upstream/mercurial-mirror Files · contrib/python-zstandard/zstd/common/pool.c

phabricator: use .arcconfig for the callsign if not set locally (issue6243)...

phabricator: use .arcconfig for the callsign if not set locally (issue6243) This makes things easier for people working with more than one repository because this file can be committed to each repository. The bug report asks to read <repo>/.arcrc, but AFAICT, that file lives in ~/ and holds the credentials. And we already track an .arcconfig file. Any callsign set globally is still used if that is all that is present, but .arcconfig will override it if available. The idea behind letting the local hgrc override .arcconfig is that the developer may need to do testing against another server, and not dirty the working directory. Originally I was going to just try to read the callsign in `getrepophid()` if it wasn't present in the hg config. That works fine, but I think it also makes sense to read the URL from this file too. That would have worked less well because `readurltoken()` doesn't have access to the repo object to know where to find the file. Supplimenting the config mechanism is less magical because it reports the source and value of the properties used, and it doesn't need to read the file twice. Invalid hgrc files generally cause the program to abort. I only flagged it as a warning here because it's not our config file, not crucial to the whole program operating, and really shouldn't be corrupt in the typical case where it is checked into the repo. Differential Revision: https://phab.mercurial-scm.org/D7934

Gregory Szorc - - Load All Authors

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      /*

       * Copyright (c) 2016-present, Yann Collet, Facebook, Inc.

       * All rights reserved.

       *

       * This source code is licensed under both the BSD-style license (found in the

       * LICENSE file in the root directory of this source tree) and the GPLv2 (found

       * in the COPYING file in the root directory of this source tree).

       * You may select, at your option, one of the above-listed licenses.

       */

      /* ======   Dependencies   ======= */

      #include <stddef.h>    /* size_t */

      #include "debug.h"     /* assert */

      #include "zstd_internal.h"  /* ZSTD_malloc, ZSTD_free */

      #include "pool.h"

      /* ======   Compiler specifics   ====== */

      #if defined(_MSC_VER)

      #  pragma warning(disable : 4204)        /* disable: C4204: non-constant aggregate initializer */

      #endif

      #ifdef ZSTD_MULTITHREAD

      #include "threading.h"   /* pthread adaptation */

      /* A job is a function and an opaque argument */

      typedef struct POOL_job_s {

          POOL_function function;

          void *opaque;

      } POOL_job;

      struct POOL_ctx_s {

          ZSTD_customMem customMem;

          /* Keep track of the threads */

          ZSTD_pthread_t* threads;

          size_t threadCapacity;

          size_t threadLimit;

          /* The queue is a circular buffer */

          POOL_job *queue;

          size_t queueHead;

          size_t queueTail;

          size_t queueSize;

          /* The number of threads working on jobs */

          size_t numThreadsBusy;

          /* Indicates if the queue is empty */

          int queueEmpty;

          /* The mutex protects the queue */

          ZSTD_pthread_mutex_t queueMutex;

          /* Condition variable for pushers to wait on when the queue is full */

          ZSTD_pthread_cond_t queuePushCond;

          /* Condition variables for poppers to wait on when the queue is empty */

          ZSTD_pthread_cond_t queuePopCond;

          /* Indicates if the queue is shutting down */

          int shutdown;

      };

      /* POOL_thread() :

       * Work thread for the thread pool.

       * Waits for jobs and executes them.

       * @returns : NULL on failure else non-null.

       */

      static void* POOL_thread(void* opaque) {

          POOL_ctx* const ctx = (POOL_ctx*)opaque;

          if (!ctx) { return NULL; }

          for (;;) {

              /* Lock the mutex and wait for a non-empty queue or until shutdown */

              ZSTD_pthread_mutex_lock(&ctx->queueMutex);

              while ( ctx->queueEmpty

                  || (ctx->numThreadsBusy >= ctx->threadLimit) ) {

                  if (ctx->shutdown) {

                      /* even if !queueEmpty, (possible if numThreadsBusy >= threadLimit),

                       * a few threads will be shutdown while !queueEmpty,

                       * but enough threads will remain active to finish the queue */

                      ZSTD_pthread_mutex_unlock(&ctx->queueMutex);

                      return opaque;

                  }

                  ZSTD_pthread_cond_wait(&ctx->queuePopCond, &ctx->queueMutex);

              }

              /* Pop a job off the queue */

              {   POOL_job const job = ctx->queue[ctx->queueHead];

                  ctx->queueHead = (ctx->queueHead + 1) % ctx->queueSize;

                  ctx->numThreadsBusy++;

                  ctx->queueEmpty = ctx->queueHead == ctx->queueTail;

                  /* Unlock the mutex, signal a pusher, and run the job */

                  ZSTD_pthread_cond_signal(&ctx->queuePushCond);

                  ZSTD_pthread_mutex_unlock(&ctx->queueMutex);

                  job.function(job.opaque);

                  /* If the intended queue size was 0, signal after finishing job */

                  ZSTD_pthread_mutex_lock(&ctx->queueMutex);

                  ctx->numThreadsBusy--;

                  if (ctx->queueSize == 1) {

                      ZSTD_pthread_cond_signal(&ctx->queuePushCond);

                  }

                  ZSTD_pthread_mutex_unlock(&ctx->queueMutex);

              }

          }  /* for (;;) */

          assert(0);  /* Unreachable */

      }

      POOL_ctx* POOL_create(size_t numThreads, size_t queueSize) {

          return POOL_create_advanced(numThreads, queueSize, ZSTD_defaultCMem);

      }

      POOL_ctx* POOL_create_advanced(size_t numThreads, size_t queueSize,

                                     ZSTD_customMem customMem) {

          POOL_ctx* ctx;

          /* Check parameters */

          if (!numThreads) { return NULL; }

          /* Allocate the context and zero initialize */

          ctx = (POOL_ctx*)ZSTD_calloc(sizeof(POOL_ctx), customMem);

          if (!ctx) { return NULL; }

          /* Initialize the job queue.

           * It needs one extra space since one space is wasted to differentiate

           * empty and full queues.

           */

          ctx->queueSize = queueSize + 1;

          ctx->queue = (POOL_job*)ZSTD_malloc(ctx->queueSize * sizeof(POOL_job), customMem);

          ctx->queueHead = 0;

          ctx->queueTail = 0;

          ctx->numThreadsBusy = 0;

          ctx->queueEmpty = 1;

          {

              int error = 0;

              error |= ZSTD_pthread_mutex_init(&ctx->queueMutex, NULL);

              error |= ZSTD_pthread_cond_init(&ctx->queuePushCond, NULL);

              error |= ZSTD_pthread_cond_init(&ctx->queuePopCond, NULL);

              if (error) { POOL_free(ctx); return NULL; }

          }

          ctx->shutdown = 0;

          /* Allocate space for the thread handles */

          ctx->threads = (ZSTD_pthread_t*)ZSTD_malloc(numThreads * sizeof(ZSTD_pthread_t), customMem);

          ctx->threadCapacity = 0;

          ctx->customMem = customMem;

          /* Check for errors */

          if (!ctx->threads || !ctx->queue) { POOL_free(ctx); return NULL; }

          /* Initialize the threads */

          {   size_t i;

              for (i = 0; i < numThreads; ++i) {

                  if (ZSTD_pthread_create(&ctx->threads[i], NULL, &POOL_thread, ctx)) {

                      ctx->threadCapacity = i;

                      POOL_free(ctx);

                      return NULL;

              }   }

              ctx->threadCapacity = numThreads;

              ctx->threadLimit = numThreads;

          }

          return ctx;

      }

      /*! POOL_join() :

          Shutdown the queue, wake any sleeping threads, and join all of the threads.

      */

      static void POOL_join(POOL_ctx* ctx) {

          /* Shut down the queue */

          ZSTD_pthread_mutex_lock(&ctx->queueMutex);

          ctx->shutdown = 1;

          ZSTD_pthread_mutex_unlock(&ctx->queueMutex);

          /* Wake up sleeping threads */

          ZSTD_pthread_cond_broadcast(&ctx->queuePushCond);

          ZSTD_pthread_cond_broadcast(&ctx->queuePopCond);

          /* Join all of the threads */

          {   size_t i;

              for (i = 0; i < ctx->threadCapacity; ++i) {

                  ZSTD_pthread_join(ctx->threads[i], NULL);  /* note : could fail */

          }   }

      }

      void POOL_free(POOL_ctx *ctx) {

          if (!ctx) { return; }

          POOL_join(ctx);

          ZSTD_pthread_mutex_destroy(&ctx->queueMutex);

          ZSTD_pthread_cond_destroy(&ctx->queuePushCond);

          ZSTD_pthread_cond_destroy(&ctx->queuePopCond);

          ZSTD_free(ctx->queue, ctx->customMem);

          ZSTD_free(ctx->threads, ctx->customMem);

          ZSTD_free(ctx, ctx->customMem);

      }

      size_t POOL_sizeof(POOL_ctx *ctx) {

          if (ctx==NULL) return 0;  /* supports sizeof NULL */

          return sizeof(*ctx)

              + ctx->queueSize * sizeof(POOL_job)

              + ctx->threadCapacity * sizeof(ZSTD_pthread_t);

      }

      /* @return : 0 on success, 1 on error */

      static int POOL_resize_internal(POOL_ctx* ctx, size_t numThreads)

      {

          if (numThreads <= ctx->threadCapacity) {

              if (!numThreads) return 1;

              ctx->threadLimit = numThreads;

              return 0;

          }

          /* numThreads > threadCapacity */

          {   ZSTD_pthread_t* const threadPool = (ZSTD_pthread_t*)ZSTD_malloc(numThreads * sizeof(ZSTD_pthread_t), ctx->customMem);

              if (!threadPool) return 1;

              /* replace existing thread pool */

              memcpy(threadPool, ctx->threads, ctx->threadCapacity * sizeof(*threadPool));

              ZSTD_free(ctx->threads, ctx->customMem);

              ctx->threads = threadPool;

              /* Initialize additional threads */

              {   size_t threadId;

                  for (threadId = ctx->threadCapacity; threadId < numThreads; ++threadId) {

                      if (ZSTD_pthread_create(&threadPool[threadId], NULL, &POOL_thread, ctx)) {

                          ctx->threadCapacity = threadId;

                          return 1;

                  }   }

          }   }

          /* successfully expanded */

          ctx->threadCapacity = numThreads;

          ctx->threadLimit = numThreads;

          return 0;

      }

      /* @return : 0 on success, 1 on error */

      int POOL_resize(POOL_ctx* ctx, size_t numThreads)

      {

          int result;

          if (ctx==NULL) return 1;

          ZSTD_pthread_mutex_lock(&ctx->queueMutex);

          result = POOL_resize_internal(ctx, numThreads);

          ZSTD_pthread_cond_broadcast(&ctx->queuePopCond);

          ZSTD_pthread_mutex_unlock(&ctx->queueMutex);

          return result;

      }

      /**

       * Returns 1 if the queue is full and 0 otherwise.

       *

       * When queueSize is 1 (pool was created with an intended queueSize of 0),

       * then a queue is empty if there is a thread free _and_ no job is waiting.

       */

      static int isQueueFull(POOL_ctx const* ctx) {

          if (ctx->queueSize > 1) {

              return ctx->queueHead == ((ctx->queueTail + 1) % ctx->queueSize);

          } else {

              return (ctx->numThreadsBusy == ctx->threadLimit) ||

                     !ctx->queueEmpty;

          }

      }

      static void POOL_add_internal(POOL_ctx* ctx, POOL_function function, void *opaque)

      {

          POOL_job const job = {function, opaque};

          assert(ctx != NULL);

          if (ctx->shutdown) return;

          ctx->queueEmpty = 0;

          ctx->queue[ctx->queueTail] = job;

          ctx->queueTail = (ctx->queueTail + 1) % ctx->queueSize;

          ZSTD_pthread_cond_signal(&ctx->queuePopCond);

      }

      void POOL_add(POOL_ctx* ctx, POOL_function function, void* opaque)

      {

          assert(ctx != NULL);

          ZSTD_pthread_mutex_lock(&ctx->queueMutex);

          /* Wait until there is space in the queue for the new job */

          while (isQueueFull(ctx) && (!ctx->shutdown)) {

              ZSTD_pthread_cond_wait(&ctx->queuePushCond, &ctx->queueMutex);

          }

          POOL_add_internal(ctx, function, opaque);

          ZSTD_pthread_mutex_unlock(&ctx->queueMutex);

      }

      int POOL_tryAdd(POOL_ctx* ctx, POOL_function function, void* opaque)

      {

          assert(ctx != NULL);

          ZSTD_pthread_mutex_lock(&ctx->queueMutex);

          if (isQueueFull(ctx)) {

              ZSTD_pthread_mutex_unlock(&ctx->queueMutex);

              return 0;

          }

          POOL_add_internal(ctx, function, opaque);

          ZSTD_pthread_mutex_unlock(&ctx->queueMutex);

          return 1;

      }

      #else  /* ZSTD_MULTITHREAD  not defined */

      /* ========================== */

      /* No multi-threading support */

      /* ========================== */

      /* We don't need any data, but if it is empty, malloc() might return NULL. */

      struct POOL_ctx_s {

          int dummy;

      };

      static POOL_ctx g_ctx;

      POOL_ctx* POOL_create(size_t numThreads, size_t queueSize) {

          return POOL_create_advanced(numThreads, queueSize, ZSTD_defaultCMem);

      }

      POOL_ctx* POOL_create_advanced(size_t numThreads, size_t queueSize, ZSTD_customMem customMem) {

          (void)numThreads;

          (void)queueSize;

          (void)customMem;

          return &g_ctx;

      }

      void POOL_free(POOL_ctx* ctx) {

          assert(!ctx || ctx == &g_ctx);

          (void)ctx;

      }

      int POOL_resize(POOL_ctx* ctx, size_t numThreads) {

          (void)ctx; (void)numThreads;

          return 0;

      }

      void POOL_add(POOL_ctx* ctx, POOL_function function, void* opaque) {

          (void)ctx;

          function(opaque);

      }

      int POOL_tryAdd(POOL_ctx* ctx, POOL_function function, void* opaque) {

          (void)ctx;

          function(opaque);

          return 1;

      }

      size_t POOL_sizeof(POOL_ctx* ctx) {

          if (ctx==NULL) return 0;  /* supports sizeof NULL */

          assert(ctx == &g_ctx);

          return sizeof(*ctx);

      }

      #endif  /* ZSTD_MULTITHREAD */

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				/*
				* Copyright (c) 2016-present, Yann Collet, Facebook, Inc.
				* All rights reserved.
				*
				* This source code is licensed under both the BSD-style license (found in the
				* LICENSE file in the root directory of this source tree) and the GPLv2 (found
				* in the COPYING file in the root directory of this source tree).
				* You may select, at your option, one of the above-listed licenses.
				*/


				/* ====== Dependencies ======= */
				#include <stddef.h> /* size_t */
				#include "debug.h" /* assert */
				#include "zstd_internal.h" /* ZSTD_malloc, ZSTD_free */
				#include "pool.h"

				/* ====== Compiler specifics ====== */
				#if defined(_MSC_VER)
				# pragma warning(disable : 4204) /* disable: C4204: non-constant aggregate initializer */
				#endif


				#ifdef ZSTD_MULTITHREAD

				#include "threading.h" /* pthread adaptation */

				/* A job is a function and an opaque argument */
				typedef struct POOL_job_s {
				POOL_function function;
				void *opaque;
				} POOL_job;

				struct POOL_ctx_s {
				ZSTD_customMem customMem;
				/* Keep track of the threads */
				ZSTD_pthread_t* threads;
				size_t threadCapacity;
				size_t threadLimit;

				/* The queue is a circular buffer */
				POOL_job *queue;
				size_t queueHead;
				size_t queueTail;
				size_t queueSize;

				/* The number of threads working on jobs */
				size_t numThreadsBusy;
				/* Indicates if the queue is empty */
				int queueEmpty;

				/* The mutex protects the queue */
				ZSTD_pthread_mutex_t queueMutex;
				/* Condition variable for pushers to wait on when the queue is full */
				ZSTD_pthread_cond_t queuePushCond;
				/* Condition variables for poppers to wait on when the queue is empty */
				ZSTD_pthread_cond_t queuePopCond;
				/* Indicates if the queue is shutting down */
				int shutdown;
				};

				/* POOL_thread() :
				* Work thread for the thread pool.
				* Waits for jobs and executes them.
				* @returns : NULL on failure else non-null.
				*/
				static void* POOL_thread(void* opaque) {
				POOL_ctx* const ctx = (POOL_ctx*)opaque;
				if (!ctx) { return NULL; }
				for (;;) {
				/* Lock the mutex and wait for a non-empty queue or until shutdown */
				ZSTD_pthread_mutex_lock(&ctx->queueMutex);

				while ( ctx->queueEmpty
				\|\| (ctx->numThreadsBusy >= ctx->threadLimit) ) {
				if (ctx->shutdown) {
				/* even if !queueEmpty, (possible if numThreadsBusy >= threadLimit),
				* a few threads will be shutdown while !queueEmpty,
				* but enough threads will remain active to finish the queue */
				ZSTD_pthread_mutex_unlock(&ctx->queueMutex);
				return opaque;
				}
				ZSTD_pthread_cond_wait(&ctx->queuePopCond, &ctx->queueMutex);
				}
				/* Pop a job off the queue */
				{ POOL_job const job = ctx->queue[ctx->queueHead];
				ctx->queueHead = (ctx->queueHead + 1) % ctx->queueSize;
				ctx->numThreadsBusy++;
				ctx->queueEmpty = ctx->queueHead == ctx->queueTail;
				/* Unlock the mutex, signal a pusher, and run the job */
				ZSTD_pthread_cond_signal(&ctx->queuePushCond);
				ZSTD_pthread_mutex_unlock(&ctx->queueMutex);

				job.function(job.opaque);

				/* If the intended queue size was 0, signal after finishing job */
				ZSTD_pthread_mutex_lock(&ctx->queueMutex);
				ctx->numThreadsBusy--;
				if (ctx->queueSize == 1) {
				ZSTD_pthread_cond_signal(&ctx->queuePushCond);
				}
				ZSTD_pthread_mutex_unlock(&ctx->queueMutex);
				}
				} /* for (;;) */
				assert(0); /* Unreachable */
				}

				POOL_ctx* POOL_create(size_t numThreads, size_t queueSize) {
				return POOL_create_advanced(numThreads, queueSize, ZSTD_defaultCMem);
				}

				POOL_ctx* POOL_create_advanced(size_t numThreads, size_t queueSize,
				ZSTD_customMem customMem) {
				POOL_ctx* ctx;
				/* Check parameters */
				if (!numThreads) { return NULL; }
				/* Allocate the context and zero initialize */
				ctx = (POOL_ctx*)ZSTD_calloc(sizeof(POOL_ctx), customMem);
				if (!ctx) { return NULL; }
				/* Initialize the job queue.
				* It needs one extra space since one space is wasted to differentiate
				* empty and full queues.
				*/
				ctx->queueSize = queueSize + 1;
				ctx->queue = (POOL_job)ZSTD_malloc(ctx->queueSize sizeof(POOL_job), customMem);
				ctx->queueHead = 0;
				ctx->queueTail = 0;
				ctx->numThreadsBusy = 0;
				ctx->queueEmpty = 1;
				{
				int error = 0;
				error \|= ZSTD_pthread_mutex_init(&ctx->queueMutex, NULL);
				error \|= ZSTD_pthread_cond_init(&ctx->queuePushCond, NULL);
				error \|= ZSTD_pthread_cond_init(&ctx->queuePopCond, NULL);
				if (error) { POOL_free(ctx); return NULL; }
				}
				ctx->shutdown = 0;
				/* Allocate space for the thread handles */
				ctx->threads = (ZSTD_pthread_t)ZSTD_malloc(numThreads sizeof(ZSTD_pthread_t), customMem);
				ctx->threadCapacity = 0;
				ctx->customMem = customMem;
				/* Check for errors */
				if (!ctx->threads \|\| !ctx->queue) { POOL_free(ctx); return NULL; }
				/* Initialize the threads */
				{ size_t i;
				for (i = 0; i < numThreads; ++i) {
				if (ZSTD_pthread_create(&ctx->threads[i], NULL, &POOL_thread, ctx)) {
				ctx->threadCapacity = i;
				POOL_free(ctx);
				return NULL;
				} }
				ctx->threadCapacity = numThreads;
				ctx->threadLimit = numThreads;
				}
				return ctx;
				}

				/*! POOL_join() :
				Shutdown the queue, wake any sleeping threads, and join all of the threads.
				*/
				static void POOL_join(POOL_ctx* ctx) {
				/* Shut down the queue */
				ZSTD_pthread_mutex_lock(&ctx->queueMutex);
				ctx->shutdown = 1;
				ZSTD_pthread_mutex_unlock(&ctx->queueMutex);
				/* Wake up sleeping threads */
				ZSTD_pthread_cond_broadcast(&ctx->queuePushCond);
				ZSTD_pthread_cond_broadcast(&ctx->queuePopCond);
				/* Join all of the threads */
				{ size_t i;
				for (i = 0; i < ctx->threadCapacity; ++i) {
				ZSTD_pthread_join(ctx->threads[i], NULL); /* note : could fail */
				} }
				}

				void POOL_free(POOL_ctx *ctx) {
				if (!ctx) { return; }
				POOL_join(ctx);
				ZSTD_pthread_mutex_destroy(&ctx->queueMutex);
				ZSTD_pthread_cond_destroy(&ctx->queuePushCond);
				ZSTD_pthread_cond_destroy(&ctx->queuePopCond);
				ZSTD_free(ctx->queue, ctx->customMem);
				ZSTD_free(ctx->threads, ctx->customMem);
				ZSTD_free(ctx, ctx->customMem);
				}



				size_t POOL_sizeof(POOL_ctx *ctx) {
				if (ctx==NULL) return 0; /* supports sizeof NULL */
				return sizeof(*ctx)
				+ ctx->queueSize * sizeof(POOL_job)
				+ ctx->threadCapacity * sizeof(ZSTD_pthread_t);
				}


				/* @return : 0 on success, 1 on error */
				static int POOL_resize_internal(POOL_ctx* ctx, size_t numThreads)
				{
				if (numThreads <= ctx->threadCapacity) {
				if (!numThreads) return 1;
				ctx->threadLimit = numThreads;
				return 0;
				}
				/* numThreads > threadCapacity */
				{ ZSTD_pthread_t* const threadPool = (ZSTD_pthread_t)ZSTD_malloc(numThreads sizeof(ZSTD_pthread_t), ctx->customMem);
				if (!threadPool) return 1;
				/* replace existing thread pool */
				memcpy(threadPool, ctx->threads, ctx->threadCapacity * sizeof(*threadPool));
				ZSTD_free(ctx->threads, ctx->customMem);
				ctx->threads = threadPool;
				/* Initialize additional threads */
				{ size_t threadId;
				for (threadId = ctx->threadCapacity; threadId < numThreads; ++threadId) {
				if (ZSTD_pthread_create(&threadPool[threadId], NULL, &POOL_thread, ctx)) {
				ctx->threadCapacity = threadId;
				return 1;
				} }
				} }
				/* successfully expanded */
				ctx->threadCapacity = numThreads;
				ctx->threadLimit = numThreads;
				return 0;
				}

				/* @return : 0 on success, 1 on error */
				int POOL_resize(POOL_ctx* ctx, size_t numThreads)
				{
				int result;
				if (ctx==NULL) return 1;
				ZSTD_pthread_mutex_lock(&ctx->queueMutex);
				result = POOL_resize_internal(ctx, numThreads);
				ZSTD_pthread_cond_broadcast(&ctx->queuePopCond);
				ZSTD_pthread_mutex_unlock(&ctx->queueMutex);
				return result;
				}

				/**
				* Returns 1 if the queue is full and 0 otherwise.
				*
				* When queueSize is 1 (pool was created with an intended queueSize of 0),
				* then a queue is empty if there is a thread free _and_ no job is waiting.
				*/
				static int isQueueFull(POOL_ctx const* ctx) {
				if (ctx->queueSize > 1) {
				return ctx->queueHead == ((ctx->queueTail + 1) % ctx->queueSize);
				} else {
				return (ctx->numThreadsBusy == ctx->threadLimit) \|\|
				!ctx->queueEmpty;
				}
				}


				static void POOL_add_internal(POOL_ctx* ctx, POOL_function function, void *opaque)
				{
				POOL_job const job = {function, opaque};
				assert(ctx != NULL);
				if (ctx->shutdown) return;

				ctx->queueEmpty = 0;
				ctx->queue[ctx->queueTail] = job;
				ctx->queueTail = (ctx->queueTail + 1) % ctx->queueSize;
				ZSTD_pthread_cond_signal(&ctx->queuePopCond);
				}

				void POOL_add(POOL_ctx* ctx, POOL_function function, void* opaque)
				{
				assert(ctx != NULL);
				ZSTD_pthread_mutex_lock(&ctx->queueMutex);
				/* Wait until there is space in the queue for the new job */
				while (isQueueFull(ctx) && (!ctx->shutdown)) {
				ZSTD_pthread_cond_wait(&ctx->queuePushCond, &ctx->queueMutex);
				}
				POOL_add_internal(ctx, function, opaque);
				ZSTD_pthread_mutex_unlock(&ctx->queueMutex);
				}


				int POOL_tryAdd(POOL_ctx* ctx, POOL_function function, void* opaque)
				{
				assert(ctx != NULL);
				ZSTD_pthread_mutex_lock(&ctx->queueMutex);
				if (isQueueFull(ctx)) {
				ZSTD_pthread_mutex_unlock(&ctx->queueMutex);
				return 0;
				}
				POOL_add_internal(ctx, function, opaque);
				ZSTD_pthread_mutex_unlock(&ctx->queueMutex);
				return 1;
				}


				#else /* ZSTD_MULTITHREAD not defined */

				/* ========================== */
				/* No multi-threading support */
				/* ========================== */


				/* We don't need any data, but if it is empty, malloc() might return NULL. */
				struct POOL_ctx_s {
				int dummy;
				};
				static POOL_ctx g_ctx;

				POOL_ctx* POOL_create(size_t numThreads, size_t queueSize) {
				return POOL_create_advanced(numThreads, queueSize, ZSTD_defaultCMem);
				}

				POOL_ctx* POOL_create_advanced(size_t numThreads, size_t queueSize, ZSTD_customMem customMem) {
				(void)numThreads;
				(void)queueSize;
				(void)customMem;
				return &g_ctx;
				}

				void POOL_free(POOL_ctx* ctx) {
				assert(!ctx \|\| ctx == &g_ctx);
				(void)ctx;
				}

				int POOL_resize(POOL_ctx* ctx, size_t numThreads) {
				(void)ctx; (void)numThreads;
				return 0;
				}

				void POOL_add(POOL_ctx* ctx, POOL_function function, void* opaque) {
				(void)ctx;
				function(opaque);
				}

				int POOL_tryAdd(POOL_ctx* ctx, POOL_function function, void* opaque) {
				(void)ctx;
				function(opaque);
				return 1;
				}

				size_t POOL_sizeof(POOL_ctx* ctx) {
				if (ctx==NULL) return 0; /* supports sizeof NULL */
				assert(ctx == &g_ctx);
				return sizeof(*ctx);
				}

				#endif /* ZSTD_MULTITHREAD */