linux-imx/crypto/ocf/safe/safevar.h - nest-learning-thermostat/5.1.3/linux - Git at Google

 /*-
  * The linux port of this code done by David McCullough
  * Copyright (C) 2004-2010 David McCullough <david_mccullough@mcafee.com>
  * The license and original author are listed below.
  *
  * Copyright (c) 2003 Sam Leffler, Errno Consulting
  * Copyright (c) 2003 Global Technology Associates, Inc.
  * 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 AND CONTRIBUTORS ``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 CONTRIBUTORS 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 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: src/sys/dev/safe/safevar.h,v 1.2 2006/05/17 18:34:26 pjd Exp $
  */
 #ifndef _SAFE_SAFEVAR_H_
 #define	_SAFE_SAFEVAR_H_

 /* Maximum queue length */
 #ifndef SAFE_MAX_NQUEUE
 #define SAFE_MAX_NQUEUE	60
 #endif

 #define	SAFE_MAX_PART		64	/* Maximum scatter/gather depth */
 #define	SAFE_DMA_BOUNDARY	0	/* No boundary for source DMA ops */
 #define	SAFE_MAX_DSIZE		2048 /* MCLBYTES Fixed scatter particle size */
 #define	SAFE_MAX_SSIZE		0x0ffff	/* Maximum gather particle size */
 #define	SAFE_MAX_DMA		0xfffff	/* Maximum PE operand size (20 bits) */
 /* total src+dst particle descriptors */
 #define	SAFE_TOTAL_DPART	(SAFE_MAX_NQUEUE * SAFE_MAX_PART)
 #define	SAFE_TOTAL_SPART	(SAFE_MAX_NQUEUE * SAFE_MAX_PART)

 #define	SAFE_RNG_MAXBUFSIZ	128	/* 32-bit words */

 #define	SAFE_CARD(sid)		(((sid) & 0xf0000000) >> 28)
 #define	SAFE_SESSION(sid)	( (sid) & 0x0fffffff)
 #define	SAFE_SID(crd, sesn)	(((crd) << 28) | ((sesn) & 0x0fffffff))

 #define SAFE_DEF_RTY		0xff	/* PCI Retry Timeout */
 #define SAFE_DEF_TOUT		0xff	/* PCI TRDY Timeout */
 #define SAFE_DEF_CACHELINE	0x01	/* Cache Line setting */

 #ifdef __KERNEL__
 /*
  * State associated with the allocation of each chunk
  * of memory setup for DMA.
  */
 struct safe_dma_alloc {
 	dma_addr_t		dma_paddr;
 	void			*dma_vaddr;
 };

 /*
  * Cryptographic operand state.  One of these exists for each
  * source and destination operand passed in from the crypto
  * subsystem.  When possible source and destination operands
  * refer to the same memory.  More often they are distinct.
  * We track the virtual address of each operand as well as
  * where each is mapped for DMA.
  */
 struct safe_operand {
 	union {
 		struct sk_buff *skb;
 		struct uio *io;
 	} u;
 	void			*map;
 	int				mapsize;	/* total number of bytes in segs */
 	struct {
 		dma_addr_t	ds_addr;
 		int			ds_len;
 		int			ds_tlen;
 	} segs[SAFE_MAX_PART];
 	int				nsegs;
 };

 /*
  * Packet engine ring entry and cryptographic operation state.
  * The packet engine requires a ring of descriptors that contain
  * pointers to various cryptographic state.  However the ring
  * configuration register allows you to specify an arbitrary size
  * for ring entries.  We use this feature to collect most of the
  * state for each cryptographic request into one spot.  Other than
  * ring entries only the ``particle descriptors'' (scatter/gather
  * lists) and the actual operand data are kept separate.  The
  * particle descriptors must also be organized in rings.  The
  * operand data can be located aribtrarily (modulo alignment constraints).
  *
  * Note that the descriptor ring is mapped onto the PCI bus so
  * the hardware can DMA data.  This means the entire ring must be
  * contiguous.
  */
 struct safe_ringentry {
 	struct safe_desc	re_desc;	/* command descriptor */
 	struct safe_sarec	re_sa;		/* SA record */
 	struct safe_sastate	re_sastate;	/* SA state record */

 	struct cryptop		*re_crp;	/* crypto operation */

 	struct safe_operand	re_src;		/* source operand */
 	struct safe_operand	re_dst;		/* destination operand */

 	int			re_sesn;	/* crypto session ID */
 	int			re_flags;
 #define	SAFE_QFLAGS_COPYOUTIV	0x1		/* copy back on completion */
 #define	SAFE_QFLAGS_COPYOUTICV	0x2		/* copy back on completion */
 };

 #define	re_src_skb	re_src.u.skb
 #define	re_src_io	re_src.u.io
 #define	re_src_map	re_src.map
 #define	re_src_nsegs	re_src.nsegs
 #define	re_src_segs	re_src.segs
 #define	re_src_mapsize	re_src.mapsize

 #define	re_dst_skb	re_dst.u.skb
 #define	re_dst_io	re_dst.u.io
 #define	re_dst_map	re_dst.map
 #define	re_dst_nsegs	re_dst.nsegs
 #define	re_dst_segs	re_dst.segs
 #define	re_dst_mapsize	re_dst.mapsize

 struct rndstate_test;

 struct safe_session {
 	u_int32_t	ses_used;
 	u_int32_t	ses_klen;		/* key length in bits */
 	u_int32_t	ses_key[8];		/* DES/3DES/AES key */
 	u_int32_t	ses_mlen;		/* hmac length in bytes */
 	u_int32_t	ses_hminner[5];		/* hmac inner state */
 	u_int32_t	ses_hmouter[5];		/* hmac outer state */
 };

 struct safe_pkq {
 	struct list_head	pkq_list;
 	struct cryptkop		*pkq_krp;
 };

 struct safe_softc {
 	softc_device_decl	sc_dev;
 	u32			sc_irq;

 	struct pci_dev		*sc_pcidev;
 	ocf_iomem_t		sc_base_addr;

 	u_int			sc_chiprev;	/* major/minor chip revision */
 	int			sc_flags;	/* device specific flags */
 #define	SAFE_FLAGS_KEY		0x01		/* has key accelerator */
 #define	SAFE_FLAGS_RNG		0x02		/* hardware rng */
 	int			sc_suspended;
 	int			sc_needwakeup;	/* notify crypto layer */
 	int32_t			sc_cid;		/* crypto tag */

 	struct safe_dma_alloc	sc_ringalloc;	/* PE ring allocation state */
 	struct safe_ringentry	*sc_ring;	/* PE ring */
 	struct safe_ringentry	*sc_ringtop;	/* PE ring top */
 	struct safe_ringentry	*sc_front;	/* next free entry */
 	struct safe_ringentry	*sc_back;	/* next pending entry */
 	int			sc_nqchip;	/* # passed to chip */
 	spinlock_t		sc_ringmtx;	/* PE ring lock */
 	struct safe_pdesc	*sc_spring;	/* src particle ring */
 	struct safe_pdesc	*sc_springtop;	/* src particle ring top */
 	struct safe_pdesc	*sc_spfree;	/* next free src particle */
 	struct safe_dma_alloc	sc_spalloc;	/* src particle ring state */
 	struct safe_pdesc	*sc_dpring;	/* dest particle ring */
 	struct safe_pdesc	*sc_dpringtop;	/* dest particle ring top */
 	struct safe_pdesc	*sc_dpfree;	/* next free dest particle */
 	struct safe_dma_alloc	sc_dpalloc;	/* dst particle ring state */
 	int			sc_nsessions;	/* # of sessions */
 	struct safe_session	*sc_sessions;	/* sessions */

 	struct timer_list	sc_pkto;	/* PK polling */
 	spinlock_t		sc_pkmtx;	/* PK lock */
 	struct list_head	sc_pkq;		/* queue of PK requests */
 	struct safe_pkq		*sc_pkq_cur;	/* current processing request */
 	u_int32_t		sc_pk_reslen, sc_pk_resoff;

 	int			sc_max_dsize;	/* maximum safe DMA size */
 };
 #endif /* __KERNEL__ */

 struct safe_stats {
 	u_int64_t st_ibytes;
 	u_int64_t st_obytes;
 	u_int32_t st_ipackets;
 	u_int32_t st_opackets;
 	u_int32_t st_invalid;		/* invalid argument */
 	u_int32_t st_badsession;	/* invalid session id */
 	u_int32_t st_badflags;		/* flags indicate !(mbuf | uio) */
 	u_int32_t st_nodesc;		/* op submitted w/o descriptors */
 	u_int32_t st_badalg;		/* unsupported algorithm */
 	u_int32_t st_ringfull;		/* PE descriptor ring full */
 	u_int32_t st_peoperr;		/* PE marked error */
 	u_int32_t st_dmaerr;		/* PE DMA error */
 	u_int32_t st_bypasstoobig;	/* bypass > 96 bytes */
 	u_int32_t st_skipmismatch;	/* enc part begins before auth part */
 	u_int32_t st_lenmismatch;	/* enc length different auth length */
 	u_int32_t st_coffmisaligned;	/* crypto offset not 32-bit aligned */
 	u_int32_t st_cofftoobig;	/* crypto offset > 255 words */
 	u_int32_t st_iovmisaligned;	/* iov op not aligned */
 	u_int32_t st_iovnotuniform;	/* iov op not suitable */
 	u_int32_t st_unaligned;		/* unaligned src caused copy */
 	u_int32_t st_notuniform;	/* non-uniform src caused copy */
 	u_int32_t st_nomap;		/* bus_dmamap_create failed */
 	u_int32_t st_noload;		/* bus_dmamap_load_* failed */
 	u_int32_t st_nombuf;		/* MGET* failed */
 	u_int32_t st_nomcl;		/* MCLGET* failed */
 	u_int32_t st_maxqchip;		/* max mcr1 ops out for processing */
 	u_int32_t st_rng;		/* RNG requests */
 	u_int32_t st_rngalarm;		/* RNG alarm requests */
 	u_int32_t st_noicvcopy;		/* ICV data copies suppressed */
 };
 #endif /* _SAFE_SAFEVAR_H_ */
	/*-
	* The linux port of this code done by David McCullough
	* Copyright (C) 2004-2010 David McCullough <david_mccullough@mcafee.com>
	* The license and original author are listed below.
	*
	* Copyright (c) 2003 Sam Leffler, Errno Consulting
	* Copyright (c) 2003 Global Technology Associates, Inc.
	* 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 AND CONTRIBUTORS ``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 CONTRIBUTORS 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 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: src/sys/dev/safe/safevar.h,v 1.2 2006/05/17 18:34:26 pjd Exp $
	*/
	#ifndef _SAFE_SAFEVAR_H_
	#define _SAFE_SAFEVAR_H_

	/* Maximum queue length */
	#ifndef SAFE_MAX_NQUEUE
	#define SAFE_MAX_NQUEUE 60
	#endif

	#define SAFE_MAX_PART 64 /* Maximum scatter/gather depth */
	#define SAFE_DMA_BOUNDARY 0 /* No boundary for source DMA ops */
	#define SAFE_MAX_DSIZE 2048 /* MCLBYTES Fixed scatter particle size */
	#define SAFE_MAX_SSIZE 0x0ffff /* Maximum gather particle size */
	#define SAFE_MAX_DMA 0xfffff /* Maximum PE operand size (20 bits) */
	/* total src+dst particle descriptors */
	#define SAFE_TOTAL_DPART (SAFE_MAX_NQUEUE * SAFE_MAX_PART)
	#define SAFE_TOTAL_SPART (SAFE_MAX_NQUEUE * SAFE_MAX_PART)

	#define SAFE_RNG_MAXBUFSIZ 128 /* 32-bit words */

	#define SAFE_CARD(sid) (((sid) & 0xf0000000) >> 28)
	#define SAFE_SESSION(sid) ( (sid) & 0x0fffffff)
	#define SAFE_SID(crd, sesn) (((crd) << 28) \| ((sesn) & 0x0fffffff))

	#define SAFE_DEF_RTY 0xff /* PCI Retry Timeout */
	#define SAFE_DEF_TOUT 0xff /* PCI TRDY Timeout */
	#define SAFE_DEF_CACHELINE 0x01 /* Cache Line setting */

	#ifdef __KERNEL__
	/*
	* State associated with the allocation of each chunk
	* of memory setup for DMA.
	*/
	struct safe_dma_alloc {
	dma_addr_t dma_paddr;
	void *dma_vaddr;
	};

	/*
	* Cryptographic operand state. One of these exists for each
	* source and destination operand passed in from the crypto
	* subsystem. When possible source and destination operands
	* refer to the same memory. More often they are distinct.
	* We track the virtual address of each operand as well as
	* where each is mapped for DMA.
	*/
	struct safe_operand {
	union {
	struct sk_buff *skb;
	struct uio *io;
	} u;
	void *map;
	int mapsize; /* total number of bytes in segs */
	struct {
	dma_addr_t ds_addr;
	int ds_len;
	int ds_tlen;
	} segs[SAFE_MAX_PART];
	int nsegs;
	};

	/*
	* Packet engine ring entry and cryptographic operation state.
	* The packet engine requires a ring of descriptors that contain
	* pointers to various cryptographic state. However the ring
	* configuration register allows you to specify an arbitrary size
	* for ring entries. We use this feature to collect most of the
	* state for each cryptographic request into one spot. Other than
	* ring entries only the ``particle descriptors'' (scatter/gather
	* lists) and the actual operand data are kept separate. The
	* particle descriptors must also be organized in rings. The
	* operand data can be located aribtrarily (modulo alignment constraints).
	*
	* Note that the descriptor ring is mapped onto the PCI bus so
	* the hardware can DMA data. This means the entire ring must be
	* contiguous.
	*/
	struct safe_ringentry {
	struct safe_desc re_desc; /* command descriptor */
	struct safe_sarec re_sa; /* SA record */
	struct safe_sastate re_sastate; /* SA state record */

	struct cryptop re_crp; / crypto operation */

	struct safe_operand re_src; /* source operand */
	struct safe_operand re_dst; /* destination operand */

	int re_sesn; /* crypto session ID */
	int re_flags;
	#define SAFE_QFLAGS_COPYOUTIV 0x1 /* copy back on completion */
	#define SAFE_QFLAGS_COPYOUTICV 0x2 /* copy back on completion */
	};

	#define re_src_skb re_src.u.skb
	#define re_src_io re_src.u.io
	#define re_src_map re_src.map
	#define re_src_nsegs re_src.nsegs
	#define re_src_segs re_src.segs
	#define re_src_mapsize re_src.mapsize

	#define re_dst_skb re_dst.u.skb
	#define re_dst_io re_dst.u.io
	#define re_dst_map re_dst.map
	#define re_dst_nsegs re_dst.nsegs
	#define re_dst_segs re_dst.segs
	#define re_dst_mapsize re_dst.mapsize

	struct rndstate_test;

	struct safe_session {
	u_int32_t ses_used;
	u_int32_t ses_klen; /* key length in bits */
	u_int32_t ses_key[8]; /* DES/3DES/AES key */
	u_int32_t ses_mlen; /* hmac length in bytes */
	u_int32_t ses_hminner[5]; /* hmac inner state */
	u_int32_t ses_hmouter[5]; /* hmac outer state */
	};

	struct safe_pkq {
	struct list_head pkq_list;
	struct cryptkop *pkq_krp;
	};

	struct safe_softc {
	softc_device_decl sc_dev;
	u32 sc_irq;

	struct pci_dev *sc_pcidev;
	ocf_iomem_t sc_base_addr;

	u_int sc_chiprev; /* major/minor chip revision */
	int sc_flags; /* device specific flags */
	#define SAFE_FLAGS_KEY 0x01 /* has key accelerator */
	#define SAFE_FLAGS_RNG 0x02 /* hardware rng */
	int sc_suspended;
	int sc_needwakeup; /* notify crypto layer */
	int32_t sc_cid; /* crypto tag */

	struct safe_dma_alloc sc_ringalloc; /* PE ring allocation state */
	struct safe_ringentry sc_ring; / PE ring */
	struct safe_ringentry sc_ringtop; / PE ring top */
	struct safe_ringentry sc_front; / next free entry */
	struct safe_ringentry sc_back; / next pending entry */
	int sc_nqchip; /* # passed to chip */
	spinlock_t sc_ringmtx; /* PE ring lock */
	struct safe_pdesc sc_spring; / src particle ring */
	struct safe_pdesc sc_springtop; / src particle ring top */
	struct safe_pdesc sc_spfree; / next free src particle */
	struct safe_dma_alloc sc_spalloc; /* src particle ring state */
	struct safe_pdesc sc_dpring; / dest particle ring */
	struct safe_pdesc sc_dpringtop; / dest particle ring top */
	struct safe_pdesc sc_dpfree; / next free dest particle */
	struct safe_dma_alloc sc_dpalloc; /* dst particle ring state */
	int sc_nsessions; /* # of sessions */
	struct safe_session sc_sessions; / sessions */

	struct timer_list sc_pkto; /* PK polling */
	spinlock_t sc_pkmtx; /* PK lock */
	struct list_head sc_pkq; /* queue of PK requests */
	struct safe_pkq sc_pkq_cur; / current processing request */
	u_int32_t sc_pk_reslen, sc_pk_resoff;

	int sc_max_dsize; /* maximum safe DMA size */
	};
	#endif /* __KERNEL__ */

	struct safe_stats {
	u_int64_t st_ibytes;
	u_int64_t st_obytes;
	u_int32_t st_ipackets;
	u_int32_t st_opackets;
	u_int32_t st_invalid; /* invalid argument */
	u_int32_t st_badsession; /* invalid session id */
	u_int32_t st_badflags; /* flags indicate !(mbuf \| uio) */
	u_int32_t st_nodesc; /* op submitted w/o descriptors */
	u_int32_t st_badalg; /* unsupported algorithm */
	u_int32_t st_ringfull; /* PE descriptor ring full */
	u_int32_t st_peoperr; /* PE marked error */
	u_int32_t st_dmaerr; /* PE DMA error */
	u_int32_t st_bypasstoobig; /* bypass > 96 bytes */
	u_int32_t st_skipmismatch; /* enc part begins before auth part */
	u_int32_t st_lenmismatch; /* enc length different auth length */
	u_int32_t st_coffmisaligned; /* crypto offset not 32-bit aligned */
	u_int32_t st_cofftoobig; /* crypto offset > 255 words */
	u_int32_t st_iovmisaligned; /* iov op not aligned */
	u_int32_t st_iovnotuniform; /* iov op not suitable */
	u_int32_t st_unaligned; /* unaligned src caused copy */
	u_int32_t st_notuniform; /* non-uniform src caused copy */
	u_int32_t st_nomap; /* bus_dmamap_create failed */
	u_int32_t st_noload; /* bus_dmamap_load_* failed */
	u_int32_t st_nombuf; /* MGET* failed */
	u_int32_t st_nomcl; /* MCLGET* failed */
	u_int32_t st_maxqchip; /* max mcr1 ops out for processing */
	u_int32_t st_rng; /* RNG requests */
	u_int32_t st_rngalarm; /* RNG alarm requests */
	u_int32_t st_noicvcopy; /* ICV data copies suppressed */
	};
	#endif /* _SAFE_SAFEVAR_H_ */