blob: 35be7baba444eba531fb7103e0cddfa93deb6aef [file] [log] [blame]
// SPDX-License-Identifier: BSD-2-Clause
/*
* fdt_helper.c - Flat Device Tree manipulation helper routines
* Implement helper routines on top of libfdt for OpenSBI usage
*
* Copyright (C) 2020 Bin Meng <bmeng.cn@gmail.com>
*/
#include <libfdt.h>
#include <sbi/riscv_asm.h>
#include <sbi/sbi_console.h>
#include <sbi/sbi_hartmask.h>
#include <sbi/sbi_platform.h>
#include <sbi/sbi_scratch.h>
#include <sbi/sbi_hart.h>
#include <sbi_utils/fdt/fdt_helper.h>
#include <sbi_utils/irqchip/aplic.h>
#include <sbi_utils/irqchip/imsic.h>
#include <sbi_utils/irqchip/plic.h>
#define DEFAULT_UART_FREQ 0
#define DEFAULT_UART_BAUD 115200
#define DEFAULT_UART_REG_SHIFT 0
#define DEFAULT_UART_REG_IO_WIDTH 1
#define DEFAULT_UART_REG_OFFSET 0
#define DEFAULT_RENESAS_SCIF_FREQ 100000000
#define DEFAULT_RENESAS_SCIF_BAUD 115200
#define DEFAULT_SIFIVE_UART_FREQ 0
#define DEFAULT_SIFIVE_UART_BAUD 115200
#define DEFAULT_SHAKTI_UART_FREQ 50000000
#define DEFAULT_SHAKTI_UART_BAUD 115200
const struct fdt_match *fdt_match_node(void *fdt, int nodeoff,
const struct fdt_match *match_table)
{
int ret;
if (!fdt || nodeoff < 0 || !match_table)
return NULL;
while (match_table->compatible) {
ret = fdt_node_check_compatible(fdt, nodeoff,
match_table->compatible);
if (!ret)
return match_table;
match_table++;
}
return NULL;
}
int fdt_find_match(void *fdt, int startoff,
const struct fdt_match *match_table,
const struct fdt_match **out_match)
{
int nodeoff;
if (!fdt || !match_table)
return SBI_ENODEV;
while (match_table->compatible) {
nodeoff = fdt_node_offset_by_compatible(fdt, startoff,
match_table->compatible);
if (nodeoff >= 0) {
if (out_match)
*out_match = match_table;
return nodeoff;
}
match_table++;
}
return SBI_ENODEV;
}
int fdt_parse_phandle_with_args(void *fdt, int nodeoff,
const char *prop, const char *cells_prop,
int index, struct fdt_phandle_args *out_args)
{
u32 i, pcells;
int len, pnodeoff;
const fdt32_t *list, *list_end, *val;
if (!fdt || (nodeoff < 0) || !prop || !cells_prop || !out_args)
return SBI_EINVAL;
list = fdt_getprop(fdt, nodeoff, prop, &len);
if (!list)
return SBI_ENOENT;
list_end = list + (len / sizeof(*list));
while (list < list_end) {
pnodeoff = fdt_node_offset_by_phandle(fdt,
fdt32_to_cpu(*list));
if (pnodeoff < 0)
return pnodeoff;
list++;
val = fdt_getprop(fdt, pnodeoff, cells_prop, &len);
if (!val)
return SBI_ENOENT;
pcells = fdt32_to_cpu(*val);
if (FDT_MAX_PHANDLE_ARGS < pcells)
return SBI_EINVAL;
if (list + pcells > list_end)
return SBI_ENOENT;
if (index > 0) {
list += pcells;
index--;
} else {
out_args->node_offset = pnodeoff;
out_args->args_count = pcells;
for (i = 0; i < pcells; i++)
out_args->args[i] = fdt32_to_cpu(list[i]);
return 0;
}
}
return SBI_ENOENT;
}
static int fdt_translate_address(void *fdt, uint64_t reg, int parent,
uint64_t *addr)
{
int i, rlen;
int cell_addr, cell_size;
const fdt32_t *ranges;
uint64_t offset, caddr = 0, paddr = 0, rsize = 0;
cell_addr = fdt_address_cells(fdt, parent);
if (cell_addr < 1)
return SBI_ENODEV;
cell_size = fdt_size_cells(fdt, parent);
if (cell_size < 0)
return SBI_ENODEV;
ranges = fdt_getprop(fdt, parent, "ranges", &rlen);
if (ranges && rlen > 0) {
for (i = 0; i < cell_addr; i++)
caddr = (caddr << 32) | fdt32_to_cpu(*ranges++);
for (i = 0; i < cell_addr; i++)
paddr = (paddr << 32) | fdt32_to_cpu(*ranges++);
for (i = 0; i < cell_size; i++)
rsize = (rsize << 32) | fdt32_to_cpu(*ranges++);
if (reg < caddr || caddr >= (reg + rsize )) {
sbi_printf("invalid address translation\n");
return SBI_ENODEV;
}
offset = reg - caddr;
*addr = paddr + offset;
} else {
/* No translation required */
*addr = reg;
}
return 0;
}
int fdt_get_node_addr_size(void *fdt, int node, int index,
uint64_t *addr, uint64_t *size)
{
int parent, len, i, rc;
int cell_addr, cell_size;
const fdt32_t *prop_addr, *prop_size;
uint64_t temp = 0;
if (!fdt || node < 0 || index < 0)
return SBI_EINVAL;
parent = fdt_parent_offset(fdt, node);
if (parent < 0)
return parent;
cell_addr = fdt_address_cells(fdt, parent);
if (cell_addr < 1)
return SBI_ENODEV;
cell_size = fdt_size_cells(fdt, parent);
if (cell_size < 0)
return SBI_ENODEV;
prop_addr = fdt_getprop(fdt, node, "reg", &len);
if (!prop_addr)
return SBI_ENODEV;
if ((len / sizeof(u32)) <= (index * (cell_addr + cell_size)))
return SBI_EINVAL;
prop_addr = prop_addr + (index * (cell_addr + cell_size));
prop_size = prop_addr + cell_addr;
if (addr) {
for (i = 0; i < cell_addr; i++)
temp = (temp << 32) | fdt32_to_cpu(*prop_addr++);
do {
if (parent < 0)
break;
rc = fdt_translate_address(fdt, temp, parent, addr);
if (rc)
break;
parent = fdt_parent_offset(fdt, parent);
temp = *addr;
} while (1);
}
temp = 0;
if (size) {
for (i = 0; i < cell_size; i++)
temp = (temp << 32) | fdt32_to_cpu(*prop_size++);
*size = temp;
}
return 0;
}
bool fdt_node_is_enabled(void *fdt, int nodeoff)
{
int len;
const void *prop;
prop = fdt_getprop(fdt, nodeoff, "status", &len);
if (!prop)
return true;
if (!strncmp(prop, "okay", strlen("okay")))
return true;
if (!strncmp(prop, "ok", strlen("ok")))
return true;
return false;
}
int fdt_parse_hart_id(void *fdt, int cpu_offset, u32 *hartid)
{
int len;
const void *prop;
const fdt32_t *val;
if (!fdt || cpu_offset < 0)
return SBI_EINVAL;
prop = fdt_getprop(fdt, cpu_offset, "device_type", &len);
if (!prop || !len)
return SBI_EINVAL;
if (strncmp (prop, "cpu", strlen ("cpu")))
return SBI_EINVAL;
val = fdt_getprop(fdt, cpu_offset, "reg", &len);
if (!val || len < sizeof(fdt32_t))
return SBI_EINVAL;
if (len > sizeof(fdt32_t))
val++;
if (hartid)
*hartid = fdt32_to_cpu(*val);
return 0;
}
int fdt_parse_max_enabled_hart_id(void *fdt, u32 *max_hartid)
{
u32 hartid;
int err, cpu_offset, cpus_offset;
if (!fdt)
return SBI_EINVAL;
if (!max_hartid)
return 0;
*max_hartid = 0;
cpus_offset = fdt_path_offset(fdt, "/cpus");
if (cpus_offset < 0)
return cpus_offset;
fdt_for_each_subnode(cpu_offset, fdt, cpus_offset) {
err = fdt_parse_hart_id(fdt, cpu_offset, &hartid);
if (err)
continue;
if (!fdt_node_is_enabled(fdt, cpu_offset))
continue;
if (hartid > *max_hartid)
*max_hartid = hartid;
}
return 0;
}
int fdt_parse_timebase_frequency(void *fdt, unsigned long *freq)
{
const fdt32_t *val;
int len, cpus_offset;
if (!fdt || !freq)
return SBI_EINVAL;
cpus_offset = fdt_path_offset(fdt, "/cpus");
if (cpus_offset < 0)
return cpus_offset;
val = fdt_getprop(fdt, cpus_offset, "timebase-frequency", &len);
if (len > 0 && val)
*freq = fdt32_to_cpu(*val);
else
return SBI_ENOENT;
return 0;
}
#define RISCV_ISA_EXT_NAME_LEN_MAX 32
static unsigned long fdt_isa_bitmap_offset;
static int fdt_parse_isa_one_hart(const char *isa, unsigned long *extensions)
{
size_t i, j, isa_len;
char mstr[RISCV_ISA_EXT_NAME_LEN_MAX];
i = 0;
isa_len = strlen(isa);
if (isa[i] == 'r' || isa[i] == 'R')
i++;
else
return SBI_EINVAL;
if (isa[i] == 'v' || isa[i] == 'V')
i++;
else
return SBI_EINVAL;
if (isa[i] == '3' || isa[i+1] == '2')
i += 2;
else if (isa[i] == '6' || isa[i+1] == '4')
i += 2;
else
return SBI_EINVAL;
/* Skip base ISA extensions */
for (; i < isa_len; i++) {
if (isa[i] == '_')
break;
}
while (i < isa_len) {
if (isa[i] != '_') {
i++;
continue;
}
/* Skip the '_' character */
i++;
/* Extract the multi-letter extension name */
j = 0;
while ((i < isa_len) && (isa[i] != '_') &&
(j < (sizeof(mstr) - 1)))
mstr[j++] = isa[i++];
mstr[j] = '\0';
/* Skip empty multi-letter extension name */
if (!j)
continue;
#define set_multi_letter_ext(name, bit) \
if (!strcmp(mstr, name)) { \
__set_bit(bit, extensions); \
continue; \
}
set_multi_letter_ext("smepmp", SBI_HART_EXT_SMEPMP);
set_multi_letter_ext("zkr", SBI_HART_EXT_ZKR);
#undef set_multi_letter_ext
}
return 0;
}
static int fdt_parse_isa_all_harts(void *fdt)
{
u32 hartid;
const fdt32_t *val;
unsigned long *hart_exts;
struct sbi_scratch *scratch;
int err, cpu_offset, cpus_offset, len;
if (!fdt || !fdt_isa_bitmap_offset)
return SBI_EINVAL;
cpus_offset = fdt_path_offset(fdt, "/cpus");
if (cpus_offset < 0)
return cpus_offset;
fdt_for_each_subnode(cpu_offset, fdt, cpus_offset) {
err = fdt_parse_hart_id(fdt, cpu_offset, &hartid);
if (err)
continue;
if (!fdt_node_is_enabled(fdt, cpu_offset))
continue;
val = fdt_getprop(fdt, cpu_offset, "riscv,isa", &len);
if (!val || len <= 0)
return SBI_ENOENT;
scratch = sbi_hartid_to_scratch(hartid);
if (!scratch)
return SBI_ENOENT;
hart_exts = sbi_scratch_offset_ptr(scratch,
fdt_isa_bitmap_offset);
err = fdt_parse_isa_one_hart((const char *)val, hart_exts);
if (err)
return err;
}
return 0;
}
int fdt_parse_isa_extensions(void *fdt, unsigned int hartid,
unsigned long *extensions)
{
int rc, i;
unsigned long *hart_exts;
struct sbi_scratch *scratch;
if (!fdt_isa_bitmap_offset) {
fdt_isa_bitmap_offset = sbi_scratch_alloc_offset(
sizeof(*hart_exts) *
BITS_TO_LONGS(SBI_HART_EXT_MAX));
if (!fdt_isa_bitmap_offset)
return SBI_ENOMEM;
rc = fdt_parse_isa_all_harts(fdt);
if (rc)
return rc;
}
scratch = sbi_hartid_to_scratch(hartid);
if (!scratch)
return SBI_ENOENT;
hart_exts = sbi_scratch_offset_ptr(scratch, fdt_isa_bitmap_offset);
for (i = 0; i < BITS_TO_LONGS(SBI_HART_EXT_MAX); i++)
extensions[i] |= hart_exts[i];
return 0;
}
static int fdt_parse_uart_node_common(void *fdt, int nodeoffset,
struct platform_uart_data *uart,
unsigned long default_freq,
unsigned long default_baud)
{
int len, rc;
const fdt32_t *val;
uint64_t reg_addr, reg_size;
if (nodeoffset < 0 || !uart || !fdt)
return SBI_ENODEV;
rc = fdt_get_node_addr_size(fdt, nodeoffset, 0,
&reg_addr, &reg_size);
if (rc < 0 || !reg_addr || !reg_size)
return SBI_ENODEV;
uart->addr = reg_addr;
/**
* UART address is mandatory. clock-frequency and current-speed
* may not be present. Don't return error.
*/
val = (fdt32_t *)fdt_getprop(fdt, nodeoffset, "clock-frequency", &len);
if (len > 0 && val)
uart->freq = fdt32_to_cpu(*val);
else
uart->freq = default_freq;
val = (fdt32_t *)fdt_getprop(fdt, nodeoffset, "current-speed", &len);
if (len > 0 && val)
uart->baud = fdt32_to_cpu(*val);
else
uart->baud = default_baud;
return 0;
}
int fdt_parse_gaisler_uart_node(void *fdt, int nodeoffset,
struct platform_uart_data *uart)
{
return fdt_parse_uart_node_common(fdt, nodeoffset, uart,
DEFAULT_UART_FREQ,
DEFAULT_UART_BAUD);
}
int fdt_parse_renesas_scif_node(void *fdt, int nodeoffset,
struct platform_uart_data *uart)
{
return fdt_parse_uart_node_common(fdt, nodeoffset, uart,
DEFAULT_RENESAS_SCIF_FREQ,
DEFAULT_RENESAS_SCIF_BAUD);
}
int fdt_parse_shakti_uart_node(void *fdt, int nodeoffset,
struct platform_uart_data *uart)
{
return fdt_parse_uart_node_common(fdt, nodeoffset, uart,
DEFAULT_SHAKTI_UART_FREQ,
DEFAULT_SHAKTI_UART_BAUD);
}
int fdt_parse_sifive_uart_node(void *fdt, int nodeoffset,
struct platform_uart_data *uart)
{
return fdt_parse_uart_node_common(fdt, nodeoffset, uart,
DEFAULT_SIFIVE_UART_FREQ,
DEFAULT_SIFIVE_UART_BAUD);
}
int fdt_parse_uart_node(void *fdt, int nodeoffset,
struct platform_uart_data *uart)
{
int len, rc;
const fdt32_t *val;
rc = fdt_parse_uart_node_common(fdt, nodeoffset, uart,
DEFAULT_UART_FREQ,
DEFAULT_UART_BAUD);
if (rc)
return rc;
val = (fdt32_t *)fdt_getprop(fdt, nodeoffset, "reg-shift", &len);
if (len > 0 && val)
uart->reg_shift = fdt32_to_cpu(*val);
else
uart->reg_shift = DEFAULT_UART_REG_SHIFT;
val = (fdt32_t *)fdt_getprop(fdt, nodeoffset, "reg-io-width", &len);
if (len > 0 && val)
uart->reg_io_width = fdt32_to_cpu(*val);
else
uart->reg_io_width = DEFAULT_UART_REG_IO_WIDTH;
val = (fdt32_t *)fdt_getprop(fdt, nodeoffset, "reg-offset", &len);
if (len > 0 && val)
uart->reg_offset = fdt32_to_cpu(*val);
else
uart->reg_offset = DEFAULT_UART_REG_OFFSET;
return 0;
}
int fdt_parse_uart8250(void *fdt, struct platform_uart_data *uart,
const char *compatible)
{
int nodeoffset;
if (!compatible || !uart || !fdt)
return SBI_ENODEV;
nodeoffset = fdt_node_offset_by_compatible(fdt, -1, compatible);
if (nodeoffset < 0)
return nodeoffset;
return fdt_parse_uart_node(fdt, nodeoffset, uart);
}
int fdt_parse_xlnx_uartlite_node(void *fdt, int nodeoffset,
struct platform_uart_data *uart)
{
return fdt_parse_uart_node_common(fdt, nodeoffset, uart, 0, 0);
}
int fdt_parse_aplic_node(void *fdt, int nodeoff, struct aplic_data *aplic)
{
bool child_found;
const fdt32_t *val;
const fdt32_t *del;
struct imsic_data imsic;
int i, j, d, dcnt, len, noff, rc;
uint64_t reg_addr, reg_size;
struct aplic_delegate_data *deleg;
if (nodeoff < 0 || !aplic || !fdt)
return SBI_ENODEV;
memset(aplic, 0, sizeof(*aplic));
rc = fdt_get_node_addr_size(fdt, nodeoff, 0, &reg_addr, &reg_size);
if (rc < 0 || !reg_addr || !reg_size)
return SBI_ENODEV;
aplic->addr = reg_addr;
aplic->size = reg_size;
val = fdt_getprop(fdt, nodeoff, "riscv,num-sources", &len);
if (len > 0)
aplic->num_source = fdt32_to_cpu(*val);
val = fdt_getprop(fdt, nodeoff, "interrupts-extended", &len);
if (val && len > sizeof(fdt32_t)) {
len = len / sizeof(fdt32_t);
for (i = 0; i < len; i += 2) {
if (fdt32_to_cpu(val[i + 1]) == IRQ_M_EXT) {
aplic->targets_mmode = true;
break;
}
}
aplic->num_idc = len / 2;
goto aplic_msi_parent_done;
}
val = fdt_getprop(fdt, nodeoff, "msi-parent", &len);
if (val && len >= sizeof(fdt32_t)) {
noff = fdt_node_offset_by_phandle(fdt, fdt32_to_cpu(*val));
if (noff < 0)
return noff;
rc = fdt_parse_imsic_node(fdt, noff, &imsic);
if (rc)
return rc;
rc = imsic_data_check(&imsic);
if (rc)
return rc;
aplic->targets_mmode = imsic.targets_mmode;
if (imsic.targets_mmode) {
aplic->has_msicfg_mmode = true;
aplic->msicfg_mmode.lhxs = imsic.guest_index_bits;
aplic->msicfg_mmode.lhxw = imsic.hart_index_bits;
aplic->msicfg_mmode.hhxw = imsic.group_index_bits;
aplic->msicfg_mmode.hhxs = imsic.group_index_shift;
if (aplic->msicfg_mmode.hhxs <
(2 * IMSIC_MMIO_PAGE_SHIFT))
return SBI_EINVAL;
aplic->msicfg_mmode.hhxs -= 24;
aplic->msicfg_mmode.base_addr = imsic.regs[0].addr;
} else {
goto aplic_msi_parent_done;
}
val = fdt_getprop(fdt, nodeoff, "riscv,children", &len);
if (!val || len < sizeof(fdt32_t))
goto aplic_msi_parent_done;
noff = fdt_node_offset_by_phandle(fdt, fdt32_to_cpu(*val));
if (noff < 0)
return noff;
val = fdt_getprop(fdt, noff, "msi-parent", &len);
if (!val || len < sizeof(fdt32_t))
goto aplic_msi_parent_done;
noff = fdt_node_offset_by_phandle(fdt, fdt32_to_cpu(*val));
if (noff < 0)
return noff;
rc = fdt_parse_imsic_node(fdt, noff, &imsic);
if (rc)
return rc;
rc = imsic_data_check(&imsic);
if (rc)
return rc;
if (!imsic.targets_mmode) {
aplic->has_msicfg_smode = true;
aplic->msicfg_smode.lhxs = imsic.guest_index_bits;
aplic->msicfg_smode.lhxw = imsic.hart_index_bits;
aplic->msicfg_smode.hhxw = imsic.group_index_bits;
aplic->msicfg_smode.hhxs = imsic.group_index_shift;
if (aplic->msicfg_smode.hhxs <
(2 * IMSIC_MMIO_PAGE_SHIFT))
return SBI_EINVAL;
aplic->msicfg_smode.hhxs -= 24;
aplic->msicfg_smode.base_addr = imsic.regs[0].addr;
}
}
aplic_msi_parent_done:
for (d = 0; d < APLIC_MAX_DELEGATE; d++) {
deleg = &aplic->delegate[d];
deleg->first_irq = 0;
deleg->last_irq = 0;
deleg->child_index = 0;
}
del = fdt_getprop(fdt, nodeoff, "riscv,delegate", &len);
if (!del || len < (3 * sizeof(fdt32_t)))
goto skip_delegate_parse;
d = 0;
dcnt = len / sizeof(fdt32_t);
for (i = 0; i < dcnt; i += 3) {
if (d >= APLIC_MAX_DELEGATE)
break;
deleg = &aplic->delegate[d];
deleg->first_irq = fdt32_to_cpu(del[i + 1]);
deleg->last_irq = fdt32_to_cpu(del[i + 2]);
deleg->child_index = 0;
child_found = false;
val = fdt_getprop(fdt, nodeoff, "riscv,children", &len);
if (!val || len < sizeof(fdt32_t)) {
deleg->first_irq = 0;
deleg->last_irq = 0;
deleg->child_index = 0;
continue;
}
len = len / sizeof(fdt32_t);
for (j = 0; j < len; j++) {
if (del[i] != val[j])
continue;
deleg->child_index = j;
child_found = true;
break;
}
if (child_found) {
d++;
} else {
deleg->first_irq = 0;
deleg->last_irq = 0;
deleg->child_index = 0;
}
}
skip_delegate_parse:
return 0;
}
bool fdt_check_imsic_mlevel(void *fdt)
{
const fdt32_t *val;
int i, len, noff = 0;
if (!fdt)
return false;
while ((noff = fdt_node_offset_by_compatible(fdt, noff,
"riscv,imsics")) >= 0) {
val = fdt_getprop(fdt, noff, "interrupts-extended", &len);
if (val && len > sizeof(fdt32_t)) {
len = len / sizeof(fdt32_t);
for (i = 0; i < len; i += 2) {
if (fdt32_to_cpu(val[i + 1]) == IRQ_M_EXT)
return true;
}
}
}
return false;
}
int fdt_parse_imsic_node(void *fdt, int nodeoff, struct imsic_data *imsic)
{
const fdt32_t *val;
struct imsic_regs *regs;
uint64_t reg_addr, reg_size;
int i, rc, len, nr_parent_irqs;
if (nodeoff < 0 || !imsic || !fdt)
return SBI_ENODEV;
imsic->targets_mmode = false;
val = fdt_getprop(fdt, nodeoff, "interrupts-extended", &len);
if (val && len > sizeof(fdt32_t)) {
len = len / sizeof(fdt32_t);
nr_parent_irqs = len / 2;
for (i = 0; i < len; i += 2) {
if (fdt32_to_cpu(val[i + 1]) == IRQ_M_EXT) {
imsic->targets_mmode = true;
break;
}
}
} else
return SBI_EINVAL;
val = fdt_getprop(fdt, nodeoff, "riscv,guest-index-bits", &len);
if (val && len > 0)
imsic->guest_index_bits = fdt32_to_cpu(*val);
else
imsic->guest_index_bits = 0;
val = fdt_getprop(fdt, nodeoff, "riscv,hart-index-bits", &len);
if (val && len > 0) {
imsic->hart_index_bits = fdt32_to_cpu(*val);
} else {
imsic->hart_index_bits = sbi_fls(nr_parent_irqs);
if ((1UL << imsic->hart_index_bits) < nr_parent_irqs)
imsic->hart_index_bits++;
}
val = fdt_getprop(fdt, nodeoff, "riscv,group-index-bits", &len);
if (val && len > 0)
imsic->group_index_bits = fdt32_to_cpu(*val);
else
imsic->group_index_bits = 0;
val = fdt_getprop(fdt, nodeoff, "riscv,group-index-shift", &len);
if (val && len > 0)
imsic->group_index_shift = fdt32_to_cpu(*val);
else
imsic->group_index_shift = 2 * IMSIC_MMIO_PAGE_SHIFT;
val = fdt_getprop(fdt, nodeoff, "riscv,num-ids", &len);
if (val && len > 0)
imsic->num_ids = fdt32_to_cpu(*val);
else
return SBI_EINVAL;
for (i = 0; i < IMSIC_MAX_REGS; i++) {
regs = &imsic->regs[i];
regs->addr = 0;
regs->size = 0;
}
for (i = 0; i < (IMSIC_MAX_REGS - 1); i++) {
regs = &imsic->regs[i];
rc = fdt_get_node_addr_size(fdt, nodeoff, i,
&reg_addr, &reg_size);
if (rc < 0 || !reg_addr || !reg_size)
break;
regs->addr = reg_addr;
regs->size = reg_size;
}
if (!imsic->regs[0].size)
return SBI_EINVAL;
return 0;
}
int fdt_parse_plic_node(void *fdt, int nodeoffset, struct plic_data *plic)
{
int len, rc;
const fdt32_t *val;
uint64_t reg_addr, reg_size;
if (nodeoffset < 0 || !plic || !fdt)
return SBI_ENODEV;
rc = fdt_get_node_addr_size(fdt, nodeoffset, 0,
&reg_addr, &reg_size);
if (rc < 0 || !reg_addr || !reg_size)
return SBI_ENODEV;
plic->addr = reg_addr;
val = fdt_getprop(fdt, nodeoffset, "riscv,ndev", &len);
if (len > 0)
plic->num_src = fdt32_to_cpu(*val);
return 0;
}
int fdt_parse_plic(void *fdt, struct plic_data *plic, const char *compat)
{
int nodeoffset;
if (!compat || !plic || !fdt)
return SBI_ENODEV;
nodeoffset = fdt_node_offset_by_compatible(fdt, -1, compat);
if (nodeoffset < 0)
return nodeoffset;
return fdt_parse_plic_node(fdt, nodeoffset, plic);
}
int fdt_parse_aclint_node(void *fdt, int nodeoffset, bool for_timer,
unsigned long *out_addr1, unsigned long *out_size1,
unsigned long *out_addr2, unsigned long *out_size2,
u32 *out_first_hartid, u32 *out_hart_count)
{
const fdt32_t *val;
uint64_t reg_addr, reg_size;
int i, rc, count, cpu_offset, cpu_intc_offset;
u32 phandle, hwirq, hartid, first_hartid, last_hartid, hart_count;
u32 match_hwirq = (for_timer) ? IRQ_M_TIMER : IRQ_M_SOFT;
if (nodeoffset < 0 || !fdt ||
!out_addr1 || !out_size1 ||
!out_first_hartid || !out_hart_count)
return SBI_EINVAL;
rc = fdt_get_node_addr_size(fdt, nodeoffset, 0,
&reg_addr, &reg_size);
if (rc < 0 || !reg_size)
return SBI_ENODEV;
*out_addr1 = reg_addr;
*out_size1 = reg_size;
rc = fdt_get_node_addr_size(fdt, nodeoffset, 1,
&reg_addr, &reg_size);
if (rc < 0 || !reg_size)
reg_addr = reg_size = 0;
if (out_addr2)
*out_addr2 = reg_addr;
if (out_size2)
*out_size2 = reg_size;
*out_first_hartid = 0;
*out_hart_count = 0;
val = fdt_getprop(fdt, nodeoffset, "interrupts-extended", &count);
if (!val || count < sizeof(fdt32_t))
return 0;
count = count / sizeof(fdt32_t);
first_hartid = -1U;
hart_count = last_hartid = 0;
for (i = 0; i < (count / 2); i++) {
phandle = fdt32_to_cpu(val[2 * i]);
hwirq = fdt32_to_cpu(val[(2 * i) + 1]);
cpu_intc_offset = fdt_node_offset_by_phandle(fdt, phandle);
if (cpu_intc_offset < 0)
continue;
cpu_offset = fdt_parent_offset(fdt, cpu_intc_offset);
if (cpu_offset < 0)
continue;
rc = fdt_parse_hart_id(fdt, cpu_offset, &hartid);
if (rc)
continue;
if (SBI_HARTMASK_MAX_BITS <= hartid)
continue;
if (match_hwirq == hwirq) {
if (hartid < first_hartid)
first_hartid = hartid;
if (hartid > last_hartid)
last_hartid = hartid;
hart_count++;
}
}
if ((last_hartid >= first_hartid) && first_hartid != -1U) {
*out_first_hartid = first_hartid;
count = last_hartid - first_hartid + 1;
*out_hart_count = (hart_count < count) ? hart_count : count;
}
return 0;
}
int fdt_parse_plmt_node(void *fdt, int nodeoffset, unsigned long *plmt_base,
unsigned long *plmt_size, u32 *hart_count)
{
const fdt32_t *val;
int rc, i, count;
uint64_t reg_addr, reg_size;
u32 phandle, hwirq, hartid, hcount;
if (nodeoffset < 0 || !fdt || !plmt_base ||
!hart_count || !plmt_size)
return SBI_EINVAL;
rc = fdt_get_node_addr_size(fdt, nodeoffset, 0,
&reg_addr, &reg_size);
if (rc < 0)
return SBI_ENODEV;
*plmt_base = reg_addr;
*plmt_size = reg_size;
val = fdt_getprop(fdt, nodeoffset, "interrupts-extended", &count);
if (!val || count < sizeof(fdt32_t))
return 0;
count = count / sizeof(fdt32_t);
hcount = 0;
for (i = 0; i < (count / 2); i++) {
int cpu_offset, cpu_intc_offset;
phandle = fdt32_to_cpu(val[2 * i]);
hwirq = fdt32_to_cpu(val[2 * i + 1]);
cpu_intc_offset = fdt_node_offset_by_phandle(fdt, phandle);
if (cpu_intc_offset < 0)
continue;
cpu_offset = fdt_parent_offset(fdt, cpu_intc_offset);
if (cpu_offset < 0)
continue;
rc = fdt_parse_hart_id(fdt, cpu_offset, &hartid);
if (rc)
continue;
if (SBI_HARTMASK_MAX_BITS <= hartid)
continue;
if (hwirq == IRQ_M_TIMER)
hcount++;
}
*hart_count = hcount;
return 0;
}
int fdt_parse_plicsw_node(void *fdt, int nodeoffset, unsigned long *plicsw_base,
unsigned long *size, u32 *hart_count)
{
const fdt32_t *val;
int rc, i, count;
uint64_t reg_addr, reg_size;
u32 phandle, hwirq, hartid, hcount;
if (nodeoffset < 0 || !fdt || !plicsw_base ||
!hart_count || !size)
return SBI_EINVAL;
rc = fdt_get_node_addr_size(fdt, nodeoffset, 0,
&reg_addr, &reg_size);
if (rc < 0)
return SBI_ENODEV;
*plicsw_base = reg_addr;
*size = reg_size;
val = fdt_getprop(fdt, nodeoffset, "interrupts-extended", &count);
if (!val || count < sizeof(fdt32_t))
return 0;
count = count / sizeof(fdt32_t);
hcount = 0;
for (i = 0; i < (count / 2); i++) {
int cpu_offset, cpu_intc_offset;
phandle = fdt32_to_cpu(val[2 * i]);
hwirq = fdt32_to_cpu(val[2 * i + 1]);
cpu_intc_offset = fdt_node_offset_by_phandle(fdt, phandle);
if (cpu_intc_offset < 0)
continue;
cpu_offset = fdt_parent_offset(fdt, cpu_intc_offset);
if (cpu_offset < 0)
continue;
rc = fdt_parse_hart_id(fdt, cpu_offset, &hartid);
if (rc)
continue;
if (SBI_HARTMASK_MAX_BITS <= hartid)
continue;
if (hwirq == IRQ_M_SOFT)
hcount++;
}
*hart_count = hcount;
return 0;
}
int fdt_parse_compat_addr(void *fdt, uint64_t *addr,
const char *compatible)
{
int nodeoffset, rc;
nodeoffset = fdt_node_offset_by_compatible(fdt, -1, compatible);
if (nodeoffset < 0)
return nodeoffset;
rc = fdt_get_node_addr_size(fdt, nodeoffset, 0, addr, NULL);
if (rc < 0 || !addr)
return SBI_ENODEV;
return 0;
}