Java Code Examples for sun.java2d.pipe.BufferedContext#getRenderQueue()

private static void testContext(final AccelGraphicsConfig agc) {
    BufferedContext c = agc.getContext();
    final AccelDeviceEventListener l = new AccelDeviceEventListener() {
        public void onDeviceDispose() {
            System.out.println("onDeviceDispose invoked");
            agc.removeDeviceEventListener(this);
        }
        public void onDeviceReset() {
            System.out.println("onDeviceReset invoked");
        }
    };
    agc.addDeviceEventListener(l);

    RenderQueue rq = c.getRenderQueue();
    rq.lock();
    try {
        c.saveState();
        rq.flushNow();
        c.restoreState();
        rq.flushNow();
        System.out.println("Passed: Save/Restore");
    } finally {
        rq.unlock();
    }
}
 

private static void testContext(final AccelGraphicsConfig agc) {
    BufferedContext c = agc.getContext();
    final AccelDeviceEventListener l = new AccelDeviceEventListener() {
        public void onDeviceDispose() {
            System.out.println("onDeviceDispose invoked");
            agc.removeDeviceEventListener(this);
        }
        public void onDeviceReset() {
            System.out.println("onDeviceReset invoked");
        }
    };
    agc.addDeviceEventListener(l);

    RenderQueue rq = c.getRenderQueue();
    rq.lock();
    try {
        c.saveState();
        rq.flushNow();
        c.restoreState();
        rq.flushNow();
        System.out.println("Passed: Save/Restore");
    } finally {
        rq.unlock();
    }
}
 

private static void testContext(final AccelGraphicsConfig agc) {
    BufferedContext c = agc.getContext();
    final AccelDeviceEventListener l = new AccelDeviceEventListener() {
        public void onDeviceDispose() {
            System.out.println("onDeviceDispose invoked");
            agc.removeDeviceEventListener(this);
        }
        public void onDeviceReset() {
            System.out.println("onDeviceReset invoked");
        }
    };
    agc.addDeviceEventListener(l);

    RenderQueue rq = c.getRenderQueue();
    rq.lock();
    try {
        c.saveState();
        rq.flushNow();
        c.restoreState();
        rq.flushNow();
        System.out.println("Passed: Save/Restore");
    } finally {
        rq.unlock();
    }
}
 

private static void testContext(final AccelGraphicsConfig agc) {
    BufferedContext c = agc.getContext();
    final AccelDeviceEventListener l = new AccelDeviceEventListener() {
        public void onDeviceDispose() {
            System.out.println("onDeviceDispose invoked");
            agc.removeDeviceEventListener(this);
        }
        public void onDeviceReset() {
            System.out.println("onDeviceReset invoked");
        }
    };
    agc.addDeviceEventListener(l);

    RenderQueue rq = c.getRenderQueue();
    rq.lock();
    try {
        c.saveState();
        rq.flushNow();
        c.restoreState();
        rq.flushNow();
        System.out.println("Passed: Save/Restore");
    } finally {
        rq.unlock();
    }
}
 

private static void testContext(final AccelGraphicsConfig agc) {
    BufferedContext c = agc.getContext();
    final AccelDeviceEventListener l = new AccelDeviceEventListener() {
        public void onDeviceDispose() {
            System.out.println("onDeviceDispose invoked");
            agc.removeDeviceEventListener(this);
        }
        public void onDeviceReset() {
            System.out.println("onDeviceReset invoked");
        }
    };
    agc.addDeviceEventListener(l);

    RenderQueue rq = c.getRenderQueue();
    rq.lock();
    try {
        c.saveState();
        rq.flushNow();
        c.restoreState();
        rq.flushNow();
        System.out.println("Passed: Save/Restore");
    } finally {
        rq.unlock();
    }
}
 

private static void testContext(final AccelGraphicsConfig agc) {
    BufferedContext c = agc.getContext();
    final AccelDeviceEventListener l = new AccelDeviceEventListener() {
        public void onDeviceDispose() {
            System.out.println("onDeviceDispose invoked");
            agc.removeDeviceEventListener(this);
        }
        public void onDeviceReset() {
            System.out.println("onDeviceReset invoked");
        }
    };
    agc.addDeviceEventListener(l);

    RenderQueue rq = c.getRenderQueue();
    rq.lock();
    try {
        c.saveState();
        rq.flushNow();
        c.restoreState();
        rq.flushNow();
        System.out.println("Passed: Save/Restore");
    } finally {
        rq.unlock();
    }
}
 

private static void testContext(final AccelGraphicsConfig agc) {
    BufferedContext c = agc.getContext();
    final AccelDeviceEventListener l = new AccelDeviceEventListener() {
        public void onDeviceDispose() {
            System.out.println("onDeviceDispose invoked");
            agc.removeDeviceEventListener(this);
        }
        public void onDeviceReset() {
            System.out.println("onDeviceReset invoked");
        }
    };
    agc.addDeviceEventListener(l);

    RenderQueue rq = c.getRenderQueue();
    rq.lock();
    try {
        c.saveState();
        rq.flushNow();
        c.restoreState();
        rq.flushNow();
        System.out.println("Passed: Save/Restore");
    } finally {
        rq.unlock();
    }
}
 

private static void testContext(final AccelGraphicsConfig agc) {
    BufferedContext c = agc.getContext();
    final AccelDeviceEventListener l = new AccelDeviceEventListener() {
        public void onDeviceDispose() {
            System.out.println("onDeviceDispose invoked");
            agc.removeDeviceEventListener(this);
        }
        public void onDeviceReset() {
            System.out.println("onDeviceReset invoked");
        }
    };
    agc.addDeviceEventListener(l);

    RenderQueue rq = c.getRenderQueue();
    rq.lock();
    try {
        c.saveState();
        rq.flushNow();
        c.restoreState();
        rq.flushNow();
        System.out.println("Passed: Save/Restore");
    } finally {
        rq.unlock();
    }
}
 

private static void testContext(final AccelGraphicsConfig agc) {
    BufferedContext c = agc.getContext();
    final AccelDeviceEventListener l = new AccelDeviceEventListener() {
        public void onDeviceDispose() {
            System.out.println("onDeviceDispose invoked");
            agc.removeDeviceEventListener(this);
        }
        public void onDeviceReset() {
            System.out.println("onDeviceReset invoked");
        }
    };
    agc.addDeviceEventListener(l);

    RenderQueue rq = c.getRenderQueue();
    rq.lock();
    try {
        c.saveState();
        rq.flushNow();
        c.restoreState();
        rq.flushNow();
        System.out.println("Passed: Save/Restore");
    } finally {
        rq.unlock();
    }
}
 

private static void testContext(final AccelGraphicsConfig agc) {
    BufferedContext c = agc.getContext();

    RenderQueue rq = c.getRenderQueue();
    rq.lock();
    try {
        c.saveState();
        rq.flushNow();
        c.restoreState();
        rq.flushNow();
        System.out.println("Passed: Save/Restore");
    } finally {
        rq.unlock();
    }
}
 

static void disposeStrike(final FontStrikeDisposer disposer) {
    // we need to execute the strike disposal on the rendering thread
    // because they may be accessed on that thread at the time of the
    // disposal (for example, when the accel. cache is invalidated)

    // Whilst this is a bit heavyweight, in most applications
    // strike disposal is a relatively infrequent operation, so it
    // doesn't matter. But in some tests that use vast numbers
    // of strikes, the switching back and forth is measurable.
    // So the "pollRemove" call is added to batch up the work.
    // If we are polling we know we've already been called back
    // and can directly dispose the record.
    // Also worrisome is the necessity of getting a GC here.

    if (Disposer.pollingQueue) {
        doDispose(disposer);
        return;
    }

    RenderQueue rq = null;
    GraphicsEnvironment ge =
        GraphicsEnvironment.getLocalGraphicsEnvironment();
    if (!ge.isHeadless()) {
        GraphicsConfiguration gc =
            ge.getDefaultScreenDevice().getDefaultConfiguration();
        if (gc instanceof AccelGraphicsConfig) {
            AccelGraphicsConfig agc = (AccelGraphicsConfig)gc;
            BufferedContext bc = agc.getContext();
            if (bc != null) {
                rq = bc.getRenderQueue();
            }
        }
    }
    if (rq != null) {
        rq.lock();
        try {
            rq.flushAndInvokeNow(new Runnable() {
                public void run() {
                    doDispose(disposer);
                    Disposer.pollRemove();
                }
            });
        } finally {
            rq.unlock();
        }
    } else {
        doDispose(disposer);
    }
}
 

static void disposeStrike(final FontStrikeDisposer disposer) {
    // we need to execute the strike disposal on the rendering thread
    // because they may be accessed on that thread at the time of the
    // disposal (for example, when the accel. cache is invalidated)

    // Whilst this is a bit heavyweight, in most applications
    // strike disposal is a relatively infrequent operation, so it
    // doesn't matter. But in some tests that use vast numbers
    // of strikes, the switching back and forth is measurable.
    // So the "pollRemove" call is added to batch up the work.
    // If we are polling we know we've already been called back
    // and can directly dispose the record.
    // Also worrisome is the necessity of getting a GC here.

    if (Disposer.pollingQueue) {
        doDispose(disposer);
        return;
    }

    RenderQueue rq = null;
    GraphicsEnvironment ge =
        GraphicsEnvironment.getLocalGraphicsEnvironment();
    if (!ge.isHeadless()) {
        GraphicsConfiguration gc =
            ge.getDefaultScreenDevice().getDefaultConfiguration();
        if (gc instanceof AccelGraphicsConfig) {
            AccelGraphicsConfig agc = (AccelGraphicsConfig)gc;
            BufferedContext bc = agc.getContext();
            if (bc != null) {
                rq = bc.getRenderQueue();
            }
        }
    }
    if (rq != null) {
        rq.lock();
        try {
            rq.flushAndInvokeNow(new Runnable() {
                public void run() {
                    doDispose(disposer);
                    Disposer.pollRemove();
                }
            });
        } finally {
            rq.unlock();
        }
    } else {
        doDispose(disposer);
    }
}
 

static void disposeStrike(final FontStrikeDisposer disposer) {
    // we need to execute the strike disposal on the rendering thread
    // because they may be accessed on that thread at the time of the
    // disposal (for example, when the accel. cache is invalidated)

    // Whilst this is a bit heavyweight, in most applications
    // strike disposal is a relatively infrequent operation, so it
    // doesn't matter. But in some tests that use vast numbers
    // of strikes, the switching back and forth is measurable.
    // So the "pollRemove" call is added to batch up the work.
    // If we are polling we know we've already been called back
    // and can directly dispose the record.
    // Also worrisome is the necessity of getting a GC here.

    if (Disposer.pollingQueue) {
        doDispose(disposer);
        return;
    }

    RenderQueue rq = null;
    GraphicsEnvironment ge =
        GraphicsEnvironment.getLocalGraphicsEnvironment();
    if (!ge.isHeadless()) {
        GraphicsConfiguration gc =
            ge.getDefaultScreenDevice().getDefaultConfiguration();
        if (gc instanceof AccelGraphicsConfig) {
            AccelGraphicsConfig agc = (AccelGraphicsConfig)gc;
            BufferedContext bc = agc.getContext();
            if (bc != null) {
                rq = bc.getRenderQueue();
            }
        }
    }
    if (rq != null) {
        rq.lock();
        try {
            rq.flushAndInvokeNow(new Runnable() {
                public void run() {
                    doDispose(disposer);
                    Disposer.pollRemove();
                }
            });
        } finally {
            rq.unlock();
        }
    } else {
        doDispose(disposer);
    }
}
 

static void disposeStrike(final FontStrikeDisposer disposer) {
    // we need to execute the strike disposal on the rendering thread
    // because they may be accessed on that thread at the time of the
    // disposal (for example, when the accel. cache is invalidated)

    // Whilst this is a bit heavyweight, in most applications
    // strike disposal is a relatively infrequent operation, so it
    // doesn't matter. But in some tests that use vast numbers
    // of strikes, the switching back and forth is measurable.
    // So the "pollRemove" call is added to batch up the work.
    // If we are polling we know we've already been called back
    // and can directly dispose the record.
    // Also worrisome is the necessity of getting a GC here.

    if (Disposer.pollingQueue) {
        doDispose(disposer);
        return;
    }

    RenderQueue rq = null;
    GraphicsEnvironment ge =
        GraphicsEnvironment.getLocalGraphicsEnvironment();
    if (!ge.isHeadless()) {
        GraphicsConfiguration gc =
            ge.getDefaultScreenDevice().getDefaultConfiguration();
        if (gc instanceof AccelGraphicsConfig) {
            AccelGraphicsConfig agc = (AccelGraphicsConfig)gc;
            BufferedContext bc = agc.getContext();
            if (bc != null) {
                rq = bc.getRenderQueue();
            }
        }
    }
    if (rq != null) {
        rq.lock();
        try {
            rq.flushAndInvokeNow(new Runnable() {
                public void run() {
                    doDispose(disposer);
                    Disposer.pollRemove();
                }
            });
        } finally {
            rq.unlock();
        }
    } else {
        doDispose(disposer);
    }
}
 

static void disposeStrike(final FontStrikeDisposer disposer) {
    // we need to execute the strike disposal on the rendering thread
    // because they may be accessed on that thread at the time of the
    // disposal (for example, when the accel. cache is invalidated)

    // Whilst this is a bit heavyweight, in most applications
    // strike disposal is a relatively infrequent operation, so it
    // doesn't matter. But in some tests that use vast numbers
    // of strikes, the switching back and forth is measurable.
    // So the "pollRemove" call is added to batch up the work.
    // If we are polling we know we've already been called back
    // and can directly dispose the record.
    // Also worrisome is the necessity of getting a GC here.

    if (Disposer.pollingQueue) {
        doDispose(disposer);
        return;
    }

    RenderQueue rq = null;
    GraphicsEnvironment ge =
        GraphicsEnvironment.getLocalGraphicsEnvironment();
    if (!GraphicsEnvironment.isHeadless()) {
        GraphicsConfiguration gc =
            ge.getDefaultScreenDevice().getDefaultConfiguration();
        if (gc instanceof AccelGraphicsConfig) {
            AccelGraphicsConfig agc = (AccelGraphicsConfig)gc;
            BufferedContext bc = agc.getContext();
            if (bc != null) {
                rq = bc.getRenderQueue();
            }
        }
    }
    if (rq != null) {
        rq.lock();
        try {
            rq.flushAndInvokeNow(new Runnable() {
                public void run() {
                    doDispose(disposer);
                    Disposer.pollRemove();
                }
            });
        } finally {
            rq.unlock();
        }
    } else {
        doDispose(disposer);
    }
}
 

static void disposeStrike(final FontStrikeDisposer disposer) {
    // we need to execute the strike disposal on the rendering thread
    // because they may be accessed on that thread at the time of the
    // disposal (for example, when the accel. cache is invalidated)

    // Whilst this is a bit heavyweight, in most applications
    // strike disposal is a relatively infrequent operation, so it
    // doesn't matter. But in some tests that use vast numbers
    // of strikes, the switching back and forth is measurable.
    // So the "pollRemove" call is added to batch up the work.
    // If we are polling we know we've already been called back
    // and can directly dispose the record.
    // Also worrisome is the necessity of getting a GC here.

    if (Disposer.pollingQueue) {
        doDispose(disposer);
        return;
    }

    RenderQueue rq = null;
    GraphicsEnvironment ge =
        GraphicsEnvironment.getLocalGraphicsEnvironment();
    if (!ge.isHeadless()) {
        GraphicsConfiguration gc =
            ge.getDefaultScreenDevice().getDefaultConfiguration();
        if (gc instanceof AccelGraphicsConfig) {
            AccelGraphicsConfig agc = (AccelGraphicsConfig)gc;
            BufferedContext bc = agc.getContext();
            if (bc != null) {
                rq = bc.getRenderQueue();
            }
        }
    }
    if (rq != null) {
        rq.lock();
        try {
            rq.flushAndInvokeNow(new Runnable() {
                public void run() {
                    doDispose(disposer);
                    Disposer.pollRemove();
                }
            });
        } finally {
            rq.unlock();
        }
    } else {
        doDispose(disposer);
    }
}
 

static void disposeStrike(final FontStrikeDisposer disposer) {
    // we need to execute the strike disposal on the rendering thread
    // because they may be accessed on that thread at the time of the
    // disposal (for example, when the accel. cache is invalidated)

    // Whilst this is a bit heavyweight, in most applications
    // strike disposal is a relatively infrequent operation, so it
    // doesn't matter. But in some tests that use vast numbers
    // of strikes, the switching back and forth is measurable.
    // So the "pollRemove" call is added to batch up the work.
    // If we are polling we know we've already been called back
    // and can directly dispose the record.
    // Also worrisome is the necessity of getting a GC here.

    if (Disposer.pollingQueue) {
        doDispose(disposer);
        return;
    }

    RenderQueue rq = null;
    GraphicsEnvironment ge =
        GraphicsEnvironment.getLocalGraphicsEnvironment();
    if (!ge.isHeadless()) {
        GraphicsConfiguration gc =
            ge.getDefaultScreenDevice().getDefaultConfiguration();
        if (gc instanceof AccelGraphicsConfig) {
            AccelGraphicsConfig agc = (AccelGraphicsConfig)gc;
            BufferedContext bc = agc.getContext();
            if (bc != null) {
                rq = bc.getRenderQueue();
            }
        }
    }
    if (rq != null) {
        rq.lock();
        try {
            rq.flushAndInvokeNow(new Runnable() {
                public void run() {
                    doDispose(disposer);
                    Disposer.pollRemove();
                }
            });
        } finally {
            rq.unlock();
        }
    } else {
        doDispose(disposer);
    }
}
 

static void disposeStrike(final FontStrikeDisposer disposer) {
    // we need to execute the strike disposal on the rendering thread
    // because they may be accessed on that thread at the time of the
    // disposal (for example, when the accel. cache is invalidated)

    // Whilst this is a bit heavyweight, in most applications
    // strike disposal is a relatively infrequent operation, so it
    // doesn't matter. But in some tests that use vast numbers
    // of strikes, the switching back and forth is measurable.
    // So the "pollRemove" call is added to batch up the work.
    // If we are polling we know we've already been called back
    // and can directly dispose the record.
    // Also worrisome is the necessity of getting a GC here.

    if (Disposer.pollingQueue) {
        doDispose(disposer);
        return;
    }

    RenderQueue rq = null;
    GraphicsEnvironment ge =
        GraphicsEnvironment.getLocalGraphicsEnvironment();
    if (!ge.isHeadless()) {
        GraphicsConfiguration gc =
            ge.getDefaultScreenDevice().getDefaultConfiguration();
        if (gc instanceof AccelGraphicsConfig) {
            AccelGraphicsConfig agc = (AccelGraphicsConfig)gc;
            BufferedContext bc = agc.getContext();
            if (bc != null) {
                rq = bc.getRenderQueue();
            }
        }
    }
    if (rq != null) {
        rq.lock();
        try {
            rq.flushAndInvokeNow(new Runnable() {
                public void run() {
                    doDispose(disposer);
                    Disposer.pollRemove();
                }
            });
        } finally {
            rq.unlock();
        }
    } else {
        doDispose(disposer);
    }
}
 

static void disposeStrike(final FontStrikeDisposer disposer) {
    // we need to execute the strike disposal on the rendering thread
    // because they may be accessed on that thread at the time of the
    // disposal (for example, when the accel. cache is invalidated)

    // Whilst this is a bit heavyweight, in most applications
    // strike disposal is a relatively infrequent operation, so it
    // doesn't matter. But in some tests that use vast numbers
    // of strikes, the switching back and forth is measurable.
    // So the "pollRemove" call is added to batch up the work.
    // If we are polling we know we've already been called back
    // and can directly dispose the record.
    // Also worrisome is the necessity of getting a GC here.

    if (Disposer.pollingQueue) {
        doDispose(disposer);
        return;
    }

    RenderQueue rq = null;
    GraphicsEnvironment ge =
        GraphicsEnvironment.getLocalGraphicsEnvironment();
    if (!ge.isHeadless()) {
        GraphicsConfiguration gc =
            ge.getDefaultScreenDevice().getDefaultConfiguration();
        if (gc instanceof AccelGraphicsConfig) {
            AccelGraphicsConfig agc = (AccelGraphicsConfig)gc;
            BufferedContext bc = agc.getContext();
            if (bc != null) {
                rq = bc.getRenderQueue();
            }
        }
    }
    if (rq != null) {
        rq.lock();
        try {
            rq.flushAndInvokeNow(new Runnable() {
                public void run() {
                    doDispose(disposer);
                    Disposer.pollRemove();
                }
            });
        } finally {
            rq.unlock();
        }
    } else {
        doDispose(disposer);
    }
}
 

static void disposeStrike(final FontStrikeDisposer disposer) {
    // we need to execute the strike disposal on the rendering thread
    // because they may be accessed on that thread at the time of the
    // disposal (for example, when the accel. cache is invalidated)

    // Whilst this is a bit heavyweight, in most applications
    // strike disposal is a relatively infrequent operation, so it
    // doesn't matter. But in some tests that use vast numbers
    // of strikes, the switching back and forth is measurable.
    // So the "pollRemove" call is added to batch up the work.
    // If we are polling we know we've already been called back
    // and can directly dispose the record.
    // Also worrisome is the necessity of getting a GC here.

    if (Disposer.pollingQueue) {
        doDispose(disposer);
        return;
    }

    RenderQueue rq = null;
    GraphicsEnvironment ge =
        GraphicsEnvironment.getLocalGraphicsEnvironment();
    if (!ge.isHeadless()) {
        GraphicsConfiguration gc =
            ge.getDefaultScreenDevice().getDefaultConfiguration();
        if (gc instanceof AccelGraphicsConfig) {
            AccelGraphicsConfig agc = (AccelGraphicsConfig)gc;
            BufferedContext bc = agc.getContext();
            if (bc != null) {
                rq = bc.getRenderQueue();
            }
        }
    }
    if (rq != null) {
        rq.lock();
        try {
            rq.flushAndInvokeNow(new Runnable() {
                public void run() {
                    doDispose(disposer);
                    Disposer.pollRemove();
                }
            });
        } finally {
            rq.unlock();
        }
    } else {
        doDispose(disposer);
    }
}