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/*
* Copyright (c) 2019-2021, The Linux Foundation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above
* copyright notice, this list of conditions and the following
* disclaimer in the documentation and/or other materials provided
* with the distribution.
* * Neither the name of The Linux Foundation nor the names of its
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
* THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS
* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
* BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
* WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE
* OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN
* IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
/*
* Changes from Qualcomm Innovation Center are provided under the following license:
*
* Copyright (c) 2022 Qualcomm Innovation Center, Inc. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted (subject to the limitations in the
* disclaimer below) provided that the following conditions are met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
*
* * Redistributions in binary form must reproduce the above
* copyright notice, this list of conditions and the following
* disclaimer in the documentation and/or other materials provided
* with the distribution.
*
* * Neither the name of Qualcomm Innovation Center, Inc. nor the names of its
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* NO EXPRESS OR IMPLIED LICENSES TO ANY PARTY'S PATENT RIGHTS ARE
* GRANTED BY THIS LICENSE. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT
* HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
* IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE
* GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER
* IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
* OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN
* IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include <stdint.h>
#include <stdlib.h>
#include <drm.h>
// The 3 headers above are a workaround to prevent kernel drm.h from being used that has the
// "virtual" keyword used for a variable. In future replace libdrm version drm.h with kernel
// version drm/drm.h
#include <drm_logger.h>
#include <drm/drm_fourcc.h>
#include <display/drm/sde_drm.h>
#include <cstring>
#include <map>
#include <sstream>
#include <string>
#include <tuple>
#include <utility>
#include <vector>
#include <algorithm>
#include "drm_utils.h"
#include "drm_plane.h"
#include "drm_property.h"
namespace sde_drm {
using std::map;
using std::string;
using std::map;
using std::pair;
using std::make_pair;
using std::vector;
using std::unique_ptr;
using std::tuple;
using std::stringstream;
using std::mutex;
using std::lock_guard;
#define MAX_SCALER_LINEWIDTH 2560
static struct sde_drm_csc_v1 csc_10bit_convert[kCscTypeMax] = {
[kCscYuv2Rgb601L] = {
{
0x12A000000, 0x000000000, 0x198800000,
0x12A000000, 0x7F9B800000, 0x7F30000000,
0x12A000000, 0x204800000, 0x000000000,
},
{ 0xffc0, 0xfe00, 0xfe00,},
{ 0x0, 0x0, 0x0,},
{ 0x40, 0x3ac, 0x40, 0x3c0, 0x40, 0x3c0,},
{ 0x0, 0x3ff, 0x0, 0x3ff, 0x0, 0x3ff,},
},
[kCscYuv2Rgb601FR] = {
{
0x100000000, 0x0, 0x167000000,
0x100000000, 0x7fa8000000, 0x7f49000000,
0x100000000, 0x1c5800000, 0x0,
},
{ 0x0000, 0xfe00, 0xfe00,},
{ 0x0, 0x0, 0x0,},
{ 0x0, 0x3ff, 0x0, 0x3ff, 0x0, 0x3ff,},
{ 0x0, 0x3ff, 0x0, 0x3ff, 0x0, 0x3ff,},
},
[kCscYuv2Rgb709L] = {
{
0x12a000000, 0x0, 0x1cb000000,
0x12a000000, 0x7fc9800000, 0x7f77800000,
0x12a000000, 0x21d000000, 0x0,
},
{ 0xffc0, 0xfe00, 0xfe00,},
{ 0x0, 0x0, 0x0,},
{ 0x40, 0x3ac, 0x40, 0x3c0, 0x40, 0x3c0,},
{ 0x0, 0x3ff, 0x0, 0x3ff, 0x0, 0x3ff,},
},
[kCscYuv2Rgb709FR] = {
{
0x100000000, 0x0, 0x193000000,
0x100000000, 0x7fd0000000, 0x7f88000000,
0x100000000, 0x1db000000, 0x0,
},
{ 0x0, 0xfe00, 0xfe00,},
{ 0x0, 0x0, 0x0, },
{ 0x0, 0x3ff, 0x0, 0x3ff, 0x0, 0x3ff,},
{ 0x0, 0x3ff, 0x0, 0x3ff, 0x0, 0x3ff,},
},
[kCscYuv2Rgb2020L] = {
{
0x12b000000, 0x0, 0x1af000000,
0x12b000000, 0x7fd0000000, 0x7f59000000,
0x12b000000, 0x226000000, 0x0,
},
{ 0xffc0, 0xfe00, 0xfe00,},
{ 0x0, 0x0, 0x0,},
{ 0x40, 0x3ac, 0x40, 0x3c0, 0x40, 0x3c0,},
{ 0x0, 0x3ff, 0x0, 0x3ff, 0x0, 0x3ff,},
},
[kCscYuv2Rgb2020FR] = {
{
0x100000000, 0x0, 0x179800000,
0x100000000, 0x7fd6000000, 0x7f6d800000,
0x100000000, 0x1e1800000, 0x0,
},
{ 0x0000, 0xfe00, 0xfe00,},
{ 0x0, 0x0, 0x0,},
{ 0x0, 0x3ff, 0x0, 0x3ff, 0x0, 0x3ff,},
{ 0x0, 0x3ff, 0x0, 0x3ff, 0x0, 0x3ff,},
},
[kCscYuv2RgbDolbyVisionP5] = {
{
0x100000000, 0x0, 0x0,
0x0, 0x100000000, 0x0,
0x0, 0x0, 0x100000000,
},
{ 0x0, 0x0, 0x0,},
{ 0x0, 0x0, 0x0,},
{ 0x0, 0x3ff, 0x0, 0x3ff, 0x0, 0x3ff,},
{ 0x0, 0x3ff, 0x0, 0x3ff, 0x0, 0x3ff,},
}
};
static struct drm_msm_fp16_csc csc_fp16_convert[kFP16CscTypeMax] = {
[kFP16CscSrgb2Dcip3] = {
0x0, // flags -- currently unused
FP16_CSC_CFG0_PARAM_LEN,
{
0x3A94, 0x31AE, 0x0, 0x0,
0x2840, 0x3BBC, 0x0, 0x0,
0x2460, 0x2CA2, 0x3B49, 0x0,
},
FP16_CSC_CFG1_PARAM_LEN,
{0xB333, 0x3CE6, 0XA962, 0x3C2B, 0xAE49, 0x3C65, 0x0, 0x3C00,}
},
[kFP16CscSrgb2Bt2020] = {
0x0, // flags -- currently unused
FP16_CSC_CFG0_PARAM_LEN,
{
0x3905, 0x3545, 0x2988, 0x0,
0x2C6D, 0x3B58, 0x21D8, 0x0,
0x2434, 0x2DA3, 0x3B2A, 0x0,
},
FP16_CSC_CFG1_PARAM_LEN,
{0xD527, 0x5A7D, 0XCC26, 0x586D, 0xCB6C, 0x585D, 0x0, 0x57D0,}
},
};
static uint8_t REFLECT_X = 0;
static uint8_t REFLECT_Y = 0;
static uint8_t ROTATE_90 = 0;
static uint8_t ROTATE_0 = 0;
// FB Secure Modes
static uint8_t NON_SECURE = 0;
static uint8_t SECURE = 1;
static uint8_t NON_SECURE_DIR_TRANSLATION = 2;
static uint8_t SECURE_DIR_TRANSLATION = 3;
// Multi rect modes
static uint8_t MULTIRECT_NONE = 0;
static uint8_t MULTIRECT_PARALLEL = 1;
static uint8_t MULTIRECT_SERIAL = 2;
// Blend Type
static uint8_t UNDEFINED = 0;
static uint8_t OPAQUE = 1;
static uint8_t PREMULTIPLIED = 2;
static uint8_t COVERAGE = 3;
static uint8_t SKIP_BLENDING = 4;
static void SetRect(DRMRect &source, drm_clip_rect *target) {
target->x1 = uint16_t(source.left);
target->y1 = uint16_t(source.top);
target->x2 = uint16_t(source.right);
target->y2 = uint16_t(source.bottom);
}
static void PopulateReflect(drmModePropertyRes *prop) {
if (REFLECT_X) {
return;
}
if (!drm_property_type_is(prop, DRM_MODE_PROP_BITMASK)) {
return;
}
for (auto i = 0; i < prop->count_enums; i++) {
string enum_name(prop->enums[i].name);
if (enum_name == "reflect-x") {
REFLECT_X = prop->enums[i].value;
} else if (enum_name == "reflect-y") {
REFLECT_Y = prop->enums[i].value;
} else if (enum_name == "rotate-90") {
ROTATE_90 = prop->enums[i].value;
} else if (enum_name == "rotate-0") {
ROTATE_0 = prop->enums[i].value;
}
}
}
static void PopulateSecureModes(drmModePropertyRes *prop) {
static bool secure_modes_populated = false;
if (!secure_modes_populated) {
for (auto i = 0; i < prop->count_enums; i++) {
string enum_name(prop->enums[i].name);
if (enum_name == "non_sec") {
NON_SECURE = prop->enums[i].value;
} else if (enum_name == "sec") {
SECURE = prop->enums[i].value;
} else if (enum_name == "non_sec_direct_translation") {
NON_SECURE_DIR_TRANSLATION = prop->enums[i].value;
} else if (enum_name == "sec_direct_translation") {
SECURE_DIR_TRANSLATION = prop->enums[i].value;
}
}
secure_modes_populated = true;
}
}
static InlineRotationVersion PopulateInlineRotationVersion(uint32_t ver) {
switch (ver) {
case 0x0000: return InlineRotationVersion::kInlineRotationNone;
case 0x0001:
case 0x0100: return InlineRotationVersion::kInlineRotationV1;
case 0x0200:
case 0x0201: return InlineRotationVersion::kInlineRotationV2;
default: return InlineRotationVersion::kInlineRotationNone;
}
}
static QSEEDStepVersion PopulateQseedStepVersion(uint32_t hw_ver) {
switch (hw_ver) {
case 0x1003: return QSEEDStepVersion::V3;
case 0x1004: return QSEEDStepVersion::V4;
case 0x2004: return QSEEDStepVersion::V3LITE_V4;
case 0x3000: return QSEEDStepVersion::V3LITE_V5;
case 0x3001: return QSEEDStepVersion::V3LITE_V7;
case 0x3002: return QSEEDStepVersion::V3LITE_V8;
// default value. also corresponds to (hw_ver == 0x1002)
default: return QSEEDStepVersion::V2;
}
}
static void PopulateMultiRectModes(drmModePropertyRes *prop) {
static bool multirect_modes_populated = false;
if (!multirect_modes_populated) {
for (auto i = 0; i < prop->count_enums; i++) {
string enum_name(prop->enums[i].name);
if (enum_name == "none") {
MULTIRECT_NONE = prop->enums[i].value;
} else if (enum_name == "parallel") {
MULTIRECT_PARALLEL = prop->enums[i].value;
} else if (enum_name == "serial") {
MULTIRECT_SERIAL = prop->enums[i].value;
}
}
multirect_modes_populated = true;
}
}
static void PopulateBlendType(drmModePropertyRes *prop) {
static bool blend_type_populated = false;
if (!blend_type_populated) {
for (auto i = 0; i < prop->count_enums; i++) {
string enum_name(prop->enums[i].name);
if (enum_name == "not_defined") {
UNDEFINED = prop->enums[i].value;
} else if (enum_name == "opaque") {
OPAQUE = prop->enums[i].value;
} else if (enum_name == "premultiplied") {
PREMULTIPLIED = prop->enums[i].value;
} else if (enum_name == "coverage") {
COVERAGE = prop->enums[i].value;
} else if (enum_name == "skip_blending") {
SKIP_BLENDING = prop->enums[i].value;
}
}
blend_type_populated = true;
}
}
static const char *GetColorLutString(DRMTonemapLutType lut_type) {
switch (lut_type) {
case DRMTonemapLutType::DMA_1D_IGC:
return "DMA IGC";
case DRMTonemapLutType::DMA_1D_GC:
return "DMA GC";
case DRMTonemapLutType::VIG_1D_IGC:
return "VIG IGC";
case DRMTonemapLutType::VIG_3D_GAMUT:
return "VIG 3D";
default:
return "Unknown Lut";
}
}
#define __CLASS__ "DRMPlaneManager"
static bool GetDRMonemapLutTypeFromPPFeatureID(DRMPPFeatureID id, DRMTonemapLutType *lut_type) {
switch (id) {
case kFeatureDgmIgc:
*lut_type = DRMTonemapLutType::DMA_1D_IGC;
break;
case kFeatureDgmGc:
*lut_type = DRMTonemapLutType::DMA_1D_GC;
break;
case kFeatureVigIgc:
*lut_type = DRMTonemapLutType::VIG_1D_IGC;
break;
case kFeatureVigGamut:
*lut_type = DRMTonemapLutType::VIG_3D_GAMUT;
break;
default:
DRM_LOGE("Invalid DRMPPFeature id = %d", id);
return false;
}
return true;
}
DRMPlaneManager::DRMPlaneManager(int fd) : fd_(fd) {}
void DRMPlaneManager::Init() {
lock_guard<mutex> lock(lock_);
drmModePlaneRes *resource = drmModeGetPlaneResources(fd_);
if (!resource) {
return;
}
const uint32_t yield_on_count = 5;
for (uint32_t i = 0; i < resource->count_planes; i++) {
if (!(i % yield_on_count)) {
sched_yield();
}
// The enumeration order itself is the priority from high to low
unique_ptr<DRMPlane> plane(new DRMPlane(fd_, i));
drmModePlane *libdrm_plane = drmModeGetPlane(fd_, resource->planes[i]);
if (libdrm_plane) {
plane->InitAndParse(libdrm_plane);
plane_pool_[resource->planes[i]] = std::move(plane);
} else {
DRM_LOGE("Critical error: drmModeGetPlane() failed for plane %d.", resource->planes[i]);
}
}
drmModeFreePlaneResources(resource);
}
void DRMPlaneManager::DumpByID(uint32_t id) {
lock_guard<mutex> lock(lock_);
plane_pool_.at(id)->Dump();
}
void DRMPlaneManager::Perform(DRMOps code, uint32_t obj_id, drmModeAtomicReq *req, va_list args) {
lock_guard<mutex> lock(lock_);
auto it = plane_pool_.find(obj_id);
if (it == plane_pool_.end()) {
DRM_LOGE("Invalid plane id %d", obj_id);
return;
}
if (code == DRMOps::PLANE_SET_SCALER_CONFIG) {
if (it->second->ConfigureScalerLUT(req, dir_lut_blob_id_, cir_lut_blob_id_,
sep_lut_blob_id_)) {
DRM_LOGD("Plane %d: Configuring scaler LUTs", obj_id);
}
}
it->second->Perform(code, req, args);
}
void DRMPlaneManager::Perform(DRMOps code, drmModeAtomicReq *req, uint32_t obj_id, ...) {
lock_guard<mutex> lock(lock_);
va_list args;
va_start(args, obj_id);
Perform(code, obj_id, req, args);
va_end(args);
}
void DRMPlaneManager::DumpAll() {
lock_guard<mutex> lock(lock_);
for (uint32_t i = 0; i < plane_pool_.size(); i++) {
plane_pool_[i]->Dump();
}
}
void DRMPlaneManager::GetPlanesInfo(DRMPlanesInfo *info) {
lock_guard<mutex> lock(lock_);
for (auto &plane : plane_pool_) {
info->push_back(std::make_pair(plane.first, plane.second->GetPlaneTypeInfo()));
}
}
void DRMPlaneManager::UnsetUnusedResources(uint32_t crtc_id, bool is_commit, drmModeAtomicReq *req) {
// Unset planes that were assigned to the crtc referred to by crtc_id but are not requested
// in this round
lock_guard<mutex> lock(lock_);
for (auto &plane : plane_pool_) {
uint32_t assigned_crtc = 0;
uint32_t requested_crtc = 0;
plane.second->GetAssignedCrtc(&assigned_crtc);
plane.second->GetRequestedCrtc(&requested_crtc);
if (assigned_crtc == crtc_id && requested_crtc == 0) {
plane.second->Unset(is_commit, req);
} else if (requested_crtc == crtc_id) {
// Plane is acquired, call reset color luts, which will reset if needed
plane.second->ResetColorLUTs(is_commit, req);
}
}
}
void DRMPlaneManager::RetainPlanes(uint32_t crtc_id) {
lock_guard<mutex> lock(lock_);
for (auto &plane : plane_pool_) {
uint32_t assigned_crtc = 0;
plane.second->GetAssignedCrtc(&assigned_crtc);
if (assigned_crtc == crtc_id) {
// Pretend this plane was requested by client
plane.second->SetRequestedCrtc(crtc_id);
const uint32_t plane_id = plane.first;
DRM_LOGD("Plane %d: Retaining on CRTC %d", plane_id, crtc_id);
}
}
}
void DRMPlaneManager::PostValidate(uint32_t crtc_id, bool success) {
lock_guard<mutex> lock(lock_);
for (auto &plane : plane_pool_) {
plane.second->PostValidate(crtc_id, success);
}
}
void DRMPlaneManager::PostCommit(uint32_t crtc_id, bool success) {
lock_guard<mutex> lock(lock_);
DRM_LOGD("crtc %d", crtc_id);
for (auto &plane : plane_pool_) {
plane.second->PostCommit(crtc_id, success);
}
}
void DRMPlaneManager::SetScalerLUT(const DRMScalerLUTInfo &lut_info) {
lock_guard<mutex> lock(lock_);
if (lut_info.dir_lut_size) {
drmModeCreatePropertyBlob(fd_, reinterpret_cast<void *>(lut_info.dir_lut),
lut_info.dir_lut_size, &dir_lut_blob_id_);
}
if (lut_info.cir_lut_size) {
drmModeCreatePropertyBlob(fd_, reinterpret_cast<void *>(lut_info.cir_lut),
lut_info.cir_lut_size, &cir_lut_blob_id_);
}
if (lut_info.sep_lut_size) {
drmModeCreatePropertyBlob(fd_, reinterpret_cast<void *>(lut_info.sep_lut),
lut_info.sep_lut_size, &sep_lut_blob_id_);
}
}
void DRMPlaneManager::UnsetScalerLUT() {
lock_guard<mutex> lock(lock_);
if (dir_lut_blob_id_) {
drmModeDestroyPropertyBlob(fd_, dir_lut_blob_id_);
dir_lut_blob_id_ = 0;
}
if (cir_lut_blob_id_) {
drmModeDestroyPropertyBlob(fd_, cir_lut_blob_id_);
cir_lut_blob_id_ = 0;
}
if (sep_lut_blob_id_) {
drmModeDestroyPropertyBlob(fd_, sep_lut_blob_id_);
sep_lut_blob_id_ = 0;
}
}
void DRMPlaneManager::ResetCache(drmModeAtomicReq *req, uint32_t crtc_id) {
lock_guard<mutex> lock(lock_);
for (auto &plane : plane_pool_) {
uint32_t assigned_crtc = 0;
plane.second->GetAssignedCrtc(&assigned_crtc);
if (assigned_crtc == crtc_id) {
plane.second->ResetCache(req);
}
}
}
void DRMPlaneManager::ResetPlanesLUT(drmModeAtomicReq *req) {
lock_guard<mutex> lock(lock_);
for (auto &plane : plane_pool_) {
plane.second->ResetPlanesLUT(req);
}
}
void DRMPlaneManager::MapPlaneToCrtc(std::map<uint32_t, uint32_t> *plane_to_crtc) {
lock_guard<mutex> lock(lock_);
if (!plane_to_crtc) {
DLOGE("Map is NULL! Not expected.");
return;
}
plane_to_crtc->clear();
for (auto &plane : plane_pool_) {
uint32_t crtc_id = 0;
plane.second->GetCrtc(&crtc_id);
if (crtc_id)
plane_to_crtc->insert(make_pair(plane.first, crtc_id));
}
}
void DRMPlaneManager::GetPlaneIdsFromDescriptions(FetchResourceList &descriptions,
std::vector<uint32_t> *plane_ids) {
lock_guard<mutex> lock(lock_);
for (auto &desc : descriptions) {
const string &type_str = std::get<0>(desc);
DRMPlaneType type = DRMPlaneType::MAX;
if (type_str == "DMA") {
type = DRMPlaneType::DMA;
} else {
continue;
}
const int32_t &idx = std::get<1>(desc);
const int8_t &rect = std::get<2>(desc);
for (auto &p : plane_pool_) {
DRMPlaneType plane_type;
p.second->GetType(&plane_type);
uint8_t plane_idx;
p.second->GetIndex(&plane_idx);
uint8_t plane_rect;
p.second->GetRect(&plane_rect);
if (plane_idx == idx && plane_rect == rect && plane_type == type) {
plane_ids->emplace_back(p.first);
break;
}
}
}
}
// ==============================================================================================//
#undef __CLASS__
#define __CLASS__ "DRMPlane"
DRMPlane::DRMPlane(int fd, uint32_t priority) : fd_(fd), priority_(priority) {}
DRMPlane::~DRMPlane() {
drmModeFreePlane(drm_plane_);
}
void DRMPlane::GetTypeInfo(const PropertyMap &prop_map) {
uint64_t blob_id = 0;
drmModePropertyRes *prop = nullptr;
DRMPlaneTypeInfo *info = &plane_type_info_;
// Ideally we should check if this property type is a blob and then proceed.
std::tie(blob_id, prop) = prop_map.at(DRMProperty::CAPABILITIES);
drmModePropertyBlobRes *blob = drmModeGetPropertyBlob(fd_, blob_id);
if (!blob) {
return;
}
if (!blob->data) {
return;
}
char *fmt_str = new char[blob->length + 1];
memcpy (fmt_str, blob->data, blob->length);
fmt_str[blob->length] = '\0';
info->max_linewidth = 2560;
info->max_scaler_linewidth = MAX_SCALER_LINEWIDTH;
info->max_upscale = 1;
info->max_downscale = 1;
info->max_horizontal_deci = 0;
info->max_vertical_deci = 0;
info->master_plane_id = 0;
if (info->type == DRMPlaneType::CURSOR) {
info->max_linewidth = 128;
}
// TODO(user): change default to V2 once we start getting V3 via capabilities blob
info->qseed3_version = QSEEDStepVersion::V3;
info->has_excl_rect = has_excl_rect_;
// We may have multiple lines with each one dedicated for something specific
// like formats etc
stringstream stream(fmt_str);
DRM_LOGI("stream str %s len %zu blob str %s len %d", stream.str().c_str(), stream.str().length(),
blob->data, blob->length);
string line = {};
string pixel_formats = "pixel_formats=";
string max_linewidth = "max_linewidth=";
string max_upscale = "max_upscale=";
string max_downscale = "max_downscale=";
string max_horizontal_deci = "max_horizontal_deci=";
string max_vertical_deci = "max_vertical_deci=";
string master_plane_id = "primary_smart_plane_id=";
string max_pipe_bw = "max_per_pipe_bw=";
string max_pipe_bw_high = "max_per_pipe_bw_high=";
string scaler_version = "scaler_step_ver=";
string block_sec_ui = "block_sec_ui=";
string true_inline_rot_rev = "true_inline_rot_rev=";
string inline_rot_pixel_formats = "inline_rot_pixel_formats=";
string true_inline_dwnscale_rt_numerator = "true_inline_dwnscale_rt_numerator=";
string true_inline_dwnscale_rt_denominator = "true_inline_dwnscale_rt_denominator=";
string true_inline_max_height = "true_inline_max_height=";
string pipe_idx = "pipe_idx=";
string demura_block = "demura_block=";
while (std::getline(stream, line)) {
if (line.find(inline_rot_pixel_formats) != string::npos) {
vector<pair<uint32_t, uint64_t>> inrot_formats_supported;
ParseFormats(line.erase(0, inline_rot_pixel_formats.length()), &inrot_formats_supported);
info->inrot_fmts_supported = std::move(inrot_formats_supported);
} else if (line.find(pixel_formats) != string::npos) {
vector<pair<uint32_t, uint64_t>> formats_supported;
ParseFormats(line.erase(0, pixel_formats.length()), &formats_supported);
info->formats_supported = std::move(formats_supported);
} else if (line.find(max_linewidth) != string::npos) {
info->max_linewidth = std::stoi(line.erase(0, max_linewidth.length()));
} else if (line.find(max_upscale) != string::npos) {
info->max_upscale = std::stoi(line.erase(0, max_upscale.length()));
} else if (line.find(max_downscale) != string::npos) {
info->max_downscale = std::stoi(line.erase(0, max_downscale.length()));
} else if (line.find(max_horizontal_deci) != string::npos) {
info->max_horizontal_deci = std::stoi(line.erase(0, max_horizontal_deci.length()));
} else if (line.find(max_vertical_deci) != string::npos) {
info->max_vertical_deci = std::stoi(line.erase(0, max_vertical_deci.length()));
} else if (line.find(master_plane_id) != string::npos) {
info->master_plane_id = std::stoi(line.erase(0, master_plane_id.length()));
DRM_LOGI("info->master_plane_id: detected master_plane=%d", info->master_plane_id);
} else if (line.find(max_pipe_bw) != string::npos) {
info->max_pipe_bandwidth = std::stoull(line.erase(0, max_pipe_bw.length()));
} else if (line.find(max_pipe_bw_high) != string::npos) {
info->max_pipe_bandwidth_high = std::stoull(line.erase(0, max_pipe_bw_high.length()));
} else if (line.find(scaler_version) != string::npos) {
info->qseed3_version =
PopulateQseedStepVersion(std::stoi(line.erase(0, scaler_version.length())));
} else if (line.find(block_sec_ui) != string::npos) {
info->block_sec_ui = !!(std::stoi(line.erase(0, block_sec_ui.length())));
} else if (line.find(true_inline_rot_rev) != string::npos) {
info->inrot_version =
PopulateInlineRotationVersion(std::stoi(line.erase(0, true_inline_rot_rev.length())));
} else if (line.find(true_inline_dwnscale_rt_numerator) != string::npos) {
info->true_inline_dwnscale_rt_num = std::stof(line.erase(0,
true_inline_dwnscale_rt_numerator.length()));
} else if (line.find(true_inline_dwnscale_rt_denominator) != string::npos) {
info->true_inline_dwnscale_rt_denom = std::stof(line.erase(0,
true_inline_dwnscale_rt_denominator.length()));
} else if (line.find(true_inline_max_height) != string::npos) {
info->max_rotation_linewidth = std::stoi(line.erase(0, true_inline_max_height.length()));
} else if (line.find(pipe_idx) != string::npos) {
info->pipe_idx = std::stoi(line.erase(0, pipe_idx.length()));
} else if (line.find(demura_block) != string::npos) {
info->demura_block_capability = std::stoi(line.erase(0, demura_block.length()));
}
}
// TODO(user): Get max_scaler_linewidth and non_scaler_linewidth from driver
// max_linewidth can be smaller than 2560 for few target, so make sure to assign the minimum of both
info->max_scaler_linewidth = (info->qseed3_version < QSEEDStepVersion::V4) ? info->max_linewidth :
std::min((uint32_t)MAX_SCALER_LINEWIDTH, info->max_linewidth);
drmModeFreePropertyBlob(blob);
delete[] fmt_str;
}
void DRMPlane::ParseProperties() {
// Map of property name to current value and property info pointer
PropertyMap prop_map;
bool csc = false;
bool scaler = false;
bool cursor = false;
drmModeObjectProperties *props =
drmModeObjectGetProperties(fd_, drm_plane_->plane_id, DRM_MODE_OBJECT_PLANE);
if (!props || !props->props || !props->prop_values) {
drmModeFreeObjectProperties(props);
return;
}
for (uint32_t j = 0; j < props->count_props; j++) {
drmModePropertyRes *info = drmModeGetProperty(fd_, props->props[j]);
if (!info) {
continue;
}
string property_name(info->name);
DRMProperty prop_enum = prop_mgr_.GetPropertyEnum(property_name);
if (prop_enum == DRMProperty::INVALID) {
DRM_LOGD("DRMProperty %s missing from global property mapping", info->name);
drmModeFreeProperty(info);
continue;
}
if (prop_enum == DRMProperty::EXCL_RECT) {
has_excl_rect_ = true;
}
if (prop_enum == DRMProperty::ROTATION) {
PopulateReflect(info);
} else if (prop_enum == DRMProperty::FB_TRANSLATION_MODE) {
PopulateSecureModes(info);
} else if (prop_enum == DRMProperty::MULTIRECT_MODE) {
PopulateMultiRectModes(info);
plane_type_info_.multirect_prop_present = true;
} else if (prop_enum == DRMProperty::BLEND_OP) {
PopulateBlendType(info);
}
prop_mgr_.SetPropertyId(prop_enum, info->prop_id);
prop_map[prop_enum] = std::make_tuple(props->prop_values[j], info);
csc = prop_enum == DRMProperty::CSC_V1 ? true : csc;
scaler = (prop_enum == DRMProperty::SCALER_V1 || prop_enum == DRMProperty::SCALER_V2) \
? true : scaler;
cursor = (prop_enum == DRMProperty::TYPE && props->prop_values[j] == DRM_PLANE_TYPE_CURSOR) \
? true : cursor;
// Tone mapping properties.
if (prop_enum == DRMProperty::INVERSE_PMA) {
plane_type_info_.inverse_pma = true;
}
if ((uint32_t)prop_enum >= (uint32_t)DRMProperty::CSC_DMA_V1 &&
(uint32_t)prop_enum <= (uint32_t)DRMProperty::CSC_DMA_V1) {
plane_type_info_.dgm_csc_version =
((uint32_t)prop_enum - (uint32_t)DRMProperty::CSC_DMA_V1 + 1);
}
if ((uint32_t)prop_enum >= (uint32_t)DRMProperty::SDE_DGM_1D_LUT_IGC_V5 &&
(uint32_t)prop_enum <= (uint32_t)DRMProperty::SDE_DGM_1D_LUT_IGC_V5) {
plane_type_info_.tonemap_lut_version_map[DRMTonemapLutType::DMA_1D_IGC] =
((uint32_t)prop_enum - (uint32_t)DRMProperty::SDE_DGM_1D_LUT_IGC_V5 + 5);
}
if ((uint32_t)prop_enum >= (uint32_t)DRMProperty::SDE_DGM_1D_LUT_GC_V5 &&
(uint32_t)prop_enum <= (uint32_t)DRMProperty::SDE_DGM_1D_LUT_GC_V5) {
plane_type_info_.tonemap_lut_version_map[DRMTonemapLutType::DMA_1D_GC] =
((uint32_t)prop_enum - (uint32_t)DRMProperty::SDE_DGM_1D_LUT_GC_V5 + 5);
}
if ((uint32_t)prop_enum >= (uint32_t)DRMProperty::SDE_VIG_1D_LUT_IGC_V5 &&
(uint32_t)prop_enum <= (uint32_t)DRMProperty::SDE_VIG_1D_LUT_IGC_V6) {
plane_type_info_.tonemap_lut_version_map[DRMTonemapLutType::VIG_1D_IGC] =
((uint32_t)prop_enum - (uint32_t)DRMProperty::SDE_VIG_1D_LUT_IGC_V5 + 5);
}
if ((uint32_t)prop_enum >= (uint32_t)DRMProperty::SDE_VIG_3D_LUT_GAMUT_V5 &&
(uint32_t)prop_enum <= (uint32_t)DRMProperty::SDE_VIG_3D_LUT_GAMUT_V6) {
plane_type_info_.tonemap_lut_version_map[DRMTonemapLutType::VIG_3D_GAMUT] =
((uint32_t)prop_enum - (uint32_t)DRMProperty::SDE_VIG_3D_LUT_GAMUT_V5 + 5);
}
}
DRMPlaneType type = DRMPlaneType::DMA;
if (csc && scaler) {
type = DRMPlaneType::VIG;
} else if (cursor) {
type = DRMPlaneType::CURSOR;
}
plane_type_info_.type = type;
GetTypeInfo(prop_map);
for (auto &prop : prop_map) {
drmModeFreeProperty(std::get<1>(prop.second));
}
drmModeFreeObjectProperties(props);
}
void DRMPlane::InitAndParse(drmModePlane *plane) {
drm_plane_ = plane;
ParseProperties();
unique_ptr<DRMPPManager> pp_mgr(new DRMPPManager(fd_));
pp_mgr_ = std::move(pp_mgr);
pp_mgr_->Init(prop_mgr_, DRM_MODE_OBJECT_PLANE);
}
bool DRMPlane::ConfigureScalerLUT(drmModeAtomicReq *req, uint32_t dir_lut_blob_id,
uint32_t cir_lut_blob_id, uint32_t sep_lut_blob_id) {
if (plane_type_info_.type != DRMPlaneType::VIG || is_lut_configured_) {
return false;
}
if (dir_lut_blob_id) {
AddProperty(req, drm_plane_->plane_id,
prop_mgr_.GetPropertyId(DRMProperty::LUT_ED),
dir_lut_blob_id, false /* cache */, tmp_prop_val_map_);
}
if (cir_lut_blob_id) {
AddProperty(req, drm_plane_->plane_id,
prop_mgr_.GetPropertyId(DRMProperty::LUT_CIR),
cir_lut_blob_id, false /* cache */, tmp_prop_val_map_);
}
if (sep_lut_blob_id) {
AddProperty(req, drm_plane_->plane_id,
prop_mgr_.GetPropertyId(DRMProperty::LUT_SEP),
sep_lut_blob_id, false /* cache */, tmp_prop_val_map_);
}
return true;
}
void DRMPlane::SetExclRect(drmModeAtomicReq *req, DRMRect rect) {
auto prop_id = prop_mgr_.GetPropertyId(DRMProperty::EXCL_RECT);
drm_clip_rect clip_rect;
SetRect(rect, &clip_rect);
excl_rect_copy_ = clip_rect;
AddProperty(req, drm_plane_->plane_id, prop_id, reinterpret_cast<uint64_t>
(&excl_rect_copy_), false /* cache */, tmp_prop_val_map_);
DRM_LOGD("Plane %d: Setting exclusion rect [x,y,w,h][%d,%d,%d,%d]", drm_plane_->plane_id,
clip_rect.x1, clip_rect.y1, (clip_rect.x2 - clip_rect.x1),
(clip_rect.y2 - clip_rect.y1));
}
bool DRMPlane::SetCscConfig(drmModeAtomicReq *req, DRMCscType csc_type) {
if (plane_type_info_.type != DRMPlaneType::VIG) {
return false;
}
if (csc_type > kCscTypeMax) {
return false;
}
if (!prop_mgr_.IsPropertyAvailable(DRMProperty::CSC_V1)) {
return false;
}
auto prop_id = prop_mgr_.GetPropertyId(DRMProperty::CSC_V1);
if (csc_type == kCscTypeMax) {
AddProperty(req, drm_plane_->plane_id, prop_id, 0, false /* cache */, tmp_prop_val_map_);
} else {
csc_config_copy_ = csc_10bit_convert[csc_type];
AddProperty(req, drm_plane_->plane_id, prop_id,
reinterpret_cast<uint64_t>(&csc_config_copy_), false /* cache */,
tmp_prop_val_map_);
}
return true;
}
bool DRMPlane::SetFp16CscConfig(drmModeAtomicReq *req, DRMFp16CscType csc_type) {
if (csc_type > kFP16CscTypeMax) {
return false;
}
auto prop_id = prop_mgr_.GetPropertyId(DRMProperty::SDE_SSPP_FP16_CSC_V1);
if (!prop_id) {
return false;
}
if (csc_type == kFP16CscTypeMax) {
// Since logic for setting FP16 properties is in SetupAtomic, adding optimization for setting and
// resetting blob properties leads to AddProperty being called in Validate and ignored during
// Commit call. This invalidates the current FP16 test cases, and to avoid this we need to add
// SDM_VIRTUAL_DRIVER checks in both SetFp16CscConfig and SetFp16GcConfig
#ifndef SDM_VIRTUAL_DRIVER
if (!fp16_csc_blob_id_) {
return true;
}
#endif
UnsetFp16CscConfig();
AddProperty(req, drm_plane_->plane_id, prop_id, 0, false /* cache */, tmp_prop_val_map_);
} else {
#ifndef SDM_VIRTUAL_DRIVER
if (csc_type == fp16_csc_type_) {
return true;
}
#endif
UnsetFp16CscConfig();
drmModeCreatePropertyBlob(fd_, reinterpret_cast<void *>(&csc_fp16_convert[csc_type]),
sizeof(drm_msm_fp16_csc), &fp16_csc_blob_id_);
AddProperty(req, drm_plane_->plane_id, prop_id, fp16_csc_blob_id_, false /* cache */,
tmp_prop_val_map_);
}
fp16_csc_type_ = csc_type;
return true;
}
bool DRMPlane::SetFp16IgcConfig(drmModeAtomicReq *req, uint32_t igc_en) {
auto prop_id = prop_mgr_.GetPropertyId(DRMProperty::SDE_SSPP_FP16_IGC_V1);
if (!prop_id) {
return false;
}
AddProperty(req, drm_plane_->plane_id, prop_id, igc_en, false /* cache */, tmp_prop_val_map_);
return true;
}
bool DRMPlane::SetFp16UnmultConfig(drmModeAtomicReq *req, uint32_t unmult_en) {
auto prop_id = prop_mgr_.GetPropertyId(DRMProperty::SDE_SSPP_FP16_UNMULT_V1);
if (!prop_id) {
return false;
}
AddProperty(req, drm_plane_->plane_id, prop_id, unmult_en, false /* cache */, tmp_prop_val_map_);
return true;
}
bool DRMPlane::SetFp16GcConfig(drmModeAtomicReq *req, drm_msm_fp16_gc *fp16_gc_config) {
auto prop_id = prop_mgr_.GetPropertyId(DRMProperty::SDE_SSPP_FP16_GC_V1);
if (!prop_id) {
return false;
}
if (fp16_gc_config->mode == FP16_GC_MODE_INVALID) {
#ifndef SDM_VIRTUAL_DRIVER
if (!fp16_gc_blob_id_) {
return true;
}
#endif
UnsetFp16GcConfig();
AddProperty(req, drm_plane_->plane_id, prop_id, 0, false /* cache */, tmp_prop_val_map_);
} else {
#ifndef SDM_VIRTUAL_DRIVER
if (fp16_gc_config->mode == fp16_gc_config_.mode &&
fp16_gc_config->flags == fp16_gc_config_.flags) {
return true;
}
#endif
UnsetFp16GcConfig();
drmModeCreatePropertyBlob(fd_, reinterpret_cast<void *>(fp16_gc_config),
sizeof(drm_msm_fp16_gc), &fp16_gc_blob_id_);
AddProperty(req, drm_plane_->plane_id, prop_id, fp16_gc_blob_id_, false /* cache */,
tmp_prop_val_map_);
}
fp16_gc_config_.mode = fp16_gc_config->mode;
fp16_gc_config_.flags = fp16_gc_config->flags;
return true;
}
void DRMPlane::UnsetFp16CscConfig() {
if (fp16_csc_blob_id_) {
drmModeDestroyPropertyBlob(fd_, fp16_csc_blob_id_);
fp16_csc_blob_id_ = 0;
}
}
void DRMPlane::UnsetFp16GcConfig() {
if (fp16_gc_blob_id_) {
drmModeDestroyPropertyBlob(fd_, fp16_gc_blob_id_);
fp16_gc_blob_id_ = 0;
}
}
bool DRMPlane::SetScalerConfig(drmModeAtomicReq *req, uint64_t handle) {
if (plane_type_info_.type != DRMPlaneType::VIG) {
return false;
}
if (prop_mgr_.IsPropertyAvailable(DRMProperty::SCALER_V2)) {
auto prop_id = prop_mgr_.GetPropertyId(DRMProperty::SCALER_V2);
sde_drm_scaler_v2 *scaler_v2_config = reinterpret_cast<sde_drm_scaler_v2 *>(handle);
uint64_t scaler_data = 0;
// The address needs to be valid even after async commit, since we are sending address to
// driver directly, instead of blob. So we need to copy over contents that client sent. Client
// may have sent an address of object on stack which will be released after this call.
scaler_v2_config_copy_ = *scaler_v2_config;
if (scaler_v2_config_copy_.enable) {
scaler_data = reinterpret_cast<uint64_t>(&scaler_v2_config_copy_);
}
AddProperty(req, drm_plane_->plane_id, prop_id, scaler_data, false /* cache */,
tmp_prop_val_map_);
return true;
}
return false;
}
void DRMPlane::SetDecimation(drmModeAtomicReq *req, uint32_t prop_id, uint32_t prop_value) {
if (plane_type_info_.type == DRMPlaneType::DMA || plane_type_info_.master_plane_id) {
// if value is 0, client is just trying to clear previous decimation, so bail out silently
if (prop_value > 0) {
DRM_LOGE("Plane %d: Setting decimation %d is not supported.", drm_plane_->plane_id,
prop_value);
}
return;
}
// TODO(user): Currently a ViG plane in smart DMA mode could receive a non-zero decimation value
// but there is no good way to catch. In any case fix will be in client
AddProperty(req, drm_plane_->plane_id, prop_id, prop_value, true /* cache */, tmp_prop_val_map_);
DRM_LOGD("Plane %d: Setting decimation %d", drm_plane_->plane_id, prop_value);
}
void DRMPlane::PostValidate(uint32_t crtc_id, bool success) {
if (requested_crtc_id_ == crtc_id) {
SetRequestedCrtc(0);
if (!success) {
ResetColorLUTs(true, nullptr);
}
tmp_prop_val_map_ = committed_prop_val_map_;
}
}
void DRMPlane::PostCommit(uint32_t crtc_id, bool success) {
DRM_LOGD("crtc %d", crtc_id);
if (!success) {
// To reset
PostValidate(crtc_id, success);
return;
}
uint32_t assigned_crtc = 0;
uint32_t requested_crtc = 0;
GetAssignedCrtc(&assigned_crtc);
GetRequestedCrtc(&requested_crtc);
// In future, it is possible that plane is already attached in case of continuous splash. This
// will cause the first commit to only unstage pipes. We want to mark luts as configured only
// when they really are, which typically happens if a crtc is requested for a plane
if (requested_crtc == crtc_id && !is_lut_configured_) {
is_lut_configured_ = true;
}
if (requested_crtc && assigned_crtc && requested_crtc != assigned_crtc) {
// We should never be here
DRM_LOGE("Found plane %d switching from crtc %d to crtc %d", drm_plane_->plane_id,
assigned_crtc, requested_crtc);
}
// If we have set a pipe OR unset a pipe during commit, update states
if (requested_crtc == crtc_id || assigned_crtc == crtc_id) {
committed_prop_val_map_ = tmp_prop_val_map_;
SetAssignedCrtc(requested_crtc);
SetRequestedCrtc(0);
}
}
void DRMPlane::Perform(DRMOps code, drmModeAtomicReq *req, va_list args) {
uint32_t prop_id = 0;
uint32_t obj_id = drm_plane_->plane_id;
switch (code) {
// TODO(user): Check if these exist in map before attempting to access
case DRMOps::PLANE_SET_SRC_RECT: {
DRMRect rect = va_arg(args, DRMRect);
// source co-ordinates accepted by DRM are 16.16 fixed point
prop_id = prop_mgr_.GetPropertyId(DRMProperty::SRC_X);
AddProperty(req, obj_id, prop_id, rect.left << 16, true /* cache */, tmp_prop_val_map_);
prop_id = prop_mgr_.GetPropertyId(DRMProperty::SRC_Y);
AddProperty(req, obj_id, prop_id, rect.top << 16, true /* cache */, tmp_prop_val_map_);
prop_id = prop_mgr_.GetPropertyId(DRMProperty::SRC_W);
AddProperty(req, obj_id, prop_id, (rect.right - rect.left) << 16, true /* cache */,
tmp_prop_val_map_);
prop_id = prop_mgr_.GetPropertyId(DRMProperty::SRC_H);
AddProperty(req, obj_id, prop_id, (rect.bottom - rect.top) << 16, true /* cache */,
tmp_prop_val_map_);
DRM_LOGV("Plane %d: Setting crop [x,y,w,h][%d,%d,%d,%d]", obj_id, rect.left,
rect.top, (rect.right - rect.left), (rect.bottom - rect.top));
} break;
case DRMOps::PLANE_SET_DST_RECT: {
DRMRect rect = va_arg(args, DRMRect);
prop_id = prop_mgr_.GetPropertyId(DRMProperty::CRTC_X);
AddProperty(req, obj_id, prop_id, rect.left, true /* cache */, tmp_prop_val_map_);
prop_id = prop_mgr_.GetPropertyId(DRMProperty::CRTC_Y);
AddProperty(req, obj_id, prop_id, rect.top, true /* cache */, tmp_prop_val_map_);
prop_id = prop_mgr_.GetPropertyId(DRMProperty::CRTC_W);
AddProperty(req, obj_id, prop_id, (rect.right - rect.left), true /* cache */,
tmp_prop_val_map_);
prop_id = prop_mgr_.GetPropertyId(DRMProperty::CRTC_H);
AddProperty(req, obj_id, prop_id, (rect.bottom - rect.top), true /* cache */,
tmp_prop_val_map_);
DRM_LOGV("Plane %d: Setting dst [x,y,w,h][%d,%d,%d,%d]", obj_id, rect.left,
rect.top, (rect.right - rect.left), (rect.bottom - rect.top));
} break;
case DRMOps::PLANE_SET_EXCL_RECT: {
DRMRect excl_rect = va_arg(args, DRMRect);
SetExclRect(req, excl_rect);
} break;
case DRMOps::PLANE_SET_ZORDER: {
uint32_t zpos = va_arg(args, uint32_t);
prop_id = prop_mgr_.GetPropertyId(DRMProperty::ZPOS);
AddProperty(req, obj_id, prop_id, zpos, true /* cache */, tmp_prop_val_map_);
DRM_LOGD("Plane %d: Setting z %d", obj_id, zpos);
} break;
case DRMOps::PLANE_SET_ROTATION: {
uint32_t rot_bit_mask = va_arg(args, uint32_t);
uint32_t drm_rot_bit_mask = 0;
if (rot_bit_mask & static_cast<uint32_t>(DRMRotation::FLIP_H)) {
drm_rot_bit_mask |= 1 << REFLECT_X;
}
if (rot_bit_mask & static_cast<uint32_t>(DRMRotation::FLIP_V)) {
drm_rot_bit_mask |= 1 << REFLECT_Y;
}
if (rot_bit_mask & static_cast<uint32_t>(DRMRotation::ROT_90)) {
drm_rot_bit_mask |= 1 << ROTATE_90;
} else {
drm_rot_bit_mask |= 1 << ROTATE_0;
}
prop_id = prop_mgr_.GetPropertyId(DRMProperty::ROTATION);
AddProperty(req, obj_id, prop_id, drm_rot_bit_mask, true /* cache */, tmp_prop_val_map_);
DRM_LOGV("Plane %d: Setting rotation mask %x", obj_id, drm_rot_bit_mask);
} break;
case DRMOps::PLANE_SET_ALPHA: {
uint32_t alpha = va_arg(args, uint32_t);
prop_id = prop_mgr_.GetPropertyId(DRMProperty::ALPHA);
AddProperty(req, obj_id, prop_id, alpha, true /* cache */, tmp_prop_val_map_);
DRM_LOGV("Plane %d: Setting alpha %d", obj_id, alpha);
} break;
case DRMOps::PLANE_SET_BLEND_TYPE: {
DRMBlendType blending = va_arg(args, DRMBlendType);
uint32_t blend_type = UNDEFINED;
switch (blending) {
case DRMBlendType::OPAQUE:
blend_type = OPAQUE;
break;
case DRMBlendType::PREMULTIPLIED:
blend_type = PREMULTIPLIED;
break;
case DRMBlendType::COVERAGE:
blend_type = COVERAGE;
break;
case DRMBlendType::SKIP_BLENDING:
blend_type = SKIP_BLENDING;
break;
case DRMBlendType::UNDEFINED:
blend_type = UNDEFINED;
break;
default:
DRM_LOGE("Invalid blend type %d to set on plane %d", blending, obj_id);
break;
}
prop_id = prop_mgr_.GetPropertyId(DRMProperty::BLEND_OP);
AddProperty(req, obj_id, prop_id, blend_type, true /* cache */, tmp_prop_val_map_);
DRM_LOGV("Plane %d: Setting blending %d", obj_id, blend_type);
} break;
case DRMOps::PLANE_SET_H_DECIMATION: {
uint32_t deci = va_arg(args, uint32_t);
prop_id = prop_mgr_.GetPropertyId(DRMProperty::H_DECIMATE);
SetDecimation(req, prop_id, deci);
} break;
case DRMOps::PLANE_SET_V_DECIMATION: {
uint32_t deci = va_arg(args, uint32_t);
prop_id = prop_mgr_.GetPropertyId(DRMProperty::V_DECIMATE);
SetDecimation(req, prop_id, deci);
} break;
case DRMOps::PLANE_SET_SRC_CONFIG: {
bool src_config = va_arg(args, uint32_t);
prop_id = prop_mgr_.GetPropertyId(DRMProperty::SRC_CONFIG);
AddProperty(req, obj_id, prop_id, src_config, true /* cache */, tmp_prop_val_map_);
DRM_LOGV("Plane %d: Setting src_config flags-%x", obj_id, src_config);
} break;
case DRMOps::PLANE_SET_CRTC: {
uint32_t crtc_id = va_arg(args, uint32_t);
prop_id = prop_mgr_.GetPropertyId(DRMProperty::CRTC_ID);
AddProperty(req, obj_id, prop_id, crtc_id, true /* cache */, tmp_prop_val_map_);
SetRequestedCrtc(crtc_id);
DRM_LOGV("Plane %d: Setting crtc %d", obj_id, crtc_id);
} break;
case DRMOps::PLANE_SET_FB_ID: {
uint32_t fb_id = va_arg(args, uint32_t);
prop_id = prop_mgr_.GetPropertyId(DRMProperty::FB_ID);
AddProperty(req, obj_id, prop_id, fb_id, true /* cache */, tmp_prop_val_map_);
DRM_LOGV("Plane %d: Setting fb_id %d", obj_id, fb_id);
} break;
case DRMOps::PLANE_SET_ROT_FB_ID: {
uint32_t fb_id = va_arg(args, uint32_t);
prop_id = prop_mgr_.GetPropertyId(DRMProperty::ROT_FB_ID);
drmModeAtomicAddProperty(req, obj_id, prop_id, fb_id);
DRM_LOGV("Plane %d: Setting rot_fb_id %d", obj_id, fb_id);
} break;
case DRMOps::PLANE_SET_INPUT_FENCE: {
int fence = va_arg(args, int);
prop_id = prop_mgr_.GetPropertyId(DRMProperty::INPUT_FENCE);
AddProperty(req, obj_id, prop_id, fence, false /* cache */, tmp_prop_val_map_);
DRM_LOGV("Plane %d: Setting input fence %d", obj_id, fence);
} break;
case DRMOps::PLANE_SET_SCALER_CONFIG: {
uint64_t handle = va_arg(args, uint64_t);
if (SetScalerConfig(req, handle)) {
DRM_LOGV("Plane %d: Setting scaler config", obj_id);
}
} break;
case DRMOps::PLANE_SET_FB_SECURE_MODE: {
int secure_mode = va_arg(args, int);
uint32_t fb_secure_mode = NON_SECURE;
switch (secure_mode) {
case (int)DRMSecureMode::NON_SECURE:
fb_secure_mode = NON_SECURE;
break;
case (int)DRMSecureMode::SECURE:
fb_secure_mode = SECURE;
break;
case (int)DRMSecureMode::NON_SECURE_DIR_TRANSLATION:
fb_secure_mode = NON_SECURE_DIR_TRANSLATION;
break;
case (int)DRMSecureMode::SECURE_DIR_TRANSLATION:
fb_secure_mode = SECURE_DIR_TRANSLATION;
break;
default:
DRM_LOGE("Invalid secure mode %d to set on plane %d", secure_mode, obj_id);
break;
}
prop_id = prop_mgr_.GetPropertyId(DRMProperty::FB_TRANSLATION_MODE);
AddProperty(req, obj_id, prop_id, fb_secure_mode, true /* cache */, tmp_prop_val_map_);
DRM_LOGD("Plane %d: Setting FB secure mode %d", obj_id, fb_secure_mode);
} break;
case DRMOps::PLANE_SET_CSC_CONFIG: {
uint32_t* csc_type = va_arg(args, uint32_t*);
if (csc_type) {
SetCscConfig(req, (DRMCscType)*csc_type);
}
} break;
case DRMOps::PLANE_SET_MULTIRECT_MODE: {
DRMMultiRectMode drm_multirect_mode = (DRMMultiRectMode)va_arg(args, uint32_t);
SetMultiRectMode(req, drm_multirect_mode);
} break;
case DRMOps::PLANE_SET_INVERSE_PMA: {
uint32_t pma = va_arg(args, uint32_t);
prop_id = prop_mgr_.GetPropertyId(DRMProperty::INVERSE_PMA);
AddProperty(req, obj_id, prop_id, pma, true /* cache */, tmp_prop_val_map_);
DRM_LOGD("Plane %d: %s inverse pma", obj_id, pma ? "Setting" : "Resetting");
} break;
case DRMOps::PLANE_SET_DGM_CSC_CONFIG: {
uint64_t handle = va_arg(args, uint64_t);
if (SetDgmCscConfig(req, handle)) {
DRM_LOGD("Plane %d: Setting Csc Lut config", obj_id);
}
} break;
case DRMOps::PLANE_SET_POST_PROC: {
DRMPPFeatureInfo *data = va_arg(args, DRMPPFeatureInfo*);
if (data) {
DRM_LOGD("Plane %d: Set post proc feature id - %d", obj_id, data->id);
pp_mgr_->SetPPFeature(req, obj_id, *data);
UpdatePPLutFeatureInuse(data);
}
} break;
case DRMOps::PLANE_SET_FP16_CSC_CONFIG: {
uint32_t config = va_arg(args, uint32_t);
SetFp16CscConfig(req, (DRMFp16CscType)config);
} break;
case DRMOps::PLANE_SET_FP16_GC_CONFIG: {
drm_msm_fp16_gc *config = va_arg(args, drm_msm_fp16_gc *);
if (config) {
SetFp16GcConfig(req, config);
}
} break;
case DRMOps::PLANE_SET_FP16_IGC_CONFIG: {
uint32_t config = va_arg(args, uint32_t);
SetFp16IgcConfig(req, config);
} break;
case DRMOps::PLANE_SET_FP16_UNMULT_CONFIG: {
uint32_t config = va_arg(args, uint32_t);
SetFp16UnmultConfig(req, config);
} break;
default:
DRM_LOGE("Invalid opcode %d for DRM Plane %d", code, obj_id);
}
}
void DRMPlane::UpdatePPLutFeatureInuse(DRMPPFeatureInfo *data) {
DRMTonemapLutType lut_type = {};
bool ret = GetDRMonemapLutTypeFromPPFeatureID(data->id, &lut_type);
if (ret == false) {
DRM_LOGE("Failed to get the lut type from PPFeatureID = %d", data->id);
return;
}
const auto state = data->payload ? kActive : kInactive;
switch (lut_type) {
case DRMTonemapLutType::DMA_1D_GC:
dgm_1d_lut_gc_state_ = state;
break;
case DRMTonemapLutType::DMA_1D_IGC:
dgm_1d_lut_igc_state_ = state;
break;
case DRMTonemapLutType::VIG_1D_IGC:
vig_1d_lut_igc_state_ = state;
break;
case DRMTonemapLutType::VIG_3D_GAMUT:
vig_3d_lut_gamut_state_ = state;
break;
default:
DRM_LOGE("Invalid lut_type = %d state = %d", lut_type, state);
}
return;
}
void DRMPlane::PerformWrapper(DRMOps code, drmModeAtomicReq *req, ...) {
va_list args;
va_start(args, req);
Perform(code, req, args);
va_end(args);
}
void DRMPlane::Dump() {
DRM_LOGE(
"id: %d\tcrtc id: %d\tfb id: %d\tCRTC_xy: %dx%d\txy: %dx%d\tgamma "
"size: %d\tpossible crtc: 0x%x\n",
drm_plane_->plane_id, drm_plane_->crtc_id, drm_plane_->fb_id, drm_plane_->crtc_x,
drm_plane_->crtc_y, drm_plane_->x, drm_plane_->y, drm_plane_->gamma_size,
drm_plane_->possible_crtcs);
DRM_LOGE("Format Suported: \n");
for (uint32_t i = 0; i < (uint32_t)drm_plane_->count_formats; i++)
DRM_LOGE(" %4.4s", (char *)&drm_plane_->formats[i]);
}
void DRMPlane::SetMultiRectMode(drmModeAtomicReq *req, DRMMultiRectMode drm_multirect_mode) {
if (!plane_type_info_.multirect_prop_present) {
return;
}
uint32_t obj_id = drm_plane_->plane_id;
uint32_t multirect_mode = MULTIRECT_NONE;
switch (drm_multirect_mode) {
case DRMMultiRectMode::NONE:
multirect_mode = MULTIRECT_NONE;
break;
case DRMMultiRectMode::PARALLEL:
multirect_mode = MULTIRECT_PARALLEL;
break;
case DRMMultiRectMode::SERIAL:
multirect_mode = MULTIRECT_SERIAL;
break;
default:
DRM_LOGE("Invalid multirect mode %d to set on plane %d", drm_multirect_mode, obj_id);
break;
}
auto prop_id = prop_mgr_.GetPropertyId(DRMProperty::MULTIRECT_MODE);
AddProperty(req, obj_id, prop_id, multirect_mode, true /* cache */, tmp_prop_val_map_);
DRM_LOGD("Plane %d: Setting multirect_mode %d", obj_id, multirect_mode);
}
void DRMPlane::Unset(bool is_commit, drmModeAtomicReq *req) {
DRM_LOGD("Plane %d: Unsetting from crtc %d", drm_plane_->plane_id, assigned_crtc_id_);
PerformWrapper(DRMOps::PLANE_SET_FB_ID, req, 0);
PerformWrapper(DRMOps::PLANE_SET_CRTC, req, 0);
DRMRect rect = {0, 0, 0, 0};
PerformWrapper(DRMOps::PLANE_SET_SRC_RECT, req, rect);
PerformWrapper(DRMOps::PLANE_SET_DST_RECT, req, rect);
PerformWrapper(DRMOps::PLANE_SET_EXCL_RECT, req, rect);
if (plane_type_info_.inverse_pma) {
PerformWrapper(DRMOps::PLANE_SET_INVERSE_PMA, req, 0);
}
// Reset the sspp tonemap properties if they were set and update the in-use only if
// its a Commit as Unset is called in Validate as well.
if (dgm_csc_in_use_) {
auto prop_id = prop_mgr_.GetPropertyId(DRMProperty::CSC_DMA_V1);
uint64_t csc_v1 = 0;
AddProperty(req, drm_plane_->plane_id, prop_id, csc_v1, false /* cache */, tmp_prop_val_map_);
DRM_LOGV("Plane %d Clearing DGM CSC", drm_plane_->plane_id);
dgm_csc_in_use_ = !is_commit;
}
ResetColorLUTs(is_commit, req);
// Reset FP16 properties
PerformWrapper(DRMOps::PLANE_SET_FP16_CSC_CONFIG, req, kFP16CscTypeMax);
PerformWrapper(DRMOps::PLANE_SET_FP16_IGC_CONFIG, req, 0);
PerformWrapper(DRMOps::PLANE_SET_FP16_UNMULT_CONFIG, req, 0);
drm_msm_fp16_gc fp16_gc_config = {.flags = 0, .mode = FP16_GC_MODE_INVALID};
PerformWrapper(DRMOps::PLANE_SET_FP16_GC_CONFIG, req, &fp16_gc_config);
tmp_prop_val_map_.clear();
committed_prop_val_map_.clear();
}
bool DRMPlane::SetDgmCscConfig(drmModeAtomicReq *req, uint64_t handle) {
if (plane_type_info_.type == DRMPlaneType::DMA &&
prop_mgr_.IsPropertyAvailable(DRMProperty::CSC_DMA_V1)) {
auto prop_id = prop_mgr_.GetPropertyId(DRMProperty::CSC_DMA_V1);
sde_drm_csc_v1 *csc_v1 = reinterpret_cast<sde_drm_csc_v1 *>(handle);
uint64_t csc_v1_data = 0;
sde_drm_csc_v1 csc_v1_tmp = {};
csc_config_copy_ = *csc_v1;
if (std::memcmp(&csc_config_copy_, &csc_v1_tmp, sizeof(sde_drm_csc_v1)) != 0) {
csc_v1_data = reinterpret_cast<uint64_t>(&csc_config_copy_);
}
AddProperty(req, drm_plane_->plane_id, prop_id,
reinterpret_cast<uint64_t>(csc_v1_data), false /* cache */,
tmp_prop_val_map_);
dgm_csc_in_use_ = (csc_v1_data != 0);
DRM_LOGV("Plane %d in_use = %d", drm_plane_->plane_id, dgm_csc_in_use_);
return true;
}
return false;
}
void DRMPlane::ResetColorLUTs(bool update_state, drmModeAtomicReq *req) {
// Reset the color luts if they were set and update the state only if its a Commit as Unset
// is called in Validate as well.
for (int i = 0; i <= (int32_t)(DRMTonemapLutType::VIG_3D_GAMUT); i++) {
auto itr = plane_type_info_.tonemap_lut_version_map.find(static_cast<DRMTonemapLutType>(i));
if (itr != plane_type_info_.tonemap_lut_version_map.end()) {
ResetColorLUTState(static_cast<DRMTonemapLutType>(i), update_state, req);
}
}
}
void DRMPlane::ResetColorLUTState(DRMTonemapLutType lut_type, bool update_state,
drmModeAtomicReq *req) {
DRMPlaneLutState *lut_state = nullptr;
DRMPPFeatureID feature_id = {};
switch (lut_type) {
case DRMTonemapLutType::DMA_1D_GC:
lut_state = &dgm_1d_lut_gc_state_;
feature_id = kFeatureDgmGc;
break;
case DRMTonemapLutType::DMA_1D_IGC:
lut_state = &dgm_1d_lut_igc_state_;
feature_id = kFeatureDgmIgc;
break;
case DRMTonemapLutType::VIG_1D_IGC:
lut_state = &vig_1d_lut_igc_state_;
feature_id = kFeatureVigIgc;
break;
case DRMTonemapLutType::VIG_3D_GAMUT:
lut_state = &vig_3d_lut_gamut_state_;
feature_id = kFeatureVigGamut;
break;
default:
DLOGE("Invalid lut type = %d", lut_type);
return;
}
if (*lut_state == kInactive) {
DRM_LOGV("Plane %d %s Lut not used", drm_plane_->plane_id, GetColorLutString(lut_type));
return;
}
DRMPlaneLutState target_state;
// If plane is getting unset, clearing of LUT will not be applied in hw.
// In that case, mark LUT as dirty and make sure that these are cleared the
// next time the plane gets used
if (*lut_state == kActive && requested_crtc_id_ == 0) {
target_state = kDirty;
} else if (*lut_state == kDirty && requested_crtc_id_ != 0) {
// If plane is getting activated while LUT is in dirty state, the new state
// should be inactive but still need to clear exiting LUT config in hw
target_state = kInactive;
} else {
return;
}
if (update_state) {
DRM_LOGD("Plane %d Clearing %s Lut, moving from (%d) -> (%d)", drm_plane_->plane_id,
GetColorLutString(lut_type), *lut_state, target_state);
*lut_state = target_state;
}
if (req) {
ResetColorLUT(feature_id, req);
}
}
void DRMPlane::ResetColorLUT(DRMPPFeatureID id, drmModeAtomicReq *req) {
DRMPPFeatureInfo pp_feature_info = {};
pp_feature_info.type = kPropBlob;
pp_feature_info.payload = nullptr;
pp_feature_info.id = id;
pp_mgr_->SetPPFeature(req, drm_plane_->plane_id, pp_feature_info);
}
void DRMPlane::ResetCache(drmModeAtomicReq *req) {
tmp_prop_val_map_.clear();
committed_prop_val_map_.clear();
}
void DRMPlane::ResetPlanesLUT(drmModeAtomicReq *req) {
ResetCache(req);
for (int i = 0; i <= (int32_t)(DRMTonemapLutType::VIG_3D_GAMUT); i++) {
auto itr = plane_type_info_.tonemap_lut_version_map.find(static_cast<DRMTonemapLutType>(i));
if (itr != plane_type_info_.tonemap_lut_version_map.end()) {
DRMPlaneLutState *lut_state = nullptr;
DRMPPFeatureID feature_id = {};
switch (static_cast<DRMTonemapLutType>(i)) {
case DRMTonemapLutType::DMA_1D_GC:
lut_state = &dgm_1d_lut_gc_state_;
feature_id = kFeatureDgmGc;
break;
case DRMTonemapLutType::DMA_1D_IGC:
lut_state = &dgm_1d_lut_igc_state_;
feature_id = kFeatureDgmIgc;
break;
case DRMTonemapLutType::VIG_1D_IGC:
lut_state = &vig_1d_lut_igc_state_;
feature_id = kFeatureVigIgc;
break;
case DRMTonemapLutType::VIG_3D_GAMUT:
lut_state = &vig_3d_lut_gamut_state_;
feature_id = kFeatureVigGamut;
break;
default:
DLOGE("Invalid lut type = %d", i);
return;
}
*lut_state = kDirty;
ResetColorLUT(feature_id, req);
}
}
}
} // namespace sde_drm