rust/appveyor.yml

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environment:
2017-07-19 07:57:56 -05:00
# By default schannel checks revocation of certificates unlike some other SSL
# backends, but we've historically had problems on CI where a revocation
# server goes down presumably. See #43333 for more info
CARGO_HTTP_CHECK_REVOKE: false
matrix:
# 32/64 bit MSVC tests
- MSYS_BITS: 64
RUST_CONFIGURE_ARGS: --build=x86_64-pc-windows-msvc --enable-profiler
SCRIPT: python x.py test
CI_JOB_NAME: x86_64-msvc
- MSYS_BITS: 32
RUST_CONFIGURE_ARGS: --build=i686-pc-windows-msvc
SCRIPT: make appveyor-subset-1
CI_JOB_NAME: i686-msvc-1
- MSYS_BITS: 32
RUST_CONFIGURE_ARGS: --build=i686-pc-windows-msvc
SCRIPT: make appveyor-subset-2
CI_JOB_NAME: i686-msvc-2
# MSVC aux tests
- MSYS_BITS: 64
2018-03-07 15:57:17 -06:00
RUST_CHECK_TARGET: check-aux EXCLUDE_CARGO=1
RUST_CONFIGURE_ARGS: --build=x86_64-pc-windows-msvc
CI_JOB_NAME: x86_64-msvc-aux
- MSYS_BITS: 64
SCRIPT: python x.py test src/tools/cargotest src/tools/cargo
RUST_CONFIGURE_ARGS: --build=x86_64-pc-windows-msvc
CI_JOB_NAME: x86_64-msvc-cargo
# MSVC tools tests
- MSYS_BITS: 64
SCRIPT: src/ci/docker/x86_64-gnu-tools/checktools.sh x.py /tmp/toolstates.json windows
RUST_CONFIGURE_ARGS: --build=x86_64-pc-windows-msvc --save-toolstates=/tmp/toolstates.json --enable-test-miri
CI_JOB_NAME: x86_64-msvc-tools
# 32/64-bit MinGW builds.
#
2017-04-14 04:27:35 -05:00
# We are using MinGW with posix threads since LLVM does not compile with
# the win32 threads version due to missing support for C++'s std::thread.
#
2017-04-14 04:27:35 -05:00
# Instead of relying on the MinGW version installed on appveryor we download
# and install one ourselves so we won't be surprised by changes to appveyor's
# build image.
#
# Finally, note that the downloads below are all in the `rust-lang-ci` S3
# bucket, but they cleraly didn't originate there! The downloads originally
# came from the mingw-w64 SourceForge download site. Unfortunately
# SourceForge is notoriously flaky, so we mirror it on our own infrastructure.
- MSYS_BITS: 32
RUST_CONFIGURE_ARGS: --build=i686-pc-windows-gnu
SCRIPT: make appveyor-subset-1
MINGW_URL: https://s3-us-west-1.amazonaws.com/rust-lang-ci2/rust-ci-mirror
MINGW_ARCHIVE: i686-6.3.0-release-posix-dwarf-rt_v5-rev2.7z
MINGW_DIR: mingw32
CI_JOB_NAME: i686-mingw-1
- MSYS_BITS: 32
RUST_CONFIGURE_ARGS: --build=i686-pc-windows-gnu
SCRIPT: make appveyor-subset-2
MINGW_URL: https://s3-us-west-1.amazonaws.com/rust-lang-ci2/rust-ci-mirror
MINGW_ARCHIVE: i686-6.3.0-release-posix-dwarf-rt_v5-rev2.7z
MINGW_DIR: mingw32
CI_JOB_NAME: i686-mingw-2
- MSYS_BITS: 64
SCRIPT: python x.py test
RUST_CONFIGURE_ARGS: --build=x86_64-pc-windows-gnu
MINGW_URL: https://s3-us-west-1.amazonaws.com/rust-lang-ci2/rust-ci-mirror
MINGW_ARCHIVE: x86_64-6.3.0-release-posix-seh-rt_v5-rev2.7z
MINGW_DIR: mingw64
CI_JOB_NAME: x86_64-mingw
# 32/64 bit MSVC and GNU deployment
- RUST_CONFIGURE_ARGS: >
--build=x86_64-pc-windows-msvc
--target=x86_64-pc-windows-msvc,aarch64-pc-windows-msvc
rust: Import LLD for linking wasm objects This commit imports the LLD project from LLVM to serve as the default linker for the `wasm32-unknown-unknown` target. The `binaryen` submoule is consequently removed along with "binaryen linker" support in rustc. Moving to LLD brings with it a number of benefits for wasm code: * LLD is itself an actual linker, so there's no need to compile all wasm code with LTO any more. As a result builds should be *much* speedier as LTO is no longer forcibly enabled for all builds of the wasm target. * LLD is quickly becoming an "official solution" for linking wasm code together. This, I believe at least, is intended to be the main supported linker for native code and wasm moving forward. Picking up support early on should help ensure that we can help LLD identify bugs and otherwise prove that it works great for all our use cases! * Improvements to the wasm toolchain are currently primarily focused around LLVM and LLD (from what I can tell at least), so it's in general much better to be on this bandwagon for bugfixes and new features. * Historical "hacks" like `wasm-gc` will soon no longer be necessary, LLD will [natively implement][gc] `--gc-sections` (better than `wasm-gc`!) which means a postprocessor is no longer needed to show off Rust's "small wasm binary size". LLD is added in a pretty standard way to rustc right now. A new rustbuild target was defined for building LLD, and this is executed when a compiler's sysroot is being assembled. LLD is compiled against the LLVM that we've got in tree, which means we're currently on the `release_60` branch, but this may get upgraded in the near future! LLD is placed into rustc's sysroot in a `bin` directory. This is similar to where `gcc.exe` can be found on Windows. This directory is automatically added to `PATH` whenever rustc executes the linker, allowing us to define a `WasmLd` linker which implements the interface that `wasm-ld`, LLD's frontend, expects. Like Emscripten the LLD target is currently only enabled for Tier 1 platforms, notably OSX/Windows/Linux, and will need to be installed manually for compiling to wasm on other platforms. LLD is by default turned off in rustbuild, and requires a `config.toml` option to be enabled to turn it on. Finally the unstable `#![wasm_import_memory]` attribute was also removed as LLD has a native option for controlling this. [gc]: https://reviews.llvm.org/D42511
2017-08-26 20:30:12 -05:00
--enable-full-tools
--enable-profiler
SCRIPT: python x.py dist
DIST_REQUIRE_ALL_TOOLS: 1
DEPLOY: 1
CI_JOB_NAME: dist-x86_64-msvc
APPVEYOR_BUILD_WORKER_IMAGE: Visual Studio 2017 Preview
- RUST_CONFIGURE_ARGS: >
--build=i686-pc-windows-msvc
--target=i586-pc-windows-msvc
rust: Import LLD for linking wasm objects This commit imports the LLD project from LLVM to serve as the default linker for the `wasm32-unknown-unknown` target. The `binaryen` submoule is consequently removed along with "binaryen linker" support in rustc. Moving to LLD brings with it a number of benefits for wasm code: * LLD is itself an actual linker, so there's no need to compile all wasm code with LTO any more. As a result builds should be *much* speedier as LTO is no longer forcibly enabled for all builds of the wasm target. * LLD is quickly becoming an "official solution" for linking wasm code together. This, I believe at least, is intended to be the main supported linker for native code and wasm moving forward. Picking up support early on should help ensure that we can help LLD identify bugs and otherwise prove that it works great for all our use cases! * Improvements to the wasm toolchain are currently primarily focused around LLVM and LLD (from what I can tell at least), so it's in general much better to be on this bandwagon for bugfixes and new features. * Historical "hacks" like `wasm-gc` will soon no longer be necessary, LLD will [natively implement][gc] `--gc-sections` (better than `wasm-gc`!) which means a postprocessor is no longer needed to show off Rust's "small wasm binary size". LLD is added in a pretty standard way to rustc right now. A new rustbuild target was defined for building LLD, and this is executed when a compiler's sysroot is being assembled. LLD is compiled against the LLVM that we've got in tree, which means we're currently on the `release_60` branch, but this may get upgraded in the near future! LLD is placed into rustc's sysroot in a `bin` directory. This is similar to where `gcc.exe` can be found on Windows. This directory is automatically added to `PATH` whenever rustc executes the linker, allowing us to define a `WasmLd` linker which implements the interface that `wasm-ld`, LLD's frontend, expects. Like Emscripten the LLD target is currently only enabled for Tier 1 platforms, notably OSX/Windows/Linux, and will need to be installed manually for compiling to wasm on other platforms. LLD is by default turned off in rustbuild, and requires a `config.toml` option to be enabled to turn it on. Finally the unstable `#![wasm_import_memory]` attribute was also removed as LLD has a native option for controlling this. [gc]: https://reviews.llvm.org/D42511
2017-08-26 20:30:12 -05:00
--enable-full-tools
--enable-profiler
SCRIPT: python x.py dist
DIST_REQUIRE_ALL_TOOLS: 1
DEPLOY: 1
CI_JOB_NAME: dist-i686-msvc
- MSYS_BITS: 32
rust: Import LLD for linking wasm objects This commit imports the LLD project from LLVM to serve as the default linker for the `wasm32-unknown-unknown` target. The `binaryen` submoule is consequently removed along with "binaryen linker" support in rustc. Moving to LLD brings with it a number of benefits for wasm code: * LLD is itself an actual linker, so there's no need to compile all wasm code with LTO any more. As a result builds should be *much* speedier as LTO is no longer forcibly enabled for all builds of the wasm target. * LLD is quickly becoming an "official solution" for linking wasm code together. This, I believe at least, is intended to be the main supported linker for native code and wasm moving forward. Picking up support early on should help ensure that we can help LLD identify bugs and otherwise prove that it works great for all our use cases! * Improvements to the wasm toolchain are currently primarily focused around LLVM and LLD (from what I can tell at least), so it's in general much better to be on this bandwagon for bugfixes and new features. * Historical "hacks" like `wasm-gc` will soon no longer be necessary, LLD will [natively implement][gc] `--gc-sections` (better than `wasm-gc`!) which means a postprocessor is no longer needed to show off Rust's "small wasm binary size". LLD is added in a pretty standard way to rustc right now. A new rustbuild target was defined for building LLD, and this is executed when a compiler's sysroot is being assembled. LLD is compiled against the LLVM that we've got in tree, which means we're currently on the `release_60` branch, but this may get upgraded in the near future! LLD is placed into rustc's sysroot in a `bin` directory. This is similar to where `gcc.exe` can be found on Windows. This directory is automatically added to `PATH` whenever rustc executes the linker, allowing us to define a `WasmLd` linker which implements the interface that `wasm-ld`, LLD's frontend, expects. Like Emscripten the LLD target is currently only enabled for Tier 1 platforms, notably OSX/Windows/Linux, and will need to be installed manually for compiling to wasm on other platforms. LLD is by default turned off in rustbuild, and requires a `config.toml` option to be enabled to turn it on. Finally the unstable `#![wasm_import_memory]` attribute was also removed as LLD has a native option for controlling this. [gc]: https://reviews.llvm.org/D42511
2017-08-26 20:30:12 -05:00
RUST_CONFIGURE_ARGS: --build=i686-pc-windows-gnu --enable-full-tools
SCRIPT: python x.py dist
MINGW_URL: https://s3-us-west-1.amazonaws.com/rust-lang-ci2/rust-ci-mirror
MINGW_ARCHIVE: i686-6.3.0-release-posix-dwarf-rt_v5-rev2.7z
MINGW_DIR: mingw32
DIST_REQUIRE_ALL_TOOLS: 1
DEPLOY: 1
CI_JOB_NAME: dist-i686-mingw
- MSYS_BITS: 64
SCRIPT: python x.py dist
rust: Import LLD for linking wasm objects This commit imports the LLD project from LLVM to serve as the default linker for the `wasm32-unknown-unknown` target. The `binaryen` submoule is consequently removed along with "binaryen linker" support in rustc. Moving to LLD brings with it a number of benefits for wasm code: * LLD is itself an actual linker, so there's no need to compile all wasm code with LTO any more. As a result builds should be *much* speedier as LTO is no longer forcibly enabled for all builds of the wasm target. * LLD is quickly becoming an "official solution" for linking wasm code together. This, I believe at least, is intended to be the main supported linker for native code and wasm moving forward. Picking up support early on should help ensure that we can help LLD identify bugs and otherwise prove that it works great for all our use cases! * Improvements to the wasm toolchain are currently primarily focused around LLVM and LLD (from what I can tell at least), so it's in general much better to be on this bandwagon for bugfixes and new features. * Historical "hacks" like `wasm-gc` will soon no longer be necessary, LLD will [natively implement][gc] `--gc-sections` (better than `wasm-gc`!) which means a postprocessor is no longer needed to show off Rust's "small wasm binary size". LLD is added in a pretty standard way to rustc right now. A new rustbuild target was defined for building LLD, and this is executed when a compiler's sysroot is being assembled. LLD is compiled against the LLVM that we've got in tree, which means we're currently on the `release_60` branch, but this may get upgraded in the near future! LLD is placed into rustc's sysroot in a `bin` directory. This is similar to where `gcc.exe` can be found on Windows. This directory is automatically added to `PATH` whenever rustc executes the linker, allowing us to define a `WasmLd` linker which implements the interface that `wasm-ld`, LLD's frontend, expects. Like Emscripten the LLD target is currently only enabled for Tier 1 platforms, notably OSX/Windows/Linux, and will need to be installed manually for compiling to wasm on other platforms. LLD is by default turned off in rustbuild, and requires a `config.toml` option to be enabled to turn it on. Finally the unstable `#![wasm_import_memory]` attribute was also removed as LLD has a native option for controlling this. [gc]: https://reviews.llvm.org/D42511
2017-08-26 20:30:12 -05:00
RUST_CONFIGURE_ARGS: --build=x86_64-pc-windows-gnu --enable-full-tools
MINGW_URL: https://s3-us-west-1.amazonaws.com/rust-lang-ci2/rust-ci-mirror
MINGW_ARCHIVE: x86_64-6.3.0-release-posix-seh-rt_v5-rev2.7z
MINGW_DIR: mingw64
DIST_REQUIRE_ALL_TOOLS: 1
DEPLOY: 1
CI_JOB_NAME: dist-x86_64-mingw
# "alternate" deployment, see .travis.yml for more info
- MSYS_BITS: 64
RUST_CONFIGURE_ARGS: --build=x86_64-pc-windows-msvc --enable-extended --enable-profiler
SCRIPT: python x.py dist
DEPLOY_ALT: 1
CI_JOB_NAME: dist-x86_64-msvc-alt
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matrix:
fast_finish: true
clone_depth: 2
build: false
install:
# If we need to download a custom MinGW, do so here and set the path
# appropriately.
#
# Note that this *also* means that we're not using what is typically
# /mingw32/bin/python2.7.exe, which is a "correct" python interpreter where
# /usr/bin/python2.7.exe is not. To ensure we use the right interpreter we
# move `C:\Python27` ahead in PATH and then also make sure the `python2.7.exe`
# file exists in there (which it doesn't by default).
- if defined MINGW_URL appveyor-retry appveyor DownloadFile %MINGW_URL%/%MINGW_ARCHIVE%
- if defined MINGW_URL 7z x -y %MINGW_ARCHIVE% > nul
- if defined MINGW_URL set PATH=%CD%\%MINGW_DIR%\bin;C:\msys64\usr\bin;%PATH%
# If we're compiling for MSVC then we, like most other distribution builders,
# switch to clang as the compiler. This'll allow us eventually to enable LTO
# amongst LLVM and rustc. Note that we only do this on MSVC as I don't think
# clang has an output mode compatible with MinGW that we need. If it does we
# should switch to clang for MinGW as well!
#
# Note that the LLVM installer is an NSIS installer
#
# Original downloaded here came from
# http://releases.llvm.org/7.0.0/LLVM-7.0.0-win64.exe
- if NOT defined MINGW_URL appveyor-retry appveyor DownloadFile https://s3-us-west-1.amazonaws.com/rust-lang-ci2/rust-ci-mirror/LLVM-7.0.0-win64.exe
- if NOT defined MINGW_URL .\LLVM-7.0.0-win64.exe /S /NCRC /D=C:\clang-rust
- if NOT defined MINGW_URL set RUST_CONFIGURE_ARGS=%RUST_CONFIGURE_ARGS% --set llvm.clang-cl=C:\clang-rust\bin\clang-cl.exe
# Here we do a pretty heinous thing which is to mangle the MinGW installation
# we just had above. Currently, as of this writing, we're using MinGW-w64
# builds of gcc, and that's currently at 6.3.0. We use 6.3.0 as it appears to
# be the first version which contains a fix for #40546, builds randomly
# failing during LLVM due to ar.exe/ranlib.exe failures.
#
# Unfortunately, though, 6.3.0 *also* is the first version of MinGW-w64 builds
# to contain a regression in gdb (#40184). As a result if we were to use the
# gdb provided (7.11.1) then we would fail all debuginfo tests.
#
# In order to fix spurious failures (pretty high priority) we use 6.3.0. To
# avoid disabling gdb tests we download an *old* version of gdb, specifically
# that found inside the 6.2.0 distribution. We then overwrite the 6.3.0 gdb
# with the 6.2.0 gdb to get tests passing.
#
# Note that we don't literally overwrite the gdb.exe binary because it appears
# to just use gdborig.exe, so that's the binary we deal with instead.
- if defined MINGW_URL appveyor-retry appveyor DownloadFile %MINGW_URL%/2017-04-20-%MSYS_BITS%bit-gdborig.exe
- if defined MINGW_URL mv 2017-04-20-%MSYS_BITS%bit-gdborig.exe %MINGW_DIR%\bin\gdborig.exe
# Otherwise pull in the MinGW installed on appveyor
- if NOT defined MINGW_URL set PATH=C:\msys64\mingw%MSYS_BITS%\bin;C:\msys64\usr\bin;%PATH%
# Prefer the "native" Python as LLVM has trouble building with MSYS sometimes
- copy C:\Python27\python.exe C:\Python27\python2.7.exe
- set PATH=C:\Python27;%PATH%
# Download and install sccache
- appveyor-retry appveyor DownloadFile https://s3-us-west-1.amazonaws.com/rust-lang-ci2/rust-ci-mirror/2018-04-26-sccache-x86_64-pc-windows-msvc
- mv 2018-04-26-sccache-x86_64-pc-windows-msvc sccache.exe
- set PATH=%PATH%;%CD%
# Download and install ninja
#
# Note that this is originally from the github releases patch of Ninja
- appveyor-retry appveyor DownloadFile https://s3-us-west-1.amazonaws.com/rust-lang-ci2/rust-ci-mirror/2017-03-15-ninja-win.zip
- 7z x 2017-03-15-ninja-win.zip
- set RUST_CONFIGURE_ARGS=%RUST_CONFIGURE_ARGS% --enable-ninja
# - set PATH=%PATH%;%CD% -- this already happens above for sccache
# Install InnoSetup to get `iscc` used to produce installers
- appveyor-retry appveyor DownloadFile https://s3-us-west-1.amazonaws.com/rust-lang-ci2/rust-ci-mirror/2017-08-22-is.exe
- 2017-08-22-is.exe /VERYSILENT /SUPPRESSMSGBOXES /NORESTART /SP-
- set PATH="C:\Program Files (x86)\Inno Setup 5";%PATH%
# Help debug some handle issues on AppVeyor
- appveyor-retry appveyor DownloadFile https://s3-us-west-1.amazonaws.com/rust-lang-ci2/rust-ci-mirror/2017-05-15-Handle.zip
- mkdir handle
- 7z x -ohandle 2017-05-15-Handle.zip
- set PATH=%PATH%;%CD%\handle
- handle.exe -accepteula -help
test_script:
- if not exist C:\cache\rustsrc\NUL mkdir C:\cache\rustsrc
- sh src/ci/init_repo.sh . /c/cache/rustsrc
- set SRC=.
- set NO_CCACHE=1
- sh src/ci/run.sh
2018-05-10 23:30:50 -05:00
on_failure:
# Dump crash log
- set PATH=%PATH%;"C:\Program Files (x86)\Windows Kits\10\Debuggers\X64"
- if exist %LOCALAPPDATA%\CrashDumps for %%f in (%LOCALAPPDATA%\CrashDumps\*) do cdb -c "k;q" -G -z "%%f"
branches:
only:
- auto
before_deploy:
- ps: |
New-Item -Path deploy -ItemType directory
Remove-Item -Recurse -Force build\dist\doc
Get-ChildItem -Path build\dist | Move-Item -Destination deploy
Get-ChildItem -Path deploy | Foreach-Object {
Push-AppveyorArtifact $_.FullName -FileName ${env:APPVEYOR_REPO_COMMIT}/$_
}
deploy:
- provider: S3
access_key_id: $(AWS_ACCESS_KEY_ID)
secret_access_key: $(AWS_SECRET_ACCESS_KEY)
bucket: rust-lang-ci2
set_public: true
region: us-west-1
artifact: /.*/
folder: rustc-builds
on:
branch: auto
DEPLOY: 1
max_error_retry: 5
# This provider is the same as the one above except that it has a slightly
# different upload directory and a slightly different trigger
- provider: S3
access_key_id: $(AWS_ACCESS_KEY_ID)
secret_access_key: $(AWS_SECRET_ACCESS_KEY)
bucket: rust-lang-ci2
set_public: true
region: us-west-1
artifact: /.*/
folder: rustc-builds-alt
on:
branch: auto
DEPLOY_ALT: 1
max_error_retry: 5
# init:
# - ps: iex ((new-object net.webclient).DownloadString('https://raw.githubusercontent.com/appveyor/ci/master/scripts/enable-rdp.ps1'))
# on_finish:
# - ps: $blockRdp = $true; iex ((new-object net.webclient).DownloadString('https://raw.githubusercontent.com/appveyor/ci/master/scripts/enable-rdp.ps1'))