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view tests/test-batching.py @ 44363:f7459da77f23
nodemap: introduce an option to use mmap to read the nodemap mapping
The performance and memory benefit is much greater if we don't have to copy all
the data in memory for each information. So we introduce an option (on by
default) to read the data using mmap.
This changeset is the last one definition the API for index support nodemap
data. (they have to be able to use the mmaping).
Below are some benchmark comparing the best we currently have in 5.3 with the
final step of this series (using the persistent nodemap implementation in
Rust). The benchmark run `hg perfindex` with various revset and the following
variants:
Before:
* do not use the persistent nodemap
* use the CPython implementation of the index for nodemap
* use mmapping of the changelog index
After:
* use the MixedIndex Rust code, with the NodeTree object for nodemap access
(still in review)
* use the persistent nodemap data from disk
* access the persistent nodemap data through mmap
* use mmapping of the changelog index
The persistent nodemap greatly speed up most operation on very large
repositories. Some of the previously very fast lookup end up a bit slower because
the persistent nodemap has to be setup. However the absolute slowdown is very
small and won't matters in the big picture.
Here are some numbers (in seconds) for the reference copy of mozilla-try:
Revset Before After abs-change speedup
-10000: 0.004622 0.005532 0.000910 × 0.83
-10: 0.000050 0.000132 0.000082 × 0.37
tip 0.000052 0.000085 0.000033 × 0.61
0 + (-10000:) 0.028222 0.005337 -0.022885 × 5.29
0 0.023521 0.000084 -0.023437 × 280.01
(-10000:) + 0 0.235539 0.005308 -0.230231 × 44.37
(-10:) + :9 0.232883 0.000180 -0.232703 ×1293.79
(-10000:) + (:99) 0.238735 0.005358 -0.233377 × 44.55
:99 + (-10000:) 0.317942 0.005593 -0.312349 × 56.84
:9 + (-10:) 0.313372 0.000179 -0.313193 ×1750.68
:9 0.316450 0.000143 -0.316307 ×2212.93
On smaller repositories, the cost of nodemap related operation is not as big, so
the win is much more modest. Yet it helps shaving a handful of millisecond here
and there.
Here are some numbers (in seconds) for the reference copy of mercurial:
Revset Before After abs-change speedup
-10: 0.000065 0.000097 0.000032 × 0.67
tip 0.000063 0.000078 0.000015 × 0.80
0 0.000561 0.000079 -0.000482 × 7.10
-10000: 0.004609 0.003648 -0.000961 × 1.26
0 + (-10000:) 0.005023 0.003715 -0.001307 × 1.35
(-10:) + :9 0.002187 0.000108 -0.002079 ×20.25
(-10000:) + 0 0.006252 0.003716 -0.002536 × 1.68
(-10000:) + (:99) 0.006367 0.003707 -0.002660 × 1.71
:9 + (-10:) 0.003846 0.000110 -0.003736 ×34.96
:9 0.003854 0.000099 -0.003755 ×38.92
:99 + (-10000:) 0.007644 0.003778 -0.003866 × 2.02
Differential Revision: https://phab.mercurial-scm.org/D7894
| author | Pierre-Yves David <pierre-yves.david@octobus.net> |
|---|---|
| date | Tue, 11 Feb 2020 11:18:52 +0100 |
| parents | 2372284d9457 |
| children | 89a2afe31e82 |
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# 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)