/************************************************************************************ PublicHeader: OVR.h Filename : OVR_DeviceMessages.h Content : Definition of messages generated by devices Created : February 5, 2013 Authors : Lee Cooper Copyright : Copyright 2014 Oculus VR, Inc. All Rights reserved. Licensed under the Oculus VR Rift SDK License Version 3.1 (the "License"); you may not use the Oculus VR Rift SDK except in compliance with the License, which is provided at the time of installation or download, or which otherwise accompanies this software in either electronic or hard copy form. You may obtain a copy of the License at http://www.oculusvr.com/licenses/LICENSE-3.1 Unless required by applicable law or agreed to in writing, the Oculus VR SDK distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. *************************************************************************************/ #ifndef OVR_DeviceMessages_h #define OVR_DeviceMessages_h #include "OVR_DeviceConstants.h" #include "OVR_DeviceHandle.h" #include "Kernel/OVR_Math.h" #include "Kernel/OVR_Array.h" #include "Kernel/OVR_Color.h" #include "Kernel/OVR_String.h" namespace OVR { class DeviceBase; class DeviceHandle; class String; #define OVR_MESSAGETYPE(devName, msgIndex) ((Device_##devName << 8) | msgIndex) // MessageType identifies the structure of the Message class; based on the message, // casting can be used to obtain the exact value. enum MessageType { // Used for unassigned message types. Message_None = 0, // Device Manager Messages Message_DeviceAdded = OVR_MESSAGETYPE(Manager, 0), // A new device is detected by manager. Message_DeviceRemoved = OVR_MESSAGETYPE(Manager, 1), // Existing device has been plugged/unplugged. // Sensor Messages Message_BodyFrame = OVR_MESSAGETYPE(Sensor, 0), // Emitted by sensor at regular intervals. Message_ExposureFrame = OVR_MESSAGETYPE(Sensor, 1), Message_PixelRead = OVR_MESSAGETYPE(Sensor, 2), // Latency Tester Messages Message_LatencyTestSamples = OVR_MESSAGETYPE(LatencyTester, 0), Message_LatencyTestColorDetected = OVR_MESSAGETYPE(LatencyTester, 1), Message_LatencyTestStarted = OVR_MESSAGETYPE(LatencyTester, 2), Message_LatencyTestButton = OVR_MESSAGETYPE(LatencyTester, 3), Message_CameraFrame = OVR_MESSAGETYPE(Camera, 0), Message_CameraAdded = OVR_MESSAGETYPE(Camera, 1), }; //------------------------------------------------------------------------------------- // Base class for all messages. class Message { public: Message(MessageType type = Message_None, DeviceBase* pdev = 0) : Type(type), pDevice(pdev) { } MessageType Type; // What kind of message this is. DeviceBase* pDevice; // Device that emitted the message. }; // Sensor BodyFrame notification. // Sensor uses Right-Handed coordinate system to return results, with the following // axis definitions: // - Y Up positive // - X Right Positive // - Z Back Positive // Rotations a counter-clockwise (CCW) while looking in the negative direction // of the axis. This means they are interpreted as follows: // - Roll is rotation around Z, counter-clockwise (tilting left) in XY plane. // - Yaw is rotation around Y, positive for turning left. // - Pitch is rotation around X, positive for pitching up. //------------------------------------------------------------------------------------- // ***** Sensor class MessageBodyFrame : public Message { public: MessageBodyFrame(DeviceBase* dev) : Message(Message_BodyFrame, dev), Temperature(0.0f), TimeDelta(0.0f) { } Vector3f Acceleration; // Acceleration in m/s^2. Vector3f RotationRate; // Angular velocity in rad/s. Vector3f MagneticField; // Magnetic field strength in Gauss. float Temperature; // Temperature reading on sensor surface, in degrees Celsius. float TimeDelta; // Time passed since last Body Frame, in seconds. // The absolute time from the host computers perspective that the message should be // interpreted as. This is based on incoming timestamp and processed by a filter // that syncs the clocks while attempting to keep the distance between messages // device clock matching. // // Integration should use TimeDelta, but prediction into the future should derive // the delta time from PredictToSeconds - AbsoluteTimeSeconds. // // This value will generally be <= the return from a call to ovr_GetTimeInSeconds(), // but could be greater by under 1 ms due to system time update interrupt delays. // double AbsoluteTimeSeconds; }; // Sent when we receive a device status changes (e.g.: // Message_DeviceAdded, Message_DeviceRemoved). class MessageDeviceStatus : public Message { public: MessageDeviceStatus(MessageType type, DeviceBase* dev, const DeviceHandle &hdev) : Message(type, dev), Handle(hdev) { } DeviceHandle Handle; }; class MessageExposureFrame : public Message { public: MessageExposureFrame(DeviceBase* dev) : Message(Message_ExposureFrame, dev), CameraPattern(0), CameraFrameCount(0), CameraTimeSeconds(0) { } UByte CameraPattern; UInt32 CameraFrameCount; double CameraTimeSeconds; }; class MessagePixelRead : public Message { public: MessagePixelRead(DeviceBase* dev) : Message(Message_PixelRead, dev), PixelReadValue(0), SensorTimeSeconds(0), FrameTimeSeconds(0) { } UByte PixelReadValue; UInt32 RawSensorTime; UInt32 RawFrameTime; double SensorTimeSeconds; double FrameTimeSeconds; }; //------------------------------------------------------------------------------------- // ***** Latency Tester // Sent when we receive Latency Tester samples. class MessageLatencyTestSamples : public Message { public: MessageLatencyTestSamples(DeviceBase* dev) : Message(Message_LatencyTestSamples, dev) { } Array Samples; }; // Sent when a Latency Tester 'color detected' event occurs. class MessageLatencyTestColorDetected : public Message { public: MessageLatencyTestColorDetected(DeviceBase* dev) : Message(Message_LatencyTestColorDetected, dev) { } UInt16 Elapsed; Color DetectedValue; Color TargetValue; }; // Sent when a Latency Tester 'change color' event occurs. class MessageLatencyTestStarted : public Message { public: MessageLatencyTestStarted(DeviceBase* dev) : Message(Message_LatencyTestStarted, dev) { } Color TargetValue; }; // Sent when a Latency Tester 'button' event occurs. class MessageLatencyTestButton : public Message { public: MessageLatencyTestButton(DeviceBase* dev) : Message(Message_LatencyTestButton, dev) { } }; //------------------------------------------------------------------------------------- // ***** Camera // Sent by camera, frame. class MessageCameraFrame : public Message { public: MessageCameraFrame(DeviceBase* dev) : Message(Message_CameraFrame, dev), CameraHandle(NULL), pFrameData(NULL) { LostFrames = 0; } void SetInfo(UInt32 frameNumber, double timeSeconds, UInt32 width, UInt32 height, UInt32 format) { FrameNumber = frameNumber; ArrivalTimeSeconds = timeSeconds; Width = width; Height = height; Format = format; } void SetData(const UByte* pdata, UInt32 sizeInBytes) { pFrameData = pdata; FrameSizeInBytes = sizeInBytes; } UInt32 FrameNumber; // an index of the frame double ArrivalTimeSeconds; // frame time in seconds, as recorded by the host computer const UByte* pFrameData; // a ptr to frame data. UInt32 FrameSizeInBytes; // size of the data in the pFrameData. UInt32 Width, Height; // width & height in pixels. UInt32 Format; // format of pixel, see CameraDevice::PixelFormat enum UInt32 LostFrames; // number of lost frames before this frame String DeviceIdentifier; // identifies the device sensing the message UInt32* CameraHandle; // Identifies the camera object associated with this frame }; // Sent when a new camera is connected class MessageCameraAdded : public Message { public: MessageCameraAdded(DeviceBase* dev) : Message(Message_CameraAdded, dev) { } MessageCameraAdded(UInt32* cam) : Message(Message_CameraAdded, NULL), CameraHandle(cam) { } UInt32* CameraHandle; // Identifies the camera object associated with this frame }; } // namespace OVR #endif