openwrt/target/linux/bcm27xx/patches-5.15/950-0393-media-rpivid-Remove-the-need-to-have-num_entry_point.patch
Álvaro Fernández Rojas 20ea6adbf1 bcm27xx: add support for linux v5.15
Build system: x86_64
Build-tested: bcm2708, bcm2709, bcm2710, bcm2711
Run-tested: bcm2708/RPiB+, bcm2709/RPi3B, bcm2710/RPi3B, bcm2711/RPi4B

Signed-off-by: Marty Jones <mj8263788@gmail.com>
Signed-off-by: Álvaro Fernández Rojas <noltari@gmail.com>
2022-05-17 15:11:22 +02:00

981 lines
31 KiB
Diff

From 4b33f988d9da9776bcfe218df4ab9865f4b771a8 Mon Sep 17 00:00:00 2001
From: John Cox <jc@kynesim.co.uk>
Date: Thu, 21 May 2020 11:49:37 +0100
Subject: [PATCH] media: rpivid: Remove the need to have
num_entry_points set
VAAPI H265 has num entry points but never sets it. Allow a VAAPI
shim to work without requiring rewriting the VAAPI driver.
num_entry_points can be calculated from the slice_segment_addr
of the next slice so delay processing until we have that.
Also includes some minor cosmetics.
Signed-off-by: John Cox <jc@kynesim.co.uk>
---
drivers/staging/media/rpivid/rpivid_h265.c | 699 +++++++++++----------
1 file changed, 365 insertions(+), 334 deletions(-)
--- a/drivers/staging/media/rpivid/rpivid_h265.c
+++ b/drivers/staging/media/rpivid/rpivid_h265.c
@@ -202,8 +202,17 @@ struct rpivid_dec_env {
unsigned int dpbno_col;
u32 reg_slicestart;
int collocated_from_l0_flag;
- unsigned int wpp_entry_x;
- unsigned int wpp_entry_y;
+ /*
+ * Last CTB/Tile X,Y processed by (wpp_)entry_point
+ * Could be in _state as P0 only but needs updating where _state
+ * is const
+ */
+ unsigned int entry_ctb_x;
+ unsigned int entry_ctb_y;
+ unsigned int entry_tile_x;
+ unsigned int entry_tile_y;
+ unsigned int entry_qp;
+ u32 entry_slice;
u32 rpi_config2;
u32 rpi_framesize;
@@ -239,22 +248,17 @@ struct rpivid_dec_state {
struct v4l2_ctrl_hevc_pps pps;
// Helper vars & tables derived from sps/pps
- unsigned int log2_ctb_size; /* log2 width of a CTB */
- unsigned int ctb_width; /* Width in CTBs */
- unsigned int ctb_height; /* Height in CTBs */
- unsigned int ctb_size; /* Pic area in CTBs */
- unsigned int num_tile_columns;
- unsigned int num_tile_rows;
- u8 column_width[member_size(struct v4l2_ctrl_hevc_pps,
- column_width_minus1)];
- u8 row_height[member_size(struct v4l2_ctrl_hevc_pps,
- row_height_minus1)];
+ unsigned int log2_ctb_size; /* log2 width of a CTB */
+ unsigned int ctb_width; /* Width in CTBs */
+ unsigned int ctb_height; /* Height in CTBs */
+ unsigned int ctb_size; /* Pic area in CTBs */
+ unsigned int tile_width; /* Width in tiles */
+ unsigned int tile_height; /* Height in tiles */
int *col_bd;
int *row_bd;
int *ctb_addr_rs_to_ts;
int *ctb_addr_ts_to_rs;
- int *tile_id;
// Aux starage for DPB
// Hold refs
@@ -274,6 +278,12 @@ struct rpivid_dec_state {
unsigned int slice_qp;
unsigned int max_num_merge_cand; // 0 if I-slice
bool dependent_slice_segment_flag;
+
+ unsigned int start_ts; /* slice_segment_addr -> ts */
+ unsigned int start_ctb_x; /* CTB X,Y of start_ts */
+ unsigned int start_ctb_y;
+ unsigned int prev_ctb_x; /* CTB X,Y of start_ts - 1 */
+ unsigned int prev_ctb_y;
};
static inline int clip_int(const int x, const int lo, const int hi)
@@ -319,15 +329,16 @@ static int ctb_to_tile(unsigned int ctb,
return i - 1;
}
-static int ctb_to_slice_w_h(unsigned int ctb, int ctb_size, int width,
- unsigned int *bd, int num)
+static unsigned int ctb_to_tile_x(const struct rpivid_dec_state *const s,
+ const unsigned int ctb_x)
{
- if (ctb < bd[num - 1])
- return ctb_size;
- else if (width % ctb_size)
- return width % ctb_size;
- else
- return ctb_size;
+ return ctb_to_tile(ctb_x, s->col_bd, s->tile_width);
+}
+
+static unsigned int ctb_to_tile_y(const struct rpivid_dec_state *const s,
+ const unsigned int ctb_y)
+{
+ return ctb_to_tile(ctb_y, s->row_bd, s->tile_height);
}
static void aux_q_free(struct rpivid_ctx *const ctx,
@@ -532,6 +543,15 @@ static void write_prob(struct rpivid_dec
p1_apb_write(de, 0x1000 + i,
dst[i] + (dst[i + 1] << 8) + (dst[i + 2] << 16) +
(dst[i + 3] << 24));
+
+ /*
+ * Having written the prob array back it up
+ * This is not always needed but is a small overhead that simplifies
+ * (and speeds up) some multi-tile & WPP scenarios
+ * There are no scenarios where having written a prob we ever want
+ * a previous (non-initial) state back
+ */
+ p1_apb_write(de, RPI_TRANSFER, PROB_BACKUP);
}
static void write_scaling_factors(struct rpivid_dec_env *const de)
@@ -552,8 +572,8 @@ static inline __u32 dma_to_axi_addr(dma_
static void write_bitstream(struct rpivid_dec_env *const de,
const struct rpivid_dec_state *const s)
{
- // Note that FFmpeg removes emulation prevention bytes, so this is
- // matched in the configuration here.
+ // Note that FFmpeg V4L2 does not remove emulation prevention bytes,
+ // so this is matched in the configuration here.
// Whether that is the correct behaviour or not is not clear in the
// spec.
const int rpi_use_emu = 1;
@@ -579,78 +599,26 @@ static void write_bitstream(struct rpivi
//////////////////////////////////////////////////////////////////////////////
-static void write_slice(struct rpivid_dec_env *const de,
- const struct rpivid_dec_state *const s,
- const unsigned int slice_w,
- const unsigned int slice_h)
-{
- u32 u32 = (s->sh->slice_type << 12) +
- (((s->sh->flags &
- V4L2_HEVC_SLICE_PARAMS_FLAG_SLICE_SAO_LUMA) != 0)
- << 14) +
- (((s->sh->flags &
- V4L2_HEVC_SLICE_PARAMS_FLAG_SLICE_SAO_CHROMA) != 0)
- << 15) +
- (slice_w << 17) + (slice_h << 24);
-
- u32 |= (s->max_num_merge_cand << 0) + (s->nb_refs[L0] << 4) +
- (s->nb_refs[L1] << 8);
-
- if (s->sh->slice_type == HEVC_SLICE_B)
- u32 |= ((s->sh->flags &
- V4L2_HEVC_SLICE_PARAMS_FLAG_MVD_L1_ZERO) != 0)
- << 16;
- p1_apb_write(de, RPI_SLICE, u32);
-}
-
-//////////////////////////////////////////////////////////////////////////////
-// Tiles mode
-
-static void new_entry_point(struct rpivid_dec_env *const de,
- const struct rpivid_dec_state *const s,
- const int do_bte,
- const int reset_qp_y, const int ctb_addr_ts)
+/*
+ * The slice constant part of the slice register - width and height need to
+ * be ORed in later as they are per-tile / WPP-row
+ */
+static u32 slice_reg_const(const struct rpivid_dec_state *const s)
{
- int ctb_col = s->ctb_addr_ts_to_rs[ctb_addr_ts] %
- de->pic_width_in_ctbs_y;
- int ctb_row = s->ctb_addr_ts_to_rs[ctb_addr_ts] /
- de->pic_width_in_ctbs_y;
-
- int tile_x = ctb_to_tile(ctb_col, s->col_bd, s->num_tile_columns);
- int tile_y = ctb_to_tile(ctb_row, s->row_bd, s->num_tile_rows);
-
- int endx = s->col_bd[tile_x + 1] - 1;
- int endy = s->row_bd[tile_y + 1] - 1;
-
- u8 slice_w = ctb_to_slice_w_h(ctb_col, 1 << s->log2_ctb_size,
- s->sps.pic_width_in_luma_samples,
- s->col_bd, s->num_tile_columns);
- u8 slice_h = ctb_to_slice_w_h(ctb_row, 1 << s->log2_ctb_size,
- s->sps.pic_height_in_luma_samples,
- s->row_bd, s->num_tile_rows);
-
- p1_apb_write(de, RPI_TILESTART,
- s->col_bd[tile_x] + (s->row_bd[tile_y] << 16));
- p1_apb_write(de, RPI_TILEEND, endx + (endy << 16));
-
- if (do_bte)
- p1_apb_write(de, RPI_BEGINTILEEND, endx + (endy << 16));
+ u32 x = (s->max_num_merge_cand << 0) |
+ (s->nb_refs[L0] << 4) |
+ (s->nb_refs[L1] << 8) |
+ (s->sh->slice_type << 12);
+
+ if (s->sh->flags & V4L2_HEVC_SLICE_PARAMS_FLAG_SLICE_SAO_LUMA)
+ x |= BIT(14);
+ if (s->sh->flags & V4L2_HEVC_SLICE_PARAMS_FLAG_SLICE_SAO_CHROMA)
+ x |= BIT(15);
+ if (s->sh->slice_type == HEVC_SLICE_B &&
+ (s->sh->flags & V4L2_HEVC_SLICE_PARAMS_FLAG_MVD_L1_ZERO))
+ x |= BIT(16);
- write_slice(de, s, slice_w, slice_h);
-
- if (reset_qp_y) {
- unsigned int sps_qp_bd_offset =
- 6 * s->sps.bit_depth_luma_minus8;
-
- p1_apb_write(de, RPI_QP, sps_qp_bd_offset + s->slice_qp);
- }
-
- p1_apb_write(de, RPI_MODE,
- (0xFFFF << 0) + (0x0 << 16) +
- ((tile_x == s->num_tile_columns - 1) << 17) +
- ((tile_y == s->num_tile_rows - 1) << 18));
-
- p1_apb_write(de, RPI_CONTROL, (ctb_col << 0) + (ctb_row << 16));
+ return x;
}
//////////////////////////////////////////////////////////////////////////////
@@ -934,197 +902,256 @@ static void pre_slice_decode(struct rpiv
(sh->slice_cb_qp_offset & 31)); // CMD_QPOFF
}
-//////////////////////////////////////////////////////////////////////////////
-// Write STATUS register with expected end CTU address of previous slice
-
-static void end_previous_slice(struct rpivid_dec_env *const de,
- const struct rpivid_dec_state *const s,
- const int ctb_addr_ts)
-{
- int last_x =
- s->ctb_addr_ts_to_rs[ctb_addr_ts - 1] % de->pic_width_in_ctbs_y;
- int last_y =
- s->ctb_addr_ts_to_rs[ctb_addr_ts - 1] / de->pic_width_in_ctbs_y;
-
- p1_apb_write(de, RPI_STATUS, 1 + (last_x << 5) + (last_y << 18));
-}
-
-static void wpp_pause(struct rpivid_dec_env *const de, int ctb_row)
-{
- p1_apb_write(de, RPI_STATUS, (ctb_row << 18) + 0x25);
- p1_apb_write(de, RPI_TRANSFER, PROB_BACKUP);
- p1_apb_write(de, RPI_MODE,
- ctb_row == de->pic_height_in_ctbs_y - 1 ?
- 0x70000 : 0x30000);
- p1_apb_write(de, RPI_CONTROL, (ctb_row << 16) + 2);
-}
-
-static void wpp_end_previous_slice(struct rpivid_dec_env *const de,
- const struct rpivid_dec_state *const s,
- int ctb_addr_ts)
-{
- int new_x = s->sh->slice_segment_addr % de->pic_width_in_ctbs_y;
- int new_y = s->sh->slice_segment_addr / de->pic_width_in_ctbs_y;
- int last_x =
- s->ctb_addr_ts_to_rs[ctb_addr_ts - 1] % de->pic_width_in_ctbs_y;
- int last_y =
- s->ctb_addr_ts_to_rs[ctb_addr_ts - 1] / de->pic_width_in_ctbs_y;
-
- if (de->wpp_entry_x < 2 && (de->wpp_entry_y < new_y || new_x > 2) &&
- de->pic_width_in_ctbs_y > 2)
- wpp_pause(de, last_y);
- p1_apb_write(de, RPI_STATUS, 1 + (last_x << 5) + (last_y << 18));
- if (new_x == 2 || (de->pic_width_in_ctbs_y == 2 &&
- de->wpp_entry_y < new_y))
- p1_apb_write(de, RPI_TRANSFER, PROB_BACKUP);
+static void write_slice(struct rpivid_dec_env *const de,
+ const struct rpivid_dec_state *const s,
+ const u32 slice_const,
+ const unsigned int ctb_col,
+ const unsigned int ctb_row)
+{
+ const unsigned int cs = (1 << s->log2_ctb_size);
+ const unsigned int w_last = s->sps.pic_width_in_luma_samples & (cs - 1);
+ const unsigned int h_last = s->sps.pic_height_in_luma_samples & (cs - 1);
+
+ p1_apb_write(de, RPI_SLICE,
+ slice_const |
+ ((ctb_col + 1 < s->ctb_width || !w_last ?
+ cs : w_last) << 17) |
+ ((ctb_row + 1 < s->ctb_height || !h_last ?
+ cs : h_last) << 24));
}
-//////////////////////////////////////////////////////////////////////////////
-// Wavefront mode
+#define PAUSE_MODE_WPP 1
+#define PAUSE_MODE_TILE 0xffff
-static void wpp_entry_point(struct rpivid_dec_env *const de,
+/*
+ * N.B. This can be called to fill in data from the previous slice so must not
+ * use any state data that may change from slice to slice (e.g. qp)
+ */
+static void new_entry_point(struct rpivid_dec_env *const de,
const struct rpivid_dec_state *const s,
- const int do_bte,
- const int reset_qp_y, const int ctb_addr_ts)
-{
- int ctb_size = 1 << s->log2_ctb_size;
- int ctb_addr_rs = s->ctb_addr_ts_to_rs[ctb_addr_ts];
-
- int ctb_col = de->wpp_entry_x = ctb_addr_rs % de->pic_width_in_ctbs_y;
- int ctb_row = de->wpp_entry_y = ctb_addr_rs / de->pic_width_in_ctbs_y;
+ const bool do_bte,
+ const bool reset_qp_y,
+ const u32 pause_mode,
+ const unsigned int tile_x,
+ const unsigned int tile_y,
+ const unsigned int ctb_col,
+ const unsigned int ctb_row,
+ const unsigned int slice_qp,
+ const u32 slice_const)
+{
+ const unsigned int endx = s->col_bd[tile_x + 1] - 1;
+ const unsigned int endy = (pause_mode == PAUSE_MODE_WPP) ?
+ ctb_row : s->row_bd[tile_y + 1] - 1;
- int endx = de->pic_width_in_ctbs_y - 1;
- int endy = ctb_row;
-
- u8 slice_w = ctb_to_slice_w_h(ctb_col, ctb_size,
- s->sps.pic_width_in_luma_samples,
- s->col_bd, s->num_tile_columns);
- u8 slice_h = ctb_to_slice_w_h(ctb_row, ctb_size,
- s->sps.pic_height_in_luma_samples,
- s->row_bd, s->num_tile_rows);
-
- p1_apb_write(de, RPI_TILESTART, 0);
- p1_apb_write(de, RPI_TILEEND, endx + (endy << 16));
+ p1_apb_write(de, RPI_TILESTART,
+ s->col_bd[tile_x] | (s->row_bd[tile_y] << 16));
+ p1_apb_write(de, RPI_TILEEND, endx | (endy << 16));
if (do_bte)
- p1_apb_write(de, RPI_BEGINTILEEND, endx + (endy << 16));
+ p1_apb_write(de, RPI_BEGINTILEEND, endx | (endy << 16));
- write_slice(de, s, slice_w,
- ctb_row == de->pic_height_in_ctbs_y - 1 ?
- slice_h : ctb_size);
+ write_slice(de, s, slice_const, endx, endy);
if (reset_qp_y) {
unsigned int sps_qp_bd_offset =
6 * s->sps.bit_depth_luma_minus8;
- p1_apb_write(de, RPI_QP, sps_qp_bd_offset + s->slice_qp);
+ p1_apb_write(de, RPI_QP, sps_qp_bd_offset + slice_qp);
}
p1_apb_write(de, RPI_MODE,
- ctb_row == de->pic_height_in_ctbs_y - 1 ?
- 0x60001 : 0x20001);
- p1_apb_write(de, RPI_CONTROL, (ctb_col << 0) + (ctb_row << 16));
+ pause_mode |
+ ((endx == s->ctb_width - 1) << 17) |
+ ((endy == s->ctb_height - 1) << 18));
+
+ p1_apb_write(de, RPI_CONTROL, (ctb_col << 0) | (ctb_row << 16));
+
+ de->entry_tile_x = tile_x;
+ de->entry_tile_y = tile_y;
+ de->entry_ctb_x = ctb_col;
+ de->entry_ctb_y = ctb_row;
+ de->entry_qp = slice_qp;
+ de->entry_slice = slice_const;
}
//////////////////////////////////////////////////////////////////////////////
// Wavefront mode
+static void wpp_pause(struct rpivid_dec_env *const de, int ctb_row)
+{
+ p1_apb_write(de, RPI_STATUS, (ctb_row << 18) | 0x25);
+ p1_apb_write(de, RPI_TRANSFER, PROB_BACKUP);
+ p1_apb_write(de, RPI_MODE,
+ ctb_row == de->pic_height_in_ctbs_y - 1 ?
+ 0x70000 : 0x30000);
+ p1_apb_write(de, RPI_CONTROL, (ctb_row << 16) + 2);
+}
+
+static void wpp_entry_fill(struct rpivid_dec_env *const de,
+ const struct rpivid_dec_state *const s,
+ const unsigned int last_y)
+{
+ const unsigned int last_x = s->ctb_width - 1;
+
+ while (de->entry_ctb_y < last_y) {
+ /* wpp_entry_x/y set by wpp_entry_point */
+ if (s->ctb_width > 2)
+ wpp_pause(de, de->entry_ctb_y);
+ p1_apb_write(de, RPI_STATUS,
+ (de->entry_ctb_y << 18) | (last_x << 5) | 2);
+
+ /* if width == 1 then the saved state is the init one */
+ if (s->ctb_width == 2)
+ p1_apb_write(de, RPI_TRANSFER, PROB_BACKUP);
+ else
+ p1_apb_write(de, RPI_TRANSFER, PROB_RELOAD);
+
+ new_entry_point(de, s, false, true, PAUSE_MODE_WPP,
+ 0, 0, 0, de->entry_ctb_y + 1,
+ de->entry_qp, de->entry_slice);
+ }
+}
+
+static void wpp_end_previous_slice(struct rpivid_dec_env *const de,
+ const struct rpivid_dec_state *const s)
+{
+ wpp_entry_fill(de, s, s->prev_ctb_y);
+
+ if (de->entry_ctb_x < 2 &&
+ (de->entry_ctb_y < s->start_ctb_y || s->start_ctb_x > 2) &&
+ s->ctb_width > 2)
+ wpp_pause(de, s->prev_ctb_y);
+ p1_apb_write(de, RPI_STATUS,
+ 1 | (s->prev_ctb_x << 5) | (s->prev_ctb_y << 18));
+ if (s->start_ctb_x == 2 ||
+ (s->ctb_width == 2 && de->entry_ctb_y < s->start_ctb_y))
+ p1_apb_write(de, RPI_TRANSFER, PROB_BACKUP);
+}
+
+/* Only main profile supported so WPP => !Tiles which makes some of the
+ * next chunk code simpler
+ */
static void wpp_decode_slice(struct rpivid_dec_env *const de,
- const struct rpivid_dec_state *const s,
- const struct v4l2_ctrl_hevc_slice_params *sh,
- int ctb_addr_ts)
-{
- int i, reset_qp_y = 1;
- int indep = !s->dependent_slice_segment_flag;
- int ctb_col = s->sh->slice_segment_addr % de->pic_width_in_ctbs_y;
+ const struct rpivid_dec_state *const s)
+{
+ bool reset_qp_y = true;
+ const bool indep = !s->dependent_slice_segment_flag;
- if (ctb_addr_ts)
- wpp_end_previous_slice(de, s, ctb_addr_ts);
+ if (s->start_ts)
+ wpp_end_previous_slice(de, s);
pre_slice_decode(de, s);
write_bitstream(de, s);
- if (ctb_addr_ts == 0 || indep || de->pic_width_in_ctbs_y == 1)
+
+ if (!s->start_ts || indep || s->ctb_width == 1)
write_prob(de, s);
- else if (ctb_col == 0)
+ else if (!s->start_ctb_x)
p1_apb_write(de, RPI_TRANSFER, PROB_RELOAD);
else
- reset_qp_y = 0;
+ reset_qp_y = false;
+
program_slicecmds(de, s->slice_idx);
new_slice_segment(de, s);
- wpp_entry_point(de, s, indep, reset_qp_y, ctb_addr_ts);
+ new_entry_point(de, s, indep, reset_qp_y, PAUSE_MODE_WPP,
+ 0, 0, s->start_ctb_x, s->start_ctb_y,
+ s->slice_qp, slice_reg_const(s));
- for (i = 0; i < s->sh->num_entry_point_offsets; i++) {
- int ctb_addr_rs = s->ctb_addr_ts_to_rs[ctb_addr_ts];
- int ctb_row = ctb_addr_rs / de->pic_width_in_ctbs_y;
- int last_x = de->pic_width_in_ctbs_y - 1;
+ if (s->frame_end) {
+ wpp_entry_fill(de, s, s->ctb_height - 1);
+
+ if (de->entry_ctb_x < 2 && s->ctb_width > 2)
+ wpp_pause(de, s->ctb_height - 1);
- if (de->pic_width_in_ctbs_y > 2)
- wpp_pause(de, ctb_row);
p1_apb_write(de, RPI_STATUS,
- (ctb_row << 18) + (last_x << 5) + 2);
- if (de->pic_width_in_ctbs_y == 2)
- p1_apb_write(de, RPI_TRANSFER, PROB_BACKUP);
- if (de->pic_width_in_ctbs_y == 1)
- write_prob(de, s);
- else
- p1_apb_write(de, RPI_TRANSFER, PROB_RELOAD);
- ctb_addr_ts += s->column_width[0];
- wpp_entry_point(de, s, 0, 1, ctb_addr_ts);
+ 1 | ((s->ctb_width - 1) << 5) |
+ ((s->ctb_height - 1) << 18));
}
+
}
//////////////////////////////////////////////////////////////////////////////
// Tiles mode
+static void tile_entry_fill(struct rpivid_dec_env *const de,
+ const struct rpivid_dec_state *const s,
+ const unsigned int last_tile_x,
+ const unsigned int last_tile_y)
+{
+ while (de->entry_tile_y < last_tile_y ||
+ (de->entry_tile_y == last_tile_y &&
+ de->entry_tile_x < last_tile_x)) {
+ unsigned int t_x = de->entry_tile_x;
+ unsigned int t_y = de->entry_tile_y;
+ const unsigned int last_x = s->col_bd[t_x + 1] - 1;
+ const unsigned int last_y = s->row_bd[t_y + 1] - 1;
+
+ p1_apb_write(de, RPI_STATUS,
+ 2 | (last_x << 5) | (last_y << 18));
+ p1_apb_write(de, RPI_TRANSFER, PROB_RELOAD);
+
+ // Inc tile
+ if (++t_x >= s->tile_width) {
+ t_x = 0;
+ ++t_y;
+ }
+
+ new_entry_point(de, s, false, true, PAUSE_MODE_TILE,
+ t_x, t_y, s->col_bd[t_x], s->row_bd[t_y],
+ de->entry_qp, de->entry_slice);
+ }
+}
+
+/*
+ * Write STATUS register with expected end CTU address of previous slice
+ */
+static void end_previous_slice(struct rpivid_dec_env *const de,
+ const struct rpivid_dec_state *const s)
+{
+ tile_entry_fill(de, s,
+ ctb_to_tile_x(s, s->prev_ctb_x),
+ ctb_to_tile_y(s, s->prev_ctb_y));
+ p1_apb_write(de, RPI_STATUS,
+ 1 | (s->prev_ctb_x << 5) | (s->prev_ctb_y << 18));
+}
+
static void decode_slice(struct rpivid_dec_env *const de,
- const struct rpivid_dec_state *const s,
- const struct v4l2_ctrl_hevc_slice_params *const sh,
- int ctb_addr_ts)
+ const struct rpivid_dec_state *const s)
{
- int i, reset_qp_y;
+ bool reset_qp_y;
+ unsigned int tile_x = ctb_to_tile_x(s, s->start_ctb_x);
+ unsigned int tile_y = ctb_to_tile_y(s, s->start_ctb_y);
- if (ctb_addr_ts)
- end_previous_slice(de, s, ctb_addr_ts);
+ if (s->start_ts)
+ end_previous_slice(de, s);
pre_slice_decode(de, s);
write_bitstream(de, s);
-#if DEBUG_TRACE_P1_CMD
- if (p1_z < 256) {
- v4l2_info(&de->ctx->dev->v4l2_dev,
- "TS=%d, tile=%d/%d, dss=%d, flags=%#llx\n",
- ctb_addr_ts, s->tile_id[ctb_addr_ts],
- s->tile_id[ctb_addr_ts - 1],
- s->dependent_slice_segment_flag, sh->flags);
- }
-#endif
-
- reset_qp_y = ctb_addr_ts == 0 ||
- s->tile_id[ctb_addr_ts] != s->tile_id[ctb_addr_ts - 1] ||
- !s->dependent_slice_segment_flag;
+ reset_qp_y = !s->start_ts ||
+ !s->dependent_slice_segment_flag ||
+ tile_x != ctb_to_tile_x(s, s->prev_ctb_x) ||
+ tile_y != ctb_to_tile_y(s, s->prev_ctb_y);
if (reset_qp_y)
write_prob(de, s);
program_slicecmds(de, s->slice_idx);
new_slice_segment(de, s);
new_entry_point(de, s, !s->dependent_slice_segment_flag, reset_qp_y,
- ctb_addr_ts);
-
- for (i = 0; i < s->sh->num_entry_point_offsets; i++) {
- int ctb_addr_rs = s->ctb_addr_ts_to_rs[ctb_addr_ts];
- int ctb_col = ctb_addr_rs % de->pic_width_in_ctbs_y;
- int ctb_row = ctb_addr_rs / de->pic_width_in_ctbs_y;
- int tile_x = ctb_to_tile(ctb_col, s->col_bd,
- s->num_tile_columns - 1);
- int tile_y =
- ctb_to_tile(ctb_row, s->row_bd, s->num_tile_rows - 1);
- int last_x = s->col_bd[tile_x + 1] - 1;
- int last_y = s->row_bd[tile_y + 1] - 1;
+ PAUSE_MODE_TILE,
+ tile_x, tile_y, s->start_ctb_x, s->start_ctb_y,
+ s->slice_qp, slice_reg_const(s));
+ /*
+ * If this is the last slice then fill in the other tile entries
+ * now, otherwise this will be done at the start of the next slice
+ * when it will be known where this slice finishes
+ */
+ if (s->frame_end) {
+ tile_entry_fill(de, s,
+ s->tile_width - 1,
+ s->tile_height - 1);
p1_apb_write(de, RPI_STATUS,
- 2 + (last_x << 5) + (last_y << 18));
- write_prob(de, s);
- ctb_addr_ts += s->column_width[tile_x] * s->row_height[tile_y];
- new_entry_point(de, s, 0, 1, ctb_addr_ts);
+ 1 | ((s->ctb_width - 1) << 5) |
+ ((s->ctb_height - 1) << 18));
}
}
@@ -1132,13 +1159,12 @@ static void decode_slice(struct rpivid_d
// Scaling factors
static void expand_scaling_list(const unsigned int size_id,
- const unsigned int matrix_id, u8 *const dst0,
+ u8 *const dst0,
const u8 *const src0, uint8_t dc)
{
u8 *d;
unsigned int x, y;
- // FIXME: matrix_id is unused ?
switch (size_id) {
case 0:
memcpy(dst0, src0, 16);
@@ -1199,24 +1225,20 @@ static void populate_scaling_factors(con
unsigned int mid;
for (mid = 0; mid < 6; mid++)
- expand_scaling_list(0, mid,
- de->scaling_factors +
+ expand_scaling_list(0, de->scaling_factors +
scaling_factor_offsets[0][mid],
sl->scaling_list_4x4[mid], 0);
for (mid = 0; mid < 6; mid++)
- expand_scaling_list(1, mid,
- de->scaling_factors +
+ expand_scaling_list(1, de->scaling_factors +
scaling_factor_offsets[1][mid],
sl->scaling_list_8x8[mid], 0);
for (mid = 0; mid < 6; mid++)
- expand_scaling_list(2, mid,
- de->scaling_factors +
+ expand_scaling_list(2, de->scaling_factors +
scaling_factor_offsets[2][mid],
sl->scaling_list_16x16[mid],
sl->scaling_list_dc_coef_16x16[mid]);
- for (mid = 0; mid < 2; mid += 1)
- expand_scaling_list(3, mid,
- de->scaling_factors +
+ for (mid = 0; mid < 2; mid++)
+ expand_scaling_list(3, de->scaling_factors +
scaling_factor_offsets[3][mid],
sl->scaling_list_32x32[mid],
sl->scaling_list_dc_coef_32x32[mid]);
@@ -1228,8 +1250,6 @@ static void free_ps_info(struct rpivid_d
s->ctb_addr_rs_to_ts = NULL;
kfree(s->ctb_addr_ts_to_rs);
s->ctb_addr_ts_to_rs = NULL;
- kfree(s->tile_id);
- s->tile_id = NULL;
kfree(s->col_bd);
s->col_bd = NULL;
@@ -1237,10 +1257,52 @@ static void free_ps_info(struct rpivid_d
s->row_bd = NULL;
}
+static unsigned int tile_width(const struct rpivid_dec_state *const s,
+ const unsigned int t_x)
+{
+ return s->col_bd[t_x + 1] - s->col_bd[t_x];
+}
+
+static unsigned int tile_height(const struct rpivid_dec_state *const s,
+ const unsigned int t_y)
+{
+ return s->row_bd[t_y + 1] - s->row_bd[t_y];
+}
+
+static void fill_rs_to_ts(struct rpivid_dec_state *const s)
+{
+ unsigned int ts = 0;
+ unsigned int t_y;
+ unsigned int tr_rs = 0;
+
+ for (t_y = 0; t_y != s->tile_height; ++t_y) {
+ const unsigned int t_h = tile_height(s, t_y);
+ unsigned int t_x;
+ unsigned int tc_rs = tr_rs;
+
+ for (t_x = 0; t_x != s->tile_width; ++t_x) {
+ const unsigned int t_w = tile_width(s, t_x);
+ unsigned int y;
+ unsigned int rs = tc_rs;
+
+ for (y = 0; y != t_h; ++y) {
+ unsigned int x;
+
+ for (x = 0; x != t_w; ++x) {
+ s->ctb_addr_rs_to_ts[rs + x] = ts;
+ s->ctb_addr_ts_to_rs[ts] = rs + x;
+ ++ts;
+ }
+ rs += s->ctb_width;
+ }
+ tc_rs += t_w;
+ }
+ tr_rs += t_h * s->ctb_width;
+ }
+}
+
static int updated_ps(struct rpivid_dec_state *const s)
{
- unsigned int ctb_addr_rs;
- int j, x, y, tile_id;
unsigned int i;
free_ps_info(s);
@@ -1259,104 +1321,49 @@ static int updated_ps(struct rpivid_dec_
// Inferred parameters
+ s->ctb_addr_rs_to_ts = kmalloc_array(s->ctb_size,
+ sizeof(*s->ctb_addr_rs_to_ts),
+ GFP_KERNEL);
+ s->ctb_addr_ts_to_rs = kmalloc_array(s->ctb_size,
+ sizeof(*s->ctb_addr_ts_to_rs),
+ GFP_KERNEL);
+
if (!(s->pps.flags & V4L2_HEVC_PPS_FLAG_TILES_ENABLED)) {
- s->num_tile_columns = 1;
- s->num_tile_rows = 1;
- s->column_width[0] = s->ctb_width;
- s->row_height[0] = s->ctb_height;
+ s->tile_width = 1;
+ s->tile_height = 1;
} else {
- s->num_tile_columns = s->pps.num_tile_columns_minus1 + 1;
- s->num_tile_rows = s->pps.num_tile_rows_minus1 + 1;
- for (i = 0; i < s->num_tile_columns; ++i)
- s->column_width[i] = s->pps.column_width_minus1[i] + 1;
- for (i = 0; i < s->num_tile_rows; ++i)
- s->row_height[i] = s->pps.row_height_minus1[i] + 1;
+ s->tile_width = s->pps.num_tile_columns_minus1 + 1;
+ s->tile_height = s->pps.num_tile_rows_minus1 + 1;
}
- s->col_bd = kmalloc((s->num_tile_columns + 1) * sizeof(*s->col_bd),
+ s->col_bd = kmalloc((s->tile_width + 1) * sizeof(*s->col_bd),
GFP_KERNEL);
- s->row_bd = kmalloc((s->num_tile_rows + 1) * sizeof(*s->row_bd),
+ s->row_bd = kmalloc((s->tile_height + 1) * sizeof(*s->row_bd),
GFP_KERNEL);
s->col_bd[0] = 0;
- for (i = 0; i < s->num_tile_columns; i++)
- s->col_bd[i + 1] = s->col_bd[i] + s->column_width[i];
+ for (i = 1; i < s->tile_width; i++)
+ s->col_bd[i] = s->col_bd[i - 1] +
+ s->pps.column_width_minus1[i - 1] + 1;
+ s->col_bd[s->tile_width] = s->ctb_width;
s->row_bd[0] = 0;
- for (i = 0; i < s->num_tile_rows; i++)
- s->row_bd[i + 1] = s->row_bd[i] + s->row_height[i];
+ for (i = 1; i < s->tile_height; i++)
+ s->row_bd[i] = s->row_bd[i - 1] +
+ s->pps.row_height_minus1[i - 1] + 1;
+ s->row_bd[s->tile_height] = s->ctb_height;
- s->ctb_addr_rs_to_ts = kmalloc_array(s->ctb_size,
- sizeof(*s->ctb_addr_rs_to_ts),
- GFP_KERNEL);
- s->ctb_addr_ts_to_rs = kmalloc_array(s->ctb_size,
- sizeof(*s->ctb_addr_ts_to_rs),
- GFP_KERNEL);
- s->tile_id = kmalloc_array(s->ctb_size, sizeof(*s->tile_id),
- GFP_KERNEL);
-
- for (ctb_addr_rs = 0; ctb_addr_rs < s->ctb_size; ctb_addr_rs++) {
- int tb_x = ctb_addr_rs % s->ctb_width;
- int tb_y = ctb_addr_rs / s->ctb_width;
- int tile_x = 0;
- int tile_y = 0;
- int val = 0;
-
- for (i = 0; i < s->num_tile_columns; i++) {
- if (tb_x < s->col_bd[i + 1]) {
- tile_x = i;
- break;
- }
- }
-
- for (i = 0; i < s->num_tile_rows; i++) {
- if (tb_y < s->row_bd[i + 1]) {
- tile_y = i;
- break;
- }
- }
-
- for (i = 0; i < tile_x; i++)
- val += s->row_height[tile_y] * s->column_width[i];
- for (i = 0; i < tile_y; i++)
- val += s->ctb_width * s->row_height[i];
-
- val += (tb_y - s->row_bd[tile_y]) * s->column_width[tile_x] +
- tb_x - s->col_bd[tile_x];
-
- s->ctb_addr_rs_to_ts[ctb_addr_rs] = val;
- s->ctb_addr_ts_to_rs[val] = ctb_addr_rs;
- }
-
- for (j = 0, tile_id = 0; j < s->num_tile_rows; j++)
- for (i = 0; i < s->num_tile_columns; i++, tile_id++)
- for (y = s->row_bd[j]; y < s->row_bd[j + 1]; y++)
- for (x = s->col_bd[i];
- x < s->col_bd[i + 1];
- x++)
- s->tile_id[s->ctb_addr_rs_to_ts
- [y * s->ctb_width +
- x]] = tile_id;
+ fill_rs_to_ts(s);
return 0;
}
-static int frame_end(struct rpivid_dev *const dev,
- struct rpivid_dec_env *const de,
- const struct rpivid_dec_state *const s)
-{
- const unsigned int last_x = s->col_bd[s->num_tile_columns] - 1;
- const unsigned int last_y = s->row_bd[s->num_tile_rows] - 1;
- size_t cmd_size;
-
- if (s->pps.flags & V4L2_HEVC_PPS_FLAG_ENTROPY_CODING_SYNC_ENABLED) {
- if (de->wpp_entry_x < 2 && de->pic_width_in_ctbs_y > 2)
- wpp_pause(de, last_y);
- }
- p1_apb_write(de, RPI_STATUS, 1 + (last_x << 5) + (last_y << 18));
-
+static int write_cmd_buffer(struct rpivid_dev *const dev,
+ struct rpivid_dec_env *const de,
+ const struct rpivid_dec_state *const s)
+{
// Copy commands out to dma buf
- cmd_size = de->cmd_len * sizeof(de->cmd_fifo[0]);
+ const size_t cmd_size = de->cmd_len * sizeof(de->cmd_fifo[0]);
if (!de->cmd_copy_gptr->ptr || cmd_size > de->cmd_copy_gptr->size) {
size_t cmd_alloc = round_up_size(cmd_size);
@@ -1521,18 +1528,19 @@ static void rpivid_h265_setup(struct rpi
struct rpivid_q_aux *dpb_q_aux[V4L2_HEVC_DPB_ENTRIES_NUM_MAX];
struct rpivid_dec_state *const s = ctx->state;
struct vb2_queue *vq;
- struct rpivid_dec_env *de;
- int ctb_addr_ts;
+ struct rpivid_dec_env *de = ctx->dec0;
+ unsigned int prev_rs;
unsigned int i;
int use_aux;
bool slice_temporal_mvp;
+ xtrace_in(dev, de);
+
pred_weight_table = &sh->pred_weight_table;
s->frame_end =
((run->src->flags & V4L2_BUF_FLAG_M2M_HOLD_CAPTURE_BUF) == 0);
- de = ctx->dec0;
slice_temporal_mvp = (sh->flags &
V4L2_HEVC_SLICE_PARAMS_FLAG_SLICE_TEMPORAL_MVP_ENABLED);
@@ -1662,6 +1670,13 @@ static void rpivid_h265_setup(struct rpi
s->sps.pic_height_in_luma_samples);
goto fail;
}
+ if ((s->tile_width != 1 || s->tile_height != 1) &&
+ (s->pps.flags &
+ V4L2_HEVC_PPS_FLAG_ENTROPY_CODING_SYNC_ENABLED)) {
+ v4l2_warn(&dev->v4l2_dev,
+ "Tiles + WPP not supported\n");
+ goto fail;
+ }
// Fill in ref planes with our address s.t. if we mess
// up refs somehow then we still have a valid address
@@ -1760,15 +1775,24 @@ static void rpivid_h265_setup(struct rpi
if (s->sps.flags & V4L2_HEVC_SPS_FLAG_SCALING_LIST_ENABLED)
populate_scaling_factors(run, de, s);
- ctb_addr_ts = s->ctb_addr_rs_to_ts[sh->slice_segment_addr];
+ // Calc all the random coord info to avoid repeated conversion in/out
+ s->start_ts = s->ctb_addr_rs_to_ts[sh->slice_segment_addr];
+ s->start_ctb_x = sh->slice_segment_addr % de->pic_width_in_ctbs_y;
+ s->start_ctb_y = sh->slice_segment_addr / de->pic_width_in_ctbs_y;
+ // Last CTB of previous slice
+ prev_rs = !s->start_ts ? 0 : s->ctb_addr_ts_to_rs[s->start_ts - 1];
+ s->prev_ctb_x = prev_rs % de->pic_width_in_ctbs_y;
+ s->prev_ctb_y = prev_rs / de->pic_width_in_ctbs_y;
if ((s->pps.flags & V4L2_HEVC_PPS_FLAG_ENTROPY_CODING_SYNC_ENABLED))
- wpp_decode_slice(de, s, sh, ctb_addr_ts);
+ wpp_decode_slice(de, s);
else
- decode_slice(de, s, sh, ctb_addr_ts);
+ decode_slice(de, s);
- if (!s->frame_end)
+ if (!s->frame_end) {
+ xtrace_ok(dev, de);
return;
+ }
// Frame end
memset(dpb_q_aux, 0,
@@ -1776,8 +1800,9 @@ static void rpivid_h265_setup(struct rpi
/*
* Need Aux ents for all (ref) DPB ents if temporal MV could
* be enabled for any pic
- * ** At the moment we have aux ents for all pics whether or not
- * they are ref
+ * ** At the moment we create aux ents for all pics whether or not
+ * they are ref - they should then be discarded by the DPB-aux
+ * garbage collection code
*/
use_aux = ((s->sps.flags &
V4L2_HEVC_SPS_FLAG_SPS_TEMPORAL_MVP_ENABLED) != 0);
@@ -1795,7 +1820,7 @@ static void rpivid_h265_setup(struct rpi
}
// v4l2_info(&dev->v4l2_dev, "rpivid_h265_end of frame\n");
- if (frame_end(dev, de, s))
+ if (write_cmd_buffer(dev, de, s))
goto fail;
for (i = 0; i < sh->num_active_dpb_entries; ++i) {
@@ -1876,6 +1901,7 @@ static void rpivid_h265_setup(struct rpi
}
de->state = RPIVID_DECODE_PHASE1;
+ xtrace_ok(dev, de);
return;
fail:
@@ -1883,6 +1909,7 @@ fail:
// Actual error reporting happens in Trigger
de->state = s->frame_end ? RPIVID_DECODE_ERROR_DONE :
RPIVID_DECODE_ERROR_CONTINUE;
+ xtrace_fail(dev, de);
}
//////////////////////////////////////////////////////////////////////////////
@@ -2210,6 +2237,10 @@ static int rpivid_h265_start(struct rpiv
size_t pu_alloc;
size_t coeff_alloc;
+#if DEBUG_TRACE_P1_CMD
+ p1_z = 0;
+#endif
+
// Generate a sanitised WxH for memory alloc
// Assume HD if unset
if (w == 0)