defmodule Cldr.Number do
@moduledoc """
Formats numbers and currencies based upon CLDR's decimal formats specification.
The format specification is documentated in [Unicode TR35](http://unicode.org/reports/tr35/tr35-numbers.html#Number_Formats).
There are several classes of formatting including non-scientific, scientific,
rules based (for spelling and ordinal formats), compact formats that display `1k`
rather than `1,000` and so on. See `Cldr.Number.to_string/2` for specific formatting
options.
### Non-Scientific Notation Formatting
The following description applies to formats that do not use scientific
notation or significant digits:
* If the number of actual integer digits exceeds the maximum integer digits,
then only the least significant digits are shown. For example, 1997 is
formatted as "97" if the maximum integer digits is set to 2.
* If the number of actual integer digits is less than the minimum integer
digits, then leading zeros are added. For example, 1997 is formatted as
"01997" if the minimum integer digits is set to 5.
* If the number of actual fraction digits exceeds the maximum fraction
digits, then half-even rounding it performed to the maximum fraction
digits. For example, 0.125 is formatted as "0.12" if the maximum fraction
digits is 2. This behavior can be changed by specifying a rounding
increment and a rounding mode.
* If the number of actual fraction digits is less than the minimum fraction
digits, then trailing zeros are added. For example, 0.125 is formatted as
"0.1250" if the minimum fraction digits is set to 4.
* Trailing fractional zeros are not displayed if they occur j positions after
the decimal, where j is less than the maximum fraction digits. For example,
0.10004 is formatted as "0.1" if the maximum fraction digits is four or
less.
### Scientific Notation Formatting
Numbers in scientific notation are expressed as the product of a mantissa and
a power of ten, for example, 1234 can be expressed as 1.234 x 10^3. The
mantissa is typically in the half-open interval [1.0, 10.0) or sometimes
[0.0, 1.0), but it need not be. In a pattern, the exponent character
immediately followed by one or more digit characters indicates scientific
notation. Example: "0.###E0" formats the number 1234 as "1.234E3".
* The number of digit characters after the exponent character gives the
minimum exponent digit count. There is no maximum. Negative exponents are
formatted using the localized minus sign, not the prefix and suffix from
the pattern. This allows patterns such as "0.###E0 m/s". To prefix positive
exponents with a localized plus sign, specify '+' between the exponent and
the digits: "0.###E+0" will produce formats "1E+1", "1E+0", "1E-1", and so
on. (In localized patterns, use the localized plus sign rather than '+'.)
* The minimum number of integer digits is achieved by adjusting the exponent.
Example: 0.00123 formatted with "00.###E0" yields "12.3E-4". This only
happens if there is no maximum number of integer digits. If there is a
maximum, then the minimum number of integer digits is fixed at one.
* The maximum number of integer digits, if present, specifies the exponent
grouping. The most common use of this is to generate engineering notation,
in which the exponent is a multiple of three, for example, "##0.###E0". The
number 12345 is formatted using "##0.####E0" as "12.345E3".
* When using scientific notation, the formatter controls the digit counts
using significant digits logic. The maximum number of significant digits
limits the total number of integer and fraction digits that will be shown
in the mantissa; it does not affect parsing. For example, 12345 formatted
with "##0.##E0" is "12.3E3". Exponential patterns may not contain grouping
separators.
### Significant Digits
There are two ways of controlling how many digits are shows: (a)
significant digits counts, or (b) integer and fraction digit counts. Integer
and fraction digit counts are described above. When a formatter is using
significant digits counts, it uses however many integer and fraction digits
are required to display the specified number of significant digits. It may
ignore min/max integer/fraction digits, or it may use them to the extent
possible.
"""
alias Cldr.Config
alias Cldr.Number.Formatter
alias Cldr.Number.Format.Options
@type format_type ::
:standard
| :decimal_short
| :decimal_long
| :currency_short
| :currency_long
| :percent
| :accounting
| :scientific
| :currency
@short_format_styles Options.short_format_styles()
@root_locale_name Config.root_locale_name()
@root_locale Map.fetch!(Config.all_language_tags(), @root_locale_name)
@doc """
Return a valid number system from a provided locale and number
system name or type.
The number system or number system type must be valid for the
given locale. If a number system type is provided, the
underlying number system is returned.
## Arguments
* `locale` is any valid locale name returned by `Cldr.known_locale_names/1`
or a `Cldr.LanguageTag` struct returned by `Cldr.Locale.new!/2`
* `system_name` is any number system name returned by
`Cldr.known_number_systems/0` or a number system type
returned by `Cldr.known_number_system_types/0`
* `backend` is any module that includes `use Cldr` and therefore
is a `Cldr` backend module
## Examples
iex> Cldr.Number.validate_number_system :en, :latn, TestBackend.Cldr
{:ok, :latn}
iex> Cldr.Number.validate_number_system :en, :default, TestBackend.Cldr
{:ok, :latn}
iex> Cldr.Number.validate_number_system :en, :unknown, TestBackend.Cldr
{:error,
{Cldr.UnknownNumberSystemError, "The number system :unknown is unknown"}}
iex> Cldr.Number.validate_number_system "zz", :default, TestBackend.Cldr
{:error, {Cldr.InvalidLanguageError, "The language \\"zz\\" is invalid"}}
"""
@spec validate_number_system(
Cldr.Locale.locale_name() | Cldr.LanguageTag.t(),
Cldr.Number.System.system_name() | Cldr.Number.System.types(),
Cldr.backend()
) ::
{:ok, Cldr.Number.System.system_name()} | {:error, {module(), String.t()}}
def validate_number_system(locale, number_system, backend \\ default_backend()) do
Cldr.Number.System.system_name_from(number_system, locale, backend)
end
@doc """
Returns a number formatted into a string according to a format pattern and options.
## Arguments
* `number` is an integer, float or Decimal to be formatted
* `backend` is any `Cldr` backend. That is, any module that
contains `use Cldr`
* `options` is a keyword list defining how the number is to be formatted. The
valid options are:
## Options
* `format`: the format style or a format string defining how the number is
formatted. See `Cldr.Number.Format` for how format strings can be constructed.
See `Cldr.Number.Format.format_styles_for/3` to return available format styles
for a locale. The default `format` is `:standard`.
* If `:format` is set to `:long` or `:short` then the formatting depends on
whether `:currency` is specified. If not specified then the number is
formatted as `:decimal_long` or `:decimal_short`. If `:currency` is
specified the number is formatted as `:currency_long` or
`:currency_short` and `:fractional_digits` is set to 0 as a default.
* If `:format` is set to `:currency_long_with_symbol` then a format composed
of `:currency_long` with the locale's currency format is used.
* `:format` may also be a format defined by CLDR's Rules Based Number
Formats (RBNF). Further information is found in the module `Cldr.Rbnf`.
The most commonly used formats in this category are to spell out the
number in a the locales language. The applicable formats are `:spellout`,
`:spellout_year`, `:ordinal`. A number can also be formatted as roman
numbers by using the format `:roman` or `:roman_lower`.
* `currency`: is the currency for which the number is formatted. If `currency`
is set and no `:format` is set, `:format` will be set to `:currency` as well.
Currency may be any [ISO 4217 currency code](https://en.wikipedia.org/wiki/ISO_4217)
returned by `Cldr.Currency.known_currencies/0` or a
[ISO 24165](https://www.iso.org/standard/80601.html) digital token
identifier (crypto currency).
* `currency_symbol`: Allows overriding a currency symbol. The alternatives
are:
* `:iso` the ISO currency code will be used instead of the default
currency symbol.
* `:narrow` uses the narrow symbol defined for the locale. The same
narrow symbol can be defined for more than one currency and therefore this
should be used with care. If no narrow symbol is defined, the standard
symbol is used.
* `:symbol` uses the standard symbol defined in CLDR. A symbol is unique
for each currency and can be safely used.
* `:standard` (the default and recommended) uses the CLDR-defined symbol
based upon the currency format for the locale.
* "string" uses `string` as the currency symbol
* `:cash`: a boolean which indicates whether a number being formatted as a
`:currency` is to be considered a cash value or not. Currencies can be
rounded differently depending on whether `:cash` is `true` or `false`.
*This option is deprecated in favour of `currency_digits: :cash`. Ignored
if the currency is a digital token.
* `:currency_digits` indicates which of the rounding and digits should be
used. The options are `:accounting` which is the default, `:cash` or
`:iso`. Ignored if the currency is a digital token.
* `:rounding_mode`: determines how a number is rounded to meet the precision
of the format requested. The available rounding modes are `:down`,
:half_up, :half_even, :ceiling, :floor, :half_down, :up. The default is
`:half_even`.
* `:number_system`: determines which of the number systems for a locale
should be used to define the separators and digits for the formatted
number. If `number_system` is an `atom` then `number_system` is
interpreted as a number system. See
`Cldr.Number.System.number_systems_for/2`. If the `:number_system` is
`binary` then it is interpreted as a number system name. See
`Cldr.Number.System.number_system_names_for/2`. The default is `:default`.
* `:locale`: determines the locale in which the number is formatted. See
`Cldr.known_locale_names/0`. The default is`Cldr.get_locale/0` which is the
locale currently in affect for this `Process` and which is set by
`Cldr.put_locale/1`.
* If `:fractional_digits` is set to a positive integer value then the number
will be rounded to that number of digits and displayed accordingly - overriding
settings that would be applied by default. For example, currencies have
fractional digits defined reflecting each currencies minor unit. Setting
`:fractional_digits` will override that setting.
* If `:maximum_integer_digits` is set to a positive integer value then the
number is left truncated before formatting. For example if the number `1234`
is formatted with the option `maximum_integer_digits: 2`, the number is
truncated to `34` and formatted.
* If `:round_nearest` is set to a positive integer value then the number
will be rounded to nearest increment of that value - overriding
settings that would be applied by default.
* `:minimum_grouping_digits` overrides the CLDR definition of minimum grouping
digits. For example in the locale `es` the number `1345` is formatted by default
as `1345` because the locale defines the `minimium_grouping_digits` as `2`. If
`minimum_grouping_digits: 1` is set as an option the number is formatted as
`1.345`. The `:minimum_grouping_digits` is added to the grouping defined by
the number format. If the sum of these two digits is greater than the number
of digits in the integer (or fractional) part of the number then no grouping
is performed.
* `:wrapper` is a 2-arity function that will be called for each number component
with parameters `string` and `tag` where `tag` is one of `:number`,
`:currency_symbol`, `:currency_space`, `:literal`, `:quote`, `:percent`,
`:permille`, `:minus` or `:plus`. The function must return either a string
or a Phoenix safe string such as that returned by `Phoenix.HTML.Tag.content_tag/3`.
The function can be used to wrap format elements in HTML or other tags.
## Locale extensions affecting formatting
A locale identifier can specify options that affect number formatting.
These options are:
* `nu`: defines the number system to be used if none is specified by the `:number_system`
option to `to_string/2`
This key is part of the [u extension](https://unicode.org/reports/tr35/#u_Extension) and
that document should be consulted for details on how to construct a locale identifier with these
extensions.
## Wrapping format elements
Wrapping elements is particularly useful when formatting a number with a
currency symbol and the requirement is to have different HTML formatting
applied to the symbol than the number. For example:
iex> Cldr.Number.to_string(100, format: :currency, currency: :USD, wrapper: fn
...> string, :currency_symbol -> "<span class=\\"symbol\\">" <> string <> "</span>"
...> string, :number -> "<span class=\\"number\\">" <> string <> "</span>"
...> string, :currency_space -> "<span>" <> string <> "</span>"
...> string, _other -> string
...> end)
{:ok, "<span class=\\"symbol\\">$</span><span class=\\"number\\">100.00</span>"}
It is also possible and recommended to use the `Phoenix.HTML.Tag.content_tag/3`
function if wrapping HTML tags since these will ensure HTML entities are
correctly encoded. For example:
iex> Cldr.Number.to_string(100, format: :currency, currency: :USD, wrapper: fn
...> string, :currency_symbol -> Phoenix.HTML.Tag.content_tag(:span, string, class: "symbol")
...> string, :number -> Phoenix.HTML.Tag.content_tag(:span, string, class: "number")
...> string, :currency_space -> Phoenix.HTML.Tag.content_tag(:span, string)
...> string, _other -> string
...> end)
{:ok, "<span class=\\"symbol\\">$</span><span class=\\"number\\">100.00</span>"}
When formatting a number the format is parsed into format elements that might include
a currency symbol, a literal string, inserted text between a currency symbol and the
currency amount, a percent sign, the number itself and several other elements. In
some cases it is helpful to be apply specific formatting to each element.
This can be achieved by specifying a `:wrapper` option. This option takes a 2-arity
function as an argument. For each element of the format the wrapper function is called
with two parameters: the format element as a string and an atom representing the
element type. The wrapper function is required to return a string that is then
inserted in the final formatted number.
## Returns
* `{:ok, string}` or
* `{:error, {exception, message}}`
## Examples
iex> Cldr.Number.to_string 12345, TestBackend.Cldr
{:ok, "12,345"}
iex> Cldr.Number.to_string 12345, TestBackend.Cldr, locale: "fr"
{:ok, "12 345"}
iex> Cldr.Number.to_string 1345.32, TestBackend.Cldr, currency: :EUR, locale: "es", minimum_grouping_digits: 1
{:ok, "1.345,32 €"}
iex> Cldr.Number.to_string 1345.32, TestBackend.Cldr, currency: :EUR, locale: "es"
{:ok, "1345,32 €"}
iex> Cldr.Number.to_string 12345, TestBackend.Cldr, locale: "fr", currency: "USD"
{:ok, "12 345,00 $US"}
iex> Cldr.Number.to_string 12345, TestBackend.Cldr, format: "#E0"
{:ok, "1.2345E4"}
iex> Cldr.Number.to_string 12345, TestBackend.Cldr, format: :accounting, currency: "THB"
{:ok, "THB 12,345.00"}
iex> Cldr.Number.to_string -12345, TestBackend.Cldr, format: :accounting, currency: "THB"
{:ok, "(THB 12,345.00)"}
iex> Cldr.Number.to_string 12345, TestBackend.Cldr, format: :accounting, currency: "THB",
...> locale: "th"
{:ok, "฿12,345.00"}
iex> Cldr.Number.to_string 12345, TestBackend.Cldr, format: :accounting, currency: "THB",
...> locale: "th", number_system: :native
{:ok, "฿๑๒,๓๔๕.๐๐"}
iex> Cldr.Number.to_string 1244.30, TestBackend.Cldr, format: :long
{:ok, "1 thousand"}
iex> Cldr.Number.to_string 1244.30, TestBackend.Cldr, format: :long, currency: "USD"
{:ok, "1,244 US dollars"}
iex> Cldr.Number.to_string 1244.30, TestBackend.Cldr, format: :short
{:ok, "1K"}
iex> Cldr.Number.to_string 1244.30, TestBackend.Cldr, format: :short, currency: "EUR"
{:ok, "€1K"}
iex> Cldr.Number.to_string 1234, TestBackend.Cldr, format: :spellout
{:ok, "one thousand two hundred thirty-four"}
iex> Cldr.Number.to_string 1234, TestBackend.Cldr, format: :spellout_verbose
{:ok, "one thousand two hundred and thirty-four"}
iex> Cldr.Number.to_string 1989, TestBackend.Cldr, format: :spellout_year
{:ok, "nineteen eighty-nine"}
iex> Cldr.Number.to_string 123, TestBackend.Cldr, format: :ordinal
{:ok, "123rd"}
iex> Cldr.Number.to_string 123, TestBackend.Cldr, format: :roman
{:ok, "CXXIII"}
iex> Cldr.Number.to_string 123, TestBackend.Cldr, locale: "th-u-nu-thai"
{:ok, "๑๒๓"}
## Errors
An error tuple `{:error, reason}` will be returned if an error is detected.
The two most likely causes of an error return are:
* A format cannot be compiled. In this case the error tuple will look like:
```
iex> Cldr.Number.to_string(12345, TestBackend.Cldr, format: "0#")
{:error, {Cldr.FormatCompileError,
"Decimal format compiler: syntax error before: \\"#\\""}}
```
* The format style requested is not defined for the `locale` and
`number_system`. This happens typically when the number system is
`:algorithmic` rather than the more common `:numeric`. In this case the error
return looks like:
```
iex> Cldr.Number.to_string(1234, TestBackend.Cldr, locale: "he", number_system: "hebr")
{:error, {Cldr.UnknownFormatError,
"The locale :he with number system :hebr does not define a format :standard"}}
```
"""
@spec to_string(
number | Decimal.t() | String.t(),
Cldr.backend() | Keyword.t() | map(),
Keyword.t() | map()
) ::
{:ok, String.t()} | {:error, {atom, String.t()}}
def to_string(number, backend \\ default_backend(), options \\ [])
# No backend supplied, just options
def to_string(number, options, []) when is_list(options) do
{backend, options} = Keyword.pop_lazy(options, :backend, &default_backend/0)
to_string(number, backend, options)
end
# Decimal -0 is formatted like 0, without the sign
def to_string(%Decimal{coef: 0, sign: -1} = number, backend, options) do
%Decimal{number | sign: 1}
|> to_string(backend, options)
end
# Pre-processed options which is nearly twice as
# fast as non-preprocessed. See
# Cldr.Number.Options.validate_options/3
def to_string(number, backend, %Options{} = options) do
case to_string(number, options.format, backend, options) do
{:error, reason} -> {:error, reason}
string -> {:ok, string}
end
end
def to_string(number, backend, options) when is_list(options) do
with {:ok, options} <- Options.validate_options(number, backend, options) do
to_string(number, backend, options)
end
end
@doc """
Same as the execution of `to_string/2` but raises an exception if an error would be
returned.
## Options
* `number` is an integer, float or Decimal to be formatted
* `options` is a keyword list defining how the number is to be formatted. See
`Cldr.Number.to_string/2`
## Returns
* a formatted number as a string or
* raises an exception
## Examples
iex> Cldr.Number.to_string! 12345, TestBackend.Cldr
"12,345"
iex> Cldr.Number.to_string! 12345, TestBackend.Cldr, locale: "fr"
"12 345"
"""
@spec to_string!(
number | Decimal.t() | String.t(),
Cldr.backend() | Keyword.t() | map(),
Keyword.t() | map()
) ::
String.t() | no_return()
def to_string!(number, backend \\ default_backend(), options \\ [])
def to_string!(number, backend, options) do
case to_string(number, backend, options) do
{:error, {exception, message}} ->
raise exception, message
{:ok, string} ->
string
end
end
@format_mapping [
{:ordinal, :digits_ordinal, Ordinal},
{:spellout, :spellout_numbering, Spellout},
{:spellout_verbose, :spellout_numbering_verbose, Spellout},
{:spellout_year, :spellout_numbering_year, Spellout}
]
for {format, function, module} <- @format_mapping do
defp to_string(number, unquote(format), backend, options) do
evaluate_rule(number, unquote(module), unquote(function), options.locale, backend)
end
end
# For Roman numerals
defp to_string(number, :roman, backend, _options) do
Module.concat(backend, Rbnf.NumberSystem).roman_upper(number, @root_locale)
end
defp to_string(number, :roman_lower, backend, _options) do
Module.concat(backend, Rbnf.NumberSystem).roman_lower(number, @root_locale)
end
# For the :currency_long format only
defp to_string(number, :currency_long = format, backend, options) do
Formatter.Currency.to_string(number, format, backend, options)
end
# For the :currency_medium format only
defp to_string(number, :currency_long_with_symbol = format, backend, options) do
Formatter.Currency.to_string(number, format, backend, options)
end
# For all other short formats
defp to_string(number, format, backend, options)
when is_atom(format) and format in @short_format_styles do
Formatter.Short.to_string(number, format, backend, options)
end
# For executing arbitrary RBNF rules that might exist for a given locale
defp to_string(_number, format, _backend, %{locale: %{rbnf_locale_name: nil} = locale}) do
{:error, Cldr.Rbnf.rbnf_rule_error(locale, format)}
end
defp to_string(number, format, backend, options) when is_atom(format) do
with {:ok, module, locale} <- find_rbnf_format_module(options.locale, format, backend) do
apply(module, format, [number, locale])
end
end
# For all other formats
defp to_string(number, format, backend, options) when is_binary(format) do
Formatter.Decimal.to_string(number, format, backend, options)
end
# For all other formats. The known atom-based formats are described
# above so this must be a format name expected to be defined by a
# locale but its not there.
defp to_string(_number, {:error, _} = error, _backend, _options) do
error
end
# Look for the RBNF rule in the given locale or in the
# root locale (called "und")
defp find_rbnf_format_module(locale, format, backend) do
root_locale = Map.put(@root_locale, :backend, backend)
cond do
module = find_rbnf_module(locale, format, backend) -> {:ok, module, locale}
module = find_rbnf_module(root_locale, format, backend) -> {:ok, module, root_locale}
true -> {:error, Cldr.Rbnf.rbnf_rule_error(locale, format)}
end
end
defp find_rbnf_module(locale, format, backend) do
Enum.reduce_while(Cldr.Rbnf.categories_for_locale!(locale), nil, fn category, acc ->
format_module = Module.concat([backend, :Rbnf, category])
rules = format_module.rule_sets(locale)
if rules && format in rules do
{:halt, format_module}
else
{:cont, acc}
end
end)
end
defp evaluate_rule(number, module, function, locale, backend) do
module = Module.concat([backend, :Rbnf, module])
rule_sets = module.rule_sets(locale)
if rule_sets && function in rule_sets do
apply(module, function, [number, locale])
else
{:error, Cldr.Rbnf.rbnf_rule_error(locale, function)}
end
end
@doc """
Formats a number and applies the `:at_least` format for
a locale and number system.
## Arguments
* `number` is an integer, float or Decimal to be formatted
* `backend` is any `Cldr` backend. That is, any module that
contains `use Cldr`
* `options` is a keyword list defining how the number is to be formatted.
See `Cldr.Number.to_string/3` for a description of the available
options.
## Example
iex> Cldr.Number.to_at_least_string 1234, TestBackend.Cldr
{:ok, "1,234+"}
"""
@spec to_at_least_string(number | Decimal.t(), Cldr.backend(), Keyword.t() | map()) ::
{:ok, String.t()} | {:error, {module(), String.t()}}
def to_at_least_string(number, backend \\ default_backend(), options \\ [])
def to_at_least_string(number, options, []) when is_list(options) do
{backend, options} = Keyword.pop_lazy(options, :backend, &default_backend/0)
to_at_least_string(number, backend, options)
end
def to_at_least_string(number, backend, options) do
other_format(number, :at_least, backend, options)
end
@doc """
Formats a number and applies the `:at_most` format for
a locale and number system.
## Arguments
* `number` is an integer, float or Decimal to be formatted
* `backend` is any `Cldr` backend. That is, any module that
contains `use Cldr`
* `options` is a keyword list defining how the number is to be formatted.
See `Cldr.Number.to_string/3` for a description of the available
options.
## Example
iex> Cldr.Number.to_at_most_string 1234, TestBackend.Cldr
{:ok, "≤1,234"}
"""
@spec to_at_most_string(number | Decimal.t(), Cldr.backend(), Keyword.t() | map()) ::
{:ok, String.t()} | {:error, {module(), String.t()}}
def to_at_most_string(number, backend \\ default_backend(), options \\ [])
def to_at_most_string(number, options, []) when is_list(options) do
{backend, options} = Keyword.pop_lazy(options, :backend, &default_backend/0)
to_at_most_string(number, backend, options)
end
def to_at_most_string(number, backend, options) do
other_format(number, :at_most, backend, options)
end
@doc """
Formats a number and applies the `:approximately` format for
a locale and number system.
## Arguments
* `number` is an integer, float or Decimal to be formatted
* `backend` is any `Cldr` backend. That is, any module that
contains `use Cldr`
* `options` is a keyword list defining how the number is to be formatted.
See `Cldr.Number.to_string/3` for a description of the available
options.
## Example
iex> Cldr.Number.to_approx_string 1234, TestBackend.Cldr
{:ok, "~1,234"}
"""
@spec to_approx_string(number | Decimal.t(), Cldr.backend(), Keyword.t() | map()) ::
{:ok, String.t()} | {:error, {module(), String.t()}}
def to_approx_string(number, backend \\ default_backend(), options \\ [])
def to_approx_string(number, options, []) when is_list(options) do
{backend, options} = Keyword.pop_lazy(options, :backend, &default_backend/0)
to_approx_string(number, backend, options)
end
def to_approx_string(number, backend, options) do
other_format(number, :approximately, backend, options)
end
@doc """
Formats the first and last numbers of a range and applies
the `:range` format for a locale and number system.
## Arguments
* `number` is an integer, float or Decimal to be formatted
* `backend` is any `Cldr` backend. That is, any module that
contains `use Cldr`
* `options` is a keyword list defining how the number is to be formatted.
See `Cldr.Number.to_string/3` for a description of the available
options.
## Example
iex> Cldr.Number.to_range_string 1234..5678, TestBackend.Cldr
{:ok, "1,234–5,678"}
"""
@spec to_range_string(Range.t(), Cldr.backend(), Keyword.t() | map()) ::
{:ok, String.t()} | {:error, {module(), String.t()}}
def to_range_string(number, backend \\ default_backend(), options \\ [])
def to_range_string(number, options, []) when is_list(options) do
{backend, options} = Keyword.pop_lazy(options, :backend, &default_backend/0)
to_range_string(number, backend, options)
end
def to_range_string(range, backend, options) do
%Range{first: first, last: last} = range
with {:ok, options} <- Options.validate_options(first, backend, options),
{:ok, format} <- Options.validate_other_format(:range, backend, options),
{:ok, first_formatted_number} <- to_string(first, backend, options),
{:ok, last_formatted_number} <- to_string(last, backend, options) do
final_format =
[first_formatted_number, last_formatted_number]
|> Cldr.Substitution.substitute(format)
|> :erlang.iolist_to_binary()
{:ok, final_format}
end
end
@spec other_format(
number | Decimal.t(),
:approximately | :at_least | :at_most,
Cldr.backend(),
Keyword.t()
) ::
{:ok, String.t()} | {:error, {module(), String.t()}}
defp other_format(number, other_format, backend, options) do
with {:ok, options} <- Options.validate_options(number, backend, options),
{:ok, format} <- Options.validate_other_format(other_format, backend, options),
{:ok, formatted_number} <- to_string(number, backend, options) do
final_format =
[formatted_number]
|> Cldr.Substitution.substitute(format)
|> :erlang.iolist_to_binary()
{:ok, final_format}
end
end
@doc """
Converts a number from the latin digits `0..9` into
another number system. Returns `{:ok, string}` or
`{:error, reason}`.
* `number` is an integer, float. Decimal is supported only for
`:numeric` number systems, not `:algorithmic`. See `Cldr.Number.System.to_system/3`
for further information.
* `system` is any number system returned by `Cldr.known_number_systems/0`
## Examples
iex> Cldr.Number.to_number_system 123, :hant, TestBackend.Cldr
{:ok, "一百二十三"}
iex> Cldr.Number.to_number_system 123, :hebr, TestBackend.Cldr
{:ok, "קכ״ג"}
"""
@spec to_number_system(number, atom, Cldr.backend()) ::
String.t() | {:error, {module(), String.t()}}
def to_number_system(number, system, backend \\ default_backend()) do
Cldr.Number.System.to_system(number, system, backend)
end
@doc """
Converts a number from the latin digits `0..9` into
another number system. Returns the converted number
or raises an exception on error.
* `number` is an integer, float. Decimal is supported only for
`:numeric` number systems, not `:algorithmic`. See `Cldr.Number.System.to_system/3`
for further information.
* `system` is any number system returned by `Cldr.Number.System.known_number_systems/0`
## Example
iex> Cldr.Number.to_number_system! 123, :hant, TestBackend.Cldr
"一百二十三"
"""
@spec to_number_system!(number, atom, Cldr.backend()) :: String.t() | no_return()
def to_number_system!(number, system, backend \\ default_backend()) do
Cldr.Number.System.to_system!(number, system, backend)
end
@doc """
Returns the metadata representing the given
format.
"""
@spec decimal_format_metadata(String.t(), Cldr.backend()) ::
{:ok, Cldr.Number.Format.Meta.t()} | {:error, String.t()}
def decimal_format_metadata(format, backend \\ default_backend()) when is_binary(format) do
backend.decimal_format_metadata(format)
end
@doc """
Return the precision (number of digits) of a number
This function delegates to `Cldr.Digits.number_of_digits/1`
## Example
iex> Cldr.Number.precision 1.234
4
"""
defdelegate precision(number), to: Cldr.Digits, as: :number_of_digits
@doc false
# TODO remove for Cldr 3.0
if Code.ensure_loaded?(Cldr) && function_exported?(Cldr, :default_backend!, 0) do
def default_backend do
Cldr.default_backend!()
end
else
def default_backend do
Cldr.default_backend()
end
end
end
