/** @file Serial I/O Port library functions with no library constructor/destructor @copyright Copyright 2006 - 2021 Intel Corporation.
SPDX-License-Identifier: BSD-2-Clause-Patent **/ #include #include #include #include #include #include #include #include "Ns16550.h" #include #include #include #include #include #include // // PCH I/O Port Defines // #define R_PCH_IOPORT_PCI_INDEX 0xCF8 #define R_PCH_IOPORT_PCI_DATA 0xCFC #define DEFAULT_PCI_BUS_NUMBER_PCH 0 #define PCI_CF8_ADDR(Bus, Dev, Func, Off) \ (((Off) & 0xFF) | (((Func) & 0x07) << 8) | (((Dev) & 0x1F) << 11) | (((Bus) & 0xFF) << 16) | (1 << 31)) #define PCH_LPC_CF8_ADDR(Offset) PCI_CF8_ADDR(DEFAULT_PCI_BUS_NUMBER_PCH, PCI_DEVICE_NUMBER_PCH_LPC, PCI_FUNCTION_NUMBER_PCH_LPC, Offset) // // PCI Defintions. // #define PCI_BRIDGE_32_BIT_IO_SPACE 0x01 #define B_UART_FCR_FIFOE BIT0 #define B_UART_FCR_FIFO64 BIT5 #define R_UART_LCR 3 #define R_UART_LSR 5 #define B_UART_LSR_RXRDY BIT0 #define R_UART_MCR 4 #define B_UART_MCR_RTS BIT1 #define B_UART_MCR_DTRC BIT0 #define R_UART_MSR 6 #define B_UART_MSR_CTS BIT4 #define B_UART_MSR_DSR BIT5 #define B_UART_MSR_RI BIT6 #define B_UART_MSR_DCD BIT7 #define B_UART_LSR_RXRDY BIT0 #define B_UART_LSR_TXRDY BIT5 #define B_UART_LSR_TEMT BIT6 #define R_UART_BAUD_LOW 0 #define R_UART_BAUD_HIGH 1 #define B_UART_LCR_DLAB BIT7 // // COM definitions // #define COM1_BASE 0x3f8 #define COM2_BASE 0x2f8 UINT32 IsSioExist ( VOID ); typedef struct { UINT8 Index; UINT8 Data; } SIO_REG_TABLE; STATIC SIO_REG_TABLE mASPEED2500Table [] = { { REG_LOGICAL_DEVICE, ASPEED2500_SIO_UART1 }, { ACTIVATE, 0x01 }, { PRIMARY_INTERRUPT_SELECT, 0x04 }, // COMA IRQ routing { INTERRUPT_TYPE, 0x01 }, // COMA Interrupt Type { REG_LOGICAL_DEVICE, ASPEED2500_SIO_UART2 }, { ACTIVATE, 0x01 }, { PRIMARY_INTERRUPT_SELECT, 0x03 }, // COMB IRQ routing { INTERRUPT_TYPE, 0x01 } // COMB Interrupt Type }; UINT8 gData = 8; UINT8 gStop = 1; UINT8 gParity = 0; UINT8 gBreakSet = 0; // // 4-byte structure for each PCI node in PcdSerialPciDeviceInfo // typedef struct { UINT8 Device; UINT8 Function; UINT16 PowerManagementStatusAndControlRegister; } PCI_UART_DEVICE_INFO; /** Check if Serial Port is enabled or not. @param none @retval TRUE Serial Port was enabled. @retval FALSE Serial Port was disabled. **/ BOOLEAN EFIAPI IsSerialPortEnabled ( ) { return TRUE; } UINT8 SerialPortReadRegister ( UINTN Base, UINTN Offset ) { if (PcdGetBool (PcdSerialUseMmio)) { return MmioRead8 (Base + Offset * PcdGet32 (PcdSerialRegisterStride)); } else { return IoRead8 (Base + Offset * PcdGet32 (PcdSerialRegisterStride)); } } UINT8 SerialPortWriteRegister ( UINTN Base, UINTN Offset, UINT8 Value ) { if (PcdGetBool (PcdSerialUseMmio)) { return MmioWrite8 (Base + Offset * PcdGet32 (PcdSerialRegisterStride), Value); } else { return IoWrite8 (Base + Offset * PcdGet32 (PcdSerialRegisterStride), Value); } } /** Update the value of an 32-bit PCI configuration register in a PCI device. If the PCI Configuration register specified by PciAddress is already programmed with a non-zero value, then return the current value. Otherwise update the PCI configuration register specified by PciAddress with the value specified by Value and return the value programmed into the PCI configuration register. All values must be masked using the bitmask specified by Mask. @param PciAddress PCI Library address of the PCI Configuration register to update. @param Value The value to program into the PCI Configuration Register. @param Mask Bitmask of the bits to check and update in the PCI configuration register. @return The Secondary bus number that is actually programed into the PCI to PCI Bridge device. **/ UINT32 SerialPortLibUpdatePciRegister32 ( UINTN PciAddress, UINT32 Value, UINT32 Mask ) { UINT32 CurrentValue; CurrentValue = PciRead32 (PciAddress) & Mask; if (CurrentValue != 0) { return CurrentValue; } return PciWrite32 (PciAddress, Value & Mask); } /** Retrieve the I/O or MMIO base address register for the PCI UART device. This function assumes Root Bus Numer is Zero, and enables I/O and MMIO in PCI UART Device if they are not already enabled. @return The base address register of the UART device. **/ UINTN GetSerialRegisterBase ( VOID ) { UINTN PciLibAddress; UINTN BusNumber; UINTN SubordinateBusNumber; UINT32 ParentIoBase; UINT32 ParentIoLimit; UINT16 ParentMemoryBase; UINT16 ParentMemoryLimit; UINT32 IoBase; UINT32 IoLimit; UINT16 MemoryBase; UINT16 MemoryLimit; UINTN SerialRegisterBase; UINTN BarIndex; UINT32 RegisterBaseMask; PCI_UART_DEVICE_INFO *DeviceInfo; // // Get PCI Device Info // DeviceInfo = (PCI_UART_DEVICE_INFO *) PcdGetPtr (PcdSerialPciDeviceInfo); // // If PCI Device Info is empty, then assume fixed address UART and return PcdSerialRegisterBase // if (DeviceInfo->Device == 0xff) { return (UINTN)PcdGet64 (PcdSerialRegisterBase); } // // Assume PCI Bus 0 I/O window is 0-64KB and MMIO windows is 0-4GB // ParentMemoryBase = 0 >> 16; ParentMemoryLimit = 0xfff00000 >> 16; ParentIoBase = 0 >> 12; ParentIoLimit = 0xf000 >> 12; // // Enable I/O and MMIO in PCI Bridge // Assume Root Bus Numer is Zero. // for (BusNumber = 0; (DeviceInfo + 1)->Device != 0xff; DeviceInfo++) { // // Compute PCI Lib Address to PCI to PCI Bridge // PciLibAddress = PCI_LIB_ADDRESS (BusNumber, DeviceInfo->Device, DeviceInfo->Function, 0); // // Retrieve and verify the bus numbers in the PCI to PCI Bridge // BusNumber = PciRead8 (PciLibAddress + PCI_BRIDGE_SECONDARY_BUS_REGISTER_OFFSET); SubordinateBusNumber = PciRead8 (PciLibAddress + PCI_BRIDGE_SUBORDINATE_BUS_REGISTER_OFFSET); if (BusNumber == 0 || BusNumber > SubordinateBusNumber) { return 0; } // // Retrieve and verify the I/O or MMIO decode window in the PCI to PCI Bridge // if (PcdGetBool (PcdSerialUseMmio)) { MemoryLimit = PciRead16 (PciLibAddress + OFFSET_OF (PCI_TYPE01, Bridge.MemoryLimit)) & 0xfff0; MemoryBase = PciRead16 (PciLibAddress + OFFSET_OF (PCI_TYPE01, Bridge.MemoryBase)) & 0xfff0; // // If PCI Bridge MMIO window is disabled, then return 0 // if (MemoryLimit < MemoryBase) { return 0; } // // If PCI Bridge MMIO window is not in the address range decoded by the parent PCI Bridge, then return 0 // if (MemoryBase < ParentMemoryBase || MemoryBase > ParentMemoryLimit || MemoryLimit > ParentMemoryLimit) { return 0; } ParentMemoryBase = MemoryBase; ParentMemoryLimit = MemoryLimit; } else { IoLimit = PciRead8 (PciLibAddress + OFFSET_OF (PCI_TYPE01, Bridge.IoLimit)); if ((IoLimit & PCI_BRIDGE_32_BIT_IO_SPACE ) == 0) { IoLimit = IoLimit >> 4; } else { IoLimit = (PciRead16 (PciLibAddress + OFFSET_OF (PCI_TYPE01, Bridge.IoLimitUpper16)) << 4) | (IoLimit >> 4); } IoBase = PciRead8 (PciLibAddress + OFFSET_OF (PCI_TYPE01, Bridge.IoBase)); if ((IoBase & PCI_BRIDGE_32_BIT_IO_SPACE ) == 0) { IoBase = IoBase >> 4; } else { IoBase = (PciRead16 (PciLibAddress + OFFSET_OF (PCI_TYPE01, Bridge.IoBaseUpper16)) << 4) | (IoBase >> 4); } // // If PCI Bridge I/O window is disabled, then return 0 // if (IoLimit < IoBase) { return 0; } // // If PCI Bridge I/O window is not in the address range decoded by the parent PCI Bridge, then return 0 // if (IoBase < ParentIoBase || IoBase > ParentIoLimit || IoLimit > ParentIoLimit) { return 0; } ParentIoBase = IoBase; ParentIoLimit = IoLimit; } } // // Compute PCI Lib Address to PCI UART // PciLibAddress = PCI_LIB_ADDRESS (BusNumber, DeviceInfo->Device, DeviceInfo->Function, 0); // // Find the first IO or MMIO BAR // RegisterBaseMask = 0xFFFFFFF0; for (BarIndex = 0; BarIndex < PCI_MAX_BAR; BarIndex ++) { SerialRegisterBase = PciRead32 (PciLibAddress + PCI_BASE_ADDRESSREG_OFFSET + BarIndex * 4); if (PcdGetBool (PcdSerialUseMmio) && ((SerialRegisterBase & BIT0) == 0)) { // // MMIO BAR is found // RegisterBaseMask = 0xFFFFFFF0; break; } if ((!PcdGetBool (PcdSerialUseMmio)) && ((SerialRegisterBase & BIT0) != 0)) { // // IO BAR is found // RegisterBaseMask = 0xFFFFFFF8; break; } } // // MMIO or IO BAR is not found. // if (BarIndex == PCI_MAX_BAR) { return 0; } // // Program UART BAR // SerialRegisterBase = SerialPortLibUpdatePciRegister32 ( PciLibAddress + PCI_BASE_ADDRESSREG_OFFSET + BarIndex * 4, (UINT32)PcdGet64 (PcdSerialRegisterBase), RegisterBaseMask ); // // Verify that the UART BAR is in the address range decoded by the parent PCI Bridge // if (PcdGetBool (PcdSerialUseMmio)) { if (((SerialRegisterBase >> 16) & 0xfff0) < ParentMemoryBase || ((SerialRegisterBase >> 16) & 0xfff0) > ParentMemoryLimit) { return 0; } } else { if ((SerialRegisterBase >> 12) < ParentIoBase || (SerialRegisterBase >> 12) > ParentIoLimit) { return 0; } } // // Enable I/O and MMIO in PCI UART Device if they are not already enabled // PciOr16 ( PciLibAddress + PCI_COMMAND_OFFSET, PcdGetBool (PcdSerialUseMmio) ? EFI_PCI_COMMAND_MEMORY_SPACE : EFI_PCI_COMMAND_IO_SPACE ); // // Force D0 state if a Power Management and Status Register is specified // if (DeviceInfo->PowerManagementStatusAndControlRegister != 0x00) { if ((PciRead16 (PciLibAddress + DeviceInfo->PowerManagementStatusAndControlRegister) & (BIT0 | BIT1)) != 0x00) { PciAnd16 (PciLibAddress + DeviceInfo->PowerManagementStatusAndControlRegister, (UINT16)~(BIT0 | BIT1)); // // If PCI UART was not in D0, then make sure FIFOs are enabled, but do not reset FIFOs // SerialPortWriteRegister (SerialRegisterBase, FCR_OFFSET, (UINT8)(PcdGet8 (PcdSerialFifoControl) & (B_UART_FCR_FIFOE | B_UART_FCR_FIFO64))); } } // // Get PCI Device Info // DeviceInfo = (PCI_UART_DEVICE_INFO *) PcdGetPtr (PcdSerialPciDeviceInfo); // // Enable I/O or MMIO in PCI Bridge // Assume Root Bus Numer is Zero. // for (BusNumber = 0; (DeviceInfo + 1)->Device != 0xff; DeviceInfo++) { // // Compute PCI Lib Address to PCI to PCI Bridge // PciLibAddress = PCI_LIB_ADDRESS (BusNumber, DeviceInfo->Device, DeviceInfo->Function, 0); // // Enable the I/O or MMIO decode windows in the PCI to PCI Bridge // PciOr16 ( PciLibAddress + PCI_COMMAND_OFFSET, PcdGetBool (PcdSerialUseMmio) ? EFI_PCI_COMMAND_MEMORY_SPACE : EFI_PCI_COMMAND_IO_SPACE ); // // Force D0 state if a Power Management and Status Register is specified // if (DeviceInfo->PowerManagementStatusAndControlRegister != 0x00) { if ((PciRead16 (PciLibAddress + DeviceInfo->PowerManagementStatusAndControlRegister) & (BIT0 | BIT1)) != 0x00) { PciAnd16 (PciLibAddress + DeviceInfo->PowerManagementStatusAndControlRegister, (UINT16)~(BIT0 | BIT1)); } } BusNumber = PciRead8 (PciLibAddress + PCI_BRIDGE_SECONDARY_BUS_REGISTER_OFFSET); } return SerialRegisterBase; } /** GC_TODO: add routine description @param None @retval None **/ VOID InitializeSio ( VOID ) { UINT32 SioExist; UINT32 SioEnable; UINT32 Index; UINT32 Decode; UINT32 Enable; UINT32 SpiConfigValue; // // Enable LPC decode // Set COMA/COMB base // Decode = ((V_LPC_CFG_IOD_COMA_3F8 << N_LPC_CFG_IOD_COMA) | (V_LPC_CFG_IOD_COMB_2F8 << N_LPC_CFG_IOD_COMB)); SpiConfigValue = MmioRead32 (PCH_PCR_ADDRESS (PID_ESPISPI, R_PCH_PCR_SPI_CONF_VALUE)); if (SpiConfigValue & B_ESPI_ENABLE_STRAP) { Enable = ( B_LPC_CFG_IOE_ME2 | B_LPC_CFG_IOE_SE | B_LPC_CFG_IOE_ME1 \ | B_LPC_CFG_IOE_CBE | B_LPC_CFG_IOE_CAE); } else { Enable = ( B_LPC_CFG_IOE_ME2 | B_LPC_CFG_IOE_SE | B_LPC_CFG_IOE_ME1 \ | B_LPC_CFG_IOE_KE | B_LPC_CFG_IOE_CBE | B_LPC_CFG_IOE_CAE); } IoWrite32 (R_PCH_IOPORT_PCI_INDEX, (UINT32) (PCH_LPC_CF8_ADDR (R_LPC_CFG_IOD))); IoWrite32 (R_PCH_IOPORT_PCI_DATA, Decode | (Enable << 16)); MmioWrite16 (PCH_PCR_ADDRESS(PID_DMI, R_PCH_DMI_PCR_LPCIOD), (UINT16)Decode); MmioWrite16 (PCH_PCR_ADDRESS(PID_DMI, R_PCH_DMI_PCR_LPCIOE), (UINT16)Enable); SioExist = IsSioExist(); if ((SioExist & (PILOTIV_EXIST | PC8374_EXIST)) == (PILOTIV_EXIST | PC8374_EXIST) ) { // // Both are there, we use DEFAULT_SIO as debug port anyway // if (DEFAULT_SIO == PILOTIV_EXIST) { SioEnable = PILOTIV_EXIST; } else { SioEnable = PC8374_EXIST; } } else { SioEnable = SioExist; } // // ASPEED AST2500/AST2600 UART init. // if (SioEnable == ASPEED_EXIST) { // // Unlock SIO // IoWrite8 (ASPEED2500_SIO_INDEX_PORT, ASPEED2500_SIO_UNLOCK); IoWrite8 (ASPEED2500_SIO_INDEX_PORT, ASPEED2500_SIO_UNLOCK); // // COM1 & COM2 // for (Index = 0; Index < sizeof (mASPEED2500Table)/sizeof (SIO_REG_TABLE); Index++) { IoWrite8 (ASPEED2500_SIO_INDEX_PORT, mASPEED2500Table[Index].Index); IoWrite8 (ASPEED2500_SIO_DATA_PORT, mASPEED2500Table[Index].Data); } // // Lock SIO // IoWrite8 (ASPEED2500_SIO_INDEX_PORT, ASPEED2500_SIO_LOCK); } } /** Initialize Serial Port The Baud Rate Divisor registers are programmed and the LCR is used to configure the communications format. Hard coded UART config comes from globals in DebugSerialPlatform lib. @param None @retval None **/ RETURN_STATUS EFIAPI SerialPortInitialize ( VOID ) { UINTN Divisor; UINT8 OutputData; UINT8 Data; UINT16 ComBase; ComBase = (UINT16)PcdGet64 (PcdSerialRegisterBase); InitializeSio(); // // Some init is done by the platform status code initialization. // // // Map 5..8 to 0..3 // Data = (UINT8) (gData - (UINT8) 5); // // Calculate divisor for baud generator // Divisor = 115200 / PcdGet32(PcdSerialBaudRate); // // Set communications format // OutputData = (UINT8) ((DLAB << 7) | ((gBreakSet << 6) | ((gParity << 3) | ((gStop << 2) | Data)))); IoWrite8 (ComBase + LCR_OFFSET, OutputData); // // Configure baud rate // IoWrite8 (ComBase + BAUD_HIGH_OFFSET, (UINT8) (Divisor >> 8)); IoWrite8 (ComBase + BAUD_LOW_OFFSET, (UINT8) (Divisor & 0xff)); // // Switch back to bank 0 // OutputData = (UINT8) ((~DLAB << 7) | ((gBreakSet << 6) | ((gParity << 3) | ((gStop << 2) | Data)))); IoWrite8 (ComBase + LCR_OFFSET, OutputData); return RETURN_SUCCESS; } /** Write data to serial device. If the buffer is NULL, then return 0; if NumberOfBytes is zero, then return 0. @param Buffer Point of data buffer which need to be writed. @param NumberOfBytes Number of output bytes which are cached in Buffer. @retval 0 Write data failed. @retval !0 Actual number of bytes writed to serial device. **/ UINTN EFIAPI SerialPortWrite ( IN UINT8 *Buffer, IN UINTN NumberOfBytes ) { UINTN Result; UINT8 Data; if ((IsSerialPortEnabled() == FALSE) || (NULL == Buffer)) { return 0; } Result = NumberOfBytes; while (NumberOfBytes--) { // // Wait for the serail port to be ready. // do { Data = IoRead8 ((UINT16) PcdGet64 (PcdSerialRegisterBase) + LSR_OFFSET); } while ((Data & LSR_TXRDY) == 0); IoWrite8 ((UINT16) PcdGet64 (PcdSerialRegisterBase), *Buffer++); } return Result; } /* Read data from serial device and save the datas in buffer. If the buffer is NULL, then return 0; if NumberOfBytes is zero, then return 0. @param Buffer Point of data buffer which need to be writed. @param NumberOfBytes Number of output bytes which are cached in Buffer. @retval 0 Read data failed. @retval !0 Actual number of bytes raed to serial device. **/ UINTN EFIAPI SerialPortRead ( OUT UINT8 *Buffer, IN UINTN NumberOfBytes ) { UINTN Result; UINT8 Data; if ((IsSerialPortEnabled() == FALSE) || (NULL == Buffer)) { return 0; } Result = NumberOfBytes; while (NumberOfBytes--) { // // Wait for the serail port to be ready. // do { Data = IoRead8 ((UINT16) PcdGet64 (PcdSerialRegisterBase) + LSR_OFFSET); } while ((Data & LSR_RXDA) == 0); *Buffer++ = IoRead8 ((UINT16) PcdGet64 (PcdSerialRegisterBase)); } return Result; } /** Polls a serial device to see if there is any data waiting to be read. Polls a serial device to see if there is any data waiting to be read. If there is data waiting to be read from the serial device, then TRUE is returned. If there is no data waiting to be read from the serial device, then FALSE is returned. @retval TRUE Data is waiting to be read from the serial device. @retval FALSE There is no data waiting to be read from the serial device. **/ BOOLEAN EFIAPI SerialPortPoll ( VOID ) { UINTN SerialRegisterBase; SerialRegisterBase = GetSerialRegisterBase (); if (SerialRegisterBase ==0) { return FALSE; } // // Read the serial port status // if ((SerialPortReadRegister (SerialRegisterBase, R_UART_LSR) & B_UART_LSR_RXRDY) != 0) { if (PcdGetBool (PcdSerialUseHardwareFlowControl)) { // // Clear RTS to prevent peer from sending data // SerialPortWriteRegister (SerialRegisterBase, R_UART_MCR, (UINT8)(SerialPortReadRegister (SerialRegisterBase, R_UART_MCR) & ~B_UART_MCR_RTS)); } return TRUE; } if (PcdGetBool (PcdSerialUseHardwareFlowControl)) { // // Set RTS to let the peer send some data // SerialPortWriteRegister (SerialRegisterBase, R_UART_MCR, (UINT8)(SerialPortReadRegister (SerialRegisterBase, R_UART_MCR) | B_UART_MCR_RTS)); } return FALSE; } /** Sets the control bits on a serial device. @param Control Sets the bits of Control that are settable. @retval RETURN_SUCCESS The new control bits were set on the serial device. @retval RETURN_UNSUPPORTED The serial device does not support this operation. @retval RETURN_DEVICE_ERROR The serial device is not functioning correctly. **/ RETURN_STATUS EFIAPI SerialPortSetControl ( IN UINT32 Control ) { UINTN SerialRegisterBase; UINT8 Mcr; // // First determine the parameter is invalid. // if ((Control & (~(EFI_SERIAL_REQUEST_TO_SEND | EFI_SERIAL_DATA_TERMINAL_READY | EFI_SERIAL_HARDWARE_FLOW_CONTROL_ENABLE))) != 0) { return RETURN_UNSUPPORTED; } SerialRegisterBase = GetSerialRegisterBase (); if (SerialRegisterBase ==0) { return RETURN_UNSUPPORTED; } // // Read the Modem Control Register. // Mcr = SerialPortReadRegister (SerialRegisterBase, R_UART_MCR); Mcr &= (~(B_UART_MCR_DTRC | B_UART_MCR_RTS)); if ((Control & EFI_SERIAL_DATA_TERMINAL_READY) == EFI_SERIAL_DATA_TERMINAL_READY) { Mcr |= B_UART_MCR_DTRC; } if ((Control & EFI_SERIAL_REQUEST_TO_SEND) == EFI_SERIAL_REQUEST_TO_SEND) { Mcr |= B_UART_MCR_RTS; } // // Write the Modem Control Register. // SerialPortWriteRegister (SerialRegisterBase, R_UART_MCR, Mcr); return RETURN_SUCCESS; } /** Retrieve the status of the control bits on a serial device. @param Control A pointer to return the current control signals from the serial device. @retval RETURN_SUCCESS The control bits were read from the serial device. @retval RETURN_UNSUPPORTED The serial device does not support this operation. @retval RETURN_DEVICE_ERROR The serial device is not functioning correctly. **/ RETURN_STATUS EFIAPI SerialPortGetControl ( OUT UINT32 *Control ) { UINTN SerialRegisterBase; UINT8 Msr; UINT8 Mcr; UINT8 Lsr; SerialRegisterBase = GetSerialRegisterBase (); if (SerialRegisterBase ==0) { return RETURN_UNSUPPORTED; } *Control = 0; // // Read the Modem Status Register. // Msr = SerialPortReadRegister (SerialRegisterBase, R_UART_MSR); if ((Msr & B_UART_MSR_CTS) == B_UART_MSR_CTS) { *Control |= EFI_SERIAL_CLEAR_TO_SEND; } if ((Msr & B_UART_MSR_DSR) == B_UART_MSR_DSR) { *Control |= EFI_SERIAL_DATA_SET_READY; } if ((Msr & B_UART_MSR_RI) == B_UART_MSR_RI) { *Control |= EFI_SERIAL_RING_INDICATE; } if ((Msr & B_UART_MSR_DCD) == B_UART_MSR_DCD) { *Control |= EFI_SERIAL_CARRIER_DETECT; } // // Read the Modem Control Register. // Mcr = SerialPortReadRegister (SerialRegisterBase, R_UART_MCR); if ((Mcr & B_UART_MCR_DTRC) == B_UART_MCR_DTRC) { *Control |= EFI_SERIAL_DATA_TERMINAL_READY; } if ((Mcr & B_UART_MCR_RTS) == B_UART_MCR_RTS) { *Control |= EFI_SERIAL_REQUEST_TO_SEND; } if (PcdGetBool (PcdSerialUseHardwareFlowControl)) { *Control |= EFI_SERIAL_HARDWARE_FLOW_CONTROL_ENABLE; } // // Read the Line Status Register. // Lsr = SerialPortReadRegister (SerialRegisterBase, R_UART_LSR); if ((Lsr & (B_UART_LSR_TEMT | B_UART_LSR_TXRDY)) == (B_UART_LSR_TEMT | B_UART_LSR_TXRDY)) { *Control |= EFI_SERIAL_OUTPUT_BUFFER_EMPTY; } if ((Lsr & B_UART_LSR_RXRDY) == 0) { *Control |= EFI_SERIAL_INPUT_BUFFER_EMPTY; } return RETURN_SUCCESS; } /** Sets the baud rate, receive FIFO depth, transmit/receice time out, parity, data bits, and stop bits on a serial device. @param BaudRate The requested baud rate. A BaudRate value of 0 will use the device's default interface speed. On output, the value actually set. @param ReveiveFifoDepth The requested depth of the FIFO on the receive side of the serial interface. A ReceiveFifoDepth value of 0 will use the device's default FIFO depth. On output, the value actually set. @param Timeout The requested time out for a single character in microseconds. This timeout applies to both the transmit and receive side of the interface. A Timeout value of 0 will use the device's default time out value. On output, the value actually set. @param Parity The type of parity to use on this serial device. A Parity value of DefaultParity will use the device's default parity value. On output, the value actually set. @param DataBits The number of data bits to use on the serial device. A DataBits vaule of 0 will use the device's default data bit setting. On output, the value actually set. @param StopBits The number of stop bits to use on this serial device. A StopBits value of DefaultStopBits will use the device's default number of stop bits. On output, the value actually set. @retval RETURN_SUCCESS The new attributes were set on the serial device. @retval RETURN_UNSUPPORTED The serial device does not support this operation. @retval RETURN_INVALID_PARAMETER One or more of the attributes has an unsupported value. @retval RETURN_DEVICE_ERROR The serial device is not functioning correctly. **/ RETURN_STATUS EFIAPI SerialPortSetAttributes ( IN OUT UINT64 *BaudRate, IN OUT UINT32 *ReceiveFifoDepth, IN OUT UINT32 *Timeout, IN OUT EFI_PARITY_TYPE *Parity, IN OUT UINT8 *DataBits, IN OUT EFI_STOP_BITS_TYPE *StopBits ) { UINTN SerialRegisterBase; UINT32 SerialBaudRate; UINTN Divisor; UINT8 Lcr; UINT8 LcrData; UINT8 LcrParity; UINT8 LcrStop; SerialRegisterBase = GetSerialRegisterBase (); if (SerialRegisterBase ==0) { return RETURN_UNSUPPORTED; } // // Check for default settings and fill in actual values. // if (*BaudRate == 0) { *BaudRate = PcdGet32 (PcdSerialBaudRate); } SerialBaudRate = (UINT32) *BaudRate; if (*DataBits == 0) { LcrData = (UINT8) (PcdGet8 (PcdSerialLineControl) & 0x3); *DataBits = LcrData + 5; } else { if ((*DataBits < 5) || (*DataBits > 8)) { return RETURN_INVALID_PARAMETER; } // // Map 5..8 to 0..3 // LcrData = (UINT8) (*DataBits - (UINT8) 5); } if (*Parity == DefaultParity) { LcrParity = (UINT8) ((PcdGet8 (PcdSerialLineControl) >> 3) & 0x7); switch (LcrParity) { case 0: *Parity = NoParity; break; case 3: *Parity = EvenParity; break; case 1: *Parity = OddParity; break; case 7: *Parity = SpaceParity; break; case 5: *Parity = MarkParity; break; default: break; } } else { switch (*Parity) { case NoParity: LcrParity = 0; break; case EvenParity: LcrParity = 3; break; case OddParity: LcrParity = 1; break; case SpaceParity: LcrParity = 7; break; case MarkParity: LcrParity = 5; break; default: return RETURN_INVALID_PARAMETER; } } if (*StopBits == DefaultStopBits) { LcrStop = (UINT8) ((PcdGet8 (PcdSerialLineControl) >> 2) & 0x1); switch (LcrStop) { case 0: *StopBits = OneStopBit; break; case 1: if (*DataBits == 5) { *StopBits = OneFiveStopBits; } else { *StopBits = TwoStopBits; } break; default: break; } } else { switch (*StopBits) { case OneStopBit: LcrStop = 0; break; case OneFiveStopBits: case TwoStopBits: LcrStop = 1; break; default: return RETURN_INVALID_PARAMETER; } } // // Calculate divisor for baud generator // Ref_Clk_Rate / Baud_Rate / 16 // Divisor = PcdGet32 (PcdSerialClockRate) / (SerialBaudRate * 16); if ((PcdGet32 (PcdSerialClockRate) % (SerialBaudRate * 16)) >= SerialBaudRate * 8) { Divisor++; } // // Configure baud rate // SerialPortWriteRegister (SerialRegisterBase, R_UART_LCR, B_UART_LCR_DLAB); SerialPortWriteRegister (SerialRegisterBase, R_UART_BAUD_HIGH, (UINT8) (Divisor >> 8)); SerialPortWriteRegister (SerialRegisterBase, R_UART_BAUD_LOW, (UINT8) (Divisor & 0xff)); // // Clear DLAB and configure Data Bits, Parity, and Stop Bits. // Strip reserved bits from line control value // Lcr = (UINT8) ((LcrParity << 3) | (LcrStop << 2) | LcrData); SerialPortWriteRegister (SerialRegisterBase, R_UART_LCR, (UINT8) (Lcr & 0x3F)); return RETURN_SUCCESS; }