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/*
* Copyright (c) 2001-2002 by David Brownell
*
* This program is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License as published by the
* Free Software Foundation; either version 2 of the License, or (at your
* option) any later version.
*
* 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.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software Foundation,
* Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*/
/* this file is part of ehci-hcd.c */
/*-------------------------------------------------------------------------*/
/*
* EHCI scheduled transaction support: interrupt, iso, split iso
* These are called "periodic" transactions in the EHCI spec.
*
* Note that for interrupt transfers, the QH/QTD manipulation is shared
* with the "asynchronous" transaction support (control/bulk transfers).
* The only real difference is in how interrupt transfers are scheduled.
* We get some funky API restrictions from the current URB model, which
* works notably better for reading transfers than for writing. (And
* which accordingly needs to change before it'll work inside devices,
* or with "USB On The Go" additions to USB 2.0 ...)
*/
static int ehci_get_frame
(struct usb_hcd
*hcd
);
/*-------------------------------------------------------------------------*/
/*
* periodic_next_shadow - return "next" pointer on shadow list
* @periodic: host pointer to qh/itd/sitd
* @tag: hardware tag for type of this record
*/
static union ehci_shadow
*
periodic_next_shadow
(union ehci_shadow
*periodic
, int tag
)
{
switch (tag
) {
case Q_TYPE_QH
:
return &periodic
->qh
->qh_next
;
case Q_TYPE_FSTN
:
return &periodic
->fstn
->fstn_next
;
case Q_TYPE_ITD
:
return &periodic
->itd
->itd_next
;
#ifdef have_split_iso
case Q_TYPE_SITD
:
return &periodic
->sitd
->sitd_next
;
#endif /* have_split_iso */
}
dbg
("BAD shadow %p tag %d", periodic
->ptr
, tag
);
// BUG ();
return 0;
}
/* returns true after successful unlink */
/* caller must hold ehci->lock */
static int periodic_unlink
(struct ehci_hcd
*ehci
, unsigned frame
, void *ptr
)
{
union ehci_shadow
*prev_p
= &ehci
->pshadow
[frame
];
u32
*hw_p
= &ehci
->periodic
[frame
];
union ehci_shadow here
= *prev_p
;
union ehci_shadow
*next_p
;
/* find predecessor of "ptr"; hw and shadow lists are in sync */
while (here.
ptr && here.
ptr != ptr
) {
prev_p
= periodic_next_shadow
(prev_p
, Q_NEXT_TYPE
(*hw_p
));
hw_p
= &here.
qh->hw_next
;
here
= *prev_p
;
}
/* an interrupt entry (at list end) could have been shared */
if (!here.
ptr) {
dbg
("entry %p no longer on frame [%d]", ptr
, frame
);
return 0;
}
// vdbg ("periodic unlink %p from frame %d", ptr, frame);
/* update hardware list ... HC may still know the old structure, so
* don't change hw_next until it'll have purged its cache
*/
next_p
= periodic_next_shadow
(&here
, Q_NEXT_TYPE
(*hw_p
));
*hw_p
= here.
qh->hw_next
;
/* unlink from shadow list; HCD won't see old structure again */
*prev_p
= *next_p
;
next_p
->ptr
= 0;
return 1;
}
/* how many of the uframe's 125 usecs are allocated? */
static unsigned short
periodic_usecs
(struct ehci_hcd
*ehci
, unsigned frame
, unsigned uframe
)
{
u32
*hw_p
= &ehci
->periodic
[frame
];
union ehci_shadow
*q
= &ehci
->pshadow
[frame
];
unsigned usecs
= 0;
while (q
->ptr
) {
switch (Q_NEXT_TYPE
(*hw_p
)) {
case Q_TYPE_QH
:
/* is it in the S-mask? */
if (q
->qh
->hw_info2
& cpu_to_le32
(1 << uframe
))
usecs
+= q
->qh
->usecs
;
/* ... or C-mask? */
if (q
->qh
->hw_info2
& cpu_to_le32
(1 << (8 + uframe
)))
usecs
+= q
->qh
->c_usecs
;
q
= &q
->qh
->qh_next
;
break;
case Q_TYPE_FSTN
:
/* for "save place" FSTNs, count the relevant INTR
* bandwidth from the previous frame
*/
if (q
->fstn
->hw_prev
!= EHCI_LIST_END
) {
dbg
("not counting FSTN bandwidth yet ...");
}
q
= &q
->fstn
->fstn_next
;
break;
case Q_TYPE_ITD
:
/* NOTE the "one uframe per itd" policy */
if (q
->itd
->hw_transaction
[uframe
] != 0)
usecs
+= q
->itd
->usecs
;
q
= &q
->itd
->itd_next
;
break;
#ifdef have_split_iso
case Q_TYPE_SITD
:
temp
= q
->sitd
->hw_fullspeed_ep
&
__constant_cpu_to_le32
(1 << 31);
// FIXME: this doesn't count data bytes right...
/* is it in the S-mask? (count SPLIT, DATA) */
if (q
->sitd
->hw_uframe
& cpu_to_le32
(1 << uframe
)) {
if (temp
)
usecs
+= HS_USECS
(188);
else
usecs
+= HS_USECS
(1);
}
/* ... C-mask? (count CSPLIT, DATA) */
if (q
->sitd
->hw_uframe
&
cpu_to_le32
(1 << (8 + uframe
))) {
if (temp
)
usecs
+= HS_USECS
(0);
else
usecs
+= HS_USECS
(188);
}
q
= &q
->sitd
->sitd_next
;
break;
#endif /* have_split_iso */
default:
BUG
();
}
}
#ifdef DEBUG
if (usecs
> 100)
err
("overallocated uframe %d, periodic is %d usecs",
frame
* 8 + uframe
, usecs
);
#endif
return usecs
;
}
/*-------------------------------------------------------------------------*/
static int enable_periodic
(struct ehci_hcd
*ehci
)
{
u32 cmd
;
int status
;
/* did clearing PSE did take effect yet?
* takes effect only at frame boundaries...
*/
status
= handshake
(&ehci
->regs
->status
, STS_PSS
, 0, 9 * 125);
if (status
!= 0) {
ehci
->hcd.
state = USB_STATE_HALT
;
return status
;
}
cmd
= readl
(&ehci
->regs
->command
) | CMD_PSE
;
writel
(cmd
, &ehci
->regs
->command
);
/* posted write ... PSS happens later */
ehci
->hcd.
state = USB_STATE_RUNNING
;
/* make sure ehci_work scans these */
ehci
->next_uframe
= readl
(&ehci
->regs
->frame_index
)
% (ehci
->periodic_size
<< 3);
return 0;
}
static int disable_periodic
(struct ehci_hcd
*ehci
)
{
u32 cmd
;
int status
;
/* did setting PSE not take effect yet?
* takes effect only at frame boundaries...
*/
status
= handshake
(&ehci
->regs
->status
, STS_PSS
, STS_PSS
, 9 * 125);
if (status
!= 0) {
ehci
->hcd.
state = USB_STATE_HALT
;
return status
;
}
cmd
= readl
(&ehci
->regs
->command
) & ~CMD_PSE
;
writel
(cmd
, &ehci
->regs
->command
);
/* posted write ... */
ehci
->next_uframe
= -1;
return 0;
}
/*-------------------------------------------------------------------------*/
// FIXME microframe periods not yet handled
static void intr_deschedule
(
struct ehci_hcd
*ehci
,
struct ehci_qh
*qh
,
int wait
) {
int status
;
unsigned frame
= qh
->start
;
do {
periodic_unlink
(ehci
, frame
, qh
);
qh_put
(ehci
, qh
);
frame
+= qh
->period
;
} while (frame
< ehci
->periodic_size
);
qh
->qh_state
= QH_STATE_UNLINK
;
qh
->qh_next.
ptr = 0;
ehci
->periodic_sched
--;
/* maybe turn off periodic schedule */
if (!ehci
->periodic_sched
)
status
= disable_periodic
(ehci
);
else {
status
= 0;
vdbg
("periodic schedule still enabled");
}
/*
* If the hc may be looking at this qh, then delay a uframe
* (yeech!) to be sure it's done.
* No other threads may be mucking with this qh.
*/
if (((ehci_get_frame
(&ehci
->hcd
) - frame
) % qh
->period
) == 0) {
if (wait
) {
udelay
(125);
qh
->hw_next
= EHCI_LIST_END
;
} else {
/* we may not be IDLE yet, but if the qh is empty
* the race is very short. then if qh also isn't
* rescheduled soon, it won't matter. otherwise...
*/
vdbg
("intr_deschedule...");
}
} else
qh
->hw_next
= EHCI_LIST_END
;
qh
->qh_state
= QH_STATE_IDLE
;
/* update per-qh bandwidth utilization (for usbfs) */
hcd_to_bus
(&ehci
->hcd
)->bandwidth_allocated
-=
(qh
->usecs
+ qh
->c_usecs
) / qh
->period
;
dbg
("descheduled qh %p, period = %d frame = %d count = %d, urbs = %d",
qh
, qh
->period
, frame
,
atomic_read
(&qh
->refcount
), ehci
->periodic_sched
);
}
static int check_period
(
struct ehci_hcd
*ehci
,
unsigned frame
,
unsigned uframe
,
unsigned period
,
unsigned usecs
) {
/* complete split running into next frame?
* given FSTN support, we could sometimes check...
*/
if (uframe
>= 8)
return 0;
/*
* 80% periodic == 100 usec/uframe available
* convert "usecs we need" to "max already claimed"
*/
usecs
= 100 - usecs
;
do {
int claimed
;
// FIXME delete when intr_submit handles non-empty queues
// this gives us a one intr/frame limit (vs N/uframe)
// ... and also lets us avoid tracking split transactions
// that might collide at a given TT/hub.
if (ehci
->pshadow
[frame
].
ptr)
return 0;
claimed
= periodic_usecs
(ehci
, frame
, uframe
);
if (claimed
> usecs
)
return 0;
// FIXME update to handle sub-frame periods
} while ((frame
+= period
) < ehci
->periodic_size
);
// success!
return 1;
}
static int check_intr_schedule
(
struct ehci_hcd
*ehci
,
unsigned frame
,
unsigned uframe
,
const struct ehci_qh
*qh
,
u32
*c_maskp
)
{
int retval
= -ENOSPC
;
if (!check_period
(ehci
, frame
, uframe
, qh
->period
, qh
->usecs
))
goto done
;
if (!qh
->c_usecs
) {
retval
= 0;
*c_maskp
= cpu_to_le32
(0);
goto done
;
}
/* This is a split transaction; check the bandwidth available for
* the completion too. Check both worst and best case gaps: worst
* case is SPLIT near uframe end, and CSPLIT near start ... best is
* vice versa. Difference can be almost two uframe times, but we
* reserve unnecessary bandwidth (waste it) this way. (Actually
* even better cases exist, like immediate device NAK.)
*
* FIXME don't even bother unless we know this TT is idle in that
* range of uframes ... for now, check_period() allows only one
* interrupt transfer per frame, so needn't check "TT busy" status
* when scheduling a split (QH, SITD, or FSTN).
*
* FIXME ehci 0.96 and above can use FSTNs
*/
if (!check_period
(ehci
, frame
, uframe
+ qh
->gap_uf
+ 1,
qh
->period
, qh
->c_usecs
))
goto done
;
if (!check_period
(ehci
, frame
, uframe
+ qh
->gap_uf
,
qh
->period
, qh
->c_usecs
))
goto done
;
*c_maskp
= cpu_to_le32
(0x03 << (8 + uframe
+ qh
->gap_uf
));
retval
= 0;
done
:
return retval
;
}
static int qh_schedule
(struct ehci_hcd
*ehci
, struct ehci_qh
*qh
)
{
int status
;
unsigned uframe
;
u32 c_mask
;
unsigned frame
; /* 0..(qh->period - 1), or NO_FRAME */
qh
->hw_next
= EHCI_LIST_END
;
frame
= qh
->start
;
/* reuse the previous schedule slots, if we can */
if (frame
< qh
->period
) {
uframe
= ffs
(le32_to_cpup
(&qh
->hw_info2
) & 0x00ff);
status
= check_intr_schedule
(ehci
, frame
, --uframe
,
qh
, &c_mask
);
} else {
uframe
= 0;
c_mask
= 0;
status
= -ENOSPC
;
}
/* else scan the schedule to find a group of slots such that all
* uframes have enough periodic bandwidth available.
*/
if (status
) {
frame
= qh
->period
- 1;
do {
for (uframe
= 0; uframe
< 8; uframe
++) {
status
= check_intr_schedule
(ehci
,
frame
, uframe
, qh
,
&c_mask
);
if (status
== 0)
break;
}
} while (status
&& frame
--);
if (status
)
goto done
;
qh
->start
= frame
;
/* reset S-frame and (maybe) C-frame masks */
qh
->hw_info2
&= ~
0xffff;
qh
->hw_info2
|= cpu_to_le32
(1 << uframe
) | c_mask
;
} else
dbg
("reused previous qh %p schedule", qh
);
/* stuff into the periodic schedule */
qh
->qh_state
= QH_STATE_LINKED
;
dbg
("scheduled qh %p usecs %d/%d period %d.0 starting %d.%d (gap %d)",
qh
, qh
->usecs
, qh
->c_usecs
,
qh
->period
, frame
, uframe
, qh
->gap_uf
);
do {
if (unlikely
(ehci
->pshadow
[frame
].
ptr != 0)) {
// FIXME -- just link toward the end, before any qh with a shorter period,
// AND accommodate it already having been linked here (after some other qh)
// AS WELL AS updating the schedule checking logic
BUG
();
} else {
ehci
->pshadow
[frame
].
qh = qh_get
(qh
);
ehci
->periodic
[frame
] =
QH_NEXT
(qh
->qh_dma
);
}
wmb
();
frame
+= qh
->period
;
} while (frame
< ehci
->periodic_size
);
/* update per-qh bandwidth for usbfs */
hcd_to_bus
(&ehci
->hcd
)->bandwidth_allocated
+=
(qh
->usecs
+ qh
->c_usecs
) / qh
->period
;
/* maybe enable periodic schedule processing */
if (!ehci
->periodic_sched
++)
status
= enable_periodic
(ehci
);
done
:
return status
;
}
static int intr_submit
(
struct ehci_hcd
*ehci
,
struct urb
*urb
,
struct list_head
*qtd_list
,
int mem_flags
) {
unsigned epnum
;
unsigned long flags
;
struct ehci_qh
*qh
;
struct hcd_dev
*dev
;
int is_input
;
int status
= 0;
struct list_head empty
;
/* get endpoint and transfer/schedule data */
epnum
= usb_pipeendpoint
(urb
->pipe
);
is_input
= usb_pipein
(urb
->pipe
);
if (is_input
)
epnum
|= 0x10;
spin_lock_irqsave
(&ehci
->lock
, flags
);
dev
= (struct hcd_dev
*)urb
->dev
->hcpriv
;
/* get qh and force any scheduling errors */
INIT_LIST_HEAD
(&empty
);
qh
= qh_append_tds
(ehci
, urb
, &empty
, epnum
, &dev
->ep
[epnum
]);
if (qh
== 0) {
status
= -ENOMEM
;
goto done
;
}
if (qh
->qh_state
== QH_STATE_IDLE
) {
if ((status
= qh_schedule
(ehci
, qh
)) != 0)
goto done
;
}
/* then queue the urb's tds to the qh */
qh
= qh_append_tds
(ehci
, urb
, qtd_list
, epnum
, &dev
->ep
[epnum
]);
BUG_ON
(qh
== 0);
/* ... update usbfs periodic stats */
hcd_to_bus
(&ehci
->hcd
)->bandwidth_int_reqs
++;
done
:
spin_unlock_irqrestore
(&ehci
->lock
, flags
);
if (status
)
qtd_list_free
(ehci
, urb
, qtd_list
);
return status
;
}
static unsigned
intr_complete
(
struct ehci_hcd
*ehci
,
unsigned frame
,
struct ehci_qh
*qh
,
struct pt_regs
*regs
) {
unsigned count
;
/* nothing to report? */
if (likely
((qh
->hw_token
& __constant_cpu_to_le32
(QTD_STS_ACTIVE
))
!= 0))
return 0;
if (unlikely
(list_empty
(&qh
->qtd_list
))) {
dbg
("intr qh %p no TDs?", qh
);
return 0;
}
/* handle any completions */
count
= qh_completions
(ehci
, qh
, regs
);
if (unlikely
(list_empty
(&qh
->qtd_list
)))
intr_deschedule
(ehci
, qh
, 0);
return count
;
}
/*-------------------------------------------------------------------------*/
static void
itd_free_list
(struct ehci_hcd
*ehci
, struct urb
*urb
)
{
struct ehci_itd
*first_itd
= urb
->hcpriv
;
while (!list_empty
(&first_itd
->itd_list
)) {
struct ehci_itd
*itd
;
itd
= list_entry
(
first_itd
->itd_list.
next,
struct ehci_itd
, itd_list
);
list_del
(&itd
->itd_list
);
pci_pool_free
(ehci
->itd_pool
, itd
, itd
->itd_dma
);
}
pci_pool_free
(ehci
->itd_pool
, first_itd
, first_itd
->itd_dma
);
urb
->hcpriv
= 0;
}
static int
itd_fill
(
struct ehci_hcd
*ehci
,
struct ehci_itd
*itd
,
struct urb
*urb
,
unsigned index
, // urb->iso_frame_desc [index]
dma_addr_t dma
// mapped transfer buffer
) {
u64 temp
;
u32 buf1
;
unsigned i
, epnum
, maxp
, multi
;
unsigned length
;
int is_input
;
itd
->hw_next
= EHCI_LIST_END
;
itd
->urb
= urb
;
itd
->index
= index
;
/* tell itd about its transfer buffer, max 2 pages */
length
= urb
->iso_frame_desc
[index
].
length;
dma
+= urb
->iso_frame_desc
[index
].
offset;
temp
= dma
& ~
0x0fff;
for (i
= 0; i
< 2; i
++) {
itd
->hw_bufp
[i
] = cpu_to_le32
((u32
) temp
);
itd
->hw_bufp_hi
[i
] = cpu_to_le32
((u32
)(temp
>> 32));
temp
+= 0x1000;
}
itd
->buf_dma
= dma
;
/*
* this might be a "high bandwidth" highspeed endpoint,
* as encoded in the ep descriptor's maxpacket field
*/
epnum
= usb_pipeendpoint
(urb
->pipe
);
is_input
= usb_pipein
(urb
->pipe
);
if (is_input
) {
maxp
= urb
->dev
->epmaxpacketin
[epnum
];
buf1
= (1 << 11);
} else {
maxp
= urb
->dev
->epmaxpacketout
[epnum
];
buf1
= 0;
}
buf1
|= (maxp
& 0x03ff);
multi
= 1;
multi
+= (maxp
>> 11) & 0x03;
maxp
&= 0x03ff;
maxp
*= multi
;
/* transfer can't fit in any uframe? */
if (length
< 0 || maxp
< length
) {
dbg
("BAD iso packet: %d bytes, max %d, urb %p [%d] (of %d)",
length
, maxp
, urb
, index
,
urb
->iso_frame_desc
[index
].
length);
return -ENOSPC
;
}
itd
->usecs
= usb_calc_bus_time
(USB_SPEED_HIGH
, is_input
, 1, length
);
/* "plus" info in low order bits of buffer pointers */
itd
->hw_bufp
[0] |= cpu_to_le32
((epnum
<< 8) | urb
->dev
->devnum
);
itd
->hw_bufp
[1] |= cpu_to_le32
(buf1
);
itd
->hw_bufp
[2] |= cpu_to_le32
(multi
);
/* figure hw_transaction[] value (it's scheduled later) */
itd
->transaction
= EHCI_ISOC_ACTIVE
;
itd
->transaction
|= dma
& 0x0fff; /* offset; buffer=0 */
if ((index
+ 1) == urb
->number_of_packets
)
itd
->transaction
|= EHCI_ITD_IOC
; /* end-of-urb irq */
itd
->transaction
|= length
<< 16;
cpu_to_le32s
(&itd
->transaction
);
return 0;
}
static int
itd_urb_transaction
(
struct ehci_hcd
*ehci
,
struct urb
*urb
,
int mem_flags
) {
int frame_index
;
struct ehci_itd
*first_itd
, *itd
;
int status
;
dma_addr_t itd_dma
;
/* allocate/init ITDs */
for (frame_index
= 0, first_itd
= 0;
frame_index
< urb
->number_of_packets
;
frame_index
++) {
itd
= pci_pool_alloc_usb
(ehci
->itd_pool
, mem_flags
, &itd_dma
);
if (!itd
) {
status
= -ENOMEM
;
goto fail
;
}
memset (itd
, 0, sizeof *itd
);
itd
->itd_dma
= itd_dma
;
status
= itd_fill
(ehci
, itd
, urb
, frame_index
,
urb
->transfer_dma
);
if (status
!= 0)
goto fail
;
if (first_itd
)
list_add_tail
(&itd
->itd_list
,
&first_itd
->itd_list
);
else {
INIT_LIST_HEAD
(&itd
->itd_list
);
urb
->hcpriv
= first_itd
= itd
;
}
}
urb
->error_count
= 0;
return 0;
fail
:
if (urb
->hcpriv
)
itd_free_list
(ehci
, urb
);
return status
;
}
/*-------------------------------------------------------------------------*/
static inline void
itd_link
(struct ehci_hcd
*ehci
, unsigned frame
, struct ehci_itd
*itd
)
{
/* always prepend ITD/SITD ... only QH tree is order-sensitive */
itd
->itd_next
= ehci
->pshadow
[frame
];
itd
->hw_next
= ehci
->periodic
[frame
];
ehci
->pshadow
[frame
].
itd = itd
;
ehci
->periodic
[frame
] = cpu_to_le32
(itd
->itd_dma
) | Q_TYPE_ITD
;
}
/*
* return zero on success, else -errno
* - start holds first uframe to start scheduling into
* - max is the first uframe it's NOT (!) OK to start scheduling into
* math to be done modulo "mod" (ehci->periodic_size << 3)
*/
static int get_iso_range
(
struct ehci_hcd
*ehci
,
struct urb
*urb
,
unsigned *start
,
unsigned *max
,
unsigned mod
) {
struct list_head
*lh
;
struct hcd_dev
*dev
= urb
->dev
->hcpriv
;
int last
= -1;
unsigned now
, span
, end
;
span
= urb
->interval
* urb
->number_of_packets
;
/* first see if we know when the next transfer SHOULD happen */
list_for_each
(lh
, &dev
->urb_list
) {
struct urb
*u
;
struct ehci_itd
*itd
;
unsigned s
;
u
= list_entry
(lh
, struct urb
, urb_list
);
if (u
== urb
|| u
->pipe
!= urb
->pipe
)
continue;
if (u
->interval
!= urb
->interval
) { /* must not change! */
dbg
("urb %p interval %d ... != %p interval %d",
u
, u
->interval
, urb
, urb
->interval
);
return -EINVAL
;
}
/* URB for this endpoint... covers through when? */
itd
= urb
->hcpriv
;
s
= itd
->uframe
+ u
->interval
* u
->number_of_packets
;
if (last
< 0)
last
= s
;
else {
/*
* So far we can only queue two ISO URBs...
*
* FIXME do interval math, figure out whether
* this URB is "before" or not ... also, handle
* the case where the URB might have completed,
* but hasn't yet been processed.
*/
dbg
("NYET: queue >2 URBs per ISO endpoint");
return -EDOM
;
}
}
/* calculate the legal range [start,max) */
now
= readl
(&ehci
->regs
->frame_index
) + 1; /* next uframe */
if (!ehci
->periodic_sched
)
now
+= 8; /* startup delay */
now
%= mod
;
end
= now
+ mod
;
if (last
< 0) {
*start
= now
+ ehci
->i_thresh
+ /* paranoia */ 1;
*max
= end
- span
;
if (*max
< *start
+ 1)
*max
= *start
+ 1;
} else {
*start
= last
% mod
;
*max
= (last
+ 1) % mod
;
}
/* explicit start frame? */
if (!(urb
->transfer_flags
& URB_ISO_ASAP
)) {
unsigned temp
;
/* sanity check: must be in range */
urb
->start_frame
%= ehci
->periodic_size
;
temp
= urb
->start_frame
<< 3;
if (temp
< *start
)
temp
+= mod
;
if (temp
> *max
)
return -EDOM
;
/* use that explicit start frame */
*start
= urb
->start_frame
<< 3;
temp
+= 8;
if (temp
< *max
)
*max
= temp
;
}
// FIXME minimize wraparound to "now" ... insist max+span
// (and start+span) remains a few frames short of "end"
*max
%= ehci
->periodic_size
;
if ((*start
+ span
) < end
)
return 0;
return -EFBIG
;
}
static int
itd_schedule
(struct ehci_hcd
*ehci
, struct urb
*urb
)
{
unsigned start
, max
, i
;
int status
;
unsigned mod
= ehci
->periodic_size
<< 3;
for (i
= 0; i
< urb
->number_of_packets
; i
++) {
urb
->iso_frame_desc
[i
].
status = -EINPROGRESS
;
urb
->iso_frame_desc
[i
].
actual_length = 0;
}
if ((status
= get_iso_range
(ehci
, urb
, &start
, &max
, mod
)) != 0)
return status
;
do {
unsigned uframe
;
unsigned usecs
;
struct ehci_itd
*itd
;
/* check schedule: enough space? */
itd
= urb
->hcpriv
;
uframe
= start
;
for (i
= 0, uframe
= start
;
i
< urb
->number_of_packets
;
i
++, uframe
+= urb
->interval
) {
uframe
%= mod
;
/* can't commit more than 80% periodic == 100 usec */
if (periodic_usecs
(ehci
, uframe
>> 3, uframe
& 0x7)
> (100 - itd
->usecs
)) {
itd
= 0;
break;
}
itd
= list_entry
(itd
->itd_list.
next,
struct ehci_itd
, itd_list
);
}
if (!itd
)
continue;
/* that's where we'll schedule this! */
itd
= urb
->hcpriv
;
urb
->start_frame
= start
>> 3;
vdbg
("ISO urb %p (%d packets period %d) starting %d.%d",
urb
, urb
->number_of_packets
, urb
->interval
,
urb
->start_frame
, start
& 0x7);
for (i
= 0, uframe
= start
, usecs
= 0;
i
< urb
->number_of_packets
;
i
++, uframe
+= urb
->interval
) {
uframe
%= mod
;
itd
->uframe
= uframe
;
itd
->hw_transaction
[uframe
& 0x07] = itd
->transaction
;
itd_link
(ehci
, (uframe
>> 3) % ehci
->periodic_size
,
itd
);
wmb
();
usecs
+= itd
->usecs
;
itd
= list_entry
(itd
->itd_list.
next,
struct ehci_itd
, itd_list
);
}
/* update bandwidth utilization records (for usbfs)
*
* FIXME This claims each URB queued to an endpoint, as if
* transfers were concurrent, not sequential. So bandwidth
* typically gets double-billed ... comes from tying it to
* URBs rather than endpoints in the schedule. Luckily we
* don't use this usbfs data for serious decision making.
*/
usecs
/= urb
->number_of_packets
;
usecs
/= urb
->interval
;
usecs
>>= 3;
if (usecs
< 1)
usecs
= 1;
usb_claim_bandwidth
(urb
->dev
, urb
, usecs
, 1);
/* maybe enable periodic schedule processing */
if (!ehci
->periodic_sched
++) {
if ((status
= enable_periodic
(ehci
)) != 0) {
// FIXME deschedule right away
err
("itd_schedule, enable = %d", status
);
}
}
return 0;
} while ((start
= ++start
% mod
) != max
);
/* no room in the schedule */
dbg
("urb %p, CAN'T SCHEDULE", urb
);
return -ENOSPC
;
}
/*-------------------------------------------------------------------------*/
#define ISO_ERRS (EHCI_ISOC_BUF_ERR | EHCI_ISOC_BABBLE | EHCI_ISOC_XACTERR)
static unsigned
itd_complete
(
struct ehci_hcd
*ehci
,
struct ehci_itd
*itd
,
unsigned uframe
,
struct pt_regs
*regs
) {
struct urb
*urb
= itd
->urb
;
struct usb_iso_packet_descriptor
*desc
;
u32 t
;
/* update status for this uframe's transfers */
desc
= &urb
->iso_frame_desc
[itd
->index
];
t
= itd
->hw_transaction
[uframe
];
itd
->hw_transaction
[uframe
] = 0;
if (t
& EHCI_ISOC_ACTIVE
)
desc
->status
= -EXDEV
;
else if (t
& ISO_ERRS
) {
urb
->error_count
++;
if (t
& EHCI_ISOC_BUF_ERR
)
desc
->status
= usb_pipein
(urb
->pipe
)
? -ENOSR
/* couldn't read */
: -ECOMM
; /* couldn't write */
else if (t
& EHCI_ISOC_BABBLE
)
desc
->status
= -EOVERFLOW
;
else /* (t & EHCI_ISOC_XACTERR) */
desc
->status
= -EPROTO
;
/* HC need not update length with this error */
if (!(t
& EHCI_ISOC_BABBLE
))
desc
->actual_length
+= EHCI_ITD_LENGTH
(t
);
} else {
desc
->status
= 0;
desc
->actual_length
+= EHCI_ITD_LENGTH
(t
);
}
vdbg
("itd %p urb %p packet %d/%d trans %x status %d len %d",
itd
, urb
, itd
->index
+ 1, urb
->number_of_packets
,
t
, desc
->status
, desc
->actual_length
);
/* handle completion now? */
if ((itd
->index
+ 1) != urb
->number_of_packets
)
return 0;
/*
* Always give the urb back to the driver ... expect it to submit
* a new urb (or resubmit this), and to have another already queued
* when un-interrupted transfers are needed.
*
* NOTE that for now we don't accelerate ISO unlinks; they just
* happen according to the current schedule. Means a delay of
* up to about a second (max).
*/
itd_free_list
(ehci
, urb
);
if (urb
->status
== -EINPROGRESS
)
urb
->status
= 0;
/* complete() can reenter this HCD */
spin_unlock
(&ehci
->lock
);
usb_hcd_giveback_urb
(&ehci
->hcd
, urb
, regs
);
spin_lock
(&ehci
->lock
);
/* defer stopping schedule; completion can submit */
ehci
->periodic_sched
--;
if (!ehci
->periodic_sched
)
(void) disable_periodic
(ehci
);
return 1;
}
/*-------------------------------------------------------------------------*/
static int itd_submit
(struct ehci_hcd
*ehci
, struct urb
*urb
, int mem_flags
)
{
int status
;
unsigned long flags
;
dbg
("itd_submit urb %p", urb
);
/* allocate ITDs w/o locking anything */
status
= itd_urb_transaction
(ehci
, urb
, mem_flags
);
if (status
< 0)
return status
;
/* schedule ... need to lock */
spin_lock_irqsave
(&ehci
->lock
, flags
);
status
= itd_schedule
(ehci
, urb
);
spin_unlock_irqrestore
(&ehci
->lock
, flags
);
if (status
< 0)
itd_free_list
(ehci
, urb
);
return status
;
}
#ifdef have_split_iso
/*-------------------------------------------------------------------------*/
/*
* "Split ISO TDs" ... used for USB 1.1 devices going through
* the TTs in USB 2.0 hubs.
*
* FIXME not yet implemented
*/
#endif /* have_split_iso */
/*-------------------------------------------------------------------------*/
static void
scan_periodic
(struct ehci_hcd
*ehci
, struct pt_regs
*regs
)
{
unsigned frame
, clock, now_uframe
, mod
;
unsigned count
= 0;
mod
= ehci
->periodic_size
<< 3;
/*
* When running, scan from last scan point up to "now"
* else clean up by scanning everything that's left.
* Touches as few pages as possible: cache-friendly.
* Don't scan ISO entries more than once, though.
*/
frame
= ehci
->next_uframe
>> 3;
if (HCD_IS_RUNNING
(ehci
->hcd.
state))
now_uframe
= readl
(&ehci
->regs
->frame_index
);
else
now_uframe
= (frame
<< 3) - 1;
now_uframe
%= mod
;
clock = now_uframe
>> 3;
for (;;) {
union ehci_shadow q
, *q_p
;
u32 type
, *hw_p
;
unsigned uframes
;
restart
:
/* scan schedule to _before_ current frame index */
if (frame
== clock)
uframes
= now_uframe
& 0x07;
else
uframes
= 8;
q_p
= &ehci
->pshadow
[frame
];
hw_p
= &ehci
->periodic
[frame
];
q.
ptr = q_p
->ptr
;
type
= Q_NEXT_TYPE
(*hw_p
);
/* scan each element in frame's queue for completions */
while (q.
ptr != 0) {
int last
;
unsigned uf
;
union ehci_shadow temp
;
switch (type
) {
case Q_TYPE_QH
:
last
= (q.
qh->hw_next
== EHCI_LIST_END
);
temp
= q.
qh->qh_next
;
type
= Q_NEXT_TYPE
(q.
qh->hw_next
);
count
+= intr_complete
(ehci
, frame
,
qh_get
(q.
qh), regs
);
qh_put
(ehci
, q.
qh);
q
= temp
;
break;
case Q_TYPE_FSTN
:
last
= (q.
fstn->hw_next
== EHCI_LIST_END
);
/* for "save place" FSTNs, look at QH entries
* in the previous frame for completions.
*/
if (q.
fstn->hw_prev
!= EHCI_LIST_END
) {
dbg
("ignoring completions from FSTNs");
}
type
= Q_NEXT_TYPE
(q.
fstn->hw_next
);
q
= q.
fstn->fstn_next
;
break;
case Q_TYPE_ITD
:
last
= (q.
itd->hw_next
== EHCI_LIST_END
);
/* Unlink each (S)ITD we see, since the ISO
* URB model forces constant rescheduling.
* That complicates sharing uframes in ITDs,
* and means we need to skip uframes the HC
* hasn't yet processed.
*/
for (uf
= 0; uf
< uframes
; uf
++) {
if (q.
itd->hw_transaction
[uf
] != 0) {
temp
= q
;
*q_p
= q.
itd->itd_next
;
*hw_p
= q.
itd->hw_next
;
type
= Q_NEXT_TYPE
(*hw_p
);
/* might free q.itd ... */
count
+= itd_complete
(ehci
,
temp.
itd, uf
, regs
);
break;
}
}
/* we might skip this ITD's uframe ... */
if (uf
== uframes
) {
q_p
= &q.
itd->itd_next
;
hw_p
= &q.
itd->hw_next
;
type
= Q_NEXT_TYPE
(q.
itd->hw_next
);
}
q
= *q_p
;
break;
#ifdef have_split_iso
case Q_TYPE_SITD
:
last
= (q.
sitd->hw_next
== EHCI_LIST_END
);
sitd_complete
(ehci
, q.
sitd);
type
= Q_NEXT_TYPE
(q.
sitd->hw_next
);
// FIXME unlink SITD after split completes
q
= q.
sitd->sitd_next
;
break;
#endif /* have_split_iso */
default:
dbg
("corrupt type %d frame %d shadow %p",
type
, frame
, q.
ptr);
// BUG ();
last
= 1;
q.
ptr = 0;
}
/* did completion remove an interior q entry? */
if (unlikely
(q.
ptr == 0 && !last
))
goto restart
;
}
/* stop when we catch up to the HC */
// FIXME: this assumes we won't get lapped when
// latencies climb; that should be rare, but...
// detect it, and just go all the way around.
// FLR might help detect this case, so long as latencies
// don't exceed periodic_size msec (default 1.024 sec).
// FIXME: likewise assumes HC doesn't halt mid-scan
if (frame
== clock) {
unsigned now
;
if (!HCD_IS_RUNNING
(ehci
->hcd.
state))
break;
ehci
->next_uframe
= now_uframe
;
now
= readl
(&ehci
->regs
->frame_index
) % mod
;
if (now_uframe
== now
)
break;
/* rescan the rest of this frame, then ... */
now_uframe
= now
;
clock = now_uframe
>> 3;
} else
frame
= (frame
+ 1) % ehci
->periodic_size
;
}
}