linux/arch/powerpc/platforms/85xx/p1022_ds.c
Wang Dongsheng 48b16180d0 fsl/pci: The new pci suspend/resume implementation
If we do nothing in suspend/resume, some platform PCIe ip-block
can't guarantee the link back to L0 state from sleep, then, when
we read the EP device will hang. Only we send pme turnoff message
in pci controller suspend, and send pme exit message in resume, the
link state will be normal.

When we send pme turnoff message in pci controller suspend, the
links will into l2/l3 ready, then, host cannot communicate with
ep device, but pci-driver will call back EP device to save them
state. So we need to change platform_driver->suspend/resume to
syscore->suspend/resume.

So the new suspend/resume implementation, send pme turnoff message
in suspend, and send pme exit message in resume. And add a PME handler,
to response PME & message interrupt.

Change platform_driver->suspend/resume to syscore->suspend/resume.
pci-driver will call back EP device, to save EP state in
pci_pm_suspend_noirq, so we need to keep the link, until
pci_pm_suspend_noirq finish.

Signed-off-by: Wang Dongsheng <dongsheng.wang@freescale.com>
Signed-off-by: Scott Wood <scottwood@freescale.com>
2014-03-19 22:37:44 -05:00

577 lines
15 KiB
C

/*
* P1022DS board specific routines
*
* Authors: Travis Wheatley <travis.wheatley@freescale.com>
* Dave Liu <daveliu@freescale.com>
* Timur Tabi <timur@freescale.com>
*
* Copyright 2010 Freescale Semiconductor, Inc.
*
* This file is taken from the Freescale P1022DS BSP, with modifications:
* 2) No AMP support
* 3) No PCI endpoint support
*
* This file is licensed under the terms of the GNU General Public License
* version 2. This program is licensed "as is" without any warranty of any
* kind, whether express or implied.
*/
#include <linux/pci.h>
#include <linux/of_platform.h>
#include <asm/div64.h>
#include <asm/mpic.h>
#include <asm/swiotlb.h>
#include <sysdev/fsl_soc.h>
#include <sysdev/fsl_pci.h>
#include <asm/udbg.h>
#include <asm/fsl_guts.h>
#include <asm/fsl_lbc.h>
#include "smp.h"
#include "mpc85xx.h"
#if defined(CONFIG_FB_FSL_DIU) || defined(CONFIG_FB_FSL_DIU_MODULE)
#define PMUXCR_ELBCDIU_MASK 0xc0000000
#define PMUXCR_ELBCDIU_NOR16 0x80000000
#define PMUXCR_ELBCDIU_DIU 0x40000000
/*
* Board-specific initialization of the DIU. This code should probably be
* executed when the DIU is opened, rather than in arch code, but the DIU
* driver does not have a mechanism for this (yet).
*
* This is especially problematic on the P1022DS because the local bus (eLBC)
* and the DIU video signals share the same pins, which means that enabling the
* DIU will disable access to NOR flash.
*/
/* DIU Pixel Clock bits of the CLKDVDR Global Utilities register */
#define CLKDVDR_PXCKEN 0x80000000
#define CLKDVDR_PXCKINV 0x10000000
#define CLKDVDR_PXCKDLY 0x06000000
#define CLKDVDR_PXCLK_MASK 0x00FF0000
/* Some ngPIXIS register definitions */
#define PX_CTL 3
#define PX_BRDCFG0 8
#define PX_BRDCFG1 9
#define PX_BRDCFG0_ELBC_SPI_MASK 0xc0
#define PX_BRDCFG0_ELBC_SPI_ELBC 0x00
#define PX_BRDCFG0_ELBC_SPI_NULL 0xc0
#define PX_BRDCFG0_ELBC_DIU 0x02
#define PX_BRDCFG1_DVIEN 0x80
#define PX_BRDCFG1_DFPEN 0x40
#define PX_BRDCFG1_BACKLIGHT 0x20
#define PX_BRDCFG1_DDCEN 0x10
#define PX_CTL_ALTACC 0x80
/*
* DIU Area Descriptor
*
* Note that we need to byte-swap the value before it's written to the AD
* register. So even though the registers don't look like they're in the same
* bit positions as they are on the MPC8610, the same value is written to the
* AD register on the MPC8610 and on the P1022.
*/
#define AD_BYTE_F 0x10000000
#define AD_ALPHA_C_MASK 0x0E000000
#define AD_ALPHA_C_SHIFT 25
#define AD_BLUE_C_MASK 0x01800000
#define AD_BLUE_C_SHIFT 23
#define AD_GREEN_C_MASK 0x00600000
#define AD_GREEN_C_SHIFT 21
#define AD_RED_C_MASK 0x00180000
#define AD_RED_C_SHIFT 19
#define AD_PALETTE 0x00040000
#define AD_PIXEL_S_MASK 0x00030000
#define AD_PIXEL_S_SHIFT 16
#define AD_COMP_3_MASK 0x0000F000
#define AD_COMP_3_SHIFT 12
#define AD_COMP_2_MASK 0x00000F00
#define AD_COMP_2_SHIFT 8
#define AD_COMP_1_MASK 0x000000F0
#define AD_COMP_1_SHIFT 4
#define AD_COMP_0_MASK 0x0000000F
#define AD_COMP_0_SHIFT 0
#define MAKE_AD(alpha, red, blue, green, size, c0, c1, c2, c3) \
cpu_to_le32(AD_BYTE_F | (alpha << AD_ALPHA_C_SHIFT) | \
(blue << AD_BLUE_C_SHIFT) | (green << AD_GREEN_C_SHIFT) | \
(red << AD_RED_C_SHIFT) | (c3 << AD_COMP_3_SHIFT) | \
(c2 << AD_COMP_2_SHIFT) | (c1 << AD_COMP_1_SHIFT) | \
(c0 << AD_COMP_0_SHIFT) | (size << AD_PIXEL_S_SHIFT))
struct fsl_law {
u32 lawbar;
u32 reserved1;
u32 lawar;
u32 reserved[5];
};
#define LAWBAR_MASK 0x00F00000
#define LAWBAR_SHIFT 12
#define LAWAR_EN 0x80000000
#define LAWAR_TGT_MASK 0x01F00000
#define LAW_TRGT_IF_LBC (0x04 << 20)
#define LAWAR_MASK (LAWAR_EN | LAWAR_TGT_MASK)
#define LAWAR_MATCH (LAWAR_EN | LAW_TRGT_IF_LBC)
#define BR_BA 0xFFFF8000
/*
* Map a BRx value to a physical address
*
* The localbus BRx registers only store the lower 32 bits of the address. To
* obtain the upper four bits, we need to scan the LAW table. The entry which
* maps to the localbus will contain the upper four bits.
*/
static phys_addr_t lbc_br_to_phys(const void *ecm, unsigned int count, u32 br)
{
#ifndef CONFIG_PHYS_64BIT
/*
* If we only have 32-bit addressing, then the BRx address *is* the
* physical address.
*/
return br & BR_BA;
#else
const struct fsl_law *law = ecm + 0xc08;
unsigned int i;
for (i = 0; i < count; i++) {
u64 lawbar = in_be32(&law[i].lawbar);
u32 lawar = in_be32(&law[i].lawar);
if ((lawar & LAWAR_MASK) == LAWAR_MATCH)
/* Extract the upper four bits */
return (br & BR_BA) | ((lawbar & LAWBAR_MASK) << 12);
}
return 0;
#endif
}
/**
* p1022ds_set_monitor_port: switch the output to a different monitor port
*/
static void p1022ds_set_monitor_port(enum fsl_diu_monitor_port port)
{
struct device_node *guts_node;
struct device_node *lbc_node = NULL;
struct device_node *law_node = NULL;
struct ccsr_guts __iomem *guts;
struct fsl_lbc_regs *lbc = NULL;
void *ecm = NULL;
u8 __iomem *lbc_lcs0_ba = NULL;
u8 __iomem *lbc_lcs1_ba = NULL;
phys_addr_t cs0_addr, cs1_addr;
u32 br0, or0, br1, or1;
const __be32 *iprop;
unsigned int num_laws;
u8 b;
/* Map the global utilities registers. */
guts_node = of_find_compatible_node(NULL, NULL, "fsl,p1022-guts");
if (!guts_node) {
pr_err("p1022ds: missing global utilities device node\n");
return;
}
guts = of_iomap(guts_node, 0);
if (!guts) {
pr_err("p1022ds: could not map global utilities device\n");
goto exit;
}
lbc_node = of_find_compatible_node(NULL, NULL, "fsl,p1022-elbc");
if (!lbc_node) {
pr_err("p1022ds: missing localbus node\n");
goto exit;
}
lbc = of_iomap(lbc_node, 0);
if (!lbc) {
pr_err("p1022ds: could not map localbus node\n");
goto exit;
}
law_node = of_find_compatible_node(NULL, NULL, "fsl,ecm-law");
if (!law_node) {
pr_err("p1022ds: missing local access window node\n");
goto exit;
}
ecm = of_iomap(law_node, 0);
if (!ecm) {
pr_err("p1022ds: could not map local access window node\n");
goto exit;
}
iprop = of_get_property(law_node, "fsl,num-laws", NULL);
if (!iprop) {
pr_err("p1022ds: LAW node is missing fsl,num-laws property\n");
goto exit;
}
num_laws = be32_to_cpup(iprop);
/*
* Indirect mode requires both BR0 and BR1 to be set to "GPCM",
* otherwise writes to these addresses won't actually appear on the
* local bus, and so the PIXIS won't see them.
*
* In FCM mode, writes go to the NAND controller, which does not pass
* them to the localbus directly. So we force BR0 and BR1 into GPCM
* mode, since we don't care about what's behind the localbus any
* more.
*/
br0 = in_be32(&lbc->bank[0].br);
br1 = in_be32(&lbc->bank[1].br);
or0 = in_be32(&lbc->bank[0].or);
or1 = in_be32(&lbc->bank[1].or);
/* Make sure CS0 and CS1 are programmed */
if (!(br0 & BR_V) || !(br1 & BR_V)) {
pr_err("p1022ds: CS0 and/or CS1 is not programmed\n");
goto exit;
}
/*
* Use the existing BRx/ORx values if it's already GPCM. Otherwise,
* force the values to simple 32KB GPCM windows with the most
* conservative timing.
*/
if ((br0 & BR_MSEL) != BR_MS_GPCM) {
br0 = (br0 & BR_BA) | BR_V;
or0 = 0xFFFF8000 | 0xFF7;
out_be32(&lbc->bank[0].br, br0);
out_be32(&lbc->bank[0].or, or0);
}
if ((br1 & BR_MSEL) != BR_MS_GPCM) {
br1 = (br1 & BR_BA) | BR_V;
or1 = 0xFFFF8000 | 0xFF7;
out_be32(&lbc->bank[1].br, br1);
out_be32(&lbc->bank[1].or, or1);
}
cs0_addr = lbc_br_to_phys(ecm, num_laws, br0);
if (!cs0_addr) {
pr_err("p1022ds: could not determine physical address for CS0"
" (BR0=%08x)\n", br0);
goto exit;
}
cs1_addr = lbc_br_to_phys(ecm, num_laws, br1);
if (!cs1_addr) {
pr_err("p1022ds: could not determine physical address for CS1"
" (BR1=%08x)\n", br1);
goto exit;
}
lbc_lcs0_ba = ioremap(cs0_addr, 1);
if (!lbc_lcs0_ba) {
pr_err("p1022ds: could not ioremap CS0 address %llx\n",
(unsigned long long)cs0_addr);
goto exit;
}
lbc_lcs1_ba = ioremap(cs1_addr, 1);
if (!lbc_lcs1_ba) {
pr_err("p1022ds: could not ioremap CS1 address %llx\n",
(unsigned long long)cs1_addr);
goto exit;
}
/* Make sure we're in indirect mode first. */
if ((in_be32(&guts->pmuxcr) & PMUXCR_ELBCDIU_MASK) !=
PMUXCR_ELBCDIU_DIU) {
struct device_node *pixis_node;
void __iomem *pixis;
pixis_node =
of_find_compatible_node(NULL, NULL, "fsl,p1022ds-fpga");
if (!pixis_node) {
pr_err("p1022ds: missing pixis node\n");
goto exit;
}
pixis = of_iomap(pixis_node, 0);
of_node_put(pixis_node);
if (!pixis) {
pr_err("p1022ds: could not map pixis registers\n");
goto exit;
}
/* Enable indirect PIXIS mode. */
setbits8(pixis + PX_CTL, PX_CTL_ALTACC);
iounmap(pixis);
/* Switch the board mux to the DIU */
out_8(lbc_lcs0_ba, PX_BRDCFG0); /* BRDCFG0 */
b = in_8(lbc_lcs1_ba);
b |= PX_BRDCFG0_ELBC_DIU;
out_8(lbc_lcs1_ba, b);
/* Set the chip mux to DIU mode. */
clrsetbits_be32(&guts->pmuxcr, PMUXCR_ELBCDIU_MASK,
PMUXCR_ELBCDIU_DIU);
in_be32(&guts->pmuxcr);
}
switch (port) {
case FSL_DIU_PORT_DVI:
/* Enable the DVI port, disable the DFP and the backlight */
out_8(lbc_lcs0_ba, PX_BRDCFG1);
b = in_8(lbc_lcs1_ba);
b &= ~(PX_BRDCFG1_DFPEN | PX_BRDCFG1_BACKLIGHT);
b |= PX_BRDCFG1_DVIEN;
out_8(lbc_lcs1_ba, b);
break;
case FSL_DIU_PORT_LVDS:
/*
* LVDS also needs backlight enabled, otherwise the display
* will be blank.
*/
/* Enable the DFP port, disable the DVI and the backlight */
out_8(lbc_lcs0_ba, PX_BRDCFG1);
b = in_8(lbc_lcs1_ba);
b &= ~PX_BRDCFG1_DVIEN;
b |= PX_BRDCFG1_DFPEN | PX_BRDCFG1_BACKLIGHT;
out_8(lbc_lcs1_ba, b);
break;
default:
pr_err("p1022ds: unsupported monitor port %i\n", port);
}
exit:
if (lbc_lcs1_ba)
iounmap(lbc_lcs1_ba);
if (lbc_lcs0_ba)
iounmap(lbc_lcs0_ba);
if (lbc)
iounmap(lbc);
if (ecm)
iounmap(ecm);
if (guts)
iounmap(guts);
of_node_put(law_node);
of_node_put(lbc_node);
of_node_put(guts_node);
}
/**
* p1022ds_set_pixel_clock: program the DIU's clock
*
* @pixclock: the wavelength, in picoseconds, of the clock
*/
void p1022ds_set_pixel_clock(unsigned int pixclock)
{
struct device_node *guts_np = NULL;
struct ccsr_guts __iomem *guts;
unsigned long freq;
u64 temp;
u32 pxclk;
/* Map the global utilities registers. */
guts_np = of_find_compatible_node(NULL, NULL, "fsl,p1022-guts");
if (!guts_np) {
pr_err("p1022ds: missing global utilities device node\n");
return;
}
guts = of_iomap(guts_np, 0);
of_node_put(guts_np);
if (!guts) {
pr_err("p1022ds: could not map global utilities device\n");
return;
}
/* Convert pixclock from a wavelength to a frequency */
temp = 1000000000000ULL;
do_div(temp, pixclock);
freq = temp;
/*
* 'pxclk' is the ratio of the platform clock to the pixel clock.
* This number is programmed into the CLKDVDR register, and the valid
* range of values is 2-255.
*/
pxclk = DIV_ROUND_CLOSEST(fsl_get_sys_freq(), freq);
pxclk = clamp_t(u32, pxclk, 2, 255);
/* Disable the pixel clock, and set it to non-inverted and no delay */
clrbits32(&guts->clkdvdr,
CLKDVDR_PXCKEN | CLKDVDR_PXCKDLY | CLKDVDR_PXCLK_MASK);
/* Enable the clock and set the pxclk */
setbits32(&guts->clkdvdr, CLKDVDR_PXCKEN | (pxclk << 16));
iounmap(guts);
}
/**
* p1022ds_valid_monitor_port: set the monitor port for sysfs
*/
enum fsl_diu_monitor_port
p1022ds_valid_monitor_port(enum fsl_diu_monitor_port port)
{
switch (port) {
case FSL_DIU_PORT_DVI:
case FSL_DIU_PORT_LVDS:
return port;
default:
return FSL_DIU_PORT_DVI; /* Dual-link LVDS is not supported */
}
}
#endif
void __init p1022_ds_pic_init(void)
{
struct mpic *mpic = mpic_alloc(NULL, 0, MPIC_BIG_ENDIAN |
MPIC_SINGLE_DEST_CPU,
0, 256, " OpenPIC ");
BUG_ON(mpic == NULL);
mpic_init(mpic);
}
#if defined(CONFIG_FB_FSL_DIU) || defined(CONFIG_FB_FSL_DIU_MODULE)
/* TRUE if there is a "video=fslfb" command-line parameter. */
static bool fslfb;
/*
* Search for a "video=fslfb" command-line parameter, and set 'fslfb' to
* true if we find it.
*
* We need to use early_param() instead of __setup() because the normal
* __setup() gets called to late. However, early_param() gets called very
* early, before the device tree is unflattened, so all we can do now is set a
* global variable. Later on, p1022_ds_setup_arch() will use that variable
* to determine if we need to update the device tree.
*/
static int __init early_video_setup(char *options)
{
fslfb = (strncmp(options, "fslfb:", 6) == 0);
return 0;
}
early_param("video", early_video_setup);
#endif
/*
* Setup the architecture
*/
static void __init p1022_ds_setup_arch(void)
{
if (ppc_md.progress)
ppc_md.progress("p1022_ds_setup_arch()", 0);
#if defined(CONFIG_FB_FSL_DIU) || defined(CONFIG_FB_FSL_DIU_MODULE)
diu_ops.set_monitor_port = p1022ds_set_monitor_port;
diu_ops.set_pixel_clock = p1022ds_set_pixel_clock;
diu_ops.valid_monitor_port = p1022ds_valid_monitor_port;
/*
* Disable the NOR and NAND flash nodes if there is video=fslfb...
* command-line parameter. When the DIU is active, the localbus is
* unavailable, so we have to disable these nodes before the MTD
* driver loads.
*/
if (fslfb) {
struct device_node *np =
of_find_compatible_node(NULL, NULL, "fsl,p1022-elbc");
if (np) {
struct device_node *np2;
of_node_get(np);
np2 = of_find_compatible_node(np, NULL, "cfi-flash");
if (np2) {
static struct property nor_status = {
.name = "status",
.value = "disabled",
.length = sizeof("disabled"),
};
/*
* of_update_property() is called before
* kmalloc() is available, so the 'new' object
* should be allocated in the global area.
* The easiest way is to do that is to
* allocate one static local variable for each
* call to this function.
*/
pr_info("p1022ds: disabling %s node",
np2->full_name);
of_update_property(np2, &nor_status);
of_node_put(np2);
}
of_node_get(np);
np2 = of_find_compatible_node(np, NULL,
"fsl,elbc-fcm-nand");
if (np2) {
static struct property nand_status = {
.name = "status",
.value = "disabled",
.length = sizeof("disabled"),
};
pr_info("p1022ds: disabling %s node",
np2->full_name);
of_update_property(np2, &nand_status);
of_node_put(np2);
}
of_node_put(np);
}
}
#endif
mpc85xx_smp_init();
fsl_pci_assign_primary();
swiotlb_detect_4g();
pr_info("Freescale P1022 DS reference board\n");
}
machine_arch_initcall(p1022_ds, mpc85xx_common_publish_devices);
machine_arch_initcall(p1022_ds, swiotlb_setup_bus_notifier);
/*
* Called very early, device-tree isn't unflattened
*/
static int __init p1022_ds_probe(void)
{
unsigned long root = of_get_flat_dt_root();
return of_flat_dt_is_compatible(root, "fsl,p1022ds");
}
define_machine(p1022_ds) {
.name = "P1022 DS",
.probe = p1022_ds_probe,
.setup_arch = p1022_ds_setup_arch,
.init_IRQ = p1022_ds_pic_init,
#ifdef CONFIG_PCI
.pcibios_fixup_bus = fsl_pcibios_fixup_bus,
.pcibios_fixup_phb = fsl_pcibios_fixup_phb,
#endif
.get_irq = mpic_get_irq,
.restart = fsl_rstcr_restart,
.calibrate_decr = generic_calibrate_decr,
.progress = udbg_progress,
};