Procedura dettagliata: connessione tramite attività e richiesta HTTP XML (IXHR2)
Questo esempio illustra come utilizzare le interfacce IXMLHTTPRequest2 e IXMLHTTPRequest2Callback insieme alle attività per inviare richieste, HTTP GET e POST ad un servizio web, in un'applicazione Windows Store.Combinando IXHR2 insieme alle attività, è possibile scrivere codice che compone altre attività.Ad esempio, è possibile utilizzare l'attività di download come parte di una catena di attività.L'attività di download può anche rispondere quando il lavoro viene annullato.
Per ulteriori informazioni sulle attività, vedere Parallelismo delle attività (runtime di concorrenza).Per ulteriori informazioni su come utilizzare le attività in un'applicazione Windows Store, vedere Asynchronous programming in C++ e Creazione di operazioni asincrone in C++ per le applicazioni Windows Store.
Questo primo documento mostra come creare HttpRequest e le relative classi di supporto.Viene quindi illustrato come utilizzare questa classe in un'applicazione Windows Store che utilizza C++ e XAML.
Per un esempio più completo, che utilizza la classe HttpReader specificata in questo documento, vedere Sviluppo dell'utilità di ottimizzazione dei viaggi di Bing Mappe, un'app di Windows Store in JavaScript e C++.Per un esempio che utilizza IXHR2, ma non utilizza le attività, vedere Quickstart: Connecting using XML HTTP Request (IXHR2).
.gif "Suggerimento") Suggerimento |
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IXMLHTTPRequest2 e IXMLHTTPRequest2Callback sono interfacce che si consiglia di utilizzare in un'applicazione Windows Store.È inoltre possibile adattare questo esempio per utilizzarlo in un'applicazione desktop. |
Definizione del HttpRequest, HttpRequestBuffersCallback e delle classi di HttpRequestStringCallback
Quando si utilizza l'interfaccia IXMLHTTPRequest2 per creare richieste Web tramite HTTP, si implementa l'interfaccia IXMLHTTPRequest2Callback per ricevere la risposta del server e rispondere agli eventi.In questo esempio viene definita la classe HttpRequest per creare richieste Web e le classi HttpRequestStringCallback, HttpRequestBuffersCallback per elaborare le risposte.Le classi di HttpRequestStringCallback e HttpRequestBuffersCallback supportano la classe HttpRequest; si utilizza solo la classe HttpRequest dal codice dell'applicazione.
I metodi GetAsync, PostAsync, della classe HttpRequest consentono di avviare rispettivamente le operazioni HTTP GET e POST.Questi metodi utilizzano la classe HttpRequestStringCallback per leggere la risposta del server come una stringa.I metodi ReadAsync e SendAsync consentono di trasmettere contenuti di grande dimensioni in blocchi.Ognuno di questi metodi restituisce concurrency::task per rappresentare l'operazione.I metodi task<std::wstring> e PostAsync producono il valore GetAsync, dove il frammento wstring rappresenta la risposta del server.I metodi ReadAsync e SendAsync producono valori task<void> ; queste attività vengono completate quando le operazioni d'invio e di lettura sono completate.
Poiché le interfacce IXHR2 funzionano in modo asincrono, utilizzare concurrency::task_completion_event per creare un'attività che può concludersi successivamente al completamento dell'oggetto di callback, oppure quando l'operazione di download viene annullata.La classe HttpRequest crea una continuazione correlata ad una attività, da questa attività, per impostare il risultato finale.La classe HttpRequest utilizza la continuazione di un'attività correlata, per garantire l'attività di continuazione anche se l'attività precedente produce un errore o viene annullata.Per ulteriori informazioni sulla continuazione di attività correlate, vedere Parallelismo delle attività (runtime di concorrenza).
Per supportare l'annullamento, HttpRequest, HttpRequestBuffersCallback e le classi di HttpRequestStringCallback utilizzano i token di annullamento.Le classi HttpRequestStringCallback e HttpRequestBuffersCallback utilizzano il metodo di concurrency::cancellation_token::register_callback per consentire all'attività di completare l'evento per rispondere all'annullamento.Questo callback di annullamento interrompe il download.Per ulteriori informazioni sull'annullamento, vedere Annullamento nella libreria PPL.
Per definire la classe HttpReques
Utilizzare il modello di Visual C++ Applicazione vuota (XAML), per creare un progetto di un'applicazione XAML vuota.In questo esempio denominare il progetto UsingIXHR2.
Aggiungere al progetto un file di intestazione denominato HttpRequest.h e un file di origine denominato HttpRequest.cpp.
In pch.h, aggiungere questo codice :
#include <ppltasks.h> #include <string> #include <sstream> #include <wrl.h> #include <msxml6.h>In HttpRequest.h, aggiungere il codice seguente:
#pragma once #include "pch.h" inline void CheckHResult(HRESULT hResult) { if (hResult == E_ABORT) { concurrency::cancel_current_task(); } else if (FAILED(hResult)) { throw Platform::Exception::CreateException(hResult); } } namespace Web { namespace Details { // Implementation of IXMLHTTPRequest2Callback used when partial buffers are needed from the response. // When only the complete response is needed, use HttpRequestStringCallback instead. class HttpRequestBuffersCallback : public Microsoft::WRL::RuntimeClass< Microsoft::WRL::RuntimeClassFlags<Microsoft::WRL::ClassicCom>, IXMLHTTPRequest2Callback, Microsoft::WRL::FtmBase> { public: HttpRequestBuffersCallback(IXMLHTTPRequest2* httpRequest, concurrency::cancellation_token ct = concurrency::cancellation_token::none()) : request(httpRequest), cancellationToken(ct), responseReceived(false), dataHResult(S_OK), statusCode(200) { // Register a callback function that aborts the HTTP operation when // the cancellation token is canceled. if (cancellationToken != concurrency::cancellation_token::none()) { registrationToken = cancellationToken.register_callback([this]() { if (request != nullptr) { request->Abort(); } }); } dataEvent = concurrency::task_completion_event<void>(); } // Called when the HTTP request is being redirected to a new URL. IFACEMETHODIMP OnRedirect(IXMLHTTPRequest2*, PCWSTR) { return S_OK; } // Called when HTTP headers have been received and processed. IFACEMETHODIMP OnHeadersAvailable(IXMLHTTPRequest2*, DWORD statusCode, PCWSTR reasonPhrase) { HRESULT hr = S_OK; // We must not propagate exceptions back to IXHR2. try { this->statusCode = statusCode; this->reasonPhrase = reasonPhrase; concurrency::critical_section::scoped_lock lock(dataEventLock); dataEvent.set(); } catch (std::bad_alloc&) { hr = E_OUTOFMEMORY; } return hr; } // Called when a portion of the entity body has been received. IFACEMETHODIMP OnDataAvailable(IXMLHTTPRequest2*, ISequentialStream* stream) { HRESULT hr = S_OK; // We must not propagate exceptions back to IXHR2. try { // Store a reference on the stream so it can be accessed by the task. dataStream = stream; // The work must be done as fast as possible, and must not block this thread, // for example, waiting on another event object. Here we simply set an event // that can be processed by another thread. concurrency::critical_section::scoped_lock lock(dataEventLock); dataEvent.set(); } catch (std::bad_alloc&) { hr = E_OUTOFMEMORY; } return hr; } // Called when the entire entity response has been received. IFACEMETHODIMP OnResponseReceived(IXMLHTTPRequest2* xhr, ISequentialStream* responseStream) { responseReceived = true; return OnDataAvailable(xhr, responseStream); } // Called when an error occurs during the HTTP request. IFACEMETHODIMP OnError(IXMLHTTPRequest2*, HRESULT hrError) { HRESULT hr = S_OK; // We must not propagate exceptions back to IXHR2. try { concurrency::critical_section::scoped_lock lock(dataEventLock); dataHResult = hrError; dataEvent.set(); } catch (std::bad_alloc&) { hr = E_OUTOFMEMORY; } return hr; } // Create a task that completes when data is available, in an exception-safe way. concurrency::task<void> CreateDataTask(); HRESULT GetError() const { return dataHResult; } int GetStatusCode() const { return statusCode; } std::wstring const& GetReasonPhrase() const { return reasonPhrase; } bool IsResponseReceived() const { return responseReceived; } // Copy bytes from the sequential stream into the buffer provided until // we reach the end of one or the other. unsigned int ReadData( _Out_writes_(outputBufferSize) byte* outputBuffer, unsigned int outputBufferSize); private: ~HttpRequestBuffersCallback() { // Unregister the callback. if (cancellationToken != concurrency::cancellation_token::none()) { cancellationToken.deregister_callback(registrationToken); } } // Signals that the download operation was canceled. concurrency::cancellation_token cancellationToken; // Used to unregister the cancellation token callback. concurrency::cancellation_token_registration registrationToken; // The IXMLHTTPRequest2 that processes the HTTP request. Microsoft::WRL::ComPtr<IXMLHTTPRequest2> request; // Task completion event that is set when data is available or error is triggered. concurrency::task_completion_event<void> dataEvent; concurrency::critical_section dataEventLock; // We cannot store the error obtained from IXHR2 in the dataEvent since any value there is first-writer-wins, // whereas we want a subsequent error to override an initial success. HRESULT dataHResult; // Referenced pointer to the data stream. Microsoft::WRL::ComPtr<ISequentialStream> dataStream; // HTTP status code and reason returned by the server. int statusCode; std::wstring reasonPhrase; // Whether the response has been completely received. bool responseReceived; }; }; // Utility class for performing asynchronous HTTP requests. // This class only supports one outstanding request at a time. class HttpRequest { public: HttpRequest(); int GetStatusCode() const { return statusCode; } std::wstring const& GetReasonPhrase() const { return reasonPhrase; } // Whether the response has been completely received, if using ReadAsync(). bool IsResponseComplete() const { return responseComplete; } // Start an HTTP GET on the specified URI. The returned task completes once the entire response // has been received, and the task produces the HTTP response text. The status code and reason // can be read with GetStatusCode() and GetReasonPhrase(). concurrency::task<std::wstring> GetAsync( Windows::Foundation::Uri^ uri, concurrency::cancellation_token cancellationToken = concurrency::cancellation_token::none()); // Start an HTTP POST on the specified URI, using a string body. The returned task produces the // HTTP response text. The status code and reason can be read with GetStatusCode() and GetReasonPhrase(). concurrency::task<std::wstring> PostAsync( Windows::Foundation::Uri^ uri, PCWSTR contentType, IStream* postStream, uint64 postStreamSizeToSend, concurrency::cancellation_token cancellationToken = concurrency::cancellation_token::none()); // Start an HTTP POST on the specified URI, using a stream body. The returned task produces the // HTTP response text. The status code and reason can be read with GetStatusCode() and GetReasonPhrase(). concurrency::task<std::wstring> PostAsync( Windows::Foundation::Uri^ uri, const std::wstring& str, concurrency::cancellation_token cancellationToken = concurrency::cancellation_token::none()); // Send a request but don't return the response. Instead, let the caller read it with ReadAsync(). concurrency::task<void> SendAsync( const std::wstring& httpMethod, Windows::Foundation::Uri^ uri, concurrency::cancellation_token cancellationToken = concurrency::cancellation_token::none()); // Read a chunk of data from the HTTP response, up to a specified length or until we reach the end // of the response, and store the value in the provided buffer. This is useful for large content, // enabling the streaming of the result. concurrency::task<void> ReadAsync( Windows::Storage::Streams::IBuffer^ readBuffer, unsigned int offsetInBuffer, unsigned int requestedBytesToRead); static void CreateMemoryStream(IStream **stream); private: // Start a download of the specified URI using the specified method. The returned task produces the // HTTP response text. The status code and reason can be read with GetStatusCode() and GetReasonPhrase(). concurrency::task<std::wstring> DownloadAsync( PCWSTR httpMethod, PCWSTR uri, concurrency::cancellation_token cancellationToken, PCWSTR contentType, IStream* postStream, uint64 postStreamBytesToSend); // Referenced pointer to the callback, if using SendAsync/ReadAsync. Microsoft::WRL::ComPtr<Details::HttpRequestBuffersCallback> buffersCallback; int statusCode; std::wstring reasonPhrase; // Whether the response has been completely received, if using ReadAsync(). bool responseComplete; }; };In HttpRequest.h, aggiungere questo codice:
#include "pch.h" #include "HttpRequest.h" #include <robuffer.h> #include <shcore.h> using namespace concurrency; using namespace Microsoft::WRL; using namespace Platform; using namespace std; using namespace Web; using namespace Windows::Foundation; using namespace Windows::Storage::Streams; // Implementation of IXMLHTTPRequest2Callback used when only the complete response is needed. // When processing chunks of response data as they are received, use HttpRequestBuffersCallback instead. class HttpRequestStringCallback : public RuntimeClass<RuntimeClassFlags<ClassicCom>, IXMLHTTPRequest2Callback, FtmBase> { public: HttpRequestStringCallback(IXMLHTTPRequest2* httpRequest, cancellation_token ct = concurrency::cancellation_token::none()) : request(httpRequest), cancellationToken(ct) { // Register a callback function that aborts the HTTP operation when // the cancellation token is canceled. if (cancellationToken != cancellation_token::none()) { registrationToken = cancellationToken.register_callback([this]() { if (request != nullptr) { request->Abort(); } }); } } // Called when the HTTP request is being redirected to a new URL. IFACEMETHODIMP OnRedirect(IXMLHTTPRequest2*, PCWSTR) { return S_OK; } // Called when HTTP headers have been received and processed. IFACEMETHODIMP OnHeadersAvailable(IXMLHTTPRequest2*, DWORD statusCode, PCWSTR reasonPhrase) { HRESULT hr = S_OK; // We must not propagate exceptions back to IXHR2. try { this->statusCode = statusCode; this->reasonPhrase = reasonPhrase; } catch (std::bad_alloc&) { hr = E_OUTOFMEMORY; } return hr; } // Called when a portion of the entity body has been received. IFACEMETHODIMP OnDataAvailable(IXMLHTTPRequest2*, ISequentialStream*) { return S_OK; } // Called when the entire entity response has been received. IFACEMETHODIMP OnResponseReceived(IXMLHTTPRequest2*, ISequentialStream* responseStream) { wstring wstr; HRESULT hr = ReadUtf8StringFromSequentialStream(responseStream, wstr); // We must not propagate exceptions back to IXHR2. try { completionEvent.set(make_tuple<HRESULT, wstring>(move(hr), move(wstr))); } catch (std::bad_alloc&) { hr = E_OUTOFMEMORY; } return hr; } // Simulate the functionality of DataReader.ReadString(). // This is needed because DataReader requires IRandomAccessStream and this // code has an ISequentialStream that does not have a conversion to IRandomAccessStream like IStream does. HRESULT ReadUtf8StringFromSequentialStream(ISequentialStream* readStream, wstring& str) { // Convert the response to Unicode wstring. HRESULT hr; // Holds the response as a Unicode string. wstringstream ss; while (true) { ULONG cb; char buffer[4096]; // Read the response as a UTF-8 string. Since UTF-8 characters are 1-4 bytes long, // we need to make sure we only read an integral number of characters. So we'll // start with 4093 bytes. hr = readStream->Read(buffer, sizeof(buffer) - 3, &cb); if (FAILED(hr) || (cb == 0)) { break; // Error or no more data to process, exit loop. } if (cb == sizeof(buffer) - 3) { ULONG subsequentBytesRead; unsigned int i, cl; // Find the first byte of the last UTF-8 character in the buffer. for (i = cb - 1; (i >= 0) && ((buffer[i] & 0xC0) == 0x80); i--); // Calculate the number of subsequent bytes in the UTF-8 character. if (((unsigned char)buffer[i]) < 0x80) { cl = 1; } else if (((unsigned char)buffer[i]) < 0xE0) { cl = 2; } else if (((unsigned char)buffer[i]) < 0xF0) { cl = 3; } else { cl = 4; } // Read any remaining bytes. if (cb < i + cl) { hr = readStream->Read(buffer + cb, i + cl - cb, &subsequentBytesRead); if (FAILED(hr)) { break; // Error, exit loop. } cb += subsequentBytesRead; } } // First determine the size required to store the Unicode string. int const sizeRequired = MultiByteToWideChar(CP_UTF8, 0, buffer, cb, nullptr, 0); if (sizeRequired == 0) { // Invalid UTF-8. hr = HRESULT_FROM_WIN32(GetLastError()); break; } unique_ptr<char16[]> wstr(new(std::nothrow) char16[sizeRequired + 1]); if (wstr.get() == nullptr) { hr = E_OUTOFMEMORY; break; } // Convert the string from UTF-8 to UTF-16LE. This can never fail, since // the previous call above succeeded. MultiByteToWideChar(CP_UTF8, 0, buffer, cb, wstr.get(), sizeRequired); wstr[sizeRequired] = L'\0'; // Terminate the string. ss << wstr.get(); // Write the string to the stream. } str = SUCCEEDED(hr) ? ss.str() : wstring(); return (SUCCEEDED(hr)) ? S_OK : hr; // Don't return S_FALSE. } // Called when an error occurs during the HTTP request. IFACEMETHODIMP OnError(IXMLHTTPRequest2*, HRESULT hrError) { HRESULT hr = S_OK; // We must not propagate exceptions back to IXHR2. try { completionEvent.set(make_tuple<HRESULT, wstring>(move(hrError), wstring())); } catch (std::bad_alloc&) { hr = E_OUTOFMEMORY; } return hr; } // Retrieves the completion event for the HTTP operation. task_completion_event<tuple<HRESULT, wstring>> const& GetCompletionEvent() const { return completionEvent; } int GetStatusCode() const { return statusCode; } wstring GetReasonPhrase() const { return reasonPhrase; } private: ~HttpRequestStringCallback() { // Unregister the callback. if (cancellationToken != cancellation_token::none()) { cancellationToken.deregister_callback(registrationToken); } } // Signals that the download operation was canceled. cancellation_token cancellationToken; // Used to unregister the cancellation token callback. cancellation_token_registration registrationToken; // The IXMLHTTPRequest2 that processes the HTTP request. ComPtr<IXMLHTTPRequest2> request; // Task completion event that is set when the // download operation completes. task_completion_event<tuple<HRESULT, wstring>> completionEvent; int statusCode; wstring reasonPhrase; }; // Copy bytes from the sequential stream into the buffer provided until // we reach the end of one or the other. unsigned int Web::Details::HttpRequestBuffersCallback::ReadData( _Out_writes_(outputBufferSize) byte* outputBuffer, unsigned int outputBufferSize) { // Lock the data event while doing the read, to ensure that any bytes we don't read will // result in the correct event getting triggered. concurrency::critical_section::scoped_lock lock(dataEventLock); ULONG bytesRead; CheckHResult(dataStream.Get()->Read(outputBuffer, outputBufferSize, &bytesRead)); if (bytesRead < outputBufferSize) { // We need to reset the data event, which we can only do by creating a new one. dataEvent = task_completion_event<void>(); } return bytesRead; } // Create a task that completes when data is available, in an exception-safe way. task<void> Web::Details::HttpRequestBuffersCallback::CreateDataTask() { concurrency::critical_section::scoped_lock lock(dataEventLock); return create_task(dataEvent, cancellationToken); } HttpRequest::HttpRequest() : responseComplete(true), statusCode(200) { } // Start a download of the specified URI using the specified method. The returned task produces the // HTTP response text. The status code and reason can be read with GetStatusCode() and GetReasonPhrase(). task<wstring> HttpRequest::DownloadAsync(PCWSTR httpMethod, PCWSTR uri, cancellation_token cancellationToken, PCWSTR contentType, IStream* postStream, uint64 postStreamSizeToSend) { // Create an IXMLHTTPRequest2 object. ComPtr<IXMLHTTPRequest2> xhr; CheckHResult(CoCreateInstance(CLSID_XmlHttpRequest, nullptr, CLSCTX_INPROC, IID_PPV_ARGS(&xhr))); // Create callback. auto stringCallback = Make<HttpRequestStringCallback>(xhr.Get(), cancellationToken); CheckHResult(stringCallback ? S_OK : E_OUTOFMEMORY); auto completionTask = create_task(stringCallback->GetCompletionEvent()); // Create a request. CheckHResult(xhr->Open(httpMethod, uri, stringCallback.Get(), nullptr, nullptr, nullptr, nullptr)); if (postStream != nullptr && contentType != nullptr) { CheckHResult(xhr->SetRequestHeader(L"Content-Type", contentType)); } // Send the request. CheckHResult(xhr->Send(postStream, postStreamSizeToSend)); // Return a task that completes when the HTTP operation completes. // We pass the callback to the continuation because the lifetime of the // callback must exceed the operation to ensure that cancellation // works correctly. return completionTask.then([this, stringCallback](tuple<HRESULT, wstring> resultTuple) { // If the GET operation failed, throw an Exception. CheckHResult(std::get<0>(resultTuple)); statusCode = stringCallback->GetStatusCode(); reasonPhrase = stringCallback->GetReasonPhrase(); return std::get<1>(resultTuple); }); } // Start an HTTP GET on the specified URI. The returned task completes once the entire response // has been received, and the task produces the HTTP response text. The status code and reason // can be read with GetStatusCode() and GetReasonPhrase(). task<wstring> HttpRequest::GetAsync(Uri^ uri, cancellation_token cancellationToken) { return DownloadAsync(L"GET", uri->AbsoluteUri->Data(), cancellationToken, nullptr, nullptr, 0); } void HttpRequest::CreateMemoryStream(IStream **stream) { auto randomAccessStream = ref new Windows::Storage::Streams::InMemoryRandomAccessStream(); CheckHResult(CreateStreamOverRandomAccessStream(randomAccessStream, IID_PPV_ARGS(stream))); } // Start an HTTP POST on the specified URI, using a string body. The returned task produces the // HTTP response text. The status code and reason can be read with GetStatusCode() and GetReasonPhrase(). task<wstring> HttpRequest::PostAsync(Uri^ uri, const wstring& body, cancellation_token cancellationToken) { int length = 0; ComPtr<IStream> postStream; CreateMemoryStream(&postStream); if (body.length() > 0) { // Get the required buffer size. int size = WideCharToMultiByte(CP_UTF8, // UTF-8 0, // Conversion type body.c_str(), // Unicode string to convert static_cast<int>(body.length()), // Size nullptr, // Output buffer 0, // Output buffer size nullptr, nullptr); CheckHResult((size != 0) ? S_OK : HRESULT_FROM_WIN32(GetLastError())); std::unique_ptr<char[]> tempData(new char[size]); length = WideCharToMultiByte(CP_UTF8, // UTF-8 0, // Conversion type body.c_str(), // Unicode string to convert static_cast<int>(body.length()), // Size tempData.get(), // Output buffer size, // Output buffer size nullptr, nullptr); CheckHResult((length != 0) ? S_OK : HRESULT_FROM_WIN32(GetLastError())); CheckHResult(postStream->Write(tempData.get(), length, nullptr)); } return DownloadAsync(L"POST", uri->AbsoluteUri->Data(), cancellationToken, L"text/plain;charset=utf-8", postStream.Get(), length); } // Start an HTTP POST on the specified URI, using a stream body. The returned task produces the // HTTP response text. The status code and reason can be read with GetStatusCode() and GetReasonPhrase(). task<wstring> HttpRequest::PostAsync(Uri^ uri, PCWSTR contentType, IStream* postStream, uint64 postStreamSizeToSend, cancellation_token cancellationToken) { return DownloadAsync(L"POST", uri->AbsoluteUri->Data(), cancellationToken, contentType, postStream, postStreamSizeToSend); } // Send a request but don't return the response. Instead, let the caller read it with ReadAsync(). task<void> HttpRequest::SendAsync(const wstring& httpMethod, Uri^ uri, cancellation_token cancellationToken) { // Create an IXMLHTTPRequest2 object. ComPtr<IXMLHTTPRequest2> xhr; CheckHResult(CoCreateInstance(CLSID_XmlHttpRequest, nullptr, CLSCTX_INPROC, IID_PPV_ARGS(&xhr))); // Create callback. buffersCallback = Make<Web::Details::HttpRequestBuffersCallback>(xhr.Get(), cancellationToken); CheckHResult(buffersCallback ? S_OK : E_OUTOFMEMORY); ComPtr<IXMLHTTPRequest2Callback> xhrCallback; CheckHResult(buffersCallback.As(&xhrCallback)); // Open and send the request. CheckHResult(xhr->Open(httpMethod.c_str(), uri->AbsoluteUri->Data(), xhrCallback.Get(), nullptr, nullptr, nullptr, nullptr)); responseComplete = false; CheckHResult(xhr->Send(nullptr, 0)); // Return a task that completes when the HTTP operation completes. // Since buffersCallback holds a reference on the callback, the lifetime of the callback will exceed // the operation and ensure that cancellation works correctly. return buffersCallback->CreateDataTask().then([this]() { CheckHResult(buffersCallback->GetError()); statusCode = buffersCallback->GetStatusCode(); reasonPhrase = buffersCallback->GetReasonPhrase(); }); } // Read a chunk of data from the HTTP response, up to a specified length or until we reach the end // of the response, and store the value in the provided buffer. This is useful for large content, // enabling the streaming of the result. task<void> HttpRequest::ReadAsync(Windows::Storage::Streams::IBuffer^ readBuffer, unsigned int offsetInBuffer, unsigned int requestedBytesToRead) { if (offsetInBuffer + requestedBytesToRead > readBuffer->Capacity) { throw ref new InvalidArgumentException(); } // Return a task that completes when a read completes. // We pass the callback to the continuation because the lifetime of the // callback must exceed the operation to ensure that cancellation // works correctly. return buffersCallback->CreateDataTask().then([this, readBuffer, offsetInBuffer, requestedBytesToRead]() { CheckHResult(buffersCallback->GetError()); // Get a pointer to the location to copy data into. ComPtr<IBufferByteAccess> bufferByteAccess; CheckHResult(reinterpret_cast<IUnknown*>(readBuffer)->QueryInterface(IID_PPV_ARGS(&bufferByteAccess))); byte* outputBuffer; // Returned internal pointer, do not free this value. CheckHResult(bufferByteAccess->Buffer(&outputBuffer)); // Copy bytes from the sequential stream into the buffer provided until // we reach the end of one or the other. readBuffer->Length = buffersCallback->ReadData(outputBuffer + offsetInBuffer, requestedBytesToRead); if (buffersCallback->IsResponseReceived() && (readBuffer->Length < requestedBytesToRead)) { responseComplete = true; } }); }
Utilizzando la classe HttpRequest in un'applicazione Windows Store.
In questa sezione viene illustrato come utilizzare la classe HttpRequest in un'applicazione Windows Store.L'applicazione fornisce una casella di input che definisce una risorsa con un URL, un pulsante che esegue le operazioni di GET e POST e un pulsante per annullare l'operazione in corso.
Per utilizzare la classe HttpRequest
Nel file MainPage.xaml, definire l'elemento StackPanel come segue.
<StackPanel HorizontalAlignment="Left" Width="440" Background="{StaticResource ApplicationPageBackgroundThemeBrush}"> <TextBox x:Name="InputTextBox" TextWrapping="Wrap" Text="https://www.fourthcoffee.com/"/> <StackPanel Orientation="Horizontal"> <Button x:Name="GetButton" Content="Get" Background="Green" Click="GetButton_Click"/> <Button x:Name="PostButton" Content="Post" Background="Blue" Click="PostButton_Click"/> <Button x:Name="CancelButton" Content="Cancel" Background="Red" IsEnabled="False" Click="CancelButton_Click"/> <ProgressRing x:Name="ResponseProgressRing" /> </StackPanel> <TextBlock x:Name="ResponseTextBlock" TextWrapping="Wrap"/> </StackPanel>In MainPage.xaml.h, aggiungere questa direttiva #include :
#include "HttpRequest.h"In MainPage.xaml.h, aggiungere queste variabili membro private alla classe MainPage :
// Produces HTTP requets. Web::HttpRequest m_httpRequest; // Enables us to cancel the active HTTP request. concurrency::cancellation_token_source m_cancelHttpRequestSource;In MainPage.xaml.h, dichiarare il metodo ProcessHttpRequest, private :
// Displays the result of the provided HTTP request on the UI. void ProcessHttpRequest(concurrency::task<std::wstring> httpRequest);In MainPage.xaml.cpp, aggiungere le istruzioni using :
using namespace concurrency; using namespace std; using namespace Web;In MainPage.xaml.cpp, implementare GetButton_Click, PostButton_Clicke i metodi CancelButton_Click della classe MainPage .
void MainPage::GetButton_Click(Object^ sender, RoutedEventArgs^ e) { // Create a new cancellation token source for the web request. m_cancelHttpRequestSource = cancellation_token_source(); // Set up the GET request parameters. auto uri = ref new Uri(InputTextBox->Text); auto token = m_cancelHttpRequestSource.get_token(); // Send the request and then update the UI. ProcessHttpRequest(m_httpRequest.GetAsync(uri, token)); } void MainPage::PostButton_Click(Object^ sender, RoutedEventArgs^ e) { // Create a new cancellation token source for the web request. m_cancelHttpRequestSource = cancellation_token_source(); // Set up the POST request parameters. auto uri = ref new Uri(InputTextBox->Text); wstring postData(L"This is sample POST data."); auto token = m_cancelHttpRequestSource.get_token(); // Send the request and then update the UI. ProcessHttpRequest(m_httpRequest.PostAsync(uri, postData, token)); } void MainPage::CancelButton_Click(Object^ sender, RoutedEventArgs^ e) { // Disable the Cancel button. // It will be re-enabled during the next web request. CancelButton->IsEnabled = false; // Initiate cancellation. m_cancelHttpRequestSource.cancel(); }SuggerimentoSe l'applicazione non richiede il supporto per l'annullamento, passare concurrency::cancellation_token::none ai metodi HttpRequest::PostAsync e HttpRequest::GetAsync.
In MainPage.xaml.cpp, implementare il metodo MainPage::ProcessHttpRequest.
// Displays the result of the provided HTTP request on the UI. void MainPage::ProcessHttpRequest(task<wstring> httpRequest) { // Enable only the Cancel button. GetButton->IsEnabled = false; PostButton->IsEnabled = false; CancelButton->IsEnabled = true; // Clear the previous response and start the progress ring. ResponseTextBlock->Text = ""; ResponseProgressRing->IsActive = true; // Create a continuation that shows the results on the UI. // The UI must be updated on the ASTA thread. // Therefore, schedule the continuation to run on the current context. httpRequest.then([this](task<wstring> previousTask) { try { // // Show the result on the UI. wstring response = previousTask.get(); if (m_httpRequest.GetStatusCode() == 200) { // The request succeeded. Show the response. ResponseTextBlock->Text = ref new String(response.c_str()); } else { // The request failed. Show the status code and reason. wstringstream ss; ss << L"The server returned " << m_httpRequest.GetStatusCode() << L" (" << m_httpRequest.GetReasonPhrase() << L')'; ResponseTextBlock->Text = ref new String(ss.str().c_str()); } } catch (const task_canceled&) { // Indicate that the operation was canceled. ResponseTextBlock->Text = "The operation was canceled"; } catch (Exception^ e) { // Indicate that the operation failed. ResponseTextBlock->Text = "The operation failed"; // TODO: Handle the error further. (void)e; } // Enable the Get and Post buttons. GetButton->IsEnabled = true; PostButton->IsEnabled = true; CancelButton->IsEnabled = false; // Stop the progress ring. ResponseProgressRing->IsActive = false; }, task_continuation_context::use_current()); }Nelle proprietà del progetto, in Linker, Input, specificare shcore.lib e msxml6.lib.
Ecco l'applicazione in esecuzione:
.png "Applicazione Windows Store in esecuzione")
Passaggi successivi
Procedure dettagliate del runtime di concorrenza
Vedere anche
Riferimenti
Classe task (runtime di concorrenza)
Concetti
Parallelismo delle attività (runtime di concorrenza)
Annullamento nella libreria PPL
Creazione di operazioni asincrone in C++ per le applicazioni Windows Store
Altre risorse
Asynchronous programming in C++