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| 1 : | tim | 1.1 | <html> |
| 2 : | <head><title> Executor examples </title></head> | ||
| 3 : | <body> | ||
| 4 : | |||
| 5 : | <p> These probably don't qualify as canonical use cases, but they | ||
| 6 : | are applications of executors that I have come across in real life. | ||
| 7 : | </p> | ||
| 8 : | |||
| 9 : | <h2> Converting a blocking request into non-blocking request </h2> | ||
| 10 : | |||
| 11 : | <p> I have a service interface with a method that blocks, possibly | ||
| 12 : | for a long time, for example, the client side of an HTTP-based | ||
| 13 : | service that blocks while waiting for a response. </p> | ||
| 14 : | |||
| 15 : | <pre> | ||
| 16 : | public interface Request ... | ||
| 17 : | public interface Response ... | ||
| 18 : | |||
| 19 : | interface BlockingService { | ||
| 20 : | Response serve (Request req) throws ServiceException; | ||
| 21 : | } | ||
| 22 : | </pre> | ||
| 23 : | |||
| 24 : | <p> I want an adapter that converts this interface into one that | ||
| 25 : | returns a <code>Future<Response></code> without blocking. </p> | ||
| 26 : | |||
| 27 : | <pre> | ||
| 28 : | interface NonBlockingService { | ||
| 29 : | Future<Response> serve (Request req); | ||
| 30 : | } | ||
| 31 : | </pre> | ||
| 32 : | |||
| 33 : | <p> Here's how I might do it under the currently checked in | ||
| 34 : | proposal. </p> | ||
| 35 : | |||
| 36 : | <pre> | ||
| 37 : | import java.util.concurrent.Callable; | ||
| 38 : | import java.util.concurrent.Executor; | ||
| 39 : | import java.util.concurrent.Executors; | ||
| 40 : | import java.util.concurrent.Future; | ||
| 41 : | import java.util.concurrent.FutureTask; | ||
| 42 : | |||
| 43 : | class NonBlockingServiceAdapter implements NonBlockingService { | ||
| 44 : | |||
| 45 : | public NonBlockingServiceAdapter (BlockingService svc) { | ||
| 46 : | this(svc, null); | ||
| 47 : | } | ||
| 48 : | |||
| 49 : | public NonBlockingServiceAdapter (BlockingService svc, Executor executor) { | ||
| 50 : | this.blockingService = svc; | ||
| 51 : | if (executor == null) { | ||
| 52 : | this.executor = Executors.newFixedThreadPool(3); | ||
| 53 : | } | ||
| 54 : | else { | ||
| 55 : | this.executor = executor; | ||
| 56 : | } | ||
| 57 : | } | ||
| 58 : | |||
| 59 : | public Future<Response> serve (final Request req) { | ||
| 60 : | Callable<Response> task = new Callable<Response>() { | ||
| 61 : | public Response call () { | ||
| 62 : | return blockingService.serve(req); | ||
| 63 : | } | ||
| 64 : | }; | ||
| 65 : | FutureTask<Response> ftask = new FutureTask<Response>(task); | ||
| 66 : | executor.execute(ftask); | ||
| 67 : | return ftask; | ||
| 68 : | } | ||
| 69 : | |||
| 70 : | private final BlockingService blockingService; | ||
| 71 : | private final Executor executor; | ||
| 72 : | } | ||
| 73 : | </pre> | ||
| 74 : | |||
| 75 : | <p> If I change my mind about using a single thread executor as the | ||
| 76 : | default and want to use, say, a thread pool, I don't have to change | ||
| 77 : | the imports and I don't have to learn any new types; I just | ||
| 78 : | consult the <code>Executors</code> javadocs and change one line to something | ||
| 79 : | like: </p> | ||
| 80 : | |||
| 81 : | <pre> | ||
| 82 : | this.executor = Executors.newCachedThreadPool(); | ||
| 83 : | </pre> | ||
| 84 : | |||
| 85 : | <p> In this case it is irrelevant that the factory method returns a | ||
| 86 : | more specific type. </p> | ||
| 87 : | |||
| 88 : | <p> If there were no <code>Executor</code> factory methods or if those factory | ||
| 89 : | methods were part of <code>AbstractExecutor/ThreadExecutor</code>, I'd have to | ||
| 90 : | learn about and import a type just so I could get access to its | ||
| 91 : | factory methods or public constructors. </p> | ||
| 92 : | |||
| 93 : | <p> If I have more complicated requirements on the internal | ||
| 94 : | executor, I can pass in an instance that has been configured in | ||
| 95 : | advance with <code>Callbacks/Hooks/Intercepts</code>, possibly an extension of an | ||
| 96 : | existing class or even my own custom implementation of <code>Executor</code>. </p> | ||
| 97 : | |||
| 98 : | <p> If a later redesign requires lifecycle management for the | ||
| 99 : | internal executor, under the current proposal I would change its | ||
| 100 : | type to <code>ExecutorService</code> and provide methods on | ||
| 101 : | <code>NonBlockingServiceAdapter</code> that ultimately call into the | ||
| 102 : | <code>ExecutorService</code> instance. The executor and the executor | ||
| 103 : | service are the same object under the current proposal, but this is not | ||
| 104 : | a requirement for this example. </p> | ||
| 105 : | |||
| 106 : | |||
| 107 : | <h2> Workaround Borland C++ DLL threading limitation </h2> | ||
| 108 : | |||
| 109 : | <p> An annoying design flaw in one version of the Borland C++ | ||
| 110 : | (for Windows) runtime libraries causes a severe crash.if a C++ | ||
| 111 : | exception is thrown in DLL code within a thread other than the one | ||
| 112 : | in which the DLL was loaded. For JNI users, there are several ways | ||
| 113 : | around this problem, including changing the compiler and avoiding | ||
| 114 : | the use of C++ exceptions. However, if none of these workarounds are | ||
| 115 : | available, the only solution is to make sure that alls calls to native | ||
| 116 : | methods implemented by such a DLL are made in the same thread as the | ||
| 117 : | one that loaded the DLL. </p> | ||
| 118 : | |||
| 119 : | <p> If you run into this situation repeatedly, as I did, you might | ||
| 120 : | find yourself wanting an adapter class to do the heavy lifting for | ||
| 121 : | you using a dynamic proxy, as follows: For a class <code>NativeImpl</code> with | ||
| 122 : | native methods implemented by a Borland C++ DLL, define an interface | ||
| 123 : | <code>NativeInterface</code> consisting of all of the native methods | ||
| 124 : | of <code>NativeImpl</code>, | ||
| 125 : | and make <code>NativeImpl</code> extend <code>NativeInterface</code>. The | ||
| 126 : | adapter uses <code>Proxy.newProxyInstance</code> to create a new instance of this | ||
| 127 : | interface by implementing the <code>invoke</code> to execute each method | ||
| 128 : | call as a Callable on a single thread executor that delegates to an | ||
| 129 : | underlying <code>NativeImpl</code>. </p> | ||
| 130 : | |||
| 131 : | <pre> | ||
| 132 : | tim | 1.2 | class SingleThreadAdapter { |
| 133 : | tim | 1.1 | |
| 134 : | public SingleThreadAdapter (String library) { | ||
| 135 : | this.executor = Executors.newSingleThreadExecutor(); | ||
| 136 : | try { | ||
| 137 : | FutureTask ftask = new FutureTask(new Runnable () { | ||
| 138 : | public void run () { | ||
| 139 : | System.loadLibrary(library); | ||
| 140 : | } | ||
| 141 : | }); | ||
| 142 : | executor.executor(ftask); | ||
| 143 : | } | ||
| 144 : | catch (ExecutionException e) { | ||
| 145 : | if (e.getCause() == null) { | ||
| 146 : | throw new RuntimeException(e); | ||
| 147 : | } | ||
| 148 : | if (e.getCause() instanceof RuntimeException) { | ||
| 149 : | throw (RuntimeException) e.getCause(); | ||
| 150 : | } | ||
| 151 : | if (e.getCause() instanceof Error) { | ||
| 152 : | throw (Error) e.getCause(); | ||
| 153 : | } | ||
| 154 : | throw new RuntimeException(e.getCause()); | ||
| 155 : | } | ||
| 156 : | // ... other invocation or interruption related catch clauses ... | ||
| 157 : | } | ||
| 158 : | |||
| 159 : | public Object newInstance (Callable creator) throws Exception { | ||
| 160 : | try { | ||
| 161 : | FutureTask createTask = new FutureTask(creator); | ||
| 162 : | executor.execute(createTask); | ||
| 163 : | Object instance = createTask.get(); | ||
| 164 : | return Proxy.newProxyInstance( | ||
| 165 : | instance.getClass().getClassLoader(), | ||
| 166 : | instance.getClass().getInterfaces(), | ||
| 167 : | new Handler(instance)); | ||
| 168 : | } | ||
| 169 : | catch (ExecutionException e) { | ||
| 170 : | if (e.getCause() == null) { | ||
| 171 : | throw e; | ||
| 172 : | } | ||
| 173 : | if (e.getCause() instanceof Exception) { | ||
| 174 : | throw e.getCause(); | ||
| 175 : | } | ||
| 176 : | else { | ||
| 177 : | throw new RuntimeException(e.getCause()); | ||
| 178 : | } | ||
| 179 : | } | ||
| 180 : | // ... other invocation or interruption related catch clauses ... | ||
| 181 : | } | ||
| 182 : | |||
| 183 : | private class Handler implements InvocationHandler { | ||
| 184 : | public Object invoke (Object proxy, | ||
| 185 : | final Method method, | ||
| 186 : | final Object[] args) throws Throwable { | ||
| 187 : | try { | ||
| 188 : | tim | 1.2 | Callable task = new Callable () { |
| 189 : | public Object call () throws Exception { | ||
| 190 : | try { | ||
| 191 : | return method.invoke(instance, args); | ||
| 192 : | } | ||
| 193 : | catch (Exception e) { | ||
| 194 : | throw e; | ||
| 195 : | } | ||
| 196 : | catch (Throwable e) { | ||
| 197 : | throw RuntimeException(e); | ||
| 198 : | } | ||
| 199 : | } | ||
| 200 : | }; | ||
| 201 : | tim | 1.1 | FutureTask ftask = new FutureTask(task) |
| 202 : | executor.execute(ftask); | ||
| 203 : | return ftask.get(); | ||
| 204 : | } | ||
| 205 : | catch (ExecutionException e) { | ||
| 206 : | throw e.getCause() == null ? e : e.getCause(); | ||
| 207 : | } | ||
| 208 : | // ... other invocation or interruption related catch clauses ... | ||
| 209 : | } | ||
| 210 : | |||
| 211 : | Handler (Object instance) { | ||
| 212 : | this.instance = instance; | ||
| 213 : | } | ||
| 214 : | |||
| 215 : | private final Object instance; | ||
| 216 : | } | ||
| 217 : | |||
| 218 : | private final Executor executor; | ||
| 219 : | } | ||
| 220 : | </pre> | ||
| 221 : | |||
| 222 : | <p> Typical use of this class would be: </p> | ||
| 223 : | |||
| 224 : | <pre> | ||
| 225 : | try { | ||
| 226 : | SingleThreadAdapter adapter = new SingleThreadAdapter("LegacyEngine.dll"); | ||
| 227 : | NativeInterface ni = (NativeInterface) | ||
| 228 : | adapter.newInstance(new Callable<NativeInterface> () { | ||
| 229 : | public NativeInterface call () { | ||
| 230 : | tim | 1.2 | return new NativeImpl(); // may use native calls |
| 231 : | tim | 1.1 | } |
| 232 : | }); | ||
| 233 : | int i = ni.nativeIntMethod(); | ||
| 234 : | } | ||
| 235 : | // catch clauses for adapter creation, instance creation, invocation, | ||
| 236 : | // interruption... | ||
| 237 : | </pre> | ||
| 238 : | |||
| 239 : | <p> Even though it is clear that SingleThreadExecutor and no other kind | ||
| 240 : | of Executor will be used in the implementation, there is no reason to | ||
| 241 : | expose this anywhere except in the SingleThreadAdapter constructor. </p> | ||
| 242 : | |||
| 243 : | <p> The exception handling is delicate and long winded. I punted on | ||
| 244 : | most of it, and I'm not sure I got the rest right either. </p> | ||
| 245 : | |||
| 246 : | </body> | ||
| 247 : | </html> |
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