Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Tiffany Lin | 2686 | 95.25% | 3 | 16.67% |
Yunfei Dong | 87 | 3.09% | 7 | 38.89% |
Nícolas F. R. A. Prado | 20 | 0.71% | 1 | 5.56% |
Kees Cook | 12 | 0.43% | 1 | 5.56% |
Alexandre Courbot | 11 | 0.39% | 3 | 16.67% |
Sebastian Fricke | 2 | 0.07% | 1 | 5.56% |
Thomas Gleixner | 1 | 0.04% | 1 | 5.56% |
Mauro Carvalho Chehab | 1 | 0.04% | 1 | 5.56% |
Total | 2820 | 18 |
// SPDX-License-Identifier: GPL-2.0 /* * Copyright (c) 2016 MediaTek Inc. * Author: Jungchang Tsao <jungchang.tsao@mediatek.com> * PC Chen <pc.chen@mediatek.com> */ #include <linux/slab.h> #include "../vdec_drv_if.h" #include "../mtk_vcodec_dec.h" #include "../../common/mtk_vcodec_intr.h" #include "../vdec_vpu_if.h" #include "../vdec_drv_base.h" /* Decoding picture buffer size (3 reference frames plus current frame) */ #define VP8_DPB_SIZE 4 /* HW working buffer size (bytes) */ #define VP8_WORKING_BUF_SZ (45 * 4096) /* HW control register address */ #define VP8_SEGID_DRAM_ADDR 0x3c #define VP8_HW_VLD_ADDR 0x93C #define VP8_HW_VLD_VALUE 0x940 #define VP8_BSASET 0x100 #define VP8_BSDSET 0x104 #define VP8_RW_CKEN_SET 0x0 #define VP8_RW_DCM_CON 0x18 #define VP8_WO_VLD_SRST 0x108 #define VP8_RW_MISC_SYS_SEL 0x84 #define VP8_RW_MISC_SPEC_CON 0xC8 #define VP8_WO_VLD_SRST 0x108 #define VP8_RW_VP8_CTRL 0xA4 #define VP8_RW_MISC_DCM_CON 0xEC #define VP8_RW_MISC_SRST 0xF4 #define VP8_RW_MISC_FUNC_CON 0xCC #define VP8_MAX_FRM_BUF_NUM 5 #define VP8_MAX_FRM_BUF_NODE_NUM (VP8_MAX_FRM_BUF_NUM * 2) /* required buffer size (bytes) to store decode information */ #define VP8_HW_SEGMENT_DATA_SZ 272 #define VP8_HW_SEGMENT_UINT 4 #define VP8_DEC_TABLE_PROC_LOOP 96 #define VP8_DEC_TABLE_UNIT 3 #define VP8_DEC_TABLE_SZ 300 #define VP8_DEC_TABLE_OFFSET 2 #define VP8_DEC_TABLE_RW_UNIT 4 /** * struct vdec_vp8_dec_info - decode misc information * @working_buf_dma : working buffer dma address * @prev_y_dma : previous decoded frame buffer Y plane address * @cur_y_fb_dma : current plane Y frame buffer dma address * @cur_c_fb_dma : current plane C frame buffer dma address * @bs_dma : bitstream dma address * @bs_sz : bitstream size * @resolution_changed: resolution change flag 1 - changed, 0 - not changed * @show_frame : display this frame or not * @wait_key_frame : wait key frame coming */ struct vdec_vp8_dec_info { uint64_t working_buf_dma; uint64_t prev_y_dma; uint64_t cur_y_fb_dma; uint64_t cur_c_fb_dma; uint64_t bs_dma; uint32_t bs_sz; uint32_t resolution_changed; uint32_t show_frame; uint32_t wait_key_frame; }; /** * struct vdec_vp8_vsi - VPU shared information * @dec : decoding information * @pic : picture information * @dec_table : decoder coefficient table * @segment_buf : segmentation buffer * @load_data : flag to indicate reload decode data */ struct vdec_vp8_vsi { struct vdec_vp8_dec_info dec; struct vdec_pic_info pic; uint32_t dec_table[VP8_DEC_TABLE_SZ]; uint32_t segment_buf[VP8_HW_SEGMENT_DATA_SZ][VP8_HW_SEGMENT_UINT]; uint32_t load_data; }; /** * struct vdec_vp8_hw_reg_base - HW register base * @misc : base address for misc * @ld : base address for ld * @top : base address for top * @cm : base address for cm * @hwd : base address for hwd * @hwb : base address for hwb */ struct vdec_vp8_hw_reg_base { void __iomem *misc; void __iomem *ld; void __iomem *top; void __iomem *cm; void __iomem *hwd; void __iomem *hwb; }; /** * struct vdec_vp8_vpu_inst - VPU instance for VP8 decode * @wq_hd : Wait queue to wait VPU message ack * @signaled : 1 - Host has received ack message from VPU, 0 - not received * @failure : VPU execution result status 0 - success, others - fail * @inst_addr : VPU decoder instance address */ struct vdec_vp8_vpu_inst { wait_queue_head_t wq_hd; int signaled; int failure; uint32_t inst_addr; }; /* frame buffer (fb) list * [available_fb_node_list] - decode fb are initialized to 0 and populated in * [fb_use_list] - fb is set after decode and is moved to this list * [fb_free_list] - fb is not needed for reference will be moved from * [fb_use_list] to [fb_free_list] and * once user remove fb from [fb_free_list], * it is circulated back to [available_fb_node_list] * [fb_disp_list] - fb is set after decode and is moved to this list * once user remove fb from [fb_disp_list] it is * circulated back to [available_fb_node_list] */ /** * struct vdec_vp8_inst - VP8 decoder instance * @cur_fb : current frame buffer * @dec_fb : decode frame buffer node * @available_fb_node_list : list to store available frame buffer node * @fb_use_list : list to store frame buffer in use * @fb_free_list : list to store free frame buffer * @fb_disp_list : list to store display ready frame buffer * @working_buf : HW decoder working buffer * @reg_base : HW register base address * @frm_cnt : decode frame count * @ctx : V4L2 context * @vpu : VPU instance for decoder * @vsi : VPU share information */ struct vdec_vp8_inst { struct vdec_fb *cur_fb; struct vdec_fb_node dec_fb[VP8_MAX_FRM_BUF_NODE_NUM]; struct list_head available_fb_node_list; struct list_head fb_use_list; struct list_head fb_free_list; struct list_head fb_disp_list; struct mtk_vcodec_mem working_buf; struct vdec_vp8_hw_reg_base reg_base; unsigned int frm_cnt; struct mtk_vcodec_dec_ctx *ctx; struct vdec_vpu_inst vpu; struct vdec_vp8_vsi *vsi; }; static void get_hw_reg_base(struct vdec_vp8_inst *inst) { void __iomem **reg_base = inst->ctx->dev->reg_base; inst->reg_base.top = mtk_vcodec_get_reg_addr(reg_base, VDEC_TOP); inst->reg_base.cm = mtk_vcodec_get_reg_addr(reg_base, VDEC_CM); inst->reg_base.hwd = mtk_vcodec_get_reg_addr(reg_base, VDEC_HWD); inst->reg_base.misc = mtk_vcodec_get_reg_addr(reg_base, VDEC_MISC); inst->reg_base.ld = mtk_vcodec_get_reg_addr(reg_base, VDEC_LD); inst->reg_base.hwb = mtk_vcodec_get_reg_addr(reg_base, VDEC_HWB); } static void write_hw_segmentation_data(struct vdec_vp8_inst *inst) { int i, j; u32 seg_id_addr; u32 val; void __iomem *cm = inst->reg_base.cm; struct vdec_vp8_vsi *vsi = inst->vsi; seg_id_addr = readl(inst->reg_base.top + VP8_SEGID_DRAM_ADDR) >> 4; for (i = 0; i < ARRAY_SIZE(vsi->segment_buf); i++) { for (j = ARRAY_SIZE(vsi->segment_buf[i]) - 1; j >= 0; j--) { val = (1 << 16) + ((seg_id_addr + i) << 2) + j; writel(val, cm + VP8_HW_VLD_ADDR); val = vsi->segment_buf[i][j]; writel(val, cm + VP8_HW_VLD_VALUE); } } } static void read_hw_segmentation_data(struct vdec_vp8_inst *inst) { int i, j; u32 seg_id_addr; u32 val; void __iomem *cm = inst->reg_base.cm; struct vdec_vp8_vsi *vsi = inst->vsi; seg_id_addr = readl(inst->reg_base.top + VP8_SEGID_DRAM_ADDR) >> 4; for (i = 0; i < ARRAY_SIZE(vsi->segment_buf); i++) { for (j = ARRAY_SIZE(vsi->segment_buf[i]) - 1; j >= 0; j--) { val = ((seg_id_addr + i) << 2) + j; writel(val, cm + VP8_HW_VLD_ADDR); val = readl(cm + VP8_HW_VLD_VALUE); vsi->segment_buf[i][j] = val; } } } /* reset HW and enable HW read/write data function */ static void enable_hw_rw_function(struct vdec_vp8_inst *inst) { u32 val = 0; void __iomem *misc = inst->reg_base.misc; void __iomem *ld = inst->reg_base.ld; void __iomem *hwb = inst->reg_base.hwb; void __iomem *hwd = inst->reg_base.hwd; mtk_vcodec_write_vdecsys(inst->ctx, VP8_RW_CKEN_SET, 0x1); writel(0x101, ld + VP8_WO_VLD_SRST); writel(0x101, hwb + VP8_WO_VLD_SRST); mtk_vcodec_write_vdecsys(inst->ctx, 0, 0x1); val = readl(misc + VP8_RW_MISC_SRST); writel((val & 0xFFFFFFFE), misc + VP8_RW_MISC_SRST); writel(0x1, misc + VP8_RW_MISC_SYS_SEL); writel(0x17F, misc + VP8_RW_MISC_SPEC_CON); writel(0x71201100, misc + VP8_RW_MISC_FUNC_CON); writel(0x0, ld + VP8_WO_VLD_SRST); writel(0x0, hwb + VP8_WO_VLD_SRST); mtk_vcodec_write_vdecsys(inst->ctx, VP8_RW_DCM_CON, 0x1); writel(0x1, misc + VP8_RW_MISC_DCM_CON); writel(0x1, hwd + VP8_RW_VP8_CTRL); } static void store_dec_table(struct vdec_vp8_inst *inst) { int i, j; u32 addr = 0, val = 0; void __iomem *hwd = inst->reg_base.hwd; u32 *p = &inst->vsi->dec_table[VP8_DEC_TABLE_OFFSET]; for (i = 0; i < VP8_DEC_TABLE_PROC_LOOP; i++) { writel(addr, hwd + VP8_BSASET); for (j = 0; j < VP8_DEC_TABLE_UNIT ; j++) { val = *p++; writel(val, hwd + VP8_BSDSET); } addr += VP8_DEC_TABLE_RW_UNIT; } } static void load_dec_table(struct vdec_vp8_inst *inst) { int i; u32 addr = 0; u32 *p = &inst->vsi->dec_table[VP8_DEC_TABLE_OFFSET]; void __iomem *hwd = inst->reg_base.hwd; for (i = 0; i < VP8_DEC_TABLE_PROC_LOOP; i++) { writel(addr, hwd + VP8_BSASET); /* read total 11 bytes */ *p++ = readl(hwd + VP8_BSDSET); *p++ = readl(hwd + VP8_BSDSET); *p++ = readl(hwd + VP8_BSDSET) & 0xFFFFFF; addr += VP8_DEC_TABLE_RW_UNIT; } } static void get_pic_info(struct vdec_vp8_inst *inst, struct vdec_pic_info *pic) { *pic = inst->vsi->pic; mtk_vdec_debug(inst->ctx, "pic(%d, %d), buf(%d, %d)", pic->pic_w, pic->pic_h, pic->buf_w, pic->buf_h); mtk_vdec_debug(inst->ctx, "fb size: Y(%d), C(%d)", pic->fb_sz[0], pic->fb_sz[1]); } static void vp8_dec_finish(struct vdec_vp8_inst *inst) { struct vdec_fb_node *node; uint64_t prev_y_dma = inst->vsi->dec.prev_y_dma; mtk_vdec_debug(inst->ctx, "prev fb base dma=%llx", prev_y_dma); /* put last decode ok frame to fb_free_list */ if (prev_y_dma != 0) { list_for_each_entry(node, &inst->fb_use_list, list) { struct vdec_fb *fb = (struct vdec_fb *)node->fb; if (prev_y_dma == (uint64_t)fb->base_y.dma_addr) { list_move_tail(&node->list, &inst->fb_free_list); break; } } } /* available_fb_node_list -> fb_use_list */ node = list_first_entry(&inst->available_fb_node_list, struct vdec_fb_node, list); node->fb = inst->cur_fb; list_move_tail(&node->list, &inst->fb_use_list); /* available_fb_node_list -> fb_disp_list */ if (inst->vsi->dec.show_frame) { node = list_first_entry(&inst->available_fb_node_list, struct vdec_fb_node, list); node->fb = inst->cur_fb; list_move_tail(&node->list, &inst->fb_disp_list); } } static void move_fb_list_use_to_free(struct vdec_vp8_inst *inst) { struct vdec_fb_node *node, *tmp; list_for_each_entry_safe(node, tmp, &inst->fb_use_list, list) list_move_tail(&node->list, &inst->fb_free_list); } static void init_list(struct vdec_vp8_inst *inst) { int i; INIT_LIST_HEAD(&inst->available_fb_node_list); INIT_LIST_HEAD(&inst->fb_use_list); INIT_LIST_HEAD(&inst->fb_free_list); INIT_LIST_HEAD(&inst->fb_disp_list); for (i = 0; i < ARRAY_SIZE(inst->dec_fb); i++) { INIT_LIST_HEAD(&inst->dec_fb[i].list); inst->dec_fb[i].fb = NULL; list_add_tail(&inst->dec_fb[i].list, &inst->available_fb_node_list); } } static void add_fb_to_free_list(struct vdec_vp8_inst *inst, void *fb) { struct vdec_fb_node *node; if (fb) { node = list_first_entry(&inst->available_fb_node_list, struct vdec_fb_node, list); node->fb = fb; list_move_tail(&node->list, &inst->fb_free_list); } } static int alloc_working_buf(struct vdec_vp8_inst *inst) { int err; struct mtk_vcodec_mem *mem = &inst->working_buf; mem->size = VP8_WORKING_BUF_SZ; err = mtk_vcodec_mem_alloc(inst->ctx, mem); if (err) { mtk_vdec_err(inst->ctx, "Cannot allocate working buffer"); return err; } inst->vsi->dec.working_buf_dma = (uint64_t)mem->dma_addr; return 0; } static void free_working_buf(struct vdec_vp8_inst *inst) { struct mtk_vcodec_mem *mem = &inst->working_buf; if (mem->va) mtk_vcodec_mem_free(inst->ctx, mem); inst->vsi->dec.working_buf_dma = 0; } static int vdec_vp8_init(struct mtk_vcodec_dec_ctx *ctx) { struct vdec_vp8_inst *inst; int err; inst = kzalloc(sizeof(*inst), GFP_KERNEL); if (!inst) return -ENOMEM; inst->ctx = ctx; inst->vpu.id = IPI_VDEC_VP8; inst->vpu.ctx = ctx; err = vpu_dec_init(&inst->vpu); if (err) { mtk_vdec_err(ctx, "vdec_vp8 init err=%d", err); goto error_free_inst; } inst->vsi = (struct vdec_vp8_vsi *)inst->vpu.vsi; init_list(inst); err = alloc_working_buf(inst); if (err) goto error_deinit; get_hw_reg_base(inst); mtk_vdec_debug(ctx, "VP8 Instance >> %p", inst); ctx->drv_handle = inst; return 0; error_deinit: vpu_dec_deinit(&inst->vpu); error_free_inst: kfree(inst); return err; } static int vdec_vp8_decode(void *h_vdec, struct mtk_vcodec_mem *bs, struct vdec_fb *fb, bool *res_chg) { struct vdec_vp8_inst *inst = (struct vdec_vp8_inst *)h_vdec; struct vdec_vp8_dec_info *dec = &inst->vsi->dec; struct vdec_vpu_inst *vpu = &inst->vpu; unsigned char *bs_va; unsigned int data; int err = 0; uint64_t y_fb_dma; uint64_t c_fb_dma; /* bs NULL means flush decoder */ if (bs == NULL) { move_fb_list_use_to_free(inst); return vpu_dec_reset(vpu); } y_fb_dma = fb ? (u64)fb->base_y.dma_addr : 0; c_fb_dma = fb ? (u64)fb->base_c.dma_addr : 0; mtk_vdec_debug(inst->ctx, "+ [%d] FB y_dma=%llx c_dma=%llx fb=%p", inst->frm_cnt, y_fb_dma, c_fb_dma, fb); inst->cur_fb = fb; dec->bs_dma = (uint64_t)bs->dma_addr; dec->bs_sz = bs->size; dec->cur_y_fb_dma = y_fb_dma; dec->cur_c_fb_dma = c_fb_dma; mtk_vdec_debug(inst->ctx, "\n + FRAME[%d] +\n", inst->frm_cnt); write_hw_segmentation_data(inst); enable_hw_rw_function(inst); store_dec_table(inst); bs_va = (unsigned char *)bs->va; /* retrieve width/hight and scale info from header */ data = (*(bs_va + 9) << 24) | (*(bs_va + 8) << 16) | (*(bs_va + 7) << 8) | *(bs_va + 6); err = vpu_dec_start(vpu, &data, 1); if (err) { add_fb_to_free_list(inst, fb); if (dec->wait_key_frame) { mtk_vdec_debug(inst->ctx, "wait key frame !"); return 0; } goto error; } if (dec->resolution_changed) { mtk_vdec_debug(inst->ctx, "- resolution_changed -"); *res_chg = true; add_fb_to_free_list(inst, fb); return 0; } /* wait decoder done interrupt */ mtk_vcodec_wait_for_done_ctx(inst->ctx, MTK_INST_IRQ_RECEIVED, WAIT_INTR_TIMEOUT_MS, 0); if (inst->vsi->load_data) load_dec_table(inst); vp8_dec_finish(inst); read_hw_segmentation_data(inst); err = vpu_dec_end(vpu); if (err) goto error; mtk_vdec_debug(inst->ctx, "\n - FRAME[%d] - show=%d\n", inst->frm_cnt, dec->show_frame); inst->frm_cnt++; *res_chg = false; return 0; error: mtk_vdec_err(inst->ctx, "\n - FRAME[%d] - err=%d\n", inst->frm_cnt, err); return err; } static void get_disp_fb(struct vdec_vp8_inst *inst, struct vdec_fb **out_fb) { struct vdec_fb_node *node; struct vdec_fb *fb; node = list_first_entry_or_null(&inst->fb_disp_list, struct vdec_fb_node, list); if (node) { list_move_tail(&node->list, &inst->available_fb_node_list); fb = (struct vdec_fb *)node->fb; fb->status |= FB_ST_DISPLAY; mtk_vdec_debug(inst->ctx, "[FB] get disp fb %p st=%d", node->fb, fb->status); } else { fb = NULL; mtk_vdec_debug(inst->ctx, "[FB] there is no disp fb"); } *out_fb = fb; } static void get_free_fb(struct vdec_vp8_inst *inst, struct vdec_fb **out_fb) { struct vdec_fb_node *node; struct vdec_fb *fb; node = list_first_entry_or_null(&inst->fb_free_list, struct vdec_fb_node, list); if (node) { list_move_tail(&node->list, &inst->available_fb_node_list); fb = (struct vdec_fb *)node->fb; fb->status |= FB_ST_FREE; mtk_vdec_debug(inst->ctx, "[FB] get free fb %p st=%d", node->fb, fb->status); } else { fb = NULL; mtk_vdec_debug(inst->ctx, "[FB] there is no free fb"); } *out_fb = fb; } static void get_crop_info(struct vdec_vp8_inst *inst, struct v4l2_rect *cr) { cr->left = 0; cr->top = 0; cr->width = inst->vsi->pic.pic_w; cr->height = inst->vsi->pic.pic_h; mtk_vdec_debug(inst->ctx, "get crop info l=%d, t=%d, w=%d, h=%d", cr->left, cr->top, cr->width, cr->height); } static int vdec_vp8_get_param(void *h_vdec, enum vdec_get_param_type type, void *out) { struct vdec_vp8_inst *inst = (struct vdec_vp8_inst *)h_vdec; switch (type) { case GET_PARAM_DISP_FRAME_BUFFER: get_disp_fb(inst, out); break; case GET_PARAM_FREE_FRAME_BUFFER: get_free_fb(inst, out); break; case GET_PARAM_PIC_INFO: get_pic_info(inst, out); break; case GET_PARAM_CROP_INFO: get_crop_info(inst, out); break; case GET_PARAM_DPB_SIZE: *((unsigned int *)out) = VP8_DPB_SIZE; break; default: mtk_vdec_err(inst->ctx, "invalid get parameter type=%d", type); return -EINVAL; } return 0; } static void vdec_vp8_deinit(void *h_vdec) { struct vdec_vp8_inst *inst = (struct vdec_vp8_inst *)h_vdec; vpu_dec_deinit(&inst->vpu); free_working_buf(inst); kfree(inst); } const struct vdec_common_if vdec_vp8_if = { .init = vdec_vp8_init, .decode = vdec_vp8_decode, .get_param = vdec_vp8_get_param, .deinit = vdec_vp8_deinit, };
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