Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Jeykumar Sankaran | 3613 | 87.80% | 1 | 4.76% |
Dmitry Eremin-Solenikov | 352 | 8.55% | 7 | 33.33% |
Jonathan Marek | 67 | 1.63% | 1 | 4.76% |
Rob Clark | 45 | 1.09% | 2 | 9.52% |
Shubhashree Dhar | 11 | 0.27% | 1 | 4.76% |
Jessica Zhang | 8 | 0.19% | 1 | 4.76% |
Jordan Crouse | 7 | 0.17% | 1 | 4.76% |
Stephen Boyd | 2 | 0.05% | 1 | 4.76% |
Thomas Gleixner | 2 | 0.05% | 1 | 4.76% |
Daniel Vetter | 2 | 0.05% | 1 | 4.76% |
Lee Jones | 2 | 0.05% | 1 | 4.76% |
Archit Taneja | 2 | 0.05% | 1 | 4.76% |
Sam Ravnborg | 1 | 0.02% | 1 | 4.76% |
Abhinav Kumar | 1 | 0.02% | 1 | 4.76% |
Total | 4115 | 21 |
// SPDX-License-Identifier: GPL-2.0-only /* Copyright (c) 2015-2018, The Linux Foundation. All rights reserved. */ #include "dpu_hwio.h" #include "dpu_hw_catalog.h" #include "dpu_hw_lm.h" #include "dpu_hw_sspp.h" #include "dpu_kms.h" #include <drm/drm_file.h> #define DPU_FETCH_CONFIG_RESET_VALUE 0x00000087 /* DPU_SSPP_SRC */ #define SSPP_SRC_SIZE 0x00 #define SSPP_SRC_XY 0x08 #define SSPP_OUT_SIZE 0x0c #define SSPP_OUT_XY 0x10 #define SSPP_SRC0_ADDR 0x14 #define SSPP_SRC1_ADDR 0x18 #define SSPP_SRC2_ADDR 0x1C #define SSPP_SRC3_ADDR 0x20 #define SSPP_SRC_YSTRIDE0 0x24 #define SSPP_SRC_YSTRIDE1 0x28 #define SSPP_SRC_FORMAT 0x30 #define SSPP_SRC_UNPACK_PATTERN 0x34 #define SSPP_SRC_OP_MODE 0x38 /* SSPP_MULTIRECT*/ #define SSPP_SRC_SIZE_REC1 0x16C #define SSPP_SRC_XY_REC1 0x168 #define SSPP_OUT_SIZE_REC1 0x160 #define SSPP_OUT_XY_REC1 0x164 #define SSPP_SRC_FORMAT_REC1 0x174 #define SSPP_SRC_UNPACK_PATTERN_REC1 0x178 #define SSPP_SRC_OP_MODE_REC1 0x17C #define SSPP_MULTIRECT_OPMODE 0x170 #define SSPP_SRC_CONSTANT_COLOR_REC1 0x180 #define SSPP_EXCL_REC_SIZE_REC1 0x184 #define SSPP_EXCL_REC_XY_REC1 0x188 #define MDSS_MDP_OP_DEINTERLACE BIT(22) #define MDSS_MDP_OP_DEINTERLACE_ODD BIT(23) #define MDSS_MDP_OP_IGC_ROM_1 BIT(18) #define MDSS_MDP_OP_IGC_ROM_0 BIT(17) #define MDSS_MDP_OP_IGC_EN BIT(16) #define MDSS_MDP_OP_FLIP_UD BIT(14) #define MDSS_MDP_OP_FLIP_LR BIT(13) #define MDSS_MDP_OP_BWC_EN BIT(0) #define MDSS_MDP_OP_PE_OVERRIDE BIT(31) #define MDSS_MDP_OP_BWC_LOSSLESS (0 << 1) #define MDSS_MDP_OP_BWC_Q_HIGH (1 << 1) #define MDSS_MDP_OP_BWC_Q_MED (2 << 1) #define SSPP_SRC_CONSTANT_COLOR 0x3c #define SSPP_EXCL_REC_CTL 0x40 #define SSPP_UBWC_STATIC_CTRL 0x44 #define SSPP_FETCH_CONFIG 0x048 #define SSPP_DANGER_LUT 0x60 #define SSPP_SAFE_LUT 0x64 #define SSPP_CREQ_LUT 0x68 #define SSPP_QOS_CTRL 0x6C #define SSPP_DECIMATION_CONFIG 0xB4 #define SSPP_SRC_ADDR_SW_STATUS 0x70 #define SSPP_CREQ_LUT_0 0x74 #define SSPP_CREQ_LUT_1 0x78 #define SSPP_SW_PIX_EXT_C0_LR 0x100 #define SSPP_SW_PIX_EXT_C0_TB 0x104 #define SSPP_SW_PIX_EXT_C0_REQ_PIXELS 0x108 #define SSPP_SW_PIX_EXT_C1C2_LR 0x110 #define SSPP_SW_PIX_EXT_C1C2_TB 0x114 #define SSPP_SW_PIX_EXT_C1C2_REQ_PIXELS 0x118 #define SSPP_SW_PIX_EXT_C3_LR 0x120 #define SSPP_SW_PIX_EXT_C3_TB 0x124 #define SSPP_SW_PIX_EXT_C3_REQ_PIXELS 0x128 #define SSPP_TRAFFIC_SHAPER 0x130 #define SSPP_CDP_CNTL 0x134 #define SSPP_UBWC_ERROR_STATUS 0x138 #define SSPP_CDP_CNTL_REC1 0x13c #define SSPP_TRAFFIC_SHAPER_PREFILL 0x150 #define SSPP_TRAFFIC_SHAPER_REC1_PREFILL 0x154 #define SSPP_TRAFFIC_SHAPER_REC1 0x158 #define SSPP_EXCL_REC_SIZE 0x1B4 #define SSPP_EXCL_REC_XY 0x1B8 #define SSPP_VIG_OP_MODE 0x0 #define SSPP_VIG_CSC_10_OP_MODE 0x0 #define SSPP_TRAFFIC_SHAPER_BPC_MAX 0xFF /* SSPP_QOS_CTRL */ #define SSPP_QOS_CTRL_VBLANK_EN BIT(16) #define SSPP_QOS_CTRL_DANGER_SAFE_EN BIT(0) #define SSPP_QOS_CTRL_DANGER_VBLANK_MASK 0x3 #define SSPP_QOS_CTRL_DANGER_VBLANK_OFF 4 #define SSPP_QOS_CTRL_CREQ_VBLANK_MASK 0x3 #define SSPP_QOS_CTRL_CREQ_VBLANK_OFF 20 /* DPU_SSPP_SCALER_QSEED2 */ #define SCALE_CONFIG 0x04 #define COMP0_3_PHASE_STEP_X 0x10 #define COMP0_3_PHASE_STEP_Y 0x14 #define COMP1_2_PHASE_STEP_X 0x18 #define COMP1_2_PHASE_STEP_Y 0x1c #define COMP0_3_INIT_PHASE_X 0x20 #define COMP0_3_INIT_PHASE_Y 0x24 #define COMP1_2_INIT_PHASE_X 0x28 #define COMP1_2_INIT_PHASE_Y 0x2C #define VIG_0_QSEED2_SHARP 0x30 /* * Definitions for ViG op modes */ #define VIG_OP_CSC_DST_DATAFMT BIT(19) #define VIG_OP_CSC_SRC_DATAFMT BIT(18) #define VIG_OP_CSC_EN BIT(17) #define VIG_OP_MEM_PROT_CONT BIT(15) #define VIG_OP_MEM_PROT_VAL BIT(14) #define VIG_OP_MEM_PROT_SAT BIT(13) #define VIG_OP_MEM_PROT_HUE BIT(12) #define VIG_OP_HIST BIT(8) #define VIG_OP_SKY_COL BIT(7) #define VIG_OP_FOIL BIT(6) #define VIG_OP_SKIN_COL BIT(5) #define VIG_OP_PA_EN BIT(4) #define VIG_OP_PA_SAT_ZERO_EXP BIT(2) #define VIG_OP_MEM_PROT_BLEND BIT(1) /* * Definitions for CSC 10 op modes */ #define VIG_CSC_10_SRC_DATAFMT BIT(1) #define VIG_CSC_10_EN BIT(0) #define CSC_10BIT_OFFSET 4 /* traffic shaper clock in Hz */ #define TS_CLK 19200000 static int _sspp_subblk_offset(struct dpu_hw_pipe *ctx, int s_id, u32 *idx) { int rc = 0; const struct dpu_sspp_sub_blks *sblk; if (!ctx || !ctx->cap || !ctx->cap->sblk) return -EINVAL; sblk = ctx->cap->sblk; switch (s_id) { case DPU_SSPP_SRC: *idx = sblk->src_blk.base; break; case DPU_SSPP_SCALER_QSEED2: case DPU_SSPP_SCALER_QSEED3: case DPU_SSPP_SCALER_RGB: *idx = sblk->scaler_blk.base; break; case DPU_SSPP_CSC: case DPU_SSPP_CSC_10BIT: *idx = sblk->csc_blk.base; break; default: rc = -EINVAL; } return rc; } static void dpu_hw_sspp_setup_multirect(struct dpu_hw_pipe *ctx, enum dpu_sspp_multirect_index index, enum dpu_sspp_multirect_mode mode) { u32 mode_mask; u32 idx; if (_sspp_subblk_offset(ctx, DPU_SSPP_SRC, &idx)) return; if (index == DPU_SSPP_RECT_SOLO) { /** * if rect index is RECT_SOLO, we cannot expect a * virtual plane sharing the same SSPP id. So we go * and disable multirect */ mode_mask = 0; } else { mode_mask = DPU_REG_READ(&ctx->hw, SSPP_MULTIRECT_OPMODE + idx); mode_mask |= index; if (mode == DPU_SSPP_MULTIRECT_TIME_MX) mode_mask |= BIT(2); else mode_mask &= ~BIT(2); } DPU_REG_WRITE(&ctx->hw, SSPP_MULTIRECT_OPMODE + idx, mode_mask); } static void _sspp_setup_opmode(struct dpu_hw_pipe *ctx, u32 mask, u8 en) { u32 idx; u32 opmode; if (!test_bit(DPU_SSPP_SCALER_QSEED2, &ctx->cap->features) || _sspp_subblk_offset(ctx, DPU_SSPP_SCALER_QSEED2, &idx) || !test_bit(DPU_SSPP_CSC, &ctx->cap->features)) return; opmode = DPU_REG_READ(&ctx->hw, SSPP_VIG_OP_MODE + idx); if (en) opmode |= mask; else opmode &= ~mask; DPU_REG_WRITE(&ctx->hw, SSPP_VIG_OP_MODE + idx, opmode); } static void _sspp_setup_csc10_opmode(struct dpu_hw_pipe *ctx, u32 mask, u8 en) { u32 idx; u32 opmode; if (_sspp_subblk_offset(ctx, DPU_SSPP_CSC_10BIT, &idx)) return; opmode = DPU_REG_READ(&ctx->hw, SSPP_VIG_CSC_10_OP_MODE + idx); if (en) opmode |= mask; else opmode &= ~mask; DPU_REG_WRITE(&ctx->hw, SSPP_VIG_CSC_10_OP_MODE + idx, opmode); } /* * Setup source pixel format, flip, */ static void dpu_hw_sspp_setup_format(struct dpu_hw_pipe *ctx, const struct dpu_format *fmt, u32 flags, enum dpu_sspp_multirect_index rect_mode) { struct dpu_hw_blk_reg_map *c; u32 chroma_samp, unpack, src_format; u32 opmode = 0; u32 fast_clear = 0; u32 op_mode_off, unpack_pat_off, format_off; u32 idx; if (_sspp_subblk_offset(ctx, DPU_SSPP_SRC, &idx) || !fmt) return; if (rect_mode == DPU_SSPP_RECT_SOLO || rect_mode == DPU_SSPP_RECT_0) { op_mode_off = SSPP_SRC_OP_MODE; unpack_pat_off = SSPP_SRC_UNPACK_PATTERN; format_off = SSPP_SRC_FORMAT; } else { op_mode_off = SSPP_SRC_OP_MODE_REC1; unpack_pat_off = SSPP_SRC_UNPACK_PATTERN_REC1; format_off = SSPP_SRC_FORMAT_REC1; } c = &ctx->hw; opmode = DPU_REG_READ(c, op_mode_off + idx); opmode &= ~(MDSS_MDP_OP_FLIP_LR | MDSS_MDP_OP_FLIP_UD | MDSS_MDP_OP_BWC_EN | MDSS_MDP_OP_PE_OVERRIDE); if (flags & DPU_SSPP_FLIP_LR) opmode |= MDSS_MDP_OP_FLIP_LR; if (flags & DPU_SSPP_FLIP_UD) opmode |= MDSS_MDP_OP_FLIP_UD; chroma_samp = fmt->chroma_sample; if (flags & DPU_SSPP_SOURCE_ROTATED_90) { if (chroma_samp == DPU_CHROMA_H2V1) chroma_samp = DPU_CHROMA_H1V2; else if (chroma_samp == DPU_CHROMA_H1V2) chroma_samp = DPU_CHROMA_H2V1; } src_format = (chroma_samp << 23) | (fmt->fetch_planes << 19) | (fmt->bits[C3_ALPHA] << 6) | (fmt->bits[C2_R_Cr] << 4) | (fmt->bits[C1_B_Cb] << 2) | (fmt->bits[C0_G_Y] << 0); if (flags & DPU_SSPP_ROT_90) src_format |= BIT(11); /* ROT90 */ if (fmt->alpha_enable && fmt->fetch_planes == DPU_PLANE_INTERLEAVED) src_format |= BIT(8); /* SRCC3_EN */ if (flags & DPU_SSPP_SOLID_FILL) src_format |= BIT(22); unpack = (fmt->element[3] << 24) | (fmt->element[2] << 16) | (fmt->element[1] << 8) | (fmt->element[0] << 0); src_format |= ((fmt->unpack_count - 1) << 12) | (fmt->unpack_tight << 17) | (fmt->unpack_align_msb << 18) | ((fmt->bpp - 1) << 9); if (fmt->fetch_mode != DPU_FETCH_LINEAR) { if (DPU_FORMAT_IS_UBWC(fmt)) opmode |= MDSS_MDP_OP_BWC_EN; src_format |= (fmt->fetch_mode & 3) << 30; /*FRAME_FORMAT */ DPU_REG_WRITE(c, SSPP_FETCH_CONFIG, DPU_FETCH_CONFIG_RESET_VALUE | ctx->mdp->highest_bank_bit << 18); switch (ctx->catalog->caps->ubwc_version) { case DPU_HW_UBWC_VER_10: /* TODO: UBWC v1 case */ break; case DPU_HW_UBWC_VER_20: fast_clear = fmt->alpha_enable ? BIT(31) : 0; DPU_REG_WRITE(c, SSPP_UBWC_STATIC_CTRL, fast_clear | (ctx->mdp->ubwc_swizzle) | (ctx->mdp->highest_bank_bit << 4)); break; case DPU_HW_UBWC_VER_30: DPU_REG_WRITE(c, SSPP_UBWC_STATIC_CTRL, BIT(30) | (ctx->mdp->ubwc_swizzle) | (ctx->mdp->highest_bank_bit << 4)); break; case DPU_HW_UBWC_VER_40: DPU_REG_WRITE(c, SSPP_UBWC_STATIC_CTRL, DPU_FORMAT_IS_YUV(fmt) ? 0 : BIT(30)); break; } } opmode |= MDSS_MDP_OP_PE_OVERRIDE; /* if this is YUV pixel format, enable CSC */ if (DPU_FORMAT_IS_YUV(fmt)) src_format |= BIT(15); if (DPU_FORMAT_IS_DX(fmt)) src_format |= BIT(14); /* update scaler opmode, if appropriate */ if (test_bit(DPU_SSPP_CSC, &ctx->cap->features)) _sspp_setup_opmode(ctx, VIG_OP_CSC_EN | VIG_OP_CSC_SRC_DATAFMT, DPU_FORMAT_IS_YUV(fmt)); else if (test_bit(DPU_SSPP_CSC_10BIT, &ctx->cap->features)) _sspp_setup_csc10_opmode(ctx, VIG_CSC_10_EN | VIG_CSC_10_SRC_DATAFMT, DPU_FORMAT_IS_YUV(fmt)); DPU_REG_WRITE(c, format_off + idx, src_format); DPU_REG_WRITE(c, unpack_pat_off + idx, unpack); DPU_REG_WRITE(c, op_mode_off + idx, opmode); /* clear previous UBWC error */ DPU_REG_WRITE(c, SSPP_UBWC_ERROR_STATUS + idx, BIT(31)); } static void dpu_hw_sspp_setup_pe_config(struct dpu_hw_pipe *ctx, struct dpu_hw_pixel_ext *pe_ext) { struct dpu_hw_blk_reg_map *c; u8 color; u32 lr_pe[4], tb_pe[4], tot_req_pixels[4]; const u32 bytemask = 0xff; const u32 shortmask = 0xffff; u32 idx; if (_sspp_subblk_offset(ctx, DPU_SSPP_SRC, &idx) || !pe_ext) return; c = &ctx->hw; /* program SW pixel extension override for all pipes*/ for (color = 0; color < DPU_MAX_PLANES; color++) { /* color 2 has the same set of registers as color 1 */ if (color == 2) continue; lr_pe[color] = ((pe_ext->right_ftch[color] & bytemask) << 24)| ((pe_ext->right_rpt[color] & bytemask) << 16)| ((pe_ext->left_ftch[color] & bytemask) << 8)| (pe_ext->left_rpt[color] & bytemask); tb_pe[color] = ((pe_ext->btm_ftch[color] & bytemask) << 24)| ((pe_ext->btm_rpt[color] & bytemask) << 16)| ((pe_ext->top_ftch[color] & bytemask) << 8)| (pe_ext->top_rpt[color] & bytemask); tot_req_pixels[color] = (((pe_ext->roi_h[color] + pe_ext->num_ext_pxls_top[color] + pe_ext->num_ext_pxls_btm[color]) & shortmask) << 16) | ((pe_ext->roi_w[color] + pe_ext->num_ext_pxls_left[color] + pe_ext->num_ext_pxls_right[color]) & shortmask); } /* color 0 */ DPU_REG_WRITE(c, SSPP_SW_PIX_EXT_C0_LR + idx, lr_pe[0]); DPU_REG_WRITE(c, SSPP_SW_PIX_EXT_C0_TB + idx, tb_pe[0]); DPU_REG_WRITE(c, SSPP_SW_PIX_EXT_C0_REQ_PIXELS + idx, tot_req_pixels[0]); /* color 1 and color 2 */ DPU_REG_WRITE(c, SSPP_SW_PIX_EXT_C1C2_LR + idx, lr_pe[1]); DPU_REG_WRITE(c, SSPP_SW_PIX_EXT_C1C2_TB + idx, tb_pe[1]); DPU_REG_WRITE(c, SSPP_SW_PIX_EXT_C1C2_REQ_PIXELS + idx, tot_req_pixels[1]); /* color 3 */ DPU_REG_WRITE(c, SSPP_SW_PIX_EXT_C3_LR + idx, lr_pe[3]); DPU_REG_WRITE(c, SSPP_SW_PIX_EXT_C3_TB + idx, lr_pe[3]); DPU_REG_WRITE(c, SSPP_SW_PIX_EXT_C3_REQ_PIXELS + idx, tot_req_pixels[3]); } static void _dpu_hw_sspp_setup_scaler3(struct dpu_hw_pipe *ctx, struct dpu_hw_pipe_cfg *sspp, void *scaler_cfg) { u32 idx; struct dpu_hw_scaler3_cfg *scaler3_cfg = scaler_cfg; if (_sspp_subblk_offset(ctx, DPU_SSPP_SCALER_QSEED3, &idx) || !sspp || !scaler3_cfg) return; dpu_hw_setup_scaler3(&ctx->hw, scaler3_cfg, idx, ctx->cap->sblk->scaler_blk.version, sspp->layout.format); } static u32 _dpu_hw_sspp_get_scaler3_ver(struct dpu_hw_pipe *ctx) { u32 idx; if (!ctx || _sspp_subblk_offset(ctx, DPU_SSPP_SCALER_QSEED3, &idx)) return 0; return dpu_hw_get_scaler3_ver(&ctx->hw, idx); } /* * dpu_hw_sspp_setup_rects() */ static void dpu_hw_sspp_setup_rects(struct dpu_hw_pipe *ctx, struct dpu_hw_pipe_cfg *cfg, enum dpu_sspp_multirect_index rect_index) { struct dpu_hw_blk_reg_map *c; u32 src_size, src_xy, dst_size, dst_xy, ystride0, ystride1; u32 src_size_off, src_xy_off, out_size_off, out_xy_off; u32 idx; if (_sspp_subblk_offset(ctx, DPU_SSPP_SRC, &idx) || !cfg) return; c = &ctx->hw; if (rect_index == DPU_SSPP_RECT_SOLO || rect_index == DPU_SSPP_RECT_0) { src_size_off = SSPP_SRC_SIZE; src_xy_off = SSPP_SRC_XY; out_size_off = SSPP_OUT_SIZE; out_xy_off = SSPP_OUT_XY; } else { src_size_off = SSPP_SRC_SIZE_REC1; src_xy_off = SSPP_SRC_XY_REC1; out_size_off = SSPP_OUT_SIZE_REC1; out_xy_off = SSPP_OUT_XY_REC1; } /* src and dest rect programming */ src_xy = (cfg->src_rect.y1 << 16) | cfg->src_rect.x1; src_size = (drm_rect_height(&cfg->src_rect) << 16) | drm_rect_width(&cfg->src_rect); dst_xy = (cfg->dst_rect.y1 << 16) | cfg->dst_rect.x1; dst_size = (drm_rect_height(&cfg->dst_rect) << 16) | drm_rect_width(&cfg->dst_rect); if (rect_index == DPU_SSPP_RECT_SOLO) { ystride0 = (cfg->layout.plane_pitch[0]) | (cfg->layout.plane_pitch[1] << 16); ystride1 = (cfg->layout.plane_pitch[2]) | (cfg->layout.plane_pitch[3] << 16); } else { ystride0 = DPU_REG_READ(c, SSPP_SRC_YSTRIDE0 + idx); ystride1 = DPU_REG_READ(c, SSPP_SRC_YSTRIDE1 + idx); if (rect_index == DPU_SSPP_RECT_0) { ystride0 = (ystride0 & 0xFFFF0000) | (cfg->layout.plane_pitch[0] & 0x0000FFFF); ystride1 = (ystride1 & 0xFFFF0000)| (cfg->layout.plane_pitch[2] & 0x0000FFFF); } else { ystride0 = (ystride0 & 0x0000FFFF) | ((cfg->layout.plane_pitch[0] << 16) & 0xFFFF0000); ystride1 = (ystride1 & 0x0000FFFF) | ((cfg->layout.plane_pitch[2] << 16) & 0xFFFF0000); } } /* rectangle register programming */ DPU_REG_WRITE(c, src_size_off + idx, src_size); DPU_REG_WRITE(c, src_xy_off + idx, src_xy); DPU_REG_WRITE(c, out_size_off + idx, dst_size); DPU_REG_WRITE(c, out_xy_off + idx, dst_xy); DPU_REG_WRITE(c, SSPP_SRC_YSTRIDE0 + idx, ystride0); DPU_REG_WRITE(c, SSPP_SRC_YSTRIDE1 + idx, ystride1); } static void dpu_hw_sspp_setup_sourceaddress(struct dpu_hw_pipe *ctx, struct dpu_hw_pipe_cfg *cfg, enum dpu_sspp_multirect_index rect_mode) { int i; u32 idx; if (_sspp_subblk_offset(ctx, DPU_SSPP_SRC, &idx)) return; if (rect_mode == DPU_SSPP_RECT_SOLO) { for (i = 0; i < ARRAY_SIZE(cfg->layout.plane_addr); i++) DPU_REG_WRITE(&ctx->hw, SSPP_SRC0_ADDR + idx + i * 0x4, cfg->layout.plane_addr[i]); } else if (rect_mode == DPU_SSPP_RECT_0) { DPU_REG_WRITE(&ctx->hw, SSPP_SRC0_ADDR + idx, cfg->layout.plane_addr[0]); DPU_REG_WRITE(&ctx->hw, SSPP_SRC2_ADDR + idx, cfg->layout.plane_addr[2]); } else { DPU_REG_WRITE(&ctx->hw, SSPP_SRC1_ADDR + idx, cfg->layout.plane_addr[0]); DPU_REG_WRITE(&ctx->hw, SSPP_SRC3_ADDR + idx, cfg->layout.plane_addr[2]); } } static void dpu_hw_sspp_setup_csc(struct dpu_hw_pipe *ctx, const struct dpu_csc_cfg *data) { u32 idx; bool csc10 = false; if (_sspp_subblk_offset(ctx, DPU_SSPP_CSC, &idx) || !data) return; if (test_bit(DPU_SSPP_CSC_10BIT, &ctx->cap->features)) { idx += CSC_10BIT_OFFSET; csc10 = true; } dpu_hw_csc_setup(&ctx->hw, idx, data, csc10); } static void dpu_hw_sspp_setup_solidfill(struct dpu_hw_pipe *ctx, u32 color, enum dpu_sspp_multirect_index rect_index) { u32 idx; if (_sspp_subblk_offset(ctx, DPU_SSPP_SRC, &idx)) return; if (rect_index == DPU_SSPP_RECT_SOLO || rect_index == DPU_SSPP_RECT_0) DPU_REG_WRITE(&ctx->hw, SSPP_SRC_CONSTANT_COLOR + idx, color); else DPU_REG_WRITE(&ctx->hw, SSPP_SRC_CONSTANT_COLOR_REC1 + idx, color); } static void dpu_hw_sspp_setup_danger_safe_lut(struct dpu_hw_pipe *ctx, u32 danger_lut, u32 safe_lut) { u32 idx; if (_sspp_subblk_offset(ctx, DPU_SSPP_SRC, &idx)) return; DPU_REG_WRITE(&ctx->hw, SSPP_DANGER_LUT + idx, danger_lut); DPU_REG_WRITE(&ctx->hw, SSPP_SAFE_LUT + idx, safe_lut); } static void dpu_hw_sspp_setup_creq_lut(struct dpu_hw_pipe *ctx, u64 creq_lut) { u32 idx; if (_sspp_subblk_offset(ctx, DPU_SSPP_SRC, &idx)) return; if (ctx->cap && test_bit(DPU_SSPP_QOS_8LVL, &ctx->cap->features)) { DPU_REG_WRITE(&ctx->hw, SSPP_CREQ_LUT_0 + idx, creq_lut); DPU_REG_WRITE(&ctx->hw, SSPP_CREQ_LUT_1 + idx, creq_lut >> 32); } else { DPU_REG_WRITE(&ctx->hw, SSPP_CREQ_LUT + idx, creq_lut); } } static void dpu_hw_sspp_setup_qos_ctrl(struct dpu_hw_pipe *ctx, struct dpu_hw_pipe_qos_cfg *cfg) { u32 idx; u32 qos_ctrl = 0; if (_sspp_subblk_offset(ctx, DPU_SSPP_SRC, &idx)) return; if (cfg->vblank_en) { qos_ctrl |= ((cfg->creq_vblank & SSPP_QOS_CTRL_CREQ_VBLANK_MASK) << SSPP_QOS_CTRL_CREQ_VBLANK_OFF); qos_ctrl |= ((cfg->danger_vblank & SSPP_QOS_CTRL_DANGER_VBLANK_MASK) << SSPP_QOS_CTRL_DANGER_VBLANK_OFF); qos_ctrl |= SSPP_QOS_CTRL_VBLANK_EN; } if (cfg->danger_safe_en) qos_ctrl |= SSPP_QOS_CTRL_DANGER_SAFE_EN; DPU_REG_WRITE(&ctx->hw, SSPP_QOS_CTRL + idx, qos_ctrl); } static void dpu_hw_sspp_setup_cdp(struct dpu_hw_pipe *ctx, struct dpu_hw_cdp_cfg *cfg, enum dpu_sspp_multirect_index index) { u32 idx; u32 cdp_cntl = 0; u32 cdp_cntl_offset = 0; if (!ctx || !cfg) return; if (_sspp_subblk_offset(ctx, DPU_SSPP_SRC, &idx)) return; if (index == DPU_SSPP_RECT_SOLO || index == DPU_SSPP_RECT_0) cdp_cntl_offset = SSPP_CDP_CNTL; else cdp_cntl_offset = SSPP_CDP_CNTL_REC1; if (cfg->enable) cdp_cntl |= BIT(0); if (cfg->ubwc_meta_enable) cdp_cntl |= BIT(1); if (cfg->tile_amortize_enable) cdp_cntl |= BIT(2); if (cfg->preload_ahead == DPU_SSPP_CDP_PRELOAD_AHEAD_64) cdp_cntl |= BIT(3); DPU_REG_WRITE(&ctx->hw, cdp_cntl_offset, cdp_cntl); } static void _setup_layer_ops(struct dpu_hw_pipe *c, unsigned long features) { if (test_bit(DPU_SSPP_SRC, &features)) { c->ops.setup_format = dpu_hw_sspp_setup_format; c->ops.setup_rects = dpu_hw_sspp_setup_rects; c->ops.setup_sourceaddress = dpu_hw_sspp_setup_sourceaddress; c->ops.setup_solidfill = dpu_hw_sspp_setup_solidfill; c->ops.setup_pe = dpu_hw_sspp_setup_pe_config; } if (test_bit(DPU_SSPP_QOS, &features)) { c->ops.setup_danger_safe_lut = dpu_hw_sspp_setup_danger_safe_lut; c->ops.setup_creq_lut = dpu_hw_sspp_setup_creq_lut; c->ops.setup_qos_ctrl = dpu_hw_sspp_setup_qos_ctrl; } if (test_bit(DPU_SSPP_CSC, &features) || test_bit(DPU_SSPP_CSC_10BIT, &features)) c->ops.setup_csc = dpu_hw_sspp_setup_csc; if (test_bit(DPU_SSPP_SMART_DMA_V1, &c->cap->features) || test_bit(DPU_SSPP_SMART_DMA_V2, &c->cap->features)) c->ops.setup_multirect = dpu_hw_sspp_setup_multirect; if (test_bit(DPU_SSPP_SCALER_QSEED3, &features) || test_bit(DPU_SSPP_SCALER_QSEED3LITE, &features) || test_bit(DPU_SSPP_SCALER_QSEED4, &features)) { c->ops.setup_scaler = _dpu_hw_sspp_setup_scaler3; c->ops.get_scaler_ver = _dpu_hw_sspp_get_scaler3_ver; } if (test_bit(DPU_SSPP_CDP, &features)) c->ops.setup_cdp = dpu_hw_sspp_setup_cdp; } #ifdef CONFIG_DEBUG_FS int _dpu_hw_sspp_init_debugfs(struct dpu_hw_pipe *hw_pipe, struct dpu_kms *kms, struct dentry *entry) { const struct dpu_sspp_cfg *cfg = hw_pipe->cap; const struct dpu_sspp_sub_blks *sblk = cfg->sblk; struct dentry *debugfs_root; char sspp_name[32]; snprintf(sspp_name, sizeof(sspp_name), "%d", hw_pipe->idx); /* create overall sub-directory for the pipe */ debugfs_root = debugfs_create_dir(sspp_name, entry); /* don't error check these */ debugfs_create_xul("features", 0600, debugfs_root, (unsigned long *)&hw_pipe->cap->features); /* add register dump support */ dpu_debugfs_create_regset32("src_blk", 0400, debugfs_root, sblk->src_blk.base + cfg->base, sblk->src_blk.len, kms); if (cfg->features & BIT(DPU_SSPP_SCALER_QSEED3) || cfg->features & BIT(DPU_SSPP_SCALER_QSEED3LITE) || cfg->features & BIT(DPU_SSPP_SCALER_QSEED2) || cfg->features & BIT(DPU_SSPP_SCALER_QSEED4)) dpu_debugfs_create_regset32("scaler_blk", 0400, debugfs_root, sblk->scaler_blk.base + cfg->base, sblk->scaler_blk.len, kms); if (cfg->features & BIT(DPU_SSPP_CSC) || cfg->features & BIT(DPU_SSPP_CSC_10BIT)) dpu_debugfs_create_regset32("csc_blk", 0400, debugfs_root, sblk->csc_blk.base + cfg->base, sblk->csc_blk.len, kms); debugfs_create_u32("xin_id", 0400, debugfs_root, (u32 *) &cfg->xin_id); debugfs_create_u32("clk_ctrl", 0400, debugfs_root, (u32 *) &cfg->clk_ctrl); debugfs_create_x32("creq_vblank", 0600, debugfs_root, (u32 *) &sblk->creq_vblank); debugfs_create_x32("danger_vblank", 0600, debugfs_root, (u32 *) &sblk->danger_vblank); return 0; } #endif static const struct dpu_sspp_cfg *_sspp_offset(enum dpu_sspp sspp, void __iomem *addr, const struct dpu_mdss_cfg *catalog, struct dpu_hw_blk_reg_map *b) { int i; if ((sspp < SSPP_MAX) && catalog && addr && b) { for (i = 0; i < catalog->sspp_count; i++) { if (sspp == catalog->sspp[i].id) { b->blk_addr = addr + catalog->sspp[i].base; b->log_mask = DPU_DBG_MASK_SSPP; return &catalog->sspp[i]; } } } return ERR_PTR(-ENOMEM); } struct dpu_hw_pipe *dpu_hw_sspp_init(enum dpu_sspp idx, void __iomem *addr, const struct dpu_mdss_cfg *catalog) { struct dpu_hw_pipe *hw_pipe; const struct dpu_sspp_cfg *cfg; if (!addr || !catalog) return ERR_PTR(-EINVAL); hw_pipe = kzalloc(sizeof(*hw_pipe), GFP_KERNEL); if (!hw_pipe) return ERR_PTR(-ENOMEM); cfg = _sspp_offset(idx, addr, catalog, &hw_pipe->hw); if (IS_ERR_OR_NULL(cfg)) { kfree(hw_pipe); return ERR_PTR(-EINVAL); } /* Assign ops */ hw_pipe->catalog = catalog; hw_pipe->mdp = &catalog->mdp[0]; hw_pipe->idx = idx; hw_pipe->cap = cfg; _setup_layer_ops(hw_pipe, hw_pipe->cap->features); return hw_pipe; } void dpu_hw_sspp_destroy(struct dpu_hw_pipe *ctx) { kfree(ctx); }
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