sidedatacopies: fast path data fetching if revision has no sidedata
When using the side data mode, we know their won't be any copy information
sidedata. Skipping revision restoration give an important speed boost.
In the future, there will be other user of sidedata, reducing the efficiency of
this. We should consider adding a dedicated flag in revlog V2 to preserve this
optimisation. The current situation is good enough for now.
revision: large amount; added files: large amount; rename small amount;
c3b14617fbd7 9ba6ab77fd29
before: ! wall 2.401569 comb 2.400000 user 2.390000 sys 0.010000 (median of 10)
after: ! wall 1.429294 comb 1.430000 user 1.410000 sys 0.020000 (median of 10)
revision: large amount; added files: small amount; rename small amount;
c3b14617fbd7 f650a9b140d2
before: ! wall 3.519140 comb 3.520000 user 3.470000 sys 0.050000 (median of 10)
after: ! wall 1.963332 comb 1.960000 user 1.960000 sys 0.000000 (median of 10)
revision: large amount; added files: large amount; rename large amount;
08ea3258278e d9fa043f30c0
before: ! wall 0.593880 comb 0.600000 user 0.590000 sys 0.010000 (median of 15)
after: ! wall 0.251679 comb 0.250000 user 0.250000 sys 0.000000 (median of 38)
revision: small amount; added files: large amount; rename large amount;
df6f7a526b60 a83dc6a2d56f
before: ! wall 0.013414 comb 0.020000 user 0.020000 sys 0.000000 (median of 220)
after: ! wall 0.013222 comb 0.020000 user 0.020000 sys 0.000000 (median of 223)
revision: small amount; added files: large amount; rename small amount;
4aa4e1f8e19a 169138063d63
before: ! wall 0.002711 comb 0.000000 user 0.000000 sys 0.000000 (median of 1000)
after: ! wall 0.001631 comb 0.000000 user 0.000000 sys 0.000000 (median of 1000)
revision: small amount; added files: small amount; rename small amount;
4bc173b045a6 964879152e2e
before: ! wall 0.000077 comb 0.000000 user 0.000000 sys 0.000000 (median of 12208)
after: ! wall 0.000078 comb 0.000000 user 0.000000 sys 0.000000 (median of 12012)
revision: medium amount; added files: large amount; rename medium amount;
c95f1ced15f2 2c68e87c3efe
before: ! wall 0.410067 comb 0.410000 user 0.410000 sys 0.000000 (median of 23)
after: ! wall 0.207786 comb 0.200000 user 0.200000 sys 0.000000 (median of 46)
revision: medium amount; added files: medium amount; rename small amount;
d343da0c55a8 d7746d32bf9d
before: ! wall 0.097004 comb 0.090000 user 0.090000 sys 0.000000 (median of 100)
after: ! wall 0.038495 comb 0.030000 user 0.030000 sys 0.000000 (median of 100)
Differential Revision: https://phab.mercurial-scm.org/D7074
# test-batching.py - tests for transparent command batching
#
# Copyright 2011 Peter Arrenbrecht <peter@arrenbrecht.ch>
#
# This software may be used and distributed according to the terms of the
# GNU General Public License version 2 or any later version.
from __future__ import absolute_import, print_function
import contextlib
from mercurial import (
localrepo,
pycompat,
wireprotov1peer,
)
def bprint(*bs):
print(*[pycompat.sysstr(b) for b in bs])
# equivalent of repo.repository
class thing(object):
def hello(self):
return b"Ready."
# equivalent of localrepo.localrepository
class localthing(thing):
def foo(self, one, two=None):
if one:
return b"%s and %s" % (one, two,)
return b"Nope"
def bar(self, b, a):
return b"%s und %s" % (b, a,)
def greet(self, name=None):
return b"Hello, %s" % name
@contextlib.contextmanager
def commandexecutor(self):
e = localrepo.localcommandexecutor(self)
try:
yield e
finally:
e.close()
# usage of "thing" interface
def use(it):
# Direct call to base method shared between client and server.
bprint(it.hello())
# Direct calls to proxied methods. They cause individual roundtrips.
bprint(it.foo(b"Un", two=b"Deux"))
bprint(it.bar(b"Eins", b"Zwei"))
# Batched call to a couple of proxied methods.
with it.commandexecutor() as e:
ffoo = e.callcommand(b'foo', {b'one': b'One', b'two': b'Two'})
fbar = e.callcommand(b'bar', {b'b': b'Eins', b'a': b'Zwei'})
fbar2 = e.callcommand(b'bar', {b'b': b'Uno', b'a': b'Due'})
bprint(ffoo.result())
bprint(fbar.result())
bprint(fbar2.result())
# local usage
mylocal = localthing()
print()
bprint(b"== Local")
use(mylocal)
# demo remoting; mimicks what wireproto and HTTP/SSH do
# shared
def escapearg(plain):
return (
plain.replace(b':', b'::')
.replace(b',', b':,')
.replace(b';', b':;')
.replace(b'=', b':=')
)
def unescapearg(escaped):
return (
escaped.replace(b':=', b'=')
.replace(b':;', b';')
.replace(b':,', b',')
.replace(b'::', b':')
)
# server side
# equivalent of wireproto's global functions
class server(object):
def __init__(self, local):
self.local = local
def _call(self, name, args):
args = dict(arg.split(b'=', 1) for arg in args)
return getattr(self, name)(**args)
def perform(self, req):
bprint(b"REQ:", req)
name, args = req.split(b'?', 1)
args = args.split(b'&')
vals = dict(arg.split(b'=', 1) for arg in args)
res = getattr(self, pycompat.sysstr(name))(**pycompat.strkwargs(vals))
bprint(b" ->", res)
return res
def batch(self, cmds):
res = []
for pair in cmds.split(b';'):
name, args = pair.split(b':', 1)
vals = {}
for a in args.split(b','):
if a:
n, v = a.split(b'=')
vals[n] = unescapearg(v)
res.append(
escapearg(
getattr(self, pycompat.sysstr(name))(
**pycompat.strkwargs(vals)
)
)
)
return b';'.join(res)
def foo(self, one, two):
return mangle(self.local.foo(unmangle(one), unmangle(two)))
def bar(self, b, a):
return mangle(self.local.bar(unmangle(b), unmangle(a)))
def greet(self, name):
return mangle(self.local.greet(unmangle(name)))
myserver = server(mylocal)
# local side
# equivalent of wireproto.encode/decodelist, that is, type-specific marshalling
# here we just transform the strings a bit to check we're properly en-/decoding
def mangle(s):
return b''.join(pycompat.bytechr(ord(c) + 1) for c in pycompat.bytestr(s))
def unmangle(s):
return b''.join(pycompat.bytechr(ord(c) - 1) for c in pycompat.bytestr(s))
# equivalent of wireproto.wirerepository and something like http's wire format
class remotething(thing):
def __init__(self, server):
self.server = server
def _submitone(self, name, args):
req = name + b'?' + b'&'.join([b'%s=%s' % (n, v) for n, v in args])
return self.server.perform(req)
def _submitbatch(self, cmds):
req = []
for name, args in cmds:
args = b','.join(n + b'=' + escapearg(v) for n, v in args)
req.append(name + b':' + args)
req = b';'.join(req)
res = self._submitone(b'batch', [(b'cmds', req,)])
for r in res.split(b';'):
yield r
@contextlib.contextmanager
def commandexecutor(self):
e = wireprotov1peer.peerexecutor(self)
try:
yield e
finally:
e.close()
@wireprotov1peer.batchable
def foo(self, one, two=None):
encargs = [(b'one', mangle(one),), (b'two', mangle(two),)]
encresref = wireprotov1peer.future()
yield encargs, encresref
yield unmangle(encresref.value)
@wireprotov1peer.batchable
def bar(self, b, a):
encresref = wireprotov1peer.future()
yield [(b'b', mangle(b),), (b'a', mangle(a),)], encresref
yield unmangle(encresref.value)
# greet is coded directly. It therefore does not support batching. If it
# does appear in a batch, the batch is split around greet, and the call to
# greet is done in its own roundtrip.
def greet(self, name=None):
return unmangle(self._submitone(b'greet', [(b'name', mangle(name),)]))
# demo remote usage
myproxy = remotething(myserver)
print()
bprint(b"== Remote")
use(myproxy)