void UARTStdioInit(void) { /* Performing the Pin Multiplexing for UART0 instance. */ /* RXD */ HWREG(SOC_CONTROL_REGS + CONTROL_CONF_UART_RXD(0)) = (CONTROL_CONF_UART0_RXD_CONF_UART0_RXD_PUTYPESEL | CONTROL_CONF_UART0_RXD_CONF_UART0_RXD_RXACTIVE); /* TXD */ HWREG(SOC_CONTROL_REGS + CONTROL_CONF_UART_TXD(0)) = CONTROL_CONF_UART0_TXD_CONF_UART0_TXD_PUTYPESEL; moduleEnable(MODULE_ID_UART0); UARTModuleReset(UART_CONSOLE_BASE); /* Performing FIFO configurations. */ UartFIFOConfigure(1, 1); /* Performing Baud Rate settings. */ UartBaudRateSet(115200); /* Switching to Configuration Mode B. */ UARTRegConfigModeEnable(UART_CONSOLE_BASE, UART_REG_CONFIG_MODE_B); /* Programming the Line Characteristics. */ UARTLineCharacConfig(UART_CONSOLE_BASE, (UART_FRAME_WORD_LENGTH_8 | UART_FRAME_NUM_STB_1), UART_PARITY_NONE); /* Disabling write access to Divisor Latches. */ UARTDivisorLatchDisable(UART_CONSOLE_BASE); /* Disabling Break Control. */ UARTBreakCtl(UART_CONSOLE_BASE, UART_BREAK_COND_DISABLE); /* Switching to UART16x operating mode. */ UARTOperatingModeSelect(UART_CONSOLE_BASE, UART16x_OPER_MODE); }
/****************************************************************************** * * * \brief Serial initilalization routine. * * * * \param none. * * * * \return none. * * * ******************************************************************************/ void SerialInit(void) { unsigned int intFlags = 0; USBBufferInit((tUSBBuffer *)&g_sTxBuffer); USBBufferInit((tUSBBuffer *)&g_sRxBuffer); /* Configuring the system clocks for UART0 instance. */ UART0ModuleClkConfig(); /* Performing the Pin Multiplexing for UART0 instance. */ UARTPinMuxSetup(0); /* Performing a module reset. */ UARTModuleReset(SOC_UART_0_REGS); /* Performing Baud Rate settings. */ UartBaudRateSet(); /* Switching to Configuration Mode B. */ UARTRegConfigModeEnable(SOC_UART_0_REGS, UART_REG_CONFIG_MODE_B); /* Programming the Line Characteristics. */ UARTLineCharacConfig(SOC_UART_0_REGS, (UART_FRAME_WORD_LENGTH_8 | UART_FRAME_NUM_STB_1), UART_PARITY_NONE); /* Disabling write access to Divisor Latches. */ UARTDivisorLatchDisable(SOC_UART_0_REGS); /* Disabling Break Control. */ UARTBreakCtl(SOC_UART_0_REGS, UART_BREAK_COND_DISABLE); /* Switching to UART16x operating mode. */ UARTOperatingModeSelect(SOC_UART_0_REGS, UART16x_OPER_MODE); /* Performing FIFO configurations. */ UartFIFOConfigure(); /* Preparing the 'intFlags' variable to be passed as an argument.*/ intFlags |= (UART_INT_LINE_STAT | UART_INT_RHR_CTI); /* Enable the Interrupts in UART.*/ UARTIntEnable(SOC_UART_0_REGS, intFlags); }
/* ** This function initializes the UART instance for use. */ static void UARTInitialize(void) { /* Performing a module reset. */ UARTModuleReset(UART_INSTANCE_BASE_ADD); #ifdef UART_ENABLE_FIFO /* Performing FIFO configurations. */ UartFIFOConfigure(); #else /* Enabling DMA Mode 1. */ UARTDMAEnable(UART_INSTANCE_BASE_ADD, UART_DMA_MODE_1_ENABLE); #endif #if (defined UART_ENABLE_FIFO) && (defined DIRECT_TX_DMA_THRESH_MODE) /* Selecting the method of setting the Transmit DMA Threshold value. */ UARTTxDMAThresholdControl(UART_INSTANCE_BASE_ADD, UART_TX_DMA_THRESHOLD_REG); /* Configuring the Transmit DMA Threshold value. */ UARTTxDMAThresholdValConfig(UART_INSTANCE_BASE_ADD, TX_DMA_THRESHOLD); #endif /* Performing Baud Rate settings. */ UartBaudRateSet(); /* Switching to Configuration Mode B. */ UARTRegConfigModeEnable(UART_INSTANCE_BASE_ADD, UART_REG_CONFIG_MODE_B); /* Programming the Line Characteristics. */ UARTLineCharacConfig(UART_INSTANCE_BASE_ADD, (UART_FRAME_WORD_LENGTH_8 | UART_FRAME_NUM_STB_1), UART_PARITY_NONE); /* Disabling write access to Divisor Latches. */ UARTDivisorLatchDisable(UART_INSTANCE_BASE_ADD); /* Disabling Break Control. */ UARTBreakCtl(UART_INSTANCE_BASE_ADD, UART_BREAK_COND_DISABLE); /* Switching to UART16x operating mode. */ UARTOperatingModeSelect(UART_INSTANCE_BASE_ADD, UART16x_OPER_MODE); }
//***************************************************************************** // // This is the main application entry function. // //***************************************************************************** int main(void) { unsigned int ulTxCount; unsigned int ulRxCount; tRectangle sRect; char pcBuffer[16]; unsigned int ulFullness; unsigned int intFlags = 0; unsigned char Intstatus; unsigned int i; unsigned char *src, *dest; MMUConfigAndEnable(); // // Not configured initially. // g_bUSBConfigured = false; // //configures arm interrupt controller to generate raster interrupt // USBInterruptEnable(); // //LCD Back light setup // LCDBackLightEnable(); // //UPD Pin setup // UPDNPinControl(); // //Delay timer setup // DelayTimerSetup(); // //Configures raster to display image // SetUpLCD(); RasterDMAFBConfig(SOC_LCDC_0_REGS, (unsigned int)(g_pucBuffer+PALETTE_OFFSET), (unsigned int)(g_pucBuffer+PALETTE_OFFSET) + sizeof(g_pucBuffer) - 2 - PALETTE_OFFSET, FRAME_BUFFER_0); RasterDMAFBConfig(SOC_LCDC_0_REGS, (unsigned int)(g_pucBuffer+PALETTE_OFFSET), (unsigned int)(g_pucBuffer+PALETTE_OFFSET) + sizeof(g_pucBuffer) - 2 - PALETTE_OFFSET, FRAME_BUFFER_1); src = (unsigned char *) palette_32b; dest = (unsigned char *) (g_pucBuffer+PALETTE_OFFSET); // Copy palette info into buffer for( i = PALETTE_OFFSET; i < (PALETTE_SIZE+PALETTE_OFFSET); i++) { *dest++ = *src++; } GrOffScreen24BPPInit(&g_s35_480x272x24Display, g_pucBuffer, LCD_WIDTH, LCD_HEIGHT); // Initialize a drawing context. GrContextInit(&g_sContext, &g_s35_480x272x24Display); /* enable End of frame interrupt */ RasterEndOfFrameIntEnable(SOC_LCDC_0_REGS); /* enable raster */ RasterEnable(SOC_LCDC_0_REGS); // // Fill the top 24 rows of the screen with blue to create the banner. // sRect.sXMin = 0; sRect.sYMin = 0; sRect.sXMax = GrContextDpyWidthGet(&g_sContext) - 1; sRect.sYMax = 23; GrContextForegroundSet(&g_sContext, ClrDarkBlue); GrRectFill(&g_sContext, &sRect); // // Put a white box around the banner. // GrContextForegroundSet(&g_sContext, ClrWhite); GrRectDraw(&g_sContext, &sRect); // // Put the application name in the middle of the banner. // GrContextFontSet(&g_sContext, &g_sFontCm20); GrStringDrawCentered(&g_sContext, "usb-dev-serial", -1, GrContextDpyWidthGet(&g_sContext) / 2, 10, 0); // // Show the various static text elements on the color STN display. // GrContextFontSet(&g_sContext, TEXT_FONT); GrStringDraw(&g_sContext, "Tx bytes:", -1, 8, 80, false); GrStringDraw(&g_sContext, "Tx buffer:", -1, 8, 105, false); GrStringDraw(&g_sContext, "Rx bytes:", -1, 8, 160, false); GrStringDraw(&g_sContext, "Rx buffer:", -1, 8, 185, false); DrawBufferMeter(&g_sContext, 150, 105); DrawBufferMeter(&g_sContext, 150, 185); // // Tell the user what we are up to. // DisplayStatus(&g_sContext, " Configuring USB... "); // //Initialize the Rx and TX Buffers // USBBufferInit((tUSBBuffer *)&g_sTxBuffer); USBBufferInit((tUSBBuffer *)&g_sRxBuffer); // // Pass our device information to the USB library and place the device // on the bus. // USBDCDCInit(0, (tUSBDCDCDevice *)&g_sCDCDevice); // // Wait for initial configuration to complete. // DisplayStatus(&g_sContext, " Waiting for host... "); // // Clear our local byte counters. // ulRxCount = 0; ulTxCount = 0; /* Configuring the system clocks for UART0 instance. */ UART0ModuleClkConfig(); /* Performing the Pin Multiplexing for UART0 instance. */ UARTPinMuxSetup(0); /* Performing a module reset. */ UARTModuleReset(SOC_UART_0_REGS); /* Performing Baud Rate settings. */ UartBaudRateSet(); /* Switching to Configuration Mode B. */ UARTRegConfigModeEnable(SOC_UART_0_REGS, UART_REG_CONFIG_MODE_B); /* Programming the Line Characteristics. */ UARTLineCharacConfig(SOC_UART_0_REGS, (UART_FRAME_WORD_LENGTH_8 | UART_FRAME_NUM_STB_1), UART_PARITY_NONE); /* Disabling write access to Divisor Latches. */ UARTDivisorLatchDisable(SOC_UART_0_REGS); /* Disabling Break Control. */ UARTBreakCtl(SOC_UART_0_REGS, UART_BREAK_COND_DISABLE); /* Switching to UART16x operating mode. */ UARTOperatingModeSelect(SOC_UART_0_REGS, UART16x_OPER_MODE); /* Performing FIFO configurations. */ UartFIFOConfigure(); /* Preparing the 'intFlags' variable to be passed as an argument.*/ intFlags |= (UART_INT_LINE_STAT | UART_INT_RHR_CTI); /* Enable the Interrupts in UART.*/ UARTIntEnable(SOC_UART_0_REGS, intFlags); // // Main application loop. // while(1) { // // Have we been asked to update the status display? // if(g_ulFlags & COMMAND_STATUS_UPDATE) { // // Clear the command flag // Intstatus = IntDisable(); g_ulFlags &= ~COMMAND_STATUS_UPDATE; IntEnable(Intstatus); DisplayStatus(&g_sContext, g_pcStatus); } // // Has there been any transmit traffic since we last checked? // if(ulTxCount != g_ulUARTTxCount) { // // Take a snapshot of the latest transmit count. // ulTxCount = g_ulUARTTxCount; // // Update the display of bytes transmitted by the UART. // usnprintf(pcBuffer, 16, "%d ", ulTxCount); GrStringDraw(&g_sContext, pcBuffer, -1, 150, 80, true); // // Update the RX buffer fullness. Remember that the buffers are // named relative to the USB whereas the status display is from // the UART's perspective. The USB's receive buffer is the UART's // transmit buffer. // ulFullness = ((USBBufferDataAvailable(&g_sRxBuffer) * 100) / UART_BUFFER_SIZE); UpdateBufferMeter(&g_sContext, ulFullness, 150, 105); } // // Has there been any receive traffic since we last checked? // if(ulRxCount != g_ulUARTRxCount) { // // Take a snapshot of the latest receive count. // ulRxCount = g_ulUARTRxCount; // // Update the display of bytes received by the UART. // usnprintf(pcBuffer, 16, "%d ", ulRxCount); GrStringDraw(&g_sContext, pcBuffer, -1, 150, 160, true); // // Update the TX buffer fullness. Remember that the buffers are // named relative to the USB whereas the status display is from // the UART's perspective. The USB's transmit buffer is the UART's // receive buffer. // ulFullness = ((USBBufferDataAvailable(&g_sTxBuffer) * 100) / UART_BUFFER_SIZE); UpdateBufferMeter(&g_sContext, ulFullness, 150, 185); } } }
/****************************************************************************** ** FUNCTION DEFINITIONS ******************************************************************************/ int main() { unsigned int numByteChunks = 0; unsigned int remainBytes = 0; unsigned int bIndex = 0; /* Configuring the system clocks for UART0 instance. */ UART0ModuleClkConfig(); /* Performing the Pin Multiplexing for UART0 instance. */ UARTPinMuxSetup(0); /* Performing a module reset. */ UARTModuleReset(SOC_UART_0_REGS); /* Performing FIFO configurations. */ UartFIFOConfigure(); /* Performing Baud Rate settings. */ UartBaudRateSet(); /* Switching to Configuration Mode B. */ UARTRegConfigModeEnable(SOC_UART_0_REGS, UART_REG_CONFIG_MODE_B); /* Programming the Line Characteristics. */ UARTLineCharacConfig(SOC_UART_0_REGS, (UART_FRAME_WORD_LENGTH_8 | UART_FRAME_NUM_STB_1), UART_PARITY_NONE); /* Disabling write access to Divisor Latches. */ UARTDivisorLatchDisable(SOC_UART_0_REGS); /* Disabling Break Control. */ UARTBreakCtl(SOC_UART_0_REGS, UART_BREAK_COND_DISABLE); /* Switching to UART16x operating mode. */ UARTOperatingModeSelect(SOC_UART_0_REGS, UART16x_OPER_MODE); /* Select the console type based on compile time check */ ConsoleUtilsSetType(CONSOLE_UART); /* Performing Interrupt configurations. */ UartInterruptEnable(); numByteChunks = (sizeof(txArray) - 1) / NUM_TX_BYTES_PER_TRANS; remainBytes = (sizeof(txArray) - 1) % NUM_TX_BYTES_PER_TRANS; while(1) { /* This branch is entered if the transmission is not yet complete. */ if(TRUE == txEmptyFlag) { if(bIndex < numByteChunks) { /* Transmitting bytes in chunks of NUM_TX_BYTES_PER_TRANS. */ currNumTxBytes += UARTFIFOWrite(SOC_UART_0_REGS,&txArray[currNumTxBytes],NUM_TX_BYTES_PER_TRANS); bIndex++; } else { /* Transmitting remaining data from the data block. */ currNumTxBytes += UARTFIFOWrite(SOC_UART_0_REGS,&txArray[currNumTxBytes],remainBytes); } txEmptyFlag = FALSE; /* ** Re-enables the Transmit Interrupt. This interrupt ** was disabled in the Transmit section of the UART ISR. */ UARTIntEnable(SOC_UART_0_REGS, UART_INT_THR); } } }