path: root/prolog/util.py

#!/usr/bin/python3

from collections import namedtuple

from .lexer import lexer, operators

# Stores a token's type and value, and optionally the position of the first
# character in the lexed stream.
class Token(namedtuple('Token', ['type', 'val', 'pos', 'rule', 'part', 'stop'])):
    __slots__ = ()

    # Custom constructor to support default parameters.
    def __new__(cls, type, val='', pos=None, rule=None, part=None, stop=False):
        return super(Token, cls).__new__(cls, type, val, pos, rule, part, stop)

    def __str__(self):
        return self.val

    # Only consider type and value when comparing tokens. There is probably a
    # cleaner way of doing this.
    __eq__ = lambda x, y: x[0] == y[0] and x[1] == y[1]
    __ne__ = lambda x, y: x[0] != y[0] or x[1] != y[1]
    __lt__ = lambda x, y: tuple.__lt__(x[0:2], y[0:2])
    __le__ = lambda x, y: tuple.__le__(x[0:2], y[0:2])
    __ge__ = lambda x, y: tuple.__ge__(x[0:2], y[0:2])
    __gt__ = lambda x, y: tuple.__gt__(x[0:2], y[0:2])

    # Only hash token's value (we don't care about position, and types are
    # determined by values).
    def __hash__(self):
        return hash(self[1])

    # Return a copy of this token, possibly modifying some fields.
    def clone(self, type=None, val=None, pos=None, rule=None, part=None, stop=None):
        return Token(self.type if type is None else type,
                     self.val if val is None else val,
                     self.pos if pos is None else pos,
                     self.rule if rule is None else rule,
                     self.part if part is None else part,
                     self.stop if stop is None else stop)

# Return a list of tokens in [text].
def tokenize(text):
    lexer.input(text)
    return [Token(t.type, t.value, t.lexpos) for t in lexer]

# Return a one-line string representation of [tokens].
def stringify(tokens):
    def token_str(t):
        if t.type in ('PERIOD', 'COMMA'):
            return str(t) + ' '
        if t.type in operators.values():
            return ' ' + str(t) + ' '
        return str(t)
    return ''.join(map(token_str, tokens))

# Yield the sequence of rules in [code].
def split(code):
    tokens = tokenize(code)
    start = 0
    for idx, token in enumerate(tokens):
        if token.type == 'PERIOD' and idx - start > 1:
            yield stringify(tokens[start:idx])
            start = idx + 1

# Lex [code] into tokens with rule indexes and stop markers.
def annotate(code):
    rule = 0
    part = 0
    parens = []        # stack of currently open parens/brackets/braces
    in_parens = 0      # COMMA means a new part if this is 0

    token = None
    lexer.input(code)
    for t in lexer:
        tok_rule = rule
        tok_part = part
        tok_stop = True

        if t.type == 'PERIOD':  # .
            rule += 1
            part = 0
            in_parens = 0
            parens = []
        elif t.type in ('FROM', 'SEMI'):  # :- ;
            part += 1
        elif t.type == 'COMMA':  # ,
            if not parens or in_parens == 0:
                part += 1
            else:
                tok_stop = False

        # Handle left parens.
        elif t.type == 'LPAREN':  # (
            if token and token.type == 'NAME':  # name(
                tok_stop = False
                parens.append('COMPOUND')
                in_parens += 1
            else:
                parens.append(t.type)  # …, (
        elif t.type == 'LBRACKET':  # [
            tok_stop = False
            parens.append(t.type)
            in_parens += 1
        elif t.type == 'LBRACE':  # {
            parens.append(t.type)

        # Handle right parens.
        elif t.type == 'RPAREN':  # )
            if parens:
                if parens[-1] == 'COMPOUND':  # name(…)
                    tok_stop = False
                    parens.pop()
                    in_parens -= 1
                elif parens[-1] == 'LPAREN':  # (…)
                    parens.pop()
        elif t.type == 'RBRACKET':  # ]
            if parens and parens[-1] == 'LBRACKET':  # […]
                tok_stop = False
                parens.pop()
                in_parens -= 1
        elif t.type == 'RBRACE':  # }
            if parens and parens[-1] == 'LBRACE':  # {…}
                parens.pop()

        # Normal tokens.
        else:
            tok_stop = False

        token = Token(t.type, t.value, t.lexpos, tok_rule, tok_part, tok_stop)
        yield token

# Format a list of annotated [tokens].
def compose(tokens):
    code = ''
    prev = None
    for t in tokens:
        if t.type == 'SEMI':
            code += '\n  '
        if prev and (prev.part != t.part or prev.rule != t.rule):
            code += '\n'
            if t.part:
                code += '  '

        if t.type in ('PERIOD', 'COMMA'):
            code += t.val + ' '
        elif t.type in operators.values():
            code += ' ' + t.val + ' '
        else:
            code += t.val
        prev = t
    return code.strip()

# Rename variables in [tokens] to A0, A1, A2,… in order of appearance.
def rename_vars(tokens, names=None):
    if names is None:
        names = {}
    next_id = len(names)

    # Return a new list.
    tokens = list(tokens)
    for i, t in enumerate(tokens):
        if t.type == 'PERIOD':
            names.clear()
            next_id = 0
        elif t.type == 'VARIABLE':
            if t.val.startswith('_'):
                tokens[i] = t.clone(val='A{}'.format(next_id))
                next_id += 1
            else:
                cur_name = t.val
                if cur_name not in names:
                    names[cur_name] = 'A{}'.format(next_id)
                    next_id += 1
                tokens[i] = t.clone(val=names[cur_name])
    return tokens

# Helper function to remove trailing punctuation from lines and rename
# variables to A1,A2,A3,… (potentially using [var_names]). Return a tuple.
def normalized(line, var_names=None):
    # Remove trailing punctuation.
    i = len(line)
    while i > 0:
        if line[i-1].type not in ('COMMA', 'PERIOD', 'SEMI'):
            break
        i -= 1
    return tuple(rename_vars(line[:i], var_names))

# Map "formal" variable names in the edit a→b to actual names in code [tokens].
# The set [variables] contains all variable names in the current scope. These
# are used in cases such as [A]→[A,B], where the edit introduces new variables.
# Return a new version of b with actual variable names.
def map_vars(a, b, tokens, variables):
    mapping = {}
    new_index = 0
    for i in range(len(a)):
        if tokens[i].type == 'VARIABLE':
            formal_name = a[i].val
            if tokens[i].val != '_':
                actual_name = tokens[i].val
            else:
                actual_name = 'New'+str(new_index)
                new_index += 1
            mapping[formal_name] = actual_name

    remaining_formal = [t.val for t in b if t.type == 'VARIABLE' and t.val not in mapping.keys()]
    remaining_actual = [var for var in variables if var not in mapping.values()]

    while len(remaining_actual) < len(remaining_formal):
        remaining_actual.append('New'+str(new_index))
        new_index += 1

    for i, formal_name in enumerate(remaining_formal):
        mapping[formal_name] = remaining_actual[i]

    return [t if t.type != 'VARIABLE' else t.clone(val=mapping[t.val]) for t in b]

# Basic sanity check.
if __name__ == '__main__':
    var_names = {}
    before = rename_vars(tokenize("dup([A0|A1], [A2|A3])"), var_names)
    after = rename_vars(tokenize("dup([A0|A1], [A5, A4|A3])"), var_names)

    line = lines[0]
    variables = [t.val for t in tokenize(code) if t.type == 'VARIABLE']
    mapped = map_vars(before, after, line, variables)
    print(mapped)