linux/drivers/usb/serial/io_16654.h

// SPDX-License-Identifier: GPL-2.0+
/************************************************************************
 *
 *	16654.H		Definitions for 16C654 UART used on EdgePorts
 *
 *	Copyright (C) 1998 Inside Out Networks, Inc.
 *
 ************************************************************************/

#if !defined(_16654_H)
#define	_16654_H

/************************************************************************
 *
 *			D e f i n e s   /   T y p e d e f s
 *
 ************************************************************************/

	//
	// UART register numbers
	// Numbers 0-7 are passed to the Edgeport directly. Numbers 8 and
	// above are used internally to indicate that we must enable access
	// to them via LCR bit 0x80 or LCR = 0xBF.
	// The register number sent to the Edgeport is then (x & 0x7).
	//
	// Driver must not access registers that affect operation of the
	// the EdgePort firmware -- that includes THR, RHR, IER, FCR.


#define THR			0	// ! Transmit Holding Register (Write)
#define RDR			0	// ! Receive Holding Register (Read)
#define IER			1	// ! Interrupt Enable Register
#define FCR			2	// ! Fifo Control Register (Write)
#define ISR			2	// Interrupt Status Register (Read)
#define LCR			3	// Line Control Register
#define MCR			4	// Modem Control Register
#define LSR			5	// Line Status Register
#define MSR			6	// Modem Status Register
#define SPR			7	// ScratchPad Register
#define DLL			8	// Bank2[ 0 ] Divisor Latch LSB
#define DLM			9	// Bank2[ 1 ] Divisor Latch MSB
#define EFR			10	// Bank2[ 2 ] Extended Function Register
//efine unused			11	// Bank2[ 3 ]
#define XON1			12	// Bank2[ 4 ] Xon-1
#define XON2			13	// Bank2[ 5 ] Xon-2
#define XOFF1			14	// Bank2[ 6 ] Xoff-1
#define XOFF2			15	// Bank2[ 7 ] Xoff-2

#define	NUM_16654_REGS		16

#define IS_REG_2ND_BANK(x)	((x) >= 8)

	//
	// Bit definitions for each register
	//

#define IER_RX			0x01	// Enable receive interrupt
#define IER_TX			0x02	// Enable transmit interrupt
#define IER_RXS			0x04	// Enable receive status interrupt
#define IER_MDM			0x08	// Enable modem status interrupt
#define IER_SLEEP		0x10	// Enable sleep mode
#define IER_XOFF		0x20	// Enable s/w flow control (XOFF) interrupt
#define IER_RTS			0x40	// Enable RTS interrupt
#define IER_CTS			0x80	// Enable CTS interrupt
#define IER_ENABLE_ALL		0xFF	// Enable all ints


#define FCR_FIFO_EN		0x01	// Enable FIFOs
#define FCR_RXCLR		0x02	// Reset Rx FIFO
#define FCR_TXCLR		0x04	// Reset Tx FIFO
#define FCR_DMA_BLK		0x08	// Enable DMA block mode
#define FCR_TX_LEVEL_MASK	0x30	// Mask for Tx FIFO Level
#define FCR_TX_LEVEL_8		0x00	// Tx FIFO Level =  8 bytes
#define FCR_TX_LEVEL_16		0x10	// Tx FIFO Level = 16 bytes
#define FCR_TX_LEVEL_32		0x20	// Tx FIFO Level = 32 bytes
#define FCR_TX_LEVEL_56		0x30	// Tx FIFO Level = 56 bytes
#define FCR_RX_LEVEL_MASK	0xC0	// Mask for Rx FIFO Level
#define FCR_RX_LEVEL_8		0x00	// Rx FIFO Level =  8 bytes
#define FCR_RX_LEVEL_16		0x40	// Rx FIFO Level = 16 bytes
#define FCR_RX_LEVEL_56		0x80	// Rx FIFO Level = 56 bytes
#define FCR_RX_LEVEL_60		0xC0	// Rx FIFO Level = 60 bytes


#define ISR_INT_MDM_STATUS	0x00	// Modem status int pending
#define ISR_INT_NONE		0x01	// No interrupt pending
#define ISR_INT_TXRDY		0x02	// Tx ready int pending
#define ISR_INT_RXRDY		0x04	// Rx ready int pending
#define ISR_INT_LINE_STATUS	0x06	// Line status int pending
#define ISR_INT_RX_TIMEOUT	0x0C	// Rx timeout int pending
#define ISR_INT_RX_XOFF		0x10	// Rx Xoff int pending
#define ISR_INT_RTS_CTS		0x20	// RTS/CTS change int pending
#define ISR_FIFO_ENABLED	0xC0	// Bits set if FIFOs enabled
#define ISR_INT_BITS_MASK	0x3E	// Mask to isolate valid int causes


#define LCR_BITS_5		0x00	// 5 bits/char
#define LCR_BITS_6		0x01	// 6 bits/char
#define LCR_BITS_7		0x02	// 7 bits/char
#define LCR_BITS_8		0x03	// 8 bits/char
#define LCR_BITS_MASK		0x03	// Mask for bits/char field

#define LCR_STOP_1		0x00	// 1 stop bit
#define LCR_STOP_1_5		0x04	// 1.5 stop bits (if 5   bits/char)
#define LCR_STOP_2		0x04	// 2 stop bits   (if 6-8 bits/char)
#define LCR_STOP_MASK		0x04	// Mask for stop bits field

#define LCR_PAR_NONE		0x00	// No parity
#define LCR_PAR_ODD		0x08	// Odd parity
#define LCR_PAR_EVEN		0x18	// Even parity
#define LCR_PAR_MARK		0x28	// Force parity bit to 1
#define LCR_PAR_SPACE		0x38	// Force parity bit to 0
#define LCR_PAR_MASK		0x38	// Mask for parity field

#define LCR_SET_BREAK		0x40	// Set Break condition
#define LCR_DL_ENABLE		0x80	// Enable access to divisor latch

#define LCR_ACCESS_EFR		0xBF	// Load this value to access DLL,DLM,
					// and also the '654-only registers
					// EFR, XON1, XON2, XOFF1, XOFF2


#define MCR_DTR			0x01	// Assert DTR
#define MCR_RTS			0x02	// Assert RTS
#define MCR_OUT1		0x04	// Loopback only: Sets state of RI
#define MCR_MASTER_IE		0x08	// Enable interrupt outputs
#define MCR_LOOPBACK		0x10	// Set internal (digital) loopback mode
#define MCR_XON_ANY		0x20	// Enable any char to exit XOFF mode
#define MCR_IR_ENABLE		0x40	// Enable IrDA functions
#define MCR_BRG_DIV_4		0x80	// Divide baud rate clk by /4 instead of /1


#define LSR_RX_AVAIL		0x01	// Rx data available
#define LSR_OVER_ERR		0x02	// Rx overrun
#define LSR_PAR_ERR		0x04	// Rx parity error
#define LSR_FRM_ERR		0x08	// Rx framing error
#define LSR_BREAK		0x10	// Rx break condition detected
#define LSR_TX_EMPTY		0x20	// Tx Fifo empty
#define LSR_TX_ALL_EMPTY	0x40	// Tx Fifo and shift register empty
#define LSR_FIFO_ERR		0x80	// Rx Fifo contains at least 1 erred char


#define EDGEPORT_MSR_DELTA_CTS	0x01	// CTS changed from last read
#define EDGEPORT_MSR_DELTA_DSR	0x02	// DSR changed from last read
#define EDGEPORT_MSR_DELTA_RI	0x04	// RI  changed from 0 -> 1
#define EDGEPORT_MSR_DELTA_CD	0x08	// CD  changed from last read
#define EDGEPORT_MSR_CTS	0x10	// Current state of CTS
#define EDGEPORT_MSR_DSR	0x20	// Current state of DSR
#define EDGEPORT_MSR_RI		0x40	// Current state of RI
#define EDGEPORT_MSR_CD		0x80	// Current state of CD


					//	Tx		Rx
					//-------------------------------
#define EFR_SWFC_NONE		0x00	//	None		None
#define EFR_SWFC_RX1		0x02 	//	None		XOFF1
#define EFR_SWFC_RX2		0x01 	//	None		XOFF2
#define EFR_SWFC_RX12		0x03 	//	None		XOFF1 & XOFF2
#define EFR_SWFC_TX1		0x08 	//	XOFF1		None
#define EFR_SWFC_TX1_RX1	0x0a 	//	XOFF1		XOFF1
#define EFR_SWFC_TX1_RX2	0x09 	//	XOFF1		XOFF2
#define EFR_SWFC_TX1_RX12	0x0b 	//	XOFF1		XOFF1 & XOFF2
#define EFR_SWFC_TX2		0x04 	//	XOFF2		None
#define EFR_SWFC_TX2_RX1	0x06 	//	XOFF2		XOFF1
#define EFR_SWFC_TX2_RX2	0x05 	//	XOFF2		XOFF2
#define EFR_SWFC_TX2_RX12	0x07 	//	XOFF2		XOFF1 & XOFF2
#define EFR_SWFC_TX12		0x0c 	//	XOFF1 & XOFF2	None
#define EFR_SWFC_TX12_RX1	0x0e 	//	XOFF1 & XOFF2	XOFF1
#define EFR_SWFC_TX12_RX2	0x0d 	//	XOFF1 & XOFF2	XOFF2
#define EFR_SWFC_TX12_RX12	0x0f 	//	XOFF1 & XOFF2	XOFF1 & XOFF2

#define EFR_TX_FC_MASK		0x0c	// Mask to isolate Rx flow control
#define EFR_TX_FC_NONE		0x00	// No Tx Xon/Xoff flow control
#define EFR_TX_FC_X1		0x08	// Transmit Xon1/Xoff1
#define EFR_TX_FC_X2		0x04	// Transmit Xon2/Xoff2
#define EFR_TX_FC_X1_2		0x0c	// Transmit Xon1&2/Xoff1&2

#define EFR_RX_FC_MASK		0x03	// Mask to isolate Rx flow control
#define EFR_RX_FC_NONE		0x00	// No Rx Xon/Xoff flow control
#define EFR_RX_FC_X1		0x02	// Receiver compares Xon1/Xoff1
#define EFR_RX_FC_X2		0x01	// Receiver compares Xon2/Xoff2
#define EFR_RX_FC_X1_2		0x03	// Receiver compares Xon1&2/Xoff1&2


#define EFR_SWFC_MASK		0x0F	// Mask for software flow control field
#define EFR_ENABLE_16654	0x10	// Enable 16C654 features
#define EFR_SPEC_DETECT		0x20	// Enable special character detect interrupt
#define EFR_AUTO_RTS		0x40	// Use RTS for Rx flow control
#define EFR_AUTO_CTS		0x80	// Use CTS for Tx flow control

#endif	// if !defined(_16654_H)
USB: add SPDX identifiers to all remaining files in drivers/usb/ It's good to have SPDX identifiers in all files to make it easier to audit the kernel tree for correct licenses. Update the drivers/usb/ and include/linux/usb* files with the correct SPDX license identifier based on the license text in the file itself. The SPDX identifier is a legally binding shorthand, which can be used instead of the full boiler plate text. This work is based on a script and data from Thomas Gleixner, Philippe Ombredanne, and Kate Stewart. Cc: Thomas Gleixner <tglx@linutronix.de> Cc: Kate Stewart <kstewart@linuxfoundation.org> Cc: Philippe Ombredanne <pombredanne@nexb.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org> Acked-by: Felipe Balbi <felipe.balbi@linux.intel.com> Acked-by: Johan Hovold <johan@kernel.org> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org> 2017-11-03 13:28:30 +03:00			`// SPDX-License-Identifier: GPL-2.0+`
Linux-2.6.12-rc2 Initial git repository build. I'm not bothering with the full history, even though we have it. We can create a separate "historical" git archive of that later if we want to, and in the meantime it's about 3.2GB when imported into git - space that would just make the early git days unnecessarily complicated, when we don't have a lot of good infrastructure for it. Let it rip! 2005-04-17 02:20:36 +04:00			`/************************************************************************`
			`*`
			`* 16654.H Definitions for 16C654 UART used on EdgePorts`
			`*`
			`* Copyright (C) 1998 Inside Out Networks, Inc.`
			`*`
			`************************************************************************/`

			`#if !defined(_16654_H)`
			`#define _16654_H`

			`/************************************************************************`
			`*`
			`* D e f i n e s / T y p e d e f s`
			`*`
			`************************************************************************/`

			`//`
			`// UART register numbers`
			`// Numbers 0-7 are passed to the Edgeport directly. Numbers 8 and`
			`// above are used internally to indicate that we must enable access`
			`// to them via LCR bit 0x80 or LCR = 0xBF.`
			`// The register number sent to the Edgeport is then (x & 0x7).`
			`//`
			`// Driver must not access registers that affect operation of the`
			`// the EdgePort firmware -- that includes THR, RHR, IER, FCR.`


			`#define THR 0 // ! Transmit Holding Register (Write)`
			`#define RDR 0 // ! Receive Holding Register (Read)`
			`#define IER 1 // ! Interrupt Enable Register`
			`#define FCR 2 // ! Fifo Control Register (Write)`
			`#define ISR 2 // Interrupt Status Register (Read)`
			`#define LCR 3 // Line Control Register`
			`#define MCR 4 // Modem Control Register`
			`#define LSR 5 // Line Status Register`
			`#define MSR 6 // Modem Status Register`
			`#define SPR 7 // ScratchPad Register`
			`#define DLL 8 // Bank2[ 0 ] Divisor Latch LSB`
			`#define DLM 9 // Bank2[ 1 ] Divisor Latch MSB`
			`#define EFR 10 // Bank2[ 2 ] Extended Function Register`
			`//efine unused 11 // Bank2[ 3 ]`
			`#define XON1 12 // Bank2[ 4 ] Xon-1`
			`#define XON2 13 // Bank2[ 5 ] Xon-2`
			`#define XOFF1 14 // Bank2[ 6 ] Xoff-1`
			`#define XOFF2 15 // Bank2[ 7 ] Xoff-2`

			`#define NUM_16654_REGS 16`

			`#define IS_REG_2ND_BANK(x) ((x) >= 8)`

			`//`
			`// Bit definitions for each register`
			`//`

			`#define IER_RX 0x01 // Enable receive interrupt`
			`#define IER_TX 0x02 // Enable transmit interrupt`
			`#define IER_RXS 0x04 // Enable receive status interrupt`
			`#define IER_MDM 0x08 // Enable modem status interrupt`
			`#define IER_SLEEP 0x10 // Enable sleep mode`
			`#define IER_XOFF 0x20 // Enable s/w flow control (XOFF) interrupt`
			`#define IER_RTS 0x40 // Enable RTS interrupt`
			`#define IER_CTS 0x80 // Enable CTS interrupt`
			`#define IER_ENABLE_ALL 0xFF // Enable all ints`


			`#define FCR_FIFO_EN 0x01 // Enable FIFOs`
			`#define FCR_RXCLR 0x02 // Reset Rx FIFO`
			`#define FCR_TXCLR 0x04 // Reset Tx FIFO`
			`#define FCR_DMA_BLK 0x08 // Enable DMA block mode`
			`#define FCR_TX_LEVEL_MASK 0x30 // Mask for Tx FIFO Level`
			`#define FCR_TX_LEVEL_8 0x00 // Tx FIFO Level = 8 bytes`
			`#define FCR_TX_LEVEL_16 0x10 // Tx FIFO Level = 16 bytes`
			`#define FCR_TX_LEVEL_32 0x20 // Tx FIFO Level = 32 bytes`
			`#define FCR_TX_LEVEL_56 0x30 // Tx FIFO Level = 56 bytes`
			`#define FCR_RX_LEVEL_MASK 0xC0 // Mask for Rx FIFO Level`
			`#define FCR_RX_LEVEL_8 0x00 // Rx FIFO Level = 8 bytes`
			`#define FCR_RX_LEVEL_16 0x40 // Rx FIFO Level = 16 bytes`
			`#define FCR_RX_LEVEL_56 0x80 // Rx FIFO Level = 56 bytes`
			`#define FCR_RX_LEVEL_60 0xC0 // Rx FIFO Level = 60 bytes`


			`#define ISR_INT_MDM_STATUS 0x00 // Modem status int pending`
			`#define ISR_INT_NONE 0x01 // No interrupt pending`
			`#define ISR_INT_TXRDY 0x02 // Tx ready int pending`
			`#define ISR_INT_RXRDY 0x04 // Rx ready int pending`
			`#define ISR_INT_LINE_STATUS 0x06 // Line status int pending`
			`#define ISR_INT_RX_TIMEOUT 0x0C // Rx timeout int pending`
			`#define ISR_INT_RX_XOFF 0x10 // Rx Xoff int pending`
			`#define ISR_INT_RTS_CTS 0x20 // RTS/CTS change int pending`
			`#define ISR_FIFO_ENABLED 0xC0 // Bits set if FIFOs enabled`
			`#define ISR_INT_BITS_MASK 0x3E // Mask to isolate valid int causes`


			`#define LCR_BITS_5 0x00 // 5 bits/char`
			`#define LCR_BITS_6 0x01 // 6 bits/char`
			`#define LCR_BITS_7 0x02 // 7 bits/char`
			`#define LCR_BITS_8 0x03 // 8 bits/char`
			`#define LCR_BITS_MASK 0x03 // Mask for bits/char field`

			`#define LCR_STOP_1 0x00 // 1 stop bit`
			`#define LCR_STOP_1_5 0x04 // 1.5 stop bits (if 5 bits/char)`
			`#define LCR_STOP_2 0x04 // 2 stop bits (if 6-8 bits/char)`
			`#define LCR_STOP_MASK 0x04 // Mask for stop bits field`

			`#define LCR_PAR_NONE 0x00 // No parity`
			`#define LCR_PAR_ODD 0x08 // Odd parity`
			`#define LCR_PAR_EVEN 0x18 // Even parity`
			`#define LCR_PAR_MARK 0x28 // Force parity bit to 1`
			`#define LCR_PAR_SPACE 0x38 // Force parity bit to 0`
			`#define LCR_PAR_MASK 0x38 // Mask for parity field`

			`#define LCR_SET_BREAK 0x40 // Set Break condition`
			`#define LCR_DL_ENABLE 0x80 // Enable access to divisor latch`

			`#define LCR_ACCESS_EFR 0xBF // Load this value to access DLL,DLM,`
			`// and also the '654-only registers`
			`// EFR, XON1, XON2, XOFF1, XOFF2`


			`#define MCR_DTR 0x01 // Assert DTR`
			`#define MCR_RTS 0x02 // Assert RTS`
			`#define MCR_OUT1 0x04 // Loopback only: Sets state of RI`
			`#define MCR_MASTER_IE 0x08 // Enable interrupt outputs`
			`#define MCR_LOOPBACK 0x10 // Set internal (digital) loopback mode`
			`#define MCR_XON_ANY 0x20 // Enable any char to exit XOFF mode`
			`#define MCR_IR_ENABLE 0x40 // Enable IrDA functions`
			`#define MCR_BRG_DIV_4 0x80 // Divide baud rate clk by /4 instead of /1`


			`#define LSR_RX_AVAIL 0x01 // Rx data available`
			`#define LSR_OVER_ERR 0x02 // Rx overrun`
			`#define LSR_PAR_ERR 0x04 // Rx parity error`
			`#define LSR_FRM_ERR 0x08 // Rx framing error`
			`#define LSR_BREAK 0x10 // Rx break condition detected`
			`#define LSR_TX_EMPTY 0x20 // Tx Fifo empty`
			`#define LSR_TX_ALL_EMPTY 0x40 // Tx Fifo and shift register empty`
			`#define LSR_FIFO_ERR 0x80 // Rx Fifo contains at least 1 erred char`


			`#define EDGEPORT_MSR_DELTA_CTS 0x01 // CTS changed from last read`
			`#define EDGEPORT_MSR_DELTA_DSR 0x02 // DSR changed from last read`
			`#define EDGEPORT_MSR_DELTA_RI 0x04 // RI changed from 0 -> 1`
			`#define EDGEPORT_MSR_DELTA_CD 0x08 // CD changed from last read`
			`#define EDGEPORT_MSR_CTS 0x10 // Current state of CTS`
			`#define EDGEPORT_MSR_DSR 0x20 // Current state of DSR`
			`#define EDGEPORT_MSR_RI 0x40 // Current state of RI`
			`#define EDGEPORT_MSR_CD 0x80 // Current state of CD`



			`// Tx Rx`
			`//-------------------------------`
			`#define EFR_SWFC_NONE 0x00 // None None`
			`#define EFR_SWFC_RX1 0x02 // None XOFF1`
			`#define EFR_SWFC_RX2 0x01 // None XOFF2`
			`#define EFR_SWFC_RX12 0x03 // None XOFF1 & XOFF2`
			`#define EFR_SWFC_TX1 0x08 // XOFF1 None`
			`#define EFR_SWFC_TX1_RX1 0x0a // XOFF1 XOFF1`
			`#define EFR_SWFC_TX1_RX2 0x09 // XOFF1 XOFF2`
			`#define EFR_SWFC_TX1_RX12 0x0b // XOFF1 XOFF1 & XOFF2`
			`#define EFR_SWFC_TX2 0x04 // XOFF2 None`
			`#define EFR_SWFC_TX2_RX1 0x06 // XOFF2 XOFF1`
			`#define EFR_SWFC_TX2_RX2 0x05 // XOFF2 XOFF2`
			`#define EFR_SWFC_TX2_RX12 0x07 // XOFF2 XOFF1 & XOFF2`
			`#define EFR_SWFC_TX12 0x0c // XOFF1 & XOFF2 None`
			`#define EFR_SWFC_TX12_RX1 0x0e // XOFF1 & XOFF2 XOFF1`
			`#define EFR_SWFC_TX12_RX2 0x0d // XOFF1 & XOFF2 XOFF2`
			`#define EFR_SWFC_TX12_RX12 0x0f // XOFF1 & XOFF2 XOFF1 & XOFF2`

			`#define EFR_TX_FC_MASK 0x0c // Mask to isolate Rx flow control`
			`#define EFR_TX_FC_NONE 0x00 // No Tx Xon/Xoff flow control`
			`#define EFR_TX_FC_X1 0x08 // Transmit Xon1/Xoff1`
			`#define EFR_TX_FC_X2 0x04 // Transmit Xon2/Xoff2`
			`#define EFR_TX_FC_X1_2 0x0c // Transmit Xon1&2/Xoff1&2`

			`#define EFR_RX_FC_MASK 0x03 // Mask to isolate Rx flow control`
			`#define EFR_RX_FC_NONE 0x00 // No Rx Xon/Xoff flow control`
			`#define EFR_RX_FC_X1 0x02 // Receiver compares Xon1/Xoff1`
			`#define EFR_RX_FC_X2 0x01 // Receiver compares Xon2/Xoff2`
			`#define EFR_RX_FC_X1_2 0x03 // Receiver compares Xon1&2/Xoff1&2`


			`#define EFR_SWFC_MASK 0x0F // Mask for software flow control field`
			`#define EFR_ENABLE_16654 0x10 // Enable 16C654 features`
			`#define EFR_SPEC_DETECT 0x20 // Enable special character detect interrupt`
			`#define EFR_AUTO_RTS 0x40 // Use RTS for Rx flow control`
			`#define EFR_AUTO_CTS 0x80 // Use CTS for Tx flow control`

			`#endif // if !defined(_16654_H)`