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// See LICENSE for license details.
#include <stdint.h>
#include <string.h>
#include <stdio.h>
#include "riscv_test.h"
void trap_entry();
void pop_tf(trapframe_t*);
volatile uint64_t tohost;
volatile uint64_t fromhost;
static void do_tohost(uint64_t tohost_value)
{
while (tohost)
fromhost = 0;
tohost = tohost_value;
}
#define pa2kva(pa) ((void*)(pa) - DRAM_BASE - MEGAPAGE_SIZE)
#define uva2kva(pa) ((void*)(pa) - MEGAPAGE_SIZE)
#define flush_page(addr) asm volatile ("sfence.vma %0" : : "r" (addr))
static uint64_t lfsr63(uint64_t x)
{
uint64_t bit = (x ^ (x >> 1)) & 1;
return (x >> 1) | (bit << 62);
}
static void cputchar(int x)
{
do_tohost(0x0101000000000000 | (unsigned char)x);
}
static void cputstring(const char* s)
{
while (*s)
cputchar(*s++);
}
static void terminate(int code)
{
do_tohost(code);
while (1);
}
void wtf()
{
terminate(841);
}
#define stringify1(x) #x
#define stringify(x) stringify1(x)
#define assert(x) do { \
if (x) break; \
cputstring("Assertion failed: " stringify(x) "\n"); \
terminate(3); \
} while(0)
#define l1pt pt[0]
#define user_l2pt pt[1]
#if __riscv_xlen == 64
# define NPT 4
#define kernel_l2pt pt[2]
# define user_l3pt pt[3]
#else
# define NPT 2
# define user_l3pt user_l2pt
#endif
pte_t pt[NPT][PTES_PER_PT] __attribute__((aligned(PGSIZE)));
typedef struct { pte_t addr; void* next; } freelist_t;
freelist_t user_mapping[MAX_TEST_PAGES];
freelist_t freelist_nodes[MAX_TEST_PAGES];
freelist_t *freelist_head, *freelist_tail;
void printhex(uint64_t x)
{
char str[17];
for (int i = 0; i < 16; i++)
{
str[15-i] = (x & 0xF) + ((x & 0xF) < 10 ? '0' : 'a'-10);
x >>= 4;
}
str[16] = 0;
cputstring(str);
}
static void evict(unsigned long addr)
{
assert(addr >= PGSIZE && addr < MAX_TEST_PAGES * PGSIZE);
addr = addr/PGSIZE*PGSIZE;
freelist_t* node = &user_mapping[addr/PGSIZE];
if (node->addr)
{
// check accessed and dirty bits
assert(user_l3pt[addr/PGSIZE] & PTE_A);
if (memcmp((void*)addr, uva2kva(addr), PGSIZE)) {
assert(user_l3pt[addr/PGSIZE] & PTE_D);
memcpy((void*)addr, uva2kva(addr), PGSIZE);
}
user_mapping[addr/PGSIZE].addr = 0;
if (freelist_tail == 0)
freelist_head = freelist_tail = node;
else
{
freelist_tail->next = node;
freelist_tail = node;
}
}
}
void handle_fault(uintptr_t addr, uintptr_t cause)
{
assert(addr >= PGSIZE && addr < MAX_TEST_PAGES * PGSIZE);
addr = addr/PGSIZE*PGSIZE;
if (user_l3pt[addr/PGSIZE]) {
if (!(user_l3pt[addr/PGSIZE] & PTE_A)) {
user_l3pt[addr/PGSIZE] |= PTE_A;
} else {
assert(!(user_l3pt[addr/PGSIZE] & PTE_D) && cause == CAUSE_FAULT_STORE);
user_l3pt[addr/PGSIZE] |= PTE_D;
}
flush_page(addr);
return;
}
freelist_t* node = freelist_head;
assert(node);
freelist_head = node->next;
if (freelist_head == freelist_tail)
freelist_tail = 0;
uintptr_t new_pte = (node->addr >> PGSHIFT << PTE_PPN_SHIFT) | PTE_V | PTE_U | PTE_R | PTE_W | PTE_X;
user_l3pt[addr/PGSIZE] = new_pte | PTE_A | PTE_D;
flush_page(addr);
assert(user_mapping[addr/PGSIZE].addr == 0);
user_mapping[addr/PGSIZE] = *node;
memcpy((void*)addr, uva2kva(addr), PGSIZE);
user_l3pt[addr/PGSIZE] = new_pte;
flush_page(addr);
__builtin___clear_cache(0,0);
}
void handle_trap(trapframe_t* tf)
{
if (tf->cause == CAUSE_USER_ECALL)
{
int n = tf->gpr[10];
for (long i = 1; i < MAX_TEST_PAGES; i++)
evict(i*PGSIZE);
terminate(n);
}
else if (tf->cause == CAUSE_ILLEGAL_INSTRUCTION)
{
assert(tf->epc % 4 == 0);
int* fssr;
asm ("jal %0, 1f; fssr x0; 1:" : "=r"(fssr));
if (*(int*)tf->epc == *fssr)
terminate(1); // FP test on non-FP hardware. "succeed."
else
assert(!"illegal instruction");
tf->epc += 4;
}
else if (tf->cause == CAUSE_FAULT_FETCH || tf->cause == CAUSE_FAULT_LOAD || tf->cause == CAUSE_FAULT_STORE)
handle_fault(tf->badvaddr, tf->cause);
else
assert(!"unexpected exception");
pop_tf(tf);
}
static void coherence_torture()
{
// cause coherence misses without affecting program semantics
unsigned int random = ENTROPY;
while (1) {
uintptr_t paddr = DRAM_BASE + ((random % (2 * (MAX_TEST_PAGES + 1) * PGSIZE)) & -4);
#ifdef __riscv_atomic
if (random & 1) // perform a no-op write
asm volatile ("amoadd.w zero, zero, (%0)" :: "r"(paddr));
else // perform a read
#endif
asm volatile ("lw zero, (%0)" :: "r"(paddr));
random = lfsr63(random);
}
}
void vm_boot(uintptr_t test_addr)
{
unsigned int random = ENTROPY;
if (read_csr(mhartid) > 0)
coherence_torture();
_Static_assert(SIZEOF_TRAPFRAME_T == sizeof(trapframe_t), "???");
#if (MAX_TEST_PAGES > PTES_PER_PT) || (DRAM_BASE % MEGAPAGE_SIZE) != 0
# error
#endif
// map user to lowermost megapage
l1pt[0] = ((pte_t)user_l2pt >> PGSHIFT << PTE_PPN_SHIFT) | PTE_V;
// map kernel to uppermost megapage
#if __riscv_xlen == 64
l1pt[PTES_PER_PT-1] = ((pte_t)kernel_l2pt >> PGSHIFT << PTE_PPN_SHIFT) | PTE_V;
kernel_l2pt[PTES_PER_PT-1] = (DRAM_BASE/RISCV_PGSIZE << PTE_PPN_SHIFT) | PTE_V | PTE_R | PTE_W | PTE_X | PTE_A | PTE_D;
user_l2pt[0] = ((pte_t)user_l3pt >> PGSHIFT << PTE_PPN_SHIFT) | PTE_V;
uintptr_t vm_choice = SPTBR_MODE_SV39;
#else
l1pt[PTES_PER_PT-1] = (DRAM_BASE/RISCV_PGSIZE << PTE_PPN_SHIFT) | PTE_V | PTE_R | PTE_W | PTE_X | PTE_A | PTE_D;
uintptr_t vm_choice = SPTBR_MODE_SV32;
#endif
write_csr(sptbr, ((uintptr_t)l1pt >> PGSHIFT) |
(vm_choice * (SPTBR_MODE & ~(SPTBR_MODE<<1))));
// set up supervisor trap handling
write_csr(stvec, pa2kva(trap_entry));
write_csr(sscratch, pa2kva(read_csr(mscratch)));
write_csr(medeleg,
(1 << CAUSE_USER_ECALL) |
(1 << CAUSE_FAULT_FETCH) |
(1 << CAUSE_FAULT_LOAD) |
(1 << CAUSE_FAULT_STORE));
// FPU on; accelerator on
write_csr(mstatus, MSTATUS_FS | MSTATUS_XS);
write_csr(mie, 0);
random = 1 + (random % MAX_TEST_PAGES);
freelist_head = pa2kva((void*)&freelist_nodes[0]);
freelist_tail = pa2kva(&freelist_nodes[MAX_TEST_PAGES-1]);
for (long i = 0; i < MAX_TEST_PAGES; i++)
{
freelist_nodes[i].addr = DRAM_BASE + (MAX_TEST_PAGES + random)*PGSIZE;
freelist_nodes[i].next = pa2kva(&freelist_nodes[i+1]);
random = LFSR_NEXT(random);
}
freelist_nodes[MAX_TEST_PAGES-1].next = 0;
trapframe_t tf;
memset(&tf, 0, sizeof(tf));
tf.epc = test_addr - DRAM_BASE;
pop_tf(&tf);
}
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