freebsd-skq/sys/netatm/spans/spans_var.h
phk acecaa1fc2 More HARP polishina:
unifdef -UFORE_SBUS -DFORE_PCI
s/ATM_KERNEL/_KERNER/g
2000-10-12 07:42:34 +00:00

260 lines
7.8 KiB
C

/*
*
* ===================================
* HARP | Host ATM Research Platform
* ===================================
*
*
* This Host ATM Research Platform ("HARP") file (the "Software") is
* made available by Network Computing Services, Inc. ("NetworkCS")
* "AS IS". NetworkCS does not provide maintenance, improvements or
* support of any kind.
*
* NETWORKCS MAKES NO WARRANTIES OR REPRESENTATIONS, EXPRESS OR IMPLIED,
* INCLUDING, BUT NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY
* AND FITNESS FOR A PARTICULAR PURPOSE, AS TO ANY ELEMENT OF THE
* SOFTWARE OR ANY SUPPORT PROVIDED IN CONNECTION WITH THIS SOFTWARE.
* In no event shall NetworkCS be responsible for any damages, including
* but not limited to consequential damages, arising from or relating to
* any use of the Software or related support.
*
* Copyright 1994-1998 Network Computing Services, Inc.
*
* Copies of this Software may be made, however, the above copyright
* notice must be reproduced on all copies.
*
* @(#) $FreeBSD$
*
*/
/*
* SPANS Signalling Manager
* ---------------------------
*
* Protocol control blocks
*
*/
#ifndef _SPANS_SPANS_VAR_H
#define _SPANS_SPANS_VAR_H
#ifdef _KERNEL
/*
* Constants to indicate the state of the signalling interface
*/
#define SPANS_UNI_UP 1
#define SPANS_UNI_DOWN -1
/*
* Structure containing state information for each SPANS protocol
* instance. There will be one instance for each ATM device interface
* using the SPANS signalling manager.
*/
struct spans {
struct siginst sp_inst; /* Header */
struct atm_time sp_time; /* Timer controls */
void (*sp_lower) /* Lower command handler */
__P((int, void *, int, int));
Atm_connection *sp_conn; /* Signalling connection */
long sp_s_epoch; /* Switch epoch */
long sp_h_epoch; /* Host epoch */
u_int sp_probe_ct; /* Status_req msgs unanswered */
u_int sp_alloc_vci; /* Next VCI to allocate */
u_int sp_alloc_vpi; /* Next VPI to allocate */
u_int sp_min_vci; /* Lowest VCI to allocate */
u_int sp_max_vci; /* Highest VCI to allocate */
struct spanscls *sp_cls; /* CLS instance */
};
#define sp_next sp_inst.si_next
#define sp_pif sp_inst.si_pif
#define sp_addr sp_inst.si_addr
#define sp_subaddr sp_inst.si_subaddr
#define sp_vccq sp_inst.si_vccq
#define sp_state sp_inst.si_state
#define sp_ipserv sp_inst.si_ipserv
#endif /* _KERNEL */
/*
* SPANS Protocol States
*/
#define SPANS_ACTIVE 1 /* Active */
#define SPANS_DETACH 2 /* Detach in progress */
#define SPANS_INIT 3 /* Initializing */
#define SPANS_PROBE 4 /* Exchanging status info */
#define SPANS_PROBE_INTERVAL (ATM_HZ) /* Interval between SPANS_STAT_REQs */
#define SPANS_PROBE_THRESH 10 /* Probe time-out threshold */
#define SPANS_PROBE_ERR_WAIT (3 * ATM_HZ) /* Time to wait if send probe fails */
#ifdef _KERNEL
/*
* SPANS Virtual Channel Connection control block. All information
* regarding the state of a SPANS-controlled VCC will be recorded here.
* There will be one SPANS VCC control block for each SPANS-controlled
* VCC.
*/
struct spans_vccb {
struct vccb vcp_hdr; /* Generic VCCB */
u_short sv_retry; /* Xmit retry count */
spans_atm_conn sv_conn; /* SPANS connection info */
spans_resrc sv_spans_qos; /* QoS for VCC */
spans_aal sv_spans_aal; /* AAL for VCC */
};
#define sv_type vcp_hdr.vc_type
#define sv_proto vcp_hdr.vc_proto
#define sv_sstate vcp_hdr.vc_sstate
#define sv_ustate vcp_hdr.vc_ustate
#define sv_pif vcp_hdr.vc_pif
#define sv_nif vcp_hdr.vc_nif
#define sv_sigelem vcp_hdr.vc_sigelem
#define sv_time vcp_hdr.vc_time
#define sv_vpi vcp_hdr.vc_vpi
#define sv_vci vcp_hdr.vc_vci
#define sv_connvc vcp_hdr.vc_connvc
#define sv_ipdus vcp_hdr.vc_ipdus
#define sv_opdus vcp_hdr.vc_opdus
#define sv_ibytes vcp_hdr.vc_ibytes
#define sv_obytes vcp_hdr.vc_obytes
#define sv_ierrors vcp_hdr.vc_ierrors
#define sv_oerrors vcp_hdr.vc_oerrors
#define sv_tstamp vcp_hdr.vc_tstamp
#define sv_daddr sv_conn.daddr
#define sv_saddr sv_conn.saddr
#define sv_dsap sv_conn.dsap
#define sv_ssap sv_conn.ssap
#define SV_MAX_RETRY 3
#define SV_TIMEOUT (ATM_HZ)
#endif /* _KERNEL */
/*
* SPANS VCC Signalling Protocol States
*/
#define SPANS_VC_NULL 0 /* No state */
#define SPANS_VC_ACTIVE 1 /* Active */
#define SPANS_VC_ACT_DOWN 2 /* Active - Interface down */
#define SPANS_VC_POPEN 3 /* VCC open in progress */
#define SPANS_VC_R_POPEN 4 /* VCC rmt open in progress */
#define SPANS_VC_OPEN 5 /* VCC open */
#define SPANS_VC_CLOSE 6 /* VCC close in progress */
#define SPANS_VC_ABORT 7 /* VCC abort in progress */
#define SPANS_VC_FREE 8 /* Waiting for user to free resources */
#ifdef _KERNEL
/*
* Macro to compare two SPANS addresses.
*
* Returns 0 if the addresses are equal.
*/
#define spans_addr_cmp(a, b) \
(bcmp((caddr_t)a, (caddr_t)b, sizeof(struct spans_addr)))
/*
* Macro to copy a SPANS address from a to b.
*/
#define spans_addr_copy(a, b) \
(KM_COPY((caddr_t)a, (caddr_t)b, sizeof(struct spans_addr)))
/*
* Timer macros
*/
#define SPANS_TIMER(s, t) atm_timeout(&(s)->sp_time, (t), spans_timer)
#define SPANS_CANCEL(s) atm_untimeout(&(s)->sp_time)
#define SPANS_VC_TIMER(v, t) atm_timeout(&(v)->vc_time, (t), spans_vctimer)
#define SPANS_VC_CANCEL(v) atm_untimeout(&(v)->vc_time)
/*
* Global function declarations
*/
struct ipvcc;
/* spans_arp.c */
int spansarp_svcout __P((struct ipvcc *, struct in_addr *));
int spansarp_svcin __P((struct ipvcc *, Atm_addr *, Atm_addr *));
int spansarp_svcactive __P((struct ipvcc *));
void spansarp_vcclose __P((struct ipvcc *));
void spansarp_ipact __P((struct spanscls *));
void spansarp_ipdact __P((struct spanscls *));
void spansarp_stop __P((void));
void spansarp_input __P((struct spanscls *, KBuffer *));
int spansarp_ioctl __P((int, caddr_t, caddr_t));
/* spans_cls.c */
int spanscls_start __P((void));
void spanscls_stop __P((void));
int spanscls_attach __P((struct spans *));
void spanscls_detach __P((struct spans *));
void spanscls_closevc __P((struct spanscls *,
struct t_atm_cause *));
/* spans_if.c */
int spans_abort __P((struct vccb *));
int spans_free __P((struct vccb *));
/* spans_msg.c */
int spans_send_msg __P((struct spans *, spans_msg *));
int spans_send_open_req __P((struct spans *,
struct spans_vccb *));
int spans_send_open_rsp __P((struct spans *,
struct spans_vccb *,
spans_result));
int spans_send_close_req __P((struct spans *,
struct spans_vccb *));
void spans_rcv_msg __P((struct spans *, KBuffer *));
/* spans_print.c */
void spans_print_msg __P((spans_msg *));
/* spans_proto.c */
void spans_timer __P((struct atm_time *));
void spans_vctimer __P((struct atm_time *));
void spans_upper __P((int, void *, int, int));
void spans_notify __P((void *, int, int));
/* spans_subr.c */
int spans_open_vcc __P((struct spans *, Atm_connvc *));
int spans_close_vcc __P((struct spans *,
struct spans_vccb *, int));
int spans_clear_vcc __P((struct spans *,
struct spans_vccb *));
void spans_switch_reset __P((struct spans *, int));
/* spans_util.c */
int spans_get_spans_sap __P((Sap_t, spans_sap *));
int spans_get_local_sap __P((spans_sap, Sap_t *));
int spans_ephemeral_sap __P((struct spans *));
int spans_get_spans_aal __P((Aal_t, spans_aal *));
int spans_get_local_aal __P((spans_aal, Aal_t *));
int spans_verify_vccb __P((struct spans *,
struct spans_vccb *));
struct spans_vccb *
spans_find_vpvc __P((struct spans *, int, int, u_char));
struct spans_vccb *
spans_find_conn __P((struct spans *,
struct spans_atm_conn *));
spans_vpvc spans_alloc_vpvc __P((struct spans *));
char * spans_addr_print __P((struct spans_addr *));
void spans_dump_buffer __P((KBuffer *));
/*
* External variables
*/
extern struct spans_addr spans_bcastaddr;
extern struct sp_info spans_vcpool;
extern struct sp_info spans_msgpool;
extern struct t_atm_cause spans_cause;
#endif /* _KERNEL */
#endif /* _SPANS_SPANS_VAR_H */