Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Yong Zhi | 14662 | 97.45% | 1 | 50.00% |
Bingbu Cao | 383 | 2.55% | 1 | 50.00% |
Total | 15045 | 2 |
// SPDX-License-Identifier: GPL-2.0 // Copyright (C) 2018 Intel Corporation #include <linux/device.h> #include "ipu3-css.h" #include "ipu3-css-fw.h" #include "ipu3-tables.h" #define DIV_ROUND_CLOSEST_DOWN(a, b) (((a) + ((b) / 2) - 1) / (b)) #define roundclosest_down(a, b) (DIV_ROUND_CLOSEST_DOWN(a, b) * (b)) #define IPU3_UAPI_ANR_MAX_RESET ((1 << 12) - 1) #define IPU3_UAPI_ANR_MIN_RESET (((-1) << 12) + 1) struct ipu3_css_scaler_info { unsigned int phase_step; /* Same for luma/chroma */ int exp_shift; unsigned int phase_init; /* luma/chroma dependent */ int pad_left; int pad_right; int crop_left; int crop_top; }; static unsigned int ipu3_css_scaler_get_exp(unsigned int counter, unsigned int divider) { int i = fls(divider) - fls(counter); if (i <= 0) return 0; if (divider >> i < counter) i = i - 1; return i; } /* Set up the CSS scaler look up table */ static void ipu3_css_scaler_setup_lut(unsigned int taps, unsigned int input_width, unsigned int output_width, int phase_step_correction, const int *coeffs, unsigned int coeffs_size, s8 coeff_lut[], struct ipu3_css_scaler_info *info) { int tap, phase, phase_sum_left, phase_sum_right; int exponent = ipu3_css_scaler_get_exp(output_width, input_width); int mantissa = (1 << exponent) * output_width; unsigned int phase_step; if (input_width == output_width) { for (phase = 0; phase < IMGU_SCALER_PHASES; phase++) { for (tap = 0; tap < taps; tap++) { coeff_lut[phase * IMGU_SCALER_FILTER_TAPS + tap] = 0; } } info->phase_step = IMGU_SCALER_PHASES * (1 << IMGU_SCALER_PHASE_COUNTER_PREC_REF); info->exp_shift = 0; info->pad_left = 0; info->pad_right = 0; info->phase_init = 0; info->crop_left = 0; info->crop_top = 0; return; } for (phase = 0; phase < IMGU_SCALER_PHASES; phase++) { for (tap = 0; tap < taps; tap++) { /* flip table to for convolution reverse indexing */ s64 coeff = coeffs[coeffs_size - ((tap * (coeffs_size / taps)) + phase) - 1]; coeff *= mantissa; coeff = div64_long(coeff, input_width); /* Add +"0.5" */ coeff += 1 << (IMGU_SCALER_COEFF_BITS - 1); coeff >>= IMGU_SCALER_COEFF_BITS; coeff_lut[phase * IMGU_SCALER_FILTER_TAPS + tap] = coeff; } } phase_step = IMGU_SCALER_PHASES * (1 << IMGU_SCALER_PHASE_COUNTER_PREC_REF) * output_width / input_width; phase_step += phase_step_correction; phase_sum_left = (taps / 2 * IMGU_SCALER_PHASES * (1 << IMGU_SCALER_PHASE_COUNTER_PREC_REF)) - (1 << (IMGU_SCALER_PHASE_COUNTER_PREC_REF - 1)); phase_sum_right = (taps / 2 * IMGU_SCALER_PHASES * (1 << IMGU_SCALER_PHASE_COUNTER_PREC_REF)) + (1 << (IMGU_SCALER_PHASE_COUNTER_PREC_REF - 1)); info->exp_shift = IMGU_SCALER_MAX_EXPONENT_SHIFT - exponent; info->pad_left = (phase_sum_left % phase_step == 0) ? phase_sum_left / phase_step - 1 : phase_sum_left / phase_step; info->pad_right = (phase_sum_right % phase_step == 0) ? phase_sum_right / phase_step - 1 : phase_sum_right / phase_step; info->phase_init = phase_sum_left - phase_step * info->pad_left; info->phase_step = phase_step; info->crop_left = taps - 1; info->crop_top = taps - 1; } /* * Calculates the exact output image width/height, based on phase_step setting * (must be perfectly aligned with hardware). */ static unsigned int ipu3_css_scaler_calc_scaled_output(unsigned int input, struct ipu3_css_scaler_info *info) { unsigned int arg1 = input * info->phase_step + (1 - IMGU_SCALER_TAPS_Y / 2) * IMGU_SCALER_FIR_PHASES - IMGU_SCALER_FIR_PHASES / (2 * IMGU_SCALER_PHASES); unsigned int arg2 = ((IMGU_SCALER_TAPS_Y / 2) * IMGU_SCALER_FIR_PHASES + IMGU_SCALER_FIR_PHASES / (2 * IMGU_SCALER_PHASES)) * IMGU_SCALER_FIR_PHASES + info->phase_step / 2; return ((arg1 + (arg2 - IMGU_SCALER_FIR_PHASES * info->phase_step) / IMGU_SCALER_FIR_PHASES) / (2 * IMGU_SCALER_FIR_PHASES)) * 2; } /* * Calculate the output width and height, given the luma * and chroma details of a scaler */ static void ipu3_css_scaler_calc(u32 input_width, u32 input_height, u32 target_width, u32 target_height, struct imgu_abi_osys_config *cfg, struct ipu3_css_scaler_info *info_luma, struct ipu3_css_scaler_info *info_chroma, unsigned int *output_width, unsigned int *output_height, unsigned int *procmode) { u32 out_width = target_width; u32 out_height = target_height; const unsigned int height_alignment = 2; int phase_step_correction = -1; /* * Calculate scaled output width. If the horizontal and vertical scaling * factor is different, then choose the biggest and crop off excess * lines or columns after formatting. */ if (target_height * input_width > target_width * input_height) target_width = DIV_ROUND_UP(target_height * input_width, input_height); if (input_width == target_width) *procmode = IMGU_ABI_OSYS_PROCMODE_BYPASS; else *procmode = IMGU_ABI_OSYS_PROCMODE_DOWNSCALE; memset(&cfg->scaler_coeffs_chroma, 0, sizeof(cfg->scaler_coeffs_chroma)); memset(&cfg->scaler_coeffs_luma, 0, sizeof(*cfg->scaler_coeffs_luma)); do { phase_step_correction++; ipu3_css_scaler_setup_lut(IMGU_SCALER_TAPS_Y, input_width, target_width, phase_step_correction, ipu3_css_downscale_4taps, IMGU_SCALER_DOWNSCALE_4TAPS_LEN, cfg->scaler_coeffs_luma, info_luma); ipu3_css_scaler_setup_lut(IMGU_SCALER_TAPS_UV, input_width, target_width, phase_step_correction, ipu3_css_downscale_2taps, IMGU_SCALER_DOWNSCALE_2TAPS_LEN, cfg->scaler_coeffs_chroma, info_chroma); out_width = ipu3_css_scaler_calc_scaled_output(input_width, info_luma); out_height = ipu3_css_scaler_calc_scaled_output(input_height, info_luma); } while ((out_width < target_width || out_height < target_height || !IS_ALIGNED(out_height, height_alignment)) && phase_step_correction <= 5); *output_width = out_width; *output_height = out_height; } /********************** Osys routines for scaler****************************/ static void ipu3_css_osys_set_format(enum imgu_abi_frame_format host_format, unsigned int *osys_format, unsigned int *osys_tiling) { *osys_format = IMGU_ABI_OSYS_FORMAT_YUV420; *osys_tiling = IMGU_ABI_OSYS_TILING_NONE; switch (host_format) { case IMGU_ABI_FRAME_FORMAT_YUV420: *osys_format = IMGU_ABI_OSYS_FORMAT_YUV420; break; case IMGU_ABI_FRAME_FORMAT_YV12: *osys_format = IMGU_ABI_OSYS_FORMAT_YV12; break; case IMGU_ABI_FRAME_FORMAT_NV12: *osys_format = IMGU_ABI_OSYS_FORMAT_NV12; break; case IMGU_ABI_FRAME_FORMAT_NV16: *osys_format = IMGU_ABI_OSYS_FORMAT_NV16; break; case IMGU_ABI_FRAME_FORMAT_NV21: *osys_format = IMGU_ABI_OSYS_FORMAT_NV21; break; case IMGU_ABI_FRAME_FORMAT_NV12_TILEY: *osys_format = IMGU_ABI_OSYS_FORMAT_NV12; *osys_tiling = IMGU_ABI_OSYS_TILING_Y; break; default: /* For now, assume use default values */ break; } } /* * Function calculates input frame stripe offset, based * on output frame stripe offset and filter parameters. */ static int ipu3_css_osys_calc_stripe_offset(int stripe_offset_out, int fir_phases, int phase_init, int phase_step, int pad_left) { int stripe_offset_inp = stripe_offset_out * fir_phases - pad_left * phase_step; return DIV_ROUND_UP(stripe_offset_inp - phase_init, phase_step); } /* * Calculate input frame phase, given the output frame * stripe offset and filter parameters */ static int ipu3_css_osys_calc_stripe_phase_init(int stripe_offset_out, int fir_phases, int phase_init, int phase_step, int pad_left) { int stripe_offset_inp = ipu3_css_osys_calc_stripe_offset(stripe_offset_out, fir_phases, phase_init, phase_step, pad_left); return phase_init + ((pad_left + stripe_offset_inp) * phase_step) - stripe_offset_out * fir_phases; } /* * This function calculates input frame stripe width, * based on output frame stripe offset and filter parameters */ static int ipu3_css_osys_calc_inp_stripe_width(int stripe_width_out, int fir_phases, int phase_init, int phase_step, int fir_taps, int pad_left, int pad_right) { int stripe_width_inp = (stripe_width_out + fir_taps - 1) * fir_phases; stripe_width_inp = DIV_ROUND_UP(stripe_width_inp - phase_init, phase_step); return stripe_width_inp - pad_left - pad_right; } /* * This function calculates output frame stripe width, basedi * on output frame stripe offset and filter parameters */ static int ipu3_css_osys_out_stripe_width(int stripe_width_inp, int fir_phases, int phase_init, int phase_step, int fir_taps, int pad_left, int pad_right, int column_offset) { int stripe_width_out = (pad_left + stripe_width_inp + pad_right - column_offset) * phase_step; stripe_width_out = (stripe_width_out + phase_init) / fir_phases; return stripe_width_out - (fir_taps - 1); } struct ipu3_css_reso { unsigned int input_width; unsigned int input_height; enum imgu_abi_frame_format input_format; unsigned int pin_width[IMGU_ABI_OSYS_PINS]; unsigned int pin_height[IMGU_ABI_OSYS_PINS]; unsigned int pin_stride[IMGU_ABI_OSYS_PINS]; enum imgu_abi_frame_format pin_format[IMGU_ABI_OSYS_PINS]; int chunk_width; int chunk_height; int block_height; int block_width; }; struct ipu3_css_frame_params { /* Output pins */ unsigned int enable; unsigned int format; unsigned int flip; unsigned int mirror; unsigned int tiling; unsigned int reduce_range; unsigned int width; unsigned int height; unsigned int stride; unsigned int scaled; unsigned int crop_left; unsigned int crop_top; }; struct ipu3_css_stripe_params { unsigned int processing_mode; unsigned int phase_step; unsigned int exp_shift; unsigned int phase_init_left_y; unsigned int phase_init_left_uv; unsigned int phase_init_top_y; unsigned int phase_init_top_uv; unsigned int pad_left_y; unsigned int pad_left_uv; unsigned int pad_right_y; unsigned int pad_right_uv; unsigned int pad_top_y; unsigned int pad_top_uv; unsigned int pad_bottom_y; unsigned int pad_bottom_uv; unsigned int crop_left_y; unsigned int crop_top_y; unsigned int crop_left_uv; unsigned int crop_top_uv; unsigned int start_column_y; unsigned int start_column_uv; unsigned int chunk_width; unsigned int chunk_height; unsigned int block_width; unsigned int block_height; unsigned int input_width; unsigned int input_height; int output_width[IMGU_ABI_OSYS_PINS]; int output_height[IMGU_ABI_OSYS_PINS]; int output_offset[IMGU_ABI_OSYS_PINS]; }; /* * frame_params - size IMGU_ABI_OSYS_PINS * stripe_params - size IPU3_UAPI_MAX_STRIPES */ static int ipu3_css_osys_calc_frame_and_stripe_params( struct ipu3_css *css, unsigned int stripes, struct imgu_abi_osys_config *osys, struct ipu3_css_scaler_info *scaler_luma, struct ipu3_css_scaler_info *scaler_chroma, struct ipu3_css_frame_params frame_params[], struct ipu3_css_stripe_params stripe_params[], unsigned int pipe) { struct ipu3_css_reso reso; unsigned int output_width, pin, s; u32 input_width, input_height, target_width, target_height; unsigned int procmode = 0; struct ipu3_css_pipe *css_pipe = &css->pipes[pipe]; input_width = css_pipe->rect[IPU3_CSS_RECT_GDC].width; input_height = css_pipe->rect[IPU3_CSS_RECT_GDC].height; target_width = css_pipe->queue[IPU3_CSS_QUEUE_VF].fmt.mpix.width; target_height = css_pipe->queue[IPU3_CSS_QUEUE_VF].fmt.mpix.height; /* Frame parameters */ /* Input width for Output System is output width of DVS (with GDC) */ reso.input_width = css_pipe->rect[IPU3_CSS_RECT_GDC].width; /* Input height for Output System is output height of DVS (with GDC) */ reso.input_height = css_pipe->rect[IPU3_CSS_RECT_GDC].height; reso.input_format = css_pipe->queue[IPU3_CSS_QUEUE_OUT].css_fmt->frame_format; reso.pin_width[IMGU_ABI_OSYS_PIN_OUT] = css_pipe->queue[IPU3_CSS_QUEUE_OUT].fmt.mpix.width; reso.pin_height[IMGU_ABI_OSYS_PIN_OUT] = css_pipe->queue[IPU3_CSS_QUEUE_OUT].fmt.mpix.height; reso.pin_stride[IMGU_ABI_OSYS_PIN_OUT] = css_pipe->queue[IPU3_CSS_QUEUE_OUT].width_pad; reso.pin_format[IMGU_ABI_OSYS_PIN_OUT] = css_pipe->queue[IPU3_CSS_QUEUE_OUT].css_fmt->frame_format; reso.pin_width[IMGU_ABI_OSYS_PIN_VF] = css_pipe->queue[IPU3_CSS_QUEUE_VF].fmt.mpix.width; reso.pin_height[IMGU_ABI_OSYS_PIN_VF] = css_pipe->queue[IPU3_CSS_QUEUE_VF].fmt.mpix.height; reso.pin_stride[IMGU_ABI_OSYS_PIN_VF] = css_pipe->queue[IPU3_CSS_QUEUE_VF].width_pad; reso.pin_format[IMGU_ABI_OSYS_PIN_VF] = css_pipe->queue[IPU3_CSS_QUEUE_VF].css_fmt->frame_format; /* Configure the frame parameters for all output pins */ frame_params[IMGU_ABI_OSYS_PIN_OUT].width = css_pipe->queue[IPU3_CSS_QUEUE_OUT].fmt.mpix.width; frame_params[IMGU_ABI_OSYS_PIN_OUT].height = css_pipe->queue[IPU3_CSS_QUEUE_OUT].fmt.mpix.height; frame_params[IMGU_ABI_OSYS_PIN_VF].width = css_pipe->queue[IPU3_CSS_QUEUE_VF].fmt.mpix.width; frame_params[IMGU_ABI_OSYS_PIN_VF].height = css_pipe->queue[IPU3_CSS_QUEUE_VF].fmt.mpix.height; frame_params[IMGU_ABI_OSYS_PIN_VF].crop_top = 0; frame_params[IMGU_ABI_OSYS_PIN_VF].crop_left = 0; for (pin = 0; pin < IMGU_ABI_OSYS_PINS; pin++) { int enable = 0; int scaled = 0; unsigned int format = 0; unsigned int tiling = 0; frame_params[pin].flip = 0; frame_params[pin].mirror = 0; frame_params[pin].reduce_range = 0; if (reso.pin_width[pin] != 0 && reso.pin_height[pin] != 0) { enable = 1; if (pin == IMGU_ABI_OSYS_PIN_OUT) { if (reso.input_width < reso.pin_width[pin] || reso.input_height < reso.pin_height[pin]) return -EINVAL; /* * When input and output resolution is * different instead of scaling, cropping * should happen. Determine the crop factor * to do the symmetric cropping */ frame_params[pin].crop_left = roundclosest_down( (reso.input_width - reso.pin_width[pin]) / 2, IMGU_OSYS_DMA_CROP_W_LIMIT); frame_params[pin].crop_top = roundclosest_down( (reso.input_height - reso.pin_height[pin]) / 2, IMGU_OSYS_DMA_CROP_H_LIMIT); } else { if (reso.pin_width[pin] != reso.input_width || reso.pin_height[pin] != reso.input_height) { /* * If resolution is different at input * and output of OSYS, scaling is * considered except when pin is MAIN. * Later it will be decide whether * scaler factor is 1 or other * and cropping has to be done or not. */ scaled = 1; } } ipu3_css_osys_set_format(reso.pin_format[pin], &format, &tiling); } else { enable = 0; } frame_params[pin].enable = enable; frame_params[pin].format = format; frame_params[pin].tiling = tiling; frame_params[pin].stride = reso.pin_stride[pin]; frame_params[pin].scaled = scaled; } ipu3_css_scaler_calc(input_width, input_height, target_width, target_height, osys, scaler_luma, scaler_chroma, &reso.pin_width[IMGU_ABI_OSYS_PIN_VF], &reso.pin_height[IMGU_ABI_OSYS_PIN_VF], &procmode); dev_dbg(css->dev, "osys scaler procmode is %u", procmode); output_width = reso.pin_width[IMGU_ABI_OSYS_PIN_VF]; if (output_width < reso.input_width / 2) { /* Scaling factor <= 0.5 */ reso.chunk_width = IMGU_OSYS_BLOCK_WIDTH; reso.block_width = IMGU_OSYS_BLOCK_WIDTH; } else { /* 0.5 <= Scaling factor <= 1.0 */ reso.chunk_width = IMGU_OSYS_BLOCK_WIDTH / 2; reso.block_width = IMGU_OSYS_BLOCK_WIDTH; } if (output_width <= reso.input_width * 7 / 8) { /* Scaling factor <= 0.875 */ reso.chunk_height = IMGU_OSYS_BLOCK_HEIGHT; reso.block_height = IMGU_OSYS_BLOCK_HEIGHT; } else { /* 1.0 <= Scaling factor <= 1.75 */ reso.chunk_height = IMGU_OSYS_BLOCK_HEIGHT / 2; reso.block_height = IMGU_OSYS_BLOCK_HEIGHT; } /* * Calculate scaler configuration parameters based on input and output * resolution. */ if (frame_params[IMGU_ABI_OSYS_PIN_VF].enable) { /* * When aspect ratio is different between target resolution and * required resolution, determine the crop factor to do * symmetric cropping */ u32 w = reso.pin_width[IMGU_ABI_OSYS_PIN_VF] - frame_params[IMGU_ABI_OSYS_PIN_VF].width; u32 h = reso.pin_height[IMGU_ABI_OSYS_PIN_VF] - frame_params[IMGU_ABI_OSYS_PIN_VF].height; frame_params[IMGU_ABI_OSYS_PIN_VF].crop_left = roundclosest_down(w / 2, IMGU_OSYS_DMA_CROP_W_LIMIT); frame_params[IMGU_ABI_OSYS_PIN_VF].crop_top = roundclosest_down(h / 2, IMGU_OSYS_DMA_CROP_H_LIMIT); if (reso.input_height % 4 || reso.input_width % 8) { dev_err(css->dev, "OSYS input width is not multiple of 8 or\n"); dev_err(css->dev, "height is not multiple of 4\n"); return -EINVAL; } } /* Stripe parameters */ if (frame_params[IMGU_ABI_OSYS_PIN_VF].enable) { output_width = reso.pin_width[IMGU_ABI_OSYS_PIN_VF]; } else { /* * in case scaler output is not enabled * take output width as input width since * there is no scaling at main pin. * Due to the fact that main pin can be different * from input resolution to osys in the case of cropping, * main pin resolution is not taken. */ output_width = reso.input_width; } for (s = 0; s < stripes; s++) { int stripe_offset_inp_y = 0; int stripe_offset_inp_uv = 0; int stripe_offset_out_y = 0; int stripe_offset_out_uv = 0; int stripe_phase_init_y = scaler_luma->phase_init; int stripe_phase_init_uv = scaler_chroma->phase_init; int stripe_offset_blk_y = 0; int stripe_offset_blk_uv = 0; int stripe_offset_col_y = 0; int stripe_offset_col_uv = 0; int stripe_pad_left_y = scaler_luma->pad_left; int stripe_pad_left_uv = scaler_chroma->pad_left; int stripe_pad_right_y = scaler_luma->pad_right; int stripe_pad_right_uv = scaler_chroma->pad_right; int stripe_crop_left_y = scaler_luma->crop_left; int stripe_crop_left_uv = scaler_chroma->crop_left; int stripe_input_width_y = reso.input_width; int stripe_input_width_uv = 0; int stripe_output_width_y = output_width; int stripe_output_width_uv = 0; int chunk_floor_y = 0; int chunk_floor_uv = 0; int chunk_ceil_uv = 0; if (stripes > 1) { if (s > 0) { /* Calculate stripe offsets */ stripe_offset_out_y = output_width * s / stripes; stripe_offset_out_y = rounddown(stripe_offset_out_y, IPU3_UAPI_ISP_VEC_ELEMS); stripe_offset_out_uv = stripe_offset_out_y / IMGU_LUMA_TO_CHROMA_RATIO; stripe_offset_inp_y = ipu3_css_osys_calc_stripe_offset( stripe_offset_out_y, IMGU_OSYS_FIR_PHASES, scaler_luma->phase_init, scaler_luma->phase_step, scaler_luma->pad_left); stripe_offset_inp_uv = ipu3_css_osys_calc_stripe_offset( stripe_offset_out_uv, IMGU_OSYS_FIR_PHASES, scaler_chroma->phase_init, scaler_chroma->phase_step, scaler_chroma->pad_left); /* Calculate stripe phase init */ stripe_phase_init_y = ipu3_css_osys_calc_stripe_phase_init( stripe_offset_out_y, IMGU_OSYS_FIR_PHASES, scaler_luma->phase_init, scaler_luma->phase_step, scaler_luma->pad_left); stripe_phase_init_uv = ipu3_css_osys_calc_stripe_phase_init( stripe_offset_out_uv, IMGU_OSYS_FIR_PHASES, scaler_chroma->phase_init, scaler_chroma->phase_step, scaler_chroma->pad_left); /* * Chunk boundary corner case - luma and chroma * start from different input chunks. */ chunk_floor_y = rounddown(stripe_offset_inp_y, reso.chunk_width); chunk_floor_uv = rounddown(stripe_offset_inp_uv, reso.chunk_width / IMGU_LUMA_TO_CHROMA_RATIO); if (chunk_floor_y != chunk_floor_uv * IMGU_LUMA_TO_CHROMA_RATIO) { /* * Match starting luma/chroma chunks. * Decrease offset for UV and add output * cropping. */ stripe_offset_inp_uv -= 1; stripe_crop_left_uv += 1; stripe_phase_init_uv -= scaler_luma->phase_step; if (stripe_phase_init_uv < 0) stripe_phase_init_uv = stripe_phase_init_uv + IMGU_OSYS_FIR_PHASES; } /* * FW workaround for a HW bug: if the first * chroma pixel is generated exactly at the end * of chunck scaler HW may not output the pixel * for downscale factors smaller than 1.5 * (timing issue). */ chunk_ceil_uv = roundup(stripe_offset_inp_uv, reso.chunk_width / IMGU_LUMA_TO_CHROMA_RATIO); if (stripe_offset_inp_uv == chunk_ceil_uv - IMGU_OSYS_TAPS_UV) { /* * Decrease input offset and add * output cropping */ stripe_offset_inp_uv -= 1; stripe_phase_init_uv -= scaler_luma->phase_step; if (stripe_phase_init_uv < 0) { stripe_phase_init_uv += IMGU_OSYS_FIR_PHASES; stripe_crop_left_uv += 1; } } /* * Calculate block and column offsets for the * input stripe */ stripe_offset_blk_y = rounddown(stripe_offset_inp_y, IMGU_INPUT_BLOCK_WIDTH); stripe_offset_blk_uv = rounddown(stripe_offset_inp_uv, IMGU_INPUT_BLOCK_WIDTH / IMGU_LUMA_TO_CHROMA_RATIO); stripe_offset_col_y = stripe_offset_inp_y - stripe_offset_blk_y; stripe_offset_col_uv = stripe_offset_inp_uv - stripe_offset_blk_uv; /* Left padding is only for the first stripe */ stripe_pad_left_y = 0; stripe_pad_left_uv = 0; } /* Right padding is only for the last stripe */ if (s < stripes - 1) { int next_offset; stripe_pad_right_y = 0; stripe_pad_right_uv = 0; next_offset = output_width * (s + 1) / stripes; next_offset = rounddown(next_offset, 64); stripe_output_width_y = next_offset - stripe_offset_out_y; } else { stripe_output_width_y = output_width - stripe_offset_out_y; } /* Calculate target output stripe width */ stripe_output_width_uv = stripe_output_width_y / IMGU_LUMA_TO_CHROMA_RATIO; /* Calculate input stripe width */ stripe_input_width_y = stripe_offset_col_y + ipu3_css_osys_calc_inp_stripe_width( stripe_output_width_y, IMGU_OSYS_FIR_PHASES, stripe_phase_init_y, scaler_luma->phase_step, IMGU_OSYS_TAPS_Y, stripe_pad_left_y, stripe_pad_right_y); stripe_input_width_uv = stripe_offset_col_uv + ipu3_css_osys_calc_inp_stripe_width( stripe_output_width_uv, IMGU_OSYS_FIR_PHASES, stripe_phase_init_uv, scaler_chroma->phase_step, IMGU_OSYS_TAPS_UV, stripe_pad_left_uv, stripe_pad_right_uv); stripe_input_width_uv = max(DIV_ROUND_UP( stripe_input_width_y, IMGU_LUMA_TO_CHROMA_RATIO), stripe_input_width_uv); stripe_input_width_y = stripe_input_width_uv * IMGU_LUMA_TO_CHROMA_RATIO; if (s >= stripes - 1) { stripe_input_width_y = reso.input_width - stripe_offset_blk_y; /* * The scaler requires that the last stripe * spans at least two input blocks. */ } /* * Spec: input stripe width must be a multiple of 8. * Increase the input width and recalculate the output * width. This may produce an extra column of junk * blocks which will be overwritten by the * next stripe. */ stripe_input_width_y = ALIGN(stripe_input_width_y, 8); stripe_output_width_y = ipu3_css_osys_out_stripe_width( stripe_input_width_y, IMGU_OSYS_FIR_PHASES, stripe_phase_init_y, scaler_luma->phase_step, IMGU_OSYS_TAPS_Y, stripe_pad_left_y, stripe_pad_right_y, stripe_offset_col_y); stripe_output_width_y = rounddown(stripe_output_width_y, IMGU_LUMA_TO_CHROMA_RATIO); } /* * Following section executes and process parameters * for both cases - Striping or No Striping. */ { unsigned int i; int pin_scale = 0; /*Input resolution */ stripe_params[s].input_width = stripe_input_width_y; stripe_params[s].input_height = reso.input_height; for (i = 0; i < IMGU_ABI_OSYS_PINS; i++) { if (frame_params[i].scaled) { /* * Output stripe resolution and offset * as produced by the scaler; actual * output resolution may be slightly * smaller. */ stripe_params[s].output_width[i] = stripe_output_width_y; stripe_params[s].output_height[i] = reso.pin_height[i]; stripe_params[s].output_offset[i] = stripe_offset_out_y; pin_scale += frame_params[i].scaled; } else { /* Unscaled pin */ stripe_params[s].output_width[i] = stripe_params[s].input_width; stripe_params[s].output_height[i] = stripe_params[s].input_height; stripe_params[s].output_offset[i] = stripe_offset_blk_y; } } /* If no pin use scale, we use BYPASS mode */ stripe_params[s].processing_mode = procmode; stripe_params[s].phase_step = scaler_luma->phase_step; stripe_params[s].exp_shift = scaler_luma->exp_shift; stripe_params[s].phase_init_left_y = stripe_phase_init_y; stripe_params[s].phase_init_left_uv = stripe_phase_init_uv; stripe_params[s].phase_init_top_y = scaler_luma->phase_init; stripe_params[s].phase_init_top_uv = scaler_chroma->phase_init; stripe_params[s].pad_left_y = stripe_pad_left_y; stripe_params[s].pad_left_uv = stripe_pad_left_uv; stripe_params[s].pad_right_y = stripe_pad_right_y; stripe_params[s].pad_right_uv = stripe_pad_right_uv; stripe_params[s].pad_top_y = scaler_luma->pad_left; stripe_params[s].pad_top_uv = scaler_chroma->pad_left; stripe_params[s].pad_bottom_y = scaler_luma->pad_right; stripe_params[s].pad_bottom_uv = scaler_chroma->pad_right; stripe_params[s].crop_left_y = stripe_crop_left_y; stripe_params[s].crop_top_y = scaler_luma->crop_top; stripe_params[s].crop_left_uv = stripe_crop_left_uv; stripe_params[s].crop_top_uv = scaler_chroma->crop_top; stripe_params[s].start_column_y = stripe_offset_col_y; stripe_params[s].start_column_uv = stripe_offset_col_uv; stripe_params[s].chunk_width = reso.chunk_width; stripe_params[s].chunk_height = reso.chunk_height; stripe_params[s].block_width = reso.block_width; stripe_params[s].block_height = reso.block_height; } } return 0; } /* * This function configures the Output Formatter System, given the number of * stripes, scaler luma and chrome parameters */ static int ipu3_css_osys_calc(struct ipu3_css *css, unsigned int pipe, unsigned int stripes, struct imgu_abi_osys_config *osys, struct ipu3_css_scaler_info *scaler_luma, struct ipu3_css_scaler_info *scaler_chroma, struct imgu_abi_stripes block_stripes[]) { struct ipu3_css_frame_params frame_params[IMGU_ABI_OSYS_PINS]; struct ipu3_css_stripe_params stripe_params[IPU3_UAPI_MAX_STRIPES]; struct imgu_abi_osys_formatter_params *param; unsigned int pin, s; struct ipu3_css_pipe *css_pipe = &css->pipes[pipe]; memset(osys, 0, sizeof(*osys)); /* Compute the frame and stripe params */ if (ipu3_css_osys_calc_frame_and_stripe_params(css, stripes, osys, scaler_luma, scaler_chroma, frame_params, stripe_params, pipe)) return -EINVAL; /* Output formatter system parameters */ for (s = 0; s < stripes; s++) { struct imgu_abi_osys_scaler_params *scaler = &osys->scaler[s].param; int fifo_addr_fmt = IMGU_FIFO_ADDR_SCALER_TO_FMT; int fifo_addr_ack = IMGU_FIFO_ADDR_SCALER_TO_SP; /* OUTPUT 0 / PIN 0 is only Scaler output */ scaler->inp_buf_y_st_addr = IMGU_VMEM1_INP_BUF_ADDR; /* * = (IMGU_OSYS_BLOCK_WIDTH / IMGU_VMEM1_ELEMS_PER_VEC) * = (2 * IPU3_UAPI_ISP_VEC_ELEMS) / * (IMGU_HIVE_OF_SYS_OF_SYSTEM_NWAYS) * = 2 * 64 / 32 = 4 */ scaler->inp_buf_y_line_stride = IMGU_VMEM1_Y_STRIDE; /* * = (IMGU_VMEM1_V_OFFSET + VMEM1_uv_size) * = (IMGU_VMEM1_U_OFFSET + VMEM1_uv_size) + * (VMEM1_y_size / 4) * = (VMEM1_y_size) + (VMEM1_y_size / 4) + * (IMGU_OSYS_BLOCK_HEIGHT * IMGU_VMEM1_Y_STRIDE)/4 * = (IMGU_OSYS_BLOCK_HEIGHT * IMGU_VMEM1_Y_STRIDE) */ scaler->inp_buf_y_buffer_stride = IMGU_VMEM1_BUF_SIZE; scaler->inp_buf_u_st_addr = IMGU_VMEM1_INP_BUF_ADDR + IMGU_VMEM1_U_OFFSET; scaler->inp_buf_v_st_addr = IMGU_VMEM1_INP_BUF_ADDR + IMGU_VMEM1_V_OFFSET; scaler->inp_buf_uv_line_stride = IMGU_VMEM1_UV_STRIDE; scaler->inp_buf_uv_buffer_stride = IMGU_VMEM1_BUF_SIZE; scaler->inp_buf_chunk_width = stripe_params[s].chunk_width; scaler->inp_buf_nr_buffers = IMGU_OSYS_NUM_INPUT_BUFFERS; /* Output buffers */ scaler->out_buf_y_st_addr = IMGU_VMEM1_INT_BUF_ADDR; scaler->out_buf_y_line_stride = stripe_params[s].block_width / IMGU_VMEM1_ELEMS_PER_VEC; scaler->out_buf_y_buffer_stride = IMGU_VMEM1_BUF_SIZE; scaler->out_buf_u_st_addr = IMGU_VMEM1_INT_BUF_ADDR + IMGU_VMEM1_U_OFFSET; scaler->out_buf_v_st_addr = IMGU_VMEM1_INT_BUF_ADDR + IMGU_VMEM1_V_OFFSET; scaler->out_buf_uv_line_stride = stripe_params[s].block_width / IMGU_VMEM1_ELEMS_PER_VEC / 2; scaler->out_buf_uv_buffer_stride = IMGU_VMEM1_BUF_SIZE; scaler->out_buf_nr_buffers = IMGU_OSYS_NUM_INTERM_BUFFERS; /* Intermediate buffers */ scaler->int_buf_y_st_addr = IMGU_VMEM2_BUF_Y_ADDR; scaler->int_buf_y_line_stride = IMGU_VMEM2_BUF_Y_STRIDE; scaler->int_buf_u_st_addr = IMGU_VMEM2_BUF_U_ADDR; scaler->int_buf_v_st_addr = IMGU_VMEM2_BUF_V_ADDR; scaler->int_buf_uv_line_stride = IMGU_VMEM2_BUF_UV_STRIDE; scaler->int_buf_height = IMGU_VMEM2_LINES_PER_BLOCK; scaler->int_buf_chunk_width = stripe_params[s].chunk_height; scaler->int_buf_chunk_height = stripe_params[s].block_width; /* Context buffers */ scaler->ctx_buf_hor_y_st_addr = IMGU_VMEM3_HOR_Y_ADDR; scaler->ctx_buf_hor_u_st_addr = IMGU_VMEM3_HOR_U_ADDR; scaler->ctx_buf_hor_v_st_addr = IMGU_VMEM3_HOR_V_ADDR; scaler->ctx_buf_ver_y_st_addr = IMGU_VMEM3_VER_Y_ADDR; scaler->ctx_buf_ver_u_st_addr = IMGU_VMEM3_VER_U_ADDR; scaler->ctx_buf_ver_v_st_addr = IMGU_VMEM3_VER_V_ADDR; /* Addresses for release-input and process-output tokens */ scaler->release_inp_buf_addr = fifo_addr_ack; scaler->release_inp_buf_en = 1; scaler->release_out_buf_en = 1; scaler->process_out_buf_addr = fifo_addr_fmt; /* Settings dimensions, padding, cropping */ scaler->input_image_y_width = stripe_params[s].input_width; scaler->input_image_y_height = stripe_params[s].input_height; scaler->input_image_y_start_column = stripe_params[s].start_column_y; scaler->input_image_uv_start_column = stripe_params[s].start_column_uv; scaler->input_image_y_left_pad = stripe_params[s].pad_left_y; scaler->input_image_uv_left_pad = stripe_params[s].pad_left_uv; scaler->input_image_y_right_pad = stripe_params[s].pad_right_y; scaler->input_image_uv_right_pad = stripe_params[s].pad_right_uv; scaler->input_image_y_top_pad = stripe_params[s].pad_top_y; scaler->input_image_uv_top_pad = stripe_params[s].pad_top_uv; scaler->input_image_y_bottom_pad = stripe_params[s].pad_bottom_y; scaler->input_image_uv_bottom_pad = stripe_params[s].pad_bottom_uv; scaler->processing_mode = stripe_params[s].processing_mode; scaler->scaling_ratio = stripe_params[s].phase_step; scaler->y_left_phase_init = stripe_params[s].phase_init_left_y; scaler->uv_left_phase_init = stripe_params[s].phase_init_left_uv; scaler->y_top_phase_init = stripe_params[s].phase_init_top_y; scaler->uv_top_phase_init = stripe_params[s].phase_init_top_uv; scaler->coeffs_exp_shift = stripe_params[s].exp_shift; scaler->out_y_left_crop = stripe_params[s].crop_left_y; scaler->out_uv_left_crop = stripe_params[s].crop_left_uv; scaler->out_y_top_crop = stripe_params[s].crop_top_y; scaler->out_uv_top_crop = stripe_params[s].crop_top_uv; for (pin = 0; pin < IMGU_ABI_OSYS_PINS; pin++) { int in_fifo_addr; int out_fifo_addr; int block_width_vecs; int input_width_s; int input_width_vecs; int input_buf_y_st_addr; int input_buf_u_st_addr; int input_buf_v_st_addr; int input_buf_y_line_stride; int input_buf_uv_line_stride; int output_buf_y_line_stride; int output_buf_uv_line_stride; int output_buf_nr_y_lines; int block_height; int block_width; struct imgu_abi_osys_frame_params *fr_pr; fr_pr = &osys->frame[pin].param; /* Frame parameters */ fr_pr->enable = frame_params[pin].enable; fr_pr->format = frame_params[pin].format; fr_pr->mirror = frame_params[pin].mirror; fr_pr->flip = frame_params[pin].flip; fr_pr->tiling = frame_params[pin].tiling; fr_pr->width = frame_params[pin].width; fr_pr->height = frame_params[pin].height; fr_pr->stride = frame_params[pin].stride; fr_pr->scaled = frame_params[pin].scaled; /* Stripe parameters */ osys->stripe[s].crop_top[pin] = frame_params[pin].crop_top; osys->stripe[s].input_width = stripe_params[s].input_width; osys->stripe[s].input_height = stripe_params[s].input_height; osys->stripe[s].block_height = stripe_params[s].block_height; osys->stripe[s].block_width = stripe_params[s].block_width; osys->stripe[s].output_width[pin] = stripe_params[s].output_width[pin]; osys->stripe[s].output_height[pin] = stripe_params[s].output_height[pin]; if (s == 0) { /* Only first stripe should do left cropping */ osys->stripe[s].crop_left[pin] = frame_params[pin].crop_left; osys->stripe[s].output_offset[pin] = stripe_params[s].output_offset[pin]; } else { /* * Stripe offset for other strips should be * adjusted according to the cropping done * at the first strip */ osys->stripe[s].crop_left[pin] = 0; osys->stripe[s].output_offset[pin] = (stripe_params[s].output_offset[pin] - osys->stripe[0].crop_left[pin]); } if (!frame_params[pin].enable) continue; /* Formatter: configurations */ /* * Get the dimensions of the input blocks of the * formatter, which is the same as the output * blocks of the scaler. */ if (frame_params[pin].scaled) { block_height = stripe_params[s].block_height; block_width = stripe_params[s].block_width; } else { block_height = IMGU_OSYS_BLOCK_HEIGHT; block_width = IMGU_OSYS_BLOCK_WIDTH; } block_width_vecs = block_width / IMGU_VMEM1_ELEMS_PER_VEC; /* * The input/output line stride depends on the * block size. */ input_buf_y_line_stride = block_width_vecs; input_buf_uv_line_stride = block_width_vecs / 2; output_buf_y_line_stride = block_width_vecs; output_buf_uv_line_stride = block_width_vecs / 2; output_buf_nr_y_lines = block_height; if (frame_params[pin].format == IMGU_ABI_OSYS_FORMAT_NV12 || frame_params[pin].format == IMGU_ABI_OSYS_FORMAT_NV21) output_buf_uv_line_stride = output_buf_y_line_stride; /* * Tiled outputs use a different output buffer * configuration. The input (= scaler output) block * width translates to a tile height, and the block * height to the tile width. The default block size of * 128x32 maps exactly onto a 4kB tile (512x8) for Y. * For UV, the tile width is always half. */ if (frame_params[pin].tiling) { output_buf_nr_y_lines = 8; output_buf_y_line_stride = 512 / IMGU_VMEM1_ELEMS_PER_VEC; output_buf_uv_line_stride = 256 / IMGU_VMEM1_ELEMS_PER_VEC; } /* * Store the output buffer line stride. Will be * used to compute buffer offsets in boundary * conditions when output blocks are partially * outside the image. */ osys->stripe[s].buf_stride[pin] = output_buf_y_line_stride * IMGU_HIVE_OF_SYS_OF_SYSTEM_NWAYS; if (frame_params[pin].scaled) { /* * The input buffs are the intermediate * buffers (scalers' output) */ input_buf_y_st_addr = IMGU_VMEM1_INT_BUF_ADDR; input_buf_u_st_addr = IMGU_VMEM1_INT_BUF_ADDR + IMGU_VMEM1_U_OFFSET; input_buf_v_st_addr = IMGU_VMEM1_INT_BUF_ADDR + IMGU_VMEM1_V_OFFSET; } else { /* * The input bufferss are the buffers * filled by the SP */ input_buf_y_st_addr = IMGU_VMEM1_INP_BUF_ADDR; input_buf_u_st_addr = IMGU_VMEM1_INP_BUF_ADDR + IMGU_VMEM1_U_OFFSET; input_buf_v_st_addr = IMGU_VMEM1_INP_BUF_ADDR + IMGU_VMEM1_V_OFFSET; } /* * The formatter input width must be rounded to * the block width. Otherwise the formatter will * not recognize the end of the line, resulting * in incorrect tiling (system may hang!) and * possibly other problems. */ input_width_s = roundup(stripe_params[s].output_width[pin], block_width); input_width_vecs = input_width_s / IMGU_VMEM1_ELEMS_PER_VEC; out_fifo_addr = IMGU_FIFO_ADDR_FMT_TO_SP; /* * Process-output tokens must be sent to the SP. * When scaling, the release-input tokens can be * sent directly to the scaler, otherwise the * formatter should send them to the SP. */ if (frame_params[pin].scaled) in_fifo_addr = IMGU_FIFO_ADDR_FMT_TO_SCALER; else in_fifo_addr = IMGU_FIFO_ADDR_FMT_TO_SP; /* Formatter */ param = &osys->formatter[s][pin].param; param->format = frame_params[pin].format; param->flip = frame_params[pin].flip; param->mirror = frame_params[pin].mirror; param->tiling = frame_params[pin].tiling; param->reduce_range = frame_params[pin].reduce_range; param->alpha_blending = 0; param->release_inp_addr = in_fifo_addr; param->release_inp_en = 1; param->process_out_buf_addr = out_fifo_addr; param->image_width_vecs = input_width_vecs; param->image_height_lines = stripe_params[s].output_height[pin]; param->inp_buff_y_st_addr = input_buf_y_st_addr; param->inp_buff_y_line_stride = input_buf_y_line_stride; param->inp_buff_y_buffer_stride = IMGU_VMEM1_BUF_SIZE; param->int_buff_u_st_addr = input_buf_u_st_addr; param->int_buff_v_st_addr = input_buf_v_st_addr; param->inp_buff_uv_line_stride = input_buf_uv_line_stride; param->inp_buff_uv_buffer_stride = IMGU_VMEM1_BUF_SIZE; param->out_buff_level = 0; param->out_buff_nr_y_lines = output_buf_nr_y_lines; param->out_buff_u_st_offset = IMGU_VMEM1_U_OFFSET; param->out_buff_v_st_offset = IMGU_VMEM1_V_OFFSET; param->out_buff_y_line_stride = output_buf_y_line_stride; param->out_buff_uv_line_stride = output_buf_uv_line_stride; param->hist_buff_st_addr = IMGU_VMEM1_HST_BUF_ADDR; param->hist_buff_line_stride = IMGU_VMEM1_HST_BUF_STRIDE; param->hist_buff_nr_lines = IMGU_VMEM1_HST_BUF_NLINES; } } block_stripes[0].offset = 0; if (stripes <= 1) { block_stripes[0].width = stripe_params[0].input_width; block_stripes[0].height = stripe_params[0].input_height; } else { struct imgu_fw_info *bi = &css->fwp->binary_header[css_pipe->bindex]; unsigned int sp_block_width = bi->info.isp.sp.block.block_width * IPU3_UAPI_ISP_VEC_ELEMS; block_stripes[0].width = roundup(stripe_params[0].input_width, sp_block_width); block_stripes[1].offset = rounddown(css_pipe->rect[IPU3_CSS_RECT_GDC].width - stripe_params[1].input_width, sp_block_width); block_stripes[1].width = roundup(css_pipe->rect[IPU3_CSS_RECT_GDC].width - block_stripes[1].offset, sp_block_width); block_stripes[0].height = css_pipe->rect[IPU3_CSS_RECT_GDC].height; block_stripes[1].height = block_stripes[0].height; } return 0; } /*********************** Mostly 3A operations ******************************/ /* * This function creates a "TO-DO list" (operations) for the sp code. * * There are 2 types of operations: * 1. Transfer: Issue DMA transfer request for copying grid cells from DDR to * accelerator space (NOTE that this space is limited) associated data: * DDR address + accelerator's config set index(acc's address). * * 2. Issue "Process Lines Command" to shd accelerator * associated data: #lines + which config set to use (actually, accelerator * will use x AND (x+1)%num_of_sets - NOTE that this implies the restriction * of not touching config sets x & (x+1)%num_of_sets when process_lines(x) * is active). * * Basically there are 2 types of operations "chunks": * 1. "initial chunk": Initially, we do as much transfers as we can (and need) * [0 - max sets(3) ] followed by 1 or 2 "process lines" operations. * * 2. "regular chunk" - 1 transfer followed by 1 process line operation. * (in some cases we might need additional transfer ate the last chunk). * * for some case: * --> init * tr (0) * tr (1) * tr (2) * pl (0) * pl (1) * --> ack (0) * tr (3) * pl (2) * --> ack (1) * pl (3) * --> ack (2) * do nothing * --> ack (3) * do nothing */ static int ipu3_css_shd_ops_calc(struct imgu_abi_shd_intra_frame_operations_data *ops, const struct ipu3_uapi_shd_grid_config *grid, unsigned int image_height) { unsigned int block_height = 1 << grid->block_height_log2; unsigned int grid_height_per_slice = grid->grid_height_per_slice; unsigned int set_height = grid_height_per_slice * block_height; /* We currently support only abs(y_start) > grid_height_per_slice */ unsigned int positive_y_start = (unsigned int)-grid->y_start; unsigned int first_process_lines = set_height - (positive_y_start % set_height); unsigned int last_set_height; unsigned int num_of_sets; struct imgu_abi_acc_operation *p_op; struct imgu_abi_acc_process_lines_cmd_data *p_pl; struct imgu_abi_shd_transfer_luts_set_data *p_tr; unsigned int op_idx, pl_idx, tr_idx; unsigned char tr_set_num, pl_cfg_set; /* * When the number of lines for the last process lines command * is equal to a set height, we need another line of grid cell - * additional transfer is required. */ unsigned char last_tr = 0; /* Add "process lines" command to the list of operations */ bool add_pl; /* Add DMA xfer (config set) command to the list of ops */ bool add_tr; /* * Available partial grid (the part that fits into #IMGU_SHD_SETS sets) * doesn't cover whole frame - need to process in chunks */ if (image_height > first_process_lines) { last_set_height = (image_height - first_process_lines) % set_height; num_of_sets = last_set_height > 0 ? (image_height - first_process_lines) / set_height + 2 : (image_height - first_process_lines) / set_height + 1; last_tr = (set_height - last_set_height <= block_height || last_set_height == 0) ? 1 : 0; } else { /* partial grid covers whole frame */ last_set_height = 0; num_of_sets = 1; first_process_lines = image_height; last_tr = set_height - image_height <= block_height ? 1 : 0; } /* Init operations lists and counters */ p_op = ops->operation_list; op_idx = 0; p_pl = ops->process_lines_data; pl_idx = 0; p_tr = ops->transfer_data; tr_idx = 0; memset(ops, 0, sizeof(*ops)); /* Cyclic counters that holds config set number [0,IMGU_SHD_SETS) */ tr_set_num = 0; pl_cfg_set = 0; /* * Always start with a transfer - process lines command must be * initiated only after appropriate config sets are in place * (2 configuration sets per process line command, except for last one). */ add_pl = false; add_tr = true; while (add_pl || add_tr) { /* Transfer ops */ if (add_tr) { if (op_idx >= IMGU_ABI_SHD_MAX_OPERATIONS || tr_idx >= IMGU_ABI_SHD_MAX_TRANSFERS) return -EINVAL; p_op[op_idx].op_type = IMGU_ABI_ACC_OPTYPE_TRANSFER_DATA; p_op[op_idx].op_indicator = IMGU_ABI_ACC_OP_IDLE; op_idx++; p_tr[tr_idx].set_number = tr_set_num; tr_idx++; tr_set_num = (tr_set_num + 1) % IMGU_SHD_SETS; } /* Process-lines ops */ if (add_pl) { if (op_idx >= IMGU_ABI_SHD_MAX_OPERATIONS || pl_idx >= IMGU_ABI_SHD_MAX_PROCESS_LINES) return -EINVAL; p_op[op_idx].op_type = IMGU_ABI_ACC_OPTYPE_PROCESS_LINES; /* * In case we have 2 process lines commands - * don't stop after the first one */ if (pl_idx == 0 && num_of_sets != 1) p_op[op_idx].op_indicator = IMGU_ABI_ACC_OP_IDLE; /* * Initiate last process lines command - * end of operation list. */ else if (pl_idx == num_of_sets - 1) p_op[op_idx].op_indicator = IMGU_ABI_ACC_OP_END_OF_OPS; /* * Intermediate process line command - end of operation * "chunk" (meaning few "transfers" followed by few * "process lines" commands). */ else p_op[op_idx].op_indicator = IMGU_ABI_ACC_OP_END_OF_ACK; op_idx++; /* first process line operation */ if (pl_idx == 0) p_pl[pl_idx].lines = first_process_lines; /* Last process line operation */ else if (pl_idx == num_of_sets - 1 && last_set_height > 0) p_pl[pl_idx].lines = last_set_height; else /* "regular" process lines operation */ p_pl[pl_idx].lines = set_height; p_pl[pl_idx].cfg_set = pl_cfg_set; pl_idx++; pl_cfg_set = (pl_cfg_set + 1) % IMGU_SHD_SETS; } /* * Initially, we always transfer * min(IMGU_SHD_SETS, num_of_sets) - after that we fill in the * corresponding process lines commands. */ if (tr_idx == IMGU_SHD_SETS || tr_idx == num_of_sets + last_tr) { add_tr = false; add_pl = true; } /* * We have finished the "initial" operations chunk - * be ready to get more chunks. */ if (pl_idx == 2) { add_tr = true; add_pl = true; } /* Stop conditions for each operation type */ if (tr_idx == num_of_sets + last_tr) add_tr = false; if (pl_idx == num_of_sets) add_pl = false; } return 0; } /* * The follow handshake procotol is the same for AF, AWB and AWB FR. * * for n sets of meta-data, the flow is: * --> init * process-lines (0) * process-lines (1) eoc * --> ack (0) * read-meta-data (0) * process-lines (2) eoc * --> ack (1) * read-meta-data (1) * process-lines (3) eoc * ... * * --> ack (n-3) * read-meta-data (n-3) * process-lines (n-1) eoc * --> ack (n-2) * read-meta-data (n-2) eoc * --> ack (n-1) * read-meta-data (n-1) eof * * for 2 sets we get: * --> init * pl (0) * pl (1) eoc * --> ack (0) * pl (2) - rest of image, if applicable) * rmd (0) eoc * --> ack (1) * rmd (1) eof * --> (ack (2)) * do nothing * * for only one set: * * --> init * pl(0) eoc * --> ack (0) * rmd (0) eof * * grid smaller than image case * for example 128x128 grid (block size 8x8, 16x16 num of blocks) * start at (0,0) * 1st set holds 160 cells - 10 blocks vertical, 16 horizontal * => 1st process lines = 80 * we're left with 128-80=48 lines (6 blocks vertical) * => 2nd process lines = 48 * last process lines to cover the image - image_height - 128 * * --> init * pl (0) first * pl (1) last-in-grid * --> ack (0) * rmd (0) * pl (2) after-grid * --> ack (1) * rmd (1) eof * --> ack (2) * do nothing */ struct process_lines { unsigned int image_height; unsigned short grid_height; unsigned short block_height; unsigned short y_start; unsigned char grid_height_per_slice; unsigned short max_op; /* max operation */ unsigned short max_tr; /* max transaction */ unsigned char acc_enable; }; /* Helper to config intra_frame_operations_data. */ static int ipu3_css_acc_process_lines(const struct process_lines *pl, struct imgu_abi_acc_operation *p_op, struct imgu_abi_acc_process_lines_cmd_data *p_pl, struct imgu_abi_acc_transfer_op_data *p_tr) { unsigned short op_idx = 0, pl_idx = 0, tr_idx = 0; unsigned char tr_set_num = 0, pl_cfg_set = 0; const unsigned short grid_last_line = pl->y_start + pl->grid_height * pl->block_height; const unsigned short process_lines = pl->grid_height_per_slice * pl->block_height; unsigned int process_lines_after_grid; unsigned short first_process_lines; unsigned short last_process_lines_in_grid; unsigned short num_of_process_lines; unsigned short num_of_sets; if (pl->grid_height_per_slice == 0) return -EINVAL; if (pl->acc_enable && grid_last_line > pl->image_height) return -EINVAL; num_of_sets = pl->grid_height / pl->grid_height_per_slice; if (num_of_sets * pl->grid_height_per_slice < pl->grid_height) num_of_sets++; /* Account for two line delay inside the FF */ if (pl->max_op == IMGU_ABI_AF_MAX_OPERATIONS) { first_process_lines = process_lines + pl->y_start + 2; last_process_lines_in_grid = (grid_last_line - first_process_lines) - ((num_of_sets - 2) * process_lines) + 4; process_lines_after_grid = pl->image_height - grid_last_line - 4; } else { first_process_lines = process_lines + pl->y_start; last_process_lines_in_grid = (grid_last_line - first_process_lines) - ((num_of_sets - 2) * process_lines); process_lines_after_grid = pl->image_height - grid_last_line; } num_of_process_lines = num_of_sets; if (process_lines_after_grid > 0) num_of_process_lines++; while (tr_idx < num_of_sets || pl_idx < num_of_process_lines) { /* Read meta-data */ if (pl_idx >= 2 || (pl_idx == 1 && num_of_sets == 1)) { if (op_idx >= pl->max_op || tr_idx >= pl->max_tr) return -EINVAL; p_op[op_idx].op_type = IMGU_ABI_ACC_OPTYPE_TRANSFER_DATA; if (tr_idx == num_of_sets - 1) /* The last operation is always a tr */ p_op[op_idx].op_indicator = IMGU_ABI_ACC_OP_END_OF_OPS; else if (tr_idx == num_of_sets - 2) if (process_lines_after_grid == 0) /* * No additional pl op left - * this op is left as lats of cycle */ p_op[op_idx].op_indicator = IMGU_ABI_ACC_OP_END_OF_ACK; else /* * We still have to process-lines after * the grid so have one more pl op */ p_op[op_idx].op_indicator = IMGU_ABI_ACC_OP_IDLE; else /* Default - usually there's a pl after a tr */ p_op[op_idx].op_indicator = IMGU_ABI_ACC_OP_IDLE; op_idx++; if (p_tr) { p_tr[tr_idx].set_number = tr_set_num; tr_set_num = 1 - tr_set_num; } tr_idx++; } /* process_lines */ if (pl_idx < num_of_process_lines) { if (op_idx >= pl->max_op || pl_idx >= pl->max_tr) return -EINVAL; p_op[op_idx].op_type = IMGU_ABI_ACC_OPTYPE_PROCESS_LINES; if (pl_idx == 0) if (num_of_process_lines == 1) /* Only one pl op */ p_op[op_idx].op_indicator = IMGU_ABI_ACC_OP_END_OF_ACK; else /* On init - do two pl ops */ p_op[op_idx].op_indicator = IMGU_ABI_ACC_OP_IDLE; else /* Usually pl is the end of the ack cycle */ p_op[op_idx].op_indicator = IMGU_ABI_ACC_OP_END_OF_ACK; op_idx++; if (pl_idx == 0) /* First process line */ p_pl[pl_idx].lines = first_process_lines; else if (pl_idx == num_of_sets - 1) /* Last in grid */ p_pl[pl_idx].lines = last_process_lines_in_grid; else if (pl_idx == num_of_process_lines - 1) /* After the grid */ p_pl[pl_idx].lines = process_lines_after_grid; else /* Inside the grid */ p_pl[pl_idx].lines = process_lines; if (p_tr) { p_pl[pl_idx].cfg_set = pl_cfg_set; pl_cfg_set = 1 - pl_cfg_set; } pl_idx++; } } return 0; } static int ipu3_css_af_ops_calc(struct ipu3_css *css, unsigned int pipe, struct imgu_abi_af_config *af_config) { struct imgu_abi_af_intra_frame_operations_data *to = &af_config->operations_data; struct ipu3_css_pipe *css_pipe = &css->pipes[pipe]; struct imgu_fw_info *bi = &css->fwp->binary_header[css_pipe->bindex]; struct process_lines pl = { .image_height = css_pipe->rect[IPU3_CSS_RECT_BDS].height, .grid_height = af_config->config.grid_cfg.height, .block_height = 1 << af_config->config.grid_cfg.block_height_log2, .y_start = af_config->config.grid_cfg.y_start & IPU3_UAPI_GRID_START_MASK, .grid_height_per_slice = af_config->stripes[0].grid_cfg.height_per_slice, .max_op = IMGU_ABI_AF_MAX_OPERATIONS, .max_tr = IMGU_ABI_AF_MAX_TRANSFERS, .acc_enable = bi->info.isp.sp.enable.af, }; return ipu3_css_acc_process_lines(&pl, to->ops, to->process_lines_data, NULL); } static int ipu3_css_awb_fr_ops_calc(struct ipu3_css *css, unsigned int pipe, struct imgu_abi_awb_fr_config *awb_fr_config) { struct imgu_abi_awb_fr_intra_frame_operations_data *to = &awb_fr_config->operations_data; struct ipu3_css_pipe *css_pipe = &css->pipes[pipe]; struct imgu_fw_info *bi = &css->fwp->binary_header[css_pipe->bindex]; struct process_lines pl = { .image_height = css_pipe->rect[IPU3_CSS_RECT_BDS].height, .grid_height = awb_fr_config->config.grid_cfg.height, .block_height = 1 << awb_fr_config->config.grid_cfg.block_height_log2, .y_start = awb_fr_config->config.grid_cfg.y_start & IPU3_UAPI_GRID_START_MASK, .grid_height_per_slice = awb_fr_config->stripes[0].grid_cfg.height_per_slice, .max_op = IMGU_ABI_AWB_FR_MAX_OPERATIONS, .max_tr = IMGU_ABI_AWB_FR_MAX_PROCESS_LINES, .acc_enable = bi->info.isp.sp.enable.awb_fr_acc, }; return ipu3_css_acc_process_lines(&pl, to->ops, to->process_lines_data, NULL); } static int ipu3_css_awb_ops_calc(struct ipu3_css *css, unsigned int pipe, struct imgu_abi_awb_config *awb_config) { struct imgu_abi_awb_intra_frame_operations_data *to = &awb_config->operations_data; struct ipu3_css_pipe *css_pipe = &css->pipes[pipe]; struct imgu_fw_info *bi = &css->fwp->binary_header[css_pipe->bindex]; struct process_lines pl = { .image_height = css_pipe->rect[IPU3_CSS_RECT_BDS].height, .grid_height = awb_config->config.grid.height, .block_height = 1 << awb_config->config.grid.block_height_log2, .y_start = awb_config->config.grid.y_start, .grid_height_per_slice = awb_config->stripes[0].grid.height_per_slice, .max_op = IMGU_ABI_AWB_MAX_OPERATIONS, .max_tr = IMGU_ABI_AWB_MAX_TRANSFERS, .acc_enable = bi->info.isp.sp.enable.awb_acc, }; return ipu3_css_acc_process_lines(&pl, to->ops, to->process_lines_data, to->transfer_data); } static u16 ipu3_css_grid_end(u16 start, u8 width, u8 block_width_log2) { return (start & IPU3_UAPI_GRID_START_MASK) + (width << block_width_log2) - 1; } static void ipu3_css_grid_end_calc(struct ipu3_uapi_grid_config *grid_cfg) { grid_cfg->x_end = ipu3_css_grid_end(grid_cfg->x_start, grid_cfg->width, grid_cfg->block_width_log2); grid_cfg->y_end = ipu3_css_grid_end(grid_cfg->y_start, grid_cfg->height, grid_cfg->block_height_log2); } /****************** config computation *****************************/ static int ipu3_css_cfg_acc_stripe(struct ipu3_css *css, unsigned int pipe, struct imgu_abi_acc_param *acc) { struct ipu3_css_pipe *css_pipe = &css->pipes[pipe]; const struct imgu_fw_info *bi = &css->fwp->binary_header[css_pipe->bindex]; struct ipu3_css_scaler_info scaler_luma, scaler_chroma; const unsigned int stripes = bi->info.isp.sp.iterator.num_stripes; const unsigned int f = IPU3_UAPI_ISP_VEC_ELEMS * 2; unsigned int bds_ds, i; memset(acc, 0, sizeof(*acc)); /* acc_param: osys_config */ if (ipu3_css_osys_calc(css, pipe, stripes, &acc->osys, &scaler_luma, &scaler_chroma, acc->stripe.block_stripes)) return -EINVAL; /* acc_param: stripe data */ /* * For the striped case the approach is as follows: * 1. down-scaled stripes are calculated - with 128 overlap * (this is the main limiter therefore it's first) * 2. input stripes are derived by up-scaling the down-scaled stripes * (there are no alignment requirements on input stripes) * 3. output stripes are derived from down-scaled stripes too */ acc->stripe.num_of_stripes = stripes; acc->stripe.input_frame.width = css_pipe->queue[IPU3_CSS_QUEUE_IN].fmt.mpix.width; acc->stripe.input_frame.height = css_pipe->queue[IPU3_CSS_QUEUE_IN].fmt.mpix.height; acc->stripe.input_frame.bayer_order = css_pipe->queue[IPU3_CSS_QUEUE_IN].css_fmt->bayer_order; for (i = 0; i < stripes; i++) acc->stripe.bds_out_stripes[i].height = css_pipe->rect[IPU3_CSS_RECT_BDS].height; acc->stripe.bds_out_stripes[0].offset = 0; if (stripes <= 1) { acc->stripe.bds_out_stripes[0].width = ALIGN(css_pipe->rect[IPU3_CSS_RECT_BDS].width, f); } else { /* Image processing is divided into two stripes */ acc->stripe.bds_out_stripes[0].width = acc->stripe.bds_out_stripes[1].width = (css_pipe->rect[IPU3_CSS_RECT_BDS].width / 2 & ~(f - 1)) + f; /* * Sum of width of the two stripes should not be smaller * than output width and must be even times of overlapping * unit f. */ if ((css_pipe->rect[IPU3_CSS_RECT_BDS].width / f & 1) != !!(css_pipe->rect[IPU3_CSS_RECT_BDS].width & (f - 1))) acc->stripe.bds_out_stripes[0].width += f; if ((css_pipe->rect[IPU3_CSS_RECT_BDS].width / f & 1) && (css_pipe->rect[IPU3_CSS_RECT_BDS].width & (f - 1))) { acc->stripe.bds_out_stripes[0].width += f; acc->stripe.bds_out_stripes[1].width += f; } /* Overlap between stripes is IPU3_UAPI_ISP_VEC_ELEMS * 4 */ acc->stripe.bds_out_stripes[1].offset = acc->stripe.bds_out_stripes[0].width - 2 * f; } acc->stripe.effective_stripes[0].height = css_pipe->rect[IPU3_CSS_RECT_EFFECTIVE].height; acc->stripe.effective_stripes[0].offset = 0; acc->stripe.bds_out_stripes_no_overlap[0].height = css_pipe->rect[IPU3_CSS_RECT_BDS].height; acc->stripe.bds_out_stripes_no_overlap[0].offset = 0; acc->stripe.output_stripes[0].height = css_pipe->queue[IPU3_CSS_QUEUE_OUT].fmt.mpix.height; acc->stripe.output_stripes[0].offset = 0; if (stripes <= 1) { acc->stripe.down_scaled_stripes[0].width = css_pipe->rect[IPU3_CSS_RECT_BDS].width; acc->stripe.down_scaled_stripes[0].height = css_pipe->rect[IPU3_CSS_RECT_BDS].height; acc->stripe.down_scaled_stripes[0].offset = 0; acc->stripe.effective_stripes[0].width = css_pipe->rect[IPU3_CSS_RECT_EFFECTIVE].width; acc->stripe.bds_out_stripes_no_overlap[0].width = ALIGN(css_pipe->rect[IPU3_CSS_RECT_BDS].width, f); acc->stripe.output_stripes[0].width = css_pipe->queue[IPU3_CSS_QUEUE_OUT].fmt.mpix.width; } else { /* Two stripes */ bds_ds = css_pipe->rect[IPU3_CSS_RECT_EFFECTIVE].width * IMGU_BDS_GRANULARITY / css_pipe->rect[IPU3_CSS_RECT_BDS].width; acc->stripe.down_scaled_stripes[0] = acc->stripe.bds_out_stripes[0]; acc->stripe.down_scaled_stripes[1] = acc->stripe.bds_out_stripes[1]; if (!IS_ALIGNED(css_pipe->rect[IPU3_CSS_RECT_BDS].width, f)) acc->stripe.down_scaled_stripes[1].width += (css_pipe->rect[IPU3_CSS_RECT_BDS].width & (f - 1)) - f; acc->stripe.effective_stripes[0].width = bds_ds * acc->stripe.down_scaled_stripes[0].width / IMGU_BDS_GRANULARITY; acc->stripe.effective_stripes[1].width = bds_ds * acc->stripe.down_scaled_stripes[1].width / IMGU_BDS_GRANULARITY; acc->stripe.effective_stripes[1].height = css_pipe->rect[IPU3_CSS_RECT_EFFECTIVE].height; acc->stripe.effective_stripes[1].offset = bds_ds * acc->stripe.down_scaled_stripes[1].offset / IMGU_BDS_GRANULARITY; acc->stripe.bds_out_stripes_no_overlap[0].width = acc->stripe.bds_out_stripes_no_overlap[1].offset = ALIGN(css_pipe->rect[IPU3_CSS_RECT_BDS].width, 2 * f) / 2; acc->stripe.bds_out_stripes_no_overlap[1].width = DIV_ROUND_UP(css_pipe->rect[IPU3_CSS_RECT_BDS].width, f) / 2 * f; acc->stripe.bds_out_stripes_no_overlap[1].height = css_pipe->rect[IPU3_CSS_RECT_BDS].height; acc->stripe.output_stripes[0].width = acc->stripe.down_scaled_stripes[0].width - f; acc->stripe.output_stripes[1].width = acc->stripe.down_scaled_stripes[1].width - f; acc->stripe.output_stripes[1].height = css_pipe->queue[IPU3_CSS_QUEUE_OUT].fmt.mpix.height; acc->stripe.output_stripes[1].offset = acc->stripe.output_stripes[0].width; } acc->stripe.output_system_in_frame_width = css_pipe->rect[IPU3_CSS_RECT_GDC].width; acc->stripe.output_system_in_frame_height = css_pipe->rect[IPU3_CSS_RECT_GDC].height; acc->stripe.effective_frame_width = css_pipe->rect[IPU3_CSS_RECT_EFFECTIVE].width; acc->stripe.bds_frame_width = css_pipe->rect[IPU3_CSS_RECT_BDS].width; acc->stripe.out_frame_width = css_pipe->queue[IPU3_CSS_QUEUE_OUT].fmt.mpix.width; acc->stripe.out_frame_height = css_pipe->queue[IPU3_CSS_QUEUE_OUT].fmt.mpix.height; acc->stripe.gdc_in_buffer_width = css_pipe->aux_frames[IPU3_CSS_AUX_FRAME_REF].bytesperline / css_pipe->aux_frames[IPU3_CSS_AUX_FRAME_REF].bytesperpixel; acc->stripe.gdc_in_buffer_height = css_pipe->aux_frames[IPU3_CSS_AUX_FRAME_REF].height; acc->stripe.gdc_in_buffer_offset_x = IMGU_GDC_BUF_X; acc->stripe.gdc_in_buffer_offset_y = IMGU_GDC_BUF_Y; acc->stripe.display_frame_width = css_pipe->queue[IPU3_CSS_QUEUE_VF].fmt.mpix.width; acc->stripe.display_frame_height = css_pipe->queue[IPU3_CSS_QUEUE_VF].fmt.mpix.height; acc->stripe.bds_aligned_frame_width = roundup(css_pipe->rect[IPU3_CSS_RECT_BDS].width, 2 * IPU3_UAPI_ISP_VEC_ELEMS); if (stripes > 1) acc->stripe.half_overlap_vectors = IMGU_STRIPE_FIXED_HALF_OVERLAP; else acc->stripe.half_overlap_vectors = 0; return 0; } static void ipu3_css_cfg_acc_dvs(struct ipu3_css *css, struct imgu_abi_acc_param *acc, unsigned int pipe) { unsigned int i; struct ipu3_css_pipe *css_pipe = &css->pipes[pipe]; /* Disable DVS statistics */ acc->dvs_stat.operations_data.process_lines_data[0].lines = css_pipe->rect[IPU3_CSS_RECT_BDS].height; acc->dvs_stat.operations_data.process_lines_data[0].cfg_set = 0; acc->dvs_stat.operations_data.ops[0].op_type = IMGU_ABI_ACC_OPTYPE_PROCESS_LINES; acc->dvs_stat.operations_data.ops[0].op_indicator = IMGU_ABI_ACC_OP_NO_OPS; for (i = 0; i < IMGU_ABI_DVS_STAT_LEVELS; i++) acc->dvs_stat.cfg.grd_config[i].enable = 0; } static void acc_bds_per_stripe_data(struct ipu3_css *css, struct imgu_abi_acc_param *acc, const int i, unsigned int pipe) { struct ipu3_css_pipe *css_pipe = &css->pipes[pipe]; acc->bds.per_stripe.aligned_data[i].data.crop.hor_crop_en = 0; acc->bds.per_stripe.aligned_data[i].data.crop.hor_crop_start = 0; acc->bds.per_stripe.aligned_data[i].data.crop.hor_crop_end = 0; acc->bds.per_stripe.aligned_data[i].data.hor_ctrl0 = acc->bds.hor.hor_ctrl0; acc->bds.per_stripe.aligned_data[i].data.hor_ctrl0.out_frame_width = acc->stripe.down_scaled_stripes[i].width; acc->bds.per_stripe.aligned_data[i].data.ver_ctrl1.out_frame_width = acc->stripe.down_scaled_stripes[i].width; acc->bds.per_stripe.aligned_data[i].data.ver_ctrl1.out_frame_height = css_pipe->rect[IPU3_CSS_RECT_BDS].height; } /* * Configure `acc' parameters. `acc_old' contains the old values (or is NULL) * and `acc_user' contains new prospective values. `use' contains flags * telling which fields to take from the old values (or generate if it is NULL) * and which to take from the new user values. */ int ipu3_css_cfg_acc(struct ipu3_css *css, unsigned int pipe, struct ipu3_uapi_flags *use, struct imgu_abi_acc_param *acc, struct imgu_abi_acc_param *acc_old, struct ipu3_uapi_acc_param *acc_user) { struct ipu3_css_pipe *css_pipe = &css->pipes[pipe]; const struct imgu_fw_info *bi = &css->fwp->binary_header[css_pipe->bindex]; const unsigned int stripes = bi->info.isp.sp.iterator.num_stripes; const unsigned int tnr_frame_width = acc->stripe.bds_aligned_frame_width; const unsigned int min_overlap = 10; const struct v4l2_pix_format_mplane *pixm = &css_pipe->queue[IPU3_CSS_QUEUE_IN].fmt.mpix; const struct ipu3_css_bds_config *cfg_bds; struct imgu_abi_input_feeder_data *feeder_data; unsigned int bds_ds, ofs_x, ofs_y, i, width, height; u8 b_w_log2; /* Block width log2 */ /* Update stripe using chroma and luma */ if (ipu3_css_cfg_acc_stripe(css, pipe, acc)) return -EINVAL; /* acc_param: input_feeder_config */ ofs_x = ((pixm->width - css_pipe->rect[IPU3_CSS_RECT_EFFECTIVE].width) >> 1) & ~1; ofs_x += css_pipe->queue[IPU3_CSS_QUEUE_IN].css_fmt->bayer_order == IMGU_ABI_BAYER_ORDER_RGGB || css_pipe->queue[IPU3_CSS_QUEUE_IN].css_fmt->bayer_order == IMGU_ABI_BAYER_ORDER_GBRG ? 1 : 0; ofs_y = ((pixm->height - css_pipe->rect[IPU3_CSS_RECT_EFFECTIVE].height) >> 1) & ~1; ofs_y += css_pipe->queue[IPU3_CSS_QUEUE_IN].css_fmt->bayer_order == IMGU_ABI_BAYER_ORDER_BGGR || css_pipe->queue[IPU3_CSS_QUEUE_IN].css_fmt->bayer_order == IMGU_ABI_BAYER_ORDER_GBRG ? 1 : 0; acc->input_feeder.data.row_stride = pixm->plane_fmt[0].bytesperline; acc->input_feeder.data.start_row_address = ofs_x / IMGU_PIXELS_PER_WORD * IMGU_BYTES_PER_WORD + ofs_y * acc->input_feeder.data.row_stride; acc->input_feeder.data.start_pixel = ofs_x % IMGU_PIXELS_PER_WORD; acc->input_feeder.data_per_stripe.input_feeder_data[0].data = acc->input_feeder.data; ofs_x += acc->stripe.effective_stripes[1].offset; feeder_data = &acc->input_feeder.data_per_stripe.input_feeder_data[1].data; feeder_data->row_stride = acc->input_feeder.data.row_stride; feeder_data->start_row_address = ofs_x / IMGU_PIXELS_PER_WORD * IMGU_BYTES_PER_WORD + ofs_y * acc->input_feeder.data.row_stride; feeder_data->start_pixel = ofs_x % IMGU_PIXELS_PER_WORD; /* acc_param: bnr_static_config */ /* * Originate from user or be the original default values if user has * never set them before, when user gives a new set of parameters, * for each chunk in the parameter structure there is a flag use->xxx * whether to use the user-provided parameter or not. If not, the * parameter remains unchanged in the driver: * it's value is taken from acc_old. */ if (use && use->acc_bnr) { /* Take values from user */ acc->bnr = acc_user->bnr; } else if (acc_old) { /* Use old value */ acc->bnr = acc_old->bnr; } else { /* Calculate from scratch */ acc->bnr = ipu3_css_bnr_defaults; } acc->bnr.column_size = tnr_frame_width; /* acc_param: bnr_static_config_green_disparity */ if (use && use->acc_green_disparity) { /* Take values from user */ acc->green_disparity = acc_user->green_disparity; } else if (acc_old) { /* Use old value */ acc->green_disparity = acc_old->green_disparity; } else { /* Calculate from scratch */ memset(&acc->green_disparity, 0, sizeof(acc->green_disparity)); } /* acc_param: dm_config */ if (use && use->acc_dm) { /* Take values from user */ acc->dm = acc_user->dm; } else if (acc_old) { /* Use old value */ acc->dm = acc_old->dm; } else { /* Calculate from scratch */ acc->dm = ipu3_css_dm_defaults; } acc->dm.frame_width = tnr_frame_width; /* acc_param: ccm_mat_config */ if (use && use->acc_ccm) { /* Take values from user */ acc->ccm = acc_user->ccm; } else if (acc_old) { /* Use old value */ acc->ccm = acc_old->ccm; } else { /* Calculate from scratch */ acc->ccm = ipu3_css_ccm_defaults; } /* acc_param: gamma_config */ if (use && use->acc_gamma) { /* Take values from user */ acc->gamma = acc_user->gamma; } else if (acc_old) { /* Use old value */ acc->gamma = acc_old->gamma; } else { /* Calculate from scratch */ acc->gamma.gc_ctrl.enable = 1; acc->gamma.gc_lut = ipu3_css_gamma_lut; } /* acc_param: csc_mat_config */ if (use && use->acc_csc) { /* Take values from user */ acc->csc = acc_user->csc; } else if (acc_old) { /* Use old value */ acc->csc = acc_old->csc; } else { /* Calculate from scratch */ acc->csc = ipu3_css_csc_defaults; } /* acc_param: cds_params */ if (use && use->acc_cds) { /* Take values from user */ acc->cds = acc_user->cds; } else if (acc_old) { /* Use old value */ acc->cds = acc_old->cds; } else { /* Calculate from scratch */ acc->cds = ipu3_css_cds_defaults; } /* acc_param: shd_config */ if (use && use->acc_shd) { /* Take values from user */ acc->shd.shd = acc_user->shd.shd; acc->shd.shd_lut = acc_user->shd.shd_lut; } else if (acc_old) { /* Use old value */ acc->shd.shd = acc_old->shd.shd; acc->shd.shd_lut = acc_old->shd.shd_lut; } else { /* Calculate from scratch */ acc->shd.shd = ipu3_css_shd_defaults; memset(&acc->shd.shd_lut, 0, sizeof(acc->shd.shd_lut)); } if (acc->shd.shd.grid.width <= 0) return -EINVAL; acc->shd.shd.grid.grid_height_per_slice = IMGU_ABI_SHD_MAX_CELLS_PER_SET / acc->shd.shd.grid.width; if (acc->shd.shd.grid.grid_height_per_slice <= 0) return -EINVAL; acc->shd.shd.general.init_set_vrt_offst_ul = (-acc->shd.shd.grid.y_start >> acc->shd.shd.grid.block_height_log2) % acc->shd.shd.grid.grid_height_per_slice; if (ipu3_css_shd_ops_calc(&acc->shd.shd_ops, &acc->shd.shd.grid, css_pipe->rect[IPU3_CSS_RECT_BDS].height)) return -EINVAL; /* acc_param: dvs_stat_config */ ipu3_css_cfg_acc_dvs(css, acc, pipe); /* acc_param: yuvp1_iefd_config */ if (use && use->acc_iefd) { /* Take values from user */ acc->iefd = acc_user->iefd; } else if (acc_old) { /* Use old value */ acc->iefd = acc_old->iefd; } else { /* Calculate from scratch */ acc->iefd = ipu3_css_iefd_defaults; } /* acc_param: yuvp1_yds_config yds_c0 */ if (use && use->acc_yds_c0) { /* Take values from user */ acc->yds_c0 = acc_user->yds_c0; } else if (acc_old) { /* Use old value */ acc->yds_c0 = acc_old->yds_c0; } else { /* Calculate from scratch */ acc->yds_c0 = ipu3_css_yds_defaults; } /* acc_param: yuvp1_chnr_config chnr_c0 */ if (use && use->acc_chnr_c0) { /* Take values from user */ acc->chnr_c0 = acc_user->chnr_c0; } else if (acc_old) { /* Use old value */ acc->chnr_c0 = acc_old->chnr_c0; } else { /* Calculate from scratch */ acc->chnr_c0 = ipu3_css_chnr_defaults; } /* acc_param: yuvp1_y_ee_nr_config */ if (use && use->acc_y_ee_nr) { /* Take values from user */ acc->y_ee_nr = acc_user->y_ee_nr; } else if (acc_old) { /* Use old value */ acc->y_ee_nr = acc_old->y_ee_nr; } else { /* Calculate from scratch */ acc->y_ee_nr = ipu3_css_y_ee_nr_defaults; } /* acc_param: yuvp1_yds_config yds */ if (use && use->acc_yds) { /* Take values from user */ acc->yds = acc_user->yds; } else if (acc_old) { /* Use old value */ acc->yds = acc_old->yds; } else { /* Calculate from scratch */ acc->yds = ipu3_css_yds_defaults; } /* acc_param: yuvp1_chnr_config chnr */ if (use && use->acc_chnr) { /* Take values from user */ acc->chnr = acc_user->chnr; } else if (acc_old) { /* Use old value */ acc->chnr = acc_old->chnr; } else { /* Calculate from scratch */ acc->chnr = ipu3_css_chnr_defaults; } /* acc_param: yuvp2_y_tm_lut_static_config */ for (i = 0; i < IMGU_ABI_YUVP2_YTM_LUT_ENTRIES; i++) acc->ytm.entries[i] = i * 32; acc->ytm.enable = 0; /* Always disabled on IPU3 */ /* acc_param: yuvp1_yds_config yds2 */ if (use && use->acc_yds2) { /* Take values from user */ acc->yds2 = acc_user->yds2; } else if (acc_old) { /* Use old value */ acc->yds2 = acc_old->yds2; } else { /* Calculate from scratch */ acc->yds2 = ipu3_css_yds_defaults; } /* acc_param: yuvp2_tcc_static_config */ if (use && use->acc_tcc) { /* Take values from user */ acc->tcc = acc_user->tcc; } else if (acc_old) { /* Use old value */ acc->tcc = acc_old->tcc; } else { /* Calculate from scratch */ memset(&acc->tcc, 0, sizeof(acc->tcc)); acc->tcc.gen_control.en = 1; acc->tcc.gen_control.blend_shift = 3; acc->tcc.gen_control.gain_according_to_y_only = 1; acc->tcc.gen_control.gamma = 8; acc->tcc.gen_control.delta = 0; for (i = 0; i < IPU3_UAPI_YUVP2_TCC_MACC_TABLE_ELEMENTS; i++) { acc->tcc.macc_table.entries[i].a = 1024; acc->tcc.macc_table.entries[i].b = 0; acc->tcc.macc_table.entries[i].c = 0; acc->tcc.macc_table.entries[i].d = 1024; } acc->tcc.inv_y_lut.entries[6] = 1023; for (i = 7; i < IPU3_UAPI_YUVP2_TCC_INV_Y_LUT_ELEMENTS; i++) acc->tcc.inv_y_lut.entries[i] = 1024 >> (i - 6); acc->tcc.gain_pcwl = ipu3_css_tcc_gain_pcwl_lut; acc->tcc.r_sqr_lut = ipu3_css_tcc_r_sqr_lut; } /* acc_param: dpc_config */ if (use && use->acc_dpc) return -EINVAL; /* Not supported yet */ /* Just disable by default */ memset(&acc->dpc, 0, sizeof(acc->dpc)); /* acc_param: bds_config */ bds_ds = (css_pipe->rect[IPU3_CSS_RECT_EFFECTIVE].height * IMGU_BDS_GRANULARITY) / css_pipe->rect[IPU3_CSS_RECT_BDS].height; if (bds_ds < IMGU_BDS_MIN_SF_INV || bds_ds - IMGU_BDS_MIN_SF_INV >= ARRAY_SIZE(ipu3_css_bds_configs)) return -EINVAL; cfg_bds = &ipu3_css_bds_configs[bds_ds - IMGU_BDS_MIN_SF_INV]; acc->bds.hor.hor_ctrl1.hor_crop_en = 0; acc->bds.hor.hor_ctrl1.hor_crop_start = 0; acc->bds.hor.hor_ctrl1.hor_crop_end = 0; acc->bds.hor.hor_ctrl0.sample_patrn_length = cfg_bds->sample_patrn_length; acc->bds.hor.hor_ctrl0.hor_ds_en = cfg_bds->hor_ds_en; acc->bds.hor.hor_ctrl0.min_clip_val = IMGU_BDS_MIN_CLIP_VAL; acc->bds.hor.hor_ctrl0.max_clip_val = IMGU_BDS_MAX_CLIP_VAL; acc->bds.hor.hor_ctrl0.out_frame_width = css_pipe->rect[IPU3_CSS_RECT_BDS].width; acc->bds.hor.hor_ptrn_arr = cfg_bds->ptrn_arr; acc->bds.hor.hor_phase_arr = cfg_bds->hor_phase_arr; acc->bds.hor.hor_ctrl2.input_frame_height = css_pipe->rect[IPU3_CSS_RECT_EFFECTIVE].height; acc->bds.ver.ver_ctrl0.min_clip_val = IMGU_BDS_MIN_CLIP_VAL; acc->bds.ver.ver_ctrl0.max_clip_val = IMGU_BDS_MAX_CLIP_VAL; acc->bds.ver.ver_ctrl0.sample_patrn_length = cfg_bds->sample_patrn_length; acc->bds.ver.ver_ctrl0.ver_ds_en = cfg_bds->ver_ds_en; acc->bds.ver.ver_ptrn_arr = cfg_bds->ptrn_arr; acc->bds.ver.ver_phase_arr = cfg_bds->ver_phase_arr; acc->bds.ver.ver_ctrl1.out_frame_width = css_pipe->rect[IPU3_CSS_RECT_BDS].width; acc->bds.ver.ver_ctrl1.out_frame_height = css_pipe->rect[IPU3_CSS_RECT_BDS].height; for (i = 0; i < stripes; i++) acc_bds_per_stripe_data(css, acc, i, pipe); acc->bds.enabled = cfg_bds->hor_ds_en || cfg_bds->ver_ds_en; /* acc_param: anr_config */ if (use && use->acc_anr) { /* Take values from user */ acc->anr.transform = acc_user->anr.transform; acc->anr.stitch.anr_stitch_en = acc_user->anr.stitch.anr_stitch_en; memcpy(acc->anr.stitch.pyramid, acc_user->anr.stitch.pyramid, sizeof(acc->anr.stitch.pyramid)); } else if (acc_old) { /* Use old value */ acc->anr.transform = acc_old->anr.transform; acc->anr.stitch.anr_stitch_en = acc_old->anr.stitch.anr_stitch_en; memcpy(acc->anr.stitch.pyramid, acc_old->anr.stitch.pyramid, sizeof(acc->anr.stitch.pyramid)); } else { /* Calculate from scratch */ acc->anr = ipu3_css_anr_defaults; } /* Always enabled */ acc->anr.search.enable = 1; acc->anr.transform.enable = 1; acc->anr.tile2strm.enable = 1; acc->anr.tile2strm.frame_width = ALIGN(css_pipe->rect[IPU3_CSS_RECT_BDS].width, IMGU_ISP_VMEM_ALIGN); acc->anr.search.frame_width = acc->anr.tile2strm.frame_width; acc->anr.stitch.frame_width = acc->anr.tile2strm.frame_width; acc->anr.tile2strm.frame_height = css_pipe->rect[IPU3_CSS_RECT_BDS].height; acc->anr.search.frame_height = acc->anr.tile2strm.frame_height; acc->anr.stitch.frame_height = acc->anr.tile2strm.frame_height; width = ALIGN(css_pipe->rect[IPU3_CSS_RECT_BDS].width, IMGU_ISP_VMEM_ALIGN); height = css_pipe->rect[IPU3_CSS_RECT_BDS].height; if (acc->anr.transform.xreset + width > IPU3_UAPI_ANR_MAX_RESET) acc->anr.transform.xreset = IPU3_UAPI_ANR_MAX_RESET - width; if (acc->anr.transform.xreset < IPU3_UAPI_ANR_MIN_RESET) acc->anr.transform.xreset = IPU3_UAPI_ANR_MIN_RESET; if (acc->anr.transform.yreset + height > IPU3_UAPI_ANR_MAX_RESET) acc->anr.transform.yreset = IPU3_UAPI_ANR_MAX_RESET - height; if (acc->anr.transform.yreset < IPU3_UAPI_ANR_MIN_RESET) acc->anr.transform.yreset = IPU3_UAPI_ANR_MIN_RESET; /* acc_param: awb_fr_config */ if (use && use->acc_awb_fr) { /* Take values from user */ acc->awb_fr.config = acc_user->awb_fr; } else if (acc_old) { /* Use old value */ acc->awb_fr.config = acc_old->awb_fr.config; } else { /* Set from scratch */ acc->awb_fr.config = ipu3_css_awb_fr_defaults; } ipu3_css_grid_end_calc(&acc->awb_fr.config.grid_cfg); if (acc->awb_fr.config.grid_cfg.width <= 0) return -EINVAL; acc->awb_fr.config.grid_cfg.height_per_slice = IMGU_ABI_AWB_FR_MAX_CELLS_PER_SET / acc->awb_fr.config.grid_cfg.width; for (i = 0; i < stripes; i++) acc->awb_fr.stripes[i] = acc->awb_fr.config; if (acc->awb_fr.config.grid_cfg.x_start >= acc->stripe.down_scaled_stripes[1].offset + min_overlap) { /* Enable only for rightmost stripe, disable left */ acc->awb_fr.stripes[0].grid_cfg.y_start &= ~IPU3_UAPI_GRID_Y_START_EN; } else if (acc->awb_fr.config.grid_cfg.x_end <= acc->stripe.bds_out_stripes[0].width - min_overlap) { /* Enable only for leftmost stripe, disable right */ acc->awb_fr.stripes[1].grid_cfg.y_start &= ~IPU3_UAPI_GRID_Y_START_EN; } else { /* Enable for both stripes */ u16 end; /* width for grid end */ acc->awb_fr.stripes[0].grid_cfg.width = (acc->stripe.bds_out_stripes[0].width - min_overlap - acc->awb_fr.config.grid_cfg.x_start + 1) >> acc->awb_fr.config.grid_cfg.block_width_log2; acc->awb_fr.stripes[1].grid_cfg.width = acc->awb_fr.config.grid_cfg.width - acc->awb_fr.stripes[0].grid_cfg.width; b_w_log2 = acc->awb_fr.stripes[0].grid_cfg.block_width_log2; end = ipu3_css_grid_end(acc->awb_fr.stripes[0].grid_cfg.x_start, acc->awb_fr.stripes[0].grid_cfg.width, b_w_log2); acc->awb_fr.stripes[0].grid_cfg.x_end = end; acc->awb_fr.stripes[1].grid_cfg.x_start = (acc->awb_fr.stripes[0].grid_cfg.x_end + 1 - acc->stripe.down_scaled_stripes[1].offset) & IPU3_UAPI_GRID_START_MASK; b_w_log2 = acc->awb_fr.stripes[1].grid_cfg.block_width_log2; end = ipu3_css_grid_end(acc->awb_fr.stripes[1].grid_cfg.x_start, acc->awb_fr.stripes[1].grid_cfg.width, b_w_log2); acc->awb_fr.stripes[1].grid_cfg.x_end = end; /* * To reduce complexity of debubbling and loading * statistics fix grid_height_per_slice to 1 for both * stripes. */ for (i = 0; i < stripes; i++) acc->awb_fr.stripes[i].grid_cfg.height_per_slice = 1; } if (ipu3_css_awb_fr_ops_calc(css, pipe, &acc->awb_fr)) return -EINVAL; /* acc_param: ae_config */ if (use && use->acc_ae) { /* Take values from user */ acc->ae.grid_cfg = acc_user->ae.grid_cfg; acc->ae.ae_ccm = acc_user->ae.ae_ccm; for (i = 0; i < IPU3_UAPI_AE_WEIGHTS; i++) acc->ae.weights[i] = acc_user->ae.weights[i]; } else if (acc_old) { /* Use old value */ acc->ae.grid_cfg = acc_old->ae.grid_cfg; acc->ae.ae_ccm = acc_old->ae.ae_ccm; for (i = 0; i < IPU3_UAPI_AE_WEIGHTS; i++) acc->ae.weights[i] = acc_old->ae.weights[i]; } else { /* Set from scratch */ static const struct ipu3_uapi_ae_weight_elem weight_def = { 1, 1, 1, 1, 1, 1, 1, 1 }; acc->ae.grid_cfg = ipu3_css_ae_grid_defaults; acc->ae.ae_ccm = ipu3_css_ae_ccm_defaults; for (i = 0; i < IPU3_UAPI_AE_WEIGHTS; i++) acc->ae.weights[i] = weight_def; } b_w_log2 = acc->ae.grid_cfg.block_width_log2; acc->ae.grid_cfg.x_end = ipu3_css_grid_end(acc->ae.grid_cfg.x_start, acc->ae.grid_cfg.width, b_w_log2); b_w_log2 = acc->ae.grid_cfg.block_height_log2; acc->ae.grid_cfg.y_end = ipu3_css_grid_end(acc->ae.grid_cfg.y_start, acc->ae.grid_cfg.height, b_w_log2); for (i = 0; i < stripes; i++) acc->ae.stripes[i].grid = acc->ae.grid_cfg; if (acc->ae.grid_cfg.x_start >= acc->stripe.down_scaled_stripes[1].offset) { /* Enable only for rightmost stripe, disable left */ acc->ae.stripes[0].grid.ae_en = 0; } else if (acc->ae.grid_cfg.x_end <= acc->stripe.bds_out_stripes[0].width) { /* Enable only for leftmost stripe, disable right */ acc->ae.stripes[1].grid.ae_en = 0; } else { /* Enable for both stripes */ u8 b_w_log2; acc->ae.stripes[0].grid.width = (acc->stripe.bds_out_stripes[0].width - acc->ae.grid_cfg.x_start + 1) >> acc->ae.grid_cfg.block_width_log2; acc->ae.stripes[1].grid.width = acc->ae.grid_cfg.width - acc->ae.stripes[0].grid.width; b_w_log2 = acc->ae.stripes[0].grid.block_width_log2; acc->ae.stripes[0].grid.x_end = ipu3_css_grid_end(acc->ae.stripes[0].grid.x_start, acc->ae.stripes[0].grid.width, b_w_log2); acc->ae.stripes[1].grid.x_start = (acc->ae.stripes[0].grid.x_end + 1 - acc->stripe.down_scaled_stripes[1].offset) & IPU3_UAPI_GRID_START_MASK; b_w_log2 = acc->ae.stripes[1].grid.block_width_log2; acc->ae.stripes[1].grid.x_end = ipu3_css_grid_end(acc->ae.stripes[1].grid.x_start, acc->ae.stripes[1].grid.width, b_w_log2); } /* acc_param: af_config */ if (use && use->acc_af) { /* Take values from user */ acc->af.config.filter_config = acc_user->af.filter_config; acc->af.config.grid_cfg = acc_user->af.grid_cfg; } else if (acc_old) { /* Use old value */ acc->af.config = acc_old->af.config; } else { /* Set from scratch */ acc->af.config.filter_config = ipu3_css_af_defaults.filter_config; acc->af.config.grid_cfg = ipu3_css_af_defaults.grid_cfg; } ipu3_css_grid_end_calc(&acc->af.config.grid_cfg); if (acc->af.config.grid_cfg.width <= 0) return -EINVAL; acc->af.config.grid_cfg.height_per_slice = IMGU_ABI_AF_MAX_CELLS_PER_SET / acc->af.config.grid_cfg.width; acc->af.config.frame_size.width = ALIGN(css_pipe->rect[IPU3_CSS_RECT_BDS].width, IMGU_ISP_VMEM_ALIGN); acc->af.config.frame_size.height = css_pipe->rect[IPU3_CSS_RECT_BDS].height; if (acc->stripe.bds_out_stripes[0].width <= min_overlap) return -EINVAL; for (i = 0; i < stripes; i++) { acc->af.stripes[i].grid_cfg = acc->af.config.grid_cfg; acc->af.stripes[i].frame_size.height = css_pipe->rect[IPU3_CSS_RECT_BDS].height; acc->af.stripes[i].frame_size.width = acc->stripe.bds_out_stripes[i].width; } if (acc->af.config.grid_cfg.x_start >= acc->stripe.down_scaled_stripes[1].offset + min_overlap) { /* Enable only for rightmost stripe, disable left */ acc->af.stripes[0].grid_cfg.y_start &= ~IPU3_UAPI_GRID_Y_START_EN; } else if (acc->af.config.grid_cfg.x_end <= acc->stripe.bds_out_stripes[0].width - min_overlap) { /* Enable only for leftmost stripe, disable right */ acc->af.stripes[1].grid_cfg.y_start &= ~IPU3_UAPI_GRID_Y_START_EN; } else { /* Enable for both stripes */ acc->af.stripes[0].grid_cfg.width = (acc->stripe.bds_out_stripes[0].width - min_overlap - acc->af.config.grid_cfg.x_start + 1) >> acc->af.config.grid_cfg.block_width_log2; acc->af.stripes[1].grid_cfg.width = acc->af.config.grid_cfg.width - acc->af.stripes[0].grid_cfg.width; b_w_log2 = acc->af.stripes[0].grid_cfg.block_width_log2; acc->af.stripes[0].grid_cfg.x_end = ipu3_css_grid_end(acc->af.stripes[0].grid_cfg.x_start, acc->af.stripes[0].grid_cfg.width, b_w_log2); acc->af.stripes[1].grid_cfg.x_start = (acc->af.stripes[0].grid_cfg.x_end + 1 - acc->stripe.down_scaled_stripes[1].offset) & IPU3_UAPI_GRID_START_MASK; b_w_log2 = acc->af.stripes[1].grid_cfg.block_width_log2; acc->af.stripes[1].grid_cfg.x_end = ipu3_css_grid_end(acc->af.stripes[1].grid_cfg.x_start, acc->af.stripes[1].grid_cfg.width, b_w_log2); /* * To reduce complexity of debubbling and loading statistics * fix grid_height_per_slice to 1 for both stripes */ for (i = 0; i < stripes; i++) acc->af.stripes[i].grid_cfg.height_per_slice = 1; } if (ipu3_css_af_ops_calc(css, pipe, &acc->af)) return -EINVAL; /* acc_param: awb_config */ if (use && use->acc_awb) { /* Take values from user */ acc->awb.config = acc_user->awb.config; } else if (acc_old) { /* Use old value */ acc->awb.config = acc_old->awb.config; } else { /* Set from scratch */ acc->awb.config = ipu3_css_awb_defaults; } if (acc->awb.config.grid.width <= 0) return -EINVAL; acc->awb.config.grid.height_per_slice = IMGU_ABI_AWB_MAX_CELLS_PER_SET / acc->awb.config.grid.width, ipu3_css_grid_end_calc(&acc->awb.config.grid); for (i = 0; i < stripes; i++) acc->awb.stripes[i] = acc->awb.config; if (acc->awb.config.grid.x_start >= acc->stripe.down_scaled_stripes[1].offset + min_overlap) { /* Enable only for rightmost stripe, disable left */ acc->awb.stripes[0].rgbs_thr_b &= ~IPU3_UAPI_AWB_RGBS_THR_B_EN; } else if (acc->awb.config.grid.x_end <= acc->stripe.bds_out_stripes[0].width - min_overlap) { /* Enable only for leftmost stripe, disable right */ acc->awb.stripes[1].rgbs_thr_b &= ~IPU3_UAPI_AWB_RGBS_THR_B_EN; } else { /* Enable for both stripes */ acc->awb.stripes[0].grid.width = (acc->stripe.bds_out_stripes[0].width - acc->awb.config.grid.x_start + 1) >> acc->awb.config.grid.block_width_log2; acc->awb.stripes[1].grid.width = acc->awb.config.grid.width - acc->awb.stripes[0].grid.width; b_w_log2 = acc->awb.stripes[0].grid.block_width_log2; acc->awb.stripes[0].grid.x_end = ipu3_css_grid_end(acc->awb.stripes[0].grid.x_start, acc->awb.stripes[0].grid.width, b_w_log2); acc->awb.stripes[1].grid.x_start = (acc->awb.stripes[0].grid.x_end + 1 - acc->stripe.down_scaled_stripes[1].offset) & IPU3_UAPI_GRID_START_MASK; b_w_log2 = acc->awb.stripes[1].grid.block_width_log2; acc->awb.stripes[1].grid.x_end = ipu3_css_grid_end(acc->awb.stripes[1].grid.x_start, acc->awb.stripes[1].grid.width, b_w_log2); /* * To reduce complexity of debubbling and loading statistics * fix grid_height_per_slice to 1 for both stripes */ for (i = 0; i < stripes; i++) acc->awb.stripes[i].grid.height_per_slice = 1; } if (ipu3_css_awb_ops_calc(css, pipe, &acc->awb)) return -EINVAL; return 0; } /* * Fill the indicated structure in `new_binary_params' from the possible * sources based on `use_user' flag: if the flag is false, copy from * `old_binary_params', or if the flag is true, copy from `user_setting' * and return NULL (or error pointer on error). * If the flag is false and `old_binary_params' is NULL, return pointer * to the structure inside `new_binary_params'. In that case the caller * should calculate and fill the structure from scratch. */ static void *ipu3_css_cfg_copy(struct ipu3_css *css, unsigned int pipe, bool use_user, void *user_setting, void *old_binary_params, void *new_binary_params, enum imgu_abi_memories m, struct imgu_fw_isp_parameter *par, size_t par_size) { const enum imgu_abi_param_class c = IMGU_ABI_PARAM_CLASS_PARAM; void *new_setting, *old_setting; new_setting = ipu3_css_fw_pipeline_params(css, pipe, c, m, par, par_size, new_binary_params); if (!new_setting) return ERR_PTR(-EPROTO); /* Corrupted firmware */ if (use_user) { /* Take new user parameters */ memcpy(new_setting, user_setting, par_size); } else if (old_binary_params) { /* Take previous value */ old_setting = ipu3_css_fw_pipeline_params(css, pipe, c, m, par, par_size, old_binary_params); if (!old_setting) return ERR_PTR(-EPROTO); memcpy(new_setting, old_setting, par_size); } else { return new_setting; /* Need to calculate */ } return NULL; /* Copied from other value */ } /* * Configure VMEM0 parameters (late binding parameters). */ int ipu3_css_cfg_vmem0(struct ipu3_css *css, unsigned int pipe, struct ipu3_uapi_flags *use, void *vmem0, void *vmem0_old, struct ipu3_uapi_params *user) { const struct imgu_fw_info *bi = &css->fwp->binary_header[css->pipes[pipe].bindex]; struct imgu_fw_param_memory_offsets *pofs = (void *)css->fwp + bi->blob.memory_offsets.offsets[IMGU_ABI_PARAM_CLASS_PARAM]; struct ipu3_uapi_isp_lin_vmem_params *lin_vmem = NULL; struct ipu3_uapi_isp_tnr3_vmem_params *tnr_vmem = NULL; struct ipu3_uapi_isp_xnr3_vmem_params *xnr_vmem = NULL; const enum imgu_abi_param_class c = IMGU_ABI_PARAM_CLASS_PARAM; const enum imgu_abi_memories m = IMGU_ABI_MEM_ISP_VMEM0; unsigned int i; /* Configure VMEM0 */ memset(vmem0, 0, bi->info.isp.sp.mem_initializers.params[c][m].size); /* Configure Linearization VMEM0 parameters */ lin_vmem = ipu3_css_cfg_copy(css, pipe, use && use->lin_vmem_params, &user->lin_vmem_params, vmem0_old, vmem0, m, &pofs->vmem.lin, sizeof(*lin_vmem)); if (!IS_ERR_OR_NULL(lin_vmem)) { /* Generate parameter from scratch */ for (i = 0; i < IPU3_UAPI_LIN_LUT_SIZE; i++) { lin_vmem->lin_lutlow_gr[i] = 32 * i; lin_vmem->lin_lutlow_r[i] = 32 * i; lin_vmem->lin_lutlow_b[i] = 32 * i; lin_vmem->lin_lutlow_gb[i] = 32 * i; lin_vmem->lin_lutdif_gr[i] = 32; lin_vmem->lin_lutdif_r[i] = 32; lin_vmem->lin_lutdif_b[i] = 32; lin_vmem->lin_lutdif_gb[i] = 32; } } /* Configure TNR3 VMEM parameters */ if (css->pipes[pipe].pipe_id == IPU3_CSS_PIPE_ID_VIDEO) { tnr_vmem = ipu3_css_cfg_copy(css, pipe, use && use->tnr3_vmem_params, &user->tnr3_vmem_params, vmem0_old, vmem0, m, &pofs->vmem.tnr3, sizeof(*tnr_vmem)); if (!IS_ERR_OR_NULL(tnr_vmem)) { /* Generate parameter from scratch */ for (i = 0; i < IPU3_UAPI_ISP_TNR3_VMEM_LEN; i++) tnr_vmem->sigma[i] = 256; } } i = IPU3_UAPI_ISP_TNR3_VMEM_LEN; /* Configure XNR3 VMEM parameters */ xnr_vmem = ipu3_css_cfg_copy(css, pipe, use && use->xnr3_vmem_params, &user->xnr3_vmem_params, vmem0_old, vmem0, m, &pofs->vmem.xnr3, sizeof(*xnr_vmem)); if (!IS_ERR_OR_NULL(xnr_vmem)) { xnr_vmem->x[i] = ipu3_css_xnr3_vmem_defaults.x [i % IMGU_XNR3_VMEM_LUT_LEN]; xnr_vmem->a[i] = ipu3_css_xnr3_vmem_defaults.a [i % IMGU_XNR3_VMEM_LUT_LEN]; xnr_vmem->b[i] = ipu3_css_xnr3_vmem_defaults.b [i % IMGU_XNR3_VMEM_LUT_LEN]; xnr_vmem->c[i] = ipu3_css_xnr3_vmem_defaults.c [i % IMGU_XNR3_VMEM_LUT_LEN]; } return IS_ERR(lin_vmem) || IS_ERR(tnr_vmem) || IS_ERR(xnr_vmem) ? -EPROTO : 0; } /* * Configure DMEM0 parameters (late binding parameters). */ int ipu3_css_cfg_dmem0(struct ipu3_css *css, unsigned int pipe, struct ipu3_uapi_flags *use, void *dmem0, void *dmem0_old, struct ipu3_uapi_params *user) { struct ipu3_css_pipe *css_pipe = &css->pipes[pipe]; const struct imgu_fw_info *bi = &css->fwp->binary_header[css_pipe->bindex]; struct imgu_fw_param_memory_offsets *pofs = (void *)css->fwp + bi->blob.memory_offsets.offsets[IMGU_ABI_PARAM_CLASS_PARAM]; struct ipu3_uapi_isp_tnr3_params *tnr_dmem = NULL; struct ipu3_uapi_isp_xnr3_params *xnr_dmem; const enum imgu_abi_param_class c = IMGU_ABI_PARAM_CLASS_PARAM; const enum imgu_abi_memories m = IMGU_ABI_MEM_ISP_DMEM0; /* Configure DMEM0 */ memset(dmem0, 0, bi->info.isp.sp.mem_initializers.params[c][m].size); /* Configure TNR3 DMEM0 parameters */ if (css_pipe->pipe_id == IPU3_CSS_PIPE_ID_VIDEO) { tnr_dmem = ipu3_css_cfg_copy(css, pipe, use && use->tnr3_dmem_params, &user->tnr3_dmem_params, dmem0_old, dmem0, m, &pofs->dmem.tnr3, sizeof(*tnr_dmem)); if (!IS_ERR_OR_NULL(tnr_dmem)) { /* Generate parameter from scratch */ tnr_dmem->knee_y1 = 768; tnr_dmem->knee_y2 = 1280; } } /* Configure XNR3 DMEM0 parameters */ xnr_dmem = ipu3_css_cfg_copy(css, pipe, use && use->xnr3_dmem_params, &user->xnr3_dmem_params, dmem0_old, dmem0, m, &pofs->dmem.xnr3, sizeof(*xnr_dmem)); if (!IS_ERR_OR_NULL(xnr_dmem)) { /* Generate parameter from scratch */ xnr_dmem->alpha.y0 = 2047; xnr_dmem->alpha.u0 = 2047; xnr_dmem->alpha.v0 = 2047; } return IS_ERR(tnr_dmem) || IS_ERR(xnr_dmem) ? -EPROTO : 0; } /* Generate unity morphing table without morphing effect */ void ipu3_css_cfg_gdc_table(struct imgu_abi_gdc_warp_param *gdc, int frame_in_x, int frame_in_y, int frame_out_x, int frame_out_y, int env_w, int env_h) { static const unsigned int FRAC_BITS = IMGU_ABI_GDC_FRAC_BITS; static const unsigned int XMEM_ALIGN = 1 << 4; const unsigned int XMEM_ALIGN_MASK = ~(XMEM_ALIGN - 1); static const unsigned int BCI_ENV = 4; static const unsigned int BYP = 2; /* Bytes per pixel */ const unsigned int OFFSET_X = 2 * IMGU_DVS_BLOCK_W + env_w + 1; const unsigned int OFFSET_Y = IMGU_DVS_BLOCK_H + env_h + 1; struct imgu_abi_gdc_warp_param gdc_luma, gdc_chroma; unsigned int blocks_x = ALIGN(DIV_ROUND_UP(frame_out_x, IMGU_DVS_BLOCK_W), 2); unsigned int blocks_y = DIV_ROUND_UP(frame_out_y, IMGU_DVS_BLOCK_H); unsigned int y0, x0, x1, x, y; /* Global luma settings */ gdc_luma.origin_x = 0; gdc_luma.origin_y = 0; gdc_luma.p0_x = (OFFSET_X - (OFFSET_X & XMEM_ALIGN_MASK)) << FRAC_BITS; gdc_luma.p0_y = 0; gdc_luma.p1_x = gdc_luma.p0_x + (IMGU_DVS_BLOCK_W << FRAC_BITS); gdc_luma.p1_y = gdc_luma.p0_y; gdc_luma.p2_x = gdc_luma.p0_x; gdc_luma.p2_y = gdc_luma.p0_y + (IMGU_DVS_BLOCK_H << FRAC_BITS); gdc_luma.p3_x = gdc_luma.p1_x; gdc_luma.p3_y = gdc_luma.p2_y; gdc_luma.in_block_width = IMGU_DVS_BLOCK_W + BCI_ENV + OFFSET_X - (OFFSET_X & XMEM_ALIGN_MASK); gdc_luma.in_block_width_a = DIV_ROUND_UP(gdc_luma.in_block_width, IPU3_UAPI_ISP_VEC_ELEMS); gdc_luma.in_block_width_b = DIV_ROUND_UP(gdc_luma.in_block_width, IMGU_ABI_ISP_DDR_WORD_BYTES / BYP); gdc_luma.in_block_height = IMGU_DVS_BLOCK_H + BCI_ENV; gdc_luma.padding = 0; /* Global chroma settings */ gdc_chroma.origin_x = 0; gdc_chroma.origin_y = 0; gdc_chroma.p0_x = (OFFSET_X / 2 - (OFFSET_X / 2 & XMEM_ALIGN_MASK)) << FRAC_BITS; gdc_chroma.p0_y = 0; gdc_chroma.p1_x = gdc_chroma.p0_x + (IMGU_DVS_BLOCK_W << FRAC_BITS); gdc_chroma.p1_y = gdc_chroma.p0_y; gdc_chroma.p2_x = gdc_chroma.p0_x; gdc_chroma.p2_y = gdc_chroma.p0_y + (IMGU_DVS_BLOCK_H / 2 << FRAC_BITS); gdc_chroma.p3_x = gdc_chroma.p1_x; gdc_chroma.p3_y = gdc_chroma.p2_y; gdc_chroma.in_block_width = IMGU_DVS_BLOCK_W + BCI_ENV; gdc_chroma.in_block_width_a = DIV_ROUND_UP(gdc_chroma.in_block_width, IPU3_UAPI_ISP_VEC_ELEMS); gdc_chroma.in_block_width_b = DIV_ROUND_UP(gdc_chroma.in_block_width, IMGU_ABI_ISP_DDR_WORD_BYTES / BYP); gdc_chroma.in_block_height = IMGU_DVS_BLOCK_H / 2 + BCI_ENV; gdc_chroma.padding = 0; /* Calculate block offsets for luma and chroma */ for (y0 = 0; y0 < blocks_y; y0++) { for (x0 = 0; x0 < blocks_x / 2; x0++) { for (x1 = 0; x1 < 2; x1++) { /* Luma blocks */ x = (x0 * 2 + x1) * IMGU_DVS_BLOCK_W + OFFSET_X; x &= XMEM_ALIGN_MASK; y = y0 * IMGU_DVS_BLOCK_H + OFFSET_Y; *gdc = gdc_luma; gdc->in_addr_offset = (y * frame_in_x + x) * BYP; gdc++; } /* Chroma block */ x = x0 * IMGU_DVS_BLOCK_W + OFFSET_X / 2; x &= XMEM_ALIGN_MASK; y = y0 * (IMGU_DVS_BLOCK_H / 2) + OFFSET_Y / 2; *gdc = gdc_chroma; gdc->in_addr_offset = (y * frame_in_x + x) * BYP; gdc++; } } }
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