hantro_vp9.c source code [linux/drivers/media/platform/verisilicon/hantro_vp9.c]

1	// SPDX-License-Identifier: GPL-2.0
2	/*
3	* Hantro VP9 codec driver
4	*
5	* Copyright (C) 2021 Collabora Ltd.
6	*/
7
8	#include <linux/types.h>
9	#include <media/v4l2-mem2mem.h>
10
11	#include "hantro.h"
12	#include "hantro_hw.h"
13	#include "hantro_vp9.h"
14
15	#define POW2(x) (1 << (x))
16
17	#define MAX_LOG2_TILE_COLUMNS 6
18	#define MAX_NUM_TILE_COLS POW2(MAX_LOG2_TILE_COLUMNS)
19	#define MAX_TILE_COLS 20
20	#define MAX_TILE_ROWS 22
21
22	static size_t hantro_vp9_tile_filter_size(unsigned int height)
23	{
24	u32 h, height32, size;
25
26	h = roundup(height, `8`);
27
28	height32 = roundup(h, `64`);
29	size = `24` * height32 * (MAX_NUM_TILE_COLS - `1`); / luma: 8, chroma: 8 + 8 /
30
31	return size;
32	}
33
34	static size_t hantro_vp9_bsd_control_size(unsigned int height)
35	{
36	u32 h, height32;
37
38	h = roundup(height, `8`);
39	height32 = roundup(h, `64`);
40
41	return `16` * (height32 / `4`) * (MAX_NUM_TILE_COLS - `1`);
42	}
43
44	static size_t hantro_vp9_segment_map_size(unsigned int width, unsigned int height)
45	{
46	u32 w, h;
47	int num_ctbs;
48
49	w = roundup(width, `8`);
50	h = roundup(height, `8`);
51	num_ctbs = ((w + `63`) / `64`) * ((h + `63`) / `64`);
52
53	return num_ctbs * `32`;
54	}
55
56	static inline size_t hantro_vp9_prob_tab_size(void)
57	{
58	return roundup(sizeof(struct hantro_g2_all_probs), `16`);
59	}
60
61	static inline size_t hantro_vp9_count_tab_size(void)
62	{
63	return roundup(sizeof(struct symbol_counts), `16`);
64	}
65
66	static inline size_t hantro_vp9_tile_info_size(void)
67	{
68	return roundup((MAX_TILE_COLS * MAX_TILE_ROWS * `4` * sizeof(u16) + `15` + `16`) & ~`0xf`, `16`);
69	}
70
71	static void get_coeffs_arr(struct* symbol_counts cnts, int* i, int j, int k, int l, int m)
72	{
73	if (i == `0`)
74	return &cnts->count_coeffs[j][k][l][m];
75
76	if (i == `1`)
77	return &cnts->count_coeffs8x8[j][k][l][m];
78
79	if (i == `2`)
80	return &cnts->count_coeffs16x16[j][k][l][m];
81
82	if (i == `3`)
83	return &cnts->count_coeffs32x32[j][k][l][m];
84
85	return NULL;
86	}
87
88	static void get_eobs1(struct* symbol_counts cnts, int* i, int j, int k, int l, int m)
89	{
90	if (i == `0`)
91	return &cnts->count_coeffs[j][k][l][m][`3`];
92
93	if (i == `1`)
94	return &cnts->count_coeffs8x8[j][k][l][m][`3`];
95
96	if (i == `2`)
97	return &cnts->count_coeffs16x16[j][k][l][m][`3`];
98
99	if (i == `3`)
100	return &cnts->count_coeffs32x32[j][k][l][m][`3`];
101
102	return NULL;
103	}
104
105	#define INNER_LOOP \
106	do { \
107	for (m = 0; m < ARRAY_SIZE(vp9_ctx->cnts.coeff[i][0][0][0]); ++m) { \
108	vp9_ctx->cnts.coeff[i][j][k][l][m] = \
109	get_coeffs_arr(cnts, i, j, k, l, m); \
110	vp9_ctx->cnts.eob[i][j][k][l][m][0] = \
111	&cnts->count_eobs[i][j][k][l][m]; \
112	vp9_ctx->cnts.eob[i][j][k][l][m][1] = \
113	get_eobs1(cnts, i, j, k, l, m); \
114	} \
115	} while (0)
116
117	static void init_v4l2_vp9_count_tbl(struct hantro_ctx *ctx)
118	{
119	struct hantro_vp9_dec_hw_ctx *vp9_ctx = &ctx->vp9_dec;
120	struct symbol_counts *cnts = vp9_ctx->misc.cpu + vp9_ctx->ctx_counters_offset;
121	int i, j, k, l, m;
122
123	vp9_ctx->cnts.partition = &cnts->partition_counts;
124	vp9_ctx->cnts.skip = &cnts->mbskip_count;
125	vp9_ctx->cnts.intra_inter = &cnts->intra_inter_count;
126	vp9_ctx->cnts.tx32p = &cnts->tx32x32_count;
127	/*
128	* g2 hardware uses tx16x16_count[2][3], while the api
129	* expects tx16p[2][4], so this must be explicitly copied
130	* into vp9_ctx->cnts.tx16p when passing the data to the
131	* vp9 library function
132	*/
133	vp9_ctx->cnts.tx8p = &cnts->tx8x8_count;
134
135	vp9_ctx->cnts.y_mode = &cnts->sb_ymode_counts;
136	vp9_ctx->cnts.uv_mode = &cnts->uv_mode_counts;
137	vp9_ctx->cnts.comp = &cnts->comp_inter_count;
138	vp9_ctx->cnts.comp_ref = &cnts->comp_ref_count;
139	vp9_ctx->cnts.single_ref = &cnts->single_ref_count;
140	vp9_ctx->cnts.filter = &cnts->switchable_interp_counts;
141	vp9_ctx->cnts.mv_joint = &cnts->mv_counts.joints;
142	vp9_ctx->cnts.sign = &cnts->mv_counts.sign;
143	vp9_ctx->cnts.classes = &cnts->mv_counts.classes;
144	vp9_ctx->cnts.class0 = &cnts->mv_counts.class0;
145	vp9_ctx->cnts.bits = &cnts->mv_counts.bits;
146	vp9_ctx->cnts.class0_fp = &cnts->mv_counts.class0_fp;
147	vp9_ctx->cnts.fp = &cnts->mv_counts.fp;
148	vp9_ctx->cnts.class0_hp = &cnts->mv_counts.class0_hp;
149	vp9_ctx->cnts.hp = &cnts->mv_counts.hp;
150
151	for (i = `0`; i < ARRAY_SIZE(vp9_ctx->cnts.coeff); ++i)
152	for (j = `0`; j < ARRAY_SIZE(vp9_ctx->cnts.coeff[i]); ++j)
153	for (k = `0`; k < ARRAY_SIZE(vp9_ctx->cnts.coeff[i][`0`]); ++k)
154	for (l = `0`; l < ARRAY_SIZE(vp9_ctx->cnts.coeff[i][`0`][`0`]); ++l)
155	INNER_LOOP;
156	}
157
158	int hantro_vp9_dec_init(struct hantro_ctx *ctx)
159	{
160	struct hantro_dev *vpu = ctx->dev;
161	const struct hantro_variant *variant = vpu->variant;
162	struct hantro_vp9_dec_hw_ctx *vp9_dec = &ctx->vp9_dec;
163	struct hantro_aux_buf *tile_edge = &vp9_dec->tile_edge;
164	struct hantro_aux_buf *segment_map = &vp9_dec->segment_map;
165	struct hantro_aux_buf *misc = &vp9_dec->misc;
166	u32 i, max_width, max_height, size;
167
168	if (variant->num_dec_fmts < `1`)
169	return -EINVAL;
170
171	for (i = `0`; i < variant->num_dec_fmts; ++i)
172	if (variant->dec_fmts[i].fourcc == V4L2_PIX_FMT_VP9_FRAME)
173	break;
174
175	if (i == variant->num_dec_fmts)
176	return -EINVAL;
177
178	max_width = vpu->variant->dec_fmts[i].frmsize.max_width;
179	max_height = vpu->variant->dec_fmts[i].frmsize.max_height;
180
181	size = hantro_vp9_tile_filter_size(height: max_height);
182	vp9_dec->bsd_ctrl_offset = size;
183	size += hantro_vp9_bsd_control_size(height: max_height);
184
185	tile_edge->cpu = dma_alloc_coherent(dev: vpu->dev, size, dma_handle: &tile_edge->dma, GFP_KERNEL);
186	if (!tile_edge->cpu)
187	return -ENOMEM;
188
189	tile_edge->size = size;
190	memset(tile_edge->cpu, `0`, size);
191
192	size = hantro_vp9_segment_map_size(width: max_width, height: max_height);
193	vp9_dec->segment_map_size = size;
194	size = `2`; /* we need two areas of this size, used alternately /
195
196	segment_map->cpu = dma_alloc_coherent(dev: vpu->dev, size, dma_handle: &segment_map->dma, GFP_KERNEL);
197	if (!segment_map->cpu)
198	goto err_segment_map;
199
200	segment_map->size = size;
201	memset(segment_map->cpu, `0`, size);
202
203	size = hantro_vp9_prob_tab_size();
204	vp9_dec->ctx_counters_offset = size;
205	size += hantro_vp9_count_tab_size();
206	vp9_dec->tile_info_offset = size;
207	size += hantro_vp9_tile_info_size();
208
209	misc->cpu = dma_alloc_coherent(dev: vpu->dev, size, dma_handle: &misc->dma, GFP_KERNEL);
210	if (!misc->cpu)
211	goto err_misc;
212
213	misc->size = size;
214	memset(misc->cpu, `0`, size);
215
216	init_v4l2_vp9_count_tbl(ctx);
217
218	return `0`;
219
220	err_misc:
221	dma_free_coherent(dev: vpu->dev, size: segment_map->size, cpu_addr: segment_map->cpu, dma_handle: segment_map->dma);
222
223	err_segment_map:
224	dma_free_coherent(dev: vpu->dev, size: tile_edge->size, cpu_addr: tile_edge->cpu, dma_handle: tile_edge->dma);
225
226	return -ENOMEM;
227	}
228
229	void hantro_vp9_dec_exit(struct hantro_ctx *ctx)
230	{
231	struct hantro_dev *vpu = ctx->dev;
232	struct hantro_vp9_dec_hw_ctx *vp9_dec = &ctx->vp9_dec;
233	struct hantro_aux_buf *tile_edge = &vp9_dec->tile_edge;
234	struct hantro_aux_buf *segment_map = &vp9_dec->segment_map;
235	struct hantro_aux_buf *misc = &vp9_dec->misc;
236
237	dma_free_coherent(dev: vpu->dev, size: misc->size, cpu_addr: misc->cpu, dma_handle: misc->dma);
238	dma_free_coherent(dev: vpu->dev, size: segment_map->size, cpu_addr: segment_map->cpu, dma_handle: segment_map->dma);
239	dma_free_coherent(dev: vpu->dev, size: tile_edge->size, cpu_addr: tile_edge->cpu, dma_handle: tile_edge->dma);
240	}
241

source code of linux/drivers/media/platform/verisilicon/hantro_vp9.c