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rotate.c
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rotate.c
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/*
* rotate.c
*
* Module for handling image rotation.
*
* Copyright 2004-2005, Per Jonsson (per@pjd.nu)
*
* This software is distributed under the GNU Public license
* Version 2. See also the file 'COPYING'.
*
* Image rotation is a feature of Motion that can be used when the
* camera is mounted upside-down or on the side. The module only
* supports rotation in multiples of 90 degrees. Using rotation
* increases the Motion CPU usage slightly.
*
* Version history:
* v6 (29-Aug-2005) - simplified the code as Motion now requires
* that width and height are multiples of 16
* v5 (3-Aug-2005) - cleanup in code comments
* - better adherence to coding standard
* - fix for __bswap_32 macro collision
* - fixed bug where initialization would be
* incomplete for invalid degrees of rotation
* - now uses MOTION_LOG for error reporting
* v4 (26-Oct-2004) - new fix for width/height from imgs/conf due to
* earlier misinterpretation
* v3 (11-Oct-2004) - cleanup of width/height from imgs/conf
* v2 (26-Sep-2004) - separation of capture/internal dimensions
* - speed optimization, including bswap
* v1 (28-Aug-2004) - initial version
*/
#include "rotate.h"
#ifndef __uint32
/**
* We don't have a 32-bit unsigned integer type, so define it, given
* a 32-bit type was found by configure.
*/
# ifdef TYPE_32BIT
typedef unsigned TYPE_32BIT __uint32;
# else
# error "Failed to find a 32-bit integer type."
# endif
#endif
/*=============================================================================
Start of code from bits/byteswap.h
=============================================================================*/
/**
* The code below is copied (with modification) from bits/byteswap.h. It provides
* a macro/function named rot__bswap_32 that swaps the bytes in a 32-bit integer,
* preferably using the bswap assembler instruction if configure found support
* for it.
*
* It would be neater to simply include byteswap.h and use the bswap_32 macro
* defined there, but the problem is that the bswap asm instruction would then
* only be used for certain processor architectures, excluding athlon (and
* probably athlon64 as well). Moreover, byteswap.h doesn't seem to exist on
* FreeBSD. So, we rely on the HAVE_BSWAP macro defined by configure instead.
*
* Note that the macro names have been prefixed with "rot" in order to avoid
* collision since we have the include chain rotate.h -> motion.h -> netcam.h ->
* netinet/in.h -> ... -> byteswap.h -> bits/byteswap.h.
*/
/* Swap bytes in 32 bit value. This is used as a fallback and for constants. */
#define rot__bswap_constant_32(x) \
((((x) & 0xff000000) >> 24) | (((x) & 0x00ff0000) >> 8) | \
(((x) & 0x0000ff00) << 8) | (((x) & 0x000000ff) << 24))
#ifdef __GNUC__
# if (__GNUC__ >= 2) && (i386 || __i386 || __i386__)
/* We're on an Intel-compatible platform, so we can use inline Intel assembler
* for the swapping.
*/
# ifndef HAVE_BSWAP
/* Bswap is not available, we have to use three instructions instead. */
# define rot__bswap_32(x) \
(__extension__ \
({ register __uint32 __v, __x = (x); \
if (__builtin_constant_p (__x)) \
__v = rot__bswap_constant_32 (__x); \
else \
__asm__ ("rorw $8, %w0;" \
"rorl $16, %0;" \
"rorw $8, %w0" \
: "=r" (__v) \
: "0" (__x) \
: "cc"); \
__v; }))
# else
# define rot__bswap_32(x) \
(__extension__ \
({ register __uint32 __v, __x = (x); \
if (__builtin_constant_p (__x)) \
__v = rot__bswap_constant_32 (__x); \
else \
__asm__ ("bswap %0" : "=r" (__v) : "0" (__x)); \
__v; }))
# endif
# else
/* Non-Intel platform or too old version of gcc. */
# define rot__bswap_32(x) \
(__extension__ \
({ register __uint32 __x = (x); \
rot__bswap_constant_32 (__x); }))
# endif
#else
/* Not a GNU compiler. */
static inline __uint32 rot__bswap_32(__uint32 __bsx)
{
return __bswap_constant_32 (__bsx);
}
#endif
/*=============================================================================
End of code from bits/byteswap.h
=============================================================================*/
/* Finally define a macro with a more appropriate name, to be used below. */
#define swap_bytes(x) rot__bswap_32(x)
/**
* reverse_inplace_quad
*
* Reverses a block of memory in-place, 4 bytes at a time. This function
* requires the __uint32 type, which is 32 bits wide.
*
* Parameters:
*
* src - the memory block to reverse
* size - the size (in bytes) of the memory block
*
* Returns: nothing
*/
static void reverse_inplace_quad(unsigned char *src, int size)
{
__uint32 *nsrc = (__uint32 *)src; /* first quad */
__uint32 *ndst = (__uint32 *)(src + size - 4); /* last quad */
register __uint32 tmp;
while (nsrc < ndst) {
tmp = swap_bytes(*ndst);
*ndst-- = swap_bytes(*nsrc);
*nsrc++ = tmp;
}
}
/**
* rot90cw
*
* Performs a 90 degrees clockwise rotation of the memory block pointed to
* by src. The rotation is NOT performed in-place; dst must point to a
* receiving memory block the same size as src.
*
* Parameters:
*
* src - pointer to the memory block (image) to rotate clockwise
* dst - where to put the rotated memory block
* size - the size (in bytes) of the memory blocks (both src and dst)
* width - the width of the memory block when seen as an image
* height - the height of the memory block when seen as an image
*
* Returns: nothing
*/
static void rot90cw(unsigned char *src, register unsigned char *dst, int size,
int width, int height)
{
unsigned char *endp;
register unsigned char *base;
int j;
endp = src + size;
for (base = endp - width; base < endp; base++) {
src = base;
for (j = 0; j < height; j++, src -= width)
*dst++ = *src;
}
}
/**
* rot90ccw
*
* Performs a 90 degrees counterclockwise rotation of the memory block pointed
* to by src. The rotation is not performed in-place; dst must point to a
* receiving memory block the same size as src.
*
* Parameters:
*
* src - pointer to the memory block (image) to rotate counterclockwise
* dst - where to put the rotated memory block
* size - the size (in bytes) of the memory blocks (both src and dst)
* width - the width of the memory block when seen as an image
* height - the height of the memory block when seen as an image
*
* Returns: nothing
*/
static inline void rot90ccw(unsigned char *src, register unsigned char *dst,
int size, int width, int height)
{
unsigned char *endp;
register unsigned char *base;
int j;
endp = src + size;
dst = dst + size - 1;
for (base = endp - width; base < endp; base++) {
src = base;
for (j = 0; j < height; j++, src -= width)
*dst-- = *src;
}
}
/**
* rotate_init
*
* Initializes rotation data - allocates memory and determines which function
* to use for 180 degrees rotation.
*
* Parameters:
*
* cnt - the current thread's context structure
*
* Returns: nothing
*/
void rotate_init(struct context *cnt)
{
int size;
/* Make sure temp_buf isn't freed if it hasn't been allocated. */
cnt->rotate_data.temp_buf = NULL;
/*
* Assign the value in conf.rotate_deg to rotate_data.degrees. This way,
* we have a value that is safe from changes caused by motion-control.
*/
if ((cnt->conf.rotate_deg % 90) > 0) {
MOTION_LOG(WRN, TYPE_ALL, NO_ERRNO, "%s: Config option \"rotate\" not a multiple of 90: %d",
cnt->conf.rotate_deg);
cnt->conf.rotate_deg = 0; /* Disable rotation. */
cnt->rotate_data.degrees = 0; /* Force return below. */
} else {
cnt->rotate_data.degrees = cnt->conf.rotate_deg % 360; /* Range: 0..359 */
}
/*
* Upon entrance to this function, imgs.width and imgs.height contain the
* capture dimensions (as set in the configuration file, or read from a
* netcam source).
*
* If rotating 90 or 270 degrees, the capture dimensions and output dimensions
* are not the same. Capture dimensions will be contained in cap_width and
* cap_height in cnt->rotate_data, while output dimensions will be contained
* in imgs.width and imgs.height.
*/
/* 1. Transfer capture dimensions into cap_width and cap_height. */
cnt->rotate_data.cap_width = cnt->imgs.width;
cnt->rotate_data.cap_height = cnt->imgs.height;
if ((cnt->rotate_data.degrees == 90) || (cnt->rotate_data.degrees == 270)) {
/* 2. "Swap" imgs.width and imgs.height. */
cnt->imgs.width = cnt->rotate_data.cap_height;
cnt->imgs.height = cnt->rotate_data.cap_width;
}
/*
* If we're not rotating, let's exit once we have setup the capture dimensions
* and output dimensions properly.
*/
if (cnt->rotate_data.degrees == 0)
return;
switch (cnt->imgs.type) {
case VIDEO_PALETTE_YUV420P:
/*
* For YUV 4:2:0 planar, the memory block used for 90/270 degrees
* rotation needs to be width x height x 1.5 bytes large.
*/
size = cnt->imgs.width * cnt->imgs.height * 3 / 2;
break;
case VIDEO_PALETTE_GREY:
/*
* For greyscale, the memory block used for 90/270 degrees rotation
* needs to be width x height bytes large.
*/
size = cnt->imgs.width * cnt->imgs.height;
break;
default:
cnt->rotate_data.degrees = 0;
MOTION_LOG(WRN, TYPE_ALL, NO_ERRNO, "%s: Unsupported palette (%d), rotation is disabled",
cnt->imgs.type);
return;
}
/*
* Allocate memory if rotating 90 or 270 degrees, because those rotations
* cannot be performed in-place (they can, but it would be too slow).
*/
if ((cnt->rotate_data.degrees == 90) || (cnt->rotate_data.degrees == 270))
cnt->rotate_data.temp_buf = mymalloc(size);
}
/**
* rotate_deinit
*
* Frees resources previously allocated by rotate_init.
*
* Parameters:
*
* cnt - the current thread's context structure
*
* Returns: nothing
*/
void rotate_deinit(struct context *cnt)
{
if (cnt->rotate_data.temp_buf)
free(cnt->rotate_data.temp_buf);
}
/**
* rotate_map
*
* Main entry point for rotation. This is the function that is called from
* video.c/video_freebsd.c to perform the rotation.
*
* Parameters:
*
* map - pointer to the image/data to rotate
* cnt - the current thread's context structure
*
* Returns:
*
* 0 - success
* -1 - failure (shouldn't happen)
*/
int rotate_map(struct context *cnt, unsigned char *map)
{
/*
* The image format is either YUV 4:2:0 planar, in which case the pixel
* data is divided in three parts:
* Y - width x height bytes
* U - width x height / 4 bytes
* V - as U
* or, it is in greyscale, in which case the pixel data simply consists
* of width x height bytes.
*/
int wh, wh4 = 0, w2 = 0, h2 = 0; /* width * height, width * height / 4 etc. */
int size, deg;
int width, height;
deg = cnt->rotate_data.degrees;
width = cnt->rotate_data.cap_width;
height = cnt->rotate_data.cap_height;
/*
* Pre-calculate some stuff:
* wh - size of the Y plane, or the entire greyscale image
* size - size of the entire memory block
* wh4 - size of the U plane, and the V plane
* w2 - width of the U plane, and the V plane
* h2 - as w2, but height instead
*/
wh = width * height;
if (cnt->imgs.type == VIDEO_PALETTE_YUV420P) {
size = wh * 3 / 2;
wh4 = wh / 4;
w2 = width / 2;
h2 = height / 2;
} else { /* VIDEO_PALETTE_GREY */
size = wh;
}
switch (deg) {
case 90:
/* First do the Y part */
rot90cw(map, cnt->rotate_data.temp_buf, wh, width, height);
if (cnt->imgs.type == VIDEO_PALETTE_YUV420P) {
/* Then do U and V */
rot90cw(map + wh, cnt->rotate_data.temp_buf + wh, wh4, w2, h2);
rot90cw(map + wh + wh4, cnt->rotate_data.temp_buf + wh + wh4,
wh4, w2, h2);
}
/* Then copy back from the temp buffer to map. */
memcpy(map, cnt->rotate_data.temp_buf, size);
break;
case 180:
/*
* 180 degrees is easy - just reverse the data within
* Y, U and V.
*/
reverse_inplace_quad(map, wh);
if (cnt->imgs.type == VIDEO_PALETTE_YUV420P) {
reverse_inplace_quad(map + wh, wh4);
reverse_inplace_quad(map + wh + wh4, wh4);
}
break;
case 270:
/* First do the Y part */
rot90ccw(map, cnt->rotate_data.temp_buf, wh, width, height);
if (cnt->imgs.type == VIDEO_PALETTE_YUV420P) {
/* Then do U and V */
rot90ccw(map + wh, cnt->rotate_data.temp_buf + wh, wh4, w2, h2);
rot90ccw(map + wh + wh4, cnt->rotate_data.temp_buf + wh + wh4,
wh4, w2, h2);
}
/* Then copy back from the temp buffer to map. */
memcpy(map, cnt->rotate_data.temp_buf, size);
break;
default:
/* Invalid */
return -1;
}
return 0;
}