def _set_cache_too_slow_without_c(self, attr): # the direct algorithm is fastest and most direct if there is only one # delta. Also, the extra overhead might not be worth it for items smaller # than X - definitely the case in python, every function call costs # huge amounts of time # if len(self._dstreams) * self._bstream.size < self.k_max_memory_move: if len(self._dstreams) == 1: return self._set_cache_brute_(attr) # Aggregate all deltas into one delta in reverse order. Hence we take # the last delta, and reverse-merge its ancestor delta, until we receive # the final delta data stream. # print "Handling %i delta streams, sizes: %s" % (len(self._dstreams), [ds.size for ds in self._dstreams]) dcl = connect_deltas(self._dstreams) # call len directly, as the (optional) c version doesn't implement the sequence # protocol if dcl.rbound() == 0: self._size = 0 self._mm_target = allocate_memory(0) return # END handle empty list self._size = dcl.rbound() self._mm_target = allocate_memory(self._size) bbuf = allocate_memory(self._bstream.size) stream_copy(self._bstream.read, bbuf.write, self._bstream.size, 256 * mmap.PAGESIZE) # APPLY CHUNKS write = self._mm_target.write dcl.apply(bbuf, write) self._mm_target.seek(0)
def _iter_objects(self, start_offset, as_stream=True): """Handle the actual iteration of objects within this pack""" c = self._cursor content_size = c.file_size() - self.footer_size cur_offset = start_offset or self.first_object_offset null = NullStream() while cur_offset < content_size: data_offset, ostream = pack_object_at(c, cur_offset, True) # scrub the stream to the end - this decompresses the object, but yields # the amount of compressed bytes we need to get to the next offset stream_copy(ostream.read, null.write, ostream.size, chunk_size) cur_offset += (data_offset - ostream.pack_offset) + ostream.stream.compressed_bytes_read() # if a stream is requested, reset it beforehand # Otherwise return the Stream object directly, its derived from the # info object if as_stream: ostream.stream.seek(0) yield ostream
def _iter_objects(self, start_offset, as_stream=True): """Handle the actual iteration of objects within this pack""" c = self._cursor content_size = c.file_size() - self.footer_size cur_offset = start_offset or self.first_object_offset null = NullStream() while cur_offset < content_size: data_offset, ostream = pack_object_at(c, cur_offset, True) # scrub the stream to the end - this decompresses the object, but yields # the amount of compressed bytes we need to get to the next offset stream_copy(ostream.read, null.write, ostream.size, chunk_size) cur_offset += (data_offset - ostream.pack_offset ) + ostream.stream.compressed_bytes_read() # if a stream is requested, reset it beforehand # Otherwise return the Stream object directly, its derived from the # info object if as_stream: ostream.stream.seek(0) yield ostream
def _set_cache_brute_(self, attr): """If we are here, we apply the actual deltas""" # TODO: There should be a special case if there is only one stream # Then the default-git algorithm should perform a tad faster, as the # delta is not peaked into, causing less overhead. buffer_info_list = list() max_target_size = 0 for dstream in self._dstreams: buf = dstream.read(512) # read the header information + X offset, src_size = msb_size(buf) offset, target_size = msb_size(buf, offset) buffer_info_list.append( (buffer(buf, offset), offset, src_size, target_size)) max_target_size = max(max_target_size, target_size) # END for each delta stream # sanity check - the first delta to apply should have the same source # size as our actual base stream base_size = self._bstream.size target_size = max_target_size # if we have more than 1 delta to apply, we will swap buffers, hence we must # assure that all buffers we use are large enough to hold all the results if len(self._dstreams) > 1: base_size = target_size = max(base_size, max_target_size) # END adjust buffer sizes # Allocate private memory map big enough to hold the first base buffer # We need random access to it bbuf = allocate_memory(base_size) stream_copy(self._bstream.read, bbuf.write, base_size, 256 * mmap.PAGESIZE) # allocate memory map large enough for the largest (intermediate) target # We will use it as scratch space for all delta ops. If the final # target buffer is smaller than our allocated space, we just use parts # of it upon return. tbuf = allocate_memory(target_size) # for each delta to apply, memory map the decompressed delta and # work on the op-codes to reconstruct everything. # For the actual copying, we use a seek and write pattern of buffer # slices. final_target_size = None for (dbuf, offset, src_size, target_size), dstream in reversed( zip(buffer_info_list, self._dstreams)): # allocate a buffer to hold all delta data - fill in the data for # fast access. We do this as we know that reading individual bytes # from our stream would be slower than necessary ( although possible ) # The dbuf buffer contains commands after the first two MSB sizes, the # offset specifies the amount of bytes read to get the sizes. ddata = allocate_memory(dstream.size - offset) ddata.write(dbuf) # read the rest from the stream. The size we give is larger than necessary stream_copy(dstream.read, ddata.write, dstream.size, 256 * mmap.PAGESIZE) ####################################################################### if 'c_apply_delta' in globals(): c_apply_delta(bbuf, ddata, tbuf) else: apply_delta_data(bbuf, src_size, ddata, len(ddata), tbuf.write) ####################################################################### # finally, swap out source and target buffers. The target is now the # base for the next delta to apply bbuf, tbuf = tbuf, bbuf bbuf.seek(0) tbuf.seek(0) final_target_size = target_size # END for each delta to apply # its already seeked to 0, constrain it to the actual size # NOTE: in the end of the loop, it swaps buffers, hence our target buffer # is not tbuf, but bbuf ! self._mm_target = bbuf self._size = final_target_size
def _set_cache_brute_(self, attr): """If we are here, we apply the actual deltas""" # TODO: There should be a special case if there is only one stream # Then the default-git algorithm should perform a tad faster, as the # delta is not peaked into, causing less overhead. buffer_info_list = list() max_target_size = 0 for dstream in self._dstreams: buf = dstream.read(512) # read the header information + X offset, src_size = msb_size(buf) offset, target_size = msb_size(buf, offset) buffer_info_list.append((buffer(buf, offset), offset, src_size, target_size)) max_target_size = max(max_target_size, target_size) # END for each delta stream # sanity check - the first delta to apply should have the same source # size as our actual base stream base_size = self._bstream.size target_size = max_target_size # if we have more than 1 delta to apply, we will swap buffers, hence we must # assure that all buffers we use are large enough to hold all the results if len(self._dstreams) > 1: base_size = target_size = max(base_size, max_target_size) # END adjust buffer sizes # Allocate private memory map big enough to hold the first base buffer # We need random access to it bbuf = allocate_memory(base_size) stream_copy(self._bstream.read, bbuf.write, base_size, 256 * mmap.PAGESIZE) # allocate memory map large enough for the largest (intermediate) target # We will use it as scratch space for all delta ops. If the final # target buffer is smaller than our allocated space, we just use parts # of it upon return. tbuf = allocate_memory(target_size) # for each delta to apply, memory map the decompressed delta and # work on the op-codes to reconstruct everything. # For the actual copying, we use a seek and write pattern of buffer # slices. final_target_size = None for (dbuf, offset, src_size, target_size), dstream in reversed(zip(buffer_info_list, self._dstreams)): # allocate a buffer to hold all delta data - fill in the data for # fast access. We do this as we know that reading individual bytes # from our stream would be slower than necessary ( although possible ) # The dbuf buffer contains commands after the first two MSB sizes, the # offset specifies the amount of bytes read to get the sizes. ddata = allocate_memory(dstream.size - offset) ddata.write(dbuf) # read the rest from the stream. The size we give is larger than necessary stream_copy(dstream.read, ddata.write, dstream.size, 256 * mmap.PAGESIZE) ####################################################################### if "c_apply_delta" in globals(): c_apply_delta(bbuf, ddata, tbuf) else: apply_delta_data(bbuf, src_size, ddata, len(ddata), tbuf.write) ####################################################################### # finally, swap out source and target buffers. The target is now the # base for the next delta to apply bbuf, tbuf = tbuf, bbuf bbuf.seek(0) tbuf.seek(0) final_target_size = target_size # END for each delta to apply # its already seeked to 0, constrain it to the actual size # NOTE: in the end of the loop, it swaps buffers, hence our target buffer # is not tbuf, but bbuf ! self._mm_target = bbuf self._size = final_target_size