blob: 12b2cc9a3fbe8a1050133582e7f553b599fbcbbf [file] [log] [blame] [edit]
/*
* Broadcom specific AMBA
* PCI Core
*
* Copyright 2005, 2011, Broadcom Corporation
* Copyright 2006, 2007, Michael Buesch <m@bues.ch>
* Copyright 2011, 2012, Hauke Mehrtens <hauke@hauke-m.de>
*
* Licensed under the GNU/GPL. See COPYING for details.
*/
#include "bcma_private.h"
#include <linux/export.h>
#include <linux/bcma/bcma.h>
/**************************************************
* R/W ops.
**************************************************/
u32 bcma_pcie_read(struct bcma_drv_pci *pc, u32 address)
{
pcicore_write32(pc, BCMA_CORE_PCI_PCIEIND_ADDR, address);
pcicore_read32(pc, BCMA_CORE_PCI_PCIEIND_ADDR);
return pcicore_read32(pc, BCMA_CORE_PCI_PCIEIND_DATA);
}
static void bcma_pcie_write(struct bcma_drv_pci *pc, u32 address, u32 data)
{
pcicore_write32(pc, BCMA_CORE_PCI_PCIEIND_ADDR, address);
pcicore_read32(pc, BCMA_CORE_PCI_PCIEIND_ADDR);
pcicore_write32(pc, BCMA_CORE_PCI_PCIEIND_DATA, data);
}
static void bcma_pcie_mdio_set_phy(struct bcma_drv_pci *pc, u16 phy)
{
u32 v;
int i;
v = BCMA_CORE_PCI_MDIODATA_START;
v |= BCMA_CORE_PCI_MDIODATA_WRITE;
v |= (BCMA_CORE_PCI_MDIODATA_DEV_ADDR <<
BCMA_CORE_PCI_MDIODATA_DEVADDR_SHF);
v |= (BCMA_CORE_PCI_MDIODATA_BLK_ADDR <<
BCMA_CORE_PCI_MDIODATA_REGADDR_SHF);
v |= BCMA_CORE_PCI_MDIODATA_TA;
v |= (phy << 4);
pcicore_write32(pc, BCMA_CORE_PCI_MDIO_DATA, v);
udelay(10);
for (i = 0; i < 200; i++) {
v = pcicore_read32(pc, BCMA_CORE_PCI_MDIO_CONTROL);
if (v & BCMA_CORE_PCI_MDIOCTL_ACCESS_DONE)
break;
usleep_range(1000, 2000);
}
}
static u16 bcma_pcie_mdio_read(struct bcma_drv_pci *pc, u16 device, u8 address)
{
int max_retries = 10;
u16 ret = 0;
u32 v;
int i;
/* enable mdio access to SERDES */
v = BCMA_CORE_PCI_MDIOCTL_PREAM_EN;
v |= BCMA_CORE_PCI_MDIOCTL_DIVISOR_VAL;
pcicore_write32(pc, BCMA_CORE_PCI_MDIO_CONTROL, v);
if (pc->core->id.rev >= 10) {
max_retries = 200;
bcma_pcie_mdio_set_phy(pc, device);
v = (BCMA_CORE_PCI_MDIODATA_DEV_ADDR <<
BCMA_CORE_PCI_MDIODATA_DEVADDR_SHF);
v |= (address << BCMA_CORE_PCI_MDIODATA_REGADDR_SHF);
} else {
v = (device << BCMA_CORE_PCI_MDIODATA_DEVADDR_SHF_OLD);
v |= (address << BCMA_CORE_PCI_MDIODATA_REGADDR_SHF_OLD);
}
v |= BCMA_CORE_PCI_MDIODATA_START;
v |= BCMA_CORE_PCI_MDIODATA_READ;
v |= BCMA_CORE_PCI_MDIODATA_TA;
pcicore_write32(pc, BCMA_CORE_PCI_MDIO_DATA, v);
/* Wait for the device to complete the transaction */
udelay(10);
for (i = 0; i < max_retries; i++) {
v = pcicore_read32(pc, BCMA_CORE_PCI_MDIO_CONTROL);
if (v & BCMA_CORE_PCI_MDIOCTL_ACCESS_DONE) {
udelay(10);
ret = pcicore_read32(pc, BCMA_CORE_PCI_MDIO_DATA);
break;
}
usleep_range(1000, 2000);
}
pcicore_write32(pc, BCMA_CORE_PCI_MDIO_CONTROL, 0);
return ret;
}
static void bcma_pcie_mdio_write(struct bcma_drv_pci *pc, u16 device,
u8 address, u16 data)
{
int max_retries = 10;
u32 v;
int i;
/* enable mdio access to SERDES */
v = BCMA_CORE_PCI_MDIOCTL_PREAM_EN;
v |= BCMA_CORE_PCI_MDIOCTL_DIVISOR_VAL;
pcicore_write32(pc, BCMA_CORE_PCI_MDIO_CONTROL, v);
if (pc->core->id.rev >= 10) {
max_retries = 200;
bcma_pcie_mdio_set_phy(pc, device);
v = (BCMA_CORE_PCI_MDIODATA_DEV_ADDR <<
BCMA_CORE_PCI_MDIODATA_DEVADDR_SHF);
v |= (address << BCMA_CORE_PCI_MDIODATA_REGADDR_SHF);
} else {
v = (device << BCMA_CORE_PCI_MDIODATA_DEVADDR_SHF_OLD);
v |= (address << BCMA_CORE_PCI_MDIODATA_REGADDR_SHF_OLD);
}
v |= BCMA_CORE_PCI_MDIODATA_START;
v |= BCMA_CORE_PCI_MDIODATA_WRITE;
v |= BCMA_CORE_PCI_MDIODATA_TA;
v |= data;
pcicore_write32(pc, BCMA_CORE_PCI_MDIO_DATA, v);
/* Wait for the device to complete the transaction */
udelay(10);
for (i = 0; i < max_retries; i++) {
v = pcicore_read32(pc, BCMA_CORE_PCI_MDIO_CONTROL);
if (v & BCMA_CORE_PCI_MDIOCTL_ACCESS_DONE)
break;
usleep_range(1000, 2000);
}
pcicore_write32(pc, BCMA_CORE_PCI_MDIO_CONTROL, 0);
}
static u16 bcma_pcie_mdio_writeread(struct bcma_drv_pci *pc, u16 device,
u8 address, u16 data)
{
bcma_pcie_mdio_write(pc, device, address, data);
return bcma_pcie_mdio_read(pc, device, address);
}
/**************************************************
* Early init.
**************************************************/
static void bcma_core_pci_fixcfg(struct bcma_drv_pci *pc)
{
struct bcma_device *core = pc->core;
u16 val16, core_index;
uint regoff;
regoff = BCMA_CORE_PCI_SPROM(BCMA_CORE_PCI_SPROM_PI_OFFSET);
core_index = (u16)core->core_index;
val16 = pcicore_read16(pc, regoff);
if (((val16 & BCMA_CORE_PCI_SPROM_PI_MASK) >> BCMA_CORE_PCI_SPROM_PI_SHIFT)
!= core_index) {
val16 = (core_index << BCMA_CORE_PCI_SPROM_PI_SHIFT) |
(val16 & ~BCMA_CORE_PCI_SPROM_PI_MASK);
pcicore_write16(pc, regoff, val16);
}
}
/*
* Apply some early fixes required before accessing SPROM.
* See also si_pci_fixcfg.
*/
void bcma_core_pci_early_init(struct bcma_drv_pci *pc)
{
if (pc->early_setup_done)
return;
pc->hostmode = bcma_core_pci_is_in_hostmode(pc);
if (pc->hostmode)
goto out;
bcma_core_pci_fixcfg(pc);
out:
pc->early_setup_done = true;
}
/**************************************************
* Workarounds.
**************************************************/
static u8 bcma_pcicore_polarity_workaround(struct bcma_drv_pci *pc)
{
u32 tmp;
tmp = bcma_pcie_read(pc, BCMA_CORE_PCI_PLP_STATUSREG);
if (tmp & BCMA_CORE_PCI_PLP_POLARITYINV_STAT)
return BCMA_CORE_PCI_SERDES_RX_CTRL_FORCE |
BCMA_CORE_PCI_SERDES_RX_CTRL_POLARITY;
else
return BCMA_CORE_PCI_SERDES_RX_CTRL_FORCE;
}
static void bcma_pcicore_serdes_workaround(struct bcma_drv_pci *pc)
{
u16 tmp;
bcma_pcie_mdio_write(pc, BCMA_CORE_PCI_MDIODATA_DEV_RX,
BCMA_CORE_PCI_SERDES_RX_CTRL,
bcma_pcicore_polarity_workaround(pc));
tmp = bcma_pcie_mdio_read(pc, BCMA_CORE_PCI_MDIODATA_DEV_PLL,
BCMA_CORE_PCI_SERDES_PLL_CTRL);
if (tmp & BCMA_CORE_PCI_PLL_CTRL_FREQDET_EN)
bcma_pcie_mdio_write(pc, BCMA_CORE_PCI_MDIODATA_DEV_PLL,
BCMA_CORE_PCI_SERDES_PLL_CTRL,
tmp & ~BCMA_CORE_PCI_PLL_CTRL_FREQDET_EN);
}
/* Fix MISC config to allow coming out of L2/L3-Ready state w/o PRST */
/* Needs to happen when coming out of 'standby'/'hibernate' */
static void bcma_core_pci_config_fixup(struct bcma_drv_pci *pc)
{
u16 val16;
uint regoff;
regoff = BCMA_CORE_PCI_SPROM(BCMA_CORE_PCI_SPROM_MISC_CONFIG);
val16 = pcicore_read16(pc, regoff);
if (!(val16 & BCMA_CORE_PCI_SPROM_L23READY_EXIT_NOPERST)) {
val16 |= BCMA_CORE_PCI_SPROM_L23READY_EXIT_NOPERST;
pcicore_write16(pc, regoff, val16);
}
}
/**************************************************
* Init.
**************************************************/
static void bcma_core_pci_clientmode_init(struct bcma_drv_pci *pc)
{
bcma_pcicore_serdes_workaround(pc);
bcma_core_pci_config_fixup(pc);
}
void bcma_core_pci_init(struct bcma_drv_pci *pc)
{
if (pc->setup_done)
return;
bcma_core_pci_early_init(pc);
if (pc->hostmode)
bcma_core_pci_hostmode_init(pc);
else
bcma_core_pci_clientmode_init(pc);
}
void bcma_core_pci_power_save(struct bcma_bus *bus, bool up)
{
struct bcma_drv_pci *pc;
u16 data;
if (bus->hosttype != BCMA_HOSTTYPE_PCI)
return;
pc = &bus->drv_pci[0];
if (pc->core->id.rev >= 15 && pc->core->id.rev <= 20) {
data = up ? 0x74 : 0x7C;
bcma_pcie_mdio_writeread(pc, BCMA_CORE_PCI_MDIO_BLK1,
BCMA_CORE_PCI_MDIO_BLK1_MGMT1, 0x7F64);
bcma_pcie_mdio_writeread(pc, BCMA_CORE_PCI_MDIO_BLK1,
BCMA_CORE_PCI_MDIO_BLK1_MGMT3, data);
} else if (pc->core->id.rev >= 21 && pc->core->id.rev <= 22) {
data = up ? 0x75 : 0x7D;
bcma_pcie_mdio_writeread(pc, BCMA_CORE_PCI_MDIO_BLK1,
BCMA_CORE_PCI_MDIO_BLK1_MGMT1, 0x7E65);
bcma_pcie_mdio_writeread(pc, BCMA_CORE_PCI_MDIO_BLK1,
BCMA_CORE_PCI_MDIO_BLK1_MGMT3, data);
}
}
EXPORT_SYMBOL_GPL(bcma_core_pci_power_save);
static void bcma_core_pci_extend_L1timer(struct bcma_drv_pci *pc, bool extend)
{
u32 w;
w = bcma_pcie_read(pc, BCMA_CORE_PCI_DLLP_PMTHRESHREG);
if (extend)
w |= BCMA_CORE_PCI_ASPMTIMER_EXTEND;
else
w &= ~BCMA_CORE_PCI_ASPMTIMER_EXTEND;
bcma_pcie_write(pc, BCMA_CORE_PCI_DLLP_PMTHRESHREG, w);
bcma_pcie_read(pc, BCMA_CORE_PCI_DLLP_PMTHRESHREG);
}
void bcma_core_pci_up(struct bcma_drv_pci *pc)
{
bcma_core_pci_extend_L1timer(pc, true);
}
void bcma_core_pci_down(struct bcma_drv_pci *pc)
{
bcma_core_pci_extend_L1timer(pc, false);
}