platform_build_blueprint/package_ctx.go
Dan Willemsen aeffbf776a Allow wrapping of PackageContext
Turn PackageContext into an interface so that build systems can wrap it
to add more custom helpers.

This does introduce an API change, though it should be fairly simple.
NewPackageContext used to provide an opaque *PackageContext struct, now it
provides a PackageContext interface.

Change-Id: I383c64a303d857ef5e0dec86ad77f791ba4c9639
2015-11-30 17:03:34 -08:00

864 lines
24 KiB
Go

// Copyright 2014 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 blueprint
import (
"errors"
"fmt"
"reflect"
"runtime"
"strings"
"sync"
)
// A PackageContext provides a way to create package-scoped Ninja pools,
// rules, and variables. A Go package should create a single unexported
// package-scoped PackageContext variable that it uses to create all package-
// scoped Ninja object definitions. This PackageContext object should then be
// passed to all calls to define module- or singleton-specific Ninja
// definitions. For example:
//
// package blah
//
// import (
// "blueprint"
// )
//
// var (
// pctx = NewPackageContext("path/to/blah")
//
// myPrivateVar = pctx.StaticVariable("myPrivateVar", "abcdef")
// MyExportedVar = pctx.StaticVariable("MyExportedVar", "$myPrivateVar 123456!")
//
// SomeRule = pctx.StaticRule(...)
// )
//
// // ...
//
// func (m *MyModule) GenerateBuildActions(ctx blueprint.Module) {
// ctx.Build(pctx, blueprint.BuildParams{
// Rule: SomeRule,
// Outputs: []string{"$myPrivateVar"},
// })
// }
type PackageContext interface {
Import(pkgPath string)
ImportAs(as, pkgPath string)
StaticVariable(name, value string) Variable
VariableFunc(name string, f func(config interface{}) (string, error)) Variable
VariableConfigMethod(name string, method interface{}) Variable
StaticPool(name string, params PoolParams) Pool
PoolFunc(name string, f func(interface{}) (PoolParams, error)) Pool
StaticRule(name string, params RuleParams, argNames ...string) Rule
RuleFunc(name string, f func(interface{}) (RuleParams, error), argNames ...string) Rule
getScope() *basicScope
}
type packageContext struct {
fullName string
shortName string
pkgPath string
scope *basicScope
}
var _ PackageContext = &packageContext{}
func (p *packageContext) getScope() *basicScope {
return p.scope
}
var packageContexts = map[string]*packageContext{}
// NewPackageContext creates a PackageContext object for a given package. The
// pkgPath argument should always be set to the full path used to import the
// package. This function may only be called from a Go package's init()
// function or as part of a package-scoped variable initialization.
func NewPackageContext(pkgPath string) PackageContext {
checkCalledFromInit()
if _, present := packageContexts[pkgPath]; present {
panic(fmt.Errorf("package %q already has a package context"))
}
pkgName := pkgPathToName(pkgPath)
err := validateNinjaName(pkgName)
if err != nil {
panic(err)
}
i := strings.LastIndex(pkgPath, "/")
shortName := pkgPath[i+1:]
p := &packageContext{
fullName: pkgName,
shortName: shortName,
pkgPath: pkgPath,
scope: newScope(nil),
}
packageContexts[pkgPath] = p
return p
}
var Phony Rule = &builtinRule{
name_: "phony",
}
var Console Pool = &builtinPool{
name_: "console",
}
var errRuleIsBuiltin = errors.New("the rule is a built-in")
var errPoolIsBuiltin = errors.New("the pool is a built-in")
var errVariableIsArg = errors.New("argument variables have no value")
// checkCalledFromInit panics if a Go package's init function is not on the
// call stack.
func checkCalledFromInit() {
for skip := 3; ; skip++ {
_, funcName, ok := callerName(skip)
if !ok {
panic("not called from an init func")
}
if funcName == "init" || strings.HasPrefix(funcName, "init·") {
return
}
}
}
// callerName returns the package path and function name of the calling
// function. The skip argument has the same meaning as the skip argument of
// runtime.Callers.
func callerName(skip int) (pkgPath, funcName string, ok bool) {
var pc [1]uintptr
n := runtime.Callers(skip+1, pc[:])
if n != 1 {
return "", "", false
}
f := runtime.FuncForPC(pc[0])
fullName := f.Name()
lastDotIndex := strings.LastIndex(fullName, ".")
if lastDotIndex == -1 {
panic("unable to distinguish function name from package")
}
if fullName[lastDotIndex-1] == ')' {
// The caller is a method on some type, so it's name looks like
// "pkg/path.(type).method". We need to go back one dot farther to get
// to the package name.
lastDotIndex = strings.LastIndex(fullName[:lastDotIndex], ".")
}
pkgPath = fullName[:lastDotIndex]
funcName = fullName[lastDotIndex+1:]
ok = true
return
}
// pkgPathToName makes a Ninja-friendly name out of a Go package name by
// replaceing all the '/' characters with '.'. We assume the results are
// unique, though this is not 100% guaranteed for Go package names that
// already contain '.' characters. Disallowing package names with '.' isn't
// reasonable since many package names contain the name of the hosting site
// (e.g. "code.google.com"). In practice this probably isn't really a
// problem.
func pkgPathToName(pkgPath string) string {
return strings.Replace(pkgPath, "/", ".", -1)
}
// Import enables access to the exported Ninja pools, rules, and variables
// that are defined at the package scope of another Go package. Go's
// visibility rules apply to these references - capitalized names indicate
// that something is exported. It may only be called from a Go package's
// init() function. The Go package path passed to Import must have already
// been imported into the Go package using a Go import statement. The
// imported variables may then be accessed from Ninja strings as
// "${pkg.Variable}", while the imported rules can simply be accessed as
// exported Go variables from the package. For example:
//
// import (
// "blueprint"
// "foo/bar"
// )
//
// var pctx = NewPackagePath("blah")
//
// func init() {
// pctx.Import("foo/bar")
// }
//
// ...
//
// func (m *MyModule) GenerateBuildActions(ctx blueprint.Module) {
// ctx.Build(pctx, blueprint.BuildParams{
// Rule: bar.SomeRule,
// Outputs: []string{"${bar.SomeVariable}"},
// })
// }
//
// Note that the local name used to refer to the package in Ninja variable names
// is derived from pkgPath by extracting the last path component. This differs
// from Go's import declaration, which derives the local name from the package
// clause in the imported package. By convention these names are made to match,
// but this is not required.
func (p *packageContext) Import(pkgPath string) {
checkCalledFromInit()
importPkg, ok := packageContexts[pkgPath]
if !ok {
panic(fmt.Errorf("package %q has no context", pkgPath))
}
err := p.scope.AddImport(importPkg.shortName, importPkg.scope)
if err != nil {
panic(err)
}
}
// ImportAs provides the same functionality as Import, but it allows the local
// name that will be used to refer to the package to be specified explicitly.
// It may only be called from a Go package's init() function.
func (p *packageContext) ImportAs(as, pkgPath string) {
checkCalledFromInit()
importPkg, ok := packageContexts[pkgPath]
if !ok {
panic(fmt.Errorf("package %q has no context", pkgPath))
}
err := validateNinjaName(as)
if err != nil {
panic(err)
}
err = p.scope.AddImport(as, importPkg.scope)
if err != nil {
panic(err)
}
}
type staticVariable struct {
pctx *packageContext
name_ string
value_ string
}
// StaticVariable returns a Variable whose value does not depend on any
// configuration information. It may only be called during a Go package's
// initialization - either from the init() function or as part of a package-
// scoped variable's initialization.
//
// This function is usually used to initialize a package-scoped Go variable that
// represents a Ninja variable that will be output. The name argument should
// exactly match the Go variable name, and the value string may reference other
// Ninja variables that are visible within the calling Go package.
func (p *packageContext) StaticVariable(name, value string) Variable {
checkCalledFromInit()
err := validateNinjaName(name)
if err != nil {
panic(err)
}
v := &staticVariable{p, name, value}
err = p.scope.AddVariable(v)
if err != nil {
panic(err)
}
return v
}
func (v *staticVariable) packageContext() *packageContext {
return v.pctx
}
func (v *staticVariable) name() string {
return v.name_
}
func (v *staticVariable) fullName(pkgNames map[*packageContext]string) string {
return packageNamespacePrefix(pkgNames[v.pctx]) + v.name_
}
func (v *staticVariable) value(interface{}) (*ninjaString, error) {
ninjaStr, err := parseNinjaString(v.pctx.scope, v.value_)
if err != nil {
err = fmt.Errorf("error parsing variable %s value: %s", v, err)
panic(err)
}
return ninjaStr, nil
}
func (v *staticVariable) String() string {
return v.pctx.pkgPath + "." + v.name_
}
type variableFunc struct {
pctx *packageContext
name_ string
value_ func(interface{}) (string, error)
}
// VariableFunc returns a Variable whose value is determined by a function that
// takes a config object as input and returns either the variable value or an
// error. It may only be called during a Go package's initialization - either
// from the init() function or as part of a package-scoped variable's
// initialization.
//
// This function is usually used to initialize a package-scoped Go variable that
// represents a Ninja variable that will be output. The name argument should
// exactly match the Go variable name, and the value string returned by f may
// reference other Ninja variables that are visible within the calling Go
// package.
func (p *packageContext) VariableFunc(name string,
f func(config interface{}) (string, error)) Variable {
checkCalledFromInit()
err := validateNinjaName(name)
if err != nil {
panic(err)
}
v := &variableFunc{p, name, f}
err = p.scope.AddVariable(v)
if err != nil {
panic(err)
}
return v
}
// VariableConfigMethod returns a Variable whose value is determined by calling
// a method on the config object. The method must take no arguments and return
// a single string that will be the variable's value. It may only be called
// during a Go package's initialization - either from the init() function or as
// part of a package-scoped variable's initialization.
//
// This function is usually used to initialize a package-scoped Go variable that
// represents a Ninja variable that will be output. The name argument should
// exactly match the Go variable name, and the value string returned by method
// may reference other Ninja variables that are visible within the calling Go
// package.
func (p *packageContext) VariableConfigMethod(name string,
method interface{}) Variable {
checkCalledFromInit()
err := validateNinjaName(name)
if err != nil {
panic(err)
}
methodValue := reflect.ValueOf(method)
validateVariableMethod(name, methodValue)
fun := func(config interface{}) (string, error) {
result := methodValue.Call([]reflect.Value{reflect.ValueOf(config)})
resultStr := result[0].Interface().(string)
return resultStr, nil
}
v := &variableFunc{p, name, fun}
err = p.scope.AddVariable(v)
if err != nil {
panic(err)
}
return v
}
func (v *variableFunc) packageContext() *packageContext {
return v.pctx
}
func (v *variableFunc) name() string {
return v.name_
}
func (v *variableFunc) fullName(pkgNames map[*packageContext]string) string {
return packageNamespacePrefix(pkgNames[v.pctx]) + v.name_
}
func (v *variableFunc) value(config interface{}) (*ninjaString, error) {
value, err := v.value_(config)
if err != nil {
return nil, err
}
ninjaStr, err := parseNinjaString(v.pctx.scope, value)
if err != nil {
err = fmt.Errorf("error parsing variable %s value: %s", v, err)
panic(err)
}
return ninjaStr, nil
}
func (v *variableFunc) String() string {
return v.pctx.pkgPath + "." + v.name_
}
func validateVariableMethod(name string, methodValue reflect.Value) {
methodType := methodValue.Type()
if methodType.Kind() != reflect.Func {
panic(fmt.Errorf("method given for variable %s is not a function",
name))
}
if n := methodType.NumIn(); n != 1 {
panic(fmt.Errorf("method for variable %s has %d inputs (should be 1)",
name, n))
}
if n := methodType.NumOut(); n != 1 {
panic(fmt.Errorf("method for variable %s has %d outputs (should be 1)",
name, n))
}
if kind := methodType.Out(0).Kind(); kind != reflect.String {
panic(fmt.Errorf("method for variable %s does not return a string",
name))
}
}
// An argVariable is a Variable that exists only when it is set by a build
// statement to pass a value to the rule being invoked. It has no value, so it
// can never be used to create a Ninja assignment statement. It is inserted
// into the rule's scope, which is used for name lookups within the rule and
// when assigning argument values as part of a build statement.
type argVariable struct {
name_ string
}
func (v *argVariable) packageContext() *packageContext {
panic("this should not be called")
}
func (v *argVariable) name() string {
return v.name_
}
func (v *argVariable) fullName(pkgNames map[*packageContext]string) string {
return v.name_
}
func (v *argVariable) value(config interface{}) (*ninjaString, error) {
return nil, errVariableIsArg
}
func (v *argVariable) String() string {
return "<arg>:" + v.name_
}
type staticPool struct {
pctx *packageContext
name_ string
params PoolParams
}
// StaticPool returns a Pool whose value does not depend on any configuration
// information. It may only be called during a Go package's initialization -
// either from the init() function or as part of a package-scoped Go variable's
// initialization.
//
// This function is usually used to initialize a package-scoped Go variable that
// represents a Ninja pool that will be output. The name argument should
// exactly match the Go variable name, and the params fields may reference other
// Ninja variables that are visible within the calling Go package.
func (p *packageContext) StaticPool(name string, params PoolParams) Pool {
checkCalledFromInit()
err := validateNinjaName(name)
if err != nil {
panic(err)
}
pool := &staticPool{p, name, params}
err = p.scope.AddPool(pool)
if err != nil {
panic(err)
}
return pool
}
func (p *staticPool) packageContext() *packageContext {
return p.pctx
}
func (p *staticPool) name() string {
return p.name_
}
func (p *staticPool) fullName(pkgNames map[*packageContext]string) string {
return packageNamespacePrefix(pkgNames[p.pctx]) + p.name_
}
func (p *staticPool) def(config interface{}) (*poolDef, error) {
def, err := parsePoolParams(p.pctx.scope, &p.params)
if err != nil {
panic(fmt.Errorf("error parsing PoolParams for %s: %s", p, err))
}
return def, nil
}
func (p *staticPool) String() string {
return p.pctx.pkgPath + "." + p.name_
}
type poolFunc struct {
pctx *packageContext
name_ string
paramsFunc func(interface{}) (PoolParams, error)
}
// PoolFunc returns a Pool whose value is determined by a function that takes a
// config object as input and returns either the pool parameters or an error. It
// may only be called during a Go package's initialization - either from the
// init() function or as part of a package-scoped variable's initialization.
//
// This function is usually used to initialize a package-scoped Go variable that
// represents a Ninja pool that will be output. The name argument should
// exactly match the Go variable name, and the string fields of the PoolParams
// returned by f may reference other Ninja variables that are visible within the
// calling Go package.
func (p *packageContext) PoolFunc(name string, f func(interface{}) (PoolParams,
error)) Pool {
checkCalledFromInit()
err := validateNinjaName(name)
if err != nil {
panic(err)
}
pool := &poolFunc{p, name, f}
err = p.scope.AddPool(pool)
if err != nil {
panic(err)
}
return pool
}
func (p *poolFunc) packageContext() *packageContext {
return p.pctx
}
func (p *poolFunc) name() string {
return p.name_
}
func (p *poolFunc) fullName(pkgNames map[*packageContext]string) string {
return packageNamespacePrefix(pkgNames[p.pctx]) + p.name_
}
func (p *poolFunc) def(config interface{}) (*poolDef, error) {
params, err := p.paramsFunc(config)
if err != nil {
return nil, err
}
def, err := parsePoolParams(p.pctx.scope, &params)
if err != nil {
panic(fmt.Errorf("error parsing PoolParams for %s: %s", p, err))
}
return def, nil
}
func (p *poolFunc) String() string {
return p.pctx.pkgPath + "." + p.name_
}
type builtinPool struct {
name_ string
}
func (p *builtinPool) packageContext() *packageContext {
return nil
}
func (p *builtinPool) name() string {
return p.name_
}
func (p *builtinPool) fullName(pkgNames map[*packageContext]string) string {
return p.name_
}
func (p *builtinPool) def(config interface{}) (*poolDef, error) {
return nil, errPoolIsBuiltin
}
func (p *builtinPool) String() string {
return "<builtin>:" + p.name_
}
type staticRule struct {
pctx *packageContext
name_ string
params RuleParams
argNames map[string]bool
scope_ *basicScope
sync.Mutex // protects scope_ during lazy creation
}
// StaticRule returns a Rule whose value does not depend on any configuration
// information. It may only be called during a Go package's initialization -
// either from the init() function or as part of a package-scoped Go variable's
// initialization.
//
// This function is usually used to initialize a package-scoped Go variable that
// represents a Ninja rule that will be output. The name argument should
// exactly match the Go variable name, and the params fields may reference other
// Ninja variables that are visible within the calling Go package.
//
// The argNames arguments list Ninja variables that may be overridden by Ninja
// build statements that invoke the rule. These arguments may be referenced in
// any of the string fields of params. Arguments can shadow package-scoped
// variables defined within the caller's Go package, but they may not shadow
// those defined in another package. Shadowing a package-scoped variable
// results in the package-scoped variable's value being used for build
// statements that do not override the argument. For argument names that do not
// shadow package-scoped variables the default value is an empty string.
func (p *packageContext) StaticRule(name string, params RuleParams,
argNames ...string) Rule {
checkCalledFromInit()
err := validateNinjaName(name)
if err != nil {
panic(err)
}
err = validateArgNames(argNames)
if err != nil {
panic(fmt.Errorf("invalid argument name: %s", err))
}
argNamesSet := make(map[string]bool)
for _, argName := range argNames {
argNamesSet[argName] = true
}
ruleScope := (*basicScope)(nil) // This will get created lazily
r := &staticRule{
pctx: p,
name_: name,
params: params,
argNames: argNamesSet,
scope_: ruleScope,
}
err = p.scope.AddRule(r)
if err != nil {
panic(err)
}
return r
}
func (r *staticRule) packageContext() *packageContext {
return r.pctx
}
func (r *staticRule) name() string {
return r.name_
}
func (r *staticRule) fullName(pkgNames map[*packageContext]string) string {
return packageNamespacePrefix(pkgNames[r.pctx]) + r.name_
}
func (r *staticRule) def(interface{}) (*ruleDef, error) {
def, err := parseRuleParams(r.scope(), &r.params)
if err != nil {
panic(fmt.Errorf("error parsing RuleParams for %s: %s", r, err))
}
return def, nil
}
func (r *staticRule) scope() *basicScope {
// We lazily create the scope so that all the package-scoped variables get
// declared before the args are created. Otherwise we could incorrectly
// shadow a package-scoped variable with an arg variable.
r.Lock()
defer r.Unlock()
if r.scope_ == nil {
r.scope_ = makeRuleScope(r.pctx.scope, r.argNames)
}
return r.scope_
}
func (r *staticRule) isArg(argName string) bool {
return r.argNames[argName]
}
func (r *staticRule) String() string {
return r.pctx.pkgPath + "." + r.name_
}
type ruleFunc struct {
pctx *packageContext
name_ string
paramsFunc func(interface{}) (RuleParams, error)
argNames map[string]bool
scope_ *basicScope
sync.Mutex // protects scope_ during lazy creation
}
// RuleFunc returns a Rule whose value is determined by a function that takes a
// config object as input and returns either the rule parameters or an error. It
// may only be called during a Go package's initialization - either from the
// init() function or as part of a package-scoped variable's initialization.
//
// This function is usually used to initialize a package-scoped Go variable that
// represents a Ninja rule that will be output. The name argument should
// exactly match the Go variable name, and the string fields of the RuleParams
// returned by f may reference other Ninja variables that are visible within the
// calling Go package.
//
// The argNames arguments list Ninja variables that may be overridden by Ninja
// build statements that invoke the rule. These arguments may be referenced in
// any of the string fields of the RuleParams returned by f. Arguments can
// shadow package-scoped variables defined within the caller's Go package, but
// they may not shadow those defined in another package. Shadowing a package-
// scoped variable results in the package-scoped variable's value being used for
// build statements that do not override the argument. For argument names that
// do not shadow package-scoped variables the default value is an empty string.
func (p *packageContext) RuleFunc(name string, f func(interface{}) (RuleParams,
error), argNames ...string) Rule {
checkCalledFromInit()
err := validateNinjaName(name)
if err != nil {
panic(err)
}
err = validateArgNames(argNames)
if err != nil {
panic(fmt.Errorf("invalid argument name: %s", err))
}
argNamesSet := make(map[string]bool)
for _, argName := range argNames {
argNamesSet[argName] = true
}
ruleScope := (*basicScope)(nil) // This will get created lazily
rule := &ruleFunc{
pctx: p,
name_: name,
paramsFunc: f,
argNames: argNamesSet,
scope_: ruleScope,
}
err = p.scope.AddRule(rule)
if err != nil {
panic(err)
}
return rule
}
func (r *ruleFunc) packageContext() *packageContext {
return r.pctx
}
func (r *ruleFunc) name() string {
return r.name_
}
func (r *ruleFunc) fullName(pkgNames map[*packageContext]string) string {
return packageNamespacePrefix(pkgNames[r.pctx]) + r.name_
}
func (r *ruleFunc) def(config interface{}) (*ruleDef, error) {
params, err := r.paramsFunc(config)
if err != nil {
return nil, err
}
def, err := parseRuleParams(r.scope(), &params)
if err != nil {
panic(fmt.Errorf("error parsing RuleParams for %s: %s", r, err))
}
return def, nil
}
func (r *ruleFunc) scope() *basicScope {
// We lazily create the scope so that all the global variables get declared
// before the args are created. Otherwise we could incorrectly shadow a
// global variable with an arg variable.
r.Lock()
defer r.Unlock()
if r.scope_ == nil {
r.scope_ = makeRuleScope(r.pctx.scope, r.argNames)
}
return r.scope_
}
func (r *ruleFunc) isArg(argName string) bool {
return r.argNames[argName]
}
func (r *ruleFunc) String() string {
return r.pctx.pkgPath + "." + r.name_
}
type builtinRule struct {
name_ string
scope_ *basicScope
sync.Mutex // protects scope_ during lazy creation
}
func (r *builtinRule) packageContext() *packageContext {
return nil
}
func (r *builtinRule) name() string {
return r.name_
}
func (r *builtinRule) fullName(pkgNames map[*packageContext]string) string {
return r.name_
}
func (r *builtinRule) def(config interface{}) (*ruleDef, error) {
return nil, errRuleIsBuiltin
}
func (r *builtinRule) scope() *basicScope {
r.Lock()
defer r.Unlock()
if r.scope_ == nil {
r.scope_ = makeRuleScope(nil, nil)
}
return r.scope_
}
func (r *builtinRule) isArg(argName string) bool {
return false
}
func (r *builtinRule) String() string {
return "<builtin>:" + r.name_
}