blob: 078ecf2e6f4681469196916ca45e0ba67078b308 [file] [log] [blame] [raw]
/*
* RISCV emulator
*
* Copyright (c) 2016 Fabrice Bellard
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
#if XLEN == 32
#define uintx_t uint32_t
#define intx_t int32_t
#elif XLEN == 64
#define uintx_t uint64_t
#define intx_t int64_t
#elif XLEN == 128
#define uintx_t uint128_t
#define intx_t int128_t
#else
#error unsupported XLEN
#endif
static inline intx_t glue(div, XLEN)(intx_t a, intx_t b)
{
if (b == 0) {
return -1;
} else if (a == ((intx_t)1 << (XLEN - 1)) && b == -1) {
return a;
} else {
return a / b;
}
}
static inline uintx_t glue(divu, XLEN)(uintx_t a, uintx_t b)
{
if (b == 0) {
return -1;
} else {
return a / b;
}
}
static inline intx_t glue(rem, XLEN)(intx_t a, intx_t b)
{
if (b == 0) {
return a;
} else if (a == ((intx_t)1 << (XLEN - 1)) && b == -1) {
return 0;
} else {
return a % b;
}
}
static inline uintx_t glue(remu, XLEN)(uintx_t a, uintx_t b)
{
if (b == 0) {
return a;
} else {
return a % b;
}
}
#if XLEN == 32
static inline uint32_t mulh32(int32_t a, int32_t b)
{
return ((int64_t)a * (int64_t)b) >> 32;
}
static inline uint32_t mulhsu32(int32_t a, uint32_t b)
{
return ((int64_t)a * (int64_t)b) >> 32;
}
static inline uint32_t mulhu32(uint32_t a, uint32_t b)
{
return ((int64_t)a * (int64_t)b) >> 32;
}
#elif XLEN == 64 && defined(HAVE_INT128)
static inline uint64_t mulh64(int64_t a, int64_t b)
{
return ((int128_t)a * (int128_t)b) >> 64;
}
static inline uint64_t mulhsu64(int64_t a, uint64_t b)
{
return ((int128_t)a * (int128_t)b) >> 64;
}
static inline uint64_t mulhu64(uint64_t a, uint64_t b)
{
return ((int128_t)a * (int128_t)b) >> 64;
}
#else
#if XLEN == 64
#define UHALF uint32_t
#define UHALF_LEN 32
#elif XLEN == 128
#define UHALF uint64_t
#define UHALF_LEN 64
#else
#error unsupported XLEN
#endif
static uintx_t glue(mulhu, XLEN)(uintx_t a, uintx_t b)
{
UHALF a0, a1, b0, b1, r2, r3;
uintx_t r00, r01, r10, r11, c;
a0 = a;
a1 = a >> UHALF_LEN;
b0 = b;
b1 = b >> UHALF_LEN;
r00 = (uintx_t)a0 * (uintx_t)b0;
r01 = (uintx_t)a0 * (uintx_t)b1;
r10 = (uintx_t)a1 * (uintx_t)b0;
r11 = (uintx_t)a1 * (uintx_t)b1;
// r0 = r00;
c = (r00 >> UHALF_LEN) + (UHALF)r01 + (UHALF)r10;
// r1 = c;
c = (c >> UHALF_LEN) + (r01 >> UHALF_LEN) + (r10 >> UHALF_LEN) + (UHALF)r11;
r2 = c;
r3 = (c >> UHALF_LEN) + (r11 >> UHALF_LEN);
// *plow = ((uintx_t)r1 << UHALF_LEN) | r0;
return ((uintx_t)r3 << UHALF_LEN) | r2;
}
#undef UHALF
static inline uintx_t glue(mulh, XLEN)(intx_t a, intx_t b)
{
uintx_t r1;
r1 = glue(mulhu, XLEN)(a, b);
if (a < 0)
r1 -= a;
if (b < 0)
r1 -= b;
return r1;
}
static inline uintx_t glue(mulhsu, XLEN)(intx_t a, uintx_t b)
{
uintx_t r1;
r1 = glue(mulhu, XLEN)(a, b);
if (a < 0)
r1 -= a;
return r1;
}
#endif
#define DUP2(F, n) F(n) F(n+1)
#define DUP4(F, n) DUP2(F, n) DUP2(F, n + 2)
#define DUP8(F, n) DUP4(F, n) DUP4(F, n + 4)
#define DUP16(F, n) DUP8(F, n) DUP8(F, n + 8)
#define DUP32(F, n) DUP16(F, n) DUP16(F, n + 16)
#define C_QUADRANT(n) \
case n+(0 << 2): case n+(1 << 2): case n+(2 << 2): case n+(3 << 2): \
case n+(4 << 2): case n+(5 << 2): case n+(6 << 2): case n+(7 << 2): \
case n+(8 << 2): case n+(9 << 2): case n+(10 << 2): case n+(11 << 2): \
case n+(12 << 2): case n+(13 << 2): case n+(14 << 2): case n+(15 << 2): \
case n+(16 << 2): case n+(17 << 2): case n+(18 << 2): case n+(19 << 2): \
case n+(20 << 2): case n+(21 << 2): case n+(22 << 2): case n+(23 << 2): \
case n+(24 << 2): case n+(25 << 2): case n+(26 << 2): case n+(27 << 2): \
case n+(28 << 2): case n+(29 << 2): case n+(30 << 2): case n+(31 << 2):
#define GET_PC() (target_ulong)((uintptr_t)code_ptr + code_to_pc_addend)
#define GET_INSN_COUNTER() (insn_counter_addend - s->n_cycles)
#define C_NEXT_INSN code_ptr += 2; break
#define NEXT_INSN code_ptr += 4; break
#define JUMP_INSN do { \
code_ptr = NULL; \
code_end = NULL; \
code_to_pc_addend = s->pc; \
goto jump_insn; \
} while (0)
static void no_inline glue(riscv_cpu_interp_x, XLEN)(RISCVCPUState *s,
int n_cycles1)
{
uint32_t opcode, insn, rd, rs1, rs2, funct3;
int32_t imm, cond, err;
target_ulong addr, val, val2;
#ifndef USE_GLOBAL_VARIABLES
uint8_t *code_ptr, *code_end;
target_ulong code_to_pc_addend;
#endif
uint64_t insn_counter_addend;
#if FLEN > 0
uint32_t rs3;
int32_t rm;
#endif
if (n_cycles1 == 0)
return;
insn_counter_addend = s->insn_counter + n_cycles1;
s->n_cycles = n_cycles1;
/* check pending interrupts */
if (unlikely((s->mip & s->mie) != 0)) {
if (raise_interrupt(s)) {
s->n_cycles--;
goto done_interp;
}
}
s->pending_exception = -1;
/* Note: we assume NULL is represented as a zero number */
code_ptr = NULL;
code_end = NULL;
code_to_pc_addend = s->pc;
/* we use a single execution loop to keep a simple control flow
for emscripten */
for(;;) {
if (unlikely(code_ptr >= code_end)) {
uint32_t tlb_idx;
uint16_t insn_high;
target_ulong addr;
uint8_t *ptr;
s->pc = GET_PC();
/* we test n_cycles only between blocks so that timer
interrupts only happen between the blocks. It is
important to reduce the translated code size. */
if (unlikely(s->n_cycles <= 0))
goto the_end;
/* check pending interrupts */
if (unlikely((s->mip & s->mie) != 0)) {
if (raise_interrupt(s)) {
s->n_cycles--;
goto the_end;
}
}
addr = s->pc;
tlb_idx = (addr >> PG_SHIFT) & (TLB_SIZE - 1);
if (likely(s->tlb_code[tlb_idx].vaddr == (addr & ~PG_MASK))) {
/* TLB match */
ptr = (uint8_t *)(s->tlb_code[tlb_idx].mem_addend +
(uintptr_t)addr);
//fprintf(stderr, "TLB matches for address 0x%016llx\n", (unsigned long long int)ptr);
} else {
if (unlikely(target_read_insn_slow(s, &ptr, addr)))
goto mmu_exception;
}
code_ptr = ptr;
code_end = ptr + (PG_MASK - 1 - (addr & PG_MASK));
code_to_pc_addend = addr - (uintptr_t)code_ptr;
if (unlikely(code_ptr >= code_end)) {
/* instruction is potentially half way between two
pages ? */
insn = get_le16(code_ptr);
if ((insn & 3) == 3) {
/* instruction is half way between two pages */
if (unlikely(target_read_insn_u16(s, &insn_high, addr + 2)))
goto mmu_exception;
insn |= insn_high << 16;
}
} else {
insn = get_insn32(code_ptr);
}
} else {
/* fast path */
insn = get_insn32(code_ptr);
}
s->n_cycles--;
#ifdef DEBUG_RISCV_INTERPRETER
#ifdef CONFIG_LOGFILE
log_printf("pc=0x"); fprint_target_ulong(log_file, GET_PC()); log_printf(" insn=%08x\n", insn);
fflush(log_file);
#else
fputs("pc=0x", stderr); fprint_target_ulong(stderr, GET_PC()); fprintf(stderr, " insn=%08x\n", insn);
// dump_regs(s);
#endif
#endif
opcode = insn & 0x7f;
rd = (insn >> 7) & 0x1f;
rs1 = (insn >> 15) & 0x1f;
rs2 = (insn >> 20) & 0x1f;
switch(opcode) {
#ifdef CONFIG_EXT_C
C_QUADRANT(0)
funct3 = (insn >> 13) & 7;
rd = ((insn >> 2) & 7) | 8;
switch(funct3) {
case 0: /* c.addi4spn */
imm = get_field1(insn, 11, 4, 5) |
get_field1(insn, 7, 6, 9) |
get_field1(insn, 6, 2, 2) |
get_field1(insn, 5, 3, 3);
if (imm == 0)
goto illegal_insn;
s->reg[rd] = (intx_t)(s->reg[2] + imm);
break;
#if XLEN >= 128
case 1: /* c.lq */
imm = get_field1(insn, 11, 4, 5) |
get_field1(insn, 10, 8, 8) |
get_field1(insn, 5, 6, 7);
rs1 = ((insn >> 7) & 7) | 8;
addr = (intx_t)(s->reg[rs1] + imm);
if (target_read_u128(s, &val, addr))
goto mmu_exception;
s->reg[rd] = val;
break;
#elif FLEN >= 64
case 1: /* c.fld */
{
uint64_t rval;
if (s->fs == 0)
goto illegal_insn;
imm = get_field1(insn, 10, 3, 5) |
get_field1(insn, 5, 6, 7);
rs1 = ((insn >> 7) & 7) | 8;
addr = (intx_t)(s->reg[rs1] + imm);
if (target_read_u64(s, &rval, addr))
goto mmu_exception;
s->fp_reg[rd] = rval | F64_HIGH;
s->fs = 3;
}
break;
#endif
case 2: /* c.lw */
{
uint32_t rval;
imm = get_field1(insn, 10, 3, 5) |
get_field1(insn, 6, 2, 2) |
get_field1(insn, 5, 6, 6);
rs1 = ((insn >> 7) & 7) | 8;
addr = (intx_t)(s->reg[rs1] + imm);
if (target_read_u32(s, &rval, addr))
goto mmu_exception;
s->reg[rd] = (int32_t)rval;
}
break;
#if XLEN >= 64
case 3: /* c.ld */
{
uint64_t rval;
imm = get_field1(insn, 10, 3, 5) |
get_field1(insn, 5, 6, 7);
rs1 = ((insn >> 7) & 7) | 8;
addr = (intx_t)(s->reg[rs1] + imm);
if (target_read_u64(s, &rval, addr))
goto mmu_exception;
s->reg[rd] = (int64_t)rval;
}
break;
#elif FLEN >= 32
case 3: /* c.flw */
{
uint32_t rval;
if (s->fs == 0)
goto illegal_insn;
imm = get_field1(insn, 10, 3, 5) |
get_field1(insn, 6, 2, 2) |
get_field1(insn, 5, 6, 6);
rs1 = ((insn >> 7) & 7) | 8;
addr = (intx_t)(s->reg[rs1] + imm);
if (target_read_u32(s, &rval, addr))
goto mmu_exception;
s->fp_reg[rd] = rval | F32_HIGH;
s->fs = 3;
}
break;
#endif
#if XLEN >= 128
case 5: /* c.sq */
imm = get_field1(insn, 11, 4, 5) |
get_field1(insn, 10, 8, 8) |
get_field1(insn, 5, 6, 7);
rs1 = ((insn >> 7) & 7) | 8;
addr = (intx_t)(s->reg[rs1] + imm);
val = s->reg[rd];
if (target_write_u128(s, addr, val))
goto mmu_exception;
break;
#elif FLEN >= 64
case 5: /* c.fsd */
if (s->fs == 0)
goto illegal_insn;
imm = get_field1(insn, 10, 3, 5) |
get_field1(insn, 5, 6, 7);
rs1 = ((insn >> 7) & 7) | 8;
addr = (intx_t)(s->reg[rs1] + imm);
if (target_write_u64(s, addr, s->fp_reg[rd]))
goto mmu_exception;
break;
#endif
case 6: /* c.sw */
imm = get_field1(insn, 10, 3, 5) |
get_field1(insn, 6, 2, 2) |
get_field1(insn, 5, 6, 6);
rs1 = ((insn >> 7) & 7) | 8;
addr = (intx_t)(s->reg[rs1] + imm);
val = s->reg[rd];
if (target_write_u32(s, addr, val))
goto mmu_exception;
break;
#if XLEN >= 64
case 7: /* c.sd */
imm = get_field1(insn, 10, 3, 5) |
get_field1(insn, 5, 6, 7);
rs1 = ((insn >> 7) & 7) | 8;
addr = (intx_t)(s->reg[rs1] + imm);
val = s->reg[rd];
if (target_write_u64(s, addr, val))
goto mmu_exception;
break;
#elif FLEN >= 32
case 7: /* c.fsw */
if (s->fs == 0)
goto illegal_insn;
imm = get_field1(insn, 10, 3, 5) |
get_field1(insn, 6, 2, 2) |
get_field1(insn, 5, 6, 6);
rs1 = ((insn >> 7) & 7) | 8;
addr = (intx_t)(s->reg[rs1] + imm);
if (target_write_u32(s, addr, s->fp_reg[rd]))
goto mmu_exception;
break;
#endif
default:
goto illegal_insn;
}
C_NEXT_INSN;
C_QUADRANT(1)
funct3 = (insn >> 13) & 7;
switch(funct3) {
case 0: /* c.addi/c.nop */
if (rd != 0) {
imm = sext(get_field1(insn, 12, 5, 5) |
get_field1(insn, 2, 0, 4), 6);
s->reg[rd] = (intx_t)(s->reg[rd] + imm);
}
break;
#if XLEN == 32
case 1: /* c.jal */
imm = sext(get_field1(insn, 12, 11, 11) |
get_field1(insn, 11, 4, 4) |
get_field1(insn, 9, 8, 9) |
get_field1(insn, 8, 10, 10) |
get_field1(insn, 7, 6, 6) |
get_field1(insn, 6, 7, 7) |
get_field1(insn, 3, 1, 3) |
get_field1(insn, 2, 5, 5), 12);
s->reg[1] = GET_PC() + 2;
s->pc = (intx_t)(GET_PC() + imm);
JUMP_INSN;
#else
case 1: /* c.addiw */
if (rd != 0) {
imm = sext(get_field1(insn, 12, 5, 5) |
get_field1(insn, 2, 0, 4), 6);
s->reg[rd] = (int32_t)(s->reg[rd] + imm);
}
break;
#endif
case 2: /* c.li */
if (rd != 0) {
imm = sext(get_field1(insn, 12, 5, 5) |
get_field1(insn, 2, 0, 4), 6);
s->reg[rd] = imm;
}
break;
case 3:
if (rd == 2) {
/* c.addi16sp */
imm = sext(get_field1(insn, 12, 9, 9) |
get_field1(insn, 6, 4, 4) |
get_field1(insn, 5, 6, 6) |
get_field1(insn, 3, 7, 8) |
get_field1(insn, 2, 5, 5), 10);
if (imm == 0)
goto illegal_insn;
s->reg[2] = (intx_t)(s->reg[2] + imm);
} else if (rd != 0) {
/* c.lui */
imm = sext(get_field1(insn, 12, 17, 17) |
get_field1(insn, 2, 12, 16), 18);
s->reg[rd] = imm;
}
break;
case 4:
funct3 = (insn >> 10) & 3;
rd = ((insn >> 7) & 7) | 8;
switch(funct3) {
case 0: /* c.srli */
case 1: /* c.srai */
imm = get_field1(insn, 12, 5, 5) |
get_field1(insn, 2, 0, 4);
#if XLEN == 32
if (imm & 0x20)
goto illegal_insn;
#elif XLEN == 128
if (imm == 0)
imm = 64;
else if (imm >= 32)
imm = 128 - imm;
#endif
if (funct3 == 0)
s->reg[rd] = (intx_t)((uintx_t)s->reg[rd] >> imm);
else
s->reg[rd] = (intx_t)s->reg[rd] >> imm;
break;
case 2: /* c.andi */
imm = sext(get_field1(insn, 12, 5, 5) |
get_field1(insn, 2, 0, 4), 6);
s->reg[rd] &= imm;
break;
case 3:
rs2 = ((insn >> 2) & 7) | 8;
funct3 = ((insn >> 5) & 3) | ((insn >> (12 - 2)) & 4);
switch(funct3) {
case 0: /* c.sub */
s->reg[rd] = (intx_t)(s->reg[rd] - s->reg[rs2]);
break;
case 1: /* c.xor */
s->reg[rd] = s->reg[rd] ^ s->reg[rs2];
break;
case 2: /* c.or */
s->reg[rd] = s->reg[rd] | s->reg[rs2];
break;
case 3: /* c.and */
s->reg[rd] = s->reg[rd] & s->reg[rs2];
break;
#if XLEN >= 64
case 4: /* c.subw */
s->reg[rd] = (int32_t)(s->reg[rd] - s->reg[rs2]);
break;
case 5: /* c.addw */
s->reg[rd] = (int32_t)(s->reg[rd] + s->reg[rs2]);
break;
#endif
default:
goto illegal_insn;
}
break;
}
break;
case 5: /* c.j */
imm = sext(get_field1(insn, 12, 11, 11) |
get_field1(insn, 11, 4, 4) |
get_field1(insn, 9, 8, 9) |
get_field1(insn, 8, 10, 10) |
get_field1(insn, 7, 6, 6) |
get_field1(insn, 6, 7, 7) |
get_field1(insn, 3, 1, 3) |
get_field1(insn, 2, 5, 5), 12);
s->pc = (intx_t)(GET_PC() + imm);
JUMP_INSN;
case 6: /* c.beqz */
rs1 = ((insn >> 7) & 7) | 8;
imm = sext(get_field1(insn, 12, 8, 8) |
get_field1(insn, 10, 3, 4) |
get_field1(insn, 5, 6, 7) |
get_field1(insn, 3, 1, 2) |
get_field1(insn, 2, 5, 5), 9);
if (s->reg[rs1] == 0) {
s->pc = (intx_t)(GET_PC() + imm);
JUMP_INSN;
}
break;
case 7: /* c.bnez */
rs1 = ((insn >> 7) & 7) | 8;
imm = sext(get_field1(insn, 12, 8, 8) |
get_field1(insn, 10, 3, 4) |
get_field1(insn, 5, 6, 7) |
get_field1(insn, 3, 1, 2) |
get_field1(insn, 2, 5, 5), 9);
if (s->reg[rs1] != 0) {
s->pc = (intx_t)(GET_PC() + imm);
JUMP_INSN;
}
break;
default:
goto illegal_insn;
}
C_NEXT_INSN;
C_QUADRANT(2)
funct3 = (insn >> 13) & 7;
rs2 = (insn >> 2) & 0x1f;
switch(funct3) {
case 0: /* c.slli */
imm = get_field1(insn, 12, 5, 5) | rs2;
#if XLEN == 32
if (imm & 0x20)
goto illegal_insn;
#elif XLEN == 128
if (imm == 0)
imm = 64;
#endif
if (rd != 0)
s->reg[rd] = (intx_t)(s->reg[rd] << imm);
break;
#if XLEN == 128
case 1: /* c.lqsp */
imm = get_field1(insn, 12, 5, 5) |
(rs2 & (1 << 4)) |
get_field1(insn, 2, 6, 9);
addr = (intx_t)(s->reg[2] + imm);
if (target_read_u128(s, &val, addr))
goto mmu_exception;
if (rd != 0)
s->reg[rd] = val;
break;
#elif FLEN >= 64
case 1: /* c.fldsp */
{
uint64_t rval;
if (s->fs == 0)
goto illegal_insn;
imm = get_field1(insn, 12, 5, 5) |
(rs2 & (3 << 3)) |
get_field1(insn, 2, 6, 8);
addr = (intx_t)(s->reg[2] + imm);
if (target_read_u64(s, &rval, addr))
goto mmu_exception;
s->fp_reg[rd] = rval | F64_HIGH;
s->fs = 3;
}
break;
#endif
case 2: /* c.lwsp */
{
uint32_t rval;
imm = get_field1(insn, 12, 5, 5) |
(rs2 & (7 << 2)) |
get_field1(insn, 2, 6, 7);
addr = (intx_t)(s->reg[2] + imm);
if (target_read_u32(s, &rval, addr))
goto mmu_exception;
if (rd != 0)
s->reg[rd] = (int32_t)rval;
}
break;
#if XLEN >= 64
case 3: /* c.ldsp */
{
uint64_t rval;
imm = get_field1(insn, 12, 5, 5) |
(rs2 & (3 << 3)) |
get_field1(insn, 2, 6, 8);
addr = (intx_t)(s->reg[2] + imm);
if (target_read_u64(s, &rval, addr))
goto mmu_exception;
if (rd != 0)
s->reg[rd] = (int64_t)rval;
}
break;
#elif FLEN >= 32
case 3: /* c.flwsp */
{
uint32_t rval;
if (s->fs == 0)
goto illegal_insn;
imm = get_field1(insn, 12, 5, 5) |
(rs2 & (7 << 2)) |
get_field1(insn, 2, 6, 7);
addr = (intx_t)(s->reg[2] + imm);
if (target_read_u32(s, &rval, addr))
goto mmu_exception;
s->fp_reg[rd] = rval | F32_HIGH;
s->fs = 3;
}
break;
#endif
case 4:
if (((insn >> 12) & 1) == 0) {
if (rs2 == 0) {
/* c.jr */
if (rd == 0)
goto illegal_insn;
s->pc = s->reg[rd] & ~1;
JUMP_INSN;
} else {
/* c.mv */
if (rd != 0)
s->reg[rd] = s->reg[rs2];
}
} else {
if (rs2 == 0) {
if (rd == 0) {
/* c.ebreak */
s->pending_exception = CAUSE_BREAKPOINT;
goto exception;
} else {
/* c.jalr */
val = GET_PC() + 2;
s->pc = s->reg[rd] & ~1;
s->reg[1] = val;
JUMP_INSN;
}
} else {
if (rd != 0) {
s->reg[rd] = (intx_t)(s->reg[rd] + s->reg[rs2]);
}
}
}
break;
#if XLEN == 128
case 5: /* c.sqsp */
imm = get_field1(insn, 10, 3, 5) |
get_field1(insn, 7, 6, 8);
addr = (intx_t)(s->reg[2] + imm);
if (target_write_u128(s, addr, s->reg[rs2]))
goto mmu_exception;
break;
#elif FLEN >= 64
case 5: /* c.fsdsp */
if (s->fs == 0)
goto illegal_insn;
imm = get_field1(insn, 10, 3, 5) |
get_field1(insn, 7, 6, 8);
addr = (intx_t)(s->reg[2] + imm);
if (target_write_u64(s, addr, s->fp_reg[rs2]))
goto mmu_exception;
break;
#endif
case 6: /* c.swsp */
imm = get_field1(insn, 9, 2, 5) |
get_field1(insn, 7, 6, 7);
addr = (intx_t)(s->reg[2] + imm);
if (target_write_u32(s, addr, s->reg[rs2]))
goto mmu_exception;
break;
#if XLEN >= 64
case 7: /* c.sdsp */
imm = get_field1(insn, 10, 3, 5) |
get_field1(insn, 7, 6, 8);
addr = (intx_t)(s->reg[2] + imm);
if (target_write_u64(s, addr, s->reg[rs2]))
goto mmu_exception;
break;
#elif FLEN >= 32
case 7: /* c.swsp */
if (s->fs == 0)
goto illegal_insn;
imm = get_field1(insn, 9, 2, 5) |
get_field1(insn, 7, 6, 7);
addr = (intx_t)(s->reg[2] + imm);
if (target_write_u32(s, addr, s->fp_reg[rs2]))
goto mmu_exception;
break;
#endif
default:
goto illegal_insn;
}
C_NEXT_INSN;
#endif /* CONFIG_EXT_C */
case 0x37: /* lui */
if (rd != 0)
s->reg[rd] = (int32_t)(insn & 0xfffff000);
NEXT_INSN;
case 0x17: /* auipc */
if (rd != 0)
s->reg[rd] = (intx_t)(GET_PC() + (int32_t)(insn & 0xfffff000));
NEXT_INSN;
case 0x6f: /* jal */
imm = ((insn >> (31 - 20)) & (1 << 20)) |
((insn >> (21 - 1)) & 0x7fe) |
((insn >> (20 - 11)) & (1 << 11)) |
(insn & 0xff000);
imm = (imm << 11) >> 11;
if (rd != 0)
s->reg[rd] = GET_PC() + 4;
s->pc = (intx_t)(GET_PC() + imm);
JUMP_INSN;
case 0x67: /* jalr */
imm = (int32_t)insn >> 20;
val = GET_PC() + 4;
s->pc = (intx_t)(s->reg[rs1] + imm) & ~1;
if (rd != 0)
s->reg[rd] = val;
JUMP_INSN;
case 0x63:
funct3 = (insn >> 12) & 7;
switch(funct3 >> 1) {
case 0: /* beq/bne */
cond = (s->reg[rs1] == s->reg[rs2]);
break;
case 2: /* blt/bge */
cond = ((target_long)s->reg[rs1] < (target_long)s->reg[rs2]);
break;
case 3: /* bltu/bgeu */
cond = (s->reg[rs1] < s->reg[rs2]);
break;
default:
goto illegal_insn;
}
cond ^= (funct3 & 1);
if (cond) {
imm = ((insn >> (31 - 12)) & (1 << 12)) |
((insn >> (25 - 5)) & 0x7e0) |
((insn >> (8 - 1)) & 0x1e) |
((insn << (11 - 7)) & (1 << 11));
imm = (imm << 19) >> 19;
s->pc = (intx_t)(GET_PC() + imm);
JUMP_INSN;
}
NEXT_INSN;
case 0x03: /* load */
funct3 = (insn >> 12) & 7;
imm = (int32_t)insn >> 20;
addr = s->reg[rs1] + imm;
switch(funct3) {
case 0: /* lb */
{
uint8_t rval;
if (target_read_u8(s, &rval, addr))
goto mmu_exception;
val = (int8_t)rval;
}
break;
case 1: /* lh */
{
uint16_t rval;
if (target_read_u16(s, &rval, addr))
goto mmu_exception;
val = (int16_t)rval;
}
break;
case 2: /* lw */
{
uint32_t rval;
if (target_read_u32(s, &rval, addr))
goto mmu_exception;
val = (int32_t)rval;
}
break;
case 4: /* lbu */
{
uint8_t rval;
if (target_read_u8(s, &rval, addr))
goto mmu_exception;
val = rval;
}
break;
case 5: /* lhu */
{
uint16_t rval;
if (target_read_u16(s, &rval, addr))
goto mmu_exception;
val = rval;
}
break;
#if XLEN >= 64
case 3: /* ld */
{
uint64_t rval;
if (target_read_u64(s, &rval, addr))
goto mmu_exception;
val = (int64_t)rval;
}
break;
case 6: /* lwu */
{
uint32_t rval;
if (target_read_u32(s, &rval, addr))
goto mmu_exception;
val = rval;
}
break;
#endif
#if XLEN >= 128
case 7: /* ldu */
{
uint64_t rval;
if (target_read_u64(s, &rval, addr))
goto mmu_exception;
val = rval;
}
break;
#endif
default:
goto illegal_insn;
}
if (rd != 0)
s->reg[rd] = val;
NEXT_INSN;
case 0x23: /* store */
funct3 = (insn >> 12) & 7;
imm = rd | ((insn >> (25 - 5)) & 0xfe0);
imm = (imm << 20) >> 20;
addr = s->reg[rs1] + imm;
val = s->reg[rs2];
switch(funct3) {
case 0: /* sb */
if (target_write_u8(s, addr, val))
goto mmu_exception;
break;
case 1: /* sh */
if (target_write_u16(s, addr, val))
goto mmu_exception;
break;
case 2: /* sw */
if (target_write_u32(s, addr, val))
goto mmu_exception;
break;
#if XLEN >= 64
case 3: /* sd */
if (target_write_u64(s, addr, val))
goto mmu_exception;
break;
#endif
#if XLEN >= 128
case 4: /* sq */
if (target_write_u128(s, addr, val))
goto mmu_exception;
break;
#endif
default:
goto illegal_insn;
}
NEXT_INSN;
case 0x13:
funct3 = (insn >> 12) & 7;
imm = (int32_t)insn >> 20;
switch(funct3) {
case 0: /* addi */
val = (intx_t)(s->reg[rs1] + imm);
break;
case 1: /* slli */
if ((imm & ~(XLEN - 1)) != 0)
goto illegal_insn;
val = (intx_t)(s->reg[rs1] << (imm & (XLEN - 1)));
break;
case 2: /* slti */
val = (target_long)s->reg[rs1] < (target_long)imm;
break;
case 3: /* sltiu */
val = s->reg[rs1] < (target_ulong)imm;
break;
case 4: /* xori */
val = s->reg[rs1] ^ imm;
break;
case 5: /* srli/srai */
if ((imm & ~((XLEN - 1) | 0x400)) != 0)
goto illegal_insn;
if (imm & 0x400)
val = (intx_t)s->reg[rs1] >> (imm & (XLEN - 1));
else
val = (intx_t)((uintx_t)s->reg[rs1] >> (imm & (XLEN - 1)));
break;
case 6: /* ori */
val = s->reg[rs1] | imm;
break;
default:
case 7: /* andi */
val = s->reg[rs1] & imm;
break;
}
if (rd != 0)
s->reg[rd] = val;
NEXT_INSN;
#if XLEN >= 64
case 0x1b:/* OP-IMM-32 */
funct3 = (insn >> 12) & 7;
imm = (int32_t)insn >> 20;
val = s->reg[rs1];
switch(funct3) {
case 0: /* addiw */
val = (int32_t)(val + imm);
break;
case 1: /* slliw */
if ((imm & ~31) != 0)
goto illegal_insn;
val = (int32_t)(val << (imm & 31));
break;
case 5: /* srliw/sraiw */
if ((imm & ~(31 | 0x400)) != 0)
goto illegal_insn;
if (imm & 0x400)
val = (int32_t)val >> (imm & 31);
else
val = (int32_t)((uint32_t)val >> (imm & 31));
break;
default:
goto illegal_insn;
}
if (rd != 0)
s->reg[rd] = val;
NEXT_INSN;
#endif
#if XLEN >= 128
case 0x5b: /* OP-IMM-64 */
funct3 = (insn >> 12) & 7;
imm = (int32_t)insn >> 20;
val = s->reg[rs1];
switch(funct3) {
case 0: /* addid */
val = (int64_t)(val + imm);
break;
case 1: /* sllid */
if ((imm & ~63) != 0)
goto illegal_insn;
val = (int64_t)(val << (imm & 63));
break;
case 5: /* srlid/sraid */
if ((imm & ~(63 | 0x400)) != 0)
goto illegal_insn;
if (imm & 0x400)
val = (int64_t)val >> (imm & 63);
else
val = (int64_t)((uint64_t)val >> (imm & 63));
break;
default:
goto illegal_insn;
}
if (rd != 0)
s->reg[rd] = val;
NEXT_INSN;
#endif
case 0x33:
imm = insn >> 25;
val = s->reg[rs1];
val2 = s->reg[rs2];
if (imm == 1) {
funct3 = (insn >> 12) & 7;
switch(funct3) {
case 0: /* mul */
val = (intx_t)((intx_t)val * (intx_t)val2);
break;
case 1: /* mulh */
val = (intx_t)glue(mulh, XLEN)(val, val2);
break;
case 2:/* mulhsu */
val = (intx_t)glue(mulhsu, XLEN)(val, val2);
break;
case 3:/* mulhu */
val = (intx_t)glue(mulhu, XLEN)(val, val2);
break;
case 4:/* div */
val = glue(div, XLEN)(val, val2);
break;
case 5:/* divu */
val = (intx_t)glue(divu, XLEN)(val, val2);
break;
case 6:/* rem */
val = glue(rem, XLEN)(val, val2);
break;
case 7:/* remu */
val = (intx_t)glue(remu, XLEN)(val, val2);
break;
default:
goto illegal_insn;
}
} else {
if (imm & ~0x20)
goto illegal_insn;
funct3 = ((insn >> 12) & 7) | ((insn >> (30 - 3)) & (1 << 3));
switch(funct3) {
case 0: /* add */
val = (intx_t)(val + val2);
break;
case 0 | 8: /* sub */
val = (intx_t)(val - val2);
break;
case 1: /* sll */
val = (intx_t)(val << (val2 & (XLEN - 1)));
break;
case 2: /* slt */
val = (target_long)val < (target_long)val2;
break;
case 3: /* sltu */
val = val < val2;
break;
case 4: /* xor */
val = val ^ val2;
break;
case 5: /* srl */
val = (intx_t)((uintx_t)val >> (val2 & (XLEN - 1)));
break;
case 5 | 8: /* sra */
val = (intx_t)val >> (val2 & (XLEN - 1));
break;
case 6: /* or */
val = val | val2;
break;
case 7: /* and */
val = val & val2;
break;
default:
goto illegal_insn;
}
}
if (rd != 0)
s->reg[rd] = val;
NEXT_INSN;
#if XLEN >= 64
case 0x3b: /* OP-32 */
imm = insn >> 25;
val = s->reg[rs1];
val2 = s->reg[rs2];
if (imm == 1) {
funct3 = (insn >> 12) & 7;
switch(funct3) {
case 0: /* mulw */
val = (int32_t)((int32_t)val * (int32_t)val2);
break;
case 4:/* divw */
val = div32(val, val2);
break;
case 5:/* divuw */
val = (int32_t)divu32(val, val2);
break;
case 6:/* remw */
val = rem32(val, val2);
break;
case 7:/* remuw */
val = (int32_t)remu32(val, val2);
break;
default:
goto illegal_insn;
}
} else {
if (imm & ~0x20)
goto illegal_insn;
funct3 = ((insn >> 12) & 7) | ((insn >> (30 - 3)) & (1 << 3));
switch(funct3) {
case 0: /* addw */
val = (int32_t)(val + val2);
break;
case 0 | 8: /* subw */
val = (int32_t)(val - val2);
break;
case 1: /* sllw */
val = (int32_t)((uint32_t)val << (val2 & 31));
break;
case 5: /* srlw */
val = (int32_t)((uint32_t)val >> (val2 & 31));
break;
case 5 | 8: /* sraw */
val = (int32_t)val >> (val2 & 31);
break;
default:
goto illegal_insn;
}
}
if (rd != 0)
s->reg[rd] = val;
NEXT_INSN;
#endif
#if XLEN >= 128
case 0x7b: /* OP-64 */
imm = insn >> 25;
val = s->reg[rs1];
val2 = s->reg[rs2];
if (imm == 1) {
funct3 = (insn >> 12) & 7;
switch(funct3) {
case 0: /* muld */
val = (int64_t)((int64_t)val * (int64_t)val2);
break;
case 4:/* divd */
val = div64(val, val2);
break;
case 5:/* divud */
val = (int64_t)divu64(val, val2);
break;
case 6:/* remd */
val = rem64(val, val2);
break;
case 7:/* remud */
val = (int64_t)remu64(val, val2);
break;
default:
goto illegal_insn;
}
} else {
if (imm & ~0x20)
goto illegal_insn;
funct3 = ((insn >> 12) & 7) | ((insn >> (30 - 3)) & (1 << 3));
switch(funct3) {
case 0: /* addd */
val = (int64_t)(val + val2);
break;
case 0 | 8: /* subd */
val = (int64_t)(val - val2);
break;
case 1: /* slld */
val = (int64_t)((uint64_t)val << (val2 & 63));
break;
case 5: /* srld */
val = (int64_t)((uint64_t)val >> (val2 & 63));
break;
case 5 | 8: /* srad */
val = (int64_t)val >> (val2 & 63);
break;
default:
goto illegal_insn;
}
}
if (rd != 0)
s->reg[rd] = val;
NEXT_INSN;
#endif
case 0x73:
funct3 = (insn >> 12) & 7;
imm = insn >> 20;
if (funct3 & 4)
val = rs1;
else
val = s->reg[rs1];
funct3 &= 3;
switch(funct3) {
case 1: /* csrrw */
s->insn_counter = GET_INSN_COUNTER();
if (csr_read(s, &val2, imm, TRUE))
goto illegal_insn;
val2 = (intx_t)val2;
err = csr_write(s, imm, val);
if (err < 0)
goto illegal_insn;
if (rd != 0)
s->reg[rd] = val2;
if (err > 0) {
s->pc = GET_PC() + 4;
if (err == 2)
JUMP_INSN;
else
goto done_interp;
}
break;
case 2: /* csrrs */
case 3: /* csrrc */
s->insn_counter = GET_INSN_COUNTER();
if (csr_read(s, &val2, imm, (rs1 != 0)))
goto illegal_insn;
val2 = (intx_t)val2;
if (rs1 != 0) {
if (funct3 == 2)
val = val2 | val;
else
val = val2 & ~val;
err = csr_write(s, imm, val);
if (err < 0)
goto illegal_insn;
} else {
err = 0;
}
if (rd != 0)
s->reg[rd] = val2;
if (err > 0) {
s->pc = GET_PC() + 4;
if (err == 2)
JUMP_INSN;
else
goto done_interp;
}
break;
case 0:
switch(imm) {
case 0x000: /* ecall */
if (insn & 0x000fff80)
goto illegal_insn;
s->pending_exception = CAUSE_USER_ECALL + s->priv;
goto exception;
case 0x001: /* ebreak */
if (insn & 0x000fff80)
goto illegal_insn;
s->pending_exception = CAUSE_BREAKPOINT;
goto exception;
case 0x102: /* sret */
{
if (insn & 0x000fff80)
goto illegal_insn;
if (s->priv < PRV_S)
goto illegal_insn;
s->pc = GET_PC();
handle_sret(s);
goto done_interp;
}
break;
case 0x302: /* mret */
{
if (insn & 0x000fff80)
goto illegal_insn;
if (s->priv < PRV_M)
goto illegal_insn;
s->pc = GET_PC();
handle_mret(s);
goto done_interp;
}
break;
case 0x105: /* wfi */
if (insn & 0x00007f80)
goto illegal_insn;
if (s->priv == PRV_U)
goto illegal_insn;
/* go to power down if no enabled interrupts are
pending */
if ((s->mip & s->mie) == 0) {
s->power_down_flag = TRUE;
s->pc = GET_PC() + 4;
goto done_interp;
}
break;
default:
if ((imm >> 5) == 0x09) {
/* sfence.vma */
if (insn & 0x00007f80)
goto illegal_insn;
if (s->priv == PRV_U)
goto illegal_insn;
if (rs1 == 0) {
tlb_flush_all(s);
} else {
tlb_flush_vaddr(s, s->reg[rs1]);
}
/* the current code TLB may have been flushed */
s->pc = GET_PC() + 4;
JUMP_INSN;
} else {
goto illegal_insn;
}
break;
}
break;
default:
goto illegal_insn;
}
NEXT_INSN;
case 0x0f: /* misc-mem */
funct3 = (insn >> 12) & 7;
switch(funct3) {
case 0: /* fence */
if (insn & 0xf00fff80)
goto illegal_insn;
break;
case 1: /* fence.i */
if (insn != 0x0000100f)
goto illegal_insn;
break;
#if XLEN >= 128
case 2: /* lq */
imm = (int32_t)insn >> 20;
addr = s->reg[rs1] + imm;
if (target_read_u128(s, &val, addr))
goto mmu_exception;
if (rd != 0)
s->reg[rd] = val;
break;
#endif
default:
goto illegal_insn;
}
NEXT_INSN;
case 0x2f:
funct3 = (insn >> 12) & 7;
#define OP_A(size) \
{ \
uint ## size ##_t rval; \
\
addr = s->reg[rs1]; \
funct3 = insn >> 27; \
switch(funct3) { \
case 2: /* lr.w */ \
if (rs2 != 0) \
goto illegal_insn; \
if (target_read_u ## size(s, &rval, addr)) \
goto mmu_exception; \
val = (int## size ## _t)rval; \
s->load_res = addr; \
break; \
case 3: /* sc.w */ \
if (s->load_res == addr) { \
if (target_write_u ## size(s, addr, s->reg[rs2])) \
goto mmu_exception; \
val = 0; \
} else { \
val = 1; \
} \
break; \
case 1: /* amiswap.w */ \
case 0: /* amoadd.w */ \
case 4: /* amoxor.w */ \
case 0xc: /* amoand.w */ \
case 0x8: /* amoor.w */ \
case 0x10: /* amomin.w */ \
case 0x14: /* amomax.w */ \
case 0x18: /* amominu.w */ \
case 0x1c: /* amomaxu.w */ \
if (target_read_u ## size(s, &rval, addr)) \
goto mmu_exception; \
val = (int## size ## _t)rval; \
val2 = s->reg[rs2]; \
switch(funct3) { \
case 1: /* amiswap.w */ \
break; \
case 0: /* amoadd.w */ \
val2 = (int## size ## _t)(val + val2); \
break; \
case 4: /* amoxor.w */ \
val2 = (int## size ## _t)(val ^ val2); \
break; \
case 0xc: /* amoand.w */ \
val2 = (int## size ## _t)(val & val2); \
break; \
case 0x8: /* amoor.w */ \
val2 = (int## size ## _t)(val | val2); \
break; \
case 0x10: /* amomin.w */ \
if ((int## size ## _t)val < (int## size ## _t)val2) \
val2 = (int## size ## _t)val; \
break; \
case 0x14: /* amomax.w */ \
if ((int## size ## _t)val > (int## size ## _t)val2) \
val2 = (int## size ## _t)val; \
break; \
case 0x18: /* amominu.w */ \
if ((uint## size ## _t)val < (uint## size ## _t)val2) \
val2 = (int## size ## _t)val; \
break; \
case 0x1c: /* amomaxu.w */ \
if ((uint## size ## _t)val > (uint## size ## _t)val2) \
val2 = (int## size ## _t)val; \
break; \
default: \
goto illegal_insn; \
} \
if (target_write_u ## size(s, addr, val2)) \
goto mmu_exception; \
break; \
default: \
goto illegal_insn; \
} \
}
switch(funct3) {
case 2:
OP_A(32);
break;
#if XLEN >= 64
case 3:
OP_A(64);
break;
#endif
#if XLEN >= 128
case 4:
OP_A(128);
break;
#endif
default:
goto illegal_insn;
}
if (rd != 0)
s->reg[rd] = val;
NEXT_INSN;
#if FLEN > 0
/* FPU */
case 0x07: /* fp load */
if (s->fs == 0)
goto illegal_insn;
funct3 = (insn >> 12) & 7;
imm = (int32_t)insn >> 20;
addr = s->reg[rs1] + imm;
switch(funct3) {
case 2: /* flw */
{
uint32_t rval;
if (target_read_u32(s, &rval, addr))
goto mmu_exception;
s->fp_reg[rd] = rval | F32_HIGH;
}
break;
#if FLEN >= 64
case 3: /* fld */
{
uint64_t rval;
if (target_read_u64(s, &rval, addr))
goto mmu_exception;
s->fp_reg[rd] = rval | F64_HIGH;
}
break;
#endif
#if FLEN >= 128
case 4: /* flq */
{
uint128_t rval;
if (target_read_u128(s, &rval, addr))
goto mmu_exception;
s->fp_reg[rd] = rval;
}
break;
#endif
default:
goto illegal_insn;
}
s->fs = 3;
NEXT_INSN;
case 0x27: /* fp store */
if (s->fs == 0)
goto illegal_insn;
funct3 = (insn >> 12) & 7;
imm = rd | ((insn >> (25 - 5)) & 0xfe0);
imm = (imm << 20) >> 20;
addr = s->reg[rs1] + imm;
switch(funct3) {
case 2: /* fsw */
if (target_write_u32(s, addr, s->fp_reg[rs2]))
goto mmu_exception;
break;
#if FLEN >= 64
case 3: /* fsd */
if (target_write_u64(s, addr, s->fp_reg[rs2]))
goto mmu_exception;
break;
#endif
#if FLEN >= 128
case 4: /* fsq */
if (target_write_u128(s, addr, s->fp_reg[rs2]))
goto mmu_exception;
break;
#endif
default:
goto illegal_insn;
}
NEXT_INSN;
case 0x43: /* fmadd */
if (s->fs == 0)
goto illegal_insn;
funct3 = (insn >> 25) & 3;
rs3 = insn >> 27;
rm = get_insn_rm(s, (insn >> 12) & 7);
if (rm < 0)
goto illegal_insn;
switch(funct3) {
case 0:
s->fp_reg[rd] = fma_sf32(s->fp_reg[rs1], s->fp_reg[rs2],
s->fp_reg[rs3], rm, &s->fflags) | F32_HIGH;
break;
#if FLEN >= 64
case 1:
s->fp_reg[rd] = fma_sf64(s->fp_reg[rs1], s->fp_reg[rs2],
s->fp_reg[rs3], rm, &s->fflags) | F64_HIGH;
break;
#endif
#if FLEN >= 128
case 3:
s->fp_reg[rd] = fma_sf128(s->fp_reg[rs1], s->fp_reg[rs2],
s->fp_reg[rs3], rm, &s->fflags);
break;
#endif
default:
goto illegal_insn;
}
s->fs = 3;
NEXT_INSN;
case 0x47: /* fmsub */
if (s->fs == 0)
goto illegal_insn;
funct3 = (insn >> 25) & 3;
rs3 = insn >> 27;
rm = get_insn_rm(s, (insn >> 12) & 7);
if (rm < 0)
goto illegal_insn;
switch(funct3) {
case 0:
s->fp_reg[rd] = fma_sf32(s->fp_reg[rs1],
s->fp_reg[rs2],
s->fp_reg[rs3] ^ FSIGN_MASK32,
rm, &s->fflags) | F32_HIGH;
break;
#if FLEN >= 64
case 1:
s->fp_reg[rd] = fma_sf64(s->fp_reg[rs1],
s->fp_reg[rs2],
s->fp_reg[rs3] ^ FSIGN_MASK64,
rm, &s->fflags) | F64_HIGH;
break;
#endif
#if FLEN >= 128
case 3:
s->fp_reg[rd] = fma_sf128(s->fp_reg[rs1],
s->fp_reg[rs2],
s->fp_reg[rs3] ^ FSIGN_MASK128,
rm, &s->fflags);
break;
#endif
default:
goto illegal_insn;
}
s->fs = 3;
NEXT_INSN;
case 0x4b: /* fnmsub */
if (s->fs == 0)
goto illegal_insn;
funct3 = (insn >> 25) & 3;
rs3 = insn >> 27;
rm = get_insn_rm(s, (insn >> 12) & 7);
if (rm < 0)
goto illegal_insn;
switch(funct3) {
case 0:
s->fp_reg[rd] = fma_sf32(s->fp_reg[rs1] ^ FSIGN_MASK32,
s->fp_reg[rs2],
s->fp_reg[rs3],
rm, &s->fflags) | F32_HIGH;
break;
#if FLEN >= 64
case 1:
s->fp_reg[rd] = fma_sf64(s->fp_reg[rs1] ^ FSIGN_MASK64,
s->fp_reg[rs2],
s->fp_reg[rs3],
rm, &s->fflags) | F64_HIGH;
break;
#endif
#if FLEN >= 128
case 3:
s->fp_reg[rd] = fma_sf128(s->fp_reg[rs1] ^ FSIGN_MASK128,
s->fp_reg[rs2],
s->fp_reg[rs3],
rm, &s->fflags);
break;
#endif
default:
goto illegal_insn;
}
s->fs = 3;
NEXT_INSN;
case 0x4f: /* fnmadd */
if (s->fs == 0)
goto illegal_insn;
funct3 = (insn >> 25) & 3;
rs3 = insn >> 27;
rm = get_insn_rm(s, (insn >> 12) & 7);
if (rm < 0)
goto illegal_insn;
switch(funct3) {
case 0:
s->fp_reg[rd] = fma_sf32(s->fp_reg[rs1] ^ FSIGN_MASK32,
s->fp_reg[rs2],
s->fp_reg[rs3] ^ FSIGN_MASK32,
rm, &s->fflags) | F32_HIGH;
break;
#if FLEN >= 64
case 1:
s->fp_reg[rd] = fma_sf64(s->fp_reg[rs1] ^ FSIGN_MASK64,
s->fp_reg[rs2],
s->fp_reg[rs3] ^ FSIGN_MASK64,
rm, &s->fflags) | F64_HIGH;
break;
#endif
#if FLEN >= 128
case 3:
s->fp_reg[rd] = fma_sf128(s->fp_reg[rs1] ^ FSIGN_MASK128,
s->fp_reg[rs2],
s->fp_reg[rs3] ^ FSIGN_MASK128,
rm, &s->fflags);
break;
#endif
default:
goto illegal_insn;
}
s->fs = 3;
NEXT_INSN;
case 0x53:
if (s->fs == 0)
goto illegal_insn;
imm = insn >> 25;
rm = (insn >> 12) & 7;
switch(imm) {
#define F_SIZE 32
#include "riscv_cpu_fp_template.h"
#if FLEN >= 64
#define F_SIZE 64
#include "riscv_cpu_fp_template.h"
#endif
#if FLEN >= 128
#define F_SIZE 128
#include "riscv_cpu_fp_template.h"
#endif
default:
goto illegal_insn;
}
NEXT_INSN;
#endif
default:
goto illegal_insn;
}
/* update PC for next instruction */
jump_insn: ;
} /* end of main loop */
illegal_insn:
s->pending_exception = CAUSE_ILLEGAL_INSTRUCTION;
s->pending_tval = insn;
mmu_exception:
exception:
s->pc = GET_PC();
if (s->pending_exception >= 0) {
/* Note: the idea is that one exception counts for one cycle. */
s->n_cycles--;
raise_exception2(s, s->pending_exception, s->pending_tval);
}
/* we exit because XLEN may have changed */
done_interp:
the_end:
s->insn_counter = GET_INSN_COUNTER();
#if 0
printf("done interp %lx int=%x mstatus=%lx prv=%d\n",
(uint64_t)s->insn_counter, s->mip & s->mie, (uint64_t)s->mstatus,
s->priv);
#endif
}
#undef uintx_t
#undef intx_t
#undef XLEN
#undef OP_A