portable/MemMang/heap_5.c - third_party/github/FreeRTOS/FreeRTOS-Kernel - Git at Google

 /*
  * FreeRTOS Kernel <DEVELOPMENT BRANCH>
  * Copyright (C) 2021 Amazon.com, Inc. or its affiliates.  All Rights Reserved.
  *
  * SPDX-License-Identifier: MIT
  *
  * Permission is hereby granted, free of charge, to any person obtaining a copy of
  * this software and associated documentation files (the "Software"), to deal in
  * the Software without restriction, including without limitation the rights to
  * use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of
  * the Software, and to permit persons to whom the Software is furnished to do so,
  * subject to the following conditions:
  *
  * The above copyright notice and this permission notice shall be included in all
  * copies or substantial portions of the Software.
  *
  * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
  * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS
  * FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR
  * COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER
  * IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
  * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
  *
  * https://www.FreeRTOS.org
  * https://github.com/FreeRTOS
  *
  */

 /*
  * A sample implementation of pvPortMalloc() that allows the heap to be defined
  * across multiple non-contigous blocks and combines (coalescences) adjacent
  * memory blocks as they are freed.
  *
  * See heap_1.c, heap_2.c, heap_3.c and heap_4.c for alternative
  * implementations, and the memory management pages of https://www.FreeRTOS.org
  * for more information.
  *
  * Usage notes:
  *
  * vPortDefineHeapRegions() ***must*** be called before pvPortMalloc().
  * pvPortMalloc() will be called if any task objects (tasks, queues, event
  * groups, etc.) are created, therefore vPortDefineHeapRegions() ***must*** be
  * called before any other objects are defined.
  *
  * vPortDefineHeapRegions() takes a single parameter.  The parameter is an array
  * of HeapRegion_t structures.  HeapRegion_t is defined in portable.h as
  *
  * typedef struct HeapRegion
  * {
  *  uint8_t *pucStartAddress; << Start address of a block of memory that will be part of the heap.
  *  size_t xSizeInBytes;      << Size of the block of memory.
  * } HeapRegion_t;
  *
  * The array is terminated using a NULL zero sized region definition, and the
  * memory regions defined in the array ***must*** appear in address order from
  * low address to high address.  So the following is a valid example of how
  * to use the function.
  *
  * HeapRegion_t xHeapRegions[] =
  * {
  *  { ( uint8_t * ) 0x80000000UL, 0x10000 }, << Defines a block of 0x10000 bytes starting at address 0x80000000
  *  { ( uint8_t * ) 0x90000000UL, 0xa0000 }, << Defines a block of 0xa0000 bytes starting at address of 0x90000000
  *  { NULL, 0 }                << Terminates the array.
  * };
  *
  * vPortDefineHeapRegions( xHeapRegions ); << Pass the array into vPortDefineHeapRegions().
  *
  * Note 0x80000000 is the lower address so appears in the array first.
  *
  */
 #include <stdlib.h>
 #include <string.h>

 /* Defining MPU_WRAPPERS_INCLUDED_FROM_API_FILE prevents task.h from redefining
  * all the API functions to use the MPU wrappers.  That should only be done when
  * task.h is included from an application file. */
 #define MPU_WRAPPERS_INCLUDED_FROM_API_FILE

 #include "FreeRTOS.h"
 #include "task.h"

 #undef MPU_WRAPPERS_INCLUDED_FROM_API_FILE

 #if ( configSUPPORT_DYNAMIC_ALLOCATION == 0 )
     #error This file must not be used if configSUPPORT_DYNAMIC_ALLOCATION is 0
 #endif

 #ifndef configHEAP_CLEAR_MEMORY_ON_FREE
     #define configHEAP_CLEAR_MEMORY_ON_FREE    0
 #endif

 /* Block sizes must not get too small. */
 #define heapMINIMUM_BLOCK_SIZE    ( ( size_t ) ( xHeapStructSize << 1 ) )

 /* Assumes 8bit bytes! */
 #define heapBITS_PER_BYTE         ( ( size_t ) 8 )

 /* Max value that fits in a size_t type. */
 #define heapSIZE_MAX              ( ~( ( size_t ) 0 ) )

 /* Check if multiplying a and b will result in overflow. */
 #define heapMULTIPLY_WILL_OVERFLOW( a, b )    ( ( ( a ) > 0 ) && ( ( b ) > ( heapSIZE_MAX / ( a ) ) ) )

 /* Check if adding a and b will result in overflow. */
 #define heapADD_WILL_OVERFLOW( a, b )         ( ( a ) > ( heapSIZE_MAX - ( b ) ) )

 /* MSB of the xBlockSize member of an BlockLink_t structure is used to track
  * the allocation status of a block.  When MSB of the xBlockSize member of
  * an BlockLink_t structure is set then the block belongs to the application.
  * When the bit is free the block is still part of the free heap space. */
 #define heapBLOCK_ALLOCATED_BITMASK    ( ( ( size_t ) 1 ) << ( ( sizeof( size_t ) * heapBITS_PER_BYTE ) - 1 ) )
 #define heapBLOCK_SIZE_IS_VALID( xBlockSize )    ( ( ( xBlockSize ) & heapBLOCK_ALLOCATED_BITMASK ) == 0 )
 #define heapBLOCK_IS_ALLOCATED( pxBlock )        ( ( ( pxBlock->xBlockSize ) & heapBLOCK_ALLOCATED_BITMASK ) != 0 )
 #define heapALLOCATE_BLOCK( pxBlock )            ( ( pxBlock->xBlockSize ) |= heapBLOCK_ALLOCATED_BITMASK )
 #define heapFREE_BLOCK( pxBlock )                ( ( pxBlock->xBlockSize ) &= ~heapBLOCK_ALLOCATED_BITMASK )

 /*-----------------------------------------------------------*/

 /* Define the linked list structure.  This is used to link free blocks in order
  * of their memory address. */
 typedef struct A_BLOCK_LINK
 {
     struct A_BLOCK_LINK * pxNextFreeBlock; /*<< The next free block in the list. */
     size_t xBlockSize;                     /*<< The size of the free block. */
 } BlockLink_t;

 /*-----------------------------------------------------------*/

 /*
  * Inserts a block of memory that is being freed into the correct position in
  * the list of free memory blocks.  The block being freed will be merged with
  * the block in front it and/or the block behind it if the memory blocks are
  * adjacent to each other.
  */
 static void prvInsertBlockIntoFreeList( BlockLink_t * pxBlockToInsert );

 /*-----------------------------------------------------------*/

 /* The size of the structure placed at the beginning of each allocated memory
  * block must by correctly byte aligned. */
 static const size_t xHeapStructSize = ( sizeof( BlockLink_t ) + ( ( size_t ) ( portBYTE_ALIGNMENT - 1 ) ) ) & ~( ( size_t ) portBYTE_ALIGNMENT_MASK );

 /* Create a couple of list links to mark the start and end of the list. */
 static BlockLink_t xStart;
 static BlockLink_t * pxEnd = NULL;

 /* Keeps track of the number of calls to allocate and free memory as well as the
  * number of free bytes remaining, but says nothing about fragmentation. */
 static size_t xFreeBytesRemaining = 0U;
 static size_t xMinimumEverFreeBytesRemaining = 0U;
 static size_t xNumberOfSuccessfulAllocations = 0;
 static size_t xNumberOfSuccessfulFrees = 0;

 /*-----------------------------------------------------------*/

 void * pvPortMalloc( size_t xWantedSize )
 {
     BlockLink_t * pxBlock;
     BlockLink_t * pxPreviousBlock;
     BlockLink_t * pxNewBlockLink;
     void * pvReturn = NULL;
     size_t xAdditionalRequiredSize;

     /* The heap must be initialised before the first call to
      * prvPortMalloc(). */
     configASSERT( pxEnd );

     vTaskSuspendAll();
     {
         if( xWantedSize > 0 )
         {
             /* The wanted size must be increased so it can contain a BlockLink_t
              * structure in addition to the requested amount of bytes. Some
              * additional increment may also be needed for alignment. */
             xAdditionalRequiredSize = xHeapStructSize + portBYTE_ALIGNMENT - ( xWantedSize & portBYTE_ALIGNMENT_MASK );

             if( heapADD_WILL_OVERFLOW( xWantedSize, xAdditionalRequiredSize ) == 0 )
             {
                 xWantedSize += xAdditionalRequiredSize;
             }
             else
             {
                 xWantedSize = 0;
             }
         }
         else
         {
             mtCOVERAGE_TEST_MARKER();
         }

         /* Check the block size we are trying to allocate is not so large that the
          * top bit is set.  The top bit of the block size member of the BlockLink_t
          * structure is used to determine who owns the block - the application or
          * the kernel, so it must be free. */
         if( heapBLOCK_SIZE_IS_VALID( xWantedSize ) != 0 )
         {
             if( ( xWantedSize > 0 ) && ( xWantedSize <= xFreeBytesRemaining ) )
             {
                 /* Traverse the list from the start (lowest address) block until
                  * one of adequate size is found. */
                 pxPreviousBlock = &xStart;
                 pxBlock = xStart.pxNextFreeBlock;

                 while( ( pxBlock->xBlockSize < xWantedSize ) && ( pxBlock->pxNextFreeBlock != NULL ) )
                 {
                     pxPreviousBlock = pxBlock;
                     pxBlock = pxBlock->pxNextFreeBlock;
                 }

                 /* If the end marker was reached then a block of adequate size
                  * was not found. */
                 if( pxBlock != pxEnd )
                 {
                     /* Return the memory space pointed to - jumping over the
                      * BlockLink_t structure at its start. */
                     pvReturn = ( void * ) ( ( ( uint8_t * ) pxPreviousBlock->pxNextFreeBlock ) + xHeapStructSize );

                     /* This block is being returned for use so must be taken out
                      * of the list of free blocks. */
                     pxPreviousBlock->pxNextFreeBlock = pxBlock->pxNextFreeBlock;

                     /* If the block is larger than required it can be split into
                      * two. */
                     if( ( pxBlock->xBlockSize - xWantedSize ) > heapMINIMUM_BLOCK_SIZE )
                     {
                         /* This block is to be split into two.  Create a new
                          * block following the number of bytes requested. The void
                          * cast is used to prevent byte alignment warnings from the
                          * compiler. */
                         pxNewBlockLink = ( void * ) ( ( ( uint8_t * ) pxBlock ) + xWantedSize );

                         /* Calculate the sizes of two blocks split from the
                          * single block. */
                         pxNewBlockLink->xBlockSize = pxBlock->xBlockSize - xWantedSize;
                         pxBlock->xBlockSize = xWantedSize;

                         /* Insert the new block into the list of free blocks. */
                         prvInsertBlockIntoFreeList( ( pxNewBlockLink ) );
                     }
                     else
                     {
                         mtCOVERAGE_TEST_MARKER();
                     }

                     xFreeBytesRemaining -= pxBlock->xBlockSize;

                     if( xFreeBytesRemaining < xMinimumEverFreeBytesRemaining )
                     {
                         xMinimumEverFreeBytesRemaining = xFreeBytesRemaining;
                     }
                     else
                     {
                         mtCOVERAGE_TEST_MARKER();
                     }

                     /* The block is being returned - it is allocated and owned
                      * by the application and has no "next" block. */
                     heapALLOCATE_BLOCK( pxBlock );
                     pxBlock->pxNextFreeBlock = NULL;
                     xNumberOfSuccessfulAllocations++;
                 }
                 else
                 {
                     mtCOVERAGE_TEST_MARKER();
                 }
             }
             else
             {
                 mtCOVERAGE_TEST_MARKER();
             }
         }
         else
         {
             mtCOVERAGE_TEST_MARKER();
         }

         traceMALLOC( pvReturn, xWantedSize );
     }
     ( void ) xTaskResumeAll();

     #if ( configUSE_MALLOC_FAILED_HOOK == 1 )
     {
         if( pvReturn == NULL )
         {
             vApplicationMallocFailedHook();
         }
         else
         {
             mtCOVERAGE_TEST_MARKER();
         }
     }
     #endif /* if ( configUSE_MALLOC_FAILED_HOOK == 1 ) */

     return pvReturn;
 }
 /*-----------------------------------------------------------*/

 void vPortFree( void * pv )
 {
     uint8_t * puc = ( uint8_t * ) pv;
     BlockLink_t * pxLink;

     if( pv != NULL )
     {
         /* The memory being freed will have an BlockLink_t structure immediately
          * before it. */
         puc -= xHeapStructSize;

         /* This casting is to keep the compiler from issuing warnings. */
         pxLink = ( void * ) puc;

         configASSERT( heapBLOCK_IS_ALLOCATED( pxLink ) != 0 );
         configASSERT( pxLink->pxNextFreeBlock == NULL );

         if( heapBLOCK_IS_ALLOCATED( pxLink ) != 0 )
         {
             if( pxLink->pxNextFreeBlock == NULL )
             {
                 /* The block is being returned to the heap - it is no longer
                  * allocated. */
                 heapFREE_BLOCK( pxLink );
                 #if ( configHEAP_CLEAR_MEMORY_ON_FREE == 1 )
                 {
                     ( void ) memset( puc + xHeapStructSize, 0, pxLink->xBlockSize - xHeapStructSize );
                 }
                 #endif

                 vTaskSuspendAll();
                 {
                     /* Add this block to the list of free blocks. */
                     xFreeBytesRemaining += pxLink->xBlockSize;
                     traceFREE( pv, pxLink->xBlockSize );
                     prvInsertBlockIntoFreeList( ( ( BlockLink_t * ) pxLink ) );
                     xNumberOfSuccessfulFrees++;
                 }
                 ( void ) xTaskResumeAll();
             }
             else
             {
                 mtCOVERAGE_TEST_MARKER();
             }
         }
         else
         {
             mtCOVERAGE_TEST_MARKER();
         }
     }
 }
 /*-----------------------------------------------------------*/

 size_t xPortGetFreeHeapSize( void )
 {
     return xFreeBytesRemaining;
 }
 /*-----------------------------------------------------------*/

 size_t xPortGetMinimumEverFreeHeapSize( void )
 {
     return xMinimumEverFreeBytesRemaining;
 }
 /*-----------------------------------------------------------*/

 void * pvPortCalloc( size_t xNum,
                      size_t xSize )
 {
     void * pv = NULL;

     if( heapMULTIPLY_WILL_OVERFLOW( xNum, xSize ) == 0 )
     {
         pv = pvPortMalloc( xNum * xSize );

         if( pv != NULL )
         {
             ( void ) memset( pv, 0, xNum * xSize );
         }
     }

     return pv;
 }
 /*-----------------------------------------------------------*/

 static void prvInsertBlockIntoFreeList( BlockLink_t * pxBlockToInsert )
 {
     BlockLink_t * pxIterator;
     uint8_t * puc;

     /* Iterate through the list until a block is found that has a higher address
      * than the block being inserted. */
     for( pxIterator = &xStart; pxIterator->pxNextFreeBlock < pxBlockToInsert; pxIterator = pxIterator->pxNextFreeBlock )
     {
         /* Nothing to do here, just iterate to the right position. */
     }

     /* Do the block being inserted, and the block it is being inserted after
      * make a contiguous block of memory? */
     puc = ( uint8_t * ) pxIterator;

     if( ( puc + pxIterator->xBlockSize ) == ( uint8_t * ) pxBlockToInsert )
     {
         pxIterator->xBlockSize += pxBlockToInsert->xBlockSize;
         pxBlockToInsert = pxIterator;
     }
     else
     {
         mtCOVERAGE_TEST_MARKER();
     }

     /* Do the block being inserted, and the block it is being inserted before
      * make a contiguous block of memory? */
     puc = ( uint8_t * ) pxBlockToInsert;

     if( ( puc + pxBlockToInsert->xBlockSize ) == ( uint8_t * ) pxIterator->pxNextFreeBlock )
     {
         if( pxIterator->pxNextFreeBlock != pxEnd )
         {
             /* Form one big block from the two blocks. */
             pxBlockToInsert->xBlockSize += pxIterator->pxNextFreeBlock->xBlockSize;
             pxBlockToInsert->pxNextFreeBlock = pxIterator->pxNextFreeBlock->pxNextFreeBlock;
         }
         else
         {
             pxBlockToInsert->pxNextFreeBlock = pxEnd;
         }
     }
     else
     {
         pxBlockToInsert->pxNextFreeBlock = pxIterator->pxNextFreeBlock;
     }

     /* If the block being inserted plugged a gab, so was merged with the block
      * before and the block after, then it's pxNextFreeBlock pointer will have
      * already been set, and should not be set here as that would make it point
      * to itself. */
     if( pxIterator != pxBlockToInsert )
     {
         pxIterator->pxNextFreeBlock = pxBlockToInsert;
     }
     else
     {
         mtCOVERAGE_TEST_MARKER();
     }
 }
 /*-----------------------------------------------------------*/

 void vPortDefineHeapRegions( const HeapRegion_t * const pxHeapRegions )
 {
     BlockLink_t * pxFirstFreeBlockInRegion = NULL;
     BlockLink_t * pxPreviousFreeBlock;
     portPOINTER_SIZE_TYPE xAlignedHeap;
     size_t xTotalRegionSize, xTotalHeapSize = 0;
     BaseType_t xDefinedRegions = 0;
     portPOINTER_SIZE_TYPE xAddress;
     const HeapRegion_t * pxHeapRegion;

     /* Can only call once! */
     configASSERT( pxEnd == NULL );

     pxHeapRegion = &( pxHeapRegions[ xDefinedRegions ] );

     while( pxHeapRegion->xSizeInBytes > 0 )
     {
         xTotalRegionSize = pxHeapRegion->xSizeInBytes;

         /* Ensure the heap region starts on a correctly aligned boundary. */
         xAddress = ( portPOINTER_SIZE_TYPE ) pxHeapRegion->pucStartAddress;

         if( ( xAddress & portBYTE_ALIGNMENT_MASK ) != 0 )
         {
             xAddress += ( portBYTE_ALIGNMENT - 1 );
             xAddress &= ~portBYTE_ALIGNMENT_MASK;

             /* Adjust the size for the bytes lost to alignment. */
             xTotalRegionSize -= ( size_t ) ( xAddress - ( portPOINTER_SIZE_TYPE ) pxHeapRegion->pucStartAddress );
         }

         xAlignedHeap = xAddress;

         /* Set xStart if it has not already been set. */
         if( xDefinedRegions == 0 )
         {
             /* xStart is used to hold a pointer to the first item in the list of
              *  free blocks.  The void cast is used to prevent compiler warnings. */
             xStart.pxNextFreeBlock = ( BlockLink_t * ) xAlignedHeap;
             xStart.xBlockSize = ( size_t ) 0;
         }
         else
         {
             /* Should only get here if one region has already been added to the
              * heap. */
             configASSERT( pxEnd != NULL );

             /* Check blocks are passed in with increasing start addresses. */
             configASSERT( xAddress > ( size_t ) pxEnd );
         }

         /* Remember the location of the end marker in the previous region, if
          * any. */
         pxPreviousFreeBlock = pxEnd;

         /* pxEnd is used to mark the end of the list of free blocks and is
          * inserted at the end of the region space. */
         xAddress = xAlignedHeap + xTotalRegionSize;
         xAddress -= xHeapStructSize;
         xAddress &= ~( ( size_t ) portBYTE_ALIGNMENT_MASK );
         pxEnd = ( BlockLink_t * ) xAddress;
         pxEnd->xBlockSize = 0;
         pxEnd->pxNextFreeBlock = NULL;

         /* To start with there is a single free block in this region that is
          * sized to take up the entire heap region minus the space taken by the
          * free block structure. */
         pxFirstFreeBlockInRegion = ( BlockLink_t * ) xAlignedHeap;
         pxFirstFreeBlockInRegion->xBlockSize = ( size_t ) ( xAddress - ( portPOINTER_SIZE_TYPE ) pxFirstFreeBlockInRegion );
         pxFirstFreeBlockInRegion->pxNextFreeBlock = pxEnd;

         /* If this is not the first region that makes up the entire heap space
          * then link the previous region to this region. */
         if( pxPreviousFreeBlock != NULL )
         {
             pxPreviousFreeBlock->pxNextFreeBlock = pxFirstFreeBlockInRegion;
         }

         xTotalHeapSize += pxFirstFreeBlockInRegion->xBlockSize;

         /* Move onto the next HeapRegion_t structure. */
         xDefinedRegions++;
         pxHeapRegion = &( pxHeapRegions[ xDefinedRegions ] );
     }

     xMinimumEverFreeBytesRemaining = xTotalHeapSize;
     xFreeBytesRemaining = xTotalHeapSize;

     /* Check something was actually defined before it is accessed. */
     configASSERT( xTotalHeapSize );
 }
 /*-----------------------------------------------------------*/

 void vPortGetHeapStats( HeapStats_t * pxHeapStats )
 {
     BlockLink_t * pxBlock;
     size_t xBlocks = 0, xMaxSize = 0, xMinSize = portMAX_DELAY; /* portMAX_DELAY used as a portable way of getting the maximum value. */

     vTaskSuspendAll();
     {
         pxBlock = xStart.pxNextFreeBlock;

         /* pxBlock will be NULL if the heap has not been initialised.  The heap
          * is initialised automatically when the first allocation is made. */
         if( pxBlock != NULL )
         {
             while( pxBlock != pxEnd )
             {
                 /* Increment the number of blocks and record the largest block seen
                  * so far. */
                 xBlocks++;

                 if( pxBlock->xBlockSize > xMaxSize )
                 {
                     xMaxSize = pxBlock->xBlockSize;
                 }

                 /* Heap five will have a zero sized block at the end of each
                  * each region - the block is only used to link to the next
                  * heap region so it not a real block. */
                 if( pxBlock->xBlockSize != 0 )
                 {
                     if( pxBlock->xBlockSize < xMinSize )
                     {
                         xMinSize = pxBlock->xBlockSize;
                     }
                 }

                 /* Move to the next block in the chain until the last block is
                  * reached. */
                 pxBlock = pxBlock->pxNextFreeBlock;
             }
         }
     }
     ( void ) xTaskResumeAll();

     pxHeapStats->xSizeOfLargestFreeBlockInBytes = xMaxSize;
     pxHeapStats->xSizeOfSmallestFreeBlockInBytes = xMinSize;
     pxHeapStats->xNumberOfFreeBlocks = xBlocks;

     taskENTER_CRITICAL();
     {
         pxHeapStats->xAvailableHeapSpaceInBytes = xFreeBytesRemaining;
         pxHeapStats->xNumberOfSuccessfulAllocations = xNumberOfSuccessfulAllocations;
         pxHeapStats->xNumberOfSuccessfulFrees = xNumberOfSuccessfulFrees;
         pxHeapStats->xMinimumEverFreeBytesRemaining = xMinimumEverFreeBytesRemaining;
     }
     taskEXIT_CRITICAL();
 }
 /*-----------------------------------------------------------*/
	/*
	* FreeRTOS Kernel <DEVELOPMENT BRANCH>
	* Copyright (C) 2021 Amazon.com, Inc. or its affiliates. All Rights Reserved.
	*
	* SPDX-License-Identifier: MIT
	*
	* Permission is hereby granted, free of charge, to any person obtaining a copy of
	* this software and associated documentation files (the "Software"), to deal in
	* the Software without restriction, including without limitation the rights to
	* use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of
	* the Software, and to permit persons to whom the Software is furnished to do so,
	* subject to the following conditions:
	*
	* The above copyright notice and this permission notice shall be included in all
	* copies or substantial portions of the Software.
	*
	* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
	* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS
	* FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR
	* COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER
	* IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
	* CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
	*
	* https://www.FreeRTOS.org
	* https://github.com/FreeRTOS
	*
	*/

	/*
	* A sample implementation of pvPortMalloc() that allows the heap to be defined
	* across multiple non-contigous blocks and combines (coalescences) adjacent
	* memory blocks as they are freed.
	*
	* See heap_1.c, heap_2.c, heap_3.c and heap_4.c for alternative
	* implementations, and the memory management pages of https://www.FreeRTOS.org
	* for more information.
	*
	* Usage notes:
	*
	* vPortDefineHeapRegions() *must* be called before pvPortMalloc().
	* pvPortMalloc() will be called if any task objects (tasks, queues, event
	* groups, etc.) are created, therefore vPortDefineHeapRegions() *must* be
	* called before any other objects are defined.
	*
	* vPortDefineHeapRegions() takes a single parameter. The parameter is an array
	* of HeapRegion_t structures. HeapRegion_t is defined in portable.h as
	*
	* typedef struct HeapRegion
	* {
	* uint8_t *pucStartAddress; << Start address of a block of memory that will be part of the heap.
	* size_t xSizeInBytes; << Size of the block of memory.
	* } HeapRegion_t;
	*
	* The array is terminated using a NULL zero sized region definition, and the
	* memory regions defined in the array *must* appear in address order from
	* low address to high address. So the following is a valid example of how
	* to use the function.
	*
	* HeapRegion_t xHeapRegions[] =
	* {
	* { ( uint8_t * ) 0x80000000UL, 0x10000 }, << Defines a block of 0x10000 bytes starting at address 0x80000000
	* { ( uint8_t * ) 0x90000000UL, 0xa0000 }, << Defines a block of 0xa0000 bytes starting at address of 0x90000000
	* { NULL, 0 } << Terminates the array.
	* };
	*
	* vPortDefineHeapRegions( xHeapRegions ); << Pass the array into vPortDefineHeapRegions().
	*
	* Note 0x80000000 is the lower address so appears in the array first.
	*
	*/
	#include <stdlib.h>
	#include <string.h>

	/* Defining MPU_WRAPPERS_INCLUDED_FROM_API_FILE prevents task.h from redefining
	* all the API functions to use the MPU wrappers. That should only be done when
	* task.h is included from an application file. */
	#define MPU_WRAPPERS_INCLUDED_FROM_API_FILE

	#include "FreeRTOS.h"
	#include "task.h"

	#undef MPU_WRAPPERS_INCLUDED_FROM_API_FILE

	#if ( configSUPPORT_DYNAMIC_ALLOCATION == 0 )
	#error This file must not be used if configSUPPORT_DYNAMIC_ALLOCATION is 0
	#endif

	#ifndef configHEAP_CLEAR_MEMORY_ON_FREE
	#define configHEAP_CLEAR_MEMORY_ON_FREE 0
	#endif

	/* Block sizes must not get too small. */
	#define heapMINIMUM_BLOCK_SIZE ( ( size_t ) ( xHeapStructSize << 1 ) )

	/* Assumes 8bit bytes! */
	#define heapBITS_PER_BYTE ( ( size_t ) 8 )

	/* Max value that fits in a size_t type. */
	#define heapSIZE_MAX ( ~( ( size_t ) 0 ) )

	/* Check if multiplying a and b will result in overflow. */
	#define heapMULTIPLY_WILL_OVERFLOW( a, b ) ( ( ( a ) > 0 ) && ( ( b ) > ( heapSIZE_MAX / ( a ) ) ) )

	/* Check if adding a and b will result in overflow. */
	#define heapADD_WILL_OVERFLOW( a, b ) ( ( a ) > ( heapSIZE_MAX - ( b ) ) )

	/* MSB of the xBlockSize member of an BlockLink_t structure is used to track
	* the allocation status of a block. When MSB of the xBlockSize member of
	* an BlockLink_t structure is set then the block belongs to the application.
	* When the bit is free the block is still part of the free heap space. */
	#define heapBLOCK_ALLOCATED_BITMASK ( ( ( size_t ) 1 ) << ( ( sizeof( size_t ) * heapBITS_PER_BYTE ) - 1 ) )
	#define heapBLOCK_SIZE_IS_VALID( xBlockSize ) ( ( ( xBlockSize ) & heapBLOCK_ALLOCATED_BITMASK ) == 0 )
	#define heapBLOCK_IS_ALLOCATED( pxBlock ) ( ( ( pxBlock->xBlockSize ) & heapBLOCK_ALLOCATED_BITMASK ) != 0 )
	#define heapALLOCATE_BLOCK( pxBlock ) ( ( pxBlock->xBlockSize ) \|= heapBLOCK_ALLOCATED_BITMASK )
	#define heapFREE_BLOCK( pxBlock ) ( ( pxBlock->xBlockSize ) &= ~heapBLOCK_ALLOCATED_BITMASK )

	/-----------------------------------------------------------/

	/* Define the linked list structure. This is used to link free blocks in order
	* of their memory address. */
	typedef struct A_BLOCK_LINK
	{
	struct A_BLOCK_LINK * pxNextFreeBlock; /<< The next free block in the list. /
	size_t xBlockSize; /<< The size of the free block. /
	} BlockLink_t;

	/-----------------------------------------------------------/

	/*
	* Inserts a block of memory that is being freed into the correct position in
	* the list of free memory blocks. The block being freed will be merged with
	* the block in front it and/or the block behind it if the memory blocks are
	* adjacent to each other.
	*/
	static void prvInsertBlockIntoFreeList( BlockLink_t * pxBlockToInsert );

	/-----------------------------------------------------------/

	/* The size of the structure placed at the beginning of each allocated memory
	* block must by correctly byte aligned. */
	static const size_t xHeapStructSize = ( sizeof( BlockLink_t ) + ( ( size_t ) ( portBYTE_ALIGNMENT - 1 ) ) ) & ~( ( size_t ) portBYTE_ALIGNMENT_MASK );

	/* Create a couple of list links to mark the start and end of the list. */
	static BlockLink_t xStart;
	static BlockLink_t * pxEnd = NULL;

	/* Keeps track of the number of calls to allocate and free memory as well as the
	* number of free bytes remaining, but says nothing about fragmentation. */
	static size_t xFreeBytesRemaining = 0U;
	static size_t xMinimumEverFreeBytesRemaining = 0U;
	static size_t xNumberOfSuccessfulAllocations = 0;
	static size_t xNumberOfSuccessfulFrees = 0;

	/-----------------------------------------------------------/

	void * pvPortMalloc( size_t xWantedSize )
	{
	BlockLink_t * pxBlock;
	BlockLink_t * pxPreviousBlock;
	BlockLink_t * pxNewBlockLink;
	void * pvReturn = NULL;
	size_t xAdditionalRequiredSize;

	/* The heap must be initialised before the first call to
	* prvPortMalloc(). */
	configASSERT( pxEnd );

	vTaskSuspendAll();
	{
	if( xWantedSize > 0 )
	{
	/* The wanted size must be increased so it can contain a BlockLink_t
	* structure in addition to the requested amount of bytes. Some
	* additional increment may also be needed for alignment. */
	xAdditionalRequiredSize = xHeapStructSize + portBYTE_ALIGNMENT - ( xWantedSize & portBYTE_ALIGNMENT_MASK );

	if( heapADD_WILL_OVERFLOW( xWantedSize, xAdditionalRequiredSize ) == 0 )
	{
	xWantedSize += xAdditionalRequiredSize;
	}
	else
	{
	xWantedSize = 0;
	}
	}
	else
	{
	mtCOVERAGE_TEST_MARKER();
	}

	/* Check the block size we are trying to allocate is not so large that the
	* top bit is set. The top bit of the block size member of the BlockLink_t
	* structure is used to determine who owns the block - the application or
	* the kernel, so it must be free. */
	if( heapBLOCK_SIZE_IS_VALID( xWantedSize ) != 0 )
	{
	if( ( xWantedSize > 0 ) && ( xWantedSize <= xFreeBytesRemaining ) )
	{
	/* Traverse the list from the start (lowest address) block until
	* one of adequate size is found. */
	pxPreviousBlock = &xStart;
	pxBlock = xStart.pxNextFreeBlock;

	while( ( pxBlock->xBlockSize < xWantedSize ) && ( pxBlock->pxNextFreeBlock != NULL ) )
	{
	pxPreviousBlock = pxBlock;
	pxBlock = pxBlock->pxNextFreeBlock;
	}

	/* If the end marker was reached then a block of adequate size
	* was not found. */
	if( pxBlock != pxEnd )
	{
	/* Return the memory space pointed to - jumping over the
	* BlockLink_t structure at its start. */
	pvReturn = ( void * ) ( ( ( uint8_t * ) pxPreviousBlock->pxNextFreeBlock ) + xHeapStructSize );

	/* This block is being returned for use so must be taken out
	* of the list of free blocks. */
	pxPreviousBlock->pxNextFreeBlock = pxBlock->pxNextFreeBlock;

	/* If the block is larger than required it can be split into
	* two. */
	if( ( pxBlock->xBlockSize - xWantedSize ) > heapMINIMUM_BLOCK_SIZE )
	{
	/* This block is to be split into two. Create a new
	* block following the number of bytes requested. The void
	* cast is used to prevent byte alignment warnings from the
	* compiler. */
	pxNewBlockLink = ( void * ) ( ( ( uint8_t * ) pxBlock ) + xWantedSize );

	/* Calculate the sizes of two blocks split from the
	* single block. */
	pxNewBlockLink->xBlockSize = pxBlock->xBlockSize - xWantedSize;
	pxBlock->xBlockSize = xWantedSize;

	/* Insert the new block into the list of free blocks. */
	prvInsertBlockIntoFreeList( ( pxNewBlockLink ) );
	}
	else
	{
	mtCOVERAGE_TEST_MARKER();
	}

	xFreeBytesRemaining -= pxBlock->xBlockSize;

	if( xFreeBytesRemaining < xMinimumEverFreeBytesRemaining )
	{
	xMinimumEverFreeBytesRemaining = xFreeBytesRemaining;
	}
	else
	{
	mtCOVERAGE_TEST_MARKER();
	}

	/* The block is being returned - it is allocated and owned
	* by the application and has no "next" block. */
	heapALLOCATE_BLOCK( pxBlock );
	pxBlock->pxNextFreeBlock = NULL;
	xNumberOfSuccessfulAllocations++;
	}
	else
	{
	mtCOVERAGE_TEST_MARKER();
	}
	}
	else
	{
	mtCOVERAGE_TEST_MARKER();
	}
	}
	else
	{
	mtCOVERAGE_TEST_MARKER();
	}

	traceMALLOC( pvReturn, xWantedSize );
	}
	( void ) xTaskResumeAll();

	#if ( configUSE_MALLOC_FAILED_HOOK == 1 )
	{
	if( pvReturn == NULL )
	{
	vApplicationMallocFailedHook();
	}
	else
	{
	mtCOVERAGE_TEST_MARKER();
	}
	}
	#endif /* if ( configUSE_MALLOC_FAILED_HOOK == 1 ) */

	return pvReturn;
	}
	/-----------------------------------------------------------/

	void vPortFree( void * pv )
	{
	uint8_t * puc = ( uint8_t * ) pv;
	BlockLink_t * pxLink;

	if( pv != NULL )
	{
	/* The memory being freed will have an BlockLink_t structure immediately
	* before it. */
	puc -= xHeapStructSize;

	/* This casting is to keep the compiler from issuing warnings. */
	pxLink = ( void * ) puc;

	configASSERT( heapBLOCK_IS_ALLOCATED( pxLink ) != 0 );
	configASSERT( pxLink->pxNextFreeBlock == NULL );

	if( heapBLOCK_IS_ALLOCATED( pxLink ) != 0 )
	{
	if( pxLink->pxNextFreeBlock == NULL )
	{
	/* The block is being returned to the heap - it is no longer
	* allocated. */
	heapFREE_BLOCK( pxLink );
	#if ( configHEAP_CLEAR_MEMORY_ON_FREE == 1 )
	{
	( void ) memset( puc + xHeapStructSize, 0, pxLink->xBlockSize - xHeapStructSize );
	}
	#endif

	vTaskSuspendAll();
	{
	/* Add this block to the list of free blocks. */
	xFreeBytesRemaining += pxLink->xBlockSize;
	traceFREE( pv, pxLink->xBlockSize );
	prvInsertBlockIntoFreeList( ( ( BlockLink_t * ) pxLink ) );
	xNumberOfSuccessfulFrees++;
	}
	( void ) xTaskResumeAll();
	}
	else
	{
	mtCOVERAGE_TEST_MARKER();
	}
	}
	else
	{
	mtCOVERAGE_TEST_MARKER();
	}
	}
	}
	/-----------------------------------------------------------/

	size_t xPortGetFreeHeapSize( void )
	{
	return xFreeBytesRemaining;
	}
	/-----------------------------------------------------------/

	size_t xPortGetMinimumEverFreeHeapSize( void )
	{
	return xMinimumEverFreeBytesRemaining;
	}
	/-----------------------------------------------------------/

	void * pvPortCalloc( size_t xNum,
	size_t xSize )
	{
	void * pv = NULL;

	if( heapMULTIPLY_WILL_OVERFLOW( xNum, xSize ) == 0 )
	{
	pv = pvPortMalloc( xNum * xSize );

	if( pv != NULL )
	{
	( void ) memset( pv, 0, xNum * xSize );
	}
	}

	return pv;
	}
	/-----------------------------------------------------------/

	static void prvInsertBlockIntoFreeList( BlockLink_t * pxBlockToInsert )
	{
	BlockLink_t * pxIterator;
	uint8_t * puc;

	/* Iterate through the list until a block is found that has a higher address
	* than the block being inserted. */
	for( pxIterator = &xStart; pxIterator->pxNextFreeBlock < pxBlockToInsert; pxIterator = pxIterator->pxNextFreeBlock )
	{
	/* Nothing to do here, just iterate to the right position. */
	}

	/* Do the block being inserted, and the block it is being inserted after
	* make a contiguous block of memory? */
	puc = ( uint8_t * ) pxIterator;

	if( ( puc + pxIterator->xBlockSize ) == ( uint8_t * ) pxBlockToInsert )
	{
	pxIterator->xBlockSize += pxBlockToInsert->xBlockSize;
	pxBlockToInsert = pxIterator;
	}
	else
	{
	mtCOVERAGE_TEST_MARKER();
	}

	/* Do the block being inserted, and the block it is being inserted before
	* make a contiguous block of memory? */
	puc = ( uint8_t * ) pxBlockToInsert;

	if( ( puc + pxBlockToInsert->xBlockSize ) == ( uint8_t * ) pxIterator->pxNextFreeBlock )
	{
	if( pxIterator->pxNextFreeBlock != pxEnd )
	{
	/* Form one big block from the two blocks. */
	pxBlockToInsert->xBlockSize += pxIterator->pxNextFreeBlock->xBlockSize;
	pxBlockToInsert->pxNextFreeBlock = pxIterator->pxNextFreeBlock->pxNextFreeBlock;
	}
	else
	{
	pxBlockToInsert->pxNextFreeBlock = pxEnd;
	}
	}
	else
	{
	pxBlockToInsert->pxNextFreeBlock = pxIterator->pxNextFreeBlock;
	}

	/* If the block being inserted plugged a gab, so was merged with the block
	* before and the block after, then it's pxNextFreeBlock pointer will have
	* already been set, and should not be set here as that would make it point
	* to itself. */
	if( pxIterator != pxBlockToInsert )
	{
	pxIterator->pxNextFreeBlock = pxBlockToInsert;
	}
	else
	{
	mtCOVERAGE_TEST_MARKER();
	}
	}
	/-----------------------------------------------------------/

	void vPortDefineHeapRegions( const HeapRegion_t * const pxHeapRegions )
	{
	BlockLink_t * pxFirstFreeBlockInRegion = NULL;
	BlockLink_t * pxPreviousFreeBlock;
	portPOINTER_SIZE_TYPE xAlignedHeap;
	size_t xTotalRegionSize, xTotalHeapSize = 0;
	BaseType_t xDefinedRegions = 0;
	portPOINTER_SIZE_TYPE xAddress;
	const HeapRegion_t * pxHeapRegion;

	/* Can only call once! */
	configASSERT( pxEnd == NULL );

	pxHeapRegion = &( pxHeapRegions[ xDefinedRegions ] );

	while( pxHeapRegion->xSizeInBytes > 0 )
	{
	xTotalRegionSize = pxHeapRegion->xSizeInBytes;

	/* Ensure the heap region starts on a correctly aligned boundary. */
	xAddress = ( portPOINTER_SIZE_TYPE ) pxHeapRegion->pucStartAddress;

	if( ( xAddress & portBYTE_ALIGNMENT_MASK ) != 0 )
	{
	xAddress += ( portBYTE_ALIGNMENT - 1 );
	xAddress &= ~portBYTE_ALIGNMENT_MASK;

	/* Adjust the size for the bytes lost to alignment. */
	xTotalRegionSize -= ( size_t ) ( xAddress - ( portPOINTER_SIZE_TYPE ) pxHeapRegion->pucStartAddress );
	}

	xAlignedHeap = xAddress;

	/* Set xStart if it has not already been set. */
	if( xDefinedRegions == 0 )
	{
	/* xStart is used to hold a pointer to the first item in the list of
	* free blocks. The void cast is used to prevent compiler warnings. */
	xStart.pxNextFreeBlock = ( BlockLink_t * ) xAlignedHeap;
	xStart.xBlockSize = ( size_t ) 0;
	}
	else
	{
	/* Should only get here if one region has already been added to the
	* heap. */
	configASSERT( pxEnd != NULL );

	/* Check blocks are passed in with increasing start addresses. */
	configASSERT( xAddress > ( size_t ) pxEnd );
	}

	/* Remember the location of the end marker in the previous region, if
	* any. */
	pxPreviousFreeBlock = pxEnd;

	/* pxEnd is used to mark the end of the list of free blocks and is
	* inserted at the end of the region space. */
	xAddress = xAlignedHeap + xTotalRegionSize;
	xAddress -= xHeapStructSize;
	xAddress &= ~( ( size_t ) portBYTE_ALIGNMENT_MASK );
	pxEnd = ( BlockLink_t * ) xAddress;
	pxEnd->xBlockSize = 0;
	pxEnd->pxNextFreeBlock = NULL;

	/* To start with there is a single free block in this region that is
	* sized to take up the entire heap region minus the space taken by the
	* free block structure. */
	pxFirstFreeBlockInRegion = ( BlockLink_t * ) xAlignedHeap;
	pxFirstFreeBlockInRegion->xBlockSize = ( size_t ) ( xAddress - ( portPOINTER_SIZE_TYPE ) pxFirstFreeBlockInRegion );
	pxFirstFreeBlockInRegion->pxNextFreeBlock = pxEnd;

	/* If this is not the first region that makes up the entire heap space
	* then link the previous region to this region. */
	if( pxPreviousFreeBlock != NULL )
	{
	pxPreviousFreeBlock->pxNextFreeBlock = pxFirstFreeBlockInRegion;
	}

	xTotalHeapSize += pxFirstFreeBlockInRegion->xBlockSize;

	/* Move onto the next HeapRegion_t structure. */
	xDefinedRegions++;
	pxHeapRegion = &( pxHeapRegions[ xDefinedRegions ] );
	}

	xMinimumEverFreeBytesRemaining = xTotalHeapSize;
	xFreeBytesRemaining = xTotalHeapSize;

	/* Check something was actually defined before it is accessed. */
	configASSERT( xTotalHeapSize );
	}
	/-----------------------------------------------------------/

	void vPortGetHeapStats( HeapStats_t * pxHeapStats )
	{
	BlockLink_t * pxBlock;
	size_t xBlocks = 0, xMaxSize = 0, xMinSize = portMAX_DELAY; /* portMAX_DELAY used as a portable way of getting the maximum value. */

	vTaskSuspendAll();
	{
	pxBlock = xStart.pxNextFreeBlock;

	/* pxBlock will be NULL if the heap has not been initialised. The heap
	* is initialised automatically when the first allocation is made. */
	if( pxBlock != NULL )
	{
	while( pxBlock != pxEnd )
	{
	/* Increment the number of blocks and record the largest block seen
	* so far. */
	xBlocks++;

	if( pxBlock->xBlockSize > xMaxSize )
	{
	xMaxSize = pxBlock->xBlockSize;
	}

	/* Heap five will have a zero sized block at the end of each
	* each region - the block is only used to link to the next
	* heap region so it not a real block. */
	if( pxBlock->xBlockSize != 0 )
	{
	if( pxBlock->xBlockSize < xMinSize )
	{
	xMinSize = pxBlock->xBlockSize;
	}
	}

	/* Move to the next block in the chain until the last block is
	* reached. */
	pxBlock = pxBlock->pxNextFreeBlock;
	}
	}
	}
	( void ) xTaskResumeAll();

	pxHeapStats->xSizeOfLargestFreeBlockInBytes = xMaxSize;
	pxHeapStats->xSizeOfSmallestFreeBlockInBytes = xMinSize;
	pxHeapStats->xNumberOfFreeBlocks = xBlocks;

	taskENTER_CRITICAL();
	{
	pxHeapStats->xAvailableHeapSpaceInBytes = xFreeBytesRemaining;
	pxHeapStats->xNumberOfSuccessfulAllocations = xNumberOfSuccessfulAllocations;
	pxHeapStats->xNumberOfSuccessfulFrees = xNumberOfSuccessfulFrees;
	pxHeapStats->xMinimumEverFreeBytesRemaining = xMinimumEverFreeBytesRemaining;
	}
	taskEXIT_CRITICAL();
	}
	/-----------------------------------------------------------/