freebsd-skq/sys/dev/sfxge/common/efx_nic.c
Andrew Rybchenko 3c838a9f51 sfxge: add 7xxx NICs family support
Support 7xxx adapters including firmware-assisted TSO and VLAN tagging:

  - Solarflare Flareon Ultra 7000 series 10/40G adapters:
    - Solarflare SFN7042Q QSFP+ Server Adapter
    - Solarflare SFN7142Q QSFP+ Server Adapter

  - Solarflare Flareon Ultra 7000 series 10G adapters:
    - Solarflare SFN7022F SFP+ Server Adapter
    - Solarflare SFN7122F SFP+ Server Adapter
    - Solarflare SFN7322F Precision Time Synchronization Server Adapter

  - Solarflare Flareon 7000 series 10G adapters:
    - Solarflare SFN7002F SFP+ Server Adapter

Support utilities to configure adapters and update firmware.

The work is done by Solarflare developers
(Andy Moreton, Andrew Lee and many others),
Artem V. Andreev <Artem.Andreev at oktetlabs.ru> and me.

Sponsored by:   Solarflare Communications, Inc.
MFC after:      2 weeks
Causually read by: gnn
Differential Revision: https://reviews.freebsd.org/D2618
2015-05-25 08:34:55 +00:00

1041 lines
26 KiB
C

/*-
* Copyright (c) 2007-2015 Solarflare Communications 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 COPYRIGHT HOLDERS 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 COPYRIGHT OWNER 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.
*
* The views and conclusions contained in the software and documentation are
* those of the authors and should not be interpreted as representing official
* policies, either expressed or implied, of the FreeBSD Project.
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include "efsys.h"
#include "efx.h"
#include "efx_types.h"
#include "efx_regs.h"
#include "efx_impl.h"
__checkReturn int
efx_family(
__in uint16_t venid,
__in uint16_t devid,
__out efx_family_t *efp)
{
if (venid == EFX_PCI_VENID_SFC) {
switch (devid) {
#if EFSYS_OPT_FALCON
case EFX_PCI_DEVID_FALCON:
*efp = EFX_FAMILY_FALCON;
return (0);
#endif
#if EFSYS_OPT_SIENA
case EFX_PCI_DEVID_SIENA_F1_UNINIT:
/*
* Hardware default for PF0 of uninitialised Siena.
* manftest must be able to cope with this device id.
*/
*efp = EFX_FAMILY_SIENA;
return (0);
case EFX_PCI_DEVID_BETHPAGE:
case EFX_PCI_DEVID_SIENA:
*efp = EFX_FAMILY_SIENA;
return (0);
#endif
#if EFSYS_OPT_HUNTINGTON
case EFX_PCI_DEVID_HUNTINGTON_PF_UNINIT:
/*
* Hardware default for PF0 of uninitialised Huntington.
* manftest must be able to cope with this device id.
*/
*efp = EFX_FAMILY_HUNTINGTON;
return (0);
case EFX_PCI_DEVID_FARMINGDALE:
case EFX_PCI_DEVID_GREENPORT:
case EFX_PCI_DEVID_HUNTINGTON:
*efp = EFX_FAMILY_HUNTINGTON;
return (0);
case EFX_PCI_DEVID_FARMINGDALE_VF:
case EFX_PCI_DEVID_GREENPORT_VF:
case EFX_PCI_DEVID_HUNTINGTON_VF:
*efp = EFX_FAMILY_HUNTINGTON;
return (0);
#endif
default:
break;
}
}
*efp = EFX_FAMILY_INVALID;
return (ENOTSUP);
}
/*
* To support clients which aren't provided with any PCI context infer
* the hardware family by inspecting the hardware. Obviously the caller
* must be damn sure they're really talking to a supported device.
*/
__checkReturn int
efx_infer_family(
__in efsys_bar_t *esbp,
__out efx_family_t *efp)
{
efx_family_t family;
efx_oword_t oword;
unsigned int portnum;
int rc;
EFSYS_BAR_READO(esbp, FR_AZ_CS_DEBUG_REG_OFST, &oword, B_TRUE);
portnum = EFX_OWORD_FIELD(oword, FRF_CZ_CS_PORT_NUM);
switch (portnum) {
case 0: {
efx_dword_t dword;
uint32_t hw_rev;
EFSYS_BAR_READD(esbp, ER_DZ_BIU_HW_REV_ID_REG_OFST, &dword,
B_TRUE);
hw_rev = EFX_DWORD_FIELD(dword, ERF_DZ_HW_REV_ID);
if (hw_rev == ER_DZ_BIU_HW_REV_ID_REG_RESET) {
#if EFSYS_OPT_HUNTINGTON
family = EFX_FAMILY_HUNTINGTON;
break;
#endif
} else {
#if EFSYS_OPT_FALCON
family = EFX_FAMILY_FALCON;
break;
#endif
}
rc = ENOTSUP;
goto fail1;
}
#if EFSYS_OPT_SIENA
case 1:
case 2:
family = EFX_FAMILY_SIENA;
break;
#endif
default:
rc = ENOTSUP;
goto fail1;
}
if (efp != NULL)
*efp = family;
return (0);
fail1:
EFSYS_PROBE1(fail1, int, rc);
return (rc);
}
#define EFX_BIU_MAGIC0 0x01234567
#define EFX_BIU_MAGIC1 0xfedcba98
__checkReturn int
efx_nic_biu_test(
__in efx_nic_t *enp)
{
efx_oword_t oword;
int rc;
/*
* Write magic values to scratch registers 0 and 1, then
* verify that the values were written correctly. Interleave
* the accesses to ensure that the BIU is not just reading
* back the cached value that was last written.
*/
EFX_POPULATE_OWORD_1(oword, FRF_AZ_DRIVER_DW0, EFX_BIU_MAGIC0);
EFX_BAR_TBL_WRITEO(enp, FR_AZ_DRIVER_REG, 0, &oword, B_TRUE);
EFX_POPULATE_OWORD_1(oword, FRF_AZ_DRIVER_DW0, EFX_BIU_MAGIC1);
EFX_BAR_TBL_WRITEO(enp, FR_AZ_DRIVER_REG, 1, &oword, B_TRUE);
EFX_BAR_TBL_READO(enp, FR_AZ_DRIVER_REG, 0, &oword, B_TRUE);
if (EFX_OWORD_FIELD(oword, FRF_AZ_DRIVER_DW0) != EFX_BIU_MAGIC0) {
rc = EIO;
goto fail1;
}
EFX_BAR_TBL_READO(enp, FR_AZ_DRIVER_REG, 1, &oword, B_TRUE);
if (EFX_OWORD_FIELD(oword, FRF_AZ_DRIVER_DW0) != EFX_BIU_MAGIC1) {
rc = EIO;
goto fail2;
}
/*
* Perform the same test, with the values swapped. This
* ensures that subsequent tests don't start with the correct
* values already written into the scratch registers.
*/
EFX_POPULATE_OWORD_1(oword, FRF_AZ_DRIVER_DW0, EFX_BIU_MAGIC1);
EFX_BAR_TBL_WRITEO(enp, FR_AZ_DRIVER_REG, 0, &oword, B_TRUE);
EFX_POPULATE_OWORD_1(oword, FRF_AZ_DRIVER_DW0, EFX_BIU_MAGIC0);
EFX_BAR_TBL_WRITEO(enp, FR_AZ_DRIVER_REG, 1, &oword, B_TRUE);
EFX_BAR_TBL_READO(enp, FR_AZ_DRIVER_REG, 0, &oword, B_TRUE);
if (EFX_OWORD_FIELD(oword, FRF_AZ_DRIVER_DW0) != EFX_BIU_MAGIC1) {
rc = EIO;
goto fail3;
}
EFX_BAR_TBL_READO(enp, FR_AZ_DRIVER_REG, 1, &oword, B_TRUE);
if (EFX_OWORD_FIELD(oword, FRF_AZ_DRIVER_DW0) != EFX_BIU_MAGIC0) {
rc = EIO;
goto fail4;
}
return (0);
fail4:
EFSYS_PROBE(fail4);
fail3:
EFSYS_PROBE(fail3);
fail2:
EFSYS_PROBE(fail2);
fail1:
EFSYS_PROBE1(fail1, int, rc);
return (rc);
}
#if EFSYS_OPT_FALCON
static efx_nic_ops_t __efx_nic_falcon_ops = {
falcon_nic_probe, /* eno_probe */
NULL, /* eno_set_drv_limits */
falcon_nic_reset, /* eno_reset */
falcon_nic_init, /* eno_init */
NULL, /* eno_get_vi_pool */
NULL, /* eno_get_bar_region */
#if EFSYS_OPT_DIAG
falcon_sram_test, /* eno_sram_test */
falcon_nic_register_test, /* eno_register_test */
#endif /* EFSYS_OPT_DIAG */
falcon_nic_fini, /* eno_fini */
falcon_nic_unprobe, /* eno_unprobe */
};
#endif /* EFSYS_OPT_FALCON */
#if EFSYS_OPT_SIENA
static efx_nic_ops_t __efx_nic_siena_ops = {
siena_nic_probe, /* eno_probe */
NULL, /* eno_set_drv_limits */
siena_nic_reset, /* eno_reset */
siena_nic_init, /* eno_init */
NULL, /* eno_get_vi_pool */
NULL, /* eno_get_bar_region */
#if EFSYS_OPT_DIAG
siena_sram_test, /* eno_sram_test */
siena_nic_register_test, /* eno_register_test */
#endif /* EFSYS_OPT_DIAG */
siena_nic_fini, /* eno_fini */
siena_nic_unprobe, /* eno_unprobe */
};
#endif /* EFSYS_OPT_SIENA */
#if EFSYS_OPT_HUNTINGTON
static efx_nic_ops_t __efx_nic_hunt_ops = {
hunt_nic_probe, /* eno_probe */
hunt_nic_set_drv_limits, /* eno_set_drv_limits */
hunt_nic_reset, /* eno_reset */
hunt_nic_init, /* eno_init */
hunt_nic_get_vi_pool, /* eno_get_vi_pool */
hunt_nic_get_bar_region, /* eno_get_bar_region */
#if EFSYS_OPT_DIAG
hunt_sram_test, /* eno_sram_test */
hunt_nic_register_test, /* eno_register_test */
#endif /* EFSYS_OPT_DIAG */
hunt_nic_fini, /* eno_fini */
hunt_nic_unprobe, /* eno_unprobe */
};
#endif /* EFSYS_OPT_HUNTINGTON */
__checkReturn int
efx_nic_create(
__in efx_family_t family,
__in efsys_identifier_t *esip,
__in efsys_bar_t *esbp,
__in efsys_lock_t *eslp,
__deref_out efx_nic_t **enpp)
{
efx_nic_t *enp;
int rc;
EFSYS_ASSERT3U(family, >, EFX_FAMILY_INVALID);
EFSYS_ASSERT3U(family, <, EFX_FAMILY_NTYPES);
/* Allocate a NIC object */
EFSYS_KMEM_ALLOC(esip, sizeof (efx_nic_t), enp);
if (enp == NULL) {
rc = ENOMEM;
goto fail1;
}
enp->en_magic = EFX_NIC_MAGIC;
switch (family) {
#if EFSYS_OPT_FALCON
case EFX_FAMILY_FALCON:
enp->en_enop = (efx_nic_ops_t *)&__efx_nic_falcon_ops;
enp->en_features = 0;
break;
#endif /* EFSYS_OPT_FALCON */
#if EFSYS_OPT_SIENA
case EFX_FAMILY_SIENA:
enp->en_enop = (efx_nic_ops_t *)&__efx_nic_siena_ops;
enp->en_features =
EFX_FEATURE_IPV6 |
EFX_FEATURE_LFSR_HASH_INSERT |
EFX_FEATURE_LINK_EVENTS |
EFX_FEATURE_PERIODIC_MAC_STATS |
EFX_FEATURE_WOL |
EFX_FEATURE_MCDI |
EFX_FEATURE_LOOKAHEAD_SPLIT |
EFX_FEATURE_MAC_HEADER_FILTERS |
EFX_FEATURE_TX_SRC_FILTERS;
break;
#endif /* EFSYS_OPT_SIENA */
#if EFSYS_OPT_HUNTINGTON
case EFX_FAMILY_HUNTINGTON:
enp->en_enop = (efx_nic_ops_t *)&__efx_nic_hunt_ops;
/* FIXME: Add WOL support */
enp->en_features =
EFX_FEATURE_IPV6 |
EFX_FEATURE_LINK_EVENTS |
EFX_FEATURE_PERIODIC_MAC_STATS |
EFX_FEATURE_MCDI |
EFX_FEATURE_MAC_HEADER_FILTERS |
EFX_FEATURE_MCDI_DMA |
EFX_FEATURE_PIO_BUFFERS |
EFX_FEATURE_FW_ASSISTED_TSO;
break;
#endif /* EFSYS_OPT_HUNTINGTON */
default:
rc = ENOTSUP;
goto fail2;
}
enp->en_family = family;
enp->en_esip = esip;
enp->en_esbp = esbp;
enp->en_eslp = eslp;
*enpp = enp;
return (0);
fail2:
EFSYS_PROBE(fail2);
enp->en_magic = 0;
/* Free the NIC object */
EFSYS_KMEM_FREE(esip, sizeof (efx_nic_t), enp);
fail1:
EFSYS_PROBE1(fail1, int, rc);
return (rc);
}
__checkReturn int
efx_nic_probe(
__in efx_nic_t *enp)
{
efx_nic_ops_t *enop;
int rc;
EFSYS_ASSERT3U(enp->en_magic, ==, EFX_NIC_MAGIC);
#if EFSYS_OPT_MCDI
EFSYS_ASSERT3U(enp->en_mod_flags, &, EFX_MOD_MCDI);
#endif /* EFSYS_OPT_MCDI */
EFSYS_ASSERT(!(enp->en_mod_flags & EFX_MOD_PROBE));
enop = enp->en_enop;
if ((rc = enop->eno_probe(enp)) != 0)
goto fail1;
if ((rc = efx_phy_probe(enp)) != 0)
goto fail2;
enp->en_mod_flags |= EFX_MOD_PROBE;
return (0);
fail2:
EFSYS_PROBE(fail2);
enop->eno_unprobe(enp);
fail1:
EFSYS_PROBE1(fail1, int, rc);
return (rc);
}
#if EFSYS_OPT_PCIE_TUNE
__checkReturn int
efx_nic_pcie_tune(
__in efx_nic_t *enp,
unsigned int nlanes)
{
EFSYS_ASSERT3U(enp->en_magic, ==, EFX_NIC_MAGIC);
EFSYS_ASSERT3U(enp->en_mod_flags, &, EFX_MOD_PROBE);
EFSYS_ASSERT(!(enp->en_mod_flags & EFX_MOD_NIC));
#if EFSYS_OPT_FALCON
if (enp->en_family == EFX_FAMILY_FALCON)
return (falcon_nic_pcie_tune(enp, nlanes));
#endif
return (ENOTSUP);
}
__checkReturn int
efx_nic_pcie_extended_sync(
__in efx_nic_t *enp)
{
EFSYS_ASSERT3U(enp->en_magic, ==, EFX_NIC_MAGIC);
EFSYS_ASSERT3U(enp->en_mod_flags, &, EFX_MOD_PROBE);
EFSYS_ASSERT(!(enp->en_mod_flags & EFX_MOD_NIC));
#if EFSYS_OPT_SIENA
if (enp->en_family == EFX_FAMILY_SIENA)
return (siena_nic_pcie_extended_sync(enp));
#endif
return (ENOTSUP);
}
#endif /* EFSYS_OPT_PCIE_TUNE */
__checkReturn int
efx_nic_set_drv_limits(
__inout efx_nic_t *enp,
__in efx_drv_limits_t *edlp)
{
efx_nic_ops_t *enop = enp->en_enop;
int rc;
EFSYS_ASSERT3U(enp->en_magic, ==, EFX_NIC_MAGIC);
EFSYS_ASSERT3U(enp->en_mod_flags, &, EFX_MOD_PROBE);
if (enop->eno_set_drv_limits != NULL) {
if ((rc = enop->eno_set_drv_limits(enp, edlp)) != 0)
goto fail1;
}
return (0);
fail1:
EFSYS_PROBE1(fail1, int, rc);
return (rc);
}
__checkReturn int
efx_nic_get_bar_region(
__in efx_nic_t *enp,
__in efx_nic_region_t region,
__out uint32_t *offsetp,
__out size_t *sizep)
{
efx_nic_ops_t *enop = enp->en_enop;
int rc;
EFSYS_ASSERT3U(enp->en_magic, ==, EFX_NIC_MAGIC);
EFSYS_ASSERT3U(enp->en_mod_flags, &, EFX_MOD_PROBE);
EFSYS_ASSERT3U(enp->en_mod_flags, &, EFX_MOD_NIC);
if (enop->eno_get_bar_region == NULL) {
rc = ENOTSUP;
goto fail1;
}
if ((rc = (enop->eno_get_bar_region)(enp,
region, offsetp, sizep)) != 0) {
goto fail2;
}
return (0);
fail2:
EFSYS_PROBE(fail2);
fail1:
EFSYS_PROBE1(fail1, int, rc);
return (rc);
}
__checkReturn int
efx_nic_get_vi_pool(
__in efx_nic_t *enp,
__out uint32_t *evq_countp,
__out uint32_t *rxq_countp,
__out uint32_t *txq_countp)
{
efx_nic_ops_t *enop = enp->en_enop;
efx_nic_cfg_t *encp = &enp->en_nic_cfg;
int rc;
EFSYS_ASSERT3U(enp->en_magic, ==, EFX_NIC_MAGIC);
EFSYS_ASSERT3U(enp->en_mod_flags, &, EFX_MOD_PROBE);
EFSYS_ASSERT3U(enp->en_mod_flags, &, EFX_MOD_NIC);
if (enop->eno_get_vi_pool != NULL) {
uint32_t vi_count = 0;
if ((rc = (enop->eno_get_vi_pool)(enp, &vi_count)) != 0)
goto fail1;
*evq_countp = vi_count;
*rxq_countp = vi_count;
*txq_countp = vi_count;
} else {
/* Use NIC limits as default value */
*evq_countp = encp->enc_evq_limit;
*rxq_countp = encp->enc_rxq_limit;
*txq_countp = encp->enc_txq_limit;
}
return (0);
fail1:
EFSYS_PROBE1(fail1, int, rc);
return (rc);
}
__checkReturn int
efx_nic_init(
__in efx_nic_t *enp)
{
efx_nic_ops_t *enop = enp->en_enop;
int rc;
EFSYS_ASSERT3U(enp->en_magic, ==, EFX_NIC_MAGIC);
EFSYS_ASSERT3U(enp->en_mod_flags, &, EFX_MOD_PROBE);
if (enp->en_mod_flags & EFX_MOD_NIC) {
rc = EINVAL;
goto fail1;
}
if ((rc = enop->eno_init(enp)) != 0)
goto fail2;
enp->en_mod_flags |= EFX_MOD_NIC;
return (0);
fail2:
EFSYS_PROBE(fail2);
fail1:
EFSYS_PROBE1(fail1, int, rc);
return (rc);
}
void
efx_nic_fini(
__in efx_nic_t *enp)
{
efx_nic_ops_t *enop = enp->en_enop;
EFSYS_ASSERT3U(enp->en_magic, ==, EFX_NIC_MAGIC);
EFSYS_ASSERT(enp->en_mod_flags & EFX_MOD_PROBE);
EFSYS_ASSERT(enp->en_mod_flags & EFX_MOD_NIC);
EFSYS_ASSERT(!(enp->en_mod_flags & EFX_MOD_INTR));
EFSYS_ASSERT(!(enp->en_mod_flags & EFX_MOD_EV));
EFSYS_ASSERT(!(enp->en_mod_flags & EFX_MOD_RX));
EFSYS_ASSERT(!(enp->en_mod_flags & EFX_MOD_TX));
enop->eno_fini(enp);
enp->en_mod_flags &= ~EFX_MOD_NIC;
}
void
efx_nic_unprobe(
__in efx_nic_t *enp)
{
efx_nic_ops_t *enop = enp->en_enop;
EFSYS_ASSERT3U(enp->en_magic, ==, EFX_NIC_MAGIC);
#if EFSYS_OPT_MCDI
EFSYS_ASSERT3U(enp->en_mod_flags, &, EFX_MOD_MCDI);
#endif /* EFSYS_OPT_MCDI */
EFSYS_ASSERT3U(enp->en_mod_flags, &, EFX_MOD_PROBE);
EFSYS_ASSERT(!(enp->en_mod_flags & EFX_MOD_NIC));
EFSYS_ASSERT(!(enp->en_mod_flags & EFX_MOD_INTR));
EFSYS_ASSERT(!(enp->en_mod_flags & EFX_MOD_EV));
EFSYS_ASSERT(!(enp->en_mod_flags & EFX_MOD_RX));
EFSYS_ASSERT(!(enp->en_mod_flags & EFX_MOD_TX));
efx_phy_unprobe(enp);
enop->eno_unprobe(enp);
enp->en_mod_flags &= ~EFX_MOD_PROBE;
}
void
efx_nic_destroy(
__in efx_nic_t *enp)
{
efsys_identifier_t *esip = enp->en_esip;
EFSYS_ASSERT3U(enp->en_magic, ==, EFX_NIC_MAGIC);
EFSYS_ASSERT3U(enp->en_mod_flags, ==, 0);
enp->en_family = 0;
enp->en_esip = NULL;
enp->en_esbp = NULL;
enp->en_eslp = NULL;
enp->en_enop = NULL;
enp->en_magic = 0;
/* Free the NIC object */
EFSYS_KMEM_FREE(esip, sizeof (efx_nic_t), enp);
}
__checkReturn int
efx_nic_reset(
__in efx_nic_t *enp)
{
efx_nic_ops_t *enop = enp->en_enop;
unsigned int mod_flags;
int rc;
EFSYS_ASSERT3U(enp->en_magic, ==, EFX_NIC_MAGIC);
EFSYS_ASSERT(enp->en_mod_flags & EFX_MOD_PROBE);
/*
* All modules except the MCDI, PROBE, NVRAM, VPD, MON (which we
* do not reset here) must have been shut down or never initialized.
*
* A rule of thumb here is: If the controller or MC reboots, is *any*
* state lost. If it's lost and needs reapplying, then the module
* *must* not be initialised during the reset.
*/
mod_flags = enp->en_mod_flags;
mod_flags &= ~(EFX_MOD_MCDI | EFX_MOD_PROBE | EFX_MOD_NVRAM |
EFX_MOD_VPD | EFX_MOD_MON);
EFSYS_ASSERT3U(mod_flags, ==, 0);
if (mod_flags != 0) {
rc = EINVAL;
goto fail1;
}
if ((rc = enop->eno_reset(enp)) != 0)
goto fail2;
enp->en_reset_flags |= EFX_RESET_MAC;
return (0);
fail2:
EFSYS_PROBE(fail2);
fail1:
EFSYS_PROBE1(fail1, int, rc);
return (rc);
}
const efx_nic_cfg_t *
efx_nic_cfg_get(
__in efx_nic_t *enp)
{
EFSYS_ASSERT3U(enp->en_magic, ==, EFX_NIC_MAGIC);
return (&(enp->en_nic_cfg));
}
#if EFSYS_OPT_DIAG
__checkReturn int
efx_nic_register_test(
__in efx_nic_t *enp)
{
efx_nic_ops_t *enop = enp->en_enop;
int rc;
EFSYS_ASSERT3U(enp->en_magic, ==, EFX_NIC_MAGIC);
EFSYS_ASSERT3U(enp->en_mod_flags, &, EFX_MOD_PROBE);
EFSYS_ASSERT(!(enp->en_mod_flags & EFX_MOD_NIC));
if ((rc = enop->eno_register_test(enp)) != 0)
goto fail1;
return (0);
fail1:
EFSYS_PROBE1(fail1, int, rc);
return (rc);
}
__checkReturn int
efx_nic_test_registers(
__in efx_nic_t *enp,
__in efx_register_set_t *rsp,
__in size_t count)
{
unsigned int bit;
efx_oword_t original;
efx_oword_t reg;
efx_oword_t buf;
int rc;
while (count > 0) {
/* This function is only suitable for registers */
EFSYS_ASSERT(rsp->rows == 1);
/* bit sweep on and off */
EFSYS_BAR_READO(enp->en_esbp, rsp->address, &original,
B_TRUE);
for (bit = 0; bit < 128; bit++) {
/* Is this bit in the mask? */
if (~(rsp->mask.eo_u32[bit >> 5]) & (1 << bit))
continue;
/* Test this bit can be set in isolation */
reg = original;
EFX_AND_OWORD(reg, rsp->mask);
EFX_SET_OWORD_BIT(reg, bit);
EFSYS_BAR_WRITEO(enp->en_esbp, rsp->address, &reg,
B_TRUE);
EFSYS_BAR_READO(enp->en_esbp, rsp->address, &buf,
B_TRUE);
EFX_AND_OWORD(buf, rsp->mask);
if (memcmp(&reg, &buf, sizeof (reg))) {
rc = EIO;
goto fail1;
}
/* Test this bit can be cleared in isolation */
EFX_OR_OWORD(reg, rsp->mask);
EFX_CLEAR_OWORD_BIT(reg, bit);
EFSYS_BAR_WRITEO(enp->en_esbp, rsp->address, &reg,
B_TRUE);
EFSYS_BAR_READO(enp->en_esbp, rsp->address, &buf,
B_TRUE);
EFX_AND_OWORD(buf, rsp->mask);
if (memcmp(&reg, &buf, sizeof (reg))) {
rc = EIO;
goto fail2;
}
}
/* Restore the old value */
EFSYS_BAR_WRITEO(enp->en_esbp, rsp->address, &original,
B_TRUE);
--count;
++rsp;
}
return (0);
fail2:
EFSYS_PROBE(fail2);
fail1:
EFSYS_PROBE1(fail1, int, rc);
/* Restore the old value */
EFSYS_BAR_WRITEO(enp->en_esbp, rsp->address, &original, B_TRUE);
return (rc);
}
__checkReturn int
efx_nic_test_tables(
__in efx_nic_t *enp,
__in efx_register_set_t *rsp,
__in efx_pattern_type_t pattern,
__in size_t count)
{
efx_sram_pattern_fn_t func;
unsigned int index;
unsigned int address;
efx_oword_t reg;
efx_oword_t buf;
int rc;
EFSYS_ASSERT(pattern < EFX_PATTERN_NTYPES);
func = __efx_sram_pattern_fns[pattern];
while (count > 0) {
/* Write */
address = rsp->address;
for (index = 0; index < rsp->rows; ++index) {
func(2 * index + 0, B_FALSE, &reg.eo_qword[0]);
func(2 * index + 1, B_FALSE, &reg.eo_qword[1]);
EFX_AND_OWORD(reg, rsp->mask);
EFSYS_BAR_WRITEO(enp->en_esbp, address, &reg, B_TRUE);
address += rsp->step;
}
/* Read */
address = rsp->address;
for (index = 0; index < rsp->rows; ++index) {
func(2 * index + 0, B_FALSE, &reg.eo_qword[0]);
func(2 * index + 1, B_FALSE, &reg.eo_qword[1]);
EFX_AND_OWORD(reg, rsp->mask);
EFSYS_BAR_READO(enp->en_esbp, address, &buf, B_TRUE);
if (memcmp(&reg, &buf, sizeof (reg))) {
rc = EIO;
goto fail1;
}
address += rsp->step;
}
++rsp;
--count;
}
return (0);
fail1:
EFSYS_PROBE1(fail1, int, rc);
return (rc);
}
#endif /* EFSYS_OPT_DIAG */
#if EFSYS_OPT_LOOPBACK
extern void
efx_loopback_mask(
__in efx_loopback_kind_t loopback_kind,
__out efx_qword_t *maskp)
{
efx_qword_t mask;
EFSYS_ASSERT3U(loopback_kind, <, EFX_LOOPBACK_NKINDS);
EFSYS_ASSERT(maskp != NULL);
/* Assert the MC_CMD_LOOPBACK and EFX_LOOPBACK namespace agree */
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_NONE == EFX_LOOPBACK_OFF);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_DATA == EFX_LOOPBACK_DATA);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_GMAC == EFX_LOOPBACK_GMAC);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_XGMII == EFX_LOOPBACK_XGMII);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_XGXS == EFX_LOOPBACK_XGXS);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_XAUI == EFX_LOOPBACK_XAUI);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_GMII == EFX_LOOPBACK_GMII);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_SGMII == EFX_LOOPBACK_SGMII);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_XGBR == EFX_LOOPBACK_XGBR);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_XFI == EFX_LOOPBACK_XFI);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_XAUI_FAR == EFX_LOOPBACK_XAUI_FAR);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_GMII_FAR == EFX_LOOPBACK_GMII_FAR);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_SGMII_FAR == EFX_LOOPBACK_SGMII_FAR);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_XFI_FAR == EFX_LOOPBACK_XFI_FAR);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_GPHY == EFX_LOOPBACK_GPHY);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_PHYXS == EFX_LOOPBACK_PHY_XS);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_PCS == EFX_LOOPBACK_PCS);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_PMAPMD == EFX_LOOPBACK_PMA_PMD);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_XPORT == EFX_LOOPBACK_XPORT);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_XGMII_WS == EFX_LOOPBACK_XGMII_WS);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_XAUI_WS == EFX_LOOPBACK_XAUI_WS);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_XAUI_WS_FAR ==
EFX_LOOPBACK_XAUI_WS_FAR);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_XAUI_WS_NEAR ==
EFX_LOOPBACK_XAUI_WS_NEAR);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_GMII_WS == EFX_LOOPBACK_GMII_WS);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_XFI_WS == EFX_LOOPBACK_XFI_WS);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_XFI_WS_FAR ==
EFX_LOOPBACK_XFI_WS_FAR);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_PHYXS_WS == EFX_LOOPBACK_PHYXS_WS);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_PMA_INT == EFX_LOOPBACK_PMA_INT);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_SD_NEAR == EFX_LOOPBACK_SD_NEAR);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_SD_FAR == EFX_LOOPBACK_SD_FAR);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_PMA_INT_WS ==
EFX_LOOPBACK_PMA_INT_WS);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_SD_FEP2_WS ==
EFX_LOOPBACK_SD_FEP2_WS);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_SD_FEP1_5_WS ==
EFX_LOOPBACK_SD_FEP1_5_WS);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_SD_FEP_WS == EFX_LOOPBACK_SD_FEP_WS);
EFX_STATIC_ASSERT(MC_CMD_LOOPBACK_SD_FES_WS == EFX_LOOPBACK_SD_FES_WS);
/* Build bitmask of possible loopback types */
EFX_ZERO_QWORD(mask);
if ((loopback_kind == EFX_LOOPBACK_KIND_OFF) ||
(loopback_kind == EFX_LOOPBACK_KIND_ALL)) {
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_OFF);
}
if ((loopback_kind == EFX_LOOPBACK_KIND_MAC) ||
(loopback_kind == EFX_LOOPBACK_KIND_ALL)) {
/*
* The "MAC" grouping has historically been used by drivers to
* mean loopbacks supported by on-chip hardware. Keep that
* meaning here, and include on-chip PHY layer loopbacks.
*/
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_DATA);
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_GMAC);
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_XGMII);
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_XGXS);
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_XAUI);
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_GMII);
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_SGMII);
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_XGBR);
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_XFI);
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_XAUI_FAR);
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_GMII_FAR);
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_SGMII_FAR);
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_XFI_FAR);
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_PMA_INT);
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_SD_NEAR);
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_SD_FAR);
}
if ((loopback_kind == EFX_LOOPBACK_KIND_PHY) ||
(loopback_kind == EFX_LOOPBACK_KIND_ALL)) {
/*
* The "PHY" grouping has historically been used by drivers to
* mean loopbacks supported by off-chip hardware. Keep that
* meaning here.
*/
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_GPHY);
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_PHY_XS);
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_PCS);
EFX_SET_QWORD_BIT(mask, EFX_LOOPBACK_PMA_PMD);
}
*maskp = mask;
}
__checkReturn int
efx_mcdi_get_loopback_modes(
__in efx_nic_t *enp)
{
efx_nic_cfg_t *encp = &(enp->en_nic_cfg);
efx_mcdi_req_t req;
uint8_t payload[MAX(MC_CMD_GET_LOOPBACK_MODES_IN_LEN,
MC_CMD_GET_LOOPBACK_MODES_OUT_LEN)];
efx_qword_t mask;
efx_qword_t modes;
int rc;
(void) memset(payload, 0, sizeof (payload));
req.emr_cmd = MC_CMD_GET_LOOPBACK_MODES;
req.emr_in_buf = payload;
req.emr_in_length = MC_CMD_GET_LOOPBACK_MODES_IN_LEN;
req.emr_out_buf = payload;
req.emr_out_length = MC_CMD_GET_LOOPBACK_MODES_OUT_LEN;
efx_mcdi_execute(enp, &req);
if (req.emr_rc != 0) {
rc = req.emr_rc;
goto fail1;
}
if (req.emr_out_length_used <
MC_CMD_GET_LOOPBACK_MODES_OUT_SUGGESTED_OFST +
MC_CMD_GET_LOOPBACK_MODES_OUT_SUGGESTED_LEN) {
rc = EMSGSIZE;
goto fail2;
}
/*
* We assert the MC_CMD_LOOPBACK and EFX_LOOPBACK namespaces agree
* in efx_loopback_mask() and in siena_phy.c:siena_phy_get_link().
*/
efx_loopback_mask(EFX_LOOPBACK_KIND_ALL, &mask);
EFX_AND_QWORD(mask,
*MCDI_OUT2(req, efx_qword_t, GET_LOOPBACK_MODES_OUT_SUGGESTED));
modes = *MCDI_OUT2(req, efx_qword_t, GET_LOOPBACK_MODES_OUT_100M);
EFX_AND_QWORD(modes, mask);
encp->enc_loopback_types[EFX_LINK_100FDX] = modes;
modes = *MCDI_OUT2(req, efx_qword_t, GET_LOOPBACK_MODES_OUT_1G);
EFX_AND_QWORD(modes, mask);
encp->enc_loopback_types[EFX_LINK_1000FDX] = modes;
modes = *MCDI_OUT2(req, efx_qword_t, GET_LOOPBACK_MODES_OUT_10G);
EFX_AND_QWORD(modes, mask);
encp->enc_loopback_types[EFX_LINK_10000FDX] = modes;
if (req.emr_out_length_used >=
MC_CMD_GET_LOOPBACK_MODES_OUT_40G_OFST +
MC_CMD_GET_LOOPBACK_MODES_OUT_40G_LEN) {
/* Response includes 40G loopback modes */
modes =
*MCDI_OUT2(req, efx_qword_t, GET_LOOPBACK_MODES_OUT_40G);
EFX_AND_QWORD(modes, mask);
encp->enc_loopback_types[EFX_LINK_40000FDX] = modes;
}
EFX_ZERO_QWORD(modes);
EFX_SET_QWORD_BIT(modes, EFX_LOOPBACK_OFF);
EFX_OR_QWORD(modes, encp->enc_loopback_types[EFX_LINK_100FDX]);
EFX_OR_QWORD(modes, encp->enc_loopback_types[EFX_LINK_1000FDX]);
EFX_OR_QWORD(modes, encp->enc_loopback_types[EFX_LINK_10000FDX]);
EFX_OR_QWORD(modes, encp->enc_loopback_types[EFX_LINK_40000FDX]);
encp->enc_loopback_types[EFX_LINK_UNKNOWN] = modes;
return (0);
fail2:
EFSYS_PROBE(fail2);
fail1:
EFSYS_PROBE1(fail1, int, rc);
return (rc);
}
#endif /* EFSYS_OPT_LOOPBACK */