namespace pxsim { enum UartOff { TypeData = 0, // Types[8][4] Repeat = 1792, // uint16[300][4] Raw = 4192, // int8[32][300][4] Actual = 42592, // uint16[4] LogIn = 42600, // uint16[4] Status = 42608, // int8[4] Output = 42612, // int8[32][4] OutputLength = 42740, // int8[4] Size = 42744 } enum UartStatus { UART_PORT_CHANGED = 1, UART_DATA_READY = 8 } enum IO { UART_SET_CONN = 0xc00c7500, UART_READ_MODE_INFO = 0xc03c7501, UART_NACK_MODE_INFO = 0xc03c7502, UART_CLEAR_CHANGED = 0xc03c7503, IIC_SET_CONN = 0xc00c6902, IIC_READ_TYPE_INFO = 0xc03c6903, IIC_SETUP = 0xc04c6905, IIC_SET = 0xc02c6906, TST_PIN_ON = 0xc00b7401, TST_PIN_OFF = 0xc00b7402, TST_PIN_READ = 0xc00b7403, TST_PIN_WRITE = 0xc00b7404, TST_UART_ON = 0xc0487405, TST_UART_OFF = 0xc0487406, TST_UART_EN = 0xc0487407, TST_UART_DIS = 0xc0487408, TST_UART_READ = 0xc0487409, TST_UART_WRITE = 0xc048740a, } enum DevConOff { Connection = 0, // int8[4] Type = 4, // int8[4] Mode = 8, // int8[4] Size = 12 } enum UartCtlOff { TypeData = 0, // Types Port = 56, // int8 Mode = 57, // int8 Size = 58 } enum TypesOff { Name = 0, // int8[12] Type = 12, // int8 Connection = 13, // int8 Mode = 14, // int8 DataSets = 15, // int8 Format = 16, // int8 Figures = 17, // int8 Decimals = 18, // int8 Views = 19, // int8 RawMin = 20, // float32 RawMax = 24, // float32 PctMin = 28, // float32 PctMax = 32, // float32 SiMin = 36, // float32 SiMax = 40, // float32 InvalidTime = 44, // uint16 IdValue = 46, // uint16 Pins = 48, // int8 Symbol = 49, // int8[5] Align = 54, // uint16 Size = 56 } export class EV3UArtState { constructor() { let data = new Uint8Array(UartOff.Size); MMapMethods.register("/dev/lms_uart", { data, beforeMemRead: () => { //console.log("uart before read"); const inputNodes = ev3board().getInputNodes(); for (let port = 0; port < DAL.NUM_INPUTS; port++) { const node = inputNodes[port]; if (node) { // Actual const index = 0; //UartOff.Actual + port * 2; data[UartOff.Raw + DAL.MAX_DEVICE_DATALENGTH * 300 * port + DAL.MAX_DEVICE_DATALENGTH * index] = node.getValue(); // Status data[UartOff.Status + port] = node.valueChange() ? UartStatus.UART_PORT_CHANGED : UartStatus.UART_DATA_READY; } } }, read: buf => { let v = "vSIM" // for (let i = 0; i < buf.data.length; ++i) // buf.data[i] = v.charCodeAt(i) || 0 console.log("uart read"); console.log(buf.data); return buf.data.length }, write: buf => { console.log("uart write"); console.log(buf); return 2 }, ioctl: (id, buf) => { switch (id) { case IO.UART_SET_CONN: { // Set mode console.log("IO.UART_SET_CONN"); for (let port = 0; port < DAL.NUM_INPUTS; port++) { const connection = buf.data[DevConOff.Connection + port]; // CONN_NONE, CONN_INPUT_UART const type = buf.data[DevConOff.Type + port]; const mode = buf.data[DevConOff.Mode + port]; console.log(`${port}, mode: ${mode}`) const node = ev3board().getInputNodes()[port]; if (node) node.setMode(mode); } return 2; } case IO.UART_CLEAR_CHANGED: { console.log("IO.UART_CLEAR_CHANGED") for (let port = 0; port < DAL.NUM_INPUTS; port++) { const connection = buf.data[DevConOff.Connection + port]; // CONN_NONE, CONN_INPUT_UART const type = buf.data[DevConOff.Type + port]; const mode = buf.data[DevConOff.Mode + port]; const node = ev3board().getInputNodes()[port]; if (node) node.setMode(mode); } return 2; } case IO.UART_READ_MODE_INFO: { console.log("IO.UART_READ_MODE_INFO") const port = buf.data[UartCtlOff.Port]; const mode = buf.data[UartCtlOff.Mode]; const node = ev3board().getInputNodes()[port]; if (node) buf.data[UartCtlOff.TypeData + TypesOff.Type] = node.getDeviceType(); // DEVICE_TYPE_NONE, DEVICE_TYPE_TOUCH, return 2; } } console.log("uart ioctl"); console.log(id); console.log(buf); return 2; } }) } } }