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gerrit-public.fairphone.software / fp2-dev / kernel / msm / 3c127f589ac1bc48c20e0ff6a2c659502b342777 / . / drivers / gpu / msm / adreno_ringbuffer.c
blob: b05650c764a98cb230f28640c0e13dca2c4962d8 [file] [log] [blame]
/* Copyright (c) 2002,2007-2011, Code Aurora Forum. All rights reserved.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 and
* only version 2 as published by the Free Software Foundation.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
*/
#include <linux/firmware.h>
#include <linux/slab.h>
#include <linux/sched.h>
#include <linux/log2.h>
#include "kgsl.h"
#include "kgsl_sharedmem.h"
#include "kgsl_cffdump.h"
#include "adreno.h"
#include "adreno_pm4types.h"
#include "adreno_ringbuffer.h"
#include "a200_reg.h"
#define GSL_RB_NOP_SIZEDWORDS 2
/* protected mode error checking below register address 0x800
* note: if CP_INTERRUPT packet is used then checking needs
* to change to below register address 0x7C8
*/
#define GSL_RB_PROTECTED_MODE_CONTROL 0x200001F2
/* Firmware file names
* Legacy names must remain but replacing macro names to
* match current kgsl model.
* a200 is yamato
* a220 is leia
*/
#define A200_PFP_FW "yamato_pfp.fw"
#define A200_PM4_FW "yamato_pm4.fw"
#define A220_PFP_470_FW "leia_pfp_470.fw"
#define A220_PM4_470_FW "leia_pm4_470.fw"
#define A225_PFP_FW "a225_pfp.fw"
#define A225_PM4_FW "a225_pm4.fw"
static void adreno_ringbuffer_submit(struct adreno_ringbuffer *rb)
{
BUG_ON(rb->wptr == 0);
/*synchronize memory before informing the hardware of the
*new commands.
*/
mb();
adreno_regwrite(rb->device, REG_CP_RB_WPTR, rb->wptr);
}
static int
adreno_ringbuffer_waitspace(struct adreno_ringbuffer *rb, unsigned int numcmds,
int wptr_ahead)
{
int nopcount;
unsigned int freecmds;
unsigned int *cmds;
uint cmds_gpu;
/* if wptr ahead, fill the remaining with NOPs */
if (wptr_ahead) {
/* -1 for header */
nopcount = rb->sizedwords - rb->wptr - 1;
cmds = (unsigned int *)rb->buffer_desc.hostptr + rb->wptr;
cmds_gpu = rb->buffer_desc.gpuaddr + sizeof(uint)*rb->wptr;
GSL_RB_WRITE(cmds, cmds_gpu, cp_nop_packet(nopcount));
/* Make sure that rptr is not 0 before submitting
* commands at the end of ringbuffer. We do not
* want the rptr and wptr to become equal when
* the ringbuffer is not empty */
do {
GSL_RB_GET_READPTR(rb, &rb->rptr);
} while (!rb->rptr);
rb->wptr++;
adreno_ringbuffer_submit(rb);
rb->wptr = 0;
}
/* wait for space in ringbuffer */
do {
GSL_RB_GET_READPTR(rb, &rb->rptr);
freecmds = rb->rptr - rb->wptr;
} while ((freecmds != 0) && (freecmds <= numcmds));
return 0;
}
static unsigned int *adreno_ringbuffer_allocspace(struct adreno_ringbuffer *rb,
unsigned int numcmds)
{
unsigned int *ptr = NULL;
int status = 0;
BUG_ON(numcmds >= rb->sizedwords);
GSL_RB_GET_READPTR(rb, &rb->rptr);
/* check for available space */
if (rb->wptr >= rb->rptr) {
/* wptr ahead or equal to rptr */
/* reserve dwords for nop packet */
if ((rb->wptr + numcmds) > (rb->sizedwords -
GSL_RB_NOP_SIZEDWORDS))
status = adreno_ringbuffer_waitspace(rb, numcmds, 1);
} else {
/* wptr behind rptr */
if ((rb->wptr + numcmds) >= rb->rptr)
status = adreno_ringbuffer_waitspace(rb, numcmds, 0);
/* check for remaining space */
/* reserve dwords for nop packet */
if ((rb->wptr + numcmds) > (rb->sizedwords -
GSL_RB_NOP_SIZEDWORDS))
status = adreno_ringbuffer_waitspace(rb, numcmds, 1);
}
if (status == 0) {
ptr = (unsigned int *)rb->buffer_desc.hostptr + rb->wptr;
rb->wptr += numcmds;
}
return ptr;
}
static int _load_firmware(struct kgsl_device *device, const char *fwfile,
void **data, int *len)
{
const struct firmware *fw = NULL;
int ret;
ret = request_firmware(&fw, fwfile, device->dev);
if (ret) {
KGSL_DRV_ERR(device, "request_firmware(%s) failed: %d\n",
fwfile, ret);
return ret;
}
*data = kmalloc(fw->size, GFP_KERNEL);
if (*data) {
memcpy(*data, fw->data, fw->size);
*len = fw->size;
} else
KGSL_MEM_ERR(device, "kmalloc(%d) failed\n", fw->size);
release_firmware(fw);
return (*data != NULL) ? 0 : -ENOMEM;
}
static int adreno_ringbuffer_load_pm4_ucode(struct kgsl_device *device)
{
struct adreno_device *adreno_dev = ADRENO_DEVICE(device);
int i, ret = 0;
if (adreno_dev->pm4_fw == NULL) {
int len;
void *ptr;
ret = _load_firmware(device, adreno_dev->pm4_fwfile,
&ptr, &len);
if (ret)
goto err;
/* PM4 size is 3 dword aligned plus 1 dword of version */
if (len % ((sizeof(uint32_t) * 3)) != sizeof(uint32_t)) {
KGSL_DRV_ERR(device, "Bad firmware size: %d\n", len);
ret = -EINVAL;
goto err;
}
adreno_dev->pm4_fw_size = len / sizeof(uint32_t);
adreno_dev->pm4_fw = ptr;
}
KGSL_DRV_INFO(device, "loading pm4 ucode version: %d\n",
adreno_dev->pm4_fw[0]);
adreno_regwrite(device, REG_CP_DEBUG, 0x02000000);
adreno_regwrite(device, REG_CP_ME_RAM_WADDR, 0);
for (i = 1; i < adreno_dev->pm4_fw_size; i++)
adreno_regwrite(device, REG_CP_ME_RAM_DATA,
adreno_dev->pm4_fw[i]);
err:
return ret;
}
static int adreno_ringbuffer_load_pfp_ucode(struct kgsl_device *device)
{
struct adreno_device *adreno_dev = ADRENO_DEVICE(device);
int i, ret = 0;
if (adreno_dev->pfp_fw == NULL) {
int len;
void *ptr;
ret = _load_firmware(device, adreno_dev->pfp_fwfile,
&ptr, &len);
if (ret)
goto err;
/* PFP size shold be dword aligned */
if (len % sizeof(uint32_t) != 0) {
KGSL_DRV_ERR(device, "Bad firmware size: %d\n", len);
ret = -EINVAL;
goto err;
}
adreno_dev->pfp_fw_size = len / sizeof(uint32_t);
adreno_dev->pfp_fw = ptr;
}
KGSL_DRV_INFO(device, "loading pfp ucode version: %d\n",
adreno_dev->pfp_fw[0]);
adreno_regwrite(device, REG_CP_PFP_UCODE_ADDR, 0);
for (i = 1; i < adreno_dev->pfp_fw_size; i++)
adreno_regwrite(device, REG_CP_PFP_UCODE_DATA,
adreno_dev->pfp_fw[i]);
err:
return ret;
}
int adreno_ringbuffer_start(struct adreno_ringbuffer *rb, unsigned int init_ram)
{
int status;
/*cp_rb_cntl_u cp_rb_cntl; */
union reg_cp_rb_cntl cp_rb_cntl;
unsigned int *cmds, rb_cntl;
struct kgsl_device *device = rb->device;
uint cmds_gpu;
if (rb->flags & KGSL_FLAGS_STARTED)
return 0;
if (init_ram) {
rb->timestamp = 0;
GSL_RB_INIT_TIMESTAMP(rb);
}
kgsl_sharedmem_set(&rb->memptrs_desc, 0, 0,
sizeof(struct kgsl_rbmemptrs));
kgsl_sharedmem_set(&rb->buffer_desc, 0, 0xAA,
(rb->sizedwords << 2));
adreno_regwrite(device, REG_CP_RB_WPTR_BASE,
(rb->memptrs_desc.gpuaddr
+ GSL_RB_MEMPTRS_WPTRPOLL_OFFSET));
/* setup WPTR delay */
adreno_regwrite(device, REG_CP_RB_WPTR_DELAY, 0 /*0x70000010 */);
/*setup REG_CP_RB_CNTL */
adreno_regread(device, REG_CP_RB_CNTL, &rb_cntl);
cp_rb_cntl.val = rb_cntl;
/*
* The size of the ringbuffer in the hardware is the log2
* representation of the size in quadwords (sizedwords / 2)
*/
cp_rb_cntl.f.rb_bufsz = ilog2(rb->sizedwords >> 1);
/*
* Specify the quadwords to read before updating mem RPTR.
* Like above, pass the log2 representation of the blocksize
* in quadwords.
*/
cp_rb_cntl.f.rb_blksz = ilog2(KGSL_RB_BLKSIZE >> 3);
cp_rb_cntl.f.rb_poll_en = GSL_RB_CNTL_POLL_EN; /* WPTR polling */
/* mem RPTR writebacks */
cp_rb_cntl.f.rb_no_update = GSL_RB_CNTL_NO_UPDATE;
adreno_regwrite(device, REG_CP_RB_CNTL, cp_rb_cntl.val);
adreno_regwrite(device, REG_CP_RB_BASE, rb->buffer_desc.gpuaddr);
adreno_regwrite(device, REG_CP_RB_RPTR_ADDR,
rb->memptrs_desc.gpuaddr +
GSL_RB_MEMPTRS_RPTR_OFFSET);
/* explicitly clear all cp interrupts */
adreno_regwrite(device, REG_CP_INT_ACK, 0xFFFFFFFF);
/* setup scratch/timestamp */
adreno_regwrite(device, REG_SCRATCH_ADDR,
device->memstore.gpuaddr +
KGSL_DEVICE_MEMSTORE_OFFSET(soptimestamp));
adreno_regwrite(device, REG_SCRATCH_UMSK,
GSL_RB_MEMPTRS_SCRATCH_MASK);
/* load the CP ucode */
status = adreno_ringbuffer_load_pm4_ucode(device);
if (status != 0)
return status;
/* load the prefetch parser ucode */
status = adreno_ringbuffer_load_pfp_ucode(device);
if (status != 0)
return status;
adreno_regwrite(device, REG_CP_QUEUE_THRESHOLDS, 0x000C0804);
rb->rptr = 0;
rb->wptr = 0;
/* clear ME_HALT to start micro engine */
adreno_regwrite(device, REG_CP_ME_CNTL, 0);
/* ME_INIT */
cmds = adreno_ringbuffer_allocspace(rb, 19);
cmds_gpu = rb->buffer_desc.gpuaddr + sizeof(uint)*(rb->wptr-19);
GSL_RB_WRITE(cmds, cmds_gpu, CP_HDR_ME_INIT);
/* All fields present (bits 9:0) */
GSL_RB_WRITE(cmds, cmds_gpu, 0x000003ff);
/* Disable/Enable Real-Time Stream processing (present but ignored) */
GSL_RB_WRITE(cmds, cmds_gpu, 0x00000000);
/* Enable (2D <-> 3D) implicit synchronization (present but ignored) */
GSL_RB_WRITE(cmds, cmds_gpu, 0x00000000);
GSL_RB_WRITE(cmds, cmds_gpu,
SUBBLOCK_OFFSET(REG_RB_SURFACE_INFO));
GSL_RB_WRITE(cmds, cmds_gpu,
SUBBLOCK_OFFSET(REG_PA_SC_WINDOW_OFFSET));
GSL_RB_WRITE(cmds, cmds_gpu,
SUBBLOCK_OFFSET(REG_VGT_MAX_VTX_INDX));
GSL_RB_WRITE(cmds, cmds_gpu,
SUBBLOCK_OFFSET(REG_SQ_PROGRAM_CNTL));
GSL_RB_WRITE(cmds, cmds_gpu,
SUBBLOCK_OFFSET(REG_RB_DEPTHCONTROL));
GSL_RB_WRITE(cmds, cmds_gpu,
SUBBLOCK_OFFSET(REG_PA_SU_POINT_SIZE));
GSL_RB_WRITE(cmds, cmds_gpu,
SUBBLOCK_OFFSET(REG_PA_SC_LINE_CNTL));
GSL_RB_WRITE(cmds, cmds_gpu,
SUBBLOCK_OFFSET(REG_PA_SU_POLY_OFFSET_FRONT_SCALE));
/* Vertex and Pixel Shader Start Addresses in instructions
* (3 DWORDS per instruction) */
GSL_RB_WRITE(cmds, cmds_gpu, 0x80000180);
/* Maximum Contexts */
GSL_RB_WRITE(cmds, cmds_gpu, 0x00000001);
/* Write Confirm Interval and The CP will wait the
* wait_interval * 16 clocks between polling */
GSL_RB_WRITE(cmds, cmds_gpu, 0x00000000);
/* NQ and External Memory Swap */
GSL_RB_WRITE(cmds, cmds_gpu, 0x00000000);
/* Protected mode error checking */
GSL_RB_WRITE(cmds, cmds_gpu, GSL_RB_PROTECTED_MODE_CONTROL);
/* Disable header dumping and Header dump address */
GSL_RB_WRITE(cmds, cmds_gpu, 0x00000000);
/* Header dump size */
GSL_RB_WRITE(cmds, cmds_gpu, 0x00000000);
adreno_ringbuffer_submit(rb);
/* idle device to validate ME INIT */
status = adreno_idle(device, KGSL_TIMEOUT_DEFAULT);
if (status == 0)
rb->flags |= KGSL_FLAGS_STARTED;
return status;
}
int adreno_ringbuffer_stop(struct adreno_ringbuffer *rb)
{
if (rb->flags & KGSL_FLAGS_STARTED) {
/* ME_HALT */
adreno_regwrite(rb->device, REG_CP_ME_CNTL, 0x10000000);
rb->flags &= ~KGSL_FLAGS_STARTED;
}
return 0;
}
int adreno_ringbuffer_init(struct kgsl_device *device)
{
int status;
struct adreno_device *adreno_dev = ADRENO_DEVICE(device);
struct adreno_ringbuffer *rb = &adreno_dev->ringbuffer;
rb->device = device;
/*
* It is silly to convert this to words and then back to bytes
* immediately below, but most of the rest of the code deals
* in words, so we might as well only do the math once
*/
rb->sizedwords = KGSL_RB_SIZE >> 2;
/* allocate memory for ringbuffer */
status = kgsl_allocate_contiguous(&rb->buffer_desc,
(rb->sizedwords << 2));
if (status != 0) {
adreno_ringbuffer_close(rb);
return status;
}
/* allocate memory for polling and timestamps */
/* This really can be at 4 byte alignment boundry but for using MMU
* we need to make it at page boundary */
status = kgsl_allocate_contiguous(&rb->memptrs_desc,
sizeof(struct kgsl_rbmemptrs));
if (status != 0) {
adreno_ringbuffer_close(rb);
return status;
}
/* overlay structure on memptrs memory */
rb->memptrs = (struct kgsl_rbmemptrs *) rb->memptrs_desc.hostptr;
return 0;
}
int adreno_ringbuffer_close(struct adreno_ringbuffer *rb)
{
struct adreno_device *adreno_dev = ADRENO_DEVICE(rb->device);
kgsl_sharedmem_free(&rb->buffer_desc);
kgsl_sharedmem_free(&rb->memptrs_desc);
kfree(adreno_dev->pfp_fw);
kfree(adreno_dev->pm4_fw);
adreno_dev->pfp_fw = NULL;
adreno_dev->pm4_fw = NULL;
memset(rb, 0, sizeof(struct adreno_ringbuffer));
return 0;
}
static uint32_t
adreno_ringbuffer_addcmds(struct adreno_ringbuffer *rb,
unsigned int flags, unsigned int *cmds,
int sizedwords)
{
unsigned int *ringcmds;
unsigned int timestamp;
unsigned int total_sizedwords = sizedwords + 6;
unsigned int i;
unsigned int rcmd_gpu;
/* reserve space to temporarily turn off protected mode
* error checking if needed
*/
total_sizedwords += flags & KGSL_CMD_FLAGS_PMODE ? 4 : 0;
total_sizedwords += !(flags & KGSL_CMD_FLAGS_NO_TS_CMP) ? 7 : 0;
total_sizedwords += !(flags & KGSL_CMD_FLAGS_NOT_KERNEL_CMD) ? 2 : 0;
ringcmds = adreno_ringbuffer_allocspace(rb, total_sizedwords);
rcmd_gpu = rb->buffer_desc.gpuaddr
+ sizeof(uint)*(rb->wptr-total_sizedwords);
if (!(flags & KGSL_CMD_FLAGS_NOT_KERNEL_CMD)) {
GSL_RB_WRITE(ringcmds, rcmd_gpu, cp_nop_packet(1));
GSL_RB_WRITE(ringcmds, rcmd_gpu, KGSL_CMD_IDENTIFIER);
}
if (flags & KGSL_CMD_FLAGS_PMODE) {
/* disable protected mode error checking */
GSL_RB_WRITE(ringcmds, rcmd_gpu,
cp_type3_packet(CP_SET_PROTECTED_MODE, 1));
GSL_RB_WRITE(ringcmds, rcmd_gpu, 0);
}
for (i = 0; i < sizedwords; i++) {
GSL_RB_WRITE(ringcmds, rcmd_gpu, *cmds);
cmds++;
}
if (flags & KGSL_CMD_FLAGS_PMODE) {
/* re-enable protected mode error checking */
GSL_RB_WRITE(ringcmds, rcmd_gpu,
cp_type3_packet(CP_SET_PROTECTED_MODE, 1));
GSL_RB_WRITE(ringcmds, rcmd_gpu, 1);
}
rb->timestamp++;
timestamp = rb->timestamp;
/* start-of-pipeline and end-of-pipeline timestamps */
GSL_RB_WRITE(ringcmds, rcmd_gpu, cp_type0_packet(REG_CP_TIMESTAMP, 1));
GSL_RB_WRITE(ringcmds, rcmd_gpu, rb->timestamp);
GSL_RB_WRITE(ringcmds, rcmd_gpu, cp_type3_packet(CP_EVENT_WRITE, 3));
GSL_RB_WRITE(ringcmds, rcmd_gpu, CACHE_FLUSH_TS);
GSL_RB_WRITE(ringcmds, rcmd_gpu,
(rb->device->memstore.gpuaddr +
KGSL_DEVICE_MEMSTORE_OFFSET(eoptimestamp)));
GSL_RB_WRITE(ringcmds, rcmd_gpu, rb->timestamp);
if (!(flags & KGSL_CMD_FLAGS_NO_TS_CMP)) {
/* Conditional execution based on memory values */
GSL_RB_WRITE(ringcmds, rcmd_gpu,
cp_type3_packet(CP_COND_EXEC, 4));
GSL_RB_WRITE(ringcmds, rcmd_gpu, (rb->device->memstore.gpuaddr +
KGSL_DEVICE_MEMSTORE_OFFSET(ts_cmp_enable)) >> 2);
GSL_RB_WRITE(ringcmds, rcmd_gpu, (rb->device->memstore.gpuaddr +
KGSL_DEVICE_MEMSTORE_OFFSET(ref_wait_ts)) >> 2);
GSL_RB_WRITE(ringcmds, rcmd_gpu, rb->timestamp);
/* # of conditional command DWORDs */
GSL_RB_WRITE(ringcmds, rcmd_gpu, 2);
GSL_RB_WRITE(ringcmds, rcmd_gpu,
cp_type3_packet(CP_INTERRUPT, 1));
GSL_RB_WRITE(ringcmds, rcmd_gpu, CP_INT_CNTL__RB_INT_MASK);
}
adreno_ringbuffer_submit(rb);
/* return timestamp of issued coREG_ands */
return timestamp;
}
void
adreno_ringbuffer_issuecmds(struct kgsl_device *device,
unsigned int flags,
unsigned int *cmds,
int sizedwords)
{
struct adreno_device *adreno_dev = ADRENO_DEVICE(device);
struct adreno_ringbuffer *rb = &adreno_dev->ringbuffer;
if (device->state & KGSL_STATE_HUNG)
return;
adreno_ringbuffer_addcmds(rb, flags, cmds, sizedwords);
}
int
adreno_ringbuffer_issueibcmds(struct kgsl_device_private *dev_priv,
struct kgsl_context *context,
struct kgsl_ibdesc *ibdesc,
unsigned int numibs,
uint32_t *timestamp,
unsigned int flags)
{
struct kgsl_device *device = dev_priv->device;
struct adreno_device *adreno_dev = ADRENO_DEVICE(device);
unsigned int *link;
unsigned int *cmds;
unsigned int i;
struct adreno_context *drawctxt;
if (device->state & KGSL_STATE_HUNG)
return -EBUSY;
if (!(adreno_dev->ringbuffer.flags & KGSL_FLAGS_STARTED) ||
context == NULL || ibdesc == 0 || numibs == 0)
return -EINVAL;
drawctxt = context->devctxt;
if (drawctxt->flags & CTXT_FLAGS_GPU_HANG) {
KGSL_CTXT_WARN(device, "Context %p caused a gpu hang.."
" will not accept commands for this context\n",
drawctxt);
return -EDEADLK;
}
link = kzalloc(sizeof(unsigned int) * numibs * 3, GFP_KERNEL);
cmds = link;
if (!link) {
KGSL_MEM_ERR(device, "Failed to allocate memory for for command"
" submission, size %x\n", numibs * 3);
return -ENOMEM;
}
for (i = 0; i < numibs; i++) {
(void)kgsl_cffdump_parse_ibs(dev_priv, NULL,
ibdesc[i].gpuaddr, ibdesc[i].sizedwords, false);
*cmds++ = CP_HDR_INDIRECT_BUFFER_PFD;
*cmds++ = ibdesc[i].gpuaddr;
*cmds++ = ibdesc[i].sizedwords;
}
kgsl_setstate(device,
kgsl_pt_get_flags(device->mmu.hwpagetable,
device->id));
adreno_drawctxt_switch(adreno_dev, drawctxt, flags);
*timestamp = adreno_ringbuffer_addcmds(&adreno_dev->ringbuffer,
KGSL_CMD_FLAGS_NOT_KERNEL_CMD,
&link[0], (cmds - link));
KGSL_CMD_INFO(device, "ctxt %d g %08x numibs %d ts %d\n",
context->id, (unsigned int)ibdesc, numibs, *timestamp);
kfree(link);
#ifdef CONFIG_MSM_KGSL_CFF_DUMP
/*
* insert wait for idle after every IB1
* this is conservative but works reliably and is ok
* even for performance simulations
*/
adreno_idle(device, KGSL_TIMEOUT_DEFAULT);
#endif
return 0;
}
int adreno_ringbuffer_extract(struct adreno_ringbuffer *rb,
unsigned int *temp_rb_buffer,
int *rb_size)
{
struct kgsl_device *device = rb->device;
unsigned int rb_rptr;
unsigned int retired_timestamp;
unsigned int temp_idx = 0;
unsigned int value;
unsigned int val1;
unsigned int val2;
unsigned int val3;
unsigned int copy_rb_contents = 0;
unsigned int cur_context;
unsigned int j;
GSL_RB_GET_READPTR(rb, &rb->rptr);
retired_timestamp = device->ftbl->readtimestamp(device,
KGSL_TIMESTAMP_RETIRED);
KGSL_DRV_ERR(device, "GPU successfully executed till ts: %x\n",
retired_timestamp);
/*
* We need to go back in history by 4 dwords from the current location
* of read pointer as 4 dwords are read to match the end of a command.
* Also, take care of wrap around when moving back
*/
if (rb->rptr >= 4)
rb_rptr = (rb->rptr - 4) * sizeof(unsigned int);
else
rb_rptr = rb->buffer_desc.size -
((4 - rb->rptr) * sizeof(unsigned int));
/* Read the rb contents going backwards to locate end of last
* sucessfully executed command */
while ((rb_rptr / sizeof(unsigned int)) != rb->wptr) {
kgsl_sharedmem_readl(&rb->buffer_desc, &value, rb_rptr);
if (value == retired_timestamp) {
rb_rptr = adreno_ringbuffer_inc_wrapped(rb_rptr,
rb->buffer_desc.size);
kgsl_sharedmem_readl(&rb->buffer_desc, &val1, rb_rptr);
rb_rptr = adreno_ringbuffer_inc_wrapped(rb_rptr,
rb->buffer_desc.size);
kgsl_sharedmem_readl(&rb->buffer_desc, &val2, rb_rptr);
rb_rptr = adreno_ringbuffer_inc_wrapped(rb_rptr,
rb->buffer_desc.size);
kgsl_sharedmem_readl(&rb->buffer_desc, &val3, rb_rptr);
/* match the pattern found at the end of a command */
if ((val1 == 2 &&
val2 == cp_type3_packet(CP_INTERRUPT, 1)
&& val3 == CP_INT_CNTL__RB_INT_MASK) ||
(val1 == cp_type3_packet(CP_EVENT_WRITE, 3)
&& val2 == CACHE_FLUSH_TS &&
val3 == (rb->device->memstore.gpuaddr +
KGSL_DEVICE_MEMSTORE_OFFSET(eoptimestamp)))) {
rb_rptr = adreno_ringbuffer_inc_wrapped(rb_rptr,
rb->buffer_desc.size);
KGSL_DRV_ERR(device,
"Found end of last executed "
"command at offset: %x\n",
rb_rptr / sizeof(unsigned int));
break;
} else {
if (rb_rptr < (3 * sizeof(unsigned int)))
rb_rptr = rb->buffer_desc.size -
(3 * sizeof(unsigned int))
+ rb_rptr;
else
rb_rptr -= (3 * sizeof(unsigned int));
}
}
if (rb_rptr == 0)
rb_rptr = rb->buffer_desc.size - sizeof(unsigned int);
else
rb_rptr -= sizeof(unsigned int);
}
if ((rb_rptr / sizeof(unsigned int)) == rb->wptr) {
KGSL_DRV_ERR(device,
"GPU recovery from hang not possible because last"
" successful timestamp is overwritten\n");
return -EINVAL;
}
/* rb_rptr is now pointing to the first dword of the command following
* the last sucessfully executed command sequence. Assumption is that
* GPU is hung in the command sequence pointed by rb_rptr */
/* make sure the GPU is not hung in a command submitted by kgsl
* itself */
kgsl_sharedmem_readl(&rb->buffer_desc, &val1, rb_rptr);
kgsl_sharedmem_readl(&rb->buffer_desc, &val2,
adreno_ringbuffer_inc_wrapped(rb_rptr,
rb->buffer_desc.size));
if (val1 == cp_nop_packet(1) && val2 == KGSL_CMD_IDENTIFIER) {
KGSL_DRV_ERR(device,
"GPU recovery from hang not possible because "
"of hang in kgsl command\n");
return -EINVAL;
}
/* current_context is the context that is presently active in the
* GPU, i.e the context in which the hang is caused */
kgsl_sharedmem_readl(&device->memstore, &cur_context,
KGSL_DEVICE_MEMSTORE_OFFSET(current_context));
while ((rb_rptr / sizeof(unsigned int)) != rb->wptr) {
kgsl_sharedmem_readl(&rb->buffer_desc, &value, rb_rptr);
rb_rptr = adreno_ringbuffer_inc_wrapped(rb_rptr,
rb->buffer_desc.size);
/* check for context switch indicator */
if (value == KGSL_CONTEXT_TO_MEM_IDENTIFIER) {
kgsl_sharedmem_readl(&rb->buffer_desc, &value, rb_rptr);
rb_rptr = adreno_ringbuffer_inc_wrapped(rb_rptr,
rb->buffer_desc.size);
BUG_ON(value != cp_type3_packet(CP_MEM_WRITE, 2));
kgsl_sharedmem_readl(&rb->buffer_desc, &val1, rb_rptr);
rb_rptr = adreno_ringbuffer_inc_wrapped(rb_rptr,
rb->buffer_desc.size);
BUG_ON(val1 != (device->memstore.gpuaddr +
KGSL_DEVICE_MEMSTORE_OFFSET(current_context)));
kgsl_sharedmem_readl(&rb->buffer_desc, &value, rb_rptr);
rb_rptr = adreno_ringbuffer_inc_wrapped(rb_rptr,
rb->buffer_desc.size);
BUG_ON((copy_rb_contents == 0) &&
(value == cur_context));
/*
* If we were copying the commands and got to this point
* then we need to remove the 3 commands that appear
* before KGSL_CONTEXT_TO_MEM_IDENTIFIER
*/
if (temp_idx)
temp_idx -= 3;
/* if context switches to a context that did not cause
* hang then start saving the rb contents as those
* commands can be executed */
if (value != cur_context) {
copy_rb_contents = 1;
temp_rb_buffer[temp_idx++] = cp_nop_packet(1);
temp_rb_buffer[temp_idx++] =
KGSL_CMD_IDENTIFIER;
temp_rb_buffer[temp_idx++] = cp_nop_packet(1);
temp_rb_buffer[temp_idx++] =
KGSL_CONTEXT_TO_MEM_IDENTIFIER;
temp_rb_buffer[temp_idx++] =
cp_type3_packet(CP_MEM_WRITE, 2);
temp_rb_buffer[temp_idx++] = val1;
temp_rb_buffer[temp_idx++] = value;
} else {
copy_rb_contents = 0;
}
} else if (copy_rb_contents)
temp_rb_buffer[temp_idx++] = value;
}
*rb_size = temp_idx;
KGSL_DRV_ERR(device, "Extracted rb contents, size: %x\n", *rb_size);
for (temp_idx = 0; temp_idx < *rb_size;) {
char str[80];
int idx = 0;
if ((temp_idx + 8) <= *rb_size)
j = 8;
else
j = *rb_size - temp_idx;
for (; j != 0; j--)
idx += scnprintf(str + idx, 80 - idx,
"%8.8X ", temp_rb_buffer[temp_idx++]);
printk(KERN_ALERT "%s", str);
}
return 0;
}
void
adreno_ringbuffer_restore(struct adreno_ringbuffer *rb, unsigned int *rb_buff,
int num_rb_contents)
{
int i;
unsigned int *ringcmds;
unsigned int rcmd_gpu;
if (!num_rb_contents)
return;
if (num_rb_contents > (rb->buffer_desc.size - rb->wptr)) {
adreno_regwrite(rb->device, REG_CP_RB_RPTR, 0);
rb->rptr = 0;
BUG_ON(num_rb_contents > rb->buffer_desc.size);
}
ringcmds = (unsigned int *)rb->buffer_desc.hostptr + rb->wptr;
rcmd_gpu = rb->buffer_desc.gpuaddr + sizeof(unsigned int) * rb->wptr;
for (i = 0; i < num_rb_contents; i++)
GSL_RB_WRITE(ringcmds, rcmd_gpu, rb_buff[i]);
rb->wptr += num_rb_contents;
adreno_ringbuffer_submit(rb);
}