Packages
ex_cldr_units
3.13.2
3.20.5
3.20.4
3.20.3
3.20.2
3.20.1
3.20.0
3.19.2
3.19.1
3.19.0
3.18.1
3.18.0
3.17.2
3.17.1
3.17.0
3.16.5
3.16.4
3.16.3
3.16.2
3.16.1
3.16.0
3.15.0
3.14.0
3.13.3
3.13.2
3.13.1
3.13.0
3.12.2
3.12.1
3.12.0
3.11.0
3.10.0
3.9.2
3.9.1
3.9.0
3.8.0
3.8.0-rc.2
3.8.0-rc.1
3.8.0-rc.0
3.7.1
3.7.0
3.6.0
3.5.3
3.5.2
3.5.1
3.5.0
3.5.0-rc.1
3.5.0-rc.0
3.4.0
3.4.0-rc.0
3.3.1
3.3.0
3.3.0-rc.0
3.2.1
3.2.0
3.1.2
3.1.1
3.1.0
3.0.1
3.0.0
3.0.0-rc.0
2.8.1
2.8.0
2.7.0
2.6.1
2.6.0
2.5.3
2.5.2
2.5.1
2.5.0
2.4.0
2.3.3
2.3.2
retired
2.3.1
2.3.0
2.2.0
2.1.0
2.0.0
1.3.0
1.2.2
1.2.1
1.2.0
1.1.1
1.1.0
retired
1.0.1
retired
1.0.0
retired
1.0.0-rc.0
retired
0.4.4
0.4.3
0.4.2
0.4.1
0.4.0
0.3.1
0.3.0
0.2.1
0.2.0
0.1.3
0.1.2
0.1.1
0.1.0
Unit formatting (volume, area, length, ...), conversion and arithmetic functions based upon the Common Locale Data Repository (CLDR).
Current section
Files
Jump to
Current section
Files
lib/cldr/unit/base_unit.ex
defmodule Cldr.Unit.BaseUnit do
@moduledoc """
Functions to support the base unit calculations
for a unit.
Base unit equality is used to determine whether
a one unit can be converted to another
"""
alias Cldr.Unit.Conversion
alias Cldr.Unit.Parser
alias Cldr.Unit
@per "_per_"
@currency_base Cldr.Unit.Parser.currency_base()
@currencies Cldr.known_currencies()
@doc """
Returns the canonical base unit name
for a unit.
The base unit is the common unit through which
conversions are passed.
## Arguments
* `unit_string` is any string representing
a unit such as `light_year_per_week`.
## Returns
* `{:ok, canonical_base_unit}` or
* `{:error, {exception, reason}}`
## Examples
iex> Cldr.Unit.Parser.canonical_base_unit "meter"
{:ok, :meter}
iex> Cldr.Unit.Parser.canonical_base_unit "meter meter"
{:ok, :square_meter}
iex> Cldr.Unit.Parser.canonical_base_unit "meter per kilogram"
{:ok, "meter_per_kilogram"}
iex> Cldr.Unit.Parser.canonical_base_unit "yottagram per mile scandinavian"
{:ok, "kilogram_per_meter"}
"""
def canonical_base_unit(unit) when is_binary(unit) do
with {:ok, parsed} <- Parser.parse_unit(unit) do
canonical_base_unit(parsed)
end
end
# A "per" unit
def canonical_base_unit({numerator, denominator}) do
with numerator <- do_canonical_base_unit(numerator),
denominator <- do_canonical_base_unit(denominator) do
{numerator, denominator}
|> merge_unit_names()
|> sort_base_units()
|> reduce_powers()
# |> reduce_factors()
|> flatten_and_stringify()
|> Unit.maybe_translatable_unit()
|> wrap(:ok)
end
end
# A list of conversions
def canonical_base_unit(numerator) do
numerator
|> do_canonical_base_unit()
|> flatten_and_stringify()
|> Unit.maybe_translatable_unit()
|> wrap(:ok)
end
def do_canonical_base_unit(numerator) when is_list(numerator) do
numerator
|> Enum.map(&canonical_base_subunit/1)
|> resolve_unit_names()
|> sort_base_units()
|> reduce_powers()
# |> reduce_factors()
end
defp canonical_base_subunit({currency, _conversion}) when currency in @currencies do
[String.downcase(@currency_base <> to_string(currency))]
end
defp canonical_base_subunit({_unit_name, %Conversion{base_unit: base_units}}) do
base_units
|> parse_base_units()
|> extract_unit_names()
end
defp parse_base_units([prefix, unit]) do
[[prefix, parse_base_units([unit])]]
end
defp parse_base_units([unit]) do
unit
|> to_string
|> Cldr.Unit.normalize_unit_name()
|> Parser.parse_unit!()
end
# Base units are either
# A {numerator, denominator} tuple
# A list of {unit, base_unit} tuples
defp extract_unit_names({numerator, denominator}) do
{extract_keys(numerator), extract_keys(denominator)}
end
defp extract_unit_names(numerator) do
extract_keys(numerator)
end
# Extract the base units from the conversion
# And simplify base units (ie unwrap them)
defp extract_keys(list) do
Enum.map(list, fn
[prefix, conversion] ->
[prefix, hd(extract_keys(conversion))]
{_unit, conversion} ->
conversion
|> Map.fetch!(:base_unit)
|> case do
[unit] -> unit
[prefix, unit] -> [prefix, unit]
end
end)
end
# Merge all list elements, starting with the first
# two until the end of the list
defp resolve_unit_names([first]) do
first
end
defp resolve_unit_names([first, second | rest]) do
resolve_unit_names([merge_unit_names(first, second) | rest])
end
# Take two list elements and merge them noting that either
# element might be a "per tuple" represented by a tuple
defp merge_unit_names({numerator_a, denominator_a}, {numerator_b, denominator_b}) do
{merge_unit_names(numerator_a, numerator_b), merge_unit_names(denominator_a, denominator_b)}
end
defp merge_unit_names({numerator_a, denominator_a}, numerator_b) do
{merge_unit_names(numerator_a, numerator_b), denominator_a}
end
defp merge_unit_names(numerator_a, {numerator_b, denominator_b}) do
{merge_unit_names(numerator_a, numerator_b), denominator_b}
end
defp merge_unit_names(numerator_a, numerator_b) do
numerator_a ++ numerator_b
end
# Final pass for "per" base units
defp merge_unit_names({{_numerator_a, _denominator_a}, {_numerator_b, _denominator_b}}) do
raise ArgumentError, "unexpected"
end
defp merge_unit_names({{numerator_a, denominator_a}, numerator_b}) do
{numerator_a, merge_unit_names(numerator_b, denominator_a)}
end
defp merge_unit_names({numerator_a, {numerator_b, denominator_b}}) do
{merge_unit_names(numerator_a, denominator_b), numerator_b}
end
defp merge_unit_names(other) do
other
end
# Sort the units in canonical order
defp sort_base_units({numerator, denominator}) do
{Enum.sort(numerator, &base_unit_sorter/2), Enum.sort(denominator, &base_unit_sorter/2)}
end
defp sort_base_units(numerator) do
Enum.sort(numerator, &base_unit_sorter/2)
end
# Relies on base units only ever being a single unit
# or a list with two elements being a prefix and a unit except
# for a currency unit in which case it will be a binary of the
# form `curr-usd` by the time we get here. And currency forms
# always sort at the head of the list.
defp base_unit_sorter(unit_a, unit_b) when is_atom(unit_a) and is_atom(unit_b) do
Map.fetch!(base_units_in_order(), unit_a) < Map.fetch!(base_units_in_order(), unit_b)
end
defp base_unit_sorter(unit_a, [_prefix, unit_b]) when is_atom(unit_a) do
Map.fetch!(base_units_in_order(), unit_a) < Map.fetch!(base_units_in_order(), unit_b)
end
defp base_unit_sorter([_prefix, unit_a], unit_b) when is_atom(unit_b) do
Map.fetch!(base_units_in_order(), unit_a) < Map.fetch!(base_units_in_order(), unit_b)
end
defp base_unit_sorter([_prefix_a, unit_a], [_prefix_b, unit_b]) do
Map.fetch!(base_units_in_order(), unit_a) < Map.fetch!(base_units_in_order(), unit_b)
end
defp base_unit_sorter(@currency_base <> _currency, _) do
true
end
defp base_unit_sorter(_, @currency_base <> _currency) do
false
end
# Reduce factors. When its a "per" unit then
# we reduce the common factors.
# This is important to ensure that base unit
# comparisons work correctly across different units
# of the same type.
# Currently not being used but in the future this
# might be required.
@doc false
def reduce_factors({[], denominator}) do
{[], denominator}
end
def reduce_factors({numerator, []}) do
{numerator, []}
end
# Numerator and denominator cancel each other
def reduce_factors({[unit | rest_1], [unit | rest_2]}) do
reduce_factors({rest_1, rest_2}) #|> IO.inspect(label: "1")
end
def reduce_factors({[[:square, unit] | rest_1], [unit | rest_2]}) do
reduce_factors({[unit | rest_1], rest_2}) #|> IO.inspect(label: "2")
end
def reduce_factors({[unit | rest_1], [[:square, unit] | rest_2]}) do
reduce_factors({rest_1, [unit | rest_2]}) #|> IO.inspect(label: "3")
end
def reduce_factors({[unit | rest_1], [[:cubic, unit] | rest_2]}) do
reduce_factors({rest_1, [[:square, unit] | rest_2]}) #|> IO.inspect(label: "4")
end
def reduce_factors({[[:square, unit] | rest_1], [[:square, unit] | rest_2]}) do
reduce_factors({rest_1, rest_2}) #|> IO.inspect(label: "5")
end
def reduce_factors({[[:cubic, unit] | rest_1], [[:cubic, unit] | rest_2]}) do
reduce_factors({rest_1, rest_2}) #|> IO.inspect(label: "6")
end
def reduce_factors({[[:cubic, unit] | rest_1], [[:square, unit] | rest_2]}) do
reduce_factors({[unit | rest_1], rest_2}) #|> IO.inspect(label: "7")
end
def reduce_factors({[[:cubic, unit] | rest_1], [unit | rest_2]}) do
reduce_factors({[[:square, unit] | rest_1], rest_2}) #|> IO.inspect(label: "8")
end
def reduce_factors({[unit_1 | rest_1], rest_2}) do
{numerator, denominator} = reduce_factors({rest_1, rest_2})
{[unit_1 | numerator], denominator} #|> IO.inspect(label: "9")
end
def reduce_factors(other) do
other #|> IO.inspect(label: "Other")
end
# Reduce powers to square and cubic
defp reduce_powers({numerator, denominator}) do
{reduce_powers(numerator), reduce_powers(denominator)}
end
defp reduce_powers([first]) do
[first]
end
defp reduce_powers([first, first | rest]) do
reduce_powers([[:square, first] | rest])
end
defp reduce_powers([[:square, first], first | rest]) do
reduce_powers([[:cubic, first] | rest])
end
defp reduce_powers([first, [:square, first] | rest]) do
reduce_powers([[:cubic, first] | rest])
end
defp reduce_powers([first | rest]) do
[first | reduce_powers(rest)]
end
# Flaten the list and turn it into a string
defp flatten_and_stringify({[], denominator}) do
flatten_and_stringify(denominator)
end
defp flatten_and_stringify({numerator, []}) do
flatten_and_stringify(numerator)
end
defp flatten_and_stringify({numerator, denominator}) do
flatten_and_stringify(numerator) <> @per <> flatten_and_stringify(denominator)
end
defp flatten_and_stringify(numerator) do
numerator
|> List.flatten()
|> Enum.map(&to_string/1)
|> Enum.join("_")
end
@doc """
Returns the canonical base unit name
for a unit.
The base unit is the common unit through which
conversions are passed.
## Arguments
* `unit_string` is any string representing
a unit such as `light_year_per_week`.
## Returns
* `canonical_base_unit` or
* raises an exception
## Examples
iex> Cldr.Unit.Parser.canonical_base_unit! "meter"
:meter
iex> Cldr.Unit.Parser.canonical_base_unit! "meter meter"
:square_meter
iex> Cldr.Unit.Parser.canonical_base_unit! "meter per kilogram"
"meter_per_kilogram"
iex> Cldr.Unit.Parser.canonical_base_unit! "yottagram per mile scandinavian"
"kilogram_per_meter"
"""
def canonical_base_unit!(unit_string) when is_binary(unit_string) do
case canonical_base_unit(unit_string) do
{:ok, unit_name} -> unit_name
{:error, {exception, reason}} -> raise exception, reason
end
end
# We wrap in a tuple since a nested list can
# create ambiguous processing in other places
@doc false
def wrap([numerator, denominator], tag) do
{tag, {numerator, denominator}}
end
def wrap([numerator], tag) do
{tag, numerator}
end
def wrap(other, tag) do
{tag, other}
end
@base_units_in_order Cldr.Config.units()
|> Map.get(:base_units)
|> Cldr.Unit.Additional.merge_base_units()
|> Enum.map(&elem(&1, 1))
|> Enum.with_index()
|> Map.new()
@doc false
def base_units_in_order do
@base_units_in_order
end
end