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gerrit-public.fairphone.software / platform / system / tools / hidl / e44e7e38c2658f1c1d6bc2330e7f9b697bb4461f / . / Interface.cpp
blob: 8eb590796a2eed90fa0a68e088a09b767ac5e5a7 [file] [log] [blame]
/*
* Copyright (C) 2016 The Android Open Source Project
*
* 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.
*/
#include "Interface.h"
#include "Annotation.h"
#include "ArrayType.h"
#include "ConstantExpression.h"
#include "DeathRecipientType.h"
#include "Method.h"
#include "ScalarType.h"
#include "StringType.h"
#include "VectorType.h"
#include <unistd.h>
#include <iostream>
#include <memory>
#include <sstream>
#include <unordered_map>
#include <android-base/logging.h>
#include <hidl-hash/Hash.h>
#include <hidl-util/Formatter.h>
#include <hidl-util/StringHelper.h>
namespace android {
#define B_PACK_CHARS(c1, c2, c3, c4) \
((((c1)<<24)) | (((c2)<<16)) | (((c3)<<8)) | (c4))
/* It is very important that these values NEVER change. These values
* must remain unchanged over the lifetime of android. This is
* because the framework on a device will be updated independently of
* the hals on a device. If the hals are compiled with one set of
* transaction values, and the framework with another, then the
* interface between them will be destroyed, and the device will not
* work.
*/
enum {
/////////////////// User defined transactions
FIRST_CALL_TRANSACTION = 0x00000001,
LAST_CALL_TRANSACTION = 0x0effffff,
/////////////////// HIDL reserved
FIRST_HIDL_TRANSACTION = 0x0f000000,
HIDL_PING_TRANSACTION = B_PACK_CHARS(0x0f, 'P', 'N', 'G'),
HIDL_DESCRIPTOR_CHAIN_TRANSACTION = B_PACK_CHARS(0x0f, 'C', 'H', 'N'),
HIDL_GET_DESCRIPTOR_TRANSACTION = B_PACK_CHARS(0x0f, 'D', 'S', 'C'),
HIDL_SYSPROPS_CHANGED_TRANSACTION = B_PACK_CHARS(0x0f, 'S', 'Y', 'S'),
HIDL_LINK_TO_DEATH_TRANSACTION = B_PACK_CHARS(0x0f, 'L', 'T', 'D'),
HIDL_UNLINK_TO_DEATH_TRANSACTION = B_PACK_CHARS(0x0f, 'U', 'T', 'D'),
HIDL_SET_HAL_INSTRUMENTATION_TRANSACTION = B_PACK_CHARS(0x0f, 'I', 'N', 'T'),
HIDL_GET_REF_INFO_TRANSACTION = B_PACK_CHARS(0x0f, 'R', 'E', 'F'),
HIDL_DEBUG_TRANSACTION = B_PACK_CHARS(0x0f, 'D', 'B', 'G'),
HIDL_HASH_CHAIN_TRANSACTION = B_PACK_CHARS(0x0f, 'H', 'S', 'H'),
LAST_HIDL_TRANSACTION = 0x0fffffff,
};
Interface::Interface(const char* localName, const Location& location, Scope* parent,
const Reference<Type>& superType)
: Scope(localName, location, parent),
mSuperType(superType),
mIsJavaCompatibleInProgress(false) {}
std::string Interface::typeName() const {
return "interface " + localName();
}
bool Interface::fillPingMethod(Method *method) const {
if (method->name() != "ping") {
return false;
}
method->fillImplementation(
HIDL_PING_TRANSACTION,
{
{IMPL_INTERFACE,
[](auto &out) {
out << "return ::android::hardware::Void();\n";
}
},
{IMPL_STUB_IMPL,
[](auto &out) {
out << "return ::android::hardware::Void();\n";
}
}
}, /*cppImpl*/
{
{IMPL_INTERFACE,
[](auto &out) {
out << "return;\n";
}
},
{IMPL_STUB, nullptr /* don't generate code */}
} /*javaImpl*/
);
return true;
}
bool Interface::fillLinkToDeathMethod(Method *method) const {
if (method->name() != "linkToDeath") {
return false;
}
method->fillImplementation(
HIDL_LINK_TO_DEATH_TRANSACTION,
{
{IMPL_INTERFACE,
[](auto &out) {
out << "(void)cookie;\n"
<< "return (recipient != nullptr);\n";
}
},
{IMPL_PROXY,
[](auto &out) {
out << "::android::hardware::ProcessState::self()->startThreadPool();\n";
out << "::android::hardware::hidl_binder_death_recipient *binder_recipient"
<< " = new ::android::hardware::hidl_binder_death_recipient(recipient, cookie, this);\n"
<< "std::unique_lock<std::mutex> lock(_hidl_mMutex);\n"
<< "_hidl_mDeathRecipients.push_back(binder_recipient);\n"
<< "return (remote()->linkToDeath(binder_recipient)"
<< " == ::android::OK);\n";
}
},
{IMPL_STUB, nullptr}
}, /*cppImpl*/
{
{IMPL_INTERFACE,
[](auto &out) {
out << "return true;";
}
},
{IMPL_PROXY,
[](auto &out) {
out << "return mRemote.linkToDeath(recipient, cookie);\n";
}
},
{IMPL_STUB, nullptr}
} /*javaImpl*/
);
return true;
}
bool Interface::fillUnlinkToDeathMethod(Method *method) const {
if (method->name() != "unlinkToDeath") {
return false;
}
method->fillImplementation(
HIDL_UNLINK_TO_DEATH_TRANSACTION,
{
{IMPL_INTERFACE,
[](auto &out) {
out << "return (recipient != nullptr);\n";
}
},
{IMPL_PROXY,
[](auto &out) {
out << "std::unique_lock<std::mutex> lock(_hidl_mMutex);\n"
<< "for (auto it = _hidl_mDeathRecipients.begin();"
<< "it != _hidl_mDeathRecipients.end();"
<< "++it) {\n";
out.indent([&] {
out.sIf("(*it)->getRecipient() == recipient", [&] {
out << "::android::status_t status = remote()->unlinkToDeath(*it);\n"
<< "_hidl_mDeathRecipients.erase(it);\n"
<< "return status == ::android::OK;\n";
});
});
out << "}\n";
out << "return false;\n";
}
},
{IMPL_STUB, nullptr /* don't generate code */}
}, /*cppImpl*/
{
{IMPL_INTERFACE,
[](auto &out) {
out << "return true;\n";
}
},
{IMPL_PROXY,
[](auto &out) {
out << "return mRemote.unlinkToDeath(recipient);\n";
}
},
{IMPL_STUB, nullptr /* don't generate code */}
} /*javaImpl*/
);
return true;
}
bool Interface::fillSyspropsChangedMethod(Method *method) const {
if (method->name() != "notifySyspropsChanged") {
return false;
}
method->fillImplementation(
HIDL_SYSPROPS_CHANGED_TRANSACTION,
{ { IMPL_INTERFACE, [](auto &out) {
out << "::android::report_sysprop_change();\n";
out << "return ::android::hardware::Void();";
} } }, /*cppImpl */
{ { IMPL_INTERFACE, [](auto &out) { /* javaImpl */
out << "android.os.HwBinder.reportSyspropChanged();";
} } } /*javaImpl */
);
return true;
}
bool Interface::fillSetHALInstrumentationMethod(Method *method) const {
if (method->name() != "setHALInstrumentation") {
return false;
}
method->fillImplementation(
HIDL_SET_HAL_INSTRUMENTATION_TRANSACTION,
{
{IMPL_INTERFACE,
[](auto &out) {
// do nothing for base class.
out << "return ::android::hardware::Void();\n";
}
},
{IMPL_STUB,
[](auto &out) {
out << "configureInstrumentation();\n";
}
},
{IMPL_PASSTHROUGH,
[](auto &out) {
out << "configureInstrumentation();\n";
out << "return ::android::hardware::Void();\n";
}
},
}, /*cppImpl */
{ { IMPL_INTERFACE, [](auto & /*out*/) { /* javaImpl */
// Not support for Java Impl for now.
} } } /*javaImpl */
);
return true;
}
bool Interface::fillDescriptorChainMethod(Method *method) const {
if (method->name() != "interfaceChain") {
return false;
}
method->fillImplementation(
HIDL_DESCRIPTOR_CHAIN_TRANSACTION,
{ { IMPL_INTERFACE, [this](auto &out) {
std::vector<const Interface *> chain = typeChain();
out << "_hidl_cb(";
out.block([&] {
for (const Interface *iface : chain) {
out << iface->fullName() << "::descriptor,\n";
}
});
out << ");\n";
out << "return ::android::hardware::Void();";
} } }, /* cppImpl */
{ { IMPL_INTERFACE, [this](auto &out) {
std::vector<const Interface *> chain = typeChain();
out << "return new java.util.ArrayList<String>(java.util.Arrays.asList(\n";
out.indent(); out.indent();
for (size_t i = 0; i < chain.size(); ++i) {
if (i != 0)
out << ",\n";
out << chain[i]->fullJavaName() << ".kInterfaceName";
}
out << "));";
out.unindent(); out.unindent();
} } } /* javaImpl */
);
return true;
}
static void emitDigestChain(
Formatter& out, const std::string& prefix, const std::vector<const Interface*>& chain,
std::function<std::string(std::unique_ptr<ConstantExpression>)> byteToString) {
out.join(chain.begin(), chain.end(), ",\n", [&] (const auto &iface) {
const Hash &hash = Hash::getHash(iface->location().begin().filename());
out << prefix;
out << "{";
out.join(hash.raw().begin(), hash.raw().end(), ",", [&](const auto &e) {
// Use ConstantExpression::cppValue / javaValue
// because Java used signed byte for uint8_t.
out << byteToString(ConstantExpression::ValueOf(ScalarType::Kind::KIND_UINT8, e));
});
out << "} /* ";
out << hash.hexString();
out << " */";
});
}
bool Interface::fillHashChainMethod(Method *method) const {
if (method->name() != "getHashChain") {
return false;
}
const VectorType *chainType = static_cast<const VectorType *>(&method->results()[0]->type());
const ArrayType *digestType = static_cast<const ArrayType *>(chainType->getElementType());
method->fillImplementation(
HIDL_HASH_CHAIN_TRANSACTION,
{ { IMPL_INTERFACE, [this, digestType](auto &out) {
std::vector<const Interface *> chain = typeChain();
out << "_hidl_cb(";
out.block([&] {
emitDigestChain(out, "(" + digestType->getInternalDataCppType() + ")", chain,
[](const auto& e) { return e->cppValue(); });
});
out << ");\n";
out << "return ::android::hardware::Void();\n";
} } }, /* cppImpl */
{ { IMPL_INTERFACE, [this, digestType, chainType](auto &out) {
std::vector<const Interface *> chain = typeChain();
out << "return new "
<< chainType->getJavaType(false /* forInitializer */)
<< "(java.util.Arrays.asList(\n";
out.indent(2, [&] {
// No need for dimensions when elements are explicitly provided.
emitDigestChain(out, "new " + digestType->getJavaType(false /* forInitializer */),
chain, [](const auto& e) { return e->javaValue(); });
});
out << "));\n";
} } } /* javaImpl */
);
return true;
}
bool Interface::fillGetDescriptorMethod(Method *method) const {
if (method->name() != "interfaceDescriptor") {
return false;
}
method->fillImplementation(
HIDL_GET_DESCRIPTOR_TRANSACTION,
{ { IMPL_INTERFACE, [this](auto &out) {
out << "_hidl_cb("
<< fullName()
<< "::descriptor);\n"
<< "return ::android::hardware::Void();";
} } }, /* cppImpl */
{ { IMPL_INTERFACE, [this](auto &out) {
out << "return "
<< fullJavaName()
<< ".kInterfaceName;\n";
} } } /* javaImpl */
);
return true;
}
bool Interface::fillGetDebugInfoMethod(Method *method) const {
if (method->name() != "getDebugInfo") {
return false;
}
static const std::string sArch =
"#if defined(__LP64__)\n"
"::android::hidl::base::V1_0::DebugInfo::Architecture::IS_64BIT\n"
"#else\n"
"::android::hidl::base::V1_0::DebugInfo::Architecture::IS_32BIT\n"
"#endif\n";
method->fillImplementation(
HIDL_GET_REF_INFO_TRANSACTION,
{
{IMPL_INTERFACE,
[](auto &out) {
// getDebugInfo returns N/A for local objects.
out << "_hidl_cb({ -1 /* pid */, 0 /* ptr */, \n"
<< sArch
<< "});\n"
<< "return ::android::hardware::Void();";
}
},
{IMPL_STUB_IMPL,
[](auto &out) {
out << "_hidl_cb(";
out.block([&] {
out << "::android::hardware::details::debuggable()"
<< "? getpid() : -1 /* pid */,\n"
<< "::android::hardware::details::debuggable()"
<< "? reinterpret_cast<uint64_t>(this) : 0 /* ptr */,\n"
<< sArch << "\n";
});
out << ");\n"
<< "return ::android::hardware::Void();";
}
}
}, /* cppImpl */
{ { IMPL_INTERFACE, [method](auto &out) {
const Type &refInfo = method->results().front()->type();
out << refInfo.getJavaType(false /* forInitializer */) << " info = new "
<< refInfo.getJavaType(true /* forInitializer */) << "();\n"
// TODO(b/34777099): PID for java.
<< "info.pid = -1;\n"
<< "info.ptr = 0;\n"
<< "info.arch = android.hidl.base.V1_0.DebugInfo.Architecture.UNKNOWN;"
<< "return info;";
} } } /* javaImpl */
);
return true;
}
bool Interface::fillDebugMethod(Method *method) const {
if (method->name() != "debug") {
return false;
}
method->fillImplementation(
HIDL_DEBUG_TRANSACTION,
{
{IMPL_INTERFACE,
[](auto &out) {
out << "(void)fd;\n"
<< "(void)options;\n"
<< "return ::android::hardware::Void();";
}
},
}, /* cppImpl */
{
/* unused, as the debug method is hidden from Java */
} /* javaImpl */
);
return true;
}
static std::map<std::string, Method *> gAllReservedMethods;
bool Interface::addMethod(Method *method) {
if (isIBase()) {
if (!gAllReservedMethods.emplace(method->name(), method).second) {
LOG(ERROR) << "ERROR: hidl-gen encountered duplicated reserved method "
<< method->name();
return false;
}
// will add it in addAllReservedMethods
return true;
}
CHECK(!method->isHidlReserved());
mUserMethods.push_back(method);
return true;
}
std::vector<Reference<Type>> Interface::getReferences() const {
std::vector<Reference<Type>> ret;
if (superType() != nullptr) {
ret.push_back(mSuperType);
}
for (const auto* method : methods()) {
const auto& references = method->getReferences();
ret.insert(ret.end(), references.begin(), references.end());
}
return ret;
}
std::vector<ConstantExpression*> Interface::getConstantExpressions() const {
std::vector<ConstantExpression*> ret;
for (const auto* method : methods()) {
const auto& retMethod = method->getConstantExpressions();
ret.insert(ret.end(), retMethod.begin(), retMethod.end());
}
return ret;
}
std::vector<Reference<Type>> Interface::getStrongReferences() const {
// Interface is a special case as a reference:
// its definiton must be completed for extension but
// not necessary for other references.
// As interface declaration appears only in global scope and
// method declaration appears only in interface, we may assume
// that all references in method definitions are acyclic.
std::vector<Reference<Type>> ret;
if (superType() != nullptr) {
ret.push_back(mSuperType);
}
return ret;
}
status_t Interface::resolveInheritance() {
size_t serial = FIRST_CALL_TRANSACTION;
for (const auto* ancestor : superTypeChain()) {
serial += ancestor->mUserMethods.size();
}
for (Method* method : mUserMethods) {
if (serial > LAST_CALL_TRANSACTION) {
std::cerr << "ERROR: More than " << LAST_CALL_TRANSACTION
<< " methods (including super and reserved) are not allowed at " << location()
<< "\n";
return UNKNOWN_ERROR;
}
method->setSerialId(serial);
serial++;
}
return Scope::resolveInheritance();
}
status_t Interface::validate() const {
CHECK(isIBase() == mSuperType.isEmptyReference());
if (!isIBase() && !mSuperType->isInterface()) {
std::cerr << "ERROR: You can only extend interfaces at " << mSuperType.location() << "\n";
return UNKNOWN_ERROR;
}
status_t err = validateUniqueNames();
if (err != OK) return err;
return Scope::validate();
}
status_t Interface::validateUniqueNames() const {
std::unordered_map<std::string, const Interface*> registeredMethodNames;
for (auto const& tuple : allSuperMethodsFromRoot()) {
// No need to check super method uniqueness
registeredMethodNames[tuple.method()->name()] = tuple.interface();
}
for (const Method* method : mUserMethods) {
auto registered = registeredMethodNames.find(method->name());
if (registered != registeredMethodNames.end()) {
const Interface* definedInType = registered->second;
if (definedInType == this) {
// Defined in this interface
std::cerr << "ERROR: Redefinition of method '" << method->name() << "'";
} else if (definedInType->isIBase()) {
// Defined in IBase
std::cerr << "ERROR: Redefinition of reserved method '" << method->name() << "'";
} else {
// Defined in super not IBase
std::cerr << "ERROR: Redefinition of method '" << method->name()
<< "'' defined in interface '" << definedInType->fullName() << "'";
}
std::cerr << " at " << method->location() << "\n";
return UNKNOWN_ERROR;
}
registeredMethodNames[method->name()] = this;
}
return OK;
}
bool Interface::addAllReservedMethods() {
// use a sorted map to insert them in serial ID order.
std::map<int32_t, Method *> reservedMethodsById;
for (const auto &pair : gAllReservedMethods) {
Method *method = pair.second->copySignature();
bool fillSuccess = fillPingMethod(method)
|| fillDescriptorChainMethod(method)
|| fillGetDescriptorMethod(method)
|| fillHashChainMethod(method)
|| fillSyspropsChangedMethod(method)
|| fillLinkToDeathMethod(method)
|| fillUnlinkToDeathMethod(method)
|| fillSetHALInstrumentationMethod(method)
|| fillGetDebugInfoMethod(method)
|| fillDebugMethod(method);
if (!fillSuccess) {
LOG(ERROR) << "ERROR: hidl-gen does not recognize a reserved method "
<< method->name();
return false;
}
if (!reservedMethodsById.emplace(method->getSerialId(), method).second) {
LOG(ERROR) << "ERROR: hidl-gen uses duplicated serial id for "
<< method->name() << " and "
<< reservedMethodsById[method->getSerialId()]->name()
<< ", serialId = " << method->getSerialId();
return false;
}
}
for (const auto &pair : reservedMethodsById) {
this->mReservedMethods.push_back(pair.second);
}
return true;
}
const Interface* Interface::superType() const {
if (isIBase()) return nullptr;
if (!mSuperType->isInterface()) {
// This is actually an error
// that would be caught in validate
return nullptr;
}
return static_cast<Interface*>(mSuperType.get());
}
std::vector<const Interface *> Interface::typeChain() const {
std::vector<const Interface *> v;
const Interface *iface = this;
while (iface != nullptr) {
v.push_back(iface);
iface = iface->superType();
}
return v;
}
std::vector<const Interface *> Interface::superTypeChain() const {
return isIBase() ? std::vector<const Interface*>() : superType()->typeChain();
}
bool Interface::isElidableType() const {
return true;
}
bool Interface::isInterface() const {
return true;
}
bool Interface::isBinder() const {
return true;
}
const std::vector<Method *> &Interface::userDefinedMethods() const {
return mUserMethods;
}
const std::vector<Method *> &Interface::hidlReservedMethods() const {
return mReservedMethods;
}
std::vector<Method *> Interface::methods() const {
std::vector<Method *> v(mUserMethods);
v.insert(v.end(), mReservedMethods.begin(), mReservedMethods.end());
return v;
}
std::vector<InterfaceAndMethod> Interface::allMethodsFromRoot() const {
std::vector<InterfaceAndMethod> v;
std::vector<const Interface *> chain = typeChain();
for (auto it = chain.rbegin(); it != chain.rend(); ++it) {
const Interface *iface = *it;
for (Method *userMethod : iface->userDefinedMethods()) {
v.push_back(InterfaceAndMethod(iface, userMethod));
}
}
for (Method *reservedMethod : hidlReservedMethods()) {
v.push_back(InterfaceAndMethod(
*chain.rbegin(), // IBase
reservedMethod));
}
return v;
}
std::vector<InterfaceAndMethod> Interface::allSuperMethodsFromRoot() const {
return isIBase() ? std::vector<InterfaceAndMethod>() : superType()->allMethodsFromRoot();
}
std::string Interface::getBaseName() const {
return fqName().getInterfaceBaseName();
}
std::string Interface::getProxyName() const {
return fqName().getInterfaceProxyName();
}
std::string Interface::getStubName() const {
return fqName().getInterfaceStubName();
}
std::string Interface::getHwName() const {
return fqName().getInterfaceHwName();
}
std::string Interface::getPassthroughName() const {
return fqName().getInterfacePassthroughName();
}
FQName Interface::getProxyFqName() const {
return fqName().getInterfaceProxyFqName();
}
FQName Interface::getStubFqName() const {
return fqName().getInterfaceStubFqName();
}
FQName Interface::getPassthroughFqName() const {
return fqName().getInterfacePassthroughFqName();
}
std::string Interface::getCppType(StorageMode mode,
bool specifyNamespaces) const {
const std::string base =
std::string(specifyNamespaces ? "::android::" : "")
+ "sp<"
+ fullName()
+ ">";
switch (mode) {
case StorageMode_Stack:
case StorageMode_Result:
return base;
case StorageMode_Argument:
return "const " + base + "&";
}
}
std::string Interface::getJavaType(bool /* forInitializer */) const {
return fullJavaName();
}
std::string Interface::getVtsType() const {
if (StringHelper::EndsWith(localName(), "Callback")) {
return "TYPE_HIDL_CALLBACK";
} else {
return "TYPE_HIDL_INTERFACE";
}
}
void Interface::emitReaderWriter(
Formatter &out,
const std::string &name,
const std::string &parcelObj,
bool parcelObjIsPointer,
bool isReader,
ErrorMode mode) const {
const std::string parcelObjDeref =
parcelObj + (parcelObjIsPointer ? "->" : ".");
if (isReader) {
out << "{\n";
out.indent();
const std::string binderName = "_hidl_" + name + "_binder";
out << "::android::sp<::android::hardware::IBinder> "
<< binderName << ";\n";
out << "_hidl_err = ";
out << parcelObjDeref
<< "readNullableStrongBinder(&"
<< binderName
<< ");\n";
handleError(out, mode);
out << name
<< " = "
<< "::android::hardware::fromBinder<"
<< fqName().cppName()
<< ","
<< getProxyFqName().cppName()
<< ","
<< getStubFqName().cppName()
<< ">("
<< binderName
<< ");\n";
out.unindent();
out << "}\n\n";
} else {
out << "if (" << name << " == nullptr) {\n";
out.indent();
out << "_hidl_err = ";
out << parcelObjDeref
<< "writeStrongBinder(nullptr);\n";
out.unindent();
out << "} else {\n";
out.indent();
out << "::android::sp<::android::hardware::IBinder> _hidl_binder = "
<< "::android::hardware::toBinder<\n";
out.indent(2, [&] {
out << fqName().cppName()
<< ">("
<< name
<< ");\n";
});
out << "if (_hidl_binder.get() != nullptr) {\n";
out.indent([&] {
out << "_hidl_err = "
<< parcelObjDeref
<< "writeStrongBinder(_hidl_binder);\n";
});
out << "} else {\n";
out.indent([&] {
out << "_hidl_err = ::android::UNKNOWN_ERROR;\n";
});
out << "}\n";
out.unindent();
out << "}\n";
handleError(out, mode);
}
}
status_t Interface::emitGlobalTypeDeclarations(Formatter &out) const {
status_t status = Scope::emitGlobalTypeDeclarations(out);
if (status != OK) {
return status;
}
out << "std::string toString("
<< getCppArgumentType()
<< ");\n";
return OK;
}
status_t Interface::emitTypeDefinitions(Formatter& out, const std::string& prefix) const {
std::string space = prefix.empty() ? "" : (prefix + "::");
status_t err = Scope::emitTypeDefinitions(out, space + localName());
if (err != OK) {
return err;
}
out << "std::string toString("
<< getCppArgumentType()
<< " o) ";
out.block([&] {
out << "std::string os = \"[class or subclass of \";\n"
<< "os += " << fullName() << "::descriptor;\n"
<< "os += \"]\";\n"
<< "os += o->isRemote() ? \"@remote\" : \"@local\";\n"
<< "return os;\n";
}).endl().endl();
return OK;
}
void Interface::emitJavaReaderWriter(
Formatter &out,
const std::string &parcelObj,
const std::string &argName,
bool isReader) const {
if (isReader) {
out << fullJavaName()
<< ".asInterface("
<< parcelObj
<< ".readStrongBinder());\n";
} else {
out << parcelObj
<< ".writeStrongBinder("
<< argName
<< " == null ? null : "
<< argName
<< ".asBinder());\n";
}
}
status_t Interface::emitVtsAttributeDeclaration(Formatter &out) const {
for (const auto &type : getSubTypes()) {
// Skip for TypeDef as it is just an alias of a defined type.
if (type->isTypeDef()) {
continue;
}
out << "attribute: {\n";
out.indent();
status_t status = type->emitVtsTypeDeclarations(out);
if (status != OK) {
return status;
}
out.unindent();
out << "}\n\n";
}
return OK;
}
status_t Interface::emitVtsMethodDeclaration(Formatter &out) const {
for (const auto &method : methods()) {
if (method->isHidlReserved()) {
continue;
}
out << "api: {\n";
out.indent();
out << "name: \"" << method->name() << "\"\n";
// Generate declaration for each return value.
for (const auto &result : method->results()) {
out << "return_type_hidl: {\n";
out.indent();
status_t status = result->type().emitVtsAttributeType(out);
if (status != OK) {
return status;
}
out.unindent();
out << "}\n";
}
// Generate declaration for each input argument
for (const auto &arg : method->args()) {
out << "arg: {\n";
out.indent();
status_t status = arg->type().emitVtsAttributeType(out);
if (status != OK) {
return status;
}
out.unindent();
out << "}\n";
}
// Generate declaration for each annotation.
for (const auto &annotation : method->annotations()) {
out << "callflow: {\n";
out.indent();
std::string name = annotation->name();
if (name == "entry") {
out << "entry: true\n";
} else if (name == "exit") {
out << "exit: true\n";
} else if (name == "callflow") {
const AnnotationParam *param =
annotation->getParam("next");
if (param != nullptr) {
for (const auto& value : param->getValues()) {
out << "next: " << value << "\n";
}
}
} else {
std::cerr << "Unrecognized annotation '"
<< name << "' for method: " << method->name()
<< ". A VTS annotation should be one of: "
<< "entry, exit, callflow. \n";
}
out.unindent();
out << "}\n";
}
out.unindent();
out << "}\n\n";
}
return OK;
}
status_t Interface::emitVtsAttributeType(Formatter &out) const {
out << "type: " << getVtsType() << "\n"
<< "predefined_type: \""
<< fullName()
<< "\"\n";
return OK;
}
bool Interface::hasOnewayMethods() const {
for (auto const &method : methods()) {
if (method->isOneway()) {
return true;
}
}
const Interface* superClass = superType();
if (superClass != nullptr) {
return superClass->hasOnewayMethods();
}
return false;
}
bool Interface::isJavaCompatible() const {
if (mIsJavaCompatibleInProgress) {
// We're currently trying to determine if this Interface is
// java-compatible and something is referencing this interface through
// one of its methods. Assume we'll ultimately succeed, if we were wrong
// the original invocation of Interface::isJavaCompatible() will then
// return the correct "false" result.
return true;
}
if (superType() != nullptr && !superType()->isJavaCompatible()) {
mIsJavaCompatibleInProgress = false;
return false;
}
mIsJavaCompatibleInProgress = true;
if (!Scope::isJavaCompatible()) {
mIsJavaCompatibleInProgress = false;
return false;
}
for (const auto &method : methods()) {
if (!method->isJavaCompatible()) {
mIsJavaCompatibleInProgress = false;
return false;
}
}
mIsJavaCompatibleInProgress = false;
return true;
}
} // namespace android