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sshpeer: initial definition and implementation of new SSH protocol...
sshpeer: initial definition and implementation of new SSH protocol The existing SSH protocol has several design flaws. Future commits will elaborate on these flaws as new features are introduced to combat these flaws. For now, hopefully you can take me for my word that a ground up rewrite of the SSH protocol is needed. This commit lays the foundation for a new SSH protocol by defining a mechanism to upgrade the SSH transport channel away from the default (version 1) protocol to something modern (which we'll call "version 2" for now). This upgrade process is detailed in the internals documentation for the wire protocol. The gist of it is the client sends a request line preceding the "hello" command/line which basically says "I'm requesting an upgrade: here's what I support." If the server recognizes that line, it processes the upgrade request and the transport channel is switched to use the new version of the protocol. If not, it sends an empty response, which is how all Mercurial SSH servers from the beginning of time reacted to unknown commands. The upgrade request is effectively ignored and the client continues to use the existing version of the protocol as if nothing happened. The new version of the SSH protocol is completely identical to version 1 aside from the upgrade dance and the bytes that follow. The immediate bytes that follow the protocol switch are defined to be a length framed "capabilities: " line containing the remote's advertised capabilities. In reality, this looks very similar to what the "hello" response would look like. But it will evolve quickly. The methodology by which the protocol will evolve is important. I'm not going to introduce the new protocol all at once. That would likely lead to endless bike shedding and forward progress would stall. Instead, I intend to tricle out new features and diversions from the existing protocol in small, incremental changes. To support the gradual evolution of the protocol, the on-the-wire advertised protocol name contains an "exp" to denote "experimental" and a 4 digit field to capture the sub-version of the protocol. Whenever we make a BC change to the wire protocol, we can increment this version and lock out all older clients because it will appear as a completely different protocol version. This means we can incur as many breaking changes as we want. We don't have to commit to supporting any one feature or idea for a long period of time. We can even evolve the handshake mechanism, because that is defined as being an implementation detail of the negotiated protocol version! Hopefully this lowers the barrier to accepting changes to the protocol and for experimenting with "radical" ideas during its development. In core, sshpeer received most of the attention. We haven't even implemented the server bits for the new protocol in core yet. Instead, we add very primitive support to our test server, mainly just to exercise the added code paths in sshpeer. Differential Revision: https://phab.mercurial-scm.org/D2061 # no-check-commit because of required foo_bar naming
Yuya Nishihara - - Load All Authors

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revsetlang.py
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# revsetlang.py - parser, tokenizer and utility for revision set language
#
# Copyright 2010 Matt Mackall <mpm@selenic.com>
#
# This software may be used and distributed according to the terms of the
# GNU General Public License version 2 or any later version.
from __future__ import absolute_import
import string
from .i18n import _
from . import (
error,
node,
parser,
pycompat,
util,
)
elements = {
# token-type: binding-strength, primary, prefix, infix, suffix
"(": (21, None, ("group", 1, ")"), ("func", 1, ")"), None),
"[": (21, None, None, ("subscript", 1, "]"), None),
"#": (21, None, None, ("relation", 21), None),
"##": (20, None, None, ("_concat", 20), None),
"~": (18, None, None, ("ancestor", 18), None),
"^": (18, None, None, ("parent", 18), "parentpost"),
"-": (5, None, ("negate", 19), ("minus", 5), None),
"::": (17, "dagrangeall", ("dagrangepre", 17), ("dagrange", 17),
"dagrangepost"),
"..": (17, "dagrangeall", ("dagrangepre", 17), ("dagrange", 17),
"dagrangepost"),
":": (15, "rangeall", ("rangepre", 15), ("range", 15), "rangepost"),
"not": (10, None, ("not", 10), None, None),
"!": (10, None, ("not", 10), None, None),
"and": (5, None, None, ("and", 5), None),
"&": (5, None, None, ("and", 5), None),
"%": (5, None, None, ("only", 5), "onlypost"),
"or": (4, None, None, ("or", 4), None),
"|": (4, None, None, ("or", 4), None),
"+": (4, None, None, ("or", 4), None),
"=": (3, None, None, ("keyvalue", 3), None),
",": (2, None, None, ("list", 2), None),
")": (0, None, None, None, None),
"]": (0, None, None, None, None),
"symbol": (0, "symbol", None, None, None),
"string": (0, "string", None, None, None),
"end": (0, None, None, None, None),
}
keywords = {'and', 'or', 'not'}
symbols = {}
_quoteletters = {'"', "'"}
_simpleopletters = set(pycompat.iterbytestr("()[]#:=,-|&+!~^%"))
# default set of valid characters for the initial letter of symbols
_syminitletters = set(pycompat.iterbytestr(
string.ascii_letters.encode('ascii') +
string.digits.encode('ascii') +
'._@')) | set(map(pycompat.bytechr, xrange(128, 256)))
# default set of valid characters for non-initial letters of symbols
_symletters = _syminitletters | set(pycompat.iterbytestr('-/'))
def tokenize(program, lookup=None, syminitletters=None, symletters=None):
'''
Parse a revset statement into a stream of tokens
``syminitletters`` is the set of valid characters for the initial
letter of symbols.
By default, character ``c`` is recognized as valid for initial
letter of symbols, if ``c.isalnum() or c in '._@' or ord(c) > 127``.
``symletters`` is the set of valid characters for non-initial
letters of symbols.
By default, character ``c`` is recognized as valid for non-initial
letters of symbols, if ``c.isalnum() or c in '-._/@' or ord(c) > 127``.
Check that @ is a valid unquoted token character (issue3686):
>>> list(tokenize(b"@::"))
[('symbol', '@', 0), ('::', None, 1), ('end', None, 3)]
'''
program = pycompat.bytestr(program)
if syminitletters is None:
syminitletters = _syminitletters
if symletters is None:
symletters = _symletters
if program and lookup:
# attempt to parse old-style ranges first to deal with
# things like old-tag which contain query metacharacters
parts = program.split(':', 1)
if all(lookup(sym) for sym in parts if sym):
if parts[0]:
yield ('symbol', parts[0], 0)
if len(parts) > 1:
s = len(parts[0])
yield (':', None, s)
if parts[1]:
yield ('symbol', parts[1], s + 1)
yield ('end', None, len(program))
return
pos, l = 0, len(program)
while pos < l:
c = program[pos]
if c.isspace(): # skip inter-token whitespace
pass
elif c == ':' and program[pos:pos + 2] == '::': # look ahead carefully
yield ('::', None, pos)
pos += 1 # skip ahead
elif c == '.' and program[pos:pos + 2] == '..': # look ahead carefully
yield ('..', None, pos)
pos += 1 # skip ahead
elif c == '#' and program[pos:pos + 2] == '##': # look ahead carefully
yield ('##', None, pos)
pos += 1 # skip ahead
elif c in _simpleopletters: # handle simple operators
yield (c, None, pos)
elif (c in _quoteletters or c == 'r' and
program[pos:pos + 2] in ("r'", 'r"')): # handle quoted strings
if c == 'r':
pos += 1
c = program[pos]
decode = lambda x: x
else:
decode = parser.unescapestr
pos += 1
s = pos
while pos < l: # find closing quote
d = program[pos]
if d == '\\': # skip over escaped characters
pos += 2
continue
if d == c:
yield ('string', decode(program[s:pos]), s)
break
pos += 1
else:
raise error.ParseError(_("unterminated string"), s)
# gather up a symbol/keyword
elif c in syminitletters:
s = pos
pos += 1
while pos < l: # find end of symbol
d = program[pos]
if d not in symletters:
break
if d == '.' and program[pos - 1] == '.': # special case for ..
pos -= 1
break
pos += 1
sym = program[s:pos]
if sym in keywords: # operator keywords
yield (sym, None, s)
elif '-' in sym:
# some jerk gave us foo-bar-baz, try to check if it's a symbol
if lookup and lookup(sym):
# looks like a real symbol
yield ('symbol', sym, s)
else:
# looks like an expression
parts = sym.split('-')
for p in parts[:-1]:
if p: # possible consecutive -
yield ('symbol', p, s)
s += len(p)
yield ('-', None, pos)
s += 1
if parts[-1]: # possible trailing -
yield ('symbol', parts[-1], s)
else:
yield ('symbol', sym, s)
pos -= 1
else:
raise error.ParseError(_("syntax error in revset '%s'") %
program, pos)
pos += 1
yield ('end', None, pos)
# helpers
_notset = object()
def getsymbol(x):
if x and x[0] == 'symbol':
return x[1]
raise error.ParseError(_('not a symbol'))
def getstring(x, err):
if x and (x[0] == 'string' or x[0] == 'symbol'):
return x[1]
raise error.ParseError(err)
def getinteger(x, err, default=_notset):
if not x and default is not _notset:
return default
try:
return int(getstring(x, err))
except ValueError:
raise error.ParseError(err)
def getboolean(x, err):
value = util.parsebool(getsymbol(x))
if value is not None:
return value
raise error.ParseError(err)
def getlist(x):
if not x:
return []
if x[0] == 'list':
return list(x[1:])
return [x]
def getrange(x, err):
if not x:
raise error.ParseError(err)
op = x[0]
if op == 'range':
return x[1], x[2]
elif op == 'rangepre':
return None, x[1]
elif op == 'rangepost':
return x[1], None
elif op == 'rangeall':
return None, None
raise error.ParseError(err)
def getargs(x, min, max, err):
l = getlist(x)
if len(l) < min or (max >= 0 and len(l) > max):
raise error.ParseError(err)
return l
def getargsdict(x, funcname, keys):
return parser.buildargsdict(getlist(x), funcname, parser.splitargspec(keys),
keyvaluenode='keyvalue', keynode='symbol')
# cache of {spec: raw parsed tree} built internally
_treecache = {}
def _cachedtree(spec):
# thread safe because parse() is reentrant and dict.__setitem__() is atomic
tree = _treecache.get(spec)
if tree is None:
_treecache[spec] = tree = parse(spec)
return tree
def _build(tmplspec, *repls):
"""Create raw parsed tree from a template revset statement
>>> _build(b'f(_) and _', (b'string', b'1'), (b'symbol', b'2'))
('and', ('func', ('symbol', 'f'), ('string', '1')), ('symbol', '2'))
"""
template = _cachedtree(tmplspec)
return parser.buildtree(template, ('symbol', '_'), *repls)
def _match(patspec, tree):
"""Test if a tree matches the given pattern statement; return the matches
>>> _match(b'f(_)', parse(b'f()'))
>>> _match(b'f(_)', parse(b'f(1)'))
[('func', ('symbol', 'f'), ('symbol', '1')), ('symbol', '1')]
>>> _match(b'f(_)', parse(b'f(1, 2)'))
"""
pattern = _cachedtree(patspec)
return parser.matchtree(pattern, tree, ('symbol', '_'),
{'keyvalue', 'list'})
def _matchonly(revs, bases):
return _match('ancestors(_) and not ancestors(_)', ('and', revs, bases))
def _fixops(x):
"""Rewrite raw parsed tree to resolve ambiguous syntax which cannot be
handled well by our simple top-down parser"""
if not isinstance(x, tuple):
return x
op = x[0]
if op == 'parent':
# x^:y means (x^) : y, not x ^ (:y)
# x^: means (x^) :, not x ^ (:)
post = ('parentpost', x[1])
if x[2][0] == 'dagrangepre':
return _fixops(('dagrange', post, x[2][1]))
elif x[2][0] == 'dagrangeall':
return _fixops(('dagrangepost', post))
elif x[2][0] == 'rangepre':
return _fixops(('range', post, x[2][1]))
elif x[2][0] == 'rangeall':
return _fixops(('rangepost', post))
elif op == 'or':
# make number of arguments deterministic:
# x + y + z -> (or x y z) -> (or (list x y z))
return (op, _fixops(('list',) + x[1:]))
elif op == 'subscript' and x[1][0] == 'relation':
# x#y[z] ternary
return _fixops(('relsubscript', x[1][1], x[1][2], x[2]))
return (op,) + tuple(_fixops(y) for y in x[1:])
def _analyze(x):
if x is None:
return x
op = x[0]
if op == 'minus':
return _analyze(_build('_ and not _', *x[1:]))
elif op == 'only':
return _analyze(_build('only(_, _)', *x[1:]))
elif op == 'onlypost':
return _analyze(_build('only(_)', x[1]))
elif op == 'dagrangeall':
raise error.ParseError(_("can't use '::' in this context"))
elif op == 'dagrangepre':
return _analyze(_build('ancestors(_)', x[1]))
elif op == 'dagrangepost':
return _analyze(_build('descendants(_)', x[1]))
elif op == 'negate':
s = getstring(x[1], _("can't negate that"))
return _analyze(('string', '-' + s))
elif op in ('string', 'symbol'):
return x
elif op == 'rangeall':
return (op, None)
elif op in {'or', 'not', 'rangepre', 'rangepost', 'parentpost'}:
return (op, _analyze(x[1]))
elif op == 'group':
return _analyze(x[1])
elif op in {'and', 'dagrange', 'range', 'parent', 'ancestor', 'relation',
'subscript'}:
ta = _analyze(x[1])
tb = _analyze(x[2])
return (op, ta, tb)
elif op == 'relsubscript':
ta = _analyze(x[1])
tb = _analyze(x[2])
tc = _analyze(x[3])
return (op, ta, tb, tc)
elif op == 'list':
return (op,) + tuple(_analyze(y) for y in x[1:])
elif op == 'keyvalue':
return (op, x[1], _analyze(x[2]))
elif op == 'func':
return (op, x[1], _analyze(x[2]))
raise ValueError('invalid operator %r' % op)
def analyze(x):
"""Transform raw parsed tree to evaluatable tree which can be fed to
optimize() or getset()
All pseudo operations should be mapped to real operations or functions
defined in methods or symbols table respectively.
"""
return _analyze(x)
def _optimize(x):
if x is None:
return 0, x
op = x[0]
if op in ('string', 'symbol'):
return 0.5, x # single revisions are small
elif op == 'and':
wa, ta = _optimize(x[1])
wb, tb = _optimize(x[2])
w = min(wa, wb)
# (draft/secret/_notpublic() & ::x) have a fast path
m = _match('_() & ancestors(_)', ('and', ta, tb))
if m and getsymbol(m[1]) in {'draft', 'secret', '_notpublic'}:
return w, _build('_phaseandancestors(_, _)', m[1], m[2])
# (::x and not ::y)/(not ::y and ::x) have a fast path
m = _matchonly(ta, tb) or _matchonly(tb, ta)
if m:
return w, _build('only(_, _)', *m[1:])
m = _match('not _', tb)
if m:
return wa, ('difference', ta, m[1])
if wa > wb:
op = 'andsmally'
return w, (op, ta, tb)
elif op == 'or':
# fast path for machine-generated expression, that is likely to have
# lots of trivial revisions: 'a + b + c()' to '_list(a b) + c()'
ws, ts, ss = [], [], []
def flushss():
if not ss:
return
if len(ss) == 1:
w, t = ss[0]
else:
s = '\0'.join(t[1] for w, t in ss)
y = _build('_list(_)', ('string', s))
w, t = _optimize(y)
ws.append(w)
ts.append(t)
del ss[:]
for y in getlist(x[1]):
w, t = _optimize(y)
if t is not None and (t[0] == 'string' or t[0] == 'symbol'):
ss.append((w, t))
continue
flushss()
ws.append(w)
ts.append(t)
flushss()
if len(ts) == 1:
return ws[0], ts[0] # 'or' operation is fully optimized out
return max(ws), (op, ('list',) + tuple(ts))
elif op == 'not':
# Optimize not public() to _notpublic() because we have a fast version
if _match('public()', x[1]):
o = _optimize(_build('_notpublic()'))
return o[0], o[1]
else:
o = _optimize(x[1])
return o[0], (op, o[1])
elif op == 'rangeall':
return 1, x
elif op in ('rangepre', 'rangepost', 'parentpost'):
o = _optimize(x[1])
return o[0], (op, o[1])
elif op in ('dagrange', 'range'):
wa, ta = _optimize(x[1])
wb, tb = _optimize(x[2])
return wa + wb, (op, ta, tb)
elif op in ('parent', 'ancestor', 'relation', 'subscript'):
w, t = _optimize(x[1])
return w, (op, t, x[2])
elif op == 'relsubscript':
w, t = _optimize(x[1])
return w, (op, t, x[2], x[3])
elif op == 'list':
ws, ts = zip(*(_optimize(y) for y in x[1:]))
return sum(ws), (op,) + ts
elif op == 'keyvalue':
w, t = _optimize(x[2])
return w, (op, x[1], t)
elif op == 'func':
f = getsymbol(x[1])
wa, ta = _optimize(x[2])
w = getattr(symbols.get(f), '_weight', 1)
return w + wa, (op, x[1], ta)
raise ValueError('invalid operator %r' % op)
def optimize(tree):
"""Optimize evaluatable tree
All pseudo operations should be transformed beforehand.
"""
_weight, newtree = _optimize(tree)
return newtree
# the set of valid characters for the initial letter of symbols in
# alias declarations and definitions
_aliassyminitletters = _syminitletters | {'$'}
def _parsewith(spec, lookup=None, syminitletters=None):
"""Generate a parse tree of given spec with given tokenizing options
>>> _parsewith(b'foo($1)', syminitletters=_aliassyminitletters)
('func', ('symbol', 'foo'), ('symbol', '$1'))
>>> _parsewith(b'$1')
Traceback (most recent call last):
...
ParseError: ("syntax error in revset '$1'", 0)
>>> _parsewith(b'foo bar')
Traceback (most recent call last):
...
ParseError: ('invalid token', 4)
"""
p = parser.parser(elements)
tree, pos = p.parse(tokenize(spec, lookup=lookup,
syminitletters=syminitletters))
if pos != len(spec):
raise error.ParseError(_('invalid token'), pos)
return _fixops(parser.simplifyinfixops(tree, ('list', 'or')))
class _aliasrules(parser.basealiasrules):
"""Parsing and expansion rule set of revset aliases"""
_section = _('revset alias')
@staticmethod
def _parse(spec):
"""Parse alias declaration/definition ``spec``
This allows symbol names to use also ``$`` as an initial letter
(for backward compatibility), and callers of this function should
examine whether ``$`` is used also for unexpected symbols or not.
"""
return _parsewith(spec, syminitletters=_aliassyminitletters)
@staticmethod
def _trygetfunc(tree):
if tree[0] == 'func' and tree[1][0] == 'symbol':
return tree[1][1], getlist(tree[2])
def expandaliases(tree, aliases, warn=None):
"""Expand aliases in a tree, aliases is a list of (name, value) tuples"""
aliases = _aliasrules.buildmap(aliases)
tree = _aliasrules.expand(aliases, tree)
# warn about problematic (but not referred) aliases
if warn is not None:
for name, alias in sorted(aliases.iteritems()):
if alias.error and not alias.warned:
warn(_('warning: %s\n') % (alias.error))
alias.warned = True
return tree
def foldconcat(tree):
"""Fold elements to be concatenated by `##`
"""
if not isinstance(tree, tuple) or tree[0] in ('string', 'symbol'):
return tree
if tree[0] == '_concat':
pending = [tree]
l = []
while pending:
e = pending.pop()
if e[0] == '_concat':
pending.extend(reversed(e[1:]))
elif e[0] in ('string', 'symbol'):
l.append(e[1])
else:
msg = _("\"##\" can't concatenate \"%s\" element") % (e[0])
raise error.ParseError(msg)
return ('string', ''.join(l))
else:
return tuple(foldconcat(t) for t in tree)
def parse(spec, lookup=None):
return _parsewith(spec, lookup=lookup)
def _quote(s):
r"""Quote a value in order to make it safe for the revset engine.
>>> _quote(b'asdf')
"'asdf'"
>>> _quote(b"asdf'\"")
'\'asdf\\\'"\''
>>> _quote(b'asdf\'')
"'asdf\\''"
>>> _quote(1)
"'1'"
"""
return "'%s'" % util.escapestr(pycompat.bytestr(s))
def _formatargtype(c, arg):
if c == 'd':
return '%d' % int(arg)
elif c == 's':
return _quote(arg)
elif c == 'r':
parse(arg) # make sure syntax errors are confined
return '(%s)' % arg
elif c == 'n':
return _quote(node.hex(arg))
elif c == 'b':
try:
return _quote(arg.branch())
except AttributeError:
raise TypeError
raise error.ParseError(_('unexpected revspec format character %s') % c)
def _formatlistexp(s, t):
l = len(s)
if l == 0:
return "_list('')"
elif l == 1:
return _formatargtype(t, s[0])
elif t == 'd':
return "_intlist('%s')" % "\0".join('%d' % int(a) for a in s)
elif t == 's':
return "_list(%s)" % _quote("\0".join(s))
elif t == 'n':
return "_hexlist('%s')" % "\0".join(node.hex(a) for a in s)
elif t == 'b':
try:
return "_list('%s')" % "\0".join(a.branch() for a in s)
except AttributeError:
raise TypeError
m = l // 2
return '(%s or %s)' % (_formatlistexp(s[:m], t), _formatlistexp(s[m:], t))
def _formatparamexp(args, t):
return ', '.join(_formatargtype(t, a) for a in args)
_formatlistfuncs = {
'l': _formatlistexp,
'p': _formatparamexp,
}
def formatspec(expr, *args):
'''
This is a convenience function for using revsets internally, and
escapes arguments appropriately. Aliases are intentionally ignored
so that intended expression behavior isn't accidentally subverted.
Supported arguments:
%r = revset expression, parenthesized
%d = int(arg), no quoting
%s = string(arg), escaped and single-quoted
%b = arg.branch(), escaped and single-quoted
%n = hex(arg), single-quoted
%% = a literal '%'
Prefixing the type with 'l' specifies a parenthesized list of that type,
and 'p' specifies a list of function parameters of that type.
>>> formatspec(b'%r:: and %lr', b'10 or 11', (b"this()", b"that()"))
'(10 or 11):: and ((this()) or (that()))'
>>> formatspec(b'%d:: and not %d::', 10, 20)
'10:: and not 20::'
>>> formatspec(b'%ld or %ld', [], [1])
"_list('') or 1"
>>> formatspec(b'keyword(%s)', b'foo\\xe9')
"keyword('foo\\\\xe9')"
>>> b = lambda: b'default'
>>> b.branch = b
>>> formatspec(b'branch(%b)', b)
"branch('default')"
>>> formatspec(b'root(%ls)', [b'a', b'b', b'c', b'd'])
"root(_list('a\\\\x00b\\\\x00c\\\\x00d'))"
>>> formatspec(b'sort(%r, %ps)', b':', [b'desc', b'user'])
"sort((:), 'desc', 'user')"
>>> formatspec(b'%ls', [b'a', b"'"])
"_list('a\\\\x00\\\\'')"
'''
expr = pycompat.bytestr(expr)
argiter = iter(args)
ret = []
pos = 0
while pos < len(expr):
q = expr.find('%', pos)
if q < 0:
ret.append(expr[pos:])
break
ret.append(expr[pos:q])
pos = q + 1
try:
d = expr[pos]
except IndexError:
raise error.ParseError(_('incomplete revspec format character'))
if d == '%':
ret.append(d)
pos += 1
continue
try:
arg = next(argiter)
except StopIteration:
raise error.ParseError(_('missing argument for revspec'))
f = _formatlistfuncs.get(d)
if f:
# a list of some type
pos += 1
try:
d = expr[pos]
except IndexError:
raise error.ParseError(_('incomplete revspec format character'))
try:
ret.append(f(list(arg), d))
except (TypeError, ValueError):
raise error.ParseError(_('invalid argument for revspec'))
else:
try:
ret.append(_formatargtype(d, arg))
except (TypeError, ValueError):
raise error.ParseError(_('invalid argument for revspec'))
pos += 1
try:
next(argiter)
raise error.ParseError(_('too many revspec arguments specified'))
except StopIteration:
pass
return ''.join(ret)
def prettyformat(tree):
return parser.prettyformat(tree, ('string', 'symbol'))
def depth(tree):
if isinstance(tree, tuple):
return max(map(depth, tree)) + 1
else:
return 0
def funcsused(tree):
if not isinstance(tree, tuple) or tree[0] in ('string', 'symbol'):
return set()
else:
funcs = set()
for s in tree[1:]:
funcs |= funcsused(s)
if tree[0] == 'func':
funcs.add(tree[1][1])
return funcs
_hashre = util.re.compile('[0-9a-fA-F]{1,40}$')
def _ishashlikesymbol(symbol):
"""returns true if the symbol looks like a hash"""
return _hashre.match(symbol)
def gethashlikesymbols(tree):
"""returns the list of symbols of the tree that look like hashes
>>> gethashlikesymbols(parse(b'3::abe3ff'))
['3', 'abe3ff']
>>> gethashlikesymbols(parse(b'precursors(.)'))
[]
>>> gethashlikesymbols(parse(b'precursors(34)'))
['34']
>>> gethashlikesymbols(parse(b'abe3ffZ'))
[]
"""
if not tree:
return []
if tree[0] == "symbol":
if _ishashlikesymbol(tree[1]):
return [tree[1]]
elif len(tree) >= 3:
results = []
for subtree in tree[1:]:
results += gethashlikesymbols(subtree)
return results
return []