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|
/*
*
* ===================================
* 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.
*
* @(#) $FreeBSD$
*
*/
/*
* Efficient ENI adapter support
* -----------------------------
*
* Module supports PCI interface to ENI adapter
*
*/
#include <netatm/kern_include.h>
#include <dev/hea/eni_stats.h>
#include <dev/hea/eni.h>
#include <dev/hea/eni_var.h>
#ifndef lint
__RCSID("@(#) $FreeBSD$");
#endif
/*
* Typedef local functions
*/
static const char *eni_pci_probe __P((pcici_t, pcidi_t));
static void eni_pci_attach __P((pcici_t, int));
static int eni_get_ack __P((Eni_unit *));
static int eni_get_sebyte __P((Eni_unit *));
static void eni_read_seeprom __P((Eni_unit *));
#ifdef __FreeBSD__
#if BSD < 199506
static int eni_pci_shutdown __P((struct kern_devconf *, int));
#else
static void eni_pci_shutdown __P((void *, int));
#endif
static void eni_pci_reset __P((Eni_unit *));
#endif /* __FreeBSD__ */
/*
* Used by kernel to return number of claimed devices
*/
#ifdef __FreeBSD__
static u_long eni_nunits;
static struct pci_device eni_pci_device = {
ENI_DEV_NAME,
eni_pci_probe,
eni_pci_attach,
&eni_nunits,
#if BSD < 199506
eni_pci_shutdown
#else
NULL
#endif
};
COMPAT_PCI_DRIVER (eni_pci, eni_pci_device);
#endif /* __FreeBSD__ */
/*
* Called by kernel with PCI device_id which was read from the PCI
* register set. If the identified vendor is Efficient, see if we
* recognize the particular device. If so, return an identifying string,
* if not, return null.
*
* Arguments:
* config_id PCI config token
* device_id contents of PCI device ID register
*
* Returns:
* string Identifying string if we will handle this device
* NULL unrecognized vendor/device
*
*/
static const char *
eni_pci_probe ( pcici_t config_id, pcidi_t device_id )
{
if ( (device_id & 0xFFFF) == EFF_VENDOR_ID ) {
switch ( (device_id >> 16) ) {
case EFF_DEV_ID:
return ( "Efficient ENI ATM Adapter" );
/* NOTREACHED */
break;
}
}
return ( NULL );
}
/*
* The ENI-155p adapter uses an ATMEL AT24C01 serial EEPROM to store
* configuration information. The SEEPROM is accessed via two wires,
* CLOCK and DATA, which are accessible via the PCI configuration
* registers. The following macros manipulate the lines to access the
* SEEPROM. See http://www.atmel.com/atmel/products/prod162.htm for
* a description of the AT24C01 part. Value to be read/written is
* part of the per unit structure.
*/
/*
* Write bits to SEEPROM
*/
#define WRITE_SEEPROM() ( \
{ \
(void) pci_conf_write ( eup->eu_pcitag, SEEPROM, \
eup->eu_sevar ); \
DELAY(SEPROM_DELAY); \
} \
)
/*
* Stobe first the DATA, then the CLK lines high
*/
#define STROBE_HIGH() ( \
{ \
eup->eu_sevar |= SEPROM_DATA; WRITE_SEEPROM(); \
eup->eu_sevar |= SEPROM_CLK; WRITE_SEEPROM(); \
} \
)
/*
* Strobe first the CLK, then the DATA lines high
*/
#define INV_STROBE_HIGH() ( \
{ \
eup->eu_sevar |= SEPROM_CLK; WRITE_SEEPROM(); \
eup->eu_sevar |= SEPROM_DATA; WRITE_SEEPROM(); \
} \
)
/*
* Strobe first the CLK, then the DATA lines low - companion to
* STROBE_HIGH()
*/
#define STROBE_LOW() ( \
{ \
eup->eu_sevar &= ~SEPROM_CLK; WRITE_SEEPROM(); \
eup->eu_sevar &= ~SEPROM_DATA; WRITE_SEEPROM(); \
} \
)
/*
* Strobe first the DATA, then the CLK lines low - companion to
* INV_STROBE_HIGH()
*/
#define INV_STROBE_LOW() ( \
{ \
eup->eu_sevar &= ~SEPROM_DATA; WRITE_SEEPROM(); \
eup->eu_sevar &= ~SEPROM_CLK; WRITE_SEEPROM(); \
} \
)
/*
* Strobe the CLK line high, then low
*/
#define STROBE_CLK() ( \
{ \
eup->eu_sevar |= SEPROM_CLK; WRITE_SEEPROM(); \
eup->eu_sevar &= ~SEPROM_CLK; WRITE_SEEPROM(); \
} \
)
/*
* Look for a positive ACK from the SEEPROM. Cycle begins by asserting
* the DATA line, then the CLK line. The DATA line is then read to
* retrieve the ACK status, and then the cycle is finished by deasserting
* the CLK line, and asserting the DATA line.
*
* Arguments:
* eup pointer to per unit structure
*
* Returns:
* 0/1 value of ACK
*
*/
static int
eni_get_ack ( eup )
Eni_unit *eup;
{
int ack;
STROBE_HIGH();
/*
* Read DATA line from SEPROM
*/
eup->eu_sevar = pci_conf_read ( eup->eu_pcitag, SEEPROM );
DELAY ( SEPROM_DELAY );
ack = eup->eu_sevar & SEPROM_DATA;
eup->eu_sevar &= ~SEPROM_CLK;
WRITE_SEEPROM ();
eup->eu_sevar |= SEPROM_DATA;
WRITE_SEEPROM ();
return ( ack );
}
/*
* Read a byte from the SEEPROM. Data is read as 8 bits. There are two types
* of read operations. The first is a single byte read, the second is
* multiple sequential bytes read. Both cycles begin with a 'START' operation,
* followed by a memory address word. Following the memory address, the
* SEEPROM will send a data byte, followed by an ACK. If the host responds
* with a 'STOP' operation, then a single byte cycle is performed. If the
* host responds with an 'ACK', then the memory address is incremented, and
* the next sequential memory byte is serialized.
*
* Arguments:
* eup pointer to per unit structure
*
* Returns:
* val value of byte read from SEEPROM
*
*/
static int
eni_get_sebyte( eup )
Eni_unit *eup;
{
int i;
int data;
int rval;
/* Initial value */
rval = 0;
/* Read 8 bits */
for ( i = 0; i < 8; i++ ) {
/* Shift bits to left so the next bit goes to position 0 */
rval <<= 1;
/* Indicate we're ready to read bit */
STROBE_HIGH();
/*
* Read DATA line from SEPROM
*/
data = pci_conf_read ( eup->eu_pcitag, SEEPROM );
DELAY ( SEPROM_DELAY );
/* (Possibly) mask bit into accumulating value */
if ( data & SEPROM_DATA )
rval |= 1; /* If DATA bit '1' */
/* Indicate we're done reading this bit */
STROBE_LOW();
}
/* Return acquired byte */
return ( rval );
}
/*
* The AT24C01 is a 1024 bit part organized as 128 words by 8 bits.
* We will read the entire contents into the per unit structure. Later,
* we'll retrieve the MAC address and serial number from the data read.
*
* Arguments:
* eup pointer to per unit structure
*
* Returns:
* none
*
*/
static void
eni_read_seeprom ( eup )
Eni_unit *eup;
{
int addr;
int i, j;
/*
* Set initial state
*/
eup->eu_sevar = SEPROM_DATA | SEPROM_CLK;
WRITE_SEEPROM ();
/* Loop for all bytes */
for ( i = 0; i < SEPROM_SIZE ; i++ ) {
/* Send START operation */
STROBE_HIGH();
INV_STROBE_LOW();
/*
* Send address. Addresses are sent as 7 bits plus
* last bit high.
*/
addr = ((i) << 1) + 1;
/*
* Start with high order bit first working toward low
* order bit.
*/
for ( j = 7; j >= 0; j-- ) {
/* Set current bit value */
eup->eu_sevar = ( addr >> j ) & 1 ?
eup->eu_sevar | SEPROM_DATA :
eup->eu_sevar & ~SEPROM_DATA;
WRITE_SEEPROM ();
/* Indicate we've sent it */
STROBE_CLK();
}
/*
* We expect a zero ACK after sending the address
*/
if ( !eni_get_ack ( eup ) ) {
/* Address okay - read data byte */
eup->eu_seeprom[i] = eni_get_sebyte ( eup );
/* Grab but ignore the ACK op */
(void) eni_get_ack ( eup );
} else {
/* Address ACK was bad - can't retrieve data byte */
eup->eu_seeprom[i] = 0xff;
}
}
return;
}
/*
* The kernel has found a device which we are willing to support.
* We are now being called to do any necessary work to make the
* device initially usable. In our case, this means allocating
* structure memory, configuring registers, mapping device
* memory, setting pointers, registering with the core services,
* and doing the initial PDU processing configuration.
*
* Arguments:
* config_id PCI device token
* unit instance of the unit
*
* Returns:
* none
*
*/
static void
eni_pci_attach ( pcici_t config_id, int unit )
{
vm_offset_t va;
vm_offset_t pa;
Eni_unit *eup;
long val;
/*
* Just checking...
*/
if ( unit >= ENI_MAX_UNITS ) {
log ( LOG_ERR, "%s%d: too many devices\n",
ENI_DEV_NAME, unit );
return;
}
/*
* Make sure this isn't a duplicate unit
*/
if ( eni_units[unit] != NULL )
return;
/*
* Allocate a new unit structure
*/
eup = (Eni_unit *) atm_dev_alloc ( sizeof(Eni_unit), sizeof(int), 0 );
if ( eup == NULL )
return;
/*
* Start initializing it
*/
eup->eu_unit = unit;
eup->eu_mtu = ENI_IFF_MTU;
eup->eu_pcitag = config_id;
eup->eu_ioctl = eni_atm_ioctl;
eup->eu_instvcc = eni_instvcc;
eup->eu_openvcc = eni_openvcc;
eup->eu_closevcc = eni_closevcc;
eup->eu_output = eni_output;
eup->eu_vcc_pool = &eni_vcc_pool;
eup->eu_nif_pool = &eni_nif_pool;
/*
* Enable Memory Mapping / Bus Mastering
*/
val = pci_conf_read(config_id, PCI_COMMAND_STATUS_REG);
val |= (PCIM_CMD_MEMEN | PCIM_CMD_BUSMASTEREN);
pci_conf_write(config_id, PCI_COMMAND_STATUS_REG, val);
/*
* Map in adapter RAM
*/
val = pci_conf_read(config_id, PCI_COMMAND_STATUS_REG);
if ((val & PCIM_CMD_MEMEN) == 0) {
log(LOG_ERR, "%s%d: memory mapping not enabled\n",
ENI_DEV_NAME, unit);
goto failed;
}
if ( ( pci_map_mem ( config_id, PCI_MAP_REG_START, &va, &pa ) ) == 0 )
{
log(LOG_ERR, "%s%d: unable to map memory\n",
ENI_DEV_NAME, unit);
goto failed;
}
/*
* Map okay - retain address assigned
*/
eup->eu_base = (Eni_mem)va;
eup->eu_ram = (Eni_mem)(eup->eu_base + RAM_OFFSET);
/*
* Map memory structures into adapter space
*/
eup->eu_suni = (Eni_mem)(eup->eu_base + SUNI_OFFSET);
eup->eu_midway = (Eni_mem)(eup->eu_base + MIDWAY_OFFSET);
eup->eu_vcitbl = (VCI_Table *)(eup->eu_base + VCITBL_OFFSET);
eup->eu_rxdma = (Eni_mem)(eup->eu_base + RXQUEUE_OFFSET);
eup->eu_txdma = (Eni_mem)(eup->eu_base + TXQUEUE_OFFSET);
eup->eu_svclist = (Eni_mem)(eup->eu_base + SVCLIST_OFFSET);
eup->eu_servread = 0;
/*
* Reset the midway chip
*/
eup->eu_midway[MIDWAY_ID] = MIDWAY_RESET;
/*
* Size and test adapter memory. Initialize our adapter memory
* allocater.
*/
if ( eni_init_memory ( eup ) < 0 ) {
/*
* Adapter memory test failed. Clean up and
* return.
*/
log(LOG_ERR, "%s%d: memory test failed\n",
ENI_DEV_NAME, unit);
goto failed;
}
/*
* Read the contents of the SEEPROM
*/
eni_read_seeprom ( eup );
/*
* Copy MAC address to PIF and config structures
*/
KM_COPY ( (caddr_t)&eup->eu_seeprom[SEPROM_MAC_OFF],
(caddr_t)&eup->eu_pif.pif_macaddr, sizeof(struct mac_addr) );
eup->eu_config.ac_macaddr = eup->eu_pif.pif_macaddr;
/*
* Copy serial number into config space
*/
eup->eu_config.ac_serial =
ntohl(*(u_long *)&eup->eu_seeprom[SEPROM_SN_OFF]);
/*
* Convert Endianess on DMA
*/
val = pci_conf_read ( config_id, PCI_CONTROL_REG );
val |= ENDIAN_SWAP_DMA;
pci_conf_write ( config_id, PCI_CONTROL_REG, val );
/*
* Map interrupt in
*/
if ( !pci_map_int ( config_id, eni_intr, (void *)eup, &net_imask ) )
{
log(LOG_ERR, "%s%d: unable to map interrupt\n",
ENI_DEV_NAME, unit);
goto failed;
}
/*
* Setup some of the adapter configuration
*/
/*
* Get MIDWAY ID
*/
val = eup->eu_midway[MIDWAY_ID];
eup->eu_config.ac_vendor = VENDOR_ENI;
eup->eu_config.ac_vendapi = VENDAPI_ENI_1;
eup->eu_config.ac_device = DEV_ENI_155P;
eup->eu_config.ac_media = val & MEDIA_MASK ? MEDIA_UTP155 : MEDIA_OC3C;
eup->eu_pif.pif_pcr = ATM_PCR_OC3C;
eup->eu_config.ac_bustype = BUS_PCI;
eup->eu_config.ac_busslot = config_id->bus << 8 | config_id->slot;
/*
* Make a hw version number from the ID register values.
* Format: {Midway ID}.{Mother board ID}.{Daughter board ID}
*/
snprintf ( eup->eu_config.ac_hard_vers,
sizeof ( eup->eu_config.ac_hard_vers ),
"%ld/%ld/%ld",
(val >> ID_SHIFT) & ID_MASK,
(val >> MID_SHIFT) & MID_MASK,
(val >> DID_SHIFT) & DID_MASK );
/*
* There is no software version number
*/
eup->eu_config.ac_firm_vers[0] = '\0';
/*
* Save device ram info for user-level programs
* NOTE: This really points to start of EEPROM
* and includes all the device registers in the
* lower 2 Megabytes.
*/
eup->eu_config.ac_ram = (long)eup->eu_base;
eup->eu_config.ac_ramsize = eup->eu_ramsize + ENI_REG_SIZE;
/*
* Setup max VPI/VCI values
*/
eup->eu_pif.pif_maxvpi = ENI_MAX_VPI;
eup->eu_pif.pif_maxvci = ENI_MAX_VCI;
/*
* Register this interface with ATM core services
*/
if ( atm_physif_register
( (Cmn_unit *)eup, ENI_DEV_NAME, eni_services ) != 0 )
{
/*
* Registration failed - back everything out
*/
log(LOG_ERR, "%s%d: atm_physif_register failed\n",
ENI_DEV_NAME, unit);
goto failed;
}
eni_units[unit] = eup;
#if BSD >= 199506
/*
* Add hook to out shutdown function
*/
EVENTHANDLER_REGISTER(shutdown_post_sync, eni_pci_shutdown, eup,
SHUTDOWN_PRI_DEFAULT);
#endif
/*
* Initialize driver processing
*/
if ( eni_init ( eup ) ) {
log(LOG_ERR, "%s%d: adapter init failed\n",
ENI_DEV_NAME, unit);
goto failed;
}
return;
failed:
/*
* Attach failed - clean up
*/
eni_pci_reset(eup);
(void) pci_unmap_int(config_id);
atm_dev_free(eup);
return;
}
/*
* Device reset routine
*
* Arguments:
* eup pointer to per unit structure
*
* Returns:
* none
*
*/
static void
eni_pci_reset ( eup )
Eni_unit *eup;
{
/*
* We should really close down any open VCI's and
* release all memory (TX and RX) buffers. For now,
* we assume we're shutting the card down for good.
*/
if (eup->eu_midway) {
/*
* Issue RESET command to Midway chip
*/
eup->eu_midway[MIDWAY_ID] = MIDWAY_RESET;
/*
* Delay to allow everything to terminate
*/
DELAY ( MIDWAY_DELAY );
}
return;
}
#ifdef __FreeBSD__
#if BSD < 199506
/*
* Device shutdown routine
*
* Arguments:
* kdc pointer to device's configuration table
* force forced shutdown flag
*
* Returns:
* none
*
*/
static int
eni_pci_shutdown ( kdc, force )
struct kern_devconf *kdc;
int force;
{
Eni_unit *eup = NULL;
if ( kdc->kdc_unit < eni_nunits ) {
eup = eni_units[kdc->kdc_unit];
if ( eup != NULL ) {
/* Do device reset */
eni_pci_reset ( eup );
}
}
(void) dev_detach ( kdc );
return ( 0 );
}
#else
/*
* Device shutdown routine
*
* Arguments:
* howto type of shutdown
* eup pointer to device unit structure
*
* Returns:
* none
*
*/
static void
eni_pci_shutdown ( eup, howto )
void *eup;
int howto;
{
/* Do device reset */
eni_pci_reset ( eup );
}
#endif /* BSD < 199506 */
#endif /* __FreeBSD__ */
|