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frameworks
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M4AIR_API.c
/* * Copyright (C) 2011 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ /** ************************************************************************* * @file M4AIR_API.c * @brief Area of Interest Resizer API ************************************************************************* */ #define M4AIR_YUV420_FORMAT_SUPPORTED #define M4AIR_YUV420A_FORMAT_SUPPORTED /************************* COMPILATION CHECKS ***************************/ #ifndef M4AIR_YUV420_FORMAT_SUPPORTED #ifndef M4AIR_BGR565_FORMAT_SUPPORTED #ifndef M4AIR_RGB565_FORMAT_SUPPORTED #ifndef M4AIR_BGR888_FORMAT_SUPPORTED #ifndef M4AIR_RGB888_FORMAT_SUPPORTED #ifndef M4AIR_JPG_FORMAT_SUPPORTED #error "Please define at least one input format for the AIR component" #endif #endif #endif #endif #endif #endif /******************************* INCLUDES *******************************/ #include "M4OSA_Types.h" #include "M4OSA_Error.h" #include "M4OSA_CoreID.h" #include "M4OSA_Mutex.h" #include "M4OSA_Memory.h" #include "M4VIFI_FiltersAPI.h" #include "M4AIR_API.h" /************************ M4AIR INTERNAL TYPES DEFINITIONS ***********************/ /** ****************************************************************************** * enum M4AIR_States * @brief The following enumeration defines the internal states of the AIR. ****************************************************************************** */ typedef enum { M4AIR_kCreated, /**< State after M4AIR_create has been called */ M4AIR_kConfigured /**< State after M4AIR_configure has been called */ }M4AIR_States; /** ****************************************************************************** * struct M4AIR_InternalContext * @brief The following structure is the internal context of the AIR. ****************************************************************************** */ typedef struct { M4AIR_States m_state; /**< Internal state */ M4AIR_InputFormatType m_inputFormat; /**< Input format like YUV420Planar, RGB565, JPG, etc ... */ M4AIR_Params m_params; /**< Current input Parameter of the processing */ M4OSA_UInt32 u32_x_inc[4]; /**< ratio between input and ouput width for YUV */ M4OSA_UInt32 u32_y_inc[4]; /**< ratio between input and ouput height for YUV */ M4OSA_UInt32 u32_x_accum_start[4]; /**< horizontal initial accumulator value */ M4OSA_UInt32 u32_y_accum_start[4]; /**< Vertical initial accumulator value */ M4OSA_UInt32 u32_x_accum[4]; /**< save of horizontal accumulator value */ M4OSA_UInt32 u32_y_accum[4]; /**< save of vertical accumulator value */ M4OSA_UInt8* pu8_data_in[4]; /**< Save of input plane pointers in case of stripe mode */ M4OSA_UInt32 m_procRows; /**< Number of processed rows, used in stripe mode only */ M4OSA_Bool m_bOnlyCopy; /**< Flag to know if we just perform a copy or a bilinear interpolation */ M4OSA_Bool m_bFlipX; /**< Depend on output orientation, used during processing to revert processing order in X coordinates */ M4OSA_Bool m_bFlipY; /**< Depend on output orientation, used during processing to revert processing order in Y coordinates */ M4OSA_Bool m_bRevertXY; /**< Depend on output orientation, used during processing to revert X and Y processing order (+-90 rotation) */ }M4AIR_InternalContext; /********************************* MACROS *******************************/ #define M4ERR_CHECK_NULL_RETURN_VALUE(retval, pointer)\ if ((pointer) == M4OSA_NULL) return ((M4OSA_ERR)(retval)); /********************** M4AIR PUBLIC API IMPLEMENTATION ********************/ /** ****************************************************************************** * M4OSA_ERR M4AIR_create(M4OSA_Context* pContext,M4AIR_InputFormatType inputFormat) * @brief This function initialize an instance of the AIR. * @param pContext: (IN/OUT) Address of the context to create * @param inputFormat: (IN) input format type. * @return M4NO_ERROR: there is no error * @return M4ERR_PARAMETER: pContext is M4OSA_NULL (debug only). Invalid formatType * @return M4ERR_ALLOC: No more memory is available ****************************************************************************** */ M4OSA_ERR M4AIR_create(M4OSA_Context* pContext,M4AIR_InputFormatType inputFormat) { M4OSA_ERR err = M4NO_ERROR ; M4AIR_InternalContext* pC = M4OSA_NULL ; /* Check that the address on the context is not NULL */ M4ERR_CHECK_NULL_RETURN_VALUE(M4ERR_PARAMETER, pContext) ; *pContext = M4OSA_NULL ; /* Internal Context creation */ pC = (M4AIR_InternalContext*)M4OSA_32bitAlignedMalloc(sizeof(M4AIR_InternalContext), M4AIR,(M4OSA_Char *)"AIR internal context") ; M4ERR_CHECK_NULL_RETURN_VALUE(M4ERR_ALLOC, pC) ; /* Check if the input format is supported */ switch(inputFormat) { #ifdef M4AIR_YUV420_FORMAT_SUPPORTED case M4AIR_kYUV420P: break ; #endif #ifdef M4AIR_YUV420A_FORMAT_SUPPORTED case M4AIR_kYUV420AP: break ; #endif default: err = M4ERR_AIR_FORMAT_NOT_SUPPORTED; goto M4AIR_create_cleanup ; } /**< Save input format and update state */ pC->m_inputFormat = inputFormat; pC->m_state = M4AIR_kCreated; /* Return the context to the caller */ *pContext = pC ; return M4NO_ERROR ; M4AIR_create_cleanup: /* Error management : we destroy the context if needed */ if(M4OSA_NULL != pC) { free(pC) ; } *pContext = M4OSA_NULL ; return err ; } /** ****************************************************************************** * M4OSA_ERR M4AIR_cleanUp(M4OSA_Context pContext) * @brief This function destroys an instance of the AIR component * @param pContext: (IN) Context identifying the instance to destroy * @return M4NO_ERROR: there is no error * @return M4ERR_PARAMETER: pContext is M4OSA_NULL (debug only). * @return M4ERR_STATE: Internal state is incompatible with this function call. ****************************************************************************** */ M4OSA_ERR M4AIR_cleanUp(M4OSA_Context pContext) { M4AIR_InternalContext* pC = (M4AIR_InternalContext*)pContext ; M4ERR_CHECK_NULL_RETURN_VALUE(M4ERR_PARAMETER, pContext) ; /**< Check state */ if((M4AIR_kCreated != pC->m_state)&&(M4AIR_kConfigured != pC->m_state)) { return M4ERR_STATE; } free(pC) ; return M4NO_ERROR ; } /** ****************************************************************************** * M4OSA_ERR M4AIR_configure(M4OSA_Context pContext, M4AIR_Params* pParams) * @brief This function will configure the AIR. * @note It will set the input and output coordinates and sizes, * and indicates if we will proceed in stripe or not. * In case a M4AIR_get in stripe mode was on going, it will cancel this previous * processing and reset the get process. * @param pContext: (IN) Context identifying the instance * @param pParams->m_bOutputStripe:(IN) Stripe mode. * @param pParams->m_inputCoord: (IN) X,Y coordinates of the first valid pixel in input. * @param pParams->m_inputSize: (IN) input ROI size. * @param pParams->m_outputSize: (IN) output size. * @return M4NO_ERROR: there is no error * @return M4ERR_ALLOC: No more memory space to add a new effect. * @return M4ERR_PARAMETER: pContext is M4OSA_NULL (debug only). * @return M4ERR_AIR_FORMAT_NOT_SUPPORTED: the requested input format is not supported. ****************************************************************************** */ M4OSA_ERR M4AIR_configure(M4OSA_Context pContext, M4AIR_Params* pParams) { M4AIR_InternalContext* pC = (M4AIR_InternalContext*)pContext ; M4OSA_UInt32 i,u32_width_in, u32_width_out, u32_height_in, u32_height_out; M4OSA_UInt32 nb_planes; M4ERR_CHECK_NULL_RETURN_VALUE(M4ERR_PARAMETER, pContext) ; if(M4AIR_kYUV420AP == pC->m_inputFormat) { nb_planes = 4; } else { nb_planes = 3; } /**< Check state */ if((M4AIR_kCreated != pC->m_state)&&(M4AIR_kConfigured != pC->m_state)) { return M4ERR_STATE; } /** Save parameters */ pC->m_params = *pParams; /* Check for the input&output width and height are even */ if( ((pC->m_params.m_inputSize.m_height)&0x1) || ((pC->m_params.m_inputSize.m_height)&0x1)) { return M4ERR_AIR_ILLEGAL_FRAME_SIZE; } if( ((pC->m_params.m_inputSize.m_width)&0x1) || ((pC->m_params.m_inputSize.m_width)&0x1)) { return M4ERR_AIR_ILLEGAL_FRAME_SIZE; } if(((pC->m_params.m_inputSize.m_width) == (pC->m_params.m_outputSize.m_width)) &&((pC->m_params.m_inputSize.m_height) == (pC->m_params.m_outputSize.m_height))) { /**< No resize in this case, we will just copy input in output */ pC->m_bOnlyCopy = M4OSA_TRUE; } else { pC->m_bOnlyCopy = M4OSA_FALSE; /**< Initialize internal variables used for resize filter */ for(i=0;i<nb_planes;i++) { u32_width_in = ((i==0)||(i==3))?pC->m_params.m_inputSize.m_width:\ (pC->m_params.m_inputSize.m_width+1)>>1; u32_height_in = ((i==0)||(i==3))?pC->m_params.m_inputSize.m_height:\ (pC->m_params.m_inputSize.m_height+1)>>1; u32_width_out = ((i==0)||(i==3))?pC->m_params.m_outputSize.m_width:\ (pC->m_params.m_outputSize.m_width+1)>>1; u32_height_out = ((i==0)||(i==3))?pC->m_params.m_outputSize.m_height:\ (pC->m_params.m_outputSize.m_height+1)>>1; /* Compute horizontal ratio between src and destination width.*/ if (u32_width_out >= u32_width_in) { pC->u32_x_inc[i] = ((u32_width_in-1) * 0x10000) / (u32_width_out-1); } else { pC->u32_x_inc[i] = (u32_width_in * 0x10000) / (u32_width_out); } /* Compute vertical ratio between src and destination height.*/ if (u32_height_out >= u32_height_in) { pC->u32_y_inc[i] = ((u32_height_in - 1) * 0x10000) / (u32_height_out-1); } else { pC->u32_y_inc[i] = (u32_height_in * 0x10000) / (u32_height_out); } /* Calculate initial accumulator value : u32_y_accum_start. u32_y_accum_start is coded on 15 bits, and represents a value between 0 and 0.5 */ if (pC->u32_y_inc[i] >= 0x10000) { /* Keep the fractionnal part, assimung that integer part is coded on the 16 high bits and the fractionnal on the 15 low bits */ pC->u32_y_accum_start[i] = pC->u32_y_inc[i] & 0xffff; if (!pC->u32_y_accum_start[i]) { pC->u32_y_accum_start[i] = 0x10000; } pC->u32_y_accum_start[i] >>= 1; } else { pC->u32_y_accum_start[i] = 0; } /**< Take into account that Y coordinate can be odd in this case we have to put a 0.5 offset for U and V plane as there a 2 times sub-sampled vs Y*/ if((pC->m_params.m_inputCoord.m_y&0x1)&&((i==1)||(i==2))) { pC->u32_y_accum_start[i] += 0x8000; } /* Calculate initial accumulator value : u32_x_accum_start. u32_x_accum_start is coded on 15 bits, and represents a value between 0 and 0.5 */ if (pC->u32_x_inc[i] >= 0x10000) { pC->u32_x_accum_start[i] = pC->u32_x_inc[i] & 0xffff; if (!pC->u32_x_accum_start[i]) { pC->u32_x_accum_start[i] = 0x10000; } pC->u32_x_accum_start[i] >>= 1; } else { pC->u32_x_accum_start[i] = 0; } /**< Take into account that X coordinate can be odd in this case we have to put a 0.5 offset for U and V plane as there a 2 times sub-sampled vs Y*/ if((pC->m_params.m_inputCoord.m_x&0x1)&&((i==1)||(i==2))) { pC->u32_x_accum_start[i] += 0x8000; } } } /**< Reset variable used for stripe mode */ pC->m_procRows = 0; /**< Initialize var for X/Y processing order according to orientation */ pC->m_bFlipX = M4OSA_FALSE; pC->m_bFlipY = M4OSA_FALSE; pC->m_bRevertXY = M4OSA_FALSE; switch(pParams->m_outputOrientation) { case M4COMMON_kOrientationTopLeft: break; case M4COMMON_kOrientationTopRight: pC->m_bFlipX = M4OSA_TRUE; break; case M4COMMON_kOrientationBottomRight: pC->m_bFlipX = M4OSA_TRUE; pC->m_bFlipY = M4OSA_TRUE; break; case M4COMMON_kOrientationBottomLeft: pC->m_bFlipY = M4OSA_TRUE; break; case M4COMMON_kOrientationLeftTop: pC->m_bRevertXY = M4OSA_TRUE; break; case M4COMMON_kOrientationRightTop: pC->m_bRevertXY = M4OSA_TRUE; pC->m_bFlipY = M4OSA_TRUE; break; case M4COMMON_kOrientationRightBottom: pC->m_bRevertXY = M4OSA_TRUE; pC->m_bFlipX = M4OSA_TRUE; pC->m_bFlipY = M4OSA_TRUE; break; case M4COMMON_kOrientationLeftBottom: pC->m_bRevertXY = M4OSA_TRUE; pC->m_bFlipX = M4OSA_TRUE; break; default: return M4ERR_PARAMETER; } /**< Update state */ pC->m_state = M4AIR_kConfigured; return M4NO_ERROR ; } /** ****************************************************************************** * M4OSA_ERR M4AIR_get(M4OSA_Context pContext, M4VIFI_ImagePlane* pIn, M4VIFI_ImagePlane* pOut) * @brief This function will provide the requested resized area of interest according to * settings provided in M4AIR_configure. * @note In case the input format type is JPEG, input plane(s) * in pIn is not used. In normal mode, dimension specified in output plane(s) structure * must be the same than the one specified in M4AIR_configure. In stripe mode, only the * width will be the same, height will be taken as the stripe height (typically 16). * In normal mode, this function is call once to get the full output picture. * In stripe mode, it is called for each stripe till the whole picture has been * retrieved,and the position of the output stripe in the output picture * is internally incremented at each step. * Any call to M4AIR_configure during stripe process will reset this one to the * beginning of the output picture. * @param pContext: (IN) Context identifying the instance * @param pIn: (IN) Plane structure containing input Plane(s). * @param pOut: (IN/OUT) Plane structure containing output Plane(s). * @return M4NO_ERROR: there is no error * @return M4ERR_ALLOC: No more memory space to add a new effect. * @return M4ERR_PARAMETER: pContext is M4OSA_NULL (debug only). ****************************************************************************** */ M4OSA_ERR M4AIR_get(M4OSA_Context pContext, M4VIFI_ImagePlane* pIn, M4VIFI_ImagePlane* pOut) { M4AIR_InternalContext* pC = (M4AIR_InternalContext*)pContext ; M4OSA_UInt32 i,j,k,u32_x_frac,u32_y_frac,u32_x_accum,u32_y_accum,u32_shift; M4OSA_UInt8 *pu8_data_in, *pu8_data_in_org, *pu8_data_in_tmp, *pu8_data_out; M4OSA_UInt8 *pu8_src_top; M4OSA_UInt8 *pu8_src_bottom; M4OSA_UInt32 u32_temp_value; M4OSA_Int32 i32_tmp_offset; M4OSA_UInt32 nb_planes; M4ERR_CHECK_NULL_RETURN_VALUE(M4ERR_PARAMETER, pContext) ; /**< Check state */ if(M4AIR_kConfigured != pC->m_state) { return M4ERR_STATE; } if(M4AIR_kYUV420AP == pC->m_inputFormat) { nb_planes = 4; } else { nb_planes = 3; } /**< Loop on each Plane */ for(i=0;i<nb_planes;i++) { /* Set the working pointers at the beginning of the input/output data field */ u32_shift = ((i==0)||(i==3))?0:1; /**< Depend on Luma or Chroma */ if((M4OSA_FALSE == pC->m_params.m_bOutputStripe)\ ||((M4OSA_TRUE == pC->m_params.m_bOutputStripe)&&(0 == pC->m_procRows))) { /**< For input, take care about ROI */ pu8_data_in = pIn[i].pac_data + pIn[i].u_topleft \ + (pC->m_params.m_inputCoord.m_x>>u32_shift) + (pC->m_params.m_inputCoord.m_y >> u32_shift) * pIn[i].u_stride; /** Go at end of line/column in case X/Y scanning is flipped */ if(M4OSA_TRUE == pC->m_bFlipX) { pu8_data_in += ((pC->m_params.m_inputSize.m_width)>>u32_shift) -1 ; } if(M4OSA_TRUE == pC->m_bFlipY) { pu8_data_in += ((pC->m_params.m_inputSize.m_height>>u32_shift) -1)\ * pIn[i].u_stride; } /**< Initialize accumulators in case we are using it (bilinear interpolation) */ if( M4OSA_FALSE == pC->m_bOnlyCopy) { pC->u32_x_accum[i] = pC->u32_x_accum_start[i]; pC->u32_y_accum[i] = pC->u32_y_accum_start[i]; } } else { /**< In case of stripe mode for other than first stripe, we need to recover input pointer from internal context */ pu8_data_in = pC->pu8_data_in[i]; } /**< In every mode, output data are at the beginning of the output plane */ pu8_data_out = pOut[i].pac_data + pOut[i].u_topleft; /**< Initialize input offset applied after each pixel */ if(M4OSA_FALSE == pC->m_bFlipY) { i32_tmp_offset = pIn[i].u_stride; } else { i32_tmp_offset = -pIn[i].u_stride; } /**< In this case, no bilinear interpolation is needed as input and output dimensions are the same */ if( M4OSA_TRUE == pC->m_bOnlyCopy) { /**< No +-90 rotation */ if(M4OSA_FALSE == pC->m_bRevertXY) { /**< No flip on X abscissa */ if(M4OSA_FALSE == pC->m_bFlipX) { /**< Loop on each row */ for(j=0;j<pOut[i].u_height;j++) { /**< Copy one whole line */ memcpy((void *)pu8_data_out, (void *)pu8_data_in, pOut[i].u_width); /**< Update pointers */ pu8_data_out += pOut[i].u_stride; if(M4OSA_FALSE == pC->m_bFlipY) { pu8_data_in += pIn[i].u_stride; } else { pu8_data_in -= pIn[i].u_stride; } } } else { /**< Loop on each row */ for(j=0;j<pOut[i].u_height;j++) { /**< Loop on each pixel of 1 row */ for(k=0;k<pOut[i].u_width;k++) { *pu8_data_out++ = *pu8_data_in--; } /**< Update pointers */ pu8_data_out += (pOut[i].u_stride - pOut[i].u_width); pu8_data_in += pOut[i].u_width + i32_tmp_offset; } } } /**< Here we have a +-90 rotation */ else { /**< Loop on each row */ for(j=0;j<pOut[i].u_height;j++) { pu8_data_in_tmp = pu8_data_in; /**< Loop on each pixel of 1 row */ for(k=0;k<pOut[i].u_width;k++) { *pu8_data_out++ = *pu8_data_in_tmp; /**< Update input pointer in order to go to next/past line */ pu8_data_in_tmp += i32_tmp_offset; } /**< Update pointers */ pu8_data_out += (pOut[i].u_stride - pOut[i].u_width); if(M4OSA_FALSE == pC->m_bFlipX) { pu8_data_in ++; } else { pu8_data_in --; } } } } /**< Bilinear interpolation */ else { if(3 != i) /**< other than alpha plane */ { /**No +-90 rotation */ if(M4OSA_FALSE == pC->m_bRevertXY) { /**< Loop on each row */ for(j=0;j<pOut[i].u_height;j++) { /* Vertical weight factor */ u32_y_frac = (pC->u32_y_accum[i]>>12)&15; /* Reinit horizontal weight factor */ u32_x_accum = pC->u32_x_accum_start[i]; if(M4OSA_TRUE == pC->m_bFlipX) { /**< Loop on each output pixel in a row */ for(k=0;k<pOut[i].u_width;k++) { u32_x_frac = (u32_x_accum >> 12)&15; /* Fraction of Horizontal weight factor */ pu8_src_top = (pu8_data_in - (u32_x_accum >> 16)) -1 ; pu8_src_bottom = pu8_src_top + i32_tmp_offset; /* Weighted combination */ u32_temp_value = (M4VIFI_UInt8)(((pu8_src_top[1]*(16-u32_x_frac) + pu8_src_top[0]*u32_x_frac)*(16-u32_y_frac) + (pu8_src_bottom[1]*(16-u32_x_frac) + pu8_src_bottom[0]*u32_x_frac)*u32_y_frac )>>8); *pu8_data_out++ = (M4VIFI_UInt8)u32_temp_value; /* Update horizontal accumulator */ u32_x_accum += pC->u32_x_inc[i]; } } else { /**< Loop on each output pixel in a row */ for(k=0;k<pOut[i].u_width;k++) { u32_x_frac = (u32_x_accum >> 12)&15; /* Fraction of Horizontal weight factor */ pu8_src_top = pu8_data_in + (u32_x_accum >> 16); pu8_src_bottom = pu8_src_top + i32_tmp_offset; /* Weighted combination */ u32_temp_value = (M4VIFI_UInt8)(((pu8_src_top[0]*(16-u32_x_frac) + pu8_src_top[1]*u32_x_frac)*(16-u32_y_frac) + (pu8_src_bottom[0]*(16-u32_x_frac) + pu8_src_bottom[1]*u32_x_frac)*u32_y_frac )>>8); *pu8_data_out++ = (M4VIFI_UInt8)u32_temp_value; /* Update horizontal accumulator */ u32_x_accum += pC->u32_x_inc[i]; } } pu8_data_out += pOut[i].u_stride - pOut[i].u_width; /* Update vertical accumulator */ pC->u32_y_accum[i] += pC->u32_y_inc[i]; if (pC->u32_y_accum[i]>>16) { pu8_data_in = pu8_data_in + (pC->u32_y_accum[i] >> 16) * i32_tmp_offset; pC->u32_y_accum[i] &= 0xffff; } } } /** +-90 rotation */ else { pu8_data_in_org = pu8_data_in; /**< Loop on each output row */ for(j=0;j<pOut[i].u_height;j++) { /* horizontal weight factor */ u32_x_frac = (pC->u32_x_accum[i]>>12)&15; /* Reinit accumulator */ u32_y_accum = pC->u32_y_accum_start[i]; if(M4OSA_TRUE == pC->m_bFlipX) { /**< Loop on each output pixel in a row */ for(k=0;k<pOut[i].u_width;k++) { u32_y_frac = (u32_y_accum >> 12)&15; /* Vertical weight factor */ pu8_src_top = (pu8_data_in - (pC->u32_x_accum[i] >> 16)) - 1; pu8_src_bottom = pu8_src_top + i32_tmp_offset; /* Weighted combination */ u32_temp_value = (M4VIFI_UInt8)(((pu8_src_top[1]*(16-u32_x_frac) + pu8_src_top[0]*u32_x_frac)*(16-u32_y_frac) + (pu8_src_bottom[1]*(16-u32_x_frac) + pu8_src_bottom[0]*u32_x_frac)*u32_y_frac )>>8); *pu8_data_out++ = (M4VIFI_UInt8)u32_temp_value; /* Update vertical accumulator */ u32_y_accum += pC->u32_y_inc[i]; if (u32_y_accum>>16) { pu8_data_in = pu8_data_in + (u32_y_accum >> 16) * i32_tmp_offset; u32_y_accum &= 0xffff; } } } else { /**< Loop on each output pixel in a row */ for(k=0;k<pOut[i].u_width;k++) { u32_y_frac = (u32_y_accum >> 12)&15; /* Vertical weight factor */ pu8_src_top = pu8_data_in + (pC->u32_x_accum[i] >> 16); pu8_src_bottom = pu8_src_top + i32_tmp_offset; /* Weighted combination */ u32_temp_value = (M4VIFI_UInt8)(((pu8_src_top[0]*(16-u32_x_frac) + pu8_src_top[1]*u32_x_frac)*(16-u32_y_frac) + (pu8_src_bottom[0]*(16-u32_x_frac) + pu8_src_bottom[1]*u32_x_frac)*u32_y_frac )>>8); *pu8_data_out++ = (M4VIFI_UInt8)u32_temp_value; /* Update vertical accumulator */ u32_y_accum += pC->u32_y_inc[i]; if (u32_y_accum>>16) { pu8_data_in = pu8_data_in + (u32_y_accum >> 16) * i32_tmp_offset; u32_y_accum &= 0xffff; } } } pu8_data_out += pOut[i].u_stride - pOut[i].u_width; /* Update horizontal accumulator */ pC->u32_x_accum[i] += pC->u32_x_inc[i]; pu8_data_in = pu8_data_in_org; } } }/** 3 != i */ else { /**No +-90 rotation */ if(M4OSA_FALSE == pC->m_bRevertXY) { /**< Loop on each row */ for(j=0;j<pOut[i].u_height;j++) { /* Vertical weight factor */ u32_y_frac = (pC->u32_y_accum[i]>>12)&15; /* Reinit horizontal weight factor */ u32_x_accum = pC->u32_x_accum_start[i]; if(M4OSA_TRUE == pC->m_bFlipX) { /**< Loop on each output pixel in a row */ for(k=0;k<pOut[i].u_width;k++) { u32_x_frac = (u32_x_accum >> 12)&15; /* Fraction of Horizontal weight factor */ pu8_src_top = (pu8_data_in - (u32_x_accum >> 16)) -1 ; pu8_src_bottom = pu8_src_top + i32_tmp_offset; /* Weighted combination */ u32_temp_value = (M4VIFI_UInt8)(((pu8_src_top[1]*(16-u32_x_frac) + pu8_src_top[0]*u32_x_frac)*(16-u32_y_frac) + (pu8_src_bottom[1]*(16-u32_x_frac) + pu8_src_bottom[0]*u32_x_frac)*u32_y_frac )>>8); u32_temp_value= (u32_temp_value >> 7)*0xff; *pu8_data_out++ = (M4VIFI_UInt8)u32_temp_value; /* Update horizontal accumulator */ u32_x_accum += pC->u32_x_inc[i]; } } else { /**< Loop on each output pixel in a row */ for(k=0;k<pOut[i].u_width;k++) { u32_x_frac = (u32_x_accum >> 12)&15; /* Fraction of Horizontal weight factor */ pu8_src_top = pu8_data_in + (u32_x_accum >> 16); pu8_src_bottom = pu8_src_top + i32_tmp_offset; /* Weighted combination */ u32_temp_value = (M4VIFI_UInt8)(((pu8_src_top[0]*(16-u32_x_frac) + pu8_src_top[1]*u32_x_frac)*(16-u32_y_frac) + (pu8_src_bottom[0]*(16-u32_x_frac) + pu8_src_bottom[1]*u32_x_frac)*u32_y_frac )>>8); u32_temp_value= (u32_temp_value >> 7)*0xff; *pu8_data_out++ = (M4VIFI_UInt8)u32_temp_value; /* Update horizontal accumulator */ u32_x_accum += pC->u32_x_inc[i]; } } pu8_data_out += pOut[i].u_stride - pOut[i].u_width; /* Update vertical accumulator */ pC->u32_y_accum[i] += pC->u32_y_inc[i]; if (pC->u32_y_accum[i]>>16) { pu8_data_in = pu8_data_in + (pC->u32_y_accum[i] >> 16) * i32_tmp_offset; pC->u32_y_accum[i] &= 0xffff; } } } /**< M4OSA_FALSE == pC->m_bRevertXY */ /** +-90 rotation */ else { pu8_data_in_org = pu8_data_in; /**< Loop on each output row */ for(j=0;j<pOut[i].u_height;j++) { /* horizontal weight factor */ u32_x_frac = (pC->u32_x_accum[i]>>12)&15; /* Reinit accumulator */ u32_y_accum = pC->u32_y_accum_start[i]; if(M4OSA_TRUE == pC->m_bFlipX) { /**< Loop on each output pixel in a row */ for(k=0;k<pOut[i].u_width;k++) { u32_y_frac = (u32_y_accum >> 12)&15; /* Vertical weight factor */ pu8_src_top = (pu8_data_in - (pC->u32_x_accum[i] >> 16)) - 1; pu8_src_bottom = pu8_src_top + i32_tmp_offset; /* Weighted combination */ u32_temp_value = (M4VIFI_UInt8)(((pu8_src_top[1]*(16-u32_x_frac) + pu8_src_top[0]*u32_x_frac)*(16-u32_y_frac) + (pu8_src_bottom[1]*(16-u32_x_frac) + pu8_src_bottom[0]*u32_x_frac)*u32_y_frac )>>8); u32_temp_value= (u32_temp_value >> 7)*0xff; *pu8_data_out++ = (M4VIFI_UInt8)u32_temp_value; /* Update vertical accumulator */ u32_y_accum += pC->u32_y_inc[i]; if (u32_y_accum>>16) { pu8_data_in = pu8_data_in + (u32_y_accum >> 16) * i32_tmp_offset; u32_y_accum &= 0xffff; } } } else { /**< Loop on each output pixel in a row */ for(k=0;k<pOut[i].u_width;k++) { u32_y_frac = (u32_y_accum >> 12)&15; /* Vertical weight factor */ pu8_src_top = pu8_data_in + (pC->u32_x_accum[i] >> 16); pu8_src_bottom = pu8_src_top + i32_tmp_offset; /* Weighted combination */ u32_temp_value = (M4VIFI_UInt8)(((pu8_src_top[0]*(16-u32_x_frac) + pu8_src_top[1]*u32_x_frac)*(16-u32_y_frac) + (pu8_src_bottom[0]*(16-u32_x_frac) + pu8_src_bottom[1]*u32_x_frac)*u32_y_frac )>>8); u32_temp_value= (u32_temp_value >> 7)*0xff; *pu8_data_out++ = (M4VIFI_UInt8)u32_temp_value; /* Update vertical accumulator */ u32_y_accum += pC->u32_y_inc[i]; if (u32_y_accum>>16) { pu8_data_in = pu8_data_in + (u32_y_accum >> 16) * i32_tmp_offset; u32_y_accum &= 0xffff; } } } pu8_data_out += pOut[i].u_stride - pOut[i].u_width; /* Update horizontal accumulator */ pC->u32_x_accum[i] += pC->u32_x_inc[i]; pu8_data_in = pu8_data_in_org; } } /**< M4OSA_TRUE == pC->m_bRevertXY */ }/** 3 == i */ } /**< In case of stripe mode, save current input pointer */ if(M4OSA_TRUE == pC->m_params.m_bOutputStripe) { pC->pu8_data_in[i] = pu8_data_in; } } /**< Update number of processed rows, reset it if we have finished with the whole processing */ pC->m_procRows += pOut[0].u_height; if(M4OSA_FALSE == pC->m_bRevertXY) { if(pC->m_params.m_outputSize.m_height <= pC->m_procRows) pC->m_procRows = 0; } else { if(pC->m_params.m_outputSize.m_width <= pC->m_procRows) pC->m_procRows = 0; } return M4NO_ERROR ; }
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