blob: 5b8389b982993a8eac7a01ac52c5ecd993e1c4ef [file] [log] [blame]
// SPDX-License-Identifier: GPL-2.0
/*
* Copyright (C) 2018 Linaro Ltd.
*
* Author: Stanimir Varbanov <stanimir.varbanov@linaro.org>
*/
#include <linux/bitops.h>
#include <linux/kernel.h>
#include "core.h"
#include "hfi_helper.h"
#include "hfi_parser.h"
typedef void (*func)(struct hfi_plat_caps *cap, const void *data,
unsigned int size);
static void init_codecs(struct venus_core *core)
{
struct hfi_plat_caps *caps = core->caps, *cap;
unsigned long bit;
for_each_set_bit(bit, &core->dec_codecs, MAX_CODEC_NUM) {
cap = &caps[core->codecs_count++];
cap->codec = BIT(bit);
cap->domain = VIDC_SESSION_TYPE_DEC;
cap->valid = false;
}
for_each_set_bit(bit, &core->enc_codecs, MAX_CODEC_NUM) {
cap = &caps[core->codecs_count++];
cap->codec = BIT(bit);
cap->domain = VIDC_SESSION_TYPE_ENC;
cap->valid = false;
}
}
static void for_each_codec(struct hfi_plat_caps *caps, unsigned int caps_num,
u32 codecs, u32 domain, func cb, void *data,
unsigned int size)
{
struct hfi_plat_caps *cap;
unsigned int i;
for (i = 0; i < caps_num; i++) {
cap = &caps[i];
if (cap->valid && cap->domain == domain)
continue;
if (cap->codec & codecs && cap->domain == domain)
cb(cap, data, size);
}
}
static void
fill_buf_mode(struct hfi_plat_caps *cap, const void *data, unsigned int num)
{
const u32 *type = data;
if (*type == HFI_BUFFER_MODE_DYNAMIC)
cap->cap_bufs_mode_dynamic = true;
}
static void
parse_alloc_mode(struct venus_core *core, u32 codecs, u32 domain, void *data)
{
struct hfi_buffer_alloc_mode_supported *mode = data;
u32 num_entries = mode->num_entries;
u32 *type;
if (num_entries > MAX_ALLOC_MODE_ENTRIES)
return;
type = mode->data;
while (num_entries--) {
if (mode->buffer_type == HFI_BUFFER_OUTPUT ||
mode->buffer_type == HFI_BUFFER_OUTPUT2)
for_each_codec(core->caps, ARRAY_SIZE(core->caps),
codecs, domain, fill_buf_mode, type, 1);
type++;
}
}
static void fill_profile_level(struct hfi_plat_caps *cap, const void *data,
unsigned int num)
{
const struct hfi_profile_level *pl = data;
memcpy(&cap->pl[cap->num_pl], pl, num * sizeof(*pl));
cap->num_pl += num;
}
static void
parse_profile_level(struct venus_core *core, u32 codecs, u32 domain, void *data)
{
struct hfi_profile_level_supported *pl = data;
struct hfi_profile_level *proflevel = pl->profile_level;
struct hfi_profile_level pl_arr[HFI_MAX_PROFILE_COUNT] = {};
if (pl->profile_count > HFI_MAX_PROFILE_COUNT)
return;
memcpy(pl_arr, proflevel, pl->profile_count * sizeof(*proflevel));
for_each_codec(core->caps, ARRAY_SIZE(core->caps), codecs, domain,
fill_profile_level, pl_arr, pl->profile_count);
}
static void
fill_caps(struct hfi_plat_caps *cap, const void *data, unsigned int num)
{
const struct hfi_capability *caps = data;
memcpy(&cap->caps[cap->num_caps], caps, num * sizeof(*caps));
cap->num_caps += num;
}
static void
parse_caps(struct venus_core *core, u32 codecs, u32 domain, void *data)
{
struct hfi_capabilities *caps = data;
struct hfi_capability *cap = caps->data;
u32 num_caps = caps->num_capabilities;
struct hfi_capability caps_arr[MAX_CAP_ENTRIES] = {};
if (num_caps > MAX_CAP_ENTRIES)
return;
memcpy(caps_arr, cap, num_caps * sizeof(*cap));
for_each_codec(core->caps, ARRAY_SIZE(core->caps), codecs, domain,
fill_caps, caps_arr, num_caps);
}
static void fill_raw_fmts(struct hfi_plat_caps *cap, const void *fmts,
unsigned int num_fmts)
{
const struct raw_formats *formats = fmts;
memcpy(&cap->fmts[cap->num_fmts], formats, num_fmts * sizeof(*formats));
cap->num_fmts += num_fmts;
}
static void
parse_raw_formats(struct venus_core *core, u32 codecs, u32 domain, void *data)
{
struct hfi_uncompressed_format_supported *fmt = data;
struct hfi_uncompressed_plane_info *pinfo = fmt->plane_info;
struct hfi_uncompressed_plane_constraints *constr;
struct raw_formats rawfmts[MAX_FMT_ENTRIES] = {};
u32 entries = fmt->format_entries;
unsigned int i = 0;
u32 num_planes;
while (entries) {
num_planes = pinfo->num_planes;
rawfmts[i].fmt = pinfo->format;
rawfmts[i].buftype = fmt->buffer_type;
i++;
if (pinfo->num_planes > MAX_PLANES)
break;
pinfo = (void *)pinfo + sizeof(*constr) * num_planes +
2 * sizeof(u32);
entries--;
}
for_each_codec(core->caps, ARRAY_SIZE(core->caps), codecs, domain,
fill_raw_fmts, rawfmts, i);
}
static void parse_codecs(struct venus_core *core, void *data)
{
struct hfi_codec_supported *codecs = data;
core->dec_codecs = codecs->dec_codecs;
core->enc_codecs = codecs->enc_codecs;
if (IS_V1(core)) {
core->dec_codecs &= ~HFI_VIDEO_CODEC_HEVC;
core->dec_codecs &= ~HFI_VIDEO_CODEC_SPARK;
core->enc_codecs &= ~HFI_VIDEO_CODEC_HEVC;
}
}
static void parse_max_sessions(struct venus_core *core, const void *data)
{
const struct hfi_max_sessions_supported *sessions = data;
core->max_sessions_supported = sessions->max_sessions;
}
static void parse_codecs_mask(u32 *codecs, u32 *domain, void *data)
{
struct hfi_codec_mask_supported *mask = data;
*codecs = mask->codecs;
*domain = mask->video_domains;
}
static void parser_init(struct venus_inst *inst, u32 *codecs, u32 *domain)
{
if (!inst || !IS_V1(inst->core))
return;
*codecs = inst->hfi_codec;
*domain = inst->session_type;
}
static void parser_fini(struct venus_inst *inst, u32 codecs, u32 domain)
{
struct hfi_plat_caps *caps, *cap;
unsigned int i;
u32 dom;
if (!inst || !IS_V1(inst->core))
return;
caps = inst->core->caps;
dom = inst->session_type;
for (i = 0; i < MAX_CODEC_NUM; i++) {
cap = &caps[i];
if (cap->codec & codecs && cap->domain == dom)
cap->valid = true;
}
}
static int hfi_platform_parser(struct venus_core *core, struct venus_inst *inst)
{
const struct hfi_platform *plat;
const struct hfi_plat_caps *caps = NULL;
u32 enc_codecs, dec_codecs, count = 0;
unsigned int entries;
plat = hfi_platform_get(core->res->hfi_version);
if (!plat)
return -EINVAL;
if (inst)
return 0;
if (plat->codecs)
plat->codecs(&enc_codecs, &dec_codecs, &count);
if (plat->capabilities)
caps = plat->capabilities(&entries);
if (!caps || !entries || !count)
return -EINVAL;
core->enc_codecs = enc_codecs;
core->dec_codecs = dec_codecs;
core->codecs_count = count;
core->max_sessions_supported = MAX_SESSIONS;
memset(core->caps, 0, sizeof(*caps) * MAX_CODEC_NUM);
memcpy(core->caps, caps, sizeof(*caps) * entries);
return 0;
}
u32 hfi_parser(struct venus_core *core, struct venus_inst *inst, void *buf,
u32 size)
{
unsigned int words_count = size >> 2;
u32 *word = buf, *data, codecs = 0, domain = 0;
int ret;
ret = hfi_platform_parser(core, inst);
if (!ret)
return HFI_ERR_NONE;
if (size % 4)
return HFI_ERR_SYS_INSUFFICIENT_RESOURCES;
parser_init(inst, &codecs, &domain);
if (core->res->hfi_version > HFI_VERSION_1XX) {
core->codecs_count = 0;
memset(core->caps, 0, sizeof(core->caps));
}
while (words_count) {
data = word + 1;
switch (*word) {
case HFI_PROPERTY_PARAM_CODEC_SUPPORTED:
parse_codecs(core, data);
init_codecs(core);
break;
case HFI_PROPERTY_PARAM_MAX_SESSIONS_SUPPORTED:
parse_max_sessions(core, data);
break;
case HFI_PROPERTY_PARAM_CODEC_MASK_SUPPORTED:
parse_codecs_mask(&codecs, &domain, data);
break;
case HFI_PROPERTY_PARAM_UNCOMPRESSED_FORMAT_SUPPORTED:
parse_raw_formats(core, codecs, domain, data);
break;
case HFI_PROPERTY_PARAM_CAPABILITY_SUPPORTED:
parse_caps(core, codecs, domain, data);
break;
case HFI_PROPERTY_PARAM_PROFILE_LEVEL_SUPPORTED:
parse_profile_level(core, codecs, domain, data);
break;
case HFI_PROPERTY_PARAM_BUFFER_ALLOC_MODE_SUPPORTED:
parse_alloc_mode(core, codecs, domain, data);
break;
default:
break;
}
word++;
words_count--;
}
if (!core->max_sessions_supported)
core->max_sessions_supported = MAX_SESSIONS;
parser_fini(inst, codecs, domain);
return HFI_ERR_NONE;
}