8.4 KiB
Contributions are much appreciated. Please open a pull request or add an issue to discuss what you intend to work on. If the pull requests passes the CI and conforms to the existing style of specs, it will be merged.
File organization
Spec are grouped in 5 separate top-level groups:
command_line
: for the ruby executable command-line flags (-v
,-e
, etc)language
: for the language keywords and syntax constructs (if
,def
,A::B
, etc)core
: for the core methods (Integer#+
,String#upcase
, no need to require anything)library
: for the standard libraries methods (CSV.new
,YAML.parse
, need to require the stdlib)optional/capi
: for functions available to the Ruby C-extension API
The exact file for methods is decided by the #owner
of a method, for instance for #group_by
:
> [].method(:group_by)
=> #<Method: Array(Enumerable)#group_by>
> [].method(:group_by).owner
=> Enumerable
Which should therefore be specified in core/enumerable/group_by_spec.rb
.
MkSpec - a tool to generate the spec structure
If you want to create new specs, you should use mkspec
, part of MSpec.
$ ../mspec/bin/mkspec -h
Creating files for unspecified modules or classes
For instance, to create specs for forwardable
:
$ ../mspec/bin/mkspec -b library -rforwardable -c Forwardable
Specify core
or library
as the base
.
Finding unspecified core methods
This is very easy, just run the command below in your spec
directory.
ruby
must be a recent version of MRI.
$ ruby --disable-gem ../mspec/bin/mkspec
You might also want to search for:
it "needs to be reviewed for spec completeness"
which indicates the file was generated but the method unspecified.
Matchers and expectations
Here is a list of frequently-used matchers, which should be enough for most specs. There are a few extra specific matchers used in the couple specs that need it.
Comparison matchers
(1 + 2).should == 3 # Calls #==
(1 + 2).should_not == 5
File.should.equal?(File) # Calls #equal? (tests identity)
(1 + 2).should.eql?(3) # Calls #eql? (Hash equality)
1.should < 2
2.should <= 2
3.should >= 3
4.should > 3
"Hello".should =~ /l{2}/ # Calls #=~ (Regexp match)
Predicate matchers
[].should.empty?
[1,2,3].should.include?(2)
"hello".should.start_with?("h")
"hello".should.end_with?("o")
(0.1 + 0.2).should be_close(0.3, TOLERANCE) # (0.2-0.1).abs < TOLERANCE
(0.0/0.0).should.nan?
(1.0/0.0).should be_positive_infinity
(-1.0/0.0).should be_negative_infinity
3.14.should be_an_instance_of(Float) # Calls #instance_of?
3.14.should be_kind_of(Numeric) # Calls #is_a?
Numeric.should be_ancestor_of(Float) # Float.ancestors.include?(Numeric)
3.14.should.respond_to?(:to_i)
Integer.should have_instance_method(:+)
Array.should have_method(:new)
Also have_constant
, have_private_instance_method
, have_singleton_method
, etc.
Exception matchers
-> {
raise "oops"
}.should raise_error(RuntimeError, /oops/)
-> {
raise "oops"
}.should raise_error(RuntimeError) { |e|
# Custom checks on the Exception object
e.message.should.include?("oops")
e.cause.should == nil
}
should_not raise_error
To avoid! Instead, use an expectation testing what the code in the lambda does. If an exception is raised, it will fail the example anyway.
-> { ... }.should_not raise_error
Warning matcher
-> {
Fixnum
}.should complain(/constant ::Fixnum is deprecated/) # Expect a warning
Guards
Different guards are available as defined by mspec. Here is a list of the most commonly-used guards:
Version guards
ruby_version_is ""..."2.6" do
# Specs for RUBY_VERSION < 2.6
end
ruby_version_is "2.6" do
# Specs for RUBY_VERSION >= 2.6
end
Platform guards
platform_is :windows do
# Specs only valid on Windows
end
platform_is_not :windows do
# Specs valid on platforms other than Windows
end
platform_is :linux, :darwin do # OR
end
platform_is_not :linux, :darwin do # Not Linux and not Darwin
end
platform_is wordsize: 64 do
# 64-bit platform
end
big_endian do
# Big-endian platform
end
Guard for bug
In case there is a bug in MRI and the fix will be backported to previous versions.
If it is not backported or not likely, use ruby_version_is
instead.
First, file a bug at https://bugs.ruby-lang.org/.
The problem is ruby_bug
would make non-MRI implementations fail this spec while MRI itself does not pass it, so it should only be used if the bug is/will be fixed and backported.
ruby_bug '#13669', ''...'3.2' do
it "works like this" do
# Specify the expected behavior here, not the bug
end
end
Combining guards
guard -> { platform_is :windows and ruby_version_is ""..."2.6" } do
# Windows and RUBY_VERSION < 2.6
end
guard_not -> { platform_is :windows and ruby_version_is ""..."2.6" } do
# The opposite
end
Custom guard
max_uint = (1 << 32) - 1
guard -> { max_uint <= fixnum_max } do
end
Custom guards are better than a simple if
as they allow mspec commands to work properly.
Implementation-specific behaviors
In general, the usage of guards should be minimized as possible.
There are no guards to define implementation-specific behavior because the Ruby Spec Suite defines common behavior and not implementation details. Use the implementation test suite for these.
If an implementation does not support some feature, simply tag the related specs as failing instead.
Shared Specs
Often throughout Ruby, identical functionality is used by different methods and modules. In order to avoid duplication of specs, we have shared specs that are re-used in other specs. The use is a bit tricky however, so let's go over it.
Commonly, if a shared spec is only reused within its own module, the shared spec will live within a
shared directory inside that module's directory. For example, the core/hash/shared/key.rb
spec is
only used by Hash
specs, and so it lives inside core/hash/shared/
.
When a shared spec is used across multiple modules or classes, it lives within the shared/
directory.
An example of this is the shared/file/socket.rb
which is used by core/file/socket_spec.rb
,
core/filetest/socket_spec.rb
, and core/file/state/socket_spec.rb
and so it lives in the root shared/
.
Defining a shared spec involves adding a shared: true
option to the top-level describe
block. This
will signal not to run the specs directly by the runner. Shared specs have access to two instance
variables from the implementor spec: @method
and @object
, which the implementor spec will pass in.
Here's an example of a snippet of a shared spec and two specs which integrates it:
# core/hash/shared/key.rb
describe :hash_key_p, shared: true do
it "returns true if the key's matching value was false" do
{ xyz: false }.send(@method, :xyz).should == true
end
end
# core/hash/key_spec.rb
describe "Hash#key?" do
it_behaves_like :hash_key_p, :key?
end
# core/hash/include_spec.rb
describe "Hash#include?" do
it_behaves_like :hash_key_p, :include?
end
In the example, the first describe
defines the shared spec :hash_key_p
, which defines a spec that
calls the @method
method with an expectation. In the implementor spec, we use it_behaves_like
to
integrate the shared spec. it_behaves_like
takes 3 parameters: the key of the shared spec, a method,
and an object. These last two parameters are accessible via @method
and @object
in the shared spec.
Sometimes, shared specs require more context from the implementor class than a simple object. We can address this by passing a lambda as the method, which will have the scope of the implementor. Here's an example of how this is used currently:
describe :kernel_sprintf, shared: true do
it "raises TypeError exception if cannot convert to Integer" do
-> { @method.call("%b", Object.new) }.should raise_error(TypeError)
end
end
describe "Kernel#sprintf" do
it_behaves_like :kernel_sprintf, -> (format, *args) {
sprintf(format, *args)
}
end
describe "Kernel.sprintf" do
it_behaves_like :kernel_sprintf, -> (format, *args) {
Kernel.sprintf(format, *args)
}
end
In the above example, the method being passed is a lambda that triggers the specific conditions of the shared spec.
Style
Do not leave any trailing space and follow the existing style.