- 根目录:
- drivers
- staging
- tidspbridge
- rmgr
- rmm.c
/*
* rmm.c
*
* DSP-BIOS Bridge driver support functions for TI OMAP processors.
*
* Copyright (C) 2005-2006 Texas Instruments, Inc.
*
* This package is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 as
* published by the Free Software Foundation.
*
* THIS PACKAGE IS PROVIDED ``AS IS'' AND WITHOUT ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, WITHOUT LIMITATION, THE IMPLIED
* WARRANTIES OF MERCHANTIBILITY AND FITNESS FOR A PARTICULAR PURPOSE.
*/
/*
* This memory manager provides general heap management and arbitrary
* alignment for any number of memory segments.
*
* Notes:
*
* Memory blocks are allocated from the end of the first free memory
* block large enough to satisfy the request. Alignment requirements
* are satisfied by "sliding" the block forward until its base satisfies
* the alignment specification; if this is not possible then the next
* free block large enough to hold the request is tried.
*
* Since alignment can cause the creation of a new free block - the
* unused memory formed between the start of the original free block
* and the start of the allocated block - the memory manager must free
* this memory to prevent a memory leak.
*
* Overlay memory is managed by reserving through rmm_alloc, and freeing
* it through rmm_free. The memory manager prevents DSP code/data that is
* overlayed from being overwritten as long as the memory it runs at has
* been allocated, and not yet freed.
*/
#include <linux/types.h>
#include <linux/list.h>
/* ----------------------------------- Host OS */
#include <dspbridge/host_os.h>
/* ----------------------------------- DSP/BIOS Bridge */
#include <dspbridge/dbdefs.h>
/* ----------------------------------- This */
#include <dspbridge/rmm.h>
/*
* ======== rmm_header ========
* This header is used to maintain a list of free memory blocks.
*/
struct rmm_header {
struct rmm_header *next; /* form a free memory link list */
u32 size; /* size of the free memory */
u32 addr; /* DSP address of memory block */
};
/*
* ======== rmm_ovly_sect ========
* Keeps track of memory occupied by overlay section.
*/
struct rmm_ovly_sect {
struct list_head list_elem;
u32 addr; /* Start of memory section */
u32 size; /* Length (target MAUs) of section */
s32 page; /* Memory page */
};
/*
* ======== rmm_target_obj ========
*/
struct rmm_target_obj {
struct rmm_segment *seg_tab;
struct rmm_header **free_list;
u32 num_segs;
struct list_head ovly_list; /* List of overlay memory in use */
};
static bool alloc_block(struct rmm_target_obj *target, u32 segid, u32 size,
u32 align, u32 *dsp_address);
static bool free_block(struct rmm_target_obj *target, u32 segid, u32 addr,
u32 size);
/*
* ======== rmm_alloc ========
*/
int rmm_alloc(struct rmm_target_obj *target, u32 segid, u32 size,
u32 align, u32 *dsp_address, bool reserve)
{
struct rmm_ovly_sect *sect, *prev_sect = NULL;
struct rmm_ovly_sect *new_sect;
u32 addr;
int status = 0;
if (!reserve) {
if (!alloc_block(target, segid, size, align, dsp_address)) {
status = -ENOMEM;
} else {
/* Increment the number of allocated blocks in this
* segment */
target->seg_tab[segid].number++;
}
goto func_end;
}
/* An overlay section - See if block is already in use. If not,
* insert into the list in ascending address size. */
addr = *dsp_address;
/* Find place to insert new list element. List is sorted from
* smallest to largest address. */
list_for_each_entry(sect, &target->ovly_list, list_elem) {
if (addr <= sect->addr) {
/* Check for overlap with sect */
if ((addr + size > sect->addr) || (prev_sect &&
(prev_sect->addr +
prev_sect->size >
addr))) {
status = -ENXIO;
}
break;
}
prev_sect = sect;
}
if (!status) {
/* No overlap - allocate list element for new section. */
new_sect = kzalloc(sizeof(struct rmm_ovly_sect), GFP_KERNEL);
if (new_sect == NULL) {
status = -ENOMEM;
} else {
new_sect->addr = addr;
new_sect->size = size;
new_sect->page = segid;
if (list_is_last(§->list_elem, &target->ovly_list))
/* Put new section at the end of the list */
list_add_tail(&new_sect->list_elem,
&target->ovly_list);
else
/* Put new section just before sect */
list_add_tail(&new_sect->list_elem,
§->list_elem);
}
}
func_end:
return status;
}
/*
* ======== rmm_create ========
*/
int rmm_create(struct rmm_target_obj **target_obj,
struct rmm_segment seg_tab[], u32 num_segs)
{
struct rmm_header *hptr;
struct rmm_segment *sptr, *tmp;
struct rmm_target_obj *target;
s32 i;
int status = 0;
/* Allocate DBL target object */
target = kzalloc(sizeof(struct rmm_target_obj), GFP_KERNEL);
if (target == NULL)
status = -ENOMEM;
if (status)
goto func_cont;
target->num_segs = num_segs;
if (!(num_segs > 0))
goto func_cont;
/* Allocate the memory for freelist from host's memory */
target->free_list = kzalloc(num_segs * sizeof(struct rmm_header *),
GFP_KERNEL);
if (target->free_list == NULL) {
status = -ENOMEM;
} else {
/* Allocate headers for each element on the free list */
for (i = 0; i < (s32) num_segs; i++) {
target->free_list[i] =
kzalloc(sizeof(struct rmm_header), GFP_KERNEL);
if (target->free_list[i] == NULL) {
status = -ENOMEM;
break;
}
}
/* Allocate memory for initial segment table */
target->seg_tab = kzalloc(num_segs * sizeof(struct rmm_segment),
GFP_KERNEL);
if (target->seg_tab == NULL) {
status = -ENOMEM;
} else {
/* Initialize segment table and free list */
sptr = target->seg_tab;
for (i = 0, tmp = seg_tab; num_segs > 0;
num_segs--, i++) {
*sptr = *tmp;
hptr = target->free_list[i];
hptr->addr = tmp->base;
hptr->size = tmp->length;
hptr->next = NULL;
tmp++;
sptr++;
}
}
}
func_cont:
/* Initialize overlay memory list */
if (!status)
INIT_LIST_HEAD(&target->ovly_list);
if (!status) {
*target_obj = target;
} else {
*target_obj = NULL;
if (target)
rmm_delete(target);
}
return status;
}
/*
* ======== rmm_delete ========
*/
void rmm_delete(struct rmm_target_obj *target)
{
struct rmm_ovly_sect *sect, *tmp;
struct rmm_header *hptr;
struct rmm_header *next;
u32 i;
kfree(target->seg_tab);
list_for_each_entry_safe(sect, tmp, &target->ovly_list, list_elem) {
list_del(§->list_elem);
kfree(sect);
}
if (target->free_list != NULL) {
/* Free elements on freelist */
for (i = 0; i < target->num_segs; i++) {
hptr = next = target->free_list[i];
while (next) {
hptr = next;
next = hptr->next;
kfree(hptr);
}
}
kfree(target->free_list);
}
kfree(target);
}
/*
* ======== rmm_free ========
*/
bool rmm_free(struct rmm_target_obj *target, u32 segid, u32 dsp_addr, u32 size,
bool reserved)
{
struct rmm_ovly_sect *sect, *tmp;
bool ret = false;
/*
* Free or unreserve memory.
*/
if (!reserved) {
ret = free_block(target, segid, dsp_addr, size);
if (ret)
target->seg_tab[segid].number--;
} else {
/* Unreserve memory */
list_for_each_entry_safe(sect, tmp, &target->ovly_list,
list_elem) {
if (dsp_addr == sect->addr) {
/* Remove from list */
list_del(§->list_elem);
kfree(sect);
return true;
}
}
}
return ret;
}
/*
* ======== rmm_stat ========
*/
bool rmm_stat(struct rmm_target_obj *target, enum dsp_memtype segid,
struct dsp_memstat *mem_stat_buf)
{
struct rmm_header *head;
bool ret = false;
u32 max_free_size = 0;
u32 total_free_size = 0;
u32 free_blocks = 0;
if ((u32) segid < target->num_segs) {
head = target->free_list[segid];
/* Collect data from free_list */
while (head != NULL) {
max_free_size = max(max_free_size, head->size);
total_free_size += head->size;
free_blocks++;
head = head->next;
}
/* ul_size */
mem_stat_buf->size = target->seg_tab[segid].length;
/* num_free_blocks */
mem_stat_buf->num_free_blocks = free_blocks;
/* total_free_size */
mem_stat_buf->total_free_size = total_free_size;
/* len_max_free_block */
mem_stat_buf->len_max_free_block = max_free_size;
/* num_alloc_blocks */
mem_stat_buf->num_alloc_blocks =
target->seg_tab[segid].number;
ret = true;
}
return ret;
}
/*
* ======== balloc ========
* This allocation function allocates memory from the lowest addresses
* first.
*/
static bool alloc_block(struct rmm_target_obj *target, u32 segid, u32 size,
u32 align, u32 *dsp_address)
{
struct rmm_header *head;
struct rmm_header *prevhead = NULL;
struct rmm_header *next;
u32 tmpalign;
u32 alignbytes;
u32 hsize;
u32 allocsize;
u32 addr;
alignbytes = (align == 0) ? 1 : align;
prevhead = NULL;
head = target->free_list[segid];
do {
hsize = head->size;
next = head->next;
addr = head->addr; /* alloc from the bottom */
/* align allocation */
(tmpalign = (u32) addr % alignbytes);
if (tmpalign != 0)
tmpalign = alignbytes - tmpalign;
allocsize = size + tmpalign;
if (hsize >= allocsize) { /* big enough */
if (hsize == allocsize && prevhead != NULL) {
prevhead->next = next;
kfree(head);
} else {
head->size = hsize - allocsize;
head->addr += allocsize;
}
/* free up any hole created by alignment */
if (tmpalign)
free_block(target, segid, addr, tmpalign);
*dsp_address = addr + tmpalign;
return true;
}
prevhead = head;
head = next;
} while (head != NULL);
return false;
}
/*
* ======== free_block ========
* TO DO: free_block() allocates memory, which could result in failure.
* Could allocate an rmm_header in rmm_alloc(), to be kept in a pool.
* free_block() could use an rmm_header from the pool, freeing as blocks
* are coalesced.
*/
static bool free_block(struct rmm_target_obj *target, u32 segid, u32 addr,
u32 size)
{
struct rmm_header *head;
struct rmm_header *thead;
struct rmm_header *rhead;
bool ret = true;
/* Create a memory header to hold the newly free'd block. */
rhead = kzalloc(sizeof(struct rmm_header), GFP_KERNEL);
if (rhead == NULL) {
ret = false;
} else {
/* search down the free list to find the right place for addr */
head = target->free_list[segid];
if (addr >= head->addr) {
while (head->next != NULL && addr > head->next->addr)
head = head->next;
thead = head->next;
head->next = rhead;
rhead->next = thead;
rhead->addr = addr;
rhead->size = size;
} else {
*rhead = *head;
head->next = rhead;
head->addr = addr;
head->size = size;
thead = rhead->next;
}
/* join with upper block, if possible */
if (thead != NULL && (rhead->addr + rhead->size) ==
thead->addr) {
head->next = rhead->next;
thead->size = size + thead->size;
thead->addr = addr;
kfree(rhead);
rhead = thead;
}
/* join with the lower block, if possible */
if ((head->addr + head->size) == rhead->addr) {
head->next = rhead->next;
head->size = head->size + rhead->size;
kfree(rhead);
}
}
return ret;
}