drm/linux-core/xgi_pcie.c

1021 lines
28 KiB
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2007-06-26 14:10:30 -06:00
/****************************************************************************
* Copyright (C) 2003-2006 by XGI Technology, Taiwan.
* *
* All Rights Reserved. *
* *
* 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 on 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 (including the
* next paragraph) 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
* NON-INFRINGEMENT. IN NO EVENT SHALL XGI AND/OR
* ITS SUPPLIERS 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.
***************************************************************************/
#include "xgi_types.h"
#include "xgi_linux.h"
#include "xgi_drv.h"
#include "xgi_regs.h"
#include "xgi_pcie.h"
#include "xgi_misc.h"
static xgi_pcie_heap_t *xgi_pcie_heap = NULL;
static kmem_cache_t *xgi_pcie_cache_block = NULL;
static xgi_pcie_block_t *xgi_pcie_vertex_block = NULL;
static xgi_pcie_block_t *xgi_pcie_cmdlist_block = NULL;
static xgi_pcie_block_t *xgi_pcie_scratchpad_block = NULL;
extern struct list_head xgi_mempid_list;
static unsigned long xgi_pcie_lut_alloc(unsigned long page_order)
{
struct page *page;
unsigned long page_addr = 0;
unsigned long page_count = 0;
int i;
page_count = (1 << page_order);
page_addr = __get_free_pages(GFP_KERNEL, page_order);
if (page_addr == 0UL) {
XGI_ERROR("Can't get free pages: 0x%lx from system memory !\n",
page_count);
return 0;
}
page = virt_to_page(page_addr);
for (i = 0; i < page_count; i++, page++) {
XGI_INC_PAGE_COUNT(page);
XGILockPage(page);
}
XGI_INFO("page_count: 0x%lx page_order: 0x%lx page_addr: 0x%lx \n",
page_count, page_order, page_addr);
return page_addr;
}
static void xgi_pcie_lut_free(unsigned long page_addr, unsigned long page_order)
{
struct page *page;
unsigned long page_count = 0;
int i;
page_count = (1 << page_order);
page = virt_to_page(page_addr);
for (i = 0; i < page_count; i++, page++) {
XGI_DEC_PAGE_COUNT(page);
XGIUnlockPage(page);
}
free_pages(page_addr, page_order);
}
static int xgi_pcie_lut_init(xgi_info_t * info)
{
unsigned char *page_addr = NULL;
unsigned long pciePageCount, lutEntryNum, lutPageCount, lutPageOrder;
unsigned long count = 0;
u8 temp = 0;
/* Jong 06/06/2006 */
unsigned long pcie_aperture_size;
info->pcie.size = 128 * 1024 * 1024;
/* Get current FB aperture size */
temp = In3x5(0x27);
XGI_INFO("In3x5(0x27): 0x%x \n", temp);
if (temp & 0x01) { /* 256MB; Jong 06/05/2006; 0x10000000 */
/* Jong 06/06/2006; allocate memory */
pcie_aperture_size = 256 * 1024 * 1024;
/* info->pcie.base = 256 * 1024 * 1024; *//* pcie base is different from fb base */
} else { /* 128MB; Jong 06/05/2006; 0x08000000 */
/* Jong 06/06/2006; allocate memory */
pcie_aperture_size = 128 * 1024 * 1024;
/* info->pcie.base = 128 * 1024 * 1024; */
}
/* Jong 06/06/2006; allocate memory; it can be used for build-in kernel modules */
/* info->pcie.base=(unsigned long)alloc_bootmem(pcie_mem_size); */
/* total 496 MB; need 256 MB (0x10000000); start from 240 MB (0x0F000000) */
/* info->pcie.base=ioremap(0x0F000000, 0x10000000); *//* Cause system hang */
info->pcie.base = pcie_aperture_size; /* works */
/* info->pcie.base=info->fb.base + info->fb.size; *//* System hang */
/* info->pcie.base=128 * 1024 * 1024; *//* System hang */
XGI_INFO("Jong06062006-info->pcie.base: 0x%lx \n", info->pcie.base);
/* Get current lookup table page size */
temp = bReadReg(0xB00C);
if (temp & 0x04) { /* 8KB */
info->lutPageSize = 8 * 1024;
} else { /* 4KB */
info->lutPageSize = 4 * 1024;
}
XGI_INFO("info->lutPageSize: 0x%lx \n", info->lutPageSize);
#if 0
/* Get current lookup table location */
temp = bReadReg(0xB00C);
if (temp & 0x02) { /* LFB */
info->isLUTInLFB = TRUE;
/* Current we only support lookup table in LFB */
temp &= 0xFD;
bWriteReg(0xB00C, temp);
info->isLUTInLFB = FALSE;
} else { /* SFB */
info->isLUTInLFB = FALSE;
}
XGI_INFO("info->lutPageSize: 0x%lx \n", info->lutPageSize);
/* Get current SDFB page size */
temp = bReadReg(0xB00C);
if (temp & 0x08) { /* 8MB */
info->sdfbPageSize = 8 * 1024 * 1024;
} else { /* 4MB */
info->sdfbPageSize = 4 * 1024 * 1024;
}
#endif
pciePageCount = (info->pcie.size + PAGE_SIZE - 1) / PAGE_SIZE;
/*
* Allocate memory for PCIE GART table;
*/
lutEntryNum = pciePageCount;
lutPageCount = (lutEntryNum * 4 + PAGE_SIZE - 1) / PAGE_SIZE;
/* get page_order base on page_count */
count = lutPageCount;
for (lutPageOrder = 0; count; count >>= 1, ++lutPageOrder) ;
if ((lutPageCount << 1) == (1 << lutPageOrder)) {
lutPageOrder -= 1;
}
XGI_INFO("lutEntryNum: 0x%lx lutPageCount: 0x%lx lutPageOrder 0x%lx\n",
lutEntryNum, lutPageCount, lutPageOrder);
info->lutPageOrder = lutPageOrder;
page_addr = (unsigned char *)xgi_pcie_lut_alloc(lutPageOrder);
if (!page_addr) {
XGI_ERROR("cannot allocate PCIE lut page!\n");
goto fail;
}
info->lut_base = (unsigned long *)page_addr;
XGI_INFO("page_addr: 0x%p virt_to_phys(page_virtual): 0x%lx \n",
page_addr, virt_to_phys(page_addr));
XGI_INFO
("info->lut_base: 0x%p __pa(info->lut_base): 0x%lx info->lutPageOrder 0x%lx\n",
info->lut_base, __pa(info->lut_base), info->lutPageOrder);
/*
* clean all PCIE GART Entry
*/
memset(page_addr, 0, PAGE_SIZE << lutPageOrder);
#if defined(__i386__) || defined(__x86_64__)
asm volatile ("wbinvd":::"memory");
#else
mb();
#endif
/* Set GART in SFB */
bWriteReg(0xB00C, bReadReg(0xB00C) & ~0x02);
/* Set GART base address to HW */
dwWriteReg(0xB034, __pa(info->lut_base));
return 1;
fail:
return 0;
}
static void xgi_pcie_lut_cleanup(xgi_info_t * info)
{
if (info->lut_base) {
XGI_INFO("info->lut_base: 0x%p info->lutPageOrder: 0x%lx \n",
info->lut_base, info->lutPageOrder);
xgi_pcie_lut_free((unsigned long)info->lut_base,
info->lutPageOrder);
info->lut_base = NULL;
}
}
static xgi_pcie_block_t *xgi_pcie_new_node(void)
{
xgi_pcie_block_t *block =
(xgi_pcie_block_t *) kmem_cache_alloc(xgi_pcie_cache_block,
GFP_KERNEL);
if (block == NULL) {
return NULL;
}
block->offset = 0; /* block's offset in pcie memory, begin from 0 */
block->size = 0; /* The block size. */
block->bus_addr = 0; /* CPU access address/bus address */
block->hw_addr = 0; /* GE access address */
block->page_count = 0;
block->page_order = 0;
block->page_block = NULL;
block->page_table = NULL;
block->owner = PCIE_INVALID;
return block;
}
static void xgi_pcie_block_stuff_free(xgi_pcie_block_t * block)
{
struct page *page;
xgi_page_block_t *page_block = block->page_block;
xgi_page_block_t *free_block;
unsigned long page_count = 0;
int i;
//XGI_INFO("block->page_block: 0x%p \n", block->page_block);
while (page_block) {
page_count = page_block->page_count;
page = virt_to_page(page_block->virt_addr);
for (i = 0; i < page_count; i++, page++) {
XGI_DEC_PAGE_COUNT(page);
XGIUnlockPage(page);
}
free_pages(page_block->virt_addr, page_block->page_order);
page_block->phys_addr = 0;
page_block->virt_addr = 0;
page_block->page_count = 0;
page_block->page_order = 0;
free_block = page_block;
page_block = page_block->next;
//XGI_INFO("free free_block: 0x%p \n", free_block);
kfree(free_block);
free_block = NULL;
}
if (block->page_table) {
//XGI_INFO("free block->page_table: 0x%p \n", block->page_table);
kfree(block->page_table);
block->page_table = NULL;
}
}
int xgi_pcie_heap_init(xgi_info_t * info)
{
xgi_pcie_block_t *block;
if (!xgi_pcie_lut_init(info)) {
XGI_ERROR("xgi_pcie_lut_init failed\n");
return 0;
}
xgi_pcie_heap =
(xgi_pcie_heap_t *) kmalloc(sizeof(xgi_pcie_heap_t), GFP_KERNEL);
if (!xgi_pcie_heap) {
XGI_ERROR("xgi_pcie_heap alloc failed\n");
goto fail1;
}
INIT_LIST_HEAD(&xgi_pcie_heap->free_list);
INIT_LIST_HEAD(&xgi_pcie_heap->used_list);
INIT_LIST_HEAD(&xgi_pcie_heap->sort_list);
xgi_pcie_heap->max_freesize = info->pcie.size;
xgi_pcie_cache_block =
kmem_cache_create("xgi_pcie_block", sizeof(xgi_pcie_block_t), 0,
SLAB_HWCACHE_ALIGN, NULL, NULL);
if (NULL == xgi_pcie_cache_block) {
XGI_ERROR("Fail to creat xgi_pcie_block\n");
goto fail2;
}
block = (xgi_pcie_block_t *) xgi_pcie_new_node();
if (!block) {
XGI_ERROR("xgi_pcie_new_node failed\n");
goto fail3;
}
block->offset = 0; /* block's offset in pcie memory, begin from 0 */
block->size = info->pcie.size;
list_add(&block->list, &xgi_pcie_heap->free_list);
XGI_INFO("PCIE start address: 0x%lx, memory size : 0x%lx\n",
block->offset, block->size);
return 1;
fail3:
if (xgi_pcie_cache_block) {
kmem_cache_destroy(xgi_pcie_cache_block);
xgi_pcie_cache_block = NULL;
}
fail2:
if (xgi_pcie_heap) {
kfree(xgi_pcie_heap);
xgi_pcie_heap = NULL;
}
fail1:
xgi_pcie_lut_cleanup(info);
return 0;
}
void xgi_pcie_heap_check(void)
{
struct list_head *useList, *temp;
xgi_pcie_block_t *block;
unsigned int ownerIndex;
#ifdef XGI_DEBUG
2007-06-26 14:10:30 -06:00
char *ownerStr[6] =
{ "2D", "3D", "3D_CMD", "3D_SCR", "3D_TEX", "ELSE" };
#endif
2007-06-26 14:10:30 -06:00
if (xgi_pcie_heap) {
useList = &xgi_pcie_heap->used_list;
temp = useList->next;
XGI_INFO("pcie freemax = 0x%lx\n", xgi_pcie_heap->max_freesize);
while (temp != useList) {
block = list_entry(temp, struct xgi_pcie_block_s, list);
if (block->owner == PCIE_2D)
ownerIndex = 0;
else if (block->owner > PCIE_3D_TEXTURE
|| block->owner < PCIE_2D
|| block->owner < PCIE_3D)
ownerIndex = 5;
else
ownerIndex = block->owner - PCIE_3D + 1;
XGI_INFO
("Allocated by %s, block->offset: 0x%lx block->size: 0x%lx \n",
ownerStr[ownerIndex], block->offset, block->size);
temp = temp->next;
}
}
}
void xgi_pcie_heap_cleanup(xgi_info_t * info)
{
struct list_head *free_list, *temp;
xgi_pcie_block_t *block;
int j;
xgi_pcie_lut_cleanup(info);
XGI_INFO("xgi_pcie_lut_cleanup scceeded\n");
if (xgi_pcie_heap) {
free_list = &xgi_pcie_heap->free_list;
for (j = 0; j < 3; j++, free_list++) {
temp = free_list->next;
while (temp != free_list) {
block =
list_entry(temp, struct xgi_pcie_block_s,
list);
XGI_INFO
("No. %d block->offset: 0x%lx block->size: 0x%lx \n",
j, block->offset, block->size);
xgi_pcie_block_stuff_free(block);
block->bus_addr = 0;
block->hw_addr = 0;
temp = temp->next;
//XGI_INFO("No. %d free block: 0x%p \n", j, block);
kmem_cache_free(xgi_pcie_cache_block, block);
block = NULL;
}
}
XGI_INFO("free xgi_pcie_heap: 0x%p \n", xgi_pcie_heap);
kfree(xgi_pcie_heap);
xgi_pcie_heap = NULL;
}
if (xgi_pcie_cache_block) {
kmem_cache_destroy(xgi_pcie_cache_block);
xgi_pcie_cache_block = NULL;
}
}
static xgi_pcie_block_t *xgi_pcie_mem_alloc(xgi_info_t * info,
unsigned long originalSize,
enum PcieOwner owner)
{
struct list_head *free_list;
xgi_pcie_block_t *block, *used_block, *free_block;
xgi_page_block_t *page_block, *prev_page_block;
struct page *page;
unsigned long page_order = 0, count = 0, index = 0;
unsigned long page_addr = 0;
unsigned long *lut_addr = NULL;
unsigned long lut_id = 0;
unsigned long size = (originalSize + PAGE_SIZE - 1) & PAGE_MASK;
int i, j, page_count = 0;
int temp = 0;
XGI_INFO("Jong05302006-xgi_pcie_mem_alloc-Begin\n");
XGI_INFO("Original 0x%lx bytes requested, really 0x%lx allocated\n",
originalSize, size);
if (owner == PCIE_3D) {
if (xgi_pcie_vertex_block) {
XGI_INFO
("PCIE Vertex has been created, return directly.\n");
return xgi_pcie_vertex_block;
}
}
if (owner == PCIE_3D_CMDLIST) {
if (xgi_pcie_cmdlist_block) {
XGI_INFO
("PCIE Cmdlist has been created, return directly.\n");
return xgi_pcie_cmdlist_block;
}
}
if (owner == PCIE_3D_SCRATCHPAD) {
if (xgi_pcie_scratchpad_block) {
XGI_INFO
("PCIE Scratchpad has been created, return directly.\n");
return xgi_pcie_scratchpad_block;
}
}
if (size == 0) {
XGI_ERROR("size == 0 \n");
return (NULL);
}
XGI_INFO("max_freesize: 0x%lx \n", xgi_pcie_heap->max_freesize);
if (size > xgi_pcie_heap->max_freesize) {
XGI_ERROR
("size: 0x%lx bigger than PCIE total free size: 0x%lx.\n",
size, xgi_pcie_heap->max_freesize);
return (NULL);
}
/* Jong 05/30/2006; find next free list which has enough space */
free_list = xgi_pcie_heap->free_list.next;
while (free_list != &xgi_pcie_heap->free_list) {
//XGI_INFO("free_list: 0x%px \n", free_list);
block = list_entry(free_list, struct xgi_pcie_block_s, list);
if (size <= block->size) {
break;
}
free_list = free_list->next;
}
if (free_list == &xgi_pcie_heap->free_list) {
XGI_ERROR("Can't allocate %ldk size from PCIE memory !\n",
size / 1024);
return (NULL);
}
free_block = block;
XGI_INFO("alloc size: 0x%lx from offset: 0x%lx size: 0x%lx \n",
size, free_block->offset, free_block->size);
if (size == free_block->size) {
used_block = free_block;
XGI_INFO("size==free_block->size: free_block = 0x%p\n",
free_block);
list_del(&free_block->list);
} else {
used_block = xgi_pcie_new_node();
if (used_block == NULL) {
return NULL;
}
if (used_block == free_block) {
XGI_ERROR("used_block == free_block = 0x%p\n",
used_block);
}
used_block->offset = free_block->offset;
used_block->size = size;
free_block->offset += size;
free_block->size -= size;
}
xgi_pcie_heap->max_freesize -= size;
used_block->bus_addr = info->pcie.base + used_block->offset;
used_block->hw_addr = info->pcie.base + used_block->offset;
used_block->page_count = page_count = size / PAGE_SIZE;
/* get page_order base on page_count */
for (used_block->page_order = 0; page_count; page_count >>= 1) {
++used_block->page_order;
}
if ((used_block->page_count << 1) == (1 << used_block->page_order)) {
used_block->page_order--;
}
XGI_INFO
("used_block->offset: 0x%lx, used_block->size: 0x%lx, used_block->bus_addr: 0x%lx, used_block->hw_addr: 0x%lx, used_block->page_count: 0x%lx used_block->page_order: 0x%lx\n",
used_block->offset, used_block->size, used_block->bus_addr,
used_block->hw_addr, used_block->page_count,
used_block->page_order);
used_block->page_block = NULL;
//used_block->page_block = (xgi_pages_block_t *)kmalloc(sizeof(xgi_pages_block_t), GFP_KERNEL);
//if (!used_block->page_block) return NULL;
//used_block->page_block->next = NULL;
used_block->page_table =
(xgi_pte_t *) kmalloc(sizeof(xgi_pte_t) * used_block->page_count,
GFP_KERNEL);
if (used_block->page_table == NULL) {
goto fail;
}
lut_id = (used_block->offset >> PAGE_SHIFT);
lut_addr = info->lut_base;
lut_addr += lut_id;
XGI_INFO("lutAddr: 0x%p lutID: 0x%lx \n", lut_addr, lut_id);
/* alloc free pages from system */
page_count = used_block->page_count;
page_block = used_block->page_block;
prev_page_block = used_block->page_block;
for (i = 0; page_count > 0; i++) {
/* if size is bigger than 2M bytes, it should be split */
if (page_count > (1 << XGI_PCIE_ALLOC_MAX_ORDER)) {
page_order = XGI_PCIE_ALLOC_MAX_ORDER;
} else {
count = page_count;
for (page_order = 0; count; count >>= 1, ++page_order) ;
if ((page_count << 1) == (1 << page_order)) {
page_order -= 1;
}
}
count = (1 << page_order);
page_addr = __get_free_pages(GFP_KERNEL, page_order);
XGI_INFO("Jong05302006-xgi_pcie_mem_alloc-page_addr=0x%lx \n",
page_addr);
if (!page_addr) {
XGI_ERROR
("No: %d :Can't get free pages: 0x%lx from system memory !\n",
i, count);
goto fail;
}
/* Jong 05/30/2006; test */
memset((unsigned char *)page_addr, 0xFF,
PAGE_SIZE << page_order);
/* memset((unsigned char *)page_addr, 0, PAGE_SIZE << page_order); */
if (page_block == NULL) {
page_block =
(xgi_page_block_t *)
kmalloc(sizeof(xgi_page_block_t), GFP_KERNEL);
if (!page_block) {
XGI_ERROR
("Can't get memory for page_block! \n");
goto fail;
}
}
if (prev_page_block == NULL) {
used_block->page_block = page_block;
prev_page_block = page_block;
} else {
prev_page_block->next = page_block;
prev_page_block = page_block;
}
page_block->next = NULL;
page_block->phys_addr = __pa(page_addr);
page_block->virt_addr = page_addr;
page_block->page_count = count;
page_block->page_order = page_order;
XGI_INFO
("Jong05302006-xgi_pcie_mem_alloc-page_block->phys_addr=0x%lx \n",
page_block->phys_addr);
XGI_INFO
("Jong05302006-xgi_pcie_mem_alloc-page_block->virt_addr=0x%lx \n",
page_block->virt_addr);
page = virt_to_page(page_addr);
//XGI_INFO("No: %d page_order: 0x%lx page_count: 0x%x count: 0x%lx index: 0x%lx lut_addr: 0x%p"
// "page_block->phys_addr: 0x%lx page_block->virt_addr: 0x%lx \n",
// i, page_order, page_count, count, index, lut_addr, page_block->phys_addr, page_block->virt_addr);
for (j = 0; j < count; j++, page++, lut_addr++) {
used_block->page_table[index + j].phys_addr =
__pa(page_address(page));
used_block->page_table[index + j].virt_addr =
(unsigned long)page_address(page);
XGI_INFO
("Jong05302006-xgi_pcie_mem_alloc-used_block->page_table[index + j].phys_addr=0x%lx \n",
used_block->page_table[index + j].phys_addr);
XGI_INFO
("Jong05302006-xgi_pcie_mem_alloc-used_block->page_table[index + j].virt_addr=0x%lx \n",
used_block->page_table[index + j].virt_addr);
*lut_addr = __pa(page_address(page));
XGI_INC_PAGE_COUNT(page);
XGILockPage(page);
if (temp) {
XGI_INFO
("__pa(page_address(page)): 0x%lx lutAddr: 0x%p lutAddr No: 0x%x = 0x%lx \n",
__pa(page_address(page)), lut_addr, j,
*lut_addr);
temp--;
}
}
page_block = page_block->next;
page_count -= count;
index += count;
temp = 0;
}
used_block->owner = owner;
list_add(&used_block->list, &xgi_pcie_heap->used_list);
#if defined(__i386__) || defined(__x86_64__)
asm volatile ("wbinvd":::"memory");
#else
mb();
#endif
/* Flush GART Table */
bWriteReg(0xB03F, 0x40);
bWriteReg(0xB03F, 0x00);
if (owner == PCIE_3D) {
xgi_pcie_vertex_block = used_block;
}
if (owner == PCIE_3D_CMDLIST) {
xgi_pcie_cmdlist_block = used_block;
}
if (owner == PCIE_3D_SCRATCHPAD) {
xgi_pcie_scratchpad_block = used_block;
}
XGI_INFO("Jong05302006-xgi_pcie_mem_alloc-End \n");
return (used_block);
fail:
xgi_pcie_block_stuff_free(used_block);
kmem_cache_free(xgi_pcie_cache_block, used_block);
return NULL;
}
static xgi_pcie_block_t *xgi_pcie_mem_free(xgi_info_t * info,
unsigned long offset)
{
struct list_head *free_list, *used_list;
xgi_pcie_block_t *used_block, *block = NULL;
xgi_pcie_block_t *prev, *next;
unsigned long upper, lower;
used_list = xgi_pcie_heap->used_list.next;
while (used_list != &xgi_pcie_heap->used_list) {
block = list_entry(used_list, struct xgi_pcie_block_s, list);
if (block->offset == offset) {
break;
}
used_list = used_list->next;
}
if (used_list == &xgi_pcie_heap->used_list) {
XGI_ERROR("can't find block: 0x%lx to free!\n", offset);
return (NULL);
}
used_block = block;
XGI_INFO
("used_block: 0x%p, offset = 0x%lx, size = 0x%lx, bus_addr = 0x%lx, hw_addr = 0x%lx\n",
used_block, used_block->offset, used_block->size,
used_block->bus_addr, used_block->hw_addr);
xgi_pcie_block_stuff_free(used_block);
/* update xgi_pcie_heap */
xgi_pcie_heap->max_freesize += used_block->size;
prev = next = NULL;
upper = used_block->offset + used_block->size;
lower = used_block->offset;
free_list = xgi_pcie_heap->free_list.next;
while (free_list != &xgi_pcie_heap->free_list) {
block = list_entry(free_list, struct xgi_pcie_block_s, list);
if (block->offset == upper) {
next = block;
} else if ((block->offset + block->size) == lower) {
prev = block;
}
free_list = free_list->next;
}
XGI_INFO("next = 0x%p, prev = 0x%p\n", next, prev);
list_del(&used_block->list);
if (prev && next) {
prev->size += (used_block->size + next->size);
list_del(&next->list);
XGI_INFO("free node 0x%p\n", next);
kmem_cache_free(xgi_pcie_cache_block, next);
kmem_cache_free(xgi_pcie_cache_block, used_block);
next = NULL;
used_block = NULL;
return (prev);
}
if (prev) {
prev->size += used_block->size;
XGI_INFO("free node 0x%p\n", used_block);
kmem_cache_free(xgi_pcie_cache_block, used_block);
used_block = NULL;
return (prev);
}
if (next) {
next->size += used_block->size;
next->offset = used_block->offset;
XGI_INFO("free node 0x%p\n", used_block);
kmem_cache_free(xgi_pcie_cache_block, used_block);
used_block = NULL;
return (next);
}
used_block->bus_addr = 0;
used_block->hw_addr = 0;
used_block->page_count = 0;
used_block->page_order = 0;
list_add(&used_block->list, &xgi_pcie_heap->free_list);
XGI_INFO("Recycled free node %p, offset = 0x%lx, size = 0x%lx\n",
used_block, used_block->offset, used_block->size);
return (used_block);
}
void xgi_pcie_alloc(xgi_info_t * info, unsigned long size,
enum PcieOwner owner, xgi_mem_alloc_t * alloc)
{
xgi_pcie_block_t *block;
xgi_mem_pid_t *mempid_block;
xgi_down(info->pcie_sem);
block = xgi_pcie_mem_alloc(info, size, owner);
xgi_up(info->pcie_sem);
if (block == NULL) {
alloc->location = INVALID;
alloc->size = 0;
alloc->bus_addr = 0;
alloc->hw_addr = 0;
XGI_ERROR("PCIE RAM allocation failed\n");
} else {
XGI_INFO
("PCIE RAM allocation succeeded: offset = 0x%lx, bus_addr = 0x%lx\n",
block->offset, block->bus_addr);
alloc->location = NON_LOCAL;
alloc->size = block->size;
alloc->bus_addr = block->bus_addr;
alloc->hw_addr = block->hw_addr;
/*
manage mempid, handle PCIE_3D, PCIE_3D_TEXTURE.
PCIE_3D request means a opengl process created.
PCIE_3D_TEXTURE request means texture cannot alloc from fb.
*/
if (owner == PCIE_3D || owner == PCIE_3D_TEXTURE) {
mempid_block =
kmalloc(sizeof(xgi_mem_pid_t), GFP_KERNEL);
if (!mempid_block)
XGI_ERROR("mempid_block alloc failed\n");
mempid_block->location = NON_LOCAL;
if (owner == PCIE_3D)
mempid_block->bus_addr = 0xFFFFFFFF; /*xgi_pcie_vertex_block has the address */
else
mempid_block->bus_addr = alloc->bus_addr;
mempid_block->pid = alloc->pid;
XGI_INFO
("Memory ProcessID add one pcie block pid:%ld successfully! \n",
mempid_block->pid);
list_add(&mempid_block->list, &xgi_mempid_list);
}
}
}
void xgi_pcie_free(xgi_info_t * info, unsigned long bus_addr)
{
xgi_pcie_block_t *block;
unsigned long offset = bus_addr - info->pcie.base;
xgi_mem_pid_t *mempid_block;
xgi_mem_pid_t *mempid_freeblock = NULL;
struct list_head *mempid_list;
char isvertex = 0;
int processcnt;
if (xgi_pcie_vertex_block
&& xgi_pcie_vertex_block->bus_addr == bus_addr)
isvertex = 1;
if (isvertex) {
/*check is there any other process using vertex */
processcnt = 0;
mempid_list = xgi_mempid_list.next;
while (mempid_list != &xgi_mempid_list) {
mempid_block =
list_entry(mempid_list, struct xgi_mem_pid_s, list);
if (mempid_block->location == NON_LOCAL
&& mempid_block->bus_addr == 0xFFFFFFFF) {
++processcnt;
}
mempid_list = mempid_list->next;
}
if (processcnt > 1) {
return;
}
}
xgi_down(info->pcie_sem);
block = xgi_pcie_mem_free(info, offset);
xgi_up(info->pcie_sem);
if (block == NULL) {
XGI_ERROR("xgi_pcie_free() failed at base 0x%lx\n", offset);
}
if (isvertex)
xgi_pcie_vertex_block = NULL;
/* manage mempid */
mempid_list = xgi_mempid_list.next;
while (mempid_list != &xgi_mempid_list) {
mempid_block =
list_entry(mempid_list, struct xgi_mem_pid_s, list);
if (mempid_block->location == NON_LOCAL
&& ((isvertex && mempid_block->bus_addr == 0xFFFFFFFF)
|| (!isvertex && mempid_block->bus_addr == bus_addr))) {
mempid_freeblock = mempid_block;
break;
}
mempid_list = mempid_list->next;
}
if (mempid_freeblock) {
list_del(&mempid_freeblock->list);
XGI_INFO
("Memory ProcessID delete one pcie block pid:%ld successfully! \n",
mempid_freeblock->pid);
kfree(mempid_freeblock);
}
}
/*
* given a bus address, fid the pcie mem block
* uses the bus address as the key.
*/
struct xgi_pcie_block_s *xgi_find_pcie_block(xgi_info_t * info,
unsigned long address)
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{
struct list_head *used_list;
xgi_pcie_block_t *block;
int i;
used_list = xgi_pcie_heap->used_list.next;
while (used_list != &xgi_pcie_heap->used_list) {
block = list_entry(used_list, struct xgi_pcie_block_s, list);
if (block->bus_addr == address) {
return block;
}
if (block->page_table) {
for (i = 0; i < block->page_count; i++) {
unsigned long offset = block->bus_addr;
if ((address >= offset)
&& (address < (offset + PAGE_SIZE))) {
return block;
}
}
}
used_list = used_list->next;
}
XGI_ERROR("could not find map for vm 0x%lx\n", address);
return NULL;
}
/**
* xgi_find_pcie_virt
* @address: GE HW address
*
* Returns CPU virtual address. Assumes the CPU VAddr is continuous in not
* the same block
*/
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void *xgi_find_pcie_virt(xgi_info_t * info, unsigned long address)
{
struct list_head *used_list = xgi_pcie_heap->used_list.next;
const unsigned long offset_in_page = address & (PAGE_SIZE - 1);
XGI_INFO("begin (used_list = 0x%p, address = 0x%lx, "
"PAGE_SIZE - 1 = %lu, offset_in_page = %lu)\n",
used_list, address, PAGE_SIZE - 1, offset_in_page);
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while (used_list != &xgi_pcie_heap->used_list) {
xgi_pcie_block_t *block =
list_entry(used_list, struct xgi_pcie_block_s, list);
XGI_INFO("block = 0x%p (hw_addr = 0x%lx, size=%lu)\n",
block, block->hw_addr, block->size);
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if ((address >= block->hw_addr)
&& (address < (block->hw_addr + block->size))) {
const unsigned long loc_in_pagetable =
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(address - block->hw_addr) >> PAGE_SHIFT;
void *const ret =
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(void *)(block->page_table[loc_in_pagetable].
virt_addr + offset_in_page);
XGI_INFO("PAGE_SHIFT = %d\n", PAGE_SHIFT);
XGI_INFO("block->page_table[0x%lx].virt_addr = 0x%lx\n",
loc_in_pagetable,
block->page_table[loc_in_pagetable].virt_addr);
XGI_INFO("return 0x%p\n", ret);
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return ret;
} else {
XGI_INFO("used_list = used_list->next;\n");
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used_list = used_list->next;
}
}
XGI_ERROR("could not find map for vm 0x%lx\n", address);
return NULL;
}
void xgi_read_pcie_mem(xgi_info_t * info, xgi_mem_req_t * req)
{
}
void xgi_write_pcie_mem(xgi_info_t * info, xgi_mem_req_t * req)
{
}
/*
address -- GE hw address
*/
void xgi_test_rwinkernel(xgi_info_t * info, unsigned long address)
{
unsigned long *virtaddr = 0;
if (address == 0) {
XGI_INFO("[Jong-kd] input GE HW addr is 0x00000000\n");
return;
}
virtaddr = (unsigned long *)xgi_find_pcie_virt(info, address);
XGI_INFO("[Jong-kd] input GE HW addr is 0x%lx\n", address);
XGI_INFO("[Jong-kd] convert to CPU virt addr 0x%px\n", virtaddr);
XGI_INFO("[Jong-kd] origin [virtaddr] = 0x%lx\n", *virtaddr);
if (virtaddr != NULL) {
*virtaddr = 0x00f00fff;
}
XGI_INFO("[Jong-kd] modified [virtaddr] = 0x%lx\n", *virtaddr);
}