freebsd-dev/sys/i4b/layer1/ifpi2/i4b_ifpi2_isacsx.c

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/*
* Copyright (c) 1997, 2000 Hellmuth Michaelis. All rights reserved.
* Copyright (c) 2001 Gary Jennejohn. 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.
*
*---------------------------------------------------------------------------
*
* i4b_ifpi2_isac.c - i4b Fritz PCI Version 2 ISACSX handler
* --------------------------------------------
*
* $Id$
*
* $FreeBSD$
*
*
*---------------------------------------------------------------------------*/
#include "ifpi2.h"
#if (NIFPI2 > 0)
#include "opt_i4b.h"
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/mbuf.h>
#include <sys/socket.h>
#include <net/if.h>
#include <machine/i4b_debug.h>
#include <machine/i4b_ioctl.h>
#include <machine/i4b_trace.h>
#include <i4b/layer1/i4b_l1.h>
#include <i4b/layer1/isic/i4b_isic.h>
#include <i4b/layer1/isic/i4b_hscx.h>
#include <i4b/layer1/ifpi2/i4b_ifpi2_ext.h>
#include <i4b/layer1/ifpi2/i4b_ifpi2_isacsx.h>
#include <i4b/include/i4b_global.h>
#include <i4b/include/i4b_mbuf.h>
static u_char ifpi2_isacsx_exir_hdlr(register struct l1_softc *sc, u_char exir);
static void ifpi2_isacsx_ind_hdlr(register struct l1_softc *sc, int ind);
/* the ISACSX has 2 mask registers of interest - cannot use ISAC_IMASK */
unsigned char isacsx_imaskd;
unsigned char isacsx_imask;
/*---------------------------------------------------------------------------*
* ISACSX interrupt service routine
*---------------------------------------------------------------------------*/
void
ifpi2_isacsx_irq(struct l1_softc *sc, int ista)
{
register u_char c = 0;
register u_char istad = 0;
NDBGL1(L1_F_MSG, "unit %d: ista = 0x%02x", sc->sc_unit, ista);
/* was it an HDLC interrupt ? */
if (ista & ISACSX_ISTA_ICD)
{
istad = ISAC_READ(I_ISTAD);
NDBGL1(L1_F_MSG, "unit %d: istad = 0x%02x", sc->sc_unit, istad);
if(istad & (ISACSX_ISTAD_RFO|ISACSX_ISTAD_XMR|ISACSX_ISTAD_XDU))
{
/* not really EXIR, but very similar */
c |= ifpi2_isacsx_exir_hdlr(sc, istad);
}
}
if(istad & ISACSX_ISTAD_RME) /* receive message end */
{
register int rest;
u_char rsta;
/* get rx status register */
rsta = ISAC_READ(I_RSTAD);
/* Check for Frame and CRC valid */
if((rsta & ISACSX_RSTAD_MASK) != (ISACSX_RSTAD_VFR|ISACSX_RSTAD_CRC))
{
int error = 0;
if(!(rsta & ISACSX_RSTAD_VFR)) /* VFR error */
{
error++;
NDBGL1(L1_I_ERR, "unit %d: Frame not valid error", sc->sc_unit);
}
if(!(rsta & ISACSX_RSTAD_CRC)) /* CRC error */
{
error++;
NDBGL1(L1_I_ERR, "unit %d: CRC error", sc->sc_unit);
}
if(rsta & ISACSX_RSTAD_RDO) /* ReceiveDataOverflow */
{
error++;
NDBGL1(L1_I_ERR, "unit %d: Data Overrun error", sc->sc_unit);
}
if(rsta & ISACSX_RSTAD_RAB) /* ReceiveABorted */
{
error++;
NDBGL1(L1_I_ERR, "unit %d: Receive Aborted error", sc->sc_unit);
}
if(error == 0)
NDBGL1(L1_I_ERR, "unit %d: RME unknown error, RSTAD = 0x%02x!", sc->sc_unit, rsta);
i4b_Dfreembuf(sc->sc_ibuf);
c |= ISACSX_CMDRD_RMC|ISACSX_CMDRD_RRES;
sc->sc_ibuf = NULL;
sc->sc_ib = NULL;
sc->sc_ilen = 0;
ISAC_WRITE(I_CMDRD, ISACSX_CMDRD_RMC|ISACSX_CMDRD_RRES);
return;
}
rest = (ISAC_READ(I_RBCLD) & (ISACSX_FIFO_LEN-1));
if(rest == 0)
rest = ISACSX_FIFO_LEN;
if(sc->sc_ibuf == NULL)
{
if((sc->sc_ibuf = i4b_Dgetmbuf(rest)) != NULL)
sc->sc_ib = sc->sc_ibuf->m_data;
else
panic("ifpi2_isacsx_irq: RME, i4b_Dgetmbuf returns NULL!\n");
sc->sc_ilen = 0;
}
if(sc->sc_ilen <= (MAX_DFRAME_LEN - rest))
{
ISAC_RDFIFO(sc->sc_ib, rest);
/* the last byte contains status, strip it */
sc->sc_ilen += rest - 1;
sc->sc_ibuf->m_pkthdr.len =
sc->sc_ibuf->m_len = sc->sc_ilen;
if(sc->sc_trace & TRACE_D_RX)
{
i4b_trace_hdr_t hdr;
hdr.unit = L0IFPI2UNIT(sc->sc_unit);
hdr.type = TRC_CH_D;
hdr.dir = FROM_NT;
hdr.count = ++sc->sc_trace_dcount;
MICROTIME(hdr.time);
i4b_l1_trace_ind(&hdr, sc->sc_ibuf->m_len, sc->sc_ibuf->m_data);
}
c |= ISACSX_CMDRD_RMC;
if(sc->sc_enabled &&
(ctrl_desc[sc->sc_unit].protocol != PROTOCOL_D64S))
{
i4b_l1_ph_data_ind(L0IFPI2UNIT(sc->sc_unit), sc->sc_ibuf);
}
else
{
i4b_Dfreembuf(sc->sc_ibuf);
}
}
else
{
NDBGL1(L1_I_ERR, "RME, input buffer overflow!");
i4b_Dfreembuf(sc->sc_ibuf);
c |= ISACSX_CMDRD_RMC|ISACSX_CMDRD_RRES;
}
sc->sc_ibuf = NULL;
sc->sc_ib = NULL;
sc->sc_ilen = 0;
}
if(istad & ISACSX_ISTAD_RPF) /* receive fifo full */
{
if(sc->sc_ibuf == NULL)
{
if((sc->sc_ibuf = i4b_Dgetmbuf(MAX_DFRAME_LEN)) != NULL)
sc->sc_ib= sc->sc_ibuf->m_data;
else
panic("ifpi2_isacsx_irq: RPF, i4b_Dgetmbuf returns NULL!\n");
sc->sc_ilen = 0;
}
if(sc->sc_ilen <= (MAX_DFRAME_LEN - ISACSX_FIFO_LEN))
{
ISAC_RDFIFO(sc->sc_ib, ISACSX_FIFO_LEN);
sc->sc_ilen += ISACSX_FIFO_LEN;
sc->sc_ib += ISACSX_FIFO_LEN;
c |= ISACSX_CMDRD_RMC;
}
else
{
NDBGL1(L1_I_ERR, "RPF, input buffer overflow!");
i4b_Dfreembuf(sc->sc_ibuf);
sc->sc_ibuf = NULL;
sc->sc_ib = NULL;
sc->sc_ilen = 0;
c |= ISACSX_CMDRD_RMC|ISACSX_CMDRD_RRES;
}
}
if(istad & ISACSX_ISTAD_XPR) /* transmit fifo empty (XPR bit set) */
{
if((sc->sc_obuf2 != NULL) && (sc->sc_obuf == NULL))
{
sc->sc_freeflag = sc->sc_freeflag2;
sc->sc_obuf = sc->sc_obuf2;
sc->sc_op = sc->sc_obuf->m_data;
sc->sc_ol = sc->sc_obuf->m_len;
sc->sc_obuf2 = NULL;
#ifdef NOTDEF
printf("ob2=%x, op=%x, ol=%d, f=%d #",
sc->sc_obuf,
sc->sc_op,
sc->sc_ol,
sc->sc_state);
#endif
}
else
{
#ifdef NOTDEF
printf("ob=%x, op=%x, ol=%d, f=%d #",
sc->sc_obuf,
sc->sc_op,
sc->sc_ol,
sc->sc_state);
#endif
}
if(sc->sc_obuf)
{
ISAC_WRFIFO(sc->sc_op, min(sc->sc_ol, ISACSX_FIFO_LEN));
if(sc->sc_ol > ISACSX_FIFO_LEN) /* length > 32 ? */
{
sc->sc_op += ISACSX_FIFO_LEN; /* bufferptr+32 */
sc->sc_ol -= ISACSX_FIFO_LEN; /* length - 32 */
c |= ISACSX_CMDRD_XTF; /* set XTF bit */
}
else
{
if(sc->sc_freeflag)
{
i4b_Dfreembuf(sc->sc_obuf);
sc->sc_freeflag = 0;
}
sc->sc_obuf = NULL;
sc->sc_op = NULL;
sc->sc_ol = 0;
c |= ISACSX_CMDRD_XTF | ISACSX_CMDRD_XME;
}
}
else
{
sc->sc_state &= ~ISAC_TX_ACTIVE;
}
}
if(ista & ISACSX_ISTA_CIC) /* channel status change CISQ */
{
register u_char ci;
/* get command/indication rx register*/
ci = ISAC_READ(I_CIR0);
/* C/I code change IRQ (flag already cleared by CIR0 read) */
if(ci & ISACSX_CIR0_CIC0)
ifpi2_isacsx_ind_hdlr(sc, (ci >> 4) & 0xf);
}
if(c)
{
ISAC_WRITE(I_CMDRD, c);
}
}
/*---------------------------------------------------------------------------*
* ISACSX L1 Extended IRQ handler
*---------------------------------------------------------------------------*/
static u_char
ifpi2_isacsx_exir_hdlr(register struct l1_softc *sc, u_char exir)
{
u_char c = 0;
if(exir & ISACSX_ISTAD_XMR)
{
NDBGL1(L1_I_ERR, "EXIRQ Tx Message Repeat");
c |= ISACSX_CMDRD_XRES;
}
if(exir & ISACSX_ISTAD_XDU)
{
NDBGL1(L1_I_ERR, "EXIRQ Tx Data Underrun");
c |= ISACSX_CMDRD_XRES;
}
if(exir & ISACSX_ISTAD_RFO)
{
NDBGL1(L1_I_ERR, "EXIRQ Rx Frame Overflow");
c |= ISACSX_CMDRD_RMC;
}
#if 0 /* all blocked per default */
if(exir & ISACSX_EXIR_SOV)
{
NDBGL1(L1_I_ERR, "EXIRQ Sync Xfer Overflow");
}
if(exir & ISACSX_EXIR_MOS)
{
NDBGL1(L1_I_ERR, "EXIRQ Monitor Status");
}
if(exir & ISACSX_EXIR_SAW)
{
/* cannot happen, STCR:TSF is set to 0 */
NDBGL1(L1_I_ERR, "EXIRQ Subscriber Awake");
}
if(exir & ISACSX_EXIR_WOV)
{
/* cannot happen, STCR:TSF is set to 0 */
NDBGL1(L1_I_ERR, "EXIRQ Watchdog Timer Overflow");
}
#endif
return(c);
}
/*---------------------------------------------------------------------------*
* ISACSX L1 Indication handler
*---------------------------------------------------------------------------*/
static void
ifpi2_isacsx_ind_hdlr(register struct l1_softc *sc, int ind)
{
register int event;
switch(ind)
{
case ISACSX_CIR0_IAI8:
NDBGL1(L1_I_CICO, "rx AI8 in state %s", ifpi2_printstate(sc));
if(sc->sc_bustyp == BUS_TYPE_IOM2)
ifpi2_isacsx_l1_cmd(sc, CMD_AR8);
event = EV_INFO48;
i4b_l1_mph_status_ind(L0IFPI2UNIT(sc->sc_unit), STI_L1STAT, LAYER_ACTIVE, NULL);
break;
case ISACSX_CIR0_IAI10:
NDBGL1(L1_I_CICO, "rx AI10 in state %s", ifpi2_printstate(sc));
if(sc->sc_bustyp == BUS_TYPE_IOM2)
ifpi2_isacsx_l1_cmd(sc, CMD_AR10);
event = EV_INFO410;
i4b_l1_mph_status_ind(L0IFPI2UNIT(sc->sc_unit), STI_L1STAT, LAYER_ACTIVE, NULL);
break;
case ISACSX_CIR0_IRSY:
NDBGL1(L1_I_CICO, "rx RSY in state %s", ifpi2_printstate(sc));
event = EV_RSY;
break;
case ISACSX_CIR0_IPU:
NDBGL1(L1_I_CICO, "rx PU in state %s", ifpi2_printstate(sc));
event = EV_PU;
break;
case ISACSX_CIR0_IDR:
NDBGL1(L1_I_CICO, "rx DR in state %s", ifpi2_printstate(sc));
ifpi2_isacsx_l1_cmd(sc, CMD_DIU);
event = EV_DR;
break;
case ISACSX_CIR0_IDID:
NDBGL1(L1_I_CICO, "rx DID in state %s", ifpi2_printstate(sc));
event = EV_INFO0;
i4b_l1_mph_status_ind(L0IFPI2UNIT(sc->sc_unit), STI_L1STAT, LAYER_IDLE, NULL);
break;
case ISACSX_CIR0_IDIS:
NDBGL1(L1_I_CICO, "rx DIS in state %s", ifpi2_printstate(sc));
event = EV_DIS;
break;
case ISACSX_CIR0_IEI:
NDBGL1(L1_I_CICO, "rx EI in state %s", ifpi2_printstate(sc));
ifpi2_isacsx_l1_cmd(sc, CMD_DIU);
event = EV_EI;
break;
case ISACSX_CIR0_IARD:
NDBGL1(L1_I_CICO, "rx ARD in state %s", ifpi2_printstate(sc));
event = EV_INFO2;
break;
case ISACSX_CIR0_ITI:
NDBGL1(L1_I_CICO, "rx TI in state %s", ifpi2_printstate(sc));
event = EV_INFO0;
break;
case ISACSX_CIR0_IATI:
NDBGL1(L1_I_CICO, "rx ATI in state %s", ifpi2_printstate(sc));
event = EV_INFO0;
break;
case ISACSX_CIR0_ISD:
NDBGL1(L1_I_CICO, "rx SD in state %s", ifpi2_printstate(sc));
event = EV_INFO0;
break;
default:
NDBGL1(L1_I_ERR, "UNKNOWN Indication 0x%x in state %s", ind, ifpi2_printstate(sc));
event = EV_INFO0;
break;
}
ifpi2_next_state(sc, event);
}
/*---------------------------------------------------------------------------*
* execute a layer 1 command
*---------------------------------------------------------------------------*/
void
ifpi2_isacsx_l1_cmd(struct l1_softc *sc, int command)
{
u_char cmd;
#ifdef I4B_SMP_WORKAROUND
/* XXXXXXXXXXXXXXXXXXX */
/*
* patch from Wolfgang Helbig:
*
* Here is a patch that makes i4b work on an SMP:
* The card (TELES 16.3) didn't interrupt on an SMP machine.
* This is a gross workaround, but anyway it works *and* provides
* some information as how to finally fix this problem.
*/
HSCX_WRITE(0, H_MASK, 0xff);
HSCX_WRITE(1, H_MASK, 0xff);
ISAC_WRITE(I_MASKD, 0xff);
ISAC_WRITE(I_MASK, 0xff);
DELAY(100);
HSCX_WRITE(0, H_MASK, HSCX_A_IMASK);
HSCX_WRITE(1, H_MASK, HSCX_B_IMASK);
ISAC_WRITE(I_MASKD, isacsx_imaskd);
ISAC_WRITE(I_MASK, isacsx_imask);
/* XXXXXXXXXXXXXXXXXXX */
#endif /* I4B_SMP_WORKAROUND */
if(command < 0 || command > CMD_ILL)
{
NDBGL1(L1_I_ERR, "illegal cmd 0x%x in state %s", command, ifpi2_printstate(sc));
return;
}
cmd = ISACSX_CIX0_LOW;
switch(command)
{
case CMD_TIM:
NDBGL1(L1_I_CICO, "tx TIM in state %s", ifpi2_printstate(sc));
cmd |= (ISACSX_CIX0_CTIM << 4);
break;
case CMD_RS:
NDBGL1(L1_I_CICO, "tx RS in state %s", ifpi2_printstate(sc));
cmd |= (ISACSX_CIX0_CRS << 4);
break;
case CMD_AR8:
NDBGL1(L1_I_CICO, "tx AR8 in state %s", ifpi2_printstate(sc));
cmd |= (ISACSX_CIX0_CAR8 << 4);
break;
case CMD_AR10:
NDBGL1(L1_I_CICO, "tx AR10 in state %s", ifpi2_printstate(sc));
cmd |= (ISACSX_CIX0_CAR10 << 4);
break;
case CMD_DIU:
NDBGL1(L1_I_CICO, "tx DIU in state %s", ifpi2_printstate(sc));
cmd |= (ISACSX_CIX0_CDIU << 4);
break;
}
ISAC_WRITE(I_CIX0, cmd);
}
/*---------------------------------------------------------------------------*
* L1 ISACSX initialization
*---------------------------------------------------------------------------*/
int
ifpi2_isacsx_init(struct l1_softc *sc)
{
isacsx_imaskd = 0xff; /* disable all irqs */
isacsx_imask = 0xff; /* disable all irqs */
ISAC_WRITE(I_MASKD, isacsx_imaskd);
ISAC_WRITE(I_MASK, isacsx_imask);
/* the ISACSX only runs in IOM-2 mode */
NDBGL1(L1_I_SETUP, "configuring for IOM-2 mode");
/* TR_CONF0: Transceiver Configuration Register 0:
* DIS_TR - transceiver enabled
* EN_ICV - normal operation
* EXLP - no external loop
* LDD - automatic clock generation
*/
ISAC_WRITE(I_WTR_CONF0, 0);
/* TR_CONF2: Transceiver Configuration Register 1:
* DIS_TX - transmitter enabled
* PDS - phase deviation 2 S-bits
* RLP - remote line loop open
*/
ISAC_WRITE(I_WTR_CONF2, 0);
/* MODED: Mode Register:
* MDSx - transparent mode 0
* TMD - timer mode = external
* RAC - Receiver enabled
* DIMx - digital i/f mode
*/
ISAC_WRITE(I_WMODED, ISACSX_MODED_MDS2|ISACSX_MODED_MDS1|ISACSX_MODED_RAC|ISACSX_MODED_DIM0);
/* enabled interrupts:
* ===================
* RME - receive message end
* RPF - receive pool full
* RPO - receive pool overflow
* XPR - transmit pool ready
* XMR - transmit message repeat
* XDU - transmit data underrun
*/
isacsx_imaskd = ISACSX_MASKD_LOW;
ISAC_WRITE(I_MASKD, isacsx_imaskd);
/* enabled interrupts:
* ===================
* ICD - HDLC interrupt from D-channel
* CIC - C/I channel change
*/
isacsx_imask = ~(ISACSX_MASK_ICD | ISACSX_MASK_CIC);
ISAC_WRITE(I_MASK, isacsx_imask);
return(0);
}
#endif /* NIFPI2 > 0 */