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# Copyright 2014-2017 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.
import re
import codecs
import types
from .mesonlib import MesonException
from . import mlog
# This is the regex for the supported escape sequences of a regular string
# literal, like 'abc\x00'
ESCAPE_SEQUENCE_SINGLE_RE = re.compile(r'''
( \\U........ # 8-digit hex escapes
| \\u.... # 4-digit hex escapes
| \\x.. # 2-digit hex escapes
| \\[0-7]{1,3} # Octal escapes
| \\N\{[^}]+\} # Unicode characters by name
| \\[\\'abfnrtv] # Single-character escapes
)''', re.UNICODE | re.VERBOSE)
class MesonUnicodeDecodeError(MesonException):
def __init__(self, match):
super().__init__("%s" % match)
self.match = match
def decode_match(match):
try:
return codecs.decode(match.group(0), 'unicode_escape')
except UnicodeDecodeError as err:
raise MesonUnicodeDecodeError(match.group(0))
class ParseException(MesonException):
def __init__(self, text, line, lineno, colno):
# Format as error message, followed by the line with the error, followed by a caret to show the error column.
super().__init__("%s\n%s\n%s" % (text, line, '%s^' % (' ' * colno)))
self.lineno = lineno
self.colno = colno
class BlockParseException(MesonException):
def __init__(self, text, line, lineno, colno, start_line, start_lineno, start_colno):
# This can be formatted in two ways - one if the block start and end are on the same line, and a different way if they are on different lines.
if lineno == start_lineno:
# If block start and end are on the same line, it is formatted as:
# Error message
# Followed by the line with the error
# Followed by a caret to show the block start
# Followed by underscores
# Followed by a caret to show the block end.
super().__init__("%s\n%s\n%s" % (text, line, '%s^%s^' % (' ' * start_colno, '_' * (colno - start_colno - 1))))
else:
# If block start and end are on different lines, it is formatted as:
# Error message
# Followed by the line with the error
# Followed by a caret to show the error column.
# Followed by a message saying where the block started.
# Followed by the line of the block start.
# Followed by a caret for the block start.
super().__init__("%s\n%s\n%s\nFor a block that started at %d,%d\n%s\n%s" % (text, line, '%s^' % (' ' * colno), start_lineno, start_colno, start_line, "%s^" % (' ' * start_colno)))
self.lineno = lineno
self.colno = colno
class Token:
def __init__(self, tid, subdir, line_start, lineno, colno, bytespan, value):
self.tid = tid
self.subdir = subdir
self.line_start = line_start
self.lineno = lineno
self.colno = colno
self.bytespan = bytespan
self.value = value
def __eq__(self, other):
if isinstance(other, str):
return self.tid == other
return self.tid == other.tid
class Lexer:
def __init__(self, code):
self.code = code
self.keywords = {'true', 'false', 'if', 'else', 'elif',
'endif', 'and', 'or', 'not', 'foreach', 'endforeach',
'in', 'continue', 'break'}
self.future_keywords = {'return'}
self.token_specification = [
# Need to be sorted longest to shortest.
('ignore', re.compile(r'[ \t]')),
('id', re.compile('[_a-zA-Z][_0-9a-zA-Z]*')),
('number', re.compile(r'0[bB][01]+|0[oO][0-7]+|0[xX][0-9a-fA-F]+|0|[1-9]\d*')),
('eol_cont', re.compile(r'\\\n')),
('eol', re.compile(r'\n')),
('multiline_string', re.compile(r"'''(.|\n)*?'''", re.M)),
('comment', re.compile(r'#.*')),
('lparen', re.compile(r'\(')),
('rparen', re.compile(r'\)')),
('lbracket', re.compile(r'\[')),
('rbracket', re.compile(r'\]')),
('lcurl', re.compile(r'\{')),
('rcurl', re.compile(r'\}')),
('dblquote', re.compile(r'"')),
('string', re.compile(r"'([^'\\]|(\\.))*'")),
('comma', re.compile(r',')),
('plusassign', re.compile(r'\+=')),
('dot', re.compile(r'\.')),
('plus', re.compile(r'\+')),
('dash', re.compile(r'-')),
('star', re.compile(r'\*')),
('percent', re.compile(r'%')),
('fslash', re.compile(r'/')),
('colon', re.compile(r':')),
('equal', re.compile(r'==')),
('nequal', re.compile(r'!=')),
('assign', re.compile(r'=')),
('le', re.compile(r'<=')),
('lt', re.compile(r'<')),
('ge', re.compile(r'>=')),
('gt', re.compile(r'>')),
('questionmark', re.compile(r'\?')),
]
def getline(self, line_start):
return self.code[line_start:self.code.find('\n', line_start)]
def lex(self, subdir):
line_start = 0
lineno = 1
loc = 0
par_count = 0
bracket_count = 0
curl_count = 0
col = 0
while loc < len(self.code):
matched = False
value = None
for (tid, reg) in self.token_specification:
mo = reg.match(self.code, loc)
if mo:
curline = lineno
curline_start = line_start
col = mo.start() - line_start
matched = True
span_start = loc
loc = mo.end()
span_end = loc
bytespan = (span_start, span_end)
match_text = mo.group()
if tid == 'ignore' or tid == 'comment':
break
elif tid == 'lparen':
par_count += 1
elif tid == 'rparen':
par_count -= 1
elif tid == 'lbracket':
bracket_count += 1
elif tid == 'rbracket':
bracket_count -= 1
elif tid == 'lcurl':
curl_count += 1
elif tid == 'rcurl':
curl_count -= 1
elif tid == 'dblquote':
raise ParseException('Double quotes are not supported. Use single quotes.', self.getline(line_start), lineno, col)
elif tid == 'string':
# Handle here and not on the regexp to give a better error message.
if match_text.find("\n") != -1:
mlog.warning("""Newline character in a string detected, use ''' (three single quotes) for multiline strings instead.
This will become a hard error in a future Meson release.""", self.getline(line_start), lineno, col)
value = match_text[1:-1]
try:
value = ESCAPE_SEQUENCE_SINGLE_RE.sub(decode_match, value)
except MesonUnicodeDecodeError as err:
raise MesonException("Failed to parse escape sequence: '{}' in string:\n {}".format(err.match, match_text))
elif tid == 'multiline_string':
tid = 'string'
value = match_text[3:-3]
lines = match_text.split('\n')
if len(lines) > 1:
lineno += len(lines) - 1
line_start = mo.end() - len(lines[-1])
elif tid == 'number':
value = int(match_text, base=0)
elif tid == 'eol' or tid == 'eol_cont':
lineno += 1
line_start = loc
if par_count > 0 or bracket_count > 0 or curl_count > 0:
break
elif tid == 'id':
if match_text in self.keywords:
tid = match_text
else:
if match_text in self.future_keywords:
mlog.warning("Identifier '{}' will become a reserved keyword in a future release. Please rename it.".format(match_text),
location=types.SimpleNamespace(subdir=subdir, lineno=lineno))
value = match_text
yield Token(tid, subdir, curline_start, curline, col, bytespan, value)
break
if not matched:
raise ParseException('lexer', self.getline(line_start), lineno, col)
class ElementaryNode:
def __init__(self, token):
self.lineno = token.lineno
self.subdir = token.subdir
self.colno = token.colno
self.value = token.value
self.bytespan = token.bytespan
class BooleanNode(ElementaryNode):
def __init__(self, token, value):
super().__init__(token)
self.value = value
assert(isinstance(self.value, bool))
class IdNode(ElementaryNode):
def __init__(self, token):
super().__init__(token)
assert(isinstance(self.value, str))
def __str__(self):
return "Id node: '%s' (%d, %d)." % (self.value, self.lineno, self.colno)
class NumberNode(ElementaryNode):
def __init__(self, token):
super().__init__(token)
assert(isinstance(self.value, int))
class StringNode(ElementaryNode):
def __init__(self, token):
super().__init__(token)
assert(isinstance(self.value, str))
def __str__(self):
return "String node: '%s' (%d, %d)." % (self.value, self.lineno, self.colno)
class ContinueNode(ElementaryNode):
pass
class BreakNode(ElementaryNode):
pass
class ArrayNode:
def __init__(self, args):
self.subdir = args.subdir
self.lineno = args.lineno
self.colno = args.colno
self.args = args
class DictNode:
def __init__(self, args):
self.subdir = args.subdir
self.lineno = args.lineno
self.colno = args.colno
self.args = args
class EmptyNode:
def __init__(self, lineno, colno):
self.subdir = ''
self.lineno = lineno
self.colno = colno
self.value = None
class OrNode:
def __init__(self, left, right):
self.subdir = left.subdir
self.lineno = left.lineno
self.colno = left.colno
self.left = left
self.right = right
class AndNode:
def __init__(self, left, right):
self.subdir = left.subdir
self.lineno = left.lineno
self.colno = left.colno
self.left = left
self.right = right
class ComparisonNode:
def __init__(self, ctype, left, right):
self.lineno = left.lineno
self.colno = left.colno
self.subdir = left.subdir
self.left = left
self.right = right
self.ctype = ctype
class ArithmeticNode:
def __init__(self, operation, left, right):
self.subdir = left.subdir
self.lineno = left.lineno
self.colno = left.colno
self.left = left
self.right = right
self.operation = operation
class NotNode:
def __init__(self, location_node, value):
self.subdir = location_node.subdir
self.lineno = location_node.lineno
self.colno = location_node.colno
self.value = value
class CodeBlockNode:
def __init__(self, location_node):
self.subdir = location_node.subdir
self.lineno = location_node.lineno
self.colno = location_node.colno
self.lines = []
class IndexNode:
def __init__(self, iobject, index):
self.iobject = iobject
self.index = index
self.subdir = iobject.subdir
self.lineno = iobject.lineno
self.colno = iobject.colno
class MethodNode:
def __init__(self, subdir, lineno, colno, source_object, name, args):
self.subdir = subdir
self.lineno = lineno
self.colno = colno
self.source_object = source_object
self.name = name
assert(isinstance(self.name, str))
self.args = args
class FunctionNode:
def __init__(self, subdir, lineno, colno, func_name, args):
self.subdir = subdir
self.lineno = lineno
self.colno = colno
self.func_name = func_name
assert(isinstance(func_name, str))
self.args = args
class AssignmentNode:
def __init__(self, lineno, colno, var_name, value):
self.lineno = lineno
self.colno = colno
self.var_name = var_name
assert(isinstance(var_name, str))
self.value = value
class PlusAssignmentNode:
def __init__(self, lineno, colno, var_name, value):
self.lineno = lineno
self.colno = colno
self.var_name = var_name
assert(isinstance(var_name, str))
self.value = value
class ForeachClauseNode:
def __init__(self, lineno, colno, varnames, items, block):
self.lineno = lineno
self.colno = colno
self.varnames = varnames
self.items = items
self.block = block
class IfClauseNode:
def __init__(self, lineno, colno):
self.lineno = lineno
self.colno = colno
self.ifs = []
self.elseblock = EmptyNode(lineno, colno)
class UMinusNode:
def __init__(self, current_location, value):
self.subdir = current_location.subdir
self.lineno = current_location.lineno
self.colno = current_location.colno
self.value = value
class IfNode:
def __init__(self, lineno, colno, condition, block):
self.lineno = lineno
self.colno = colno
self.condition = condition
self.block = block
class TernaryNode:
def __init__(self, lineno, colno, condition, trueblock, falseblock):
self.lineno = lineno
self.colno = colno
self.condition = condition
self.trueblock = trueblock
self.falseblock = falseblock
class ArgumentNode:
def __init__(self, token):
self.lineno = token.lineno
self.colno = token.colno
self.subdir = token.subdir
self.arguments = []
self.commas = []
self.kwargs = {}
self.order_error = False
def prepend(self, statement):
if self.num_kwargs() > 0:
self.order_error = True
if not isinstance(statement, EmptyNode):
self.arguments = [statement] + self.arguments
def append(self, statement):
if self.num_kwargs() > 0:
self.order_error = True
if not isinstance(statement, EmptyNode):
self.arguments += [statement]
def set_kwarg(self, name, value):
if name in self.kwargs:
mlog.warning('Keyword argument "{}" defined multiple times.'.format(name), location=self)
mlog.warning('This will be an error in future Meson releases.')
self.kwargs[name] = value
def num_args(self):
return len(self.arguments)
def num_kwargs(self):
return len(self.kwargs)
def incorrect_order(self):
return self.order_error
def __len__(self):
return self.num_args() # Fixme
comparison_map = {'equal': '==',
'nequal': '!=',
'lt': '<',
'le': '<=',
'gt': '>',
'ge': '>=',
'in': 'in',
'notin': 'not in',
}
# Recursive descent parser for Meson's definition language.
# Very basic apart from the fact that we have many precedence
# levels so there are not enough words to describe them all.
# Enter numbering:
#
# 1 assignment
# 2 or
# 3 and
# 4 comparison
# 5 arithmetic
# 6 negation
# 7 funcall, method call
# 8 parentheses
# 9 plain token
class Parser:
def __init__(self, code, subdir):
self.lexer = Lexer(code)
self.stream = self.lexer.lex(subdir)
self.current = Token('eof', '', 0, 0, 0, (0, 0), None)
self.getsym()
self.in_ternary = False
def getsym(self):
try:
self.current = next(self.stream)
except StopIteration:
self.current = Token('eof', '', self.current.line_start, self.current.lineno, self.current.colno + self.current.bytespan[1] - self.current.bytespan[0], (0, 0), None)
def getline(self):
return self.lexer.getline(self.current.line_start)
def accept(self, s):
if self.current.tid == s:
self.getsym()
return True
return False
def expect(self, s):
if self.accept(s):
return True
raise ParseException('Expecting %s got %s.' % (s, self.current.tid), self.getline(), self.current.lineno, self.current.colno)
def block_expect(self, s, block_start):
if self.accept(s):
return True
raise BlockParseException('Expecting %s got %s.' % (s, self.current.tid), self.getline(), self.current.lineno, self.current.colno, self.lexer.getline(block_start.line_start), block_start.lineno, block_start.colno)
def parse(self):
block = self.codeblock()
self.expect('eof')
return block
def statement(self):
return self.e1()
def e1(self):
left = self.e2()
if self.accept('plusassign'):
value = self.e1()
if not isinstance(left, IdNode):
raise ParseException('Plusassignment target must be an id.', self.getline(), left.lineno, left.colno)
return PlusAssignmentNode(left.lineno, left.colno, left.value, value)
elif self.accept('assign'):
value = self.e1()
if not isinstance(left, IdNode):
raise ParseException('Assignment target must be an id.',
self.getline(), left.lineno, left.colno)
return AssignmentNode(left.lineno, left.colno, left.value, value)
elif self.accept('questionmark'):
if self.in_ternary:
raise ParseException('Nested ternary operators are not allowed.',
self.getline(), left.lineno, left.colno)
self.in_ternary = True
trueblock = self.e1()
self.expect('colon')
falseblock = self.e1()
self.in_ternary = False
return TernaryNode(left.lineno, left.colno, left, trueblock, falseblock)
return left
def e2(self):
left = self.e3()
while self.accept('or'):
if isinstance(left, EmptyNode):
raise ParseException('Invalid or clause.',
self.getline(), left.lineno, left.colno)
left = OrNode(left, self.e3())
return left
def e3(self):
left = self.e4()
while self.accept('and'):
if isinstance(left, EmptyNode):
raise ParseException('Invalid and clause.',
self.getline(), left.lineno, left.colno)
left = AndNode(left, self.e4())
return left
def e4(self):
left = self.e5()
for nodename, operator_type in comparison_map.items():
if self.accept(nodename):
return ComparisonNode(operator_type, left, self.e5())
if self.accept('not') and self.accept('in'):
return ComparisonNode('notin', left, self.e5())
return left
def e5(self):
return self.e5add()
def e5add(self):
left = self.e5sub()
if self.accept('plus'):
return ArithmeticNode('add', left, self.e5add())
return left
def e5sub(self):
left = self.e5mod()
if self.accept('dash'):
return ArithmeticNode('sub', left, self.e5sub())
return left
def e5mod(self):
left = self.e5mul()
if self.accept('percent'):
return ArithmeticNode('mod', left, self.e5mod())
return left
def e5mul(self):
left = self.e5div()
if self.accept('star'):
return ArithmeticNode('mul', left, self.e5mul())
return left
def e5div(self):
left = self.e6()
if self.accept('fslash'):
return ArithmeticNode('div', left, self.e5div())
return left
def e6(self):
if self.accept('not'):
return NotNode(self.current, self.e7())
if self.accept('dash'):
return UMinusNode(self.current, self.e7())
return self.e7()
def e7(self):
left = self.e8()
block_start = self.current
if self.accept('lparen'):
args = self.args()
self.block_expect('rparen', block_start)
if not isinstance(left, IdNode):
raise ParseException('Function call must be applied to plain id',
self.getline(), left.lineno, left.colno)
left = FunctionNode(left.subdir, left.lineno, left.colno, left.value, args)
go_again = True
while go_again:
go_again = False
if self.accept('dot'):
go_again = True
left = self.method_call(left)
if self.accept('lbracket'):
go_again = True
left = self.index_call(left)
return left
def e8(self):
block_start = self.current
if self.accept('lparen'):
e = self.statement()
self.block_expect('rparen', block_start)
return e
elif self.accept('lbracket'):
args = self.args()
self.block_expect('rbracket', block_start)
return ArrayNode(args)
elif self.accept('lcurl'):
key_values = self.key_values()
self.block_expect('rcurl', block_start)
return DictNode(key_values)
else:
return self.e9()
def e9(self):
t = self.current
if self.accept('true'):
return BooleanNode(t, True)
if self.accept('false'):
return BooleanNode(t, False)
if self.accept('id'):
return IdNode(t)
if self.accept('number'):
return NumberNode(t)
if self.accept('string'):
return StringNode(t)
return EmptyNode(self.current.lineno, self.current.colno)
def key_values(self):
s = self.statement()
a = ArgumentNode(s)
while not isinstance(s, EmptyNode):
potential = self.current
if self.accept('colon'):
if not isinstance(s, StringNode):
raise ParseException('Key must be a string.',
self.getline(), s.lineno, s.colno)
if s.value in a.kwargs:
# + 1 to colno to point to the actual string, not the opening quote
raise ParseException('Duplicate dictionary key: {}'.format(s.value),
self.getline(), s.lineno, s.colno + 1)
a.set_kwarg(s.value, self.statement())
potential = self.current
if not self.accept('comma'):
return a
a.commas.append(potential)
else:
raise ParseException('Only key:value pairs are valid in dict construction.',
self.getline(), s.lineno, s.colno)
s = self.statement()
return a
def args(self):
s = self.statement()
a = ArgumentNode(s)
while not isinstance(s, EmptyNode):
potential = self.current
if self.accept('comma'):
a.commas.append(potential)
a.append(s)
elif self.accept('colon'):
if not isinstance(s, IdNode):
raise ParseException('Dictionary key must be a plain identifier.',
self.getline(), s.lineno, s.colno)
a.set_kwarg(s.value, self.statement())
potential = self.current
if not self.accept('comma'):
return a
a.commas.append(potential)
else:
a.append(s)
return a
s = self.statement()
return a
def method_call(self, source_object):
methodname = self.e9()
if not(isinstance(methodname, IdNode)):
raise ParseException('Method name must be plain id',
self.getline(), self.current.lineno, self.current.colno)
self.expect('lparen')
args = self.args()
self.expect('rparen')
method = MethodNode(methodname.subdir, methodname.lineno, methodname.colno, source_object, methodname.value, args)
if self.accept('dot'):
return self.method_call(method)
return method
def index_call(self, source_object):
index_statement = self.statement()
self.expect('rbracket')
return IndexNode(source_object, index_statement)
def foreachblock(self):
t = self.current
self.expect('id')
varname = t
varnames = [t]
if self.accept('comma'):
t = self.current
self.expect('id')
varnames.append(t)
self.expect('colon')
items = self.statement()
block = self.codeblock()
return ForeachClauseNode(varname.lineno, varname.colno, varnames, items, block)
def ifblock(self):
condition = self.statement()
clause = IfClauseNode(condition.lineno, condition.colno)
self.expect('eol')
block = self.codeblock()
clause.ifs.append(IfNode(clause.lineno, clause.colno, condition, block))
self.elseifblock(clause)
clause.elseblock = self.elseblock()
return clause
def elseifblock(self, clause):
while self.accept('elif'):
s = self.statement()
self.expect('eol')
b = self.codeblock()
clause.ifs.append(IfNode(s.lineno, s.colno, s, b))
def elseblock(self):
if self.accept('else'):
self.expect('eol')
return self.codeblock()
def line(self):
block_start = self.current
if self.current == 'eol':
return EmptyNode(self.current.lineno, self.current.colno)
if self.accept('if'):
block = self.ifblock()
self.block_expect('endif', block_start)
return block
if self.accept('foreach'):
block = self.foreachblock()
self.block_expect('endforeach', block_start)
return block
if self.accept('continue'):
return ContinueNode(self.current)
if self.accept('break'):
return BreakNode(self.current)
return self.statement()
def codeblock(self):
block = CodeBlockNode(self.current)
cond = True
while cond:
curline = self.line()
if not isinstance(curline, EmptyNode):
block.lines.append(curline)
cond = self.accept('eol')
return block