Leptonica 1.54
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Классы | |
struct | L_Pixel |
Определения типов | |
typedef struct L_Pixel | L_PIXEL |
Функции | |
void | seedfillBinaryLow (l_uint32 *datas, l_int32 hs, l_int32 wpls, l_uint32 *datam, l_int32 hm, l_int32 wplm, l_int32 connectivity) |
void | seedfillGrayLow (l_uint32 *datas, l_int32 w, l_int32 h, l_int32 wpls, l_uint32 *datam, l_int32 wplm, l_int32 connectivity) |
void | seedfillGrayInvLow (l_uint32 *datas, l_int32 w, l_int32 h, l_int32 wpls, l_uint32 *datam, l_int32 wplm, l_int32 connectivity) |
void | seedfillGrayLowSimple (l_uint32 *datas, l_int32 w, l_int32 h, l_int32 wpls, l_uint32 *datam, l_int32 wplm, l_int32 connectivity) |
void | seedfillGrayInvLowSimple (l_uint32 *datas, l_int32 w, l_int32 h, l_int32 wpls, l_uint32 *datam, l_int32 wplm, l_int32 connectivity) |
void | distanceFunctionLow (l_uint32 *datad, l_int32 w, l_int32 h, l_int32 d, l_int32 wpld, l_int32 connectivity) |
void | seedspreadLow (l_uint32 *datad, l_int32 w, l_int32 h, l_int32 wpld, l_uint32 *datat, l_int32 wplt, l_int32 connectivity) |
void seedfillBinaryLow | ( | l_uint32 * | datas, |
l_int32 | hs, | ||
l_int32 | wpls, | ||
l_uint32 * | datam, | ||
l_int32 | hm, | ||
l_int32 | wplm, | ||
l_int32 | connectivity | ||
) |
Notes: (1) This is an in-place fill, where the seed image is filled, clipping to the filling mask, in one full cycle of UL -> LR and LR -> UL raster scans. (2) Assume the mask is a filling mask, not a blocking mask. (3) Assume that the RHS pad bits of the mask are properly set to 0. (4) Clip to the smallest dimensions to avoid invalid reads.
void seedfillGrayInvLow | ( | l_uint32 * | datas, |
l_int32 | w, | ||
l_int32 | h, | ||
l_int32 | wpls, | ||
l_uint32 * | datam, | ||
l_int32 | wplm, | ||
l_int32 | connectivity | ||
) |
Notes: (1) The pixels are numbered as follows: 1 2 3 4 x 5 6 7 8 This low-level filling operation consists of two scans, raster and anti-raster, covering the entire seed image. During the anti-raster scan, every pixel p such that its current value could still be propogated during the next raster scanning is put into the FIFO-queue. Next step is the propagation step where where we update and propagate the values using FIFO structure created in anti-raster scan. (2) The "Inv" signifies the fact that in this case, filling of the seed only takes place when the seed value is greater than the mask value. The mask will act to stop the fill when it is higher than the seed level. (This is in contrast to conventional grayscale filling where the seed always fills below the mask.) (3) An example of use is a basin, described by the mask (pixm), where within the basin, the seed pix (pixs) gets filled to the height of the highest seed pixel that is above its corresponding max pixel. Filling occurs while the propagating seed pixels in pixs are larger than the corresponding mask values in pixm. (4) Reference paper : L. Vincent, Morphological grayscale reconstruction in image analysis: applications and efficient algorithms, IEEE Transactions on Image Processing, vol. 2, no. 2, pp. 176-201, 1993.
void seedfillGrayInvLowSimple | ( | l_uint32 * | datas, |
l_int32 | w, | ||
l_int32 | h, | ||
l_int32 | wpls, | ||
l_uint32 * | datam, | ||
l_int32 | wplm, | ||
l_int32 | connectivity | ||
) |
Notes: (1) The pixels are numbered as follows: 1 2 3 4 x 5 6 7 8 This low-level filling operation consists of two scans, raster and anti-raster, covering the entire seed image. The caller typically iterates until the filling is complete. (2) The "Inv" signifies the fact that in this case, filling of the seed only takes place when the seed value is greater than the mask value. The mask will act to stop the fill when it is higher than the seed level. (This is in contrast to conventional grayscale filling where the seed always fills below the mask.) (3) An example of use is a basin, described by the mask (pixm), where within the basin, the seed pix (pixs) gets filled to the height of the highest seed pixel that is above its corresponding max pixel. Filling occurs while the propagating seed pixels in pixs are larger than the corresponding mask values in pixm.
void seedfillGrayLow | ( | l_uint32 * | datas, |
l_int32 | w, | ||
l_int32 | h, | ||
l_int32 | wpls, | ||
l_uint32 * | datam, | ||
l_int32 | wplm, | ||
l_int32 | connectivity | ||
) |
Notes: (1) The pixels are numbered as follows: 1 2 3 4 x 5 6 7 8 This low-level filling operation consists of two scans, raster and anti-raster, covering the entire seed image. This is followed by a breadth-first propagation operation to complete the fill. During the anti-raster scan, every pixel p whose current value could still be propagated after the anti-raster scan is put into the FIFO queue. The propagation step is a breadth-first fill to completion. Unlike the simple grayscale seedfill pixSeedfillGraySimple(), where at least two full raster/anti-raster iterations are required for completion and verification, the hybrid method uses only a single raster/anti-raster set of scans. (2) The filling action can be visualized from the following example. Suppose the mask, which clips the fill, is a sombrero-shaped surface, where the highest point is 200 and the low pixels around the rim are 30. Beyond the rim, the mask goes up a bit. Suppose the seed, which is filled, consists of a single point of height 150, located below the max of the mask, with the rest 0. Then in the raster scan, nothing happens until the high seed point is encountered, and then this value is propagated right and down, until it hits the side of the sombrero. The seed can never exceed the mask, so it fills to the rim, going lower along the mask surface. When it passes the rim, the seed continues to fill at the rim height to the edge of the seed image. Then on the anti-raster scan, the seed fills flat inside the sombrero to the upper and left, and then out from the rim as before. The final result has a seed that is flat outside the rim, and inside it fills the sombrero but only up to 150. If the rim height varies, the filled seed outside the rim will be at the highest point on the rim, which is a saddle point on the rim. (3) Reference paper : L. Vincent, Morphological grayscale reconstruction in image analysis: applications and efficient algorithms, IEEE Transactions on Image Processing, vol. 2, no. 2, pp. 176-201, 1993.
void seedfillGrayLowSimple | ( | l_uint32 * | datas, |
l_int32 | w, | ||
l_int32 | h, | ||
l_int32 | wpls, | ||
l_uint32 * | datam, | ||
l_int32 | wplm, | ||
l_int32 | connectivity | ||
) |
Notes: (1) The pixels are numbered as follows: 1 2 3 4 x 5 6 7 8 This low-level filling operation consists of two scans, raster and anti-raster, covering the entire seed image. The caller typically iterates until the filling is complete. (2) The filling action can be visualized from the following example. Suppose the mask, which clips the fill, is a sombrero-shaped surface, where the highest point is 200 and the low pixels around the rim are 30. Beyond the rim, the mask goes up a bit. Suppose the seed, which is filled, consists of a single point of height 150, located below the max of the mask, with the rest 0. Then in the raster scan, nothing happens until the high seed point is encountered, and then this value is propagated right and down, until it hits the side of the sombrero. The seed can never exceed the mask, so it fills to the rim, going lower along the mask surface. When it passes the rim, the seed continues to fill at the rim height to the edge of the seed image. Then on the anti-raster scan, the seed fills flat inside the sombrero to the upper and left, and then out from the rim as before. The final result has a seed that is flat outside the rim, and inside it fills the sombrero but only up to 150. If the rim height varies, the filled seed outside the rim will be at the highest point on the rim, which is a saddle point on the rim.