Google Git
Sign in
kernel / pub / scm / linux / kernel / git / davem / netdev-vger-cvs / 80048cfb639d5a43a554f7d7aa1be0152ab24d55 / . / drivers / usb / usbvideo.c
blob: a7a5fc1052af33e35c6c7069ac1aea0630b12b44 [file] [log] [blame]
/*
* 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, 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.
*/
#include <linux/kernel.h>
#include <linux/sched.h>
#include <linux/list.h>
#include <linux/slab.h>
#define __NO_VERSION__ /* Temporary: usbvideo is not a module yet */
#include <linux/module.h>
#include <linux/mm.h>
#include <linux/smp_lock.h>
#include <linux/vmalloc.h>
#include <linux/wrapper.h>
#include <linux/init.h>
#include <linux/spinlock.h>
#include <asm/io.h>
#include "usbvideo.h"
#if defined(MAP_NR)
#define virt_to_page(v) MAP_NR(v) /* Kernels 2.2.x */
#endif
static int video_nr = -1;
MODULE_PARM(video_nr, "i");
/*
* Local prototypes.
*/
#if USES_PROC_FS
static void usbvideo_procfs_level1_create(usbvideo_t *ut);
static void usbvideo_procfs_level1_destroy(usbvideo_t *ut);
static void usbvideo_procfs_level2_create(uvd_t *uvd);
static void usbvideo_procfs_level2_destroy(uvd_t *uvd);
static int usbvideo_default_procfs_read_proc(
char *page, char **start, off_t off, int count,
int *eof, void *data);
static int usbvideo_default_procfs_write_proc(
struct file *file, const char *buffer,
unsigned long count, void *data);
#endif
/*******************************/
/* Memory management functions */
/*******************************/
#define MDEBUG(x) do { } while(0) /* Debug memory management */
/* Given PGD from the address space's page table, return the kernel
* virtual mapping of the physical memory mapped at ADR.
*/
unsigned long usbvideo_uvirt_to_kva(pgd_t *pgd, unsigned long adr)
{
unsigned long ret = 0UL;
pmd_t *pmd;
pte_t *ptep, pte;
if (!pgd_none(*pgd)) {
pmd = pmd_offset(pgd, adr);
if (!pmd_none(*pmd)) {
ptep = pte_offset(pmd, adr);
pte = *ptep;
if (pte_present(pte)) {
ret = (unsigned long) page_address(pte_page(pte));
ret |= (adr & (PAGE_SIZE-1));
}
}
}
MDEBUG(printk("uv2kva(%lx-->%lx)", adr, ret));
return ret;
}
/*
* Here we want the physical address of the memory.
* This is used when initializing the contents of the
* area and marking the pages as reserved.
*/
unsigned long usbvideo_kvirt_to_pa(unsigned long adr)
{
unsigned long va, kva, ret;
va = VMALLOC_VMADDR(adr);
kva = usbvideo_uvirt_to_kva(pgd_offset_k(va), va);
ret = __pa(kva);
MDEBUG(printk("kv2pa(%lx-->%lx)", adr, ret));
return ret;
}
void *usbvideo_rvmalloc(unsigned long size)
{
void *mem;
unsigned long adr, page;
/* Round it off to PAGE_SIZE */
size += (PAGE_SIZE - 1);
size &= ~(PAGE_SIZE - 1);
mem = vmalloc_32(size);
if (!mem)
return NULL;
memset(mem, 0, size); /* Clear the ram out, no junk to the user */
adr = (unsigned long) mem;
while (size > 0) {
page = usbvideo_kvirt_to_pa(adr);
mem_map_reserve(virt_to_page(__va(page)));
adr += PAGE_SIZE;
if (size > PAGE_SIZE)
size -= PAGE_SIZE;
else
size = 0;
}
return mem;
}
void usbvideo_rvfree(void *mem, unsigned long size)
{
unsigned long adr, page;
if (!mem)
return;
size += (PAGE_SIZE - 1);
size &= ~(PAGE_SIZE - 1);
adr=(unsigned long) mem;
while (size > 0) {
page = usbvideo_kvirt_to_pa(adr);
mem_map_unreserve(virt_to_page(__va(page)));
adr += PAGE_SIZE;
if (size > PAGE_SIZE)
size -= PAGE_SIZE;
else
size = 0;
}
vfree(mem);
}
void RingQueue_Initialize(RingQueue_t *rq)
{
assert(rq != NULL);
init_waitqueue_head(&rq->wqh);
}
void RingQueue_Allocate(RingQueue_t *rq, int rqLen)
{
assert(rq != NULL);
assert(rqLen > 0);
rq->length = rqLen;
rq->queue = usbvideo_rvmalloc(rq->length);
assert(rq->queue != NULL);
}
int RingQueue_IsAllocated(const RingQueue_t *rq)
{
if (rq == NULL)
return 0;
return (rq->queue != NULL) && (rq->length > 0);
}
void RingQueue_Free(RingQueue_t *rq)
{
assert(rq != NULL);
if (RingQueue_IsAllocated(rq)) {
usbvideo_rvfree(rq->queue, rq->length);
rq->queue = NULL;
rq->length = 0;
}
}
int RingQueue_Dequeue(RingQueue_t *rq, unsigned char *dst, int len)
{
int i;
assert(rq != NULL);
assert(dst != NULL);
for (i=0; i < len; i++) {
dst[i] = rq->queue[rq->ri];
RING_QUEUE_DEQUEUE_BYTES(rq,1);
}
return len;
}
int RingQueue_Enqueue(RingQueue_t *rq, const unsigned char *cdata, int n)
{
int enqueued = 0;
assert(rq != NULL);
assert(cdata != NULL);
assert(rq->length > 0);
while (n > 0) {
int m, q_avail;
/* Calculate the largest chunk that fits the tail of the ring */
q_avail = rq->length - rq->wi;
if (q_avail <= 0) {
rq->wi = 0;
q_avail = rq->length;
}
m = n;
assert(q_avail > 0);
if (m > q_avail)
m = q_avail;
memmove(rq->queue + rq->wi, cdata, m);
RING_QUEUE_ADVANCE_INDEX(rq, wi, m);
cdata += m;
enqueued += m;
n -= m;
}
return enqueued;
}
int RingQueue_GetLength(const RingQueue_t *rq)
{
int ri, wi;
assert(rq != NULL);
ri = rq->ri;
wi = rq->wi;
if (ri == wi)
return 0;
else if (ri < wi)
return wi - ri;
else
return wi + (rq->length - ri);
}
void RingQueue_InterruptibleSleepOn(RingQueue_t *rq)
{
assert(rq != NULL);
interruptible_sleep_on(&rq->wqh);
}
void RingQueue_WakeUpInterruptible(RingQueue_t *rq)
{
assert(rq != NULL);
if (waitqueue_active(&rq->wqh))
wake_up_interruptible(&rq->wqh);
}
/*
* usbvideo_VideosizeToString()
*
* This procedure converts given videosize value to readable string.
*
* History:
* 07-Aug-2000 Created.
* 19-Oct-2000 Reworked for usbvideo module.
*/
void usbvideo_VideosizeToString(char *buf, int bufLen, videosize_t vs)
{
char tmp[40];
int n;
n = 1 + sprintf(tmp, "%ldx%ld", VIDEOSIZE_X(vs), VIDEOSIZE_Y(vs));
assert(n < sizeof(tmp));
if ((buf == NULL) || (bufLen < n))
err("usbvideo_VideosizeToString: buffer is too small.");
else
memmove(buf, tmp, n);
}
/*
* usbvideo_OverlayChar()
*
* History:
* 01-Feb-2000 Created.
*/
void usbvideo_OverlayChar(uvd_t *uvd, usbvideo_frame_t *frame,
int x, int y, int ch)
{
static const unsigned short digits[16] = {
0xF6DE, /* 0 */
0x2492, /* 1 */
0xE7CE, /* 2 */
0xE79E, /* 3 */
0xB792, /* 4 */
0xF39E, /* 5 */
0xF3DE, /* 6 */
0xF492, /* 7 */
0xF7DE, /* 8 */
0xF79E, /* 9 */
0x77DA, /* a */
0xD75C, /* b */
0xF24E, /* c */
0xD6DC, /* d */
0xF34E, /* e */
0xF348 /* f */
};
unsigned short digit;
int ix, iy;
if ((uvd == NULL) || (frame == NULL))
return;
if (ch >= '0' && ch <= '9')
ch -= '0';
else if (ch >= 'A' && ch <= 'F')
ch = 10 + (ch - 'A');
else if (ch >= 'a' && ch <= 'f')
ch = 10 + (ch - 'a');
else
return;
digit = digits[ch];
for (iy=0; iy < 5; iy++) {
for (ix=0; ix < 3; ix++) {
if (digit & 0x8000) {
if (uvd->paletteBits & (1L << VIDEO_PALETTE_RGB24)) {
/* TODO */ RGB24_PUTPIXEL(frame, x+ix, y+iy, 0xFF, 0xFF, 0xFF);
}
}
digit = digit << 1;
}
}
}
/*
* usbvideo_OverlayString()
*
* History:
* 01-Feb-2000 Created.
*/
void usbvideo_OverlayString(uvd_t *uvd, usbvideo_frame_t *frame,
int x, int y, const char *str)
{
while (*str) {
usbvideo_OverlayChar(uvd, frame, x, y, *str);
str++;
x += 4; /* 3 pixels character + 1 space */
}
}
/*
* usbvideo_OverlayStats()
*
* Overlays important debugging information.
*
* History:
* 01-Feb-2000 Created.
*/
void usbvideo_OverlayStats(uvd_t *uvd, usbvideo_frame_t *frame)
{
const int y_diff = 8;
char tmp[16];
int x = 10, y=10;
long i, j, barLength;
const int qi_x1 = 60, qi_y1 = 10;
const int qi_x2 = VIDEOSIZE_X(frame->request) - 10, qi_h = 10;
/* Call the user callback, see if we may proceed after that */
if (VALID_CALLBACK(uvd, overlayHook)) {
if (GET_CALLBACK(uvd, overlayHook)(uvd, frame) < 0)
return;
}
/*
* We draw a (mostly) hollow rectangle with qi_xxx coordinates.
* Left edge symbolizes the queue index 0; right edge symbolizes
* the full capacity of the queue.
*/
barLength = qi_x2 - qi_x1 - 2;
if ((barLength > 10) && (uvd->paletteBits & (1L << VIDEO_PALETTE_RGB24))) {
/* TODO */ long u_lo, u_hi, q_used;
long m_ri, m_wi, m_lo, m_hi;
/*
* Determine fill zones (used areas of the queue):
* 0 xxxxxxx u_lo ...... uvd->dp.ri xxxxxxxx u_hi ..... uvd->dp.length
*
* if u_lo < 0 then there is no first filler.
*/
q_used = RingQueue_GetLength(&uvd->dp);
if ((uvd->dp.ri + q_used) >= uvd->dp.length) {
u_hi = uvd->dp.length;
u_lo = (q_used + uvd->dp.ri) % uvd->dp.length;
} else {
u_hi = (q_used + uvd->dp.ri);
u_lo = -1;
}
/* Convert byte indices into screen units */
m_ri = qi_x1 + ((barLength * uvd->dp.ri) / uvd->dp.length);
m_wi = qi_x1 + ((barLength * uvd->dp.wi) / uvd->dp.length);
m_lo = (u_lo > 0) ? (qi_x1 + ((barLength * u_lo) / uvd->dp.length)) : -1;
m_hi = qi_x1 + ((barLength * u_hi) / uvd->dp.length);
for (j=qi_y1; j < (qi_y1 + qi_h); j++) {
for (i=qi_x1; i < qi_x2; i++) {
/* Draw border lines */
if ((j == qi_y1) || (j == (qi_y1 + qi_h - 1)) ||
(i == qi_x1) || (i == (qi_x2 - 1))) {
RGB24_PUTPIXEL(frame, i, j, 0xFF, 0xFF, 0xFF);
continue;
}
/* For all other points the Y coordinate does not matter */
if ((i >= m_ri) && (i <= (m_ri + 3))) {
RGB24_PUTPIXEL(frame, i, j, 0x00, 0xFF, 0x00);
} else if ((i >= m_wi) && (i <= (m_wi + 3))) {
RGB24_PUTPIXEL(frame, i, j, 0xFF, 0x00, 0x00);
} else if ((i < m_lo) || ((i > m_ri) && (i < m_hi)))
RGB24_PUTPIXEL(frame, i, j, 0x00, 0x00, 0xFF);
}
}
}
sprintf(tmp, "%8lx", uvd->stats.frame_num);
usbvideo_OverlayString(uvd, frame, x, y, tmp);
y += y_diff;
sprintf(tmp, "%8lx", uvd->stats.urb_count);
usbvideo_OverlayString(uvd, frame, x, y, tmp);
y += y_diff;
sprintf(tmp, "%8lx", uvd->stats.urb_length);
usbvideo_OverlayString(uvd, frame, x, y, tmp);
y += y_diff;
sprintf(tmp, "%8lx", uvd->stats.data_count);
usbvideo_OverlayString(uvd, frame, x, y, tmp);
y += y_diff;
sprintf(tmp, "%8lx", uvd->stats.header_count);
usbvideo_OverlayString(uvd, frame, x, y, tmp);
y += y_diff;
sprintf(tmp, "%8lx", uvd->stats.iso_skip_count);
usbvideo_OverlayString(uvd, frame, x, y, tmp);
y += y_diff;
sprintf(tmp, "%8lx", uvd->stats.iso_err_count);
usbvideo_OverlayString(uvd, frame, x, y, tmp);
y += y_diff;
sprintf(tmp, "%8x", uvd->vpic.colour);
usbvideo_OverlayString(uvd, frame, x, y, tmp);
y += y_diff;
sprintf(tmp, "%8x", uvd->vpic.hue);
usbvideo_OverlayString(uvd, frame, x, y, tmp);
y += y_diff;
sprintf(tmp, "%8x", uvd->vpic.brightness >> 8);
usbvideo_OverlayString(uvd, frame, x, y, tmp);
y += y_diff;
sprintf(tmp, "%8x", uvd->vpic.contrast >> 12);
usbvideo_OverlayString(uvd, frame, x, y, tmp);
y += y_diff;
sprintf(tmp, "%8d", uvd->vpic.whiteness >> 8);
usbvideo_OverlayString(uvd, frame, x, y, tmp);
y += y_diff;
}
/*
* usbvideo_ReportStatistics()
*
* This procedure prints packet and transfer statistics.
*
* History:
* 14-Jan-2000 Corrected default multiplier.
*/
void usbvideo_ReportStatistics(const uvd_t *uvd)
{
if ((uvd != NULL) && (uvd->stats.urb_count > 0)) {
unsigned long allPackets, badPackets, goodPackets, percent;
allPackets = uvd->stats.urb_count * CAMERA_URB_FRAMES;
badPackets = uvd->stats.iso_skip_count + uvd->stats.iso_err_count;
goodPackets = allPackets - badPackets;
/* Calculate percentage wisely, remember integer limits */
assert(allPackets != 0);
if (goodPackets < (((unsigned long)-1)/100))
percent = (100 * goodPackets) / allPackets;
else
percent = goodPackets / (allPackets / 100);
info("Packet Statistics: Total=%lu. Empty=%lu. Usage=%lu%%",
allPackets, badPackets, percent);
if (uvd->iso_packet_len > 0) {
unsigned long allBytes, xferBytes;
char multiplier = ' ';
allBytes = allPackets * uvd->iso_packet_len;
xferBytes = uvd->stats.data_count;
assert(allBytes != 0);
if (xferBytes < (((unsigned long)-1)/100))
percent = (100 * xferBytes) / allBytes;
else
percent = xferBytes / (allBytes / 100);
/* Scale xferBytes for easy reading */
if (xferBytes > 10*1024) {
xferBytes /= 1024;
multiplier = 'K';
if (xferBytes > 10*1024) {
xferBytes /= 1024;
multiplier = 'M';
if (xferBytes > 10*1024) {
xferBytes /= 1024;
multiplier = 'G';
if (xferBytes > 10*1024) {
xferBytes /= 1024;
multiplier = 'T';
}
}
}
}
info("Transfer Statistics: Transferred=%lu%cB Usage=%lu%%",
xferBytes, multiplier, percent);
}
}
}
/*
* usbvideo_DrawLine()
*
* A standard implementation of Bresenham's line drawing algorithm.
* This procedure is provided primarily for debugging or demo
* purposes.
*/
void usbvideo_DrawLine(
usbvideo_frame_t *frame,
int x1, int y1,
int x2, int y2,
unsigned char cr, unsigned char cg, unsigned char cb)
{
int i, dx, dy, np, d;
int dinc1, dinc2, x, xinc1, xinc2, y, yinc1, yinc2;
if ((dx = x2 - x1) < 0)
dx = -dx;
if ((dy = y2 - y1) < 0)
dy = -dy;
if (dx >= dy) {
np = dx + 1;
d = (2 * dy) - dx;
dinc1 = dy << 1;
dinc2 = (dy - dx) << 1;
xinc1 = 1;
xinc2 = 1;
yinc1 = 0;
yinc2 = 1;
} else {
np = dy + 1;
d = (2 * dx) - dy;
dinc1 = dx << 1;
dinc2 = (dx - dy) << 1;
xinc1 = 0;
xinc2 = 1;
yinc1 = 1;
yinc2 = 1;
}
/* Make sure x and y move in the right directions */
if (x1 > x2) {
xinc1 = -xinc1;
xinc2 = -xinc2;
}
if (y1 > y2) {
yinc1 = -yinc1;
yinc2 = -yinc2;
}
for (i=0, x=x1, y=y1; i < np; i++) {
if (frame->palette == VIDEO_PALETTE_RGB24) {
/* TODO */ RGB24_PUTPIXEL(frame, x, y, cr, cg, cb);
}
if (d < 0) {
d += dinc1;
x += xinc1;
y += yinc1;
} else {
d += dinc2;
x += xinc2;
y += yinc2;
}
}
}
/*
* usbvideo_TestPattern()
*
* Procedure forms a test pattern (yellow grid on blue background).
*
* Parameters:
* fullframe: if TRUE then entire frame is filled, otherwise the procedure
* continues from the current scanline.
* pmode 0: fill the frame with solid blue color (like on VCR or TV)
* 1: Draw a colored grid
*
* History:
* 01-Feb-2000 Created.
*/
void usbvideo_TestPattern(uvd_t *uvd, int fullframe, int pmode)
{
static const char proc[] = "usbvideo_TestPattern";
usbvideo_frame_t *frame;
int num_cell = 0;
int scan_length = 0;
static int num_pass = 0;
if (uvd == NULL) {
err("%s: uvd == NULL", proc);
return;
}
if ((uvd->curframe < 0) || (uvd->curframe >= USBVIDEO_NUMFRAMES)) {
err("%s: uvd->curframe=%d.", proc, uvd->curframe);
return;
}
/* Grab the current frame */
frame = &uvd->frame[uvd->curframe];
/* Optionally start at the beginning */
if (fullframe) {
frame->curline = 0;
frame->seqRead_Length = 0;
}
#if 0
{ /* For debugging purposes only */
char tmp[20];
usbvideo_VideosizeToString(tmp, sizeof(tmp), frame->request);
info("testpattern: frame=%s", tmp);
}
#endif
/* Form every scan line */
for (; frame->curline < VIDEOSIZE_Y(frame->request); frame->curline++) {
int i;
unsigned char *f = frame->data +
(VIDEOSIZE_X(frame->request) * V4L_BYTES_PER_PIXEL * frame->curline);
for (i=0; i < VIDEOSIZE_X(frame->request); i++) {
unsigned char cb=0x80;
unsigned char cg = 0;
unsigned char cr = 0;
if (pmode == 1) {
if (frame->curline % 32 == 0)
cb = 0, cg = cr = 0xFF;
else if (i % 32 == 0) {
if (frame->curline % 32 == 1)
num_cell++;
cb = 0, cg = cr = 0xFF;
} else {
cb = ((num_cell*7) + num_pass) & 0xFF;
cg = ((num_cell*5) + num_pass*2) & 0xFF;
cr = ((num_cell*3) + num_pass*3) & 0xFF;
}
} else {
/* Just the blue screen */
}
*f++ = cb;
*f++ = cg;
*f++ = cr;
scan_length += 3;
}
}
frame->frameState = FrameState_Done;
frame->seqRead_Length += scan_length;
++num_pass;
/* We do this unconditionally, regardless of FLAGS_OVERLAY_STATS */
usbvideo_OverlayStats(uvd, frame);
}
/*
* usbvideo_HexDump()
*
* A debugging tool. Prints hex dumps.
*
* History:
* 29-Jul-2000 Added printing of offsets.
*/
void usbvideo_HexDump(const unsigned char *data, int len)
{
const int bytes_per_line = 32;
char tmp[128]; /* 32*3 + 5 */
int i, k;
for (i=k=0; len > 0; i++, len--) {
if (i > 0 && ((i % bytes_per_line) == 0)) {
printk("%s\n", tmp);
k=0;
}
if ((i % bytes_per_line) == 0)
k += sprintf(&tmp[k], "%04x: ", i);
k += sprintf(&tmp[k], "%02x ", data[i]);
}
if (k > 0)
printk("%s\n", tmp);
}
/* Debugging aid */
void usbvideo_SayAndWait(const char *what)
{
wait_queue_head_t wq;
init_waitqueue_head(&wq);
info("Say: %s", what);
interruptible_sleep_on_timeout (&wq, HZ*3); /* Timeout */
}
/* ******************************************************************** */
static void usbvideo_ClientIncModCount(uvd_t *uvd)
{
static const char proc[] = "usbvideo_ClientIncModCount";
if (uvd == NULL) {
err("%s: uvd == NULL", proc);
return;
}
if (uvd->handle == NULL) {
err("%s: uvd->handle == NULL", proc);
return;
}
if (uvd->handle->md_module == NULL) {
err("%s: uvd->handle->md_module == NULL", proc);
return;
}
__MOD_INC_USE_COUNT(uvd->handle->md_module);
}
static void usbvideo_ClientDecModCount(uvd_t *uvd)
{
static const char proc[] = "usbvideo_ClientDecModCount";
if (uvd == NULL) {
err("%s: uvd == NULL", proc);
return;
}
if (uvd->handle == NULL) {
err("%s: uvd->handle == NULL", proc);
return;
}
if (uvd->handle->md_module == NULL) {
err("%s: uvd->handle->md_module == NULL", proc);
return;
}
__MOD_DEC_USE_COUNT(uvd->handle->md_module);
}
int usbvideo_register(
usbvideo_t **pCams,
const int num_cams,
const int num_extra,
const char *driverName,
const usbvideo_cb_t *cbTbl,
struct module *md )
{
static const char proc[] = "usbvideo_register";
usbvideo_t *cams;
int i, base_size;
/* Check parameters for sanity */
if ((num_cams <= 0) || (pCams == NULL) || (cbTbl == NULL)) {
err("%s: Illegal call", proc);
return -EINVAL;
}
/* Check registration callback - must be set! */
if (cbTbl->probe == NULL) {
err("%s: probe() is required!", proc);
return -EINVAL;
}
base_size = num_cams * sizeof(uvd_t) + sizeof(usbvideo_t);
cams = (usbvideo_t *) kmalloc(base_size, GFP_KERNEL);
if (cams == NULL) {
err("Failed to allocate %d. bytes for usbvideo_t", base_size);
return -ENOMEM;
}
dbg("%s: Allocated $%p (%d. bytes) for %d. cameras",
proc, cams, base_size, num_cams);
memset(cams, 0, base_size);
/* Copy callbacks, apply defaults for those that are not set */
memmove(&cams->cb, cbTbl, sizeof(cams->cb));
if (cams->cb.getFrame == NULL)
cams->cb.getFrame = usbvideo_GetFrame;
if (cams->cb.disconnect == NULL)
cams->cb.disconnect = usbvideo_Disconnect;
#if USES_PROC_FS
/*
* If both /proc fs callbacks are NULL then we assume that the driver
* does not need procfs services at all. Leave them NULL.
*/
cams->uses_procfs = (cams->cb.procfs_read != NULL) || (cams->cb.procfs_write == NULL);
if (cams->uses_procfs) {
if (cams->cb.procfs_read == NULL)
cams->cb.procfs_read = usbvideo_default_procfs_read_proc;
if (cams->cb.procfs_write == NULL)
cams->cb.procfs_write = usbvideo_default_procfs_write_proc;
}
#else /* !USES_PROC_FS */
/* Report a warning so that user knows why there is no /proc entries */
if ((cams->cb.procfs_read != NULL) || (cams->cb.procfs_write == NULL)) {
dbg("%s: /proc fs support requested but not configured!", proc);
}
#endif
cams->num_cameras = num_cams;
cams->cam = (uvd_t *) &cams[1];
cams->md_module = md;
if (cams->md_module == NULL)
warn("%s: module == NULL!", proc);
init_MUTEX(&cams->lock); /* to 1 == available */
for (i = 0; i < num_cams; i++) {
uvd_t *up = &cams->cam[i];
up->handle = cams;
/* Allocate user_data separately because of kmalloc's limits */
if (num_extra > 0) {
up->user_size = num_cams * num_extra;
up->user_data = (char *) kmalloc(up->user_size, GFP_KERNEL);
if (up->user_data == NULL) {
up->user_size = 0;
err("%s: Failed to allocate user_data (%d. bytes)",
proc, up->user_size);
return -ENOMEM;
}
dbg("%s: Allocated cams[%d].user_data=$%p (%d. bytes)",
proc, i, up->user_data, up->user_size);
}
}
/*
* Register ourselves with USB stack.
*/
strcpy(cams->drvName, (driverName != NULL) ? driverName : "Unknown");
cams->usbdrv.name = cams->drvName;
cams->usbdrv.probe = cams->cb.probe;
cams->usbdrv.disconnect = cams->cb.disconnect;
#if USES_PROC_FS
if (cams->uses_procfs) {
dbg("%s: Creating /proc filesystem entries.", proc);
usbvideo_procfs_level1_create(cams);
}
#endif
/*
* Update global handle to usbvideo. This is very important
* because probe() can be called before usb_register() returns.
* If the handle is not yet updated then the probe() will fail.
*/
*pCams = cams;
usb_register(&cams->usbdrv);
return 0;
}
/*
* usbvideo_Deregister()
*
* Procedure frees all usbvideo and user data structures. Be warned that
* if you had some dynamically allocated components in ->user field then
* you should free them before calling here.
*/
void usbvideo_Deregister(usbvideo_t **pCams)
{
static const char proc[] = "usbvideo_deregister";
usbvideo_t *cams;
int i;
if (pCams == NULL) {
err("%s: pCams == NULL", proc);
return;
}
cams = *pCams;
if (cams == NULL) {
err("%s: cams == NULL", proc);
return;
}
#if USES_PROC_FS
if (cams->uses_procfs) {
dbg("%s: Deregistering filesystem entries.", proc);
usbvideo_procfs_level1_destroy(cams);
}
#endif
dbg("%s: Deregistering %s driver.", proc, cams->drvName);
usb_deregister(&cams->usbdrv);
dbg("%s: Deallocating cams=$%p (%d. cameras)", proc, cams, cams->num_cameras);
for (i=0; i < cams->num_cameras; i++) {
uvd_t *up = &cams->cam[i];
int warning = 0;
if (up->user_data != NULL) {
if (up->user_size <= 0)
++warning;
} else {
if (up->user_size > 0)
++warning;
}
if (warning) {
err("%s: Warning: user_data=$%p user_size=%d.",
proc, up->user_data, up->user_size);
} else {
dbg("%s: Freeing %d. $%p->user_data=$%p",
proc, i, up, up->user_data);
kfree(up->user_data);
}
}
/* Whole array was allocated in one chunk */
dbg("%s: Freed %d uvd_t structures",
proc, cams->num_cameras);
kfree(cams);
*pCams = NULL;
}
/*
* usbvideo_Disconnect()
*
* This procedure stops all driver activity. Deallocation of
* the interface-private structure (pointed by 'ptr') is done now
* (if we don't have any open files) or later, when those files
* are closed. After that driver should be removable.
*
* This code handles surprise removal. The uvd->user is a counter which
* increments on open() and decrements on close(). If we see here that
* this counter is not 0 then we have a client who still has us opened.
* We set uvd->remove_pending flag as early as possible, and after that
* all access to the camera will gracefully fail. These failures should
* prompt client to (eventually) close the video device, and then - in
* usbvideo_v4l_close() - we decrement uvd->uvd_used and usage counter.
*
* History:
* 22-Jan-2000 Added polling of MOD_IN_USE to delay removal until all users gone.
* 27-Jan-2000 Reworked to allow pending disconnects; see xxx_close()
* 24-May-2000 Corrected to prevent race condition (MOD_xxx_USE_COUNT).
* 19-Oct-2000 Moved to usbvideo module.
*/
void usbvideo_Disconnect(struct usb_device *dev, void *ptr)
{
static const char proc[] = "usbvideo_Disconnect";
uvd_t *uvd = (uvd_t *) ptr;
int i;
if ((dev == NULL) || (uvd == NULL)) {
err("%s($%p,$%p): Illegal call.", proc, dev, ptr);
return;
}
usbvideo_ClientIncModCount(uvd);
if (uvd->debug > 0)
info("%s(%p,%p.)", proc, dev, ptr);
down(&uvd->lock);
uvd->remove_pending = 1; /* Now all ISO data will be ignored */
/* At this time we ask to cancel outstanding URBs */
usbvideo_StopDataPump(uvd);
for (i=0; i < USBVIDEO_NUMSBUF; i++)
usb_free_urb(uvd->sbuf[i].urb);
usb_dec_dev_use(uvd->dev);
uvd->dev = NULL; /* USB device is no more */
if (uvd->user)
info("%s: In use, disconnect pending.", proc);
else
usbvideo_CameraRelease(uvd);
up(&uvd->lock);
info("USB camera disconnected.");
usbvideo_ClientDecModCount(uvd);
}
/*
* usbvideo_CameraRelease()
*
* This code does final release of uvd_t. This happens
* after the device is disconnected -and- all clients
* closed their files.
*
* History:
* 27-Jan-2000 Created.
*/
void usbvideo_CameraRelease(uvd_t *uvd)
{
static const char proc[] = "usbvideo_CameraRelease";
if (uvd == NULL) {
err("%s: Illegal call", proc);
return;
}
video_unregister_device(&uvd->vdev);
if (uvd->debug > 0)
info("%s: Video unregistered.", proc);
#if USES_PROC_FS
assert(uvd->handle != NULL);
if (uvd->handle->uses_procfs) {
dbg("%s: Removing /proc/%s/ filesystem entries.", proc, uvd->handle->drvName);
usbvideo_procfs_level2_destroy(uvd);
}
#endif
RingQueue_Free(&uvd->dp);
if (VALID_CALLBACK(uvd, userFree))
GET_CALLBACK(uvd, userFree)(uvd);
uvd->uvd_used = 0; /* This is atomic, no need to take mutex */
}
/*
* usbvideo_find_struct()
*
* This code searches the array of preallocated (static) structures
* and returns index of the first one that isn't in use. Returns -1
* if there are no free structures.
*
* History:
* 27-Jan-2000 Created.
*/
static int usbvideo_find_struct(usbvideo_t *cams)
{
int u, rv = -1;
if (cams == NULL) {
err("No usbvideo_t handle?");
return -1;
}
down(&cams->lock);
for (u = 0; u < cams->num_cameras; u++) {
uvd_t *uvd = &cams->cam[u];
if (!uvd->uvd_used) /* This one is free */
{
uvd->uvd_used = 1; /* In use now */
init_MUTEX(&uvd->lock); /* to 1 == available */
uvd->dev = NULL;
rv = u;
break;
}
}
up(&cams->lock);
return rv;
}
uvd_t *usbvideo_AllocateDevice(usbvideo_t *cams)
{
int i, devnum;
uvd_t *uvd = NULL;
if (cams == NULL) {
err("No usbvideo_t handle?");
return NULL;
}
devnum = usbvideo_find_struct(cams);
if (devnum == -1) {
err("IBM USB camera driver: Too many devices!");
return NULL;
}
uvd = &cams->cam[devnum];
dbg("Device entry #%d. at $%p", devnum, uvd);
/* Not relying upon caller we increase module counter ourselves */
usbvideo_ClientIncModCount(uvd);
down(&uvd->lock);
for (i=0; i < USBVIDEO_NUMSBUF; i++) {
uvd->sbuf[i].urb = usb_alloc_urb(FRAMES_PER_DESC);
if (uvd->sbuf[i].urb == NULL) {
err("usb_alloc_urb(%d.) failed.", FRAMES_PER_DESC);
uvd->uvd_used = 0;
uvd = NULL;
goto allocate_done;
}
}
uvd->user=0;
uvd->remove_pending = 0;
uvd->last_error = 0;
RingQueue_Initialize(&uvd->dp);
/* Initialize video device structure */
memset(&uvd->vdev, 0, sizeof(uvd->vdev));
i = sprintf(uvd->vdev.name, "%s USB Camera", cams->drvName);
if (i >= sizeof(uvd->vdev.name)) {
err("Wrote too much into uvd->vdev.name, expect trouble!");
}
uvd->vdev.type = VID_TYPE_CAPTURE;
uvd->vdev.hardware = VID_HARDWARE_CPIA;
uvd->vdev.open = usbvideo_v4l_open;
uvd->vdev.close = usbvideo_v4l_close;
uvd->vdev.read = usbvideo_v4l_read;
uvd->vdev.write = usbvideo_v4l_write;
uvd->vdev.ioctl = usbvideo_v4l_ioctl;
uvd->vdev.mmap = usbvideo_v4l_mmap;
uvd->vdev.initialize = usbvideo_v4l_initialize;
/*
* The client is free to overwrite those because we
* return control to the client's probe function right now.
*/
allocate_done:
up (&uvd->lock);
usbvideo_ClientDecModCount(uvd);
return uvd;
}
int usbvideo_RegisterVideoDevice(uvd_t *uvd)
{
static const char proc[] = "usbvideo_RegisterVideoDevice";
char tmp1[20], tmp2[20]; /* Buffers for printing */
if (uvd == NULL) {
err("%s: Illegal call.", proc);
return -EINVAL;
}
if (uvd->video_endp == 0) {
info("%s: No video endpoint specified; data pump disabled.", proc);
}
if (uvd->paletteBits == 0) {
err("%s: No palettes specified!", proc);
return -EINVAL;
}
if (uvd->defaultPalette == 0) {
info("%s: No default palette!", proc);
}
uvd->max_frame_size = VIDEOSIZE_X(uvd->canvas) *
VIDEOSIZE_Y(uvd->canvas) * V4L_BYTES_PER_PIXEL;
usbvideo_VideosizeToString(tmp1, sizeof(tmp1), uvd->videosize);
usbvideo_VideosizeToString(tmp2, sizeof(tmp2), uvd->canvas);
if (uvd->debug > 0) {
info("%s: iface=%d. endpoint=$%02x paletteBits=$%08lx",
proc, uvd->iface, uvd->video_endp, uvd->paletteBits);
}
if (video_register_device(&uvd->vdev, VFL_TYPE_GRABBER, video_nr) == -1) {
err("%s: video_register_device failed", proc);
return -EPIPE;
}
if (uvd->debug > 1) {
info("%s: video_register_device() successful", proc);
}
if (uvd->dev == NULL) {
err("%s: uvd->dev == NULL", proc);
return -EINVAL;
}
info("%s on /dev/video%d: canvas=%s videosize=%s",
(uvd->handle != NULL) ? uvd->handle->drvName : "???",
uvd->vdev.minor, tmp2, tmp1);
#if USES_PROC_FS
assert(uvd->handle != NULL);
if (uvd->handle->uses_procfs) {
if (uvd->debug > 0) {
info("%s: Creating /proc/video/%s/ filesystem entries.",
proc, uvd->handle->drvName);
}
usbvideo_procfs_level2_create(uvd);
}
#endif
usb_inc_dev_use(uvd->dev);
return 0;
}
/* ******************************************************************** */
int usbvideo_v4l_initialize(struct video_device *dev)
{
return 0;
}
long usbvideo_v4l_write(struct video_device *dev, const char *buf,
unsigned long count, int noblock)
{
return -EINVAL;
}
int usbvideo_v4l_mmap(struct vm_area_struct *vma, struct video_device *dev, const char *adr, unsigned long size)
{
uvd_t *uvd = (uvd_t *) dev;
unsigned long start = (unsigned long) adr;
unsigned long page, pos;
if (!CAMERA_IS_OPERATIONAL(uvd))
return -EFAULT;
if (size > (((2 * uvd->max_frame_size) + PAGE_SIZE - 1) & ~(PAGE_SIZE - 1)))
return -EINVAL;
pos = (unsigned long) uvd->fbuf;
while (size > 0) {
page = usbvideo_kvirt_to_pa(pos);
if (remap_page_range(vma, start, page, PAGE_SIZE, PAGE_SHARED))
return -EAGAIN;
start += PAGE_SIZE;
pos += PAGE_SIZE;
if (size > PAGE_SIZE)
size -= PAGE_SIZE;
else
size = 0;
}
return 0;
}
/*
* usbvideo_v4l_open()
*
* This is part of Video 4 Linux API. The driver can be opened by one
* client only (checks internal counter 'uvdser'). The procedure
* then allocates buffers needed for video processing.
*
* History:
* 22-Jan-2000 Rewrote, moved scratch buffer allocation here. Now the
* camera is also initialized here (once per connect), at
* expense of V4L client (it waits on open() call).
* 27-Jan-2000 Used USBVIDEO_NUMSBUF as number of URB buffers.
* 24-May-2000 Corrected to prevent race condition (MOD_xxx_USE_COUNT).
*/
int usbvideo_v4l_open(struct video_device *dev, int flags)
{
static const char proc[] = "usbvideo_v4l_open";
uvd_t *uvd = (uvd_t *) dev;
const int sb_size = FRAMES_PER_DESC * uvd->iso_packet_len;
int i, errCode = 0;
if (uvd->debug > 1)
info("%s($%p,$%08x", proc, dev, flags);
usbvideo_ClientIncModCount(uvd);
down(&uvd->lock);
if (uvd->user) {
err("%s: Someone tried to open an already opened device!", proc);
errCode = -EBUSY;
} else {
/* Clear statistics */
memset(&uvd->stats, 0, sizeof(uvd->stats));
/* Clean pointers so we know if we allocated something */
for (i=0; i < USBVIDEO_NUMSBUF; i++)
uvd->sbuf[i].data = NULL;
/* Allocate memory for the frame buffers */
uvd->fbuf_size = USBVIDEO_NUMFRAMES * uvd->max_frame_size;
uvd->fbuf = usbvideo_rvmalloc(uvd->fbuf_size);
RingQueue_Allocate(&uvd->dp, 128*1024); /* FIXME #define */
if ((uvd->fbuf == NULL) ||
(!RingQueue_IsAllocated(&uvd->dp))) {
err("%s: Failed to allocate fbuf or dp", proc);
errCode = -ENOMEM;
} else {
/* Allocate all buffers */
for (i=0; i < USBVIDEO_NUMFRAMES; i++) {
uvd->frame[i].frameState = FrameState_Unused;
uvd->frame[i].data = uvd->fbuf + i*(uvd->max_frame_size);
/*
* Set default sizes in case IOCTL (VIDIOCMCAPTURE)
* is not used (using read() instead).
*/
uvd->frame[i].canvas = uvd->canvas;
uvd->frame[i].seqRead_Index = 0;
}
for (i=0; i < USBVIDEO_NUMSBUF; i++) {
uvd->sbuf[i].data = kmalloc(sb_size, GFP_KERNEL);
if (uvd->sbuf[i].data == NULL) {
errCode = -ENOMEM;
break;
}
}
}
if (errCode != 0) {
/* Have to free all that memory */
if (uvd->fbuf != NULL) {
usbvideo_rvfree(uvd->fbuf, uvd->fbuf_size);
uvd->fbuf = NULL;
}
RingQueue_Free(&uvd->dp);
for (i=0; i < USBVIDEO_NUMSBUF; i++) {
if (uvd->sbuf[i].data != NULL) {
kfree (uvd->sbuf[i].data);
uvd->sbuf[i].data = NULL;
}
}
}
}
/* If so far no errors then we shall start the camera */
if (errCode == 0) {
/* Start data pump if we have valid endpoint */
if (uvd->video_endp != 0)
errCode = usbvideo_StartDataPump(uvd);
if (errCode == 0) {
if (VALID_CALLBACK(uvd, setupOnOpen)) {
if (uvd->debug > 1)
info("%s: setupOnOpen callback", proc);
errCode = GET_CALLBACK(uvd, setupOnOpen)(uvd);
if (errCode < 0) {
err("%s: setupOnOpen callback failed (%d.).",
proc, errCode);
} else if (uvd->debug > 1) {
info("%s: setupOnOpen callback successful", proc);
}
}
if (errCode == 0) {
uvd->settingsAdjusted = 0;
if (uvd->debug > 1)
info("%s: Open succeeded.", proc);
uvd->user++;
}
}
}
up(&uvd->lock);
if (errCode != 0)
usbvideo_ClientDecModCount(uvd);
if (uvd->debug > 0)
info("%s: Returning %d.", proc, errCode);
return errCode;
}
/*
* usbvideo_v4l_close()
*
* This is part of Video 4 Linux API. The procedure
* stops streaming and deallocates all buffers that were earlier
* allocated in usbvideo_v4l_open().
*
* History:
* 22-Jan-2000 Moved scratch buffer deallocation here.
* 27-Jan-2000 Used USBVIDEO_NUMSBUF as number of URB buffers.
* 24-May-2000 Moved MOD_DEC_USE_COUNT outside of code that can sleep.
*/
void usbvideo_v4l_close(struct video_device *dev)
{
static const char proc[] = "usbvideo_v4l_close";
uvd_t *uvd = (uvd_t *)dev;
int i;
if (uvd->debug > 1)
info("%s($%p)", proc, dev);
down(&uvd->lock);
usbvideo_StopDataPump(uvd);
usbvideo_rvfree(uvd->fbuf, uvd->fbuf_size);
uvd->fbuf = NULL;
RingQueue_Free(&uvd->dp);
for (i=0; i < USBVIDEO_NUMSBUF; i++) {
kfree(uvd->sbuf[i].data);
uvd->sbuf[i].data = NULL;
}
#if USBVIDEO_REPORT_STATS
usbvideo_ReportStatistics(uvd);
#endif
uvd->user--;
if (uvd->remove_pending) {
if (uvd->debug > 0)
info("usbvideo_v4l_close: Final disconnect.");
usbvideo_CameraRelease(uvd);
}
up(&uvd->lock);
usbvideo_ClientDecModCount(uvd);
if (uvd->debug > 1)
info("%s: Completed.", proc);
}
/*
* usbvideo_v4l_ioctl()
*
* This is part of Video 4 Linux API. The procedure handles ioctl() calls.
*
* History:
* 22-Jan-2000 Corrected VIDIOCSPICT to reject unsupported settings.
*/
int usbvideo_v4l_ioctl(struct video_device *dev, unsigned int cmd, void *arg)
{
uvd_t *uvd = (uvd_t *)dev;
if (!CAMERA_IS_OPERATIONAL(uvd))
return -EFAULT;
switch (cmd) {
case VIDIOCGCAP:
{
if (copy_to_user(arg, &uvd->vcap, sizeof(uvd->vcap)))
return -EFAULT;
return 0;
}
case VIDIOCGCHAN:
{
if (copy_to_user(arg, &uvd->vchan, sizeof(uvd->vchan)))
return -EFAULT;
return 0;
}
case VIDIOCSCHAN:
{ /* Not used but we return success */
int v;
if (copy_from_user(&v, arg, sizeof(v)))
return -EFAULT;
return 0;
}
case VIDIOCGPICT:
{
if (copy_to_user(arg, &uvd->vpic, sizeof(uvd->vpic)))
return -EFAULT;
return 0;
}
case VIDIOCSPICT:
{
struct video_picture tmp;
/*
* Use temporary 'video_picture' structure to preserve our
* own settings (such as color depth, palette) that we
* aren't allowing everyone (V4L client) to change.
*/
if (copy_from_user(&tmp, arg, sizeof(tmp)))
return -EFAULT;
uvd->vpic.brightness = tmp.brightness;
uvd->vpic.hue = tmp.hue;
uvd->vpic.colour = tmp.colour;
uvd->vpic.contrast = tmp.contrast;
uvd->settingsAdjusted = 0; /* Will force new settings */
return 0;
}
case VIDIOCSWIN:
{
struct video_window vw;
if (copy_from_user(&vw, arg, sizeof(vw)))
return -EFAULT;
if (vw.flags)
return -EINVAL;
if (vw.clipcount)
return -EINVAL;
if (vw.width != VIDEOSIZE_X(uvd->canvas))
return -EINVAL;
if (vw.height != VIDEOSIZE_Y(uvd->canvas))
return -EINVAL;
return 0;
}
case VIDIOCGWIN:
{
struct video_window vw;
vw.x = 0;
vw.y = 0;
vw.width = VIDEOSIZE_X(uvd->canvas);
vw.height = VIDEOSIZE_Y(uvd->canvas);
vw.chromakey = 0;
if (VALID_CALLBACK(uvd, getFPS))
vw.flags = GET_CALLBACK(uvd, getFPS)(uvd);
else
vw.flags = 10; /* FIXME: do better! */
if (copy_to_user(arg, &vw, sizeof(vw)))
return -EFAULT;
return 0;
}
case VIDIOCGMBUF:
{
struct video_mbuf vm;
memset(&vm, 0, sizeof(vm));
vm.size = uvd->max_frame_size * 2;
vm.frames = 2;
vm.offsets[0] = 0;
vm.offsets[1] = uvd->max_frame_size;
if (copy_to_user((void *)arg, (void *)&vm, sizeof(vm)))
return -EFAULT;
return 0;
}
case VIDIOCMCAPTURE:
{
struct video_mmap vm;
if (copy_from_user((void *)&vm, (void *)arg, sizeof(vm))) {
err("VIDIOCMCAPTURE: copy_from_user() failed.");
return -EFAULT;
}
if (uvd->debug >= 1) {
info("VIDIOCMCAPTURE: frame=%d. size=%dx%d, format=%d.",
vm.frame, vm.width, vm.height, vm.format);
}
/*
* Check if the requested size is supported. If the requestor
* requests too big a frame then we may be tricked into accessing
* outside of own preallocated frame buffer (in uvd->frame).
* This will cause oops or a security hole. Theoretically, we
* could only clamp the size down to acceptable bounds, but then
* we'd need to figure out how to insert our smaller buffer into
* larger caller's buffer... this is not an easy question. So we
* here just flatly reject too large requests, assuming that the
* caller will resubmit with smaller size. Callers should know
* what size we support (returned by VIDIOCGCAP). However vidcat,
* for one, does not care and allows to ask for any size.
*/
if ((vm.width > VIDEOSIZE_X(uvd->canvas)) ||
(vm.height > VIDEOSIZE_Y(uvd->canvas))) {
if (uvd->debug > 0) {
info("VIDIOCMCAPTURE: Size=%dx%d too large; "
"allowed only up to %ldx%ld", vm.width, vm.height,
VIDEOSIZE_X(uvd->canvas), VIDEOSIZE_Y(uvd->canvas));
}
return -EINVAL;
}
/* Check if the palette is supported */
if (((1L << vm.format) & uvd->paletteBits) == 0) {
if (uvd->debug > 0) {
info("VIDIOCMCAPTURE: format=%d. not supported"
" (paletteBits=$%08lx)",
vm.format, uvd->paletteBits);
}
return -EINVAL;
}
if ((vm.frame != 0) && (vm.frame != 1)) {
err("VIDIOCMCAPTURE: vm.frame=%d. !E [0,1]", vm.frame);
return -EINVAL;
}
if (uvd->frame[vm.frame].frameState == FrameState_Grabbing) {
/* Not an error - can happen */
}
uvd->frame[vm.frame].request = VIDEOSIZE(vm.width, vm.height);
uvd->frame[vm.frame].palette = vm.format;
/* Mark it as ready */
uvd->frame[vm.frame].frameState = FrameState_Ready;
return usbvideo_NewFrame(uvd, vm.frame);
}
case VIDIOCSYNC:
{
int frameNum, ret;
if (copy_from_user((void *)&frameNum, arg, sizeof(frameNum))) {
err("VIDIOCSYNC: copy_from_user() failed.");
return -EFAULT;
}
if(frameNum < 0 || frameNum >= USBVIDEO_NUMFRAMES)
return -EINVAL;
if (uvd->debug >= 1)
info("VIDIOCSYNC: syncing to frame %d.", frameNum);
if (uvd->flags & FLAGS_NO_DECODING)
ret = usbvideo_GetFrame(uvd, frameNum);
else if (VALID_CALLBACK(uvd, getFrame)) {
ret = GET_CALLBACK(uvd, getFrame)(uvd, frameNum);
if ((ret < 0) && (uvd->debug >= 1)) {
err("VIDIOCSYNC: getFrame() returned %d.", ret);
}
} else {
err("VIDIOCSYNC: getFrame is not set");
ret = -EFAULT;
}
/*
* The frame is in FrameState_Done_Hold state. Release it
* right now because its data is already mapped into
* the user space and it's up to the application to
* make use of it until it asks for another frame.
*/
uvd->frame[frameNum].frameState = FrameState_Unused;
return ret;
}
case VIDIOCGFBUF:
{
struct video_buffer vb;
memset(&vb, 0, sizeof(vb));
vb.base = NULL; /* frame buffer not supported, not used */
if (copy_to_user((void *)arg, (void *)&vb, sizeof(vb)))
return -EFAULT;
return 0;
}
case VIDIOCKEY:
return 0;
case VIDIOCCAPTURE:
return -EINVAL;
case VIDIOCSFBUF:
case VIDIOCGTUNER:
case VIDIOCSTUNER:
case VIDIOCGFREQ:
case VIDIOCSFREQ:
case VIDIOCGAUDIO:
case VIDIOCSAUDIO:
return -EINVAL;
default:
return -ENOIOCTLCMD;
}
return 0;
}
/*
* usbvideo_v4l_read()
*
* This is mostly boring stuff. We simply ask for a frame and when it
* arrives copy all the video data from it into user space. There is
* no obvious need to override this method.
*
* History:
* 20-Oct-2000 Created.
* 01-Nov-2000 Added mutex (uvd->lock).
*/
long usbvideo_v4l_read(struct video_device *dev, char *buf, unsigned long count, int noblock)
{
static const char proc[] = "usbvideo_v4l_read";
uvd_t *uvd = (uvd_t *) dev;
int frmx = -1;
usbvideo_frame_t *frame;
if (!CAMERA_IS_OPERATIONAL(uvd) || (buf == NULL))
return -EFAULT;
if (uvd->debug >= 1)
info("%s: %ld. bytes, noblock=%d.", proc, count, noblock);
down(&uvd->lock);
/* See if a frame is completed, then use it. */
if ((uvd->frame[0].frameState == FrameState_Done) ||
(uvd->frame[0].frameState == FrameState_Done_Hold) ||
(uvd->frame[0].frameState == FrameState_Error)) {
frmx = 0;
} else if ((uvd->frame[1].frameState >= FrameState_Done) ||
(uvd->frame[1].frameState == FrameState_Done_Hold) ||
(uvd->frame[1].frameState >= FrameState_Done)) {
frmx = 1;
}
/* FIXME: If we don't start a frame here then who ever does? */
if (noblock && (frmx == -1)) {
count = -EAGAIN;
goto read_done;
}
/*
* If no FrameState_Done, look for a FrameState_Grabbing state.
* See if a frame is in process (grabbing), then use it.
* We will need to wait until it becomes cooked, of course.
*/
if (frmx == -1) {
if (uvd->frame[0].frameState == FrameState_Grabbing)
frmx = 0;
else if (uvd->frame[1].frameState == FrameState_Grabbing)
frmx = 1;
}
/*
* If no frame is active, start one. We don't care which one
* it will be, so #0 is as good as any.
* In read access mode we don't have convenience of VIDIOCMCAPTURE
* to specify the requested palette (video format) on per-frame
* basis. This means that we have to return data in -some- format
* and just hope that the client knows what to do with it.
* The default format is configured in uvd->defaultPalette field
* as one of VIDEO_PALETTE_xxx values. We stuff it into the new
* frame and initiate the frame filling process.
*/
if (frmx == -1) {
if (uvd->defaultPalette == 0) {
err("%s: No default palette; don't know what to do!", proc);
count = -EFAULT;
goto read_done;
}
frmx = 0;
/*
* We have no per-frame control over video size.
* Therefore we only can use whatever size was
* specified as default.
*/
uvd->frame[frmx].request = uvd->videosize;
uvd->frame[frmx].palette = uvd->defaultPalette;
uvd->frame[frmx].frameState = FrameState_Ready;
usbvideo_NewFrame(uvd, frmx);
/* Now frame 0 is supposed to start filling... */
}
/*
* Get a pointer to the active frame. It is either previously
* completed frame or frame in progress but not completed yet.
*/
frame = &uvd->frame[frmx];
/*
* Sit back & wait until the frame gets filled and postprocessed.
* If we fail to get the picture [in time] then return the error.
* In this call we specify that we want the frame to be waited for,
* postprocessed and switched into FrameState_Done_Hold state. This
* state is used to hold the frame as "fully completed" between
* subsequent partial reads of the same frame.
*/
if (frame->frameState != FrameState_Done_Hold) {
long rv = -EFAULT;
if (uvd->flags & FLAGS_NO_DECODING)
rv = usbvideo_GetFrame(uvd, frmx);
else if (VALID_CALLBACK(uvd, getFrame))
rv = GET_CALLBACK(uvd, getFrame)(uvd, frmx);
else
err("getFrame is not set");
if ((rv != 0) || (frame->frameState != FrameState_Done_Hold)) {
count = rv;
goto read_done;
}
}
/*
* Copy bytes to user space. We allow for partial reads, which
* means that the user application can request read less than
* the full frame size. It is up to the application to issue
* subsequent calls until entire frame is read.
*
* First things first, make sure we don't copy more than we
* have - even if the application wants more. That would be
* a big security embarassment!
*/
if ((count + frame->seqRead_Index) > frame->seqRead_Length)
count = frame->seqRead_Length - frame->seqRead_Index;
/*
* Copy requested amount of data to user space. We start
* copying from the position where we last left it, which
* will be zero for a new frame (not read before).
*/
if (copy_to_user(buf, frame->data + frame->seqRead_Index, count)) {
count = -EFAULT;
goto read_done;
}
/* Update last read position */
frame->seqRead_Index += count;
if (uvd->debug >= 1) {
err("%s: {copy} count used=%ld, new seqRead_Index=%ld",
proc, count, frame->seqRead_Index);
}
/* Finally check if the frame is done with and "release" it */
if (frame->seqRead_Index >= frame->seqRead_Length) {
/* All data has been read */
frame->seqRead_Index = 0;
/* Mark it as available to be used again. */
uvd->frame[frmx].frameState = FrameState_Unused;
if (usbvideo_NewFrame(uvd, frmx ? 0 : 1)) {
err("%s: usbvideo_NewFrame failed.", proc);
}
}
read_done:
up(&uvd->lock);
return count;
}
/*
* Make all of the blocks of data contiguous
*/
static int usbvideo_CompressIsochronous(uvd_t *uvd, struct urb *urb)
{
char *cdata;
int i, totlen = 0;
for (i = 0; i < urb->number_of_packets; i++) {
int n = urb->iso_frame_desc[i].actual_length;
int st = urb->iso_frame_desc[i].status;
cdata = urb->transfer_buffer + urb->iso_frame_desc[i].offset;
/* Detect and ignore errored packets */
if (st < 0) {
if (uvd->debug >= 1)
err("Data error: packet=%d. len=%d. status=%d.", i, n, st);
uvd->stats.iso_err_count++;
continue;
}
/* Detect and ignore empty packets */
if (n <= 0) {
uvd->stats.iso_skip_count++;
continue;
}
totlen += n; /* Little local accounting */
RingQueue_Enqueue(&uvd->dp, cdata, n);
}
return totlen;
}
static void usbvideo_IsocIrq(struct urb *urb)
{
int i, len;
uvd_t *uvd = urb->context;
/* We don't want to do anything if we are about to be removed! */
if (!CAMERA_IS_OPERATIONAL(uvd))
return;
#if 0
if (urb->actual_length > 0) {
info("urb=$%p status=%d. errcount=%d. length=%d.",
urb, urb->status, urb->error_count, urb->actual_length);
} else {
static int c = 0;
if (c++ % 100 == 0)
info("No Isoc data");
}
#endif
if (!uvd->streaming) {
if (uvd->debug >= 1)
info("Not streaming, but interrupt!");
return;
}
uvd->stats.urb_count++;
if (urb->actual_length <= 0)
goto urb_done_with;
/* Copy the data received into ring queue */
len = usbvideo_CompressIsochronous(uvd, urb);
uvd->stats.urb_length = len;
if (len <= 0)
goto urb_done_with;
/* Here we got some data */
uvd->stats.data_count += len;
RingQueue_WakeUpInterruptible(&uvd->dp);
urb_done_with:
for (i = 0; i < FRAMES_PER_DESC; i++) {
urb->iso_frame_desc[i].status = 0;
urb->iso_frame_desc[i].actual_length = 0;
}
return;
}
/*
* usbvideo_StartDataPump()
*
* History:
* 27-Jan-2000 Used ibmcam->iface, ibmcam->ifaceAltActive instead
* of hardcoded values. Simplified by using for loop,
* allowed any number of URBs.
*/
int usbvideo_StartDataPump(uvd_t *uvd)
{
static const char proc[] = "usbvideo_StartDataPump";
struct usb_device *dev = uvd->dev;
int i, errFlag;
if (uvd->debug > 1)
info("%s($%p)", proc, uvd);
if (!CAMERA_IS_OPERATIONAL(uvd)) {
err("%s: Camera is not operational",proc);
return -EFAULT;
}
uvd->curframe = -1;
/* Alternate interface 1 is is the biggest frame size */
i = usb_set_interface(dev, uvd->iface, uvd->ifaceAltActive);
if (i < 0) {
err("%s: usb_set_interface error", proc);
uvd->last_error = i;
return -EBUSY;
}
if (VALID_CALLBACK(uvd, videoStart))
GET_CALLBACK(uvd, videoStart)(uvd);
else
err("%s: videoStart not set", proc);
/* We double buffer the Iso lists */
for (i=0; i < USBVIDEO_NUMSBUF; i++) {
int j, k;
struct urb *urb = uvd->sbuf[i].urb;
urb->dev = dev;
urb->context = uvd;
urb->pipe = usb_rcvisocpipe(dev, uvd->video_endp);
urb->transfer_flags = USB_ISO_ASAP;
urb->transfer_buffer = uvd->sbuf[i].data;
urb->complete = usbvideo_IsocIrq;
urb->number_of_packets = FRAMES_PER_DESC;
urb->transfer_buffer_length = uvd->iso_packet_len * FRAMES_PER_DESC;
for (j=k=0; j < FRAMES_PER_DESC; j++, k += uvd->iso_packet_len) {
urb->iso_frame_desc[j].offset = k;
urb->iso_frame_desc[j].length = uvd->iso_packet_len;
}
}
/* Link URBs into a ring so that they invoke each other infinitely */
for (i=0; i < USBVIDEO_NUMSBUF; i++) {
if ((i+1) < USBVIDEO_NUMSBUF)
uvd->sbuf[i].urb->next = uvd->sbuf[i+1].urb;
else
uvd->sbuf[i].urb->next = uvd->sbuf[0].urb;
}
/* Submit all URBs */
for (i=0; i < USBVIDEO_NUMSBUF; i++) {
errFlag = usb_submit_urb(uvd->sbuf[i].urb, GFP_KERNEL);
if (errFlag)
err("%s: usb_submit_isoc(%d) ret %d", proc, i, errFlag);
}
uvd->streaming = 1;
if (uvd->debug > 1)
info("%s: streaming=1 video_endp=$%02x", proc, uvd->video_endp);
return 0;
}
/*
* usbvideo_StopDataPump()
*
* This procedure stops streaming and deallocates URBs. Then it
* activates zero-bandwidth alt. setting of the video interface.
*
* History:
* 22-Jan-2000 Corrected order of actions to work after surprise removal.
* 27-Jan-2000 Used uvd->iface, uvd->ifaceAltInactive instead of hardcoded values.
*/
void usbvideo_StopDataPump(uvd_t *uvd)
{
static const char proc[] = "usbvideo_StopDataPump";
int i, j;
if (uvd->debug > 1)
info("%s($%p)", proc, uvd);
if ((uvd == NULL) || (!uvd->streaming) || (uvd->dev == NULL))
return;
/* Unschedule all of the iso td's */
for (i=0; i < USBVIDEO_NUMSBUF; i++) {
j = usb_unlink_urb(uvd->sbuf[i].urb);
if (j < 0)
err("%s: usb_unlink_urb() error %d.", proc, j);
}
if (uvd->debug > 1)
info("%s: streaming=0", proc);
uvd->streaming = 0;
if (!uvd->remove_pending) {
/* Invoke minidriver's magic to stop the camera */
if (VALID_CALLBACK(uvd, videoStop))
GET_CALLBACK(uvd, videoStop)(uvd);
else
err("%s: videoStop not set" ,proc);
/* Set packet size to 0 */
j = usb_set_interface(uvd->dev, uvd->iface, uvd->ifaceAltInactive);
if (j < 0) {
err("%s: usb_set_interface() error %d.", proc, j);
uvd->last_error = j;
}
}
}
/*
* usbvideo_NewFrame()
*
* History:
* 29-Mar-00 Added copying of previous frame into the current one.
* 6-Aug-00 Added model 3 video sizes, removed redundant width, height.
*/
int usbvideo_NewFrame(uvd_t *uvd, int framenum)
{
usbvideo_frame_t *frame;
int n;
if (uvd->debug > 1)
info("usbvideo_NewFrame($%p,%d.)", uvd, framenum);
/* If we're not grabbing a frame right now and the other frame is */
/* ready to be grabbed into, then use it instead */
if (uvd->curframe != -1)
return 0;
/* If necessary we adjust picture settings between frames */
if (!uvd->settingsAdjusted) {
if (VALID_CALLBACK(uvd, adjustPicture))
GET_CALLBACK(uvd, adjustPicture)(uvd);
uvd->settingsAdjusted = 1;
}
n = (framenum - 1 + USBVIDEO_NUMFRAMES) % USBVIDEO_NUMFRAMES;
if (uvd->frame[n].frameState == FrameState_Ready)
framenum = n;
frame = &uvd->frame[framenum];
frame->frameState = FrameState_Grabbing;
frame->scanstate = ScanState_Scanning;
frame->seqRead_Length = 0; /* Accumulated in xxx_parse_data() */
frame->deinterlace = Deinterlace_None;
frame->flags = 0; /* No flags yet, up to minidriver (or us) to set them */
uvd->curframe = framenum;
/*
* Normally we would want to copy previous frame into the current one
* before we even start filling it with data; this allows us to stop
* filling at any moment; top portion of the frame will be new and
* bottom portion will stay as it was in previous frame. If we don't
* do that then missing chunks of video stream will result in flickering
* portions of old data whatever it was before.
*
* If we choose not to copy previous frame (to, for example, save few
* bus cycles - the frame can be pretty large!) then we have an option
* to clear the frame before using. If we experience losses in this
* mode then missing picture will be black (no flickering).
*
* Finally, if user chooses not to clean the current frame before
* filling it with data then the old data will be visible if we fail
* to refill entire frame with new data.
*/
if (!(uvd->flags & FLAGS_SEPARATE_FRAMES)) {
/* This copies previous frame into this one to mask losses */
memmove(frame->data, uvd->frame[1-framenum].data, uvd->max_frame_size);
} else {
if (uvd->flags & FLAGS_CLEAN_FRAMES) {
/* This provides a "clean" frame but slows things down */
memset(frame->data, 0, uvd->max_frame_size);
}
}
return 0;
}
/*
* usbvideo_CollectRawData()
*
* This procedure can be used instead of 'processData' callback if you
* only want to dump the raw data from the camera into the output
* device (frame buffer). You can look at it with V4L client, but the
* image will be unwatchable. The main purpose of this code and of the
* mode FLAGS_NO_DECODING is debugging and capturing of datastreams from
* new, unknown cameras. This procedure will be automatically invoked
* instead of the specified callback handler when uvd->flags has bit
* FLAGS_NO_DECODING set. Therefore, any regular build of any driver
* based on usbvideo can use this feature at any time.
*/
void usbvideo_CollectRawData(uvd_t *uvd, usbvideo_frame_t *frame)
{
int n;
assert(uvd != NULL);
assert(frame != NULL);
/* Try to move data from queue into frame buffer */
n = RingQueue_GetLength(&uvd->dp);
if (n > 0) {
int m;
/* See how much space we have left */
m = uvd->max_frame_size - frame->seqRead_Length;
if (n > m)
n = m;
/* Now move that much data into frame buffer */
RingQueue_Dequeue(
&uvd->dp,
frame->data + frame->seqRead_Length,
m);
frame->seqRead_Length += m;
}
/* See if we filled the frame */
if (frame->seqRead_Length >= uvd->max_frame_size) {
frame->frameState = FrameState_Done;
uvd->curframe = -1;
uvd->stats.frame_num++;
}
}
int usbvideo_GetFrame(uvd_t *uvd, int frameNum)
{
static const char proc[] = "usbvideo_GetFrame";
usbvideo_frame_t *frame = &uvd->frame[frameNum];
if (uvd->debug >= 2)
info("%s($%p,%d.)", proc, uvd, frameNum);
switch (frame->frameState) {
case FrameState_Unused:
if (uvd->debug >= 2)
info("%s: FrameState_Unused", proc);
return -EINVAL;
case FrameState_Ready:
case FrameState_Grabbing:
case FrameState_Error:
{
int ntries, signalPending;
redo:
if (!CAMERA_IS_OPERATIONAL(uvd)) {
if (uvd->debug >= 2)
info("%s: Camera is not operational (1)", proc);
return -EIO;
}
ntries = 0;
do {
RingQueue_InterruptibleSleepOn(&uvd->dp);
signalPending = signal_pending(current);
if (!CAMERA_IS_OPERATIONAL(uvd)) {
if (uvd->debug >= 2)
info("%s: Camera is not operational (2)", proc);
return -EIO;
}
assert(uvd->fbuf != NULL);
if (signalPending) {
if (uvd->debug >= 2)
info("%s: Signal=$%08x", proc, signalPending);
if (uvd->flags & FLAGS_RETRY_VIDIOCSYNC) {
usbvideo_TestPattern(uvd, 1, 0);
uvd->curframe = -1;
uvd->stats.frame_num++;
if (uvd->debug >= 2)
info("%s: Forced test pattern screen", proc);
return 0;
} else {
/* Standard answer: Interrupted! */
if (uvd->debug >= 2)
info("%s: Interrupted!", proc);
return -EINTR;
}
} else {
/* No signals - we just got new data in dp queue */
if (uvd->flags & FLAGS_NO_DECODING)
usbvideo_CollectRawData(uvd, frame);
else if (VALID_CALLBACK(uvd, processData))
GET_CALLBACK(uvd, processData)(uvd, frame);
else
err("%s: processData not set", proc);
}
} while (frame->frameState == FrameState_Grabbing);
if (uvd->debug >= 2) {
info("%s: Grabbing done; state=%d. (%lu. bytes)",
proc, frame->frameState, frame->seqRead_Length);
}
if (frame->frameState == FrameState_Error) {
int ret = usbvideo_NewFrame(uvd, frameNum);
if (ret < 0) {
err("%s: usbvideo_NewFrame() failed (%d.)", proc, ret);
return ret;
}
goto redo;
}
/* Note that we fall through to meet our destiny below */
}
case FrameState_Done:
/*
* Do all necessary postprocessing of data prepared in
* "interrupt" code and the collecting code above. The
* frame gets marked as FrameState_Done by queue parsing code.
* This status means that we collected enough data and
* most likely processed it as we went through. However
* the data may need postprocessing, such as deinterlacing
* or picture adjustments implemented in software (horror!)
*
* As soon as the frame becomes "final" it gets promoted to
* FrameState_Done_Hold status where it will remain until the
* caller consumed all the video data from the frame. Then
* the empty shell of ex-frame is thrown out for dogs to eat.
* But we, worried about pets, will recycle the frame!
*/
uvd->stats.frame_num++;
if ((uvd->flags & FLAGS_NO_DECODING) == 0) {
if (VALID_CALLBACK(uvd, postProcess))
GET_CALLBACK(uvd, postProcess)(uvd, frame);
if (frame->flags & USBVIDEO_FRAME_FLAG_SOFTWARE_CONTRAST)
usbvideo_SoftwareContrastAdjustment(uvd, frame);
}
frame->frameState = FrameState_Done_Hold;
if (uvd->debug >= 2)
info("%s: Entered FrameState_Done_Hold state.", proc);
return 0;
case FrameState_Done_Hold:
/*
* We stay in this state indefinitely until someone external,
* like ioctl() or read() call finishes digesting the frame
* data. Then it will mark the frame as FrameState_Unused and
* it will be released back into the wild to roam freely.
*/
if (uvd->debug >= 2)
info("%s: FrameState_Done_Hold state.", proc);
return 0;
}
/* Catch-all for other cases. We shall not be here. */
err("%s: Invalid state %d.", proc, frame->frameState);
frame->frameState = FrameState_Unused;
return 0;
}
/*
* usbvideo_DeinterlaceFrame()
*
* This procedure deinterlaces the given frame. Some cameras produce
* only half of scanlines - sometimes only even lines, sometimes only
* odd lines. The deinterlacing method is stored in frame->deinterlace
* variable.
*
* Here we scan the frame vertically and replace missing scanlines with
* average between surrounding ones - before and after. If we have no
* line above then we just copy next line. Similarly, if we need to
* create a last line then preceding line is used.
*/
void usbvideo_DeinterlaceFrame(uvd_t *uvd, usbvideo_frame_t *frame)
{
if ((uvd == NULL) || (frame == NULL))
return;
if ((frame->deinterlace == Deinterlace_FillEvenLines) ||
(frame->deinterlace == Deinterlace_FillOddLines))
{
const int v4l_linesize = VIDEOSIZE_X(frame->request) * V4L_BYTES_PER_PIXEL;
int i = (frame->deinterlace == Deinterlace_FillEvenLines) ? 0 : 1;
for (; i < VIDEOSIZE_Y(frame->request); i += 2) {
const unsigned char *fs1, *fs2;
unsigned char *fd;
int ip, in, j; /* Previous and next lines */
/*
* Need to average lines before and after 'i'.
* If we go out of bounds seeking those lines then
* we point back to existing line.
*/
ip = i - 1; /* First, get rough numbers */
in = i + 1;
/* Now validate */
if (ip < 0)
ip = in;
if (in >= VIDEOSIZE_Y(frame->request))
in = ip;
/* Sanity check */
if ((ip < 0) || (in < 0) ||
(ip >= VIDEOSIZE_Y(frame->request)) ||
(in >= VIDEOSIZE_Y(frame->request)))
{
err("Error: ip=%d. in=%d. req.height=%ld.",
ip, in, VIDEOSIZE_Y(frame->request));
break;
}
/* Now we need to average lines 'ip' and 'in' to produce line 'i' */
fs1 = frame->data + (v4l_linesize * ip);
fs2 = frame->data + (v4l_linesize * in);
fd = frame->data + (v4l_linesize * i);
/* Average lines around destination */
for (j=0; j < v4l_linesize; j++) {
fd[j] = (unsigned char)((((unsigned) fs1[j]) +
((unsigned)fs2[j])) >> 1);
}
}
}
/* Optionally display statistics on the screen */
if (uvd->flags & FLAGS_OVERLAY_STATS)
usbvideo_OverlayStats(uvd, frame);
}
/*
* usbvideo_SoftwareContrastAdjustment()
*
* This code adjusts the contrast of the frame, assuming RGB24 format.
* As most software image processing, this job is CPU-intensive.
* Get a camera that supports hardware adjustment!
*
* History:
* 09-Feb-2001 Created.
*/
void usbvideo_SoftwareContrastAdjustment(uvd_t *uvd, usbvideo_frame_t *frame)
{
static const char proc[] = "usbvideo_SoftwareContrastAdjustment";
int i, j, v4l_linesize;
signed long adj;
const int ccm = 128; /* Color correction median - see below */
if ((uvd == NULL) || (frame == NULL)) {
err("%s: Illegal call.", proc);
return;
}
adj = (uvd->vpic.contrast - 0x8000) >> 8; /* -128..+127 = -ccm..+(ccm-1)*/
RESTRICT_TO_RANGE(adj, -ccm, ccm+1);
if (adj == 0) {
/* In rare case of no adjustment */
return;
}
v4l_linesize = VIDEOSIZE_X(frame->request) * V4L_BYTES_PER_PIXEL;
for (i=0; i < VIDEOSIZE_Y(frame->request); i++) {
unsigned char *fd = frame->data + (v4l_linesize * i);
for (j=0; j < v4l_linesize; j++) {
signed long v = (signed long) fd[j];
/* Magnify up to 2 times, reduce down to zero */
v = 128 + ((ccm + adj) * (v - 128)) / ccm;
RESTRICT_TO_RANGE(v, 0, 0xFF); /* Must flatten tails */
fd[j] = (unsigned char) v;
}
}
}
/*
* /proc interface
*
* We will be creating directories and entries under /proc/video using
* external 'video_proc_entry' directory which is exported by videodev.o
* module. Within that directory we will create $driver/ directory to
* uniquely and uniformly refer to our specific $driver. Within that
* directory we will finally create an entry that is named after the
* video device node - video3, for example. The format of that file
* is determined by callbacks that the minidriver may provide. If no
* callbacks are provided (neither read nor write) then we don't create
* the entry.
*
* Here is a sample directory entry: /proc/video/ibmcam/video3
*
* The "file" video3 (in example above) is readable and writeable, in
* theory. If the minidriver provides callbacks to do reading and
* writing then both those procedures are supported. However if the
* driver leaves callbacks in default (NULL) state the default
* read and write handlers are used. The default read handler reports
* that the driver does not support /proc fs. The default write handler
* returns error code on any write attempt.
*/
#if USES_PROC_FS
extern struct proc_dir_entry *video_proc_entry;
static void usbvideo_procfs_level1_create(usbvideo_t *ut)
{
static const char proc[] = "usbvideo_procfs_level1_create";
if (ut == NULL) {
err("%s: ut == NULL", proc);
return;
}
if (video_proc_entry == NULL) {
err("%s: /proc/video/ doesn't exist.", proc);
return;
}
ut->procfs_dEntry = create_proc_entry(ut->drvName, S_IFDIR, video_proc_entry);
if (ut->procfs_dEntry != NULL) {
if (ut->md_module != NULL)
ut->procfs_dEntry->owner = ut->md_module;
} else {
err("%s: Unable to initialize /proc/video/%s", proc, ut->drvName);
}
}
static void usbvideo_procfs_level1_destroy(usbvideo_t *ut)
{
static const char proc[] = "usbvideo_procfs_level1_destroy";
if (ut == NULL) {
err("%s: ut == NULL", proc);
return;
}
if (ut->procfs_dEntry != NULL) {
remove_proc_entry(ut->drvName, video_proc_entry);
ut->procfs_dEntry = NULL;
}
}
static void usbvideo_procfs_level2_create(uvd_t *uvd)
{
static const char proc[] = "usbvideo_procfs_level2_create";
if (uvd == NULL) {
err("%s: uvd == NULL", proc);
return;
}
assert(uvd->handle != NULL);
if (uvd->handle->procfs_dEntry == NULL) {
err("%s: uvd->handle->procfs_dEntry == NULL", proc);
return;
}
sprintf(uvd->videoName, "video%d", uvd->vdev.minor);
uvd->procfs_vEntry = create_proc_entry(
uvd->videoName,
S_IFREG | S_IRUGO | S_IWUSR,
uvd->handle->procfs_dEntry);
if (uvd->procfs_vEntry != NULL) {
uvd->procfs_vEntry->data = uvd;
uvd->procfs_vEntry->read_proc = uvd->handle->cb.procfs_read;
uvd->procfs_vEntry->write_proc = uvd->handle->cb.procfs_write;
} else {
err("%s: Failed to create entry \"%s\"", proc, uvd->videoName);
}
}
static void usbvideo_procfs_level2_destroy(uvd_t *uvd)
{
static const char proc[] = "usbvideo_procfs_level2_destroy";
if (uvd == NULL) {
err("%s: uvd == NULL", proc);
return;
}
if (uvd->procfs_vEntry != NULL) {
remove_proc_entry(uvd->videoName, uvd->procfs_vEntry);
uvd->procfs_vEntry = NULL;
}
}
static int usbvideo_default_procfs_read_proc(
char *page, char **start, off_t off, int count,
int *eof, void *data)
{
char *out = page;
int len;
/* Stay under PAGE_SIZE or else */
out += sprintf(out, "This driver does not support /proc services.\n");
len = out - page;
len -= off;
if (len < count) {
*eof = 1;
if (len <= 0)
return 0;
} else
len = count;
*start = page + off;
return len;
}
static int usbvideo_default_procfs_write_proc(
struct file *file, const char *buffer,
unsigned long count, void *data)
{
return -EINVAL;
}
#endif /* USES_PROC_FS */
MODULE_LICENSE("GPL");