LookingGlass/host/Service.cpp
Geoffrey McRae 758b7af754 [host] use a local copy of the header and then update it all in one go
Writing to shared memory is much faster then reading as the shared
memory is not cached, this change ensures we are using a local copy
of the header performing the final update all in one go.
2017-12-16 10:06:55 +11:00

359 lines
9.3 KiB
C++

/*
Looking Glass - KVM FrameRelay (KVMFR) Client
Copyright (C) 2017 Geoffrey McRae <geoff@hostfission.com>
https://looking-glass.hostfission.com
This program is free software; you can redistribute it and/or modify it under
the terms of the GNU General Public License as published by the Free Software
Foundation; either version 2 of the License, or (at your option) any later
version.
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.
You should have received a copy of the GNU General Public License along with
this program; if not, write to the Free Software Foundation, Inc., 59 Temple
Place, Suite 330, Boston, MA 02111-1307 USA
*/
#include "Service.h"
#include "IVSHMEM.h"
#include "common/debug.h"
#include "common/KVMFR.h"
#include "CaptureFactory.h"
#if __MINGW32__
#define INTERLOCKED_AND8 __sync_and_and_fetch
#define INTERLOCKED_OR8 __sync_or_and_fetch
#else
#define INTERLOCKED_OR8 InterlockedOr8
#define INTERLOCKED_AND8 InterlockedAnd8
#endif
Service * Service::m_instance = NULL;
Service::Service() :
m_initialized(false),
m_memory(NULL),
m_timer(NULL),
m_capture(NULL),
m_shmHeader(NULL),
m_frameIndex(0),
m_cursorDataSize(0),
m_cursorData(NULL),
m_shapePending(false)
{
m_ivshmem = IVSHMEM::Get();
}
Service::~Service()
{
}
bool Service::Initialize(ICapture * captureDevice)
{
if (m_initialized)
DeInitialize();
m_capture = captureDevice;
if (!m_ivshmem->Initialize())
{
DEBUG_ERROR("IVSHMEM failed to initalize");
DeInitialize();
return false;
}
if (m_ivshmem->GetSize() < sizeof(KVMFRHeader))
{
DEBUG_ERROR("Shared memory is not large enough for the KVMFRHeader");
DeInitialize();
return false;
}
m_memory = static_cast<uint8_t*>(m_ivshmem->GetMemory());
if (!m_memory)
{
DEBUG_ERROR("Failed to get IVSHMEM memory");
DeInitialize();
return false;
}
if (!InitPointers())
return false;
m_timer = CreateWaitableTimer(NULL, TRUE, NULL);
if (!m_timer)
{
DEBUG_ERROR("Failed to create waitable timer");
return false;
}
// update everything except for the hostID
memcpy(m_shmHeader->magic, KVMFR_HEADER_MAGIC, sizeof(KVMFR_HEADER_MAGIC));
m_shmHeader->version = KVMFR_HEADER_VERSION;
m_shmHeader->guestID = m_ivshmem->GetPeerID();
m_shmHeader->updateCount = 0;
// clear but retain the restart flag if it was set by the client
INTERLOCKED_AND8((char *)&m_shmHeader->flags, KVMFR_HEADER_FLAG_RESTART);
ZeroMemory(&m_shmHeader->frame , sizeof(KVMFRFrame ));
ZeroMemory(&m_shmHeader->cursor, sizeof(KVMFRCursor));
m_initialized = true;
return true;
}
bool Service::InitPointers()
{
m_shmHeader = reinterpret_cast<KVMFRHeader *>(m_memory);
m_frame[0] = (uint8_t *)(((uintptr_t)m_memory + sizeof(KVMFRHeader *) + 0x7F) & ~0x7F);
m_frameSize = ((m_ivshmem->GetSize() - (m_frame[0] - m_memory)) & ~0x7F) >> 1;
m_frame[1] = m_frame[0] + m_frameSize;
m_dataOffset[0] = m_frame[0] - m_memory;
m_dataOffset[1] = m_frame[1] - m_memory;
if (m_capture->GetMaxFrameSize() > m_frameSize)
{
DEBUG_ERROR("Frame can exceed buffer size!");
DeInitialize();
return false;
}
return true;
}
void Service::DeInitialize()
{
if (m_timer)
{
CloseHandle(m_timer);
m_timer = NULL;
}
m_shapePending = false;
if (m_cursorData)
{
delete[] m_cursorData;
m_cursorDataSize = 0;
m_cursorData = NULL;
}
m_shmHeader = NULL;
m_frame[0] = NULL;
m_frame[1] = NULL;
m_dataOffset[0] = 0;
m_dataOffset[1] = 0;
m_ivshmem->DeInitialize();
if (m_capture)
{
m_capture->DeInitialize();
m_capture = NULL;
}
m_memory = NULL;
m_initialized = false;
}
bool Service::Process()
{
if (!m_initialized)
return false;
bool restart = false;
struct FrameInfo frame;
ZeroMemory(&frame, sizeof(FrameInfo));
frame.buffer = m_frame[m_frameIndex];
frame.bufferSize = m_frameSize;
volatile uint8_t *flags = &m_shmHeader->flags;
// wait for the host to notify that is it is ready to proceed
while (true)
{
const uint8_t f = *flags;
// check if the client has flagged a restart
if (f & KVMFR_HEADER_FLAG_RESTART)
{
m_shmHeader->updateCount = 0;
INTERLOCKED_AND8((volatile char *)flags, ~(KVMFR_HEADER_FLAG_RESTART));
restart = true;
break;
}
// check if the client has flagged it's ready
if (f & KVMFR_HEADER_FLAG_READY)
{
INTERLOCKED_AND8((volatile char *)flags, ~(KVMFR_HEADER_FLAG_READY));
break;
}
// wait for 100ns before polling again
LARGE_INTEGER timeout;
timeout.QuadPart = -100;
if (!SetWaitableTimer(m_timer, &timeout, 0, NULL, NULL, FALSE))
{
DEBUG_ERROR("Failed to set waitable timer");
return false;
}
WaitForSingleObject(m_timer, INFINITE);
}
bool ok = false;
bool cursorOnly = false;
if (m_shapePending)
{
ok = true;
cursorOnly = true;
}
else
for(int i = 0; i < 2; ++i)
{
// capture a frame of data
switch (m_capture->GrabFrame(frame))
{
case GRAB_STATUS_OK:
ok = true;
break;
case GRAB_STATUS_CURSOR:
ok = true;
cursorOnly = true;
break;
case GRAB_STATUS_ERROR:
DEBUG_ERROR("Capture failed");
return false;
case GRAB_STATUS_REINIT:
DEBUG_INFO("ReInitialize Requested");
if (!m_capture->ReInitialize() || !InitPointers())
{
DEBUG_ERROR("ReInitialize Failed");
return false;
}
continue;
}
if (ok)
break;
}
if (!ok)
{
DEBUG_ERROR("Capture retry count exceeded");
return false;
}
uint8_t updateFlags = 0;
m_header.cursor.flags = 0;
if (!cursorOnly)
{
// signal a frame update
updateFlags |= KVMFR_HEADER_FLAG_FRAME;
m_header.frame.type = m_capture->GetFrameType();
m_header.frame.width = frame.width;
m_header.frame.height = frame.height;
m_header.frame.stride = frame.stride;
m_header.frame.dataPos = m_dataOffset[m_frameIndex];
if (++m_frameIndex == 2)
m_frameIndex = 0;
}
if (frame.cursor.hasPos || (m_cursor.hasPos && restart))
{
// remember the last state for client restart
if (frame.cursor.hasPos)
{
m_cursor.hasPos = true;
m_cursor.visible = frame.cursor.visible;
m_cursor.x = frame.cursor.x;
m_cursor.y = frame.cursor.y;
}
// tell the host where the cursor is
updateFlags |= KVMFR_HEADER_FLAG_CURSOR;
m_header.cursor.flags |= KVMFR_CURSOR_FLAG_POS;
if (m_cursor.visible)
m_header.cursor.flags |= KVMFR_CURSOR_FLAG_VISIBLE;
m_header.cursor.x = m_cursor.x;
m_header.cursor.y = m_cursor.y;
}
if (frame.cursor.hasShape || m_shapePending || (m_cursor.hasShape && restart))
{
if (!m_shapePending && !restart)
{
if (frame.cursor.dataSize > m_frameSize)
{
DEBUG_ERROR("Cursor size exceeds frame size! This should never happen unless your shared memory is WAY too small");
return false;
}
// take a copy of the shape information for client restarts or pending shape changes
m_cursor.hasShape = frame.cursor.hasShape;
m_cursor.type = frame.cursor.type;
m_cursor.w = frame.cursor.w;
m_cursor.h = frame.cursor.h;
m_cursor.pitch = frame.cursor.pitch;
m_cursor.dataSize = frame.cursor.dataSize;
memcpy(&m_cursor, &frame.cursor, sizeof(CursorInfo));
if (m_cursorDataSize < frame.cursor.dataSize)
{
delete[] m_cursorData;
m_cursorData = new uint8_t[frame.cursor.dataSize];
m_cursorDataSize = frame.cursor.dataSize;
}
memcpy(m_cursorData, frame.cursor.shape, frame.cursor.dataSize);
}
// we can't send a frame with the cursor shape as we need the buffer location
// flag it to send on the next packet
if (updateFlags & KVMFR_HEADER_FLAG_FRAME)
m_shapePending = true;
else
{
// give the host the new cursor shape
updateFlags |= KVMFR_HEADER_FLAG_CURSOR;
m_header.cursor.flags |= KVMFR_CURSOR_FLAG_SHAPE;
if (m_cursor.visible)
m_header.cursor.flags |= KVMFR_CURSOR_FLAG_VISIBLE;
m_header.cursor.type = m_cursor.type;
m_header.cursor.w = m_cursor.w;
m_header.cursor.h = m_cursor.h;
m_header.cursor.pitch = m_cursor.pitch;
m_header.cursor.dataPos = m_dataOffset[m_frameIndex];
memcpy(m_frame[m_frameIndex], m_cursorData, m_cursor.dataSize);
m_shapePending = false;
if (++m_frameIndex == 2)
m_frameIndex = 0;
}
}
// update the flags
INTERLOCKED_AND8((volatile char *)flags, KVMFR_HEADER_FLAG_RESTART);
INTERLOCKED_OR8 ((volatile char *)flags, updateFlags);
// update the shared header but don't touch the setup fields
const size_t offset = (uintptr_t)&m_header.frame - (uintptr_t)&m_header;
memcpy(
(uint8_t *)m_shmHeader + offset,
(uint8_t *)&m_header + offset,
sizeof(KVMFRHeader) - offset
);
// increment the update count so the guest stops waiting
++m_shmHeader->updateCount;
return true;
}