linux/arch/arm/mach-omap2/omap-smp.c
Tero Kristo 1d9a542565 ARM: OMAP2+: clockdomain: add usecounting support to autoidle APIs
The previous implementation was racy in many locations, where the current
status of the clockdomain was read out, some operations were executed,
and the previous status info was used afterwards to decide next state
for the clockdomain. Instead, fix the implementation of the allow_idle /
deny_idle APIs to properly have usecounting support. This allows clean
handling internally within the clockdomain core, and simplifies the
usage also within hwmod.

Signed-off-by: Tero Kristo <t-kristo@ti.com>
Signed-off-by: Tony Lindgren <tony@atomide.com>
2016-07-04 07:15:38 -07:00

335 lines
9.1 KiB
C

/*
* OMAP4 SMP source file. It contains platform specific functions
* needed for the linux smp kernel.
*
* Copyright (C) 2009 Texas Instruments, Inc.
*
* Author:
* Santosh Shilimkar <santosh.shilimkar@ti.com>
*
* Platform file needed for the OMAP4 SMP. This file is based on arm
* realview smp platform.
* * Copyright (c) 2002 ARM Limited.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 as
* published by the Free Software Foundation.
*/
#include <linux/init.h>
#include <linux/device.h>
#include <linux/smp.h>
#include <linux/io.h>
#include <linux/irqchip/arm-gic.h>
#include <asm/smp_scu.h>
#include <asm/virt.h>
#include "omap-secure.h"
#include "omap-wakeupgen.h"
#include <asm/cputype.h>
#include "soc.h"
#include "iomap.h"
#include "common.h"
#include "clockdomain.h"
#include "pm.h"
#define CPU_MASK 0xff0ffff0
#define CPU_CORTEX_A9 0x410FC090
#define CPU_CORTEX_A15 0x410FC0F0
#define OMAP5_CORE_COUNT 0x2
struct omap_smp_config {
unsigned long cpu1_rstctrl_pa;
void __iomem *cpu1_rstctrl_va;
void __iomem *scu_base;
void *startup_addr;
};
static struct omap_smp_config cfg;
static const struct omap_smp_config omap443x_cfg __initconst = {
.cpu1_rstctrl_pa = 0x4824380c,
.startup_addr = omap4_secondary_startup,
};
static const struct omap_smp_config omap446x_cfg __initconst = {
.cpu1_rstctrl_pa = 0x4824380c,
.startup_addr = omap4460_secondary_startup,
};
static const struct omap_smp_config omap5_cfg __initconst = {
.cpu1_rstctrl_pa = 0x48243810,
.startup_addr = omap5_secondary_startup,
};
static DEFINE_SPINLOCK(boot_lock);
void __iomem *omap4_get_scu_base(void)
{
return cfg.scu_base;
}
#ifdef CONFIG_OMAP5_ERRATA_801819
void omap5_erratum_workaround_801819(void)
{
u32 acr, revidr;
u32 acr_mask;
/* REVIDR[3] indicates erratum fix available on silicon */
asm volatile ("mrc p15, 0, %0, c0, c0, 6" : "=r" (revidr));
if (revidr & (0x1 << 3))
return;
asm volatile ("mrc p15, 0, %0, c1, c0, 1" : "=r" (acr));
/*
* BIT(27) - Disables streaming. All write-allocate lines allocate in
* the L1 or L2 cache.
* BIT(25) - Disables streaming. All write-allocate lines allocate in
* the L1 cache.
*/
acr_mask = (0x3 << 25) | (0x3 << 27);
/* do we already have it done.. if yes, skip expensive smc */
if ((acr & acr_mask) == acr_mask)
return;
acr |= acr_mask;
omap_smc1(OMAP5_DRA7_MON_SET_ACR_INDEX, acr);
pr_debug("%s: ARM erratum workaround 801819 applied on CPU%d\n",
__func__, smp_processor_id());
}
#else
static inline void omap5_erratum_workaround_801819(void) { }
#endif
static void omap4_secondary_init(unsigned int cpu)
{
/*
* Configure ACTRL and enable NS SMP bit access on CPU1 on HS device.
* OMAP44XX EMU/HS devices - CPU0 SMP bit access is enabled in PPA
* init and for CPU1, a secure PPA API provided. CPU0 must be ON
* while executing NS_SMP API on CPU1 and PPA version must be 1.4.0+.
* OMAP443X GP devices- SMP bit isn't accessible.
* OMAP446X GP devices - SMP bit access is enabled on both CPUs.
*/
if (soc_is_omap443x() && (omap_type() != OMAP2_DEVICE_TYPE_GP))
omap_secure_dispatcher(OMAP4_PPA_CPU_ACTRL_SMP_INDEX,
4, 0, 0, 0, 0, 0);
if (soc_is_omap54xx() || soc_is_dra7xx()) {
/*
* Configure the CNTFRQ register for the secondary cpu's which
* indicates the frequency of the cpu local timers.
*/
set_cntfreq();
/* Configure ACR to disable streaming WA for 801819 */
omap5_erratum_workaround_801819();
}
/*
* Synchronise with the boot thread.
*/
spin_lock(&boot_lock);
spin_unlock(&boot_lock);
}
static int omap4_boot_secondary(unsigned int cpu, struct task_struct *idle)
{
static struct clockdomain *cpu1_clkdm;
static bool booted;
static struct powerdomain *cpu1_pwrdm;
void __iomem *base = omap_get_wakeupgen_base();
/*
* Set synchronisation state between this boot processor
* and the secondary one
*/
spin_lock(&boot_lock);
/*
* Update the AuxCoreBoot0 with boot state for secondary core.
* omap4_secondary_startup() routine will hold the secondary core till
* the AuxCoreBoot1 register is updated with cpu state
* A barrier is added to ensure that write buffer is drained
*/
if (omap_secure_apis_support())
omap_modify_auxcoreboot0(0x200, 0xfffffdff);
else
writel_relaxed(0x20, base + OMAP_AUX_CORE_BOOT_0);
if (!cpu1_clkdm && !cpu1_pwrdm) {
cpu1_clkdm = clkdm_lookup("mpu1_clkdm");
cpu1_pwrdm = pwrdm_lookup("cpu1_pwrdm");
}
/*
* The SGI(Software Generated Interrupts) are not wakeup capable
* from low power states. This is known limitation on OMAP4 and
* needs to be worked around by using software forced clockdomain
* wake-up. To wakeup CPU1, CPU0 forces the CPU1 clockdomain to
* software force wakeup. The clockdomain is then put back to
* hardware supervised mode.
* More details can be found in OMAP4430 TRM - Version J
* Section :
* 4.3.4.2 Power States of CPU0 and CPU1
*/
if (booted && cpu1_pwrdm && cpu1_clkdm) {
/*
* GIC distributor control register has changed between
* CortexA9 r1pX and r2pX. The Control Register secure
* banked version is now composed of 2 bits:
* bit 0 == Secure Enable
* bit 1 == Non-Secure Enable
* The Non-Secure banked register has not changed
* Because the ROM Code is based on the r1pX GIC, the CPU1
* GIC restoration will cause a problem to CPU0 Non-Secure SW.
* The workaround must be:
* 1) Before doing the CPU1 wakeup, CPU0 must disable
* the GIC distributor
* 2) CPU1 must re-enable the GIC distributor on
* it's wakeup path.
*/
if (IS_PM44XX_ERRATUM(PM_OMAP4_ROM_SMP_BOOT_ERRATUM_GICD)) {
local_irq_disable();
gic_dist_disable();
}
/*
* Ensure that CPU power state is set to ON to avoid CPU
* powerdomain transition on wfi
*/
clkdm_deny_idle_nolock(cpu1_clkdm);
pwrdm_set_next_pwrst(cpu1_pwrdm, PWRDM_POWER_ON);
clkdm_allow_idle_nolock(cpu1_clkdm);
if (IS_PM44XX_ERRATUM(PM_OMAP4_ROM_SMP_BOOT_ERRATUM_GICD)) {
while (gic_dist_disabled()) {
udelay(1);
cpu_relax();
}
gic_timer_retrigger();
local_irq_enable();
}
} else {
dsb_sev();
booted = true;
}
arch_send_wakeup_ipi_mask(cpumask_of(cpu));
/*
* Now the secondary core is starting up let it run its
* calibrations, then wait for it to finish
*/
spin_unlock(&boot_lock);
return 0;
}
/*
* Initialise the CPU possible map early - this describes the CPUs
* which may be present or become present in the system.
*/
static void __init omap4_smp_init_cpus(void)
{
unsigned int i = 0, ncores = 1, cpu_id;
/* Use ARM cpuid check here, as SoC detection will not work so early */
cpu_id = read_cpuid_id() & CPU_MASK;
if (cpu_id == CPU_CORTEX_A9) {
/*
* Currently we can't call ioremap here because
* SoC detection won't work until after init_early.
*/
cfg.scu_base = OMAP2_L4_IO_ADDRESS(scu_a9_get_base());
BUG_ON(!cfg.scu_base);
ncores = scu_get_core_count(cfg.scu_base);
} else if (cpu_id == CPU_CORTEX_A15) {
ncores = OMAP5_CORE_COUNT;
}
/* sanity check */
if (ncores > nr_cpu_ids) {
pr_warn("SMP: %u cores greater than maximum (%u), clipping\n",
ncores, nr_cpu_ids);
ncores = nr_cpu_ids;
}
for (i = 0; i < ncores; i++)
set_cpu_possible(i, true);
}
static void __init omap4_smp_prepare_cpus(unsigned int max_cpus)
{
void __iomem *base = omap_get_wakeupgen_base();
const struct omap_smp_config *c = NULL;
if (soc_is_omap443x())
c = &omap443x_cfg;
else if (soc_is_omap446x())
c = &omap446x_cfg;
else if (soc_is_dra74x() || soc_is_omap54xx())
c = &omap5_cfg;
if (!c) {
pr_err("%s Unknown SMP SoC?\n", __func__);
return;
}
/* Must preserve cfg.scu_base set earlier */
cfg.cpu1_rstctrl_pa = c->cpu1_rstctrl_pa;
cfg.startup_addr = c->startup_addr;
if (soc_is_dra74x() || soc_is_omap54xx()) {
if ((__boot_cpu_mode & MODE_MASK) == HYP_MODE)
cfg.startup_addr = omap5_secondary_hyp_startup;
omap5_erratum_workaround_801819();
}
cfg.cpu1_rstctrl_va = ioremap(cfg.cpu1_rstctrl_pa, 4);
if (!cfg.cpu1_rstctrl_va)
return;
/*
* Initialise the SCU and wake up the secondary core using
* wakeup_secondary().
*/
if (cfg.scu_base)
scu_enable(cfg.scu_base);
/*
* Reset CPU1 before configuring, otherwise kexec will
* end up trying to use old kernel startup address.
*/
if (cfg.cpu1_rstctrl_va) {
writel_relaxed(1, cfg.cpu1_rstctrl_va);
readl_relaxed(cfg.cpu1_rstctrl_va);
writel_relaxed(0, cfg.cpu1_rstctrl_va);
}
/*
* Write the address of secondary startup routine into the
* AuxCoreBoot1 where ROM code will jump and start executing
* on secondary core once out of WFE
* A barrier is added to ensure that write buffer is drained
*/
if (omap_secure_apis_support())
omap_auxcoreboot_addr(virt_to_phys(cfg.startup_addr));
else
writel_relaxed(virt_to_phys(cfg.startup_addr),
base + OMAP_AUX_CORE_BOOT_1);
}
const struct smp_operations omap4_smp_ops __initconst = {
.smp_init_cpus = omap4_smp_init_cpus,
.smp_prepare_cpus = omap4_smp_prepare_cpus,
.smp_secondary_init = omap4_secondary_init,
.smp_boot_secondary = omap4_boot_secondary,
#ifdef CONFIG_HOTPLUG_CPU
.cpu_die = omap4_cpu_die,
.cpu_kill = omap4_cpu_kill,
#endif
};