| /* |
| Copyright 2014 The Kubernetes Authors. |
| |
| Licensed under the Apache License, Version 2.0 (the "License"); |
| you may not use this file except in compliance with the License. |
| You may obtain a copy of the License at |
| |
| http://www.apache.org/licenses/LICENSE-2.0 |
| |
| Unless required by applicable law or agreed to in writing, software |
| distributed under the License is distributed on an "AS IS" BASIS, |
| WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. |
| See the License for the specific language governing permissions and |
| limitations under the License. |
| */ |
| |
| package resource |
| |
| import ( |
| "bytes" |
| "errors" |
| "fmt" |
| "math/big" |
| "strconv" |
| "strings" |
| |
| inf "gopkg.in/inf.v0" |
| ) |
| |
| // Quantity is a fixed-point representation of a number. |
| // It provides convenient marshaling/unmarshaling in JSON and YAML, |
| // in addition to String() and Int64() accessors. |
| // |
| // The serialization format is: |
| // |
| // <quantity> ::= <signedNumber><suffix> |
| // (Note that <suffix> may be empty, from the "" case in <decimalSI>.) |
| // <digit> ::= 0 | 1 | ... | 9 |
| // <digits> ::= <digit> | <digit><digits> |
| // <number> ::= <digits> | <digits>.<digits> | <digits>. | .<digits> |
| // <sign> ::= "+" | "-" |
| // <signedNumber> ::= <number> | <sign><number> |
| // <suffix> ::= <binarySI> | <decimalExponent> | <decimalSI> |
| // <binarySI> ::= Ki | Mi | Gi | Ti | Pi | Ei |
| // (International System of units; See: http://physics.nist.gov/cuu/Units/binary.html) |
| // <decimalSI> ::= m | "" | k | M | G | T | P | E |
| // (Note that 1024 = 1Ki but 1000 = 1k; I didn't choose the capitalization.) |
| // <decimalExponent> ::= "e" <signedNumber> | "E" <signedNumber> |
| // |
| // No matter which of the three exponent forms is used, no quantity may represent |
| // a number greater than 2^63-1 in magnitude, nor may it have more than 3 decimal |
| // places. Numbers larger or more precise will be capped or rounded up. |
| // (E.g.: 0.1m will rounded up to 1m.) |
| // This may be extended in the future if we require larger or smaller quantities. |
| // |
| // When a Quantity is parsed from a string, it will remember the type of suffix |
| // it had, and will use the same type again when it is serialized. |
| // |
| // Before serializing, Quantity will be put in "canonical form". |
| // This means that Exponent/suffix will be adjusted up or down (with a |
| // corresponding increase or decrease in Mantissa) such that: |
| // a. No precision is lost |
| // b. No fractional digits will be emitted |
| // c. The exponent (or suffix) is as large as possible. |
| // The sign will be omitted unless the number is negative. |
| // |
| // Examples: |
| // 1.5 will be serialized as "1500m" |
| // 1.5Gi will be serialized as "1536Mi" |
| // |
| // Note that the quantity will NEVER be internally represented by a |
| // floating point number. That is the whole point of this exercise. |
| // |
| // Non-canonical values will still parse as long as they are well formed, |
| // but will be re-emitted in their canonical form. (So always use canonical |
| // form, or don't diff.) |
| // |
| // This format is intended to make it difficult to use these numbers without |
| // writing some sort of special handling code in the hopes that that will |
| // cause implementors to also use a fixed point implementation. |
| // |
| // +protobuf=true |
| // +protobuf.embed=string |
| // +protobuf.options.marshal=false |
| // +protobuf.options.(gogoproto.goproto_stringer)=false |
| // +k8s:deepcopy-gen=true |
| // +k8s:openapi-gen=true |
| type Quantity struct { |
| // i is the quantity in int64 scaled form, if d.Dec == nil |
| i int64Amount |
| // d is the quantity in inf.Dec form if d.Dec != nil |
| d infDecAmount |
| // s is the generated value of this quantity to avoid recalculation |
| s string |
| |
| // Change Format at will. See the comment for Canonicalize for |
| // more details. |
| Format |
| } |
| |
| // CanonicalValue allows a quantity amount to be converted to a string. |
| type CanonicalValue interface { |
| // AsCanonicalBytes returns a byte array representing the string representation |
| // of the value mantissa and an int32 representing its exponent in base-10. Callers may |
| // pass a byte slice to the method to avoid allocations. |
| AsCanonicalBytes(out []byte) ([]byte, int32) |
| // AsCanonicalBase1024Bytes returns a byte array representing the string representation |
| // of the value mantissa and an int32 representing its exponent in base-1024. Callers |
| // may pass a byte slice to the method to avoid allocations. |
| AsCanonicalBase1024Bytes(out []byte) ([]byte, int32) |
| } |
| |
| // Format lists the three possible formattings of a quantity. |
| type Format string |
| |
| const ( |
| DecimalExponent = Format("DecimalExponent") // e.g., 12e6 |
| BinarySI = Format("BinarySI") // e.g., 12Mi (12 * 2^20) |
| DecimalSI = Format("DecimalSI") // e.g., 12M (12 * 10^6) |
| ) |
| |
| // MustParse turns the given string into a quantity or panics; for tests |
| // or others cases where you know the string is valid. |
| func MustParse(str string) Quantity { |
| q, err := ParseQuantity(str) |
| if err != nil { |
| panic(fmt.Errorf("cannot parse '%v': %v", str, err)) |
| } |
| return q |
| } |
| |
| const ( |
| // splitREString is used to separate a number from its suffix; as such, |
| // this is overly permissive, but that's OK-- it will be checked later. |
| splitREString = "^([+-]?[0-9.]+)([eEinumkKMGTP]*[-+]?[0-9]*)$" |
| ) |
| |
| var ( |
| // Errors that could happen while parsing a string. |
| ErrFormatWrong = errors.New("quantities must match the regular expression '" + splitREString + "'") |
| ErrNumeric = errors.New("unable to parse numeric part of quantity") |
| ErrSuffix = errors.New("unable to parse quantity's suffix") |
| ) |
| |
| // parseQuantityString is a fast scanner for quantity values. |
| func parseQuantityString(str string) (positive bool, value, num, denom, suffix string, err error) { |
| positive = true |
| pos := 0 |
| end := len(str) |
| |
| // handle leading sign |
| if pos < end { |
| switch str[0] { |
| case '-': |
| positive = false |
| pos++ |
| case '+': |
| pos++ |
| } |
| } |
| |
| // strip leading zeros |
| Zeroes: |
| for i := pos; ; i++ { |
| if i >= end { |
| num = "0" |
| value = num |
| return |
| } |
| switch str[i] { |
| case '0': |
| pos++ |
| default: |
| break Zeroes |
| } |
| } |
| |
| // extract the numerator |
| Num: |
| for i := pos; ; i++ { |
| if i >= end { |
| num = str[pos:end] |
| value = str[0:end] |
| return |
| } |
| switch str[i] { |
| case '0', '1', '2', '3', '4', '5', '6', '7', '8', '9': |
| default: |
| num = str[pos:i] |
| pos = i |
| break Num |
| } |
| } |
| |
| // if we stripped all numerator positions, always return 0 |
| if len(num) == 0 { |
| num = "0" |
| } |
| |
| // handle a denominator |
| if pos < end && str[pos] == '.' { |
| pos++ |
| Denom: |
| for i := pos; ; i++ { |
| if i >= end { |
| denom = str[pos:end] |
| value = str[0:end] |
| return |
| } |
| switch str[i] { |
| case '0', '1', '2', '3', '4', '5', '6', '7', '8', '9': |
| default: |
| denom = str[pos:i] |
| pos = i |
| break Denom |
| } |
| } |
| // TODO: we currently allow 1.G, but we may not want to in the future. |
| // if len(denom) == 0 { |
| // err = ErrFormatWrong |
| // return |
| // } |
| } |
| value = str[0:pos] |
| |
| // grab the elements of the suffix |
| suffixStart := pos |
| for i := pos; ; i++ { |
| if i >= end { |
| suffix = str[suffixStart:end] |
| return |
| } |
| if !strings.ContainsAny(str[i:i+1], "eEinumkKMGTP") { |
| pos = i |
| break |
| } |
| } |
| if pos < end { |
| switch str[pos] { |
| case '-', '+': |
| pos++ |
| } |
| } |
| Suffix: |
| for i := pos; ; i++ { |
| if i >= end { |
| suffix = str[suffixStart:end] |
| return |
| } |
| switch str[i] { |
| case '0', '1', '2', '3', '4', '5', '6', '7', '8', '9': |
| default: |
| break Suffix |
| } |
| } |
| // we encountered a non decimal in the Suffix loop, but the last character |
| // was not a valid exponent |
| err = ErrFormatWrong |
| return |
| } |
| |
| // ParseQuantity turns str into a Quantity, or returns an error. |
| func ParseQuantity(str string) (Quantity, error) { |
| if len(str) == 0 { |
| return Quantity{}, ErrFormatWrong |
| } |
| if str == "0" { |
| return Quantity{Format: DecimalSI, s: str}, nil |
| } |
| |
| positive, value, num, denom, suf, err := parseQuantityString(str) |
| if err != nil { |
| return Quantity{}, err |
| } |
| |
| base, exponent, format, ok := quantitySuffixer.interpret(suffix(suf)) |
| if !ok { |
| return Quantity{}, ErrSuffix |
| } |
| |
| precision := int32(0) |
| scale := int32(0) |
| mantissa := int64(1) |
| switch format { |
| case DecimalExponent, DecimalSI: |
| scale = exponent |
| precision = maxInt64Factors - int32(len(num)+len(denom)) |
| case BinarySI: |
| scale = 0 |
| switch { |
| case exponent >= 0 && len(denom) == 0: |
| // only handle positive binary numbers with the fast path |
| mantissa = int64(int64(mantissa) << uint64(exponent)) |
| // 1Mi (2^20) has ~6 digits of decimal precision, so exponent*3/10 -1 is roughly the precision |
| precision = 15 - int32(len(num)) - int32(float32(exponent)*3/10) - 1 |
| default: |
| precision = -1 |
| } |
| } |
| |
| if precision >= 0 { |
| // if we have a denominator, shift the entire value to the left by the number of places in the |
| // denominator |
| scale -= int32(len(denom)) |
| if scale >= int32(Nano) { |
| shifted := num + denom |
| |
| var value int64 |
| value, err := strconv.ParseInt(shifted, 10, 64) |
| if err != nil { |
| return Quantity{}, ErrNumeric |
| } |
| if result, ok := int64Multiply(value, int64(mantissa)); ok { |
| if !positive { |
| result = -result |
| } |
| // if the number is in canonical form, reuse the string |
| switch format { |
| case BinarySI: |
| if exponent%10 == 0 && (value&0x07 != 0) { |
| return Quantity{i: int64Amount{value: result, scale: Scale(scale)}, Format: format, s: str}, nil |
| } |
| default: |
| if scale%3 == 0 && !strings.HasSuffix(shifted, "000") && shifted[0] != '0' { |
| return Quantity{i: int64Amount{value: result, scale: Scale(scale)}, Format: format, s: str}, nil |
| } |
| } |
| return Quantity{i: int64Amount{value: result, scale: Scale(scale)}, Format: format}, nil |
| } |
| } |
| } |
| |
| amount := new(inf.Dec) |
| if _, ok := amount.SetString(value); !ok { |
| return Quantity{}, ErrNumeric |
| } |
| |
| // So that no one but us has to think about suffixes, remove it. |
| if base == 10 { |
| amount.SetScale(amount.Scale() + Scale(exponent).infScale()) |
| } 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 < .5n to zero. |
| if v, ok := amount.Unscaled(); v != int64(0) || !ok { |
| amount.Round(amount, Nano.infScale(), inf.RoundUp) |
| } |
| |
| // The max is just a simple cap. |
| // TODO: this prevents accumulating quantities greater than int64, for instance quota across a cluster |
| if format == BinarySI && amount.Cmp(maxAllowed.Dec) > 0 { |
| amount.Set(maxAllowed.Dec) |
| } |
| |
| 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{d: infDecAmount{amount}, Format: format}, nil |
| } |
| |
| // DeepCopy returns a deep-copy of the Quantity value. Note that the method |
| // receiver is a value, so we can mutate it in-place and return it. |
| func (q Quantity) DeepCopy() Quantity { |
| if q.d.Dec != nil { |
| tmp := &inf.Dec{} |
| q.d.Dec = tmp.Set(q.d.Dec) |
| } |
| return q |
| } |
| |
| // OpenAPISchemaType is used by the kube-openapi generator when constructing |
| // the OpenAPI spec of this type. |
| // |
| // See: https://github.com/kubernetes/kube-openapi/tree/master/pkg/generators |
| func (_ Quantity) OpenAPISchemaType() []string { return []string{"string"} } |
| |
| // OpenAPISchemaFormat is used by the kube-openapi generator when constructing |
| // the OpenAPI spec of this type. |
| func (_ Quantity) OpenAPISchemaFormat() string { return "" } |
| |
| // CanonicalizeBytes returns the canonical form of q and its suffix (see comment on Quantity). |
| // |
| // Note about BinarySI: |
| // * If q.Format is set to BinarySI and q.Amount represents a non-zero value between |
| // -1 and +1, it will be emitted as if q.Format were DecimalSI. |
| // * Otherwise, if q.Format is set to BinarySI, fractional parts of q.Amount will be |
| // rounded up. (1.1i becomes 2i.) |
| func (q *Quantity) CanonicalizeBytes(out []byte) (result, suffix []byte) { |
| if q.IsZero() { |
| return zeroBytes, nil |
| } |
| |
| var rounded CanonicalValue |
| format := q.Format |
| switch format { |
| case DecimalExponent, DecimalSI: |
| case BinarySI: |
| if q.CmpInt64(-1024) > 0 && q.CmpInt64(1024) < 0 { |
| // This avoids rounding and hopefully confusion, too. |
| format = DecimalSI |
| } else { |
| var exact bool |
| if rounded, exact = q.AsScale(0); !exact { |
| // Don't lose precision-- show as DecimalSI |
| format = DecimalSI |
| } |
| } |
| default: |
| format = DecimalExponent |
| } |
| |
| // TODO: If BinarySI formatting is requested but would cause rounding, upgrade to |
| // one of the other formats. |
| switch format { |
| case DecimalExponent, DecimalSI: |
| number, exponent := q.AsCanonicalBytes(out) |
| suffix, _ := quantitySuffixer.constructBytes(10, exponent, format) |
| return number, suffix |
| default: |
| // format must be BinarySI |
| number, exponent := rounded.AsCanonicalBase1024Bytes(out) |
| suffix, _ := quantitySuffixer.constructBytes(2, exponent*10, format) |
| return number, suffix |
| } |
| } |
| |
| // AsInt64 returns a representation of the current value as an int64 if a fast conversion |
| // is possible. If false is returned, callers must use the inf.Dec form of this quantity. |
| func (q *Quantity) AsInt64() (int64, bool) { |
| if q.d.Dec != nil { |
| return 0, false |
| } |
| return q.i.AsInt64() |
| } |
| |
| // ToDec promotes the quantity in place to use an inf.Dec representation and returns itself. |
| func (q *Quantity) ToDec() *Quantity { |
| if q.d.Dec == nil { |
| q.d.Dec = q.i.AsDec() |
| q.i = int64Amount{} |
| } |
| return q |
| } |
| |
| // AsDec returns the quantity as represented by a scaled inf.Dec. |
| func (q *Quantity) AsDec() *inf.Dec { |
| if q.d.Dec != nil { |
| return q.d.Dec |
| } |
| q.d.Dec = q.i.AsDec() |
| q.i = int64Amount{} |
| return q.d.Dec |
| } |
| |
| // AsCanonicalBytes returns the canonical byte representation of this quantity as a mantissa |
| // and base 10 exponent. The out byte slice may be passed to the method to avoid an extra |
| // allocation. |
| func (q *Quantity) AsCanonicalBytes(out []byte) (result []byte, exponent int32) { |
| if q.d.Dec != nil { |
| return q.d.AsCanonicalBytes(out) |
| } |
| return q.i.AsCanonicalBytes(out) |
| } |
| |
| // IsZero returns true if the quantity is equal to zero. |
| func (q *Quantity) IsZero() bool { |
| if q.d.Dec != nil { |
| return q.d.Dec.Sign() == 0 |
| } |
| return q.i.value == 0 |
| } |
| |
| // Sign returns 0 if the quantity is zero, -1 if the quantity is less than zero, or 1 if the |
| // quantity is greater than zero. |
| func (q *Quantity) Sign() int { |
| if q.d.Dec != nil { |
| return q.d.Dec.Sign() |
| } |
| return q.i.Sign() |
| } |
| |
| // AsScale returns the current value, rounded up to the provided scale, and returns |
| // false if the scale resulted in a loss of precision. |
| func (q *Quantity) AsScale(scale Scale) (CanonicalValue, bool) { |
| if q.d.Dec != nil { |
| return q.d.AsScale(scale) |
| } |
| return q.i.AsScale(scale) |
| } |
| |
| // RoundUp updates the quantity to the provided scale, ensuring that the value is at |
| // least 1. False is returned if the rounding operation resulted in a loss of precision. |
| // Negative numbers are rounded away from zero (-9 scale 1 rounds to -10). |
| func (q *Quantity) RoundUp(scale Scale) bool { |
| if q.d.Dec != nil { |
| q.s = "" |
| d, exact := q.d.AsScale(scale) |
| q.d = d |
| return exact |
| } |
| // avoid clearing the string value if we have already calculated it |
| if q.i.scale >= scale { |
| return true |
| } |
| q.s = "" |
| i, exact := q.i.AsScale(scale) |
| q.i = i |
| return exact |
| } |
| |
| // Add adds the provide y quantity to the current value. If the current value is zero, |
| // the format of the quantity will be updated to the format of y. |
| func (q *Quantity) Add(y Quantity) { |
| q.s = "" |
| if q.d.Dec == nil && y.d.Dec == nil { |
| if q.i.value == 0 { |
| q.Format = y.Format |
| } |
| if q.i.Add(y.i) { |
| return |
| } |
| } else if q.IsZero() { |
| q.Format = y.Format |
| } |
| q.ToDec().d.Dec.Add(q.d.Dec, y.AsDec()) |
| } |
| |
| // Sub subtracts the provided quantity from the current value in place. If the current |
| // value is zero, the format of the quantity will be updated to the format of y. |
| func (q *Quantity) Sub(y Quantity) { |
| q.s = "" |
| if q.IsZero() { |
| q.Format = y.Format |
| } |
| if q.d.Dec == nil && y.d.Dec == nil && q.i.Sub(y.i) { |
| return |
| } |
| q.ToDec().d.Dec.Sub(q.d.Dec, y.AsDec()) |
| } |
| |
| // Cmp returns 0 if the quantity is equal to y, -1 if the quantity is less than y, or 1 if the |
| // quantity is greater than y. |
| func (q *Quantity) Cmp(y Quantity) int { |
| if q.d.Dec == nil && y.d.Dec == nil { |
| return q.i.Cmp(y.i) |
| } |
| return q.AsDec().Cmp(y.AsDec()) |
| } |
| |
| // CmpInt64 returns 0 if the quantity is equal to y, -1 if the quantity is less than y, or 1 if the |
| // quantity is greater than y. |
| func (q *Quantity) CmpInt64(y int64) int { |
| if q.d.Dec != nil { |
| return q.d.Dec.Cmp(inf.NewDec(y, inf.Scale(0))) |
| } |
| return q.i.Cmp(int64Amount{value: y}) |
| } |
| |
| // Neg sets quantity to be the negative value of itself. |
| func (q *Quantity) Neg() { |
| q.s = "" |
| if q.d.Dec == nil { |
| q.i.value = -q.i.value |
| return |
| } |
| q.d.Dec.Neg(q.d.Dec) |
| } |
| |
| // Equal checks equality of two Quantities. This is useful for testing with |
| // cmp.Equal. |
| func (q Quantity) Equal(v Quantity) bool { |
| return q.Cmp(v) == 0 |
| } |
| |
| // int64QuantityExpectedBytes is the expected width in bytes of the canonical string representation |
| // of most Quantity values. |
| const int64QuantityExpectedBytes = 18 |
| |
| // String formats the Quantity as a string, caching the result if not calculated. |
| // String is an expensive operation and caching this result significantly reduces the cost of |
| // normal parse / marshal operations on Quantity. |
| func (q *Quantity) String() string { |
| if len(q.s) == 0 { |
| result := make([]byte, 0, int64QuantityExpectedBytes) |
| number, suffix := q.CanonicalizeBytes(result) |
| number = append(number, suffix...) |
| q.s = string(number) |
| } |
| return q.s |
| } |
| |
| // MarshalJSON implements the json.Marshaller interface. |
| func (q Quantity) MarshalJSON() ([]byte, error) { |
| if len(q.s) > 0 { |
| out := make([]byte, len(q.s)+2) |
| out[0], out[len(out)-1] = '"', '"' |
| copy(out[1:], q.s) |
| return out, nil |
| } |
| result := make([]byte, int64QuantityExpectedBytes, int64QuantityExpectedBytes) |
| result[0] = '"' |
| number, suffix := q.CanonicalizeBytes(result[1:1]) |
| // if the same slice was returned to us that we passed in, avoid another allocation by copying number into |
| // the source slice and returning that |
| if len(number) > 0 && &number[0] == &result[1] && (len(number)+len(suffix)+2) <= int64QuantityExpectedBytes { |
| number = append(number, suffix...) |
| number = append(number, '"') |
| return result[:1+len(number)], nil |
| } |
| // if CanonicalizeBytes needed more space than our slice provided, we may need to allocate again so use |
| // append |
| result = result[:1] |
| result = append(result, number...) |
| result = append(result, suffix...) |
| result = append(result, '"') |
| return result, nil |
| } |
| |
| // UnmarshalJSON implements the json.Unmarshaller interface. |
| // TODO: Remove support for leading/trailing whitespace |
| func (q *Quantity) UnmarshalJSON(value []byte) error { |
| l := len(value) |
| if l == 4 && bytes.Equal(value, []byte("null")) { |
| q.d.Dec = nil |
| q.i = int64Amount{} |
| return nil |
| } |
| if l >= 2 && value[0] == '"' && value[l-1] == '"' { |
| value = value[1 : l-1] |
| } |
| |
| parsed, err := ParseQuantity(strings.TrimSpace(string(value))) |
| if err != nil { |
| return err |
| } |
| |
| // This copy is safe because parsed will not be referred to again. |
| *q = parsed |
| return nil |
| } |
| |
| // NewQuantity returns a new Quantity representing the given |
| // value in the given format. |
| func NewQuantity(value int64, format Format) *Quantity { |
| return &Quantity{ |
| i: int64Amount{value: value}, |
| Format: format, |
| } |
| } |
| |
| // NewMilliQuantity returns a new Quantity representing the given |
| // value * 1/1000 in the given format. Note that BinarySI formatting |
| // will round fractional values, and will be changed to DecimalSI for |
| // values x where (-1 < x < 1) && (x != 0). |
| func NewMilliQuantity(value int64, format Format) *Quantity { |
| return &Quantity{ |
| i: int64Amount{value: value, scale: -3}, |
| Format: format, |
| } |
| } |
| |
| // NewScaledQuantity returns a new Quantity representing the given |
| // value * 10^scale in DecimalSI format. |
| func NewScaledQuantity(value int64, scale Scale) *Quantity { |
| return &Quantity{ |
| i: int64Amount{value: value, scale: scale}, |
| Format: DecimalSI, |
| } |
| } |
| |
| // Value returns the unscaled value of q rounded up to the nearest integer away from 0. |
| func (q *Quantity) Value() int64 { |
| return q.ScaledValue(0) |
| } |
| |
| // MilliValue returns the value of ceil(q * 1000); this could overflow an int64; |
| // if that's a concern, call Value() first to verify the number is small enough. |
| func (q *Quantity) MilliValue() int64 { |
| return q.ScaledValue(Milli) |
| } |
| |
| // ScaledValue returns the value of ceil(q * 10^scale); this could overflow an int64. |
| // To detect overflow, call Value() first and verify the expected magnitude. |
| func (q *Quantity) ScaledValue(scale Scale) int64 { |
| if q.d.Dec == nil { |
| i, _ := q.i.AsScaledInt64(scale) |
| return i |
| } |
| dec := q.d.Dec |
| return scaledValue(dec.UnscaledBig(), int(dec.Scale()), int(scale.infScale())) |
| } |
| |
| // Set sets q's value to be value. |
| func (q *Quantity) Set(value int64) { |
| q.SetScaled(value, 0) |
| } |
| |
| // SetMilli sets q's value to be value * 1/1000. |
| func (q *Quantity) SetMilli(value int64) { |
| q.SetScaled(value, Milli) |
| } |
| |
| // SetScaled sets q's value to be value * 10^scale |
| func (q *Quantity) SetScaled(value int64, scale Scale) { |
| q.s = "" |
| q.d.Dec = nil |
| q.i = int64Amount{value: value, scale: scale} |
| } |
| |
| // Copy is a convenience function that makes a deep copy for you. Non-deep |
| // copies of quantities share pointers and you will regret that. |
| func (q *Quantity) Copy() *Quantity { |
| if q.d.Dec == nil { |
| return &Quantity{ |
| s: q.s, |
| i: q.i, |
| Format: q.Format, |
| } |
| } |
| tmp := &inf.Dec{} |
| return &Quantity{ |
| s: q.s, |
| d: infDecAmount{tmp.Set(q.d.Dec)}, |
| Format: q.Format, |
| } |
| } |