[PATCH] fsl_ifc_nand: Added random output enable cmd
Ronak Desai
ronak.desai at rockwellcollins.com
Wed Sep 7 07:50:50 PDT 2016
On Wed, Sep 7, 2016 at 2:22 AM, Boris Brezillon
<boris.brezillon at free-electrons.com> wrote:
> Hi Scott,
>
> On Wed, 07 Sep 2016 01:03:53 -0500
> Scott Wood <oss at buserror.net> wrote:
>
>> On Tue, 2016-09-06 at 21:50 +0200, Boris Brezillon wrote:
>> > On Tue, 6 Sep 2016 14:13:17 -0500
>> > Matt Weber <matthew.weber at rockwellcollins.com> wrote:
>> >
>> > >
>> > > This patch adds random output enable command support in IFC nand
>> > > controller driver. This command implements change read
>> > > column (05h-E0h).
>> > >
>> > > Signed-off-by: Matthew Weber <matthew.weber at rockwellcollins.com>
>> > > Signed-off-by: Ronak Desai <ronak.desai at rockwellcollins.com>
>> > > ---
>> > > drivers/mtd/nand/fsl_ifc_nand.c | 30 +++++++++++++++++++++++++++---
>> > > 1 file changed, 27 insertions(+), 3 deletions(-)
>> > >
>> > > diff --git a/drivers/mtd/nand/fsl_ifc_nand.c
>> > > b/drivers/mtd/nand/fsl_ifc_nand.c
>> > > index 4e9e5fd..230919f 100644
>> > > --- a/drivers/mtd/nand/fsl_ifc_nand.c
>> > > +++ b/drivers/mtd/nand/fsl_ifc_nand.c
>> > > @@ -387,10 +387,11 @@ static void fsl_ifc_cmdfunc(struct mtd_info *mtd,
>> > > unsigned int command,
>> > >
>> > > /*
>> > > * although currently it's 8 bytes for READID, we always
>> > > read
>> > > - * the maximum 256 bytes(for PARAM)
>> > > + * the maximum 8192 bytes(for PARAM) supported by IFC
>> > > controller
>> > > + * as extended page may be available for some NAND
>> > > devices.
>> > > */
>> > > - ifc_out32(256, &ifc->ifc_nand.nand_fbcr);
>> > > - ifc_nand_ctrl->read_bytes = 256;
>> > > + ifc_out32(0, &ifc->ifc_nand.nand_fbcr); /* Read whole
>> > > page */
>> > > + ifc_nand_ctrl->read_bytes = 8192; /* Maximum supported
>> > > page by IFC */
>>
>> Are you sure that reading 8192 bytes will work if the configured page size is
>> smaller?
>
> I'm pretty sure it will, but you will either get garbage or have the
> same content duplicated in your buffer.
>
Yes, it works fine. I have tested it with 2 KB page size NAND device.
>>
>> > And this exactly why letting drivers implement their own ->cmdfunc()
>> > method is a bad idea.
>> > ->cmdfunc() does not provide enough information to guess how much data
>> > should be read or written. Actually it's not supposed to be used this
>> > way, but drivers usually abuse it.
>>
>> It would be even uglier if we used the standard nand_command_lp() and had to
>> abuse cmd_ctrl() instead. :-P
>
> Well, I can't say, I haven't read the whole driver. But I've been said
> so many times that ->cmd_ctrl() was not a good solution and in the end
> it appeared to be untrue (you don't necessarily have to issue the CMD
> and ADDR cycles right away, you can cache them and send the whole
> sequence once the command parameter is CMD_NONE).
>
> Anyway, the problem is not really whether ->cmd_ctrl() should be used
> instead of ->cmdfunc() here. The thing is, you're doing the I/Os in a
> place where you don't know how many bytes should be retrieved.
>
> If we stick to the ->cmdfunc() + ->{read,write}_buf() model (which is
> definitely inappropriate for most controllers), the data transfer should
> be done in ->{read,write}_buf() (where you have the size information).
>
> Actually, the PXA driver is doing pretty much the same thing as you do,
> and I remember that they had to tweak the size they were reading in
> ->cmdfunc() because the core decided to read more data at some point.
>
>>
>> The current NAND driver interface is too low level for controllers that expose
>> higher level interfaces.
>
> That's for sure.
>
>> If we can't/shouldn't replace cmdfunc() then we need
>> to replace the things that call cmdfunc(). Yes, we probably should have
>> pushed for a better interface back then rather than just "making it work"...
>
> No, let's not add more random hacks. I was just complaining because I
> see more and more drivers implementing their own ->cmdfunc() and adding
> this kind of hacks.
> Most of them can implement ->cmd_ctrl() and rely on the default
> nand_command_lp(), but I agree that some controllers do not fit in this
> model.
>
> For these ones, I was planning to provide a ->send_op(chip, nand_op)
> method, where nand_op would contain both the CMD, ADDR cycles and
> the data transfer.
>
>>
>> > I know you're just adding support for a new feature here, and I don't
>> > blame you, but this kind of things make the whole NAND framework
>> > impossible to maintain.
>> >
>> > >
>> > >
>> > > set_addr(mtd, 0, 0, 0);
>> > > fsl_ifc_run_command(mtd);
>> > > @@ -530,6 +531,29 @@ static void fsl_ifc_cmdfunc(struct mtd_info *mtd,
>> > > unsigned int command,
>> > > fsl_ifc_run_command(mtd);
>> > > return;
>> > >
>> > > + case NAND_CMD_RNDOUT: {
>> > > + __le16 Tccs = 0;
>> > > + chip->onfi_version ? (Tccs = chip->onfi_params.t_ccs)
>> > > + : (Tccs = chip-
>> > > >jedec_params.t_ccs);
>>
>> Please don't put assignments inside a conditional. An if-statement would work
>> just fine here.
>>
>> > > + ifc_out32((IFC_FIR_OP_CW0 << IFC_NAND_FIR0_OP0_SHIFT) |
>> > > + (IFC_FIR_OP_CA0 <<
>> > > IFC_NAND_FIR0_OP1_SHIFT) |
>> > > + (IFC_FIR_OP_CMD1 <<
>> > > IFC_NAND_FIR0_OP2_SHIFT) |
>> > > + (IFC_FIR_OP_NWAIT <<
>> > > IFC_NAND_FIR0_OP3_SHIFT),
>> > > + &ifc->ifc_nand.nand_fir0);
>> > > +
>> > > + ifc_out32((NAND_CMD_RNDOUT << IFC_NAND_FCR0_CMD0_SHIFT) |
>> > > + (NAND_CMD_RNDOUTSTART <<
>> > > IFC_NAND_FCR0_CMD1_SHIFT),
>> > > + &ifc->ifc_nand.nand_fcr0);
>> > > +
>> > > + /* Wait for minimum change column set-up time. But it
>> > > does not harm
>> > > + * to wait more time, so calculated based on 333.3 MHz
>> > > input IFC clock
>> > > + */
>> > Can't you know the clk rate at runtime instead of basing your
>> > calculation on the hypothetic clk rate?
>>
>> If we really need to know the clock rate, we could add a clocks property to
>> the IFC node. But we haven't needed to deal with clocking anywhere else in
>> this driver, so I'm not too happy about introducing it for this.
>
> Will the base clk always be running at the same rate on all designs? To
> me, it sounds a bit risky to do this assumption, but maybe I'm wrong.
>
IFC input clock is divide by 2 platform clock which is fixed in T, P series
and Layerscape series of processors where IFC is used, maximum
platform clock is 600 MHz so IFC input clock becomes 300 MHz maximum.
To avoid floating operation, I chose next possible frequency of
333.33 MHz which gives me period of 3 ns. There was no easy way to find
the input IFC clock without knowing platform clock which requires RCW values.
So, to avoid that I selected this route where we will end up waiting few more
cycles then required but it does not harm. For example, my input IFC clock is
266.66 Mhz and my NAND part tells me to wait minimum 200 ns so I have to
wait for 54 cycles while with this calculation I will be waiting for 66 cycles
which I think won't matter as the data-sheet specifies minimum change column
set-up time.
>> In
>> particular, I don't think we should be sending a real RNDOUT command at the
>> device here -- it breaks the model of self-contained operations. The read
>> command is over and the chipselect has been dropped (do all ONFI chips support
>> "CE don't care"?). If the new offset (plus size to be read) fits within the
>> page buffer, we could just adjust ifc_nand_ctrl->index to the desired
>> location.
>
> It should be supported (releasing the CE after the PARAM command and
> then sending a RNDOUT), but who knows what NAND vendors decide to
> implement.
>
Initially I though of just adjusting the index as we don't do any read operation
again and already we read the required bytes.
So, what should be the final take on this ? Should I just update the index and
avoid sending the change column command at all? Or should I keep the existing
implementation ?
>>
>> OTOH, if we need to read parameter data beyond the size of the page buffer,
>> then we'd need to send another read command (possibly from read_buf)... or we
>> can do the sane thing and introduce an interface function to read a certain
>> number of parameter bytes from a certain offset.
>
> No please, do not add any complex logic in read_buf() (like resending a
> NAND cmd from there), it will just make the whole thing worst.
>
>> Which we should do anyway if
>> we want to move in the direction of a better interface with less cmdfunc
>> abuse.
>
> Not really. Ideally, ->read_buf() should just launch the I/O transfer
> (same for ->write_buf()), nothing more. It shouldn't have to test which
> command was sent before and adapt its behavior.
> Now, I know that some controllers are not able to dissociate the
> CMD/ADDR cycles from the DATA transfers, which is why a new interface
> is needed.
>
>>
>> >
>> > > + ifc_out32((0xFF & (le16_to_cpu(Tccs)/3)), &ifc-
>> > > >ifc_nand.ncfgr);
>> > Why is it done in ->cmdfunc()? I mean, this timing parameter should be
>> > set for all operations, and applied as soon as ->select_chip() is
>> > called.
>>
>> select_chip() is a no-op[1].
>
> Maybe it is in your implementation, but this is where you should have
> all the CHIP specific settings (switching from one NAND chip to another
> requires adapting the timing, setting a new CS line, ...).
> The what the sunxi_nand driver is doing if you want an example where
> the driver is tweaking the timing config at chip selection time.
>
>> IFC normally handles the delays internally when
>> running a command sequence.
>
> Same for a lot of controllers out there, but that doesn't prevent you
> from configuring the timings (on the controller side) when a chip is
> selected.
>
> Note that ->select_chip() is not implying that you assert the CE line,
> it's here to inform your controller driver that the core wants to
> interact with a different NAND chip. What's done in there is completely
> controller dependent.
>
>>
>> -Scott
>>
>> [1] In any case, this is the time between RNDOUT and reading the data, not
>> the time between asserting the chipselect and issuing a command -- and I don't
>> see other drivers doing a delay in select_chip().
>
> It's not about applying the delay in ->select_chip() it's about
> configuring the chip specific timings on the controller side. I guess
> the first byte of the ncfgr register is always encoding the tCCS
> timing, not something different depending on the command that is sent.
> If that's the case, then you don't need to reconfigure the register
> each time you send the RNDOUT command, only once, when you activate a
> chip.
>
> But again, I don't know this controller, so I might be wrong.
NCFGR may be used in future to wait for custom number of clock cycles, so I
don't think it's a good idea to to configure tCCS time into it only
once during init.
>
> Regards,
>
> Boris
>
Best Regards,
Ronak
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