// Copyright 2015 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 ( "fmt" "reflect" "runtime" "strings" "github.com/google/blueprint" "github.com/google/blueprint/proptools" ) func init() { RegisterBottomUpMutator("defaults_deps", defaultsDepsMutator) RegisterTopDownMutator("defaults", defaultsMutator) RegisterBottomUpMutator("arch", ArchMutator) } var ( Arm = newArch("arm", "lib32") Arm64 = newArch("arm64", "lib64") Mips = newArch("mips", "lib32") Mips64 = newArch("mips64", "lib64") X86 = newArch("x86", "lib32") X86_64 = newArch("x86_64", "lib64") Common = ArchType{ Name: "common", } ) var archTypeMap = map[string]ArchType{ "arm": Arm, "arm64": Arm64, "mips": Mips, "mips64": Mips64, "x86": X86, "x86_64": X86_64, } /* Example blueprints file containing all variant property groups, with comment listing what type of variants get properties in that group: module { arch: { arm: { // Host or device variants with arm architecture }, arm64: { // Host or device variants with arm64 architecture }, mips: { // Host or device variants with mips architecture }, mips64: { // Host or device variants with mips64 architecture }, x86: { // Host or device variants with x86 architecture }, x86_64: { // Host or device variants with x86_64 architecture }, }, multilib: { lib32: { // Host or device variants for 32-bit architectures }, lib64: { // Host or device variants for 64-bit architectures }, }, target: { android: { // Device variants }, host: { // Host variants }, linux: { // Linux host variants }, darwin: { // Darwin host variants }, windows: { // Windows host variants }, not_windows: { // Non-windows host variants }, }, } */ type Embed interface{} type archProperties struct { // Properties to vary by target architecture Arch struct { // Properties for module variants being built to run on arm (host or device) Arm struct { Embed `blueprint:"filter(android:\"arch_variant\")"` // Arm arch variants Armv5te interface{} `blueprint:"filter(android:\"arch_variant\")"` Armv7_a interface{} `blueprint:"filter(android:\"arch_variant\")"` Armv7_a_neon interface{} `blueprint:"filter(android:\"arch_variant\")"` // Arm cpu variants Cortex_a7 interface{} `blueprint:"filter(android:\"arch_variant\")"` Cortex_a8 interface{} `blueprint:"filter(android:\"arch_variant\")"` Cortex_a9 interface{} `blueprint:"filter(android:\"arch_variant\")"` Cortex_a15 interface{} `blueprint:"filter(android:\"arch_variant\")"` Cortex_a53 interface{} `blueprint:"filter(android:\"arch_variant\")"` Cortex_a53_a57 interface{} `blueprint:"filter(android:\"arch_variant\")"` Krait interface{} `blueprint:"filter(android:\"arch_variant\")"` Denver interface{} `blueprint:"filter(android:\"arch_variant\")"` } // Properties for module variants being built to run on arm64 (host or device) Arm64 struct { Embed `blueprint:"filter(android:\"arch_variant\")"` // Arm64 arch variants Armv8_a interface{} `blueprint:"filter(android:\"arch_variant\")"` // Arm64 cpu variants Cortex_a53 interface{} `blueprint:"filter(android:\"arch_variant\")"` Denver64 interface{} `blueprint:"filter(android:\"arch_variant\")"` } // Properties for module variants being built to run on mips (host or device) Mips struct { Embed `blueprint:"filter(android:\"arch_variant\")"` // Mips arch variants Mips32_fp interface{} `blueprint:"filter(android:\"arch_variant\")"` Mips32r2_fp interface{} `blueprint:"filter(android:\"arch_variant\")"` Mips32r2_fp_xburst interface{} `blueprint:"filter(android:\"arch_variant\")"` Mips32r2dsp_fp interface{} `blueprint:"filter(android:\"arch_variant\")"` Mips32r2dspr2_fp interface{} `blueprint:"filter(android:\"arch_variant\")"` Mips32r6 interface{} `blueprint:"filter(android:\"arch_variant\")"` // Mips arch features Rev6 interface{} `blueprint:"filter(android:\"arch_variant\")"` } // Properties for module variants being built to run on mips64 (host or device) Mips64 struct { Embed `blueprint:"filter(android:\"arch_variant\")"` // Mips64 arch variants Mips64r2 interface{} `blueprint:"filter(android:\"arch_variant\")"` Mips64r6 interface{} `blueprint:"filter(android:\"arch_variant\")"` // Mips64 arch features Rev6 interface{} `blueprint:"filter(android:\"arch_variant\")"` } // Properties for module variants being built to run on x86 (host or device) X86 struct { Embed `blueprint:"filter(android:\"arch_variant\")"` // X86 arch variants Atom interface{} `blueprint:"filter(android:\"arch_variant\")"` Haswell interface{} `blueprint:"filter(android:\"arch_variant\")"` Ivybridge interface{} `blueprint:"filter(android:\"arch_variant\")"` Sandybridge interface{} `blueprint:"filter(android:\"arch_variant\")"` Silvermont interface{} `blueprint:"filter(android:\"arch_variant\")"` // Generic variant for X86 on X86_64 X86_64 interface{} `blueprint:"filter(android:\"arch_variant\")"` // X86 arch features Ssse3 interface{} `blueprint:"filter(android:\"arch_variant\")"` Sse4 interface{} `blueprint:"filter(android:\"arch_variant\")"` Sse4_1 interface{} `blueprint:"filter(android:\"arch_variant\")"` Sse4_2 interface{} `blueprint:"filter(android:\"arch_variant\")"` Aes_ni interface{} `blueprint:"filter(android:\"arch_variant\")"` Avx interface{} `blueprint:"filter(android:\"arch_variant\")"` Popcnt interface{} `blueprint:"filter(android:\"arch_variant\")"` Movbe interface{} `blueprint:"filter(android:\"arch_variant\")"` } // Properties for module variants being built to run on x86_64 (host or device) X86_64 struct { Embed `blueprint:"filter(android:\"arch_variant\")"` // X86 arch variants Haswell interface{} `blueprint:"filter(android:\"arch_variant\")"` Ivybridge interface{} `blueprint:"filter(android:\"arch_variant\")"` Sandybridge interface{} `blueprint:"filter(android:\"arch_variant\")"` Silvermont interface{} `blueprint:"filter(android:\"arch_variant\")"` // X86 arch features Ssse3 interface{} `blueprint:"filter(android:\"arch_variant\")"` Sse4 interface{} `blueprint:"filter(android:\"arch_variant\")"` Sse4_1 interface{} `blueprint:"filter(android:\"arch_variant\")"` Sse4_2 interface{} `blueprint:"filter(android:\"arch_variant\")"` Aes_ni interface{} `blueprint:"filter(android:\"arch_variant\")"` Avx interface{} `blueprint:"filter(android:\"arch_variant\")"` Popcnt interface{} `blueprint:"filter(android:\"arch_variant\")"` } } // Properties to vary by 32-bit or 64-bit Multilib struct { // Properties for module variants being built to run on 32-bit devices Lib32 interface{} `blueprint:"filter(android:\"arch_variant\")"` // Properties for module variants being built to run on 64-bit devices Lib64 interface{} `blueprint:"filter(android:\"arch_variant\")"` } // Properties to vary by build target (host or device, os, os+archictecture) Target struct { // Properties for module variants being built to run on the host Host interface{} `blueprint:"filter(android:\"arch_variant\")"` // Properties for module variants being built to run on the device Android interface{} `blueprint:"filter(android:\"arch_variant\")"` // Properties for module variants being built to run on arm devices Android_arm interface{} `blueprint:"filter(android:\"arch_variant\")"` // Properties for module variants being built to run on arm64 devices Android_arm64 interface{} `blueprint:"filter(android:\"arch_variant\")"` // Properties for module variants being built to run on mips devices Android_mips interface{} `blueprint:"filter(android:\"arch_variant\")"` // Properties for module variants being built to run on mips64 devices Android_mips64 interface{} `blueprint:"filter(android:\"arch_variant\")"` // Properties for module variants being built to run on x86 devices Android_x86 interface{} `blueprint:"filter(android:\"arch_variant\")"` // Properties for module variants being built to run on x86_64 devices Android_x86_64 interface{} `blueprint:"filter(android:\"arch_variant\")"` // Properties for module variants being built to run on devices that support 64-bit Android64 interface{} `blueprint:"filter(android:\"arch_variant\")"` // Properties for module variants being built to run on devices that do not support 64-bit Android32 interface{} `blueprint:"filter(android:\"arch_variant\")"` // Properties for module variants being built to run on linux hosts Linux interface{} `blueprint:"filter(android:\"arch_variant\")"` // Properties for module variants being built to run on linux x86 hosts Linux_x86 interface{} `blueprint:"filter(android:\"arch_variant\")"` // Properties for module variants being built to run on linux x86_64 hosts Linux_x86_64 interface{} `blueprint:"filter(android:\"arch_variant\")"` // Properties for module variants being built to run on darwin hosts Darwin interface{} `blueprint:"filter(android:\"arch_variant\")"` // Properties for module variants being built to run on darwin x86 hosts Darwin_x86 interface{} `blueprint:"filter(android:\"arch_variant\")"` // Properties for module variants being built to run on darwin x86_64 hosts Darwin_x86_64 interface{} `blueprint:"filter(android:\"arch_variant\")"` // Properties for module variants being built to run on windows hosts Windows interface{} `blueprint:"filter(android:\"arch_variant\")"` // Properties for module variants being built to run on windows x86 hosts Windows_x86 interface{} `blueprint:"filter(android:\"arch_variant\")"` // Properties for module variants being built to run on windows x86_64 hosts Windows_x86_64 interface{} `blueprint:"filter(android:\"arch_variant\")"` // Properties for module variants being built to run on linux or darwin hosts Not_windows interface{} `blueprint:"filter(android:\"arch_variant\")"` } } var archFeatureMap = map[ArchType]map[string][]string{} func RegisterArchFeatures(arch ArchType, variant string, features ...string) { archField := proptools.FieldNameForProperty(arch.Name) variantField := proptools.FieldNameForProperty(variant) archStruct := reflect.ValueOf(archProperties{}.Arch).FieldByName(archField) if variant != "" { if !archStruct.FieldByName(variantField).IsValid() { panic(fmt.Errorf("Invalid variant %q for arch %q", variant, arch)) } } for _, feature := range features { field := proptools.FieldNameForProperty(feature) if !archStruct.FieldByName(field).IsValid() { panic(fmt.Errorf("Invalid feature %q for arch %q variant %q", feature, arch, variant)) } } if archFeatureMap[arch] == nil { archFeatureMap[arch] = make(map[string][]string) } archFeatureMap[arch][variant] = features } // An Arch indicates a single CPU architecture. type Arch struct { ArchType ArchType ArchVariant string CpuVariant string Abi []string ArchFeatures []string Native bool } func (a Arch) String() string { s := a.ArchType.String() if a.ArchVariant != "" { s += "_" + a.ArchVariant } if a.CpuVariant != "" { s += "_" + a.CpuVariant } return s } type ArchType struct { Name string Multilib string } func newArch(name, multilib string) ArchType { return ArchType{ Name: name, Multilib: multilib, } } func (a ArchType) String() string { return a.Name } var BuildOs = func() OsType { switch runtime.GOOS { case "linux": return Linux case "darwin": return Darwin default: panic(fmt.Sprintf("unsupported OS: %s", runtime.GOOS)) } }() var ( osTypeList []OsType NoOsType OsType Linux = NewOsType("linux", Host) Darwin = NewOsType("darwin", Host) Windows = NewOsType("windows", HostCross) Android = NewOsType("android", Device) ) type OsType struct { Name, Field string Class OsClass } type OsClass int const ( Device OsClass = iota Host HostCross ) func (os OsType) String() string { return os.Name } func NewOsType(name string, class OsClass) OsType { os := OsType{ Name: name, Field: strings.Title(name), Class: class, } osTypeList = append(osTypeList, os) return os } func osByName(name string) OsType { for _, os := range osTypeList { if os.Name == name { return os } } return NoOsType } var ( commonTarget = Target{ Os: Android, Arch: Arch{ ArchType: Common, }, } ) type Target struct { Os OsType Arch Arch } func (target Target) String() string { return target.Os.String() + "_" + target.Arch.String() } func ArchMutator(mctx BottomUpMutatorContext) { var module Module var ok bool if module, ok = mctx.Module().(Module); !ok { return } osClasses := module.base().OsClassSupported() if len(osClasses) == 0 { return } var moduleTargets []Target for _, class := range osClasses { targets := mctx.AConfig().Targets[class] if len(targets) == 0 { continue } multilib := module.base().commonProperties.Compile_multilib targets, err := decodeMultilib(multilib, targets) if err != nil { mctx.ModuleErrorf("%s", err.Error()) } moduleTargets = append(moduleTargets, targets...) } if len(moduleTargets) == 0 { module.base().commonProperties.Enabled = boolPtr(false) return } targetNames := make([]string, len(moduleTargets)) for i, target := range moduleTargets { targetNames[i] = target.String() } modules := mctx.CreateVariations(targetNames...) for i, m := range modules { m.(Module).base().SetTarget(moduleTargets[i]) m.(Module).base().setArchProperties(mctx) } } func InitArchModule(m Module, propertyStructs ...interface{}) (blueprint.Module, []interface{}) { base := m.base() base.generalProperties = append(base.generalProperties, propertyStructs...) for _, properties := range base.generalProperties { propertiesValue := reflect.ValueOf(properties) if propertiesValue.Kind() != reflect.Ptr { panic(fmt.Errorf("properties must be a pointer to a struct, got %T", propertiesValue.Interface())) } propertiesValue = propertiesValue.Elem() if propertiesValue.Kind() != reflect.Struct { panic(fmt.Errorf("properties must be a pointer to a struct, got %T", propertiesValue.Interface())) } archProperties := &archProperties{} forEachInterface(reflect.ValueOf(archProperties), func(v reflect.Value) { newValue := proptools.CloneEmptyProperties(propertiesValue) v.Set(newValue) }) base.archProperties = append(base.archProperties, archProperties) } var allProperties []interface{} allProperties = append(allProperties, base.generalProperties...) for _, asp := range base.archProperties { allProperties = append(allProperties, asp) } return m, allProperties } var variantReplacer = strings.NewReplacer("-", "_", ".", "_") func (a *ModuleBase) appendProperties(ctx BottomUpMutatorContext, dst, src interface{}, field, srcPrefix string) interface{} { srcField := reflect.ValueOf(src).FieldByName(field) if !srcField.IsValid() { ctx.ModuleErrorf("field %q does not exist", srcPrefix) return nil } ret := srcField if srcField.Kind() == reflect.Struct { srcField = srcField.FieldByName("Embed") } src = srcField.Elem().Interface() filter := func(property string, dstField, srcField reflect.StructField, dstValue, srcValue interface{}) (bool, error) { srcProperty := srcPrefix + "." + property if !proptools.HasTag(dstField, "android", "arch_variant") { if ctx.ContainsProperty(srcProperty) { return false, fmt.Errorf("can't be specific to a build variant") } else { return false, nil } } return true, nil } order := func(property string, dstField, srcField reflect.StructField, dstValue, srcValue interface{}) (proptools.Order, error) { if proptools.HasTag(dstField, "android", "variant_prepend") { return proptools.Prepend, nil } else { return proptools.Append, nil } } err := proptools.ExtendProperties(dst, src, filter, order) if err != nil { if propertyErr, ok := err.(*proptools.ExtendPropertyError); ok { ctx.PropertyErrorf(propertyErr.Property, "%s", propertyErr.Err.Error()) } else { panic(err) } } return ret.Interface() } // Rewrite the module's properties structs to contain arch-specific values. func (a *ModuleBase) setArchProperties(ctx BottomUpMutatorContext) { arch := a.Arch() os := a.Os() if arch.ArchType == Common { return } for i := range a.generalProperties { genProps := a.generalProperties[i] archProps := a.archProperties[i] // Handle arch-specific properties in the form: // arch: { // arm64: { // key: value, // }, // }, t := arch.ArchType field := proptools.FieldNameForProperty(t.Name) prefix := "arch." + t.Name archStruct := a.appendProperties(ctx, genProps, archProps.Arch, field, prefix) // Handle arch-variant-specific properties in the form: // arch: { // variant: { // key: value, // }, // }, v := variantReplacer.Replace(arch.ArchVariant) if v != "" { field := proptools.FieldNameForProperty(v) prefix := "arch." + t.Name + "." + v a.appendProperties(ctx, genProps, archStruct, field, prefix) } // Handle cpu-variant-specific properties in the form: // arch: { // variant: { // key: value, // }, // }, c := variantReplacer.Replace(arch.CpuVariant) if c != "" { field := proptools.FieldNameForProperty(c) prefix := "arch." + t.Name + "." + c a.appendProperties(ctx, genProps, archStruct, field, prefix) } // Handle arch-feature-specific properties in the form: // arch: { // feature: { // key: value, // }, // }, for _, feature := range arch.ArchFeatures { field := proptools.FieldNameForProperty(feature) prefix := "arch." + t.Name + "." + feature a.appendProperties(ctx, genProps, archStruct, field, prefix) } // Handle multilib-specific properties in the form: // multilib: { // lib32: { // key: value, // }, // }, field = proptools.FieldNameForProperty(t.Multilib) prefix = "multilib." + t.Multilib a.appendProperties(ctx, genProps, archProps.Multilib, field, prefix) // Handle host-specific properties in the form: // target: { // host: { // key: value, // }, // }, if os.Class == Host || os.Class == HostCross { field = "Host" prefix = "target.host" a.appendProperties(ctx, genProps, archProps.Target, field, prefix) } // Handle target OS properties in the form: // target: { // linux: { // key: value, // }, // not_windows: { // key: value, // }, // linux_x86: { // key: value, // }, // linux_arm: { // key: value, // }, // android { // key: value, // }, // android_arm { // key: value, // }, // android_x86 { // key: value, // }, // }, // }, field = os.Field prefix = "target." + os.Name a.appendProperties(ctx, genProps, archProps.Target, field, prefix) field = os.Field + "_" + t.Name prefix = "target." + os.Name + "_" + t.Name a.appendProperties(ctx, genProps, archProps.Target, field, prefix) if (os.Class == Host || os.Class == HostCross) && os != Windows { field := "Not_windows" prefix := "target.not_windows" a.appendProperties(ctx, genProps, archProps.Target, field, prefix) } // Handle 64-bit device properties in the form: // target { // android64 { // key: value, // }, // android32 { // key: value, // }, // }, // WARNING: this is probably not what you want to use in your blueprints file, it selects // options for all targets on a device that supports 64-bit binaries, not just the targets // that are being compiled for 64-bit. Its expected use case is binaries like linker and // debuggerd that need to know when they are a 32-bit process running on a 64-bit device if os.Class == Device { if ctx.AConfig().Android64() { field := "Android64" prefix := "target.android64" a.appendProperties(ctx, genProps, archProps.Target, field, prefix) } else { field := "Android32" prefix := "target.android32" a.appendProperties(ctx, genProps, archProps.Target, field, prefix) } } } } func forEachInterface(v reflect.Value, f func(reflect.Value)) { switch v.Kind() { case reflect.Interface: f(v) case reflect.Struct: for i := 0; i < v.NumField(); i++ { forEachInterface(v.Field(i), f) } case reflect.Ptr: forEachInterface(v.Elem(), f) default: panic(fmt.Errorf("Unsupported kind %s", v.Kind())) } } // Convert the arch product variables into a list of targets for each os class structs func decodeTargetProductVariables(config Config) (map[OsClass][]Target, error) { variables := config.ProductVariables targets := make(map[OsClass][]Target) var targetErr error addTarget := func(os OsType, archName string, archVariant, cpuVariant *string, abi *[]string) { if targetErr != nil { return } arch, err := decodeArch(archName, archVariant, cpuVariant, abi) if err != nil { targetErr = err return } targets[os.Class] = append(targets[os.Class], Target{ Os: os, Arch: arch, }) } if variables.HostArch == nil { return nil, fmt.Errorf("No host primary architecture set") } addTarget(BuildOs, *variables.HostArch, nil, nil, nil) if variables.HostSecondaryArch != nil && *variables.HostSecondaryArch != "" { addTarget(BuildOs, *variables.HostSecondaryArch, nil, nil, nil) } if variables.CrossHost != nil && *variables.CrossHost != "" { crossHostOs := osByName(*variables.CrossHost) if crossHostOs == NoOsType { return nil, fmt.Errorf("Unknown cross host OS %q", *variables.CrossHost) } if variables.CrossHostArch == nil || *variables.CrossHostArch == "" { return nil, fmt.Errorf("No cross-host primary architecture set") } addTarget(crossHostOs, *variables.CrossHostArch, nil, nil, nil) if variables.CrossHostSecondaryArch != nil && *variables.CrossHostSecondaryArch != "" { addTarget(crossHostOs, *variables.CrossHostSecondaryArch, nil, nil, nil) } } if variables.DeviceArch != nil && *variables.DeviceArch != "" { addTarget(Android, *variables.DeviceArch, variables.DeviceArchVariant, variables.DeviceCpuVariant, variables.DeviceAbi) if variables.DeviceSecondaryArch != nil && *variables.DeviceSecondaryArch != "" { addTarget(Android, *variables.DeviceSecondaryArch, variables.DeviceSecondaryArchVariant, variables.DeviceSecondaryCpuVariant, variables.DeviceSecondaryAbi) deviceArches := targets[Device] if deviceArches[0].Arch.ArchType.Multilib == deviceArches[1].Arch.ArchType.Multilib { deviceArches[1].Arch.Native = false } } } if targetErr != nil { return nil, targetErr } return targets, nil } func decodeMegaDevice() ([]Target, error) { archSettings := []struct { arch string archVariant string cpuVariant string abi []string }{ // armv5 is only used for unbundled apps //{"arm", "armv5te", "", []string{"armeabi"}}, {"arm", "armv7-a", "generic", []string{"armeabi-v7a"}}, {"arm", "armv7-a-neon", "generic", []string{"armeabi-v7a"}}, {"arm", "armv7-a-neon", "cortex-a7", []string{"armeabi-v7a"}}, {"arm", "armv7-a-neon", "cortex-a8", []string{"armeabi-v7a"}}, {"arm", "armv7-a-neon", "cortex-a9", []string{"armeabi-v7a"}}, {"arm", "armv7-a-neon", "cortex-a15", []string{"armeabi-v7a"}}, {"arm", "armv7-a-neon", "cortex-a53", []string{"armeabi-v7a"}}, {"arm", "armv7-a-neon", "cortex-a53.a57", []string{"armeabi-v7a"}}, {"arm", "armv7-a-neon", "denver", []string{"armeabi-v7a"}}, {"arm", "armv7-a-neon", "krait", []string{"armeabi-v7a"}}, {"arm64", "armv8-a", "cortex-a53", []string{"arm64-v8a"}}, {"arm64", "armv8-a", "denver64", []string{"arm64-v8a"}}, {"mips", "mips32-fp", "", []string{"mips"}}, {"mips", "mips32r2-fp", "", []string{"mips"}}, {"mips", "mips32r2-fp-xburst", "", []string{"mips"}}, {"mips", "mips32r6", "", []string{"mips"}}, // mips32r2dsp[r2]-fp fails in the assembler for divdf3.c in compiler-rt: // (same errors in make and soong) // Error: invalid operands `mtlo $ac0,$11' // Error: invalid operands `mthi $ac0,$12' //{"mips", "mips32r2dsp-fp", "", []string{"mips"}}, //{"mips", "mips32r2dspr2-fp", "", []string{"mips"}}, // mips64r2 is mismatching 64r2 and 64r6 libraries during linking to libgcc //{"mips64", "mips64r2", "", []string{"mips64"}}, {"mips64", "mips64r6", "", []string{"mips64"}}, {"x86", "", "", []string{"x86"}}, {"x86", "atom", "", []string{"x86"}}, {"x86", "haswell", "", []string{"x86"}}, {"x86", "ivybridge", "", []string{"x86"}}, {"x86", "sandybridge", "", []string{"x86"}}, {"x86", "silvermont", "", []string{"x86"}}, {"x86", "x86_64", "", []string{"x86"}}, {"x86_64", "", "", []string{"x86_64"}}, {"x86_64", "haswell", "", []string{"x86_64"}}, {"x86_64", "ivybridge", "", []string{"x86_64"}}, {"x86_64", "sandybridge", "", []string{"x86_64"}}, {"x86_64", "silvermont", "", []string{"x86_64"}}, } var ret []Target for _, config := range archSettings { arch, err := decodeArch(config.arch, &config.archVariant, &config.cpuVariant, &config.abi) if err != nil { return nil, err } arch.Native = false ret = append(ret, Target{ Os: Android, Arch: arch, }) } return ret, nil } // Convert a set of strings from product variables into a single Arch struct func decodeArch(arch string, archVariant, cpuVariant *string, abi *[]string) (Arch, error) { stringPtr := func(p *string) string { if p != nil { return *p } return "" } slicePtr := func(p *[]string) []string { if p != nil { return *p } return nil } archType, ok := archTypeMap[arch] if !ok { return Arch{}, fmt.Errorf("unknown arch %q", arch) } a := Arch{ ArchType: archType, ArchVariant: stringPtr(archVariant), CpuVariant: stringPtr(cpuVariant), Abi: slicePtr(abi), Native: true, } if a.ArchVariant == a.ArchType.Name || a.ArchVariant == "generic" { a.ArchVariant = "" } if a.CpuVariant == a.ArchType.Name || a.CpuVariant == "generic" { a.CpuVariant = "" } for i := 0; i < len(a.Abi); i++ { if a.Abi[i] == "" { a.Abi = append(a.Abi[:i], a.Abi[i+1:]...) i-- } } if featureMap, ok := archFeatureMap[archType]; ok { a.ArchFeatures = featureMap[a.ArchVariant] } return a, nil } // Use the module multilib setting to select one or more targets from a target list func decodeMultilib(multilib string, targets []Target) ([]Target, error) { buildTargets := []Target{} switch multilib { case "common": buildTargets = append(buildTargets, commonTarget) case "both": buildTargets = append(buildTargets, targets...) case "first": buildTargets = append(buildTargets, targets[0]) case "32": for _, t := range targets { if t.Arch.ArchType.Multilib == "lib32" { buildTargets = append(buildTargets, t) } } case "64": for _, t := range targets { if t.Arch.ArchType.Multilib == "lib64" { buildTargets = append(buildTargets, t) } } default: return nil, fmt.Errorf(`compile_multilib must be "both", "first", "32", or "64", found %q`, multilib) } return buildTargets, nil }