Live abstract syntax trees of methods and procs. Fork of live_ast
(quix.github.com/live_ast).
require 'live_ast' class Greet def default "hello" end end #### ASTs of methods p Greet.instance_method(:default).to_ast # => s(:defn, :default, s(:args), s(:str, "hello")) #### ASTs of lambdas, procs, blocks f = lambda { "foo" } p f.to_ast # => s(:iter, s(:call, nil, :lambda), 0, s(:str, "foo")) def query(&block) p block.to_ast # => s(:iter, s(:call, nil, :query), 0, s(:str, "bar")) end query do "bar" end #### ASTs from dynamic code -- pure ruby version u = ast_eval "lambda { 'dynamic3' }", binding p u.to_ast # => s(:iter, s(:call, nil, :lambda), 0, s(:str, "dynamic3")) ast_eval "def v ; 'dynamic4' ; end", binding p method(:v).to_ast # => s(:defn, :v, s(:args), s(:str, "dynamic4")) #### ASTs from dynamic code -- fully integrated version require 'live_ast/full' f = eval "lambda { 'dynamic1' }" p f.to_ast # => s(:iter, s(:call, nil, :lambda), 0, s(:str, "dynamic1")) eval "def g ; 'dynamic2' ; end" p method(:g).to_ast # => s(:defn, :g, s(:args), s(:str, "dynamic2"))
% gem install mvz-live_ast
LiveAST enables a program to find the ASTs of objects created by dynamically generated code. It may be used in a strictly noninvasive manner, where no standard classes or methods are modified, or it may be transparently integrated into Ruby. The default setting is in between.
RubyParser is the default parsing engine. To replace it with Ripper, gem install live_ast_ripper
and then require 'live_ast_ripper'
. A simple plug-in interface allows LiveAST to work with any parser.
The advantage of RubyParser is that it gives the traditional ParseTree sexps used by tools such as ruby2ruby
.
LiveAST is thread-safe.
Ruby 2.3.0 or higher is required.
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Home: github.com/mvz/live_ast
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Feature Requests, Bug Reports: github.com/mvz/live_ast/issues
When the default parser is active,
require 'live_ast/to_ruby'
will define the to_ruby
method for the Method
, UnboundMethod
, and Proc
classes. These methods are one-liners which pass the extracted ASTs to ruby2ruby
.
require 'live_ast/to_ruby' p lambda { |x, y| x + y }.to_ruby # => "lambda { |x, y| (x + y) }" class A def f "A#f" end end p A.instance_method(:f).to_ruby # => "def f\n \"A#f\"\nend"
In general, to_ruby
will hook into the unparser provided by the parser plug-in, if one is found.
An essential feature of require 'live_ast'
is that it is implemented in pure ruby. However since pure ruby is not powerful enough to replace eval
, in this case ast_eval
must be used instead of eval
for AST-accessible objects. ast_eval
has the same semantics as eval
except that the binding argument is required.
require 'live_ast' u = ast_eval "lambda { 'dynamic3' }", binding p u.to_ast # => s(:iter, s(:call, nil, :lambda), 0, s(:str, "dynamic3"))
In order for LiveAST to be transparent to the user, eval
must be replaced. This is accomplished with the help of the binding_of_caller
gem (github.com/banister/binding_of_caller).
To replace eval
,
require 'live_ast/full'
The new AST-electrified eval
, instance_eval
, module_eval
, class_eval
, and Binding#eval
all pass RubySpec (rubyspec.org) with the minor exception of backtraces sometimes not matching that of the original eval
(see the “Backtraces” section below for details).
require 'live_ast/full' f = eval "lambda { 'dynamic1' }" p f.to_ast # => s(:iter, s(:call, nil, :lambda), 0, s(:str, "dynamic1"))
Since LiveAST itself is pure ruby, any platforms supported by binding_of_caller
should work with live_ast/full
.
A method or block definition must not share a line with other methods or blocks in order for its AST to be accessible.
require 'live_ast' class A def f ; end ; def g ; end end A.instance_method(:f).to_ast # => raises LiveAST::MultipleDefinitionsOnSameLineError a = lambda { } ; b = lambda { } a.to_ast # => raises LiveAST::MultipleDefinitionsOnSameLineError
Code given to the -e
command-line switch is not AST-accessible.
Evaled code appearing before require 'live_ast/full'
is not AST-accessible.
In some circumstances ast_eval
and the replaced eval
will not give the same backtrace as the original eval
(next section).
You can probably skip these next sections. Goodbye.
ast_eval
is meant to be compatible with eval
. For instance the first line of ast_eval
‘s backtrace should be identical to that of eval
:
require 'live_ast' ast_eval %{ raise "boom" }, binding # => test.rb:3:in `<main>': boom (RuntimeError)
Let’s make a slight change,
require 'live_ast' f = ast_eval %{ lambda { raise "boom" } }, binding f.call # => test.rb|ast@a:3:in `block in <main>': boom (RuntimeError)
What the heck is ‘|ast@a
’ doing there? LiveAST’s implementation has just been exposed: each source input is assigned a unique key which enables a Ruby object to find its own definition.
In the first case above, ast_eval
has removed the key from the exception backtrace. But in the second case there is no opportunity to remove it since ast_eval
has already returned.
If you find this to be problem—for example if you cannot add a filter for the jump-to-location feature in your editor—then raise
may be redefined to strip these tokens,
require 'live_ast' require 'live_ast/replace_raise' f = ast_eval %{ lambda { raise "boom" } }, binding f.call # => test.rb:4:in `block in <main>': boom (RuntimeError)
However this only applies to a raise
call originating from Ruby code. An exception from within a native method will likely still contain the token in its backtrace (e.g., in MRI the exception raised by 1/0
comes from C).
Despite its name, LiveAST knows nothing about ASTs. It merely reports what it finds in the line-to-AST hash returned by the parser’s parse
method. Replacing the parser class is therefore easy: the only specification is that the parse
instance method return such a hash.
To override the default parser with your own,
LiveAST.parser = YourParser
To test it, provide some examples of what the ASTs look like in YourParser::Test
. See live_ast/ruby_parser
for reference.
For safety purposes, require 'live_ast'
performs the invasive act of redefining load
(but not require
); otherwise bad things can happen to the unwary. The addition of to_ast
to a few standard Ruby classes is also a meddlesome move.
To avoid these modifications,
require 'live_ast/base'
will provide the essentials of LiveAST but will not touch core classes or methods.
To select features individually,
require 'live_ast/to_ast' # define to_ast for Method, UnboundMethod, Proc require 'live_ast/to_ruby' # define to_ruby for Method, UnboundMethod, Proc require 'live_ast/ast_eval' # define Kernel#ast_eval require 'live_ast/ast_load' # define Kernel#ast_load (mentioned below) require 'live_ast/replace_load' # redefine Kernel#load
The following alternative interface is available.
require 'live_ast/base' class A def f "A#f" end end p LiveAST.ast(A.instance_method(:f)) # => s(:defn, :f, s(:args), s(:str, "A#f")) p LiveAST.ast(lambda { }) # => s(:iter, s(:call, nil, :lambda), 0) f = LiveAST.eval("lambda { }", binding) p LiveAST.ast(f) # => s(:iter, s(:call, nil, :lambda), 0) ast_eval # => raises NameError
Use ast_load
or (equivalently) LiveAST.load
when reloading an AST-aware file.
require 'live_ast/ast_load' require 'live_ast/to_ast' require "foo" Foo.instance_method(:bar).to_ast # caches AST # ... the bar method is changed in foo.rb ... ast_load "foo.rb" p Foo.instance_method(:bar).to_ast # => updated AST
Note if load
is called instead of ast_load
then the last line will give the old AST,
load "foo.rb" # oops! forgot to use ast_load p Foo.instance_method(:bar).to_ast # => stale AST
Realize that foo.rb
may be referenced by an unknown number of methods and blocks. If the original foo.rb
source were dumped in favor of the modified foo.rb
, then an unknown number of those references would be invalidated (and some may even point to the wrong AST).
This is the reason for the caching that results in the stale AST above. It should now be clear why the default behavior of require 'live_ast'
is to redefine load
: doing so prevents this problem entirely. On the other hand if it is fully known where files are being reloaded (if at all) then there’s no need for paranoia; the noninvasive option may be the most appropriate.
ast_eval
and load
cache all incoming code, while require
d files are cached on a need-to-know basis. When an AST is requested, the corresponding source file is parsed and discarded, leaving behind method and block ASTs. to_ast
fetches an AST from the cache and attaches it to the appropriate object (a Proc or Module).
Ignored, unextracted ASTs will therefore linger in the cache. Since sexps are generally small there is little need for concern unless one is continually evaling/reloading. Nevertheless it is possible that old ASTs will eventually need to be garbage collected. To flush the cache,
(1) Check that to_ast
has been called on all objects whose ASTs are desired.
(2) Call LiveAST.flush_cache
.
Calling to_ast
prevents the object’s AST from being flushed (since it grafts the AST onto the object).
ASTs of procs and methods whose sources lie in require
d files will never be flushed. However a method redefined via ast_eval
or load
is susceptible to flush_cache
even when its original definition pointed to a require
d file.
No measures have been taken to detect manipulations of $LOADED_FEATURES
which would cause require
to load the same file twice. Though require
could be replaced in similar fashion to load
—heading off problems arising from such “raw” reloads—the overhead would seem inappropriate in relation to the rarity of this case.
Therefore the working assumption is that require
will load a file only once. Furthermore, if a file has not been reloaded then it is assumed that the file is unmodified between the moment it is require
d and the moment the first AST is pulled from it.
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James M. Lawrence < [email protected] >
-
Matijs van Zuijlen < [email protected] >
Copyright (c) 2011 James M. Lawrence. All rights reserved. Copyright (c) 2014 Matijs van Zuijlen. All rights reserved. Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
LiveAST includes the source code of live_ast_ruby_parser, which is licensed as follows:
Copyright (c) 2011 James M. Lawrence. All rights reserved. Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.