upstream/mercurial-mirror Files · mercurial/pure/mpatch.py

hgweb: use separate repo instances per thread...

hgweb: use separate repo instances per thread Before this change, multiple threads/requests could share a localrepository instance. This meant that all of localrepository needed to be thread safe. Many bugs have been reported telling us that localrepository isn't actually thread safe. While making localrepository thread safe is a noble cause, it is a lot of work. And there is little gain from doing so. Due to Python's GIL, only 1 thread may be processing Python code at a time. The benefits to multi-threaded servers are marginal. Thread safety would be a lot of work for little gain. So, we're not going to even attempt it. This patch establishes a pool of repos in hgweb. When a request arrives, we obtain the most recently used repository from the pool or create a new one if none is available. When the request has finished, we put that repo back in the pool. We start with a pool size of 1. For servers using a single thread, the pool will only ever be of size 1. For multi-threaded servers, the pool size will grow to the max number of simultaneous requests the server processes. No logic for pruning the pool has been implemented. We assume server operators either limit the number of threads to something they can handle or restart the Mercurial process after a certain amount of requests or time has passed.

Brodie Rao - - Load All Authors

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      # mpatch.py - Python implementation of mpatch.c

      #

      # Copyright 2009 Matt Mackall <mpm@selenic.com> and others

      #

      # This software may be used and distributed according to the terms of the

      # GNU General Public License version 2 or any later version.

      import struct

      try:

          from cStringIO import StringIO

      except ImportError:

          from StringIO import StringIO

      # This attempts to apply a series of patches in time proportional to

      # the total size of the patches, rather than patches * len(text). This

      # means rather than shuffling strings around, we shuffle around

      # pointers to fragments with fragment lists.

      #

      # When the fragment lists get too long, we collapse them. To do this

      # efficiently, we do all our operations inside a buffer created by

      # mmap and simply use memmove. This avoids creating a bunch of large

      # temporary string buffers.

      def patches(a, bins):

          if not bins:

              return a

          plens = [len(x) for x in bins]

          pl = sum(plens)

          bl = len(a) + pl

          tl = bl + bl + pl # enough for the patches and two working texts

          b1, b2 = 0, bl

          if not tl:

              return a

          m = StringIO()

          def move(dest, src, count):

              """move count bytes from src to dest

              The file pointer is left at the end of dest.

              """

              m.seek(src)

              buf = m.read(count)

              m.seek(dest)

              m.write(buf)

          # load our original text

          m.write(a)

          frags = [(len(a), b1)]

          # copy all the patches into our segment so we can memmove from them

          pos = b2 + bl

          m.seek(pos)

          for p in bins: m.write(p)

          def pull(dst, src, l): # pull l bytes from src

              while l:

                  f = src.pop()

                  if f[0] > l: # do we need to split?

                      src.append((f[0] - l, f[1] + l))

                      dst.append((l, f[1]))

                      return

                  dst.append(f)

                  l -= f[0]

          def collect(buf, list):

              start = buf

              for l, p in reversed(list):

                  move(buf, p, l)

                  buf += l

              return (buf - start, start)

          for plen in plens:

              # if our list gets too long, execute it

              if len(frags) > 128:

                  b2, b1 = b1, b2

                  frags = [collect(b1, frags)]

              new = []

              end = pos + plen

              last = 0

              while pos < end:

                  m.seek(pos)

                  p1, p2, l = struct.unpack(">lll", m.read(12))

                  pull(new, frags, p1 - last) # what didn't change

                  pull([], frags, p2 - p1)    # what got deleted

                  new.append((l, pos + 12))   # what got added

                  pos += l + 12

                  last = p2

              frags.extend(reversed(new))     # what was left at the end

          t = collect(b2, frags)

          m.seek(t[1])

          return m.read(t[0])

      def patchedsize(orig, delta):

          outlen, last, bin = 0, 0, 0

          binend = len(delta)

          data = 12

          while data <= binend:

              decode = delta[bin:bin + 12]

              start, end, length = struct.unpack(">lll", decode)

              if start > end:

                  break

              bin = data + length

              data = bin + 12

              outlen += start - last

              last = end

              outlen += length

          if bin != binend:

              raise ValueError("patch cannot be decoded")

          outlen += orig - last

          return outlen

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				# mpatch.py - Python implementation of mpatch.c
				#
				# Copyright 2009 Matt Mackall <mpm@selenic.com> and others
				#
				# This software may be used and distributed according to the terms of the
				# GNU General Public License version 2 or any later version.

				import struct
				try:
				from cStringIO import StringIO
				except ImportError:
				from StringIO import StringIO

				# This attempts to apply a series of patches in time proportional to
				# the total size of the patches, rather than patches * len(text). This
				# means rather than shuffling strings around, we shuffle around
				# pointers to fragments with fragment lists.
				#
				# When the fragment lists get too long, we collapse them. To do this
				# efficiently, we do all our operations inside a buffer created by
				# mmap and simply use memmove. This avoids creating a bunch of large
				# temporary string buffers.

				def patches(a, bins):
				if not bins:
				return a

				plens = [len(x) for x in bins]
				pl = sum(plens)
				bl = len(a) + pl
				tl = bl + bl + pl # enough for the patches and two working texts
				b1, b2 = 0, bl

				if not tl:
				return a

				m = StringIO()
				def move(dest, src, count):
				"""move count bytes from src to dest

				The file pointer is left at the end of dest.
				"""
				m.seek(src)
				buf = m.read(count)
				m.seek(dest)
				m.write(buf)

				# load our original text
				m.write(a)
				frags = [(len(a), b1)]

				# copy all the patches into our segment so we can memmove from them
				pos = b2 + bl
				m.seek(pos)
				for p in bins: m.write(p)

				def pull(dst, src, l): # pull l bytes from src
				while l:
				f = src.pop()
				if f[0] > l: # do we need to split?
				src.append((f[0] - l, f[1] + l))
				dst.append((l, f[1]))
				return
				dst.append(f)
				l -= f[0]

				def collect(buf, list):
				start = buf
				for l, p in reversed(list):
				move(buf, p, l)
				buf += l
				return (buf - start, start)

				for plen in plens:
				# if our list gets too long, execute it
				if len(frags) > 128:
				b2, b1 = b1, b2
				frags = [collect(b1, frags)]

				new = []
				end = pos + plen
				last = 0
				while pos < end:
				m.seek(pos)
				p1, p2, l = struct.unpack(">lll", m.read(12))
				pull(new, frags, p1 - last) # what didn't change
				pull([], frags, p2 - p1) # what got deleted
				new.append((l, pos + 12)) # what got added
				pos += l + 12
				last = p2
				frags.extend(reversed(new)) # what was left at the end

				t = collect(b2, frags)

				m.seek(t[1])
				return m.read(t[0])

				def patchedsize(orig, delta):
				outlen, last, bin = 0, 0, 0
				binend = len(delta)
				data = 12

				while data <= binend:
				decode = delta[bin:bin + 12]
				start, end, length = struct.unpack(">lll", decode)
				if start > end:
				break
				bin = data + length
				data = bin + 12
				outlen += start - last
				last = end
				outlen += length

				if bin != binend:
				raise ValueError("patch cannot be decoded")

				outlen += orig - last
				return outlen