cmp(expected) != 0 { t.Errorf("#%d (input '%s') got: %s want: %d", i, test.in, n1, test.val) } if n2.Cmp(expected) != 0 { t.Errorf("#%d (input '%s') got: %s want: %d", i, test.in, n2, test.val) } } }
// ParseQuantity turns str into a Quantity, or returns an error. func ParseQuantity(str string) (*Quantity, error) { parts := splitRE.FindStringSubmatch(strings.TrimSpace(str)) // regexp returns are entire match, followed by an entry for each () section. if len(parts) != 3 { return nil, ErrFormatWrong } amount := new(inf.Dec) if _, ok := amount.SetString(parts[1]); !ok { return nil, ErrNumeric } base, exponent, format, ok := quantitySuffixer.interpret(suffix(parts[2])) if !ok { return nil, ErrSuffix } // So that no one but us has to think about suffixes, remove it. if base == 10 { amount.SetScale(amount.Scale() + inf.Scale(-exponent)) } else if base == 2 { // numericSuffix = 2 ** exponent numericSuffix := big.NewInt(1).Lsh(bigOne, uint(exponent)) ub := amount.UnscaledBig() amount.SetUnscaledBig(ub.Mul(ub, numericSuffix)) } // Cap at min/max bounds. sign := amount.Sign() if sign == -1 { amount.Neg(amount) } // This rounds non-zero values up to the minimum representable // value, under the theory that if you want some resources, you // should get some resources, even if you asked for way too small // of an amount. // Arguably, this should be inf.RoundHalfUp (normal rounding), but // that would have the side effect of rounding values < .5m to zero. if v, ok := amount.Unscaled(); v != int64(0) || !ok { amount.Round(amount, 3, inf.RoundUp) } // The max is just a simple cap. if amount.Cmp(maxAllowed) > 0 { amount.Set(maxAllowed) } if format == BinarySI && amount.Cmp(decOne) < 0 && amount.Cmp(decZero) > 0 { // This avoids rounding and hopefully confusion, too. format = DecimalSI } if sign == -1 { amount.Neg(amount) } return &Quantity{amount, format}, nil }