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android / platform / hardware / qcom / display / 8fe8dcb0747934df7e87504bc5e6c916b3ec9678 / . / msm8998 / sdm / libs / core / resource_default.cpp
blob: 31d8704e5b16ad2f3fd7505bc05a955a95fb3e00 [file] [log] [blame]
/*
* Copyright (c) 2014 - 2016, 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.
*/
#include <math.h>
#include <utils/constants.h>
#include <utils/debug.h>
#include <utils/rect.h>
#include <utils/formats.h>
#include <utils/sys.h>
#include <dlfcn.h>
#include <algorithm>
#include "resource_default.h"
#define __CLASS__ "ResourceDefault"
namespace sdm {
DisplayError ResourceDefault::CreateResourceDefault(const HWResourceInfo &hw_resource_info,
ResourceInterface **resource_intf) {
DisplayError error = kErrorNone;
ResourceDefault *resource_default = new ResourceDefault(hw_resource_info);
if (!resource_default) {
return kErrorNone;
}
error = resource_default->Init();
if (error != kErrorNone) {
delete resource_default;
}
*resource_intf = resource_default;
return kErrorNone;
}
DisplayError ResourceDefault::DestroyResourceDefault(ResourceInterface *resource_intf) {
ResourceDefault *resource_default = static_cast<ResourceDefault *>(resource_intf);
resource_default->Deinit();
delete resource_default;
return kErrorNone;
}
ResourceDefault::ResourceDefault(const HWResourceInfo &hw_res_info)
: hw_res_info_(hw_res_info) {
}
DisplayError ResourceDefault::Init() {
DisplayError error = kErrorNone;
num_pipe_ = hw_res_info_.num_vig_pipe + hw_res_info_.num_rgb_pipe + hw_res_info_.num_dma_pipe;
if (!num_pipe_) {
DLOGE("Number of H/W pipes is Zero!");
return kErrorParameters;
}
src_pipes_.resize(num_pipe_);
// Priority order of pipes: VIG, RGB, DMA
uint32_t vig_index = 0;
uint32_t rgb_index = hw_res_info_.num_vig_pipe;
uint32_t dma_index = rgb_index + hw_res_info_.num_rgb_pipe;
for (uint32_t i = 0; i < num_pipe_; i++) {
const HWPipeCaps &pipe_caps = hw_res_info_.hw_pipes.at(i);
if (pipe_caps.type == kPipeTypeVIG) {
src_pipes_[vig_index].type = kPipeTypeVIG;
src_pipes_[vig_index].index = i;
src_pipes_[vig_index].mdss_pipe_id = pipe_caps.id;
vig_index++;
} else if (pipe_caps.type == kPipeTypeRGB) {
src_pipes_[rgb_index].type = kPipeTypeRGB;
src_pipes_[rgb_index].index = i;
src_pipes_[rgb_index].mdss_pipe_id = pipe_caps.id;
rgb_index++;
} else if (pipe_caps.type == kPipeTypeDMA) {
src_pipes_[dma_index].type = kPipeTypeDMA;
src_pipes_[dma_index].index = i;
src_pipes_[dma_index].mdss_pipe_id = pipe_caps.id;
dma_index++;
}
}
for (uint32_t i = 0; i < num_pipe_; i++) {
src_pipes_[i].priority = INT(i);
}
DLOGI("hw_rev=%x, DMA=%d RGB=%d VIG=%d", hw_res_info_.hw_revision, hw_res_info_.num_dma_pipe,
hw_res_info_.num_rgb_pipe, hw_res_info_.num_vig_pipe);
if (hw_res_info_.max_scale_down < 1 || hw_res_info_.max_scale_up < 1) {
DLOGE("Max scaling setting is invalid! max_scale_down = %d, max_scale_up = %d",
hw_res_info_.max_scale_down, hw_res_info_.max_scale_up);
hw_res_info_.max_scale_down = 1;
hw_res_info_.max_scale_up = 1;
}
// TODO(user): clean it up, query from driver for initial pipe status.
#ifndef SDM_VIRTUAL_DRIVER
rgb_index = hw_res_info_.num_vig_pipe;
src_pipes_[rgb_index].owner = kPipeOwnerKernelMode;
src_pipes_[rgb_index + 1].owner = kPipeOwnerKernelMode;
#endif
return error;
}
DisplayError ResourceDefault::Deinit() {
return kErrorNone;
}
DisplayError ResourceDefault::RegisterDisplay(DisplayType type,
const HWDisplayAttributes &display_attributes,
const HWPanelInfo &hw_panel_info,
const HWMixerAttributes &mixer_attributes,
Handle *display_ctx) {
DisplayError error = kErrorNone;
HWBlockType hw_block_id = kHWBlockMax;
switch (type) {
case kPrimary:
if (!hw_block_ctx_[kHWPrimary].is_in_use) {
hw_block_id = kHWPrimary;
}
break;
case kHDMI:
if (!hw_block_ctx_[kHWHDMI].is_in_use) {
hw_block_id = kHWHDMI;
}
break;
default:
DLOGW("RegisterDisplay, invalid type %d", type);
return kErrorParameters;
}
if (hw_block_id == kHWBlockMax) {
return kErrorResources;
}
DisplayResourceContext *display_resource_ctx = new DisplayResourceContext();
if (!display_resource_ctx) {
return kErrorMemory;
}
hw_block_ctx_[hw_block_id].is_in_use = true;
display_resource_ctx->display_attributes = display_attributes;
display_resource_ctx->hw_block_id = hw_block_id;
display_resource_ctx->mixer_attributes = mixer_attributes;
*display_ctx = display_resource_ctx;
return error;
}
DisplayError ResourceDefault::UnregisterDisplay(Handle display_ctx) {
DisplayResourceContext *display_resource_ctx =
reinterpret_cast<DisplayResourceContext *>(display_ctx);
Purge(display_ctx);
hw_block_ctx_[display_resource_ctx->hw_block_id].is_in_use = false;
delete display_resource_ctx;
return kErrorNone;
}
DisplayError ResourceDefault::ReconfigureDisplay(Handle display_ctx,
const HWDisplayAttributes &display_attributes,
const HWPanelInfo &hw_panel_info,
const HWMixerAttributes &mixer_attributes) {
SCOPE_LOCK(locker_);
DisplayResourceContext *display_resource_ctx =
reinterpret_cast<DisplayResourceContext *>(display_ctx);
display_resource_ctx->display_attributes = display_attributes;
display_resource_ctx->mixer_attributes = mixer_attributes;
return kErrorNone;
}
DisplayError ResourceDefault::Start(Handle display_ctx) {
locker_.Lock();
return kErrorNone;
}
DisplayError ResourceDefault::Stop(Handle display_ctx) {
locker_.Unlock();
return kErrorNone;
}
DisplayError ResourceDefault::Prepare(Handle display_ctx, HWLayers *hw_layers) {
DisplayResourceContext *display_resource_ctx =
reinterpret_cast<DisplayResourceContext *>(display_ctx);
DisplayError error = kErrorNone;
const struct HWLayersInfo &layer_info = hw_layers->info;
HWBlockType hw_block_id = display_resource_ctx->hw_block_id;
DLOGV_IF(kTagResources, "==== Resource reserving start: hw_block = %d ====", hw_block_id);
if (layer_info.hw_layers.size() > 1) {
DLOGV_IF(kTagResources, "More than one FB layers");
return kErrorResources;
}
const Layer &layer = layer_info.hw_layers.at(0);
if (layer.composition != kCompositionGPUTarget) {
DLOGV_IF(kTagResources, "Not an FB layer");
return kErrorParameters;
}
error = Config(display_resource_ctx, hw_layers);
if (error != kErrorNone) {
DLOGV_IF(kTagResources, "Resource config failed");
return error;
}
for (uint32_t i = 0; i < num_pipe_; i++) {
if (src_pipes_[i].hw_block_id == hw_block_id && src_pipes_[i].owner == kPipeOwnerUserMode) {
src_pipes_[i].ResetState();
}
}
uint32_t left_index = num_pipe_;
uint32_t right_index = num_pipe_;
bool need_scale = false;
struct HWLayerConfig &layer_config = hw_layers->config[0];
HWPipeInfo *left_pipe = &layer_config.left_pipe;
HWPipeInfo *right_pipe = &layer_config.right_pipe;
// left pipe is needed
if (left_pipe->valid) {
need_scale = IsScalingNeeded(left_pipe);
left_index = GetPipe(hw_block_id, need_scale);
if (left_index >= num_pipe_) {
DLOGV_IF(kTagResources, "Get left pipe failed: hw_block_id = %d, need_scale = %d",
hw_block_id, need_scale);
ResourceStateLog();
goto CleanupOnError;
}
}
error = SetDecimationFactor(left_pipe);
if (error != kErrorNone) {
goto CleanupOnError;
}
if (!right_pipe->valid) {
// assign single pipe
if (left_index < num_pipe_) {
left_pipe->pipe_id = src_pipes_[left_index].mdss_pipe_id;
}
DLOGV_IF(kTagResources, "1 pipe acquired for FB layer, left_pipe = %x", left_pipe->pipe_id);
return kErrorNone;
}
need_scale = IsScalingNeeded(right_pipe);
right_index = GetPipe(hw_block_id, need_scale);
if (right_index >= num_pipe_) {
DLOGV_IF(kTagResources, "Get right pipe failed: hw_block_id = %d, need_scale = %d", hw_block_id,
need_scale);
ResourceStateLog();
goto CleanupOnError;
}
if (src_pipes_[right_index].priority < src_pipes_[left_index].priority) {
// Swap pipe based on priority
std::swap(left_index, right_index);
}
// assign dual pipes
left_pipe->pipe_id = src_pipes_[left_index].mdss_pipe_id;
right_pipe->pipe_id = src_pipes_[right_index].mdss_pipe_id;
error = SetDecimationFactor(right_pipe);
if (error != kErrorNone) {
goto CleanupOnError;
}
DLOGV_IF(kTagResources, "2 pipes acquired for FB layer, left_pipe = %x, right_pipe = %x",
left_pipe->pipe_id, right_pipe->pipe_id);
return kErrorNone;
CleanupOnError:
DLOGV_IF(kTagResources, "Resource reserving failed! hw_block = %d", hw_block_id);
return kErrorResources;
}
DisplayError ResourceDefault::PostPrepare(Handle display_ctx, HWLayers *hw_layers) {
SCOPE_LOCK(locker_);
return kErrorNone;
}
DisplayError ResourceDefault::Commit(Handle display_ctx, HWLayers *hw_layers) {
SCOPE_LOCK(locker_);
return kErrorNone;
}
DisplayError ResourceDefault::PostCommit(Handle display_ctx, HWLayers *hw_layers) {
SCOPE_LOCK(locker_);
DisplayResourceContext *display_resource_ctx =
reinterpret_cast<DisplayResourceContext *>(display_ctx);
HWBlockType hw_block_id = display_resource_ctx->hw_block_id;
uint64_t frame_count = display_resource_ctx->frame_count;
DLOGV_IF(kTagResources, "Resource for hw_block = %d, frame_count = %d", hw_block_id, frame_count);
// handoff pipes which are used by splash screen
if ((frame_count == 0) && (hw_block_id == kHWPrimary)) {
for (uint32_t i = 0; i < num_pipe_; i++) {
if (src_pipes_[i].hw_block_id == hw_block_id && src_pipes_[i].owner == kPipeOwnerKernelMode) {
src_pipes_[i].owner = kPipeOwnerUserMode;
}
}
}
if (hw_layers->info.sync_handle >= 0)
Sys::close_(hw_layers->info.sync_handle);
display_resource_ctx->frame_count++;
return kErrorNone;
}
void ResourceDefault::Purge(Handle display_ctx) {
SCOPE_LOCK(locker_);
DisplayResourceContext *display_resource_ctx =
reinterpret_cast<DisplayResourceContext *>(display_ctx);
HWBlockType hw_block_id = display_resource_ctx->hw_block_id;
for (uint32_t i = 0; i < num_pipe_; i++) {
if (src_pipes_[i].hw_block_id == hw_block_id && src_pipes_[i].owner == kPipeOwnerUserMode) {
src_pipes_[i].ResetState();
}
}
DLOGV_IF(kTagResources, "display id = %d", display_resource_ctx->hw_block_id);
}
DisplayError ResourceDefault::SetMaxMixerStages(Handle display_ctx, uint32_t max_mixer_stages) {
SCOPE_LOCK(locker_);
return kErrorNone;
}
uint32_t ResourceDefault::SearchPipe(HWBlockType hw_block_id, SourcePipe *src_pipes,
uint32_t num_pipe) {
uint32_t index = num_pipe_;
SourcePipe *src_pipe;
// search the pipe being used
for (uint32_t i = 0; i < num_pipe; i++) {
src_pipe = &src_pipes[i];
if (src_pipe->owner == kPipeOwnerUserMode && src_pipe->hw_block_id == kHWBlockMax) {
index = src_pipe->index;
src_pipe->hw_block_id = hw_block_id;
break;
}
}
return index;
}
uint32_t ResourceDefault::NextPipe(PipeType type, HWBlockType hw_block_id) {
uint32_t num_pipe = 0;
SourcePipe *src_pipes = NULL;
switch (type) {
case kPipeTypeVIG:
src_pipes = &src_pipes_[0];
num_pipe = hw_res_info_.num_vig_pipe;
break;
case kPipeTypeRGB:
src_pipes = &src_pipes_[hw_res_info_.num_vig_pipe];
num_pipe = hw_res_info_.num_rgb_pipe;
break;
case kPipeTypeDMA:
default:
src_pipes = &src_pipes_[hw_res_info_.num_vig_pipe + hw_res_info_.num_rgb_pipe];
num_pipe = hw_res_info_.num_dma_pipe;
break;
}
return SearchPipe(hw_block_id, src_pipes, num_pipe);
}
uint32_t ResourceDefault::GetPipe(HWBlockType hw_block_id, bool need_scale) {
uint32_t index = num_pipe_;
// The default behavior is to assume RGB and VG pipes have scalars
if (!need_scale) {
index = NextPipe(kPipeTypeDMA, hw_block_id);
}
if ((index >= num_pipe_) && (!need_scale || !hw_res_info_.has_non_scalar_rgb)) {
index = NextPipe(kPipeTypeRGB, hw_block_id);
}
if (index >= num_pipe_) {
index = NextPipe(kPipeTypeVIG, hw_block_id);
}
return index;
}
bool ResourceDefault::IsScalingNeeded(const HWPipeInfo *pipe_info) {
const LayerRect &src_roi = pipe_info->src_roi;
const LayerRect &dst_roi = pipe_info->dst_roi;
return ((dst_roi.right - dst_roi.left) != (src_roi.right - src_roi.left)) ||
((dst_roi.bottom - dst_roi.top) != (src_roi.bottom - src_roi.top));
}
void ResourceDefault::ResourceStateLog() {
DLOGV_IF(kTagResources, "==== resource manager pipe state ====");
uint32_t i;
for (i = 0; i < num_pipe_; i++) {
SourcePipe *src_pipe = &src_pipes_[i];
DLOGV_IF(kTagResources, "index = %d, id = %x, hw_block = %d, owner = %s",
src_pipe->index, src_pipe->mdss_pipe_id, src_pipe->hw_block_id,
(src_pipe->owner == kPipeOwnerUserMode) ? "user mode" : "kernel mode");
}
}
DisplayError ResourceDefault::SrcSplitConfig(DisplayResourceContext *display_resource_ctx,
const LayerRect &src_rect, const LayerRect &dst_rect,
HWLayerConfig *layer_config) {
HWPipeInfo *left_pipe = &layer_config->left_pipe;
HWPipeInfo *right_pipe = &layer_config->right_pipe;
float src_width = src_rect.right - src_rect.left;
float dst_width = dst_rect.right - dst_rect.left;
// Layer cannot qualify for SrcSplit if source or destination width exceeds max pipe width.
if ((src_width > hw_res_info_.max_pipe_width) || (dst_width > hw_res_info_.max_pipe_width)) {
SplitRect(src_rect, dst_rect, &left_pipe->src_roi, &left_pipe->dst_roi, &right_pipe->src_roi,
&right_pipe->dst_roi);
left_pipe->valid = true;
right_pipe->valid = true;
} else {
left_pipe->src_roi = src_rect;
left_pipe->dst_roi = dst_rect;
left_pipe->valid = true;
right_pipe->Reset();
}
return kErrorNone;
}
DisplayError ResourceDefault::DisplaySplitConfig(DisplayResourceContext *display_resource_ctx,
const LayerRect &src_rect, const LayerRect &dst_rect,
HWLayerConfig *layer_config) {
HWMixerAttributes &mixer_attributes = display_resource_ctx->mixer_attributes;
// for display split case
HWPipeInfo *left_pipe = &layer_config->left_pipe;
HWPipeInfo *right_pipe = &layer_config->right_pipe;
LayerRect scissor_left, scissor_right, dst_left, crop_left, crop_right, dst_right;
scissor_left.right = FLOAT(mixer_attributes.split_left);
scissor_left.bottom = FLOAT(mixer_attributes.height);
scissor_right.left = FLOAT(mixer_attributes.split_left);
scissor_right.top = 0.0f;
scissor_right.right = FLOAT(mixer_attributes.width);
scissor_right.bottom = FLOAT(mixer_attributes.height);
crop_left = src_rect;
dst_left = dst_rect;
crop_right = crop_left;
dst_right = dst_left;
bool crop_left_valid = CalculateCropRects(scissor_left, &crop_left, &dst_left);
bool crop_right_valid = false;
if (IsValid(scissor_right)) {
crop_right_valid = CalculateCropRects(scissor_right, &crop_right, &dst_right);
}
// Reset left_pipe and right_pipe to invalid by default
left_pipe->Reset();
right_pipe->Reset();
if (crop_left_valid) {
// assign left pipe
left_pipe->src_roi = crop_left;
left_pipe->dst_roi = dst_left;
left_pipe->valid = true;
}
// assign right pipe if needed
if (crop_right_valid) {
right_pipe->src_roi = crop_right;
right_pipe->dst_roi = dst_right;
right_pipe->valid = true;
}
return kErrorNone;
}
DisplayError ResourceDefault::Config(DisplayResourceContext *display_resource_ctx,
HWLayers *hw_layers) {
HWLayersInfo &layer_info = hw_layers->info;
DisplayError error = kErrorNone;
const Layer &layer = layer_info.hw_layers.at(0);
error = ValidateLayerParams(&layer);
if (error != kErrorNone) {
return error;
}
struct HWLayerConfig *layer_config = &hw_layers->config[0];
HWPipeInfo &left_pipe = layer_config->left_pipe;
HWPipeInfo &right_pipe = layer_config->right_pipe;
LayerRect src_rect = layer.src_rect;
LayerRect dst_rect = layer.dst_rect;
error = ValidateDimensions(src_rect, dst_rect);
if (error != kErrorNone) {
return error;
}
BufferLayout layout = GetBufferLayout(layer.input_buffer.format);
error = ValidateScaling(src_rect, dst_rect, false /*rotated90 */, layout,
false /* use_rotator_downscale */);
if (error != kErrorNone) {
return error;
}
if (hw_res_info_.is_src_split) {
error = SrcSplitConfig(display_resource_ctx, src_rect, dst_rect, layer_config);
} else {
error = DisplaySplitConfig(display_resource_ctx, src_rect, dst_rect, layer_config);
}
if (error != kErrorNone) {
return error;
}
error = AlignPipeConfig(&layer, &left_pipe, &right_pipe);
if (error != kErrorNone) {
return error;
}
// set z_order, left_pipe should always be valid
left_pipe.z_order = 0;
DLOGV_IF(kTagResources, "==== FB layer Config ====");
Log(kTagResources, "input layer src_rect", layer.src_rect);
Log(kTagResources, "input layer dst_rect", layer.dst_rect);
Log(kTagResources, "cropped src_rect", src_rect);
Log(kTagResources, "cropped dst_rect", dst_rect);
Log(kTagResources, "left pipe src", layer_config->left_pipe.src_roi);
Log(kTagResources, "left pipe dst", layer_config->left_pipe.dst_roi);
if (right_pipe.valid) {
right_pipe.z_order = 0;
Log(kTagResources, "right pipe src", layer_config->right_pipe.src_roi);
Log(kTagResources, "right pipe dst", layer_config->right_pipe.dst_roi);
}
return error;
}
bool ResourceDefault::CalculateCropRects(const LayerRect &scissor, LayerRect *crop,
LayerRect *dst) {
float &crop_left = crop->left;
float &crop_top = crop->top;
float &crop_right = crop->right;
float &crop_bottom = crop->bottom;
float crop_width = crop->right - crop->left;
float crop_height = crop->bottom - crop->top;
float &dst_left = dst->left;
float &dst_top = dst->top;
float &dst_right = dst->right;
float &dst_bottom = dst->bottom;
float dst_width = dst->right - dst->left;
float dst_height = dst->bottom - dst->top;
const float &sci_left = scissor.left;
const float &sci_top = scissor.top;
const float &sci_right = scissor.right;
const float &sci_bottom = scissor.bottom;
float left_cut_ratio = 0.0, right_cut_ratio = 0.0, top_cut_ratio = 0.0, bottom_cut_ratio = 0.0;
bool need_cut = false;
if (dst_left < sci_left) {
left_cut_ratio = (sci_left - dst_left) / dst_width;
dst_left = sci_left;
need_cut = true;
}
if (dst_right > sci_right) {
right_cut_ratio = (dst_right - sci_right) / dst_width;
dst_right = sci_right;
need_cut = true;
}
if (dst_top < sci_top) {
top_cut_ratio = (sci_top - dst_top) / (dst_height);
dst_top = sci_top;
need_cut = true;
}
if (dst_bottom > sci_bottom) {
bottom_cut_ratio = (dst_bottom - sci_bottom) / (dst_height);
dst_bottom = sci_bottom;
need_cut = true;
}
if (!need_cut)
return true;
crop_left += crop_width * left_cut_ratio;
crop_top += crop_height * top_cut_ratio;
crop_right -= crop_width * right_cut_ratio;
crop_bottom -= crop_height * bottom_cut_ratio;
Normalize(1, 1, crop);
Normalize(1, 1, dst);
if (IsValid(*crop) && IsValid(*dst))
return true;
else
return false;
}
DisplayError ResourceDefault::ValidateLayerParams(const Layer *layer) {
const LayerRect &src = layer->src_rect;
const LayerRect &dst = layer->dst_rect;
const LayerBuffer &input_buffer = layer->input_buffer;
if (input_buffer.format == kFormatInvalid) {
DLOGV_IF(kTagResources, "Invalid input buffer format %d", input_buffer.format);
return kErrorNotSupported;
}
if (!IsValid(src) || !IsValid(dst)) {
Log(kTagResources, "input layer src_rect", src);
Log(kTagResources, "input layer dst_rect", dst);
return kErrorNotSupported;
}
// Make sure source in integral only if it is a non secure layer.
if (!input_buffer.flags.secure &&
((src.left - roundf(src.left) != 0.0f) ||
(src.top - roundf(src.top) != 0.0f) ||
(src.right - roundf(src.right) != 0.0f) ||
(src.bottom - roundf(src.bottom) != 0.0f))) {
DLOGV_IF(kTagResources, "Input ROI is not integral");
return kErrorNotSupported;
}
return kErrorNone;
}
DisplayError ResourceDefault::ValidateDimensions(const LayerRect &crop, const LayerRect &dst) {
if (!IsValid(crop)) {
Log(kTagResources, "Invalid crop rect", crop);
return kErrorNotSupported;
}
if (!IsValid(dst)) {
Log(kTagResources, "Invalid dst rect", dst);
return kErrorNotSupported;
}
float crop_width = crop.right - crop.left;
float crop_height = crop.bottom - crop.top;
float dst_width = dst.right - dst.left;
float dst_height = dst.bottom - dst.top;
if ((UINT32(crop_width - dst_width) == 1) || (UINT32(crop_height - dst_height) == 1)) {
DLOGV_IF(kTagResources, "One pixel downscaling detected crop_w = %.0f, dst_w = %.0f, " \
"crop_h = %.0f, dst_h = %.0f", crop_width, dst_width, crop_height, dst_height);
return kErrorNotSupported;
}
return kErrorNone;
}
DisplayError ResourceDefault::ValidatePipeParams(HWPipeInfo *pipe_info, LayerBufferFormat format) {
DisplayError error = kErrorNone;
const LayerRect &src_rect = pipe_info->src_roi;
const LayerRect &dst_rect = pipe_info->dst_roi;
error = ValidateDimensions(src_rect, dst_rect);
if (error != kErrorNone) {
return error;
}
BufferLayout layout = GetBufferLayout(format);
error = ValidateScaling(src_rect, dst_rect, false /* rotated90 */, layout,
false /* use_rotator_downscale */);
if (error != kErrorNone) {
return error;
}
return kErrorNone;
}
DisplayError ResourceDefault::ValidateScaling(const LayerRect &crop, const LayerRect &dst,
bool rotate90, BufferLayout layout,
bool use_rotator_downscale) {
DisplayError error = kErrorNone;
float scale_x = 1.0f;
float scale_y = 1.0f;
error = GetScaleFactor(crop, dst, &scale_x, &scale_y);
if (error != kErrorNone) {
return error;
}
error = ValidateDownScaling(scale_x, scale_y, (layout != kLinear));
if (error != kErrorNone) {
return error;
}
error = ValidateUpScaling(scale_x, scale_y);
if (error != kErrorNone) {
return error;
}
return kErrorNone;
}
DisplayError ResourceDefault::ValidateDownScaling(float scale_x, float scale_y, bool ubwc_tiled) {
if ((UINT32(scale_x) > 1) || (UINT32(scale_y) > 1)) {
float max_scale_down = FLOAT(hw_res_info_.max_scale_down);
// MDP H/W cannot apply decimation on UBWC tiled framebuffer
if (!ubwc_tiled && hw_res_info_.has_decimation) {
max_scale_down *= FLOAT(kMaxDecimationDownScaleRatio);
}
if (scale_x > max_scale_down || scale_y > max_scale_down) {
DLOGV_IF(kTagResources,
"Scaling down is over the limit: scale_x = %.0f, scale_y = %.0f, " \
"has_deci = %d", scale_x, scale_y, hw_res_info_.has_decimation);
return kErrorNotSupported;
}
}
DLOGV_IF(kTagResources, "scale_x = %.4f, scale_y = %.4f", scale_x, scale_y);
return kErrorNone;
}
DisplayError ResourceDefault::ValidateUpScaling(float scale_x, float scale_y) {
float max_scale_up = FLOAT(hw_res_info_.max_scale_up);
if (UINT32(scale_x) < 1 && scale_x > 0.0f) {
if ((1.0f / scale_x) > max_scale_up) {
DLOGV_IF(kTagResources, "Scaling up is over limit scale_x = %f", 1.0f / scale_x);
return kErrorNotSupported;
}
}
if (UINT32(scale_y) < 1 && scale_y > 0.0f) {
if ((1.0f / scale_y) > max_scale_up) {
DLOGV_IF(kTagResources, "Scaling up is over limit scale_y = %f", 1.0f / scale_y);
return kErrorNotSupported;
}
}
DLOGV_IF(kTagResources, "scale_x = %.4f, scale_y = %.4f", scale_x, scale_y);
return kErrorNone;
}
DisplayError ResourceDefault::GetScaleFactor(const LayerRect &crop, const LayerRect &dst,
float *scale_x, float *scale_y) {
float crop_width = crop.right - crop.left;
float crop_height = crop.bottom - crop.top;
float dst_width = dst.right - dst.left;
float dst_height = dst.bottom - dst.top;
*scale_x = crop_width / dst_width;
*scale_y = crop_height / dst_height;
return kErrorNone;
}
DisplayError ResourceDefault::SetDecimationFactor(HWPipeInfo *pipe) {
float src_h = pipe->src_roi.bottom - pipe->src_roi.top;
float dst_h = pipe->dst_roi.bottom - pipe->dst_roi.top;
float down_scale_h = src_h / dst_h;
float src_w = pipe->src_roi.right - pipe->src_roi.left;
float dst_w = pipe->dst_roi.right - pipe->dst_roi.left;
float down_scale_w = src_w / dst_w;
pipe->horizontal_decimation = 0;
pipe->vertical_decimation = 0;
if (CalculateDecimation(down_scale_w, &pipe->horizontal_decimation) != kErrorNone) {
return kErrorNotSupported;
}
if (CalculateDecimation(down_scale_h, &pipe->vertical_decimation) != kErrorNone) {
return kErrorNotSupported;
}
DLOGI_IF(kTagResources, "horizontal_decimation %d, vertical_decimation %d",
pipe->horizontal_decimation, pipe->vertical_decimation);
return kErrorNone;
}
void ResourceDefault::SplitRect(const LayerRect &src_rect, const LayerRect &dst_rect,
LayerRect *src_left, LayerRect *dst_left, LayerRect *src_right,
LayerRect *dst_right) {
// Split rectangle horizontally and evenly into two.
float src_width = src_rect.right - src_rect.left;
float dst_width = dst_rect.right - dst_rect.left;
float src_width_ori = src_width;
src_width = ROUND_UP_ALIGN_DOWN(src_width / 2, 1);
dst_width = ROUND_UP_ALIGN_DOWN(dst_width * src_width / src_width_ori, 1);
src_left->left = src_rect.left;
src_left->right = src_rect.left + src_width;
src_right->left = src_left->right;
src_right->right = src_rect.right;
src_left->top = src_rect.top;
src_left->bottom = src_rect.bottom;
src_right->top = src_rect.top;
src_right->bottom = src_rect.bottom;
dst_left->top = dst_rect.top;
dst_left->bottom = dst_rect.bottom;
dst_right->top = dst_rect.top;
dst_right->bottom = dst_rect.bottom;
dst_left->left = dst_rect.left;
dst_left->right = dst_rect.left + dst_width;
dst_right->left = dst_left->right;
dst_right->right = dst_rect.right;
}
DisplayError ResourceDefault::AlignPipeConfig(const Layer *layer, HWPipeInfo *left_pipe,
HWPipeInfo *right_pipe) {
DisplayError error = kErrorNone;
if (!left_pipe->valid) {
DLOGE_IF(kTagResources, "left_pipe should not be invalid");
return kErrorNotSupported;
}
error = ValidatePipeParams(left_pipe, layer->input_buffer.format);
if (error != kErrorNone) {
goto PipeConfigExit;
}
if (right_pipe->valid) {
// Make sure the left and right ROI are conjunct
right_pipe->src_roi.left = left_pipe->src_roi.right;
right_pipe->dst_roi.left = left_pipe->dst_roi.right;
error = ValidatePipeParams(right_pipe, layer->input_buffer.format);
}
PipeConfigExit:
if (error != kErrorNone) {
DLOGV_IF(kTagResources, "AlignPipeConfig failed");
}
return error;
}
DisplayError ResourceDefault::CalculateDecimation(float downscale, uint8_t *decimation) {
float max_down_scale = FLOAT(hw_res_info_.max_scale_down);
if (downscale <= max_down_scale) {
*decimation = 0;
return kErrorNone;
} else if (!hw_res_info_.has_decimation) {
DLOGE("Downscaling exceeds the maximum MDP downscale limit but decimation not enabled");
return kErrorNotSupported;
}
// Decimation is the remaining downscale factor after doing max SDE downscale.
// In SDE, decimation is supported in powers of 2.
// For ex: If a pipe needs downscale of 8 but max_down_scale is 4
// So decimation = powf(2.0, ceilf(log2f(8 / 4))) = powf(2.0, 1.0) = 2
*decimation = UINT8(ceilf(log2f(downscale / max_down_scale)));
return kErrorNone;
}
DisplayError ResourceDefault::ValidateCursorConfig(Handle display_ctx, const Layer *layer,
bool is_top) {
return kErrorNotSupported;
}
DisplayError ResourceDefault::ValidateCursorPosition(Handle display_ctx, HWLayers *hw_layers,
int x, int y) {
return kErrorNotSupported;
}
DisplayError ResourceDefault::SetMaxBandwidthMode(HWBwModes mode) {
return kErrorNotSupported;
}
DisplayError ResourceDefault::GetScaleLutConfig(HWScaleLutInfo *lut_info) {
return kErrorNone;
}
DisplayError ResourceDefault::SetDetailEnhancerData(Handle display_ctx,
const DisplayDetailEnhancerData &de_data) {
return kErrorNotSupported;
}
} // namespace sdm