/**
* @file
*
* @ingroup riscv_interrupt
*
* @brief Interrupt support.
*/
/*
* Copyright (c) 2018 embedded brains GmbH
*
* Copyright (c) 2015 University of York.
* Hesham Almatary <hesham@alumni.york.ac.uk>
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``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 OR CONTRIBUTORS 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.
*/
#include <bsp/irq.h>
#include <bsp/fatal.h>
#include <bsp/fdt.h>
#include <bsp/irq-generic.h>
#include <bsp/riscv.h>
#include <rtems/score/percpu.h>
#include <rtems/score/riscv-utility.h>
#include <rtems/score/smpimpl.h>
#include <libfdt.h>
volatile RISCV_CLINT_regs *riscv_clint;
/*
* The lovely PLIC has an interrupt enable bit per hart for each interrupt
* source. This makes the interrupt enable/disable a bit difficult. We have
* to store the interrupt distribution in software. To keep it simple, we
* support only a one-to-one and one-to-all interrupt to processor
* distribution. For a one-to-one distribution, the array member must point to
* the enable register block of the corresponding. For a one-to-all
* distribution, the array member must be NULL. The array index is the
* external interrupt index minus one (external interrupt index zero is a
* special value, see PLIC documentation).
*/
static volatile uint32_t *
riscv_plic_irq_to_cpu[RISCV_MAXIMUM_EXTERNAL_INTERRUPTS];
RTEMS_INTERRUPT_LOCK_DEFINE(static, riscv_plic_lock, "PLIC")
void _RISCV_Interrupt_dispatch(uintptr_t mcause, Per_CPU_Control *cpu_self)
{
/*
* Get rid of the most significant bit which indicates if the exception was
* caused by an interrupt or not.
*/
mcause <<= 1;
if (mcause == (RISCV_INTERRUPT_TIMER_MACHINE << 1)) {
bsp_interrupt_handler_dispatch(RISCV_INTERRUPT_VECTOR_TIMER);
} else if (mcause == (RISCV_INTERRUPT_EXTERNAL_MACHINE << 1)) {
volatile RISCV_PLIC_hart_regs *plic_hart_regs;
uint32_t interrupt_index;
plic_hart_regs = cpu_self->cpu_per_cpu.plic_hart_regs;
while ((interrupt_index = plic_hart_regs->claim_complete) != 0) {
bsp_interrupt_handler_dispatch(
RISCV_INTERRUPT_VECTOR_EXTERNAL(interrupt_index)
);
plic_hart_regs->claim_complete = interrupt_index;
/*
* FIXME: It is not clear which fence is necessary here or if a fence is
* necessary at all. The goal is that the complete signal is somehow
* recognized by the PLIC before the next claim is issued.
*/
__asm__ volatile ("fence o, i" : : : "memory");
}
} else if (mcause == (RISCV_INTERRUPT_SOFTWARE_MACHINE << 1)) {
#ifdef RTEMS_SMP
/*
* Clear the software interrupt on this processor. Synchronization of
* inter-processor interrupts is done via Per_CPU_Control::message in
* _SMP_Inter_processor_interrupt_handler().
*/
*cpu_self->cpu_per_cpu.clint_msip = 0;
_SMP_Inter_processor_interrupt_handler(cpu_self);
#else
bsp_interrupt_handler_dispatch(RISCV_INTERRUPT_VECTOR_SOFTWARE);
#endif
} else {
bsp_fatal(RISCV_FATAL_UNEXPECTED_INTERRUPT_EXCEPTION);
}
}
static void riscv_clint_init(const void *fdt)
{
volatile RISCV_CLINT_regs *clint;
int node;
const uint32_t *val;
int len;
int i;
node = fdt_node_offset_by_compatible(fdt, -1, "riscv,clint0");
clint = riscv_fdt_get_address(fdt, node);
if (clint == NULL) {
bsp_fatal(RISCV_FATAL_NO_CLINT_REG_IN_DEVICE_TREE);
}
riscv_clint = clint;
val = fdt_getprop(fdt, node, "interrupts-extended", &len);
for (i = 0; i < len; i += 16) {
uint32_t hart_index;
Per_CPU_Control *cpu;
hart_index = riscv_get_hart_index_by_phandle(fdt32_to_cpu(val[i / 4]));
if (hart_index >= rtems_configuration_get_maximum_processors()) {
continue;
}
cpu = _Per_CPU_Get_by_index(hart_index);
cpu->cpu_per_cpu.clint_msip = &clint->msip[i / 16];
cpu->cpu_per_cpu.clint_mtimecmp = &clint->mtimecmp[i / 16];
}
}
static void riscv_plic_init(const void *fdt)
{
volatile RISCV_PLIC_regs *plic;
int node;
int i;
const uint32_t *val;
int len;
uint32_t interrupt_index;
uint32_t ndev;
Per_CPU_Control *cpu;
node = fdt_node_offset_by_compatible(fdt, -1, "riscv,plic0");
plic = riscv_fdt_get_address(fdt, node);
if (plic == NULL) {
#if RISCV_ENABLE_HTIF_SUPPORT != 0
/* Spike platform has HTIF and does not have a PLIC */
return;
#else
bsp_fatal(RISCV_FATAL_NO_PLIC_REG_IN_DEVICE_TREE);
#endif
}
val = fdt_getprop(fdt, node, "riscv,ndev", &len);
if (val == NULL || len != 4) {
bsp_fatal(RISCV_FATAL_INVALID_PLIC_NDEV_IN_DEVICE_TREE);
}
ndev = fdt32_to_cpu(val[0]);
if (ndev > RISCV_MAXIMUM_EXTERNAL_INTERRUPTS) {
bsp_fatal(RISCV_FATAL_TOO_LARGE_PLIC_NDEV_IN_DEVICE_TREE);
}
val = fdt_getprop(fdt, node, "interrupts-extended", &len);
for (i = 0; i < len; i += 8) {
uint32_t hart_index;
hart_index = riscv_get_hart_index_by_phandle(fdt32_to_cpu(val[i / 4]));
if (hart_index >= rtems_configuration_get_maximum_processors()) {
continue;
}
interrupt_index = fdt32_to_cpu(val[i / 4 + 1]);
if (interrupt_index != RISCV_INTERRUPT_EXTERNAL_MACHINE) {
continue;
}
plic->harts[i / 8].priority_threshold = 0;
cpu = _Per_CPU_Get_by_index(hart_index);
cpu->cpu_per_cpu.plic_hart_regs = &plic->harts[i / 8];
cpu->cpu_per_cpu.plic_m_ie = &plic->enable[i / 8][0];
}
cpu = _Per_CPU_Get_by_index(0);
for (interrupt_index = 1; interrupt_index <= ndev; ++interrupt_index) {
plic->priority[interrupt_index] = 1;
riscv_plic_irq_to_cpu[interrupt_index - 1] = cpu->cpu_per_cpu.plic_m_ie;
}
/*
* External M-mode interrupts on secondary processors are enabled in
* bsp_start_on_secondary_processor().
*/
set_csr(mie, MIP_MEIP);
}
rtems_status_code bsp_interrupt_facility_initialize(void)
{
const void *fdt;
fdt = bsp_fdt_get();
riscv_clint_init(fdt);
riscv_plic_init(fdt);
return RTEMS_SUCCESSFUL;
}
void bsp_interrupt_vector_enable(rtems_vector_number vector)
{
bsp_interrupt_assert(bsp_interrupt_is_valid_vector(vector));
if (RISCV_INTERRUPT_VECTOR_IS_EXTERNAL(vector)) {
uint32_t interrupt_index;
volatile uint32_t *enable;
uint32_t group;
uint32_t bit;
rtems_interrupt_lock_context lock_context;
interrupt_index = RISCV_INTERRUPT_VECTOR_EXTERNAL_TO_INDEX(vector);
enable = riscv_plic_irq_to_cpu[interrupt_index - 1];
group = interrupt_index / 32;
bit = UINT32_C(1) << (interrupt_index % 32);
rtems_interrupt_lock_acquire(&riscv_plic_lock, &lock_context);
if (enable != NULL) {
enable[group] |= bit;
} else {
uint32_t cpu_max;
uint32_t cpu_index;
cpu_max = _SMP_Get_processor_maximum();
for (cpu_index = 0; cpu_index < cpu_max; ++cpu_index) {
Per_CPU_Control *cpu;
cpu = _Per_CPU_Get_by_index(cpu_index);
enable = cpu->cpu_per_cpu.plic_m_ie;
if (enable != NULL) {
enable[group] |= bit;
}
}
}
rtems_interrupt_lock_release(&riscv_plic_lock, &lock_context);
}
}
void bsp_interrupt_vector_disable(rtems_vector_number vector)
{
bsp_interrupt_assert(bsp_interrupt_is_valid_vector(vector));
if (RISCV_INTERRUPT_VECTOR_IS_EXTERNAL(vector)) {
uint32_t interrupt_index;
volatile uint32_t *enable;
uint32_t group;
uint32_t bit;
rtems_interrupt_lock_context lock_context;
interrupt_index = RISCV_INTERRUPT_VECTOR_EXTERNAL_TO_INDEX(vector);
enable = riscv_plic_irq_to_cpu[interrupt_index - 1];
group = interrupt_index / 32;
bit = UINT32_C(1) << (interrupt_index % 32);
rtems_interrupt_lock_acquire(&riscv_plic_lock, &lock_context);
if (enable != NULL) {
enable[group] &= ~bit;
} else {
uint32_t cpu_max;
uint32_t cpu_index;
cpu_max = _SMP_Get_processor_maximum();
for (cpu_index = 0; cpu_index < cpu_max; ++cpu_index) {
Per_CPU_Control *cpu;
cpu = _Per_CPU_Get_by_index(cpu_index);
enable = cpu->cpu_per_cpu.plic_m_ie;
if (enable != NULL) {
enable[group] &= ~bit;
}
}
}
rtems_interrupt_lock_release(&riscv_plic_lock, &lock_context);
}
}
void bsp_interrupt_set_affinity(
rtems_vector_number vector,
const Processor_mask *affinity
)
{
if (RISCV_INTERRUPT_VECTOR_IS_EXTERNAL(vector)) {
uint32_t interrupt_index;
Processor_mask mask;
interrupt_index = RISCV_INTERRUPT_VECTOR_EXTERNAL_TO_INDEX(vector);
_Processor_mask_And(&mask, affinity, _SMP_Get_online_processors());
if (_Processor_mask_Is_equal(&mask, _SMP_Get_online_processors())) {
riscv_plic_irq_to_cpu[interrupt_index - 1] = NULL;
return;
}
if (_Processor_mask_Count(&mask) == 1) {
uint32_t cpu_index;
Per_CPU_Control *cpu;
cpu_index = _Processor_mask_Find_last_set(&mask) - 1;
cpu = _Per_CPU_Get_by_index(cpu_index);
riscv_plic_irq_to_cpu[interrupt_index - 1] = cpu->cpu_per_cpu.plic_m_ie;
return;
}
bsp_fatal(RISCV_FATAL_INVALID_INTERRUPT_AFFINITY);
}
}
void bsp_interrupt_get_affinity(
rtems_vector_number vector,
Processor_mask *affinity
)
{
_Processor_mask_Zero(affinity);
if (RISCV_INTERRUPT_VECTOR_IS_EXTERNAL(vector)) {
uint32_t interrupt_index;
volatile uint32_t *enable;
interrupt_index = RISCV_INTERRUPT_VECTOR_EXTERNAL_TO_INDEX(vector);
enable = riscv_plic_irq_to_cpu[interrupt_index - 1];
if (enable != NULL) {
uint32_t cpu_max;
uint32_t cpu_index;
cpu_max = _SMP_Get_processor_maximum();
for (cpu_index = 0; cpu_index < cpu_max; ++cpu_index) {
Per_CPU_Control *cpu;
cpu = _Per_CPU_Get_by_index(cpu_index);
if (enable == cpu->cpu_per_cpu.plic_m_ie) {
_Processor_mask_Set(affinity, cpu_index);
break;
}
}
} else {
_Processor_mask_Assign(affinity, _SMP_Get_online_processors());
}
}
}
