coreboot-libre-fam15h-rdimm/3rdparty/chromeec/common/shmalloc.c

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2024-03-04 11:14:53 +01:00
/*
* Copyright 2016 The Chromium OS Authors. All rights reserved.
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
/* Malloc/free memory module for Chrome EC */
#include <stdint.h>
#include "common.h"
#include "hooks.h"
#include "link_defs.h"
#include "shared_mem.h"
#include "system.h"
#include "task.h"
#include "util.h"
static struct mutex shmem_lock;
#ifndef TEST_SHMALLOC
#define set_map_bit(x)
#define TEST_GLOBAL static
#else
#define TEST_GLOBAL
#endif
/*
* At the beginning there is a single free memory chunk which includes all
* memory available in the system. It then gets fragmented/defragmented based
* on actual allocations/releases.
*/
TEST_GLOBAL struct shm_buffer *free_buf_chain;
/* At the beginning there is no allocated buffers */
TEST_GLOBAL struct shm_buffer *allocced_buf_chain;
/* The size of the biggest ever allocated buffer. */
static int max_allocated_size;
static void shared_mem_init(void)
{
/*
* Use all the RAM we can. The shared memory buffer is the last thing
* allocated from the start of RAM, so we can use everything up to the
* jump data at the end of RAM.
*/
free_buf_chain = (struct shm_buffer *)__shared_mem_buf;
free_buf_chain->next_buffer = NULL;
free_buf_chain->prev_buffer = NULL;
free_buf_chain->buffer_size = system_usable_ram_end() -
(uintptr_t)__shared_mem_buf;
}
DECLARE_HOOK(HOOK_INIT, shared_mem_init, HOOK_PRIO_FIRST);
/* Called with the mutex lock acquired. */
static void do_release(struct shm_buffer *ptr)
{
struct shm_buffer *pfb;
struct shm_buffer *top;
size_t released_size;
/* Take the buffer out of the allocated buffers chain. */
if (ptr == allocced_buf_chain) {
if (ptr->next_buffer) {
set_map_bit(BIT(20));
ptr->next_buffer->prev_buffer = NULL;
} else {
set_map_bit(BIT(21));
}
allocced_buf_chain = ptr->next_buffer;
} else {
/*
* Saninty check: verify that the buffer is in the allocated
* buffers chain.
*/
for (pfb = allocced_buf_chain->next_buffer;
pfb;
pfb = pfb->next_buffer)
if (pfb == ptr)
break;
if (!pfb)
return;
ptr->prev_buffer->next_buffer = ptr->next_buffer;
if (ptr->next_buffer) {
set_map_bit(BIT(22));
ptr->next_buffer->prev_buffer = ptr->prev_buffer;
} else {
set_map_bit(BIT(23));
}
}
/*
* Let's bring the released buffer back into the fold. Cache its size
* for quick reference.
*/
released_size = ptr->buffer_size;
if (!free_buf_chain) {
/*
* All memory had been allocated - this buffer is going to be
* the only available free space.
*/
set_map_bit(BIT(0));
free_buf_chain = ptr;
free_buf_chain->buffer_size = released_size;
free_buf_chain->next_buffer = NULL;
free_buf_chain->prev_buffer = NULL;
return;
}
if (ptr < free_buf_chain) {
/*
* Insert this buffer in the beginning of the chain, possibly
* merging it with the first buffer of the chain.
*/
pfb = (struct shm_buffer *)((uintptr_t)ptr + released_size);
if (pfb == free_buf_chain) {
set_map_bit(BIT(1));
/* Merge the two buffers. */
ptr->buffer_size = free_buf_chain->buffer_size +
released_size;
ptr->next_buffer =
free_buf_chain->next_buffer;
} else {
set_map_bit(BIT(2));
ptr->buffer_size = released_size;
ptr->next_buffer = free_buf_chain;
free_buf_chain->prev_buffer = ptr;
}
if (ptr->next_buffer) {
set_map_bit(BIT(3));
ptr->next_buffer->prev_buffer = ptr;
} else {
set_map_bit(BIT(4));
}
ptr->prev_buffer = NULL;
free_buf_chain = ptr;
return;
}
/*
* Need to merge the new free buffer into the existing chain. Find a
* spot for it, it should be above the highest address buffer which is
* still below the new one.
*/
pfb = free_buf_chain;
while (pfb->next_buffer && (pfb->next_buffer < ptr))
pfb = pfb->next_buffer;
top = (struct shm_buffer *)((uintptr_t)pfb + pfb->buffer_size);
if (top == ptr) {
/*
* The returned buffer is adjacent to an existing free buffer,
* below it, merge the two buffers.
*/
pfb->buffer_size += released_size;
/*
* Is the returned buffer the exact gap between two free
* buffers?
*/
top = (struct shm_buffer *)((uintptr_t)ptr + released_size);
if (top == pfb->next_buffer) {
/* Yes, it is. */
pfb->buffer_size += pfb->next_buffer->buffer_size;
pfb->next_buffer =
pfb->next_buffer->next_buffer;
if (pfb->next_buffer) {
set_map_bit(BIT(5));
pfb->next_buffer->prev_buffer = pfb;
} else {
set_map_bit(BIT(6));
}
}
return;
}
top = (struct shm_buffer *)((uintptr_t)ptr + released_size);
if (top == pfb->next_buffer) {
/* The new buffer is adjacent with the one right above it. */
set_map_bit(BIT(7));
ptr->buffer_size = released_size +
pfb->next_buffer->buffer_size;
ptr->next_buffer = pfb->next_buffer->next_buffer;
} else {
/* Just include the new free buffer into the chain. */
set_map_bit(BIT(8));
ptr->next_buffer = pfb->next_buffer;
ptr->buffer_size = released_size;
}
ptr->prev_buffer = pfb;
pfb->next_buffer = ptr;
if (ptr->next_buffer) {
set_map_bit(BIT(9));
ptr->next_buffer->prev_buffer = ptr;
} else {
set_map_bit(BIT(10));
}
}
/* Called with the mutex lock acquired. */
static int do_acquire(int size, struct shm_buffer **dest_ptr)
{
int headroom = 0x10000000; /* we'll never have this much. */
struct shm_buffer *pfb;
struct shm_buffer *candidate = 0;
/* To keep things simple let's align the size. */
size = (size + sizeof(int) - 1) & ~(sizeof(int) - 1);
/* And let's allocate room to fit the buffer header. */
size += sizeof(struct shm_buffer);
pfb = free_buf_chain;
while (pfb) {
if ((pfb->buffer_size >= size) &&
((pfb->buffer_size - size) < headroom)) {
/* this is a new candidate. */
headroom = pfb->buffer_size - size;
candidate = pfb;
}
pfb = pfb->next_buffer;
}
if (!candidate) {
set_map_bit(BIT(11));
return EC_ERROR_BUSY;
}
*dest_ptr = candidate;
/* Now let's take the candidate out of the free buffer chain. */
if (headroom <= sizeof(struct shm_buffer)) {
/*
* The entire buffer should be allocated, there is no need to
* re-define its tail as a new free buffer.
*/
if (candidate == free_buf_chain) {
/*
* The next buffer becomes the head of the free buffer
* chain.
*/
free_buf_chain = candidate->next_buffer;
if (free_buf_chain) {
set_map_bit(BIT(12));
free_buf_chain->prev_buffer = 0;
} else {
set_map_bit(BIT(13));
}
} else {
candidate->prev_buffer->next_buffer =
candidate->next_buffer;
if (candidate->next_buffer) {
set_map_bit(BIT(14));
candidate->next_buffer->prev_buffer =
candidate->prev_buffer;
} else {
set_map_bit(BIT(15));
}
}
return EC_SUCCESS;
}
candidate->buffer_size = size;
/* Candidate's tail becomes a new free buffer. */
pfb = (struct shm_buffer *)((uintptr_t)candidate + size);
pfb->buffer_size = headroom;
pfb->next_buffer = candidate->next_buffer;
pfb->prev_buffer = candidate->prev_buffer;
if (pfb->next_buffer) {
set_map_bit(BIT(16));
pfb->next_buffer->prev_buffer = pfb;
} else {
set_map_bit(BIT(17));
}
if (candidate == free_buf_chain) {
set_map_bit(BIT(18));
free_buf_chain = pfb;
} else {
set_map_bit(BIT(19));
pfb->prev_buffer->next_buffer = pfb;
}
return EC_SUCCESS;
}
int shared_mem_size(void)
{
struct shm_buffer *pfb;
size_t max_available = 0;
mutex_lock(&shmem_lock);
/* Find the maximum available buffer size. */
pfb = free_buf_chain;
while (pfb) {
if (pfb->buffer_size > max_available)
max_available = pfb->buffer_size;
pfb = pfb->next_buffer;
}
mutex_unlock(&shmem_lock);
/* Leave room for shmem header */
max_available -= sizeof(struct shm_buffer);
return max_available;
}
int shared_mem_acquire(int size, char **dest_ptr)
{
int rv;
struct shm_buffer *new_buf;
*dest_ptr = NULL;
if (in_interrupt_context())
return EC_ERROR_INVAL;
if (!free_buf_chain)
return EC_ERROR_BUSY;
mutex_lock(&shmem_lock);
rv = do_acquire(size, &new_buf);
if (rv == EC_SUCCESS) {
new_buf->next_buffer = allocced_buf_chain;
new_buf->prev_buffer = NULL;
if (allocced_buf_chain)
allocced_buf_chain->prev_buffer = new_buf;
allocced_buf_chain = new_buf;
*dest_ptr = (void *)(new_buf + 1);
if (size > max_allocated_size)
max_allocated_size = size;
}
mutex_unlock(&shmem_lock);
return rv;
}
void shared_mem_release(void *ptr)
{
if (in_interrupt_context())
return;
mutex_lock(&shmem_lock);
do_release((struct shm_buffer *)ptr - 1);
mutex_unlock(&shmem_lock);
}
#ifdef CONFIG_CMD_SHMEM
static int command_shmem(int argc, char **argv)
{
size_t allocated_size;
size_t free_size;
size_t max_free;
struct shm_buffer *buf;
allocated_size = free_size = max_free = 0;
mutex_lock(&shmem_lock);
for (buf = free_buf_chain; buf; buf = buf->next_buffer) {
size_t buf_room;
buf_room = buf->buffer_size;
free_size += buf_room;
if (buf_room > max_free)
max_free = buf_room;
}
for (buf = allocced_buf_chain; buf;
buf = buf->next_buffer)
allocated_size += buf->buffer_size;
mutex_unlock(&shmem_lock);
ccprintf("Total: %6d\n", allocated_size + free_size);
ccprintf("Allocated: %6d\n", allocated_size);
ccprintf("Free: %6d\n", free_size);
ccprintf("Max free buf: %6d\n", max_free);
ccprintf("Max allocated: %6d\n", max_allocated_size);
return EC_SUCCESS;
}
DECLARE_SAFE_CONSOLE_COMMAND(shmem, command_shmem,
NULL,
"Print shared memory stats");
#endif /* CONFIG_CMD_SHMEM ^^^^^^^ defined */