v8/test/cctest/test-assembler-mips64.cc
Clemens Hammacher 5f6510825a [cleanup] Fix remaining (D)CHECK macro usages
This CL fixes all occurences that don't require special OWNER reviews,
or can be reviewed by Michi.

After this one, we should be able to reenable the readability/check
cpplint check.

R=mstarzinger@chromium.org

Bug: v8:6837, v8:6921
Cq-Include-Trybots: master.tryserver.chromium.linux:linux_chromium_rel_ng;master.tryserver.v8:v8_linux_noi18n_rel_ng
Change-Id: Ic81d68d5534eaa795b7197fed5c41ed158361d62
Reviewed-on: https://chromium-review.googlesource.com/721120
Commit-Queue: Clemens Hammacher <clemensh@chromium.org>
Reviewed-by: Michael Starzinger <mstarzinger@chromium.org>
Cr-Commit-Position: refs/heads/master@{#48670}
2017-10-18 10:12:31 +00:00

11023 lines
385 KiB
C++

// Copyright 2012 the V8 project authors. All rights reserved.
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * 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.
// * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived
// from this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS 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 COPYRIGHT
// OWNER 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 <iostream> // NOLINT(readability/streams)
#include "src/v8.h"
#include "src/assembler-inl.h"
#include "src/base/utils/random-number-generator.h"
#include "src/disassembler.h"
#include "src/factory.h"
#include "src/macro-assembler.h"
#include "src/mips64/macro-assembler-mips64.h"
#include "src/mips64/simulator-mips64.h"
#include "test/cctest/cctest.h"
namespace v8 {
namespace internal {
// Define these function prototypes to match JSEntryFunction in execution.cc.
typedef Object* (*F1)(int x, int p1, int p2, int p3, int p4);
typedef Object* (*F2)(int x, int y, int p2, int p3, int p4);
typedef Object* (*F3)(void* p, int p1, int p2, int p3, int p4);
typedef Object* (*F4)(int64_t x, int64_t y, int64_t p2, int64_t p3, int64_t p4);
typedef Object* (*F5)(void* p0, void* p1, int p2, int p3, int p4);
#define __ assm.
TEST(MIPS0) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
// Addition.
__ addu(v0, a0, a1);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
int64_t res = reinterpret_cast<int64_t>(
CALL_GENERATED_CODE(isolate, f, 0xab0, 0xc, 0, 0, 0));
CHECK_EQ(0xabcL, res);
}
TEST(MIPS1) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
Label L, C;
__ mov(a1, a0);
__ li(v0, 0);
__ b(&C);
__ nop();
__ bind(&L);
__ addu(v0, v0, a1);
__ addiu(a1, a1, -1);
__ bind(&C);
__ xori(v1, a1, 0);
__ Branch(&L, ne, v1, Operand((int64_t)0));
__ nop();
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F1 f = FUNCTION_CAST<F1>(code->entry());
int64_t res = reinterpret_cast<int64_t>(
CALL_GENERATED_CODE(isolate, f, 50, 0, 0, 0, 0));
CHECK_EQ(1275L, res);
}
TEST(MIPS2) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
Label exit, error;
// ----- Test all instructions.
// Test lui, ori, and addiu, used in the li pseudo-instruction.
// This way we can then safely load registers with chosen values.
__ ori(a4, zero_reg, 0);
__ lui(a4, 0x1234);
__ ori(a4, a4, 0);
__ ori(a4, a4, 0x0f0f);
__ ori(a4, a4, 0xf0f0);
__ addiu(a5, a4, 1);
__ addiu(a6, a5, -0x10);
// Load values in temporary registers.
__ li(a4, 0x00000004);
__ li(a5, 0x00001234);
__ li(a6, 0x12345678);
__ li(a7, 0x7fffffff);
__ li(t0, 0xfffffffc);
__ li(t1, 0xffffedcc);
__ li(t2, 0xedcba988);
__ li(t3, 0x80000000);
// SPECIAL class.
__ srl(v0, a6, 8); // 0x00123456
__ sll(v0, v0, 11); // 0x91a2b000
__ sra(v0, v0, 3); // 0xf2345600
__ srav(v0, v0, a4); // 0xff234560
__ sllv(v0, v0, a4); // 0xf2345600
__ srlv(v0, v0, a4); // 0x0f234560
__ Branch(&error, ne, v0, Operand(0x0f234560));
__ nop();
__ addu(v0, a4, a5); // 0x00001238
__ subu(v0, v0, a4); // 0x00001234
__ Branch(&error, ne, v0, Operand(0x00001234));
__ nop();
__ addu(v1, a7, a4); // 32bit addu result is sign-extended into 64bit reg.
__ Branch(&error, ne, v1, Operand(0xffffffff80000003));
__ nop();
__ subu(v1, t3, a4); // 0x7ffffffc
__ Branch(&error, ne, v1, Operand(0x7ffffffc));
__ nop();
__ and_(v0, a5, a6); // 0x0000000000001230
__ or_(v0, v0, a5); // 0x0000000000001234
__ xor_(v0, v0, a6); // 0x000000001234444c
__ nor(v0, v0, a6); // 0xffffffffedcba987
__ Branch(&error, ne, v0, Operand(0xffffffffedcba983));
__ nop();
// Shift both 32bit number to left, to preserve meaning of next comparison.
__ dsll32(a7, a7, 0);
__ dsll32(t3, t3, 0);
__ slt(v0, t3, a7);
__ Branch(&error, ne, v0, Operand(0x1));
__ nop();
__ sltu(v0, t3, a7);
__ Branch(&error, ne, v0, Operand(zero_reg));
__ nop();
// Restore original values in registers.
__ dsrl32(a7, a7, 0);
__ dsrl32(t3, t3, 0);
// End of SPECIAL class.
__ addiu(v0, zero_reg, 0x7421); // 0x00007421
__ addiu(v0, v0, -0x1); // 0x00007420
__ addiu(v0, v0, -0x20); // 0x00007400
__ Branch(&error, ne, v0, Operand(0x00007400));
__ nop();
__ addiu(v1, a7, 0x1); // 0x80000000 - result is sign-extended.
__ Branch(&error, ne, v1, Operand(0xffffffff80000000));
__ nop();
__ slti(v0, a5, 0x00002000); // 0x1
__ slti(v0, v0, 0xffff8000); // 0x0
__ Branch(&error, ne, v0, Operand(zero_reg));
__ nop();
__ sltiu(v0, a5, 0x00002000); // 0x1
__ sltiu(v0, v0, 0x00008000); // 0x1
__ Branch(&error, ne, v0, Operand(0x1));
__ nop();
__ andi(v0, a5, 0xf0f0); // 0x00001030
__ ori(v0, v0, 0x8a00); // 0x00009a30
__ xori(v0, v0, 0x83cc); // 0x000019fc
__ Branch(&error, ne, v0, Operand(0x000019fc));
__ nop();
__ lui(v1, 0x8123); // Result is sign-extended into 64bit register.
__ Branch(&error, ne, v1, Operand(0xffffffff81230000));
__ nop();
// Bit twiddling instructions & conditional moves.
// Uses a4-t3 as set above.
__ Clz(v0, a4); // 29
__ Clz(v1, a5); // 19
__ addu(v0, v0, v1); // 48
__ Clz(v1, a6); // 3
__ addu(v0, v0, v1); // 51
__ Clz(v1, t3); // 0
__ addu(v0, v0, v1); // 51
__ Branch(&error, ne, v0, Operand(51));
__ Movn(a0, a7, a4); // Move a0<-a7 (a4 is NOT 0).
__ Ins(a0, a5, 12, 8); // 0x7ff34fff
__ Branch(&error, ne, a0, Operand(0x7ff34fff));
__ Movz(a0, t2, t3); // a0 not updated (t3 is NOT 0).
__ Ext(a1, a0, 8, 12); // 0x34f
__ Branch(&error, ne, a1, Operand(0x34f));
__ Movz(a0, t2, v1); // a0<-t2, v0 is 0, from 8 instr back.
__ Branch(&error, ne, a0, Operand(t2));
// Everything was correctly executed. Load the expected result.
__ li(v0, 0x31415926);
__ b(&exit);
__ nop();
__ bind(&error);
// Got an error. Return a wrong result.
__ li(v0, 666);
__ bind(&exit);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
int64_t res = reinterpret_cast<int64_t>(
CALL_GENERATED_CODE(isolate, f, 0xab0, 0xc, 0, 0, 0));
CHECK_EQ(0x31415926L, res);
}
TEST(MIPS3) {
// Test floating point instructions.
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
typedef struct {
double a;
double b;
double c;
double d;
double e;
double f;
double g;
double h;
double i;
float fa;
float fb;
float fc;
float fd;
float fe;
float ff;
float fg;
} T;
T t;
// Create a function that accepts &t, and loads, manipulates, and stores
// the doubles t.a ... t.f.
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
Label L, C;
// Double precision floating point instructions.
__ Ldc1(f4, MemOperand(a0, offsetof(T, a)));
__ Ldc1(f6, MemOperand(a0, offsetof(T, b)));
__ add_d(f8, f4, f6);
__ Sdc1(f8, MemOperand(a0, offsetof(T, c))); // c = a + b.
__ mov_d(f10, f8); // c
__ neg_d(f12, f6); // -b
__ sub_d(f10, f10, f12);
__ Sdc1(f10, MemOperand(a0, offsetof(T, d))); // d = c - (-b).
__ Sdc1(f4, MemOperand(a0, offsetof(T, b))); // b = a.
__ li(a4, 120);
__ mtc1(a4, f14);
__ cvt_d_w(f14, f14); // f14 = 120.0.
__ mul_d(f10, f10, f14);
__ Sdc1(f10, MemOperand(a0, offsetof(T, e))); // e = d * 120 = 1.8066e16.
__ div_d(f12, f10, f4);
__ Sdc1(f12, MemOperand(a0, offsetof(T, f))); // f = e / a = 120.44.
__ sqrt_d(f14, f12);
__ Sdc1(f14, MemOperand(a0, offsetof(T, g)));
// g = sqrt(f) = 10.97451593465515908537
if (kArchVariant == kMips64r2) {
__ Ldc1(f4, MemOperand(a0, offsetof(T, h)));
__ Ldc1(f6, MemOperand(a0, offsetof(T, i)));
__ Madd_d(f14, f6, f4, f6, f8);
__ Sdc1(f14, MemOperand(a0, offsetof(T, h)));
}
// Single precision floating point instructions.
__ Lwc1(f4, MemOperand(a0, offsetof(T, fa)));
__ Lwc1(f6, MemOperand(a0, offsetof(T, fb)));
__ add_s(f8, f4, f6);
__ Swc1(f8, MemOperand(a0, offsetof(T, fc))); // fc = fa + fb.
__ neg_s(f10, f6); // -fb
__ sub_s(f10, f8, f10);
__ Swc1(f10, MemOperand(a0, offsetof(T, fd))); // fd = fc - (-fb).
__ Swc1(f4, MemOperand(a0, offsetof(T, fb))); // fb = fa.
__ li(t0, 120);
__ mtc1(t0, f14);
__ cvt_s_w(f14, f14); // f14 = 120.0.
__ mul_s(f10, f10, f14);
__ Swc1(f10, MemOperand(a0, offsetof(T, fe))); // fe = fd * 120
__ div_s(f12, f10, f4);
__ Swc1(f12, MemOperand(a0, offsetof(T, ff))); // ff = fe / fa
__ sqrt_s(f14, f12);
__ Swc1(f14, MemOperand(a0, offsetof(T, fg)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
// Double test values.
t.a = 1.5e14;
t.b = 2.75e11;
t.c = 0.0;
t.d = 0.0;
t.e = 0.0;
t.f = 0.0;
t.h = 1.5;
t.i = 2.75;
// Single test values.
t.fa = 1.5e6;
t.fb = 2.75e4;
t.fc = 0.0;
t.fd = 0.0;
t.fe = 0.0;
t.ff = 0.0;
Object* dummy = CALL_GENERATED_CODE(isolate, f, &t, 0, 0, 0, 0);
USE(dummy);
// Expected double results.
CHECK_EQ(1.5e14, t.a);
CHECK_EQ(1.5e14, t.b);
CHECK_EQ(1.50275e14, t.c);
CHECK_EQ(1.50550e14, t.d);
CHECK_EQ(1.8066e16, t.e);
CHECK_EQ(120.44, t.f);
CHECK_EQ(10.97451593465515908537, t.g);
if (kArchVariant == kMips64r2) {
CHECK_EQ(6.875, t.h);
}
// Expected single results.
CHECK_EQ(1.5e6, t.fa);
CHECK_EQ(1.5e6, t.fb);
CHECK_EQ(1.5275e06, t.fc);
CHECK_EQ(1.5550e06, t.fd);
CHECK_EQ(1.866e08, t.fe);
CHECK_EQ(124.40000152587890625, t.ff);
CHECK_EQ(11.1534748077392578125, t.fg);
}
TEST(MIPS4) {
// Test moves between floating point and integer registers.
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
typedef struct {
double a;
double b;
double c;
double d;
int64_t high;
int64_t low;
} T;
T t;
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
Label L, C;
__ Ldc1(f4, MemOperand(a0, offsetof(T, a)));
__ Ldc1(f5, MemOperand(a0, offsetof(T, b)));
// Swap f4 and f5, by using 3 integer registers, a4-a6,
// both two 32-bit chunks, and one 64-bit chunk.
// mXhc1 is mips32/64-r2 only, not r1,
// but we will not support r1 in practice.
__ mfc1(a4, f4);
__ mfhc1(a5, f4);
__ dmfc1(a6, f5);
__ mtc1(a4, f5);
__ mthc1(a5, f5);
__ dmtc1(a6, f4);
// Store the swapped f4 and f5 back to memory.
__ Sdc1(f4, MemOperand(a0, offsetof(T, a)));
__ Sdc1(f5, MemOperand(a0, offsetof(T, c)));
// Test sign extension of move operations from coprocessor.
__ Ldc1(f4, MemOperand(a0, offsetof(T, d)));
__ mfhc1(a4, f4);
__ mfc1(a5, f4);
__ Sd(a4, MemOperand(a0, offsetof(T, high)));
__ Sd(a5, MemOperand(a0, offsetof(T, low)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
t.a = 1.5e22;
t.b = 2.75e11;
t.c = 17.17;
t.d = -2.75e11;
Object* dummy = CALL_GENERATED_CODE(isolate, f, &t, 0, 0, 0, 0);
USE(dummy);
CHECK_EQ(2.75e11, t.a);
CHECK_EQ(2.75e11, t.b);
CHECK_EQ(1.5e22, t.c);
CHECK_EQ(static_cast<int64_t>(0xffffffffc25001d1L), t.high);
CHECK_EQ(static_cast<int64_t>(0xffffffffbf800000L), t.low);
}
TEST(MIPS5) {
// Test conversions between doubles and integers.
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
typedef struct {
double a;
double b;
int i;
int j;
} T;
T t;
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
Label L, C;
// Load all structure elements to registers.
__ Ldc1(f4, MemOperand(a0, offsetof(T, a)));
__ Ldc1(f6, MemOperand(a0, offsetof(T, b)));
__ Lw(a4, MemOperand(a0, offsetof(T, i)));
__ Lw(a5, MemOperand(a0, offsetof(T, j)));
// Convert double in f4 to int in element i.
__ cvt_w_d(f8, f4);
__ mfc1(a6, f8);
__ Sw(a6, MemOperand(a0, offsetof(T, i)));
// Convert double in f6 to int in element j.
__ cvt_w_d(f10, f6);
__ mfc1(a7, f10);
__ Sw(a7, MemOperand(a0, offsetof(T, j)));
// Convert int in original i (a4) to double in a.
__ mtc1(a4, f12);
__ cvt_d_w(f0, f12);
__ Sdc1(f0, MemOperand(a0, offsetof(T, a)));
// Convert int in original j (a5) to double in b.
__ mtc1(a5, f14);
__ cvt_d_w(f2, f14);
__ Sdc1(f2, MemOperand(a0, offsetof(T, b)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
t.a = 1.5e4;
t.b = 2.75e8;
t.i = 12345678;
t.j = -100000;
Object* dummy = CALL_GENERATED_CODE(isolate, f, &t, 0, 0, 0, 0);
USE(dummy);
CHECK_EQ(12345678.0, t.a);
CHECK_EQ(-100000.0, t.b);
CHECK_EQ(15000, t.i);
CHECK_EQ(275000000, t.j);
}
TEST(MIPS6) {
// Test simple memory loads and stores.
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
typedef struct {
uint32_t ui;
int32_t si;
int32_t r1;
int32_t r2;
int32_t r3;
int32_t r4;
int32_t r5;
int32_t r6;
} T;
T t;
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
Label L, C;
// Basic word load/store.
__ Lw(a4, MemOperand(a0, offsetof(T, ui)));
__ Sw(a4, MemOperand(a0, offsetof(T, r1)));
// lh with positive data.
__ Lh(a5, MemOperand(a0, offsetof(T, ui)));
__ Sw(a5, MemOperand(a0, offsetof(T, r2)));
// lh with negative data.
__ Lh(a6, MemOperand(a0, offsetof(T, si)));
__ Sw(a6, MemOperand(a0, offsetof(T, r3)));
// lhu with negative data.
__ Lhu(a7, MemOperand(a0, offsetof(T, si)));
__ Sw(a7, MemOperand(a0, offsetof(T, r4)));
// Lb with negative data.
__ Lb(t0, MemOperand(a0, offsetof(T, si)));
__ Sw(t0, MemOperand(a0, offsetof(T, r5)));
// sh writes only 1/2 of word.
__ lui(t1, 0x3333);
__ ori(t1, t1, 0x3333);
__ Sw(t1, MemOperand(a0, offsetof(T, r6)));
__ Lhu(t1, MemOperand(a0, offsetof(T, si)));
__ Sh(t1, MemOperand(a0, offsetof(T, r6)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
t.ui = 0x11223344;
t.si = 0x99aabbcc;
Object* dummy = CALL_GENERATED_CODE(isolate, f, &t, 0, 0, 0, 0);
USE(dummy);
CHECK_EQ(static_cast<int32_t>(0x11223344), t.r1);
if (kArchEndian == kLittle) {
CHECK_EQ(static_cast<int32_t>(0x3344), t.r2);
CHECK_EQ(static_cast<int32_t>(0xffffbbcc), t.r3);
CHECK_EQ(static_cast<int32_t>(0x0000bbcc), t.r4);
CHECK_EQ(static_cast<int32_t>(0xffffffcc), t.r5);
CHECK_EQ(static_cast<int32_t>(0x3333bbcc), t.r6);
} else {
CHECK_EQ(static_cast<int32_t>(0x1122), t.r2);
CHECK_EQ(static_cast<int32_t>(0xffff99aa), t.r3);
CHECK_EQ(static_cast<int32_t>(0x000099aa), t.r4);
CHECK_EQ(static_cast<int32_t>(0xffffff99), t.r5);
CHECK_EQ(static_cast<int32_t>(0x99aa3333), t.r6);
}
}
TEST(MIPS7) {
// Test floating point compare and branch instructions.
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
typedef struct {
double a;
double b;
double c;
double d;
double e;
double f;
int32_t result;
} T;
T t;
// Create a function that accepts &t, and loads, manipulates, and stores
// the doubles t.a ... t.f.
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
Label neither_is_nan, less_than, outa_here;
__ Ldc1(f4, MemOperand(a0, offsetof(T, a)));
__ Ldc1(f6, MemOperand(a0, offsetof(T, b)));
if (kArchVariant != kMips64r6) {
__ c(UN, D, f4, f6);
__ bc1f(&neither_is_nan);
} else {
__ cmp(UN, L, f2, f4, f6);
__ bc1eqz(&neither_is_nan, f2);
}
__ nop();
__ Sw(zero_reg, MemOperand(a0, offsetof(T, result)));
__ Branch(&outa_here);
__ bind(&neither_is_nan);
if (kArchVariant == kMips64r6) {
__ cmp(OLT, L, f2, f6, f4);
__ bc1nez(&less_than, f2);
} else {
__ c(OLT, D, f6, f4, 2);
__ bc1t(&less_than, 2);
}
__ nop();
__ Sw(zero_reg, MemOperand(a0, offsetof(T, result)));
__ Branch(&outa_here);
__ bind(&less_than);
__ Addu(a4, zero_reg, Operand(1));
__ Sw(a4, MemOperand(a0, offsetof(T, result))); // Set true.
// This test-case should have additional tests.
__ bind(&outa_here);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
t.a = 1.5e14;
t.b = 2.75e11;
t.c = 2.0;
t.d = -4.0;
t.e = 0.0;
t.f = 0.0;
t.result = 0;
Object* dummy = CALL_GENERATED_CODE(isolate, f, &t, 0, 0, 0, 0);
USE(dummy);
CHECK_EQ(1.5e14, t.a);
CHECK_EQ(2.75e11, t.b);
CHECK_EQ(1, t.result);
}
TEST(MIPS8) {
if (kArchVariant == kMips64r2) {
// Test ROTR and ROTRV instructions.
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
typedef struct {
int32_t input;
int32_t result_rotr_4;
int32_t result_rotr_8;
int32_t result_rotr_12;
int32_t result_rotr_16;
int32_t result_rotr_20;
int32_t result_rotr_24;
int32_t result_rotr_28;
int32_t result_rotrv_4;
int32_t result_rotrv_8;
int32_t result_rotrv_12;
int32_t result_rotrv_16;
int32_t result_rotrv_20;
int32_t result_rotrv_24;
int32_t result_rotrv_28;
} T;
T t;
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
// Basic word load.
__ Lw(a4, MemOperand(a0, offsetof(T, input)));
// ROTR instruction (called through the Ror macro).
__ Ror(a5, a4, 0x0004);
__ Ror(a6, a4, 0x0008);
__ Ror(a7, a4, 0x000c);
__ Ror(t0, a4, 0x0010);
__ Ror(t1, a4, 0x0014);
__ Ror(t2, a4, 0x0018);
__ Ror(t3, a4, 0x001c);
// Basic word store.
__ Sw(a5, MemOperand(a0, offsetof(T, result_rotr_4)));
__ Sw(a6, MemOperand(a0, offsetof(T, result_rotr_8)));
__ Sw(a7, MemOperand(a0, offsetof(T, result_rotr_12)));
__ Sw(t0, MemOperand(a0, offsetof(T, result_rotr_16)));
__ Sw(t1, MemOperand(a0, offsetof(T, result_rotr_20)));
__ Sw(t2, MemOperand(a0, offsetof(T, result_rotr_24)));
__ Sw(t3, MemOperand(a0, offsetof(T, result_rotr_28)));
// ROTRV instruction (called through the Ror macro).
__ li(t3, 0x0004);
__ Ror(a5, a4, t3);
__ li(t3, 0x0008);
__ Ror(a6, a4, t3);
__ li(t3, 0x000C);
__ Ror(a7, a4, t3);
__ li(t3, 0x0010);
__ Ror(t0, a4, t3);
__ li(t3, 0x0014);
__ Ror(t1, a4, t3);
__ li(t3, 0x0018);
__ Ror(t2, a4, t3);
__ li(t3, 0x001C);
__ Ror(t3, a4, t3);
// Basic word store.
__ Sw(a5, MemOperand(a0, offsetof(T, result_rotrv_4)));
__ Sw(a6, MemOperand(a0, offsetof(T, result_rotrv_8)));
__ Sw(a7, MemOperand(a0, offsetof(T, result_rotrv_12)));
__ Sw(t0, MemOperand(a0, offsetof(T, result_rotrv_16)));
__ Sw(t1, MemOperand(a0, offsetof(T, result_rotrv_20)));
__ Sw(t2, MemOperand(a0, offsetof(T, result_rotrv_24)));
__ Sw(t3, MemOperand(a0, offsetof(T, result_rotrv_28)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
t.input = 0x12345678;
Object* dummy = CALL_GENERATED_CODE(isolate, f, &t, 0x0, 0, 0, 0);
USE(dummy);
CHECK_EQ(static_cast<int32_t>(0x81234567), t.result_rotr_4);
CHECK_EQ(static_cast<int32_t>(0x78123456), t.result_rotr_8);
CHECK_EQ(static_cast<int32_t>(0x67812345), t.result_rotr_12);
CHECK_EQ(static_cast<int32_t>(0x56781234), t.result_rotr_16);
CHECK_EQ(static_cast<int32_t>(0x45678123), t.result_rotr_20);
CHECK_EQ(static_cast<int32_t>(0x34567812), t.result_rotr_24);
CHECK_EQ(static_cast<int32_t>(0x23456781), t.result_rotr_28);
CHECK_EQ(static_cast<int32_t>(0x81234567), t.result_rotrv_4);
CHECK_EQ(static_cast<int32_t>(0x78123456), t.result_rotrv_8);
CHECK_EQ(static_cast<int32_t>(0x67812345), t.result_rotrv_12);
CHECK_EQ(static_cast<int32_t>(0x56781234), t.result_rotrv_16);
CHECK_EQ(static_cast<int32_t>(0x45678123), t.result_rotrv_20);
CHECK_EQ(static_cast<int32_t>(0x34567812), t.result_rotrv_24);
CHECK_EQ(static_cast<int32_t>(0x23456781), t.result_rotrv_28);
}
}
TEST(MIPS9) {
// Test BRANCH improvements.
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
Label exit, exit2, exit3;
__ Branch(&exit, ge, a0, Operand(zero_reg));
__ Branch(&exit2, ge, a0, Operand(0x00001FFF));
__ Branch(&exit3, ge, a0, Operand(0x0001FFFF));
__ bind(&exit);
__ bind(&exit2);
__ bind(&exit3);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
}
TEST(MIPS10) {
// Test conversions between doubles and long integers.
// Test hos the long ints map to FP regs pairs.
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
typedef struct {
double a;
double a_converted;
double b;
int32_t dbl_mant;
int32_t dbl_exp;
int32_t long_hi;
int32_t long_lo;
int64_t long_as_int64;
int32_t b_long_hi;
int32_t b_long_lo;
int64_t b_long_as_int64;
} T;
T t;
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
Label L, C;
if (kArchVariant == kMips64r2) {
// Rewritten for FR=1 FPU mode:
// - 32 FP regs of 64-bits each, no odd/even pairs.
// - Note that cvt_l_d/cvt_d_l ARE legal in FR=1 mode.
// Load all structure elements to registers.
__ Ldc1(f0, MemOperand(a0, offsetof(T, a)));
// Save the raw bits of the double.
__ mfc1(a4, f0);
__ mfhc1(a5, f0);
__ Sw(a4, MemOperand(a0, offsetof(T, dbl_mant)));
__ Sw(a5, MemOperand(a0, offsetof(T, dbl_exp)));
// Convert double in f0 to long, save hi/lo parts.
__ cvt_l_d(f0, f0);
__ mfc1(a4, f0); // f0 LS 32 bits of long.
__ mfhc1(a5, f0); // f0 MS 32 bits of long.
__ Sw(a4, MemOperand(a0, offsetof(T, long_lo)));
__ Sw(a5, MemOperand(a0, offsetof(T, long_hi)));
// Combine the high/low ints, convert back to double.
__ dsll32(a6, a5, 0); // Move a5 to high bits of a6.
__ or_(a6, a6, a4);
__ dmtc1(a6, f1);
__ cvt_d_l(f1, f1);
__ Sdc1(f1, MemOperand(a0, offsetof(T, a_converted)));
// Convert the b long integers to double b.
__ Lw(a4, MemOperand(a0, offsetof(T, b_long_lo)));
__ Lw(a5, MemOperand(a0, offsetof(T, b_long_hi)));
__ mtc1(a4, f8); // f8 LS 32-bits.
__ mthc1(a5, f8); // f8 MS 32-bits.
__ cvt_d_l(f10, f8);
__ Sdc1(f10, MemOperand(a0, offsetof(T, b)));
// Convert double b back to long-int.
__ Ldc1(f31, MemOperand(a0, offsetof(T, b)));
__ cvt_l_d(f31, f31);
__ dmfc1(a7, f31);
__ Sd(a7, MemOperand(a0, offsetof(T, b_long_as_int64)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
t.a = 2.147483647e9; // 0x7fffffff -> 0x41DFFFFFFFC00000 as double.
t.b_long_hi = 0x000000ff; // 0xFF00FF00FF -> 0x426FE01FE01FE000 as double.
t.b_long_lo = 0x00ff00ff;
Object* dummy = CALL_GENERATED_CODE(isolate, f, &t, 0, 0, 0, 0);
USE(dummy);
CHECK_EQ(static_cast<int32_t>(0x41DFFFFF), t.dbl_exp);
CHECK_EQ(static_cast<int32_t>(0xFFC00000), t.dbl_mant);
CHECK_EQ(0, t.long_hi);
CHECK_EQ(static_cast<int32_t>(0x7fffffff), t.long_lo);
CHECK_EQ(2.147483647e9, t.a_converted);
// 0xFF00FF00FF -> 1.095233372415e12.
CHECK_EQ(1.095233372415e12, t.b);
CHECK_EQ(static_cast<int64_t>(0xFF00FF00FF), t.b_long_as_int64);
}
}
TEST(MIPS11) {
// Do not run test on MIPS64r6, as these instructions are removed.
if (kArchVariant != kMips64r6) {
// Test LWL, LWR, SWL and SWR instructions.
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
typedef struct {
int32_t reg_init;
int32_t mem_init;
int32_t lwl_0;
int32_t lwl_1;
int32_t lwl_2;
int32_t lwl_3;
int32_t lwr_0;
int32_t lwr_1;
int32_t lwr_2;
int32_t lwr_3;
int32_t swl_0;
int32_t swl_1;
int32_t swl_2;
int32_t swl_3;
int32_t swr_0;
int32_t swr_1;
int32_t swr_2;
int32_t swr_3;
} T;
T t;
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
// Test all combinations of LWL and vAddr.
__ Lw(a4, MemOperand(a0, offsetof(T, reg_init)));
__ lwl(a4, MemOperand(a0, offsetof(T, mem_init)));
__ Sw(a4, MemOperand(a0, offsetof(T, lwl_0)));
__ Lw(a5, MemOperand(a0, offsetof(T, reg_init)));
__ lwl(a5, MemOperand(a0, offsetof(T, mem_init) + 1));
__ Sw(a5, MemOperand(a0, offsetof(T, lwl_1)));
__ Lw(a6, MemOperand(a0, offsetof(T, reg_init)));
__ lwl(a6, MemOperand(a0, offsetof(T, mem_init) + 2));
__ Sw(a6, MemOperand(a0, offsetof(T, lwl_2)));
__ Lw(a7, MemOperand(a0, offsetof(T, reg_init)));
__ lwl(a7, MemOperand(a0, offsetof(T, mem_init) + 3));
__ Sw(a7, MemOperand(a0, offsetof(T, lwl_3)));
// Test all combinations of LWR and vAddr.
__ Lw(a4, MemOperand(a0, offsetof(T, reg_init)));
__ lwr(a4, MemOperand(a0, offsetof(T, mem_init)));
__ Sw(a4, MemOperand(a0, offsetof(T, lwr_0)));
__ Lw(a5, MemOperand(a0, offsetof(T, reg_init)));
__ lwr(a5, MemOperand(a0, offsetof(T, mem_init) + 1));
__ Sw(a5, MemOperand(a0, offsetof(T, lwr_1)));
__ Lw(a6, MemOperand(a0, offsetof(T, reg_init)));
__ lwr(a6, MemOperand(a0, offsetof(T, mem_init) + 2));
__ Sw(a6, MemOperand(a0, offsetof(T, lwr_2)));
__ Lw(a7, MemOperand(a0, offsetof(T, reg_init)));
__ lwr(a7, MemOperand(a0, offsetof(T, mem_init) + 3));
__ Sw(a7, MemOperand(a0, offsetof(T, lwr_3)));
// Test all combinations of SWL and vAddr.
__ Lw(a4, MemOperand(a0, offsetof(T, mem_init)));
__ Sw(a4, MemOperand(a0, offsetof(T, swl_0)));
__ Lw(a4, MemOperand(a0, offsetof(T, reg_init)));
__ swl(a4, MemOperand(a0, offsetof(T, swl_0)));
__ Lw(a5, MemOperand(a0, offsetof(T, mem_init)));
__ Sw(a5, MemOperand(a0, offsetof(T, swl_1)));
__ Lw(a5, MemOperand(a0, offsetof(T, reg_init)));
__ swl(a5, MemOperand(a0, offsetof(T, swl_1) + 1));
__ Lw(a6, MemOperand(a0, offsetof(T, mem_init)));
__ Sw(a6, MemOperand(a0, offsetof(T, swl_2)));
__ Lw(a6, MemOperand(a0, offsetof(T, reg_init)));
__ swl(a6, MemOperand(a0, offsetof(T, swl_2) + 2));
__ Lw(a7, MemOperand(a0, offsetof(T, mem_init)));
__ Sw(a7, MemOperand(a0, offsetof(T, swl_3)));
__ Lw(a7, MemOperand(a0, offsetof(T, reg_init)));
__ swl(a7, MemOperand(a0, offsetof(T, swl_3) + 3));
// Test all combinations of SWR and vAddr.
__ Lw(a4, MemOperand(a0, offsetof(T, mem_init)));
__ Sw(a4, MemOperand(a0, offsetof(T, swr_0)));
__ Lw(a4, MemOperand(a0, offsetof(T, reg_init)));
__ swr(a4, MemOperand(a0, offsetof(T, swr_0)));
__ Lw(a5, MemOperand(a0, offsetof(T, mem_init)));
__ Sw(a5, MemOperand(a0, offsetof(T, swr_1)));
__ Lw(a5, MemOperand(a0, offsetof(T, reg_init)));
__ swr(a5, MemOperand(a0, offsetof(T, swr_1) + 1));
__ Lw(a6, MemOperand(a0, offsetof(T, mem_init)));
__ Sw(a6, MemOperand(a0, offsetof(T, swr_2)));
__ Lw(a6, MemOperand(a0, offsetof(T, reg_init)));
__ swr(a6, MemOperand(a0, offsetof(T, swr_2) + 2));
__ Lw(a7, MemOperand(a0, offsetof(T, mem_init)));
__ Sw(a7, MemOperand(a0, offsetof(T, swr_3)));
__ Lw(a7, MemOperand(a0, offsetof(T, reg_init)));
__ swr(a7, MemOperand(a0, offsetof(T, swr_3) + 3));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
t.reg_init = 0xaabbccdd;
t.mem_init = 0x11223344;
Object* dummy = CALL_GENERATED_CODE(isolate, f, &t, 0, 0, 0, 0);
USE(dummy);
if (kArchEndian == kLittle) {
CHECK_EQ(static_cast<int32_t>(0x44bbccdd), t.lwl_0);
CHECK_EQ(static_cast<int32_t>(0x3344ccdd), t.lwl_1);
CHECK_EQ(static_cast<int32_t>(0x223344dd), t.lwl_2);
CHECK_EQ(static_cast<int32_t>(0x11223344), t.lwl_3);
CHECK_EQ(static_cast<int32_t>(0x11223344), t.lwr_0);
CHECK_EQ(static_cast<int32_t>(0xaa112233), t.lwr_1);
CHECK_EQ(static_cast<int32_t>(0xaabb1122), t.lwr_2);
CHECK_EQ(static_cast<int32_t>(0xaabbcc11), t.lwr_3);
CHECK_EQ(static_cast<int32_t>(0x112233aa), t.swl_0);
CHECK_EQ(static_cast<int32_t>(0x1122aabb), t.swl_1);
CHECK_EQ(static_cast<int32_t>(0x11aabbcc), t.swl_2);
CHECK_EQ(static_cast<int32_t>(0xaabbccdd), t.swl_3);
CHECK_EQ(static_cast<int32_t>(0xaabbccdd), t.swr_0);
CHECK_EQ(static_cast<int32_t>(0xbbccdd44), t.swr_1);
CHECK_EQ(static_cast<int32_t>(0xccdd3344), t.swr_2);
CHECK_EQ(static_cast<int32_t>(0xdd223344), t.swr_3);
} else {
CHECK_EQ(static_cast<int32_t>(0x11223344), t.lwl_0);
CHECK_EQ(static_cast<int32_t>(0x223344dd), t.lwl_1);
CHECK_EQ(static_cast<int32_t>(0x3344ccdd), t.lwl_2);
CHECK_EQ(static_cast<int32_t>(0x44bbccdd), t.lwl_3);
CHECK_EQ(static_cast<int32_t>(0xaabbcc11), t.lwr_0);
CHECK_EQ(static_cast<int32_t>(0xaabb1122), t.lwr_1);
CHECK_EQ(static_cast<int32_t>(0xaa112233), t.lwr_2);
CHECK_EQ(static_cast<int32_t>(0x11223344), t.lwr_3);
CHECK_EQ(static_cast<int32_t>(0xaabbccdd), t.swl_0);
CHECK_EQ(static_cast<int32_t>(0x11aabbcc), t.swl_1);
CHECK_EQ(static_cast<int32_t>(0x1122aabb), t.swl_2);
CHECK_EQ(static_cast<int32_t>(0x112233aa), t.swl_3);
CHECK_EQ(static_cast<int32_t>(0xdd223344), t.swr_0);
CHECK_EQ(static_cast<int32_t>(0xccdd3344), t.swr_1);
CHECK_EQ(static_cast<int32_t>(0xbbccdd44), t.swr_2);
CHECK_EQ(static_cast<int32_t>(0xaabbccdd), t.swr_3);
}
}
}
TEST(MIPS12) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
typedef struct {
int32_t x;
int32_t y;
int32_t y1;
int32_t y2;
int32_t y3;
int32_t y4;
} T;
T t;
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
__ mov(t2, fp); // Save frame pointer.
__ mov(fp, a0); // Access struct T by fp.
__ Lw(a4, MemOperand(a0, offsetof(T, y)));
__ Lw(a7, MemOperand(a0, offsetof(T, y4)));
__ addu(a5, a4, a7);
__ subu(t0, a4, a7);
__ nop();
__ push(a4); // These instructions disappear after opt.
__ Pop();
__ addu(a4, a4, a4);
__ nop();
__ Pop(); // These instructions disappear after opt.
__ push(a7);
__ nop();
__ push(a7); // These instructions disappear after opt.
__ pop(a7);
__ nop();
__ push(a7);
__ pop(t0);
__ nop();
__ Sw(a4, MemOperand(fp, offsetof(T, y)));
__ Lw(a4, MemOperand(fp, offsetof(T, y)));
__ nop();
__ Sw(a4, MemOperand(fp, offsetof(T, y)));
__ Lw(a5, MemOperand(fp, offsetof(T, y)));
__ nop();
__ push(a5);
__ Lw(a5, MemOperand(fp, offsetof(T, y)));
__ pop(a5);
__ nop();
__ push(a5);
__ Lw(a6, MemOperand(fp, offsetof(T, y)));
__ pop(a5);
__ nop();
__ push(a5);
__ Lw(a6, MemOperand(fp, offsetof(T, y)));
__ pop(a6);
__ nop();
__ push(a6);
__ Lw(a6, MemOperand(fp, offsetof(T, y)));
__ pop(a5);
__ nop();
__ push(a5);
__ Lw(a6, MemOperand(fp, offsetof(T, y)));
__ pop(a7);
__ nop();
__ mov(fp, t2);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
t.x = 1;
t.y = 2;
t.y1 = 3;
t.y2 = 4;
t.y3 = 0XBABA;
t.y4 = 0xDEDA;
Object* dummy = CALL_GENERATED_CODE(isolate, f, &t, 0, 0, 0, 0);
USE(dummy);
CHECK_EQ(3, t.y1);
}
TEST(MIPS13) {
// Test Cvt_d_uw and Trunc_uw_d macros.
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
typedef struct {
double cvt_big_out;
double cvt_small_out;
uint32_t trunc_big_out;
uint32_t trunc_small_out;
uint32_t cvt_big_in;
uint32_t cvt_small_in;
} T;
T t;
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
__ Sw(a4, MemOperand(a0, offsetof(T, cvt_small_in)));
__ Cvt_d_uw(f10, a4);
__ Sdc1(f10, MemOperand(a0, offsetof(T, cvt_small_out)));
__ Trunc_uw_d(f10, f10, f4);
__ Swc1(f10, MemOperand(a0, offsetof(T, trunc_small_out)));
__ Sw(a4, MemOperand(a0, offsetof(T, cvt_big_in)));
__ Cvt_d_uw(f8, a4);
__ Sdc1(f8, MemOperand(a0, offsetof(T, cvt_big_out)));
__ Trunc_uw_d(f8, f8, f4);
__ Swc1(f8, MemOperand(a0, offsetof(T, trunc_big_out)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
t.cvt_big_in = 0xFFFFFFFF;
t.cvt_small_in = 333;
Object* dummy = CALL_GENERATED_CODE(isolate, f, &t, 0, 0, 0, 0);
USE(dummy);
CHECK_EQ(t.cvt_big_out, static_cast<double>(t.cvt_big_in));
CHECK_EQ(t.cvt_small_out, static_cast<double>(t.cvt_small_in));
CHECK_EQ(static_cast<int>(t.trunc_big_out), static_cast<int>(t.cvt_big_in));
CHECK_EQ(static_cast<int>(t.trunc_small_out),
static_cast<int>(t.cvt_small_in));
}
TEST(MIPS14) {
// Test round, floor, ceil, trunc, cvt.
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
#define ROUND_STRUCT_ELEMENT(x) \
uint32_t x##_isNaN2008; \
int32_t x##_up_out; \
int32_t x##_down_out; \
int32_t neg_##x##_up_out; \
int32_t neg_##x##_down_out; \
uint32_t x##_err1_out; \
uint32_t x##_err2_out; \
uint32_t x##_err3_out; \
uint32_t x##_err4_out; \
int32_t x##_invalid_result;
typedef struct {
double round_up_in;
double round_down_in;
double neg_round_up_in;
double neg_round_down_in;
double err1_in;
double err2_in;
double err3_in;
double err4_in;
ROUND_STRUCT_ELEMENT(round)
ROUND_STRUCT_ELEMENT(floor)
ROUND_STRUCT_ELEMENT(ceil)
ROUND_STRUCT_ELEMENT(trunc)
ROUND_STRUCT_ELEMENT(cvt)
} T;
T t;
#undef ROUND_STRUCT_ELEMENT
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
// Save FCSR.
__ cfc1(a1, FCSR);
// Disable FPU exceptions.
__ ctc1(zero_reg, FCSR);
#define RUN_ROUND_TEST(x) \
__ cfc1(t0, FCSR); \
__ Sw(t0, MemOperand(a0, offsetof(T, x##_isNaN2008))); \
__ Ldc1(f0, MemOperand(a0, offsetof(T, round_up_in))); \
__ x##_w_d(f0, f0); \
__ Swc1(f0, MemOperand(a0, offsetof(T, x##_up_out))); \
\
__ Ldc1(f0, MemOperand(a0, offsetof(T, round_down_in))); \
__ x##_w_d(f0, f0); \
__ Swc1(f0, MemOperand(a0, offsetof(T, x##_down_out))); \
\
__ Ldc1(f0, MemOperand(a0, offsetof(T, neg_round_up_in))); \
__ x##_w_d(f0, f0); \
__ Swc1(f0, MemOperand(a0, offsetof(T, neg_##x##_up_out))); \
\
__ Ldc1(f0, MemOperand(a0, offsetof(T, neg_round_down_in))); \
__ x##_w_d(f0, f0); \
__ Swc1(f0, MemOperand(a0, offsetof(T, neg_##x##_down_out))); \
\
__ Ldc1(f0, MemOperand(a0, offsetof(T, err1_in))); \
__ ctc1(zero_reg, FCSR); \
__ x##_w_d(f0, f0); \
__ cfc1(a2, FCSR); \
__ Sw(a2, MemOperand(a0, offsetof(T, x##_err1_out))); \
\
__ Ldc1(f0, MemOperand(a0, offsetof(T, err2_in))); \
__ ctc1(zero_reg, FCSR); \
__ x##_w_d(f0, f0); \
__ cfc1(a2, FCSR); \
__ Sw(a2, MemOperand(a0, offsetof(T, x##_err2_out))); \
\
__ Ldc1(f0, MemOperand(a0, offsetof(T, err3_in))); \
__ ctc1(zero_reg, FCSR); \
__ x##_w_d(f0, f0); \
__ cfc1(a2, FCSR); \
__ Sw(a2, MemOperand(a0, offsetof(T, x##_err3_out))); \
\
__ Ldc1(f0, MemOperand(a0, offsetof(T, err4_in))); \
__ ctc1(zero_reg, FCSR); \
__ x##_w_d(f0, f0); \
__ cfc1(a2, FCSR); \
__ Sw(a2, MemOperand(a0, offsetof(T, x##_err4_out))); \
__ Swc1(f0, MemOperand(a0, offsetof(T, x##_invalid_result)));
RUN_ROUND_TEST(round)
RUN_ROUND_TEST(floor)
RUN_ROUND_TEST(ceil)
RUN_ROUND_TEST(trunc)
RUN_ROUND_TEST(cvt)
// Restore FCSR.
__ ctc1(a1, FCSR);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
t.round_up_in = 123.51;
t.round_down_in = 123.49;
t.neg_round_up_in = -123.5;
t.neg_round_down_in = -123.49;
t.err1_in = 123.51;
t.err2_in = 1;
t.err3_in = static_cast<double>(1) + 0xFFFFFFFF;
t.err4_in = NAN;
Object* dummy = CALL_GENERATED_CODE(isolate, f, &t, 0, 0, 0, 0);
USE(dummy);
#define GET_FPU_ERR(x) (static_cast<int>(x & kFCSRFlagMask))
#define CHECK_NAN2008(x) (x & kFCSRNaN2008FlagMask)
#define CHECK_ROUND_RESULT(type) \
CHECK(GET_FPU_ERR(t.type##_err1_out) & kFCSRInexactFlagMask); \
CHECK_EQ(0, GET_FPU_ERR(t.type##_err2_out)); \
CHECK(GET_FPU_ERR(t.type##_err3_out) & kFCSRInvalidOpFlagMask); \
CHECK(GET_FPU_ERR(t.type##_err4_out) & kFCSRInvalidOpFlagMask); \
if (CHECK_NAN2008(t.type##_isNaN2008) && kArchVariant == kMips64r6) { \
CHECK_EQ(static_cast<int32_t>(0), t.type##_invalid_result);\
} else { \
CHECK_EQ(static_cast<int32_t>(kFPUInvalidResult), t.type##_invalid_result);\
}
CHECK_ROUND_RESULT(round);
CHECK_ROUND_RESULT(floor);
CHECK_ROUND_RESULT(ceil);
CHECK_ROUND_RESULT(cvt);
}
TEST(MIPS15) {
// Test chaining of label usages within instructions (issue 1644).
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
Assembler assm(isolate, nullptr, 0);
Label target;
__ beq(v0, v1, &target);
__ nop();
__ bne(v0, v1, &target);
__ nop();
__ bind(&target);
__ nop();
}
// ----- mips64 tests -----------------------------------------------
TEST(MIPS16) {
// Test 64-bit memory loads and stores.
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
struct T {
int64_t r1;
int64_t r2;
int64_t r3;
int64_t r4;
int64_t r5;
int64_t r6;
int64_t r7;
int64_t r8;
int64_t r9;
int64_t r10;
int64_t r11;
int64_t r12;
uint32_t ui;
int32_t si;
};
T t;
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
Label L, C;
// Basic 32-bit word load/store, with un-signed data.
__ Lw(a4, MemOperand(a0, offsetof(T, ui)));
__ Sw(a4, MemOperand(a0, offsetof(T, r1)));
// Check that the data got zero-extended into 64-bit a4.
__ Sd(a4, MemOperand(a0, offsetof(T, r2)));
// Basic 32-bit word load/store, with SIGNED data.
__ Lw(a5, MemOperand(a0, offsetof(T, si)));
__ Sw(a5, MemOperand(a0, offsetof(T, r3)));
// Check that the data got sign-extended into 64-bit a4.
__ Sd(a5, MemOperand(a0, offsetof(T, r4)));
// 32-bit UNSIGNED word load/store, with SIGNED data.
__ Lwu(a6, MemOperand(a0, offsetof(T, si)));
__ Sw(a6, MemOperand(a0, offsetof(T, r5)));
// Check that the data got zero-extended into 64-bit a4.
__ Sd(a6, MemOperand(a0, offsetof(T, r6)));
// lh with positive data.
__ Lh(a5, MemOperand(a0, offsetof(T, ui)));
__ Sw(a5, MemOperand(a0, offsetof(T, r7)));
// lh with negative data.
__ Lh(a6, MemOperand(a0, offsetof(T, si)));
__ Sw(a6, MemOperand(a0, offsetof(T, r8)));
// lhu with negative data.
__ Lhu(a7, MemOperand(a0, offsetof(T, si)));
__ Sw(a7, MemOperand(a0, offsetof(T, r9)));
// Lb with negative data.
__ Lb(t0, MemOperand(a0, offsetof(T, si)));
__ Sw(t0, MemOperand(a0, offsetof(T, r10)));
// sh writes only 1/2 of word.
__ Lw(a4, MemOperand(a0, offsetof(T, ui)));
__ Sh(a4, MemOperand(a0, offsetof(T, r11)));
__ Lw(a4, MemOperand(a0, offsetof(T, si)));
__ Sh(a4, MemOperand(a0, offsetof(T, r12)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
t.ui = 0x44332211;
t.si = 0x99aabbcc;
t.r1 = 0x5555555555555555;
t.r2 = 0x5555555555555555;
t.r3 = 0x5555555555555555;
t.r4 = 0x5555555555555555;
t.r5 = 0x5555555555555555;
t.r6 = 0x5555555555555555;
t.r7 = 0x5555555555555555;
t.r8 = 0x5555555555555555;
t.r9 = 0x5555555555555555;
t.r10 = 0x5555555555555555;
t.r11 = 0x5555555555555555;
t.r12 = 0x5555555555555555;
Object* dummy = CALL_GENERATED_CODE(isolate, f, &t, 0, 0, 0, 0);
USE(dummy);
if (kArchEndian == kLittle) {
// Unsigned data, 32 & 64
CHECK_EQ(static_cast<int64_t>(0x5555555544332211L), t.r1); // lw, sw.
CHECK_EQ(static_cast<int64_t>(0x0000000044332211L), t.r2); // sd.
// Signed data, 32 & 64.
CHECK_EQ(static_cast<int64_t>(0x5555555599aabbccL), t.r3); // lw, sw.
CHECK_EQ(static_cast<int64_t>(0xffffffff99aabbccL), t.r4); // sd.
// Signed data, 32 & 64.
CHECK_EQ(static_cast<int64_t>(0x5555555599aabbccL), t.r5); // lwu, sw.
CHECK_EQ(static_cast<int64_t>(0x0000000099aabbccL), t.r6); // sd.
// lh with unsigned and signed data.
CHECK_EQ(static_cast<int64_t>(0x5555555500002211L), t.r7); // lh, sw.
CHECK_EQ(static_cast<int64_t>(0x55555555ffffbbccL), t.r8); // lh, sw.
// lhu with signed data.
CHECK_EQ(static_cast<int64_t>(0x555555550000bbccL), t.r9); // lhu, sw.
// lb with signed data.
CHECK_EQ(static_cast<int64_t>(0x55555555ffffffccL), t.r10); // lb, sw.
// sh with unsigned and signed data.
CHECK_EQ(static_cast<int64_t>(0x5555555555552211L), t.r11); // lw, sh.
CHECK_EQ(static_cast<int64_t>(0x555555555555bbccL), t.r12); // lw, sh.
} else {
// Unsigned data, 32 & 64
CHECK_EQ(static_cast<int64_t>(0x4433221155555555L), t.r1); // lw, sw.
CHECK_EQ(static_cast<int64_t>(0x0000000044332211L), t.r2); // sd.
// Signed data, 32 & 64.
CHECK_EQ(static_cast<int64_t>(0x99aabbcc55555555L), t.r3); // lw, sw.
CHECK_EQ(static_cast<int64_t>(0xffffffff99aabbccL), t.r4); // sd.
// Signed data, 32 & 64.
CHECK_EQ(static_cast<int64_t>(0x99aabbcc55555555L), t.r5); // lwu, sw.
CHECK_EQ(static_cast<int64_t>(0x0000000099aabbccL), t.r6); // sd.
// lh with unsigned and signed data.
CHECK_EQ(static_cast<int64_t>(0x0000443355555555L), t.r7); // lh, sw.
CHECK_EQ(static_cast<int64_t>(0xffff99aa55555555L), t.r8); // lh, sw.
// lhu with signed data.
CHECK_EQ(static_cast<int64_t>(0x000099aa55555555L), t.r9); // lhu, sw.
// lb with signed data.
CHECK_EQ(static_cast<int64_t>(0xffffff9955555555L), t.r10); // lb, sw.
// sh with unsigned and signed data.
CHECK_EQ(static_cast<int64_t>(0x2211555555555555L), t.r11); // lw, sh.
CHECK_EQ(static_cast<int64_t>(0xbbcc555555555555L), t.r12); // lw, sh.
}
}
// ----------------------mips64r6 specific tests----------------------
TEST(seleqz_selnez) {
if (kArchVariant == kMips64r6) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test {
int a;
int b;
int c;
int d;
double e;
double f;
double g;
double h;
float i;
float j;
float k;
float l;
} Test;
Test test;
// Integer part of test.
__ addiu(t1, zero_reg, 1); // t1 = 1
__ seleqz(t3, t1, zero_reg); // t3 = 1
__ Sw(t3, MemOperand(a0, offsetof(Test, a))); // a = 1
__ seleqz(t2, t1, t1); // t2 = 0
__ Sw(t2, MemOperand(a0, offsetof(Test, b))); // b = 0
__ selnez(t3, t1, zero_reg); // t3 = 1;
__ Sw(t3, MemOperand(a0, offsetof(Test, c))); // c = 0
__ selnez(t3, t1, t1); // t3 = 1
__ Sw(t3, MemOperand(a0, offsetof(Test, d))); // d = 1
// Floating point part of test.
__ Ldc1(f0, MemOperand(a0, offsetof(Test, e))); // src
__ Ldc1(f2, MemOperand(a0, offsetof(Test, f))); // test
__ Lwc1(f8, MemOperand(a0, offsetof(Test, i))); // src
__ Lwc1(f10, MemOperand(a0, offsetof(Test, j))); // test
__ seleqz_d(f4, f0, f2);
__ selnez_d(f6, f0, f2);
__ seleqz_s(f12, f8, f10);
__ selnez_s(f14, f8, f10);
__ Sdc1(f4, MemOperand(a0, offsetof(Test, g))); // src
__ Sdc1(f6, MemOperand(a0, offsetof(Test, h))); // src
__ Swc1(f12, MemOperand(a0, offsetof(Test, k))); // src
__ Swc1(f14, MemOperand(a0, offsetof(Test, l))); // src
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(1, test.a);
CHECK_EQ(0, test.b);
CHECK_EQ(0, test.c);
CHECK_EQ(1, test.d);
const int test_size = 3;
const int input_size = 5;
double inputs_D[input_size] = {0.0, 65.2, -70.32,
18446744073709551621.0, -18446744073709551621.0};
double outputs_D[input_size] = {0.0, 65.2, -70.32,
18446744073709551621.0, -18446744073709551621.0};
double tests_D[test_size*2] = {2.8, 2.9, -2.8, -2.9,
18446744073709551616.0, 18446744073709555712.0};
float inputs_S[input_size] = {0.0, 65.2, -70.32,
18446744073709551621.0, -18446744073709551621.0};
float outputs_S[input_size] = {0.0, 65.2, -70.32,
18446744073709551621.0, -18446744073709551621.0};
float tests_S[test_size*2] = {2.9, 2.8, -2.9, -2.8,
18446744073709551616.0, 18446746272732807168.0};
for (int j=0; j < test_size; j+=2) {
for (int i=0; i < input_size; i++) {
test.e = inputs_D[i];
test.f = tests_D[j];
test.i = inputs_S[i];
test.j = tests_S[j];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(outputs_D[i], test.g);
CHECK_EQ(0, test.h);
CHECK_EQ(outputs_S[i], test.k);
CHECK_EQ(0, test.l);
test.f = tests_D[j+1];
test.j = tests_S[j+1];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(0, test.g);
CHECK_EQ(outputs_D[i], test.h);
CHECK_EQ(0, test.k);
CHECK_EQ(outputs_S[i], test.l);
}
}
}
}
TEST(min_max) {
if (kArchVariant == kMips64r6) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
struct TestFloat {
double a;
double b;
double c;
double d;
float e;
float f;
float g;
float h;
};
TestFloat test;
const double dnan = std::numeric_limits<double>::quiet_NaN();
const double dinf = std::numeric_limits<double>::infinity();
const double dminf = -std::numeric_limits<double>::infinity();
const float fnan = std::numeric_limits<float>::quiet_NaN();
const float finf = std::numeric_limits<float>::infinity();
const float fminf = std::numeric_limits<float>::infinity();
const int kTableLength = 13;
double inputsa[kTableLength] = {2.0, 3.0, dnan, 3.0, -0.0, 0.0, dinf,
dnan, 42.0, dinf, dminf, dinf, dnan};
double inputsb[kTableLength] = {3.0, 2.0, 3.0, dnan, 0.0, -0.0, dnan,
dinf, dinf, 42.0, dinf, dminf, dnan};
double outputsdmin[kTableLength] = {2.0, 2.0, 3.0, 3.0, -0.0,
-0.0, dinf, dinf, 42.0, 42.0,
dminf, dminf, dnan};
double outputsdmax[kTableLength] = {3.0, 3.0, 3.0, 3.0, 0.0, 0.0, dinf,
dinf, dinf, dinf, dinf, dinf, dnan};
float inputse[kTableLength] = {2.0, 3.0, fnan, 3.0, -0.0, 0.0, finf,
fnan, 42.0, finf, fminf, finf, fnan};
float inputsf[kTableLength] = {3.0, 2.0, 3.0, fnan, 0.0, -0.0, fnan,
finf, finf, 42.0, finf, fminf, fnan};
float outputsfmin[kTableLength] = {2.0, 2.0, 3.0, 3.0, -0.0,
-0.0, finf, finf, 42.0, 42.0,
fminf, fminf, fnan};
float outputsfmax[kTableLength] = {3.0, 3.0, 3.0, 3.0, 0.0, 0.0, finf,
finf, finf, finf, finf, finf, fnan};
__ Ldc1(f4, MemOperand(a0, offsetof(TestFloat, a)));
__ Ldc1(f8, MemOperand(a0, offsetof(TestFloat, b)));
__ Lwc1(f2, MemOperand(a0, offsetof(TestFloat, e)));
__ Lwc1(f6, MemOperand(a0, offsetof(TestFloat, f)));
__ min_d(f10, f4, f8);
__ max_d(f12, f4, f8);
__ min_s(f14, f2, f6);
__ max_s(f16, f2, f6);
__ Sdc1(f10, MemOperand(a0, offsetof(TestFloat, c)));
__ Sdc1(f12, MemOperand(a0, offsetof(TestFloat, d)));
__ Swc1(f14, MemOperand(a0, offsetof(TestFloat, g)));
__ Swc1(f16, MemOperand(a0, offsetof(TestFloat, h)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
for (int i = 4; i < kTableLength; i++) {
test.a = inputsa[i];
test.b = inputsb[i];
test.e = inputse[i];
test.f = inputsf[i];
CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0);
CHECK_EQ(0, memcmp(&test.c, &outputsdmin[i], sizeof(test.c)));
CHECK_EQ(0, memcmp(&test.d, &outputsdmax[i], sizeof(test.d)));
CHECK_EQ(0, memcmp(&test.g, &outputsfmin[i], sizeof(test.g)));
CHECK_EQ(0, memcmp(&test.h, &outputsfmax[i], sizeof(test.h)));
}
}
}
TEST(rint_d) {
if (kArchVariant == kMips64r6) {
const int kTableLength = 30;
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test_float {
double a;
double b;
int fcsr;
}TestFloat;
TestFloat test;
double inputs[kTableLength] = {18446744073709551617.0,
4503599627370496.0, -4503599627370496.0,
1.26782468584154733584017312973E30, 1.44860108245951772690707170478E147,
1.7976931348623157E+308, 6.27463370218383111104242366943E-307,
309485009821345068724781056.89,
2.1, 2.6, 2.5, 3.1, 3.6, 3.5,
-2.1, -2.6, -2.5, -3.1, -3.6, -3.5,
37778931862957161709568.0, 37778931862957161709569.0,
37778931862957161709580.0, 37778931862957161709581.0,
37778931862957161709582.0, 37778931862957161709583.0,
37778931862957161709584.0, 37778931862957161709585.0,
37778931862957161709586.0, 37778931862957161709587.0};
double outputs_RN[kTableLength] = {18446744073709551617.0,
4503599627370496.0, -4503599627370496.0,
1.26782468584154733584017312973E30, 1.44860108245951772690707170478E147,
1.7976931348623157E308, 0,
309485009821345068724781057.0,
2.0, 3.0, 2.0, 3.0, 4.0, 4.0,
-2.0, -3.0, -2.0, -3.0, -4.0, -4.0,
37778931862957161709568.0, 37778931862957161709569.0,
37778931862957161709580.0, 37778931862957161709581.0,
37778931862957161709582.0, 37778931862957161709583.0,
37778931862957161709584.0, 37778931862957161709585.0,
37778931862957161709586.0, 37778931862957161709587.0};
double outputs_RZ[kTableLength] = {18446744073709551617.0,
4503599627370496.0, -4503599627370496.0,
1.26782468584154733584017312973E30, 1.44860108245951772690707170478E147,
1.7976931348623157E308, 0,
309485009821345068724781057.0,
2.0, 2.0, 2.0, 3.0, 3.0, 3.0,
-2.0, -2.0, -2.0, -3.0, -3.0, -3.0,
37778931862957161709568.0, 37778931862957161709569.0,
37778931862957161709580.0, 37778931862957161709581.0,
37778931862957161709582.0, 37778931862957161709583.0,
37778931862957161709584.0, 37778931862957161709585.0,
37778931862957161709586.0, 37778931862957161709587.0};
double outputs_RP[kTableLength] = {18446744073709551617.0,
4503599627370496.0, -4503599627370496.0,
1.26782468584154733584017312973E30, 1.44860108245951772690707170478E147,
1.7976931348623157E308, 1,
309485009821345068724781057.0,
3.0, 3.0, 3.0, 4.0, 4.0, 4.0,
-2.0, -2.0, -2.0, -3.0, -3.0, -3.0,
37778931862957161709568.0, 37778931862957161709569.0,
37778931862957161709580.0, 37778931862957161709581.0,
37778931862957161709582.0, 37778931862957161709583.0,
37778931862957161709584.0, 37778931862957161709585.0,
37778931862957161709586.0, 37778931862957161709587.0};
double outputs_RM[kTableLength] = {18446744073709551617.0,
4503599627370496.0, -4503599627370496.0,
1.26782468584154733584017312973E30, 1.44860108245951772690707170478E147,
1.7976931348623157E308, 0,
309485009821345068724781057.0,
2.0, 2.0, 2.0, 3.0, 3.0, 3.0,
-3.0, -3.0, -3.0, -4.0, -4.0, -4.0,
37778931862957161709568.0, 37778931862957161709569.0,
37778931862957161709580.0, 37778931862957161709581.0,
37778931862957161709582.0, 37778931862957161709583.0,
37778931862957161709584.0, 37778931862957161709585.0,
37778931862957161709586.0, 37778931862957161709587.0};
int fcsr_inputs[4] =
{kRoundToNearest, kRoundToZero, kRoundToPlusInf, kRoundToMinusInf};
double* outputs[4] = {outputs_RN, outputs_RZ, outputs_RP, outputs_RM};
__ Ldc1(f4, MemOperand(a0, offsetof(TestFloat, a)));
__ Lw(t0, MemOperand(a0, offsetof(TestFloat, fcsr)));
__ ctc1(t0, FCSR);
__ rint_d(f8, f4);
__ Sdc1(f8, MemOperand(a0, offsetof(TestFloat, b)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
for (int j = 0; j < 4; j++) {
test.fcsr = fcsr_inputs[j];
for (int i = 0; i < kTableLength; i++) {
test.a = inputs[i];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.b, outputs[j][i]);
}
}
}
}
TEST(sel) {
if (kArchVariant == kMips64r6) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test {
double dd;
double ds;
double dt;
float fd;
float fs;
float ft;
} Test;
Test test;
__ Ldc1(f0, MemOperand(a0, offsetof(Test, dd))); // test
__ Ldc1(f2, MemOperand(a0, offsetof(Test, ds))); // src1
__ Ldc1(f4, MemOperand(a0, offsetof(Test, dt))); // src2
__ Lwc1(f6, MemOperand(a0, offsetof(Test, fd))); // test
__ Lwc1(f8, MemOperand(a0, offsetof(Test, fs))); // src1
__ Lwc1(f10, MemOperand(a0, offsetof(Test, ft))); // src2
__ sel_d(f0, f2, f4);
__ sel_s(f6, f8, f10);
__ Sdc1(f0, MemOperand(a0, offsetof(Test, dd)));
__ Swc1(f6, MemOperand(a0, offsetof(Test, fd)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
const int test_size = 3;
const int input_size = 5;
double inputs_dt[input_size] = {0.0, 65.2, -70.32,
18446744073709551621.0, -18446744073709551621.0};
double inputs_ds[input_size] = {0.1, 69.88, -91.325,
18446744073709551625.0, -18446744073709551625.0};
float inputs_ft[input_size] = {0.0, 65.2, -70.32,
18446744073709551621.0, -18446744073709551621.0};
float inputs_fs[input_size] = {0.1, 69.88, -91.325,
18446744073709551625.0, -18446744073709551625.0};
double tests_D[test_size*2] = {2.8, 2.9, -2.8, -2.9,
18446744073709551616.0, 18446744073709555712.0};
float tests_S[test_size*2] = {2.9, 2.8, -2.9, -2.8,
18446744073709551616.0, 18446746272732807168.0};
for (int j=0; j < test_size; j+=2) {
for (int i=0; i < input_size; i++) {
test.dt = inputs_dt[i];
test.dd = tests_D[j];
test.ds = inputs_ds[i];
test.ft = inputs_ft[i];
test.fd = tests_S[j];
test.fs = inputs_fs[i];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.dd, inputs_ds[i]);
CHECK_EQ(test.fd, inputs_fs[i]);
test.dd = tests_D[j+1];
test.fd = tests_S[j+1];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.dd, inputs_dt[i]);
CHECK_EQ(test.fd, inputs_ft[i]);
}
}
}
}
TEST(rint_s) {
if (kArchVariant == kMips64r6) {
const int kTableLength = 30;
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test_float {
float a;
float b;
int fcsr;
}TestFloat;
TestFloat test;
float inputs[kTableLength] = {18446744073709551617.0,
4503599627370496.0, -4503599627370496.0,
1.26782468584154733584017312973E30, 1.44860108245951772690707170478E37,
1.7976931348623157E+38, 6.27463370218383111104242366943E-37,
309485009821345068724781056.89,
2.1, 2.6, 2.5, 3.1, 3.6, 3.5,
-2.1, -2.6, -2.5, -3.1, -3.6, -3.5,
37778931862957161709568.0, 37778931862957161709569.0,
37778931862957161709580.0, 37778931862957161709581.0,
37778931862957161709582.0, 37778931862957161709583.0,
37778931862957161709584.0, 37778931862957161709585.0,
37778931862957161709586.0, 37778931862957161709587.0};
float outputs_RN[kTableLength] = {18446744073709551617.0,
4503599627370496.0, -4503599627370496.0,
1.26782468584154733584017312973E30, 1.44860108245951772690707170478E37,
1.7976931348623157E38, 0,
309485009821345068724781057.0,
2.0, 3.0, 2.0, 3.0, 4.0, 4.0,
-2.0, -3.0, -2.0, -3.0, -4.0, -4.0,
37778931862957161709568.0, 37778931862957161709569.0,
37778931862957161709580.0, 37778931862957161709581.0,
37778931862957161709582.0, 37778931862957161709583.0,
37778931862957161709584.0, 37778931862957161709585.0,
37778931862957161709586.0, 37778931862957161709587.0};
float outputs_RZ[kTableLength] = {18446744073709551617.0,
4503599627370496.0, -4503599627370496.0,
1.26782468584154733584017312973E30, 1.44860108245951772690707170478E37,
1.7976931348623157E38, 0,
309485009821345068724781057.0,
2.0, 2.0, 2.0, 3.0, 3.0, 3.0,
-2.0, -2.0, -2.0, -3.0, -3.0, -3.0,
37778931862957161709568.0, 37778931862957161709569.0,
37778931862957161709580.0, 37778931862957161709581.0,
37778931862957161709582.0, 37778931862957161709583.0,
37778931862957161709584.0, 37778931862957161709585.0,
37778931862957161709586.0, 37778931862957161709587.0};
float outputs_RP[kTableLength] = {18446744073709551617.0,
4503599627370496.0, -4503599627370496.0,
1.26782468584154733584017312973E30, 1.44860108245951772690707170478E37,
1.7976931348623157E38, 1,
309485009821345068724781057.0,
3.0, 3.0, 3.0, 4.0, 4.0, 4.0,
-2.0, -2.0, -2.0, -3.0, -3.0, -3.0,
37778931862957161709568.0, 37778931862957161709569.0,
37778931862957161709580.0, 37778931862957161709581.0,
37778931862957161709582.0, 37778931862957161709583.0,
37778931862957161709584.0, 37778931862957161709585.0,
37778931862957161709586.0, 37778931862957161709587.0};
float outputs_RM[kTableLength] = {18446744073709551617.0,
4503599627370496.0, -4503599627370496.0,
1.26782468584154733584017312973E30, 1.44860108245951772690707170478E37,
1.7976931348623157E38, 0,
309485009821345068724781057.0,
2.0, 2.0, 2.0, 3.0, 3.0, 3.0,
-3.0, -3.0, -3.0, -4.0, -4.0, -4.0,
37778931862957161709568.0, 37778931862957161709569.0,
37778931862957161709580.0, 37778931862957161709581.0,
37778931862957161709582.0, 37778931862957161709583.0,
37778931862957161709584.0, 37778931862957161709585.0,
37778931862957161709586.0, 37778931862957161709587.0};
int fcsr_inputs[4] =
{kRoundToNearest, kRoundToZero, kRoundToPlusInf, kRoundToMinusInf};
float* outputs[4] = {outputs_RN, outputs_RZ, outputs_RP, outputs_RM};
__ Lwc1(f4, MemOperand(a0, offsetof(TestFloat, a)));
__ Lw(t0, MemOperand(a0, offsetof(TestFloat, fcsr)));
__ cfc1(t1, FCSR);
__ ctc1(t0, FCSR);
__ rint_s(f8, f4);
__ Swc1(f8, MemOperand(a0, offsetof(TestFloat, b)));
__ ctc1(t1, FCSR);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
for (int j = 0; j < 4; j++) {
test.fcsr = fcsr_inputs[j];
for (int i = 0; i < kTableLength; i++) {
test.a = inputs[i];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.b, outputs[j][i]);
}
}
}
}
TEST(mina_maxa) {
if (kArchVariant == kMips64r6) {
const int kTableLength = 23;
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
const double dnan = std::numeric_limits<double>::quiet_NaN();
const double dinf = std::numeric_limits<double>::infinity();
const double dminf = -std::numeric_limits<double>::infinity();
const float fnan = std::numeric_limits<float>::quiet_NaN();
const float finf = std::numeric_limits<float>::infinity();
const float fminf = std::numeric_limits<float>::infinity();
struct TestFloat {
double a;
double b;
double resd;
double resd1;
float c;
float d;
float resf;
float resf1;
};
TestFloat test;
double inputsa[kTableLength] = {
5.3, 4.8, 6.1, 9.8, 9.8, 9.8, -10.0, -8.9, -9.8, -10.0, -8.9, -9.8,
dnan, 3.0, -0.0, 0.0, dinf, dnan, 42.0, dinf, dminf, dinf, dnan};
double inputsb[kTableLength] = {
4.8, 5.3, 6.1, -10.0, -8.9, -9.8, 9.8, 9.8, 9.8, -9.8, -11.2, -9.8,
3.0, dnan, 0.0, -0.0, dnan, dinf, dinf, 42.0, dinf, dminf, dnan};
double resd[kTableLength] = {
4.8, 4.8, 6.1, 9.8, -8.9, -9.8, 9.8, -8.9, -9.8, -9.8, -8.9, -9.8,
3.0, 3.0, -0.0, -0.0, dinf, dinf, 42.0, 42.0, dminf, dminf, dnan};
double resd1[kTableLength] = {
5.3, 5.3, 6.1, -10.0, 9.8, 9.8, -10.0, 9.8, 9.8, -10.0, -11.2, -9.8,
3.0, 3.0, 0.0, 0.0, dinf, dinf, dinf, dinf, dinf, dinf, dnan};
float inputsc[kTableLength] = {
5.3, 4.8, 6.1, 9.8, 9.8, 9.8, -10.0, -8.9, -9.8, -10.0, -8.9, -9.8,
fnan, 3.0, -0.0, 0.0, finf, fnan, 42.0, finf, fminf, finf, fnan};
float inputsd[kTableLength] = {4.8, 5.3, 6.1, -10.0, -8.9, -9.8,
9.8, 9.8, 9.8, -9.8, -11.2, -9.8,
3.0, fnan, -0.0, 0.0, fnan, finf,
finf, 42.0, finf, fminf, fnan};
float resf[kTableLength] = {
4.8, 4.8, 6.1, 9.8, -8.9, -9.8, 9.8, -8.9, -9.8, -9.8, -8.9, -9.8,
3.0, 3.0, -0.0, -0.0, finf, finf, 42.0, 42.0, fminf, fminf, fnan};
float resf1[kTableLength] = {
5.3, 5.3, 6.1, -10.0, 9.8, 9.8, -10.0, 9.8, 9.8, -10.0, -11.2, -9.8,
3.0, 3.0, 0.0, 0.0, finf, finf, finf, finf, finf, finf, fnan};
__ Ldc1(f2, MemOperand(a0, offsetof(TestFloat, a)));
__ Ldc1(f4, MemOperand(a0, offsetof(TestFloat, b)));
__ Lwc1(f8, MemOperand(a0, offsetof(TestFloat, c)));
__ Lwc1(f10, MemOperand(a0, offsetof(TestFloat, d)));
__ mina_d(f6, f2, f4);
__ mina_s(f12, f8, f10);
__ maxa_d(f14, f2, f4);
__ maxa_s(f16, f8, f10);
__ Swc1(f12, MemOperand(a0, offsetof(TestFloat, resf)));
__ Sdc1(f6, MemOperand(a0, offsetof(TestFloat, resd)));
__ Swc1(f16, MemOperand(a0, offsetof(TestFloat, resf1)));
__ Sdc1(f14, MemOperand(a0, offsetof(TestFloat, resd1)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
for (int i = 0; i < kTableLength; i++) {
test.a = inputsa[i];
test.b = inputsb[i];
test.c = inputsc[i];
test.d = inputsd[i];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
if (i < kTableLength - 1) {
CHECK_EQ(test.resd, resd[i]);
CHECK_EQ(test.resf, resf[i]);
CHECK_EQ(test.resd1, resd1[i]);
CHECK_EQ(test.resf1, resf1[i]);
} else {
CHECK(std::isnan(test.resd));
CHECK(std::isnan(test.resf));
CHECK(std::isnan(test.resd1));
CHECK(std::isnan(test.resf1));
}
}
}
}
// ----------------------mips64r2 specific tests----------------------
TEST(trunc_l) {
if (kArchVariant == kMips64r2) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
const double dFPU64InvalidResult = static_cast<double>(kFPU64InvalidResult);
typedef struct test_float {
uint32_t isNaN2008;
double a;
float b;
int64_t c; // a trunc result
int64_t d; // b trunc result
}Test;
const int kTableLength = 15;
double inputs_D[kTableLength] = {
2.1, 2.6, 2.5, 3.1, 3.6, 3.5,
-2.1, -2.6, -2.5, -3.1, -3.6, -3.5,
2147483648.0,
std::numeric_limits<double>::quiet_NaN(),
std::numeric_limits<double>::infinity()
};
float inputs_S[kTableLength] = {
2.1, 2.6, 2.5, 3.1, 3.6, 3.5,
-2.1, -2.6, -2.5, -3.1, -3.6, -3.5,
2147483648.0,
std::numeric_limits<float>::quiet_NaN(),
std::numeric_limits<float>::infinity()
};
double outputs[kTableLength] = {
2.0, 2.0, 2.0, 3.0, 3.0, 3.0,
-2.0, -2.0, -2.0, -3.0, -3.0, -3.0,
2147483648.0, dFPU64InvalidResult,
dFPU64InvalidResult};
double outputsNaN2008[kTableLength] = {
2.0, 2.0, 2.0, 3.0, 3.0, 3.0,
-2.0, -2.0, -2.0, -3.0, -3.0, -3.0,
2147483648.0, dFPU64InvalidResult,
dFPU64InvalidResult};
__ cfc1(t1, FCSR);
__ Sw(t1, MemOperand(a0, offsetof(Test, isNaN2008)));
__ Ldc1(f4, MemOperand(a0, offsetof(Test, a)));
__ Lwc1(f6, MemOperand(a0, offsetof(Test, b)));
__ trunc_l_d(f8, f4);
__ trunc_l_s(f10, f6);
__ Sdc1(f8, MemOperand(a0, offsetof(Test, c)));
__ Sdc1(f10, MemOperand(a0, offsetof(Test, d)));
__ jr(ra);
__ nop();
Test test;
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
for (int i = 0; i < kTableLength; i++) {
test.a = inputs_D[i];
test.b = inputs_S[i];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
if ((test.isNaN2008 & kFCSRNaN2008FlagMask) &&
kArchVariant == kMips64r6) {
CHECK_EQ(test.c, outputsNaN2008[i]);
} else {
CHECK_EQ(test.c, outputs[i]);
}
CHECK_EQ(test.d, test.c);
}
}
}
TEST(movz_movn) {
if (kArchVariant == kMips64r2) {
const int kTableLength = 4;
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test_float {
int64_t rt;
double a;
double b;
double bold;
double b1;
double bold1;
float c;
float d;
float dold;
float d1;
float dold1;
}TestFloat;
TestFloat test;
double inputs_D[kTableLength] = {
5.3, -5.3, 5.3, -2.9
};
double inputs_S[kTableLength] = {
4.8, 4.8, -4.8, -0.29
};
float outputs_S[kTableLength] = {
4.8, 4.8, -4.8, -0.29
};
double outputs_D[kTableLength] = {
5.3, -5.3, 5.3, -2.9
};
__ Ldc1(f2, MemOperand(a0, offsetof(TestFloat, a)));
__ Lwc1(f6, MemOperand(a0, offsetof(TestFloat, c)));
__ Ld(t0, MemOperand(a0, offsetof(TestFloat, rt)));
__ Move(f12, 0.0);
__ Move(f10, 0.0);
__ Move(f16, 0.0);
__ Move(f14, 0.0);
__ Sdc1(f12, MemOperand(a0, offsetof(TestFloat, bold)));
__ Swc1(f10, MemOperand(a0, offsetof(TestFloat, dold)));
__ Sdc1(f16, MemOperand(a0, offsetof(TestFloat, bold1)));
__ Swc1(f14, MemOperand(a0, offsetof(TestFloat, dold1)));
__ movz_s(f10, f6, t0);
__ movz_d(f12, f2, t0);
__ movn_s(f14, f6, t0);
__ movn_d(f16, f2, t0);
__ Swc1(f10, MemOperand(a0, offsetof(TestFloat, d)));
__ Sdc1(f12, MemOperand(a0, offsetof(TestFloat, b)));
__ Swc1(f14, MemOperand(a0, offsetof(TestFloat, d1)));
__ Sdc1(f16, MemOperand(a0, offsetof(TestFloat, b1)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
for (int i = 0; i < kTableLength; i++) {
test.a = inputs_D[i];
test.c = inputs_S[i];
test.rt = 1;
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.b, test.bold);
CHECK_EQ(test.d, test.dold);
CHECK_EQ(test.b1, outputs_D[i]);
CHECK_EQ(test.d1, outputs_S[i]);
test.rt = 0;
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.b, outputs_D[i]);
CHECK_EQ(test.d, outputs_S[i]);
CHECK_EQ(test.b1, test.bold1);
CHECK_EQ(test.d1, test.dold1);
}
}
}
TEST(movt_movd) {
if (kArchVariant == kMips64r2) {
const int kTableLength = 4;
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
typedef struct test_float {
double srcd;
double dstd;
double dstdold;
double dstd1;
double dstdold1;
float srcf;
float dstf;
float dstfold;
float dstf1;
float dstfold1;
int32_t cc;
int32_t fcsr;
}TestFloat;
TestFloat test;
double inputs_D[kTableLength] = {
5.3, -5.3, 20.8, -2.9
};
double inputs_S[kTableLength] = {
4.88, 4.8, -4.8, -0.29
};
float outputs_S[kTableLength] = {
4.88, 4.8, -4.8, -0.29
};
double outputs_D[kTableLength] = {
5.3, -5.3, 20.8, -2.9
};
int condition_flags[8] = {0, 1, 2, 3, 4, 5, 6, 7};
for (int i = 0; i < kTableLength; i++) {
test.srcd = inputs_D[i];
test.srcf = inputs_S[i];
for (int j = 0; j< 8; j++) {
test.cc = condition_flags[j];
if (test.cc == 0) {
test.fcsr = 1 << 23;
} else {
test.fcsr = 1 << (24+condition_flags[j]);
}
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
__ Ldc1(f2, MemOperand(a0, offsetof(TestFloat, srcd)));
__ Lwc1(f4, MemOperand(a0, offsetof(TestFloat, srcf)));
__ Lw(t1, MemOperand(a0, offsetof(TestFloat, fcsr)));
__ cfc1(t0, FCSR);
__ ctc1(t1, FCSR);
__ li(t2, 0x0);
__ mtc1(t2, f12);
__ mtc1(t2, f10);
__ Sdc1(f10, MemOperand(a0, offsetof(TestFloat, dstdold)));
__ Swc1(f12, MemOperand(a0, offsetof(TestFloat, dstfold)));
__ movt_s(f12, f4, test.cc);
__ movt_d(f10, f2, test.cc);
__ Swc1(f12, MemOperand(a0, offsetof(TestFloat, dstf)));
__ Sdc1(f10, MemOperand(a0, offsetof(TestFloat, dstd)));
__ Sdc1(f10, MemOperand(a0, offsetof(TestFloat, dstdold1)));
__ Swc1(f12, MemOperand(a0, offsetof(TestFloat, dstfold1)));
__ movf_s(f12, f4, test.cc);
__ movf_d(f10, f2, test.cc);
__ Swc1(f12, MemOperand(a0, offsetof(TestFloat, dstf1)));
__ Sdc1(f10, MemOperand(a0, offsetof(TestFloat, dstd1)));
__ ctc1(t0, FCSR);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.dstf, outputs_S[i]);
CHECK_EQ(test.dstd, outputs_D[i]);
CHECK_EQ(test.dstf1, test.dstfold1);
CHECK_EQ(test.dstd1, test.dstdold1);
test.fcsr = 0;
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.dstf, test.dstfold);
CHECK_EQ(test.dstd, test.dstdold);
CHECK_EQ(test.dstf1, outputs_S[i]);
CHECK_EQ(test.dstd1, outputs_D[i]);
}
}
}
}
// ----------------------tests for all archs--------------------------
TEST(cvt_w_d) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test_float {
double a;
int32_t b;
int fcsr;
}Test;
const int kTableLength = 24;
double inputs[kTableLength] = {
2.1, 2.6, 2.5, 3.1, 3.6, 3.5,
-2.1, -2.6, -2.5, -3.1, -3.6, -3.5,
2147483637.0, 2147483638.0, 2147483639.0,
2147483640.0, 2147483641.0, 2147483642.0,
2147483643.0, 2147483644.0, 2147483645.0,
2147483646.0, 2147483647.0, 2147483653.0
};
double outputs_RN[kTableLength] = {
2.0, 3.0, 2.0, 3.0, 4.0, 4.0,
-2.0, -3.0, -2.0, -3.0, -4.0, -4.0,
2147483637.0, 2147483638.0, 2147483639.0,
2147483640.0, 2147483641.0, 2147483642.0,
2147483643.0, 2147483644.0, 2147483645.0,
2147483646.0, 2147483647.0, kFPUInvalidResult};
double outputs_RZ[kTableLength] = {
2.0, 2.0, 2.0, 3.0, 3.0, 3.0,
-2.0, -2.0, -2.0, -3.0, -3.0, -3.0,
2147483637.0, 2147483638.0, 2147483639.0,
2147483640.0, 2147483641.0, 2147483642.0,
2147483643.0, 2147483644.0, 2147483645.0,
2147483646.0, 2147483647.0, kFPUInvalidResult};
double outputs_RP[kTableLength] = {
3.0, 3.0, 3.0, 4.0, 4.0, 4.0,
-2.0, -2.0, -2.0, -3.0, -3.0, -3.0,
2147483637.0, 2147483638.0, 2147483639.0,
2147483640.0, 2147483641.0, 2147483642.0,
2147483643.0, 2147483644.0, 2147483645.0,
2147483646.0, 2147483647.0, kFPUInvalidResult};
double outputs_RM[kTableLength] = {
2.0, 2.0, 2.0, 3.0, 3.0, 3.0,
-3.0, -3.0, -3.0, -4.0, -4.0, -4.0,
2147483637.0, 2147483638.0, 2147483639.0,
2147483640.0, 2147483641.0, 2147483642.0,
2147483643.0, 2147483644.0, 2147483645.0,
2147483646.0, 2147483647.0, kFPUInvalidResult};
int fcsr_inputs[4] =
{kRoundToNearest, kRoundToZero, kRoundToPlusInf, kRoundToMinusInf};
double* outputs[4] = {outputs_RN, outputs_RZ, outputs_RP, outputs_RM};
__ Ldc1(f4, MemOperand(a0, offsetof(Test, a)));
__ Lw(t0, MemOperand(a0, offsetof(Test, fcsr)));
__ cfc1(t1, FCSR);
__ ctc1(t0, FCSR);
__ cvt_w_d(f8, f4);
__ Swc1(f8, MemOperand(a0, offsetof(Test, b)));
__ ctc1(t1, FCSR);
__ jr(ra);
__ nop();
Test test;
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
for (int j = 0; j < 4; j++) {
test.fcsr = fcsr_inputs[j];
for (int i = 0; i < kTableLength; i++) {
test.a = inputs[i];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.b, outputs[j][i]);
}
}
}
TEST(trunc_w) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test_float {
uint32_t isNaN2008;
double a;
float b;
int32_t c; // a trunc result
int32_t d; // b trunc result
}Test;
const int kTableLength = 15;
double inputs_D[kTableLength] = {
2.1, 2.6, 2.5, 3.1, 3.6, 3.5,
-2.1, -2.6, -2.5, -3.1, -3.6, -3.5,
2147483648.0,
std::numeric_limits<double>::quiet_NaN(),
std::numeric_limits<double>::infinity()
};
float inputs_S[kTableLength] = {
2.1, 2.6, 2.5, 3.1, 3.6, 3.5,
-2.1, -2.6, -2.5, -3.1, -3.6, -3.5,
2147483648.0,
std::numeric_limits<float>::quiet_NaN(),
std::numeric_limits<float>::infinity()
};
double outputs[kTableLength] = {
2.0, 2.0, 2.0, 3.0, 3.0, 3.0,
-2.0, -2.0, -2.0, -3.0, -3.0, -3.0,
kFPUInvalidResult, kFPUInvalidResult,
kFPUInvalidResult};
double outputsNaN2008[kTableLength] = {
2.0, 2.0, 2.0, 3.0, 3.0, 3.0,
-2.0, -2.0, -2.0, -3.0, -3.0, -3.0,
kFPUInvalidResult,
0,
kFPUInvalidResult};
__ cfc1(t1, FCSR);
__ Sw(t1, MemOperand(a0, offsetof(Test, isNaN2008)));
__ Ldc1(f4, MemOperand(a0, offsetof(Test, a)));
__ Lwc1(f6, MemOperand(a0, offsetof(Test, b)));
__ trunc_w_d(f8, f4);
__ trunc_w_s(f10, f6);
__ Swc1(f8, MemOperand(a0, offsetof(Test, c)));
__ Swc1(f10, MemOperand(a0, offsetof(Test, d)));
__ jr(ra);
__ nop();
Test test;
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
for (int i = 0; i < kTableLength; i++) {
test.a = inputs_D[i];
test.b = inputs_S[i];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
if ((test.isNaN2008 & kFCSRNaN2008FlagMask) && kArchVariant == kMips64r6) {
CHECK_EQ(test.c, outputsNaN2008[i]);
} else {
CHECK_EQ(test.c, outputs[i]);
}
CHECK_EQ(test.d, test.c);
}
}
TEST(round_w) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test_float {
uint32_t isNaN2008;
double a;
float b;
int32_t c; // a trunc result
int32_t d; // b trunc result
}Test;
const int kTableLength = 15;
double inputs_D[kTableLength] = {
2.1, 2.6, 2.5, 3.1, 3.6, 3.5,
-2.1, -2.6, -2.5, -3.1, -3.6, -3.5,
2147483648.0,
std::numeric_limits<double>::quiet_NaN(),
std::numeric_limits<double>::infinity()
};
float inputs_S[kTableLength] = {
2.1, 2.6, 2.5, 3.1, 3.6, 3.5,
-2.1, -2.6, -2.5, -3.1, -3.6, -3.5,
2147483648.0,
std::numeric_limits<float>::quiet_NaN(),
std::numeric_limits<float>::infinity()
};
double outputs[kTableLength] = {
2.0, 3.0, 2.0, 3.0, 4.0, 4.0,
-2.0, -3.0, -2.0, -3.0, -4.0, -4.0,
kFPUInvalidResult, kFPUInvalidResult,
kFPUInvalidResult};
double outputsNaN2008[kTableLength] = {
2.0, 3.0, 2.0, 3.0, 4.0, 4.0,
-2.0, -3.0, -2.0, -3.0, -4.0, -4.0,
kFPUInvalidResult, 0,
kFPUInvalidResult};
__ cfc1(t1, FCSR);
__ Sw(t1, MemOperand(a0, offsetof(Test, isNaN2008)));
__ Ldc1(f4, MemOperand(a0, offsetof(Test, a)));
__ Lwc1(f6, MemOperand(a0, offsetof(Test, b)));
__ round_w_d(f8, f4);
__ round_w_s(f10, f6);
__ Swc1(f8, MemOperand(a0, offsetof(Test, c)));
__ Swc1(f10, MemOperand(a0, offsetof(Test, d)));
__ jr(ra);
__ nop();
Test test;
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
for (int i = 0; i < kTableLength; i++) {
test.a = inputs_D[i];
test.b = inputs_S[i];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
if ((test.isNaN2008 & kFCSRNaN2008FlagMask) && kArchVariant == kMips64r6) {
CHECK_EQ(test.c, outputsNaN2008[i]);
} else {
CHECK_EQ(test.c, outputs[i]);
}
CHECK_EQ(test.d, test.c);
}
}
TEST(round_l) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
const double dFPU64InvalidResult = static_cast<double>(kFPU64InvalidResult);
typedef struct test_float {
uint32_t isNaN2008;
double a;
float b;
int64_t c;
int64_t d;
}Test;
const int kTableLength = 15;
double inputs_D[kTableLength] = {
2.1, 2.6, 2.5, 3.1, 3.6, 3.5,
-2.1, -2.6, -2.5, -3.1, -3.6, -3.5,
2147483648.0,
std::numeric_limits<double>::quiet_NaN(),
std::numeric_limits<double>::infinity()
};
float inputs_S[kTableLength] = {
2.1, 2.6, 2.5, 3.1, 3.6, 3.5,
-2.1, -2.6, -2.5, -3.1, -3.6, -3.5,
2147483648.0,
std::numeric_limits<float>::quiet_NaN(),
std::numeric_limits<float>::infinity()
};
double outputs[kTableLength] = {
2.0, 3.0, 2.0, 3.0, 4.0, 4.0,
-2.0, -3.0, -2.0, -3.0, -4.0, -4.0,
2147483648.0, dFPU64InvalidResult,
dFPU64InvalidResult};
double outputsNaN2008[kTableLength] = {
2.0, 3.0, 2.0, 3.0, 4.0, 4.0,
-2.0, -3.0, -2.0, -3.0, -4.0, -4.0,
2147483648.0,
0,
dFPU64InvalidResult};
__ cfc1(t1, FCSR);
__ Sw(t1, MemOperand(a0, offsetof(Test, isNaN2008)));
__ Ldc1(f4, MemOperand(a0, offsetof(Test, a)));
__ Lwc1(f6, MemOperand(a0, offsetof(Test, b)));
__ round_l_d(f8, f4);
__ round_l_s(f10, f6);
__ Sdc1(f8, MemOperand(a0, offsetof(Test, c)));
__ Sdc1(f10, MemOperand(a0, offsetof(Test, d)));
__ jr(ra);
__ nop();
Test test;
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
for (int i = 0; i < kTableLength; i++) {
test.a = inputs_D[i];
test.b = inputs_S[i];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
if ((test.isNaN2008 & kFCSRNaN2008FlagMask) &&
kArchVariant == kMips64r6) {
CHECK_EQ(test.c, outputsNaN2008[i]);
} else {
CHECK_EQ(test.c, outputs[i]);
}
CHECK_EQ(test.d, test.c);
}
}
TEST(sub) {
const int kTableLength = 12;
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test_float {
float a;
float b;
float resultS;
double c;
double d;
double resultD;
}TestFloat;
TestFloat test;
double inputfs_D[kTableLength] = {
5.3, 4.8, 2.9, -5.3, -4.8, -2.9,
5.3, 4.8, 2.9, -5.3, -4.8, -2.9
};
double inputft_D[kTableLength] = {
4.8, 5.3, 2.9, 4.8, 5.3, 2.9,
-4.8, -5.3, -2.9, -4.8, -5.3, -2.9
};
double outputs_D[kTableLength] = {
0.5, -0.5, 0.0, -10.1, -10.1, -5.8,
10.1, 10.1, 5.8, -0.5, 0.5, 0.0
};
float inputfs_S[kTableLength] = {
5.3, 4.8, 2.9, -5.3, -4.8, -2.9,
5.3, 4.8, 2.9, -5.3, -4.8, -2.9
};
float inputft_S[kTableLength] = {
4.8, 5.3, 2.9, 4.8, 5.3, 2.9,
-4.8, -5.3, -2.9, -4.8, -5.3, -2.9
};
float outputs_S[kTableLength] = {
0.5, -0.5, 0.0, -10.1, -10.1, -5.8,
10.1, 10.1, 5.8, -0.5, 0.5, 0.0
};
__ Lwc1(f2, MemOperand(a0, offsetof(TestFloat, a)));
__ Lwc1(f4, MemOperand(a0, offsetof(TestFloat, b)));
__ Ldc1(f8, MemOperand(a0, offsetof(TestFloat, c)));
__ Ldc1(f10, MemOperand(a0, offsetof(TestFloat, d)));
__ sub_s(f6, f2, f4);
__ sub_d(f12, f8, f10);
__ Swc1(f6, MemOperand(a0, offsetof(TestFloat, resultS)));
__ Sdc1(f12, MemOperand(a0, offsetof(TestFloat, resultD)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
for (int i = 0; i < kTableLength; i++) {
test.a = inputfs_S[i];
test.b = inputft_S[i];
test.c = inputfs_D[i];
test.d = inputft_D[i];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.resultS, outputs_S[i]);
CHECK_EQ(test.resultD, outputs_D[i]);
}
}
TEST(sqrt_rsqrt_recip) {
const int kTableLength = 4;
const double deltaDouble = 2E-15;
const float deltaFloat = 2E-7;
const float sqrt2_s = sqrt(2);
const double sqrt2_d = sqrt(2);
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test_float {
float a;
float resultS;
float resultS1;
float resultS2;
double c;
double resultD;
double resultD1;
double resultD2;
}TestFloat;
TestFloat test;
double inputs_D[kTableLength] = {
0.0L, 4.0L, 2.0L, 4e-28L
};
double outputs_D[kTableLength] = {
0.0L, 2.0L, sqrt2_d, 2e-14L
};
float inputs_S[kTableLength] = {
0.0, 4.0, 2.0, 4e-28
};
float outputs_S[kTableLength] = {
0.0, 2.0, sqrt2_s, 2e-14
};
__ Lwc1(f2, MemOperand(a0, offsetof(TestFloat, a)));
__ Ldc1(f8, MemOperand(a0, offsetof(TestFloat, c)));
__ sqrt_s(f6, f2);
__ sqrt_d(f12, f8);
__ rsqrt_d(f14, f8);
__ rsqrt_s(f16, f2);
__ recip_d(f18, f8);
__ recip_s(f4, f2);
__ Swc1(f6, MemOperand(a0, offsetof(TestFloat, resultS)));
__ Sdc1(f12, MemOperand(a0, offsetof(TestFloat, resultD)));
__ Swc1(f16, MemOperand(a0, offsetof(TestFloat, resultS1)));
__ Sdc1(f14, MemOperand(a0, offsetof(TestFloat, resultD1)));
__ Swc1(f4, MemOperand(a0, offsetof(TestFloat, resultS2)));
__ Sdc1(f18, MemOperand(a0, offsetof(TestFloat, resultD2)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
for (int i = 0; i < kTableLength; i++) {
float f1;
double d1;
test.a = inputs_S[i];
test.c = inputs_D[i];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.resultS, outputs_S[i]);
CHECK_EQ(test.resultD, outputs_D[i]);
if (i != 0) {
f1 = test.resultS1 - 1.0F/outputs_S[i];
f1 = (f1 < 0) ? f1 : -f1;
CHECK(f1 <= deltaFloat);
d1 = test.resultD1 - 1.0L/outputs_D[i];
d1 = (d1 < 0) ? d1 : -d1;
CHECK(d1 <= deltaDouble);
f1 = test.resultS2 - 1.0F/inputs_S[i];
f1 = (f1 < 0) ? f1 : -f1;
CHECK(f1 <= deltaFloat);
d1 = test.resultD2 - 1.0L/inputs_D[i];
d1 = (d1 < 0) ? d1 : -d1;
CHECK(d1 <= deltaDouble);
} else {
CHECK_EQ(test.resultS1, 1.0F/outputs_S[i]);
CHECK_EQ(test.resultD1, 1.0L/outputs_D[i]);
CHECK_EQ(test.resultS2, 1.0F/inputs_S[i]);
CHECK_EQ(test.resultD2, 1.0L/inputs_D[i]);
}
}
}
TEST(neg) {
const int kTableLength = 2;
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test_float {
float a;
float resultS;
double c;
double resultD;
}TestFloat;
TestFloat test;
double inputs_D[kTableLength] = {
4.0, -2.0
};
double outputs_D[kTableLength] = {
-4.0, 2.0
};
float inputs_S[kTableLength] = {
4.0, -2.0
};
float outputs_S[kTableLength] = {
-4.0, 2.0
};
__ Lwc1(f2, MemOperand(a0, offsetof(TestFloat, a)));
__ Ldc1(f8, MemOperand(a0, offsetof(TestFloat, c)));
__ neg_s(f6, f2);
__ neg_d(f12, f8);
__ Swc1(f6, MemOperand(a0, offsetof(TestFloat, resultS)));
__ Sdc1(f12, MemOperand(a0, offsetof(TestFloat, resultD)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
for (int i = 0; i < kTableLength; i++) {
test.a = inputs_S[i];
test.c = inputs_D[i];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.resultS, outputs_S[i]);
CHECK_EQ(test.resultD, outputs_D[i]);
}
}
TEST(mul) {
const int kTableLength = 4;
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test_float {
float a;
float b;
float resultS;
double c;
double d;
double resultD;
}TestFloat;
TestFloat test;
double inputfs_D[kTableLength] = {
5.3, -5.3, 5.3, -2.9
};
double inputft_D[kTableLength] = {
4.8, 4.8, -4.8, -0.29
};
float inputfs_S[kTableLength] = {
5.3, -5.3, 5.3, -2.9
};
float inputft_S[kTableLength] = {
4.8, 4.8, -4.8, -0.29
};
__ Lwc1(f2, MemOperand(a0, offsetof(TestFloat, a)));
__ Lwc1(f4, MemOperand(a0, offsetof(TestFloat, b)));
__ Ldc1(f6, MemOperand(a0, offsetof(TestFloat, c)));
__ Ldc1(f8, MemOperand(a0, offsetof(TestFloat, d)));
__ mul_s(f10, f2, f4);
__ mul_d(f12, f6, f8);
__ Swc1(f10, MemOperand(a0, offsetof(TestFloat, resultS)));
__ Sdc1(f12, MemOperand(a0, offsetof(TestFloat, resultD)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
for (int i = 0; i < kTableLength; i++) {
test.a = inputfs_S[i];
test.b = inputft_S[i];
test.c = inputfs_D[i];
test.d = inputft_D[i];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.resultS, inputfs_S[i]*inputft_S[i]);
CHECK_EQ(test.resultD, inputfs_D[i]*inputft_D[i]);
}
}
TEST(mov) {
const int kTableLength = 4;
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test_float {
double a;
double b;
float c;
float d;
}TestFloat;
TestFloat test;
double inputs_D[kTableLength] = {
5.3, -5.3, 5.3, -2.9
};
double inputs_S[kTableLength] = {
4.8, 4.8, -4.8, -0.29
};
float outputs_S[kTableLength] = {
4.8, 4.8, -4.8, -0.29
};
double outputs_D[kTableLength] = {
5.3, -5.3, 5.3, -2.9
};
__ Ldc1(f4, MemOperand(a0, offsetof(TestFloat, a)));
__ Lwc1(f6, MemOperand(a0, offsetof(TestFloat, c)));
__ mov_s(f8, f6);
__ mov_d(f10, f4);
__ Swc1(f8, MemOperand(a0, offsetof(TestFloat, d)));
__ Sdc1(f10, MemOperand(a0, offsetof(TestFloat, b)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
for (int i = 0; i < kTableLength; i++) {
test.a = inputs_D[i];
test.c = inputs_S[i];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.b, outputs_D[i]);
CHECK_EQ(test.d, outputs_S[i]);
}
}
TEST(floor_w) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test_float {
uint32_t isNaN2008;
double a;
float b;
int32_t c; // a floor result
int32_t d; // b floor result
}Test;
const int kTableLength = 15;
double inputs_D[kTableLength] = {
2.1, 2.6, 2.5, 3.1, 3.6, 3.5,
-2.1, -2.6, -2.5, -3.1, -3.6, -3.5,
2147483648.0,
std::numeric_limits<double>::quiet_NaN(),
std::numeric_limits<double>::infinity()
};
float inputs_S[kTableLength] = {
2.1, 2.6, 2.5, 3.1, 3.6, 3.5,
-2.1, -2.6, -2.5, -3.1, -3.6, -3.5,
2147483648.0,
std::numeric_limits<float>::quiet_NaN(),
std::numeric_limits<float>::infinity()
};
double outputs[kTableLength] = {
2.0, 2.0, 2.0, 3.0, 3.0, 3.0,
-3.0, -3.0, -3.0, -4.0, -4.0, -4.0,
kFPUInvalidResult, kFPUInvalidResult,
kFPUInvalidResult};
double outputsNaN2008[kTableLength] = {
2.0, 2.0, 2.0, 3.0, 3.0, 3.0,
-3.0, -3.0, -3.0, -4.0, -4.0, -4.0,
kFPUInvalidResult,
0,
kFPUInvalidResult};
__ cfc1(t1, FCSR);
__ Sw(t1, MemOperand(a0, offsetof(Test, isNaN2008)));
__ Ldc1(f4, MemOperand(a0, offsetof(Test, a)));
__ Lwc1(f6, MemOperand(a0, offsetof(Test, b)));
__ floor_w_d(f8, f4);
__ floor_w_s(f10, f6);
__ Swc1(f8, MemOperand(a0, offsetof(Test, c)));
__ Swc1(f10, MemOperand(a0, offsetof(Test, d)));
__ jr(ra);
__ nop();
Test test;
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
for (int i = 0; i < kTableLength; i++) {
test.a = inputs_D[i];
test.b = inputs_S[i];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
if ((test.isNaN2008 & kFCSRNaN2008FlagMask) && kArchVariant == kMips64r6) {
CHECK_EQ(test.c, outputsNaN2008[i]);
} else {
CHECK_EQ(test.c, outputs[i]);
}
CHECK_EQ(test.d, test.c);
}
}
TEST(floor_l) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
const double dFPU64InvalidResult = static_cast<double>(kFPU64InvalidResult);
typedef struct test_float {
uint32_t isNaN2008;
double a;
float b;
int64_t c;
int64_t d;
}Test;
const int kTableLength = 15;
double inputs_D[kTableLength] = {
2.1, 2.6, 2.5, 3.1, 3.6, 3.5,
-2.1, -2.6, -2.5, -3.1, -3.6, -3.5,
2147483648.0,
std::numeric_limits<double>::quiet_NaN(),
std::numeric_limits<double>::infinity()
};
float inputs_S[kTableLength] = {
2.1, 2.6, 2.5, 3.1, 3.6, 3.5,
-2.1, -2.6, -2.5, -3.1, -3.6, -3.5,
2147483648.0,
std::numeric_limits<float>::quiet_NaN(),
std::numeric_limits<float>::infinity()
};
double outputs[kTableLength] = {
2.0, 2.0, 2.0, 3.0, 3.0, 3.0,
-3.0, -3.0, -3.0, -4.0, -4.0, -4.0,
2147483648.0, dFPU64InvalidResult,
dFPU64InvalidResult};
double outputsNaN2008[kTableLength] = {
2.0, 2.0, 2.0, 3.0, 3.0, 3.0,
-3.0, -3.0, -3.0, -4.0, -4.0, -4.0,
2147483648.0,
0,
dFPU64InvalidResult};
__ cfc1(t1, FCSR);
__ Sw(t1, MemOperand(a0, offsetof(Test, isNaN2008)));
__ Ldc1(f4, MemOperand(a0, offsetof(Test, a)));
__ Lwc1(f6, MemOperand(a0, offsetof(Test, b)));
__ floor_l_d(f8, f4);
__ floor_l_s(f10, f6);
__ Sdc1(f8, MemOperand(a0, offsetof(Test, c)));
__ Sdc1(f10, MemOperand(a0, offsetof(Test, d)));
__ jr(ra);
__ nop();
Test test;
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
for (int i = 0; i < kTableLength; i++) {
test.a = inputs_D[i];
test.b = inputs_S[i];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
if ((test.isNaN2008 & kFCSRNaN2008FlagMask) &&
kArchVariant == kMips64r6) {
CHECK_EQ(test.c, outputsNaN2008[i]);
} else {
CHECK_EQ(test.c, outputs[i]);
}
CHECK_EQ(test.d, test.c);
}
}
TEST(ceil_w) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test_float {
uint32_t isNaN2008;
double a;
float b;
int32_t c; // a floor result
int32_t d; // b floor result
}Test;
const int kTableLength = 15;
double inputs_D[kTableLength] = {
2.1, 2.6, 2.5, 3.1, 3.6, 3.5,
-2.1, -2.6, -2.5, -3.1, -3.6, -3.5,
2147483648.0,
std::numeric_limits<double>::quiet_NaN(),
std::numeric_limits<double>::infinity()
};
float inputs_S[kTableLength] = {
2.1, 2.6, 2.5, 3.1, 3.6, 3.5,
-2.1, -2.6, -2.5, -3.1, -3.6, -3.5,
2147483648.0,
std::numeric_limits<float>::quiet_NaN(),
std::numeric_limits<float>::infinity()
};
double outputs[kTableLength] = {
3.0, 3.0, 3.0, 4.0, 4.0, 4.0,
-2.0, -2.0, -2.0, -3.0, -3.0, -3.0,
kFPUInvalidResult, kFPUInvalidResult,
kFPUInvalidResult};
double outputsNaN2008[kTableLength] = {
3.0, 3.0, 3.0, 4.0, 4.0, 4.0,
-2.0, -2.0, -2.0, -3.0, -3.0, -3.0,
kFPUInvalidResult,
0,
kFPUInvalidResult};
__ cfc1(t1, FCSR);
__ Sw(t1, MemOperand(a0, offsetof(Test, isNaN2008)));
__ Ldc1(f4, MemOperand(a0, offsetof(Test, a)));
__ Lwc1(f6, MemOperand(a0, offsetof(Test, b)));
__ ceil_w_d(f8, f4);
__ ceil_w_s(f10, f6);
__ Swc1(f8, MemOperand(a0, offsetof(Test, c)));
__ Swc1(f10, MemOperand(a0, offsetof(Test, d)));
__ jr(ra);
__ nop();
Test test;
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
for (int i = 0; i < kTableLength; i++) {
test.a = inputs_D[i];
test.b = inputs_S[i];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
if ((test.isNaN2008 & kFCSRNaN2008FlagMask) && kArchVariant == kMips64r6) {
CHECK_EQ(test.c, outputsNaN2008[i]);
} else {
CHECK_EQ(test.c, outputs[i]);
}
CHECK_EQ(test.d, test.c);
}
}
TEST(ceil_l) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
const double dFPU64InvalidResult = static_cast<double>(kFPU64InvalidResult);
typedef struct test_float {
uint32_t isNaN2008;
double a;
float b;
int64_t c;
int64_t d;
}Test;
const int kTableLength = 15;
double inputs_D[kTableLength] = {
2.1, 2.6, 2.5, 3.1, 3.6, 3.5,
-2.1, -2.6, -2.5, -3.1, -3.6, -3.5,
2147483648.0,
std::numeric_limits<double>::quiet_NaN(),
std::numeric_limits<double>::infinity()
};
float inputs_S[kTableLength] = {
2.1, 2.6, 2.5, 3.1, 3.6, 3.5,
-2.1, -2.6, -2.5, -3.1, -3.6, -3.5,
2147483648.0,
std::numeric_limits<float>::quiet_NaN(),
std::numeric_limits<float>::infinity()
};
double outputs[kTableLength] = {
3.0, 3.0, 3.0, 4.0, 4.0, 4.0,
-2.0, -2.0, -2.0, -3.0, -3.0, -3.0,
2147483648.0, dFPU64InvalidResult,
dFPU64InvalidResult};
double outputsNaN2008[kTableLength] = {
3.0, 3.0, 3.0, 4.0, 4.0, 4.0,
-2.0, -2.0, -2.0, -3.0, -3.0, -3.0,
2147483648.0,
0,
dFPU64InvalidResult};
__ cfc1(t1, FCSR);
__ Sw(t1, MemOperand(a0, offsetof(Test, isNaN2008)));
__ Ldc1(f4, MemOperand(a0, offsetof(Test, a)));
__ Lwc1(f6, MemOperand(a0, offsetof(Test, b)));
__ ceil_l_d(f8, f4);
__ ceil_l_s(f10, f6);
__ Sdc1(f8, MemOperand(a0, offsetof(Test, c)));
__ Sdc1(f10, MemOperand(a0, offsetof(Test, d)));
__ jr(ra);
__ nop();
Test test;
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
for (int i = 0; i < kTableLength; i++) {
test.a = inputs_D[i];
test.b = inputs_S[i];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
if ((test.isNaN2008 & kFCSRNaN2008FlagMask) &&
kArchVariant == kMips64r6) {
CHECK_EQ(test.c, outputsNaN2008[i]);
} else {
CHECK_EQ(test.c, outputs[i]);
}
CHECK_EQ(test.d, test.c);
}
}
TEST(jump_tables1) {
// Test jump tables with forward jumps.
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
const int kNumCases = 512;
int values[kNumCases];
isolate->random_number_generator()->NextBytes(values, sizeof(values));
Label labels[kNumCases];
__ daddiu(sp, sp, -8);
__ Sd(ra, MemOperand(sp));
__ Align(8);
Label done;
{
__ BlockTrampolinePoolFor(kNumCases * 2 + 6);
PredictableCodeSizeScope predictable(
&assm, (kNumCases * 2 + 6) * Assembler::kInstrSize);
Label here;
__ bal(&here);
__ dsll(at, a0, 3); // In delay slot.
__ bind(&here);
__ daddu(at, at, ra);
__ Ld(at, MemOperand(at, 4 * Assembler::kInstrSize));
__ jr(at);
__ nop();
for (int i = 0; i < kNumCases; ++i) {
__ dd(&labels[i]);
}
}
for (int i = 0; i < kNumCases; ++i) {
__ bind(&labels[i]);
__ lui(v0, (values[i] >> 16) & 0xffff);
__ ori(v0, v0, values[i] & 0xffff);
__ b(&done);
__ nop();
}
__ bind(&done);
__ Ld(ra, MemOperand(sp));
__ daddiu(sp, sp, 8);
__ jr(ra);
__ nop();
CHECK_EQ(0, assm.UnboundLabelsCount());
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F1 f = FUNCTION_CAST<F1>(code->entry());
for (int i = 0; i < kNumCases; ++i) {
int64_t res = reinterpret_cast<int64_t>(
CALL_GENERATED_CODE(isolate, f, i, 0, 0, 0, 0));
::printf("f(%d) = %" PRId64 "\n", i, res);
CHECK_EQ(values[i], static_cast<int>(res));
}
}
TEST(jump_tables2) {
// Test jump tables with backward jumps.
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
const int kNumCases = 512;
int values[kNumCases];
isolate->random_number_generator()->NextBytes(values, sizeof(values));
Label labels[kNumCases];
__ daddiu(sp, sp, -8);
__ Sd(ra, MemOperand(sp));
Label done, dispatch;
__ b(&dispatch);
__ nop();
for (int i = 0; i < kNumCases; ++i) {
__ bind(&labels[i]);
__ lui(v0, (values[i] >> 16) & 0xffff);
__ ori(v0, v0, values[i] & 0xffff);
__ b(&done);
__ nop();
}
__ Align(8);
__ bind(&dispatch);
{
__ BlockTrampolinePoolFor(kNumCases * 2 + 6);
PredictableCodeSizeScope predictable(
&assm, (kNumCases * 2 + 6) * Assembler::kInstrSize);
Label here;
__ bal(&here);
__ dsll(at, a0, 3); // In delay slot.
__ bind(&here);
__ daddu(at, at, ra);
__ Ld(at, MemOperand(at, 4 * Assembler::kInstrSize));
__ jr(at);
__ nop();
for (int i = 0; i < kNumCases; ++i) {
__ dd(&labels[i]);
}
}
__ bind(&done);
__ Ld(ra, MemOperand(sp));
__ daddiu(sp, sp, 8);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F1 f = FUNCTION_CAST<F1>(code->entry());
for (int i = 0; i < kNumCases; ++i) {
int64_t res = reinterpret_cast<int64_t>(
CALL_GENERATED_CODE(isolate, f, i, 0, 0, 0, 0));
::printf("f(%d) = %" PRId64 "\n", i, res);
CHECK_EQ(values[i], res);
}
}
TEST(jump_tables3) {
// Test jump tables with backward jumps and embedded heap objects.
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
const int kNumCases = 512;
Handle<Object> values[kNumCases];
for (int i = 0; i < kNumCases; ++i) {
double value = isolate->random_number_generator()->NextDouble();
values[i] = isolate->factory()->NewHeapNumber(value, IMMUTABLE, TENURED);
}
Label labels[kNumCases];
Object* obj;
int64_t imm64;
__ daddiu(sp, sp, -8);
__ Sd(ra, MemOperand(sp));
Label done, dispatch;
__ b(&dispatch);
__ nop();
for (int i = 0; i < kNumCases; ++i) {
__ bind(&labels[i]);
obj = *values[i];
imm64 = reinterpret_cast<intptr_t>(obj);
__ lui(v0, (imm64 >> 32) & kImm16Mask);
__ ori(v0, v0, (imm64 >> 16) & kImm16Mask);
__ dsll(v0, v0, 16);
__ ori(v0, v0, imm64 & kImm16Mask);
__ b(&done);
__ nop();
}
__ Align(8);
__ bind(&dispatch);
{
__ BlockTrampolinePoolFor(kNumCases * 2 + 6);
PredictableCodeSizeScope predictable(
&assm, (kNumCases * 2 + 6) * Assembler::kInstrSize);
Label here;
__ bal(&here);
__ dsll(at, a0, 3); // In delay slot.
__ bind(&here);
__ daddu(at, at, ra);
__ Ld(at, MemOperand(at, 4 * Assembler::kInstrSize));
__ jr(at);
__ nop();
for (int i = 0; i < kNumCases; ++i) {
__ dd(&labels[i]);
}
}
__ bind(&done);
__ Ld(ra, MemOperand(sp));
__ daddiu(sp, sp, 8);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F1 f = FUNCTION_CAST<F1>(code->entry());
for (int i = 0; i < kNumCases; ++i) {
Handle<Object> result(
CALL_GENERATED_CODE(isolate, f, i, 0, 0, 0, 0), isolate);
#ifdef OBJECT_PRINT
::printf("f(%d) = ", i);
result->Print(std::cout);
::printf("\n");
#endif
CHECK(values[i].is_identical_to(result));
}
}
TEST(BITSWAP) {
// Test BITSWAP
if (kArchVariant == kMips64r6) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
typedef struct {
int64_t r1;
int64_t r2;
int64_t r3;
int64_t r4;
int64_t r5;
int64_t r6;
} T;
T t;
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
__ Ld(a4, MemOperand(a0, offsetof(T, r1)));
__ nop();
__ bitswap(a6, a4);
__ Sd(a6, MemOperand(a0, offsetof(T, r1)));
__ Ld(a4, MemOperand(a0, offsetof(T, r2)));
__ nop();
__ bitswap(a6, a4);
__ Sd(a6, MemOperand(a0, offsetof(T, r2)));
__ Ld(a4, MemOperand(a0, offsetof(T, r3)));
__ nop();
__ bitswap(a6, a4);
__ Sd(a6, MemOperand(a0, offsetof(T, r3)));
__ Ld(a4, MemOperand(a0, offsetof(T, r4)));
__ nop();
__ bitswap(a6, a4);
__ Sd(a6, MemOperand(a0, offsetof(T, r4)));
__ Ld(a4, MemOperand(a0, offsetof(T, r5)));
__ nop();
__ dbitswap(a6, a4);
__ Sd(a6, MemOperand(a0, offsetof(T, r5)));
__ Ld(a4, MemOperand(a0, offsetof(T, r6)));
__ nop();
__ dbitswap(a6, a4);
__ Sd(a6, MemOperand(a0, offsetof(T, r6)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
t.r1 = 0x00102100781A15C3;
t.r2 = 0x001021008B71FCDE;
t.r3 = 0xFF8017FF781A15C3;
t.r4 = 0xFF8017FF8B71FCDE;
t.r5 = 0x10C021098B71FCDE;
t.r6 = 0xFB8017FF781A15C3;
Object* dummy = CALL_GENERATED_CODE(isolate, f, &t, 0, 0, 0, 0);
USE(dummy);
CHECK_EQ(static_cast<int64_t>(0x000000001E58A8C3L), t.r1);
CHECK_EQ(static_cast<int64_t>(0xFFFFFFFFD18E3F7BL), t.r2);
CHECK_EQ(static_cast<int64_t>(0x000000001E58A8C3L), t.r3);
CHECK_EQ(static_cast<int64_t>(0xFFFFFFFFD18E3F7BL), t.r4);
CHECK_EQ(static_cast<int64_t>(0x08038490D18E3F7BL), t.r5);
CHECK_EQ(static_cast<int64_t>(0xDF01E8FF1E58A8C3L), t.r6);
}
}
TEST(class_fmt) {
if (kArchVariant == kMips64r6) {
// Test CLASS.fmt instruction.
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
typedef struct {
double dSignalingNan;
double dQuietNan;
double dNegInf;
double dNegNorm;
double dNegSubnorm;
double dNegZero;
double dPosInf;
double dPosNorm;
double dPosSubnorm;
double dPosZero;
float fSignalingNan;
float fQuietNan;
float fNegInf;
float fNegNorm;
float fNegSubnorm;
float fNegZero;
float fPosInf;
float fPosNorm;
float fPosSubnorm;
float fPosZero; } T;
T t;
// Create a function that accepts &t, and loads, manipulates, and stores
// the doubles t.a ... t.f.
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
__ Ldc1(f4, MemOperand(a0, offsetof(T, dSignalingNan)));
__ class_d(f6, f4);
__ Sdc1(f6, MemOperand(a0, offsetof(T, dSignalingNan)));
__ Ldc1(f4, MemOperand(a0, offsetof(T, dQuietNan)));
__ class_d(f6, f4);
__ Sdc1(f6, MemOperand(a0, offsetof(T, dQuietNan)));
__ Ldc1(f4, MemOperand(a0, offsetof(T, dNegInf)));
__ class_d(f6, f4);
__ Sdc1(f6, MemOperand(a0, offsetof(T, dNegInf)));
__ Ldc1(f4, MemOperand(a0, offsetof(T, dNegNorm)));
__ class_d(f6, f4);
__ Sdc1(f6, MemOperand(a0, offsetof(T, dNegNorm)));
__ Ldc1(f4, MemOperand(a0, offsetof(T, dNegSubnorm)));
__ class_d(f6, f4);
__ Sdc1(f6, MemOperand(a0, offsetof(T, dNegSubnorm)));
__ Ldc1(f4, MemOperand(a0, offsetof(T, dNegZero)));
__ class_d(f6, f4);
__ Sdc1(f6, MemOperand(a0, offsetof(T, dNegZero)));
__ Ldc1(f4, MemOperand(a0, offsetof(T, dPosInf)));
__ class_d(f6, f4);
__ Sdc1(f6, MemOperand(a0, offsetof(T, dPosInf)));
__ Ldc1(f4, MemOperand(a0, offsetof(T, dPosNorm)));
__ class_d(f6, f4);
__ Sdc1(f6, MemOperand(a0, offsetof(T, dPosNorm)));
__ Ldc1(f4, MemOperand(a0, offsetof(T, dPosSubnorm)));
__ class_d(f6, f4);
__ Sdc1(f6, MemOperand(a0, offsetof(T, dPosSubnorm)));
__ Ldc1(f4, MemOperand(a0, offsetof(T, dPosZero)));
__ class_d(f6, f4);
__ Sdc1(f6, MemOperand(a0, offsetof(T, dPosZero)));
// Testing instruction CLASS.S
__ Lwc1(f4, MemOperand(a0, offsetof(T, fSignalingNan)));
__ class_s(f6, f4);
__ Swc1(f6, MemOperand(a0, offsetof(T, fSignalingNan)));
__ Lwc1(f4, MemOperand(a0, offsetof(T, fQuietNan)));
__ class_s(f6, f4);
__ Swc1(f6, MemOperand(a0, offsetof(T, fQuietNan)));
__ Lwc1(f4, MemOperand(a0, offsetof(T, fNegInf)));
__ class_s(f6, f4);
__ Swc1(f6, MemOperand(a0, offsetof(T, fNegInf)));
__ Lwc1(f4, MemOperand(a0, offsetof(T, fNegNorm)));
__ class_s(f6, f4);
__ Swc1(f6, MemOperand(a0, offsetof(T, fNegNorm)));
__ Lwc1(f4, MemOperand(a0, offsetof(T, fNegSubnorm)));
__ class_s(f6, f4);
__ Swc1(f6, MemOperand(a0, offsetof(T, fNegSubnorm)));
__ Lwc1(f4, MemOperand(a0, offsetof(T, fNegZero)));
__ class_s(f6, f4);
__ Swc1(f6, MemOperand(a0, offsetof(T, fNegZero)));
__ Lwc1(f4, MemOperand(a0, offsetof(T, fPosInf)));
__ class_s(f6, f4);
__ Swc1(f6, MemOperand(a0, offsetof(T, fPosInf)));
__ Lwc1(f4, MemOperand(a0, offsetof(T, fPosNorm)));
__ class_s(f6, f4);
__ Swc1(f6, MemOperand(a0, offsetof(T, fPosNorm)));
__ Lwc1(f4, MemOperand(a0, offsetof(T, fPosSubnorm)));
__ class_s(f6, f4);
__ Swc1(f6, MemOperand(a0, offsetof(T, fPosSubnorm)));
__ Lwc1(f4, MemOperand(a0, offsetof(T, fPosZero)));
__ class_s(f6, f4);
__ Swc1(f6, MemOperand(a0, offsetof(T, fPosZero)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
// Double test values.
t.dSignalingNan = std::numeric_limits<double>::signaling_NaN();
t.dQuietNan = std::numeric_limits<double>::quiet_NaN();
t.dNegInf = -1.0 / 0.0;
t.dNegNorm = -5.0;
t.dNegSubnorm = -DBL_MIN / 2.0;
t.dNegZero = -0.0;
t.dPosInf = 2.0 / 0.0;
t.dPosNorm = 275.35;
t.dPosSubnorm = DBL_MIN / 2.0;
t.dPosZero = +0.0;
// Float test values
t.fSignalingNan = std::numeric_limits<float>::signaling_NaN();
t.fQuietNan = std::numeric_limits<float>::quiet_NaN();
t.fNegInf = -0.5/0.0;
t.fNegNorm = -FLT_MIN;
t.fNegSubnorm = -FLT_MIN / 1.5;
t.fNegZero = -0.0;
t.fPosInf = 100000.0 / 0.0;
t.fPosNorm = FLT_MAX;
t.fPosSubnorm = FLT_MIN / 20.0;
t.fPosZero = +0.0;
Object* dummy = CALL_GENERATED_CODE(isolate, f, &t, 0, 0, 0, 0);
USE(dummy);
// Expected double results.
CHECK_EQ(bit_cast<int64_t>(t.dSignalingNan), 0x001);
CHECK_EQ(bit_cast<int64_t>(t.dQuietNan), 0x002);
CHECK_EQ(bit_cast<int64_t>(t.dNegInf), 0x004);
CHECK_EQ(bit_cast<int64_t>(t.dNegNorm), 0x008);
CHECK_EQ(bit_cast<int64_t>(t.dNegSubnorm), 0x010);
CHECK_EQ(bit_cast<int64_t>(t.dNegZero), 0x020);
CHECK_EQ(bit_cast<int64_t>(t.dPosInf), 0x040);
CHECK_EQ(bit_cast<int64_t>(t.dPosNorm), 0x080);
CHECK_EQ(bit_cast<int64_t>(t.dPosSubnorm), 0x100);
CHECK_EQ(bit_cast<int64_t>(t.dPosZero), 0x200);
// Expected float results.
CHECK_EQ(bit_cast<int32_t>(t.fSignalingNan), 0x001);
CHECK_EQ(bit_cast<int32_t>(t.fQuietNan), 0x002);
CHECK_EQ(bit_cast<int32_t>(t.fNegInf), 0x004);
CHECK_EQ(bit_cast<int32_t>(t.fNegNorm), 0x008);
CHECK_EQ(bit_cast<int32_t>(t.fNegSubnorm), 0x010);
CHECK_EQ(bit_cast<int32_t>(t.fNegZero), 0x020);
CHECK_EQ(bit_cast<int32_t>(t.fPosInf), 0x040);
CHECK_EQ(bit_cast<int32_t>(t.fPosNorm), 0x080);
CHECK_EQ(bit_cast<int32_t>(t.fPosSubnorm), 0x100);
CHECK_EQ(bit_cast<int32_t>(t.fPosZero), 0x200);
}
}
TEST(ABS) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test_float {
int64_t fir;
double a;
float b;
double fcsr;
} TestFloat;
TestFloat test;
// Save FIR.
__ cfc1(a1, FCSR);
__ Sd(a1, MemOperand(a0, offsetof(TestFloat, fcsr)));
// Disable FPU exceptions.
__ ctc1(zero_reg, FCSR);
__ Ldc1(f4, MemOperand(a0, offsetof(TestFloat, a)));
__ abs_d(f10, f4);
__ Sdc1(f10, MemOperand(a0, offsetof(TestFloat, a)));
__ Lwc1(f4, MemOperand(a0, offsetof(TestFloat, b)));
__ abs_s(f10, f4);
__ Swc1(f10, MemOperand(a0, offsetof(TestFloat, b)));
// Restore FCSR.
__ ctc1(a1, FCSR);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
test.a = -2.0;
test.b = -2.0;
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.a, 2.0);
CHECK_EQ(test.b, 2.0);
test.a = 2.0;
test.b = 2.0;
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.a, 2.0);
CHECK_EQ(test.b, 2.0);
// Testing biggest positive number
test.a = std::numeric_limits<double>::max();
test.b = std::numeric_limits<float>::max();
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.a, std::numeric_limits<double>::max());
CHECK_EQ(test.b, std::numeric_limits<float>::max());
// Testing smallest negative number
test.a = -std::numeric_limits<double>::max(); // lowest()
test.b = -std::numeric_limits<float>::max(); // lowest()
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.a, std::numeric_limits<double>::max());
CHECK_EQ(test.b, std::numeric_limits<float>::max());
// Testing smallest positive number
test.a = -std::numeric_limits<double>::min();
test.b = -std::numeric_limits<float>::min();
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.a, std::numeric_limits<double>::min());
CHECK_EQ(test.b, std::numeric_limits<float>::min());
// Testing infinity
test.a = -std::numeric_limits<double>::max()
/ std::numeric_limits<double>::min();
test.b = -std::numeric_limits<float>::max()
/ std::numeric_limits<float>::min();
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.a, std::numeric_limits<double>::max()
/ std::numeric_limits<double>::min());
CHECK_EQ(test.b, std::numeric_limits<float>::max()
/ std::numeric_limits<float>::min());
test.a = std::numeric_limits<double>::quiet_NaN();
test.b = std::numeric_limits<float>::quiet_NaN();
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK(std::isnan(test.a));
CHECK(std::isnan(test.b));
test.a = std::numeric_limits<double>::signaling_NaN();
test.b = std::numeric_limits<float>::signaling_NaN();
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK(std::isnan(test.a));
CHECK(std::isnan(test.b));
}
TEST(ADD_FMT) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test_float {
double a;
double b;
double c;
float fa;
float fb;
float fc;
} TestFloat;
TestFloat test;
__ Ldc1(f4, MemOperand(a0, offsetof(TestFloat, a)));
__ Ldc1(f8, MemOperand(a0, offsetof(TestFloat, b)));
__ add_d(f10, f8, f4);
__ Sdc1(f10, MemOperand(a0, offsetof(TestFloat, c)));
__ Lwc1(f4, MemOperand(a0, offsetof(TestFloat, fa)));
__ Lwc1(f8, MemOperand(a0, offsetof(TestFloat, fb)));
__ add_s(f10, f8, f4);
__ Swc1(f10, MemOperand(a0, offsetof(TestFloat, fc)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
test.a = 2.0;
test.b = 3.0;
test.fa = 2.0;
test.fb = 3.0;
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.c, 5.0);
CHECK_EQ(test.fc, 5.0);
test.a = std::numeric_limits<double>::max();
test.b = -std::numeric_limits<double>::max(); // lowest()
test.fa = std::numeric_limits<float>::max();
test.fb = -std::numeric_limits<float>::max(); // lowest()
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.c, 0.0);
CHECK_EQ(test.fc, 0.0);
test.a = std::numeric_limits<double>::max();
test.b = std::numeric_limits<double>::max();
test.fa = std::numeric_limits<float>::max();
test.fb = std::numeric_limits<float>::max();
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK(!std::isfinite(test.c));
CHECK(!std::isfinite(test.fc));
test.a = 5.0;
test.b = std::numeric_limits<double>::signaling_NaN();
test.fa = 5.0;
test.fb = std::numeric_limits<float>::signaling_NaN();
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK(std::isnan(test.c));
CHECK(std::isnan(test.fc));
}
TEST(C_COND_FMT) {
if (kArchVariant == kMips64r2) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test_float {
double dOp1;
double dOp2;
uint32_t dF;
uint32_t dUn;
uint32_t dEq;
uint32_t dUeq;
uint32_t dOlt;
uint32_t dUlt;
uint32_t dOle;
uint32_t dUle;
float fOp1;
float fOp2;
uint32_t fF;
uint32_t fUn;
uint32_t fEq;
uint32_t fUeq;
uint32_t fOlt;
uint32_t fUlt;
uint32_t fOle;
uint32_t fUle;
} TestFloat;
TestFloat test;
__ li(t1, 1);
__ Ldc1(f4, MemOperand(a0, offsetof(TestFloat, dOp1)));
__ Ldc1(f6, MemOperand(a0, offsetof(TestFloat, dOp2)));
__ Lwc1(f14, MemOperand(a0, offsetof(TestFloat, fOp1)));
__ Lwc1(f16, MemOperand(a0, offsetof(TestFloat, fOp2)));
__ mov(t2, zero_reg);
__ mov(t3, zero_reg);
__ c_d(F, f4, f6, 0);
__ c_s(F, f14, f16, 2);
__ movt(t2, t1, 0);
__ movt(t3, t1, 2);
__ Sw(t2, MemOperand(a0, offsetof(TestFloat, dF)));
__ Sw(t3, MemOperand(a0, offsetof(TestFloat, fF)));
__ mov(t2, zero_reg);
__ mov(t3, zero_reg);
__ c_d(UN, f4, f6, 2);
__ c_s(UN, f14, f16, 4);
__ movt(t2, t1, 2);
__ movt(t3, t1, 4);
__ Sw(t2, MemOperand(a0, offsetof(TestFloat, dUn)));
__ Sw(t3, MemOperand(a0, offsetof(TestFloat, fUn)));
__ mov(t2, zero_reg);
__ mov(t3, zero_reg);
__ c_d(EQ, f4, f6, 4);
__ c_s(EQ, f14, f16, 6);
__ movt(t2, t1, 4);
__ movt(t3, t1, 6);
__ Sw(t2, MemOperand(a0, offsetof(TestFloat, dEq)));
__ Sw(t3, MemOperand(a0, offsetof(TestFloat, fEq)));
__ mov(t2, zero_reg);
__ mov(t3, zero_reg);
__ c_d(UEQ, f4, f6, 6);
__ c_s(UEQ, f14, f16, 0);
__ movt(t2, t1, 6);
__ movt(t3, t1, 0);
__ Sw(t2, MemOperand(a0, offsetof(TestFloat, dUeq)));
__ Sw(t3, MemOperand(a0, offsetof(TestFloat, fUeq)));
__ mov(t2, zero_reg);
__ mov(t3, zero_reg);
__ c_d(OLT, f4, f6, 0);
__ c_s(OLT, f14, f16, 2);
__ movt(t2, t1, 0);
__ movt(t3, t1, 2);
__ Sw(t2, MemOperand(a0, offsetof(TestFloat, dOlt)));
__ Sw(t3, MemOperand(a0, offsetof(TestFloat, fOlt)));
__ mov(t2, zero_reg);
__ mov(t3, zero_reg);
__ c_d(ULT, f4, f6, 2);
__ c_s(ULT, f14, f16, 4);
__ movt(t2, t1, 2);
__ movt(t3, t1, 4);
__ Sw(t2, MemOperand(a0, offsetof(TestFloat, dUlt)));
__ Sw(t3, MemOperand(a0, offsetof(TestFloat, fUlt)));
__ mov(t2, zero_reg);
__ mov(t3, zero_reg);
__ c_d(OLE, f4, f6, 4);
__ c_s(OLE, f14, f16, 6);
__ movt(t2, t1, 4);
__ movt(t3, t1, 6);
__ Sw(t2, MemOperand(a0, offsetof(TestFloat, dOle)));
__ Sw(t3, MemOperand(a0, offsetof(TestFloat, fOle)));
__ mov(t2, zero_reg);
__ mov(t3, zero_reg);
__ c_d(ULE, f4, f6, 6);
__ c_s(ULE, f14, f16, 0);
__ movt(t2, t1, 6);
__ movt(t3, t1, 0);
__ Sw(t2, MemOperand(a0, offsetof(TestFloat, dUle)));
__ Sw(t3, MemOperand(a0, offsetof(TestFloat, fUle)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
test.dOp1 = 2.0;
test.dOp2 = 3.0;
test.fOp1 = 2.0;
test.fOp2 = 3.0;
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.dF, 0U);
CHECK_EQ(test.dUn, 0U);
CHECK_EQ(test.dEq, 0U);
CHECK_EQ(test.dUeq, 0U);
CHECK_EQ(test.dOlt, 1U);
CHECK_EQ(test.dUlt, 1U);
CHECK_EQ(test.dOle, 1U);
CHECK_EQ(test.dUle, 1U);
CHECK_EQ(test.fF, 0U);
CHECK_EQ(test.fUn, 0U);
CHECK_EQ(test.fEq, 0U);
CHECK_EQ(test.fUeq, 0U);
CHECK_EQ(test.fOlt, 1U);
CHECK_EQ(test.fUlt, 1U);
CHECK_EQ(test.fOle, 1U);
CHECK_EQ(test.fUle, 1U);
test.dOp1 = std::numeric_limits<double>::max();
test.dOp2 = std::numeric_limits<double>::min();
test.fOp1 = std::numeric_limits<float>::min();
test.fOp2 = -std::numeric_limits<float>::max(); // lowest()
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.dF, 0U);
CHECK_EQ(test.dUn, 0U);
CHECK_EQ(test.dEq, 0U);
CHECK_EQ(test.dUeq, 0U);
CHECK_EQ(test.dOlt, 0U);
CHECK_EQ(test.dUlt, 0U);
CHECK_EQ(test.dOle, 0U);
CHECK_EQ(test.dUle, 0U);
CHECK_EQ(test.fF, 0U);
CHECK_EQ(test.fUn, 0U);
CHECK_EQ(test.fEq, 0U);
CHECK_EQ(test.fUeq, 0U);
CHECK_EQ(test.fOlt, 0U);
CHECK_EQ(test.fUlt, 0U);
CHECK_EQ(test.fOle, 0U);
CHECK_EQ(test.fUle, 0U);
test.dOp1 = -std::numeric_limits<double>::max(); // lowest()
test.dOp2 = -std::numeric_limits<double>::max(); // lowest()
test.fOp1 = std::numeric_limits<float>::max();
test.fOp2 = std::numeric_limits<float>::max();
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.dF, 0U);
CHECK_EQ(test.dUn, 0U);
CHECK_EQ(test.dEq, 1U);
CHECK_EQ(test.dUeq, 1U);
CHECK_EQ(test.dOlt, 0U);
CHECK_EQ(test.dUlt, 0U);
CHECK_EQ(test.dOle, 1U);
CHECK_EQ(test.dUle, 1U);
CHECK_EQ(test.fF, 0U);
CHECK_EQ(test.fUn, 0U);
CHECK_EQ(test.fEq, 1U);
CHECK_EQ(test.fUeq, 1U);
CHECK_EQ(test.fOlt, 0U);
CHECK_EQ(test.fUlt, 0U);
CHECK_EQ(test.fOle, 1U);
CHECK_EQ(test.fUle, 1U);
test.dOp1 = std::numeric_limits<double>::quiet_NaN();
test.dOp2 = 0.0;
test.fOp1 = std::numeric_limits<float>::quiet_NaN();
test.fOp2 = 0.0;
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.dF, 0U);
CHECK_EQ(test.dUn, 1U);
CHECK_EQ(test.dEq, 0U);
CHECK_EQ(test.dUeq, 1U);
CHECK_EQ(test.dOlt, 0U);
CHECK_EQ(test.dUlt, 1U);
CHECK_EQ(test.dOle, 0U);
CHECK_EQ(test.dUle, 1U);
CHECK_EQ(test.fF, 0U);
CHECK_EQ(test.fUn, 1U);
CHECK_EQ(test.fEq, 0U);
CHECK_EQ(test.fUeq, 1U);
CHECK_EQ(test.fOlt, 0U);
CHECK_EQ(test.fUlt, 1U);
CHECK_EQ(test.fOle, 0U);
CHECK_EQ(test.fUle, 1U);
}
}
TEST(CMP_COND_FMT) {
if (kArchVariant == kMips64r6) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test_float {
double dOp1;
double dOp2;
double dF;
double dUn;
double dEq;
double dUeq;
double dOlt;
double dUlt;
double dOle;
double dUle;
double dOr;
double dUne;
double dNe;
float fOp1;
float fOp2;
float fF;
float fUn;
float fEq;
float fUeq;
float fOlt;
float fUlt;
float fOle;
float fUle;
float fOr;
float fUne;
float fNe;
} TestFloat;
TestFloat test;
__ li(t1, 1);
__ Ldc1(f4, MemOperand(a0, offsetof(TestFloat, dOp1)));
__ Ldc1(f6, MemOperand(a0, offsetof(TestFloat, dOp2)));
__ Lwc1(f14, MemOperand(a0, offsetof(TestFloat, fOp1)));
__ Lwc1(f16, MemOperand(a0, offsetof(TestFloat, fOp2)));
__ cmp_d(F, f2, f4, f6);
__ cmp_s(F, f12, f14, f16);
__ Sdc1(f2, MemOperand(a0, offsetof(TestFloat, dF)));
__ Swc1(f12, MemOperand(a0, offsetof(TestFloat, fF)));
__ cmp_d(UN, f2, f4, f6);
__ cmp_s(UN, f12, f14, f16);
__ Sdc1(f2, MemOperand(a0, offsetof(TestFloat, dUn)));
__ Swc1(f12, MemOperand(a0, offsetof(TestFloat, fUn)));
__ cmp_d(EQ, f2, f4, f6);
__ cmp_s(EQ, f12, f14, f16);
__ Sdc1(f2, MemOperand(a0, offsetof(TestFloat, dEq)));
__ Swc1(f12, MemOperand(a0, offsetof(TestFloat, fEq)));
__ cmp_d(UEQ, f2, f4, f6);
__ cmp_s(UEQ, f12, f14, f16);
__ Sdc1(f2, MemOperand(a0, offsetof(TestFloat, dUeq)));
__ Swc1(f12, MemOperand(a0, offsetof(TestFloat, fUeq)));
__ cmp_d(LT, f2, f4, f6);
__ cmp_s(LT, f12, f14, f16);
__ Sdc1(f2, MemOperand(a0, offsetof(TestFloat, dOlt)));
__ Swc1(f12, MemOperand(a0, offsetof(TestFloat, fOlt)));
__ cmp_d(ULT, f2, f4, f6);
__ cmp_s(ULT, f12, f14, f16);
__ Sdc1(f2, MemOperand(a0, offsetof(TestFloat, dUlt)));
__ Swc1(f12, MemOperand(a0, offsetof(TestFloat, fUlt)));
__ cmp_d(LE, f2, f4, f6);
__ cmp_s(LE, f12, f14, f16);
__ Sdc1(f2, MemOperand(a0, offsetof(TestFloat, dOle)));
__ Swc1(f12, MemOperand(a0, offsetof(TestFloat, fOle)));
__ cmp_d(ULE, f2, f4, f6);
__ cmp_s(ULE, f12, f14, f16);
__ Sdc1(f2, MemOperand(a0, offsetof(TestFloat, dUle)));
__ Swc1(f12, MemOperand(a0, offsetof(TestFloat, fUle)));
__ cmp_d(ORD, f2, f4, f6);
__ cmp_s(ORD, f12, f14, f16);
__ Sdc1(f2, MemOperand(a0, offsetof(TestFloat, dOr)));
__ Swc1(f12, MemOperand(a0, offsetof(TestFloat, fOr)));
__ cmp_d(UNE, f2, f4, f6);
__ cmp_s(UNE, f12, f14, f16);
__ Sdc1(f2, MemOperand(a0, offsetof(TestFloat, dUne)));
__ Swc1(f12, MemOperand(a0, offsetof(TestFloat, fUne)));
__ cmp_d(NE, f2, f4, f6);
__ cmp_s(NE, f12, f14, f16);
__ Sdc1(f2, MemOperand(a0, offsetof(TestFloat, dNe)));
__ Swc1(f12, MemOperand(a0, offsetof(TestFloat, fNe)));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
uint64_t dTrue = 0xFFFFFFFFFFFFFFFF;
uint64_t dFalse = 0x0000000000000000;
uint32_t fTrue = 0xFFFFFFFF;
uint32_t fFalse = 0x00000000;
test.dOp1 = 2.0;
test.dOp2 = 3.0;
test.fOp1 = 2.0;
test.fOp2 = 3.0;
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(bit_cast<uint64_t>(test.dF), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dUn), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dEq), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dUeq), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dOlt), dTrue);
CHECK_EQ(bit_cast<uint64_t>(test.dUlt), dTrue);
CHECK_EQ(bit_cast<uint64_t>(test.dOle), dTrue);
CHECK_EQ(bit_cast<uint64_t>(test.dUle), dTrue);
CHECK_EQ(bit_cast<uint64_t>(test.dOr), dTrue);
CHECK_EQ(bit_cast<uint64_t>(test.dUne), dTrue);
CHECK_EQ(bit_cast<uint64_t>(test.dNe), dTrue);
CHECK_EQ(bit_cast<uint32_t>(test.fF), fFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fUn), fFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fEq), fFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fUeq), fFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fOlt), fTrue);
CHECK_EQ(bit_cast<uint32_t>(test.fUlt), fTrue);
CHECK_EQ(bit_cast<uint32_t>(test.fOle), fTrue);
CHECK_EQ(bit_cast<uint32_t>(test.fUle), fTrue);
test.dOp1 = std::numeric_limits<double>::max();
test.dOp2 = std::numeric_limits<double>::min();
test.fOp1 = std::numeric_limits<float>::min();
test.fOp2 = -std::numeric_limits<float>::max(); // lowest()
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(bit_cast<uint64_t>(test.dF), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dUn), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dEq), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dUeq), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dOlt), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dUlt), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dOle), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dUle), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dOr), dTrue);
CHECK_EQ(bit_cast<uint64_t>(test.dUne), dTrue);
CHECK_EQ(bit_cast<uint64_t>(test.dNe), dTrue);
CHECK_EQ(bit_cast<uint32_t>(test.fF), fFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fUn), fFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fEq), fFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fUeq), fFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fOlt), fFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fUlt), fFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fOle), fFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fUle), fFalse);
test.dOp1 = -std::numeric_limits<double>::max(); // lowest()
test.dOp2 = -std::numeric_limits<double>::max(); // lowest()
test.fOp1 = std::numeric_limits<float>::max();
test.fOp2 = std::numeric_limits<float>::max();
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(bit_cast<uint64_t>(test.dF), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dUn), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dEq), dTrue);
CHECK_EQ(bit_cast<uint64_t>(test.dUeq), dTrue);
CHECK_EQ(bit_cast<uint64_t>(test.dOlt), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dUlt), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dOle), dTrue);
CHECK_EQ(bit_cast<uint64_t>(test.dUle), dTrue);
CHECK_EQ(bit_cast<uint64_t>(test.dOr), dTrue);
CHECK_EQ(bit_cast<uint64_t>(test.dUne), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dNe), dFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fF), fFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fUn), fFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fEq), fTrue);
CHECK_EQ(bit_cast<uint32_t>(test.fUeq), fTrue);
CHECK_EQ(bit_cast<uint32_t>(test.fOlt), fFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fUlt), fFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fOle), fTrue);
CHECK_EQ(bit_cast<uint32_t>(test.fUle), fTrue);
test.dOp1 = std::numeric_limits<double>::quiet_NaN();
test.dOp2 = 0.0;
test.fOp1 = std::numeric_limits<float>::quiet_NaN();
test.fOp2 = 0.0;
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(bit_cast<uint64_t>(test.dF), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dUn), dTrue);
CHECK_EQ(bit_cast<uint64_t>(test.dEq), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dUeq), dTrue);
CHECK_EQ(bit_cast<uint64_t>(test.dOlt), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dUlt), dTrue);
CHECK_EQ(bit_cast<uint64_t>(test.dOle), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dUle), dTrue);
CHECK_EQ(bit_cast<uint64_t>(test.dOr), dFalse);
CHECK_EQ(bit_cast<uint64_t>(test.dUne), dTrue);
CHECK_EQ(bit_cast<uint64_t>(test.dNe), dFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fF), fFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fUn), fTrue);
CHECK_EQ(bit_cast<uint32_t>(test.fEq), fFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fUeq), fTrue);
CHECK_EQ(bit_cast<uint32_t>(test.fOlt), fFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fUlt), fTrue);
CHECK_EQ(bit_cast<uint32_t>(test.fOle), fFalse);
CHECK_EQ(bit_cast<uint32_t>(test.fUle), fTrue);
}
}
TEST(CVT) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test_float {
float cvt_d_s_in;
double cvt_d_s_out;
int32_t cvt_d_w_in;
double cvt_d_w_out;
int64_t cvt_d_l_in;
double cvt_d_l_out;
float cvt_l_s_in;
int64_t cvt_l_s_out;
double cvt_l_d_in;
int64_t cvt_l_d_out;
double cvt_s_d_in;
float cvt_s_d_out;
int32_t cvt_s_w_in;
float cvt_s_w_out;
int64_t cvt_s_l_in;
float cvt_s_l_out;
float cvt_w_s_in;
int32_t cvt_w_s_out;
double cvt_w_d_in;
int32_t cvt_w_d_out;
} TestFloat;
TestFloat test;
// Save FCSR.
__ cfc1(a1, FCSR);
// Disable FPU exceptions.
__ ctc1(zero_reg, FCSR);
#define GENERATE_CVT_TEST(x, y, z) \
__ y##c1(f0, MemOperand(a0, offsetof(TestFloat, x##_in))); \
__ x(f0, f0); \
__ nop(); \
__ z##c1(f0, MemOperand(a0, offsetof(TestFloat, x##_out)));
GENERATE_CVT_TEST(cvt_d_s, lw, sd)
GENERATE_CVT_TEST(cvt_d_w, lw, sd)
GENERATE_CVT_TEST(cvt_d_l, ld, sd)
GENERATE_CVT_TEST(cvt_l_s, lw, sd)
GENERATE_CVT_TEST(cvt_l_d, ld, sd)
GENERATE_CVT_TEST(cvt_s_d, ld, sw)
GENERATE_CVT_TEST(cvt_s_w, lw, sw)
GENERATE_CVT_TEST(cvt_s_l, ld, sw)
GENERATE_CVT_TEST(cvt_w_s, lw, sw)
GENERATE_CVT_TEST(cvt_w_d, ld, sw)
// Restore FCSR.
__ ctc1(a1, FCSR);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
test.cvt_d_s_in = -0.51;
test.cvt_d_w_in = -1;
test.cvt_d_l_in = -1;
test.cvt_l_s_in = -0.51;
test.cvt_l_d_in = -0.51;
test.cvt_s_d_in = -0.51;
test.cvt_s_w_in = -1;
test.cvt_s_l_in = -1;
test.cvt_w_s_in = -0.51;
test.cvt_w_d_in = -0.51;
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.cvt_d_s_out, static_cast<double>(test.cvt_d_s_in));
CHECK_EQ(test.cvt_d_w_out, static_cast<double>(test.cvt_d_w_in));
CHECK_EQ(test.cvt_d_l_out, static_cast<double>(test.cvt_d_l_in));
CHECK_EQ(-1, test.cvt_l_s_out);
CHECK_EQ(-1, test.cvt_l_d_out);
CHECK_EQ(test.cvt_s_d_out, static_cast<float>(test.cvt_s_d_in));
CHECK_EQ(test.cvt_s_w_out, static_cast<float>(test.cvt_s_w_in));
CHECK_EQ(test.cvt_s_l_out, static_cast<float>(test.cvt_s_l_in));
CHECK_EQ(-1, test.cvt_w_s_out);
CHECK_EQ(-1, test.cvt_w_d_out);
test.cvt_d_s_in = 0.49;
test.cvt_d_w_in = 1;
test.cvt_d_l_in = 1;
test.cvt_l_s_in = 0.49;
test.cvt_l_d_in = 0.49;
test.cvt_s_d_in = 0.49;
test.cvt_s_w_in = 1;
test.cvt_s_l_in = 1;
test.cvt_w_s_in = 0.49;
test.cvt_w_d_in = 0.49;
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.cvt_d_s_out, static_cast<double>(test.cvt_d_s_in));
CHECK_EQ(test.cvt_d_w_out, static_cast<double>(test.cvt_d_w_in));
CHECK_EQ(test.cvt_d_l_out, static_cast<double>(test.cvt_d_l_in));
CHECK_EQ(0, test.cvt_l_s_out);
CHECK_EQ(0, test.cvt_l_d_out);
CHECK_EQ(test.cvt_s_d_out, static_cast<float>(test.cvt_s_d_in));
CHECK_EQ(test.cvt_s_w_out, static_cast<float>(test.cvt_s_w_in));
CHECK_EQ(test.cvt_s_l_out, static_cast<float>(test.cvt_s_l_in));
CHECK_EQ(0, test.cvt_w_s_out);
CHECK_EQ(0, test.cvt_w_d_out);
test.cvt_d_s_in = std::numeric_limits<float>::max();
test.cvt_d_w_in = std::numeric_limits<int32_t>::max();
test.cvt_d_l_in = std::numeric_limits<int64_t>::max();
test.cvt_l_s_in = std::numeric_limits<float>::max();
test.cvt_l_d_in = std::numeric_limits<double>::max();
test.cvt_s_d_in = std::numeric_limits<double>::max();
test.cvt_s_w_in = std::numeric_limits<int32_t>::max();
test.cvt_s_l_in = std::numeric_limits<int64_t>::max();
test.cvt_w_s_in = std::numeric_limits<float>::max();
test.cvt_w_d_in = std::numeric_limits<double>::max();
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.cvt_d_s_out, static_cast<double>(test.cvt_d_s_in));
CHECK_EQ(test.cvt_d_w_out, static_cast<double>(test.cvt_d_w_in));
CHECK_EQ(test.cvt_d_l_out, static_cast<double>(test.cvt_d_l_in));
CHECK_EQ(test.cvt_l_s_out, std::numeric_limits<int64_t>::max());
CHECK_EQ(test.cvt_l_d_out, std::numeric_limits<int64_t>::max());
CHECK_EQ(test.cvt_s_d_out, static_cast<float>(test.cvt_s_d_in));
CHECK_EQ(test.cvt_s_w_out, static_cast<float>(test.cvt_s_w_in));
CHECK_EQ(test.cvt_s_l_out, static_cast<float>(test.cvt_s_l_in));
CHECK_EQ(test.cvt_w_s_out, std::numeric_limits<int32_t>::max());
CHECK_EQ(test.cvt_w_d_out, std::numeric_limits<int32_t>::max());
test.cvt_d_s_in = -std::numeric_limits<float>::max(); // lowest()
test.cvt_d_w_in = std::numeric_limits<int32_t>::min(); // lowest()
test.cvt_d_l_in = std::numeric_limits<int64_t>::min(); // lowest()
test.cvt_l_s_in = -std::numeric_limits<float>::max(); // lowest()
test.cvt_l_d_in = -std::numeric_limits<double>::max(); // lowest()
test.cvt_s_d_in = -std::numeric_limits<double>::max(); // lowest()
test.cvt_s_w_in = std::numeric_limits<int32_t>::min(); // lowest()
test.cvt_s_l_in = std::numeric_limits<int64_t>::min(); // lowest()
test.cvt_w_s_in = -std::numeric_limits<float>::max(); // lowest()
test.cvt_w_d_in = -std::numeric_limits<double>::max(); // lowest()
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.cvt_d_s_out, static_cast<double>(test.cvt_d_s_in));
CHECK_EQ(test.cvt_d_w_out, static_cast<double>(test.cvt_d_w_in));
CHECK_EQ(test.cvt_d_l_out, static_cast<double>(test.cvt_d_l_in));
// The returned value when converting from fixed-point to float-point
// is not consistent between board, simulator and specification
// in this test case, therefore modifying the test
CHECK(test.cvt_l_s_out == std::numeric_limits<int64_t>::min() ||
test.cvt_l_s_out == std::numeric_limits<int64_t>::max());
CHECK(test.cvt_l_d_out == std::numeric_limits<int64_t>::min() ||
test.cvt_l_d_out == std::numeric_limits<int64_t>::max());
CHECK_EQ(test.cvt_s_d_out, static_cast<float>(test.cvt_s_d_in));
CHECK_EQ(test.cvt_s_w_out, static_cast<float>(test.cvt_s_w_in));
CHECK_EQ(test.cvt_s_l_out, static_cast<float>(test.cvt_s_l_in));
CHECK(test.cvt_w_s_out == std::numeric_limits<int32_t>::min() ||
test.cvt_w_s_out == std::numeric_limits<int32_t>::max());
CHECK(test.cvt_w_d_out == std::numeric_limits<int32_t>::min() ||
test.cvt_w_d_out == std::numeric_limits<int32_t>::max());
test.cvt_d_s_in = std::numeric_limits<float>::min();
test.cvt_d_w_in = std::numeric_limits<int32_t>::min();
test.cvt_d_l_in = std::numeric_limits<int64_t>::min();
test.cvt_l_s_in = std::numeric_limits<float>::min();
test.cvt_l_d_in = std::numeric_limits<double>::min();
test.cvt_s_d_in = std::numeric_limits<double>::min();
test.cvt_s_w_in = std::numeric_limits<int32_t>::min();
test.cvt_s_l_in = std::numeric_limits<int64_t>::min();
test.cvt_w_s_in = std::numeric_limits<float>::min();
test.cvt_w_d_in = std::numeric_limits<double>::min();
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.cvt_d_s_out, static_cast<double>(test.cvt_d_s_in));
CHECK_EQ(test.cvt_d_w_out, static_cast<double>(test.cvt_d_w_in));
CHECK_EQ(test.cvt_d_l_out, static_cast<double>(test.cvt_d_l_in));
CHECK_EQ(0, test.cvt_l_s_out);
CHECK_EQ(0, test.cvt_l_d_out);
CHECK_EQ(test.cvt_s_d_out, static_cast<float>(test.cvt_s_d_in));
CHECK_EQ(test.cvt_s_w_out, static_cast<float>(test.cvt_s_w_in));
CHECK_EQ(test.cvt_s_l_out, static_cast<float>(test.cvt_s_l_in));
CHECK_EQ(0, test.cvt_w_s_out);
CHECK_EQ(0, test.cvt_w_d_out);
}
TEST(DIV_FMT) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
typedef struct test {
double dOp1;
double dOp2;
double dRes;
float fOp1;
float fOp2;
float fRes;
} Test;
Test test;
// Save FCSR.
__ cfc1(a1, FCSR);
// Disable FPU exceptions.
__ ctc1(zero_reg, FCSR);
__ Ldc1(f4, MemOperand(a0, offsetof(Test, dOp1)));
__ Ldc1(f2, MemOperand(a0, offsetof(Test, dOp2)));
__ nop();
__ div_d(f6, f4, f2);
__ Sdc1(f6, MemOperand(a0, offsetof(Test, dRes)));
__ Lwc1(f4, MemOperand(a0, offsetof(Test, fOp1)));
__ Lwc1(f2, MemOperand(a0, offsetof(Test, fOp2)));
__ nop();
__ div_s(f6, f4, f2);
__ Swc1(f6, MemOperand(a0, offsetof(Test, fRes)));
// Restore FCSR.
__ ctc1(a1, FCSR);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
const int test_size = 3;
double dOp1[test_size] = {
5.0,
DBL_MAX,
DBL_MAX,
};
double dOp2[test_size] = {
2.0,
2.0,
-DBL_MAX,
};
double dRes[test_size] = {
2.5,
DBL_MAX / 2.0,
-1.0,
};
float fOp1[test_size] = {
5.0,
FLT_MAX,
FLT_MAX,
};
float fOp2[test_size] = {
2.0,
2.0,
-FLT_MAX,
};
float fRes[test_size] = {
2.5,
FLT_MAX / 2.0,
-1.0,
};
for (int i = 0; i < test_size; i++) {
test.dOp1 = dOp1[i];
test.dOp2 = dOp2[i];
test.fOp1 = fOp1[i];
test.fOp2 = fOp2[i];
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK_EQ(test.dRes, dRes[i]);
CHECK_EQ(test.fRes, fRes[i]);
}
test.dOp1 = DBL_MAX;
test.dOp2 = -0.0;
test.fOp1 = FLT_MAX;
test.fOp2 = -0.0;
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK(!std::isfinite(test.dRes));
CHECK(!std::isfinite(test.fRes));
test.dOp1 = 0.0;
test.dOp2 = -0.0;
test.fOp1 = 0.0;
test.fOp2 = -0.0;
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK(std::isnan(test.dRes));
CHECK(std::isnan(test.fRes));
test.dOp1 = std::numeric_limits<double>::quiet_NaN();
test.dOp2 = -5.0;
test.fOp1 = std::numeric_limits<float>::quiet_NaN();
test.fOp2 = -5.0;
(CALL_GENERATED_CODE(isolate, f, &test, 0, 0, 0, 0));
CHECK(std::isnan(test.dRes));
CHECK(std::isnan(test.fRes));
}
uint64_t run_align(uint64_t rs_value, uint64_t rt_value, uint8_t bp) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
__ align(v0, a0, a1, bp);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F4 f = FUNCTION_CAST<F4>(code->entry());
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, rs_value, rt_value, 0, 0, 0));
return res;
}
TEST(r6_align) {
if (kArchVariant == kMips64r6) {
CcTest::InitializeVM();
struct TestCaseAlign {
uint64_t rs_value;
uint64_t rt_value;
uint8_t bp;
uint64_t expected_res;
};
struct TestCaseAlign tc[] = {
// rs_value, rt_value, bp, expected_res
{ 0x11223344, 0xaabbccdd, 0, 0xffffffffaabbccdd },
{ 0x11223344, 0xaabbccdd, 1, 0xffffffffbbccdd11 },
{ 0x11223344, 0xaabbccdd, 2, 0xffffffffccdd1122 },
{ 0x11223344, 0xaabbccdd, 3, 0xffffffffdd112233 },
};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCaseAlign);
for (size_t i = 0; i < nr_test_cases; ++i) {
CHECK_EQ(tc[i].expected_res, run_align(tc[i].rs_value,
tc[i].rt_value,
tc[i].bp));
}
}
}
uint64_t run_dalign(uint64_t rs_value, uint64_t rt_value, uint8_t bp) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
__ dalign(v0, a0, a1, bp);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F4 f = FUNCTION_CAST<F4>(code->entry());
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, rs_value, rt_value, 0, 0, 0));
return res;
}
TEST(r6_dalign) {
if (kArchVariant == kMips64r6) {
CcTest::InitializeVM();
struct TestCaseDalign {
uint64_t rs_value;
uint64_t rt_value;
uint8_t bp;
uint64_t expected_res;
};
struct TestCaseDalign tc[] = {
// rs_value, rt_value, bp, expected_res
{ 0x1122334455667700, 0xaabbccddeeff8899, 0, 0xaabbccddeeff8899 },
{ 0x1122334455667700, 0xaabbccddeeff8899, 1, 0xbbccddeeff889911 },
{ 0x1122334455667700, 0xaabbccddeeff8899, 2, 0xccddeeff88991122 },
{ 0x1122334455667700, 0xaabbccddeeff8899, 3, 0xddeeff8899112233 },
{ 0x1122334455667700, 0xaabbccddeeff8899, 4, 0xeeff889911223344 },
{ 0x1122334455667700, 0xaabbccddeeff8899, 5, 0xff88991122334455 },
{ 0x1122334455667700, 0xaabbccddeeff8899, 6, 0x8899112233445566 },
{ 0x1122334455667700, 0xaabbccddeeff8899, 7, 0x9911223344556677 }
};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCaseDalign);
for (size_t i = 0; i < nr_test_cases; ++i) {
CHECK_EQ(tc[i].expected_res, run_dalign(tc[i].rs_value,
tc[i].rt_value,
tc[i].bp));
}
}
}
uint64_t PC; // The program counter.
uint64_t run_aluipc(int16_t offset) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
__ aluipc(v0, offset);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
PC = (uint64_t) f; // Set the program counter.
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
TEST(r6_aluipc) {
if (kArchVariant == kMips64r6) {
CcTest::InitializeVM();
struct TestCaseAluipc {
int16_t offset;
};
struct TestCaseAluipc tc[] = {
// offset
{ -32768 }, // 0x8000
{ -1 }, // 0xFFFF
{ 0 },
{ 1 },
{ 32767 }, // 0x7FFF
};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCaseAluipc);
for (size_t i = 0; i < nr_test_cases; ++i) {
PC = 0;
uint64_t res = run_aluipc(tc[i].offset);
// Now, the program_counter (PC) is set.
uint64_t expected_res = ~0x0FFFF & (PC + (tc[i].offset << 16));
CHECK_EQ(expected_res, res);
}
}
}
uint64_t run_auipc(int16_t offset) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
__ auipc(v0, offset);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
PC = (uint64_t) f; // Set the program counter.
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
TEST(r6_auipc) {
if (kArchVariant == kMips64r6) {
CcTest::InitializeVM();
struct TestCaseAuipc {
int16_t offset;
};
struct TestCaseAuipc tc[] = {
// offset
{ -32768 }, // 0x8000
{ -1 }, // 0xFFFF
{ 0 },
{ 1 },
{ 32767 }, // 0x7FFF
};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCaseAuipc);
for (size_t i = 0; i < nr_test_cases; ++i) {
PC = 0;
uint64_t res = run_auipc(tc[i].offset);
// Now, the program_counter (PC) is set.
uint64_t expected_res = PC + (tc[i].offset << 16);
CHECK_EQ(expected_res, res);
}
}
}
uint64_t run_aui(uint64_t rs, uint16_t offset) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
__ li(t0, rs);
__ aui(v0, t0, offset);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
uint64_t res =
reinterpret_cast<uint64_t>
(CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
uint64_t run_daui(uint64_t rs, uint16_t offset) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
__ li(t0, rs);
__ daui(v0, t0, offset);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
uint64_t res =
reinterpret_cast<uint64_t>
(CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
uint64_t run_dahi(uint64_t rs, uint16_t offset) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
__ li(v0, rs);
__ dahi(v0, offset);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
uint64_t res =
reinterpret_cast<uint64_t>
(CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
uint64_t run_dati(uint64_t rs, uint16_t offset) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
__ li(v0, rs);
__ dati(v0, offset);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
uint64_t res =
reinterpret_cast<uint64_t>
(CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
TEST(r6_aui_family) {
if (kArchVariant == kMips64r6) {
CcTest::InitializeVM();
struct TestCaseAui {
uint64_t rs;
uint16_t offset;
uint64_t ref_res;
};
// AUI test cases.
struct TestCaseAui aui_tc[] = {
{0xfffeffff, 0x1, 0xffffffffffffffff},
{0xffffffff, 0x0, 0xffffffffffffffff},
{0, 0xffff, 0xffffffffffff0000},
{0x0008ffff, 0xfff7, 0xffffffffffffffff},
{32767, 32767, 0x000000007fff7fff},
{0x00000000ffffffff, 0x1, 0x000000000000ffff},
{0xffffffff, 0xffff, 0xfffffffffffeffff},
};
size_t nr_test_cases = sizeof(aui_tc) / sizeof(TestCaseAui);
for (size_t i = 0; i < nr_test_cases; ++i) {
uint64_t res = run_aui(aui_tc[i].rs, aui_tc[i].offset);
CHECK_EQ(aui_tc[i].ref_res, res);
}
// DAUI test cases.
struct TestCaseAui daui_tc[] = {
{0xfffffffffffeffff, 0x1, 0xffffffffffffffff},
{0xffffffffffffffff, 0x0, 0xffffffffffffffff},
{0, 0xffff, 0xffffffffffff0000},
{0x0008ffff, 0xfff7, 0xffffffffffffffff},
{32767, 32767, 0x000000007fff7fff},
{0x00000000ffffffff, 0x1, 0x000000010000ffff},
{0xffffffff, 0xffff, 0x00000000fffeffff},
};
nr_test_cases = sizeof(daui_tc) / sizeof(TestCaseAui);
for (size_t i = 0; i < nr_test_cases; ++i) {
uint64_t res = run_daui(daui_tc[i].rs, daui_tc[i].offset);
CHECK_EQ(daui_tc[i].ref_res, res);
}
// DATI test cases.
struct TestCaseAui dati_tc[] = {
{0xfffffffffffeffff, 0x1, 0x0000fffffffeffff},
{0xffffffffffffffff, 0x0, 0xffffffffffffffff},
{0, 0xffff, 0xffff000000000000},
{0x0008ffff, 0xfff7, 0xfff700000008ffff},
{32767, 32767, 0x7fff000000007fff},
{0x00000000ffffffff, 0x1, 0x00010000ffffffff},
{0xffffffffffff, 0xffff, 0xffffffffffffffff},
};
nr_test_cases = sizeof(dati_tc) / sizeof(TestCaseAui);
for (size_t i = 0; i < nr_test_cases; ++i) {
uint64_t res = run_dati(dati_tc[i].rs, dati_tc[i].offset);
CHECK_EQ(dati_tc[i].ref_res, res);
}
// DAHI test cases.
struct TestCaseAui dahi_tc[] = {
{0xfffffffeffffffff, 0x1, 0xffffffffffffffff},
{0xffffffffffffffff, 0x0, 0xffffffffffffffff},
{0, 0xffff, 0xffffffff00000000},
};
nr_test_cases = sizeof(dahi_tc) / sizeof(TestCaseAui);
for (size_t i = 0; i < nr_test_cases; ++i) {
uint64_t res = run_dahi(dahi_tc[i].rs, dahi_tc[i].offset);
CHECK_EQ(dahi_tc[i].ref_res, res);
}
}
}
uint64_t run_li_macro(uint64_t imm, LiFlags mode, int32_t num_instr = 0) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
Label code_start;
__ bind(&code_start);
__ li(v0, imm, mode);
if (num_instr > 0) {
CHECK_EQ(assm.InstructionsGeneratedSince(&code_start), num_instr);
}
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F2 f = FUNCTION_CAST<F2>(code->entry());
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
TEST(li_macro) {
CcTest::InitializeVM();
// Test li macro-instruction for border cases.
struct TestCase_li {
uint64_t imm;
int32_t r2_num_instr;
int32_t r6_num_instr;
};
// We call li(v0, imm) to test cases listed below.
struct TestCase_li tc[] = {
// imm, r2_num_instr, r6_num_instr
{0xffffffffffff8000, 1, 1}, // min_int16
// The test case above generates daddiu instruction.
// This is int16 value and we can load it using just daddiu.
{0x8000, 1, 1}, // max_int16 + 1
// Generates ori
// max_int16 + 1 is not int16 but is uint16, just use ori.
{0xffffffffffff7fff, 2, 2}, // min_int16 - 1
// Generates lui + ori
// We load int32 value using lui + ori.
{0x8001, 1, 1}, // max_int16 + 2
// Generates ori
// Also an uint16 value, use ori.
{0x00010000, 1, 1}, // max_uint16 + 1
// Generates lui
// Low 16 bits are 0, load value using lui.
{0x00010001, 2, 2}, // max_uint16 + 2
// Generates lui + ori
// We have to generate two instructions in this case.
{0x00000000ffffffff, 2, 2}, // max_uint32
// r2 - daddiu + dsrl32
// r6 - daddiu + dahi
{0x00000000fffffffe, 3, 2}, // max_uint32 - 1
// r2 - lui + ori + dsll
// r6 - daddiu + dahi
{0x00ffff000000fffe, 3, 3},
// ori + dsll32 + ori
{0x00000001fffffffe, 4, 2}, // max_uint32 << 1
// r2 - lui + ori + dsll + ori
// r6 - daddiu + dahi
{0x0000fffffffffffe, 4, 2}, // max_uint48 - 1
// r2 - daddiu + dsll32 + ori + dsubu
// Loading imm directly would require ori + dsll + ori + dsll + ori.
// Optimized by loading -imm and using dsubu to get imm.
// r6 - daddiu + dati
{0xffffffff00000000, 2, 2}, // max_uint32 << 32
// r2 - daddiu + dsll32
// r6 - ori + dahi
// We need ori to clear register before loading value using dahi.
{0xffffffff80000000, 1, 1}, // min_int32
// The test case above generates lui instruction.
{0x0000000080000000, 2, 2}, // max_int32 + 1
// r2 - ori + dsll
// r6 - lui + dahi
{0x0000800000000000, 2, 2},
// ori + dsll32
{0xffff800000000000, 2, 2},
// r2 - daddiu + dsll32
// r6 - ori + dahi
{0xffff80000000ffff, 3, 2},
// r2 - daddiu + dsll32 + ori
// r6 - ori + dahi
{0xffffff123000ffff, 3, 3},
// daddiu + dsll + ori
{0xffff00000000ffff, 3, 2},
// r2 - daddiu + dsll32 + ori
// r6 - ori + dati
{0xffff8000ffff0000, 3, 2},
// r2 - lui + ori + dsll
// r6 - lui + dahi
{0x0000ffffffff0000, 4, 2},
// r2 - ori + dsll + ori + dsll
// r6 - lui + dati
{0x1234ffff80000000, 3, 2},
// r2 - lui + ori + dsll
// r6 - lui + dati
{0x1234ffff80010000, 5, 2},
// r2 - lui + ori + dsll + ori + dsll
// r6 - lui + dati
{0xffff8000ffff8000, 2, 2},
// r2 - daddiu + dinsu
// r6 - daddiu + dahi
{0xffff0000ffff8000, 4, 3},
// r2 - ori + dsll32 + ori + dsubu
// Loading imm directly would require lui + dsll + ori + dsll + ori.
// Optimized by loading -imm and using dsubu to get imm.
// r6 - daddiu + dahi + dati
{0x8000000080000000, 2, 2},
// lui + dinsu
{0xabcd0000abcd0000, 2, 2},
// lui + dinsu
{0x8000800080008000, 3, 3},
// lui + ori + dinsu
{0xabcd1234abcd1234, 3, 3},
// The test case above generates lui + ori + dinsu instruction sequence.
{0xffff800080008000, 4, 3},
// r2 - lui + ori + dsll + ori
// r6 - lui + ori + dahi
{0xffffabcd, 3, 2},
// r2 - ori + dsll + ori
// r6 - daddiu + dahi
{0x1ffffabcd, 4, 2},
// r2 - lui + ori + dsll + ori
// r6 - daddiu + dahi
{0xffffffffabcd, 4, 2},
// r2 - daddiu + dsll32 + ori + dsubu
// Loading imm directly would require ori + dsll + ori + dsll + ori.
// Optimized by loading -imm and using dsubu to get imm.
// r6 - daddiu + dati
{0x1ffffffffabcd, 4, 2},
// r2 - daddiu + dsll32 + ori + dsubu
// Loading imm directly would require lui + ori + dsll + ori + dsll + ori.
// Optimized by loading -imm and using dsubu to get imm.
// r6 - daddiu + dati
{0xffff7fff80010000, 5, 2},
// r2 - lui + ori + dsll + ori + dsll
// r6 - lui + dahi
// Here lui sets high 32 bits to 1 so dahi can be used to get target
// value.
{0x00007fff7fff0000, 3, 2},
// r2 - lui + ori + dsll
// r6 - lui + dahi
// High 32 bits are not set so dahi can be used to get target value.
{0xffff7fff7fff0000, 5, 3},
// r2 - lui + ori + dsll + ori + dsll
// r6 - lui + dahi + dati
// High 32 bits are not set so just dahi can't be used to get target
// value.
{0x00007fff80010000, 3, 3},
// r2 - lui + ori + dsll
// r6 - lui + ori + dsll
// High 32 bits are set so can't just use lui + dahi to get target value.
{0x1234abcd87654321, 6, 4},
// The test case above generates:
// r2 - lui + ori + dsll + ori + dsll + ori instruction sequence,
// r6 - lui + ori + dahi + dati.
// Load using full instruction sequence.
{0xffff0000ffffffff, 3, 3},
// r2 - ori + dsll32 + nor
// Loading imm directly would require lui + dsll + ori + dsll + ori.
// Optimized by loading ~imm and using nor to get imm. Loading -imm would
// require one instruction more.
// r6 - daddiu + dahi + dati
};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCase_li);
for (size_t i = 0; i < nr_test_cases; ++i) {
if (kArchVariant == kMips64r2) {
CHECK_EQ(tc[i].imm,
run_li_macro(tc[i].imm, OPTIMIZE_SIZE, tc[i].r2_num_instr));
} else {
CHECK_EQ(tc[i].imm,
run_li_macro(tc[i].imm, OPTIMIZE_SIZE, tc[i].r6_num_instr));
}
CHECK_EQ(tc[i].imm, run_li_macro(tc[i].imm, CONSTANT_SIZE));
if (is_int48(tc[i].imm)) {
CHECK_EQ(tc[i].imm, run_li_macro(tc[i].imm, ADDRESS_LOAD));
}
}
}
uint64_t run_lwpc(int offset) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
// 256k instructions; 2^8k
// addiu t3, a4, 0xffff; (0x250fffff)
// ...
// addiu t0, a4, 0x0000; (0x250c0000)
uint32_t addiu_start_1 = 0x25000000;
for (int32_t i = 0xfffff; i >= 0xc0000; --i) {
uint32_t addiu_new = addiu_start_1 + i;
__ dd(addiu_new);
}
__ lwpc(t8, offset); // offset 0; 0xef080000 (t8 register)
__ mov(v0, t8);
// 256k instructions; 2^8k
// addiu a4, a4, 0x0000; (0x25080000)
// ...
// addiu a7, a4, 0xffff; (0x250bffff)
uint32_t addiu_start_2 = 0x25000000;
for (int32_t i = 0x80000; i <= 0xbffff; ++i) {
uint32_t addiu_new = addiu_start_2 + i;
__ dd(addiu_new);
}
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
TEST(r6_lwpc) {
if (kArchVariant == kMips64r6) {
CcTest::InitializeVM();
struct TestCaseLwpc {
int offset;
uint64_t expected_res;
};
struct TestCaseLwpc tc[] = {
// offset, expected_res
{ -262144, 0x250fffff }, // offset 0x40000
{ -4, 0x250c0003 },
{ -1, 0x250c0000 },
{ 0, 0xffffffffef080000 },
{ 1, 0x03001025 }, // mov(v0, t8)
{ 2, 0x25080000 },
{ 4, 0x25080002 },
{ 262143, 0x250bfffd }, // offset 0x3ffff
};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCaseLwpc);
for (size_t i = 0; i < nr_test_cases; ++i) {
uint64_t res = run_lwpc(tc[i].offset);
CHECK_EQ(tc[i].expected_res, res);
}
}
}
uint64_t run_lwupc(int offset) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
// 256k instructions; 2^8k
// addiu t3, a4, 0xffff; (0x250fffff)
// ...
// addiu t0, a4, 0x0000; (0x250c0000)
uint32_t addiu_start_1 = 0x25000000;
for (int32_t i = 0xfffff; i >= 0xc0000; --i) {
uint32_t addiu_new = addiu_start_1 + i;
__ dd(addiu_new);
}
__ lwupc(t8, offset); // offset 0; 0xef080000 (t8 register)
__ mov(v0, t8);
// 256k instructions; 2^8k
// addiu a4, a4, 0x0000; (0x25080000)
// ...
// addiu a7, a4, 0xffff; (0x250bffff)
uint32_t addiu_start_2 = 0x25000000;
for (int32_t i = 0x80000; i <= 0xbffff; ++i) {
uint32_t addiu_new = addiu_start_2 + i;
__ dd(addiu_new);
}
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
TEST(r6_lwupc) {
if (kArchVariant == kMips64r6) {
CcTest::InitializeVM();
struct TestCaseLwupc {
int offset;
uint64_t expected_res;
};
struct TestCaseLwupc tc[] = {
// offset, expected_res
{ -262144, 0x250fffff }, // offset 0x40000
{ -4, 0x250c0003 },
{ -1, 0x250c0000 },
{ 0, 0xef100000 },
{ 1, 0x03001025 }, // mov(v0, t8)
{ 2, 0x25080000 },
{ 4, 0x25080002 },
{ 262143, 0x250bfffd }, // offset 0x3ffff
};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCaseLwupc);
for (size_t i = 0; i < nr_test_cases; ++i) {
uint64_t res = run_lwupc(tc[i].offset);
CHECK_EQ(tc[i].expected_res, res);
}
}
}
uint64_t run_jic(int16_t offset) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
Label get_program_counter, stop_execution;
__ push(ra);
__ li(v0, 0);
__ li(t1, 0x66);
__ addiu(v0, v0, 0x1); // <-- offset = -32
__ addiu(v0, v0, 0x2);
__ addiu(v0, v0, 0x10);
__ addiu(v0, v0, 0x20);
__ beq(v0, t1, &stop_execution);
__ nop();
__ bal(&get_program_counter); // t0 <- program counter
__ nop();
__ jic(t0, offset);
__ addiu(v0, v0, 0x100);
__ addiu(v0, v0, 0x200);
__ addiu(v0, v0, 0x1000);
__ addiu(v0, v0, 0x2000); // <--- offset = 16
__ pop(ra);
__ jr(ra);
__ nop();
__ bind(&get_program_counter);
__ mov(t0, ra);
__ jr(ra);
__ nop();
__ bind(&stop_execution);
__ pop(ra);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
TEST(r6_jic) {
if (kArchVariant == kMips64r6) {
CcTest::InitializeVM();
struct TestCaseJic {
// As rt will be used t0 register which will have value of
// the program counter for the jic instruction.
int16_t offset;
uint32_t expected_res;
};
struct TestCaseJic tc[] = {
// offset, expected_result
{ 16, 0x2033 },
{ 4, 0x3333 },
{ -32, 0x66 },
};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCaseJic);
for (size_t i = 0; i < nr_test_cases; ++i) {
uint64_t res = run_jic(tc[i].offset);
CHECK_EQ(tc[i].expected_res, res);
}
}
}
uint64_t run_beqzc(int32_t value, int32_t offset) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
Label stop_execution;
__ li(v0, 0);
__ li(t1, 0x66);
__ addiu(v0, v0, 0x1); // <-- offset = -8
__ addiu(v0, v0, 0x2);
__ addiu(v0, v0, 0x10);
__ addiu(v0, v0, 0x20);
__ beq(v0, t1, &stop_execution);
__ nop();
__ beqzc(a0, offset);
__ addiu(v0, v0, 0x1);
__ addiu(v0, v0, 0x100);
__ addiu(v0, v0, 0x200);
__ addiu(v0, v0, 0x1000);
__ addiu(v0, v0, 0x2000); // <--- offset = 4
__ jr(ra);
__ nop();
__ bind(&stop_execution);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, value, 0, 0, 0, 0));
return res;
}
TEST(r6_beqzc) {
if (kArchVariant == kMips64r6) {
CcTest::InitializeVM();
struct TestCaseBeqzc {
uint32_t value;
int32_t offset;
uint32_t expected_res;
};
struct TestCaseBeqzc tc[] = {
// value, offset, expected_res
{ 0x0, -8, 0x66 },
{ 0x0, 0, 0x3334 },
{ 0x0, 1, 0x3333 },
{ 0xabc, 1, 0x3334 },
{ 0x0, 4, 0x2033 },
};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCaseBeqzc);
for (size_t i = 0; i < nr_test_cases; ++i) {
uint64_t res = run_beqzc(tc[i].value, tc[i].offset);
CHECK_EQ(tc[i].expected_res, res);
}
}
}
uint64_t run_jialc(int16_t offset) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
Label main_block, get_program_counter;
__ push(ra);
__ li(v0, 0);
__ beq(v0, v0, &main_block);
__ nop();
// Block 1
__ addiu(v0, v0, 0x1); // <-- offset = -40
__ addiu(v0, v0, 0x2);
__ jr(ra);
__ nop();
// Block 2
__ addiu(v0, v0, 0x10); // <-- offset = -24
__ addiu(v0, v0, 0x20);
__ jr(ra);
__ nop();
// Block 3 (Main)
__ bind(&main_block);
__ bal(&get_program_counter); // t0 <- program counter
__ nop();
__ jialc(t0, offset);
__ addiu(v0, v0, 0x4);
__ pop(ra);
__ jr(ra);
__ nop();
// Block 4
__ addiu(v0, v0, 0x100); // <-- offset = 20
__ addiu(v0, v0, 0x200);
__ jr(ra);
__ nop();
// Block 5
__ addiu(v0, v0, 0x1000); // <--- offset = 36
__ addiu(v0, v0, 0x2000);
__ jr(ra);
__ nop();
__ bind(&get_program_counter);
__ mov(t0, ra);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
TEST(r6_jialc) {
if (kArchVariant == kMips64r6) {
CcTest::InitializeVM();
struct TestCaseJialc {
// As rt will be used t0 register which will have value of
// the program counter for the jialc instruction.
int16_t offset;
uint32_t expected_res;
};
struct TestCaseJialc tc[] = {
// offset, expected_res
{ -40, 0x7 },
{ -24, 0x34 },
{ 20, 0x304 },
{ 36, 0x3004 }
};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCaseJialc);
for (size_t i = 0; i < nr_test_cases; ++i) {
uint64_t res = run_jialc(tc[i].offset);
CHECK_EQ(tc[i].expected_res, res);
}
}
}
uint64_t run_addiupc(int32_t imm19) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
__ addiupc(v0, imm19);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
PC = (uint64_t) f; // Set the program counter.
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
TEST(r6_addiupc) {
if (kArchVariant == kMips64r6) {
CcTest::InitializeVM();
struct TestCaseAddiupc {
int32_t imm19;
};
struct TestCaseAddiupc tc[] = {
// imm19
{ -262144 }, // 0x40000
{ -1 }, // 0x7FFFF
{ 0 },
{ 1 }, // 0x00001
{ 262143 } // 0x3FFFF
};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCaseAddiupc);
for (size_t i = 0; i < nr_test_cases; ++i) {
PC = 0;
uint64_t res = run_addiupc(tc[i].imm19);
// Now, the program_counter (PC) is set.
uint64_t expected_res = PC + (tc[i].imm19 << 2);
CHECK_EQ(expected_res, res);
}
}
}
uint64_t run_ldpc(int offset) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
// 256k instructions; 2 * 2^7k = 2^8k
// addiu t3, a4, 0xffff; (0x250fffff)
// ...
// addiu t0, a4, 0x0000; (0x250c0000)
uint32_t addiu_start_1 = 0x25000000;
for (int32_t i = 0xfffff; i >= 0xc0000; --i) {
uint32_t addiu_new = addiu_start_1 + i;
__ dd(addiu_new);
}
__ ldpc(t8, offset); // offset 0; 0xef080000 (t8 register)
__ mov(v0, t8);
// 256k instructions; 2 * 2^7k = 2^8k
// addiu a4, a4, 0x0000; (0x25080000)
// ...
// addiu a7, a4, 0xffff; (0x250bffff)
uint32_t addiu_start_2 = 0x25000000;
for (int32_t i = 0x80000; i <= 0xbffff; ++i) {
uint32_t addiu_new = addiu_start_2 + i;
__ dd(addiu_new);
}
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
TEST(r6_ldpc) {
if (kArchVariant == kMips64r6) {
CcTest::InitializeVM();
struct TestCaseLdpc {
int offset;
uint64_t expected_res;
};
auto doubleword = [](uint32_t word2, uint32_t word1) {
if (kArchEndian == kLittle)
return (static_cast<uint64_t>(word2) << 32) + word1;
else
return (static_cast<uint64_t>(word1) << 32) + word2;
};
TestCaseLdpc tc[] = {
// offset, expected_res
{-131072, doubleword(0x250ffffe, 0x250fffff)},
{-4, doubleword(0x250c0006, 0x250c0007)},
{-1, doubleword(0x250c0000, 0x250c0001)},
{0, doubleword(0x03001025, 0xef180000)},
{1, doubleword(0x25080001, 0x25080000)},
{4, doubleword(0x25080007, 0x25080006)},
{131071, doubleword(0x250bfffd, 0x250bfffc)},
};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCaseLdpc);
for (size_t i = 0; i < nr_test_cases; ++i) {
uint64_t res = run_ldpc(tc[i].offset);
CHECK_EQ(tc[i].expected_res, res);
}
}
}
int64_t run_bc(int32_t offset) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
Label continue_1, stop_execution;
__ push(ra);
__ li(v0, 0);
__ li(t8, 0);
__ li(t9, 2); // Condition for the stopping execution.
for (int32_t i = -100; i <= -11; ++i) {
__ addiu(v0, v0, 1);
}
__ addiu(t8, t8, 1); // -10
__ beq(t8, t9, &stop_execution); // -9
__ nop(); // -8
__ beq(t8, t8, &continue_1); // -7
__ nop(); // -6
__ bind(&stop_execution);
__ pop(ra); // -5, -4
__ jr(ra); // -3
__ nop(); // -2
__ bind(&continue_1);
__ bc(offset); // -1
for (int32_t i = 0; i <= 99; ++i) {
__ addiu(v0, v0, 1);
}
__ pop(ra);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
int64_t res = reinterpret_cast<int64_t>(
CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
TEST(r6_bc) {
if (kArchVariant == kMips64r6) {
CcTest::InitializeVM();
struct TestCaseBc {
int32_t offset;
int64_t expected_res;
};
struct TestCaseBc tc[] = {
// offset, expected_result
{ -100, (abs(-100) - 10) * 2 },
{ -11, (abs(-100) - 10 + 1) },
{ 0, (abs(-100) - 10 + 1 + 99) },
{ 1, (abs(-100) - 10 + 99) },
{ 99, (abs(-100) - 10 + 1) },
};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCaseBc);
for (size_t i = 0; i < nr_test_cases; ++i) {
int64_t res = run_bc(tc[i].offset);
CHECK_EQ(tc[i].expected_res, res);
}
}
}
int64_t run_balc(int32_t offset) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
Label continue_1, stop_execution;
__ push(ra);
__ li(v0, 0);
__ li(t8, 0);
__ li(t9, 2); // Condition for stopping execution.
__ beq(t8, t8, &continue_1);
__ nop();
uint32_t instruction_addiu = 0x24420001; // addiu v0, v0, 1
for (int32_t i = -117; i <= -57; ++i) {
__ dd(instruction_addiu);
}
__ jr(ra); // -56
__ nop(); // -55
for (int32_t i = -54; i <= -4; ++i) {
__ dd(instruction_addiu);
}
__ jr(ra); // -3
__ nop(); // -2
__ bind(&continue_1);
__ balc(offset); // -1
__ pop(ra); // 0, 1
__ jr(ra); // 2
__ nop(); // 3
for (int32_t i = 4; i <= 44; ++i) {
__ dd(instruction_addiu);
}
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
int64_t res = reinterpret_cast<int64_t>(
CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
TEST(r6_balc) {
if (kArchVariant == kMips64r6) {
CcTest::InitializeVM();
struct TestCaseBalc {
int32_t offset;
int64_t expected_res;
};
struct TestCaseBalc tc[] = {
// offset, expected_result
{ -117, 61 },
{ -54, 51 },
{ 0, 0 },
{ 4, 41 },
};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCaseBalc);
for (size_t i = 0; i < nr_test_cases; ++i) {
int64_t res = run_balc(tc[i].offset);
CHECK_EQ(tc[i].expected_res, res);
}
}
}
uint64_t run_dsll(uint64_t rt_value, uint16_t sa_value) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
__ dsll(v0, a0, sa_value);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F4 f = FUNCTION_CAST<F4>(code->entry());
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, rt_value, 0, 0, 0, 0));
return res;
}
TEST(dsll) {
CcTest::InitializeVM();
struct TestCaseDsll {
uint64_t rt_value;
uint16_t sa_value;
uint64_t expected_res;
};
struct TestCaseDsll tc[] = {
// rt_value, sa_value, expected_res
{ 0xffffffffffffffff, 0, 0xffffffffffffffff },
{ 0xffffffffffffffff, 16, 0xffffffffffff0000 },
{ 0xffffffffffffffff, 31, 0xffffffff80000000 },
};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCaseDsll);
for (size_t i = 0; i < nr_test_cases; ++i) {
CHECK_EQ(tc[i].expected_res,
run_dsll(tc[i].rt_value, tc[i].sa_value));
}
}
uint64_t run_bal(int16_t offset) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
__ mov(t0, ra);
__ bal(offset); // Equivalent for "BGEZAL zero_reg, offset".
__ nop();
__ mov(ra, t0);
__ jr(ra);
__ nop();
__ li(v0, 1);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
TEST(bal) {
CcTest::InitializeVM();
struct TestCaseBal {
int16_t offset;
uint64_t expected_res;
};
struct TestCaseBal tc[] = {
// offset, expected_res
{ 4, 1 },
};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCaseBal);
for (size_t i = 0; i < nr_test_cases; ++i) {
CHECK_EQ(tc[i].expected_res, run_bal(tc[i].offset));
}
}
TEST(Trampoline) {
// Private member of Assembler class.
static const int kMaxBranchOffset = (1 << (18 - 1)) - 1;
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
Label done;
size_t nr_calls = kMaxBranchOffset / (2 * Instruction::kInstrSize) + 2;
for (size_t i = 0; i < nr_calls; ++i) {
__ BranchShort(&done, eq, a0, Operand(a1));
}
__ bind(&done);
__ Ret(USE_DELAY_SLOT);
__ mov(v0, zero_reg);
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
int64_t res = reinterpret_cast<int64_t>(
CALL_GENERATED_CODE(isolate, f, 42, 42, 0, 0, 0));
CHECK_EQ(0, res);
}
template <class T>
struct TestCaseMaddMsub {
T fr, fs, ft, fd_add, fd_sub;
};
template <typename T, typename F>
void helper_madd_msub_maddf_msubf(F func) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
T x = std::sqrt(static_cast<T>(2.0));
T y = std::sqrt(static_cast<T>(3.0));
T z = std::sqrt(static_cast<T>(5.0));
T x2 = 11.11, y2 = 22.22, z2 = 33.33;
TestCaseMaddMsub<T> test_cases[] = {
{x, y, z, 0.0, 0.0},
{x, y, -z, 0.0, 0.0},
{x, -y, z, 0.0, 0.0},
{x, -y, -z, 0.0, 0.0},
{-x, y, z, 0.0, 0.0},
{-x, y, -z, 0.0, 0.0},
{-x, -y, z, 0.0, 0.0},
{-x, -y, -z, 0.0, 0.0},
{-3.14, 0.2345, -123.000056, 0.0, 0.0},
{7.3, -23.257, -357.1357, 0.0, 0.0},
{x2, y2, z2, 0.0, 0.0},
{x2, y2, -z2, 0.0, 0.0},
{x2, -y2, z2, 0.0, 0.0},
{x2, -y2, -z2, 0.0, 0.0},
{-x2, y2, z2, 0.0, 0.0},
{-x2, y2, -z2, 0.0, 0.0},
{-x2, -y2, z2, 0.0, 0.0},
{-x2, -y2, -z2, 0.0, 0.0},
};
if (std::is_same<T, float>::value) {
__ Lwc1(f4, MemOperand(a0, offsetof(TestCaseMaddMsub<T>, fr)));
__ Lwc1(f6, MemOperand(a0, offsetof(TestCaseMaddMsub<T>, fs)));
__ Lwc1(f8, MemOperand(a0, offsetof(TestCaseMaddMsub<T>, ft)));
__ Lwc1(f16, MemOperand(a0, offsetof(TestCaseMaddMsub<T>, fr)));
} else if (std::is_same<T, double>::value) {
__ Ldc1(f4, MemOperand(a0, offsetof(TestCaseMaddMsub<T>, fr)));
__ Ldc1(f6, MemOperand(a0, offsetof(TestCaseMaddMsub<T>, fs)));
__ Ldc1(f8, MemOperand(a0, offsetof(TestCaseMaddMsub<T>, ft)));
__ Ldc1(f16, MemOperand(a0, offsetof(TestCaseMaddMsub<T>, fr)));
} else {
UNREACHABLE();
}
func(assm);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F3 f = FUNCTION_CAST<F3>(code->entry());
const size_t kTableLength = sizeof(test_cases) / sizeof(TestCaseMaddMsub<T>);
TestCaseMaddMsub<T> tc;
for (size_t i = 0; i < kTableLength; i++) {
tc.fr = test_cases[i].fr;
tc.fs = test_cases[i].fs;
tc.ft = test_cases[i].ft;
(CALL_GENERATED_CODE(isolate, f, &tc, 0, 0, 0, 0));
T res_sub;
T res_add;
if (kArchVariant != kMips64r6) {
res_add = tc.fr + (tc.fs * tc.ft);
res_sub = (tc.fs * tc.ft) - tc.fr;
} else {
res_add = std::fma(tc.fs, tc.ft, tc.fr);
res_sub = std::fma(-tc.fs, tc.ft, tc.fr);
}
CHECK_EQ(tc.fd_add, res_add);
CHECK_EQ(tc.fd_sub, res_sub);
}
}
TEST(madd_msub_s) {
if (kArchVariant == kMips64r6) return;
helper_madd_msub_maddf_msubf<float>([](MacroAssembler& assm) {
__ Madd_s(f10, f4, f6, f8, f12);
__ Swc1(f10, MemOperand(a0, offsetof(TestCaseMaddMsub<float>, fd_add)));
__ Msub_s(f16, f4, f6, f8, f12);
__ Swc1(f16, MemOperand(a0, offsetof(TestCaseMaddMsub<float>, fd_sub)));
});
}
TEST(madd_msub_d) {
if (kArchVariant == kMips64r6) return;
helper_madd_msub_maddf_msubf<double>([](MacroAssembler& assm) {
__ Madd_d(f10, f4, f6, f8, f12);
__ Sdc1(f10, MemOperand(a0, offsetof(TestCaseMaddMsub<double>, fd_add)));
__ Msub_d(f16, f4, f6, f8, f12);
__ Sdc1(f16, MemOperand(a0, offsetof(TestCaseMaddMsub<double>, fd_sub)));
});
}
TEST(maddf_msubf_s) {
if (kArchVariant != kMips64r6) return;
helper_madd_msub_maddf_msubf<float>([](MacroAssembler& assm) {
__ maddf_s(f4, f6, f8);
__ Swc1(f4, MemOperand(a0, offsetof(TestCaseMaddMsub<float>, fd_add)));
__ msubf_s(f16, f6, f8);
__ Swc1(f16, MemOperand(a0, offsetof(TestCaseMaddMsub<float>, fd_sub)));
});
}
TEST(maddf_msubf_d) {
if (kArchVariant != kMips64r6) return;
helper_madd_msub_maddf_msubf<double>([](MacroAssembler& assm) {
__ maddf_d(f4, f6, f8);
__ Sdc1(f4, MemOperand(a0, offsetof(TestCaseMaddMsub<double>, fd_add)));
__ msubf_d(f16, f6, f8);
__ Sdc1(f16, MemOperand(a0, offsetof(TestCaseMaddMsub<double>, fd_sub)));
});
}
uint64_t run_Subu(uint64_t imm, int32_t num_instr) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
Label code_start;
__ bind(&code_start);
__ Subu(v0, zero_reg, Operand(imm));
CHECK_EQ(assm.InstructionsGeneratedSince(&code_start), num_instr);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F2 f = FUNCTION_CAST<F2>(code->entry());
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
TEST(Subu) {
CcTest::InitializeVM();
// Test Subu macro-instruction for min_int16 and max_int16 border cases.
// For subtracting int16 immediate values we use addiu.
struct TestCaseSubu {
uint64_t imm;
uint64_t expected_res;
int32_t num_instr;
};
// We call Subu(v0, zero_reg, imm) to test cases listed below.
// 0 - imm = expected_res
struct TestCaseSubu tc[] = {
// imm, expected_res, num_instr
{0xffffffffffff8000, 0x8000, 2}, // min_int16
// The test case above generates ori + addu instruction sequence.
// We can't have just addiu because -min_int16 > max_int16 so use
// register. We can load min_int16 to at register with addiu and then
// subtract at with subu, but now we use ori + addu because -min_int16 can
// be loaded using ori.
{0x8000, 0xffffffffffff8000, 1}, // max_int16 + 1
// Generates addiu
// max_int16 + 1 is not int16 but -(max_int16 + 1) is, just use addiu.
{0xffffffffffff7fff, 0x8001, 2}, // min_int16 - 1
// Generates ori + addu
// To load this value to at we need two instructions and another one to
// subtract, lui + ori + subu. But we can load -value to at using just
// ori and then add at register with addu.
{0x8001, 0xffffffffffff7fff, 2}, // max_int16 + 2
// Generates ori + subu
// Not int16 but is uint16, load value to at with ori and subtract with
// subu.
{0x00010000, 0xffffffffffff0000, 2},
// Generates lui + subu
// Load value using lui to at and subtract with subu.
{0x00010001, 0xfffffffffffeffff, 3},
// Generates lui + ori + subu
// We have to generate three instructions in this case.
{0x7fffffff, 0xffffffff80000001, 3}, // max_int32
// Generates lui + ori + subu
{0xffffffff80000000, 0xffffffff80000000, 2}, // min_int32
// The test case above generates lui + subu intruction sequence.
// The result of 0 - min_int32 eqauls max_int32 + 1, which wraps around to
// min_int32 again.
};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCaseSubu);
for (size_t i = 0; i < nr_test_cases; ++i) {
CHECK_EQ(tc[i].expected_res, run_Subu(tc[i].imm, tc[i].num_instr));
}
}
uint64_t run_Dsubu(uint64_t imm, int32_t num_instr) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
Label code_start;
__ bind(&code_start);
__ Dsubu(v0, zero_reg, Operand(imm));
CHECK_EQ(assm.InstructionsGeneratedSince(&code_start), num_instr);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F2 f = FUNCTION_CAST<F2>(code->entry());
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
TEST(Dsubu) {
CcTest::InitializeVM();
// Test Dsubu macro-instruction for min_int16 and max_int16 border cases.
// For subtracting int16 immediate values we use daddiu.
struct TestCaseDsubu {
uint64_t imm;
uint64_t expected_res;
int32_t num_instr;
};
// We call Dsubu(v0, zero_reg, imm) to test cases listed below.
// 0 - imm = expected_res
struct TestCaseDsubu tc[] = {
// imm, expected_res, num_instr
{0xffffffffffff8000, 0x8000, 2}, // min_int16
// The test case above generates daddiu + dsubu instruction sequence.
// We can't have just daddiu because -min_int16 > max_int16 so use
// register, but we can load min_int16 to at register with daddiu and then
// subtract at with dsubu.
{0x8000, 0xffffffffffff8000, 1}, // max_int16 + 1
// Generates daddiu
// max_int16 + 1 is not int16 but -(max_int16 + 1) is, just use daddiu.
{0xffffffffffff7fff, 0x8001, 2}, // min_int16 - 1
// Generates ori + daddu
// To load this value to at we need two instructions and another one to
// subtract, lui + ori + dsubu. But we can load -value to at using just
// ori and then dadd at register with daddu.
{0x8001, 0xffffffffffff7fff, 2}, // max_int16 + 2
// Generates ori + dsubu
// Not int16 but is uint16, load value to at with ori and subtract with
// dsubu.
{0x00010000, 0xffffffffffff0000, 2},
// Generates lui + dsubu
// Load value using lui to at and subtract with dsubu.
{0x00010001, 0xfffffffffffeffff, 3},
// Generates lui + ori + dsubu
// We have to generate three instructions in this case.
{0x7fffffff, 0xffffffff80000001, 3}, // max_int32
// Generates lui + ori + dsubu
{0xffffffff80000000, 0x0000000080000000, 2}, // min_int32
// Generates lui + dsubu
// The result of 0 - min_int32 eqauls max_int32 + 1, which fits into a 64
// bit register, Dsubu gives a different result here.
{0x7fffffffffffffff, 0x8000000000000001, 3}, // max_int64
// r2 - Generates daddiu + dsrl + dsubu
// r6 - Generates daddiu + dati + dsubu
{0x8000000000000000, 0x8000000000000000, 3}, // min_int64
// The test case above generates:
// r2 - daddiu + dsll32 + dsubu instruction sequence,
// r6 - ori + dati + dsubu.
// The result of 0 - min_int64 eqauls max_int64 + 1, which wraps around to
// min_int64 again.
{0xffff0000ffffffff, 0x0000ffff00000001, 4},
// The test case above generates:
// r2 - ori + dsll32 + ori + daddu instruction sequence,
// r6 - daddiu + dahi + dati + dsubu.
// For r2 loading imm would take more instructions than loading -imm so we
// can load -imm and add with daddu.
};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCaseDsubu);
for (size_t i = 0; i < nr_test_cases; ++i) {
CHECK_EQ(tc[i].expected_res, run_Dsubu(tc[i].imm, tc[i].num_instr));
}
}
uint64_t run_Dins(uint64_t imm, uint64_t source, uint16_t pos, uint16_t size) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
__ li(v0, imm);
__ li(t0, source);
__ Dins(v0, t0, pos, size);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
TEST(Dins) {
CcTest::InitializeVM();
// Test Dins macro-instruction.
struct TestCaseDins {
uint64_t imm;
uint64_t source;
uint16_t pos;
uint16_t size;
uint64_t expected_res;
};
// We load imm to v0 and source to t0 and then call
// Dins(v0, t0, pos, size) to test cases listed below.
struct TestCaseDins tc[] = {
// imm, source, pos, size, expected_res
{0x5555555555555555, 0x1abcdef01, 31, 1, 0x55555555d5555555},
{0x5555555555555555, 0x1abcdef02, 30, 2, 0x5555555595555555},
{0x201234567, 0x1fabcdeff, 0, 32, 0x2fabcdeff},
{0x201234567, 0x7fabcdeff, 31, 2, 0x381234567},
{0x800000000, 0x7fabcdeff, 0, 33, 0x9fabcdeff},
{0x1234, 0xabcdabcdabcdabcd, 0, 64, 0xabcdabcdabcdabcd},
{0xabcd, 0xabceabcf, 32, 1, 0x10000abcd},
{0xabcd, 0xabceabcf, 63, 1, 0x800000000000abcd},
{0x10000abcd, 0xabc1abc2abc3abc4, 32, 32, 0xabc3abc40000abcd},
};
size_t nr_test_cases = sizeof(tc) / sizeof(TestCaseDins);
for (size_t i = 0; i < nr_test_cases; ++i) {
CHECK_EQ(tc[i].expected_res,
run_Dins(tc[i].imm, tc[i].source, tc[i].pos, tc[i].size));
}
}
uint64_t run_Ins(uint64_t imm, uint64_t source, uint16_t pos, uint16_t size) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
__ li(v0, imm);
__ li(t0, source);
__ Ins(v0, t0, pos, size);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
TEST(Ins) {
CcTest::InitializeVM();
// run_Ins(rt_value, rs_value, pos, size),
// expected_result
CHECK_EQ(run_Ins(0x0000000055555555, 0xffffffffabcdef01, 31, 1),
0xffffffffd5555555);
CHECK_EQ(run_Ins(0x0000000055555555, 0xffffffffabcdef02, 30, 2),
0xffffffff95555555);
CHECK_EQ(run_Ins(0x0000000001234567, 0xfffffffffabcdeff, 0, 32),
0xfffffffffabcdeff);
// Results with positive sign.
CHECK_EQ(run_Ins(0x0000000055555550, 0xffffffff80000001, 0, 1),
0x0000000055555551);
CHECK_EQ(run_Ins(0x0000000055555555, 0x0000000040000001, 0, 32),
0x0000000040000001);
CHECK_EQ(run_Ins(0x0000000055555555, 0x0000000020000001, 1, 31),
0x0000000040000003);
CHECK_EQ(run_Ins(0x0000000055555555, 0xffffffff80700001, 8, 24),
0x0000000070000155);
CHECK_EQ(run_Ins(0x0000000055555555, 0xffffffff80007001, 16, 16),
0x0000000070015555);
CHECK_EQ(run_Ins(0x0000000055555555, 0xffffffff80000071, 24, 8),
0x0000000071555555);
CHECK_EQ(run_Ins(0x0000000075555555, 0x0000000040000000, 31, 1),
0x0000000075555555);
// Results with negative sign.
CHECK_EQ(run_Ins(0xffffffff85555550, 0xffffffff80000001, 0, 1),
0xffffffff85555551);
CHECK_EQ(run_Ins(0x0000000055555555, 0xffffffff80000001, 0, 32),
0xffffffff80000001);
CHECK_EQ(run_Ins(0x0000000055555555, 0x0000000040000001, 1, 31),
0xffffffff80000003);
CHECK_EQ(run_Ins(0x0000000055555555, 0xffffffff80800001, 8, 24),
0xffffffff80000155);
CHECK_EQ(run_Ins(0x0000000055555555, 0xffffffff80008001, 16, 16),
0xffffffff80015555);
CHECK_EQ(run_Ins(0x0000000055555555, 0xffffffff80000081, 24, 8),
0xffffffff81555555);
CHECK_EQ(run_Ins(0x0000000075555555, 0x0000000000000001, 31, 1),
0xfffffffff5555555);
}
uint64_t run_Ext(uint64_t source, uint16_t pos, uint16_t size) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
__ li(v0, 0xffffffffffffffff);
__ li(t0, source);
__ Ext(v0, t0, pos, size);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
F2 f = FUNCTION_CAST<F2>(code->entry());
uint64_t res = reinterpret_cast<uint64_t>(
CALL_GENERATED_CODE(isolate, f, 0, 0, 0, 0, 0));
return res;
}
TEST(Ext) {
CcTest::InitializeVM();
// Source values with negative sign.
// run_Ext(rs_value, pos, size), expected_result
CHECK_EQ(run_Ext(0xffffffff80000001, 0, 1), 0x0000000000000001);
CHECK_EQ(run_Ext(0xffffffff80000001, 0, 32), 0xffffffff80000001);
CHECK_EQ(run_Ext(0xffffffff80000002, 1, 31), 0x0000000040000001);
CHECK_EQ(run_Ext(0xffffffff80000100, 8, 24), 0x0000000000800001);
CHECK_EQ(run_Ext(0xffffffff80010000, 16, 16), 0x0000000000008001);
CHECK_EQ(run_Ext(0xffffffff81000000, 24, 8), 0x0000000000000081);
CHECK_EQ(run_Ext(0xffffffff80000000, 31, 1), 0x0000000000000001);
// Source values with positive sign.
CHECK_EQ(run_Ext(0x0000000000000001, 0, 1), 0x0000000000000001);
CHECK_EQ(run_Ext(0x0000000040000001, 0, 32), 0x0000000040000001);
CHECK_EQ(run_Ext(0x0000000040000002, 1, 31), 0x0000000020000001);
CHECK_EQ(run_Ext(0x0000000040000100, 8, 24), 0x0000000000400001);
CHECK_EQ(run_Ext(0x0000000040010000, 16, 16), 0x0000000000004001);
CHECK_EQ(run_Ext(0x0000000041000000, 24, 8), 0x0000000000000041);
CHECK_EQ(run_Ext(0x0000000040000000, 31, 1), 0x0000000000000000);
}
// Load elements in w0 MSA vector register
void load_uint64_elements_of_vector(MacroAssembler& assm,
const uint64_t elements[], MSARegister w,
Register t0, Register t1) {
__ li(t0, elements[0]);
__ li(t1, elements[1]);
__ insert_d(w, 0, t0);
__ insert_d(w, 1, t1);
}
void load_uint32_elements_of_vector(MacroAssembler& assm,
const uint64_t elements[], MSARegister w,
Register t0, Register t1) {
const uint32_t* const element = reinterpret_cast<const uint32_t*>(elements);
__ li(t0, element[0]);
__ li(t1, element[1]);
__ insert_w(w, 0, t0);
__ insert_w(w, 1, t1);
__ li(t0, element[2]);
__ li(t1, element[3]);
__ insert_w(w, 2, t0);
__ insert_w(w, 3, t1);
}
void load_uint16_elements_of_vector(MacroAssembler& assm,
const uint64_t elements[], MSARegister w,
Register t0, Register t1) {
const uint16_t* const element = reinterpret_cast<const uint16_t*>(elements);
__ li(t0, element[0]);
__ li(t1, element[1]);
__ insert_h(w, 0, t0);
__ insert_h(w, 1, t1);
__ li(t0, element[2]);
__ li(t1, element[3]);
__ insert_h(w, 2, t0);
__ insert_h(w, 3, t1);
__ li(t0, element[4]);
__ li(t1, element[5]);
__ insert_h(w, 4, t0);
__ insert_h(w, 5, t1);
__ li(t0, element[6]);
__ li(t1, element[7]);
__ insert_h(w, 6, t0);
__ insert_h(w, 7, t1);
}
// Store vector elements from w2 to the memory pointed by a0
void store_uint64_elements_of_vector(MacroAssembler& assm, MSARegister w,
Register a) {
__ st_d(w, MemOperand(a, 0));
}
void store_uint32_elements_of_vector(MacroAssembler& assm, MSARegister w,
Register a) {
__ st_w(w, MemOperand(a, 0));
}
void store_uint16_elements_of_vector(MacroAssembler& assm, MSARegister w,
Register a) {
__ st_h(w, MemOperand(a, 0));
}
TEST(MSA_fill_copy) {
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
typedef struct {
uint64_t u8;
uint64_t u16;
uint64_t u32;
uint64_t s8;
uint64_t s16;
uint64_t s32;
uint64_t s64;
} T;
T t;
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
{
CpuFeatureScope fscope(&assm, MIPS_SIMD);
__ li(t0, 0x9e7689aca512b683);
__ fill_b(w0, t0);
__ fill_h(w2, t0);
__ fill_w(w4, t0);
__ fill_d(w6, t0);
__ copy_u_b(t1, w0, 11);
__ sd(t1, MemOperand(a0, offsetof(T, u8)));
__ copy_u_h(t1, w2, 6);
__ sd(t1, MemOperand(a0, offsetof(T, u16)));
__ copy_u_w(t1, w4, 3);
__ sd(t1, MemOperand(a0, offsetof(T, u32)));
__ copy_s_b(t1, w0, 8);
__ sd(t1, MemOperand(a0, offsetof(T, s8)));
__ copy_s_h(t1, w2, 5);
__ sd(t1, MemOperand(a0, offsetof(T, s16)));
__ copy_s_w(t1, w4, 1);
__ sd(t1, MemOperand(a0, offsetof(T, s32)));
__ copy_s_d(t1, w6, 0);
__ sd(t1, MemOperand(a0, offsetof(T, s64)));
__ jr(ra);
__ nop();
}
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F3 f = FUNCTION_CAST<F3>(code->entry());
Object* dummy = CALL_GENERATED_CODE(isolate, f, &t, 0, 0, 0, 0);
USE(dummy);
CHECK_EQ(0x83u, t.u8);
CHECK_EQ(0xb683u, t.u16);
CHECK_EQ(0xa512b683u, t.u32);
CHECK_EQ(0xffffffffffffff83u, t.s8);
CHECK_EQ(0xffffffffffffb683u, t.s16);
CHECK_EQ(0xffffffffa512b683u, t.s32);
CHECK_EQ(0x9e7689aca512b683u, t.s64);
}
TEST(MSA_fill_copy_2) {
// Similar to MSA_fill_copy test, but also check overlaping between MSA and
// FPU registers with same numbers
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
typedef struct {
uint64_t d0;
uint64_t d1;
} T;
T t[2];
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
{
CpuFeatureScope fscope(&assm, MIPS_SIMD);
__ li(t0, 0xaaaaaaaaaaaaaaaa);
__ li(t1, 0x5555555555555555);
__ fill_d(w0, t0);
__ fill_d(w2, t0);
__ Move(f0, t1);
__ Move(f2, t1);
#define STORE_MSA_REG(w_reg, base, scratch) \
__ copy_s_d(scratch, w_reg, 0); \
__ sd(scratch, MemOperand(base, offsetof(T, d0))); \
__ copy_s_d(scratch, w_reg, 1); \
__ sd(scratch, MemOperand(base, offsetof(T, d1)));
STORE_MSA_REG(w0, a0, t2)
STORE_MSA_REG(w2, a1, t2)
#undef STORE_MSA_REG
__ jr(ra);
__ nop();
}
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F5 f = FUNCTION_CAST<F5>(code->entry());
Object* dummy = CALL_GENERATED_CODE(isolate, f, &t[0], &t[1], 0, 0, 0);
USE(dummy);
CHECK_EQ(0x5555555555555555, t[0].d0);
CHECK_EQ(0xaaaaaaaaaaaaaaaa, t[0].d1);
CHECK_EQ(0x5555555555555555, t[1].d0);
CHECK_EQ(0xaaaaaaaaaaaaaaaa, t[1].d1);
}
TEST(MSA_fill_copy_3) {
// Similar to MSA_fill_copy test, but also check overlaping between MSA and
// FPU registers with same numbers
CcTest::InitializeVM();
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
typedef struct {
uint64_t d0;
uint64_t d1;
} T;
T t[2];
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
{
CpuFeatureScope fscope(&assm, MIPS_SIMD);
__ li(t0, 0xaaaaaaaaaaaaaaaa);
__ li(t1, 0x5555555555555555);
__ Move(f0, t0);
__ Move(f2, t0);
__ fill_d(w0, t1);
__ fill_d(w2, t1);
__ Sdc1(f0, MemOperand(a0, offsetof(T, d0)));
__ Sdc1(f2, MemOperand(a1, offsetof(T, d0)));
__ jr(ra);
__ nop();
}
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F5 f = FUNCTION_CAST<F5>(code->entry());
Object* dummy = CALL_GENERATED_CODE(isolate, f, &t[0], &t[1], 0, 0, 0);
USE(dummy);
CHECK_EQ(0x5555555555555555, t[0].d0);
CHECK_EQ(0x5555555555555555, t[1].d0);
}
typedef union {
uint8_t b[16];
uint16_t h[8];
uint32_t w[4];
uint64_t d[2];
} msa_reg_t;
template <typename T>
void run_msa_insert(int64_t rs_value, int n, msa_reg_t* w) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
CpuFeatureScope fscope(&assm, MIPS_SIMD);
__ li(t0, -1);
__ li(t1, rs_value);
__ fill_w(w0, t0);
if (std::is_same<T, int8_t>::value) {
DCHECK_LT(n, 16);
__ insert_b(w0, n, t1);
} else if (std::is_same<T, int16_t>::value) {
DCHECK_LT(n, 8);
__ insert_h(w0, n, t1);
} else if (std::is_same<T, int32_t>::value) {
DCHECK_LT(n, 4);
__ insert_w(w0, n, t1);
} else if (std::is_same<T, int64_t>::value) {
DCHECK_LT(n, 2);
__ insert_d(w0, n, t1);
} else {
UNREACHABLE();
}
store_uint64_elements_of_vector(assm, w0, a0);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F3 f = FUNCTION_CAST<F3>(code->entry());
(CALL_GENERATED_CODE(isolate, f, w, 0, 0, 0, 0));
}
TEST(MSA_insert) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
struct TestCaseInsert {
uint64_t input;
int n;
uint64_t exp_res_lo;
uint64_t exp_res_hi;
};
struct TestCaseInsert tc_b[] = {
// input, n, exp_res_lo, exp_res_hi
{0xa2, 13, 0xffffffffffffffffu, 0xffffa2ffffffffffu},
{0x73, 10, 0xffffffffffffffffu, 0xffffffffff73ffffu},
{0x3494, 5, 0xffff94ffffffffffu, 0xffffffffffffffffu},
{0xa6b8, 1, 0xffffffffffffb8ffu, 0xffffffffffffffffu}};
for (size_t i = 0; i < sizeof(tc_b) / sizeof(TestCaseInsert); ++i) {
msa_reg_t res;
run_msa_insert<int8_t>(tc_b[i].input, tc_b[i].n, &res);
CHECK_EQ(tc_b[i].exp_res_lo, res.d[0]);
CHECK_EQ(tc_b[i].exp_res_hi, res.d[1]);
}
struct TestCaseInsert tc_h[] = {
// input, n, exp_res_lo, exp_res_hi
{0x85a2, 7, 0xffffffffffffffffu, 0x85a2ffffffffffffu},
{0xe873, 5, 0xffffffffffffffffu, 0xffffffffe873ffffu},
{0x3494, 3, 0x3494ffffffffffffu, 0xffffffffffffffffu},
{0xa6b8, 1, 0xffffffffa6b8ffffu, 0xffffffffffffffffu}};
for (size_t i = 0; i < sizeof(tc_h) / sizeof(TestCaseInsert); ++i) {
msa_reg_t res;
run_msa_insert<int16_t>(tc_h[i].input, tc_h[i].n, &res);
CHECK_EQ(tc_h[i].exp_res_lo, res.d[0]);
CHECK_EQ(tc_h[i].exp_res_hi, res.d[1]);
}
struct TestCaseInsert tc_w[] = {
// input, n, exp_res_lo, exp_res_hi
{0xd2f085a2u, 3, 0xffffffffffffffffu, 0xd2f085a2ffffffffu},
{0x4567e873u, 2, 0xffffffffffffffffu, 0xffffffff4567e873u},
{0xacdb3494u, 1, 0xacdb3494ffffffffu, 0xffffffffffffffffu},
{0x89aba6b8u, 0, 0xffffffff89aba6b8u, 0xffffffffffffffffu}};
for (size_t i = 0; i < sizeof(tc_w) / sizeof(TestCaseInsert); ++i) {
msa_reg_t res;
run_msa_insert<int32_t>(tc_w[i].input, tc_w[i].n, &res);
CHECK_EQ(tc_w[i].exp_res_lo, res.d[0]);
CHECK_EQ(tc_w[i].exp_res_hi, res.d[1]);
}
struct TestCaseInsert tc_d[] = {
// input, n, exp_res_lo, exp_res_hi
{0xf35862e13e38f8b0, 1, 0xffffffffffffffffu, 0xf35862e13e38f8b0},
{0x4f41ffdef2bfe636, 0, 0x4f41ffdef2bfe636, 0xffffffffffffffffu}};
for (size_t i = 0; i < sizeof(tc_d) / sizeof(TestCaseInsert); ++i) {
msa_reg_t res;
run_msa_insert<int64_t>(tc_d[i].input, tc_d[i].n, &res);
CHECK_EQ(tc_d[i].exp_res_lo, res.d[0]);
CHECK_EQ(tc_d[i].exp_res_hi, res.d[1]);
}
}
void run_msa_ctc_cfc(uint64_t value) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
CpuFeatureScope fscope(&assm, MIPS_SIMD);
MSAControlRegister msareg = {kMSACSRRegister};
__ li(t0, value);
__ li(t2, 0);
__ cfcmsa(t1, msareg);
__ ctcmsa(msareg, t0);
__ cfcmsa(t2, msareg);
__ ctcmsa(msareg, t1);
__ sd(t2, MemOperand(a0, 0));
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F3 f = FUNCTION_CAST<F3>(code->entry());
uint64_t res;
(CALL_GENERATED_CODE(isolate, f, &res, 0, 0, 0, 0));
CHECK_EQ(bit_cast<uint64_t>(static_cast<int64_t>(
bit_cast<int32_t>(static_cast<uint32_t>(value & 0x0167ffff)))),
res);
}
TEST(MSA_cfc_ctc) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
const uint64_t mask_without_cause = 0xffffffffff9c0fff;
const uint64_t mask_always_zero = 0x0167ffff;
const uint64_t mask_enables = 0x0000000000000f80;
uint64_t test_case[] = {0x30c6f6352d5ede31, 0xefc9fed507955425,
0x64f2a3ff15b7dbe3, 0x6aa069352bf8bc37,
0x7ea7ab2ae6aae923, 0xa10f5d4c24d0f68d,
0x6dd14c9441afa84c, 0xc366373b2d6bf64f,
0x6b35fb04925014bd, 0x9e3ea39a4dba7e61};
for (unsigned i = 0; i < arraysize(test_case); i++) {
// Setting enable bits and corresponding cause bits could result in
// exception raised and this prevents that from happening
test_case[i] = (~test_case[i] & mask_enables) << 5 |
(test_case[i] & mask_without_cause);
run_msa_ctc_cfc(test_case[i] & mask_always_zero);
}
}
struct ExpResShf {
uint8_t i8;
uint64_t lo;
uint64_t hi;
};
void run_msa_i8(SecondaryField opcode, uint64_t ws_lo, uint64_t ws_hi,
uint8_t i8) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
CpuFeatureScope fscope(&assm, MIPS_SIMD);
msa_reg_t res;
uint64_t wd_lo = 0xf35862e13e38f8b0;
uint64_t wd_hi = 0x4f41ffdef2bfe636;
#define LOAD_W_REG(lo, hi, w_reg) \
__ li(t0, lo); \
__ li(t1, hi); \
__ insert_d(w_reg, 0, t0); \
__ insert_d(w_reg, 1, t1);
LOAD_W_REG(ws_lo, ws_hi, w0)
switch (opcode) {
case ANDI_B:
__ andi_b(w2, w0, i8);
break;
case ORI_B:
__ ori_b(w2, w0, i8);
break;
case NORI_B:
__ nori_b(w2, w0, i8);
break;
case XORI_B:
__ xori_b(w2, w0, i8);
break;
case BMNZI_B:
LOAD_W_REG(wd_lo, wd_hi, w2);
__ bmnzi_b(w2, w0, i8);
break;
case BMZI_B:
LOAD_W_REG(wd_lo, wd_hi, w2);
__ bmzi_b(w2, w0, i8);
break;
case BSELI_B:
LOAD_W_REG(wd_lo, wd_hi, w2);
__ bseli_b(w2, w0, i8);
break;
case SHF_B:
__ shf_b(w2, w0, i8);
break;
case SHF_H:
__ shf_h(w2, w0, i8);
break;
case SHF_W:
__ shf_w(w2, w0, i8);
break;
default:
UNREACHABLE();
}
store_uint64_elements_of_vector(assm, w2, a0);
__ jr(ra);
__ nop();
#undef LOAD_W_REG
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F3 f = FUNCTION_CAST<F3>(code->entry());
(CALL_GENERATED_CODE(isolate, f, &res, 0, 0, 0, 0));
uint64_t mask = i8 * 0x0101010101010101ull;
switch (opcode) {
case ANDI_B:
CHECK_EQ(ws_lo & mask, res.d[0]);
CHECK_EQ(ws_hi & mask, res.d[1]);
break;
case ORI_B:
CHECK_EQ(ws_lo | mask, res.d[0]);
CHECK_EQ(ws_hi | mask, res.d[1]);
break;
case NORI_B:
CHECK_EQ(~(ws_lo | mask), res.d[0]);
CHECK_EQ(~(ws_hi | mask), res.d[1]);
break;
case XORI_B:
CHECK_EQ(ws_lo ^ mask, res.d[0]);
CHECK_EQ(ws_hi ^ mask, res.d[1]);
break;
case BMNZI_B:
CHECK_EQ((ws_lo & mask) | (wd_lo & ~mask), res.d[0]);
CHECK_EQ((ws_hi & mask) | (wd_hi & ~mask), res.d[1]);
break;
case BMZI_B:
CHECK_EQ((ws_lo & ~mask) | (wd_lo & mask), res.d[0]);
CHECK_EQ((ws_hi & ~mask) | (wd_hi & mask), res.d[1]);
break;
case BSELI_B:
CHECK_EQ((ws_lo & ~wd_lo) | (mask & wd_lo), res.d[0]);
CHECK_EQ((ws_hi & ~wd_hi) | (mask & wd_hi), res.d[1]);
break;
case SHF_B: {
struct ExpResShf exp_b[] = {
// i8, exp_lo, exp_hi
{0xffu, 0x11111111b9b9b9b9, 0xf7f7f7f7c8c8c8c8},
{0x0u, 0x62626262dfdfdfdf, 0xd6d6d6d6c8c8c8c8},
{0xe4u, 0xf35862e13e38f8b0, 0x4f41ffdef2bfe636},
{0x1bu, 0x1b756911c3d9a7b9, 0xae94a5f79c8aefc8},
{0xb1u, 0x662b6253e8c4df12, 0x0d3ad6803f8bc88b},
{0x4eu, 0x62e1f358f8b03e38, 0xffde4f41e636f2bf},
{0x27u, 0x1b697511c3a7d9b9, 0xaea594f79cef8ac8}};
for (size_t i = 0; i < sizeof(exp_b) / sizeof(ExpResShf); ++i) {
if (exp_b[i].i8 == i8) {
CHECK_EQ(exp_b[i].lo, res.d[0]);
CHECK_EQ(exp_b[i].hi, res.d[1]);
}
}
} break;
case SHF_H: {
struct ExpResShf exp_h[] = {
// i8, exp_lo, exp_hi
{0xffu, 0x1169116911691169, 0xf7a5f7a5f7a5f7a5},
{0x0u, 0x12df12df12df12df, 0x8bc88bc88bc88bc8},
{0xe4u, 0xf35862e13e38f8b0, 0x4f41ffdef2bfe636},
{0x1bu, 0xd9c3b9a7751b1169, 0x8a9cc8ef94aef7a5},
{0xb1u, 0x53622b6612dfc4e8, 0x80d63a0d8bc88b3f},
{0x4eu, 0x3e38f8b0f35862e1, 0xf2bfe6364f41ffde},
{0x27u, 0xd9c3751bb9a71169, 0x8a9c94aec8eff7a5}};
for (size_t i = 0; i < sizeof(exp_h) / sizeof(ExpResShf); ++i) {
if (exp_h[i].i8 == i8) {
CHECK_EQ(exp_h[i].lo, res.d[0]);
CHECK_EQ(exp_h[i].hi, res.d[1]);
}
}
} break;
case SHF_W: {
struct ExpResShf exp_w[] = {
// i8, exp_lo, exp_hi
{0xffu, 0xf7a594aef7a594ae, 0xf7a594aef7a594ae},
{0x0u, 0xc4e812dfc4e812df, 0xc4e812dfc4e812df},
{0xe4u, 0xf35862e13e38f8b0, 0x4f41ffdef2bfe636},
{0x1bu, 0xc8ef8a9cf7a594ae, 0xb9a7d9c31169751b},
{0xb1u, 0xc4e812df2b665362, 0x8b3f8bc83a0d80d6},
{0x4eu, 0x4f41ffdef2bfe636, 0xf35862e13e38f8b0},
{0x27u, 0x1169751bf7a594ae, 0xb9a7d9c3c8ef8a9c}};
for (size_t i = 0; i < sizeof(exp_w) / sizeof(ExpResShf); ++i) {
if (exp_w[i].i8 == i8) {
CHECK_EQ(exp_w[i].lo, res.d[0]);
CHECK_EQ(exp_w[i].hi, res.d[1]);
}
}
} break;
default:
UNREACHABLE();
}
}
struct TestCaseMsaI8 {
uint64_t input_lo;
uint64_t input_hi;
uint8_t i8;
};
TEST(MSA_andi_ori_nori_xori) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
struct TestCaseMsaI8 tc[] = {// input_lo, input_hi, i8
{0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c, 0xffu},
{0x2b665362c4e812df, 0x3a0d80d68b3f8bc8, 0x0u},
{0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c, 0x3bu},
{0x2b665362c4e812df, 0x3a0d80d68b3f8bc8, 0xd9u}};
for (size_t i = 0; i < sizeof(tc) / sizeof(TestCaseMsaI8); ++i) {
run_msa_i8(ANDI_B, tc[i].input_lo, tc[i].input_hi, tc[i].i8);
run_msa_i8(ORI_B, tc[i].input_lo, tc[i].input_hi, tc[i].i8);
run_msa_i8(NORI_B, tc[i].input_lo, tc[i].input_hi, tc[i].i8);
run_msa_i8(XORI_B, tc[i].input_lo, tc[i].input_hi, tc[i].i8);
}
}
TEST(MSA_bmnzi_bmzi_bseli) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
struct TestCaseMsaI8 tc[] = {// input_lo, input_hi, i8
{0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c, 0xffu},
{0x2b665362c4e812df, 0x3a0d80d68b3f8bc8, 0x0u},
{0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c, 0x3bu},
{0x2b665362c4e812df, 0x3a0d80d68b3f8bc8, 0xd9u}};
for (size_t i = 0; i < sizeof(tc) / sizeof(TestCaseMsaI8); ++i) {
run_msa_i8(BMNZI_B, tc[i].input_lo, tc[i].input_hi, tc[i].i8);
run_msa_i8(BMZI_B, tc[i].input_lo, tc[i].input_hi, tc[i].i8);
run_msa_i8(BSELI_B, tc[i].input_lo, tc[i].input_hi, tc[i].i8);
}
}
TEST(MSA_shf) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
struct TestCaseMsaI8 tc[] = {
// input_lo, input_hi, i8
{0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c, 0xffu}, // 3333
{0x2b665362c4e812df, 0x3a0d80d68b3f8bc8, 0x0u}, // 0000
{0xf35862e13e38f8b0, 0x4f41ffdef2bfe636, 0xe4u}, // 3210
{0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c, 0x1bu}, // 0123
{0x2b665362c4e812df, 0x3a0d80d68b3f8bc8, 0xb1u}, // 2301
{0xf35862e13e38f8b0, 0x4f41ffdef2bfe636, 0x4eu}, // 1032
{0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c, 0x27u} // 0213
};
for (size_t i = 0; i < sizeof(tc) / sizeof(TestCaseMsaI8); ++i) {
run_msa_i8(SHF_B, tc[i].input_lo, tc[i].input_hi, tc[i].i8);
run_msa_i8(SHF_H, tc[i].input_lo, tc[i].input_hi, tc[i].i8);
run_msa_i8(SHF_W, tc[i].input_lo, tc[i].input_hi, tc[i].i8);
}
}
struct TestCaseMsaI5 {
uint64_t ws_lo;
uint64_t ws_hi;
uint32_t i5;
};
template <typename InstFunc, typename OperFunc>
void run_msa_i5(struct TestCaseMsaI5* input, bool i5_sign_ext,
InstFunc GenerateI5InstructionFunc,
OperFunc GenerateOperationFunc) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
CpuFeatureScope fscope(&assm, MIPS_SIMD);
msa_reg_t res;
int32_t i5 =
i5_sign_ext ? static_cast<int32_t>(input->i5 << 27) >> 27 : input->i5;
load_uint64_elements_of_vector(assm, &(input->ws_lo), w0, t0, t1);
GenerateI5InstructionFunc(assm, i5);
store_uint64_elements_of_vector(assm, w2, a0);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F3 f = FUNCTION_CAST<F3>(code->entry());
(CALL_GENERATED_CODE(isolate, f, &res, 0, 0, 0, 0));
CHECK_EQ(GenerateOperationFunc(input->ws_lo, input->i5), res.d[0]);
CHECK_EQ(GenerateOperationFunc(input->ws_hi, input->i5), res.d[1]);
}
TEST(MSA_addvi_subvi) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
struct TestCaseMsaI5 tc[] = {
// ws_lo, ws_hi, i5
{0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c, 0x0000001f},
{0x2b665362c4e812df, 0x3a0d80d68b3f8bc8, 0x0000000f},
{0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c, 0x00000005},
{0x2b665362c4e812df, 0x3a0d80d68b3f8bc8, 0x00000010},
{0xffab807f807fffcd, 0x7f23ff80ff567f80, 0x0000000f},
{0x80ffefff7f12807f, 0x807f80ff7fdeff78, 0x00000010}};
#define ADDVI_DF(lanes, mask) \
uint64_t res = 0; \
for (int i = 0; i < lanes / 2; ++i) { \
int shift = (kMSARegSize / lanes) * i; \
res |= ((((ws >> shift) & mask) + i5) & mask) << shift; \
} \
return res
#define SUBVI_DF(lanes, mask) \
uint64_t res = 0; \
for (int i = 0; i < lanes / 2; ++i) { \
int shift = (kMSARegSize / lanes) * i; \
res |= ((((ws >> shift) & mask) - i5) & mask) << shift; \
} \
return res
for (size_t i = 0; i < sizeof(tc) / sizeof(TestCaseMsaI5); ++i) {
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ addvi_b(w2, w0, i5); },
[](uint64_t ws, uint32_t i5) { ADDVI_DF(kMSALanesByte, UINT8_MAX); });
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ addvi_h(w2, w0, i5); },
[](uint64_t ws, uint32_t i5) { ADDVI_DF(kMSALanesHalf, UINT16_MAX); });
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ addvi_w(w2, w0, i5); },
[](uint64_t ws, uint32_t i5) { ADDVI_DF(kMSALanesWord, UINT32_MAX); });
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ addvi_d(w2, w0, i5); },
[](uint64_t ws, uint32_t i5) { ADDVI_DF(kMSALanesDword, UINT64_MAX); });
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ subvi_b(w2, w0, i5); },
[](uint64_t ws, uint32_t i5) { SUBVI_DF(kMSALanesByte, UINT8_MAX); });
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ subvi_h(w2, w0, i5); },
[](uint64_t ws, uint32_t i5) { SUBVI_DF(kMSALanesHalf, UINT16_MAX); });
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ subvi_w(w2, w0, i5); },
[](uint64_t ws, uint32_t i5) { SUBVI_DF(kMSALanesWord, UINT32_MAX); });
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ subvi_d(w2, w0, i5); },
[](uint64_t ws, uint32_t i5) { SUBVI_DF(kMSALanesDword, UINT64_MAX); });
}
#undef ADDVI_DF
#undef SUBVI_DF
}
TEST(MSA_maxi_mini) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
struct TestCaseMsaI5 tc[] = {
// ws_lo, ws_hi, i5
{0x7f80ff3480ff7f00, 0x8d7fff80ff7f6780, 0x0000001f},
{0x7f80ff3480ff7f00, 0x8d7fff80ff7f6780, 0x0000000f},
{0x7f80ff3480ff7f00, 0x8d7fff80ff7f6780, 0x00000010},
{0x80007fff91daffff, 0x7fff8000ffff5678, 0x0000001f},
{0x80007fff91daffff, 0x7fff8000ffff5678, 0x0000000f},
{0x80007fff91daffff, 0x7fff8000ffff5678, 0x00000010},
{0x7fffffff80000000, 0x12345678ffffffff, 0x0000001f},
{0x7fffffff80000000, 0x12345678ffffffff, 0x0000000f},
{0x7fffffff80000000, 0x12345678ffffffff, 0x00000010},
{0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c, 0x0000001f},
{0x2b665362c4e812df, 0x3a0d80d68b3f8bc8, 0x0000000f},
{0xf35862e13e38f8b0, 0x4f41ffdef2bfe636, 0x00000010},
{0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c, 0x00000015},
{0x2b665362c4e812df, 0x3a0d80d68b3f8bc8, 0x00000009},
{0xf35862e13e38f8b0, 0x4f41ffdef2bfe636, 0x00000003}};
#define MAXI_MINI_S_DF(lanes, mask, func) \
[](uint64_t ws, uint32_t ui5) { \
uint64_t res = 0; \
int64_t i5 = ArithmeticShiftRight(static_cast<int64_t>(ui5) << 59, 59); \
int elem_size = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
int shift = elem_size * i; \
int64_t elem = \
static_cast<int64_t>(((ws >> shift) & mask) << (64 - elem_size)) >> \
(64 - elem_size); \
res |= static_cast<uint64_t>(func(elem, i5) & mask) << shift; \
} \
return res; \
}
#define MAXI_MINI_U_DF(lanes, mask, func) \
[](uint64_t ws, uint32_t ui5) { \
uint64_t res = 0; \
int elem_size = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
int shift = elem_size * i; \
uint64_t elem = (ws >> shift) & mask; \
res |= (func(elem, static_cast<uint64_t>(ui5)) & mask) << shift; \
} \
return res; \
}
for (size_t i = 0; i < sizeof(tc) / sizeof(TestCaseMsaI5); ++i) {
run_msa_i5(
&tc[i], true,
[](MacroAssembler& assm, int32_t i5) { __ maxi_s_b(w2, w0, i5); },
MAXI_MINI_S_DF(kMSALanesByte, UINT8_MAX, Max));
run_msa_i5(
&tc[i], true,
[](MacroAssembler& assm, int32_t i5) { __ maxi_s_h(w2, w0, i5); },
MAXI_MINI_S_DF(kMSALanesHalf, UINT16_MAX, Max));
run_msa_i5(
&tc[i], true,
[](MacroAssembler& assm, int32_t i5) { __ maxi_s_w(w2, w0, i5); },
MAXI_MINI_S_DF(kMSALanesWord, UINT32_MAX, Max));
run_msa_i5(
&tc[i], true,
[](MacroAssembler& assm, int32_t i5) { __ maxi_s_d(w2, w0, i5); },
MAXI_MINI_S_DF(kMSALanesDword, UINT64_MAX, Max));
run_msa_i5(
&tc[i], true,
[](MacroAssembler& assm, int32_t i5) { __ mini_s_b(w2, w0, i5); },
MAXI_MINI_S_DF(kMSALanesByte, UINT8_MAX, Min));
run_msa_i5(
&tc[i], true,
[](MacroAssembler& assm, int32_t i5) { __ mini_s_h(w2, w0, i5); },
MAXI_MINI_S_DF(kMSALanesHalf, UINT16_MAX, Min));
run_msa_i5(
&tc[i], true,
[](MacroAssembler& assm, int32_t i5) { __ mini_s_w(w2, w0, i5); },
MAXI_MINI_S_DF(kMSALanesWord, UINT32_MAX, Min));
run_msa_i5(
&tc[i], true,
[](MacroAssembler& assm, int32_t i5) { __ mini_s_d(w2, w0, i5); },
MAXI_MINI_S_DF(kMSALanesDword, UINT64_MAX, Min));
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ maxi_u_b(w2, w0, i5); },
MAXI_MINI_U_DF(kMSALanesByte, UINT8_MAX, Max));
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ maxi_u_h(w2, w0, i5); },
MAXI_MINI_U_DF(kMSALanesHalf, UINT16_MAX, Max));
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ maxi_u_w(w2, w0, i5); },
MAXI_MINI_U_DF(kMSALanesWord, UINT32_MAX, Max));
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ maxi_u_d(w2, w0, i5); },
MAXI_MINI_U_DF(kMSALanesDword, UINT64_MAX, Max));
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ mini_u_b(w2, w0, i5); },
MAXI_MINI_U_DF(kMSALanesByte, UINT8_MAX, Min));
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ mini_u_h(w2, w0, i5); },
MAXI_MINI_U_DF(kMSALanesHalf, UINT16_MAX, Min));
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ mini_u_w(w2, w0, i5); },
MAXI_MINI_U_DF(kMSALanesWord, UINT32_MAX, Min));
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ mini_u_d(w2, w0, i5); },
MAXI_MINI_U_DF(kMSALanesDword, UINT64_MAX, Min));
}
#undef MAXI_MINI_S_DF
#undef MAXI_MINI_U_DF
}
TEST(MSA_ceqi_clti_clei) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
struct TestCaseMsaI5 tc[] = {
{0xff69751bb9a7d9c3, 0xf7a594aec8ff8a9c, 0x0000001f},
{0xe669ffffb9a7d9c3, 0xf7a594aeffff8a9c, 0x0000001f},
{0xffffffffb9a7d9c3, 0xf7a594aeffffffff, 0x0000001f},
{0x2b0b5362c4e812df, 0x3a0d80d68b3f0bc8, 0x0000000b},
{0x2b66000bc4e812df, 0x3a0d000b8b3f8bc8, 0x0000000b},
{0x0000000bc4e812df, 0x3a0d80d60000000b, 0x0000000b},
{0xf38062e13e38f8b0, 0x8041ffdef2bfe636, 0x00000010},
{0xf35880003e38f8b0, 0x4f41ffdef2bf8000, 0x00000010},
{0xf35862e180000000, 0x80000000f2bfe636, 0x00000010},
{0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c, 0x00000015},
{0x2b665362c4e812df, 0x3a0d80d68b3f8bc8, 0x00000009},
{0xf30062e13e38f800, 0x4f00ffdef2bf0036, 0x00000000}};
#define CEQI_CLTI_CLEI_S_DF(lanes, mask, func) \
[](uint64_t ws, uint32_t ui5) { \
uint64_t res = 0; \
int elem_size = kMSARegSize / lanes; \
int64_t i5 = ArithmeticShiftRight(static_cast<int64_t>(ui5) << 59, 59); \
for (int i = 0; i < lanes / 2; ++i) { \
int shift = elem_size * i; \
int64_t elem = \
static_cast<int64_t>(((ws >> shift) & mask) << (64 - elem_size)) >> \
(64 - elem_size); \
res |= static_cast<uint64_t>((func)&mask) << shift; \
} \
return res; \
}
#define CEQI_CLTI_CLEI_U_DF(lanes, mask, func) \
[](uint64_t ws, uint64_t ui5) { \
uint64_t res = 0; \
int elem_size = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
int shift = elem_size * i; \
uint64_t elem = (ws >> shift) & mask; \
res |= ((func)&mask) << shift; \
} \
return res; \
}
for (size_t i = 0; i < sizeof(tc) / sizeof(TestCaseMsaI5); ++i) {
run_msa_i5(&tc[i], true,
[](MacroAssembler& assm, int32_t i5) { __ ceqi_b(w2, w0, i5); },
CEQI_CLTI_CLEI_S_DF(kMSALanesByte, UINT8_MAX,
!Compare(elem, i5) ? -1u : 0u));
run_msa_i5(&tc[i], true,
[](MacroAssembler& assm, int32_t i5) { __ ceqi_h(w2, w0, i5); },
CEQI_CLTI_CLEI_S_DF(kMSALanesHalf, UINT16_MAX,
!Compare(elem, i5) ? -1u : 0u));
run_msa_i5(&tc[i], true,
[](MacroAssembler& assm, int32_t i5) { __ ceqi_w(w2, w0, i5); },
CEQI_CLTI_CLEI_S_DF(kMSALanesWord, UINT32_MAX,
!Compare(elem, i5) ? -1u : 0u));
run_msa_i5(&tc[i], true,
[](MacroAssembler& assm, int32_t i5) { __ ceqi_d(w2, w0, i5); },
CEQI_CLTI_CLEI_S_DF(kMSALanesDword, UINT64_MAX,
!Compare(elem, i5) ? -1u : 0u));
run_msa_i5(
&tc[i], true,
[](MacroAssembler& assm, int32_t i5) { __ clti_s_b(w2, w0, i5); },
CEQI_CLTI_CLEI_S_DF(kMSALanesByte, UINT8_MAX,
(Compare(elem, i5) == -1) ? -1u : 0u));
run_msa_i5(
&tc[i], true,
[](MacroAssembler& assm, int32_t i5) { __ clti_s_h(w2, w0, i5); },
CEQI_CLTI_CLEI_S_DF(kMSALanesHalf, UINT16_MAX,
(Compare(elem, i5) == -1) ? -1u : 0u));
run_msa_i5(
&tc[i], true,
[](MacroAssembler& assm, int32_t i5) { __ clti_s_w(w2, w0, i5); },
CEQI_CLTI_CLEI_S_DF(kMSALanesWord, UINT32_MAX,
(Compare(elem, i5) == -1) ? -1u : 0u));
run_msa_i5(
&tc[i], true,
[](MacroAssembler& assm, int32_t i5) { __ clti_s_d(w2, w0, i5); },
CEQI_CLTI_CLEI_S_DF(kMSALanesDword, UINT64_MAX,
(Compare(elem, i5) == -1) ? -1ull : 0ull));
run_msa_i5(
&tc[i], true,
[](MacroAssembler& assm, int32_t i5) { __ clei_s_b(w2, w0, i5); },
CEQI_CLTI_CLEI_S_DF(kMSALanesByte, UINT8_MAX,
(Compare(elem, i5) != 1) ? -1u : 0u));
run_msa_i5(
&tc[i], true,
[](MacroAssembler& assm, int32_t i5) { __ clei_s_h(w2, w0, i5); },
CEQI_CLTI_CLEI_S_DF(kMSALanesHalf, UINT16_MAX,
(Compare(elem, i5) != 1) ? -1u : 0u));
run_msa_i5(
&tc[i], true,
[](MacroAssembler& assm, int32_t i5) { __ clei_s_w(w2, w0, i5); },
CEQI_CLTI_CLEI_S_DF(kMSALanesWord, UINT32_MAX,
(Compare(elem, i5) != 1) ? -1u : 0u));
run_msa_i5(
&tc[i], true,
[](MacroAssembler& assm, int32_t i5) { __ clei_s_d(w2, w0, i5); },
CEQI_CLTI_CLEI_S_DF(kMSALanesDword, UINT64_MAX,
(Compare(elem, i5) != 1) ? -1ull : 0ull));
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ clti_u_b(w2, w0, i5); },
CEQI_CLTI_CLEI_U_DF(kMSALanesByte, UINT8_MAX,
(Compare(elem, ui5) == -1) ? -1ull : 0ull));
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ clti_u_h(w2, w0, i5); },
CEQI_CLTI_CLEI_U_DF(kMSALanesHalf, UINT16_MAX,
(Compare(elem, ui5) == -1) ? -1ull : 0ull));
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ clti_u_w(w2, w0, i5); },
CEQI_CLTI_CLEI_U_DF(kMSALanesWord, UINT32_MAX,
(Compare(elem, ui5) == -1) ? -1ull : 0ull));
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ clti_u_d(w2, w0, i5); },
CEQI_CLTI_CLEI_U_DF(kMSALanesDword, UINT64_MAX,
(Compare(elem, ui5) == -1) ? -1ull : 0ull));
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ clei_u_b(w2, w0, i5); },
CEQI_CLTI_CLEI_U_DF(kMSALanesByte, UINT8_MAX,
(Compare(elem, ui5) != 1) ? -1ull : 0ull));
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ clei_u_h(w2, w0, i5); },
CEQI_CLTI_CLEI_U_DF(kMSALanesHalf, UINT16_MAX,
(Compare(elem, ui5) != 1) ? -1ull : 0ull));
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ clei_u_w(w2, w0, i5); },
CEQI_CLTI_CLEI_U_DF(kMSALanesWord, UINT32_MAX,
(Compare(elem, ui5) != 1) ? -1ull : 0ull));
run_msa_i5(
&tc[i], false,
[](MacroAssembler& assm, int32_t i5) { __ clei_u_d(w2, w0, i5); },
CEQI_CLTI_CLEI_U_DF(kMSALanesDword, UINT64_MAX,
(Compare(elem, ui5) != 1) ? -1ull : 0ull));
}
#undef CEQI_CLTI_CLEI_S_DF
#undef CEQI_CLTI_CLEI_U_DF
}
struct TestCaseMsa2R {
uint64_t ws_lo;
uint64_t ws_hi;
uint64_t exp_res_lo;
uint64_t exp_res_hi;
};
template <typename Func, typename FuncLoad, typename FuncStore>
void run_msa_2r(const struct TestCaseMsa2R* input,
Func Generate2RInstructionFunc,
FuncLoad load_elements_of_vector,
FuncStore store_elements_of_vector) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
CpuFeatureScope fscope(&assm, MIPS_SIMD);
msa_reg_t res;
load_elements_of_vector(assm, reinterpret_cast<const uint64_t*>(input), w0,
t0, t1);
Generate2RInstructionFunc(assm);
store_elements_of_vector(assm, w2, a0);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F3 f = FUNCTION_CAST<F3>(code->entry());
(CALL_GENERATED_CODE(isolate, f, &res, 0, 0, 0, 0));
if (store_elements_of_vector == store_uint64_elements_of_vector) {
CHECK_EQ(input->exp_res_lo, res.d[0]);
CHECK_EQ(input->exp_res_hi, res.d[1]);
} else if (store_elements_of_vector == store_uint32_elements_of_vector) {
const uint32_t* exp_res =
reinterpret_cast<const uint32_t*>(&input->exp_res_lo);
CHECK_EQ(exp_res[0], res.w[0]);
CHECK_EQ(exp_res[1], res.w[1]);
CHECK_EQ(exp_res[2], res.w[2]);
CHECK_EQ(exp_res[3], res.w[3]);
}
}
TEST(MSA_pcnt) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
struct TestCaseMsa2R tc_b[] = {// ws_lo, ws_hi, exp_res_lo, exp_res_hi
{0x0000000000000000, 0x0000000000000000, 0, 0},
{0xffffffffffffffff, 0xffffffffffffffff,
0x0808080808080808, 0x0808080808080808},
{0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c,
0x0204050405050504, 0x0704030503070304},
{0x2b665362c4e812df, 0x3a0d80d68b3f8bc8,
0x0404040303040207, 0x0403010504060403},
{0xf35862e13e38f8b0, 0x4f41ffdef2bfe636,
0x0603030405030503, 0x0502080605070504}};
struct TestCaseMsa2R tc_h[] = {// ws_lo, ws_hi, exp_res_lo, exp_res_hi
{0x0000000000000000, 0x0000000000000000, 0, 0},
{0xffffffffffffffff, 0xffffffffffffffff,
0x0010001000100010, 0x0010001000100010},
{0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c,
0x00060009000a0009, 0x000b0008000a0007},
{0x2b665362c4e812df, 0x3a0d80d68b3f8bc8,
0x0008000700070009, 0x00070006000a0007},
{0xf35862e13e38f8b0, 0x4f41ffdef2bfe636,
0x0009000700080008, 0x0007000e000c0009}};
struct TestCaseMsa2R tc_w[] = {// ws_lo, ws_hi, exp_res_lo, exp_res_hi
{0x0000000000000000, 0x0000000000000000, 0, 0},
{0xffffffffffffffff, 0xffffffffffffffff,
0x0000002000000020, 0x0000002000000020},
{0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c,
0x0000000f00000013, 0x0000001300000011},
{0x2b665362c4e812df, 0x3a0d80d68b3f8bc8,
0x0000000f00000010, 0x0000000d00000011},
{0xf35862e13e38f8b0, 0x4f41ffdef2bfe636,
0x0000001000000010, 0x0000001500000015}};
struct TestCaseMsa2R tc_d[] = {
// ws_lo, ws_hi, exp_res_lo, exp_res_hi
{0x0000000000000000, 0x0000000000000000, 0, 0},
{0xffffffffffffffff, 0xffffffffffffffff, 0x40, 0x40},
{0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c, 0x22, 0x24},
{0x2b665362c4e812df, 0x3a0d80d68b3f8bc8, 0x1f, 0x1e},
{0xf35862e13e38f8b0, 0x4f41ffdef2bfe636, 0x20, 0x2a}};
for (size_t i = 0; i < sizeof(tc_b) / sizeof(TestCaseMsa2R); ++i) {
run_msa_2r(&tc_b[i], [](MacroAssembler& assm) { __ pcnt_b(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
run_msa_2r(&tc_h[i], [](MacroAssembler& assm) { __ pcnt_h(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
run_msa_2r(&tc_w[i], [](MacroAssembler& assm) { __ pcnt_w(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
run_msa_2r(&tc_d[i], [](MacroAssembler& assm) { __ pcnt_d(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
}
}
TEST(MSA_nlzc) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
struct TestCaseMsa2R tc_b[] = {// ws_lo, ws_hi, exp_res_lo, exp_res_hi
{0x0000000000000000, 0x0000000000000000,
0x0808080808080808, 0x0808080808080808},
{0xffffffffffffffff, 0xffffffffffffffff, 0, 0},
{0x1169350b07030100, 0x7f011402381f0a6c,
0x0301020405060708, 0x0107030602030401},
{0x010806003478121f, 0x03013016073f7b08,
0x0704050802010303, 0x0607020305020104},
{0x0168321100083803, 0x07113f03013f1676,
0x0701020308040206, 0x0503020607020301}};
struct TestCaseMsa2R tc_h[] = {// ws_lo, ws_hi, exp_res_lo, exp_res_hi
{0x0000000000000000, 0x0000000000000000,
0x0010001000100010, 0x0010001000100010},
{0xffffffffffffffff, 0xffffffffffffffff, 0, 0},
{0x00010007000a003c, 0x37a5001e00010002,
0x000f000d000c000a, 0x0002000b000f000e},
{0x0026066200780edf, 0x003d0003000f00c8,
0x000a000500090004, 0x000a000e000c0008},
{0x335807e100480030, 0x01410fde12bf5636,
0x000200050009000a, 0x0007000400030001}};
struct TestCaseMsa2R tc_w[] = {// ws_lo, ws_hi, exp_res_lo, exp_res_hi
{0x0000000000000000, 0x0000000000000000,
0x0000002000000020, 0x0000002000000020},
{0xffffffffffffffff, 0xffffffffffffffff, 0, 0},
{0x00000005000007c3, 0x000014ae00006a9c,
0x0000001d00000015, 0x0000001300000011},
{0x00009362000112df, 0x000380d6003f8bc8,
0x000000100000000f, 0x0000000e0000000a},
{0x135862e17e38f8b0, 0x0061ffde03bfe636,
0x0000000300000001, 0x0000000900000006}};
struct TestCaseMsa2R tc_d[] = {
// ws_lo, ws_hi, exp_res_lo, exp_res_hi
{0x0000000000000000, 0x0000000000000000, 0x40, 0x40},
{0xffffffffffffffff, 0xffffffffffffffff, 0, 0},
{0x000000000000014e, 0x00000000000176da, 0x37, 0x2f},
{0x00000062c4e812df, 0x000065d68b3f8bc8, 0x19, 0x11},
{0x00000000e338f8b0, 0x0754534acab32654, 0x20, 0x5}};
for (size_t i = 0; i < sizeof(tc_b) / sizeof(TestCaseMsa2R); ++i) {
run_msa_2r(&tc_b[i], [](MacroAssembler& assm) { __ nlzc_b(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
run_msa_2r(&tc_h[i], [](MacroAssembler& assm) { __ nlzc_h(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
run_msa_2r(&tc_w[i], [](MacroAssembler& assm) { __ nlzc_w(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
run_msa_2r(&tc_d[i], [](MacroAssembler& assm) { __ nlzc_d(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
}
}
TEST(MSA_nloc) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
struct TestCaseMsa2R tc_b[] = {// ws_lo, ws_hi, exp_res_lo, exp_res_hi
{0xffffffffffffffff, 0xffffffffffffffff,
0x0808080808080808, 0x0808080808080808},
{0x0000000000000000, 0x0000000000000000, 0, 0},
{0xEE96CAF4F8FCFEFF, 0x80FEEBFDC7E0F593,
0x0301020405060708, 0x0107030602030401},
{0xFEF7F9FFCB87EDE0, 0xFCFECFE9F8C084F7,
0x0704050802010303, 0x0607020305020104},
{0xFE97CDEEFFF7C7FC, 0xF8EEC0FCFEC0E989,
0x0701020308040206, 0x0503020607020301}};
struct TestCaseMsa2R tc_h[] = {// ws_lo, ws_hi, exp_res_lo, exp_res_hi
{0xffffffffffffffff, 0xffffffffffffffff,
0x0010001000100010, 0x0010001000100010},
{0x0000000000000000, 0x0000000000000000, 0, 0},
{0xFFFEFFF8FFF5FFC3, 0xC85AFFE1FFFEFFFD,
0x000f000d000c000a, 0x0002000b000f000e},
{0xFFD9F99DFF87F120, 0xFFC2FFFCFFF0FF37,
0x000a000500090004, 0x000a000e000c0008},
{0xCCA7F81EFFB7FFCF, 0xFEBEF021ED40A9C9,
0x000200050009000a, 0x0007000400030001}};
struct TestCaseMsa2R tc_w[] = {// ws_lo, ws_hi, exp_res_lo, exp_res_hi
{0xffffffffffffffff, 0xffffffffffffffff,
0x0000002000000020, 0x0000002000000020},
{0x0000000000000000, 0x0000000000000000, 0, 0},
{0xFFFFFFFAFFFFF83C, 0xFFFFEB51FFFF9563,
0x0000001d00000015, 0x0000001300000011},
{0xFFFF6C9DFFFEED20, 0xFFFC7F29FFC07437,
0x000000100000000f, 0x0000000e0000000a},
{0xECA79D1E81C7074F, 0xFF9E0021FC4019C9,
0x0000000300000001, 0x0000000900000006}};
struct TestCaseMsa2R tc_d[] = {
// ws_lo, ws_hi, exp_res_lo, exp_res_hi
{0xffffffffffffffff, 0xffffffffffffffff, 0x40, 0x40},
{0x0000000000000000, 0x0000000000000000, 0, 0},
{0xFFFFFFFFFFFFFEB1, 0xFFFFFFFFFFFE8925, 0x37, 0x2f},
{0xFFFFFF9D3B17ED20, 0xFFFF9A2974C07437, 0x19, 0x11},
{0xFFFFFFFF1CC7074F, 0xF8ABACB5354CD9AB, 0x20, 0x5}};
for (size_t i = 0; i < sizeof(tc_b) / sizeof(TestCaseMsa2R); ++i) {
run_msa_2r(&tc_b[i], [](MacroAssembler& assm) { __ nloc_b(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
run_msa_2r(&tc_h[i], [](MacroAssembler& assm) { __ nloc_h(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
run_msa_2r(&tc_w[i], [](MacroAssembler& assm) { __ nloc_w(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
run_msa_2r(&tc_d[i], [](MacroAssembler& assm) { __ nloc_d(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
}
}
struct TestCaseMsa2RF_F_U {
float ws1;
float ws2;
float ws3;
float ws4;
uint32_t exp_res_1;
uint32_t exp_res_2;
uint32_t exp_res_3;
uint32_t exp_res_4;
};
struct TestCaseMsa2RF_D_U {
double ws1;
double ws2;
uint64_t exp_res_1;
uint64_t exp_res_2;
};
TEST(MSA_fclass) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
#define BIT(n) (0x1 << n)
#define SNAN BIT(0)
#define QNAN BIT(1)
#define NEG_INFINITY BIT((2))
#define NEG_NORMAL BIT(3)
#define NEG_SUBNORMAL BIT(4)
#define NEG_ZERO BIT(5)
#define POS_INFINITY BIT(6)
#define POS_NORMAL BIT(7)
#define POS_SUBNORMAL BIT(8)
#define POS_ZERO BIT(9)
const float inf_float = std::numeric_limits<float>::infinity();
const double inf_double = std::numeric_limits<double>::infinity();
const struct TestCaseMsa2RF_F_U tc_s[] = {
{1.f, -0.00001, 208e10f, -34.8e-30f, POS_NORMAL, NEG_NORMAL, POS_NORMAL,
NEG_NORMAL},
{inf_float, -inf_float, 0, -0.f, POS_INFINITY, NEG_INFINITY, POS_ZERO,
NEG_ZERO},
{3.036e-40f, -6.392e-43f, 1.41e-45f, -1.17e-38f, POS_SUBNORMAL,
NEG_SUBNORMAL, POS_SUBNORMAL, NEG_SUBNORMAL}};
const struct TestCaseMsa2RF_D_U tc_d[] = {
{1., -0.00000001, POS_NORMAL, NEG_NORMAL},
{208e10, -34.8e-300, POS_NORMAL, NEG_NORMAL},
{inf_double, -inf_double, POS_INFINITY, NEG_INFINITY},
{0, -0., POS_ZERO, NEG_ZERO},
{1.036e-308, -6.392e-309, POS_SUBNORMAL, NEG_SUBNORMAL},
{1.41e-323, -3.17e208, POS_SUBNORMAL, NEG_NORMAL}};
for (size_t i = 0; i < sizeof(tc_s) / sizeof(TestCaseMsa2RF_F_U); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_s[i]),
[](MacroAssembler& assm) { __ fclass_w(w2, w0); },
load_uint32_elements_of_vector, store_uint32_elements_of_vector);
}
for (size_t i = 0; i < sizeof(tc_d) / sizeof(TestCaseMsa2RF_D_U); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_d[i]),
[](MacroAssembler& assm) { __ fclass_d(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
}
#undef BIT
#undef SNAN
#undef QNAN
#undef NEG_INFINITY
#undef NEG_NORMAL
#undef NEG_SUBNORMAL
#undef NEG_ZERO
#undef POS_INFINITY
#undef POS_NORMAL
#undef POS_SUBNORMAL
#undef POS_ZERO
}
struct TestCaseMsa2RF_F_I {
float ws1;
float ws2;
float ws3;
float ws4;
int32_t exp_res_1;
int32_t exp_res_2;
int32_t exp_res_3;
int32_t exp_res_4;
};
struct TestCaseMsa2RF_D_I {
double ws1;
double ws2;
int64_t exp_res_1;
int64_t exp_res_2;
};
TEST(MSA_ftrunc_s) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
const float inf_float = std::numeric_limits<float>::infinity();
const float qNaN_float = std::numeric_limits<float>::quiet_NaN();
const double inf_double = std::numeric_limits<double>::infinity();
const double qNaN_double = std::numeric_limits<double>::quiet_NaN();
const int32_t max_int32 = std::numeric_limits<int32_t>::max();
const int32_t min_int32 = std::numeric_limits<int32_t>::min();
const int64_t max_int64 = std::numeric_limits<int64_t>::max();
const int64_t min_int64 = std::numeric_limits<int64_t>::min();
const struct TestCaseMsa2RF_F_I tc_s[] = {
{inf_float, 2.345f, -324.9235f, 30004.51f, max_int32, 2, -324, 30004},
{-inf_float, -0.983f, 0.0832f, static_cast<float>(max_int32) * 3.f,
min_int32, 0, 0, max_int32},
{-23.125f, qNaN_float, 2 * static_cast<float>(min_int32), -0.f, -23, 0,
min_int32, 0}};
const struct TestCaseMsa2RF_D_I tc_d[] = {
{inf_double, 2.345, max_int64, 2},
{-324.9235, 246569139.51, -324, 246569139},
{-inf_double, -0.983, min_int64, 0},
{0.0832, 6 * static_cast<double>(max_int64), 0, max_int64},
{-21453889872.94, qNaN_double, -21453889872, 0},
{2 * static_cast<double>(min_int64), -0., min_int64, 0}};
for (size_t i = 0; i < sizeof(tc_s) / sizeof(TestCaseMsa2RF_F_I); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_s[i]),
[](MacroAssembler& assm) { __ ftrunc_s_w(w2, w0); },
load_uint32_elements_of_vector, store_uint32_elements_of_vector);
}
for (size_t i = 0; i < sizeof(tc_d) / sizeof(TestCaseMsa2RF_D_I); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_d[i]),
[](MacroAssembler& assm) { __ ftrunc_s_d(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
}
}
TEST(MSA_ftrunc_u) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
const float inf_float = std::numeric_limits<float>::infinity();
const float qNaN_float = std::numeric_limits<float>::quiet_NaN();
const double inf_double = std::numeric_limits<double>::infinity();
const double qNaN_double = std::numeric_limits<double>::quiet_NaN();
const uint32_t max_uint32 = std::numeric_limits<uint32_t>::max();
const uint64_t max_uint64 = std::numeric_limits<uint64_t>::max();
const struct TestCaseMsa2RF_F_U tc_s[] = {
{inf_float, 2.345f, -324.9235f, 30004.51f, max_uint32, 2, 0, 30004},
{-inf_float, 0.983f, 0.0832f, static_cast<float>(max_uint32) * 3., 0, 0,
0, max_uint32},
{23.125f, qNaN_float, -0.982, -0.f, 23, 0, 0, 0}};
const struct TestCaseMsa2RF_D_U tc_d[] = {
{inf_double, 2.345, max_uint64, 2},
{-324.9235, 246569139.51, 0, 246569139},
{-inf_double, -0.983, 0, 0},
{0.0832, 6 * static_cast<double>(max_uint64), 0, max_uint64},
{21453889872.94, qNaN_double, 21453889872, 0},
{0.9889, -0., 0, 0}};
for (size_t i = 0; i < sizeof(tc_s) / sizeof(TestCaseMsa2RF_F_U); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_s[i]),
[](MacroAssembler& assm) { __ ftrunc_u_w(w2, w0); },
load_uint32_elements_of_vector, store_uint32_elements_of_vector);
}
for (size_t i = 0; i < sizeof(tc_d) / sizeof(TestCaseMsa2RF_D_U); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_d[i]),
[](MacroAssembler& assm) { __ ftrunc_u_d(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
}
}
struct TestCaseMsa2RF_F_F {
float ws1;
float ws2;
float ws3;
float ws4;
float exp_res_1;
float exp_res_2;
float exp_res_3;
float exp_res_4;
};
struct TestCaseMsa2RF_D_D {
double ws1;
double ws2;
double exp_res_1;
double exp_res_2;
};
TEST(MSA_fsqrt) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
const float inf_float = std::numeric_limits<float>::infinity();
const double inf_double = std::numeric_limits<double>::infinity();
const struct TestCaseMsa2RF_F_F tc_s[] = {
{81.f, 576.f, inf_float, -0.f, 9.f, 24.f, inf_float, -0.f}};
const struct TestCaseMsa2RF_D_D tc_d[] = {{81., inf_double, 9., inf_double},
{331776., -0., 576, -0.}};
for (size_t i = 0; i < sizeof(tc_s) / sizeof(TestCaseMsa2RF_F_F); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_s[i]),
[](MacroAssembler& assm) { __ fsqrt_w(w2, w0); },
load_uint32_elements_of_vector, store_uint32_elements_of_vector);
}
for (size_t i = 0; i < sizeof(tc_d) / sizeof(TestCaseMsa2RF_D_D); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_d[i]),
[](MacroAssembler& assm) { __ fsqrt_d(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
}
}
TEST(MSA_frsqrt) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
const float inf_float = std::numeric_limits<float>::infinity();
const double inf_double = std::numeric_limits<double>::infinity();
const struct TestCaseMsa2RF_F_F tc_s[] = {
{81.f, 576.f, inf_float, -0.f, 1.f / 9.f, 1.f / 24.f, 0.f, -inf_float},
{0.f, 1.f / 576.f, 1.f / 81.f, 1.f / 4.f, inf_float, 24.f, 9.f, 2.f}};
const struct TestCaseMsa2RF_D_D tc_d[] = {
{81., inf_double, 1. / 9., 0.},
{331776., -0., 1. / 576., -inf_double},
{0., 1. / 81, inf_double, 9.}};
for (size_t i = 0; i < sizeof(tc_s) / sizeof(TestCaseMsa2RF_F_F); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_s[i]),
[](MacroAssembler& assm) { __ frsqrt_w(w2, w0); },
load_uint32_elements_of_vector, store_uint32_elements_of_vector);
}
for (size_t i = 0; i < sizeof(tc_d) / sizeof(TestCaseMsa2RF_D_D); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_d[i]),
[](MacroAssembler& assm) { __ frsqrt_d(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
}
}
TEST(MSA_frcp) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
const float inf_float = std::numeric_limits<float>::infinity();
const double inf_double = std::numeric_limits<double>::infinity();
const struct TestCaseMsa2RF_F_F tc_s[] = {
{12.f, 576.f, inf_float, -0.f, 1.f / 12.f, 1.f / 576.f, 0.f, -inf_float},
{0.f, 1.f / 576.f, -inf_float, 1.f / 400.f, inf_float, 576.f, -0.f,
400.f}};
const struct TestCaseMsa2RF_D_D tc_d[] = {
{81., inf_double, 1. / 81., 0.},
{331777., -0., 1. / 331777., -inf_double},
{0., 1. / 80, inf_double, 80.},
{1. / 40000., -inf_double, 40000., -0.}};
for (size_t i = 0; i < sizeof(tc_s) / sizeof(TestCaseMsa2RF_F_F); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_s[i]),
[](MacroAssembler& assm) { __ frcp_w(w2, w0); },
load_uint32_elements_of_vector, store_uint32_elements_of_vector);
}
for (size_t i = 0; i < sizeof(tc_d) / sizeof(TestCaseMsa2RF_D_D); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_d[i]),
[](MacroAssembler& assm) { __ frcp_d(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
}
}
void test_frint_s(size_t data_size, TestCaseMsa2RF_F_F tc_d[],
int rounding_mode) {
for (size_t i = 0; i < data_size / sizeof(TestCaseMsa2RF_F_F); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_d[i]),
[&rounding_mode](MacroAssembler& assm) {
MSAControlRegister msareg = {kMSACSRRegister};
__ li(t0, static_cast<uint32_t>(rounding_mode));
__ cfcmsa(t1, msareg);
__ ctcmsa(msareg, t0);
__ frint_w(w2, w0);
__ ctcmsa(msareg, t1);
},
load_uint32_elements_of_vector, store_uint32_elements_of_vector);
}
}
void test_frint_d(size_t data_size, TestCaseMsa2RF_D_D tc_d[],
int rounding_mode) {
for (size_t i = 0; i < data_size / sizeof(TestCaseMsa2RF_D_D); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_d[i]),
[&rounding_mode](MacroAssembler& assm) {
MSAControlRegister msareg = {kMSACSRRegister};
__ li(t0, static_cast<uint32_t>(rounding_mode));
__ cfcmsa(t1, msareg);
__ ctcmsa(msareg, t0);
__ frint_d(w2, w0);
__ ctcmsa(msareg, t1);
},
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
}
}
TEST(MSA_frint) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
struct TestCaseMsa2RF_F_F tc_s1[] = {
{0.f, 4.51f, 1.49f, -12.51f, 0.f, 5.f, 1.f, -13.f},
{-1.32f, -23.38f, 2.8f, -32.6f, -1.f, -23.f, 3.f, -33.f}};
struct TestCaseMsa2RF_D_D tc_d1[] = {{0., 4.51, 0., 5.},
{1.49, -12.51, 1., -13.},
{-1.32, -23.38, -1., -23.},
{2.8, -32.6, 3., -33.}};
test_frint_s(sizeof(tc_s1), tc_s1, kRoundToNearest);
test_frint_d(sizeof(tc_d1), tc_d1, kRoundToNearest);
struct TestCaseMsa2RF_F_F tc_s2[] = {
{0.f, 4.5f, 1.49f, -12.51f, 0.f, 4.f, 1.f, -12.f},
{-1.f, -23.38f, 2.8f, -32.6f, -1.f, -23.f, 2.f, -32.f}};
struct TestCaseMsa2RF_D_D tc_d2[] = {{0., 4.5, 0., 4.},
{1.49, -12.51, 1., -12.},
{-1., -23.38, -1., -23.},
{2.8, -32.6, 2., -32.}};
test_frint_s(sizeof(tc_s2), tc_s2, kRoundToZero);
test_frint_d(sizeof(tc_d2), tc_d2, kRoundToZero);
struct TestCaseMsa2RF_F_F tc_s3[] = {
{0.f, 4.5f, 1.49f, -12.51f, 0.f, 5.f, 2.f, -12.f},
{-1.f, -23.38f, 2.8f, -32.6f, -1.f, -23.f, 3.f, -32.f}};
struct TestCaseMsa2RF_D_D tc_d3[] = {{0., 4.5, 0., 5.},
{1.49, -12.51, 2., -12.},
{-1., -23.38, -1., -23.},
{2.8, -32.6, 3., -32.}};
test_frint_s(sizeof(tc_s3), tc_s3, kRoundToPlusInf);
test_frint_d(sizeof(tc_d3), tc_d3, kRoundToPlusInf);
struct TestCaseMsa2RF_F_F tc_s4[] = {
{0.f, 4.5f, 1.49f, -12.51f, 0.f, 4.f, 1.f, -13.f},
{-1.f, -23.38f, 2.8f, -32.6f, -1.f, -24.f, 2.f, -33.f}};
struct TestCaseMsa2RF_D_D tc_d4[] = {{0., 4.5, 0., 4.},
{1.49, -12.51, 1., -13.},
{-1., -23.38, -1., -24.},
{2.8, -32.6, 2., -33.}};
test_frint_s(sizeof(tc_s4), tc_s4, kRoundToMinusInf);
test_frint_d(sizeof(tc_d4), tc_d4, kRoundToMinusInf);
}
TEST(MSA_flog2) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
const float inf_float = std::numeric_limits<float>::infinity();
const double inf_double = std::numeric_limits<double>::infinity();
struct TestCaseMsa2RF_F_F tc_s[] = {
{std::ldexp(0.58f, -48), std::ldexp(0.5f, 110), std::ldexp(1.11f, -130),
inf_float, -49.f, 109.f, -130.f, inf_float},
{0.f, -0.f, std::ldexp(0.89f, -12), std::ldexp(0.32f, 126), -inf_float,
-inf_float, -13.f, 124.f}};
struct TestCaseMsa2RF_D_D tc_d[] = {
{std::ldexp(0.58, -48), std::ldexp(0.5, 110), -49., 109.},
{std::ldexp(1.11, -1050), inf_double, -1050., inf_double},
{0., -0., -inf_double, -inf_double},
{std::ldexp(0.32, 1021), std::ldexp(1.23, -123), 1019., -123.}};
for (size_t i = 0; i < sizeof(tc_s) / sizeof(TestCaseMsa2RF_F_F); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_s[i]),
[](MacroAssembler& assm) { __ flog2_w(w2, w0); },
load_uint32_elements_of_vector, store_uint32_elements_of_vector);
}
for (size_t i = 0; i < sizeof(tc_d) / sizeof(TestCaseMsa2RF_D_D); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_d[i]),
[](MacroAssembler& assm) { __ flog2_d(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
}
}
void test_ftint_s_s(size_t data_size, TestCaseMsa2RF_F_I tc_d[],
int rounding_mode) {
for (size_t i = 0; i < data_size / sizeof(TestCaseMsa2RF_F_I); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_d[i]),
[&rounding_mode](MacroAssembler& assm) {
MSAControlRegister msareg = {kMSACSRRegister};
__ li(t0, static_cast<uint32_t>(rounding_mode));
__ cfcmsa(t1, msareg);
__ ctcmsa(msareg, t0);
__ ftint_s_w(w2, w0);
__ ctcmsa(msareg, t1);
},
load_uint32_elements_of_vector, store_uint32_elements_of_vector);
}
}
void test_ftint_s_d(size_t data_size, TestCaseMsa2RF_D_I tc_d[],
int rounding_mode) {
for (size_t i = 0; i < data_size / sizeof(TestCaseMsa2RF_D_I); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_d[i]),
[&rounding_mode](MacroAssembler& assm) {
MSAControlRegister msareg = {kMSACSRRegister};
__ li(t0, static_cast<uint32_t>(rounding_mode));
__ cfcmsa(t1, msareg);
__ ctcmsa(msareg, t0);
__ ftint_s_d(w2, w0);
__ ctcmsa(msareg, t1);
},
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
}
}
TEST(MSA_ftint_s) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
const float inf_float = std::numeric_limits<float>::infinity();
const double inf_double = std::numeric_limits<double>::infinity();
const int32_t int32_max = std::numeric_limits<int32_t>::max();
const int32_t int32_min = std::numeric_limits<int32_t>::min();
const int64_t int64_max = std::numeric_limits<int64_t>::max();
const int64_t int64_min = std::numeric_limits<int64_t>::min();
struct TestCaseMsa2RF_F_I tc_s1[] = {
{0.f, 4.51f, 1.49f, -12.51f, 0, 5, 1, -13},
{-0.32f, -23.38f, 2.8f, -32.6f, 0, -23, 3, -33},
{inf_float, -inf_float, 3.f * int32_min, 4.f * int32_max, int32_max,
int32_min, int32_min, int32_max}};
struct TestCaseMsa2RF_D_I tc_d1[] = {
{0., 4.51, 0, 5},
{1.49, -12.51, 1, -13},
{-0.32, -23.38, 0, -23},
{2.8, -32.6, 3, -33},
{inf_double, -inf_double, int64_max, int64_min},
{33.23 * int64_min, 4000. * int64_max, int64_min, int64_max}};
test_ftint_s_s(sizeof(tc_s1), tc_s1, kRoundToNearest);
test_ftint_s_d(sizeof(tc_d1), tc_d1, kRoundToNearest);
struct TestCaseMsa2RF_F_I tc_s2[] = {
{0.f, 4.5f, 1.49f, -12.51f, 0, 4, 1, -12},
{-0.f, -23.38f, 2.8f, -32.6f, -0, -23, 2, -32},
{inf_float, -inf_float, 3.f * int32_min, 4.f * int32_max, int32_max,
int32_min, int32_min, int32_max}};
struct TestCaseMsa2RF_D_I tc_d2[] = {
{0., 4.5, 0, 4},
{1.49, -12.51, 1, -12},
{-0., -23.38, -0, -23},
{2.8, -32.6, 2, -32},
{inf_double, -inf_double, int64_max, int64_min},
{33.23 * int64_min, 4000. * int64_max, int64_min, int64_max}};
test_ftint_s_s(sizeof(tc_s2), tc_s2, kRoundToZero);
test_ftint_s_d(sizeof(tc_d2), tc_d2, kRoundToZero);
struct TestCaseMsa2RF_F_I tc_s3[] = {
{0.f, 4.5f, 1.49f, -12.51f, 0, 5, 2, -12},
{-0.f, -23.38f, 2.8f, -32.6f, -0, -23, 3, -32},
{inf_float, -inf_float, 3.f * int32_min, 4.f * int32_max, int32_max,
int32_min, int32_min, int32_max}};
struct TestCaseMsa2RF_D_I tc_d3[] = {
{0., 4.5, 0, 5},
{1.49, -12.51, 2, -12},
{-0., -23.38, -0, -23},
{2.8, -32.6, 3, -32},
{inf_double, -inf_double, int64_max, int64_min},
{33.23 * int64_min, 4000. * int64_max, int64_min, int64_max}};
test_ftint_s_s(sizeof(tc_s3), tc_s3, kRoundToPlusInf);
test_ftint_s_d(sizeof(tc_d3), tc_d3, kRoundToPlusInf);
struct TestCaseMsa2RF_F_I tc_s4[] = {
{0.f, 4.5f, 1.49f, -12.51f, 0, 4, 1, -13},
{-0.f, -23.38f, 2.8f, -32.6f, -0, -24, 2, -33},
{inf_float, -inf_float, 3.f * int32_min, 4.f * int32_max, int32_max,
int32_min, int32_min, int32_max}};
struct TestCaseMsa2RF_D_I tc_d4[] = {
{0., 4.5, 0, 4},
{1.49, -12.51, 1, -13},
{-0., -23.38, -0, -24},
{2.8, -32.6, 2, -33},
{inf_double, -inf_double, int64_max, int64_min},
{33.23 * int64_min, 4000. * int64_max, int64_min, int64_max}};
test_ftint_s_s(sizeof(tc_s4), tc_s4, kRoundToMinusInf);
test_ftint_s_d(sizeof(tc_d4), tc_d4, kRoundToMinusInf);
}
void test_ftint_u_s(size_t data_size, TestCaseMsa2RF_F_U tc_d[],
int rounding_mode) {
for (size_t i = 0; i < data_size / sizeof(TestCaseMsa2RF_F_U); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_d[i]),
[&rounding_mode](MacroAssembler& assm) {
MSAControlRegister msareg = {kMSACSRRegister};
__ li(t0, static_cast<uint32_t>(rounding_mode));
__ cfcmsa(t1, msareg);
__ ctcmsa(msareg, t0);
__ ftint_u_w(w2, w0);
__ ctcmsa(msareg, t1);
},
load_uint32_elements_of_vector, store_uint32_elements_of_vector);
}
}
void test_ftint_u_d(size_t data_size, TestCaseMsa2RF_D_U tc_d[],
int rounding_mode) {
for (size_t i = 0; i < data_size / sizeof(TestCaseMsa2RF_D_U); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_d[i]),
[&rounding_mode](MacroAssembler& assm) {
MSAControlRegister msareg = {kMSACSRRegister};
__ li(t0, static_cast<uint32_t>(rounding_mode));
__ cfcmsa(t1, msareg);
__ ctcmsa(msareg, t0);
__ ftint_u_d(w2, w0);
__ ctcmsa(msareg, t1);
},
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
}
}
TEST(MSA_ftint_u) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
const float inf_float = std::numeric_limits<float>::infinity();
const double inf_double = std::numeric_limits<double>::infinity();
const uint32_t uint32_max = std::numeric_limits<uint32_t>::max();
const uint64_t uint64_max = std::numeric_limits<uint64_t>::max();
struct TestCaseMsa2RF_F_U tc_s1[] = {
{0.f, 4.51f, 1.49f, -12.51f, 0, 5, 1, 0},
{-0.32f, 23.38f, 2.8f, 32.6f, 0, 23, 3, 33},
{inf_float, -inf_float, 0, 4.f * uint32_max, uint32_max, 0, 0,
uint32_max}};
struct TestCaseMsa2RF_D_U tc_d1[] = {
{0., 4.51, 0, 5},
{1.49, -12.51, 1, 0},
{-0.32, 23.38, 0, 23},
{2.8, 32.6, 3, 33},
{inf_double, -inf_double, uint64_max, 0},
{-0., 4000. * uint64_max, 0, uint64_max}};
test_ftint_u_s(sizeof(tc_s1), tc_s1, kRoundToNearest);
test_ftint_u_d(sizeof(tc_d1), tc_d1, kRoundToNearest);
struct TestCaseMsa2RF_F_U tc_s2[] = {
{0.f, 4.5f, 1.49f, -12.51f, 0, 4, 1, 0},
{-0.f, 23.38f, 2.8f, 32.6f, 0, 23, 2, 32},
{inf_float, -inf_float, 0., 4.f * uint32_max, uint32_max, 0, 0,
uint32_max}};
struct TestCaseMsa2RF_D_U tc_d2[] = {
{0., 4.5, 0, 4},
{1.49, -12.51, 1, 0},
{-0., 23.38, 0, 23},
{2.8, 32.6, 2, 32},
{inf_double, -inf_double, uint64_max, 0},
{-0.2345, 4000. * uint64_max, 0, uint64_max}};
test_ftint_u_s(sizeof(tc_s2), tc_s2, kRoundToZero);
test_ftint_u_d(sizeof(tc_d2), tc_d2, kRoundToZero);
struct TestCaseMsa2RF_F_U tc_s3[] = {
{0.f, 4.5f, 1.49f, -12.51f, 0, 5, 2, 0},
{-0.f, 23.38f, 2.8f, 32.6f, 0, 24, 3, 33},
{inf_float, -inf_float, 0, 4.f * uint32_max, uint32_max, 0, 0,
uint32_max}};
struct TestCaseMsa2RF_D_U tc_d3[] = {
{0., 4.5, 0, 5},
{1.49, -12.51, 2, 0},
{-0., 23.38, -0, 24},
{2.8, 32.6, 3, 33},
{inf_double, -inf_double, uint64_max, 0},
{-0.5252, 4000. * uint64_max, 0, uint64_max}};
test_ftint_u_s(sizeof(tc_s3), tc_s3, kRoundToPlusInf);
test_ftint_u_d(sizeof(tc_d3), tc_d3, kRoundToPlusInf);
struct TestCaseMsa2RF_F_U tc_s4[] = {
{0.f, 4.5f, 1.49f, -12.51f, 0, 4, 1, 0},
{-0.f, 23.38f, 2.8f, 32.6f, 0, 23, 2, 32},
{inf_float, -inf_float, 0, 4.f * uint32_max, uint32_max, 0, 0,
uint32_max}};
struct TestCaseMsa2RF_D_U tc_d4[] = {
{0., 4.5, 0, 4},
{1.49, -12.51, 1, 0},
{-0., 23.38, -0, 23},
{2.8, 32.6, 2, 32},
{inf_double, -inf_double, uint64_max, 0},
{-0.098797, 4000. * uint64_max, 0, uint64_max}};
test_ftint_u_s(sizeof(tc_s4), tc_s4, kRoundToMinusInf);
test_ftint_u_d(sizeof(tc_d4), tc_d4, kRoundToMinusInf);
}
struct TestCaseMsa2RF_U_F {
uint32_t ws1;
uint32_t ws2;
uint32_t ws3;
uint32_t ws4;
float exp_res_1;
float exp_res_2;
float exp_res_3;
float exp_res_4;
};
struct TestCaseMsa2RF_U_D {
uint64_t ws1;
uint64_t ws2;
double exp_res_1;
double exp_res_2;
};
TEST(MSA_ffint_u) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
struct TestCaseMsa2RF_U_F tc_s[] = {
{0, 345, 234, 1000, 0.f, 345.f, 234.f, 1000.f}};
struct TestCaseMsa2RF_U_D tc_d[] = {{0, 345, 0., 345.},
{234, 1000, 234., 1000.}};
for (size_t i = 0; i < sizeof(tc_s) / sizeof(TestCaseMsa2RF_U_F); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_s[i]),
[](MacroAssembler& assm) { __ ffint_u_w(w2, w0); },
load_uint32_elements_of_vector, store_uint32_elements_of_vector);
}
for (size_t i = 0; i < sizeof(tc_d) / sizeof(TestCaseMsa2RF_U_D); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_d[i]),
[](MacroAssembler& assm) { __ ffint_u_d(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
}
}
struct TestCaseMsa2RF_I_F {
int32_t ws1;
int32_t ws2;
int32_t ws3;
int32_t ws4;
float exp_res_1;
float exp_res_2;
float exp_res_3;
float exp_res_4;
};
struct TestCaseMsa2RF_I_D {
int64_t ws1;
int64_t ws2;
double exp_res_1;
double exp_res_2;
};
TEST(MSA_ffint_s) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
struct TestCaseMsa2RF_I_F tc_s[] = {
{0, 345, -234, 1000, 0.f, 345.f, -234.f, 1000.f}};
struct TestCaseMsa2RF_I_D tc_d[] = {{0, 345, 0., 345.},
{-234, 1000, -234., 1000.}};
for (size_t i = 0; i < sizeof(tc_s) / sizeof(TestCaseMsa2RF_I_F); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_s[i]),
[](MacroAssembler& assm) { __ ffint_s_w(w2, w0); },
load_uint32_elements_of_vector, store_uint32_elements_of_vector);
}
for (size_t i = 0; i < sizeof(tc_d) / sizeof(TestCaseMsa2RF_I_D); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_d[i]),
[](MacroAssembler& assm) { __ ffint_s_d(w2, w0); },
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
}
}
struct TestCaseMsa2RF_U16_F {
uint16_t ws1;
uint16_t ws2;
uint16_t ws3;
uint16_t ws4;
uint16_t ws5;
uint16_t ws6;
uint16_t ws7;
uint16_t ws8;
float exp_res_1;
float exp_res_2;
float exp_res_3;
float exp_res_4;
};
struct TestCaseMsa2RF_F_D {
float ws1;
float ws2;
float ws3;
float ws4;
double exp_res_1;
double exp_res_2;
};
TEST(MSA_fexupl) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
const float inf_float = std::numeric_limits<float>::infinity();
const double inf_double = std::numeric_limits<double>::infinity();
struct TestCaseMsa2RF_U16_F tc_s[] = {
{1, 2, 0x7c00, 0x0c00, 0, 0x7c00, 0xfc00, 0x8000, 0.f, inf_float,
-inf_float, -0.f},
{0xfc00, 0xffff, 0x00ff, 0x8000, 0x81fe, 0x8000, 0x0345, 0xaaaa,
-3.0398368835e-5f, -0.f, 4.9889088e-5f, -5.2062988281e-2f},
{3, 4, 0x5555, 6, 0x2aaa, 0x8700, 0x7777, 0x6a8b, 5.2062988281e-2f,
-1.06811523458e-4f, 3.0576e4f, 3.35e3f}};
struct TestCaseMsa2RF_F_D tc_d[] = {
{0.f, 123.456f, inf_float, -0.f, inf_double, -0.},
{-inf_float, -3.f, 0.f, -inf_float, 0., -inf_double},
{2.3f, 3., 1.37747639043129518071e-41f, -3.22084585277826e35f,
1.37747639043129518071e-41, -3.22084585277826e35}};
for (size_t i = 0; i < sizeof(tc_s) / sizeof(TestCaseMsa2RF_U16_F); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_s[i]),
[](MacroAssembler& assm) { __ fexupl_w(w2, w0); },
load_uint16_elements_of_vector, store_uint32_elements_of_vector);
}
for (size_t i = 0; i < sizeof(tc_d) / sizeof(TestCaseMsa2RF_F_D); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_d[i]),
[](MacroAssembler& assm) { __ fexupl_d(w2, w0); },
load_uint32_elements_of_vector, store_uint64_elements_of_vector);
}
}
TEST(MSA_fexupr) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
const float inf_float = std::numeric_limits<float>::infinity();
const double inf_double = std::numeric_limits<double>::infinity();
struct TestCaseMsa2RF_U16_F tc_s[] = {
{0, 0x7c00, 0xfc00, 0x8000, 1, 2, 0x7c00, 0x0c00, 0.f, inf_float,
-inf_float, -0.f},
{0x81fe, 0x8000, 0x0345, 0xaaaa, 0xfc00, 0xffff, 0x00ff, 0x8000,
-3.0398368835e-5f, -0.f, 4.9889088e-5f, -5.2062988281e-2f},
{0x2aaa, 0x8700, 0x7777, 0x6a8b, 3, 4, 0x5555, 6, 5.2062988281e-2f,
-1.06811523458e-4f, 3.0576e4f, 3.35e3f}};
struct TestCaseMsa2RF_F_D tc_d[] = {
{inf_float, -0.f, 0.f, 123.456f, inf_double, -0.},
{0.f, -inf_float, -inf_float, -3.f, 0., -inf_double},
{1.37747639043129518071e-41f, -3.22084585277826e35f, 2.3f, 3.,
1.37747639043129518071e-41, -3.22084585277826e35}};
for (size_t i = 0; i < sizeof(tc_s) / sizeof(TestCaseMsa2RF_U16_F); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_s[i]),
[](MacroAssembler& assm) { __ fexupr_w(w2, w0); },
load_uint16_elements_of_vector, store_uint32_elements_of_vector);
}
for (size_t i = 0; i < sizeof(tc_d) / sizeof(TestCaseMsa2RF_F_D); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_d[i]),
[](MacroAssembler& assm) { __ fexupr_d(w2, w0); },
load_uint32_elements_of_vector, store_uint64_elements_of_vector);
}
}
struct TestCaseMsa2RF_U32_D {
uint32_t ws1;
uint32_t ws2;
uint32_t ws3;
uint32_t ws4;
double exp_res_1;
double exp_res_2;
};
TEST(MSA_ffql) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
struct TestCaseMsa2RF_U16_F tc_s[] = {{0, 3, 0xffff, 0x8000, 0x8000, 0xe000,
0x0FF0, 0, -1.f, -0.25f,
0.12451171875f, 0.f}};
struct TestCaseMsa2RF_U32_D tc_d[] = {
{0, 45, 0x80000000, 0xe0000000, -1., -0.25},
{0x28379, 0xaaaa5555, 0x024903d3, 0, 17.853239085525274277e-3, 0.}};
for (size_t i = 0; i < sizeof(tc_s) / sizeof(TestCaseMsa2RF_U16_F); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_s[i]),
[](MacroAssembler& assm) { __ ffql_w(w2, w0); },
load_uint16_elements_of_vector, store_uint32_elements_of_vector);
}
for (size_t i = 0; i < sizeof(tc_d) / sizeof(TestCaseMsa2RF_U32_D); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_d[i]),
[](MacroAssembler& assm) { __ ffql_d(w2, w0); },
load_uint32_elements_of_vector, store_uint64_elements_of_vector);
}
}
TEST(MSA_ffqr) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
struct TestCaseMsa2RF_U16_F tc_s[] = {{0x8000, 0xe000, 0x0FF0, 0, 0, 3,
0xffff, 0x8000, -1.f, -0.25f,
0.12451171875f, 0.f}};
struct TestCaseMsa2RF_U32_D tc_d[] = {
{0x80000000, 0xe0000000, 0, 45, -1., -0.25},
{0x024903d3, 0, 0x28379, 0xaaaa5555, 17.853239085525274277e-3, 0.}};
for (size_t i = 0; i < sizeof(tc_s) / sizeof(TestCaseMsa2RF_U16_F); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_s[i]),
[](MacroAssembler& assm) { __ ffqr_w(w2, w0); },
load_uint16_elements_of_vector, store_uint32_elements_of_vector);
}
for (size_t i = 0; i < sizeof(tc_d) / sizeof(TestCaseMsa2RF_U32_D); ++i) {
run_msa_2r(reinterpret_cast<const TestCaseMsa2R*>(&tc_d[i]),
[](MacroAssembler& assm) { __ ffqr_d(w2, w0); },
load_uint32_elements_of_vector, store_uint64_elements_of_vector);
}
}
struct TestCaseMsaVector {
uint64_t wd_lo;
uint64_t wd_hi;
uint64_t ws_lo;
uint64_t ws_hi;
uint64_t wt_lo;
uint64_t wt_hi;
};
template <typename InstFunc, typename OperFunc>
void run_msa_vector(struct TestCaseMsaVector* input,
InstFunc GenerateVectorInstructionFunc,
OperFunc GenerateOperationFunc) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
CpuFeatureScope fscope(&assm, MIPS_SIMD);
msa_reg_t res;
load_uint64_elements_of_vector(assm, &(input->ws_lo), w0, t0, t1);
load_uint64_elements_of_vector(assm, &(input->wt_lo), w2, t0, t1);
load_uint64_elements_of_vector(assm, &(input->wd_lo), w4, t0, t1);
GenerateVectorInstructionFunc(assm);
store_uint64_elements_of_vector(assm, w4, a0);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F3 f = FUNCTION_CAST<F3>(code->entry());
(CALL_GENERATED_CODE(isolate, f, &res, 0, 0, 0, 0));
CHECK_EQ(GenerateOperationFunc(input->wd_lo, input->ws_lo, input->wt_lo),
res.d[0]);
CHECK_EQ(GenerateOperationFunc(input->wd_hi, input->ws_hi, input->wt_hi),
res.d[1]);
}
TEST(MSA_vector) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
struct TestCaseMsaVector tc[] = {
// wd_lo, wd_hi, ws_lo, ws_hi, wt_lo, wt_hi
{0xf35862e13e38f8b0, 0x4f41ffdef2bfe636, 0xdcd39d91f9057627,
0x64be4f6dbe9caa51, 0x6b23de1a687d9cb9, 0x49547aad691da4ca},
{0xf35862e13e38f8b0, 0x4f41ffdef2bfe636, 0x401614523d830549,
0xd7c46d613f50eddd, 0x52284cbc60a1562b, 0x1756ed510d8849cd},
{0xf35862e13e38f8b0, 0x4f41ffdef2bfe636, 0xd6e2d2ebcb40d72f,
0x13a619afce67b079, 0x36cce284343e40f9, 0xb4e8f44fd148bf7f}};
for (size_t i = 0; i < sizeof(tc) / sizeof(TestCaseMsaVector); ++i) {
run_msa_vector(
&tc[i], [](MacroAssembler& assm) { __ and_v(w4, w0, w2); },
[](uint64_t wd, uint64_t ws, uint64_t wt) { return ws & wt; });
run_msa_vector(
&tc[i], [](MacroAssembler& assm) { __ or_v(w4, w0, w2); },
[](uint64_t wd, uint64_t ws, uint64_t wt) { return ws | wt; });
run_msa_vector(
&tc[i], [](MacroAssembler& assm) { __ nor_v(w4, w0, w2); },
[](uint64_t wd, uint64_t ws, uint64_t wt) { return ~(ws | wt); });
run_msa_vector(
&tc[i], [](MacroAssembler& assm) { __ xor_v(w4, w0, w2); },
[](uint64_t wd, uint64_t ws, uint64_t wt) { return ws ^ wt; });
run_msa_vector(&tc[i], [](MacroAssembler& assm) { __ bmnz_v(w4, w0, w2); },
[](uint64_t wd, uint64_t ws, uint64_t wt) {
return (ws & wt) | (wd & ~wt);
});
run_msa_vector(&tc[i], [](MacroAssembler& assm) { __ bmz_v(w4, w0, w2); },
[](uint64_t wd, uint64_t ws, uint64_t wt) {
return (ws & ~wt) | (wd & wt);
});
run_msa_vector(&tc[i], [](MacroAssembler& assm) { __ bsel_v(w4, w0, w2); },
[](uint64_t wd, uint64_t ws, uint64_t wt) {
return (ws & ~wd) | (wt & wd);
});
}
}
struct TestCaseMsaBit {
uint64_t wd_lo;
uint64_t wd_hi;
uint64_t ws_lo;
uint64_t ws_hi;
uint32_t m;
};
template <typename InstFunc, typename OperFunc>
void run_msa_bit(struct TestCaseMsaBit* input, InstFunc GenerateInstructionFunc,
OperFunc GenerateOperationFunc) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
CpuFeatureScope fscope(&assm, MIPS_SIMD);
msa_reg_t res;
load_uint64_elements_of_vector(assm, &(input->ws_lo), w0, t0, t1);
load_uint64_elements_of_vector(assm, &(input->wd_lo), w2, t0, t1);
GenerateInstructionFunc(assm, input->m);
store_uint64_elements_of_vector(assm, w2, a0);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F3 f = FUNCTION_CAST<F3>(code->entry());
(CALL_GENERATED_CODE(isolate, f, &res, 0, 0, 0, 0));
CHECK_EQ(GenerateOperationFunc(input->wd_lo, input->ws_lo, input->m),
res.d[0]);
CHECK_EQ(GenerateOperationFunc(input->wd_hi, input->ws_hi, input->m),
res.d[1]);
}
TEST(MSA_slli_srai_srli) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
struct TestCaseMsaBit tc[] = {
// wd_lo, wd_hi ws_lo, ws_hi, m
{0, 0, 0xf35862e13e38f8b0, 0x4f41ffdef2bfe636, 3},
{0, 0, 0x64be4f6dbe9caa51, 0x6b23de1a687d9cb9, 5},
{0, 0, 0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c, 9},
{0, 0, 0x2b665362c4e812df, 0x3a0d80d68b3f8bc8, 13},
{0, 0, 0x566be7ba4365b70a, 0x01ebbc1937d76cb4, 21},
{0, 0, 0x380e2deb9d3f8aae, 0x017e0de0bcc6ca42, 30},
{0, 0, 0xa46a3a9bcb43f4e5, 0x1c62c8473bdfcffb, 45},
{0, 0, 0xf6759d85f23b5a2b, 0x5c042ae42c6d12c1, 61}};
#define SLLI_SRLI_DF(lanes, mask, func) \
[](uint64_t wd, uint64_t ws, uint32_t m) { \
uint64_t res = 0; \
int elem_size = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
int shift = elem_size * i; \
uint64_t elem = (ws >> shift) & mask; \
res |= ((func)&mask) << shift; \
} \
return res; \
}
#define SRAI_DF(lanes, mask, func) \
[](uint64_t wd, uint64_t ws, uint32_t m) { \
uint64_t res = 0; \
int elem_size = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
int shift = elem_size * i; \
int64_t elem = \
static_cast<int64_t>(((ws >> shift) & mask) << (64 - elem_size)) >> \
(64 - elem_size); \
res |= static_cast<uint64_t>((func)&mask) << shift; \
} \
return res; \
}
for (size_t i = 0; i < sizeof(tc) / sizeof(TestCaseMsaBit); ++i) {
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ slli_b(w2, w0, m % 8); },
SLLI_SRLI_DF(kMSALanesByte, UINT8_MAX, (elem << (m % elem_size))));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ slli_h(w2, w0, m % 16); },
SLLI_SRLI_DF(kMSALanesHalf, UINT16_MAX, (elem << (m % elem_size))));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ slli_w(w2, w0, m % 32); },
SLLI_SRLI_DF(kMSALanesWord, UINT32_MAX, (elem << (m % elem_size))));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ slli_d(w2, w0, m % 64); },
SLLI_SRLI_DF(kMSALanesDword, UINT64_MAX, (elem << (m % elem_size))));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ srli_b(w2, w0, m % 8); },
SLLI_SRLI_DF(kMSALanesByte, UINT8_MAX, (elem >> (m % elem_size))));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ srli_h(w2, w0, m % 16); },
SLLI_SRLI_DF(kMSALanesHalf, UINT16_MAX, (elem >> (m % elem_size))));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ srli_w(w2, w0, m % 32); },
SLLI_SRLI_DF(kMSALanesWord, UINT32_MAX, (elem >> (m % elem_size))));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ srli_d(w2, w0, m % 64); },
SLLI_SRLI_DF(kMSALanesDword, UINT64_MAX, (elem >> (m % elem_size))));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ srlri_b(w2, w0, m % 8); },
SLLI_SRLI_DF(
kMSALanesByte, UINT8_MAX,
(elem >> (m % elem_size)) + ((elem >> (m % elem_size - 1)) & 0x1)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ srlri_h(w2, w0, m % 16); },
SLLI_SRLI_DF(
kMSALanesHalf, UINT16_MAX,
(elem >> (m % elem_size)) + ((elem >> (m % elem_size - 1)) & 0x1)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ srlri_w(w2, w0, m % 32); },
SLLI_SRLI_DF(
kMSALanesWord, UINT32_MAX,
(elem >> (m % elem_size)) + ((elem >> (m % elem_size - 1)) & 0x1)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ srlri_d(w2, w0, m % 64); },
SLLI_SRLI_DF(
kMSALanesDword, UINT64_MAX,
(elem >> (m % elem_size)) + ((elem >> (m % elem_size - 1)) & 0x1)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ srai_b(w2, w0, m % 8); },
SRAI_DF(kMSALanesByte, UINT8_MAX,
ArithmeticShiftRight(elem, m % elem_size)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ srai_h(w2, w0, m % 16); },
SRAI_DF(kMSALanesHalf, UINT16_MAX,
ArithmeticShiftRight(elem, m % elem_size)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ srai_w(w2, w0, m % 32); },
SRAI_DF(kMSALanesWord, UINT32_MAX,
ArithmeticShiftRight(elem, m % elem_size)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ srai_d(w2, w0, m % 64); },
SRAI_DF(kMSALanesDword, UINT64_MAX,
ArithmeticShiftRight(elem, m % elem_size)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ srari_b(w2, w0, m % 8); },
SRAI_DF(kMSALanesByte, UINT8_MAX,
ArithmeticShiftRight(elem, m % elem_size) +
((elem >> (m % elem_size - 1)) & 0x1)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ srari_h(w2, w0, m % 16); },
SRAI_DF(kMSALanesHalf, UINT16_MAX,
ArithmeticShiftRight(elem, m % elem_size) +
((elem >> (m % elem_size - 1)) & 0x1)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ srari_w(w2, w0, m % 32); },
SRAI_DF(kMSALanesWord, UINT32_MAX,
ArithmeticShiftRight(elem, m % elem_size) +
((elem >> (m % elem_size - 1)) & 0x1)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ srari_d(w2, w0, m % 64); },
SRAI_DF(kMSALanesDword, UINT64_MAX,
ArithmeticShiftRight(elem, m % elem_size) +
((elem >> (m % elem_size - 1)) & 0x1)));
}
#undef SLLI_SRLI_DF
#undef SRAI_DF
}
TEST(MSA_bclri_bseti_bnegi) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
struct TestCaseMsaBit tc[] = {
// wd_lo, wd_hi, ws_lo, ws_hi, m
{0, 0, 0xf35862e13e38f8b0, 0x4f41ffdef2bfe636, 3},
{0, 0, 0x64be4f6dbe9caa51, 0x6b23de1a687d9cb9, 5},
{0, 0, 0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c, 9},
{0, 0, 0x2b665362c4e812df, 0x3a0d80d68b3f8bc8, 13},
{0, 0, 0x566be7ba4365b70a, 0x01ebbc1937d76cb4, 21},
{0, 0, 0x380e2deb9d3f8aae, 0x017e0de0bcc6ca42, 30},
{0, 0, 0xa46a3a9bcb43f4e5, 0x1c62c8473bdfcffb, 45},
{0, 0, 0xf6759d85f23b5a2b, 0x5c042ae42c6d12c1, 61}};
#define BCLRI_BSETI_BNEGI_DF(lanes, mask, func) \
[](uint64_t wd, uint64_t ws, uint32_t m) { \
uint64_t res = 0; \
int elem_size = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
int shift = elem_size * i; \
uint64_t elem = (ws >> shift) & mask; \
res |= ((func)&mask) << shift; \
} \
return res; \
}
for (size_t i = 0; i < sizeof(tc) / sizeof(TestCaseMsaBit); ++i) {
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ bclri_b(w2, w0, m % 8); },
BCLRI_BSETI_BNEGI_DF(kMSALanesByte, UINT8_MAX,
(~(1ull << (m % elem_size)) & elem)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ bclri_h(w2, w0, m % 16); },
BCLRI_BSETI_BNEGI_DF(kMSALanesHalf, UINT16_MAX,
(~(1ull << (m % elem_size)) & elem)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ bclri_w(w2, w0, m % 32); },
BCLRI_BSETI_BNEGI_DF(kMSALanesWord, UINT32_MAX,
(~(1ull << (m % elem_size)) & elem)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ bclri_d(w2, w0, m % 64); },
BCLRI_BSETI_BNEGI_DF(kMSALanesDword, UINT64_MAX,
(~(1ull << (m % elem_size)) & elem)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ bseti_b(w2, w0, m % 8); },
BCLRI_BSETI_BNEGI_DF(kMSALanesByte, UINT8_MAX,
((1ull << (m % elem_size)) | elem)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ bseti_h(w2, w0, m % 16); },
BCLRI_BSETI_BNEGI_DF(kMSALanesHalf, UINT16_MAX,
((1ull << (m % elem_size)) | elem)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ bseti_w(w2, w0, m % 32); },
BCLRI_BSETI_BNEGI_DF(kMSALanesWord, UINT32_MAX,
((1ull << (m % elem_size)) | elem)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ bseti_d(w2, w0, m % 64); },
BCLRI_BSETI_BNEGI_DF(kMSALanesDword, UINT64_MAX,
((1ull << (m % elem_size)) | elem)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ bnegi_b(w2, w0, m % 8); },
BCLRI_BSETI_BNEGI_DF(kMSALanesByte, UINT8_MAX,
((1ull << (m % elem_size)) ^ elem)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ bnegi_h(w2, w0, m % 16); },
BCLRI_BSETI_BNEGI_DF(kMSALanesHalf, UINT16_MAX,
((1ull << (m % elem_size)) ^ elem)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ bnegi_w(w2, w0, m % 32); },
BCLRI_BSETI_BNEGI_DF(kMSALanesWord, UINT32_MAX,
((1ull << (m % elem_size)) ^ elem)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ bnegi_d(w2, w0, m % 64); },
BCLRI_BSETI_BNEGI_DF(kMSALanesDword, UINT64_MAX,
((1ull << (m % elem_size)) ^ elem)));
}
#undef BCLRI_BSETI_BNEGI_DF
}
TEST(MSA_binsli_binsri) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
struct TestCaseMsaBit tc[] = {// wd_lo, wd_hi, ws_lo, ws_hi, m
{0x53f4457553bbd5b4, 0x5fb8250eacc296b2,
0xf35862e13e38f8b0, 0x4f41ffdef2bfe636, 3},
{0xf61bfdb0f312e6fc, 0xc9437568dd1ea925,
0x64be4f6dbe9caa51, 0x6b23de1a687d9cb9, 5},
{0x53f4457553bbd5b4, 0x5fb8250eacc296b2,
0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c, 9},
{0xf61bfdb0f312e6fc, 0xc9437568dd1ea925,
0x2b665362c4e812df, 0x3a0d80d68b3f8bc8, 13},
{0x53f4457553bbd5b4, 0x5fb8250eacc296b2,
0x566be7ba4365b70a, 0x01ebbc1937d76cb4, 21},
{0xf61bfdb0f312e6fc, 0xc9437568dd1ea925,
0x380e2deb9d3f8aae, 0x017e0de0bcc6ca42, 30},
{0x53f4457553bbd5b4, 0x5fb8250eacc296b2,
0xa46a3a9bcb43f4e5, 0x1c62c8473bdfcffb, 45},
{0xf61bfdb0f312e6fc, 0xc9437568dd1ea925,
0xf6759d85f23b5a2b, 0x5c042ae42c6d12c1, 61}};
#define BINSLI_BINSRI_DF(lanes, mask, func) \
[](uint64_t wd, uint64_t ws, uint32_t m) { \
uint64_t res = 0; \
int elem_size = kMSARegSize / lanes; \
int bits = m % elem_size + 1; \
for (int i = 0; i < lanes / 2; ++i) { \
int shift = elem_size * i; \
uint64_t ws_elem = (ws >> shift) & mask; \
if (bits == elem_size) { \
res |= (ws_elem & mask) << shift; \
} else { \
uint64_t r_mask = (1ull << bits) - 1; \
uint64_t l_mask = r_mask << (elem_size - bits); \
USE(l_mask); \
uint64_t wd_elem = (wd >> shift) & mask; \
res |= ((func)&mask) << shift; \
} \
} \
return res; \
}
for (size_t i = 0; i < sizeof(tc) / sizeof(TestCaseMsaBit); ++i) {
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ binsli_b(w2, w0, m % 8); },
BINSLI_BINSRI_DF(kMSALanesByte, UINT8_MAX,
((ws_elem & l_mask) | (wd_elem & ~l_mask))));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ binsli_h(w2, w0, m % 16); },
BINSLI_BINSRI_DF(kMSALanesHalf, UINT16_MAX,
((ws_elem & l_mask) | (wd_elem & ~l_mask))));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ binsli_w(w2, w0, m % 32); },
BINSLI_BINSRI_DF(kMSALanesWord, UINT32_MAX,
((ws_elem & l_mask) | (wd_elem & ~l_mask))));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ binsli_d(w2, w0, m % 64); },
BINSLI_BINSRI_DF(kMSALanesDword, UINT64_MAX,
((ws_elem & l_mask) | (wd_elem & ~l_mask))));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ binsri_b(w2, w0, m % 8); },
BINSLI_BINSRI_DF(kMSALanesByte, UINT8_MAX,
((ws_elem & r_mask) | (wd_elem & ~r_mask))));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ binsri_h(w2, w0, m % 16); },
BINSLI_BINSRI_DF(kMSALanesHalf, UINT16_MAX,
((ws_elem & r_mask) | (wd_elem & ~r_mask))));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ binsri_w(w2, w0, m % 32); },
BINSLI_BINSRI_DF(kMSALanesWord, UINT32_MAX,
((ws_elem & r_mask) | (wd_elem & ~r_mask))));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ binsri_d(w2, w0, m % 64); },
BINSLI_BINSRI_DF(kMSALanesDword, UINT64_MAX,
((ws_elem & r_mask) | (wd_elem & ~r_mask))));
}
#undef BINSLI_BINSRI_DF
}
TEST(MSA_sat_s_sat_u) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
struct TestCaseMsaBit tc[] = {
// wd_lo, wd_hi, ws_lo, ws_hi, m
{0, 0, 0xf35862e13e3808b0, 0x4f41ffdef2bfe636, 3},
{0, 0, 0x64be4f6dbe9caa51, 0x6b23de1a687d9cb9, 5},
{0, 0, 0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c, 9},
{0, 0, 0x2b665362c4e812df, 0x3a0d80d68b3f8bc8, 13},
{0, 0, 0x566be7ba4365b70a, 0x01ebbc1937d76cb4, 21},
{0, 0, 0x380e2deb9d3f8aae, 0x017e0de0bcc6ca42, 30},
{0, 0, 0xa46a3a9bcb43f4e5, 0x1c62c8473bdfcffb, 45},
{0, 0, 0xf6759d85f23b5a2b, 0x5c042ae42c6d12c1, 61}};
#define SAT_DF(lanes, mask, func) \
[](uint64_t wd, uint64_t ws, uint32_t m) { \
uint64_t res = 0; \
int elem_size = kMSARegSize / lanes; \
m %= elem_size; \
for (int i = 0; i < lanes / 2; ++i) { \
int shift = elem_size * i; \
uint64_t elem_u64 = (ws >> shift) & mask; \
int64_t elem_i64 = static_cast<int64_t>(elem_u64 << (64 - elem_size)) >> \
(64 - elem_size); \
USE(elem_i64); \
res |= ((func)&mask) << shift; \
} \
return res; \
}
#define M_MAX_INT(x) static_cast<int64_t>((1LL << ((x)-1)) - 1)
#define M_MIN_INT(x) static_cast<int64_t>(-(1LL << ((x)-1)))
#define M_MAX_UINT(x) static_cast<uint64_t>(-1ULL >> (64 - (x)))
for (size_t i = 0; i < sizeof(tc) / sizeof(TestCaseMsaBit); ++i) {
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ sat_u_b(w2, w0, m % 8); },
SAT_DF(kMSALanesByte, UINT8_MAX,
(elem_u64 < M_MAX_UINT(m + 1) ? elem_u64 : M_MAX_UINT(m + 1))));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ sat_u_h(w2, w0, m % 16); },
SAT_DF(kMSALanesHalf, UINT16_MAX,
(elem_u64 < M_MAX_UINT(m + 1) ? elem_u64 : M_MAX_UINT(m + 1))));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ sat_u_w(w2, w0, m % 32); },
SAT_DF(kMSALanesWord, UINT32_MAX,
(elem_u64 < M_MAX_UINT(m + 1) ? elem_u64 : M_MAX_UINT(m + 1))));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ sat_u_d(w2, w0, m % 64); },
SAT_DF(kMSALanesDword, UINT64_MAX,
(elem_u64 < M_MAX_UINT(m + 1) ? elem_u64 : M_MAX_UINT(m + 1))));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ sat_s_b(w2, w0, m % 8); },
SAT_DF(
kMSALanesByte, UINT8_MAX,
(elem_i64 < M_MIN_INT(m + 1)
? M_MIN_INT(m + 1)
: elem_i64 > M_MAX_INT(m + 1) ? M_MAX_INT(m + 1) : elem_i64)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ sat_s_h(w2, w0, m % 16); },
SAT_DF(
kMSALanesHalf, UINT16_MAX,
(elem_i64 < M_MIN_INT(m + 1)
? M_MIN_INT(m + 1)
: elem_i64 > M_MAX_INT(m + 1) ? M_MAX_INT(m + 1) : elem_i64)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ sat_s_w(w2, w0, m % 32); },
SAT_DF(
kMSALanesWord, UINT32_MAX,
(elem_i64 < M_MIN_INT(m + 1)
? M_MIN_INT(m + 1)
: elem_i64 > M_MAX_INT(m + 1) ? M_MAX_INT(m + 1) : elem_i64)));
run_msa_bit(
&tc[i],
[](MacroAssembler& assm, uint32_t m) { __ sat_s_d(w2, w0, m % 64); },
SAT_DF(
kMSALanesDword, UINT64_MAX,
(elem_i64 < M_MIN_INT(m + 1)
? M_MIN_INT(m + 1)
: elem_i64 > M_MAX_INT(m + 1) ? M_MAX_INT(m + 1) : elem_i64)));
}
#undef SAT_DF
#undef M_MAX_INT
#undef M_MIN_INT
#undef M_MAX_UINT
}
template <typename InstFunc, typename OperFunc>
void run_msa_i10(int32_t input, InstFunc GenerateVectorInstructionFunc,
OperFunc GenerateOperationFunc) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
CpuFeatureScope fscope(&assm, MIPS_SIMD);
msa_reg_t res;
GenerateVectorInstructionFunc(assm, input);
store_uint64_elements_of_vector(assm, w0, a0);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F3 f = FUNCTION_CAST<F3>(code->entry());
(CALL_GENERATED_CODE(isolate, f, &res, 0, 0, 0, 0));
CHECK_EQ(GenerateOperationFunc(input), res.d[0]);
CHECK_EQ(GenerateOperationFunc(input), res.d[1]);
}
TEST(MSA_ldi) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
// signed 10bit integers: -512 .. 511
int32_t tc[] = {0, -1, 1, 256, -256, -178, 352, -512, 511};
#define LDI_DF(lanes, mask) \
[](int32_t s10) { \
uint64_t res = 0; \
int elem_size = kMSARegSize / lanes; \
int64_t s10_64 = \
ArithmeticShiftRight(static_cast<int64_t>(s10) << 54, 54); \
for (int i = 0; i < lanes / 2; ++i) { \
int shift = elem_size * i; \
res |= static_cast<uint64_t>(s10_64 & mask) << shift; \
} \
return res; \
}
for (size_t i = 0; i < sizeof(tc) / sizeof(int32_t); ++i) {
run_msa_i10(tc[i],
[](MacroAssembler& assm, int32_t s10) { __ ldi_b(w0, s10); },
LDI_DF(kMSALanesByte, UINT8_MAX));
run_msa_i10(tc[i],
[](MacroAssembler& assm, int32_t s10) { __ ldi_h(w0, s10); },
LDI_DF(kMSALanesHalf, UINT16_MAX));
run_msa_i10(tc[i],
[](MacroAssembler& assm, int32_t s10) { __ ldi_w(w0, s10); },
LDI_DF(kMSALanesWord, UINT32_MAX));
run_msa_i10(tc[i],
[](MacroAssembler& assm, int32_t s10) { __ ldi_d(w0, s10); },
LDI_DF(kMSALanesDword, UINT64_MAX));
}
#undef LDI_DF
}
template <typename T, typename InstFunc>
void run_msa_mi10(InstFunc GenerateVectorInstructionFunc) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
CpuFeatureScope fscope(&assm, MIPS_SIMD);
T in_test_vector[1024];
T out_test_vector[1024];
T* in_array_middle = in_test_vector + arraysize(in_test_vector) / 2;
T* out_array_middle = out_test_vector + arraysize(out_test_vector) / 2;
v8::base::RandomNumberGenerator rand_gen(FLAG_random_seed);
for (unsigned int i = 0; i < arraysize(in_test_vector); i++) {
in_test_vector[i] = static_cast<T>(rand_gen.NextInt());
out_test_vector[i] = 0;
}
GenerateVectorInstructionFunc(assm);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F5 f = FUNCTION_CAST<F5>(code->entry());
(CALL_GENERATED_CODE(isolate, f, in_array_middle, out_array_middle, 0, 0, 0));
CHECK_EQ(memcmp(in_test_vector, out_test_vector, arraysize(in_test_vector)),
0);
}
TEST(MSA_load_store_vector) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
run_msa_mi10<uint8_t>([](MacroAssembler& assm) {
for (int i = -512; i < 512; i += 16) {
__ ld_b(w0, MemOperand(a0, i));
__ st_b(w0, MemOperand(a1, i));
}
});
run_msa_mi10<uint16_t>([](MacroAssembler& assm) {
for (int i = -512; i < 512; i += 8) {
__ ld_h(w0, MemOperand(a0, i));
__ st_h(w0, MemOperand(a1, i));
}
});
run_msa_mi10<uint32_t>([](MacroAssembler& assm) {
for (int i = -512; i < 512; i += 4) {
__ ld_w(w0, MemOperand(a0, i));
__ st_w(w0, MemOperand(a1, i));
}
});
run_msa_mi10<uint64_t>([](MacroAssembler& assm) {
for (int i = -512; i < 512; i += 2) {
__ ld_d(w0, MemOperand(a0, i));
__ st_d(w0, MemOperand(a1, i));
}
});
#undef LDI_DF
}
struct TestCaseMsa3R {
uint64_t ws_lo;
uint64_t ws_hi;
uint64_t wt_lo;
uint64_t wt_hi;
uint64_t wd_lo;
uint64_t wd_hi;
};
static const uint64_t Unpredictable = 0x312014017725ll;
template <typename InstFunc, typename OperFunc>
void run_msa_3r(struct TestCaseMsa3R* input, InstFunc GenerateI5InstructionFunc,
OperFunc GenerateOperationFunc) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, nullptr, 0,
v8::internal::CodeObjectRequired::kYes);
CpuFeatureScope fscope(&assm, MIPS_SIMD);
msa_reg_t res;
uint64_t expected;
load_uint64_elements_of_vector(assm, &(input->wt_lo), w0, t0, t1);
load_uint64_elements_of_vector(assm, &(input->ws_lo), w1, t0, t1);
load_uint64_elements_of_vector(assm, &(input->wd_lo), w2, t0, t1);
GenerateI5InstructionFunc(assm);
store_uint64_elements_of_vector(assm, w2, a0);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F3 f = FUNCTION_CAST<F3>(code->entry());
(CALL_GENERATED_CODE(isolate, f, &res, 0, 0, 0, 0));
expected = GenerateOperationFunc(input->ws_lo, input->wt_lo, input->wd_lo);
if (expected != Unpredictable) {
CHECK_EQ(expected, res.d[0]);
}
expected = GenerateOperationFunc(input->ws_hi, input->wt_hi, input->wd_hi);
if (expected != Unpredictable) {
CHECK_EQ(expected, res.d[1]);
}
}
TEST(MSA_3R_instructions) {
if (kArchVariant == kMips64r6 || !CpuFeatures::IsSupported(MIPS_SIMD)) return;
CcTest::InitializeVM();
struct TestCaseMsa3R tc[] = {
{0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c, 0x1169751bb9a7d9c3,
0xf7a594aec8ef8a9c, 0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c},
{0x2b665362c4e812df, 0x3a0d80d68b3f8bc8, 0x2b665362c4e812df,
0x3a0d80d68b3f8bc8, 0x2b665362c4e812df, 0x3a0d80d68b3f8bc8},
{0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c, 0x1169751bb9a7d9c3,
0xf7a594aec8ef8a9c, 0x1169751bb9a7d9c3, 0xf7a594aec8ef8a9c},
{0x2b665362c4e812df, 0x3a0d80d68b3f8bc8, 0x2b665362c4e812df,
0x3a0d80d68b3f8bc8, 0x2b665362c4e812df, 0x3a0d80d68b3f8bc8},
{0xffab807f807fffcd, 0x7f23ff80ff567f80, 0xffab807f807fffcd,
0x7f23ff80ff567f80, 0xffab807f807fffcd, 0x7f23ff80ff567f80},
{0x80ffefff7f12807f, 0x807f80ff7fdeff78, 0x80ffefff7f12807f,
0x807f80ff7fdeff78, 0x80ffefff7f12807f, 0x807f80ff7fdeff78},
{0xffffffffffffffff, 0xffffffffffffffff, 0xffffffffffffffff,
0xffffffffffffffff, 0xffffffffffffffff, 0xffffffffffffffff},
{0x0000000000000000, 0xffffffffffffffff, 0xffffffffffffffff,
0x0000000000000000, 0x0000000000000000, 0xffffffffffffffff},
{0xffff0000ffff0000, 0xffff0000ffff0000, 0xffff0000ffff0000,
0xffff0000ffff0000, 0xffff0000ffff0000, 0xffff0000ffff0000},
{0xff00ff00ff00ff00, 0xff00ff00ff00ff00, 0xff00ff00ff00ff00,
0xff00ff00ff00ff00, 0xff00ff00ff00ff00, 0xff00ff00ff00ff00},
{0xf0f0f0f0f0f0f0f0, 0xf0f0f0f0f0f0f0f0, 0xf0f0f0f0f0f0f0f0,
0xf0f0f0f0f0f0f0f0, 0xf0f0f0f0f0f0f0f0, 0xf0f0f0f0f0f0f0f0},
{0xff0000ffff0000ff, 0xff0000ffff0000ff, 0xff0000ffff0000ff,
0xff0000ffff0000ff, 0xff0000ffff0000ff, 0xff0000ffff0000ff},
{0xffff00000000ffff, 0xffff00000000ffff, 0xffff00000000ffff,
0xffff00000000ffff, 0xffff00000000ffff, 0xffff00000000ffff}};
#define SLL_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T src_op = static_cast<T>((ws >> shift) & mask); \
T shift_op = static_cast<T>((wt >> shift) & mask) % size_in_bits; \
res |= (static_cast<uint64_t>(src_op << shift_op) & mask) << shift; \
} \
return res
#define SRA_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T src_op = static_cast<T>((ws >> shift) & mask); \
int shift_op = ((wt >> shift) & mask) % size_in_bits; \
res |= \
(static_cast<uint64_t>(ArithmeticShiftRight(src_op, shift_op) & mask)) \
<< shift; \
} \
return res
#define SRL_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T src_op = static_cast<T>((ws >> shift) & mask); \
T shift_op = static_cast<T>(((wt >> shift) & mask) % size_in_bits); \
res |= (static_cast<uint64_t>(src_op >> shift_op) & mask) << shift; \
} \
return res
#define BCRL_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T src_op = static_cast<T>((ws >> shift) & mask); \
T shift_op = static_cast<T>(((wt >> shift) & mask) % size_in_bits); \
T r = (static_cast<T>(~(1ull << shift_op)) & src_op) & mask; \
res |= static_cast<uint64_t>(r) << shift; \
} \
return res
#define BSET_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T src_op = static_cast<T>((ws >> shift) & mask); \
T shift_op = static_cast<T>(((wt >> shift) & mask) % size_in_bits); \
T r = (static_cast<T>(1ull << shift_op) | src_op) & mask; \
res |= static_cast<uint64_t>(r) << shift; \
} \
return res
#define BNEG_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T src_op = static_cast<T>((ws >> shift) & mask); \
T shift_op = static_cast<T>(((wt >> shift) & mask) % size_in_bits); \
T r = (static_cast<T>(1ull << shift_op) ^ src_op) & mask; \
res |= static_cast<uint64_t>(r) << shift; \
} \
return res
#define BINSL_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wd_op = static_cast<T>((wd >> shift) & mask); \
int shift_op = static_cast<int>(((wt >> shift) & mask) % size_in_bits); \
int bits = shift_op + 1; \
T r; \
if (bits == size_in_bits) { \
r = static_cast<T>(ws_op); \
} else { \
uint64_t mask2 = ((1ull << bits) - 1) << (size_in_bits - bits); \
r = static_cast<T>((static_cast<T>(mask2) & ws_op) | \
(static_cast<T>(~mask2) & wd_op)); \
} \
res |= static_cast<uint64_t>(r) << shift; \
} \
return res
#define BINSR_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wd_op = static_cast<T>((wd >> shift) & mask); \
int shift_op = static_cast<int>(((wt >> shift) & mask) % size_in_bits); \
int bits = shift_op + 1; \
T r; \
if (bits == size_in_bits) { \
r = static_cast<T>(ws_op); \
} else { \
uint64_t mask2 = (1ull << bits) - 1; \
r = static_cast<T>((static_cast<T>(mask2) & ws_op) | \
(static_cast<T>(~mask2) & wd_op)); \
} \
res |= static_cast<uint64_t>(r) << shift; \
} \
return res
#define ADDV_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
res |= (static_cast<uint64_t>(ws_op + wt_op) & mask) << shift; \
} \
return res
#define SUBV_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
res |= (static_cast<uint64_t>(ws_op - wt_op) & mask) << shift; \
} \
return res
#define MAX_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
res |= (static_cast<uint64_t>(Max<T>(ws_op, wt_op)) & mask) << shift; \
} \
return res
#define MIN_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
res |= (static_cast<uint64_t>(Min<T>(ws_op, wt_op)) & mask) << shift; \
} \
return res
#define MAXA_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
res |= (static_cast<uint64_t>(Nabs(ws_op) < Nabs(wt_op) ? ws_op : wt_op) & \
mask) \
<< shift; \
} \
return res
#define MINA_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
res |= (static_cast<uint64_t>(Nabs(ws_op) > Nabs(wt_op) ? ws_op : wt_op) & \
mask) \
<< shift; \
} \
return res
#define CEQ_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
res |= \
(static_cast<uint64_t>(!Compare(ws_op, wt_op) ? -1ull : 0ull) & mask) \
<< shift; \
} \
return res
#define CLT_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
res |= \
(static_cast<uint64_t>((Compare(ws_op, wt_op) == -1) ? -1ull : 0ull) & \
mask) \
<< shift; \
} \
return res
#define CLE_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
res |= \
(static_cast<uint64_t>((Compare(ws_op, wt_op) != 1) ? -1ull : 0ull) & \
mask) \
<< shift; \
} \
return res
#define ADD_A_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
res |= (static_cast<uint64_t>(Abs(ws_op) + Abs(wt_op)) & mask) << shift; \
} \
return res
#define ADDS_A_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = Nabs(static_cast<T>((ws >> shift) & mask)); \
T wt_op = Nabs(static_cast<T>((wt >> shift) & mask)); \
T r; \
if (ws_op < -std::numeric_limits<T>::max() - wt_op) { \
r = std::numeric_limits<T>::max(); \
} else { \
r = -(ws_op + wt_op); \
} \
res |= (static_cast<uint64_t>(r) & mask) << shift; \
} \
return res
#define ADDS_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
res |= (static_cast<uint64_t>(SaturateAdd(ws_op, wt_op)) & mask) << shift; \
} \
return res
#define AVE_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
res |= (static_cast<uint64_t>(((wt_op & ws_op) + ((ws_op ^ wt_op) >> 1)) & \
mask)) \
<< shift; \
} \
return res
#define AVER_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
res |= (static_cast<uint64_t>(((wt_op | ws_op) - ((ws_op ^ wt_op) >> 1)) & \
mask)) \
<< shift; \
} \
return res
#define SUBS_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
res |= (static_cast<uint64_t>(SaturateSub(ws_op, wt_op)) & mask) << shift; \
} \
return res
#define SUBSUS_U_DF(T, lanes, mask) \
typedef typename std::make_unsigned<T>::type uT; \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
uT ws_op = static_cast<uT>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
T r; \
if (wt_op > 0) { \
uT wtu = static_cast<uT>(wt_op); \
if (wtu > ws_op) { \
r = 0; \
} else { \
r = static_cast<T>(ws_op - wtu); \
} \
} else { \
if (ws_op > std::numeric_limits<uT>::max() + wt_op) { \
r = static_cast<T>(std::numeric_limits<uT>::max()); \
} else { \
r = static_cast<T>(ws_op - wt_op); \
} \
} \
res |= (static_cast<uint64_t>(r) & mask) << shift; \
} \
return res
#define SUBSUU_S_DF(T, lanes, mask) \
typedef typename std::make_unsigned<T>::type uT; \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
uT ws_op = static_cast<uT>((ws >> shift) & mask); \
uT wt_op = static_cast<uT>((wt >> shift) & mask); \
uT wdu; \
T r; \
if (ws_op > wt_op) { \
wdu = ws_op - wt_op; \
if (wdu > std::numeric_limits<T>::max()) { \
r = std::numeric_limits<T>::max(); \
} else { \
r = static_cast<T>(wdu); \
} \
} else { \
wdu = wt_op - ws_op; \
CHECK(-std::numeric_limits<T>::max() == \
std::numeric_limits<T>::min() + 1); \
if (wdu <= std::numeric_limits<T>::max()) { \
r = -static_cast<T>(wdu); \
} else { \
r = std::numeric_limits<T>::min(); \
} \
} \
res |= (static_cast<uint64_t>(r) & mask) << shift; \
} \
return res
#define ASUB_S_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
res |= (static_cast<uint64_t>(Abs(ws_op - wt_op)) & mask) << shift; \
} \
return res
#define ASUB_U_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
res |= (static_cast<uint64_t>(ws_op > wt_op ? ws_op - wt_op \
: wt_op - ws_op) & \
mask) \
<< shift; \
} \
return res
#define MULV_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
res |= (static_cast<uint64_t>(ws_op * wt_op) & mask) << shift; \
} \
return res
#define MADDV_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
T wd_op = static_cast<T>((wd >> shift) & mask); \
res |= (static_cast<uint64_t>(wd_op + ws_op * wt_op) & mask) << shift; \
} \
return res
#define MSUBV_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
T wd_op = static_cast<T>((wd >> shift) & mask); \
res |= (static_cast<uint64_t>(wd_op - ws_op * wt_op) & mask) << shift; \
} \
return res
#define DIV_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
if (wt_op == 0) { \
res = Unpredictable; \
break; \
} \
res |= (static_cast<uint64_t>(ws_op / wt_op) & mask) << shift; \
} \
return res
#define MOD_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T ws_op = static_cast<T>((ws >> shift) & mask); \
T wt_op = static_cast<T>((wt >> shift) & mask); \
if (wt_op == 0) { \
res = Unpredictable; \
break; \
} \
res |= (static_cast<uint64_t>(wt_op != 0 ? ws_op % wt_op : 0) & mask) \
<< shift; \
} \
return res
#define SRAR_DF(T, lanes, mask) \
uint64_t res = 0; \
int size_in_bits = kMSARegSize / lanes; \
for (int i = 0; i < lanes / 2; ++i) { \
uint64_t shift = size_in_bits * i; \
T src_op = static_cast<T>((ws >> shift) & mask); \
int shift_op = ((wt >> shift) & mask) % size_in_bits; \
uint32_t bit = shift_op == 0 ? 0 : src_op >> (shift_op - 1) & 1; \
res |= \
(static_cast<uint64_t>(ArithmeticShiftRight(src_op, shift_op) + bit) & \
mask) \
<< shift; \
} \
return res
#define TEST_CASE(V) \
V(sll_b, SLL_DF, uint8_t, kMSALanesByte, UINT8_MAX) \
V(sll_h, SLL_DF, uint16_t, kMSALanesHalf, UINT16_MAX) \
V(sll_w, SLL_DF, uint32_t, kMSALanesWord, UINT32_MAX) \
V(sll_d, SLL_DF, uint64_t, kMSALanesDword, UINT64_MAX) \
V(sra_b, SRA_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(sra_h, SRA_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(sra_w, SRA_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(sra_d, SRA_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(srl_b, SRL_DF, uint8_t, kMSALanesByte, UINT8_MAX) \
V(srl_h, SRL_DF, uint16_t, kMSALanesHalf, UINT16_MAX) \
V(srl_w, SRL_DF, uint32_t, kMSALanesWord, UINT32_MAX) \
V(srl_d, SRL_DF, uint64_t, kMSALanesDword, UINT64_MAX) \
V(bclr_b, BCRL_DF, uint8_t, kMSALanesByte, UINT8_MAX) \
V(bclr_h, BCRL_DF, uint16_t, kMSALanesHalf, UINT16_MAX) \
V(bclr_w, BCRL_DF, uint32_t, kMSALanesWord, UINT32_MAX) \
V(bclr_d, BCRL_DF, uint64_t, kMSALanesDword, UINT64_MAX) \
V(bset_b, BSET_DF, uint8_t, kMSALanesByte, UINT8_MAX) \
V(bset_h, BSET_DF, uint16_t, kMSALanesHalf, UINT16_MAX) \
V(bset_w, BSET_DF, uint32_t, kMSALanesWord, UINT32_MAX) \
V(bset_d, BSET_DF, uint64_t, kMSALanesDword, UINT64_MAX) \
V(bneg_b, BNEG_DF, uint8_t, kMSALanesByte, UINT8_MAX) \
V(bneg_h, BNEG_DF, uint16_t, kMSALanesHalf, UINT16_MAX) \
V(bneg_w, BNEG_DF, uint32_t, kMSALanesWord, UINT32_MAX) \
V(bneg_d, BNEG_DF, uint64_t, kMSALanesDword, UINT64_MAX) \
V(binsl_b, BINSL_DF, uint8_t, kMSALanesByte, UINT8_MAX) \
V(binsl_h, BINSL_DF, uint16_t, kMSALanesHalf, UINT16_MAX) \
V(binsl_w, BINSL_DF, uint32_t, kMSALanesWord, UINT32_MAX) \
V(binsl_d, BINSL_DF, uint64_t, kMSALanesDword, UINT64_MAX) \
V(binsr_b, BINSR_DF, uint8_t, kMSALanesByte, UINT8_MAX) \
V(binsr_h, BINSR_DF, uint16_t, kMSALanesHalf, UINT16_MAX) \
V(binsr_w, BINSR_DF, uint32_t, kMSALanesWord, UINT32_MAX) \
V(binsr_d, BINSR_DF, uint64_t, kMSALanesDword, UINT64_MAX) \
V(addv_b, ADDV_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(addv_h, ADDV_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(addv_w, ADDV_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(addv_d, ADDV_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(subv_b, SUBV_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(subv_h, SUBV_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(subv_w, SUBV_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(subv_d, SUBV_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(max_s_b, MAX_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(max_s_h, MAX_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(max_s_w, MAX_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(max_s_d, MAX_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(max_u_b, MAX_DF, uint8_t, kMSALanesByte, UINT8_MAX) \
V(max_u_h, MAX_DF, uint16_t, kMSALanesHalf, UINT16_MAX) \
V(max_u_w, MAX_DF, uint32_t, kMSALanesWord, UINT32_MAX) \
V(max_u_d, MAX_DF, uint64_t, kMSALanesDword, UINT64_MAX) \
V(min_s_b, MIN_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(min_s_h, MIN_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(min_s_w, MIN_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(min_s_d, MIN_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(min_u_b, MIN_DF, uint8_t, kMSALanesByte, UINT8_MAX) \
V(min_u_h, MIN_DF, uint16_t, kMSALanesHalf, UINT16_MAX) \
V(min_u_w, MIN_DF, uint32_t, kMSALanesWord, UINT32_MAX) \
V(min_u_d, MIN_DF, uint64_t, kMSALanesDword, UINT64_MAX) \
V(max_a_b, MAXA_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(max_a_h, MAXA_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(max_a_w, MAXA_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(max_a_d, MAXA_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(min_a_b, MINA_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(min_a_h, MINA_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(min_a_w, MINA_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(min_a_d, MINA_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(ceq_b, CEQ_DF, uint8_t, kMSALanesByte, UINT8_MAX) \
V(ceq_h, CEQ_DF, uint16_t, kMSALanesHalf, UINT16_MAX) \
V(ceq_w, CEQ_DF, uint32_t, kMSALanesWord, UINT32_MAX) \
V(ceq_d, CEQ_DF, uint64_t, kMSALanesDword, UINT64_MAX) \
V(clt_s_b, CLT_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(clt_s_h, CLT_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(clt_s_w, CLT_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(clt_s_d, CLT_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(clt_u_b, CLT_DF, uint8_t, kMSALanesByte, UINT8_MAX) \
V(clt_u_h, CLT_DF, uint16_t, kMSALanesHalf, UINT16_MAX) \
V(clt_u_w, CLT_DF, uint32_t, kMSALanesWord, UINT32_MAX) \
V(clt_u_d, CLT_DF, uint64_t, kMSALanesDword, UINT64_MAX) \
V(cle_s_b, CLE_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(cle_s_h, CLE_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(cle_s_w, CLE_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(cle_s_d, CLE_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(cle_u_b, CLE_DF, uint8_t, kMSALanesByte, UINT8_MAX) \
V(cle_u_h, CLE_DF, uint16_t, kMSALanesHalf, UINT16_MAX) \
V(cle_u_w, CLE_DF, uint32_t, kMSALanesWord, UINT32_MAX) \
V(cle_u_d, CLE_DF, uint64_t, kMSALanesDword, UINT64_MAX) \
V(add_a_b, ADD_A_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(add_a_h, ADD_A_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(add_a_w, ADD_A_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(add_a_d, ADD_A_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(adds_a_b, ADDS_A_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(adds_a_h, ADDS_A_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(adds_a_w, ADDS_A_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(adds_a_d, ADDS_A_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(adds_s_b, ADDS_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(adds_s_h, ADDS_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(adds_s_w, ADDS_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(adds_s_d, ADDS_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(adds_u_b, ADDS_DF, uint8_t, kMSALanesByte, UINT8_MAX) \
V(adds_u_h, ADDS_DF, uint16_t, kMSALanesHalf, UINT16_MAX) \
V(adds_u_w, ADDS_DF, uint32_t, kMSALanesWord, UINT32_MAX) \
V(adds_u_d, ADDS_DF, uint64_t, kMSALanesDword, UINT64_MAX) \
V(ave_s_b, AVE_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(ave_s_h, AVE_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(ave_s_w, AVE_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(ave_s_d, AVE_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(ave_u_b, AVE_DF, uint8_t, kMSALanesByte, UINT8_MAX) \
V(ave_u_h, AVE_DF, uint16_t, kMSALanesHalf, UINT16_MAX) \
V(ave_u_w, AVE_DF, uint32_t, kMSALanesWord, UINT32_MAX) \
V(ave_u_d, AVE_DF, uint64_t, kMSALanesDword, UINT64_MAX) \
V(aver_s_b, AVER_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(aver_s_h, AVER_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(aver_s_w, AVER_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(aver_s_d, AVER_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(aver_u_b, AVER_DF, uint8_t, kMSALanesByte, UINT8_MAX) \
V(aver_u_h, AVER_DF, uint16_t, kMSALanesHalf, UINT16_MAX) \
V(aver_u_w, AVER_DF, uint32_t, kMSALanesWord, UINT32_MAX) \
V(aver_u_d, AVER_DF, uint64_t, kMSALanesDword, UINT64_MAX) \
V(subs_s_b, SUBS_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(subs_s_h, SUBS_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(subs_s_w, SUBS_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(subs_s_d, SUBS_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(subs_u_b, SUBS_DF, uint8_t, kMSALanesByte, UINT8_MAX) \
V(subs_u_h, SUBS_DF, uint16_t, kMSALanesHalf, UINT16_MAX) \
V(subs_u_w, SUBS_DF, uint32_t, kMSALanesWord, UINT32_MAX) \
V(subs_u_d, SUBS_DF, uint64_t, kMSALanesDword, UINT64_MAX) \
V(subsus_u_b, SUBSUS_U_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(subsus_u_h, SUBSUS_U_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(subsus_u_w, SUBSUS_U_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(subsus_u_d, SUBSUS_U_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(subsuu_s_b, SUBSUU_S_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(subsuu_s_h, SUBSUU_S_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(subsuu_s_w, SUBSUU_S_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(subsuu_s_d, SUBSUU_S_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(asub_s_b, ASUB_S_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(asub_s_h, ASUB_S_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(asub_s_w, ASUB_S_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(asub_s_d, ASUB_S_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(asub_u_b, ASUB_U_DF, uint8_t, kMSALanesByte, UINT8_MAX) \
V(asub_u_h, ASUB_U_DF, uint16_t, kMSALanesHalf, UINT16_MAX) \
V(asub_u_w, ASUB_U_DF, uint32_t, kMSALanesWord, UINT32_MAX) \
V(asub_u_d, ASUB_U_DF, uint64_t, kMSALanesDword, UINT64_MAX) \
V(mulv_b, MULV_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(mulv_h, MULV_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(mulv_w, MULV_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(mulv_d, MULV_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(maddv_b, MADDV_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(maddv_h, MADDV_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(maddv_w, MADDV_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(maddv_d, MADDV_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(msubv_b, MSUBV_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(msubv_h, MSUBV_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(msubv_w, MSUBV_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(msubv_d, MSUBV_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(div_s_b, DIV_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(div_s_h, DIV_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(div_s_w, DIV_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(div_s_d, DIV_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(div_u_b, DIV_DF, uint8_t, kMSALanesByte, UINT8_MAX) \
V(div_u_h, DIV_DF, uint16_t, kMSALanesHalf, UINT16_MAX) \
V(div_u_w, DIV_DF, uint32_t, kMSALanesWord, UINT32_MAX) \
V(div_u_d, DIV_DF, uint64_t, kMSALanesDword, UINT64_MAX) \
V(mod_s_b, MOD_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(mod_s_h, MOD_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(mod_s_w, MOD_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(mod_s_d, MOD_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(mod_u_b, MOD_DF, uint8_t, kMSALanesByte, UINT8_MAX) \
V(mod_u_h, MOD_DF, uint16_t, kMSALanesHalf, UINT16_MAX) \
V(mod_u_w, MOD_DF, uint32_t, kMSALanesWord, UINT32_MAX) \
V(mod_u_d, MOD_DF, uint64_t, kMSALanesDword, UINT64_MAX) \
V(srar_b, SRAR_DF, int8_t, kMSALanesByte, UINT8_MAX) \
V(srar_h, SRAR_DF, int16_t, kMSALanesHalf, UINT16_MAX) \
V(srar_w, SRAR_DF, int32_t, kMSALanesWord, UINT32_MAX) \
V(srar_d, SRAR_DF, int64_t, kMSALanesDword, UINT64_MAX) \
V(srlr_b, SRAR_DF, uint8_t, kMSALanesByte, UINT8_MAX) \
V(srlr_h, SRAR_DF, uint16_t, kMSALanesHalf, UINT16_MAX) \
V(srlr_w, SRAR_DF, uint32_t, kMSALanesWord, UINT32_MAX) \
V(srlr_d, SRAR_DF, uint64_t, kMSALanesDword, UINT64_MAX)
#define RUN_TEST(instr, verify, type, lanes, mask) \
run_msa_3r(&tc[i], [](MacroAssembler& assm) { __ instr(w2, w1, w0); }, \
[](uint64_t ws, uint64_t wt, uint64_t wd) { \
verify(type, lanes, mask); \
});
for (size_t i = 0; i < arraysize(tc); ++i) {
TEST_CASE(RUN_TEST)
}
#undef RUN_TEST
#undef SLL_DF
#undef SRL_DF
#undef BCRL_DF
#undef BSET_DF
#undef BNEG_DF
#undef BINSL_DF
#undef BINSR_DF
#undef ADDV_DF
#undef SUBV_DF
#undef MAX_DF
#undef MIN_DF
#undef MAXA_DF
#undef MINA_DF
#undef CEQ_DF
#undef CLT_DF
#undef CLE_DF
#undef ADD_A_DF
#undef ADDS_A_DF
#undef ADDS_DF
#undef AVE_DF
#undef AVER_DF
#undef SUBS_DF
#undef SUBSUS_U_DF
#undef SUBSUU_S_DF
#undef ASUB_S_DF
#undef ASUB_U_DF
#undef MULV_DF
#undef MADDV_DF
#undef MSUBV_DF
#undef DIV_DF
#undef MOD_DF
#undef SRAR_DF
}
struct TestCaseMsa3RF {
uint64_t ws_lo;
uint64_t ws_hi;
uint64_t wt_lo;
uint64_t wt_hi;
uint64_t wd_lo;
uint64_t wd_hi;
};
struct ExpectedResult_MSA3RF {
uint64_t exp_res_lo;
uint64_t exp_res_hi;
};
template <typename Func, typename FuncLoad, typename FuncStore>
void run_msa_3rf(const struct TestCaseMsa3RF* input,
const struct ExpectedResult_MSA3RF* output,
Func Generate2RInstructionFunc,
FuncLoad load_elements_of_vector,
FuncStore store_elements_of_vector) {
Isolate* isolate = CcTest::i_isolate();
HandleScope scope(isolate);
MacroAssembler assm(isolate, NULL, 0, v8::internal::CodeObjectRequired::kYes);
CpuFeatureScope fscope(&assm, MIPS_SIMD);
msa_reg_t res;
load_elements_of_vector(
assm, reinterpret_cast<const uint64_t*>(&input->ws_lo), w0, t0, t1);
load_elements_of_vector(
assm, reinterpret_cast<const uint64_t*>(&input->wt_lo), w1, t0, t1);
load_elements_of_vector(
assm, reinterpret_cast<const uint64_t*>(&input->wd_lo), w2, t0, t1);
Generate2RInstructionFunc(assm);
store_elements_of_vector(assm, w2, a0);
__ jr(ra);
__ nop();
CodeDesc desc;
assm.GetCode(isolate, &desc);
Handle<Code> code =
isolate->factory()->NewCode(desc, Code::STUB, Handle<Code>());
#ifdef OBJECT_PRINT
code->Print(std::cout);
#endif
F3 f = FUNCTION_CAST<F3>(code->entry());
(CALL_GENERATED_CODE(isolate, f, &res, 0, 0, 0, 0));
if (store_elements_of_vector == store_uint64_elements_of_vector) {
CHECK_EQ(output->exp_res_lo, res.d[0]);
CHECK_EQ(output->exp_res_hi, res.d[1]);
} else if (store_elements_of_vector == store_uint32_elements_of_vector) {
const uint32_t* exp_res =
reinterpret_cast<const uint32_t*>(&output->exp_res_lo);
CHECK_EQ(exp_res[0], res.w[0]);
CHECK_EQ(exp_res[1], res.w[1]);
CHECK_EQ(exp_res[2], res.w[2]);
CHECK_EQ(exp_res[3], res.w[3]);
} else {
const uint16_t* exp_res =
reinterpret_cast<const uint16_t*>(&output->exp_res_lo);
CHECK_EQ(exp_res[0], res.h[0]);
CHECK_EQ(exp_res[1], res.h[1]);
CHECK_EQ(exp_res[2], res.h[2]);
CHECK_EQ(exp_res[3], res.h[3]);
CHECK_EQ(exp_res[4], res.h[4]);
CHECK_EQ(exp_res[5], res.h[5]);
CHECK_EQ(exp_res[6], res.h[6]);
CHECK_EQ(exp_res[7], res.h[7]);
}
}
struct TestCaseMsa3RF_F {
float ws_1, ws_2, ws_3, ws_4;
float wt_1, wt_2, wt_3, wt_4;
float wd_1, wd_2, wd_3, wd_4;
};
struct ExpRes_32I {
int32_t exp_res_1;
int32_t exp_res_2;
int32_t exp_res_3;
int32_t exp_res_4;
};
struct TestCaseMsa3RF_D {
double ws_lo, ws_hi;
double wt_lo, wt_hi;
double wd_lo, wd_hi;
};
struct ExpRes_64I {
int64_t exp_res_lo;
int64_t exp_res_hi;
};
TEST(MSA_floating_point_quiet_compare) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
const float qnan_f = std::numeric_limits<float>::quiet_NaN();
const double qnan_d = std::numeric_limits<double>::quiet_NaN();
const float inf_f = std::numeric_limits<float>::infinity();
const double inf_d = std::numeric_limits<double>::infinity();
const int32_t ones = -1;
const struct TestCaseMsa3RF_F tc_w[]{
{qnan_f, -qnan_f, inf_f, 2.14e9f, // ws
qnan_f, 0.f, qnan_f, -2.14e9f, // wt
0, 0, 0, 0}, // wd
{inf_f, -inf_f, -3.4e38f, 1.5e-45f, -inf_f, -inf_f, -inf_f, inf_f, 0, 0,
0, 0},
{0.f, 19.871e24f, -1.5e-45f, -1.5e-45f, -19.871e24f, 19.871e24f, 1.5e-45f,
-1.5e-45f, 0, 0, 0, 0}};
const struct TestCaseMsa3RF_D tc_d[]{
// ws_lo, ws_hi, wt_lo, wt_hi, wd_lo, wd_hi
{qnan_d, -qnan_d, qnan_f, 0., 0, 0},
{inf_d, 9.22e18, qnan_d, -9.22e18, 0, 0},
{inf_d, inf_d, -inf_d, inf_d, 0, 0},
{-2.3e-308, 5e-324, -inf_d, inf_d, 0, 0},
{0., 24.1e87, -1.6e308, 24.1e87, 0, 0},
{-5e-324, -5e-324, 5e-324, -5e-324, 0, 0}};
const struct ExpectedResult_MSA3RF exp_res_fcaf = {0, 0};
const struct ExpRes_32I exp_res_fcun_w[] = {
{ones, ones, ones, 0}, {0, 0, 0, 0}, {0, 0, 0, 0}};
const struct ExpRes_64I exp_res_fcun_d[] = {{ones, ones}, {ones, 0}, {0, 0},
{0, 0}, {0, 0}, {0, 0}};
const struct ExpRes_32I exp_res_fceq_w[] = {
{0, 0, 0, 0}, {0, ones, 0, 0}, {0, ones, 0, ones}};
const struct ExpRes_64I exp_res_fceq_d[] = {{0, 0}, {0, 0}, {0, ones},
{0, 0}, {0, ones}, {0, ones}};
const struct ExpRes_32I exp_res_fcueq_w[] = {
{ones, ones, ones, 0}, {0, ones, 0, 0}, {0, ones, 0, ones}};
const struct ExpRes_64I exp_res_fcueq_d[] = {
{ones, ones}, {ones, 0}, {0, ones}, {0, 0}, {0, ones}, {0, ones}};
const struct ExpRes_32I exp_res_fclt_w[] = {
{0, 0, 0, 0}, {0, 0, 0, ones}, {0, 0, ones, 0}};
const struct ExpRes_64I exp_res_fclt_d[] = {{0, 0}, {0, 0}, {0, 0},
{0, ones}, {0, 0}, {ones, 0}};
const struct ExpRes_32I exp_res_fcult_w[] = {
{ones, ones, ones, 0}, {0, 0, 0, ones}, {0, 0, ones, 0}};
const struct ExpRes_64I exp_res_fcult_d[] = {
{ones, ones}, {ones, 0}, {0, 0}, {0, ones}, {0, 0}, {ones, 0}};
const struct ExpRes_32I exp_res_fcle_w[] = {
{0, 0, 0, 0}, {0, ones, 0, ones}, {0, ones, ones, ones}};
const struct ExpRes_64I exp_res_fcle_d[] = {
{0, 0}, {0, 0}, {0, ones}, {0, ones}, {0, ones}, {ones, ones}};
const struct ExpRes_32I exp_res_fcule_w[] = {
{ones, ones, ones, 0}, {0, ones, 0, ones}, {0, ones, ones, ones}};
const struct ExpRes_64I exp_res_fcule_d[] = {
{ones, ones}, {ones, 0}, {0, ones}, {0, ones}, {0, ones}, {ones, ones}};
const struct ExpRes_32I exp_res_fcor_w[] = {
{0, 0, 0, ones}, {ones, ones, ones, ones}, {ones, ones, ones, ones}};
const struct ExpRes_64I exp_res_fcor_d[] = {{0, 0}, {0, ones},
{ones, ones}, {ones, ones},
{ones, ones}, {ones, ones}};
const struct ExpRes_32I exp_res_fcune_w[] = {
{ones, ones, ones, ones}, {ones, 0, ones, ones}, {ones, 0, ones, 0}};
const struct ExpRes_64I exp_res_fcune_d[] = {{ones, ones}, {ones, ones},
{ones, 0}, {ones, ones},
{ones, 0}, {ones, 0}};
const struct ExpRes_32I exp_res_fcne_w[] = {
{0, 0, 0, ones}, {ones, 0, ones, ones}, {ones, 0, ones, 0}};
const struct ExpRes_64I exp_res_fcne_d[] = {
{0, 0}, {0, ones}, {ones, 0}, {ones, ones}, {ones, 0}, {ones, 0}};
#define TEST_FP_QUIET_COMPARE_W(instruction, src, exp_res) \
run_msa_3rf(reinterpret_cast<const struct TestCaseMsa3RF*>(src), \
reinterpret_cast<const struct ExpectedResult_MSA3RF*>(exp_res), \
[](MacroAssembler& assm) { __ instruction(w2, w0, w1); }, \
load_uint32_elements_of_vector, \
store_uint32_elements_of_vector);
#define TEST_FP_QUIET_COMPARE_D(instruction, src, exp_res) \
run_msa_3rf(reinterpret_cast<const struct TestCaseMsa3RF*>(src), \
reinterpret_cast<const struct ExpectedResult_MSA3RF*>(exp_res), \
[](MacroAssembler& assm) { __ instruction(w2, w0, w1); }, \
load_uint64_elements_of_vector, \
store_uint64_elements_of_vector);
for (uint64_t i = 0; i < arraysize(tc_w); i++) {
TEST_FP_QUIET_COMPARE_W(fcaf_w, &tc_w[i], &exp_res_fcaf)
TEST_FP_QUIET_COMPARE_W(fcun_w, &tc_w[i], &exp_res_fcun_w[i])
TEST_FP_QUIET_COMPARE_W(fceq_w, &tc_w[i], &exp_res_fceq_w[i])
TEST_FP_QUIET_COMPARE_W(fcueq_w, &tc_w[i], &exp_res_fcueq_w[i])
TEST_FP_QUIET_COMPARE_W(fclt_w, &tc_w[i], &exp_res_fclt_w[i])
TEST_FP_QUIET_COMPARE_W(fcult_w, &tc_w[i], &exp_res_fcult_w[i])
TEST_FP_QUIET_COMPARE_W(fcle_w, &tc_w[i], &exp_res_fcle_w[i])
TEST_FP_QUIET_COMPARE_W(fcule_w, &tc_w[i], &exp_res_fcule_w[i])
TEST_FP_QUIET_COMPARE_W(fcor_w, &tc_w[i], &exp_res_fcor_w[i])
TEST_FP_QUIET_COMPARE_W(fcune_w, &tc_w[i], &exp_res_fcune_w[i])
TEST_FP_QUIET_COMPARE_W(fcne_w, &tc_w[i], &exp_res_fcne_w[i])
}
for (uint64_t i = 0; i < arraysize(tc_d); i++) {
TEST_FP_QUIET_COMPARE_D(fcaf_d, &tc_d[i], &exp_res_fcaf)
TEST_FP_QUIET_COMPARE_D(fcun_d, &tc_d[i], &exp_res_fcun_d[i])
TEST_FP_QUIET_COMPARE_D(fceq_d, &tc_d[i], &exp_res_fceq_d[i])
TEST_FP_QUIET_COMPARE_D(fcueq_d, &tc_d[i], &exp_res_fcueq_d[i])
TEST_FP_QUIET_COMPARE_D(fclt_d, &tc_d[i], &exp_res_fclt_d[i])
TEST_FP_QUIET_COMPARE_D(fcult_d, &tc_d[i], &exp_res_fcult_d[i])
TEST_FP_QUIET_COMPARE_D(fcle_d, &tc_d[i], &exp_res_fcle_d[i])
TEST_FP_QUIET_COMPARE_D(fcule_d, &tc_d[i], &exp_res_fcule_d[i])
TEST_FP_QUIET_COMPARE_D(fcor_d, &tc_d[i], &exp_res_fcor_d[i])
TEST_FP_QUIET_COMPARE_D(fcune_d, &tc_d[i], &exp_res_fcune_d[i])
TEST_FP_QUIET_COMPARE_D(fcne_d, &tc_d[i], &exp_res_fcne_d[i])
}
#undef TEST_FP_QUIET_COMPARE_W
#undef TEST_FP_QUIET_COMPARE_D
}
template <typename T>
inline const T* fadd_function(const T* src1, const T* src2, const T* src3,
T* dst) {
for (uint64_t i = 0; i < kMSALanesByte / sizeof(T); i++) {
dst[i] = src1[i] + src2[i];
}
return dst;
}
template <typename T>
inline const T* fsub_function(const T* src1, const T* src2, const T* src3,
T* dst) {
for (uint64_t i = 0; i < kMSALanesByte / sizeof(T); i++) {
dst[i] = src1[i] - src2[i];
}
return dst;
}
template <typename T>
inline const T* fmul_function(const T* src1, const T* src2, const T* src3,
T* dst) {
for (uint64_t i = 0; i < kMSALanesByte / sizeof(T); i++) {
dst[i] = src1[i] * src2[i];
}
return dst;
}
template <typename T>
inline const T* fdiv_function(const T* src1, const T* src2, const T* src3,
T* dst) {
for (uint64_t i = 0; i < kMSALanesByte / sizeof(T); i++) {
dst[i] = src1[i] / src2[i];
}
return dst;
}
template <typename T>
inline const T* fmadd_function(const T* src1, const T* src2, const T* src3,
T* dst) {
for (uint64_t i = 0; i < kMSALanesByte / sizeof(T); i++) {
dst[i] = std::fma(src1[i], src2[i], src3[i]);
}
return dst;
}
template <typename T>
inline const T* fmsub_function(const T* src1, const T* src2, const T* src3,
T* dst) {
for (uint64_t i = 0; i < kMSALanesByte / sizeof(T); i++) {
dst[i] = std::fma(src1[i], -src2[i], src3[i]);
}
return dst;
}
TEST(MSA_floating_point_arithmetic) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
const float inf_f = std::numeric_limits<float>::infinity();
const double inf_d = std::numeric_limits<double>::infinity();
const struct TestCaseMsa3RF_F tc_w[] = {
{0.3, -2.14e13f, inf_f, 0.f, // ws
-inf_f, std::sqrt(8.e-26f), -23.e34, -2.14e9f, // wt
-1e30f, 4.6e12f, 0, 2.14e9f}, // wd
{3.4e38f, -1.2e-38f, 1e19f, -1e19f, 3.4e38f, 1.2e-38f, -1e19f, -1e-19f,
3.4e38f, 1.2e-38f * 3, 3.4e38f, -4e19f},
{-3e-31f, 3e10f, 1e25f, 123.f, 1e-14f, 1e-34f, 4e25f, 321.f, 3e-17f,
2e-24f, 2.f, -123456.f}};
const struct TestCaseMsa3RF_D tc_d[] = {
// ws_lo, ws_hi, wt_lo, wt_hi, wd_lo, wd_hi
{0.3, -2.14e103, -inf_d, std::sqrt(8.e-206), -1e30, 4.6e102},
{inf_d, 0., -23.e304, -2.104e9, 0, 2.104e9},
{3.4e307, -1.2e-307, 3.4e307, 1.2e-307, 3.4e307, 1.2e-307 * 3},
{1e154, -1e154, -1e154, -1e-154, 2.9e38, -4e19},
{-3e-301, 3e100, 1e-104, 1e-304, 3e-107, 2e-204},
{1e205, 123., 4e205, 321., 2., -123456.}};
struct ExpectedResult_MSA3RF dst_container;
#define FP_ARITHMETIC_DF_W(instr, function, src1, src2, src3) \
run_msa_3rf( \
reinterpret_cast<const struct TestCaseMsa3RF*>(src1), \
reinterpret_cast<const struct ExpectedResult_MSA3RF*>(function( \
src1, src2, src3, reinterpret_cast<float*>(&dst_container))), \
[](MacroAssembler& assm) { __ instr(w2, w0, w1); }, \
load_uint32_elements_of_vector, store_uint32_elements_of_vector);
#define FP_ARITHMETIC_DF_D(instr, function, src1, src2, src3) \
run_msa_3rf( \
reinterpret_cast<const struct TestCaseMsa3RF*>(src1), \
reinterpret_cast<const struct ExpectedResult_MSA3RF*>(function( \
src1, src2, src3, reinterpret_cast<double*>(&dst_container))), \
[](MacroAssembler& assm) { __ instr(w2, w0, w1); }, \
load_uint64_elements_of_vector, store_uint64_elements_of_vector);
for (uint64_t i = 0; i < arraysize(tc_w); i++) {
FP_ARITHMETIC_DF_W(fadd_w, fadd_function, &tc_w[i].ws_1, &tc_w[i].wt_1,
&tc_w[i].wd_1)
FP_ARITHMETIC_DF_W(fsub_w, fsub_function, &tc_w[i].ws_1, &tc_w[i].wt_1,
&tc_w[i].wd_1)
FP_ARITHMETIC_DF_W(fmul_w, fmul_function, &tc_w[i].ws_1, &tc_w[i].wt_1,
&tc_w[i].wd_1)
FP_ARITHMETIC_DF_W(fdiv_w, fdiv_function, &tc_w[i].ws_1, &tc_w[i].wt_1,
&tc_w[i].wd_1)
FP_ARITHMETIC_DF_W(fmadd_w, fmadd_function, &tc_w[i].ws_1, &tc_w[i].wt_1,
&tc_w[i].wd_1)
FP_ARITHMETIC_DF_W(fmsub_w, fmsub_function, &tc_w[i].ws_1, &tc_w[i].wt_1,
&tc_w[i].wd_1)
}
for (uint64_t i = 0; i < arraysize(tc_d); i++) {
FP_ARITHMETIC_DF_D(fadd_d, fadd_function, &tc_d[i].ws_lo, &tc_d[i].wt_lo,
&tc_d[i].wd_lo)
FP_ARITHMETIC_DF_D(fsub_d, fsub_function, &tc_d[i].ws_lo, &tc_d[i].wt_lo,
&tc_d[i].wd_lo)
FP_ARITHMETIC_DF_D(fmul_d, fmul_function, &tc_d[i].ws_lo, &tc_d[i].wt_lo,
&tc_d[i].wd_lo)
FP_ARITHMETIC_DF_D(fdiv_d, fdiv_function, &tc_d[i].ws_lo, &tc_d[i].wt_lo,
&tc_d[i].wd_lo)
FP_ARITHMETIC_DF_D(fmadd_d, fmadd_function, &tc_d[i].ws_lo, &tc_d[i].wt_lo,
&tc_d[i].wd_lo)
FP_ARITHMETIC_DF_D(fmsub_d, fmsub_function, &tc_d[i].ws_lo, &tc_d[i].wt_lo,
&tc_d[i].wd_lo)
}
#undef FP_ARITHMETIC_DF_W
#undef FP_ARITHMETIC_DF_D
}
struct ExpRes_F {
float exp_res_1;
float exp_res_2;
float exp_res_3;
float exp_res_4;
};
struct ExpRes_D {
double exp_res_1;
double exp_res_2;
};
TEST(MSA_fmin_fmin_a_fmax_fmax_a) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
const float inf_f = std::numeric_limits<float>::infinity();
const double inf_d = std::numeric_limits<double>::infinity();
const struct TestCaseMsa3RF_F tc_w[] = {
{0.3f, -2.14e13f, inf_f, -0.f, // ws
-inf_f, -std::sqrt(8.e26f), -23.e34f, -2.14e9f, // wt
0, 0, 0, 0}, // wd
{3.4e38f, 1.2e-41f, 1e19f, 1e19f, // ws
3.4e38f, -1.1e-41f, -1e-42f, -1e29f, // wt
0, 0, 0, 0}}; // wd
const struct TestCaseMsa3RF_D tc_d[] = {
// ws_lo, ws_hi, wt_lo, wt_hi, wd_lo, wd_hi
{0.3, -2.14e103, -inf_d, -std::sqrt(8e206), 0, 0},
{inf_d, -0., -23e304, -2.14e90, 0, 0},
{3.4e307, 1.2e-320, 3.4e307, -1.1e-320, 0, 0},
{1e154, 1e154, -1e-321, -1e174, 0, 0}};
const struct ExpRes_F exp_res_fmax_w[] = {{0.3f, -2.14e13f, inf_f, -0.f},
{3.4e38f, 1.2e-41f, 1e19f, 1e19f}};
const struct ExpRes_F exp_res_fmax_a_w[] = {
{-inf_f, -std::sqrt(8e26f), inf_f, -2.14e9f},
{3.4e38f, 1.2e-41f, 1e19f, -1e29f}};
const struct ExpRes_F exp_res_fmin_w[] = {
{-inf_f, -std::sqrt(8.e26f), -23e34f, -2.14e9f},
{3.4e38f, -1.1e-41f, -1e-42f, -1e29f}};
const struct ExpRes_F exp_res_fmin_a_w[] = {
{0.3, -2.14e13f, -23.e34f, -0.f}, {3.4e38f, -1.1e-41f, -1e-42f, 1e19f}};
const struct ExpRes_D exp_res_fmax_d[] = {
{0.3, -2.14e103}, {inf_d, -0.}, {3.4e307, 1.2e-320}, {1e154, 1e154}};
const struct ExpRes_D exp_res_fmax_a_d[] = {{-inf_d, -std::sqrt(8e206)},
{inf_d, -2.14e90},
{3.4e307, 1.2e-320},
{1e154, -1e174}};
const struct ExpRes_D exp_res_fmin_d[] = {{-inf_d, -std::sqrt(8e206)},
{-23e304, -2.14e90},
{3.4e307, -1.1e-320},
{-1e-321, -1e174}};
const struct ExpRes_D exp_res_fmin_a_d[] = {
{0.3, -2.14e103}, {-23e304, -0.}, {3.4e307, -1.1e-320}, {-1e-321, 1e154}};
#define TEST_FP_MIN_MAX_W(instruction, src, exp_res) \
run_msa_3rf(reinterpret_cast<const struct TestCaseMsa3RF*>(src), \
reinterpret_cast<const struct ExpectedResult_MSA3RF*>(exp_res), \
[](MacroAssembler& assm) { __ instruction(w2, w0, w1); }, \
load_uint32_elements_of_vector, \
store_uint32_elements_of_vector);
#define TEST_FP_MIN_MAX_D(instruction, src, exp_res) \
run_msa_3rf(reinterpret_cast<const struct TestCaseMsa3RF*>(src), \
reinterpret_cast<const struct ExpectedResult_MSA3RF*>(exp_res), \
[](MacroAssembler& assm) { __ instruction(w2, w0, w1); }, \
load_uint64_elements_of_vector, \
store_uint64_elements_of_vector);
for (uint64_t i = 0; i < arraysize(tc_w); i++) {
TEST_FP_MIN_MAX_W(fmax_w, &tc_w[i], &exp_res_fmax_w[i])
TEST_FP_MIN_MAX_W(fmax_a_w, &tc_w[i], &exp_res_fmax_a_w[i])
TEST_FP_MIN_MAX_W(fmin_w, &tc_w[i], &exp_res_fmin_w[i])
TEST_FP_MIN_MAX_W(fmin_a_w, &tc_w[i], &exp_res_fmin_a_w[i])
}
for (uint64_t i = 0; i < arraysize(tc_d); i++) {
TEST_FP_MIN_MAX_D(fmax_d, &tc_d[i], &exp_res_fmax_d[i])
TEST_FP_MIN_MAX_D(fmax_a_d, &tc_d[i], &exp_res_fmax_a_d[i])
TEST_FP_MIN_MAX_D(fmin_d, &tc_d[i], &exp_res_fmin_d[i])
TEST_FP_MIN_MAX_D(fmin_a_d, &tc_d[i], &exp_res_fmin_a_d[i])
}
#undef TEST_FP_MIN_MAX_W
#undef TEST_FP_MIN_MAX_D
}
struct TestCaseMsa3RF_16I {
int16_t ws_1, ws_2, ws_3, ws_4, ws_5, ws_6, ws_7, ws_8;
int16_t wt_1, wt_2, wt_3, wt_4, wt_5, wt_6, wt_7, wt_8;
int16_t wd_1, wd_2, wd_3, wd_4, wd_5, wd_6, wd_7, wd_8;
};
struct ExpRes_16I {
int16_t exp_res_1;
int16_t exp_res_2;
int16_t exp_res_3;
int16_t exp_res_4;
int16_t exp_res_5;
int16_t exp_res_6;
int16_t exp_res_7;
int16_t exp_res_8;
};
struct TestCaseMsa3RF_32I {
int32_t ws_1, ws_2, ws_3, ws_4;
int32_t wt_1, wt_2, wt_3, wt_4;
int32_t wd_1, wd_2, wd_3, wd_4;
};
TEST(MSA_fixed_point_arithmetic) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
const struct TestCaseMsa3RF tc_h[]{
{0x800080007fff7fff, 0xe1ed8000fad3863a, 0x80007fff00af7fff,
0x800015a77fffa0eb, 0x7fff800080007fff, 0x80007fff1f207364},
{0x800080007fff006a, 0x002affc4329ad87b, 0x80007fff7fff00f3,
0xffecffb4d0d7f429, 0x80007fff80007c33, 0x54ac6bbce53b8c91}};
const struct TestCaseMsa3RF tc_w[]{
{0x8000000080000000, 0x7fffffff7fffffff, 0x800000007fffffff,
0x00001ff37fffffff, 0x7fffffff80000000, 0x800000007fffffff},
{0xe1ed035580000000, 0xfad3863aed462c0b, 0x8000000015a70aec,
0x7fffffffa0ebd354, 0x800000007fffffff, 0xd0d7f4291f207364},
{0x8000000080000000, 0x7fffffff0000da1f, 0x800000007fffffff,
0x7fffffff00f39c3b, 0x800000007fffffff, 0x800000007c33f2fd},
{0x0000ac33ffff329a, 0x54ac6bbce53bd87b, 0xffffe2b4d0d7f429,
0x0355ed462c0b1ff3, 0xb5deb625939dd3f9, 0xe642adfa69519596}};
const struct ExpectedResult_MSA3RF exp_res_mul_q_h[] = {
{0x7fff800100ae7ffe, 0x1e13ea59fad35a74},
{0x7fff80017ffe0000, 0xffff0000ed5b03a7}};
const struct ExpectedResult_MSA3RF exp_res_madd_q_h[] = {
{0x7fff800080ae7fff, 0x9e136a5819f37fff},
{0x00000000fffe7c33, 0x54ab6bbcd2969038}};
const struct ExpectedResult_MSA3RF exp_res_msub_q_h[] = {
{0xffffffff80000000, 0x80007fff244c18ef},
{0x80007fff80007c32, 0x54ac6bbbf7df88e9}};
const struct ExpectedResult_MSA3RF exp_res_mulr_q_h[] = {
{0x7fff800100af7ffe, 0x1e13ea59fad35a75},
{0x7fff80017ffe0001, 0x00000000ed5b03a8}};
const struct ExpectedResult_MSA3RF exp_res_maddr_q_h[] = {
{0x7fff800080af7fff, 0x9e136a5819f37fff},
{0x00000000fffe7c34, 0x54ac6bbcd2969039}};
const struct ExpectedResult_MSA3RF exp_res_msubr_q_h[] = {
{0xffffffff80000001, 0x80007fff244d18ef},
{0x80007fff80007c32, 0x54ac6bbcf7e088e9}};
const struct ExpectedResult_MSA3RF exp_res_mul_q_w[] = {
{0x7fffffff80000001, 0x00001ff27ffffffe},
{0x1e12fcabea58f514, 0xfad3863a0de8dee1},
{0x7fffffff80000001, 0x7ffffffe0000019f},
{0xffffffff00004bab, 0x0234e1fbf6ca3ee0}};
const struct ExpectedResult_MSA3RF exp_res_madd_q_w[] = {
{0x7fffffff80000000, 0x80001ff27fffffff},
{0x9e12fcab6a58f513, 0xcbab7a632d095245},
{0x0000000000000000, 0xfffffffe7c33f49c},
{0xb5deb624939e1fa4, 0xe8778ff5601bd476}};
const struct ExpectedResult_MSA3RF exp_res_msub_q_w[] = {
{0xffffffffffffffff, 0x8000000000000000},
{0x800000007fffffff, 0xd6046dee11379482},
{0x800000007fffffff, 0x800000007c33f15d},
{0xb5deb625939d884d, 0xe40dcbfe728756b5}};
const struct ExpectedResult_MSA3RF exp_res_mulr_q_w[] = {
{0x7fffffff80000001, 0x00001ff37ffffffe},
{0x1e12fcabea58f514, 0xfad3863a0de8dee2},
{0x7fffffff80000001, 0x7ffffffe0000019f},
{0x0000000000004bac, 0x0234e1fcf6ca3ee1}};
const struct ExpectedResult_MSA3RF exp_res_maddr_q_w[] = {
{0x7fffffff80000000, 0x80001ff37fffffff},
{0x9e12fcab6a58f513, 0xcbab7a632d095246},
{0x0000000000000000, 0xfffffffe7c33f49c},
{0xb5deb625939e1fa5, 0xe8778ff6601bd477}};
const struct ExpectedResult_MSA3RF exp_res_msubr_q_w[] = {
{0xffffffffffffffff, 0x8000000000000001},
{0x800000007fffffff, 0xd6046def11379482},
{0x800000007fffffff, 0x800000007c33f15e},
{0xb5deb625939d884d, 0xe40dcbfe728756b5}};
#define TEST_FIXED_POINT_DF_H(instruction, src, exp_res) \
run_msa_3rf((src), (exp_res), \
[](MacroAssembler& assm) { __ instruction(w2, w0, w1); }, \
load_uint16_elements_of_vector, \
store_uint16_elements_of_vector);
#define TEST_FIXED_POINT_DF_W(instruction, src, exp_res) \
run_msa_3rf((src), (exp_res), \
[](MacroAssembler& assm) { __ instruction(w2, w0, w1); }, \
load_uint32_elements_of_vector, \
store_uint32_elements_of_vector);
for (uint64_t i = 0; i < arraysize(tc_h); i++) {
TEST_FIXED_POINT_DF_H(mul_q_h, &tc_h[i], &exp_res_mul_q_h[i])
TEST_FIXED_POINT_DF_H(madd_q_h, &tc_h[i], &exp_res_madd_q_h[i])
TEST_FIXED_POINT_DF_H(msub_q_h, &tc_h[i], &exp_res_msub_q_h[i])
TEST_FIXED_POINT_DF_H(mulr_q_h, &tc_h[i], &exp_res_mulr_q_h[i])
TEST_FIXED_POINT_DF_H(maddr_q_h, &tc_h[i], &exp_res_maddr_q_h[i])
TEST_FIXED_POINT_DF_H(msubr_q_h, &tc_h[i], &exp_res_msubr_q_h[i])
}
for (uint64_t i = 0; i < arraysize(tc_w); i++) {
TEST_FIXED_POINT_DF_W(mul_q_w, &tc_w[i], &exp_res_mul_q_w[i])
TEST_FIXED_POINT_DF_W(madd_q_w, &tc_w[i], &exp_res_madd_q_w[i])
TEST_FIXED_POINT_DF_W(msub_q_w, &tc_w[i], &exp_res_msub_q_w[i])
TEST_FIXED_POINT_DF_W(mulr_q_w, &tc_w[i], &exp_res_mulr_q_w[i])
TEST_FIXED_POINT_DF_W(maddr_q_w, &tc_w[i], &exp_res_maddr_q_w[i])
TEST_FIXED_POINT_DF_W(msubr_q_w, &tc_w[i], &exp_res_msubr_q_w[i])
}
#undef TEST_FIXED_POINT_DF_H
#undef TEST_FIXED_POINT_DF_W
}
TEST(MSA_fexdo) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
const float inf_float = std::numeric_limits<float>::infinity();
const float nan_float = std::numeric_limits<float>::quiet_NaN();
const double inf_double = std::numeric_limits<double>::infinity();
const struct TestCaseMsa3RF_F tc_w[] = {
// ws_1, ws_2, ws_3, ws_4, wt_1, wt_2, wt_3, wt_4, wd_1, wd_2, wd_3, wd_4
{inf_float, nan_float, 66505.f, 65504.f, 6.2e-5f, 5e-5f, -32.42f,
-inf_float, 0, 0, 0, 0},
{-0.f, 0.f, 123.567f, -765.321f, -6e-8f, 5.9e-8f, 1e-7f, -1e-20f, 0, 0, 0,
0},
{1e-36f, 1e20f, -1e20f, 2e-20f, 6e-8f, -2.9e-8f, -66505.f, -65504.f}};
const struct TestCaseMsa3RF_D tc_d[] = {
// ws_lo, ws_hi, wt_lo, wt_hi, wd_lo, wd_hi
{inf_double, -1234., 4e38, 3.4e38, 0, 0},
{1.2e-38, 1.1e-39, -38.92f, -inf_double, 0, 0},
{-0., 0., 123.567e31, -765.321e33, 0, 0},
{-1.5e-45, 1.3e-45, 1e-42, -1e-200, 0, 0},
{1e-202, 1e158, -1e159, 1e14, 0, 0},
{1.5e-42, 1.3e-46, -123.567e31, 765.321e33, 0, 0}};
const struct ExpRes_16I exp_res_fexdo_w[] = {
{static_cast<int16_t>(0x0410), static_cast<int16_t>(0x0347),
static_cast<int16_t>(0xd00d), static_cast<int16_t>(0xfc00),
static_cast<int16_t>(0x7c00), static_cast<int16_t>(0x7dff),
static_cast<int16_t>(0x7c00), static_cast<int16_t>(0x7bff)},
{static_cast<int16_t>(0x8001), static_cast<int16_t>(0x0001),
static_cast<int16_t>(0x0002), static_cast<int16_t>(0x8000),
static_cast<int16_t>(0x8000), static_cast<int16_t>(0x0000),
static_cast<int16_t>(0x57b9), static_cast<int16_t>(0xe1fb)},
{static_cast<int16_t>(0x0001), static_cast<int16_t>(0x8000),
static_cast<int16_t>(0xfc00), static_cast<int16_t>(0xfbff),
static_cast<int16_t>(0x0000), static_cast<int16_t>(0x7c00),
static_cast<int16_t>(0xfc00), static_cast<int16_t>(0x0000)}};
const struct ExpRes_32I exp_res_fexdo_d[] = {
{bit_cast<int32_t>(0x7f800000), bit_cast<int32_t>(0x7f7fc99e),
bit_cast<int32_t>(0x7f800000), bit_cast<int32_t>(0xc49a4000)},
{bit_cast<int32_t>(0xc21bae14), bit_cast<int32_t>(0xff800000),
bit_cast<int32_t>(0x0082ab1e), bit_cast<int32_t>(0x000bfa5a)},
{bit_cast<int32_t>(0x7673b164), bit_cast<int32_t>(0xfb13653d),
bit_cast<int32_t>(0x80000000), bit_cast<int32_t>(0x00000000)},
{bit_cast<int32_t>(0x000002ca), bit_cast<int32_t>(0x80000000),
bit_cast<int32_t>(0x80000001), bit_cast<int32_t>(0x00000001)},
{bit_cast<int32_t>(0xff800000), bit_cast<int32_t>(0x56b5e621),
bit_cast<int32_t>(0x00000000), bit_cast<int32_t>(0x7f800000)},
{bit_cast<int32_t>(0xf673b164), bit_cast<int32_t>(0x7b13653d),
bit_cast<int32_t>(0x0000042e), bit_cast<int32_t>(0x00000000)}};
#define TEST_FEXDO_H(instruction, src, exp_res) \
run_msa_3rf(reinterpret_cast<const struct TestCaseMsa3RF*>(src), \
reinterpret_cast<const struct ExpectedResult_MSA3RF*>(exp_res), \
[](MacroAssembler& assm) { __ instruction(w2, w0, w1); }, \
load_uint32_elements_of_vector, \
store_uint16_elements_of_vector);
#define TEST_FEXDO_W(instruction, src, exp_res) \
run_msa_3rf(reinterpret_cast<const struct TestCaseMsa3RF*>(src), \
reinterpret_cast<const struct ExpectedResult_MSA3RF*>(exp_res), \
[](MacroAssembler& assm) { __ instruction(w2, w0, w1); }, \
load_uint64_elements_of_vector, \
store_uint32_elements_of_vector);
for (uint64_t i = 0; i < arraysize(tc_w); i++) {
TEST_FEXDO_H(fexdo_h, &tc_w[i], &exp_res_fexdo_w[i])
}
for (uint64_t i = 0; i < arraysize(tc_d); i++) {
TEST_FEXDO_W(fexdo_w, &tc_d[i], &exp_res_fexdo_d[i])
}
#undef TEST_FEXDO_H
#undef TEST_FEXDO_W
}
TEST(MSA_ftq) {
if ((kArchVariant != kMips64r6) || !CpuFeatures::IsSupported(MIPS_SIMD))
return;
CcTest::InitializeVM();
const float nan_float = std::numeric_limits<float>::quiet_NaN();
const float inf_float = std::numeric_limits<float>::infinity();
const double nan_double = std::numeric_limits<double>::quiet_NaN();
const double inf_double = std::numeric_limits<double>::infinity();
const struct TestCaseMsa3RF_F tc_w[] = {
{1.f, -0.999f, 1.5f, -31e-6, 1e-7, -0.598, 0.0023, -0.f, 0, 0, 0, 0},
{100.f, -102.f, -1.1f, 1.3f, 0.f, -1.f, 0.9999f, -0.000322, 0, 0, 0, 0},
{nan_float, inf_float, -inf_float, -nan_float, -1e-40, 3e-44, 8.3e36,
-0.00003, 0, 0, 0, 0}};
const struct TestCaseMsa3RF_D tc_d[] = {
{1., -0.999, 1.5, -31e-6, 0, 0},
{1e-7, -0.598, 0.0023, -0.f, 0, 0},
{100.f, -102.f, -1.1f, 1.3f, 0, 0},
{0.f, -1.f, 0.9999f, -0.000322, 0, 0},
{nan_double, inf_double, -inf_double, -nan_double, 0, 0},
{-3e306, 2e-307, 9e307, 2e-307, 0, 0}};
const struct ExpRes_16I exp_res_ftq_w[] = {
{static_cast<int16_t>(0x0000), static_cast<int16_t>(0xb375),
static_cast<int16_t>(0x004b), static_cast<int16_t>(0x0000),
static_cast<int16_t>(0x7fff), static_cast<int16_t>(0x8021),
static_cast<int16_t>(0x7fff), static_cast<int16_t>(0xffff)},
{static_cast<int16_t>(0x0000), static_cast<int16_t>(0x8000),
static_cast<int16_t>(0x7ffd), static_cast<int16_t>(0xfff5),
static_cast<int16_t>(0x7fff), static_cast<int16_t>(0x8000),
static_cast<int16_t>(0x8000), static_cast<int16_t>(0x7fff)},
{static_cast<int16_t>(0x0000), static_cast<int16_t>(0x0000),
static_cast<int16_t>(0x7fff), static_cast<int16_t>(0xffff),
static_cast<int16_t>(0x0000), static_cast<int16_t>(0x7fff),
static_cast<int16_t>(0x8000), static_cast<int16_t>(0x0000)}};
const struct ExpRes_32I exp_res_ftq_d[] = {
{bit_cast<int32_t>(0x7fffffff), bit_cast<int32_t>(0xfffefbf4),
bit_cast<int32_t>(0x7fffffff), bit_cast<int32_t>(0x8020c49c)},
{bit_cast<int32_t>(0x004b5dcc), bit_cast<int32_t>(0x00000000),
bit_cast<int32_t>(0x000000d7), bit_cast<int32_t>(0xb374bc6a)},
{bit_cast<int32_t>(0x80000000), bit_cast<int32_t>(0x7fffffff),
bit_cast<int32_t>(0x7fffffff), bit_cast<int32_t>(0x80000000)},
{bit_cast<int32_t>(0x7ffcb900), bit_cast<int32_t>(0xfff572de),
bit_cast<int32_t>(0x00000000), bit_cast<int32_t>(0x80000000)},
{bit_cast<int32_t>(0x80000000), bit_cast<int32_t>(0x00000000),
bit_cast<int32_t>(0x00000000), bit_cast<int32_t>(0x7fffffff)},
{bit_cast<int32_t>(0x7fffffff), bit_cast<int32_t>(0x00000000),
bit_cast<int32_t>(0x80000000), bit_cast<int32_t>(0x00000000)}};
#define TEST_FTQ_H(instruction, src, exp_res) \
run_msa_3rf(reinterpret_cast<const struct TestCaseMsa3RF*>(src), \
reinterpret_cast<const struct ExpectedResult_MSA3RF*>(exp_res), \
[](MacroAssembler& assm) { __ instruction(w2, w0, w1); }, \
load_uint32_elements_of_vector, \
store_uint16_elements_of_vector);
#define TEST_FTQ_W(instruction, src, exp_res) \
run_msa_3rf(reinterpret_cast<const struct TestCaseMsa3RF*>(src), \
reinterpret_cast<const struct ExpectedResult_MSA3RF*>(exp_res), \
[](MacroAssembler& assm) { __ instruction(w2, w0, w1); }, \
load_uint64_elements_of_vector, \
store_uint32_elements_of_vector);
for (uint64_t i = 0; i < arraysize(tc_w); i++) {
TEST_FTQ_H(ftq_h, &tc_w[i], &exp_res_ftq_w[i])
}
for (uint64_t i = 0; i < arraysize(tc_d); i++) {
TEST_FTQ_W(ftq_w, &tc_d[i], &exp_res_ftq_d[i])
}
#undef TEST_FTQ_H
#undef TEST_FTQ_W
}
#undef __
} // namespace internal
} // namespace v8