trying to use disk_add_alias() to make spi* an alias for mx25l*. It turns
out disk_add_alias() works for partitions, but not slices, and that's hard
to fix.
This change is, in effect, a partial revert of r344526.
The mips world relies on the existence of flashmap names formatted as
/dev/flash/spi0s.name, whereas pretty much nothing relies on at45d devices
using the /dev/spi* names (because until recently the at45d driver didn't
even work reliably). So this change makes mx25l devices the sole owner of
the /dev/flash/spi* namespace, which actually makes some sense because it is
a SpiFlash(tm) device, so flash/spi isn't a horrible name.
Reported by: Mori Hiroki <yamori813@yahoo.co.jp>
FDT data. The sector size must be a multiple of the device's page size.
If not configured, use the historical default of the device page size.
Setting the disk sector size to 512 or 4096 allows a variety of standard
filesystems to be used on the device. Of course you wouldn't want to be
writing frequently to a SPI flash chip like it was a disk drive, but for
data that gets written once (or rarely) and read often, using a standard
filesystem is a nice convenient thing.
some #define'd names to be more descriptive. When reporting a post-write
compare failure, report the page number, not the byte address of the page.
The latter is the only functional change, it makes the number match the
words of the error message.
This is especially important for writes. SPI is inherently a bidirectional
bus; you receive data (even if it's garbage) while writing. We should not
receive that data into the same buffer we're writing to the device.
When reading it doesn't matter what we send to the device, but using the
dummy buffer for that as well is pleasingly symmetrical.
Both SpiFlash (mx25l) and DataFlash (at45d) drivers create a disk device
with a name of /dev/flash/spiN where N is the driver's unit number. If
both types of devices are present in the same system, this creates a fatal
conflict that prevents attachment of whichever device attaches second
(because mx25l0 and at45d0 both try to create a spi0).
This gives each type of device a unique name (mx25lN or at45dN respectively)
and also adds an alias of spiN for compatibility. When both device types
appear in the same system, only the first to attach gets the spiN alias.
When the second device attaches there is a non-fatal warning that the alias
can't be created, but both devices are still accessible via their primary
names (and there is no need for the spiN name to work for backwards
compatibility on such a system, because it has never been possible to use
the spiN names when both devices exist).
jedec ID as its older cousin the AT45DB642D, but uses a different page size.
The only way to distinguish between the two chips is that the 2D chip has
0 bytes of extended ID info and the new 1E has 1 byte of extended ID. The
actual value of the extended ID byte is all zeroes. In other words, it's
the presence of the extended info that identifies this chip. (Presumably
a future upgrade might define non-zero values for the extended ID byte.)
to match a chip to our table of metadata describing the chips. At least one
new DataFlash chip has a 3-byte jedec ID identical to its predecessors and
differs only in the extended info, and it has different metadata requiring a
unique entry in the table. This paves the way for supporting such chips.
The metadata table now includes two new fields, extmask and extid. The two
bytes of extended info obtained from the chip are ANDed with extmask then
compared to extid, so it's possible to use only a subset of the extended
info in the matching.
We now always read 6 bytes of jedec ID info. Most chips don't return any
extended info, and the values read back for those two bytes may be
indeterminate, but such chips have extmask and extid values of 0x0000 in the
table, so the extid effectively doesn't participate in the matching on those
chips and it doesn't matter what they return in the extended info bytes.
in the delayed attach to use early returns, which allows reducing the level
of indentation. So all in all, what looks like a lot of changes is really
no change in behavior, mostly just moving whitespace around.
Intel® Arria® 10 SoC.
Cadence Quad SPI Flash is not generic SPI controller, but SPI flash
controller, so don't use spibus here, instead provide quad spi flash
interface.
Since it is not on spibus, then mx25l flash device driver is not usable
here, so provide new n25q flash device driver with quad spi flash
interface.
Sponsored by: DARPA, AFRL
Differential Revision: https://reviews.freebsd.org/D10245
about the chip including the erase block size at attach time.
Also add myself to the copyrights since at this point svn blame would point
to me as the culprit for much of this.
all over the place. Also pass the softc as the arg to all the internal
functions instead of passing a device_t and calling device_get_softc() in
each function.
before starting them.
Using the wait-before logic would make sense if there was useful time-
consuming work that could be done between the end of one write and the
beginning of the next, but it also requires doing the wait-for-ready before
reading, because a prior write or erase could still be in progress. Reading
is the far more common case, so adding a whole extra bus transaction to
check for ready before each read would soak up any small gains that might be
had from doing async writes.
for the same condition that the preceeding lines checked for and would have
returned EIO, so the assert could never possibly trigger (sc_sectorsize must
inherently be an integer multiple of FLASH_PAGE_SIZE).
transfers data in both directions at once. When writing to the device,
use a dummy buffer for the incoming data, not the same buffer as the
outgoing data. Writes are done in FLASH_PAGE_SIZE chunks, which is only
256 bytes, so just put the dummy buffer into the softc.
Mainly focus on files that use BSD 2-Clause license, however the tool I
was using misidentified many licenses so this was mostly a manual - error
prone - task.
The Software Package Data Exchange (SPDX) group provides a specification
to make it easier for automated tools to detect and summarize well known
opensource licenses. We are gradually adopting the specification, noting
that the tags are considered only advisory and do not, in any way,
superceed or replace the license texts.
If we cannot establish compatibility by only looking at the compat_data we
also check the flash_devices structure's names for a compatible device.
Approved by: adrian (mentor)
Sponsored by: Smartcom - Bulgaria AD
Differential Revision: https://reviews.freebsd.org/D6026
No functional change, only trivial cases are done in this sweep,
Drivers that can get further enhancements will be done independently.
Discussed in: freebsd-current
A lot of dts files define the SPI flashes supported by mx25l as
compatible with 'jedec,spi-nor', so we add this to the mx25l
compat_data.
Approved by: adrian (mentor)
Sponsored by: Smartcom - Bulgaria AD
Differential Revision: https://reviews.freebsd.org/D5962
Introduce 2 new flags:
- FL_ENABLE_4B_ADDR (forces the use of 4-byte addresses)
- FL_DISABLE_4B_ADDR (forces the use of 3-byte addresses)
If an SPI flash chip is defined with FL_ENABLE_4B_ADDR in its flags,
then an 'Enter 4-byte mode' command is sent to the chip at attach time
and, later, all commands that require addressing are issued with 4-byte
addresses.
If an SPI flash chip is defined with FL_DISABLE_4B_ADDR in its flags,
then an 'Exit 4-byte mode' command is sent to the chip at attach time
and, later, all commands that require addressing are issued with 3-byte
addresses.
For chips that do not have any of these flags defined the behaviour is
unchanged.
This change also adds support for the MX25L25735F and MX25L25635E chips
(vendor id 0xc2, device id 0x2019), which support 4-byte mode and enables
4-byte mode for them. These are 256Mbit devices (32MiB) and, as such, can
only be fully addressed by using 4-byte addresses.
Approved by: adrian (mentor)
Sponsored by: Smartcom - Bulgaria AD
Differential Revision: https://reviews.freebsd.org/D5808
This teaches the mx25l driver (sys/dev/flash/mx25l.c) to interact with
sys/dev/fdt/fdt_slicer.c and sys/geom/geom_flashmap.c.
This allows systems with SPI flash to benefit from the possibility to define
flash 'slices' via FDT, just the same way that it's currently possible for
CFI and NAND flashes.
Tested:
* Carambola 2, AR9331 + SPI NOR flash
PR: kern/206227
Submitted by: Stanislav Galabov <sgalabov@gmail.com>