Before this CL, if the system resolver does a very slow DNS
lookup for a particular host, all subsequent requests for that
host will hang waiting for that lookup to complete. That is
more or less expected when Dial is called with no deadline.
When Dial has a deadline, though, we can accumulate a large
number of goroutines waiting for that slow DNS lookup. Try to
avoid this problem by restarting the DNS lookup when it is
redone after a deadline is passed.
This CL also avoids creating an extra goroutine purely to
handle the deadline.
No test because we would have to simulate a slow DNS lookup
followed by a fast DNS lookup.
Fixes#8602.
LGTM=bradfitz
R=bradfitz, mikioh.mikioh
CC=golang-codereviews, r, rsc
https://golang.org/cl/154610044
ARPHELPLINK yields 404; update the URL.
While here, also prefix the ARPREADME and ARPURLINFOABOUT URL's with the HTTP scheme to make 'em clickable links in the Add or Remove Programs listing.
LGTM=adg
R=golang-codereviews
CC=adg, golang-codereviews
https://golang.org/cl/154580045
Wrong article, one stylistic point that bothers someone (but not me).
LGTM=bradfitz
R=golang-codereviews, bradfitz
CC=golang-codereviews
https://golang.org/cl/156680043
The compatibility guideline needs to be clear about this even
though it means adding a clause that was not there from the
beginning. It has always been understood, so this isn't really
a change in policy, just in its expression.
LGTM=bradfitz, gri, rsc
R=golang-codereviews, bradfitz, gri, rsc
CC=golang-codereviews
https://golang.org/cl/162060043
We force runtime.GC before WriteHeapProfile with -test.heapprofile.
Make it possible to do the same with the HTTP interface.
Some servers only run a GC every few minutes.
On such servers, the heap profile will be a few minutes stale,
which may be too old to be useful.
Requested by private mail.
LGTM=dvyukov
R=dvyukov
CC=golang-codereviews
https://golang.org/cl/161990043
In theory both of these lines encode the same three fields:
a,,c
a,"",c
However, Postgres defines that when importing CSV, the unquoted
version is treated as NULL (missing), while the quoted version is
treated as a string value (empty string). If the middle field is supposed to
be an integer value, the first line can be imported (NULL is okay), but
the second line cannot (empty string is not).
Postgres's import command (COPY FROM) has an option to force
the unquoted empty to be interpreted as a string but it does not
have an option to force the quoted empty to be interpreted as a NULL.
From http://www.postgresql.org/docs/9.0/static/sql-copy.html:
The CSV format has no standard way to distinguish a NULL
value from an empty string. PostgreSQL's COPY handles this
by quoting. A NULL is output as the NULL parameter string
and is not quoted, while a non-NULL value matching the NULL
parameter string is quoted. For example, with the default
settings, a NULL is written as an unquoted empty string,
while an empty string data value is written with double
quotes (""). Reading values follows similar rules. You can
use FORCE_NOT_NULL to prevent NULL input comparisons for
specific columns.
Therefore printing the unquoted empty is more flexible for
imports into Postgres than printing the quoted empty.
In addition to making the output more useful with Postgres, not
quoting empty strings makes the output smaller and easier to read.
It also matches the behavior of Microsoft Excel and Google Drive.
Since we are here and making concessions for Postgres, handle this
case too (again quoting the Postgres docs):
Because backslash is not a special character in the CSV
format, \., the end-of-data marker, could also appear as a
data value. To avoid any misinterpretation, a \. data value
appearing as a lone entry on a line is automatically quoted
on output, and on input, if quoted, is not interpreted as
the end-of-data marker. If you are loading a file created by
another application that has a single unquoted column and
might have a value of \., you might need to quote that value
in the input file.
Fixes#7586.
LGTM=bradfitz
R=bradfitz
CC=golang-codereviews
https://golang.org/cl/164760043
Per suggestion from rsc as a result of the dicussion of
(abandoned) CL 153110044.
Fixes#7192.
LGTM=r, rsc, iant
R=r, rsc, iant, ken
CC=golang-codereviews
https://golang.org/cl/163050043
Pool memory was only being released during the first GC after the first Put.
Put assumes that p.local != nil means p is on the allPools list.
poolCleanup (called during each GC) removed each pool from allPools
but did not clear p.local, so each pool was cleared by exactly one GC
and then never cleared again.
This bug was introduced late in the Go 1.3 release cycle.
Fixes#8979.
LGTM=rsc
R=golang-codereviews, bradfitz, r, rsc
CC=golang-codereviews, khr
https://golang.org/cl/162980043
test16 used to fail with gccgo. The withoutRecoverRecursive
test would have failed in some possible implementations.
LGTM=bradfitz
R=golang-codereviews, bradfitz
CC=golang-codereviews
https://golang.org/cl/151630043
Fixes#8348.
Trying to work around clang's dodgy support for .arch by reverting to the external assembler didn't work out so well. Minux had a much better solution to encode the instructions we need as .word directives which avoids .arch altogether.
I've confirmed with gdb that this form produces the expected machine code
Dump of assembler code for function crosscall_arm1:
0x00000000 <+0>: push {r4, r5, r6, r7, r8, r9, r10, r11, r12, lr}
0x00000004 <+4>: mov r4, r0
0x00000008 <+8>: mov r5, r1
0x0000000c <+12>: mov r0, r2
0x00000010 <+16>: blx r5
0x00000014 <+20>: blx r4
0x00000018 <+24>: pop {r4, r5, r6, r7, r8, r9, r10, r11, r12, pc}
There is another compilation failure that blocks building Go with clang on arm
# ../misc/cgo/test
# _/home/dfc/go/misc/cgo/test
/tmp/--407b12.s: Assembler messages:
/tmp/--407b12.s:59: Error: selected processor does not support ARM mode `blx r0'
clang: error: assembler command failed with exit code 1 (use -v to see invocation)
FAIL _/home/dfc/go/misc/cgo/test [build failed]
I'll open a new issue for that
LGTM=iant
R=iant, minux
CC=golang-codereviews
https://golang.org/cl/158180047
Set correct version number at Windows installer based on
Go's Mercurial tag.
Name | Version
------------------------------------------------
Go Programming Language amd64 go1.3.3 | 1.3.3
Go Programming Language amd64 go1.2rc3 | 1.2
Go Programming Language amd64 go1.2beta1 | 1.2
Fixes#8239.
LGTM=adg
R=adg, c.emil.hessman, alex.brainman
CC=golang-codereviews
https://golang.org/cl/160950044
Partial undo, changes to ldelf.c retained.
Some platforms are still not working even with the integrated assembler disabled, will have to find another solution.
««« original CL description
cmd/cgo: disable clang's integrated assembler
Fixes#8348.
Clang's internal assembler (introduced by default in clang 3.4) understands the .arch directive, but doesn't change the default value of -march. This causes the build to fail when we use BLX (armv5 and above) when clang is compiled for the default armv4t architecture (which appears to be the default on all the distros I've used).
This is probably a clang bug, so work around it for the time being by disabling the integrated assembler when compiling the cgo assembly shim.
This CL also includes a small change to ldelf.c which was required as clang 3.4 and above generate more weird symtab entries.
LGTM=iant
R=golang-codereviews, iant
CC=golang-codereviews
https://golang.org/cl/156430044
»»»
LGTM=minux
R=iant, minux
CC=golang-codereviews
https://golang.org/cl/162880044
Get rid of gocputicks(), it is no longer used.
LGTM=bradfitz, dave
R=golang-codereviews, bradfitz, dave, minux
CC=golang-codereviews
https://golang.org/cl/161110044
This brings cmd/gc in line with the spec on this question.
It might break existing code, but that code was not conformant
with the spec.
Credit to Rémy for finding the broken code.
Fixes#6366.
LGTM=r
R=golang-codereviews, r
CC=adonovan, golang-codereviews, gri
https://golang.org/cl/129550043
Allows parsing some file formats that assign special
meaning to which stream data is found in.
Will do the same for compress/bzip2 once this is
reviewed and submitted.
Fixes#6486.
LGTM=nigeltao
R=nigeltao, dan.kortschak
CC=adg, bradfitz, golang-codereviews, r
https://golang.org/cl/159120044
Fixes#8348.
Clang's internal assembler (introduced by default in clang 3.4) understands the .arch directive, but doesn't change the default value of -march. This causes the build to fail when we use BLX (armv5 and above) when clang is compiled for the default armv4t architecture (which appears to be the default on all the distros I've used).
This is probably a clang bug, so work around it for the time being by disabling the integrated assembler when compiling the cgo assembly shim.
This CL also includes a small change to ldelf.c which was required as clang 3.4 and above generate more weird symtab entries.
LGTM=iant
R=golang-codereviews, iant
CC=golang-codereviews
https://golang.org/cl/156430044
It has been failing periodically on Solaris/x64.
Change blockevent so it always records an event if we called
SetBlockProfileRate(1), even if the time delta is negative or zero.
Hopefully this will fix the test on Solaris.
Caveat: I don't actually know what the Solaris problem is, this
is just an educated guess.
LGTM=dave
R=dvyukov, dave
CC=golang-codereviews
https://golang.org/cl/159150043
Russ Cox pointed out that environment strings are not
required to be nil-terminated on Plan 9.
LGTM=rsc
R=rsc
CC=golang-codereviews
https://golang.org/cl/159130044
Since CL 104570043 and 112720043, we are using the
nsec system call instead of /dev/bintime on Plan 9.
LGTM=rsc
R=rsc
CC=aram, golang-codereviews
https://golang.org/cl/155590043
Shell scripts depend on the old behavior too often.
It's too late to make this change.
LGTM=bradfitz
R=rsc, bradfitz
CC=golang-codereviews
https://golang.org/cl/161890044
This test was failing but did not break the build because it
was not run when -test.short was used.
LGTM=bradfitz
R=golang-codereviews, bradfitz
CC=golang-codereviews
https://golang.org/cl/157150043
I came across this while debugging a GC problem in gccgo.
There is code in assignTo and cvtT2I that handles assignment
to all interface values. It allocates an empty interface even
if the real type is a non-empty interface. The fields are
then set for a non-empty interface, but the memory is recorded
as holding an empty interface. This means that the GC has
incorrect information.
This is extremely unlikely to fail, because the code in the GC
that handles empty interfaces looks like this:
obj = nil;
typ = eface->type;
if(typ != nil) {
if(!(typ->kind&KindDirectIface) || !(typ->kind&KindNoPointers))
obj = eface->data;
In the current runtime the condition is always true--if
KindDirectIface is set, then KindNoPointers is clear--and we
always want to set obj = eface->data. So the question is what
happens when we incorrectly store a non-empty interface value
in memory marked as an empty interface. In that case
eface->type will not be a *rtype as we expect, but will
instead be a pointer to an Itab. We are going to use this
pointer to look at a *rtype kind field. The *rtype struct
starts out like this:
type rtype struct {
size uintptr
hash uint32 // hash of type; avoids computation in hash tables
_ uint8 // unused/padding
align uint8 // alignment of variable with this type
fieldAlign uint8 // alignment of struct field with this type
kind uint8 // enumeration for C
An Itab always has at least two pointers, so on a
little-endian 64-bit system the kind field will be the high
byte of the second pointer. This will normally be zero, so
the test of typ->kind will succeed, which is what we want.
On a 32-bit system it might be possible to construct a failing
case by somehow getting the Itab for an interface with one
method to be immediately followed by a word that is all ones.
The effect would be that the test would sometimes fail and the
GC would not mark obj, leading to an invalid dangling
pointer. I have not tried to construct this test.
I noticed this in gccgo, where this error is much more likely
to cause trouble for a rather random reason: gccgo uses a
different layout of rtype, and in gccgo the kind field happens
to be the low byte of a pointer, not the high byte.
LGTM=rsc
R=rsc
CC=golang-codereviews
https://golang.org/cl/155450044
The stack blowout can no longer happen,
but we can still test that too-complex regexps
are rejected.
Replacement for CL 162770043.
LGTM=iant, r
R=r, iant
CC=bradfitz, golang-codereviews
https://golang.org/cl/162860043
This is already tested by TestRE2Exhaustive, but the build has
not broken because that test is not run when using -test.short.
LGTM=rsc
R=rsc
CC=golang-codereviews
https://golang.org/cl/155580043
https://golang.org/cl/152700045/ made it possible for struct literals assigned to globals to use <N> as the RHS. Normally, this is to zero out variables on first use. Because globals are already zero (or their linker initialized value), we just ignored this.
Now that <N> can occur from non-initialization code, we need to emit this code. We don't use <N> for initialization of globals any more, so this shouldn't cause any excessive zeroing.
Fixes#8961.
LGTM=rsc
R=golang-codereviews, rsc
CC=bradfitz, golang-codereviews
https://golang.org/cl/154540044
As we did with encoding, provide a trivial byte reader for
faster decoding. We can also reduce some of the copying
by doing the allocation all at once using a slightly different
interface from byte buffers.
benchmark old ns/op new ns/op delta
BenchmarkEndToEndPipe 13368 12902 -3.49%
BenchmarkEndToEndByteBuffer 5969 5642 -5.48%
BenchmarkEndToEndSliceByteBuffer 479485 470798 -1.81%
BenchmarkEncodeComplex128Slice 92367 92201 -0.18%
BenchmarkEncodeFloat64Slice 39990 38960 -2.58%
BenchmarkEncodeInt32Slice 30510 27938 -8.43%
BenchmarkEncodeStringSlice 33753 33365 -1.15%
BenchmarkDecodeComplex128Slice 232278 196704 -15.32%
BenchmarkDecodeFloat64Slice 150258 128191 -14.69%
BenchmarkDecodeInt32Slice 133806 115748 -13.50%
BenchmarkDecodeStringSlice 335117 300534 -10.32%
LGTM=rsc
R=rsc
CC=golang-codereviews
https://golang.org/cl/154360049
This adds a Reset() to compress/flate's decompressor and plumbs that through
to compress/zlib and compress/gzip's Readers so callers can avoid large
allocations when performing many inflate operations. In particular this
preserves the allocation of the decompressor.hist buffer, which is 32kb and
overwritten as needed while inflating.
On the benchmark described in issue 6317, produces the following speedup on
my 2.3ghz Intel Core i7 MBP with go version devel +6b696a34e0af Sun Aug 03
15:14:59 2014 -0700 darwin/amd64:
blocked.text w/out patch vs blocked.text w/ patch:
benchmark old ns/op new ns/op delta
BenchmarkGunzip 8371577533 7927917687 -5.30%
benchmark old allocs new allocs delta
BenchmarkGunzip 176818 148519 -16.00%
benchmark old bytes new bytes delta
BenchmarkGunzip 292184936 12739528 -95.64%
flat.text vs blocked.text w/patch:
benchmark old ns/op new ns/op delta
BenchmarkGunzip 7939447827 7927917687 -0.15%
benchmark old allocs new allocs delta
BenchmarkGunzip 90702 148519 +63.74%
benchmark old bytes new bytes delta
BenchmarkGunzip 9959528 12739528 +27.91%
Similar speedups to those bradfitz saw in https://golang.org/cl/13416045.
Fixes#6317.
Fixes#7950.
LGTM=nigeltao
R=golang-codereviews, bradfitz, dan.kortschak, adg, nigeltao, jamesr
CC=golang-codereviews
https://golang.org/cl/97140043
This is a day 1 error in the flag package: It did not check
that a flag was set at most once on the command line.
Because user-defined flags may have more general
properties, the check applies only to the standard flag
types in this package: bool, string, etc.
Fixes#8960.
LGTM=bradfitz
R=golang-codereviews, bradfitz
CC=golang-codereviews
https://golang.org/cl/156390043
select {
case <- c:
case <- c:
}
In this case, c.recvq lists two SudoGs which have the same G.
So we can't use the G as the key to dequeue the correct SudoG,
as that key is ambiguous. Dequeueing the wrong SudoG ends up
freeing a SudoG that is still in c.recvq.
The fix is to use the actual SudoG pointer as the key.
LGTM=dvyukov
R=rsc, bradfitz, dvyukov, khr
CC=austin, golang-codereviews
https://golang.org/cl/159040043
Simple bug in argument processing: The final arg may
be the pipeline value, in which case it gets bound to the
fixed argument section. The code got that wrong. Easy
to fix.
Fixes#8950.
LGTM=bradfitz
R=golang-codereviews, bradfitz
CC=golang-codereviews
https://golang.org/cl/161750043
Bytes buffers have more API and are a little slower. Since appending
is a key part of the path in encode, using a faster implementation
speeds things up measurably.
The couple of positive swings are likely garbage-collection related
since memory allocation looks different in the benchmark now.
I am not concerned by them.
benchmark old ns/op new ns/op delta
BenchmarkEndToEndPipe 6620 6388 -3.50%
BenchmarkEndToEndByteBuffer 3548 3600 +1.47%
BenchmarkEndToEndSliceByteBuffer 336678 367980 +9.30%
BenchmarkEncodeComplex128Slice 78199 71297 -8.83%
BenchmarkEncodeFloat64Slice 37731 32258 -14.51%
BenchmarkEncodeInt32Slice 26780 22977 -14.20%
BenchmarkEncodeStringSlice 35882 26492 -26.17%
BenchmarkDecodeComplex128Slice 194819 185126 -4.98%
BenchmarkDecodeFloat64Slice 120538 120102 -0.36%
BenchmarkDecodeInt32Slice 106442 107275 +0.78%
BenchmarkDecodeStringSlice 272902 269866 -1.11%
LGTM=ruiu
R=golang-codereviews, ruiu
CC=golang-codereviews
https://golang.org/cl/160990043
Use go generate to write better loops for decoding arrays,
just as we did for encoding. It doesn't help as much,
relatively speaking, but it's still noticeable.
benchmark old ns/op new ns/op delta
BenchmarkDecodeComplex128Slice 202348 184529 -8.81%
BenchmarkDecodeFloat64Slice 135800 120979 -10.91%
BenchmarkDecodeInt32Slice 121200 105149 -13.24%
BenchmarkDecodeStringSlice 288129 278214 -3.44%
LGTM=rsc
R=rsc
CC=golang-codereviews
https://golang.org/cl/154420044
Don't use cmd/pprof as it is not necessary installed
and does not work on nacl and plan9.
Instead just look at the raw profile.
LGTM=crawshaw, rsc
R=golang-codereviews, crawshaw, 0intro, rsc
CC=golang-codereviews
https://golang.org/cl/159010043
Better to avoid the memory loads and just use immediate constants.
This especially applies to zeroing, which was being done by
copying zeros from elsewhere in the binary, even if the value
was going to be completely initialized with non-zero values.
The zero writes were optimized away but the zero loads from
the data segment were not.
LGTM=r
R=r, bradfitz, dvyukov
CC=golang-codereviews
https://golang.org/cl/152700045