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lib/vector.ex
defmodule A.Vector do
@moduledoc """
A Clojure-like persistent vector with efficient appends and random access.
[Persistent vectors](https://hypirion.com/musings/understanding-persistent-vector-pt-1)
are an efficient alternative to lists.
Many operations for `A.Vector` run in effective constant time (length, random access, appends...),
unlike linked lists for which most operations run in linear time.
Functions that need to go through the whole collection like `map/2` or `foldl/3` are as often fast as
their list equivalents, or sometimes even slightly faster.
Vectors also use less memory than lists for "big" collections (see the [Memory usage section](#module-memory-usage)).
Make sure to read the [Efficiency guide section](#module-efficiency-guide) to get the best performance
out of vectors.
Erlang's [`:array`](http://erlang.org/doc/man/array.html) module offer similar functionalities.
However `A.Vector`:
- is a better Elixir citizen: pipe-friendliness, `Access` behaviour, `Enum` / `Inspect` / `Collectable` protocols
- should have higher performance in most use cases, especially "loops" like `map/2` / `to_list/1` / `foldl/3`
- mirrors the `Enum` module API, with highly optimized versions for vectors (`join/1`, `sum/1`, `random/1`...)
- supports negative indexing (e.g. `-1` corresponds to the last element)
- optionally implements the `Jason.Encoder` protocol if `Jason` is installed
Note: most of the design is inspired by
[this series of blog posts](https://hypirion.com/musings/understanding-persistent-vector-pt-1),
but a branching factor of `16 = 2 ^ 4` has been picked instead of `32 = 2 ^ 5`.
This choice was made following performance benchmarking that showed better overall performance
for this particular implementation.
## Examples
iex> vector = A.Vector.new(1..10)
#A<vec([1, 2, 3, 4, 5, 6, 7, 8, 9, 10])>
iex> A.Vector.append(vector, :foo)
#A<vec([1, 2, 3, 4, 5, 6, 7, 8, 9, 10, :foo])>
iex> vector[3]
4
iex> A.Vector.replace_at(vector, -1, :bar)
#A<vec([1, 2, 3, 4, 5, 6, 7, 8, 9, :bar])>
iex> 3 in vector
true
## Access behaviour
`A.Vector` implements the `Access` behaviour.
iex> vector = A.Vector.new(1..10)
iex> vector[3]
4
iex> put_in(vector[5], :foo)
#A<vec([1, 2, 3, 4, 5, :foo, 7, 8, 9, 10])>
iex> {9, updated} = pop_in(vector[8]); updated
#A<vec([1, 2, 3, 4, 5, 6, 7, 8, 10])>
## Convenience [`vec/1`](`A.vec/1`) and [`vec_size/1`](`A.vec_size/1`) macros
The `A.Vector` module can be used without any macro.
The `A.vec/1` macro does however provide some syntactic sugar to make
it more convenient to work with vectors of known size, namely:
- pattern match on elements for vectors of known size
- construct new vectors of known size faster, by generating the AST at compile time
Examples:
iex> import A
iex> vec([1, 2, 3])
#A<vec([1, 2, 3])>
iex> vec([1, 2, var, _, _, _]) = A.Vector.new(1..6); var
3
The `A.vec_size/1` macro can be used in guards:
iex> import A
iex> match?(v when vec_size(v) > 99, A.Vector.new(1..100))
true
## Pattern-matching and opaque type
An `A.Vector` is represented internally using the `%A.Vector{}` struct. This struct
can be used whenever there's a need to pattern match on something being an `A.Vector`:
iex> match?(%A.Vector{}, A.Vector.new())
true
Note, however, than `A.Vector` is an [opaque type](https://hexdocs.pm/elixir/typespecs.html#user-defined-types):
its struct internal fields must not be accessed directly.
As discussed in the previous section, [`vec/1`](`A.vec/1`) makes it
possible to pattern match on size and elements as well as checking the type.
## Memory usage
Vectors have a small overhead over lists for smaller collections, but are using
far less memory for bigger collections:
iex> memory_for = fn n -> [Enum.to_list(1..n), A.Vector.new(1..n)] |> Enum.map(&:erts_debug.size/1) end
iex> memory_for.(1)
[2, 28]
iex> memory_for.(10)
[20, 28]
iex> memory_for.(100)
[200, 150]
iex> memory_for.(10_000)
[20000, 11370]
If you need to work with vectors containing mostly the same value, `A.Vector.duplicate/2`
is highly efficient both in time and memory (logarithmic).
It minimizes the number of actual copies and reuses the same nested structures under the hood:
iex> A.Vector.duplicate(0, 10_000) |> :erts_debug.size()
116
iex> A.Vector.duplicate(0, 10_000) |> :erts_debug.flat_size() # when shared over processes / ETS
11370
Even a 1B x 1B matrix of the same element costs virtually nothing!
big_n = 1_000_000_000
0 |> A.Vector.duplicate(big_n) |> A.Vector.duplicate(big_n) |> :erts_debug.size()
538
## Efficiency guide
If you are using vectors and not lists, chances are that you care about
performance. Here are a couple notes about how to use vectors in an optimal
way. Most functions from this module are highly efficient, those that are not
will indicate it in their documentation.
But remember the golden rule: **in case of doubt, always benchmark**.
### Avoid prepending
Appending is very efficient, but prepending is highly inefficient since the
whole array needs to be reconstructed.
**DON'T**
A.Vector.prepend(vector, :foo)
**DO**
[:foo | list] # use lists
A.Vector.append(vector, :foo)
### Avoid deletions
This implementation of persistent vectors has many advantages, but it does
not support efficient deletion, with the exception of the last element that
can be popped very efficiently (`A.Vector.pop_last/1`, `A.Vector.delete_last/1`).
Deleting close to the end of the vector is still fairly fast, but deleting near
the beginning needs to reconstruct most of the vector.
Deletion functionality is provided through functions like `A.Vector.pop_at/3`
and `A.Vector.delete_at/2` for the sake of completion, but please note that they
are inefficient and their usage is discouraged.
If you need to be able to pop arbitrary indexes, chances are you should consider
an alternative data structure.
Another possibility could be to use sparse arrays, defining `nil` as a deleted value
(but then the indexing and size won't reflect this).
**DON'T**
A.Vector.pop_at(vector, 3)
A.Vector.delete_at(vector, 3)
pop_in(vector[3])
**DO**
A.Vector.pop_last(vector)
A.Vector.delete_last(vector)
A.Vector.delete_at(vector, -3) # close to the end
A.Vector.replace_at(vector, 3, nil)
### Successive appends
If you just need to append all elements of an enumerable, it is more efficient to use
`A.Vector.concat/2` than successive calls to `A.Vector.append/2`:
**DON'T**
Enum.reduce(enumerable, vector, fn val, acc -> A.Vector.append(acc, val) end)
Enum.into(enumerable, vector)
**DO**
A.Vector.concat(vector, enumerable)
### Prefer `A.Vector` to `Enum` for vectors
Many functions provided in this module are very efficient and should be
used over `Enum` functions whenever possible, even if `A.Vector` implements
the `Enumerable` and `Collectable` protocols for convienience:
**DON'T**
Enum.sum(vector)
Enum.to_list(vector)
Enum.reduce(vector, [], fun)
Enum.into(enumerable, %A.Vector.new())
Enum.into(enumerable, vector)
**DO**
A.Vector.sum(vector)
A.Vector.to_list(vector)
A.Vector.foldl(vector, [], fun)
A.Vector.new(enumerable)
A.Vector.concat(vector, enumerable)
`for` comprehensions are actually using `Enumerable` as well, so
the same advice holds:
**DON'T**
for value <- vector do
do_stuff()
end
**DO**
for value <- A.Vector.to_list(vector) do
do_stuff()
end
### Exceptions: `Enum` optimized functions
`Enum.member?/2` is implemented in an efficient way, so `in/2` is optimal:
**DO**
33 in vector
`Enum.slice/2` and `Enum.slice/3` are optimized and their use is encouraged,
other "slicing" functions like `Enum.take/2` or `Enum.drop/2` however are inefficient:
**DON'T**
Enum.take(vector, 10)
Enum.drop(vector, 25)
**DO**
Enum.slice(vector, 0, 10)
Enum.slice(vector, 0..10)
Enum.slice(vector, 25..-1)
### Slicing optimization
Slicing any subset on the left on the vector using methods from `A.Vector` is
extremely efficient as the vector internals can be reused:
**DO**
A.Vector.take(vector, 10) # take a positive amount
A.Vector.drop(vector, -20) # drop a negative amount
A.Vector.slice(vector, 0, 10) # slicing from 0
A.Vector.slice(vector, 0..-5) # slicing from 0
### `A.Vector` and `Enum` APIs
Not all `Enum` functions have been mirrored in `A.Vector`, but
you can try either to:
- use `A.Vector.foldl/3` or `A.Vector.foldr/3` to implement it
(the latter is better to build lists)
- call `A.Vector.to_list/1` before using `Enum`
Also, it is worth noting that several `A.Vector` functions return vectors,
not lists like their `Enum` counterpart:
iex> vector = A.Vector.new(1..10)
iex> A.Vector.map(vector, & (&1 * 7))
#A<vec([7, 14, 21, 28, 35, 42, 49, 56, 63, 70])>
iex> A.Vector.reverse(vector)
#A<vec([10, 9, 8, 7, 6, 5, 4, 3, 2, 1])>
### Additional notes
* If you need to work with vectors containing mostly the same value,
use `A.Vector.duplicate/2` (more details in the [Memory usage section](#module-memory-usage)).
* If you work with functions returning vectors of known size, you can use
the `A.vec/1` macro to defer the generation of the AST for the internal
structure to compile time instead of runtime.
A.Vector.new([a, 1, 2, 3, 4]) # structure created at runtime
vec([a, 1, 2, 3, 4]) # structure AST defined at compile time
"""
alias A.Vector.{EmptyError, IndexError, Raw}
require Raw
@behaviour Access
@type index :: integer
@type value :: term
@opaque t(value) :: %__MODULE__{__vector__: Raw.t(value)}
@enforce_keys [:__vector__]
defstruct [:__vector__]
@type t :: t(value)
@empty_raw Raw.empty()
@doc """
Returns the number of elements in `vector`.
Runs in constant time.
## Examples
iex> A.Vector.new(10_000..20_000) |> A.Vector.size()
10001
iex> A.Vector.new() |> A.Vector.size()
0
"""
@compile {:inline, size: 1}
@spec size(t()) :: non_neg_integer
def size(%__MODULE__{__vector__: internal}) do
Raw.size(internal)
end
@doc """
Returns a new empty vector.
## Examples
iex> A.Vector.new()
#A<vec([])>
"""
@compile {:inline, new: 0}
@spec new :: t()
def new() do
%__MODULE__{__vector__: @empty_raw}
end
@doc """
Creates a vector from an `enumerable`.
Runs in linear time.
## Examples
iex> A.Vector.new(10..25)
#A<vec([10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25])>
"""
@spec new(Enumerable.t()) :: t()
def new(%__MODULE__{} = vector) do
vector
end
def new(enumerable) do
%__MODULE__{
__vector__: Raw.new(enumerable)
}
end
@doc """
Creates a vector from an `enumerable` via the given `transform` function.
## Examples
iex> A.Vector.new(1..10, &(&1 * &1))
#A<vec([1, 4, 9, 16, 25, 36, 49, 64, 81, 100])>
"""
@spec new(Enumerable.t(), (v1 -> v2)) :: t(v2) when v1: value, v2: value
def new(enumerable, fun) when is_function(fun, 1) do
case enumerable do
%__MODULE__{} ->
map(enumerable, fun)
_ ->
%__MODULE__{
__vector__: Raw.new(enumerable, fun)
}
end
end
@doc """
Duplicates the given element `n` times in a vector.
`n` is an integer greater than or equal to `0`.
If `n` is `0`, an empty list is returned.
Runs in logarithmic time regarding `n`. It is very fast and memory efficient
(see [Memory usage](#module-memory-usage)).
## Examples
iex> A.Vector.duplicate(nil, 10)
#A<vec([nil, nil, nil, nil, nil, nil, nil, nil, nil, nil])>
iex> A.Vector.duplicate(:foo, 0)
#A<vec([])>
"""
@spec duplicate(val, non_neg_integer) :: t(val) when val: value
def duplicate(value, n) when is_integer(n) and n >= 0 do
%__MODULE__{
__vector__: Raw.duplicate(value, n)
}
end
@doc """
Populates a vector of size `n` by calling `generator_fun` repeatedly.
## Examples
# Although not necessary, let's seed the random algorithm
iex> :rand.seed(:exsplus, {1, 2, 3})
iex> A.Vector.repeatedly(&:rand.uniform/0, 3)
#A<vec([0.40502929729990744, 0.45336720247823126, 0.04094511692041057])>
"""
def repeatedly(generator_fun, n)
when is_function(generator_fun, 0) and is_integer(n) and n >= 0 do
%__MODULE__{
__vector__: A.List.repeatedly(generator_fun, n) |> Raw.from_list()
}
end
@doc """
Appends a `value` at the end of a `vector`.
Runs in effective constant time.
## Examples
iex> A.Vector.new() |> A.Vector.append(:foo)
#A<vec([:foo])>
iex> A.Vector.new(1..5) |> A.Vector.append(:foo)
#A<vec([1, 2, 3, 4, 5, :foo])>
"""
@spec append(t(val), val) :: t(val) when val: value
def append(%__MODULE__{__vector__: internal}, value) do
%__MODULE__{
__vector__: Raw.append(internal, value)
}
end
@doc """
Appends all values from an `enumerable` at the end of a `vector`.
Runs in effective linear time in respect with the length of `enumerable`,
disregarding the size of the `vector`.
## Examples
iex> A.Vector.new(1..5) |> A.Vector.concat(10..15)
#A<vec([1, 2, 3, 4, 5, 10, 11, 12, 13, 14, 15])>
iex> A.Vector.new() |> A.Vector.concat(10..15)
#A<vec([10, 11, 12, 13, 14, 15])>
"""
@spec concat(t(val), Enumerable.t()) :: t(val) when val: value
def concat(%__MODULE__{__vector__: internal}, enumerable) do
list = A.FastEnum.to_list(enumerable)
%__MODULE__{
__vector__: Raw.concat(internal, list)
}
end
@deprecated "Use A.Vector.concat/2 instead"
defdelegate append_many(vector, enumerable), to: __MODULE__, as: :concat
@doc """
(Inefficient) Prepends `value` at the beginning of the `vector`.
Runs in linear time because the whole vector needs to be reconstructuded,
and should be avoided.
## Examples
iex> A.Vector.new() |> A.Vector.prepend(:foo)
#A<vec([:foo])>
iex> A.Vector.new(1..5) |> A.Vector.prepend(:foo)
#A<vec([:foo, 1, 2, 3, 4, 5])>
"""
@spec prepend(t(val), val) :: t(val) when val: value
def prepend(%__MODULE__{__vector__: internal}, value) do
%__MODULE__{
__vector__: Raw.prepend(internal, value)
}
end
@doc """
Returns the first element in the `vector` or `default` if `vector` is empty.
Runs in effective constant time.
## Examples
iex> A.Vector.new(1..10_000) |> A.Vector.first()
1
iex> A.Vector.new() |> A.Vector.first()
nil
"""
@spec first(t(val), default) :: val | default when val: value, default: term
def first(vector, default \\ nil)
def first(%__MODULE__{__vector__: internal}, default) do
Raw.first(internal, default)
end
@doc """
Returns the last element in the `vector` or `default` if `vector` is empty.
Runs in constant time (actual, not effective).
## Examples
iex> A.Vector.new(1..10_000) |> A.Vector.last()
10_000
iex> A.Vector.new() |> A.Vector.last()
nil
"""
@spec last(t(val), default) :: val | default when val: value, default: term
def last(vector, default \\ nil)
def last(%__MODULE__{__vector__: internal}, default) do
Raw.last(internal, default)
end
@doc """
Finds the element at the given `index` (zero-based), and returns it in a ok-entry.
If the `index` does not exist, returns `:error`.
Supports negative indexing from the end of the `vector`.
Runs in effective constant time.
## Examples
iex> A.Vector.new(1..1_000) |> A.Vector.fetch(555)
{:ok, 556}
iex> A.Vector.new(1..1_000) |> A.Vector.fetch(1_000)
:error
iex> A.Vector.new(1..1_000) |> A.Vector.fetch(-1)
{:ok, 1000}
"""
@impl Access
@spec fetch(t(val), index) :: {:ok, val} | :error when val: value
def fetch(vector, index)
def fetch(%__MODULE__{__vector__: internal}, index) when is_integer(index) do
Raw.fetch_any(internal, index)
end
@doc """
Finds the element at the given `index` (zero-based).
Returns `default` if `index` is out of bounds.
Supports negative indexing from the end of the `vector`.
Runs in effective constant time.
## Examples
iex> A.Vector.new(1..1_000) |> A.Vector.at(555)
556
iex> A.Vector.new(1..1_000) |> A.Vector.at(1_000)
nil
"""
@spec at(t(val), index, default) :: val | default when val: value, default: term
def at(vector, index, default \\ nil)
def at(%__MODULE__{__vector__: internal}, index, default) when is_integer(index) do
case Raw.fetch_any(internal, index) do
{:ok, value} -> value
:error -> default
end
end
@doc """
Finds the element at the given `index` (zero-based).
Raises an `A.Vector.IndexError` if `index` is out of bounds.
Supports negative indexing from the end of the `vector`.
Runs in effective constant time.
## Examples
iex> A.Vector.new(1..1_000) |> A.Vector.at!(555)
556
iex> A.Vector.new(1..1_000) |> A.Vector.at!(-10)
991
iex> A.Vector.new(1..1_000) |> A.Vector.at!(1_000)
** (A.Vector.IndexError) out of bound index: 1000 not in -1000..999
"""
@spec at(t(val), index) :: val when val: value
def at!(vector, index)
def at!(%__MODULE__{__vector__: internal}, index) when is_integer(index) do
case Raw.fetch_any(internal, index) do
{:ok, value} -> value
:error -> raise IndexError, index: index, size: Raw.size(internal)
end
end
@doc """
Returns a copy of `vector` with a replaced `value` at the specified `index`.
Returns the `vector` untouched if `index` is out of bounds.
Supports negative indexing from the end of the `vector`.
Runs in effective constant time.
## Examples
iex> A.Vector.new(1..8) |> A.Vector.replace_at(5, :foo)
#A<vec([1, 2, 3, 4, 5, :foo, 7, 8])>
iex> A.Vector.new(1..8) |> A.Vector.replace_at(8, :foo)
#A<vec([1, 2, 3, 4, 5, 6, 7, 8])>
iex> A.Vector.new(1..8) |> A.Vector.replace_at(-2, :foo)
#A<vec([1, 2, 3, 4, 5, 6, :foo, 8])>
"""
@spec replace_at(t(val), index, val) :: t(val) when val: value
def replace_at(%__MODULE__{__vector__: internal} = vector, index, value)
when is_integer(index) do
case Raw.replace_any(internal, index, value) do
{:ok, updated} -> %__MODULE__{__vector__: updated}
:error -> vector
end
end
@doc """
Returns a copy of `vector` with a replaced `value` at the specified `index`.
Raises an `A.Vector.IndexError` if `index` is out of bounds.
Supports negative indexing from the end of the `vector`.
Runs in effective constant time.
## Examples
iex> A.Vector.new(1..8) |> A.Vector.replace_at!(5, :foo)
#A<vec([1, 2, 3, 4, 5, :foo, 7, 8])>
iex> A.Vector.new(1..8) |> A.Vector.replace_at!(-2, :foo)
#A<vec([1, 2, 3, 4, 5, 6, :foo, 8])>
iex> A.Vector.new(1..8) |> A.Vector.replace_at!(8, :foo)
** (A.Vector.IndexError) out of bound index: 8 not in -8..7
"""
@spec replace_at!(t(val), index, val) :: t(val) when val: value
def replace_at!(%__MODULE__{__vector__: internal}, index, value)
when is_integer(index) do
case Raw.replace_any(internal, index, value) do
{:ok, updated} -> %__MODULE__{__vector__: updated}
:error -> raise IndexError, index: index, size: Raw.size(internal)
end
end
@doc """
Returns a copy of `vector` with an updated value at the specified `index`.
Returns the `vector` untouched if `index` is out of bounds.
Supports negative indexing from the end of the `vector`.
Runs in effective constant time.
## Examples
iex> A.Vector.new(1..8) |> A.Vector.update_at(2, &(&1 * 1000))
#A<vec([1, 2, 3000, 4, 5, 6, 7, 8])>
iex> A.Vector.new(1..8) |> A.Vector.update_at(8, &(&1 * 1000))
#A<vec([1, 2, 3, 4, 5, 6, 7, 8])>
iex> A.Vector.new(1..8) |> A.Vector.update_at(-1, &(&1 * 1000))
#A<vec([1, 2, 3, 4, 5, 6, 7, 8000])>
"""
@spec update_at(t(val), index, (val -> val)) :: t(val) when val: value
def update_at(%__MODULE__{__vector__: internal} = vector, index, fun)
when is_integer(index) and is_function(fun) do
case Raw.update_any(internal, index, fun) do
{:ok, updated} -> %__MODULE__{__vector__: updated}
:error -> vector
end
end
@doc """
Returns a copy of `vector` with an updated value at the specified `index`.
Raises an `A.Vector.IndexError` if `index` is out of bounds.
Supports negative indexing from the end of the `vector`.
Runs in effective constant time.
## Examples
iex> A.Vector.new(1..8) |> A.Vector.update_at!(2, &(&1 * 1000))
#A<vec([1, 2, 3000, 4, 5, 6, 7, 8])>
iex> A.Vector.new(1..8) |> A.Vector.update_at!(-1, &(&1 * 1000))
#A<vec([1, 2, 3, 4, 5, 6, 7, 8000])>
iex> A.Vector.new(1..8) |> A.Vector.update_at!(-9, &(&1 * 1000))
** (A.Vector.IndexError) out of bound index: -9 not in -8..7
"""
@spec update_at!(t(val), index, (val -> val)) :: t(val) when val: value
def update_at!(%__MODULE__{__vector__: internal}, index, fun)
when is_integer(index) and is_function(fun) do
case Raw.update_any(internal, index, fun) do
{:ok, updated} -> %__MODULE__{__vector__: updated}
:error -> raise IndexError, index: index, size: Raw.size(internal)
end
end
@doc """
Removes the last value from the `vector` and returns both the value and the updated vector.
Leaves the `vector` untouched if empty.
Runs in effective constant time.
## Examples
iex> vector = A.Vector.new(1..8)
iex> {8, updated} = A.Vector.pop_last(vector); updated
#A<vec([1, 2, 3, 4, 5, 6, 7])>
iex> {nil, updated} = A.Vector.pop_last(A.Vector.new()); updated
#A<vec([])>
"""
@spec pop_last(t(val), default) :: {val | default, t(val)} when val: value, default: term
def pop_last(vector, default \\ nil)
def pop_last(%__MODULE__{__vector__: internal} = vector, default) do
case Raw.pop_last(internal) do
{value, new_internal} -> {value, %__MODULE__{__vector__: new_internal}}
:error -> {default, vector}
end
end
@doc """
Removes the last value from the `vector` and returns both the value and the updated vector.
Raises an `A.Vector.EmptyError` if empty.
Runs in effective constant time.
## Examples
iex> vector = A.Vector.new(1..8)
iex> {8, updated} = A.Vector.pop_last!(vector); updated
#A<vec([1, 2, 3, 4, 5, 6, 7])>
iex> {nil, updated} = A.Vector.pop_last!(A.Vector.new()); updated
** (A.Vector.EmptyError) empty vector error
"""
@spec pop_last!(t(val)) :: {val, t(val)} when val: value
def pop_last!(vector)
def pop_last!(%__MODULE__{__vector__: internal}) do
case Raw.pop_last(internal) do
{value, new_internal} -> {value, %__MODULE__{__vector__: new_internal}}
:error -> raise EmptyError
end
end
@doc """
Removes the last value from the `vector` and returns the updated vector.
Leaves the `vector` untouched if empty.
Runs in effective constant time.
## Examples
iex> vector = A.Vector.new(1..8)
iex> A.Vector.delete_last(vector)
#A<vec([1, 2, 3, 4, 5, 6, 7])>
iex> A.Vector.delete_last(A.Vector.new())
#A<vec([])>
"""
@spec delete_last(t(val)) :: t(val) when val: value
def delete_last(vector)
def delete_last(%__MODULE__{__vector__: internal} = vector) do
case Raw.pop_last(internal) do
{_value, new_internal} -> %__MODULE__{__vector__: new_internal}
:error -> vector
end
end
@doc """
Removes the last value from the `vector` and returns the updated vector.
Raises an `A.Vector.EmptyError` if empty.
Runs in effective constant time.
## Examples
iex> vector = A.Vector.new(1..8)
iex> A.Vector.delete_last!(vector)
#A<vec([1, 2, 3, 4, 5, 6, 7])>
iex> A.Vector.delete_last!(A.Vector.new())
** (A.Vector.EmptyError) empty vector error
"""
@spec delete_last!(t(val)) :: t(val) when val: value
def delete_last!(vector)
def delete_last!(%__MODULE__{__vector__: internal}) do
case Raw.pop_last(internal) do
{_value, new_internal} -> %__MODULE__{__vector__: new_internal}
:error -> raise EmptyError
end
end
@doc """
(Inefficient) Returns and removes the value at the specified `index` in the `vector`.
Returns the `vector` untouched if `index` is out of bounds.
Supports negative indexing from the end of the `vector`.
Runs in linear time. Its usage is discouraged, see the
[Efficiency guide](#module-efficiency-guide).
## Examples
iex> vector = A.Vector.new(1..8)
iex> {5, updated} = A.Vector.pop_at(vector, 4); updated
#A<vec([1, 2, 3, 4, 6, 7, 8])>
iex> {nil, updated} = A.Vector.pop_at(vector, -9); updated
#A<vec([1, 2, 3, 4, 5, 6, 7, 8])>
"""
@spec pop_at(t(val), index, default) :: {val | default, t(val)} when val: value, default: term
def pop_at(vector, index, default \\ nil)
def pop_at(%__MODULE__{__vector__: internal} = vector, index, default) when is_integer(index) do
case Raw.pop_any(internal, index) do
{value, new_internal} -> {value, %__MODULE__{__vector__: new_internal}}
:error -> {default, vector}
end
end
@doc """
(Inefficient) Returns and removes the value at the specified `index` in the `vector`.
Raises an `A.Vector.IndexError` if `index` is out of bounds.
Supports negative indexing from the end of the `vector`.
Runs in linear time. Its usage is discouraged, see the
[Efficiency guide](#module-efficiency-guide).
## Examples
iex> vector = A.Vector.new(1..8)
iex> {5, updated} = A.Vector.pop_at!(vector, 4); updated
#A<vec([1, 2, 3, 4, 6, 7, 8])>
iex> A.Vector.pop_at!(vector, -9)
** (A.Vector.IndexError) out of bound index: -9 not in -8..7
"""
@spec pop_at!(t(val), index) :: {val, t(val)} when val: value
def pop_at!(vector, index)
def pop_at!(%__MODULE__{__vector__: internal}, index) when is_integer(index) do
case Raw.pop_any(internal, index) do
{value, new_internal} -> {value, %__MODULE__{__vector__: new_internal}}
:error -> raise IndexError, index: index, size: Raw.size(internal)
end
end
@doc false
@impl Access
@spec pop(t(val), index) :: {val | nil, t(val)} when val: value
defdelegate pop(vector, key), to: __MODULE__, as: :pop_at
@doc """
(Inefficient) Returns a copy of `vector` without the value at the specified `index`.
Returns the `vector` untouched if `index` is out of bounds.
Supports negative indexing from the end of the `vector`.
Runs in linear time. Its usage is discouraged, see the
[Efficiency guide](#module-efficiency-guide).
## Examples
iex> vector = A.Vector.new(1..8)
iex> A.Vector.delete_at(vector, 4)
#A<vec([1, 2, 3, 4, 6, 7, 8])>
iex> A.Vector.delete_at(vector, -9)
#A<vec([1, 2, 3, 4, 5, 6, 7, 8])>
"""
@spec delete_at(t(val), index) :: t(val) when val: value
def delete_at(%__MODULE__{__vector__: internal} = vector, index) when is_integer(index) do
case Raw.delete_any(internal, index) do
{:ok, new_internal} -> %__MODULE__{__vector__: new_internal}
:error -> vector
end
end
@doc """
(Inefficient) Returns a copy of `vector` without the value at the specified `index`.
Raises an `A.Vector.IndexError` if `index` is out of bounds.
Supports negative indexing from the end of the `vector`.
Runs in linear time. Its usage is discouraged, see the
[Efficiency guide](#module-efficiency-guide).
## Examples
iex> vector = A.Vector.new(1..8)
iex> A.Vector.delete_at!(vector, 4)
#A<vec([1, 2, 3, 4, 6, 7, 8])>
iex> A.Vector.delete_at!(vector, -9)
** (A.Vector.IndexError) out of bound index: -9 not in -8..7
"""
@spec delete_at!(t(val), index) :: t(val) when val: value
def delete_at!(vector, index)
def delete_at!(%__MODULE__{__vector__: internal}, index) when is_integer(index) do
case Raw.delete_any(internal, index) do
{:ok, new_internal} -> %__MODULE__{__vector__: new_internal}
:error -> raise IndexError, index: index, size: Raw.size(internal)
end
end
@doc """
Gets the value from key and updates it, all in one pass.
See `Access.get_and_update/3` for more details.
## Examples
iex> vector = A.Vector.new(1..8)
iex> {6, updated} = A.Vector.get_and_update(vector, 5, fn current_value ->
...> {current_value, current_value && current_value * 100}
...> end); updated
#A<vec([1, 2, 3, 4, 5, 600, 7, 8])>
iex> {nil, updated} = A.Vector.get_and_update(vector, 8, fn current_value ->
...> {current_value, current_value && current_value * 100}
...> end); updated
#A<vec([1, 2, 3, 4, 5, 6, 7, 8])>
iex> {4, updated} = A.Vector.get_and_update(vector, 3, fn _ -> :pop end); updated
#A<vec([1, 2, 3, 5, 6, 7, 8])>
iex> {nil, updated} = A.Vector.get_and_update(vector, 8, fn _ -> :pop end); updated
#A<vec([1, 2, 3, 4, 5, 6, 7, 8])>
"""
@impl Access
@spec get_and_update(t(v), index, (v -> {returned, v} | :pop)) :: {returned, t(v)}
when v: value, returned: term
def get_and_update(%__MODULE__{__vector__: internal}, index, fun)
when is_integer(index) and is_function(fun, 1) do
{returned, new_internal} = Raw.get_and_update_any(internal, index, fun)
{returned, %__MODULE__{__vector__: new_internal}}
end
@doc """
Converts the `vector` to a list.
Runs in linear time.
## Examples
iex> A.Vector.new(10..25) |> A.Vector.to_list()
[10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25]
iex> A.Vector.new() |> A.Vector.to_list()
[]
"""
@spec to_list(t(val)) :: [val] when val: value
def to_list(%__MODULE__{__vector__: internal}) do
Raw.to_list(internal)
end
@doc """
Returns a new vector where each element is the result of invoking `fun`
on each corresponding element of `vector`.
Runs in linear time.
## Examples
iex> A.Vector.new(1..10) |> A.Vector.map(&(&1 * &1))
#A<vec([1, 4, 9, 16, 25, 36, 49, 64, 81, 100])>
"""
@spec map(t(v1), (v1 -> v2)) :: t(v2) when v1: value, v2: value
def map(%__MODULE__{__vector__: internal}, fun) when is_function(fun, 1) do
%__MODULE__{
__vector__: Raw.map(internal, fun)
}
end
@doc """
Filters the `vector`, i.e. return a new vector containing only elements
for which `fun` returns a truthy (neither `false` nor `nil`) value.
Runs in linear time.
## Examples
iex> vector = A.Vector.new(1..100)
iex> A.Vector.filter(vector, fn i -> rem(i, 13) == 0 end)
#A<vec([13, 26, 39, 52, 65, 78, 91])>
"""
@spec filter(t(val), (val -> boolean)) :: t(val) when val: value
def filter(%__MODULE__{__vector__: internal}, fun) when is_function(fun, 1) do
%__MODULE__{
__vector__: Raw.filter(internal, fun)
}
end
@doc """
Filters the `vector`, i.e. return a new vector containing only elements
for which `fun` returns a falsy (either `false` or `nil`) value.
Runs in linear time.
## Examples
iex> vector = A.Vector.new(1..12)
iex> A.Vector.reject(vector, fn i -> rem(i, 3) == 0 end)
#A<vec([1, 2, 4, 5, 7, 8, 10, 11])>
"""
@spec reject(t(val), (val -> boolean)) :: t(val) when val: value
def reject(%__MODULE__{__vector__: internal}, fun) when is_function(fun, 1) do
%__MODULE__{
__vector__: Raw.reject(internal, fun)
}
end
@doc """
Sorts the `vector` in the same way as `Enum.sort/1`.
## Examples
iex> A.Vector.new(9..1) |> A.Vector.sort()
#A<vec([1, 2, 3, 4, 5, 6, 7, 8, 9])>
"""
@spec sort(t(val)) :: t(val) when val: value
def sort(%__MODULE__{__vector__: internal}) do
new_internal =
internal
|> Raw.to_list()
|> Enum.sort()
|> Raw.from_list()
%__MODULE__{__vector__: new_internal}
end
@doc """
Sorts the `vector` in the same way as `Enum.sort/2`.
See `Enum.sort/2` documentation for detailled usage.
## Examples
iex> A.Vector.new(1..9) |> A.Vector.sort(:desc)
#A<vec([9, 8, 7, 6, 5, 4, 3, 2, 1])>
"""
@spec sort(
t(val),
(val, val -> boolean)
| :asc
| :desc
| module
| {:asc | :desc, module}
) :: t(val)
when val: value
def sort(%__MODULE__{__vector__: internal}, fun) do
new_internal =
internal
|> Raw.to_list()
|> Enum.sort(fun)
|> Raw.from_list()
%__MODULE__{__vector__: new_internal}
end
@doc """
Sorts the `vector` in the same way as `Enum.sort_by/3`.
See `Enum.sort_by/3` documentation for detailled usage.
## Examples
iex> vector = A.Vector.new(["some", "kind", "of", "monster"])
iex> A.Vector.sort_by(vector, &byte_size/1)
#A<vec(["of", "some", "kind", "monster"])>
iex> A.Vector.sort_by(vector, &{byte_size(&1), String.first(&1)})
#A<vec(["of", "kind", "some", "monster"])>
"""
@spec sort_by(
t(val),
(val -> mapped_val),
(val, val -> boolean)
| :asc
| :desc
| module
| {:asc | :desc, module}
) :: t(val)
when val: value, mapped_val: value
def sort_by(%__MODULE__{__vector__: internal}, mapper, sorter \\ &<=/2) do
new_internal =
internal
|> Raw.to_list()
|> Enum.sort_by(mapper, sorter)
|> Raw.from_list()
%__MODULE__{__vector__: new_internal}
end
@doc """
Returns a copy of the vector without any duplicated element.
The first occurrence of each element is kept.
Runs in linear time.
## Examples
iex> A.Vector.new([1, 1, 2, 1, 2, 3, 2]) |> A.Vector.uniq()
#A<vec([1, 2, 3])>
"""
@spec uniq(t(val)) :: t(val) when val: value
def uniq(%__MODULE__{__vector__: internal}) do
# TODO optimize (take until found a dupe, and concat the rest)
new_internal =
internal
|> Raw.to_list()
|> Enum.uniq()
|> Raw.from_list()
%__MODULE__{__vector__: new_internal}
end
@doc """
Returns a copy of the vector without elements for which the function `fun` returned duplicate elements.
The first occurrence of each element is kept.
Runs in linear time.
## Examples
iex> vector = A.Vector.new([x: 1, y: 2, z: 1])
#A<vec([x: 1, y: 2, z: 1])>
iex> A.Vector.uniq_by(vector, fn {_x, y} -> y end)
#A<vec([x: 1, y: 2])>
"""
@spec uniq_by(t(val), (val -> term)) :: t(val) when val: value
def uniq_by(%__MODULE__{__vector__: internal}, fun) when is_function(fun, 1) do
new_internal =
internal
|> Raw.to_list()
|> Enum.uniq_by(fun)
|> Raw.from_list()
%__MODULE__{__vector__: new_internal}
end
@doc """
Intersperses `separator` between each element of the `vector`.
Runs in linear time.
## Examples
iex> A.Vector.new(1..6) |> A.Vector.intersperse(nil)
#A<vec([1, nil, 2, nil, 3, nil, 4, nil, 5, nil, 6])>
"""
@spec intersperse(
t(val),
separator
) :: t(val | separator)
when val: value, separator: value
def intersperse(%__MODULE__{__vector__: internal}, separator) do
new_internal =
internal
|> Raw.intersperse(separator)
|> Raw.from_list()
%__MODULE__{__vector__: new_internal}
end
@doc """
Maps and intersperses the `vector` in one pass.
Runs in linear time.
## Examples
iex> A.Vector.new(1..6) |> A.Vector.map_intersperse(nil, &(&1 * 10))
#A<vec([10, nil, 20, nil, 30, nil, 40, nil, 50, nil, 60])>
"""
@spec map_intersperse(
t(val),
separator,
(val -> mapped_val)
) :: t(mapped_val | separator)
when val: value, separator: value, mapped_val: value
def map_intersperse(%__MODULE__{__vector__: internal}, separator, mapper)
when is_function(mapper, 1) do
new_internal =
internal
|> Raw.map(mapper)
|> Raw.intersperse(separator)
|> Raw.from_list()
%__MODULE__{__vector__: new_internal}
end
@doc """
Folds (reduces) the given `vector` from the left with the function `fun`.
Requires an accumulator `acc`.
Runs in linear time.
## Examples
iex> A.Vector.new(1..10) |> A.Vector.foldl(0, &+/2)
55
iex> A.Vector.new(1..10) |> A.Vector.foldl([], & [&1 | &2])
[10, 9, 8, 7, 6, 5, 4, 3, 2, 1]
"""
@spec foldl(t(val), acc, (val, acc -> acc)) :: acc when val: value, acc: term
def foldl(%__MODULE__{__vector__: internal}, acc, fun) when is_function(fun, 2) do
Raw.foldl(internal, acc, fun)
end
@doc """
Folds (reduces) the given `vector` from the right with the function `fun`.
Requires an accumulator `acc`.
Unlike linked lists, this is as efficient as `foldl/3`. This can typically save a call
to `Enum.reverse/1` on the result when building a list.
Runs in linear time.
## Examples
iex> A.Vector.new(1..10) |> A.Vector.foldr(0, &+/2)
55
iex> A.Vector.new(1..10) |> A.Vector.foldr([], & [&1 | &2])
[1, 2, 3, 4, 5, 6, 7, 8, 9, 10]
"""
@spec foldr(t(val), acc, (val, acc -> acc)) :: acc when val: value, acc: term
def foldr(%__MODULE__{__vector__: internal}, acc, fun) when is_function(fun, 2) do
Raw.foldr(internal, acc, fun)
end
@doc """
Invokes the given `fun` for each element in the `vector`.
Returns `:ok`.
Runs in linear time.
## Examples
A.Vector.new(1..3) |> A.Vector.each(&IO.inspect/1)
1
2
3
:ok
"""
@spec each(t(val), (val -> term)) :: :ok when val: value
def each(%__MODULE__{__vector__: internal}, fun) when is_function(fun, 1) do
Raw.each(internal, fun)
end
@doc """
Returns the sum of all elements in the `vector`.
Raises `ArithmeticError` if `vector` contains a non-numeric value.
Runs in linear time.
## Examples
iex> A.Vector.new(1..10) |> A.Vector.sum()
55
iex> A.Vector.new() |> A.Vector.sum()
0
"""
@spec sum(t(num)) :: num when num: number
def sum(%__MODULE__{__vector__: internal}) do
Raw.sum(internal)
end
@doc """
Returns the product of all elements in the `vector`.
Raises `ArithmeticError` if `vector` contains a non-numeric value.
Runs in linear time.
## Examples
iex> A.Vector.new(1..5) |> A.Vector.product()
120
iex> A.Vector.new() |> A.Vector.product()
1
"""
@spec product(t(num)) :: num when num: number
def product(%__MODULE__{__vector__: internal}) do
Raw.product(internal)
end
@doc """
Joins the given `vector` into a string using `joiner` as a separator.
If `joiner` is not passed at all, it defaults to an empty string.
All elements in the `vector` must be convertible to a string, otherwise an error is raised.
Runs in linear time.
## Examples
iex> A.Vector.new(1..6) |> A.Vector.join()
"123456"
iex> A.Vector.new(1..6) |> A.Vector.join(" + ")
"1 + 2 + 3 + 4 + 5 + 6"
iex> A.Vector.new() |> A.Vector.join(" + ")
""
"""
@spec join(t(val), String.t()) :: String.t() when val: String.Chars.t()
def join(%__MODULE__{__vector__: internal}, joiner \\ "") when is_binary(joiner) do
Raw.join_as_iodata(internal, joiner) |> IO.iodata_to_binary()
end
@doc """
Maps and joins the given `vector` into a string using `joiner` as a separator.
If `joiner` is not passed at all, it defaults to an empty string.
`mapper` should only return values that are convertible to a string, otherwise an error is raised.
Runs in linear time.
## Examples
iex> A.Vector.new(1..6) |> A.Vector.map_join(fn x -> x * 10 end)
"102030405060"
iex> A.Vector.new(1..6) |> A.Vector.map_join(" + ", fn x -> x * 10 end)
"10 + 20 + 30 + 40 + 50 + 60"
iex> A.Vector.new() |> A.Vector.map_join(" + ", fn x -> x * 10 end)
""
"""
@spec map_join(t(val), String.t(), (val -> String.Chars.t())) :: String.t()
when val: value
def map_join(%__MODULE__{__vector__: internal}, joiner \\ "", mapper)
when is_binary(joiner) and is_function(mapper, 1) do
internal
|> Raw.map(mapper)
|> Raw.join_as_iodata(joiner)
|> IO.iodata_to_binary()
end
@doc """
Returns the maximal element in the `vector` according to Erlang's term ordering.
Runs in linear time.
## Examples
iex> A.Vector.new(1..10) |> A.Vector.max()
10
iex> A.Vector.new() |> A.Vector.max()
** (A.Vector.EmptyError) empty vector error
"""
@spec max(t(val)) :: val when val: value
def max(%__MODULE__{__vector__: internal}) do
Raw.max(internal)
end
@doc """
Returns the minimal element in the `vector` according to Erlang's term ordering.
Runs in linear time.
## Examples
iex> A.Vector.new(1..10) |> A.Vector.min()
1
iex> A.Vector.new() |> A.Vector.min()
** (A.Vector.EmptyError) empty vector error
"""
@spec min(t(val)) :: val when val: value
def min(%__MODULE__{__vector__: internal}) do
# TODO mirror Enum API
Raw.min(internal)
end
@doc """
Returns `true` if at least one element in `enumerable` is truthy.
Runs in linear time, but stops evaluating when finds the first truthy value.
Iterates over the `enumerable`, and when it finds a truthy value
(neither `false` nor `nil`), `true` is returned.
In all other cases `false` is returned.
## Examples
iex> A.Vector.new([false, false, true]) |> A.Vector.any?()
true
iex> A.Vector.new([false, nil]) |> A.Vector.any?()
false
iex> A.Vector.new() |> A.Vector.any?()
false
"""
@spec any?(t(val)) :: boolean when val: value
def any?(%__MODULE__{__vector__: internal}) do
Raw.any?(internal)
end
@doc """
Returns `true` if `fun.(element)` is truthy for at least one element in `enumerable`.
Runs in linear time, but stops evaluating when finds the first truthy value.
Iterates over the `enumerable` and invokes `fun` on each element. When an invocation
of `fun` returns a truthy value (neither `false` nor `nil`) iteration stops immediately
and `true` is returned. In all other cases `false` is returned.
## Examples
iex> vector = A.Vector.new(1..10)
iex> A.Vector.any?(vector, fn i -> rem(i, 7) == 0 end)
true
iex> A.Vector.any?(vector, fn i -> rem(i, 13) == 0 end)
false
iex> A.Vector.new() |> A.Vector.any?(fn i -> rem(i, 7) == 0 end)
false
"""
@spec any?(t(val), (val -> as_boolean(term))) :: boolean when val: value
def any?(%__MODULE__{__vector__: internal}, fun) when is_function(fun, 1) do
Raw.any?(internal, fun)
end
@doc """
Returns `true` if all elements in `enumerable` are truthy.
Runs in linear time, but stops evaluating when finds the first falsy value.
Iterates over the `enumerable`, and when it finds a falsy value (`false` or `nil`),
`false` is returned. In all other cases `true` is returned.
## Examples
iex> A.Vector.new([true, true, false]) |> A.Vector.all?()
false
iex> A.Vector.new([true, [], %{}, 5]) |> A.Vector.all?()
true
iex> A.Vector.new() |> A.Vector.all?()
true
"""
@spec all?(t(val)) :: boolean when val: value
def all?(%__MODULE__{__vector__: internal}) do
Raw.all?(internal)
end
@doc """
Returns `true` if `fun.(element)` is truthy for all elements in `enumerable`.
Runs in linear time, but stops evaluating when finds the first falsy value.
Iterates over the `enumerable` and invokes `fun` on each element. When an invocation
of `fun` returns a falsy value (`false` or `nil`) iteration stops immediately and
`false` is returned. In all other cases `true` is returned.
## Examples
iex> vector = A.Vector.new(1..10)
iex> A.Vector.all?(vector, fn i -> rem(i, 13) != 0 end)
true
iex> A.Vector.all?(vector, fn i -> rem(i, 7) != 0 end)
false
iex> A.Vector.new() |> A.Vector.all?(fn i -> rem(i, 7) != 0 end)
true
"""
@spec all?(t(val), (val -> as_boolean(term))) :: boolean when val: value
def all?(%__MODULE__{__vector__: internal}, fun) when is_function(fun, 1) do
Raw.all?(internal, fun)
end
@doc """
Returns the `vector` in reverse order.
Runs in linear time.
## Examples
iex> A.Vector.new(1..12) |> A.Vector.reverse()
#A<vec([12, 11, 10, 9, 8, 7, 6, 5, 4, 3, 2, 1])>
"""
@spec reverse(t(val)) :: t(val) when val: value
def reverse(%__MODULE__{__vector__: internal}) do
internal
|> Raw.to_reverse_list()
|> new()
end
@doc """
Returns a subset of the given `vector` by `index_range`.
Works the same as `Enum.slice/2`, see its documentation for more details.
Runs in linear time regarding the size of the returned subset.
## Examples
iex> A.Vector.new(0..100) |> A.Vector.slice(80..90)
#A<vec([80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90])>
iex> A.Vector.new(0..100) |> A.Vector.slice(-40..-30)
#A<vec([61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71])>
iex> A.Vector.new([:only_one]) |> A.Vector.slice(0..1000)
#A<vec([:only_one])>
"""
@spec slice(t(val), Range.t()) :: t(val) when val: value
def slice(%__MODULE__{} = vector, first..last = index_range) do
case first do
0 ->
amount = last + 1
if last < 0 do
drop(vector, amount)
else
take(vector, amount)
end
_ ->
vector
|> Enum.slice(index_range)
|> new()
end
end
@doc """
Returns a subset of the given `vector`, from `start_index` (zero-based)
with `amount number` of elements if available.
Works the same as `Enum.slice/3`, see its documentation for more details.
Runs in linear time regarding the size of the returned subset.
## Examples
iex> A.Vector.new(0..100) |> A.Vector.slice(80, 10)
#A<vec([80, 81, 82, 83, 84, 85, 86, 87, 88, 89])>
iex> A.Vector.new(0..100) |> A.Vector.slice(-40, 10)
#A<vec([61, 62, 63, 64, 65, 66, 67, 68, 69, 70])>
iex> A.Vector.new([:only_one]) |> A.Vector.slice(0, 1000)
#A<vec([:only_one])>
"""
@spec slice(t(val), index, non_neg_integer) :: t(val) when val: value
def slice(%__MODULE__{__vector__: internal} = vector, start_index, amount)
when is_integer(start_index) and is_integer(amount) and amount >= 0 do
if start_index == 0 or start_index == -Raw.size(internal) do
new_internal = Raw.take(internal, amount)
%__MODULE__{__vector__: new_internal}
else
vector
|> Enum.slice(start_index, amount)
|> new()
end
end
@doc """
Takes an `amount` of elements from the beginning or the end of the `vector`.
If a positive `amount` is given, it takes the amount elements from the beginning of the `vector`.
If a negative `amount` is given, the amount of elements will be taken from the end.
If amount is 0, it returns the empty vector.
Time complexity is:
- effective constant time when `amount` is positive, as the vector structure can be shared
- linear when `amount` is negative, as the vector needs to be reconstructed.
## Examples
iex> A.Vector.new(0..100) |> A.Vector.take(10)
#A<vec([0, 1, 2, 3, 4, 5, 6, 7, 8, 9])>
iex> A.Vector.new([:only_one]) |> A.Vector.take(1000)
#A<vec([:only_one])>
iex> A.Vector.new(0..10) |> A.Vector.take(-5)
#A<vec([6, 7, 8, 9, 10])>
"""
@spec take(t(val), integer) :: t(val) when val: value
def take(%__MODULE__{__vector__: internal}, amount) when is_integer(amount) do
new_internal = do_take(internal, amount)
%__MODULE__{__vector__: new_internal}
end
defp do_take(internal, amount) when amount < 0 do
size = Raw.size(internal)
case size + amount do
start when start > 0 ->
internal
|> Raw.slice(start, size - 1)
|> Raw.from_list()
_ ->
internal
end
end
defp do_take(internal, amount) do
Raw.take(internal, amount)
end
@doc """
Drops the amount of elements from the `vector`.
If a negative `amount` is given, the amount of last values will be dropped.
Time complexity is:
- linear when `amount` is positive, as the vector needs to be reconstructed.
- effective constant time when `amount` is negative, as the vector structure can be shared
## Examples
iex> A.Vector.new(0..15) |> A.Vector.drop(10)
#A<vec([10, 11, 12, 13, 14, 15])>
iex> A.Vector.new(0..5) |> A.Vector.drop(0)
#A<vec([0, 1, 2, 3, 4, 5])>
iex> A.Vector.new(0..10) |> A.Vector.drop(-5)
#A<vec([0, 1, 2, 3, 4, 5])>
"""
@spec drop(t(val), integer) :: t(val) when val: value
def drop(%__MODULE__{__vector__: internal}, amount) when is_integer(amount) do
new_internal = do_drop(internal, amount)
%__MODULE__{__vector__: new_internal}
end
defp do_drop(internal, _amount = 0) do
internal
end
defp do_drop(internal, amount) when amount < 0 do
size = Raw.size(internal)
case size + amount do
keep when keep > 0 -> Raw.take(internal, size + amount)
_ -> @empty_raw
end
end
defp do_drop(internal, amount) do
size = Raw.size(internal)
if amount >= size do
@empty_raw
else
internal
|> Raw.slice(amount, size - 1)
|> Raw.from_list()
end
end
@doc """
Returns the `vector` with each element wrapped in a tuple alongside its index.
If an `offset` is given, we will index from the given `offset` instead of from zero.
Runs in linear time.
## Examples
iex> A.Vector.new(["foo", "bar", "baz"]) |> A.Vector.with_index()
#A<vec([{"foo", 0}, {"bar", 1}, {"baz", 2}])>
iex> A.Vector.new() |> A.Vector.with_index()
#A<vec([])>
iex> A.Vector.new(["foo", "bar", "baz"]) |> A.Vector.with_index(100)
#A<vec([{"foo", 100}, {"bar", 101}, {"baz", 102}])>
"""
@spec with_index(t(val), index) :: t({val, index}) when val: value
def with_index(%__MODULE__{__vector__: internal}, offset \\ 0) when is_integer(offset) do
new_internal = Raw.with_index(internal, offset)
%__MODULE__{__vector__: new_internal}
end
@doc """
Returns a random element of a `vector`.
Raises `Vector.EmptyError` if `vector` is empty.
Like `Enum.random/1`, this function uses Erlang's [`:rand` module](http://www.erlang.org/doc/man/rand.html)
to calculate the random value.
Check its documentation for setting a different random algorithm or a different seed.
Runs in effective constant time, and is therefore more efficient than `Enum.random/1` on lists.
## Examples
# Although not necessary, let's seed the random algorithm
iex>:rand.seed(:exrop, {101, 102, 103})
iex> A.Vector.new([1, 2, 3]) |> A.Vector.random()
3
iex> A.Vector.new([1, 2, 3]) |> A.Vector.random()
2
iex> A.Vector.new(1..1_000) |> A.Vector.random()
846
iex> A.Vector.new([]) |> A.Vector.random()
** (A.Vector.EmptyError) empty vector error
"""
@spec random(t(val)) :: val when val: value
def random(%__MODULE__{__vector__: internal}) do
Raw.random(internal)
end
@doc """
Takes `amount` random elements from `vector`.
Note that, unless `amount` is `0` or `1`, this function will
traverse the whole `vector` to get the random sub-vector.
If `amount` is more than the `vector` size, this is equivalent to shuffling the `vector`:
the returned vector cannot be bigger than the original one.
See `Enum.random/1` for notes on implementation and random seed.
Runs in linerar time (except for `amount <= 1`, which is effective constant time).
## Examples
# Although not necessary, let's seed the random algorithm
iex> :rand.seed(:exrop, {1, 2, 3})
iex> A.Vector.new(1..10) |> A.Vector.take_random(2)
#A<vec([7, 2])>
iex> A.Vector.new([:foo, :bar, :baz]) |> A.Vector.take_random(100)
#A<vec([:bar, :baz, :foo])>
"""
@spec take_random(t(val), non_neg_integer) :: t(val) when val: value
def take_random(%__MODULE__{__vector__: internal}, amount)
when is_integer(amount) and amount >= 0 do
new_internal = Raw.take_random(internal, amount)
%__MODULE__{__vector__: new_internal}
end
@doc """
Returns a new vector with the elements of `vector` shuffled.
See `Enum.shuffle/1` for notes on implementation and random seed.
## Examples
# Although not necessary, let's seed the random algorithm
iex> :rand.seed(:exrop, {1, 2, 3})
iex> A.Vector.new([1, 2, 3]) |> A.Vector.shuffle()
#A<vec([3, 1, 2])>
iex> A.Vector.new([1, 2, 3]) |> A.Vector.shuffle()
#A<vec([1, 3, 2])>
"""
@spec shuffle(t(val)) :: t(val) when val: value
def shuffle(%__MODULE__{__vector__: internal}) do
# Note: benchmarks suggest that this is already fast without further optimization
new_internal =
internal
|> Raw.to_list()
|> Enum.shuffle()
|> Raw.from_list()
%__MODULE__{__vector__: new_internal}
end
defimpl Inspect do
import Inspect.Algebra
def inspect(vector, opts) do
opts = %Inspect.Opts{opts | charlists: :as_lists}
concat(["#A<vec(", Inspect.List.inspect(A.Vector.to_list(vector), opts), ")>"])
end
end
defimpl Enumerable do
def count(vector) do
{:ok, A.Vector.size(vector)}
end
def member?(%A.Vector{__vector__: internal}, value) do
{:ok, Raw.member?(internal, value)}
end
def slice(%A.Vector{__vector__: internal}) do
size = A.Vector.Raw.size(internal)
{:ok, size, fn start, length -> A.Vector.Raw.slice(internal, start, start + length - 1) end}
end
def reduce(%A.Vector{__vector__: internal}, acc, fun) do
internal
|> A.Vector.Raw.to_list()
|> Enumerable.List.reduce(acc, fun)
end
end
defimpl Collectable do
alias A.Vector.Raw
def into(%A.Vector{__vector__: internal}) do
{{[], internal}, &collector_fun/2}
end
@compile {:inline, collector_fun: 2}
defp collector_fun({acc, internal}, {:cont, value}), do: {[value | acc], internal}
defp collector_fun({acc, internal}, :done) do
new_internal = Raw.concat(internal, :lists.reverse(acc))
%A.Vector{__vector__: new_internal}
end
defp collector_fun(_acc, :halt), do: :ok
end
if Code.ensure_loaded?(Jason.Encoder) do
defimpl Jason.Encoder do
def encode(vector, opts) do
vector |> A.Vector.to_list() |> Jason.Encode.list(opts)
end
end
end
end