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Java example source code file (mlib_ImageConv_16nw.c)

This example Java source code file (mlib_ImageConv_16nw.c) is included in the alvinalexander.com "Java Source Code Warehouse" project. The intent of this project is to help you "Learn Java by Example" TM.

Learn more about this Java project at its project page.

Java - Java tags/keywords

clamp_store, conv_func, d2i, dtype, from_s32, ftype, get_src_dst_parameters, img_type, ksize, load_buff, mlib_failure, mlib_success, null, store_res

The mlib_ImageConv_16nw.c Java example source code

/*
 * Copyright (c) 2000, 2013, Oracle and/or its affiliates. All rights reserved.
 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
 *
 * This code is free software; you can redistribute it and/or modify it
 * under the terms of the GNU General Public License version 2 only, as
 * published by the Free Software Foundation.  Oracle designates this
 * particular file as subject to the "Classpath" exception as provided
 * by Oracle in the LICENSE file that accompanied this code.
 *
 * This code 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
 * version 2 for more details (a copy is included in the LICENSE file that
 * accompanied this code).
 *
 * You should have received a copy of the GNU General Public License version
 * 2 along with this work; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
 *
 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
 * or visit www.oracle.com if you need additional information or have any
 * questions.
 */


/*
 * FUNCTION
 *   Internal functions for mlib_ImageConv* on U8/S16/U16 types and
 *   MLIB_EDGE_DST_NO_WRITE mask
 */

#include "mlib_image.h"
#include "mlib_c_ImageConv.h"

/*
  This define switches between functions of different data types
*/
#define IMG_TYPE 2

/***************************************************************/
#if IMG_TYPE == 1

#define DTYPE             mlib_u8
#define CONV_FUNC(KERN)   mlib_c_conv##KERN##nw_u8
#define CONV_FUNC_I(KERN) mlib_i_conv##KERN##nw_u8
#define DSCALE            (1 << 24)
#define FROM_S32(x)       (((x) >> 24) ^ 128)
#define S64TOS32(x)       (x)
#define SAT_OFF           -(1u << 31)

#elif IMG_TYPE == 2

#define DTYPE             mlib_s16
#define CONV_FUNC(KERN)   mlib_conv##KERN##nw_s16
#define CONV_FUNC_I(KERN) mlib_i_conv##KERN##nw_s16
#define DSCALE            65536.0
#define FROM_S32(x)       ((x) >> 16)
#define S64TOS32(x)       ((x) & 0xffffffff)
#define SAT_OFF

#elif IMG_TYPE == 3

#define DTYPE             mlib_u16
#define CONV_FUNC(KERN)   mlib_conv##KERN##nw_u16
#define CONV_FUNC_I(KERN) mlib_i_conv##KERN##nw_u16
#define DSCALE            65536.0
#define FROM_S32(x)       (((x) >> 16) ^ 0x8000)
#define S64TOS32(x)       (x)
#define SAT_OFF           -(1u << 31)

#endif /* IMG_TYPE == 1 */

/***************************************************************/
#define BUFF_SIZE   1600

#define CACHE_SIZE  (64*1024)

/***************************************************************/
#define FTYPE mlib_d64

#ifndef MLIB_USE_FTOI_CLAMPING

#define CLAMP_S32(x)                                            \
  (((x) <= MLIB_S32_MIN) ? MLIB_S32_MIN : (((x) >= MLIB_S32_MAX) ? MLIB_S32_MAX : (mlib_s32)(x)))

#else

#define CLAMP_S32(x) ((mlib_s32)(x))

#endif /* MLIB_USE_FTOI_CLAMPING */

/***************************************************************/
#define D2I(x) CLAMP_S32((x) SAT_OFF)

/***************************************************************/
#ifdef _LITTLE_ENDIAN

#define STORE2(res0, res1)                                      \
  dp[0    ] = res1;                                             \
  dp[chan1] = res0

#else

#define STORE2(res0, res1)                                      \
  dp[0    ] = res0;                                             \
  dp[chan1] = res1

#endif /* _LITTLE_ENDIAN */

/***************************************************************/
#ifdef _NO_LONGLONG

#define LOAD_BUFF(buff)                                         \
  buff[i    ] = sp[0];                                          \
  buff[i + 1] = sp[chan1]

#else /* _NO_LONGLONG */

#ifdef _LITTLE_ENDIAN

#define LOAD_BUFF(buff)                                         \
  *(mlib_s64*)(buff + i) = (((mlib_s64)sp[chan1]) << 32) | S64TOS32((mlib_s64)sp[0])

#else /* _LITTLE_ENDIAN */

#define LOAD_BUFF(buff)                                         \
  *(mlib_s64*)(buff + i) = (((mlib_s64)sp[0]) << 32) | S64TOS32((mlib_s64)sp[chan1])

#endif /* _LITTLE_ENDIAN */
#endif /* _NO_LONGLONG */

/***************************************************************/
typedef union {
  mlib_d64 d64;
  struct {
    mlib_s32 i0;
    mlib_s32 i1;
  } i32s;
  struct {
    mlib_s32 f0;
    mlib_s32 f1;
  } f32s;
} d64_2x32;

/***************************************************************/
#define BUFF_LINE 256

/***************************************************************/
#define DEF_VARS(type)                                          \
  type     *adr_src, *sl, *sp = NULL;                           \
  type     *adr_dst, *dl, *dp = NULL;                           \
  FTYPE    *pbuff = buff;                                       \
  mlib_s32 wid, hgt, sll, dll;                                  \
  mlib_s32 nchannel, chan1;                                     \
  mlib_s32 i, j, c

/***************************************************************/
#define LOAD_KERNEL3()                                                   \
  FTYPE    scalef = DSCALE;                                              \
  FTYPE    k0, k1, k2, k3, k4, k5, k6, k7, k8;                           \
  FTYPE    p00, p01, p02, p03,                                           \
           p10, p11, p12, p13,                                           \
           p20, p21, p22, p23;                                           \
                                                                         \
  while (scalef_expon > 30) {                                            \
    scalef /= (1 << 30);                                                 \
    scalef_expon -= 30;                                                  \
  }                                                                      \
                                                                         \
  scalef /= (1 << scalef_expon);                                         \
                                                                         \
  /* keep kernel in regs */                                              \
  k0 = scalef * kern[0];  k1 = scalef * kern[1];  k2 = scalef * kern[2]; \
  k3 = scalef * kern[3];  k4 = scalef * kern[4];  k5 = scalef * kern[5]; \
  k6 = scalef * kern[6];  k7 = scalef * kern[7];  k8 = scalef * kern[8]

/***************************************************************/
#define LOAD_KERNEL(SIZE)                                       \
  FTYPE    scalef = DSCALE;                                     \
                                                                \
  while (scalef_expon > 30) {                                   \
    scalef /= (1 << 30);                                        \
    scalef_expon -= 30;                                         \
  }                                                             \
                                                                \
  scalef /= (1 << scalef_expon);                                \
                                                                \
  for (j = 0; j < SIZE; j++) k[j] = scalef * kern[j]

/***************************************************************/
#define GET_SRC_DST_PARAMETERS(type)                            \
  hgt = mlib_ImageGetHeight(src);                               \
  wid = mlib_ImageGetWidth(src);                                \
  nchannel = mlib_ImageGetChannels(src);                        \
  sll = mlib_ImageGetStride(src) / sizeof(type);                \
  dll = mlib_ImageGetStride(dst) / sizeof(type);                \
  adr_src = (type *)mlib_ImageGetData(src);                     \
  adr_dst = (type *)mlib_ImageGetData(dst)

/***************************************************************/
#ifndef __sparc

#if IMG_TYPE == 1

/* Test for the presence of any "1" bit in bits
   8 to 31 of val. If present, then val is either
   negative or >255. If over/underflows of 8 bits
   are uncommon, then this technique can be a win,
   since only a single test, rather than two, is
   necessary to determine if clamping is needed.
   On the other hand, if over/underflows are common,
   it adds an extra test.
*/
#define CLAMP_STORE(dst, val)                                   \
  if (val & 0xffffff00) {                                       \
    if (val < MLIB_U8_MIN)                                      \
      dst = MLIB_U8_MIN;                                        \
    else                                                        \
      dst = MLIB_U8_MAX;                                        \
  } else {                                                      \
    dst = (mlib_u8)val;                                         \
  }

#elif IMG_TYPE == 2

#define CLAMP_STORE(dst, val)                                   \
  if (val >= MLIB_S16_MAX)                                      \
    dst = MLIB_S16_MAX;                                         \
  else if (val <= MLIB_S16_MIN)                                 \
    dst = MLIB_S16_MIN;                                         \
  else                                                          \
    dst = (mlib_s16)val

#elif IMG_TYPE == 3

#define CLAMP_STORE(dst, val)                                   \
  if (val >= MLIB_U16_MAX)                                      \
    dst = MLIB_U16_MAX;                                         \
  else if (val <= MLIB_U16_MIN)                                 \
    dst = MLIB_U16_MIN;                                         \
  else                                                          \
    dst = (mlib_u16)val

#endif /* IMG_TYPE == 1 */
#endif /* __sparc */

/***************************************************************/
#define KSIZE  3

mlib_status CONV_FUNC(3x3)(mlib_image       *dst,
                           const mlib_image *src,
                           const mlib_s32   *kern,
                           mlib_s32         scalef_expon,
                           mlib_s32         cmask)
{
  FTYPE    buff[(KSIZE + 2)*BUFF_LINE], *buff0, *buff1, *buff2, *buff3, *buffT;
  DEF_VARS(DTYPE);
  DTYPE *sl1;
  mlib_s32 chan2;
  mlib_s32 *buffo, *buffi;
  DTYPE *sl2;
#ifndef __sparc
  mlib_s32 d0, d1;
#endif /* __sparc */
  LOAD_KERNEL3();
  GET_SRC_DST_PARAMETERS(DTYPE);

  if (wid > BUFF_LINE) {
    pbuff = mlib_malloc((KSIZE + 2)*sizeof(FTYPE)*wid);

    if (pbuff == NULL) return MLIB_FAILURE;
  }

  buff0 = pbuff;
  buff1 = buff0 + wid;
  buff2 = buff1 + wid;
  buff3 = buff2 + wid;
  buffo = (mlib_s32*)(buff3 + wid);
  buffi = buffo + (wid &~ 1);

  chan1 = nchannel;
  chan2 = chan1 + chan1;

  wid -= (KSIZE - 1);
  hgt -= (KSIZE - 1);

  adr_dst += ((KSIZE - 1)/2)*(dll + chan1);

  for (c = 0; c < nchannel; c++) {
    if (!(cmask & (1 << (nchannel - 1 - c)))) continue;

    sl = adr_src + c;
    dl = adr_dst + c;

    sl1 = sl  + sll;
    sl2 = sl1 + sll;
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
    for (i = 0; i < wid + (KSIZE - 1); i++) {
      buff0[i] = (FTYPE)sl[i*chan1];
      buff1[i] = (FTYPE)sl1[i*chan1];
      buff2[i] = (FTYPE)sl2[i*chan1];
    }

    sl += KSIZE*sll;

    for (j = 0; j < hgt; j++) {
      FTYPE    s0, s1;

      p02 = buff0[0];
      p12 = buff1[0];
      p22 = buff2[0];

      p03 = buff0[1];
      p13 = buff1[1];
      p23 = buff2[1];

      s0 = p02 * k0 + p03 * k1 + p12 * k3 + p13 * k4 + p22 * k6 + p23 * k7;
      s1 = p03 * k0 + p13 * k3 + p23 * k6;

      sp = sl;
      dp = dl;

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
      for (i = 0; i <= (wid - 2); i += 2) {
#ifdef __sparc
#ifdef _NO_LONGLONG
        mlib_s32 o64_1, o64_2;
#else /* _NO_LONGLONG */
        mlib_s64 o64;
#endif /* _NO_LONGLONG */
#endif /* __sparc */
        d64_2x32 dd;

        p02 = buff0[i + 2]; p12 = buff1[i + 2]; p22 = buff2[i + 2];
        p03 = buff0[i + 3]; p13 = buff1[i + 3]; p23 = buff2[i + 3];

        LOAD_BUFF(buffi);

        dd.d64 = *(FTYPE   *)(buffi + i);
        buff3[i    ] = (FTYPE)dd.i32s.i0;
        buff3[i + 1] = (FTYPE)dd.i32s.i1;

#ifndef __sparc
        d0 = D2I(s0 + p02 * k2 + p12 * k5 + p22 * k8);
        d1 = D2I(s1 + p02 * k1 + p03 * k2 + p12 * k4 + p13 * k5 + p22 * k7 + p23 * k8);

        s0 = p02 * k0 + p03 * k1 + p12 * k3 + p13 * k4 + p22 * k6 + p23 * k7;
        s1 = p03 * k0 + p13 * k3 + p23 * k6;

        dp[0    ] = FROM_S32(d0);
        dp[chan1] = FROM_S32(d1);

#else /* __sparc */

        dd.i32s.i0 = D2I(s0 + p02 * k2 + p12 * k5 + p22 * k8);
        dd.i32s.i1 = D2I(s1 + p02 * k1 + p03 * k2 + p12 * k4 + p13 * k5 + p22 * k7 + p23 * k8);
        *(FTYPE   *)(buffo + i) = dd.d64;

        s0 = p02 * k0 + p03 * k1 + p12 * k3 + p13 * k4 + p22 * k6 + p23 * k7;
        s1 = p03 * k0 + p13 * k3 + p23 * k6;

#ifdef _NO_LONGLONG

        o64_1 = buffo[i];
        o64_2 = buffo[i+1];
#if IMG_TYPE != 1
        STORE2(FROM_S32(o64_1), FROM_S32(o64_2));
#else
        STORE2(o64_1 >> 24, o64_2 >> 24);
#endif /* IMG_TYPE != 1 */

#else /* _NO_LONGLONG */

        o64 = *(mlib_s64*)(buffo + i);
#if IMG_TYPE != 1
        STORE2(FROM_S32(o64 >> 32), FROM_S32(o64));
#else
        STORE2(o64 >> 56, o64 >> 24);
#endif /* IMG_TYPE != 1 */
#endif /* _NO_LONGLONG */
#endif /* __sparc */

        sp += chan2;
        dp += chan2;
      }

      for (; i < wid; i++) {
        p00 = buff0[i];     p10 = buff1[i];     p20 = buff2[i];
        p01 = buff0[i + 1]; p11 = buff1[i + 1]; p21 = buff2[i + 1];
        p02 = buff0[i + 2]; p12 = buff1[i + 2]; p22 = buff2[i + 2];

        buffi[i] = (mlib_s32)sp[0];
        buff3[i] = (FTYPE)buffi[i];

#ifndef __sparc

        d0 = D2I(p00 * k0 + p01 * k1 + p02 * k2 + p10 * k3 + p11 * k4 +
                 p12 * k5 + p20 * k6 + p21 * k7 + p22 * k8);

        dp[0] = FROM_S32(d0);

#else  /* __sparc */

        buffo[i] = D2I(p00 * k0 + p01 * k1 + p02 * k2 + p10 * k3 + p11 * k4 +
                       p12 * k5 + p20 * k6 + p21 * k7 + p22 * k8);
#if IMG_TYPE != 1
        dp[0] = FROM_S32(buffo[i]);
#else
        dp[0] = buffo[i] >> 24;
#endif /* IMG_TYPE != 1 */
#endif /* __sparc */

        sp += chan1;
        dp += chan1;
      }

      buffi[wid] = (mlib_s32)sp[0];
      buff3[wid] = (FTYPE)buffi[wid];
      buffi[wid + 1] = (mlib_s32)sp[chan1];
      buff3[wid + 1] = (FTYPE)buffi[wid + 1];

      sl += sll;
      dl += dll;

      buffT = buff0;
      buff0 = buff1;
      buff1 = buff2;
      buff2 = buff3;
      buff3 = buffT;
    }
  }

#ifdef __sparc
#if IMG_TYPE == 1
  {
    mlib_s32 amask = (1 << nchannel) - 1;

    if ((cmask & amask) != amask) {
      mlib_ImageXor80(adr_dst, wid, hgt, dll, nchannel, cmask);
    } else {
      mlib_ImageXor80_aa(adr_dst, wid*nchannel, hgt, dll);
    }
  }

#endif /* IMG_TYPE == 1 */
#endif /* __sparc */

  if (pbuff != buff) mlib_free(pbuff);

  return MLIB_SUCCESS;
}

/***************************************************************/
#ifndef __sparc /* for x86, using integer multiplies is faster */

mlib_status CONV_FUNC_I(3x3)(mlib_image       *dst,
                             const mlib_image *src,
                             const mlib_s32   *kern,
                             mlib_s32         scalef_expon,
                             mlib_s32         cmask)
{
  DTYPE    *adr_src, *sl, *sp0, *sp1, *sp2;
  DTYPE    *adr_dst, *dl, *dp;
  mlib_s32 wid, hgt, sll, dll;
  mlib_s32 nchannel, chan1, chan2;
  mlib_s32 i, j, c;
  mlib_s32 shift1, shift2;
  mlib_s32 k0, k1, k2, k3, k4, k5, k6, k7, k8;
  mlib_s32 p02, p03,
           p12, p13,
           p22, p23;

#if IMG_TYPE != 1
  shift1 = 16;
#else
  shift1 = 8;
#endif /* IMG_TYPE != 1 */

  shift2 = scalef_expon - shift1;

  /* keep kernel in regs */
  k0 = kern[0] >> shift1;  k1 = kern[1] >> shift1;  k2 = kern[2] >> shift1;
  k3 = kern[3] >> shift1;  k4 = kern[4] >> shift1;  k5 = kern[5] >> shift1;
  k6 = kern[6] >> shift1;  k7 = kern[7] >> shift1;  k8 = kern[8] >> shift1;

  GET_SRC_DST_PARAMETERS(DTYPE);

  chan1 = nchannel;
  chan2 = chan1 + chan1;

  wid -= (KSIZE - 1);
  hgt -= (KSIZE - 1);

  adr_dst += ((KSIZE - 1)/2)*(dll + chan1);

  for (c = 0; c < chan1; c++) {
    if (!(cmask & (1 << (chan1 - 1 - c)))) continue;

    sl = adr_src + c;
    dl = adr_dst + c;

    for (j = 0; j < hgt; j++) {
      mlib_s32 s0, s1;
      mlib_s32 pix0, pix1;

      dp  = dl;
      sp0 = sl;
      sp1 = sp0 + sll;
      sp2 = sp1 + sll;

      p02 = sp0[0];
      p12 = sp1[0];
      p22 = sp2[0];

      p03 = sp0[chan1];
      p13 = sp1[chan1];
      p23 = sp2[chan1];

      s0 = p02 * k0 + p03 * k1 + p12 * k3 + p13 * k4 + p22 * k6 + p23 * k7;
      s1 = p03 * k0 + p13 * k3 + p23 * k6;

      sp0 += chan2;
      sp1 += chan2;
      sp2 += chan2;

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
      for (i = 0; i <= (wid - 2); i += 2) {
        p02 = sp0[0];     p12 = sp1[0];     p22 = sp2[0];
        p03 = sp0[chan1]; p13 = sp1[chan1]; p23 = sp2[chan1];

        pix0 = (s0 + p02 * k2 + p12 * k5 + p22 * k8) >> shift2;
        pix1 = (s1 + p02 * k1 + p03 * k2 + p12 * k4 +
                p13 * k5 + p22 * k7 + p23 * k8) >> shift2;

        CLAMP_STORE(dp[0],     pix0);
        CLAMP_STORE(dp[chan1], pix1);

        s0 = p02 * k0 + p03 * k1 + p12 * k3 + p13 * k4 + p22 * k6 + p23 * k7;
        s1 = p03 * k0 + p13 * k3 + p23 * k6;

        sp0 += chan2;
        sp1 += chan2;
        sp2 += chan2;
        dp += chan2;
      }

      if (wid & 1) {
        p02 = sp0[0]; p12 = sp1[0]; p22 = sp2[0];
        pix0 = (s0 + p02 * k2 + p12 * k5 + p22 * k8) >> shift2;
        CLAMP_STORE(dp[0], pix0);
      }

      sl += sll;
      dl += dll;
    }
  }

  return MLIB_SUCCESS;
}

#endif /* __sparc ( for x86, using integer multiplies is faster ) */

/***************************************************************/
#undef  KSIZE
#define KSIZE 4

mlib_status CONV_FUNC(4x4)(mlib_image       *dst,
                           const mlib_image *src,
                           const mlib_s32   *kern,
                           mlib_s32         scalef_expon,
                           mlib_s32         cmask)
{
  FTYPE    buff[(KSIZE + 3)*BUFF_LINE];
  FTYPE    *buff0, *buff1, *buff2, *buff3, *buff4, *buffd, *buffT;
  FTYPE    k[KSIZE*KSIZE];
  mlib_s32 d0, d1;
  FTYPE    k0, k1, k2, k3, k4, k5, k6, k7;
  FTYPE    p00, p01, p02, p03, p04,
           p10, p11, p12, p13, p14,
           p20, p21, p22, p23,
           p30, p31, p32, p33;
  DEF_VARS(DTYPE);
  DTYPE *sl1;
  mlib_s32 chan2;
  mlib_s32 *buffo, *buffi;
  DTYPE *sl2, *sl3;
  LOAD_KERNEL(KSIZE*KSIZE);
  GET_SRC_DST_PARAMETERS(DTYPE);

  if (wid > BUFF_LINE) {
    pbuff = mlib_malloc((KSIZE + 3)*sizeof(FTYPE)*wid);

    if (pbuff == NULL) return MLIB_FAILURE;
  }

  buff0 = pbuff;
  buff1 = buff0 + wid;
  buff2 = buff1 + wid;
  buff3 = buff2 + wid;
  buff4 = buff3 + wid;
  buffd = buff4 + wid;
  buffo = (mlib_s32*)(buffd + wid);
  buffi = buffo + (wid &~ 1);

  chan1 = nchannel;
  chan2 = chan1 + chan1;

  wid -= (KSIZE - 1);
  hgt -= (KSIZE - 1);

  adr_dst += ((KSIZE - 1)/2)*(dll + chan1);

  for (c = 0; c < nchannel; c++) {
    if (!(cmask & (1 << (nchannel - 1 - c)))) continue;

    sl = adr_src + c;
    dl = adr_dst + c;

    sl1 = sl  + sll;
    sl2 = sl1 + sll;
    sl3 = sl2 + sll;
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
    for (i = 0; i < wid + (KSIZE - 1); i++) {
      buff0[i] = (FTYPE)sl[i*chan1];
      buff1[i] = (FTYPE)sl1[i*chan1];
      buff2[i] = (FTYPE)sl2[i*chan1];
      buff3[i] = (FTYPE)sl3[i*chan1];
    }

    sl += KSIZE*sll;

    for (j = 0; j < hgt; j++) {
      d64_2x32 dd;

      /*
       *  First loop on two first lines of kernel
       */
      k0 = k[0]; k1 = k[1]; k2 = k[2]; k3 = k[3];
      k4 = k[4]; k5 = k[5]; k6 = k[6]; k7 = k[7];

      sp = sl;
      dp = dl;

      p02 = buff0[0];
      p12 = buff1[0];
      p03 = buff0[1];
      p13 = buff1[1];
      p04 = buff0[2];

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
      for (i = 0; i <= (wid - 2); i += 2) {
        p00 = p02; p10 = p12;
        p01 = p03; p11 = p13;
        p02 = p04; p12 = buff1[i + 2];
        p03 = buff0[i + 3]; p13 = buff1[i + 3];
        p04 = buff0[i + 4]; p14 = buff1[i + 4];

        LOAD_BUFF(buffi);

        dd.d64 = *(FTYPE   *)(buffi + i);
        buff4[i    ] = (FTYPE)dd.i32s.i0;
        buff4[i + 1] = (FTYPE)dd.i32s.i1;

        buffd[i    ] = (p00 * k0 + p01 * k1 + p02 * k2 + p03 * k3 +
                        p10 * k4 + p11 * k5 + p12 * k6 + p13 * k7);
        buffd[i + 1] = (p01 * k0 + p02 * k1 + p03 * k2 + p04 * k3 +
                        p11 * k4 + p12 * k5 + p13 * k6 + p14 * k7);

        sp += chan2;
        dp += chan2;
      }

      /*
       *  Second loop on two last lines of kernel
       */
      k0 = k[ 8]; k1 = k[ 9]; k2 = k[10]; k3 = k[11];
      k4 = k[12]; k5 = k[13]; k6 = k[14]; k7 = k[15];

      sp = sl;
      dp = dl;

      p02 = buff2[0];
      p12 = buff3[0];
      p03 = buff2[1];
      p13 = buff3[1];
      p04 = buff2[2];

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
      for (i = 0; i <= (wid - 2); i += 2) {
        p00 = p02; p10 = p12;
        p01 = p03; p11 = p13;
        p02 = p04; p12 = buff3[i + 2];
        p03 = buff2[i + 3]; p13 = buff3[i + 3];
        p04 = buff2[i + 4]; p14 = buff3[i + 4];

        d0 = D2I(p00 * k0 + p01 * k1 + p02 * k2 + p03 * k3 +
                 p10 * k4 + p11 * k5 + p12 * k6 + p13 * k7 + buffd[i]);
        d1 = D2I(p01 * k0 + p02 * k1 + p03 * k2 + p04 * k3 +
                 p11 * k4 + p12 * k5 + p13 * k6 + p14 * k7 + buffd[i + 1]);

        dp[0    ] = FROM_S32(d0);
        dp[chan1] = FROM_S32(d1);

        sp += chan2;
        dp += chan2;
      }

      /* last pixels */
      for (; i < wid; i++) {
        p00 = buff0[i];     p10 = buff1[i];     p20 = buff2[i];     p30 = buff3[i];
        p01 = buff0[i + 1]; p11 = buff1[i + 1]; p21 = buff2[i + 1]; p31 = buff3[i + 1];
        p02 = buff0[i + 2]; p12 = buff1[i + 2]; p22 = buff2[i + 2]; p32 = buff3[i + 2];
        p03 = buff0[i + 3]; p13 = buff1[i + 3]; p23 = buff2[i + 3]; p33 = buff3[i + 3];

        buff4[i] = (FTYPE)sp[0];

        buffo[i] = D2I(p00 * k[0] + p01 * k[1] + p02 * k[2] + p03 * k[3] +
                       p10 * k[4] + p11 * k[5] + p12 * k[6] + p13 * k[7] +
                       p20 * k[ 8] + p21 * k[ 9] + p22 * k[10] + p23 * k[11] +
                       p30 * k[12] + p31 * k[13] + p32 * k[14] + p33 * k[15]);

        dp[0] = FROM_S32(buffo[i]);

        sp += chan1;
        dp += chan1;
      }

      buff4[wid    ] = (FTYPE)sp[0];
      buff4[wid + 1] = (FTYPE)sp[chan1];
      buff4[wid + 2] = (FTYPE)sp[chan2];

      /* next line */
      sl += sll;
      dl += dll;

      buffT = buff0;
      buff0 = buff1;
      buff1 = buff2;
      buff2 = buff3;
      buff3 = buff4;
      buff4 = buffT;
    }
  }

  if (pbuff != buff) mlib_free(pbuff);

  return MLIB_SUCCESS;
}

/***************************************************************/
#undef  KSIZE
#define KSIZE 5

mlib_status CONV_FUNC(5x5)(mlib_image       *dst,
                           const mlib_image *src,
                           const mlib_s32   *kern,
                           mlib_s32         scalef_expon,
                           mlib_s32         cmask)
{
  FTYPE    buff[(KSIZE + 3)*BUFF_LINE];
  FTYPE    *buff0, *buff1, *buff2, *buff3, *buff4, *buff5, *buffd, *buffT;
  FTYPE    k[KSIZE*KSIZE];
  mlib_s32 d0, d1;
  FTYPE    k0, k1, k2, k3, k4, k5, k6, k7, k8, k9;
  FTYPE    p00, p01, p02, p03, p04, p05,
           p10, p11, p12, p13, p14, p15,
           p20, p21, p22, p23, p24,
           p30, p31, p32, p33, p34,
           p40, p41, p42, p43, p44;
  DEF_VARS(DTYPE);
  DTYPE *sl1;
  mlib_s32 chan2;
  mlib_s32 *buffo, *buffi;
  DTYPE *sl2, *sl3, *sl4;
  LOAD_KERNEL(KSIZE*KSIZE);
  GET_SRC_DST_PARAMETERS(DTYPE);

  if (wid > BUFF_LINE) {
    pbuff = mlib_malloc((KSIZE + 3)*sizeof(FTYPE)*wid);

    if (pbuff == NULL) return MLIB_FAILURE;
  }

  buff0 = pbuff;
  buff1 = buff0 + wid;
  buff2 = buff1 + wid;
  buff3 = buff2 + wid;
  buff4 = buff3 + wid;
  buff5 = buff4 + wid;
  buffd = buff5 + wid;
  buffo = (mlib_s32*)(buffd + wid);
  buffi = buffo + (wid &~ 1);

  chan1 = nchannel;
  chan2 = chan1 + chan1;

  wid -= (KSIZE - 1);
  hgt -= (KSIZE - 1);

  adr_dst += ((KSIZE - 1)/2)*(dll + chan1);

  for (c = 0; c < nchannel; c++) {
    if (!(cmask & (1 << (nchannel - 1 - c)))) continue;

    sl = adr_src + c;
    dl = adr_dst + c;

    sl1 = sl  + sll;
    sl2 = sl1 + sll;
    sl3 = sl2 + sll;
    sl4 = sl3 + sll;
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
    for (i = 0; i < wid + (KSIZE - 1); i++) {
      buff0[i] = (FTYPE)sl[i*chan1];
      buff1[i] = (FTYPE)sl1[i*chan1];
      buff2[i] = (FTYPE)sl2[i*chan1];
      buff3[i] = (FTYPE)sl3[i*chan1];
      buff4[i] = (FTYPE)sl4[i*chan1];
    }

    sl += KSIZE*sll;

    for (j = 0; j < hgt; j++) {
      d64_2x32 dd;

      /*
       *  First loop
       */
      k0 = k[0]; k1 = k[1]; k2 = k[2]; k3 = k[3]; k4 = k[4];
      k5 = k[5]; k6 = k[6]; k7 = k[7]; k8 = k[8]; k9 = k[9];

      sp = sl;
      dp = dl;

      p02 = buff0[0];
      p12 = buff1[0];
      p03 = buff0[1];
      p13 = buff1[1];
      p04 = buff0[2];
      p14 = buff1[2];

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
      for (i = 0; i <= (wid - 2); i += 2) {
        p00 = p02; p10 = p12;
        p01 = p03; p11 = p13;
        p02 = p04; p12 = p14;

        LOAD_BUFF(buffi);

        p03 = buff0[i + 3]; p13 = buff1[i + 3];
        p04 = buff0[i + 4]; p14 = buff1[i + 4];
        p05 = buff0[i + 5]; p15 = buff1[i + 5];

        buffd[i    ] = (p00 * k0 + p01 * k1 + p02 * k2 + p03 * k3 + p04 * k4 +
                        p10 * k5 + p11 * k6 + p12 * k7 + p13 * k8 + p14 * k9);
        buffd[i + 1] = (p01 * k0 + p02 * k1 + p03 * k2 + p04 * k3 + p05 * k4 +
                        p11 * k5 + p12 * k6 + p13 * k7 + p14 * k8 + p15 * k9);

        sp += chan2;
        dp += chan2;
      }

      /*
       *  Second loop
       */
      k0 = k[10]; k1 = k[11]; k2 = k[12]; k3 = k[13]; k4 = k[14];
      k5 = k[15]; k6 = k[16]; k7 = k[17]; k8 = k[18]; k9 = k[19];

      sp = sl;
      dp = dl;

      p02 = buff2[0];
      p12 = buff3[0];
      p03 = buff2[1];
      p13 = buff3[1];
      p04 = buff2[2];
      p14 = buff3[2];

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
      for (i = 0; i <= (wid - 2); i += 2) {
        p00 = p02; p10 = p12;
        p01 = p03; p11 = p13;

        p02 = buff2[i + 2]; p12 = buff3[i + 2];
        p03 = buff2[i + 3]; p13 = buff3[i + 3];
        p04 = buff2[i + 4]; p14 = buff3[i + 4];
        p05 = buff2[i + 5]; p15 = buff3[i + 5];

        dd.d64 = *(FTYPE   *)(buffi + i);
        buff5[i    ] = (FTYPE)dd.i32s.i0;
        buff5[i + 1] = (FTYPE)dd.i32s.i1;

        buffd[i    ] += (p00 * k0 + p01 * k1 + p02 * k2 + p03 * k3 + p04 * k4 +
                         p10 * k5 + p11 * k6 + p12 * k7 + p13 * k8 + p14 * k9);
        buffd[i + 1] += (p01 * k0 + p02 * k1 + p03 * k2 + p04 * k3 + p05 * k4 +
                         p11 * k5 + p12 * k6 + p13 * k7 + p14 * k8 + p15 * k9);

        sp += chan2;
        dp += chan2;
      }

      /*
       *  3 loop
       */
      k0 = k[20]; k1 = k[21]; k2 = k[22]; k3 = k[23]; k4 = k[24];

      sp = sl;
      dp = dl;

      p02 = buff4[0];
      p03 = buff4[1];
      p04 = buff4[2];
      p05 = buff4[3];

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
      for (i = 0; i <= (wid - 2); i += 2) {
        p00 = p02; p01 = p03; p02 = p04; p03 = p05;

        p04 = buff4[i + 4]; p05 = buff4[i + 5];

        d0 = D2I(p00 * k0 + p01 * k1 + p02 * k2 + p03 * k3 + p04 * k4 + buffd[i]);
        d1 = D2I(p01 * k0 + p02 * k1 + p03 * k2 + p04 * k3 + p05 * k4 + buffd[i + 1]);

        dp[0    ] = FROM_S32(d0);
        dp[chan1] = FROM_S32(d1);

        sp += chan2;
        dp += chan2;
      }

      /* last pixels */
      for (; i < wid; i++) {
        p00 = buff0[i];     p10 = buff1[i];     p20 = buff2[i];     p30 = buff3[i];
        p01 = buff0[i + 1]; p11 = buff1[i + 1]; p21 = buff2[i + 1]; p31 = buff3[i + 1];
        p02 = buff0[i + 2]; p12 = buff1[i + 2]; p22 = buff2[i + 2]; p32 = buff3[i + 2];
        p03 = buff0[i + 3]; p13 = buff1[i + 3]; p23 = buff2[i + 3]; p33 = buff3[i + 3];
        p04 = buff0[i + 4]; p14 = buff1[i + 4]; p24 = buff2[i + 4]; p34 = buff3[i + 4];

        p40 = buff4[i];     p41 = buff4[i + 1]; p42 = buff4[i + 2];
        p43 = buff4[i + 3]; p44 = buff4[i + 4];

        buff5[i] = (FTYPE)sp[0];

        buffo[i] = D2I(p00 * k[0] + p01 * k[1] + p02 * k[2] + p03 * k[3] + p04 * k[4] +
                       p10 * k[5] + p11 * k[6] + p12 * k[7] + p13 * k[8] + p14 * k[9] +
                       p20 * k[10] + p21 * k[11] + p22 * k[12] + p23 * k[13] + p24 * k[14] +
                       p30 * k[15] + p31 * k[16] + p32 * k[17] + p33 * k[18] + p34 * k[19] +
                       p40 * k[20] + p41 * k[21] + p42 * k[22] + p43 * k[23] + p44 * k[24]);

        dp[0] = FROM_S32(buffo[i]);

        sp += chan1;
        dp += chan1;
      }

      buff5[wid    ] = (FTYPE)sp[0];
      buff5[wid + 1] = (FTYPE)sp[chan1];
      buff5[wid + 2] = (FTYPE)sp[chan2];
      buff5[wid + 3] = (FTYPE)sp[chan2 + chan1];

      /* next line */
      sl += sll;
      dl += dll;

      buffT = buff0;
      buff0 = buff1;
      buff1 = buff2;
      buff2 = buff3;
      buff3 = buff4;
      buff4 = buff5;
      buff5 = buffT;
    }
  }

  if (pbuff != buff) mlib_free(pbuff);

  return MLIB_SUCCESS;
}

/***************************************************************/
#ifndef __sparc /* for x86, using integer multiplies is faster */

mlib_status CONV_FUNC_I(5x5)(mlib_image       *dst,
                             const mlib_image *src,
                             const mlib_s32   *kern,
                             mlib_s32         scalef_expon,
                             mlib_s32         cmask)
{
  mlib_s32 buff[BUFF_LINE];
  mlib_s32 *buffd;
  mlib_s32 k[KSIZE*KSIZE];
  mlib_s32 shift1, shift2;
  mlib_s32 k0, k1, k2, k3, k4, k5, k6, k7, k8, k9;
  mlib_s32 p00, p01, p02, p03, p04, p05,
           p10, p11, p12, p13, p14, p15;
  DTYPE    *adr_src, *sl, *sp0, *sp1;
  DTYPE    *adr_dst, *dl, *dp;
  mlib_s32 *pbuff = buff;
  mlib_s32 wid, hgt, sll, dll;
  mlib_s32 nchannel, chan1, chan2, chan3, chan4;
  mlib_s32 i, j, c;

#if IMG_TYPE != 1
  shift1 = 16;
#else
  shift1 = 8;
#endif /* IMG_TYPE != 1 */

  shift2 = scalef_expon - shift1;

  for (j = 0; j < KSIZE*KSIZE; j++) k[j] = kern[j] >> shift1;

  GET_SRC_DST_PARAMETERS(DTYPE);

  if (wid > BUFF_LINE) {
    pbuff = mlib_malloc(sizeof(mlib_s32)*wid);

    if (pbuff == NULL) return MLIB_FAILURE;
  }

  buffd = pbuff;

  chan1 = nchannel;
  chan2 = chan1 + chan1;
  chan3 = chan2 + chan1;
  chan4 = chan3 + chan1;

  wid -= (KSIZE - 1);
  hgt -= (KSIZE - 1);

  adr_dst += ((KSIZE - 1)/2)*(dll + chan1);

  for (c = 0; c < chan1; c++) {
    if (!(cmask & (1 << (chan1 - 1 - c)))) continue;

    sl = adr_src + c;
    dl = adr_dst + c;

    for (j = 0; j < hgt; j++) {
      mlib_s32 pix0, pix1;
      /*
       *  First loop
       */
      sp0 = sl;
      sp1 = sp0 + sll;
      dp = dl;

      k0 = k[0]; k1 = k[1]; k2 = k[2]; k3 = k[3]; k4 = k[4];
      k5 = k[5]; k6 = k[6]; k7 = k[7]; k8 = k[8]; k9 = k[9];

      p02 = sp0[0];     p12 = sp1[0];
      p03 = sp0[chan1]; p13 = sp1[chan1];
      p04 = sp0[chan2]; p14 = sp1[chan2];
      p05 = sp0[chan3]; p15 = sp1[chan3];

      sp0 += chan4;
      sp1 += chan4;

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
      for (i = 0; i <= (wid - 2); i += 2) {
        p00 = p02; p10 = p12;
        p01 = p03; p11 = p13;
        p02 = p04; p12 = p14;
        p03 = p05; p13 = p15;

        p04 = sp0[0];     p14 = sp1[0];
        p05 = sp0[chan1]; p15 = sp1[chan1];

        buffd[i    ] = (p00 * k0 + p01 * k1 + p02 * k2 + p03 * k3 + p04 * k4 +
                        p10 * k5 + p11 * k6 + p12 * k7 + p13 * k8 + p14 * k9);
        buffd[i + 1] = (p01 * k0 + p02 * k1 + p03 * k2 + p04 * k3 + p05 * k4 +
                        p11 * k5 + p12 * k6 + p13 * k7 + p14 * k8 + p15 * k9);

        sp0 += chan2;
        sp1 += chan2;
        dp += chan2;
      }

      if (wid & 1) {
        p00 = p02; p10 = p12;
        p01 = p03; p11 = p13;
        p02 = p04; p12 = p14;
        p03 = p05; p13 = p15;

        p04 = sp0[0];     p14 = sp1[0];

        buffd[i] = (p00 * k0 + p01 * k1 + p02 * k2 + p03 * k3 + p04 * k4 +
                    p10 * k5 + p11 * k6 + p12 * k7 + p13 * k8 + p14 * k9);
      }

      /*
       *  Second loop
       */
      sp0 = sl + 2*sll;
      sp1 = sp0 + sll;
      dp = dl;

      k0 = k[10]; k1 = k[11]; k2 = k[12]; k3 = k[13]; k4 = k[14];
      k5 = k[15]; k6 = k[16]; k7 = k[17]; k8 = k[18]; k9 = k[19];

      p02 = sp0[0];     p12 = sp1[0];
      p03 = sp0[chan1]; p13 = sp1[chan1];
      p04 = sp0[chan2]; p14 = sp1[chan2];
      p05 = sp0[chan3]; p15 = sp1[chan3];

      sp0 += chan4;
      sp1 += chan4;

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
      for (i = 0; i <= (wid - 2); i += 2) {
        p00 = p02; p10 = p12;
        p01 = p03; p11 = p13;
        p02 = p04; p12 = p14;
        p03 = p05; p13 = p15;

        p04 = sp0[0];     p14 = sp1[0];
        p05 = sp0[chan1]; p15 = sp1[chan1];

        buffd[i    ] += (p00 * k0 + p01 * k1 + p02 * k2 + p03 * k3 + p04 * k4 +
                         p10 * k5 + p11 * k6 + p12 * k7 + p13 * k8 + p14 * k9);
        buffd[i + 1] += (p01 * k0 + p02 * k1 + p03 * k2 + p04 * k3 + p05 * k4 +
                         p11 * k5 + p12 * k6 + p13 * k7 + p14 * k8 + p15 * k9);

        sp0 += chan2;
        sp1 += chan2;
        dp += chan2;
      }

      if (wid & 1) {
        p00 = p02; p10 = p12;
        p01 = p03; p11 = p13;
        p02 = p04; p12 = p14;
        p03 = p05; p13 = p15;

        p04 = sp0[0];     p14 = sp1[0];

        buffd[i] += (p00 * k0 + p01 * k1 + p02 * k2 + p03 * k3 + p04 * k4 +
                     p10 * k5 + p11 * k6 + p12 * k7 + p13 * k8 + p14 * k9);
      }

      /*
       *  3 loop
       */
      dp = dl;
      sp0 = sl + 4*sll;

      k0 = k[20]; k1 = k[21]; k2 = k[22]; k3 = k[23]; k4 = k[24];

      p02 = sp0[0];
      p03 = sp0[chan1];
      p04 = sp0[chan2];
      p05 = sp0[chan3];

      sp0 += chan2 + chan2;

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
      for (i = 0; i <= (wid - 2); i += 2) {
        p00 = p02; p01 = p03; p02 = p04; p03 = p05;

        p04 = sp0[0]; p05 = sp0[chan1];

        pix0 = (buffd[i    ] + p00 * k0 + p01 * k1 + p02 * k2 +
                p03 * k3 + p04 * k4) >> shift2;
        pix1 = (buffd[i + 1] + p01 * k0 + p02 * k1 + p03 * k2 +
                p04 * k3 + p05 * k4) >> shift2;

        CLAMP_STORE(dp[0],     pix0);
        CLAMP_STORE(dp[chan1], pix1);

        dp  += chan2;
        sp0 += chan2;
      }

      if (wid & 1) {
        p00 = p02; p01 = p03; p02 = p04; p03 = p05;

        p04 = sp0[0];

        pix0 = (buffd[i    ] + p00 * k0 + p01 * k1 + p02 * k2 +
                p03 * k3 + p04 * k4) >> shift2;
        CLAMP_STORE(dp[0],     pix0);
      }

      /* next line */
      sl += sll;
      dl += dll;
    }
  }

  if (pbuff != buff) mlib_free(pbuff);

  return MLIB_SUCCESS;
}

#endif /* __sparc ( for x86, using integer multiplies is faster ) */

/***************************************************************/
#if IMG_TYPE == 1

#undef  KSIZE
#define KSIZE 7

mlib_status CONV_FUNC(7x7)(mlib_image       *dst,
                           const mlib_image *src,
                           const mlib_s32   *kern,
                           mlib_s32         scalef_expon,
                           mlib_s32         cmask)
{
  FTYPE    buff[(KSIZE + 3)*BUFF_LINE], *buffs[2*(KSIZE + 1)], *buffd;
  FTYPE    k[KSIZE*KSIZE];
  mlib_s32 l, m, buff_ind;
  mlib_s32 d0, d1;
  FTYPE    k0, k1, k2, k3, k4, k5, k6;
  FTYPE    p0, p1, p2, p3, p4, p5, p6, p7;
  DTYPE *sl2, *sl3, *sl4, *sl5, *sl6;
  DEF_VARS(DTYPE);
  DTYPE *sl1;
  mlib_s32 chan2;
  mlib_s32 *buffo, *buffi;
  LOAD_KERNEL(KSIZE*KSIZE);
  GET_SRC_DST_PARAMETERS(DTYPE);

  if (wid > BUFF_LINE) {
    pbuff = mlib_malloc((KSIZE + 3)*sizeof(FTYPE)*wid);

    if (pbuff == NULL) return MLIB_FAILURE;
  }

  for (l = 0; l < KSIZE + 1; l++) buffs[l] = pbuff + l*wid;
  for (l = 0; l < KSIZE + 1; l++) buffs[l + (KSIZE + 1)] = buffs[l];
  buffd = buffs[KSIZE] + wid;
  buffo = (mlib_s32*)(buffd + wid);
  buffi = buffo + (wid &~ 1);

  chan1 = nchannel;
  chan2 = chan1 + chan1;

  wid -= (KSIZE - 1);
  hgt -= (KSIZE - 1);

  adr_dst += ((KSIZE - 1)/2)*(dll + chan1);

  for (c = 0; c < nchannel; c++) {
    if (!(cmask & (1 << (nchannel - 1 - c)))) continue;

    sl = adr_src + c;
    dl = adr_dst + c;

    sl1 = sl  + sll;
    sl2 = sl1 + sll;
    sl3 = sl2 + sll;
    sl4 = sl3 + sll;
    sl5 = sl4 + sll;
    sl6 = sl5 + sll;
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
    for (i = 0; i < wid + (KSIZE - 1); i++) {
      buffs[0][i] = (FTYPE)sl[i*chan1];
      buffs[1][i] = (FTYPE)sl1[i*chan1];
      buffs[2][i] = (FTYPE)sl2[i*chan1];
      buffs[3][i] = (FTYPE)sl3[i*chan1];
      buffs[4][i] = (FTYPE)sl4[i*chan1];
      buffs[5][i] = (FTYPE)sl5[i*chan1];
      buffs[6][i] = (FTYPE)sl6[i*chan1];
    }

    buff_ind = 0;

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
    for (i = 0; i < wid; i++) buffd[i] = 0.0;

    sl += KSIZE*sll;

    for (j = 0; j < hgt; j++) {
      FTYPE    **buffc = buffs + buff_ind;
      FTYPE    *buffn = buffc[KSIZE];
      FTYPE    *pk = k;

      for (l = 0; l < KSIZE; l++) {
        FTYPE    *buff = buffc[l];
        d64_2x32 dd;

        sp = sl;
        dp = dl;

        p2 = buff[0]; p3 = buff[1]; p4 = buff[2];
        p5 = buff[3]; p6 = buff[4]; p7 = buff[5];

        k0 = *pk++; k1 = *pk++; k2 = *pk++; k3 = *pk++;
        k4 = *pk++; k5 = *pk++; k6 = *pk++;

        if (l < (KSIZE - 1)) {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
          for (i = 0; i <= (wid - 2); i += 2) {
            p0 = p2; p1 = p3; p2 = p4; p3 = p5; p4 = p6; p5 = p7;

            p6 = buff[i + 6]; p7 = buff[i + 7];

            buffd[i    ] += p0*k0 + p1*k1 + p2*k2 + p3*k3 + p4*k4 + p5*k5 + p6*k6;
            buffd[i + 1] += p1*k0 + p2*k1 + p3*k2 + p4*k3 + p5*k4 + p6*k5 + p7*k6;
          }

        } else {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
          for (i = 0; i <= (wid - 2); i += 2) {
            p0 = p2; p1 = p3; p2 = p4; p3 = p5; p4 = p6; p5 = p7;

            p6 = buff[i + 6]; p7 = buff[i + 7];

            LOAD_BUFF(buffi);

            dd.d64 = *(FTYPE   *)(buffi + i);
            buffn[i    ] = (FTYPE)dd.i32s.i0;
            buffn[i + 1] = (FTYPE)dd.i32s.i1;

            d0 = D2I(p0*k0 + p1*k1 + p2*k2 + p3*k3 + p4*k4 + p5*k5 + p6*k6 + buffd[i    ]);
            d1 = D2I(p1*k0 + p2*k1 + p3*k2 + p4*k3 + p5*k4 + p6*k5 + p7*k6 + buffd[i + 1]);

            dp[0    ] = FROM_S32(d0);
            dp[chan1] = FROM_S32(d1);

            buffd[i    ] = 0.0;
            buffd[i + 1] = 0.0;

            sp += chan2;
            dp += chan2;
          }
        }
      }

      /* last pixels */
      for (; i < wid; i++) {
        FTYPE    *pk = k, s = 0;
        mlib_s32 d0;

        for (l = 0; l < KSIZE; l++) {
          FTYPE    *buff = buffc[l] + i;

          for (m = 0; m < KSIZE; m++) s += buff[m] * (*pk++);
        }

        d0 = D2I(s);
        dp[0] = FROM_S32(d0);

        buffn[i] = (FTYPE)sp[0];

        sp += chan1;
        dp += chan1;
      }

      for (l = 0; l < (KSIZE - 1); l++) buffn[wid + l] = sp[l*chan1];

      /* next line */
      sl += sll;
      dl += dll;

      buff_ind++;

      if (buff_ind >= KSIZE + 1) buff_ind = 0;
    }
  }

  if (pbuff != buff) mlib_free(pbuff);

  return MLIB_SUCCESS;
}

#endif /* IMG_TYPE == 1 */

/***************************************************************/
#define MAX_KER   7
#define MAX_N    15

static mlib_status mlib_ImageConv1xN(mlib_image       *dst,
                                     const mlib_image *src,
                                     const mlib_d64   *k,
                                     mlib_s32         n,
                                     mlib_s32         dn,
                                     mlib_s32         cmask)
{
  FTYPE    buff[BUFF_SIZE];
  mlib_s32 off, kh;
  mlib_s32 d0, d1;
  const FTYPE    *pk;
  FTYPE    k0, k1, k2, k3;
  FTYPE    p0, p1, p2, p3, p4;
  DEF_VARS(DTYPE);
  DTYPE    *sl_c, *dl_c, *sl0;
  mlib_s32 l, hsize, max_hsize;
  GET_SRC_DST_PARAMETERS(DTYPE);

  hgt -= (n - 1);
  adr_dst += dn*dll;

  max_hsize = (CACHE_SIZE/sizeof(DTYPE))/sll;

  if (!max_hsize) max_hsize = 1;

  if (max_hsize > BUFF_SIZE) {
    pbuff = mlib_malloc(sizeof(FTYPE)*max_hsize);
  }

  chan1 = nchannel;

  sl_c = adr_src;
  dl_c = adr_dst;

  for (l = 0; l < hgt; l += hsize) {
    hsize = hgt - l;

    if (hsize > max_hsize) hsize = max_hsize;

    for (c = 0; c < nchannel; c++) {
      if (!(cmask & (1 << (chan1 - 1 - c)))) continue;

      sl = sl_c + c;
      dl = dl_c + c;

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
      for (j = 0; j < hsize; j++) pbuff[j] = 0.0;

      for (i = 0; i < wid; i++) {
        sl0 = sl;

        for (off = 0; off < (n - 4); off += 4) {
          pk = k + off;
          sp = sl0;

          k0 = pk[0]; k1 = pk[1]; k2 = pk[2]; k3 = pk[3];
          p2 = sp[0]; p3 = sp[sll]; p4 = sp[2*sll];
          sp += 3*sll;

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
          for (j = 0; j < hsize; j += 2) {
            p0 = p2; p1 = p3; p2 = p4;
            p3 = sp[0];
            p4 = sp[sll];

            pbuff[j    ] += p0*k0 + p1*k1 + p2*k2 + p3*k3;
            pbuff[j + 1] += p1*k0 + p2*k1 + p3*k2 + p4*k3;

            sp += 2*sll;
          }

          sl0 += 4*sll;
        }

        pk = k + off;
        sp = sl0;

        k0 = pk[0]; k1 = pk[1]; k2 = pk[2]; k3 = pk[3];
        p2 = sp[0]; p3 = sp[sll]; p4 = sp[2*sll];

        dp = dl;
        kh = n - off;

        if (kh == 4) {
          sp += 3*sll;

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
          for (j = 0; j <= (hsize - 2); j += 2) {
            p0 = p2; p1 = p3; p2 = p4;
            p3 = sp[0];
            p4 = sp[sll];

            d0 = D2I(p0*k0 + p1*k1 + p2*k2 + p3*k3 + pbuff[j]);
            d1 = D2I(p1*k0 + p2*k1 + p3*k2 + p4*k3 + pbuff[j + 1]);

            dp[0  ] = FROM_S32(d0);
            dp[dll] = FROM_S32(d1);

            pbuff[j] = 0;
            pbuff[j + 1] = 0;

            sp += 2*sll;
            dp += 2*dll;
          }

          if (j < hsize) {
            p0 = p2; p1 = p3; p2 = p4;
            p3 = sp[0];

            d0 = D2I(p0*k0 + p1*k1 + p2*k2 + p3*k3 + pbuff[j]);

            pbuff[j] = 0;

            dp[0] = FROM_S32(d0);
          }

        } else if (kh == 3) {
          sp += 2*sll;

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
          for (j = 0; j <= (hsize - 2); j += 2) {
            p0 = p2; p1 = p3;
            p2 = sp[0];
            p3 = sp[sll];

            d0 = D2I(p0*k0 + p1*k1 + p2*k2 + pbuff[j]);
            d1 = D2I(p1*k0 + p2*k1 + p3*k2 + pbuff[j + 1]);

            dp[0  ] = FROM_S32(d0);
            dp[dll] = FROM_S32(d1);

            pbuff[j] = 0;
            pbuff[j + 1] = 0;

            sp += 2*sll;
            dp += 2*dll;
          }

          if (j < hsize) {
            p0 = p2; p1 = p3;
            p2 = sp[0];

            d0 = D2I(p0*k0 + p1*k1 + p2*k2 + pbuff[j]);

            pbuff[j] = 0;

            dp[0] = FROM_S32(d0);
          }

        } else if (kh == 2) {
          sp += sll;

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
          for (j = 0; j <= (hsize - 2); j += 2) {
            p0 = p2;
            p1 = sp[0];
            p2 = sp[sll];

            d0 = D2I(p0*k0 + p1*k1 + pbuff[j]);
            d1 = D2I(p1*k0 + p2*k1 + pbuff[j + 1]);

            dp[0  ] = FROM_S32(d0);
            dp[dll] = FROM_S32(d1);

            pbuff[j] = 0;
            pbuff[j + 1] = 0;

            sp += 2*sll;
            dp += 2*dll;
          }

          if (j < hsize) {
            p0 = p2;
            p1 = sp[0];

            d0 = D2I(p0*k0 + p1*k1 + pbuff[j]);

            pbuff[j] = 0;

            dp[0] = FROM_S32(d0);
          }

        } else /* if (kh == 1) */ {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
          for (j = 0; j < hsize; j++) {
            p0 = sp[0];

            d0 = D2I(p0*k0 + pbuff[j]);

            dp[0] = FROM_S32(d0);

            pbuff[j] = 0;

            sp += sll;
            dp += dll;
          }
        }

        sl += chan1;
        dl += chan1;
      }
    }

    sl_c += max_hsize*sll;
    dl_c += max_hsize*dll;
  }

  if (pbuff != buff) mlib_free(pbuff);

  return MLIB_SUCCESS;
}

/***************************************************************/
mlib_status CONV_FUNC(MxN)(mlib_image       *dst,
                           const mlib_image *src,
                           const mlib_s32   *kernel,
                           mlib_s32         m,
                           mlib_s32         n,
                           mlib_s32         dm,
                           mlib_s32         dn,
                           mlib_s32         scale,
                           mlib_s32         cmask)
{
  FTYPE    buff[BUFF_SIZE], *buffs_arr[2*(MAX_N + 1)];
  FTYPE    **buffs = buffs_arr, *buffd;
  FTYPE    akernel[256], *k = akernel, fscale = DSCALE;
  mlib_s32 mn, l, off, kw, bsize, buff_ind;
  mlib_s32 d0, d1;
  FTYPE    k0, k1, k2, k3, k4, k5, k6;
  FTYPE    p0, p1, p2, p3, p4, p5, p6, p7;
  d64_2x32 dd;
  DEF_VARS(DTYPE);
  mlib_s32 chan2;
  mlib_s32 *buffo, *buffi;
  mlib_status status = MLIB_SUCCESS;

  GET_SRC_DST_PARAMETERS(DTYPE);

  if (scale > 30) {
    fscale *= 1.0/(1 << 30);
    scale -= 30;
  }

  fscale /= (1 << scale);

  mn = m*n;

  if (mn > 256) {
    k = mlib_malloc(mn*sizeof(mlib_d64));

    if (k == NULL) return MLIB_FAILURE;
  }

  for (i = 0; i < mn; i++) {
    k[i] = kernel[i]*fscale;
  }

  if (m == 1) {
    status = mlib_ImageConv1xN(dst, src, k, n, dn, cmask);
    FREE_AND_RETURN_STATUS;
  }

  bsize = (n + 3)*wid;

  if ((bsize > BUFF_SIZE) || (n > MAX_N)) {
    pbuff = mlib_malloc(sizeof(FTYPE)*bsize + sizeof(FTYPE *)*2*(n + 1));

    if (pbuff == NULL) {
      status = MLIB_FAILURE;
      FREE_AND_RETURN_STATUS;
    }
    buffs = (FTYPE   **)(pbuff + bsize);
  }

  for (l = 0; l < (n + 1); l++) buffs[l] = pbuff + l*wid;
  for (l = 0; l < (n + 1); l++) buffs[l + (n + 1)] = buffs[l];
  buffd = buffs[n] + wid;
  buffo = (mlib_s32*)(buffd + wid);
  buffi = buffo + (wid &~ 1);

  chan1 = nchannel;
  chan2 = chan1 + chan1;

  wid -= (m - 1);
  hgt -= (n - 1);
  adr_dst += dn*dll + dm*nchannel;

  for (c = 0; c < nchannel; c++) {
    if (!(cmask & (1 << (chan1 - 1 - c)))) continue;

    sl = adr_src + c;
    dl = adr_dst + c;

    for (l = 0; l < n; l++) {
      FTYPE    *buff = buffs[l];

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
      for (i = 0; i < wid + (m - 1); i++) {
        buff[i] = (FTYPE)sl[i*chan1];
      }

      sl += sll;
    }

    buff_ind = 0;

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
    for (i = 0; i < wid; i++) buffd[i] = 0.0;

    for (j = 0; j < hgt; j++) {
      FTYPE    **buffc = buffs + buff_ind;
      FTYPE    *buffn = buffc[n];
      FTYPE    *pk = k;

      for (l = 0; l < n; l++) {
        FTYPE    *buff_l = buffc[l];

        for (off = 0; off < m;) {
          FTYPE    *buff = buff_l + off;

          kw = m - off;

          if (kw > 2*MAX_KER) kw = MAX_KER; else
            if (kw > MAX_KER) kw = kw/2;
          off += kw;

          sp = sl;
          dp = dl;

          p2 = buff[0]; p3 = buff[1]; p4 = buff[2];
          p5 = buff[3]; p6 = buff[4]; p7 = buff[5];

          k0 = pk[0]; k1 = pk[1]; k2 = pk[2]; k3 = pk[3];
          k4 = pk[4]; k5 = pk[5]; k6 = pk[6];
          pk += kw;

          if (kw == 7) {

            if (l < (n - 1) || off < m) {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2; p1 = p3; p2 = p4; p3 = p5; p4 = p6; p5 = p7;

                p6 = buff[i + 6]; p7 = buff[i + 7];

                buffd[i    ] += p0*k0 + p1*k1 + p2*k2 + p3*k3 + p4*k4 + p5*k5 + p6*k6;
                buffd[i + 1] += p1*k0 + p2*k1 + p3*k2 + p4*k3 + p5*k4 + p6*k5 + p7*k6;
              }

            } else {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2; p1 = p3; p2 = p4; p3 = p5; p4 = p6; p5 = p7;

                p6 = buff[i + 6]; p7 = buff[i + 7];

                LOAD_BUFF(buffi);

                dd.d64 = *(FTYPE   *)(buffi + i);
                buffn[i    ] = (FTYPE)dd.i32s.i0;
                buffn[i + 1] = (FTYPE)dd.i32s.i1;

                d0 = D2I(p0*k0 + p1*k1 + p2*k2 + p3*k3 + p4*k4 + p5*k5 + p6*k6 + buffd[i    ]);
                d1 = D2I(p1*k0 + p2*k1 + p3*k2 + p4*k3 + p5*k4 + p6*k5 + p7*k6 + buffd[i + 1]);

                dp[0    ] = FROM_S32(d0);
                dp[chan1] = FROM_S32(d1);

                buffd[i    ] = 0.0;
                buffd[i + 1] = 0.0;

                sp += chan2;
                dp += chan2;
              }
            }

          } else if (kw == 6) {

            if (l < (n - 1) || off < m) {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2; p1 = p3; p2 = p4; p3 = p5; p4 = p6;

                p5 = buff[i + 5]; p6 = buff[i + 6];

                buffd[i    ] += p0*k0 + p1*k1 + p2*k2 + p3*k3 + p4*k4 + p5*k5;
                buffd[i + 1] += p1*k0 + p2*k1 + p3*k2 + p4*k3 + p5*k4 + p6*k5;
              }

            } else {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2; p1 = p3; p2 = p4; p3 = p5; p4 = p6;

                p5 = buff[i + 5]; p6 = buff[i + 6];

                buffn[i    ] = (FTYPE)sp[0];
                buffn[i + 1] = (FTYPE)sp[chan1];

                d0 = D2I(p0*k0 + p1*k1 + p2*k2 + p3*k3 + p4*k4 + p5*k5 + buffd[i    ]);
                d1 = D2I(p1*k0 + p2*k1 + p3*k2 + p4*k3 + p5*k4 + p6*k5 + buffd[i + 1]);

                dp[0    ] = FROM_S32(d0);
                dp[chan1] = FROM_S32(d1);

                buffd[i    ] = 0.0;
                buffd[i + 1] = 0.0;

                sp += chan2;
                dp += chan2;
              }
            }

          } else if (kw == 5) {

            if (l < (n - 1) || off < m) {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2; p1 = p3; p2 = p4; p3 = p5;

                p4 = buff[i + 4]; p5 = buff[i + 5];

                buffd[i    ] += p0*k0 + p1*k1 + p2*k2 + p3*k3 + p4*k4;
                buffd[i + 1] += p1*k0 + p2*k1 + p3*k2 + p4*k3 + p5*k4;
              }

            } else {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2; p1 = p3; p2 = p4; p3 = p5;

                p4 = buff[i + 4]; p5 = buff[i + 5];

                buffn[i    ] = (FTYPE)sp[0];
                buffn[i + 1] = (FTYPE)sp[chan1];

                d0 = D2I(p0*k0 + p1*k1 + p2*k2 + p3*k3 + p4*k4 + buffd[i    ]);
                d1 = D2I(p1*k0 + p2*k1 + p3*k2 + p4*k3 + p5*k4 + buffd[i + 1]);

                dp[0    ] = FROM_S32(d0);
                dp[chan1] = FROM_S32(d1);

                buffd[i    ] = 0.0;
                buffd[i + 1] = 0.0;

                sp += chan2;
                dp += chan2;
              }
            }

          } else if (kw == 4) {

            if (l < (n - 1) || off < m) {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2; p1 = p3; p2 = p4;

                p3 = buff[i + 3]; p4 = buff[i + 4];

                buffd[i    ] += p0*k0 + p1*k1 + p2*k2 + p3*k3;
                buffd[i + 1] += p1*k0 + p2*k1 + p3*k2 + p4*k3;
              }

            } else {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2; p1 = p3; p2 = p4;

                p3 = buff[i + 3]; p4 = buff[i + 4];

                buffn[i    ] = (FTYPE)sp[0];
                buffn[i + 1] = (FTYPE)sp[chan1];

                d0 = D2I(p0*k0 + p1*k1 + p2*k2 + p3*k3 + buffd[i    ]);
                d1 = D2I(p1*k0 + p2*k1 + p3*k2 + p4*k3 + buffd[i + 1]);

                dp[0    ] = FROM_S32(d0);
                dp[chan1] = FROM_S32(d1);

                buffd[i    ] = 0.0;
                buffd[i + 1] = 0.0;

                sp += chan2;
                dp += chan2;
              }
            }

          } else if (kw == 3) {

            if (l < (n - 1) || off < m) {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2; p1 = p3;

                p2 = buff[i + 2]; p3 = buff[i + 3];

                buffd[i    ] += p0*k0 + p1*k1 + p2*k2;
                buffd[i + 1] += p1*k0 + p2*k1 + p3*k2;
              }

            } else {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2; p1 = p3;

                p2 = buff[i + 2]; p3 = buff[i + 3];

                buffn[i    ] = (FTYPE)sp[0];
                buffn[i + 1] = (FTYPE)sp[chan1];

                d0 = D2I(p0*k0 + p1*k1 + p2*k2 + buffd[i    ]);
                d1 = D2I(p1*k0 + p2*k1 + p3*k2 + buffd[i + 1]);

                dp[0    ] = FROM_S32(d0);
                dp[chan1] = FROM_S32(d1);

                buffd[i    ] = 0.0;
                buffd[i + 1] = 0.0;

                sp += chan2;
                dp += chan2;
              }
            }

          } else /*if (kw == 2)*/ {

            if (l < (n - 1) || off < m) {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2;

                p1 = buff[i + 1]; p2 = buff[i + 2];

                buffd[i    ] += p0*k0 + p1*k1;
                buffd[i + 1] += p1*k0 + p2*k1;
              }

            } else {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2;

                p1 = buff[i + 1]; p2 = buff[i + 2];

                buffn[i    ] = (FTYPE)sp[0];
                buffn[i + 1] = (FTYPE)sp[chan1];

                d0 = D2I(p0*k0 + p1*k1 + buffd[i    ]);
                d1 = D2I(p1*k0 + p2*k1 + buffd[i + 1]);

                dp[0    ] = FROM_S32(d0);
                dp[chan1] = FROM_S32(d1);

                buffd[i    ] = 0.0;
                buffd[i + 1] = 0.0;

                sp += chan2;
                dp += chan2;
              }
            }
          }
        }
      }

      /* last pixels */
      for (; i < wid; i++) {
        FTYPE    *pk = k, s = 0;
        mlib_s32 x, d0;

        for (l = 0; l < n; l++) {
          FTYPE    *buff = buffc[l] + i;

          for (x = 0; x < m; x++) s += buff[x] * (*pk++);
        }

        d0 = D2I(s);
        dp[0] = FROM_S32(d0);

        buffn[i] = (FTYPE)sp[0];

        sp += chan1;
        dp += chan1;
      }

      for (l = 0; l < (m - 1); l++) buffn[wid + l] = sp[l*chan1];

      /* next line */
      sl += sll;
      dl += dll;

      buff_ind++;

      if (buff_ind >= n + 1) buff_ind = 0;
    }
  }

  FREE_AND_RETURN_STATUS;
}

/***************************************************************/
#ifndef __sparc /* for x86, using integer multiplies is faster */

#define STORE_RES(res, x)                                       \
  x >>= shift2;                                                 \
  CLAMP_STORE(res, x)

mlib_status CONV_FUNC_I(MxN)(mlib_image       *dst,
                             const mlib_image *src,
                             const mlib_s32   *kernel,
                             mlib_s32         m,
                             mlib_s32         n,
                             mlib_s32         dm,
                             mlib_s32         dn,
                             mlib_s32         scale,
                             mlib_s32         cmask)
{
  mlib_s32 buff[BUFF_SIZE], *buffd = buff;
  mlib_s32 l, off, kw;
  mlib_s32 d0, d1, shift1, shift2;
  mlib_s32 k0, k1, k2, k3, k4, k5, k6;
  mlib_s32 p0, p1, p2, p3, p4, p5, p6, p7;
  DTYPE    *adr_src, *sl, *sp = NULL;
  DTYPE    *adr_dst, *dl, *dp = NULL;
  mlib_s32 wid, hgt, sll, dll;
  mlib_s32 nchannel, chan1;
  mlib_s32 i, j, c;
  mlib_s32 chan2;
  mlib_s32 k_locl[MAX_N*MAX_N], *k = k_locl;
  GET_SRC_DST_PARAMETERS(DTYPE);

#if IMG_TYPE != 1
  shift1 = 16;
#else
  shift1 = 8;
#endif /* IMG_TYPE != 1 */
  shift2 = scale - shift1;

  chan1 = nchannel;
  chan2 = chan1 + chan1;

  wid -= (m - 1);
  hgt -= (n - 1);
  adr_dst += dn*dll + dm*nchannel;

  if (wid > BUFF_SIZE) {
    buffd = mlib_malloc(sizeof(mlib_s32)*wid);

    if (buffd == NULL) return MLIB_FAILURE;
  }

  if (m*n > MAX_N*MAX_N) {
    k = mlib_malloc(sizeof(mlib_s32)*(m*n));

    if (k == NULL) {
      if (buffd != buff) mlib_free(buffd);
      return MLIB_FAILURE;
    }
  }

  for (i = 0; i < m*n; i++) {
    k[i] = kernel[i] >> shift1;
  }

  for (c = 0; c < nchannel; c++) {
    if (!(cmask & (1 << (nchannel - 1 - c)))) continue;

    sl = adr_src + c;
    dl = adr_dst + c;

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
    for (i = 0; i < wid; i++) buffd[i] = 0;

    for (j = 0; j < hgt; j++) {
      mlib_s32 *pk = k;

      for (l = 0; l < n; l++) {
        DTYPE *sp0 = sl + l*sll;

        for (off = 0; off < m;) {
          sp = sp0 + off*chan1;
          dp = dl;

          kw = m - off;

          if (kw > 2*MAX_KER) kw = MAX_KER; else
            if (kw > MAX_KER) kw = kw/2;
          off += kw;

          p2 = sp[0]; p3 = sp[chan1]; p4 = sp[chan2];
          p5 = sp[chan2 + chan1]; p6 = sp[chan2 + chan2]; p7 = sp[5*chan1];

          k0 = pk[0]; k1 = pk[1]; k2 = pk[2]; k3 = pk[3];
          k4 = pk[4]; k5 = pk[5]; k6 = pk[6];
          pk += kw;

          sp += (kw - 1)*chan1;

          if (kw == 7) {

            if (l < (n - 1) || off < m) {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2; p1 = p3; p2 = p4; p3 = p5; p4 = p6; p5 = p7;
                p6 = sp[0];
                p7 = sp[chan1];

                buffd[i    ] += p0*k0 + p1*k1 + p2*k2 + p3*k3 + p4*k4 + p5*k5 + p6*k6;
                buffd[i + 1] += p1*k0 + p2*k1 + p3*k2 + p4*k3 + p5*k4 + p6*k5 + p7*k6;

                sp += chan2;
              }

            } else {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2; p1 = p3; p2 = p4; p3 = p5; p4 = p6; p5 = p7;
                p6 = sp[0];
                p7 = sp[chan1];

                d0 = (p0*k0 + p1*k1 + p2*k2 + p3*k3 + p4*k4 + p5*k5 + p6*k6 + buffd[i    ]);
                d1 = (p1*k0 + p2*k1 + p3*k2 + p4*k3 + p5*k4 + p6*k5 + p7*k6 + buffd[i + 1]);

                STORE_RES(dp[0    ], d0);
                STORE_RES(dp[chan1], d1);

                buffd[i    ] = 0;
                buffd[i + 1] = 0;

                sp += chan2;
                dp += chan2;
              }
            }

          } else if (kw == 6) {

            if (l < (n - 1) || off < m) {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2; p1 = p3; p2 = p4; p3 = p5; p4 = p6;
                p5 = sp[0];
                p6 = sp[chan1];

                buffd[i    ] += p0*k0 + p1*k1 + p2*k2 + p3*k3 + p4*k4 + p5*k5;
                buffd[i + 1] += p1*k0 + p2*k1 + p3*k2 + p4*k3 + p5*k4 + p6*k5;

                sp += chan2;
              }

            } else {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2; p1 = p3; p2 = p4; p3 = p5; p4 = p6;
                p5 = sp[0];
                p6 = sp[chan1];

                d0 = (p0*k0 + p1*k1 + p2*k2 + p3*k3 + p4*k4 + p5*k5 + buffd[i    ]);
                d1 = (p1*k0 + p2*k1 + p3*k2 + p4*k3 + p5*k4 + p6*k5 + buffd[i + 1]);

                STORE_RES(dp[0    ], d0);
                STORE_RES(dp[chan1], d1);

                buffd[i    ] = 0;
                buffd[i + 1] = 0;

                sp += chan2;
                dp += chan2;
              }
            }

          } else if (kw == 5) {

            if (l < (n - 1) || off < m) {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2; p1 = p3; p2 = p4; p3 = p5;
                p4 = sp[0];
                p5 = sp[chan1];

                buffd[i    ] += p0*k0 + p1*k1 + p2*k2 + p3*k3 + p4*k4;
                buffd[i + 1] += p1*k0 + p2*k1 + p3*k2 + p4*k3 + p5*k4;

                sp += chan2;
              }

            } else {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2; p1 = p3; p2 = p4; p3 = p5;
                p4 = sp[0];
                p5 = sp[chan1];

                d0 = (p0*k0 + p1*k1 + p2*k2 + p3*k3 + p4*k4 + buffd[i    ]);
                d1 = (p1*k0 + p2*k1 + p3*k2 + p4*k3 + p5*k4 + buffd[i + 1]);

                STORE_RES(dp[0    ], d0);
                STORE_RES(dp[chan1], d1);

                buffd[i    ] = 0;
                buffd[i + 1] = 0;

                sp += chan2;
                dp += chan2;
              }
            }

          } else if (kw == 4) {

            if (l < (n - 1) || off < m) {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2; p1 = p3; p2 = p4;
                p3 = sp[0];
                p4 = sp[chan1];

                buffd[i    ] += p0*k0 + p1*k1 + p2*k2 + p3*k3;
                buffd[i + 1] += p1*k0 + p2*k1 + p3*k2 + p4*k3;

                sp += chan2;
              }

            } else {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2; p1 = p3; p2 = p4;
                p3 = sp[0];
                p4 = sp[chan1];

                d0 = (p0*k0 + p1*k1 + p2*k2 + p3*k3 + buffd[i    ]);
                d1 = (p1*k0 + p2*k1 + p3*k2 + p4*k3 + buffd[i + 1]);

                STORE_RES(dp[0    ], d0);
                STORE_RES(dp[chan1], d1);

                buffd[i    ] = 0;
                buffd[i + 1] = 0;

                sp += chan2;
                dp += chan2;
              }
            }

          } else if (kw == 3) {

            if (l < (n - 1) || off < m) {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2; p1 = p3;
                p2 = sp[0];
                p3 = sp[chan1];

                buffd[i    ] += p0*k0 + p1*k1 + p2*k2;
                buffd[i + 1] += p1*k0 + p2*k1 + p3*k2;

                sp += chan2;
              }

            } else {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2; p1 = p3;
                p2 = sp[0];
                p3 = sp[chan1];

                d0 = (p0*k0 + p1*k1 + p2*k2 + buffd[i    ]);
                d1 = (p1*k0 + p2*k1 + p3*k2 + buffd[i + 1]);

                STORE_RES(dp[0    ], d0);
                STORE_RES(dp[chan1], d1);

                buffd[i    ] = 0;
                buffd[i + 1] = 0;

                sp += chan2;
                dp += chan2;
              }
            }

          } else if (kw == 2) {

            if (l < (n - 1) || off < m) {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2;
                p1 = sp[0];
                p2 = sp[chan1];

                buffd[i    ] += p0*k0 + p1*k1;
                buffd[i + 1] += p1*k0 + p2*k1;

                sp += chan2;
              }

            } else {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = p2;
                p1 = sp[0];
                p2 = sp[chan1];

                d0 = (p0*k0 + p1*k1 + buffd[i    ]);
                d1 = (p1*k0 + p2*k1 + buffd[i + 1]);

                STORE_RES(dp[0    ], d0);
                STORE_RES(dp[chan1], d1);

                buffd[i    ] = 0;
                buffd[i + 1] = 0;

                sp += chan2;
                dp += chan2;
              }
            }

          } else /*if (kw == 1)*/ {

            if (l < (n - 1) || off < m) {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = sp[0];
                p1 = sp[chan1];

                buffd[i    ] += p0*k0;
                buffd[i + 1] += p1*k0;

                sp += chan2;
              }

            } else {
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
              for (i = 0; i <= (wid - 2); i += 2) {
                p0 = sp[0];
                p1 = sp[chan1];

                d0 = (p0*k0 + buffd[i    ]);
                d1 = (p1*k0 + buffd[i + 1]);

                STORE_RES(dp[0    ], d0);
                STORE_RES(dp[chan1], d1);

                buffd[i    ] = 0;
                buffd[i + 1] = 0;

                sp += chan2;
                dp += chan2;
              }
            }
          }
        }
      }

      /* last pixels */
      for (; i < wid; i++) {
        mlib_s32 *pk = k, s = 0;
        mlib_s32 x;

        for (l = 0; l < n; l++) {
          sp = sl + l*sll + i*chan1;

          for (x = 0; x < m; x++) {
            s += sp[0] * pk[0];
            sp += chan1;
            pk ++;
          }
        }

        STORE_RES(dp[0], s);

        sp += chan1;
        dp += chan1;
      }

      sl += sll;
      dl += dll;
    }
  }

  if (buffd != buff) mlib_free(buffd);
  if (k != k_locl) mlib_free(k);

  return MLIB_SUCCESS;
}

/***************************************************************/
#endif /* __sparc ( for x86, using integer multiplies is faster ) */

/***************************************************************/

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