freebsd-dev/sys/mips/idt/if_krreg.h

/*-
 * Copyright (C) 2007 
 *	Oleksandr Tymoshenko <gonzo@freebsd.org>. All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions
 * are met:
 * 1. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions and the following disclaimer.
 * 2. Redistributions in binary form must reproduce the above copyright
 *    notice, this list of conditions and the following disclaimer in the
 *    documentation and/or other materials provided with the distribution.
 *
 * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
 * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
 * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
 * IN NO EVENT SHALL THE AUTHOR OR HIS RELATIVES BE LIABLE FOR ANY DIRECT,
 * INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
 * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
 * SERVICES; LOSS OF MIND, USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
 * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING
 * IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
 * THE POSSIBILITY OF SUCH DAMAGE.
 *
 * $FreeBSD$
 *
 */

#ifndef __IF_KRREG_H__
#define __IF_KRREG_H__

#define	KR_ETHINTFC 	0x0000	/* Ethernet interface control             */
#define		ETH_INTFC_EN 	0x0001
#define		ETH_INTFC_RIP 	0x0004
#define		ETH_INTFC_EN 	0x0001
#define	KR_ETHFIFOTT	0x0004	/* Ethernet FIFO transmit threshold       */
#define	KR_ETHARC   	0x0008	/* Ethernet address recognition control   */
#define	KR_ETHHASH0 	0x000C	/* Ethernet hash table 0                  */
#define	KR_ETHHASH1 	0x0010	/* Ethernet hash table 1                  */
#define	KR_ETHPFS   	0x0024	/* Ethernet pause frame status            */
#define	KR_ETHMCP   	0x0028	/* Ethernet management clock prescalar    */
#define	KR_ETHSAL0  	0x0100	/* Ethernet station address 0 low         */
#define	KR_ETHSAH0  	0x0104	/* Ethernet station address 0 high        */
#define	KR_ETHSAL1  	0x0108	/* Ethernet station address 1 low         */
#define	KR_ETHSAH1  	0x010C	/* Ethernet station address 1 high        */
#define	KR_ETHSAL2  	0x0110	/* Ethernet station address 2 low         */
#define	KR_ETHSAH2  	0x0114	/* Ethernet station address 2 high        */
#define	KR_ETHSAL3  	0x0118	/* Ethernet station address 3 low         */
#define	KR_ETHSAH3  	0x011C	/* Ethernet station address 3 high        */
#define	KR_ETHRBC   	0x0120	/* Ethernet receive byte count            */
#define	KR_ETHRPC   	0x0124	/* Ethernet receive packet count          */
#define	KR_ETHRUPC  	0x0128	/* Ethernet receive undersized packet cnt */
#define	KR_ETHRFC   	0x012C	/* Ethernet receive fragment count        */
#define	KR_ETHTBC   	0x0130	/* Ethernet transmit byte count           */
#define	KR_ETHGPF   	0x0134	/* Ethernet generate pause frame          */
#define	KR_ETHMAC1 	0x0200	/* Ethernet MAC configuration 1           */
#define		KR_ETH_MAC1_RE	0x01
#define		KR_ETH_MAC1_PAF	0x02
#define		KR_ETH_MAC1_MR	0x80
#define	KR_ETHMAC2 	0x0204	/* Ethernet MAC configuration 2           */
#define		KR_ETH_MAC2_FD	0x01
#define		KR_ETH_MAC2_FLC	0x02
#define		KR_ETH_MAC2_HFE	0x04
#define		KR_ETH_MAC2_DC	0x08
#define		KR_ETH_MAC2_CEN	0x10
#define		KR_ETH_MAC2_PEN	0x20
#define		KR_ETH_MAC2_VPE	0x08
#define	KR_ETHIPGT 	0x0208	/* Ethernet back-to-back inter-packet gap */
#define	KR_ETHIPGR 	0x020C	/* Ethernet non back-to-back inter-packet gap */
#define	KR_ETHCLRT 	0x0210	/* Ethernet collision window retry        */
#define	KR_ETHMAXF 	0x0214	/* Ethernet maximum frame length          */
#define	KR_ETHMTEST	0x021C	/* Ethernet MAC test                      */
#define	KR_MIIMCFG 	0x0220	/* MII management configuration           */
#define		KR_MIIMCFG_R	0x8000 	
#define	KR_MIIMCMD 	0x0224	/* MII management command                 */
#define		KR_MIIMCMD_RD 	0x01
#define		KR_MIIMCMD_SCN 	0x02
#define	KR_MIIMADDR	0x0228	/* MII management address                 */
#define	KR_MIIMWTD 	0x022C	/* MII management write data              */
#define	KR_MIIMRDD 	0x0230	/* MII management read data               */
#define	KR_MIIMIND 	0x0234	/* MII management indicators              */
#define		KR_MIIMIND_BSY 	0x1
#define		KR_MIIMIND_SCN 	0x2
#define		KR_MIIMIND_NV 	0x4
#define	KR_ETHCFSA0	0x0240	/* Ethernet control frame station address 0   */
#define	KR_ETHCFSA1	0x0244	/* Ethernet control frame station address 1   */
#define	KR_ETHCFSA2	0x0248	/* Ethernet control frame station address 2   */

#define	KR_ETHIPGT_HALF_DUPLEX	0x12
#define	KR_ETHIPGT_FULL_DUPLEX	0x15

#define KR_TIMEOUT	0xf000
#define KR_MII_TIMEOUT	0xf000

#define KR_RX_IRQ	40
#define KR_TX_IRQ	41
#define KR_RX_UND_IRQ	42
#define KR_TX_OVR_IRQ	43
#define RC32434_DMA_BASE_ADDR	MIPS_PHYS_TO_KSEG1(0x18040000)
#define		DMA_C		0x00
#define			DMA_C_R		0x01
#define			DMA_C_ABORT	0x10
#define		DMA_S		0x04
#define			DMA_S_F		0x01
#define			DMA_S_D		0x02
#define			DMA_S_C		0x04
#define			DMA_S_E		0x08
#define			DMA_S_H		0x10
#define		DMA_SM		0x08
#define			DMA_SM_F	0x01
#define			DMA_SM_D	0x02
#define			DMA_SM_C	0x04
#define			DMA_SM_E	0x08
#define			DMA_SM_H	0x10
#define		DMA_DPTR	0x0C
#define		DMA_NDPTR	0x10

#define	RC32434_DMA_CHAN_SIZE	0x14
#define KR_DMA_RXCHAN		0
#define KR_DMA_TXCHAN		1

#define	KR_DMA_READ_REG(chan, reg) \
	(*(volatile uint32_t *)	\
	    (RC32434_DMA_BASE_ADDR + chan * RC32434_DMA_CHAN_SIZE + reg))

#define	KR_DMA_WRITE_REG(chan, reg, val) \
	((*(volatile uint32_t *)	\
	    (RC32434_DMA_BASE_ADDR + chan * RC32434_DMA_CHAN_SIZE + reg)) = val)

#define	KR_DMA_SETBITS_REG(chan, reg, bits) \
	KR_DMA_WRITE_REG((chan), (reg), KR_DMA_READ_REG((chan), (reg)) | (bits))

#define	KR_DMA_CLEARBITS_REG(chan, reg, bits)		\
	KR_DMA_WRITE_REG((chan), (reg),			\
	    KR_DMA_READ_REG((chan), (reg)) & ~(bits))

struct kr_desc {
	uint32_t	kr_ctl;
	uint32_t	kr_ca;
	uint32_t	kr_devcs;
	uint32_t	kr_link;
};


#define KR_DMASIZE(len)		((len)  & ((1 << 18)-1))		
#define KR_PKTSIZE(len)		((len & 0xffff0000) >> 16)

#define	KR_CTL_COF	0x02000000
#define	KR_CTL_COD	0x04000000
#define	KR_CTL_IOF	0x08000000
#define	KR_CTL_IOD	0x10000000
#define	KR_CTL_T	0x20000000
#define	KR_CTL_D	0x40000000
#define	KR_CTL_F	0x80000000

#define	KR_DMARX_DEVCS_RSV	0x00000001
#define	KR_DMARX_DEVCS_LD	0x00000002
#define	KR_DMARX_DEVCS_ROK	0x00000004
#define	KR_DMARX_DEVCS_FM	0x00000008
#define	KR_DMARX_DEVCS_MP	0x00000010
#define	KR_DMARX_DEVCS_BP	0x00000020
#define	KR_DMARX_DEVCS_VLT	0x00000040
#define	KR_DMARX_DEVCS_CF	0x00000080
#define	KR_DMARX_DEVCS_OVR	0x00000100
#define	KR_DMARX_DEVCS_CRC	0x00000200
#define	KR_DMARX_DEVCS_CV	0x00000400
#define	KR_DMARX_DEVCS_DB	0x00000800
#define	KR_DMARX_DEVCS_LE	0x00001000
#define	KR_DMARX_DEVCS_LOR	0x00002000
#define	KR_DMARX_DEVCS_CES	0x00004000

#define	KR_DMATX_DEVCS_FD	0x00000001
#define	KR_DMATX_DEVCS_LD	0x00000002
#define	KR_DMATX_DEVCS_OEN	0x00000004
#define	KR_DMATX_DEVCS_PEN	0x00000008
#define	KR_DMATX_DEVCS_CEN	0x00000010
#define	KR_DMATX_DEVCS_HEN	0x00000020
#define	KR_DMATX_DEVCS_TOK	0x00000040
#define	KR_DMATX_DEVCS_MP	0x00000080
#define	KR_DMATX_DEVCS_BP	0x00000100
#define	KR_DMATX_DEVCS_UND	0x00000200
#define	KR_DMATX_DEVCS_OF	0x00000400
#define	KR_DMATX_DEVCS_ED	0x00000800
#define	KR_DMATX_DEVCS_EC	0x00001000
#define	KR_DMATX_DEVCS_LC	0x00002000
#define	KR_DMATX_DEVCS_TD	0x00004000
#define	KR_DMATX_DEVCS_CRC	0x00008000
#define	KR_DMATX_DEVCS_LE	0x00010000

#define KR_RX_RING_CNT		128
#define KR_TX_RING_CNT		128
#define KR_TX_RING_SIZE		sizeof(struct kr_desc) * KR_TX_RING_CNT
#define KR_RX_RING_SIZE		sizeof(struct kr_desc) * KR_RX_RING_CNT
#define KR_RING_ALIGN		sizeof(struct kr_desc)
#define KR_RX_ALIGN		sizeof(uint32_t)
#define KR_MAXFRAGS		8
#define KR_TX_INTR_THRESH	8

#define	KR_TX_RING_ADDR(sc, i)	\
    ((sc)->kr_rdata.kr_tx_ring_paddr + sizeof(struct kr_desc) * (i))
#define	KR_RX_RING_ADDR(sc, i)	\
    ((sc)->kr_rdata.kr_rx_ring_paddr + sizeof(struct kr_desc) * (i))
#define	KR_INC(x,y)		(x) = (((x) + 1) % y)

struct kr_txdesc {
	struct mbuf	*tx_m;
	bus_dmamap_t	tx_dmamap;
};

struct kr_rxdesc {
	struct mbuf	*rx_m;
	bus_dmamap_t	rx_dmamap;
	struct kr_desc	*desc;
	/* Use this values on error instead of allocating new mbuf */
	uint32_t	saved_ctl, saved_ca; 
};

struct kr_chain_data {
	bus_dma_tag_t		kr_parent_tag;
	bus_dma_tag_t		kr_tx_tag;
	struct kr_txdesc	kr_txdesc[KR_TX_RING_CNT];
	bus_dma_tag_t		kr_rx_tag;
	struct kr_rxdesc	kr_rxdesc[KR_RX_RING_CNT];
	bus_dma_tag_t		kr_tx_ring_tag;
	bus_dma_tag_t		kr_rx_ring_tag;
	bus_dmamap_t		kr_tx_ring_map;
	bus_dmamap_t		kr_rx_ring_map;
	bus_dmamap_t		kr_rx_sparemap;
	int			kr_tx_pkts;
	int			kr_tx_prod;
	int			kr_tx_cons;
	int			kr_tx_cnt;
	int			kr_rx_cons;
};

struct kr_ring_data {
	struct kr_desc		*kr_rx_ring;
	struct kr_desc		*kr_tx_ring;
	bus_addr_t		kr_rx_ring_paddr;
	bus_addr_t		kr_tx_ring_paddr;
};

struct kr_softc {
	struct ifnet		*kr_ifp;	/* interface info */
	bus_space_handle_t	kr_bhandle;	/* bus space handle */
	bus_space_tag_t		kr_btag;	/* bus space tag */
	device_t		kr_dev;
	struct resource		*kr_res;
	int			kr_rid;
	struct resource		*kr_rx_irq;
	void			*kr_rx_intrhand;
	struct resource		*kr_tx_irq;
	void			*kr_tx_intrhand;
	struct resource		*kr_rx_und_irq;
	void			*kr_rx_und_intrhand;
	struct resource		*kr_tx_ovr_irq;
	void			*kr_tx_ovr_intrhand;
	device_t		kr_miibus;
	bus_dma_tag_t		kr_parent_tag;
	bus_dma_tag_t		kr_tag;
	struct mtx		kr_mtx;
	struct callout		kr_stat_callout;
	struct task		kr_link_task;
	struct kr_chain_data	kr_cdata;
	struct kr_ring_data	kr_rdata;
	int			kr_link_status;
	int			kr_detach;
};

#define	KR_LOCK(_sc)		mtx_lock(&(_sc)->kr_mtx)
#define	KR_UNLOCK(_sc)		mtx_unlock(&(_sc)->kr_mtx)
#define	KR_LOCK_ASSERT(_sc)	mtx_assert(&(_sc)->kr_mtx, MA_OWNED)

/*
 * register space access macros
 */
#define CSR_WRITE_4(sc, reg, val)	\
	bus_space_write_4(sc->kr_btag, sc->kr_bhandle, reg, val)

#define CSR_READ_4(sc, reg)		\
	bus_space_read_4(sc->kr_btag, sc->kr_bhandle, reg)

#endif /* __IF_KRREG_H__ */
FreeBSD/mips port. The FreeBSD/mips port targets mips32, mips64, mips32r2 and mips64r2 (and close relatives) processors. There presently is support for ADMtek ADM5120, A mips 4Kc in a malta board, the RB533 routerboard (based on IDT RC32434) and some preliminary support for sibtye/broadcom designs. Other hardware support will be forthcomcing. This port boots multiuser under gxemul emulating the malta board and also bootstraps on the hardware whose support is forthcoming... Oleksandr Tymoshenko, Wojciech Koszek, Warner Losh, Olivier Houchard, Randall Stewert and others that have contributed to the mips2 and/or mips2-jnpr perforce branches. Juniper contirbuted a generic mips port late in the life cycle of the misp2 branch. Warner Losh merged the mips2 and Juniper code bases, and others list above have worked for the past several months to get to multiuser. In addition, the mips2 work owe a debt to the trail blazing efforts of the original mips branch in perforce done by Juli Mallett. 2008-04-13 07:44:55 +00:00			`/*-`
			`* Copyright (C) 2007`
			`* Oleksandr Tymoshenko <gonzo@freebsd.org>. All rights reserved.`
			`*`
			`* Redistribution and use in source and binary forms, with or without`
			`* modification, are permitted provided that the following conditions`
			`* are met:`
			`* 1. Redistributions of source code must retain the above copyright`
			`* notice, this list of conditions and the following disclaimer.`
			`* 2. Redistributions in binary form must reproduce the above copyright`
			`* notice, this list of conditions and the following disclaimer in the`
			`* documentation and/or other materials provided with the distribution.`
			`*`
			* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
			`* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES`
			`* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.`
			`* IN NO EVENT SHALL THE AUTHOR OR HIS RELATIVES BE LIABLE FOR ANY DIRECT,`
			`* INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES`
			`* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR`
			`* SERVICES; LOSS OF MIND, USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)`
			`* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,`
			`* STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING`
			`* IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF`
			`* THE POSSIBILITY OF SUCH DAMAGE.`
			`*`
			`* $FreeBSD$`
			`*`
			`*/`

			`#ifndef __IF_KRREG_H__`
			`#define __IF_KRREG_H__`

			`#define KR_ETHINTFC 0x0000 /* Ethernet interface control */`
			`#define ETH_INTFC_EN 0x0001`
			`#define ETH_INTFC_RIP 0x0004`
			`#define ETH_INTFC_EN 0x0001`
			`#define KR_ETHFIFOTT 0x0004 /* Ethernet FIFO transmit threshold */`
			`#define KR_ETHARC 0x0008 /* Ethernet address recognition control */`
			`#define KR_ETHHASH0 0x000C /* Ethernet hash table 0 */`
			`#define KR_ETHHASH1 0x0010 /* Ethernet hash table 1 */`
			`#define KR_ETHPFS 0x0024 /* Ethernet pause frame status */`
			`#define KR_ETHMCP 0x0028 /* Ethernet management clock prescalar */`
			`#define KR_ETHSAL0 0x0100 /* Ethernet station address 0 low */`
			`#define KR_ETHSAH0 0x0104 /* Ethernet station address 0 high */`
			`#define KR_ETHSAL1 0x0108 /* Ethernet station address 1 low */`
			`#define KR_ETHSAH1 0x010C /* Ethernet station address 1 high */`
			`#define KR_ETHSAL2 0x0110 /* Ethernet station address 2 low */`
			`#define KR_ETHSAH2 0x0114 /* Ethernet station address 2 high */`
			`#define KR_ETHSAL3 0x0118 /* Ethernet station address 3 low */`
			`#define KR_ETHSAH3 0x011C /* Ethernet station address 3 high */`
			`#define KR_ETHRBC 0x0120 /* Ethernet receive byte count */`
			`#define KR_ETHRPC 0x0124 /* Ethernet receive packet count */`
			`#define KR_ETHRUPC 0x0128 /* Ethernet receive undersized packet cnt */`
			`#define KR_ETHRFC 0x012C /* Ethernet receive fragment count */`
			`#define KR_ETHTBC 0x0130 /* Ethernet transmit byte count */`
			`#define KR_ETHGPF 0x0134 /* Ethernet generate pause frame */`
			`#define KR_ETHMAC1 0x0200 /* Ethernet MAC configuration 1 */`
			`#define KR_ETH_MAC1_RE 0x01`
			`#define KR_ETH_MAC1_PAF 0x02`
			`#define KR_ETH_MAC1_MR 0x80`
			`#define KR_ETHMAC2 0x0204 /* Ethernet MAC configuration 2 */`
			`#define KR_ETH_MAC2_FD 0x01`
			`#define KR_ETH_MAC2_FLC 0x02`
			`#define KR_ETH_MAC2_HFE 0x04`
			`#define KR_ETH_MAC2_DC 0x08`
			`#define KR_ETH_MAC2_CEN 0x10`
			`#define KR_ETH_MAC2_PEN 0x20`
			`#define KR_ETH_MAC2_VPE 0x08`
			`#define KR_ETHIPGT 0x0208 /* Ethernet back-to-back inter-packet gap */`
			`#define KR_ETHIPGR 0x020C /* Ethernet non back-to-back inter-packet gap */`
			`#define KR_ETHCLRT 0x0210 /* Ethernet collision window retry */`
			`#define KR_ETHMAXF 0x0214 /* Ethernet maximum frame length */`
			`#define KR_ETHMTEST 0x021C /* Ethernet MAC test */`
			`#define KR_MIIMCFG 0x0220 /* MII management configuration */`
			`#define KR_MIIMCFG_R 0x8000`
			`#define KR_MIIMCMD 0x0224 /* MII management command */`
			`#define KR_MIIMCMD_RD 0x01`
			`#define KR_MIIMCMD_SCN 0x02`
			`#define KR_MIIMADDR 0x0228 /* MII management address */`
			`#define KR_MIIMWTD 0x022C /* MII management write data */`
			`#define KR_MIIMRDD 0x0230 /* MII management read data */`
			`#define KR_MIIMIND 0x0234 /* MII management indicators */`
			`#define KR_MIIMIND_BSY 0x1`
			`#define KR_MIIMIND_SCN 0x2`
			`#define KR_MIIMIND_NV 0x4`
			`#define KR_ETHCFSA0 0x0240 /* Ethernet control frame station address 0 */`
			`#define KR_ETHCFSA1 0x0244 /* Ethernet control frame station address 1 */`
			`#define KR_ETHCFSA2 0x0248 /* Ethernet control frame station address 2 */`

			`#define KR_ETHIPGT_HALF_DUPLEX 0x12`
			`#define KR_ETHIPGT_FULL_DUPLEX 0x15`

			`#define KR_TIMEOUT 0xf000`
			`#define KR_MII_TIMEOUT 0xf000`

			`#define KR_RX_IRQ 40`
			`#define KR_TX_IRQ 41`
			`#define KR_RX_UND_IRQ 42`
			`#define KR_TX_OVR_IRQ 43`
			`#define RC32434_DMA_BASE_ADDR MIPS_PHYS_TO_KSEG1(0x18040000)`
			`#define DMA_C 0x00`
			`#define DMA_C_R 0x01`
			`#define DMA_C_ABORT 0x10`
			`#define DMA_S 0x04`
			`#define DMA_S_F 0x01`
			`#define DMA_S_D 0x02`
			`#define DMA_S_C 0x04`
			`#define DMA_S_E 0x08`
			`#define DMA_S_H 0x10`
			`#define DMA_SM 0x08`
			`#define DMA_SM_F 0x01`
			`#define DMA_SM_D 0x02`
			`#define DMA_SM_C 0x04`
			`#define DMA_SM_E 0x08`
			`#define DMA_SM_H 0x10`
			`#define DMA_DPTR 0x0C`
			`#define DMA_NDPTR 0x10`

			`#define RC32434_DMA_CHAN_SIZE 0x14`
			`#define KR_DMA_RXCHAN 0`
			`#define KR_DMA_TXCHAN 1`

			`#define KR_DMA_READ_REG(chan, reg) \`
			`((volatile uint32_t ) \`
			`(RC32434_DMA_BASE_ADDR + chan * RC32434_DMA_CHAN_SIZE + reg))`

			`#define KR_DMA_WRITE_REG(chan, reg, val) \`
			`(((volatile uint32_t ) \`
			`(RC32434_DMA_BASE_ADDR + chan * RC32434_DMA_CHAN_SIZE + reg)) = val)`

			`#define KR_DMA_SETBITS_REG(chan, reg, bits) \`
			`KR_DMA_WRITE_REG((chan), (reg), KR_DMA_READ_REG((chan), (reg)) \| (bits))`

			`#define KR_DMA_CLEARBITS_REG(chan, reg, bits) \`
			`KR_DMA_WRITE_REG((chan), (reg), \`
			`KR_DMA_READ_REG((chan), (reg)) & ~(bits))`

			`struct kr_desc {`
			`uint32_t kr_ctl;`
			`uint32_t kr_ca;`
			`uint32_t kr_devcs;`
			`uint32_t kr_link;`
			`};`


			`#define KR_DMASIZE(len) ((len) & ((1 << 18)-1))`
			`#define KR_PKTSIZE(len) ((len & 0xffff0000) >> 16)`

			`#define KR_CTL_COF 0x02000000`
			`#define KR_CTL_COD 0x04000000`
			`#define KR_CTL_IOF 0x08000000`
			`#define KR_CTL_IOD 0x10000000`
			`#define KR_CTL_T 0x20000000`
			`#define KR_CTL_D 0x40000000`
			`#define KR_CTL_F 0x80000000`

			`#define KR_DMARX_DEVCS_RSV 0x00000001`
			`#define KR_DMARX_DEVCS_LD 0x00000002`
			`#define KR_DMARX_DEVCS_ROK 0x00000004`
			`#define KR_DMARX_DEVCS_FM 0x00000008`
			`#define KR_DMARX_DEVCS_MP 0x00000010`
			`#define KR_DMARX_DEVCS_BP 0x00000020`
			`#define KR_DMARX_DEVCS_VLT 0x00000040`
			`#define KR_DMARX_DEVCS_CF 0x00000080`
			`#define KR_DMARX_DEVCS_OVR 0x00000100`
			`#define KR_DMARX_DEVCS_CRC 0x00000200`
			`#define KR_DMARX_DEVCS_CV 0x00000400`
			`#define KR_DMARX_DEVCS_DB 0x00000800`
			`#define KR_DMARX_DEVCS_LE 0x00001000`
			`#define KR_DMARX_DEVCS_LOR 0x00002000`
			`#define KR_DMARX_DEVCS_CES 0x00004000`

			`#define KR_DMATX_DEVCS_FD 0x00000001`
			`#define KR_DMATX_DEVCS_LD 0x00000002`
			`#define KR_DMATX_DEVCS_OEN 0x00000004`
			`#define KR_DMATX_DEVCS_PEN 0x00000008`
			`#define KR_DMATX_DEVCS_CEN 0x00000010`
			`#define KR_DMATX_DEVCS_HEN 0x00000020`
			`#define KR_DMATX_DEVCS_TOK 0x00000040`
			`#define KR_DMATX_DEVCS_MP 0x00000080`
			`#define KR_DMATX_DEVCS_BP 0x00000100`
			`#define KR_DMATX_DEVCS_UND 0x00000200`
			`#define KR_DMATX_DEVCS_OF 0x00000400`
			`#define KR_DMATX_DEVCS_ED 0x00000800`
			`#define KR_DMATX_DEVCS_EC 0x00001000`
			`#define KR_DMATX_DEVCS_LC 0x00002000`
			`#define KR_DMATX_DEVCS_TD 0x00004000`
			`#define KR_DMATX_DEVCS_CRC 0x00008000`
			`#define KR_DMATX_DEVCS_LE 0x00010000`

			`#define KR_RX_RING_CNT 128`
			`#define KR_TX_RING_CNT 128`
			`#define KR_TX_RING_SIZE sizeof(struct kr_desc) * KR_TX_RING_CNT`
			`#define KR_RX_RING_SIZE sizeof(struct kr_desc) * KR_RX_RING_CNT`
			`#define KR_RING_ALIGN sizeof(struct kr_desc)`
			`#define KR_RX_ALIGN sizeof(uint32_t)`
			`#define KR_MAXFRAGS 8`
			`#define KR_TX_INTR_THRESH 8`

			`#define KR_TX_RING_ADDR(sc, i) \`
			`((sc)->kr_rdata.kr_tx_ring_paddr + sizeof(struct kr_desc) * (i))`
			`#define KR_RX_RING_ADDR(sc, i) \`
			`((sc)->kr_rdata.kr_rx_ring_paddr + sizeof(struct kr_desc) * (i))`
			`#define KR_INC(x,y) (x) = (((x) + 1) % y)`

			`struct kr_txdesc {`
			`struct mbuf *tx_m;`
			`bus_dmamap_t tx_dmamap;`
			`};`

			`struct kr_rxdesc {`
			`struct mbuf *rx_m;`
			`bus_dmamap_t rx_dmamap;`
			`struct kr_desc *desc;`
			`/* Use this values on error instead of allocating new mbuf */`
			`uint32_t saved_ctl, saved_ca;`
			`};`

			`struct kr_chain_data {`
			`bus_dma_tag_t kr_parent_tag;`
			`bus_dma_tag_t kr_tx_tag;`
			`struct kr_txdesc kr_txdesc[KR_TX_RING_CNT];`
			`bus_dma_tag_t kr_rx_tag;`
			`struct kr_rxdesc kr_rxdesc[KR_RX_RING_CNT];`
			`bus_dma_tag_t kr_tx_ring_tag;`
			`bus_dma_tag_t kr_rx_ring_tag;`
			`bus_dmamap_t kr_tx_ring_map;`
			`bus_dmamap_t kr_rx_ring_map;`
			`bus_dmamap_t kr_rx_sparemap;`
			`int kr_tx_pkts;`
			`int kr_tx_prod;`
			`int kr_tx_cons;`
			`int kr_tx_cnt;`
			`int kr_rx_cons;`
			`};`

			`struct kr_ring_data {`
			`struct kr_desc *kr_rx_ring;`
			`struct kr_desc *kr_tx_ring;`
			`bus_addr_t kr_rx_ring_paddr;`
			`bus_addr_t kr_tx_ring_paddr;`
			`};`

			`struct kr_softc {`
			`struct ifnet kr_ifp; / interface info */`
			`bus_space_handle_t kr_bhandle; /* bus space handle */`
			`bus_space_tag_t kr_btag; /* bus space tag */`
			`device_t kr_dev;`
			`struct resource *kr_res;`
			`int kr_rid;`
			`struct resource *kr_rx_irq;`
			`void *kr_rx_intrhand;`
			`struct resource *kr_tx_irq;`
			`void *kr_tx_intrhand;`
			`struct resource *kr_rx_und_irq;`
			`void *kr_rx_und_intrhand;`
			`struct resource *kr_tx_ovr_irq;`
			`void *kr_tx_ovr_intrhand;`
			`device_t kr_miibus;`
			`bus_dma_tag_t kr_parent_tag;`
			`bus_dma_tag_t kr_tag;`
			`struct mtx kr_mtx;`
			`struct callout kr_stat_callout;`
			`struct task kr_link_task;`
			`struct kr_chain_data kr_cdata;`
			`struct kr_ring_data kr_rdata;`
			`int kr_link_status;`
			`int kr_detach;`
			`};`

			`#define KR_LOCK(_sc) mtx_lock(&(_sc)->kr_mtx)`
			`#define KR_UNLOCK(_sc) mtx_unlock(&(_sc)->kr_mtx)`
			`#define KR_LOCK_ASSERT(_sc) mtx_assert(&(_sc)->kr_mtx, MA_OWNED)`

			`/*`
			`* register space access macros`
			`*/`
			`#define CSR_WRITE_4(sc, reg, val) \`
			`bus_space_write_4(sc->kr_btag, sc->kr_bhandle, reg, val)`

			`#define CSR_READ_4(sc, reg) \`
			`bus_space_read_4(sc->kr_btag, sc->kr_bhandle, reg)`

			`#endif /* __IF_KRREG_H__ */`