platform_build_soong/android/bazel_handler.go
Chris Parsons f874e46153 Refactor mixed builds to only take one pass
This large refactoring has both immense performance implications and
improves mixed builds complexity / usability. Summary:

1. Queueing calls to Bazel is done in a new mutator instead of a full
   soong_build pass. Normal soong_build flow is interrupted (via a
   functional hook in blueprint) to invoke bazel and parse its response.
2. Implementing mixed build support for additional modules is as simple
   as implementing MixedBuildsBuildable. In this interface, define the
   request that must be queued to Bazel, and then subsequently define
   how to handle the returned bazel cquery metadata.
3. Mixed builds consists of only a single pass. This greatly
   improves mixed build performance.

Result:
  A 33% runtime improvement on soong analysis phase with mixed builds.

Caveats:
  C++ BazelHandler handling still remains a bit of a mess; I did what
  I could within this CL's scope, but this may require additional cleanup.

Test: Treehugger
Test: Verified that aosp_arm ninja file is bit-for-bit identical with or
without this change.

Change-Id: I412d9c94d429105f4ebfafc84100d546069e6621
2022-05-20 10:04:13 -04:00

941 lines
30 KiB
Go

// Copyright 2020 Google Inc. All rights reserved.
//
// 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
//
// http://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.
package android
import (
"bytes"
"errors"
"fmt"
"io/ioutil"
"os"
"os/exec"
"path/filepath"
"runtime"
"strings"
"sync"
"android/soong/bazel/cquery"
"android/soong/shared"
"github.com/google/blueprint"
"android/soong/bazel"
)
func init() {
RegisterMixedBuildsMutator(InitRegistrationContext)
}
func RegisterMixedBuildsMutator(ctx RegistrationContext) {
ctx.PostDepsMutators(func(ctx RegisterMutatorsContext) {
ctx.BottomUp("mixed_builds_prep", mixedBuildsPrepareMutator).Parallel()
})
}
func mixedBuildsPrepareMutator(ctx BottomUpMutatorContext) {
if m := ctx.Module(); m.Enabled() {
if mixedBuildMod, ok := m.(MixedBuildBuildable); ok {
if mixedBuildMod.IsMixedBuildSupported(ctx) && MixedBuildsEnabled(ctx) {
mixedBuildMod.QueueBazelCall(ctx)
}
}
}
}
type cqueryRequest interface {
// Name returns a string name for this request type. Such request type names must be unique,
// and must only consist of alphanumeric characters.
Name() string
// StarlarkFunctionBody returns a starlark function body to process this request type.
// The returned string is the body of a Starlark function which obtains
// all request-relevant information about a target and returns a string containing
// this information.
// The function should have the following properties:
// - `target` is the only parameter to this function (a configured target).
// - The return value must be a string.
// - The function body should not be indented outside of its own scope.
StarlarkFunctionBody() string
}
// Portion of cquery map key to describe target configuration.
type configKey struct {
arch string
osType OsType
}
// Map key to describe bazel cquery requests.
type cqueryKey struct {
label string
requestType cqueryRequest
configKey configKey
}
// BazelContext is a context object useful for interacting with Bazel during
// the course of a build. Use of Bazel to evaluate part of the build graph
// is referred to as a "mixed build". (Some modules are managed by Soong,
// some are managed by Bazel). To facilitate interop between these build
// subgraphs, Soong may make requests to Bazel and evaluate their responses
// so that Soong modules may accurately depend on Bazel targets.
type BazelContext interface {
// Add a cquery request to the bazel request queue. All queued requests
// will be sent to Bazel on a subsequent invocation of InvokeBazel.
QueueBazelRequest(label string, requestType cqueryRequest, cfgKey configKey)
// ** Cquery Results Retrieval Functions
// The below functions pertain to retrieving cquery results from a prior
// InvokeBazel function call and parsing the results.
// Returns result files built by building the given bazel target label.
GetOutputFiles(label string, cfgKey configKey) ([]string, error)
// Returns the results of GetOutputFiles and GetCcObjectFiles in a single query (in that order).
GetCcInfo(label string, cfgKey configKey) (cquery.CcInfo, error)
// Returns the executable binary resultant from building together the python sources
// TODO(b/232976601): Remove.
GetPythonBinary(label string, cfgKey configKey) (string, error)
// ** end Cquery Results Retrieval Functions
// Issues commands to Bazel to receive results for all cquery requests
// queued in the BazelContext.
InvokeBazel() error
// Returns true if bazel is enabled for the given configuration.
BazelEnabled() bool
// Returns the bazel output base (the root directory for all bazel intermediate outputs).
OutputBase() string
// Returns build statements which should get registered to reflect Bazel's outputs.
BuildStatementsToRegister() []bazel.BuildStatement
// Returns the depsets defined in Bazel's aquery response.
AqueryDepsets() []bazel.AqueryDepset
}
type bazelRunner interface {
issueBazelCommand(paths *bazelPaths, runName bazel.RunName, command bazelCommand, extraFlags ...string) (string, string, error)
}
type bazelPaths struct {
homeDir string
bazelPath string
outputBase string
workspaceDir string
soongOutDir string
metricsDir string
}
// A context object which tracks queued requests that need to be made to Bazel,
// and their results after the requests have been made.
type bazelContext struct {
bazelRunner
paths *bazelPaths
requests map[cqueryKey]bool // cquery requests that have not yet been issued to Bazel
requestMutex sync.Mutex // requests can be written in parallel
results map[cqueryKey]string // Results of cquery requests after Bazel invocations
// Build statements which should get registered to reflect Bazel's outputs.
buildStatements []bazel.BuildStatement
// Depsets which should be used for Bazel's build statements.
depsets []bazel.AqueryDepset
}
var _ BazelContext = &bazelContext{}
// A bazel context to use when Bazel is disabled.
type noopBazelContext struct{}
var _ BazelContext = noopBazelContext{}
// A bazel context to use for tests.
type MockBazelContext struct {
OutputBaseDir string
LabelToOutputFiles map[string][]string
LabelToCcInfo map[string]cquery.CcInfo
LabelToPythonBinary map[string]string
}
func (m MockBazelContext) QueueBazelRequest(label string, requestType cqueryRequest, cfgKey configKey) {
panic("unimplemented")
}
func (m MockBazelContext) GetOutputFiles(label string, cfgKey configKey) ([]string, error) {
result, _ := m.LabelToOutputFiles[label]
return result, nil
}
func (m MockBazelContext) GetCcInfo(label string, cfgKey configKey) (cquery.CcInfo, error) {
result, _ := m.LabelToCcInfo[label]
return result, nil
}
func (m MockBazelContext) GetPythonBinary(label string, cfgKey configKey) (string, error) {
result, _ := m.LabelToPythonBinary[label]
return result, nil
}
func (m MockBazelContext) InvokeBazel() error {
panic("unimplemented")
}
func (m MockBazelContext) BazelEnabled() bool {
return true
}
func (m MockBazelContext) OutputBase() string { return m.OutputBaseDir }
func (m MockBazelContext) BuildStatementsToRegister() []bazel.BuildStatement {
return []bazel.BuildStatement{}
}
func (m MockBazelContext) AqueryDepsets() []bazel.AqueryDepset {
return []bazel.AqueryDepset{}
}
var _ BazelContext = MockBazelContext{}
func (bazelCtx *bazelContext) QueueBazelRequest(label string, requestType cqueryRequest, cfgKey configKey) {
key := cqueryKey{label, requestType, cfgKey}
bazelCtx.requestMutex.Lock()
defer bazelCtx.requestMutex.Unlock()
bazelCtx.requests[key] = true
}
func (bazelCtx *bazelContext) GetOutputFiles(label string, cfgKey configKey) ([]string, error) {
key := cqueryKey{label, cquery.GetOutputFiles, cfgKey}
if rawString, ok := bazelCtx.results[key]; ok {
bazelOutput := strings.TrimSpace(rawString)
return cquery.GetOutputFiles.ParseResult(bazelOutput), nil
}
return nil, fmt.Errorf("no bazel response found for %v", key)
}
func (bazelCtx *bazelContext) GetCcInfo(label string, cfgKey configKey) (cquery.CcInfo, error) {
key := cqueryKey{label, cquery.GetCcInfo, cfgKey}
if rawString, ok := bazelCtx.results[key]; ok {
bazelOutput := strings.TrimSpace(rawString)
return cquery.GetCcInfo.ParseResult(bazelOutput)
}
return cquery.CcInfo{}, fmt.Errorf("no bazel response found for %v", key)
}
func (bazelCtx *bazelContext) GetPythonBinary(label string, cfgKey configKey) (string, error) {
key := cqueryKey{label, cquery.GetPythonBinary, cfgKey}
if rawString, ok := bazelCtx.results[key]; ok {
bazelOutput := strings.TrimSpace(rawString)
return cquery.GetPythonBinary.ParseResult(bazelOutput), nil
}
return "", fmt.Errorf("no bazel response found for %v", key)
}
func (n noopBazelContext) QueueBazelRequest(label string, requestType cqueryRequest, cfgKey configKey) {
panic("unimplemented")
}
func (n noopBazelContext) GetOutputFiles(label string, cfgKey configKey) ([]string, error) {
panic("unimplemented")
}
func (n noopBazelContext) GetCcInfo(label string, cfgKey configKey) (cquery.CcInfo, error) {
panic("unimplemented")
}
func (n noopBazelContext) GetPythonBinary(label string, cfgKey configKey) (string, error) {
panic("unimplemented")
}
func (n noopBazelContext) InvokeBazel() error {
panic("unimplemented")
}
func (m noopBazelContext) OutputBase() string {
return ""
}
func (n noopBazelContext) BazelEnabled() bool {
return false
}
func (m noopBazelContext) BuildStatementsToRegister() []bazel.BuildStatement {
return []bazel.BuildStatement{}
}
func (m noopBazelContext) AqueryDepsets() []bazel.AqueryDepset {
return []bazel.AqueryDepset{}
}
func NewBazelContext(c *config) (BazelContext, error) {
// TODO(cparsons): Assess USE_BAZEL=1 instead once "mixed Soong/Bazel builds"
// are production ready.
if !c.IsEnvTrue("USE_BAZEL_ANALYSIS") {
return noopBazelContext{}, nil
}
p, err := bazelPathsFromConfig(c)
if err != nil {
return nil, err
}
return &bazelContext{
bazelRunner: &builtinBazelRunner{},
paths: p,
requests: make(map[cqueryKey]bool),
}, nil
}
func bazelPathsFromConfig(c *config) (*bazelPaths, error) {
p := bazelPaths{
soongOutDir: c.soongOutDir,
}
missingEnvVars := []string{}
if len(c.Getenv("BAZEL_HOME")) > 1 {
p.homeDir = c.Getenv("BAZEL_HOME")
} else {
missingEnvVars = append(missingEnvVars, "BAZEL_HOME")
}
if len(c.Getenv("BAZEL_PATH")) > 1 {
p.bazelPath = c.Getenv("BAZEL_PATH")
} else {
missingEnvVars = append(missingEnvVars, "BAZEL_PATH")
}
if len(c.Getenv("BAZEL_OUTPUT_BASE")) > 1 {
p.outputBase = c.Getenv("BAZEL_OUTPUT_BASE")
} else {
missingEnvVars = append(missingEnvVars, "BAZEL_OUTPUT_BASE")
}
if len(c.Getenv("BAZEL_WORKSPACE")) > 1 {
p.workspaceDir = c.Getenv("BAZEL_WORKSPACE")
} else {
missingEnvVars = append(missingEnvVars, "BAZEL_WORKSPACE")
}
if len(c.Getenv("BAZEL_METRICS_DIR")) > 1 {
p.metricsDir = c.Getenv("BAZEL_METRICS_DIR")
} else {
missingEnvVars = append(missingEnvVars, "BAZEL_METRICS_DIR")
}
if len(missingEnvVars) > 0 {
return nil, errors.New(fmt.Sprintf("missing required env vars to use bazel: %s", missingEnvVars))
} else {
return &p, nil
}
}
func (p *bazelPaths) BazelMetricsDir() string {
return p.metricsDir
}
func (context *bazelContext) BazelEnabled() bool {
return true
}
func pwdPrefix() string {
// Darwin doesn't have /proc
if runtime.GOOS != "darwin" {
return "PWD=/proc/self/cwd"
}
return ""
}
type bazelCommand struct {
command string
// query or label
expression string
}
type mockBazelRunner struct {
bazelCommandResults map[bazelCommand]string
commands []bazelCommand
}
func (r *mockBazelRunner) issueBazelCommand(paths *bazelPaths,
runName bazel.RunName,
command bazelCommand,
extraFlags ...string) (string, string, error) {
r.commands = append(r.commands, command)
if ret, ok := r.bazelCommandResults[command]; ok {
return ret, "", nil
}
return "", "", nil
}
type builtinBazelRunner struct{}
// Issues the given bazel command with given build label and additional flags.
// Returns (stdout, stderr, error). The first and second return values are strings
// containing the stdout and stderr of the run command, and an error is returned if
// the invocation returned an error code.
func (r *builtinBazelRunner) issueBazelCommand(paths *bazelPaths, runName bazel.RunName, command bazelCommand,
extraFlags ...string) (string, string, error) {
cmdFlags := []string{
// --noautodetect_server_javabase has the practical consequence of preventing Bazel from
// attempting to download rules_java, which is incompatible with
// --experimental_repository_disable_download set further below.
// rules_java is also not needed until mixed builds start building java targets.
// TODO(b/197958133): Once rules_java is pulled into AOSP, remove this flag.
"--noautodetect_server_javabase",
"--output_base=" + absolutePath(paths.outputBase),
command.command,
}
cmdFlags = append(cmdFlags, command.expression)
cmdFlags = append(cmdFlags, "--profile="+shared.BazelMetricsFilename(paths, runName))
// Set default platforms to canonicalized values for mixed builds requests.
// If these are set in the bazelrc, they will have values that are
// non-canonicalized to @sourceroot labels, and thus be invalid when
// referenced from the buildroot.
//
// The actual platform values here may be overridden by configuration
// transitions from the buildroot.
cmdFlags = append(cmdFlags,
fmt.Sprintf("--platforms=%s", "//build/bazel/platforms:android_target"))
cmdFlags = append(cmdFlags,
fmt.Sprintf("--extra_toolchains=%s", "//prebuilts/clang/host/linux-x86:all"))
// This should be parameterized on the host OS, but let's restrict to linux
// to keep things simple for now.
cmdFlags = append(cmdFlags,
fmt.Sprintf("--host_platform=%s", "//build/bazel/platforms:linux_x86_64"))
// Explicitly disable downloading rules (such as canonical C++ and Java rules) from the network.
cmdFlags = append(cmdFlags, "--experimental_repository_disable_download")
cmdFlags = append(cmdFlags, extraFlags...)
bazelCmd := exec.Command(paths.bazelPath, cmdFlags...)
bazelCmd.Dir = absolutePath(paths.syntheticWorkspaceDir())
bazelCmd.Env = append(os.Environ(),
"HOME="+paths.homeDir,
pwdPrefix(),
"BUILD_DIR="+absolutePath(paths.soongOutDir),
// Make OUT_DIR absolute here so tools/bazel.sh uses the correct
// OUT_DIR at <root>/out, instead of <root>/out/soong/workspace/out.
"OUT_DIR="+absolutePath(paths.outDir()),
// Disables local host detection of gcc; toolchain information is defined
// explicitly in BUILD files.
"BAZEL_DO_NOT_DETECT_CPP_TOOLCHAIN=1")
stderr := &bytes.Buffer{}
bazelCmd.Stderr = stderr
if output, err := bazelCmd.Output(); err != nil {
return "", string(stderr.Bytes()),
fmt.Errorf("bazel command failed. command: [%s], env: [%s], error [%s]", bazelCmd, bazelCmd.Env, stderr)
} else {
return string(output), string(stderr.Bytes()), nil
}
}
func (context *bazelContext) mainBzlFileContents() []byte {
// TODO(cparsons): Define configuration transitions programmatically based
// on available archs.
contents := `
#####################################################
# This file is generated by soong_build. Do not edit.
#####################################################
def _config_node_transition_impl(settings, attr):
return {
"//command_line_option:platforms": "@//build/bazel/platforms:%s_%s" % (attr.os, attr.arch),
}
_config_node_transition = transition(
implementation = _config_node_transition_impl,
inputs = [],
outputs = [
"//command_line_option:platforms",
],
)
def _passthrough_rule_impl(ctx):
return [DefaultInfo(files = depset(ctx.files.deps))]
config_node = rule(
implementation = _passthrough_rule_impl,
attrs = {
"arch" : attr.string(mandatory = True),
"os" : attr.string(mandatory = True),
"deps" : attr.label_list(cfg = _config_node_transition, allow_files = True),
"_allowlist_function_transition": attr.label(default = "@bazel_tools//tools/allowlists/function_transition_allowlist"),
},
)
# Rule representing the root of the build, to depend on all Bazel targets that
# are required for the build. Building this target will build the entire Bazel
# build tree.
mixed_build_root = rule(
implementation = _passthrough_rule_impl,
attrs = {
"deps" : attr.label_list(),
},
)
def _phony_root_impl(ctx):
return []
# Rule to depend on other targets but build nothing.
# This is useful as follows: building a target of this rule will generate
# symlink forests for all dependencies of the target, without executing any
# actions of the build.
phony_root = rule(
implementation = _phony_root_impl,
attrs = {"deps" : attr.label_list()},
)
`
return []byte(contents)
}
func (context *bazelContext) mainBuildFileContents() []byte {
// TODO(cparsons): Map label to attribute programmatically; don't use hard-coded
// architecture mapping.
formatString := `
# This file is generated by soong_build. Do not edit.
load(":main.bzl", "config_node", "mixed_build_root", "phony_root")
%s
mixed_build_root(name = "buildroot",
deps = [%s],
)
phony_root(name = "phonyroot",
deps = [":buildroot"],
)
`
configNodeFormatString := `
config_node(name = "%s",
arch = "%s",
os = "%s",
deps = [%s],
)
`
configNodesSection := ""
labelsByConfig := map[string][]string{}
for val, _ := range context.requests {
labelString := fmt.Sprintf("\"@%s\"", val.label)
configString := getConfigString(val)
labelsByConfig[configString] = append(labelsByConfig[configString], labelString)
}
allLabels := []string{}
for configString, labels := range labelsByConfig {
configTokens := strings.Split(configString, "|")
if len(configTokens) != 2 {
panic(fmt.Errorf("Unexpected config string format: %s", configString))
}
archString := configTokens[0]
osString := configTokens[1]
targetString := fmt.Sprintf("%s_%s", osString, archString)
allLabels = append(allLabels, fmt.Sprintf("\":%s\"", targetString))
labelsString := strings.Join(labels, ",\n ")
configNodesSection += fmt.Sprintf(configNodeFormatString, targetString, archString, osString, labelsString)
}
return []byte(fmt.Sprintf(formatString, configNodesSection, strings.Join(allLabels, ",\n ")))
}
func indent(original string) string {
result := ""
for _, line := range strings.Split(original, "\n") {
result += " " + line + "\n"
}
return result
}
// Returns the file contents of the buildroot.cquery file that should be used for the cquery
// expression in order to obtain information about buildroot and its dependencies.
// The contents of this file depend on the bazelContext's requests; requests are enumerated
// and grouped by their request type. The data retrieved for each label depends on its
// request type.
func (context *bazelContext) cqueryStarlarkFileContents() []byte {
requestTypeToCqueryIdEntries := map[cqueryRequest][]string{}
for val, _ := range context.requests {
cqueryId := getCqueryId(val)
mapEntryString := fmt.Sprintf("%q : True", cqueryId)
requestTypeToCqueryIdEntries[val.requestType] =
append(requestTypeToCqueryIdEntries[val.requestType], mapEntryString)
}
labelRegistrationMapSection := ""
functionDefSection := ""
mainSwitchSection := ""
mapDeclarationFormatString := `
%s = {
%s
}
`
functionDefFormatString := `
def %s(target):
%s
`
mainSwitchSectionFormatString := `
if id_string in %s:
return id_string + ">>" + %s(target)
`
for requestType := range requestTypeToCqueryIdEntries {
labelMapName := requestType.Name() + "_Labels"
functionName := requestType.Name() + "_Fn"
labelRegistrationMapSection += fmt.Sprintf(mapDeclarationFormatString,
labelMapName,
strings.Join(requestTypeToCqueryIdEntries[requestType], ",\n "))
functionDefSection += fmt.Sprintf(functionDefFormatString,
functionName,
indent(requestType.StarlarkFunctionBody()))
mainSwitchSection += fmt.Sprintf(mainSwitchSectionFormatString,
labelMapName, functionName)
}
formatString := `
# This file is generated by soong_build. Do not edit.
# Label Map Section
%s
# Function Def Section
%s
def get_arch(target):
# TODO(b/199363072): filegroups and file targets aren't associated with any
# specific platform architecture in mixed builds. This is consistent with how
# Soong treats filegroups, but it may not be the case with manually-written
# filegroup BUILD targets.
buildoptions = build_options(target)
if buildoptions == None:
# File targets do not have buildoptions. File targets aren't associated with
# any specific platform architecture in mixed builds, so use the host.
return "x86_64|linux"
platforms = build_options(target)["//command_line_option:platforms"]
if len(platforms) != 1:
# An individual configured target should have only one platform architecture.
# Note that it's fine for there to be multiple architectures for the same label,
# but each is its own configured target.
fail("expected exactly 1 platform for " + str(target.label) + " but got " + str(platforms))
platform_name = build_options(target)["//command_line_option:platforms"][0].name
if platform_name == "host":
return "HOST"
elif platform_name.startswith("android_"):
return platform_name[len("android_"):] + "|" + platform_name[:len("android_")-1]
elif platform_name.startswith("linux_"):
return platform_name[len("linux_"):] + "|" + platform_name[:len("linux_")-1]
else:
fail("expected platform name of the form 'android_<arch>' or 'linux_<arch>', but was " + str(platforms))
return "UNKNOWN"
def format(target):
id_string = str(target.label) + "|" + get_arch(target)
# Main switch section
%s
# This target was not requested via cquery, and thus must be a dependency
# of a requested target.
return id_string + ">>NONE"
`
return []byte(fmt.Sprintf(formatString, labelRegistrationMapSection, functionDefSection,
mainSwitchSection))
}
// Returns a path containing build-related metadata required for interfacing
// with Bazel. Example: out/soong/bazel.
func (p *bazelPaths) intermediatesDir() string {
return filepath.Join(p.soongOutDir, "bazel")
}
// Returns the path where the contents of the @soong_injection repository live.
// It is used by Soong to tell Bazel things it cannot over the command line.
func (p *bazelPaths) injectedFilesDir() string {
return filepath.Join(p.soongOutDir, bazel.SoongInjectionDirName)
}
// Returns the path of the synthetic Bazel workspace that contains a symlink
// forest composed the whole source tree and BUILD files generated by bp2build.
func (p *bazelPaths) syntheticWorkspaceDir() string {
return filepath.Join(p.soongOutDir, "workspace")
}
// Returns the path to the top level out dir ($OUT_DIR).
func (p *bazelPaths) outDir() string {
return filepath.Dir(p.soongOutDir)
}
// Issues commands to Bazel to receive results for all cquery requests
// queued in the BazelContext.
func (context *bazelContext) InvokeBazel() error {
context.results = make(map[cqueryKey]string)
var cqueryOutput string
var cqueryErr string
var err error
soongInjectionPath := absolutePath(context.paths.injectedFilesDir())
mixedBuildsPath := filepath.Join(soongInjectionPath, "mixed_builds")
if _, err := os.Stat(mixedBuildsPath); os.IsNotExist(err) {
err = os.MkdirAll(mixedBuildsPath, 0777)
}
if err != nil {
return err
}
if metricsDir := context.paths.BazelMetricsDir(); metricsDir != "" {
err = os.MkdirAll(metricsDir, 0777)
if err != nil {
return err
}
}
err = ioutil.WriteFile(filepath.Join(soongInjectionPath, "WORKSPACE.bazel"), []byte{}, 0666)
if err != nil {
return err
}
err = ioutil.WriteFile(
filepath.Join(mixedBuildsPath, "main.bzl"),
context.mainBzlFileContents(), 0666)
if err != nil {
return err
}
err = ioutil.WriteFile(
filepath.Join(mixedBuildsPath, "BUILD.bazel"),
context.mainBuildFileContents(), 0666)
if err != nil {
return err
}
cqueryFileRelpath := filepath.Join(context.paths.injectedFilesDir(), "buildroot.cquery")
err = ioutil.WriteFile(
absolutePath(cqueryFileRelpath),
context.cqueryStarlarkFileContents(), 0666)
if err != nil {
return err
}
buildrootLabel := "@soong_injection//mixed_builds:buildroot"
cqueryOutput, cqueryErr, err = context.issueBazelCommand(
context.paths,
bazel.CqueryBuildRootRunName,
bazelCommand{"cquery", fmt.Sprintf("deps(%s, 2)", buildrootLabel)},
"--output=starlark",
"--starlark:file="+absolutePath(cqueryFileRelpath))
err = ioutil.WriteFile(filepath.Join(soongInjectionPath, "cquery.out"),
[]byte(cqueryOutput), 0666)
if err != nil {
return err
}
if err != nil {
return err
}
cqueryResults := map[string]string{}
for _, outputLine := range strings.Split(cqueryOutput, "\n") {
if strings.Contains(outputLine, ">>") {
splitLine := strings.SplitN(outputLine, ">>", 2)
cqueryResults[splitLine[0]] = splitLine[1]
}
}
for val := range context.requests {
if cqueryResult, ok := cqueryResults[getCqueryId(val)]; ok {
context.results[val] = cqueryResult
} else {
return fmt.Errorf("missing result for bazel target %s. query output: [%s], cquery err: [%s]",
getCqueryId(val), cqueryOutput, cqueryErr)
}
}
// Issue an aquery command to retrieve action information about the bazel build tree.
//
// TODO(cparsons): Use --target_pattern_file to avoid command line limits.
var aqueryOutput string
aqueryOutput, _, err = context.issueBazelCommand(
context.paths,
bazel.AqueryBuildRootRunName,
bazelCommand{"aquery", fmt.Sprintf("deps(%s)", buildrootLabel)},
// Use jsonproto instead of proto; actual proto parsing would require a dependency on Bazel's
// proto sources, which would add a number of unnecessary dependencies.
"--output=jsonproto")
if err != nil {
return err
}
context.buildStatements, context.depsets, err = bazel.AqueryBuildStatements([]byte(aqueryOutput))
if err != nil {
return err
}
// Issue a build command of the phony root to generate symlink forests for dependencies of the
// Bazel build. This is necessary because aquery invocations do not generate this symlink forest,
// but some of symlinks may be required to resolve source dependencies of the build.
_, _, err = context.issueBazelCommand(
context.paths,
bazel.BazelBuildPhonyRootRunName,
bazelCommand{"build", "@soong_injection//mixed_builds:phonyroot"})
if err != nil {
return err
}
// Clear requests.
context.requests = map[cqueryKey]bool{}
return nil
}
func (context *bazelContext) BuildStatementsToRegister() []bazel.BuildStatement {
return context.buildStatements
}
func (context *bazelContext) AqueryDepsets() []bazel.AqueryDepset {
return context.depsets
}
func (context *bazelContext) OutputBase() string {
return context.paths.outputBase
}
// Singleton used for registering BUILD file ninja dependencies (needed
// for correctness of builds which use Bazel.
func BazelSingleton() Singleton {
return &bazelSingleton{}
}
type bazelSingleton struct{}
func (c *bazelSingleton) GenerateBuildActions(ctx SingletonContext) {
// bazelSingleton is a no-op if mixed-soong-bazel-builds are disabled.
if !ctx.Config().BazelContext.BazelEnabled() {
return
}
// Add ninja file dependencies for files which all bazel invocations require.
bazelBuildList := absolutePath(filepath.Join(
filepath.Dir(ctx.Config().moduleListFile), "bazel.list"))
ctx.AddNinjaFileDeps(bazelBuildList)
data, err := ioutil.ReadFile(bazelBuildList)
if err != nil {
ctx.Errorf(err.Error())
}
files := strings.Split(strings.TrimSpace(string(data)), "\n")
for _, file := range files {
ctx.AddNinjaFileDeps(file)
}
for _, depset := range ctx.Config().BazelContext.AqueryDepsets() {
var outputs []Path
for _, depsetDepHash := range depset.TransitiveDepSetHashes {
otherDepsetName := bazelDepsetName(depsetDepHash)
outputs = append(outputs, PathForPhony(ctx, otherDepsetName))
}
for _, artifactPath := range depset.DirectArtifacts {
outputs = append(outputs, PathForBazelOut(ctx, artifactPath))
}
thisDepsetName := bazelDepsetName(depset.ContentHash)
ctx.Build(pctx, BuildParams{
Rule: blueprint.Phony,
Outputs: []WritablePath{PathForPhony(ctx, thisDepsetName)},
Implicits: outputs,
})
}
// Register bazel-owned build statements (obtained from the aquery invocation).
for index, buildStatement := range ctx.Config().BazelContext.BuildStatementsToRegister() {
if len(buildStatement.Command) < 1 {
panic(fmt.Sprintf("unhandled build statement: %v", buildStatement))
}
rule := NewRuleBuilder(pctx, ctx)
cmd := rule.Command()
// cd into Bazel's execution root, which is the action cwd.
cmd.Text(fmt.Sprintf("cd %s/execroot/__main__ &&", ctx.Config().BazelContext.OutputBase()))
// Remove old outputs, as some actions might not rerun if the outputs are detected.
if len(buildStatement.OutputPaths) > 0 {
cmd.Text("rm -f")
for _, outputPath := range buildStatement.OutputPaths {
cmd.Text(outputPath)
}
cmd.Text("&&")
}
for _, pair := range buildStatement.Env {
// Set per-action env variables, if any.
cmd.Flag(pair.Key + "=" + pair.Value)
}
// The actual Bazel action.
cmd.Text(" " + buildStatement.Command)
for _, outputPath := range buildStatement.OutputPaths {
cmd.ImplicitOutput(PathForBazelOut(ctx, outputPath))
}
for _, inputPath := range buildStatement.InputPaths {
cmd.Implicit(PathForBazelOut(ctx, inputPath))
}
for _, inputDepsetHash := range buildStatement.InputDepsetHashes {
otherDepsetName := bazelDepsetName(inputDepsetHash)
cmd.Implicit(PathForPhony(ctx, otherDepsetName))
}
if depfile := buildStatement.Depfile; depfile != nil {
cmd.ImplicitDepFile(PathForBazelOut(ctx, *depfile))
}
for _, symlinkPath := range buildStatement.SymlinkPaths {
cmd.ImplicitSymlinkOutput(PathForBazelOut(ctx, symlinkPath))
}
// This is required to silence warnings pertaining to unexpected timestamps. Particularly,
// some Bazel builtins (such as files in the bazel_tools directory) have far-future
// timestamps. Without restat, Ninja would emit warnings that the input files of a
// build statement have later timestamps than the outputs.
rule.Restat()
desc := fmt.Sprintf("%s: %s", buildStatement.Mnemonic, buildStatement.OutputPaths)
rule.Build(fmt.Sprintf("bazel %d", index), desc)
}
}
func getCqueryId(key cqueryKey) string {
return key.label + "|" + getConfigString(key)
}
func getConfigString(key cqueryKey) string {
arch := key.configKey.arch
if len(arch) == 0 || arch == "common" {
// Use host platform, which is currently hardcoded to be x86_64.
arch = "x86_64"
}
os := key.configKey.osType.Name
if len(os) == 0 || os == "common_os" || os == "linux_glibc" {
// Use host OS, which is currently hardcoded to be linux.
os = "linux"
}
return arch + "|" + os
}
func GetConfigKey(ctx BaseModuleContext) configKey {
return configKey{
// use string because Arch is not a valid key in go
arch: ctx.Arch().String(),
osType: ctx.Os(),
}
}
func bazelDepsetName(contentHash string) string {
return fmt.Sprintf("bazel_depset_%s", contentHash)
}