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

revset: inline spanset containment check (fix perf regression)...

revset: inline spanset containment check (fix perf regression) Calling a function is super expensive in python. We inline the trivial range comparison to get back to more sensible performance on common revset operation. Benchmark result below: Revision mapping: 0) 2.9.2 release 1) current @ 2) This revision revset : public() 0) wall 0.010890 comb 0.010000 user 0.010000 sys 0.000000 (best of 201) 1) wall 0.012109 comb 0.010000 user 0.010000 sys 0.000000 (best of 199) 2) wall 0.012211 comb 0.020000 user 0.020000 sys 0.000000 (best of 197) revset : :10000 and public() 0) wall 0.007141 comb 0.010000 user 0.010000 sys 0.000000 (best of 361) 1) wall 0.014139 comb 0.010000 user 0.010000 sys 0.000000 (best of 186) 2) wall 0.008334 comb 0.010000 user 0.010000 sys 0.000000 (best of 308) revset : draft() 0) wall 0.009610 comb 0.010000 user 0.010000 sys 0.000000 (best of 279) 1) wall 0.010942 comb 0.010000 user 0.010000 sys 0.000000 (best of 243) 2) wall 0.011036 comb 0.010000 user 0.010000 sys 0.000000 (best of 239) revset : :10000 and draft() 0) wall 0.006852 comb 0.010000 user 0.010000 sys 0.000000 (best of 383) 1) wall 0.014641 comb 0.010000 user 0.010000 sys 0.000000 (best of 183) 2) wall 0.008314 comb 0.010000 user 0.010000 sys 0.000000 (best of 299) We can see this changeset gains back the regression for `and` operation on spanset. We are still a bit slowerfor the `public()` and `draft()`. Predicates not touched by this changeset.

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