drivers/net/eexpress.h - linux/kernel/git/torvalds/linux - Git at Google

 /*
  * eexpress.h: Intel EtherExpress16 defines
  */

 /*
  * EtherExpress card register addresses
  * as offsets from the base IO region (dev->base_addr)
  */

 #define DATAPORT      0x0000
 #define WRITE_PTR     0x0002
 #define READ_PTR      0x0004
 #define SIGNAL_CA     0x0006
 #define SET_IRQ       0x0007
 #define SM_PTR        0x0008
 #define	MEM_Dec	      0x000a
 #define MEM_Ctrl      0x000b
 #define MEM_Page_Ctrl 0x000c
 #define Config        0x000d
 #define EEPROM_Ctrl   0x000e
 #define ID_PORT       0x000f
 #define	MEM_ECtrl     0x000f

 /*
  * card register defines
  */

 /* SET_IRQ */
 #define SIRQ_en       0x08
 #define SIRQ_dis      0x00

 /* EEPROM_Ctrl */
 #define EC_Clk        0x01
 #define EC_CS         0x02
 #define EC_Wr         0x04
 #define EC_Rd         0x08
 #define ASIC_RST      0x40
 #define i586_RST      0x80

 #define eeprom_delay() { udelay(40); }

 /*
  * i82586 Memory Configuration
  */

 /* (System Configuration Pointer) System start up block, read after 586_RST */
 #define SCP_START 0xfff6

 /* Intermediate System Configuration Pointer */
 #define ISCP_START 0x0000

 /* System Command Block */
 #define SCB_START 0x0008

 /* Start of buffer region.  Everything before this is used for control
  * structures and the CU configuration program.  The memory layout is
  * determined in eexp_hw_probe(), once we know how much memory is
  * available on the card.
  */

 #define TX_BUF_START 0x0100

 #define TX_BUF_SIZE ((24+ETH_FRAME_LEN+31)&~0x1f)
 #define RX_BUF_SIZE ((32+ETH_FRAME_LEN+31)&~0x1f)

 /*
  * SCB defines
  */

 /* these functions take the SCB status word and test the relevant status bit */
 #define SCB_complete(s) ((s&0x8000)!=0)
 #define SCB_rxdframe(s) ((s&0x4000)!=0)
 #define SCB_CUdead(s)   ((s&0x2000)!=0)
 #define SCB_RUdead(s)   ((s&0x1000)!=0)
 #define SCB_ack(s)      (s & 0xf000)

 /* Command unit status: 0=idle, 1=suspended, 2=active */
 #define SCB_CUstat(s)   ((s&0x0300)>>8)

 /* Receive unit status: 0=idle, 1=suspended, 2=out of resources, 4=ready */
 #define SCB_RUstat(s)   ((s&0x0070)>>4)

 /* SCB commands */
 #define SCB_CUnop       0x0000
 #define SCB_CUstart     0x0100
 #define SCB_CUresume    0x0200
 #define SCB_CUsuspend   0x0300
 #define SCB_CUabort     0x0400
 #define SCB_resetchip   0x0080

 #define SCB_RUnop       0x0000
 #define SCB_RUstart     0x0010
 #define SCB_RUresume    0x0020
 #define SCB_RUsuspend   0x0030
 #define SCB_RUabort     0x0040

 /*
  * Command block defines
  */

 #define Stat_Done(s)    ((s&0x8000)!=0)
 #define Stat_Busy(s)    ((s&0x4000)!=0)
 #define Stat_OK(s)      ((s&0x2000)!=0)
 #define Stat_Abort(s)   ((s&0x1000)!=0)
 #define Stat_STFail     ((s&0x0800)!=0)
 #define Stat_TNoCar(s)  ((s&0x0400)!=0)
 #define Stat_TNoCTS(s)  ((s&0x0200)!=0)
 #define Stat_TNoDMA(s)  ((s&0x0100)!=0)
 #define Stat_TDefer(s)  ((s&0x0080)!=0)
 #define Stat_TColl(s)   ((s&0x0040)!=0)
 #define Stat_TXColl(s)  ((s&0x0020)!=0)
 #define Stat_NoColl(s)  (s&0x000f)

 /* Cmd_END will end AFTER the command if this is the first
  * command block after an SCB_CUstart, but BEFORE the command
  * for all subsequent commands. Best strategy is to place
  * Cmd_INT on the last command in the sequence, followed by a
  * dummy Cmd_Nop with Cmd_END after this.
  */

 #define Cmd_END     0x8000
 #define Cmd_SUS     0x4000
 #define Cmd_INT     0x2000

 #define Cmd_Nop     0x0000
 #define Cmd_SetAddr 0x0001
 #define Cmd_Config  0x0002
 #define Cmd_MCast   0x0003
 #define Cmd_Xmit    0x0004
 #define Cmd_TDR     0x0005
 #define Cmd_Dump    0x0006
 #define Cmd_Diag    0x0007


 /*
  * Frame Descriptor (Receive block) defines
  */

 #define FD_Done(s)  ((s&0x8000)!=0)
 #define FD_Busy(s)  ((s&0x4000)!=0)
 #define FD_OK(s)    ((s&0x2000)!=0)

 #define FD_CRC(s)   ((s&0x0800)!=0)
 #define FD_Align(s) ((s&0x0400)!=0)
 #define FD_Resrc(s) ((s&0x0200)!=0)
 #define FD_DMA(s)   ((s&0x0100)!=0)
 #define FD_Short(s) ((s&0x0080)!=0)
 #define FD_NoEOF(s) ((s&0x0040)!=0)

 struct rfd_header {
 	volatile unsigned long flags;
 	volatile unsigned short link;
 	volatile unsigned short rbd_offset;
 	volatile unsigned short dstaddr1;
 	volatile unsigned short dstaddr2;
 	volatile unsigned short dstaddr3;
 	volatile unsigned short srcaddr1;
 	volatile unsigned short srcaddr2;
 	volatile unsigned short srcaddr3;
 	volatile unsigned short length;

 	/* This is actually a Receive Buffer Descriptor.  The way we
 	 * arrange memory means that an RBD always follows the RFD that
 	 * points to it, so they might as well be in the same structure.
 	 */
 	volatile unsigned short actual_count;
 	volatile unsigned short next_rbd;
 	volatile unsigned short buf_addr1;
 	volatile unsigned short buf_addr2;
 	volatile unsigned short size;
 };

 /* Returned data from the Time Domain Reflectometer */

 #define TDR_LINKOK       (1<<15)
 #define TDR_XCVRPROBLEM  (1<<14)
 #define TDR_OPEN         (1<<13)
 #define TDR_SHORT        (1<<12)
 #define TDR_TIME         0x7ff
	/*
	* eexpress.h: Intel EtherExpress16 defines
	*/

	/*
	* EtherExpress card register addresses
	* as offsets from the base IO region (dev->base_addr)
	*/

	#define DATAPORT 0x0000
	#define WRITE_PTR 0x0002
	#define READ_PTR 0x0004
	#define SIGNAL_CA 0x0006
	#define SET_IRQ 0x0007
	#define SM_PTR 0x0008
	#define MEM_Dec 0x000a
	#define MEM_Ctrl 0x000b
	#define MEM_Page_Ctrl 0x000c
	#define Config 0x000d
	#define EEPROM_Ctrl 0x000e
	#define ID_PORT 0x000f
	#define MEM_ECtrl 0x000f

	/*
	* card register defines
	*/

	/* SET_IRQ */
	#define SIRQ_en 0x08
	#define SIRQ_dis 0x00

	/* EEPROM_Ctrl */
	#define EC_Clk 0x01
	#define EC_CS 0x02
	#define EC_Wr 0x04
	#define EC_Rd 0x08
	#define ASIC_RST 0x40
	#define i586_RST 0x80

	#define eeprom_delay() { udelay(40); }

	/*
	* i82586 Memory Configuration
	*/

	/* (System Configuration Pointer) System start up block, read after 586_RST */
	#define SCP_START 0xfff6

	/* Intermediate System Configuration Pointer */
	#define ISCP_START 0x0000

	/* System Command Block */
	#define SCB_START 0x0008

	/* Start of buffer region. Everything before this is used for control
	* structures and the CU configuration program. The memory layout is
	* determined in eexp_hw_probe(), once we know how much memory is
	* available on the card.
	*/

	#define TX_BUF_START 0x0100

	#define TX_BUF_SIZE ((24+ETH_FRAME_LEN+31)&~0x1f)
	#define RX_BUF_SIZE ((32+ETH_FRAME_LEN+31)&~0x1f)

	/*
	* SCB defines
	*/

	/* these functions take the SCB status word and test the relevant status bit */
	#define SCB_complete(s) ((s&0x8000)!=0)
	#define SCB_rxdframe(s) ((s&0x4000)!=0)
	#define SCB_CUdead(s) ((s&0x2000)!=0)
	#define SCB_RUdead(s) ((s&0x1000)!=0)
	#define SCB_ack(s) (s & 0xf000)

	/* Command unit status: 0=idle, 1=suspended, 2=active */
	#define SCB_CUstat(s) ((s&0x0300)>>8)

	/* Receive unit status: 0=idle, 1=suspended, 2=out of resources, 4=ready */
	#define SCB_RUstat(s) ((s&0x0070)>>4)

	/* SCB commands */
	#define SCB_CUnop 0x0000
	#define SCB_CUstart 0x0100
	#define SCB_CUresume 0x0200
	#define SCB_CUsuspend 0x0300
	#define SCB_CUabort 0x0400
	#define SCB_resetchip 0x0080

	#define SCB_RUnop 0x0000
	#define SCB_RUstart 0x0010
	#define SCB_RUresume 0x0020
	#define SCB_RUsuspend 0x0030
	#define SCB_RUabort 0x0040

	/*
	* Command block defines
	*/

	#define Stat_Done(s) ((s&0x8000)!=0)
	#define Stat_Busy(s) ((s&0x4000)!=0)
	#define Stat_OK(s) ((s&0x2000)!=0)
	#define Stat_Abort(s) ((s&0x1000)!=0)
	#define Stat_STFail ((s&0x0800)!=0)
	#define Stat_TNoCar(s) ((s&0x0400)!=0)
	#define Stat_TNoCTS(s) ((s&0x0200)!=0)
	#define Stat_TNoDMA(s) ((s&0x0100)!=0)
	#define Stat_TDefer(s) ((s&0x0080)!=0)
	#define Stat_TColl(s) ((s&0x0040)!=0)
	#define Stat_TXColl(s) ((s&0x0020)!=0)
	#define Stat_NoColl(s) (s&0x000f)

	/* Cmd_END will end AFTER the command if this is the first
	* command block after an SCB_CUstart, but BEFORE the command
	* for all subsequent commands. Best strategy is to place
	* Cmd_INT on the last command in the sequence, followed by a
	* dummy Cmd_Nop with Cmd_END after this.
	*/

	#define Cmd_END 0x8000
	#define Cmd_SUS 0x4000
	#define Cmd_INT 0x2000

	#define Cmd_Nop 0x0000
	#define Cmd_SetAddr 0x0001
	#define Cmd_Config 0x0002
	#define Cmd_MCast 0x0003
	#define Cmd_Xmit 0x0004
	#define Cmd_TDR 0x0005
	#define Cmd_Dump 0x0006
	#define Cmd_Diag 0x0007


	/*
	* Frame Descriptor (Receive block) defines
	*/

	#define FD_Done(s) ((s&0x8000)!=0)
	#define FD_Busy(s) ((s&0x4000)!=0)
	#define FD_OK(s) ((s&0x2000)!=0)

	#define FD_CRC(s) ((s&0x0800)!=0)
	#define FD_Align(s) ((s&0x0400)!=0)
	#define FD_Resrc(s) ((s&0x0200)!=0)
	#define FD_DMA(s) ((s&0x0100)!=0)
	#define FD_Short(s) ((s&0x0080)!=0)
	#define FD_NoEOF(s) ((s&0x0040)!=0)

	struct rfd_header {
	volatile unsigned long flags;
	volatile unsigned short link;
	volatile unsigned short rbd_offset;
	volatile unsigned short dstaddr1;
	volatile unsigned short dstaddr2;
	volatile unsigned short dstaddr3;
	volatile unsigned short srcaddr1;
	volatile unsigned short srcaddr2;
	volatile unsigned short srcaddr3;
	volatile unsigned short length;

	/* This is actually a Receive Buffer Descriptor. The way we
	* arrange memory means that an RBD always follows the RFD that
	* points to it, so they might as well be in the same structure.
	*/
	volatile unsigned short actual_count;
	volatile unsigned short next_rbd;
	volatile unsigned short buf_addr1;
	volatile unsigned short buf_addr2;
	volatile unsigned short size;
	};

	/* Returned data from the Time Domain Reflectometer */

	#define TDR_LINKOK (1<<15)
	#define TDR_XCVRPROBLEM (1<<14)
	#define TDR_OPEN (1<<13)
	#define TDR_SHORT (1<<12)
	#define TDR_TIME 0x7ff