[PATCH v8 2/3] CMDQ: Mediatek CMDQ driver

Matthias Brugger matthias.bgg at gmail.com
Tue May 31 13:04:16 PDT 2016



On 31/05/16 10:36, Horng-Shyang Liao wrote:
> Hi Mathias,
>
> Please see my inline reply.
>
> On Mon, 2016-05-30 at 17:31 +0200, Matthias Brugger wrote:
>>
>> On 30/05/16 05:19, HS Liao wrote:
>>> This patch is first version of Mediatek Command Queue(CMDQ) driver. The
>>> CMDQ is used to help read/write registers with critical time limitation,
>>> such as updating display configuration during the vblank. It controls
>>> Global Command Engine (GCE) hardware to achieve this requirement.
>>> Currently, CMDQ only supports display related hardwares, but we expect
>>> it can be extended to other hardwares for future requirements.
>>>
>>> Signed-off-by: HS Liao <hs.liao at mediatek.com>
>>> Signed-off-by: CK Hu <ck.hu at mediatek.com>
>>> ---
>>>    drivers/soc/mediatek/Kconfig    |  10 +
>>>    drivers/soc/mediatek/Makefile   |   1 +
>>>    drivers/soc/mediatek/mtk-cmdq.c | 943 ++++++++++++++++++++++++++++++++++++++++
>>>    include/soc/mediatek/cmdq.h     | 197 +++++++++
>>>    4 files changed, 1151 insertions(+)
>>>    create mode 100644 drivers/soc/mediatek/mtk-cmdq.c
>>>    create mode 100644 include/soc/mediatek/cmdq.h
>>>
>>> diff --git a/drivers/soc/mediatek/Kconfig b/drivers/soc/mediatek/Kconfig
>>> index 0a4ea80..c4ad75c 100644
>>> --- a/drivers/soc/mediatek/Kconfig
>>> +++ b/drivers/soc/mediatek/Kconfig
>>> @@ -1,6 +1,16 @@
>>>    #
>>>    # MediaTek SoC drivers
>>>    #
>>> +config MTK_CMDQ
>>> +	bool "MediaTek CMDQ Support"
>>> +	depends on ARCH_MEDIATEK || COMPILE_TEST

depends on ARM64 ?

>>> +	select MTK_INFRACFG
>>> +	help
>>> +	  Say yes here to add support for the MediaTek Command Queue (CMDQ)
>>> +	  driver. The CMDQ is used to help read/write registers with critical
>>> +	  time limitation, such as updating display configuration during the
>>> +	  vblank.
>>> +
>>>    config MTK_INFRACFG
>>>    	bool "MediaTek INFRACFG Support"
>>>    	depends on ARCH_MEDIATEK || COMPILE_TEST
>>> diff --git a/drivers/soc/mediatek/Makefile b/drivers/soc/mediatek/Makefile
>>> index 12998b0..f7397ef 100644
>>> --- a/drivers/soc/mediatek/Makefile
>>> +++ b/drivers/soc/mediatek/Makefile
>>> @@ -1,3 +1,4 @@
>>> +obj-$(CONFIG_MTK_CMDQ) += mtk-cmdq.o
>>>    obj-$(CONFIG_MTK_INFRACFG) += mtk-infracfg.o
>>>    obj-$(CONFIG_MTK_PMIC_WRAP) += mtk-pmic-wrap.o
>>>    obj-$(CONFIG_MTK_SCPSYS) += mtk-scpsys.o
>>> diff --git a/drivers/soc/mediatek/mtk-cmdq.c b/drivers/soc/mediatek/mtk-cmdq.c
>>> new file mode 100644
>>> index 0000000..e9d6e1c
>>> --- /dev/null
>>> +++ b/drivers/soc/mediatek/mtk-cmdq.c
>>> @@ -0,0 +1,943 @@
>>> +/*
>>> + * Copyright (c) 2015 MediaTek Inc.
>>> + *
>>> + * This program is free software; you can redistribute it and/or modify
>>> + * it under the terms of the GNU General Public License version 2 as
>>> + * published by the Free Software Foundation.
>>> + *
>>> + * This program is distributed in the hope that it will be useful,
>>> + * but WITHOUT ANY WARRANTY; without even the implied warranty of
>>> + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
>>> + * GNU General Public License for more details.
>>> + */
>>> +
>>> +#include <linux/clk.h>
>>> +#include <linux/clk-provider.h>
>>> +#include <linux/completion.h>
>>> +#include <linux/dma-mapping.h>
>>> +#include <linux/errno.h>
>>> +#include <linux/interrupt.h>
>>> +#include <linux/iopoll.h>
>>> +#include <linux/kernel.h>
>>> +#include <linux/kthread.h>
>>> +#include <linux/module.h>
>>> +#include <linux/mutex.h>
>>> +#include <linux/of_address.h>
>>> +#include <linux/of_irq.h>
>>> +#include <linux/platform_device.h>
>>> +#include <linux/slab.h>
>>> +#include <linux/spinlock.h>
>>> +#include <linux/suspend.h>
>>> +#include <linux/workqueue.h>
>>> +#include <soc/mediatek/cmdq.h>
>>> +
>>> +#define CMDQ_INITIAL_CMD_BLOCK_SIZE	PAGE_SIZE
>>> +#define CMDQ_INST_SIZE			8 /* instruction is 64-bit */
>>> +#define CMDQ_TIMEOUT_MS			1000
>>> +#define CMDQ_IRQ_MASK			0xffff
>>> +#define CMDQ_DRIVER_DEVICE_NAME		"mtk_cmdq"
>>> +#define CMDQ_CLK_NAME			"gce"
>>
>> We can put the names in directly to un-bloat the defines.
>
> I will use the names directly and remove defines.
>
>>> +
>>> +#define CMDQ_CURR_IRQ_STATUS		0x010
>>> +#define CMDQ_CURR_LOADED_THR		0x018
>>> +#define CMDQ_THR_SLOT_CYCLES		0x030
>>> +
>>> +#define CMDQ_THR_BASE			0x100
>>> +#define CMDQ_THR_SHIFT			0x080
>>
>> Wouldn't be CMDQ_THR_SIZE more accurate?
>
> Will rename it.
>
>>> +#define CMDQ_THR_WARM_RESET		0x00
>>> +#define CMDQ_THR_ENABLE_TASK		0x04
>>> +#define CMDQ_THR_SUSPEND_TASK		0x08
>>> +#define CMDQ_THR_CURR_STATUS		0x0c
>>> +#define CMDQ_THR_IRQ_STATUS		0x10
>>> +#define CMDQ_THR_IRQ_ENABLE		0x14
>>> +#define CMDQ_THR_CURR_ADDR		0x20
>>> +#define CMDQ_THR_END_ADDR		0x24
>>> +#define CMDQ_THR_CFG			0x40
>>> +
>>> +#define CMDQ_THR_ENABLED		0x1
>>> +#define CMDQ_THR_DISABLED		0x0
>>> +#define CMDQ_THR_SUSPEND		0x1
>>> +#define CMDQ_THR_RESUME			0x0
>>> +#define CMDQ_THR_STATUS_SUSPENDED	BIT(1)
>>> +#define CMDQ_THR_DO_WARM_RESET		BIT(0)
>>> +#define CMDQ_THR_ACTIVE_SLOT_CYCLES	0x3200
>>> +#define CMDQ_THR_PRIORITY		3
>>> +#define CMDQ_THR_IRQ_DONE		0x1
>>> +#define CMDQ_THR_IRQ_ERROR		0x12
>>> +#define CMDQ_THR_IRQ_EN			0x13 /* done + error */
>>
>> #define CMDQ_THR_IRQ_EN (CMDQ_THR_IRQ_ERROR | CMDQ_THR_IRQ_DONE)
>
> Will do.
>
>>> +#define CMDQ_THR_IRQ_MASK		0x13
>>
>> never used.
>
> Will remove.
>
>>> +#define CMDQ_THR_EXECUTING		BIT(31)
>>> +
>>> +#define CMDQ_ARG_A_WRITE_MASK		0xffff
>>> +#define CMDQ_SUBSYS_MASK		0x1f
>>> +#define CMDQ_OP_CODE_MASK		0xff000000
>>> +
>>> +#define CMDQ_OP_CODE_SHIFT		24
>>
>> Couldn't we connect the mask with the shift, or aren't they related?
>>
>> #define CMDQ_OP_CODE_MASK (0xff << CMDQ_OP_CODE_SHIFT)
>
> Will do.
>
>>> +#define CMDQ_SUBSYS_SHIFT		16
>>> +
>>> +#define CMDQ_WRITE_ENABLE_MASK		BIT(0)
>>> +#define CMDQ_JUMP_BY_OFFSET		0x10000000
>>> +#define CMDQ_JUMP_BY_PA			0x10000001
>>> +#define CMDQ_JUMP_PASS			CMDQ_INST_SIZE
>>> +#define CMDQ_WFE_UPDATE			BIT(31)
>>> +#define CMDQ_WFE_WAIT			BIT(15)
>>> +#define CMDQ_WFE_WAIT_VALUE		0x1
>>> +#define CMDQ_EOC_IRQ_EN			BIT(0)
>>> +
>>> +enum cmdq_thread_index {
>>> +	CMDQ_THR_DISP_MAIN_IDX,	/* main */
>>> +	CMDQ_THR_DISP_SUB_IDX,	/* sub */
>>> +	CMDQ_THR_DISP_MISC_IDX,	/* misc */
>>> +	CMDQ_THR_MAX_COUNT,	/* max */
>>> +};
>>> +
>>> +/*
>>> + * CMDQ_CODE_MOVE:
>>> + *   move value into internal register as mask
>>> + *   format: op mask
>>> + * CMDQ_CODE_WRITE:
>>> + *   write value into target register
>>> + *   format: op subsys address value
>>> + * CMDQ_CODE_JUMP:
>>> + *   jump by offset
>>> + *   format: op offset
>>> + * CMDQ_CODE_WFE:
>>> + *   wait for event and clear
>>> + *   it is just clear if no wait
>>> + *   format: [wait]  op event update:1 to_wait:1 wait:1
>>> + *           [clear] op event update:1 to_wait:0 wait:0
>>> + * CMDQ_CODE_EOC:
>>> + *   end of command
>>> + *   format: op irq_flag
>>> + */
>>
>> I think we need more documentation of how this command queue engine is
>> working. If not, I think it will be really complicated to understand how
>> to use this.
>>
>>> +enum cmdq_code {
>>> +	CMDQ_CODE_MOVE = 0x02,
>>> +	CMDQ_CODE_WRITE = 0x04,
>>> +	CMDQ_CODE_JUMP = 0x10,
>>> +	CMDQ_CODE_WFE = 0x20,
>>> +	CMDQ_CODE_EOC = 0x40,
>>> +};
>>> +
>>> +enum cmdq_task_state {
>>> +	TASK_STATE_BUSY, /* running on a GCE thread */
>>> +	TASK_STATE_ERROR,
>>> +	TASK_STATE_DONE,
>>> +};
>>> +
>>> +struct cmdq_task_cb {
>>> +	cmdq_async_flush_cb	cb;
>>> +	void			*data;
>>> +};
>>> +
>>> +struct cmdq_thread {
>>> +	void __iomem		*base;
>>> +	struct list_head	task_busy_list;
>>> +	wait_queue_head_t	wait_task_done;
>>> +};
>>> +
>>> +struct cmdq_task {
>>> +	struct cmdq		*cmdq;
>>> +	struct list_head	list_entry;
>>> +	enum cmdq_task_state	task_state;
>>> +	void			*va_base;
>>> +	dma_addr_t		pa_base;
>>> +	u64			engine_flag;
>>> +	size_t			command_size;
>>> +	u32			num_cmd;
>>
>> num_cmd is directly connected to command_size. I prefer to just keep
>> num_cmd and calculate the command_size where necessary.
>
> After I trace code, I prefer to keep command_size and calculate num_cmd
> where necessary. What do you think?
>

I suppose you prefer this, as you are writing to the GCE depending on 
the command_size. I think it is worth to create a macro for the 
calculation of the number of commands, to make the code more readable.
Would be nice if you would just pass cmdq_task to it and it would return 
the number. Just as an idea.

>>> +	struct cmdq_thread	*thread;
>>> +	struct cmdq_task_cb	cb;
>>> +	struct work_struct	release_work;
>>> +};
>>> +
>>> +struct cmdq {
>>> +	struct device		*dev;
>>> +	void __iomem		*base;
>>> +	u32			irq;
>>> +	struct workqueue_struct	*task_release_wq;
>>> +	struct cmdq_thread	thread[CMDQ_THR_MAX_COUNT];
>>> +	struct mutex		task_mutex;	/* for task */
>>> +	spinlock_t		exec_lock;	/* for exec */
>>> +	struct clk		*clock;
>>> +	bool			suspended;
>>> +};
>>> +
>>> +struct cmdq_subsys {
>>> +	u32	base;
>>> +	int	id;
>>> +};
>>> +
>>> +static const struct cmdq_subsys gce_subsys[] = {
>>> +	{0x1400, 1},
>>> +	{0x1401, 2},
>>> +	{0x1402, 3},
>>> +};
>>> +
>>> +static int cmdq_subsys_base_to_id(u32 base)
>>> +{
>>> +	int i;
>>> +
>>> +	for (i = 0; i < ARRAY_SIZE(gce_subsys); i++)
>>> +		if (gce_subsys[i].base == base)
>>> +			return gce_subsys[i].id;
>>> +	return -EFAULT;
>>> +}
>>> +
>>> +static int cmdq_eng_get_thread(u64 flag)
>>> +{
>>> +	if (flag & BIT_ULL(CMDQ_ENG_DISP_DSI0))
>>> +		return CMDQ_THR_DISP_MAIN_IDX;
>>> +	else if (flag & BIT_ULL(CMDQ_ENG_DISP_DPI0))
>>> +		return CMDQ_THR_DISP_SUB_IDX;
>>> +	else
>>> +		return CMDQ_THR_DISP_MISC_IDX;
>>> +}
>>> +
>>> +static void cmdq_task_release(struct cmdq_task *task)
>>> +{
>>> +	struct cmdq *cmdq = task->cmdq;
>>> +
>>> +	dma_free_coherent(cmdq->dev, task->command_size, task->va_base,
>>> +			  task->pa_base);
>>> +	kfree(task);
>>> +}
>>> +
>>> +static struct cmdq_task *cmdq_task_acquire(struct cmdq_rec *rec,
>>> +					   struct cmdq_task_cb cb)
>>> +{
>>> +	struct cmdq *cmdq = rec->cmdq;
>>> +	struct device *dev = cmdq->dev;
>>> +	struct cmdq_task *task;
>>> +
>>> +	task = kzalloc(sizeof(*task), GFP_KERNEL);
>>> +	INIT_LIST_HEAD(&task->list_entry);
>>> +	task->va_base = dma_alloc_coherent(dev, rec->command_size,
>>> +					   &task->pa_base, GFP_KERNEL);
>>> +	if (!task->va_base) {
>>> +		dev_err(dev, "allocate command buffer failed\n");
>>> +		kfree(task);
>>> +		return NULL;
>>> +	}
>>> +
>>> +	task->cmdq = cmdq;
>>> +	task->command_size = rec->command_size;
>>> +	task->engine_flag = rec->engine_flag;
>>> +	task->task_state = TASK_STATE_BUSY;
>>> +	task->cb = cb;
>>> +	memcpy(task->va_base, rec->buf, rec->command_size);
>>> +	task->num_cmd = task->command_size / CMDQ_INST_SIZE;
>>> +	return task;
>>> +}
>>> +
>>> +static void cmdq_thread_writel(struct cmdq_thread *thread, u32 value,
>>> +			       u32 offset)
>>> +{
>>> +	writel(value, thread->base + offset);
>>> +}
>>> +
>>> +static u32 cmdq_thread_readl(struct cmdq_thread *thread, u32 offset)
>>> +{
>>> +	return readl(thread->base + offset);
>>> +}
>>
>> We can get rid of cmdq_thread_readl/writel.
>
> Will do.
>
>>> +
>>> +static int cmdq_thread_suspend(struct cmdq *cmdq, struct cmdq_thread *thread)
>>> +{
>>> +	u32 status;
>>> +
>>> +	cmdq_thread_writel(thread, CMDQ_THR_SUSPEND, CMDQ_THR_SUSPEND_TASK);
>>> +
>>> +	/* If already disabled, treat as suspended successful. */
>>> +	if (!(cmdq_thread_readl(thread, CMDQ_THR_ENABLE_TASK) &
>>> +	      CMDQ_THR_ENABLED))
>>> +		return 0;
>>> +
>>> +	if (readl_poll_timeout_atomic(thread->base + CMDQ_THR_CURR_STATUS,
>>> +			status, status & CMDQ_THR_STATUS_SUSPENDED, 0, 10)) {
>>> +		dev_err(cmdq->dev, "suspend GCE thread 0x%x failed\n",
>>> +			(u32)(thread->base - cmdq->base));
>>> +		return -EFAULT;
>>> +	}
>>> +
>>> +	return 0;
>>> +}
>>> +
>>> +static void cmdq_thread_resume(struct cmdq_thread *thread)
>>> +{
>>> +	cmdq_thread_writel(thread, CMDQ_THR_RESUME, CMDQ_THR_SUSPEND_TASK);
>>> +}
>>> +
>>> +static int cmdq_thread_reset(struct cmdq *cmdq, struct cmdq_thread *thread)
>>> +{
>>> +	u32 warm_reset;
>>> +
>>> +	cmdq_thread_writel(thread, CMDQ_THR_DO_WARM_RESET, CMDQ_THR_WARM_RESET);
>>> +	if (readl_poll_timeout_atomic(thread->base + CMDQ_THR_WARM_RESET,
>>> +			warm_reset, !(warm_reset & CMDQ_THR_DO_WARM_RESET),
>>> +			0, 10)) {
>>> +		dev_err(cmdq->dev, "reset GCE thread 0x%x failed\n",
>>> +			(u32)(thread->base - cmdq->base));
>>> +		return -EFAULT;
>>> +	}
>>> +	writel(CMDQ_THR_ACTIVE_SLOT_CYCLES, cmdq->base + CMDQ_THR_SLOT_CYCLES);
>>> +	return 0;
>>> +}
>>> +
>>> +static void cmdq_thread_disable(struct cmdq *cmdq, struct cmdq_thread *thread)
>>> +{
>>> +	cmdq_thread_reset(cmdq, thread);
>>> +	cmdq_thread_writel(thread, CMDQ_THR_DISABLED, CMDQ_THR_ENABLE_TASK);
>>> +}
>>> +
>>> +/* notify GCE to re-fetch commands by setting GCE thread PC */
>>> +static void cmdq_thread_invalidate_fetched_data(struct cmdq_thread *thread)
>>> +{
>>> +	cmdq_thread_writel(thread,
>>> +			   cmdq_thread_readl(thread, CMDQ_THR_CURR_ADDR),
>>> +			   CMDQ_THR_CURR_ADDR);
>>> +}
>>> +
>>> +static void cmdq_task_insert_into_thread(struct cmdq_task *task)
>>> +{
>>> +	struct cmdq_thread *thread = task->thread;
>>> +	struct cmdq_task *prev_task = list_last_entry(
>>> +			&thread->task_busy_list, typeof(*task), list_entry);
>>> +	u64 *prev_task_base = prev_task->va_base;
>>> +
>>> +	/* let previous task jump to this task */
>>> +	prev_task_base[prev_task->num_cmd - 1] = (u64)CMDQ_JUMP_BY_PA << 32 |
>>> +						 task->pa_base;
>>> +
>>> +	cmdq_thread_invalidate_fetched_data(thread);
>>> +}
>>> +
>>> +/* we assume tasks in the same display GCE thread are waiting the same event. */
>>> +static void cmdq_task_remove_wfe(struct cmdq_task *task)
>>> +{
>>> +	u32 wfe_option = CMDQ_WFE_UPDATE | CMDQ_WFE_WAIT | CMDQ_WFE_WAIT_VALUE;
>>> +	u32 wfe_op = CMDQ_CODE_WFE << CMDQ_OP_CODE_SHIFT;
>>> +	u32 *base = task->va_base;
>>> +	u32 num_cmd = task->num_cmd << 1;
>>> +	int i;
>>> +
>>> +	for (i = 0; i < num_cmd; i += 2)
>>> +		if (base[i] == wfe_option &&
>>> +		    (base[i + 1] & CMDQ_OP_CODE_MASK) == wfe_op) {
>>> +			base[i] = CMDQ_JUMP_PASS;
>>> +			base[i + 1] = CMDQ_JUMP_BY_OFFSET;
>>> +		}
>>
>> After using the command buffer as a void pointer a u64 pointer, we now
>> reference to it as u32. I would prefer to explain here, how the command
>> looks like we are searching for and use a for loop passing task->num_cmd
>> instead.
>
> Will use u64* to rewrite the above code.
>
>>> +}
>>> +
>>> +static void cmdq_task_exec(struct cmdq_task *task, struct cmdq_thread *thread)
>>> +{
>>> +	struct cmdq *cmdq = task->cmdq;
>>> +	unsigned long flags;
>>> +	unsigned long curr_pa, end_pa;
>>> +
>>> +	WARN_ON(clk_prepare_enable(cmdq->clock) < 0);
>>> +	spin_lock_irqsave(&cmdq->exec_lock, flags);
>>
>> cmdq_task_exec is called with cmdq->task_mutex held, so why do we need
>> the spin_lock here? Can't we just use one of the two?
>
> We can drop task_mutex, but we will get some side effects.
> 1. exec_lock needs to include more code, but I think it is not good for
>     spinlock.
> 2. In cmdq_rec_flush_async(), task_mutex needs to protect
>     (1) cmdq->suspended, (2) cmdq_task_exec(), and
>     (3) cmdq_task_wait_release_schedule().
>     If we drop task_mutex, we have to put cmdq->suspended if condition
>     just before cmdq_task_exec() and inside exec_lock, and we have to
>     release task and its command buffer if error. This will let flow
>     become more complex and enlarge code size.
>
> What do you think?

Why do you need to protect cmdq_task_wait_release_schedule? We don't 
care about the order of the workqueue elements, do we?

As far as I understand you would need to protect cmdq_task_acquire as 
well, to "ensure" continously growing pa_base. More on that below.

>
>>> +	task->thread = thread;
>>> +	task->task_state = TASK_STATE_BUSY;
>>
>> That was already set in cmdq_task_acquire, why do we need to set it here
>> again?
>
> Will drop it.
>

Yeah, but I think it makes more sense to drop it in cmdq_task_acquire 
instead.

>>> +	if (list_empty(&thread->task_busy_list)) {
>>> +		WARN_ON(cmdq_thread_reset(cmdq, thread) < 0);
>>> +
>>> +		cmdq_thread_writel(thread, task->pa_base, CMDQ_THR_CURR_ADDR);
>>> +		cmdq_thread_writel(thread, task->pa_base + task->command_size,
>>> +				   CMDQ_THR_END_ADDR);
>>> +		cmdq_thread_writel(thread, CMDQ_THR_PRIORITY, CMDQ_THR_CFG);
>>> +		cmdq_thread_writel(thread, CMDQ_THR_IRQ_EN,
>>> +				   CMDQ_THR_IRQ_ENABLE);
>>> +
>>> +		cmdq_thread_writel(thread, CMDQ_THR_ENABLED,
>>> +				   CMDQ_THR_ENABLE_TASK);
>>> +	} else {
>>> +		WARN_ON(cmdq_thread_suspend(cmdq, thread) < 0);
>>> +
>>> +		/*
>>> +		 * check boundary condition
>>> +		 * PC = END - 8, EOC is executed
>>> +		 * PC = END, all CMDs are executed
>>> +		 */
>>> +		curr_pa = cmdq_thread_readl(thread, CMDQ_THR_CURR_ADDR);
>>> +		end_pa = cmdq_thread_readl(thread, CMDQ_THR_END_ADDR);
>>> +		if (curr_pa == end_pa - 8 || curr_pa == end_pa) {
>>
>> 8 refers to CMDQ_INST_SIZE, right?
>
> Yes, I will use CMDQ_INST_SIZE.
>
>>> +			/* set to this task directly */
>>> +			cmdq_thread_writel(thread, task->pa_base,
>>> +					   CMDQ_THR_CURR_ADDR);
>>> +		} else {
>>> +			cmdq_task_insert_into_thread(task);
>>> +
>>> +			if (thread == &cmdq->thread[CMDQ_THR_DISP_MAIN_IDX] ||
>>> +			    thread == &cmdq->thread[CMDQ_THR_DISP_SUB_IDX])
>>> +				cmdq_task_remove_wfe(task);
>>
>> We could do this check using the task->engine_flag, I suppose that's
>> easier to undestand then.
>
> Will use task->engine_flag.
>
>>> +
>>> +			smp_mb(); /* modify jump before enable thread */
>>> +		}
>>> +
>>> +		cmdq_thread_writel(thread, task->pa_base + task->command_size,
>>> +				   CMDQ_THR_END_ADDR);
>>> +		cmdq_thread_resume(thread);
>>> +	}
>>> +	list_move_tail(&task->list_entry, &thread->task_busy_list);
>>> +	spin_unlock_irqrestore(&cmdq->exec_lock, flags);
>>> +}
>>> +
>>> +static void cmdq_handle_error_done(struct cmdq *cmdq,
>>> +				   struct cmdq_thread *thread, u32 irq_flag)
>>> +{
>>> +	struct cmdq_task *task, *tmp, *curr_task = NULL;
>>> +	u32 curr_pa;
>>> +	struct cmdq_cb_data cmdq_cb_data;
>>> +	bool err;
>>> +
>>> +	if (irq_flag & CMDQ_THR_IRQ_ERROR)
>>> +		err = true;
>>> +	else if (irq_flag & CMDQ_THR_IRQ_DONE)
>>> +		err = false;
>>> +	else
>>> +		return;
>>> +
>>> +	curr_pa = cmdq_thread_readl(thread, CMDQ_THR_CURR_ADDR);
>>> +
>>> +	list_for_each_entry_safe(task, tmp, &thread->task_busy_list,
>>> +				 list_entry) {
>>> +		if (curr_pa >= task->pa_base &&
>>> +		    curr_pa < (task->pa_base + task->command_size))
>>
>> What are you checking here? It seems as if you make some implcit
>> assumptions about pa_base and the order of execution of commands in the
>> thread. Is it save to do so? Does dma_alloc_coherent give any guarantees
>> about dma_handle?
>
> 1. Check what is the current running task in this GCE thread.
> 2. Yes.
> 3. Yes, CMDQ doesn't use iommu, so physical address is continuous.
>

Yes, physical addresses might be continous, but AFAIK there is no 
guarantee that the dma_handle address is steadily growing, when calling 
dma_alloc_coherent. And if I understand the code correctly, you use this 
assumption to decide if the task picked from task_busy_list is currently 
executing. So I think this mecanism is not working.

In which cases does the HW thread raise an interrupt.
In case of error. When does CMDQ_THR_IRQ_DONE get raised?

>>> +			curr_task = task;
>>> +		if (task->cb.cb) {
>>> +			cmdq_cb_data.err = curr_task ? err : false;
>>> +			cmdq_cb_data.data = task->cb.data;
>>> +			task->cb.cb(cmdq_cb_data);
>>> +		}
>>> +		task->task_state = (curr_task && err) ? TASK_STATE_ERROR :
>>> +				TASK_STATE_DONE;
>>> +		list_del(&task->list_entry);
>>> +		if (curr_task)
>>> +			break;
>>> +	}
>>> +
>>> +	wake_up(&thread->wait_task_done);
>>> +}
>>> +
>>> +static void cmdq_thread_irq_handler(struct cmdq *cmdq, int tid)
>>> +{
>>> +	struct cmdq_thread *thread = &cmdq->thread[tid];
>>> +	unsigned long flags = 0L;
>>> +	u32 irq_flag;
>>> +
>>> +	spin_lock_irqsave(&cmdq->exec_lock, flags);
>>> +
>>> +	irq_flag = cmdq_thread_readl(thread, CMDQ_THR_IRQ_STATUS);
>>> +	cmdq_thread_writel(thread, ~irq_flag, CMDQ_THR_IRQ_STATUS);
>>> +
>>> +	/*
>>> +	 * Another CPU core could run "release task" right before we acquire
>>> +	 * the spin lock, and thus reset / disable this GCE thread, so we
>>> +	 * need to check the enable bit of this GCE thread.
>>> +	 */
>>> +	if (!(cmdq_thread_readl(thread, CMDQ_THR_ENABLE_TASK) &
>>> +	      CMDQ_THR_ENABLED))
>>> +		irq_flag = 0;
>>
>> cmdq_handle_error_done just retuns in this case. Programming this way
>> just makes things confusing. What about:
>>
>> if (cmdq_thread_readl(thread, CMDQ_THR_ENABLE_TASK) &
>> 	      CMDQ_THR_ENABLED)
>> 	cmdq_handle_error_done(cmdq, thread, irq_flag);
>> else
>> 		irq_flag = 0;
>>
>> spin_unlock_irqrestore(&cmdq->exec_lock, flags);
>
> We still need to clear irq_flag if GCE thread is disabled.
> So, I think we can just return here.
>
> 	if (!(cmdq_thread_readl(thread, CMDQ_THR_ENABLE_TASK) &
> 	      CMDQ_THR_ENABLED))
> 		return;
>
> What do you think?
>

No, you can't just return, you need to unlock the spinlock.
Anyway I would prefer it the other way round, as I put it in my last 
mail. Just delete the else branch, we don't need to set irq_flag to zero.

>>> +
>>> +	cmdq_handle_error_done(cmdq, thread, irq_flag);
>>> +	spin_unlock_irqrestore(&cmdq->exec_lock, flags);
>>> +}
>>> +
>>> +static irqreturn_t cmdq_irq_handler(int irq, void *dev)
>>> +{
>>> +	struct cmdq *cmdq = dev;
>>> +	u32 irq_status;
>>> +	int i;
>>> +
>>> +	irq_status = readl(cmdq->base + CMDQ_CURR_IRQ_STATUS);
>>> +	irq_status &= CMDQ_IRQ_MASK;
>>> +	irq_status ^= CMDQ_IRQ_MASK;
>>
>> irq_status can be much bigger then 3, which is the number of threads in
>> the system (CMDQ_THR_MAX_COUNT). So why we use this mask here isn't
>> clear to me.
>
> Our GCE hardware has 16 threads, but we only use 3 threads currently.
>

Ok, but please use bitops here.

>>> +
>>> +	if (!irq_status)
>>> +		return IRQ_NONE;
>>> +
>>> +	while (irq_status) {
>>> +		i = ffs(irq_status) - 1;
>>> +		irq_status &= ~BIT(i);
>>> +		cmdq_thread_irq_handler(cmdq, i);
>>> +	}
>>
>> Can you explain how the irq status register looks like, that would it
>> make much easier to understand what happens here.
>
> Bit 0 ~ 15 of irq status register represents GCE thread 0 ~ 15
> interrupt. 0 means asserting interrupt; 1 means no interrupt.
>

Thanks, that helped. :)

>>> +
>>> +	return IRQ_HANDLED;	
>>> +}
>>> +
>>> +static int cmdq_task_handle_error_result(struct cmdq_task *task)
>>
>> We never check the return values, why do we have them?
>
> Will drop return value.
>
>>> +{
>>> +	struct cmdq *cmdq = task->cmdq;
>>> +	struct device *dev = cmdq->dev;
>>> +	struct cmdq_thread *thread = task->thread;
>>> +	struct cmdq_task *next_task, *prev_task;
>>> +	u32 irq_flag;
>>> +
>>> +	/* suspend GCE thread to ensure consistency */
>>> +	WARN_ON(cmdq_thread_suspend(cmdq, thread) < 0);
>>> +
>>> +	/* ISR has handled this error task */
>>> +	if (task->task_state == TASK_STATE_ERROR) {
>>> +		next_task = list_first_entry_or_null(&thread->task_busy_list,
>>> +				struct cmdq_task, list_entry);
>>> +		if (next_task) /* move to next task */
>>> +			cmdq_thread_writel(thread, next_task->pa_base,
>>> +					   CMDQ_THR_CURR_ADDR);
>>
>> We have to do this, as we suppose that the thread did not reach the jump
>> instruction we put into it's command queue, right?
>
> Yes.
>

So this should then go into it's own function. In wait_release_work, 
something like this:

if(task->task_state == TASK_STATE_ERROR)
      cmdq_task_handle_error(task)

>>> +		cmdq_thread_resume(thread);
>>> +		return -ECANCELED;
>>> +	}
>>> +
>>
>> if task_state != ERROR and != DONE. This means that the timeout of
>> task_release_wq has timed out, right?
>
> Yes.
>
>>> +	/*
>>> +	 * Save next_task and prev_task in advance
>>> +	 * since cmdq_handle_error_done will remove list_entry.
>>> +	 */
>>> +	next_task = prev_task = NULL;
>>> +	if (task->list_entry.next != &thread->task_busy_list)
>>> +		next_task = list_next_entry(task, list_entry);
>>> +	if (task->list_entry.prev != &thread->task_busy_list)
>>> +		prev_task = list_prev_entry(task, list_entry);
>>> +
>>> +	/*
>>> +	 * Although IRQ is disabled, GCE continues to execute.
>>> +	 * It may have pending IRQ before GCE thread is suspended,
>>> +	 * so check this condition again.
>>> +	 */
>>
>> The first thing we did in this function was suspending the thread. Why
>> do we need this then?
>
> Because timeout is CPU timeout not GCE timeout, GCE could just finish
> this task before the GCE thread is suspended.
>

What are the reasons for a timeout? An error has happend, or the task is 
still executing.

>> To be honest this whole functions looks really like a design error. We
>> have to sperate the states much clearer so that it is possible to
>> understand what is happening in the GCE. Isn't it for example posible to
>> have worker queues for timed out tasks and tasks with an error? I'm not
>> sure how to do this, actually I'm not sure if I really understood how
>> this is supposed to work.
>
> GCE doesn't have timeout. The timeout is decided and controlled by CPU,
> so we check timeout in release work.
> For error and done, they are easy to check by register, and we have
> already created release work for timeout. So, I don't think we need to
> create work queue for each case.
>
> What do you think?
>

I think, if we find in here, that the irq_flag is set, then the the 
interrupt handler was triggered and is spinning the spinlock. If this is 
not the case, we have a timeout and we handle this.

>> How much do we win, when we patch the thread command queue for every
>> task we add, instead of just taking one task after another from the
>> task_busy_list?
>
> GCE is used to help read/write registers with critical time limitation.
> Sometimes, client may ask to process multiple tasks in a short period
> of time, e.g. display flush multiple tasks for next vblank. So, CMDQ
> shouldn't limit to process one task after another from the
> task_busy_list. Currently, when interrupt or timeout, we will check
> how many tasks are done, and which one is error or timeout.
>

So I suppose the device driver who use this are interested in throughput 
and not in latency. The callback of every

>>> +	irq_flag = cmdq_thread_readl(thread, CMDQ_THR_IRQ_STATUS);
>>> +	cmdq_handle_error_done(cmdq, thread, irq_flag);
>>> +	cmdq_thread_writel(thread, ~irq_flag, CMDQ_THR_IRQ_STATUS);
>>> +
>>> +	if (task->task_state == TASK_STATE_DONE) {
>>> +		cmdq_thread_resume(thread);
>>> +		return 0;
>>> +	}
>>> +
>>> +	if (task->task_state == TASK_STATE_ERROR) {
>>> +		dev_err(dev, "task 0x%p error\n", task);
>>> +		if (next_task) /* move to next task */
>>> +			cmdq_thread_writel(thread, next_task->pa_base,
>>> +					   CMDQ_THR_CURR_ADDR);
>>> +		cmdq_thread_resume(thread);
>>> +		return -ECANCELED;
>>> +	}
>>> +
>>> +	/* Task is running, so we force to remove it. */
>>> +	dev_err(dev, "task 0x%p timeout or killed\n", task);
>>> +	task->task_state = TASK_STATE_ERROR;
>>> +
>>> +	if (prev_task) {
>>> +		u64 *prev_va = prev_task->va_base;
>>> +		u64 *curr_va = task->va_base;
>>> +
>>> +		/* copy JUMP instruction */
>>> +		prev_va[prev_task->num_cmd - 1] = curr_va[task->num_cmd - 1];
>>> +
>>> +		cmdq_thread_invalidate_fetched_data(thread);
>>> +	} else if (next_task) { /* move to next task */
>>> +		cmdq_thread_writel(thread, next_task->pa_base,
>>> +				   CMDQ_THR_CURR_ADDR);
>>> +	}
>>> +
>>> +	list_del(&task->list_entry);
>>> +	cmdq_thread_resume(thread);
>>> +
>>> +	/* call cb here to prevent lock */
>>> +	if (task->cb.cb) {
>>> +		struct cmdq_cb_data cmdq_cb_data;
>>> +
>>> +		cmdq_cb_data.err = true;
>>> +		cmdq_cb_data.data = task->cb.data;
>>> +		task->cb.cb(cmdq_cb_data);
>>> +	}
>>> +
>>> +	return -ECANCELED;
>>> +}
>>> +
>>> +static void cmdq_task_wait_release_work(struct work_struct *work_item)
>>> +{
>>> +	struct cmdq_task *task = container_of(work_item, struct cmdq_task,
>>> +					      release_work);
>>> +	struct cmdq *cmdq = task->cmdq;
>>> +	struct cmdq_thread *thread = task->thread;
>>> +	unsigned long flags;
>>> +
>>> +	wait_event_timeout(thread->wait_task_done,
>>> +			   task->task_state != TASK_STATE_BUSY,
>>> +			   msecs_to_jiffies(CMDQ_TIMEOUT_MS));
>>> +
>>> +	spin_lock_irqsave(&cmdq->exec_lock, flags);
>>> +	if (task->task_state != TASK_STATE_DONE)
>>> +		cmdq_task_handle_error_result(task);
>>> +	if (list_empty(&thread->task_busy_list))
>>> +		cmdq_thread_disable(cmdq, thread);
>>> +	spin_unlock_irqrestore(&cmdq->exec_lock, flags);
>>> +
>>> +	/* release regardless of success or not */
>>> +	clk_disable_unprepare(cmdq->clock);
>>> +	cmdq_task_release(task);
>>> +}
>>> +
>>> +static void cmdq_task_wait_release_schedule(struct cmdq_task *task)
>>> +{
>>> +	struct cmdq *cmdq = task->cmdq;
>>> +
>>> +	INIT_WORK(&task->release_work, cmdq_task_wait_release_work);
>>> +	queue_work(cmdq->task_release_wq, &task->release_work);
>>> +}
>>> +
>>> +static int cmdq_rec_realloc_cmd_buffer(struct cmdq_rec *rec, size_t size)
>>> +{
>>> +	void *new_buf;
>>> +
>>> +	new_buf = krealloc(rec->buf, size, GFP_KERNEL | __GFP_ZERO);
>>> +	if (!new_buf)
>>> +		return -ENOMEM;
>>> +	rec->buf = new_buf;
>>> +	rec->buf_size = size;
>>> +	return 0;
>>> +}
>>> +
>>> +struct cmdq_base *cmdq_register_device(struct device *dev)
>>> +{
>>> +	struct cmdq_base *cmdq_base;
>>> +	struct resource res;
>>> +	int subsys;
>>> +	u32 base;
>>> +
>>> +	if (of_address_to_resource(dev->of_node, 0, &res))
>>> +		return NULL;
>>> +	base = (u32)res.start;
>>> +
>>> +	subsys = cmdq_subsys_base_to_id(base >> 16);
>>> +	if (subsys < 0)
>>> +		return NULL;
>>> +
>>> +	cmdq_base = devm_kmalloc(dev, sizeof(*cmdq_base), GFP_KERNEL);
>>> +	if (!cmdq_base)
>>> +		return NULL;
>>> +	cmdq_base->subsys = subsys;
>>> +	cmdq_base->base = base;
>>> +
>>> +	return cmdq_base;
>>> +}
>>> +EXPORT_SYMBOL(cmdq_register_device);
>>> +
>>> +int cmdq_rec_create(struct device *dev, u64 engine_flag,
>>> +		    struct cmdq_rec **rec_ptr)
>>> +{
>>> +	struct cmdq_rec *rec;
>>> +	int err;
>>> +
>>> +	rec = kzalloc(sizeof(*rec), GFP_KERNEL);
>>> +	if (!rec)
>>> +		return -ENOMEM;
>>> +	rec->cmdq = dev_get_drvdata(dev);
>>> +	rec->engine_flag = engine_flag;
>>> +	err = cmdq_rec_realloc_cmd_buffer(rec, CMDQ_INITIAL_CMD_BLOCK_SIZE);
>>
>> Just pass PAGE_SIZE here, no need for CMDQ_INITIAL_CMD_BLOCK_SIZE.
>
> Will do.
>
>>> +	if (err < 0) {
>>> +		kfree(rec);
>>> +		return err;
>>> +	}
>>> +	*rec_ptr = rec;
>>> +	return 0;
>>> +}
>>> +EXPORT_SYMBOL(cmdq_rec_create);
>>> +
>>> +static int cmdq_rec_append_command(struct cmdq_rec *rec, enum cmdq_code code,
>>> +				   u32 arg_a, u32 arg_b)
>>> +{
>>> +	u64 *cmd_ptr;
>>> +	int err;
>>> +
>>> +	if (WARN_ON(rec->finalized))
>>> +		return -EBUSY;
>>> +	if (code < CMDQ_CODE_MOVE || code > CMDQ_CODE_EOC)
>>> +		return -EINVAL;
>>
>> cmdq_rec_append_command is just called from inside this driver and code
>> is a enum. We can expect it to be correct, no need for this check.
>
> Will drop this check.
>
>>> +	if (unlikely(rec->command_size + CMDQ_INST_SIZE > rec->buf_size)) {
>>
>> command_size is the offset into the buffer to which a new command is
>> written, so this name is highly confusing. I wonder if this would be
>> easier to understand if we redefine command_size to something like the
>> number of commands and divide/multiply CMDQ_INST_SIZE where this is needed.
>
> I can rename command_size to cmd_buf_size and calculate num_cmd by
> dividing CMDQ_INST_SIZE.
> What do you think?
>
>>> +		err = cmdq_rec_realloc_cmd_buffer(rec, rec->buf_size * 2);
>>> +		if (err < 0)
>>> +			return err;
>>> +	}
>>> +	cmd_ptr = rec->buf + rec->command_size;
>>> +	(*cmd_ptr) = (u64)((code << CMDQ_OP_CODE_SHIFT) | arg_a) << 32 | arg_b;
>>> +	rec->command_size += CMDQ_INST_SIZE;
>>> +	return 0;
>>> +}
>>> +
>>> +int cmdq_rec_write(struct cmdq_rec *rec, u32 value, struct cmdq_base *base,
>>> +		   u32 offset)
>>> +{
>>> +	u32 arg_a = ((base->base + offset) & CMDQ_ARG_A_WRITE_MASK) |
>>> +		    ((base->subsys & CMDQ_SUBSYS_MASK) << CMDQ_SUBSYS_SHIFT);
>>
>> base->subsys is the id from gce_sybsys, so we can expect it to be
>> correct, no need to mask with CMDQ_SUBSYS_MASK.
>
> Will drop it.
>
>>> +	return cmdq_rec_append_command(rec, CMDQ_CODE_WRITE, arg_a, value);
>>> +}
>>> +EXPORT_SYMBOL(cmdq_rec_write);
>>> +
>>> +int cmdq_rec_write_mask(struct cmdq_rec *rec, u32 value,
>>> +			struct cmdq_base *base, u32 offset, u32 mask)
>>> +{
>>> +	u32 offset_mask = offset;
>>> +	int err;
>>> +
>>> +	if (mask != 0xffffffff) {
>>> +		err = cmdq_rec_append_command(rec, CMDQ_CODE_MOVE, 0, ~mask);
>>> +		if (err < 0)
>>> +			return err;
>>> +		offset_mask |= CMDQ_WRITE_ENABLE_MASK;
>>> +	}
>>> +	return cmdq_rec_write(rec, value, base, offset_mask);
>>> +}
>>> +EXPORT_SYMBOL(cmdq_rec_write_mask);
>>> +
>>> +int cmdq_rec_wfe(struct cmdq_rec *rec, enum cmdq_event event)
>>> +{
>>> +	u32 arg_b;
>>> +
>>> +	if (event >= CMDQ_MAX_HW_EVENT_COUNT || event < 0)
>>> +		return -EINVAL;
>>> +
>>> +	/*
>>> +	 * bit 0-11: wait value
>>> +	 * bit 15: 1 - wait, 0 - no wait
>>> +	 * bit 16-27: update value
>>> +	 * bit 31: 1 - update, 0 - no update
>>> +	 */
>>
>> I don't understand this comments. What are they for?
>
> This is for WFE command. I will comment it.
>
>>> +	arg_b = CMDQ_WFE_UPDATE | CMDQ_WFE_WAIT | CMDQ_WFE_WAIT_VALUE;
>>> +	return cmdq_rec_append_command(rec, CMDQ_CODE_WFE, event, arg_b);
>>> +}
>>> +EXPORT_SYMBOL(cmdq_rec_wfe);
>>> +
>>> +int cmdq_rec_clear_event(struct cmdq_rec *rec, enum cmdq_event event)
>>> +{
>>> +	if (event >= CMDQ_MAX_HW_EVENT_COUNT || event < 0)
>>> +		return -EINVAL;
>>> +
>>> +	return cmdq_rec_append_command(rec, CMDQ_CODE_WFE, event,
>>> +				       CMDQ_WFE_UPDATE);
>>> +}
>>> +EXPORT_SYMBOL(cmdq_rec_clear_event);
>>> +
>>> +static int cmdq_rec_finalize(struct cmdq_rec *rec)
>>> +{
>>> +	int err;
>>> +
>>> +	if (rec->finalized)
>>> +		return 0;
>>> +
>>> +	/* insert EOC and generate IRQ for each command iteration */
>>> +	err = cmdq_rec_append_command(rec, CMDQ_CODE_EOC, 0, CMDQ_EOC_IRQ_EN);
>>> +	if (err < 0)
>>> +		return err;
>>> +
>>> +	/* JUMP to end */
>>> +	err = cmdq_rec_append_command(rec, CMDQ_CODE_JUMP, 0, CMDQ_JUMP_PASS);
>>> +	if (err < 0)
>>> +		return err;
>>> +
>>
>> Does this need to be atomic?
>> What happens if after CODE_EOC and before CODE_JUMP some
>> write/read/event gets added?
>> What happens if more commands get added to the queue after CODE_JUMP,
>> but before finalized is set to true. Why don't you use atomic functions
>> to access finalized?
>
> Since cmdq_rec doesn't guarantee thread safe, mutex is needed when
> client uses cmdq_rec.
>

Well I think that rec->finalized tries to implement this, but might 
fail, if two kernel threads work on the same cmdq_rec.

>>> +	rec->finalized = true;
>>> +	return 0;
>>> +}
>>> +
>>> +int cmdq_rec_flush_async(struct cmdq_rec *rec, cmdq_async_flush_cb cb,
>>> +			 void *data)
>>> +{
>>> +	struct cmdq *cmdq = rec->cmdq;
>>> +	struct cmdq_task *task;
>>> +	struct cmdq_task_cb task_cb;
>>> +	struct cmdq_thread *thread;
>>> +	int err;
>>> +
>>> +	mutex_lock(&cmdq->task_mutex);
>>> +	if (cmdq->suspended) {
>>> +		dev_err(cmdq->dev, "%s is called after suspended\n", __func__);
>>> +		mutex_unlock(&cmdq->task_mutex);
>>> +		return -EPERM;
>>> +	}
>>> +
>>> +	err = cmdq_rec_finalize(rec);
>>> +	if (err < 0) {
>>> +		mutex_unlock(&cmdq->task_mutex);
>>> +		return err;
>>> +	}
>>> +
>>> +	task_cb.cb = cb;
>>> +	task_cb.data = data;
>>> +	task = cmdq_task_acquire(rec, task_cb);
>>> +	if (!task) {
>>> +		mutex_unlock(&cmdq->task_mutex);
>>> +		return -EFAULT;
>>> +	}
>>> +
>>> +	thread = &cmdq->thread[cmdq_eng_get_thread(task->engine_flag)];
>>> +	cmdq_task_exec(task, thread);
>>> +	cmdq_task_wait_release_schedule(task);
>>> +	mutex_unlock(&cmdq->task_mutex);
>>> +	return 0;
>>> +}
>>> +EXPORT_SYMBOL(cmdq_rec_flush_async);
>>> +
>>> +struct cmdq_flush_completion {
>>> +	struct completion cmplt;
>>> +	bool err;
>>> +};
>>> +
>>> +static int cmdq_rec_flush_cb(struct cmdq_cb_data data)
>>> +{
>>> +	struct cmdq_flush_completion *cmplt = data.data;
>>> +
>>> +	cmplt->err = data.err;
>>> +	complete(&cmplt->cmplt);
>>> +	return 0;
>>> +}
>>> +
>>> +int cmdq_rec_flush(struct cmdq_rec *rec)
>>> +{
>>> +	struct cmdq_flush_completion cmplt;
>>> +	int err;
>>> +
>>> +	init_completion(&cmplt.cmplt);
>>> +	err = cmdq_rec_flush_async(rec, cmdq_rec_flush_cb, &cmplt);
>>> +	if (err < 0)
>>> +		return err;
>>> +	wait_for_completion(&cmplt.cmplt);
>>> +	return cmplt.err ? -EFAULT : 0;
>>> +}
>>> +EXPORT_SYMBOL(cmdq_rec_flush);
>>> +
>>> +void cmdq_rec_destroy(struct cmdq_rec *rec)
>>> +{
>>> +	kfree(rec->buf);
>>> +	kfree(rec);
>>> +}
>>> +EXPORT_SYMBOL(cmdq_rec_destroy);
>>> +
>>> +static bool cmdq_task_is_empty(struct cmdq *cmdq)
>>> +{
>>> +	struct cmdq_thread *thread;
>>> +	int i;
>>> +
>>> +	for (i = 0; i < ARRAY_SIZE(cmdq->thread); i++) {
>>> +		thread = &cmdq->thread[i];
>>> +		if (!list_empty(&thread->task_busy_list))
>>> +			return false;
>>> +	}
>>> +	return true;
>>> +}
>>> +
>>> +static int cmdq_suspend(struct device *dev)
>>> +{
>>> +	struct cmdq *cmdq = dev_get_drvdata(dev);
>>> +	u32 exec_threads;
>>> +
>>> +	mutex_lock(&cmdq->task_mutex);
>>> +	cmdq->suspended = true;
>>> +	mutex_unlock(&cmdq->task_mutex);
>>> +
>>> +	exec_threads = readl(cmdq->base + CMDQ_CURR_LOADED_THR);
>>> +	if ((exec_threads & CMDQ_THR_EXECUTING) && !cmdq_task_is_empty(cmdq)) {
>>> +		dev_err(dev, "wait active tasks timeout.\n");
>>> +		flush_workqueue(cmdq->task_release_wq);
>>> +	}
>>> +	return 0;
>>> +}
>>> +
>>> +static int cmdq_resume(struct device *dev)
>>> +{
>>> +	struct cmdq *cmdq = dev_get_drvdata(dev);
>>> +
>>> +	cmdq->suspended = false;
>>> +	return 0;
>>> +}
>>> +
>>> +static int cmdq_remove(struct platform_device *pdev)
>>> +{
>>> +	struct cmdq *cmdq = platform_get_drvdata(pdev);
>>> +
>>> +	destroy_workqueue(cmdq->task_release_wq);
>>> +	cmdq->task_release_wq = NULL;
>>> +	return 0;
>>> +}
>>> +
>>> +static int cmdq_probe(struct platform_device *pdev)
>>> +{
>>> +	struct device *dev = &pdev->dev;
>>> +	struct device_node *node = dev->of_node;
>>> +	struct resource *res;
>>> +	struct cmdq *cmdq;
>>> +	int err, i;
>>> +
>>> +	cmdq = devm_kzalloc(dev, sizeof(*cmdq), GFP_KERNEL);
>>> +	if (!cmdq)
>>> +		return -ENOMEM;
>>> +	cmdq->dev = dev;
>>> +
>>> +	res = platform_get_resource(pdev, IORESOURCE_MEM, 0);
>>> +	cmdq->base = devm_ioremap_resource(dev, res);
>>> +	if (IS_ERR(cmdq->base)) {
>>> +		dev_err(dev, "failed to ioremap gce\n");
>>> +		return PTR_ERR(cmdq->base);
>>> +	}
>>> +
>>> +	cmdq->irq = irq_of_parse_and_map(node, 0);
>>> +	if (!cmdq->irq) {
>>> +		dev_err(dev, "failed to get irq\n");
>>> +		return -EINVAL;
>>> +	}
>>> +
>>> +	dev_dbg(dev, "cmdq device: addr:0x%p, va:0x%p, irq:%d\n",
>>> +		dev, cmdq->base, cmdq->irq);
>>> +
>>> +	mutex_init(&cmdq->task_mutex);
>>> +	spin_lock_init(&cmdq->exec_lock);
>>> +	cmdq->task_release_wq = alloc_ordered_workqueue(
>>> +			"%s", WQ_MEM_RECLAIM | WQ_HIGHPRI,
>>> +			"cmdq_task_wait_release");
>>> +
>>> +	for (i = 0; i < ARRAY_SIZE(cmdq->thread); i++) {
>>> +		cmdq->thread[i].base = cmdq->base + CMDQ_THR_BASE +
>>> +				CMDQ_THR_SHIFT * i;
>>> +		init_waitqueue_head(&cmdq->thread[i].wait_task_done);
>>> +		INIT_LIST_HEAD(&cmdq->thread[i].task_busy_list);
>>> +	}
>>> +
>>> +	platform_set_drvdata(pdev, cmdq);
>>> +
>>> +	err = devm_request_irq(dev, cmdq->irq, cmdq_irq_handler, IRQF_SHARED,
>>> +			       CMDQ_DRIVER_DEVICE_NAME, cmdq);
>>> +	if (err < 0) {
>>> +		dev_err(dev, "failed to register ISR (%d)\n", err);
>>> +		goto fail;
>>> +	}
>>> +
>>> +	cmdq->clock = devm_clk_get(dev, CMDQ_CLK_NAME);
>>> +	if (IS_ERR(cmdq->clock)) {
>>> +		dev_err(dev, "failed to get clk:%s\n", CMDQ_CLK_NAME);
>>> +		err = PTR_ERR(cmdq->clock);
>>> +		goto fail;
>>> +	}
>>> +	return 0;
>>> +
>>> +fail:
>>> +	cmdq_remove(pdev);
>>> +	return err;
>>> +}
>>> +
>>> +static const struct dev_pm_ops cmdq_pm_ops = {
>>> +	.suspend = cmdq_suspend,
>>> +	.resume = cmdq_resume,
>>> +};
>>> +
>>> +static const struct of_device_id cmdq_of_ids[] = {
>>> +	{.compatible = "mediatek,mt8173-gce",},
>>> +	{}
>>> +};
>>> +
>>> +static struct platform_driver cmdq_drv = {
>>> +	.probe = cmdq_probe,
>>> +	.remove = cmdq_remove,
>>> +	.driver = {
>>> +		.name = CMDQ_DRIVER_DEVICE_NAME,
>>> +		.owner = THIS_MODULE,
>>> +		.pm = &cmdq_pm_ops,
>>> +		.of_match_table = cmdq_of_ids,
>>> +	}
>>> +};
>>> +
>>> +builtin_platform_driver(cmdq_drv);
>>> diff --git a/include/soc/mediatek/cmdq.h b/include/soc/mediatek/cmdq.h
>>> new file mode 100644
>>> index 0000000..60eef3d
>>> --- /dev/null
>>> +++ b/include/soc/mediatek/cmdq.h
>>> @@ -0,0 +1,197 @@
>>> +/*
>>> + * Copyright (c) 2015 MediaTek Inc.
>>> + *
>>> + * This program is free software; you can redistribute it and/or modify
>>> + * it under the terms of the GNU General Public License version 2 as
>>> + * published by the Free Software Foundation.
>>> + *
>>> + * This program is distributed in the hope that it will be useful,
>>> + * but WITHOUT ANY WARRANTY; without even the implied warranty of
>>> + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
>>> + * GNU General Public License for more details.
>>> + */
>>> +
>>> +#ifndef __MTK_CMDQ_H__
>>> +#define __MTK_CMDQ_H__
>>> +
>>> +#include <linux/platform_device.h>
>>> +#include <linux/types.h>
>>> +
>>> +enum cmdq_eng {
>>> +	CMDQ_ENG_DISP_AAL,
>>> +	CMDQ_ENG_DISP_COLOR0,
>>> +	CMDQ_ENG_DISP_COLOR1,
>>> +	CMDQ_ENG_DISP_DPI0,
>>> +	CMDQ_ENG_DISP_DSI0,
>>> +	CMDQ_ENG_DISP_DSI1,
>>> +	CMDQ_ENG_DISP_GAMMA,
>>> +	CMDQ_ENG_DISP_OD,
>>> +	CMDQ_ENG_DISP_OVL0,
>>> +	CMDQ_ENG_DISP_OVL1,
>>> +	CMDQ_ENG_DISP_PWM0,
>>> +	CMDQ_ENG_DISP_PWM1,
>>> +	CMDQ_ENG_DISP_RDMA0,
>>> +	CMDQ_ENG_DISP_RDMA1,
>>> +	CMDQ_ENG_DISP_RDMA2,
>>> +	CMDQ_ENG_DISP_UFOE,
>>> +	CMDQ_ENG_DISP_WDMA0,
>>> +	CMDQ_ENG_DISP_WDMA1,
>>> +	CMDQ_ENG_MAX,
>>> +};
>>> +
>>> +/* events for CMDQ and display */
>>> +enum cmdq_event {
>>> +	/* Display start of frame(SOF) events */
>>> +	CMDQ_EVENT_DISP_OVL0_SOF = 11,
>>> +	CMDQ_EVENT_DISP_OVL1_SOF = 12,
>>> +	CMDQ_EVENT_DISP_RDMA0_SOF = 13,
>>> +	CMDQ_EVENT_DISP_RDMA1_SOF = 14,
>>> +	CMDQ_EVENT_DISP_RDMA2_SOF = 15,
>>> +	CMDQ_EVENT_DISP_WDMA0_SOF = 16,
>>> +	CMDQ_EVENT_DISP_WDMA1_SOF = 17,
>>> +	/* Display end of frame(EOF) events */
>>> +	CMDQ_EVENT_DISP_OVL0_EOF = 39,
>>> +	CMDQ_EVENT_DISP_OVL1_EOF = 40,
>>> +	CMDQ_EVENT_DISP_RDMA0_EOF = 41,
>>> +	CMDQ_EVENT_DISP_RDMA1_EOF = 42,
>>> +	CMDQ_EVENT_DISP_RDMA2_EOF = 43,
>>> +	CMDQ_EVENT_DISP_WDMA0_EOF = 44,
>>> +	CMDQ_EVENT_DISP_WDMA1_EOF = 45,
>>> +	/* Mutex end of frame(EOF) events */
>>> +	CMDQ_EVENT_MUTEX0_STREAM_EOF = 53,
>>> +	CMDQ_EVENT_MUTEX1_STREAM_EOF = 54,
>>> +	CMDQ_EVENT_MUTEX2_STREAM_EOF = 55,
>>> +	CMDQ_EVENT_MUTEX3_STREAM_EOF = 56,
>>> +	CMDQ_EVENT_MUTEX4_STREAM_EOF = 57,
>>> +	/* Display underrun events */
>>> +	CMDQ_EVENT_DISP_RDMA0_UNDERRUN = 63,
>>> +	CMDQ_EVENT_DISP_RDMA1_UNDERRUN = 64,
>>> +	CMDQ_EVENT_DISP_RDMA2_UNDERRUN = 65,
>>> +	/* Keep this at the end of HW events */
>>> +	CMDQ_MAX_HW_EVENT_COUNT = 260,
>>> +};
>>> +
>>> +struct cmdq_cb_data {
>>> +	bool	err;
>>> +	void	*data;
>>> +};
>>> +
>>> +typedef int (*cmdq_async_flush_cb)(struct cmdq_cb_data data);
>>> +
>>> +struct cmdq_task;
>>> +struct cmdq;
>>> +
>>> +struct cmdq_rec {
>>> +	struct cmdq		*cmdq;
>>> +	u64			engine_flag;
>>> +	size_t			command_size;
>>> +	void			*buf;
>>> +	size_t			buf_size;
>>> +	bool			finalized;
>>> +};

Why do we need cmdq_rec at all? Can't we just use the cmdq_task for that 
and this way make the driver less complex?

>>> +
>>> +struct cmdq_base {
>>> +	int	subsys;
>>> +	u32	base;
>>
>> subsys can always be calculated via cmdq_subsys_base_to_id(base >> 16)
>> so we can get rid of the struct, right?
>
> Current subsys method is based on previous comment from Daniel Kurtz.
> Please take a look of our previous discussion.
> http://lists.infradead.org/pipermail/linux-mediatek/2016-February/004483.html
> Thanks.
>

I have to look deeper into this, but from what I read, the proposal from 
Daniel [1] seems good to me.

[1] https://patchwork.kernel.org/patch/8068311/

>>> +};
>>> +
>>> +/**
>>> + * cmdq_register_device() - register device which needs CMDQ
>>> + * @dev:		device
>>> + *
>>> + * Return: cmdq_base pointer or NULL for failed
>>> + */
>>> +struct cmdq_base *cmdq_register_device(struct device *dev);
>>> +
>>> +/**
>>> + * cmdq_rec_create() - create command queue record
>>> + * @dev:		device
>>> + * @engine_flag:	command queue engine flag
>>> + * @rec_ptr:		command queue record pointer to retrieve cmdq_rec
>>> + *
>>> + * Return: 0 for success; else the error code is returned
>>> + */
>>> +int cmdq_rec_create(struct device *dev, u64 engine_flag,
>>> +		    struct cmdq_rec **rec_ptr);
>>> +
>>> +/**
>>> + * cmdq_rec_write() - append write command to the command queue record
>>> + * @rec:	the command queue record
>>> + * @value:	the specified target register value
>>> + * @base:	the command queue base
>>> + * @offset:	register offset from module base
>>> + *
>>> + * Return: 0 for success; else the error code is returned
>>> + */
>>> +int cmdq_rec_write(struct cmdq_rec *rec, u32 value,
>>> +		   struct cmdq_base *base, u32 offset);
>>> +
>>> +/**
>>> + * cmdq_rec_write_mask() - append write command with mask to the command
>>> + *			   queue record
>>> + * @rec:	the command queue record
>>> + * @value:	the specified target register value
>>> + * @base:	the command queue base
>>> + * @offset:	register offset from module base
>>> + * @mask:	the specified target register mask
>>> + *
>>> + * Return: 0 for success; else the error code is returned
>>> + */
>>> +int cmdq_rec_write_mask(struct cmdq_rec *rec, u32 value,
>>> +			struct cmdq_base *base, u32 offset, u32 mask);
>>> +
>>> +/**
>>> + * cmdq_rec_wfe() - append wait for event command to the command queue reco	rd
>>
>> reco rd -> record
>
> Will fix it.
>
>> Regards,
>> Matthias
>>
>>> + * @rec:	the command queue record
>>> + * @event:	the desired event type to "wait and CLEAR"
>>> + *
>>> + * Return: 0 for success; else the error code is returned
>>> + */
>>> +int cmdq_rec_wfe(struct cmdq_rec *rec, enum cmdq_event event);
>>> +
>>> +/**
>>> + * cmdq_rec_clear_event() - append clear event command to the command queue
>>> + *			    record
>>> + * @rec:	the command queue record
>>> + * @event:	the desired event to be cleared
>>> + *
>>> + * Return: 0 for success; else the error code is returned
>>> + */
>>> +int cmdq_rec_clear_event(struct cmdq_rec *rec, enum cmdq_event event);
>>> +
>>> +/**
>>> + * cmdq_rec_flush() - trigger CMDQ to execute the recorded commands
>>> + * @rec:	the command queue record
>>> + *
>>> + * Return: 0 for success; else the error code is returned
>>> + *
>>> + * Trigger CMDQ to execute the recorded commands. Note that this is a
>>> + * synchronous flush function. When the function returned, the recorded
>>> + * commands have been done.
>>> + */
>>> +int cmdq_rec_flush(struct cmdq_rec *rec);
>>> +
>>> +/**
>>> + * cmdq_rec_flush_async() - trigger CMDQ to asynchronously execute the recorded
>>> + *			    commands and call back after ISR is finished
>>> + * @rec:	the command queue record
>>> + * @cb:		called in the end of CMDQ ISR
>>> + * @data:	this data will pass back to cb
>>> + *
>>> + * Return: 0 for success; else the error code is returned
>>> + *
>>> + * Trigger CMDQ to asynchronously execute the recorded commands and call back
>>> + * after ISR is finished. Note that this is an ASYNC function. When the function
>>> + * returned, it may or may not be finished. The ISR callback function is called
>>> + * in the end of ISR.

"The callback is called from the ISR."

Regards,
Matthias

>>> + */
>>> +int cmdq_rec_flush_async(struct cmdq_rec *rec, cmdq_async_flush_cb cb,
>>> +			 void *data);
>>> +
>>> +/**
>>> + * cmdq_rec_destroy() - destroy command queue record
>>> + * @rec:	the command queue record
>>> + */
>>> +void cmdq_rec_destroy(struct cmdq_rec *rec);
>>> +
>>> +#endif	/* __MTK_CMDQ_H__ */
>>>
>
> Thanks,
> HS
>



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