public bool ReadAddresses()
{
if (_memory == null)
{
var tempProcess = MemoryHelpers.GetProcessIfRunning(ProcessNames[0]);
if (tempProcess == null)
{
return(false);
}
_memory = new Memory(tempProcess);
}
if (_memory == null)
{
return(false);
}
var boostOffsets = _pointer.GameAddresses.First(ga => ga.Description == "Boost").ToString();
boostAddress = _memory.GetAddress("\"RocketLeague.exe\"" + boostOffsets);
var speedOffsets = _pointer.GameAddresses.First(ga => ga.Description == "Speed").ToString();
speedAddress = _memory.GetAddress("\"RocketLeague.exe\"" + speedOffsets);
return(true);
}
public override float ReadRawValueFrom(IntPtr statePtr)
{
var valuePtr = new IntPtr(statePtr.ToInt64() + (int)m_StateBlock.byteOffset);
var intValue = MemoryHelpers.ReadIntFromMultipleBits(valuePtr, m_StateBlock.bitOffset, m_StateBlock.sizeInBits);
var value = 0.0f;
if (minValue > maxValue)
{
// If no wrapping point is set, default to wrapping around exactly
// at the point of minValue.
if (wrapAtValue == nullValue)
{
wrapAtValue = minValue;
}
if ((intValue >= minValue && intValue <= wrapAtValue) ||
(intValue != nullValue && intValue <= maxValue))
{
value = 1.0f;
}
}
else
{
value = intValue >= minValue && intValue <= maxValue ? 1.0f : 0.0f;
}
return(Preprocess(value));
}
internal unsafe void __MarshalTo(ref __Native @ref)
{
@ref.NumEntries = Elements?.Length ?? 0;
if (@ref.NumEntries > 0)
{
var nativeElements = (StreamOutputElement.__Native *)Interop.Alloc <StreamOutputElement.__Native>(@ref.NumEntries);
for (int i = 0; i < @ref.NumEntries; i++)
{
Elements[i].__MarshalTo(ref nativeElements[i]);
}
@ref.pSODeclaration = nativeElements;
}
@ref.NumStrides = Strides?.Length ?? 0;
if (@ref.NumStrides > 0)
{
var nativeStrides = Interop.Alloc <int>(@ref.NumStrides);
fixed(int *src = &Strides[0])
{
MemoryHelpers.CopyMemory(nativeStrides, (IntPtr)src, @ref.NumStrides * sizeof(int));
}
@ref.pBufferStrides = nativeStrides;
}
@ref.RasterizedStream = RasterizedStream;
}
public float ReadFloat(void *statePtr)
{
Debug.Assert(sizeInBits != 0);
var valuePtr = (byte *)statePtr + (int)byteOffset;
float value;
if (format == kTypeFloat)
{
Debug.Assert(sizeInBits == 32, "FLT state must have sizeInBits=32");
Debug.Assert(bitOffset == 0, "FLT state must be byte-aligned");
value = *(float *)valuePtr;
}
else if (format == kTypeBit)
{
if (sizeInBits != 1)
{
throw new NotImplementedException("Cannot yet convert multi-bit fields to floats");
}
value = MemoryHelpers.ReadSingleBit(valuePtr, bitOffset) ? 1.0f : 0.0f;
}
// If a control with an integer-based representation does not use the full range
// of its integer size (e.g. only goes from [0..128]), processors or the parameters
// above have to be used to re-process the resulting float values.
else if (format == kTypeShort)
{
Debug.Assert(sizeInBits == 16, "SHRT state must have sizeInBits=16");
Debug.Assert(bitOffset == 0, "SHRT state must be byte-aligned");
////REVIEW: What's better here? This code reaches a clean -1 but doesn't reach a clean +1 as the range is [-32768..32767].
//// Should we cut off at -32767? Or just live with the fact that 0.999 is as high as it gets?
value = *(short *)valuePtr / 32768.0f;
}
else if (format == kTypeUShort)
{
Debug.Assert(sizeInBits == 16, "USHT state must have sizeInBits=16");
Debug.Assert(bitOffset == 0, "USHT state must be byte-aligned");
value = *(ushort *)valuePtr / 65535.0f;
}
else if (format == kTypeByte)
{
Debug.Assert(sizeInBits == 8, "BYTE state must have sizeInBits=8");
Debug.Assert(bitOffset == 0, "BYTE state must be byte-aligned");
value = *valuePtr / 255.0f;
}
else if (format == kTypeSByte)
{
Debug.Assert(sizeInBits == 8, "SBYT state must have sizeInBits=8");
Debug.Assert(bitOffset == 0, "SBYT state must be byte-aligned");
////REVIEW: Same problem here as with 'short'
value = *(sbyte *)valuePtr / 128.0f;
}
else
{
throw new Exception(string.Format("State format '{0}' is not supported as floating-point format", format));
}
return(value);
}
public unsafe void WriteFloat(IntPtr statePtr, float value)
{
var valuePtr = new IntPtr(statePtr.ToInt64() + (int)byteOffset);
if (format == kTypeFloat)
{
*(float *)valuePtr = value;
}
else if (format == kTypeBit)
{
if (sizeInBits != 1)
{
throw new NotImplementedException("Cannot yet convert multi-bit fields to floats");
}
MemoryHelpers.WriteSingleBit(valuePtr, bitOffset, value >= 0.5f);
}
else if (format == kTypeShort)
{
*(short *)valuePtr = (short)(value * 65535.0f);
}
else if (format == kTypeByte)
{
*(byte *)valuePtr = (byte)(value * 255.0f);
}
else
{
throw new Exception(string.Format("State format '{0}' is not supported as floating-point format", format));
}
}
public override void Update()
{
if (_memory == null)
{
var tempProcess = MemoryHelpers.GetProcessIfRunning(ProcessNames[0]);
if (tempProcess == null)
{
return;
}
_memory = new Memory(tempProcess);
}
if (ProfileModel == null || DataModel == null || _memory == null)
{
return;
}
var offsets = _pointer.GameAddresses.First(ga => ga.Description == "Boost").ToString();
var boostAddress = _memory.GetAddress("\"RocketLeague.exe\"" + offsets);
var boostInt = (int)(_memory.ReadFloat(boostAddress) * 100);
if (boostInt > 100)
{
boostInt = 100;
}
if (boostInt < 0)
{
boostInt = 0;
}
((RocketLeagueDataModel)DataModel).Boost = boostInt;
}
public override unsafe float ReadUnprocessedValueFromState(void *statePtr)
{
var valuePtr = (byte *)statePtr + (int)m_StateBlock.byteOffset;
// Note that all signed data in state buffers is in excess-K format.
var intValue = MemoryHelpers.ReadTwosComplementMultipleBitsAsInt(valuePtr, m_StateBlock.bitOffset, m_StateBlock.sizeInBits);
var value = 0.0f;
if (minValue > maxValue)
{
// If no wrapping point is set, default to wrapping around exactly
// at the point of minValue.
if (wrapAtValue == nullValue)
{
wrapAtValue = minValue;
}
if ((intValue >= minValue && intValue <= wrapAtValue) ||
(intValue != nullValue && intValue <= maxValue))
{
value = 1.0f;
}
}
else
{
value = intValue >= minValue && intValue <= maxValue ? 1.0f : 0.0f;
}
return(Preprocess(value));
}
public unsafe void Utilities_CanCompareMemoryBitRegions()
{
using (var array1 = new NativeArray <byte>(6, Allocator.Temp))
using (var array2 = new NativeArray <byte>(6, Allocator.Temp))
{
var array1Ptr = (byte *)array1.GetUnsafePtr();
var array2Ptr = (byte *)array2.GetUnsafePtr();
MemoryHelpers.SetBitsInBuffer(array1Ptr, 0, 2, 1, true);
Assert.That(MemoryHelpers.MemCmpBitRegion(array1Ptr, array2Ptr, 2, 1), Is.False);
MemoryHelpers.SetBitsInBuffer(array2Ptr, 0, 2, 1, true);
Assert.That(MemoryHelpers.MemCmpBitRegion(array1Ptr, array2Ptr, 2, 1), Is.True);
UnsafeUtility.MemClear(array1Ptr, 6);
UnsafeUtility.MemClear(array2Ptr, 6);
MemoryHelpers.SetBitsInBuffer(array1Ptr, 0, 5, 24, true);
Assert.That(MemoryHelpers.MemCmpBitRegion(array1Ptr, array2Ptr, 5, 24), Is.False);
MemoryHelpers.SetBitsInBuffer(array2Ptr, 0, 5, 24, true);
Assert.That(MemoryHelpers.MemCmpBitRegion(array1Ptr, array2Ptr, 5, 24), Is.True);
}
}
////TODO: pass state ptr *NOT* value ptr (it's confusing)
// We don't allow custom default values for state so all zeros indicates
// default states for us.
// NOTE: The given argument should point directly to the value *not* to the
// base state to which the state block offset has to be added.
internal unsafe bool CheckStateIsAllZeros(IntPtr valuePtr = new IntPtr())
{
if (valuePtr == IntPtr.Zero)
{
valuePtr = new IntPtr(currentStatePtr.ToInt64() + (int)m_StateBlock.byteOffset);
}
// Bitfield value.
if (m_StateBlock.sizeInBits % 8 != 0 || m_StateBlock.bitOffset != 0)
{
if (m_StateBlock.sizeInBits > 1)
{
throw new NotImplementedException("multi-bit zero check");
}
return(MemoryHelpers.ReadSingleBit(valuePtr, m_StateBlock.bitOffset) == false);
}
// Multi-byte value.
var ptr = (byte *)valuePtr;
var numBytes = m_StateBlock.alignedSizeInBytes;
for (var i = 0; i < numBytes; ++i, ++ptr)
{
if (*ptr != 0)
{
return(false);
}
}
return(true);
}
public unsafe AudioBuffer(int sizeInBytes, BufferFlags flags = BufferFlags.EndOfStream)
{
Flags = flags;
AudioBytes = sizeInBytes;
AudioDataPointer = new IntPtr(MemoryHelpers.AllocateMemory((nuint)sizeInBytes));
_ownsBuffer = true;
}
public void WriteDouble(void *statePtr, double value)
{
var valuePtr = (byte *)statePtr + (int)byteOffset;
var fmt = (int)format;
if (fmt == kFormatFloat)
{
Debug.Assert(sizeInBits == 32, "FLT state must have sizeInBits=32");
Debug.Assert(bitOffset == 0, "FLT state must be byte-aligned");
*(float *)valuePtr = (float)value;
}
else if (fmt == kFormatBit)
{
if (sizeInBits == 1)
{
MemoryHelpers.WriteSingleBit(valuePtr, bitOffset, value >= 0.5f);
}
else
{
var maxValue = (1 << (int)sizeInBits) - 1;
var intValue = (int)(value * maxValue);
MemoryHelpers.WriteIntFromMultipleBits(valuePtr, bitOffset, sizeInBits, intValue);
}
}
else if (fmt == kFormatShort)
{
Debug.Assert(sizeInBits == 16, "SHRT state must have sizeInBits=16");
Debug.Assert(bitOffset == 0, "SHRT state must be byte-aligned");
*(short *)valuePtr = (short)(value * 32768.0f);
}
else if (fmt == kFormatUShort)
{
Debug.Assert(sizeInBits == 16, "USHT state must have sizeInBits=16");
Debug.Assert(bitOffset == 0, "USHT state must be byte-aligned");
*(ushort *)valuePtr = (ushort)(value * 65535.0f);
}
else if (fmt == kFormatByte)
{
Debug.Assert(sizeInBits == 8, "BYTE state must have sizeInBits=8");
Debug.Assert(bitOffset == 0, "BYTE state must be byte-aligned");
*valuePtr = (byte)(value * 255.0f);
}
else if (fmt == kFormatSByte)
{
Debug.Assert(sizeInBits == 8, "SBYT state must have sizeInBits=8");
Debug.Assert(bitOffset == 0, "SBYT state must be byte-aligned");
*(sbyte *)valuePtr = (sbyte)(value * 128.0f);
}
else if (fmt == kFormatDouble)
{
Debug.Assert(sizeInBits == 64, "DBL state must have sizeInBits=64");
Debug.Assert(bitOffset == 0, "DBL state must be byte-aligned");
*(double *)valuePtr = value;
}
else
{
throw new InvalidOperationException($"State format '{format}' is not supported as floating-point format");
}
}
public static string CreateFakeString(string targetString = null)
{
byte[] bytes = Encoding.Unicode.GetBytes(targetString ?? "hello worD");
string str = MemoryHelpers.MakeString(bytes);
return(str);
}
public AudioBuffer(int sizeInBytes, BufferFlags flags = BufferFlags.EndOfStream)
{
Flags = flags;
AudioBytes = sizeInBytes;
AudioDataPointer = MemoryHelpers.AllocateMemory(sizeInBytes);
_ownsBuffer = true;
}
public InterfaceArray(params T[] array)
{
if (array != null)
{
var length = unchecked ((uint)array.Length);
if (length != 0)
{
_values = new T[length];
_nativePointer = MemoryHelpers.AllocateMemory(length * (uint)IntPtr.Size);
for (var i = 0; i < length; i++)
{
this[i] = array[i];
}
}
else
{
_nativePointer = default;
_values = null;
}
}
else
{
_nativePointer = default;
_values = null;
}
}
public void Write(void *statePtr, PrimitiveValue value)
{
var valuePtr = (byte *)statePtr + (int)byteOffset;
if (format == kTypeBit || format == kTypeSBit)
{
if (sizeInBits > 32)
{
throw new NotImplementedException(
"Cannot yet write primitive values into bitfields wider than 32 bits");
}
if (sizeInBits == 1)
{
MemoryHelpers.WriteSingleBit(valuePtr, bitOffset, value.ToBool());
}
else
{
MemoryHelpers.WriteIntFromMultipleBits(valuePtr, bitOffset, sizeInBits, value.ToInt());
}
}
else if (format == kTypeFloat)
{
Debug.Assert(sizeInBits == 32, "FLT state must have sizeInBits=32");
Debug.Assert(bitOffset == 0, "FLT state must be byte-aligned");
*(float *)valuePtr = value.ToFloat();
}
else
{
throw new NotImplementedException(string.Format(
"Writing primitive value of type '{0}' into state block with format '{1}'", value.valueType,
format));
}
}
public override void Update()
{
if (_memory == null)
{
var tempProcess = MemoryHelpers.GetProcessIfRunning(ProcessNames[0]);
if (tempProcess == null)
{
return;
}
_memory = new Memory(tempProcess);
}
if (ProfileModel == null || DataModel == null || _memory == null)
{
return;
}
var offsets = _pointer.GameAddresses.First(ga => ga.Description == "PlayerBase").ToString();
var baseAddress = _memory.GetAddress("\"Terraria.exe\"" + offsets);
var basePointer = new IntPtr(_memory.ReadInt32(baseAddress));
var playerPointer = new IntPtr(_memory.ReadInt32(basePointer + 0x18));
var dataModel = (TerrariaDataModel)DataModel;
dataModel.Hp = _memory.ReadInt32(playerPointer + 0x340);
dataModel.MaxHp = _memory.ReadInt32(playerPointer + 0x338);
dataModel.Mana = _memory.ReadInt32(playerPointer + 0x344);
dataModel.MaxMana = _memory.ReadInt32(playerPointer + 0x348);
dataModel.Breath = _memory.ReadInt32(playerPointer + 0x2B4);
dataModel.MaxBreath = _memory.ReadInt32(playerPointer + 0x2B0);
dataModel.InWater = Convert.ToBoolean(_memory.ReadInt32(playerPointer + 0x1D));
dataModel.InLava = Convert.ToBoolean(_memory.ReadInt32(playerPointer + 0x20));
}
////TODO: expose the checks for default state
/// <summary>
/// Check if the given state corresponds to the default state of the control/device.
/// </summary>
/// <param name="statePtr">Pointer to a state buffer or null to use <see cref="currentStatePtr"/>.</param>
/// <param name="maskPtr">If not null, any bits set to true in the buffer will be ignored. This can be used
/// to mask out noise.</param>
/// <returns>True if the control/device is in its default state.</returns>
/// <remarks>
/// Note that default does not equate all zeroes. Stick axes, for example, that are stored as unsigned byte
/// values will have their resting position at 127 and not at 0. This is why we explicitly store default
/// state in a memory buffer instead of assuming zeroes.
/// </remarks>
/// <seealso cref="InputStateBuffers.defaultStateBuffer"/>
internal unsafe bool CheckStateIsAtDefault(void *statePtr = null, void *maskPtr = null)
{
////REVIEW: for compound controls, do we want to go check leaves so as to not pick up on non-control noise in the state?
//// e.g. from HID input reports
if (statePtr == null)
{
statePtr = currentStatePtr;
}
var defaultValuePtr = (byte *)defaultStatePtr + (int)m_StateBlock.byteOffset;
var valuePtr = (byte *)statePtr + (int)m_StateBlock.byteOffset;
if (m_StateBlock.sizeInBits == 1)
{
// If we have a mask and the bit is set in the mask, the control is to be ignored
// and thus we consider it at default value.
if (maskPtr != null && MemoryHelpers.ReadSingleBit(maskPtr, m_StateBlock.bitOffset))
{
return(true);
}
return(MemoryHelpers.ReadSingleBit(valuePtr, m_StateBlock.bitOffset) ==
MemoryHelpers.ReadSingleBit(defaultValuePtr, m_StateBlock.bitOffset));
}
return(MemoryHelpers.MemCmpBitRegion(defaultValuePtr, valuePtr,
m_StateBlock.bitOffset, m_StateBlock.sizeInBits));
}
/// <summary>
/// Compare the control's stored state in <paramref name="firstStatePtr"/> to <paramref name="secondStatePtr"/>.
/// </summary>
/// <param name="firstStatePtr">Memory containing the control's <see cref="InputControl.stateBlock"/>.</param>
/// <param name="secondStatePtr">Memory containing the control's <see cref="InputControl.stateBlock"/></param>
/// <param name="maskPtr">Optional mask. If supplied, it will be used to mask the comparison between
/// <paramref name="firstStatePtr"/> and <paramref name="secondStatePtr"/> such that any bit not set in the
/// mask will be ignored even if different between the two states. This can be used, for example, to ignore
/// noise in the state (<see cref="InputControl.noiseMaskPtr"/>).</param>
/// <returns>True if the state is equivalent in both memory buffers.</returns>
/// <remarks>
/// Unlike <see cref="InputControl.CompareValue"/>, this method only compares raw memory state. If used on a stick, for example,
/// it may mean that this method returns false for two stick values that would compare equal using <see cref="CompareValue"/>
/// (e.g. if both stick values fall below the deadzone).
/// </remarks>
/// <seealso cref="InputControl.CompareValue"/>
public static unsafe bool CompareState(this InputControl control, void *firstStatePtr, void *secondStatePtr, void *maskPtr = null)
{
////REVIEW: for compound controls, do we want to go check leaves so as to not pick up on non-control noise in the state?
//// e.g. from HID input reports; or should we just leave that to maskPtr?
var firstPtr = (byte *)firstStatePtr + (int)control.m_StateBlock.byteOffset;
var secondPtr = (byte *)secondStatePtr + (int)control.m_StateBlock.byteOffset;
var mask = maskPtr != null ? (byte *)maskPtr + (int)control.m_StateBlock.byteOffset : null;
if (control.m_StateBlock.sizeInBits == 1)
{
// If we have a mask and the bit is set in the mask, the control is to be ignored
// and thus we consider it at default value.
if (mask != null && MemoryHelpers.ReadSingleBit(mask, control.m_StateBlock.bitOffset))
{
return(true);
}
return(MemoryHelpers.ReadSingleBit(secondPtr, control.m_StateBlock.bitOffset) ==
MemoryHelpers.ReadSingleBit(firstPtr, control.m_StateBlock.bitOffset));
}
return(MemoryHelpers.MemCmpBitRegion(firstPtr, secondPtr,
control.m_StateBlock.bitOffset, control.m_StateBlock.sizeInBits, mask));
}
/// <summary>
/// Called when the InputNoiseFilter gets applied to a device, calls down to any individual FilteredElements that need to do any work.
/// </summary>
/// <param name="device">The device you want to apply filtering to.</param>
internal void Apply(InputDevice device)
{
if (device == null)
{
throw new ArgumentException("No device supplied to apply InputNoiseFilter to.", "device");
}
if (IsEmpty())
{
return;
}
var noiseBitmaskPtr = InputStateBuffers.s_NoiseBitmaskBuffer;
if (noiseBitmaskPtr == IntPtr.Zero)
{
return;
}
MemoryHelpers.SetBitsInBuffer(noiseBitmaskPtr, device, true);
for (var i = 0; i < elements.Length; i++)
{
elements[i].Apply(noiseBitmaskPtr, device);
}
}
private unsafe string ReadRawValueAsString(InputControl control, byte[] state)
{
fixed(byte *statePtr = state)
{
var ptr = statePtr + control.m_StateBlock.byteOffset - m_RootControl.m_StateBlock.byteOffset;
var format = control.m_StateBlock.format;
object value = null;
if (format == InputStateBlock.kTypeBit)
{
if (MemoryHelpers.ReadSingleBit(ptr, control.m_StateBlock.bitOffset))
{
value = "1";
}
else
{
value = "0";
}
}
else if (format == InputStateBlock.kTypeByte || format == InputStateBlock.kTypeSByte)
{
value = *ptr;
}
else if (format == InputStateBlock.kTypeShort)
{
value = *(short *)ptr;
}
else if (format == InputStateBlock.kTypeUShort)
{
value = *(ushort *)ptr;
}
else if (format == InputStateBlock.kTypeInt)
{
value = *(int *)ptr;
}
else if (format == InputStateBlock.kTypeUInt)
{
value = *(uint *)ptr;
}
else if (format == InputStateBlock.kTypeFloat)
{
value = *(float *)ptr;
}
else if (format == InputStateBlock.kTypeDouble)
{
value = *(double *)ptr;
}
// Stringify enum values, for. ex., PointerPhase
if (value != null && control.valueType.IsEnum)
{
var intValue = Convert.ToInt32(value);
value = Enum.ToObject(control.valueType, intValue);
}
return(value != null?value.ToString() : null);
}
}
public static unsafe AudioBuffer Create <T>(ReadOnlySpan <T> data, BufferFlags flags = BufferFlags.EndOfStream) where T : struct
{
var sizeInBytes = data.Length * Unsafe.SizeOf <T>();
var dataPtr = MemoryHelpers.AllocateMemory(data.Length);
MemoryHelpers.CopyMemory(dataPtr, data);
return(new AudioBuffer(flags, dataPtr, sizeInBytes, true));
}
public static unsafe AudioBuffer Create <T>(ReadOnlySpan <T> data, BufferFlags flags = BufferFlags.EndOfStream) where T : unmanaged
{
int sizeInBytes = data.Length * sizeof(T);
IntPtr dataPtr = MemoryHelpers.AllocateMemory(data.Length);
MemoryHelpers.CopyMemory(dataPtr, data);
return(new AudioBuffer(flags, dataPtr, sizeInBytes, true));
}
private static void AddBeziersImpl(IntPtr thisPtr, IntPtr beziers, int beziersCount)
{
var shadow = ToShadow <ID2D1SimplifiedGeometrySinkShadow>(thisPtr);
var callback = (ID2D1SimplifiedGeometrySink)shadow.Callback;
var managedBeziers = new BezierSegment[beziersCount];
MemoryHelpers.Read(beziers, managedBeziers, 0, beziersCount);
callback.AddBeziers(managedBeziers);
}
private static void AddLinesImpl(IntPtr thisPtr, IntPtr points, int pointsCount)
{
var shadow = ToShadow <ID2D1SimplifiedGeometrySinkShadow>(thisPtr);
var callback = (ID2D1SimplifiedGeometrySink)shadow.Callback;
var managedPoints = new PointF[pointsCount];
MemoryHelpers.Read(points, managedPoints, 0, pointsCount);
callback.AddLines(managedPoints);
}
public void OutInterfaceParameters()
{
using (SetupTests(false, out var nativeView, out _))
{
var test = nativeView.CloneInstance();
Assert.Equal(1, test.Add(0, 1));
MemoryHelpers.Dispose(ref test);
}
}
public void Dispose()
{
if (_ownsBuffer &&
AudioDataPointer != IntPtr.Zero)
{
MemoryHelpers.FreeMemory(AudioDataPointer);
AudioDataPointer = IntPtr.Zero;
}
}
public unsafe int ReadInt(IntPtr statePtr)
{
Debug.Assert(sizeInBits != 0);
var valuePtr = (byte *)statePtr.ToPointer() + (int)byteOffset;
int value;
if (format == kTypeInt || format == kTypeUInt)
{
Debug.Assert(sizeInBits == 32, "INT and UINT state must have sizeInBits=32");
Debug.Assert(bitOffset == 0, "INT and UINT state must be byte-aligned");
value = *(int *)valuePtr;
}
else if (format == kTypeBit)
{
if (sizeInBits == 1)
{
value = MemoryHelpers.ReadSingleBit(new IntPtr(valuePtr), bitOffset) ? 1 : 0;
}
else
{
value = MemoryHelpers.ReadIntFromMultipleBits(new IntPtr(valuePtr), bitOffset, sizeInBits);
}
}
else if (format == kTypeByte)
{
Debug.Assert(sizeInBits == 8, "BYTE state must have sizeInBits=8");
Debug.Assert(bitOffset == 0, "BYTE state must be byte-aligned");
value = *valuePtr;
}
else if (format == kTypeSByte)
{
Debug.Assert(sizeInBits == 8, "SBYT state must have sizeInBits=8");
Debug.Assert(bitOffset == 0, "SBYT state must be byte-aligned");
value = *(sbyte *)valuePtr;
}
else if (format == kTypeShort)
{
Debug.Assert(sizeInBits == 16, "SHRT state must have sizeInBits=16");
Debug.Assert(bitOffset == 0, "SHRT state must be byte-aligned");
value = *(short *)valuePtr;
}
else if (format == kTypeUShort)
{
Debug.Assert(sizeInBits == 16, "USHT state must have sizeInBits=16");
Debug.Assert(bitOffset == 0, "USHT state must be byte-aligned");
value = *(ushort *)valuePtr;
}
else
{
throw new Exception(string.Format("State format '{0}' is not supported as integer format", format));
}
return(value);
}
/// <summary>
/// Initializes a new instance of the <see cref="DataStream"/> class and allocates a new buffer to use as a backing store.
/// </summary>
/// <param name="sizeInBytes">The size of the buffer to be allocated, in bytes.</param>
/// <param name="canRead"><c>true</c> if reading from the buffer should be allowed; otherwise, <c>false</c>.</param>
/// <param name = "canWrite"><c>true</c> if writing to the buffer should be allowed; otherwise, <c>false</c>.</param>
public DataStream(int sizeInBytes, bool canRead, bool canWrite)
{
Debug.Assert(sizeInBytes > 0);
_buffer = (byte *)MemoryHelpers.AllocateMemory((nuint)sizeInBytes);
_size = sizeInBytes;
_ownsBuffer = true;
CanRead = canRead;
CanWrite = canWrite;
}
/// <summary>
/// Called when the InputNoiseFilter gets applied to a device, marks out any controls that can be wholly bitmasked.
/// </summary>
/// <param name="noiseFilterBuffer">The noise filter buffer for doing whole control filtering.</param>
/// <param name="device">The device you want to apply filtering to.</param>
public void Apply(IntPtr noiseFilterBuffer, InputDevice device)
{
if (controlIndex >= device.allControls.Count)
{
throw new IndexOutOfRangeException("InputNoiseFilter has array index beyond total size of device's controls");
}
var control = device.allControls[controlIndex];
MemoryHelpers.SetBitsInBuffer(noiseFilterBuffer, control, false);
}
public KeyboardState(params Key[] pressedKeys)
{
fixed(byte *keysPtr = keys)
{
UnsafeUtility.MemClear(keysPtr, kSizeInBytes);
for (var i = 0; i < pressedKeys.Length; ++i)
{
MemoryHelpers.WriteSingleBit(keysPtr, (uint)pressedKeys[i], true);
}
}
}
