# Copyright 2016-2017 The Meson development team
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
# http://www.apache.org/licenses/LICENSE-2.0
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# This class contains the basic functionality needed to run any interpreter
# or an interpreter-based tool.
from . import mparser , mesonlib , mlog
from . import environment , dependencies
import os , copy , re
from functools import wraps
class ObjectHolder :
def __init__ ( self , obj , subproject = None ) :
self . held_object = obj
self . subproject = subproject
def __repr__ ( self ) :
return ' <Holder: {!r} > ' . format ( self . held_object )
# Decorators for method calls.
def check_stringlist ( a , msg = ' Arguments must be strings. ' ) :
if not isinstance ( a , list ) :
mlog . debug ( ' Not a list: ' , str ( a ) )
raise InvalidArguments ( ' Argument not a list. ' )
if not all ( isinstance ( s , str ) for s in a ) :
mlog . debug ( ' Element not a string: ' , str ( a ) )
raise InvalidArguments ( msg )
def _get_callee_args ( wrapped_args , want_subproject = False ) :
s = wrapped_args [ 0 ]
n = len ( wrapped_args )
# Raise an error if the codepaths are not there
subproject = None
if want_subproject and n == 2 :
if hasattr ( s , ' subproject ' ) :
# Interpreter base types have 2 args: self, node
node = wrapped_args [ 1 ]
# args and kwargs are inside the node
args = None
kwargs = None
subproject = s . subproject
elif hasattr ( wrapped_args [ 1 ] , ' subproject ' ) :
# Module objects have 2 args: self, interpreter
node = wrapped_args [ 1 ] . current_node
# args and kwargs are inside the node
args = None
kwargs = None
subproject = wrapped_args [ 1 ] . subproject
else :
raise AssertionError ( ' Unknown args: {!r} ' . format ( wrapped_args ) )
elif n == 3 :
# Methods on objects (*Holder, MesonMain, etc) have 3 args: self, args, kwargs
node = s . current_node
args = wrapped_args [ 1 ]
kwargs = wrapped_args [ 2 ]
if want_subproject :
if hasattr ( s , ' subproject ' ) :
subproject = s . subproject
elif hasattr ( s , ' interpreter ' ) :
subproject = s . interpreter . subproject
elif n == 4 :
# Meson functions have 4 args: self, node, args, kwargs
# Module functions have 4 args: self, state, args, kwargs
if isinstance ( s , InterpreterBase ) :
node = wrapped_args [ 1 ]
else :
node = wrapped_args [ 1 ] . current_node
args = wrapped_args [ 2 ]
kwargs = wrapped_args [ 3 ]
if want_subproject :
if isinstance ( s , InterpreterBase ) :
subproject = s . subproject
else :
subproject = wrapped_args [ 1 ] . subproject
elif n == 5 :
# Module snippets have 5 args: self, interpreter, state, args, kwargs
node = wrapped_args [ 2 ] . current_node
args = wrapped_args [ 3 ]
kwargs = wrapped_args [ 4 ]
if want_subproject :
subproject = wrapped_args [ 2 ] . subproject
else :
raise AssertionError ( ' Unknown args: {!r} ' . format ( wrapped_args ) )
# Sometimes interpreter methods are called internally with None instead of
# empty list/dict
args = args if args is not None else [ ]
kwargs = kwargs if kwargs is not None else { }
return s , node , args , kwargs , subproject
def flatten ( args ) :
if isinstance ( args , mparser . StringNode ) :
return args . value
if isinstance ( args , ( int , str , mesonlib . File , InterpreterObject ) ) :
return args
result = [ ]
for a in args :
if isinstance ( a , list ) :
rest = flatten ( a )
result = result + rest
elif isinstance ( a , mparser . StringNode ) :
result . append ( a . value )
else :
result . append ( a )
return result
def noPosargs ( f ) :
@wraps ( f )
def wrapped ( * wrapped_args , * * wrapped_kwargs ) :
args = _get_callee_args ( wrapped_args ) [ 2 ]
Don't use len() to test emptiness vs not emptiness
Meson has a common pattern of using 'if len(foo) == 0:' or
'if len(foo) != 0:', however, this is a common anti-pattern in python.
Instead tests for emptiness/non-emptiness should be done with a simple
'if foo:' or 'if not foo:'
Consider the following:
>>> import timeit
>>> timeit.timeit('if len([]) == 0: pass')
0.10730923599840025
>>> timeit.timeit('if not []: pass')
0.030033907998586074
>>> timeit.timeit('if len(['a', 'b', 'c', 'd']) == 0: pass')
0.1154778649979562
>>> timeit.timeit("if not ['a', 'b', 'c', 'd']: pass")
0.08259823200205574
>>> timeit.timeit('if len("") == 0: pass')
0.089759664999292
>>> timeit.timeit('if not "": pass')
0.02340641999762738
>>> timeit.timeit('if len("foo") == 0: pass')
0.08848102600313723
>>> timeit.timeit('if not "foo": pass')
0.04032287199879647
And for the one additional case of 'if len(foo.strip()) == 0', which can
be replaced with 'if not foo.isspace()'
>>> timeit.timeit('if len(" ".strip()) == 0: pass')
0.15294511600222904
>>> timeit.timeit('if " ".isspace(): pass')
0.09413968399894657
>>> timeit.timeit('if len(" abc".strip()) == 0: pass')
0.2023209120015963
>>> timeit.timeit('if " abc".isspace(): pass')
0.09571301700270851
In other words, it's always a win to not use len(), when you don't
actually want to check the length.
8 years ago
if args :
raise InvalidArguments ( ' Function does not take positional arguments. ' )
return f ( * wrapped_args , * * wrapped_kwargs )
return wrapped
def noKwargs ( f ) :
@wraps ( f )
def wrapped ( * wrapped_args , * * wrapped_kwargs ) :
kwargs = _get_callee_args ( wrapped_args ) [ 3 ]
Don't use len() to test emptiness vs not emptiness
Meson has a common pattern of using 'if len(foo) == 0:' or
'if len(foo) != 0:', however, this is a common anti-pattern in python.
Instead tests for emptiness/non-emptiness should be done with a simple
'if foo:' or 'if not foo:'
Consider the following:
>>> import timeit
>>> timeit.timeit('if len([]) == 0: pass')
0.10730923599840025
>>> timeit.timeit('if not []: pass')
0.030033907998586074
>>> timeit.timeit('if len(['a', 'b', 'c', 'd']) == 0: pass')
0.1154778649979562
>>> timeit.timeit("if not ['a', 'b', 'c', 'd']: pass")
0.08259823200205574
>>> timeit.timeit('if len("") == 0: pass')
0.089759664999292
>>> timeit.timeit('if not "": pass')
0.02340641999762738
>>> timeit.timeit('if len("foo") == 0: pass')
0.08848102600313723
>>> timeit.timeit('if not "foo": pass')
0.04032287199879647
And for the one additional case of 'if len(foo.strip()) == 0', which can
be replaced with 'if not foo.isspace()'
>>> timeit.timeit('if len(" ".strip()) == 0: pass')
0.15294511600222904
>>> timeit.timeit('if " ".isspace(): pass')
0.09413968399894657
>>> timeit.timeit('if len(" abc".strip()) == 0: pass')
0.2023209120015963
>>> timeit.timeit('if " abc".isspace(): pass')
0.09571301700270851
In other words, it's always a win to not use len(), when you don't
actually want to check the length.
8 years ago
if kwargs :
raise InvalidArguments ( ' Function does not take keyword arguments. ' )
return f ( * wrapped_args , * * wrapped_kwargs )
return wrapped
def stringArgs ( f ) :
@wraps ( f )
def wrapped ( * wrapped_args , * * wrapped_kwargs ) :
args = _get_callee_args ( wrapped_args ) [ 2 ]
assert ( isinstance ( args , list ) )
check_stringlist ( args )
return f ( * wrapped_args , * * wrapped_kwargs )
return wrapped
def noArgsFlattening ( f ) :
setattr ( f , ' no-args-flattening ' , True ) # noqa: B010
return f
def disablerIfNotFound ( f ) :
@wraps ( f )
def wrapped ( * wrapped_args , * * wrapped_kwargs ) :
kwargs = _get_callee_args ( wrapped_args ) [ 3 ]
disabler = kwargs . pop ( ' disabler ' , False )
ret = f ( * wrapped_args , * * wrapped_kwargs )
if disabler and not ret . held_object . found ( ) :
return Disabler ( )
return ret
return wrapped
class permittedKwargs :
def __init__ ( self , permitted ) :
self . permitted = permitted
def __call__ ( self , f ) :
@wraps ( f )
def wrapped ( * wrapped_args , * * wrapped_kwargs ) :
s , node , args , kwargs , _ = _get_callee_args ( wrapped_args )
for k in kwargs :
if k not in self . permitted :
mlog . warning ( ''' Passed invalid keyword argument " {} " . ''' . format ( k ) , location = node )
mlog . warning ( ' This will become a hard error in the future. ' )
return f ( * wrapped_args , * * wrapped_kwargs )
return wrapped
class FeatureCheckBase :
" Base class for feature version checks "
def __init__ ( self , feature_name , version ) :
self . feature_name = feature_name
self . feature_version = version
@staticmethod
def get_target_version ( subproject ) :
# Don't do any checks if project() has not been parsed yet
if subproject not in mesonlib . project_meson_versions :
return ' '
return mesonlib . project_meson_versions [ subproject ]
def use ( self , subproject ) :
tv = self . get_target_version ( subproject )
# No target version
if tv == ' ' :
return
# Target version is new enough
if mesonlib . version_compare_condition_with_min ( tv , self . feature_version ) :
return
# Feature is too new for target version, register it
if subproject not in self . feature_registry :
self . feature_registry [ subproject ] = { self . feature_version : set ( ) }
register = self . feature_registry [ subproject ]
if self . feature_version not in register :
register [ self . feature_version ] = set ( )
if self . feature_name in register [ self . feature_version ] :
# Don't warn about the same feature multiple times
# FIXME: This is needed to prevent duplicate warnings, but also
# means we won't warn about a feature used in multiple places.
return
register [ self . feature_version ] . add ( self . feature_name )
self . log_usage_warning ( tv )
@classmethod
def report ( cls , subproject ) :
if subproject not in cls . feature_registry :
return
warning_str = cls . get_warning_str_prefix ( cls . get_target_version ( subproject ) )
fv = cls . feature_registry [ subproject ]
for version in sorted ( fv . keys ( ) ) :
warning_str + = ' \n * {} : {} ' . format ( version , fv [ version ] )
mlog . warning ( warning_str )
def __call__ ( self , f ) :
@wraps ( f )
def wrapped ( * wrapped_args , * * wrapped_kwargs ) :
subproject = _get_callee_args ( wrapped_args , want_subproject = True ) [ 4 ]
if subproject is None :
raise AssertionError ( ' {!r} ' . format ( wrapped_args ) )
self . use ( subproject )
return f ( * wrapped_args , * * wrapped_kwargs )
return wrapped
class FeatureNew ( FeatureCheckBase ) :
""" Checks for new features """
# Class variable, shared across all instances
#
# Format: {subproject: {feature_version: set(feature_names)}}
feature_registry = { }
@staticmethod
def get_warning_str_prefix ( tv ) :
return ' Project specifies a minimum meson_version \' {} \' but uses features which were added in newer versions: ' . format ( tv )
def log_usage_warning ( self , tv ) :
mlog . warning ( ' Project targetting \' {} \' but tried to use feature introduced '
' in \' {} \' : {} ' . format ( tv , self . feature_version , self . feature_name ) )
class FeatureDeprecated ( FeatureCheckBase ) :
""" Checks for deprecated features """
# Class variable, shared across all instances
#
# Format: {subproject: {feature_version: set(feature_names)}}
feature_registry = { }
@staticmethod
def get_warning_str_prefix ( tv ) :
return ' Deprecated features used: '
def log_usage_warning ( self , tv ) :
mlog . deprecation ( ' Project targetting \' {} \' but tried to use feature '
' deprecated since \' {} \' : {} '
' ' . format ( tv , self . feature_version , self . feature_name ) )
class FeatureCheckKwargsBase :
def __init__ ( self , feature_name , feature_version , kwargs ) :
self . feature_name = feature_name
self . feature_version = feature_version
self . kwargs = kwargs
def __call__ ( self , f ) :
@wraps ( f )
def wrapped ( * wrapped_args , * * wrapped_kwargs ) :
# Which FeatureCheck class to invoke
FeatureCheckClass = self . feature_check_class
kwargs , subproject = _get_callee_args ( wrapped_args , want_subproject = True ) [ 3 : 5 ]
if subproject is None :
raise AssertionError ( ' {!r} ' . format ( wrapped_args ) )
for arg in self . kwargs :
if arg not in kwargs :
continue
name = arg + ' arg in ' + self . feature_name
FeatureCheckClass ( name , self . feature_version ) . use ( subproject )
return f ( * wrapped_args , * * wrapped_kwargs )
return wrapped
class FeatureNewKwargs ( FeatureCheckKwargsBase ) :
feature_check_class = FeatureNew
class FeatureDeprecatedKwargs ( FeatureCheckKwargsBase ) :
feature_check_class = FeatureDeprecated
class InterpreterException ( mesonlib . MesonException ) :
pass
class InvalidCode ( InterpreterException ) :
pass
class InvalidArguments ( InterpreterException ) :
pass
class SubdirDoneRequest ( BaseException ) :
pass
class ContinueRequest ( BaseException ) :
pass
class BreakRequest ( BaseException ) :
pass
class InterpreterObject :
def __init__ ( self ) :
self . methods = { }
# Current node set during a method call. This can be used as location
# when printing a warning message during a method call.
self . current_node = None
def method_call ( self , method_name , args , kwargs ) :
if method_name in self . methods :
method = self . methods [ method_name ]
if not getattr ( method , ' no-args-flattening ' , False ) :
args = flatten ( args )
return method ( args , kwargs )
raise InvalidCode ( ' Unknown method " %s " in object. ' % method_name )
class MutableInterpreterObject ( InterpreterObject ) :
def __init__ ( self ) :
super ( ) . __init__ ( )
class Disabler ( InterpreterObject ) :
def __init__ ( self ) :
super ( ) . __init__ ( )
self . methods . update ( { ' found ' : self . found_method } )
def found_method ( self , args , kwargs ) :
return False
def is_disabler ( i ) - > bool :
return isinstance ( i , Disabler )
def is_arg_disabled ( arg ) - > bool :
if is_disabler ( arg ) :
return True
if isinstance ( arg , list ) :
for i in arg :
if is_arg_disabled ( i ) :
return True
return False
def is_disabled ( args , kwargs ) - > bool :
for i in args :
if is_arg_disabled ( i ) :
return True
for i in kwargs . values ( ) :
if is_arg_disabled ( i ) :
return True
return False
class InterpreterBase :
def __init__ ( self , source_root , subdir ) :
self . source_root = source_root
self . funcs = { }
self . builtin = { }
self . subdir = subdir
self . variables = { }
self . argument_depth = 0
self . current_lineno = - 1
# Current node set during a function call. This can be used as location
# when printing a warning message during a method call.
self . current_node = None
def load_root_meson_file ( self ) :
mesonfile = os . path . join ( self . source_root , self . subdir , environment . build_filename )
if not os . path . isfile ( mesonfile ) :
raise InvalidArguments ( ' Missing Meson file in %s ' % mesonfile )
with open ( mesonfile , encoding = ' utf8 ' ) as mf :
code = mf . read ( )
Don't use len() to test emptiness vs not emptiness
Meson has a common pattern of using 'if len(foo) == 0:' or
'if len(foo) != 0:', however, this is a common anti-pattern in python.
Instead tests for emptiness/non-emptiness should be done with a simple
'if foo:' or 'if not foo:'
Consider the following:
>>> import timeit
>>> timeit.timeit('if len([]) == 0: pass')
0.10730923599840025
>>> timeit.timeit('if not []: pass')
0.030033907998586074
>>> timeit.timeit('if len(['a', 'b', 'c', 'd']) == 0: pass')
0.1154778649979562
>>> timeit.timeit("if not ['a', 'b', 'c', 'd']: pass")
0.08259823200205574
>>> timeit.timeit('if len("") == 0: pass')
0.089759664999292
>>> timeit.timeit('if not "": pass')
0.02340641999762738
>>> timeit.timeit('if len("foo") == 0: pass')
0.08848102600313723
>>> timeit.timeit('if not "foo": pass')
0.04032287199879647
And for the one additional case of 'if len(foo.strip()) == 0', which can
be replaced with 'if not foo.isspace()'
>>> timeit.timeit('if len(" ".strip()) == 0: pass')
0.15294511600222904
>>> timeit.timeit('if " ".isspace(): pass')
0.09413968399894657
>>> timeit.timeit('if len(" abc".strip()) == 0: pass')
0.2023209120015963
>>> timeit.timeit('if " abc".isspace(): pass')
0.09571301700270851
In other words, it's always a win to not use len(), when you don't
actually want to check the length.
8 years ago
if code . isspace ( ) :
raise InvalidCode ( ' Builder file is empty. ' )
assert ( isinstance ( code , str ) )
try :
self . ast = mparser . Parser ( code , self . subdir ) . parse ( )
except mesonlib . MesonException as me :
me . file = environment . build_filename
raise me
def join_path_strings ( self , args ) :
return os . path . join ( * args ) . replace ( ' \\ ' , ' / ' )
def parse_project ( self ) :
"""
Parses project ( ) and initializes languages , compilers etc . Do this
early because we need this before we parse the rest of the AST .
"""
self . evaluate_codeblock ( self . ast , end = 1 )
def sanity_check_ast ( self ) :
if not isinstance ( self . ast , mparser . CodeBlockNode ) :
raise InvalidCode ( ' AST is of invalid type. Possibly a bug in the parser. ' )
Don't use len() to test emptiness vs not emptiness
Meson has a common pattern of using 'if len(foo) == 0:' or
'if len(foo) != 0:', however, this is a common anti-pattern in python.
Instead tests for emptiness/non-emptiness should be done with a simple
'if foo:' or 'if not foo:'
Consider the following:
>>> import timeit
>>> timeit.timeit('if len([]) == 0: pass')
0.10730923599840025
>>> timeit.timeit('if not []: pass')
0.030033907998586074
>>> timeit.timeit('if len(['a', 'b', 'c', 'd']) == 0: pass')
0.1154778649979562
>>> timeit.timeit("if not ['a', 'b', 'c', 'd']: pass")
0.08259823200205574
>>> timeit.timeit('if len("") == 0: pass')
0.089759664999292
>>> timeit.timeit('if not "": pass')
0.02340641999762738
>>> timeit.timeit('if len("foo") == 0: pass')
0.08848102600313723
>>> timeit.timeit('if not "foo": pass')
0.04032287199879647
And for the one additional case of 'if len(foo.strip()) == 0', which can
be replaced with 'if not foo.isspace()'
>>> timeit.timeit('if len(" ".strip()) == 0: pass')
0.15294511600222904
>>> timeit.timeit('if " ".isspace(): pass')
0.09413968399894657
>>> timeit.timeit('if len(" abc".strip()) == 0: pass')
0.2023209120015963
>>> timeit.timeit('if " abc".isspace(): pass')
0.09571301700270851
In other words, it's always a win to not use len(), when you don't
actually want to check the length.
8 years ago
if not self . ast . lines :
raise InvalidCode ( ' No statements in code. ' )
first = self . ast . lines [ 0 ]
if not isinstance ( first , mparser . FunctionNode ) or first . func_name != ' project ' :
raise InvalidCode ( ' First statement must be a call to project ' )
def run ( self ) :
# Evaluate everything after the first line, which is project() because
# we already parsed that in self.parse_project()
try :
self . evaluate_codeblock ( self . ast , start = 1 )
except SubdirDoneRequest :
pass
def evaluate_codeblock ( self , node , start = 0 , end = None ) :
if node is None :
return
if not isinstance ( node , mparser . CodeBlockNode ) :
e = InvalidCode ( ' Tried to execute a non-codeblock. Possibly a bug in the parser. ' )
e . lineno = node . lineno
e . colno = node . colno
raise e
statements = node . lines [ start : end ]
i = 0
while i < len ( statements ) :
cur = statements [ i ]
try :
self . current_lineno = cur . lineno
self . evaluate_statement ( cur )
except Exception as e :
if not hasattr ( e , ' lineno ' ) :
e . lineno = cur . lineno
e . colno = cur . colno
e . file = os . path . join ( self . subdir , ' meson.build ' )
raise e
i + = 1 # In THE FUTURE jump over blocks and stuff.
def evaluate_statement ( self , cur ) :
if isinstance ( cur , mparser . FunctionNode ) :
return self . function_call ( cur )
elif isinstance ( cur , mparser . AssignmentNode ) :
return self . assignment ( cur )
elif isinstance ( cur , mparser . MethodNode ) :
return self . method_call ( cur )
elif isinstance ( cur , mparser . StringNode ) :
return cur . value
elif isinstance ( cur , mparser . BooleanNode ) :
return cur . value
elif isinstance ( cur , mparser . IfClauseNode ) :
return self . evaluate_if ( cur )
elif isinstance ( cur , mparser . IdNode ) :
return self . get_variable ( cur . value )
elif isinstance ( cur , mparser . ComparisonNode ) :
return self . evaluate_comparison ( cur )
elif isinstance ( cur , mparser . ArrayNode ) :
return self . evaluate_arraystatement ( cur )
elif isinstance ( cur , mparser . DictNode ) :
return self . evaluate_dictstatement ( cur )
elif isinstance ( cur , mparser . NumberNode ) :
return cur . value
elif isinstance ( cur , mparser . AndNode ) :
return self . evaluate_andstatement ( cur )
elif isinstance ( cur , mparser . OrNode ) :
return self . evaluate_orstatement ( cur )
elif isinstance ( cur , mparser . NotNode ) :
return self . evaluate_notstatement ( cur )
elif isinstance ( cur , mparser . UMinusNode ) :
return self . evaluate_uminusstatement ( cur )
elif isinstance ( cur , mparser . ArithmeticNode ) :
return self . evaluate_arithmeticstatement ( cur )
elif isinstance ( cur , mparser . ForeachClauseNode ) :
return self . evaluate_foreach ( cur )
elif isinstance ( cur , mparser . PlusAssignmentNode ) :
return self . evaluate_plusassign ( cur )
elif isinstance ( cur , mparser . IndexNode ) :
return self . evaluate_indexing ( cur )
elif isinstance ( cur , mparser . TernaryNode ) :
return self . evaluate_ternary ( cur )
elif isinstance ( cur , mparser . ContinueNode ) :
raise ContinueRequest ( )
elif isinstance ( cur , mparser . BreakNode ) :
raise BreakRequest ( )
elif self . is_elementary_type ( cur ) :
return cur
else :
raise InvalidCode ( " Unknown statement. " )
def evaluate_arraystatement ( self , cur ) :
( arguments , kwargs ) = self . reduce_arguments ( cur . args )
if len ( kwargs ) > 0 :
raise InvalidCode ( ' Keyword arguments are invalid in array construction. ' )
return arguments
@FeatureNew ( ' dict ' , ' 0.47.0 ' )
def evaluate_dictstatement ( self , cur ) :
( arguments , kwargs ) = self . reduce_arguments ( cur . args )
assert ( not arguments )
return kwargs
def evaluate_notstatement ( self , cur ) :
v = self . evaluate_statement ( cur . value )
if not isinstance ( v , bool ) :
raise InterpreterException ( ' Argument to " not " is not a boolean. ' )
return not v
def evaluate_if ( self , node ) :
assert ( isinstance ( node , mparser . IfClauseNode ) )
for i in node . ifs :
result = self . evaluate_statement ( i . condition )
if is_disabler ( result ) :
return result
if not ( isinstance ( result , bool ) ) :
raise InvalidCode ( ' If clause {!r} does not evaluate to true or false. ' . format ( result ) )
if result :
self . evaluate_codeblock ( i . block )
return
if not isinstance ( node . elseblock , mparser . EmptyNode ) :
self . evaluate_codeblock ( node . elseblock )
def validate_comparison_types ( self , val1 , val2 ) :
if type ( val1 ) != type ( val2 ) :
return False
return True
def evaluate_in ( self , val1 , val2 ) :
if not isinstance ( val1 , ( str , int , float , ObjectHolder ) ) :
raise InvalidArguments ( ' lvalue of " in " operator must be a string, integer, float, or object ' )
if not isinstance ( val2 , ( list , dict ) ) :
raise InvalidArguments ( ' rvalue of " in " operator must be an array or a dict ' )
return val1 in val2
def evaluate_comparison ( self , node ) :
val1 = self . evaluate_statement ( node . left )
if is_disabler ( val1 ) :
return val1
val2 = self . evaluate_statement ( node . right )
if is_disabler ( val2 ) :
return val2
if node . ctype == ' in ' :
return self . evaluate_in ( val1 , val2 )
elif node . ctype == ' notin ' :
return not self . evaluate_in ( val1 , val2 )
valid = self . validate_comparison_types ( val1 , val2 )
# Ordering comparisons of different types isn't allowed since PR #1810
# (0.41.0). Since PR #2884 we also warn about equality comparisons of
# different types, which will one day become an error.
if not valid and ( node . ctype == ' == ' or node . ctype == ' != ' ) :
mlog . warning ( ''' Trying to compare values of different types ( {} , {} ) using {} .
The result of this is undefined and will become a hard error in a future Meson release . '''
. format ( type ( val1 ) . __name__ , type ( val2 ) . __name__ , node . ctype ) , location = node )
if node . ctype == ' == ' :
return val1 == val2
elif node . ctype == ' != ' :
return val1 != val2
elif not valid :
raise InterpreterException (
' Values of different types ( {} , {} ) cannot be compared using {} . ' . format ( type ( val1 ) . __name__ ,
type ( val2 ) . __name__ ,
node . ctype ) )
elif not self . is_elementary_type ( val1 ) :
raise InterpreterException ( ' {} can only be compared for equality. ' . format ( node . left . value ) )
elif not self . is_elementary_type ( val2 ) :
raise InterpreterException ( ' {} can only be compared for equality. ' . format ( node . right . value ) )
elif node . ctype == ' < ' :
return val1 < val2
elif node . ctype == ' <= ' :
return val1 < = val2
elif node . ctype == ' > ' :
return val1 > val2
elif node . ctype == ' >= ' :
return val1 > = val2
else :
raise InvalidCode ( ' You broke my compare eval. ' )
def evaluate_andstatement ( self , cur ) :
l = self . evaluate_statement ( cur . left )
if is_disabler ( l ) :
return l
if not isinstance ( l , bool ) :
raise InterpreterException ( ' First argument to " and " is not a boolean. ' )
if not l :
return False
r = self . evaluate_statement ( cur . right )
if is_disabler ( r ) :
return r
if not isinstance ( r , bool ) :
raise InterpreterException ( ' Second argument to " and " is not a boolean. ' )
return r
def evaluate_orstatement ( self , cur ) :
l = self . evaluate_statement ( cur . left )
if is_disabler ( l ) :
return l
if not isinstance ( l , bool ) :
raise InterpreterException ( ' First argument to " or " is not a boolean. ' )
if l :
return True
r = self . evaluate_statement ( cur . right )
if is_disabler ( r ) :
return r
if not isinstance ( r , bool ) :
raise InterpreterException ( ' Second argument to " or " is not a boolean. ' )
return r
def evaluate_uminusstatement ( self , cur ) :
v = self . evaluate_statement ( cur . value )
if is_disabler ( v ) :
return v
if not isinstance ( v , int ) :
raise InterpreterException ( ' Argument to negation is not an integer. ' )
return - v
@FeatureNew ( ' / with string arguments ' , ' 0.49.0 ' )
def evaluate_path_join ( self , l , r ) :
if not isinstance ( l , str ) :
raise InvalidCode ( ' The division operator can only append to a string. ' )
if not isinstance ( r , str ) :
raise InvalidCode ( ' The division operator can only append a string. ' )
return self . join_path_strings ( ( l , r ) )
def evaluate_division ( self , l , r ) :
if isinstance ( l , str ) or isinstance ( r , str ) :
return self . evaluate_path_join ( l , r )
if isinstance ( l , int ) and isinstance ( r , int ) :
if r == 0 :
raise InvalidCode ( ' Division by zero. ' )
return l / / r
raise InvalidCode ( ' Division works only with strings or integers. ' )
def evaluate_arithmeticstatement ( self , cur ) :
l = self . evaluate_statement ( cur . left )
if is_disabler ( l ) :
return l
r = self . evaluate_statement ( cur . right )
if is_disabler ( r ) :
return r
if cur . operation == ' add ' :
if isinstance ( l , dict ) and isinstance ( r , dict ) :
return { * * l , * * r }
try :
return l + r
except Exception as e :
raise InvalidCode ( ' Invalid use of addition: ' + str ( e ) )
elif cur . operation == ' sub ' :
if not isinstance ( l , int ) or not isinstance ( r , int ) :
raise InvalidCode ( ' Subtraction works only with integers. ' )
return l - r
elif cur . operation == ' mul ' :
if not isinstance ( l , int ) or not isinstance ( r , int ) :
raise InvalidCode ( ' Multiplication works only with integers. ' )
return l * r
elif cur . operation == ' div ' :
return self . evaluate_division ( l , r )
elif cur . operation == ' mod ' :
if not isinstance ( l , int ) or not isinstance ( r , int ) :
raise InvalidCode ( ' Modulo works only with integers. ' )
return l % r
else :
raise InvalidCode ( ' You broke me. ' )
def evaluate_ternary ( self , node ) :
assert ( isinstance ( node , mparser . TernaryNode ) )
result = self . evaluate_statement ( node . condition )
if is_disabler ( result ) :
return result
if not isinstance ( result , bool ) :
raise InterpreterException ( ' Ternary condition is not boolean. ' )
if result :
return self . evaluate_statement ( node . trueblock )
else :
return self . evaluate_statement ( node . falseblock )
def evaluate_foreach ( self , node ) :
assert ( isinstance ( node , mparser . ForeachClauseNode ) )
items = self . evaluate_statement ( node . items )
if isinstance ( items , list ) :
if len ( node . varnames ) != 1 :
raise InvalidArguments ( ' Foreach on array does not unpack ' )
varname = node . varnames [ 0 ] . value
if is_disabler ( items ) :
return items
for item in items :
self . set_variable ( varname , item )
try :
self . evaluate_codeblock ( node . block )
except ContinueRequest :
continue
except BreakRequest :
break
elif isinstance ( items , dict ) :
if len ( node . varnames ) != 2 :
raise InvalidArguments ( ' Foreach on dict unpacks key and value ' )
if is_disabler ( items ) :
return items
for key , value in items . items ( ) :
self . set_variable ( node . varnames [ 0 ] . value , key )
self . set_variable ( node . varnames [ 1 ] . value , value )
try :
self . evaluate_codeblock ( node . block )
except ContinueRequest :
continue
except BreakRequest :
break
else :
raise InvalidArguments ( ' Items of foreach loop must be an array or a dict ' )
def evaluate_plusassign ( self , node ) :
assert ( isinstance ( node , mparser . PlusAssignmentNode ) )
varname = node . var_name
addition = self . evaluate_statement ( node . value )
if is_disabler ( addition ) :
self . set_variable ( varname , addition )
return
# Remember that all variables are immutable. We must always create a
# full new variable and then assign it.
old_variable = self . get_variable ( varname )
if isinstance ( old_variable , str ) :
if not isinstance ( addition , str ) :
raise InvalidArguments ( ' The += operator requires a string on the right hand side if the variable on the left is a string ' )
new_value = old_variable + addition
elif isinstance ( old_variable , int ) :
if not isinstance ( addition , int ) :
raise InvalidArguments ( ' The += operator requires an int on the right hand side if the variable on the left is an int ' )
new_value = old_variable + addition
elif isinstance ( old_variable , list ) :
if isinstance ( addition , list ) :
new_value = old_variable + addition
else :
new_value = old_variable + [ addition ]
elif isinstance ( old_variable , dict ) :
if not isinstance ( addition , dict ) :
raise InvalidArguments ( ' The += operator requires a dict on the right hand side if the variable on the left is a dict ' )
new_value = { * * old_variable , * * addition }
# Add other data types here.
else :
raise InvalidArguments ( ' The += operator currently only works with arrays, dicts, strings or ints ' )
self . set_variable ( varname , new_value )
def evaluate_indexing ( self , node ) :
assert ( isinstance ( node , mparser . IndexNode ) )
iobject = self . evaluate_statement ( node . iobject )
if is_disabler ( iobject ) :
return iobject
if not hasattr ( iobject , ' __getitem__ ' ) :
raise InterpreterException (
' Tried to index an object that doesn \' t support indexing. ' )
index = self . evaluate_statement ( node . index )
if isinstance ( iobject , dict ) :
if not isinstance ( index , str ) :
raise InterpreterException ( ' Key is not a string ' )
try :
return iobject [ index ]
except KeyError :
raise InterpreterException ( ' Key %s is not in dict ' % index )
else :
if not isinstance ( index , int ) :
raise InterpreterException ( ' Index value is not an integer. ' )
try :
return iobject [ index ]
except IndexError :
raise InterpreterException ( ' Index %d out of bounds of array of size %d . ' % ( index , len ( iobject ) ) )
def function_call ( self , node ) :
func_name = node . func_name
( posargs , kwargs ) = self . reduce_arguments ( node . args )
if is_disabled ( posargs , kwargs ) :
return Disabler ( )
if func_name in self . funcs :
func = self . funcs [ func_name ]
if not getattr ( func , ' no-args-flattening ' , False ) :
posargs = flatten ( posargs )
self . current_node = node
return func ( node , posargs , kwargs )
else :
self . unknown_function_called ( func_name )
def method_call ( self , node ) :
invokable = node . source_object
if isinstance ( invokable , mparser . IdNode ) :
object_name = invokable . value
obj = self . get_variable ( object_name )
else :
obj = self . evaluate_statement ( invokable )
method_name = node . name
args = node . args
if isinstance ( obj , str ) :
return self . string_method_call ( obj , method_name , args )
if isinstance ( obj , bool ) :
return self . bool_method_call ( obj , method_name , args )
if isinstance ( obj , int ) :
return self . int_method_call ( obj , method_name , args )
if isinstance ( obj , list ) :
return self . array_method_call ( obj , method_name , args )
if isinstance ( obj , dict ) :
return self . dict_method_call ( obj , method_name , args )
if isinstance ( obj , mesonlib . File ) :
raise InvalidArguments ( ' File object " %s " is not callable. ' % obj )
if not isinstance ( obj , InterpreterObject ) :
raise InvalidArguments ( ' Variable " %s " is not callable. ' % object_name )
( args , kwargs ) = self . reduce_arguments ( args )
# Special case. This is the only thing you can do with a disabler
# object. Every other use immediately returns the disabler object.
if isinstance ( obj , Disabler ) and method_name == ' found ' :
return False
if is_disabled ( args , kwargs ) :
return Disabler ( )
if method_name == ' extract_objects ' :
self . validate_extraction ( obj . held_object )
obj . current_node = node
return obj . method_call ( method_name , args , kwargs )
def bool_method_call ( self , obj , method_name , args ) :
( posargs , kwargs ) = self . reduce_arguments ( args )
if is_disabled ( posargs , kwargs ) :
return Disabler ( )
if method_name == ' to_string ' :
Don't use len() to test emptiness vs not emptiness
Meson has a common pattern of using 'if len(foo) == 0:' or
'if len(foo) != 0:', however, this is a common anti-pattern in python.
Instead tests for emptiness/non-emptiness should be done with a simple
'if foo:' or 'if not foo:'
Consider the following:
>>> import timeit
>>> timeit.timeit('if len([]) == 0: pass')
0.10730923599840025
>>> timeit.timeit('if not []: pass')
0.030033907998586074
>>> timeit.timeit('if len(['a', 'b', 'c', 'd']) == 0: pass')
0.1154778649979562
>>> timeit.timeit("if not ['a', 'b', 'c', 'd']: pass")
0.08259823200205574
>>> timeit.timeit('if len("") == 0: pass')
0.089759664999292
>>> timeit.timeit('if not "": pass')
0.02340641999762738
>>> timeit.timeit('if len("foo") == 0: pass')
0.08848102600313723
>>> timeit.timeit('if not "foo": pass')
0.04032287199879647
And for the one additional case of 'if len(foo.strip()) == 0', which can
be replaced with 'if not foo.isspace()'
>>> timeit.timeit('if len(" ".strip()) == 0: pass')
0.15294511600222904
>>> timeit.timeit('if " ".isspace(): pass')
0.09413968399894657
>>> timeit.timeit('if len(" abc".strip()) == 0: pass')
0.2023209120015963
>>> timeit.timeit('if " abc".isspace(): pass')
0.09571301700270851
In other words, it's always a win to not use len(), when you don't
actually want to check the length.
8 years ago
if not posargs :
if obj :
return ' true '
else :
return ' false '
elif len ( posargs ) == 2 and isinstance ( posargs [ 0 ] , str ) and isinstance ( posargs [ 1 ] , str ) :
if obj :
return posargs [ 0 ]
else :
return posargs [ 1 ]
else :
raise InterpreterException ( ' bool.to_string() must have either no arguments or exactly two string arguments that signify what values to return for true and false. ' )
elif method_name == ' to_int ' :
if obj :
return 1
else :
return 0
else :
raise InterpreterException ( ' Unknown method " %s " for a boolean. ' % method_name )
def int_method_call ( self , obj , method_name , args ) :
( posargs , kwargs ) = self . reduce_arguments ( args )
if is_disabled ( posargs , kwargs ) :
return Disabler ( )
if method_name == ' is_even ' :
Don't use len() to test emptiness vs not emptiness
Meson has a common pattern of using 'if len(foo) == 0:' or
'if len(foo) != 0:', however, this is a common anti-pattern in python.
Instead tests for emptiness/non-emptiness should be done with a simple
'if foo:' or 'if not foo:'
Consider the following:
>>> import timeit
>>> timeit.timeit('if len([]) == 0: pass')
0.10730923599840025
>>> timeit.timeit('if not []: pass')
0.030033907998586074
>>> timeit.timeit('if len(['a', 'b', 'c', 'd']) == 0: pass')
0.1154778649979562
>>> timeit.timeit("if not ['a', 'b', 'c', 'd']: pass")
0.08259823200205574
>>> timeit.timeit('if len("") == 0: pass')
0.089759664999292
>>> timeit.timeit('if not "": pass')
0.02340641999762738
>>> timeit.timeit('if len("foo") == 0: pass')
0.08848102600313723
>>> timeit.timeit('if not "foo": pass')
0.04032287199879647
And for the one additional case of 'if len(foo.strip()) == 0', which can
be replaced with 'if not foo.isspace()'
>>> timeit.timeit('if len(" ".strip()) == 0: pass')
0.15294511600222904
>>> timeit.timeit('if " ".isspace(): pass')
0.09413968399894657
>>> timeit.timeit('if len(" abc".strip()) == 0: pass')
0.2023209120015963
>>> timeit.timeit('if " abc".isspace(): pass')
0.09571301700270851
In other words, it's always a win to not use len(), when you don't
actually want to check the length.
8 years ago
if not posargs :
return obj % 2 == 0
else :
raise InterpreterException ( ' int.is_even() must have no arguments. ' )
elif method_name == ' is_odd ' :
Don't use len() to test emptiness vs not emptiness
Meson has a common pattern of using 'if len(foo) == 0:' or
'if len(foo) != 0:', however, this is a common anti-pattern in python.
Instead tests for emptiness/non-emptiness should be done with a simple
'if foo:' or 'if not foo:'
Consider the following:
>>> import timeit
>>> timeit.timeit('if len([]) == 0: pass')
0.10730923599840025
>>> timeit.timeit('if not []: pass')
0.030033907998586074
>>> timeit.timeit('if len(['a', 'b', 'c', 'd']) == 0: pass')
0.1154778649979562
>>> timeit.timeit("if not ['a', 'b', 'c', 'd']: pass")
0.08259823200205574
>>> timeit.timeit('if len("") == 0: pass')
0.089759664999292
>>> timeit.timeit('if not "": pass')
0.02340641999762738
>>> timeit.timeit('if len("foo") == 0: pass')
0.08848102600313723
>>> timeit.timeit('if not "foo": pass')
0.04032287199879647
And for the one additional case of 'if len(foo.strip()) == 0', which can
be replaced with 'if not foo.isspace()'
>>> timeit.timeit('if len(" ".strip()) == 0: pass')
0.15294511600222904
>>> timeit.timeit('if " ".isspace(): pass')
0.09413968399894657
>>> timeit.timeit('if len(" abc".strip()) == 0: pass')
0.2023209120015963
>>> timeit.timeit('if " abc".isspace(): pass')
0.09571301700270851
In other words, it's always a win to not use len(), when you don't
actually want to check the length.
8 years ago
if not posargs :
return obj % 2 != 0
else :
raise InterpreterException ( ' int.is_odd() must have no arguments. ' )
elif method_name == ' to_string ' :
if not posargs :
return str ( obj )
else :
raise InterpreterException ( ' int.to_string() must have no arguments. ' )
else :
raise InterpreterException ( ' Unknown method " %s " for an integer. ' % method_name )
@staticmethod
def _get_one_string_posarg ( posargs , method_name ) :
if len ( posargs ) > 1 :
m = ' {} () must have zero or one arguments '
raise InterpreterException ( m . format ( method_name ) )
elif len ( posargs ) == 1 :
s = posargs [ 0 ]
if not isinstance ( s , str ) :
m = ' {} () argument must be a string '
raise InterpreterException ( m . format ( method_name ) )
return s
return None
def string_method_call ( self , obj , method_name , args ) :
( posargs , kwargs ) = self . reduce_arguments ( args )
if is_disabled ( posargs , kwargs ) :
return Disabler ( )
if method_name == ' strip ' :
s = self . _get_one_string_posarg ( posargs , ' strip ' )
if s is not None :
return obj . strip ( s )
return obj . strip ( )
elif method_name == ' format ' :
return self . format_string ( obj , args )
elif method_name == ' to_upper ' :
return obj . upper ( )
elif method_name == ' to_lower ' :
return obj . lower ( )
elif method_name == ' underscorify ' :
return re . sub ( r ' [^a-zA-Z0-9] ' , ' _ ' , obj )
elif method_name == ' split ' :
s = self . _get_one_string_posarg ( posargs , ' split ' )
if s is not None :
return obj . split ( s )
return obj . split ( )
elif method_name == ' startswith ' or method_name == ' contains ' or method_name == ' endswith ' :
s = posargs [ 0 ]
if not isinstance ( s , str ) :
raise InterpreterException ( ' Argument must be a string. ' )
if method_name == ' startswith ' :
return obj . startswith ( s )
elif method_name == ' contains ' :
return obj . find ( s ) > = 0
return obj . endswith ( s )
elif method_name == ' to_int ' :
try :
return int ( obj )
except Exception :
raise InterpreterException ( ' String {!r} cannot be converted to int ' . format ( obj ) )
elif method_name == ' join ' :
if len ( posargs ) != 1 :
raise InterpreterException ( ' Join() takes exactly one argument. ' )
strlist = posargs [ 0 ]
check_stringlist ( strlist )
return obj . join ( strlist )
elif method_name == ' version_compare ' :
if len ( posargs ) != 1 :
raise InterpreterException ( ' Version_compare() takes exactly one argument. ' )
cmpr = posargs [ 0 ]
if not isinstance ( cmpr , str ) :
raise InterpreterException ( ' Version_compare() argument must be a string. ' )
return mesonlib . version_compare ( obj , cmpr )
raise InterpreterException ( ' Unknown method " %s " for a string. ' % method_name )
def format_string ( self , templ , args ) :
if isinstance ( args , mparser . ArgumentNode ) :
args = args . arguments
arg_strings = [ ]
for arg in args :
arg = self . evaluate_statement ( arg )
if isinstance ( arg , bool ) : # Python boolean is upper case.
arg = str ( arg ) . lower ( )
arg_strings . append ( str ( arg ) )
def arg_replace ( match ) :
idx = int ( match . group ( 1 ) )
if idx > = len ( arg_strings ) :
raise InterpreterException ( ' Format placeholder @ {} @ out of range. ' . format ( idx ) )
return arg_strings [ idx ]
return re . sub ( r ' @( \ d+)@ ' , arg_replace , templ )
def unknown_function_called ( self , func_name ) :
raise InvalidCode ( ' Unknown function " %s " . ' % func_name )
def array_method_call ( self , obj , method_name , args ) :
( posargs , kwargs ) = self . reduce_arguments ( args )
if is_disabled ( posargs , kwargs ) :
return Disabler ( )
if method_name == ' contains ' :
return self . check_contains ( obj , posargs )
elif method_name == ' length ' :
return len ( obj )
elif method_name == ' get ' :
index = posargs [ 0 ]
fallback = None
if len ( posargs ) == 2 :
fallback = posargs [ 1 ]
elif len ( posargs ) > 2 :
m = ' Array method \' get() \' only takes two arguments: the ' \
' index and an optional fallback value if the index is ' \
' out of range. '
raise InvalidArguments ( m )
if not isinstance ( index , int ) :
raise InvalidArguments ( ' Array index must be a number. ' )
if index < - len ( obj ) or index > = len ( obj ) :
if fallback is None :
m = ' Array index {!r} is out of bounds for array of size {!r} . '
raise InvalidArguments ( m . format ( index , len ( obj ) ) )
return fallback
return obj [ index ]
m = ' Arrays do not have a method called {!r} . '
raise InterpreterException ( m . format ( method_name ) )
def dict_method_call ( self , obj , method_name , args ) :
( posargs , kwargs ) = self . reduce_arguments ( args )
if is_disabled ( posargs , kwargs ) :
return Disabler ( )
if method_name in ( ' has_key ' , ' get ' ) :
if method_name == ' has_key ' :
if len ( posargs ) != 1 :
raise InterpreterException ( ' has_key() takes exactly one argument. ' )
else :
if len ( posargs ) not in ( 1 , 2 ) :
raise InterpreterException ( ' get() takes one or two arguments. ' )
key = posargs [ 0 ]
if not isinstance ( key , ( str ) ) :
raise InvalidArguments ( ' Dictionary key must be a string. ' )
has_key = key in obj
if method_name == ' has_key ' :
return has_key
if has_key :
return obj [ key ]
if len ( posargs ) == 2 :
return posargs [ 1 ]
raise InterpreterException ( ' Key {!r} is not in the dictionary. ' . format ( key ) )
if method_name == ' keys ' :
if len ( posargs ) != 0 :
raise InterpreterException ( ' keys() takes no arguments. ' )
return list ( obj . keys ( ) )
raise InterpreterException ( ' Dictionaries do not have a method called " %s " . ' % method_name )
def reduce_arguments ( self , args ) :
assert ( isinstance ( args , mparser . ArgumentNode ) )
if args . incorrect_order ( ) :
raise InvalidArguments ( ' All keyword arguments must be after positional arguments. ' )
self . argument_depth + = 1
reduced_pos = [ self . evaluate_statement ( arg ) for arg in args . arguments ]
reduced_kw = { }
for key in args . kwargs . keys ( ) :
if not isinstance ( key , str ) :
raise InvalidArguments ( ' Keyword argument name is not a string. ' )
a = args . kwargs [ key ]
reduced_kw [ key ] = self . evaluate_statement ( a )
self . argument_depth - = 1
final_kw = self . expand_default_kwargs ( reduced_kw )
return reduced_pos , final_kw
def expand_default_kwargs ( self , kwargs ) :
if ' kwargs ' not in kwargs :
return kwargs
to_expand = kwargs . pop ( ' kwargs ' )
if not isinstance ( to_expand , dict ) :
raise InterpreterException ( ' Value of " kwargs " must be dictionary. ' )
if ' kwargs ' in to_expand :
raise InterpreterException ( ' Kwargs argument must not contain a " kwargs " entry. Points for thinking meta, though. :P ' )
for k , v in to_expand . items ( ) :
if k in kwargs :
raise InterpreterException ( ' Entry " {} " defined both as a keyword argument and in a " kwarg " entry. ' . format ( k ) )
kwargs [ k ] = v
return kwargs
def assignment ( self , node ) :
assert ( isinstance ( node , mparser . AssignmentNode ) )
if self . argument_depth != 0 :
raise InvalidArguments ( ''' Tried to assign values inside an argument list.
To specify a keyword argument , use : instead of = . ''' )
var_name = node . var_name
if not isinstance ( var_name , str ) :
raise InvalidArguments ( ' Tried to assign value to a non-variable. ' )
value = self . evaluate_statement ( node . value )
if not self . is_assignable ( value ) :
raise InvalidCode ( ' Tried to assign an invalid value to variable. ' )
# For mutable objects we need to make a copy on assignment
if isinstance ( value , MutableInterpreterObject ) :
value = copy . deepcopy ( value )
self . set_variable ( var_name , value )
return None
def set_variable ( self , varname , variable ) :
if variable is None :
raise InvalidCode ( ' Can not assign None to variable. ' )
if not isinstance ( varname , str ) :
raise InvalidCode ( ' First argument to set_variable must be a string. ' )
if not self . is_assignable ( variable ) :
raise InvalidCode ( ' Assigned value not of assignable type. ' )
if re . match ( ' [_a-zA-Z][_0-9a-zA-Z]*$ ' , varname ) is None :
raise InvalidCode ( ' Invalid variable name: ' + varname )
if varname in self . builtin :
raise InvalidCode ( ' Tried to overwrite internal variable " %s " ' % varname )
self . variables [ varname ] = variable
def get_variable ( self , varname ) :
if varname in self . builtin :
return self . builtin [ varname ]
if varname in self . variables :
return self . variables [ varname ]
raise InvalidCode ( ' Unknown variable " %s " . ' % varname )
def is_assignable ( self , value ) :
return isinstance ( value , ( InterpreterObject , dependencies . Dependency ,
str , int , list , dict , mesonlib . File ) )
def is_elementary_type ( self , v ) :
return isinstance ( v , ( int , float , str , bool , list ) )