blob: 5b5a44f50b0b14992eff31a425e3193ea1c1f391 [file] [log] [blame]
/*
* Copyright (C) 2010, 2011, 2012, Lemote, Inc.
* Author: Chen Huacai, chenhc@lemote.com
*
* 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 program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
*/
#include <linux/init.h>
#include <linux/cpu.h>
#include <linux/sched.h>
#include <linux/sched/hotplug.h>
#include <linux/sched/task_stack.h>
#include <linux/smp.h>
#include <linux/cpufreq.h>
#include <asm/processor.h>
#include <asm/time.h>
#include <asm/clock.h>
#include <asm/tlbflush.h>
#include <asm/cacheflush.h>
#include <loongson.h>
#include <workarounds.h>
#include "smp.h"
DEFINE_PER_CPU(int, cpu_state);
static void *ipi_set0_regs[16];
static void *ipi_clear0_regs[16];
static void *ipi_status0_regs[16];
static void *ipi_en0_regs[16];
static void *ipi_mailbox_buf[16];
static uint32_t core0_c0count[NR_CPUS];
/* read a 32bit value from ipi register */
#define loongson3_ipi_read32(addr) readl(addr)
/* read a 64bit value from ipi register */
#define loongson3_ipi_read64(addr) readq(addr)
/* write a 32bit value to ipi register */
#define loongson3_ipi_write32(action, addr) \
do { \
writel(action, addr); \
__wbflush(); \
} while (0)
/* write a 64bit value to ipi register */
#define loongson3_ipi_write64(action, addr) \
do { \
writeq(action, addr); \
__wbflush(); \
} while (0)
static void ipi_set0_regs_init(void)
{
ipi_set0_regs[0] = (void *)
(SMP_CORE_GROUP0_BASE + SMP_CORE0_OFFSET + SET0);
ipi_set0_regs[1] = (void *)
(SMP_CORE_GROUP0_BASE + SMP_CORE1_OFFSET + SET0);
ipi_set0_regs[2] = (void *)
(SMP_CORE_GROUP0_BASE + SMP_CORE2_OFFSET + SET0);
ipi_set0_regs[3] = (void *)
(SMP_CORE_GROUP0_BASE + SMP_CORE3_OFFSET + SET0);
ipi_set0_regs[4] = (void *)
(SMP_CORE_GROUP1_BASE + SMP_CORE0_OFFSET + SET0);
ipi_set0_regs[5] = (void *)
(SMP_CORE_GROUP1_BASE + SMP_CORE1_OFFSET + SET0);
ipi_set0_regs[6] = (void *)
(SMP_CORE_GROUP1_BASE + SMP_CORE2_OFFSET + SET0);
ipi_set0_regs[7] = (void *)
(SMP_CORE_GROUP1_BASE + SMP_CORE3_OFFSET + SET0);
ipi_set0_regs[8] = (void *)
(SMP_CORE_GROUP2_BASE + SMP_CORE0_OFFSET + SET0);
ipi_set0_regs[9] = (void *)
(SMP_CORE_GROUP2_BASE + SMP_CORE1_OFFSET + SET0);
ipi_set0_regs[10] = (void *)
(SMP_CORE_GROUP2_BASE + SMP_CORE2_OFFSET + SET0);
ipi_set0_regs[11] = (void *)
(SMP_CORE_GROUP2_BASE + SMP_CORE3_OFFSET + SET0);
ipi_set0_regs[12] = (void *)
(SMP_CORE_GROUP3_BASE + SMP_CORE0_OFFSET + SET0);
ipi_set0_regs[13] = (void *)
(SMP_CORE_GROUP3_BASE + SMP_CORE1_OFFSET + SET0);
ipi_set0_regs[14] = (void *)
(SMP_CORE_GROUP3_BASE + SMP_CORE2_OFFSET + SET0);
ipi_set0_regs[15] = (void *)
(SMP_CORE_GROUP3_BASE + SMP_CORE3_OFFSET + SET0);
}
static void ipi_clear0_regs_init(void)
{
ipi_clear0_regs[0] = (void *)
(SMP_CORE_GROUP0_BASE + SMP_CORE0_OFFSET + CLEAR0);
ipi_clear0_regs[1] = (void *)
(SMP_CORE_GROUP0_BASE + SMP_CORE1_OFFSET + CLEAR0);
ipi_clear0_regs[2] = (void *)
(SMP_CORE_GROUP0_BASE + SMP_CORE2_OFFSET + CLEAR0);
ipi_clear0_regs[3] = (void *)
(SMP_CORE_GROUP0_BASE + SMP_CORE3_OFFSET + CLEAR0);
ipi_clear0_regs[4] = (void *)
(SMP_CORE_GROUP1_BASE + SMP_CORE0_OFFSET + CLEAR0);
ipi_clear0_regs[5] = (void *)
(SMP_CORE_GROUP1_BASE + SMP_CORE1_OFFSET + CLEAR0);
ipi_clear0_regs[6] = (void *)
(SMP_CORE_GROUP1_BASE + SMP_CORE2_OFFSET + CLEAR0);
ipi_clear0_regs[7] = (void *)
(SMP_CORE_GROUP1_BASE + SMP_CORE3_OFFSET + CLEAR0);
ipi_clear0_regs[8] = (void *)
(SMP_CORE_GROUP2_BASE + SMP_CORE0_OFFSET + CLEAR0);
ipi_clear0_regs[9] = (void *)
(SMP_CORE_GROUP2_BASE + SMP_CORE1_OFFSET + CLEAR0);
ipi_clear0_regs[10] = (void *)
(SMP_CORE_GROUP2_BASE + SMP_CORE2_OFFSET + CLEAR0);
ipi_clear0_regs[11] = (void *)
(SMP_CORE_GROUP2_BASE + SMP_CORE3_OFFSET + CLEAR0);
ipi_clear0_regs[12] = (void *)
(SMP_CORE_GROUP3_BASE + SMP_CORE0_OFFSET + CLEAR0);
ipi_clear0_regs[13] = (void *)
(SMP_CORE_GROUP3_BASE + SMP_CORE1_OFFSET + CLEAR0);
ipi_clear0_regs[14] = (void *)
(SMP_CORE_GROUP3_BASE + SMP_CORE2_OFFSET + CLEAR0);
ipi_clear0_regs[15] = (void *)
(SMP_CORE_GROUP3_BASE + SMP_CORE3_OFFSET + CLEAR0);
}
static void ipi_status0_regs_init(void)
{
ipi_status0_regs[0] = (void *)
(SMP_CORE_GROUP0_BASE + SMP_CORE0_OFFSET + STATUS0);
ipi_status0_regs[1] = (void *)
(SMP_CORE_GROUP0_BASE + SMP_CORE1_OFFSET + STATUS0);
ipi_status0_regs[2] = (void *)
(SMP_CORE_GROUP0_BASE + SMP_CORE2_OFFSET + STATUS0);
ipi_status0_regs[3] = (void *)
(SMP_CORE_GROUP0_BASE + SMP_CORE3_OFFSET + STATUS0);
ipi_status0_regs[4] = (void *)
(SMP_CORE_GROUP1_BASE + SMP_CORE0_OFFSET + STATUS0);
ipi_status0_regs[5] = (void *)
(SMP_CORE_GROUP1_BASE + SMP_CORE1_OFFSET + STATUS0);
ipi_status0_regs[6] = (void *)
(SMP_CORE_GROUP1_BASE + SMP_CORE2_OFFSET + STATUS0);
ipi_status0_regs[7] = (void *)
(SMP_CORE_GROUP1_BASE + SMP_CORE3_OFFSET + STATUS0);
ipi_status0_regs[8] = (void *)
(SMP_CORE_GROUP2_BASE + SMP_CORE0_OFFSET + STATUS0);
ipi_status0_regs[9] = (void *)
(SMP_CORE_GROUP2_BASE + SMP_CORE1_OFFSET + STATUS0);
ipi_status0_regs[10] = (void *)
(SMP_CORE_GROUP2_BASE + SMP_CORE2_OFFSET + STATUS0);
ipi_status0_regs[11] = (void *)
(SMP_CORE_GROUP2_BASE + SMP_CORE3_OFFSET + STATUS0);
ipi_status0_regs[12] = (void *)
(SMP_CORE_GROUP3_BASE + SMP_CORE0_OFFSET + STATUS0);
ipi_status0_regs[13] = (void *)
(SMP_CORE_GROUP3_BASE + SMP_CORE1_OFFSET + STATUS0);
ipi_status0_regs[14] = (void *)
(SMP_CORE_GROUP3_BASE + SMP_CORE2_OFFSET + STATUS0);
ipi_status0_regs[15] = (void *)
(SMP_CORE_GROUP3_BASE + SMP_CORE3_OFFSET + STATUS0);
}
static void ipi_en0_regs_init(void)
{
ipi_en0_regs[0] = (void *)
(SMP_CORE_GROUP0_BASE + SMP_CORE0_OFFSET + EN0);
ipi_en0_regs[1] = (void *)
(SMP_CORE_GROUP0_BASE + SMP_CORE1_OFFSET + EN0);
ipi_en0_regs[2] = (void *)
(SMP_CORE_GROUP0_BASE + SMP_CORE2_OFFSET + EN0);
ipi_en0_regs[3] = (void *)
(SMP_CORE_GROUP0_BASE + SMP_CORE3_OFFSET + EN0);
ipi_en0_regs[4] = (void *)
(SMP_CORE_GROUP1_BASE + SMP_CORE0_OFFSET + EN0);
ipi_en0_regs[5] = (void *)
(SMP_CORE_GROUP1_BASE + SMP_CORE1_OFFSET + EN0);
ipi_en0_regs[6] = (void *)
(SMP_CORE_GROUP1_BASE + SMP_CORE2_OFFSET + EN0);
ipi_en0_regs[7] = (void *)
(SMP_CORE_GROUP1_BASE + SMP_CORE3_OFFSET + EN0);
ipi_en0_regs[8] = (void *)
(SMP_CORE_GROUP2_BASE + SMP_CORE0_OFFSET + EN0);
ipi_en0_regs[9] = (void *)
(SMP_CORE_GROUP2_BASE + SMP_CORE1_OFFSET + EN0);
ipi_en0_regs[10] = (void *)
(SMP_CORE_GROUP2_BASE + SMP_CORE2_OFFSET + EN0);
ipi_en0_regs[11] = (void *)
(SMP_CORE_GROUP2_BASE + SMP_CORE3_OFFSET + EN0);
ipi_en0_regs[12] = (void *)
(SMP_CORE_GROUP3_BASE + SMP_CORE0_OFFSET + EN0);
ipi_en0_regs[13] = (void *)
(SMP_CORE_GROUP3_BASE + SMP_CORE1_OFFSET + EN0);
ipi_en0_regs[14] = (void *)
(SMP_CORE_GROUP3_BASE + SMP_CORE2_OFFSET + EN0);
ipi_en0_regs[15] = (void *)
(SMP_CORE_GROUP3_BASE + SMP_CORE3_OFFSET + EN0);
}
static void ipi_mailbox_buf_init(void)
{
ipi_mailbox_buf[0] = (void *)
(SMP_CORE_GROUP0_BASE + SMP_CORE0_OFFSET + BUF);
ipi_mailbox_buf[1] = (void *)
(SMP_CORE_GROUP0_BASE + SMP_CORE1_OFFSET + BUF);
ipi_mailbox_buf[2] = (void *)
(SMP_CORE_GROUP0_BASE + SMP_CORE2_OFFSET + BUF);
ipi_mailbox_buf[3] = (void *)
(SMP_CORE_GROUP0_BASE + SMP_CORE3_OFFSET + BUF);
ipi_mailbox_buf[4] = (void *)
(SMP_CORE_GROUP1_BASE + SMP_CORE0_OFFSET + BUF);
ipi_mailbox_buf[5] = (void *)
(SMP_CORE_GROUP1_BASE + SMP_CORE1_OFFSET + BUF);
ipi_mailbox_buf[6] = (void *)
(SMP_CORE_GROUP1_BASE + SMP_CORE2_OFFSET + BUF);
ipi_mailbox_buf[7] = (void *)
(SMP_CORE_GROUP1_BASE + SMP_CORE3_OFFSET + BUF);
ipi_mailbox_buf[8] = (void *)
(SMP_CORE_GROUP2_BASE + SMP_CORE0_OFFSET + BUF);
ipi_mailbox_buf[9] = (void *)
(SMP_CORE_GROUP2_BASE + SMP_CORE1_OFFSET + BUF);
ipi_mailbox_buf[10] = (void *)
(SMP_CORE_GROUP2_BASE + SMP_CORE2_OFFSET + BUF);
ipi_mailbox_buf[11] = (void *)
(SMP_CORE_GROUP2_BASE + SMP_CORE3_OFFSET + BUF);
ipi_mailbox_buf[12] = (void *)
(SMP_CORE_GROUP3_BASE + SMP_CORE0_OFFSET + BUF);
ipi_mailbox_buf[13] = (void *)
(SMP_CORE_GROUP3_BASE + SMP_CORE1_OFFSET + BUF);
ipi_mailbox_buf[14] = (void *)
(SMP_CORE_GROUP3_BASE + SMP_CORE2_OFFSET + BUF);
ipi_mailbox_buf[15] = (void *)
(SMP_CORE_GROUP3_BASE + SMP_CORE3_OFFSET + BUF);
}
/*
* Simple enough, just poke the appropriate ipi register
*/
static void loongson3_send_ipi_single(int cpu, unsigned int action)
{
loongson3_ipi_write32((u32)action, ipi_set0_regs[cpu_logical_map(cpu)]);
}
static void
loongson3_send_ipi_mask(const struct cpumask *mask, unsigned int action)
{
unsigned int i;
for_each_cpu(i, mask)
loongson3_ipi_write32((u32)action, ipi_set0_regs[cpu_logical_map(i)]);
}
#define IPI_IRQ_OFFSET 6
void loongson3_send_irq_by_ipi(int cpu, int irqs)
{
loongson3_ipi_write32(irqs << IPI_IRQ_OFFSET, ipi_set0_regs[cpu_logical_map(cpu)]);
}
void loongson3_ipi_interrupt(struct pt_regs *regs)
{
int i, cpu = smp_processor_id();
unsigned int action, c0count, irqs;
/* Load the ipi register to figure out what we're supposed to do */
action = loongson3_ipi_read32(ipi_status0_regs[cpu_logical_map(cpu)]);
irqs = action >> IPI_IRQ_OFFSET;
/* Clear the ipi register to clear the interrupt */
loongson3_ipi_write32((u32)action, ipi_clear0_regs[cpu_logical_map(cpu)]);
if (action & SMP_RESCHEDULE_YOURSELF)
scheduler_ipi();
if (action & SMP_CALL_FUNCTION) {
irq_enter();
generic_smp_call_function_interrupt();
irq_exit();
}
if (action & SMP_ASK_C0COUNT) {
BUG_ON(cpu != 0);
c0count = read_c0_count();
c0count = c0count ? c0count : 1;
for (i = 1; i < nr_cpu_ids; i++)
core0_c0count[i] = c0count;
__wbflush(); /* Let others see the result ASAP */
}
if (irqs) {
int irq;
while ((irq = ffs(irqs))) {
do_IRQ(irq-1);
irqs &= ~(1<<(irq-1));
}
}
}
#define MAX_LOOPS 800
/*
* SMP init and finish on secondary CPUs
*/
static void loongson3_init_secondary(void)
{
int i;
uint32_t initcount;
unsigned int cpu = smp_processor_id();
unsigned int imask = STATUSF_IP7 | STATUSF_IP6 |
STATUSF_IP3 | STATUSF_IP2;
/* Set interrupt mask, but don't enable */
change_c0_status(ST0_IM, imask);
for (i = 0; i < num_possible_cpus(); i++)
loongson3_ipi_write32(0xffffffff, ipi_en0_regs[cpu_logical_map(i)]);
per_cpu(cpu_state, cpu) = CPU_ONLINE;
cpu_data[cpu].core =
cpu_logical_map(cpu) % loongson_sysconf.cores_per_package;
cpu_data[cpu].package =
cpu_logical_map(cpu) / loongson_sysconf.cores_per_package;
i = 0;
core0_c0count[cpu] = 0;
loongson3_send_ipi_single(0, SMP_ASK_C0COUNT);
while (!core0_c0count[cpu]) {
i++;
cpu_relax();
}
if (i > MAX_LOOPS)
i = MAX_LOOPS;
if (cpu_data[cpu].package)
initcount = core0_c0count[cpu] + i;
else /* Local access is faster for loops */
initcount = core0_c0count[cpu] + i/2;
write_c0_count(initcount);
}
static void loongson3_smp_finish(void)
{
int cpu = smp_processor_id();
write_c0_compare(read_c0_count() + mips_hpt_frequency/HZ);
local_irq_enable();
loongson3_ipi_write64(0,
(void *)(ipi_mailbox_buf[cpu_logical_map(cpu)]+0x0));
pr_info("CPU#%d finished, CP0_ST=%x\n",
smp_processor_id(), read_c0_status());
}
static void __init loongson3_smp_setup(void)
{
int i = 0, num = 0; /* i: physical id, num: logical id */
init_cpu_possible(cpu_none_mask);
/* For unified kernel, NR_CPUS is the maximum possible value,
* loongson_sysconf.nr_cpus is the really present value */
while (i < loongson_sysconf.nr_cpus) {
if (loongson_sysconf.reserved_cpus_mask & (1<<i)) {
/* Reserved physical CPU cores */
__cpu_number_map[i] = -1;
} else {
__cpu_number_map[i] = num;
__cpu_logical_map[num] = i;
set_cpu_possible(num, true);
num++;
}
i++;
}
pr_info("Detected %i available CPU(s)\n", num);
while (num < loongson_sysconf.nr_cpus) {
__cpu_logical_map[num] = -1;
num++;
}
ipi_set0_regs_init();
ipi_clear0_regs_init();
ipi_status0_regs_init();
ipi_en0_regs_init();
ipi_mailbox_buf_init();
cpu_data[0].core = cpu_logical_map(0) % loongson_sysconf.cores_per_package;
cpu_data[0].package = cpu_logical_map(0) / loongson_sysconf.cores_per_package;
}
static void __init loongson3_prepare_cpus(unsigned int max_cpus)
{
init_cpu_present(cpu_possible_mask);
per_cpu(cpu_state, smp_processor_id()) = CPU_ONLINE;
}
/*
* Setup the PC, SP, and GP of a secondary processor and start it runing!
*/
static void loongson3_boot_secondary(int cpu, struct task_struct *idle)
{
unsigned long startargs[4];
pr_info("Booting CPU#%d...\n", cpu);
/* startargs[] are initial PC, SP and GP for secondary CPU */
startargs[0] = (unsigned long)&smp_bootstrap;
startargs[1] = (unsigned long)__KSTK_TOS(idle);
startargs[2] = (unsigned long)task_thread_info(idle);
startargs[3] = 0;
pr_debug("CPU#%d, func_pc=%lx, sp=%lx, gp=%lx\n",
cpu, startargs[0], startargs[1], startargs[2]);
loongson3_ipi_write64(startargs[3],
(void *)(ipi_mailbox_buf[cpu_logical_map(cpu)]+0x18));
loongson3_ipi_write64(startargs[2],
(void *)(ipi_mailbox_buf[cpu_logical_map(cpu)]+0x10));
loongson3_ipi_write64(startargs[1],
(void *)(ipi_mailbox_buf[cpu_logical_map(cpu)]+0x8));
loongson3_ipi_write64(startargs[0],
(void *)(ipi_mailbox_buf[cpu_logical_map(cpu)]+0x0));
}
#ifdef CONFIG_HOTPLUG_CPU
static int loongson3_cpu_disable(void)
{
unsigned long flags;
unsigned int cpu = smp_processor_id();
if (cpu == 0)
return -EBUSY;
set_cpu_online(cpu, false);
calculate_cpu_foreign_map();
local_irq_save(flags);
fixup_irqs();
local_irq_restore(flags);
local_flush_tlb_all();
return 0;
}
static void loongson3_cpu_die(unsigned int cpu)
{
while (per_cpu(cpu_state, cpu) != CPU_DEAD)
cpu_relax();
mb();
}
/* To shutdown a core in Loongson 3, the target core should go to CKSEG1 and
* flush all L1 entries at first. Then, another core (usually Core 0) can
* safely disable the clock of the target core. loongson3_play_dead() is
* called via CKSEG1 (uncached and unmmaped) */
static void loongson3a_r1_play_dead(int *state_addr)
{
register int val;
register long cpuid, core, node, count;
register void *addr, *base, *initfunc;
__asm__ __volatile__(
" .set push \n"
" .set noreorder \n"
" li %[addr], 0x80000000 \n" /* KSEG0 */
"1: cache 0, 0(%[addr]) \n" /* flush L1 ICache */
" cache 0, 1(%[addr]) \n"
" cache 0, 2(%[addr]) \n"
" cache 0, 3(%[addr]) \n"
" cache 1, 0(%[addr]) \n" /* flush L1 DCache */
" cache 1, 1(%[addr]) \n"
" cache 1, 2(%[addr]) \n"
" cache 1, 3(%[addr]) \n"
" addiu %[sets], %[sets], -1 \n"
" bnez %[sets], 1b \n"
" addiu %[addr], %[addr], 0x20 \n"
" li %[val], 0x7 \n" /* *state_addr = CPU_DEAD; */
" sw %[val], (%[state_addr]) \n"
" sync \n"
" cache 21, (%[state_addr]) \n" /* flush entry of *state_addr */
" .set pop \n"
: [addr] "=&r" (addr), [val] "=&r" (val)
: [state_addr] "r" (state_addr),
[sets] "r" (cpu_data[smp_processor_id()].dcache.sets));
__asm__ __volatile__(
" .set push \n"
" .set noreorder \n"
" .set mips64 \n"
" mfc0 %[cpuid], $15, 1 \n"
" andi %[cpuid], 0x3ff \n"
" dli %[base], 0x900000003ff01000 \n"
" andi %[core], %[cpuid], 0x3 \n"
" sll %[core], 8 \n" /* get core id */
" or %[base], %[base], %[core] \n"
" andi %[node], %[cpuid], 0xc \n"
" dsll %[node], 42 \n" /* get node id */
" or %[base], %[base], %[node] \n"
"1: li %[count], 0x100 \n" /* wait for init loop */
"2: bnez %[count], 2b \n" /* limit mailbox access */
" addiu %[count], -1 \n"
" ld %[initfunc], 0x20(%[base]) \n" /* get PC via mailbox */
" beqz %[initfunc], 1b \n"
" nop \n"
" ld $sp, 0x28(%[base]) \n" /* get SP via mailbox */
" ld $gp, 0x30(%[base]) \n" /* get GP via mailbox */
" ld $a1, 0x38(%[base]) \n"
" jr %[initfunc] \n" /* jump to initial PC */
" nop \n"
" .set pop \n"
: [core] "=&r" (core), [node] "=&r" (node),
[base] "=&r" (base), [cpuid] "=&r" (cpuid),
[count] "=&r" (count), [initfunc] "=&r" (initfunc)
: /* No Input */
: "a1");
}
static void loongson3a_r2r3_play_dead(int *state_addr)
{
register int val;
register long cpuid, core, node, count;
register void *addr, *base, *initfunc;
__asm__ __volatile__(
" .set push \n"
" .set noreorder \n"
" li %[addr], 0x80000000 \n" /* KSEG0 */
"1: cache 0, 0(%[addr]) \n" /* flush L1 ICache */
" cache 0, 1(%[addr]) \n"
" cache 0, 2(%[addr]) \n"
" cache 0, 3(%[addr]) \n"
" cache 1, 0(%[addr]) \n" /* flush L1 DCache */
" cache 1, 1(%[addr]) \n"
" cache 1, 2(%[addr]) \n"
" cache 1, 3(%[addr]) \n"
" addiu %[sets], %[sets], -1 \n"
" bnez %[sets], 1b \n"
" addiu %[addr], %[addr], 0x40 \n"
" li %[addr], 0x80000000 \n" /* KSEG0 */
"2: cache 2, 0(%[addr]) \n" /* flush L1 VCache */
" cache 2, 1(%[addr]) \n"
" cache 2, 2(%[addr]) \n"
" cache 2, 3(%[addr]) \n"
" cache 2, 4(%[addr]) \n"
" cache 2, 5(%[addr]) \n"
" cache 2, 6(%[addr]) \n"
" cache 2, 7(%[addr]) \n"
" cache 2, 8(%[addr]) \n"
" cache 2, 9(%[addr]) \n"
" cache 2, 10(%[addr]) \n"
" cache 2, 11(%[addr]) \n"
" cache 2, 12(%[addr]) \n"
" cache 2, 13(%[addr]) \n"
" cache 2, 14(%[addr]) \n"
" cache 2, 15(%[addr]) \n"
" addiu %[vsets], %[vsets], -1 \n"
" bnez %[vsets], 2b \n"
" addiu %[addr], %[addr], 0x40 \n"
" li %[val], 0x7 \n" /* *state_addr = CPU_DEAD; */
" sw %[val], (%[state_addr]) \n"
" sync \n"
" cache 21, (%[state_addr]) \n" /* flush entry of *state_addr */
" .set pop \n"
: [addr] "=&r" (addr), [val] "=&r" (val)
: [state_addr] "r" (state_addr),
[sets] "r" (cpu_data[smp_processor_id()].dcache.sets),
[vsets] "r" (cpu_data[smp_processor_id()].vcache.sets));
__asm__ __volatile__(
" .set push \n"
" .set noreorder \n"
" .set mips64 \n"
" mfc0 %[cpuid], $15, 1 \n"
" andi %[cpuid], 0x3ff \n"
" dli %[base], 0x900000003ff01000 \n"
" andi %[core], %[cpuid], 0x3 \n"
" sll %[core], 8 \n" /* get core id */
" or %[base], %[base], %[core] \n"
" andi %[node], %[cpuid], 0xc \n"
" dsll %[node], 42 \n" /* get node id */
" or %[base], %[base], %[node] \n"
"1: li %[count], 0x100 \n" /* wait for init loop */
"2: bnez %[count], 2b \n" /* limit mailbox access */
" addiu %[count], -1 \n"
" ld %[initfunc], 0x20(%[base]) \n" /* get PC via mailbox */
" beqz %[initfunc], 1b \n"
" nop \n"
" ld $sp, 0x28(%[base]) \n" /* get SP via mailbox */
" ld $gp, 0x30(%[base]) \n" /* get GP via mailbox */
" ld $a1, 0x38(%[base]) \n"
" jr %[initfunc] \n" /* jump to initial PC */
" nop \n"
" .set pop \n"
: [core] "=&r" (core), [node] "=&r" (node),
[base] "=&r" (base), [cpuid] "=&r" (cpuid),
[count] "=&r" (count), [initfunc] "=&r" (initfunc)
: /* No Input */
: "a1");
}
static void loongson3b_play_dead(int *state_addr)
{
register int val;
register long cpuid, core, node, count;
register void *addr, *base, *initfunc;
__asm__ __volatile__(
" .set push \n"
" .set noreorder \n"
" li %[addr], 0x80000000 \n" /* KSEG0 */
"1: cache 0, 0(%[addr]) \n" /* flush L1 ICache */
" cache 0, 1(%[addr]) \n"
" cache 0, 2(%[addr]) \n"
" cache 0, 3(%[addr]) \n"
" cache 1, 0(%[addr]) \n" /* flush L1 DCache */
" cache 1, 1(%[addr]) \n"
" cache 1, 2(%[addr]) \n"
" cache 1, 3(%[addr]) \n"
" addiu %[sets], %[sets], -1 \n"
" bnez %[sets], 1b \n"
" addiu %[addr], %[addr], 0x20 \n"
" li %[val], 0x7 \n" /* *state_addr = CPU_DEAD; */
" sw %[val], (%[state_addr]) \n"
" sync \n"
" cache 21, (%[state_addr]) \n" /* flush entry of *state_addr */
" .set pop \n"
: [addr] "=&r" (addr), [val] "=&r" (val)
: [state_addr] "r" (state_addr),
[sets] "r" (cpu_data[smp_processor_id()].dcache.sets));
__asm__ __volatile__(
" .set push \n"
" .set noreorder \n"
" .set mips64 \n"
" mfc0 %[cpuid], $15, 1 \n"
" andi %[cpuid], 0x3ff \n"
" dli %[base], 0x900000003ff01000 \n"
" andi %[core], %[cpuid], 0x3 \n"
" sll %[core], 8 \n" /* get core id */
" or %[base], %[base], %[core] \n"
" andi %[node], %[cpuid], 0xc \n"
" dsll %[node], 42 \n" /* get node id */
" or %[base], %[base], %[node] \n"
" dsrl %[node], 30 \n" /* 15:14 */
" or %[base], %[base], %[node] \n"
"1: li %[count], 0x100 \n" /* wait for init loop */
"2: bnez %[count], 2b \n" /* limit mailbox access */
" addiu %[count], -1 \n"
" ld %[initfunc], 0x20(%[base]) \n" /* get PC via mailbox */
" beqz %[initfunc], 1b \n"
" nop \n"
" ld $sp, 0x28(%[base]) \n" /* get SP via mailbox */
" ld $gp, 0x30(%[base]) \n" /* get GP via mailbox */
" ld $a1, 0x38(%[base]) \n"
" jr %[initfunc] \n" /* jump to initial PC */
" nop \n"
" .set pop \n"
: [core] "=&r" (core), [node] "=&r" (node),
[base] "=&r" (base), [cpuid] "=&r" (cpuid),
[count] "=&r" (count), [initfunc] "=&r" (initfunc)
: /* No Input */
: "a1");
}
void play_dead(void)
{
int *state_addr;
unsigned int cpu = smp_processor_id();
void (*play_dead_at_ckseg1)(int *);
idle_task_exit();
switch (read_c0_prid() & PRID_REV_MASK) {
case PRID_REV_LOONGSON3A_R1:
default:
play_dead_at_ckseg1 =
(void *)CKSEG1ADDR((unsigned long)loongson3a_r1_play_dead);
break;
case PRID_REV_LOONGSON3A_R2:
case PRID_REV_LOONGSON3A_R3:
play_dead_at_ckseg1 =
(void *)CKSEG1ADDR((unsigned long)loongson3a_r2r3_play_dead);
break;
case PRID_REV_LOONGSON3B_R1:
case PRID_REV_LOONGSON3B_R2:
play_dead_at_ckseg1 =
(void *)CKSEG1ADDR((unsigned long)loongson3b_play_dead);
break;
}
state_addr = &per_cpu(cpu_state, cpu);
mb();
play_dead_at_ckseg1(state_addr);
}
static int loongson3_disable_clock(unsigned int cpu)
{
uint64_t core_id = cpu_data[cpu].core;
uint64_t package_id = cpu_data[cpu].package;
if ((read_c0_prid() & PRID_REV_MASK) == PRID_REV_LOONGSON3A_R1) {
LOONGSON_CHIPCFG(package_id) &= ~(1 << (12 + core_id));
} else {
if (!(loongson_sysconf.workarounds & WORKAROUND_CPUHOTPLUG))
LOONGSON_FREQCTRL(package_id) &= ~(1 << (core_id * 4 + 3));
}
return 0;
}
static int loongson3_enable_clock(unsigned int cpu)
{
uint64_t core_id = cpu_data[cpu].core;
uint64_t package_id = cpu_data[cpu].package;
if ((read_c0_prid() & PRID_REV_MASK) == PRID_REV_LOONGSON3A_R1) {
LOONGSON_CHIPCFG(package_id) |= 1 << (12 + core_id);
} else {
if (!(loongson_sysconf.workarounds & WORKAROUND_CPUHOTPLUG))
LOONGSON_FREQCTRL(package_id) |= 1 << (core_id * 4 + 3);
}
return 0;
}
static int register_loongson3_notifier(void)
{
return cpuhp_setup_state_nocalls(CPUHP_MIPS_SOC_PREPARE,
"mips/loongson:prepare",
loongson3_enable_clock,
loongson3_disable_clock);
}
early_initcall(register_loongson3_notifier);
#endif
const struct plat_smp_ops loongson3_smp_ops = {
.send_ipi_single = loongson3_send_ipi_single,
.send_ipi_mask = loongson3_send_ipi_mask,
.init_secondary = loongson3_init_secondary,
.smp_finish = loongson3_smp_finish,
.boot_secondary = loongson3_boot_secondary,
.smp_setup = loongson3_smp_setup,
.prepare_cpus = loongson3_prepare_cpus,
#ifdef CONFIG_HOTPLUG_CPU
.cpu_disable = loongson3_cpu_disable,
.cpu_die = loongson3_cpu_die,
#endif
};