/* * Copyright (C) 2012 Texas Instruments Inc * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License as * published by the Free Software Foundation version 2. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA * * Contributors: * Manjunath Hadli * Prabhakar Lad */ #include "dm365_ipipe_hw.h" #define IPIPE_MODE_CONTINUOUS 0 #define IPIPE_MODE_SINGLE_SHOT 1 static void ipipe_clock_enable(void *__iomem base_addr) { /* enable IPIPE MMR for register write access */ regw_ip(base_addr, IPIPE_GCK_MMR_DEFAULT, IPIPE_GCK_MMR); /* enable the clock wb,cfa,dfc,d2f,pre modules */ regw_ip(base_addr, IPIPE_GCK_PIX_DEFAULT, IPIPE_GCK_PIX); } static void rsz_set_common_params(void *__iomem rsz_base, struct resizer_params *params) { struct rsz_common_params *rsz_common = ¶ms->rsz_common; u32 val; /* Set mode */ regw_rsz(rsz_base, params->oper_mode, RSZ_SRC_MODE); /* data source selection and bypass */ val = (rsz_common->passthrough << RSZ_BYPASS_SHIFT) | rsz_common->source; regw_rsz(rsz_base, val, RSZ_SRC_FMT0); /* src image selection */ val = (rsz_common->raw_flip & 1) | (rsz_common->src_img_fmt << RSZ_SRC_IMG_FMT_SHIFT) | ((rsz_common->y_c & 1) << RSZ_SRC_Y_C_SEL_SHIFT); regw_rsz(rsz_base, val, RSZ_SRC_FMT1); regw_rsz(rsz_base, rsz_common->vps & IPIPE_RSZ_VPS_MASK, RSZ_SRC_VPS); regw_rsz(rsz_base, rsz_common->hps & IPIPE_RSZ_HPS_MASK, RSZ_SRC_HPS); regw_rsz(rsz_base, rsz_common->vsz & IPIPE_RSZ_VSZ_MASK, RSZ_SRC_VSZ); regw_rsz(rsz_base, rsz_common->hsz & IPIPE_RSZ_HSZ_MASK, RSZ_SRC_HSZ); regw_rsz(rsz_base, rsz_common->yuv_y_min, RSZ_YUV_Y_MIN); regw_rsz(rsz_base, rsz_common->yuv_y_max, RSZ_YUV_Y_MAX); regw_rsz(rsz_base, rsz_common->yuv_c_min, RSZ_YUV_C_MIN); regw_rsz(rsz_base, rsz_common->yuv_c_max, RSZ_YUV_C_MAX); /* chromatic position */ regw_rsz(rsz_base, rsz_common->out_chr_pos, RSZ_YUV_PHS); } static void rsz_set_rsz_regs(void *__iomem rsz_base, unsigned int rsz_id, struct resizer_params *params) { struct resizer_scale_param *rsc_params; struct rsz_ext_mem_param *ext_mem; struct resizer_rgb *rgb; u32 reg_base; u32 val; rsc_params = ¶ms->rsz_rsc_param[rsz_id]; rgb = ¶ms->rsz2rgb[rsz_id]; ext_mem = ¶ms->ext_mem_param[rsz_id]; if (rsz_id == RSZ_A) { val = rsc_params->h_flip << RSZA_H_FLIP_SHIFT; val |= rsc_params->v_flip << RSZA_V_FLIP_SHIFT; reg_base = RSZ_EN_A; } else { val = rsc_params->h_flip << RSZB_H_FLIP_SHIFT; val |= rsc_params->v_flip << RSZB_V_FLIP_SHIFT; reg_base = RSZ_EN_B; } /* update flip settings */ regw_rsz(rsz_base, val, RSZ_SEQ); regw_rsz(rsz_base, params->oper_mode, reg_base + RSZ_MODE); val = (rsc_params->cen << RSZ_CEN_SHIFT) | rsc_params->yen; regw_rsz(rsz_base, val, reg_base + RSZ_420); regw_rsz(rsz_base, rsc_params->i_vps & RSZ_VPS_MASK, reg_base + RSZ_I_VPS); regw_rsz(rsz_base, rsc_params->i_hps & RSZ_HPS_MASK, reg_base + RSZ_I_HPS); regw_rsz(rsz_base, rsc_params->o_vsz & RSZ_O_VSZ_MASK, reg_base + RSZ_O_VSZ); regw_rsz(rsz_base, rsc_params->o_hsz & RSZ_O_HSZ_MASK, reg_base + RSZ_O_HSZ); regw_rsz(rsz_base, rsc_params->v_phs_y & RSZ_V_PHS_MASK, reg_base + RSZ_V_PHS_Y); regw_rsz(rsz_base, rsc_params->v_phs_c & RSZ_V_PHS_MASK, reg_base + RSZ_V_PHS_C); /* keep this additional adjustment to zero for now */ regw_rsz(rsz_base, rsc_params->v_dif & RSZ_V_DIF_MASK, reg_base + RSZ_V_DIF); val = (rsc_params->v_typ_y & 1) | ((rsc_params->v_typ_c & 1) << RSZ_TYP_C_SHIFT); regw_rsz(rsz_base, val, reg_base + RSZ_V_TYP); val = (rsc_params->v_lpf_int_y & RSZ_LPF_INT_MASK) | ((rsc_params->v_lpf_int_c & RSZ_LPF_INT_MASK) << RSZ_LPF_INT_C_SHIFT); regw_rsz(rsz_base, val, reg_base + RSZ_V_LPF); regw_rsz(rsz_base, rsc_params->h_phs & RSZ_H_PHS_MASK, reg_base + RSZ_H_PHS); regw_rsz(rsz_base, 0, reg_base + RSZ_H_PHS_ADJ); regw_rsz(rsz_base, rsc_params->h_dif & RSZ_H_DIF_MASK, reg_base + RSZ_H_DIF); val = (rsc_params->h_typ_y & 1) | ((rsc_params->h_typ_c & 1) << RSZ_TYP_C_SHIFT); regw_rsz(rsz_base, val, reg_base + RSZ_H_TYP); val = (rsc_params->h_lpf_int_y & RSZ_LPF_INT_MASK) | ((rsc_params->h_lpf_int_c & RSZ_LPF_INT_MASK) << RSZ_LPF_INT_C_SHIFT); regw_rsz(rsz_base, val, reg_base + RSZ_H_LPF); regw_rsz(rsz_base, rsc_params->dscale_en & 1, reg_base + RSZ_DWN_EN); val = (rsc_params->h_dscale_ave_sz & RSZ_DWN_SCALE_AV_SZ_MASK) | ((rsc_params->v_dscale_ave_sz & RSZ_DWN_SCALE_AV_SZ_MASK) << RSZ_DWN_SCALE_AV_SZ_V_SHIFT); regw_rsz(rsz_base, val, reg_base + RSZ_DWN_AV); /* setting rgb conversion parameters */ regw_rsz(rsz_base, rgb->rgb_en, reg_base + RSZ_RGB_EN); val = (rgb->rgb_typ << RSZ_RGB_TYP_SHIFT) | (rgb->rgb_msk0 << RSZ_RGB_MSK0_SHIFT) | (rgb->rgb_msk1 << RSZ_RGB_MSK1_SHIFT); regw_rsz(rsz_base, val, reg_base + RSZ_RGB_TYP); regw_rsz(rsz_base, rgb->rgb_alpha_val & RSZ_RGB_ALPHA_MASK, reg_base + RSZ_RGB_BLD); /* setting external memory parameters */ regw_rsz(rsz_base, ext_mem->rsz_sdr_oft_y, reg_base + RSZ_SDR_Y_OFT); regw_rsz(rsz_base, ext_mem->rsz_sdr_ptr_s_y, reg_base + RSZ_SDR_Y_PTR_S); regw_rsz(rsz_base, ext_mem->rsz_sdr_ptr_e_y, reg_base + RSZ_SDR_Y_PTR_E); regw_rsz(rsz_base, ext_mem->rsz_sdr_oft_c, reg_base + RSZ_SDR_C_OFT); regw_rsz(rsz_base, ext_mem->rsz_sdr_ptr_s_c, reg_base + RSZ_SDR_C_PTR_S); regw_rsz(rsz_base, (ext_mem->rsz_sdr_ptr_e_c >> 1), reg_base + RSZ_SDR_C_PTR_E); } /*set the registers of either RSZ0 or RSZ1 */ static void ipipe_setup_resizer(void *__iomem rsz_base, struct resizer_params *params) { /* enable MMR gate to write to Resizer */ regw_rsz(rsz_base, 1, RSZ_GCK_MMR); /* Enable resizer if it is not in bypass mode */ if (params->rsz_common.passthrough) regw_rsz(rsz_base, 0, RSZ_GCK_SDR); else regw_rsz(rsz_base, 1, RSZ_GCK_SDR); rsz_set_common_params(rsz_base, params); regw_rsz(rsz_base, params->rsz_en[RSZ_A], RSZ_EN_A); if (params->rsz_en[RSZ_A]) /*setting rescale parameters */ rsz_set_rsz_regs(rsz_base, RSZ_A, params); regw_rsz(rsz_base, params->rsz_en[RSZ_B], RSZ_EN_B); if (params->rsz_en[RSZ_B]) rsz_set_rsz_regs(rsz_base, RSZ_B, params); } static u32 ipipe_get_color_pat(enum v4l2_mbus_pixelcode pix) { switch (pix) { case V4L2_MBUS_FMT_SGRBG10_ALAW8_1X8: case V4L2_MBUS_FMT_SGRBG10_DPCM8_1X8: case V4L2_MBUS_FMT_SGRBG12_1X12: return ipipe_sgrbg_pattern; default: return ipipe_srggb_pattern; } } static int ipipe_get_data_path(struct vpfe_ipipe_device *ipipe) { enum v4l2_mbus_pixelcode temp_pix_fmt; switch (ipipe->formats[IPIPE_PAD_SINK].code) { case V4L2_MBUS_FMT_SBGGR8_1X8: case V4L2_MBUS_FMT_SGRBG10_ALAW8_1X8: case V4L2_MBUS_FMT_SGRBG10_DPCM8_1X8: case V4L2_MBUS_FMT_SGRBG12_1X12: temp_pix_fmt = V4L2_MBUS_FMT_SGRBG12_1X12; break; default: temp_pix_fmt = V4L2_MBUS_FMT_UYVY8_2X8; } if (temp_pix_fmt == V4L2_MBUS_FMT_SGRBG12_1X12) { if (ipipe->formats[IPIPE_PAD_SOURCE].code == V4L2_MBUS_FMT_SGRBG12_1X12) return IPIPE_RAW2RAW; return IPIPE_RAW2YUV; } return IPIPE_YUV2YUV; } static int get_ipipe_mode(struct vpfe_ipipe_device *ipipe) { struct vpfe_device *vpfe_dev = to_vpfe_device(ipipe); u16 ipipeif_sink = vpfe_dev->vpfe_ipipeif.input; if (ipipeif_sink == IPIPEIF_INPUT_MEMORY) return IPIPE_MODE_SINGLE_SHOT; else if (ipipeif_sink == IPIPEIF_INPUT_ISIF) return IPIPE_MODE_CONTINUOUS; return -EINVAL; } int config_ipipe_hw(struct vpfe_ipipe_device *ipipe) { struct vpfe_ipipe_input_config *config = &ipipe->config.input_config; void __iomem *ipipe_base = ipipe->base_addr; struct v4l2_mbus_framefmt *outformat; u32 color_pat; u32 ipipe_mode; u32 data_path; /* enable clock to IPIPE */ vpss_enable_clock(VPSS_IPIPE_CLOCK, 1); ipipe_clock_enable(ipipe_base); if (ipipe->input == IPIPE_INPUT_NONE) { regw_ip(ipipe_base, 0, IPIPE_SRC_EN); return 0; } ipipe_mode = get_ipipe_mode(ipipe); if (ipipe < 0) { pr_err("Failed to get ipipe mode"); return -EINVAL; } regw_ip(ipipe_base, ipipe_mode, IPIPE_SRC_MODE); data_path = ipipe_get_data_path(ipipe); regw_ip(ipipe_base, data_path, IPIPE_SRC_FMT); regw_ip(ipipe_base, config->vst & IPIPE_RSZ_VPS_MASK, IPIPE_SRC_VPS); regw_ip(ipipe_base, config->hst & IPIPE_RSZ_HPS_MASK, IPIPE_SRC_HPS); outformat = &ipipe->formats[IPIPE_PAD_SOURCE]; regw_ip(ipipe_base, (outformat->height + 1) & IPIPE_RSZ_VSZ_MASK, IPIPE_SRC_VSZ); regw_ip(ipipe_base, (outformat->width + 1) & IPIPE_RSZ_HSZ_MASK, IPIPE_SRC_HSZ); if (data_path == IPIPE_RAW2YUV || data_path == IPIPE_RAW2RAW) { color_pat = ipipe_get_color_pat(ipipe->formats[IPIPE_PAD_SINK].code); regw_ip(ipipe_base, color_pat, IPIPE_SRC_COL); } return 0; } /* * config_rsz_hw() - Performs hardware setup of resizer. */ int config_rsz_hw(struct vpfe_resizer_device *resizer, struct resizer_params *config) { struct vpfe_device *vpfe_dev = to_vpfe_device(resizer); void *__iomem ipipe_base = vpfe_dev->vpfe_ipipe.base_addr; void *__iomem rsz_base = vpfe_dev->vpfe_resizer.base_addr; /* enable VPSS clock */ vpss_enable_clock(VPSS_IPIPE_CLOCK, 1); ipipe_clock_enable(ipipe_base); ipipe_setup_resizer(rsz_base, config); return 0; } static void rsz_set_y_address(void *__iomem rsz_base, unsigned int address, unsigned int offset) { u32 val; val = address & SET_LOW_ADDR; regw_rsz(rsz_base, val, offset + RSZ_SDR_Y_BAD_L); regw_rsz(rsz_base, val, offset + RSZ_SDR_Y_SAD_L); val = (address & SET_HIGH_ADDR) >> 16; regw_rsz(rsz_base, val, offset + RSZ_SDR_Y_BAD_H); regw_rsz(rsz_base, val, offset + RSZ_SDR_Y_SAD_H); } static void rsz_set_c_address(void *__iomem rsz_base, unsigned int address, unsigned int offset) { u32 val; val = address & SET_LOW_ADDR; regw_rsz(rsz_base, val, offset + RSZ_SDR_C_BAD_L); regw_rsz(rsz_base, val, offset + RSZ_SDR_C_SAD_L); val = (address & SET_HIGH_ADDR) >> 16; regw_rsz(rsz_base, val, offset + RSZ_SDR_C_BAD_H); regw_rsz(rsz_base, val, offset + RSZ_SDR_C_SAD_H); } /* * resizer_set_outaddr() - set the address for given resize_no * @rsz_base: resizer base address * @params: pointer to ipipe_params structure * @resize_no: 0 - Resizer-A, 1 - Resizer B * @address: the address to set */ int resizer_set_outaddr(void *__iomem rsz_base, struct resizer_params *params, int resize_no, unsigned int address) { struct resizer_scale_param *rsc_param; struct rsz_ext_mem_param *mem_param; struct rsz_common_params *rsz_common; unsigned int rsz_start_add; unsigned int val; if (resize_no != RSZ_A && resize_no != RSZ_B) return -EINVAL; mem_param = ¶ms->ext_mem_param[resize_no]; rsc_param = ¶ms->rsz_rsc_param[resize_no]; rsz_common = ¶ms->rsz_common; if (resize_no == RSZ_A) rsz_start_add = RSZ_EN_A; else rsz_start_add = RSZ_EN_B; /* y_c = 0 for y, = 1 for c */ if (rsz_common->src_img_fmt == RSZ_IMG_420) { if (rsz_common->y_c) { /* C channel */ val = address + mem_param->flip_ofst_c; rsz_set_c_address(rsz_base, val, rsz_start_add); } else { val = address + mem_param->flip_ofst_y; rsz_set_y_address(rsz_base, val, rsz_start_add); } } else { if (rsc_param->cen && rsc_param->yen) { /* 420 */ val = address + mem_param->c_offset + mem_param->flip_ofst_c + mem_param->user_y_ofst + mem_param->user_c_ofst; if (resize_no == RSZ_B) val += params->ext_mem_param[RSZ_A].user_y_ofst + params->ext_mem_param[RSZ_A].user_c_ofst; /* set C address */ rsz_set_c_address(rsz_base, val, rsz_start_add); } val = address + mem_param->flip_ofst_y + mem_param->user_y_ofst; if (resize_no == RSZ_B) val += params->ext_mem_param[RSZ_A].user_y_ofst + params->ext_mem_param[RSZ_A].user_c_ofst; /* set Y address */ rsz_set_y_address(rsz_base, val, rsz_start_add); } /* resizer must be enabled */ regw_rsz(rsz_base, params->rsz_en[resize_no], rsz_start_add); return 0; } void ipipe_set_lutdpc_regs(void *__iomem base_addr, void *__iomem isp5_base_addr, struct vpfe_ipipe_lutdpc *dpc) { u32 max_tbl_size = LUT_DPC_MAX_SIZE >> 1; u32 lut_start_addr = DPC_TB0_START_ADDR; u32 val; u32 count; ipipe_clock_enable(base_addr); regw_ip(base_addr, dpc->en, DPC_LUT_EN); if (dpc->en != 1) return; val = LUTDPC_TBL_256_EN | (dpc->repl_white & 1); regw_ip(base_addr, val, DPC_LUT_SEL); regw_ip(base_addr, LUT_DPC_START_ADDR, DPC_LUT_ADR); regw_ip(base_addr, dpc->dpc_size, DPC_LUT_SIZ & LUT_DPC_SIZE_MASK); if (dpc->table == NULL) return; for (count = 0; count < dpc->dpc_size; count++) { if (count >= max_tbl_size) lut_start_addr = DPC_TB1_START_ADDR; val = (dpc->table[count].horz_pos & LUT_DPC_H_POS_MASK) | ((dpc->table[count].vert_pos & LUT_DPC_V_POS_MASK) << LUT_DPC_V_POS_SHIFT) | (dpc->table[count].method << LUT_DPC_CORR_METH_SHIFT); w_ip_table(isp5_base_addr, val, (lut_start_addr + ((count % max_tbl_size) << 2))); } } static void set_dpc_thresholds(void *__iomem base_addr, struct vpfe_ipipe_otfdpc_2_0_cfg *dpc_thr) { regw_ip(base_addr, dpc_thr->corr_thr.r & OTFDPC_DPC2_THR_MASK, DPC_OTF_2C_THR_R); regw_ip(base_addr, dpc_thr->corr_thr.gr & OTFDPC_DPC2_THR_MASK, DPC_OTF_2C_THR_GR); regw_ip(base_addr, dpc_thr->corr_thr.gb & OTFDPC_DPC2_THR_MASK, DPC_OTF_2C_THR_GB); regw_ip(base_addr, dpc_thr->corr_thr.b & OTFDPC_DPC2_THR_MASK, DPC_OTF_2C_THR_B); regw_ip(base_addr, dpc_thr->det_thr.r & OTFDPC_DPC2_THR_MASK, DPC_OTF_2D_THR_R); regw_ip(base_addr, dpc_thr->det_thr.gr & OTFDPC_DPC2_THR_MASK, DPC_OTF_2D_THR_GR); regw_ip(base_addr, dpc_thr->det_thr.gb & OTFDPC_DPC2_THR_MASK, DPC_OTF_2D_THR_GB); regw_ip(base_addr, dpc_thr->det_thr.b & OTFDPC_DPC2_THR_MASK, DPC_OTF_2D_THR_B); } void ipipe_set_otfdpc_regs(void *__iomem base_addr, struct vpfe_ipipe_otfdpc *otfdpc) { struct vpfe_ipipe_otfdpc_2_0_cfg *dpc_2_0 = &otfdpc->alg_cfg.dpc_2_0; struct vpfe_ipipe_otfdpc_3_0_cfg *dpc_3_0 = &otfdpc->alg_cfg.dpc_3_0; u32 val; ipipe_clock_enable(base_addr); regw_ip(base_addr, (otfdpc->en & 1), DPC_OTF_EN); if (!otfdpc->en) return; /* dpc enabled */ val = (otfdpc->det_method << OTF_DET_METHOD_SHIFT) | otfdpc->alg; regw_ip(base_addr, val, DPC_OTF_TYP); if (otfdpc->det_method == VPFE_IPIPE_DPC_OTF_MIN_MAX) { /* ALG= 0, TYP = 0, DPC_OTF_2D_THR_[x]=0 * DPC_OTF_2C_THR_[x] = Maximum thresohld * MinMax method */ dpc_2_0->det_thr.r = dpc_2_0->det_thr.gb = dpc_2_0->det_thr.gr = dpc_2_0->det_thr.b = 0; set_dpc_thresholds(base_addr, dpc_2_0); return; } /* MinMax2 */ if (otfdpc->alg == VPFE_IPIPE_OTFDPC_2_0) { set_dpc_thresholds(base_addr, dpc_2_0); return; } regw_ip(base_addr, dpc_3_0->act_adj_shf & OTF_DPC3_0_SHF_MASK, DPC_OTF_3_SHF); /* Detection thresholds */ regw_ip(base_addr, ((dpc_3_0->det_thr & OTF_DPC3_0_THR_MASK) << OTF_DPC3_0_THR_SHIFT), DPC_OTF_3D_THR); regw_ip(base_addr, dpc_3_0->det_slp & OTF_DPC3_0_SLP_MASK, DPC_OTF_3D_SLP); regw_ip(base_addr, dpc_3_0->det_thr_min & OTF_DPC3_0_DET_MASK, DPC_OTF_3D_MIN); regw_ip(base_addr, dpc_3_0->det_thr_max & OTF_DPC3_0_DET_MASK, DPC_OTF_3D_MAX); /* Correction thresholds */ regw_ip(base_addr, ((dpc_3_0->corr_thr & OTF_DPC3_0_THR_MASK) << OTF_DPC3_0_THR_SHIFT), DPC_OTF_3C_THR); regw_ip(base_addr, dpc_3_0->corr_slp & OTF_DPC3_0_SLP_MASK, DPC_OTF_3C_SLP); regw_ip(base_addr, dpc_3_0->corr_thr_min & OTF_DPC3_0_CORR_MASK, DPC_OTF_3C_MIN); regw_ip(base_addr, dpc_3_0->corr_thr_max & OTF_DPC3_0_CORR_MASK, DPC_OTF_3C_MAX); } /* 2D Noise filter */ void ipipe_set_d2f_regs(void *__iomem base_addr, unsigned int id, struct vpfe_ipipe_nf *noise_filter) { u32 offset = D2F_1ST; int count; u32 val; if (id == IPIPE_D2F_2ND) offset = D2F_2ND; ipipe_clock_enable(base_addr); regw_ip(base_addr, noise_filter->en & 1, offset + D2F_EN); if (!noise_filter->en) return; /*noise filter enabled */ /* Combine all the fields to make D2F_CFG register of IPIPE */ val = ((noise_filter->spread_val & D2F_SPR_VAL_MASK) << D2F_SPR_VAL_SHIFT) | ((noise_filter->shft_val & D2F_SHFT_VAL_MASK) << D2F_SHFT_VAL_SHIFT) | (noise_filter->gr_sample_meth << D2F_SAMPLE_METH_SHIFT) | ((noise_filter->apply_lsc_gain & 1) << D2F_APPLY_LSC_GAIN_SHIFT) | D2F_USE_SPR_REG_VAL; regw_ip(base_addr, val, offset + D2F_TYP); /* edge detection minimum */ regw_ip(base_addr, noise_filter->edge_det_min_thr & D2F_EDGE_DET_THR_MASK, offset + D2F_EDG_MIN); /* edge detection maximum */ regw_ip(base_addr, noise_filter->edge_det_max_thr & D2F_EDGE_DET_THR_MASK, offset + D2F_EDG_MAX); for (count = 0; count < VPFE_IPIPE_NF_STR_TABLE_SIZE; count++) regw_ip(base_addr, (noise_filter->str[count] & D2F_STR_VAL_MASK), offset + D2F_STR + count * 4); for (count = 0; count < VPFE_IPIPE_NF_THR_TABLE_SIZE; count++) regw_ip(base_addr, noise_filter->thr[count] & D2F_THR_VAL_MASK, offset + D2F_THR + count * 4); } #define IPIPE_U8Q5(decimal, integer) \ (((decimal & 0x1f) | ((integer & 0x7) << 5))) /* Green Imbalance Correction */ void ipipe_set_gic_regs(void *__iomem base_addr, struct vpfe_ipipe_gic *gic) { u32 val; ipipe_clock_enable(base_addr); regw_ip(base_addr, gic->en & 1, GIC_EN); if (!gic->en) return; /*gic enabled */ val = (gic->wt_fn_type << GIC_TYP_SHIFT) | (gic->thr_sel << GIC_THR_SEL_SHIFT) | ((gic->apply_lsc_gain & 1) << GIC_APPLY_LSC_GAIN_SHIFT); regw_ip(base_addr, val, GIC_TYP); regw_ip(base_addr, gic->gain & GIC_GAIN_MASK, GIC_GAN); if (gic->gic_alg != VPFE_IPIPE_GIC_ALG_ADAPT_GAIN) { /* Constant Gain. Set threshold to maximum */ regw_ip(base_addr, GIC_THR_MASK, GIC_THR); return; } if (gic->thr_sel == VPFE_IPIPE_GIC_THR_REG) { regw_ip(base_addr, gic->thr & GIC_THR_MASK, GIC_THR); regw_ip(base_addr, gic->slope & GIC_SLOPE_MASK, GIC_SLP); } else { /* Use NF thresholds */ val = IPIPE_U8Q5(gic->nf2_thr_gain.decimal, gic->nf2_thr_gain.integer); regw_ip(base_addr, val, GIC_NFGAN); } } #define IPIPE_U13Q9(decimal, integer) \ (((decimal & 0x1ff) | ((integer & 0xf) << 9))) /* White balance */ void ipipe_set_wb_regs(void *__iomem base_addr, struct vpfe_ipipe_wb *wb) { u32 val; ipipe_clock_enable(base_addr); /* Ofsets. S12 */ regw_ip(base_addr, wb->ofst_r & WB_OFFSET_MASK, WB2_OFT_R); regw_ip(base_addr, wb->ofst_gr & WB_OFFSET_MASK, WB2_OFT_GR); regw_ip(base_addr, wb->ofst_gb & WB_OFFSET_MASK, WB2_OFT_GB); regw_ip(base_addr, wb->ofst_b & WB_OFFSET_MASK, WB2_OFT_B); /* Gains. U13Q9 */ val = IPIPE_U13Q9(wb->gain_r.decimal, wb->gain_r.integer); regw_ip(base_addr, val, WB2_WGN_R); val = IPIPE_U13Q9(wb->gain_gr.decimal, wb->gain_gr.integer); regw_ip(base_addr, val, WB2_WGN_GR); val = IPIPE_U13Q9(wb->gain_gb.decimal, wb->gain_gb.integer); regw_ip(base_addr, val, WB2_WGN_GB); val = IPIPE_U13Q9(wb->gain_b.decimal, wb->gain_b.integer); regw_ip(base_addr, val, WB2_WGN_B); } /* CFA */ void ipipe_set_cfa_regs(void *__iomem base_addr, struct vpfe_ipipe_cfa *cfa) { ipipe_clock_enable(base_addr); regw_ip(base_addr, cfa->alg, CFA_MODE); regw_ip(base_addr, cfa->hpf_thr_2dir & CFA_HPF_THR_2DIR_MASK, CFA_2DIR_HPF_THR); regw_ip(base_addr, cfa->hpf_slp_2dir & CFA_HPF_SLOPE_2DIR_MASK, CFA_2DIR_HPF_SLP); regw_ip(base_addr, cfa->hp_mix_thr_2dir & CFA_HPF_MIX_THR_2DIR_MASK, CFA_2DIR_MIX_THR); regw_ip(base_addr, cfa->hp_mix_slope_2dir & CFA_HPF_MIX_SLP_2DIR_MASK, CFA_2DIR_MIX_SLP); regw_ip(base_addr, cfa->dir_thr_2dir & CFA_DIR_THR_2DIR_MASK, CFA_2DIR_DIR_THR); regw_ip(base_addr, cfa->dir_slope_2dir & CFA_DIR_SLP_2DIR_MASK, CFA_2DIR_DIR_SLP); regw_ip(base_addr, cfa->nd_wt_2dir & CFA_ND_WT_2DIR_MASK, CFA_2DIR_NDWT); regw_ip(base_addr, cfa->hue_fract_daa & CFA_DAA_HUE_FRA_MASK, CFA_MONO_HUE_FRA); regw_ip(base_addr, cfa->edge_thr_daa & CFA_DAA_EDG_THR_MASK, CFA_MONO_EDG_THR); regw_ip(base_addr, cfa->thr_min_daa & CFA_DAA_THR_MIN_MASK, CFA_MONO_THR_MIN); regw_ip(base_addr, cfa->thr_slope_daa & CFA_DAA_THR_SLP_MASK, CFA_MONO_THR_SLP); regw_ip(base_addr, cfa->slope_min_daa & CFA_DAA_SLP_MIN_MASK, CFA_MONO_SLP_MIN); regw_ip(base_addr, cfa->slope_slope_daa & CFA_DAA_SLP_SLP_MASK, CFA_MONO_SLP_SLP); regw_ip(base_addr, cfa->lp_wt_daa & CFA_DAA_LP_WT_MASK, CFA_MONO_LPWT); } void ipipe_set_rgb2rgb_regs(void *__iomem base_addr, unsigned int id, struct vpfe_ipipe_rgb2rgb *rgb) { u32 offset_mask = RGB2RGB_1_OFST_MASK; u32 offset = RGB1_MUL_BASE; u32 integ_mask = 0xf; u32 val; ipipe_clock_enable(base_addr); if (id == IPIPE_RGB2RGB_2) { /* For second RGB module, gain integer is 3 bits instead of 4, offset has 11 bits insread of 13 */ offset = RGB2_MUL_BASE; integ_mask = 0x7; offset_mask = RGB2RGB_2_OFST_MASK; } /* Gains */ val = (rgb->coef_rr.decimal & 0xff) | ((rgb->coef_rr.integer & integ_mask) << 8); regw_ip(base_addr, val, offset + RGB_MUL_RR); val = (rgb->coef_gr.decimal & 0xff) | ((rgb->coef_gr.integer & integ_mask) << 8); regw_ip(base_addr, val, offset + RGB_MUL_GR); val = (rgb->coef_br.decimal & 0xff) | ((rgb->coef_br.integer & integ_mask) << 8); regw_ip(base_addr, val, offset + RGB_MUL_BR); val = (rgb->coef_rg.decimal & 0xff) | ((rgb->coef_rg.integer & integ_mask) << 8); regw_ip(base_addr, val, offset + RGB_MUL_RG); val = (rgb->coef_gg.decimal & 0xff) | ((rgb->coef_gg.integer & integ_mask) << 8); regw_ip(base_addr, val, offset + RGB_MUL_GG); val = (rgb->coef_bg.decimal & 0xff) | ((rgb->coef_bg.integer & integ_mask) << 8); regw_ip(base_addr, val, offset + RGB_MUL_BG); val = (rgb->coef_rb.decimal & 0xff) | ((rgb->coef_rb.integer & integ_mask) << 8); regw_ip(base_addr, val, offset + RGB_MUL_RB); val = (rgb->coef_gb.decimal & 0xff) | ((rgb->coef_gb.integer & integ_mask) << 8); regw_ip(base_addr, val, offset + RGB_MUL_GB); val = (rgb->coef_bb.decimal & 0xff) | ((rgb->coef_bb.integer & integ_mask) << 8); regw_ip(base_addr, val, offset + RGB_MUL_BB); /* Offsets */ regw_ip(base_addr, rgb->out_ofst_r & offset_mask, offset + RGB_OFT_OR); regw_ip(base_addr, rgb->out_ofst_g & offset_mask, offset + RGB_OFT_OG); regw_ip(base_addr, rgb->out_ofst_b & offset_mask, offset + RGB_OFT_OB); } static void ipipe_update_gamma_tbl(void *__iomem isp5_base_addr, struct vpfe_ipipe_gamma_entry *table, int size, u32 addr) { int count; u32 val; for (count = 0; count < size; count++) { val = table[count].slope & GAMMA_MASK; val |= (table[count].offset & GAMMA_MASK) << GAMMA_SHIFT; w_ip_table(isp5_base_addr, val, (addr + (count * 4))); } } void ipipe_set_gamma_regs(void *__iomem base_addr, void *__iomem isp5_base_addr, struct vpfe_ipipe_gamma *gamma) { int table_size; u32 val; ipipe_clock_enable(base_addr); val = (gamma->bypass_r << GAMMA_BYPR_SHIFT) | (gamma->bypass_b << GAMMA_BYPG_SHIFT) | (gamma->bypass_g << GAMMA_BYPB_SHIFT) | (gamma->tbl_sel << GAMMA_TBL_SEL_SHIFT) | (gamma->tbl_size << GAMMA_TBL_SIZE_SHIFT); regw_ip(base_addr, val, GMM_CFG); if (gamma->tbl_sel != VPFE_IPIPE_GAMMA_TBL_RAM) return; table_size = gamma->tbl_size; if (!gamma->bypass_r && gamma->table_r != NULL) ipipe_update_gamma_tbl(isp5_base_addr, gamma->table_r, table_size, GAMMA_R_START_ADDR); if (!gamma->bypass_b && gamma->table_b != NULL) ipipe_update_gamma_tbl(isp5_base_addr, gamma->table_b, table_size, GAMMA_B_START_ADDR); if (!gamma->bypass_g && gamma->table_g != NULL) ipipe_update_gamma_tbl(isp5_base_addr, gamma->table_g, table_size, GAMMA_G_START_ADDR); } void ipipe_set_3d_lut_regs(void *__iomem base_addr, void *__iomem isp5_base_addr, struct vpfe_ipipe_3d_lut *lut_3d) { struct vpfe_ipipe_3d_lut_entry *tbl; u32 bnk_index; u32 tbl_index; u32 val; u32 i; ipipe_clock_enable(base_addr); regw_ip(base_addr, lut_3d->en, D3LUT_EN); if (!lut_3d->en) return; /* lut_3d enabled */ if (!lut_3d->table) return; /* valied table */ tbl = lut_3d->table; for (i = 0 ; i < VPFE_IPIPE_MAX_SIZE_3D_LUT; i++) { /* Each entry has 0-9 (B), 10-19 (G) and 20-29 R values */ val = tbl[i].b & D3_LUT_ENTRY_MASK; val |= (tbl[i].g & D3_LUT_ENTRY_MASK) << D3_LUT_ENTRY_G_SHIFT; val |= (tbl[i].r & D3_LUT_ENTRY_MASK) << D3_LUT_ENTRY_R_SHIFT; bnk_index = i % 4; tbl_index = i >> 2; tbl_index <<= 2; if (bnk_index == 0) w_ip_table(isp5_base_addr, val, tbl_index + D3L_TB0_START_ADDR); else if (bnk_index == 1) w_ip_table(isp5_base_addr, val, tbl_index + D3L_TB1_START_ADDR); else if (bnk_index == 2) w_ip_table(isp5_base_addr, val, tbl_index + D3L_TB2_START_ADDR); else w_ip_table(isp5_base_addr, val, tbl_index + D3L_TB3_START_ADDR); } } /* Lumina adjustments */ void ipipe_set_lum_adj_regs(void *__iomem base_addr, struct ipipe_lum_adj *lum_adj) { u32 val; ipipe_clock_enable(base_addr); /* combine fields of YUV_ADJ to set brightness and contrast */ val = lum_adj->contrast << LUM_ADJ_CONTR_SHIFT | lum_adj->brightness << LUM_ADJ_BRIGHT_SHIFT; regw_ip(base_addr, val, YUV_ADJ); } #define IPIPE_S12Q8(decimal, integer) \ (((decimal & 0xff) | ((integer & 0xf) << 8))) void ipipe_set_rgb2ycbcr_regs(void *__iomem base_addr, struct vpfe_ipipe_rgb2yuv *yuv) { u32 val; /* S10Q8 */ ipipe_clock_enable(base_addr); val = IPIPE_S12Q8(yuv->coef_ry.decimal, yuv->coef_ry.integer); regw_ip(base_addr, val, YUV_MUL_RY); val = IPIPE_S12Q8(yuv->coef_gy.decimal, yuv->coef_gy.integer); regw_ip(base_addr, val, YUV_MUL_GY); val = IPIPE_S12Q8(yuv->coef_by.decimal, yuv->coef_by.integer); regw_ip(base_addr, val, YUV_MUL_BY); val = IPIPE_S12Q8(yuv->coef_rcb.decimal, yuv->coef_rcb.integer); regw_ip(base_addr, val, YUV_MUL_RCB); val = IPIPE_S12Q8(yuv->coef_gcb.decimal, yuv->coef_gcb.integer); regw_ip(base_addr, val, YUV_MUL_GCB); val = IPIPE_S12Q8(yuv->coef_bcb.decimal, yuv->coef_bcb.integer); regw_ip(base_addr, val, YUV_MUL_BCB); val = IPIPE_S12Q8(yuv->coef_rcr.decimal, yuv->coef_rcr.integer); regw_ip(base_addr, val, YUV_MUL_RCR); val = IPIPE_S12Q8(yuv->coef_gcr.decimal, yuv->coef_gcr.integer); regw_ip(base_addr, val, YUV_MUL_GCR); val = IPIPE_S12Q8(yuv->coef_bcr.decimal, yuv->coef_bcr.integer); regw_ip(base_addr, val, YUV_MUL_BCR); regw_ip(base_addr, yuv->out_ofst_y & RGB2YCBCR_OFST_MASK, YUV_OFT_Y); regw_ip(base_addr, yuv->out_ofst_cb & RGB2YCBCR_OFST_MASK, YUV_OFT_CB); regw_ip(base_addr, yuv->out_ofst_cr & RGB2YCBCR_OFST_MASK, YUV_OFT_CR); } /* YUV 422 conversion */ void ipipe_set_yuv422_conv_regs(void *__iomem base_addr, struct vpfe_ipipe_yuv422_conv *conv) { u32 val; ipipe_clock_enable(base_addr); /* Combine all the fields to make YUV_PHS register of IPIPE */ val = (conv->chrom_pos << 0) | (conv->en_chrom_lpf << 1); regw_ip(base_addr, val, YUV_PHS); } void ipipe_set_gbce_regs(void *__iomem base_addr, void *__iomem isp5_base_addr, struct vpfe_ipipe_gbce *gbce) { unsigned int count; u32 mask = GBCE_Y_VAL_MASK; if (gbce->type == VPFE_IPIPE_GBCE_GAIN_TBL) mask = GBCE_GAIN_VAL_MASK; ipipe_clock_enable(base_addr); regw_ip(base_addr, gbce->en & 1, GBCE_EN); if (!gbce->en) return; regw_ip(base_addr, gbce->type, GBCE_TYP); if (!gbce->table) return; for (count = 0; count < VPFE_IPIPE_MAX_SIZE_GBCE_LUT ; count += 2) w_ip_table(isp5_base_addr, ((gbce->table[count + 1] & mask) << GBCE_ENTRY_SHIFT) | (gbce->table[count] & mask), ((count/2) << 2) + GBCE_TB_START_ADDR); } void ipipe_set_ee_regs(void *__iomem base_addr, void *__iomem isp5_base_addr, struct vpfe_ipipe_yee *ee) { unsigned int count; u32 val; ipipe_clock_enable(base_addr); regw_ip(base_addr, ee->en, YEE_EN); if (!ee->en) return; val = ee->en_halo_red & 1; val |= ee->merge_meth << YEE_HALO_RED_EN_SHIFT; regw_ip(base_addr, val, YEE_TYP); regw_ip(base_addr, ee->hpf_shft, YEE_SHF); regw_ip(base_addr, ee->hpf_coef_00 & YEE_COEF_MASK, YEE_MUL_00); regw_ip(base_addr, ee->hpf_coef_01 & YEE_COEF_MASK, YEE_MUL_01); regw_ip(base_addr, ee->hpf_coef_02 & YEE_COEF_MASK, YEE_MUL_02); regw_ip(base_addr, ee->hpf_coef_10 & YEE_COEF_MASK, YEE_MUL_10); regw_ip(base_addr, ee->hpf_coef_11 & YEE_COEF_MASK, YEE_MUL_11); regw_ip(base_addr, ee->hpf_coef_12 & YEE_COEF_MASK, YEE_MUL_12); regw_ip(base_addr, ee->hpf_coef_20 & YEE_COEF_MASK, YEE_MUL_20); regw_ip(base_addr, ee->hpf_coef_21 & YEE_COEF_MASK, YEE_MUL_21); regw_ip(base_addr, ee->hpf_coef_22 & YEE_COEF_MASK, YEE_MUL_22); regw_ip(base_addr, ee->yee_thr & YEE_THR_MASK, YEE_THR); regw_ip(base_addr, ee->es_gain & YEE_ES_GAIN_MASK, YEE_E_GAN); regw_ip(base_addr, ee->es_thr1 & YEE_ES_THR1_MASK, YEE_E_THR1); regw_ip(base_addr, ee->es_thr2 & YEE_THR_MASK, YEE_E_THR2); regw_ip(base_addr, ee->es_gain_grad & YEE_THR_MASK, YEE_G_GAN); regw_ip(base_addr, ee->es_ofst_grad & YEE_THR_MASK, YEE_G_OFT); if (ee->table == NULL) return; for (count = 0; count < VPFE_IPIPE_MAX_SIZE_YEE_LUT; count += 2) w_ip_table(isp5_base_addr, ((ee->table[count + 1] & YEE_ENTRY_MASK) << YEE_ENTRY_SHIFT) | (ee->table[count] & YEE_ENTRY_MASK), ((count/2) << 2) + YEE_TB_START_ADDR); } /* Chromatic Artifact Correction. CAR */ static void ipipe_set_mf(void *__iomem base_addr) { /* typ to dynamic switch */ regw_ip(base_addr, VPFE_IPIPE_CAR_DYN_SWITCH, CAR_TYP); /* Set SW0 to maximum */ regw_ip(base_addr, CAR_MF_THR, CAR_SW); } static void ipipe_set_gain_ctrl(void *__iomem base_addr, struct vpfe_ipipe_car *car) { regw_ip(base_addr, VPFE_IPIPE_CAR_CHR_GAIN_CTRL, CAR_TYP); regw_ip(base_addr, car->hpf, CAR_HPF_TYP); regw_ip(base_addr, car->hpf_shft & CAR_HPF_SHIFT_MASK, CAR_HPF_SHF); regw_ip(base_addr, car->hpf_thr, CAR_HPF_THR); regw_ip(base_addr, car->gain1.gain, CAR_GN1_GAN); regw_ip(base_addr, car->gain1.shft & CAR_GAIN1_SHFT_MASK, CAR_GN1_SHF); regw_ip(base_addr, car->gain1.gain_min & CAR_GAIN_MIN_MASK, CAR_GN1_MIN); regw_ip(base_addr, car->gain2.gain, CAR_GN2_GAN); regw_ip(base_addr, car->gain2.shft & CAR_GAIN2_SHFT_MASK, CAR_GN2_SHF); regw_ip(base_addr, car->gain2.gain_min & CAR_GAIN_MIN_MASK, CAR_GN2_MIN); } void ipipe_set_car_regs(void *__iomem base_addr, struct vpfe_ipipe_car *car) { u32 val; ipipe_clock_enable(base_addr); regw_ip(base_addr, car->en, CAR_EN); if (!car->en) return; switch (car->meth) { case VPFE_IPIPE_CAR_MED_FLTR: ipipe_set_mf(base_addr); break; case VPFE_IPIPE_CAR_CHR_GAIN_CTRL: ipipe_set_gain_ctrl(base_addr, car); break; default: /* Dynamic switch between MF and Gain Ctrl. */ ipipe_set_mf(base_addr); ipipe_set_gain_ctrl(base_addr, car); /* Set the threshold for switching between * the two Here we overwrite the MF SW0 value */ regw_ip(base_addr, VPFE_IPIPE_CAR_DYN_SWITCH, CAR_TYP); val = car->sw1; val <<= CAR_SW1_SHIFT; val |= car->sw0; regw_ip(base_addr, val, CAR_SW); } } /* Chromatic Gain Suppression */ void ipipe_set_cgs_regs(void *__iomem base_addr, struct vpfe_ipipe_cgs *cgs) { ipipe_clock_enable(base_addr); regw_ip(base_addr, cgs->en, CGS_EN); if (!cgs->en) return; /* Set the bright side parameters */ regw_ip(base_addr, cgs->h_thr, CGS_GN1_H_THR); regw_ip(base_addr, cgs->h_slope, CGS_GN1_H_GAN); regw_ip(base_addr, cgs->h_shft & CAR_SHIFT_MASK, CGS_GN1_H_SHF); regw_ip(base_addr, cgs->h_min, CGS_GN1_H_MIN); } void rsz_src_enable(void *__iomem rsz_base, int enable) { regw_rsz(rsz_base, enable, RSZ_SRC_EN); } int rsz_enable(void *__iomem rsz_base, int rsz_id, int enable) { if (rsz_id == RSZ_A) { regw_rsz(rsz_base, enable, RSZ_EN_A); /* We always enable RSZ_A. RSZ_B is enable upon request from * application. So enable RSZ_SRC_EN along with RSZ_A */ regw_rsz(rsz_base, enable, RSZ_SRC_EN); } else if (rsz_id == RSZ_B) { regw_rsz(rsz_base, enable, RSZ_EN_B); } else { BUG(); } return 0; }