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[erlang/en] Various (mostly cosmetic) improvements
* Add missing square brackets in example of pattern matching on lists * Keep lines under 80 characters * Hiphenate complex modifiers (e.g. "pattern-matching operation") * Consistently proper case the language name * Improve punctuation in comments * Properly format Markdown inline code * Tense changes (where appropriate)
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@ -18,7 +18,7 @@ filename: learnerlang.erl
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% Periods (`.`) (followed by whitespace) separate entire functions and
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% expressions in the shell.
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% Semicolons (`;`) separate clauses. We find clauses in several contexts:
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% function definitions and in `case`, `if`, `try..catch` and `receive`
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% function definitions and in `case`, `if`, `try..catch`, and `receive`
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% expressions.
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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@ -27,20 +27,20 @@ filename: learnerlang.erl
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Num = 42. % All variable names must start with an uppercase letter.
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% Erlang has single assignment variables, if you try to assign a different value
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% to the variable `Num`, you’ll get an error.
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% Erlang has single-assignment variables; if you try to assign a different
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% value to the variable `Num`, you’ll get an error.
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Num = 43. % ** exception error: no match of right hand side value 43
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% In most languages, `=` denotes an assignment statement. In Erlang, however,
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% `=` denotes a pattern matching operation. `Lhs = Rhs` really means this:
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% evaluate the right side (Rhs), and then match the result against the pattern
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% on the left side (Lhs).
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% `=` denotes a pattern-matching operation. `Lhs = Rhs` really means this:
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% evaluate the right side (`Rhs`), and then match the result against the
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% pattern on the left side (`Lhs`).
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Num = 7 * 6.
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% Floating point number.
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% Floating-point number.
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Pi = 3.14159.
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% Atoms, are used to represent different non-numerical constant values. Atoms
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% Atoms are used to represent different non-numerical constant values. Atoms
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% start with lowercase letters, followed by a sequence of alphanumeric
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% characters or the underscore (`_`) or at (`@`) sign.
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Hello = hello.
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@ -53,34 +53,34 @@ AtomWithSpace = 'some atom with space'.
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% Tuples are similar to structs in C.
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Point = {point, 10, 45}.
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% If we want to extract some values from a tuple, we use the pattern matching
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% If we want to extract some values from a tuple, we use the pattern-matching
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% operator `=`.
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{point, X, Y} = Point. % X = 10, Y = 45
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% We can use `_` as a placeholder for variables that we’re not interested in.
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% The symbol `_` is called an anonymous variable. Unlike regular variables,
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% several occurrences of _ in the same pattern don’t have to bind to the same
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% value.
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% several occurrences of `_` in the same pattern don’t have to bind to the
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% same value.
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Person = {person, {name, {first, joe}, {last, armstrong}}, {footsize, 42}}.
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{_, {_, {_, Who}, _}, _} = Person. % Who = joe
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% We create a list by enclosing the list elements in square brackets and
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% separating them with commas.
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% The individual elements of a list can be of any type.
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% The first element of a list is the head of the list. If you imagine removing the
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% head from the list, what’s left is called the tail of the list.
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% The first element of a list is the head of the list. If you imagine removing
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% the head from the list, what’s left is called the tail of the list.
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ThingsToBuy = [{apples, 10}, {pears, 6}, {milk, 3}].
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% If `T` is a list, then `[H|T]` is also a list, with head `H` and tail `T`.
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% The vertical bar (`|`) separates the head of a list from its tail.
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% `[]` is the empty list.
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% We can extract elements from a list with a pattern matching operation. If we
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% We can extract elements from a list with a pattern-matching operation. If we
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% have a nonempty list `L`, then the expression `[X|Y] = L`, where `X` and `Y`
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% are unbound variables, will extract the head of the list into `X` and the tail
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% of the list into `Y`.
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[FirstThing|OtherThingsToBuy] = ThingsToBuy.
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% FirstThing = {apples, 10}
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% OtherThingsToBuy = {pears, 6}, {milk, 3}
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% OtherThingsToBuy = [{pears, 6}, {milk, 3}]
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% There are no strings in Erlang. Strings are really just lists of integers.
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% Strings are enclosed in double quotation marks (`"`).
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@ -117,17 +117,19 @@ c(geometry). % {ok,geometry}
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geometry:area({rectangle, 10, 5}). % 50
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geometry:area({circle, 1.4}). % 6.15752
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% In Erlang, two functions with the same name and different arity (number of arguments)
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% in the same module represent entirely different functions.
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% In Erlang, two functions with the same name and different arity (number of
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% arguments) in the same module represent entirely different functions.
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-module(lib_misc).
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-export([sum/1]). % export function `sum` of arity 1 accepting one argument: list of integers.
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-export([sum/1]). % export function `sum` of arity 1
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% accepting one argument: list of integers.
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sum(L) -> sum(L, 0).
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sum([], N) -> N;
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sum([H|T], N) -> sum(T, H+N).
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% Funs are "anonymous" functions. They are called this way because they have no
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% name. However they can be assigned to variables.
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Double = fun(X) -> 2*X end. % `Double` points to an anonymous function with handle: #Fun<erl_eval.6.17052888>
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% Funs are "anonymous" functions. They are called this way because they have
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% no name. However, they can be assigned to variables.
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Double = fun(X) -> 2 * X end. % `Double` points to an anonymous function
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% with handle: #Fun<erl_eval.6.17052888>
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Double(2). % 4
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% Functions accept funs as their arguments and can return funs.
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@ -140,8 +142,9 @@ Triple(5). % 15
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% The notation `[F(X) || X <- L]` means "the list of `F(X)` where `X` is taken
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% from the list `L`."
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L = [1,2,3,4,5].
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[2*X || X <- L]. % [2,4,6,8,10]
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% A list comprehension can have generators and filters which select subset of the generated values.
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[2 * X || X <- L]. % [2,4,6,8,10]
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% A list comprehension can have generators and filters, which select subset of
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% the generated values.
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EvenNumbers = [N || N <- [1, 2, 3, 4], N rem 2 == 0]. % [2, 4]
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% Guards are constructs that we can use to increase the power of pattern
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@ -155,15 +158,15 @@ max(X, Y) -> Y.
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% A guard is a series of guard expressions, separated by commas (`,`).
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% The guard `GuardExpr1, GuardExpr2, ..., GuardExprN` is true if all the guard
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% expressions `GuardExpr1, GuardExpr2, ...` evaluate to true.
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% expressions `GuardExpr1`, `GuardExpr2`, ..., `GuardExprN` evaluate to `true`.
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is_cat(A) when is_atom(A), A =:= cat -> true;
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is_cat(A) -> false.
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is_dog(A) when is_atom(A), A =:= dog -> true;
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is_dog(A) -> false.
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% A `guard sequence` is either a single guard or a series of guards, separated
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%by semicolons (`;`). The guard sequence `G1; G2; ...; Gn` is true if at least
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% one of the guards `G1, G2, ...` evaluates to true.
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% A guard sequence is either a single guard or a series of guards, separated
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% by semicolons (`;`). The guard sequence `G1; G2; ...; Gn` is true if at
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% least one of the guards `G1`, `G2`, ..., `Gn` evaluates to `true`.
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is_pet(A) when is_dog(A); is_cat(A) -> true;
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is_pet(A) -> false.
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@ -188,7 +191,7 @@ X = #todo{}.
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X1 = #todo{status = urgent, text = "Fix errata in book"}.
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% #todo{status = urgent, who = joe, text = "Fix errata in book"}
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X2 = X1#todo{status = done}.
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% #todo{status = done,who = joe,text = "Fix errata in book"}
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% #todo{status = done, who = joe, text = "Fix errata in book"}
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% `case` expressions.
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% `filter` returns a list of all elements `X` in a list `L` for which `P(X)` is
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@ -209,8 +212,8 @@ max(X, Y) ->
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true -> nil
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end.
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% Warning: at least one of the guards in the `if` expression must evaluate to true;
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% otherwise, an exception will be raised.
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% Warning: at least one of the guards in the `if` expression must evaluate to
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% `true`; otherwise, an exception will be raised.
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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@ -218,7 +221,7 @@ max(X, Y) ->
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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% Exceptions are raised by the system when internal errors are encountered or
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% explicitly in code by calling `throw(Exception)`, `exit(Exception)` or
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% explicitly in code by calling `throw(Exception)`, `exit(Exception)`, or
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% `erlang:error(Exception)`.
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generate_exception(1) -> a;
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generate_exception(2) -> throw(a);
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@ -227,7 +230,7 @@ generate_exception(4) -> {'EXIT', a};
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generate_exception(5) -> erlang:error(a).
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% Erlang has two methods of catching an exception. One is to enclose the call to
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% the function, which raised the exception within a `try...catch` expression.
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% the function that raises the exception within a `try...catch` expression.
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catcher(N) ->
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try generate_exception(N) of
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Val -> {N, normal, Val}
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@ -241,23 +244,24 @@ catcher(N) ->
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% exception, it is converted into a tuple that describes the error.
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catcher(N) -> catch generate_exception(N).
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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%% 4. Concurrency
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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% Erlang relies on the actor model for concurrency. All we need to write
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% concurrent programs in erlang are three primitives: spawning processes,
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% concurrent programs in Erlang are three primitives: spawning processes,
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% sending messages and receiving messages.
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% To start a new process we use the `spawn` function, which takes a function
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% To start a new process, we use the `spawn` function, which takes a function
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% as argument.
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F = fun() -> 2 + 2 end. % #Fun<erl_eval.20.67289768>
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spawn(F). % <0.44.0>
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% `spawn` returns a pid (process identifier), you can use this pid to send
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% messages to the process. To do message passing we use the `!` operator.
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% For all of this to be useful we need to be able to receive messages. This is
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% `spawn` returns a pid (process identifier); you can use this pid to send
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% messages to the process. To do message passing, we use the `!` operator.
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% For all of this to be useful, we need to be able to receive messages. This is
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% achieved with the `receive` mechanism:
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-module(calculateGeometry).
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@ -272,12 +276,13 @@ calculateArea() ->
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io:format("We can only calculate area of rectangles or circles.")
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end.
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% Compile the module and create a process that evaluates `calculateArea` in the shell
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% Compile the module and create a process that evaluates `calculateArea` in the
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% shell.
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c(calculateGeometry).
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CalculateArea = spawn(calculateGeometry, calculateArea, []).
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CalculateArea ! {circle, 2}. % 12.56000000000000049738
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% The shell is also a process, you can use `self` to get the current pid
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% The shell is also a process; you can use `self` to get the current pid.
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self(). % <0.41.0>
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```
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