unit/unittype.go - third_party/github.com/gonum/gonum - Git at Google

 // Copyright ©2013 The gonum 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 unit

 import (
 	"bytes"
 	"fmt"
 	"sort"
 )

 // Uniter is a type that can be converted to a Unit.
 type Uniter interface {
 	Unit() *Unit
 }

 // Dimension is a type representing an SI base dimension or a distinct
 // orthogonal dimension. Non-SI dimensions can be created using the NewDimension
 // function, typically within an init function.
 type Dimension int

 // String returns the string for the dimension.
 func (d Dimension) String() string {
 	switch {
 	case d == reserved:
 		return "reserved"
 	case d < Dimension(len(symbols)):
 		return symbols[d]
 	default:
 		panic("unit: illegal dimension")
 	}
 }

 const (
 	// SI Base Units
 	reserved Dimension = iota
 	CurrentDim
 	LengthDim
 	LuminousIntensityDim
 	MassDim
 	TemperatureDim
 	TimeDim
 	// Other common SI Dimensions
 	AngleDim // e.g. radians
 )

 var (
 	symbols = []string{
 		CurrentDim:           "A",
 		LengthDim:            "m",
 		LuminousIntensityDim: "cd",
 		MassDim:              "kg",
 		TemperatureDim:       "K",
 		TimeDim:              "s",
 		AngleDim:             "rad",
 	}

 	// dimensions guarantees there aren't two identical symbols
 	// SI symbol list from http://lamar.colostate.edu/~hillger/basic.htm
 	dimensions = map[string]Dimension{
 		"A":   CurrentDim,
 		"m":   LengthDim,
 		"cd":  LuminousIntensityDim,
 		"kg":  MassDim,
 		"K":   TemperatureDim,
 		"s":   TimeDim,
 		"rad": AngleDim,

 		// Reserve common SI symbols
 		// base units
 		"mol": reserved,
 		// prefixes
 		"Y":  reserved,
 		"Z":  reserved,
 		"E":  reserved,
 		"P":  reserved,
 		"T":  reserved,
 		"G":  reserved,
 		"M":  reserved,
 		"k":  reserved,
 		"h":  reserved,
 		"da": reserved,
 		"d":  reserved,
 		"c":  reserved,
 		"μ":  reserved,
 		"n":  reserved,
 		"p":  reserved,
 		"f":  reserved,
 		"a":  reserved,
 		"z":  reserved,
 		"y":  reserved,
 		// SI Derived units with special symbols
 		"sr":  reserved,
 		"F":   reserved,
 		"C":   reserved,
 		"S":   reserved,
 		"H":   reserved,
 		"V":   reserved,
 		"Ω":   reserved,
 		"J":   reserved,
 		"N":   reserved,
 		"Hz":  reserved,
 		"lx":  reserved,
 		"lm":  reserved,
 		"Wb":  reserved,
 		"W":   reserved,
 		"Pa":  reserved,
 		"Bq":  reserved,
 		"Gy":  reserved,
 		"Sv":  reserved,
 		"kat": reserved,
 		// Units in use with SI
 		"ha": reserved,
 		"L":  reserved,
 		"l":  reserved,
 		// Units in Use Temporarily with SI
 		"bar": reserved,
 		"b":   reserved,
 		"Ci":  reserved,
 		"R":   reserved,
 		"rd":  reserved,
 		"rem": reserved,
 	}
 )

 // Dimensions represent the dimensionality of the unit in powers
 // of that dimension. If a key is not present, the power of that
 // dimension is zero. Dimensions is used in conjunction with New.
 type Dimensions map[Dimension]int

 func (d Dimensions) String() string {
 	// Map iterates randomly, but print should be in a fixed order. Can't use
 	// dimension number, because for user-defined dimension that number may
 	// not be fixed from run to run.
 	atoms := make(unitPrinters, 0, len(d))
 	for dimension, power := range d {
 		if power != 0 {
 			atoms = append(atoms, atom{dimension, power})
 		}
 	}
 	sort.Sort(atoms)
 	var b bytes.Buffer
 	for i, a := range atoms {
 		if i > 0 {
 			b.WriteByte(' ')
 		}
 		fmt.Fprintf(&b, "%s", a.Dimension)
 		if a.pow != 1 {
 			fmt.Fprintf(&b, "^%d", a.pow)
 		}
 	}

 	return b.String()
 }

 type atom struct {
 	Dimension
 	pow int
 }

 type unitPrinters []atom

 func (u unitPrinters) Len() int {
 	return len(u)
 }

 func (u unitPrinters) Less(i, j int) bool {
 	// Order first by positive powers, then by name.
 	if u[i].pow*u[j].pow < 0 {
 		return u[i].pow > 0
 	}
 	return u[i].String() < u[j].String()
 }

 func (u unitPrinters) Swap(i, j int) {
 	u[i], u[j] = u[j], u[i]
 }

 // NewDimension creates a new orthogonal dimension with the given symbol, and
 // returns the value of that dimension. The input symbol must not overlap with
 // any of the any of the SI base units or other symbols of common use in SI ("kg",
 // "J", etc.), and must not overlap with any other dimensions created by calls
 // to NewDimension. The SymbolExists function can check if the symbol exists.
 // NewDimension will panic if the input symbol matches an existing symbol.
 //
 // NewDimension should only be called for unit types that are actually orthogonal
 // to the base dimensions defined in this package. Please see the package-level
 // documentation for further explanation.
 func NewDimension(symbol string) Dimension {
 	_, ok := dimensions[symbol]
 	if ok {
 		panic("unit: dimension string \"" + symbol + "\" already used")
 	}
 	d := Dimension(len(symbols))
 	symbols = append(symbols, symbol)
 	dimensions[symbol] = d
 	return d
 }

 // SymoblExists returns whether the given symbol is already in use.
 func SymbolExists(symbol string) bool {
 	_, ok := dimensions[symbol]
 	return ok
 }

 // Unit represents a dimensional value. The dimensions will typically be in SI
 // units, but can also include dimensions created with NewDimension. The Unit type
 // is most useful for ensuring dimensional consistency when manipulating types
 // with different units, for example, by multiplying  an acceleration with a
 // mass to get a force. Please see the package documentation for further explanation.
 type Unit struct {
 	dimensions Dimensions
 	formatted  string
 	value      float64
 }

 // New creates a new variable of type Unit which has the value and dimensions
 // specified by the inputs. The built-in dimensions are always in SI units
 // (meters, kilograms, etc.).
 func New(value float64, d Dimensions) *Unit {
 	u := &Unit{
 		dimensions: make(map[Dimension]int),
 		value:      value,
 	}
 	for key, val := range d {
 		if val != 0 {
 			u.dimensions[key] = val
 		}
 	}
 	return u
 }

 // DimensionsMatch checks if the dimensions of two Uniters are the same.
 func DimensionsMatch(a, b Uniter) bool {
 	aUnit := a.Unit()
 	bUnit := b.Unit()
 	if len(aUnit.dimensions) != len(bUnit.dimensions) {
 		return false
 	}
 	for key, val := range aUnit.dimensions {
 		if bUnit.dimensions[key] != val {
 			return false
 		}
 	}
 	return true
 }

 // Add adds the function argument to the receiver. Panics if the units of
 // the receiver and the argument don't match.
 func (u *Unit) Add(uniter Uniter) *Unit {
 	a := uniter.Unit()
 	if !DimensionsMatch(u, a) {
 		panic("unit: mismatched dimensions in addition")
 	}
 	u.value += a.value
 	return u
 }

 // Unit implements the Uniter interface
 func (u *Unit) Unit() *Unit {
 	return u
 }

 // Mul multiply the receiver by the input changing the dimensions
 // of the receiver as appropriate. The input is not changed.
 func (u *Unit) Mul(uniter Uniter) *Unit {
 	a := uniter.Unit()
 	for key, val := range a.dimensions {
 		if d := u.dimensions[key]; d == -val {
 			delete(u.dimensions, key)
 		} else {
 			u.dimensions[key] = d + val
 		}
 	}
 	u.formatted = ""
 	u.value *= a.value
 	return u
 }

 // Div divides the receiver by the argument changing the
 // dimensions of the receiver as appropriate.
 func (u *Unit) Div(uniter Uniter) *Unit {
 	a := uniter.Unit()
 	u.value /= a.value
 	for key, val := range a.dimensions {
 		if d := u.dimensions[key]; d == val {
 			delete(u.dimensions, key)
 		} else {
 			u.dimensions[key] = d - val
 		}
 	}
 	u.formatted = ""
 	return u
 }

 // Value return the raw value of the unit as a float64. Use of this
 // method is, in general, not recommended, though it can be useful
 // for printing. Instead, the From type of a specific dimension
 // should be used to guarantee dimension consistency.
 func (u *Unit) Value() float64 {
 	return u.value
 }

 // Format makes Unit satisfy the fmt.Formatter interface. The unit is formatted
 // with dimensions appended. If the power if the dimension is not zero or one,
 // symbol^power is appended, if the power is one, just the symbol is appended
 // and if the power is zero, nothing is appended. Dimensions are appended
 // in order by symbol name with positive powers ahead of negative powers.
 func (u *Unit) Format(fs fmt.State, c rune) {
 	if u == nil {
 		fmt.Fprint(fs, "<nil>")
 	}
 	switch c {
 	case 'v':
 		if fs.Flag('#') {
 			fmt.Fprintf(fs, "&%#v", *u)
 			return
 		}
 		fallthrough
 	case 'e', 'E', 'f', 'F', 'g', 'G':
 		p, pOk := fs.Precision()
 		w, wOk := fs.Width()
 		switch {
 		case pOk && wOk:
 			fmt.Fprintf(fs, "%*.*"+string(c), w, p, u.value)
 		case pOk:
 			fmt.Fprintf(fs, "%.*"+string(c), p, u.value)
 		case wOk:
 			fmt.Fprintf(fs, "%*"+string(c), w, u.value)
 		default:
 			fmt.Fprintf(fs, "%"+string(c), u.value)
 		}
 	default:
 		fmt.Fprintf(fs, "%%!%c(*Unit=%g)", c, u)
 		return
 	}
 	if u.formatted == "" && len(u.dimensions) > 0 {
 		u.formatted = u.dimensions.String()
 	}
 	fmt.Fprintf(fs, " %s", u.formatted)
 }
	// Copyright ©2013 The gonum 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 unit

	import (
	"bytes"
	"fmt"
	"sort"
	)

	// Uniter is a type that can be converted to a Unit.
	type Uniter interface {
	Unit() *Unit
	}

	// Dimension is a type representing an SI base dimension or a distinct
	// orthogonal dimension. Non-SI dimensions can be created using the NewDimension
	// function, typically within an init function.
	type Dimension int

	// String returns the string for the dimension.
	func (d Dimension) String() string {
	switch {
	case d == reserved:
	return "reserved"
	case d < Dimension(len(symbols)):
	return symbols[d]
	default:
	panic("unit: illegal dimension")
	}
	}

	const (
	// SI Base Units
	reserved Dimension = iota
	CurrentDim
	LengthDim
	LuminousIntensityDim
	MassDim
	TemperatureDim
	TimeDim
	// Other common SI Dimensions
	AngleDim // e.g. radians
	)

	var (
	symbols = []string{
	CurrentDim: "A",
	LengthDim: "m",
	LuminousIntensityDim: "cd",
	MassDim: "kg",
	TemperatureDim: "K",
	TimeDim: "s",
	AngleDim: "rad",
	}

	// dimensions guarantees there aren't two identical symbols
	// SI symbol list from http://lamar.colostate.edu/~hillger/basic.htm
	dimensions = map[string]Dimension{
	"A": CurrentDim,
	"m": LengthDim,
	"cd": LuminousIntensityDim,
	"kg": MassDim,
	"K": TemperatureDim,
	"s": TimeDim,
	"rad": AngleDim,

	// Reserve common SI symbols
	// base units
	"mol": reserved,
	// prefixes
	"Y": reserved,
	"Z": reserved,
	"E": reserved,
	"P": reserved,
	"T": reserved,
	"G": reserved,
	"M": reserved,
	"k": reserved,
	"h": reserved,
	"da": reserved,
	"d": reserved,
	"c": reserved,
	"μ": reserved,
	"n": reserved,
	"p": reserved,
	"f": reserved,
	"a": reserved,
	"z": reserved,
	"y": reserved,
	// SI Derived units with special symbols
	"sr": reserved,
	"F": reserved,
	"C": reserved,
	"S": reserved,
	"H": reserved,
	"V": reserved,
	"Ω": reserved,
	"J": reserved,
	"N": reserved,
	"Hz": reserved,
	"lx": reserved,
	"lm": reserved,
	"Wb": reserved,
	"W": reserved,
	"Pa": reserved,
	"Bq": reserved,
	"Gy": reserved,
	"Sv": reserved,
	"kat": reserved,
	// Units in use with SI
	"ha": reserved,
	"L": reserved,
	"l": reserved,
	// Units in Use Temporarily with SI
	"bar": reserved,
	"b": reserved,
	"Ci": reserved,
	"R": reserved,
	"rd": reserved,
	"rem": reserved,
	}
	)

	// Dimensions represent the dimensionality of the unit in powers
	// of that dimension. If a key is not present, the power of that
	// dimension is zero. Dimensions is used in conjunction with New.
	type Dimensions map[Dimension]int

	func (d Dimensions) String() string {
	// Map iterates randomly, but print should be in a fixed order. Can't use
	// dimension number, because for user-defined dimension that number may
	// not be fixed from run to run.
	atoms := make(unitPrinters, 0, len(d))
	for dimension, power := range d {
	if power != 0 {
	atoms = append(atoms, atom{dimension, power})
	}
	}
	sort.Sort(atoms)
	var b bytes.Buffer
	for i, a := range atoms {
	if i > 0 {
	b.WriteByte(' ')
	}
	fmt.Fprintf(&b, "%s", a.Dimension)
	if a.pow != 1 {
	fmt.Fprintf(&b, "^%d", a.pow)
	}
	}

	return b.String()
	}

	type atom struct {
	Dimension
	pow int
	}

	type unitPrinters []atom

	func (u unitPrinters) Len() int {
	return len(u)
	}

	func (u unitPrinters) Less(i, j int) bool {
	// Order first by positive powers, then by name.
	if u[i].pow*u[j].pow < 0 {
	return u[i].pow > 0
	}
	return u[i].String() < u[j].String()
	}

	func (u unitPrinters) Swap(i, j int) {
	u[i], u[j] = u[j], u[i]
	}

	// NewDimension creates a new orthogonal dimension with the given symbol, and
	// returns the value of that dimension. The input symbol must not overlap with
	// any of the any of the SI base units or other symbols of common use in SI ("kg",
	// "J", etc.), and must not overlap with any other dimensions created by calls
	// to NewDimension. The SymbolExists function can check if the symbol exists.
	// NewDimension will panic if the input symbol matches an existing symbol.
	//
	// NewDimension should only be called for unit types that are actually orthogonal
	// to the base dimensions defined in this package. Please see the package-level
	// documentation for further explanation.
	func NewDimension(symbol string) Dimension {
	_, ok := dimensions[symbol]
	if ok {
	panic("unit: dimension string \"" + symbol + "\" already used")
	}
	d := Dimension(len(symbols))
	symbols = append(symbols, symbol)
	dimensions[symbol] = d
	return d
	}

	// SymoblExists returns whether the given symbol is already in use.
	func SymbolExists(symbol string) bool {
	_, ok := dimensions[symbol]
	return ok
	}

	// Unit represents a dimensional value. The dimensions will typically be in SI
	// units, but can also include dimensions created with NewDimension. The Unit type
	// is most useful for ensuring dimensional consistency when manipulating types
	// with different units, for example, by multiplying an acceleration with a
	// mass to get a force. Please see the package documentation for further explanation.
	type Unit struct {
	dimensions Dimensions
	formatted string
	value float64
	}

	// New creates a new variable of type Unit which has the value and dimensions
	// specified by the inputs. The built-in dimensions are always in SI units
	// (meters, kilograms, etc.).
	func New(value float64, d Dimensions) *Unit {
	u := &Unit{
	dimensions: make(map[Dimension]int),
	value: value,
	}
	for key, val := range d {
	if val != 0 {
	u.dimensions[key] = val
	}
	}
	return u
	}

	// DimensionsMatch checks if the dimensions of two Uniters are the same.
	func DimensionsMatch(a, b Uniter) bool {
	aUnit := a.Unit()
	bUnit := b.Unit()
	if len(aUnit.dimensions) != len(bUnit.dimensions) {
	return false
	}
	for key, val := range aUnit.dimensions {
	if bUnit.dimensions[key] != val {
	return false
	}
	}
	return true
	}

	// Add adds the function argument to the receiver. Panics if the units of
	// the receiver and the argument don't match.
	func (u Unit) Add(uniter Uniter) Unit {
	a := uniter.Unit()
	if !DimensionsMatch(u, a) {
	panic("unit: mismatched dimensions in addition")
	}
	u.value += a.value
	return u
	}

	// Unit implements the Uniter interface
	func (u Unit) Unit() Unit {
	return u
	}

	// Mul multiply the receiver by the input changing the dimensions
	// of the receiver as appropriate. The input is not changed.
	func (u Unit) Mul(uniter Uniter) Unit {
	a := uniter.Unit()
	for key, val := range a.dimensions {
	if d := u.dimensions[key]; d == -val {
	delete(u.dimensions, key)
	} else {
	u.dimensions[key] = d + val
	}
	}
	u.formatted = ""
	u.value *= a.value
	return u
	}

	// Div divides the receiver by the argument changing the
	// dimensions of the receiver as appropriate.
	func (u Unit) Div(uniter Uniter) Unit {
	a := uniter.Unit()
	u.value /= a.value
	for key, val := range a.dimensions {
	if d := u.dimensions[key]; d == val {
	delete(u.dimensions, key)
	} else {
	u.dimensions[key] = d - val
	}
	}
	u.formatted = ""
	return u
	}

	// Value return the raw value of the unit as a float64. Use of this
	// method is, in general, not recommended, though it can be useful
	// for printing. Instead, the From type of a specific dimension
	// should be used to guarantee dimension consistency.
	func (u *Unit) Value() float64 {
	return u.value
	}

	// Format makes Unit satisfy the fmt.Formatter interface. The unit is formatted
	// with dimensions appended. If the power if the dimension is not zero or one,
	// symbol^power is appended, if the power is one, just the symbol is appended
	// and if the power is zero, nothing is appended. Dimensions are appended
	// in order by symbol name with positive powers ahead of negative powers.
	func (u *Unit) Format(fs fmt.State, c rune) {
	if u == nil {
	fmt.Fprint(fs, "<nil>")
	}
	switch c {
	case 'v':
	if fs.Flag('#') {
	fmt.Fprintf(fs, "&%#v", *u)
	return
	}
	fallthrough
	case 'e', 'E', 'f', 'F', 'g', 'G':
	p, pOk := fs.Precision()
	w, wOk := fs.Width()
	switch {
	case pOk && wOk:
	fmt.Fprintf(fs, "%."+string(c), w, p, u.value)
	case pOk:
	fmt.Fprintf(fs, "%.*"+string(c), p, u.value)
	case wOk:
	fmt.Fprintf(fs, "%*"+string(c), w, u.value)
	default:
	fmt.Fprintf(fs, "%"+string(c), u.value)
	}
	default:
	fmt.Fprintf(fs, "%%!%c(*Unit=%g)", c, u)
	return
	}
	if u.formatted == "" && len(u.dimensions) > 0 {
	u.formatted = u.dimensions.String()
	}
	fmt.Fprintf(fs, " %s", u.formatted)
	}