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linux-next/drivers/infiniband/hw/qib/qib_sd7220.c
Ben Hutchings ecd4b48a16 IB/qib: Use request_firmware() to load SD7220 firmware
Extract the microcode for the QLogic QLE7220 series IB HCA and use the
kernel microcode request facility to load the microcode.  This
supports Debian Linux's requirements to separate microcode which
doesn't have open source code available from the device driver.

Signed-off-by: Ben Hutchings <ben@decadent.org.uk>
Signed-off-by: Roland Dreier <rolandd@cisco.com>
2010-07-08 13:27:05 -07:00

1448 lines
40 KiB
C

/*
* Copyright (c) 2006, 2007, 2008, 2009, 2010 QLogic Corporation.
* All rights reserved.
* Copyright (c) 2003, 2004, 2005, 2006 PathScale, Inc. All rights reserved.
*
* This software is available to you under a choice of one of two
* licenses. You may choose to be licensed under the terms of the GNU
* General Public License (GPL) Version 2, available from the file
* COPYING in the main directory of this source tree, or the
* OpenIB.org BSD license below:
*
* Redistribution and use in source and binary forms, with or
* without modification, are permitted provided that the following
* conditions are met:
*
* - Redistributions of source code must retain the above
* copyright notice, this list of conditions and the following
* disclaimer.
*
* - 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.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS
* BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN
* ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
* CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE.
*/
/*
* This file contains all of the code that is specific to the SerDes
* on the QLogic_IB 7220 chip.
*/
#include <linux/pci.h>
#include <linux/delay.h>
#include <linux/firmware.h>
#include "qib.h"
#include "qib_7220.h"
#define SD7220_FW_NAME "qlogic/sd7220.fw"
MODULE_FIRMWARE(SD7220_FW_NAME);
/*
* Same as in qib_iba7220.c, but just the registers needed here.
* Could move whole set to qib_7220.h, but decided better to keep
* local.
*/
#define KREG_IDX(regname) (QIB_7220_##regname##_OFFS / sizeof(u64))
#define kr_hwerrclear KREG_IDX(HwErrClear)
#define kr_hwerrmask KREG_IDX(HwErrMask)
#define kr_hwerrstatus KREG_IDX(HwErrStatus)
#define kr_ibcstatus KREG_IDX(IBCStatus)
#define kr_ibserdesctrl KREG_IDX(IBSerDesCtrl)
#define kr_scratch KREG_IDX(Scratch)
#define kr_xgxs_cfg KREG_IDX(XGXSCfg)
/* these are used only here, not in qib_iba7220.c */
#define kr_ibsd_epb_access_ctrl KREG_IDX(ibsd_epb_access_ctrl)
#define kr_ibsd_epb_transaction_reg KREG_IDX(ibsd_epb_transaction_reg)
#define kr_pciesd_epb_transaction_reg KREG_IDX(pciesd_epb_transaction_reg)
#define kr_pciesd_epb_access_ctrl KREG_IDX(pciesd_epb_access_ctrl)
#define kr_serdes_ddsrxeq0 KREG_IDX(SerDes_DDSRXEQ0)
/*
* The IBSerDesMappTable is a memory that holds values to be stored in
* various SerDes registers by IBC.
*/
#define kr_serdes_maptable KREG_IDX(IBSerDesMappTable)
/*
* Below used for sdnum parameter, selecting one of the two sections
* used for PCIe, or the single SerDes used for IB.
*/
#define PCIE_SERDES0 0
#define PCIE_SERDES1 1
/*
* The EPB requires addressing in a particular form. EPB_LOC() is intended
* to make #definitions a little more readable.
*/
#define EPB_ADDR_SHF 8
#define EPB_LOC(chn, elt, reg) \
(((elt & 0xf) | ((chn & 7) << 4) | ((reg & 0x3f) << 9)) << \
EPB_ADDR_SHF)
#define EPB_IB_QUAD0_CS_SHF (25)
#define EPB_IB_QUAD0_CS (1U << EPB_IB_QUAD0_CS_SHF)
#define EPB_IB_UC_CS_SHF (26)
#define EPB_PCIE_UC_CS_SHF (27)
#define EPB_GLOBAL_WR (1U << (EPB_ADDR_SHF + 8))
/* Forward declarations. */
static int qib_sd7220_reg_mod(struct qib_devdata *dd, int sdnum, u32 loc,
u32 data, u32 mask);
static int ibsd_mod_allchnls(struct qib_devdata *dd, int loc, int val,
int mask);
static int qib_sd_trimdone_poll(struct qib_devdata *dd);
static void qib_sd_trimdone_monitor(struct qib_devdata *dd, const char *where);
static int qib_sd_setvals(struct qib_devdata *dd);
static int qib_sd_early(struct qib_devdata *dd);
static int qib_sd_dactrim(struct qib_devdata *dd);
static int qib_internal_presets(struct qib_devdata *dd);
/* Tweak the register (CMUCTRL5) that contains the TRIMSELF controls */
static int qib_sd_trimself(struct qib_devdata *dd, int val);
static int epb_access(struct qib_devdata *dd, int sdnum, int claim);
static int qib_sd7220_ib_load(struct qib_devdata *dd,
const struct firmware *fw);
static int qib_sd7220_ib_vfy(struct qib_devdata *dd,
const struct firmware *fw);
/*
* Below keeps track of whether the "once per power-on" initialization has
* been done, because uC code Version 1.32.17 or higher allows the uC to
* be reset at will, and Automatic Equalization may require it. So the
* state of the reset "pin", is no longer valid. Instead, we check for the
* actual uC code having been loaded.
*/
static int qib_ibsd_ucode_loaded(struct qib_pportdata *ppd,
const struct firmware *fw)
{
struct qib_devdata *dd = ppd->dd;
if (!dd->cspec->serdes_first_init_done &&
qib_sd7220_ib_vfy(dd, fw) > 0)
dd->cspec->serdes_first_init_done = 1;
return dd->cspec->serdes_first_init_done;
}
/* repeat #define for local use. "Real" #define is in qib_iba7220.c */
#define QLOGIC_IB_HWE_IB_UC_MEMORYPARITYERR 0x0000004000000000ULL
#define IB_MPREG5 (EPB_LOC(6, 0, 0xE) | (1L << EPB_IB_UC_CS_SHF))
#define IB_MPREG6 (EPB_LOC(6, 0, 0xF) | (1U << EPB_IB_UC_CS_SHF))
#define UC_PAR_CLR_D 8
#define UC_PAR_CLR_M 0xC
#define IB_CTRL2(chn) (EPB_LOC(chn, 7, 3) | EPB_IB_QUAD0_CS)
#define START_EQ1(chan) EPB_LOC(chan, 7, 0x27)
void qib_sd7220_clr_ibpar(struct qib_devdata *dd)
{
int ret;
/* clear, then re-enable parity errs */
ret = qib_sd7220_reg_mod(dd, IB_7220_SERDES, IB_MPREG6,
UC_PAR_CLR_D, UC_PAR_CLR_M);
if (ret < 0) {
qib_dev_err(dd, "Failed clearing IBSerDes Parity err\n");
goto bail;
}
ret = qib_sd7220_reg_mod(dd, IB_7220_SERDES, IB_MPREG6, 0,
UC_PAR_CLR_M);
qib_read_kreg32(dd, kr_scratch);
udelay(4);
qib_write_kreg(dd, kr_hwerrclear,
QLOGIC_IB_HWE_IB_UC_MEMORYPARITYERR);
qib_read_kreg32(dd, kr_scratch);
bail:
return;
}
/*
* After a reset or other unusual event, the epb interface may need
* to be re-synchronized, between the host and the uC.
* returns <0 for failure to resync within IBSD_RESYNC_TRIES (not expected)
*/
#define IBSD_RESYNC_TRIES 3
#define IB_PGUDP(chn) (EPB_LOC((chn), 2, 1) | EPB_IB_QUAD0_CS)
#define IB_CMUDONE(chn) (EPB_LOC((chn), 7, 0xF) | EPB_IB_QUAD0_CS)
static int qib_resync_ibepb(struct qib_devdata *dd)
{
int ret, pat, tries, chn;
u32 loc;
ret = -1;
chn = 0;
for (tries = 0; tries < (4 * IBSD_RESYNC_TRIES); ++tries) {
loc = IB_PGUDP(chn);
ret = qib_sd7220_reg_mod(dd, IB_7220_SERDES, loc, 0, 0);
if (ret < 0) {
qib_dev_err(dd, "Failed read in resync\n");
continue;
}
if (ret != 0xF0 && ret != 0x55 && tries == 0)
qib_dev_err(dd, "unexpected pattern in resync\n");
pat = ret ^ 0xA5; /* alternate F0 and 55 */
ret = qib_sd7220_reg_mod(dd, IB_7220_SERDES, loc, pat, 0xFF);
if (ret < 0) {
qib_dev_err(dd, "Failed write in resync\n");
continue;
}
ret = qib_sd7220_reg_mod(dd, IB_7220_SERDES, loc, 0, 0);
if (ret < 0) {
qib_dev_err(dd, "Failed re-read in resync\n");
continue;
}
if (ret != pat) {
qib_dev_err(dd, "Failed compare1 in resync\n");
continue;
}
loc = IB_CMUDONE(chn);
ret = qib_sd7220_reg_mod(dd, IB_7220_SERDES, loc, 0, 0);
if (ret < 0) {
qib_dev_err(dd, "Failed CMUDONE rd in resync\n");
continue;
}
if ((ret & 0x70) != ((chn << 4) | 0x40)) {
qib_dev_err(dd, "Bad CMUDONE value %02X, chn %d\n",
ret, chn);
continue;
}
if (++chn == 4)
break; /* Success */
}
return (ret > 0) ? 0 : ret;
}
/*
* Localize the stuff that should be done to change IB uC reset
* returns <0 for errors.
*/
static int qib_ibsd_reset(struct qib_devdata *dd, int assert_rst)
{
u64 rst_val;
int ret = 0;
unsigned long flags;
rst_val = qib_read_kreg64(dd, kr_ibserdesctrl);
if (assert_rst) {
/*
* Vendor recommends "interrupting" uC before reset, to
* minimize possible glitches.
*/
spin_lock_irqsave(&dd->cspec->sdepb_lock, flags);
epb_access(dd, IB_7220_SERDES, 1);
rst_val |= 1ULL;
/* Squelch possible parity error from _asserting_ reset */
qib_write_kreg(dd, kr_hwerrmask,
dd->cspec->hwerrmask &
~QLOGIC_IB_HWE_IB_UC_MEMORYPARITYERR);
qib_write_kreg(dd, kr_ibserdesctrl, rst_val);
/* flush write, delay to ensure it took effect */
qib_read_kreg32(dd, kr_scratch);
udelay(2);
/* once it's reset, can remove interrupt */
epb_access(dd, IB_7220_SERDES, -1);
spin_unlock_irqrestore(&dd->cspec->sdepb_lock, flags);
} else {
/*
* Before we de-assert reset, we need to deal with
* possible glitch on the Parity-error line.
* Suppress it around the reset, both in chip-level
* hwerrmask and in IB uC control reg. uC will allow
* it again during startup.
*/
u64 val;
rst_val &= ~(1ULL);
qib_write_kreg(dd, kr_hwerrmask,
dd->cspec->hwerrmask &
~QLOGIC_IB_HWE_IB_UC_MEMORYPARITYERR);
ret = qib_resync_ibepb(dd);
if (ret < 0)
qib_dev_err(dd, "unable to re-sync IB EPB\n");
/* set uC control regs to suppress parity errs */
ret = qib_sd7220_reg_mod(dd, IB_7220_SERDES, IB_MPREG5, 1, 1);
if (ret < 0)
goto bail;
/* IB uC code past Version 1.32.17 allow suppression of wdog */
ret = qib_sd7220_reg_mod(dd, IB_7220_SERDES, IB_MPREG6, 0x80,
0x80);
if (ret < 0) {
qib_dev_err(dd, "Failed to set WDOG disable\n");
goto bail;
}
qib_write_kreg(dd, kr_ibserdesctrl, rst_val);
/* flush write, delay for startup */
qib_read_kreg32(dd, kr_scratch);
udelay(1);
/* clear, then re-enable parity errs */
qib_sd7220_clr_ibpar(dd);
val = qib_read_kreg64(dd, kr_hwerrstatus);
if (val & QLOGIC_IB_HWE_IB_UC_MEMORYPARITYERR) {
qib_dev_err(dd, "IBUC Parity still set after RST\n");
dd->cspec->hwerrmask &=
~QLOGIC_IB_HWE_IB_UC_MEMORYPARITYERR;
}
qib_write_kreg(dd, kr_hwerrmask,
dd->cspec->hwerrmask);
}
bail:
return ret;
}
static void qib_sd_trimdone_monitor(struct qib_devdata *dd,
const char *where)
{
int ret, chn, baduns;
u64 val;
if (!where)
where = "?";
/* give time for reset to settle out in EPB */
udelay(2);
ret = qib_resync_ibepb(dd);
if (ret < 0)
qib_dev_err(dd, "not able to re-sync IB EPB (%s)\n", where);
/* Do "sacrificial read" to get EPB in sane state after reset */
ret = qib_sd7220_reg_mod(dd, IB_7220_SERDES, IB_CTRL2(0), 0, 0);
if (ret < 0)
qib_dev_err(dd, "Failed TRIMDONE 1st read, (%s)\n", where);
/* Check/show "summary" Trim-done bit in IBCStatus */
val = qib_read_kreg64(dd, kr_ibcstatus);
if (!(val & (1ULL << 11)))
qib_dev_err(dd, "IBCS TRIMDONE clear (%s)\n", where);
/*
* Do "dummy read/mod/wr" to get EPB in sane state after reset
* The default value for MPREG6 is 0.
*/
udelay(2);
ret = qib_sd7220_reg_mod(dd, IB_7220_SERDES, IB_MPREG6, 0x80, 0x80);
if (ret < 0)
qib_dev_err(dd, "Failed Dummy RMW, (%s)\n", where);
udelay(10);
baduns = 0;
for (chn = 3; chn >= 0; --chn) {
/* Read CTRL reg for each channel to check TRIMDONE */
ret = qib_sd7220_reg_mod(dd, IB_7220_SERDES,
IB_CTRL2(chn), 0, 0);
if (ret < 0)
qib_dev_err(dd, "Failed checking TRIMDONE, chn %d"
" (%s)\n", chn, where);
if (!(ret & 0x10)) {
int probe;
baduns |= (1 << chn);
qib_dev_err(dd, "TRIMDONE cleared on chn %d (%02X)."
" (%s)\n", chn, ret, where);
probe = qib_sd7220_reg_mod(dd, IB_7220_SERDES,
IB_PGUDP(0), 0, 0);
qib_dev_err(dd, "probe is %d (%02X)\n",
probe, probe);
probe = qib_sd7220_reg_mod(dd, IB_7220_SERDES,
IB_CTRL2(chn), 0, 0);
qib_dev_err(dd, "re-read: %d (%02X)\n",
probe, probe);
ret = qib_sd7220_reg_mod(dd, IB_7220_SERDES,
IB_CTRL2(chn), 0x10, 0x10);
if (ret < 0)
qib_dev_err(dd,
"Err on TRIMDONE rewrite1\n");
}
}
for (chn = 3; chn >= 0; --chn) {
/* Read CTRL reg for each channel to check TRIMDONE */
if (baduns & (1 << chn)) {
qib_dev_err(dd,
"Reseting TRIMDONE on chn %d (%s)\n",
chn, where);
ret = qib_sd7220_reg_mod(dd, IB_7220_SERDES,
IB_CTRL2(chn), 0x10, 0x10);
if (ret < 0)
qib_dev_err(dd, "Failed re-setting "
"TRIMDONE, chn %d (%s)\n",
chn, where);
}
}
}
/*
* Below is portion of IBA7220-specific bringup_serdes() that actually
* deals with registers and memory within the SerDes itself.
* Post IB uC code version 1.32.17, was_reset being 1 is not really
* informative, so we double-check.
*/
int qib_sd7220_init(struct qib_devdata *dd)
{
const struct firmware *fw;
int ret = 1; /* default to failure */
int first_reset, was_reset;
/* SERDES MPU reset recorded in D0 */
was_reset = (qib_read_kreg64(dd, kr_ibserdesctrl) & 1);
if (!was_reset) {
/* entered with reset not asserted, we need to do it */
qib_ibsd_reset(dd, 1);
qib_sd_trimdone_monitor(dd, "Driver-reload");
}
ret = request_firmware(&fw, SD7220_FW_NAME, &dd->pcidev->dev);
if (ret) {
qib_dev_err(dd, "Failed to load IB SERDES image\n");
goto done;
}
/* Substitute our deduced value for was_reset */
ret = qib_ibsd_ucode_loaded(dd->pport, fw);
if (ret < 0)
goto bail;
first_reset = !ret; /* First reset if IBSD uCode not yet loaded */
/*
* Alter some regs per vendor latest doc, reset-defaults
* are not right for IB.
*/
ret = qib_sd_early(dd);
if (ret < 0) {
qib_dev_err(dd, "Failed to set IB SERDES early defaults\n");
goto bail;
}
/*
* Set DAC manual trim IB.
* We only do this once after chip has been reset (usually
* same as once per system boot).
*/
if (first_reset) {
ret = qib_sd_dactrim(dd);
if (ret < 0) {
qib_dev_err(dd, "Failed IB SERDES DAC trim\n");
goto bail;
}
}
/*
* Set various registers (DDS and RXEQ) that will be
* controlled by IBC (in 1.2 mode) to reasonable preset values
* Calling the "internal" version avoids the "check for needed"
* and "trimdone monitor" that might be counter-productive.
*/
ret = qib_internal_presets(dd);
if (ret < 0) {
qib_dev_err(dd, "Failed to set IB SERDES presets\n");
goto bail;
}
ret = qib_sd_trimself(dd, 0x80);
if (ret < 0) {
qib_dev_err(dd, "Failed to set IB SERDES TRIMSELF\n");
goto bail;
}
/* Load image, then try to verify */
ret = 0; /* Assume success */
if (first_reset) {
int vfy;
int trim_done;
ret = qib_sd7220_ib_load(dd, fw);
if (ret < 0) {
qib_dev_err(dd, "Failed to load IB SERDES image\n");
goto bail;
} else {
/* Loaded image, try to verify */
vfy = qib_sd7220_ib_vfy(dd, fw);
if (vfy != ret) {
qib_dev_err(dd, "SERDES PRAM VFY failed\n");
goto bail;
} /* end if verified */
} /* end if loaded */
/*
* Loaded and verified. Almost good...
* hold "success" in ret
*/
ret = 0;
/*
* Prev steps all worked, continue bringup
* De-assert RESET to uC, only in first reset, to allow
* trimming.
*
* Since our default setup sets START_EQ1 to
* PRESET, we need to clear that for this very first run.
*/
ret = ibsd_mod_allchnls(dd, START_EQ1(0), 0, 0x38);
if (ret < 0) {
qib_dev_err(dd, "Failed clearing START_EQ1\n");
goto bail;
}
qib_ibsd_reset(dd, 0);
/*
* If this is not the first reset, trimdone should be set
* already. We may need to check about this.
*/
trim_done = qib_sd_trimdone_poll(dd);
/*
* Whether or not trimdone succeeded, we need to put the
* uC back into reset to avoid a possible fight with the
* IBC state-machine.
*/
qib_ibsd_reset(dd, 1);
if (!trim_done) {
qib_dev_err(dd, "No TRIMDONE seen\n");
goto bail;
}
/*
* DEBUG: check each time we reset if trimdone bits have
* gotten cleared, and re-set them.
*/
qib_sd_trimdone_monitor(dd, "First-reset");
/* Remember so we do not re-do the load, dactrim, etc. */
dd->cspec->serdes_first_init_done = 1;
}
/*
* setup for channel training and load values for
* RxEq and DDS in tables used by IBC in IB1.2 mode
*/
ret = 0;
if (qib_sd_setvals(dd) >= 0)
goto done;
bail:
ret = 1;
done:
/* start relock timer regardless, but start at 1 second */
set_7220_relock_poll(dd, -1);
release_firmware(fw);
return ret;
}
#define EPB_ACC_REQ 1
#define EPB_ACC_GNT 0x100
#define EPB_DATA_MASK 0xFF
#define EPB_RD (1ULL << 24)
#define EPB_TRANS_RDY (1ULL << 31)
#define EPB_TRANS_ERR (1ULL << 30)
#define EPB_TRANS_TRIES 5
/*
* query, claim, release ownership of the EPB (External Parallel Bus)
* for a specified SERDES.
* the "claim" parameter is >0 to claim, <0 to release, 0 to query.
* Returns <0 for errors, >0 if we had ownership, else 0.
*/
static int epb_access(struct qib_devdata *dd, int sdnum, int claim)
{
u16 acc;
u64 accval;
int owned = 0;
u64 oct_sel = 0;
switch (sdnum) {
case IB_7220_SERDES:
/*
* The IB SERDES "ownership" is fairly simple. A single each
* request/grant.
*/
acc = kr_ibsd_epb_access_ctrl;
break;
case PCIE_SERDES0:
case PCIE_SERDES1:
/* PCIe SERDES has two "octants", need to select which */
acc = kr_pciesd_epb_access_ctrl;
oct_sel = (2 << (sdnum - PCIE_SERDES0));
break;
default:
return 0;
}
/* Make sure any outstanding transaction was seen */
qib_read_kreg32(dd, kr_scratch);
udelay(15);
accval = qib_read_kreg32(dd, acc);
owned = !!(accval & EPB_ACC_GNT);
if (claim < 0) {
/* Need to release */
u64 pollval;
/*
* The only writeable bits are the request and CS.
* Both should be clear
*/
u64 newval = 0;
qib_write_kreg(dd, acc, newval);
/* First read after write is not trustworthy */
pollval = qib_read_kreg32(dd, acc);
udelay(5);
pollval = qib_read_kreg32(dd, acc);
if (pollval & EPB_ACC_GNT)
owned = -1;
} else if (claim > 0) {
/* Need to claim */
u64 pollval;
u64 newval = EPB_ACC_REQ | oct_sel;
qib_write_kreg(dd, acc, newval);
/* First read after write is not trustworthy */
pollval = qib_read_kreg32(dd, acc);
udelay(5);
pollval = qib_read_kreg32(dd, acc);
if (!(pollval & EPB_ACC_GNT))
owned = -1;
}
return owned;
}
/*
* Lemma to deal with race condition of write..read to epb regs
*/
static int epb_trans(struct qib_devdata *dd, u16 reg, u64 i_val, u64 *o_vp)
{
int tries;
u64 transval;
qib_write_kreg(dd, reg, i_val);
/* Throw away first read, as RDY bit may be stale */
transval = qib_read_kreg64(dd, reg);
for (tries = EPB_TRANS_TRIES; tries; --tries) {
transval = qib_read_kreg32(dd, reg);
if (transval & EPB_TRANS_RDY)
break;
udelay(5);
}
if (transval & EPB_TRANS_ERR)
return -1;
if (tries > 0 && o_vp)
*o_vp = transval;
return tries;
}
/**
* qib_sd7220_reg_mod - modify SERDES register
* @dd: the qlogic_ib device
* @sdnum: which SERDES to access
* @loc: location - channel, element, register, as packed by EPB_LOC() macro.
* @wd: Write Data - value to set in register
* @mask: ones where data should be spliced into reg.
*
* Basic register read/modify/write, with un-needed acesses elided. That is,
* a mask of zero will prevent write, while a mask of 0xFF will prevent read.
* returns current (presumed, if a write was done) contents of selected
* register, or <0 if errors.
*/
static int qib_sd7220_reg_mod(struct qib_devdata *dd, int sdnum, u32 loc,
u32 wd, u32 mask)
{
u16 trans;
u64 transval;
int owned;
int tries, ret;
unsigned long flags;
switch (sdnum) {
case IB_7220_SERDES:
trans = kr_ibsd_epb_transaction_reg;
break;
case PCIE_SERDES0:
case PCIE_SERDES1:
trans = kr_pciesd_epb_transaction_reg;
break;
default:
return -1;
}
/*
* All access is locked in software (vs other host threads) and
* hardware (vs uC access).
*/
spin_lock_irqsave(&dd->cspec->sdepb_lock, flags);
owned = epb_access(dd, sdnum, 1);
if (owned < 0) {
spin_unlock_irqrestore(&dd->cspec->sdepb_lock, flags);
return -1;
}
ret = 0;
for (tries = EPB_TRANS_TRIES; tries; --tries) {
transval = qib_read_kreg32(dd, trans);
if (transval & EPB_TRANS_RDY)
break;
udelay(5);
}
if (tries > 0) {
tries = 1; /* to make read-skip work */
if (mask != 0xFF) {
/*
* Not a pure write, so need to read.
* loc encodes chip-select as well as address
*/
transval = loc | EPB_RD;
tries = epb_trans(dd, trans, transval, &transval);
}
if (tries > 0 && mask != 0) {
/*
* Not a pure read, so need to write.
*/
wd = (wd & mask) | (transval & ~mask);
transval = loc | (wd & EPB_DATA_MASK);
tries = epb_trans(dd, trans, transval, &transval);
}
}
/* else, failed to see ready, what error-handling? */
/*
* Release bus. Failure is an error.
*/
if (epb_access(dd, sdnum, -1) < 0)
ret = -1;
else
ret = transval & EPB_DATA_MASK;
spin_unlock_irqrestore(&dd->cspec->sdepb_lock, flags);
if (tries <= 0)
ret = -1;
return ret;
}
#define EPB_ROM_R (2)
#define EPB_ROM_W (1)
/*
* Below, all uC-related, use appropriate UC_CS, depending
* on which SerDes is used.
*/
#define EPB_UC_CTL EPB_LOC(6, 0, 0)
#define EPB_MADDRL EPB_LOC(6, 0, 2)
#define EPB_MADDRH EPB_LOC(6, 0, 3)
#define EPB_ROMDATA EPB_LOC(6, 0, 4)
#define EPB_RAMDATA EPB_LOC(6, 0, 5)
/* Transfer date to/from uC Program RAM of IB or PCIe SerDes */
static int qib_sd7220_ram_xfer(struct qib_devdata *dd, int sdnum, u32 loc,
u8 *buf, int cnt, int rd_notwr)
{
u16 trans;
u64 transval;
u64 csbit;
int owned;
int tries;
int sofar;
int addr;
int ret;
unsigned long flags;
const char *op;
/* Pick appropriate transaction reg and "Chip select" for this serdes */
switch (sdnum) {
case IB_7220_SERDES:
csbit = 1ULL << EPB_IB_UC_CS_SHF;
trans = kr_ibsd_epb_transaction_reg;
break;
case PCIE_SERDES0:
case PCIE_SERDES1:
/* PCIe SERDES has uC "chip select" in different bit, too */
csbit = 1ULL << EPB_PCIE_UC_CS_SHF;
trans = kr_pciesd_epb_transaction_reg;
break;
default:
return -1;
}
op = rd_notwr ? "Rd" : "Wr";
spin_lock_irqsave(&dd->cspec->sdepb_lock, flags);
owned = epb_access(dd, sdnum, 1);
if (owned < 0) {
spin_unlock_irqrestore(&dd->cspec->sdepb_lock, flags);
return -1;
}
/*
* In future code, we may need to distinguish several address ranges,
* and select various memories based on this. For now, just trim
* "loc" (location including address and memory select) to
* "addr" (address within memory). we will only support PRAM
* The memory is 8KB.
*/
addr = loc & 0x1FFF;
for (tries = EPB_TRANS_TRIES; tries; --tries) {
transval = qib_read_kreg32(dd, trans);
if (transval & EPB_TRANS_RDY)
break;
udelay(5);
}
sofar = 0;
if (tries > 0) {
/*
* Every "memory" access is doubly-indirect.
* We set two bytes of address, then read/write
* one or mores bytes of data.
*/
/* First, we set control to "Read" or "Write" */
transval = csbit | EPB_UC_CTL |
(rd_notwr ? EPB_ROM_R : EPB_ROM_W);
tries = epb_trans(dd, trans, transval, &transval);
while (tries > 0 && sofar < cnt) {
if (!sofar) {
/* Only set address at start of chunk */
int addrbyte = (addr + sofar) >> 8;
transval = csbit | EPB_MADDRH | addrbyte;
tries = epb_trans(dd, trans, transval,
&transval);
if (tries <= 0)
break;
addrbyte = (addr + sofar) & 0xFF;
transval = csbit | EPB_MADDRL | addrbyte;
tries = epb_trans(dd, trans, transval,
&transval);
if (tries <= 0)
break;
}
if (rd_notwr)
transval = csbit | EPB_ROMDATA | EPB_RD;
else
transval = csbit | EPB_ROMDATA | buf[sofar];
tries = epb_trans(dd, trans, transval, &transval);
if (tries <= 0)
break;
if (rd_notwr)
buf[sofar] = transval & EPB_DATA_MASK;
++sofar;
}
/* Finally, clear control-bit for Read or Write */
transval = csbit | EPB_UC_CTL;
tries = epb_trans(dd, trans, transval, &transval);
}
ret = sofar;
/* Release bus. Failure is an error */
if (epb_access(dd, sdnum, -1) < 0)
ret = -1;
spin_unlock_irqrestore(&dd->cspec->sdepb_lock, flags);
if (tries <= 0)
ret = -1;
return ret;
}
#define PROG_CHUNK 64
static int qib_sd7220_prog_ld(struct qib_devdata *dd, int sdnum,
const u8 *img, int len, int offset)
{
int cnt, sofar, req;
sofar = 0;
while (sofar < len) {
req = len - sofar;
if (req > PROG_CHUNK)
req = PROG_CHUNK;
cnt = qib_sd7220_ram_xfer(dd, sdnum, offset + sofar,
(u8 *)img + sofar, req, 0);
if (cnt < req) {
sofar = -1;
break;
}
sofar += req;
}
return sofar;
}
#define VFY_CHUNK 64
#define SD_PRAM_ERROR_LIMIT 42
static int qib_sd7220_prog_vfy(struct qib_devdata *dd, int sdnum,
const u8 *img, int len, int offset)
{
int cnt, sofar, req, idx, errors;
unsigned char readback[VFY_CHUNK];
errors = 0;
sofar = 0;
while (sofar < len) {
req = len - sofar;
if (req > VFY_CHUNK)
req = VFY_CHUNK;
cnt = qib_sd7220_ram_xfer(dd, sdnum, sofar + offset,
readback, req, 1);
if (cnt < req) {
/* failed in read itself */
sofar = -1;
break;
}
for (idx = 0; idx < cnt; ++idx) {
if (readback[idx] != img[idx+sofar])
++errors;
}
sofar += cnt;
}
return errors ? -errors : sofar;
}
static int
qib_sd7220_ib_load(struct qib_devdata *dd, const struct firmware *fw)
{
return qib_sd7220_prog_ld(dd, IB_7220_SERDES, fw->data, fw->size, 0);
}
static int
qib_sd7220_ib_vfy(struct qib_devdata *dd, const struct firmware *fw)
{
return qib_sd7220_prog_vfy(dd, IB_7220_SERDES, fw->data, fw->size, 0);
}
/*
* IRQ not set up at this point in init, so we poll.
*/
#define IB_SERDES_TRIM_DONE (1ULL << 11)
#define TRIM_TMO (30)
static int qib_sd_trimdone_poll(struct qib_devdata *dd)
{
int trim_tmo, ret;
uint64_t val;
/*
* Default to failure, so IBC will not start
* without IB_SERDES_TRIM_DONE.
*/
ret = 0;
for (trim_tmo = 0; trim_tmo < TRIM_TMO; ++trim_tmo) {
val = qib_read_kreg64(dd, kr_ibcstatus);
if (val & IB_SERDES_TRIM_DONE) {
ret = 1;
break;
}
msleep(10);
}
if (trim_tmo >= TRIM_TMO) {
qib_dev_err(dd, "No TRIMDONE in %d tries\n", trim_tmo);
ret = 0;
}
return ret;
}
#define TX_FAST_ELT (9)
/*
* Set the "negotiation" values for SERDES. These are used by the IB1.2
* link negotiation. Macros below are attempt to keep the values a
* little more human-editable.
* First, values related to Drive De-emphasis Settings.
*/
#define NUM_DDS_REGS 6
#define DDS_REG_MAP 0x76A910 /* LSB-first list of regs (in elt 9) to mod */
#define DDS_VAL(amp_d, main_d, ipst_d, ipre_d, amp_s, main_s, ipst_s, ipre_s) \
{ { ((amp_d & 0x1F) << 1) | 1, ((amp_s & 0x1F) << 1) | 1, \
(main_d << 3) | 4 | (ipre_d >> 2), \
(main_s << 3) | 4 | (ipre_s >> 2), \
((ipst_d & 0xF) << 1) | ((ipre_d & 3) << 6) | 0x21, \
((ipst_s & 0xF) << 1) | ((ipre_s & 3) << 6) | 0x21 } }
static struct dds_init {
uint8_t reg_vals[NUM_DDS_REGS];
} dds_init_vals[] = {
/* DDR(FDR) SDR(HDR) */
/* Vendor recommends below for 3m cable */
#define DDS_3M 0
DDS_VAL(31, 19, 12, 0, 29, 22, 9, 0),
DDS_VAL(31, 12, 15, 4, 31, 15, 15, 1),
DDS_VAL(31, 13, 15, 3, 31, 16, 15, 0),
DDS_VAL(31, 14, 15, 2, 31, 17, 14, 0),
DDS_VAL(31, 15, 15, 1, 31, 18, 13, 0),
DDS_VAL(31, 16, 15, 0, 31, 19, 12, 0),
DDS_VAL(31, 17, 14, 0, 31, 20, 11, 0),
DDS_VAL(31, 18, 13, 0, 30, 21, 10, 0),
DDS_VAL(31, 20, 11, 0, 28, 23, 8, 0),
DDS_VAL(31, 21, 10, 0, 27, 24, 7, 0),
DDS_VAL(31, 22, 9, 0, 26, 25, 6, 0),
DDS_VAL(30, 23, 8, 0, 25, 26, 5, 0),
DDS_VAL(29, 24, 7, 0, 23, 27, 4, 0),
/* Vendor recommends below for 1m cable */
#define DDS_1M 13
DDS_VAL(28, 25, 6, 0, 21, 28, 3, 0),
DDS_VAL(27, 26, 5, 0, 19, 29, 2, 0),
DDS_VAL(25, 27, 4, 0, 17, 30, 1, 0)
};
/*
* Now the RXEQ section of the table.
*/
/* Hardware packs an element number and register address thus: */
#define RXEQ_INIT_RDESC(elt, addr) (((elt) & 0xF) | ((addr) << 4))
#define RXEQ_VAL(elt, adr, val0, val1, val2, val3) \
{RXEQ_INIT_RDESC((elt), (adr)), {(val0), (val1), (val2), (val3)} }
#define RXEQ_VAL_ALL(elt, adr, val) \
{RXEQ_INIT_RDESC((elt), (adr)), {(val), (val), (val), (val)} }
#define RXEQ_SDR_DFELTH 0
#define RXEQ_SDR_TLTH 0
#define RXEQ_SDR_G1CNT_Z1CNT 0x11
#define RXEQ_SDR_ZCNT 23
static struct rxeq_init {
u16 rdesc; /* in form used in SerDesDDSRXEQ */
u8 rdata[4];
} rxeq_init_vals[] = {
/* Set Rcv Eq. to Preset node */
RXEQ_VAL_ALL(7, 0x27, 0x10),
/* Set DFELTHFDR/HDR thresholds */
RXEQ_VAL(7, 8, 0, 0, 0, 0), /* FDR, was 0, 1, 2, 3 */
RXEQ_VAL(7, 0x21, 0, 0, 0, 0), /* HDR */
/* Set TLTHFDR/HDR theshold */
RXEQ_VAL(7, 9, 2, 2, 2, 2), /* FDR, was 0, 2, 4, 6 */
RXEQ_VAL(7, 0x23, 2, 2, 2, 2), /* HDR, was 0, 1, 2, 3 */
/* Set Preamp setting 2 (ZFR/ZCNT) */
RXEQ_VAL(7, 0x1B, 12, 12, 12, 12), /* FDR, was 12, 16, 20, 24 */
RXEQ_VAL(7, 0x1C, 12, 12, 12, 12), /* HDR, was 12, 16, 20, 24 */
/* Set Preamp DC gain and Setting 1 (GFR/GHR) */
RXEQ_VAL(7, 0x1E, 16, 16, 16, 16), /* FDR, was 16, 17, 18, 20 */
RXEQ_VAL(7, 0x1F, 16, 16, 16, 16), /* HDR, was 16, 17, 18, 20 */
/* Toggle RELOCK (in VCDL_CTRL0) to lock to data */
RXEQ_VAL_ALL(6, 6, 0x20), /* Set D5 High */
RXEQ_VAL_ALL(6, 6, 0), /* Set D5 Low */
};
/* There are 17 values from vendor, but IBC only accesses the first 16 */
#define DDS_ROWS (16)
#define RXEQ_ROWS ARRAY_SIZE(rxeq_init_vals)
static int qib_sd_setvals(struct qib_devdata *dd)
{
int idx, midx;
int min_idx; /* Minimum index for this portion of table */
uint32_t dds_reg_map;
u64 __iomem *taddr, *iaddr;
uint64_t data;
uint64_t sdctl;
taddr = dd->kregbase + kr_serdes_maptable;
iaddr = dd->kregbase + kr_serdes_ddsrxeq0;
/*
* Init the DDS section of the table.
* Each "row" of the table provokes NUM_DDS_REG writes, to the
* registers indicated in DDS_REG_MAP.
*/
sdctl = qib_read_kreg64(dd, kr_ibserdesctrl);
sdctl = (sdctl & ~(0x1f << 8)) | (NUM_DDS_REGS << 8);
sdctl = (sdctl & ~(0x1f << 13)) | (RXEQ_ROWS << 13);
qib_write_kreg(dd, kr_ibserdesctrl, sdctl);
/*
* Iterate down table within loop for each register to store.
*/
dds_reg_map = DDS_REG_MAP;
for (idx = 0; idx < NUM_DDS_REGS; ++idx) {
data = ((dds_reg_map & 0xF) << 4) | TX_FAST_ELT;
writeq(data, iaddr + idx);
mmiowb();
qib_read_kreg32(dd, kr_scratch);
dds_reg_map >>= 4;
for (midx = 0; midx < DDS_ROWS; ++midx) {
u64 __iomem *daddr = taddr + ((midx << 4) + idx);
data = dds_init_vals[midx].reg_vals[idx];
writeq(data, daddr);
mmiowb();
qib_read_kreg32(dd, kr_scratch);
} /* End inner for (vals for this reg, each row) */
} /* end outer for (regs to be stored) */
/*
* Init the RXEQ section of the table.
* This runs in a different order, as the pattern of
* register references is more complex, but there are only
* four "data" values per register.
*/
min_idx = idx; /* RXEQ indices pick up where DDS left off */
taddr += 0x100; /* RXEQ data is in second half of table */
/* Iterate through RXEQ register addresses */
for (idx = 0; idx < RXEQ_ROWS; ++idx) {
int didx; /* "destination" */
int vidx;
/* didx is offset by min_idx to address RXEQ range of regs */
didx = idx + min_idx;
/* Store the next RXEQ register address */
writeq(rxeq_init_vals[idx].rdesc, iaddr + didx);
mmiowb();
qib_read_kreg32(dd, kr_scratch);
/* Iterate through RXEQ values */
for (vidx = 0; vidx < 4; vidx++) {
data = rxeq_init_vals[idx].rdata[vidx];
writeq(data, taddr + (vidx << 6) + idx);
mmiowb();
qib_read_kreg32(dd, kr_scratch);
}
} /* end outer for (Reg-writes for RXEQ) */
return 0;
}
#define CMUCTRL5 EPB_LOC(7, 0, 0x15)
#define RXHSCTRL0(chan) EPB_LOC(chan, 6, 0)
#define VCDL_DAC2(chan) EPB_LOC(chan, 6, 5)
#define VCDL_CTRL0(chan) EPB_LOC(chan, 6, 6)
#define VCDL_CTRL2(chan) EPB_LOC(chan, 6, 8)
#define START_EQ2(chan) EPB_LOC(chan, 7, 0x28)
/*
* Repeat a "store" across all channels of the IB SerDes.
* Although nominally it inherits the "read value" of the last
* channel it modified, the only really useful return is <0 for
* failure, >= 0 for success. The parameter 'loc' is assumed to
* be the location in some channel of the register to be modified
* The caller can specify use of the "gang write" option of EPB,
* in which case we use the specified channel data for any fields
* not explicitely written.
*/
static int ibsd_mod_allchnls(struct qib_devdata *dd, int loc, int val,
int mask)
{
int ret = -1;
int chnl;
if (loc & EPB_GLOBAL_WR) {
/*
* Our caller has assured us that we can set all four
* channels at once. Trust that. If mask is not 0xFF,
* we will read the _specified_ channel for our starting
* value.
*/
loc |= (1U << EPB_IB_QUAD0_CS_SHF);
chnl = (loc >> (4 + EPB_ADDR_SHF)) & 7;
if (mask != 0xFF) {
ret = qib_sd7220_reg_mod(dd, IB_7220_SERDES,
loc & ~EPB_GLOBAL_WR, 0, 0);
if (ret < 0) {
int sloc = loc >> EPB_ADDR_SHF;
qib_dev_err(dd, "pre-read failed: elt %d,"
" addr 0x%X, chnl %d\n",
(sloc & 0xF),
(sloc >> 9) & 0x3f, chnl);
return ret;
}
val = (ret & ~mask) | (val & mask);
}
loc &= ~(7 << (4+EPB_ADDR_SHF));
ret = qib_sd7220_reg_mod(dd, IB_7220_SERDES, loc, val, 0xFF);
if (ret < 0) {
int sloc = loc >> EPB_ADDR_SHF;
qib_dev_err(dd, "Global WR failed: elt %d,"
" addr 0x%X, val %02X\n",
(sloc & 0xF), (sloc >> 9) & 0x3f, val);
}
return ret;
}
/* Clear "channel" and set CS so we can simply iterate */
loc &= ~(7 << (4+EPB_ADDR_SHF));
loc |= (1U << EPB_IB_QUAD0_CS_SHF);
for (chnl = 0; chnl < 4; ++chnl) {
int cloc = loc | (chnl << (4+EPB_ADDR_SHF));
ret = qib_sd7220_reg_mod(dd, IB_7220_SERDES, cloc, val, mask);
if (ret < 0) {
int sloc = loc >> EPB_ADDR_SHF;
qib_dev_err(dd, "Write failed: elt %d,"
" addr 0x%X, chnl %d, val 0x%02X,"
" mask 0x%02X\n",
(sloc & 0xF), (sloc >> 9) & 0x3f, chnl,
val & 0xFF, mask & 0xFF);
break;
}
}
return ret;
}
/*
* Set the Tx values normally modified by IBC in IB1.2 mode to default
* values, as gotten from first row of init table.
*/
static int set_dds_vals(struct qib_devdata *dd, struct dds_init *ddi)
{
int ret;
int idx, reg, data;
uint32_t regmap;
regmap = DDS_REG_MAP;
for (idx = 0; idx < NUM_DDS_REGS; ++idx) {
reg = (regmap & 0xF);
regmap >>= 4;
data = ddi->reg_vals[idx];
/* Vendor says RMW not needed for these regs, use 0xFF mask */
ret = ibsd_mod_allchnls(dd, EPB_LOC(0, 9, reg), data, 0xFF);
if (ret < 0)
break;
}
return ret;
}
/*
* Set the Rx values normally modified by IBC in IB1.2 mode to default
* values, as gotten from selected column of init table.
*/
static int set_rxeq_vals(struct qib_devdata *dd, int vsel)
{
int ret;
int ridx;
int cnt = ARRAY_SIZE(rxeq_init_vals);
for (ridx = 0; ridx < cnt; ++ridx) {
int elt, reg, val, loc;
elt = rxeq_init_vals[ridx].rdesc & 0xF;
reg = rxeq_init_vals[ridx].rdesc >> 4;
loc = EPB_LOC(0, elt, reg);
val = rxeq_init_vals[ridx].rdata[vsel];
/* mask of 0xFF, because hardware does full-byte store. */
ret = ibsd_mod_allchnls(dd, loc, val, 0xFF);
if (ret < 0)
break;
}
return ret;
}
/*
* Set the default values (row 0) for DDR Driver Demphasis.
* we do this initially and whenever we turn off IB-1.2
*
* The "default" values for Rx equalization are also stored to
* SerDes registers. Formerly (and still default), we used set 2.
* For experimenting with cables and link-partners, we allow changing
* that via a module parameter.
*/
static unsigned qib_rxeq_set = 2;
module_param_named(rxeq_default_set, qib_rxeq_set, uint,
S_IWUSR | S_IRUGO);
MODULE_PARM_DESC(rxeq_default_set,
"Which set [0..3] of Rx Equalization values is default");
static int qib_internal_presets(struct qib_devdata *dd)
{
int ret = 0;
ret = set_dds_vals(dd, dds_init_vals + DDS_3M);
if (ret < 0)
qib_dev_err(dd, "Failed to set default DDS values\n");
ret = set_rxeq_vals(dd, qib_rxeq_set & 3);
if (ret < 0)
qib_dev_err(dd, "Failed to set default RXEQ values\n");
return ret;
}
int qib_sd7220_presets(struct qib_devdata *dd)
{
int ret = 0;
if (!dd->cspec->presets_needed)
return ret;
dd->cspec->presets_needed = 0;
/* Assert uC reset, so we don't clash with it. */
qib_ibsd_reset(dd, 1);
udelay(2);
qib_sd_trimdone_monitor(dd, "link-down");
ret = qib_internal_presets(dd);
return ret;
}
static int qib_sd_trimself(struct qib_devdata *dd, int val)
{
int loc = CMUCTRL5 | (1U << EPB_IB_QUAD0_CS_SHF);
return qib_sd7220_reg_mod(dd, IB_7220_SERDES, loc, val, 0xFF);
}
static int qib_sd_early(struct qib_devdata *dd)
{
int ret;
ret = ibsd_mod_allchnls(dd, RXHSCTRL0(0) | EPB_GLOBAL_WR, 0xD4, 0xFF);
if (ret < 0)
goto bail;
ret = ibsd_mod_allchnls(dd, START_EQ1(0) | EPB_GLOBAL_WR, 0x10, 0xFF);
if (ret < 0)
goto bail;
ret = ibsd_mod_allchnls(dd, START_EQ2(0) | EPB_GLOBAL_WR, 0x30, 0xFF);
bail:
return ret;
}
#define BACTRL(chnl) EPB_LOC(chnl, 6, 0x0E)
#define LDOUTCTRL1(chnl) EPB_LOC(chnl, 7, 6)
#define RXHSSTATUS(chnl) EPB_LOC(chnl, 6, 0xF)
static int qib_sd_dactrim(struct qib_devdata *dd)
{
int ret;
ret = ibsd_mod_allchnls(dd, VCDL_DAC2(0) | EPB_GLOBAL_WR, 0x2D, 0xFF);
if (ret < 0)
goto bail;
/* more fine-tuning of what will be default */
ret = ibsd_mod_allchnls(dd, VCDL_CTRL2(0), 3, 0xF);
if (ret < 0)
goto bail;
ret = ibsd_mod_allchnls(dd, BACTRL(0) | EPB_GLOBAL_WR, 0x40, 0xFF);
if (ret < 0)
goto bail;
ret = ibsd_mod_allchnls(dd, LDOUTCTRL1(0) | EPB_GLOBAL_WR, 0x04, 0xFF);
if (ret < 0)
goto bail;
ret = ibsd_mod_allchnls(dd, RXHSSTATUS(0) | EPB_GLOBAL_WR, 0x04, 0xFF);
if (ret < 0)
goto bail;
/*
* Delay for max possible number of steps, with slop.
* Each step is about 4usec.
*/
udelay(415);
ret = ibsd_mod_allchnls(dd, LDOUTCTRL1(0) | EPB_GLOBAL_WR, 0x00, 0xFF);
bail:
return ret;
}
#define RELOCK_FIRST_MS 3
#define RXLSPPM(chan) EPB_LOC(chan, 0, 2)
void toggle_7220_rclkrls(struct qib_devdata *dd)
{
int loc = RXLSPPM(0) | EPB_GLOBAL_WR;
int ret;
ret = ibsd_mod_allchnls(dd, loc, 0, 0x80);
if (ret < 0)
qib_dev_err(dd, "RCLKRLS failed to clear D7\n");
else {
udelay(1);
ibsd_mod_allchnls(dd, loc, 0x80, 0x80);
}
/* And again for good measure */
udelay(1);
ret = ibsd_mod_allchnls(dd, loc, 0, 0x80);
if (ret < 0)
qib_dev_err(dd, "RCLKRLS failed to clear D7\n");
else {
udelay(1);
ibsd_mod_allchnls(dd, loc, 0x80, 0x80);
}
/* Now reset xgxs and IBC to complete the recovery */
dd->f_xgxs_reset(dd->pport);
}
/*
* Shut down the timer that polls for relock occasions, if needed
* this is "hooked" from qib_7220_quiet_serdes(), which is called
* just before qib_shutdown_device() in qib_driver.c shuts down all
* the other timers
*/
void shutdown_7220_relock_poll(struct qib_devdata *dd)
{
if (dd->cspec->relock_timer_active)
del_timer_sync(&dd->cspec->relock_timer);
}
static unsigned qib_relock_by_timer = 1;
module_param_named(relock_by_timer, qib_relock_by_timer, uint,
S_IWUSR | S_IRUGO);
MODULE_PARM_DESC(relock_by_timer, "Allow relock attempt if link not up");
static void qib_run_relock(unsigned long opaque)
{
struct qib_devdata *dd = (struct qib_devdata *)opaque;
struct qib_pportdata *ppd = dd->pport;
struct qib_chip_specific *cs = dd->cspec;
int timeoff;
/*
* Check link-training state for "stuck" state, when down.
* if found, try relock and schedule another try at
* exponentially growing delay, maxed at one second.
* if not stuck, our work is done.
*/
if ((dd->flags & QIB_INITTED) && !(ppd->lflags &
(QIBL_IB_AUTONEG_INPROG | QIBL_LINKINIT | QIBL_LINKARMED |
QIBL_LINKACTIVE))) {
if (qib_relock_by_timer) {
if (!(ppd->lflags & QIBL_IB_LINK_DISABLED))
toggle_7220_rclkrls(dd);
}
/* re-set timer for next check */
timeoff = cs->relock_interval << 1;
if (timeoff > HZ)
timeoff = HZ;
cs->relock_interval = timeoff;
} else
timeoff = HZ;
mod_timer(&cs->relock_timer, jiffies + timeoff);
}
void set_7220_relock_poll(struct qib_devdata *dd, int ibup)
{
struct qib_chip_specific *cs = dd->cspec;
if (ibup) {
/* We are now up, relax timer to 1 second interval */
if (cs->relock_timer_active) {
cs->relock_interval = HZ;
mod_timer(&cs->relock_timer, jiffies + HZ);
}
} else {
/* Transition to down, (re-)set timer to short interval. */
unsigned int timeout;
timeout = msecs_to_jiffies(RELOCK_FIRST_MS);
if (timeout == 0)
timeout = 1;
/* If timer has not yet been started, do so. */
if (!cs->relock_timer_active) {
cs->relock_timer_active = 1;
init_timer(&cs->relock_timer);
cs->relock_timer.function = qib_run_relock;
cs->relock_timer.data = (unsigned long) dd;
cs->relock_interval = timeout;
cs->relock_timer.expires = jiffies + timeout;
add_timer(&cs->relock_timer);
} else {
cs->relock_interval = timeout;
mod_timer(&cs->relock_timer, jiffies + timeout);
}
}
}