[chore] Validate/set account domain (#619)

* add miekg/dns dependency

* set/validate accountDomain
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tobi 2022-06-11 11:09:31 +02:00 committed by GitHub
parent dfdc473cef
commit cf5c6d724d
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304 changed files with 34218 additions and 1 deletions

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@ -224,6 +224,7 @@ The following libraries and frameworks are used by GoToSocial, with gratitude
- [jackc/pgx](https://github.com/jackc/pgx); Postgres driver. [MIT License](https://spdx.org/licenses/MIT.html).
- [mcuadros/go-syslog](https://github.com/mcuadros/go-syslog); Syslog server library. [MIT License](https://spdx.org/licenses/MIT.html).
- [microcosm-cc/bluemonday](https://github.com/microcosm-cc/bluemonday); HTML user-input sanitization. [BSD-3-Clause License](https://spdx.org/licenses/BSD-3-Clause.html).
- [miekg/dns](https://github.com/miekg/dns); DNS utilities. [Go License](https://go.dev/LICENSE).
- [mitchellh/mapstructure](https://github.com/mitchellh/mapstructure); Go interface => struct parsing. [MIT License](https://spdx.org/licenses/MIT.html).
- [modernc.org/sqlite](https://gitlab.com/cznic/sqlite); cgo-free port of SQLite. [Other License](https://gitlab.com/cznic/sqlite/-/blob/master/LICENSE).
- [modernc.org/ccgo](https://gitlab.com/cznic/ccgo); c99 AST -> Go translater. [BSD-3-Clause License](https://spdx.org/licenses/BSD-3-Clause.html).

1
go.mod
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@ -94,6 +94,7 @@ require (
github.com/leodido/go-urn v1.2.1 // indirect
github.com/magiconair/properties v1.8.6 // indirect
github.com/mattn/go-isatty v0.0.14 // indirect
github.com/miekg/dns v1.1.49 // indirect
github.com/modern-go/concurrent v0.0.0-20180306012644-bacd9c7ef1dd // indirect
github.com/modern-go/reflect2 v1.0.2 // indirect
github.com/pelletier/go-toml v1.9.5 // indirect

10
go.sum
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@ -391,6 +391,8 @@ github.com/mattn/go-sqlite3 v1.14.12/go.mod h1:NyWgC/yNuGj7Q9rpYnZvas74GogHl5/Z4
github.com/mattn/go-sqlite3 v2.0.3+incompatible h1:gXHsfypPkaMZrKbD5209QV9jbUTJKjyR5WD3HYQSd+U=
github.com/microcosm-cc/bluemonday v1.0.18 h1:6HcxvXDAi3ARt3slx6nTesbvorIc3QeTzBNRvWktHBo=
github.com/microcosm-cc/bluemonday v1.0.18/go.mod h1:Z0r70sCuXHig8YpBzCc5eGHAap2K7e/u082ZUpDRRqM=
github.com/miekg/dns v1.1.49 h1:qe0mQU3Z/XpFeE+AEBo2rqaS1IPBJ3anmqZ4XiZJVG8=
github.com/miekg/dns v1.1.49/go.mod h1:e3IlAVfNqAllflbibAZEWOXOQ+Ynzk/dDozDxY7XnME=
github.com/mitchellh/mapstructure v1.5.0 h1:jeMsZIYE/09sWLaz43PL7Gy6RuMjD2eJVyuac5Z2hdY=
github.com/mitchellh/mapstructure v1.5.0/go.mod h1:bFUtVrKA4DC2yAKiSyO/QUcy7e+RRV2QTWOzhPopBRo=
github.com/modern-go/concurrent v0.0.0-20180228061459-e0a39a4cb421/go.mod h1:6dJC0mAP4ikYIbvyc7fijjWJddQyLn8Ig3JB5CqoB9Q=
@ -551,6 +553,7 @@ github.com/yuin/goldmark v1.1.25/go.mod h1:3hX8gzYuyVAZsxl0MRgGTJEmQBFcNTphYh9de
github.com/yuin/goldmark v1.1.27/go.mod h1:3hX8gzYuyVAZsxl0MRgGTJEmQBFcNTphYh9decYSb74=
github.com/yuin/goldmark v1.1.32/go.mod h1:3hX8gzYuyVAZsxl0MRgGTJEmQBFcNTphYh9decYSb74=
github.com/yuin/goldmark v1.2.1/go.mod h1:3hX8gzYuyVAZsxl0MRgGTJEmQBFcNTphYh9decYSb74=
github.com/yuin/goldmark v1.3.5/go.mod h1:mwnBkeHKe2W/ZEtQ+71ViKU8L12m81fl3OWwC1Zlc8k=
github.com/zeebo/assert v1.1.0/go.mod h1:Pq9JiuJQpG8JLJdtkwrJESF0Foym2/D9XMU5ciN/wJ0=
github.com/zeebo/blake3 v0.2.1/go.mod h1:TSQ0KjMH+pht+bRyvVooJ1rBpvvngSGaPISafq9MxJk=
github.com/zeebo/pcg v1.0.1/go.mod h1:09F0S9iiKrwn9rlI5yjLkmrug154/YRW6KnnXVDM/l4=
@ -622,6 +625,7 @@ golang.org/x/mod v0.2.0/go.mod h1:s0Qsj1ACt9ePp/hMypM3fl4fZqREWJwdYDEqhRiZZUA=
golang.org/x/mod v0.3.0/go.mod h1:s0Qsj1ACt9ePp/hMypM3fl4fZqREWJwdYDEqhRiZZUA=
golang.org/x/mod v0.4.0/go.mod h1:s0Qsj1ACt9ePp/hMypM3fl4fZqREWJwdYDEqhRiZZUA=
golang.org/x/mod v0.4.1/go.mod h1:s0Qsj1ACt9ePp/hMypM3fl4fZqREWJwdYDEqhRiZZUA=
golang.org/x/mod v0.4.2/go.mod h1:s0Qsj1ACt9ePp/hMypM3fl4fZqREWJwdYDEqhRiZZUA=
golang.org/x/mod v0.6.0-dev.0.20220419223038-86c51ed26bb4 h1:6zppjxzCulZykYSLyVDYbneBfbaBIQPYMevg0bEwv2s=
golang.org/x/mod v0.6.0-dev.0.20220419223038-86c51ed26bb4/go.mod h1:jJ57K6gSWd91VN4djpZkiMVwK6gcyfeH4XE8wZrZaV4=
golang.org/x/net v0.0.0-20180724234803-3673e40ba225/go.mod h1:mL1N/T3taQHkDXs73rZJwtUhF3w3ftmwwsq0BUmARs4=
@ -660,7 +664,9 @@ golang.org/x/net v0.0.0-20201031054903-ff519b6c9102/go.mod h1:sp8m0HH+o8qH0wwXwY
golang.org/x/net v0.0.0-20201209123823-ac852fbbde11/go.mod h1:m0MpNAwzfU5UDzcl9v0D8zg8gWTRqZa9RBIspLL5mdg=
golang.org/x/net v0.0.0-20201224014010-6772e930b67b/go.mod h1:m0MpNAwzfU5UDzcl9v0D8zg8gWTRqZa9RBIspLL5mdg=
golang.org/x/net v0.0.0-20210226172049-e18ecbb05110/go.mod h1:m0MpNAwzfU5UDzcl9v0D8zg8gWTRqZa9RBIspLL5mdg=
golang.org/x/net v0.0.0-20210405180319-a5a99cb37ef4/go.mod h1:p54w0d4576C0XHj96bSt6lcn1PtDYWL6XObtHCRCNQM=
golang.org/x/net v0.0.0-20210614182718-04defd469f4e/go.mod h1:9nx3DQGgdP8bBQD5qxJ1jj9UTztislL4KSBs9R2vV5Y=
golang.org/x/net v0.0.0-20210726213435-c6fcb2dbf985/go.mod h1:9nx3DQGgdP8bBQD5qxJ1jj9UTztislL4KSBs9R2vV5Y=
golang.org/x/net v0.0.0-20211112202133-69e39bad7dc2/go.mod h1:9nx3DQGgdP8bBQD5qxJ1jj9UTztislL4KSBs9R2vV5Y=
golang.org/x/net v0.0.0-20220127200216-cd36cc0744dd/go.mod h1:CfG3xpIq0wQ8r1q4Su4UZFWDARRcnwPjda9FqA0JpMk=
golang.org/x/net v0.0.0-20220524220425-1d687d428aca h1:xTaFYiPROfpPhqrfTIDXj0ri1SpfueYT951s4bAuDO8=
@ -687,6 +693,7 @@ golang.org/x/sync v0.0.0-20200317015054-43a5402ce75a/go.mod h1:RxMgew5VJxzue5/jJ
golang.org/x/sync v0.0.0-20200625203802-6e8e738ad208/go.mod h1:RxMgew5VJxzue5/jJTE5uejpjVlOe/izrB70Jof72aM=
golang.org/x/sync v0.0.0-20201020160332-67f06af15bc9/go.mod h1:RxMgew5VJxzue5/jJTE5uejpjVlOe/izrB70Jof72aM=
golang.org/x/sync v0.0.0-20201207232520-09787c993a3a/go.mod h1:RxMgew5VJxzue5/jJTE5uejpjVlOe/izrB70Jof72aM=
golang.org/x/sync v0.0.0-20210220032951-036812b2e83c/go.mod h1:RxMgew5VJxzue5/jJTE5uejpjVlOe/izrB70Jof72aM=
golang.org/x/sys v0.0.0-20180830151530-49385e6e1522/go.mod h1:STP8DvDyc/dI5b8T5hshtkjS+E42TnysNCUPdjciGhY=
golang.org/x/sys v0.0.0-20180905080454-ebe1bf3edb33/go.mod h1:STP8DvDyc/dI5b8T5hshtkjS+E42TnysNCUPdjciGhY=
golang.org/x/sys v0.0.0-20180909124046-d0be0721c37e/go.mod h1:STP8DvDyc/dI5b8T5hshtkjS+E42TnysNCUPdjciGhY=
@ -732,8 +739,10 @@ golang.org/x/sys v0.0.0-20201201145000-ef89a241ccb3/go.mod h1:h1NjWce9XRLGQEsW7w
golang.org/x/sys v0.0.0-20210104204734-6f8348627aad/go.mod h1:h1NjWce9XRLGQEsW7wpKNCjG9DtNlClVuFLEZdDNbEs=
golang.org/x/sys v0.0.0-20210119212857-b64e53b001e4/go.mod h1:h1NjWce9XRLGQEsW7wpKNCjG9DtNlClVuFLEZdDNbEs=
golang.org/x/sys v0.0.0-20210225134936-a50acf3fe073/go.mod h1:h1NjWce9XRLGQEsW7wpKNCjG9DtNlClVuFLEZdDNbEs=
golang.org/x/sys v0.0.0-20210330210617-4fbd30eecc44/go.mod h1:h1NjWce9XRLGQEsW7wpKNCjG9DtNlClVuFLEZdDNbEs=
golang.org/x/sys v0.0.0-20210423082822-04245dca01da/go.mod h1:h1NjWce9XRLGQEsW7wpKNCjG9DtNlClVuFLEZdDNbEs=
golang.org/x/sys v0.0.0-20210423185535-09eb48e85fd7/go.mod h1:h1NjWce9XRLGQEsW7wpKNCjG9DtNlClVuFLEZdDNbEs=
golang.org/x/sys v0.0.0-20210510120138-977fb7262007/go.mod h1:oPkhp1MJrh7nUepCBck5+mAzfO9JrbApNNgaTdGDITg=
golang.org/x/sys v0.0.0-20210615035016-665e8c7367d1/go.mod h1:oPkhp1MJrh7nUepCBck5+mAzfO9JrbApNNgaTdGDITg=
golang.org/x/sys v0.0.0-20210630005230-0f9fa26af87c/go.mod h1:oPkhp1MJrh7nUepCBck5+mAzfO9JrbApNNgaTdGDITg=
golang.org/x/sys v0.0.0-20210806184541-e5e7981a1069/go.mod h1:oPkhp1MJrh7nUepCBck5+mAzfO9JrbApNNgaTdGDITg=
@ -812,6 +821,7 @@ golang.org/x/tools v0.0.0-20201208233053-a543418bbed2/go.mod h1:emZCQorbCU4vsT4f
golang.org/x/tools v0.0.0-20210105154028-b0ab187a4818/go.mod h1:emZCQorbCU4vsT4fOWvOPXz4eW1wZW4PmDk9uLelYpA=
golang.org/x/tools v0.0.0-20210108195828-e2f9c7f1fc8e/go.mod h1:emZCQorbCU4vsT4fOWvOPXz4eW1wZW4PmDk9uLelYpA=
golang.org/x/tools v0.1.0/go.mod h1:xkSsbof2nBLbhDlRMhhhyNLN/zl3eTqcnHD5viDpcZ0=
golang.org/x/tools v0.1.6-0.20210726203631-07bc1bf47fb2/go.mod h1:o0xws9oXOQQZyjljx8fwUC0k7L1pTE6eaCbjGeHmOkk=
golang.org/x/tools v0.1.10 h1:QjFRCZxdOhBJ/UNgnBZLbNV13DlbnK0quyivTnXJM20=
golang.org/x/tools v0.1.10/go.mod h1:Uh6Zz+xoGYZom868N8YTex3t7RhtHDBrE8Gzo9bV56E=
golang.org/x/xerrors v0.0.0-20190410155217-1f06c39b4373/go.mod h1:I/5z698sn9Ka8TeJc9MKroUUfqBBauWjQqLJ2OPfmY0=

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@ -23,6 +23,7 @@
"fmt"
"strings"
"github.com/miekg/dns"
"github.com/sirupsen/logrus"
)
@ -31,10 +32,23 @@ func Validate() error {
errs := []error{}
// host
if GetHost() == "" {
host := GetHost()
if host == "" {
errs = append(errs, fmt.Errorf("%s must be set", HostFlag()))
}
// accountDomain; only check if host was set, otherwise there's no point
if host != "" {
switch ad := GetAccountDomain(); ad {
case "":
SetAccountDomain(GetHost())
default:
if !dns.IsSubDomain(ad, host) {
errs = append(errs, fmt.Errorf("%s was %s and %s was %s, but %s is not a valid subdomain of %s", HostFlag(), host, AccountDomainFlag(), ad, host, ad))
}
}
}
// protocol
switch proto := GetProtocol(); proto {
case "https":

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@ -46,6 +46,54 @@ func (suite *ConfigValidateTestSuite) TestValidateConfigNoHost() {
suite.EqualError(err, "host must be set")
}
func (suite *ConfigValidateTestSuite) TestValidateAccountDomainOK1() {
testrig.InitTestConfig()
err := config.Validate()
suite.NoError(err)
suite.Equal(config.GetHost(), config.GetAccountDomain())
}
func (suite *ConfigValidateTestSuite) TestValidateAccountDomainOK2() {
testrig.InitTestConfig()
config.SetAccountDomain("localhost:8080")
err := config.Validate()
suite.NoError(err)
}
func (suite *ConfigValidateTestSuite) TestValidateAccountDomainOK3() {
testrig.InitTestConfig()
config.SetHost("gts.example.org")
config.SetAccountDomain("example.org")
err := config.Validate()
suite.NoError(err)
}
func (suite *ConfigValidateTestSuite) TestValidateAccountDomainNotSubdomain1() {
testrig.InitTestConfig()
config.SetHost("gts.example.org")
config.SetAccountDomain("example.com")
err := config.Validate()
suite.EqualError(err, "host was gts.example.org and account-domain was example.com, but gts.example.org is not a valid subdomain of example.com")
}
func (suite *ConfigValidateTestSuite) TestValidateAccountDomainNotSubdomain2() {
testrig.InitTestConfig()
config.SetHost("example.org")
config.SetAccountDomain("gts.example.org")
err := config.Validate()
suite.EqualError(err, "host was example.org and account-domain was gts.example.org, but example.org is not a valid subdomain of gts.example.org")
}
func (suite *ConfigValidateTestSuite) TestValidateConfigNoProtocol() {
testrig.InitTestConfig()

8
vendor/github.com/miekg/dns/.codecov.yml generated vendored Normal file
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@ -0,0 +1,8 @@
coverage:
status:
project:
default:
target: 40%
threshold: null
patch: false
changes: false

4
vendor/github.com/miekg/dns/.gitignore generated vendored Normal file
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@ -0,0 +1,4 @@
*.6
tags
test.out
a.out

1
vendor/github.com/miekg/dns/AUTHORS generated vendored Normal file
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@ -0,0 +1 @@
Miek Gieben <miek@miek.nl>

1
vendor/github.com/miekg/dns/CODEOWNERS generated vendored Normal file
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@ -0,0 +1 @@
* @miekg @tmthrgd

10
vendor/github.com/miekg/dns/CONTRIBUTORS generated vendored Normal file
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@ -0,0 +1,10 @@
Alex A. Skinner
Andrew Tunnell-Jones
Ask Bjørn Hansen
Dave Cheney
Dusty Wilson
Marek Majkowski
Peter van Dijk
Omri Bahumi
Alex Sergeyev
James Hartig

9
vendor/github.com/miekg/dns/COPYRIGHT generated vendored Normal file
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@ -0,0 +1,9 @@
Copyright 2009 The Go Authors. All rights reserved. Use of this source code
is governed by a BSD-style license that can be found in the LICENSE file.
Extensions of the original work are copyright (c) 2011 Miek Gieben
Copyright 2011 Miek Gieben. All rights reserved. Use of this source code is
governed by a BSD-style license that can be found in the LICENSE file.
Copyright 2014 CloudFlare. All rights reserved. Use of this source code is
governed by a BSD-style license that can be found in the LICENSE file.

30
vendor/github.com/miekg/dns/LICENSE generated vendored Normal file
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@ -0,0 +1,30 @@
Copyright (c) 2009 The Go Authors. All rights reserved.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
* Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
* Redistributions in binary form must reproduce the above
copyright notice, this list of conditions and the following disclaimer
in the documentation and/or other materials provided with the
distribution.
* Neither the name of Google Inc. nor the names of its
contributors may be used to endorse or promote products derived from
this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
As this is fork of the official Go code the same license applies.
Extensions of the original work are copyright (c) 2011 Miek Gieben

33
vendor/github.com/miekg/dns/Makefile.fuzz generated vendored Normal file
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@ -0,0 +1,33 @@
# Makefile for fuzzing
#
# Use go-fuzz and needs the tools installed.
# See https://blog.cloudflare.com/dns-parser-meet-go-fuzzer/
#
# Installing go-fuzz:
# $ make -f Makefile.fuzz get
# Installs:
# * github.com/dvyukov/go-fuzz/go-fuzz
# * get github.com/dvyukov/go-fuzz/go-fuzz-build
all: build
.PHONY: build
build:
go-fuzz-build -tags fuzz github.com/miekg/dns
.PHONY: build-newrr
build-newrr:
go-fuzz-build -func FuzzNewRR -tags fuzz github.com/miekg/dns
.PHONY: fuzz
fuzz:
go-fuzz -bin=dns-fuzz.zip -workdir=fuzz
.PHONY: get
get:
go get github.com/dvyukov/go-fuzz/go-fuzz
go get github.com/dvyukov/go-fuzz/go-fuzz-build
.PHONY: clean
clean:
rm *-fuzz.zip

52
vendor/github.com/miekg/dns/Makefile.release generated vendored Normal file
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@ -0,0 +1,52 @@
# Makefile for releasing.
#
# The release is controlled from version.go. The version found there is
# used to tag the git repo, we're not building any artifacts so there is nothing
# to upload to github.
#
# * Up the version in version.go
# * Run: make -f Makefile.release release
# * will *commit* your change with 'Release $VERSION'
# * push to github
#
define GO
//+build ignore
package main
import (
"fmt"
"github.com/miekg/dns"
)
func main() {
fmt.Println(dns.Version.String())
}
endef
$(file > version_release.go,$(GO))
VERSION:=$(shell go run version_release.go)
TAG="v$(VERSION)"
all:
@echo Use the \'release\' target to start a release $(VERSION)
rm -f version_release.go
.PHONY: release
release: commit push
@echo Released $(VERSION)
rm -f version_release.go
.PHONY: commit
commit:
@echo Committing release $(VERSION)
git commit -am"Release $(VERSION)"
git tag $(TAG)
.PHONY: push
push:
@echo Pushing release $(VERSION) to master
git push --tags
git push

186
vendor/github.com/miekg/dns/README.md generated vendored Normal file
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@ -0,0 +1,186 @@
[![Build Status](https://travis-ci.org/miekg/dns.svg?branch=master)](https://travis-ci.org/miekg/dns)
[![Code Coverage](https://img.shields.io/codecov/c/github/miekg/dns/master.svg)](https://codecov.io/github/miekg/dns?branch=master)
[![Go Report Card](https://goreportcard.com/badge/github.com/miekg/dns)](https://goreportcard.com/report/miekg/dns)
[![](https://godoc.org/github.com/miekg/dns?status.svg)](https://godoc.org/github.com/miekg/dns)
# Alternative (more granular) approach to a DNS library
> Less is more.
Complete and usable DNS library. All Resource Records are supported, including the DNSSEC types.
It follows a lean and mean philosophy. If there is stuff you should know as a DNS programmer there
isn't a convenience function for it. Server side and client side programming is supported, i.e. you
can build servers and resolvers with it.
We try to keep the "master" branch as sane as possible and at the bleeding edge of standards,
avoiding breaking changes wherever reasonable. We support the last two versions of Go.
# Goals
* KISS;
* Fast;
* Small API. If it's easy to code in Go, don't make a function for it.
# Users
A not-so-up-to-date-list-that-may-be-actually-current:
* https://github.com/coredns/coredns
* https://github.com/abh/geodns
* https://github.com/baidu/bfe
* http://www.statdns.com/
* http://www.dnsinspect.com/
* https://github.com/chuangbo/jianbing-dictionary-dns
* http://www.dns-lg.com/
* https://github.com/fcambus/rrda
* https://github.com/kenshinx/godns
* https://github.com/skynetservices/skydns
* https://github.com/hashicorp/consul
* https://github.com/DevelopersPL/godnsagent
* https://github.com/duedil-ltd/discodns
* https://github.com/StalkR/dns-reverse-proxy
* https://github.com/tianon/rawdns
* https://mesosphere.github.io/mesos-dns/
* https://github.com/fcambus/statzone
* https://github.com/benschw/dns-clb-go
* https://github.com/corny/dnscheck for <http://public-dns.info/>
* https://github.com/miekg/unbound
* https://github.com/miekg/exdns
* https://dnslookup.org
* https://github.com/looterz/grimd
* https://github.com/phamhongviet/serf-dns
* https://github.com/mehrdadrad/mylg
* https://github.com/bamarni/dockness
* https://github.com/fffaraz/microdns
* https://github.com/ipdcode/hades <https://jd.com>
* https://github.com/StackExchange/dnscontrol/
* https://www.dnsperf.com/
* https://dnssectest.net/
* https://github.com/oif/apex
* https://github.com/jedisct1/dnscrypt-proxy
* https://github.com/jedisct1/rpdns
* https://github.com/xor-gate/sshfp
* https://github.com/rs/dnstrace
* https://blitiri.com.ar/p/dnss ([github mirror](https://github.com/albertito/dnss))
* https://render.com
* https://github.com/peterzen/goresolver
* https://github.com/folbricht/routedns
* https://domainr.com/
* https://zonedb.org/
* https://router7.org/
* https://github.com/fortio/dnsping
* https://github.com/Luzilla/dnsbl_exporter
* https://github.com/bodgit/tsig
* https://github.com/v2fly/v2ray-core (test only)
* https://kuma.io/
* https://www.misaka.io/services/dns
* https://ping.sx/dig
* https://fleetdeck.io/
* https://github.com/markdingo/autoreverse
Send pull request if you want to be listed here.
# Features
* UDP/TCP queries, IPv4 and IPv6
* RFC 1035 zone file parsing ($INCLUDE, $ORIGIN, $TTL and $GENERATE (for all record types) are supported
* Fast
* Server side programming (mimicking the net/http package)
* Client side programming
* DNSSEC: signing, validating and key generation for DSA, RSA, ECDSA and Ed25519
* EDNS0, NSID, Cookies
* AXFR/IXFR
* TSIG, SIG(0)
* DNS over TLS (DoT): encrypted connection between client and server over TCP
* DNS name compression
Have fun!
Miek Gieben - 2010-2012 - <miek@miek.nl>
DNS Authors 2012-
# Building
This library uses Go modules and uses semantic versioning. Building is done with the `go` tool, so
the following should work:
go get github.com/miekg/dns
go build github.com/miekg/dns
## Examples
A short "how to use the API" is at the beginning of doc.go (this also will show when you call `godoc
github.com/miekg/dns`).
Example programs can be found in the `github.com/miekg/exdns` repository.
## Supported RFCs
*all of them*
* 103{4,5} - DNS standard
* 1348 - NSAP record (removed the record)
* 1982 - Serial Arithmetic
* 1876 - LOC record
* 1995 - IXFR
* 1996 - DNS notify
* 2136 - DNS Update (dynamic updates)
* 2181 - RRset definition - there is no RRset type though, just []RR
* 2537 - RSAMD5 DNS keys
* 2065 - DNSSEC (updated in later RFCs)
* 2671 - EDNS record
* 2782 - SRV record
* 2845 - TSIG record
* 2915 - NAPTR record
* 2929 - DNS IANA Considerations
* 3110 - RSASHA1 DNS keys
* 3123 - APL record
* 3225 - DO bit (DNSSEC OK)
* 340{1,2,3} - NAPTR record
* 3445 - Limiting the scope of (DNS)KEY
* 3597 - Unknown RRs
* 403{3,4,5} - DNSSEC + validation functions
* 4255 - SSHFP record
* 4343 - Case insensitivity
* 4408 - SPF record
* 4509 - SHA256 Hash in DS
* 4592 - Wildcards in the DNS
* 4635 - HMAC SHA TSIG
* 4701 - DHCID
* 4892 - id.server
* 5001 - NSID
* 5155 - NSEC3 record
* 5205 - HIP record
* 5702 - SHA2 in the DNS
* 5936 - AXFR
* 5966 - TCP implementation recommendations
* 6605 - ECDSA
* 6725 - IANA Registry Update
* 6742 - ILNP DNS
* 6840 - Clarifications and Implementation Notes for DNS Security
* 6844 - CAA record
* 6891 - EDNS0 update
* 6895 - DNS IANA considerations
* 6944 - DNSSEC DNSKEY Algorithm Status
* 6975 - Algorithm Understanding in DNSSEC
* 7043 - EUI48/EUI64 records
* 7314 - DNS (EDNS) EXPIRE Option
* 7477 - CSYNC RR
* 7828 - edns-tcp-keepalive EDNS0 Option
* 7553 - URI record
* 7858 - DNS over TLS: Initiation and Performance Considerations
* 7871 - EDNS0 Client Subnet
* 7873 - Domain Name System (DNS) Cookies
* 8080 - EdDSA for DNSSEC
* 8499 - DNS Terminology
* 8659 - DNS Certification Authority Authorization (CAA) Resource Record
* 8914 - Extended DNS Errors
* 8976 - Message Digest for DNS Zones (ZONEMD RR)
## Loosely Based Upon
* ldns - <https://nlnetlabs.nl/projects/ldns/about/>
* NSD - <https://nlnetlabs.nl/projects/nsd/about/>
* Net::DNS - <http://www.net-dns.org/>
* GRONG - <https://github.com/bortzmeyer/grong>

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vendor/github.com/miekg/dns/acceptfunc.go generated vendored Normal file
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package dns
// MsgAcceptFunc is used early in the server code to accept or reject a message with RcodeFormatError.
// It returns a MsgAcceptAction to indicate what should happen with the message.
type MsgAcceptFunc func(dh Header) MsgAcceptAction
// DefaultMsgAcceptFunc checks the request and will reject if:
//
// * isn't a request (don't respond in that case)
//
// * opcode isn't OpcodeQuery or OpcodeNotify
//
// * Zero bit isn't zero
//
// * does not have exactly 1 question in the question section
//
// * has more than 1 RR in the Answer section
//
// * has more than 0 RRs in the Authority section
//
// * has more than 2 RRs in the Additional section
//
var DefaultMsgAcceptFunc MsgAcceptFunc = defaultMsgAcceptFunc
// MsgAcceptAction represents the action to be taken.
type MsgAcceptAction int
// Allowed returned values from a MsgAcceptFunc.
const (
MsgAccept MsgAcceptAction = iota // Accept the message
MsgReject // Reject the message with a RcodeFormatError
MsgIgnore // Ignore the error and send nothing back.
MsgRejectNotImplemented // Reject the message with a RcodeNotImplemented
)
func defaultMsgAcceptFunc(dh Header) MsgAcceptAction {
if isResponse := dh.Bits&_QR != 0; isResponse {
return MsgIgnore
}
// Don't allow dynamic updates, because then the sections can contain a whole bunch of RRs.
opcode := int(dh.Bits>>11) & 0xF
if opcode != OpcodeQuery && opcode != OpcodeNotify {
return MsgRejectNotImplemented
}
if dh.Qdcount != 1 {
return MsgReject
}
// NOTIFY requests can have a SOA in the ANSWER section. See RFC 1996 Section 3.7 and 3.11.
if dh.Ancount > 1 {
return MsgReject
}
// IXFR request could have one SOA RR in the NS section. See RFC 1995, section 3.
if dh.Nscount > 1 {
return MsgReject
}
if dh.Arcount > 2 {
return MsgReject
}
return MsgAccept
}

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vendor/github.com/miekg/dns/client.go generated vendored Normal file
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package dns
// A client implementation.
import (
"context"
"crypto/tls"
"encoding/binary"
"fmt"
"io"
"net"
"strings"
"time"
)
const (
dnsTimeout time.Duration = 2 * time.Second
tcpIdleTimeout time.Duration = 8 * time.Second
)
func isPacketConn(c net.Conn) bool {
if _, ok := c.(net.PacketConn); !ok {
return false
}
if ua, ok := c.LocalAddr().(*net.UnixAddr); ok {
return ua.Net == "unixgram"
}
return true
}
// A Conn represents a connection to a DNS server.
type Conn struct {
net.Conn // a net.Conn holding the connection
UDPSize uint16 // minimum receive buffer for UDP messages
TsigSecret map[string]string // secret(s) for Tsig map[<zonename>]<base64 secret>, zonename must be in canonical form (lowercase, fqdn, see RFC 4034 Section 6.2)
TsigProvider TsigProvider // An implementation of the TsigProvider interface. If defined it replaces TsigSecret and is used for all TSIG operations.
tsigRequestMAC string
}
func (co *Conn) tsigProvider() TsigProvider {
if co.TsigProvider != nil {
return co.TsigProvider
}
// tsigSecretProvider will return ErrSecret if co.TsigSecret is nil.
return tsigSecretProvider(co.TsigSecret)
}
// A Client defines parameters for a DNS client.
type Client struct {
Net string // if "tcp" or "tcp-tls" (DNS over TLS) a TCP query will be initiated, otherwise an UDP one (default is "" for UDP)
UDPSize uint16 // minimum receive buffer for UDP messages
TLSConfig *tls.Config // TLS connection configuration
Dialer *net.Dialer // a net.Dialer used to set local address, timeouts and more
// Timeout is a cumulative timeout for dial, write and read, defaults to 0 (disabled) - overrides DialTimeout, ReadTimeout,
// WriteTimeout when non-zero. Can be overridden with net.Dialer.Timeout (see Client.ExchangeWithDialer and
// Client.Dialer) or context.Context.Deadline (see ExchangeContext)
Timeout time.Duration
DialTimeout time.Duration // net.DialTimeout, defaults to 2 seconds, or net.Dialer.Timeout if expiring earlier - overridden by Timeout when that value is non-zero
ReadTimeout time.Duration // net.Conn.SetReadTimeout value for connections, defaults to 2 seconds - overridden by Timeout when that value is non-zero
WriteTimeout time.Duration // net.Conn.SetWriteTimeout value for connections, defaults to 2 seconds - overridden by Timeout when that value is non-zero
TsigSecret map[string]string // secret(s) for Tsig map[<zonename>]<base64 secret>, zonename must be in canonical form (lowercase, fqdn, see RFC 4034 Section 6.2)
TsigProvider TsigProvider // An implementation of the TsigProvider interface. If defined it replaces TsigSecret and is used for all TSIG operations.
SingleInflight bool // if true suppress multiple outstanding queries for the same Qname, Qtype and Qclass
group singleflight
}
// Exchange performs a synchronous UDP query. It sends the message m to the address
// contained in a and waits for a reply. Exchange does not retry a failed query, nor
// will it fall back to TCP in case of truncation.
// See client.Exchange for more information on setting larger buffer sizes.
func Exchange(m *Msg, a string) (r *Msg, err error) {
client := Client{Net: "udp"}
r, _, err = client.Exchange(m, a)
return r, err
}
func (c *Client) dialTimeout() time.Duration {
if c.Timeout != 0 {
return c.Timeout
}
if c.DialTimeout != 0 {
return c.DialTimeout
}
return dnsTimeout
}
func (c *Client) readTimeout() time.Duration {
if c.ReadTimeout != 0 {
return c.ReadTimeout
}
return dnsTimeout
}
func (c *Client) writeTimeout() time.Duration {
if c.WriteTimeout != 0 {
return c.WriteTimeout
}
return dnsTimeout
}
// Dial connects to the address on the named network.
func (c *Client) Dial(address string) (conn *Conn, err error) {
return c.DialContext(context.Background(), address)
}
// DialContext connects to the address on the named network, with a context.Context.
// For TLS over TCP (DoT) the context isn't used yet. This will be enabled when Go 1.18 is released.
func (c *Client) DialContext(ctx context.Context, address string) (conn *Conn, err error) {
// create a new dialer with the appropriate timeout
var d net.Dialer
if c.Dialer == nil {
d = net.Dialer{Timeout: c.getTimeoutForRequest(c.dialTimeout())}
} else {
d = *c.Dialer
}
network := c.Net
if network == "" {
network = "udp"
}
useTLS := strings.HasPrefix(network, "tcp") && strings.HasSuffix(network, "-tls")
conn = new(Conn)
if useTLS {
network = strings.TrimSuffix(network, "-tls")
// TODO(miekg): Enable after Go 1.18 is released, to be able to support two prev. releases.
/*
tlsDialer := tls.Dialer{
NetDialer: &d,
Config: c.TLSConfig,
}
conn.Conn, err = tlsDialer.DialContext(ctx, network, address)
*/
conn.Conn, err = tls.DialWithDialer(&d, network, address, c.TLSConfig)
} else {
conn.Conn, err = d.DialContext(ctx, network, address)
}
if err != nil {
return nil, err
}
conn.UDPSize = c.UDPSize
return conn, nil
}
// Exchange performs a synchronous query. It sends the message m to the address
// contained in a and waits for a reply. Basic use pattern with a *dns.Client:
//
// c := new(dns.Client)
// in, rtt, err := c.Exchange(message, "127.0.0.1:53")
//
// Exchange does not retry a failed query, nor will it fall back to TCP in
// case of truncation.
// It is up to the caller to create a message that allows for larger responses to be
// returned. Specifically this means adding an EDNS0 OPT RR that will advertise a larger
// buffer, see SetEdns0. Messages without an OPT RR will fallback to the historic limit
// of 512 bytes
// To specify a local address or a timeout, the caller has to set the `Client.Dialer`
// attribute appropriately
func (c *Client) Exchange(m *Msg, address string) (r *Msg, rtt time.Duration, err error) {
co, err := c.Dial(address)
if err != nil {
return nil, 0, err
}
defer co.Close()
return c.ExchangeWithConn(m, co)
}
// ExchangeWithConn has the same behavior as Exchange, just with a predetermined connection
// that will be used instead of creating a new one.
// Usage pattern with a *dns.Client:
//
// c := new(dns.Client)
// // connection management logic goes here
//
// conn := c.Dial(address)
// in, rtt, err := c.ExchangeWithConn(message, conn)
//
// This allows users of the library to implement their own connection management,
// as opposed to Exchange, which will always use new connections and incur the added overhead
// that entails when using "tcp" and especially "tcp-tls" clients.
//
// When the singleflight is set for this client the context is _not_ forwarded to the (shared) exchange, to
// prevent one cancelation from canceling all outstanding requests.
func (c *Client) ExchangeWithConn(m *Msg, conn *Conn) (r *Msg, rtt time.Duration, err error) {
return c.exchangeWithConnContext(context.Background(), m, conn)
}
func (c *Client) exchangeWithConnContext(ctx context.Context, m *Msg, conn *Conn) (r *Msg, rtt time.Duration, err error) {
if !c.SingleInflight {
return c.exchangeContext(ctx, m, conn)
}
q := m.Question[0]
key := fmt.Sprintf("%s:%d:%d", q.Name, q.Qtype, q.Qclass)
r, rtt, err, shared := c.group.Do(key, func() (*Msg, time.Duration, error) {
// When we're doing singleflight we don't want one context cancelation, cancel _all_ outstanding queries.
// Hence we ignore the context and use Background().
return c.exchangeContext(context.Background(), m, conn)
})
if r != nil && shared {
r = r.Copy()
}
return r, rtt, err
}
func (c *Client) exchangeContext(ctx context.Context, m *Msg, co *Conn) (r *Msg, rtt time.Duration, err error) {
opt := m.IsEdns0()
// If EDNS0 is used use that for size.
if opt != nil && opt.UDPSize() >= MinMsgSize {
co.UDPSize = opt.UDPSize()
}
// Otherwise use the client's configured UDP size.
if opt == nil && c.UDPSize >= MinMsgSize {
co.UDPSize = c.UDPSize
}
// write with the appropriate write timeout
t := time.Now()
writeDeadline := t.Add(c.getTimeoutForRequest(c.writeTimeout()))
readDeadline := t.Add(c.getTimeoutForRequest(c.readTimeout()))
if deadline, ok := ctx.Deadline(); ok {
if deadline.Before(writeDeadline) {
writeDeadline = deadline
}
if deadline.Before(readDeadline) {
readDeadline = deadline
}
}
co.SetWriteDeadline(writeDeadline)
co.SetReadDeadline(readDeadline)
co.TsigSecret, co.TsigProvider = c.TsigSecret, c.TsigProvider
if err = co.WriteMsg(m); err != nil {
return nil, 0, err
}
if isPacketConn(co.Conn) {
for {
r, err = co.ReadMsg()
// Ignore replies with mismatched IDs because they might be
// responses to earlier queries that timed out.
if err != nil || r.Id == m.Id {
break
}
}
} else {
r, err = co.ReadMsg()
if err == nil && r.Id != m.Id {
err = ErrId
}
}
rtt = time.Since(t)
return r, rtt, err
}
// ReadMsg reads a message from the connection co.
// If the received message contains a TSIG record the transaction signature
// is verified. This method always tries to return the message, however if an
// error is returned there are no guarantees that the returned message is a
// valid representation of the packet read.
func (co *Conn) ReadMsg() (*Msg, error) {
p, err := co.ReadMsgHeader(nil)
if err != nil {
return nil, err
}
m := new(Msg)
if err := m.Unpack(p); err != nil {
// If an error was returned, we still want to allow the user to use
// the message, but naively they can just check err if they don't want
// to use an erroneous message
return m, err
}
if t := m.IsTsig(); t != nil {
// Need to work on the original message p, as that was used to calculate the tsig.
err = tsigVerifyProvider(p, co.tsigProvider(), co.tsigRequestMAC, false)
}
return m, err
}
// ReadMsgHeader reads a DNS message, parses and populates hdr (when hdr is not nil).
// Returns message as a byte slice to be parsed with Msg.Unpack later on.
// Note that error handling on the message body is not possible as only the header is parsed.
func (co *Conn) ReadMsgHeader(hdr *Header) ([]byte, error) {
var (
p []byte
n int
err error
)
if isPacketConn(co.Conn) {
if co.UDPSize > MinMsgSize {
p = make([]byte, co.UDPSize)
} else {
p = make([]byte, MinMsgSize)
}
n, err = co.Read(p)
} else {
var length uint16
if err := binary.Read(co.Conn, binary.BigEndian, &length); err != nil {
return nil, err
}
p = make([]byte, length)
n, err = io.ReadFull(co.Conn, p)
}
if err != nil {
return nil, err
} else if n < headerSize {
return nil, ErrShortRead
}
p = p[:n]
if hdr != nil {
dh, _, err := unpackMsgHdr(p, 0)
if err != nil {
return nil, err
}
*hdr = dh
}
return p, err
}
// Read implements the net.Conn read method.
func (co *Conn) Read(p []byte) (n int, err error) {
if co.Conn == nil {
return 0, ErrConnEmpty
}
if isPacketConn(co.Conn) {
// UDP connection
return co.Conn.Read(p)
}
var length uint16
if err := binary.Read(co.Conn, binary.BigEndian, &length); err != nil {
return 0, err
}
if int(length) > len(p) {
return 0, io.ErrShortBuffer
}
return io.ReadFull(co.Conn, p[:length])
}
// WriteMsg sends a message through the connection co.
// If the message m contains a TSIG record the transaction
// signature is calculated.
func (co *Conn) WriteMsg(m *Msg) (err error) {
var out []byte
if t := m.IsTsig(); t != nil {
// Set tsigRequestMAC for the next read, although only used in zone transfers.
out, co.tsigRequestMAC, err = tsigGenerateProvider(m, co.tsigProvider(), co.tsigRequestMAC, false)
} else {
out, err = m.Pack()
}
if err != nil {
return err
}
_, err = co.Write(out)
return err
}
// Write implements the net.Conn Write method.
func (co *Conn) Write(p []byte) (int, error) {
if len(p) > MaxMsgSize {
return 0, &Error{err: "message too large"}
}
if isPacketConn(co.Conn) {
return co.Conn.Write(p)
}
msg := make([]byte, 2+len(p))
binary.BigEndian.PutUint16(msg, uint16(len(p)))
copy(msg[2:], p)
return co.Conn.Write(msg)
}
// Return the appropriate timeout for a specific request
func (c *Client) getTimeoutForRequest(timeout time.Duration) time.Duration {
var requestTimeout time.Duration
if c.Timeout != 0 {
requestTimeout = c.Timeout
} else {
requestTimeout = timeout
}
// net.Dialer.Timeout has priority if smaller than the timeouts computed so
// far
if c.Dialer != nil && c.Dialer.Timeout != 0 {
if c.Dialer.Timeout < requestTimeout {
requestTimeout = c.Dialer.Timeout
}
}
return requestTimeout
}
// Dial connects to the address on the named network.
func Dial(network, address string) (conn *Conn, err error) {
conn = new(Conn)
conn.Conn, err = net.Dial(network, address)
if err != nil {
return nil, err
}
return conn, nil
}
// ExchangeContext performs a synchronous UDP query, like Exchange. It
// additionally obeys deadlines from the passed Context.
func ExchangeContext(ctx context.Context, m *Msg, a string) (r *Msg, err error) {
client := Client{Net: "udp"}
r, _, err = client.ExchangeContext(ctx, m, a)
// ignoring rtt to leave the original ExchangeContext API unchanged, but
// this function will go away
return r, err
}
// ExchangeConn performs a synchronous query. It sends the message m via the connection
// c and waits for a reply. The connection c is not closed by ExchangeConn.
// Deprecated: This function is going away, but can easily be mimicked:
//
// co := &dns.Conn{Conn: c} // c is your net.Conn
// co.WriteMsg(m)
// in, _ := co.ReadMsg()
// co.Close()
//
func ExchangeConn(c net.Conn, m *Msg) (r *Msg, err error) {
println("dns: ExchangeConn: this function is deprecated")
co := new(Conn)
co.Conn = c
if err = co.WriteMsg(m); err != nil {
return nil, err
}
r, err = co.ReadMsg()
if err == nil && r.Id != m.Id {
err = ErrId
}
return r, err
}
// DialTimeout acts like Dial but takes a timeout.
func DialTimeout(network, address string, timeout time.Duration) (conn *Conn, err error) {
client := Client{Net: network, Dialer: &net.Dialer{Timeout: timeout}}
return client.Dial(address)
}
// DialWithTLS connects to the address on the named network with TLS.
func DialWithTLS(network, address string, tlsConfig *tls.Config) (conn *Conn, err error) {
if !strings.HasSuffix(network, "-tls") {
network += "-tls"
}
client := Client{Net: network, TLSConfig: tlsConfig}
return client.Dial(address)
}
// DialTimeoutWithTLS acts like DialWithTLS but takes a timeout.
func DialTimeoutWithTLS(network, address string, tlsConfig *tls.Config, timeout time.Duration) (conn *Conn, err error) {
if !strings.HasSuffix(network, "-tls") {
network += "-tls"
}
client := Client{Net: network, Dialer: &net.Dialer{Timeout: timeout}, TLSConfig: tlsConfig}
return client.Dial(address)
}
// ExchangeContext acts like Exchange, but honors the deadline on the provided
// context, if present. If there is both a context deadline and a configured
// timeout on the client, the earliest of the two takes effect.
func (c *Client) ExchangeContext(ctx context.Context, m *Msg, a string) (r *Msg, rtt time.Duration, err error) {
conn, err := c.DialContext(ctx, a)
if err != nil {
return nil, 0, err
}
defer conn.Close()
return c.exchangeWithConnContext(ctx, m, conn)
}

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vendor/github.com/miekg/dns/clientconfig.go generated vendored Normal file
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package dns
import (
"bufio"
"io"
"os"
"strconv"
"strings"
)
// ClientConfig wraps the contents of the /etc/resolv.conf file.
type ClientConfig struct {
Servers []string // servers to use
Search []string // suffixes to append to local name
Port string // what port to use
Ndots int // number of dots in name to trigger absolute lookup
Timeout int // seconds before giving up on packet
Attempts int // lost packets before giving up on server, not used in the package dns
}
// ClientConfigFromFile parses a resolv.conf(5) like file and returns
// a *ClientConfig.
func ClientConfigFromFile(resolvconf string) (*ClientConfig, error) {
file, err := os.Open(resolvconf)
if err != nil {
return nil, err
}
defer file.Close()
return ClientConfigFromReader(file)
}
// ClientConfigFromReader works like ClientConfigFromFile but takes an io.Reader as argument
func ClientConfigFromReader(resolvconf io.Reader) (*ClientConfig, error) {
c := new(ClientConfig)
scanner := bufio.NewScanner(resolvconf)
c.Servers = make([]string, 0)
c.Search = make([]string, 0)
c.Port = "53"
c.Ndots = 1
c.Timeout = 5
c.Attempts = 2
for scanner.Scan() {
if err := scanner.Err(); err != nil {
return nil, err
}
line := scanner.Text()
f := strings.Fields(line)
if len(f) < 1 {
continue
}
switch f[0] {
case "nameserver": // add one name server
if len(f) > 1 {
// One more check: make sure server name is
// just an IP address. Otherwise we need DNS
// to look it up.
name := f[1]
c.Servers = append(c.Servers, name)
}
case "domain": // set search path to just this domain
if len(f) > 1 {
c.Search = make([]string, 1)
c.Search[0] = f[1]
} else {
c.Search = make([]string, 0)
}
case "search": // set search path to given servers
c.Search = append([]string(nil), f[1:]...)
case "options": // magic options
for _, s := range f[1:] {
switch {
case len(s) >= 6 && s[:6] == "ndots:":
n, _ := strconv.Atoi(s[6:])
if n < 0 {
n = 0
} else if n > 15 {
n = 15
}
c.Ndots = n
case len(s) >= 8 && s[:8] == "timeout:":
n, _ := strconv.Atoi(s[8:])
if n < 1 {
n = 1
}
c.Timeout = n
case len(s) >= 9 && s[:9] == "attempts:":
n, _ := strconv.Atoi(s[9:])
if n < 1 {
n = 1
}
c.Attempts = n
case s == "rotate":
/* not imp */
}
}
}
}
return c, nil
}
// NameList returns all of the names that should be queried based on the
// config. It is based off of go's net/dns name building, but it does not
// check the length of the resulting names.
func (c *ClientConfig) NameList(name string) []string {
// if this domain is already fully qualified, no append needed.
if IsFqdn(name) {
return []string{name}
}
// Check to see if the name has more labels than Ndots. Do this before making
// the domain fully qualified.
hasNdots := CountLabel(name) > c.Ndots
// Make the domain fully qualified.
name = Fqdn(name)
// Make a list of names based off search.
names := []string{}
// If name has enough dots, try that first.
if hasNdots {
names = append(names, name)
}
for _, s := range c.Search {
names = append(names, Fqdn(name+s))
}
// If we didn't have enough dots, try after suffixes.
if !hasNdots {
names = append(names, name)
}
return names
}

43
vendor/github.com/miekg/dns/dane.go generated vendored Normal file
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package dns
import (
"crypto/sha256"
"crypto/sha512"
"crypto/x509"
"encoding/hex"
"errors"
)
// CertificateToDANE converts a certificate to a hex string as used in the TLSA or SMIMEA records.
func CertificateToDANE(selector, matchingType uint8, cert *x509.Certificate) (string, error) {
switch matchingType {
case 0:
switch selector {
case 0:
return hex.EncodeToString(cert.Raw), nil
case 1:
return hex.EncodeToString(cert.RawSubjectPublicKeyInfo), nil
}
case 1:
h := sha256.New()
switch selector {
case 0:
h.Write(cert.Raw)
return hex.EncodeToString(h.Sum(nil)), nil
case 1:
h.Write(cert.RawSubjectPublicKeyInfo)
return hex.EncodeToString(h.Sum(nil)), nil
}
case 2:
h := sha512.New()
switch selector {
case 0:
h.Write(cert.Raw)
return hex.EncodeToString(h.Sum(nil)), nil
case 1:
h.Write(cert.RawSubjectPublicKeyInfo)
return hex.EncodeToString(h.Sum(nil)), nil
}
}
return "", errors.New("dns: bad MatchingType or Selector")
}

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vendor/github.com/miekg/dns/defaults.go generated vendored Normal file
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package dns
import (
"errors"
"net"
"strconv"
"strings"
)
const hexDigit = "0123456789abcdef"
// Everything is assumed in ClassINET.
// SetReply creates a reply message from a request message.
func (dns *Msg) SetReply(request *Msg) *Msg {
dns.Id = request.Id
dns.Response = true
dns.Opcode = request.Opcode
if dns.Opcode == OpcodeQuery {
dns.RecursionDesired = request.RecursionDesired // Copy rd bit
dns.CheckingDisabled = request.CheckingDisabled // Copy cd bit
}
dns.Rcode = RcodeSuccess
if len(request.Question) > 0 {
dns.Question = make([]Question, 1)
dns.Question[0] = request.Question[0]
}
return dns
}
// SetQuestion creates a question message, it sets the Question
// section, generates an Id and sets the RecursionDesired (RD)
// bit to true.
func (dns *Msg) SetQuestion(z string, t uint16) *Msg {
dns.Id = Id()
dns.RecursionDesired = true
dns.Question = make([]Question, 1)
dns.Question[0] = Question{z, t, ClassINET}
return dns
}
// SetNotify creates a notify message, it sets the Question
// section, generates an Id and sets the Authoritative (AA)
// bit to true.
func (dns *Msg) SetNotify(z string) *Msg {
dns.Opcode = OpcodeNotify
dns.Authoritative = true
dns.Id = Id()
dns.Question = make([]Question, 1)
dns.Question[0] = Question{z, TypeSOA, ClassINET}
return dns
}
// SetRcode creates an error message suitable for the request.
func (dns *Msg) SetRcode(request *Msg, rcode int) *Msg {
dns.SetReply(request)
dns.Rcode = rcode
return dns
}
// SetRcodeFormatError creates a message with FormError set.
func (dns *Msg) SetRcodeFormatError(request *Msg) *Msg {
dns.Rcode = RcodeFormatError
dns.Opcode = OpcodeQuery
dns.Response = true
dns.Authoritative = false
dns.Id = request.Id
return dns
}
// SetUpdate makes the message a dynamic update message. It
// sets the ZONE section to: z, TypeSOA, ClassINET.
func (dns *Msg) SetUpdate(z string) *Msg {
dns.Id = Id()
dns.Response = false
dns.Opcode = OpcodeUpdate
dns.Compress = false // BIND9 cannot handle compression
dns.Question = make([]Question, 1)
dns.Question[0] = Question{z, TypeSOA, ClassINET}
return dns
}
// SetIxfr creates message for requesting an IXFR.
func (dns *Msg) SetIxfr(z string, serial uint32, ns, mbox string) *Msg {
dns.Id = Id()
dns.Question = make([]Question, 1)
dns.Ns = make([]RR, 1)
s := new(SOA)
s.Hdr = RR_Header{z, TypeSOA, ClassINET, defaultTtl, 0}
s.Serial = serial
s.Ns = ns
s.Mbox = mbox
dns.Question[0] = Question{z, TypeIXFR, ClassINET}
dns.Ns[0] = s
return dns
}
// SetAxfr creates message for requesting an AXFR.
func (dns *Msg) SetAxfr(z string) *Msg {
dns.Id = Id()
dns.Question = make([]Question, 1)
dns.Question[0] = Question{z, TypeAXFR, ClassINET}
return dns
}
// SetTsig appends a TSIG RR to the message.
// This is only a skeleton TSIG RR that is added as the last RR in the
// additional section. The TSIG is calculated when the message is being send.
func (dns *Msg) SetTsig(z, algo string, fudge uint16, timesigned int64) *Msg {
t := new(TSIG)
t.Hdr = RR_Header{z, TypeTSIG, ClassANY, 0, 0}
t.Algorithm = algo
t.Fudge = fudge
t.TimeSigned = uint64(timesigned)
t.OrigId = dns.Id
dns.Extra = append(dns.Extra, t)
return dns
}
// SetEdns0 appends a EDNS0 OPT RR to the message.
// TSIG should always the last RR in a message.
func (dns *Msg) SetEdns0(udpsize uint16, do bool) *Msg {
e := new(OPT)
e.Hdr.Name = "."
e.Hdr.Rrtype = TypeOPT
e.SetUDPSize(udpsize)
if do {
e.SetDo()
}
dns.Extra = append(dns.Extra, e)
return dns
}
// IsTsig checks if the message has a TSIG record as the last record
// in the additional section. It returns the TSIG record found or nil.
func (dns *Msg) IsTsig() *TSIG {
if len(dns.Extra) > 0 {
if dns.Extra[len(dns.Extra)-1].Header().Rrtype == TypeTSIG {
return dns.Extra[len(dns.Extra)-1].(*TSIG)
}
}
return nil
}
// IsEdns0 checks if the message has a EDNS0 (OPT) record, any EDNS0
// record in the additional section will do. It returns the OPT record
// found or nil.
func (dns *Msg) IsEdns0() *OPT {
// RFC 6891, Section 6.1.1 allows the OPT record to appear
// anywhere in the additional record section, but it's usually at
// the end so start there.
for i := len(dns.Extra) - 1; i >= 0; i-- {
if dns.Extra[i].Header().Rrtype == TypeOPT {
return dns.Extra[i].(*OPT)
}
}
return nil
}
// popEdns0 is like IsEdns0, but it removes the record from the message.
func (dns *Msg) popEdns0() *OPT {
// RFC 6891, Section 6.1.1 allows the OPT record to appear
// anywhere in the additional record section, but it's usually at
// the end so start there.
for i := len(dns.Extra) - 1; i >= 0; i-- {
if dns.Extra[i].Header().Rrtype == TypeOPT {
opt := dns.Extra[i].(*OPT)
dns.Extra = append(dns.Extra[:i], dns.Extra[i+1:]...)
return opt
}
}
return nil
}
// IsDomainName checks if s is a valid domain name, it returns the number of
// labels and true, when a domain name is valid. Note that non fully qualified
// domain name is considered valid, in this case the last label is counted in
// the number of labels. When false is returned the number of labels is not
// defined. Also note that this function is extremely liberal; almost any
// string is a valid domain name as the DNS is 8 bit protocol. It checks if each
// label fits in 63 characters and that the entire name will fit into the 255
// octet wire format limit.
func IsDomainName(s string) (labels int, ok bool) {
// XXX: The logic in this function was copied from packDomainName and
// should be kept in sync with that function.
const lenmsg = 256
if len(s) == 0 { // Ok, for instance when dealing with update RR without any rdata.
return 0, false
}
s = Fqdn(s)
// Each dot ends a segment of the name. Except for escaped dots (\.), which
// are normal dots.
var (
off int
begin int
wasDot bool
)
for i := 0; i < len(s); i++ {
switch s[i] {
case '\\':
if off+1 > lenmsg {
return labels, false
}
// check for \DDD
if i+3 < len(s) && isDigit(s[i+1]) && isDigit(s[i+2]) && isDigit(s[i+3]) {
i += 3
begin += 3
} else {
i++
begin++
}
wasDot = false
case '.':
if wasDot {
// two dots back to back is not legal
return labels, false
}
wasDot = true
labelLen := i - begin
if labelLen >= 1<<6 { // top two bits of length must be clear
return labels, false
}
// off can already (we're in a loop) be bigger than lenmsg
// this happens when a name isn't fully qualified
off += 1 + labelLen
if off > lenmsg {
return labels, false
}
labels++
begin = i + 1
default:
wasDot = false
}
}
return labels, true
}
// IsSubDomain checks if child is indeed a child of the parent. If child and parent
// are the same domain true is returned as well.
func IsSubDomain(parent, child string) bool {
// Entire child is contained in parent
return CompareDomainName(parent, child) == CountLabel(parent)
}
// IsMsg sanity checks buf and returns an error if it isn't a valid DNS packet.
// The checking is performed on the binary payload.
func IsMsg(buf []byte) error {
// Header
if len(buf) < headerSize {
return errors.New("dns: bad message header")
}
// Header: Opcode
// TODO(miek): more checks here, e.g. check all header bits.
return nil
}
// IsFqdn checks if a domain name is fully qualified.
func IsFqdn(s string) bool {
s2 := strings.TrimSuffix(s, ".")
if s == s2 {
return false
}
i := strings.LastIndexFunc(s2, func(r rune) bool {
return r != '\\'
})
// Test whether we have an even number of escape sequences before
// the dot or none.
return (len(s2)-i)%2 != 0
}
// IsRRset checks if a set of RRs is a valid RRset as defined by RFC 2181.
// This means the RRs need to have the same type, name, and class. Returns true
// if the RR set is valid, otherwise false.
func IsRRset(rrset []RR) bool {
if len(rrset) == 0 {
return false
}
if len(rrset) == 1 {
return true
}
rrHeader := rrset[0].Header()
rrType := rrHeader.Rrtype
rrClass := rrHeader.Class
rrName := rrHeader.Name
for _, rr := range rrset[1:] {
curRRHeader := rr.Header()
if curRRHeader.Rrtype != rrType || curRRHeader.Class != rrClass || curRRHeader.Name != rrName {
// Mismatch between the records, so this is not a valid rrset for
//signing/verifying
return false
}
}
return true
}
// Fqdn return the fully qualified domain name from s.
// If s is already fully qualified, it behaves as the identity function.
func Fqdn(s string) string {
if IsFqdn(s) {
return s
}
return s + "."
}
// CanonicalName returns the domain name in canonical form. A name in canonical
// form is lowercase and fully qualified. See Section 6.2 in RFC 4034.
func CanonicalName(s string) string {
return strings.ToLower(Fqdn(s))
}
// Copied from the official Go code.
// ReverseAddr returns the in-addr.arpa. or ip6.arpa. hostname of the IP
// address suitable for reverse DNS (PTR) record lookups or an error if it fails
// to parse the IP address.
func ReverseAddr(addr string) (arpa string, err error) {
ip := net.ParseIP(addr)
if ip == nil {
return "", &Error{err: "unrecognized address: " + addr}
}
if v4 := ip.To4(); v4 != nil {
buf := make([]byte, 0, net.IPv4len*4+len("in-addr.arpa."))
// Add it, in reverse, to the buffer
for i := len(v4) - 1; i >= 0; i-- {
buf = strconv.AppendInt(buf, int64(v4[i]), 10)
buf = append(buf, '.')
}
// Append "in-addr.arpa." and return (buf already has the final .)
buf = append(buf, "in-addr.arpa."...)
return string(buf), nil
}
// Must be IPv6
buf := make([]byte, 0, net.IPv6len*4+len("ip6.arpa."))
// Add it, in reverse, to the buffer
for i := len(ip) - 1; i >= 0; i-- {
v := ip[i]
buf = append(buf, hexDigit[v&0xF], '.', hexDigit[v>>4], '.')
}
// Append "ip6.arpa." and return (buf already has the final .)
buf = append(buf, "ip6.arpa."...)
return string(buf), nil
}
// String returns the string representation for the type t.
func (t Type) String() string {
if t1, ok := TypeToString[uint16(t)]; ok {
return t1
}
return "TYPE" + strconv.Itoa(int(t))
}
// String returns the string representation for the class c.
func (c Class) String() string {
if s, ok := ClassToString[uint16(c)]; ok {
// Only emit mnemonics when they are unambiguous, specially ANY is in both.
if _, ok := StringToType[s]; !ok {
return s
}
}
return "CLASS" + strconv.Itoa(int(c))
}
// String returns the string representation for the name n.
func (n Name) String() string {
return sprintName(string(n))
}

158
vendor/github.com/miekg/dns/dns.go generated vendored Normal file
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package dns
import (
"encoding/hex"
"strconv"
)
const (
year68 = 1 << 31 // For RFC1982 (Serial Arithmetic) calculations in 32 bits.
defaultTtl = 3600 // Default internal TTL.
// DefaultMsgSize is the standard default for messages larger than 512 bytes.
DefaultMsgSize = 4096
// MinMsgSize is the minimal size of a DNS packet.
MinMsgSize = 512
// MaxMsgSize is the largest possible DNS packet.
MaxMsgSize = 65535
)
// Error represents a DNS error.
type Error struct{ err string }
func (e *Error) Error() string {
if e == nil {
return "dns: <nil>"
}
return "dns: " + e.err
}
// An RR represents a resource record.
type RR interface {
// Header returns the header of an resource record. The header contains
// everything up to the rdata.
Header() *RR_Header
// String returns the text representation of the resource record.
String() string
// copy returns a copy of the RR
copy() RR
// len returns the length (in octets) of the compressed or uncompressed RR in wire format.
//
// If compression is nil, the uncompressed size will be returned, otherwise the compressed
// size will be returned and domain names will be added to the map for future compression.
len(off int, compression map[string]struct{}) int
// pack packs the records RDATA into wire format. The header will
// already have been packed into msg.
pack(msg []byte, off int, compression compressionMap, compress bool) (off1 int, err error)
// unpack unpacks an RR from wire format.
//
// This will only be called on a new and empty RR type with only the header populated. It
// will only be called if the record's RDATA is non-empty.
unpack(msg []byte, off int) (off1 int, err error)
// parse parses an RR from zone file format.
//
// This will only be called on a new and empty RR type with only the header populated.
parse(c *zlexer, origin string) *ParseError
// isDuplicate returns whether the two RRs are duplicates.
isDuplicate(r2 RR) bool
}
// RR_Header is the header all DNS resource records share.
type RR_Header struct {
Name string `dns:"cdomain-name"`
Rrtype uint16
Class uint16
Ttl uint32
Rdlength uint16 // Length of data after header.
}
// Header returns itself. This is here to make RR_Header implements the RR interface.
func (h *RR_Header) Header() *RR_Header { return h }
// Just to implement the RR interface.
func (h *RR_Header) copy() RR { return nil }
func (h *RR_Header) String() string {
var s string
if h.Rrtype == TypeOPT {
s = ";"
// and maybe other things
}
s += sprintName(h.Name) + "\t"
s += strconv.FormatInt(int64(h.Ttl), 10) + "\t"
s += Class(h.Class).String() + "\t"
s += Type(h.Rrtype).String() + "\t"
return s
}
func (h *RR_Header) len(off int, compression map[string]struct{}) int {
l := domainNameLen(h.Name, off, compression, true)
l += 10 // rrtype(2) + class(2) + ttl(4) + rdlength(2)
return l
}
func (h *RR_Header) pack(msg []byte, off int, compression compressionMap, compress bool) (off1 int, err error) {
// RR_Header has no RDATA to pack.
return off, nil
}
func (h *RR_Header) unpack(msg []byte, off int) (int, error) {
panic("dns: internal error: unpack should never be called on RR_Header")
}
func (h *RR_Header) parse(c *zlexer, origin string) *ParseError {
panic("dns: internal error: parse should never be called on RR_Header")
}
// ToRFC3597 converts a known RR to the unknown RR representation from RFC 3597.
func (rr *RFC3597) ToRFC3597(r RR) error {
buf := make([]byte, Len(r))
headerEnd, off, err := packRR(r, buf, 0, compressionMap{}, false)
if err != nil {
return err
}
buf = buf[:off]
*rr = RFC3597{Hdr: *r.Header()}
rr.Hdr.Rdlength = uint16(off - headerEnd)
if noRdata(rr.Hdr) {
return nil
}
_, err = rr.unpack(buf, headerEnd)
return err
}
// fromRFC3597 converts an unknown RR representation from RFC 3597 to the known RR type.
func (rr *RFC3597) fromRFC3597(r RR) error {
hdr := r.Header()
*hdr = rr.Hdr
// Can't overflow uint16 as the length of Rdata is validated in (*RFC3597).parse.
// We can only get here when rr was constructed with that method.
hdr.Rdlength = uint16(hex.DecodedLen(len(rr.Rdata)))
if noRdata(*hdr) {
// Dynamic update.
return nil
}
// rr.pack requires an extra allocation and a copy so we just decode Rdata
// manually, it's simpler anyway.
msg, err := hex.DecodeString(rr.Rdata)
if err != nil {
return err
}
_, err = r.unpack(msg, 0)
return err
}

749
vendor/github.com/miekg/dns/dnssec.go generated vendored Normal file
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package dns
import (
"bytes"
"crypto"
"crypto/ecdsa"
"crypto/ed25519"
"crypto/elliptic"
"crypto/rand"
"crypto/rsa"
_ "crypto/sha1" // need its init function
_ "crypto/sha256" // need its init function
_ "crypto/sha512" // need its init function
"encoding/asn1"
"encoding/binary"
"encoding/hex"
"math/big"
"sort"
"strings"
"time"
)
// DNSSEC encryption algorithm codes.
const (
_ uint8 = iota
RSAMD5
DH
DSA
_ // Skip 4, RFC 6725, section 2.1
RSASHA1
DSANSEC3SHA1
RSASHA1NSEC3SHA1
RSASHA256
_ // Skip 9, RFC 6725, section 2.1
RSASHA512
_ // Skip 11, RFC 6725, section 2.1
ECCGOST
ECDSAP256SHA256
ECDSAP384SHA384
ED25519
ED448
INDIRECT uint8 = 252
PRIVATEDNS uint8 = 253 // Private (experimental keys)
PRIVATEOID uint8 = 254
)
// AlgorithmToString is a map of algorithm IDs to algorithm names.
var AlgorithmToString = map[uint8]string{
RSAMD5: "RSAMD5",
DH: "DH",
DSA: "DSA",
RSASHA1: "RSASHA1",
DSANSEC3SHA1: "DSA-NSEC3-SHA1",
RSASHA1NSEC3SHA1: "RSASHA1-NSEC3-SHA1",
RSASHA256: "RSASHA256",
RSASHA512: "RSASHA512",
ECCGOST: "ECC-GOST",
ECDSAP256SHA256: "ECDSAP256SHA256",
ECDSAP384SHA384: "ECDSAP384SHA384",
ED25519: "ED25519",
ED448: "ED448",
INDIRECT: "INDIRECT",
PRIVATEDNS: "PRIVATEDNS",
PRIVATEOID: "PRIVATEOID",
}
// AlgorithmToHash is a map of algorithm crypto hash IDs to crypto.Hash's.
// For newer algorithm that do their own hashing (i.e. ED25519) the returned value
// is 0, implying no (external) hashing should occur. The non-exported identityHash is then
// used.
var AlgorithmToHash = map[uint8]crypto.Hash{
RSAMD5: crypto.MD5, // Deprecated in RFC 6725
DSA: crypto.SHA1,
RSASHA1: crypto.SHA1,
RSASHA1NSEC3SHA1: crypto.SHA1,
RSASHA256: crypto.SHA256,
ECDSAP256SHA256: crypto.SHA256,
ECDSAP384SHA384: crypto.SHA384,
RSASHA512: crypto.SHA512,
ED25519: 0,
}
// DNSSEC hashing algorithm codes.
const (
_ uint8 = iota
SHA1 // RFC 4034
SHA256 // RFC 4509
GOST94 // RFC 5933
SHA384 // Experimental
SHA512 // Experimental
)
// HashToString is a map of hash IDs to names.
var HashToString = map[uint8]string{
SHA1: "SHA1",
SHA256: "SHA256",
GOST94: "GOST94",
SHA384: "SHA384",
SHA512: "SHA512",
}
// DNSKEY flag values.
const (
SEP = 1
REVOKE = 1 << 7
ZONE = 1 << 8
)
// The RRSIG needs to be converted to wireformat with some of the rdata (the signature) missing.
type rrsigWireFmt struct {
TypeCovered uint16
Algorithm uint8
Labels uint8
OrigTtl uint32
Expiration uint32
Inception uint32
KeyTag uint16
SignerName string `dns:"domain-name"`
/* No Signature */
}
// Used for converting DNSKEY's rdata to wirefmt.
type dnskeyWireFmt struct {
Flags uint16
Protocol uint8
Algorithm uint8
PublicKey string `dns:"base64"`
/* Nothing is left out */
}
func divRoundUp(a, b int) int {
return (a + b - 1) / b
}
// KeyTag calculates the keytag (or key-id) of the DNSKEY.
func (k *DNSKEY) KeyTag() uint16 {
if k == nil {
return 0
}
var keytag int
switch k.Algorithm {
case RSAMD5:
// This algorithm has been deprecated, but keep this key-tag calculation.
// Look at the bottom two bytes of the modules, which the last item in the pubkey.
// See https://www.rfc-editor.org/errata/eid193 .
modulus, _ := fromBase64([]byte(k.PublicKey))
if len(modulus) > 1 {
x := binary.BigEndian.Uint16(modulus[len(modulus)-3:])
keytag = int(x)
}
default:
keywire := new(dnskeyWireFmt)
keywire.Flags = k.Flags
keywire.Protocol = k.Protocol
keywire.Algorithm = k.Algorithm
keywire.PublicKey = k.PublicKey
wire := make([]byte, DefaultMsgSize)
n, err := packKeyWire(keywire, wire)
if err != nil {
return 0
}
wire = wire[:n]
for i, v := range wire {
if i&1 != 0 {
keytag += int(v) // must be larger than uint32
} else {
keytag += int(v) << 8
}
}
keytag += keytag >> 16 & 0xFFFF
keytag &= 0xFFFF
}
return uint16(keytag)
}
// ToDS converts a DNSKEY record to a DS record.
func (k *DNSKEY) ToDS(h uint8) *DS {
if k == nil {
return nil
}
ds := new(DS)
ds.Hdr.Name = k.Hdr.Name
ds.Hdr.Class = k.Hdr.Class
ds.Hdr.Rrtype = TypeDS
ds.Hdr.Ttl = k.Hdr.Ttl
ds.Algorithm = k.Algorithm
ds.DigestType = h
ds.KeyTag = k.KeyTag()
keywire := new(dnskeyWireFmt)
keywire.Flags = k.Flags
keywire.Protocol = k.Protocol
keywire.Algorithm = k.Algorithm
keywire.PublicKey = k.PublicKey
wire := make([]byte, DefaultMsgSize)
n, err := packKeyWire(keywire, wire)
if err != nil {
return nil
}
wire = wire[:n]
owner := make([]byte, 255)
off, err1 := PackDomainName(CanonicalName(k.Hdr.Name), owner, 0, nil, false)
if err1 != nil {
return nil
}
owner = owner[:off]
// RFC4034:
// digest = digest_algorithm( DNSKEY owner name | DNSKEY RDATA);
// "|" denotes concatenation
// DNSKEY RDATA = Flags | Protocol | Algorithm | Public Key.
var hash crypto.Hash
switch h {
case SHA1:
hash = crypto.SHA1
case SHA256:
hash = crypto.SHA256
case SHA384:
hash = crypto.SHA384
case SHA512:
hash = crypto.SHA512
default:
return nil
}
s := hash.New()
s.Write(owner)
s.Write(wire)
ds.Digest = hex.EncodeToString(s.Sum(nil))
return ds
}
// ToCDNSKEY converts a DNSKEY record to a CDNSKEY record.
func (k *DNSKEY) ToCDNSKEY() *CDNSKEY {
c := &CDNSKEY{DNSKEY: *k}
c.Hdr = k.Hdr
c.Hdr.Rrtype = TypeCDNSKEY
return c
}
// ToCDS converts a DS record to a CDS record.
func (d *DS) ToCDS() *CDS {
c := &CDS{DS: *d}
c.Hdr = d.Hdr
c.Hdr.Rrtype = TypeCDS
return c
}
// Sign signs an RRSet. The signature needs to be filled in with the values:
// Inception, Expiration, KeyTag, SignerName and Algorithm. The rest is copied
// from the RRset. Sign returns a non-nill error when the signing went OK.
// There is no check if RRSet is a proper (RFC 2181) RRSet. If OrigTTL is non
// zero, it is used as-is, otherwise the TTL of the RRset is used as the
// OrigTTL.
func (rr *RRSIG) Sign(k crypto.Signer, rrset []RR) error {
if k == nil {
return ErrPrivKey
}
// s.Inception and s.Expiration may be 0 (rollover etc.), the rest must be set
if rr.KeyTag == 0 || len(rr.SignerName) == 0 || rr.Algorithm == 0 {
return ErrKey
}
h0 := rrset[0].Header()
rr.Hdr.Rrtype = TypeRRSIG
rr.Hdr.Name = h0.Name
rr.Hdr.Class = h0.Class
if rr.OrigTtl == 0 { // If set don't override
rr.OrigTtl = h0.Ttl
}
rr.TypeCovered = h0.Rrtype
rr.Labels = uint8(CountLabel(h0.Name))
if strings.HasPrefix(h0.Name, "*") {
rr.Labels-- // wildcard, remove from label count
}
sigwire := new(rrsigWireFmt)
sigwire.TypeCovered = rr.TypeCovered
sigwire.Algorithm = rr.Algorithm
sigwire.Labels = rr.Labels
sigwire.OrigTtl = rr.OrigTtl
sigwire.Expiration = rr.Expiration
sigwire.Inception = rr.Inception
sigwire.KeyTag = rr.KeyTag
// For signing, lowercase this name
sigwire.SignerName = CanonicalName(rr.SignerName)
// Create the desired binary blob
signdata := make([]byte, DefaultMsgSize)
n, err := packSigWire(sigwire, signdata)
if err != nil {
return err
}
signdata = signdata[:n]
wire, err := rawSignatureData(rrset, rr)
if err != nil {
return err
}
h, cryptohash, err := hashFromAlgorithm(rr.Algorithm)
if err != nil {
return err
}
switch rr.Algorithm {
case RSAMD5, DSA, DSANSEC3SHA1:
// See RFC 6944.
return ErrAlg
default:
h.Write(signdata)
h.Write(wire)
signature, err := sign(k, h.Sum(nil), cryptohash, rr.Algorithm)
if err != nil {
return err
}
rr.Signature = toBase64(signature)
return nil
}
}
func sign(k crypto.Signer, hashed []byte, hash crypto.Hash, alg uint8) ([]byte, error) {
signature, err := k.Sign(rand.Reader, hashed, hash)
if err != nil {
return nil, err
}
switch alg {
case RSASHA1, RSASHA1NSEC3SHA1, RSASHA256, RSASHA512, ED25519:
return signature, nil
case ECDSAP256SHA256, ECDSAP384SHA384:
ecdsaSignature := &struct {
R, S *big.Int
}{}
if _, err := asn1.Unmarshal(signature, ecdsaSignature); err != nil {
return nil, err
}
var intlen int
switch alg {
case ECDSAP256SHA256:
intlen = 32
case ECDSAP384SHA384:
intlen = 48
}
signature := intToBytes(ecdsaSignature.R, intlen)
signature = append(signature, intToBytes(ecdsaSignature.S, intlen)...)
return signature, nil
default:
return nil, ErrAlg
}
}
// Verify validates an RRSet with the signature and key. This is only the
// cryptographic test, the signature validity period must be checked separately.
// This function copies the rdata of some RRs (to lowercase domain names) for the validation to work.
// It also checks that the Zone Key bit (RFC 4034 2.1.1) is set on the DNSKEY
// and that the Protocol field is set to 3 (RFC 4034 2.1.2).
func (rr *RRSIG) Verify(k *DNSKEY, rrset []RR) error {
// First the easy checks
if !IsRRset(rrset) {
return ErrRRset
}
if rr.KeyTag != k.KeyTag() {
return ErrKey
}
if rr.Hdr.Class != k.Hdr.Class {
return ErrKey
}
if rr.Algorithm != k.Algorithm {
return ErrKey
}
if !strings.EqualFold(rr.SignerName, k.Hdr.Name) {
return ErrKey
}
if k.Protocol != 3 {
return ErrKey
}
// RFC 4034 2.1.1 If bit 7 has value 0, then the DNSKEY record holds some
// other type of DNS public key and MUST NOT be used to verify RRSIGs that
// cover RRsets.
if k.Flags&ZONE == 0 {
return ErrKey
}
// IsRRset checked that we have at least one RR and that the RRs in
// the set have consistent type, class, and name. Also check that type and
// class matches the RRSIG record.
if h0 := rrset[0].Header(); h0.Class != rr.Hdr.Class || h0.Rrtype != rr.TypeCovered {
return ErrRRset
}
// RFC 4035 5.3.2. Reconstructing the Signed Data
// Copy the sig, except the rrsig data
sigwire := new(rrsigWireFmt)
sigwire.TypeCovered = rr.TypeCovered
sigwire.Algorithm = rr.Algorithm
sigwire.Labels = rr.Labels
sigwire.OrigTtl = rr.OrigTtl
sigwire.Expiration = rr.Expiration
sigwire.Inception = rr.Inception
sigwire.KeyTag = rr.KeyTag
sigwire.SignerName = CanonicalName(rr.SignerName)
// Create the desired binary blob
signeddata := make([]byte, DefaultMsgSize)
n, err := packSigWire(sigwire, signeddata)
if err != nil {
return err
}
signeddata = signeddata[:n]
wire, err := rawSignatureData(rrset, rr)
if err != nil {
return err
}
sigbuf := rr.sigBuf() // Get the binary signature data
if rr.Algorithm == PRIVATEDNS { // PRIVATEOID
// TODO(miek)
// remove the domain name and assume its ours?
}
h, cryptohash, err := hashFromAlgorithm(rr.Algorithm)
if err != nil {
return err
}
switch rr.Algorithm {
case RSASHA1, RSASHA1NSEC3SHA1, RSASHA256, RSASHA512:
// TODO(mg): this can be done quicker, ie. cache the pubkey data somewhere??
pubkey := k.publicKeyRSA() // Get the key
if pubkey == nil {
return ErrKey
}
h.Write(signeddata)
h.Write(wire)
return rsa.VerifyPKCS1v15(pubkey, cryptohash, h.Sum(nil), sigbuf)
case ECDSAP256SHA256, ECDSAP384SHA384:
pubkey := k.publicKeyECDSA()
if pubkey == nil {
return ErrKey
}
// Split sigbuf into the r and s coordinates
r := new(big.Int).SetBytes(sigbuf[:len(sigbuf)/2])
s := new(big.Int).SetBytes(sigbuf[len(sigbuf)/2:])
h.Write(signeddata)
h.Write(wire)
if ecdsa.Verify(pubkey, h.Sum(nil), r, s) {
return nil
}
return ErrSig
case ED25519:
pubkey := k.publicKeyED25519()
if pubkey == nil {
return ErrKey
}
if ed25519.Verify(pubkey, append(signeddata, wire...), sigbuf) {
return nil
}
return ErrSig
default:
return ErrAlg
}
}
// ValidityPeriod uses RFC1982 serial arithmetic to calculate
// if a signature period is valid. If t is the zero time, the
// current time is taken other t is. Returns true if the signature
// is valid at the given time, otherwise returns false.
func (rr *RRSIG) ValidityPeriod(t time.Time) bool {
var utc int64
if t.IsZero() {
utc = time.Now().UTC().Unix()
} else {
utc = t.UTC().Unix()
}
modi := (int64(rr.Inception) - utc) / year68
mode := (int64(rr.Expiration) - utc) / year68
ti := int64(rr.Inception) + modi*year68
te := int64(rr.Expiration) + mode*year68
return ti <= utc && utc <= te
}
// Return the signatures base64 encoding sigdata as a byte slice.
func (rr *RRSIG) sigBuf() []byte {
sigbuf, err := fromBase64([]byte(rr.Signature))
if err != nil {
return nil
}
return sigbuf
}
// publicKeyRSA returns the RSA public key from a DNSKEY record.
func (k *DNSKEY) publicKeyRSA() *rsa.PublicKey {
keybuf, err := fromBase64([]byte(k.PublicKey))
if err != nil {
return nil
}
if len(keybuf) < 1+1+64 {
// Exponent must be at least 1 byte and modulus at least 64
return nil
}
// RFC 2537/3110, section 2. RSA Public KEY Resource Records
// Length is in the 0th byte, unless its zero, then it
// it in bytes 1 and 2 and its a 16 bit number
explen := uint16(keybuf[0])
keyoff := 1
if explen == 0 {
explen = uint16(keybuf[1])<<8 | uint16(keybuf[2])
keyoff = 3
}
if explen > 4 || explen == 0 || keybuf[keyoff] == 0 {
// Exponent larger than supported by the crypto package,
// empty, or contains prohibited leading zero.
return nil
}
modoff := keyoff + int(explen)
modlen := len(keybuf) - modoff
if modlen < 64 || modlen > 512 || keybuf[modoff] == 0 {
// Modulus is too small, large, or contains prohibited leading zero.
return nil
}
pubkey := new(rsa.PublicKey)
var expo uint64
// The exponent of length explen is between keyoff and modoff.
for _, v := range keybuf[keyoff:modoff] {
expo <<= 8
expo |= uint64(v)
}
if expo > 1<<31-1 {
// Larger exponent than supported by the crypto package.
return nil
}
pubkey.E = int(expo)
pubkey.N = new(big.Int).SetBytes(keybuf[modoff:])
return pubkey
}
// publicKeyECDSA returns the Curve public key from the DNSKEY record.
func (k *DNSKEY) publicKeyECDSA() *ecdsa.PublicKey {
keybuf, err := fromBase64([]byte(k.PublicKey))
if err != nil {
return nil
}
pubkey := new(ecdsa.PublicKey)
switch k.Algorithm {
case ECDSAP256SHA256:
pubkey.Curve = elliptic.P256()
if len(keybuf) != 64 {
// wrongly encoded key
return nil
}
case ECDSAP384SHA384:
pubkey.Curve = elliptic.P384()
if len(keybuf) != 96 {
// Wrongly encoded key
return nil
}
}
pubkey.X = new(big.Int).SetBytes(keybuf[:len(keybuf)/2])
pubkey.Y = new(big.Int).SetBytes(keybuf[len(keybuf)/2:])
return pubkey
}
func (k *DNSKEY) publicKeyED25519() ed25519.PublicKey {
keybuf, err := fromBase64([]byte(k.PublicKey))
if err != nil {
return nil
}
if len(keybuf) != ed25519.PublicKeySize {
return nil
}
return keybuf
}
type wireSlice [][]byte
func (p wireSlice) Len() int { return len(p) }
func (p wireSlice) Swap(i, j int) { p[i], p[j] = p[j], p[i] }
func (p wireSlice) Less(i, j int) bool {
_, ioff, _ := UnpackDomainName(p[i], 0)
_, joff, _ := UnpackDomainName(p[j], 0)
return bytes.Compare(p[i][ioff+10:], p[j][joff+10:]) < 0
}
// Return the raw signature data.
func rawSignatureData(rrset []RR, s *RRSIG) (buf []byte, err error) {
wires := make(wireSlice, len(rrset))
for i, r := range rrset {
r1 := r.copy()
h := r1.Header()
h.Ttl = s.OrigTtl
labels := SplitDomainName(h.Name)
// 6.2. Canonical RR Form. (4) - wildcards
if len(labels) > int(s.Labels) {
// Wildcard
h.Name = "*." + strings.Join(labels[len(labels)-int(s.Labels):], ".") + "."
}
// RFC 4034: 6.2. Canonical RR Form. (2) - domain name to lowercase
h.Name = CanonicalName(h.Name)
// 6.2. Canonical RR Form. (3) - domain rdata to lowercase.
// NS, MD, MF, CNAME, SOA, MB, MG, MR, PTR,
// HINFO, MINFO, MX, RP, AFSDB, RT, SIG, PX, NXT, NAPTR, KX,
// SRV, DNAME, A6
//
// RFC 6840 - Clarifications and Implementation Notes for DNS Security (DNSSEC):
// Section 6.2 of [RFC4034] also erroneously lists HINFO as a record
// that needs conversion to lowercase, and twice at that. Since HINFO
// records contain no domain names, they are not subject to case
// conversion.
switch x := r1.(type) {
case *NS:
x.Ns = CanonicalName(x.Ns)
case *MD:
x.Md = CanonicalName(x.Md)
case *MF:
x.Mf = CanonicalName(x.Mf)
case *CNAME:
x.Target = CanonicalName(x.Target)
case *SOA:
x.Ns = CanonicalName(x.Ns)
x.Mbox = CanonicalName(x.Mbox)
case *MB:
x.Mb = CanonicalName(x.Mb)
case *MG:
x.Mg = CanonicalName(x.Mg)
case *MR:
x.Mr = CanonicalName(x.Mr)
case *PTR:
x.Ptr = CanonicalName(x.Ptr)
case *MINFO:
x.Rmail = CanonicalName(x.Rmail)
x.Email = CanonicalName(x.Email)
case *MX:
x.Mx = CanonicalName(x.Mx)
case *RP:
x.Mbox = CanonicalName(x.Mbox)
x.Txt = CanonicalName(x.Txt)
case *AFSDB:
x.Hostname = CanonicalName(x.Hostname)
case *RT:
x.Host = CanonicalName(x.Host)
case *SIG:
x.SignerName = CanonicalName(x.SignerName)
case *PX:
x.Map822 = CanonicalName(x.Map822)
x.Mapx400 = CanonicalName(x.Mapx400)
case *NAPTR:
x.Replacement = CanonicalName(x.Replacement)
case *KX:
x.Exchanger = CanonicalName(x.Exchanger)
case *SRV:
x.Target = CanonicalName(x.Target)
case *DNAME:
x.Target = CanonicalName(x.Target)
}
// 6.2. Canonical RR Form. (5) - origTTL
wire := make([]byte, Len(r1)+1) // +1 to be safe(r)
off, err1 := PackRR(r1, wire, 0, nil, false)
if err1 != nil {
return nil, err1
}
wire = wire[:off]
wires[i] = wire
}
sort.Sort(wires)
for i, wire := range wires {
if i > 0 && bytes.Equal(wire, wires[i-1]) {
continue
}
buf = append(buf, wire...)
}
return buf, nil
}
func packSigWire(sw *rrsigWireFmt, msg []byte) (int, error) {
// copied from zmsg.go RRSIG packing
off, err := packUint16(sw.TypeCovered, msg, 0)
if err != nil {
return off, err
}
off, err = packUint8(sw.Algorithm, msg, off)
if err != nil {
return off, err
}
off, err = packUint8(sw.Labels, msg, off)
if err != nil {
return off, err
}
off, err = packUint32(sw.OrigTtl, msg, off)
if err != nil {
return off, err
}
off, err = packUint32(sw.Expiration, msg, off)
if err != nil {
return off, err
}
off, err = packUint32(sw.Inception, msg, off)
if err != nil {
return off, err
}
off, err = packUint16(sw.KeyTag, msg, off)
if err != nil {
return off, err
}
off, err = PackDomainName(sw.SignerName, msg, off, nil, false)
if err != nil {
return off, err
}
return off, nil
}
func packKeyWire(dw *dnskeyWireFmt, msg []byte) (int, error) {
// copied from zmsg.go DNSKEY packing
off, err := packUint16(dw.Flags, msg, 0)
if err != nil {
return off, err
}
off, err = packUint8(dw.Protocol, msg, off)
if err != nil {
return off, err
}
off, err = packUint8(dw.Algorithm, msg, off)
if err != nil {
return off, err
}
off, err = packStringBase64(dw.PublicKey, msg, off)
if err != nil {
return off, err
}
return off, nil
}

139
vendor/github.com/miekg/dns/dnssec_keygen.go generated vendored Normal file
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@ -0,0 +1,139 @@
package dns
import (
"crypto"
"crypto/ecdsa"
"crypto/ed25519"
"crypto/elliptic"
"crypto/rand"
"crypto/rsa"
"math/big"
)
// Generate generates a DNSKEY of the given bit size.
// The public part is put inside the DNSKEY record.
// The Algorithm in the key must be set as this will define
// what kind of DNSKEY will be generated.
// The ECDSA algorithms imply a fixed keysize, in that case
// bits should be set to the size of the algorithm.
func (k *DNSKEY) Generate(bits int) (crypto.PrivateKey, error) {
switch k.Algorithm {
case RSASHA1, RSASHA256, RSASHA1NSEC3SHA1:
if bits < 512 || bits > 4096 {
return nil, ErrKeySize
}
case RSASHA512:
if bits < 1024 || bits > 4096 {
return nil, ErrKeySize
}
case ECDSAP256SHA256:
if bits != 256 {
return nil, ErrKeySize
}
case ECDSAP384SHA384:
if bits != 384 {
return nil, ErrKeySize
}
case ED25519:
if bits != 256 {
return nil, ErrKeySize
}
default:
return nil, ErrAlg
}
switch k.Algorithm {
case RSASHA1, RSASHA256, RSASHA512, RSASHA1NSEC3SHA1:
priv, err := rsa.GenerateKey(rand.Reader, bits)
if err != nil {
return nil, err
}
k.setPublicKeyRSA(priv.PublicKey.E, priv.PublicKey.N)
return priv, nil
case ECDSAP256SHA256, ECDSAP384SHA384:
var c elliptic.Curve
switch k.Algorithm {
case ECDSAP256SHA256:
c = elliptic.P256()
case ECDSAP384SHA384:
c = elliptic.P384()
}
priv, err := ecdsa.GenerateKey(c, rand.Reader)
if err != nil {
return nil, err
}
k.setPublicKeyECDSA(priv.PublicKey.X, priv.PublicKey.Y)
return priv, nil
case ED25519:
pub, priv, err := ed25519.GenerateKey(rand.Reader)
if err != nil {
return nil, err
}
k.setPublicKeyED25519(pub)
return priv, nil
default:
return nil, ErrAlg
}
}
// Set the public key (the value E and N)
func (k *DNSKEY) setPublicKeyRSA(_E int, _N *big.Int) bool {
if _E == 0 || _N == nil {
return false
}
buf := exponentToBuf(_E)
buf = append(buf, _N.Bytes()...)
k.PublicKey = toBase64(buf)
return true
}
// Set the public key for Elliptic Curves
func (k *DNSKEY) setPublicKeyECDSA(_X, _Y *big.Int) bool {
if _X == nil || _Y == nil {
return false
}
var intlen int
switch k.Algorithm {
case ECDSAP256SHA256:
intlen = 32
case ECDSAP384SHA384:
intlen = 48
}
k.PublicKey = toBase64(curveToBuf(_X, _Y, intlen))
return true
}
// Set the public key for Ed25519
func (k *DNSKEY) setPublicKeyED25519(_K ed25519.PublicKey) bool {
if _K == nil {
return false
}
k.PublicKey = toBase64(_K)
return true
}
// Set the public key (the values E and N) for RSA
// RFC 3110: Section 2. RSA Public KEY Resource Records
func exponentToBuf(_E int) []byte {
var buf []byte
i := big.NewInt(int64(_E)).Bytes()
if len(i) < 256 {
buf = make([]byte, 1, 1+len(i))
buf[0] = uint8(len(i))
} else {
buf = make([]byte, 3, 3+len(i))
buf[0] = 0
buf[1] = uint8(len(i) >> 8)
buf[2] = uint8(len(i))
}
buf = append(buf, i...)
return buf
}
// Set the public key for X and Y for Curve. The two
// values are just concatenated.
func curveToBuf(_X, _Y *big.Int, intlen int) []byte {
buf := intToBytes(_X, intlen)
buf = append(buf, intToBytes(_Y, intlen)...)
return buf
}

309
vendor/github.com/miekg/dns/dnssec_keyscan.go generated vendored Normal file
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@ -0,0 +1,309 @@
package dns
import (
"bufio"
"crypto"
"crypto/ecdsa"
"crypto/ed25519"
"crypto/rsa"
"io"
"math/big"
"strconv"
"strings"
)
// NewPrivateKey returns a PrivateKey by parsing the string s.
// s should be in the same form of the BIND private key files.
func (k *DNSKEY) NewPrivateKey(s string) (crypto.PrivateKey, error) {
if s == "" || s[len(s)-1] != '\n' { // We need a closing newline
return k.ReadPrivateKey(strings.NewReader(s+"\n"), "")
}
return k.ReadPrivateKey(strings.NewReader(s), "")
}
// ReadPrivateKey reads a private key from the io.Reader q. The string file is
// only used in error reporting.
// The public key must be known, because some cryptographic algorithms embed
// the public inside the privatekey.
func (k *DNSKEY) ReadPrivateKey(q io.Reader, file string) (crypto.PrivateKey, error) {
m, err := parseKey(q, file)
if m == nil {
return nil, err
}
if _, ok := m["private-key-format"]; !ok {
return nil, ErrPrivKey
}
if m["private-key-format"] != "v1.2" && m["private-key-format"] != "v1.3" {
return nil, ErrPrivKey
}
// TODO(mg): check if the pubkey matches the private key
algo, err := strconv.ParseUint(strings.SplitN(m["algorithm"], " ", 2)[0], 10, 8)
if err != nil {
return nil, ErrPrivKey
}
switch uint8(algo) {
case RSASHA1, RSASHA1NSEC3SHA1, RSASHA256, RSASHA512:
priv, err := readPrivateKeyRSA(m)
if err != nil {
return nil, err
}
pub := k.publicKeyRSA()
if pub == nil {
return nil, ErrKey
}
priv.PublicKey = *pub
return priv, nil
case ECDSAP256SHA256, ECDSAP384SHA384:
priv, err := readPrivateKeyECDSA(m)
if err != nil {
return nil, err
}
pub := k.publicKeyECDSA()
if pub == nil {
return nil, ErrKey
}
priv.PublicKey = *pub
return priv, nil
case ED25519:
return readPrivateKeyED25519(m)
default:
return nil, ErrAlg
}
}
// Read a private key (file) string and create a public key. Return the private key.
func readPrivateKeyRSA(m map[string]string) (*rsa.PrivateKey, error) {
p := new(rsa.PrivateKey)
p.Primes = []*big.Int{nil, nil}
for k, v := range m {
switch k {
case "modulus", "publicexponent", "privateexponent", "prime1", "prime2":
v1, err := fromBase64([]byte(v))
if err != nil {
return nil, err
}
switch k {
case "modulus":
p.PublicKey.N = new(big.Int).SetBytes(v1)
case "publicexponent":
i := new(big.Int).SetBytes(v1)
p.PublicKey.E = int(i.Int64()) // int64 should be large enough
case "privateexponent":
p.D = new(big.Int).SetBytes(v1)
case "prime1":
p.Primes[0] = new(big.Int).SetBytes(v1)
case "prime2":
p.Primes[1] = new(big.Int).SetBytes(v1)
}
case "exponent1", "exponent2", "coefficient":
// not used in Go (yet)
case "created", "publish", "activate":
// not used in Go (yet)
}
}
return p, nil
}
func readPrivateKeyECDSA(m map[string]string) (*ecdsa.PrivateKey, error) {
p := new(ecdsa.PrivateKey)
p.D = new(big.Int)
// TODO: validate that the required flags are present
for k, v := range m {
switch k {
case "privatekey":
v1, err := fromBase64([]byte(v))
if err != nil {
return nil, err
}
p.D.SetBytes(v1)
case "created", "publish", "activate":
/* not used in Go (yet) */
}
}
return p, nil
}
func readPrivateKeyED25519(m map[string]string) (ed25519.PrivateKey, error) {
var p ed25519.PrivateKey
// TODO: validate that the required flags are present
for k, v := range m {
switch k {
case "privatekey":
p1, err := fromBase64([]byte(v))
if err != nil {
return nil, err
}
if len(p1) != ed25519.SeedSize {
return nil, ErrPrivKey
}
p = ed25519.NewKeyFromSeed(p1)
case "created", "publish", "activate":
/* not used in Go (yet) */
}
}
return p, nil
}
// parseKey reads a private key from r. It returns a map[string]string,
// with the key-value pairs, or an error when the file is not correct.
func parseKey(r io.Reader, file string) (map[string]string, error) {
m := make(map[string]string)
var k string
c := newKLexer(r)
for l, ok := c.Next(); ok; l, ok = c.Next() {
// It should alternate
switch l.value {
case zKey:
k = l.token
case zValue:
if k == "" {
return nil, &ParseError{file, "no private key seen", l}
}
m[strings.ToLower(k)] = l.token
k = ""
}
}
// Surface any read errors from r.
if err := c.Err(); err != nil {
return nil, &ParseError{file: file, err: err.Error()}
}
return m, nil
}
type klexer struct {
br io.ByteReader
readErr error
line int
column int
key bool
eol bool // end-of-line
}
func newKLexer(r io.Reader) *klexer {
br, ok := r.(io.ByteReader)
if !ok {
br = bufio.NewReaderSize(r, 1024)
}
return &klexer{
br: br,
line: 1,
key: true,
}
}
func (kl *klexer) Err() error {
if kl.readErr == io.EOF {
return nil
}
return kl.readErr
}
// readByte returns the next byte from the input
func (kl *klexer) readByte() (byte, bool) {
if kl.readErr != nil {
return 0, false
}
c, err := kl.br.ReadByte()
if err != nil {
kl.readErr = err
return 0, false
}
// delay the newline handling until the next token is delivered,
// fixes off-by-one errors when reporting a parse error.
if kl.eol {
kl.line++
kl.column = 0
kl.eol = false
}
if c == '\n' {
kl.eol = true
} else {
kl.column++
}
return c, true
}
func (kl *klexer) Next() (lex, bool) {
var (
l lex
str strings.Builder
commt bool
)
for x, ok := kl.readByte(); ok; x, ok = kl.readByte() {
l.line, l.column = kl.line, kl.column
switch x {
case ':':
if commt || !kl.key {
break
}
kl.key = false
// Next token is a space, eat it
kl.readByte()
l.value = zKey
l.token = str.String()
return l, true
case ';':
commt = true
case '\n':
if commt {
// Reset a comment
commt = false
}
if kl.key && str.Len() == 0 {
// ignore empty lines
break
}
kl.key = true
l.value = zValue
l.token = str.String()
return l, true
default:
if commt {
break
}
str.WriteByte(x)
}
}
if kl.readErr != nil && kl.readErr != io.EOF {
// Don't return any tokens after a read error occurs.
return lex{value: zEOF}, false
}
if str.Len() > 0 {
// Send remainder
l.value = zValue
l.token = str.String()
return l, true
}
return lex{value: zEOF}, false
}

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package dns
import (
"crypto"
"crypto/ecdsa"
"crypto/ed25519"
"crypto/rsa"
"math/big"
"strconv"
)
const format = "Private-key-format: v1.3\n"
var bigIntOne = big.NewInt(1)
// PrivateKeyString converts a PrivateKey to a string. This string has the same
// format as the private-key-file of BIND9 (Private-key-format: v1.3).
// It needs some info from the key (the algorithm), so its a method of the DNSKEY.
// It supports *rsa.PrivateKey, *ecdsa.PrivateKey and ed25519.PrivateKey.
func (r *DNSKEY) PrivateKeyString(p crypto.PrivateKey) string {
algorithm := strconv.Itoa(int(r.Algorithm))
algorithm += " (" + AlgorithmToString[r.Algorithm] + ")"
switch p := p.(type) {
case *rsa.PrivateKey:
modulus := toBase64(p.PublicKey.N.Bytes())
e := big.NewInt(int64(p.PublicKey.E))
publicExponent := toBase64(e.Bytes())
privateExponent := toBase64(p.D.Bytes())
prime1 := toBase64(p.Primes[0].Bytes())
prime2 := toBase64(p.Primes[1].Bytes())
// Calculate Exponent1/2 and Coefficient as per: http://en.wikipedia.org/wiki/RSA#Using_the_Chinese_remainder_algorithm
// and from: http://code.google.com/p/go/issues/detail?id=987
p1 := new(big.Int).Sub(p.Primes[0], bigIntOne)
q1 := new(big.Int).Sub(p.Primes[1], bigIntOne)
exp1 := new(big.Int).Mod(p.D, p1)
exp2 := new(big.Int).Mod(p.D, q1)
coeff := new(big.Int).ModInverse(p.Primes[1], p.Primes[0])
exponent1 := toBase64(exp1.Bytes())
exponent2 := toBase64(exp2.Bytes())
coefficient := toBase64(coeff.Bytes())
return format +
"Algorithm: " + algorithm + "\n" +
"Modulus: " + modulus + "\n" +
"PublicExponent: " + publicExponent + "\n" +
"PrivateExponent: " + privateExponent + "\n" +
"Prime1: " + prime1 + "\n" +
"Prime2: " + prime2 + "\n" +
"Exponent1: " + exponent1 + "\n" +
"Exponent2: " + exponent2 + "\n" +
"Coefficient: " + coefficient + "\n"
case *ecdsa.PrivateKey:
var intlen int
switch r.Algorithm {
case ECDSAP256SHA256:
intlen = 32
case ECDSAP384SHA384:
intlen = 48
}
private := toBase64(intToBytes(p.D, intlen))
return format +
"Algorithm: " + algorithm + "\n" +
"PrivateKey: " + private + "\n"
case ed25519.PrivateKey:
private := toBase64(p.Seed())
return format +
"Algorithm: " + algorithm + "\n" +
"PrivateKey: " + private + "\n"
default:
return ""
}
}

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vendor/github.com/miekg/dns/doc.go generated vendored Normal file
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/*
Package dns implements a full featured interface to the Domain Name System.
Both server- and client-side programming is supported. The package allows
complete control over what is sent out to the DNS. The API follows the
less-is-more principle, by presenting a small, clean interface.
It supports (asynchronous) querying/replying, incoming/outgoing zone transfers,
TSIG, EDNS0, dynamic updates, notifies and DNSSEC validation/signing.
Note that domain names MUST be fully qualified before sending them, unqualified
names in a message will result in a packing failure.
Resource records are native types. They are not stored in wire format. Basic
usage pattern for creating a new resource record:
r := new(dns.MX)
r.Hdr = dns.RR_Header{Name: "miek.nl.", Rrtype: dns.TypeMX, Class: dns.ClassINET, Ttl: 3600}
r.Preference = 10
r.Mx = "mx.miek.nl."
Or directly from a string:
mx, err := dns.NewRR("miek.nl. 3600 IN MX 10 mx.miek.nl.")
Or when the default origin (.) and TTL (3600) and class (IN) suit you:
mx, err := dns.NewRR("miek.nl MX 10 mx.miek.nl")
Or even:
mx, err := dns.NewRR("$ORIGIN nl.\nmiek 1H IN MX 10 mx.miek")
In the DNS messages are exchanged, these messages contain resource records
(sets). Use pattern for creating a message:
m := new(dns.Msg)
m.SetQuestion("miek.nl.", dns.TypeMX)
Or when not certain if the domain name is fully qualified:
m.SetQuestion(dns.Fqdn("miek.nl"), dns.TypeMX)
The message m is now a message with the question section set to ask the MX
records for the miek.nl. zone.
The following is slightly more verbose, but more flexible:
m1 := new(dns.Msg)
m1.Id = dns.Id()
m1.RecursionDesired = true
m1.Question = make([]dns.Question, 1)
m1.Question[0] = dns.Question{"miek.nl.", dns.TypeMX, dns.ClassINET}
After creating a message it can be sent. Basic use pattern for synchronous
querying the DNS at a server configured on 127.0.0.1 and port 53:
c := new(dns.Client)
in, rtt, err := c.Exchange(m1, "127.0.0.1:53")
Suppressing multiple outstanding queries (with the same question, type and
class) is as easy as setting:
c.SingleInflight = true
More advanced options are available using a net.Dialer and the corresponding API.
For example it is possible to set a timeout, or to specify a source IP address
and port to use for the connection:
c := new(dns.Client)
laddr := net.UDPAddr{
IP: net.ParseIP("[::1]"),
Port: 12345,
Zone: "",
}
c.Dialer := &net.Dialer{
Timeout: 200 * time.Millisecond,
LocalAddr: &laddr,
}
in, rtt, err := c.Exchange(m1, "8.8.8.8:53")
If these "advanced" features are not needed, a simple UDP query can be sent,
with:
in, err := dns.Exchange(m1, "127.0.0.1:53")
When this functions returns you will get DNS message. A DNS message consists
out of four sections.
The question section: in.Question, the answer section: in.Answer,
the authority section: in.Ns and the additional section: in.Extra.
Each of these sections (except the Question section) contain a []RR. Basic
use pattern for accessing the rdata of a TXT RR as the first RR in
the Answer section:
if t, ok := in.Answer[0].(*dns.TXT); ok {
// do something with t.Txt
}
Domain Name and TXT Character String Representations
Both domain names and TXT character strings are converted to presentation form
both when unpacked and when converted to strings.
For TXT character strings, tabs, carriage returns and line feeds will be
converted to \t, \r and \n respectively. Back slashes and quotations marks will
be escaped. Bytes below 32 and above 127 will be converted to \DDD form.
For domain names, in addition to the above rules brackets, periods, spaces,
semicolons and the at symbol are escaped.
DNSSEC
DNSSEC (DNS Security Extension) adds a layer of security to the DNS. It uses
public key cryptography to sign resource records. The public keys are stored in
DNSKEY records and the signatures in RRSIG records.
Requesting DNSSEC information for a zone is done by adding the DO (DNSSEC OK)
bit to a request.
m := new(dns.Msg)
m.SetEdns0(4096, true)
Signature generation, signature verification and key generation are all supported.
DYNAMIC UPDATES
Dynamic updates reuses the DNS message format, but renames three of the
sections. Question is Zone, Answer is Prerequisite, Authority is Update, only
the Additional is not renamed. See RFC 2136 for the gory details.
You can set a rather complex set of rules for the existence of absence of
certain resource records or names in a zone to specify if resource records
should be added or removed. The table from RFC 2136 supplemented with the Go
DNS function shows which functions exist to specify the prerequisites.
3.2.4 - Table Of Metavalues Used In Prerequisite Section
CLASS TYPE RDATA Meaning Function
--------------------------------------------------------------
ANY ANY empty Name is in use dns.NameUsed
ANY rrset empty RRset exists (value indep) dns.RRsetUsed
NONE ANY empty Name is not in use dns.NameNotUsed
NONE rrset empty RRset does not exist dns.RRsetNotUsed
zone rrset rr RRset exists (value dep) dns.Used
The prerequisite section can also be left empty. If you have decided on the
prerequisites you can tell what RRs should be added or deleted. The next table
shows the options you have and what functions to call.
3.4.2.6 - Table Of Metavalues Used In Update Section
CLASS TYPE RDATA Meaning Function
---------------------------------------------------------------
ANY ANY empty Delete all RRsets from name dns.RemoveName
ANY rrset empty Delete an RRset dns.RemoveRRset
NONE rrset rr Delete an RR from RRset dns.Remove
zone rrset rr Add to an RRset dns.Insert
TRANSACTION SIGNATURE
An TSIG or transaction signature adds a HMAC TSIG record to each message sent.
The supported algorithms include: HmacSHA1, HmacSHA256 and HmacSHA512.
Basic use pattern when querying with a TSIG name "axfr." (note that these key names
must be fully qualified - as they are domain names) and the base64 secret
"so6ZGir4GPAqINNh9U5c3A==":
If an incoming message contains a TSIG record it MUST be the last record in
the additional section (RFC2845 3.2). This means that you should make the
call to SetTsig last, right before executing the query. If you make any
changes to the RRset after calling SetTsig() the signature will be incorrect.
c := new(dns.Client)
c.TsigSecret = map[string]string{"axfr.": "so6ZGir4GPAqINNh9U5c3A=="}
m := new(dns.Msg)
m.SetQuestion("miek.nl.", dns.TypeMX)
m.SetTsig("axfr.", dns.HmacSHA256, 300, time.Now().Unix())
...
// When sending the TSIG RR is calculated and filled in before sending
When requesting an zone transfer (almost all TSIG usage is when requesting zone
transfers), with TSIG, this is the basic use pattern. In this example we
request an AXFR for miek.nl. with TSIG key named "axfr." and secret
"so6ZGir4GPAqINNh9U5c3A==" and using the server 176.58.119.54:
t := new(dns.Transfer)
m := new(dns.Msg)
t.TsigSecret = map[string]string{"axfr.": "so6ZGir4GPAqINNh9U5c3A=="}
m.SetAxfr("miek.nl.")
m.SetTsig("axfr.", dns.HmacSHA256, 300, time.Now().Unix())
c, err := t.In(m, "176.58.119.54:53")
for r := range c { ... }
You can now read the records from the transfer as they come in. Each envelope
is checked with TSIG. If something is not correct an error is returned.
A custom TSIG implementation can be used. This requires additional code to
perform any session establishment and signature generation/verification. The
client must be configured with an implementation of the TsigProvider interface:
type Provider struct{}
func (*Provider) Generate(msg []byte, tsig *dns.TSIG) ([]byte, error) {
// Use tsig.Hdr.Name and tsig.Algorithm in your code to
// generate the MAC using msg as the payload.
}
func (*Provider) Verify(msg []byte, tsig *dns.TSIG) error {
// Use tsig.Hdr.Name and tsig.Algorithm in your code to verify
// that msg matches the value in tsig.MAC.
}
c := new(dns.Client)
c.TsigProvider = new(Provider)
m := new(dns.Msg)
m.SetQuestion("miek.nl.", dns.TypeMX)
m.SetTsig(keyname, dns.HmacSHA256, 300, time.Now().Unix())
...
// TSIG RR is calculated by calling your Generate method
Basic use pattern validating and replying to a message that has TSIG set.
server := &dns.Server{Addr: ":53", Net: "udp"}
server.TsigSecret = map[string]string{"axfr.": "so6ZGir4GPAqINNh9U5c3A=="}
go server.ListenAndServe()
dns.HandleFunc(".", handleRequest)
func handleRequest(w dns.ResponseWriter, r *dns.Msg) {
m := new(dns.Msg)
m.SetReply(r)
if r.IsTsig() != nil {
if w.TsigStatus() == nil {
// *Msg r has an TSIG record and it was validated
m.SetTsig("axfr.", dns.HmacSHA256, 300, time.Now().Unix())
} else {
// *Msg r has an TSIG records and it was not validated
}
}
w.WriteMsg(m)
}
PRIVATE RRS
RFC 6895 sets aside a range of type codes for private use. This range is 65,280
- 65,534 (0xFF00 - 0xFFFE). When experimenting with new Resource Records these
can be used, before requesting an official type code from IANA.
See https://miek.nl/2014/september/21/idn-and-private-rr-in-go-dns/ for more
information.
EDNS0
EDNS0 is an extension mechanism for the DNS defined in RFC 2671 and updated by
RFC 6891. It defines a new RR type, the OPT RR, which is then completely
abused.
Basic use pattern for creating an (empty) OPT RR:
o := new(dns.OPT)
o.Hdr.Name = "." // MUST be the root zone, per definition.
o.Hdr.Rrtype = dns.TypeOPT
The rdata of an OPT RR consists out of a slice of EDNS0 (RFC 6891) interfaces.
Currently only a few have been standardized: EDNS0_NSID (RFC 5001) and
EDNS0_SUBNET (RFC 7871). Note that these options may be combined in an OPT RR.
Basic use pattern for a server to check if (and which) options are set:
// o is a dns.OPT
for _, s := range o.Option {
switch e := s.(type) {
case *dns.EDNS0_NSID:
// do stuff with e.Nsid
case *dns.EDNS0_SUBNET:
// access e.Family, e.Address, etc.
}
}
SIG(0)
From RFC 2931:
SIG(0) provides protection for DNS transactions and requests ....
... protection for glue records, DNS requests, protection for message headers
on requests and responses, and protection of the overall integrity of a response.
It works like TSIG, except that SIG(0) uses public key cryptography, instead of
the shared secret approach in TSIG. Supported algorithms: ECDSAP256SHA256,
ECDSAP384SHA384, RSASHA1, RSASHA256 and RSASHA512.
Signing subsequent messages in multi-message sessions is not implemented.
*/
package dns

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vendor/github.com/miekg/dns/duplicate.go generated vendored Normal file
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package dns
//go:generate go run duplicate_generate.go
// IsDuplicate checks of r1 and r2 are duplicates of each other, excluding the TTL.
// So this means the header data is equal *and* the RDATA is the same. Returns true
// if so, otherwise false. It's a protocol violation to have identical RRs in a message.
func IsDuplicate(r1, r2 RR) bool {
// Check whether the record header is identical.
if !r1.Header().isDuplicate(r2.Header()) {
return false
}
// Check whether the RDATA is identical.
return r1.isDuplicate(r2)
}
func (r1 *RR_Header) isDuplicate(_r2 RR) bool {
r2, ok := _r2.(*RR_Header)
if !ok {
return false
}
if r1.Class != r2.Class {
return false
}
if r1.Rrtype != r2.Rrtype {
return false
}
if !isDuplicateName(r1.Name, r2.Name) {
return false
}
// ignore TTL
return true
}
// isDuplicateName checks if the domain names s1 and s2 are equal.
func isDuplicateName(s1, s2 string) bool { return equal(s1, s2) }

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vendor/github.com/miekg/dns/edns.go generated vendored Normal file
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package dns
import (
"encoding/binary"
"encoding/hex"
"errors"
"fmt"
"net"
"strconv"
)
// EDNS0 Option codes.
const (
EDNS0LLQ = 0x1 // long lived queries: http://tools.ietf.org/html/draft-sekar-dns-llq-01
EDNS0UL = 0x2 // update lease draft: http://files.dns-sd.org/draft-sekar-dns-ul.txt
EDNS0NSID = 0x3 // nsid (See RFC 5001)
EDNS0ESU = 0x4 // ENUM Source-URI draft: https://datatracker.ietf.org/doc/html/draft-kaplan-enum-source-uri-00
EDNS0DAU = 0x5 // DNSSEC Algorithm Understood
EDNS0DHU = 0x6 // DS Hash Understood
EDNS0N3U = 0x7 // NSEC3 Hash Understood
EDNS0SUBNET = 0x8 // client-subnet (See RFC 7871)
EDNS0EXPIRE = 0x9 // EDNS0 expire
EDNS0COOKIE = 0xa // EDNS0 Cookie
EDNS0TCPKEEPALIVE = 0xb // EDNS0 tcp keep alive (See RFC 7828)
EDNS0PADDING = 0xc // EDNS0 padding (See RFC 7830)
EDNS0EDE = 0xf // EDNS0 extended DNS errors (See RFC 8914)
EDNS0LOCALSTART = 0xFDE9 // Beginning of range reserved for local/experimental use (See RFC 6891)
EDNS0LOCALEND = 0xFFFE // End of range reserved for local/experimental use (See RFC 6891)
_DO = 1 << 15 // DNSSEC OK
)
// makeDataOpt is used to unpack the EDNS0 option(s) from a message.
func makeDataOpt(code uint16) EDNS0 {
// All the EDNS0.* constants above need to be in this switch.
switch code {
case EDNS0LLQ:
return new(EDNS0_LLQ)
case EDNS0UL:
return new(EDNS0_UL)
case EDNS0NSID:
return new(EDNS0_NSID)
case EDNS0DAU:
return new(EDNS0_DAU)
case EDNS0DHU:
return new(EDNS0_DHU)
case EDNS0N3U:
return new(EDNS0_N3U)
case EDNS0SUBNET:
return new(EDNS0_SUBNET)
case EDNS0EXPIRE:
return new(EDNS0_EXPIRE)
case EDNS0COOKIE:
return new(EDNS0_COOKIE)
case EDNS0TCPKEEPALIVE:
return new(EDNS0_TCP_KEEPALIVE)
case EDNS0PADDING:
return new(EDNS0_PADDING)
case EDNS0EDE:
return new(EDNS0_EDE)
case EDNS0ESU:
return &EDNS0_ESU{Code: EDNS0ESU}
default:
e := new(EDNS0_LOCAL)
e.Code = code
return e
}
}
// OPT is the EDNS0 RR appended to messages to convey extra (meta) information.
// See RFC 6891.
type OPT struct {
Hdr RR_Header
Option []EDNS0 `dns:"opt"`
}
func (rr *OPT) String() string {
s := "\n;; OPT PSEUDOSECTION:\n; EDNS: version " + strconv.Itoa(int(rr.Version())) + "; "
if rr.Do() {
s += "flags: do; "
} else {
s += "flags: ; "
}
s += "udp: " + strconv.Itoa(int(rr.UDPSize()))
for _, o := range rr.Option {
switch o.(type) {
case *EDNS0_NSID:
s += "\n; NSID: " + o.String()
h, e := o.pack()
var r string
if e == nil {
for _, c := range h {
r += "(" + string(c) + ")"
}
s += " " + r
}
case *EDNS0_SUBNET:
s += "\n; SUBNET: " + o.String()
case *EDNS0_COOKIE:
s += "\n; COOKIE: " + o.String()
case *EDNS0_TCP_KEEPALIVE:
s += "\n; KEEPALIVE: " + o.String()
case *EDNS0_UL:
s += "\n; UPDATE LEASE: " + o.String()
case *EDNS0_LLQ:
s += "\n; LONG LIVED QUERIES: " + o.String()
case *EDNS0_DAU:
s += "\n; DNSSEC ALGORITHM UNDERSTOOD: " + o.String()
case *EDNS0_DHU:
s += "\n; DS HASH UNDERSTOOD: " + o.String()
case *EDNS0_N3U:
s += "\n; NSEC3 HASH UNDERSTOOD: " + o.String()
case *EDNS0_LOCAL:
s += "\n; LOCAL OPT: " + o.String()
case *EDNS0_PADDING:
s += "\n; PADDING: " + o.String()
case *EDNS0_EDE:
s += "\n; EDE: " + o.String()
case *EDNS0_ESU:
s += "\n; ESU: " + o.String()
}
}
return s
}
func (rr *OPT) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
for _, o := range rr.Option {
l += 4 // Account for 2-byte option code and 2-byte option length.
lo, _ := o.pack()
l += len(lo)
}
return l
}
func (*OPT) parse(c *zlexer, origin string) *ParseError {
return &ParseError{err: "OPT records do not have a presentation format"}
}
func (rr *OPT) isDuplicate(r2 RR) bool { return false }
// return the old value -> delete SetVersion?
// Version returns the EDNS version used. Only zero is defined.
func (rr *OPT) Version() uint8 {
return uint8(rr.Hdr.Ttl & 0x00FF0000 >> 16)
}
// SetVersion sets the version of EDNS. This is usually zero.
func (rr *OPT) SetVersion(v uint8) {
rr.Hdr.Ttl = rr.Hdr.Ttl&0xFF00FFFF | uint32(v)<<16
}
// ExtendedRcode returns the EDNS extended RCODE field (the upper 8 bits of the TTL).
func (rr *OPT) ExtendedRcode() int {
return int(rr.Hdr.Ttl&0xFF000000>>24) << 4
}
// SetExtendedRcode sets the EDNS extended RCODE field.
//
// If the RCODE is not an extended RCODE, will reset the extended RCODE field to 0.
func (rr *OPT) SetExtendedRcode(v uint16) {
rr.Hdr.Ttl = rr.Hdr.Ttl&0x00FFFFFF | uint32(v>>4)<<24
}
// UDPSize returns the UDP buffer size.
func (rr *OPT) UDPSize() uint16 {
return rr.Hdr.Class
}
// SetUDPSize sets the UDP buffer size.
func (rr *OPT) SetUDPSize(size uint16) {
rr.Hdr.Class = size
}
// Do returns the value of the DO (DNSSEC OK) bit.
func (rr *OPT) Do() bool {
return rr.Hdr.Ttl&_DO == _DO
}
// SetDo sets the DO (DNSSEC OK) bit.
// If we pass an argument, set the DO bit to that value.
// It is possible to pass 2 or more arguments. Any arguments after the 1st is silently ignored.
func (rr *OPT) SetDo(do ...bool) {
if len(do) == 1 {
if do[0] {
rr.Hdr.Ttl |= _DO
} else {
rr.Hdr.Ttl &^= _DO
}
} else {
rr.Hdr.Ttl |= _DO
}
}
// Z returns the Z part of the OPT RR as a uint16 with only the 15 least significant bits used.
func (rr *OPT) Z() uint16 {
return uint16(rr.Hdr.Ttl & 0x7FFF)
}
// SetZ sets the Z part of the OPT RR, note only the 15 least significant bits of z are used.
func (rr *OPT) SetZ(z uint16) {
rr.Hdr.Ttl = rr.Hdr.Ttl&^0x7FFF | uint32(z&0x7FFF)
}
// EDNS0 defines an EDNS0 Option. An OPT RR can have multiple options appended to it.
type EDNS0 interface {
// Option returns the option code for the option.
Option() uint16
// pack returns the bytes of the option data.
pack() ([]byte, error)
// unpack sets the data as found in the buffer. Is also sets
// the length of the slice as the length of the option data.
unpack([]byte) error
// String returns the string representation of the option.
String() string
// copy returns a deep-copy of the option.
copy() EDNS0
}
// EDNS0_NSID option is used to retrieve a nameserver
// identifier. When sending a request Nsid must be set to the empty string
// The identifier is an opaque string encoded as hex.
// Basic use pattern for creating an nsid option:
//
// o := new(dns.OPT)
// o.Hdr.Name = "."
// o.Hdr.Rrtype = dns.TypeOPT
// e := new(dns.EDNS0_NSID)
// e.Code = dns.EDNS0NSID
// e.Nsid = "AA"
// o.Option = append(o.Option, e)
type EDNS0_NSID struct {
Code uint16 // Always EDNS0NSID
Nsid string // This string needs to be hex encoded
}
func (e *EDNS0_NSID) pack() ([]byte, error) {
h, err := hex.DecodeString(e.Nsid)
if err != nil {
return nil, err
}
return h, nil
}
// Option implements the EDNS0 interface.
func (e *EDNS0_NSID) Option() uint16 { return EDNS0NSID } // Option returns the option code.
func (e *EDNS0_NSID) unpack(b []byte) error { e.Nsid = hex.EncodeToString(b); return nil }
func (e *EDNS0_NSID) String() string { return e.Nsid }
func (e *EDNS0_NSID) copy() EDNS0 { return &EDNS0_NSID{e.Code, e.Nsid} }
// EDNS0_SUBNET is the subnet option that is used to give the remote nameserver
// an idea of where the client lives. See RFC 7871. It can then give back a different
// answer depending on the location or network topology.
// Basic use pattern for creating an subnet option:
//
// o := new(dns.OPT)
// o.Hdr.Name = "."
// o.Hdr.Rrtype = dns.TypeOPT
// e := new(dns.EDNS0_SUBNET)
// e.Code = dns.EDNS0SUBNET
// e.Family = 1 // 1 for IPv4 source address, 2 for IPv6
// e.SourceNetmask = 32 // 32 for IPV4, 128 for IPv6
// e.SourceScope = 0
// e.Address = net.ParseIP("127.0.0.1").To4() // for IPv4
// // e.Address = net.ParseIP("2001:7b8:32a::2") // for IPV6
// o.Option = append(o.Option, e)
//
// This code will parse all the available bits when unpacking (up to optlen).
// When packing it will apply SourceNetmask. If you need more advanced logic,
// patches welcome and good luck.
type EDNS0_SUBNET struct {
Code uint16 // Always EDNS0SUBNET
Family uint16 // 1 for IP, 2 for IP6
SourceNetmask uint8
SourceScope uint8
Address net.IP
}
// Option implements the EDNS0 interface.
func (e *EDNS0_SUBNET) Option() uint16 { return EDNS0SUBNET }
func (e *EDNS0_SUBNET) pack() ([]byte, error) {
b := make([]byte, 4)
binary.BigEndian.PutUint16(b[0:], e.Family)
b[2] = e.SourceNetmask
b[3] = e.SourceScope
switch e.Family {
case 0:
// "dig" sets AddressFamily to 0 if SourceNetmask is also 0
// We might don't need to complain either
if e.SourceNetmask != 0 {
return nil, errors.New("dns: bad address family")
}
case 1:
if e.SourceNetmask > net.IPv4len*8 {
return nil, errors.New("dns: bad netmask")
}
if len(e.Address.To4()) != net.IPv4len {
return nil, errors.New("dns: bad address")
}
ip := e.Address.To4().Mask(net.CIDRMask(int(e.SourceNetmask), net.IPv4len*8))
needLength := (e.SourceNetmask + 8 - 1) / 8 // division rounding up
b = append(b, ip[:needLength]...)
case 2:
if e.SourceNetmask > net.IPv6len*8 {
return nil, errors.New("dns: bad netmask")
}
if len(e.Address) != net.IPv6len {
return nil, errors.New("dns: bad address")
}
ip := e.Address.Mask(net.CIDRMask(int(e.SourceNetmask), net.IPv6len*8))
needLength := (e.SourceNetmask + 8 - 1) / 8 // division rounding up
b = append(b, ip[:needLength]...)
default:
return nil, errors.New("dns: bad address family")
}
return b, nil
}
func (e *EDNS0_SUBNET) unpack(b []byte) error {
if len(b) < 4 {
return ErrBuf
}
e.Family = binary.BigEndian.Uint16(b)
e.SourceNetmask = b[2]
e.SourceScope = b[3]
switch e.Family {
case 0:
// "dig" sets AddressFamily to 0 if SourceNetmask is also 0
// It's okay to accept such a packet
if e.SourceNetmask != 0 {
return errors.New("dns: bad address family")
}
e.Address = net.IPv4(0, 0, 0, 0)
case 1:
if e.SourceNetmask > net.IPv4len*8 || e.SourceScope > net.IPv4len*8 {
return errors.New("dns: bad netmask")
}
addr := make(net.IP, net.IPv4len)
copy(addr, b[4:])
e.Address = addr.To16()
case 2:
if e.SourceNetmask > net.IPv6len*8 || e.SourceScope > net.IPv6len*8 {
return errors.New("dns: bad netmask")
}
addr := make(net.IP, net.IPv6len)
copy(addr, b[4:])
e.Address = addr
default:
return errors.New("dns: bad address family")
}
return nil
}
func (e *EDNS0_SUBNET) String() (s string) {
if e.Address == nil {
s = "<nil>"
} else if e.Address.To4() != nil {
s = e.Address.String()
} else {
s = "[" + e.Address.String() + "]"
}
s += "/" + strconv.Itoa(int(e.SourceNetmask)) + "/" + strconv.Itoa(int(e.SourceScope))
return
}
func (e *EDNS0_SUBNET) copy() EDNS0 {
return &EDNS0_SUBNET{
e.Code,
e.Family,
e.SourceNetmask,
e.SourceScope,
e.Address,
}
}
// The EDNS0_COOKIE option is used to add a DNS Cookie to a message.
//
// o := new(dns.OPT)
// o.Hdr.Name = "."
// o.Hdr.Rrtype = dns.TypeOPT
// e := new(dns.EDNS0_COOKIE)
// e.Code = dns.EDNS0COOKIE
// e.Cookie = "24a5ac.."
// o.Option = append(o.Option, e)
//
// The Cookie field consists out of a client cookie (RFC 7873 Section 4), that is
// always 8 bytes. It may then optionally be followed by the server cookie. The server
// cookie is of variable length, 8 to a maximum of 32 bytes. In other words:
//
// cCookie := o.Cookie[:16]
// sCookie := o.Cookie[16:]
//
// There is no guarantee that the Cookie string has a specific length.
type EDNS0_COOKIE struct {
Code uint16 // Always EDNS0COOKIE
Cookie string // Hex-encoded cookie data
}
func (e *EDNS0_COOKIE) pack() ([]byte, error) {
h, err := hex.DecodeString(e.Cookie)
if err != nil {
return nil, err
}
return h, nil
}
// Option implements the EDNS0 interface.
func (e *EDNS0_COOKIE) Option() uint16 { return EDNS0COOKIE }
func (e *EDNS0_COOKIE) unpack(b []byte) error { e.Cookie = hex.EncodeToString(b); return nil }
func (e *EDNS0_COOKIE) String() string { return e.Cookie }
func (e *EDNS0_COOKIE) copy() EDNS0 { return &EDNS0_COOKIE{e.Code, e.Cookie} }
// The EDNS0_UL (Update Lease) (draft RFC) option is used to tell the server to set
// an expiration on an update RR. This is helpful for clients that cannot clean
// up after themselves. This is a draft RFC and more information can be found at
// https://tools.ietf.org/html/draft-sekar-dns-ul-02
//
// o := new(dns.OPT)
// o.Hdr.Name = "."
// o.Hdr.Rrtype = dns.TypeOPT
// e := new(dns.EDNS0_UL)
// e.Code = dns.EDNS0UL
// e.Lease = 120 // in seconds
// o.Option = append(o.Option, e)
type EDNS0_UL struct {
Code uint16 // Always EDNS0UL
Lease uint32
KeyLease uint32
}
// Option implements the EDNS0 interface.
func (e *EDNS0_UL) Option() uint16 { return EDNS0UL }
func (e *EDNS0_UL) String() string { return fmt.Sprintf("%d %d", e.Lease, e.KeyLease) }
func (e *EDNS0_UL) copy() EDNS0 { return &EDNS0_UL{e.Code, e.Lease, e.KeyLease} }
// Copied: http://golang.org/src/pkg/net/dnsmsg.go
func (e *EDNS0_UL) pack() ([]byte, error) {
var b []byte
if e.KeyLease == 0 {
b = make([]byte, 4)
} else {
b = make([]byte, 8)
binary.BigEndian.PutUint32(b[4:], e.KeyLease)
}
binary.BigEndian.PutUint32(b, e.Lease)
return b, nil
}
func (e *EDNS0_UL) unpack(b []byte) error {
switch len(b) {
case 4:
e.KeyLease = 0
case 8:
e.KeyLease = binary.BigEndian.Uint32(b[4:])
default:
return ErrBuf
}
e.Lease = binary.BigEndian.Uint32(b)
return nil
}
// EDNS0_LLQ stands for Long Lived Queries: http://tools.ietf.org/html/draft-sekar-dns-llq-01
// Implemented for completeness, as the EDNS0 type code is assigned.
type EDNS0_LLQ struct {
Code uint16 // Always EDNS0LLQ
Version uint16
Opcode uint16
Error uint16
Id uint64
LeaseLife uint32
}
// Option implements the EDNS0 interface.
func (e *EDNS0_LLQ) Option() uint16 { return EDNS0LLQ }
func (e *EDNS0_LLQ) pack() ([]byte, error) {
b := make([]byte, 18)
binary.BigEndian.PutUint16(b[0:], e.Version)
binary.BigEndian.PutUint16(b[2:], e.Opcode)
binary.BigEndian.PutUint16(b[4:], e.Error)
binary.BigEndian.PutUint64(b[6:], e.Id)
binary.BigEndian.PutUint32(b[14:], e.LeaseLife)
return b, nil
}
func (e *EDNS0_LLQ) unpack(b []byte) error {
if len(b) < 18 {
return ErrBuf
}
e.Version = binary.BigEndian.Uint16(b[0:])
e.Opcode = binary.BigEndian.Uint16(b[2:])
e.Error = binary.BigEndian.Uint16(b[4:])
e.Id = binary.BigEndian.Uint64(b[6:])
e.LeaseLife = binary.BigEndian.Uint32(b[14:])
return nil
}
func (e *EDNS0_LLQ) String() string {
s := strconv.FormatUint(uint64(e.Version), 10) + " " + strconv.FormatUint(uint64(e.Opcode), 10) +
" " + strconv.FormatUint(uint64(e.Error), 10) + " " + strconv.FormatUint(e.Id, 10) +
" " + strconv.FormatUint(uint64(e.LeaseLife), 10)
return s
}
func (e *EDNS0_LLQ) copy() EDNS0 {
return &EDNS0_LLQ{e.Code, e.Version, e.Opcode, e.Error, e.Id, e.LeaseLife}
}
// EDNS0_DAU implements the EDNS0 "DNSSEC Algorithm Understood" option. See RFC 6975.
type EDNS0_DAU struct {
Code uint16 // Always EDNS0DAU
AlgCode []uint8
}
// Option implements the EDNS0 interface.
func (e *EDNS0_DAU) Option() uint16 { return EDNS0DAU }
func (e *EDNS0_DAU) pack() ([]byte, error) { return e.AlgCode, nil }
func (e *EDNS0_DAU) unpack(b []byte) error { e.AlgCode = b; return nil }
func (e *EDNS0_DAU) String() string {
s := ""
for _, alg := range e.AlgCode {
if a, ok := AlgorithmToString[alg]; ok {
s += " " + a
} else {
s += " " + strconv.Itoa(int(alg))
}
}
return s
}
func (e *EDNS0_DAU) copy() EDNS0 { return &EDNS0_DAU{e.Code, e.AlgCode} }
// EDNS0_DHU implements the EDNS0 "DS Hash Understood" option. See RFC 6975.
type EDNS0_DHU struct {
Code uint16 // Always EDNS0DHU
AlgCode []uint8
}
// Option implements the EDNS0 interface.
func (e *EDNS0_DHU) Option() uint16 { return EDNS0DHU }
func (e *EDNS0_DHU) pack() ([]byte, error) { return e.AlgCode, nil }
func (e *EDNS0_DHU) unpack(b []byte) error { e.AlgCode = b; return nil }
func (e *EDNS0_DHU) String() string {
s := ""
for _, alg := range e.AlgCode {
if a, ok := HashToString[alg]; ok {
s += " " + a
} else {
s += " " + strconv.Itoa(int(alg))
}
}
return s
}
func (e *EDNS0_DHU) copy() EDNS0 { return &EDNS0_DHU{e.Code, e.AlgCode} }
// EDNS0_N3U implements the EDNS0 "NSEC3 Hash Understood" option. See RFC 6975.
type EDNS0_N3U struct {
Code uint16 // Always EDNS0N3U
AlgCode []uint8
}
// Option implements the EDNS0 interface.
func (e *EDNS0_N3U) Option() uint16 { return EDNS0N3U }
func (e *EDNS0_N3U) pack() ([]byte, error) { return e.AlgCode, nil }
func (e *EDNS0_N3U) unpack(b []byte) error { e.AlgCode = b; return nil }
func (e *EDNS0_N3U) String() string {
// Re-use the hash map
s := ""
for _, alg := range e.AlgCode {
if a, ok := HashToString[alg]; ok {
s += " " + a
} else {
s += " " + strconv.Itoa(int(alg))
}
}
return s
}
func (e *EDNS0_N3U) copy() EDNS0 { return &EDNS0_N3U{e.Code, e.AlgCode} }
// EDNS0_EXPIRE implements the EDNS0 option as described in RFC 7314.
type EDNS0_EXPIRE struct {
Code uint16 // Always EDNS0EXPIRE
Expire uint32
Empty bool // Empty is used to signal an empty Expire option in a backwards compatible way, it's not used on the wire.
}
// Option implements the EDNS0 interface.
func (e *EDNS0_EXPIRE) Option() uint16 { return EDNS0EXPIRE }
func (e *EDNS0_EXPIRE) copy() EDNS0 { return &EDNS0_EXPIRE{e.Code, e.Expire, e.Empty} }
func (e *EDNS0_EXPIRE) pack() ([]byte, error) {
if e.Empty {
return []byte{}, nil
}
b := make([]byte, 4)
binary.BigEndian.PutUint32(b, e.Expire)
return b, nil
}
func (e *EDNS0_EXPIRE) unpack(b []byte) error {
if len(b) == 0 {
// zero-length EXPIRE query, see RFC 7314 Section 2
e.Empty = true
return nil
}
if len(b) < 4 {
return ErrBuf
}
e.Expire = binary.BigEndian.Uint32(b)
e.Empty = false
return nil
}
func (e *EDNS0_EXPIRE) String() (s string) {
if e.Empty {
return ""
}
return strconv.FormatUint(uint64(e.Expire), 10)
}
// The EDNS0_LOCAL option is used for local/experimental purposes. The option
// code is recommended to be within the range [EDNS0LOCALSTART, EDNS0LOCALEND]
// (RFC6891), although any unassigned code can actually be used. The content of
// the option is made available in Data, unaltered.
// Basic use pattern for creating a local option:
//
// o := new(dns.OPT)
// o.Hdr.Name = "."
// o.Hdr.Rrtype = dns.TypeOPT
// e := new(dns.EDNS0_LOCAL)
// e.Code = dns.EDNS0LOCALSTART
// e.Data = []byte{72, 82, 74}
// o.Option = append(o.Option, e)
type EDNS0_LOCAL struct {
Code uint16
Data []byte
}
// Option implements the EDNS0 interface.
func (e *EDNS0_LOCAL) Option() uint16 { return e.Code }
func (e *EDNS0_LOCAL) String() string {
return strconv.FormatInt(int64(e.Code), 10) + ":0x" + hex.EncodeToString(e.Data)
}
func (e *EDNS0_LOCAL) copy() EDNS0 {
b := make([]byte, len(e.Data))
copy(b, e.Data)
return &EDNS0_LOCAL{e.Code, b}
}
func (e *EDNS0_LOCAL) pack() ([]byte, error) {
b := make([]byte, len(e.Data))
copied := copy(b, e.Data)
if copied != len(e.Data) {
return nil, ErrBuf
}
return b, nil
}
func (e *EDNS0_LOCAL) unpack(b []byte) error {
e.Data = make([]byte, len(b))
copied := copy(e.Data, b)
if copied != len(b) {
return ErrBuf
}
return nil
}
// EDNS0_TCP_KEEPALIVE is an EDNS0 option that instructs the server to keep
// the TCP connection alive. See RFC 7828.
type EDNS0_TCP_KEEPALIVE struct {
Code uint16 // Always EDNSTCPKEEPALIVE
// Timeout is an idle timeout value for the TCP connection, specified in
// units of 100 milliseconds, encoded in network byte order. If set to 0,
// pack will return a nil slice.
Timeout uint16
// Length is the option's length.
// Deprecated: this field is deprecated and is always equal to 0.
Length uint16
}
// Option implements the EDNS0 interface.
func (e *EDNS0_TCP_KEEPALIVE) Option() uint16 { return EDNS0TCPKEEPALIVE }
func (e *EDNS0_TCP_KEEPALIVE) pack() ([]byte, error) {
if e.Timeout > 0 {
b := make([]byte, 2)
binary.BigEndian.PutUint16(b, e.Timeout)
return b, nil
}
return nil, nil
}
func (e *EDNS0_TCP_KEEPALIVE) unpack(b []byte) error {
switch len(b) {
case 0:
case 2:
e.Timeout = binary.BigEndian.Uint16(b)
default:
return fmt.Errorf("dns: length mismatch, want 0/2 but got %d", len(b))
}
return nil
}
func (e *EDNS0_TCP_KEEPALIVE) String() string {
s := "use tcp keep-alive"
if e.Timeout == 0 {
s += ", timeout omitted"
} else {
s += fmt.Sprintf(", timeout %dms", e.Timeout*100)
}
return s
}
func (e *EDNS0_TCP_KEEPALIVE) copy() EDNS0 { return &EDNS0_TCP_KEEPALIVE{e.Code, e.Timeout, e.Length} }
// EDNS0_PADDING option is used to add padding to a request/response. The default
// value of padding SHOULD be 0x0 but other values MAY be used, for instance if
// compression is applied before encryption which may break signatures.
type EDNS0_PADDING struct {
Padding []byte
}
// Option implements the EDNS0 interface.
func (e *EDNS0_PADDING) Option() uint16 { return EDNS0PADDING }
func (e *EDNS0_PADDING) pack() ([]byte, error) { return e.Padding, nil }
func (e *EDNS0_PADDING) unpack(b []byte) error { e.Padding = b; return nil }
func (e *EDNS0_PADDING) String() string { return fmt.Sprintf("%0X", e.Padding) }
func (e *EDNS0_PADDING) copy() EDNS0 {
b := make([]byte, len(e.Padding))
copy(b, e.Padding)
return &EDNS0_PADDING{b}
}
// Extended DNS Error Codes (RFC 8914).
const (
ExtendedErrorCodeOther uint16 = iota
ExtendedErrorCodeUnsupportedDNSKEYAlgorithm
ExtendedErrorCodeUnsupportedDSDigestType
ExtendedErrorCodeStaleAnswer
ExtendedErrorCodeForgedAnswer
ExtendedErrorCodeDNSSECIndeterminate
ExtendedErrorCodeDNSBogus
ExtendedErrorCodeSignatureExpired
ExtendedErrorCodeSignatureNotYetValid
ExtendedErrorCodeDNSKEYMissing
ExtendedErrorCodeRRSIGsMissing
ExtendedErrorCodeNoZoneKeyBitSet
ExtendedErrorCodeNSECMissing
ExtendedErrorCodeCachedError
ExtendedErrorCodeNotReady
ExtendedErrorCodeBlocked
ExtendedErrorCodeCensored
ExtendedErrorCodeFiltered
ExtendedErrorCodeProhibited
ExtendedErrorCodeStaleNXDOMAINAnswer
ExtendedErrorCodeNotAuthoritative
ExtendedErrorCodeNotSupported
ExtendedErrorCodeNoReachableAuthority
ExtendedErrorCodeNetworkError
ExtendedErrorCodeInvalidData
)
// ExtendedErrorCodeToString maps extended error info codes to a human readable
// description.
var ExtendedErrorCodeToString = map[uint16]string{
ExtendedErrorCodeOther: "Other",
ExtendedErrorCodeUnsupportedDNSKEYAlgorithm: "Unsupported DNSKEY Algorithm",
ExtendedErrorCodeUnsupportedDSDigestType: "Unsupported DS Digest Type",
ExtendedErrorCodeStaleAnswer: "Stale Answer",
ExtendedErrorCodeForgedAnswer: "Forged Answer",
ExtendedErrorCodeDNSSECIndeterminate: "DNSSEC Indeterminate",
ExtendedErrorCodeDNSBogus: "DNSSEC Bogus",
ExtendedErrorCodeSignatureExpired: "Signature Expired",
ExtendedErrorCodeSignatureNotYetValid: "Signature Not Yet Valid",
ExtendedErrorCodeDNSKEYMissing: "DNSKEY Missing",
ExtendedErrorCodeRRSIGsMissing: "RRSIGs Missing",
ExtendedErrorCodeNoZoneKeyBitSet: "No Zone Key Bit Set",
ExtendedErrorCodeNSECMissing: "NSEC Missing",
ExtendedErrorCodeCachedError: "Cached Error",
ExtendedErrorCodeNotReady: "Not Ready",
ExtendedErrorCodeBlocked: "Blocked",
ExtendedErrorCodeCensored: "Censored",
ExtendedErrorCodeFiltered: "Filtered",
ExtendedErrorCodeProhibited: "Prohibited",
ExtendedErrorCodeStaleNXDOMAINAnswer: "Stale NXDOMAIN Answer",
ExtendedErrorCodeNotAuthoritative: "Not Authoritative",
ExtendedErrorCodeNotSupported: "Not Supported",
ExtendedErrorCodeNoReachableAuthority: "No Reachable Authority",
ExtendedErrorCodeNetworkError: "Network Error",
ExtendedErrorCodeInvalidData: "Invalid Data",
}
// StringToExtendedErrorCode is a map from human readable descriptions to
// extended error info codes.
var StringToExtendedErrorCode = reverseInt16(ExtendedErrorCodeToString)
// EDNS0_EDE option is used to return additional information about the cause of
// DNS errors.
type EDNS0_EDE struct {
InfoCode uint16
ExtraText string
}
// Option implements the EDNS0 interface.
func (e *EDNS0_EDE) Option() uint16 { return EDNS0EDE }
func (e *EDNS0_EDE) copy() EDNS0 { return &EDNS0_EDE{e.InfoCode, e.ExtraText} }
func (e *EDNS0_EDE) String() string {
info := strconv.FormatUint(uint64(e.InfoCode), 10)
if s, ok := ExtendedErrorCodeToString[e.InfoCode]; ok {
info += fmt.Sprintf(" (%s)", s)
}
return fmt.Sprintf("%s: (%s)", info, e.ExtraText)
}
func (e *EDNS0_EDE) pack() ([]byte, error) {
b := make([]byte, 2+len(e.ExtraText))
binary.BigEndian.PutUint16(b[0:], e.InfoCode)
copy(b[2:], []byte(e.ExtraText))
return b, nil
}
func (e *EDNS0_EDE) unpack(b []byte) error {
if len(b) < 2 {
return ErrBuf
}
e.InfoCode = binary.BigEndian.Uint16(b[0:])
e.ExtraText = string(b[2:])
return nil
}
// The EDNS0_ESU option for ENUM Source-URI Extension
type EDNS0_ESU struct {
Code uint16
Uri string
}
// Option implements the EDNS0 interface.
func (e *EDNS0_ESU) Option() uint16 { return EDNS0ESU }
func (e *EDNS0_ESU) String() string { return e.Uri }
func (e *EDNS0_ESU) copy() EDNS0 { return &EDNS0_ESU{e.Code, e.Uri} }
func (e *EDNS0_ESU) pack() ([]byte, error) { return []byte(e.Uri), nil }
func (e *EDNS0_ESU) unpack(b []byte) error {
e.Uri = string(b)
return nil
}

93
vendor/github.com/miekg/dns/format.go generated vendored Normal file
View file

@ -0,0 +1,93 @@
package dns
import (
"net"
"reflect"
"strconv"
)
// NumField returns the number of rdata fields r has.
func NumField(r RR) int {
return reflect.ValueOf(r).Elem().NumField() - 1 // Remove RR_Header
}
// Field returns the rdata field i as a string. Fields are indexed starting from 1.
// RR types that holds slice data, for instance the NSEC type bitmap will return a single
// string where the types are concatenated using a space.
// Accessing non existing fields will cause a panic.
func Field(r RR, i int) string {
if i == 0 {
return ""
}
d := reflect.ValueOf(r).Elem().Field(i)
switch d.Kind() {
case reflect.String:
return d.String()
case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
return strconv.FormatInt(d.Int(), 10)
case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64:
return strconv.FormatUint(d.Uint(), 10)
case reflect.Slice:
switch reflect.ValueOf(r).Elem().Type().Field(i).Tag {
case `dns:"a"`:
// TODO(miek): Hmm store this as 16 bytes
if d.Len() < net.IPv4len {
return ""
}
if d.Len() < net.IPv6len {
return net.IPv4(byte(d.Index(0).Uint()),
byte(d.Index(1).Uint()),
byte(d.Index(2).Uint()),
byte(d.Index(3).Uint())).String()
}
return net.IPv4(byte(d.Index(12).Uint()),
byte(d.Index(13).Uint()),
byte(d.Index(14).Uint()),
byte(d.Index(15).Uint())).String()
case `dns:"aaaa"`:
if d.Len() < net.IPv6len {
return ""
}
return net.IP{
byte(d.Index(0).Uint()),
byte(d.Index(1).Uint()),
byte(d.Index(2).Uint()),
byte(d.Index(3).Uint()),
byte(d.Index(4).Uint()),
byte(d.Index(5).Uint()),
byte(d.Index(6).Uint()),
byte(d.Index(7).Uint()),
byte(d.Index(8).Uint()),
byte(d.Index(9).Uint()),
byte(d.Index(10).Uint()),
byte(d.Index(11).Uint()),
byte(d.Index(12).Uint()),
byte(d.Index(13).Uint()),
byte(d.Index(14).Uint()),
byte(d.Index(15).Uint()),
}.String()
case `dns:"nsec"`:
if d.Len() == 0 {
return ""
}
s := Type(d.Index(0).Uint()).String()
for i := 1; i < d.Len(); i++ {
s += " " + Type(d.Index(i).Uint()).String()
}
return s
default:
// if it does not have a tag its a string slice
fallthrough
case `dns:"txt"`:
if d.Len() == 0 {
return ""
}
s := d.Index(0).String()
for i := 1; i < d.Len(); i++ {
s += " " + d.Index(i).String()
}
return s
}
}
return ""
}

32
vendor/github.com/miekg/dns/fuzz.go generated vendored Normal file
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@ -0,0 +1,32 @@
// +build fuzz
package dns
import "strings"
func Fuzz(data []byte) int {
msg := new(Msg)
if err := msg.Unpack(data); err != nil {
return 0
}
if _, err := msg.Pack(); err != nil {
return 0
}
return 1
}
func FuzzNewRR(data []byte) int {
str := string(data)
// Do not fuzz lines that include the $INCLUDE keyword and hint the fuzzer
// at avoiding them.
// See GH#1025 for context.
if strings.Contains(strings.ToUpper(str), "$INCLUDE") {
return -1
}
if _, err := NewRR(str); err != nil {
return 0
}
return 1
}

247
vendor/github.com/miekg/dns/generate.go generated vendored Normal file
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@ -0,0 +1,247 @@
package dns
import (
"bytes"
"fmt"
"io"
"strconv"
"strings"
)
// Parse the $GENERATE statement as used in BIND9 zones.
// See http://www.zytrax.com/books/dns/ch8/generate.html for instance.
// We are called after '$GENERATE '. After which we expect:
// * the range (12-24/2)
// * lhs (ownername)
// * [[ttl][class]]
// * type
// * rhs (rdata)
// But we are lazy here, only the range is parsed *all* occurrences
// of $ after that are interpreted.
func (zp *ZoneParser) generate(l lex) (RR, bool) {
token := l.token
step := int64(1)
if i := strings.IndexByte(token, '/'); i >= 0 {
if i+1 == len(token) {
return zp.setParseError("bad step in $GENERATE range", l)
}
s, err := strconv.ParseInt(token[i+1:], 10, 64)
if err != nil || s <= 0 {
return zp.setParseError("bad step in $GENERATE range", l)
}
step = s
token = token[:i]
}
sx := strings.SplitN(token, "-", 2)
if len(sx) != 2 {
return zp.setParseError("bad start-stop in $GENERATE range", l)
}
start, err := strconv.ParseInt(sx[0], 10, 64)
if err != nil {
return zp.setParseError("bad start in $GENERATE range", l)
}
end, err := strconv.ParseInt(sx[1], 10, 64)
if err != nil {
return zp.setParseError("bad stop in $GENERATE range", l)
}
if end < 0 || start < 0 || end < start || (end-start)/step > 65535 {
return zp.setParseError("bad range in $GENERATE range", l)
}
// _BLANK
l, ok := zp.c.Next()
if !ok || l.value != zBlank {
return zp.setParseError("garbage after $GENERATE range", l)
}
// Create a complete new string, which we then parse again.
var s string
for l, ok := zp.c.Next(); ok; l, ok = zp.c.Next() {
if l.err {
return zp.setParseError("bad data in $GENERATE directive", l)
}
if l.value == zNewline {
break
}
s += l.token
}
r := &generateReader{
s: s,
cur: start,
start: start,
end: end,
step: step,
file: zp.file,
lex: &l,
}
zp.sub = NewZoneParser(r, zp.origin, zp.file)
zp.sub.includeDepth, zp.sub.includeAllowed = zp.includeDepth, zp.includeAllowed
zp.sub.generateDisallowed = true
zp.sub.SetDefaultTTL(defaultTtl)
return zp.subNext()
}
type generateReader struct {
s string
si int
cur int64
start int64
end int64
step int64
mod bytes.Buffer
escape bool
eof bool
file string
lex *lex
}
func (r *generateReader) parseError(msg string, end int) *ParseError {
r.eof = true // Make errors sticky.
l := *r.lex
l.token = r.s[r.si-1 : end]
l.column += r.si // l.column starts one zBLANK before r.s
return &ParseError{r.file, msg, l}
}
func (r *generateReader) Read(p []byte) (int, error) {
// NewZLexer, through NewZoneParser, should use ReadByte and
// not end up here.
panic("not implemented")
}
func (r *generateReader) ReadByte() (byte, error) {
if r.eof {
return 0, io.EOF
}
if r.mod.Len() > 0 {
return r.mod.ReadByte()
}
if r.si >= len(r.s) {
r.si = 0
r.cur += r.step
r.eof = r.cur > r.end || r.cur < 0
return '\n', nil
}
si := r.si
r.si++
switch r.s[si] {
case '\\':
if r.escape {
r.escape = false
return '\\', nil
}
r.escape = true
return r.ReadByte()
case '$':
if r.escape {
r.escape = false
return '$', nil
}
mod := "%d"
if si >= len(r.s)-1 {
// End of the string
fmt.Fprintf(&r.mod, mod, r.cur)
return r.mod.ReadByte()
}
if r.s[si+1] == '$' {
r.si++
return '$', nil
}
var offset int64
// Search for { and }
if r.s[si+1] == '{' {
// Modifier block
sep := strings.Index(r.s[si+2:], "}")
if sep < 0 {
return 0, r.parseError("bad modifier in $GENERATE", len(r.s))
}
var errMsg string
mod, offset, errMsg = modToPrintf(r.s[si+2 : si+2+sep])
if errMsg != "" {
return 0, r.parseError(errMsg, si+3+sep)
}
if r.start+offset < 0 || r.end+offset > 1<<31-1 {
return 0, r.parseError("bad offset in $GENERATE", si+3+sep)
}
r.si += 2 + sep // Jump to it
}
fmt.Fprintf(&r.mod, mod, r.cur+offset)
return r.mod.ReadByte()
default:
if r.escape { // Pretty useless here
r.escape = false
return r.ReadByte()
}
return r.s[si], nil
}
}
// Convert a $GENERATE modifier 0,0,d to something Printf can deal with.
func modToPrintf(s string) (string, int64, string) {
// Modifier is { offset [ ,width [ ,base ] ] } - provide default
// values for optional width and type, if necessary.
var offStr, widthStr, base string
switch xs := strings.Split(s, ","); len(xs) {
case 1:
offStr, widthStr, base = xs[0], "0", "d"
case 2:
offStr, widthStr, base = xs[0], xs[1], "d"
case 3:
offStr, widthStr, base = xs[0], xs[1], xs[2]
default:
return "", 0, "bad modifier in $GENERATE"
}
switch base {
case "o", "d", "x", "X":
default:
return "", 0, "bad base in $GENERATE"
}
offset, err := strconv.ParseInt(offStr, 10, 64)
if err != nil {
return "", 0, "bad offset in $GENERATE"
}
width, err := strconv.ParseInt(widthStr, 10, 64)
if err != nil || width < 0 || width > 255 {
return "", 0, "bad width in $GENERATE"
}
if width == 0 {
return "%" + base, offset, ""
}
return "%0" + widthStr + base, offset, ""
}

31
vendor/github.com/miekg/dns/hash.go generated vendored Normal file
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@ -0,0 +1,31 @@
package dns
import (
"bytes"
"crypto"
"hash"
)
// identityHash will not hash, it only buffers the data written into it and returns it as-is.
type identityHash struct {
b *bytes.Buffer
}
// Implement the hash.Hash interface.
func (i identityHash) Write(b []byte) (int, error) { return i.b.Write(b) }
func (i identityHash) Size() int { return i.b.Len() }
func (i identityHash) BlockSize() int { return 1024 }
func (i identityHash) Reset() { i.b.Reset() }
func (i identityHash) Sum(b []byte) []byte { return append(b, i.b.Bytes()...) }
func hashFromAlgorithm(alg uint8) (hash.Hash, crypto.Hash, error) {
hashnumber, ok := AlgorithmToHash[alg]
if !ok {
return nil, 0, ErrAlg
}
if hashnumber == 0 {
return identityHash{b: &bytes.Buffer{}}, hashnumber, nil
}
return hashnumber.New(), hashnumber, nil
}

212
vendor/github.com/miekg/dns/labels.go generated vendored Normal file
View file

@ -0,0 +1,212 @@
package dns
// Holds a bunch of helper functions for dealing with labels.
// SplitDomainName splits a name string into it's labels.
// www.miek.nl. returns []string{"www", "miek", "nl"}
// .www.miek.nl. returns []string{"", "www", "miek", "nl"},
// The root label (.) returns nil. Note that using
// strings.Split(s) will work in most cases, but does not handle
// escaped dots (\.) for instance.
// s must be a syntactically valid domain name, see IsDomainName.
func SplitDomainName(s string) (labels []string) {
if s == "" {
return nil
}
fqdnEnd := 0 // offset of the final '.' or the length of the name
idx := Split(s)
begin := 0
if IsFqdn(s) {
fqdnEnd = len(s) - 1
} else {
fqdnEnd = len(s)
}
switch len(idx) {
case 0:
return nil
case 1:
// no-op
default:
for _, end := range idx[1:] {
labels = append(labels, s[begin:end-1])
begin = end
}
}
return append(labels, s[begin:fqdnEnd])
}
// CompareDomainName compares the names s1 and s2 and
// returns how many labels they have in common starting from the *right*.
// The comparison stops at the first inequality. The names are downcased
// before the comparison.
//
// www.miek.nl. and miek.nl. have two labels in common: miek and nl
// www.miek.nl. and www.bla.nl. have one label in common: nl
//
// s1 and s2 must be syntactically valid domain names.
func CompareDomainName(s1, s2 string) (n int) {
// the first check: root label
if s1 == "." || s2 == "." {
return 0
}
l1 := Split(s1)
l2 := Split(s2)
j1 := len(l1) - 1 // end
i1 := len(l1) - 2 // start
j2 := len(l2) - 1
i2 := len(l2) - 2
// the second check can be done here: last/only label
// before we fall through into the for-loop below
if equal(s1[l1[j1]:], s2[l2[j2]:]) {
n++
} else {
return
}
for {
if i1 < 0 || i2 < 0 {
break
}
if equal(s1[l1[i1]:l1[j1]], s2[l2[i2]:l2[j2]]) {
n++
} else {
break
}
j1--
i1--
j2--
i2--
}
return
}
// CountLabel counts the number of labels in the string s.
// s must be a syntactically valid domain name.
func CountLabel(s string) (labels int) {
if s == "." {
return
}
off := 0
end := false
for {
off, end = NextLabel(s, off)
labels++
if end {
return
}
}
}
// Split splits a name s into its label indexes.
// www.miek.nl. returns []int{0, 4, 9}, www.miek.nl also returns []int{0, 4, 9}.
// The root name (.) returns nil. Also see SplitDomainName.
// s must be a syntactically valid domain name.
func Split(s string) []int {
if s == "." {
return nil
}
idx := make([]int, 1, 3)
off := 0
end := false
for {
off, end = NextLabel(s, off)
if end {
return idx
}
idx = append(idx, off)
}
}
// NextLabel returns the index of the start of the next label in the
// string s starting at offset.
// The bool end is true when the end of the string has been reached.
// Also see PrevLabel.
func NextLabel(s string, offset int) (i int, end bool) {
if s == "" {
return 0, true
}
for i = offset; i < len(s)-1; i++ {
if s[i] != '.' {
continue
}
j := i - 1
for j >= 0 && s[j] == '\\' {
j--
}
if (j-i)%2 == 0 {
continue
}
return i + 1, false
}
return i + 1, true
}
// PrevLabel returns the index of the label when starting from the right and
// jumping n labels to the left.
// The bool start is true when the start of the string has been overshot.
// Also see NextLabel.
func PrevLabel(s string, n int) (i int, start bool) {
if s == "" {
return 0, true
}
if n == 0 {
return len(s), false
}
l := len(s) - 1
if s[l] == '.' {
l--
}
for ; l >= 0 && n > 0; l-- {
if s[l] != '.' {
continue
}
j := l - 1
for j >= 0 && s[j] == '\\' {
j--
}
if (j-l)%2 == 0 {
continue
}
n--
if n == 0 {
return l + 1, false
}
}
return 0, n > 1
}
// equal compares a and b while ignoring case. It returns true when equal otherwise false.
func equal(a, b string) bool {
// might be lifted into API function.
la := len(a)
lb := len(b)
if la != lb {
return false
}
for i := la - 1; i >= 0; i-- {
ai := a[i]
bi := b[i]
if ai >= 'A' && ai <= 'Z' {
ai |= 'a' - 'A'
}
if bi >= 'A' && bi <= 'Z' {
bi |= 'a' - 'A'
}
if ai != bi {
return false
}
}
return true
}

23
vendor/github.com/miekg/dns/listen_no_reuseport.go generated vendored Normal file
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@ -0,0 +1,23 @@
// +build !go1.11 !aix,!darwin,!dragonfly,!freebsd,!linux,!netbsd,!openbsd
package dns
import "net"
const supportsReusePort = false
func listenTCP(network, addr string, reuseport bool) (net.Listener, error) {
if reuseport {
// TODO(tmthrgd): return an error?
}
return net.Listen(network, addr)
}
func listenUDP(network, addr string, reuseport bool) (net.PacketConn, error) {
if reuseport {
// TODO(tmthrgd): return an error?
}
return net.ListenPacket(network, addr)
}

44
vendor/github.com/miekg/dns/listen_reuseport.go generated vendored Normal file
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@ -0,0 +1,44 @@
// +build go1.11
// +build aix darwin dragonfly freebsd linux netbsd openbsd
package dns
import (
"context"
"net"
"syscall"
"golang.org/x/sys/unix"
)
const supportsReusePort = true
func reuseportControl(network, address string, c syscall.RawConn) error {
var opErr error
err := c.Control(func(fd uintptr) {
opErr = unix.SetsockoptInt(int(fd), unix.SOL_SOCKET, unix.SO_REUSEPORT, 1)
})
if err != nil {
return err
}
return opErr
}
func listenTCP(network, addr string, reuseport bool) (net.Listener, error) {
var lc net.ListenConfig
if reuseport {
lc.Control = reuseportControl
}
return lc.Listen(context.Background(), network, addr)
}
func listenUDP(network, addr string, reuseport bool) (net.PacketConn, error) {
var lc net.ListenConfig
if reuseport {
lc.Control = reuseportControl
}
return lc.ListenPacket(context.Background(), network, addr)
}

1202
vendor/github.com/miekg/dns/msg.go generated vendored Normal file

File diff suppressed because it is too large Load diff

812
vendor/github.com/miekg/dns/msg_helpers.go generated vendored Normal file
View file

@ -0,0 +1,812 @@
package dns
import (
"encoding/base32"
"encoding/base64"
"encoding/binary"
"encoding/hex"
"net"
"sort"
"strings"
)
// helper functions called from the generated zmsg.go
// These function are named after the tag to help pack/unpack, if there is no tag it is the name
// of the type they pack/unpack (string, int, etc). We prefix all with unpackData or packData, so packDataA or
// packDataDomainName.
func unpackDataA(msg []byte, off int) (net.IP, int, error) {
if off+net.IPv4len > len(msg) {
return nil, len(msg), &Error{err: "overflow unpacking a"}
}
a := append(make(net.IP, 0, net.IPv4len), msg[off:off+net.IPv4len]...)
off += net.IPv4len
return a, off, nil
}
func packDataA(a net.IP, msg []byte, off int) (int, error) {
switch len(a) {
case net.IPv4len, net.IPv6len:
// It must be a slice of 4, even if it is 16, we encode only the first 4
if off+net.IPv4len > len(msg) {
return len(msg), &Error{err: "overflow packing a"}
}
copy(msg[off:], a.To4())
off += net.IPv4len
case 0:
// Allowed, for dynamic updates.
default:
return len(msg), &Error{err: "overflow packing a"}
}
return off, nil
}
func unpackDataAAAA(msg []byte, off int) (net.IP, int, error) {
if off+net.IPv6len > len(msg) {
return nil, len(msg), &Error{err: "overflow unpacking aaaa"}
}
aaaa := append(make(net.IP, 0, net.IPv6len), msg[off:off+net.IPv6len]...)
off += net.IPv6len
return aaaa, off, nil
}
func packDataAAAA(aaaa net.IP, msg []byte, off int) (int, error) {
switch len(aaaa) {
case net.IPv6len:
if off+net.IPv6len > len(msg) {
return len(msg), &Error{err: "overflow packing aaaa"}
}
copy(msg[off:], aaaa)
off += net.IPv6len
case 0:
// Allowed, dynamic updates.
default:
return len(msg), &Error{err: "overflow packing aaaa"}
}
return off, nil
}
// unpackHeader unpacks an RR header, returning the offset to the end of the header and a
// re-sliced msg according to the expected length of the RR.
func unpackHeader(msg []byte, off int) (rr RR_Header, off1 int, truncmsg []byte, err error) {
hdr := RR_Header{}
if off == len(msg) {
return hdr, off, msg, nil
}
hdr.Name, off, err = UnpackDomainName(msg, off)
if err != nil {
return hdr, len(msg), msg, err
}
hdr.Rrtype, off, err = unpackUint16(msg, off)
if err != nil {
return hdr, len(msg), msg, err
}
hdr.Class, off, err = unpackUint16(msg, off)
if err != nil {
return hdr, len(msg), msg, err
}
hdr.Ttl, off, err = unpackUint32(msg, off)
if err != nil {
return hdr, len(msg), msg, err
}
hdr.Rdlength, off, err = unpackUint16(msg, off)
if err != nil {
return hdr, len(msg), msg, err
}
msg, err = truncateMsgFromRdlength(msg, off, hdr.Rdlength)
return hdr, off, msg, err
}
// packHeader packs an RR header, returning the offset to the end of the header.
// See PackDomainName for documentation about the compression.
func (hdr RR_Header) packHeader(msg []byte, off int, compression compressionMap, compress bool) (int, error) {
if off == len(msg) {
return off, nil
}
off, err := packDomainName(hdr.Name, msg, off, compression, compress)
if err != nil {
return len(msg), err
}
off, err = packUint16(hdr.Rrtype, msg, off)
if err != nil {
return len(msg), err
}
off, err = packUint16(hdr.Class, msg, off)
if err != nil {
return len(msg), err
}
off, err = packUint32(hdr.Ttl, msg, off)
if err != nil {
return len(msg), err
}
off, err = packUint16(0, msg, off) // The RDLENGTH field will be set later in packRR.
if err != nil {
return len(msg), err
}
return off, nil
}
// helper helper functions.
// truncateMsgFromRdLength truncates msg to match the expected length of the RR.
// Returns an error if msg is smaller than the expected size.
func truncateMsgFromRdlength(msg []byte, off int, rdlength uint16) (truncmsg []byte, err error) {
lenrd := off + int(rdlength)
if lenrd > len(msg) {
return msg, &Error{err: "overflowing header size"}
}
return msg[:lenrd], nil
}
var base32HexNoPadEncoding = base32.HexEncoding.WithPadding(base32.NoPadding)
func fromBase32(s []byte) (buf []byte, err error) {
for i, b := range s {
if b >= 'a' && b <= 'z' {
s[i] = b - 32
}
}
buflen := base32HexNoPadEncoding.DecodedLen(len(s))
buf = make([]byte, buflen)
n, err := base32HexNoPadEncoding.Decode(buf, s)
buf = buf[:n]
return
}
func toBase32(b []byte) string {
return base32HexNoPadEncoding.EncodeToString(b)
}
func fromBase64(s []byte) (buf []byte, err error) {
buflen := base64.StdEncoding.DecodedLen(len(s))
buf = make([]byte, buflen)
n, err := base64.StdEncoding.Decode(buf, s)
buf = buf[:n]
return
}
func toBase64(b []byte) string { return base64.StdEncoding.EncodeToString(b) }
// dynamicUpdate returns true if the Rdlength is zero.
func noRdata(h RR_Header) bool { return h.Rdlength == 0 }
func unpackUint8(msg []byte, off int) (i uint8, off1 int, err error) {
if off+1 > len(msg) {
return 0, len(msg), &Error{err: "overflow unpacking uint8"}
}
return msg[off], off + 1, nil
}
func packUint8(i uint8, msg []byte, off int) (off1 int, err error) {
if off+1 > len(msg) {
return len(msg), &Error{err: "overflow packing uint8"}
}
msg[off] = i
return off + 1, nil
}
func unpackUint16(msg []byte, off int) (i uint16, off1 int, err error) {
if off+2 > len(msg) {
return 0, len(msg), &Error{err: "overflow unpacking uint16"}
}
return binary.BigEndian.Uint16(msg[off:]), off + 2, nil
}
func packUint16(i uint16, msg []byte, off int) (off1 int, err error) {
if off+2 > len(msg) {
return len(msg), &Error{err: "overflow packing uint16"}
}
binary.BigEndian.PutUint16(msg[off:], i)
return off + 2, nil
}
func unpackUint32(msg []byte, off int) (i uint32, off1 int, err error) {
if off+4 > len(msg) {
return 0, len(msg), &Error{err: "overflow unpacking uint32"}
}
return binary.BigEndian.Uint32(msg[off:]), off + 4, nil
}
func packUint32(i uint32, msg []byte, off int) (off1 int, err error) {
if off+4 > len(msg) {
return len(msg), &Error{err: "overflow packing uint32"}
}
binary.BigEndian.PutUint32(msg[off:], i)
return off + 4, nil
}
func unpackUint48(msg []byte, off int) (i uint64, off1 int, err error) {
if off+6 > len(msg) {
return 0, len(msg), &Error{err: "overflow unpacking uint64 as uint48"}
}
// Used in TSIG where the last 48 bits are occupied, so for now, assume a uint48 (6 bytes)
i = uint64(msg[off])<<40 | uint64(msg[off+1])<<32 | uint64(msg[off+2])<<24 | uint64(msg[off+3])<<16 |
uint64(msg[off+4])<<8 | uint64(msg[off+5])
off += 6
return i, off, nil
}
func packUint48(i uint64, msg []byte, off int) (off1 int, err error) {
if off+6 > len(msg) {
return len(msg), &Error{err: "overflow packing uint64 as uint48"}
}
msg[off] = byte(i >> 40)
msg[off+1] = byte(i >> 32)
msg[off+2] = byte(i >> 24)
msg[off+3] = byte(i >> 16)
msg[off+4] = byte(i >> 8)
msg[off+5] = byte(i)
off += 6
return off, nil
}
func unpackUint64(msg []byte, off int) (i uint64, off1 int, err error) {
if off+8 > len(msg) {
return 0, len(msg), &Error{err: "overflow unpacking uint64"}
}
return binary.BigEndian.Uint64(msg[off:]), off + 8, nil
}
func packUint64(i uint64, msg []byte, off int) (off1 int, err error) {
if off+8 > len(msg) {
return len(msg), &Error{err: "overflow packing uint64"}
}
binary.BigEndian.PutUint64(msg[off:], i)
off += 8
return off, nil
}
func unpackString(msg []byte, off int) (string, int, error) {
if off+1 > len(msg) {
return "", off, &Error{err: "overflow unpacking txt"}
}
l := int(msg[off])
off++
if off+l > len(msg) {
return "", off, &Error{err: "overflow unpacking txt"}
}
var s strings.Builder
consumed := 0
for i, b := range msg[off : off+l] {
switch {
case b == '"' || b == '\\':
if consumed == 0 {
s.Grow(l * 2)
}
s.Write(msg[off+consumed : off+i])
s.WriteByte('\\')
s.WriteByte(b)
consumed = i + 1
case b < ' ' || b > '~': // unprintable
if consumed == 0 {
s.Grow(l * 2)
}
s.Write(msg[off+consumed : off+i])
s.WriteString(escapeByte(b))
consumed = i + 1
}
}
if consumed == 0 { // no escaping needed
return string(msg[off : off+l]), off + l, nil
}
s.Write(msg[off+consumed : off+l])
return s.String(), off + l, nil
}
func packString(s string, msg []byte, off int) (int, error) {
txtTmp := make([]byte, 256*4+1)
off, err := packTxtString(s, msg, off, txtTmp)
if err != nil {
return len(msg), err
}
return off, nil
}
func unpackStringBase32(msg []byte, off, end int) (string, int, error) {
if end > len(msg) {
return "", len(msg), &Error{err: "overflow unpacking base32"}
}
s := toBase32(msg[off:end])
return s, end, nil
}
func packStringBase32(s string, msg []byte, off int) (int, error) {
b32, err := fromBase32([]byte(s))
if err != nil {
return len(msg), err
}
if off+len(b32) > len(msg) {
return len(msg), &Error{err: "overflow packing base32"}
}
copy(msg[off:off+len(b32)], b32)
off += len(b32)
return off, nil
}
func unpackStringBase64(msg []byte, off, end int) (string, int, error) {
// Rest of the RR is base64 encoded value, so we don't need an explicit length
// to be set. Thus far all RR's that have base64 encoded fields have those as their
// last one. What we do need is the end of the RR!
if end > len(msg) {
return "", len(msg), &Error{err: "overflow unpacking base64"}
}
s := toBase64(msg[off:end])
return s, end, nil
}
func packStringBase64(s string, msg []byte, off int) (int, error) {
b64, err := fromBase64([]byte(s))
if err != nil {
return len(msg), err
}
if off+len(b64) > len(msg) {
return len(msg), &Error{err: "overflow packing base64"}
}
copy(msg[off:off+len(b64)], b64)
off += len(b64)
return off, nil
}
func unpackStringHex(msg []byte, off, end int) (string, int, error) {
// Rest of the RR is hex encoded value, so we don't need an explicit length
// to be set. NSEC and TSIG have hex fields with a length field.
// What we do need is the end of the RR!
if end > len(msg) {
return "", len(msg), &Error{err: "overflow unpacking hex"}
}
s := hex.EncodeToString(msg[off:end])
return s, end, nil
}
func packStringHex(s string, msg []byte, off int) (int, error) {
h, err := hex.DecodeString(s)
if err != nil {
return len(msg), err
}
if off+len(h) > len(msg) {
return len(msg), &Error{err: "overflow packing hex"}
}
copy(msg[off:off+len(h)], h)
off += len(h)
return off, nil
}
func unpackStringAny(msg []byte, off, end int) (string, int, error) {
if end > len(msg) {
return "", len(msg), &Error{err: "overflow unpacking anything"}
}
return string(msg[off:end]), end, nil
}
func packStringAny(s string, msg []byte, off int) (int, error) {
if off+len(s) > len(msg) {
return len(msg), &Error{err: "overflow packing anything"}
}
copy(msg[off:off+len(s)], s)
off += len(s)
return off, nil
}
func unpackStringTxt(msg []byte, off int) ([]string, int, error) {
txt, off, err := unpackTxt(msg, off)
if err != nil {
return nil, len(msg), err
}
return txt, off, nil
}
func packStringTxt(s []string, msg []byte, off int) (int, error) {
txtTmp := make([]byte, 256*4+1) // If the whole string consists out of \DDD we need this many.
off, err := packTxt(s, msg, off, txtTmp)
if err != nil {
return len(msg), err
}
return off, nil
}
func unpackDataOpt(msg []byte, off int) ([]EDNS0, int, error) {
var edns []EDNS0
Option:
var code uint16
if off+4 > len(msg) {
return nil, len(msg), &Error{err: "overflow unpacking opt"}
}
code = binary.BigEndian.Uint16(msg[off:])
off += 2
optlen := binary.BigEndian.Uint16(msg[off:])
off += 2
if off+int(optlen) > len(msg) {
return nil, len(msg), &Error{err: "overflow unpacking opt"}
}
e := makeDataOpt(code)
if err := e.unpack(msg[off : off+int(optlen)]); err != nil {
return nil, len(msg), err
}
edns = append(edns, e)
off += int(optlen)
if off < len(msg) {
goto Option
}
return edns, off, nil
}
func packDataOpt(options []EDNS0, msg []byte, off int) (int, error) {
for _, el := range options {
b, err := el.pack()
if err != nil || off+4 > len(msg) {
return len(msg), &Error{err: "overflow packing opt"}
}
binary.BigEndian.PutUint16(msg[off:], el.Option()) // Option code
binary.BigEndian.PutUint16(msg[off+2:], uint16(len(b))) // Length
off += 4
if off+len(b) > len(msg) {
return len(msg), &Error{err: "overflow packing opt"}
}
// Actual data
copy(msg[off:off+len(b)], b)
off += len(b)
}
return off, nil
}
func unpackStringOctet(msg []byte, off int) (string, int, error) {
s := string(msg[off:])
return s, len(msg), nil
}
func packStringOctet(s string, msg []byte, off int) (int, error) {
txtTmp := make([]byte, 256*4+1)
off, err := packOctetString(s, msg, off, txtTmp)
if err != nil {
return len(msg), err
}
return off, nil
}
func unpackDataNsec(msg []byte, off int) ([]uint16, int, error) {
var nsec []uint16
length, window, lastwindow := 0, 0, -1
for off < len(msg) {
if off+2 > len(msg) {
return nsec, len(msg), &Error{err: "overflow unpacking nsecx"}
}
window = int(msg[off])
length = int(msg[off+1])
off += 2
if window <= lastwindow {
// RFC 4034: Blocks are present in the NSEC RR RDATA in
// increasing numerical order.
return nsec, len(msg), &Error{err: "out of order NSEC block"}
}
if length == 0 {
// RFC 4034: Blocks with no types present MUST NOT be included.
return nsec, len(msg), &Error{err: "empty NSEC block"}
}
if length > 32 {
return nsec, len(msg), &Error{err: "NSEC block too long"}
}
if off+length > len(msg) {
return nsec, len(msg), &Error{err: "overflowing NSEC block"}
}
// Walk the bytes in the window and extract the type bits
for j, b := range msg[off : off+length] {
// Check the bits one by one, and set the type
if b&0x80 == 0x80 {
nsec = append(nsec, uint16(window*256+j*8+0))
}
if b&0x40 == 0x40 {
nsec = append(nsec, uint16(window*256+j*8+1))
}
if b&0x20 == 0x20 {
nsec = append(nsec, uint16(window*256+j*8+2))
}
if b&0x10 == 0x10 {
nsec = append(nsec, uint16(window*256+j*8+3))
}
if b&0x8 == 0x8 {
nsec = append(nsec, uint16(window*256+j*8+4))
}
if b&0x4 == 0x4 {
nsec = append(nsec, uint16(window*256+j*8+5))
}
if b&0x2 == 0x2 {
nsec = append(nsec, uint16(window*256+j*8+6))
}
if b&0x1 == 0x1 {
nsec = append(nsec, uint16(window*256+j*8+7))
}
}
off += length
lastwindow = window
}
return nsec, off, nil
}
// typeBitMapLen is a helper function which computes the "maximum" length of
// a the NSEC Type BitMap field.
func typeBitMapLen(bitmap []uint16) int {
var l int
var lastwindow, lastlength uint16
for _, t := range bitmap {
window := t / 256
length := (t-window*256)/8 + 1
if window > lastwindow && lastlength != 0 { // New window, jump to the new offset
l += int(lastlength) + 2
lastlength = 0
}
if window < lastwindow || length < lastlength {
// packDataNsec would return Error{err: "nsec bits out of order"} here, but
// when computing the length, we want do be liberal.
continue
}
lastwindow, lastlength = window, length
}
l += int(lastlength) + 2
return l
}
func packDataNsec(bitmap []uint16, msg []byte, off int) (int, error) {
if len(bitmap) == 0 {
return off, nil
}
if off > len(msg) {
return off, &Error{err: "overflow packing nsec"}
}
toZero := msg[off:]
if maxLen := typeBitMapLen(bitmap); maxLen < len(toZero) {
toZero = toZero[:maxLen]
}
for i := range toZero {
toZero[i] = 0
}
var lastwindow, lastlength uint16
for _, t := range bitmap {
window := t / 256
length := (t-window*256)/8 + 1
if window > lastwindow && lastlength != 0 { // New window, jump to the new offset
off += int(lastlength) + 2
lastlength = 0
}
if window < lastwindow || length < lastlength {
return len(msg), &Error{err: "nsec bits out of order"}
}
if off+2+int(length) > len(msg) {
return len(msg), &Error{err: "overflow packing nsec"}
}
// Setting the window #
msg[off] = byte(window)
// Setting the octets length
msg[off+1] = byte(length)
// Setting the bit value for the type in the right octet
msg[off+1+int(length)] |= byte(1 << (7 - t%8))
lastwindow, lastlength = window, length
}
off += int(lastlength) + 2
return off, nil
}
func unpackDataSVCB(msg []byte, off int) ([]SVCBKeyValue, int, error) {
var xs []SVCBKeyValue
var code uint16
var length uint16
var err error
for off < len(msg) {
code, off, err = unpackUint16(msg, off)
if err != nil {
return nil, len(msg), &Error{err: "overflow unpacking SVCB"}
}
length, off, err = unpackUint16(msg, off)
if err != nil || off+int(length) > len(msg) {
return nil, len(msg), &Error{err: "overflow unpacking SVCB"}
}
e := makeSVCBKeyValue(SVCBKey(code))
if e == nil {
return nil, len(msg), &Error{err: "bad SVCB key"}
}
if err := e.unpack(msg[off : off+int(length)]); err != nil {
return nil, len(msg), err
}
if len(xs) > 0 && e.Key() <= xs[len(xs)-1].Key() {
return nil, len(msg), &Error{err: "SVCB keys not in strictly increasing order"}
}
xs = append(xs, e)
off += int(length)
}
return xs, off, nil
}
func packDataSVCB(pairs []SVCBKeyValue, msg []byte, off int) (int, error) {
pairs = append([]SVCBKeyValue(nil), pairs...)
sort.Slice(pairs, func(i, j int) bool {
return pairs[i].Key() < pairs[j].Key()
})
prev := svcb_RESERVED
for _, el := range pairs {
if el.Key() == prev {
return len(msg), &Error{err: "repeated SVCB keys are not allowed"}
}
prev = el.Key()
packed, err := el.pack()
if err != nil {
return len(msg), err
}
off, err = packUint16(uint16(el.Key()), msg, off)
if err != nil {
return len(msg), &Error{err: "overflow packing SVCB"}
}
off, err = packUint16(uint16(len(packed)), msg, off)
if err != nil || off+len(packed) > len(msg) {
return len(msg), &Error{err: "overflow packing SVCB"}
}
copy(msg[off:off+len(packed)], packed)
off += len(packed)
}
return off, nil
}
func unpackDataDomainNames(msg []byte, off, end int) ([]string, int, error) {
var (
servers []string
s string
err error
)
if end > len(msg) {
return nil, len(msg), &Error{err: "overflow unpacking domain names"}
}
for off < end {
s, off, err = UnpackDomainName(msg, off)
if err != nil {
return servers, len(msg), err
}
servers = append(servers, s)
}
return servers, off, nil
}
func packDataDomainNames(names []string, msg []byte, off int, compression compressionMap, compress bool) (int, error) {
var err error
for _, name := range names {
off, err = packDomainName(name, msg, off, compression, compress)
if err != nil {
return len(msg), err
}
}
return off, nil
}
func packDataApl(data []APLPrefix, msg []byte, off int) (int, error) {
var err error
for i := range data {
off, err = packDataAplPrefix(&data[i], msg, off)
if err != nil {
return len(msg), err
}
}
return off, nil
}
func packDataAplPrefix(p *APLPrefix, msg []byte, off int) (int, error) {
if len(p.Network.IP) != len(p.Network.Mask) {
return len(msg), &Error{err: "address and mask lengths don't match"}
}
var err error
prefix, _ := p.Network.Mask.Size()
addr := p.Network.IP.Mask(p.Network.Mask)[:(prefix+7)/8]
switch len(p.Network.IP) {
case net.IPv4len:
off, err = packUint16(1, msg, off)
case net.IPv6len:
off, err = packUint16(2, msg, off)
default:
err = &Error{err: "unrecognized address family"}
}
if err != nil {
return len(msg), err
}
off, err = packUint8(uint8(prefix), msg, off)
if err != nil {
return len(msg), err
}
var n uint8
if p.Negation {
n = 0x80
}
// trim trailing zero bytes as specified in RFC3123 Sections 4.1 and 4.2.
i := len(addr) - 1
for ; i >= 0 && addr[i] == 0; i-- {
}
addr = addr[:i+1]
adflen := uint8(len(addr)) & 0x7f
off, err = packUint8(n|adflen, msg, off)
if err != nil {
return len(msg), err
}
if off+len(addr) > len(msg) {
return len(msg), &Error{err: "overflow packing APL prefix"}
}
off += copy(msg[off:], addr)
return off, nil
}
func unpackDataApl(msg []byte, off int) ([]APLPrefix, int, error) {
var result []APLPrefix
for off < len(msg) {
prefix, end, err := unpackDataAplPrefix(msg, off)
if err != nil {
return nil, len(msg), err
}
off = end
result = append(result, prefix)
}
return result, off, nil
}
func unpackDataAplPrefix(msg []byte, off int) (APLPrefix, int, error) {
family, off, err := unpackUint16(msg, off)
if err != nil {
return APLPrefix{}, len(msg), &Error{err: "overflow unpacking APL prefix"}
}
prefix, off, err := unpackUint8(msg, off)
if err != nil {
return APLPrefix{}, len(msg), &Error{err: "overflow unpacking APL prefix"}
}
nlen, off, err := unpackUint8(msg, off)
if err != nil {
return APLPrefix{}, len(msg), &Error{err: "overflow unpacking APL prefix"}
}
var ip []byte
switch family {
case 1:
ip = make([]byte, net.IPv4len)
case 2:
ip = make([]byte, net.IPv6len)
default:
return APLPrefix{}, len(msg), &Error{err: "unrecognized APL address family"}
}
if int(prefix) > 8*len(ip) {
return APLPrefix{}, len(msg), &Error{err: "APL prefix too long"}
}
afdlen := int(nlen & 0x7f)
if afdlen > len(ip) {
return APLPrefix{}, len(msg), &Error{err: "APL length too long"}
}
if off+afdlen > len(msg) {
return APLPrefix{}, len(msg), &Error{err: "overflow unpacking APL address"}
}
// Address MUST NOT contain trailing zero bytes per RFC3123 Sections 4.1 and 4.2.
off += copy(ip, msg[off:off+afdlen])
if afdlen > 0 {
last := ip[afdlen-1]
if last == 0 {
return APLPrefix{}, len(msg), &Error{err: "extra APL address bits"}
}
}
ipnet := net.IPNet{
IP: ip,
Mask: net.CIDRMask(int(prefix), 8*len(ip)),
}
return APLPrefix{
Negation: (nlen & 0x80) != 0,
Network: ipnet,
}, off, nil
}

117
vendor/github.com/miekg/dns/msg_truncate.go generated vendored Normal file
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package dns
// Truncate ensures the reply message will fit into the requested buffer
// size by removing records that exceed the requested size.
//
// It will first check if the reply fits without compression and then with
// compression. If it won't fit with compression, Truncate then walks the
// record adding as many records as possible without exceeding the
// requested buffer size.
//
// If the message fits within the requested size without compression,
// Truncate will set the message's Compress attribute to false. It is
// the caller's responsibility to set it back to true if they wish to
// compress the payload regardless of size.
//
// The TC bit will be set if any records were excluded from the message.
// If the TC bit is already set on the message it will be retained.
// TC indicates that the client should retry over TCP.
//
// According to RFC 2181, the TC bit should only be set if not all of the
// "required" RRs can be included in the response. Unfortunately, we have
// no way of knowing which RRs are required so we set the TC bit if any RR
// had to be omitted from the response.
//
// The appropriate buffer size can be retrieved from the requests OPT
// record, if present, and is transport specific otherwise. dns.MinMsgSize
// should be used for UDP requests without an OPT record, and
// dns.MaxMsgSize for TCP requests without an OPT record.
func (dns *Msg) Truncate(size int) {
if dns.IsTsig() != nil {
// To simplify this implementation, we don't perform
// truncation on responses with a TSIG record.
return
}
// RFC 6891 mandates that the payload size in an OPT record
// less than 512 (MinMsgSize) bytes must be treated as equal to 512 bytes.
//
// For ease of use, we impose that restriction here.
if size < MinMsgSize {
size = MinMsgSize
}
l := msgLenWithCompressionMap(dns, nil) // uncompressed length
if l <= size {
// Don't waste effort compressing this message.
dns.Compress = false
return
}
dns.Compress = true
edns0 := dns.popEdns0()
if edns0 != nil {
// Account for the OPT record that gets added at the end,
// by subtracting that length from our budget.
//
// The EDNS(0) OPT record must have the root domain and
// it's length is thus unaffected by compression.
size -= Len(edns0)
}
compression := make(map[string]struct{})
l = headerSize
for _, r := range dns.Question {
l += r.len(l, compression)
}
var numAnswer int
if l < size {
l, numAnswer = truncateLoop(dns.Answer, size, l, compression)
}
var numNS int
if l < size {
l, numNS = truncateLoop(dns.Ns, size, l, compression)
}
var numExtra int
if l < size {
_, numExtra = truncateLoop(dns.Extra, size, l, compression)
}
// See the function documentation for when we set this.
dns.Truncated = dns.Truncated || len(dns.Answer) > numAnswer ||
len(dns.Ns) > numNS || len(dns.Extra) > numExtra
dns.Answer = dns.Answer[:numAnswer]
dns.Ns = dns.Ns[:numNS]
dns.Extra = dns.Extra[:numExtra]
if edns0 != nil {
// Add the OPT record back onto the additional section.
dns.Extra = append(dns.Extra, edns0)
}
}
func truncateLoop(rrs []RR, size, l int, compression map[string]struct{}) (int, int) {
for i, r := range rrs {
if r == nil {
continue
}
l += r.len(l, compression)
if l > size {
// Return size, rather than l prior to this record,
// to prevent any further records being added.
return size, i
}
if l == size {
return l, i + 1
}
}
return l, len(rrs)
}

95
vendor/github.com/miekg/dns/nsecx.go generated vendored Normal file
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@ -0,0 +1,95 @@
package dns
import (
"crypto/sha1"
"encoding/hex"
"strings"
)
// HashName hashes a string (label) according to RFC 5155. It returns the hashed string in uppercase.
func HashName(label string, ha uint8, iter uint16, salt string) string {
if ha != SHA1 {
return ""
}
wireSalt := make([]byte, hex.DecodedLen(len(salt)))
n, err := packStringHex(salt, wireSalt, 0)
if err != nil {
return ""
}
wireSalt = wireSalt[:n]
name := make([]byte, 255)
off, err := PackDomainName(strings.ToLower(label), name, 0, nil, false)
if err != nil {
return ""
}
name = name[:off]
s := sha1.New()
// k = 0
s.Write(name)
s.Write(wireSalt)
nsec3 := s.Sum(nil)
// k > 0
for k := uint16(0); k < iter; k++ {
s.Reset()
s.Write(nsec3)
s.Write(wireSalt)
nsec3 = s.Sum(nsec3[:0])
}
return toBase32(nsec3)
}
// Cover returns true if a name is covered by the NSEC3 record.
func (rr *NSEC3) Cover(name string) bool {
nameHash := HashName(name, rr.Hash, rr.Iterations, rr.Salt)
owner := strings.ToUpper(rr.Hdr.Name)
labelIndices := Split(owner)
if len(labelIndices) < 2 {
return false
}
ownerHash := owner[:labelIndices[1]-1]
ownerZone := owner[labelIndices[1]:]
if !IsSubDomain(ownerZone, strings.ToUpper(name)) { // name is outside owner zone
return false
}
nextHash := rr.NextDomain
// if empty interval found, try cover wildcard hashes so nameHash shouldn't match with ownerHash
if ownerHash == nextHash && nameHash != ownerHash { // empty interval
return true
}
if ownerHash > nextHash { // end of zone
if nameHash > ownerHash { // covered since there is nothing after ownerHash
return true
}
return nameHash < nextHash // if nameHash is before beginning of zone it is covered
}
if nameHash < ownerHash { // nameHash is before ownerHash, not covered
return false
}
return nameHash < nextHash // if nameHash is before nextHash is it covered (between ownerHash and nextHash)
}
// Match returns true if a name matches the NSEC3 record
func (rr *NSEC3) Match(name string) bool {
nameHash := HashName(name, rr.Hash, rr.Iterations, rr.Salt)
owner := strings.ToUpper(rr.Hdr.Name)
labelIndices := Split(owner)
if len(labelIndices) < 2 {
return false
}
ownerHash := owner[:labelIndices[1]-1]
ownerZone := owner[labelIndices[1]:]
if !IsSubDomain(ownerZone, strings.ToUpper(name)) { // name is outside owner zone
return false
}
if ownerHash == nameHash {
return true
}
return false
}

113
vendor/github.com/miekg/dns/privaterr.go generated vendored Normal file
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@ -0,0 +1,113 @@
package dns
import "strings"
// PrivateRdata is an interface used for implementing "Private Use" RR types, see
// RFC 6895. This allows one to experiment with new RR types, without requesting an
// official type code. Also see dns.PrivateHandle and dns.PrivateHandleRemove.
type PrivateRdata interface {
// String returns the text presentation of the Rdata of the Private RR.
String() string
// Parse parses the Rdata of the private RR.
Parse([]string) error
// Pack is used when packing a private RR into a buffer.
Pack([]byte) (int, error)
// Unpack is used when unpacking a private RR from a buffer.
Unpack([]byte) (int, error)
// Copy copies the Rdata into the PrivateRdata argument.
Copy(PrivateRdata) error
// Len returns the length in octets of the Rdata.
Len() int
}
// PrivateRR represents an RR that uses a PrivateRdata user-defined type.
// It mocks normal RRs and implements dns.RR interface.
type PrivateRR struct {
Hdr RR_Header
Data PrivateRdata
generator func() PrivateRdata // for copy
}
// Header return the RR header of r.
func (r *PrivateRR) Header() *RR_Header { return &r.Hdr }
func (r *PrivateRR) String() string { return r.Hdr.String() + r.Data.String() }
// Private len and copy parts to satisfy RR interface.
func (r *PrivateRR) len(off int, compression map[string]struct{}) int {
l := r.Hdr.len(off, compression)
l += r.Data.Len()
return l
}
func (r *PrivateRR) copy() RR {
// make new RR like this:
rr := &PrivateRR{r.Hdr, r.generator(), r.generator}
if err := r.Data.Copy(rr.Data); err != nil {
panic("dns: got value that could not be used to copy Private rdata: " + err.Error())
}
return rr
}
func (r *PrivateRR) pack(msg []byte, off int, compression compressionMap, compress bool) (int, error) {
n, err := r.Data.Pack(msg[off:])
if err != nil {
return len(msg), err
}
off += n
return off, nil
}
func (r *PrivateRR) unpack(msg []byte, off int) (int, error) {
off1, err := r.Data.Unpack(msg[off:])
off += off1
return off, err
}
func (r *PrivateRR) parse(c *zlexer, origin string) *ParseError {
var l lex
text := make([]string, 0, 2) // could be 0..N elements, median is probably 1
Fetch:
for {
// TODO(miek): we could also be returning _QUOTE, this might or might not
// be an issue (basically parsing TXT becomes hard)
switch l, _ = c.Next(); l.value {
case zNewline, zEOF:
break Fetch
case zString:
text = append(text, l.token)
}
}
err := r.Data.Parse(text)
if err != nil {
return &ParseError{"", err.Error(), l}
}
return nil
}
func (r *PrivateRR) isDuplicate(r2 RR) bool { return false }
// PrivateHandle registers a private resource record type. It requires
// string and numeric representation of private RR type and generator function as argument.
func PrivateHandle(rtypestr string, rtype uint16, generator func() PrivateRdata) {
rtypestr = strings.ToUpper(rtypestr)
TypeToRR[rtype] = func() RR { return &PrivateRR{RR_Header{}, generator(), generator} }
TypeToString[rtype] = rtypestr
StringToType[rtypestr] = rtype
}
// PrivateHandleRemove removes definitions required to support private RR type.
func PrivateHandleRemove(rtype uint16) {
rtypestr, ok := TypeToString[rtype]
if ok {
delete(TypeToRR, rtype)
delete(TypeToString, rtype)
delete(StringToType, rtypestr)
}
}

52
vendor/github.com/miekg/dns/reverse.go generated vendored Normal file
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package dns
// StringToType is the reverse of TypeToString, needed for string parsing.
var StringToType = reverseInt16(TypeToString)
// StringToClass is the reverse of ClassToString, needed for string parsing.
var StringToClass = reverseInt16(ClassToString)
// StringToOpcode is a map of opcodes to strings.
var StringToOpcode = reverseInt(OpcodeToString)
// StringToRcode is a map of rcodes to strings.
var StringToRcode = reverseInt(RcodeToString)
func init() {
// Preserve previous NOTIMP typo, see github.com/miekg/dns/issues/733.
StringToRcode["NOTIMPL"] = RcodeNotImplemented
}
// StringToAlgorithm is the reverse of AlgorithmToString.
var StringToAlgorithm = reverseInt8(AlgorithmToString)
// StringToHash is a map of names to hash IDs.
var StringToHash = reverseInt8(HashToString)
// StringToCertType is the reverseof CertTypeToString.
var StringToCertType = reverseInt16(CertTypeToString)
// Reverse a map
func reverseInt8(m map[uint8]string) map[string]uint8 {
n := make(map[string]uint8, len(m))
for u, s := range m {
n[s] = u
}
return n
}
func reverseInt16(m map[uint16]string) map[string]uint16 {
n := make(map[string]uint16, len(m))
for u, s := range m {
n[s] = u
}
return n
}
func reverseInt(m map[int]string) map[string]int {
n := make(map[string]int, len(m))
for u, s := range m {
n[s] = u
}
return n
}

86
vendor/github.com/miekg/dns/sanitize.go generated vendored Normal file
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package dns
// Dedup removes identical RRs from rrs. It preserves the original ordering.
// The lowest TTL of any duplicates is used in the remaining one. Dedup modifies
// rrs.
// m is used to store the RRs temporary. If it is nil a new map will be allocated.
func Dedup(rrs []RR, m map[string]RR) []RR {
if m == nil {
m = make(map[string]RR)
}
// Save the keys, so we don't have to call normalizedString twice.
keys := make([]*string, 0, len(rrs))
for _, r := range rrs {
key := normalizedString(r)
keys = append(keys, &key)
if mr, ok := m[key]; ok {
// Shortest TTL wins.
rh, mrh := r.Header(), mr.Header()
if mrh.Ttl > rh.Ttl {
mrh.Ttl = rh.Ttl
}
continue
}
m[key] = r
}
// If the length of the result map equals the amount of RRs we got,
// it means they were all different. We can then just return the original rrset.
if len(m) == len(rrs) {
return rrs
}
j := 0
for i, r := range rrs {
// If keys[i] lives in the map, we should copy and remove it.
if _, ok := m[*keys[i]]; ok {
delete(m, *keys[i])
rrs[j] = r
j++
}
if len(m) == 0 {
break
}
}
return rrs[:j]
}
// normalizedString returns a normalized string from r. The TTL
// is removed and the domain name is lowercased. We go from this:
// DomainName<TAB>TTL<TAB>CLASS<TAB>TYPE<TAB>RDATA to:
// lowercasename<TAB>CLASS<TAB>TYPE...
func normalizedString(r RR) string {
// A string Go DNS makes has: domainname<TAB>TTL<TAB>...
b := []byte(r.String())
// find the first non-escaped tab, then another, so we capture where the TTL lives.
esc := false
ttlStart, ttlEnd := 0, 0
for i := 0; i < len(b) && ttlEnd == 0; i++ {
switch {
case b[i] == '\\':
esc = !esc
case b[i] == '\t' && !esc:
if ttlStart == 0 {
ttlStart = i
continue
}
if ttlEnd == 0 {
ttlEnd = i
}
case b[i] >= 'A' && b[i] <= 'Z' && !esc:
b[i] += 32
default:
esc = false
}
}
// remove TTL.
copy(b[ttlStart:], b[ttlEnd:])
cut := ttlEnd - ttlStart
return string(b[:len(b)-cut])
}

1368
vendor/github.com/miekg/dns/scan.go generated vendored Normal file

File diff suppressed because it is too large Load diff

1778
vendor/github.com/miekg/dns/scan_rr.go generated vendored Normal file

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122
vendor/github.com/miekg/dns/serve_mux.go generated vendored Normal file
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package dns
import (
"sync"
)
// ServeMux is an DNS request multiplexer. It matches the zone name of
// each incoming request against a list of registered patterns add calls
// the handler for the pattern that most closely matches the zone name.
//
// ServeMux is DNSSEC aware, meaning that queries for the DS record are
// redirected to the parent zone (if that is also registered), otherwise
// the child gets the query.
//
// ServeMux is also safe for concurrent access from multiple goroutines.
//
// The zero ServeMux is empty and ready for use.
type ServeMux struct {
z map[string]Handler
m sync.RWMutex
}
// NewServeMux allocates and returns a new ServeMux.
func NewServeMux() *ServeMux {
return new(ServeMux)
}
// DefaultServeMux is the default ServeMux used by Serve.
var DefaultServeMux = NewServeMux()
func (mux *ServeMux) match(q string, t uint16) Handler {
mux.m.RLock()
defer mux.m.RUnlock()
if mux.z == nil {
return nil
}
q = CanonicalName(q)
var handler Handler
for off, end := 0, false; !end; off, end = NextLabel(q, off) {
if h, ok := mux.z[q[off:]]; ok {
if t != TypeDS {
return h
}
// Continue for DS to see if we have a parent too, if so delegate to the parent
handler = h
}
}
// Wildcard match, if we have found nothing try the root zone as a last resort.
if h, ok := mux.z["."]; ok {
return h
}
return handler
}
// Handle adds a handler to the ServeMux for pattern.
func (mux *ServeMux) Handle(pattern string, handler Handler) {
if pattern == "" {
panic("dns: invalid pattern " + pattern)
}
mux.m.Lock()
if mux.z == nil {
mux.z = make(map[string]Handler)
}
mux.z[CanonicalName(pattern)] = handler
mux.m.Unlock()
}
// HandleFunc adds a handler function to the ServeMux for pattern.
func (mux *ServeMux) HandleFunc(pattern string, handler func(ResponseWriter, *Msg)) {
mux.Handle(pattern, HandlerFunc(handler))
}
// HandleRemove deregisters the handler specific for pattern from the ServeMux.
func (mux *ServeMux) HandleRemove(pattern string) {
if pattern == "" {
panic("dns: invalid pattern " + pattern)
}
mux.m.Lock()
delete(mux.z, CanonicalName(pattern))
mux.m.Unlock()
}
// ServeDNS dispatches the request to the handler whose pattern most
// closely matches the request message.
//
// ServeDNS is DNSSEC aware, meaning that queries for the DS record
// are redirected to the parent zone (if that is also registered),
// otherwise the child gets the query.
//
// If no handler is found, or there is no question, a standard REFUSED
// message is returned
func (mux *ServeMux) ServeDNS(w ResponseWriter, req *Msg) {
var h Handler
if len(req.Question) >= 1 { // allow more than one question
h = mux.match(req.Question[0].Name, req.Question[0].Qtype)
}
if h != nil {
h.ServeDNS(w, req)
} else {
handleRefused(w, req)
}
}
// Handle registers the handler with the given pattern
// in the DefaultServeMux. The documentation for
// ServeMux explains how patterns are matched.
func Handle(pattern string, handler Handler) { DefaultServeMux.Handle(pattern, handler) }
// HandleRemove deregisters the handle with the given pattern
// in the DefaultServeMux.
func HandleRemove(pattern string) { DefaultServeMux.HandleRemove(pattern) }
// HandleFunc registers the handler function with the given pattern
// in the DefaultServeMux.
func HandleFunc(pattern string, handler func(ResponseWriter, *Msg)) {
DefaultServeMux.HandleFunc(pattern, handler)
}

836
vendor/github.com/miekg/dns/server.go generated vendored Normal file
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// DNS server implementation.
package dns
import (
"context"
"crypto/tls"
"encoding/binary"
"errors"
"io"
"net"
"strings"
"sync"
"time"
)
// Default maximum number of TCP queries before we close the socket.
const maxTCPQueries = 128
// aLongTimeAgo is a non-zero time, far in the past, used for
// immediate cancelation of network operations.
var aLongTimeAgo = time.Unix(1, 0)
// Handler is implemented by any value that implements ServeDNS.
type Handler interface {
ServeDNS(w ResponseWriter, r *Msg)
}
// The HandlerFunc type is an adapter to allow the use of
// ordinary functions as DNS handlers. If f is a function
// with the appropriate signature, HandlerFunc(f) is a
// Handler object that calls f.
type HandlerFunc func(ResponseWriter, *Msg)
// ServeDNS calls f(w, r).
func (f HandlerFunc) ServeDNS(w ResponseWriter, r *Msg) {
f(w, r)
}
// A ResponseWriter interface is used by an DNS handler to
// construct an DNS response.
type ResponseWriter interface {
// LocalAddr returns the net.Addr of the server
LocalAddr() net.Addr
// RemoteAddr returns the net.Addr of the client that sent the current request.
RemoteAddr() net.Addr
// WriteMsg writes a reply back to the client.
WriteMsg(*Msg) error
// Write writes a raw buffer back to the client.
Write([]byte) (int, error)
// Close closes the connection.
Close() error
// TsigStatus returns the status of the Tsig.
TsigStatus() error
// TsigTimersOnly sets the tsig timers only boolean.
TsigTimersOnly(bool)
// Hijack lets the caller take over the connection.
// After a call to Hijack(), the DNS package will not do anything with the connection.
Hijack()
}
// A ConnectionStater interface is used by a DNS Handler to access TLS connection state
// when available.
type ConnectionStater interface {
ConnectionState() *tls.ConnectionState
}
type response struct {
closed bool // connection has been closed
hijacked bool // connection has been hijacked by handler
tsigTimersOnly bool
tsigStatus error
tsigRequestMAC string
tsigProvider TsigProvider
udp net.PacketConn // i/o connection if UDP was used
tcp net.Conn // i/o connection if TCP was used
udpSession *SessionUDP // oob data to get egress interface right
pcSession net.Addr // address to use when writing to a generic net.PacketConn
writer Writer // writer to output the raw DNS bits
}
// handleRefused returns a HandlerFunc that returns REFUSED for every request it gets.
func handleRefused(w ResponseWriter, r *Msg) {
m := new(Msg)
m.SetRcode(r, RcodeRefused)
w.WriteMsg(m)
}
// HandleFailed returns a HandlerFunc that returns SERVFAIL for every request it gets.
// Deprecated: This function is going away.
func HandleFailed(w ResponseWriter, r *Msg) {
m := new(Msg)
m.SetRcode(r, RcodeServerFailure)
// does not matter if this write fails
w.WriteMsg(m)
}
// ListenAndServe Starts a server on address and network specified Invoke handler
// for incoming queries.
func ListenAndServe(addr string, network string, handler Handler) error {
server := &Server{Addr: addr, Net: network, Handler: handler}
return server.ListenAndServe()
}
// ListenAndServeTLS acts like http.ListenAndServeTLS, more information in
// http://golang.org/pkg/net/http/#ListenAndServeTLS
func ListenAndServeTLS(addr, certFile, keyFile string, handler Handler) error {
cert, err := tls.LoadX509KeyPair(certFile, keyFile)
if err != nil {
return err
}
config := tls.Config{
Certificates: []tls.Certificate{cert},
}
server := &Server{
Addr: addr,
Net: "tcp-tls",
TLSConfig: &config,
Handler: handler,
}
return server.ListenAndServe()
}
// ActivateAndServe activates a server with a listener from systemd,
// l and p should not both be non-nil.
// If both l and p are not nil only p will be used.
// Invoke handler for incoming queries.
func ActivateAndServe(l net.Listener, p net.PacketConn, handler Handler) error {
server := &Server{Listener: l, PacketConn: p, Handler: handler}
return server.ActivateAndServe()
}
// Writer writes raw DNS messages; each call to Write should send an entire message.
type Writer interface {
io.Writer
}
// Reader reads raw DNS messages; each call to ReadTCP or ReadUDP should return an entire message.
type Reader interface {
// ReadTCP reads a raw message from a TCP connection. Implementations may alter
// connection properties, for example the read-deadline.
ReadTCP(conn net.Conn, timeout time.Duration) ([]byte, error)
// ReadUDP reads a raw message from a UDP connection. Implementations may alter
// connection properties, for example the read-deadline.
ReadUDP(conn *net.UDPConn, timeout time.Duration) ([]byte, *SessionUDP, error)
}
// PacketConnReader is an optional interface that Readers can implement to support using generic net.PacketConns.
type PacketConnReader interface {
Reader
// ReadPacketConn reads a raw message from a generic net.PacketConn UDP connection. Implementations may
// alter connection properties, for example the read-deadline.
ReadPacketConn(conn net.PacketConn, timeout time.Duration) ([]byte, net.Addr, error)
}
// defaultReader is an adapter for the Server struct that implements the Reader and
// PacketConnReader interfaces using the readTCP, readUDP and readPacketConn funcs
// of the embedded Server.
type defaultReader struct {
*Server
}
var _ PacketConnReader = defaultReader{}
func (dr defaultReader) ReadTCP(conn net.Conn, timeout time.Duration) ([]byte, error) {
return dr.readTCP(conn, timeout)
}
func (dr defaultReader) ReadUDP(conn *net.UDPConn, timeout time.Duration) ([]byte, *SessionUDP, error) {
return dr.readUDP(conn, timeout)
}
func (dr defaultReader) ReadPacketConn(conn net.PacketConn, timeout time.Duration) ([]byte, net.Addr, error) {
return dr.readPacketConn(conn, timeout)
}
// DecorateReader is a decorator hook for extending or supplanting the functionality of a Reader.
// Implementations should never return a nil Reader.
// Readers should also implement the optional PacketConnReader interface.
// PacketConnReader is required to use a generic net.PacketConn.
type DecorateReader func(Reader) Reader
// DecorateWriter is a decorator hook for extending or supplanting the functionality of a Writer.
// Implementations should never return a nil Writer.
type DecorateWriter func(Writer) Writer
// A Server defines parameters for running an DNS server.
type Server struct {
// Address to listen on, ":dns" if empty.
Addr string
// if "tcp" or "tcp-tls" (DNS over TLS) it will invoke a TCP listener, otherwise an UDP one
Net string
// TCP Listener to use, this is to aid in systemd's socket activation.
Listener net.Listener
// TLS connection configuration
TLSConfig *tls.Config
// UDP "Listener" to use, this is to aid in systemd's socket activation.
PacketConn net.PacketConn
// Handler to invoke, dns.DefaultServeMux if nil.
Handler Handler
// Default buffer size to use to read incoming UDP messages. If not set
// it defaults to MinMsgSize (512 B).
UDPSize int
// The net.Conn.SetReadTimeout value for new connections, defaults to 2 * time.Second.
ReadTimeout time.Duration
// The net.Conn.SetWriteTimeout value for new connections, defaults to 2 * time.Second.
WriteTimeout time.Duration
// TCP idle timeout for multiple queries, if nil, defaults to 8 * time.Second (RFC 5966).
IdleTimeout func() time.Duration
// An implementation of the TsigProvider interface. If defined it replaces TsigSecret and is used for all TSIG operations.
TsigProvider TsigProvider
// Secret(s) for Tsig map[<zonename>]<base64 secret>. The zonename must be in canonical form (lowercase, fqdn, see RFC 4034 Section 6.2).
TsigSecret map[string]string
// If NotifyStartedFunc is set it is called once the server has started listening.
NotifyStartedFunc func()
// DecorateReader is optional, allows customization of the process that reads raw DNS messages.
DecorateReader DecorateReader
// DecorateWriter is optional, allows customization of the process that writes raw DNS messages.
DecorateWriter DecorateWriter
// Maximum number of TCP queries before we close the socket. Default is maxTCPQueries (unlimited if -1).
MaxTCPQueries int
// Whether to set the SO_REUSEPORT socket option, allowing multiple listeners to be bound to a single address.
// It is only supported on go1.11+ and when using ListenAndServe.
ReusePort bool
// AcceptMsgFunc will check the incoming message and will reject it early in the process.
// By default DefaultMsgAcceptFunc will be used.
MsgAcceptFunc MsgAcceptFunc
// Shutdown handling
lock sync.RWMutex
started bool
shutdown chan struct{}
conns map[net.Conn]struct{}
// A pool for UDP message buffers.
udpPool sync.Pool
}
func (srv *Server) tsigProvider() TsigProvider {
if srv.TsigProvider != nil {
return srv.TsigProvider
}
if srv.TsigSecret != nil {
return tsigSecretProvider(srv.TsigSecret)
}
return nil
}
func (srv *Server) isStarted() bool {
srv.lock.RLock()
started := srv.started
srv.lock.RUnlock()
return started
}
func makeUDPBuffer(size int) func() interface{} {
return func() interface{} {
return make([]byte, size)
}
}
func (srv *Server) init() {
srv.shutdown = make(chan struct{})
srv.conns = make(map[net.Conn]struct{})
if srv.UDPSize == 0 {
srv.UDPSize = MinMsgSize
}
if srv.MsgAcceptFunc == nil {
srv.MsgAcceptFunc = DefaultMsgAcceptFunc
}
if srv.Handler == nil {
srv.Handler = DefaultServeMux
}
srv.udpPool.New = makeUDPBuffer(srv.UDPSize)
}
func unlockOnce(l sync.Locker) func() {
var once sync.Once
return func() { once.Do(l.Unlock) }
}
// ListenAndServe starts a nameserver on the configured address in *Server.
func (srv *Server) ListenAndServe() error {
unlock := unlockOnce(&srv.lock)
srv.lock.Lock()
defer unlock()
if srv.started {
return &Error{err: "server already started"}
}
addr := srv.Addr
if addr == "" {
addr = ":domain"
}
srv.init()
switch srv.Net {
case "tcp", "tcp4", "tcp6":
l, err := listenTCP(srv.Net, addr, srv.ReusePort)
if err != nil {
return err
}
srv.Listener = l
srv.started = true
unlock()
return srv.serveTCP(l)
case "tcp-tls", "tcp4-tls", "tcp6-tls":
if srv.TLSConfig == nil || (len(srv.TLSConfig.Certificates) == 0 && srv.TLSConfig.GetCertificate == nil) {
return errors.New("dns: neither Certificates nor GetCertificate set in Config")
}
network := strings.TrimSuffix(srv.Net, "-tls")
l, err := listenTCP(network, addr, srv.ReusePort)
if err != nil {
return err
}
l = tls.NewListener(l, srv.TLSConfig)
srv.Listener = l
srv.started = true
unlock()
return srv.serveTCP(l)
case "udp", "udp4", "udp6":
l, err := listenUDP(srv.Net, addr, srv.ReusePort)
if err != nil {
return err
}
u := l.(*net.UDPConn)
if e := setUDPSocketOptions(u); e != nil {
u.Close()
return e
}
srv.PacketConn = l
srv.started = true
unlock()
return srv.serveUDP(u)
}
return &Error{err: "bad network"}
}
// ActivateAndServe starts a nameserver with the PacketConn or Listener
// configured in *Server. Its main use is to start a server from systemd.
func (srv *Server) ActivateAndServe() error {
unlock := unlockOnce(&srv.lock)
srv.lock.Lock()
defer unlock()
if srv.started {
return &Error{err: "server already started"}
}
srv.init()
if srv.PacketConn != nil {
// Check PacketConn interface's type is valid and value
// is not nil
if t, ok := srv.PacketConn.(*net.UDPConn); ok && t != nil {
if e := setUDPSocketOptions(t); e != nil {
return e
}
}
srv.started = true
unlock()
return srv.serveUDP(srv.PacketConn)
}
if srv.Listener != nil {
srv.started = true
unlock()
return srv.serveTCP(srv.Listener)
}
return &Error{err: "bad listeners"}
}
// Shutdown shuts down a server. After a call to Shutdown, ListenAndServe and
// ActivateAndServe will return.
func (srv *Server) Shutdown() error {
return srv.ShutdownContext(context.Background())
}
// ShutdownContext shuts down a server. After a call to ShutdownContext,
// ListenAndServe and ActivateAndServe will return.
//
// A context.Context may be passed to limit how long to wait for connections
// to terminate.
func (srv *Server) ShutdownContext(ctx context.Context) error {
srv.lock.Lock()
if !srv.started {
srv.lock.Unlock()
return &Error{err: "server not started"}
}
srv.started = false
if srv.PacketConn != nil {
srv.PacketConn.SetReadDeadline(aLongTimeAgo) // Unblock reads
}
if srv.Listener != nil {
srv.Listener.Close()
}
for rw := range srv.conns {
rw.SetReadDeadline(aLongTimeAgo) // Unblock reads
}
srv.lock.Unlock()
if testShutdownNotify != nil {
testShutdownNotify.Broadcast()
}
var ctxErr error
select {
case <-srv.shutdown:
case <-ctx.Done():
ctxErr = ctx.Err()
}
if srv.PacketConn != nil {
srv.PacketConn.Close()
}
return ctxErr
}
var testShutdownNotify *sync.Cond
// getReadTimeout is a helper func to use system timeout if server did not intend to change it.
func (srv *Server) getReadTimeout() time.Duration {
if srv.ReadTimeout != 0 {
return srv.ReadTimeout
}
return dnsTimeout
}
// serveTCP starts a TCP listener for the server.
func (srv *Server) serveTCP(l net.Listener) error {
defer l.Close()
if srv.NotifyStartedFunc != nil {
srv.NotifyStartedFunc()
}
var wg sync.WaitGroup
defer func() {
wg.Wait()
close(srv.shutdown)
}()
for srv.isStarted() {
rw, err := l.Accept()
if err != nil {
if !srv.isStarted() {
return nil
}
if neterr, ok := err.(net.Error); ok && neterr.Temporary() {
continue
}
return err
}
srv.lock.Lock()
// Track the connection to allow unblocking reads on shutdown.
srv.conns[rw] = struct{}{}
srv.lock.Unlock()
wg.Add(1)
go srv.serveTCPConn(&wg, rw)
}
return nil
}
// serveUDP starts a UDP listener for the server.
func (srv *Server) serveUDP(l net.PacketConn) error {
defer l.Close()
reader := Reader(defaultReader{srv})
if srv.DecorateReader != nil {
reader = srv.DecorateReader(reader)
}
lUDP, isUDP := l.(*net.UDPConn)
readerPC, canPacketConn := reader.(PacketConnReader)
if !isUDP && !canPacketConn {
return &Error{err: "PacketConnReader was not implemented on Reader returned from DecorateReader but is required for net.PacketConn"}
}
if srv.NotifyStartedFunc != nil {
srv.NotifyStartedFunc()
}
var wg sync.WaitGroup
defer func() {
wg.Wait()
close(srv.shutdown)
}()
rtimeout := srv.getReadTimeout()
// deadline is not used here
for srv.isStarted() {
var (
m []byte
sPC net.Addr
sUDP *SessionUDP
err error
)
if isUDP {
m, sUDP, err = reader.ReadUDP(lUDP, rtimeout)
} else {
m, sPC, err = readerPC.ReadPacketConn(l, rtimeout)
}
if err != nil {
if !srv.isStarted() {
return nil
}
if netErr, ok := err.(net.Error); ok && netErr.Temporary() {
continue
}
return err
}
if len(m) < headerSize {
if cap(m) == srv.UDPSize {
srv.udpPool.Put(m[:srv.UDPSize])
}
continue
}
wg.Add(1)
go srv.serveUDPPacket(&wg, m, l, sUDP, sPC)
}
return nil
}
// Serve a new TCP connection.
func (srv *Server) serveTCPConn(wg *sync.WaitGroup, rw net.Conn) {
w := &response{tsigProvider: srv.tsigProvider(), tcp: rw}
if srv.DecorateWriter != nil {
w.writer = srv.DecorateWriter(w)
} else {
w.writer = w
}
reader := Reader(defaultReader{srv})
if srv.DecorateReader != nil {
reader = srv.DecorateReader(reader)
}
idleTimeout := tcpIdleTimeout
if srv.IdleTimeout != nil {
idleTimeout = srv.IdleTimeout()
}
timeout := srv.getReadTimeout()
limit := srv.MaxTCPQueries
if limit == 0 {
limit = maxTCPQueries
}
for q := 0; (q < limit || limit == -1) && srv.isStarted(); q++ {
m, err := reader.ReadTCP(w.tcp, timeout)
if err != nil {
// TODO(tmthrgd): handle error
break
}
srv.serveDNS(m, w)
if w.closed {
break // Close() was called
}
if w.hijacked {
break // client will call Close() themselves
}
// The first read uses the read timeout, the rest use the
// idle timeout.
timeout = idleTimeout
}
if !w.hijacked {
w.Close()
}
srv.lock.Lock()
delete(srv.conns, w.tcp)
srv.lock.Unlock()
wg.Done()
}
// Serve a new UDP request.
func (srv *Server) serveUDPPacket(wg *sync.WaitGroup, m []byte, u net.PacketConn, udpSession *SessionUDP, pcSession net.Addr) {
w := &response{tsigProvider: srv.tsigProvider(), udp: u, udpSession: udpSession, pcSession: pcSession}
if srv.DecorateWriter != nil {
w.writer = srv.DecorateWriter(w)
} else {
w.writer = w
}
srv.serveDNS(m, w)
wg.Done()
}
func (srv *Server) serveDNS(m []byte, w *response) {
dh, off, err := unpackMsgHdr(m, 0)
if err != nil {
// Let client hang, they are sending crap; any reply can be used to amplify.
return
}
req := new(Msg)
req.setHdr(dh)
switch action := srv.MsgAcceptFunc(dh); action {
case MsgAccept:
if req.unpack(dh, m, off) == nil {
break
}
fallthrough
case MsgReject, MsgRejectNotImplemented:
opcode := req.Opcode
req.SetRcodeFormatError(req)
req.Zero = false
if action == MsgRejectNotImplemented {
req.Opcode = opcode
req.Rcode = RcodeNotImplemented
}
// Are we allowed to delete any OPT records here?
req.Ns, req.Answer, req.Extra = nil, nil, nil
w.WriteMsg(req)
fallthrough
case MsgIgnore:
if w.udp != nil && cap(m) == srv.UDPSize {
srv.udpPool.Put(m[:srv.UDPSize])
}
return
}
w.tsigStatus = nil
if w.tsigProvider != nil {
if t := req.IsTsig(); t != nil {
w.tsigStatus = tsigVerifyProvider(m, w.tsigProvider, "", false)
w.tsigTimersOnly = false
w.tsigRequestMAC = t.MAC
}
}
if w.udp != nil && cap(m) == srv.UDPSize {
srv.udpPool.Put(m[:srv.UDPSize])
}
srv.Handler.ServeDNS(w, req) // Writes back to the client
}
func (srv *Server) readTCP(conn net.Conn, timeout time.Duration) ([]byte, error) {
// If we race with ShutdownContext, the read deadline may
// have been set in the distant past to unblock the read
// below. We must not override it, otherwise we may block
// ShutdownContext.
srv.lock.RLock()
if srv.started {
conn.SetReadDeadline(time.Now().Add(timeout))
}
srv.lock.RUnlock()
var length uint16
if err := binary.Read(conn, binary.BigEndian, &length); err != nil {
return nil, err
}
m := make([]byte, length)
if _, err := io.ReadFull(conn, m); err != nil {
return nil, err
}
return m, nil
}
func (srv *Server) readUDP(conn *net.UDPConn, timeout time.Duration) ([]byte, *SessionUDP, error) {
srv.lock.RLock()
if srv.started {
// See the comment in readTCP above.
conn.SetReadDeadline(time.Now().Add(timeout))
}
srv.lock.RUnlock()
m := srv.udpPool.Get().([]byte)
n, s, err := ReadFromSessionUDP(conn, m)
if err != nil {
srv.udpPool.Put(m)
return nil, nil, err
}
m = m[:n]
return m, s, nil
}
func (srv *Server) readPacketConn(conn net.PacketConn, timeout time.Duration) ([]byte, net.Addr, error) {
srv.lock.RLock()
if srv.started {
// See the comment in readTCP above.
conn.SetReadDeadline(time.Now().Add(timeout))
}
srv.lock.RUnlock()
m := srv.udpPool.Get().([]byte)
n, addr, err := conn.ReadFrom(m)
if err != nil {
srv.udpPool.Put(m)
return nil, nil, err
}
m = m[:n]
return m, addr, nil
}
// WriteMsg implements the ResponseWriter.WriteMsg method.
func (w *response) WriteMsg(m *Msg) (err error) {
if w.closed {
return &Error{err: "WriteMsg called after Close"}
}
var data []byte
if w.tsigProvider != nil { // if no provider, dont check for the tsig (which is a longer check)
if t := m.IsTsig(); t != nil {
data, w.tsigRequestMAC, err = tsigGenerateProvider(m, w.tsigProvider, w.tsigRequestMAC, w.tsigTimersOnly)
if err != nil {
return err
}
_, err = w.writer.Write(data)
return err
}
}
data, err = m.Pack()
if err != nil {
return err
}
_, err = w.writer.Write(data)
return err
}
// Write implements the ResponseWriter.Write method.
func (w *response) Write(m []byte) (int, error) {
if w.closed {
return 0, &Error{err: "Write called after Close"}
}
switch {
case w.udp != nil:
if u, ok := w.udp.(*net.UDPConn); ok {
return WriteToSessionUDP(u, m, w.udpSession)
}
return w.udp.WriteTo(m, w.pcSession)
case w.tcp != nil:
if len(m) > MaxMsgSize {
return 0, &Error{err: "message too large"}
}
msg := make([]byte, 2+len(m))
binary.BigEndian.PutUint16(msg, uint16(len(m)))
copy(msg[2:], m)
return w.tcp.Write(msg)
default:
panic("dns: internal error: udp and tcp both nil")
}
}
// LocalAddr implements the ResponseWriter.LocalAddr method.
func (w *response) LocalAddr() net.Addr {
switch {
case w.udp != nil:
return w.udp.LocalAddr()
case w.tcp != nil:
return w.tcp.LocalAddr()
default:
panic("dns: internal error: udp and tcp both nil")
}
}
// RemoteAddr implements the ResponseWriter.RemoteAddr method.
func (w *response) RemoteAddr() net.Addr {
switch {
case w.udpSession != nil:
return w.udpSession.RemoteAddr()
case w.pcSession != nil:
return w.pcSession
case w.tcp != nil:
return w.tcp.RemoteAddr()
default:
panic("dns: internal error: udpSession, pcSession and tcp are all nil")
}
}
// TsigStatus implements the ResponseWriter.TsigStatus method.
func (w *response) TsigStatus() error { return w.tsigStatus }
// TsigTimersOnly implements the ResponseWriter.TsigTimersOnly method.
func (w *response) TsigTimersOnly(b bool) { w.tsigTimersOnly = b }
// Hijack implements the ResponseWriter.Hijack method.
func (w *response) Hijack() { w.hijacked = true }
// Close implements the ResponseWriter.Close method
func (w *response) Close() error {
if w.closed {
return &Error{err: "connection already closed"}
}
w.closed = true
switch {
case w.udp != nil:
// Can't close the udp conn, as that is actually the listener.
return nil
case w.tcp != nil:
return w.tcp.Close()
default:
panic("dns: internal error: udp and tcp both nil")
}
}
// ConnectionState() implements the ConnectionStater.ConnectionState() interface.
func (w *response) ConnectionState() *tls.ConnectionState {
type tlsConnectionStater interface {
ConnectionState() tls.ConnectionState
}
if v, ok := w.tcp.(tlsConnectionStater); ok {
t := v.ConnectionState()
return &t
}
return nil
}

194
vendor/github.com/miekg/dns/sig0.go generated vendored Normal file
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@ -0,0 +1,194 @@
package dns
import (
"crypto"
"crypto/ecdsa"
"crypto/ed25519"
"crypto/rsa"
"encoding/binary"
"math/big"
"strings"
"time"
)
// Sign signs a dns.Msg. It fills the signature with the appropriate data.
// The SIG record should have the SignerName, KeyTag, Algorithm, Inception
// and Expiration set.
func (rr *SIG) Sign(k crypto.Signer, m *Msg) ([]byte, error) {
if k == nil {
return nil, ErrPrivKey
}
if rr.KeyTag == 0 || rr.SignerName == "" || rr.Algorithm == 0 {
return nil, ErrKey
}
rr.Hdr = RR_Header{Name: ".", Rrtype: TypeSIG, Class: ClassANY, Ttl: 0}
rr.OrigTtl, rr.TypeCovered, rr.Labels = 0, 0, 0
buf := make([]byte, m.Len()+Len(rr))
mbuf, err := m.PackBuffer(buf)
if err != nil {
return nil, err
}
if &buf[0] != &mbuf[0] {
return nil, ErrBuf
}
off, err := PackRR(rr, buf, len(mbuf), nil, false)
if err != nil {
return nil, err
}
buf = buf[:off:cap(buf)]
h, cryptohash, err := hashFromAlgorithm(rr.Algorithm)
if err != nil {
return nil, err
}
// Write SIG rdata
h.Write(buf[len(mbuf)+1+2+2+4+2:])
// Write message
h.Write(buf[:len(mbuf)])
signature, err := sign(k, h.Sum(nil), cryptohash, rr.Algorithm)
if err != nil {
return nil, err
}
rr.Signature = toBase64(signature)
buf = append(buf, signature...)
if len(buf) > int(^uint16(0)) {
return nil, ErrBuf
}
// Adjust sig data length
rdoff := len(mbuf) + 1 + 2 + 2 + 4
rdlen := binary.BigEndian.Uint16(buf[rdoff:])
rdlen += uint16(len(signature))
binary.BigEndian.PutUint16(buf[rdoff:], rdlen)
// Adjust additional count
adc := binary.BigEndian.Uint16(buf[10:])
adc++
binary.BigEndian.PutUint16(buf[10:], adc)
return buf, nil
}
// Verify validates the message buf using the key k.
// It's assumed that buf is a valid message from which rr was unpacked.
func (rr *SIG) Verify(k *KEY, buf []byte) error {
if k == nil {
return ErrKey
}
if rr.KeyTag == 0 || rr.SignerName == "" || rr.Algorithm == 0 {
return ErrKey
}
h, cryptohash, err := hashFromAlgorithm(rr.Algorithm)
if err != nil {
return err
}
buflen := len(buf)
qdc := binary.BigEndian.Uint16(buf[4:])
anc := binary.BigEndian.Uint16(buf[6:])
auc := binary.BigEndian.Uint16(buf[8:])
adc := binary.BigEndian.Uint16(buf[10:])
offset := headerSize
for i := uint16(0); i < qdc && offset < buflen; i++ {
_, offset, err = UnpackDomainName(buf, offset)
if err != nil {
return err
}
// Skip past Type and Class
offset += 2 + 2
}
for i := uint16(1); i < anc+auc+adc && offset < buflen; i++ {
_, offset, err = UnpackDomainName(buf, offset)
if err != nil {
return err
}
// Skip past Type, Class and TTL
offset += 2 + 2 + 4
if offset+1 >= buflen {
continue
}
rdlen := binary.BigEndian.Uint16(buf[offset:])
offset += 2
offset += int(rdlen)
}
if offset >= buflen {
return &Error{err: "overflowing unpacking signed message"}
}
// offset should be just prior to SIG
bodyend := offset
// owner name SHOULD be root
_, offset, err = UnpackDomainName(buf, offset)
if err != nil {
return err
}
// Skip Type, Class, TTL, RDLen
offset += 2 + 2 + 4 + 2
sigstart := offset
// Skip Type Covered, Algorithm, Labels, Original TTL
offset += 2 + 1 + 1 + 4
if offset+4+4 >= buflen {
return &Error{err: "overflow unpacking signed message"}
}
expire := binary.BigEndian.Uint32(buf[offset:])
offset += 4
incept := binary.BigEndian.Uint32(buf[offset:])
offset += 4
now := uint32(time.Now().Unix())
if now < incept || now > expire {
return ErrTime
}
// Skip key tag
offset += 2
var signername string
signername, offset, err = UnpackDomainName(buf, offset)
if err != nil {
return err
}
// If key has come from the DNS name compression might
// have mangled the case of the name
if !strings.EqualFold(signername, k.Header().Name) {
return &Error{err: "signer name doesn't match key name"}
}
sigend := offset
h.Write(buf[sigstart:sigend])
h.Write(buf[:10])
h.Write([]byte{
byte((adc - 1) << 8),
byte(adc - 1),
})
h.Write(buf[12:bodyend])
hashed := h.Sum(nil)
sig := buf[sigend:]
switch k.Algorithm {
case RSASHA1, RSASHA256, RSASHA512:
pk := k.publicKeyRSA()
if pk != nil {
return rsa.VerifyPKCS1v15(pk, cryptohash, hashed, sig)
}
case ECDSAP256SHA256, ECDSAP384SHA384:
pk := k.publicKeyECDSA()
r := new(big.Int).SetBytes(sig[:len(sig)/2])
s := new(big.Int).SetBytes(sig[len(sig)/2:])
if pk != nil {
if ecdsa.Verify(pk, hashed, r, s) {
return nil
}
return ErrSig
}
case ED25519:
pk := k.publicKeyED25519()
if pk != nil {
if ed25519.Verify(pk, hashed, sig) {
return nil
}
return ErrSig
}
}
return ErrKeyAlg
}

61
vendor/github.com/miekg/dns/singleinflight.go generated vendored Normal file
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@ -0,0 +1,61 @@
// Copyright 2013 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
// Adapted for dns package usage by Miek Gieben.
package dns
import "sync"
import "time"
// call is an in-flight or completed singleflight.Do call
type call struct {
wg sync.WaitGroup
val *Msg
rtt time.Duration
err error
dups int
}
// singleflight represents a class of work and forms a namespace in
// which units of work can be executed with duplicate suppression.
type singleflight struct {
sync.Mutex // protects m
m map[string]*call // lazily initialized
dontDeleteForTesting bool // this is only to be used by TestConcurrentExchanges
}
// Do executes and returns the results of the given function, making
// sure that only one execution is in-flight for a given key at a
// time. If a duplicate comes in, the duplicate caller waits for the
// original to complete and receives the same results.
// The return value shared indicates whether v was given to multiple callers.
func (g *singleflight) Do(key string, fn func() (*Msg, time.Duration, error)) (v *Msg, rtt time.Duration, err error, shared bool) {
g.Lock()
if g.m == nil {
g.m = make(map[string]*call)
}
if c, ok := g.m[key]; ok {
c.dups++
g.Unlock()
c.wg.Wait()
return c.val, c.rtt, c.err, true
}
c := new(call)
c.wg.Add(1)
g.m[key] = c
g.Unlock()
c.val, c.rtt, c.err = fn()
c.wg.Done()
if !g.dontDeleteForTesting {
g.Lock()
delete(g.m, key)
g.Unlock()
}
return c.val, c.rtt, c.err, c.dups > 0
}

44
vendor/github.com/miekg/dns/smimea.go generated vendored Normal file
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@ -0,0 +1,44 @@
package dns
import (
"crypto/sha256"
"crypto/x509"
"encoding/hex"
)
// Sign creates a SMIMEA record from an SSL certificate.
func (r *SMIMEA) Sign(usage, selector, matchingType int, cert *x509.Certificate) (err error) {
r.Hdr.Rrtype = TypeSMIMEA
r.Usage = uint8(usage)
r.Selector = uint8(selector)
r.MatchingType = uint8(matchingType)
r.Certificate, err = CertificateToDANE(r.Selector, r.MatchingType, cert)
return err
}
// Verify verifies a SMIMEA record against an SSL certificate. If it is OK
// a nil error is returned.
func (r *SMIMEA) Verify(cert *x509.Certificate) error {
c, err := CertificateToDANE(r.Selector, r.MatchingType, cert)
if err != nil {
return err // Not also ErrSig?
}
if r.Certificate == c {
return nil
}
return ErrSig // ErrSig, really?
}
// SMIMEAName returns the ownername of a SMIMEA resource record as per the
// format specified in RFC 'draft-ietf-dane-smime-12' Section 2 and 3
func SMIMEAName(email, domain string) (string, error) {
hasher := sha256.New()
hasher.Write([]byte(email))
// RFC Section 3: "The local-part is hashed using the SHA2-256
// algorithm with the hash truncated to 28 octets and
// represented in its hexadecimal representation to become the
// left-most label in the prepared domain name"
return hex.EncodeToString(hasher.Sum(nil)[:28]) + "." + "_smimecert." + domain, nil
}

935
vendor/github.com/miekg/dns/svcb.go generated vendored Normal file
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@ -0,0 +1,935 @@
package dns
import (
"bytes"
"encoding/binary"
"errors"
"fmt"
"net"
"sort"
"strconv"
"strings"
)
// SVCBKey is the type of the keys used in the SVCB RR.
type SVCBKey uint16
// Keys defined in draft-ietf-dnsop-svcb-https-08 Section 14.3.2.
const (
SVCB_MANDATORY SVCBKey = iota
SVCB_ALPN
SVCB_NO_DEFAULT_ALPN
SVCB_PORT
SVCB_IPV4HINT
SVCB_ECHCONFIG
SVCB_IPV6HINT
SVCB_DOHPATH // draft-ietf-add-svcb-dns-02 Section 9
svcb_RESERVED SVCBKey = 65535
)
var svcbKeyToStringMap = map[SVCBKey]string{
SVCB_MANDATORY: "mandatory",
SVCB_ALPN: "alpn",
SVCB_NO_DEFAULT_ALPN: "no-default-alpn",
SVCB_PORT: "port",
SVCB_IPV4HINT: "ipv4hint",
SVCB_ECHCONFIG: "ech",
SVCB_IPV6HINT: "ipv6hint",
SVCB_DOHPATH: "dohpath",
}
var svcbStringToKeyMap = reverseSVCBKeyMap(svcbKeyToStringMap)
func reverseSVCBKeyMap(m map[SVCBKey]string) map[string]SVCBKey {
n := make(map[string]SVCBKey, len(m))
for u, s := range m {
n[s] = u
}
return n
}
// String takes the numerical code of an SVCB key and returns its name.
// Returns an empty string for reserved keys.
// Accepts unassigned keys as well as experimental/private keys.
func (key SVCBKey) String() string {
if x := svcbKeyToStringMap[key]; x != "" {
return x
}
if key == svcb_RESERVED {
return ""
}
return "key" + strconv.FormatUint(uint64(key), 10)
}
// svcbStringToKey returns the numerical code of an SVCB key.
// Returns svcb_RESERVED for reserved/invalid keys.
// Accepts unassigned keys as well as experimental/private keys.
func svcbStringToKey(s string) SVCBKey {
if strings.HasPrefix(s, "key") {
a, err := strconv.ParseUint(s[3:], 10, 16)
// no leading zeros
// key shouldn't be registered
if err != nil || a == 65535 || s[3] == '0' || svcbKeyToStringMap[SVCBKey(a)] != "" {
return svcb_RESERVED
}
return SVCBKey(a)
}
if key, ok := svcbStringToKeyMap[s]; ok {
return key
}
return svcb_RESERVED
}
func (rr *SVCB) parse(c *zlexer, o string) *ParseError {
l, _ := c.Next()
i, e := strconv.ParseUint(l.token, 10, 16)
if e != nil || l.err {
return &ParseError{l.token, "bad SVCB priority", l}
}
rr.Priority = uint16(i)
c.Next() // zBlank
l, _ = c.Next() // zString
rr.Target = l.token
name, nameOk := toAbsoluteName(l.token, o)
if l.err || !nameOk {
return &ParseError{l.token, "bad SVCB Target", l}
}
rr.Target = name
// Values (if any)
l, _ = c.Next()
var xs []SVCBKeyValue
// Helps require whitespace between pairs.
// Prevents key1000="a"key1001=...
canHaveNextKey := true
for l.value != zNewline && l.value != zEOF {
switch l.value {
case zString:
if !canHaveNextKey {
// The key we can now read was probably meant to be
// a part of the last value.
return &ParseError{l.token, "bad SVCB value quotation", l}
}
// In key=value pairs, value does not have to be quoted unless value
// contains whitespace. And keys don't need to have values.
// Similarly, keys with an equality signs after them don't need values.
// l.token includes at least up to the first equality sign.
idx := strings.IndexByte(l.token, '=')
var key, value string
if idx < 0 {
// Key with no value and no equality sign
key = l.token
} else if idx == 0 {
return &ParseError{l.token, "bad SVCB key", l}
} else {
key, value = l.token[:idx], l.token[idx+1:]
if value == "" {
// We have a key and an equality sign. Maybe we have nothing
// after "=" or we have a double quote.
l, _ = c.Next()
if l.value == zQuote {
// Only needed when value ends with double quotes.
// Any value starting with zQuote ends with it.
canHaveNextKey = false
l, _ = c.Next()
switch l.value {
case zString:
// We have a value in double quotes.
value = l.token
l, _ = c.Next()
if l.value != zQuote {
return &ParseError{l.token, "SVCB unterminated value", l}
}
case zQuote:
// There's nothing in double quotes.
default:
return &ParseError{l.token, "bad SVCB value", l}
}
}
}
}
kv := makeSVCBKeyValue(svcbStringToKey(key))
if kv == nil {
return &ParseError{l.token, "bad SVCB key", l}
}
if err := kv.parse(value); err != nil {
return &ParseError{l.token, err.Error(), l}
}
xs = append(xs, kv)
case zQuote:
return &ParseError{l.token, "SVCB key can't contain double quotes", l}
case zBlank:
canHaveNextKey = true
default:
return &ParseError{l.token, "bad SVCB values", l}
}
l, _ = c.Next()
}
// "In AliasMode, records SHOULD NOT include any SvcParams, and recipients MUST
// ignore any SvcParams that are present."
// However, we don't check rr.Priority == 0 && len(xs) > 0 here
// It is the responsibility of the user of the library to check this.
// This is to encourage the fixing of the source of this error.
rr.Value = xs
return nil
}
// makeSVCBKeyValue returns an SVCBKeyValue struct with the key or nil for reserved keys.
func makeSVCBKeyValue(key SVCBKey) SVCBKeyValue {
switch key {
case SVCB_MANDATORY:
return new(SVCBMandatory)
case SVCB_ALPN:
return new(SVCBAlpn)
case SVCB_NO_DEFAULT_ALPN:
return new(SVCBNoDefaultAlpn)
case SVCB_PORT:
return new(SVCBPort)
case SVCB_IPV4HINT:
return new(SVCBIPv4Hint)
case SVCB_ECHCONFIG:
return new(SVCBECHConfig)
case SVCB_IPV6HINT:
return new(SVCBIPv6Hint)
case SVCB_DOHPATH:
return new(SVCBDoHPath)
case svcb_RESERVED:
return nil
default:
e := new(SVCBLocal)
e.KeyCode = key
return e
}
}
// SVCB RR. See RFC xxxx (https://tools.ietf.org/html/draft-ietf-dnsop-svcb-https-08).
//
// NOTE: The HTTPS/SVCB RFCs are in the draft stage.
// The API, including constants and types related to SVCBKeyValues, may
// change in future versions in accordance with the latest drafts.
type SVCB struct {
Hdr RR_Header
Priority uint16 // If zero, Value must be empty or discarded by the user of this library
Target string `dns:"domain-name"`
Value []SVCBKeyValue `dns:"pairs"`
}
// HTTPS RR. Everything valid for SVCB applies to HTTPS as well.
// Except that the HTTPS record is intended for use with the HTTP and HTTPS protocols.
//
// NOTE: The HTTPS/SVCB RFCs are in the draft stage.
// The API, including constants and types related to SVCBKeyValues, may
// change in future versions in accordance with the latest drafts.
type HTTPS struct {
SVCB
}
func (rr *HTTPS) String() string {
return rr.SVCB.String()
}
func (rr *HTTPS) parse(c *zlexer, o string) *ParseError {
return rr.SVCB.parse(c, o)
}
// SVCBKeyValue defines a key=value pair for the SVCB RR type.
// An SVCB RR can have multiple SVCBKeyValues appended to it.
type SVCBKeyValue interface {
Key() SVCBKey // Key returns the numerical key code.
pack() ([]byte, error) // pack returns the encoded value.
unpack([]byte) error // unpack sets the value.
String() string // String returns the string representation of the value.
parse(string) error // parse sets the value to the given string representation of the value.
copy() SVCBKeyValue // copy returns a deep-copy of the pair.
len() int // len returns the length of value in the wire format.
}
// SVCBMandatory pair adds to required keys that must be interpreted for the RR
// to be functional. If ignored, the whole RRSet must be ignored.
// "port" and "no-default-alpn" are mandatory by default if present,
// so they shouldn't be included here.
//
// It is incumbent upon the user of this library to reject the RRSet if
// or avoid constructing such an RRSet that:
// - "mandatory" is included as one of the keys of mandatory
// - no key is listed multiple times in mandatory
// - all keys listed in mandatory are present
// - escape sequences are not used in mandatory
// - mandatory, when present, lists at least one key
//
// Basic use pattern for creating a mandatory option:
//
// s := &dns.SVCB{Hdr: dns.RR_Header{Name: ".", Rrtype: dns.TypeSVCB, Class: dns.ClassINET}}
// e := new(dns.SVCBMandatory)
// e.Code = []uint16{dns.SVCB_ALPN}
// s.Value = append(s.Value, e)
// t := new(dns.SVCBAlpn)
// t.Alpn = []string{"xmpp-client"}
// s.Value = append(s.Value, t)
type SVCBMandatory struct {
Code []SVCBKey
}
func (*SVCBMandatory) Key() SVCBKey { return SVCB_MANDATORY }
func (s *SVCBMandatory) String() string {
str := make([]string, len(s.Code))
for i, e := range s.Code {
str[i] = e.String()
}
return strings.Join(str, ",")
}
func (s *SVCBMandatory) pack() ([]byte, error) {
codes := append([]SVCBKey(nil), s.Code...)
sort.Slice(codes, func(i, j int) bool {
return codes[i] < codes[j]
})
b := make([]byte, 2*len(codes))
for i, e := range codes {
binary.BigEndian.PutUint16(b[2*i:], uint16(e))
}
return b, nil
}
func (s *SVCBMandatory) unpack(b []byte) error {
if len(b)%2 != 0 {
return errors.New("dns: svcbmandatory: value length is not a multiple of 2")
}
codes := make([]SVCBKey, 0, len(b)/2)
for i := 0; i < len(b); i += 2 {
// We assume strictly increasing order.
codes = append(codes, SVCBKey(binary.BigEndian.Uint16(b[i:])))
}
s.Code = codes
return nil
}
func (s *SVCBMandatory) parse(b string) error {
str := strings.Split(b, ",")
codes := make([]SVCBKey, 0, len(str))
for _, e := range str {
codes = append(codes, svcbStringToKey(e))
}
s.Code = codes
return nil
}
func (s *SVCBMandatory) len() int {
return 2 * len(s.Code)
}
func (s *SVCBMandatory) copy() SVCBKeyValue {
return &SVCBMandatory{
append([]SVCBKey(nil), s.Code...),
}
}
// SVCBAlpn pair is used to list supported connection protocols.
// The user of this library must ensure that at least one protocol is listed when alpn is present.
// Protocol IDs can be found at:
// https://www.iana.org/assignments/tls-extensiontype-values/tls-extensiontype-values.xhtml#alpn-protocol-ids
// Basic use pattern for creating an alpn option:
//
// h := new(dns.HTTPS)
// h.Hdr = dns.RR_Header{Name: ".", Rrtype: dns.TypeHTTPS, Class: dns.ClassINET}
// e := new(dns.SVCBAlpn)
// e.Alpn = []string{"h2", "http/1.1"}
// h.Value = append(h.Value, e)
type SVCBAlpn struct {
Alpn []string
}
func (*SVCBAlpn) Key() SVCBKey { return SVCB_ALPN }
func (s *SVCBAlpn) String() string {
// An ALPN value is a comma-separated list of values, each of which can be
// an arbitrary binary value. In order to allow parsing, the comma and
// backslash characters are themselves excaped.
//
// However, this escaping is done in addition to the normal escaping which
// happens in zone files, meaning that these values must be
// double-escaped. This looks terrible, so if you see a never-ending
// sequence of backslash in a zone file this may be why.
//
// https://datatracker.ietf.org/doc/html/draft-ietf-dnsop-svcb-https-08#appendix-A.1
var str strings.Builder
for i, alpn := range s.Alpn {
// 4*len(alpn) is the worst case where we escape every character in the alpn as \123, plus 1 byte for the ',' separating the alpn from others
str.Grow(4*len(alpn) + 1)
if i > 0 {
str.WriteByte(',')
}
for j := 0; j < len(alpn); j++ {
e := alpn[j]
if ' ' > e || e > '~' {
str.WriteString(escapeByte(e))
continue
}
switch e {
// We escape a few characters which may confuse humans or parsers.
case '"', ';', ' ':
str.WriteByte('\\')
str.WriteByte(e)
// The comma and backslash characters themselves must be
// doubly-escaped. We use `\\` for the first backslash and
// the escaped numeric value for the other value. We especially
// don't want a comma in the output.
case ',':
str.WriteString(`\\\044`)
case '\\':
str.WriteString(`\\\092`)
default:
str.WriteByte(e)
}
}
}
return str.String()
}
func (s *SVCBAlpn) pack() ([]byte, error) {
// Liberally estimate the size of an alpn as 10 octets
b := make([]byte, 0, 10*len(s.Alpn))
for _, e := range s.Alpn {
if e == "" {
return nil, errors.New("dns: svcbalpn: empty alpn-id")
}
if len(e) > 255 {
return nil, errors.New("dns: svcbalpn: alpn-id too long")
}
b = append(b, byte(len(e)))
b = append(b, e...)
}
return b, nil
}
func (s *SVCBAlpn) unpack(b []byte) error {
// Estimate the size of the smallest alpn as 4 bytes
alpn := make([]string, 0, len(b)/4)
for i := 0; i < len(b); {
length := int(b[i])
i++
if i+length > len(b) {
return errors.New("dns: svcbalpn: alpn array overflowing")
}
alpn = append(alpn, string(b[i:i+length]))
i += length
}
s.Alpn = alpn
return nil
}
func (s *SVCBAlpn) parse(b string) error {
if len(b) == 0 {
s.Alpn = []string{}
return nil
}
alpn := []string{}
a := []byte{}
for p := 0; p < len(b); {
c, q := nextByte(b, p)
if q == 0 {
return errors.New("dns: svcbalpn: unterminated escape")
}
p += q
// If we find a comma, we have finished reading an alpn.
if c == ',' {
if len(a) == 0 {
return errors.New("dns: svcbalpn: empty protocol identifier")
}
alpn = append(alpn, string(a))
a = []byte{}
continue
}
// If it's a backslash, we need to handle a comma-separated list.
if c == '\\' {
dc, dq := nextByte(b, p)
if dq == 0 {
return errors.New("dns: svcbalpn: unterminated escape decoding comma-separated list")
}
if dc != '\\' && dc != ',' {
return errors.New("dns: svcbalpn: bad escaped character decoding comma-separated list")
}
p += dq
c = dc
}
a = append(a, c)
}
// Add the final alpn.
if len(a) == 0 {
return errors.New("dns: svcbalpn: last protocol identifier empty")
}
s.Alpn = append(alpn, string(a))
return nil
}
func (s *SVCBAlpn) len() int {
var l int
for _, e := range s.Alpn {
l += 1 + len(e)
}
return l
}
func (s *SVCBAlpn) copy() SVCBKeyValue {
return &SVCBAlpn{
append([]string(nil), s.Alpn...),
}
}
// SVCBNoDefaultAlpn pair signifies no support for default connection protocols.
// Should be used in conjunction with alpn.
// Basic use pattern for creating a no-default-alpn option:
//
// s := &dns.SVCB{Hdr: dns.RR_Header{Name: ".", Rrtype: dns.TypeSVCB, Class: dns.ClassINET}}
// t := new(dns.SVCBAlpn)
// t.Alpn = []string{"xmpp-client"}
// s.Value = append(s.Value, t)
// e := new(dns.SVCBNoDefaultAlpn)
// s.Value = append(s.Value, e)
type SVCBNoDefaultAlpn struct{}
func (*SVCBNoDefaultAlpn) Key() SVCBKey { return SVCB_NO_DEFAULT_ALPN }
func (*SVCBNoDefaultAlpn) copy() SVCBKeyValue { return &SVCBNoDefaultAlpn{} }
func (*SVCBNoDefaultAlpn) pack() ([]byte, error) { return []byte{}, nil }
func (*SVCBNoDefaultAlpn) String() string { return "" }
func (*SVCBNoDefaultAlpn) len() int { return 0 }
func (*SVCBNoDefaultAlpn) unpack(b []byte) error {
if len(b) != 0 {
return errors.New("dns: svcbnodefaultalpn: no-default-alpn must have no value")
}
return nil
}
func (*SVCBNoDefaultAlpn) parse(b string) error {
if b != "" {
return errors.New("dns: svcbnodefaultalpn: no-default-alpn must have no value")
}
return nil
}
// SVCBPort pair defines the port for connection.
// Basic use pattern for creating a port option:
//
// s := &dns.SVCB{Hdr: dns.RR_Header{Name: ".", Rrtype: dns.TypeSVCB, Class: dns.ClassINET}}
// e := new(dns.SVCBPort)
// e.Port = 80
// s.Value = append(s.Value, e)
type SVCBPort struct {
Port uint16
}
func (*SVCBPort) Key() SVCBKey { return SVCB_PORT }
func (*SVCBPort) len() int { return 2 }
func (s *SVCBPort) String() string { return strconv.FormatUint(uint64(s.Port), 10) }
func (s *SVCBPort) copy() SVCBKeyValue { return &SVCBPort{s.Port} }
func (s *SVCBPort) unpack(b []byte) error {
if len(b) != 2 {
return errors.New("dns: svcbport: port length is not exactly 2 octets")
}
s.Port = binary.BigEndian.Uint16(b)
return nil
}
func (s *SVCBPort) pack() ([]byte, error) {
b := make([]byte, 2)
binary.BigEndian.PutUint16(b, s.Port)
return b, nil
}
func (s *SVCBPort) parse(b string) error {
port, err := strconv.ParseUint(b, 10, 16)
if err != nil {
return errors.New("dns: svcbport: port out of range")
}
s.Port = uint16(port)
return nil
}
// SVCBIPv4Hint pair suggests an IPv4 address which may be used to open connections
// if A and AAAA record responses for SVCB's Target domain haven't been received.
// In that case, optionally, A and AAAA requests can be made, after which the connection
// to the hinted IP address may be terminated and a new connection may be opened.
// Basic use pattern for creating an ipv4hint option:
//
// h := new(dns.HTTPS)
// h.Hdr = dns.RR_Header{Name: ".", Rrtype: dns.TypeHTTPS, Class: dns.ClassINET}
// e := new(dns.SVCBIPv4Hint)
// e.Hint = []net.IP{net.IPv4(1,1,1,1).To4()}
//
// Or
//
// e.Hint = []net.IP{net.ParseIP("1.1.1.1").To4()}
// h.Value = append(h.Value, e)
type SVCBIPv4Hint struct {
Hint []net.IP
}
func (*SVCBIPv4Hint) Key() SVCBKey { return SVCB_IPV4HINT }
func (s *SVCBIPv4Hint) len() int { return 4 * len(s.Hint) }
func (s *SVCBIPv4Hint) pack() ([]byte, error) {
b := make([]byte, 0, 4*len(s.Hint))
for _, e := range s.Hint {
x := e.To4()
if x == nil {
return nil, errors.New("dns: svcbipv4hint: expected ipv4, hint is ipv6")
}
b = append(b, x...)
}
return b, nil
}
func (s *SVCBIPv4Hint) unpack(b []byte) error {
if len(b) == 0 || len(b)%4 != 0 {
return errors.New("dns: svcbipv4hint: ipv4 address byte array length is not a multiple of 4")
}
x := make([]net.IP, 0, len(b)/4)
for i := 0; i < len(b); i += 4 {
x = append(x, net.IP(b[i:i+4]))
}
s.Hint = x
return nil
}
func (s *SVCBIPv4Hint) String() string {
str := make([]string, len(s.Hint))
for i, e := range s.Hint {
x := e.To4()
if x == nil {
return "<nil>"
}
str[i] = x.String()
}
return strings.Join(str, ",")
}
func (s *SVCBIPv4Hint) parse(b string) error {
if strings.Contains(b, ":") {
return errors.New("dns: svcbipv4hint: expected ipv4, got ipv6")
}
str := strings.Split(b, ",")
dst := make([]net.IP, len(str))
for i, e := range str {
ip := net.ParseIP(e).To4()
if ip == nil {
return errors.New("dns: svcbipv4hint: bad ip")
}
dst[i] = ip
}
s.Hint = dst
return nil
}
func (s *SVCBIPv4Hint) copy() SVCBKeyValue {
hint := make([]net.IP, len(s.Hint))
for i, ip := range s.Hint {
hint[i] = copyIP(ip)
}
return &SVCBIPv4Hint{
Hint: hint,
}
}
// SVCBECHConfig pair contains the ECHConfig structure defined in draft-ietf-tls-esni [RFC xxxx].
// Basic use pattern for creating an ech option:
//
// h := new(dns.HTTPS)
// h.Hdr = dns.RR_Header{Name: ".", Rrtype: dns.TypeHTTPS, Class: dns.ClassINET}
// e := new(dns.SVCBECHConfig)
// e.ECH = []byte{0xfe, 0x08, ...}
// h.Value = append(h.Value, e)
type SVCBECHConfig struct {
ECH []byte // Specifically ECHConfigList including the redundant length prefix
}
func (*SVCBECHConfig) Key() SVCBKey { return SVCB_ECHCONFIG }
func (s *SVCBECHConfig) String() string { return toBase64(s.ECH) }
func (s *SVCBECHConfig) len() int { return len(s.ECH) }
func (s *SVCBECHConfig) pack() ([]byte, error) {
return append([]byte(nil), s.ECH...), nil
}
func (s *SVCBECHConfig) copy() SVCBKeyValue {
return &SVCBECHConfig{
append([]byte(nil), s.ECH...),
}
}
func (s *SVCBECHConfig) unpack(b []byte) error {
s.ECH = append([]byte(nil), b...)
return nil
}
func (s *SVCBECHConfig) parse(b string) error {
x, err := fromBase64([]byte(b))
if err != nil {
return errors.New("dns: svcbech: bad base64 ech")
}
s.ECH = x
return nil
}
// SVCBIPv6Hint pair suggests an IPv6 address which may be used to open connections
// if A and AAAA record responses for SVCB's Target domain haven't been received.
// In that case, optionally, A and AAAA requests can be made, after which the
// connection to the hinted IP address may be terminated and a new connection may be opened.
// Basic use pattern for creating an ipv6hint option:
//
// h := new(dns.HTTPS)
// h.Hdr = dns.RR_Header{Name: ".", Rrtype: dns.TypeHTTPS, Class: dns.ClassINET}
// e := new(dns.SVCBIPv6Hint)
// e.Hint = []net.IP{net.ParseIP("2001:db8::1")}
// h.Value = append(h.Value, e)
type SVCBIPv6Hint struct {
Hint []net.IP
}
func (*SVCBIPv6Hint) Key() SVCBKey { return SVCB_IPV6HINT }
func (s *SVCBIPv6Hint) len() int { return 16 * len(s.Hint) }
func (s *SVCBIPv6Hint) pack() ([]byte, error) {
b := make([]byte, 0, 16*len(s.Hint))
for _, e := range s.Hint {
if len(e) != net.IPv6len || e.To4() != nil {
return nil, errors.New("dns: svcbipv6hint: expected ipv6, hint is ipv4")
}
b = append(b, e...)
}
return b, nil
}
func (s *SVCBIPv6Hint) unpack(b []byte) error {
if len(b) == 0 || len(b)%16 != 0 {
return errors.New("dns: svcbipv6hint: ipv6 address byte array length not a multiple of 16")
}
x := make([]net.IP, 0, len(b)/16)
for i := 0; i < len(b); i += 16 {
ip := net.IP(b[i : i+16])
if ip.To4() != nil {
return errors.New("dns: svcbipv6hint: expected ipv6, got ipv4")
}
x = append(x, ip)
}
s.Hint = x
return nil
}
func (s *SVCBIPv6Hint) String() string {
str := make([]string, len(s.Hint))
for i, e := range s.Hint {
if x := e.To4(); x != nil {
return "<nil>"
}
str[i] = e.String()
}
return strings.Join(str, ",")
}
func (s *SVCBIPv6Hint) parse(b string) error {
str := strings.Split(b, ",")
dst := make([]net.IP, len(str))
for i, e := range str {
ip := net.ParseIP(e)
if ip == nil {
return errors.New("dns: svcbipv6hint: bad ip")
}
if ip.To4() != nil {
return errors.New("dns: svcbipv6hint: expected ipv6, got ipv4-mapped-ipv6")
}
dst[i] = ip
}
s.Hint = dst
return nil
}
func (s *SVCBIPv6Hint) copy() SVCBKeyValue {
hint := make([]net.IP, len(s.Hint))
for i, ip := range s.Hint {
hint[i] = copyIP(ip)
}
return &SVCBIPv6Hint{
Hint: hint,
}
}
// SVCBDoHPath pair is used to indicate the URI template that the
// clients may use to construct a DNS over HTTPS URI.
//
// See RFC xxxx (https://datatracker.ietf.org/doc/html/draft-ietf-add-svcb-dns-02)
// and RFC yyyy (https://datatracker.ietf.org/doc/html/draft-ietf-add-ddr-06).
//
// A basic example of using the dohpath option together with the alpn
// option to indicate support for DNS over HTTPS on a certain path:
//
// s := new(dns.SVCB)
// s.Hdr = dns.RR_Header{Name: ".", Rrtype: dns.TypeSVCB, Class: dns.ClassINET}
// e := new(dns.SVCBAlpn)
// e.Alpn = []string{"h2", "h3"}
// p := new(dns.SVCBDoHPath)
// p.Template = "/dns-query{?dns}"
// s.Value = append(s.Value, e, p)
//
// The parsing currently doesn't validate that Template is a valid
// RFC 6570 URI template.
type SVCBDoHPath struct {
Template string
}
func (*SVCBDoHPath) Key() SVCBKey { return SVCB_DOHPATH }
func (s *SVCBDoHPath) String() string { return svcbParamToStr([]byte(s.Template)) }
func (s *SVCBDoHPath) len() int { return len(s.Template) }
func (s *SVCBDoHPath) pack() ([]byte, error) { return []byte(s.Template), nil }
func (s *SVCBDoHPath) unpack(b []byte) error {
s.Template = string(b)
return nil
}
func (s *SVCBDoHPath) parse(b string) error {
template, err := svcbParseParam(b)
if err != nil {
return fmt.Errorf("dns: svcbdohpath: %w", err)
}
s.Template = string(template)
return nil
}
func (s *SVCBDoHPath) copy() SVCBKeyValue {
return &SVCBDoHPath{
Template: s.Template,
}
}
// SVCBLocal pair is intended for experimental/private use. The key is recommended
// to be in the range [SVCB_PRIVATE_LOWER, SVCB_PRIVATE_UPPER].
// Basic use pattern for creating a keyNNNNN option:
//
// h := new(dns.HTTPS)
// h.Hdr = dns.RR_Header{Name: ".", Rrtype: dns.TypeHTTPS, Class: dns.ClassINET}
// e := new(dns.SVCBLocal)
// e.KeyCode = 65400
// e.Data = []byte("abc")
// h.Value = append(h.Value, e)
type SVCBLocal struct {
KeyCode SVCBKey // Never 65535 or any assigned keys.
Data []byte // All byte sequences are allowed.
}
func (s *SVCBLocal) Key() SVCBKey { return s.KeyCode }
func (s *SVCBLocal) String() string { return svcbParamToStr(s.Data) }
func (s *SVCBLocal) pack() ([]byte, error) { return append([]byte(nil), s.Data...), nil }
func (s *SVCBLocal) len() int { return len(s.Data) }
func (s *SVCBLocal) unpack(b []byte) error {
s.Data = append([]byte(nil), b...)
return nil
}
func (s *SVCBLocal) parse(b string) error {
data, err := svcbParseParam(b)
if err != nil {
return fmt.Errorf("dns: svcblocal: svcb private/experimental key %w", err)
}
s.Data = data
return nil
}
func (s *SVCBLocal) copy() SVCBKeyValue {
return &SVCBLocal{s.KeyCode,
append([]byte(nil), s.Data...),
}
}
func (rr *SVCB) String() string {
s := rr.Hdr.String() +
strconv.Itoa(int(rr.Priority)) + " " +
sprintName(rr.Target)
for _, e := range rr.Value {
s += " " + e.Key().String() + "=\"" + e.String() + "\""
}
return s
}
// areSVCBPairArraysEqual checks if SVCBKeyValue arrays are equal after sorting their
// copies. arrA and arrB have equal lengths, otherwise zduplicate.go wouldn't call this function.
func areSVCBPairArraysEqual(a []SVCBKeyValue, b []SVCBKeyValue) bool {
a = append([]SVCBKeyValue(nil), a...)
b = append([]SVCBKeyValue(nil), b...)
sort.Slice(a, func(i, j int) bool { return a[i].Key() < a[j].Key() })
sort.Slice(b, func(i, j int) bool { return b[i].Key() < b[j].Key() })
for i, e := range a {
if e.Key() != b[i].Key() {
return false
}
b1, err1 := e.pack()
b2, err2 := b[i].pack()
if err1 != nil || err2 != nil || !bytes.Equal(b1, b2) {
return false
}
}
return true
}
// svcbParamStr converts the value of an SVCB parameter into a DNS presentation-format string.
func svcbParamToStr(s []byte) string {
var str strings.Builder
str.Grow(4 * len(s))
for _, e := range s {
if ' ' <= e && e <= '~' {
switch e {
case '"', ';', ' ', '\\':
str.WriteByte('\\')
str.WriteByte(e)
default:
str.WriteByte(e)
}
} else {
str.WriteString(escapeByte(e))
}
}
return str.String()
}
// svcbParseParam parses a DNS presentation-format string into an SVCB parameter value.
func svcbParseParam(b string) ([]byte, error) {
data := make([]byte, 0, len(b))
for i := 0; i < len(b); {
if b[i] != '\\' {
data = append(data, b[i])
i++
continue
}
if i+1 == len(b) {
return nil, errors.New("escape unterminated")
}
if isDigit(b[i+1]) {
if i+3 < len(b) && isDigit(b[i+2]) && isDigit(b[i+3]) {
a, err := strconv.ParseUint(b[i+1:i+4], 10, 8)
if err == nil {
i += 4
data = append(data, byte(a))
continue
}
}
return nil, errors.New("bad escaped octet")
} else {
data = append(data, b[i+1])
i += 2
}
}
return data, nil
}

44
vendor/github.com/miekg/dns/tlsa.go generated vendored Normal file
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package dns
import (
"crypto/x509"
"net"
"strconv"
)
// Sign creates a TLSA record from an SSL certificate.
func (r *TLSA) Sign(usage, selector, matchingType int, cert *x509.Certificate) (err error) {
r.Hdr.Rrtype = TypeTLSA
r.Usage = uint8(usage)
r.Selector = uint8(selector)
r.MatchingType = uint8(matchingType)
r.Certificate, err = CertificateToDANE(r.Selector, r.MatchingType, cert)
return err
}
// Verify verifies a TLSA record against an SSL certificate. If it is OK
// a nil error is returned.
func (r *TLSA) Verify(cert *x509.Certificate) error {
c, err := CertificateToDANE(r.Selector, r.MatchingType, cert)
if err != nil {
return err // Not also ErrSig?
}
if r.Certificate == c {
return nil
}
return ErrSig // ErrSig, really?
}
// TLSAName returns the ownername of a TLSA resource record as per the
// rules specified in RFC 6698, Section 3.
func TLSAName(name, service, network string) (string, error) {
if !IsFqdn(name) {
return "", ErrFqdn
}
p, err := net.LookupPort(network, service)
if err != nil {
return "", err
}
return "_" + strconv.Itoa(p) + "._" + network + "." + name, nil
}

9
vendor/github.com/miekg/dns/tools.go generated vendored Normal file
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// +build tools
// We include our tool dependencies for `go generate` here to ensure they're
// properly tracked by the go tool. See the Go Wiki for the rationale behind this:
// https://github.com/golang/go/wiki/Modules#how-can-i-track-tool-dependencies-for-a-module.
package dns
import _ "golang.org/x/tools/go/packages"

456
vendor/github.com/miekg/dns/tsig.go generated vendored Normal file
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package dns
import (
"crypto/hmac"
"crypto/sha1"
"crypto/sha256"
"crypto/sha512"
"encoding/binary"
"encoding/hex"
"hash"
"strconv"
"strings"
"time"
)
// HMAC hashing codes. These are transmitted as domain names.
const (
HmacSHA1 = "hmac-sha1."
HmacSHA224 = "hmac-sha224."
HmacSHA256 = "hmac-sha256."
HmacSHA384 = "hmac-sha384."
HmacSHA512 = "hmac-sha512."
HmacMD5 = "hmac-md5.sig-alg.reg.int." // Deprecated: HmacMD5 is no longer supported.
)
// TsigProvider provides the API to plug-in a custom TSIG implementation.
type TsigProvider interface {
// Generate is passed the DNS message to be signed and the partial TSIG RR. It returns the signature and nil, otherwise an error.
Generate(msg []byte, t *TSIG) ([]byte, error)
// Verify is passed the DNS message to be verified and the TSIG RR. If the signature is valid it will return nil, otherwise an error.
Verify(msg []byte, t *TSIG) error
}
type tsigHMACProvider string
func (key tsigHMACProvider) Generate(msg []byte, t *TSIG) ([]byte, error) {
// If we barf here, the caller is to blame
rawsecret, err := fromBase64([]byte(key))
if err != nil {
return nil, err
}
var h hash.Hash
switch CanonicalName(t.Algorithm) {
case HmacSHA1:
h = hmac.New(sha1.New, rawsecret)
case HmacSHA224:
h = hmac.New(sha256.New224, rawsecret)
case HmacSHA256:
h = hmac.New(sha256.New, rawsecret)
case HmacSHA384:
h = hmac.New(sha512.New384, rawsecret)
case HmacSHA512:
h = hmac.New(sha512.New, rawsecret)
default:
return nil, ErrKeyAlg
}
h.Write(msg)
return h.Sum(nil), nil
}
func (key tsigHMACProvider) Verify(msg []byte, t *TSIG) error {
b, err := key.Generate(msg, t)
if err != nil {
return err
}
mac, err := hex.DecodeString(t.MAC)
if err != nil {
return err
}
if !hmac.Equal(b, mac) {
return ErrSig
}
return nil
}
type tsigSecretProvider map[string]string
func (ts tsigSecretProvider) Generate(msg []byte, t *TSIG) ([]byte, error) {
key, ok := ts[t.Hdr.Name]
if !ok {
return nil, ErrSecret
}
return tsigHMACProvider(key).Generate(msg, t)
}
func (ts tsigSecretProvider) Verify(msg []byte, t *TSIG) error {
key, ok := ts[t.Hdr.Name]
if !ok {
return ErrSecret
}
return tsigHMACProvider(key).Verify(msg, t)
}
// TSIG is the RR the holds the transaction signature of a message.
// See RFC 2845 and RFC 4635.
type TSIG struct {
Hdr RR_Header
Algorithm string `dns:"domain-name"`
TimeSigned uint64 `dns:"uint48"`
Fudge uint16
MACSize uint16
MAC string `dns:"size-hex:MACSize"`
OrigId uint16
Error uint16
OtherLen uint16
OtherData string `dns:"size-hex:OtherLen"`
}
// TSIG has no official presentation format, but this will suffice.
func (rr *TSIG) String() string {
s := "\n;; TSIG PSEUDOSECTION:\n; " // add another semi-colon to signify TSIG does not have a presentation format
s += rr.Hdr.String() +
" " + rr.Algorithm +
" " + tsigTimeToString(rr.TimeSigned) +
" " + strconv.Itoa(int(rr.Fudge)) +
" " + strconv.Itoa(int(rr.MACSize)) +
" " + strings.ToUpper(rr.MAC) +
" " + strconv.Itoa(int(rr.OrigId)) +
" " + strconv.Itoa(int(rr.Error)) + // BIND prints NOERROR
" " + strconv.Itoa(int(rr.OtherLen)) +
" " + rr.OtherData
return s
}
func (*TSIG) parse(c *zlexer, origin string) *ParseError {
return &ParseError{err: "TSIG records do not have a presentation format"}
}
// The following values must be put in wireformat, so that the MAC can be calculated.
// RFC 2845, section 3.4.2. TSIG Variables.
type tsigWireFmt struct {
// From RR_Header
Name string `dns:"domain-name"`
Class uint16
Ttl uint32
// Rdata of the TSIG
Algorithm string `dns:"domain-name"`
TimeSigned uint64 `dns:"uint48"`
Fudge uint16
// MACSize, MAC and OrigId excluded
Error uint16
OtherLen uint16
OtherData string `dns:"size-hex:OtherLen"`
}
// If we have the MAC use this type to convert it to wiredata. Section 3.4.3. Request MAC
type macWireFmt struct {
MACSize uint16
MAC string `dns:"size-hex:MACSize"`
}
// 3.3. Time values used in TSIG calculations
type timerWireFmt struct {
TimeSigned uint64 `dns:"uint48"`
Fudge uint16
}
// TsigGenerate fills out the TSIG record attached to the message.
// The message should contain
// a "stub" TSIG RR with the algorithm, key name (owner name of the RR),
// time fudge (defaults to 300 seconds) and the current time
// The TSIG MAC is saved in that Tsig RR.
// When TsigGenerate is called for the first time requestMAC is set to the empty string and
// timersOnly is false.
// If something goes wrong an error is returned, otherwise it is nil.
func TsigGenerate(m *Msg, secret, requestMAC string, timersOnly bool) ([]byte, string, error) {
return tsigGenerateProvider(m, tsigHMACProvider(secret), requestMAC, timersOnly)
}
func tsigGenerateProvider(m *Msg, provider TsigProvider, requestMAC string, timersOnly bool) ([]byte, string, error) {
if m.IsTsig() == nil {
panic("dns: TSIG not last RR in additional")
}
rr := m.Extra[len(m.Extra)-1].(*TSIG)
m.Extra = m.Extra[0 : len(m.Extra)-1] // kill the TSIG from the msg
mbuf, err := m.Pack()
if err != nil {
return nil, "", err
}
buf, err := tsigBuffer(mbuf, rr, requestMAC, timersOnly)
if err != nil {
return nil, "", err
}
t := new(TSIG)
// Copy all TSIG fields except MAC, its size, and time signed which are filled when signing.
*t = *rr
t.TimeSigned = 0
t.MAC = ""
t.MACSize = 0
// Sign unless there is a key or MAC validation error (RFC 8945 5.3.2)
if rr.Error != RcodeBadKey && rr.Error != RcodeBadSig {
mac, err := provider.Generate(buf, rr)
if err != nil {
return nil, "", err
}
t.TimeSigned = rr.TimeSigned
t.MAC = hex.EncodeToString(mac)
t.MACSize = uint16(len(t.MAC) / 2) // Size is half!
}
tbuf := make([]byte, Len(t))
off, err := PackRR(t, tbuf, 0, nil, false)
if err != nil {
return nil, "", err
}
mbuf = append(mbuf, tbuf[:off]...)
// Update the ArCount directly in the buffer.
binary.BigEndian.PutUint16(mbuf[10:], uint16(len(m.Extra)+1))
return mbuf, t.MAC, nil
}
// TsigVerify verifies the TSIG on a message.
// If the signature does not validate err contains the
// error, otherwise it is nil.
func TsigVerify(msg []byte, secret, requestMAC string, timersOnly bool) error {
return tsigVerify(msg, tsigHMACProvider(secret), requestMAC, timersOnly, uint64(time.Now().Unix()))
}
func tsigVerifyProvider(msg []byte, provider TsigProvider, requestMAC string, timersOnly bool) error {
return tsigVerify(msg, provider, requestMAC, timersOnly, uint64(time.Now().Unix()))
}
// actual implementation of TsigVerify, taking the current time ('now') as a parameter for the convenience of tests.
func tsigVerify(msg []byte, provider TsigProvider, requestMAC string, timersOnly bool, now uint64) error {
// Strip the TSIG from the incoming msg
stripped, tsig, err := stripTsig(msg)
if err != nil {
return err
}
buf, err := tsigBuffer(stripped, tsig, requestMAC, timersOnly)
if err != nil {
return err
}
if err := provider.Verify(buf, tsig); err != nil {
return err
}
// Fudge factor works both ways. A message can arrive before it was signed because
// of clock skew.
// We check this after verifying the signature, following draft-ietf-dnsop-rfc2845bis
// instead of RFC2845, in order to prevent a security vulnerability as reported in CVE-2017-3142/3143.
ti := now - tsig.TimeSigned
if now < tsig.TimeSigned {
ti = tsig.TimeSigned - now
}
if uint64(tsig.Fudge) < ti {
return ErrTime
}
return nil
}
// Create a wiredata buffer for the MAC calculation.
func tsigBuffer(msgbuf []byte, rr *TSIG, requestMAC string, timersOnly bool) ([]byte, error) {
var buf []byte
if rr.TimeSigned == 0 {
rr.TimeSigned = uint64(time.Now().Unix())
}
if rr.Fudge == 0 {
rr.Fudge = 300 // Standard (RFC) default.
}
// Replace message ID in header with original ID from TSIG
binary.BigEndian.PutUint16(msgbuf[0:2], rr.OrigId)
if requestMAC != "" {
m := new(macWireFmt)
m.MACSize = uint16(len(requestMAC) / 2)
m.MAC = requestMAC
buf = make([]byte, len(requestMAC)) // long enough
n, err := packMacWire(m, buf)
if err != nil {
return nil, err
}
buf = buf[:n]
}
tsigvar := make([]byte, DefaultMsgSize)
if timersOnly {
tsig := new(timerWireFmt)
tsig.TimeSigned = rr.TimeSigned
tsig.Fudge = rr.Fudge
n, err := packTimerWire(tsig, tsigvar)
if err != nil {
return nil, err
}
tsigvar = tsigvar[:n]
} else {
tsig := new(tsigWireFmt)
tsig.Name = CanonicalName(rr.Hdr.Name)
tsig.Class = ClassANY
tsig.Ttl = rr.Hdr.Ttl
tsig.Algorithm = CanonicalName(rr.Algorithm)
tsig.TimeSigned = rr.TimeSigned
tsig.Fudge = rr.Fudge
tsig.Error = rr.Error
tsig.OtherLen = rr.OtherLen
tsig.OtherData = rr.OtherData
n, err := packTsigWire(tsig, tsigvar)
if err != nil {
return nil, err
}
tsigvar = tsigvar[:n]
}
if requestMAC != "" {
x := append(buf, msgbuf...)
buf = append(x, tsigvar...)
} else {
buf = append(msgbuf, tsigvar...)
}
return buf, nil
}
// Strip the TSIG from the raw message.
func stripTsig(msg []byte) ([]byte, *TSIG, error) {
// Copied from msg.go's Unpack() Header, but modified.
var (
dh Header
err error
)
off, tsigoff := 0, 0
if dh, off, err = unpackMsgHdr(msg, off); err != nil {
return nil, nil, err
}
if dh.Arcount == 0 {
return nil, nil, ErrNoSig
}
// Rcode, see msg.go Unpack()
if int(dh.Bits&0xF) == RcodeNotAuth {
return nil, nil, ErrAuth
}
for i := 0; i < int(dh.Qdcount); i++ {
_, off, err = unpackQuestion(msg, off)
if err != nil {
return nil, nil, err
}
}
_, off, err = unpackRRslice(int(dh.Ancount), msg, off)
if err != nil {
return nil, nil, err
}
_, off, err = unpackRRslice(int(dh.Nscount), msg, off)
if err != nil {
return nil, nil, err
}
rr := new(TSIG)
var extra RR
for i := 0; i < int(dh.Arcount); i++ {
tsigoff = off
extra, off, err = UnpackRR(msg, off)
if err != nil {
return nil, nil, err
}
if extra.Header().Rrtype == TypeTSIG {
rr = extra.(*TSIG)
// Adjust Arcount.
arcount := binary.BigEndian.Uint16(msg[10:])
binary.BigEndian.PutUint16(msg[10:], arcount-1)
break
}
}
if rr == nil {
return nil, nil, ErrNoSig
}
return msg[:tsigoff], rr, nil
}
// Translate the TSIG time signed into a date. There is no
// need for RFC1982 calculations as this date is 48 bits.
func tsigTimeToString(t uint64) string {
ti := time.Unix(int64(t), 0).UTC()
return ti.Format("20060102150405")
}
func packTsigWire(tw *tsigWireFmt, msg []byte) (int, error) {
// copied from zmsg.go TSIG packing
// RR_Header
off, err := PackDomainName(tw.Name, msg, 0, nil, false)
if err != nil {
return off, err
}
off, err = packUint16(tw.Class, msg, off)
if err != nil {
return off, err
}
off, err = packUint32(tw.Ttl, msg, off)
if err != nil {
return off, err
}
off, err = PackDomainName(tw.Algorithm, msg, off, nil, false)
if err != nil {
return off, err
}
off, err = packUint48(tw.TimeSigned, msg, off)
if err != nil {
return off, err
}
off, err = packUint16(tw.Fudge, msg, off)
if err != nil {
return off, err
}
off, err = packUint16(tw.Error, msg, off)
if err != nil {
return off, err
}
off, err = packUint16(tw.OtherLen, msg, off)
if err != nil {
return off, err
}
off, err = packStringHex(tw.OtherData, msg, off)
if err != nil {
return off, err
}
return off, nil
}
func packMacWire(mw *macWireFmt, msg []byte) (int, error) {
off, err := packUint16(mw.MACSize, msg, 0)
if err != nil {
return off, err
}
off, err = packStringHex(mw.MAC, msg, off)
if err != nil {
return off, err
}
return off, nil
}
func packTimerWire(tw *timerWireFmt, msg []byte) (int, error) {
off, err := packUint48(tw.TimeSigned, msg, 0)
if err != nil {
return off, err
}
off, err = packUint16(tw.Fudge, msg, off)
if err != nil {
return off, err
}
return off, nil
}

1559
vendor/github.com/miekg/dns/types.go generated vendored Normal file

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102
vendor/github.com/miekg/dns/udp.go generated vendored Normal file
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// +build !windows
package dns
import (
"net"
"golang.org/x/net/ipv4"
"golang.org/x/net/ipv6"
)
// This is the required size of the OOB buffer to pass to ReadMsgUDP.
var udpOOBSize = func() int {
// We can't know whether we'll get an IPv4 control message or an
// IPv6 control message ahead of time. To get around this, we size
// the buffer equal to the largest of the two.
oob4 := ipv4.NewControlMessage(ipv4.FlagDst | ipv4.FlagInterface)
oob6 := ipv6.NewControlMessage(ipv6.FlagDst | ipv6.FlagInterface)
if len(oob4) > len(oob6) {
return len(oob4)
}
return len(oob6)
}()
// SessionUDP holds the remote address and the associated
// out-of-band data.
type SessionUDP struct {
raddr *net.UDPAddr
context []byte
}
// RemoteAddr returns the remote network address.
func (s *SessionUDP) RemoteAddr() net.Addr { return s.raddr }
// ReadFromSessionUDP acts just like net.UDPConn.ReadFrom(), but returns a session object instead of a
// net.UDPAddr.
func ReadFromSessionUDP(conn *net.UDPConn, b []byte) (int, *SessionUDP, error) {
oob := make([]byte, udpOOBSize)
n, oobn, _, raddr, err := conn.ReadMsgUDP(b, oob)
if err != nil {
return n, nil, err
}
return n, &SessionUDP{raddr, oob[:oobn]}, err
}
// WriteToSessionUDP acts just like net.UDPConn.WriteTo(), but uses a *SessionUDP instead of a net.Addr.
func WriteToSessionUDP(conn *net.UDPConn, b []byte, session *SessionUDP) (int, error) {
oob := correctSource(session.context)
n, _, err := conn.WriteMsgUDP(b, oob, session.raddr)
return n, err
}
func setUDPSocketOptions(conn *net.UDPConn) error {
// Try setting the flags for both families and ignore the errors unless they
// both error.
err6 := ipv6.NewPacketConn(conn).SetControlMessage(ipv6.FlagDst|ipv6.FlagInterface, true)
err4 := ipv4.NewPacketConn(conn).SetControlMessage(ipv4.FlagDst|ipv4.FlagInterface, true)
if err6 != nil && err4 != nil {
return err4
}
return nil
}
// parseDstFromOOB takes oob data and returns the destination IP.
func parseDstFromOOB(oob []byte) net.IP {
// Start with IPv6 and then fallback to IPv4
// TODO(fastest963): Figure out a way to prefer one or the other. Looking at
// the lvl of the header for a 0 or 41 isn't cross-platform.
cm6 := new(ipv6.ControlMessage)
if cm6.Parse(oob) == nil && cm6.Dst != nil {
return cm6.Dst
}
cm4 := new(ipv4.ControlMessage)
if cm4.Parse(oob) == nil && cm4.Dst != nil {
return cm4.Dst
}
return nil
}
// correctSource takes oob data and returns new oob data with the Src equal to the Dst
func correctSource(oob []byte) []byte {
dst := parseDstFromOOB(oob)
if dst == nil {
return nil
}
// If the dst is definitely an IPv6, then use ipv6's ControlMessage to
// respond otherwise use ipv4's because ipv6's marshal ignores ipv4
// addresses.
if dst.To4() == nil {
cm := new(ipv6.ControlMessage)
cm.Src = dst
oob = cm.Marshal()
} else {
cm := new(ipv4.ControlMessage)
cm.Src = dst
oob = cm.Marshal()
}
return oob
}

35
vendor/github.com/miekg/dns/udp_windows.go generated vendored Normal file
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// +build windows
package dns
import "net"
// SessionUDP holds the remote address
type SessionUDP struct {
raddr *net.UDPAddr
}
// RemoteAddr returns the remote network address.
func (s *SessionUDP) RemoteAddr() net.Addr { return s.raddr }
// ReadFromSessionUDP acts just like net.UDPConn.ReadFrom(), but returns a session object instead of a
// net.UDPAddr.
// TODO(fastest963): Once go1.10 is released, use ReadMsgUDP.
func ReadFromSessionUDP(conn *net.UDPConn, b []byte) (int, *SessionUDP, error) {
n, raddr, err := conn.ReadFrom(b)
if err != nil {
return n, nil, err
}
return n, &SessionUDP{raddr.(*net.UDPAddr)}, err
}
// WriteToSessionUDP acts just like net.UDPConn.WriteTo(), but uses a *SessionUDP instead of a net.Addr.
// TODO(fastest963): Once go1.10 is released, use WriteMsgUDP.
func WriteToSessionUDP(conn *net.UDPConn, b []byte, session *SessionUDP) (int, error) {
return conn.WriteTo(b, session.raddr)
}
// TODO(fastest963): Once go1.10 is released and we can use *MsgUDP methods
// use the standard method in udp.go for these.
func setUDPSocketOptions(*net.UDPConn) error { return nil }
func parseDstFromOOB([]byte, net.IP) net.IP { return nil }

112
vendor/github.com/miekg/dns/update.go generated vendored Normal file
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package dns
// NameUsed sets the RRs in the prereq section to
// "Name is in use" RRs. RFC 2136 section 2.4.4.
func (u *Msg) NameUsed(rr []RR) {
if u.Answer == nil {
u.Answer = make([]RR, 0, len(rr))
}
for _, r := range rr {
u.Answer = append(u.Answer, &ANY{Hdr: RR_Header{Name: r.Header().Name, Ttl: 0, Rrtype: TypeANY, Class: ClassANY}})
}
}
// NameNotUsed sets the RRs in the prereq section to
// "Name is in not use" RRs. RFC 2136 section 2.4.5.
func (u *Msg) NameNotUsed(rr []RR) {
if u.Answer == nil {
u.Answer = make([]RR, 0, len(rr))
}
for _, r := range rr {
u.Answer = append(u.Answer, &ANY{Hdr: RR_Header{Name: r.Header().Name, Ttl: 0, Rrtype: TypeANY, Class: ClassNONE}})
}
}
// Used sets the RRs in the prereq section to
// "RRset exists (value dependent -- with rdata)" RRs. RFC 2136 section 2.4.2.
func (u *Msg) Used(rr []RR) {
if len(u.Question) == 0 {
panic("dns: empty question section")
}
if u.Answer == nil {
u.Answer = make([]RR, 0, len(rr))
}
for _, r := range rr {
hdr := r.Header()
hdr.Class = u.Question[0].Qclass
hdr.Ttl = 0
u.Answer = append(u.Answer, r)
}
}
// RRsetUsed sets the RRs in the prereq section to
// "RRset exists (value independent -- no rdata)" RRs. RFC 2136 section 2.4.1.
func (u *Msg) RRsetUsed(rr []RR) {
if u.Answer == nil {
u.Answer = make([]RR, 0, len(rr))
}
for _, r := range rr {
h := r.Header()
u.Answer = append(u.Answer, &ANY{Hdr: RR_Header{Name: h.Name, Ttl: 0, Rrtype: h.Rrtype, Class: ClassANY}})
}
}
// RRsetNotUsed sets the RRs in the prereq section to
// "RRset does not exist" RRs. RFC 2136 section 2.4.3.
func (u *Msg) RRsetNotUsed(rr []RR) {
if u.Answer == nil {
u.Answer = make([]RR, 0, len(rr))
}
for _, r := range rr {
h := r.Header()
u.Answer = append(u.Answer, &ANY{Hdr: RR_Header{Name: h.Name, Ttl: 0, Rrtype: h.Rrtype, Class: ClassNONE}})
}
}
// Insert creates a dynamic update packet that adds an complete RRset, see RFC 2136 section 2.5.1.
func (u *Msg) Insert(rr []RR) {
if len(u.Question) == 0 {
panic("dns: empty question section")
}
if u.Ns == nil {
u.Ns = make([]RR, 0, len(rr))
}
for _, r := range rr {
r.Header().Class = u.Question[0].Qclass
u.Ns = append(u.Ns, r)
}
}
// RemoveRRset creates a dynamic update packet that deletes an RRset, see RFC 2136 section 2.5.2.
func (u *Msg) RemoveRRset(rr []RR) {
if u.Ns == nil {
u.Ns = make([]RR, 0, len(rr))
}
for _, r := range rr {
h := r.Header()
u.Ns = append(u.Ns, &ANY{Hdr: RR_Header{Name: h.Name, Ttl: 0, Rrtype: h.Rrtype, Class: ClassANY}})
}
}
// RemoveName creates a dynamic update packet that deletes all RRsets of a name, see RFC 2136 section 2.5.3
func (u *Msg) RemoveName(rr []RR) {
if u.Ns == nil {
u.Ns = make([]RR, 0, len(rr))
}
for _, r := range rr {
u.Ns = append(u.Ns, &ANY{Hdr: RR_Header{Name: r.Header().Name, Ttl: 0, Rrtype: TypeANY, Class: ClassANY}})
}
}
// Remove creates a dynamic update packet deletes RR from a RRSset, see RFC 2136 section 2.5.4
func (u *Msg) Remove(rr []RR) {
if u.Ns == nil {
u.Ns = make([]RR, 0, len(rr))
}
for _, r := range rr {
h := r.Header()
h.Class = ClassNONE
h.Ttl = 0
u.Ns = append(u.Ns, r)
}
}

15
vendor/github.com/miekg/dns/version.go generated vendored Normal file
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@ -0,0 +1,15 @@
package dns
import "fmt"
// Version is current version of this library.
var Version = v{1, 1, 49}
// v holds the version of this library.
type v struct {
Major, Minor, Patch int
}
func (v v) String() string {
return fmt.Sprintf("%d.%d.%d", v.Major, v.Minor, v.Patch)
}

271
vendor/github.com/miekg/dns/xfr.go generated vendored Normal file
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@ -0,0 +1,271 @@
package dns
import (
"fmt"
"time"
)
// Envelope is used when doing a zone transfer with a remote server.
type Envelope struct {
RR []RR // The set of RRs in the answer section of the xfr reply message.
Error error // If something went wrong, this contains the error.
}
// A Transfer defines parameters that are used during a zone transfer.
type Transfer struct {
*Conn
DialTimeout time.Duration // net.DialTimeout, defaults to 2 seconds
ReadTimeout time.Duration // net.Conn.SetReadTimeout value for connections, defaults to 2 seconds
WriteTimeout time.Duration // net.Conn.SetWriteTimeout value for connections, defaults to 2 seconds
TsigProvider TsigProvider // An implementation of the TsigProvider interface. If defined it replaces TsigSecret and is used for all TSIG operations.
TsigSecret map[string]string // Secret(s) for Tsig map[<zonename>]<base64 secret>, zonename must be in canonical form (lowercase, fqdn, see RFC 4034 Section 6.2)
tsigTimersOnly bool
}
func (t *Transfer) tsigProvider() TsigProvider {
if t.TsigProvider != nil {
return t.TsigProvider
}
if t.TsigSecret != nil {
return tsigSecretProvider(t.TsigSecret)
}
return nil
}
// TODO: Think we need to away to stop the transfer
// In performs an incoming transfer with the server in a.
// If you would like to set the source IP, or some other attribute
// of a Dialer for a Transfer, you can do so by specifying the attributes
// in the Transfer.Conn:
//
// d := net.Dialer{LocalAddr: transfer_source}
// con, err := d.Dial("tcp", master)
// dnscon := &dns.Conn{Conn:con}
// transfer = &dns.Transfer{Conn: dnscon}
// channel, err := transfer.In(message, master)
//
func (t *Transfer) In(q *Msg, a string) (env chan *Envelope, err error) {
switch q.Question[0].Qtype {
case TypeAXFR, TypeIXFR:
default:
return nil, &Error{"unsupported question type"}
}
timeout := dnsTimeout
if t.DialTimeout != 0 {
timeout = t.DialTimeout
}
if t.Conn == nil {
t.Conn, err = DialTimeout("tcp", a, timeout)
if err != nil {
return nil, err
}
}
if err := t.WriteMsg(q); err != nil {
return nil, err
}
env = make(chan *Envelope)
switch q.Question[0].Qtype {
case TypeAXFR:
go t.inAxfr(q, env)
case TypeIXFR:
go t.inIxfr(q, env)
}
return env, nil
}
func (t *Transfer) inAxfr(q *Msg, c chan *Envelope) {
first := true
defer t.Close()
defer close(c)
timeout := dnsTimeout
if t.ReadTimeout != 0 {
timeout = t.ReadTimeout
}
for {
t.Conn.SetReadDeadline(time.Now().Add(timeout))
in, err := t.ReadMsg()
if err != nil {
c <- &Envelope{nil, err}
return
}
if q.Id != in.Id {
c <- &Envelope{in.Answer, ErrId}
return
}
if first {
if in.Rcode != RcodeSuccess {
c <- &Envelope{in.Answer, &Error{err: fmt.Sprintf(errXFR, in.Rcode)}}
return
}
if !isSOAFirst(in) {
c <- &Envelope{in.Answer, ErrSoa}
return
}
first = !first
// only one answer that is SOA, receive more
if len(in.Answer) == 1 {
t.tsigTimersOnly = true
c <- &Envelope{in.Answer, nil}
continue
}
}
if !first {
t.tsigTimersOnly = true // Subsequent envelopes use this.
if isSOALast(in) {
c <- &Envelope{in.Answer, nil}
return
}
c <- &Envelope{in.Answer, nil}
}
}
}
func (t *Transfer) inIxfr(q *Msg, c chan *Envelope) {
var serial uint32 // The first serial seen is the current server serial
axfr := true
n := 0
qser := q.Ns[0].(*SOA).Serial
defer t.Close()
defer close(c)
timeout := dnsTimeout
if t.ReadTimeout != 0 {
timeout = t.ReadTimeout
}
for {
t.SetReadDeadline(time.Now().Add(timeout))
in, err := t.ReadMsg()
if err != nil {
c <- &Envelope{nil, err}
return
}
if q.Id != in.Id {
c <- &Envelope{in.Answer, ErrId}
return
}
if in.Rcode != RcodeSuccess {
c <- &Envelope{in.Answer, &Error{err: fmt.Sprintf(errXFR, in.Rcode)}}
return
}
if n == 0 {
// Check if the returned answer is ok
if !isSOAFirst(in) {
c <- &Envelope{in.Answer, ErrSoa}
return
}
// This serial is important
serial = in.Answer[0].(*SOA).Serial
// Check if there are no changes in zone
if qser >= serial {
c <- &Envelope{in.Answer, nil}
return
}
}
// Now we need to check each message for SOA records, to see what we need to do
t.tsigTimersOnly = true
for _, rr := range in.Answer {
if v, ok := rr.(*SOA); ok {
if v.Serial == serial {
n++
// quit if it's a full axfr or the the servers' SOA is repeated the third time
if axfr && n == 2 || n == 3 {
c <- &Envelope{in.Answer, nil}
return
}
} else if axfr {
// it's an ixfr
axfr = false
}
}
}
c <- &Envelope{in.Answer, nil}
}
}
// Out performs an outgoing transfer with the client connecting in w.
// Basic use pattern:
//
// ch := make(chan *dns.Envelope)
// tr := new(dns.Transfer)
// var wg sync.WaitGroup
// go func() {
// tr.Out(w, r, ch)
// wg.Done()
// }()
// ch <- &dns.Envelope{RR: []dns.RR{soa, rr1, rr2, rr3, soa}}
// close(ch)
// wg.Wait() // wait until everything is written out
// w.Close() // close connection
//
// The server is responsible for sending the correct sequence of RRs through the channel ch.
func (t *Transfer) Out(w ResponseWriter, q *Msg, ch chan *Envelope) error {
for x := range ch {
r := new(Msg)
// Compress?
r.SetReply(q)
r.Authoritative = true
// assume it fits TODO(miek): fix
r.Answer = append(r.Answer, x.RR...)
if tsig := q.IsTsig(); tsig != nil && w.TsigStatus() == nil {
r.SetTsig(tsig.Hdr.Name, tsig.Algorithm, tsig.Fudge, time.Now().Unix())
}
if err := w.WriteMsg(r); err != nil {
return err
}
w.TsigTimersOnly(true)
}
return nil
}
// ReadMsg reads a message from the transfer connection t.
func (t *Transfer) ReadMsg() (*Msg, error) {
m := new(Msg)
p := make([]byte, MaxMsgSize)
n, err := t.Read(p)
if err != nil && n == 0 {
return nil, err
}
p = p[:n]
if err := m.Unpack(p); err != nil {
return nil, err
}
if ts, tp := m.IsTsig(), t.tsigProvider(); ts != nil && tp != nil {
// Need to work on the original message p, as that was used to calculate the tsig.
err = tsigVerifyProvider(p, tp, t.tsigRequestMAC, t.tsigTimersOnly)
t.tsigRequestMAC = ts.MAC
}
return m, err
}
// WriteMsg writes a message through the transfer connection t.
func (t *Transfer) WriteMsg(m *Msg) (err error) {
var out []byte
if ts, tp := m.IsTsig(), t.tsigProvider(); ts != nil && tp != nil {
out, t.tsigRequestMAC, err = tsigGenerateProvider(m, tp, t.tsigRequestMAC, t.tsigTimersOnly)
} else {
out, err = m.Pack()
}
if err != nil {
return err
}
_, err = t.Write(out)
return err
}
func isSOAFirst(in *Msg) bool {
return len(in.Answer) > 0 &&
in.Answer[0].Header().Rrtype == TypeSOA
}
func isSOALast(in *Msg) bool {
return len(in.Answer) > 0 &&
in.Answer[len(in.Answer)-1].Header().Rrtype == TypeSOA
}
const errXFR = "bad xfr rcode: %d"

1340
vendor/github.com/miekg/dns/zduplicate.go generated vendored Normal file

File diff suppressed because it is too large Load diff

2875
vendor/github.com/miekg/dns/zmsg.go generated vendored Normal file

File diff suppressed because it is too large Load diff

952
vendor/github.com/miekg/dns/ztypes.go generated vendored Normal file
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@ -0,0 +1,952 @@
// Code generated by "go run types_generate.go"; DO NOT EDIT.
package dns
import (
"encoding/base64"
"net"
)
// TypeToRR is a map of constructors for each RR type.
var TypeToRR = map[uint16]func() RR{
TypeA: func() RR { return new(A) },
TypeAAAA: func() RR { return new(AAAA) },
TypeAFSDB: func() RR { return new(AFSDB) },
TypeANY: func() RR { return new(ANY) },
TypeAPL: func() RR { return new(APL) },
TypeAVC: func() RR { return new(AVC) },
TypeCAA: func() RR { return new(CAA) },
TypeCDNSKEY: func() RR { return new(CDNSKEY) },
TypeCDS: func() RR { return new(CDS) },
TypeCERT: func() RR { return new(CERT) },
TypeCNAME: func() RR { return new(CNAME) },
TypeCSYNC: func() RR { return new(CSYNC) },
TypeDHCID: func() RR { return new(DHCID) },
TypeDLV: func() RR { return new(DLV) },
TypeDNAME: func() RR { return new(DNAME) },
TypeDNSKEY: func() RR { return new(DNSKEY) },
TypeDS: func() RR { return new(DS) },
TypeEID: func() RR { return new(EID) },
TypeEUI48: func() RR { return new(EUI48) },
TypeEUI64: func() RR { return new(EUI64) },
TypeGID: func() RR { return new(GID) },
TypeGPOS: func() RR { return new(GPOS) },
TypeHINFO: func() RR { return new(HINFO) },
TypeHIP: func() RR { return new(HIP) },
TypeHTTPS: func() RR { return new(HTTPS) },
TypeKEY: func() RR { return new(KEY) },
TypeKX: func() RR { return new(KX) },
TypeL32: func() RR { return new(L32) },
TypeL64: func() RR { return new(L64) },
TypeLOC: func() RR { return new(LOC) },
TypeLP: func() RR { return new(LP) },
TypeMB: func() RR { return new(MB) },
TypeMD: func() RR { return new(MD) },
TypeMF: func() RR { return new(MF) },
TypeMG: func() RR { return new(MG) },
TypeMINFO: func() RR { return new(MINFO) },
TypeMR: func() RR { return new(MR) },
TypeMX: func() RR { return new(MX) },
TypeNAPTR: func() RR { return new(NAPTR) },
TypeNID: func() RR { return new(NID) },
TypeNIMLOC: func() RR { return new(NIMLOC) },
TypeNINFO: func() RR { return new(NINFO) },
TypeNS: func() RR { return new(NS) },
TypeNSAPPTR: func() RR { return new(NSAPPTR) },
TypeNSEC: func() RR { return new(NSEC) },
TypeNSEC3: func() RR { return new(NSEC3) },
TypeNSEC3PARAM: func() RR { return new(NSEC3PARAM) },
TypeNULL: func() RR { return new(NULL) },
TypeOPENPGPKEY: func() RR { return new(OPENPGPKEY) },
TypeOPT: func() RR { return new(OPT) },
TypePTR: func() RR { return new(PTR) },
TypePX: func() RR { return new(PX) },
TypeRKEY: func() RR { return new(RKEY) },
TypeRP: func() RR { return new(RP) },
TypeRRSIG: func() RR { return new(RRSIG) },
TypeRT: func() RR { return new(RT) },
TypeSIG: func() RR { return new(SIG) },
TypeSMIMEA: func() RR { return new(SMIMEA) },
TypeSOA: func() RR { return new(SOA) },
TypeSPF: func() RR { return new(SPF) },
TypeSRV: func() RR { return new(SRV) },
TypeSSHFP: func() RR { return new(SSHFP) },
TypeSVCB: func() RR { return new(SVCB) },
TypeTA: func() RR { return new(TA) },
TypeTALINK: func() RR { return new(TALINK) },
TypeTKEY: func() RR { return new(TKEY) },
TypeTLSA: func() RR { return new(TLSA) },
TypeTSIG: func() RR { return new(TSIG) },
TypeTXT: func() RR { return new(TXT) },
TypeUID: func() RR { return new(UID) },
TypeUINFO: func() RR { return new(UINFO) },
TypeURI: func() RR { return new(URI) },
TypeX25: func() RR { return new(X25) },
TypeZONEMD: func() RR { return new(ZONEMD) },
}
// TypeToString is a map of strings for each RR type.
var TypeToString = map[uint16]string{
TypeA: "A",
TypeAAAA: "AAAA",
TypeAFSDB: "AFSDB",
TypeANY: "ANY",
TypeAPL: "APL",
TypeATMA: "ATMA",
TypeAVC: "AVC",
TypeAXFR: "AXFR",
TypeCAA: "CAA",
TypeCDNSKEY: "CDNSKEY",
TypeCDS: "CDS",
TypeCERT: "CERT",
TypeCNAME: "CNAME",
TypeCSYNC: "CSYNC",
TypeDHCID: "DHCID",
TypeDLV: "DLV",
TypeDNAME: "DNAME",
TypeDNSKEY: "DNSKEY",
TypeDS: "DS",
TypeEID: "EID",
TypeEUI48: "EUI48",
TypeEUI64: "EUI64",
TypeGID: "GID",
TypeGPOS: "GPOS",
TypeHINFO: "HINFO",
TypeHIP: "HIP",
TypeHTTPS: "HTTPS",
TypeISDN: "ISDN",
TypeIXFR: "IXFR",
TypeKEY: "KEY",
TypeKX: "KX",
TypeL32: "L32",
TypeL64: "L64",
TypeLOC: "LOC",
TypeLP: "LP",
TypeMAILA: "MAILA",
TypeMAILB: "MAILB",
TypeMB: "MB",
TypeMD: "MD",
TypeMF: "MF",
TypeMG: "MG",
TypeMINFO: "MINFO",
TypeMR: "MR",
TypeMX: "MX",
TypeNAPTR: "NAPTR",
TypeNID: "NID",
TypeNIMLOC: "NIMLOC",
TypeNINFO: "NINFO",
TypeNS: "NS",
TypeNSEC: "NSEC",
TypeNSEC3: "NSEC3",
TypeNSEC3PARAM: "NSEC3PARAM",
TypeNULL: "NULL",
TypeNXT: "NXT",
TypeNone: "None",
TypeOPENPGPKEY: "OPENPGPKEY",
TypeOPT: "OPT",
TypePTR: "PTR",
TypePX: "PX",
TypeRKEY: "RKEY",
TypeRP: "RP",
TypeRRSIG: "RRSIG",
TypeRT: "RT",
TypeReserved: "Reserved",
TypeSIG: "SIG",
TypeSMIMEA: "SMIMEA",
TypeSOA: "SOA",
TypeSPF: "SPF",
TypeSRV: "SRV",
TypeSSHFP: "SSHFP",
TypeSVCB: "SVCB",
TypeTA: "TA",
TypeTALINK: "TALINK",
TypeTKEY: "TKEY",
TypeTLSA: "TLSA",
TypeTSIG: "TSIG",
TypeTXT: "TXT",
TypeUID: "UID",
TypeUINFO: "UINFO",
TypeUNSPEC: "UNSPEC",
TypeURI: "URI",
TypeX25: "X25",
TypeZONEMD: "ZONEMD",
TypeNSAPPTR: "NSAP-PTR",
}
func (rr *A) Header() *RR_Header { return &rr.Hdr }
func (rr *AAAA) Header() *RR_Header { return &rr.Hdr }
func (rr *AFSDB) Header() *RR_Header { return &rr.Hdr }
func (rr *ANY) Header() *RR_Header { return &rr.Hdr }
func (rr *APL) Header() *RR_Header { return &rr.Hdr }
func (rr *AVC) Header() *RR_Header { return &rr.Hdr }
func (rr *CAA) Header() *RR_Header { return &rr.Hdr }
func (rr *CDNSKEY) Header() *RR_Header { return &rr.Hdr }
func (rr *CDS) Header() *RR_Header { return &rr.Hdr }
func (rr *CERT) Header() *RR_Header { return &rr.Hdr }
func (rr *CNAME) Header() *RR_Header { return &rr.Hdr }
func (rr *CSYNC) Header() *RR_Header { return &rr.Hdr }
func (rr *DHCID) Header() *RR_Header { return &rr.Hdr }
func (rr *DLV) Header() *RR_Header { return &rr.Hdr }
func (rr *DNAME) Header() *RR_Header { return &rr.Hdr }
func (rr *DNSKEY) Header() *RR_Header { return &rr.Hdr }
func (rr *DS) Header() *RR_Header { return &rr.Hdr }
func (rr *EID) Header() *RR_Header { return &rr.Hdr }
func (rr *EUI48) Header() *RR_Header { return &rr.Hdr }
func (rr *EUI64) Header() *RR_Header { return &rr.Hdr }
func (rr *GID) Header() *RR_Header { return &rr.Hdr }
func (rr *GPOS) Header() *RR_Header { return &rr.Hdr }
func (rr *HINFO) Header() *RR_Header { return &rr.Hdr }
func (rr *HIP) Header() *RR_Header { return &rr.Hdr }
func (rr *HTTPS) Header() *RR_Header { return &rr.Hdr }
func (rr *KEY) Header() *RR_Header { return &rr.Hdr }
func (rr *KX) Header() *RR_Header { return &rr.Hdr }
func (rr *L32) Header() *RR_Header { return &rr.Hdr }
func (rr *L64) Header() *RR_Header { return &rr.Hdr }
func (rr *LOC) Header() *RR_Header { return &rr.Hdr }
func (rr *LP) Header() *RR_Header { return &rr.Hdr }
func (rr *MB) Header() *RR_Header { return &rr.Hdr }
func (rr *MD) Header() *RR_Header { return &rr.Hdr }
func (rr *MF) Header() *RR_Header { return &rr.Hdr }
func (rr *MG) Header() *RR_Header { return &rr.Hdr }
func (rr *MINFO) Header() *RR_Header { return &rr.Hdr }
func (rr *MR) Header() *RR_Header { return &rr.Hdr }
func (rr *MX) Header() *RR_Header { return &rr.Hdr }
func (rr *NAPTR) Header() *RR_Header { return &rr.Hdr }
func (rr *NID) Header() *RR_Header { return &rr.Hdr }
func (rr *NIMLOC) Header() *RR_Header { return &rr.Hdr }
func (rr *NINFO) Header() *RR_Header { return &rr.Hdr }
func (rr *NS) Header() *RR_Header { return &rr.Hdr }
func (rr *NSAPPTR) Header() *RR_Header { return &rr.Hdr }
func (rr *NSEC) Header() *RR_Header { return &rr.Hdr }
func (rr *NSEC3) Header() *RR_Header { return &rr.Hdr }
func (rr *NSEC3PARAM) Header() *RR_Header { return &rr.Hdr }
func (rr *NULL) Header() *RR_Header { return &rr.Hdr }
func (rr *OPENPGPKEY) Header() *RR_Header { return &rr.Hdr }
func (rr *OPT) Header() *RR_Header { return &rr.Hdr }
func (rr *PTR) Header() *RR_Header { return &rr.Hdr }
func (rr *PX) Header() *RR_Header { return &rr.Hdr }
func (rr *RFC3597) Header() *RR_Header { return &rr.Hdr }
func (rr *RKEY) Header() *RR_Header { return &rr.Hdr }
func (rr *RP) Header() *RR_Header { return &rr.Hdr }
func (rr *RRSIG) Header() *RR_Header { return &rr.Hdr }
func (rr *RT) Header() *RR_Header { return &rr.Hdr }
func (rr *SIG) Header() *RR_Header { return &rr.Hdr }
func (rr *SMIMEA) Header() *RR_Header { return &rr.Hdr }
func (rr *SOA) Header() *RR_Header { return &rr.Hdr }
func (rr *SPF) Header() *RR_Header { return &rr.Hdr }
func (rr *SRV) Header() *RR_Header { return &rr.Hdr }
func (rr *SSHFP) Header() *RR_Header { return &rr.Hdr }
func (rr *SVCB) Header() *RR_Header { return &rr.Hdr }
func (rr *TA) Header() *RR_Header { return &rr.Hdr }
func (rr *TALINK) Header() *RR_Header { return &rr.Hdr }
func (rr *TKEY) Header() *RR_Header { return &rr.Hdr }
func (rr *TLSA) Header() *RR_Header { return &rr.Hdr }
func (rr *TSIG) Header() *RR_Header { return &rr.Hdr }
func (rr *TXT) Header() *RR_Header { return &rr.Hdr }
func (rr *UID) Header() *RR_Header { return &rr.Hdr }
func (rr *UINFO) Header() *RR_Header { return &rr.Hdr }
func (rr *URI) Header() *RR_Header { return &rr.Hdr }
func (rr *X25) Header() *RR_Header { return &rr.Hdr }
func (rr *ZONEMD) Header() *RR_Header { return &rr.Hdr }
// len() functions
func (rr *A) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
if len(rr.A) != 0 {
l += net.IPv4len
}
return l
}
func (rr *AAAA) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
if len(rr.AAAA) != 0 {
l += net.IPv6len
}
return l
}
func (rr *AFSDB) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 2 // Subtype
l += domainNameLen(rr.Hostname, off+l, compression, false)
return l
}
func (rr *ANY) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
return l
}
func (rr *APL) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
for _, x := range rr.Prefixes {
l += x.len()
}
return l
}
func (rr *AVC) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
for _, x := range rr.Txt {
l += len(x) + 1
}
return l
}
func (rr *CAA) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l++ // Flag
l += len(rr.Tag) + 1
l += len(rr.Value)
return l
}
func (rr *CERT) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 2 // Type
l += 2 // KeyTag
l++ // Algorithm
l += base64.StdEncoding.DecodedLen(len(rr.Certificate))
return l
}
func (rr *CNAME) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += domainNameLen(rr.Target, off+l, compression, true)
return l
}
func (rr *DHCID) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += base64.StdEncoding.DecodedLen(len(rr.Digest))
return l
}
func (rr *DNAME) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += domainNameLen(rr.Target, off+l, compression, false)
return l
}
func (rr *DNSKEY) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 2 // Flags
l++ // Protocol
l++ // Algorithm
l += base64.StdEncoding.DecodedLen(len(rr.PublicKey))
return l
}
func (rr *DS) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 2 // KeyTag
l++ // Algorithm
l++ // DigestType
l += len(rr.Digest) / 2
return l
}
func (rr *EID) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += len(rr.Endpoint) / 2
return l
}
func (rr *EUI48) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 6 // Address
return l
}
func (rr *EUI64) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 8 // Address
return l
}
func (rr *GID) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 4 // Gid
return l
}
func (rr *GPOS) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += len(rr.Longitude) + 1
l += len(rr.Latitude) + 1
l += len(rr.Altitude) + 1
return l
}
func (rr *HINFO) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += len(rr.Cpu) + 1
l += len(rr.Os) + 1
return l
}
func (rr *HIP) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l++ // HitLength
l++ // PublicKeyAlgorithm
l += 2 // PublicKeyLength
l += len(rr.Hit) / 2
l += base64.StdEncoding.DecodedLen(len(rr.PublicKey))
for _, x := range rr.RendezvousServers {
l += domainNameLen(x, off+l, compression, false)
}
return l
}
func (rr *KX) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 2 // Preference
l += domainNameLen(rr.Exchanger, off+l, compression, false)
return l
}
func (rr *L32) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 2 // Preference
if len(rr.Locator32) != 0 {
l += net.IPv4len
}
return l
}
func (rr *L64) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 2 // Preference
l += 8 // Locator64
return l
}
func (rr *LOC) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l++ // Version
l++ // Size
l++ // HorizPre
l++ // VertPre
l += 4 // Latitude
l += 4 // Longitude
l += 4 // Altitude
return l
}
func (rr *LP) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 2 // Preference
l += domainNameLen(rr.Fqdn, off+l, compression, false)
return l
}
func (rr *MB) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += domainNameLen(rr.Mb, off+l, compression, true)
return l
}
func (rr *MD) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += domainNameLen(rr.Md, off+l, compression, true)
return l
}
func (rr *MF) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += domainNameLen(rr.Mf, off+l, compression, true)
return l
}
func (rr *MG) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += domainNameLen(rr.Mg, off+l, compression, true)
return l
}
func (rr *MINFO) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += domainNameLen(rr.Rmail, off+l, compression, true)
l += domainNameLen(rr.Email, off+l, compression, true)
return l
}
func (rr *MR) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += domainNameLen(rr.Mr, off+l, compression, true)
return l
}
func (rr *MX) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 2 // Preference
l += domainNameLen(rr.Mx, off+l, compression, true)
return l
}
func (rr *NAPTR) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 2 // Order
l += 2 // Preference
l += len(rr.Flags) + 1
l += len(rr.Service) + 1
l += len(rr.Regexp) + 1
l += domainNameLen(rr.Replacement, off+l, compression, false)
return l
}
func (rr *NID) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 2 // Preference
l += 8 // NodeID
return l
}
func (rr *NIMLOC) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += len(rr.Locator) / 2
return l
}
func (rr *NINFO) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
for _, x := range rr.ZSData {
l += len(x) + 1
}
return l
}
func (rr *NS) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += domainNameLen(rr.Ns, off+l, compression, true)
return l
}
func (rr *NSAPPTR) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += domainNameLen(rr.Ptr, off+l, compression, false)
return l
}
func (rr *NSEC3PARAM) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l++ // Hash
l++ // Flags
l += 2 // Iterations
l++ // SaltLength
l += len(rr.Salt) / 2
return l
}
func (rr *NULL) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += len(rr.Data)
return l
}
func (rr *OPENPGPKEY) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += base64.StdEncoding.DecodedLen(len(rr.PublicKey))
return l
}
func (rr *PTR) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += domainNameLen(rr.Ptr, off+l, compression, true)
return l
}
func (rr *PX) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 2 // Preference
l += domainNameLen(rr.Map822, off+l, compression, false)
l += domainNameLen(rr.Mapx400, off+l, compression, false)
return l
}
func (rr *RFC3597) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += len(rr.Rdata) / 2
return l
}
func (rr *RKEY) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 2 // Flags
l++ // Protocol
l++ // Algorithm
l += base64.StdEncoding.DecodedLen(len(rr.PublicKey))
return l
}
func (rr *RP) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += domainNameLen(rr.Mbox, off+l, compression, false)
l += domainNameLen(rr.Txt, off+l, compression, false)
return l
}
func (rr *RRSIG) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 2 // TypeCovered
l++ // Algorithm
l++ // Labels
l += 4 // OrigTtl
l += 4 // Expiration
l += 4 // Inception
l += 2 // KeyTag
l += domainNameLen(rr.SignerName, off+l, compression, false)
l += base64.StdEncoding.DecodedLen(len(rr.Signature))
return l
}
func (rr *RT) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 2 // Preference
l += domainNameLen(rr.Host, off+l, compression, false)
return l
}
func (rr *SMIMEA) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l++ // Usage
l++ // Selector
l++ // MatchingType
l += len(rr.Certificate) / 2
return l
}
func (rr *SOA) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += domainNameLen(rr.Ns, off+l, compression, true)
l += domainNameLen(rr.Mbox, off+l, compression, true)
l += 4 // Serial
l += 4 // Refresh
l += 4 // Retry
l += 4 // Expire
l += 4 // Minttl
return l
}
func (rr *SPF) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
for _, x := range rr.Txt {
l += len(x) + 1
}
return l
}
func (rr *SRV) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 2 // Priority
l += 2 // Weight
l += 2 // Port
l += domainNameLen(rr.Target, off+l, compression, false)
return l
}
func (rr *SSHFP) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l++ // Algorithm
l++ // Type
l += len(rr.FingerPrint) / 2
return l
}
func (rr *SVCB) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 2 // Priority
l += domainNameLen(rr.Target, off+l, compression, false)
for _, x := range rr.Value {
l += 4 + int(x.len())
}
return l
}
func (rr *TA) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 2 // KeyTag
l++ // Algorithm
l++ // DigestType
l += len(rr.Digest) / 2
return l
}
func (rr *TALINK) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += domainNameLen(rr.PreviousName, off+l, compression, false)
l += domainNameLen(rr.NextName, off+l, compression, false)
return l
}
func (rr *TKEY) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += domainNameLen(rr.Algorithm, off+l, compression, false)
l += 4 // Inception
l += 4 // Expiration
l += 2 // Mode
l += 2 // Error
l += 2 // KeySize
l += len(rr.Key) / 2
l += 2 // OtherLen
l += len(rr.OtherData) / 2
return l
}
func (rr *TLSA) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l++ // Usage
l++ // Selector
l++ // MatchingType
l += len(rr.Certificate) / 2
return l
}
func (rr *TSIG) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += domainNameLen(rr.Algorithm, off+l, compression, false)
l += 6 // TimeSigned
l += 2 // Fudge
l += 2 // MACSize
l += len(rr.MAC) / 2
l += 2 // OrigId
l += 2 // Error
l += 2 // OtherLen
l += len(rr.OtherData) / 2
return l
}
func (rr *TXT) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
for _, x := range rr.Txt {
l += len(x) + 1
}
return l
}
func (rr *UID) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 4 // Uid
return l
}
func (rr *UINFO) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += len(rr.Uinfo) + 1
return l
}
func (rr *URI) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 2 // Priority
l += 2 // Weight
l += len(rr.Target)
return l
}
func (rr *X25) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += len(rr.PSDNAddress) + 1
return l
}
func (rr *ZONEMD) len(off int, compression map[string]struct{}) int {
l := rr.Hdr.len(off, compression)
l += 4 // Serial
l++ // Scheme
l++ // Hash
l += len(rr.Digest) / 2
return l
}
// copy() functions
func (rr *A) copy() RR {
return &A{rr.Hdr, copyIP(rr.A)}
}
func (rr *AAAA) copy() RR {
return &AAAA{rr.Hdr, copyIP(rr.AAAA)}
}
func (rr *AFSDB) copy() RR {
return &AFSDB{rr.Hdr, rr.Subtype, rr.Hostname}
}
func (rr *ANY) copy() RR {
return &ANY{rr.Hdr}
}
func (rr *APL) copy() RR {
Prefixes := make([]APLPrefix, len(rr.Prefixes))
for i, e := range rr.Prefixes {
Prefixes[i] = e.copy()
}
return &APL{rr.Hdr, Prefixes}
}
func (rr *AVC) copy() RR {
Txt := make([]string, len(rr.Txt))
copy(Txt, rr.Txt)
return &AVC{rr.Hdr, Txt}
}
func (rr *CAA) copy() RR {
return &CAA{rr.Hdr, rr.Flag, rr.Tag, rr.Value}
}
func (rr *CDNSKEY) copy() RR {
return &CDNSKEY{*rr.DNSKEY.copy().(*DNSKEY)}
}
func (rr *CDS) copy() RR {
return &CDS{*rr.DS.copy().(*DS)}
}
func (rr *CERT) copy() RR {
return &CERT{rr.Hdr, rr.Type, rr.KeyTag, rr.Algorithm, rr.Certificate}
}
func (rr *CNAME) copy() RR {
return &CNAME{rr.Hdr, rr.Target}
}
func (rr *CSYNC) copy() RR {
TypeBitMap := make([]uint16, len(rr.TypeBitMap))
copy(TypeBitMap, rr.TypeBitMap)
return &CSYNC{rr.Hdr, rr.Serial, rr.Flags, TypeBitMap}
}
func (rr *DHCID) copy() RR {
return &DHCID{rr.Hdr, rr.Digest}
}
func (rr *DLV) copy() RR {
return &DLV{*rr.DS.copy().(*DS)}
}
func (rr *DNAME) copy() RR {
return &DNAME{rr.Hdr, rr.Target}
}
func (rr *DNSKEY) copy() RR {
return &DNSKEY{rr.Hdr, rr.Flags, rr.Protocol, rr.Algorithm, rr.PublicKey}
}
func (rr *DS) copy() RR {
return &DS{rr.Hdr, rr.KeyTag, rr.Algorithm, rr.DigestType, rr.Digest}
}
func (rr *EID) copy() RR {
return &EID{rr.Hdr, rr.Endpoint}
}
func (rr *EUI48) copy() RR {
return &EUI48{rr.Hdr, rr.Address}
}
func (rr *EUI64) copy() RR {
return &EUI64{rr.Hdr, rr.Address}
}
func (rr *GID) copy() RR {
return &GID{rr.Hdr, rr.Gid}
}
func (rr *GPOS) copy() RR {
return &GPOS{rr.Hdr, rr.Longitude, rr.Latitude, rr.Altitude}
}
func (rr *HINFO) copy() RR {
return &HINFO{rr.Hdr, rr.Cpu, rr.Os}
}
func (rr *HIP) copy() RR {
RendezvousServers := make([]string, len(rr.RendezvousServers))
copy(RendezvousServers, rr.RendezvousServers)
return &HIP{rr.Hdr, rr.HitLength, rr.PublicKeyAlgorithm, rr.PublicKeyLength, rr.Hit, rr.PublicKey, RendezvousServers}
}
func (rr *HTTPS) copy() RR {
return &HTTPS{*rr.SVCB.copy().(*SVCB)}
}
func (rr *KEY) copy() RR {
return &KEY{*rr.DNSKEY.copy().(*DNSKEY)}
}
func (rr *KX) copy() RR {
return &KX{rr.Hdr, rr.Preference, rr.Exchanger}
}
func (rr *L32) copy() RR {
return &L32{rr.Hdr, rr.Preference, copyIP(rr.Locator32)}
}
func (rr *L64) copy() RR {
return &L64{rr.Hdr, rr.Preference, rr.Locator64}
}
func (rr *LOC) copy() RR {
return &LOC{rr.Hdr, rr.Version, rr.Size, rr.HorizPre, rr.VertPre, rr.Latitude, rr.Longitude, rr.Altitude}
}
func (rr *LP) copy() RR {
return &LP{rr.Hdr, rr.Preference, rr.Fqdn}
}
func (rr *MB) copy() RR {
return &MB{rr.Hdr, rr.Mb}
}
func (rr *MD) copy() RR {
return &MD{rr.Hdr, rr.Md}
}
func (rr *MF) copy() RR {
return &MF{rr.Hdr, rr.Mf}
}
func (rr *MG) copy() RR {
return &MG{rr.Hdr, rr.Mg}
}
func (rr *MINFO) copy() RR {
return &MINFO{rr.Hdr, rr.Rmail, rr.Email}
}
func (rr *MR) copy() RR {
return &MR{rr.Hdr, rr.Mr}
}
func (rr *MX) copy() RR {
return &MX{rr.Hdr, rr.Preference, rr.Mx}
}
func (rr *NAPTR) copy() RR {
return &NAPTR{rr.Hdr, rr.Order, rr.Preference, rr.Flags, rr.Service, rr.Regexp, rr.Replacement}
}
func (rr *NID) copy() RR {
return &NID{rr.Hdr, rr.Preference, rr.NodeID}
}
func (rr *NIMLOC) copy() RR {
return &NIMLOC{rr.Hdr, rr.Locator}
}
func (rr *NINFO) copy() RR {
ZSData := make([]string, len(rr.ZSData))
copy(ZSData, rr.ZSData)
return &NINFO{rr.Hdr, ZSData}
}
func (rr *NS) copy() RR {
return &NS{rr.Hdr, rr.Ns}
}
func (rr *NSAPPTR) copy() RR {
return &NSAPPTR{rr.Hdr, rr.Ptr}
}
func (rr *NSEC) copy() RR {
TypeBitMap := make([]uint16, len(rr.TypeBitMap))
copy(TypeBitMap, rr.TypeBitMap)
return &NSEC{rr.Hdr, rr.NextDomain, TypeBitMap}
}
func (rr *NSEC3) copy() RR {
TypeBitMap := make([]uint16, len(rr.TypeBitMap))
copy(TypeBitMap, rr.TypeBitMap)
return &NSEC3{rr.Hdr, rr.Hash, rr.Flags, rr.Iterations, rr.SaltLength, rr.Salt, rr.HashLength, rr.NextDomain, TypeBitMap}
}
func (rr *NSEC3PARAM) copy() RR {
return &NSEC3PARAM{rr.Hdr, rr.Hash, rr.Flags, rr.Iterations, rr.SaltLength, rr.Salt}
}
func (rr *NULL) copy() RR {
return &NULL{rr.Hdr, rr.Data}
}
func (rr *OPENPGPKEY) copy() RR {
return &OPENPGPKEY{rr.Hdr, rr.PublicKey}
}
func (rr *OPT) copy() RR {
Option := make([]EDNS0, len(rr.Option))
for i, e := range rr.Option {
Option[i] = e.copy()
}
return &OPT{rr.Hdr, Option}
}
func (rr *PTR) copy() RR {
return &PTR{rr.Hdr, rr.Ptr}
}
func (rr *PX) copy() RR {
return &PX{rr.Hdr, rr.Preference, rr.Map822, rr.Mapx400}
}
func (rr *RFC3597) copy() RR {
return &RFC3597{rr.Hdr, rr.Rdata}
}
func (rr *RKEY) copy() RR {
return &RKEY{rr.Hdr, rr.Flags, rr.Protocol, rr.Algorithm, rr.PublicKey}
}
func (rr *RP) copy() RR {
return &RP{rr.Hdr, rr.Mbox, rr.Txt}
}
func (rr *RRSIG) copy() RR {
return &RRSIG{rr.Hdr, rr.TypeCovered, rr.Algorithm, rr.Labels, rr.OrigTtl, rr.Expiration, rr.Inception, rr.KeyTag, rr.SignerName, rr.Signature}
}
func (rr *RT) copy() RR {
return &RT{rr.Hdr, rr.Preference, rr.Host}
}
func (rr *SIG) copy() RR {
return &SIG{*rr.RRSIG.copy().(*RRSIG)}
}
func (rr *SMIMEA) copy() RR {
return &SMIMEA{rr.Hdr, rr.Usage, rr.Selector, rr.MatchingType, rr.Certificate}
}
func (rr *SOA) copy() RR {
return &SOA{rr.Hdr, rr.Ns, rr.Mbox, rr.Serial, rr.Refresh, rr.Retry, rr.Expire, rr.Minttl}
}
func (rr *SPF) copy() RR {
Txt := make([]string, len(rr.Txt))
copy(Txt, rr.Txt)
return &SPF{rr.Hdr, Txt}
}
func (rr *SRV) copy() RR {
return &SRV{rr.Hdr, rr.Priority, rr.Weight, rr.Port, rr.Target}
}
func (rr *SSHFP) copy() RR {
return &SSHFP{rr.Hdr, rr.Algorithm, rr.Type, rr.FingerPrint}
}
func (rr *SVCB) copy() RR {
Value := make([]SVCBKeyValue, len(rr.Value))
for i, e := range rr.Value {
Value[i] = e.copy()
}
return &SVCB{rr.Hdr, rr.Priority, rr.Target, Value}
}
func (rr *TA) copy() RR {
return &TA{rr.Hdr, rr.KeyTag, rr.Algorithm, rr.DigestType, rr.Digest}
}
func (rr *TALINK) copy() RR {
return &TALINK{rr.Hdr, rr.PreviousName, rr.NextName}
}
func (rr *TKEY) copy() RR {
return &TKEY{rr.Hdr, rr.Algorithm, rr.Inception, rr.Expiration, rr.Mode, rr.Error, rr.KeySize, rr.Key, rr.OtherLen, rr.OtherData}
}
func (rr *TLSA) copy() RR {
return &TLSA{rr.Hdr, rr.Usage, rr.Selector, rr.MatchingType, rr.Certificate}
}
func (rr *TSIG) copy() RR {
return &TSIG{rr.Hdr, rr.Algorithm, rr.TimeSigned, rr.Fudge, rr.MACSize, rr.MAC, rr.OrigId, rr.Error, rr.OtherLen, rr.OtherData}
}
func (rr *TXT) copy() RR {
Txt := make([]string, len(rr.Txt))
copy(Txt, rr.Txt)
return &TXT{rr.Hdr, Txt}
}
func (rr *UID) copy() RR {
return &UID{rr.Hdr, rr.Uid}
}
func (rr *UINFO) copy() RR {
return &UINFO{rr.Hdr, rr.Uinfo}
}
func (rr *URI) copy() RR {
return &URI{rr.Hdr, rr.Priority, rr.Weight, rr.Target}
}
func (rr *X25) copy() RR {
return &X25{rr.Hdr, rr.PSDNAddress}
}
func (rr *ZONEMD) copy() RR {
return &ZONEMD{rr.Hdr, rr.Serial, rr.Scheme, rr.Hash, rr.Digest}
}

41
vendor/golang.org/x/net/bpf/asm.go generated vendored Normal file
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// Copyright 2016 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package bpf
import "fmt"
// Assemble converts insts into raw instructions suitable for loading
// into a BPF virtual machine.
//
// Currently, no optimization is attempted, the assembled program flow
// is exactly as provided.
func Assemble(insts []Instruction) ([]RawInstruction, error) {
ret := make([]RawInstruction, len(insts))
var err error
for i, inst := range insts {
ret[i], err = inst.Assemble()
if err != nil {
return nil, fmt.Errorf("assembling instruction %d: %s", i+1, err)
}
}
return ret, nil
}
// Disassemble attempts to parse raw back into
// Instructions. Unrecognized RawInstructions are assumed to be an
// extension not implemented by this package, and are passed through
// unchanged to the output. The allDecoded value reports whether insts
// contains no RawInstructions.
func Disassemble(raw []RawInstruction) (insts []Instruction, allDecoded bool) {
insts = make([]Instruction, len(raw))
allDecoded = true
for i, r := range raw {
insts[i] = r.Disassemble()
if _, ok := insts[i].(RawInstruction); ok {
allDecoded = false
}
}
return insts, allDecoded
}

222
vendor/golang.org/x/net/bpf/constants.go generated vendored Normal file
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// Copyright 2016 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package bpf
// A Register is a register of the BPF virtual machine.
type Register uint16
const (
// RegA is the accumulator register. RegA is always the
// destination register of ALU operations.
RegA Register = iota
// RegX is the indirection register, used by LoadIndirect
// operations.
RegX
)
// An ALUOp is an arithmetic or logic operation.
type ALUOp uint16
// ALU binary operation types.
const (
ALUOpAdd ALUOp = iota << 4
ALUOpSub
ALUOpMul
ALUOpDiv
ALUOpOr
ALUOpAnd
ALUOpShiftLeft
ALUOpShiftRight
aluOpNeg // Not exported because it's the only unary ALU operation, and gets its own instruction type.
ALUOpMod
ALUOpXor
)
// A JumpTest is a comparison operator used in conditional jumps.
type JumpTest uint16
// Supported operators for conditional jumps.
// K can be RegX for JumpIfX
const (
// K == A
JumpEqual JumpTest = iota
// K != A
JumpNotEqual
// K > A
JumpGreaterThan
// K < A
JumpLessThan
// K >= A
JumpGreaterOrEqual
// K <= A
JumpLessOrEqual
// K & A != 0
JumpBitsSet
// K & A == 0
JumpBitsNotSet
)
// An Extension is a function call provided by the kernel that
// performs advanced operations that are expensive or impossible
// within the BPF virtual machine.
//
// Extensions are only implemented by the Linux kernel.
//
// TODO: should we prune this list? Some of these extensions seem
// either broken or near-impossible to use correctly, whereas other
// (len, random, ifindex) are quite useful.
type Extension int
// Extension functions available in the Linux kernel.
const (
// extOffset is the negative maximum number of instructions used
// to load instructions by overloading the K argument.
extOffset = -0x1000
// ExtLen returns the length of the packet.
ExtLen Extension = 1
// ExtProto returns the packet's L3 protocol type.
ExtProto Extension = 0
// ExtType returns the packet's type (skb->pkt_type in the kernel)
//
// TODO: better documentation. How nice an API do we want to
// provide for these esoteric extensions?
ExtType Extension = 4
// ExtPayloadOffset returns the offset of the packet payload, or
// the first protocol header that the kernel does not know how to
// parse.
ExtPayloadOffset Extension = 52
// ExtInterfaceIndex returns the index of the interface on which
// the packet was received.
ExtInterfaceIndex Extension = 8
// ExtNetlinkAttr returns the netlink attribute of type X at
// offset A.
ExtNetlinkAttr Extension = 12
// ExtNetlinkAttrNested returns the nested netlink attribute of
// type X at offset A.
ExtNetlinkAttrNested Extension = 16
// ExtMark returns the packet's mark value.
ExtMark Extension = 20
// ExtQueue returns the packet's assigned hardware queue.
ExtQueue Extension = 24
// ExtLinkLayerType returns the packet's hardware address type
// (e.g. Ethernet, Infiniband).
ExtLinkLayerType Extension = 28
// ExtRXHash returns the packets receive hash.
//
// TODO: figure out what this rxhash actually is.
ExtRXHash Extension = 32
// ExtCPUID returns the ID of the CPU processing the current
// packet.
ExtCPUID Extension = 36
// ExtVLANTag returns the packet's VLAN tag.
ExtVLANTag Extension = 44
// ExtVLANTagPresent returns non-zero if the packet has a VLAN
// tag.
//
// TODO: I think this might be a lie: it reads bit 0x1000 of the
// VLAN header, which changed meaning in recent revisions of the
// spec - this extension may now return meaningless information.
ExtVLANTagPresent Extension = 48
// ExtVLANProto returns 0x8100 if the frame has a VLAN header,
// 0x88a8 if the frame has a "Q-in-Q" double VLAN header, or some
// other value if no VLAN information is present.
ExtVLANProto Extension = 60
// ExtRand returns a uniformly random uint32.
ExtRand Extension = 56
)
// The following gives names to various bit patterns used in opcode construction.
const (
opMaskCls uint16 = 0x7
// opClsLoad masks
opMaskLoadDest = 0x01
opMaskLoadWidth = 0x18
opMaskLoadMode = 0xe0
// opClsALU & opClsJump
opMaskOperand = 0x08
opMaskOperator = 0xf0
)
const (
// +---------------+-----------------+---+---+---+
// | AddrMode (3b) | LoadWidth (2b) | 0 | 0 | 0 |
// +---------------+-----------------+---+---+---+
opClsLoadA uint16 = iota
// +---------------+-----------------+---+---+---+
// | AddrMode (3b) | LoadWidth (2b) | 0 | 0 | 1 |
// +---------------+-----------------+---+---+---+
opClsLoadX
// +---+---+---+---+---+---+---+---+
// | 0 | 0 | 0 | 0 | 0 | 0 | 1 | 0 |
// +---+---+---+---+---+---+---+---+
opClsStoreA
// +---+---+---+---+---+---+---+---+
// | 0 | 0 | 0 | 0 | 0 | 0 | 1 | 1 |
// +---+---+---+---+---+---+---+---+
opClsStoreX
// +---------------+-----------------+---+---+---+
// | Operator (4b) | OperandSrc (1b) | 1 | 0 | 0 |
// +---------------+-----------------+---+---+---+
opClsALU
// +-----------------------------+---+---+---+---+
// | TestOperator (4b) | 0 | 1 | 0 | 1 |
// +-----------------------------+---+---+---+---+
opClsJump
// +---+-------------------------+---+---+---+---+
// | 0 | 0 | 0 | RetSrc (1b) | 0 | 1 | 1 | 0 |
// +---+-------------------------+---+---+---+---+
opClsReturn
// +---+-------------------------+---+---+---+---+
// | 0 | 0 | 0 | TXAorTAX (1b) | 0 | 1 | 1 | 1 |
// +---+-------------------------+---+---+---+---+
opClsMisc
)
const (
opAddrModeImmediate uint16 = iota << 5
opAddrModeAbsolute
opAddrModeIndirect
opAddrModeScratch
opAddrModePacketLen // actually an extension, not an addressing mode.
opAddrModeMemShift
)
const (
opLoadWidth4 uint16 = iota << 3
opLoadWidth2
opLoadWidth1
)
// Operand for ALU and Jump instructions
type opOperand uint16
// Supported operand sources.
const (
opOperandConstant opOperand = iota << 3
opOperandX
)
// An jumpOp is a conditional jump condition.
type jumpOp uint16
// Supported jump conditions.
const (
opJumpAlways jumpOp = iota << 4
opJumpEqual
opJumpGT
opJumpGE
opJumpSet
)
const (
opRetSrcConstant uint16 = iota << 4
opRetSrcA
)
const (
opMiscTAX = 0x00
opMiscTXA = 0x80
)

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// Copyright 2016 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
/*
Package bpf implements marshaling and unmarshaling of programs for the
Berkeley Packet Filter virtual machine, and provides a Go implementation
of the virtual machine.
BPF's main use is to specify a packet filter for network taps, so that
the kernel doesn't have to expensively copy every packet it sees to
userspace. However, it's been repurposed to other areas where running
user code in-kernel is needed. For example, Linux's seccomp uses BPF
to apply security policies to system calls. For simplicity, this
documentation refers only to packets, but other uses of BPF have their
own data payloads.
BPF programs run in a restricted virtual machine. It has almost no
access to kernel functions, and while conditional branches are
allowed, they can only jump forwards, to guarantee that there are no
infinite loops.
# The virtual machine
The BPF VM is an accumulator machine. Its main register, called
register A, is an implicit source and destination in all arithmetic
and logic operations. The machine also has 16 scratch registers for
temporary storage, and an indirection register (register X) for
indirect memory access. All registers are 32 bits wide.
Each run of a BPF program is given one packet, which is placed in the
VM's read-only "main memory". LoadAbsolute and LoadIndirect
instructions can fetch up to 32 bits at a time into register A for
examination.
The goal of a BPF program is to produce and return a verdict (uint32),
which tells the kernel what to do with the packet. In the context of
packet filtering, the returned value is the number of bytes of the
packet to forward to userspace, or 0 to ignore the packet. Other
contexts like seccomp define their own return values.
In order to simplify programs, attempts to read past the end of the
packet terminate the program execution with a verdict of 0 (ignore
packet). This means that the vast majority of BPF programs don't need
to do any explicit bounds checking.
In addition to the bytes of the packet, some BPF programs have access
to extensions, which are essentially calls to kernel utility
functions. Currently, the only extensions supported by this package
are the Linux packet filter extensions.
# Examples
This packet filter selects all ARP packets.
bpf.Assemble([]bpf.Instruction{
// Load "EtherType" field from the ethernet header.
bpf.LoadAbsolute{Off: 12, Size: 2},
// Skip over the next instruction if EtherType is not ARP.
bpf.JumpIf{Cond: bpf.JumpNotEqual, Val: 0x0806, SkipTrue: 1},
// Verdict is "send up to 4k of the packet to userspace."
bpf.RetConstant{Val: 4096},
// Verdict is "ignore packet."
bpf.RetConstant{Val: 0},
})
This packet filter captures a random 1% sample of traffic.
bpf.Assemble([]bpf.Instruction{
// Get a 32-bit random number from the Linux kernel.
bpf.LoadExtension{Num: bpf.ExtRand},
// 1% dice roll?
bpf.JumpIf{Cond: bpf.JumpLessThan, Val: 2^32/100, SkipFalse: 1},
// Capture.
bpf.RetConstant{Val: 4096},
// Ignore.
bpf.RetConstant{Val: 0},
})
*/
package bpf // import "golang.org/x/net/bpf"

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// Copyright 2016 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package bpf
import "fmt"
// An Instruction is one instruction executed by the BPF virtual
// machine.
type Instruction interface {
// Assemble assembles the Instruction into a RawInstruction.
Assemble() (RawInstruction, error)
}
// A RawInstruction is a raw BPF virtual machine instruction.
type RawInstruction struct {
// Operation to execute.
Op uint16
// For conditional jump instructions, the number of instructions
// to skip if the condition is true/false.
Jt uint8
Jf uint8
// Constant parameter. The meaning depends on the Op.
K uint32
}
// Assemble implements the Instruction Assemble method.
func (ri RawInstruction) Assemble() (RawInstruction, error) { return ri, nil }
// Disassemble parses ri into an Instruction and returns it. If ri is
// not recognized by this package, ri itself is returned.
func (ri RawInstruction) Disassemble() Instruction {
switch ri.Op & opMaskCls {
case opClsLoadA, opClsLoadX:
reg := Register(ri.Op & opMaskLoadDest)
sz := 0
switch ri.Op & opMaskLoadWidth {
case opLoadWidth4:
sz = 4
case opLoadWidth2:
sz = 2
case opLoadWidth1:
sz = 1
default:
return ri
}
switch ri.Op & opMaskLoadMode {
case opAddrModeImmediate:
if sz != 4 {
return ri
}
return LoadConstant{Dst: reg, Val: ri.K}
case opAddrModeScratch:
if sz != 4 || ri.K > 15 {
return ri
}
return LoadScratch{Dst: reg, N: int(ri.K)}
case opAddrModeAbsolute:
if ri.K > extOffset+0xffffffff {
return LoadExtension{Num: Extension(-extOffset + ri.K)}
}
return LoadAbsolute{Size: sz, Off: ri.K}
case opAddrModeIndirect:
return LoadIndirect{Size: sz, Off: ri.K}
case opAddrModePacketLen:
if sz != 4 {
return ri
}
return LoadExtension{Num: ExtLen}
case opAddrModeMemShift:
return LoadMemShift{Off: ri.K}
default:
return ri
}
case opClsStoreA:
if ri.Op != opClsStoreA || ri.K > 15 {
return ri
}
return StoreScratch{Src: RegA, N: int(ri.K)}
case opClsStoreX:
if ri.Op != opClsStoreX || ri.K > 15 {
return ri
}
return StoreScratch{Src: RegX, N: int(ri.K)}
case opClsALU:
switch op := ALUOp(ri.Op & opMaskOperator); op {
case ALUOpAdd, ALUOpSub, ALUOpMul, ALUOpDiv, ALUOpOr, ALUOpAnd, ALUOpShiftLeft, ALUOpShiftRight, ALUOpMod, ALUOpXor:
switch operand := opOperand(ri.Op & opMaskOperand); operand {
case opOperandX:
return ALUOpX{Op: op}
case opOperandConstant:
return ALUOpConstant{Op: op, Val: ri.K}
default:
return ri
}
case aluOpNeg:
return NegateA{}
default:
return ri
}
case opClsJump:
switch op := jumpOp(ri.Op & opMaskOperator); op {
case opJumpAlways:
return Jump{Skip: ri.K}
case opJumpEqual, opJumpGT, opJumpGE, opJumpSet:
cond, skipTrue, skipFalse := jumpOpToTest(op, ri.Jt, ri.Jf)
switch operand := opOperand(ri.Op & opMaskOperand); operand {
case opOperandX:
return JumpIfX{Cond: cond, SkipTrue: skipTrue, SkipFalse: skipFalse}
case opOperandConstant:
return JumpIf{Cond: cond, Val: ri.K, SkipTrue: skipTrue, SkipFalse: skipFalse}
default:
return ri
}
default:
return ri
}
case opClsReturn:
switch ri.Op {
case opClsReturn | opRetSrcA:
return RetA{}
case opClsReturn | opRetSrcConstant:
return RetConstant{Val: ri.K}
default:
return ri
}
case opClsMisc:
switch ri.Op {
case opClsMisc | opMiscTAX:
return TAX{}
case opClsMisc | opMiscTXA:
return TXA{}
default:
return ri
}
default:
panic("unreachable") // switch is exhaustive on the bit pattern
}
}
func jumpOpToTest(op jumpOp, skipTrue uint8, skipFalse uint8) (JumpTest, uint8, uint8) {
var test JumpTest
// Decode "fake" jump conditions that don't appear in machine code
// Ensures the Assemble -> Disassemble stage recreates the same instructions
// See https://github.com/golang/go/issues/18470
if skipTrue == 0 {
switch op {
case opJumpEqual:
test = JumpNotEqual
case opJumpGT:
test = JumpLessOrEqual
case opJumpGE:
test = JumpLessThan
case opJumpSet:
test = JumpBitsNotSet
}
return test, skipFalse, 0
}
switch op {
case opJumpEqual:
test = JumpEqual
case opJumpGT:
test = JumpGreaterThan
case opJumpGE:
test = JumpGreaterOrEqual
case opJumpSet:
test = JumpBitsSet
}
return test, skipTrue, skipFalse
}
// LoadConstant loads Val into register Dst.
type LoadConstant struct {
Dst Register
Val uint32
}
// Assemble implements the Instruction Assemble method.
func (a LoadConstant) Assemble() (RawInstruction, error) {
return assembleLoad(a.Dst, 4, opAddrModeImmediate, a.Val)
}
// String returns the instruction in assembler notation.
func (a LoadConstant) String() string {
switch a.Dst {
case RegA:
return fmt.Sprintf("ld #%d", a.Val)
case RegX:
return fmt.Sprintf("ldx #%d", a.Val)
default:
return fmt.Sprintf("unknown instruction: %#v", a)
}
}
// LoadScratch loads scratch[N] into register Dst.
type LoadScratch struct {
Dst Register
N int // 0-15
}
// Assemble implements the Instruction Assemble method.
func (a LoadScratch) Assemble() (RawInstruction, error) {
if a.N < 0 || a.N > 15 {
return RawInstruction{}, fmt.Errorf("invalid scratch slot %d", a.N)
}
return assembleLoad(a.Dst, 4, opAddrModeScratch, uint32(a.N))
}
// String returns the instruction in assembler notation.
func (a LoadScratch) String() string {
switch a.Dst {
case RegA:
return fmt.Sprintf("ld M[%d]", a.N)
case RegX:
return fmt.Sprintf("ldx M[%d]", a.N)
default:
return fmt.Sprintf("unknown instruction: %#v", a)
}
}
// LoadAbsolute loads packet[Off:Off+Size] as an integer value into
// register A.
type LoadAbsolute struct {
Off uint32
Size int // 1, 2 or 4
}
// Assemble implements the Instruction Assemble method.
func (a LoadAbsolute) Assemble() (RawInstruction, error) {
return assembleLoad(RegA, a.Size, opAddrModeAbsolute, a.Off)
}
// String returns the instruction in assembler notation.
func (a LoadAbsolute) String() string {
switch a.Size {
case 1: // byte
return fmt.Sprintf("ldb [%d]", a.Off)
case 2: // half word
return fmt.Sprintf("ldh [%d]", a.Off)
case 4: // word
if a.Off > extOffset+0xffffffff {
return LoadExtension{Num: Extension(a.Off + 0x1000)}.String()
}
return fmt.Sprintf("ld [%d]", a.Off)
default:
return fmt.Sprintf("unknown instruction: %#v", a)
}
}
// LoadIndirect loads packet[X+Off:X+Off+Size] as an integer value
// into register A.
type LoadIndirect struct {
Off uint32
Size int // 1, 2 or 4
}
// Assemble implements the Instruction Assemble method.
func (a LoadIndirect) Assemble() (RawInstruction, error) {
return assembleLoad(RegA, a.Size, opAddrModeIndirect, a.Off)
}
// String returns the instruction in assembler notation.
func (a LoadIndirect) String() string {
switch a.Size {
case 1: // byte
return fmt.Sprintf("ldb [x + %d]", a.Off)
case 2: // half word
return fmt.Sprintf("ldh [x + %d]", a.Off)
case 4: // word
return fmt.Sprintf("ld [x + %d]", a.Off)
default:
return fmt.Sprintf("unknown instruction: %#v", a)
}
}
// LoadMemShift multiplies the first 4 bits of the byte at packet[Off]
// by 4 and stores the result in register X.
//
// This instruction is mainly useful to load into X the length of an
// IPv4 packet header in a single instruction, rather than have to do
// the arithmetic on the header's first byte by hand.
type LoadMemShift struct {
Off uint32
}
// Assemble implements the Instruction Assemble method.
func (a LoadMemShift) Assemble() (RawInstruction, error) {
return assembleLoad(RegX, 1, opAddrModeMemShift, a.Off)
}
// String returns the instruction in assembler notation.
func (a LoadMemShift) String() string {
return fmt.Sprintf("ldx 4*([%d]&0xf)", a.Off)
}
// LoadExtension invokes a linux-specific extension and stores the
// result in register A.
type LoadExtension struct {
Num Extension
}
// Assemble implements the Instruction Assemble method.
func (a LoadExtension) Assemble() (RawInstruction, error) {
if a.Num == ExtLen {
return assembleLoad(RegA, 4, opAddrModePacketLen, 0)
}
return assembleLoad(RegA, 4, opAddrModeAbsolute, uint32(extOffset+a.Num))
}
// String returns the instruction in assembler notation.
func (a LoadExtension) String() string {
switch a.Num {
case ExtLen:
return "ld #len"
case ExtProto:
return "ld #proto"
case ExtType:
return "ld #type"
case ExtPayloadOffset:
return "ld #poff"
case ExtInterfaceIndex:
return "ld #ifidx"
case ExtNetlinkAttr:
return "ld #nla"
case ExtNetlinkAttrNested:
return "ld #nlan"
case ExtMark:
return "ld #mark"
case ExtQueue:
return "ld #queue"
case ExtLinkLayerType:
return "ld #hatype"
case ExtRXHash:
return "ld #rxhash"
case ExtCPUID:
return "ld #cpu"
case ExtVLANTag:
return "ld #vlan_tci"
case ExtVLANTagPresent:
return "ld #vlan_avail"
case ExtVLANProto:
return "ld #vlan_tpid"
case ExtRand:
return "ld #rand"
default:
return fmt.Sprintf("unknown instruction: %#v", a)
}
}
// StoreScratch stores register Src into scratch[N].
type StoreScratch struct {
Src Register
N int // 0-15
}
// Assemble implements the Instruction Assemble method.
func (a StoreScratch) Assemble() (RawInstruction, error) {
if a.N < 0 || a.N > 15 {
return RawInstruction{}, fmt.Errorf("invalid scratch slot %d", a.N)
}
var op uint16
switch a.Src {
case RegA:
op = opClsStoreA
case RegX:
op = opClsStoreX
default:
return RawInstruction{}, fmt.Errorf("invalid source register %v", a.Src)
}
return RawInstruction{
Op: op,
K: uint32(a.N),
}, nil
}
// String returns the instruction in assembler notation.
func (a StoreScratch) String() string {
switch a.Src {
case RegA:
return fmt.Sprintf("st M[%d]", a.N)
case RegX:
return fmt.Sprintf("stx M[%d]", a.N)
default:
return fmt.Sprintf("unknown instruction: %#v", a)
}
}
// ALUOpConstant executes A = A <Op> Val.
type ALUOpConstant struct {
Op ALUOp
Val uint32
}
// Assemble implements the Instruction Assemble method.
func (a ALUOpConstant) Assemble() (RawInstruction, error) {
return RawInstruction{
Op: opClsALU | uint16(opOperandConstant) | uint16(a.Op),
K: a.Val,
}, nil
}
// String returns the instruction in assembler notation.
func (a ALUOpConstant) String() string {
switch a.Op {
case ALUOpAdd:
return fmt.Sprintf("add #%d", a.Val)
case ALUOpSub:
return fmt.Sprintf("sub #%d", a.Val)
case ALUOpMul:
return fmt.Sprintf("mul #%d", a.Val)
case ALUOpDiv:
return fmt.Sprintf("div #%d", a.Val)
case ALUOpMod:
return fmt.Sprintf("mod #%d", a.Val)
case ALUOpAnd:
return fmt.Sprintf("and #%d", a.Val)
case ALUOpOr:
return fmt.Sprintf("or #%d", a.Val)
case ALUOpXor:
return fmt.Sprintf("xor #%d", a.Val)
case ALUOpShiftLeft:
return fmt.Sprintf("lsh #%d", a.Val)
case ALUOpShiftRight:
return fmt.Sprintf("rsh #%d", a.Val)
default:
return fmt.Sprintf("unknown instruction: %#v", a)
}
}
// ALUOpX executes A = A <Op> X
type ALUOpX struct {
Op ALUOp
}
// Assemble implements the Instruction Assemble method.
func (a ALUOpX) Assemble() (RawInstruction, error) {
return RawInstruction{
Op: opClsALU | uint16(opOperandX) | uint16(a.Op),
}, nil
}
// String returns the instruction in assembler notation.
func (a ALUOpX) String() string {
switch a.Op {
case ALUOpAdd:
return "add x"
case ALUOpSub:
return "sub x"
case ALUOpMul:
return "mul x"
case ALUOpDiv:
return "div x"
case ALUOpMod:
return "mod x"
case ALUOpAnd:
return "and x"
case ALUOpOr:
return "or x"
case ALUOpXor:
return "xor x"
case ALUOpShiftLeft:
return "lsh x"
case ALUOpShiftRight:
return "rsh x"
default:
return fmt.Sprintf("unknown instruction: %#v", a)
}
}
// NegateA executes A = -A.
type NegateA struct{}
// Assemble implements the Instruction Assemble method.
func (a NegateA) Assemble() (RawInstruction, error) {
return RawInstruction{
Op: opClsALU | uint16(aluOpNeg),
}, nil
}
// String returns the instruction in assembler notation.
func (a NegateA) String() string {
return fmt.Sprintf("neg")
}
// Jump skips the following Skip instructions in the program.
type Jump struct {
Skip uint32
}
// Assemble implements the Instruction Assemble method.
func (a Jump) Assemble() (RawInstruction, error) {
return RawInstruction{
Op: opClsJump | uint16(opJumpAlways),
K: a.Skip,
}, nil
}
// String returns the instruction in assembler notation.
func (a Jump) String() string {
return fmt.Sprintf("ja %d", a.Skip)
}
// JumpIf skips the following Skip instructions in the program if A
// <Cond> Val is true.
type JumpIf struct {
Cond JumpTest
Val uint32
SkipTrue uint8
SkipFalse uint8
}
// Assemble implements the Instruction Assemble method.
func (a JumpIf) Assemble() (RawInstruction, error) {
return jumpToRaw(a.Cond, opOperandConstant, a.Val, a.SkipTrue, a.SkipFalse)
}
// String returns the instruction in assembler notation.
func (a JumpIf) String() string {
return jumpToString(a.Cond, fmt.Sprintf("#%d", a.Val), a.SkipTrue, a.SkipFalse)
}
// JumpIfX skips the following Skip instructions in the program if A
// <Cond> X is true.
type JumpIfX struct {
Cond JumpTest
SkipTrue uint8
SkipFalse uint8
}
// Assemble implements the Instruction Assemble method.
func (a JumpIfX) Assemble() (RawInstruction, error) {
return jumpToRaw(a.Cond, opOperandX, 0, a.SkipTrue, a.SkipFalse)
}
// String returns the instruction in assembler notation.
func (a JumpIfX) String() string {
return jumpToString(a.Cond, "x", a.SkipTrue, a.SkipFalse)
}
// jumpToRaw assembles a jump instruction into a RawInstruction
func jumpToRaw(test JumpTest, operand opOperand, k uint32, skipTrue, skipFalse uint8) (RawInstruction, error) {
var (
cond jumpOp
flip bool
)
switch test {
case JumpEqual:
cond = opJumpEqual
case JumpNotEqual:
cond, flip = opJumpEqual, true
case JumpGreaterThan:
cond = opJumpGT
case JumpLessThan:
cond, flip = opJumpGE, true
case JumpGreaterOrEqual:
cond = opJumpGE
case JumpLessOrEqual:
cond, flip = opJumpGT, true
case JumpBitsSet:
cond = opJumpSet
case JumpBitsNotSet:
cond, flip = opJumpSet, true
default:
return RawInstruction{}, fmt.Errorf("unknown JumpTest %v", test)
}
jt, jf := skipTrue, skipFalse
if flip {
jt, jf = jf, jt
}
return RawInstruction{
Op: opClsJump | uint16(cond) | uint16(operand),
Jt: jt,
Jf: jf,
K: k,
}, nil
}
// jumpToString converts a jump instruction to assembler notation
func jumpToString(cond JumpTest, operand string, skipTrue, skipFalse uint8) string {
switch cond {
// K == A
case JumpEqual:
return conditionalJump(operand, skipTrue, skipFalse, "jeq", "jneq")
// K != A
case JumpNotEqual:
return fmt.Sprintf("jneq %s,%d", operand, skipTrue)
// K > A
case JumpGreaterThan:
return conditionalJump(operand, skipTrue, skipFalse, "jgt", "jle")
// K < A
case JumpLessThan:
return fmt.Sprintf("jlt %s,%d", operand, skipTrue)
// K >= A
case JumpGreaterOrEqual:
return conditionalJump(operand, skipTrue, skipFalse, "jge", "jlt")
// K <= A
case JumpLessOrEqual:
return fmt.Sprintf("jle %s,%d", operand, skipTrue)
// K & A != 0
case JumpBitsSet:
if skipFalse > 0 {
return fmt.Sprintf("jset %s,%d,%d", operand, skipTrue, skipFalse)
}
return fmt.Sprintf("jset %s,%d", operand, skipTrue)
// K & A == 0, there is no assembler instruction for JumpBitNotSet, use JumpBitSet and invert skips
case JumpBitsNotSet:
return jumpToString(JumpBitsSet, operand, skipFalse, skipTrue)
default:
return fmt.Sprintf("unknown JumpTest %#v", cond)
}
}
func conditionalJump(operand string, skipTrue, skipFalse uint8, positiveJump, negativeJump string) string {
if skipTrue > 0 {
if skipFalse > 0 {
return fmt.Sprintf("%s %s,%d,%d", positiveJump, operand, skipTrue, skipFalse)
}
return fmt.Sprintf("%s %s,%d", positiveJump, operand, skipTrue)
}
return fmt.Sprintf("%s %s,%d", negativeJump, operand, skipFalse)
}
// RetA exits the BPF program, returning the value of register A.
type RetA struct{}
// Assemble implements the Instruction Assemble method.
func (a RetA) Assemble() (RawInstruction, error) {
return RawInstruction{
Op: opClsReturn | opRetSrcA,
}, nil
}
// String returns the instruction in assembler notation.
func (a RetA) String() string {
return fmt.Sprintf("ret a")
}
// RetConstant exits the BPF program, returning a constant value.
type RetConstant struct {
Val uint32
}
// Assemble implements the Instruction Assemble method.
func (a RetConstant) Assemble() (RawInstruction, error) {
return RawInstruction{
Op: opClsReturn | opRetSrcConstant,
K: a.Val,
}, nil
}
// String returns the instruction in assembler notation.
func (a RetConstant) String() string {
return fmt.Sprintf("ret #%d", a.Val)
}
// TXA copies the value of register X to register A.
type TXA struct{}
// Assemble implements the Instruction Assemble method.
func (a TXA) Assemble() (RawInstruction, error) {
return RawInstruction{
Op: opClsMisc | opMiscTXA,
}, nil
}
// String returns the instruction in assembler notation.
func (a TXA) String() string {
return fmt.Sprintf("txa")
}
// TAX copies the value of register A to register X.
type TAX struct{}
// Assemble implements the Instruction Assemble method.
func (a TAX) Assemble() (RawInstruction, error) {
return RawInstruction{
Op: opClsMisc | opMiscTAX,
}, nil
}
// String returns the instruction in assembler notation.
func (a TAX) String() string {
return fmt.Sprintf("tax")
}
func assembleLoad(dst Register, loadSize int, mode uint16, k uint32) (RawInstruction, error) {
var (
cls uint16
sz uint16
)
switch dst {
case RegA:
cls = opClsLoadA
case RegX:
cls = opClsLoadX
default:
return RawInstruction{}, fmt.Errorf("invalid target register %v", dst)
}
switch loadSize {
case 1:
sz = opLoadWidth1
case 2:
sz = opLoadWidth2
case 4:
sz = opLoadWidth4
default:
return RawInstruction{}, fmt.Errorf("invalid load byte length %d", sz)
}
return RawInstruction{
Op: cls | sz | mode,
K: k,
}, nil
}

10
vendor/golang.org/x/net/bpf/setter.go generated vendored Normal file
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// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package bpf
// A Setter is a type which can attach a compiled BPF filter to itself.
type Setter interface {
SetBPF(filter []RawInstruction) error
}

150
vendor/golang.org/x/net/bpf/vm.go generated vendored Normal file
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// Copyright 2016 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package bpf
import (
"errors"
"fmt"
)
// A VM is an emulated BPF virtual machine.
type VM struct {
filter []Instruction
}
// NewVM returns a new VM using the input BPF program.
func NewVM(filter []Instruction) (*VM, error) {
if len(filter) == 0 {
return nil, errors.New("one or more Instructions must be specified")
}
for i, ins := range filter {
check := len(filter) - (i + 1)
switch ins := ins.(type) {
// Check for out-of-bounds jumps in instructions
case Jump:
if check <= int(ins.Skip) {
return nil, fmt.Errorf("cannot jump %d instructions; jumping past program bounds", ins.Skip)
}
case JumpIf:
if check <= int(ins.SkipTrue) {
return nil, fmt.Errorf("cannot jump %d instructions in true case; jumping past program bounds", ins.SkipTrue)
}
if check <= int(ins.SkipFalse) {
return nil, fmt.Errorf("cannot jump %d instructions in false case; jumping past program bounds", ins.SkipFalse)
}
case JumpIfX:
if check <= int(ins.SkipTrue) {
return nil, fmt.Errorf("cannot jump %d instructions in true case; jumping past program bounds", ins.SkipTrue)
}
if check <= int(ins.SkipFalse) {
return nil, fmt.Errorf("cannot jump %d instructions in false case; jumping past program bounds", ins.SkipFalse)
}
// Check for division or modulus by zero
case ALUOpConstant:
if ins.Val != 0 {
break
}
switch ins.Op {
case ALUOpDiv, ALUOpMod:
return nil, errors.New("cannot divide by zero using ALUOpConstant")
}
// Check for unknown extensions
case LoadExtension:
switch ins.Num {
case ExtLen:
default:
return nil, fmt.Errorf("extension %d not implemented", ins.Num)
}
}
}
// Make sure last instruction is a return instruction
switch filter[len(filter)-1].(type) {
case RetA, RetConstant:
default:
return nil, errors.New("BPF program must end with RetA or RetConstant")
}
// Though our VM works using disassembled instructions, we
// attempt to assemble the input filter anyway to ensure it is compatible
// with an operating system VM.
_, err := Assemble(filter)
return &VM{
filter: filter,
}, err
}
// Run runs the VM's BPF program against the input bytes.
// Run returns the number of bytes accepted by the BPF program, and any errors
// which occurred while processing the program.
func (v *VM) Run(in []byte) (int, error) {
var (
// Registers of the virtual machine
regA uint32
regX uint32
regScratch [16]uint32
// OK is true if the program should continue processing the next
// instruction, or false if not, causing the loop to break
ok = true
)
// TODO(mdlayher): implement:
// - NegateA:
// - would require a change from uint32 registers to int32
// registers
// TODO(mdlayher): add interop tests that check signedness of ALU
// operations against kernel implementation, and make sure Go
// implementation matches behavior
for i := 0; i < len(v.filter) && ok; i++ {
ins := v.filter[i]
switch ins := ins.(type) {
case ALUOpConstant:
regA = aluOpConstant(ins, regA)
case ALUOpX:
regA, ok = aluOpX(ins, regA, regX)
case Jump:
i += int(ins.Skip)
case JumpIf:
jump := jumpIf(ins, regA)
i += jump
case JumpIfX:
jump := jumpIfX(ins, regA, regX)
i += jump
case LoadAbsolute:
regA, ok = loadAbsolute(ins, in)
case LoadConstant:
regA, regX = loadConstant(ins, regA, regX)
case LoadExtension:
regA = loadExtension(ins, in)
case LoadIndirect:
regA, ok = loadIndirect(ins, in, regX)
case LoadMemShift:
regX, ok = loadMemShift(ins, in)
case LoadScratch:
regA, regX = loadScratch(ins, regScratch, regA, regX)
case RetA:
return int(regA), nil
case RetConstant:
return int(ins.Val), nil
case StoreScratch:
regScratch = storeScratch(ins, regScratch, regA, regX)
case TAX:
regX = regA
case TXA:
regA = regX
default:
return 0, fmt.Errorf("unknown Instruction at index %d: %T", i, ins)
}
}
return 0, nil
}

182
vendor/golang.org/x/net/bpf/vm_instructions.go generated vendored Normal file
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// Copyright 2016 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package bpf
import (
"encoding/binary"
"fmt"
)
func aluOpConstant(ins ALUOpConstant, regA uint32) uint32 {
return aluOpCommon(ins.Op, regA, ins.Val)
}
func aluOpX(ins ALUOpX, regA uint32, regX uint32) (uint32, bool) {
// Guard against division or modulus by zero by terminating
// the program, as the OS BPF VM does
if regX == 0 {
switch ins.Op {
case ALUOpDiv, ALUOpMod:
return 0, false
}
}
return aluOpCommon(ins.Op, regA, regX), true
}
func aluOpCommon(op ALUOp, regA uint32, value uint32) uint32 {
switch op {
case ALUOpAdd:
return regA + value
case ALUOpSub:
return regA - value
case ALUOpMul:
return regA * value
case ALUOpDiv:
// Division by zero not permitted by NewVM and aluOpX checks
return regA / value
case ALUOpOr:
return regA | value
case ALUOpAnd:
return regA & value
case ALUOpShiftLeft:
return regA << value
case ALUOpShiftRight:
return regA >> value
case ALUOpMod:
// Modulus by zero not permitted by NewVM and aluOpX checks
return regA % value
case ALUOpXor:
return regA ^ value
default:
return regA
}
}
func jumpIf(ins JumpIf, regA uint32) int {
return jumpIfCommon(ins.Cond, ins.SkipTrue, ins.SkipFalse, regA, ins.Val)
}
func jumpIfX(ins JumpIfX, regA uint32, regX uint32) int {
return jumpIfCommon(ins.Cond, ins.SkipTrue, ins.SkipFalse, regA, regX)
}
func jumpIfCommon(cond JumpTest, skipTrue, skipFalse uint8, regA uint32, value uint32) int {
var ok bool
switch cond {
case JumpEqual:
ok = regA == value
case JumpNotEqual:
ok = regA != value
case JumpGreaterThan:
ok = regA > value
case JumpLessThan:
ok = regA < value
case JumpGreaterOrEqual:
ok = regA >= value
case JumpLessOrEqual:
ok = regA <= value
case JumpBitsSet:
ok = (regA & value) != 0
case JumpBitsNotSet:
ok = (regA & value) == 0
}
if ok {
return int(skipTrue)
}
return int(skipFalse)
}
func loadAbsolute(ins LoadAbsolute, in []byte) (uint32, bool) {
offset := int(ins.Off)
size := int(ins.Size)
return loadCommon(in, offset, size)
}
func loadConstant(ins LoadConstant, regA uint32, regX uint32) (uint32, uint32) {
switch ins.Dst {
case RegA:
regA = ins.Val
case RegX:
regX = ins.Val
}
return regA, regX
}
func loadExtension(ins LoadExtension, in []byte) uint32 {
switch ins.Num {
case ExtLen:
return uint32(len(in))
default:
panic(fmt.Sprintf("unimplemented extension: %d", ins.Num))
}
}
func loadIndirect(ins LoadIndirect, in []byte, regX uint32) (uint32, bool) {
offset := int(ins.Off) + int(regX)
size := int(ins.Size)
return loadCommon(in, offset, size)
}
func loadMemShift(ins LoadMemShift, in []byte) (uint32, bool) {
offset := int(ins.Off)
// Size of LoadMemShift is always 1 byte
if !inBounds(len(in), offset, 1) {
return 0, false
}
// Mask off high 4 bits and multiply low 4 bits by 4
return uint32(in[offset]&0x0f) * 4, true
}
func inBounds(inLen int, offset int, size int) bool {
return offset+size <= inLen
}
func loadCommon(in []byte, offset int, size int) (uint32, bool) {
if !inBounds(len(in), offset, size) {
return 0, false
}
switch size {
case 1:
return uint32(in[offset]), true
case 2:
return uint32(binary.BigEndian.Uint16(in[offset : offset+size])), true
case 4:
return uint32(binary.BigEndian.Uint32(in[offset : offset+size])), true
default:
panic(fmt.Sprintf("invalid load size: %d", size))
}
}
func loadScratch(ins LoadScratch, regScratch [16]uint32, regA uint32, regX uint32) (uint32, uint32) {
switch ins.Dst {
case RegA:
regA = regScratch[ins.N]
case RegX:
regX = regScratch[ins.N]
}
return regA, regX
}
func storeScratch(ins StoreScratch, regScratch [16]uint32, regA uint32, regX uint32) [16]uint32 {
switch ins.Src {
case RegA:
regScratch[ins.N] = regA
case RegX:
regScratch[ins.N] = regX
}
return regScratch
}

223
vendor/golang.org/x/net/internal/iana/const.go generated vendored Normal file
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// go generate gen.go
// Code generated by the command above; DO NOT EDIT.
// Package iana provides protocol number resources managed by the Internet Assigned Numbers Authority (IANA).
package iana // import "golang.org/x/net/internal/iana"
// Differentiated Services Field Codepoints (DSCP), Updated: 2018-05-04
const (
DiffServCS0 = 0x00 // CS0
DiffServCS1 = 0x20 // CS1
DiffServCS2 = 0x40 // CS2
DiffServCS3 = 0x60 // CS3
DiffServCS4 = 0x80 // CS4
DiffServCS5 = 0xa0 // CS5
DiffServCS6 = 0xc0 // CS6
DiffServCS7 = 0xe0 // CS7
DiffServAF11 = 0x28 // AF11
DiffServAF12 = 0x30 // AF12
DiffServAF13 = 0x38 // AF13
DiffServAF21 = 0x48 // AF21
DiffServAF22 = 0x50 // AF22
DiffServAF23 = 0x58 // AF23
DiffServAF31 = 0x68 // AF31
DiffServAF32 = 0x70 // AF32
DiffServAF33 = 0x78 // AF33
DiffServAF41 = 0x88 // AF41
DiffServAF42 = 0x90 // AF42
DiffServAF43 = 0x98 // AF43
DiffServEF = 0xb8 // EF
DiffServVOICEADMIT = 0xb0 // VOICE-ADMIT
NotECNTransport = 0x00 // Not-ECT (Not ECN-Capable Transport)
ECNTransport1 = 0x01 // ECT(1) (ECN-Capable Transport(1))
ECNTransport0 = 0x02 // ECT(0) (ECN-Capable Transport(0))
CongestionExperienced = 0x03 // CE (Congestion Experienced)
)
// Protocol Numbers, Updated: 2017-10-13
const (
ProtocolIP = 0 // IPv4 encapsulation, pseudo protocol number
ProtocolHOPOPT = 0 // IPv6 Hop-by-Hop Option
ProtocolICMP = 1 // Internet Control Message
ProtocolIGMP = 2 // Internet Group Management
ProtocolGGP = 3 // Gateway-to-Gateway
ProtocolIPv4 = 4 // IPv4 encapsulation
ProtocolST = 5 // Stream
ProtocolTCP = 6 // Transmission Control
ProtocolCBT = 7 // CBT
ProtocolEGP = 8 // Exterior Gateway Protocol
ProtocolIGP = 9 // any private interior gateway (used by Cisco for their IGRP)
ProtocolBBNRCCMON = 10 // BBN RCC Monitoring
ProtocolNVPII = 11 // Network Voice Protocol
ProtocolPUP = 12 // PUP
ProtocolEMCON = 14 // EMCON
ProtocolXNET = 15 // Cross Net Debugger
ProtocolCHAOS = 16 // Chaos
ProtocolUDP = 17 // User Datagram
ProtocolMUX = 18 // Multiplexing
ProtocolDCNMEAS = 19 // DCN Measurement Subsystems
ProtocolHMP = 20 // Host Monitoring
ProtocolPRM = 21 // Packet Radio Measurement
ProtocolXNSIDP = 22 // XEROX NS IDP
ProtocolTRUNK1 = 23 // Trunk-1
ProtocolTRUNK2 = 24 // Trunk-2
ProtocolLEAF1 = 25 // Leaf-1
ProtocolLEAF2 = 26 // Leaf-2
ProtocolRDP = 27 // Reliable Data Protocol
ProtocolIRTP = 28 // Internet Reliable Transaction
ProtocolISOTP4 = 29 // ISO Transport Protocol Class 4
ProtocolNETBLT = 30 // Bulk Data Transfer Protocol
ProtocolMFENSP = 31 // MFE Network Services Protocol
ProtocolMERITINP = 32 // MERIT Internodal Protocol
ProtocolDCCP = 33 // Datagram Congestion Control Protocol
Protocol3PC = 34 // Third Party Connect Protocol
ProtocolIDPR = 35 // Inter-Domain Policy Routing Protocol
ProtocolXTP = 36 // XTP
ProtocolDDP = 37 // Datagram Delivery Protocol
ProtocolIDPRCMTP = 38 // IDPR Control Message Transport Proto
ProtocolTPPP = 39 // TP++ Transport Protocol
ProtocolIL = 40 // IL Transport Protocol
ProtocolIPv6 = 41 // IPv6 encapsulation
ProtocolSDRP = 42 // Source Demand Routing Protocol
ProtocolIPv6Route = 43 // Routing Header for IPv6
ProtocolIPv6Frag = 44 // Fragment Header for IPv6
ProtocolIDRP = 45 // Inter-Domain Routing Protocol
ProtocolRSVP = 46 // Reservation Protocol
ProtocolGRE = 47 // Generic Routing Encapsulation
ProtocolDSR = 48 // Dynamic Source Routing Protocol
ProtocolBNA = 49 // BNA
ProtocolESP = 50 // Encap Security Payload
ProtocolAH = 51 // Authentication Header
ProtocolINLSP = 52 // Integrated Net Layer Security TUBA
ProtocolNARP = 54 // NBMA Address Resolution Protocol
ProtocolMOBILE = 55 // IP Mobility
ProtocolTLSP = 56 // Transport Layer Security Protocol using Kryptonet key management
ProtocolSKIP = 57 // SKIP
ProtocolIPv6ICMP = 58 // ICMP for IPv6
ProtocolIPv6NoNxt = 59 // No Next Header for IPv6
ProtocolIPv6Opts = 60 // Destination Options for IPv6
ProtocolCFTP = 62 // CFTP
ProtocolSATEXPAK = 64 // SATNET and Backroom EXPAK
ProtocolKRYPTOLAN = 65 // Kryptolan
ProtocolRVD = 66 // MIT Remote Virtual Disk Protocol
ProtocolIPPC = 67 // Internet Pluribus Packet Core
ProtocolSATMON = 69 // SATNET Monitoring
ProtocolVISA = 70 // VISA Protocol
ProtocolIPCV = 71 // Internet Packet Core Utility
ProtocolCPNX = 72 // Computer Protocol Network Executive
ProtocolCPHB = 73 // Computer Protocol Heart Beat
ProtocolWSN = 74 // Wang Span Network
ProtocolPVP = 75 // Packet Video Protocol
ProtocolBRSATMON = 76 // Backroom SATNET Monitoring
ProtocolSUNND = 77 // SUN ND PROTOCOL-Temporary
ProtocolWBMON = 78 // WIDEBAND Monitoring
ProtocolWBEXPAK = 79 // WIDEBAND EXPAK
ProtocolISOIP = 80 // ISO Internet Protocol
ProtocolVMTP = 81 // VMTP
ProtocolSECUREVMTP = 82 // SECURE-VMTP
ProtocolVINES = 83 // VINES
ProtocolTTP = 84 // Transaction Transport Protocol
ProtocolIPTM = 84 // Internet Protocol Traffic Manager
ProtocolNSFNETIGP = 85 // NSFNET-IGP
ProtocolDGP = 86 // Dissimilar Gateway Protocol
ProtocolTCF = 87 // TCF
ProtocolEIGRP = 88 // EIGRP
ProtocolOSPFIGP = 89 // OSPFIGP
ProtocolSpriteRPC = 90 // Sprite RPC Protocol
ProtocolLARP = 91 // Locus Address Resolution Protocol
ProtocolMTP = 92 // Multicast Transport Protocol
ProtocolAX25 = 93 // AX.25 Frames
ProtocolIPIP = 94 // IP-within-IP Encapsulation Protocol
ProtocolSCCSP = 96 // Semaphore Communications Sec. Pro.
ProtocolETHERIP = 97 // Ethernet-within-IP Encapsulation
ProtocolENCAP = 98 // Encapsulation Header
ProtocolGMTP = 100 // GMTP
ProtocolIFMP = 101 // Ipsilon Flow Management Protocol
ProtocolPNNI = 102 // PNNI over IP
ProtocolPIM = 103 // Protocol Independent Multicast
ProtocolARIS = 104 // ARIS
ProtocolSCPS = 105 // SCPS
ProtocolQNX = 106 // QNX
ProtocolAN = 107 // Active Networks
ProtocolIPComp = 108 // IP Payload Compression Protocol
ProtocolSNP = 109 // Sitara Networks Protocol
ProtocolCompaqPeer = 110 // Compaq Peer Protocol
ProtocolIPXinIP = 111 // IPX in IP
ProtocolVRRP = 112 // Virtual Router Redundancy Protocol
ProtocolPGM = 113 // PGM Reliable Transport Protocol
ProtocolL2TP = 115 // Layer Two Tunneling Protocol
ProtocolDDX = 116 // D-II Data Exchange (DDX)
ProtocolIATP = 117 // Interactive Agent Transfer Protocol
ProtocolSTP = 118 // Schedule Transfer Protocol
ProtocolSRP = 119 // SpectraLink Radio Protocol
ProtocolUTI = 120 // UTI
ProtocolSMP = 121 // Simple Message Protocol
ProtocolPTP = 123 // Performance Transparency Protocol
ProtocolISIS = 124 // ISIS over IPv4
ProtocolFIRE = 125 // FIRE
ProtocolCRTP = 126 // Combat Radio Transport Protocol
ProtocolCRUDP = 127 // Combat Radio User Datagram
ProtocolSSCOPMCE = 128 // SSCOPMCE
ProtocolIPLT = 129 // IPLT
ProtocolSPS = 130 // Secure Packet Shield
ProtocolPIPE = 131 // Private IP Encapsulation within IP
ProtocolSCTP = 132 // Stream Control Transmission Protocol
ProtocolFC = 133 // Fibre Channel
ProtocolRSVPE2EIGNORE = 134 // RSVP-E2E-IGNORE
ProtocolMobilityHeader = 135 // Mobility Header
ProtocolUDPLite = 136 // UDPLite
ProtocolMPLSinIP = 137 // MPLS-in-IP
ProtocolMANET = 138 // MANET Protocols
ProtocolHIP = 139 // Host Identity Protocol
ProtocolShim6 = 140 // Shim6 Protocol
ProtocolWESP = 141 // Wrapped Encapsulating Security Payload
ProtocolROHC = 142 // Robust Header Compression
ProtocolReserved = 255 // Reserved
)
// Address Family Numbers, Updated: 2018-04-02
const (
AddrFamilyIPv4 = 1 // IP (IP version 4)
AddrFamilyIPv6 = 2 // IP6 (IP version 6)
AddrFamilyNSAP = 3 // NSAP
AddrFamilyHDLC = 4 // HDLC (8-bit multidrop)
AddrFamilyBBN1822 = 5 // BBN 1822
AddrFamily802 = 6 // 802 (includes all 802 media plus Ethernet "canonical format")
AddrFamilyE163 = 7 // E.163
AddrFamilyE164 = 8 // E.164 (SMDS, Frame Relay, ATM)
AddrFamilyF69 = 9 // F.69 (Telex)
AddrFamilyX121 = 10 // X.121 (X.25, Frame Relay)
AddrFamilyIPX = 11 // IPX
AddrFamilyAppletalk = 12 // Appletalk
AddrFamilyDecnetIV = 13 // Decnet IV
AddrFamilyBanyanVines = 14 // Banyan Vines
AddrFamilyE164withSubaddress = 15 // E.164 with NSAP format subaddress
AddrFamilyDNS = 16 // DNS (Domain Name System)
AddrFamilyDistinguishedName = 17 // Distinguished Name
AddrFamilyASNumber = 18 // AS Number
AddrFamilyXTPoverIPv4 = 19 // XTP over IP version 4
AddrFamilyXTPoverIPv6 = 20 // XTP over IP version 6
AddrFamilyXTPnativemodeXTP = 21 // XTP native mode XTP
AddrFamilyFibreChannelWorldWidePortName = 22 // Fibre Channel World-Wide Port Name
AddrFamilyFibreChannelWorldWideNodeName = 23 // Fibre Channel World-Wide Node Name
AddrFamilyGWID = 24 // GWID
AddrFamilyL2VPN = 25 // AFI for L2VPN information
AddrFamilyMPLSTPSectionEndpointID = 26 // MPLS-TP Section Endpoint Identifier
AddrFamilyMPLSTPLSPEndpointID = 27 // MPLS-TP LSP Endpoint Identifier
AddrFamilyMPLSTPPseudowireEndpointID = 28 // MPLS-TP Pseudowire Endpoint Identifier
AddrFamilyMTIPv4 = 29 // MT IP: Multi-Topology IP version 4
AddrFamilyMTIPv6 = 30 // MT IPv6: Multi-Topology IP version 6
AddrFamilyEIGRPCommonServiceFamily = 16384 // EIGRP Common Service Family
AddrFamilyEIGRPIPv4ServiceFamily = 16385 // EIGRP IPv4 Service Family
AddrFamilyEIGRPIPv6ServiceFamily = 16386 // EIGRP IPv6 Service Family
AddrFamilyLISPCanonicalAddressFormat = 16387 // LISP Canonical Address Format (LCAF)
AddrFamilyBGPLS = 16388 // BGP-LS
AddrFamily48bitMAC = 16389 // 48-bit MAC
AddrFamily64bitMAC = 16390 // 64-bit MAC
AddrFamilyOUI = 16391 // OUI
AddrFamilyMACFinal24bits = 16392 // MAC/24
AddrFamilyMACFinal40bits = 16393 // MAC/40
AddrFamilyIPv6Initial64bits = 16394 // IPv6/64
AddrFamilyRBridgePortID = 16395 // RBridge Port ID
AddrFamilyTRILLNickname = 16396 // TRILL Nickname
)

12
vendor/golang.org/x/net/internal/socket/cmsghdr.go generated vendored Normal file
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// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build aix || darwin || dragonfly || freebsd || linux || netbsd || openbsd || solaris || zos
// +build aix darwin dragonfly freebsd linux netbsd openbsd solaris zos
package socket
func (h *cmsghdr) len() int { return int(h.Len) }
func (h *cmsghdr) lvl() int { return int(h.Level) }
func (h *cmsghdr) typ() int { return int(h.Type) }

14
vendor/golang.org/x/net/internal/socket/cmsghdr_bsd.go generated vendored Normal file
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// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build aix || darwin || dragonfly || freebsd || netbsd || openbsd
// +build aix darwin dragonfly freebsd netbsd openbsd
package socket
func (h *cmsghdr) set(l, lvl, typ int) {
h.Len = uint32(l)
h.Level = int32(lvl)
h.Type = int32(typ)
}

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@ -0,0 +1,15 @@
// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build (arm || mips || mipsle || 386 || ppc) && linux
// +build arm mips mipsle 386 ppc
// +build linux
package socket
func (h *cmsghdr) set(l, lvl, typ int) {
h.Len = uint32(l)
h.Level = int32(lvl)
h.Type = int32(typ)
}

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@ -0,0 +1,15 @@
// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build (arm64 || amd64 || loong64 || ppc64 || ppc64le || mips64 || mips64le || riscv64 || s390x) && linux
// +build arm64 amd64 loong64 ppc64 ppc64le mips64 mips64le riscv64 s390x
// +build linux
package socket
func (h *cmsghdr) set(l, lvl, typ int) {
h.Len = uint64(l)
h.Level = int32(lvl)
h.Type = int32(typ)
}

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@ -0,0 +1,14 @@
// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build amd64 && solaris
// +build amd64,solaris
package socket
func (h *cmsghdr) set(l, lvl, typ int) {
h.Len = uint32(l)
h.Level = int32(lvl)
h.Type = int32(typ)
}

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// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build !aix && !darwin && !dragonfly && !freebsd && !linux && !netbsd && !openbsd && !solaris && !zos
// +build !aix,!darwin,!dragonfly,!freebsd,!linux,!netbsd,!openbsd,!solaris,!zos
package socket
func controlHeaderLen() int {
return 0
}
func controlMessageLen(dataLen int) int {
return 0
}
func controlMessageSpace(dataLen int) int {
return 0
}
type cmsghdr struct{}
func (h *cmsghdr) len() int { return 0 }
func (h *cmsghdr) lvl() int { return 0 }
func (h *cmsghdr) typ() int { return 0 }
func (h *cmsghdr) set(l, lvl, typ int) {}

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@ -0,0 +1,22 @@
// Copyright 2020 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build aix || darwin || dragonfly || freebsd || linux || netbsd || openbsd || solaris || zos
// +build aix darwin dragonfly freebsd linux netbsd openbsd solaris zos
package socket
import "golang.org/x/sys/unix"
func controlHeaderLen() int {
return unix.CmsgLen(0)
}
func controlMessageLen(dataLen int) int {
return unix.CmsgLen(dataLen)
}
func controlMessageSpace(dataLen int) int {
return unix.CmsgSpace(dataLen)
}

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@ -0,0 +1,11 @@
// Copyright 2020 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package socket
func (h *cmsghdr) set(l, lvl, typ int) {
h.Len = int32(l)
h.Level = int32(lvl)
h.Type = int32(typ)
}

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@ -0,0 +1,26 @@
// Copyright 2021 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build darwin || dragonfly || freebsd || linux || netbsd || openbsd || solaris
// +build darwin dragonfly freebsd linux netbsd openbsd solaris
package socket
import (
"syscall"
)
// ioComplete checks the flags and result of a syscall, to be used as return
// value in a syscall.RawConn.Read or Write callback.
func ioComplete(flags int, operr error) bool {
if flags&syscall.MSG_DONTWAIT != 0 {
// Caller explicitly said don't wait, so always return immediately.
return true
}
if operr == syscall.EAGAIN || operr == syscall.EWOULDBLOCK {
// No data available, block for I/O and try again.
return false
}
return true
}

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@ -0,0 +1,22 @@
// Copyright 2021 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build aix || windows || zos
// +build aix windows zos
package socket
import (
"syscall"
)
// ioComplete checks the flags and result of a syscall, to be used as return
// value in a syscall.RawConn.Read or Write callback.
func ioComplete(flags int, operr error) bool {
if operr == syscall.EAGAIN || operr == syscall.EWOULDBLOCK {
// No data available, block for I/O and try again.
return false
}
return true
}

8
vendor/golang.org/x/net/internal/socket/empty.s generated vendored Normal file
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@ -0,0 +1,8 @@
// Copyright 2018 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build darwin && go1.12
// +build darwin,go1.12
// This exists solely so we can linkname in symbols from syscall.

32
vendor/golang.org/x/net/internal/socket/error_unix.go generated vendored Normal file
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@ -0,0 +1,32 @@
// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build aix || darwin || dragonfly || freebsd || linux || netbsd || openbsd || solaris || zos
// +build aix darwin dragonfly freebsd linux netbsd openbsd solaris zos
package socket
import "syscall"
var (
errEAGAIN error = syscall.EAGAIN
errEINVAL error = syscall.EINVAL
errENOENT error = syscall.ENOENT
)
// errnoErr returns common boxed Errno values, to prevent allocations
// at runtime.
func errnoErr(errno syscall.Errno) error {
switch errno {
case 0:
return nil
case syscall.EAGAIN:
return errEAGAIN
case syscall.EINVAL:
return errEINVAL
case syscall.ENOENT:
return errENOENT
}
return errno
}

View file

@ -0,0 +1,26 @@
// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package socket
import "syscall"
var (
errERROR_IO_PENDING error = syscall.ERROR_IO_PENDING
errEINVAL error = syscall.EINVAL
)
// errnoErr returns common boxed Errno values, to prevent allocations
// at runtime.
func errnoErr(errno syscall.Errno) error {
switch errno {
case 0:
return nil
case syscall.ERROR_IO_PENDING:
return errERROR_IO_PENDING
case syscall.EINVAL:
return errEINVAL
}
return errno
}

20
vendor/golang.org/x/net/internal/socket/iovec_32bit.go generated vendored Normal file
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@ -0,0 +1,20 @@
// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build (arm || mips || mipsle || 386 || ppc) && (darwin || dragonfly || freebsd || linux || netbsd || openbsd)
// +build arm mips mipsle 386 ppc
// +build darwin dragonfly freebsd linux netbsd openbsd
package socket
import "unsafe"
func (v *iovec) set(b []byte) {
l := len(b)
if l == 0 {
return
}
v.Base = (*byte)(unsafe.Pointer(&b[0]))
v.Len = uint32(l)
}

20
vendor/golang.org/x/net/internal/socket/iovec_64bit.go generated vendored Normal file
View file

@ -0,0 +1,20 @@
// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build (arm64 || amd64 || loong64 || ppc64 || ppc64le || mips64 || mips64le || riscv64 || s390x) && (aix || darwin || dragonfly || freebsd || linux || netbsd || openbsd || zos)
// +build arm64 amd64 loong64 ppc64 ppc64le mips64 mips64le riscv64 s390x
// +build aix darwin dragonfly freebsd linux netbsd openbsd zos
package socket
import "unsafe"
func (v *iovec) set(b []byte) {
l := len(b)
if l == 0 {
return
}
v.Base = (*byte)(unsafe.Pointer(&b[0]))
v.Len = uint64(l)
}

View file

@ -0,0 +1,19 @@
// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build amd64 && solaris
// +build amd64,solaris
package socket
import "unsafe"
func (v *iovec) set(b []byte) {
l := len(b)
if l == 0 {
return
}
v.Base = (*int8)(unsafe.Pointer(&b[0]))
v.Len = uint64(l)
}

12
vendor/golang.org/x/net/internal/socket/iovec_stub.go generated vendored Normal file
View file

@ -0,0 +1,12 @@
// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build !aix && !darwin && !dragonfly && !freebsd && !linux && !netbsd && !openbsd && !solaris && !zos
// +build !aix,!darwin,!dragonfly,!freebsd,!linux,!netbsd,!openbsd,!solaris,!zos
package socket
type iovec struct{}
func (v *iovec) set(b []byte) {}

View file

@ -0,0 +1,22 @@
// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build !aix && !linux && !netbsd
// +build !aix,!linux,!netbsd
package socket
import "net"
type mmsghdr struct{}
type mmsghdrs []mmsghdr
func (hs mmsghdrs) pack(ms []Message, parseFn func([]byte, string) (net.Addr, error), marshalFn func(net.Addr) []byte) error {
return nil
}
func (hs mmsghdrs) unpack(ms []Message, parseFn func([]byte, string) (net.Addr, error), hint string) error {
return nil
}

180
vendor/golang.org/x/net/internal/socket/mmsghdr_unix.go generated vendored Normal file
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@ -0,0 +1,180 @@
// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build aix || linux || netbsd
// +build aix linux netbsd
package socket
import (
"net"
"os"
"sync"
"syscall"
)
type mmsghdrs []mmsghdr
func (hs mmsghdrs) unpack(ms []Message, parseFn func([]byte, string) (net.Addr, error), hint string) error {
for i := range hs {
ms[i].N = int(hs[i].Len)
ms[i].NN = hs[i].Hdr.controllen()
ms[i].Flags = hs[i].Hdr.flags()
if parseFn != nil {
var err error
ms[i].Addr, err = parseFn(hs[i].Hdr.name(), hint)
if err != nil {
return err
}
}
}
return nil
}
// mmsghdrsPacker packs Message-slices into mmsghdrs (re-)using pre-allocated buffers.
type mmsghdrsPacker struct {
// hs are the pre-allocated mmsghdrs.
hs mmsghdrs
// sockaddrs is the pre-allocated buffer for the Hdr.Name buffers.
// We use one large buffer for all messages and slice it up.
sockaddrs []byte
// vs are the pre-allocated iovecs.
// We allocate one large buffer for all messages and slice it up. This allows to reuse the buffer
// if the number of buffers per message is distributed differently between calls.
vs []iovec
}
func (p *mmsghdrsPacker) prepare(ms []Message) {
n := len(ms)
if n <= cap(p.hs) {
p.hs = p.hs[:n]
} else {
p.hs = make(mmsghdrs, n)
}
if n*sizeofSockaddrInet6 <= cap(p.sockaddrs) {
p.sockaddrs = p.sockaddrs[:n*sizeofSockaddrInet6]
} else {
p.sockaddrs = make([]byte, n*sizeofSockaddrInet6)
}
nb := 0
for _, m := range ms {
nb += len(m.Buffers)
}
if nb <= cap(p.vs) {
p.vs = p.vs[:nb]
} else {
p.vs = make([]iovec, nb)
}
}
func (p *mmsghdrsPacker) pack(ms []Message, parseFn func([]byte, string) (net.Addr, error), marshalFn func(net.Addr, []byte) int) mmsghdrs {
p.prepare(ms)
hs := p.hs
vsRest := p.vs
saRest := p.sockaddrs
for i := range hs {
nvs := len(ms[i].Buffers)
vs := vsRest[:nvs]
vsRest = vsRest[nvs:]
var sa []byte
if parseFn != nil {
sa = saRest[:sizeofSockaddrInet6]
saRest = saRest[sizeofSockaddrInet6:]
} else if marshalFn != nil {
n := marshalFn(ms[i].Addr, saRest)
if n > 0 {
sa = saRest[:n]
saRest = saRest[n:]
}
}
hs[i].Hdr.pack(vs, ms[i].Buffers, ms[i].OOB, sa)
}
return hs
}
// syscaller is a helper to invoke recvmmsg and sendmmsg via the RawConn.Read/Write interface.
// It is reusable, to amortize the overhead of allocating a closure for the function passed to
// RawConn.Read/Write.
type syscaller struct {
n int
operr error
hs mmsghdrs
flags int
boundRecvmmsgF func(uintptr) bool
boundSendmmsgF func(uintptr) bool
}
func (r *syscaller) init() {
r.boundRecvmmsgF = r.recvmmsgF
r.boundSendmmsgF = r.sendmmsgF
}
func (r *syscaller) recvmmsg(c syscall.RawConn, hs mmsghdrs, flags int) (int, error) {
r.n = 0
r.operr = nil
r.hs = hs
r.flags = flags
if err := c.Read(r.boundRecvmmsgF); err != nil {
return r.n, err
}
if r.operr != nil {
return r.n, os.NewSyscallError("recvmmsg", r.operr)
}
return r.n, nil
}
func (r *syscaller) recvmmsgF(s uintptr) bool {
r.n, r.operr = recvmmsg(s, r.hs, r.flags)
return ioComplete(r.flags, r.operr)
}
func (r *syscaller) sendmmsg(c syscall.RawConn, hs mmsghdrs, flags int) (int, error) {
r.n = 0
r.operr = nil
r.hs = hs
r.flags = flags
if err := c.Write(r.boundSendmmsgF); err != nil {
return r.n, err
}
if r.operr != nil {
return r.n, os.NewSyscallError("sendmmsg", r.operr)
}
return r.n, nil
}
func (r *syscaller) sendmmsgF(s uintptr) bool {
r.n, r.operr = sendmmsg(s, r.hs, r.flags)
return ioComplete(r.flags, r.operr)
}
// mmsgTmps holds reusable temporary helpers for recvmmsg and sendmmsg.
type mmsgTmps struct {
packer mmsghdrsPacker
syscaller syscaller
}
var defaultMmsgTmpsPool = mmsgTmpsPool{
p: sync.Pool{
New: func() interface{} {
tmps := new(mmsgTmps)
tmps.syscaller.init()
return tmps
},
},
}
type mmsgTmpsPool struct {
p sync.Pool
}
func (p *mmsgTmpsPool) Get() *mmsgTmps {
return p.p.Get().(*mmsgTmps)
}
func (p *mmsgTmpsPool) Put(tmps *mmsgTmps) {
p.p.Put(tmps)
}

40
vendor/golang.org/x/net/internal/socket/msghdr_bsd.go generated vendored Normal file
View file

@ -0,0 +1,40 @@
// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build aix || darwin || dragonfly || freebsd || netbsd || openbsd
// +build aix darwin dragonfly freebsd netbsd openbsd
package socket
import "unsafe"
func (h *msghdr) pack(vs []iovec, bs [][]byte, oob []byte, sa []byte) {
for i := range vs {
vs[i].set(bs[i])
}
h.setIov(vs)
if len(oob) > 0 {
h.Control = (*byte)(unsafe.Pointer(&oob[0]))
h.Controllen = uint32(len(oob))
}
if sa != nil {
h.Name = (*byte)(unsafe.Pointer(&sa[0]))
h.Namelen = uint32(len(sa))
}
}
func (h *msghdr) name() []byte {
if h.Name != nil && h.Namelen > 0 {
return (*[sizeofSockaddrInet6]byte)(unsafe.Pointer(h.Name))[:h.Namelen]
}
return nil
}
func (h *msghdr) controllen() int {
return int(h.Controllen)
}
func (h *msghdr) flags() int {
return int(h.Flags)
}

View file

@ -0,0 +1,17 @@
// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build aix || darwin || dragonfly || freebsd || netbsd
// +build aix darwin dragonfly freebsd netbsd
package socket
func (h *msghdr) setIov(vs []iovec) {
l := len(vs)
if l == 0 {
return
}
h.Iov = &vs[0]
h.Iovlen = int32(l)
}

View file

@ -0,0 +1,39 @@
// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package socket
import "unsafe"
func (h *msghdr) pack(vs []iovec, bs [][]byte, oob []byte, sa []byte) {
for i := range vs {
vs[i].set(bs[i])
}
h.setIov(vs)
if len(oob) > 0 {
h.setControl(oob)
}
if sa != nil {
h.Name = (*byte)(unsafe.Pointer(&sa[0]))
h.Namelen = uint32(len(sa))
} else {
h.Name = nil
h.Namelen = 0
}
}
func (h *msghdr) name() []byte {
if h.Name != nil && h.Namelen > 0 {
return (*[sizeofSockaddrInet6]byte)(unsafe.Pointer(h.Name))[:h.Namelen]
}
return nil
}
func (h *msghdr) controllen() int {
return int(h.Controllen)
}
func (h *msghdr) flags() int {
return int(h.Flags)
}

View file

@ -0,0 +1,25 @@
// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build (arm || mips || mipsle || 386 || ppc) && linux
// +build arm mips mipsle 386 ppc
// +build linux
package socket
import "unsafe"
func (h *msghdr) setIov(vs []iovec) {
l := len(vs)
if l == 0 {
return
}
h.Iov = &vs[0]
h.Iovlen = uint32(l)
}
func (h *msghdr) setControl(b []byte) {
h.Control = (*byte)(unsafe.Pointer(&b[0]))
h.Controllen = uint32(len(b))
}

View file

@ -0,0 +1,25 @@
// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build (arm64 || amd64 || loong64 || ppc64 || ppc64le || mips64 || mips64le || riscv64 || s390x) && linux
// +build arm64 amd64 loong64 ppc64 ppc64le mips64 mips64le riscv64 s390x
// +build linux
package socket
import "unsafe"
func (h *msghdr) setIov(vs []iovec) {
l := len(vs)
if l == 0 {
return
}
h.Iov = &vs[0]
h.Iovlen = uint64(l)
}
func (h *msghdr) setControl(b []byte) {
h.Control = (*byte)(unsafe.Pointer(&b[0]))
h.Controllen = uint64(len(b))
}

View file

@ -0,0 +1,14 @@
// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package socket
func (h *msghdr) setIov(vs []iovec) {
l := len(vs)
if l == 0 {
return
}
h.Iov = &vs[0]
h.Iovlen = uint32(l)
}

View file

@ -0,0 +1,36 @@
// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build amd64 && solaris
// +build amd64,solaris
package socket
import "unsafe"
func (h *msghdr) pack(vs []iovec, bs [][]byte, oob []byte, sa []byte) {
for i := range vs {
vs[i].set(bs[i])
}
if len(vs) > 0 {
h.Iov = &vs[0]
h.Iovlen = int32(len(vs))
}
if len(oob) > 0 {
h.Accrights = (*int8)(unsafe.Pointer(&oob[0]))
h.Accrightslen = int32(len(oob))
}
if sa != nil {
h.Name = (*byte)(unsafe.Pointer(&sa[0]))
h.Namelen = uint32(len(sa))
}
}
func (h *msghdr) controllen() int {
return int(h.Accrightslen)
}
func (h *msghdr) flags() int {
return int(NativeEndian.Uint32(h.Pad_cgo_2[:]))
}

15
vendor/golang.org/x/net/internal/socket/msghdr_stub.go generated vendored Normal file
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@ -0,0 +1,15 @@
// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build !aix && !darwin && !dragonfly && !freebsd && !linux && !netbsd && !openbsd && !solaris && !zos
// +build !aix,!darwin,!dragonfly,!freebsd,!linux,!netbsd,!openbsd,!solaris,!zos
package socket
type msghdr struct{}
func (h *msghdr) pack(vs []iovec, bs [][]byte, oob []byte, sa []byte) {}
func (h *msghdr) name() []byte { return nil }
func (h *msghdr) controllen() int { return 0 }
func (h *msghdr) flags() int { return 0 }

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@ -0,0 +1,36 @@
// Copyright 2020 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build s390x && zos
// +build s390x,zos
package socket
import "unsafe"
func (h *msghdr) pack(vs []iovec, bs [][]byte, oob []byte, sa []byte) {
for i := range vs {
vs[i].set(bs[i])
}
if len(vs) > 0 {
h.Iov = &vs[0]
h.Iovlen = int32(len(vs))
}
if len(oob) > 0 {
h.Control = (*byte)(unsafe.Pointer(&oob[0]))
h.Controllen = uint32(len(oob))
}
if sa != nil {
h.Name = (*byte)(unsafe.Pointer(&sa[0]))
h.Namelen = uint32(len(sa))
}
}
func (h *msghdr) controllen() int {
return int(h.Controllen)
}
func (h *msghdr) flags() int {
return int(h.Flags)
}

13
vendor/golang.org/x/net/internal/socket/norace.go generated vendored Normal file
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@ -0,0 +1,13 @@
// Copyright 2019 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build !race
// +build !race
package socket
func (m *Message) raceRead() {
}
func (m *Message) raceWrite() {
}

38
vendor/golang.org/x/net/internal/socket/race.go generated vendored Normal file
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@ -0,0 +1,38 @@
// Copyright 2019 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build race
// +build race
package socket
import (
"runtime"
"unsafe"
)
// This package reads and writes the Message buffers using a
// direct system call, which the race detector can't see.
// These functions tell the race detector what is going on during the syscall.
func (m *Message) raceRead() {
for _, b := range m.Buffers {
if len(b) > 0 {
runtime.RaceReadRange(unsafe.Pointer(&b[0]), len(b))
}
}
if b := m.OOB; len(b) > 0 {
runtime.RaceReadRange(unsafe.Pointer(&b[0]), len(b))
}
}
func (m *Message) raceWrite() {
for _, b := range m.Buffers {
if len(b) > 0 {
runtime.RaceWriteRange(unsafe.Pointer(&b[0]), len(b))
}
}
if b := m.OOB; len(b) > 0 {
runtime.RaceWriteRange(unsafe.Pointer(&b[0]), len(b))
}
}

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