DataReader Classe

Definição

Namespace:

Windows.Storage.Streams

Lê dados de um fluxo de entrada.

public ref class DataReader sealed : IClosable, IDataReader

/// [Windows.Foundation.Metadata.ContractVersion(Windows.Foundation.UniversalApiContract, 65536)]
/// [Windows.Foundation.Metadata.MarshalingBehavior(Windows.Foundation.Metadata.MarshalingType.Agile)]
/// [Windows.Foundation.Metadata.Threading(Windows.Foundation.Metadata.ThreadingModel.Both)]
/// [Windows.Foundation.Metadata.Activatable(Windows.Storage.Streams.IDataReaderFactory, 65536, "Windows.Foundation.UniversalApiContract")]
class DataReader final : IClosable, IDataReader

[Windows.Foundation.Metadata.ContractVersion(typeof(Windows.Foundation.UniversalApiContract), 65536)]
[Windows.Foundation.Metadata.MarshalingBehavior(Windows.Foundation.Metadata.MarshalingType.Agile)]
[Windows.Foundation.Metadata.Threading(Windows.Foundation.Metadata.ThreadingModel.Both)]
[Windows.Foundation.Metadata.Activatable(typeof(Windows.Storage.Streams.IDataReaderFactory), 65536, "Windows.Foundation.UniversalApiContract")]
public sealed class DataReader : System.IDisposable, IDataReader

function DataReader(inputStream)

Public NotInheritable Class DataReader
Implements IDataReader, IDisposable

Herança

Object Platform::Object IInspectable DataReader

Atributos

ActivatableAttribute ContractVersionAttribute MarshalingBehaviorAttribute ThreadingAttribute

Implementações

IClosable IDisposable IDataReader

Requisitos do Windows

Família de dispositivos	Windows 10 (introduzida na 10.0.10240.0)
API contract	Windows.Foundation.UniversalApiContract (introduzida na v1.0)

Exemplos

O exemplo de código a seguir mostra como gravar e ler cadeias de caracteres em um fluxo na memória. Para obter o aplicativo de exemplo completo em C# e em C++/CX, consulte Serializando e desserializando o exemplo de dados.

using System;
using System.Diagnostics;
using Windows.Foundation;
using Windows.UI.Xaml;
using Windows.UI.Xaml.Controls;
using Windows.UI.Xaml.Navigation;

// This is the click handler for the 'Copy Strings' button.  Here we will parse the
// strings contained in the ElementsToWrite text block, write them to a stream using
// DataWriter, retrieve them using DataReader, and output the results in the
// ElementsRead text block.
private async void TransferData(object sender, RoutedEventArgs e)
{
    // Initialize the in-memory stream where data will be stored.
    using (var stream = new Windows.Storage.Streams.InMemoryRandomAccessStream())
    {
        // Create the data writer object backed by the in-memory stream.
        using (var dataWriter = new Windows.Storage.Streams.DataWriter(stream))
        {
            dataWriter.UnicodeEncoding = Windows.Storage.Streams.UnicodeEncoding.Utf8;
            dataWriter.ByteOrder = Windows.Storage.Streams.ByteOrder.LittleEndian;

            // Parse the input stream and write each element separately.
            string[] inputElements = ElementsToWrite.Text.Split(';');
            foreach (string inputElement in inputElements)
            {
                uint inputElementSize = dataWriter.MeasureString(inputElement);
                dataWriter.WriteUInt32(inputElementSize);
                dataWriter.WriteString(inputElement);
            }

            // Send the contents of the writer to the backing stream.
            await dataWriter.StoreAsync();

            // For the in-memory stream implementation we are using, the flushAsync call 
            // is superfluous,but other types of streams may require it.
            await dataWriter.FlushAsync();

            // In order to prolong the lifetime of the stream, detach it from the 
            // DataWriter so that it will not be closed when Dispose() is called on 
            // dataWriter. Were we to fail to detach the stream, the call to 
            // dataWriter.Dispose() would close the underlying stream, preventing 
            // its subsequent use by the DataReader below.
            dataWriter.DetachStream();
        }

        // Create the input stream at position 0 so that the stream can be read 
        // from the beginning.
        using (var inputStream = stream.GetInputStreamAt(0))
        {
            using (var dataReader = new Windows.Storage.Streams.DataReader(inputStream))
            {
                // The encoding and byte order need to match the settings of the writer 
                // we previously used.
                dataReader.UnicodeEncoding = Windows.Storage.Streams.UnicodeEncoding.Utf8;
                dataReader.ByteOrder = Windows.Storage.Streams.ByteOrder.LittleEndian;

                // Once we have written the contents successfully we load the stream.
                await dataReader.LoadAsync((uint)stream.Size);

                var receivedStrings = "";

                // Keep reading until we consume the complete stream.
                while (dataReader.UnconsumedBufferLength > 0)
                {
                    // Note that the call to readString requires a length of "code units" 
                    // to read. This is the reason each string is preceded by its length 
                    // when "on the wire".
                    uint bytesToRead = dataReader.ReadUInt32();
                    receivedStrings += dataReader.ReadString(bytesToRead) + "\n";
                }

                // Populate the ElementsRead text block with the items we read 
                // from the stream.
                ElementsRead.Text = receivedStrings;
            }
        }
    }
}

#include "pch.h"
#include "WriteReadStream.h" // header file for WriteReadStream.xaml.
#include <sstream>

#include <winrt/Windows.Foundation.h>
#include <winrt/Windows.Storage.Streams.h>

using namespace winrt;

std::array<winrt::hstring, 5> m_inputElements{ L"Hello", L"World", L"1 2 3 4 5", L"Très bien!", L"Goodbye" };

WriteReadStream::WriteReadStream()
{
    InitializeComponent();

    // Populate the text block with the input elements.
    std::wstringstream stringstream;
    for (winrt::hstring const& element : m_inputElements)
    {
        stringstream << element.c_str() << L";";
    }
    ElementsToWrite().Text(stringstream.str().c_str());
}

// This is the click handler for the 'Copy Strings' button. Here we will parse the
// strings contained in the ElementsToWrite text block, write them to a stream using
// DataWriter, retrieve them using DataReader, and output the results in the
// ElementsRead text block.
winrt::Windows::Foundation::IAsyncAction WriteReadStream::TransferData(
    Windows::Foundation::IInspectable const& /* sender */,
    Windows::UI::Xaml::RoutedEventArgs const& /* args */)
{
    // Initialize the in-memory stream where data will be stored.
    Windows::Storage::Streams::InMemoryRandomAccessStream stream;

    // Create the DataWriter object backed by the in-memory stream. When
    // dataWriter goes out of scope, it closes the underlying stream.
    Windows::Storage::Streams::DataWriter dataWriter{ stream };
    dataWriter.UnicodeEncoding(Windows::Storage::Streams::UnicodeEncoding::Utf16LE);
    dataWriter.ByteOrder(Windows::Storage::Streams::ByteOrder::LittleEndian);

    // Create the data reader by using the input stream set at position 0 so that 
    // the stream will be read from the beginning regardless of the position that
    // the original stream ends up in after the store.
    Windows::Storage::Streams::IInputStream inputStream{ stream.GetInputStreamAt(0) };
    Windows::Storage::Streams::DataReader dataReader{ inputStream };
    // The encoding and byte order need to match the settings of the writer that
    // we previously used.
    dataReader.UnicodeEncoding(Windows::Storage::Streams::UnicodeEncoding::Utf16LE);
    dataReader.ByteOrder(Windows::Storage::Streams::ByteOrder::LittleEndian);

    // Write the input data to the output stream. Serialize the elements by writing
    // each string separately, preceded by its length in bytes.
    for (winrt::hstring const& element : m_inputElements)
    {
        dataWriter.WriteUInt32(element.size());
        dataWriter.WriteString(element);
    }

    // Send the contents of the writer to the backing stream.
    unsigned int bytesStored{ co_await dataWriter.StoreAsync() };

    // For the in-memory stream implementation we are using, the FlushAsync() call 
    // is superfluous, but other types of streams may require it.
    if (co_await dataWriter.FlushAsync())
    {
        try
        {
            // Once we've written the contents successfully, we load the stream.
            unsigned int bytesLoaded{ co_await dataReader.LoadAsync((unsigned int)stream.Size()) };

            std::wstringstream readFromStream;

            // Keep reading until we consume the complete stream.
            while (dataReader.UnconsumedBufferLength() > 0)
            {
                // Note that the call to ReadString requires a length of 
                // "code units" to read. This is the reason each string is 
                // preceded by its length when "on the wire".
                unsigned int bytesToRead{ dataReader.ReadUInt32() };
                readFromStream << dataReader.ReadString(bytesToRead).c_str() << std::endl;
            }

            // Populate the ElementsRead text block with the items we read from the stream
            ElementsRead().Text(readFromStream.str().c_str());
        }
        catch (winrt::hresult_error const& ex)
        {
            ElementsRead().Text(L"Error: " + ex.message());
        }
    }
}

#include "pch.h"
#include "WriteReadStream.xaml.h"

using namespace Concurrency;
using namespace DataReaderWriter;
using namespace Platform;
using namespace Windows::Storage::Streams;
using namespace Windows::UI::Xaml;
using namespace Windows::UI::Xaml::Controls;
using namespace Windows::UI::Xaml::Navigation;

Array<String^>^ _inputElements = ref new Array<String^>
{
    "Hello", "World", "1 2 3 4 5", "Très bien!", "Goodbye"
};

WriteReadStream::WriteReadStream()
{
    InitializeComponent();

    // Populate the text block with the input elements.
    ElementsToWrite->Text = "";
    for (unsigned int i = 0; i < _inputElements->Length; i++)
    {
        ElementsToWrite->Text += _inputElements[i] + ";";
    }
}

// Invoked when this page is about to be displayed in a Frame.
void WriteReadStream::OnNavigatedTo(NavigationEventArgs^ e)
{
    // Get a pointer to our main page.
    rootPage = MainPage::Current;
}

// This is the click handler for the 'Copy Strings' button.  Here we will parse the
// strings contained in the ElementsToWrite text block, write them to a stream using
// DataWriter, retrieve them using DataReader, and output the results in the
// ElementsRead text block.
void DataReaderWriter::WriteReadStream::TransferData(
Platform::Object^ sender, Windows::UI::Xaml::RoutedEventArgs^ e)
{
    // Initialize the in-memory stream where data will be stored.
    InMemoryRandomAccessStream^ stream = ref new InMemoryRandomAccessStream();

    // Create the DataWriter object backed by the in-memory stream.  When
    // dataWriter is deleted, it will also close the underlying stream.
    DataWriter^ dataWriter = ref new DataWriter(stream);
    dataWriter->UnicodeEncoding = UnicodeEncoding::Utf8;
    dataWriter->ByteOrder = ByteOrder::LittleEndian;

    // Create the data reader by using the input stream set at position 0 so that 
    // the stream will be read from the beginning regardless of where the position
    // the original stream ends up in after the store.
    IInputStream^ inputStream = stream->GetInputStreamAt(0);
    DataReader^ dataReader = ref new DataReader(inputStream);
    // The encoding and byte order need to match the settings of the writer 
    // we previously used.
    dataReader->UnicodeEncoding = UnicodeEncoding::Utf8;
    dataReader->ByteOrder = ByteOrder::LittleEndian;

    // Write the input data to the output stream.  Serialize the elements by writing
    // each string separately, preceded by its length.
    for (unsigned int i = 0; i < _inputElements->Length; i++) 
    {
        unsigned int inputElementSize = dataWriter->MeasureString(_inputElements[i]);
        dataWriter->WriteUInt32(inputElementSize);
        dataWriter->WriteString(_inputElements[i]);
    }

    // Send the contents of the writer to the backing stream.
    create_task(dataWriter->StoreAsync()).then([this, dataWriter] (unsigned int bytesStored)
    {
        // For the in-memory stream implementation we are using, the FlushAsync() call 
        // is superfluous, but other types of streams may require it.
        return dataWriter->FlushAsync();
    }).then([this, dataReader, stream] (bool flushOp)
    {
        // Once we have written the contents successfully we load the stream.
        return dataReader->LoadAsync((unsigned int) stream->Size);
    }).then([this, dataReader] (task<unsigned int> bytesLoaded)
    {
        try
        {
            // Check for possible exceptions that could have been thrown 
            // in the async call chain.
            bytesLoaded.get();

            String^ readFromStream = "";

            // Keep reading until we consume the complete stream.
            while (dataReader->UnconsumedBufferLength > 0)
            {
                // Note that the call to ReadString requires a length of 
                // "code units" to read. This is the reason each string is 
                // preceded by its length when "on the wire".
                unsigned int bytesToRead = dataReader->ReadUInt32();
                readFromStream += dataReader->ReadString(bytesToRead) + "\n";
            }

            // Populate the ElementsRead text block with the items we read from the stream
            ElementsRead->Text = readFromStream;
        }
        catch (Exception^ e)
        {
            ElementsRead->Text = "Error: " + e->Message;
        }
    });
}

Comentários

Instâncias de objetos DataReader não dão suporte a operações de leitura simultâneas. Se um aplicativo ler ou desanexar simultaneamente um fluxo de uma instância do DataReader que está sendo lida, a chamada para o objeto falhará com o erro HRESULT_FROM_WIN32(ERROR_INVALID_OPERATION).

Construtores

DataReader(IInputStream)

Cria e inicializa uma nova instância do leitor de dados.

Propriedades

ByteOrder	Obtém ou define a ordem de bytes dos dados no fluxo de entrada.
InputStreamOptions	Obtém ou define as opções de leitura para o fluxo de entrada.
UnconsumedBufferLength	Obtém o tamanho do buffer que não foi lido.
UnicodeEncoding	Obtém ou define a codificação de caracteres Unicode para o fluxo de entrada.

Métodos

Close()	Fecha o fluxo atual e libera os recursos do sistema.
DetachBuffer()	Desanexa o buffer associado ao leitor de dados. Isso será útil se você quiser manter o buffer depois de descartar o leitor de dados.
DetachStream()	Desanexa o fluxo associado ao leitor de dados.
Dispose()	Realiza tarefas definidas pelo aplicativo associadas à liberação ou à redefinição de recursos não gerenciados.
FromBuffer(IBuffer)	Cria uma nova instância do leitor de dados com dados do buffer especificado.
LoadAsync(UInt32)	Carrega dados do fluxo de entrada.
ReadBoolean()	Lê um valor booliano do fluxo de entrada.
ReadBuffer(UInt32)	Lê um buffer do fluxo de entrada.
ReadByte()	Lê um valor de byte do fluxo de entrada.
ReadBytes(Byte[])	Lê uma matriz de valores de bytes do fluxo de entrada.
ReadDateTime()	Lê um valor de data e hora do fluxo de entrada.
ReadDouble()	Lê um valor de ponto flutuante do fluxo de entrada.
ReadGuid()	Lê um valor GUID do fluxo de entrada.
ReadInt16()	Lê um valor inteiro de 16 bits do fluxo de entrada.
ReadInt32()	Lê um valor inteiro de 32 bits do fluxo de entrada.
ReadInt64()	Lê um valor inteiro de 64 bits do fluxo de entrada.
ReadSingle()	Lê um valor de ponto flutuante do fluxo de entrada.
ReadString(UInt32)	Lê um valor de cadeia de caracteres do fluxo de entrada.
ReadTimeSpan()	Lê um valor de intervalo de tempo do fluxo de entrada.
ReadUInt16()	Lê um inteiro sem sinal de 16 bits do fluxo de entrada.
ReadUInt32()	Lê um inteiro sem sinal de 32 bits do fluxo de entrada.
ReadUInt64()	Lê um inteiro sem sinal de 64 bits do fluxo de entrada.

Confira também

• DataReaderLoadOperation
• DataWriter
• Exemplo de dados serializando e desserializando (Windows 10)
• Exemplo de acesso a arquivos (Windows 10)
• Exemplo de StreamSocket (Windows 10)
• Exemplo de dispositivo USB personalizado (Windows 10)
• Exemplo de DatagramSocket (Windows 10)