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#include <stdbool.h>
#include <stdint.h>
#include <string.h>
#include "config.h"
#include "fdt.h"
#include "mtrap.h"
static inline uint32_t bswap(uint32_t x)
{
uint32_t y = (x & 0x00FF00FF) << 8 | (x & 0xFF00FF00) >> 8;
uint32_t z = (y & 0x0000FFFF) << 16 | (y & 0xFFFF0000) >> 16;
return z;
}
static inline int isstring(char c)
{
if (c >= 'A' && c <= 'Z')
return 1;
if (c >= 'a' && c <= 'z')
return 1;
if (c >= '0' && c <= '9')
return 1;
if (c == '\0' || c == ' ' || c == ',' || c == '-')
return 1;
return 0;
}
static uint32_t *fdt_scan_helper(
uint32_t *lex,
const char *strings,
struct fdt_scan_node *node,
const struct fdt_cb *cb)
{
struct fdt_scan_node child;
struct fdt_scan_prop prop;
int last = 0;
child.parent = node;
// these are the default cell counts, as per the FDT spec
child.address_cells = 2;
child.size_cells = 1;
prop.node = node;
while (1) {
switch (bswap(lex[0])) {
case FDT_NOP: {
lex += 1;
break;
}
case FDT_PROP: {
assert (!last);
prop.name = strings + bswap(lex[2]);
prop.len = bswap(lex[1]);
prop.value = lex + 3;
if (node && !strcmp(prop.name, "#address-cells")) { node->address_cells = bswap(lex[3]); }
if (node && !strcmp(prop.name, "#size-cells")) { node->size_cells = bswap(lex[3]); }
lex += 3 + (prop.len+3)/4;
cb->prop(&prop, cb->extra);
break;
}
case FDT_BEGIN_NODE: {
uint32_t *lex_next;
if (!last && node && cb->done) cb->done(node, cb->extra);
last = 1;
child.name = (const char *)(lex+1);
if (cb->open) cb->open(&child, cb->extra);
lex_next = fdt_scan_helper(
lex + 2 + strlen(child.name)/4,
strings, &child, cb);
if (cb->close && cb->close(&child, cb->extra) == -1)
while (lex != lex_next) *lex++ = bswap(FDT_NOP);
lex = lex_next;
break;
}
case FDT_END_NODE: {
if (!last && node && cb->done) cb->done(node, cb->extra);
return lex + 1;
}
default: { // FDT_END
if (!last && node && cb->done) cb->done(node, cb->extra);
return lex;
}
}
}
}
void fdt_scan(uintptr_t fdt, const struct fdt_cb *cb)
{
struct fdt_header *header = (struct fdt_header *)fdt;
// Only process FDT that we understand
if (bswap(header->magic) != FDT_MAGIC ||
bswap(header->last_comp_version) > FDT_VERSION) return;
const char *strings = (const char *)(fdt + bswap(header->off_dt_strings));
uint32_t *lex = (uint32_t *)(fdt + bswap(header->off_dt_struct));
fdt_scan_helper(lex, strings, 0, cb);
}
uint32_t fdt_size(uintptr_t fdt)
{
struct fdt_header *header = (struct fdt_header *)fdt;
// Only process FDT that we understand
if (bswap(header->magic) != FDT_MAGIC ||
bswap(header->last_comp_version) > FDT_VERSION) return 0;
return bswap(header->totalsize);
}
const uint32_t *fdt_get_address(const struct fdt_scan_node *node, const uint32_t *value, uint64_t *result)
{
*result = 0;
for (int cells = node->address_cells; cells > 0; --cells)
*result = (*result << 32) + bswap(*value++);
return value;
}
const uint32_t *fdt_get_size(const struct fdt_scan_node *node, const uint32_t *value, uint64_t *result)
{
*result = 0;
for (int cells = node->size_cells; cells > 0; --cells)
*result = (*result << 32) + bswap(*value++);
return value;
}
int fdt_string_list_index(const struct fdt_scan_prop *prop, const char *str)
{
const char *list = (const char *)prop->value;
const char *end = list + prop->len;
int index = 0;
while (end - list > 0) {
if (!strcmp(list, str)) return index;
++index;
list += strlen(list) + 1;
}
return -1;
}
//////////////////////////////////////////// MEMORY SCAN /////////////////////////////////////////
struct mem_scan {
int memory;
const uint32_t *reg_value;
int reg_len;
};
static void mem_open(const struct fdt_scan_node *node, void *extra)
{
struct mem_scan *scan = (struct mem_scan *)extra;
memset(scan, 0, sizeof(*scan));
}
static void mem_prop(const struct fdt_scan_prop *prop, void *extra)
{
struct mem_scan *scan = (struct mem_scan *)extra;
if (!strcmp(prop->name, "device_type") && !strcmp((const char*)prop->value, "memory")) {
scan->memory = 1;
} else if (!strcmp(prop->name, "reg")) {
scan->reg_value = prop->value;
scan->reg_len = prop->len;
}
}
static void mem_done(const struct fdt_scan_node *node, void *extra)
{
struct mem_scan *scan = (struct mem_scan *)extra;
const uint32_t *value = scan->reg_value;
const uint32_t *end = value + scan->reg_len/4;
uintptr_t self = (uintptr_t)mem_done;
if (!scan->memory) return;
assert (scan->reg_value && scan->reg_len % 4 == 0);
while (end - value > 0) {
uint64_t base, size;
value = fdt_get_address(node->parent, value, &base);
value = fdt_get_size (node->parent, value, &size);
if (base <= self && self <= base + size) { mem_size = size; }
}
assert (end == value);
}
void query_mem(uintptr_t fdt)
{
struct fdt_cb cb;
struct mem_scan scan;
memset(&cb, 0, sizeof(cb));
cb.open = mem_open;
cb.prop = mem_prop;
cb.done = mem_done;
cb.extra = &scan;
mem_size = 0;
fdt_scan(fdt, &cb);
assert (mem_size > 0);
}
///////////////////////////////////////////// HART SCAN //////////////////////////////////////////
static uint32_t hart_phandles[MAX_HARTS];
uint64_t hart_mask;
struct hart_scan {
const struct fdt_scan_node *cpu;
int hart;
const struct fdt_scan_node *controller;
int cells;
uint32_t phandle;
};
static void hart_open(const struct fdt_scan_node *node, void *extra)
{
struct hart_scan *scan = (struct hart_scan *)extra;
if (!scan->cpu) {
scan->hart = -1;
}
if (!scan->controller) {
scan->cells = 0;
scan->phandle = 0;
}
}
static void hart_prop(const struct fdt_scan_prop *prop, void *extra)
{
struct hart_scan *scan = (struct hart_scan *)extra;
if (!strcmp(prop->name, "device_type") && !strcmp((const char*)prop->value, "cpu")) {
assert (!scan->cpu);
scan->cpu = prop->node;
} else if (!strcmp(prop->name, "interrupt-controller")) {
assert (!scan->controller);
scan->controller = prop->node;
} else if (!strcmp(prop->name, "#interrupt-cells")) {
scan->cells = bswap(prop->value[0]);
} else if (!strcmp(prop->name, "phandle")) {
scan->phandle = bswap(prop->value[0]);
} else if (!strcmp(prop->name, "reg")) {
uint64_t reg;
fdt_get_address(prop->node->parent, prop->value, &reg);
scan->hart = reg;
}
}
static void hart_done(const struct fdt_scan_node *node, void *extra)
{
struct hart_scan *scan = (struct hart_scan *)extra;
if (scan->cpu == node) {
assert (scan->hart >= 0);
}
if (scan->controller == node && scan->cpu) {
assert (scan->phandle > 0);
assert (scan->cells == 1);
if (scan->hart < MAX_HARTS) {
hart_phandles[scan->hart] = scan->phandle;
hart_mask |= 1 << scan->hart;
hls_init(scan->hart);
}
}
}
static int hart_close(const struct fdt_scan_node *node, void *extra)
{
struct hart_scan *scan = (struct hart_scan *)extra;
if (scan->cpu == node) scan->cpu = 0;
if (scan->controller == node) scan->controller = 0;
return 0;
}
void query_harts(uintptr_t fdt)
{
struct fdt_cb cb;
struct hart_scan scan;
memset(&cb, 0, sizeof(cb));
memset(&scan, 0, sizeof(scan));
cb.open = hart_open;
cb.prop = hart_prop;
cb.done = hart_done;
cb.close= hart_close;
cb.extra = &scan;
fdt_scan(fdt, &cb);
// The current hart should have been detected
assert ((hart_mask >> read_csr(mhartid)) != 0);
}
///////////////////////////////////////////// CLINT SCAN /////////////////////////////////////////
struct clint_scan
{
int compat;
uint64_t reg;
const uint32_t *int_value;
int int_len;
int done;
};
static void clint_open(const struct fdt_scan_node *node, void *extra)
{
struct clint_scan *scan = (struct clint_scan *)extra;
scan->compat = 0;
scan->reg = 0;
scan->int_value = 0;
}
static void clint_prop(const struct fdt_scan_prop *prop, void *extra)
{
struct clint_scan *scan = (struct clint_scan *)extra;
if (!strcmp(prop->name, "compatible") && fdt_string_list_index(prop, "riscv,clint0") >= 0) {
scan->compat = 1;
} else if (!strcmp(prop->name, "reg")) {
fdt_get_address(prop->node->parent, prop->value, &scan->reg);
} else if (!strcmp(prop->name, "interrupts-extended")) {
scan->int_value = prop->value;
scan->int_len = prop->len;
}
}
static void clint_done(const struct fdt_scan_node *node, void *extra)
{
struct clint_scan *scan = (struct clint_scan *)extra;
const uint32_t *value = scan->int_value;
const uint32_t *end = value + scan->int_len/4;
if (!scan->compat) return;
assert (scan->reg != 0);
assert (scan->int_value && scan->int_len % 16 == 0);
assert (!scan->done); // only one clint
scan->done = 1;
mtime = (void*)((uintptr_t)scan->reg + 0xbff8);
for (int index = 0; end - value > 0; ++index) {
uint32_t phandle = bswap(value[0]);
int hart;
for (hart = 0; hart < MAX_HARTS; ++hart)
if (hart_phandles[hart] == phandle)
break;
if (hart < MAX_HARTS) {
hls_t *hls = OTHER_HLS(hart);
hls->ipi = (void*)((uintptr_t)scan->reg + index * 4);
hls->timecmp = (void*)((uintptr_t)scan->reg + 0x4000 + (index * 8));
}
value += 4;
}
}
void query_clint(uintptr_t fdt)
{
struct fdt_cb cb;
struct clint_scan scan;
memset(&cb, 0, sizeof(cb));
cb.open = clint_open;
cb.prop = clint_prop;
cb.done = clint_done;
cb.extra = &scan;
scan.done = 0;
fdt_scan(fdt, &cb);
assert (scan.done);
}
///////////////////////////////////////////// PLIC SCAN /////////////////////////////////////////
struct plic_scan
{
int compat;
uint64_t reg;
uint32_t *int_value;
int int_len;
int done;
int ndev;
};
static void plic_open(const struct fdt_scan_node *node, void *extra)
{
struct plic_scan *scan = (struct plic_scan *)extra;
scan->compat = 0;
scan->reg = 0;
scan->int_value = 0;
}
static void plic_prop(const struct fdt_scan_prop *prop, void *extra)
{
struct plic_scan *scan = (struct plic_scan *)extra;
if (!strcmp(prop->name, "compatible") && fdt_string_list_index(prop, "riscv,plic0") >= 0) {
scan->compat = 1;
} else if (!strcmp(prop->name, "reg")) {
fdt_get_address(prop->node->parent, prop->value, &scan->reg);
} else if (!strcmp(prop->name, "interrupts-extended")) {
scan->int_value = prop->value;
scan->int_len = prop->len;
} else if (!strcmp(prop->name, "riscv,ndev")) {
scan->ndev = bswap(prop->value[0]);
}
}
#define HART_BASE 0x200000
#define HART_SIZE 0x1000
#define ENABLE_BASE 0x2000
#define ENABLE_SIZE 0x80
static void plic_done(const struct fdt_scan_node *node, void *extra)
{
struct plic_scan *scan = (struct plic_scan *)extra;
const uint32_t *value = scan->int_value;
const uint32_t *end = value + scan->int_len/4;
if (!scan->compat) return;
assert (scan->reg != 0);
assert (scan->int_value && scan->int_len % 8 == 0);
assert (scan->ndev >= 0 && scan->ndev < 1024);
assert (!scan->done); // only one plic
scan->done = 1;
plic_priorities = (uint32_t*)(uintptr_t)scan->reg;
plic_ndevs = scan->ndev;
for (int index = 0; end - value > 0; ++index) {
uint32_t phandle = bswap(value[0]);
uint32_t cpu_int = bswap(value[1]);
int hart;
for (hart = 0; hart < MAX_HARTS; ++hart)
if (hart_phandles[hart] == phandle)
break;
if (hart < MAX_HARTS) {
hls_t *hls = OTHER_HLS(hart);
if (cpu_int == IRQ_M_EXT) {
hls->plic_m_ie = (uintptr_t*)((uintptr_t)scan->reg + ENABLE_BASE + ENABLE_SIZE * index);
hls->plic_m_thresh = (uint32_t*) ((uintptr_t)scan->reg + HART_BASE + HART_SIZE * index);
} else if (cpu_int == IRQ_S_EXT) {
hls->plic_s_ie = (uintptr_t*)((uintptr_t)scan->reg + ENABLE_BASE + ENABLE_SIZE * index);
hls->plic_s_thresh = (uint32_t*) ((uintptr_t)scan->reg + HART_BASE + HART_SIZE * index);
} else {
printm("PLIC wired hart %d to wrong interrupt %d", hart, cpu_int);
}
}
value += 2;
}
#if 0
printm("PLIC: prio %x devs %d\r\n", (uint32_t)(uintptr_t)plic_priorities, plic_ndevs);
for (int i = 0; i < MAX_HARTS; ++i) {
hls_t *hls = OTHER_HLS(i);
printm("CPU %d: %x %x %x %x\r\n", i, (uint32_t)(uintptr_t)hls->plic_m_ie, (uint32_t)(uintptr_t)hls->plic_m_thresh, (uint32_t)(uintptr_t)hls->plic_s_ie, (uint32_t)(uintptr_t)hls->plic_s_thresh);
}
#endif
}
void query_plic(uintptr_t fdt)
{
struct fdt_cb cb;
struct plic_scan scan;
memset(&cb, 0, sizeof(cb));
cb.open = plic_open;
cb.prop = plic_prop;
cb.done = plic_done;
cb.extra = &scan;
scan.done = 0;
fdt_scan(fdt, &cb);
}
static void plic_redact(const struct fdt_scan_node *node, void *extra)
{
struct plic_scan *scan = (struct plic_scan *)extra;
uint32_t *value = scan->int_value;
uint32_t *end = value + scan->int_len/4;
if (!scan->compat) return;
scan->done = 1;
while (end - value > 0) {
if (bswap(value[1]) == IRQ_M_EXT) value[1] = bswap(-1);
value += 2;
}
}
void filter_plic(uintptr_t fdt)
{
struct fdt_cb cb;
struct plic_scan scan;
memset(&cb, 0, sizeof(cb));
cb.open = plic_open;
cb.prop = plic_prop;
cb.done = plic_redact;
cb.extra = &scan;
scan.done = 0;
fdt_scan(fdt, &cb);
}
//////////////////////////////////////////// COMPAT SCAN ////////////////////////////////////////
struct compat_scan
{
const char *compat;
int depth;
int kill;
};
static void compat_open(const struct fdt_scan_node *node, void *extra)
{
struct compat_scan *scan = (struct compat_scan *)extra;
++scan->depth;
}
static void compat_prop(const struct fdt_scan_prop *prop, void *extra)
{
struct compat_scan *scan = (struct compat_scan *)extra;
if (!strcmp(prop->name, "compatible") && fdt_string_list_index(prop, scan->compat) >= 0)
if (scan->depth < scan->kill)
scan->kill = scan->depth;
}
static int compat_close(const struct fdt_scan_node *node, void *extra)
{
struct compat_scan *scan = (struct compat_scan *)extra;
if (scan->kill == scan->depth--) {
scan->kill = 999;
return -1;
} else {
return 0;
}
}
void filter_compat(uintptr_t fdt, const char *compat)
{
struct fdt_cb cb;
struct compat_scan scan;
memset(&cb, 0, sizeof(cb));
cb.open = compat_open;
cb.prop = compat_prop;
cb.close = compat_close;
cb.extra = &scan;
scan.compat = compat;
scan.depth = 0;
scan.kill = 999;
fdt_scan(fdt, &cb);
}
//////////////////////////////////////////// HART FILTER ////////////////////////////////////////
struct hart_filter {
int compat;
int hart;
char *status;
char *mmu_type;
long *disabled_hart_mask;
};
static void hart_filter_open(const struct fdt_scan_node *node, void *extra)
{
struct hart_filter *filter = (struct hart_filter *)extra;
filter->status = NULL;
filter->mmu_type = NULL;
filter->compat = 0;
filter->hart = -1;
}
static void hart_filter_prop(const struct fdt_scan_prop *prop, void *extra)
{
struct hart_filter *filter = (struct hart_filter *)extra;
if (!strcmp(prop->name, "device_type") && !strcmp((const char*)prop->value, "cpu")) {
filter->compat = 1;
} else if (!strcmp(prop->name, "reg")) {
uint64_t reg;
fdt_get_address(prop->node->parent, prop->value, &reg);
filter->hart = reg;
} else if (!strcmp(prop->name, "status")) {
filter->status = (char*)prop->value;
} else if (!strcmp(prop->name, "mmu-type")) {
filter->mmu_type = (char*)prop->value;
}
}
static bool hart_filter_mask(const struct hart_filter *filter)
{
if (filter->mmu_type == NULL) return true;
if (strcmp(filter->status, "okay")) return true;
if (!strcmp(filter->mmu_type, "riscv,sv39")) return false;
if (!strcmp(filter->mmu_type, "riscv,sv48")) return false;
printm("hart_filter_mask saw unknown hart type: status=\"%s\", mmu_type=\"%s\"\n",
filter->status, filter->mmu_type);
return true;
}
static void hart_filter_done(const struct fdt_scan_node *node, void *extra)
{
struct hart_filter *filter = (struct hart_filter *)extra;
if (!filter->compat) return;
assert (filter->status);
assert (filter->hart >= 0);
if (hart_filter_mask(filter)) {
strcpy(filter->status, "masked");
uint32_t *len = (uint32_t*)filter->status;
len[-2] = bswap(strlen("masked")+1);
*filter->disabled_hart_mask |= (1 << filter->hart);
}
}
void filter_harts(uintptr_t fdt, long *disabled_hart_mask)
{
struct fdt_cb cb;
struct hart_filter filter;
memset(&cb, 0, sizeof(cb));
cb.open = hart_filter_open;
cb.prop = hart_filter_prop;
cb.done = hart_filter_done;
cb.extra = &filter;
filter.disabled_hart_mask = disabled_hart_mask;
*disabled_hart_mask = 0;
fdt_scan(fdt, &cb);
}
//////////////////////////////////////////// PRINT //////////////////////////////////////////////
#ifdef PK_PRINT_DEVICE_TREE
#define FDT_PRINT_MAX_DEPTH 32
struct fdt_print_info {
int depth;
const struct fdt_scan_node *stack[FDT_PRINT_MAX_DEPTH];
};
void fdt_print_printm(struct fdt_print_info *info, const char *format, ...)
{
va_list vl;
for (int i = 0; i < info->depth; ++i)
printm(" ");
va_start(vl, format);
vprintm(format, vl);
va_end(vl);
}
static void fdt_print_open(const struct fdt_scan_node *node, void *extra)
{
struct fdt_print_info *info = (struct fdt_print_info *)extra;
while (node->parent != NULL && info->stack[info->depth-1] != node->parent) {
info->depth--;
fdt_print_printm(info, "}\r\n");
}
fdt_print_printm(info, "%s {\r\n", node->name);
info->stack[info->depth] = node;
info->depth++;
}
static void fdt_print_prop(const struct fdt_scan_prop *prop, void *extra)
{
struct fdt_print_info *info = (struct fdt_print_info *)extra;
int asstring = 1;
char *char_data = (char *)(prop->value);
fdt_print_printm(info, "%s", prop->name);
if (prop->len == 0) {
printm(";\r\n");
return;
} else {
printm(" = ");
}
/* It appears that dtc uses a hueristic to detect strings so I'm using a
* similar one here. */
for (int i = 0; i < prop->len; ++i) {
if (!isstring(char_data[i]))
asstring = 0;
if (i > 0 && char_data[i] == '\0' && char_data[i-1] == '\0')
asstring = 0;
}
if (asstring) {
for (size_t i = 0; i < prop->len; i += strlen(char_data + i) + 1) {
if (i != 0)
printm(", ");
printm("\"%s\"", char_data + i);
}
} else {
printm("<");
for (size_t i = 0; i < prop->len/4; ++i) {
if (i != 0)
printm(" ");
printm("0x%08x", bswap(prop->value[i]));
}
printm(">");
}
printm(";\r\n");
}
static void fdt_print_done(const struct fdt_scan_node *node, void *extra)
{
struct fdt_print_info *info = (struct fdt_print_info *)extra;
}
static int fdt_print_close(const struct fdt_scan_node *node, void *extra)
{
struct fdt_print_info *info = (struct fdt_print_info *)extra;
return 0;
}
void fdt_print(uintptr_t fdt)
{
struct fdt_print_info info;
struct fdt_cb cb;
info.depth = 0;
memset(&cb, 0, sizeof(cb));
cb.open = fdt_print_open;
cb.prop = fdt_print_prop;
cb.done = fdt_print_done;
cb.close = fdt_print_close;
cb.extra = &info;
fdt_scan(fdt, &cb);
while (info.depth > 0) {
info.depth--;
fdt_print_printm(&info, "}\r\n");
}
}
#endif