Re: [PATCH V6 2/7] soc: qcom: dcc:Add driver support for Data Capture and Compare unit(DCC)

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On 1/7/2022 9:27 PM, Bjorn Andersson wrote:
On Fri 07 Jan 07:27 PST 2022, Souradeep Chowdhury wrote:

On 1/7/2022 5:31 AM, Bjorn Andersson wrote:
On Wed 05 Jan 23:57 PST 2022, Souradeep Chowdhury wrote:

On 12/18/2021 1:41 AM, Bjorn Andersson wrote:
On Tue 10 Aug 12:54 CDT 2021, Souradeep Chowdhury wrote:

The DCC is a DMA Engine designed to capture and store data
during system crash or software triggers.The DCC operates
Please include a space after '.'
Ack
based on user inputs via the sysfs interface.The user gives
addresses as inputs and these addresses are stored in the
form of linkedlists.In case of a system crash or a manual
I think the user configures the DCC hardware with "a sequence of
operations to be performed as DCC is triggered".

Afaict the sequence is stored just as a sequence of operations in SRAM,
there's no linked list involved - except in your intermediate
implementation.
The user just enters the addresses as input whereas the sequence of
operations takes

place as per configuration code inside the driver. The end result is storage
of these

addresses inside the DCC SRAM. The DCC hardware will capture the value at
these

addresses on a crash or manual trigger by the user.

software trigger by the user through the sysfs interface,
the dcc captures and stores the values at these addresses.
This patch contains the driver which has all the methods
pertaining to the sysfs interface, auxiliary functions to
support all the four fundamental operations of dcc namely
read, write, first read then write and loop.The probe method
"first read then write" is called "read/modify/write"
Ack
here instantiates all the resources necessary for dcc to
operate mainly the dedicated dcc sram where it stores the
values.The DCC driver can be used for debugging purposes
without going for a reboot since it can perform manual
triggers.

Also added the documentation for sysfs entries
and explained the functionalities of each sysfs file that
has been created for dcc.

The following is the justification of using sysfs interface
over the other alternatives like ioctls

i) As can be seen from the sysfs attribute descriptions,
most of it does basic hardware manipulations like dcc_enable,
dcc_disable, config reset etc. As a result sysfs is preferred
over ioctl as we just need to enter a 0 or 1.

As I mentioned in our chat, using sysfs allows us to operate the
interface using the shell without additional tools.

But I don't think that it's easy to implement enable/disable/reset using
sysfs is a strong argument. The difficult part of this ABI is the
operations to manipulate the sequence of operations, so that's what you
need to have a solid plan for.
The sysfs interface is being used to get the addresses values entered by the
user

and to also go for manual triggers. The sequence of operations are kept as a
part of

fixed driver code which is called when the user enters the data.

But does the hardware really just operate on "addresses values entered
by the user". Given the various types of operations: read, write,
read-modify-write and loop I get the feeling that the hardware
"executes" a series of actions.

I'm don't think the proposed sysfs interface best exposes this to the
user and I don't think that "it's easy to implement enable/disable
attributes in sysfs" is reason enough to go with that approach.
So the sysfs interface here has been introduced keeping in mind how the
DCC_SRAM needs to be

programmed for the dcc hardware to work. We are maintaining a list here
based on the address

entry. The 4 cases for the type of addresses are as follows-:

i) READ ADDRESSES

user enters something like "echo <addr> <len> > config"

DCC driver stores the <addr> along with the length information in the
DCC_SRAM.

ii) WRITE ADDRESSES

User enters something like "echo <addr> <write_val> 1  > config_write"

DCC stores the <addr> first in sram followed by <write_val>.

For the above 2 type of addresses there won't be much difference if we use
IOCTL.

However, for the next 2 type of addresses

iii) LOOP ADDRESSES

user has to enter something like below

echo 9 > loop
echo 0x01741010 1 > config
echo 0x01741014 1 > config
echo 1 > loop

The DCC SRAM will be programmed precisely like the above entries where the
loop count will be stored first

followed by loop addresses and then again a "echo 1 > loop " marks the end
of loop addresses.

in DCC_SRAM.

iv) READ_WRITE ADDRESSES

User has to enter something like below

echo <addr> > /sys/bus/platform/devices/../config

echo <mask> <val> > /sys/bus/platform/devices/../rd_mod_wr

Here first the  <addr> is stored in DCC_SRAM followed by <mask> and then the
<val>.

The above representation to the user space is consistent with the dcc
hardware in terms of

the way the sequence of values are programmed in the DCC SRAM . Moving to
IOCTL will

only change the way the READ_WRITE address is represented although user will
have to enter

multiple parameters at once, let me know if we still need to go for the
same.

So if I understand correctly, my concern is that if I would like to
perform something like (in pseudo code):

readl(X)
write(1, Y)
readl(Z) 5 times

then I will do this as:

echo X > config
echo Y 1 > config_write
echo 5 > loop
echo Z > config
echo 1 > loop

And the DCC driver will then write this to SRAM as something like:

read X
write Y, 1
loop 5
read Z
loop


In other words, my mind and the DCC has the same representation of this
sequence of operations, but I have to shuffle the information into 4
different sysfs attributes to get there.

The design guideline for sysfs is that each attribute should hold one
value per attribute, but in your model the attributes are tangled and
writing things to them depends on what has been written in that or other
attributes previously.

I simply don't think that's a good ABI.

Ack.

Should I change this to have separate sysfs files dealing with separate type of instructions?

For example I can have separate files like config_read, config_write(already exists), config_loop

and config_read_write to handle 4 different type of instructions with inputs like

echo <loop_offset> <loop_address_numbers> <loop_address_1> <loop_address_2>.. > config_loop

echo <address> <mask> <val> > config_read_write

and so on


[..]
+		The address argument should
+		be given of the form <mask> <value>.For debugging
+		purposes sometimes we need to first read from a register
+		and then set some values to the register.
+		Example:
+		echo 0x80000000 > /sys/bus/platform/devices/.../config
+		(Set the address in config file)
+		echo 0xF 0xA > /sys/bus/platform/devices/.../rd_mod_wr
+		(Provide the mask and the value to write)
+
+What:           /sys/bus/platform/devices/.../ready
+Date:           March 2021
+Contact:        Souradeep Chowdhury<schowdhu@xxxxxxxxxxxxxx>
+Description:
+		This file is used to check the status of the dcc
+		hardware if it's ready to take the inputs.
When will this read "false"?
This will give false if the DCC hardware is not in an operational state.

Will update accordingly.

+		Example:
+		cat /sys/bus/platform/devices/.../ready
+
+What:		/sys/bus/platform/devices/.../curr_list
+Date:		February 2021
+Contact:	Souradeep Chowdhury<schowdhu@xxxxxxxxxxxxxx>
+Description:
+		This attribute is used to enter the linklist to be
I think it would be more appropriate to use the verb "select" here and
afaict it's a "list" as the "linked" part only relates to your
implementation).

But that said, I don't like this ABI. I think it would be cleaner if you
had specific attributes for each of the lists. That way it would be
clear that you have N lists and they can be configured and enabled
independently, and there's no possible race conditions.
So we do have attributes for independent lists in this case. The user is
given the option

to configure multiple lists at one go. For example I can do

echo 1 > curr_list

echo 0x18000010 1 > config
echo 0x18000024 1 > config

Then followed by

echo 2 > curr_list

echo 0x18010038 6 > config
echo 0x18020010 1 > config

We will get the output in terms of two separate list of registers values.

I understand that this will define two lists of operations and that we
will get 2 and 7 registers dumped, respectively. Perhaps unlikely, but
what happens if you try to do these two operations concurrently?


What I'm suggesting here is that if you have N contexts, you should have
N interfaces to modify each one independently - simply because that's
generally a very good thing.
Not sure if there will ever be a concurrency issue in this case.
This is just about programming the DCC SRAM from the user entries
sequentially.
So you've decided that two such sequences must not happen at the same
time. (I know it's unlikely, but there's nothing preventing me from
running the two snippets of echos concurrently and the outcome will be
unexpected)

So as per the dcc hardware configuration document, parallel programming of lists are not

supported for dcc. We program the lists sequentially one after the other.


The curr_list number is nothing but some register writes
done in the dcc so that the dcc_hardware knows the beginning and end
of a particular list and can dump the captured data according. Even if
an user chooses multiple curr_list entries, it will be programmed
sequentially in DCC_SRAM.

So there's no separation between the lists in the hardware?

Looking at the driver I get a sense that we have N lists that can be
configured independently and will be run "independently" upon a trigger.

If this isn't the case, what's the purpose of the multiple lists?

Lists are programmed sequentially from the driver perspective.

We have multiple lists in case of dcc because multiple software components may be using

dcc hardware at once in which case there are individual lists allotted for each individual components.

For example kernel might have a few lists to access whereas the rest maybe used by SDI which is a

separate component. Each list is of arbitrary length as entered by the user and one list can be updated

with it's base address after the previous list has been programmed in DCC_SRAM like below :-

                ret = __dcc_ll_cfg(drvdata, list);
                if (ret) {
                        dcc_writel(drvdata, 0, DCC_LL_LOCK(list));
                        goto err;
                }

                /* 3. program DCC_RAM_CFG reg */
                dcc_writel(drvdata, ram_cfg_base +
                        drvdata->ram_offset/4, DCC_LL_BASE(list));

+		used while appending addresses.The range of values
+		for this can be from 0 to 3.This feature is given in
+		order to use certain linkedlist for certain debugging
+		purposes.
+		Example:
+		echo 0 > /sys/bus/platform/devices/10a2000.dcc/curr_list
+
[..]
diff --git a/drivers/soc/qcom/dcc.c b/drivers/soc/qcom/dcc.c
[..]
+static int dcc_valid_list(struct dcc_drvdata *drvdata, int curr_list)
+{
+	u32 lock_reg;
+
+	if (list_empty(&drvdata->cfg_head[curr_list]))
+		return -EINVAL;
+
+	if (drvdata->enable[curr_list]) {
+		dev_err(drvdata->dev, "List %d is already enabled\n",
+				curr_list);
+		return -EINVAL;
+	}
+
+	lock_reg = dcc_readl(drvdata, DCC_LL_LOCK(curr_list));
Under what circumstances would this differ from
drvdata->enable[curr_list}?
So locking the list is done on the register as soon as the user enters the
curr_list entry whereas

the list is marked as enabled only on successfully programming the SRAM
contents. So a list can

be locked and not marked enabled in certain cases. The first is used so that
the user doesn't

mistakenly enter the same curr_list twice whereas the later is used to mark
that the list has been

successfully configured.

So this will mark the list as "actively in use, but disabled"? Why is
this kept in the hardware? When is this not the same as the list of
operations for that list being non-empty?
So this is in accordance with the dcc hardware configuration
requirement. We have to lock the list first and after that proceed
with the subsequent writes.
But what does this mean? What happens when I lock a list?

Afacit we have a "lock" bit and an "enable" bit. So in what circumstance
does the hardware care about a list being locked? Wouldn't it be
sufficient to just have the enable bit?

As explained above multiple software components might be using DCC hardware for which lock bit is

necessary. From only kernel perspective enable bit alone suffices for the operation.


As per the driver code below

                /* 1. Take ownership of the list */
                 dcc_writel(drvdata, BIT(0), DCC_LL_LOCK(list));

                 /* 2. Program linked-list in the SRAM */
                 ram_cfg_base = drvdata->ram_cfg;
                 ret = __dcc_ll_cfg(drvdata, list);
                 if (ret) {
                         dcc_writel(drvdata, 0, DCC_LL_LOCK(list));
                         goto err;
                 }

                 /* 3. program DCC_RAM_CFG reg */
                 dcc_writel(drvdata, ram_cfg_base +
                         drvdata->ram_offset/4, DCC_LL_BASE(list));
                 dcc_writel(drvdata, drvdata->ram_start +
                         drvdata->ram_offset/4, DCC_FD_BASE(list));
                 dcc_writel(drvdata, 0xFFF, DCC_LL_TIMEOUT(list));

                 /* 4. Clears interrupt status register */
                 dcc_writel(drvdata, 0, DCC_LL_INT_ENABLE(list));
                 dcc_writel(drvdata, (BIT(0) | BIT(1) | BIT(2)),
                                         DCC_LL_INT_STATUS(list));

In case of any errors we again unlock the list before exiting.

So it needs to be locked while SRAM contains a valid sequence of
operations?

Or does it need to be locked while we write to SRAM? If so, why is that?

So it needs to be locked while SRAM contains a valid sequence of operations.

The reason has been explained as above.

Regards,
Bjorn



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