Mercurial > hg-stable
view mercurial/bundle2.py @ 20949:571f2903ff1e
bundle2: record processing results in the bundleoperation object
Part handlers can now add records to the `bundleoperation` object. This can be
used to help other parts or to let the caller of the unbundling process react
to the results.
author | Pierre-Yves David <pierre-yves.david@fb.com> |
---|---|
date | Wed, 02 Apr 2014 22:37:50 -0700 |
parents | 329cd74b52bd |
children | c7ceae0faf69 |
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# bundle2.py - generic container format to transmit arbitrary data. # # Copyright 2013 Facebook, Inc. # # This software may be used and distributed according to the terms of the # GNU General Public License version 2 or any later version. """Handling of the new bundle2 format The goal of bundle2 is to act as an atomically packet to transmit a set of payloads in an application agnostic way. It consist in a sequence of "parts" that will be handed to and processed by the application layer. General format architecture =========================== The format is architectured as follow - magic string - stream level parameters - payload parts (any number) - end of stream marker. the Binary format ============================ All numbers are unsigned and big endian. stream level parameters ------------------------ Binary format is as follow :params size: (16 bits integer) The total number of Bytes used by the parameters :params value: arbitrary number of Bytes A blob of `params size` containing the serialized version of all stream level parameters. The blob contains a space separated list of parameters. parameter with value are stored in the form `<name>=<value>`. Both name and value are urlquoted. Empty name are obviously forbidden. Name MUST start with a letter. If this first letter is lower case, the parameter is advisory and can be safefly ignored. However when the first letter is capital, the parameter is mandatory and the bundling process MUST stop if he is not able to proceed it. Stream parameters use a simple textual format for two main reasons: - Stream level parameters should remains simple and we want to discourage any crazy usage. - Textual data allow easy human inspection of a the bundle2 header in case of troubles. Any Applicative level options MUST go into a bundle2 part instead. Payload part ------------------------ Binary format is as follow :header size: (16 bits inter) The total number of Bytes used by the part headers. When the header is empty (size = 0) this is interpreted as the end of stream marker. :header: The header defines how to interpret the part. It contains two piece of data: the part type, and the part parameters. The part type is used to route an application level handler, that can interpret payload. Part parameters are passed to the application level handler. They are meant to convey information that will help the application level object to interpret the part payload. The binary format of the header is has follow :typesize: (one byte) :typename: alphanumerical part name :parameters: Part's parameter may have arbitraty content, the binary structure is:: <mandatory-count><advisory-count><param-sizes><param-data> :mandatory-count: 1 byte, number of mandatory parameters :advisory-count: 1 byte, number of advisory parameters :param-sizes: N couple of bytes, where N is the total number of parameters. Each couple contains (<size-of-key>, <size-of-value) for one parameter. :param-data: A blob of bytes from which each parameter key and value can be retrieved using the list of size couples stored in the previous field. Mandatory parameters comes first, then the advisory ones. :payload: payload is a series of `<chunksize><chunkdata>`. `chunksize` is a 32 bits integer, `chunkdata` are plain bytes (as much as `chunksize` says)` The payload part is concluded by a zero size chunk. The current implementation always produces either zero or one chunk. This is an implementation limitation that will ultimatly be lifted. Bundle processing ============================ Each part is processed in order using a "part handler". Handler are registered for a certain part type. The matching of a part to its handler is case insensitive. The case of the part type is used to know if a part is mandatory or advisory. If the Part type contains any uppercase char it is considered mandatory. When no handler is known for a Mandatory part, the process is aborted and an exception is raised. If the part is advisory and no handler is known, the part is ignored. When the process is aborted, the full bundle is still read from the stream to keep the channel usable. But none of the part read from an abort are processed. In the future, dropping the stream may become an option for channel we do not care to preserve. """ import util import struct import urllib import string import changegroup from i18n import _ _pack = struct.pack _unpack = struct.unpack _magicstring = 'HG20' _fstreamparamsize = '>H' _fpartheadersize = '>H' _fparttypesize = '>B' _fpayloadsize = '>I' _fpartparamcount = '>BB' def _makefpartparamsizes(nbparams): """return a struct format to read part parameter sizes The number parameters is variable so we need to build that format dynamically. """ return '>'+('BB'*nbparams) parthandlermapping = {} def parthandler(parttype): """decorator that register a function as a bundle2 part handler eg:: @parthandler('myparttype') def myparttypehandler(...): '''process a part of type "my part".''' ... """ def _decorator(func): lparttype = parttype.lower() # enforce lower case matching. assert lparttype not in parthandlermapping parthandlermapping[lparttype] = func return func return _decorator class unbundlerecords(object): """keep record of what happens during and unbundle New records are added using `records.add('cat', obj)`. Where 'cat' is a category of record and obj is an arbitraty object. `records['cat']` will return all entries of this category 'cat'. Iterating on the object itself will yield `('category', obj)` tuples for all entries. All iterations happens in chronological order. """ def __init__(self): self._categories = {} self._sequences = [] def add(self, category, entry): """add a new record of a given category. The entry can then be retrieved in the list returned by self['category'].""" self._categories.setdefault(category, []).append(entry) self._sequences.append((category, entry)) def __getitem__(self, cat): return tuple(self._categories.get(cat, ())) def __iter__(self): return iter(self._sequences) def __len__(self): return len(self._sequences) def __nonzero__(self): return bool(self._sequences) class bundleoperation(object): """an object that represents a single bundling process Its purpose is to carry unbundle-related objects and states. A new object should be created at the beginning of each bundle processing. The object is to be returned by the processing function. The object has very little content now it will ultimately contain: * an access to the repo the bundle is applied to, * a ui object, * a way to retrieve a transaction to add changes to the repo, * a way to record the result of processing each part, * a way to construct a bundle response when applicable. """ def __init__(self, repo): self.repo = repo self.ui = repo.ui self.records = unbundlerecords() def processbundle(repo, unbundler): """This function process a bundle, apply effect to/from a repo It iterates over each part then searches for and uses the proper handling code to process the part. Parts are processed in order. This is very early version of this function that will be strongly reworked before final usage. Unknown Mandatory part will abort the process. """ op = bundleoperation(repo) # todo: # - replace this is a init function soon. # - exception catching unbundler.params iterparts = iter(unbundler) try: for part in iterparts: parttype = part.type # part key are matched lower case key = parttype.lower() try: handler = parthandlermapping[key] op.ui.debug('found a handler for part %r\n' % parttype) except KeyError: if key != parttype: # mandatory parts # todo: # - use a more precise exception raise op.ui.debug('ignoring unknown advisory part %r\n' % key) # todo: # - consume the part once we use streaming continue handler(op, part) except Exception: for part in iterparts: pass # consume the bundle content raise return op class bundle20(object): """represent an outgoing bundle2 container Use the `addparam` method to add stream level parameter. and `addpart` to populate it. Then call `getchunks` to retrieve all the binary chunks of datathat compose the bundle2 container.""" def __init__(self, ui): self.ui = ui self._params = [] self._parts = [] def addparam(self, name, value=None): """add a stream level parameter""" if not name: raise ValueError('empty parameter name') if name[0] not in string.letters: raise ValueError('non letter first character: %r' % name) self._params.append((name, value)) def addpart(self, part): """add a new part to the bundle2 container Parts contains the actuall applicative payload.""" self._parts.append(part) def getchunks(self): self.ui.debug('start emission of %s stream\n' % _magicstring) yield _magicstring param = self._paramchunk() self.ui.debug('bundle parameter: %s\n' % param) yield _pack(_fstreamparamsize, len(param)) if param: yield param self.ui.debug('start of parts\n') for part in self._parts: self.ui.debug('bundle part: "%s"\n' % part.type) for chunk in part.getchunks(): yield chunk self.ui.debug('end of bundle\n') yield '\0\0' def _paramchunk(self): """return a encoded version of all stream parameters""" blocks = [] for par, value in self._params: par = urllib.quote(par) if value is not None: value = urllib.quote(value) par = '%s=%s' % (par, value) blocks.append(par) return ' '.join(blocks) class unbundle20(object): """interpret a bundle2 stream (this will eventually yield parts)""" def __init__(self, ui, fp): self.ui = ui self._fp = fp header = self._readexact(4) magic, version = header[0:2], header[2:4] if magic != 'HG': raise util.Abort(_('not a Mercurial bundle')) if version != '20': raise util.Abort(_('unknown bundle version %s') % version) self.ui.debug('start processing of %s stream\n' % header) def _unpack(self, format): """unpack this struct format from the stream""" data = self._readexact(struct.calcsize(format)) return _unpack(format, data) def _readexact(self, size): """read exactly <size> bytes from the stream""" return changegroup.readexactly(self._fp, size) @util.propertycache def params(self): """dictionnary of stream level parameters""" self.ui.debug('reading bundle2 stream parameters\n') params = {} paramssize = self._unpack(_fstreamparamsize)[0] if paramssize: for p in self._readexact(paramssize).split(' '): p = p.split('=', 1) p = [urllib.unquote(i) for i in p] if len(p) < 2: p.append(None) self._processparam(*p) params[p[0]] = p[1] return params def _processparam(self, name, value): """process a parameter, applying its effect if needed Parameter starting with a lower case letter are advisory and will be ignored when unknown. Those starting with an upper case letter are mandatory and will this function will raise a KeyError when unknown. Note: no option are currently supported. Any input will be either ignored or failing. """ if not name: raise ValueError('empty parameter name') if name[0] not in string.letters: raise ValueError('non letter first character: %r' % name) # Some logic will be later added here to try to process the option for # a dict of known parameter. if name[0].islower(): self.ui.debug("ignoring unknown parameter %r\n" % name) else: raise KeyError(name) def __iter__(self): """yield all parts contained in the stream""" # make sure param have been loaded self.params self.ui.debug('start extraction of bundle2 parts\n') part = self._readpart() while part is not None: yield part part = self._readpart() self.ui.debug('end of bundle2 stream\n') def _readpart(self): """return None when an end of stream markers is reach""" headersize = self._unpack(_fpartheadersize)[0] self.ui.debug('part header size: %i\n' % headersize) if not headersize: return None headerblock = self._readexact(headersize) # some utility to help reading from the header block self._offset = 0 # layer violation to have something easy to understand def fromheader(size): """return the next <size> byte from the header""" offset = self._offset data = headerblock[offset:(offset + size)] self._offset = offset + size return data def unpackheader(format): """read given format from header This automatically compute the size of the format to read.""" data = fromheader(struct.calcsize(format)) return _unpack(format, data) typesize = unpackheader(_fparttypesize)[0] parttype = fromheader(typesize) self.ui.debug('part type: "%s"\n' % parttype) ## reading parameters # param count mancount, advcount = unpackheader(_fpartparamcount) self.ui.debug('part parameters: %i\n' % (mancount + advcount)) # param size paramsizes = unpackheader(_makefpartparamsizes(mancount + advcount)) # make it a list of couple again paramsizes = zip(paramsizes[::2], paramsizes[1::2]) # split mandatory from advisory mansizes = paramsizes[:mancount] advsizes = paramsizes[mancount:] # retrive param value manparams = [] for key, value in mansizes: manparams.append((fromheader(key), fromheader(value))) advparams = [] for key, value in advsizes: advparams.append((fromheader(key), fromheader(value))) del self._offset # clean up layer, nobody saw anything. ## part payload payload = [] payloadsize = self._unpack(_fpayloadsize)[0] self.ui.debug('payload chunk size: %i\n' % payloadsize) while payloadsize: payload.append(self._readexact(payloadsize)) payloadsize = self._unpack(_fpayloadsize)[0] self.ui.debug('payload chunk size: %i\n' % payloadsize) payload = ''.join(payload) current = part(parttype, manparams, advparams, data=payload) return current class part(object): """A bundle2 part contains application level payload The part `type` is used to route the part to the application level handler. """ def __init__(self, parttype, mandatoryparams=(), advisoryparams=(), data=''): self.type = parttype self.data = data self.mandatoryparams = mandatoryparams self.advisoryparams = advisoryparams def getchunks(self): #### header ## parttype header = [_pack(_fparttypesize, len(self.type)), self.type, ] ## parameters # count manpar = self.mandatoryparams advpar = self.advisoryparams header.append(_pack(_fpartparamcount, len(manpar), len(advpar))) # size parsizes = [] for key, value in manpar: parsizes.append(len(key)) parsizes.append(len(value)) for key, value in advpar: parsizes.append(len(key)) parsizes.append(len(value)) paramsizes = _pack(_makefpartparamsizes(len(parsizes) / 2), *parsizes) header.append(paramsizes) # key, value for key, value in manpar: header.append(key) header.append(value) for key, value in advpar: header.append(key) header.append(value) ## finalize header headerchunk = ''.join(header) yield _pack(_fpartheadersize, len(headerchunk)) yield headerchunk ## payload # we only support fixed size data now. # This will be improved in the future. if len(self.data): yield _pack(_fpayloadsize, len(self.data)) yield self.data # end of payload yield _pack(_fpayloadsize, 0)