kernel-fxtec-pro1x/arch/mips/bcm47xx/sprom.c
Hauke Mehrtens b8ebbaff03 MIPS: BCM47xx: sprom: read values without prefix as fallback
There are bcma based devices like the Linksys E2000 out there, which do
have one ieee80211 core, but no PCIe core and they are using no
prefixes for the sprom. In addition some values like boardtype are
stored without a prefix for the main SoC chip also when they have an
additional PCIe wifi chip with an own boardtype var on some devices.

The Ethernet addresses are now also read out correctly without a prefix
so calling bcm47xx_fill_sprom_ethernet is not needed any more.

Signed-off-by: Hauke Mehrtens <hauke@hauke-m.de>
Patchwork: http://patchwork.linux-mips.org/patch/4364
Signed-off-by: John Crispin <blogic@openwrt.org>
2012-11-09 11:37:17 +01:00

756 lines
29 KiB
C

/*
* Copyright (C) 2004 Florian Schirmer <jolt@tuxbox.org>
* Copyright (C) 2006 Felix Fietkau <nbd@openwrt.org>
* Copyright (C) 2006 Michael Buesch <m@bues.ch>
* Copyright (C) 2010 Waldemar Brodkorb <wbx@openadk.org>
* Copyright (C) 2010-2012 Hauke Mehrtens <hauke@hauke-m.de>
*
* 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.
*
* THIS SOFTWARE IS PROVIDED ``AS IS'' AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN
* NO EVENT SHALL THE AUTHOR 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.
*
* You should have received a copy of the GNU General Public License along
* with this program; if not, write to the Free Software Foundation, Inc.,
* 675 Mass Ave, Cambridge, MA 02139, USA.
*/
#include <bcm47xx.h>
#include <nvram.h>
static void create_key(const char *prefix, const char *postfix,
const char *name, char *buf, int len)
{
if (prefix && postfix)
snprintf(buf, len, "%s%s%s", prefix, name, postfix);
else if (prefix)
snprintf(buf, len, "%s%s", prefix, name);
else if (postfix)
snprintf(buf, len, "%s%s", name, postfix);
else
snprintf(buf, len, "%s", name);
}
static int get_nvram_var(const char *prefix, const char *postfix,
const char *name, char *buf, int len, bool fallback)
{
char key[40];
int err;
create_key(prefix, postfix, name, key, sizeof(key));
err = nvram_getenv(key, buf, len);
if (fallback && err == NVRAM_ERR_ENVNOTFOUND && prefix) {
create_key(NULL, postfix, name, key, sizeof(key));
err = nvram_getenv(key, buf, len);
}
return err;
}
#define NVRAM_READ_VAL(type) \
static void nvram_read_ ## type (const char *prefix, \
const char *postfix, const char *name, \
type *val, type allset, bool fallback) \
{ \
char buf[100]; \
int err; \
type var; \
\
err = get_nvram_var(prefix, postfix, name, buf, sizeof(buf), \
fallback); \
if (err < 0) \
return; \
err = kstrto ## type (buf, 0, &var); \
if (err) { \
pr_warn("can not parse nvram name %s%s%s with value %s got %i\n", \
prefix, name, postfix, buf, err); \
return; \
} \
if (allset && var == allset) \
return; \
*val = var; \
}
NVRAM_READ_VAL(u8)
NVRAM_READ_VAL(s8)
NVRAM_READ_VAL(u16)
NVRAM_READ_VAL(u32)
#undef NVRAM_READ_VAL
static void nvram_read_u32_2(const char *prefix, const char *name,
u16 *val_lo, u16 *val_hi, bool fallback)
{
char buf[100];
int err;
u32 val;
err = get_nvram_var(prefix, NULL, name, buf, sizeof(buf), fallback);
if (err < 0)
return;
err = kstrtou32(buf, 0, &val);
if (err) {
pr_warn("can not parse nvram name %s%s with value %s got %i\n",
prefix, name, buf, err);
return;
}
*val_lo = (val & 0x0000FFFFU);
*val_hi = (val & 0xFFFF0000U) >> 16;
}
static void nvram_read_leddc(const char *prefix, const char *name,
u8 *leddc_on_time, u8 *leddc_off_time,
bool fallback)
{
char buf[100];
int err;
u32 val;
err = get_nvram_var(prefix, NULL, name, buf, sizeof(buf), fallback);
if (err < 0)
return;
err = kstrtou32(buf, 0, &val);
if (err) {
pr_warn("can not parse nvram name %s%s with value %s got %i\n",
prefix, name, buf, err);
return;
}
if (val == 0xffff || val == 0xffffffff)
return;
*leddc_on_time = val & 0xff;
*leddc_off_time = (val >> 16) & 0xff;
}
static void nvram_read_macaddr(const char *prefix, const char *name,
u8 (*val)[6], bool fallback)
{
char buf[100];
int err;
err = get_nvram_var(prefix, NULL, name, buf, sizeof(buf), fallback);
if (err < 0)
return;
nvram_parse_macaddr(buf, *val);
}
static void nvram_read_alpha2(const char *prefix, const char *name,
char (*val)[2], bool fallback)
{
char buf[10];
int err;
err = get_nvram_var(prefix, NULL, name, buf, sizeof(buf), fallback);
if (err < 0)
return;
if (buf[0] == '0')
return;
if (strlen(buf) > 2) {
pr_warn("alpha2 is too long %s\n", buf);
return;
}
memcpy(val, buf, sizeof(val));
}
static void bcm47xx_fill_sprom_r1234589(struct ssb_sprom *sprom,
const char *prefix, bool fallback)
{
nvram_read_u8(prefix, NULL, "ledbh0", &sprom->gpio0, 0xff, fallback);
nvram_read_u8(prefix, NULL, "ledbh1", &sprom->gpio1, 0xff, fallback);
nvram_read_u8(prefix, NULL, "ledbh2", &sprom->gpio2, 0xff, fallback);
nvram_read_u8(prefix, NULL, "ledbh3", &sprom->gpio3, 0xff, fallback);
nvram_read_u8(prefix, NULL, "aa2g", &sprom->ant_available_bg, 0,
fallback);
nvram_read_u8(prefix, NULL, "aa5g", &sprom->ant_available_a, 0,
fallback);
nvram_read_s8(prefix, NULL, "ag0", &sprom->antenna_gain.a0, 0,
fallback);
nvram_read_s8(prefix, NULL, "ag1", &sprom->antenna_gain.a1, 0,
fallback);
nvram_read_alpha2(prefix, "ccode", &sprom->alpha2, fallback);
}
static void bcm47xx_fill_sprom_r12389(struct ssb_sprom *sprom,
const char *prefix, bool fallback)
{
nvram_read_u16(prefix, NULL, "pa0b0", &sprom->pa0b0, 0, fallback);
nvram_read_u16(prefix, NULL, "pa0b1", &sprom->pa0b1, 0, fallback);
nvram_read_u16(prefix, NULL, "pa0b2", &sprom->pa0b2, 0, fallback);
nvram_read_u8(prefix, NULL, "pa0itssit", &sprom->itssi_bg, 0, fallback);
nvram_read_u8(prefix, NULL, "pa0maxpwr", &sprom->maxpwr_bg, 0,
fallback);
nvram_read_u16(prefix, NULL, "pa1b0", &sprom->pa1b0, 0, fallback);
nvram_read_u16(prefix, NULL, "pa1b1", &sprom->pa1b1, 0, fallback);
nvram_read_u16(prefix, NULL, "pa1b2", &sprom->pa1b2, 0, fallback);
nvram_read_u8(prefix, NULL, "pa1itssit", &sprom->itssi_a, 0, fallback);
nvram_read_u8(prefix, NULL, "pa1maxpwr", &sprom->maxpwr_a, 0, fallback);
}
static void bcm47xx_fill_sprom_r1(struct ssb_sprom *sprom, const char *prefix,
bool fallback)
{
nvram_read_u16(prefix, NULL, "boardflags", &sprom->boardflags_lo, 0,
fallback);
nvram_read_u8(prefix, NULL, "cc", &sprom->country_code, 0, fallback);
}
static void bcm47xx_fill_sprom_r2389(struct ssb_sprom *sprom,
const char *prefix, bool fallback)
{
nvram_read_u8(prefix, NULL, "opo", &sprom->opo, 0, fallback);
nvram_read_u16(prefix, NULL, "pa1lob0", &sprom->pa1lob0, 0, fallback);
nvram_read_u16(prefix, NULL, "pa1lob1", &sprom->pa1lob1, 0, fallback);
nvram_read_u16(prefix, NULL, "pa1lob2", &sprom->pa1lob2, 0, fallback);
nvram_read_u16(prefix, NULL, "pa1hib0", &sprom->pa1hib0, 0, fallback);
nvram_read_u16(prefix, NULL, "pa1hib1", &sprom->pa1hib1, 0, fallback);
nvram_read_u16(prefix, NULL, "pa1hib2", &sprom->pa1hib2, 0, fallback);
nvram_read_u8(prefix, NULL, "pa1lomaxpwr", &sprom->maxpwr_al, 0,
fallback);
nvram_read_u8(prefix, NULL, "pa1himaxpwr", &sprom->maxpwr_ah, 0,
fallback);
}
static void bcm47xx_fill_sprom_r389(struct ssb_sprom *sprom, const char *prefix,
bool fallback)
{
nvram_read_u8(prefix, NULL, "bxa2g", &sprom->bxa2g, 0, fallback);
nvram_read_u8(prefix, NULL, "rssisav2g", &sprom->rssisav2g, 0,
fallback);
nvram_read_u8(prefix, NULL, "rssismc2g", &sprom->rssismc2g, 0,
fallback);
nvram_read_u8(prefix, NULL, "rssismf2g", &sprom->rssismf2g, 0,
fallback);
nvram_read_u8(prefix, NULL, "bxa5g", &sprom->bxa5g, 0, fallback);
nvram_read_u8(prefix, NULL, "rssisav5g", &sprom->rssisav5g, 0,
fallback);
nvram_read_u8(prefix, NULL, "rssismc5g", &sprom->rssismc5g, 0,
fallback);
nvram_read_u8(prefix, NULL, "rssismf5g", &sprom->rssismf5g, 0,
fallback);
nvram_read_u8(prefix, NULL, "tri2g", &sprom->tri2g, 0, fallback);
nvram_read_u8(prefix, NULL, "tri5g", &sprom->tri5g, 0, fallback);
nvram_read_u8(prefix, NULL, "tri5gl", &sprom->tri5gl, 0, fallback);
nvram_read_u8(prefix, NULL, "tri5gh", &sprom->tri5gh, 0, fallback);
nvram_read_s8(prefix, NULL, "rxpo2g", &sprom->rxpo2g, 0, fallback);
nvram_read_s8(prefix, NULL, "rxpo5g", &sprom->rxpo5g, 0, fallback);
}
static void bcm47xx_fill_sprom_r3(struct ssb_sprom *sprom, const char *prefix,
bool fallback)
{
nvram_read_u8(prefix, NULL, "regrev", &sprom->regrev, 0, fallback);
nvram_read_leddc(prefix, "leddc", &sprom->leddc_on_time,
&sprom->leddc_off_time, fallback);
}
static void bcm47xx_fill_sprom_r4589(struct ssb_sprom *sprom,
const char *prefix, bool fallback)
{
nvram_read_u8(prefix, NULL, "regrev", &sprom->regrev, 0, fallback);
nvram_read_s8(prefix, NULL, "ag2", &sprom->antenna_gain.a2, 0,
fallback);
nvram_read_s8(prefix, NULL, "ag3", &sprom->antenna_gain.a3, 0,
fallback);
nvram_read_u8(prefix, NULL, "txchain", &sprom->txchain, 0xf, fallback);
nvram_read_u8(prefix, NULL, "rxchain", &sprom->rxchain, 0xf, fallback);
nvram_read_u8(prefix, NULL, "antswitch", &sprom->antswitch, 0xff,
fallback);
nvram_read_leddc(prefix, "leddc", &sprom->leddc_on_time,
&sprom->leddc_off_time, fallback);
}
static void bcm47xx_fill_sprom_r458(struct ssb_sprom *sprom, const char *prefix,
bool fallback)
{
nvram_read_u16(prefix, NULL, "cck2gpo", &sprom->cck2gpo, 0, fallback);
nvram_read_u32(prefix, NULL, "ofdm2gpo", &sprom->ofdm2gpo, 0, fallback);
nvram_read_u32(prefix, NULL, "ofdm5gpo", &sprom->ofdm5gpo, 0, fallback);
nvram_read_u32(prefix, NULL, "ofdm5glpo", &sprom->ofdm5glpo, 0,
fallback);
nvram_read_u32(prefix, NULL, "ofdm5ghpo", &sprom->ofdm5ghpo, 0,
fallback);
nvram_read_u16(prefix, NULL, "cddpo", &sprom->cddpo, 0, fallback);
nvram_read_u16(prefix, NULL, "stbcpo", &sprom->stbcpo, 0, fallback);
nvram_read_u16(prefix, NULL, "bw40po", &sprom->bw40po, 0, fallback);
nvram_read_u16(prefix, NULL, "bwduppo", &sprom->bwduppo, 0, fallback);
nvram_read_u16(prefix, NULL, "mcs2gpo0", &sprom->mcs2gpo[0], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs2gpo1", &sprom->mcs2gpo[1], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs2gpo2", &sprom->mcs2gpo[2], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs2gpo3", &sprom->mcs2gpo[3], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs2gpo4", &sprom->mcs2gpo[4], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs2gpo5", &sprom->mcs2gpo[5], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs2gpo6", &sprom->mcs2gpo[6], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs2gpo7", &sprom->mcs2gpo[7], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5gpo0", &sprom->mcs5gpo[0], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5gpo1", &sprom->mcs5gpo[1], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5gpo2", &sprom->mcs5gpo[2], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5gpo3", &sprom->mcs5gpo[3], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5gpo4", &sprom->mcs5gpo[4], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5gpo5", &sprom->mcs5gpo[5], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5gpo6", &sprom->mcs5gpo[6], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5gpo7", &sprom->mcs5gpo[7], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5glpo0", &sprom->mcs5glpo[0], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5glpo1", &sprom->mcs5glpo[1], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5glpo2", &sprom->mcs5glpo[2], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5glpo3", &sprom->mcs5glpo[3], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5glpo4", &sprom->mcs5glpo[4], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5glpo5", &sprom->mcs5glpo[5], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5glpo6", &sprom->mcs5glpo[6], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5glpo7", &sprom->mcs5glpo[7], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5ghpo0", &sprom->mcs5ghpo[0], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5ghpo1", &sprom->mcs5ghpo[1], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5ghpo2", &sprom->mcs5ghpo[2], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5ghpo3", &sprom->mcs5ghpo[3], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5ghpo4", &sprom->mcs5ghpo[4], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5ghpo5", &sprom->mcs5ghpo[5], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5ghpo6", &sprom->mcs5ghpo[6], 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs5ghpo7", &sprom->mcs5ghpo[7], 0,
fallback);
}
static void bcm47xx_fill_sprom_r45(struct ssb_sprom *sprom, const char *prefix,
bool fallback)
{
nvram_read_u8(prefix, NULL, "txpid2ga0", &sprom->txpid2g[0], 0,
fallback);
nvram_read_u8(prefix, NULL, "txpid2ga1", &sprom->txpid2g[1], 0,
fallback);
nvram_read_u8(prefix, NULL, "txpid2ga2", &sprom->txpid2g[2], 0,
fallback);
nvram_read_u8(prefix, NULL, "txpid2ga3", &sprom->txpid2g[3], 0,
fallback);
nvram_read_u8(prefix, NULL, "txpid5ga0", &sprom->txpid5g[0], 0,
fallback);
nvram_read_u8(prefix, NULL, "txpid5ga1", &sprom->txpid5g[1], 0,
fallback);
nvram_read_u8(prefix, NULL, "txpid5ga2", &sprom->txpid5g[2], 0,
fallback);
nvram_read_u8(prefix, NULL, "txpid5ga3", &sprom->txpid5g[3], 0,
fallback);
nvram_read_u8(prefix, NULL, "txpid5gla0", &sprom->txpid5gl[0], 0,
fallback);
nvram_read_u8(prefix, NULL, "txpid5gla1", &sprom->txpid5gl[1], 0,
fallback);
nvram_read_u8(prefix, NULL, "txpid5gla2", &sprom->txpid5gl[2], 0,
fallback);
nvram_read_u8(prefix, NULL, "txpid5gla3", &sprom->txpid5gl[3], 0,
fallback);
nvram_read_u8(prefix, NULL, "txpid5gha0", &sprom->txpid5gh[0], 0,
fallback);
nvram_read_u8(prefix, NULL, "txpid5gha1", &sprom->txpid5gh[1], 0,
fallback);
nvram_read_u8(prefix, NULL, "txpid5gha2", &sprom->txpid5gh[2], 0,
fallback);
nvram_read_u8(prefix, NULL, "txpid5gha3", &sprom->txpid5gh[3], 0,
fallback);
}
static void bcm47xx_fill_sprom_r89(struct ssb_sprom *sprom, const char *prefix,
bool fallback)
{
nvram_read_u8(prefix, NULL, "tssipos2g", &sprom->fem.ghz2.tssipos, 0,
fallback);
nvram_read_u8(prefix, NULL, "extpagain2g",
&sprom->fem.ghz2.extpa_gain, 0, fallback);
nvram_read_u8(prefix, NULL, "pdetrange2g",
&sprom->fem.ghz2.pdet_range, 0, fallback);
nvram_read_u8(prefix, NULL, "triso2g", &sprom->fem.ghz2.tr_iso, 0,
fallback);
nvram_read_u8(prefix, NULL, "antswctl2g", &sprom->fem.ghz2.antswlut, 0,
fallback);
nvram_read_u8(prefix, NULL, "tssipos5g", &sprom->fem.ghz5.tssipos, 0,
fallback);
nvram_read_u8(prefix, NULL, "extpagain5g",
&sprom->fem.ghz5.extpa_gain, 0, fallback);
nvram_read_u8(prefix, NULL, "pdetrange5g",
&sprom->fem.ghz5.pdet_range, 0, fallback);
nvram_read_u8(prefix, NULL, "triso5g", &sprom->fem.ghz5.tr_iso, 0,
fallback);
nvram_read_u8(prefix, NULL, "antswctl5g", &sprom->fem.ghz5.antswlut, 0,
fallback);
nvram_read_u8(prefix, NULL, "tempthresh", &sprom->tempthresh, 0,
fallback);
nvram_read_u8(prefix, NULL, "tempoffset", &sprom->tempoffset, 0,
fallback);
nvram_read_u16(prefix, NULL, "rawtempsense", &sprom->rawtempsense, 0,
fallback);
nvram_read_u8(prefix, NULL, "measpower", &sprom->measpower, 0,
fallback);
nvram_read_u8(prefix, NULL, "tempsense_slope",
&sprom->tempsense_slope, 0, fallback);
nvram_read_u8(prefix, NULL, "tempcorrx", &sprom->tempcorrx, 0,
fallback);
nvram_read_u8(prefix, NULL, "tempsense_option",
&sprom->tempsense_option, 0, fallback);
nvram_read_u8(prefix, NULL, "freqoffset_corr",
&sprom->freqoffset_corr, 0, fallback);
nvram_read_u8(prefix, NULL, "iqcal_swp_dis", &sprom->iqcal_swp_dis, 0,
fallback);
nvram_read_u8(prefix, NULL, "hw_iqcal_en", &sprom->hw_iqcal_en, 0,
fallback);
nvram_read_u8(prefix, NULL, "elna2g", &sprom->elna2g, 0, fallback);
nvram_read_u8(prefix, NULL, "elna5g", &sprom->elna5g, 0, fallback);
nvram_read_u8(prefix, NULL, "phycal_tempdelta",
&sprom->phycal_tempdelta, 0, fallback);
nvram_read_u8(prefix, NULL, "temps_period", &sprom->temps_period, 0,
fallback);
nvram_read_u8(prefix, NULL, "temps_hysteresis",
&sprom->temps_hysteresis, 0, fallback);
nvram_read_u8(prefix, NULL, "measpower1", &sprom->measpower1, 0,
fallback);
nvram_read_u8(prefix, NULL, "measpower2", &sprom->measpower2, 0,
fallback);
nvram_read_u8(prefix, NULL, "rxgainerr2ga0",
&sprom->rxgainerr2ga[0], 0, fallback);
nvram_read_u8(prefix, NULL, "rxgainerr2ga1",
&sprom->rxgainerr2ga[1], 0, fallback);
nvram_read_u8(prefix, NULL, "rxgainerr2ga2",
&sprom->rxgainerr2ga[2], 0, fallback);
nvram_read_u8(prefix, NULL, "rxgainerr5gla0",
&sprom->rxgainerr5gla[0], 0, fallback);
nvram_read_u8(prefix, NULL, "rxgainerr5gla1",
&sprom->rxgainerr5gla[1], 0, fallback);
nvram_read_u8(prefix, NULL, "rxgainerr5gla2",
&sprom->rxgainerr5gla[2], 0, fallback);
nvram_read_u8(prefix, NULL, "rxgainerr5gma0",
&sprom->rxgainerr5gma[0], 0, fallback);
nvram_read_u8(prefix, NULL, "rxgainerr5gma1",
&sprom->rxgainerr5gma[1], 0, fallback);
nvram_read_u8(prefix, NULL, "rxgainerr5gma2",
&sprom->rxgainerr5gma[2], 0, fallback);
nvram_read_u8(prefix, NULL, "rxgainerr5gha0",
&sprom->rxgainerr5gha[0], 0, fallback);
nvram_read_u8(prefix, NULL, "rxgainerr5gha1",
&sprom->rxgainerr5gha[1], 0, fallback);
nvram_read_u8(prefix, NULL, "rxgainerr5gha2",
&sprom->rxgainerr5gha[2], 0, fallback);
nvram_read_u8(prefix, NULL, "rxgainerr5gua0",
&sprom->rxgainerr5gua[0], 0, fallback);
nvram_read_u8(prefix, NULL, "rxgainerr5gua1",
&sprom->rxgainerr5gua[1], 0, fallback);
nvram_read_u8(prefix, NULL, "rxgainerr5gua2",
&sprom->rxgainerr5gua[2], 0, fallback);
nvram_read_u8(prefix, NULL, "noiselvl2ga0", &sprom->noiselvl2ga[0], 0,
fallback);
nvram_read_u8(prefix, NULL, "noiselvl2ga1", &sprom->noiselvl2ga[1], 0,
fallback);
nvram_read_u8(prefix, NULL, "noiselvl2ga2", &sprom->noiselvl2ga[2], 0,
fallback);
nvram_read_u8(prefix, NULL, "noiselvl5gla0",
&sprom->noiselvl5gla[0], 0, fallback);
nvram_read_u8(prefix, NULL, "noiselvl5gla1",
&sprom->noiselvl5gla[1], 0, fallback);
nvram_read_u8(prefix, NULL, "noiselvl5gla2",
&sprom->noiselvl5gla[2], 0, fallback);
nvram_read_u8(prefix, NULL, "noiselvl5gma0",
&sprom->noiselvl5gma[0], 0, fallback);
nvram_read_u8(prefix, NULL, "noiselvl5gma1",
&sprom->noiselvl5gma[1], 0, fallback);
nvram_read_u8(prefix, NULL, "noiselvl5gma2",
&sprom->noiselvl5gma[2], 0, fallback);
nvram_read_u8(prefix, NULL, "noiselvl5gha0",
&sprom->noiselvl5gha[0], 0, fallback);
nvram_read_u8(prefix, NULL, "noiselvl5gha1",
&sprom->noiselvl5gha[1], 0, fallback);
nvram_read_u8(prefix, NULL, "noiselvl5gha2",
&sprom->noiselvl5gha[2], 0, fallback);
nvram_read_u8(prefix, NULL, "noiselvl5gua0",
&sprom->noiselvl5gua[0], 0, fallback);
nvram_read_u8(prefix, NULL, "noiselvl5gua1",
&sprom->noiselvl5gua[1], 0, fallback);
nvram_read_u8(prefix, NULL, "noiselvl5gua2",
&sprom->noiselvl5gua[2], 0, fallback);
nvram_read_u8(prefix, NULL, "pcieingress_war",
&sprom->pcieingress_war, 0, fallback);
}
static void bcm47xx_fill_sprom_r9(struct ssb_sprom *sprom, const char *prefix,
bool fallback)
{
nvram_read_u16(prefix, NULL, "cckbw202gpo", &sprom->cckbw202gpo, 0,
fallback);
nvram_read_u16(prefix, NULL, "cckbw20ul2gpo", &sprom->cckbw20ul2gpo, 0,
fallback);
nvram_read_u32(prefix, NULL, "legofdmbw202gpo",
&sprom->legofdmbw202gpo, 0, fallback);
nvram_read_u32(prefix, NULL, "legofdmbw20ul2gpo",
&sprom->legofdmbw20ul2gpo, 0, fallback);
nvram_read_u32(prefix, NULL, "legofdmbw205glpo",
&sprom->legofdmbw205glpo, 0, fallback);
nvram_read_u32(prefix, NULL, "legofdmbw20ul5glpo",
&sprom->legofdmbw20ul5glpo, 0, fallback);
nvram_read_u32(prefix, NULL, "legofdmbw205gmpo",
&sprom->legofdmbw205gmpo, 0, fallback);
nvram_read_u32(prefix, NULL, "legofdmbw20ul5gmpo",
&sprom->legofdmbw20ul5gmpo, 0, fallback);
nvram_read_u32(prefix, NULL, "legofdmbw205ghpo",
&sprom->legofdmbw205ghpo, 0, fallback);
nvram_read_u32(prefix, NULL, "legofdmbw20ul5ghpo",
&sprom->legofdmbw20ul5ghpo, 0, fallback);
nvram_read_u32(prefix, NULL, "mcsbw202gpo", &sprom->mcsbw202gpo, 0,
fallback);
nvram_read_u32(prefix, NULL, "mcsbw20ul2gpo", &sprom->mcsbw20ul2gpo, 0,
fallback);
nvram_read_u32(prefix, NULL, "mcsbw402gpo", &sprom->mcsbw402gpo, 0,
fallback);
nvram_read_u32(prefix, NULL, "mcsbw205glpo", &sprom->mcsbw205glpo, 0,
fallback);
nvram_read_u32(prefix, NULL, "mcsbw20ul5glpo",
&sprom->mcsbw20ul5glpo, 0, fallback);
nvram_read_u32(prefix, NULL, "mcsbw405glpo", &sprom->mcsbw405glpo, 0,
fallback);
nvram_read_u32(prefix, NULL, "mcsbw205gmpo", &sprom->mcsbw205gmpo, 0,
fallback);
nvram_read_u32(prefix, NULL, "mcsbw20ul5gmpo",
&sprom->mcsbw20ul5gmpo, 0, fallback);
nvram_read_u32(prefix, NULL, "mcsbw405gmpo", &sprom->mcsbw405gmpo, 0,
fallback);
nvram_read_u32(prefix, NULL, "mcsbw205ghpo", &sprom->mcsbw205ghpo, 0,
fallback);
nvram_read_u32(prefix, NULL, "mcsbw20ul5ghpo",
&sprom->mcsbw20ul5ghpo, 0, fallback);
nvram_read_u32(prefix, NULL, "mcsbw405ghpo", &sprom->mcsbw405ghpo, 0,
fallback);
nvram_read_u16(prefix, NULL, "mcs32po", &sprom->mcs32po, 0, fallback);
nvram_read_u16(prefix, NULL, "legofdm40duppo",
&sprom->legofdm40duppo, 0, fallback);
nvram_read_u8(prefix, NULL, "sar2g", &sprom->sar2g, 0, fallback);
nvram_read_u8(prefix, NULL, "sar5g", &sprom->sar5g, 0, fallback);
}
static void bcm47xx_fill_sprom_path_r4589(struct ssb_sprom *sprom,
const char *prefix, bool fallback)
{
char postfix[2];
int i;
for (i = 0; i < ARRAY_SIZE(sprom->core_pwr_info); i++) {
struct ssb_sprom_core_pwr_info *pwr_info = &sprom->core_pwr_info[i];
snprintf(postfix, sizeof(postfix), "%i", i);
nvram_read_u8(prefix, postfix, "maxp2ga",
&pwr_info->maxpwr_2g, 0, fallback);
nvram_read_u8(prefix, postfix, "itt2ga",
&pwr_info->itssi_2g, 0, fallback);
nvram_read_u8(prefix, postfix, "itt5ga",
&pwr_info->itssi_5g, 0, fallback);
nvram_read_u16(prefix, postfix, "pa2gw0a",
&pwr_info->pa_2g[0], 0, fallback);
nvram_read_u16(prefix, postfix, "pa2gw1a",
&pwr_info->pa_2g[1], 0, fallback);
nvram_read_u16(prefix, postfix, "pa2gw2a",
&pwr_info->pa_2g[2], 0, fallback);
nvram_read_u8(prefix, postfix, "maxp5ga",
&pwr_info->maxpwr_5g, 0, fallback);
nvram_read_u8(prefix, postfix, "maxp5gha",
&pwr_info->maxpwr_5gh, 0, fallback);
nvram_read_u8(prefix, postfix, "maxp5gla",
&pwr_info->maxpwr_5gl, 0, fallback);
nvram_read_u16(prefix, postfix, "pa5gw0a",
&pwr_info->pa_5g[0], 0, fallback);
nvram_read_u16(prefix, postfix, "pa5gw1a",
&pwr_info->pa_5g[1], 0, fallback);
nvram_read_u16(prefix, postfix, "pa5gw2a",
&pwr_info->pa_5g[2], 0, fallback);
nvram_read_u16(prefix, postfix, "pa5glw0a",
&pwr_info->pa_5gl[0], 0, fallback);
nvram_read_u16(prefix, postfix, "pa5glw1a",
&pwr_info->pa_5gl[1], 0, fallback);
nvram_read_u16(prefix, postfix, "pa5glw2a",
&pwr_info->pa_5gl[2], 0, fallback);
nvram_read_u16(prefix, postfix, "pa5ghw0a",
&pwr_info->pa_5gh[0], 0, fallback);
nvram_read_u16(prefix, postfix, "pa5ghw1a",
&pwr_info->pa_5gh[1], 0, fallback);
nvram_read_u16(prefix, postfix, "pa5ghw2a",
&pwr_info->pa_5gh[2], 0, fallback);
}
}
static void bcm47xx_fill_sprom_path_r45(struct ssb_sprom *sprom,
const char *prefix, bool fallback)
{
char postfix[2];
int i;
for (i = 0; i < ARRAY_SIZE(sprom->core_pwr_info); i++) {
struct ssb_sprom_core_pwr_info *pwr_info = &sprom->core_pwr_info[i];
snprintf(postfix, sizeof(postfix), "%i", i);
nvram_read_u16(prefix, postfix, "pa2gw3a",
&pwr_info->pa_2g[3], 0, fallback);
nvram_read_u16(prefix, postfix, "pa5gw3a",
&pwr_info->pa_5g[3], 0, fallback);
nvram_read_u16(prefix, postfix, "pa5glw3a",
&pwr_info->pa_5gl[3], 0, fallback);
nvram_read_u16(prefix, postfix, "pa5ghw3a",
&pwr_info->pa_5gh[3], 0, fallback);
}
}
static void bcm47xx_fill_sprom_ethernet(struct ssb_sprom *sprom,
const char *prefix, bool fallback)
{
nvram_read_macaddr(prefix, "et0macaddr", &sprom->et0mac, fallback);
nvram_read_u8(prefix, NULL, "et0mdcport", &sprom->et0mdcport, 0,
fallback);
nvram_read_u8(prefix, NULL, "et0phyaddr", &sprom->et0phyaddr, 0,
fallback);
nvram_read_macaddr(prefix, "et1macaddr", &sprom->et1mac, fallback);
nvram_read_u8(prefix, NULL, "et1mdcport", &sprom->et1mdcport, 0,
fallback);
nvram_read_u8(prefix, NULL, "et1phyaddr", &sprom->et1phyaddr, 0,
fallback);
nvram_read_macaddr(prefix, "macaddr", &sprom->il0mac, fallback);
nvram_read_macaddr(prefix, "il0macaddr", &sprom->il0mac, fallback);
}
static void bcm47xx_fill_board_data(struct ssb_sprom *sprom, const char *prefix,
bool fallback)
{
nvram_read_u16(prefix, NULL, "boardrev", &sprom->board_rev, 0,
fallback);
nvram_read_u16(prefix, NULL, "boardnum", &sprom->board_num, 0,
fallback);
nvram_read_u16(prefix, NULL, "boardtype", &sprom->board_type, 0,
fallback);
nvram_read_u32_2(prefix, "boardflags", &sprom->boardflags_lo,
&sprom->boardflags_hi, fallback);
nvram_read_u32_2(prefix, "boardflags2", &sprom->boardflags2_lo,
&sprom->boardflags2_hi, fallback);
}
void bcm47xx_fill_sprom(struct ssb_sprom *sprom, const char *prefix,
bool fallback)
{
bcm47xx_fill_sprom_ethernet(sprom, prefix, fallback);
bcm47xx_fill_board_data(sprom, prefix, fallback);
nvram_read_u8(prefix, NULL, "sromrev", &sprom->revision, 0, fallback);
switch (sprom->revision) {
case 1:
bcm47xx_fill_sprom_r1234589(sprom, prefix, fallback);
bcm47xx_fill_sprom_r12389(sprom, prefix, fallback);
bcm47xx_fill_sprom_r1(sprom, prefix, fallback);
break;
case 2:
bcm47xx_fill_sprom_r1234589(sprom, prefix, fallback);
bcm47xx_fill_sprom_r12389(sprom, prefix, fallback);
bcm47xx_fill_sprom_r2389(sprom, prefix, fallback);
break;
case 3:
bcm47xx_fill_sprom_r1234589(sprom, prefix, fallback);
bcm47xx_fill_sprom_r12389(sprom, prefix, fallback);
bcm47xx_fill_sprom_r2389(sprom, prefix, fallback);
bcm47xx_fill_sprom_r389(sprom, prefix, fallback);
bcm47xx_fill_sprom_r3(sprom, prefix, fallback);
break;
case 4:
case 5:
bcm47xx_fill_sprom_r1234589(sprom, prefix, fallback);
bcm47xx_fill_sprom_r4589(sprom, prefix, fallback);
bcm47xx_fill_sprom_r458(sprom, prefix, fallback);
bcm47xx_fill_sprom_r45(sprom, prefix, fallback);
bcm47xx_fill_sprom_path_r4589(sprom, prefix, fallback);
bcm47xx_fill_sprom_path_r45(sprom, prefix, fallback);
break;
case 8:
bcm47xx_fill_sprom_r1234589(sprom, prefix, fallback);
bcm47xx_fill_sprom_r12389(sprom, prefix, fallback);
bcm47xx_fill_sprom_r2389(sprom, prefix, fallback);
bcm47xx_fill_sprom_r389(sprom, prefix, fallback);
bcm47xx_fill_sprom_r4589(sprom, prefix, fallback);
bcm47xx_fill_sprom_r458(sprom, prefix, fallback);
bcm47xx_fill_sprom_r89(sprom, prefix, fallback);
bcm47xx_fill_sprom_path_r4589(sprom, prefix, fallback);
break;
case 9:
bcm47xx_fill_sprom_r1234589(sprom, prefix, fallback);
bcm47xx_fill_sprom_r12389(sprom, prefix, fallback);
bcm47xx_fill_sprom_r2389(sprom, prefix, fallback);
bcm47xx_fill_sprom_r389(sprom, prefix, fallback);
bcm47xx_fill_sprom_r4589(sprom, prefix, fallback);
bcm47xx_fill_sprom_r89(sprom, prefix, fallback);
bcm47xx_fill_sprom_r9(sprom, prefix, fallback);
bcm47xx_fill_sprom_path_r4589(sprom, prefix, fallback);
break;
default:
pr_warn("Unsupported SPROM revision %d detected. Will extract"
" v1\n", sprom->revision);
sprom->revision = 1;
bcm47xx_fill_sprom_r1234589(sprom, prefix, fallback);
bcm47xx_fill_sprom_r12389(sprom, prefix, fallback);
bcm47xx_fill_sprom_r1(sprom, prefix, fallback);
}
}
#ifdef CONFIG_BCM47XX_SSB
void bcm47xx_fill_ssb_boardinfo(struct ssb_boardinfo *boardinfo,
const char *prefix)
{
nvram_read_u16(prefix, NULL, "boardvendor", &boardinfo->vendor, 0,
true);
if (!boardinfo->vendor)
boardinfo->vendor = SSB_BOARDVENDOR_BCM;
nvram_read_u16(prefix, NULL, "boardtype", &boardinfo->type, 0, true);
}
#endif
#ifdef CONFIG_BCM47XX_BCMA
void bcm47xx_fill_bcma_boardinfo(struct bcma_boardinfo *boardinfo,
const char *prefix)
{
nvram_read_u16(prefix, NULL, "boardvendor", &boardinfo->vendor, 0,
true);
if (!boardinfo->vendor)
boardinfo->vendor = SSB_BOARDVENDOR_BCM;
nvram_read_u16(prefix, NULL, "boardtype", &boardinfo->type, 0, true);
}
#endif