diff options
Diffstat (limited to 'elixir.html.markdown')
-rw-r--r-- | elixir.html.markdown | 154 |
1 files changed, 78 insertions, 76 deletions
diff --git a/elixir.html.markdown b/elixir.html.markdown index 255d311d..0ded7562 100644 --- a/elixir.html.markdown +++ b/elixir.html.markdown @@ -141,33 +141,33 @@ number < atom < reference < functions < port < pid < tuple < list < bit string # `if` expression if false do - "This will never be seen" + "This will never be seen" else - "This will" + "This will" end # There's also `unless` unless true do - "This will never be seen" + "This will never be seen" else - "This will" + "This will" end # Remember pattern matching? Many control-flow structures in elixir rely on it. # `case` allows us to compare a value against many patterns: case {:one, :two} do - {:four, :five} -> - "This won't match" - {:one, x} -> - "This will match and assign `x` to `:two`" - _ -> - "This will match any value" + {:four, :five} -> + "This won't match" + {:one, x} -> + "This will match and assign `x` to `:two`" + _ -> + "This will match any value" end # It's common practive to assign a value to `_` if we don't need it. # For example, if only the head of a list matters to us: -[head | _] = [1,2,3] +[head | _] = [1,2,3] head #=> 1 # For better readability we can do the following: @@ -177,35 +177,35 @@ head #=> :a # `cond` lets us check for many conditions at the same time. # Use `cond` instead of nesting many `if` expressions. cond do - 1 + 1 == 3 -> - "I will never be seen" - 2 * 5 == 12 -> - "Me neither" - 1 + 2 == 3 -> - "But I will" + 1 + 1 == 3 -> + "I will never be seen" + 2 * 5 == 12 -> + "Me neither" + 1 + 2 == 3 -> + "But I will" end # It is common to see a last condition equal to `true`, which will always match. cond do - 1 + 1 == 3 -> - "I will never be seen" - 2 * 5 == 12 -> - "Me neither" - true -> - "But I will (this is essentially an else)" + 1 + 1 == 3 -> + "I will never be seen" + 2 * 5 == 12 -> + "Me neither" + true -> + "But I will (this is essentially an else)" end # `try/catch` is used to catch values that are thrown, it also supports an # `after` clause that is invoked whether or not a value is catched. try do - throw(:hello) + throw(:hello) catch - message -> "Got #{message}." + message -> "Got #{message}." after - IO.puts("I'm the after clause.") + IO.puts("I'm the after clause.") end #=> I'm the after clause -# "Got :hello" +# "Got :hello" ## --------------------------- ## -- Modules and Functions @@ -218,8 +218,8 @@ square.(5) #=> 25 # They also accept many clauses and guards. Guards let you fine tune pattern matching, # they are indicated by the `when` keyword: f = fn - x, y when x > 0 -> x + y - x, y -> x * y + x, y when x > 0 -> x + y + x, y -> x * y end f.(1, 3) #=> 4 @@ -234,32 +234,32 @@ elem({1,2,3}, 0) #=> 1 # You can group several functions into a module. Inside a module use `def` # to define your functions. defmodule Math do - def sum(a, b) do - a + b - end + def sum(a, b) do + a + b + end - def square(x) do - x * x - end + def square(x) do + x * x + end end Math.sum(1, 2) #=> 3 Match.square(3) #=> 9 -# To compile our little Math module save it as `math.ex` and use `elixirc` -elixirc math.ex +# To compile our simple Math module save it as `math.ex` and use `elixirc` +# in your terminal: elixirc math.ex # Inside a module we can define functions with `def` and private functions with `defp`. # A function defined with `def` is available to be invoked from other modules, # a private function can only be invoked locally. defmodule PrivateMath do - def sum(a, b) do - do_sum(a, b) - end + def sum(a, b) do + do_sum(a, b) + end - defp do_sum(a, b) do - a + b - end + defp do_sum(a, b) do + a + b + end end PrivateMath.sum(1, 2) #=> 3 @@ -267,27 +267,29 @@ PrivateMath.do_sum(1, 2) #=> ** (UndefinedFunctionError) # Function declarations also support guards and multiple clauses: defmodule Geometry do - def area({:rectangle, w, h}) do - w * h - end + def area({:rectangle, w, h}) do + w * h + end - def area({:circle, r}) when is_number(r) do - 3.14 * r * r - end + def area({:circle, r}) when is_number(r) do + 3.14 * r * r + end end Geometry.area({:rectangle, 2, 3}) #=> 6 Geometry.area({:circle, 3}) #=> 28.25999999999999801048 +Geometry.area({:circle, "not_a_number"}) +#=> ** (FunctionClauseError) no function clause matching in Geometry.area/1 # Due to immutability, recursion is a big part of elixir defmodule Recursion do - def sum_list([head | tail], acc) do - sum_list(tail, acc + head) - end + def sum_list([head | tail], acc) do + sum_list(tail, acc + head) + end - def sum_list([], acc) do - acc - end + def sum_list([], acc) do + acc + end end Recursion.sum_list([1,2,3], 0) #=> 6 @@ -295,12 +297,12 @@ Recursion.sum_list([1,2,3], 0) #=> 6 # Elixir modules support attributes, there are built-in attributes and you # may also add custom attributes. defmodule MyMod do - @moduledoc """ - This is a built-in attribute on a example module. - """ + @moduledoc """ + This is a built-in attribute on a example module. + """ - @my_data 100 # This is a custom attribute. - IO.inspect(@my_data) #=> 100 + @my_data 100 # This is a custom attribute. + IO.inspect(@my_data) #=> 100 end ## --------------------------- @@ -322,18 +324,18 @@ joe_info = joe_info.age(31) #=> Person[name: "Joe", age: 31, height: 180] # The `try` block with the `rescue` keyword is used to handle exceptions try do - raise "some error" + raise "some error" rescue - RuntimeError -> "rescued a runtime error" - _error -> "this will rescue any error" + RuntimeError -> "rescued a runtime error" + _error -> "this will rescue any error" end # All exceptions have a message try do - raise "some error" + raise "some error" rescue - x in [RuntimeError] -> - x.message + x in [RuntimeError] -> + x.message end ## --------------------------- @@ -354,16 +356,16 @@ spawn(f) #=> #PID<0.40.0> # For all of this to be useful we need to be able to receive messages. This is # achived with the `receive` mechanism: defmodule Geometry do - def area_loop do - receive do - {:rectangle, w, h} -> - IO.puts("Area = #{w * h}") - area_loop() - {:circle, r} -> - IO.puts("Area = #{3.14 * r * r}") - area_loop() - end - end + def area_loop do + receive do + {:rectangle, w, h} -> + IO.puts("Area = #{w * h}") + area_loop() + {:circle, r} -> + IO.puts("Area = #{3.14 * r * r}") + area_loop() + end + end end # Compile the module and create a process that evaluates `area_loop` in the shell |