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/*
 * Copyright (c) 2000, 2020, Oracle and/or its affiliates.
 *
 * Licensed under the Universal Permissive License v 1.0 as shown at
 * http://oss.oracle.com/licenses/upl.
 */
package com.oracle.coherence.common.internal.io;


import com.oracle.coherence.common.base.Disposable;
import com.oracle.coherence.common.collections.ConcurrentLinkedStack;
import com.oracle.coherence.common.collections.Stack;
import com.oracle.coherence.common.io.BufferManager;
import com.oracle.coherence.common.io.BufferManagers;
import com.oracle.coherence.common.io.Buffers;
import com.oracle.coherence.common.util.Duration;
import com.oracle.coherence.common.util.MemorySize;

import java.nio.ByteOrder;
import java.util.logging.Logger;
import java.util.logging.Level;

import java.util.concurrent.atomic.AtomicInteger;
import java.util.concurrent.atomic.AtomicLong;
import java.nio.ByteBuffer;


/**
 * The SegmentedBufferManager performs buffer managment by dividing
 * the buffers into a number of segments, such as small, medium, and large.
 * 

* Each segment contains a number of generations, where generations are created * on demand and lazily collected. * * @author ch 2010.03.04 */ public class SegmentedBufferManager implements BufferManager, Disposable { // ----- constructors --------------------------------------------------- /** * Creates a SegmentedBufferManager. * * @param allocator the BufferAllocator to use to fill the pool * @param cbBufferMin the minimum buffer size * @param cbMax the total amount of memory to pool */ public SegmentedBufferManager(BufferAllocator allocator, int cbBufferMin, long cbMax) { this(allocator, DEFAULT_SEGMENT_COUNT, cbMax / DEFAULT_SEGMENT_COUNT, cbBufferMin, DEFAULT_GROWTH_FACTOR); } /** * Creates a SegmentedBufferManager. * * @param allocator the BufferAllocator to use to fill the pool * @param cbMax the total amount of memory to pool */ public SegmentedBufferManager(BufferAllocator allocator, long cbMax) { this(allocator, DEFAULT_SEGMENT_COUNT, cbMax / DEFAULT_SEGMENT_COUNT, DEFAULT_BUF_SIZE, DEFAULT_GROWTH_FACTOR); } /** * Creates a SegmentedBufferManager. * * @param allocator the BufferAllocator to use to fill the pool * @param cSegments the number of segments * @param cbSegment the maximum number bytes each segment will consume * @param cbBufferMin the smallest buffer size * @param nGrowthFactor the segment growth factor */ public SegmentedBufferManager(BufferAllocator allocator, int cSegments, long cbSegment, int cbBufferMin, int nGrowthFactor) { m_allocator = allocator; final int cbDefaultBuf = SegmentedBufferManager.DEFAULT_BUF_SIZE; cbSegment = Math.min(cbSegment, (long) Integer.MAX_VALUE * GEN_ID_UNPOOLED); // max gen size is 2GB if ((cbBufferMin & (DEFAULT_BUF_SIZE - 1)) != 0) { // ensure that the size doesn't touch our bits // TODO cbBufferMin = (cbBufferMin + DEFAULT_BUF_SIZE - 1) & ~(DEFAULT_BUF_SIZE - 1); cbBufferMin = (cbBufferMin / cbDefaultBuf) * cbDefaultBuf + (cbBufferMin % cbDefaultBuf == 0 ? 0 : cbDefaultBuf); } final int cHighestBit = Integer.SIZE - 1; final int cLowestBit = Integer.numberOfTrailingZeros(cbBufferMin); final int nMaxSegments = cHighestBit - (cLowestBit * nGrowthFactor); if (nMaxSegments < 1) { throw new IllegalArgumentException("Growthfactor is to aggressive: " + nGrowthFactor); } else if (cSegments > nMaxSegments) { throw new IllegalArgumentException("The number of segments exceeded: " + nMaxSegments); } int cbBuff = m_cbMin = cbBufferMin; Segment[] aSegment = f_aSegments = new Segment[cSegments]; for (int i = 0; i < cSegments; i++) { long cBuf = cbSegment / cbBuff; aSegment[i] = allocateSegment(cbBuff, (int) (cBuf > Integer.MAX_VALUE ? Integer.MAX_VALUE : cBuf)); cbBuff = cbBuff << nGrowthFactor; } m_cbMax = cbBuff >> nGrowthFactor; m_nSegmentGrowthFactor = nGrowthFactor; } // ----- SegmentedBufferManager interface ------------------------------- /** * Set the name of this BufferManager * * @param sName the name */ public void setName(String sName) { m_sName = sName; } /** * Return the name of this BufferManager * * @return the name */ public String getName() { return m_sName; } // ----- BufferManager interface ---------------------------------------- @Override public long getCapacity() { long cbCapacity = 0; for (Segment seg : f_aSegments) { long cbBuf = seg.getBufferSize(); long cbGen = cbBuf * seg.getGenerationSize(); cbCapacity += cbGen * GEN_ID_UNPOOLED; } return cbCapacity; } /** * {@inheritDoc} */ public ByteBuffer acquire(final int cbMin) { ByteBuffer buff = ensureMinBuffer(cbMin, Integer.MAX_VALUE); if (buff.capacity() > cbMin) { buff.limit(cbMin); } return buff; } /** * {@inheritDoc} */ public ByteBuffer acquirePref(int cbPref) { ByteBuffer buff = ensureBuffer(cbPref); if (buff.capacity() > cbPref) { buff.limit(cbPref); } return buff; } /** * {@inheritDoc} */ public ByteBuffer acquireSum(int cbSum) { return ensureBuffer(cbSum); } /** * {@inheritDoc} */ public void release(ByteBuffer buffer) { getSegment(buffer.capacity()).release(buffer); } /** * {@inheritDoc} */ public ByteBuffer truncate(ByteBuffer buff) { int nGen = decodeGeneration(buff.capacity()); return nGen < GEN_ID_TRUNCATE ? buff // common path : truncateComplex(buff); } /** * Truncate the specified buffer as described by {@link #truncate truncate}. * * @param buff the buffer to truncate * * @return the replacement buffer */ protected ByteBuffer truncateComplex(ByteBuffer buff) { int cbSeg = decodeSize(buff.capacity()); int cbSegPre = cbSeg >> m_nSegmentGrowthFactor; int cbUsed = buff.remaining(); if (cbSeg > m_cbMin && cbUsed <= cbSegPre) { // the used buffer could fit in the previous segment ByteBuffer buffNew; try { buffNew = ensureMinBuffer(/*cbMin*/ cbUsed, /*cbMax*/ cbSeg - 1); } catch (OutOfMemoryError e) { return buff; // use the original } buffNew.put(buff).flip(); release(buff); return buffNew; } return buff; } // ----- Disposable interface ------------------------------------------- /** * {@inheritDoc} */ public void dispose() { for (Segment pool : f_aSegments) { pool.dispose(); } } // ----- Object interface ------------------------------------------------ @Override public String toString() { long cbCapacity = 0; long cbUsed = 0; long cAlloc = 0; long cNonPooled = 0; long cbAvailable = 0; long cbPeakHist = 0; StringBuilder sbSeg = new StringBuilder(); for (Segment seg : f_aSegments) { long cbBuf = seg.getBufferSize(); long cbGen = cbBuf * seg.getGenerationSize(); cbAvailable += seg.f_stackBuf.size() * cbBuf; cbCapacity += cbGen * GEN_ID_UNPOOLED; cbUsed += seg.getAcquired() * cbBuf; cAlloc += seg.getAllocationCount(); cNonPooled += seg.getNonPooledAllocationCount(); cbPeakHist += seg.m_cMaxBuffersHistoric * cbBuf; // peak since last full GC sbSeg.append(seg).append(", "); } return getName() + "(capacity=" + new MemorySize(cbCapacity) + ", usage=" + new MemorySize(cbUsed) + ".." + new MemorySize(cbPeakHist) + "/" + new MemorySize(cbAvailable) + ", hit rate=" + ((cAlloc - cNonPooled) * 100/ (cAlloc == 0 ? 1 : cAlloc)) + "%" + ", segment utilization=" + sbSeg.toString() + "allocator=" + m_allocator + ")"; } // ----- helpers --------------------------------------------------------- /** * Return the allocator used by this manager. * * @return the allocator */ protected BufferAllocator getAllocator() { return m_allocator; } // ----- private members ------------------------------------------------- /** * Given a buffer allocation size, extract the generation id of that * buffer. * * @param cbBuffer the buffer allocation size * * @return the generation id */ protected int decodeGeneration(final int cbBuffer) { return (cbBuffer & GEN_ID_MASK) >> GEN_ID_SHIFT; } /** * Given an allocated buffer size, determine the configured buffer size * of that buffer. * * @param cb the allocated buffer size * * @return the configured buffer size */ private int decodeSize(final int cb) { return cb & ~GEN_ID_MASK; } /** * Return a ByteBuffer from the optimal PoolSegment for a specific count of bytes. * * @param cb the size to match * * @return the buffer */ private ByteBuffer ensureBuffer(int cb) { Segment[] aSegments = f_aSegments; int cSegments = aSegments.length; int iSeg = 0; if (cb >= m_cbMax) { iSeg = cSegments - 1; } else { for (int cbMin = m_cbMin; cb > cbMin; ++iSeg) { cb = cb >> m_nSegmentGrowthFactor; } } // try to find the closest matching segment by incrementally checking neighboring segments // this as apposed to simply looping around showed 50% performance gaines in some tests ByteBuffer buff = null; for (int i = 0; i < cSegments && buff == null; ++i) { if (iSeg + i < cSegments) { buff = aSegments[iSeg + i].acquire(/*fEnsure*/ false); } if (buff == null && i > 0 && iSeg - i >= 0) { buff = aSegments[iSeg - i].acquire(/*fEnsure*/ false); } // no space in segment; try next } // fall back on non-pooled allocation if necessary return buff == null ? aSegments[iSeg].acquire(/*fEnsure*/ true) : buff; } /** * Return a ByteBuffer of at least the specified size. * * @param cbMin the minimum required size * @param cbMax the maximum desired size * * @return the buffer */ private ByteBuffer ensureMinBuffer(int cbMin, int cbMax) { Segment[] aSegments = f_aSegments; int cSegments = aSegments.length; if (cbMin > m_cbMax) { throw new OutOfMemoryError("requested buffer size exceeds pool maximum"); } int iSeg = 0; for (int cSeg = aSegments.length; iSeg < cSeg && aSegments[iSeg].f_cbBuffer < cbMin; ++iSeg) {} for (int i = iSeg; i < cSegments; ++i) { Segment segment = aSegments[i]; if (segment.f_cbUnpooledBuffer > cbMax) { break; } ByteBuffer buf = segment.acquire(/*fEnsure*/ false); if (buf != null) { return buf; } // no space in segment; try next } // all suitable segments are full; allow non-pooled from best fit return aSegments[iSeg].acquire(/*fEnsure*/ true); } /** * Return the matching PoolSegment for a specific count of bytes. * * @param cb the size to match * * @return the PoolSegment that matches the size * * @throws IllegalArgumentException if no PoolSegment matches the size * exactly */ private Segment getSegment(int cb) throws IllegalArgumentException { Segment[] aSegments = f_aSegments; final int cbDecoded = cb = decodeSize(cb); final int cSeg = aSegments.length; int iSeg = 0; for (int cbMin = m_cbMin; cb > cbMin && iSeg < cSeg; ++iSeg) { cb = cb >> m_nSegmentGrowthFactor; } if (iSeg < cSeg && cbDecoded == aSegments[iSeg].getBufferSize()) { return aSegments[iSeg]; } throw new IllegalArgumentException("No pool segment for size: " + cbDecoded + " in " + cSeg + " segment(s) between " + aSegments[0].getBufferSize() + " .. " + aSegments[cSeg - 1].getBufferSize()); } // ----- inner class: Segment ------------------------------------------- /** * Allocate a segment for buffers of the specified size. * * @param cbBuffer the size of the individual ByteBuffers * @param cBuffers the number of ByteBuffers for the pool * * @return the allocated segment */ protected Segment allocateSegment(int cbBuffer, int cBuffers) { return new Segment(cbBuffer, cBuffers); } /** * PoolSegment defines the pools which buffers can be allocated from * and released to. The implementation provide highly concurrent access so * that elements can be acquired and released to the pool without * synchronization. *

* A PoolSegment is shrunk when its capacity remains greater than the actual * usage for a period of time. The capacity will be evaluated periodically * based on the number of buffer releases (cReevalFreq) and at * specific time (PERIODIC_CLEANUP_FREQUENCY) intervals. * When a pool shrinks, buffers that belong to purged generations will no * longer be retained when released back to the pool. */ protected class Segment implements Disposable { // ----- constructors--------------------------------------------- /** * Construct a pool for buffers of the specified size. * * @param cbBuffer the size of the individual ByteBuffers * @param cBuffers the number of ByteBuffers for the pool */ protected Segment(int cbBuffer, int cBuffers) { f_cbBuffer = cbBuffer; // COH-4231: there should be at least one buffer per generation f_cBufferGen = Math.max(cBuffers / GEN_ID_UNPOOLED, 1); f_stackBuf = new ConcurrentLinkedStack(); f_cGeneration = new AtomicInteger(GEN_ID_EMPTY); f_cReleased = new AtomicLong(0L); f_cNonPooledReleased = new AtomicLong(0L); f_cAcquired = new AtomicLong(0L); f_cNonPooledAllocations = new AtomicLong(0L); f_cbUnpooledBuffer = encodeGeneration(GEN_ID_UNPOOLED); } // ----- public methods ------------------------------------------ /** * Acquire the next available buffer from the pool. If the pool is * empty, either grow the pool or as the last resort return a * non-pooled buffer. * * @return a ByteBuffer */ public ByteBuffer acquire() { return acquire(/*fEnsure*/ true); } /** * Acquire the next available buffer from the pool. If the pool is * empty, either grow the pool or as the last resort return a * non-pooled buffer. * * @param fEnsure true iff non-pooled allocation is allowable * * @return a ByteBuffer or null if fEnsure == false and no suitable buffer is available */ public ByteBuffer acquire(boolean fEnsure) { // optimized for most common scenario: there's something in the pool // (otherwise it wouldn't be a pool) ByteBuffer buffer = f_stackBuf.pop(); if (buffer == null) { buffer = acquireComplex(fEnsure); if (buffer == null) { return null; } } f_cAcquired.incrementAndGet(); return buffer; } /** * Return true iff the segment is currently allowed to shrink * * @return true iff the segment is currently allowed to shrink */ protected boolean isShrinkable() { return true; } /** * Release a buffer back to the pool, and occasionally check if it is * possible to shrink the pool. * * @param buffer the buffer to release */ public void release(ByteBuffer buffer) { int nGeneration = decodeGeneration(buffer.capacity()); if ((f_cReleased.incrementAndGet() & STATS_FREQUENCY) == 0) { recordUsage(); evaluateCapacity(/*fOthers*/ true); } if (nGeneration == GEN_ID_UNPOOLED && f_cNonPooledReleased.incrementAndGet() % UNPOOLED_RECLAIM_INTERVAL != 0 && // only for so long f_stackBuf.size() < f_cBufferGen * GEN_ID_TRUNCATE) // only so much { // we've been given an unpooled buffer to release, which indicates that at some "recent" point // we were out of pool buffers and had to allocate an unpooled one which is expensive. If this // happens frequently then either the pool is undersized or the application has a leak. In // the case of a leak, overtime it could completely drain the pool of poolable buffers, which // if not refilled would entirely negate the pooling benefits. In an effort to avoid penalizing // good shared pool users we will allow pooling of the "unpooled" buffers, but not all of them. // But we do limit the number of re-uses so that if there is no leak we won't overinflate our // pool. Also we don't allow ourselves to hold unpooled buffers if the pool is fairly full --nGeneration; // treat it like the max gen, so it may still be released now if pool has "shrunk" } // always store in default java byte order BIG_ENDIAN // so that acquired buffers are as good as freshly allocated // ones. buffer.order(ByteOrder.BIG_ENDIAN).clear(); // just resets position and limit if (BufferManagers.ZERO_ON_RELEASE) { Buffers.zero(buffer); } // Release the buffer back into the pool if: // 1) buffer is not of the non-pooled generation // 2) buffer belongs to a generation that is less or equal to the // current generation // 3) the current generation is 'LOCKED' (meaning at least one // other thread is in need of a buffer, or is shrinking // capacity at this instant) final int cCurrentGen = getGenerationId(); if (nGeneration <= cCurrentGen || (cCurrentGen == GEN_ID_LOCKED && nGeneration != GEN_ID_UNPOOLED) || !isShrinkable()) { f_stackBuf.push(buffer); } else { dropBuffer(buffer); } } /** * Release the specified buffer from the segment. * * @param buffer the buffer */ protected void dropBuffer(ByteBuffer buffer) { m_allocator.release(buffer); } // ----- Disposable implementation ------------------------------ /** * {@inheritDoc} */ public void dispose() { trim(0); } // ----- accessors ---------------------------------------------- /** * Get the default size of buffers in this pool. Note that the * actual size of buffers may be larger, since each generation's * size is incrementally larger to differentiate it from other * generations. * * @return the default size of the buffers in this pool */ public int getBufferSize() { return f_cbBuffer; } /** * Get the number of buffers that are allocated per generation. * * @return the number of buffers in each generation */ public int getGenerationSize() { return f_cBufferGen; } // ----- private accessors -------------------------------------- /** * Get the current number of generations for this pool. * * @return the number of generations for this pool */ private int getGenerationId() { return f_cGeneration.get(); } /** * Return the number of currently acquired buffers. * * @return the number of currently acquired buffers */ protected int getAcquired() { return Math.max(0, (int) (f_cAcquired.get() - f_cReleased.get())); } /** * Return the number of allocations performed on this segment. * * @return the number of allocations performed on this segment */ private long getAllocationCount() { return f_cAcquired.get(); } /** * Return the number of releases performed on this segment. * * @return the number of releases performed on this segment */ private long getReleaseCount() { return f_cReleased.get(); } /** * Return the number of non-pooled allocations performed on this segment. * * @return the number of non-pooled allocations performed on this segment */ private long getNonPooledAllocationCount() { return f_cNonPooledAllocations.get(); } // ----- internal --------------------------------------------------- /** * Return a buffer, potentially grow the PoolSegment or returning a non * pooled buffer. * * @param fEnsure true if a non-pooled buffer should be allocated if necessary * * @return a buffer */ protected ByteBuffer acquireComplex(boolean fEnsure) { final AtomicInteger atomicGen = f_cGeneration; while (true) { // we poll after obtaining cGen to avoid accidently growing by // two generations int cGen = atomicGen.get(); ByteBuffer buffer = f_stackBuf.pop(); if (buffer != null) { return buffer; } switch (cGen) { case GEN_ID_UNPOOLED - 1: // no more generations; allocate a "throw away" buffer return fEnsure ? allocateNonPooledBuffer() : null; case GEN_ID_LOCKED: // this spin is limited as it will end once there are // available buffers in the queue break; case GEN_ID_EMPTY: // fall through default: // attempt to allocate a generation if (atomicGen.compareAndSet(cGen, GEN_ID_LOCKED)) { int nGen = cGen + 1; boolean fSuccess = false; try { // allocate an entire generation recordUsage(); fSuccess = allocateGeneration(nGen); } finally { atomicGen.set(fSuccess ? nGen : cGen); } } // else spin to obtain growth lock break; } } } /** * Allocate a new buffer which will not be returned to the pool * after it has been released. * * @return a buffer that will not be pooled when it is released */ protected ByteBuffer allocateNonPooledBuffer() { f_cNonPooledAllocations.incrementAndGet(); return m_allocator.allocate(f_cbUnpooledBuffer); } /** * Allocate a generation of ByteBuffers. * * @param nGeneration the generation id of the block * * @return true iff the generation was successfully allocated */ protected boolean allocateGeneration(int nGeneration) { int cbBuffer = encodeGeneration(nGeneration); LOGGER.log(Level.FINE, getName() + " growing segment '" + getBufferSize() + "' to " + (nGeneration + 1) + " generations"); // record when this happened (do this first so we won't bother // checking the capacity to see if it needs to shrink on another // thread) m_ldtNextEvaluation = System.currentTimeMillis() + CLEANUP_FREQUENCY_MILLIS; try { return allocateGenerationBuffers(nGeneration, cbBuffer); } catch (OutOfMemoryError e) { return false; } } /** * Allocate a series of buffers. * * @param nGen the generation id * @param cbBuffer the size of each buffer * * @return true iff the generation was allocated */ protected boolean allocateGenerationBuffers(int nGen, int cbBuffer) { for (int i = 0, c = getGenerationSize(); i < c; ++i) { try { f_stackBuf.push(m_allocator.allocate(cbBuffer)); } catch (OutOfMemoryError e) { return i > 0; // return true if any buffers for this generation were allocated } } return true; } /** * Evaluate if and how much the pool should shrink. If the capacity * is twice the amount needed in the pool. The pool will be cut in * half. * * @param fEvalPeers true if all segments should be evaluated */ private void evaluateCapacity(final boolean fEvalPeers) { final long ldtNow = System.currentTimeMillis(); final int nGen = getGenerationId(); if (nGen > GEN_ID_EMPTY && ldtNow > m_ldtNextEvaluation && f_cGeneration.compareAndSet(nGen, GEN_ID_LOCKED)) { // record next check time m_ldtNextEvaluation = ldtNow + CLEANUP_FREQUENCY_MILLIS; int nDesiredGen = nGen; try { if (isShrinkable()) { int nInUse = nGen - (f_stackBuf.size() / f_cBufferGen); // we certainly need whatever the app is currently using int nRecent = GEN_ID_EMPTY + (m_cMaxBuffers / f_cBufferGen) + (m_cMaxBuffers % f_cBufferGen == 0 ? 0 : 1); // recent high water mark nDesiredGen = Math.min(nGen, Math.max(nInUse, nRecent)); int cCapacity = Math.min(nGen + 1, GEN_ID_UNPOOLED); if (nDesiredGen == GEN_ID_EMPTY || (nDesiredGen < cCapacity && nDesiredGen != nGen)) { m_cMaxBuffersHistoric = m_cMaxBuffers; LOGGER.log(Level.FINE, getName() + " shrinking segment '" + getBufferSize() + "' by " + (nGen - nDesiredGen) + " generation(s) to " + (nDesiredGen + 1) + ", based on recent high water mark of " + new MemorySize(m_cMaxBuffers * f_cbBuffer)); // since we hand out buffers in LIFO order we must actively trim buffers now; rather then // let them bleed off over time otherwise we could hold them "forever" int cTrimmed = trim(nDesiredGen); LOGGER.log(Level.FINEST, getName() + " scavenged " + cTrimmed + " buffers; " + new MemorySize(f_cbBuffer * cTrimmed)); } } if (fEvalPeers) { for (Segment pool : SegmentedBufferManager.this.f_aSegments) { if (pool != this) { pool.evaluateCapacity(/*fOthers*/ false); } } } } finally { m_cMaxBuffers /= 2; // don't completely blow out stats f_cGeneration.set(nDesiredGen); } } } /** * Record the current buffer usage. */ private void recordUsage() { m_cMaxBuffers = Math.max(m_cMaxBuffers, getAcquired()); m_cMaxBuffersHistoric = Math.max(m_cMaxBuffersHistoric, m_cMaxBuffers); } /** * Release the buffers from later generations. * * @param nGeneration the minimum generation to retain * * @return the number of trimmed buffers */ private int trim(final int nGeneration) { int cbCutoff = encodeGeneration(nGeneration + 1); int cRemove = 0; // in case the application has a leak, and we've been replenishing the // pool with "unpoolable" buffers, refuse to reclaim all of them ConcurrentLinkedStack stackTmp = new ConcurrentLinkedStack(); for (ByteBuffer buf = f_stackBuf.pop(); buf != null; buf = f_stackBuf.pop()) { if (buf.capacity() >= cbCutoff) { ++cRemove; dropBuffer(buf); } else { stackTmp.push(buf); } } for (ByteBuffer buf : stackTmp) { f_stackBuf.push(buf); } return cRemove; } /** * Return the buffer allocation size for a given generation. * * @param nGenId the generation id *= * @return the buffer allocation size */ protected int encodeGeneration(final int nGenId) { return getBufferSize() | (nGenId << GEN_ID_SHIFT); } @Override public String toString() { return new MemorySize(f_cbBuffer).toString() + "(" + (getAcquired() * 100) / (f_cBufferGen * GEN_ID_UNPOOLED) + "%)"; } // ----- constants ---------------------------------------------- /** * Generation id that indicates that the segment has yet to be initialized. */ private static final int GEN_ID_EMPTY = -1; /** * Generation id that indicates that the generation lock has been * taken, which means that a thread is either growing or shrinking * the pool. */ private static final int GEN_ID_LOCKED = -2; // ----- data members-------------------------------------------- /** * The configured size of the buffers in the pool. */ protected final int f_cbBuffer; /** * The number of buffers allocated in a generation. */ protected final int f_cBufferGen; /** * The stack which pools all the buffers that are not acquired. *

* Maintained as a stack improves performance especially for the RDMA extended allocator as * keys for recently used buffers may still be in the HCA cache. */ protected final Stack f_stackBuf; /** * The current generation id. This is a counter that starts at zero * and goes up to GEN_ID_UNPOOLED. Buffers that belong to * generation id zero through (GEN_ID_UNPOOLED - 1) may be * pooled, and buffers that belong to generation id * GEN_ID_UNPOOLED are never pooled. By altering the * current generation id, only buffers of that (or older) generation * are returned to the pool when they are released. */ protected final AtomicInteger f_cGeneration; /** * The next the segment should be evaluated for shrinkage. */ private volatile long m_ldtNextEvaluation; /** * This is the count of pooled buffers that have been handed out by * this pool. */ protected final AtomicLong f_cAcquired; /** * The count of non-pooled allocations. */ protected final AtomicLong f_cNonPooledAllocations; /** * This is the count of buffers that have been released back to this * pool. */ protected final AtomicLong f_cReleased; /** * The count of the number of unpooled releases. */ protected final AtomicLong f_cNonPooledReleased; /** * The size of a non-pooled buffer. Since the size of a buffer * indicates its generation id, we pre-calculate the size of the * generation of buffers that are not pooled. */ protected final int f_cbUnpooledBuffer; /** * The peak recorded sample usage during the pending cleanup interval. */ private int m_cMaxBuffers; /** * The peak recorded sample usage since the last shrinkage. */ private int m_cMaxBuffersHistoric; } // ----- inner class: BufferAllocator ----------------------------------- /** * A BufferAllocator is provides a mean for allocating ByteBuffers. */ public interface BufferAllocator { /** * Allocate and return buffer of the specified size. * * @param cb the required buffer size * * @return the buffer * * @throws OutOfMemoryError if the request cannot be satisified */ public ByteBuffer allocate(int cb); /** * Release a ByteBuffer back to the allocator. * * @param buff the buffer to release */ public void release(ByteBuffer buff); } // ----- constants ------------------------------------------------------ /** * The generation id is stored in bits 6-9 (bits 0-5 are reserved to * enforce a 64 byte paragraph boundary). */ private static final int GEN_ID_SHIFT = 6; /** * The number of bits reserved to store the generation id. */ protected static final int GEN_ID_BITS = 4; /** * The bit mask of the bits used to store the generation id inside a size. */ private static final int GEN_ID_MASK = ((1 << GEN_ID_BITS) - 1) << GEN_ID_SHIFT; /** * The ID of the generation that is freely allocated and un-pooled. In * other words, when we reach this generation, the buffers that are * allocated will not be returned to the pool when they are released. */ protected static final int GEN_ID_UNPOOLED = (1 << GEN_ID_BITS) - 1; /** * The ID of the first generation at which truncation will be considered necessary. * Exempting lower generations from truncation allows for the truncate logic to very * efficiently avoid truncating buffers when there is significant space available * within the segment. */ private static final int GEN_ID_TRUNCATE = (GEN_ID_UNPOOLED * 2) / 3; /** * The number of times an unpooled buffer is reused before being released. */ public static final long UNPOOLED_RECLAIM_INTERVAL = 1024; /** * The default release frequency at which to records statistics. * * Note this value must be a power of two - 1. */ public static final int STATS_FREQUENCY = 255; /** * The default size of the smallest ByteBuffer. Note that the actual size * of the ByteBuffer may be larger, since the size includes an implicit * generation ID. Also note that the default buffer size cannot use any of * the bits 0-9. */ public static final int DEFAULT_BUF_SIZE = 1 << (GEN_ID_BITS + GEN_ID_SHIFT); // 1024 /** * The growth factor between each pool segment. The factor describes the * number of left shifts. */ public static final short DEFAULT_GROWTH_FACTOR = 1; /** * The default number of segments. */ public static final int DEFAULT_SEGMENT_COUNT = 7; // sufficiently large to allow for 1KB..64KB segments, covering standard MTU sizes /** * Reevaluation of capacity does not occur more than once every * period, as defined here. Furthermore, reevaluation of one pool * (i.e. a pool of one buffer size) will ensure that the other pools * (i.e. the pools that hold buffers of the other sizes) have also * reevaluated, since it is possible that they have no activity that * would cause them to reevaluate on their own. */ protected static final long CLEANUP_FREQUENCY_MILLIS = new Duration(System.getProperty( SegmentedBufferManager.class.getName() + ".cleanup.frequency", "1s")).as(Duration.Magnitude.MILLI); /** * The logger. */ protected static final Logger LOGGER = Logger.getLogger( SegmentedBufferManager.class.getName()); // ----- data members --------------------------------------------------- /** * The BufferAllocator to use to grow the pool. */ private final BufferAllocator m_allocator; /** * The pool is composed of several sub-ordinate pools represented by the * PoolSegment inner class, each of a specific allocation size. This array * holds the various PoolSegment instances, starting with the smallest * allocation size and proceeding to the largest. */ private final Segment[] f_aSegments; /** * The buffer size of the smallest buffer. */ private final int m_cbMin; /** * The buffer size of the largest buffer. */ private final int m_cbMax; /** * The segment growth factor. */ private final int m_nSegmentGrowthFactor; /** * The name of the allocator */ protected String m_sName = getClass().getSimpleName() + "(" + System.identityHashCode(this) + ")"; }





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