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Merge pull request !37 from zjucx/master |
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.gitee | ||
communication/broadcast | ||
config | ||
figures | ||
interfaces/kits | ||
samgr | ||
samgr_client | ||
samgr_endpoint | ||
samgr_server | ||
BUILD.gn | ||
LICENSE | ||
README.md | ||
README_zh.md | ||
config.gni |
README.md
samgr_lite
- Introduction
- Directory Structure
- Constraints
- Developing a Service
- Developing a Feature of a Service
- Developing an External API for Intra-Process Communication
- Invoking a Service in the Same Process
- Developing an External API for IPC
- Invoking a Service in Another Process
- Developing a Client Proxy for Inter-Process Service Invocation
- Repositories Involved
Introduction
Due to limited platform resources, a unified system ability SA
framework is provided to harmonize differences of hardware architectures for example, RISC-V, Cortex-M, and Cortex-A
, resources, and running modes. Two types of hardware platforms M- and A-core
are defined.
- M-core: hardware platforms with Cortex-M or equivalent processing capabilities. The system memory is generally less than 512 KB. There is only a lightweight file system that can be used in limited scenarios, or no file system at all. M-core platforms comply with the Cortex Microcontroller Software Interface Standard
CMSIS
. - A-core: hardware platforms with Cortex-A or equivalent processing capabilities. The system memory is greater than 512 KB. There is a comprehensive file system for storing a large amount of data. A-core platforms comply with the Portable Operating System Interface
POSIX
specifications.
This service-oriented SA framework enables you to develop services, features, and external APIs, and implement multi-service process sharing and service invoking for inter-process communication IPC
. Wherein:
- M core provides services, features, external APIs, and multi-service process sharing development.
- In addition to the capabilities provided by M-core, A-core provides capabilities such as IPC service invoking, permission control for IPC service invoking, and IPC service API development.
Service-oriented architecture
- Provider: a service provider that provides capabilities
external APIs
for the system - Consumer: a service consumer that invokes the features
external APIs
provided by the service - Samgr: an agency that manages capabilities provided by providers and helps consumers discover providers' capabilities
Main objects of the SA framework:
- SamgrLite: provides service registration and discovery.
- Service: implements lifecycle APIs of the service during service development.
- Feature: implements lifecycle APIs of the feature during feature development.
- IUnknown: implements external APIs for services or features based on IUnknown.
- IClientProxy: implements the consumer's proxy to send messages during IPC invoking.
- IServerProxy: implements the provider's proxy during IPC invoking, which needs to be implemented by developers.
Directory Structure
Table 1 Structure of the source code directory of the SA framework
Constraints
- The SA framework is developed using the C programming language.
- Services in the same process use IUnknown for invoking. Messages are passed to the service through IUnknown.
- The service name and feature name must be constant character strings and the length must be less than 16 bytes.
- More-core depends on the Bootstrap service and calls the OHOS_SystemInit() function in the system startup function.
- A-core depends on the Samgr library and calls the SAMGR_Bootstrap() function in the main function.
Developing a Service
-
Inherit and redefine a service.
typedef struct ExampleService { INHERIT_SERVICE; INHERIT_IUNKNOWNENTRY(DefaultFeatureApi); Identity identity; } ExampleService;
-
Implement the lifecycle function of the service.
static const char *GetName(Service *service) { return EXAMPLE_SERVICE; } static BOOL Initialize(Service *service, Identity identity) { ExampleService *example = (ExampleService *)service; // Save the unique ID of the service, which is used when IUnknown is used to send messages to the service. example->identity = identity; return TRUE; } static BOOL MessageHandle(Service *service, Request *msg) { ExampleService *example = (ExampleService *)service; switch (msg->msgId) { case MSG_SYNC: // Process the service. break; default:break; } return FALSE; } static TaskConfig GetTaskConfig(Service *service) { TaskConfig config = {LEVEL_HIGH, PRI_BELOW_NORMAL, 0x800, 20, SHARED_TASK}; return config; }
-
Create a service object.
static ExampleService g_example = { .GetName = GetName, .Initialize = Initialize, .MessageHandle = MessageHandle, .GetTaskConfig = GetTaskConfig, SERVER_IPROXY_IMPL_BEGIN, .Invoke = NULL, .SyncCall = SyncCall, IPROXY_END, };
-
Register the service and API with Samgr.
static void Init(void) { SAMGR_GetInstance()->RegisterService((Service *)&g_example); SAMGR_GetInstance()->RegisterDefaultFeatureApi(EXAMPLE_SERVICE, GET_IUNKNOWN(g_example)); }
-
Define the initializer of the service.
SYSEX_SERVICE_INIT(Init);
Developing a Feature of a Service
-
Inherit and redefine a feature.
typedef struct DemoFeature { INHERIT_FEATURE; INHERIT_IUNKNOWNENTRY(DemoApi); Identity identity; Service *parent; } DemoFeature;
-
Implement the lifecycle function of the feature.
static const char *FEATURE_GetName(Feature *feature) { return EXAMPLE_FEATURE; } static void FEATURE_OnInitialize(Feature *feature, Service *parent, Identity identity) { DemoFeature *demoFeature = (DemoFeature *)feature; demoFeature->identity = identity; demoFeature->parent = parent; } static void FEATURE_OnStop(Feature *feature, Identity identity) { g_example.identity.queueId = NULL; g_example.identity.featureId = -1; g_example.identity.serviceId = -1; } static BOOL FEATURE_OnMessage(Feature *feature, Request *request) { if (request->msgId == MSG_PROC) { Response response = {.data = "Yes, you did!", .len = 0}; SAMGR_SendResponse(request, &response); return TRUE; } else { if (request->msgId == MSG_TIME_PROC) { LOS_Msleep(WAIT_FEATURE_PROC * 10); if (request->msgValue) { SAMGR_PrintServices(); } else { SAMGR_PrintOperations(); } AsyncTimeCall(GET_IUNKNOWN(g_example)); return FALSE; } } return FALSE; }
-
Create a feature object.
static DemoFeature g_example = { .GetName = FEATURE_GetName, .OnInitialize = FEATURE_OnInitialize, .OnStop = FEATURE_OnStop, .OnMessage = FEATURE_OnMessage, DEFAULT_IUNKNOWN_ENTRY_BEGIN, .AsyncCall = AsyncCall, .AsyncTimeCall = AsyncTimeCall, .SyncCall = SyncCall, .AsyncCallBack = AsyncCallBack, DEFAULT_IUNKNOWN_ENTRY_END, .identity = {-1, -1, NULL}, };
-
Register the feature and API with Samgr.
static void Init(void){ SAMGR_GetInstance()->RegisterFeature(EXAMPLE_SERVICE, (Feature *)&g_example); SAMGR_GetInstance()->RegisterFeatureApi(EXAMPLE_SERVICE, EXAMPLE_FEATURE, GET_IUNKNOWN(g_example)); }
-
Define the initializer of the feature.
SYSEX_FEATURE_INIT(Init);
Developing an External API for Intra-Process Communication
-
Define the IUnknown API.
typedef struct DemoApi { INHERIT_IUNKNOWN; BOOL (*AsyncCall)(IUnknown *iUnknown, const char *buff); BOOL (*AsyncTimeCall)(IUnknown *iUnknown); BOOL (*SyncCall)(IUnknown *iUnknown, struct Payload *payload); BOOL (*AsyncCallBack)(IUnknown *iUnknown, const char *buff, Handler handler); } DemoApi;
-
Define the reference object of IUnknown.
typedef struct DemoRefApi { INHERIT_IUNKNOWNENTRY(DemoApi); } DemoRefApi;
-
Initialize the object of IUnknown.
static DemoRefApi api = { DEFAULT_IUNKNOWN_ENTRY_BEGIN, .AsyncCall = AsyncCall, .AsyncTimeCall = AsyncTimeCall, .SyncCall = SyncCall, .AsyncCallBack = AsyncCallBack, DEFAULT_IUNKNOWN_ENTRY_END, };
-
Register the feature API.
SAMGR_GetInstance()->RegisterFeatureApi(EXAMPLE_SERVICE, EXAMPLE_FEATURE, GET_IUNKNOWN(api));
Invoking a Service in the Same Process
-
Obtain the external API of the service.
DemoApi *demoApi = NULL; IUnknown *iUnknown = SAMGR_GetInstance()->GetFeatureApi(EXAMPLE_SERVICE, EXAMPLE_FEATURE); if (iUnknown == NULL) { return NULL; } int result = iUnknown->QueryInterface(iUnknown, DEFAULT_VERSION, (void **)&demoApi); if (result != 0 || demoApi == NULL) { return NULL; }
-
Call the API.
if (demoApi->AsyncCallBack == NULL) { return NULL; } demoApi->AsyncCallBack((IUnknown *)demoApi, "I wanna async call callback good result!", AsyncHandler);
-
Release the API.
int32 ref = demoApi->Release((IUnknown *)demoApi);
Developing an External API for IPC
-
Inherit IServerProxy to replace IUnknown: INHERIT_SERVER_IPROXY
typedef struct DemoFeatureApi { INHERIT_SERVER_IPROXY; BOOL (*AsyncCall)(IUnknown *iUnknown, const char *buff); BOOL (*AsyncTimeCall)(IUnknown *iUnknown); BOOL (*SyncCall)(IUnknown *iUnknown, struct Payload *payload); BOOL (*AsyncCallBack)(IUnknown *iUnknown, const char *buff, IOwner notify, INotifyFunc handler); } DemoFeatureApi;
-
Initialize the IServerProxy object.
static DemoFeature g_example = { SERVER_IPROXY_IMPL_BEGIN, .Invoke = Invoke, .AsyncCall = AsyncCall, .AsyncTimeCall = AsyncTimeCall, .SyncCall = SyncCall, .AsyncCallBack = AsyncCallBack, IPROXY_END, };
-
Implement the Invoke function to process IPC messages.
static int32 Invoke(IServerProxy *iProxy, int funcId, void *origin, IpcIo *req, IpcIo *reply) { DemoFeatureApi *api = (DemoFeatureApi *)iProxy; BOOL ret; size_t len = 0; switch (funcId) { case ID_ASYNCALL: ret = api->AsyncCall((IUnknown *)iProxy, (char *)IpcIoPopString(req, &len)); IpcIoPushBool(reply, ret); break; case ID_ASYNTIMECALL: ret = api->AsyncTimeCall((IUnknown *)iProxy); IpcIoPushBool(reply, ret); break; case ID_SYNCCALL: { struct Payload payload; payload.id = IpcIoPopInt32(req); payload.value = IpcIoPopInt32(req); payload.name = (char *)IpcIoPopString(req, &len); ret = api->SyncCall((IUnknown *)iProxy, &payload); IpcIoPushString(reply, ret ? "TRUE" : "FALSE"); } break; case ID_ASYNCCALLBACK: { // convert to sync proxy IpcIoPushString(reply, "Yes, you did!"); IpcIoPushBool(reply, TRUE); } break; default: IpcIoPushBool(reply, FALSE); break; } return EC_SUCCESS; }
-
Register the API. This step is same as the API registration for intra-process communication.
SAMGR_GetInstance()->RegisterFeatureApi(EXAMPLE_SERVICE, EXAMPLE_FEATURE, GET_IUNKNOWN(g_example));
Invoking a Service in Another Process
-
Obtain the external API of the service in another process.
IClientProxy *demoApi = NULL; IUnknown *iUnknown = SAMGR_GetInstance()->GetFeatureApi(EXAMPLE_SERVICE, EXAMPLE_FEATURE); if (iUnknown == NULL) { return NULL; } int result = iUnknown->QueryInterface(iUnknown, CLIENT_PROXY_VER, (void **)&demoApi); if (result != 0 || demoApi == NULL) { return NULL; }
-
Invoke the API for sending IPC messages.
IpcIo request;char data[250]; IpcIoInit(&request, data, sizeof(data), 0); demoApi->Invoke(demoApi, 0, &request, NULL, NULL);
-
Release the API.
int32 ref = demoApi->Release((IUnknown *)demoApi);
Developing a Client Proxy for Inter-Process Service Invocation
-
Define a client proxy for the IPC API.
typedef struct DemoClientProxy { INHERIT_CLIENT_IPROXY; BOOL (*AsyncCall)(IUnknown *iUnknown, const char *buff); BOOL (*AsyncTimeCall)(IUnknown *iUnknown); BOOL (*SyncCall)(IUnknown *iUnknown, struct Payload *payload); BOOL (*AsyncCallBack)(IUnknown *iUnknown, const char *buff, IOwner notify, INotifyFunc handler); } DemoClientProxy; typedef struct DemoClientEntry { INHERIT_IUNKNOWNENTRY(DemoClientProxy); } DemoClientEntry;
-
Enable the client proxy to encapsulate the IPC message API.
static BOOL AsyncCall(IUnknown *iUnknown, const char *buff) { DemoClientProxy *proxy = (DemoClientProxy *)iUnknown; IpcIo request; char data[MAX_DATA_LEN]; IpcIoInit(&request, data, MAX_DATA_LEN, 0); IpcIoPushString(&request, buff); int ret = proxy->Invoke((IClientProxy *)proxy, ID_ASYNCALL, &request, NULL, NULL); return ret == EC_SUCCESS; } static BOOL AsyncTimeCall(IUnknown *iUnknown) { DemoClientProxy *proxy = (DemoClientProxy *)iUnknown; IpcIo request; char data[MAX_DATA_LEN]; IpcIoInit(&request, data, MAX_DATA_LEN, 0); int ret = proxy->Invoke((IClientProxy *)proxy, ID_ASYNTIMECALL, &request, NULL, NULL); return ret == EC_SUCCESS; } static int Callback(IOwner owner, int code, IpcIo *reply) { size_t len = 0; return strcpy_s(owner, MAX_DATA_LEN, (char *)IpcIoPopString(reply, &len)); } static BOOL SyncCall(IUnknown *iUnknown, struct Payload *payload) { DemoClientProxy *proxy = (DemoClientProxy *)iUnknown; IpcIo request; char data[MAX_DATA_LEN]; IpcIoInit(&request, data, MAX_DATA_LEN, 0); IpcIoPushInt32(&request, payload->id); IpcIoPushInt32(&request, payload->value); IpcIoPushString(&request, payload->name); int ret = proxy->Invoke((IClientProxy *)proxy, ID_SYNCCALL, &request, data, Callback); data[MAX_DATA_LEN - 1] = 0; HILOG_INFO(HILOG_MODULE_APP, "[TID:0x%lx]Remote response is %s!", pthread_self(), data); return ret == EC_SUCCESS; } struct CurrentNotify { IOwner notify; INotifyFunc handler; }; static int CurrentCallback(IOwner owner, int code, IpcIo *reply) { struct CurrentNotify *notify = (struct CurrentNotify *)owner; size_t len = 0; char *response = (char *)IpcIoPopString(reply, &len); HILOG_INFO(HILOG_MODULE_APP, "[TID:0x%lx]Notify Remote response is %s!", pthread_self(), response); notify->handler(notify->notify, response); return EC_SUCCESS; } static BOOL AsyncCallBack(IUnknown *iUnknown, const char *buff, IOwner notify, INotifyFunc handler) { struct CurrentNotify owner = {notify, handler}; DemoClientProxy *proxy = (DemoClientProxy *)iUnknown; IpcIo request; char data[MAX_DATA_LEN]; IpcIoInit(&request, data, MAX_DATA_LEN, 0); IpcIoPushString(&request, buff); int ret = proxy->Invoke((IClientProxy *)proxy, ID_ASYNCCALLBACK, &request, &owner, CurrentCallback); return ret == EC_SUCCESS; }
-
Implement the factory method for creating the client proxy.
void *DEMO_CreatClient(const char *service, const char *feature, uint32 size) { (void)service; (void)feature; uint32 len = size + sizeof(DemoClientEntry); uint8 *client = malloc(len); (void)memset_s(client, len, 0, len); DemoClientEntry *entry = (DemoClientEntry *)&client[size]; entry->ver = ((uint16)CLIENT_PROXY_VER | (uint16)DEFAULT_VERSION); entry->ref = 1; entry->iUnknown.QueryInterface = IUNKNOWN_QueryInterface; entry->iUnknown.AddRef = IUNKNOWN_AddRef; entry->iUnknown.Release = IUNKNOWN_Release; entry->iUnknown.Invoke = NULL; entry->iUnknown.AsyncCall = AsyncCall; entry->iUnknown.AsyncTimeCall = AsyncTimeCall; entry->iUnknown.SyncCall = SyncCall; entry->iUnknown.AsyncCallBack = AsyncCallBack; return client; } void DEMO_DestroyClient(const char *service, const char *feature, void *iproxy) { free(iproxy); }
-
Register the factory method of the client proxy with Samgr.
SAMGR_RegisterFactory(EXAMPLE_SERVICE, EXAMPLE_FEATURE, DEMO_CreatClient, DEMO_DestroyClient);
-
Obtain the external API of the service in another process.
DemoClientProxy *demoApi = NULL; IUnknown *iUnknown = SAMGR_GetInstance()->GetFeatureApi(EXAMPLE_SERVICE, EXAMPLE_FEATURE); if (iUnknown == NULL) { return NULL; } int result = iUnknown->QueryInterface(iUnknown, DEFAULT_VERSION, (void **)&demoApi); if (result != 0 || demoApi == NULL) { return NULL; }
-
Invoke the client proxy API of the service in another process.
if (demoApi->AsyncCallBack == NULL) { return NULL; } demoApi->AsyncCallBack((IUnknown *)demoApi, "I wanna async call callback good result!", NULL, AsyncHandler);
-
Release the API.
int32 ref = demoApi->Release((IUnknown *)demoApi);
Repositories Involved
Distributed Scheduler subsystem
samgr_lite