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Merge pull request #5201 from ameerj/bufferq-refactor

vi/buffer_queue: Buffer queue management refactor
This commit is contained in:
bunnei 2020-12-20 15:48:39 -08:00 committed by GitHub
commit c3e201a829
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3 changed files with 65 additions and 72 deletions

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@ -22,10 +22,11 @@ BufferQueue::BufferQueue(Kernel::KernelCore& kernel, u32 id, u64 layer_id)
BufferQueue::~BufferQueue() = default; BufferQueue::~BufferQueue() = default;
void BufferQueue::SetPreallocatedBuffer(u32 slot, const IGBPBuffer& igbp_buffer) { void BufferQueue::SetPreallocatedBuffer(u32 slot, const IGBPBuffer& igbp_buffer) {
ASSERT(slot < buffer_slots);
LOG_WARNING(Service, "Adding graphics buffer {}", slot); LOG_WARNING(Service, "Adding graphics buffer {}", slot);
free_buffers.push_back(slot); free_buffers.push_back(slot);
queue.push_back({ buffers[slot] = {
.slot = slot, .slot = slot,
.status = Buffer::Status::Free, .status = Buffer::Status::Free,
.igbp_buffer = igbp_buffer, .igbp_buffer = igbp_buffer,
@ -33,7 +34,7 @@ void BufferQueue::SetPreallocatedBuffer(u32 slot, const IGBPBuffer& igbp_buffer)
.crop_rect = {}, .crop_rect = {},
.swap_interval = 0, .swap_interval = 0,
.multi_fence = {}, .multi_fence = {},
}); };
buffer_wait_event.writable->Signal(); buffer_wait_event.writable->Signal();
} }
@ -44,73 +45,57 @@ std::optional<std::pair<u32, Service::Nvidia::MultiFence*>> BufferQueue::Dequeue
if (free_buffers.empty()) { if (free_buffers.empty()) {
return std::nullopt; return std::nullopt;
} }
auto f_itr = free_buffers.begin(); auto f_itr = free_buffers.begin();
auto itr = queue.end(); auto slot = buffers.size();
while (f_itr != free_buffers.end()) { while (f_itr != free_buffers.end()) {
auto slot = *f_itr; const Buffer& buffer = buffers[*f_itr];
itr = std::find_if(queue.begin(), queue.end(), [&](const Buffer& buffer) { if (buffer.status == Buffer::Status::Free && buffer.igbp_buffer.width == width &&
// Only consider free buffers. Buffers become free once again after they've been buffer.igbp_buffer.height == height) {
// Acquired and Released by the compositor, see the NVFlinger::Compose method. slot = *f_itr;
if (buffer.status != Buffer::Status::Free) {
return false;
}
if (buffer.slot != slot) {
return false;
}
// Make sure that the parameters match.
return buffer.igbp_buffer.width == width && buffer.igbp_buffer.height == height;
});
if (itr != queue.end()) {
free_buffers.erase(f_itr); free_buffers.erase(f_itr);
break; break;
} }
++f_itr; ++f_itr;
} }
if (slot == buffers.size()) {
if (itr == queue.end()) {
return std::nullopt; return std::nullopt;
} }
buffers[slot].status = Buffer::Status::Dequeued;
itr->status = Buffer::Status::Dequeued; return {{buffers[slot].slot, &buffers[slot].multi_fence}};
return {{itr->slot, &itr->multi_fence}};
} }
const IGBPBuffer& BufferQueue::RequestBuffer(u32 slot) const { const IGBPBuffer& BufferQueue::RequestBuffer(u32 slot) const {
auto itr = std::find_if(queue.begin(), queue.end(), ASSERT(slot < buffers.size());
[&](const Buffer& buffer) { return buffer.slot == slot; }); ASSERT(buffers[slot].status == Buffer::Status::Dequeued);
ASSERT(itr != queue.end()); ASSERT(buffers[slot].slot == slot);
ASSERT(itr->status == Buffer::Status::Dequeued);
return itr->igbp_buffer; return buffers[slot].igbp_buffer;
} }
void BufferQueue::QueueBuffer(u32 slot, BufferTransformFlags transform, void BufferQueue::QueueBuffer(u32 slot, BufferTransformFlags transform,
const Common::Rectangle<int>& crop_rect, u32 swap_interval, const Common::Rectangle<int>& crop_rect, u32 swap_interval,
Service::Nvidia::MultiFence& multi_fence) { Service::Nvidia::MultiFence& multi_fence) {
auto itr = std::find_if(queue.begin(), queue.end(), ASSERT(slot < buffers.size());
[&](const Buffer& buffer) { return buffer.slot == slot; }); ASSERT(buffers[slot].status == Buffer::Status::Dequeued);
ASSERT(itr != queue.end()); ASSERT(buffers[slot].slot == slot);
ASSERT(itr->status == Buffer::Status::Dequeued);
itr->status = Buffer::Status::Queued; buffers[slot].status = Buffer::Status::Queued;
itr->transform = transform; buffers[slot].transform = transform;
itr->crop_rect = crop_rect; buffers[slot].crop_rect = crop_rect;
itr->swap_interval = swap_interval; buffers[slot].swap_interval = swap_interval;
itr->multi_fence = multi_fence; buffers[slot].multi_fence = multi_fence;
queue_sequence.push_back(slot); queue_sequence.push_back(slot);
} }
void BufferQueue::CancelBuffer(u32 slot, const Service::Nvidia::MultiFence& multi_fence) { void BufferQueue::CancelBuffer(u32 slot, const Service::Nvidia::MultiFence& multi_fence) {
const auto itr = std::find_if(queue.begin(), queue.end(), ASSERT(slot < buffers.size());
[slot](const Buffer& buffer) { return buffer.slot == slot; }); ASSERT(buffers[slot].status != Buffer::Status::Free);
ASSERT(itr != queue.end()); ASSERT(buffers[slot].slot == slot);
ASSERT(itr->status != Buffer::Status::Free);
itr->status = Buffer::Status::Free; buffers[slot].status = Buffer::Status::Free;
itr->multi_fence = multi_fence; buffers[slot].multi_fence = multi_fence;
itr->swap_interval = 0; buffers[slot].swap_interval = 0;
free_buffers.push_back(slot); free_buffers.push_back(slot);
@ -118,38 +103,39 @@ void BufferQueue::CancelBuffer(u32 slot, const Service::Nvidia::MultiFence& mult
} }
std::optional<std::reference_wrapper<const BufferQueue::Buffer>> BufferQueue::AcquireBuffer() { std::optional<std::reference_wrapper<const BufferQueue::Buffer>> BufferQueue::AcquireBuffer() {
auto itr = queue.end(); std::size_t buffer_slot = buffers.size();
// Iterate to find a queued buffer matching the requested slot. // Iterate to find a queued buffer matching the requested slot.
while (itr == queue.end() && !queue_sequence.empty()) { while (buffer_slot == buffers.size() && !queue_sequence.empty()) {
const u32 slot = queue_sequence.front(); const auto slot = static_cast<std::size_t>(queue_sequence.front());
itr = std::find_if(queue.begin(), queue.end(), [&slot](const Buffer& buffer) { ASSERT(slot < buffers.size());
return buffer.status == Buffer::Status::Queued && buffer.slot == slot; if (buffers[slot].status == Buffer::Status::Queued) {
}); ASSERT(buffers[slot].slot == slot);
buffer_slot = slot;
}
queue_sequence.pop_front(); queue_sequence.pop_front();
} }
if (itr == queue.end()) { if (buffer_slot == buffers.size()) {
return std::nullopt; return std::nullopt;
} }
itr->status = Buffer::Status::Acquired; buffers[buffer_slot].status = Buffer::Status::Acquired;
return *itr; return {{buffers[buffer_slot]}};
} }
void BufferQueue::ReleaseBuffer(u32 slot) { void BufferQueue::ReleaseBuffer(u32 slot) {
auto itr = std::find_if(queue.begin(), queue.end(), ASSERT(slot < buffers.size());
[&](const Buffer& buffer) { return buffer.slot == slot; }); ASSERT(buffers[slot].status == Buffer::Status::Acquired);
ASSERT(itr != queue.end()); ASSERT(buffers[slot].slot == slot);
ASSERT(itr->status == Buffer::Status::Acquired);
itr->status = Buffer::Status::Free; buffers[slot].status = Buffer::Status::Free;
free_buffers.push_back(slot); free_buffers.push_back(slot);
buffer_wait_event.writable->Signal(); buffer_wait_event.writable->Signal();
} }
void BufferQueue::Disconnect() { void BufferQueue::Disconnect() {
queue.clear(); buffers.fill({});
queue_sequence.clear(); queue_sequence.clear();
id = 1; buffer_wait_event.writable->Signal();
layer_id = 1;
} }
u32 BufferQueue::Query(QueryType type) { u32 BufferQueue::Query(QueryType type) {

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@ -21,6 +21,7 @@ class KernelCore;
namespace Service::NVFlinger { namespace Service::NVFlinger {
constexpr u32 buffer_slots = 0x40;
struct IGBPBuffer { struct IGBPBuffer {
u32_le magic; u32_le magic;
u32_le width; u32_le width;
@ -114,7 +115,7 @@ private:
u64 layer_id; u64 layer_id;
std::list<u32> free_buffers; std::list<u32> free_buffers;
std::vector<Buffer> queue; std::array<Buffer, buffer_slots> buffers;
std::list<u32> queue_sequence; std::list<u32> queue_sequence;
Kernel::EventPair buffer_wait_event; Kernel::EventPair buffer_wait_event;
}; };

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@ -282,18 +282,24 @@ public:
void DeserializeData() override { void DeserializeData() override {
[[maybe_unused]] const std::u16string token = ReadInterfaceToken(); [[maybe_unused]] const std::u16string token = ReadInterfaceToken();
data = Read<Data>(); data = Read<Data>();
buffer = Read<NVFlinger::IGBPBuffer>(); if (data.contains_object != 0) {
buffer_container = Read<BufferContainer>();
}
} }
struct Data { struct Data {
u32_le slot; u32_le slot;
INSERT_PADDING_WORDS(1); u32_le contains_object;
u32_le graphic_buffer_length;
INSERT_PADDING_WORDS(1);
}; };
Data data; struct BufferContainer {
NVFlinger::IGBPBuffer buffer; u32_le graphic_buffer_length;
INSERT_PADDING_WORDS(1);
NVFlinger::IGBPBuffer buffer{};
};
Data data{};
BufferContainer buffer_container{};
}; };
class IGBPSetPreallocatedBufferResponseParcel : public Parcel { class IGBPSetPreallocatedBufferResponseParcel : public Parcel {
@ -547,7 +553,7 @@ private:
case TransactionId::SetPreallocatedBuffer: { case TransactionId::SetPreallocatedBuffer: {
IGBPSetPreallocatedBufferRequestParcel request{ctx.ReadBuffer()}; IGBPSetPreallocatedBufferRequestParcel request{ctx.ReadBuffer()};
buffer_queue.SetPreallocatedBuffer(request.data.slot, request.buffer); buffer_queue.SetPreallocatedBuffer(request.data.slot, request.buffer_container.buffer);
IGBPSetPreallocatedBufferResponseParcel response{}; IGBPSetPreallocatedBufferResponseParcel response{};
ctx.WriteBuffer(response.Serialize()); ctx.WriteBuffer(response.Serialize());