mirror of
https://github.com/docker/docker-credential-helpers.git
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Sebastiaan van Stijn
d930f0631a
- https://github.com/golang/go/issues?q=milestone%3AGo1.26.3+label%3ACherryPickApproved - full diff: https://github.com/golang/go/compare/go1.26.2...go1.26.3 This release include 11 security fixes: - cmd/go: malicious module proxy can bypass checksum database A malicious module proxy could exploit a flaw in the go command's validation of module checksums to bypass checksum database validation. This vulnerability affects any user using an untrusted module proxy (GOMODPROXY) or checksum database (GOSUMDB). A malicious module proxy can serve altered versions of the Go toolchain. When selecting a different version of the Go toolchain than the currently installed toolchain (due to the GOTOOLCHAIN environment variable, or a go.work or go.mod with a toolchain line), the go command will download and execute a toolchain provided by the module proxy. A malicious module proxy can bypass checksum database validation for this downloaded toolchain. Since this vulnerability affects the security of toolchain downloads, setting GOTOOLCHAIN to a fixed version is not sufficient. You must upgrade your base Go toolchain. The go tool always validates the hash of a toolchain before executing it, so fixed versions will refuse to execute any cached, altered versions of the toolchain. The go tool trusts go.sum files to contain accurate hashes of the current module's dependencies. A malicious proxy exploiting this vulnerability to serve an altered module will have caused an incorrect hash to be recorded in the go.sum. Users who have configured a non-trusted GOPROXY can determine if they have been affected by running "rm go.sum ; go mod tidy ; go mod verify", which will revalidate all dependencies of the current module. The specific flaw in more detail: The go command consults the checksum database to validate downloaded modules, when a module is not listed in the go.sum file. It verifies that the module hash reported by the checksum database matches the hash of the downloaded module. If, however, the checksum database returns a successful response that contains no entry for the module, the go command incorrectly permitted validation to succeed. A module proxy may mirror or proxy the checksum database, in which case the go command will not connect to the checksum database directly. Checksums reported by the checksum database are cryptographically signed, so a malicious proxy cannot alter the reported checksum for a module. However, a proxy which returns an empty checksum response, or a checksum response for an unrelated module, could cause the go command to proceed as if a downloaded module has been validated. The go command now properly checks checksum database responses to ensure that the expected module signature is present, not just that if a signature is present it matches the expectation. Thanks to Mundur (https://github.com/M0nd0R) for reporting this issue. This is CVE-2026-42501 and Go issue https://go.dev/issue/79070. - net/http/httputil: ReverseProxy forwards queries with more than urlmaxqueryparams parameters When used with a Rewrite function, or a Director function which parses query parameters, ReverseProxy sanitizes the forwarded request to remove query parameters which are not parsed by url.ParseQuery. ReverseProxy did not take ParseQuery's limit on the total number of query parameters (controlled by GODEBUG=urlmaxqueryparams=N) into account. This could permit ReverseProxy to forward a request containing a query parameter that was not visible to the Rewrite function. For example, the query "a1=x&a2=x&...&a10000=x&hidden=y" could forward the parameter "hidden=y" while hiding it from the proxy's Rewrite function. ReverseProxy now avoids forwarding parameters that exceed the ParseQuery limit. This is CVE-2026-39825 and Go issue https://go.dev/issue/78948. - net: panic in Dial and LookupPort when handling NUL byte on Windows The Dial and LookupPort functions would panic on Windows when provided with an input containing a NUL (0). These functions now return an error rather than panicking. This is CVE-2026-39836 and Go issue https://go.dev/issue/79006. - net/mail: quadratic string concatenation in consumePhrase Pathological inputs could cause DoS through consumePhrase when parsing an email address according to RFC 5322. This is CVE-2026-42499 and Go issue https://go.dev/issue/78987. - net/mail: quadratic string concatentation in consumeComment Well-crafted inputs reaching ParseAddress, ParseAddressList, and ParseDate were able to trigger excessive CPU exhaustion and memory allocations. This is CVE-2026-39820 and Go issue https://go.dev/issue/78566. - cmd/go: "go bug" follows symlinks in predictable temporary filenames The "go bug" command wrote to two files with predictable names in the system temporary directory (for example, "/tmp"). An attacker with access to the temporary directory could create a symlink in one of these names, causing "go bug" to overwrite the target of the symlink. The "go bug" command now uses os.MkdirTemp to create a safe working directory. Thanks to Harshit Gupta (Mr HAX) for reporting this issue. This is CVE-2026-39819 and Go issue https://go.dev/issue/78584. - cmd/go: "go tool pack" does not sanitize output paths The "go tool pack" subcommand is a minimal version of the Unix ar utility. It is used by the compiler as an internal tool with known-good inputs. The "pack" subcommand did not sanitize output filenames. When invoked to extract a malicious archive file, it could write files to arbitrary locations on the filesystem. The "pack" subcommand now refuses to extract files with names containing any directory components. Thanks to Harshit Gupta (Mr HAX) for reporting this issue. This is CVE-2026-39817 and Go issue https://go.dev/issue/78778. - net/http: infinite loop in HTTP/2 transport when given bad SETTINGS_MAX_FRAME_SIZE When processing HTTP/2 SETTINGS frames, transport will enter an infinite loop of writing CONTINUATION frames if it receives a SETTINGS_MAX_FRAME_SIZE with a value of 0. This allows potential DoS against a client by a malicious server. HTTP/2 transport now properly checks that the received SETTINGS_MAX_FRAME_SIZE is valid. Thanks to Marwan Atia (marwansamir688@gmail.com) for reporting this issue. This is CVE-2026-33814 and Go issue https://go.dev/issue/78476. - html/template: escaper bypass leads to XSS If a trusted template author were to write a tag containing an empty type attribute or a type attribute with an ASCII whitespace, the execution of the template would incorrectly escape any data passed into the block. Thanks to Mundur (https://github.com/M0nd0R) for reporting this issue. This is CVE-2026-39826 and Go issue https://go.dev/issue/78981. - net: crash when handling long CNAME response When using LookupCNAME with the cgo DNS resolver, a very long CNAME response could trigger a double-free of C memory and a crash. The double-free has been fixed. Thanks to hamayanhamayan for reporting this issue. This is CVE-2026-33811 and Go issue https://go.dev/issue/78803. - html/template: bypass of meta content URL escaping causes XSS CVE-2026-27142 fixed a vulnerability in which URLs were not correctly escaped inside of a tag's attribute. If the URL content were to insert ASCII whitespaces around the = rune inside of the attribute, the escaper would fail to similarly escape it, leading to XSS. Dynamic inputs to a tag's attribute are now whitespace sanitized prior to escaping. Thanks to Samy Ghannad for reporting this issue. Signed-off-by: Sebastiaan van Stijn <github@gone.nl>
Introduction
docker-credential-helpers is a suite of programs to use native stores to keep Docker credentials safe.
Installation
Go to the Releases page and download the binary that works better for you. Put that binary in your $PATH, so Docker can find it.
Building
You can build the credential helpers using Docker:
# install emulators
$ docker run --privileged --rm tonistiigi/binfmt --install all
# create builder
$ docker buildx create --use
# build credential helpers from remote repository and output to ./bin/build
$ docker buildx bake "https://github.com/docker/docker-credential-helpers.git"
# or from local source
$ git clone https://github.com/docker/docker-credential-helpers.git
$ cd docker-credential-helpers
$ docker buildx bake
Or if the toolchain is already installed on your machine:
- Download the source.
$ git clone https://github.com/docker/docker-credential-helpers.git
$ cd docker-credential-helpers
- Use
maketo build the program you want. That will leave an executable in thebindirectory inside the repository.
$ make osxkeychain
- Put that binary in your
$PATH, so Docker can find it.
$ cp bin/build/docker-credential-osxkeychain /usr/local/bin/
Usage
With the Docker Engine
Set the credsStore option in your ~/.docker/config.json file with the suffix of the program you want to use. For instance, set it to osxkeychain if you want to use docker-credential-osxkeychain.
{
"credsStore": "osxkeychain"
}
With other command line applications
The sub-package client includes functions to call external programs from your own command line applications.
There are three things you need to know if you need to interact with a helper:
- The name of the program to execute, for instance
docker-credential-osxkeychain. - The server address to identify the credentials, for instance
https://example.com. - The username and secret to store, when you want to store credentials.
You can see examples of each function in the client documentation.
Available programs
- osxkeychain: Provides a helper to use the OS X keychain as credentials store.
- secretservice: Provides a helper to use the D-Bus secret service as credentials store.
- wincred: Provides a helper to use Windows credentials manager as store.
- pass: Provides a helper to use
passas credentials store.
Note
pass needs to be configured for docker-credential-pass to work properly.
It must be initialized with a gpg2 key ID. Make sure your GPG key exists is in gpg2 keyring as pass uses gpg2 instead of the regular gpg.
Development
A credential helper can be any program that can read values from the standard input. We use the first argument in the command line to differentiate the kind of command to execute. There are four valid values:
store: Adds credentials to the keychain. The payload in the standard input is a JSON document withServerURL,UsernameandSecret.get: Retrieves credentials from the keychain. The payload in the standard input is the raw value for theServerURL.erase: Removes credentials from the keychain. The payload in the standard input is the raw value for theServerURL.list: Lists stored credentials. There is no standard input payload.
This repository also includes libraries to implement new credentials programs in Go. Adding a new helper program is pretty easy. You can see how the OS X keychain helper works in the osxkeychain directory.
- Implement the interface
credentials.HelperinYOUR_PACKAGE/ - Create a main program in
YOUR_PACKAGE/cmd/. - Add make tasks to build your program and run tests.
License
MIT. See LICENSE for more information.