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gerrit-public.fairphone.software / kernel / msm-4.9 / 3f54f3b513321ef57e23f74e2bd7c716258f3395 / . / drivers / media / platform / msm / vidc_3x / hfi_response_handler.c
blob: 654d9fa936922344bf53e44c4f5901c0e0db9bd5 [file] [log] [blame]
/* Copyright (c) 2012-2019, The Linux Foundation. All rights reserved.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 and
* only version 2 as published by the Free Software Foundation.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
*/
#include <linux/bitops.h>
#include <linux/slab.h>
#include <linux/list.h>
#include <linux/interrupt.h>
#include <linux/hash.h>
#include <soc/qcom/smem.h>
#include "vidc_hfi_helper.h"
#include "vidc_hfi_io.h"
#include "msm_vidc_debug.h"
#include "vidc_hfi.h"
static enum vidc_status hfi_parse_init_done_properties(
struct msm_vidc_capability *capability,
u32 num_sessions, u8 *data_ptr, u32 num_properties,
u32 rem_bytes, u32 codec, u32 domain);
static enum vidc_status hfi_map_err_status(u32 hfi_err)
{
enum vidc_status vidc_err;
switch (hfi_err) {
case HFI_ERR_NONE:
case HFI_ERR_SESSION_SAME_STATE_OPERATION:
vidc_err = VIDC_ERR_NONE;
break;
case HFI_ERR_SYS_FATAL:
vidc_err = VIDC_ERR_HW_FATAL;
break;
case HFI_ERR_SYS_VERSION_MISMATCH:
case HFI_ERR_SYS_INVALID_PARAMETER:
case HFI_ERR_SYS_SESSION_ID_OUT_OF_RANGE:
case HFI_ERR_SESSION_INVALID_PARAMETER:
case HFI_ERR_SESSION_INVALID_SESSION_ID:
case HFI_ERR_SESSION_INVALID_STREAM_ID:
vidc_err = VIDC_ERR_BAD_PARAM;
break;
case HFI_ERR_SYS_INSUFFICIENT_RESOURCES:
case HFI_ERR_SYS_UNSUPPORTED_DOMAIN:
case HFI_ERR_SYS_UNSUPPORTED_CODEC:
case HFI_ERR_SESSION_UNSUPPORTED_PROPERTY:
case HFI_ERR_SESSION_UNSUPPORTED_SETTING:
case HFI_ERR_SESSION_INSUFFICIENT_RESOURCES:
case HFI_ERR_SESSION_UNSUPPORTED_STREAM:
vidc_err = VIDC_ERR_NOT_SUPPORTED;
break;
case HFI_ERR_SYS_MAX_SESSIONS_REACHED:
vidc_err = VIDC_ERR_MAX_CLIENTS;
break;
case HFI_ERR_SYS_SESSION_IN_USE:
vidc_err = VIDC_ERR_CLIENT_PRESENT;
break;
case HFI_ERR_SESSION_FATAL:
vidc_err = VIDC_ERR_CLIENT_FATAL;
break;
case HFI_ERR_SESSION_BAD_POINTER:
vidc_err = VIDC_ERR_BAD_PARAM;
break;
case HFI_ERR_SESSION_INCORRECT_STATE_OPERATION:
vidc_err = VIDC_ERR_BAD_STATE;
break;
case HFI_ERR_SESSION_STREAM_CORRUPT:
case HFI_ERR_SESSION_STREAM_CORRUPT_OUTPUT_STALLED:
vidc_err = VIDC_ERR_BITSTREAM_ERR;
break;
case HFI_ERR_SESSION_SYNC_FRAME_NOT_DETECTED:
vidc_err = VIDC_ERR_IFRAME_EXPECTED;
break;
case HFI_ERR_SESSION_START_CODE_NOT_FOUND:
vidc_err = VIDC_ERR_START_CODE_NOT_FOUND;
break;
case HFI_ERR_SESSION_EMPTY_BUFFER_DONE_OUTPUT_PENDING:
default:
vidc_err = VIDC_ERR_FAIL;
break;
}
return vidc_err;
}
static enum msm_vidc_pixel_depth get_hal_pixel_depth(u32 hfi_bit_depth)
{
switch (hfi_bit_depth) {
case HFI_BITDEPTH_8: return MSM_VIDC_BIT_DEPTH_8;
case HFI_BITDEPTH_9:
case HFI_BITDEPTH_10: return MSM_VIDC_BIT_DEPTH_10;
}
dprintk(VIDC_ERR, "Unsupported bit depth: %d\n", hfi_bit_depth);
return MSM_VIDC_BIT_DEPTH_UNSUPPORTED;
}
static inline int validate_pkt_size(u32 rem_size, u32 msg_size)
{
if (rem_size < msg_size) {
dprintk(VIDC_ERR, "%s: bad_pkt_size: %d\n",
__func__, rem_size);
return false;
}
return true;
}
static int hfi_process_sess_evt_seq_changed(u32 device_id,
struct hfi_msg_event_notify_packet *pkt,
struct msm_vidc_cb_info *info)
{
struct msm_vidc_cb_event event_notify = {0};
u32 num_properties_changed, rem_size;
struct hfi_frame_size *frame_sz;
struct hfi_profile_level *profile_level;
struct hfi_bit_depth *pixel_depth;
struct hfi_pic_struct *pic_struct;
u8 *data_ptr;
int prop_id;
enum msm_vidc_pixel_depth luma_bit_depth, chroma_bit_depth;
struct hfi_colour_space *colour_info;
/* Initialize pic_struct to unknown as default */
event_notify.pic_struct = MSM_VIDC_PIC_STRUCT_UNKNOWN;
if (!validate_pkt_size(pkt->size,
sizeof(struct hfi_msg_event_notify_packet)))
return -E2BIG;
event_notify.device_id = device_id;
event_notify.session_id = (void *)(uintptr_t)pkt->session_id;
event_notify.status = VIDC_ERR_NONE;
num_properties_changed = pkt->event_data2;
switch (pkt->event_data1) {
case HFI_EVENT_DATA_SEQUENCE_CHANGED_SUFFICIENT_BUFFER_RESOURCES:
event_notify.hal_event_type =
HAL_EVENT_SEQ_CHANGED_SUFFICIENT_RESOURCES;
break;
case HFI_EVENT_DATA_SEQUENCE_CHANGED_INSUFFICIENT_BUFFER_RESOURCES:
event_notify.hal_event_type =
HAL_EVENT_SEQ_CHANGED_INSUFFICIENT_RESOURCES;
break;
default:
break;
}
if (num_properties_changed) {
data_ptr = (u8 *) &pkt->rg_ext_event_data[0];
rem_size = pkt->size - sizeof(struct
hfi_msg_event_notify_packet) + sizeof(u32);
do {
if (!validate_pkt_size(rem_size, sizeof(u32)))
return -E2BIG;
prop_id = (int) *((u32 *)data_ptr);
rem_size -= sizeof(u32);
switch (prop_id) {
case HFI_PROPERTY_PARAM_FRAME_SIZE:
if (!validate_pkt_size(rem_size, sizeof(struct
hfi_frame_size)))
return -E2BIG;
data_ptr = data_ptr + sizeof(u32);
frame_sz =
(struct hfi_frame_size *) data_ptr;
event_notify.width = frame_sz->width;
event_notify.height = frame_sz->height;
dprintk(VIDC_DBG, "height: %d width: %d\n",
frame_sz->height, frame_sz->width);
data_ptr +=
sizeof(struct hfi_frame_size);
rem_size -= sizeof(struct hfi_frame_size);
break;
case HFI_PROPERTY_PARAM_PROFILE_LEVEL_CURRENT:
if (!validate_pkt_size(rem_size, sizeof(struct
hfi_profile_level)))
return -E2BIG;
data_ptr = data_ptr + sizeof(u32);
profile_level =
(struct hfi_profile_level *) data_ptr;
dprintk(VIDC_DBG, "profile: %d level: %d\n",
profile_level->profile,
profile_level->level);
data_ptr +=
sizeof(struct hfi_profile_level);
rem_size -= sizeof(struct hfi_profile_level);
break;
case HFI_PROPERTY_PARAM_VDEC_PIXEL_BITDEPTH:
if (!validate_pkt_size(rem_size, sizeof(struct
hfi_bit_depth)))
return -E2BIG;
data_ptr = data_ptr + sizeof(u32);
pixel_depth = (struct hfi_bit_depth *) data_ptr;
/*
* Luma and chroma can have different bitdepths.
* Driver should rely on luma and chroma
* bitdepth for determining output bitdepth
* type.
*
* pixel_depth->bitdepth will include luma
* bitdepth info in bits 0..15 and chroma
* bitdept in bits 16..31.
*/
luma_bit_depth = get_hal_pixel_depth(
pixel_depth->bit_depth &
GENMASK(15, 0));
chroma_bit_depth = get_hal_pixel_depth(
(pixel_depth->bit_depth &
GENMASK(31, 16)) >> 16);
if (luma_bit_depth == MSM_VIDC_BIT_DEPTH_10 ||
chroma_bit_depth ==
MSM_VIDC_BIT_DEPTH_10)
event_notify.bit_depth =
MSM_VIDC_BIT_DEPTH_10;
else
event_notify.bit_depth = luma_bit_depth;
dprintk(VIDC_DBG,
"bitdepth(%d), luma_bit_depth(%d), chroma_bit_depth(%d)\n",
event_notify.bit_depth, luma_bit_depth,
chroma_bit_depth);
data_ptr += sizeof(struct hfi_bit_depth);
rem_size -= sizeof(struct hfi_bit_depth);
break;
case HFI_PROPERTY_PARAM_VDEC_PIC_STRUCT:
if (!validate_pkt_size(rem_size, sizeof(struct
hfi_pic_struct)))
return -E2BIG;
data_ptr = data_ptr + sizeof(u32);
pic_struct = (struct hfi_pic_struct *) data_ptr;
event_notify.pic_struct =
pic_struct->progressive_only;
dprintk(VIDC_DBG,
"Progressive only flag: %d\n",
pic_struct->progressive_only);
data_ptr +=
sizeof(struct hfi_pic_struct);
rem_size -= sizeof(struct hfi_pic_struct);
break;
case HFI_PROPERTY_PARAM_VDEC_COLOUR_SPACE:
if (!validate_pkt_size(rem_size, sizeof(struct
hfi_colour_space)))
return -E2BIG;
data_ptr = data_ptr + sizeof(u32);
colour_info =
(struct hfi_colour_space *) data_ptr;
event_notify.colour_space =
colour_info->colour_space;
dprintk(VIDC_DBG,
"Colour space value is: %d\n",
colour_info->colour_space);
data_ptr +=
sizeof(struct hfi_colour_space);
rem_size -= sizeof(struct hfi_colour_space);
break;
break;
default:
dprintk(VIDC_ERR,
"%s cmd: %#x not supported\n",
__func__, prop_id);
break;
}
num_properties_changed--;
} while (num_properties_changed > 0);
}
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SESSION_EVENT_CHANGE,
.response.event = event_notify,
};
return 0;
}
static int hfi_process_evt_release_buffer_ref(u32 device_id,
struct hfi_msg_event_notify_packet *pkt,
struct msm_vidc_cb_info *info)
{
struct msm_vidc_cb_event event_notify = {0};
struct hfi_msg_release_buffer_ref_event_packet *data;
dprintk(VIDC_DBG,
"RECEIVED: EVENT_NOTIFY - release_buffer_reference\n");
if (sizeof(struct hfi_msg_event_notify_packet)
> pkt->size) {
dprintk(VIDC_ERR,
"hal_process_session_init_done: bad_pkt_size\n");
return -E2BIG;
}
if (pkt->size < sizeof(struct hfi_msg_event_notify_packet) - sizeof(u32)
+ sizeof(struct hfi_msg_release_buffer_ref_event_packet)) {
dprintk(VIDC_ERR,
"hfi_msg_release_buffer_ref_event: bad_pkt_size\n");
return -E2BIG;
}
data = (struct hfi_msg_release_buffer_ref_event_packet *)
pkt->rg_ext_event_data;
event_notify.device_id = device_id;
event_notify.session_id = (void *)(uintptr_t)pkt->session_id;
event_notify.status = VIDC_ERR_NONE;
event_notify.hal_event_type = HAL_EVENT_RELEASE_BUFFER_REFERENCE;
event_notify.packet_buffer = data->packet_buffer;
event_notify.extra_data_buffer = data->extra_data_buffer;
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SESSION_EVENT_CHANGE,
.response.event = event_notify,
};
return 0;
}
static int hfi_process_sys_error(u32 device_id, struct msm_vidc_cb_info *info)
{
struct msm_vidc_cb_cmd_done cmd_done = {0};
cmd_done.device_id = device_id;
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SYS_ERROR,
.response.cmd = cmd_done,
};
return 0;
}
static int hfi_process_session_error(u32 device_id,
struct hfi_msg_event_notify_packet *pkt,
struct msm_vidc_cb_info *info)
{
struct msm_vidc_cb_cmd_done cmd_done = {0};
cmd_done.device_id = device_id;
cmd_done.session_id = (void *)(uintptr_t)pkt->session_id;
cmd_done.status = hfi_map_err_status(pkt->event_data1);
dprintk(VIDC_INFO, "Received: SESSION_ERROR with event id : %d\n",
pkt->event_data1);
switch (pkt->event_data1) {
case HFI_ERR_SESSION_INVALID_SCALE_FACTOR:
case HFI_ERR_SESSION_UNSUPPORT_BUFFERTYPE:
case HFI_ERR_SESSION_UNSUPPORTED_SETTING:
case HFI_ERR_SESSION_UPSCALE_NOT_SUPPORTED:
cmd_done.status = VIDC_ERR_NONE;
dprintk(VIDC_INFO, "Non Fatal: HFI_EVENT_SESSION_ERROR\n");
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_RESPONSE_UNUSED,
.response.cmd = cmd_done,
};
return 0;
default:
dprintk(VIDC_ERR, "HFI_EVENT_SESSION_ERROR\n");
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SESSION_ERROR,
.response.cmd = cmd_done,
};
return 0;
}
}
static int hfi_process_event_notify(u32 device_id,
void *_pkt,
struct msm_vidc_cb_info *info)
{
struct hfi_msg_event_notify_packet *pkt = _pkt;
dprintk(VIDC_DBG, "Received: EVENT_NOTIFY\n");
if (pkt->size < sizeof(struct hfi_msg_event_notify_packet)) {
dprintk(VIDC_ERR, "Invalid Params\n");
return -E2BIG;
}
switch (pkt->event_id) {
case HFI_EVENT_SYS_ERROR:
dprintk(VIDC_ERR, "HFI_EVENT_SYS_ERROR: %d, %#x\n",
pkt->event_data1, pkt->event_data2);
return hfi_process_sys_error(device_id, info);
case HFI_EVENT_SESSION_ERROR:
dprintk(VIDC_INFO, "HFI_EVENT_SESSION_ERROR[%#x]\n",
pkt->session_id);
return hfi_process_session_error(device_id, pkt, info);
case HFI_EVENT_SESSION_SEQUENCE_CHANGED:
dprintk(VIDC_INFO, "HFI_EVENT_SESSION_SEQUENCE_CHANGED[%#x]\n",
pkt->session_id);
return hfi_process_sess_evt_seq_changed(device_id, pkt, info);
case HFI_EVENT_RELEASE_BUFFER_REFERENCE:
dprintk(VIDC_INFO, "HFI_EVENT_RELEASE_BUFFER_REFERENCE[%#x]\n",
pkt->session_id);
return hfi_process_evt_release_buffer_ref(device_id, pkt, info);
case HFI_EVENT_SESSION_PROPERTY_CHANGED:
default:
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_RESPONSE_UNUSED,
};
return 0;
}
}
static int hfi_process_sys_init_done(u32 device_id,
void *_pkt,
struct msm_vidc_cb_info *info)
{
struct hfi_msg_sys_init_done_packet *pkt = _pkt;
struct msm_vidc_cb_cmd_done cmd_done = {0};
enum vidc_status status = VIDC_ERR_NONE;
dprintk(VIDC_DBG, "RECEIVED: SYS_INIT_DONE\n");
if (sizeof(struct hfi_msg_sys_init_done_packet) > pkt->size) {
dprintk(VIDC_ERR, "%s: bad_pkt_size: %d\n", __func__,
pkt->size);
return -E2BIG;
}
if (!pkt->num_properties) {
dprintk(VIDC_ERR,
"hal_process_sys_init_done: no_properties\n");
status = VIDC_ERR_FAIL;
goto err_no_prop;
}
status = hfi_map_err_status(pkt->error_type);
if (status) {
dprintk(VIDC_ERR, "%s: status %#x\n",
__func__, status);
goto err_no_prop;
}
err_no_prop:
cmd_done.device_id = device_id;
cmd_done.session_id = NULL;
cmd_done.status = (u32)status;
cmd_done.size = sizeof(struct vidc_hal_sys_init_done);
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SYS_INIT_DONE,
.response.cmd = cmd_done,
};
return 0;
}
static int hfi_process_sys_rel_resource_done(u32 device_id,
void *_pkt,
struct msm_vidc_cb_info *info)
{
struct hfi_msg_sys_release_resource_done_packet *pkt = _pkt;
struct msm_vidc_cb_cmd_done cmd_done = {0};
enum vidc_status status = VIDC_ERR_NONE;
u32 pkt_size;
dprintk(VIDC_DBG, "RECEIVED: SYS_RELEASE_RESOURCE_DONE\n");
pkt_size = sizeof(struct hfi_msg_sys_release_resource_done_packet);
if (pkt_size > pkt->size) {
dprintk(VIDC_ERR,
"hal_process_sys_rel_resource_done: bad size: %d\n",
pkt->size);
return -E2BIG;
}
status = hfi_map_err_status(pkt->error_type);
cmd_done.device_id = device_id;
cmd_done.session_id = NULL;
cmd_done.status = (u32) status;
cmd_done.size = 0;
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SYS_RELEASE_RESOURCE_DONE,
.response.cmd = cmd_done,
};
return 0;
}
enum hal_capability get_hal_cap_type(u32 capability_type)
{
enum hal_capability hal_cap = 0;
switch (capability_type) {
case HFI_CAPABILITY_FRAME_WIDTH:
hal_cap = HAL_CAPABILITY_FRAME_WIDTH;
break;
case HFI_CAPABILITY_FRAME_HEIGHT:
hal_cap = HAL_CAPABILITY_FRAME_HEIGHT;
break;
case HFI_CAPABILITY_MBS_PER_FRAME:
hal_cap = HAL_CAPABILITY_MBS_PER_FRAME;
break;
case HFI_CAPABILITY_MBS_PER_SECOND:
hal_cap = HAL_CAPABILITY_MBS_PER_SECOND;
break;
case HFI_CAPABILITY_FRAMERATE:
hal_cap = HAL_CAPABILITY_FRAMERATE;
break;
case HFI_CAPABILITY_SCALE_X:
hal_cap = HAL_CAPABILITY_SCALE_X;
break;
case HFI_CAPABILITY_SCALE_Y:
hal_cap = HAL_CAPABILITY_SCALE_Y;
break;
case HFI_CAPABILITY_BITRATE:
hal_cap = HAL_CAPABILITY_BITRATE;
break;
case HFI_CAPABILITY_BFRAME:
hal_cap = HAL_CAPABILITY_BFRAME;
break;
case HFI_CAPABILITY_PEAKBITRATE:
hal_cap = HAL_CAPABILITY_PEAKBITRATE;
break;
case HFI_CAPABILITY_HIER_P_NUM_ENH_LAYERS:
hal_cap = HAL_CAPABILITY_HIER_P_NUM_ENH_LAYERS;
break;
case HFI_CAPABILITY_ENC_LTR_COUNT:
hal_cap = HAL_CAPABILITY_ENC_LTR_COUNT;
break;
case HFI_CAPABILITY_CP_OUTPUT2_THRESH:
hal_cap = HAL_CAPABILITY_SECURE_OUTPUT2_THRESHOLD;
break;
case HFI_CAPABILITY_HIER_B_NUM_ENH_LAYERS:
hal_cap = HAL_CAPABILITY_HIER_B_NUM_ENH_LAYERS;
break;
case HFI_CAPABILITY_LCU_SIZE:
hal_cap = HAL_CAPABILITY_LCU_SIZE;
break;
case HFI_CAPABILITY_HIER_P_HYBRID_NUM_ENH_LAYERS:
hal_cap = HAL_CAPABILITY_HIER_P_HYBRID_NUM_ENH_LAYERS;
break;
case HFI_CAPABILITY_MBS_PER_SECOND_POWERSAVE:
hal_cap = HAL_CAPABILITY_MBS_PER_SECOND_POWER_SAVE;
break;
default:
dprintk(VIDC_DBG, "%s: unknown capablity %#x\n",
__func__, capability_type);
break;
}
return hal_cap;
}
static inline void copy_cap_prop(
struct hfi_capability_supported *in,
struct msm_vidc_capability *capability)
{
struct hal_capability_supported *out = NULL;
if (!in || !capability) {
dprintk(VIDC_ERR, "%s Invalid input parameters\n",
__func__);
return;
}
switch (in->capability_type) {
case HFI_CAPABILITY_FRAME_WIDTH:
out = &capability->width;
break;
case HFI_CAPABILITY_FRAME_HEIGHT:
out = &capability->height;
break;
case HFI_CAPABILITY_MBS_PER_FRAME:
out = &capability->mbs_per_frame;
break;
case HFI_CAPABILITY_MBS_PER_SECOND:
out = &capability->mbs_per_sec;
break;
case HFI_CAPABILITY_FRAMERATE:
out = &capability->frame_rate;
break;
case HFI_CAPABILITY_SCALE_X:
out = &capability->scale_x;
break;
case HFI_CAPABILITY_SCALE_Y:
out = &capability->scale_y;
break;
case HFI_CAPABILITY_BITRATE:
out = &capability->bitrate;
break;
case HFI_CAPABILITY_BFRAME:
out = &capability->bframe;
break;
case HFI_CAPABILITY_PEAKBITRATE:
out = &capability->peakbitrate;
break;
case HFI_CAPABILITY_HIER_P_NUM_ENH_LAYERS:
out = &capability->hier_p;
break;
case HFI_CAPABILITY_ENC_LTR_COUNT:
out = &capability->ltr_count;
break;
case HFI_CAPABILITY_CP_OUTPUT2_THRESH:
out = &capability->secure_output2_threshold;
break;
case HFI_CAPABILITY_HIER_B_NUM_ENH_LAYERS:
out = &capability->hier_b;
break;
case HFI_CAPABILITY_LCU_SIZE:
out = &capability->lcu_size;
break;
case HFI_CAPABILITY_HIER_P_HYBRID_NUM_ENH_LAYERS:
out = &capability->hier_p_hybrid;
break;
case HFI_CAPABILITY_MBS_PER_SECOND_POWERSAVE:
out = &capability->mbs_per_sec_power_save;
break;
default:
dprintk(VIDC_DBG, "%s: unknown capablity %#x\n",
__func__, in->capability_type);
break;
}
if (out) {
out->capability_type = get_hal_cap_type(in->capability_type);
out->min = in->min;
out->max = in->max;
out->step_size = in->step_size;
}
}
static int hfi_fill_codec_info(u8 *data_ptr,
struct vidc_hal_sys_init_done *sys_init_done, u32 rem_size) {
u32 i;
u32 codecs = 0, codec_count = 0, size = 0;
struct msm_vidc_capability *capability;
u32 prop_id = *((u32 *)data_ptr);
u8 *orig_data_ptr = data_ptr;
if (prop_id == HFI_PROPERTY_PARAM_CODEC_SUPPORTED) {
struct hfi_codec_supported *prop;
if (!validate_pkt_size(rem_size - sizeof(u32),
sizeof(struct hfi_codec_supported)))
return -E2BIG;
data_ptr = data_ptr + sizeof(u32);
prop = (struct hfi_codec_supported *) data_ptr;
sys_init_done->dec_codec_supported =
prop->decoder_codec_supported;
sys_init_done->enc_codec_supported =
prop->encoder_codec_supported;
size = sizeof(struct hfi_codec_supported) + sizeof(u32);
rem_size -=
sizeof(struct hfi_codec_supported) + sizeof(u32);
} else {
dprintk(VIDC_WARN,
"%s: prop_id %#x, expected codec_supported property\n",
__func__, prop_id);
}
codecs = sys_init_done->dec_codec_supported;
for (i = 0; i < 8 * sizeof(codecs); i++) {
if ((1 << i) & codecs) {
capability =
&sys_init_done->capabilities[codec_count++];
capability->codec =
vidc_get_hal_codec((1 << i) & codecs);
capability->domain =
vidc_get_hal_domain(HFI_VIDEO_DOMAIN_DECODER);
if (codec_count == VIDC_MAX_DECODE_SESSIONS) {
dprintk(VIDC_ERR,
"Max supported decoder sessions reached\n");
break;
}
}
}
codecs = sys_init_done->enc_codec_supported;
for (i = 0; i < 8 * sizeof(codecs); i++) {
if ((1 << i) & codecs) {
capability =
&sys_init_done->capabilities[codec_count++];
capability->codec =
vidc_get_hal_codec((1 << i) & codecs);
capability->domain =
vidc_get_hal_domain(HFI_VIDEO_DOMAIN_ENCODER);
if (codec_count == VIDC_MAX_SESSIONS) {
dprintk(VIDC_ERR,
"Max supported sessions reached\n");
break;
}
}
}
sys_init_done->codec_count = codec_count;
if (!validate_pkt_size(rem_size, sizeof(u32)))
return -E2BIG;
prop_id = *((u32 *)(orig_data_ptr + size));
if (prop_id == HFI_PROPERTY_PARAM_MAX_SESSIONS_SUPPORTED) {
struct hfi_max_sessions_supported *prop;
if (!validate_pkt_size(rem_size - sizeof(u32), sizeof(struct
hfi_max_sessions_supported)))
return -E2BIG;
prop = (struct hfi_max_sessions_supported *)
(orig_data_ptr + size + sizeof(u32));
sys_init_done->max_sessions_supported = prop->max_sessions;
size += sizeof(struct hfi_max_sessions_supported) + sizeof(u32);
rem_size -=
sizeof(struct hfi_max_sessions_supported) + sizeof(u32);
dprintk(VIDC_DBG, "max_sessions_supported %d\n",
prop->max_sessions);
}
return size;
}
enum vidc_status hfi_process_session_init_done_prop_read(
struct hfi_msg_sys_session_init_done_packet *pkt,
struct vidc_hal_session_init_done *session_init_done)
{
enum vidc_status status = VIDC_ERR_NONE;
struct msm_vidc_capability *capability = NULL;
u32 rem_bytes, num_properties;
u8 *data_ptr;
rem_bytes = pkt->size - sizeof(struct
hfi_msg_sys_session_init_done_packet) + sizeof(u32);
if (!rem_bytes) {
dprintk(VIDC_ERR, "%s: invalid property info\n", __func__);
return VIDC_ERR_FAIL;
}
status = hfi_map_err_status(pkt->error_type);
if (status) {
dprintk(VIDC_ERR, "%s: error status 0x%x\n", __func__, status);
return status;
}
data_ptr = (u8 *)&pkt->rg_property_data[0];
num_properties = pkt->num_properties;
capability = &session_init_done->capability;
status = hfi_parse_init_done_properties(
capability, 1, data_ptr, num_properties, rem_bytes,
vidc_get_hfi_codec(capability->codec),
vidc_get_hfi_domain(capability->domain));
if (status) {
dprintk(VIDC_ERR, "%s: parse status 0x%x\n", __func__, status);
return status;
}
return status;
}
static int copy_caps_to_sessions(struct hfi_capability_supported *cap,
u32 num_caps, struct msm_vidc_capability *capabilities,
u32 num_sessions, u32 codecs, u32 domain)
{
u32 i = 0, j = 0;
struct msm_vidc_capability *capability;
u32 sess_codec;
u32 sess_domain;
/*
* iterate over num_sessions and copy all the capabilities
* to matching sessions.
*/
for (i = 0; i < num_sessions; i++) {
sess_codec = 0;
sess_domain = 0;
capability = &capabilities[i];
if (capability->codec)
sess_codec =
vidc_get_hfi_codec(capability->codec);
if (capability->domain)
sess_domain =
vidc_get_hfi_domain(capability->domain);
if (!(sess_codec & codecs && sess_domain & domain))
continue;
for (j = 0; j < num_caps; j++)
copy_cap_prop(&cap[j], capability);
}
return 0;
}
static int copy_alloc_mode_to_sessions(
struct hfi_buffer_alloc_mode_supported *prop,
struct msm_vidc_capability *capabilities,
u32 num_sessions, u32 codecs, u32 domain)
{
u32 i = 0, j = 0;
struct msm_vidc_capability *capability;
u32 sess_codec;
u32 sess_domain;
/*
* iterate over num_sessions and copy all the entries
* to matching sessions.
*/
for (i = 0; i < num_sessions; i++) {
sess_codec = 0;
sess_domain = 0;
capability = &capabilities[i];
if (capability->codec)
sess_codec =
vidc_get_hfi_codec(capability->codec);
if (capability->domain)
sess_domain =
vidc_get_hfi_domain(capability->domain);
if (!(sess_codec & codecs && sess_domain & domain))
continue;
for (j = 0; j < prop->num_entries; j++) {
if (prop->buffer_type == HFI_BUFFER_OUTPUT ||
prop->buffer_type == HFI_BUFFER_OUTPUT2) {
switch (prop->rg_data[j]) {
case HFI_BUFFER_MODE_STATIC:
capability->alloc_mode_out |=
HAL_BUFFER_MODE_STATIC;
break;
case HFI_BUFFER_MODE_RING:
capability->alloc_mode_out |=
HAL_BUFFER_MODE_RING;
break;
case HFI_BUFFER_MODE_DYNAMIC:
capability->alloc_mode_out |=
HAL_BUFFER_MODE_DYNAMIC;
break;
}
} else if (prop->buffer_type == HFI_BUFFER_INPUT) {
switch (prop->rg_data[j]) {
case HFI_BUFFER_MODE_STATIC:
capability->alloc_mode_in |=
HAL_BUFFER_MODE_STATIC;
break;
case HFI_BUFFER_MODE_RING:
capability->alloc_mode_in |=
HAL_BUFFER_MODE_RING;
break;
case HFI_BUFFER_MODE_DYNAMIC:
capability->alloc_mode_in |=
HAL_BUFFER_MODE_DYNAMIC;
break;
}
}
}
}
return 0;
}
static enum vidc_status hfi_parse_init_done_properties(
struct msm_vidc_capability *capabilities,
u32 num_sessions, u8 *data_ptr, u32 num_properties,
u32 rem_bytes, u32 codecs, u32 domain)
{
enum vidc_status status = VIDC_ERR_NONE;
u32 prop_id, next_offset;
#define VALIDATE_PROPERTY_STRUCTURE_SIZE(pkt_size, property_size) ({\
if (pkt_size < property_size) { \
status = VIDC_ERR_BAD_PARAM; \
break; \
} \
})
#define VALIDATE_PROPERTY_PAYLOAD_SIZE(pkt_size, payload_size, \
property_count) ({\
if (pkt_size/payload_size < property_count) { \
status = VIDC_ERR_BAD_PARAM; \
break; \
} \
})
while (status == VIDC_ERR_NONE && num_properties &&
rem_bytes >= sizeof(u32)) {
prop_id = *((u32 *)data_ptr);
next_offset = sizeof(u32);
switch (prop_id) {
case HFI_PROPERTY_PARAM_CODEC_MASK_SUPPORTED:
{
struct hfi_codec_mask_supported *prop =
(struct hfi_codec_mask_supported *)
(data_ptr + next_offset);
VALIDATE_PROPERTY_STRUCTURE_SIZE(rem_bytes -
next_offset,
sizeof(*prop));
codecs = prop->codecs;
domain = prop->video_domains;
next_offset += sizeof(struct hfi_codec_mask_supported);
num_properties--;
break;
}
case HFI_PROPERTY_PARAM_CAPABILITY_SUPPORTED:
{
struct hfi_capability_supported_info *prop =
(struct hfi_capability_supported_info *)
(data_ptr + next_offset);
VALIDATE_PROPERTY_STRUCTURE_SIZE(rem_bytes -
next_offset,
sizeof(*prop));
VALIDATE_PROPERTY_PAYLOAD_SIZE(rem_bytes -
next_offset - sizeof(u32),
sizeof(struct hfi_capability_supported),
prop->num_capabilities);
next_offset += sizeof(u32) +
prop->num_capabilities *
sizeof(struct hfi_capability_supported);
copy_caps_to_sessions(&prop->rg_data[0],
prop->num_capabilities,
capabilities, num_sessions,
codecs, domain);
num_properties--;
break;
}
case HFI_PROPERTY_PARAM_UNCOMPRESSED_FORMAT_SUPPORTED:
{
struct hfi_uncompressed_format_supported *prop =
(struct hfi_uncompressed_format_supported *)
(data_ptr + next_offset);
u32 num_format_entries;
char *fmt_ptr;
struct hfi_uncompressed_plane_info *plane_info;
VALIDATE_PROPERTY_STRUCTURE_SIZE(rem_bytes -
next_offset,
sizeof(*prop));
num_format_entries = prop->format_entries;
next_offset = sizeof(*prop);
fmt_ptr = (char *)&prop->rg_format_info[0];
while (num_format_entries) {
u32 bytes_to_skip;
plane_info =
(struct hfi_uncompressed_plane_info *) fmt_ptr;
VALIDATE_PROPERTY_STRUCTURE_SIZE(rem_bytes -
next_offset,
sizeof(*plane_info));
bytes_to_skip = sizeof(*plane_info) -
sizeof(struct
hfi_uncompressed_plane_constraints) +
plane_info->num_planes *
sizeof(struct
hfi_uncompressed_plane_constraints);
VALIDATE_PROPERTY_STRUCTURE_SIZE(rem_bytes -
next_offset,
bytes_to_skip);
fmt_ptr += bytes_to_skip;
next_offset += bytes_to_skip;
num_format_entries--;
}
num_properties--;
break;
}
case HFI_PROPERTY_PARAM_PROPERTIES_SUPPORTED:
{
struct hfi_properties_supported *prop =
(struct hfi_properties_supported *)
(data_ptr + next_offset);
VALIDATE_PROPERTY_STRUCTURE_SIZE(rem_bytes -
next_offset,
sizeof(*prop));
VALIDATE_PROPERTY_PAYLOAD_SIZE(rem_bytes -
next_offset - sizeof(*prop) +
sizeof(u32), sizeof(u32),
prop->num_properties);
next_offset += sizeof(*prop) - sizeof(u32)
+ prop->num_properties * sizeof(u32);
num_properties--;
break;
}
case HFI_PROPERTY_PARAM_PROFILE_LEVEL_SUPPORTED:
{
struct msm_vidc_capability capability;
char *ptr = NULL;
u32 count = 0;
u32 prof_count = 0;
struct hfi_profile_level *prof_level;
struct hfi_profile_level_supported *prop =
(struct hfi_profile_level_supported *)
(data_ptr + next_offset);
VALIDATE_PROPERTY_STRUCTURE_SIZE(rem_bytes -
next_offset,
sizeof(*prop));
ptr = (char *) &prop->rg_profile_level[0];
prof_count = prop->profile_count;
next_offset += sizeof(u32);
if (prof_count > MAX_PROFILE_COUNT) {
prof_count = MAX_PROFILE_COUNT;
dprintk(VIDC_WARN,
"prop count exceeds max profile count\n");
break;
}
while (prof_count) {
prof_level = (struct hfi_profile_level *)ptr;
VALIDATE_PROPERTY_STRUCTURE_SIZE(rem_bytes -
next_offset,
sizeof(*prof_level));
capability.
profile_level.profile_level[count].profile
= prof_level->profile;
capability.
profile_level.profile_level[count].level
= prof_level->level;
prof_count--;
count++;
ptr += sizeof(struct hfi_profile_level);
next_offset += sizeof(struct hfi_profile_level);
}
num_properties--;
break;
}
case HFI_PROPERTY_PARAM_INTERLACE_FORMAT_SUPPORTED:
{
VALIDATE_PROPERTY_STRUCTURE_SIZE(rem_bytes -
next_offset,
sizeof(struct hfi_interlace_format_supported));
next_offset +=
sizeof(struct hfi_interlace_format_supported);
num_properties--;
break;
}
case HFI_PROPERTY_PARAM_NAL_STREAM_FORMAT_SUPPORTED:
{
VALIDATE_PROPERTY_STRUCTURE_SIZE(rem_bytes -
next_offset,
sizeof(struct hfi_nal_stream_format_supported));
next_offset +=
sizeof(struct hfi_nal_stream_format_supported);
num_properties--;
break;
}
case HFI_PROPERTY_PARAM_NAL_STREAM_FORMAT_SELECT:
{
VALIDATE_PROPERTY_STRUCTURE_SIZE(rem_bytes -
next_offset,
sizeof(u32));
next_offset += sizeof(u32);
num_properties--;
break;
}
case HFI_PROPERTY_PARAM_MAX_SEQUENCE_HEADER_SIZE:
{
VALIDATE_PROPERTY_STRUCTURE_SIZE(rem_bytes -
next_offset,
sizeof(u32));
next_offset += sizeof(u32);
num_properties--;
break;
}
case HFI_PROPERTY_PARAM_VENC_INTRA_REFRESH:
{
VALIDATE_PROPERTY_STRUCTURE_SIZE(rem_bytes -
next_offset,
sizeof(struct hfi_intra_refresh));
next_offset +=
sizeof(struct hfi_intra_refresh);
num_properties--;
break;
}
case HFI_PROPERTY_PARAM_BUFFER_ALLOC_MODE_SUPPORTED:
{
struct hfi_buffer_alloc_mode_supported *prop =
(struct hfi_buffer_alloc_mode_supported *)
(data_ptr + next_offset);
VALIDATE_PROPERTY_STRUCTURE_SIZE(rem_bytes -
next_offset,
sizeof(*prop));
if (prop->num_entries >= 32) {
dprintk(VIDC_ERR,
"%s - num_entries: %d from f/w seems suspect\n",
__func__, prop->num_entries);
break;
}
VALIDATE_PROPERTY_PAYLOAD_SIZE(rem_bytes -
next_offset -
sizeof(struct hfi_buffer_alloc_mode_supported) +
sizeof(u32),
sizeof(u32),
prop->num_entries);
next_offset +=
sizeof(struct hfi_buffer_alloc_mode_supported) -
sizeof(u32) + prop->num_entries * sizeof(u32);
copy_alloc_mode_to_sessions(prop,
capabilities, num_sessions,
codecs, domain);
num_properties--;
break;
}
default:
dprintk(VIDC_DBG,
"%s: default case - data_ptr %pK, prop_id 0x%x\n",
__func__, data_ptr, prop_id);
break;
}
if (rem_bytes > next_offset) {
rem_bytes -= next_offset;
data_ptr += next_offset;
} else {
rem_bytes = 0;
}
}
return status;
}
enum vidc_status hfi_process_sys_init_done_prop_read(
struct hfi_msg_sys_init_done_packet *pkt,
struct vidc_hal_sys_init_done *sys_init_done)
{
enum vidc_status status = VIDC_ERR_NONE;
int bytes_read;
u32 rem_bytes, num_properties;
u8 *data_ptr;
u32 codecs = 0, domain = 0;
if (!pkt || !sys_init_done) {
dprintk(VIDC_ERR,
"hfi_msg_sys_init_done: Invalid input\n");
return VIDC_ERR_FAIL;
}
if (pkt->size < sizeof(struct hfi_msg_sys_init_done_packet)) {
dprintk(VIDC_ERR, "%s: bad packet size: %d\n",
__func__, pkt->size);
return VIDC_ERR_FAIL;
}
rem_bytes = pkt->size - sizeof(struct
hfi_msg_sys_init_done_packet) + sizeof(u32);
if (!rem_bytes) {
dprintk(VIDC_ERR,
"hfi_msg_sys_init_done: missing_prop_info\n");
return VIDC_ERR_FAIL;
}
status = hfi_map_err_status(pkt->error_type);
if (status) {
dprintk(VIDC_ERR, "%s: status %#x\n", __func__, status);
return status;
}
data_ptr = (u8 *) &pkt->rg_property_data[0];
num_properties = pkt->num_properties;
dprintk(VIDC_DBG,
"%s: data_start %pK, num_properties %#x\n",
__func__, data_ptr, num_properties);
if (!num_properties) {
sys_init_done->capabilities = NULL;
dprintk(VIDC_DBG,
"Venus didn't set any properties in SYS_INIT_DONE");
return status;
}
bytes_read = hfi_fill_codec_info(data_ptr, sys_init_done, rem_bytes);
if (bytes_read < 0)
return VIDC_ERR_FAIL;
data_ptr += bytes_read;
rem_bytes -= bytes_read;
num_properties--;
status = hfi_parse_init_done_properties(
sys_init_done->capabilities,
VIDC_MAX_SESSIONS, data_ptr, num_properties,
rem_bytes, codecs, domain);
if (status) {
dprintk(VIDC_ERR, "%s: parse status %#x\n",
__func__, status);
return status;
}
return status;
}
static void hfi_process_sess_get_prop_dec_entropy(
struct hfi_msg_session_property_info_packet *prop,
enum hal_h264_entropy *entropy)
{
u32 req_bytes, hfi_entropy;
req_bytes = prop->size - sizeof(
struct hfi_msg_session_property_info_packet);
if (!req_bytes || req_bytes % sizeof(hfi_entropy)) {
dprintk(VIDC_ERR, "%s: bad packet: %d\n", __func__, req_bytes);
return;
}
hfi_entropy = prop->rg_property_data[1];
*entropy =
hfi_entropy == HFI_H264_ENTROPY_CAVLC ? HAL_H264_ENTROPY_CAVLC :
hfi_entropy == HFI_H264_ENTROPY_CABAC ? HAL_H264_ENTROPY_CABAC :
HAL_UNUSED_ENTROPY;
}
static void hfi_process_sess_get_prop_profile_level(
struct hfi_msg_session_property_info_packet *prop,
struct hfi_profile_level *profile_level)
{
struct hfi_profile_level *hfi_profile_level;
u32 req_bytes;
dprintk(VIDC_DBG, "Entered %s\n", __func__);
if (!prop) {
dprintk(VIDC_ERR,
"hal_process_sess_get_profile_level: bad_prop: %pK\n",
prop);
return;
}
req_bytes = prop->size - sizeof(
struct hfi_msg_session_property_info_packet);
if (!req_bytes || req_bytes % sizeof(struct hfi_profile_level)) {
dprintk(VIDC_ERR,
"hal_process_sess_get_profile_level: bad_pkt: %d\n",
req_bytes);
return;
}
hfi_profile_level = (struct hfi_profile_level *)
&prop->rg_property_data[1];
profile_level->profile = hfi_profile_level->profile;
profile_level->level = hfi_profile_level->level;
dprintk(VIDC_DBG, "%s profile: %d level: %d\n",
__func__, profile_level->profile,
profile_level->level);
}
static void hfi_process_sess_get_prop_buf_req(
struct hfi_msg_session_property_info_packet *prop,
struct buffer_requirements *buffreq)
{
struct hfi_buffer_requirements *hfi_buf_req;
u32 req_bytes;
if (!prop) {
dprintk(VIDC_ERR,
"hal_process_sess_get_prop_buf_req: bad_prop: %pK\n",
prop);
return;
}
req_bytes = prop->size - sizeof(
struct hfi_msg_session_property_info_packet);
if (!req_bytes || req_bytes % sizeof(struct hfi_buffer_requirements) ||
!prop->rg_property_data[1]) {
dprintk(VIDC_ERR,
"hal_process_sess_get_prop_buf_req: bad_pkt: %d\n",
req_bytes);
return;
}
hfi_buf_req = (struct hfi_buffer_requirements *)
&prop->rg_property_data[1];
if (!hfi_buf_req) {
dprintk(VIDC_ERR, "%s - invalid buffer req pointer\n",
__func__);
return;
}
while (req_bytes) {
if (hfi_buf_req->buffer_size &&
hfi_buf_req->buffer_count_min > hfi_buf_req->
buffer_count_actual)
dprintk(VIDC_WARN,
"Bad buffer requirements for %#x: min %d, actual %d\n",
hfi_buf_req->buffer_type,
hfi_buf_req->buffer_count_min,
hfi_buf_req->buffer_count_actual);
dprintk(VIDC_DBG, "got buffer requirements for: %d\n",
hfi_buf_req->buffer_type);
switch (hfi_buf_req->buffer_type) {
case HFI_BUFFER_INPUT:
memcpy(&buffreq->buffer[0], hfi_buf_req,
sizeof(struct hfi_buffer_requirements));
buffreq->buffer[0].buffer_type = HAL_BUFFER_INPUT;
break;
case HFI_BUFFER_OUTPUT:
memcpy(&buffreq->buffer[1], hfi_buf_req,
sizeof(struct hfi_buffer_requirements));
buffreq->buffer[1].buffer_type = HAL_BUFFER_OUTPUT;
break;
case HFI_BUFFER_OUTPUT2:
memcpy(&buffreq->buffer[2], hfi_buf_req,
sizeof(struct hfi_buffer_requirements));
buffreq->buffer[2].buffer_type = HAL_BUFFER_OUTPUT2;
break;
case HFI_BUFFER_EXTRADATA_INPUT:
memcpy(&buffreq->buffer[3], hfi_buf_req,
sizeof(struct hfi_buffer_requirements));
buffreq->buffer[3].buffer_type =
HAL_BUFFER_EXTRADATA_INPUT;
break;
case HFI_BUFFER_EXTRADATA_OUTPUT:
memcpy(&buffreq->buffer[4], hfi_buf_req,
sizeof(struct hfi_buffer_requirements));
buffreq->buffer[4].buffer_type =
HAL_BUFFER_EXTRADATA_OUTPUT;
break;
case HFI_BUFFER_EXTRADATA_OUTPUT2:
memcpy(&buffreq->buffer[5], hfi_buf_req,
sizeof(struct hfi_buffer_requirements));
buffreq->buffer[5].buffer_type =
HAL_BUFFER_EXTRADATA_OUTPUT2;
break;
case HFI_BUFFER_INTERNAL_SCRATCH:
memcpy(&buffreq->buffer[6], hfi_buf_req,
sizeof(struct hfi_buffer_requirements));
buffreq->buffer[6].buffer_type =
HAL_BUFFER_INTERNAL_SCRATCH;
break;
case HFI_BUFFER_INTERNAL_SCRATCH_1:
memcpy(&buffreq->buffer[7], hfi_buf_req,
sizeof(struct hfi_buffer_requirements));
buffreq->buffer[7].buffer_type =
HAL_BUFFER_INTERNAL_SCRATCH_1;
break;
case HFI_BUFFER_INTERNAL_SCRATCH_2:
memcpy(&buffreq->buffer[8], hfi_buf_req,
sizeof(struct hfi_buffer_requirements));
buffreq->buffer[8].buffer_type =
HAL_BUFFER_INTERNAL_SCRATCH_2;
break;
case HFI_BUFFER_INTERNAL_PERSIST:
memcpy(&buffreq->buffer[9], hfi_buf_req,
sizeof(struct hfi_buffer_requirements));
buffreq->buffer[9].buffer_type =
HAL_BUFFER_INTERNAL_PERSIST;
break;
case HFI_BUFFER_INTERNAL_PERSIST_1:
memcpy(&buffreq->buffer[10], hfi_buf_req,
sizeof(struct hfi_buffer_requirements));
buffreq->buffer[10].buffer_type =
HAL_BUFFER_INTERNAL_PERSIST_1;
break;
default:
dprintk(VIDC_ERR,
"hal_process_sess_get_prop_buf_req: bad_buffer_type: %d\n",
hfi_buf_req->buffer_type);
break;
}
req_bytes -= sizeof(struct hfi_buffer_requirements);
hfi_buf_req++;
}
}
static int hfi_process_session_prop_info(u32 device_id,
void *_pkt,
struct msm_vidc_cb_info *info)
{
struct hfi_msg_session_property_info_packet *pkt = _pkt;
struct msm_vidc_cb_cmd_done cmd_done = {0};
struct hfi_profile_level profile_level = {0};
enum hal_h264_entropy entropy = HAL_UNUSED_ENTROPY;
struct buffer_requirements buff_req = { { {0} } };
dprintk(VIDC_DBG, "Received SESSION_PROPERTY_INFO[%#x]\n",
pkt->session_id);
if (pkt->size < sizeof(struct hfi_msg_session_property_info_packet)) {
dprintk(VIDC_ERR,
"hal_process_session_prop_info: bad_pkt_size\n");
return -E2BIG;
} else if (!pkt->num_properties) {
dprintk(VIDC_ERR,
"hal_process_session_prop_info: no_properties\n");
return -EINVAL;
}
switch (pkt->rg_property_data[0]) {
case HFI_PROPERTY_CONFIG_BUFFER_REQUIREMENTS:
hfi_process_sess_get_prop_buf_req(pkt, &buff_req);
cmd_done.device_id = device_id;
cmd_done.session_id = (void *)(uintptr_t)pkt->session_id;
cmd_done.status = VIDC_ERR_NONE;
cmd_done.data.property.buf_req = buff_req;
cmd_done.size = sizeof(buff_req);
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SESSION_PROPERTY_INFO,
.response.cmd = cmd_done,
};
return 0;
case HFI_PROPERTY_PARAM_PROFILE_LEVEL_CURRENT:
hfi_process_sess_get_prop_profile_level(pkt, &profile_level);
cmd_done.device_id = device_id;
cmd_done.session_id = (void *)(uintptr_t)pkt->session_id;
cmd_done.status = VIDC_ERR_NONE;
cmd_done.data.property.profile_level =
(struct hal_profile_level) {
.profile = profile_level.profile,
.level = profile_level.level,
};
cmd_done.size = sizeof(struct hal_profile_level);
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SESSION_PROPERTY_INFO,
.response.cmd = cmd_done,
};
return 0;
case HFI_PROPERTY_CONFIG_VDEC_ENTROPY:
hfi_process_sess_get_prop_dec_entropy(pkt, &entropy);
cmd_done.device_id = device_id;
cmd_done.session_id = (void *)(uintptr_t)pkt->session_id;
cmd_done.status = VIDC_ERR_NONE;
cmd_done.data.property.h264_entropy = entropy;
cmd_done.size = sizeof(enum hal_h264_entropy);
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SESSION_PROPERTY_INFO,
.response.cmd = cmd_done,
};
return 0;
default:
dprintk(VIDC_DBG,
"hal_process_session_prop_info: unknown_prop_id: %x\n",
pkt->rg_property_data[0]);
return -ENOTSUPP;
}
}
static int hfi_process_session_init_done(u32 device_id,
void *_pkt,
struct msm_vidc_cb_info *info)
{
struct hfi_msg_sys_session_init_done_packet *pkt = _pkt;
struct msm_vidc_cb_cmd_done cmd_done = {0};
struct vidc_hal_session_init_done session_init_done = { {0} };
dprintk(VIDC_DBG, "RECEIVED: SESSION_INIT_DONE[%x]\n", pkt->session_id);
if (sizeof(struct hfi_msg_sys_session_init_done_packet) > pkt->size) {
dprintk(VIDC_ERR,
"hal_process_session_init_done: bad_pkt_size\n");
return -E2BIG;
}
cmd_done.device_id = device_id;
cmd_done.session_id = (void *)(uintptr_t)pkt->session_id;
cmd_done.status = hfi_map_err_status(pkt->error_type);
if (!cmd_done.status) {
cmd_done.status = hfi_process_session_init_done_prop_read(
pkt, &session_init_done);
}
cmd_done.data.session_init_done = session_init_done;
cmd_done.size = sizeof(struct vidc_hal_session_init_done);
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SESSION_INIT_DONE,
.response.cmd = cmd_done,
};
return 0;
}
static int hfi_process_session_load_res_done(u32 device_id,
void *_pkt,
struct msm_vidc_cb_info *info)
{
struct hfi_msg_session_load_resources_done_packet *pkt = _pkt;
struct msm_vidc_cb_cmd_done cmd_done = {0};
dprintk(VIDC_DBG, "RECEIVED: SESSION_LOAD_RESOURCES_DONE[%#x]\n",
pkt->session_id);
if (sizeof(struct hfi_msg_session_load_resources_done_packet) !=
pkt->size) {
dprintk(VIDC_ERR,
"hal_process_session_load_res_done: bad packet size: %d\n",
pkt->size);
return -E2BIG;
}
cmd_done.device_id = device_id;
cmd_done.session_id = (void *)(uintptr_t)pkt->session_id;
cmd_done.status = hfi_map_err_status(pkt->error_type);
cmd_done.size = 0;
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SESSION_LOAD_RESOURCE_DONE,
.response.cmd = cmd_done,
};
return 0;
}
static int hfi_process_session_flush_done(u32 device_id,
void *_pkt,
struct msm_vidc_cb_info *info)
{
struct hfi_msg_session_flush_done_packet *pkt = _pkt;
struct msm_vidc_cb_cmd_done cmd_done = {0};
dprintk(VIDC_DBG, "RECEIVED: SESSION_FLUSH_DONE[%#x]\n",
pkt->session_id);
if (sizeof(struct hfi_msg_session_flush_done_packet) != pkt->size) {
dprintk(VIDC_ERR,
"hal_process_session_flush_done: bad packet size: %d\n",
pkt->size);
return -E2BIG;
}
cmd_done.device_id = device_id;
cmd_done.session_id = (void *)(uintptr_t)pkt->session_id;
cmd_done.status = hfi_map_err_status(pkt->error_type);
cmd_done.size = sizeof(u32);
switch (pkt->flush_type) {
case HFI_FLUSH_OUTPUT:
cmd_done.data.flush_type = HAL_FLUSH_OUTPUT;
break;
case HFI_FLUSH_INPUT:
cmd_done.data.flush_type = HAL_FLUSH_INPUT;
break;
case HFI_FLUSH_ALL:
cmd_done.data.flush_type = HAL_FLUSH_ALL;
break;
default:
dprintk(VIDC_ERR,
"%s: invalid flush type!", __func__);
return -EINVAL;
}
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SESSION_FLUSH_DONE,
.response.cmd = cmd_done,
};
return 0;
}
static int hfi_process_session_etb_done(u32 device_id,
void *_pkt,
struct msm_vidc_cb_info *info)
{
struct hfi_msg_session_empty_buffer_done_packet *pkt = _pkt;
struct msm_vidc_cb_data_done data_done = {0};
struct hfi_picture_type *hfi_picture_type = NULL;
u32 is_sync_frame;
dprintk(VIDC_DBG, "RECEIVED: SESSION_ETB_DONE[%#x]\n", pkt->session_id);
if (!pkt || pkt->size <
sizeof(struct hfi_msg_session_empty_buffer_done_packet))
goto bad_packet_size;
data_done.device_id = device_id;
data_done.session_id = (void *)(uintptr_t)pkt->session_id;
data_done.status = hfi_map_err_status(pkt->error_type);
data_done.size = sizeof(struct msm_vidc_cb_data_done);
data_done.clnt_data = pkt->input_tag;
data_done.input_done.offset = pkt->offset;
data_done.input_done.filled_len = pkt->filled_len;
data_done.input_done.packet_buffer =
(ion_phys_addr_t)pkt->packet_buffer;
data_done.input_done.extra_data_buffer =
(ion_phys_addr_t)pkt->extra_data_buffer;
data_done.input_done.status =
hfi_map_err_status(pkt->error_type);
is_sync_frame = pkt->rgData[0];
if (is_sync_frame == 1) {
if (pkt->size <
sizeof(struct hfi_msg_session_empty_buffer_done_packet)
+ sizeof(struct hfi_picture_type))
goto bad_packet_size;
hfi_picture_type = (struct hfi_picture_type *)&pkt->rgData[1];
if (hfi_picture_type->picture_type)
data_done.input_done.flags =
hfi_picture_type->picture_type;
else
dprintk(VIDC_DBG,
"Non-Sync frame sent for H264/HEVC\n");
}
trace_msm_v4l2_vidc_buffer_event_end("ETB",
(u32)pkt->packet_buffer, -1, -1,
pkt->filled_len, pkt->offset);
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SESSION_ETB_DONE,
.response.data = data_done,
};
return 0;
bad_packet_size:
dprintk(VIDC_ERR, "%s: bad_pkt_size: %d\n",
__func__, pkt ? pkt->size : 0);
return -E2BIG;
}
static int hfi_process_session_ftb_done(
u32 device_id, void *_pkt,
struct msm_vidc_cb_info *info)
{
struct vidc_hal_msg_pkt_hdr *msg_hdr = _pkt;
struct msm_vidc_cb_data_done data_done = {0};
bool is_decoder = false, is_encoder = false;
if (!msg_hdr) {
dprintk(VIDC_ERR, "Invalid Params\n");
return -EINVAL;
}
is_encoder = msg_hdr->size == sizeof(struct
hfi_msg_session_fill_buffer_done_compressed_packet) + 4;
is_decoder = msg_hdr->size == sizeof(struct
hfi_msg_session_fbd_uncompressed_plane0_packet) + 4;
if (!(is_encoder ^ is_decoder)) {
dprintk(VIDC_ERR, "Ambiguous packet (%#x) received (size %d)\n",
msg_hdr->packet, msg_hdr->size);
return -EBADHANDLE;
}
if (is_encoder) {
struct hfi_msg_session_fill_buffer_done_compressed_packet *pkt =
(struct hfi_msg_session_fill_buffer_done_compressed_packet *)
msg_hdr;
dprintk(VIDC_DBG, "RECEIVED: SESSION_FTB_DONE[%#x]\n",
pkt->session_id);
if (sizeof(struct
hfi_msg_session_fill_buffer_done_compressed_packet)
> pkt->size) {
dprintk(VIDC_ERR,
"hal_process_session_ftb_done: bad_pkt_size\n");
return -E2BIG;
} else if (pkt->error_type != HFI_ERR_NONE) {
dprintk(VIDC_ERR,
"got buffer back with error %x\n",
pkt->error_type);
/* Proceed with the FBD */
}
data_done.device_id = device_id;
data_done.session_id = (void *)(uintptr_t)pkt->session_id;
data_done.status = hfi_map_err_status(pkt->error_type);
data_done.size = sizeof(struct msm_vidc_cb_data_done);
data_done.clnt_data = 0;
data_done.output_done.timestamp_hi = pkt->time_stamp_hi;
data_done.output_done.timestamp_lo = pkt->time_stamp_lo;
data_done.output_done.flags1 = pkt->flags;
data_done.output_done.mark_target = pkt->mark_target;
data_done.output_done.mark_data = pkt->mark_data;
data_done.output_done.stats = pkt->stats;
data_done.output_done.offset1 = pkt->offset;
data_done.output_done.alloc_len1 = pkt->alloc_len;
data_done.output_done.filled_len1 = pkt->filled_len;
data_done.output_done.picture_type = pkt->picture_type;
data_done.output_done.packet_buffer1 =
(ion_phys_addr_t)pkt->packet_buffer;
data_done.output_done.extra_data_buffer =
(ion_phys_addr_t)pkt->extra_data_buffer;
data_done.output_done.buffer_type = HAL_BUFFER_OUTPUT;
} else /* if (is_decoder) */ {
struct hfi_msg_session_fbd_uncompressed_plane0_packet *pkt =
(struct hfi_msg_session_fbd_uncompressed_plane0_packet *)
msg_hdr;
dprintk(VIDC_DBG, "RECEIVED: SESSION_FTB_DONE[%#x]\n",
pkt->session_id);
if (sizeof(
struct hfi_msg_session_fbd_uncompressed_plane0_packet) >
pkt->size) {
dprintk(VIDC_ERR,
"hal_process_session_ftb_done: bad_pkt_size\n");
return -E2BIG;
}
data_done.device_id = device_id;
data_done.session_id = (void *)(uintptr_t)pkt->session_id;
data_done.status = hfi_map_err_status(pkt->error_type);
data_done.size = sizeof(struct msm_vidc_cb_data_done);
data_done.clnt_data = 0;
data_done.output_done.stream_id = pkt->stream_id;
data_done.output_done.view_id = pkt->view_id;
data_done.output_done.timestamp_hi = pkt->time_stamp_hi;
data_done.output_done.timestamp_lo = pkt->time_stamp_lo;
data_done.output_done.flags1 = pkt->flags;
data_done.output_done.mark_target = pkt->mark_target;
data_done.output_done.mark_data = pkt->mark_data;
data_done.output_done.stats = pkt->stats;
data_done.output_done.alloc_len1 = pkt->alloc_len;
data_done.output_done.filled_len1 = pkt->filled_len;
data_done.output_done.offset1 = pkt->offset;
data_done.output_done.frame_width = pkt->frame_width;
data_done.output_done.frame_height = pkt->frame_height;
data_done.output_done.start_x_coord = pkt->start_x_coord;
data_done.output_done.start_y_coord = pkt->start_y_coord;
data_done.output_done.input_tag1 = pkt->input_tag;
data_done.output_done.picture_type = pkt->picture_type;
data_done.output_done.packet_buffer1 = pkt->packet_buffer;
data_done.output_done.extra_data_buffer =
pkt->extra_data_buffer;
if (!pkt->stream_id)
data_done.output_done.buffer_type = HAL_BUFFER_OUTPUT;
else if (pkt->stream_id == 1)
data_done.output_done.buffer_type = HAL_BUFFER_OUTPUT2;
}
trace_msm_v4l2_vidc_buffer_event_end("FTB",
(u32)data_done.output_done.packet_buffer1,
(((u64)data_done.output_done.timestamp_hi) << 32)
+ ((u64)data_done.output_done.timestamp_lo),
data_done.output_done.alloc_len1,
data_done.output_done.filled_len1,
data_done.output_done.offset1);
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SESSION_FTB_DONE,
.response.data = data_done,
};
return 0;
}
static int hfi_process_session_start_done(u32 device_id,
void *_pkt,
struct msm_vidc_cb_info *info)
{
struct hfi_msg_session_start_done_packet *pkt = _pkt;
struct msm_vidc_cb_cmd_done cmd_done = {0};
dprintk(VIDC_DBG, "RECEIVED: SESSION_START_DONE[%#x]\n",
pkt->session_id);
if (!pkt || pkt->size !=
sizeof(struct hfi_msg_session_start_done_packet)) {
dprintk(VIDC_ERR, "%s: bad packet/packet size\n",
__func__);
return -E2BIG;
}
cmd_done.device_id = device_id;
cmd_done.session_id = (void *)(uintptr_t)pkt->session_id;
cmd_done.status = hfi_map_err_status(pkt->error_type);
cmd_done.size = 0;
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SESSION_START_DONE,
.response.cmd = cmd_done,
};
return 0;
}
static int hfi_process_session_stop_done(u32 device_id,
void *_pkt,
struct msm_vidc_cb_info *info)
{
struct hfi_msg_session_stop_done_packet *pkt = _pkt;
struct msm_vidc_cb_cmd_done cmd_done = {0};
dprintk(VIDC_DBG, "RECEIVED: SESSION_STOP_DONE[%#x]\n",
pkt->session_id);
if (!pkt || pkt->size !=
sizeof(struct hfi_msg_session_stop_done_packet)) {
dprintk(VIDC_ERR, "%s: bad packet/packet size\n",
__func__);
return -E2BIG;
}
cmd_done.device_id = device_id;
cmd_done.session_id = (void *)(uintptr_t)pkt->session_id;
cmd_done.status = hfi_map_err_status(pkt->error_type);
cmd_done.size = 0;
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SESSION_STOP_DONE,
.response.cmd = cmd_done,
};
return 0;
}
static int hfi_process_session_rel_res_done(u32 device_id,
void *_pkt,
struct msm_vidc_cb_info *info)
{
struct hfi_msg_session_release_resources_done_packet *pkt = _pkt;
struct msm_vidc_cb_cmd_done cmd_done = {0};
dprintk(VIDC_DBG, "RECEIVED: SESSION_RELEASE_RESOURCES_DONE[%#x]\n",
pkt->session_id);
if (!pkt || pkt->size !=
sizeof(struct hfi_msg_session_release_resources_done_packet)) {
dprintk(VIDC_ERR, "%s: bad packet/packet size\n",
__func__);
return -E2BIG;
}
cmd_done.device_id = device_id;
cmd_done.session_id = (void *)(uintptr_t)pkt->session_id;
cmd_done.status = hfi_map_err_status(pkt->error_type);
cmd_done.size = 0;
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SESSION_RELEASE_RESOURCE_DONE,
.response.cmd = cmd_done,
};
return 0;
}
static int hfi_process_session_rel_buf_done(u32 device_id,
void *_pkt,
struct msm_vidc_cb_info *info)
{
struct hfi_msg_session_release_buffers_done_packet *pkt = _pkt;
struct msm_vidc_cb_cmd_done cmd_done = {0};
if (!pkt || pkt->size <
sizeof(struct hfi_msg_session_release_buffers_done_packet)) {
dprintk(VIDC_ERR, "bad packet/packet size %d\n",
pkt ? pkt->size : 0);
return -E2BIG;
}
dprintk(VIDC_DBG, "RECEIVED:SESSION_RELEASE_BUFFER_DONE[%#x]\n",
pkt->session_id);
cmd_done.device_id = device_id;
cmd_done.size = sizeof(struct msm_vidc_cb_cmd_done);
cmd_done.session_id = (void *)(uintptr_t)pkt->session_id;
cmd_done.status = hfi_map_err_status(pkt->error_type);
if (pkt->rg_buffer_info) {
cmd_done.data.buffer_info.buffer_addr = *pkt->rg_buffer_info;
cmd_done.size = sizeof(struct hal_buffer_info);
} else {
dprintk(VIDC_ERR, "invalid payload in rel_buff_done\n");
}
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SESSION_RELEASE_BUFFER_DONE,
.response.cmd = cmd_done,
};
return 0;
}
static int hfi_process_session_end_done(u32 device_id,
void *_pkt,
struct msm_vidc_cb_info *info)
{
struct hfi_msg_sys_session_end_done_packet *pkt = _pkt;
struct msm_vidc_cb_cmd_done cmd_done = {0};
dprintk(VIDC_DBG, "RECEIVED: SESSION_END_DONE[%#x]\n", pkt->session_id);
if (!pkt || pkt->size !=
sizeof(struct hfi_msg_sys_session_end_done_packet)) {
dprintk(VIDC_ERR, "%s: bad packet/packet size\n", __func__);
return -E2BIG;
}
cmd_done.device_id = device_id;
cmd_done.session_id = (void *)(uintptr_t)pkt->session_id;
cmd_done.status = hfi_map_err_status(pkt->error_type);
cmd_done.size = 0;
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SESSION_END_DONE,
.response.cmd = cmd_done,
};
return 0;
}
static int hfi_process_session_abort_done(u32 device_id,
void *_pkt,
struct msm_vidc_cb_info *info)
{
struct hfi_msg_sys_session_abort_done_packet *pkt = _pkt;
struct msm_vidc_cb_cmd_done cmd_done = {0};
dprintk(VIDC_DBG, "RECEIVED: SESSION_ABORT_DONE[%#x]\n",
pkt->session_id);
if (!pkt || pkt->size !=
sizeof(struct hfi_msg_sys_session_abort_done_packet)) {
dprintk(VIDC_ERR, "%s: bad packet/packet size: %d\n",
__func__, pkt ? pkt->size : 0);
return -E2BIG;
}
cmd_done.device_id = device_id;
cmd_done.session_id = (void *)(uintptr_t)pkt->session_id;
cmd_done.status = hfi_map_err_status(pkt->error_type);
cmd_done.size = 0;
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SESSION_ABORT_DONE,
.response.cmd = cmd_done,
};
return 0;
}
static int hfi_process_session_get_seq_hdr_done(
u32 device_id,
struct hfi_msg_session_get_sequence_header_done_packet *pkt,
struct msm_vidc_cb_info *info)
{
struct msm_vidc_cb_data_done data_done = {0};
if (!pkt || pkt->size !=
sizeof(struct
hfi_msg_session_get_sequence_header_done_packet)) {
dprintk(VIDC_ERR, "%s: bad packet/packet size\n",
__func__);
return -E2BIG;
}
dprintk(VIDC_DBG, "RECEIVED:SESSION_GET_SEQ_HDR_DONE[%#x]\n",
pkt->session_id);
data_done.device_id = device_id;
data_done.size = sizeof(struct msm_vidc_cb_data_done);
data_done.session_id = (void *)(uintptr_t)pkt->session_id;
data_done.status = hfi_map_err_status(pkt->error_type);
data_done.output_done.packet_buffer1 =
(ion_phys_addr_t)pkt->sequence_header;
data_done.output_done.filled_len1 = pkt->header_len;
dprintk(VIDC_INFO, "seq_hdr: %#x, Length: %d\n",
pkt->sequence_header, pkt->header_len);
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_SESSION_GET_SEQ_HDR_DONE,
.response.data = data_done,
};
return 0;
}
static void hfi_process_sys_get_prop_image_version(
struct hfi_msg_sys_property_info_packet *pkt)
{
int i = 0;
u32 smem_block_size = 0;
u8 *smem_table_ptr;
char version[256];
const u32 version_string_size = 128;
const u32 smem_image_index_venus = 14 * 128;
u8 *str_image_version;
int req_bytes;
req_bytes = pkt->size - sizeof(*pkt);
if (req_bytes < version_string_size ||
!pkt->rg_property_data[1] ||
pkt->num_properties > 1) {
dprintk(VIDC_ERR,
"hfi_process_sys_get_prop_image_version: bad_pkt: %d\n",
req_bytes);
return;
}
str_image_version = (u8 *)&pkt->rg_property_data[1];
/*
* The version string returned by firmware includes null
* characters at the start and in between. Replace the null
* characters with space, to print the version info.
*/
for (i = 0; i < version_string_size; i++) {
if (str_image_version[i] != '\0')
version[i] = str_image_version[i];
else
version[i] = ' ';
}
version[i] = '\0';
dprintk(VIDC_DBG, "F/W version: %s\n", version);
smem_table_ptr = smem_get_entry(SMEM_IMAGE_VERSION_TABLE,
&smem_block_size, 0, SMEM_ANY_HOST_FLAG);
if ((smem_image_index_venus + version_string_size) <= smem_block_size &&
smem_table_ptr)
memcpy(smem_table_ptr + smem_image_index_venus,
str_image_version, version_string_size);
}
static int hfi_process_sys_property_info(u32 device_id,
void *_pkt,
struct msm_vidc_cb_info *info)
{
struct hfi_msg_sys_property_info_packet *pkt = _pkt;
if (!pkt) {
dprintk(VIDC_ERR, "%s: invalid param\n", __func__);
return -EINVAL;
} else if (pkt->size < sizeof(*pkt)) {
dprintk(VIDC_ERR,
"hfi_process_sys_property_info: bad_pkt_size\n");
return -E2BIG;
} else if (!pkt->num_properties) {
dprintk(VIDC_ERR,
"hfi_process_sys_property_info: no_properties\n");
return -EINVAL;
}
switch (pkt->rg_property_data[0]) {
case HFI_PROPERTY_SYS_IMAGE_VERSION:
hfi_process_sys_get_prop_image_version(pkt);
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_RESPONSE_UNUSED,
};
return 0;
default:
dprintk(VIDC_DBG,
"hfi_process_sys_property_info: unknown_prop_id: %x\n",
pkt->rg_property_data[0]);
return -ENOTSUPP;
}
}
static int hfi_process_ignore(u32 device_id,
void *_pkt,
struct msm_vidc_cb_info *info)
{
*info = (struct msm_vidc_cb_info) {
.response_type = HAL_RESPONSE_UNUSED,
};
return 0;
}
int hfi_process_msg_packet(u32 device_id, struct vidc_hal_msg_pkt_hdr *msg_hdr,
struct msm_vidc_cb_info *info)
{
typedef int (*pkt_func_def)(u32, void *, struct msm_vidc_cb_info *info);
pkt_func_def pkt_func = NULL;
if (!info || !msg_hdr || msg_hdr->size < VIDC_IFACEQ_MIN_PKT_SIZE) {
dprintk(VIDC_ERR, "%s: bad packet/packet size\n",
__func__);
return -EINVAL;
}
dprintk(VIDC_DBG, "Parse response %#x\n", msg_hdr->packet);
switch (msg_hdr->packet) {
case HFI_MSG_EVENT_NOTIFY:
pkt_func = (pkt_func_def)hfi_process_event_notify;
break;
case HFI_MSG_SYS_INIT_DONE:
pkt_func = (pkt_func_def)hfi_process_sys_init_done;
break;
case HFI_MSG_SYS_SESSION_INIT_DONE:
pkt_func = (pkt_func_def)hfi_process_session_init_done;
break;
case HFI_MSG_SYS_PROPERTY_INFO:
pkt_func = (pkt_func_def)hfi_process_sys_property_info;
break;
case HFI_MSG_SYS_SESSION_END_DONE:
pkt_func = (pkt_func_def)hfi_process_session_end_done;
break;
case HFI_MSG_SESSION_LOAD_RESOURCES_DONE:
pkt_func = (pkt_func_def)hfi_process_session_load_res_done;
break;
case HFI_MSG_SESSION_START_DONE:
pkt_func = (pkt_func_def)hfi_process_session_start_done;
break;
case HFI_MSG_SESSION_STOP_DONE:
pkt_func = (pkt_func_def)hfi_process_session_stop_done;
break;
case HFI_MSG_SESSION_EMPTY_BUFFER_DONE:
pkt_func = (pkt_func_def)hfi_process_session_etb_done;
break;
case HFI_MSG_SESSION_FILL_BUFFER_DONE:
pkt_func = (pkt_func_def)hfi_process_session_ftb_done;
break;
case HFI_MSG_SESSION_FLUSH_DONE:
pkt_func = (pkt_func_def)hfi_process_session_flush_done;
break;
case HFI_MSG_SESSION_PROPERTY_INFO:
pkt_func = (pkt_func_def)hfi_process_session_prop_info;
break;
case HFI_MSG_SESSION_RELEASE_RESOURCES_DONE:
pkt_func = (pkt_func_def)hfi_process_session_rel_res_done;
break;
case HFI_MSG_SYS_RELEASE_RESOURCE:
pkt_func = (pkt_func_def)hfi_process_sys_rel_resource_done;
break;
case HFI_MSG_SESSION_GET_SEQUENCE_HEADER_DONE:
pkt_func = (pkt_func_def) hfi_process_session_get_seq_hdr_done;
break;
case HFI_MSG_SESSION_RELEASE_BUFFERS_DONE:
pkt_func = (pkt_func_def)hfi_process_session_rel_buf_done;
break;
case HFI_MSG_SYS_SESSION_ABORT_DONE:
pkt_func = (pkt_func_def)hfi_process_session_abort_done;
break;
case HFI_MSG_SESSION_SYNC_DONE:
pkt_func = (pkt_func_def)hfi_process_ignore;
break;
default:
dprintk(VIDC_DBG, "Unable to parse message: %#x\n",
msg_hdr->packet);
break;
}
return pkt_func ?
pkt_func(device_id, (void *)msg_hdr, info) : -ENOTSUPP;
}