View Source Formulae (formulae v0.15.2)

A set of functions to deal with analytical formulae.

The typical way of using this module would be to call Formulae.compile/1 on the binary representing the string.

iex|1  f = Formulae.compile "a + :math.sin(3.14 * div(b, 2)) - c"

#ℱ<[
  sigil: "~F[a + :math.sin(3.14 * div(b, 2)) - c]",
  eval: &:"Elixir.Formulae.a + :math.sin(3.14 * div(b, 2)) - c".eval/1,
  formula: "a + :math.sin(3.14 * div(b, 2)) - c",
  guard: nil,
  module: :"Elixir.Formulae.a + :math.sin(3.14 * div(b, 2)) - c",
  variables: [:a, :b, :c],
  options: [defaults: [], imports: [:...], evaluator: :function, alias: nil]
]>

Now the formula is compiled and might be invoked by calling Formulae.eval/2 passing a formula and bindings. First call to eval/2 would lazily compile the module if needed.

iex|2  f.eval.(a: 3, b: 4, c: 2)
0.9968146982068622

The formulae might be curried.

iex|3  Formulae.curry(f, a: 3, b: 4)

#ℱ<[
  sigil: "~F[3 + :math.sin(3.14 * div(4, 2)) - c]",
  eval: &:"Elixir.Formulae.3 + :math.sin(3.14 * div(4, 2)) - c".eval/1,
  formula: "3 + :math.sin(3.14 * div(4, 2)) - c",
  guard: nil,
  module: :"Elixir.Formulae.3 + :math.sin(3.14 * div(4, 2)) - c",
  variables: [:c],
  options: [defaults: [], imports: [:...], evaluator: :function, alias: nil]
]>

Since v0.10.0 there is an ability to pass defaults via options.

Examples:

iex> "z + t" |> Formulae.compile(defaults: [t: 5]) |> Formulae.eval(t: 10, z: 3)
13
iex> "z + t" |> Formulae.compile(defaults: [t: 5]) |> Formulae.eval(z: 3)
8

Summary

Types

t()

The formulae is internally represented as struct, exposing the original binary representing the formula, AST, the module this formula was compiled into, variables (bindings) this formula has and the evaluator, which is the function of arity one, accepting the bindings as a keyword list and returning the result of this formula application.

Functions

bindings?(formula, bindings \\ [], options \\ [imports: :none]) deprecated

Returns the binding this formula requires.

check(string, bindings \\ [], options \\ []) deprecated

Revalidates the formula with bindings given. Returns true if the formula strictly evaluates to true, false otherwise. Compiles the formula before evaluation if needed.

combinations(l, n)

Generated clauses for n ∈ [1..42] to be used with dynamic number

compile(input, options \\ [])

Compiles the formula into module.

compiled?(input, options \\ [])

Checks whether the formula was already compiled into module.

curry(input, binding \\ [], options \\ [])

Curries the formula by substituting the known bindings into it.

ensure_compiled(input, options \\ [])

Checks whether the formula was already compiled into module. Similar to compiled?/1, but returns what Code.ensure_compiled/1 returns.

eval(input, bindings \\ [], options \\ [imports: :none])

Evaluates the formula returning the result back.

eval!(input, bindings \\ [], options \\ [])

Evaluates the formula returning the result back; throws in a case of unseccessful processing.

evaluate(input, binding \\ [], options \\ []) deprecated

Evaluates normalized representation of formula.

formulas(include_internals? \\ false)

Lists all the compiled formulas.

normalize(input) deprecated

Returns a normalized representation for the formula given.

permutations(l, n)

Generated clauses for n ∈ [1..12] to be used with dynamic number

purge(input, options \\ [])

Purges and discards the module for the formula given (if exists.)

unit(input, env \\ []) deprecated

Produces the normalized representation of formula. If the rho is an instance of Integer or Float, it’s left intact, otherwise it’s moved to the left side with negation.

Types

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t()

View Source 
@type t() :: %{
  __struct__: atom(),
  formula: binary(),
  ast: nil | Macro.t(),
  eval: nil | (keyword() -> any()),
  guard: nil | Macro.t(),
  module: nil | atom(),
  variables: nil | [atom()],
  options: options()
}

The formulae is internally represented as struct, exposing the original binary representing the formula, AST, the module this formula was compiled into, variables (bindings) this formula has and the evaluator, which is the function of arity one, accepting the bindings as a keyword list and returning the result of this formula application.

Functions

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bindings?(formula, bindings \\ [], options \\ [imports: :none])

View Source
This function is deprecated. Use `Formulae.compile/1` and `%Formulae{}.variables` or `Formula.curry/2` instead.

Returns the binding this formula requires.

Examples 

iex> "a > 5" |> Formulae.bindings?()
~w|a|a

iex> ":math.sin(a / (3.14 * b)) > c" |> Formulae.bindings?([], imports: [:math])
~w|a b c|a

iex> "a + b * 4 - :math.pow(c, 2) / d > 1.0 * e" |> Formulae.bindings?([], imports: :math)
~w|a b c d e|a
Link to this function

check(string, bindings \\ [], options \\ [])

View Source
This function is deprecated. Use `Formulae.eval/2` instead. 
@spec check(string :: binary(), bindings :: keyword(), options :: options()) ::
  boolean()

Revalidates the formula with bindings given. Returns true if the formula strictly evaluates to true, false otherwise. Compiles the formula before evaluation if needed.

Link to this function

combinations(l, n)

View Source 
@spec combinations(list :: list(), count :: non_neg_integer()) :: [list()]

Generated clauses for n ∈ [1..42] to be used with dynamic number

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compile(input, options \\ [])

View Source 
@spec compile(t() | binary(), options :: options()) :: t()

Compiles the formula into module.

The allowed imports must be specified explicitly with imports: :all or a list of allowed imports imports: [DateTime, Range].

Examples:

iex> f = Formulae.compile("rem(a, 5) - b == 0")
iex> f.formula
"rem(a, 5) - b == 0"
iex> f.variables
[:a, :b]
iex> f.module
:"Elixir.Formulae.rem(a, 5) - b == 0"
iex> f.module.eval(a: 12, b: 2)
true

iex> f = Formulae.compile("rem(a, 5) + b == a")
iex> f.variables
[:a, :b]
iex> f.eval.(a: 7, b: 5)
true
iex> f.eval.(a: 7, b: 0)
false
Link to this function

compiled?(input, options \\ [])

View Source 
@spec compiled?(binary() | t(), options :: options()) :: boolean()

Checks whether the formula was already compiled into module.

Typically one does not need to call this function, since this check would be nevertheless transparently performed before the evaluation.

Examples:

iex> Formulae.compiled?("foo > 42")
false
iex> Formulae.compile("foo > 42")
iex> Formulae.compiled?("foo > 42")
true
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curry(input, binding \\ [], options \\ [])

View Source 
@spec curry(input :: t() | binary(), binding :: keyword(), options :: options()) ::
  t()

Curries the formula by substituting the known bindings into it.

Example 

iex> Formulae.curry("(temp - foo * 4) > speed / 3.14", temp: 7, speed: 3.14).formula
"7 - foo * 4 > 3.14 / 3.14"
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ensure_compiled(input, options \\ [])

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@spec ensure_compiled(binary() | t(), options :: options()) ::
  {:module, module()}
  | {:error,
     :embedded
     | :badfile
     | :nofile
     | :on_load_failure
     | :unavailable
     | {:already_taken, module()}
     | {:external_module, module()}}

Checks whether the formula was already compiled into module. Similar to compiled?/1, but returns what Code.ensure_compiled/1 returns.

Typically one does not need to call this function, since this check would be nevertheless transparently performed before the evaluation.

Examples:

iex> Formulae.ensure_compiled("bar > 42")
{:error, :nofile}
iex> Formulae.compile("bar > 42")
iex> Formulae.ensure_compiled("bar > 42")
{:module, :"Elixir.Formulae.bar > 42"}
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eval(input, bindings \\ [], options \\ [imports: :none])

View Source 
@spec eval(input :: binary() | t(), bindings :: keyword(), options :: options()) ::
  term() | {:error, any()}

Evaluates the formula returning the result back.

Examples:

iex> Formulae.eval("rem(a, 5) + rem(b, 4) == 0", a: 20, b: 20)
true
iex> Formulae.eval("rem(a, 5) == 0", a: 21)
false
iex> Formulae.eval("rem(a, 5) + rem(b, 4)", a: 21, b: 22)
3
iex> Formulae.eval("rem(a, 5) == b", [a: 8], defaults: [b: 3])
true
iex> Formulae.eval("rem(a, 5) == c", [a: 8, c: 3], defaults: [b: 3])
true
iex> Formulae.eval("to_integer(s) == i", [s: "42", i: 42], imports: [String])
true

Binary input is deprecated, create a formula explicitly with Formulae.compile/2 and then pass it as the first argument to eval/2".

The call to eval/3 would compile the formulae with default options.

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eval!(input, bindings \\ [], options \\ [])

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Evaluates the formula returning the result back; throws in a case of unseccessful processing.

Examples:

iex> Formulae.eval!("rem(a, 5) == 0", a: 20)
true
iex> Formulae.eval!("rem(a, 5) == 0")
** (Formulae.RunnerError) Formula ~F[rem(a, 5) == 0] failed to run (compile): [:missing_arguments], wrong or incomplete evaluator call: [given_keys: [], expected_keys: [:a]].
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evaluate(input, binding \\ [], options \\ [])

View Source
This function is deprecated. Use `Formulae.eval/2` instead. 
@spec evaluate(
  input :: binary() | tuple(),
  binding :: keyword(),
  options :: options()
) ::
  boolean() | no_return()

Evaluates normalized representation of formula.

Examples 

iex> Formulae.eval("3 > 2")
true

iex> Formulae.eval("3 < 2")
false

iex> Formulae.eval("a < 2", a: 1)
true

iex> Formulae.eval("a > 2", a: 1)
false

iex> Formulae.eval("a < 2", [])
{:error, {:missing_arguments, [given_keys: [], expected_keys: [:a]]}}

iex> Formulae.eval!("a < 2", [])
** (Formulae.RunnerError) Formula ~F[a < 2] failed to run (compile): [:missing_arguments], wrong or incomplete evaluator call: [given_keys: [], expected_keys: [:a]].

iex> Formulae.eval("a + 2 == 3", a: 1)
true

iex> Formulae.eval("a + 2 == 3", a: 2)
false

iex> Formulae.eval(~S|a == "3"|, a: "3")
true

iex> Formulae.eval(~S|a == "3"|, a: 3)
false

iex> Formulae.eval(~S|a == "3"|, a: "hello")
false

iex> Formulae.eval("a + 2 == 3", a: 2)
false

iex> Formulae.eval(~S|a == "3"|, a: "3")
true

iex> Formulae.eval("a_b_c_490000 > 2", a_b_c_490000: 3)
true
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formulas(include_internals? \\ false)

View Source 
@spec formulas(include_internals? :: boolean()) :: %{optional(binary()) => module()}

Lists all the compiled formulas.

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normalize(input)

View Source
This function is deprecated. Use `Formulae.compile/1` and `%Formulae{}.variables` instead.

Returns a normalized representation for the formula given.

Link to this function

permutations(l, n)

View Source 
@spec permutations(list :: list(), count :: non_neg_integer()) :: [list()]

Generated clauses for n ∈ [1..12] to be used with dynamic number

Link to this function

purge(input, options \\ [])

View Source 
@spec purge(t() | binary(), options()) ::
  :ok | {:error, :not_compiled} | {:error, :code_delete}

Purges and discards the module for the formula given (if exists.)

Link to this function

unit(input, env \\ [])

View Source
This function is deprecated. Use `Formulae.eval/2` instead.

Produces the normalized representation of formula. If the rho is an instance of Integer or Float, it’s left intact, otherwise it’s moved to the left side with negation.

Examples 

iex > Formulae.unit("3 > 2")
{"3 > 2", {:>, [], [3, 2]}}

iex > Formulae.unit("3 - a > 2")
{"3 - a > 2", {:>, [], [{:-, [line: 1], [3, {:a, [line: 1], nil}]}, 2]}}

iex > Formulae.unit("3 > A + 2")
{"3 > a + 2",
  {:>, [],
    [{:-, [context: Formulae, import: Kernel],
      [3, {:+, [line: 1], [{:a, [line: 1], nil}, 2]}]}, 0]}}

iex > Formulae.unit("3 >= a + 2")
{"3 >= a + 2",
  {:>=, [],
    [{:-, [context: Formulae, import: Kernel],
      [3, {:+, [line: 1], [{:a, [line: 1], nil}, 2]}]}, 0]}}

iex > Formulae.unit("3 a > A + 2")
** (Formulae.SyntaxError) Formula [3 a > A + 2] syntax is incorrect (parsing): syntax error before: “a”.

iex > Formulae.unit("a + 2 = 3")
{"a + 2 = 3", {:==, [], [{:+, [line: 1], [{:a, [line: 1], nil}, 2]}, 3]}}

iex > Formulae.unit(~S|A = "3"|)
{"a = \"3\"", {:==, [], [{:a, [line: 1], nil}, "3"]}}