kernel_samsung_a34x-permissive/drivers/misc/mediatek/mdp/cmdq_helper_ext.c
2024-04-28 15:49:01 +02:00

5095 lines
127 KiB
C
Executable file

/* SPDX-License-Identifier: GPL-2.0 */
/*
* Copyright (c) 2019 MediaTek Inc.
*/
#include <linux/kernel.h>
#include <linux/memblock.h>
#include <linux/memory.h>
#include <linux/workqueue.h>
#include <linux/dma-mapping.h>
#include <linux/dmapool.h>
#include <linux/uaccess.h>
#include <linux/notifier.h>
#include <linux/irqchip/mtk-gic-extend.h>
#include <linux/sched/clock.h>
#include <linux/mailbox_controller.h>
#ifdef CMDQ_DAPC_DEBUG
#include <devapc_public.h>
#endif
#include <linux/arm-smccc.h>
#include <mt-plat/mtk_secure_api.h>
#include "cmdq-util.h"
#include "mdp_cmdq_helper_ext.h"
#include "mdp_cmdq_record.h"
#include "mdp_cmdq_device.h"
#include "cmdq_virtual.h"
#include "cmdq_reg.h"
#include "mdp_common.h"
#if IS_ENABLED(CONFIG_MMPROFILE)
#include "cmdq_mmp.h"
#endif
#ifdef CMDQ_SECURE_PATH_SUPPORT
#include <cmdq-sec.h>
#endif
#if defined(CONFIG_MACH_MT6853)
#include <soc/mediatek/smi.h>
#endif
#define CMDQ_GET_COOKIE_CNT(thread) \
(CMDQ_REG_GET32(CMDQ_THR_EXEC_CNT(thread)) & CMDQ_MAX_COOKIE_VALUE)
#define CMDQ_PROFILE_LIMIT_0 3000000
#define CMDQ_PROFILE_LIMIT_1 10000000
#define CMDQ_PROFILE_LIMIT_2 20000000
struct cmdq_cmd_struct {
void *p_va_base; /* VA: denote CMD virtual address space */
dma_addr_t mva_base; /* PA: denote the PA for CMD */
u32 sram_base; /* SRAM base offset for CMD start */
u32 buffer_size; /* size of allocated command buffer */
};
/* mutex and spinlock in core, first define first lock */
static DEFINE_MUTEX(cmdq_clock_mutex);
static DEFINE_MUTEX(cmdq_res_mutex);
static DEFINE_MUTEX(cmdq_handle_list_mutex);
static DEFINE_MUTEX(cmdq_thread_mutex);
static DEFINE_MUTEX(cmdq_inst_check_mutex);
static DEFINE_SPINLOCK(cmdq_write_addr_lock);
static DEFINE_SPINLOCK(cmdq_record_lock);
/* wake lock to prevnet system off */
static struct wakeup_source *mdp_wake_lock;
static bool mdp_wake_locked;
static struct dma_pool *mdp_rb_pool;
static atomic_t mdp_rb_pool_cnt;
static u32 mdp_rb_pool_limit = 256;
/* callbacks */
static BLOCKING_NOTIFIER_HEAD(cmdq_status_dump_notifier);
static struct cmdq_client *cmdq_clients[CMDQ_MAX_THREAD_COUNT];
static struct cmdq_client *cmdq_entry;
static struct cmdq_base *cmdq_client_base;
static atomic_t cmdq_thread_usage;
static wait_queue_head_t *cmdq_wait_queue; /* task done notify */
static struct ContextStruct cmdq_ctx; /* cmdq driver context */
static struct DumpCommandBufferStruct cmdq_command_dump;
static struct CmdqCBkStruct cmdq_group_cb[CMDQ_MAX_GROUP_COUNT];
static struct CmdqDebugCBkStruct cmdq_debug_cb;
static struct cmdqDTSDataStruct cmdq_dts_data;
static struct SubsysStruct cmdq_adds_subsys = {
.msb = 0,
.subsysID = -1,
.mask = 0,
.grpName = "AddOn"
};
/* debug for alloc hw buffer count */
static atomic_t cmdq_alloc_cnt[CMDQ_CLT_MAX + 1];
/* CMDQ core feature functions */
static bool cmdq_core_check_gpr_valid(const u32 gpr, const bool val)
{
if (val)
switch (gpr) {
case CMDQ_DATA_REG_JPEG:
case CMDQ_DATA_REG_PQ_COLOR:
case CMDQ_DATA_REG_2D_SHARPNESS_0:
case CMDQ_DATA_REG_2D_SHARPNESS_1:
case CMDQ_DATA_REG_DEBUG:
return true;
default:
return false;
}
else
switch (gpr >> 16) {
case CMDQ_DATA_REG_JPEG_DST:
case CMDQ_DATA_REG_PQ_COLOR_DST:
case CMDQ_DATA_REG_2D_SHARPNESS_0:
case CMDQ_DATA_REG_2D_SHARPNESS_0_DST:
case CMDQ_DATA_REG_2D_SHARPNESS_1_DST:
case CMDQ_DATA_REG_DEBUG_DST:
return true;
default:
return false;
}
return false;
}
static bool cmdq_core_check_dma_addr_valid(const unsigned long pa)
{
struct WriteAddrStruct *waddr = NULL;
unsigned long flags = 0L;
phys_addr_t start = memblock_start_of_DRAM();
bool ret = false;
if (pa < start)
return true;
spin_lock_irqsave(&cmdq_write_addr_lock, flags);
list_for_each_entry(waddr, &cmdq_ctx.writeAddrList, list_node)
if (pa - (unsigned long)waddr->pa < waddr->count << 2) {
ret = true;
break;
}
spin_unlock_irqrestore(&cmdq_write_addr_lock, flags);
return ret;
}
static bool cmdq_core_check_instr_valid(const u64 instr)
{
u32 op = instr >> 56, option = (instr >> 53) & 0x7;
u32 argA = (instr >> 32) & 0x1FFFFF, argB = instr & 0xFFFFFFFF;
#ifdef CMDQ_MDP_ENABLE_SPR
u32 sOP = argA >> 16, argA_i = argA & 0xFFFF;
u32 argB_i = argB >> 16, argC_i = argB & 0xFFFF;
#endif
switch (op) {
case CMDQ_CODE_WRITE:
if (!option)
return true;
if (option == 0x2 && cmdq_core_check_gpr_valid(argB, true))
return true;
if (option == 0x4 && cmdq_core_check_gpr_valid(argA, false))
return true;
if (option == 0x6 && cmdq_core_check_gpr_valid(argA, false) &&
cmdq_core_check_gpr_valid(argB, true))
return true;
break;
case CMDQ_CODE_READ:
if (option == 0x2 && cmdq_core_check_gpr_valid(argB, true))
return true;
if (option == 0x6 && cmdq_core_check_gpr_valid(argA, false) &&
cmdq_core_check_gpr_valid(argB, true))
return true;
break;
case CMDQ_CODE_MOVE:
if (!option && !argA)
return true;
if (option == 0x4 && cmdq_core_check_gpr_valid(argA, false) &&
cmdq_core_check_dma_addr_valid(argB))
return true;
break;
case CMDQ_CODE_JUMP:
if (!argA && argB == 0x8)
return true;
break;
#ifdef CMDQ_MDP_ENABLE_SPR
case CMDQ_CODE_READ_S:
if (option == 0x4 && argA_i == 1 && !argC_i)
return true;
break;
case CMDQ_CODE_WRITE_S:
case CMDQ_CODE_WRITE_S_W_MASK:
if (!option)
return true;
if (option == 0x2 && (!argB_i || argB_i == 1) && !argC_i)
return true;
break;
case CMDQ_CODE_LOGIC:
if (option == 0x4 && !sOP && !argA_i && !argB_i)
return true;
break;
#else
case CMDQ_CODE_READ_S:
case CMDQ_CODE_WRITE_S:
case CMDQ_CODE_WRITE_S_W_MASK:
case CMDQ_CODE_LOGIC:
break;
#endif
case CMDQ_CODE_JUMP_C_ABSOLUTE:
case CMDQ_CODE_JUMP_C_RELATIVE:
break;
case 0:
CMDQ_ERR("unknown instruction:%llx\n", instr);
return true;
default:
return true;
}
CMDQ_ERR("instr:%#llx\n", instr);
return false;
}
bool cmdq_core_check_user_valid(void *src, u32 size)
{
void *buffer;
u64 *va;
bool ret = true;
u32 copy_size;
u32 remain_size = size;
void *cur_src = src;
CMDQ_TIME cost = sched_clock();
mutex_lock(&cmdq_inst_check_mutex);
if (!cmdq_ctx.inst_check_buffer) {
cmdq_ctx.inst_check_buffer = kmalloc(CMDQ_CMD_BUFFER_SIZE,
GFP_KERNEL);
if (!cmdq_ctx.inst_check_buffer) {
CMDQ_ERR("fail to alloc check buffer\n");
mutex_unlock(&cmdq_inst_check_mutex);
return false;
}
}
buffer = cmdq_ctx.inst_check_buffer;
while (remain_size > 0 && ret) {
copy_size = remain_size > CMDQ_CMD_BUFFER_SIZE ?
CMDQ_CMD_BUFFER_SIZE : remain_size;
if (copy_from_user(buffer, cur_src, copy_size)) {
CMDQ_ERR("copy from user fail size:%u\n", size);
ret = false;
break;
}
for (va = (u64 *)buffer;
va < (u64 *)(buffer + copy_size); va++) {
ret = cmdq_core_check_instr_valid(*va);
if (unlikely(!ret))
break;
}
remain_size -= copy_size;
cur_src += copy_size;
}
mutex_unlock(&cmdq_inst_check_mutex);
cost = sched_clock() - cost;
do_div(cost, 1000);
CMDQ_MSG("%s size:%u cost:%lluus ret:%s\n", __func__, size, (u64)cost,
ret ? "true" : "false");
return ret;
}
static void cmdq_core_init_thread_work_queue(void)
{
int index;
const u32 max_thread_count = cmdq_dev_get_thread_count();
cmdq_ctx.taskThreadAutoReleaseWQ = kcalloc(max_thread_count,
sizeof(*cmdq_ctx.taskThreadAutoReleaseWQ), GFP_KERNEL);
/* Initialize work queue per thread */
for (index = 0; index < max_thread_count; index++) {
cmdq_ctx.taskThreadAutoReleaseWQ[index] =
create_singlethread_workqueue("cmdq_auto_release_thread");
}
}
static void cmdq_core_destroy_thread_work_queue(void)
{
int index;
const u32 max_thread_count = cmdq_dev_get_thread_count();
/* destroy work queue per thread */
for (index = 0; index < max_thread_count; index++) {
destroy_workqueue(
cmdq_ctx.taskThreadAutoReleaseWQ[index]);
cmdq_ctx.taskThreadAutoReleaseWQ[index] = NULL;
}
kfree(cmdq_ctx.taskThreadAutoReleaseWQ);
}
void cmdq_core_deinit_group_cb(void)
{
memset(&cmdq_group_cb, 0x0, sizeof(cmdq_group_cb));
memset(&cmdq_debug_cb, 0x0, sizeof(cmdq_debug_cb));
}
static bool cmdq_core_is_valid_group(enum CMDQ_GROUP_ENUM engGroup)
{
/* check range */
if (engGroup < 0 || engGroup >= CMDQ_MAX_GROUP_COUNT)
return false;
return true;
}
s32 cmdqCoreRegisterCB(enum CMDQ_GROUP_ENUM engGroup,
CmdqClockOnCB clockOn, CmdqDumpInfoCB dumpInfo,
CmdqResetEngCB resetEng, CmdqClockOffCB clockOff)
{
struct CmdqCBkStruct *callback;
if (!cmdq_core_is_valid_group(engGroup))
return -EFAULT;
CMDQ_MSG("Register %d group engines' callback\n", engGroup);
CMDQ_MSG("clockOn:%pf dumpInfo:%pf resetEng:%pf clockOff:%pf\n",
clockOn, dumpInfo, resetEng, clockOff);
callback = &cmdq_group_cb[engGroup];
callback->clockOn = clockOn;
callback->dumpInfo = dumpInfo;
callback->resetEng = resetEng;
callback->clockOff = clockOff;
return 0;
}
s32 cmdqCoreRegisterDispatchModCB(
enum CMDQ_GROUP_ENUM engGroup, CmdqDispatchModuleCB dispatchMod)
{
struct CmdqCBkStruct *callback;
if (!cmdq_core_is_valid_group(engGroup))
return -EFAULT;
CMDQ_MSG("Register %d group engines' dispatch callback\n",
engGroup);
callback = &cmdq_group_cb[engGroup];
callback->dispatchMod = dispatchMod;
return 0;
}
s32 cmdqCoreRegisterDebugRegDumpCB(
CmdqDebugRegDumpBeginCB beginCB, CmdqDebugRegDumpEndCB endCB)
{
CMDQ_VERBOSE("Register reg dump: begin:%p end:%p\n",
beginCB, endCB);
cmdq_debug_cb.beginDebugRegDump = beginCB;
cmdq_debug_cb.endDebugRegDump = endCB;
return 0;
}
s32 cmdqCoreRegisterTrackTaskCB(enum CMDQ_GROUP_ENUM engGroup,
CmdqTrackTaskCB trackTask)
{
struct CmdqCBkStruct *callback;
if (!cmdq_core_is_valid_group(engGroup))
return -EFAULT;
CMDQ_MSG("Register %d group engines' callback\n", engGroup);
CMDQ_MSG("trackTask:%pf\n", trackTask);
callback = &cmdq_group_cb[engGroup];
callback->trackTask = trackTask;
return 0;
}
s32 cmdqCoreRegisterErrorResetCB(enum CMDQ_GROUP_ENUM engGroup,
CmdqErrorResetCB errorReset)
{
struct CmdqCBkStruct *callback;
if (!cmdq_core_is_valid_group(engGroup))
return -EFAULT;
CMDQ_MSG("Register %d group engines' callback\n", engGroup);
CMDQ_MSG("errorReset:%pf\n", errorReset);
callback = &cmdq_group_cb[engGroup];
callback->errorReset = errorReset;
return 0;
}
void cmdq_core_register_status_dump(struct notifier_block *notifier)
{
s32 ret;
CMDQ_LOG("%s notifier:0x%p\n", __func__, notifier);
ret = blocking_notifier_chain_register(&cmdq_status_dump_notifier,
notifier);
if (ret < 0)
CMDQ_ERR("fail to register chanin:0x%p\n", notifier);
}
void cmdq_core_remove_status_dump(struct notifier_block *notifier)
{
s32 ret;
ret = blocking_notifier_chain_unregister(&cmdq_status_dump_notifier,
notifier);
if (ret < 0)
CMDQ_ERR("fail to unregister chanin:0x%p\n", notifier);
}
/* for PMQOS task begin/end */
s32 cmdq_core_register_task_cycle_cb(enum CMDQ_GROUP_ENUM group,
CmdqBeginTaskCB beginTask, CmdqEndTaskCB endTask)
{
struct CmdqCBkStruct *callback;
if (!cmdq_core_is_valid_group(group))
return -EFAULT;
CMDQ_MSG("Register %d group engines' callback begin:%pf end:%pf\n",
group, beginTask, endTask);
callback = &cmdq_group_cb[group];
callback->beginTask = beginTask;
callback->endTask = endTask;
return 0;
}
const char *cmdq_core_parse_op(u32 op_code)
{
switch (op_code) {
case CMDQ_CODE_POLL:
return "POLL";
case CMDQ_CODE_WRITE:
return "WRIT";
case CMDQ_CODE_WFE:
return "SYNC";
case CMDQ_CODE_READ:
return "READ";
case CMDQ_CODE_MOVE:
return "MASK";
case CMDQ_CODE_JUMP:
return "JUMP";
case CMDQ_CODE_EOC:
return "MARK";
case CMDQ_CODE_READ_S:
return "READ_S";
case CMDQ_CODE_WRITE_S:
return "WRITE_S";
case CMDQ_CODE_WRITE_S_W_MASK:
return "WRITE_S with mask";
case CMDQ_CODE_LOGIC:
return "LOGIC";
case CMDQ_CODE_JUMP_C_RELATIVE:
return "JUMP_C related";
case CMDQ_CODE_JUMP_C_ABSOLUTE:
return "JUMP_C absolute";
}
return NULL;
}
static const char *cmdq_core_parse_logic_sop(u32 s_op)
{
switch (s_op) {
case CMDQ_LOGIC_ASSIGN:
return "=";
case CMDQ_LOGIC_ADD:
return "+";
case CMDQ_LOGIC_SUBTRACT:
return "-";
case CMDQ_LOGIC_MULTIPLY:
return "*";
case CMDQ_LOGIC_XOR:
return "^";
case CMDQ_LOGIC_NOT:
return "~";
case CMDQ_LOGIC_OR:
return "|";
case CMDQ_LOGIC_AND:
return "&";
case CMDQ_LOGIC_LEFT_SHIFT:
return "<<";
case CMDQ_LOGIC_RIGHT_SHIFT:
return ">>";
}
return NULL;
}
static const char *cmdq_core_parse_jump_c_sop(u32 s_op)
{
switch (s_op) {
case CMDQ_EQUAL:
return "==";
case CMDQ_NOT_EQUAL:
return "!=";
case CMDQ_GREATER_THAN_AND_EQUAL:
return ">=";
case CMDQ_LESS_THAN_AND_EQUAL:
return "<=";
case CMDQ_GREATER_THAN:
return ">";
case CMDQ_LESS_THAN:
return "<";
}
return NULL;
}
static u32 cmdq_core_interpret_wpr_value_data_register(
const u32 op, u32 arg_value)
{
u32 reg_id = arg_value;
if (op == CMDQ_CODE_WRITE_S || op == CMDQ_CODE_WRITE_S_W_MASK)
reg_id = ((arg_value >> 16) & 0xFFFF);
else if (op == CMDQ_CODE_READ_S)
reg_id = (arg_value & 0xFFFF);
else
reg_id += CMDQ_GPR_V3_OFFSET;
return reg_id;
}
static u32 cmdq_core_interpret_wpr_address_data_register(
const u32 op, u32 arg_addr)
{
u32 reg_id = (arg_addr >> 16) & 0x1F;
if (op == CMDQ_CODE_WRITE_S || op == CMDQ_CODE_WRITE_S_W_MASK ||
op == CMDQ_CODE_READ_S)
reg_id = (arg_addr & 0xFFFF);
else
reg_id += CMDQ_GPR_V3_OFFSET;
return reg_id;
}
s32 cmdq_core_interpret_instruction(char *textBuf, s32 bufLen,
const u32 op, const u32 arg_a, const u32 arg_b)
{
int reqLen = 0;
u32 arg_addr, arg_value;
u32 arg_addr_type, arg_value_type;
u32 reg_addr;
u32 reg_id, use_mask;
const u32 addr_mask = 0xFFFFFFFE;
switch (op) {
case CMDQ_CODE_MOVE:
if (1 & (arg_a >> 23)) {
reg_id = ((arg_a >> 16) & 0x1f) + CMDQ_GPR_V3_OFFSET;
reqLen = snprintf(textBuf, bufLen,
"MOVE:0x%08x to Reg%d\n", arg_b, reg_id);
} else {
reqLen = snprintf(textBuf, bufLen,
"Set MASK:0x%08x\n", arg_b);
}
if (reqLen >= bufLen)
pr_debug("%s:%d reqLen:%d over bufLen:%d\n",
__func__, __LINE__, reqLen, bufLen);
break;
case CMDQ_CODE_READ:
case CMDQ_CODE_WRITE:
case CMDQ_CODE_POLL:
case CMDQ_CODE_READ_S:
case CMDQ_CODE_WRITE_S:
case CMDQ_CODE_WRITE_S_W_MASK:
reqLen = snprintf(textBuf, bufLen, "%s: ",
cmdq_core_parse_op(op));
if (reqLen >= bufLen)
pr_debug("%s:%d reqLen:%d over bufLen:%d\n",
__func__, __LINE__, reqLen, bufLen);
bufLen -= reqLen;
textBuf += reqLen;
if (op == CMDQ_CODE_READ_S) {
arg_addr = (arg_a & CMDQ_ARG_A_SUBSYS_MASK) |
((arg_b >> 16) & 0xFFFF);
arg_addr_type = arg_a & (1 << 22);
arg_value = arg_a & 0xFFFF;
arg_value_type = arg_a & (1 << 23);
} else {
arg_addr = arg_a;
arg_addr_type = arg_a & (1 << 23);
arg_value = arg_b;
arg_value_type = arg_a & (1 << 22);
}
/* data (value) */
if (arg_value_type != 0) {
reg_id = cmdq_core_interpret_wpr_value_data_register(
op, arg_value);
reqLen = snprintf(textBuf, bufLen, "Reg%d, ", reg_id);
} else {
reqLen = snprintf(textBuf, bufLen, "0x%08x, ",
arg_value);
}
if (reqLen >= bufLen)
pr_debug("%s:%d reqLen:%d over bufLen:%d\n",
__func__, __LINE__, reqLen, bufLen);
bufLen -= reqLen;
textBuf += reqLen;
/* address */
if (arg_addr_type != 0) {
reg_id = cmdq_core_interpret_wpr_address_data_register(
op, arg_addr);
reqLen = snprintf(textBuf, bufLen, "Reg%d, ", reg_id);
} else {
reg_addr = cmdq_core_subsys_to_reg_addr(arg_addr);
reqLen = snprintf(textBuf, bufLen,
"addr:0x%08x [%s], ", reg_addr & addr_mask,
cmdq_get_func()->parseModule(reg_addr));
}
if (reqLen >= bufLen)
pr_debug("%s:%d reqLen:%d over bufLen:%d\n",
__func__, __LINE__, reqLen, bufLen);
bufLen -= reqLen;
textBuf += reqLen;
use_mask = (arg_addr & 0x1);
if (op == CMDQ_CODE_WRITE_S_W_MASK)
use_mask = 1;
else if (op == CMDQ_CODE_READ_S || op == CMDQ_CODE_WRITE_S)
use_mask = 0;
reqLen = snprintf(textBuf, bufLen, "use_mask:%d\n", use_mask);
if (reqLen >= bufLen)
pr_debug("%s:%d reqLen:%d over bufLen:%d\n",
__func__, __LINE__, reqLen, bufLen);
break;
case CMDQ_CODE_JUMP:
if (arg_a) {
if (arg_a & (1 << 22)) {
/* jump by register */
reqLen = snprintf(textBuf, bufLen,
"JUMP(register): Reg%d\n", arg_b);
} else {
/* absolute */
reqLen = snprintf(textBuf, bufLen,
"JUMP(absolute):0x%08x\n", arg_b);
}
} else {
/* relative */
if ((s32) arg_b >= 0) {
reqLen = snprintf(textBuf, bufLen,
"JUMP(relative):+%d\n",
(s32)CMDQ_REG_REVERT_ADDR(arg_b));
} else {
reqLen = snprintf(textBuf, bufLen,
"JUMP(relative):%d\n",
(s32)CMDQ_REG_REVERT_ADDR(arg_b));
}
}
if (reqLen >= bufLen)
pr_debug("%s:%d reqLen:%d over bufLen:%d\n",
__func__, __LINE__, reqLen, bufLen);
break;
case CMDQ_CODE_WFE:
if (arg_b == 0x80008001) {
reqLen = snprintf(textBuf, bufLen,
"Wait And Clear Event:%s\n",
cmdq_core_get_event_name(arg_a));
} else if (arg_b == 0x80000000) {
reqLen = snprintf(textBuf, bufLen, "Clear Event:%s\n",
cmdq_core_get_event_name(arg_a));
} else if (arg_b == 0x80010000) {
reqLen = snprintf(textBuf, bufLen, "Set Event:%s\n",
cmdq_core_get_event_name(arg_a));
} else if (arg_b == 0x00008001) {
reqLen = snprintf(textBuf, bufLen,
"Wait No Clear Event:%s\n",
cmdq_core_get_event_name(arg_a));
} else {
reqLen = snprintf(textBuf, bufLen,
"SYNC:%s, upd:%d op:%d val:%d wait:%d wop:%d val:%d\n",
cmdq_core_get_event_name(arg_a),
(arg_b >> 31) & 0x1,
(arg_b >> 28) & 0x7,
(arg_b >> 16) & 0xFFF,
(arg_b >> 15) & 0x1,
(arg_b >> 12) & 0x7, (arg_b >> 0) & 0xFFF);
}
if (reqLen >= bufLen)
pr_debug("%s:%d reqLen:%d over bufLen:%d\n",
__func__, __LINE__, reqLen, bufLen);
break;
case CMDQ_CODE_EOC:
if (arg_a == 0 && arg_b == 0x00000001) {
reqLen = snprintf(textBuf, bufLen, "EOC\n");
} else {
reqLen = snprintf(textBuf, bufLen, "MARKER:");
if (reqLen >= bufLen)
pr_debug("%s:%d reqLen:%d over bufLen:%d\n",
__func__, __LINE__, reqLen, bufLen);
bufLen -= reqLen;
textBuf += reqLen;
if (arg_b == 0x00100000) {
reqLen = snprintf(textBuf, bufLen, " Disable");
} else if (arg_b == 0x00130000) {
reqLen = snprintf(textBuf, bufLen, " Enable");
} else {
reqLen = snprintf(textBuf, bufLen,
"no_suspnd:%d no_inc:%d m:%d m_en:%d prefetch:%d irq:%d\n",
(arg_a & (1 << 21)) > 0,
(arg_a & (1 << 16)) > 0,
(arg_b & (1 << 20)) > 0,
(arg_b & (1 << 17)) > 0,
(arg_b & (1 << 16)) > 0,
(arg_b & (1 << 0)) > 0);
}
}
if (reqLen >= bufLen)
pr_debug("%s:%d reqLen:%d over bufLen:%d\n",
__func__, __LINE__, reqLen, bufLen);
break;
case CMDQ_CODE_LOGIC:
{
const u32 subsys_bit =
cmdq_get_func()->getSubsysLSBArgA();
const u32 s_op =
(arg_a & CMDQ_ARG_A_SUBSYS_MASK) >> subsys_bit;
reqLen = snprintf(textBuf, bufLen, "%s: ",
cmdq_core_parse_op(op));
if (reqLen >= bufLen)
pr_debug("%s:%d reqLen:%d over bufLen:%d\n",
__func__, __LINE__, reqLen, bufLen);
bufLen -= reqLen;
textBuf += reqLen;
reqLen = snprintf(textBuf, bufLen, "Reg%d = ",
(arg_a & 0xFFFF));
if (reqLen >= bufLen)
pr_debug("%s:%d reqLen:%d over bufLen:%d\n",
__func__, __LINE__, reqLen, bufLen);
bufLen -= reqLen;
textBuf += reqLen;
if (s_op == CMDQ_LOGIC_ASSIGN) {
reqLen = snprintf(textBuf, bufLen, "0x%08x\n",
arg_b);
if (reqLen >= bufLen)
pr_debug("reqLen:%d over bufLen:%d\n",
reqLen, bufLen);
bufLen -= reqLen;
textBuf += reqLen;
} else if (s_op == CMDQ_LOGIC_NOT) {
const u32 arg_b_type = arg_a & (1 << 22);
const u32 arg_b_i = (arg_b >> 16) & 0xFFFF;
if (arg_b_type != 0)
reqLen = snprintf(textBuf, bufLen,
"~Reg%d\n", arg_b_i);
else
reqLen = snprintf(textBuf, bufLen,
"~%d\n", arg_b_i);
if (reqLen >= bufLen)
pr_debug("reqLen:%d over bufLen:%d\n",
reqLen, bufLen);
bufLen -= reqLen;
textBuf += reqLen;
} else {
const u32 arg_b_i = (arg_b >> 16) & 0xFFFF;
const u32 arg_c_i = arg_b & 0xFFFF;
const u32 arg_b_type = arg_a & (1 << 22);
const u32 arg_c_type = arg_a & (1 << 21);
/* arg_b_i */
if (arg_b_type != 0) {
reqLen = snprintf(textBuf, bufLen,
"Reg%d ", arg_b_i);
} else {
reqLen = snprintf(textBuf, bufLen,
"%d ", arg_b_i);
}
if (reqLen >= bufLen)
pr_debug("reqLen:%d over bufLen:%d\n",
reqLen, bufLen);
bufLen -= reqLen;
textBuf += reqLen;
/* operator */
reqLen = snprintf(textBuf, bufLen, "%s ",
cmdq_core_parse_logic_sop(s_op));
if (reqLen >= bufLen)
pr_debug("reqLen:%d over bufLen:%d\n",
reqLen, bufLen);
bufLen -= reqLen;
textBuf += reqLen;
/* arg_c_i */
if (arg_c_type != 0) {
reqLen = snprintf(textBuf, bufLen,
"Reg%d\n", arg_c_i);
} else {
reqLen = snprintf(textBuf, bufLen,
"%d\n", CMDQ_REG_REVERT_ADDR(
arg_c_i));
}
if (reqLen >= bufLen)
pr_debug("reqLen:%d over bufLen:%d\n",
reqLen, bufLen);
bufLen -= reqLen;
textBuf += reqLen;
}
}
break;
case CMDQ_CODE_JUMP_C_RELATIVE:
case CMDQ_CODE_JUMP_C_ABSOLUTE:
{
const u32 subsys_bit =
cmdq_get_func()->getSubsysLSBArgA();
const u32 s_op =
(arg_a & CMDQ_ARG_A_SUBSYS_MASK) >> subsys_bit;
const u32 arg_a_i = arg_a & 0xFFFF;
const u32 arg_b_i = (arg_b >> 16) & 0xFFFF;
const u32 arg_c_i = arg_b & 0xFFFF;
const u32 arg_a_type = arg_a & (1 << 23);
const u32 arg_b_type = arg_a & (1 << 22);
const u32 arg_c_type = arg_a & (1 << 21);
reqLen = snprintf(textBuf, bufLen, "%s: if (",
cmdq_core_parse_op(op));
if (reqLen >= bufLen)
pr_debug("%s:%d reqLen:%d over bufLen:%d\n",
__func__, __LINE__, reqLen, bufLen);
bufLen -= reqLen;
textBuf += reqLen;
/* arg_b_i */
if (arg_b_type != 0) {
reqLen = snprintf(textBuf, bufLen, "Reg%d ",
arg_b_i);
} else {
reqLen = snprintf(textBuf, bufLen, "%d ",
arg_b_i);
}
if (reqLen >= bufLen)
pr_debug("%s:%d reqLen:%d over bufLen:%d\n",
__func__, __LINE__, reqLen, bufLen);
bufLen -= reqLen;
textBuf += reqLen;
/* operator */
reqLen = snprintf(textBuf, bufLen, "%s ",
cmdq_core_parse_jump_c_sop(s_op));
if (reqLen >= bufLen)
pr_debug("%s:%d reqLen:%d over bufLen:%d\n",
__func__, __LINE__, reqLen, bufLen);
bufLen -= reqLen;
textBuf += reqLen;
/* arg_c_i */
if (arg_c_type != 0) {
reqLen = snprintf(textBuf, bufLen,
"Reg%d) jump ", arg_c_i);
} else {
reqLen = snprintf(textBuf, bufLen,
"%d) jump ", CMDQ_REG_REVERT_ADDR(
arg_c_i));
}
if (reqLen >= bufLen)
pr_debug("%s:%d reqLen:%d over bufLen:%d\n",
__func__, __LINE__, reqLen, bufLen);
bufLen -= reqLen;
textBuf += reqLen;
/* jump to */
if (arg_a_type != 0) {
reqLen = snprintf(textBuf, bufLen,
"Reg%d\n", arg_a_i);
} else {
reqLen = snprintf(textBuf, bufLen,
"+%d\n", arg_a_i);
}
if (reqLen >= bufLen)
pr_debug("%s:%d reqLen:%d over bufLen:%d\n",
__func__, __LINE__, reqLen, bufLen);
bufLen -= reqLen;
textBuf += reqLen;
}
break;
default:
reqLen = snprintf(textBuf, bufLen,
"UNDEFINED (0x%02x 0x%08x%08x)\n",
op, arg_a, arg_b);
if (reqLen >= bufLen)
pr_debug("%s:%d reqLen:%d over bufLen:%d\n",
__func__, __LINE__, reqLen, bufLen);
break;
}
return reqLen;
}
s32 cmdq_core_parse_instruction(const u32 *pCmd, char *textBuf, int bufLen)
{
int reqLen = 0;
const u32 op = (pCmd[1] & 0xFF000000) >> 24;
const u32 arg_a = pCmd[1] & (~0xFF000000);
const u32 arg_b = pCmd[0];
reqLen = cmdq_core_interpret_instruction(
textBuf, bufLen, op, arg_a, arg_b);
return reqLen;
}
bool cmdq_core_should_print_msg(void)
{
bool logLevel = (cmdq_ctx.logLevel & (1 << CMDQ_LOG_LEVEL_MSG)) ?
(1) : (0);
return logLevel;
}
bool cmdq_core_should_full_error(void)
{
bool logLevel = (cmdq_ctx.logLevel &
(1 << CMDQ_LOG_LEVEL_FULL_ERROR)) ? (1) : (0);
return logLevel;
}
bool cmdq_core_should_pmqos_log(void)
{
return cmdq_ctx.logLevel & (1 << CMDQ_LOG_LEVEL_PMQOS);
}
bool cmdq_core_should_secure_log(void)
{
return cmdq_ctx.logLevel & (1 << CMDQ_LOG_LEVEL_SECURE);
}
bool cmdq_core_aee_enable(void)
{
return cmdq_ctx.aee;
}
void cmdq_core_set_aee(bool enable)
{
cmdq_ctx.aee = enable;
}
bool cmdq_core_met_enabled(void)
{
return cmdq_ctx.enableProfile & (1 << CMDQ_PROFILE_MET);
}
bool cmdq_core_ftrace_enabled(void)
{
return cmdq_ctx.enableProfile & (1 << CMDQ_PROFILE_FTRACE);
}
bool cmdq_core_profile_exec_enabled(void)
{
return cmdq_ctx.enableProfile & (1 << CMDQ_PROFILE_EXEC);
}
bool cmdq_core_profile_pqreadback_once_enabled(void)
{
bool en = cmdq_ctx.enableProfile & (1 << CMDQ_PROFILE_PQRB_ONCE);
if (en)
cmdq_ctx.enableProfile = cmdq_ctx.enableProfile &
~(1 << CMDQ_PROFILE_PQRB_ONCE);
return en;
}
bool cmdq_core_profile_pqreadback_enabled(void)
{
return cmdq_ctx.enableProfile & (1 << CMDQ_PROFILE_PQRB);
}
bool cmdq_core_ftrace2_enabled(void)
{
return cmdq_ctx.enableProfile & (1 << CMDQ_PROFILE_FTRACE2);
}
void cmdq_long_string_init(bool force, char *buf, u32 *offset, s32 *max_size)
{
buf[0] = '\0';
*offset = 0;
if (force || cmdq_core_should_print_msg())
*max_size = CMDQ_LONGSTRING_MAX - 1;
else
*max_size = 0;
}
void cmdq_long_string(char *buf, u32 *offset, s32 *max_size,
const char *string, ...)
{
int msg_len;
va_list arg_ptr;
char *buffer;
if (*max_size <= 0)
return;
va_start(arg_ptr, string);
buffer = buf + (*offset);
msg_len = vsnprintf(buffer, *max_size, string, arg_ptr);
if (msg_len >= *max_size)
pr_debug("%s:%d msg_len:%d over max_size:%d\n%s\n",
__func__, __LINE__, msg_len, *max_size, buffer);
*max_size -= msg_len;
if (*max_size < 0)
*max_size = 0;
*offset += msg_len;
va_end(arg_ptr);
}
s32 cmdq_core_reg_dump_begin(u32 taskID, u32 *regCount, u32 **regAddress)
{
if (!cmdq_debug_cb.beginDebugRegDump) {
CMDQ_ERR("beginDebugRegDump not registered\n");
return -EFAULT;
}
return cmdq_debug_cb.beginDebugRegDump(taskID, regCount,
regAddress);
}
s32 cmdq_core_reg_dump_end(u32 taskID, u32 regCount, u32 *regValues)
{
if (!cmdq_debug_cb.endDebugRegDump) {
CMDQ_ERR("endDebugRegDump not registered\n");
return -EFAULT;
}
return cmdq_debug_cb.endDebugRegDump(taskID, regCount, regValues);
}
int cmdq_core_print_record_title(char *_buf, int bufLen)
{
int length = 0;
char *buf;
buf = _buf;
length = snprintf(buf, bufLen,
"index,pid,scn,flag,task_pri,is_sec,size,thr#,thr_pri,");
if (length >= bufLen)
pr_debug("%s:%d length:%d over bufLen:%d\n%s\n",
__func__, __LINE__, length, bufLen, buf);
bufLen -= length;
buf += length;
length = snprintf(buf, bufLen,
"submit,acq_thr,irq_time,begin_wait,exec_time,buf_alloc,buf_rec,buf_rel,total_time,start,end,jump\n");
if (length >= bufLen)
pr_debug("%s:%d length:%d over bufLen:%d\n%s\n",
__func__, __LINE__, length, bufLen, buf);
bufLen -= length;
buf += length;
length = (buf - _buf);
return length;
}
static int cmdq_core_print_record(const struct RecordStruct *pRecord,
int index, char *_buf, int bufLen)
{
int length = 0;
char *unit[5] = { "ms", "ms", "ms", "ms", "ms" };
s32 IRQTime;
s32 execTime;
s32 beginWaitTime;
s32 totalTime;
s32 acquireThreadTime;
unsigned long rem_nsec;
CMDQ_TIME submitTimeSec;
char *buf;
s32 profileMarkerCount;
s32 i;
rem_nsec = 0;
submitTimeSec = pRecord->submit;
rem_nsec = do_div(submitTimeSec, 1000000000);
buf = _buf;
CMDQ_GET_TIME_IN_MS(pRecord->submit, pRecord->done, totalTime);
CMDQ_GET_TIME_IN_MS(pRecord->submit, pRecord->trigger,
acquireThreadTime);
CMDQ_GET_TIME_IN_MS(pRecord->submit, pRecord->beginWait,
beginWaitTime);
CMDQ_GET_TIME_IN_MS(pRecord->trigger, pRecord->gotIRQ, IRQTime);
CMDQ_GET_TIME_IN_MS(pRecord->trigger, pRecord->wakedUp, execTime);
/* detect us interval */
if (acquireThreadTime == 0) {
CMDQ_GET_TIME_IN_US_PART(pRecord->submit, pRecord->trigger,
acquireThreadTime);
unit[0] = "us";
}
if (IRQTime == 0) {
CMDQ_GET_TIME_IN_US_PART(pRecord->trigger, pRecord->gotIRQ,
IRQTime);
unit[1] = "us";
}
if (beginWaitTime == 0) {
CMDQ_GET_TIME_IN_US_PART(pRecord->submit, pRecord->beginWait,
beginWaitTime);
unit[2] = "us";
}
if (execTime == 0) {
CMDQ_GET_TIME_IN_US_PART(pRecord->trigger, pRecord->wakedUp,
execTime);
unit[3] = "us";
}
if (totalTime == 0) {
CMDQ_GET_TIME_IN_US_PART(pRecord->submit, pRecord->done,
totalTime);
unit[4] = "us";
}
/* pRecord->priority for task priority */
/* when pRecord->is_secure is 0 for secure task */
length = snprintf(buf, bufLen,
"%4d,%5d,%2d,0x%012llx,%2d,%d,%d,%02d,%02d,",
index, pRecord->user, pRecord->scenario, pRecord->engineFlag,
pRecord->priority, pRecord->is_secure, pRecord->size,
pRecord->thread,
cmdq_get_func()->priority(pRecord->scenario));
if (length >= bufLen)
pr_debug("%s:%d length:%d over bufLen:%d\n%s\n",
__func__, __LINE__, length, bufLen, buf);
bufLen -= length;
buf += length;
length = snprintf(buf, bufLen,
"%5llu.%06lu,%4d%s,%4d%s,%4d%s,%4d%s,%dus,%dus,%dus,%4d%s,",
submitTimeSec, rem_nsec / 1000, acquireThreadTime, unit[0],
IRQTime, unit[1], beginWaitTime, unit[2], execTime, unit[3],
pRecord->durAlloc, pRecord->durReclaim, pRecord->durRelease,
totalTime, unit[4]);
if (length >= bufLen)
pr_debug("%s:%d length:%d over bufLen:%d\n%s\n",
__func__, __LINE__, length, bufLen, buf);
bufLen -= length;
buf += length;
/* record address */
length = snprintf(buf, bufLen,
"0x%08x,0x%08x,0x%08x",
pRecord->start, pRecord->end, pRecord->jump);
if (length >= bufLen)
pr_debug("%s:%d length:%d over bufLen:%d\n%s\n",
__func__, __LINE__, length, bufLen, buf);
bufLen -= length;
buf += length;
profileMarkerCount = pRecord->profileMarkerCount;
if (profileMarkerCount > CMDQ_MAX_PROFILE_MARKER_IN_TASK)
profileMarkerCount = CMDQ_MAX_PROFILE_MARKER_IN_TASK;
for (i = 0; i < profileMarkerCount; i++) {
length = snprintf(buf, bufLen, ",%s,%lld",
pRecord->profileMarkerTag[i],
pRecord->profileMarkerTimeNS[i]);
if (length >= bufLen)
pr_debug("%s:%d length:%d over bufLen:%d\n%s\n",
__func__, __LINE__, length, bufLen, buf);
bufLen -= length;
buf += length;
}
length = snprintf(buf, bufLen, "\n");
if (length >= bufLen)
pr_debug("%s:%d length:%d over bufLen:%d\n%s\n",
__func__, __LINE__, length, bufLen, buf);
bufLen -= length;
buf += length;
length = (buf - _buf);
return length;
}
int cmdq_core_print_record_seq(struct seq_file *m, void *v)
{
unsigned long flags;
s32 index;
s32 numRec;
struct RecordStruct record;
char msg[160] = { 0 };
/* we try to minimize time spent in spin lock */
/* since record is an array so it is okay to */
/* allow displaying an out-of-date entry. */
spin_lock_irqsave(&cmdq_record_lock, flags);
numRec = cmdq_ctx.recNum;
index = cmdq_ctx.lastID - 1;
spin_unlock_irqrestore(&cmdq_record_lock, flags);
/* we print record in reverse order. */
cmdq_core_print_record_title(msg, sizeof(msg));
seq_printf(m, "%s", msg);
for (; numRec > 0; --numRec, --index) {
if (index >= CMDQ_MAX_RECORD_COUNT)
index = 0;
else if (index < 0)
index = CMDQ_MAX_RECORD_COUNT - 1;
spin_lock_irqsave(&cmdq_record_lock, flags);
record = cmdq_ctx.record[index];
spin_unlock_irqrestore(&cmdq_record_lock, flags);
cmdq_core_print_record(&record, index, msg, sizeof(msg));
seq_printf(m, "%s", msg);
}
return 0;
}
static void cmdq_core_print_thd_usage(struct seq_file *m, void *v,
u32 thread_idx)
{
void *va = NULL;
dma_addr_t pa = 0;
u32 *pcva, pcpa = 0;
u32 insts[2] = {0};
char parsed_inst[128] = { 0 };
struct cmdq_core_thread *thread = &cmdq_ctx.thread[thread_idx];
struct cmdqRecStruct *task;
u32 counter = 0;
seq_printf(m, "====== Thread %d Usage =======\n", thread_idx);
#if 0
seq_printf(m, "Wait Cookie:%d Next Cookie:%d\n",
thread->waitCookie, thread->nextCookie);
#endif
seq_printf(m, "acquire:%u scenario:%d used:%s\n",
thread->acquire, thread->scenario,
thread->used ? "true" : "false");
mutex_lock(&cmdq_handle_list_mutex);
mutex_lock(&cmdq_thread_mutex);
list_for_each_entry(task, &cmdq_ctx.handle_active, list_entry) {
if (task->thread != thread_idx)
continue;
/* dump task basic info */
seq_printf(m,
"Index:%u handle:0x%p Pid:%d Name:%s Scn:%d",
counter, task, task->caller_pid,
task->caller_name, task->scenario);
/* here only print first buffer to reduce log */
cmdq_pkt_get_first_buffer(task, &va, &pa);
seq_printf(m,
" va:0x%p pa:%pa size:%zu",
va, &pa, task->pkt->cmd_buf_size);
if (task->cmd_end) {
seq_printf(m,
" Last Command:0x%08x:0x%08x",
task->cmd_end[0], task->cmd_end[1]);
}
seq_puts(m, "\n");
/* dump PC info */
pcva = cmdq_core_get_pc_inst(task, thread_idx, insts, &pcpa);
if (pcva) {
cmdq_core_parse_instruction(
pcva, parsed_inst, sizeof(parsed_inst));
seq_printf(m,
"PC:0x%p(0x%08x) 0x%08x:0x%08x => %s",
pcva, pcpa, insts[0], insts[1],
parsed_inst);
} else {
seq_puts(m, "PC(VA): Not available\n");
}
counter++;
}
mutex_unlock(&cmdq_thread_mutex);
mutex_unlock(&cmdq_handle_list_mutex);
}
/* TODO: move all engine to cmdq_mdp_common.c */
struct EngineStruct *cmdq_mdp_get_engines(void);
int cmdq_core_print_status_seq(struct seq_file *m, void *v)
{
s32 index = 0;
struct cmdqRecStruct *handle = NULL;
struct cmdq_client *client = NULL;
struct cmdq_pkt_buffer *buf;
const u32 max_thread_count = cmdq_dev_get_thread_count();
/* Save command buffer dump */
if (cmdq_command_dump.count > 0) {
s32 buffer_id;
seq_puts(m, "================= [CMDQ] Dump Command Buffer =================\n");
/* use which mutex? */
for (buffer_id = 0; buffer_id < cmdq_command_dump.bufferSize;
buffer_id++)
seq_printf(m, "%c",
cmdq_command_dump.cmdqString[buffer_id]);
seq_puts(m, "\n=============== [CMDQ] Dump Command Buffer END ===============\n\n\n");
}
#ifdef CMDQ_PWR_AWARE
/* note for constatnt format (without a % substitution),
* use seq_puts to speed up outputs
*/
seq_puts(m, "====== Clock Status =======\n");
cmdq_get_func()->printStatusSeqClock(m);
#endif
seq_puts(m, "====== DMA Mask Status =======\n");
seq_printf(m, "dma_set_mask result:%d\n",
cmdq_dev_get_dma_mask_result());
/* call to dump other infos */
blocking_notifier_call_chain(&cmdq_status_dump_notifier, 0, m);
/* finally dump all active handles */
mutex_lock(&cmdq_handle_list_mutex);
index = 0;
list_for_each_entry(handle, &cmdq_ctx.handle_active, list_entry) {
u32 irq = 0;
seq_printf(m,
"====== Handle(%d) 0x%p pkt 0x%p Usage =======\n",
index, handle, handle->pkt);
seq_printf(m, "State:%d Size:%zu\n",
handle->state, handle->pkt->cmd_buf_size);
list_for_each_entry(buf, &handle->pkt->buf, list_entry) {
seq_printf(m, "va:0x%p pa:%pa\n",
buf->va_base, &buf->pa_base);
}
client = cmdq_clients[(u32)handle->thread];
cmdq_task_get_thread_irq(client->chan, &irq);
seq_printf(m,
"Scenario:%d Priority:%d Flag:0x%llx va end:0x%p IRQ:0x%x\n",
handle->scenario, 0, handle->engineFlag,
handle->cmd_end, irq);
seq_printf(m,
"Reorder:%d Trigger:%lld IRQ:0x%llx Wait:%lld Wake Up:%lld\n",
handle->reorder,
handle->trigger, handle->gotIRQ,
handle->beginWait, handle->wakedUp);
++index;
}
seq_printf(m, "====== Total %d Handle =======\n", index);
mutex_unlock(&cmdq_handle_list_mutex);
for (index = 0; index < max_thread_count; index++)
cmdq_core_print_thd_usage(m, v, index);
return 0;
}
#if 0
static s32 cmdq_core_thread_exec_counter(const s32 thread)
{
#ifdef CMDQ_SECURE_PATH_SUPPORT
return (!cmdq_get_func()->isSecureThread(thread)) ?
(CMDQ_GET_COOKIE_CNT(thread)) :
(cmdq_sec_get_secure_thread_exec_counter(thread));
#else
return CMDQ_GET_COOKIE_CNT(thread);
#endif
}
#endif
static s32 cmdq_core_get_thread_id(s32 scenario)
{
return cmdq_get_func()->getThreadID(scenario, false);
}
static void cmdq_core_dump_thread(const struct cmdqRecStruct *handle,
s32 thread, bool dump_irq, const char *tag)
{
u32 value[15] = { 0 };
if (thread == CMDQ_INVALID_THREAD)
return;
#if IS_ENABLED(CONFIG_MACH_MT6885) || IS_ENABLED(CONFIG_MACH_MT6893)
if (thread <= 7)
return;
#endif
/* normal thread */
value[0] = cmdq_core_get_pc(thread);
value[1] = cmdq_core_get_end(thread);
value[2] = CMDQ_REG_GET32(CMDQ_THR_IRQ_STATUS(thread));
value[3] = CMDQ_REG_GET32(CMDQ_THR_WAIT_TOKEN(thread));
value[4] = CMDQ_GET_COOKIE_CNT(thread);
value[5] = CMDQ_REG_GET32(CMDQ_THR_INST_CYCLES(thread));
value[6] = CMDQ_REG_GET32(CMDQ_THR_CURR_STATUS(thread));
value[7] = CMDQ_REG_GET32(CMDQ_THR_IRQ_ENABLE(thread));
value[8] = CMDQ_REG_GET32(CMDQ_THR_ENABLE_TASK(thread));
value[9] = CMDQ_REG_GET32(CMDQ_THR_WARM_RESET(thread));
value[10] = CMDQ_REG_GET32(CMDQ_THR_SUSPEND_TASK(thread));
value[11] = CMDQ_REG_GET32(CMDQ_THR_SECURITY(thread));
value[12] = CMDQ_REG_GET32(CMDQ_THR_CFG(thread));
value[13] = CMDQ_REG_GET32(CMDQ_THR_PREFETCH(thread));
value[14] = CMDQ_REG_GET32(CMDQ_THR_INST_THRESX(thread));
CMDQ_LOG(
"[%s]===== Error Thread Status index:%d enabled:%d scenario:%d =====\n",
tag, thread, value[8], cmdq_ctx.thread[(u32)thread].scenario);
CMDQ_LOG(
"[%s]PC:0x%08x End:0x%08x Wait Token:0x%08x IRQ:0x%x IRQ_EN:0x%x cookie:%u\n",
tag, value[0], value[1], value[3], value[2], value[7],
value[4]);
/* TODO: support cookie */
#if 0
CMDQ_LOG(
"[%s]Curr Cookie:%d Wait Cookie:%d Next Cookie:%d Task Count:%d engineFlag:0x%llx\n",
tag, value[4], pThread->waitCookie, pThread->nextCookie,
pThread->taskCount, pThread->engineFlag);
#endif
CMDQ_LOG(
"[%s]Timeout Cycle:%d Status:0x%x reset:0x%x Suspend:%d sec:%d cfg:%d prefetch:%d thrsex:%d\n",
tag, value[5], value[6], value[9], value[10],
value[11], value[12], value[13], value[14]);
CMDQ_LOG("[%s]spr:%#x %#x %#x %#x\n",
tag, CMDQ_REG_GET32(CMDQ_THR_SPR0(thread)),
CMDQ_REG_GET32(CMDQ_THR_SPR1(thread)),
CMDQ_REG_GET32(CMDQ_THR_SPR2(thread)),
CMDQ_REG_GET32(CMDQ_THR_SPR3(thread)));
/* if pc match end and irq flag on, dump irq status */
if (dump_irq && value[0] == value[1] && value[2] == 1)
#ifdef CONFIG_MTK_GIC_V3_EXT
mt_irq_dump_status(cmdq_dev_get_irq_id());
#else
CMDQ_LOG("gic dump not support irq id:%u\n",
cmdq_dev_get_irq_id());
#endif
}
void cmdq_core_dump_trigger_loop_thread(const char *tag)
{
u32 i;
const u32 max_thread_count = cmdq_dev_get_thread_count();
u32 val;
const u32 evt_rdma = CMDQ_EVENT_DISP_RDMA0_EOF;
s32 static_id = cmdq_core_get_thread_id(CMDQ_SCENARIO_TRIGGER_LOOP);
/* dump trigger loop */
for (i = 0; i < max_thread_count; i++) {
if (cmdq_ctx.thread[i].scenario !=
CMDQ_SCENARIO_TRIGGER_LOOP &&
i != static_id)
continue;
cmdq_core_dump_thread(NULL, i, false, tag);
cmdq_core_dump_pc(NULL, i, tag);
val = cmdqCoreGetEvent(evt_rdma);
CMDQ_LOG("[%s]CMDQ_EVENT_DISP_RDMA0_EOF is %d\n", tag, val);
break;
}
}
s32 cmdq_core_save_first_dump(const char *format, ...)
{
va_list args;
va_start(args, format);
cmdq_util_error_save_lst(format, args);
va_end(args);
return 0;
}
const char *cmdq_core_query_first_err_mod(void)
{
u8 i;
for (i = 0; i < ARRAY_SIZE(cmdq_clients); i++)
if (cmdq_clients[i])
return cmdq_util_get_first_err_mod(
cmdq_clients[i]->chan);
return NULL;
}
void cmdq_core_hex_dump_to_buffer(const void *buf, size_t len, int rowsize,
int groupsize, char *linebuf, size_t linebuflen)
{
const u8 *ptr = buf;
u8 ch;
int j, lx = 0;
if (rowsize != 16 && rowsize != 32)
rowsize = 16;
if (!len)
goto nil;
if (len > rowsize) /* limit to one line at a time */
len = rowsize;
if ((len % groupsize) != 0) /* no mixed size output */
groupsize = 1;
switch (groupsize) {
case 8:{
const u64 *ptr8 = buf;
int ngroups = len / groupsize;
for (j = 0; j < ngroups; j++)
lx += scnprintf(linebuf + lx, linebuflen - lx,
"%s%16.16llx", j ? " " : "",
(unsigned long long)*(ptr8 + j));
break;
}
case 4:{
const u32 *ptr4 = buf;
int ngroups = len / groupsize;
for (j = 0; j < ngroups; j++)
lx += scnprintf(linebuf + lx, linebuflen - lx,
"%s%8.8x", j ? " " : "", *(ptr4 + j));
break;
}
case 2:{
const u16 *ptr2 = buf;
int ngroups = len / groupsize;
for (j = 0; j < ngroups; j++)
lx += scnprintf(linebuf + lx, linebuflen - lx,
"%s%4.4x", j ? " " : "", *(ptr2 + j));
break;
}
default:
for (j = 0; (j < len) && (lx + 3) <= linebuflen; j++) {
ch = ptr[j];
linebuf[lx++] = hex_asc_hi(ch);
linebuf[lx++] = hex_asc_lo(ch);
linebuf[lx++] = ' ';
}
if (j)
lx--;
break;
}
nil:
linebuf[lx++] = '\0';
}
static void *mdp_pool_alloc_impl(struct dma_pool *pool,
dma_addr_t *pa_out, atomic_t *cnt, u32 limit)
{
void *va;
dma_addr_t pa;
if (atomic_inc_return(cnt) > limit) {
/* not use pool, decrease to value before call */
atomic_dec(cnt);
return NULL;
}
va = dma_pool_alloc(pool, GFP_KERNEL, &pa);
if (!va) {
atomic_dec(cnt);
cmdq_err(
"alloc buffer from pool fail va:0x%p pa:%pa pool:0x%p count:%d",
va, &pa, pool,
(s32)atomic_read(cnt));
return NULL;
}
*pa_out = pa;
return va;
}
static void mdp_pool_free_impl(struct dma_pool *pool, void *va,
dma_addr_t pa, atomic_t *cnt)
{
if (unlikely(atomic_read(cnt) <= 0 || !pool)) {
cmdq_err("free pool cnt:%d pool:0x%p",
(s32)atomic_read(cnt), pool);
return;
}
dma_pool_free(pool, va, pa);
atomic_dec(cnt);
}
void *cmdq_core_alloc_hw_buffer_clt(struct device *dev, size_t size,
dma_addr_t *dma_handle, const gfp_t flag, enum CMDQ_CLT_ENUM clt,
bool *pool)
{
s32 alloc_cnt, alloc_max = 1 << 10;
void *va = NULL;
va = mdp_pool_alloc_impl(mdp_rb_pool, dma_handle,
&mdp_rb_pool_cnt, mdp_rb_pool_limit);
if (!va) {
*pool = false;
va = cmdq_core_alloc_hw_buffer(dev, size, dma_handle, flag);
if (!va)
return NULL;
} else {
*pool = true;
}
alloc_cnt = atomic_inc_return(&cmdq_alloc_cnt[CMDQ_CLT_MAX]);
alloc_cnt = atomic_inc_return(&cmdq_alloc_cnt[clt]);
if (alloc_cnt > alloc_max)
CMDQ_ERR(
"clt:%u MDP(1):%u CMDQ(2):%u GNRL(3):%u DISP(4):%u TTL:%u\n",
clt, atomic_read(&cmdq_alloc_cnt[1]),
atomic_read(&cmdq_alloc_cnt[2]),
atomic_read(&cmdq_alloc_cnt[3]),
atomic_read(&cmdq_alloc_cnt[4]),
atomic_read(&cmdq_alloc_cnt[5]));
return va;
}
void *cmdq_core_alloc_hw_buffer(struct device *dev, size_t size,
dma_addr_t *dma_handle, const gfp_t flag)
{
void *pVA;
dma_addr_t PA;
CMDQ_TIME alloc_cost = 0;
do {
PA = 0;
pVA = NULL;
CMDQ_PROF_START(current->pid, __func__);
CMDQ_PROF_MMP(mdp_mmp_get_event()->alloc_buffer,
MMPROFILE_FLAG_START, current->pid, size);
alloc_cost = sched_clock();
pVA = dma_alloc_coherent(dev, size, &PA, flag);
alloc_cost = sched_clock() - alloc_cost;
CMDQ_PROF_MMP(mdp_mmp_get_event()->alloc_buffer,
MMPROFILE_FLAG_END, current->pid, alloc_cost);
CMDQ_PROF_END(current->pid, __func__);
if (alloc_cost > CMDQ_PROFILE_LIMIT_1) {
#if defined(__LP64__) || defined(_LP64)
CMDQ_LOG(
"[warn] alloc buffer (size:%zu) cost %llu us > %ums\n",
size, alloc_cost / 1000,
CMDQ_PROFILE_LIMIT_1 / 1000000);
#else
CMDQ_LOG(
"[warn] alloc buffer (size:%zu) cost %llu us > %llums\n",
size, div_s64(alloc_cost, 1000),
div_s64(CMDQ_PROFILE_LIMIT_1, 1000000));
#endif
}
} while (0);
*dma_handle = PA;
CMDQ_VERBOSE("%s va:0x%p pa:%pa paout:%pa\n",
__func__, pVA, &PA, &(*dma_handle));
return pVA;
}
void cmdq_core_free_hw_buffer_clt(struct device *dev, size_t size,
void *cpu_addr, dma_addr_t dma_handle, enum CMDQ_CLT_ENUM clt,
bool pool)
{
atomic_dec(&cmdq_alloc_cnt[CMDQ_CLT_MAX]);
atomic_dec(&cmdq_alloc_cnt[clt]);
if (pool)
mdp_pool_free_impl(mdp_rb_pool, cpu_addr, dma_handle,
&mdp_rb_pool_cnt);
else
cmdq_core_free_hw_buffer(dev, size, cpu_addr, dma_handle);
}
void cmdq_core_free_hw_buffer(struct device *dev, size_t size,
void *cpu_addr, dma_addr_t dma_handle)
{
CMDQ_TIME free_cost = 0;
CMDQ_VERBOSE("%s va:0x%p pa:%pa\n",
__func__, cpu_addr, &dma_handle);
free_cost = sched_clock();
dma_free_coherent(dev, size, cpu_addr, dma_handle);
free_cost = sched_clock() - free_cost;
if (free_cost > CMDQ_PROFILE_LIMIT_1) {
#if defined(__LP64__) || defined(_LP64)
CMDQ_LOG(
"[warn] free buffer (size:%zu) cost %llu us > %ums\n",
size, free_cost/1000, CMDQ_PROFILE_LIMIT_1 / 1000000);
#else
CMDQ_LOG(
"[warn] free buffer (size:%zu) cost %llu us > %llums\n",
size, div_s64(free_cost, 1000),
div_s64(CMDQ_PROFILE_LIMIT_1, 1000000));
#endif
}
}
int cmdqCoreAllocWriteAddress(u32 count, dma_addr_t *paStart,
enum CMDQ_CLT_ENUM clt, void *fp)
{
unsigned long flags;
struct WriteAddrStruct *pWriteAddr = NULL;
int status = 0;
do {
if (!paStart) {
CMDQ_ERR("invalid output argument\n");
status = -EINVAL;
break;
}
*paStart = 0;
if (!count || count > CMDQ_MAX_WRITE_ADDR_COUNT) {
CMDQ_ERR("invalid alloc write addr count:%u max:%u\n",
count, (u32)CMDQ_MAX_WRITE_ADDR_COUNT);
status = -EINVAL;
break;
}
pWriteAddr = kzalloc(sizeof(struct WriteAddrStruct),
GFP_KERNEL);
if (!pWriteAddr) {
CMDQ_ERR("failed to alloc WriteAddrStruct\n");
status = -ENOMEM;
break;
}
memset(pWriteAddr, 0, sizeof(struct WriteAddrStruct));
pWriteAddr->count = count;
pWriteAddr->va = cmdq_core_alloc_hw_buffer_clt(cmdq_dev_get(),
count * sizeof(u32), &(pWriteAddr->pa), GFP_KERNEL,
clt, &pWriteAddr->pool);
if (current)
pWriteAddr->user = current->pid;
pWriteAddr->fp = fp;
if (!pWriteAddr->va) {
CMDQ_ERR("failed to alloc write buffer\n");
status = -ENOMEM;
break;
}
/* assign output pa */
*paStart = pWriteAddr->pa;
spin_lock_irqsave(&cmdq_write_addr_lock, flags);
list_add_tail(&(pWriteAddr->list_node),
&cmdq_ctx.writeAddrList);
spin_unlock_irqrestore(&cmdq_write_addr_lock, flags);
status = 0;
atomic_inc(&cmdq_ctx.write_addr_cnt);
} while (0);
if (status != 0) {
/* release resources */
if (pWriteAddr && pWriteAddr->va) {
cmdq_core_free_hw_buffer_clt(cmdq_dev_get(),
sizeof(u32) * pWriteAddr->count,
pWriteAddr->va, pWriteAddr->pa, clt,
pWriteAddr->pool);
memset(pWriteAddr, 0, sizeof(struct WriteAddrStruct));
}
kfree(pWriteAddr);
pWriteAddr = NULL;
}
return status;
}
u32 cmdqCoreReadWriteAddress(dma_addr_t pa)
{
struct list_head *p = NULL;
struct WriteAddrStruct *pWriteAddr = NULL;
s32 offset = 0;
u32 value = 0;
unsigned long flags;
/* search for the entry */
spin_lock_irqsave(&cmdq_write_addr_lock, flags);
list_for_each(p, &cmdq_ctx.writeAddrList) {
pWriteAddr = list_entry(p, struct WriteAddrStruct, list_node);
if (!pWriteAddr)
continue;
offset = pa - pWriteAddr->pa;
if (offset >= 0 && (offset / sizeof(u32)) <
pWriteAddr->count) {
CMDQ_VERBOSE(
"%s input:%pa got offset:%d va:%p pa_start:%pa\n",
__func__, &pa, offset,
pWriteAddr->va + offset, &pWriteAddr->pa);
value = *((u32 *)(pWriteAddr->va + offset));
CMDQ_VERBOSE(
"%s found offset:%d va:%p value:0x%08x\n",
__func__, offset, pWriteAddr->va + offset,
value);
break;
}
}
spin_unlock_irqrestore(&cmdq_write_addr_lock, flags);
return value;
}
void cmdqCoreReadWriteAddressBatch(u32 *addrs, u32 count, u32 *val_out)
{
struct WriteAddrStruct *waddr, *cur_waddr = NULL;
unsigned long flags = 0L;
u32 i;
dma_addr_t pa;
/* search for the entry */
spin_lock_irqsave(&cmdq_write_addr_lock, flags);
CMDQ_PROF_MMP(mdp_mmp_get_event()->read_reg,
MMPROFILE_FLAG_START, ((unsigned long)addrs),
(u32)atomic_read(&cmdq_ctx.write_addr_cnt));
for (i = 0; i < count; i++) {
pa = addrs[i];
if (!cur_waddr || pa < cur_waddr->pa ||
pa >= cur_waddr->pa + cur_waddr->count * sizeof(u32)) {
cur_waddr = NULL;
list_for_each_entry(waddr, &cmdq_ctx.writeAddrList,
list_node) {
if (pa < waddr->pa || pa >= waddr->pa +
waddr->count * sizeof(u32))
continue;
cur_waddr = waddr;
break;
}
}
if (cur_waddr)
val_out[i] = *((u32 *)(cur_waddr->va +
(pa - cur_waddr->pa)));
else
val_out[i] = 0;
}
CMDQ_PROF_MMP(mdp_mmp_get_event()->read_reg,
MMPROFILE_FLAG_END, ((unsigned long)addrs), count);
spin_unlock_irqrestore(&cmdq_write_addr_lock, flags);
}
u32 cmdqCoreWriteWriteAddress(dma_addr_t pa, u32 value)
{
struct list_head *p = NULL;
struct WriteAddrStruct *pWriteAddr = NULL;
s32 offset = 0;
unsigned long flags;
char long_msg[CMDQ_LONGSTRING_MAX];
u32 msg_offset;
s32 msg_max_size;
/* search for the entry */
spin_lock_irqsave(&cmdq_write_addr_lock, flags);
list_for_each(p, &cmdq_ctx.writeAddrList) {
pWriteAddr = list_entry(p, struct WriteAddrStruct, list_node);
if (!pWriteAddr)
continue;
offset = pa - pWriteAddr->pa;
/* note it is 64 bit length for u32 variable in 64 bit kernel
* use sizeof(u_log) to check valid offset range
*/
if (offset >= 0 && (offset / sizeof(u32)) <
pWriteAddr->count) {
cmdq_long_string_init(false, long_msg, &msg_offset,
&msg_max_size);
cmdq_long_string(long_msg, &msg_offset, &msg_max_size,
"%s input:%pa", __func__, &pa);
cmdq_long_string(long_msg, &msg_offset, &msg_max_size,
" got offset:%d va:%p pa_start:%pa value:0x%08x\n",
offset, pWriteAddr->va + offset,
&pWriteAddr->pa, value);
CMDQ_VERBOSE("%s", long_msg);
*((u32 *)(pWriteAddr->va + offset)) = value;
break;
}
}
spin_unlock_irqrestore(&cmdq_write_addr_lock, flags);
return value;
}
int cmdqCoreFreeWriteAddress(dma_addr_t paStart, enum CMDQ_CLT_ENUM clt)
{
struct list_head *p, *n = NULL;
struct WriteAddrStruct *pWriteAddr = NULL;
bool foundEntry;
unsigned long flags;
foundEntry = false;
/* search for the entry */
spin_lock_irqsave(&cmdq_write_addr_lock, flags);
list_for_each_safe(p, n, &cmdq_ctx.writeAddrList) {
pWriteAddr = list_entry(p, struct WriteAddrStruct, list_node);
if (pWriteAddr && pWriteAddr->pa == paStart) {
list_del(&(pWriteAddr->list_node));
foundEntry = true;
break;
}
}
spin_unlock_irqrestore(&cmdq_write_addr_lock, flags);
/* when list is not empty, we always get a entry
* even we don't found a valid entry
* use foundEntry to confirm search result
*/
if (!foundEntry) {
CMDQ_ERR("%s no matching entry, paStart:%pa\n",
__func__, &paStart);
return -EINVAL;
}
/* release resources */
if (pWriteAddr->va) {
cmdq_core_free_hw_buffer_clt(cmdq_dev_get(),
sizeof(u32) * pWriteAddr->count,
pWriteAddr->va, pWriteAddr->pa, clt, pWriteAddr->pool);
memset(pWriteAddr, 0xda, sizeof(struct WriteAddrStruct));
}
kfree(pWriteAddr);
pWriteAddr = NULL;
atomic_dec(&cmdq_ctx.write_addr_cnt);
return 0;
}
int cmdqCoreFreeWriteAddressByNode(void *fp, enum CMDQ_CLT_ENUM clt)
{
struct WriteAddrStruct *write_addr, *tmp;
struct list_head free_list;
unsigned long flags;
u32 pid = 0;
INIT_LIST_HEAD(&free_list);
/* search for the entry */
spin_lock_irqsave(&cmdq_write_addr_lock, flags);
list_for_each_entry_safe(write_addr, tmp, &cmdq_ctx.writeAddrList,
list_node) {
if (write_addr->fp != fp)
continue;
list_del(&write_addr->list_node);
list_add_tail(&write_addr->list_node, &free_list);
}
spin_unlock_irqrestore(&cmdq_write_addr_lock, flags);
while (!list_empty(&free_list)) {
write_addr = list_first_entry(&free_list, typeof(*write_addr),
list_node);
if (pid != write_addr->user) {
pid = write_addr->user;
CMDQ_LOG("free write buf by node:%p clt:%d pid:%u\n",
fp, clt, pid);
}
cmdq_core_free_hw_buffer_clt(cmdq_dev_get(),
sizeof(u32) * write_addr->count,
write_addr->va, write_addr->pa, clt, write_addr->pool);
list_del(&write_addr->list_node);
memset(write_addr, 0xda, sizeof(struct WriteAddrStruct));
kfree(write_addr);
atomic_dec(&cmdq_ctx.write_addr_cnt);
}
return 0;
}
void cmdq_core_init_dts_data(void)
{
u32 i;
memset(&cmdq_dts_data, 0x0, sizeof(cmdq_dts_data));
for (i = 0; i < CMDQ_SYNC_TOKEN_MAX; i++) {
if (i <= CMDQ_MAX_HW_EVENT_COUNT) {
/* GCE HW evevt */
cmdq_dts_data.eventTable[i] =
CMDQ_SYNC_TOKEN_INVALID - 1 - i;
} else {
/* GCE SW evevt */
cmdq_dts_data.eventTable[i] = i;
}
}
}
struct cmdqDTSDataStruct *cmdq_core_get_dts_data(void)
{
return &cmdq_dts_data;
}
void cmdq_core_set_event_table(enum cmdq_event event, const s32 value)
{
if (event >= 0 && event < CMDQ_SYNC_TOKEN_MAX)
cmdq_dts_data.eventTable[event] = value;
}
s32 cmdq_core_get_event_value(enum cmdq_event event)
{
if (event < 0 || event >= CMDQ_SYNC_TOKEN_MAX)
return -EINVAL;
return cmdq_dts_data.eventTable[event];
}
static s32 cmdq_core_reverse_event_enum(const u32 value)
{
u32 evt;
for (evt = 0; evt < CMDQ_SYNC_TOKEN_MAX; evt++)
if (value == cmdq_dts_data.eventTable[evt])
return evt;
return CMDQ_SYNC_TOKEN_INVALID;
}
const char *cmdq_core_get_event_name_enum(enum cmdq_event event)
{
const char *eventName = "CMDQ_EVENT_UNKNOWN";
struct cmdq_event_table *events = cmdq_event_get_table();
u32 table_size = cmdq_event_get_table_size();
u32 i = 0;
for (i = 0; i < table_size; i++) {
if (events[i].event == event)
return events[i].event_name;
}
return eventName;
}
const char *cmdq_core_get_event_name(u32 hw_event)
{
const s32 event_enum = cmdq_core_reverse_event_enum(hw_event);
return cmdq_core_get_event_name_enum(event_enum);
}
void cmdqCoreClearEvent(enum cmdq_event event)
{
s32 eventValue = cmdq_core_get_event_value(event);
if (eventValue < 0)
return;
if (!cmdq_entry) {
CMDQ_ERR("%s no cmdq entry\n", __func__);
return;
}
cmdq_clear_event(cmdq_entry->chan, eventValue);
}
void cmdqCoreSetEvent(enum cmdq_event event)
{
s32 eventValue = cmdq_core_get_event_value(event);
if (eventValue < 0)
return;
if (!cmdq_entry) {
CMDQ_ERR("%s no cmdq entry\n", __func__);
return;
}
cmdq_set_event(cmdq_entry->chan, eventValue);
}
u32 cmdqCoreGetEvent(enum cmdq_event event)
{
s32 eventValue = cmdq_core_get_event_value(event);
if (!cmdq_entry) {
CMDQ_ERR("%s no cmdq entry\n", __func__);
return 0;
}
return cmdq_get_event(cmdq_entry->chan, eventValue);
}
void cmdq_core_reset_gce(void)
{
/* CMDQ init flow:
* 1. clock-on
* 2. reset all events
*/
cmdq_get_func()->enableGCEClockLocked(true);
cmdq_mdp_reset_resource();
#ifdef CMDQ_ENABLE_BUS_ULTRA
CMDQ_LOG("Enable GCE Ultra ability");
CMDQ_REG_SET32(CMDQ_BUS_CONTROL_TYPE, 0x3);
#endif
/* Restore event */
cmdq_get_func()->eventRestore();
}
void cmdq_core_set_addon_subsys(u32 msb, s32 subsys_id, u32 mask)
{
cmdq_adds_subsys.msb = msb;
cmdq_adds_subsys.subsysID = subsys_id;
cmdq_adds_subsys.mask = mask;
CMDQ_LOG("Set AddOn Subsys:msb:0x%08x mask:0x%08x id:%d\n",
msb, mask, subsys_id);
}
u32 cmdq_core_subsys_to_reg_addr(u32 arg_a)
{
const u32 subsysBit = cmdq_get_func()->getSubsysLSBArgA();
const s32 subsys_id = (arg_a & CMDQ_ARG_A_SUBSYS_MASK) >> subsysBit;
u32 offset = 0;
u32 base_addr = 0;
u32 i;
for (i = 0; i < CMDQ_SUBSYS_MAX_COUNT; i++) {
if (cmdq_dts_data.subsys[i].subsysID == subsys_id) {
base_addr = cmdq_dts_data.subsys[i].msb;
offset = arg_a & ~cmdq_dts_data.subsys[i].mask;
break;
}
}
if (!base_addr && cmdq_adds_subsys.subsysID > 0 &&
subsys_id == cmdq_adds_subsys.subsysID) {
base_addr = cmdq_adds_subsys.msb;
offset = arg_a & ~cmdq_adds_subsys.mask;
}
return base_addr | offset;
}
const char *cmdq_core_parse_subsys_from_reg_addr(u32 reg_addr)
{
u32 addr_base_shifted;
const char *module = "CMDQ";
u32 i;
for (i = 0; i < CMDQ_SUBSYS_MAX_COUNT; i++) {
if (cmdq_dts_data.subsys[i].subsysID == -1)
continue;
addr_base_shifted = reg_addr & cmdq_dts_data.subsys[i].mask;
if (cmdq_dts_data.subsys[i].msb == addr_base_shifted) {
module = cmdq_dts_data.subsys[i].grpName;
break;
}
}
return module;
}
s32 cmdq_core_subsys_from_phys_addr(u32 physAddr)
{
s32 msb;
s32 subsysID = CMDQ_SPECIAL_SUBSYS_ADDR;
u32 i;
for (i = 0; i < CMDQ_SUBSYS_MAX_COUNT; i++) {
if (cmdq_dts_data.subsys[i].subsysID == -1)
continue;
msb = physAddr & cmdq_dts_data.subsys[i].mask;
if (msb == cmdq_dts_data.subsys[i].msb) {
subsysID = cmdq_dts_data.subsys[i].subsysID;
break;
}
}
return subsysID;
}
ssize_t cmdq_core_print_error(struct device *dev,
struct device_attribute *attr, char *buf)
{
int i;
int length = 0;
for (i = 0; i < cmdq_ctx.errNum && i < CMDQ_MAX_ERROR_COUNT;
i++) {
struct ErrorStruct *pError = &cmdq_ctx.error[i];
u64 ts = pError->ts_nsec;
unsigned long rem_nsec = do_div(ts, 1000000000);
length += snprintf(buf + length,
PAGE_SIZE - length, "[%5lu.%06lu] ",
(unsigned long)ts, rem_nsec / 1000);
length += cmdq_core_print_record(&pError->errorRec,
i, buf + length, PAGE_SIZE - length);
if (length >= PAGE_SIZE)
break;
}
return length;
}
void cmdq_core_set_log_level(const s32 value)
{
if (value == CMDQ_LOG_LEVEL_NORMAL) {
/* Only print CMDQ ERR and CMDQ LOG */
cmdq_ctx.logLevel = CMDQ_LOG_LEVEL_NORMAL;
} else if (value < CMDQ_LOG_LEVEL_MAX) {
/* Modify log level */
cmdq_ctx.logLevel = (1 << value);
}
}
ssize_t cmdq_core_print_log_level(struct device *dev,
struct device_attribute *attr, char *buf)
{
int len = 0;
if (buf) {
len = snprintf(buf, 10, "%d\n", cmdq_ctx.logLevel);
if (len >= 10)
pr_debug("%s:%d len:%d over 10\n",
__func__, __LINE__, len);
}
return len;
}
ssize_t cmdq_core_write_log_level(struct device *dev,
struct device_attribute *attr, const char *buf, size_t size)
{
int value = 0;
int status = 0;
char textBuf[12] = { 0 };
do {
if (size >= 10) {
status = -EFAULT;
break;
}
memcpy(textBuf, buf, size);
textBuf[size] = '\0';
if (kstrtoint(textBuf, 10, &value) < 0) {
status = -EFAULT;
break;
}
status = size;
if (value < 0 || value > CMDQ_LOG_LEVEL_MAX)
value = 0;
cmdq_core_set_log_level(value);
} while (0);
return status;
}
ssize_t cmdq_core_print_profile_enable(struct device *dev,
struct device_attribute *attr, char *buf)
{
int len = 0;
if (buf) {
len = snprintf(buf, 10, "0x%x\n", cmdq_ctx.enableProfile);
if (len >= 10)
pr_debug("%s:%d len:%d over 10\n",
__func__, __LINE__, len);
}
return len;
}
ssize_t cmdq_core_write_profile_enable(struct device *dev,
struct device_attribute *attr, const char *buf, size_t size)
{
int value = 0;
int status = 0;
char textBuf[12] = { 0 };
do {
if (size >= 10) {
status = -EFAULT;
break;
}
memcpy(textBuf, buf, size);
textBuf[size] = '\0';
if (kstrtoint(textBuf, 10, &value) < 0) {
status = -EFAULT;
break;
}
status = size;
if (value < 0 || value > CMDQ_PROFILE_MAX)
value = 0;
if (value == CMDQ_PROFILE_OFF)
cmdq_ctx.enableProfile = CMDQ_PROFILE_OFF;
else
cmdq_ctx.enableProfile |= (1 << value);
} while (0);
return status;
}
static void cmdq_core_fill_handle_record(
struct RecordStruct *record, const struct cmdqRecStruct *handle,
u32 thread)
{
if (record && handle) {
/* Record scenario */
record->user = handle->caller_pid;
record->scenario = handle->scenario;
record->priority = handle->pkt ? handle->pkt->priority : 0;
record->thread = thread;
record->reorder = handle->reorder;
record->engineFlag = handle->engineFlag;
record->size = handle->pkt ? handle->pkt->cmd_buf_size : 0;
record->is_secure = handle->secData.is_secure;
/* TODO: extend Record time field*/
record->submit = handle->submit;
record->trigger = handle->trigger;
record->gotIRQ = handle->gotIRQ;
record->beginWait = handle->beginWait;
record->wakedUp = handle->wakedUp;
record->durAlloc = handle->durAlloc;
record->durReclaim = handle->durReclaim;
record->durRelease = handle->durRelease;
/* Record address */
if (handle->pkt && !list_empty(&handle->pkt->buf)) {
struct cmdq_pkt_buffer *first = list_first_entry(
&handle->pkt->buf, typeof(*first), list_entry);
struct cmdq_pkt_buffer *last = list_last_entry(
&handle->pkt->buf, typeof(*first), list_entry);
record->start = (u32)first->pa_base;
record->end = (u32)last->pa_base +
CMDQ_CMD_BUFFER_SIZE -
handle->pkt->avail_buf_size;
record->jump = handle->cmd_end ?
handle->cmd_end[0] : 0;
} else {
record->start = 0;
record->end = 0;
record->jump = 0;
}
}
}
static void cmdq_core_track_handle_record(struct cmdqRecStruct *handle,
u32 thread)
{
struct RecordStruct *pRecord;
unsigned long flags;
CMDQ_TIME done;
int lastID;
char buf[256];
done = sched_clock();
spin_lock_irqsave(&cmdq_record_lock, flags);
pRecord = &(cmdq_ctx.record[cmdq_ctx.lastID]);
lastID = cmdq_ctx.lastID;
cmdq_core_fill_handle_record(pRecord, handle, thread);
pRecord->done = done;
cmdq_ctx.lastID++;
if (cmdq_ctx.lastID >= CMDQ_MAX_RECORD_COUNT)
cmdq_ctx.lastID = 0;
cmdq_ctx.recNum++;
if (cmdq_ctx.recNum >= CMDQ_MAX_RECORD_COUNT)
cmdq_ctx.recNum = CMDQ_MAX_RECORD_COUNT;
spin_unlock_irqrestore(&cmdq_record_lock, flags);
if (handle->dumpAllocTime) {
cmdq_core_print_record(pRecord, lastID, buf,
ARRAY_SIZE(buf));
CMDQ_LOG("Record:%s\n", buf);
}
}
void cmdq_core_dump_tasks_info(void)
{
/* TODO: dump mailbox cmdq tasks */
#if 0
struct TaskStruct *pTask = NULL;
struct list_head *p = NULL;
s32 index = 0;
CMDQ_ERR("========= Active List Task Dump =========\n");
index = 0;
list_for_each(p, &cmdq_ctx.taskActiveList) {
pTask = list_entry(p, struct TaskStruct, listEntry);
CMDQ_ERR(
"Task(%d) 0x%p Pid:%d Name:%s Scenario:%d engineFlag:0x%llx\n",
index, pTask, pTask->callerPid, pTask->callerName,
pTask->scenario, pTask->engineFlag);
++index;
}
CMDQ_ERR("====== Total %d in Active Task =======\n", index);
#endif
}
static void *cmdq_core_get_pc_va(dma_addr_t pc,
const struct cmdqRecStruct *handle)
{
struct cmdq_pkt_buffer *buf;
if (!pc)
return NULL;
list_for_each_entry(buf, &handle->pkt->buf, list_entry) {
if (!(pc >= buf->pa_base &&
pc < buf->pa_base + CMDQ_CMD_BUFFER_SIZE))
continue;
return buf->va_base + (pc - buf->pa_base);
}
return NULL;
}
struct cmdqRecStruct *cmdq_core_get_valid_handle(unsigned long job)
{
struct cmdqRecStruct *handle = NULL, *entry;
mutex_lock(&cmdq_handle_list_mutex);
list_for_each_entry(entry, &cmdq_ctx.handle_active, list_entry) {
if (entry == (void *)job) {
handle = entry;
break;
}
}
mutex_unlock(&cmdq_handle_list_mutex);
return handle;
}
u32 *cmdq_core_get_pc_inst(const struct cmdqRecStruct *handle,
s32 thread, u32 insts[2], u32 *pa_out)
{
u32 curr_pc = 0L;
void *inst_ptr = NULL;
if (unlikely(!handle || list_empty(&handle->pkt->buf) ||
thread == CMDQ_INVALID_THREAD)) {
CMDQ_ERR(
"get pc failed since invalid param handle:0x%p thread:%d\n",
handle, thread);
return NULL;
}
curr_pc = CMDQ_AREG_TO_PHYS(cmdq_core_get_pc(thread));
if (curr_pc)
inst_ptr = cmdq_core_get_pc_va(curr_pc, handle);
if (inst_ptr) {
cmdq_pkt_get_cmd_by_pc(handle, curr_pc, insts, 2);
insts[0] = CMDQ_REG_GET32(inst_ptr + 0);
insts[1] = CMDQ_REG_GET32(inst_ptr + 4);
} else {
insts[0] = 0;
insts[1] = 0;
}
if (pa_out)
*pa_out = curr_pc;
return (u32 *)inst_ptr;
}
static void cmdq_core_parse_handle_error(const struct cmdqRecStruct *handle,
u32 thread, const char **moduleName, s32 *flag,
u32 *insts, u32 size, u32 **pc_va)
{
u32 op, arg_a, arg_b;
s32 eventENUM;
u32 addr = 0;
const char *module = NULL;
dma_addr_t curr_pc = 0;
u32 tmp_instr[2] = { 0 };
struct cmdq_client *client;
if (unlikely(!handle)) {
CMDQ_ERR("No handle to parse error\n");
return;
}
client = cmdq_clients[(u32)handle->thread];
do {
/* other cases, use instruction to judge
* because scenario / HW flag are not sufficient
a* e.g. ISP pass 2 involves both MDP and ISP
* so we need to check which instruction timeout-ed.
*/
if (!insts || !size)
break;
cmdq_task_get_thread_pc(client->chan, &curr_pc);
if (cmdq_pkt_get_cmd_by_pc(handle, curr_pc, tmp_instr, 2) <
0) {
CMDQ_ERR("%s get handle cmd fail\n", __func__);
break;
}
insts[0] = tmp_instr[0];
insts[1] = tmp_instr[1];
if (!insts[0] && !insts[1])
break;
op = (insts[1] & 0xFF000000) >> 24;
arg_a = insts[1] & (~0xFF000000);
arg_b = insts[0];
/* quick exam by hwflag first */
module = cmdq_get_func()->parseHandleErrorModule(handle);
if (module != NULL)
break;
switch (op) {
case CMDQ_CODE_POLL:
case CMDQ_CODE_WRITE:
addr = cmdq_core_subsys_to_reg_addr(arg_a);
module = cmdq_get_func()->parseModule(addr);
break;
case CMDQ_CODE_WFE:
/* arg_a is the event ID */
eventENUM = cmdq_core_reverse_event_enum(arg_a);
module = cmdq_get_func()->moduleFromEvent(eventENUM,
cmdq_group_cb, handle->engineFlag);
break;
case CMDQ_CODE_READ:
case CMDQ_CODE_MOVE:
case CMDQ_CODE_JUMP:
case CMDQ_CODE_EOC:
default:
module = "CMDQ";
break;
}
} while (0);
/* fill output parameter */
*moduleName = module ? module : "CMDQ";
cmdq_task_get_thread_irq(client->chan, flag);
if (pc_va)
*pc_va = cmdq_core_get_pc_va(curr_pc, handle);
}
void cmdq_core_dump_handle_error_instruction(const u32 *pcVA, const long pcPA,
u32 *insts, int thread, u32 lineNum)
{
char parsedInstruction[128] = { 0 };
const u32 op = (insts[1] & 0xFF000000) >> 24;
if (CMDQ_IS_END_ADDR(pcPA)) {
/* in end address case instruction may not correct */
CMDQ_ERR("PC stay at GCE end address, line:%u\n", lineNum);
return;
} else if (pcVA == NULL) {
CMDQ_ERR("Dump error instruction with null va, line:%u\n",
lineNum);
return;
}
cmdq_core_parse_instruction(pcVA, parsedInstruction,
sizeof(parsedInstruction));
CMDQ_ERR("Thread %d error instruction:0x%p 0x%08x:0x%08x => %s",
thread, pcVA, insts[0], insts[1], parsedInstruction);
/* for WFE, we specifically dump the event value */
if (op == CMDQ_CODE_WFE) {
const u32 eventID = 0x3FF & insts[1];
CMDQ_ERR("CMDQ_SYNC_TOKEN_VAL(idx:%u) of %s is %d\n",
eventID, cmdq_core_get_event_name(eventID),
cmdqCoreGetEvent(eventID));
}
}
static void cmdq_core_create_nghandleinfo(const struct cmdqRecStruct *nghandle,
void *va_pc, struct cmdq_ng_handle_info *nginfo_out)
{
void *buffer = NULL;
struct cmdq_pkt_buffer *buf;
if (!nginfo_out)
return;
/* copy ngtask info */
buf = list_first_entry(&nghandle->pkt->buf, typeof(*buf), list_entry);
nginfo_out->va_start = buf->va_base;
nginfo_out->va_pc = (u32 *)va_pc;
nginfo_out->buffer = NULL;
nginfo_out->engine_flag = nghandle->engineFlag;
nginfo_out->scenario = nghandle->scenario;
nginfo_out->nghandle = nghandle;
nginfo_out->buffer_size = nghandle->pkt->cmd_buf_size;
buffer = kzalloc(nghandle->pkt->buf_size, GFP_ATOMIC);
if (!buffer) {
CMDQ_ERR("fail to allocate NG buffer\n");
return;
}
nginfo_out->buffer = (u32 *)buffer;
list_for_each_entry(buf, &nghandle->pkt->buf, list_entry) {
u32 buf_size;
if (list_is_last(&buf->list_entry, &nghandle->pkt->buf))
buf_size = CMDQ_CMD_BUFFER_SIZE -
nghandle->pkt->avail_buf_size;
else
buf_size = CMDQ_CMD_BUFFER_SIZE;
memcpy(buffer, buf->va_base, buf_size);
if (va_pc >= buf->va_base &&
va_pc < buf->va_base + CMDQ_CMD_BUFFER_SIZE) {
buffer += va_pc - buf->va_base;
break;
}
buffer += buf_size;
}
/* only dump to pc */
nginfo_out->dump_size = buffer - (void *)nginfo_out->buffer;
}
static void cmdq_core_dump_handle_summary(const struct cmdqRecStruct *handle,
s32 thread, const struct cmdqRecStruct **nghandle_out,
struct cmdq_ng_handle_info *nginfo_out)
{
const char *module = NULL;
s32 irqFlag = 0;
u32 insts[2] = { 0 };
u32 *pcVA = NULL;
dma_addr_t curr_pc = 0;
struct cmdq_client *client;
if (!handle || !handle->pkt || list_empty(&handle->pkt->buf) ||
thread == CMDQ_INVALID_THREAD) {
CMDQ_ERR(
"%s invalid param handle:0x%p pkt:0x%p thread:%d\n",
__func__, handle, handle ? handle->pkt : NULL, thread);
return;
}
client = cmdq_clients[(u32)handle->thread];
/* Do summary ! */
cmdq_core_parse_handle_error(handle, thread, &module, &irqFlag,
insts, ARRAY_SIZE(insts), &pcVA);
CMDQ_ERR("** [Module] %s **\n", module);
CMDQ_ERR(
"** [Error Info] Refer to instruction and check engine dump for debug**\n");
cmdq_task_get_thread_pc(client->chan, &curr_pc);
cmdq_core_dump_handle_error_instruction(pcVA,
(long)curr_pc, insts, thread, __LINE__);
cmdq_core_dump_trigger_loop_thread("ERR");
*nghandle_out = handle;
if (nginfo_out) {
cmdq_core_create_nghandleinfo(handle, pcVA, nginfo_out);
nginfo_out->module = module;
nginfo_out->irq_flag = irqFlag;
nginfo_out->inst[0] = insts[0];
nginfo_out->inst[1] = insts[1];
}
}
void cmdq_core_dump_handle_buffer(const struct cmdq_pkt *pkt,
const char *tag)
{
struct cmdq_pkt_buffer *buf;
list_for_each_entry(buf, &pkt->buf, list_entry) {
u32 *va;
if (list_is_last(&buf->list_entry, &pkt->buf))
va = (u32 *)(buf->va_base + CMDQ_CMD_BUFFER_SIZE -
pkt->avail_buf_size);
else
va = (u32 *)(buf->va_base + CMDQ_CMD_BUFFER_SIZE);
va -= 4;
CMDQ_LOG(
"[%s]va:0x%p pa:%pa last inst (0x%p) 0x%08x:%08x 0x%08x:%08x\n",
tag, buf->va_base, &buf->pa_base,
va, va[1], va[0], va[3], va[2]);
}
}
static void cmdq_core_dump_handle(const struct cmdqRecStruct *handle,
const char *tag)
{
CMDQ_LOG(
"[%s]handle:0x%p pkt:0x%p scenario:%d pri:%u state:%d flag:0x%llx\n",
tag, handle, handle->pkt, handle->scenario,
handle->pkt->priority, handle->state, handle->engineFlag);
cmdq_core_dump_handle_buffer(handle->pkt, tag);
CMDQ_LOG("[%s]cmd size:%zu buffer size:%zu available size:%zu\n",
tag, handle->pkt->cmd_buf_size, handle->pkt->buf_size,
handle->pkt->avail_buf_size);
if (handle->reg_values || handle->reg_count)
CMDQ_LOG("[%s]Result buffer va:0x%p pa:%pa count:%u\n",
tag, handle->reg_values, &handle->reg_values_pa,
handle->reg_count);
if (handle->sram_base)
CMDQ_LOG("[%s]** This is SRAM task, sram base:0x%08x\n",
tag, handle->sram_base);
CMDQ_LOG(
"[%s]Reorder:%d Trigger:%lld Got IRQ:0x%llx Wait:%lld Finish:%lld\n",
tag, handle->reorder, handle->trigger, handle->gotIRQ,
handle->beginWait, handle->wakedUp);
CMDQ_LOG("[%s]Caller pid:%d name:%s\n",
tag, handle->caller_pid, handle->caller_name);
}
u32 *cmdq_core_dump_pc(const struct cmdqRecStruct *handle,
int thread, const char *tag)
{
u32 *pcVA = NULL;
u32 insts[2] = { 0 };
char parsedInstruction[128] = { 0 };
dma_addr_t curr_pc = 0;
u32 tmp_insts[2] = { 0 };
struct cmdq_client *client;
if (!handle)
return NULL;
client = cmdq_clients[(u32)handle->thread];
cmdq_task_get_thread_pc(client->chan, &curr_pc);
pcVA = cmdq_core_get_pc_va(curr_pc, handle);
if (cmdq_pkt_get_cmd_by_pc(handle, curr_pc, tmp_insts, 2) < 0) {
CMDQ_ERR("%s get handle cmd fail\n", __func__);
return NULL;
}
insts[0] = tmp_insts[0];
insts[1] = tmp_insts[1];
if (pcVA) {
const u32 op = (insts[1] & 0xFF000000) >> 24;
cmdq_core_parse_instruction(pcVA,
parsedInstruction, sizeof(parsedInstruction));
/* for WFE, we specifically dump the event value */
if (op == CMDQ_CODE_WFE) {
const u32 eventID = 0x3FF & insts[1];
CMDQ_LOG(
"[%s]Thread %d PC:0x%p(%pa) 0x%08x:0x%08x => %s value:%d",
tag, thread, pcVA, &curr_pc,
insts[0], insts[1],
parsedInstruction,
cmdqCoreGetEvent(eventID));
} else {
CMDQ_LOG(
"[%s]Thread %d PC:0x%p(%pa), 0x%08x:0x%08x => %s",
tag, thread, pcVA, &curr_pc,
insts[0], insts[1], parsedInstruction);
}
} else {
CMDQ_LOG("[%s]Thread %d PC:%s\n", tag, thread,
handle->secData.is_secure ?
"HIDDEN INFO since is it's secure thread" :
"Not available");
}
return pcVA;
}
static void cmdq_core_dump_error_handle(const struct cmdqRecStruct *handle,
u32 thread, u32 **pc_out)
{
u32 *hwPC = NULL;
u64 printEngineFlag = 0;
cmdq_core_dump_thread(handle, thread, true, "ERR");
if (handle) {
CMDQ_ERR("============ [CMDQ] Error Thread PC ============\n");
hwPC = cmdq_core_dump_pc(handle, thread, "ERR");
CMDQ_ERR("========= [CMDQ] Error Task Status =========\n");
cmdq_core_dump_handle(handle, "ERR");
printEngineFlag |= handle->engineFlag;
}
if (cmdq_ctx.errNum > 1)
return;
CMDQ_ERR("============ [CMDQ] Clock Gating Status ============\n");
CMDQ_ERR("[CLOCK] common clock ref:%d\n",
atomic_read(&cmdq_thread_usage));
if (pc_out)
*pc_out = hwPC;
}
static void cmdq_core_attach_cmdq_error(
const struct cmdqRecStruct *handle, s32 thread,
u32 **pc_out, struct cmdq_ng_handle_info *nginfo_out)
{
const struct cmdqRecStruct *nghandle = NULL;
u64 eng_flag = 0;
s32 index = 0;
struct EngineStruct *engines = cmdq_mdp_get_engines();
CMDQ_PROF_MMP(mdp_mmp_get_event()->warning, MMPROFILE_FLAG_PULSE,
((unsigned long)handle), thread);
/* Update engine fail count */
eng_flag = handle->engineFlag;
for (index = 0; index < CMDQ_MAX_ENGINE_COUNT; index++) {
if (eng_flag & (1LL << index))
engines[index].failCount++;
}
/* register error record */
if (cmdq_ctx.errNum < CMDQ_MAX_ERROR_COUNT) {
struct ErrorStruct *error = &cmdq_ctx.error[cmdq_ctx.errNum];
cmdq_core_fill_handle_record(&error->errorRec, handle, thread);
error->ts_nsec = local_clock();
}
/* Then we just print out info */
CMDQ_ERR("============== [CMDQ] Begin of Error %d =============\n",
cmdq_ctx.errNum);
cmdq_core_dump_handle_summary(handle, thread, &nghandle, nginfo_out);
cmdq_core_dump_error_handle(handle, thread, pc_out);
CMDQ_ERR("============== [CMDQ] End of Error %d =============\n",
cmdq_ctx.errNum);
cmdq_ctx.errNum++;
}
static void cmdq_core_release_nghandleinfo(struct cmdq_ng_handle_info *nginfo)
{
kfree(nginfo->buffer);
}
static void cmdq_core_dump_error_buffer(const struct cmdqRecStruct *handle,
void *pc, u32 pc_pa)
{
struct cmdq_pkt_buffer *buf;
const struct cmdq_pkt *pkt = handle->pkt;
u32 cmd_size = 0, dump_size = 0;
bool dump = false;
u32 dump_buff_count = 0;
u32 cnt = 0;
if (list_empty(&pkt->buf))
return;
list_for_each_entry(buf, &pkt->buf, list_entry) {
if (list_is_last(&buf->list_entry, &pkt->buf))
/* remain buffer always print */
cmd_size = CMDQ_CMD_BUFFER_SIZE - pkt->avail_buf_size;
else
cmd_size = CMDQ_CMD_BUFFER_SIZE;
if (pc && pc >= buf->va_base && pc < buf->va_base + cmd_size) {
/* because hwPC points to "start" of the
* instruction, add offset 1
*/
dump_size = pc - buf->va_base + CMDQ_INST_SIZE;
dump = true;
} else if (pc_pa && pc_pa >= buf->pa_base &&
pc_pa < buf->pa_base + cmd_size) {
dump_size = pc_pa - buf->pa_base + CMDQ_INST_SIZE;
dump = true;
} else {
dump_size = cmd_size;
}
CMDQ_LOG("buffer %u va:0x%p pa:%pa\n",
cnt, buf->va_base, &buf->pa_base);
print_hex_dump(KERN_ERR, "", DUMP_PREFIX_ADDRESS,
16, 4, buf->va_base, dump_size, true);
if (dump)
break;
if (dump_buff_count++ >= 2) {
CMDQ_LOG("only dump 2 buffer...\n");
break;
}
cnt++;
}
if (pc_pa && !dump)
CMDQ_LOG("PC is not in region, dump all\n");
}
s32 cmdq_core_is_group_flag(enum CMDQ_GROUP_ENUM engGroup, u64 engineFlag)
{
if (!cmdq_core_is_valid_group(engGroup))
return false;
if (cmdq_mdp_get_func()->getEngineGroupBits(engGroup) & engineFlag)
return true;
return false;
}
static void cmdq_core_attach_engine_error(
const struct cmdqRecStruct *handle, s32 thread,
const struct cmdq_ng_handle_info *nginfo, bool short_log)
{
s32 index = 0;
u64 print_eng_flag = 0;
CmdqMdpGetEngineGroupBits get_engine_group_bit = NULL;
struct CmdqCBkStruct *callback = NULL;
static const char *const engineGroupName[] = {
CMDQ_FOREACH_GROUP(GENERATE_STRING)
};
if (short_log) {
CMDQ_ERR("============ skip detail error dump ============\n");
return;
}
print_eng_flag = handle->engineFlag;
get_engine_group_bit = cmdq_mdp_get_func()->getEngineGroupBits;
if (nginfo)
print_eng_flag |= nginfo->engine_flag;
/* Dump MMSYS configuration */
if (handle->engineFlag & CMDQ_ENG_MDP_GROUP_BITS) {
CMDQ_ERR("============ [CMDQ] MMSYS_CONFIG ============\n");
cmdq_mdp_get_func()->dumpMMSYSConfig();
}
/* ask each module to print their status */
CMDQ_ERR("============ [CMDQ] Engine Status ============\n");
callback = cmdq_group_cb;
for (index = 0; index < CMDQ_MAX_GROUP_COUNT; index++) {
if (!cmdq_core_is_group_flag(
(enum CMDQ_GROUP_ENUM) index, print_eng_flag))
continue;
CMDQ_ERR("====== engine group %s status =======\n",
engineGroupName[index]);
if (callback[index].dumpInfo == NULL) {
CMDQ_ERR("(no dump function)\n");
continue;
}
callback[index].dumpInfo(
(get_engine_group_bit(index) & print_eng_flag),
cmdq_ctx.logLevel);
}
for (index = 0; index < CMDQ_MAX_GROUP_COUNT; ++index) {
if (!cmdq_core_is_group_flag((enum CMDQ_GROUP_ENUM) index,
print_eng_flag))
continue;
if (callback[index].errorReset) {
callback[index].errorReset(
get_engine_group_bit(index) & print_eng_flag);
CMDQ_LOG(
"engine group (%s): function is called\n",
engineGroupName[index]);
}
}
}
static void cmdq_core_attach_error_handle_detail(
const struct cmdqRecStruct *handle, s32 thread,
const struct cmdqRecStruct **nghandle_out, const char **module_out,
u32 *irq_flag_out, u32 *inst_a_out, u32 *inst_b_out, bool *aee_out)
{
s32 error_num = cmdq_ctx.errNum;
u32 *pc = NULL;
struct cmdq_ng_handle_info nginfo = {0};
bool detail_log = false;
if (!handle) {
CMDQ_ERR("attach error failed since handle is NULL");
if (aee_out)
*aee_out = false;
return;
}
cmdq_core_attach_cmdq_error(handle, thread, &pc, &nginfo);
if (nghandle_out && nginfo.nghandle)
*nghandle_out = nginfo.nghandle;
if (module_out && irq_flag_out && inst_a_out && inst_b_out) {
*module_out = nginfo.module;
*irq_flag_out = nginfo.irq_flag;
*inst_a_out = nginfo.inst[1];
*inst_b_out = nginfo.inst[0];
}
if (((nginfo.inst[1] & 0xFF000000) >> 24) == CMDQ_CODE_WFE) {
const u32 event = nginfo.inst[1] & ~0xFF000000;
if (event >= CMDQ_SYNC_RESOURCE_WROT0)
cmdq_mdp_dump_resource(event);
}
/* clear lock token */
if (!nghandle_out || *nghandle_out == handle)
cmdq_mdp_get_func()->resolve_token(handle->engineFlag, handle);
detail_log = error_num <= 2 || error_num % 16 == 0 ||
cmdq_core_should_full_error();
cmdq_core_attach_engine_error(handle, thread,
&nginfo, !detail_log);
CMDQ_ERR("=========== [CMDQ] End of Full Error %d ==========\n",
error_num);
cmdq_core_release_nghandleinfo(&nginfo);
if (aee_out)
*aee_out = true;
}
void cmdq_core_attach_error_handle(const struct cmdqRecStruct *handle,
s32 thread)
{
cmdq_core_attach_error_handle_detail(handle, thread, NULL, NULL, NULL,
NULL, NULL, NULL);
}
static void cmdq_core_attach_error_handle_by_state(
const struct cmdqRecStruct *handle, enum TASK_STATE_ENUM state)
{
const struct cmdqRecStruct *nghandle = NULL;
const char *module = NULL;
u32 irq_flag = 0, inst_a = 0, inst_b = 0;
u32 op = 0;
bool aee = true;
if (unlikely(!handle)) {
CMDQ_ERR("attach error without handle\n");
return;
}
if (unlikely((state != TASK_STATE_TIMEOUT))) {
CMDQ_ERR("attach error handle:0x%p state:%d\n",
handle, state);
return;
}
cmdq_core_attach_error_handle_detail(handle, handle->thread,
&nghandle, &module, &irq_flag, &inst_a, &inst_b, &aee);
op = (inst_a & 0xFF000000) >> 24;
if (!aee) {
CMDQ_ERR(
"Skip AEE for %s in CMDQ IRQ:0x%02x, INST:(0x%08x, 0x%08x), OP:%s\n",
module, irq_flag, inst_a, inst_b,
cmdq_core_parse_op(op));
return;
}
switch (op) {
case CMDQ_CODE_WFE:
CMDQ_ERR(
"%s in CMDQ IRQ:0x%02x, INST:(0x%08x, 0x%08x), OP:WAIT EVENT:%s\n",
module, irq_flag, inst_a, inst_b,
cmdq_core_get_event_name(inst_a & (~0xFF000000)));
break;
default:
CMDQ_ERR(
"%s in CMDQ IRQ:0x%02x, INST:(0x%08x, 0x%08x), OP:%s\n",
module, irq_flag, inst_a, inst_b,
cmdq_core_parse_op(op));
break;
}
}
static void cmdq_core_dump_thread_usage(void)
{
u32 idx;
for (idx = CMDQ_DYNAMIC_THREAD_ID_START;
idx < cmdq_dev_get_thread_count(); idx++) {
CMDQ_LOG(
"thread:%d used:%s acquire:%u scenario:%d\n",
idx,
cmdq_ctx.thread[idx].used ? "true" : "false",
cmdq_ctx.thread[idx].acquire,
cmdq_ctx.thread[idx].scenario);
}
}
#ifdef CMDQ_DAPC_DEBUG
static void cmdq_core_handle_devapc_vio(void)
{
s32 mdp_smi_usage = cmdq_mdp_get_smi_usage();
s32 thd_usage = atomic_read(&cmdq_thread_usage);
CMDQ_ERR("GCE devapc vio dump mdp smi:%d cmdq thd:%d mmsys clk:%s\n",
mdp_smi_usage, thd_usage,
cmdq_dev_mmsys_clock_is_enable() ? "on" : "off");
cmdq_core_dump_thread_usage();
cmdq_mdp_dump_engine_usage();
cmdq_mdp_dump_thread_usage();
cmdq_get_func()->dumpSMI(0);
}
#endif
s32 cmdq_core_acquire_thread(enum CMDQ_SCENARIO_ENUM scenario, bool exclusive)
{
s32 thread_id = CMDQ_INVALID_THREAD;
u32 idx;
mutex_lock(&cmdq_thread_mutex);
for (idx = CMDQ_DYNAMIC_THREAD_ID_START;
idx < cmdq_dev_get_thread_count(); idx++) {
/* ignore all static thread */
if (cmdq_ctx.thread[idx].used)
continue;
/* acquire for same scenario */
if (cmdq_ctx.thread[idx].acquire &&
cmdq_ctx.thread[idx].scenario != scenario)
continue;
/* for exclusvie acquire case, do not match scenario */
if (exclusive && cmdq_ctx.thread[idx].acquire)
continue;
cmdq_ctx.thread[idx].acquire++;
cmdq_ctx.thread[idx].scenario = scenario;
thread_id = idx;
CMDQ_MSG("dispatch scenario:%d to thread:%d acquired:%u\n",
scenario, idx, cmdq_ctx.thread[idx].acquire);
break;
}
mutex_unlock(&cmdq_thread_mutex);
if (thread_id == CMDQ_INVALID_THREAD) {
CMDQ_ERR("unable dispatch scenario:%d dump usage\n", scenario);
cmdq_core_dump_thread_usage();
}
return thread_id;
}
void cmdq_core_release_thread(s32 scenario, s32 thread)
{
if (thread == CMDQ_INVALID_THREAD || thread < 0) {
CMDQ_ERR("release invalid thread by scenario:%d\n",
scenario);
return;
}
mutex_lock(&cmdq_thread_mutex);
if (!cmdq_ctx.thread[thread].acquire)
CMDQ_ERR("counter fatal error thread:%d scenario:%d\n",
thread, scenario);
cmdq_ctx.thread[thread].acquire--;
if (scenario != cmdq_ctx.thread[thread].scenario) {
CMDQ_ERR(
"use diff scenario to release thread:%d to %d acquire:%d thread:%d\n",
cmdq_ctx.thread[thread].scenario,
scenario,
cmdq_ctx.thread[thread].acquire,
thread);
dump_stack();
}
if (!cmdq_ctx.thread[thread].acquire)
CMDQ_MSG("thread:%d released\n", thread);
mutex_unlock(&cmdq_thread_mutex);
}
static void cmdq_core_group_reset_hw(u64 engine_flag)
{
struct CmdqCBkStruct *callback = cmdq_group_cb;
s32 status;
u32 i;
CMDQ_LOG("%s engine:0x%llx\n", __func__, engine_flag);
for (i = 0; i < CMDQ_MAX_GROUP_COUNT; i++) {
if (cmdq_core_is_group_flag((enum CMDQ_GROUP_ENUM)i,
engine_flag)) {
if (!callback[i].resetEng) {
CMDQ_ERR(
"no reset func to reset engine group:%u\n",
i);
continue;
}
status = callback[i].resetEng(
cmdq_mdp_get_func()->getEngineGroupBits(i) &
engine_flag);
if (status < 0) {
/* Error status print */
CMDQ_ERR("Reset engine group %d failed:%d\n",
i, status);
}
}
}
}
static void cmdq_core_group_clk_on(enum CMDQ_GROUP_ENUM group,
u64 engine_flag)
{
struct CmdqCBkStruct *callback = cmdq_group_cb;
s32 status;
if (!callback[group].clockOn) {
CMDQ_MSG("[CLOCK][WARN]enable group %d clockOn func NULL\n",
group);
return;
}
status = callback[group].clockOn(
cmdq_mdp_get_func()->getEngineGroupBits(group) & engine_flag);
if (status < 0)
CMDQ_ERR("[CLOCK]enable group %d clockOn failed\n", group);
}
static void cmdq_core_group_clk_off(enum CMDQ_GROUP_ENUM group,
u64 engine_flag)
{
struct CmdqCBkStruct *callback = cmdq_group_cb;
s32 status;
if (!callback[group].clockOff) {
CMDQ_MSG("[CLOCK][WARN]enable group %d clockOff func NULL\n",
group);
return;
}
status = callback[group].clockOff(
cmdq_mdp_get_func()->getEngineGroupBits(group) & engine_flag);
if (status < 0)
CMDQ_ERR("[CLOCK]enable group %d clockOn failed\n", group);
}
static void cmdq_core_group_clk_cb(bool enable,
u64 engine_flag, u64 engine_clk)
{
s32 index;
/* ISP special check: Always call ISP on/off if this task
* involves ISP. Ignore the ISP HW flags.
*/
if (cmdq_core_is_group_flag(CMDQ_GROUP_ISP, engine_flag)) {
if (enable)
cmdq_core_group_clk_on(CMDQ_GROUP_ISP, engine_flag);
else
cmdq_core_group_clk_off(CMDQ_GROUP_ISP, engine_flag);
}
for (index = CMDQ_MAX_GROUP_COUNT - 1; index >= 0; index--) {
/* note that ISP is per-task on/off, not per HW flag */
if (index == CMDQ_GROUP_ISP)
continue;
if (cmdq_core_is_group_flag(index, engine_flag)) {
if (enable)
cmdq_core_group_clk_on(index, engine_clk);
else
cmdq_core_group_clk_off(index, engine_clk);
}
}
#if defined(CONFIG_MACH_MT6853)
if ((engine_flag & CMDQ_ENG_MDP_GROUP_BITS) && enable)
smi_larb_port_check();
#endif
}
bool cmdq_thread_in_use(void)
{
return (bool)(atomic_read(&cmdq_thread_usage) > 0);
}
static void mdp_lock_wake_lock(bool lock)
{
CMDQ_SYSTRACE_BEGIN("%s_%s\n", __func__, lock ? "lock" : "unlock");
if (lock) {
if (!mdp_wake_locked) {
__pm_stay_awake(mdp_wake_lock);
mdp_wake_locked = true;
} else {
/* should not reach here */
CMDQ_ERR("try lock twice\n");
dump_stack();
}
} else {
if (mdp_wake_locked) {
__pm_relax(mdp_wake_lock);
mdp_wake_locked = false;
} else {
/* should not reach here */
CMDQ_ERR("try unlock twice\n");
dump_stack();
}
}
CMDQ_SYSTRACE_END();
}
static void cmdq_core_clk_enable(struct cmdqRecStruct *handle)
{
s32 clock_count;
clock_count = atomic_inc_return(&cmdq_thread_usage);
CMDQ_MSG("[CLOCK]enable usage:%d scenario:%d\n",
clock_count, handle->scenario);
if (clock_count == 1)
mdp_lock_wake_lock(true);
cmdq_core_group_clk_cb(true, handle->engineFlag, handle->engine_clk);
}
static void cmdq_core_clk_disable(struct cmdqRecStruct *handle)
{
s32 clock_count;
cmdq_core_group_clk_cb(false, handle->engineFlag, handle->engine_clk);
clock_count = atomic_dec_return(&cmdq_thread_usage);
CMDQ_MSG("[CLOCK]disable usage:%d\n", clock_count);
if (clock_count == 0)
mdp_lock_wake_lock(false);
else if (clock_count < 0)
CMDQ_ERR(
"enable clock %s error usage:%d smi use:%d\n",
__func__, clock_count,
(s32)atomic_read(&cmdq_thread_usage));
}
s32 cmdq_core_suspend_hw_thread(s32 thread)
{
struct cmdq_client *client;
if (thread == CMDQ_INVALID_THREAD) {
CMDQ_ERR("invalid thread to suspend\n");
return -EINVAL;
}
client = cmdq_clients[(u32)thread];
if (!client) {
CMDQ_ERR("mbox client not ready for thread:%d suspend\n",
thread);
dump_stack();
return -EINVAL;
}
return cmdq_mbox_thread_suspend(client->chan);
}
u64 cmdq_core_get_gpr64(const enum cmdq_gpr_reg regID)
{
u64 value, value1, value2;
const u32 x = regID & 0x0F;
if ((regID & 0x10) > 0) {
/* query address GPR(64bit), Px */
value1 = 0LL | CMDQ_REG_GET32(CMDQ_GPR_R32((2 * x)));
value2 = 0LL | CMDQ_REG_GET32(CMDQ_GPR_R32((2 * x + 1)));
} else {
/* query data GPR(32bit), Rx */
value1 = 0LL | CMDQ_REG_GET32(CMDQ_GPR_R32(x));
value2 = 0LL;
}
value = (0LL) | (value2 << 32) | (value1);
CMDQ_VERBOSE("get_GPR64(%x):0x%llx(0x%llx, 0x%llx)\n",
regID, value, value2, value1);
return value;
}
void cmdq_core_set_gpr64(const enum cmdq_gpr_reg reg_id, const u64 value)
{
const u64 value1 = 0x00000000FFFFFFFF & value;
const u64 value2 = 0LL | value >> 32;
const u32 x = reg_id & 0x0F;
u64 result;
if ((reg_id & 0x10) > 0) {
/* set address GPR(64bit), Px */
CMDQ_REG_SET32(CMDQ_GPR_R32((2 * x)), value1);
CMDQ_REG_SET32(CMDQ_GPR_R32((2 * x + 1)), value2);
} else {
/* set data GPR(32bit), Rx */
CMDQ_REG_SET32(CMDQ_GPR_R32((2 * x)), value1);
}
result = 0LL | cmdq_core_get_gpr64(reg_id);
if (value != result) {
CMDQ_ERR(
"set GPR64 0x%08x failed value:0x%llx is not value:0x%llx\n",
reg_id, result, value);
}
}
static inline u32 cmdq_core_get_subsys_id(u32 arg_a)
{
return (arg_a & CMDQ_ARG_A_SUBSYS_MASK) >> subsys_lsb_bit;
}
static void cmdq_core_replace_overwrite_instr(struct cmdqRecStruct *handle,
u32 index)
{
/* check if this is overwrite instruction */
u32 *p_cmd_assign = (u32 *)cmdq_pkt_get_va_by_offset(handle->pkt,
(index - 1) * CMDQ_INST_SIZE);
if (!p_cmd_assign) {
CMDQ_LOG("Cannot find va, handle:%p pkt:%p index:%u\n",
handle, handle->pkt, index);
return;
}
if ((p_cmd_assign[1] >> 24) == CMDQ_CODE_LOGIC &&
((p_cmd_assign[1] >> 23) & 1) == 1 &&
cmdq_core_get_subsys_id(p_cmd_assign[1]) ==
CMDQ_LOGIC_ASSIGN &&
(p_cmd_assign[1] & 0xFFFF) == CMDQ_SPR_FOR_TEMP) {
u32 overwrite_index = p_cmd_assign[0];
dma_addr_t overwrite_pa = cmdq_pkt_get_pa_by_offset(
handle->pkt, overwrite_index * CMDQ_INST_SIZE);
p_cmd_assign[0] = (u32) overwrite_pa;
CMDQ_LOG("overwrite: original index:%d, change to PA:%pa\n",
overwrite_index, &overwrite_pa);
}
}
static void cmdq_core_v3_adjust_jump(struct cmdqRecStruct *handle,
u32 instr_pos, u32 *va)
{
u32 offset;
dma_addr_t pa;
if (va[1] & 0x1)
return;
offset = instr_pos * CMDQ_INST_SIZE + CMDQ_REG_REVERT_ADDR(va[0]);
if (offset == handle->pkt->buf_size) {
/* offset to last instruction may not adjust,
* return back 1 instruction
*/
offset = offset - CMDQ_INST_SIZE;
}
/* change to absolute to avoid jump cross buffer */
pa = cmdq_pkt_get_pa_by_offset(handle->pkt, offset);
CMDQ_MSG("Replace jump from:0x%08x to offset:%u\n", va[0], offset);
va[1] = va[1] | 0x1;
va[0] = CMDQ_PHYS_TO_AREG(CMDQ_REG_SHIFT_ADDR(pa));
}
static void cmdq_core_v3_replace_arg(struct cmdqRecStruct *handle, u32 *va,
u32 arg_op_code, u32 inst_idx)
{
u32 arg_a_i;
u32 arg_a_type;
arg_a_type = va[1] & (1 << 23);
arg_a_i = va[1] & 0xFFFF;
if (arg_op_code == CMDQ_CODE_WRITE_S && inst_idx > 0 &&
arg_a_type != 0 && arg_a_i == CMDQ_SPR_FOR_TEMP)
cmdq_core_replace_overwrite_instr(handle, inst_idx);
}
static void cmdq_core_v3_replace_jumpc(struct cmdqRecStruct *handle,
u32 *va, u32 inst_idx, u32 inst_pos)
{
u32 *p_cmd_logic = (u32 *)cmdq_pkt_get_va_by_offset(handle->pkt,
(inst_idx - 1) * CMDQ_INST_SIZE);
bool revise_offset = false;
if (!p_cmd_logic) {
CMDQ_LOG("Cannot find va, handle:%p pkt:%p idx:%u pos:%u\n",
handle, handle->pkt, inst_idx, inst_pos);
return;
}
/* logic and jump relative maybe separate by jump cross buffer */
if (p_cmd_logic[1] == ((CMDQ_CODE_JUMP << 24) | 1)) {
CMDQ_MSG(
"Re-adjust new logic instruction due to jump cross buffer:%u\n",
inst_idx);
p_cmd_logic = (u32 *)cmdq_pkt_get_va_by_offset(
handle->pkt, (inst_idx - 2) * CMDQ_INST_SIZE);
revise_offset = true;
}
if (!p_cmd_logic) {
CMDQ_LOG("Cannot find va, handle:%p pkt:%p idx:%u pos:%u\n",
handle, handle->pkt, inst_idx, inst_pos);
return;
}
if ((p_cmd_logic[1] >> 24) == CMDQ_CODE_LOGIC &&
((p_cmd_logic[1] >> 16) & 0x1F) == CMDQ_LOGIC_ASSIGN) {
u32 jump_op = CMDQ_CODE_JUMP_C_ABSOLUTE << 24;
u32 jump_op_header = va[1] & 0xFFFFFF;
u32 jump_offset = CMDQ_REG_REVERT_ADDR(p_cmd_logic[0]);
u32 offset_target = (revise_offset) ?
(inst_pos - 1) * CMDQ_INST_SIZE + jump_offset :
inst_pos * CMDQ_INST_SIZE + jump_offset;
dma_addr_t dest_addr_pa;
dest_addr_pa = cmdq_pkt_get_pa_by_offset(
handle->pkt, offset_target);
if (dest_addr_pa == 0) {
cmdq_core_dump_handle(handle, "ERR");
CMDQ_AEE("CMDQ",
"Wrong PA offset, task:0x%p, inst idx:0x%08x cmd:0x%08x:%08x addr:0x%p\n",
handle, inst_idx, p_cmd_logic[1],
p_cmd_logic[0], p_cmd_logic);
return;
}
p_cmd_logic[0] = CMDQ_PHYS_TO_AREG(
CMDQ_REG_SHIFT_ADDR(dest_addr_pa));
va[1] = jump_op | jump_op_header;
CMDQ_MSG(
"Replace jump_c inst idx:%u(%u) cmd:0x%p %#018llx logic:0x%p %#018llx\n",
inst_idx, inst_pos,
va, *(u64 *)va,
p_cmd_logic, *(u64 *)p_cmd_logic);
} else {
/* unable to jump correctly since relative offset
* may cross page
*/
CMDQ_ERR(
"No logic before jump, handle:0x%p, inst idx:0x%08x cmd:0x%p 0x%08x:%08x logic:0x%p 0x%08x:0x%08x\n",
handle, inst_idx,
va, va[1], va[0],
p_cmd_logic, p_cmd_logic[1], p_cmd_logic[0]);
}
}
void cmdq_core_replace_v3_instr(struct cmdqRecStruct *handle, s32 thread)
{
u32 i;
u32 arg_op_code;
u32 *p_cmd_va;
u32 *p_instr_position = CMDQ_U32_PTR(handle->replace_instr.position);
u32 inst_idx = 0;
const u32 boundary_idx = (handle->pkt->buf_size / CMDQ_INST_SIZE);
if (handle->replace_instr.number == 0)
return;
CMDQ_MSG("replace_instr.number:%u\n", handle->replace_instr.number);
for (i = 0; i < handle->replace_instr.number; i++) {
if ((p_instr_position[i] + 1) * CMDQ_INST_SIZE >
handle->pkt->cmd_buf_size) {
CMDQ_ERR(
"Incorrect replace instruction position, index (%d), size (%zu)\n",
p_instr_position[i],
handle->pkt->cmd_buf_size);
break;
}
inst_idx = p_instr_position[i];
if (inst_idx == boundary_idx) {
/* last jump instruction may not adjust,
* return back 1 instruction
*/
inst_idx--;
}
p_cmd_va = (u32 *)cmdq_pkt_get_va_by_offset(handle->pkt,
inst_idx * CMDQ_INST_SIZE);
if (!p_cmd_va) {
CMDQ_AEE("CMDQ",
"Cannot find va, task:0x%p idx:%u/%u instruction idx:%u(%u) size:%zu+%zu\n",
handle, i, handle->replace_instr.number,
inst_idx, p_instr_position[i],
handle->pkt->buf_size,
handle->pkt->avail_buf_size);
cmdq_core_dump_handle_buffer(handle->pkt, "ERR");
continue;
}
arg_op_code = p_cmd_va[1] >> 24;
if (arg_op_code == CMDQ_CODE_JUMP) {
if (!handle->ctrl->change_jump)
continue;
cmdq_core_v3_adjust_jump(handle,
(u32)p_instr_position[i], p_cmd_va);
} else {
CMDQ_MSG(
"replace instruction: (%d)0x%p:0x%08x 0x%08x\n",
i, p_cmd_va, p_cmd_va[0], p_cmd_va[1]);
cmdq_core_v3_replace_arg(handle, p_cmd_va,
arg_op_code, inst_idx);
}
if (arg_op_code == CMDQ_CODE_JUMP_C_RELATIVE) {
if (!handle->ctrl->change_jump)
continue;
cmdq_core_v3_replace_jumpc(handle, p_cmd_va, inst_idx,
p_instr_position[i]);
}
}
}
void cmdq_core_release_handle_by_file_node(void *file_node)
{
struct cmdqRecStruct *handle;
struct cmdq_client *client;
mutex_lock(&cmdq_handle_list_mutex);
list_for_each_entry(handle, &cmdq_ctx.handle_active, list_entry) {
if (handle->node_private != file_node)
continue;
CMDQ_LOG(
"[warn]running handle 0x%p auto release because file node 0x%p closed\n",
handle, file_node);
/* since we already inside mutex, do not release directly,
* instead we change state to "KILLED"
* and arrange a auto-release.
* Note that these tasks may already issued to HW
* so there is a chance that following MPU/M4U
* violation may occur, if the user space process has
* destroyed.
* The ideal solution is to stop / cancel HW operation
* immediately, but we cannot do so due to SMI hang risk.
*/
client = cmdq_clients[(u32)handle->thread];
#if IS_ENABLED(CONFIG_MTK_CMDQ_MBOX_EXT)
#if defined(CONFIG_MTK_SEC_VIDEO_PATH_SUPPORT) || \
defined(CONFIG_MTK_CAM_SECURITY_SUPPORT)
#ifdef CMDQ_SECURE_PATH_SUPPORT
if (handle->pkt->sec_data)
cmdq_sec_mbox_stop(client);
else
#endif
#endif
#endif
cmdq_mbox_thread_remove_task(client->chan, handle->pkt);
cmdq_pkt_auto_release_task(handle, true);
}
mutex_unlock(&cmdq_handle_list_mutex);
}
s32 cmdq_core_suspend(void)
{
s32 ref_count;
u32 exec_thread = 0;
bool kill_task = false;
ref_count = atomic_read(&cmdq_thread_usage);
if (ref_count)
exec_thread = CMDQ_REG_GET32(CMDQ_CURR_LOADED_THR);
CMDQ_LOG("%s usage:%d exec thread:0x%x\n",
__func__, ref_count, exec_thread);
if (cmdq_get_func()->moduleEntrySuspend(cmdq_mdp_get_engines()) < 0) {
CMDQ_ERR(
"[SUSPEND] MDP running, kill tasks. threads:0x%08x ref:%d\n",
exec_thread, ref_count);
kill_task = true;
} else if ((ref_count > 0) || (0x80000000 & exec_thread)) {
CMDQ_ERR(
"[SUSPEND] other running, kill tasks. threads:0x%08x ref:%d\n",
exec_thread, ref_count);
kill_task = true;
}
/* TODO:
* We need to ensure the system is ready to suspend,
* so kill all running CMDQ tasks
* and release HW engines.
*/
if (kill_task) {
#if 0
CMDQ_PROF_MUTEX_LOCK(gCmdqTaskMutex, suspend_kill);
/* print active tasks */
CMDQ_ERR("[SUSPEND] active tasks during suspend:\n");
list_for_each(p, &cmdq_ctx.taskActiveList) {
pTask = list_entry(p, struct TaskStruct, listEntry);
if (cmdq_core_is_valid_in_active_list(pTask))
cmdq_core_dump_task(pTask);
}
/* remove all active task from thread */
CMDQ_ERR("[SUSPEND] remove all active tasks\n");
list_for_each(p, &cmdq_ctx.taskActiveList) {
pTask = list_entry(p, struct TaskStruct, listEntry);
if (pTask->thread != CMDQ_INVALID_THREAD) {
spin_lock_irqsave(&gCmdqExecLock, flags,
suspend_loop);
CMDQ_ERR("[SUSPEND] release task:0x%p\n",
pTask);
cmdq_core_force_remove_task_from_thread(pTask,
pTask->thread);
pTask->taskState = TASK_STATE_KILLED;
spin_unlock_irqrestore(&gCmdqExecLock, flags,
suspend_loop);
/* release all thread and mark active tasks
* as "KILLED" (so that thread won't release
* again)
*/
CMDQ_ERR(
"[SUSPEND] release all threads and HW clocks\n");
cmdq_core_release_thread(pTask);
}
}
CMDQ_PROF_MUTEX_UNLOCK(gCmdqTaskMutex, suspend_kill);
/* TODO: skip secure path thread... */
/* disable all HW thread */
CMDQ_ERR("[SUSPEND] disable all HW threads\n");
for (i = 0; i < max_thread_count; i++)
cmdq_core_disable_HW_thread(i);
/* reset all threadStruct */
cmdq_core_reset_thread_struct();
/* reset all engineStruct */
memset(&cmdq_ctx.engine[0], 0,
sizeof(cmdq_ctx.engine));
cmdq_core_reset_engine_struct();
#endif
}
CMDQ_MSG("CMDQ is suspended\n");
/* ALWAYS allow suspend */
return 0;
}
s32 cmdq_core_resume(void)
{
CMDQ_VERBOSE("[RESUME] do nothing\n");
/* do nothing */
return 0;
}
s32 cmdq_core_resume_notifier(void)
{
s32 ref_count;
CMDQ_LOG("%s\n", __func__);
/* TEE project limitation:
* .t-base daemon process is available after process-unfreeze
* .need t-base daemon for communication to secure world
* .M4U port security setting backup/resore needs to entry sec world
* .M4U port security setting is access normal PA
*
* Delay resume timing until process-unfreeze done in order to
* ensure M4U driver had restore M4U port security setting
*/
ref_count = atomic_read(&cmdq_thread_usage);
cmdq_mdp_resume();
return 0;
}
void cmdq_core_set_spm_mode(enum CMDQ_SPM_MODE mode)
{
CMDQ_MSG("before setting, reg:0x%x\n",
CMDQ_REG_GET32(CMDQ_H_SPEED_BUSY));
switch (mode) {
case CMDQ_CG_MODE:
CMDQ_REG_SET32(CMDQ_H_SPEED_BUSY, 0x20002);
break;
case CMDQ_PD_MODE:
CMDQ_REG_SET32(CMDQ_H_SPEED_BUSY, 0x3);
break;
default:
break;
}
CMDQ_MSG("after setting, reg:0x%x\n",
CMDQ_REG_GET32(CMDQ_H_SPEED_BUSY));
}
struct ContextStruct *cmdq_core_get_context(void)
{
return &cmdq_ctx;
}
struct CmdqCBkStruct *cmdq_core_get_group_cb(void)
{
return cmdq_group_cb;
}
dma_addr_t cmdq_core_get_pc(s32 thread)
{
dma_addr_t pc;
if (atomic_read(&cmdq_thread_usage) <= 0) {
CMDQ_ERR("%s get pc thread:%d violation\n",
__func__, thread);
dump_stack();
return 0;
}
pc = CMDQ_REG_GET32(CMDQ_THR_CURR_ADDR(thread));
if (CMDQ_IS_SRAM_ADDR(pc))
return pc;
return CMDQ_REG_REVERT_ADDR(pc);
}
dma_addr_t cmdq_core_get_end(s32 thread)
{
dma_addr_t end = CMDQ_REG_GET32(CMDQ_THR_END_ADDR(thread));
if (CMDQ_IS_SRAM_ADDR(end))
return end;
return CMDQ_REG_REVERT_ADDR(end);
}
static s32 cmdq_pkt_handle_wait_result(struct cmdqRecStruct *handle, s32 thread)
{
s32 ret = 0;
/* set to timeout if state change to */
if (handle->state == TASK_STATE_TIMEOUT) {
/* timeout info already dump during callback */
ret = -ETIMEDOUT;
} else if (handle->state == TASK_STATE_ERR_IRQ) {
/* dump current buffer for trace */
ret = -EINVAL;
CMDQ_ERR("dump error irq handle:0x%p pc:0x%08x\n",
handle, handle->error_irq_pc);
cmdq_core_dump_error_buffer(handle, NULL,
handle->error_irq_pc);
CMDQ_AEE("CMDQ", "Error IRQ\n");
}
return ret;
}
/* core controller function */
static const struct cmdq_controller g_cmdq_core_ctrl = {
#if 0
.compose = cmdq_core_task_compose,
.copy_command = cmdq_core_task_copy_command,
#endif
.get_thread_id = cmdq_core_get_thread_id,
#if 0
.execute_prepare = cmdq_core_exec_task_prepare,
.execute = cmdq_core_exec_task_async_impl,
.handle_wait_result = cmdq_core_handle_wait_task_result_impl,
.free_buffer = cmdq_core_task_free_buffer_impl,
.append_command = cmdq_core_append_command,
.dump_err_buffer = cmdq_core_dump_err_buffer,
.dump_summary = cmdq_core_dump_summary,
#endif
.handle_wait_result = cmdq_pkt_handle_wait_result,
.change_jump = true,
};
const struct cmdq_controller *cmdq_core_get_controller(void)
{
return &g_cmdq_core_ctrl;
}
static bool cmdq_pkt_is_buffer_size_valid(const struct cmdqRecStruct *handle)
{
return (handle->pkt->cmd_buf_size % CMDQ_CMD_BUFFER_SIZE ==
(handle->pkt->avail_buf_size > 0 ?
CMDQ_CMD_BUFFER_SIZE - handle->pkt->avail_buf_size : 0));
}
s32 cmdq_pkt_get_cmd_by_pc(const struct cmdqRecStruct *handle, u32 pc,
u32 *inst_out, u32 size)
{
void *va = NULL;
u32 i = 0;
struct cmdq_pkt_buffer *buf;
bool found = false;
if (!inst_out)
return -EINVAL;
CMDQ_MSG("%s handle:0x%p pc:0x%08x inst_out:0x%p size:%d\n",
__func__, handle, pc, inst_out, size);
list_for_each_entry(buf, &handle->pkt->buf, list_entry) {
if (!found && !(pc >= buf->pa_base &&
pc < buf->pa_base + CMDQ_CMD_BUFFER_SIZE))
continue;
if (!found)
va = buf->va_base + (pc - buf->pa_base);
else
va = buf->va_base;
found = true;
for (i = 0; i < size; i++, va += 4) {
if (va >= buf->va_base + CMDQ_CMD_BUFFER_SIZE)
break;
inst_out[i] = *((u32 *)va);
}
/* maybe next buffer */
size -= i;
if (!size)
break;
}
return 0;
}
void cmdq_pkt_get_first_buffer(struct cmdqRecStruct *handle,
void **va_out, dma_addr_t *pa_out)
{
struct cmdq_pkt_buffer *buf;
if (list_empty(&handle->pkt->buf))
return;
buf = list_first_entry(&handle->pkt->buf, typeof(*buf), list_entry);
*va_out = buf->va_base;
*pa_out = buf->pa_base;
}
void *cmdq_pkt_get_first_va(const struct cmdqRecStruct *handle)
{
struct cmdq_pkt_buffer *buf;
if (list_empty(&handle->pkt->buf))
return NULL;
buf = list_first_entry(&handle->pkt->buf, typeof(*buf), list_entry);
return buf->va_base;
}
static s32 cmdq_pkt_copy_buffer(void *dst, void *src, const u32 size,
const bool is_copy_from_user)
{
s32 status = 0;
if (!is_copy_from_user) {
CMDQ_VERBOSE("copy kernel to 0x%p\n", dst);
memcpy(dst, src, size);
} else {
CMDQ_VERBOSE("copy user to 0x%p\n", dst);
if (copy_from_user(dst, src, size)) {
CMDQ_AEE("CMDQ",
"CRDISPATCH_KEY:CMDQ Fail to copy from user 0x%p, size:%d\n",
src, size);
status = -ENOMEM;
}
}
return status;
}
s32 cmdq_pkt_copy_cmd(struct cmdqRecStruct *handle, void *src, const u32 size,
const bool is_copy_from_user)
{
s32 status = 0;
u32 remaind_cmd_size = size;
u32 copy_size = 0;
struct cmdq_pkt *pkt = handle->pkt;
void *va;
struct cmdq_pkt_buffer *buf;
u64 exec_cost = sched_clock();
while (remaind_cmd_size > 0) {
/* extend buffer to copy more instruction */
if (!handle->pkt->avail_buf_size) {
if (cmdq_pkt_add_cmd_buffer(handle->pkt) < 0)
return -ENOMEM;
}
copy_size = pkt->avail_buf_size > remaind_cmd_size ?
remaind_cmd_size : pkt->avail_buf_size;
buf = list_last_entry(&pkt->buf, typeof(*buf), list_entry);
va = buf->va_base + CMDQ_CMD_BUFFER_SIZE - pkt->avail_buf_size;
status = cmdq_pkt_copy_buffer(va,
src + size - remaind_cmd_size,
copy_size, is_copy_from_user);
if (status < 0)
return status;
/* update last instruction position */
pkt->avail_buf_size -= copy_size;
pkt->cmd_buf_size += copy_size;
remaind_cmd_size -= copy_size;
handle->cmd_end = buf->va_base + CMDQ_CMD_BUFFER_SIZE -
pkt->avail_buf_size - CMDQ_INST_SIZE;
if (unlikely(!cmdq_pkt_is_buffer_size_valid(handle))) {
/* buffer size is total size and should sync
* with available space
*/
CMDQ_AEE("CMDQ",
"buf size:%zu size:%zu available size:%zu of %u end cmd:0x%p first va:0x%p out of sync!\n",
pkt->buf_size, pkt->cmd_buf_size,
pkt->avail_buf_size,
(u32)CMDQ_CMD_BUFFER_SIZE,
handle->cmd_end,
cmdq_pkt_get_first_va(handle));
cmdq_core_dump_handle(handle, "ERR");
}
CMDQ_MSG(
"buf size:%zu size:%zu available:%zu end:0x%p va:0x%p\n",
pkt->buf_size, pkt->cmd_buf_size, pkt->avail_buf_size,
handle->cmd_end, va);
}
exec_cost = div_s64(sched_clock() - exec_cost, 1000);
if (exec_cost > 2000)
CMDQ_LOG("[warn]%s > 2ms cost:%lluus size:%u\n",
__func__, exec_cost, size);
return status;
}
static s32 cmdq_pkt_lock_handle(struct cmdqRecStruct *handle,
struct cmdq_client **client_out)
{
struct cmdq_client *client;
s32 ref;
if (handle->thread == CMDQ_INVALID_THREAD) {
CMDQ_ERR("invalid thread handle:0x%p scenario:%d\n",
handle, handle->scenario);
return -EINVAL;
}
client = cmdq_clients[(u32)handle->thread];
if (!client) {
CMDQ_ERR("mbox client not ready for thread:%d\n",
handle->thread);
dump_stack();
return -EINVAL;
}
ref = atomic_inc_return(&handle->exec);
if (ref > 1) {
atomic_dec(&handle->exec);
CMDQ_LOG(
"[warn]handle already executed:0x%p ref:%d scenario:%u\n",
handle, ref, handle->scenario);
return -EBUSY;
}
CMDQ_MSG("lock handle:0x%p thread:%d engine:0x%llx scenario:%u\n",
handle, handle->thread, handle->res_flag_acquire,
handle->scenario);
/* change state to busy */
handle->state = TASK_STATE_BUSY;
handle->gotIRQ = 0;
*client_out = client;
/* protect multi-thread lock/unlock same time */
mutex_lock(&cmdq_clock_mutex);
/* callback clients we are about to start handle in gce */
handle->prepare(handle);
/* task and thread dispatched, increase usage */
cmdq_core_clk_enable(handle);
mutex_unlock(&cmdq_clock_mutex);
mutex_lock(&cmdq_handle_list_mutex);
list_add_tail(&handle->list_entry, &cmdq_ctx.handle_active);
mutex_unlock(&cmdq_handle_list_mutex);
return 0;
}
static void cmdq_core_group_begin_task(struct cmdqRecStruct *handle,
struct cmdqRecStruct **handle_list, u32 size)
{
enum CMDQ_GROUP_ENUM group = 0;
for (group = 0; group < CMDQ_MAX_GROUP_COUNT; group++) {
if (!cmdq_group_cb[group].beginTask ||
!cmdq_core_is_group_flag(group, handle->engineFlag))
continue;
cmdq_group_cb[group].beginTask(handle, handle_list, size);
}
}
static void cmdq_core_group_end_task(struct cmdqRecStruct *handle,
struct cmdqRecStruct **handle_list, u32 size)
{
enum CMDQ_GROUP_ENUM group = 0;
for (group = 0; group < CMDQ_MAX_GROUP_COUNT; group++) {
if (!cmdq_group_cb[group].endTask ||
!cmdq_core_is_group_flag(group, handle->engineFlag))
continue;
cmdq_group_cb[group].endTask(handle, handle_list, size);
}
}
static s32 cmdq_core_get_pmqos_handle_list(struct cmdqRecStruct *handle,
struct cmdqRecStruct **handle_out, u32 handle_list_size)
{
struct cmdq_client *client;
struct cmdq_pkt **pkt_list = NULL;
u32 i;
u32 pkt_count;
if (!handle || !handle_out || !handle_list_size)
return -EINVAL;
pkt_list = kcalloc(handle_list_size, sizeof(*pkt_list), GFP_KERNEL);
if (!pkt_list)
return -ENOMEM;
client = cmdq_clients[(u32)handle->thread];
cmdq_task_get_pkt_from_thread(client->chan, pkt_list,
handle_list_size, &pkt_count);
/* get handle from user_data */
for (i = 0; i < pkt_count; i++) {
if (!pkt_list[i])
continue;
handle_out[i] = pkt_list[i]->user_data;
}
kfree(pkt_list);
return 0;
}
void cmdq_pkt_release_handle(struct cmdqRecStruct *handle)
{
s32 ref;
struct ContextStruct *ctx;
struct cmdqRecStruct **pmqos_handle_list = NULL;
u32 handle_count;
CMDQ_MSG("release handle:0x%p pkt:0x%p thread:%d engine:0x%llx\n",
handle, handle->pkt, handle->thread,
handle->res_flag_release);
ref = atomic_dec_return(&handle->exec);
if (ref != 0) {
CMDQ_ERR("handle state not right:0x%p ref:%d thread:%d\n",
handle, ref, handle->thread);
mutex_lock(&cmdq_handle_list_mutex);
list_del_init(&handle->list_entry);
mutex_unlock(&cmdq_handle_list_mutex);
dump_stack();
return;
}
cmdq_core_track_handle_record(handle, handle->thread);
/* TODO: remove is_secure check */
if (handle->thread != CMDQ_INVALID_THREAD) {
ctx = cmdq_core_get_context();
mutex_lock(&ctx->thread[(u32)handle->thread].thread_mutex);
/* PMQoS Implement */
mutex_lock(&cmdq_thread_mutex);
handle_count =
--ctx->thread[(u32)handle->thread].handle_count;
if (handle_count) {
pmqos_handle_list = kcalloc(handle_count + 1,
sizeof(*pmqos_handle_list), GFP_KERNEL);
if (pmqos_handle_list)
cmdq_core_get_pmqos_handle_list(
handle,
pmqos_handle_list,
handle_count);
}
cmdq_core_group_end_task(handle, pmqos_handle_list,
handle_count);
kfree(pmqos_handle_list);
mutex_unlock(&cmdq_thread_mutex);
mutex_unlock(&ctx->thread[(u32)handle->thread].thread_mutex);
}
/* protect multi-thread lock/unlock same time */
mutex_lock(&cmdq_clock_mutex);
/* callback clients this thread about to clean */
handle->unprepare(handle);
/* before stop job, decrease usage */
cmdq_core_clk_disable(handle);
/* stop callback */
if (handle->stop)
handle->stop(handle);
mutex_unlock(&cmdq_clock_mutex);
mutex_lock(&cmdq_handle_list_mutex);
list_del_init(&handle->list_entry);
mutex_unlock(&cmdq_handle_list_mutex);
}
static void cmdq_pkt_err_dump_handler(struct cmdq_cb_data data)
{
struct cmdqRecStruct *handle = (struct cmdqRecStruct *)data.data;
if (!handle)
return;
if (!handle->pkt->loop && handle->gotIRQ) {
CMDQ_ERR(
"%s handle:0x%p irq already processed:%llu scene:%d thread:%d\n",
__func__, handle, handle->gotIRQ, handle->scenario,
handle->thread);
return;
}
CMDQ_PROF_MMP(mdp_mmp_get_event()->timeout, MMPROFILE_FLAG_START,
(unsigned long)handle, handle->thread);
if (data.err == -ETIMEDOUT) {
atomic_inc(&handle->exec);
cmdq_core_attach_error_handle_by_state(handle,
TASK_STATE_TIMEOUT);
atomic_dec(&handle->exec);
} else if (data.err == -EINVAL) {
/* store PC for later dump buffer */
handle->error_irq_pc = cmdq_core_get_pc(handle->thread);
}
CMDQ_PROF_MMP(mdp_mmp_get_event()->timeout, MMPROFILE_FLAG_END,
(unsigned long)handle, handle->thread);
}
static void cmdq_pkt_flush_handler(struct cmdq_cb_data data)
{
struct cmdqRecStruct *handle = (struct cmdqRecStruct *)data.data;
struct cmdq_client *client = NULL;
if (!handle)
return;
if (!handle->pkt->loop && handle->gotIRQ) {
CMDQ_ERR(
"%s handle:0x%p irq already processed:%llu scene:%d thread:%d\n",
__func__, handle, handle->gotIRQ, handle->scenario,
handle->thread);
return;
}
if (atomic_read(&handle->exec) > 1) {
CMDQ_ERR("irq during error dump:%d err:%d\n",
atomic_read(&handle->exec), data.err);
dump_stack();
return;
}
handle->gotIRQ = sched_clock();
/* revise log level for debug */
if (data.err && data.err != -ECONNABORTED && !handle->pkt->loop) {
CMDQ_ERR(
"flush handler handle:0x%p err:%d thread:%d\n",
data.data, data.err, handle->thread);
} else {
CMDQ_MSG(
"flush handler handle:0x%p err:%d loop cb:0x%p thread:%d\n",
data.data, data.err, handle->loop_cb, handle->thread);
}
if (handle->pkt->loop) {
s32 loop_ret = 0;
if (handle->loop_cb) {
/* for loop task only callback and no need to do more */
CMDQ_LOG("loop callback handle:0x%p\n", handle);
loop_ret = handle->loop_cb(handle->loop_user_data);
CMDQ_LOG("loop callback done\n");
}
CMDQ_PROF_MMP(mdp_mmp_get_event()->loopBeat,
MMPROFILE_FLAG_PULSE, handle->thread, loop_ret);
if (data.err == -ECONNABORTED) {
/* loop stopped */
handle->state = TASK_STATE_KILLED;
}
return;
}
client = cmdq_clients[(u32)handle->thread];
if (data.err == -ETIMEDOUT) {
/* error dump may processed on error handler */
handle->state = TASK_STATE_TIMEOUT;
} else if (data.err == -ECONNABORTED) {
/* task killed */
handle->state = TASK_STATE_KILLED;
} else if (data.err == -EINVAL) {
/* IRQ with error, dump commands */
handle->state = TASK_STATE_ERR_IRQ;
} else if (data.err < 0) {
/* unknown error print it */
handle->state = TASK_STATE_KILLED;
CMDQ_ERR("%s error code:%d\n", __func__, data.err);
} else {
/* success done */
handle->state = TASK_STATE_DONE;
}
/* reset hardware in timeout or error irq case,
* so that hardware may work again on next task.
*/
if (handle->state == TASK_STATE_TIMEOUT ||
handle->state == TASK_STATE_ERR_IRQ)
cmdq_core_group_reset_hw(handle->engineFlag);
CMDQ_PROF_MMP(mdp_mmp_get_event()->CMDQ_IRQ, MMPROFILE_FLAG_PULSE,
(unsigned long)handle, handle->thread);
}
s32 cmdq_pkt_dump_command(struct cmdqRecStruct *handle)
{
const void *inst;
u32 size;
static char text[128] = { 0 };
struct cmdq_pkt *pkt;
struct cmdq_pkt_buffer *buf;
u32 cnt = 0;
if (!handle)
return -EINVAL;
pkt = handle->pkt;
CMDQ_LOG("===== REC 0x%p command buffer =====\n", handle);
cmdq_core_dump_error_buffer(handle, NULL, 0);
CMDQ_LOG("===== REC 0x%p command buffer END =====\n", handle);
list_for_each_entry(buf, &pkt->buf, list_entry) {
if (list_is_last(&buf->list_entry, &pkt->buf)) {
size = CMDQ_CMD_BUFFER_SIZE - pkt->avail_buf_size;
} else if (cnt > 2) {
CMDQ_LOG(
"buffer %u va:0x%p pa:%pa 0x%016llx (skip detail) 0x%016llx\n",
cnt, buf->va_base, &buf->pa_base,
*((u64 *)buf->va_base),
*((u64 *)(buf->va_base +
CMDQ_CMD_BUFFER_SIZE - CMDQ_INST_SIZE)));
cnt++;
continue;
} else {
size = CMDQ_CMD_BUFFER_SIZE;
}
CMDQ_LOG("buffer %u va:0x%p pa:%pa\n",
cnt, buf->va_base, &buf->pa_base);
for (inst = buf->va_base; inst < buf->va_base + size;
inst += CMDQ_INST_SIZE) {
cmdq_core_parse_instruction(inst, text, 128);
CMDQ_LOG("0x%p %s", inst, text);
}
cnt++;
}
CMDQ_LOG("======REC 0x%p command END\n", handle);
return 0;
}
s32 cmdq_pkt_wait_flush_ex_result(struct cmdqRecStruct *handle)
{
s32 waitq;
s32 status;
struct cmdq_client *client;
CMDQ_PROF_MMP(mdp_mmp_get_event()->wait_task,
MMPROFILE_FLAG_PULSE, ((unsigned long)handle), handle->thread);
if (!cmdq_clients[(u32)handle->thread]) {
CMDQ_ERR("thread:%d cannot use since client is not used\n",
handle->thread);
return -EINVAL;
}
client = cmdq_clients[(u32)handle->thread];
if (!client->chan->mbox || !client->chan->mbox->dev)
CMDQ_AEE("CMDQ",
"chan:%u mbox:%p or mbox->dev:%p invalid!!",
handle->thread, client->chan->mbox,
client->chan->mbox->dev);
do {
/* wait event and pre-dump */
waitq = wait_event_timeout(
cmdq_wait_queue[(u32)handle->thread],
handle->pkt->flush_item != NULL,
msecs_to_jiffies(CMDQ_PREDUMP_TIMEOUT_MS));
if (waitq)
break;
CMDQ_LOG("wait flush handle:%p thread:%d\n",
handle, handle->thread);
cmdq_dump_pkt(handle->pkt, 0, false);
} while (1);
status = cmdq_pkt_wait_complete(handle->pkt);
if (status != -EINVAL) {
u64 submit_sec, wait_sec;
unsigned long submit_rem, wait_rem;
submit_sec = handle->pkt->rec_submit;
submit_rem = do_div(submit_sec, 1000000000);
wait_sec = handle->pkt->rec_wait;
wait_rem = do_div(wait_sec, 1000000000);
CMDQ_SYSTRACE2_BEGIN("%s %u %llu.%06lu %llu.%06lu\n", __func__,
handle->pkt->cmd_buf_size, submit_sec, submit_rem / 1000,
wait_sec, wait_rem / 1000);
CMDQ_SYSTRACE2_END();
}
if (handle->profile_exec && cmdq_util_is_feature_en(CMDQ_LOG_FEAT_PERF)) {
u32 *va = cmdq_pkt_get_perf_ret(handle->pkt);
if (va) {
if (va[0] == 0xdeaddead || va[1] == 0xdeaddead) {
CMDQ_ERR(
"task may not execute handle:%p pkt:%p exec:%#x %#x",
handle, handle->pkt, va[0], va[1]);
cmdq_dump_pkt(handle->pkt, 0, true);
} else {
u32 cost = va[1] < va[0] ?
~va[0] + va[1] : va[1] - va[0];
#if BITS_PER_LONG == 64
do_div(cost, 26);
#elif BITS_PER_LONG == 32
cost /= 26;
#else
#error "unsigned long division is not supported for this architecture"
#endif
if (cost > 80000) {
CMDQ_LOG(
"[WARN]task executes %uus engine:%#llx caller:%llu-%s\n",
cost, handle->engineFlag,
(u64)handle->caller_pid,
handle->caller_name);
}
}
}
}
CMDQ_PROF_MMP(mdp_mmp_get_event()->wait_task_done,
MMPROFILE_FLAG_PULSE, ((unsigned long)handle),
handle->wakedUp - handle->beginWait);
CMDQ_SYSTRACE_BEGIN("%s_wait_release\n", __func__);
cmdq_pkt_release_handle(handle);
CMDQ_SYSTRACE_END();
CMDQ_PROF_MMP(mdp_mmp_get_event()->wait_task_clean,
MMPROFILE_FLAG_PULSE, ((unsigned long)handle->pkt),
(unsigned long)handle->pkt);
return status;
}
static void cmdq_pkt_auto_release_work(struct work_struct *work)
{
struct cmdqRecStruct *handle;
CmdqAsyncFlushCB cb;
u64 user_data;
handle = container_of(work, struct cmdqRecStruct, auto_release_work);
if (unlikely(!handle)) {
CMDQ_ERR(
"auto release leak task! cannot get task from work item:0x%p\n",
work);
return;
}
cb = handle->async_callback;
user_data = handle->async_user_data;
CMDQ_PROF_MMP(mdp_mmp_get_event()->autoRelease_done,
MMPROFILE_FLAG_PULSE, ((unsigned long)handle), current->pid);
cmdq_pkt_wait_flush_ex_result(handle);
if (cb)
cb(user_data);
}
static void cmdq_pkt_auto_release_destroy_work(struct work_struct *work)
{
struct cmdqRecStruct *handle;
handle = container_of(work, struct cmdqRecStruct, auto_release_work);
if (unlikely(!handle)) {
CMDQ_ERR(
"auto w/ destroy leak task! cannot get task from work item:0x%p\n",
work);
return;
}
cmdq_pkt_auto_release_work(work);
CMDQ_LOG("in auto release destroy task:%p\n", handle);
cmdq_task_destroy(handle);
}
s32 cmdq_pkt_auto_release_task(struct cmdqRecStruct *handle,
bool destroy)
{
if (handle->thread == CMDQ_INVALID_THREAD) {
CMDQ_ERR(
"handle:0x%p pkt:0x%p invalid thread:%d scenario:%d\n",
handle, handle->pkt, handle->thread, handle->scenario);
return -EINVAL;
}
CMDQ_PROF_MMP(mdp_mmp_get_event()->autoRelease_add,
MMPROFILE_FLAG_PULSE, ((unsigned long)handle), handle->thread);
if (destroy) {
/* the work item is embedded in pTask already
* but we need to initialized it
*/
INIT_WORK(&handle->auto_release_work,
cmdq_pkt_auto_release_destroy_work);
} else {
/* use for mdp release by file node case,
* helps destroy task since user space not wait.
*/
INIT_WORK(&handle->auto_release_work,
cmdq_pkt_auto_release_work);
}
queue_work(cmdq_ctx.taskThreadAutoReleaseWQ[(u32)handle->thread],
&handle->auto_release_work);
return 0;
}
static s32 cmdq_pkt_flush_async_ex_impl(struct cmdqRecStruct *handle,
CmdqAsyncFlushCB cb, u64 user_data)
{
s32 err;
struct cmdq_client *client = NULL;
struct cmdqRecStruct **pmqos_handle_list = NULL;
struct ContextStruct *ctx;
u32 handle_count;
static wait_queue_head_t *wait_q;
int32_t thread;
if (!handle->finalized) {
CMDQ_ERR("handle not finalized:0x%p scenario:%d\n",
handle, handle->scenario);
return -EINVAL;
}
err = cmdq_pkt_lock_handle(handle, &client);
if (err < 0)
return err;
/* assign user async flush callback */
handle->async_callback = cb;
handle->async_user_data = user_data;
handle->pkt->err_cb.cb = cmdq_pkt_err_dump_handler;
handle->pkt->err_cb.data = (void *)handle;
CMDQ_MSG("%s handle:0x%p pkt:0x%p size:%zu thread:%d\n",
__func__, handle, handle->pkt, handle->pkt->cmd_buf_size,
handle->thread);
handle->trigger = sched_clock();
ctx = cmdq_core_get_context();
/* protect qos and communite with mbox */
mutex_lock(&ctx->thread[(u32)handle->thread].thread_mutex);
/* TODO: remove pmqos in seure path */
/* PMQoS */
CMDQ_SYSTRACE_BEGIN("%s_pmqos\n", __func__);
mutex_lock(&cmdq_thread_mutex);
handle_count = ctx->thread[(u32)handle->thread].handle_count;
pmqos_handle_list = kcalloc(handle_count + 1,
sizeof(*pmqos_handle_list), GFP_KERNEL);
if (pmqos_handle_list) {
if (handle_count)
cmdq_core_get_pmqos_handle_list(handle,
pmqos_handle_list, handle_count);
pmqos_handle_list[handle_count] = handle;
}
cmdq_core_group_begin_task(handle, pmqos_handle_list,
handle_count + 1);
kfree(pmqos_handle_list);
ctx->thread[(u32)handle->thread].handle_count++;
mutex_unlock(&cmdq_thread_mutex);
CMDQ_SYSTRACE_END();
CMDQ_SYSTRACE_BEGIN("%s\n", __func__);
cmdq_core_replace_v3_instr(handle, handle->thread);
if (handle->pkt->cl != client) {
CMDQ_LOG("[warn]client not match before flush:0x%p and 0x%p\n",
handle->pkt->cl, client);
handle->pkt->cl = client;
}
wait_q = &cmdq_wait_queue[(u32)handle->thread];
thread = handle->thread;
err = cmdq_pkt_flush_async(handle->pkt, cmdq_pkt_flush_handler,
(void *)handle);
wake_up(wait_q);
CMDQ_SYSTRACE_END();
mutex_unlock(&ctx->thread[(u32)thread].thread_mutex);
if (err < 0) {
CMDQ_ERR("pkt flush failed err:%d handle:0x%p thread:%d\n",
err, handle, thread);
return err;
}
return 0;
}
s32 cmdq_pkt_flush_ex(struct cmdqRecStruct *handle)
{
s32 err;
err = cmdq_pkt_flush_async_ex_impl(handle, NULL, 0);
if (err < 0) {
CMDQ_ERR("handle:0x%p start flush failed err:%d\n",
handle, err);
return err;
}
err = cmdq_pkt_wait_flush_ex_result(handle);
if (err < 0)
CMDQ_ERR("handle:%p wait flush failed err:%d\n", handle, err);
CMDQ_MSG("%s done handle:0x%p\n", __func__, handle);
return err;
}
s32 cmdq_pkt_flush_async_ex(struct cmdqRecStruct *handle,
CmdqAsyncFlushCB cb, u64 user_data, bool auto_release)
{
s32 err;
int32_t thread;
/* mark self as running to notify client */
if (handle->pkt->loop)
handle->running_task = (void *)handle;
CMDQ_SYSTRACE_BEGIN("%s\n", __func__);
thread = handle->thread;
err = cmdq_pkt_flush_async_ex_impl(handle, cb, user_data);
CMDQ_SYSTRACE_END();
if (err < 0) {
if (thread == CMDQ_INVALID_THREAD || err == -EBUSY)
return err;
/* client may already wait for flush done, trigger as error */
wake_up(&cmdq_wait_queue[(u32)thread]);
return err;
}
if (auto_release) {
err = cmdq_pkt_auto_release_task(handle, false);
if (err < 0) {
CMDQ_ERR("wait flush failed err:%d\n", err);
return err;
}
}
CMDQ_MSG("%s done handle:0x%p\n", __func__, handle);
return 0;
}
s32 cmdq_pkt_stop(struct cmdqRecStruct *handle)
{
struct cmdq_client *client = NULL;
CMDQ_MSG("%s handle:0x%p state:%d thread:%d\n",
__func__, handle, handle->state, handle->thread);
if (handle->thread == CMDQ_INVALID_THREAD) {
CMDQ_ERR("invalid thread to stop pkt handle:0x%p pkt:0x%p\n",
handle, handle->pkt);
return -EINVAL;
}
client = cmdq_clients[(u32)handle->thread];
/* TODO: need way to prevent user destroy handle in callback,
* but before we handle all things, since after callback we still
* hold handle and do lots of work
*/
#if 0
if (handle->pkt->loop && handle->state != TASK_STATE_IDLE &&
atomic_read(&handle->exec) > 0) {
CMDQ_MSG("%s release running handle:0x%p pkt:0x%p\n",
__func__, handle, handle->pkt);
err = cmdq_pkt_auto_release_task(handle);
if (err < 0) {
CMDQ_ERR("add loop to auto release err:%d\n", err);
cmdq_pkt_release_handle(handle);
return err;
}
/* make thread stop */
cmdq_mbox_stop(client);
/* wake again in case thread stops before */
wake_up(&cmdq_wait_queue[(u32)handle->thread]);
} else {
/* stop directly and other thread shoudl clean up */
cmdq_mbox_stop(client);
}
#else
cmdq_mbox_stop(client);
if (handle->pkt->loop && handle->state != TASK_STATE_IDLE &&
atomic_read(&handle->exec) > 0) {
cmdq_pkt_release_handle(handle);
} else {
CMDQ_ERR(
"still available after stop handle:0x%p loop:%s 0x%p state:%u exec:%d\n",
handle, handle->pkt->loop ? "true" : "false",
handle->running_task, handle->state,
atomic_read(&handle->exec));
}
handle->running_task = NULL;
#endif
CMDQ_MSG("%s done handle:0x%p\n", __func__, handle);
return 0;
}
void cmdq_core_dump_active(void)
{
u64 cost;
u32 idx = 0;
struct cmdqRecStruct *task;
mutex_lock(&cmdq_handle_list_mutex);
list_for_each_entry(task, &cmdq_ctx.handle_active, list_entry) {
if (idx >= 3)
break;
cost = div_u64(sched_clock() - task->submit, 1000);
if (cost <= 800000)
break;
CMDQ_LOG(
"[warn] waiting task %u cost time:%lluus submit:%llu enging:%#llx thd:%d caller:%llu-%s sec:%s handle:%p\n",
idx, cost, task->submit, task->engineFlag,
task->thread,
(u64)task->caller_pid, task->caller_name,
task->secData.is_secure ? "true" : "false",
task);
idx++;
}
mutex_unlock(&cmdq_handle_list_mutex);
}
/* mailbox helper functions */
s32 cmdq_helper_mbox_register(struct device *dev)
{
u32 i;
s32 chan_id;
struct cmdq_client *clt;
int thread_cnt;
thread_cnt = of_count_phandle_with_args(
dev->of_node, "mboxes", "#mbox-cells");
CMDQ_LOG("thread count:%d\n", thread_cnt);
if (thread_cnt <= 0)
thread_cnt = CMDQ_MAX_THREAD_COUNT;
/* for display we start from thread 0 */
for (i = 0; i < thread_cnt; i++) {
clt = cmdq_mbox_create(dev, i);
if (!clt || IS_ERR(clt)) {
CMDQ_MSG("register mbox stop:0x%p idx:%u\n", clt, i);
continue;
}
chan_id = cmdq_mbox_chan_id(clt->chan);
if (chan_id < 0 || cmdq_clients[chan_id]) {
CMDQ_ERR("channel and client duplicate:%d\n", chan_id);
cmdq_mbox_destroy(clt);
continue;
}
cmdq_clients[chan_id] = clt;
CMDQ_LOG("chan %d 0x%px dev:0x%px\n",
chan_id, cmdq_clients[chan_id]->chan, dev);
if (!cmdq_entry && chan_id >= CMDQ_DYNAMIC_THREAD_ID_START)
cmdq_entry = clt;
}
cmdq_client_base = cmdq_register_device(dev);
/* for mm like mdp set large pool count */
for (i = CMDQ_DYNAMIC_THREAD_ID_START;
i < CMDQ_DYNAMIC_THREAD_ID_START + 3; i++) {
if (!cmdq_clients[i])
continue;
cmdq_mbox_pool_set_limit(cmdq_clients[i], CMDQ_DMA_POOL_COUNT);
}
return 0;
}
struct cmdq_client *cmdq_helper_mbox_client(u32 idx)
{
if (idx >= ARRAY_SIZE(cmdq_clients))
return NULL;
return cmdq_clients[idx];
}
struct cmdq_base *cmdq_helper_mbox_base(void)
{
return cmdq_client_base;
}
void cmdq_helper_mbox_clear_pools(void)
{
u32 i;
for (i = 0; i < CMDQ_MAX_THREAD_COUNT; i++) {
if (!cmdq_clients[i])
continue;
cmdq_mbox_pool_clear(cmdq_clients[i]);
}
}
void cmdq_core_initialize(void)
{
const u32 max_thread_count = cmdq_dev_get_thread_count();
u32 index;
u32 thread_id;
char long_msg[CMDQ_LONGSTRING_MAX];
u32 msg_offset;
s32 msg_max_size;
cmdq_helper_mbox_register(cmdq_dev_get());
atomic_set(&cmdq_thread_usage, 0);
cmdq_wait_queue = kcalloc(max_thread_count, sizeof(*cmdq_wait_queue),
GFP_KERNEL);
for (index = 0; index < max_thread_count; index++)
init_waitqueue_head(&cmdq_wait_queue[index]);
/* Reset overall context */
memset(&cmdq_ctx, 0x0, sizeof(cmdq_ctx));
cmdq_ctx.aee = true;
/* mark available threads */
for (index = 0; index < CMDQ_MAX_SCENARIO_COUNT; index++) {
/* mark static thread dispatch thread as used */
thread_id = cmdq_core_get_thread_id(index);
if (thread_id != CMDQ_INVALID_THREAD)
cmdq_ctx.thread[thread_id].used = true;
}
for (index = 0; index < ARRAY_SIZE(cmdq_clients); index++)
if (!cmdq_clients[index])
cmdq_ctx.thread[index].used = true;
#if defined(CONFIG_MTK_SEC_VIDEO_PATH_SUPPORT) || \
defined(CONFIG_MTK_CAM_SECURITY_SUPPORT)
/* for secure path reserve irq notify thread */
cmdq_ctx.thread[CMDQ_SEC_IRQ_THREAD].used = true;
#endif
for (index = 0; index < ARRAY_SIZE(cmdq_ctx.thread); index++)
mutex_init(&cmdq_ctx.thread[index].thread_mutex);
cmdq_long_string_init(false, long_msg, &msg_offset, &msg_max_size);
for (index = 0; index < max_thread_count; index++) {
if (!cmdq_ctx.thread[index].used)
cmdq_long_string(long_msg, &msg_offset, &msg_max_size,
"%d, ", index);
}
CMDQ_LOG("available thread pool:%s max:%u\n",
long_msg, max_thread_count);
/* Initialize task lists */
INIT_LIST_HEAD(&cmdq_ctx.handle_active);
/* Initialize writable address */
INIT_LIST_HEAD(&cmdq_ctx.writeAddrList);
/* Initialize work queue */
cmdq_core_init_thread_work_queue();
/* Initialize command buffer dump */
memset(&cmdq_command_dump, 0x0, sizeof(cmdq_command_dump));
#if 0
cmdqCoreRegisterDebugRegDumpCB(testcase_regdump_begin,
testcase_regdump_end);
#endif
/* Initialize MET for statistics */
/* note that we don't need to uninit it. */
CMDQ_PROF_INIT();
#if IS_ENABLED(CONFIG_MMPROFILE)
mdp_mmp_init();
#endif
#if 0
/* Initialize test case structure */
cmdq_test_init_setting();
#endif
/* Initialize enableProfile disable */
cmdq_ctx.enableProfile = CMDQ_PROFILE_OFF;
mdp_rb_pool = dma_pool_create("mdp_rb", cmdq_dev_get(),
CMDQ_BUF_ALLOC_SIZE, 0, 0);
atomic_set(&mdp_rb_pool_cnt, 0);
mdp_wake_lock = wakeup_source_register(NULL, "mdp_wake_lock");
}
#ifdef CMDQ_DAPC_DEBUG
static struct devapc_vio_callbacks devapc_vio_handle = {
.id = INFRA_SUBSYS_GCE,
.debug_dump = cmdq_core_handle_devapc_vio,
};
#endif
static int __init cmdq_core_late_init(void)
{
CMDQ_LOG("CMDQ driver late init begin\n");
#ifdef CMDQ_DAPC_DEBUG
register_devapc_vio_callback(&devapc_vio_handle);
#endif
CMDQ_MSG("CMDQ driver late init end\n");
return 0;
}
void cmdq_core_deinitialize(void)
{
cmdq_core_destroy_thread_work_queue();
/* TODO: destroy all task in mailbox controller */
#if 0
/* release all tasks in both list */
for (index = 0; index < ARRAY_SIZE(lists); ++index) {
list_for_each(p, lists[index]) {
CMDQ_PROF_MUTEX_LOCK(gCmdqTaskMutex, deinitialize);
pTask = list_entry(p, struct TaskStruct, listEntry);
/* free allocated DMA buffer */
cmdq_task_free_task_command_buffer(pTask);
kmem_cache_free(cmdq_ctx.taskCache, pTask);
list_del(p);
CMDQ_PROF_MUTEX_UNLOCK(gCmdqTaskMutex, deinitialize);
}
}
/* check if there are dangling write addresses. */
if (!list_empty(&cmdq_ctx.writeAddrList)) {
/* there are unreleased write buffer, raise AEE */
CMDQ_AEE("CMDQ", "there are unreleased write buffer");
}
kmem_cache_destroy(cmdq_ctx.taskCache);
cmdq_ctx.taskCache = NULL;
#endif
kfree(cmdq_wait_queue);
cmdq_wait_queue = NULL;
kfree(cmdq_ctx.inst_check_buffer);
cmdq_ctx.inst_check_buffer = NULL;
cmdq_helper_mbox_clear_pools();
}
late_initcall(cmdq_core_late_init);