linux/drivers/net/wimax/i2400m/tx.c

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/*
* Intel Wireless WiMAX Connection 2400m
* Generic (non-bus specific) TX handling
*
*
* Copyright (C) 2007-2008 Intel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
* * Neither the name of Intel Corporation nor the names of its
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
*
* Intel Corporation <linux-wimax@intel.com>
* Yanir Lubetkin <yanirx.lubetkin@intel.com>
* - Initial implementation
*
* Intel Corporation <linux-wimax@intel.com>
* Inaky Perez-Gonzalez <inaky.perez-gonzalez@intel.com>
* - Rewritten to use a single FIFO to lower the memory allocation
* pressure and optimize cache hits when copying to the queue, as
* well as splitting out bus-specific code.
*
*
* Implements data transmission to the device; this is done through a
* software FIFO, as data/control frames can be coalesced (while the
* device is reading the previous tx transaction, others accumulate).
*
* A FIFO is used because at the end it is resource-cheaper that trying
* to implement scatter/gather over USB. As well, most traffic is going
* to be download (vs upload).
*
* The format for sending/receiving data to/from the i2400m is
* described in detail in rx.c:PROTOCOL FORMAT. In here we implement
* the transmission of that. This is split between a bus-independent
* part that just prepares everything and a bus-specific part that
* does the actual transmission over the bus to the device (in the
* bus-specific driver).
*
*
* The general format of a device-host transaction is MSG-HDR, PLD1,
* PLD2...PLDN, PL1, PL2,...PLN, PADDING.
*
* Because we need the send payload descriptors and then payloads and
* because it is kind of expensive to do scatterlists in USB (one URB
* per node), it becomes cheaper to append all the data to a FIFO
* (copying to a FIFO potentially in cache is cheaper).
*
* Then the bus-specific code takes the parts of that FIFO that are
* written and passes them to the device.
*
* So the concepts to keep in mind there are:
*
* We use a FIFO to queue the data in a linear buffer. We first append
* a MSG-HDR, space for I2400M_TX_PLD_MAX payload descriptors and then
* go appending payloads until we run out of space or of payload
* descriptors. Then we append padding to make the whole transaction a
* multiple of i2400m->bus_tx_block_size (as defined by the bus layer).
*
* - A TX message: a combination of a message header, payload
* descriptors and payloads.
*
* Open: it is marked as active (i2400m->tx_msg is valid) and we
* can keep adding payloads to it.
*
* Closed: we are not appending more payloads to this TX message
* (exahusted space in the queue, too many payloads or
* whichever). We have appended padding so the whole message
* length is aligned to i2400m->bus_tx_block_size (as set by the
* bus/transport layer).
*
* - Most of the time we keep a TX message open to which we append
* payloads.
*
* - If we are going to append and there is no more space (we are at
* the end of the FIFO), we close the message, mark the rest of the
* FIFO space unusable (skip_tail), create a new message at the
* beginning of the FIFO (if there is space) and append the message
* there.
*
* This is because we need to give linear TX messages to the bus
* engine. So we don't write a message to the remaining FIFO space
* until the tail and continue at the head of it.
*
* - We overload one of the fields in the message header to use it as
* 'size' of the TX message, so we can iterate over them. It also
* contains a flag that indicates if we have to skip it or not.
* When we send the buffer, we update that to its real on-the-wire
* value.
*
* - The MSG-HDR PLD1...PLD2 stuff has to be a size multiple of 16.
*
* It follows that if MSG-HDR says we have N messages, the whole
* header + descriptors is 16 + 4*N; for those to be a multiple of
* 16, it follows that N can be 4, 8, 12, ... (32, 48, 64, 80...
* bytes).
*
* So if we have only 1 payload, we have to submit a header that in
* all truth has space for 4.
*
* The implication is that we reserve space for 12 (64 bytes); but
* if we fill up only (eg) 2, our header becomes 32 bytes only. So
* the TX engine has to shift those 32 bytes of msg header and 2
* payloads and padding so that right after it the payloads start
* and the TX engine has to know about that.
*
* It is cheaper to move the header up than the whole payloads down.
*
* We do this in i2400m_tx_close(). See 'i2400m_msg_hdr->offset'.
*
* - Each payload has to be size-padded to 16 bytes; before appending
* it, we just do it.
*
* - The whole message has to be padded to i2400m->bus_tx_block_size;
* we do this at close time. Thus, when reserving space for the
* payload, we always make sure there is also free space for this
* padding that sooner or later will happen.
*
* When we append a message, we tell the bus specific code to kick in
* TXs. It will TX (in parallel) until the buffer is exhausted--hence
* the lockin we do. The TX code will only send a TX message at the
* time (which remember, might contain more than one payload). Of
* course, when the bus-specific driver attempts to TX a message that
* is still open, it gets closed first.
*
* Gee, this is messy; well a picture. In the example below we have a
* partially full FIFO, with a closed message ready to be delivered
* (with a moved message header to make sure it is size-aligned to
* 16), TAIL room that was unusable (and thus is marked with a message
* header that says 'skip this') and at the head of the buffer, an
* incomplete message with a couple of payloads.
*
* N ___________________________________________________
* | |
* | TAIL room |
* | |
* | msg_hdr to skip (size |= 0x80000) |
* |---------------------------------------------------|-------
* | | /|\
* | | |
* | TX message padding | |
* | | |
* | | |
* |- - - - - - - - - - - - - - - - - - - - - - - - - -| |
* | | |
* | payload 1 | |
* | | N * tx_block_size
* | | |
* |- - - - - - - - - - - - - - - - - - - - - - - - - -| |
* | | |
* | payload 1 | |
* | | |
* | | |
* |- - - - - - - - - - - - - - - - - - - - - - - - - -|- -|- - - -
* | padding 3 /|\ | | /|\
* | padding 2 | | | |
* | pld 1 32 bytes (2 * 16) | | |
* | pld 0 | | | |
* | moved msg_hdr \|/ | \|/ |
* |- - - - - - - - - - - - - - - - - - - - - - - - - -|- - - |
* | | _PLD_SIZE
* | unused | |
* | | |
* |- - - - - - - - - - - - - - - - - - - - - - - - - -| |
* | msg_hdr (size X) [this message is closed] | \|/
* |===================================================|========== <=== OUT
* | |
* | |
* | |
* | Free rooom |
* | |
* | |
* | |
* | |
* | |
* | |
* | |
* | |
* | |
* |===================================================|========== <=== IN
* | |
* | |
* | |
* | |
* | payload 1 |
* | |
* | |
* |- - - - - - - - - - - - - - - - - - - - - - - - - -|
* | |
* | payload 0 |
* | |
* | |
* |- - - - - - - - - - - - - - - - - - - - - - - - - -|
* | pld 11 /|\ |
* | ... | |
* | pld 1 64 bytes (2 * 16) |
* | pld 0 | |
* | msg_hdr (size X) \|/ [message is open] |
* 0 ---------------------------------------------------
*
*
* ROADMAP
*
* i2400m_tx_setup() Called by i2400m_setup
* i2400m_tx_release() Called by i2400m_release()
*
* i2400m_tx() Called to send data or control frames
* i2400m_tx_fifo_push() Allocates append-space in the FIFO
* i2400m_tx_new() Opens a new message in the FIFO
* i2400m_tx_fits() Checks if a new payload fits in the message
* i2400m_tx_close() Closes an open message in the FIFO
* i2400m_tx_skip_tail() Marks unusable FIFO tail space
* i2400m->bus_tx_kick()
*
* Now i2400m->bus_tx_kick() is the the bus-specific driver backend
* implementation; that would do:
*
* i2400m->bus_tx_kick()
* i2400m_tx_msg_get() Gets first message ready to go
* ...sends it...
* i2400m_tx_msg_sent() Ack the message is sent; repeat from
* _tx_msg_get() until it returns NULL
* (FIFO empty).
*/
#include <linux/netdevice.h>
include cleanup: Update gfp.h and slab.h includes to prepare for breaking implicit slab.h inclusion from percpu.h percpu.h is included by sched.h and module.h and thus ends up being included when building most .c files. percpu.h includes slab.h which in turn includes gfp.h making everything defined by the two files universally available and complicating inclusion dependencies. percpu.h -> slab.h dependency is about to be removed. Prepare for this change by updating users of gfp and slab facilities include those headers directly instead of assuming availability. As this conversion needs to touch large number of source files, the following script is used as the basis of conversion. http://userweb.kernel.org/~tj/misc/slabh-sweep.py The script does the followings. * Scan files for gfp and slab usages and update includes such that only the necessary includes are there. ie. if only gfp is used, gfp.h, if slab is used, slab.h. * When the script inserts a new include, it looks at the include blocks and try to put the new include such that its order conforms to its surrounding. It's put in the include block which contains core kernel includes, in the same order that the rest are ordered - alphabetical, Christmas tree, rev-Xmas-tree or at the end if there doesn't seem to be any matching order. * If the script can't find a place to put a new include (mostly because the file doesn't have fitting include block), it prints out an error message indicating which .h file needs to be added to the file. The conversion was done in the following steps. 1. The initial automatic conversion of all .c files updated slightly over 4000 files, deleting around 700 includes and adding ~480 gfp.h and ~3000 slab.h inclusions. The script emitted errors for ~400 files. 2. Each error was manually checked. Some didn't need the inclusion, some needed manual addition while adding it to implementation .h or embedding .c file was more appropriate for others. This step added inclusions to around 150 files. 3. The script was run again and the output was compared to the edits from #2 to make sure no file was left behind. 4. Several build tests were done and a couple of problems were fixed. e.g. lib/decompress_*.c used malloc/free() wrappers around slab APIs requiring slab.h to be added manually. 5. The script was run on all .h files but without automatically editing them as sprinkling gfp.h and slab.h inclusions around .h files could easily lead to inclusion dependency hell. Most gfp.h inclusion directives were ignored as stuff from gfp.h was usually wildly available and often used in preprocessor macros. Each slab.h inclusion directive was examined and added manually as necessary. 6. percpu.h was updated not to include slab.h. 7. Build test were done on the following configurations and failures were fixed. CONFIG_GCOV_KERNEL was turned off for all tests (as my distributed build env didn't work with gcov compiles) and a few more options had to be turned off depending on archs to make things build (like ipr on powerpc/64 which failed due to missing writeq). * x86 and x86_64 UP and SMP allmodconfig and a custom test config. * powerpc and powerpc64 SMP allmodconfig * sparc and sparc64 SMP allmodconfig * ia64 SMP allmodconfig * s390 SMP allmodconfig * alpha SMP allmodconfig * um on x86_64 SMP allmodconfig 8. percpu.h modifications were reverted so that it could be applied as a separate patch and serve as bisection point. Given the fact that I had only a couple of failures from tests on step 6, I'm fairly confident about the coverage of this conversion patch. If there is a breakage, it's likely to be something in one of the arch headers which should be easily discoverable easily on most builds of the specific arch. Signed-off-by: Tejun Heo <tj@kernel.org> Guess-its-ok-by: Christoph Lameter <cl@linux-foundation.org> Cc: Ingo Molnar <mingo@redhat.com> Cc: Lee Schermerhorn <Lee.Schermerhorn@hp.com>
2010-03-24 08:04:11 +00:00
#include <linux/slab.h>
#include <linux/export.h>
#include "i2400m.h"
#define D_SUBMODULE tx
#include "debug-levels.h"
enum {
/**
* TX Buffer size
*
* Doc says maximum transaction is 16KiB. If we had 16KiB en
* route and 16KiB being queued, it boils down to needing
* 32KiB.
* 32KiB is insufficient for 1400 MTU, hence increasing
* tx buffer size to 64KiB.
*/
I2400M_TX_BUF_SIZE = 65536,
/**
* Message header and payload descriptors have to be 16
* aligned (16 + 4 * N = 16 * M). If we take that average sent
* packets are MTU size (~1400-~1500) it follows that we could
* fit at most 10-11 payloads in one transaction. To meet the
* alignment requirement, that means we need to leave space
* for 12 (64 bytes). To simplify, we leave space for that. If
* at the end there are less, we pad up to the nearest
* multiple of 16.
*/
/*
* According to Intel Wimax i3200, i5x50 and i6x50 specification
* documents, the maximum number of payloads per message can be
* up to 60. Increasing the number of payloads to 60 per message
* helps to accommodate smaller payloads in a single transaction.
*/
I2400M_TX_PLD_MAX = 60,
I2400M_TX_PLD_SIZE = sizeof(struct i2400m_msg_hdr)
+ I2400M_TX_PLD_MAX * sizeof(struct i2400m_pld),
I2400M_TX_SKIP = 0x80000000,
/*
* According to Intel Wimax i3200, i5x50 and i6x50 specification
* documents, the maximum size of each message can be up to 16KiB.
*/
I2400M_TX_MSG_SIZE = 16384,
};
#define TAIL_FULL ((void *)~(unsigned long)NULL)
/*
* Calculate how much tail room is available
*
* Note the trick here. This path is ONLY caleed for Case A (see
* i2400m_tx_fifo_push() below), where we have:
*
* Case A
* N ___________
* | tail room |
* | |
* |<- IN ->|
* | |
* | data |
* | |
* |<- OUT ->|
* | |
* | head room |
* 0 -----------
*
* When calculating the tail_room, tx_in might get to be zero if
* i2400m->tx_in is right at the end of the buffer (really full
* buffer) if there is no head room. In this case, tail_room would be
* I2400M_TX_BUF_SIZE, although it is actually zero. Hence the final
* mod (%) operation. However, when doing this kind of optimization,
* i2400m->tx_in being zero would fail, so we treat is an a special
* case.
*/
static inline
size_t __i2400m_tx_tail_room(struct i2400m *i2400m)
{
size_t tail_room;
size_t tx_in;
if (unlikely(i2400m->tx_in == 0))
return I2400M_TX_BUF_SIZE;
tx_in = i2400m->tx_in % I2400M_TX_BUF_SIZE;
tail_room = I2400M_TX_BUF_SIZE - tx_in;
tail_room %= I2400M_TX_BUF_SIZE;
return tail_room;
}
/*
* Allocate @size bytes in the TX fifo, return a pointer to it
*
* @i2400m: device descriptor
* @size: size of the buffer we need to allocate
* @padding: ensure that there is at least this many bytes of free
* contiguous space in the fifo. This is needed because later on
* we might need to add padding.
* @try_head: specify either to allocate head room or tail room space
* in the TX FIFO. This boolean is required to avoids a system hang
* due to an infinite loop caused by i2400m_tx_fifo_push().
* The caller must always try to allocate tail room space first by
* calling this routine with try_head = 0. In case if there
* is not enough tail room space but there is enough head room space,
* (i2400m_tx_fifo_push() returns TAIL_FULL) try to allocate head
* room space, by calling this routine again with try_head = 1.
*
* Returns:
*
* Pointer to the allocated space. NULL if there is no
* space. TAIL_FULL if there is no space at the tail but there is at
* the head (Case B below).
*
* These are the two basic cases we need to keep an eye for -- it is
* much better explained in linux/kernel/kfifo.c, but this code
* basically does the same. No rocket science here.
*
* Case A Case B
* N ___________ ___________
* | tail room | | data |
* | | | |
* |<- IN ->| |<- OUT ->|
* | | | |
* | data | | room |
* | | | |
* |<- OUT ->| |<- IN ->|
* | | | |
* | head room | | data |
* 0 ----------- -----------
*
* We allocate only *contiguous* space.
*
* We can allocate only from 'room'. In Case B, it is simple; in case
* A, we only try from the tail room; if it is not enough, we just
* fail and return TAIL_FULL and let the caller figure out if we wants to
* skip the tail room and try to allocate from the head.
*
* There is a corner case, wherein i2400m_tx_new() can get into
* an infinite loop calling i2400m_tx_fifo_push().
* In certain situations, tx_in would have reached on the top of TX FIFO
* and i2400m_tx_tail_room() returns 0, as described below:
*
* N ___________ tail room is zero
* |<- IN ->|
* | |
* | |
* | |
* | data |
* |<- OUT ->|
* | |
* | |
* | head room |
* 0 -----------
* During such a time, where tail room is zero in the TX FIFO and if there
* is a request to add a payload to TX FIFO, which calls:
* i2400m_tx()
* ->calls i2400m_tx_close()
* ->calls i2400m_tx_skip_tail()
* goto try_new;
* ->calls i2400m_tx_new()
* |----> [try_head:]
* infinite loop | ->calls i2400m_tx_fifo_push()
* | if (tail_room < needed)
* | if (head_room => needed)
* | return TAIL_FULL;
* |<---- goto try_head;
*
* i2400m_tx() calls i2400m_tx_close() to close the message, since there
* is no tail room to accommodate the payload and calls
* i2400m_tx_skip_tail() to skip the tail space. Now i2400m_tx() calls
* i2400m_tx_new() to allocate space for new message header calling
* i2400m_tx_fifo_push() that returns TAIL_FULL, since there is no tail space
* to accommodate the message header, but there is enough head space.
* The i2400m_tx_new() keeps re-retrying by calling i2400m_tx_fifo_push()
* ending up in a loop causing system freeze.
*
* This corner case is avoided by using a try_head boolean,
* as an argument to i2400m_tx_fifo_push().
*
* Note:
*
* Assumes i2400m->tx_lock is taken, and we use that as a barrier
*
* The indexes keep increasing and we reset them to zero when we
* pop data off the queue
*/
static
void *i2400m_tx_fifo_push(struct i2400m *i2400m, size_t size,
size_t padding, bool try_head)
{
struct device *dev = i2400m_dev(i2400m);
size_t room, tail_room, needed_size;
void *ptr;
needed_size = size + padding;
room = I2400M_TX_BUF_SIZE - (i2400m->tx_in - i2400m->tx_out);
if (room < needed_size) { /* this takes care of Case B */
d_printf(2, dev, "fifo push %zu/%zu: no space\n",
size, padding);
return NULL;
}
/* Is there space at the tail? */
tail_room = __i2400m_tx_tail_room(i2400m);
if (!try_head && tail_room < needed_size) {
/*
* If the tail room space is not enough to push the message
* in the TX FIFO, then there are two possibilities:
* 1. There is enough head room space to accommodate
* this message in the TX FIFO.
* 2. There is not enough space in the head room and
* in tail room of the TX FIFO to accommodate the message.
* In the case (1), return TAIL_FULL so that the caller
* can figure out, if the caller wants to push the message
* into the head room space.
* In the case (2), return NULL, indicating that the TX FIFO
* cannot accommodate the message.
*/
if (room - tail_room >= needed_size) {
d_printf(2, dev, "fifo push %zu/%zu: tail full\n",
size, padding);
return TAIL_FULL; /* There might be head space */
} else {
d_printf(2, dev, "fifo push %zu/%zu: no head space\n",
size, padding);
return NULL; /* There is no space */
}
}
ptr = i2400m->tx_buf + i2400m->tx_in % I2400M_TX_BUF_SIZE;
d_printf(2, dev, "fifo push %zu/%zu: at @%zu\n", size, padding,
i2400m->tx_in % I2400M_TX_BUF_SIZE);
i2400m->tx_in += size;
return ptr;
}
/*
* Mark the tail of the FIFO buffer as 'to-skip'
*
* We should never hit the BUG_ON() because all the sizes we push to
* the FIFO are padded to be a multiple of 16 -- the size of *msg
* (I2400M_PL_PAD for the payloads, I2400M_TX_PLD_SIZE for the
* header).
*
* Tail room can get to be zero if a message was opened when there was
* space only for a header. _tx_close() will mark it as to-skip (as it
* will have no payloads) and there will be no more space to flush, so
* nothing has to be done here. This is probably cheaper than ensuring
* in _tx_new() that there is some space for payloads...as we could
* always possibly hit the same problem if the payload wouldn't fit.
*
* Note:
*
* Assumes i2400m->tx_lock is taken, and we use that as a barrier
*
* This path is only taken for Case A FIFO situations [see
* i2400m_tx_fifo_push()]
*/
static
void i2400m_tx_skip_tail(struct i2400m *i2400m)
{
struct device *dev = i2400m_dev(i2400m);
size_t tx_in = i2400m->tx_in % I2400M_TX_BUF_SIZE;
size_t tail_room = __i2400m_tx_tail_room(i2400m);
struct i2400m_msg_hdr *msg = i2400m->tx_buf + tx_in;
if (unlikely(tail_room == 0))
return;
BUG_ON(tail_room < sizeof(*msg));
msg->size = tail_room | I2400M_TX_SKIP;
d_printf(2, dev, "skip tail: skipping %zu bytes @%zu\n",
tail_room, tx_in);
i2400m->tx_in += tail_room;
}
/*
* Check if a skb will fit in the TX queue's current active TX
* message (if there are still descriptors left unused).
*
* Returns:
* 0 if the message won't fit, 1 if it will.
*
* Note:
*
* Assumes a TX message is active (i2400m->tx_msg).
*
* Assumes i2400m->tx_lock is taken, and we use that as a barrier
*/
static
unsigned i2400m_tx_fits(struct i2400m *i2400m)
{
struct i2400m_msg_hdr *msg_hdr = i2400m->tx_msg;
return le16_to_cpu(msg_hdr->num_pls) < I2400M_TX_PLD_MAX;
}
/*
* Start a new TX message header in the queue.
*
* Reserve memory from the base FIFO engine and then just initialize
* the message header.
*
* We allocate the biggest TX message header we might need (one that'd
* fit I2400M_TX_PLD_MAX payloads) -- when it is closed it will be
* 'ironed it out' and the unneeded parts removed.
*
* NOTE:
*
* Assumes that the previous message is CLOSED (eg: either
* there was none or 'i2400m_tx_close()' was called on it).
*
* Assumes i2400m->tx_lock is taken, and we use that as a barrier
*/
static
void i2400m_tx_new(struct i2400m *i2400m)
{
struct device *dev = i2400m_dev(i2400m);
struct i2400m_msg_hdr *tx_msg;
bool try_head = false;
BUG_ON(i2400m->tx_msg != NULL);
/*
* In certain situations, TX queue might have enough space to
* accommodate the new message header I2400M_TX_PLD_SIZE, but
* might not have enough space to accommodate the payloads.
* Adding bus_tx_room_min padding while allocating a new TX message
* increases the possibilities of including at least one payload of the
* size <= bus_tx_room_min.
*/
try_head:
tx_msg = i2400m_tx_fifo_push(i2400m, I2400M_TX_PLD_SIZE,
i2400m->bus_tx_room_min, try_head);
if (tx_msg == NULL)
goto out;
else if (tx_msg == TAIL_FULL) {
i2400m_tx_skip_tail(i2400m);
d_printf(2, dev, "new TX message: tail full, trying head\n");
try_head = true;
goto try_head;
}
memset(tx_msg, 0, I2400M_TX_PLD_SIZE);
tx_msg->size = I2400M_TX_PLD_SIZE;
out:
i2400m->tx_msg = tx_msg;
d_printf(2, dev, "new TX message: %p @%zu\n",
tx_msg, (void *) tx_msg - i2400m->tx_buf);
}
/*
* Finalize the current TX message header
*
* Sets the message header to be at the proper location depending on
* how many descriptors we have (check documentation at the file's
* header for more info on that).
*
* Appends padding bytes to make sure the whole TX message (counting
* from the 'relocated' message header) is aligned to
* tx_block_size. We assume the _append() code has left enough space
* in the FIFO for that. If there are no payloads, just pass, as it
* won't be transferred.
*
* The amount of padding bytes depends on how many payloads are in the
* TX message, as the "msg header and payload descriptors" will be
* shifted up in the buffer.
*/
static
void i2400m_tx_close(struct i2400m *i2400m)
{
struct device *dev = i2400m_dev(i2400m);
struct i2400m_msg_hdr *tx_msg = i2400m->tx_msg;
struct i2400m_msg_hdr *tx_msg_moved;
size_t aligned_size, padding, hdr_size;
void *pad_buf;
unsigned num_pls;
if (tx_msg->size & I2400M_TX_SKIP) /* a skipper? nothing to do */
goto out;
num_pls = le16_to_cpu(tx_msg->num_pls);
/* We can get this situation when a new message was started
* and there was no space to add payloads before hitting the
tail (and taking padding into consideration). */
if (num_pls == 0) {
tx_msg->size |= I2400M_TX_SKIP;
goto out;
}
/* Relocate the message header
*
* Find the current header size, align it to 16 and if we need
* to move it so the tail is next to the payloads, move it and
* set the offset.
*
* If it moved, this header is good only for transmission; the
* original one (it is kept if we moved) is still used to
* figure out where the next TX message starts (and where the
* offset to the moved header is).
*/
hdr_size = sizeof(*tx_msg)
+ le16_to_cpu(tx_msg->num_pls) * sizeof(tx_msg->pld[0]);
hdr_size = ALIGN(hdr_size, I2400M_PL_ALIGN);
tx_msg->offset = I2400M_TX_PLD_SIZE - hdr_size;
tx_msg_moved = (void *) tx_msg + tx_msg->offset;
memmove(tx_msg_moved, tx_msg, hdr_size);
tx_msg_moved->size -= tx_msg->offset;
/*
* Now figure out how much we have to add to the (moved!)
* message so the size is a multiple of i2400m->bus_tx_block_size.
*/
aligned_size = ALIGN(tx_msg_moved->size, i2400m->bus_tx_block_size);
padding = aligned_size - tx_msg_moved->size;
if (padding > 0) {
pad_buf = i2400m_tx_fifo_push(i2400m, padding, 0, 0);
if (unlikely(WARN_ON(pad_buf == NULL
|| pad_buf == TAIL_FULL))) {
/* This should not happen -- append should verify
* there is always space left at least to append
* tx_block_size */
dev_err(dev,
"SW BUG! Possible data leakage from memory the "
"device should not read for padding - "
"size %lu aligned_size %zu tx_buf %p in "
"%zu out %zu\n",
(unsigned long) tx_msg_moved->size,
aligned_size, i2400m->tx_buf, i2400m->tx_in,
i2400m->tx_out);
} else
memset(pad_buf, 0xad, padding);
}
tx_msg_moved->padding = cpu_to_le16(padding);
tx_msg_moved->size += padding;
if (tx_msg != tx_msg_moved)
tx_msg->size += padding;
out:
i2400m->tx_msg = NULL;
}
/**
* i2400m_tx - send the data in a buffer to the device
*
* @buf: pointer to the buffer to transmit
*
* @buf_len: buffer size
*
* @pl_type: type of the payload we are sending.
*
* Returns:
* 0 if ok, < 0 errno code on error (-ENOSPC, if there is no more
* room for the message in the queue).
*
* Appends the buffer to the TX FIFO and notifies the bus-specific
* part of the driver that there is new data ready to transmit.
* Once this function returns, the buffer has been copied, so it can
* be reused.
*
* The steps followed to append are explained in detail in the file
* header.
*
* Whenever we write to a message, we increase msg->size, so it
* reflects exactly how big the message is. This is needed so that if
* we concatenate two messages before they can be sent, the code that
* sends the messages can find the boundaries (and it will replace the
* size with the real barker before sending).
*
* Note:
*
* Cold and warm reset payloads need to be sent as a single
* payload, so we handle that.
*/
int i2400m_tx(struct i2400m *i2400m, const void *buf, size_t buf_len,
enum i2400m_pt pl_type)
{
int result = -ENOSPC;
struct device *dev = i2400m_dev(i2400m);
unsigned long flags;
size_t padded_len;
void *ptr;
bool try_head = false;
unsigned is_singleton = pl_type == I2400M_PT_RESET_WARM
|| pl_type == I2400M_PT_RESET_COLD;
d_fnstart(3, dev, "(i2400m %p skb %p [%zu bytes] pt %u)\n",
i2400m, buf, buf_len, pl_type);
padded_len = ALIGN(buf_len, I2400M_PL_ALIGN);
d_printf(5, dev, "padded_len %zd buf_len %zd\n", padded_len, buf_len);
/* If there is no current TX message, create one; if the
* current one is out of payload slots or we have a singleton,
* close it and start a new one */
spin_lock_irqsave(&i2400m->tx_lock, flags);
/* If tx_buf is NULL, device is shutdown */
if (i2400m->tx_buf == NULL) {
result = -ESHUTDOWN;
goto error_tx_new;
}
try_new:
if (unlikely(i2400m->tx_msg == NULL))
i2400m_tx_new(i2400m);
else if (unlikely(!i2400m_tx_fits(i2400m)
|| (is_singleton && i2400m->tx_msg->num_pls != 0))) {
d_printf(2, dev, "closing TX message (fits %u singleton "
"%u num_pls %u)\n", i2400m_tx_fits(i2400m),
is_singleton, i2400m->tx_msg->num_pls);
i2400m_tx_close(i2400m);
i2400m_tx_new(i2400m);
}
if (i2400m->tx_msg == NULL)
goto error_tx_new;
/*
* Check if this skb will fit in the TX queue's current active
* TX message. The total message size must not exceed the maximum
* size of each message I2400M_TX_MSG_SIZE. If it exceeds,
* close the current message and push this skb into the new message.
*/
if (i2400m->tx_msg->size + padded_len > I2400M_TX_MSG_SIZE) {
d_printf(2, dev, "TX: message too big, going new\n");
i2400m_tx_close(i2400m);
i2400m_tx_new(i2400m);
}
if (i2400m->tx_msg == NULL)
goto error_tx_new;
/* So we have a current message header; now append space for
* the message -- if there is not enough, try the head */
ptr = i2400m_tx_fifo_push(i2400m, padded_len,
i2400m->bus_tx_block_size, try_head);
if (ptr == TAIL_FULL) { /* Tail is full, try head */
d_printf(2, dev, "pl append: tail full\n");
i2400m_tx_close(i2400m);
i2400m_tx_skip_tail(i2400m);
try_head = true;
goto try_new;
} else if (ptr == NULL) { /* All full */
result = -ENOSPC;
d_printf(2, dev, "pl append: all full\n");
} else { /* Got space, copy it, set padding */
struct i2400m_msg_hdr *tx_msg = i2400m->tx_msg;
unsigned num_pls = le16_to_cpu(tx_msg->num_pls);
memcpy(ptr, buf, buf_len);
memset(ptr + buf_len, 0xad, padded_len - buf_len);
i2400m_pld_set(&tx_msg->pld[num_pls], buf_len, pl_type);
d_printf(3, dev, "pld 0x%08x (type 0x%1x len 0x%04zx\n",
le32_to_cpu(tx_msg->pld[num_pls].val),
pl_type, buf_len);
tx_msg->num_pls = le16_to_cpu(num_pls+1);
tx_msg->size += padded_len;
d_printf(2, dev, "TX: appended %zu b (up to %u b) pl #%u\n",
padded_len, tx_msg->size, num_pls+1);
d_printf(2, dev,
"TX: appended hdr @%zu %zu b pl #%u @%zu %zu/%zu b\n",
(void *)tx_msg - i2400m->tx_buf, (size_t)tx_msg->size,
num_pls+1, ptr - i2400m->tx_buf, buf_len, padded_len);
result = 0;
if (is_singleton)
i2400m_tx_close(i2400m);
}
error_tx_new:
spin_unlock_irqrestore(&i2400m->tx_lock, flags);
/* kick in most cases, except when the TX subsys is down, as
* it might free space */
if (likely(result != -ESHUTDOWN))
i2400m->bus_tx_kick(i2400m);
d_fnend(3, dev, "(i2400m %p skb %p [%zu bytes] pt %u) = %d\n",
i2400m, buf, buf_len, pl_type, result);
return result;
}
EXPORT_SYMBOL_GPL(i2400m_tx);
/**
* i2400m_tx_msg_get - Get the first TX message in the FIFO to start sending it
*
* @i2400m: device descriptors
* @bus_size: where to place the size of the TX message
*
* Called by the bus-specific driver to get the first TX message at
* the FIF that is ready for transmission.
*
* It sets the state in @i2400m to indicate the bus-specific driver is
* transferring that message (i2400m->tx_msg_size).
*
* Once the transfer is completed, call i2400m_tx_msg_sent().
*
* Notes:
*
* The size of the TX message to be transmitted might be smaller than
* that of the TX message in the FIFO (in case the header was
* shorter). Hence, we copy it in @bus_size, for the bus layer to
* use. We keep the message's size in i2400m->tx_msg_size so that
* when the bus later is done transferring we know how much to
* advance the fifo.
*
* We collect statistics here as all the data is available and we
* assume it is going to work [see i2400m_tx_msg_sent()].
*/
struct i2400m_msg_hdr *i2400m_tx_msg_get(struct i2400m *i2400m,
size_t *bus_size)
{
struct device *dev = i2400m_dev(i2400m);
struct i2400m_msg_hdr *tx_msg, *tx_msg_moved;
unsigned long flags, pls;
d_fnstart(3, dev, "(i2400m %p bus_size %p)\n", i2400m, bus_size);
spin_lock_irqsave(&i2400m->tx_lock, flags);
tx_msg_moved = NULL;
if (i2400m->tx_buf == NULL)
goto out_unlock;
skip:
tx_msg_moved = NULL;
if (i2400m->tx_in == i2400m->tx_out) { /* Empty FIFO? */
i2400m->tx_in = 0;
i2400m->tx_out = 0;
d_printf(2, dev, "TX: FIFO empty: resetting\n");
goto out_unlock;
}
tx_msg = i2400m->tx_buf + i2400m->tx_out % I2400M_TX_BUF_SIZE;
if (tx_msg->size & I2400M_TX_SKIP) { /* skip? */
d_printf(2, dev, "TX: skip: msg @%zu (%zu b)\n",
i2400m->tx_out % I2400M_TX_BUF_SIZE,
(size_t) tx_msg->size & ~I2400M_TX_SKIP);
i2400m->tx_out += tx_msg->size & ~I2400M_TX_SKIP;
goto skip;
}
if (tx_msg->num_pls == 0) { /* No payloads? */
if (tx_msg == i2400m->tx_msg) { /* open, we are done */
d_printf(2, dev,
"TX: FIFO empty: open msg w/o payloads @%zu\n",
(void *) tx_msg - i2400m->tx_buf);
tx_msg = NULL;
goto out_unlock;
} else { /* closed, skip it */
d_printf(2, dev,
"TX: skip msg w/o payloads @%zu (%zu b)\n",
(void *) tx_msg - i2400m->tx_buf,
(size_t) tx_msg->size);
i2400m->tx_out += tx_msg->size & ~I2400M_TX_SKIP;
goto skip;
}
}
if (tx_msg == i2400m->tx_msg) /* open msg? */
i2400m_tx_close(i2400m);
/* Now we have a valid TX message (with payloads) to TX */
tx_msg_moved = (void *) tx_msg + tx_msg->offset;
i2400m->tx_msg_size = tx_msg->size;
*bus_size = tx_msg_moved->size;
d_printf(2, dev, "TX: pid %d msg hdr at @%zu offset +@%zu "
"size %zu bus_size %zu\n",
current->pid, (void *) tx_msg - i2400m->tx_buf,
(size_t) tx_msg->offset, (size_t) tx_msg->size,
(size_t) tx_msg_moved->size);
tx_msg_moved->barker = le32_to_cpu(I2400M_H2D_PREVIEW_BARKER);
tx_msg_moved->sequence = le32_to_cpu(i2400m->tx_sequence++);
pls = le32_to_cpu(tx_msg_moved->num_pls);
i2400m->tx_pl_num += pls; /* Update stats */
if (pls > i2400m->tx_pl_max)
i2400m->tx_pl_max = pls;
if (pls < i2400m->tx_pl_min)
i2400m->tx_pl_min = pls;
i2400m->tx_num++;
i2400m->tx_size_acc += *bus_size;
if (*bus_size < i2400m->tx_size_min)
i2400m->tx_size_min = *bus_size;
if (*bus_size > i2400m->tx_size_max)
i2400m->tx_size_max = *bus_size;
out_unlock:
spin_unlock_irqrestore(&i2400m->tx_lock, flags);
d_fnstart(3, dev, "(i2400m %p bus_size %p [%zu]) = %p\n",
i2400m, bus_size, *bus_size, tx_msg_moved);
return tx_msg_moved;
}
EXPORT_SYMBOL_GPL(i2400m_tx_msg_get);
/**
* i2400m_tx_msg_sent - indicate the transmission of a TX message
*
* @i2400m: device descriptor
*
* Called by the bus-specific driver when a message has been sent;
* this pops it from the FIFO; and as there is space, start the queue
* in case it was stopped.
*
* Should be called even if the message send failed and we are
* dropping this TX message.
*/
void i2400m_tx_msg_sent(struct i2400m *i2400m)
{
unsigned n;
unsigned long flags;
struct device *dev = i2400m_dev(i2400m);
d_fnstart(3, dev, "(i2400m %p)\n", i2400m);
spin_lock_irqsave(&i2400m->tx_lock, flags);
if (i2400m->tx_buf == NULL)
goto out_unlock;
i2400m->tx_out += i2400m->tx_msg_size;
d_printf(2, dev, "TX: sent %zu b\n", (size_t) i2400m->tx_msg_size);
i2400m->tx_msg_size = 0;
BUG_ON(i2400m->tx_out > i2400m->tx_in);
/* level them FIFO markers off */
n = i2400m->tx_out / I2400M_TX_BUF_SIZE;
i2400m->tx_out %= I2400M_TX_BUF_SIZE;
i2400m->tx_in -= n * I2400M_TX_BUF_SIZE;
out_unlock:
spin_unlock_irqrestore(&i2400m->tx_lock, flags);
d_fnend(3, dev, "(i2400m %p) = void\n", i2400m);
}
EXPORT_SYMBOL_GPL(i2400m_tx_msg_sent);
/**
* i2400m_tx_setup - Initialize the TX queue and infrastructure
*
* Make sure we reset the TX sequence to zero, as when this function
* is called, the firmware has been just restarted. Same rational
* for tx_in, tx_out, tx_msg_size and tx_msg. We reset them since
* the memory for TX queue is reallocated.
*/
int i2400m_tx_setup(struct i2400m *i2400m)
{
int result = 0;
void *tx_buf;
unsigned long flags;
/* Do this here only once -- can't do on
* i2400m_hard_start_xmit() as we'll cause race conditions if
* the WS was scheduled on another CPU */
INIT_WORK(&i2400m->wake_tx_ws, i2400m_wake_tx_work);
tx_buf = kmalloc(I2400M_TX_BUF_SIZE, GFP_ATOMIC);
if (tx_buf == NULL) {
result = -ENOMEM;
goto error_kmalloc;
}
/*
* Fail the build if we can't fit at least two maximum size messages
* on the TX FIFO [one being delivered while one is constructed].
*/
BUILD_BUG_ON(2 * I2400M_TX_MSG_SIZE > I2400M_TX_BUF_SIZE);
spin_lock_irqsave(&i2400m->tx_lock, flags);
i2400m->tx_sequence = 0;
i2400m->tx_in = 0;
i2400m->tx_out = 0;
i2400m->tx_msg_size = 0;
i2400m->tx_msg = NULL;
i2400m->tx_buf = tx_buf;
spin_unlock_irqrestore(&i2400m->tx_lock, flags);
/* Huh? the bus layer has to define this... */
BUG_ON(i2400m->bus_tx_block_size == 0);
error_kmalloc:
return result;
}
/**
* i2400m_tx_release - Tear down the TX queue and infrastructure
*/
void i2400m_tx_release(struct i2400m *i2400m)
{
unsigned long flags;
spin_lock_irqsave(&i2400m->tx_lock, flags);
kfree(i2400m->tx_buf);
i2400m->tx_buf = NULL;
spin_unlock_irqrestore(&i2400m->tx_lock, flags);
}