import logging from itertools import * # noqa from jsonpath_ng.lexer import JsonPathLexer # Get logger name logger = logging.getLogger(__name__) # Turn on/off the automatic creation of id attributes # ... could be a kwarg pervasively but uses are rare and simple today auto_id_field = None NOT_SET = object() LIST_KEY = object() class JSONPath: """ The base class for JSONPath abstract syntax; those methods stubbed here are the interface to supported JSONPath semantics. """ def find(self, data): """ All `JSONPath` types support `find()`, which returns an iterable of `DatumInContext`s. They keep track of the path followed to the current location, so if the calling code has some opinion about that, it can be passed in here as a starting point. """ raise NotImplementedError() def find_or_create(self, data): return self.find(data) def update(self, data, val): """ Returns `data` with the specified path replaced by `val`. Only updates if the specified path exists. """ raise NotImplementedError() def update_or_create(self, data, val): return self.update(data, val) def filter(self, fn, data): """ Returns `data` with the specified path filtering nodes according the filter evaluation result returned by the filter function. Arguments: fn (function): unary function that accepts one argument and returns bool. data (dict|list|tuple): JSON object to filter. """ raise NotImplementedError() def child(self, child): """ Equivalent to Child(self, next) but with some canonicalization """ if isinstance(self, This) or isinstance(self, Root): return child elif isinstance(child, This): return self elif isinstance(child, Root): return child else: return Child(self, child) def make_datum(self, value): if isinstance(value, DatumInContext): return value else: return DatumInContext(value, path=Root(), context=None) class DatumInContext: """ Represents a datum along a path from a context. Essentially a zipper but with a structure represented by JsonPath, and where the context is more of a parent pointer than a proper representation of the context. For quick-and-dirty work, this proxies any non-special attributes to the underlying datum, but the actual datum can (and usually should) be retrieved via the `value` attribute. To place `datum` within another, use `datum.in_context(context=..., path=...)` which extends the path. If the datum already has a context, it places the entire context within that passed in, so an object can be built from the inside out. """ @classmethod def wrap(cls, data): if isinstance(data, cls): return data else: return cls(data) def __init__(self, value, path=None, context=None): self.value = value self.path = path or This() self.context = None if context is None else DatumInContext.wrap(context) def in_context(self, context, path): context = DatumInContext.wrap(context) if self.context: return DatumInContext(value=self.value, path=self.path, context=context.in_context(path=path, context=context)) else: return DatumInContext(value=self.value, path=path, context=context) @property def full_path(self): return self.path if self.context is None else self.context.full_path.child(self.path) @property def id_pseudopath(self): """ Looks like a path, but with ids stuck in when available """ try: pseudopath = Fields(str(self.value[auto_id_field])) except (TypeError, AttributeError, KeyError): # This may not be all the interesting exceptions pseudopath = self.path if self.context: return self.context.id_pseudopath.child(pseudopath) else: return pseudopath def __repr__(self): return '%s(value=%r, path=%r, context=%r)' % (self.__class__.__name__, self.value, self.path, self.context) def __eq__(self, other): return isinstance(other, DatumInContext) and other.value == self.value and other.path == self.path and self.context == other.context class AutoIdForDatum(DatumInContext): """ This behaves like a DatumInContext, but the value is always the path leading up to it, not including the "id", and with any "id" fields along the way replacing the prior segment of the path For example, it will make "foo.bar.id" return a datum that behaves like DatumInContext(value="foo.bar", path="foo.bar.id"). This is disabled by default; it can be turned on by settings the `auto_id_field` global to a value other than `None`. """ def __init__(self, datum, id_field=None): """ Invariant is that datum.path is the path from context to datum. The auto id will either be the id in the datum (if present) or the id of the context followed by the path to the datum. The path to this datum is always the path to the context, the path to the datum, and then the auto id field. """ self.datum = datum self.id_field = id_field or auto_id_field @property def value(self): return str(self.datum.id_pseudopath) @property def path(self): return self.id_field @property def context(self): return self.datum def __repr__(self): return '%s(%r)' % (self.__class__.__name__, self.datum) def in_context(self, context, path): return AutoIdForDatum(self.datum.in_context(context=context, path=path)) def __eq__(self, other): return isinstance(other, AutoIdForDatum) and other.datum == self.datum and self.id_field == other.id_field class Root(JSONPath): """ The JSONPath referring to the "root" object. Concrete syntax is '$'. The root is the topmost datum without any context attached. """ def find(self, data): if not isinstance(data, DatumInContext): return [DatumInContext(data, path=Root(), context=None)] else: if data.context is None: return [DatumInContext(data.value, context=None, path=Root())] else: return Root().find(data.context) def update(self, data, val): return val def filter(self, fn, data): return data if fn(data) else None def __str__(self): return '$' def __repr__(self): return 'Root()' def __eq__(self, other): return isinstance(other, Root) def __hash__(self): return hash('$') class This(JSONPath): """ The JSONPath referring to the current datum. Concrete syntax is '@'. """ def find(self, datum): return [DatumInContext.wrap(datum)] def update(self, data, val): return val def filter(self, fn, data): return data if fn(data) else None def __str__(self): return '`this`' def __repr__(self): return 'This()' def __eq__(self, other): return isinstance(other, This) def __hash__(self): return hash('this') class Child(JSONPath): """ JSONPath that first matches the left, then the right. Concrete syntax is '.' """ def __init__(self, left, right): self.left = left self.right = right def find(self, datum): """ Extra special case: auto ids do not have children, so cut it off right now rather than auto id the auto id """ return [submatch for subdata in self.left.find(datum) if not isinstance(subdata, AutoIdForDatum) for submatch in self.right.find(subdata)] def update(self, data, val): for datum in self.left.find(data): self.right.update(datum.value, val) return data def find_or_create(self, datum): datum = DatumInContext.wrap(datum) submatches = [] for subdata in self.left.find_or_create(datum): if isinstance(subdata, AutoIdForDatum): # Extra special case: auto ids do not have children, # so cut it off right now rather than auto id the auto id continue for submatch in self.right.find_or_create(subdata): submatches.append(submatch) return submatches def update_or_create(self, data, val): for datum in self.left.find_or_create(data): self.right.update_or_create(datum.value, val) return _clean_list_keys(data) def filter(self, fn, data): for datum in self.left.find(data): self.right.filter(fn, datum.value) return data def __eq__(self, other): return isinstance(other, Child) and self.left == other.left and self.right == other.right def __str__(self): return '%s.%s' % (self.left, self.right) def __repr__(self): return '%s(%r, %r)' % (self.__class__.__name__, self.left, self.right) def __hash__(self): return hash((self.left, self.right)) class Parent(JSONPath): """ JSONPath that matches the parent node of the current match. Will crash if no such parent exists. Available via named operator `parent`. """ def find(self, datum): datum = DatumInContext.wrap(datum) return [datum.context] def __eq__(self, other): return isinstance(other, Parent) def __str__(self): return '`parent`' def __repr__(self): return 'Parent()' def __hash__(self): return hash('parent') class Where(JSONPath): """ JSONPath that first matches the left, and then filters for only those nodes that have a match on the right. WARNING: Subject to change. May want to have "contains" or some other better word for it. """ def __init__(self, left, right): self.left = left self.right = right def find(self, data): return [subdata for subdata in self.left.find(data) if self.right.find(subdata)] def update(self, data, val): for datum in self.find(data): datum.path.update(data, val) return data def filter(self, fn, data): for datum in self.find(data): datum.path.filter(fn, datum.value) return data def __str__(self): return '%s where %s' % (self.left, self.right) def __eq__(self, other): return isinstance(other, Where) and other.left == self.left and other.right == self.right def __hash__(self): return hash((self.left, self.right)) class WhereNot(Where): """ Identical to ``Where``, but filters for only those nodes that do *not* have a match on the right. >>> jsonpath = WhereNot(Fields('spam'), Fields('spam')) >>> jsonpath.find({"spam": {"spam": 1}}) [] >>> matches = jsonpath.find({"spam": 1}) >>> matches[0].value 1 """ def find(self, data): return [subdata for subdata in self.left.find(data) if not self.right.find(subdata)] def __str__(self): return '%s wherenot %s' % (self.left, self.right) def __eq__(self, other): return (isinstance(other, WhereNot) and other.left == self.left and other.right == self.right) def __hash__(self): return hash((self.left, self.right)) class Descendants(JSONPath): """ JSONPath that matches first the left expression then any descendant of it which matches the right expression. """ def __init__(self, left, right): self.left = left self.right = right def find(self, datum): # .. ==> . ( | *.. | [*]..) # # With with a wonky caveat that since Slice() has funky coercions # we cannot just delegate to that equivalence or we'll hit an # infinite loop. So right here we implement the coercion-free version. # Get all left matches into a list left_matches = self.left.find(datum) if not isinstance(left_matches, list): left_matches = [left_matches] def match_recursively(datum): right_matches = self.right.find(datum) # Manually do the * or [*] to avoid coercion and recurse just the right-hand pattern if isinstance(datum.value, list): recursive_matches = [submatch for i in range(0, len(datum.value)) for submatch in match_recursively(DatumInContext(datum.value[i], context=datum, path=Index(i)))] elif isinstance(datum.value, dict): recursive_matches = [submatch for field in datum.value.keys() for submatch in match_recursively(DatumInContext(datum.value[field], context=datum, path=Fields(field)))] else: recursive_matches = [] return right_matches + list(recursive_matches) # TODO: repeatable iterator instead of list? return [submatch for left_match in left_matches for submatch in match_recursively(left_match)] def is_singular(self): return False def update(self, data, val): # Get all left matches into a list left_matches = self.left.find(data) if not isinstance(left_matches, list): left_matches = [left_matches] def update_recursively(data): # Update only mutable values corresponding to JSON types if not (isinstance(data, list) or isinstance(data, dict)): return self.right.update(data, val) # Manually do the * or [*] to avoid coercion and recurse just the right-hand pattern if isinstance(data, list): for i in range(0, len(data)): update_recursively(data[i]) elif isinstance(data, dict): for field in data.keys(): update_recursively(data[field]) for submatch in left_matches: update_recursively(submatch.value) return data def filter(self, fn, data): # Get all left matches into a list left_matches = self.left.find(data) if not isinstance(left_matches, list): left_matches = [left_matches] def filter_recursively(data): # Update only mutable values corresponding to JSON types if not (isinstance(data, list) or isinstance(data, dict)): return self.right.filter(fn, data) # Manually do the * or [*] to avoid coercion and recurse just the right-hand pattern if isinstance(data, list): for i in range(0, len(data)): filter_recursively(data[i]) elif isinstance(data, dict): for field in data.keys(): filter_recursively(data[field]) for submatch in left_matches: filter_recursively(submatch.value) return data def __str__(self): return '%s..%s' % (self.left, self.right) def __eq__(self, other): return isinstance(other, Descendants) and self.left == other.left and self.right == other.right def __repr__(self): return '%s(%r, %r)' % (self.__class__.__name__, self.left, self.right) def __hash__(self): return hash((self.left, self.right)) class Union(JSONPath): """ JSONPath that returns the union of the results of each match. This is pretty shoddily implemented for now. The nicest semantics in case of mismatched bits (list vs atomic) is to put them all in a list, but I haven't done that yet. WARNING: Any appearance of this being the _concatenation_ is coincidence. It may even be a bug! (or laziness) """ def __init__(self, left, right): self.left = left self.right = right def is_singular(self): return False def find(self, data): return self.left.find(data) + self.right.find(data) def __eq__(self, other): return isinstance(other, Union) and self.left == other.left and self.right == other.right def __hash__(self): return hash((self.left, self.right)) class Intersect(JSONPath): """ JSONPath for bits that match *both* patterns. This can be accomplished a couple of ways. The most efficient is to actually build the intersected AST as in building a state machine for matching the intersection of regular languages. The next idea is to build a filtered data and match against that. """ def __init__(self, left, right): self.left = left self.right = right def is_singular(self): return False def find(self, data): raise NotImplementedError() def __eq__(self, other): return isinstance(other, Intersect) and self.left == other.left and self.right == other.right def __hash__(self): return hash((self.left, self.right)) class Fields(JSONPath): """ JSONPath referring to some field of the current object. Concrete syntax ix comma-separated field names. WARNING: If '*' is any of the field names, then they will all be returned. """ def __init__(self, *fields): self.fields = fields @staticmethod def get_field_datum(datum, field, create): if field == auto_id_field: return AutoIdForDatum(datum) try: field_value = datum.value.get(field, NOT_SET) if field_value is NOT_SET: if create: datum.value[field] = field_value = {} else: return None return DatumInContext(field_value, path=Fields(field), context=datum) except (TypeError, AttributeError): return None def reified_fields(self, datum): if '*' not in self.fields: return self.fields else: try: fields = tuple(datum.value.keys()) return fields if auto_id_field is None else fields + (auto_id_field,) except AttributeError: return () def find(self, datum): return self._find_base(datum, create=False) def find_or_create(self, datum): return self._find_base(datum, create=True) def _find_base(self, datum, create): datum = DatumInContext.wrap(datum) field_data = [self.get_field_datum(datum, field, create) for field in self.reified_fields(datum)] return [fd for fd in field_data if fd is not None] def update(self, data, val): return self._update_base(data, val, create=False) def update_or_create(self, data, val): return self._update_base(data, val, create=True) def _update_base(self, data, val, create): if data is not None: for field in self.reified_fields(DatumInContext.wrap(data)): if create and field not in data: data[field] = {} if type(data) is not bool and field in data: if hasattr(val, '__call__'): data[field] = val(data[field], data, field) else: data[field] = val return data def filter(self, fn, data): if data is not None: for field in self.reified_fields(DatumInContext.wrap(data)): if field in data: if fn(data[field]): data.pop(field) return data def __str__(self): # If any JsonPathLexer.literals are included in field name need quotes # This avoids unnecessary quotes to keep strings short. # Test each field whether it contains a literal and only then add quotes # The test loops over all literals, could possibly optimize to short circuit if one found fields_as_str = ("'" + str(f) + "'" if any([l in f for l in JsonPathLexer.literals]) else str(f) for f in self.fields) return ','.join(fields_as_str) def __repr__(self): return '%s(%s)' % (self.__class__.__name__, ','.join(map(repr, self.fields))) def __eq__(self, other): return isinstance(other, Fields) and tuple(self.fields) == tuple(other.fields) def __hash__(self): return hash(tuple(self.fields)) class Index(JSONPath): """ JSONPath that matches indices of the current datum, or none if not large enough. Concrete syntax is brackets. WARNING: If the datum is None or not long enough, it will not crash but will not match anything. NOTE: For the concrete syntax of `[*]`, the abstract syntax is a Slice() with no parameters (equiv to `[:]` """ def __init__(self, index): self.index = index def find(self, datum): return self._find_base(datum, create=False) def find_or_create(self, datum): return self._find_base(datum, create=True) def _find_base(self, datum, create): datum = DatumInContext.wrap(datum) if create: if datum.value == {}: datum.value = _create_list_key(datum.value) self._pad_value(datum.value) if datum.value and len(datum.value) > self.index: return [DatumInContext(datum.value[self.index], path=self, context=datum)] else: return [] def update(self, data, val): return self._update_base(data, val, create=False) def update_or_create(self, data, val): return self._update_base(data, val, create=True) def _update_base(self, data, val, create): if create: if data == {}: data = _create_list_key(data) self._pad_value(data) if hasattr(val, '__call__'): data[self.index] = val.__call__(data[self.index], data, self.index) elif len(data) > self.index: data[self.index] = val return data def filter(self, fn, data): if fn(data[self.index]): data.pop(self.index) # relies on mutation :( return data def __eq__(self, other): return isinstance(other, Index) and self.index == other.index def __str__(self): return '[%i]' % self.index def __repr__(self): return '%s(index=%r)' % (self.__class__.__name__, self.index) def _pad_value(self, value): if len(value) <= self.index: pad = self.index - len(value) + 1 value += [{} for __ in range(pad)] def __hash__(self): return hash(self.index) class Slice(JSONPath): """ JSONPath matching a slice of an array. Because of a mismatch between JSON and XML when schema-unaware, this always returns an iterable; if the incoming data was not a list, then it returns a one element list _containing_ that data. Consider these two docs, and their schema-unaware translation to JSON: hello ==> {"a": {"b": "hello"}} hellogoodbye ==> {"a": {"b": ["hello", "goodbye"]}} If there were a schema, it would be known that "b" should always be an array (unless the schema were wonky, but that is too much to fix here) so when querying with JSON if the one writing the JSON knows that it should be an array, they can write a slice operator and it will coerce a non-array value to an array. This may be a bit unfortunate because it would be nice to always have an iterator, but dictionaries and other objects may also be iterable, so this is the compromise. """ def __init__(self, start=None, end=None, step=None): self.start = start self.end = end self.step = step def find(self, datum): datum = DatumInContext.wrap(datum) # Used for catching null value instead of empty list in path if not datum.value: return [] # Here's the hack. If it is a dictionary or some kind of constant, # put it in a single-element list if (isinstance(datum.value, dict) or isinstance(datum.value, int) or isinstance(datum.value, str)): return self.find(DatumInContext([datum.value], path=datum.path, context=datum.context)) # Some iterators do not support slicing but we can still # at least work for '*' if self.start is None and self.end is None and self.step is None: return [DatumInContext(datum.value[i], path=Index(i), context=datum) for i in range(0, len(datum.value))] else: return [DatumInContext(datum.value[i], path=Index(i), context=datum) for i in range(0, len(datum.value))[self.start:self.end:self.step]] def update(self, data, val): for datum in self.find(data): datum.path.update(data, val) return data def filter(self, fn, data): while True: length = len(data) for datum in self.find(data): data = datum.path.filter(fn, data) if len(data) < length: break if length == len(data): break return data def __str__(self): if self.start is None and self.end is None and self.step is None: return '[*]' else: return '[%s%s%s]' % (self.start or '', ':%d'%self.end if self.end else '', ':%d'%self.step if self.step else '') def __repr__(self): return '%s(start=%r,end=%r,step=%r)' % (self.__class__.__name__, self.start, self.end, self.step) def __eq__(self, other): return isinstance(other, Slice) and other.start == self.start and self.end == other.end and other.step == self.step def __hash__(self): return hash((self.start, self.end, self.step)) def _create_list_key(dict_): """ Adds a list to a dictionary by reference and returns the list. See `_clean_list_keys()` """ dict_[LIST_KEY] = new_list = [{}] return new_list def _clean_list_keys(struct_): """ Replace {LIST_KEY: ['foo', 'bar']} with ['foo', 'bar']. >>> _clean_list_keys({LIST_KEY: ['foo', 'bar']}) ['foo', 'bar'] """ if(isinstance(struct_, list)): for ind, value in enumerate(struct_): struct_[ind] = _clean_list_keys(value) elif(isinstance(struct_, dict)): if(LIST_KEY in struct_): return _clean_list_keys(struct_[LIST_KEY]) else: for key, value in struct_.items(): struct_[key] = _clean_list_keys(value) return struct_