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kernel / pub / scm / linux / kernel / git / iwlwifi / iwlwifi-next / 1da177e4c3f41524e886b7f1b8a0c1fc7321cac2 / . / drivers / net / skfp / drvfbi.c
blob: 052e841ba187176fcb89d43f2775120e16f651e8 [file] [log] [blame]
/******************************************************************************
*
* (C)Copyright 1998,1999 SysKonnect,
* a business unit of Schneider & Koch & Co. Datensysteme GmbH.
*
* See the file "skfddi.c" for further information.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* The information in this file is provided "AS IS" without warranty.
*
******************************************************************************/
/*
* FBI board dependent Driver for SMT and LLC
*/
#include "h/types.h"
#include "h/fddi.h"
#include "h/smc.h"
#include "h/supern_2.h"
#include "h/skfbiinc.h"
#ifndef lint
static const char ID_sccs[] = "@(#)drvfbi.c 1.63 99/02/11 (C) SK " ;
#endif
/*
* PCM active state
*/
#define PC8_ACTIVE 8
#define LED_Y_ON 0x11 /* Used for ring up/down indication */
#define LED_Y_OFF 0x10
#define MS2BCLK(x) ((x)*12500L)
/*
* valid configuration values are:
*/
#ifdef ISA
const int opt_ints[] = {8, 3, 4, 5, 9, 10, 11, 12, 15} ;
const int opt_iops[] = {8,
0x100, 0x120, 0x180, 0x1a0, 0x220, 0x240, 0x320, 0x340};
const int opt_dmas[] = {4, 3, 5, 6, 7} ;
const int opt_eproms[] = {15, 0xc0, 0xc2, 0xc4, 0xc6, 0xc8, 0xca, 0xcc, 0xce,
0xd0, 0xd2, 0xd4, 0xd6, 0xd8, 0xda, 0xdc} ;
#endif
#ifdef EISA
const int opt_ints[] = {5, 9, 10, 11} ;
const int opt_dmas[] = {0, 5, 6, 7} ;
const int opt_eproms[] = {0xc0, 0xc2, 0xc4, 0xc6, 0xc8, 0xca, 0xcc, 0xce,
0xd0, 0xd2, 0xd4, 0xd6, 0xd8, 0xda, 0xdc} ;
#endif
#ifdef MCA
int opt_ints[] = {3, 11, 10, 9} ; /* FM1 */
int opt_eproms[] = {0, 0xc4, 0xc8, 0xcc, 0xd0, 0xd4, 0xd8, 0xdc} ;
#endif /* MCA */
/*
* xPOS_ID:xxxx
* | \ /
* | \/
* | --------------------- the patched POS_ID of the Adapter
* | xxxx = (Vendor ID low byte,
* | Vendor ID high byte,
* | Device ID low byte,
* | Device ID high byte)
* +------------------------------ the patched oem_id must be
* 'S' for SK or 'I' for IBM
* this is a short id for the driver.
*/
#ifndef MULT_OEM
#ifndef OEM_CONCEPT
#ifndef MCA
const u_char oem_id[] = "xPOS_ID:xxxx" ;
#else
const u_char oem_id[] = "xPOSID1:xxxx" ; /* FM1 card id. */
#endif
#else /* OEM_CONCEPT */
#ifndef MCA
const u_char oem_id[] = OEM_ID ;
#else
const u_char oem_id[] = OEM_ID1 ; /* FM1 card id. */
#endif /* MCA */
#endif /* OEM_CONCEPT */
#define ID_BYTE0 8
#define OEMID(smc,i) oem_id[ID_BYTE0 + i]
#else /* MULT_OEM */
const struct s_oem_ids oem_ids[] = {
#include "oemids.h"
{0}
};
#define OEMID(smc,i) smc->hw.oem_id->oi_id[i]
#endif /* MULT_OEM */
/* Prototypes of external functions */
#ifdef AIX
extern int AIX_vpdReadByte() ;
#endif
/* Prototypes of local functions. */
void smt_stop_watchdog(struct s_smc *smc);
#ifdef MCA
static int read_card_id() ;
static void DisableSlotAccess() ;
static void EnableSlotAccess() ;
#ifdef AIX
extern int attach_POS_addr() ;
extern int detach_POS_addr() ;
extern u_char read_POS() ;
extern void write_POS() ;
extern int AIX_vpdReadByte() ;
#else
#define read_POS(smc,a1,a2) ((u_char) inp(a1))
#define write_POS(smc,a1,a2,a3) outp((a1),(a3))
#endif
#endif /* MCA */
/*
* FDDI card reset
*/
static void card_start(struct s_smc *smc)
{
int i ;
#ifdef PCI
u_char rev_id ;
u_short word;
#endif
smt_stop_watchdog(smc) ;
#ifdef ISA
outpw(CSR_A,0) ; /* reset for all chips */
for (i = 10 ; i ; i--) /* delay for PLC's */
(void)inpw(ISR_A) ;
OUT_82c54_TIMER(3,COUNT(2) | RW_OP(3) | TMODE(2)) ;
/* counter 2, mode 2 */
OUT_82c54_TIMER(2,97) ; /* LSB */
OUT_82c54_TIMER(2,0) ; /* MSB ( 15.6 us ) */
outpw(CSR_A,CS_CRESET) ;
#endif
#ifdef EISA
outpw(CSR_A,0) ; /* reset for all chips */
for (i = 10 ; i ; i--) /* delay for PLC's */
(void)inpw(ISR_A) ;
outpw(CSR_A,CS_CRESET) ;
smc->hw.led = (2<<6) ;
outpw(CSR_A,CS_CRESET | smc->hw.led) ;
#endif
#ifdef MCA
outp(ADDR(CARD_DIS),0) ; /* reset for all chips */
for (i = 10 ; i ; i--) /* delay for PLC's */
(void)inpw(ISR_A) ;
outp(ADDR(CARD_EN),0) ;
/* first I/O after reset must not be a access to FORMAC or PLC */
/*
* bus timeout (MCA)
*/
OUT_82c54_TIMER(3,COUNT(2) | RW_OP(3) | TMODE(3)) ;
/* counter 2, mode 3 */
OUT_82c54_TIMER(2,(2*24)) ; /* 3.9 us * 2 square wave */
OUT_82c54_TIMER(2,0) ; /* MSB */
/* POS 102 indicated an activ Check Line or Buss Error monitoring */
if (inpw(CSA_A) & (POS_EN_CHKINT | POS_EN_BUS_ERR)) {
outp(ADDR(IRQ_CHCK_EN),0) ;
}
if (!((i = inpw(CSR_A)) & CS_SAS)) {
if (!(i & CS_BYSTAT)) {
outp(ADDR(BYPASS(STAT_INS)),0) ;/* insert station */
}
}
outpw(LEDR_A,LED_1) ; /* yellow */
#endif /* MCA */
#ifdef PCI
/*
* make sure no transfer activity is pending
*/
outpw(FM_A(FM_MDREG1),FM_MINIT) ;
outp(ADDR(B0_CTRL), CTRL_HPI_SET) ;
hwt_wait_time(smc,hwt_quick_read(smc),MS2BCLK(10)) ;
/*
* now reset everything
*/
outp(ADDR(B0_CTRL),CTRL_RST_SET) ; /* reset for all chips */
i = (int) inp(ADDR(B0_CTRL)) ; /* do dummy read */
SK_UNUSED(i) ; /* Make LINT happy. */
outp(ADDR(B0_CTRL), CTRL_RST_CLR) ;
/*
* Reset all bits in the PCI STATUS register
*/
outp(ADDR(B0_TST_CTRL), TST_CFG_WRITE_ON) ; /* enable for writes */
word = inpw(PCI_C(PCI_STATUS)) ;
outpw(PCI_C(PCI_STATUS), word | PCI_ERRBITS) ;
outp(ADDR(B0_TST_CTRL), TST_CFG_WRITE_OFF) ; /* disable writes */
/*
* Release the reset of all the State machines
* Release Master_Reset
* Release HPI_SM_Reset
*/
outp(ADDR(B0_CTRL), CTRL_MRST_CLR|CTRL_HPI_CLR) ;
/*
* determine the adapter type
* Note: Do it here, because some drivers may call card_start() once
* at very first before any other initialization functions is
* executed.
*/
rev_id = inp(PCI_C(PCI_REV_ID)) ;
if ((rev_id & 0xf0) == SK_ML_ID_1 || (rev_id & 0xf0) == SK_ML_ID_2) {
smc->hw.hw_is_64bit = TRUE ;
} else {
smc->hw.hw_is_64bit = FALSE ;
}
/*
* Watermark initialization
*/
if (!smc->hw.hw_is_64bit) {
outpd(ADDR(B4_R1_F), RX_WATERMARK) ;
outpd(ADDR(B5_XA_F), TX_WATERMARK) ;
outpd(ADDR(B5_XS_F), TX_WATERMARK) ;
}
outp(ADDR(B0_CTRL),CTRL_RST_CLR) ; /* clear the reset chips */
outp(ADDR(B0_LED),LED_GA_OFF|LED_MY_ON|LED_GB_OFF) ; /* ye LED on */
/* init the timer value for the watch dog 2,5 minutes */
outpd(ADDR(B2_WDOG_INI),0x6FC23AC0) ;
/* initialize the ISR mask */
smc->hw.is_imask = ISR_MASK ;
smc->hw.hw_state = STOPPED ;
#endif
GET_PAGE(0) ; /* necessary for BOOT */
}
void card_stop(struct s_smc *smc)
{
smt_stop_watchdog(smc) ;
smc->hw.mac_ring_is_up = 0 ; /* ring down */
#ifdef ISA
outpw(CSR_A,0) ; /* reset for all chips */
#endif
#ifdef EISA
outpw(CSR_A,0) ; /* reset for all chips */
#endif
#ifdef MCA
outp(ADDR(CARD_DIS),0) ; /* reset for all chips */
#endif
#ifdef PCI
/*
* make sure no transfer activity is pending
*/
outpw(FM_A(FM_MDREG1),FM_MINIT) ;
outp(ADDR(B0_CTRL), CTRL_HPI_SET) ;
hwt_wait_time(smc,hwt_quick_read(smc),MS2BCLK(10)) ;
/*
* now reset everything
*/
outp(ADDR(B0_CTRL),CTRL_RST_SET) ; /* reset for all chips */
outp(ADDR(B0_CTRL),CTRL_RST_CLR) ; /* reset for all chips */
outp(ADDR(B0_LED),LED_GA_OFF|LED_MY_OFF|LED_GB_OFF) ; /* all LEDs off */
smc->hw.hw_state = STOPPED ;
#endif
}
/*--------------------------- ISR handling ----------------------------------*/
void mac1_irq(struct s_smc *smc, u_short stu, u_short stl)
{
int restart_tx = 0 ;
again:
#ifndef PCI
#ifndef ISA
/*
* FORMAC+ bug modified the queue pointer if many read/write accesses happens!?
*/
if (stl & (FM_SPCEPDS | /* parit/coding err. syn.q.*/
FM_SPCEPDA0 | /* parit/coding err. a.q.0 */
FM_SPCEPDA1 | /* parit/coding err. a.q.1 */
FM_SPCEPDA2)) { /* parit/coding err. a.q.2 */
SMT_PANIC(smc,SMT_E0132, SMT_E0132_MSG) ;
}
if (stl & (FM_STBURS | /* tx buffer underrun syn.q.*/
FM_STBURA0 | /* tx buffer underrun a.q.0 */
FM_STBURA1 | /* tx buffer underrun a.q.1 */
FM_STBURA2)) { /* tx buffer underrun a.q.2 */
SMT_PANIC(smc,SMT_E0133, SMT_E0133_MSG) ;
}
#endif
if ( (stu & (FM_SXMTABT | /* transmit abort */
#ifdef SYNC
FM_STXABRS | /* syn. tx abort */
#endif /* SYNC */
FM_STXABRA0)) || /* asyn. tx abort */
(stl & (FM_SQLCKS | /* lock for syn. q. */
FM_SQLCKA0)) ) { /* lock for asyn. q. */
formac_tx_restart(smc) ; /* init tx */
restart_tx = 1 ;
stu = inpw(FM_A(FM_ST1U)) ;
stl = inpw(FM_A(FM_ST1L)) ;
stu &= ~ (FM_STECFRMA0 | FM_STEFRMA0 | FM_STEFRMS) ;
if (stu || stl)
goto again ;
}
#ifndef SYNC
if (stu & (FM_STECFRMA0 | /* end of chain asyn tx */
FM_STEFRMA0)) { /* end of frame asyn tx */
/* free tx_queue */
smc->hw.n_a_send = 0 ;
if (++smc->hw.fp.tx_free < smc->hw.fp.tx_max) {
start_next_send(smc);
}
restart_tx = 1 ;
}
#else /* SYNC */
if (stu & (FM_STEFRMA0 | /* end of asyn tx */
FM_STEFRMS)) { /* end of sync tx */
restart_tx = 1 ;
}
#endif /* SYNC */
if (restart_tx)
llc_restart_tx(smc) ;
}
#else /* PCI */
/*
* parity error: note encoding error is not possible in tag mode
*/
if (stl & (FM_SPCEPDS | /* parity err. syn.q.*/
FM_SPCEPDA0 | /* parity err. a.q.0 */
FM_SPCEPDA1)) { /* parity err. a.q.1 */
SMT_PANIC(smc,SMT_E0134, SMT_E0134_MSG) ;
}
/*
* buffer underrun: can only occur if a tx threshold is specified
*/
if (stl & (FM_STBURS | /* tx buffer underrun syn.q.*/
FM_STBURA0 | /* tx buffer underrun a.q.0 */
FM_STBURA1)) { /* tx buffer underrun a.q.2 */
SMT_PANIC(smc,SMT_E0133, SMT_E0133_MSG) ;
}
if ( (stu & (FM_SXMTABT | /* transmit abort */
FM_STXABRS | /* syn. tx abort */
FM_STXABRA0)) || /* asyn. tx abort */
(stl & (FM_SQLCKS | /* lock for syn. q. */
FM_SQLCKA0)) ) { /* lock for asyn. q. */
formac_tx_restart(smc) ; /* init tx */
restart_tx = 1 ;
stu = inpw(FM_A(FM_ST1U)) ;
stl = inpw(FM_A(FM_ST1L)) ;
stu &= ~ (FM_STECFRMA0 | FM_STEFRMA0 | FM_STEFRMS) ;
if (stu || stl)
goto again ;
}
if (stu & (FM_STEFRMA0 | /* end of asyn tx */
FM_STEFRMS)) { /* end of sync tx */
restart_tx = 1 ;
}
if (restart_tx)
llc_restart_tx(smc) ;
}
#endif /* PCI */
/*
* interrupt source= plc1
* this function is called in nwfbisr.asm
*/
void plc1_irq(struct s_smc *smc)
{
u_short st = inpw(PLC(PB,PL_INTR_EVENT)) ;
#if (defined(ISA) || defined(EISA))
/* reset PLC Int. bits */
outpw(PLC1_I,inpw(PLC1_I)) ;
#endif
plc_irq(smc,PB,st) ;
}
/*
* interrupt source= plc2
* this function is called in nwfbisr.asm
*/
void plc2_irq(struct s_smc *smc)
{
u_short st = inpw(PLC(PA,PL_INTR_EVENT)) ;
#if (defined(ISA) || defined(EISA))
/* reset PLC Int. bits */
outpw(PLC2_I,inpw(PLC2_I)) ;
#endif
plc_irq(smc,PA,st) ;
}
/*
* interrupt source= timer
*/
void timer_irq(struct s_smc *smc)
{
hwt_restart(smc);
smc->hw.t_stop = smc->hw.t_start;
smt_timer_done(smc) ;
}
/*
* return S-port (PA or PB)
*/
int pcm_get_s_port(struct s_smc *smc)
{
SK_UNUSED(smc) ;
return(PS) ;
}
/*
* Station Label = "FDDI-XYZ" where
*
* X = connector type
* Y = PMD type
* Z = port type
*/
#define STATION_LABEL_CONNECTOR_OFFSET 5
#define STATION_LABEL_PMD_OFFSET 6
#define STATION_LABEL_PORT_OFFSET 7
void read_address(struct s_smc *smc, u_char *mac_addr)
{
char ConnectorType ;
char PmdType ;
int i ;
extern const u_char canonical[256] ;
#if (defined(ISA) || defined(MCA))
for (i = 0; i < 4 ;i++) { /* read mac address from board */
smc->hw.fddi_phys_addr.a[i] =
canonical[(inpw(PR_A(i+SA_MAC))&0xff)] ;
}
for (i = 4; i < 6; i++) {
smc->hw.fddi_phys_addr.a[i] =
canonical[(inpw(PR_A(i+SA_MAC+PRA_OFF))&0xff)] ;
}
#endif
#ifdef EISA
/*
* Note: We get trouble on an Alpha machine if we make a inpw()
* instead of inp()
*/
for (i = 0; i < 4 ;i++) { /* read mac address from board */
smc->hw.fddi_phys_addr.a[i] =
canonical[inp(PR_A(i+SA_MAC))] ;
}
for (i = 4; i < 6; i++) {
smc->hw.fddi_phys_addr.a[i] =
canonical[inp(PR_A(i+SA_MAC+PRA_OFF))] ;
}
#endif
#ifdef PCI
for (i = 0; i < 6; i++) { /* read mac address from board */
smc->hw.fddi_phys_addr.a[i] =
canonical[inp(ADDR(B2_MAC_0+i))] ;
}
#endif
#ifndef PCI
ConnectorType = inpw(PR_A(SA_PMD_TYPE)) & 0xff ;
PmdType = inpw(PR_A(SA_PMD_TYPE+1)) & 0xff ;
#else
ConnectorType = inp(ADDR(B2_CONN_TYP)) ;
PmdType = inp(ADDR(B2_PMD_TYP)) ;
#endif
smc->y[PA].pmd_type[PMD_SK_CONN] =
smc->y[PB].pmd_type[PMD_SK_CONN] = ConnectorType ;
smc->y[PA].pmd_type[PMD_SK_PMD ] =
smc->y[PB].pmd_type[PMD_SK_PMD ] = PmdType ;
if (mac_addr) {
for (i = 0; i < 6 ;i++) {
smc->hw.fddi_canon_addr.a[i] = mac_addr[i] ;
smc->hw.fddi_home_addr.a[i] = canonical[mac_addr[i]] ;
}
return ;
}
smc->hw.fddi_home_addr = smc->hw.fddi_phys_addr ;
for (i = 0; i < 6 ;i++) {
smc->hw.fddi_canon_addr.a[i] =
canonical[smc->hw.fddi_phys_addr.a[i]] ;
}
}
/*
* FDDI card soft reset
*/
void init_board(struct s_smc *smc, u_char *mac_addr)
{
card_start(smc) ;
read_address(smc,mac_addr) ;
#ifndef PCI
if (inpw(CSR_A) & CS_SAS)
#else
if (!(inp(ADDR(B0_DAS)) & DAS_AVAIL))
#endif
smc->s.sas = SMT_SAS ; /* Single att. station */
else
smc->s.sas = SMT_DAS ; /* Dual att. station */
#ifndef PCI
if (inpw(CSR_A) & CS_BYSTAT)
#else
if (!(inp(ADDR(B0_DAS)) & DAS_BYP_ST))
#endif
smc->mib.fddiSMTBypassPresent = 0 ;
/* without opt. bypass */
else
smc->mib.fddiSMTBypassPresent = 1 ;
/* with opt. bypass */
}
/*
* insert or deinsert optical bypass (called by ECM)
*/
void sm_pm_bypass_req(struct s_smc *smc, int mode)
{
#if (defined(ISA) || defined(EISA))
int csra_v ;
#endif
DB_ECMN(1,"ECM : sm_pm_bypass_req(%s)\n",(mode == BP_INSERT) ?
"BP_INSERT" : "BP_DEINSERT",0) ;
if (smc->s.sas != SMT_DAS)
return ;
#if (defined(ISA) || defined(EISA))
csra_v = inpw(CSR_A) & ~CS_BYPASS ;
#ifdef EISA
csra_v |= smc->hw.led ;
#endif
switch(mode) {
case BP_INSERT :
outpw(CSR_A,csra_v | CS_BYPASS) ;
break ;
case BP_DEINSERT :
outpw(CSR_A,csra_v) ;
break ;
}
#endif /* ISA / EISA */
#ifdef MCA
switch(mode) {
case BP_INSERT :
outp(ADDR(BYPASS(STAT_INS)),0) ;/* insert station */
break ;
case BP_DEINSERT :
outp(ADDR(BYPASS(STAT_BYP)),0) ; /* bypass station */
break ;
}
#endif
#ifdef PCI
switch(mode) {
case BP_INSERT :
outp(ADDR(B0_DAS),DAS_BYP_INS) ; /* insert station */
break ;
case BP_DEINSERT :
outp(ADDR(B0_DAS),DAS_BYP_RMV) ; /* bypass station */
break ;
}
#endif
}
/*
* check if bypass connected
*/
int sm_pm_bypass_present(struct s_smc *smc)
{
#ifndef PCI
return( (inpw(CSR_A) & CS_BYSTAT) ? FALSE : TRUE ) ;
#else
return( (inp(ADDR(B0_DAS)) & DAS_BYP_ST) ? TRUE: FALSE) ;
#endif
}
void plc_clear_irq(struct s_smc *smc, int p)
{
SK_UNUSED(p) ;
#if (defined(ISA) || defined(EISA))
switch (p) {
case PA :
/* reset PLC Int. bits */
outpw(PLC2_I,inpw(PLC2_I)) ;
break ;
case PB :
/* reset PLC Int. bits */
outpw(PLC1_I,inpw(PLC1_I)) ;
break ;
}
#else
SK_UNUSED(smc) ;
#endif
}
/*
* led_indication called by rmt_indication() and
* pcm_state_change()
*
* Input:
* smc: SMT context
* led_event:
* 0 Only switch green LEDs according to their respective PCM state
* LED_Y_OFF just switch yellow LED off
* LED_Y_ON just switch yello LED on
*/
void led_indication(struct s_smc *smc, int led_event)
{
/* use smc->hw.mac_ring_is_up == TRUE
* as indication for Ring Operational
*/
u_short led_state ;
struct s_phy *phy ;
struct fddi_mib_p *mib_a ;
struct fddi_mib_p *mib_b ;
phy = &smc->y[PA] ;
mib_a = phy->mib ;
phy = &smc->y[PB] ;
mib_b = phy->mib ;
#ifdef EISA
/* Ring up = yellow led OFF*/
if (led_event == LED_Y_ON) {
smc->hw.led |= CS_LED_1 ;
}
else if (led_event == LED_Y_OFF) {
smc->hw.led &= ~CS_LED_1 ;
}
else {
/* Link at Port A or B = green led ON */
if (mib_a->fddiPORTPCMState == PC8_ACTIVE ||
mib_b->fddiPORTPCMState == PC8_ACTIVE) {
smc->hw.led |= CS_LED_0 ;
}
else {
smc->hw.led &= ~CS_LED_0 ;
}
}
#endif
#ifdef MCA
led_state = inpw(LEDR_A) ;
/* Ring up = yellow led OFF*/
if (led_event == LED_Y_ON) {
led_state |= LED_1 ;
}
else if (led_event == LED_Y_OFF) {
led_state &= ~LED_1 ;
}
else {
led_state &= ~(LED_2|LED_0) ;
/* Link at Port A = green led A ON */
if (mib_a->fddiPORTPCMState == PC8_ACTIVE) {
led_state |= LED_2 ;
}
/* Link at Port B/S = green led B ON */
if (mib_b->fddiPORTPCMState == PC8_ACTIVE) {
led_state |= LED_0 ;
}
}
outpw(LEDR_A, led_state) ;
#endif /* MCA */
#ifdef PCI
led_state = 0 ;
/* Ring up = yellow led OFF*/
if (led_event == LED_Y_ON) {
led_state |= LED_MY_ON ;
}
else if (led_event == LED_Y_OFF) {
led_state |= LED_MY_OFF ;
}
else { /* PCM state changed */
/* Link at Port A/S = green led A ON */
if (mib_a->fddiPORTPCMState == PC8_ACTIVE) {
led_state |= LED_GA_ON ;
}
else {
led_state |= LED_GA_OFF ;
}
/* Link at Port B = green led B ON */
if (mib_b->fddiPORTPCMState == PC8_ACTIVE) {
led_state |= LED_GB_ON ;
}
else {
led_state |= LED_GB_OFF ;
}
}
outp(ADDR(B0_LED), led_state) ;
#endif /* PCI */
}
void pcm_state_change(struct s_smc *smc, int plc, int p_state)
{
/*
* the current implementation of pcm_state_change() in the driver
* parts must be renamed to drv_pcm_state_change() which will be called
* now after led_indication.
*/
DRV_PCM_STATE_CHANGE(smc,plc,p_state) ;
led_indication(smc,0) ;
}
void rmt_indication(struct s_smc *smc, int i)
{
/* Call a driver special function if defined */
DRV_RMT_INDICATION(smc,i) ;
led_indication(smc, i ? LED_Y_OFF : LED_Y_ON) ;
}
/*
* llc_recover_tx called by init_tx (fplus.c)
*/
void llc_recover_tx(struct s_smc *smc)
{
#ifdef LOAD_GEN
extern int load_gen_flag ;
load_gen_flag = 0 ;
#endif
#ifndef SYNC
smc->hw.n_a_send= 0 ;
#else
SK_UNUSED(smc) ;
#endif
}
/*--------------------------- DMA init ----------------------------*/
#ifdef ISA
/*
* init DMA
*/
void init_dma(struct s_smc *smc, int dma)
{
SK_UNUSED(smc) ;
/*
* set cascade mode,
* clear mask bit (enable DMA cannal)
*/
if (dma > 3) {
outp(0xd6,(dma & 0x03) | 0xc0) ;
outp(0xd4, dma & 0x03) ;
}
else {
outp(0x0b,(dma & 0x03) | 0xc0) ;
outp(0x0a,dma & 0x03) ;
}
}
/*
* disable DMA
*/
void dis_dma(struct s_smc *smc, int dma)
{
SK_UNUSED(smc) ;
/*
* set mask bit (disable DMA cannal)
*/
if (dma > 3) {
outp(0xd4,(dma & 0x03) | 0x04) ;
}
else {
outp(0x0a,(dma & 0x03) | 0x04) ;
}
}
#endif /* ISA */
#ifdef EISA
/*arrays with io addresses of dma controller length and address registers*/
static const int cntr[8] = { 0x001,0x003,0x005,0x007,0,0x0c6,0x0ca,0x0ce } ;
static const int base[8] = { 0x000,0x002,0x004,0x006,0,0x0c4,0x0c8,0x0cc } ;
static const int page[8] = { 0x087,0x083,0x081,0x082,0,0x08b,0x089,0x08a } ;
void init_dma(struct s_smc *smc, int dma)
{
/*
* extended mode register
* 32 bit IO
* type c
* TC output
* disable stop
*/
/* mode read (write) demand */
smc->hw.dma_rmode = (dma & 3) | 0x08 | 0x0 ;
smc->hw.dma_wmode = (dma & 3) | 0x04 | 0x0 ;
/* 32 bit IO's, burst DMA mode (type "C") */
smc->hw.dma_emode = (dma & 3) | 0x08 | 0x30 ;
outp((dma < 4) ? 0x40b : 0x4d6,smc->hw.dma_emode) ;
/* disable chaining */
outp((dma < 4) ? 0x40a : 0x4d4,(dma&3)) ;
/*load dma controller addresses for fast access during set dma*/
smc->hw.dma_base_word_count = cntr[smc->hw.dma];
smc->hw.dma_base_address = base[smc->hw.dma];
smc->hw.dma_base_address_page = page[smc->hw.dma];
}
void dis_dma(struct s_smc *smc, int dma)
{
SK_UNUSED(smc) ;
outp((dma < 4) ? 0x0a : 0xd4,(dma&3)|4) ;/* mask bit */
}
#endif /* EISA */
#ifdef MCA
void init_dma(struct s_smc *smc, int dma)
{
SK_UNUSED(smc) ;
SK_UNUSED(dma) ;
}
void dis_dma(struct s_smc *smc, int dma)
{
SK_UNUSED(smc) ;
SK_UNUSED(dma) ;
}
#endif
#ifdef PCI
void init_dma(struct s_smc *smc, int dma)
{
SK_UNUSED(smc) ;
SK_UNUSED(dma) ;
}
void dis_dma(struct s_smc *smc, int dma)
{
SK_UNUSED(smc) ;
SK_UNUSED(dma) ;
}
#endif
#ifdef MULT_OEM
static int is_equal_num(char comp1[], char comp2[], int num)
{
int i ;
for (i = 0 ; i < num ; i++) {
if (comp1[i] != comp2[i])
return (0) ;
}
return (1) ;
} /* is_equal_num */
/*
* set the OEM ID defaults, and test the contents of the OEM data base
* The default OEM is the first ACTIVE entry in the OEM data base
*
* returns: 0 success
* 1 error in data base
* 2 data base empty
* 3 no active entry
*/
int set_oi_id_def(struct s_smc *smc)
{
int sel_id ;
int i ;
int act_entries ;
i = 0 ;
sel_id = -1 ;
act_entries = FALSE ;
smc->hw.oem_id = 0 ;
smc->hw.oem_min_status = OI_STAT_ACTIVE ;
/* check OEM data base */
while (oem_ids[i].oi_status) {
switch (oem_ids[i].oi_status) {
case OI_STAT_ACTIVE:
act_entries = TRUE ; /* we have active IDs */
if (sel_id == -1)
sel_id = i ; /* save the first active ID */
case OI_STAT_VALID:
case OI_STAT_PRESENT:
i++ ;
break ; /* entry ok */
default:
return (1) ; /* invalid oi_status */
}
}
if (i == 0)
return (2) ;
if (!act_entries)
return (3) ;
/* ok, we have a valid OEM data base with an active entry */
smc->hw.oem_id = (struct s_oem_ids *) &oem_ids[sel_id] ;
return (0) ;
}
#endif /* MULT_OEM */
#ifdef MCA
/************************
*
* BEGIN_MANUAL_ENTRY()
*
* exist_board
*
* Check if an MCA board is present in the specified slot.
*
* int exist_board(
* struct s_smc *smc,
* int slot) ;
* In
* smc - A pointer to the SMT Context struct.
*
* slot - The number of the slot to inspect.
* Out
* 0 = No adapter present.
* 1 = Found FM1 adapter.
*
* Pseudo
* Read MCA ID
* for all valid OEM_IDs
* compare with ID read
* if equal, return 1
* return(0
*
* Note
* The smc pointer must be valid now.
*
* END_MANUAL_ENTRY()
*
************************/
#define LONG_CARD_ID(lo, hi) ((((hi) & 0xff) << 8) | ((lo) & 0xff))
int exist_board(struct s_smc *smc, int slot)
{
#ifdef MULT_OEM
SK_LOC_DECL(u_char,id[2]) ;
int idi ;
#endif /* MULT_OEM */
/* No longer valid. */
if (smc == NULL)
return(0) ;
#ifndef MULT_OEM
if (read_card_id(smc, slot)
== LONG_CARD_ID(OEMID(smc,0), OEMID(smc,1)))
return (1) ; /* Found FM adapter. */
#else /* MULT_OEM */
idi = read_card_id(smc, slot) ;
id[0] = idi & 0xff ;
id[1] = idi >> 8 ;
smc->hw.oem_id = (struct s_oem_ids *) &oem_ids[0] ;
for (; smc->hw.oem_id->oi_status != OI_STAT_LAST; smc->hw.oem_id++) {
if (smc->hw.oem_id->oi_status < smc->hw.oem_min_status)
continue ;
if (is_equal_num(&id[0],&OEMID(smc,0),2))
return (1) ;
}
#endif /* MULT_OEM */
return (0) ; /* No adapter found. */
}
/************************
*
* read_card_id
*
* Read the MCA card id from the specified slot.
* In
* smc - A pointer to the SMT Context struct.
* CAVEAT: This pointer may be NULL and *must not* be used within this
* function. It's only purpose is for drivers that need some information
* for the inp() and outp() macros.
*
* slot - The number of the slot for which the card id is returned.
* Out
* Returns the card id read from the specified slot. If an illegal slot
* number is specified, the function returns zero.
*
************************/
static int read_card_id(struct s_smc *smc, int slot)
/* struct s_smc *smc ; Do not use. */
{
int card_id ;
SK_UNUSED(smc) ; /* Make LINT happy. */
if ((slot < 1) || (slot > 15)) /* max 16 slots, 0 = motherboard */
return (0) ; /* Illegal slot number specified. */
EnableSlotAccess(smc, slot) ;
card_id = ((read_POS(smc,POS_ID_HIGH,slot - 1) & 0xff) << 8) |
(read_POS(smc,POS_ID_LOW,slot - 1) & 0xff) ;
DisableSlotAccess(smc) ;
return (card_id) ;
}
/************************
*
* BEGIN_MANUAL_ENTRY()
*
* get_board_para
*
* Get adapter configuration information. Fill all board specific
* parameters within the 'smc' structure.
*
* int get_board_para(
* struct s_smc *smc,
* int slot) ;
* In
* smc - A pointer to the SMT Context struct, to which this function will
* write some adapter configuration data.
*
* slot - The number of the slot, in which the adapter is installed.
* Out
* 0 = No adapter present.
* 1 = Ok.
* 2 = Adapter present, but card enable bit not set.
*
* END_MANUAL_ENTRY()
*
************************/
int get_board_para(struct s_smc *smc, int slot)
{
int val ;
int i ;
/* Check if adapter present & get type of adapter. */
switch (exist_board(smc, slot)) {
case 0: /* Adapter not present. */
return (0) ;
case 1: /* FM Rev. 1 */
smc->hw.rev = FM1_REV ;
smc->hw.VFullRead = 0x0a ;
smc->hw.VFullWrite = 0x05 ;
smc->hw.DmaWriteExtraBytes = 8 ; /* 2 extra words. */
break ;
}
smc->hw.slot = slot ;
EnableSlotAccess(smc, slot) ;
if (!(read_POS(smc,POS_102, slot - 1) & POS_CARD_EN)) {
DisableSlotAccess(smc) ;
return (2) ; /* Card enable bit not set. */
}
val = read_POS(smc,POS_104, slot - 1) ; /* I/O, IRQ */
#ifndef MEM_MAPPED_IO /* is defined by the operating system */
i = val & POS_IOSEL ; /* I/O base addr. (0x0200 .. 0xfe00) */
smc->hw.iop = (i + 1) * 0x0400 - 0x200 ;
#endif
i = ((val & POS_IRQSEL) >> 6) & 0x03 ; /* IRQ <0, 1> */
smc->hw.irq = opt_ints[i] ;
/* FPROM base addr. */
i = ((read_POS(smc,POS_103, slot - 1) & POS_MSEL) >> 4) & 0x07 ;
smc->hw.eprom = opt_eproms[i] ;
DisableSlotAccess(smc) ;
/* before this, the smc->hw.iop must be set !!! */
smc->hw.slot_32 = inpw(CSF_A) & SLOT_32 ;
return (1) ;
}
/* Enable access to specified MCA slot. */
static void EnableSlotAccess(struct s_smc *smc, int slot)
{
SK_UNUSED(slot) ;
#ifndef AIX
SK_UNUSED(smc) ;
/* System mode. */
outp(POS_SYS_SETUP, POS_SYSTEM) ;
/* Select slot. */
outp(POS_CHANNEL_POS, POS_CHANNEL_BIT | (slot-1)) ;
#else
attach_POS_addr (smc) ;
#endif
}
/* Disable access to MCA slot formerly enabled via EnableSlotAccess(). */
static void DisableSlotAccess(struct s_smc *smc)
{
#ifndef AIX
SK_UNUSED(smc) ;
outp(POS_CHANNEL_POS, 0) ;
#else
detach_POS_addr (smc) ;
#endif
}
#endif /* MCA */
#ifdef EISA
#ifndef MEM_MAPPED_IO
#define SADDR(slot) (((slot)<<12)&0xf000)
#else /* MEM_MAPPED_IO */
#define SADDR(slot) (smc->hw.iop)
#endif /* MEM_MAPPED_IO */
/************************
*
* BEGIN_MANUAL_ENTRY()
*
* exist_board
*
* Check if an EISA board is present in the specified slot.
*
* int exist_board(
* struct s_smc *smc,
* int slot) ;
* In
* smc - A pointer to the SMT Context struct.
*
* slot - The number of the slot to inspect.
* Out
* 0 = No adapter present.
* 1 = Found adapter.
*
* Pseudo
* Read EISA ID
* for all valid OEM_IDs
* compare with ID read
* if equal, return 1
* return(0
*
* Note
* The smc pointer must be valid now.
*
************************/
int exist_board(struct s_smc *smc, int slot)
{
int i ;
#ifdef MULT_OEM
SK_LOC_DECL(u_char,id[4]) ;
#endif /* MULT_OEM */
/* No longer valid. */
if (smc == NULL)
return(0);
SK_UNUSED(slot) ;
#ifndef MULT_OEM
for (i = 0 ; i < 4 ; i++) {
if (inp(SADDR(slot)+PRA(i)) != OEMID(smc,i))
return(0) ;
}
return(1) ;
#else /* MULT_OEM */
for (i = 0 ; i < 4 ; i++)
id[i] = inp(SADDR(slot)+PRA(i)) ;
smc->hw.oem_id = (struct s_oem_ids *) &oem_ids[0] ;
for (; smc->hw.oem_id->oi_status != OI_STAT_LAST; smc->hw.oem_id++) {
if (smc->hw.oem_id->oi_status < smc->hw.oem_min_status)
continue ;
if (is_equal_num(&id[0],&OEMID(smc,0),4))
return (1) ;
}
return (0) ; /* No adapter found. */
#endif /* MULT_OEM */
}
int get_board_para(struct s_smc *smc, int slot)
{
int i ;
if (!exist_board(smc,slot))
return(0) ;
smc->hw.slot = slot ;
#ifndef MEM_MAPPED_IO /* if defined by the operating system */
smc->hw.iop = SADDR(slot) ;
#endif
if (!(inp(C0_A(0))&CFG_CARD_EN)) {
return(2) ; /* CFG_CARD_EN bit not set! */
}
smc->hw.irq = opt_ints[(inp(C1_A(0)) & CFG_IRQ_SEL)] ;
smc->hw.dma = opt_dmas[((inp(C1_A(0)) & CFG_DRQ_SEL)>>3)] ;
if ((i = inp(C2_A(0)) & CFG_EPROM_SEL) != 0x0f)
smc->hw.eprom = opt_eproms[i] ;
else
smc->hw.eprom = 0 ;
smc->hw.DmaWriteExtraBytes = 8 ;
return(1) ;
}
#endif /* EISA */
#ifdef ISA
#ifndef MULT_OEM
const u_char sklogo[6] = SKLOGO_STR ;
#define SIZE_SKLOGO(smc) sizeof(sklogo)
#define SKLOGO(smc,i) sklogo[i]
#else /* MULT_OEM */
#define SIZE_SKLOGO(smc) smc->hw.oem_id->oi_logo_len
#define SKLOGO(smc,i) smc->hw.oem_id->oi_logo[i]
#endif /* MULT_OEM */
int exist_board(struct s_smc *smc, HW_PTR port)
{
int i ;
#ifdef MULT_OEM
int bytes_read ;
u_char board_logo[15] ;
SK_LOC_DECL(u_char,id[4]) ;
#endif /* MULT_OEM */
/* No longer valid. */
if (smc == NULL)
return(0);
SK_UNUSED(smc) ;
#ifndef MULT_OEM
for (i = SADDRL ; i < (signed) (SADDRL+SIZE_SKLOGO(smc)) ; i++) {
if ((u_char)inpw((PRA(i)+port)) != SKLOGO(smc,i-SADDRL)) {
return(0) ;
}
}
/* check MAC address (S&K or other) */
for (i = 0 ; i < 3 ; i++) {
if ((u_char)inpw((PRA(i)+port)) != OEMID(smc,i))
return(0) ;
}
return(1) ;
#else /* MULT_OEM */
smc->hw.oem_id = (struct s_oem_ids *) &oem_ids[0] ;
board_logo[0] = (u_char)inpw((PRA(SADDRL)+port)) ;
bytes_read = 1 ;
for (; smc->hw.oem_id->oi_status != OI_STAT_LAST; smc->hw.oem_id++) {
if (smc->hw.oem_id->oi_status < smc->hw.oem_min_status)
continue ;
/* Test all read bytes with current OEM_entry */
/* for (i=0; (i<bytes_read) && (i < SIZE_SKLOGO(smc)); i++) { */
for (i = 0; i < bytes_read; i++) {
if (board_logo[i] != SKLOGO(smc,i))
break ;
}
/* If mismatch, switch to next OEM entry */
if ((board_logo[i] != SKLOGO(smc,i)) && (i < bytes_read))
continue ;
--i ;
while (bytes_read < SIZE_SKLOGO(smc)) {
// inpw next byte SK_Logo
i++ ;
board_logo[i] = (u_char)inpw((PRA(SADDRL+i)+port)) ;
bytes_read++ ;
if (board_logo[i] != SKLOGO(smc,i))
break ;
}
for (i = 0 ; i < 3 ; i++)
id[i] = (u_char)inpw((PRA(i)+port)) ;
if ((board_logo[i] == SKLOGO(smc,i))
&& (bytes_read == SIZE_SKLOGO(smc))) {
if (is_equal_num(&id[0],&OEMID(smc,0),3))
return(1);
}
} /* for */
return(0) ;
#endif /* MULT_OEM */
}
int get_board_para(struct s_smc *smc, int slot)
{
SK_UNUSED(smc) ;
SK_UNUSED(slot) ;
return(0) ; /* for ISA not supported */
}
#endif /* ISA */
#ifdef PCI
#ifdef USE_BIOS_FUN
int exist_board(struct s_smc *smc, int slot)
{
u_short dev_id ;
u_short ven_id ;
int found ;
int i ;
found = FALSE ; /* make sure we returned with adatper not found*/
/* if an empty oemids.h was included */
#ifdef MULT_OEM
smc->hw.oem_id = (struct s_oem_ids *) &oem_ids[0] ;
for (; smc->hw.oem_id->oi_status != OI_STAT_LAST; smc->hw.oem_id++) {
if (smc->hw.oem_id->oi_status < smc->hw.oem_min_status)
continue ;
#endif
ven_id = OEMID(smc,0) + (OEMID(smc,1) << 8) ;
dev_id = OEMID(smc,2) + (OEMID(smc,3) << 8) ;
for (i = 0; i < slot; i++) {
if (pci_find_device(i,&smc->hw.pci_handle,
dev_id,ven_id) != 0) {
found = FALSE ;
} else {
found = TRUE ;
}
}
if (found) {
return(1) ; /* adapter was found */
}
#ifdef MULT_OEM
}
#endif
return(0) ; /* adapter was not found */
}
#endif /* PCI */
#endif /* USE_BIOS_FUNC */
void driver_get_bia(struct s_smc *smc, struct fddi_addr *bia_addr)
{
int i ;
extern const u_char canonical[256] ;
for (i = 0 ; i < 6 ; i++) {
bia_addr->a[i] = canonical[smc->hw.fddi_phys_addr.a[i]] ;
}
}
void smt_start_watchdog(struct s_smc *smc)
{
SK_UNUSED(smc) ; /* Make LINT happy. */
#ifndef DEBUG
#ifdef PCI
if (smc->hw.wdog_used) {
outpw(ADDR(B2_WDOG_CRTL),TIM_START) ; /* Start timer. */
}
#endif
#endif /* DEBUG */
}
void smt_stop_watchdog(struct s_smc *smc)
{
SK_UNUSED(smc) ; /* Make LINT happy. */
#ifndef DEBUG
#ifdef PCI
if (smc->hw.wdog_used) {
outpw(ADDR(B2_WDOG_CRTL),TIM_STOP) ; /* Stop timer. */
}
#endif
#endif /* DEBUG */
}
#ifdef PCI
static char get_rom_byte(struct s_smc *smc, u_short addr)
{
GET_PAGE(addr) ;
return (READ_PROM(ADDR(B2_FDP))) ;
}
/*
* ROM image defines
*/
#define ROM_SIG_1 0
#define ROM_SIG_2 1
#define PCI_DATA_1 0x18
#define PCI_DATA_2 0x19
/*
* PCI data structure defines
*/
#define VPD_DATA_1 0x08
#define VPD_DATA_2 0x09
#define IMAGE_LEN_1 0x10
#define IMAGE_LEN_2 0x11
#define CODE_TYPE 0x14
#define INDICATOR 0x15
/*
* BEGIN_MANUAL_ENTRY(mac_drv_vpd_read)
* mac_drv_vpd_read(smc,buf,size,image)
*
* function DOWNCALL (FDDIWARE)
* reads the VPD data of the FPROM and writes it into the
* buffer
*
* para buf points to the buffer for the VPD data
* size size of the VPD data buffer
* image boot image; code type of the boot image
* image = 0 Intel x86, PC-AT compatible
* 1 OPENBOOT standard for PCI
* 2-FF reserved
*
* returns len number of VPD data bytes read form the FPROM
* <0 number of read bytes
* >0 error: data invalid
*
* END_MANUAL_ENTRY
*/
int mac_drv_vpd_read(struct s_smc *smc, char *buf, int size, char image)
{
u_short ibase ;
u_short pci_base ;
u_short vpd ;
int len ;
len = 0 ;
ibase = 0 ;
/*
* as long images defined
*/
while (get_rom_byte(smc,ibase+ROM_SIG_1) == 0x55 &&
(u_char) get_rom_byte(smc,ibase+ROM_SIG_2) == 0xaa) {
/*
* get the pointer to the PCI data structure
*/
pci_base = ibase + get_rom_byte(smc,ibase+PCI_DATA_1) +
(get_rom_byte(smc,ibase+PCI_DATA_2) << 8) ;
if (image == get_rom_byte(smc,pci_base+CODE_TYPE)) {
/*
* we have the right image, read the VPD data
*/
vpd = ibase + get_rom_byte(smc,pci_base+VPD_DATA_1) +
(get_rom_byte(smc,pci_base+VPD_DATA_2) << 8) ;
if (vpd == ibase) {
break ; /* no VPD data */
}
for (len = 0; len < size; len++,buf++,vpd++) {
*buf = get_rom_byte(smc,vpd) ;
}
break ;
}
else {
/*
* try the next image
*/
if (get_rom_byte(smc,pci_base+INDICATOR) & 0x80) {
break ; /* this was the last image */
}
ibase = ibase + get_rom_byte(smc,ibase+IMAGE_LEN_1) +
(get_rom_byte(smc,ibase+IMAGE_LEN_2) << 8) ;
}
}
return(len) ;
}
void mac_drv_pci_fix(struct s_smc *smc, u_long fix_value)
{
smc->hw.pci_fix_value = fix_value ;
}
void mac_do_pci_fix(struct s_smc *smc)
{
SK_UNUSED(smc) ;
}
#endif /* PCI */