Distributed File

• Introduction

  • Architecture

• Directory

• Constraints

• Usage

  • Available APIs
  • Usage Guidelines

• Repositories Involved

Introduction

Currently, the Distributed File subsystem provides apps with JavaScript APIs for I/O capabilities, including APIs for managing files and directories, obtaining file information, reading and writing data streams of files, and receiving URIs rather than absolute paths.

Architecture

Currently, the Distributed File subsystem provides only local JavaScript file APIs for apps through the FileIO and File modules. The Distributed File subsystem uses LibN to abstract APIs at the NAPI layer, providing basic capabilities such as the basic type system, memory management, and general programming models for the subsystem. This subsystem depends on the engine layer of the JS application development framework to provide the capability of converting JavaScript APIs into C++ code, depends on the application framework to provide app-related directories, and depends on the GLIBC runtimes to provide I/O capabilities.

Figure 1 Distributed File subsystem architecture

Directory

foundation/distributeddatamgr/distributedfile
├── figures                     # Figures
├── interfaces                  # APIs
├    └── kits                   # APIs exposed externally
├── utils                       # Common Components
├    └── filemgmt_libhilog      # Log Components
├    └── filemgmt_libn          # Platform related components

Constraints

Constraints on local I/O APIs:

• Only UTF-8/16 encoding is supported.
• The URIs cannot include external storage directories.

Usage

Available APIs

Currently, the Distributed File subsystem provides APIs for accessing local files and directories. The following table describes the API types classified by function.

Table 1 API types

The URIs used in sandbox file APIs are classified into three types, as described in the following table.

Table 2 URI types

Usage Guidelines

The I/O APIs provided by the Distributed File subsystem can be classified into the following types based on the programming model:

• Synchronous programming model

  APIs whose names contain Sync are implemented as a synchronous model. When a synchronous API is called, the calling process waits until a value is returned.

  The following example opens a file stream in read-only mode, attempts to read the first 4096 bytes, converts them into a UTF-8-encoded string, and then closes the file stream:

  import fileio from '@OHOS.distributedfile.fileio';
  
  try {
      var ss = fileio.createStreamSync("tmp", "r")
      buf = new ArrayBuffer(4096)
      ss.readSync(buf)
      console.log(String.fromCharCode.apply(null, new Uint8Array(buf)))
      ss.closeSync()
  }
  catch (e) {
      console.log(e);
  }

• Asynchronous programming model: Callback

  In the @OHOS.distributedfile.fileio module, the APIs whose names do not contain Sync and to which a callback is directly passed as their input parameter are implemented as the callback asynchronous model. The callback asynchronous model is also one of the OHOS standard asynchronous models. When an asynchronous API with a callback passed is called, the API executes the concerned task asynchronously and returns the execution result as the input parameters of the registered callback. The first parameter is of the undefined or Error type, indicating that the execution succeeds or fails, respectively.

  The following example creates a file stream asynchronously, reads the first 4096 bytes of the file asynchronously in the callback invoked when the file stream is created, and then closes the file asynchronously in the callback invoked when the file is read:

  import fileio from '@OHOS.distributedfile.fileio';
  
  try {
      fileio.createStream("./testdir/test_stream.txt", "r", function (err, ss) {
          if (!err) {
              ss.read(new ArrayBuffer(4096), {}, function (err, buf, readLen) {
                  if (!err) {
                      console.log('readLen: ' + readLen)
                      console.log('data: ' + String.fromCharCode.apply(null, new Uint8Array(buf)))
                  } else {
                      console.log('Cannot read from the stream ' + err)
                  }
                  ss.close(function (err) {
                      console.log(`Stream is ${err ? 'not' : ''}closed`)
                  });
              })
          } else {
              console.log('Cannot open the stream ' + err)
          }
      })
  } catch (e) {
      console.log(e)
  }

• Asynchronous programming model: Legacy

  All APIs in the @system.file module are implemented as the legacy asynchronous model. When calling such an API, you need to implement three callbacks (including success, fail, and complete) to be invoked when the execution is successful, fails, or is complete, respectively. If the input parameters are correct, the API calls the success or fail callback based on whether the asynchronous task is successful after the task execution is complete, and finally calls the complete callback.

  The following example asynchronously checks whether the file pointed to by the specified URI exists and provides three callbacks to print the check result:

  import file from '@system.file'
  
  file.access({
      uri: 'internal://app/test.txt',
      success: function() {
          console.log('call access success.');
      },
      fail: function(data, code) {
          console.error('call fail callback fail, code: ' + code + ', data: ' + data);
      },
      complete: function () {
          console.log('call access finally.');
      }
  });
  
  console.log("file access tested done")

Repositories Involved

• distributeddatamgr_file
• filemanagement_dfs_service
• filemanagement_user_file_service
• filemanagement_storage_service
• filemanagement_app_file_service