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Elphel
linux-elphel
Commits
c92588c9
Commit
c92588c9
authored
Aug 27, 2016
by
Mikhail Karpenko
Browse files
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Plain Diff
Frame alignment tests look fine
parent
e41643e0
Changes
2
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Showing
2 changed files
with
129 additions
and
342 deletions
+129
-342
ahci_elphel.c
src/drivers/ata/ahci_elphel.c
+127
-337
ahci_elphel.h
src/drivers/ata/ahci_elphel.h
+2
-5
No files found.
src/drivers/ata/ahci_elphel.c
View file @
c92588c9
...
...
@@ -389,6 +389,8 @@ static void elphel_qc_prep(struct ata_queued_cmd *qc)
#define PHY_BLOCK_SIZE 512
//#define PHY_BLOCK_SIZE 4096
#define JPEG_MARKER_LEN 2
/** The size in bytes of JPEG marker length field */
#define JPEG_SIZE_LEN 2
#define SG_TBL_SZ 256
/** Include REM buffer to total size calculation */
#define INCLUDE_REM 1
...
...
@@ -477,13 +479,17 @@ static int circbuf_get_ptr_tst(int sensor_port, size_t offset, size_t len, struc
if
(
use_preset
==
0
)
{
if
(
jpg_0_sz
!=
0
)
jpg_0_sz
=
jpg_0_sz
%
(
DATA_BUFF_SIZE
-
1
);
if
(
jpg_1_sz
!=
0
)
if
(
jpg_1_sz
!=
0
)
{
jpg_0_sz
-=
(
jpg_0_sz
%
ALIGNMENT_SIZE
);
jpg_1_sz
=
jpg_1_sz
%
(
DATA_BUFF_SIZE
-
1
);
}
}
else
if
(
use_preset
==
1
)
{
if
(
g_jpg_0_sz
!=
0
)
jpg_0_sz
=
jpg_0_sz
%
g_jpg_0_sz
;
if
(
g_jpg_1_sz
!=
0
)
if
(
g_jpg_1_sz
!=
0
)
{
jpg_0_sz
-=
(
jpg_0_sz
%
ALIGNMENT_SIZE
);
jpg_1_sz
=
jpg_1_sz
%
g_jpg_1_sz
;
}
}
else
if
(
use_preset
==
2
)
{
jpg_0_sz
=
g_jpg_0_sz
;
jpg_1_sz
=
g_jpg_1_sz
;
...
...
@@ -536,14 +542,6 @@ static int check_chunks(struct fvec *vects)
dev_err
(
NULL
,
"ERROR: unaligned write from slot %d, length %u
\n
"
,
i
,
vects
[
i
].
iov_len
);
ret
=
-
1
;
}
if
((
vects
[
i
].
iov_dma
%
ALIGNMENT_ADDR
)
!=
0
)
{
dev_err
(
NULL
,
"ERROR: unaligned DMA address in slot %d: 0x%x
\n
"
,
i
,
vects
[
i
].
iov_dma
);
ret
=
-
1
;
}
}
if
((
i
==
CHUNK_ALIGN_0
||
i
==
CHUNK_ALIGN_1
)
&&
vects
[
i
].
iov_len
>
2
*
ALIGNMENT_SIZE
)
{
dev_err
(
NULL
,
"ERROR: alignment buffer %d overflow
\n
"
,
i
);
ret
=
-
1
;
}
}
if
((
sz
%
PHY_BLOCK_SIZE
)
!=
0
)
{
...
...
@@ -688,37 +686,9 @@ static inline unsigned char *vectrpos(struct fvec *vec, size_t offset)
{
return
(
unsigned
char
*
)
vec
->
iov_base
+
(
vec
->
iov_len
-
offset
);
}
/** Check if bus address will be properly aligned after moving vector forward by @e len bytes */
static
inline
int
is_addr_aligned
(
const
struct
fvec
*
vec
,
size_t
len
)
{
int
ret
=
0
;
if
(
vec
->
iov_len
>=
len
)
{
if
(((
vec
->
iov_dma
+
len
)
%
ALIGNMENT_ADDR
)
==
0
)
ret
=
1
;
}
return
ret
;
}
static
size_t
align_address
(
struct
fvec
*
dest
,
struct
fvec
*
src
,
size_t
len
)
{
size_t
cut_bytes
=
(
src
->
iov_dma
+
len
)
%
ALIGNMENT_ADDR
;
size_t
pad_len
=
ALIGNMENT_SIZE
-
cut_bytes
;
if
(
pad_len
<=
len
)
{
len
-=
pad_len
;
}
if
(
len
!=
0
)
{
len
+=
cut_bytes
;
}
/* set marker length */
app15
[
3
]
=
pad_len
-
JPEG_MARKER_LEN
;
printk
(
KERN_DEBUG
">>> copy %u bytes from APP15 to other buffer
\n
"
,
pad_len
);
vectcpy
(
dest
,
app15
,
pad_len
);
return
len
;
}
static
void
align_frame
(
struct
device
*
dev
,
struct
elphel_ahci_priv
*
dpriv
)
{
int
i
;
int
is_delayed
=
0
;
unsigned
char
*
src
;
size_t
len
,
total_sz
,
data_len
;
...
...
@@ -778,332 +748,153 @@ static void align_frame(struct device *dev, struct elphel_ahci_priv *dpriv)
vectcpy
(
cbuff
,
chunks
[
CHUNK_HEADER
].
iov_base
,
len
);
vectshrink
(
&
chunks
[
CHUNK_HEADER
],
chunks
[
CHUNK_HEADER
].
iov_len
);
/* check if
we have enough data for further processing
*/
len
=
chunks
[
CHUNK_DATA_0
].
iov_len
+
chunks
[
CHUNK_DATA_1
].
iov_len
+
chunks
[
CHUNK_TRAILER
].
iov_len
;
/* check if
there is enough data to continue - JPEG data length can be too short
*/
len
=
get_size_from
(
chunks
,
CHUNK_DATA_0
,
0
,
EXCLUDE_REM
)
;
if
(
len
<
PHY_BLOCK_SIZE
)
{
data_len
=
cbuff
->
iov_len
%
PHY_BLOCK_SIZE
;
dev_dbg
(
dev
,
"JPEG data size is too small: %u; unaligned data length: %u
\n
"
,
len
,
data_len
);
if
(
data_len
+
len
<=
fbuffs
->
rem_buff
.
iov_len
)
{
/* place data to REM buffer and continue */
src
=
vectrpos
(
cbuff
,
data_len
);
printk
(
KERN_DEBUG
">>> 5.0.1 copy %u bytes from COMMON to REM buffer
\n
"
,
len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
src
,
data_len
);
vectshrink
(
cbuff
,
data_len
);
printk
(
KERN_DEBUG
">>> 5.0.1 copy %u bytes from DATA_0 to REM buffer
\n
"
,
len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_DATA_0
].
iov_base
,
chunks
[
CHUNK_DATA_0
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_0
],
chunks
[
CHUNK_DATA_0
].
iov_len
);
printk
(
KERN_DEBUG
">>> 5.0.1 copy %u bytes from DATA_1 to REM buffer
\n
"
,
len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_DATA_1
].
iov_base
,
chunks
[
CHUNK_DATA_1
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_1
],
chunks
[
CHUNK_DATA_1
].
iov_len
);
printk
(
KERN_DEBUG
">>> 5.0.1 copy %u bytes from TRAILER to REM buffer
\n
"
,
len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_TRAILER
].
iov_base
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_TRAILER
],
chunks
[
CHUNK_TRAILER
].
iov_len
);
}
else
{
/* the REM buffer is too short, process some buffers to align COMMON buffer to sector boundary */
dev_dbg
(
dev
,
"REM buffer is too short, align COMMON to sector boundary
\n
"
);
data_len
=
PHY_BLOCK_SIZE
-
data_len
;
if
(
data_len
>=
chunks
[
CHUNK_DATA_0
].
iov_len
)
{
/* copy whole DATA_0 to COMMON */
printk
(
KERN_DEBUG
">>> 5.0.2 copy %u bytes from DATA_0 to COMMON buffer
\n
"
,
chunks
[
CHUNK_DATA_0
].
iov_len
);
size_t
num
=
align_bytes_num
(
cbuff
->
iov_len
,
PHY_BLOCK_SIZE
);
if
(
len
>=
num
)
{
/* there is enough data to align common buffer to sector boundary */
if
(
num
>=
chunks
[
CHUNK_DATA_0
].
iov_len
)
{
printk
(
KERN_DEBUG
">>> copy %u bytes from DATA_0 to common buffer
\n
"
,
chunks
[
CHUNK_DATA_0
].
iov_len
);
vectcpy
(
cbuff
,
chunks
[
CHUNK_DATA_0
].
iov_base
,
chunks
[
CHUNK_DATA_0
].
iov_len
);
data_len
-=
chunks
[
CHUNK_DATA_0
].
iov_len
;
num
-=
chunks
[
CHUNK_DATA_0
].
iov_len
;
vectshrink
(
&
chunks
[
CHUNK_DATA_0
],
chunks
[
CHUNK_DATA_0
].
iov_len
);
}
else
{
/* copy a part of DATA_0 to COMMON */
printk
(
KERN_DEBUG
">>> 5.0.2 copy %u bytes from DATA_0 to COMMON buffer
\n
"
,
data_len
);
src
=
vectrpos
(
&
chunks
[
CHUNK_DATA_0
],
data_len
);
vectcpy
(
cbuff
,
src
,
data_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_0
],
data_len
);
data_len
=
0
;
}
if
(
data_len
!=
0
)
{
if
(
data_len
>=
chunks
[
CHUNK_DATA_1
].
iov_len
)
{
/* copy whole DATA_1 to COMMON */
printk
(
KERN_DEBUG
">>> 5.0.2 copy %u bytes from DATA_1 to COMMON buffer
\n
"
,
chunks
[
CHUNK_DATA_1
].
iov_len
);
vectcpy
(
cbuff
,
chunks
[
CHUNK_DATA_1
].
iov_base
,
chunks
[
CHUNK_DATA_1
].
iov_len
);
data_len
-=
chunks
[
CHUNK_DATA_1
].
iov_len
;
vectshrink
(
&
chunks
[
CHUNK_DATA_1
],
chunks
[
CHUNK_DATA_1
].
iov_len
);
}
else
{
/* copy a part of DATA_1 to COMMON */
printk
(
KERN_DEBUG
">>> 5.0.2 copy %u bytes from DATA_1 to COMMON buffer
\n
"
,
data_len
);
src
=
vectrpos
(
&
chunks
[
CHUNK_DATA_1
],
data_len
);
vectcpy
(
cbuff
,
src
,
data_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_1
],
data_len
);
data_len
=
0
;
}
if
(
data_len
!=
0
)
{
/* copy a part of TRAILER to COMMON */
printk
(
KERN_DEBUG
">>> 5.0.2 copy %u bytes from TRAILER to COMMON buffer
\n
"
,
data_len
);
src
=
vectrpos
(
&
chunks
[
CHUNK_TRAILER
],
data_len
);
vectcpy
(
cbuff
,
src
,
data_len
);
vectshrink
(
&
chunks
[
CHUNK_TRAILER
],
data_len
);
data_len
=
0
;
}
}
/* COMMON buffer is aligned to sector boundary, copy all other data to REM buffer */
if
(
chunks
[
CHUNK_DATA_0
].
iov_len
!=
0
)
{
printk
(
KERN_DEBUG
">>> 5.0.3 copy %u bytes from DATA_0 to REM buffer
\n
"
,
chunks
[
CHUNK_DATA_0
].
iov_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_DATA_0
].
iov_base
,
chunks
[
CHUNK_DATA_0
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_0
],
chunks
[
CHUNK_DATA_0
].
iov_len
);
}
if
(
chunks
[
CHUNK_DATA_1
].
iov_len
!=
0
)
{
printk
(
KERN_DEBUG
">>> 5.0.3 copy %u bytes from DATA_1 to REM buffer
\n
"
,
chunks
[
CHUNK_DATA_1
].
iov_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_DATA_1
].
iov_base
,
chunks
[
CHUNK_DATA_1
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_1
],
chunks
[
CHUNK_DATA_1
].
iov_len
);
}
if
(
chunks
[
CHUNK_TRAILER
].
iov_len
!=
0
)
{
printk
(
KERN_DEBUG
">>> 5.0.3 copy %u bytes from TRAILER to REM buffer
\n
"
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_TRAILER
].
iov_base
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_TRAILER
],
chunks
[
CHUNK_TRAILER
].
iov_len
);
}
}
return
;
}
/* there is enough data in data buffers, align common buffer */
len
=
align_bytes_num
(
cbuff
->
iov_len
,
ALIGNMENT_SIZE
);
if
(
likely
(
len
!=
0
))
{
dev_dbg
(
dev
,
"align COMMON buffer, add %u bytes from other buffers
\n
"
,
len
);
if
((
len
+
ALIGNMENT_ADDR
)
<=
chunks
[
CHUNK_DATA_0
].
iov_len
)
{
printk
(
KERN_DEBUG
">>> check alignment of DMA address: 0x%x
\n
"
,
chunks
[
CHUNK_DATA_0
].
iov_dma
);
if
(
is_addr_aligned
(
&
chunks
[
CHUNK_DATA_0
],
len
)
==
0
)
{
/* we are going to copy =len= bytes from DATA_0 buffer to align COMMON buffer to
* ALIGNMNET_SIZE boundary which will make the starting address of DATA_0 buffer
* unaligned to ALIGNMENT_ADDR boundary, fix this by moving additional bytes from
* the beginning of DATA_0 buffer and padding COMMON buffer with APP15 marker */
len
=
align_address
(
cbuff
,
&
chunks
[
CHUNK_DATA_0
],
len
);
}
printk
(
KERN_DEBUG
">>> 5.1.1 copy %u bytes from DATA_0 to common buffer
\n
"
,
len
);
vectcpy
(
cbuff
,
chunks
[
CHUNK_DATA_0
].
iov_base
,
len
);
vectmov
(
&
chunks
[
CHUNK_DATA_0
],
len
);
}
else
{
/* handle special case: JPEG data rolls over circular buffer boundary and the
* data chunk in the end of the buffer is less than we need for alignment; copy
* all data from first chunk, discard it, copy remainder from second chunk
* and from trailer if needed
*/
if
(
len
<=
(
chunks
[
CHUNK_DATA_0
].
iov_len
+
chunks
[
CHUNK_DATA_1
].
iov_len
+
chunks
[
CHUNK_TRAILER
].
iov_len
+
ALIGNMENT_ADDR
))
{
printk
(
KERN_DEBUG
">>> 5.2 copy %u bytes from DATA_0 to common buffer
\n
"
,
chunks
[
CHUNK_DATA_0
].
iov_len
);
vectcpy
(
cbuff
,
chunks
[
CHUNK_DATA_0
].
iov_base
,
chunks
[
CHUNK_DATA_0
].
iov_len
);
len
-=
chunks
[
CHUNK_DATA_0
].
iov_len
;
vectshrink
(
&
chunks
[
CHUNK_DATA_0
],
chunks
[
CHUNK_DATA_0
].
iov_len
);
if
(
chunks
[
CHUNK_DATA_1
].
iov_len
>=
len
)
{
printk
(
KERN_DEBUG
">>> check alignment of DMA address: 0x%x
\n
"
,
chunks
[
CHUNK_DATA_1
].
iov_dma
);
if
(
is_addr_aligned
(
&
chunks
[
CHUNK_DATA_1
],
len
)
==
0
)
{
len
=
align_address
(
cbuff
,
&
chunks
[
CHUNK_DATA_1
],
len
);
}
printk
(
KERN_DEBUG
">>> 5.2.4 copy %u bytes from DATA_1 to common buffer
\n
"
,
len
);
vectcpy
(
cbuff
,
chunks
[
CHUNK_DATA_1
].
iov_base
,
len
);
vectmov
(
&
chunks
[
CHUNK_DATA_1
],
len
);
len
=
0
;
}
else
{
printk
(
KERN_DEBUG
">>> 5.2.5 copy %u bytes from DATA_1 to common buffer
\n
"
,
chunks
[
CHUNK_DATA_1
].
iov_len
);
printk
(
KERN_DEBUG
">>> copy %u bytes from DATA_0 to common buffer
\n
"
,
num
);
src
=
vectrpos
(
&
chunks
[
CHUNK_DATA_0
],
num
);
vectcpy
(
cbuff
,
chunks
[
CHUNK_DATA_0
].
iov_base
,
num
);
vectshrink
(
&
chunks
[
CHUNK_DATA_0
],
num
);
num
=
0
;
}
if
(
num
>=
chunks
[
CHUNK_DATA_1
].
iov_len
)
{
printk
(
KERN_DEBUG
">>> copy %u bytes from DATA_1 to common buffer
\n
"
,
chunks
[
CHUNK_DATA_1
].
iov_len
);
vectcpy
(
cbuff
,
chunks
[
CHUNK_DATA_1
].
iov_base
,
chunks
[
CHUNK_DATA_1
].
iov_len
);
len
-=
chunks
[
CHUNK_DATA_1
].
iov_len
;
num
-=
chunks
[
CHUNK_DATA_1
].
iov_len
;
vectshrink
(
&
chunks
[
CHUNK_DATA_1
],
chunks
[
CHUNK_DATA_1
].
iov_len
);
}
if
(
chunks
[
CHUNK_TRAILER
].
iov_len
>=
len
)
{
printk
(
KERN_DEBUG
">>> 5.2.6 copy %u bytes from TRAILER to common buffer
\n
"
,
len
);
vectcpy
(
cbuff
,
chunks
[
CHUNK_TRAILER
].
iov_base
,
len
);
vectmov
(
&
chunks
[
CHUNK_TRAILER
],
len
);
len
=
0
;
}
else
{
printk
(
KERN_DEBUG
">>> 5.2.7 copy %u bytes from TRAILER to common buffer
\n
"
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
printk
(
KERN_DEBUG
">>> copy %u bytes from DATA_1 to common buffer
\n
"
,
num
);
src
=
vectrpos
(
&
chunks
[
CHUNK_DATA_1
],
num
);
vectcpy
(
cbuff
,
chunks
[
CHUNK_DATA_1
].
iov_base
,
num
);
vectshrink
(
&
chunks
[
CHUNK_DATA_1
],
num
);
num
=
0
;
}
if
(
num
>=
chunks
[
CHUNK_TRAILER
].
iov_len
)
{
printk
(
KERN_DEBUG
">>> copy %u bytes from TRAILER to common buffer
\n
"
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectcpy
(
cbuff
,
chunks
[
CHUNK_TRAILER
].
iov_base
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
len
-=
chunks
[
CHUNK_TRAILER
].
iov_len
;
num
-=
chunks
[
CHUNK_TRAILER
].
iov_len
;
vectshrink
(
&
chunks
[
CHUNK_TRAILER
],
chunks
[
CHUNK_TRAILER
].
iov_len
);
}
else
{
printk
(
KERN_DEBUG
">>> copy %u bytes from TRAILER to common buffer
\n
"
,
num
);
src
=
vectrpos
(
&
chunks
[
CHUNK_TRAILER
],
num
);
vectcpy
(
cbuff
,
chunks
[
CHUNK_TRAILER
].
iov_base
,
num
);
vectshrink
(
&
chunks
[
CHUNK_TRAILER
],
num
);
num
=
0
;
}
}
else
{
/* JPEG data is too short, place all to remainder
buffer */
/* there is not enough data to align common buffer to sector boundary, truncate common
buffer */
data_len
=
cbuff
->
iov_len
%
PHY_BLOCK_SIZE
;
src
=
vectrpos
(
cbuff
,
data_len
);
printk
(
KERN_DEBUG
">>>
5.2.1
copy %u bytes from COMMON to REM buffer
\n
"
,
data_len
);
printk
(
KERN_DEBUG
">>> copy %u bytes from COMMON to REM buffer
\n
"
,
data_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
src
,
data_len
);
vectshrink
(
cbuff
,
data_len
);
printk
(
KERN_DEBUG
">>> 5.2.1 copy %u bytes from DATA_0 to REM buffer
\n
"
,
chunks
[
CHUNK_DATA_0
].
iov_len
);
}
printk
(
KERN_DEBUG
">>> copy %u bytes from DATA_0 to REM buffer
\n
"
,
chunks
[
CHUNK_DATA_0
].
iov_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_DATA_0
].
iov_base
,
chunks
[
CHUNK_DATA_0
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_0
],
chunks
[
CHUNK_DATA_0
].
iov_len
);
printk
(
KERN_DEBUG
">>>
5.2.1
copy %u bytes from DATA_1 to REM buffer
\n
"
,
chunks
[
CHUNK_DATA_1
].
iov_len
);
printk
(
KERN_DEBUG
">>> copy %u bytes from DATA_1 to REM buffer
\n
"
,
chunks
[
CHUNK_DATA_1
].
iov_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_DATA_1
].
iov_base
,
chunks
[
CHUNK_DATA_1
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_1
],
chunks
[
CHUNK_DATA_1
].
iov_len
);
printk
(
KERN_DEBUG
">>>
5.2.1
copy %u bytes from TRAILER to REM buffer
\n
"
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
printk
(
KERN_DEBUG
">>> copy %u bytes from TRAILER to REM buffer
\n
"
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_TRAILER
].
iov_base
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_TRAILER
],
chunks
[
CHUNK_TRAILER
].
iov_len
);
return
;
}
/* align common buffer to ALIGNMENT boundary */
len
=
align_bytes_num
(
cbuff
->
iov_len
,
ALIGNMENT_SIZE
);
if
(
len
<
JPEG_MARKER_LEN
+
JPEG_SIZE_LEN
)
{
/* the number of bytes needed for alignment is less than the length of the marker itself, increase the number of stuffing bytes */
len
+=
ALIGNMENT_SIZE
;
}
}
dev_dbg
(
dev
,
"total number of stuffing bytes in APP15 marker: %u
\n
"
,
len
);
app15
[
3
]
=
len
-
JPEG_MARKER_LEN
;
vectcpy
(
cbuff
,
app15
,
len
);
/* JPEG header and Exif data is aligned to ALIGNMENT_SIZE boundary in a common buffer now,
* the entire frame should be aligned to physical sector boundary and remainder should be
* copied to a buffer for recording during next frame */
/* align frame to sector size boundary; total size could have changed by the moment - recalculate */
total_sz
=
get_size_from
(
chunks
,
0
,
0
,
INCLUDE_REM
);
len
=
total_sz
%
PHY_BLOCK_SIZE
;
chunks
[
CHUNK_ALIGN_0
].
iov_base
=
(
unsigned
char
*
)
cbuff
->
iov_base
+
cbuff
->
iov_len
;
chunks
[
CHUNK_ALIGN_0
].
iov_len
=
0
;
dev_dbg
(
dev
,
"total frame size: %u, unaligned bytes to sector boundary: %u
\n
"
,
total_sz
,
len
);
if
(
likely
(
chunks
[
CHUNK_DATA_1
].
iov_len
==
0
))
{
/* JPEG data is not split, align just one buffer to physical sector boundary if it is not already aligned */
if
(
chunks
[
CHUNK_DATA_0
].
iov_len
+
chunks
[
CHUNK_TRAILER
].
iov_len
>=
len
)
{
if
(
likely
(
len
>=
chunks
[
CHUNK_TRAILER
].
iov_len
))
{
data_len
=
len
-
chunks
[
CHUNK_TRAILER
].
iov_len
;
src
=
vectrpos
(
&
chunks
[
CHUNK_DATA_0
],
data_len
);
printk
(
KERN_DEBUG
">>> 6.1 copy %u bytes from DATA_0 to remainder buffer
\n
"
,
data_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
src
,
data_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_0
],
data_len
);
printk
(
KERN_DEBUG
">>> 6.1 copy %u bytes from TRAILER to remainder buffer
\n
"
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_TRAILER
].
iov_base
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_TRAILER
],
chunks
[
CHUNK_TRAILER
].
iov_len
);
}
else
{
/* align DATA_0 buffer, break trailing marker and place first part to ALIGN_0 buffer and second part to REM */
data_len
=
chunks
[
CHUNK_DATA_0
].
iov_len
%
ALIGNMENT_SIZE
;
printk
(
KERN_DEBUG
">>> 6.1.2 copy %u bytes from DATA_0 to ALIGN_0 buffer
\n
"
,
data_len
);
src
=
vectrpos
(
&
chunks
[
CHUNK_DATA_0
],
data_len
);
vectcpy
(
&
chunks
[
CHUNK_ALIGN_0
],
src
,
data_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_0
],
data_len
);
if
(
len
==
0
)
len
=
chunks
[
CHUNK_TRAILER
].
iov_len
;
printk
(
KERN_DEBUG
">>> 6.1.2 copy %u bytes from TRAILER to ALIGN_0 buffer
\n
"
,
len
);
vectcpy
(
&
chunks
[
CHUNK_ALIGN_0
],
chunks
[
CHUNK_TRAILER
].
iov_base
,
len
);
vectmov
(
&
chunks
[
CHUNK_TRAILER
],
len
);
printk
(
KERN_DEBUG
">>> 6.1.2 copy %u bytes from TRAILER to remainder buffer
\n
"
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_TRAILER
].
iov_base
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_TRAILER
],
chunks
[
CHUNK_TRAILER
].
iov_len
);
}
}
else
{
/* the number of bytes needed to align to sector boundary is greater than the number of bytes left
* in DATA_0 and TRAILER buffers, realign COMMON buffer and delay DATA_0 and TRAILING buffers recording */
data_len
=
cbuff
->
iov_len
%
PHY_BLOCK_SIZE
;
printk
(
KERN_DEBUG
">>> 6.1.3 copy %u bytes from COMMON to remainder buffer
\n
"
,
data_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
cbuff
->
iov_base
,
data_len
);
vectshrink
(
cbuff
,
data_len
);
printk
(
KERN_DEBUG
">>> 6.1.3 copy %u bytes from DATA_0 to remainder buffer
\n
"
,
chunks
[
CHUNK_DATA_0
].
iov_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_DATA_0
].
iov_base
,
chunks
[
CHUNK_DATA_0
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_0
],
chunks
[
CHUNK_DATA_0
].
iov_len
);
printk
(
KERN_DEBUG
">>> 6.1.3 copy %u bytes from TRAILER to remainder buffer
\n
"
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_TRAILER
].
iov_base
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_TRAILER
],
chunks
[
CHUNK_TRAILER
].
iov_len
);
}
}
else
{
printk
(
KERN_DEBUG
">>> 6.2 <<<
\n
"
);
/* JPEG data rolls over circular buffer boundary */
struct
kvec
data_rem
;
data_len
=
chunks
[
CHUNK_DATA_0
].
iov_len
%
ALIGNMENT_SIZE
;
size_t
align_len
=
ALIGNMENT_SIZE
-
data_len
;
chunks
[
CHUNK_ALIGN_1
].
iov_base
=
(
unsigned
char
*
)
chunks
[
CHUNK_ALIGN_0
].
iov_base
+
chunks
[
CHUNK_ALIGN_0
].
iov_len
;
chunks
[
CHUNK_ALIGN_1
].
iov_len
=
0
;
if
(
chunks
[
CHUNK_DATA_1
].
iov_len
>=
len
+
align_len
)
{
/* DATA_1 buffer contains enough bytes to align frame to sector boundary,
* align DATA_0 buffer to ALIGNMENT_SIZE boundary only */
if
(
data_len
!=
0
)
{
printk
(
KERN_DEBUG
">>> 6.2 copy %u bytes from DATA_0 to ALIGN_0 buffer
\n
"
,
data_len
);
src
=
vectrpos
(
&
chunks
[
CHUNK_DATA_0
],
data_len
);
vectcpy
(
&
chunks
[
CHUNK_ALIGN_0
],
src
,
data_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_0
],
data_len
);
printk
(
KERN_DEBUG
">>> check alignment of DMA address: 0x%x
\n
"
,
chunks
[
CHUNK_DATA_1
].
iov_dma
);
if
(
is_addr_aligned
(
&
chunks
[
CHUNK_DATA_1
],
align_len
)
==
0
)
{
align_len
=
align_address
(
&
chunks
[
CHUNK_ALIGN_0
],
&
chunks
[
CHUNK_DATA_1
],
align_len
);
}
printk
(
KERN_DEBUG
">>> 6.2 copy %u bytes from DATA_1 to ALIGN_0 buffer
\n
"
,
align_len
);
vectcpy
(
&
chunks
[
CHUNK_ALIGN_0
],
chunks
[
CHUNK_DATA_1
].
iov_base
,
align_len
);
vectmov
(
&
chunks
[
CHUNK_DATA_1
],
align_len
);
/* adjust ALIGN_1 position */
chunks
[
CHUNK_ALIGN_1
].
iov_base
=
(
unsigned
char
*
)
chunks
[
CHUNK_ALIGN_0
].
iov_base
+
chunks
[
CHUNK_ALIGN_0
].
iov_len
;
chunks
[
CHUNK_ALIGN_1
].
iov_len
=
0
;
}
}
else
{
/* there is no enough data in the second JPEG data buffer, delay its recording and
* align first buffer to physical sector boundary */
data_len
=
(
cbuff
->
iov_len
+
chunks
[
CHUNK_DATA_0
].
iov_len
)
%
PHY_BLOCK_SIZE
;
printk
(
KERN_DEBUG
">>> 6.2.2 align to data_len: %u
\n
"
,
data_len
);
if
(
data_len
<=
chunks
[
CHUNK_DATA_0
].
iov_len
)
{
dev_dbg
(
dev
,
"number of bytes crossing sector boundary: %u
\n
"
,
len
);
if
(
len
!=
0
)
{
if
(
len
>=
(
chunks
[
CHUNK_DATA_1
].
iov_len
+
chunks
[
CHUNK_TRAILER
].
iov_len
))
{
/* current frame is not split or the second part of JPEG data is too short */
data_len
=
len
-
chunks
[
CHUNK_DATA_1
].
iov_len
-
chunks
[
CHUNK_TRAILER
].
iov_len
;
src
=
vectrpos
(
&
chunks
[
CHUNK_DATA_0
],
data_len
);
printk
(
KERN_DEBUG
">>>
6.2.2
copy %u bytes from DATA_0 to REM buffer
\n
"
,
data_len
);
printk
(
KERN_DEBUG
">>>
5.1
copy %u bytes from DATA_0 to REM buffer
\n
"
,
data_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
src
,
data_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_0
],
data_len
);
}
else
{
data_len
-=
chunks
[
CHUNK_DATA_0
].
iov_len
;
src
=
vectrpos
(
cbuff
,
data_len
);
printk
(
KERN_DEBUG
">>> 6.2.2 copy %u bytes from COMMON to REM buffer
\n
"
,
data_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
cbuff
->
iov_base
,
data_len
);
vectshrink
(
cbuff
,
data_len
);
printk
(
KERN_DEBUG
">>> 6.2.2 copy %u bytes from DATA_0 to REM buffer
\n
"
,
chunks
[
CHUNK_DATA_0
].
iov_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_DATA_0
].
iov_base
,
chunks
[
CHUNK_DATA_0
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_0
],
chunks
[
CHUNK_DATA_0
].
iov_len
);
/* COMMON buffer has been updated, adjust ALIGN_0 and ALIGN_1 position */
chunks
[
CHUNK_ALIGN_1
].
iov_base
=
(
unsigned
char
*
)
chunks
[
CHUNK_ALIGN_0
].
iov_base
+
chunks
[
CHUNK_ALIGN_0
].
iov_len
;
chunks
[
CHUNK_ALIGN_1
].
iov_len
=
0
;
chunks
[
CHUNK_ALIGN_1
].
iov_base
=
(
unsigned
char
*
)
chunks
[
CHUNK_ALIGN_0
].
iov_base
+
chunks
[
CHUNK_ALIGN_0
].
iov_len
;
chunks
[
CHUNK_ALIGN_1
].
iov_len
=
0
;
}
printk
(
KERN_DEBUG
">>> 6.2.2 copy %u bytes from DATA_1 to REM buffer
\n
"
,
chunks
[
CHUNK_DATA_1
].
iov_len
);
printk
(
KERN_DEBUG
">>> 5.1 copy %u bytes from DATA_1 to REM buffer
\n
"
,
chunks
[
CHUNK_DATA_1
].
iov_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_DATA_1
].
iov_base
,
chunks
[
CHUNK_DATA_1
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_1
],
chunks
[
CHUNK_DATA_1
].
iov_len
);
printk
(
KERN_DEBUG
">>>
6.2.2
copy %u bytes from TRAILER to REM buffer
\n
"
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
printk
(
KERN_DEBUG
">>>
5.1
copy %u bytes from TRAILER to REM buffer
\n
"
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_TRAILER
].
iov_base
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_TRAILER
],
chunks
[
CHUNK_TRAILER
].
iov_len
);
}
printk
(
KERN_DEBUG
">>> 6.3 <<<
\n
"
);
/* the total length could have changed by the moment, recalculate */
total_sz
=
get_size_from
(
chunks
,
0
,
0
,
INCLUDE_REM
);
len
=
total_sz
%
PHY_BLOCK_SIZE
;
dev_dbg
(
dev
,
"total frame size: %u, unaligned bytes to sector boundary: %u
\n
"
,
total_sz
,
len
);
if
(
chunks
[
CHUNK_DATA_1
].
iov_len
+
chunks
[
CHUNK_TRAILER
].
iov_len
>
len
)
{
if
(
len
>=
chunks
[
CHUNK_TRAILER
].
iov_len
)
{
/* DATA_1 and TRAILER buffers contain enough data to align the current frame to sector boundary */
}
else
if
(
len
>=
chunks
[
CHUNK_TRAILER
].
iov_len
)
{
/* there is enough data in second part to align the frame */
data_len
=
len
-
chunks
[
CHUNK_TRAILER
].
iov_len
;
printk
(
KERN_DEBUG
">>> 6.3.1 copy %u bytes from DATA_1 to REM buffer
\n
"
,
data_len
);
src
=
vectrpos
(
&
chunks
[
CHUNK_DATA_1
],
data_len
);
printk
(
KERN_DEBUG
">>> 5.2 copy %u bytes from DATA_1 to REM buffer
\n
"
,
data_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
src
,
data_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_1
],
data_len
);
printk
(
KERN_DEBUG
">>> 6.3.1 copy %u bytes from TRAILER to REM buffer
\n
"
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_TRAILER
].
iov_base
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_TRAILER
],
chunks
[
CHUNK_TRAILER
].
iov_len
);
}
else
if
(
len
!=
0
)
{
/* break trailing marker and copy the remaining data to REM buffer, align DATA_1 and TRAILER parts in
* ALIGN_1 buffer */
data_len
=
chunks
[
CHUNK_DATA_1
].
iov_len
%
ALIGNMENT_SIZE
;
printk
(
KERN_DEBUG
">>> 6.3.2 copy %u bytes from DATA_1 to ALIGN_1 buffer
\n
"
,
data_len
);
src
=
vectrpos
(
&
chunks
[
CHUNK_DATA_1
],
data_len
);
vectcpy
(
&
chunks
[
CHUNK_ALIGN_1
],
chunks
[
CHUNK_DATA_1
].
iov_base
,
data_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_1
],
data_len
);
printk
(
KERN_DEBUG
">>> 6.3.2 copy %u bytes from TRAILER to ALIGN_1 buffer
\n
"
,
len
);
vectcpy
(
&
chunks
[
CHUNK_ALIGN_1
],
chunks
[
CHUNK_TRAILER
].
iov_base
,
len
);
vectmov
(
&
chunks
[
CHUNK_TRAILER
],
len
);
printk
(
KERN_DEBUG
">>> 6.3.2 copy %u bytes from TRAILER to REM buffer
\n
"
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
printk
(
KERN_DEBUG
">>> 5.2 copy %u bytes from TRAILER to REM buffer
\n
"
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_TRAILER
].
iov_base
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_TRAILER
],
chunks
[
CHUNK_TRAILER
].
iov_len
);
}
else
{
/* the frame is aligned to sector boundary, but DATA_1 and TRAILER buffers may be
* unaligned to ALIGNMENT_SIZE boundary */
data_len
=
chunks
[
CHUNK_DATA_1
].
iov_len
%
ALIGNMENT_SIZE
;
if
(
data_len
>=
chunks
[
CHUNK_TRAILER
].
iov_len
)
{
printk
(
KERN_DEBUG
">>> 6.3.3 copy %u bytes from DATA_1 to ALIGN_1 buffer
\n
"
,
data_len
);
src
=
vectrpos
(
&
chunks
[
CHUNK_DATA_1
],
data_len
);
vectcpy
(
&
chunks
[
CHUNK_ALIGN_1
],
src
,
data_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_1
],
data_len
);
printk
(
KERN_DEBUG
">>> 6.3.3 copy %u bytes from TRAILER to ALIGN_1 buffer
\n
"
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectcpy
(
&
chunks
[
CHUNK_ALIGN_1
],
chunks
[
CHUNK_TRAILER
].
iov_base
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
/* the trailing marker is split by sector boundary, copy (PHY_BLOCK_SIZE - 1) bytes from
* JPEG data block(s) to remainder buffer and then add trailing marker */
data_len
=
PHY_BLOCK_SIZE
-
(
chunks
[
CHUNK_TRAILER
].
iov_len
-
len
);
if
(
data_len
>=
chunks
[
CHUNK_DATA_1
].
iov_len
)
{
size_t
cut_len
=
data_len
-
chunks
[
CHUNK_DATA_1
].
iov_len
;
src
=
vectrpos
(
&
chunks
[
CHUNK_DATA_0
],
cut_len
);
printk
(
KERN_DEBUG
">>> 5.3 copy %u bytes from DATA_0 to REM buffer
\n
"
,
cut_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
src
,
cut_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_0
],
cut_len
);
printk
(
KERN_DEBUG
">>> 5.3 copy %u bytes from DATA_1 to REM buffer
\n
"
,
chunks
[
CHUNK_DATA_1
].
iov_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_DATA_1
].
iov_base
,
chunks
[
CHUNK_DATA_1
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_1
],
chunks
[
CHUNK_DATA_1
].
iov_len
);
printk
(
KERN_DEBUG
">>> 5.3 copy %u bytes from TRAILER to REM buffer
\n
"
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_TRAILER
].
iov_base
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_TRAILER
],
chunks
[
CHUNK_TRAILER
].
iov_len
);
}
else
{
/* break trailing marker and copy the remaining data to REM buffer */
data_len
=
chunks
[
CHUNK_DATA_1
].
iov_len
%
ALIGNMENT_SIZE
-
len
;
printk
(
KERN_DEBUG
">>> 6.3.4 copy %u bytes from DATA_1 to ALIGN_1 buffer
\n
"
,
data_len
);
src
=
vectrpos
(
&
chunks
[
CHUNK_DATA_1
],
data_len
);
vectcpy
(
&
chunks
[
CHUNK_ALIGN_1
],
chunks
[
CHUNK_DATA_1
].
iov_base
,
data_len
);
printk
(
KERN_DEBUG
">>> 5.3 copy %u bytes from DATA_1 to REM buffer
\n
"
,
data_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
src
,
data_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_1
],
data_len
);
printk
(
KERN_DEBUG
">>> 6.3.4 copy %u bytes from TRAILER to ALIGN_1 buffer
\n
"
,
len
);
vectcpy
(
&
chunks
[
CHUNK_ALIGN_1
],
chunks
[
CHUNK_TRAILER
].
iov_base
,
len
);
vectmov
(
&
chunks
[
CHUNK_TRAILER
],
len
);
printk
(
KERN_DEBUG
">>> 6.3.4 copy %u bytes from TRAILER to REM buffer
\n
"
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
printk
(
KERN_DEBUG
">>> 5.3 copy %u bytes from TRAILER to REM buffer
\n
"
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectcpy
(
&
chunks
[
CHUNK_REM
],
chunks
[
CHUNK_TRAILER
].
iov_base
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_TRAILER
],
chunks
[
CHUNK_TRAILER
].
iov_len
);
}
}
}
else
{
/* the frame is aligned to sector boundary but some buffers may be not */
chunks
[
CHUNK_ALIGN
].
iov_base
=
vectrpos
(
cbuff
,
0
);
chunks
[
CHUNK_ALIGN
].
iov_len
=
0
;
if
(
chunks
[
CHUNK_DATA_1
].
iov_len
==
0
)
{
data_len
=
chunks
[
CHUNK_DATA_0
].
iov_len
%
ALIGNMENT_SIZE
;
src
=
vectrpos
(
&
chunks
[
CHUNK_DATA_0
],
data_len
);
printk
(
KERN_DEBUG
">>> 5.4 copy %u bytes from DATA_0 to ALIGN buffer
\n
"
,
data_len
);
vectcpy
(
&
chunks
[
CHUNK_ALIGN
],
src
,
data_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_0
],
data_len
);
}
else
{
data_len
=
chunks
[
CHUNK_DATA_1
].
iov_len
%
ALIGNMENT_SIZE
;
src
=
vectrpos
(
&
chunks
[
CHUNK_DATA_1
],
data_len
);
printk
(
KERN_DEBUG
">>> 5.4 copy %u bytes from DATA_1 to ALIGN buffer
\n
"
,
data_len
);
vectcpy
(
&
chunks
[
CHUNK_ALIGN
],
src
,
data_len
);
vectshrink
(
&
chunks
[
CHUNK_DATA_1
],
data_len
);
}
printk
(
KERN_DEBUG
">>> 5.4 copy %u bytes from TRAILER to ALIGN buffer
\n
"
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectcpy
(
&
chunks
[
CHUNK_ALIGN
],
chunks
[
CHUNK_TRAILER
].
iov_base
,
chunks
[
CHUNK_TRAILER
].
iov_len
);
vectshrink
(
&
chunks
[
CHUNK_TRAILER
],
chunks
[
CHUNK_TRAILER
].
iov_len
);
}
/* debug sanity check, should not happen */
...
...
@@ -1252,10 +1043,10 @@ static int init_buffers(struct device *dev, struct frame_buffers *buffs)
if
(
dma_mapping_error
(
dev
,
buffs
->
common_buff
.
iov_dma
))
goto
err_common_dma
;
buffs
->
rem_buff
.
iov_base
=
kmalloc
(
PHY_BLOCK_SIZE
,
GFP_KERNEL
);
buffs
->
rem_buff
.
iov_base
=
kmalloc
(
2
*
PHY_BLOCK_SIZE
,
GFP_KERNEL
);
if
(
!
buffs
->
rem_buff
.
iov_base
)
goto
err_remainder
;
buffs
->
rem_buff
.
iov_len
=
PHY_BLOCK_SIZE
;
buffs
->
rem_buff
.
iov_len
=
2
*
PHY_BLOCK_SIZE
;
/* debug code follows */
g_jpg_data_0
=
kzalloc
(
DATA_BUFF_SIZE
,
GFP_KERNEL
);
...
...
@@ -1460,7 +1251,6 @@ static ssize_t rawdev_write(struct device *dev, ///<
printk
(
KERN_DEBUG
">>> bytes received from exif driver: %u
\n
"
,
rcvd
);
if
(
rcvd
>
0
&&
rcvd
<
buffs
->
exif_buff
.
iov_len
)
// print_hex_dump_bytes("", DUMP_PREFIX_OFFSET, buffs->exif_buff.iov_base, rcvd);
printk
(
KERN_DEBUG
">>>
\t
skipped"
);
chunks
[
CHUNK_EXIF
].
iov_len
=
rcvd
;
// rcvd = jpeghead_get_data(fdata.sensor_port, buffs->jpheader_buff.iov_base, buffs->jpheader_buff.iov_len, 0);
...
...
src/drivers/ata/ahci_elphel.h
View file @
c92588c9
...
...
@@ -41,13 +41,11 @@
* trailing marker, and pointer to a buffer containing the remainder of a
* frame. Ten chunks of data in total.
* @todo Fix description */
#define MAX_DATA_CHUNKS
10
#define MAX_DATA_CHUNKS
9
/** Default port number */
#define DEFAULT_PORT_NUM 0
/** Align buffers length to this amount of bytes */
#define ALIGNMENT_SIZE 32
/** Address alignment boundary */
#define ALIGNMENT_ADDR 2
/** This structure holds raw device buffer pointers */
struct
drv_pointers
{
...
...
@@ -88,10 +86,9 @@ enum {
CHUNK_HEADER
,
CHUNK_COMMON
,
CHUNK_DATA_0
,
CHUNK_ALIGN_0
,
CHUNK_DATA_1
,
CHUNK_ALIGN_1
,
CHUNK_TRAILER
,
CHUNK_ALIGN
,
CHUNK_REM
};
...
...
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