tvl-depot/tools/nixery/build-image/build-image.nix

161 lines
6.3 KiB
Nix

# Copyright 2019 Google LLC
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# https://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# This file contains a derivation that outputs structured information
# about the runtime dependencies of an image with a given set of
# packages. This is used by Nixery to determine the layer grouping and
# assemble each layer.
#
# In addition it creates and outputs a meta-layer with the symlink
# structure required for using the image together with the individual
# package layers.
{
# Description of the package set to be used (will be loaded by load-pkgs.nix)
srcType ? "nixpkgs",
srcArgs ? "nixos-19.03",
importArgs ? { },
# Path to load-pkgs.nix
loadPkgs ? ./load-pkgs.nix,
# Packages to install by name (which must refer to top-level attributes of
# nixpkgs). This is passed in as a JSON-array in string form.
packages ? "[]"
}:
let
inherit (builtins)
foldl'
fromJSON
hasAttr
length
readFile
toFile
toJSON;
inherit (pkgs) lib runCommand writeText;
pkgs = import loadPkgs { inherit srcType srcArgs importArgs; };
# deepFetch traverses the top-level Nix package set to retrieve an item via a
# path specified in string form.
#
# For top-level items, the name of the key yields the result directly. Nested
# items are fetched by using dot-syntax, as in Nix itself.
#
# Due to a restriction of the registry API specification it is not possible to
# pass uppercase characters in an image name, however the Nix package set
# makes use of camelCasing repeatedly (for example for `haskellPackages`).
#
# To work around this, if no value is found on the top-level a second lookup
# is done on the package set using lowercase-names. This is not done for
# nested sets, as they often have keys that only differ in case.
#
# For example, `deepFetch pkgs "xorg.xev"` retrieves `pkgs.xorg.xev` and
# `deepFetch haskellpackages.stylish-haskell` retrieves
# `haskellPackages.stylish-haskell`.
deepFetch = with lib; s: n:
let path = splitString "." n;
err = { error = "not_found"; pkg = n; };
# The most efficient way I've found to do a lookup against
# case-differing versions of an attribute is to first construct a
# mapping of all lowercased attribute names to their differently cased
# equivalents.
#
# This map is then used for a second lookup if the top-level
# (case-sensitive) one does not yield a result.
hasUpper = str: (match ".*[A-Z].*" str) != null;
allUpperKeys = filter hasUpper (attrNames s);
lowercased = listToAttrs (map (k: {
name = toLower k;
value = k;
}) allUpperKeys);
caseAmendedPath = map (v: if hasAttr v lowercased then lowercased."${v}" else v) path;
fetchLower = attrByPath caseAmendedPath err s;
in attrByPath path fetchLower s;
# allContents contains all packages successfully retrieved by name
# from the package set, as well as any errors encountered while
# attempting to fetch a package.
#
# Accumulated error information is returned back to the server.
allContents =
# Folds over the results of 'deepFetch' on all requested packages to
# separate them into errors and content. This allows the program to
# terminate early and return only the errors if any are encountered.
let splitter = attrs: res:
if hasAttr "error" res
then attrs // { errors = attrs.errors ++ [ res ]; }
else attrs // { contents = attrs.contents ++ [ res ]; };
init = { contents = []; errors = []; };
fetched = (map (deepFetch pkgs) (fromJSON packages));
in foldl' splitter init fetched;
# Contains the export references graph of all retrieved packages,
# which has information about all runtime dependencies of the image.
#
# This is used by Nixery to group closures into image layers.
runtimeGraph = runCommand "runtime-graph.json" {
__structuredAttrs = true;
exportReferencesGraph.graph = allContents.contents;
PATH = "${pkgs.coreutils}/bin";
builder = toFile "builder" ''
. .attrs.sh
cp .attrs.json ''${outputs[out]}
'';
} "";
# Create a symlink forest into all top-level store paths of the
# image contents.
contentsEnv = pkgs.symlinkJoin {
name = "bulk-layers";
paths = allContents.contents;
};
# Image layer that contains the symlink forest created above. This
# must be included in the image to ensure that the filesystem has a
# useful layout at runtime.
symlinkLayer = runCommand "symlink-layer.tar" {} ''
cp -r ${contentsEnv}/ ./layer
tar --transform='s|^\./||' -C layer --sort=name --mtime="@$SOURCE_DATE_EPOCH" --owner=0 --group=0 -cf $out .
'';
# Metadata about the symlink layer which is required for serving it.
# Two different hashes are computed for different usages (inclusion
# in manifest vs. content-checking in the layer cache).
symlinkLayerMeta = fromJSON (readFile (runCommand "symlink-layer-meta.json" {
buildInputs = with pkgs; [ coreutils jq openssl ];
}''
layerSha256=$(sha256sum ${symlinkLayer} | cut -d ' ' -f1)
layerSize=$(stat --printf '%s' ${symlinkLayer})
jq -n -c --arg sha256 $layerSha256 --arg size $layerSize --arg path ${symlinkLayer} \
'{ size: ($size | tonumber), sha256: $sha256, path: $path }' >> $out
''));
# Final output structure returned to Nixery if the build succeeded
buildOutput = {
runtimeGraph = fromJSON (readFile runtimeGraph);
symlinkLayer = symlinkLayerMeta;
};
# Output structure returned if errors occured during the build. Currently the
# only error type that is returned in a structured way is 'not_found'.
errorOutput = {
error = "not_found";
pkgs = map (err: err.pkg) allContents.errors;
};
in writeText "build-output.json" (if (length allContents.errors) == 0
then toJSON buildOutput
else toJSON errorOutput
)