2012-09-13 08:34:43 +08:00
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mm/README.txt
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=============
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This directory contains the NuttX memory management logic. This include:
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2013-06-06 03:35:19 +08:00
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1) Standard Memory Management Functions:
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2012-09-13 08:34:43 +08:00
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2014-09-23 21:11:47 +08:00
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Standard Functions:
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2013-06-06 03:35:19 +08:00
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The standard memory management functions as prototyped in stdlib.h as
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specified in the Base definitions volume of IEEE Std 1003.1-2001. This
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include the files:
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o Standard Interfaces: mm_malloc.c, mm_calloc.c, mm_realloc.c,
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2012-09-13 08:34:43 +08:00
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mm_memalign.c, mm_free.c
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o Less-Standard Interfaces: mm_zalloc.c, mm_mallinfo.c
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o Internal Implementation: mm_initialize.c mm_sem.c mm_addfreechunk.c
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2015-12-30 21:56:56 +08:00
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mm_size2ndx.c mm_shrinkchunk.c
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o Build and Configuration files: Kconfig, Makefile
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2012-09-13 08:34:43 +08:00
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Memory Models:
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2013-06-06 03:35:19 +08:00
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o Small Memory Model. If the MCU supports only 16-bit data addressing
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then the small memory model is automatically used. The maximum size
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of the heap is then 64K. The small memory model can also be forced
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MCUs with wider addressing by defining CONFIG_SMALL_MEMORY in the
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NuttX configuration file.
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o Large Memory Model. Otherwise, the allocator uses a model that
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supports a heap of up to 4G.
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This implementation uses a variable length allocator with the following
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properties:
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o Overhead: Either 8- or 4-bytes per allocation for large and small
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models, respectively.
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o Alignment: All allocations are aligned to 8- or 4-bytes for large
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and small models, respectively.
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Multiple Heaps:
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This allocator can be used to manage multiple heaps (albeit with some
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non-standard interfaces). A heap is represented by struct mm_heap_s
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as defined in the file include/nuttx/mm/mm.h. To create another heap
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instance, you would allocate a heap structure, most likely statically
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in memory:
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2014-09-24 21:29:09 +08:00
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include <nuttx/mm/mm.h>
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static struct mm_heap_s g_myheap;
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Then initialize the heap using:
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mm_initialize(&g_myheap, myheap_start, myheap_size);
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Where mm_initialize() and all related interfaces are prototyped in the
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header file include/nuttx/mm/mm.h.
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After the new heap instance has been initialized, it can then be used
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with these almost familiar interfaces: mm_malloc(), mm_realloc(), mm_free(),
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etc. These are 'almost familiar' because they are analogous of the
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standard malloc(), realloc(), free(), etc. except that they expect a
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reference to the initialized heap structure as the first parameter.
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In fact, the standard malloc(), realloc(), free() use this same mechanism,
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but with a global heap structure called g_mmheap.
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2014-09-23 21:11:47 +08:00
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User/Kernel Heaps
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This multiple heap capability is exploited in some of the more complex NuttX
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build configurations to provide separate kernel-mode and user-mode heaps.
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Sub-Directories:
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mm/mm_heap - Holds the common base logic for all heap allocators
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mm/umm_heap - Holds the user-mode memory allocation interfaces
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mm/kmm_heap - Holds the kernel-mode memory allocation interfaces
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2) Granule Allocator.
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A non-standard granule allocator is also available in this directory The
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granule allocator allocates memory in units of a fixed sized block ("granule").
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Allocations may be aligned to a user-provided address boundary.
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2014-09-24 20:55:26 +08:00
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The granule allocator interfaces are defined in nuttx/include/nuttx/mm/gran.h.
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The granule allocator consists of these files in this directory:
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mm_gran.h, mm_granalloc.c, mm_grancritical.c, mm_granfree.c
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mm_graninit.c
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The granule allocator is not used anywhere within the base NuttX code
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as of this writing. The intent of the granule allocator is to provide
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a tool to support platform-specific management of aligned DMA memory.
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NOTE: Because each granule may be aligned and each allocation is in
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units of the granule size, selection of the granule size is important:
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Larger granules will give better performance and less overhead but more
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losses of memory due to quantization waste. Additional memory waste
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can occur from alignment; Of course, heap alignment should no be
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used unless (a) you are using the granule allocator to manage DMA memory
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and (b) your hardware has specific memory alignment requirements.
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The current implementation also restricts the maximum allocation size
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to 32 granules. That restriction could be eliminated with some
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additional coding effort, but currently requires larger granule
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sizes for larger allocations.
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General Usage Example.
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This is an example using the GCC section attribute to position a DMA
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heap in memory (logic in the linker script would assign the section
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.dmaheap to the DMA memory.
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FAR uint32_t g_dmaheap[DMAHEAP_SIZE] __attribute__((section(.dmaheap)));
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The heap is created by calling gran_initialize. Here the granule size
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is set to 64 bytes and the alignment to 16 bytes:
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GRAN_HANDLE handle = gran_initialize(g_dmaheap, DMAHEAP_SIZE, 6, 4);
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Then the GRAN_HANDLE can be used to allocate memory (There is no
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GRAN_HANDLE if CONFIG_GRAN_SINGLE=y):
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FAR uint8_t *dma_memory = (FAR uint8_t *)gran_alloc(handle, 47);
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The actual memory allocates will be 64 byte (wasting 17 bytes) and
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will be aligned at least to (1 << log2align).
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2014-09-23 21:11:47 +08:00
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Sub-Directories:
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mm/mm_gran - Holds the granule allocation logic
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3) Page Allocator
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The page allocator is an application of the granule allocator. It is a
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special purpose memory allocator intended to allocate physical memory
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pages for use with systems that have a memory management unit (MMU).
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Sub-Directories:
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mm/mm_gran - The page allocator cohabits the same directory as the
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granule allocator.
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4) Shared Memory Management
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When NuttX is build in kernel mode with a separate, privileged, kernel-
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mode address space and multiple, unprivileged, user-mode address spaces,
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then shared memory regions must also be managed. Shared memory regions
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are user-accessible memory regions that can be attached into the user
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process address space for sharing between user process.
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Sub-Directories:
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mm/shm - The shared memory logic
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The shared memory management logic has its own README file that can be
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found at nuttx/mm/shm/README.txt.
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