Darien Figueroa
repo time
Dependencies: mbed MAX14720 MAX30205 USBDevice
HspGuiSourceV301/HSPGui/NimitzHID.cs
- Committer:
- darienf
- Date:
- 2021-04-06
- Revision:
- 20:6d2af70c92ab
File content as of revision 20:6d2af70c92ab:
using Microsoft.VisualBasic;
using System;
using System.Collections;
using System.Data;
using System.Diagnostics;
using System.Drawing;
using System.Windows.Forms;
using Microsoft.Win32.SafeHandles;
using System.Runtime.InteropServices;
namespace SimpleHID
{
class NimitzHID
{
internal const byte COMMAND_SUCCEED = 0xEE;
internal const byte COMMAND_FAILED = 0xFA;
// private IntPtr deviceNotificationHandle;
// private Boolean exclusiveAccess;
private SafeFileHandle hidHandle;
private String hidUsage;
private Boolean myDeviceDetected;
private String myDevicePathName;
private SafeFileHandle readHandle;
private SafeFileHandle writeHandle;
// private Debugging MyDebugging = new Debugging(); // For viewing results of API calls via Debug.Write.
private Guid hidGuid;
private IntPtr deviceNotificationHandle = System.IntPtr.Zero;
private HID myHID;
//internal FrmMain FrmMy;
/// <summary>
/// Define a class of delegates that point to the Hid.ReportIn.Read function.
/// The delegate has the same parameters as Hid.ReportIn.Read.
/// Used for asynchronous reads from the device.
/// </summary>
private delegate void ReadInputReportDelegate(SafeFileHandle hidHandle, SafeFileHandle readHandle, SafeFileHandle writeHandle, ref Boolean myDeviceDetected, ref Byte[] readBuffer, ref Boolean success);
// This delegate has the same parameters as AccessForm.
// Used in accessing the application's form from a different thread.
private delegate void MarshalToForm(String action, String textToAdd);
/// <summary>
/// Uses a series of API calls to locate a HID-class device
/// by its Vendor ID and Product ID.
/// </summary>
///
/// <returns>
/// True if the device is detected, False if not detected.
/// </returns>
internal Boolean OpenNimitzH()
{
Boolean deviceFound = false;
String[] devicePathName = new String[128];
Guid hidGuid = Guid.Empty;
Int32 memberIndex = 0;
Int32 myProductID = 0x1365;
Int32 myVendorID = 0x0B6A;
Boolean success = false;
myDeviceDetected = false;
myHID.findHIDs();
// ***
// API function: 'HidD_GetHidGuid
// Purpose: Retrieves the interface class GUID for the HID class.
// Accepts: 'A System.Guid object for storing the GUID.
// ***
Hid.HidD_GetHidGuid(ref hidGuid);
// Fill an array with the device path names of all attached HIDs.
deviceFound = MyDeviceManagement.FindDeviceFromGuid(hidGuid, ref devicePathName);
// If there is at least one HID, attempt to read the Vendor ID and Product ID
// of each device until there is a match or all devices have been examined.
if (deviceFound)
{
memberIndex = 0;
do
{
// ***
// API function:
// CreateFile
// Purpose:
// Retrieves a handle to a device.
// Accepts:
// A device path name returned by SetupDiGetDeviceInterfaceDetail
// The type of access requested (read/write).
// FILE_SHARE attributes to allow other processes to access the device while this handle is open.
// A Security structure or IntPtr.Zero.
// A creation disposition value. Use OPEN_EXISTING for devices.
// Flags and attributes for files. Not used for devices.
// Handle to a template file. Not used.
// Returns: a handle without read or write access.
// This enables obtaining information about all HIDs, even system
// keyboards and mice.
// Separate handles are used for reading and writing.
// ***
hidHandle = FileIO.CreateFile(devicePathName[memberIndex], 0, FileIO.FILE_SHARE_READ | FileIO.FILE_SHARE_WRITE, IntPtr.Zero, FileIO.OPEN_EXISTING, 0, 0);
if (!hidHandle.IsInvalid)
{
// The returned handle is valid,
// so find out if this is the device we're looking for.
// Set the Size property of DeviceAttributes to the number of bytes in the structure.
MyHid.DeviceAttributes.Size = Marshal.SizeOf(MyHid.DeviceAttributes);
// ***
// API function:
// HidD_GetAttributes
// Purpose:
// Retrieves a HIDD_ATTRIBUTES structure containing the Vendor ID,
// Product ID, and Product Version Number for a device.
// Accepts:
// A handle returned by CreateFile.
// A pointer to receive a HIDD_ATTRIBUTES structure.
// Returns:
// True on success, False on failure.
// ***
success = Hid.HidD_GetAttributes(hidHandle, ref MyHid.DeviceAttributes);
if (success)
{
// Find out if the device matches the one we're looking for.
if ((MyHid.DeviceAttributes.VendorID == myVendorID) && (MyHid.DeviceAttributes.ProductID == myProductID))
{
myDeviceDetected = true;
// Save the DevicePathName for OnDeviceChange().
myDevicePathName = devicePathName[memberIndex];
}
else
{
// It's not a match, so close the handle.
myDeviceDetected = false;
hidHandle.Close();
}
}
else
{
// There was a problem in retrieving the information.
myDeviceDetected = false;
hidHandle.Close();
}
}
// Keep looking until we find the device or there are no devices left to examine.
memberIndex = memberIndex + 1;
}
while (!((myDeviceDetected || (memberIndex == devicePathName.Length))));
}
if (myDeviceDetected)
{
// The device was detected.
// Learn the capabilities of the device.
MyHid.Capabilities = MyHid.GetDeviceCapabilities(hidHandle);
// Find out if the device is a system mouse or keyboard.
hidUsage = MyHid.GetHidUsage(MyHid.Capabilities);
// Get handles to use in requesting Input and Output reports.
readHandle = FileIO.CreateFile(myDevicePathName, FileIO.GENERIC_READ, FileIO.FILE_SHARE_READ | FileIO.FILE_SHARE_WRITE, IntPtr.Zero, FileIO.OPEN_EXISTING, FileIO.FILE_FLAG_OVERLAPPED, 0);
writeHandle = FileIO.CreateFile(myDevicePathName, FileIO.GENERIC_WRITE, FileIO.FILE_SHARE_READ | FileIO.FILE_SHARE_WRITE, IntPtr.Zero, FileIO.OPEN_EXISTING, 0, 0);
// Flush any waiting reports in the input buffer. (optional)
MyHid.FlushQueue(readHandle);
}
return myDeviceDetected;
}
internal void CloseNimitzH()
{
if (!(hidHandle == null))
{
if (!(hidHandle.IsInvalid))
{
hidHandle.Close();
}
}
if (!(readHandle == null))
{
if (!(readHandle.IsInvalid))
{
readHandle.Close();
}
}
if (!(writeHandle == null))
{
if (!(writeHandle.IsInvalid))
{
writeHandle.Close();
}
}
}
// This function only checks the status variable and does not actively check
// if the NimitzH is still present. This function
// only checks the variable to avoid any timeout delays.
internal Boolean NimitzHPresent()
{
if (myDeviceDetected)
return true;
else
return false;
}
//////////////////////////////////////////////////////////////////////
// Functions that can be called once NimitzH is opened
//////////////////////////////////////////////////////////////////////
// This function calls the NimitzH Read Revision command.
// This is done by sending 0xC2, and then receiving 1 byte major rev, then 1byte minor Rev, and then 0xD2
// This function returns firmware MAJORVERSION in upper word and MINORVERSION in lower word
// This function returns -1 if an error occurs
internal int GetFirmwareVersion()
{
Boolean success = false;
Byte[] inputBuffer = null;
Byte[] dataOut = new Byte[2];
dataOut[0] = 0x01;//number of bytes to send
dataOut[1] = 0x02;//firmware command
success = InputOutputReports(dataOut, ref inputBuffer);
if (!success)
return -1;
if (inputBuffer[2] == COMMAND_SUCCEED)
return (inputBuffer[3] << 16) + inputBuffer[4];
else
return -1;
}
internal Boolean TestSendPacket(byte[] sendData, ref byte[] readData)
{
Boolean success = false;
Byte[] inputBuffer = null;
byte numData = (byte)sendData.Length;
Byte[] dataOut = new Byte[3 + numData];
if ((numData > 62) || (numData < 0))
return false; // Max packet size is 62 bytes
dataOut[0] = (byte)(0x02 + numData);//number of bytes to send (include command and data bytes)
dataOut[1] = 0x01;//command byte
dataOut[2] = (byte)(numData);//number of data bytes
for (int i = 0; i < numData; i++)
dataOut[i + 3] = sendData[i];
success = InputOutputReports(dataOut, ref inputBuffer);
if (!success)
return false;
for (int i = 0; i < numData; i++)
readData[i] = inputBuffer[i + 3];
if (inputBuffer[2] == COMMAND_SUCCEED)
return true;
else
return false;
}
/****************I2CPacketWrite****************/
/* Description: Generates the correct sequence of events on the I2C bus for a packet write (up to 60 data bytes)
/* Information: New Implementation for packet writes ( SHOULD BE USED in most ALLL Writes/Read of and I2C Device )!!
/* Paramters: slaveAddress = slave address of DUT (R/W# is set in firmware), numBytes = Number of data bytes to write (1 to 60),
/* memoryaddress = Desired memory location, databuffer = pointer to the data to write on the buss*/
internal Boolean I2CWritePacket(Byte slaveAddress, Byte memoryaddress, Byte numBytes, Byte[] databuffer)
{
Boolean success = false;
Byte[] inputBuffer = null;
Byte[] dataOut = new Byte[64];
if ((numBytes > 59) || (numBytes < 0))
return false; // Max packet size is 60 bytes
dataOut[0] = (byte)(numBytes + 4);
dataOut[1] = 0x20;
dataOut[2] = slaveAddress;
dataOut[3] = memoryaddress;
dataOut[4] = numBytes;
for (int i = 0; i < numBytes; i++)
dataOut[i + 5] = databuffer[i];
success = InputOutputReports(dataOut, ref inputBuffer);
if (!success)
return false;
if (inputBuffer[2] == COMMAND_SUCCEED)
return true;
else
return false;
}
/****************I2CPacketRead****************/
/* Description: Generates the correct sequence of events on the I2C bus for a packet read (up to 60 data bytes)
/* Information: New Implementation for packet reads ( SHOULD BE USED in most ALLL Writes/Read of and I2C Device )!!
/* Paramters: slaveAddress = slave address of DUT (R/W# is set in firmware), numBytes = Number of data bytes to write (1 to 60),
/* memoryaddress = Desired memory location, databuffer = pointer to the data read should be saved*/
internal Boolean I2CReadPacket(Byte slaveAddress, Byte memoryaddress, Byte numBytes, ref Byte[] databuffer)
{
Boolean success = false;
Byte[] inputBuffer = null;
Byte[] dataOut = new Byte[5];
if ((numBytes > 62) || (numBytes < 1))
return false; // Max packet size is 62 bytes
dataOut[0] = 0x04;
dataOut[1] = 0x21;
dataOut[2] = (byte)(slaveAddress | 0x01);
dataOut[3] = memoryaddress;
dataOut[4] = numBytes;
success = InputOutputReports(dataOut, ref inputBuffer);
if (!success)
return false;
for (int i = 0; i < numBytes; i++)
databuffer[i] = inputBuffer[i + 3];
if (inputBuffer[2] == COMMAND_SUCCEED)
return true;
else
return false;
}
internal Boolean SPIReadPacket(Byte address, Byte numBytes, ref Byte[] data)
{
Boolean success = false;
Byte[] inputBuffer = null;
Byte[] dataOut = new Byte[4];
if ((numBytes > 62) || (numBytes < 1))
return false; // Max packet size is 62 bytes
dataOut[0] = 3;
dataOut[1] = 0x41;
dataOut[2] = address;
dataOut[3] = numBytes;
success = InputOutputReports(dataOut, ref inputBuffer);
if (!success)
return false;
for (int i = 0; i < numBytes; i++)
data[i] = inputBuffer[i + 3];
if (inputBuffer[2] == COMMAND_SUCCEED)
return true;
else
return false;
}
internal Boolean SPIStartSampling(Byte address, Byte numBytes, uint numSamples, ref Byte[] data)
{
Boolean success = false;
Byte[] inputBuffer = null;
Byte[] dataOut = new Byte[6];
if ((numBytes > 62) || (numBytes < 1))
return false; // Max packet size is 62 bytes
dataOut[0] = 5;
dataOut[1] = 0x45;
dataOut[2] = address;
dataOut[3] = numBytes;
dataOut[4] = (byte)(numSamples >> 8);
dataOut[5] = (byte)numSamples;
success = InputOutputReports(dataOut, ref inputBuffer);
if (!success)
return false;
for (int i = 0; i < numBytes; i++)
data[i] = inputBuffer[i + 3];
if (inputBuffer[2] == COMMAND_SUCCEED)
return true;
else
return false;
}
internal bool SPIWritePacket(Byte address, Byte numBytes, Byte[] data)
{
Boolean success = false;
Byte[] inputBuffer = null;
Byte[] dataOut = new Byte[64];
if ((numBytes > 60) || (numBytes < 1))
return false; // Max packet size is 60 bytes
dataOut[0] = (byte)(numBytes + 3);
dataOut[1] = 0x40;
dataOut[2] = address;
dataOut[3] = numBytes;
for (int i = 0; i < numBytes; i++)
dataOut[4 + i] = data[i];
success = InputOutputReports(dataOut, ref inputBuffer);
if (!success)
return false;
if (inputBuffer[2] == COMMAND_SUCCEED)
return true;
else
return false;
}
/// <summary>
/// Sends an Output report, then retrieves an Input report.
/// Assumes report ID = 0 for both reports.
/// </summary>
private Boolean InputOutputReports(Byte[] data, ref Byte[] inputReportBuffer)
{
// Byte[] inputReportBuffer = null;
Byte[] outputReportBuffer = null;
Boolean success = false;
success = false;
// Don't attempt to exchange reports if valid handles aren't available
// (as for a mouse or keyboard under Windows 2000/XP.)
if (!readHandle.IsInvalid && !writeHandle.IsInvalid)
{
// Don't attempt to send an Output report if the HID has no Output report.
if (MyHid.Capabilities.OutputReportByteLength > 0)
{
// Set the size of the Output report buffer.
outputReportBuffer = new Byte[MyHid.Capabilities.OutputReportByteLength];
outputReportBuffer[0] = 0; // Ensure Report ID = 0
for (int i = 0; i < data.Length; i++)
outputReportBuffer[i + 1] = data[i];
// Use WriteFile to send the report.
// If the HID has an interrupt OUT endpoint, WriteFile uses an
// interrupt transfer to send the report.
// If not, WriteFile uses a control transfer.
Hid.OutputReportViaInterruptTransfer myOutputReport = new Hid.OutputReportViaInterruptTransfer();
success = myOutputReport.Write(outputReportBuffer, writeHandle);
}
if (!success)
return false;
// Read an Input report
success = false;
// Don't attempt to send an Input report if the HID has no Input report.
// (The HID spec requires all HIDs to have an interrupt IN endpoint,
// which suggests that all HIDs must support Input reports.)
if (MyHid.Capabilities.InputReportByteLength > 0)
{
// Set the size of the Input report buffer.
inputReportBuffer = new Byte[MyHid.Capabilities.InputReportByteLength];
Hid.InputReportViaInterruptTransfer myInputReport = new Hid.InputReportViaInterruptTransfer();
myInputReport.Read(hidHandle, readHandle, writeHandle, ref myDeviceDetected, ref inputReportBuffer, ref success);
}
}
return success;
}
}
}