Summary:
We're currently returning a fake value on all of our automation builds. Might
as well not run the script at all.
Tags: #secure-revision
Bug #: 1371485
Differential Revision: https://phabricator.services.mozilla.com/D1803
--HG--
extra : rebase_source : 642aa33c31d2912e402b2e3775629608d5922eb6
When I originally implemented bug 1458161, this is how it was done, but
it was suggested to use a configure-time check. This turned out to not
be great, because the rust compiler changes regularly, and we don't run
the configure tests when the version changes. When people upgraded their
rust compiler to 1.27, the code subsequently failed to build because the
features were still set for the previous version they had installed.
--HG--
extra : rebase_source : 1b5f7a02ad8495d68cd29289f7beea59b8912183
When a binary has a PT_GNU_RELRO segment, the elfhack injected code
uses mprotect to add the writable flag to relocated pages before
applying relocations, removing it afterwards. To do so, the elfhack
program uses the location and size of the PT_GNU_RELRO segment, and
adjusts it to be aligned according to the PT_LOAD alignment.
The problem here is that the PT_LOAD alignment doesn't necessarily match
the actual page alignment, and the resulting mprotect may end up not
covering the full extent of what the dynamic linker has protected
read-only according to the PT_GNU_RELRO segment. In turn, this can lead
to a crash on startup when trying to apply relocations to the still
read-only locations.
Practically speaking, this doesn't end up being a problem on x86, where
the PT_LOAD alignment is usually 4096, which happens to be the page
size, but on Debian armhf, it is 64k, while the run time page size can be
4k.
--HG--
extra : rebase_source : 5ac7356f685d87c1628727e6c84f7615409c57a5
We're well overdue for an upgrade of the rust compiler requirements.
Now that we're building with 1.28 (albeit a beta, due to be bumped when
it's released), we can bump the requirement away from 1.24 which is now
old. 1.27 is too new, though, so settle for the older 1.26.
--HG--
extra : rebase_source : c788ef4f7da9949b81df2f0577af6f6039ea63d8
When we're running using pipenv, we have more than one virtual environment. This means the current check to see if python matches the initial virtual environment gives a false positive when we're in a secondary virtual environment. This patch changes the condition to check if the current python path exists within the virtual environments root directory.
MozReview-Commit-ID: AAONwLWsigL
--HG--
extra : rebase_source : c0ac94448ee4545417b5116e58b51c6187cdb175
We used to do that before bug 1455767. Taking a step back, what we want
(and what this change implements) is to:
- allow to specify a linker to use explicitly
- check that using the corresponding linker flags makes us use that
linker
- if no linker is specified, and developer options are enabled, we want
to try to use gold if it's available, otherwise, we want to detect
what kind of linker the default linker is
- if --disable-gold is explicitly given, we don't want to automatically
use it.
--HG--
extra : rebase_source : 8d89c54bd5e555984d815beb8fdd3f5f75dae31e
Instead of clang 4, which they were the last to use, so remove the
clang 4 toolchain.
--HG--
extra : rebase_source : d03a083e9217aeb6c1d2c91decb978426f0e8d1a
The linux64-clang toolchain alias is currently clang 5. Switch it to
clang 6, but keep the spidermonkey tsan builds on clang 5 because of
bug 1467673.
The LLVM headers that come with clang 6 contain a DEBUG define that
conflicts with our DEBUG define and breaks the clang-plugin build,
so force unset ours.
--HG--
extra : rebase_source : aae88f1166108f003b06c022f14d5f4c61fc1ed9
Also work around https://bugs.llvm.org/show_bug.cgi?id=37746 by
explicitly handling ObjC interface variables separately. This actually
allows the searchfox macosx build to go much further than it used to (it
now fails during make package with apparently no output for rust code)
--HG--
extra : rebase_source : 354981ca9deebed5c60d3684f5c3abc554422393
We used to do that before bug 1455767. Taking a step back, what we want
(and what this change implements) is to:
- allow to specify a linker to use explicitly
- check that using the corresponding linker flags makes us use that
linker
- if no linker is specified, and developer options are enabled, we want
to try to use gold if it's available, otherwise, we want to detect
what kind of linker the default linker is
--HG--
extra : rebase_source : 655089f29c6403f6c31a977dcf5c6fd1e9941121
--enable-release not being passed means developer options are enabled,
which is generally speaking not desirable for builds meant to be
shipped. This is somewhat alleviated for Firefox by MOZILLA_OFFICIAL
implying --enable-release (as well as MOZ_AUTOMATION), but that doesn't
apply to e.g. standalone js builds (even some of the standalone js jobs
on our automation don't set MOZ_AUTOMATION for some reason).
A reasonable thing to do is just to default builds for release/beta
milestones to --enable-release, but still allow --disable-release
to enable the developer options.
--HG--
extra : rebase_source : 770d51b10a9cd17c63972435bb61eed10345ea71
Currently, many tasks fetch content from the Internets. A problem with
that is fetching from the Internets is unreliable: servers may have
outages or be slow; content may disappear or change out from under us.
The unreliability of 3rd party services poses a risk to Firefox CI.
If services aren't available, we could potentially not run some CI tasks.
In the worst case, we might not be able to release Firefox. That would
be bad. In fact, as I write this, gmplib.org has been unavailable for
~24 hours and Firefox CI is unable to retrieve the GMP source code.
As a result, building GCC toolchains is failing.
A solution to this is to make tasks more hermetic by depending on
fewer network services (which by definition aren't reliable over time
and therefore introduce instability).
This commit attempts to mitigate some external service dependencies
by introducing the *fetch* task kind.
The primary goal of the *fetch* kind is to obtain remote content and
re-expose it as a task artifact. By making external content available
as a cached task artifact, we allow dependent tasks to consume this
content without touching the service originally providing that
content, thus eliminating a run-time dependency and making tasks more
hermetic and reproducible over time.
We introduce a single "fetch-url" "using" flavor to define tasks that
fetch single URLs and then re-expose that URL as an artifact. Powering
this is a new, minimal "fetch" Docker image that contains a
"fetch-content" Python script that does the work for us.
We have added tasks to fetch source archives used to build the GCC
toolchains.
Fetching remote content and re-exposing it as an artifact is not
very useful by itself: the value is in having tasks use those
artifacts.
We introduce a taskgraph transform that allows tasks to define an
array of "fetches." Each entry corresponds to the name of a "fetch"
task kind. When present, the corresponding "fetch" task is added as a
dependency. And the task ID and artifact path from that "fetch" task
is added to the MOZ_FETCHES environment variable of the task depending
on it. Our "fetch-content" script has a "task-artifacts"
sub-command that tasks can execute to perform retrieval of all
artifacts listed in MOZ_FETCHES.
To prove all of this works, the code for fetching dependencies when
building GCC toolchains has been updated to use `fetch-content`. The
now-unused legacy code has been deleted.
This commit improves the reliability and efficiency of GCC toolchain
tasks. Dependencies now all come from task artifacts and should always
be available in the common case. In addition, `fetch-content` downloads
and extracts files concurrently. This makes it faster than the serial
application which we were previously using.
There are some things I don't like about this commit.
First, a new Docker image and Python script for downloading URLs feels
a bit heavyweight. The Docker image is definitely overkill as things
stand. I can eventually justify it because I want to implement support
for fetching and repackaging VCS repositories and for caching Debian
packages. These will require more packages than what I'm comfortable
installing on the base Debian image, therefore justifying a dedicated
image.
The `fetch-content static-url` sub-command could definitely be
implemented as a shell script. But Python is readily available and
is more pleasant to maintain than shell, so I wrote it in Python.
`fetch-content task-artifacts` is more advanced and writing it in
Python is more justified, IMO. FWIW, the script is Python 3 only,
which conveniently gives us access to `concurrent.futures`, which
facilitates concurrent download.
`fetch-content` also duplicates functionality found elsewhere.
generic-worker's task payload supports a "mounts" feature which
facilitates downloading remote content, including from a task
artifact. However, this feature doesn't exist on docker-worker.
So we have to implement downloading inside the task rather than
at the worker level. I concede that if all workers had generic-worker's
"mounts" feature and supported concurrent download, `fetch-content`
wouldn't need to exist.
`fetch-content` also duplicates functionality of
`mach artifact toolchain`. I probably could have used
`mach artifact toolchain` instead of writing
`fetch-content task-artifacts`. However, I didn't want to introduce
the requirement of a VCS checkout. `mach artifact toolchain` has its
origins in providing a feature to the build system. And "fetching
artifacts from tasks" is a more generic feature than that. I think
it should be implemented as a generic feature and not something that is
"toolchain" specific.
I think the best place for a generic "fetch content" feature is in
the worker, where content can be defined in the task payload. But as
explained above, that feature isn't universally available. The next
best place is probably run-task. run-task already performs generic,
very-early task preparation steps, such as performing a VCS checkout.
I would like to fold `fetch-content` into run-task and make it all
driven by environment variables. But run-task is currently Python 2
and achieving concurrency would involve a bit of programming (or
adding package dependencies). I may very well port run-task to Python
3 and then fold fetch-content into it. Or maybe we leave
`fetch-content` as a standalone script.
MozReview-Commit-ID: AGuTcwNcNJR
--HG--
extra : source : 0b941cbdca76fb2fbb98dc5bbc1a0237c69954d0
extra : histedit_source : a3e43bdd8a9a58550bef02fec3be832ca304ea93
After this change, we consistently import GPG keys from files in
the GCC build scripts.
MozReview-Commit-ID: BcyvCQoGbMS
--HG--
extra : source : 5fce34a460b51e45ac280a9f0cb8bad896fbcff1
extra : histedit_source : 01621ea8111315c251a9493a11efca72c2ba3c7d
Currently, many tasks fetch content from the Internets. A problem with
that is fetching from the Internets is unreliable: servers may have
outages or be slow; content may disappear or change out from under us.
The unreliability of 3rd party services poses a risk to Firefox CI.
If services aren't available, we could potentially not run some CI tasks.
In the worst case, we might not be able to release Firefox. That would
be bad. In fact, as I write this, gmplib.org has been unavailable for
~24 hours and Firefox CI is unable to retrieve the GMP source code.
As a result, building GCC toolchains is failing.
A solution to this is to make tasks more hermetic by depending on
fewer network services (which by definition aren't reliable over time
and therefore introduce instability).
This commit attempts to mitigate some external service dependencies
by introducing the *fetch* task kind.
The primary goal of the *fetch* kind is to obtain remote content and
re-expose it as a task artifact. By making external content available
as a cached task artifact, we allow dependent tasks to consume this
content without touching the service originally providing that
content, thus eliminating a run-time dependency and making tasks more
hermetic and reproducible over time.
We introduce a single "fetch-url" "using" flavor to define tasks that
fetch single URLs and then re-expose that URL as an artifact. Powering
this is a new, minimal "fetch" Docker image that contains a
"fetch-content" Python script that does the work for us.
We have added tasks to fetch source archives used to build the GCC
toolchains.
Fetching remote content and re-exposing it as an artifact is not
very useful by itself: the value is in having tasks use those
artifacts.
We introduce a taskgraph transform that allows tasks to define an
array of "fetches." Each entry corresponds to the name of a "fetch"
task kind. When present, the corresponding "fetch" task is added as a
dependency. And the task ID and artifact path from that "fetch" task
is added to the MOZ_FETCHES environment variable of the task depending
on it. Our "fetch-content" script has a "task-artifacts"
sub-command that tasks can execute to perform retrieval of all
artifacts listed in MOZ_FETCHES.
To prove all of this works, the code for fetching dependencies when
building GCC toolchains has been updated to use `fetch-content`. The
now-unused legacy code has been deleted.
This commit improves the reliability and efficiency of GCC toolchain
tasks. Dependencies now all come from task artifacts and should always
be available in the common case. In addition, `fetch-content` downloads
and extracts files concurrently. This makes it faster than the serial
application which we were previously using.
There are some things I don't like about this commit.
First, a new Docker image and Python script for downloading URLs feels
a bit heavyweight. The Docker image is definitely overkill as things
stand. I can eventually justify it because I want to implement support
for fetching and repackaging VCS repositories and for caching Debian
packages. These will require more packages than what I'm comfortable
installing on the base Debian image, therefore justifying a dedicated
image.
The `fetch-content static-url` sub-command could definitely be
implemented as a shell script. But Python is readily available and
is more pleasant to maintain than shell, so I wrote it in Python.
`fetch-content task-artifacts` is more advanced and writing it in
Python is more justified, IMO. FWIW, the script is Python 3 only,
which conveniently gives us access to `concurrent.futures`, which
facilitates concurrent download.
`fetch-content` also duplicates functionality found elsewhere.
generic-worker's task payload supports a "mounts" feature which
facilitates downloading remote content, including from a task
artifact. However, this feature doesn't exist on docker-worker.
So we have to implement downloading inside the task rather than
at the worker level. I concede that if all workers had generic-worker's
"mounts" feature and supported concurrent download, `fetch-content`
wouldn't need to exist.
`fetch-content` also duplicates functionality of
`mach artifact toolchain`. I probably could have used
`mach artifact toolchain` instead of writing
`fetch-content task-artifacts`. However, I didn't want to introduce
the requirement of a VCS checkout. `mach artifact toolchain` has its
origins in providing a feature to the build system. And "fetching
artifacts from tasks" is a more generic feature than that. I think
it should be implemented as a generic feature and not something that is
"toolchain" specific.
I think the best place for a generic "fetch content" feature is in
the worker, where content can be defined in the task payload. But as
explained above, that feature isn't universally available. The next
best place is probably run-task. run-task already performs generic,
very-early task preparation steps, such as performing a VCS checkout.
I would like to fold `fetch-content` into run-task and make it all
driven by environment variables. But run-task is currently Python 2
and achieving concurrency would involve a bit of programming (or
adding package dependencies). I may very well port run-task to Python
3 and then fold fetch-content into it. Or maybe we leave
`fetch-content` as a standalone script.
MozReview-Commit-ID: AGuTcwNcNJR
--HG--
extra : rebase_source : 4918b8c3bac53d63665006802054038bfbca0314
After this change, we consistently import GPG keys from files in
the GCC build scripts.
MozReview-Commit-ID: BcyvCQoGbMS
--HG--
extra : rebase_source : 657ccce8e242cabdfaff396fd0d6439754a3f364
python-zstandard's 0.9.1 source distribution contains a debian/
directory.
On Squeeze, producing a Debian package is straightforward.
On Wheezy, we need to hack up Build-Depends because Wheezy doesn't
have a package for the Hypothesis fuzzing library. This package is
only used for testing and our package building disables testing,
so we don't even need to further hack up the packaging to disable
tests.
MozReview-Commit-ID: 6raXjdzggCH
--HG--
extra : rebase_source : 672492a40d65df8430eb17ba033bcb1c0890b7df
This build target doesn't have LTO enabled on it (yet)
MozReview-Commit-ID: 56tAHMyvH7o
--HG--
extra : rebase_source : 90039cd8e97332e2ef8aad7908b8a04b2869f4a5