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dart / sdk.git / 83735546dbc6ee32909fbb2e86e20365c114822e / . / runtime / vm / assembler_arm64_test.cc
blob: 1bd0644ace30684dd72016e35b0c5ea9f293c1f5 [file] [log] [blame]
// Copyright (c) 2013, the Dart project authors. Please see the AUTHORS file
// for details. All rights reserved. Use of this source code is governed by a
// BSD-style license that can be found in the LICENSE file.
#include "vm/globals.h"
#if defined(TARGET_ARCH_ARM64)
#include "vm/assembler.h"
#include "vm/cpu.h"
#include "vm/os.h"
#include "vm/unit_test.h"
#include "vm/virtual_memory.h"
namespace dart {
#define __ assembler->
ASSEMBLER_TEST_GENERATE(Simple, assembler) {
__ add(R0, ZR, Operand(ZR));
__ add(R0, R0, Operand(42));
__ ret();
}
ASSEMBLER_TEST_RUN(Simple, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
// Move wide immediate tests.
// movz
ASSEMBLER_TEST_GENERATE(Movz0, assembler) {
__ movz(R0, Immediate(42), 0);
__ ret();
}
ASSEMBLER_TEST_RUN(Movz0, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Movz1, assembler) {
__ movz(R0, Immediate(42), 0); // Overwritten by next instruction.
__ movz(R0, Immediate(42), 1);
__ ret();
}
ASSEMBLER_TEST_RUN(Movz1, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42LL << 16, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Movz2, assembler) {
__ movz(R0, Immediate(42), 2);
__ ret();
}
ASSEMBLER_TEST_RUN(Movz2, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42LL << 32, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Movz3, assembler) {
__ movz(R0, Immediate(42), 3);
__ ret();
}
ASSEMBLER_TEST_RUN(Movz3, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42LL << 48, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
// movn
ASSEMBLER_TEST_GENERATE(Movn0, assembler) {
__ movn(R0, Immediate(42), 0);
__ ret();
}
ASSEMBLER_TEST_RUN(Movn0, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(~42LL, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Movn1, assembler) {
__ movn(R0, Immediate(42), 1);
__ ret();
}
ASSEMBLER_TEST_RUN(Movn1, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(~(42LL << 16), EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Movn2, assembler) {
__ movn(R0, Immediate(42), 2);
__ ret();
}
ASSEMBLER_TEST_RUN(Movn2, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(~(42LL << 32), EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Movn3, assembler) {
__ movn(R0, Immediate(42), 3);
__ ret();
}
ASSEMBLER_TEST_RUN(Movn3, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(~(42LL << 48), EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
// movk
ASSEMBLER_TEST_GENERATE(Movk0, assembler) {
__ movz(R0, Immediate(1), 3);
__ movk(R0, Immediate(42), 0);
__ ret();
}
ASSEMBLER_TEST_RUN(Movk0, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42LL | (1LL << 48),
EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Movk1, assembler) {
__ movz(R0, Immediate(1), 0);
__ movk(R0, Immediate(42), 1);
__ ret();
}
ASSEMBLER_TEST_RUN(Movk1, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ((42LL << 16) | 1,
EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Movk2, assembler) {
__ movz(R0, Immediate(1), 0);
__ movk(R0, Immediate(42), 2);
__ ret();
}
ASSEMBLER_TEST_RUN(Movk2, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ((42LL << 32) | 1,
EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Movk3, assembler) {
__ movz(R0, Immediate(1), 0);
__ movk(R0, Immediate(42), 3);
__ ret();
}
ASSEMBLER_TEST_RUN(Movk3, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ((42LL << 48) | 1,
EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(MovzBig, assembler) {
__ movz(R0, Immediate(0x8000), 0);
__ ret();
}
ASSEMBLER_TEST_RUN(MovzBig, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(0x8000, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
// add tests.
ASSEMBLER_TEST_GENERATE(AddReg, assembler) {
__ movz(R0, Immediate(20), 0);
__ movz(R1, Immediate(22), 0);
__ add(R0, R0, Operand(R1));
__ ret();
}
ASSEMBLER_TEST_RUN(AddReg, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(AddLSLReg, assembler) {
__ movz(R0, Immediate(20), 0);
__ movz(R1, Immediate(11), 0);
__ add(R0, R0, Operand(R1, LSL, 1));
__ ret();
}
ASSEMBLER_TEST_RUN(AddLSLReg, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(AddLSRReg, assembler) {
__ movz(R0, Immediate(20), 0);
__ movz(R1, Immediate(44), 0);
__ add(R0, R0, Operand(R1, LSR, 1));
__ ret();
}
ASSEMBLER_TEST_RUN(AddLSRReg, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(AddASRReg, assembler) {
__ movz(R0, Immediate(20), 0);
__ movz(R1, Immediate(44), 0);
__ add(R0, R0, Operand(R1, ASR, 1));
__ ret();
}
ASSEMBLER_TEST_RUN(AddASRReg, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(AddASRNegReg, assembler) {
__ movz(R0, Immediate(43), 0);
__ movn(R1, Immediate(0), 0); // R1 <- -1
__ add(R1, ZR, Operand(R1, LSL, 3)); // R1 <- -8
__ add(R0, R0, Operand(R1, ASR, 3)); // R0 <- 43 + (-8 >> 3)
__ ret();
}
ASSEMBLER_TEST_RUN(AddASRNegReg, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
// TODO(zra): test other sign extension modes.
ASSEMBLER_TEST_GENERATE(AddExtReg, assembler) {
__ movz(R0, Immediate(43), 0);
__ movz(R1, Immediate(0xffff), 0);
__ movk(R1, Immediate(0xffff), 1); // R1 <- -1 (32-bit)
__ add(R0, R0, Operand(R1, SXTW, 0)); // R0 <- R0 + (sign extended R1)
__ ret();
}
ASSEMBLER_TEST_RUN(AddExtReg, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(AddCarryInOut, assembler) {
__ LoadImmediate(R2, -1);
__ LoadImmediate(R1, 1);
__ LoadImmediate(R0, 0);
__ adds(IP0, R2, Operand(R1)); // c_out = 1.
__ adcs(IP0, R2, R0); // c_in = 1, c_out = 1.
__ adc(R0, R0, R0); // c_in = 1.
__ ret();
}
ASSEMBLER_TEST_RUN(AddCarryInOut, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(1, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(SubCarryInOut, assembler) {
__ LoadImmediate(R1, 1);
__ LoadImmediate(R0, 0);
__ subs(IP0, R0, Operand(R1)); // c_out = 1.
__ sbcs(IP0, R0, R0); // c_in = 1, c_out = 1.
__ sbc(R0, R0, R0); // c_in = 1.
__ ret();
}
ASSEMBLER_TEST_RUN(SubCarryInOut, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(-1, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Overflow, assembler) {
__ LoadImmediate(R0, 0);
__ LoadImmediate(R1, 1);
__ LoadImmediate(R2, 0xFFFFFFFFFFFFFFFF);
__ LoadImmediate(R3, 0x7FFFFFFFFFFFFFFF);
__ adds(IP0, R2, Operand(R1)); // c_out = 1.
__ adcs(IP0, R3, R0); // c_in = 1, c_out = 1, v = 1.
__ csinc(R0, R0, R0, VS); // R0 = v ? R0 : R0 + 1.
__ ret();
}
ASSEMBLER_TEST_RUN(Overflow, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(0, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(WordAddCarryInOut, assembler) {
__ LoadImmediate(R2, -1);
__ LoadImmediate(R1, 1);
__ LoadImmediate(R0, 0);
__ addsw(IP0, R2, Operand(R1)); // c_out = 1.
__ adcsw(IP0, R2, R0); // c_in = 1, c_out = 1.
__ adcw(R0, R0, R0); // c_in = 1.
__ ret();
}
ASSEMBLER_TEST_RUN(WordAddCarryInOut, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(1, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(WordSubCarryInOut, assembler) {
__ LoadImmediate(R1, 1);
__ LoadImmediate(R0, 0);
__ subsw(IP0, R0, Operand(R1)); // c_out = 1.
__ sbcsw(IP0, R0, R0); // c_in = 1, c_out = 1.
__ sbcw(R0, R0, R0); // c_in = 1.
__ ret();
}
ASSEMBLER_TEST_RUN(WordSubCarryInOut, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(0x0FFFFFFFF, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(WordOverflow, assembler) {
__ LoadImmediate(R0, 0);
__ LoadImmediate(R1, 1);
__ LoadImmediate(R2, 0xFFFFFFFF);
__ LoadImmediate(R3, 0x7FFFFFFF);
__ addsw(IP0, R2, Operand(R1)); // c_out = 1.
__ adcsw(IP0, R3, R0); // c_in = 1, c_out = 1, v = 1.
__ csinc(R0, R0, R0, VS); // R0 = v ? R0 : R0 + 1.
__ ret();
}
ASSEMBLER_TEST_RUN(WordOverflow, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(0, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
// Loads and Stores.
ASSEMBLER_TEST_GENERATE(SimpleLoadStore, assembler) {
__ SetupDartSP();
__ movz(R0, Immediate(43), 0);
__ movz(R1, Immediate(42), 0);
__ str(R1, Address(SP, -1 * kWordSize, Address::PreIndex));
__ ldr(R0, Address(SP, 1 * kWordSize, Address::PostIndex));
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(SimpleLoadStore, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(SimpleLoadStoreHeapTag, assembler) {
__ SetupDartSP();
__ movz(R0, Immediate(43), 0);
__ movz(R1, Immediate(42), 0);
__ add(R2, SP, Operand(1));
__ str(R1, Address(R2, -1));
__ ldr(R0, Address(R2, -1));
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(SimpleLoadStoreHeapTag, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(LoadStoreLargeIndex, assembler) {
__ SetupDartSP();
__ movz(R0, Immediate(43), 0);
__ movz(R1, Immediate(42), 0);
// Largest negative offset that can fit in the signed 9-bit immediate field.
__ str(R1, Address(SP, -32 * kWordSize, Address::PreIndex));
// Largest positive kWordSize aligned offset that we can fit.
__ ldr(R0, Address(SP, 31 * kWordSize, Address::PostIndex));
// Correction.
__ add(SP, SP, Operand(kWordSize)); // Restore SP.
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(LoadStoreLargeIndex, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(LoadStoreLargeOffset, assembler) {
__ SetupDartSP();
__ movz(R0, Immediate(43), 0);
__ movz(R1, Immediate(42), 0);
__ sub(SP, SP, Operand(512 * kWordSize));
__ str(R1, Address(SP, 512 * kWordSize, Address::Offset));
__ add(SP, SP, Operand(512 * kWordSize));
__ ldr(R0, Address(SP));
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(LoadStoreLargeOffset, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(LoadStoreExtReg, assembler) {
__ SetupDartSP();
__ movz(R0, Immediate(43), 0);
__ movz(R1, Immediate(42), 0);
__ movz(R2, Immediate(0xfff8), 0);
__ movk(R2, Immediate(0xffff), 1); // R2 <- -8 (int32_t).
// This should sign extend R2, and add to SP to get address,
// i.e. SP - kWordSize.
__ str(R1, Address(SP, R2, SXTW));
__ sub(SP, SP, Operand(kWordSize));
__ ldr(R0, Address(SP));
__ add(SP, SP, Operand(kWordSize));
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(LoadStoreExtReg, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(LoadStoreScaledReg, assembler) {
__ SetupDartSP();
__ movz(R0, Immediate(43), 0);
__ movz(R1, Immediate(42), 0);
__ movz(R2, Immediate(10), 0);
__ sub(SP, SP, Operand(10 * kWordSize));
// Store R1 into SP + R2 * kWordSize.
__ str(R1, Address(SP, R2, UXTX, Address::Scaled));
__ ldr(R0, Address(SP, R2, UXTX, Address::Scaled));
__ add(SP, SP, Operand(10 * kWordSize));
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(LoadStoreScaledReg, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(LoadSigned32Bit, assembler) {
__ SetupDartSP();
__ LoadImmediate(R1, 0xffffffff);
__ str(R1, Address(SP, -4, Address::PreIndex, kWord), kWord);
__ ldr(R0, Address(SP), kWord);
__ ldr(R1, Address(SP, 4, Address::PostIndex, kWord), kWord);
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(LoadSigned32Bit, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(-1, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(SimpleLoadStorePair, assembler) {
__ SetupDartSP();
__ LoadImmediate(R2, 43);
__ LoadImmediate(R3, 42);
__ stp(R2, R3, Address(SP, -2 * kWordSize, Address::PairPreIndex));
__ ldp(R0, R1, Address(SP, 2 * kWordSize, Address::PairPostIndex));
__ sub(R0, R0, Operand(R1));
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(SimpleLoadStorePair, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(1, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(LoadStorePairOffset, assembler) {
__ SetupDartSP();
__ LoadImmediate(R2, 43);
__ LoadImmediate(R3, 42);
__ sub(SP, SP, Operand(4 * kWordSize));
__ stp(R2, R3, Address::Pair(SP, 2 * kWordSize));
__ ldp(R0, R1, Address::Pair(SP, 2 * kWordSize));
__ add(SP, SP, Operand(4 * kWordSize));
__ sub(R0, R0, Operand(R1));
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(LoadStorePairOffset, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(1, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Semaphore, assembler) {
__ SetupDartSP();
__ movz(R0, Immediate(40), 0);
__ movz(R1, Immediate(42), 0);
__ Push(R0);
Label retry;
__ Bind(&retry);
__ ldxr(R0, SP);
__ stxr(TMP, R1, SP); // IP == 0, success
__ cmp(TMP, Operand(0));
__ b(&retry, NE); // NE if context switch occurred between ldrex and strex.
__ Pop(R0); // 42
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(Semaphore, test) {
EXPECT(test != NULL);
typedef int (*Semaphore)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Semaphore, test->entry()));
}
ASSEMBLER_TEST_GENERATE(FailedSemaphore, assembler) {
__ SetupDartSP();
__ movz(R0, Immediate(40), 0);
__ movz(R1, Immediate(42), 0);
__ Push(R0);
__ ldxr(R0, SP);
__ clrex(); // Simulate a context switch.
__ stxr(TMP, R1, SP); // IP == 1, failure
__ Pop(R0); // 40
__ add(R0, R0, Operand(TMP));
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(FailedSemaphore, test) {
EXPECT(test != NULL);
typedef int (*FailedSemaphore)() DART_UNUSED;
EXPECT_EQ(41, EXECUTE_TEST_CODE_INT64(FailedSemaphore, test->entry()));
}
// Logical register operations.
ASSEMBLER_TEST_GENERATE(AndRegs, assembler) {
__ movz(R1, Immediate(43), 0);
__ movz(R2, Immediate(42), 0);
__ and_(R0, R1, Operand(R2));
__ ret();
}
ASSEMBLER_TEST_RUN(AndRegs, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(AndShiftRegs, assembler) {
__ movz(R1, Immediate(42), 0);
__ movz(R2, Immediate(21), 0);
__ and_(R0, R1, Operand(R2, LSL, 1));
__ ret();
}
ASSEMBLER_TEST_RUN(AndShiftRegs, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(BicRegs, assembler) {
__ movz(R1, Immediate(42), 0);
__ movz(R2, Immediate(5), 0);
__ bic(R0, R1, Operand(R2));
__ ret();
}
ASSEMBLER_TEST_RUN(BicRegs, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(OrrRegs, assembler) {
__ movz(R1, Immediate(32), 0);
__ movz(R2, Immediate(10), 0);
__ orr(R0, R1, Operand(R2));
__ ret();
}
ASSEMBLER_TEST_RUN(OrrRegs, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(OrnRegs, assembler) {
__ movz(R1, Immediate(32), 0);
__ movn(R2, Immediate(0), 0); // R2 <- 0xffffffffffffffff.
__ movk(R2, Immediate(0xffd5), 0); // R2 <- 0xffffffffffffffe5.
__ orn(R0, R1, Operand(R2));
__ ret();
}
ASSEMBLER_TEST_RUN(OrnRegs, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(EorRegs, assembler) {
__ movz(R1, Immediate(0xffd5), 0);
__ movz(R2, Immediate(0xffff), 0);
__ eor(R0, R1, Operand(R2));
__ ret();
}
ASSEMBLER_TEST_RUN(EorRegs, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(EonRegs, assembler) {
__ movz(R1, Immediate(0xffd5), 0);
__ movn(R2, Immediate(0xffff), 0);
__ eon(R0, R1, Operand(R2));
__ ret();
}
ASSEMBLER_TEST_RUN(EonRegs, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
// Logical immediate operations.
ASSEMBLER_TEST_GENERATE(AndImm, assembler) {
__ movz(R1, Immediate(42), 0);
__ andi(R0, R1, Immediate(0xaaaaaaaaaaaaaaaaULL));
__ ret();
}
ASSEMBLER_TEST_RUN(AndImm, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(AndImmCsp, assembler) {
// Note we must maintain the ARM64 ABI invariants on CSP here.
__ mov(TMP, CSP);
__ sub(TMP2, CSP, Operand(31));
__ andi(CSP, TMP2, Immediate(~15));
__ mov(R0, CSP);
__ sub(R0, TMP, Operand(R0));
__ mov(CSP, TMP);
__ ret();
}
ASSEMBLER_TEST_RUN(AndImmCsp, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(32, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(AndOneImm, assembler) {
__ movz(R1, Immediate(43), 0);
__ andi(R0, R1, Immediate(1));
__ ret();
}
ASSEMBLER_TEST_RUN(AndOneImm, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(1, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(OrrImm, assembler) {
__ movz(R1, Immediate(0), 0);
__ movz(R2, Immediate(0x3f), 0);
__ movz(R3, Immediate(0xa), 0);
__ orri(R1, R1, Immediate(0x0020002000200020ULL));
__ orr(R1, R1, Operand(R3));
__ and_(R0, R1, Operand(R2));
__ ret();
}
ASSEMBLER_TEST_RUN(OrrImm, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(EorImm, assembler) {
__ movn(R0, Immediate(0), 0);
__ movk(R0, Immediate(0xffd5), 0); // R0 < 0xffffffffffffffd5.
__ movz(R1, Immediate(0x3f), 0);
__ eori(R0, R0, Immediate(0x3f3f3f3f3f3f3f3fULL));
__ and_(R0, R0, Operand(R1));
__ ret();
}
ASSEMBLER_TEST_RUN(EorImm, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Clz, assembler) {
Label error;
__ clz(R1, ZR);
__ cmp(R1, Operand(64));
__ b(&error, NE);
__ LoadImmediate(R2, 42);
__ clz(R2, R2);
__ cmp(R2, Operand(58));
__ b(&error, NE);
__ LoadImmediate(R0, -1);
__ clz(R1, R0);
__ cmp(R1, Operand(0));
__ b(&error, NE);
__ add(R0, ZR, Operand(R0, LSR, 3));
__ clz(R1, R0);
__ cmp(R1, Operand(3));
__ b(&error, NE);
__ mov(R0, ZR);
__ ret();
__ Bind(&error);
__ LoadImmediate(R0, 1);
__ ret();
}
ASSEMBLER_TEST_RUN(Clz, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(0, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
// Comparisons, branching.
ASSEMBLER_TEST_GENERATE(BranchALForward, assembler) {
Label l;
__ movz(R0, Immediate(42), 0);
__ b(&l, AL);
__ movz(R0, Immediate(0), 0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(BranchALForward, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(BranchALBackwards, assembler) {
Label l, leave;
__ movz(R0, Immediate(42), 0);
__ b(&l, AL);
__ movz(R0, Immediate(0), 0);
__ Bind(&leave);
__ ret();
__ movz(R0, Immediate(0), 0);
__ Bind(&l);
__ b(&leave, AL);
__ movz(R0, Immediate(0), 0);
__ ret();
}
ASSEMBLER_TEST_RUN(BranchALBackwards, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(CmpEqBranch, assembler) {
Label l;
__ movz(R0, Immediate(42), 0);
__ movz(R1, Immediate(234), 0);
__ movz(R2, Immediate(234), 0);
__ cmp(R1, Operand(R2));
__ b(&l, EQ);
__ movz(R0, Immediate(0), 0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(CmpEqBranch, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(CmpEqBranchNotTaken, assembler) {
Label l;
__ movz(R0, Immediate(0), 0);
__ movz(R1, Immediate(233), 0);
__ movz(R2, Immediate(234), 0);
__ cmp(R1, Operand(R2));
__ b(&l, EQ);
__ movz(R0, Immediate(42), 0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(CmpEqBranchNotTaken, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(CmpEq1Branch, assembler) {
Label l;
__ movz(R0, Immediate(42), 0);
__ movz(R1, Immediate(1), 0);
__ cmp(R1, Operand(1));
__ b(&l, EQ);
__ movz(R0, Immediate(0), 0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(CmpEq1Branch, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(CmnEq1Branch, assembler) {
Label l;
__ movz(R0, Immediate(42), 0);
__ movn(R1, Immediate(0), 0); // R1 <- -1
__ cmn(R1, Operand(1));
__ b(&l, EQ);
__ movz(R0, Immediate(0), 0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(CmnEq1Branch, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(CmpLtBranch, assembler) {
Label l;
__ movz(R0, Immediate(42), 0);
__ movz(R1, Immediate(233), 0);
__ movz(R2, Immediate(234), 0);
__ cmp(R1, Operand(R2));
__ b(&l, LT);
__ movz(R0, Immediate(0), 0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(CmpLtBranch, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(CmpLtBranchNotTaken, assembler) {
Label l;
__ movz(R0, Immediate(0), 0);
__ movz(R1, Immediate(235), 0);
__ movz(R2, Immediate(234), 0);
__ cmp(R1, Operand(R2));
__ b(&l, LT);
__ movz(R0, Immediate(42), 0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(CmpLtBranchNotTaken, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(CmpBranchIfZero, assembler) {
Label l;
__ movz(R0, Immediate(42), 0);
__ movz(R1, Immediate(0), 0);
__ cbz(&l, R1);
__ movz(R0, Immediate(0), 0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(CmpBranchIfZero, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(CmpBranchIfZeroNotTaken, assembler) {
Label l;
__ movz(R0, Immediate(0), 0);
__ movz(R1, Immediate(1), 0);
__ cbz(&l, R1);
__ movz(R0, Immediate(42), 0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(CmpBranchIfZeroNotTaken, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(CmpBranchIfNotZero, assembler) {
Label l;
__ movz(R0, Immediate(42), 0);
__ movz(R1, Immediate(1), 0);
__ cbnz(&l, R1);
__ movz(R0, Immediate(0), 0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(CmpBranchIfNotZero, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(CmpBranchIfNotZeroNotTaken, assembler) {
Label l;
__ movz(R0, Immediate(0), 0);
__ movz(R1, Immediate(0), 0);
__ cbnz(&l, R1);
__ movz(R0, Immediate(42), 0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(CmpBranchIfNotZeroNotTaken, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(FcmpEqBranch, assembler) {
Label l;
__ LoadDImmediate(V0, 42.0);
__ LoadDImmediate(V1, 234.0);
__ LoadDImmediate(V2, 234.0);
__ fcmpd(V1, V2);
__ b(&l, EQ);
__ LoadDImmediate(V0, 0.0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(FcmpEqBranch, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(FcmpEqBranchNotTaken, assembler) {
Label l;
__ LoadDImmediate(V0, 0.0);
__ LoadDImmediate(V1, 233.0);
__ LoadDImmediate(V2, 234.0);
__ fcmpd(V1, V2);
__ b(&l, EQ);
__ LoadDImmediate(V0, 42.0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(FcmpEqBranchNotTaken, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(FcmpLtBranch, assembler) {
Label l;
__ LoadDImmediate(V0, 42.0);
__ LoadDImmediate(V1, 233.0);
__ LoadDImmediate(V2, 234.0);
__ fcmpd(V1, V2);
__ b(&l, LT);
__ LoadDImmediate(V0, 0.0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(FcmpLtBranch, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(FcmpLtBranchNotTaken, assembler) {
Label l;
__ LoadDImmediate(V0, 0.0);
__ LoadDImmediate(V1, 235.0);
__ LoadDImmediate(V2, 234.0);
__ fcmpd(V1, V2);
__ b(&l, LT);
__ LoadDImmediate(V0, 42.0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(FcmpLtBranchNotTaken, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(FcmpzGtBranch, assembler) {
Label l;
__ LoadDImmediate(V0, 235.0);
__ LoadDImmediate(V1, 233.0);
__ fcmpdz(V1);
__ b(&l, GT);
__ LoadDImmediate(V0, 0.0);
__ ret();
__ Bind(&l);
__ LoadDImmediate(V0, 42.0);
__ ret();
}
ASSEMBLER_TEST_RUN(FcmpzGtBranch, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(AndsBranch, assembler) {
Label l;
__ movz(R0, Immediate(42), 0);
__ movz(R1, Immediate(2), 0);
__ movz(R2, Immediate(1), 0);
__ ands(R3, R1, Operand(R2));
__ b(&l, EQ);
__ movz(R0, Immediate(0), 0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(AndsBranch, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(AndsBranchNotTaken, assembler) {
Label l;
__ movz(R0, Immediate(0), 0);
__ movz(R1, Immediate(2), 0);
__ movz(R2, Immediate(2), 0);
__ ands(R3, R1, Operand(R2));
__ b(&l, EQ);
__ movz(R0, Immediate(42), 0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(AndsBranchNotTaken, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(BicsBranch, assembler) {
Label l;
__ movz(R0, Immediate(42), 0);
__ movz(R1, Immediate(2), 0);
__ movz(R2, Immediate(2), 0);
__ bics(R3, R1, Operand(R2));
__ b(&l, EQ);
__ movz(R0, Immediate(0), 0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(BicsBranch, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(BicsBranchNotTaken, assembler) {
Label l;
__ movz(R0, Immediate(0), 0);
__ movz(R1, Immediate(2), 0);
__ movz(R2, Immediate(1), 0);
__ bics(R3, R1, Operand(R2));
__ b(&l, EQ);
__ movz(R0, Immediate(42), 0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(BicsBranchNotTaken, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(AndisBranch, assembler) {
Label l;
__ movz(R0, Immediate(42), 0);
__ movz(R1, Immediate(2), 0);
__ andis(R3, R1, Immediate(1));
__ b(&l, EQ);
__ movz(R0, Immediate(0), 0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(AndisBranch, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(AndisBranchNotTaken, assembler) {
Label l;
__ movz(R0, Immediate(0), 0);
__ movz(R1, Immediate(2), 0);
__ andis(R3, R1, Immediate(2));
__ b(&l, EQ);
__ movz(R0, Immediate(42), 0);
__ Bind(&l);
__ ret();
}
ASSEMBLER_TEST_RUN(AndisBranchNotTaken, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
// Address of PC-rel offset, br, blr.
ASSEMBLER_TEST_GENERATE(AdrBr, assembler) {
__ movz(R0, Immediate(123), 0);
// R1 <- PC + 3*Instr::kInstrSize
__ adr(R1, Immediate(3 * Instr::kInstrSize));
__ br(R1);
__ ret();
// br goes here.
__ movz(R0, Immediate(42), 0);
__ ret();
}
ASSEMBLER_TEST_RUN(AdrBr, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(AdrBlr, assembler) {
__ movz(R0, Immediate(123), 0);
__ add(R3, ZR, Operand(LR)); // Save LR.
// R1 <- PC + 4*Instr::kInstrSize
__ adr(R1, Immediate(4 * Instr::kInstrSize));
__ blr(R1);
__ add(LR, ZR, Operand(R3));
__ ret();
// blr goes here.
__ movz(R0, Immediate(42), 0);
__ ret();
}
ASSEMBLER_TEST_RUN(AdrBlr, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
// Misc. arithmetic.
ASSEMBLER_TEST_GENERATE(Udiv, assembler) {
__ movz(R0, Immediate(27), 0);
__ movz(R1, Immediate(9), 0);
__ udiv(R2, R0, R1);
__ mov(R0, R2);
__ ret();
}
ASSEMBLER_TEST_RUN(Udiv, test) {
EXPECT(test != NULL);
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(3, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Sdiv, assembler) {
__ movz(R0, Immediate(27), 0);
__ movz(R1, Immediate(9), 0);
__ neg(R1, R1);
__ sdiv(R2, R0, R1);
__ mov(R0, R2);
__ ret();
}
ASSEMBLER_TEST_RUN(Sdiv, test) {
EXPECT(test != NULL);
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(-3, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Udiv_zero, assembler) {
__ movz(R0, Immediate(27), 0);
__ movz(R1, Immediate(0), 0);
__ udiv(R2, R0, R1);
__ mov(R0, R2);
__ ret();
}
ASSEMBLER_TEST_RUN(Udiv_zero, test) {
EXPECT(test != NULL);
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(0, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Sdiv_zero, assembler) {
__ movz(R0, Immediate(27), 0);
__ movz(R1, Immediate(0), 0);
__ sdiv(R2, R0, R1);
__ mov(R0, R2);
__ ret();
}
ASSEMBLER_TEST_RUN(Sdiv_zero, test) {
EXPECT(test != NULL);
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(0, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Udiv_corner, assembler) {
__ movz(R0, Immediate(0x8000), 3); // R0 <- 0x8000000000000000
__ movn(R1, Immediate(0), 0); // R1 <- 0xffffffffffffffff
__ udiv(R2, R0, R1);
__ mov(R0, R2);
__ ret();
}
ASSEMBLER_TEST_RUN(Udiv_corner, test) {
EXPECT(test != NULL);
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(0, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Sdiv_corner, assembler) {
__ movz(R3, Immediate(0x8000), 3); // R0 <- 0x8000000000000000
__ movn(R1, Immediate(0), 0); // R1 <- 0xffffffffffffffff
__ sdiv(R2, R3, R1);
__ mov(R0, R2);
__ ret();
}
ASSEMBLER_TEST_RUN(Sdiv_corner, test) {
EXPECT(test != NULL);
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(static_cast<int64_t>(0x8000000000000000),
EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Lslv, assembler) {
__ movz(R1, Immediate(21), 0);
__ movz(R2, Immediate(1), 0);
__ lslv(R0, R1, R2);
__ ret();
}
ASSEMBLER_TEST_RUN(Lslv, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Lsrv, assembler) {
__ movz(R1, Immediate(84), 0);
__ movz(R2, Immediate(1), 0);
__ lsrv(R0, R1, R2);
__ ret();
}
ASSEMBLER_TEST_RUN(Lsrv, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(LShiftingV, assembler) {
__ movz(R1, Immediate(1), 0);
__ movz(R2, Immediate(63), 0);
__ lslv(R1, R1, R2);
__ lsrv(R0, R1, R2);
__ ret();
}
ASSEMBLER_TEST_RUN(LShiftingV, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(1, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(RShiftingV, assembler) {
__ movz(R1, Immediate(1), 0);
__ movz(R2, Immediate(63), 0);
__ lslv(R1, R1, R2);
__ asrv(R0, R1, R2);
__ ret();
}
ASSEMBLER_TEST_RUN(RShiftingV, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(-1, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Mult_pos, assembler) {
__ movz(R1, Immediate(6), 0);
__ movz(R2, Immediate(7), 0);
__ mul(R0, R1, R2);
__ ret();
}
ASSEMBLER_TEST_RUN(Mult_pos, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Mult_neg, assembler) {
__ movz(R1, Immediate(6), 0);
__ movz(R2, Immediate(7), 0);
__ neg(R2, R2);
__ mul(R0, R1, R2);
__ ret();
}
ASSEMBLER_TEST_RUN(Mult_neg, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(-42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Smulh_pos, assembler) {
__ movz(R1, Immediate(6), 0);
__ movz(R2, Immediate(7), 0);
__ smulh(R0, R1, R2);
__ ret();
}
ASSEMBLER_TEST_RUN(Smulh_pos, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(0, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Smulh_neg, assembler) {
__ movz(R1, Immediate(6), 0);
__ movz(R2, Immediate(7), 0);
__ neg(R2, R2);
__ smulh(R0, R1, R2);
__ ret();
}
ASSEMBLER_TEST_RUN(Smulh_neg, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(-1, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Umulh, assembler) {
__ movz(R1, Immediate(-1), 3); // 0xffff000000000000
__ movz(R2, Immediate(7), 3); // 0x0007000000000000
__ umulh(R0, R1, R2); // 0x0006fff900000000
__ ret();
}
ASSEMBLER_TEST_RUN(Umulh, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(static_cast<int64_t>(0x6fff900000000),
EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Umaddl, assembler) {
__ movn(R1, Immediate(0), 0); // W1 = 0xffffffff.
__ movz(R2, Immediate(7), 0); // W2 = 7.
__ movz(R3, Immediate(8), 0); // X3 = 8.
__ umaddl(R0, R1, R2, R3); // X0 = W1*W2 + X3 = 0x700000001.
__ ret();
}
ASSEMBLER_TEST_RUN(Umaddl, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(0x700000001, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
// Loading immediate values without the object pool.
ASSEMBLER_TEST_GENERATE(LoadImmediateSmall, assembler) {
__ LoadImmediate(R0, 42);
__ ret();
}
ASSEMBLER_TEST_RUN(LoadImmediateSmall, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(LoadImmediateMed, assembler) {
__ LoadImmediate(R0, 0xf1234123);
__ ret();
}
ASSEMBLER_TEST_RUN(LoadImmediateMed, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(0xf1234123, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(LoadImmediateMed2, assembler) {
__ LoadImmediate(R0, 0x4321f1234123);
__ ret();
}
ASSEMBLER_TEST_RUN(LoadImmediateMed2, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(0x4321f1234123,
EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(LoadImmediateLarge, assembler) {
__ LoadImmediate(R0, 0x9287436598237465);
__ ret();
}
ASSEMBLER_TEST_RUN(LoadImmediateLarge, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(static_cast<int64_t>(0x9287436598237465),
EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(LoadImmediateSmallNeg, assembler) {
__ LoadImmediate(R0, -42);
__ ret();
}
ASSEMBLER_TEST_RUN(LoadImmediateSmallNeg, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(-42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(LoadImmediateMedNeg, assembler) {
__ LoadImmediate(R0, -0x1212341234);
__ ret();
}
ASSEMBLER_TEST_RUN(LoadImmediateMedNeg, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(-0x1212341234, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(LoadImmediateMedNeg2, assembler) {
__ LoadImmediate(R0, -0x1212340000);
__ ret();
}
ASSEMBLER_TEST_RUN(LoadImmediateMedNeg2, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(-0x1212340000, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(LoadImmediateMedNeg3, assembler) {
__ LoadImmediate(R0, -0x1200001234);
__ ret();
}
ASSEMBLER_TEST_RUN(LoadImmediateMedNeg3, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(-0x1200001234, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(LoadImmediateMedNeg4, assembler) {
__ LoadImmediate(R0, -0x12341234);
__ ret();
}
ASSEMBLER_TEST_RUN(LoadImmediateMedNeg4, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(-0x12341234, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(LoadHalfWordUnaligned, assembler) {
__ LoadUnaligned(R1, R0, TMP, kHalfword);
__ mov(R0, R1);
__ ret();
}
ASSEMBLER_TEST_RUN(LoadHalfWordUnaligned, test) {
EXPECT(test != NULL);
typedef intptr_t (*LoadHalfWordUnaligned)(intptr_t) DART_UNUSED;
uint8_t buffer[4] = {
0x89, 0xAB, 0xCD, 0xEF,
};
EXPECT_EQ(
static_cast<int16_t>(static_cast<uint16_t>(0xAB89)),
EXECUTE_TEST_CODE_INTPTR_INTPTR(LoadHalfWordUnaligned, test->entry(),
reinterpret_cast<intptr_t>(&buffer[0])));
EXPECT_EQ(
static_cast<int16_t>(static_cast<uint16_t>(0xCDAB)),
EXECUTE_TEST_CODE_INTPTR_INTPTR(LoadHalfWordUnaligned, test->entry(),
reinterpret_cast<intptr_t>(&buffer[1])));
}
ASSEMBLER_TEST_GENERATE(LoadHalfWordUnsignedUnaligned, assembler) {
__ LoadUnaligned(R1, R0, TMP, kUnsignedHalfword);
__ mov(R0, R1);
__ ret();
}
ASSEMBLER_TEST_RUN(LoadHalfWordUnsignedUnaligned, test) {
EXPECT(test != NULL);
typedef intptr_t (*LoadHalfWordUnsignedUnaligned)(intptr_t) DART_UNUSED;
uint8_t buffer[4] = {
0x89, 0xAB, 0xCD, 0xEF,
};
EXPECT_EQ(0xAB89, EXECUTE_TEST_CODE_INTPTR_INTPTR(
LoadHalfWordUnsignedUnaligned, test->entry(),
reinterpret_cast<intptr_t>(&buffer[0])));
EXPECT_EQ(0xCDAB, EXECUTE_TEST_CODE_INTPTR_INTPTR(
LoadHalfWordUnsignedUnaligned, test->entry(),
reinterpret_cast<intptr_t>(&buffer[1])));
}
ASSEMBLER_TEST_GENERATE(StoreHalfWordUnaligned, assembler) {
__ LoadImmediate(R1, 0xABCD);
__ StoreUnaligned(R1, R0, TMP, kHalfword);
__ mov(R0, R1);
__ ret();
}
ASSEMBLER_TEST_RUN(StoreHalfWordUnaligned, test) {
EXPECT(test != NULL);
typedef intptr_t (*StoreHalfWordUnaligned)(intptr_t) DART_UNUSED;
uint8_t buffer[4] = {
0, 0, 0, 0,
};
EXPECT_EQ(0xABCD, EXECUTE_TEST_CODE_INTPTR_INTPTR(
StoreHalfWordUnaligned, test->entry(),
reinterpret_cast<intptr_t>(&buffer[0])));
EXPECT_EQ(0xCD, buffer[0]);
EXPECT_EQ(0xAB, buffer[1]);
EXPECT_EQ(0, buffer[2]);
EXPECT_EQ(0xABCD, EXECUTE_TEST_CODE_INTPTR_INTPTR(
StoreHalfWordUnaligned, test->entry(),
reinterpret_cast<intptr_t>(&buffer[1])));
EXPECT_EQ(0xCD, buffer[1]);
EXPECT_EQ(0xAB, buffer[2]);
EXPECT_EQ(0, buffer[3]);
}
ASSEMBLER_TEST_GENERATE(LoadWordUnaligned, assembler) {
__ LoadUnaligned(R1, R0, TMP, kUnsignedWord);
__ mov(R0, R1);
__ ret();
}
ASSEMBLER_TEST_RUN(LoadWordUnaligned, test) {
EXPECT(test != NULL);
typedef int32_t (*LoadWordUnaligned)(intptr_t) DART_UNUSED;
uint8_t buffer[8] = {0x12, 0x34, 0x56, 0x78, 0x9A, 0xBC, 0xDE, 0xF0};
EXPECT_EQ(
static_cast<int32_t>(0x78563412),
EXECUTE_TEST_CODE_INT32_INTPTR(LoadWordUnaligned, test->entry(),
reinterpret_cast<intptr_t>(&buffer[0])));
EXPECT_EQ(
static_cast<int32_t>(0x9A785634),
EXECUTE_TEST_CODE_INT32_INTPTR(LoadWordUnaligned, test->entry(),
reinterpret_cast<intptr_t>(&buffer[1])));
EXPECT_EQ(
static_cast<int32_t>(0xBC9A7856),
EXECUTE_TEST_CODE_INT32_INTPTR(LoadWordUnaligned, test->entry(),
reinterpret_cast<intptr_t>(&buffer[2])));
EXPECT_EQ(
static_cast<int32_t>(0xDEBC9A78),
EXECUTE_TEST_CODE_INT32_INTPTR(LoadWordUnaligned, test->entry(),
reinterpret_cast<intptr_t>(&buffer[3])));
}
ASSEMBLER_TEST_GENERATE(StoreWordUnaligned, assembler) {
__ LoadImmediate(R1, 0x12345678);
__ StoreUnaligned(R1, R0, TMP, kUnsignedWord);
__ mov(R0, R1);
__ ret();
}
ASSEMBLER_TEST_RUN(StoreWordUnaligned, test) {
EXPECT(test != NULL);
typedef intptr_t (*StoreWordUnaligned)(intptr_t) DART_UNUSED;
uint8_t buffer[8] = {0, 0, 0, 0, 0, 0, 0, 0};
EXPECT_EQ(0x12345678, EXECUTE_TEST_CODE_INTPTR_INTPTR(
StoreWordUnaligned, test->entry(),
reinterpret_cast<intptr_t>(&buffer[0])));
EXPECT_EQ(0x78, buffer[0]);
EXPECT_EQ(0x56, buffer[1]);
EXPECT_EQ(0x34, buffer[2]);
EXPECT_EQ(0x12, buffer[3]);
EXPECT_EQ(0x12345678, EXECUTE_TEST_CODE_INTPTR_INTPTR(
StoreWordUnaligned, test->entry(),
reinterpret_cast<intptr_t>(&buffer[1])));
EXPECT_EQ(0x78, buffer[1]);
EXPECT_EQ(0x56, buffer[2]);
EXPECT_EQ(0x34, buffer[3]);
EXPECT_EQ(0x12, buffer[4]);
EXPECT_EQ(0x12345678, EXECUTE_TEST_CODE_INTPTR_INTPTR(
StoreWordUnaligned, test->entry(),
reinterpret_cast<intptr_t>(&buffer[2])));
EXPECT_EQ(0x78, buffer[2]);
EXPECT_EQ(0x56, buffer[3]);
EXPECT_EQ(0x34, buffer[4]);
EXPECT_EQ(0x12, buffer[5]);
EXPECT_EQ(0x12345678, EXECUTE_TEST_CODE_INTPTR_INTPTR(
StoreWordUnaligned, test->entry(),
reinterpret_cast<intptr_t>(&buffer[3])));
EXPECT_EQ(0x78, buffer[3]);
EXPECT_EQ(0x56, buffer[4]);
EXPECT_EQ(0x34, buffer[5]);
EXPECT_EQ(0x12, buffer[6]);
}
static void EnterTestFrame(Assembler* assembler) {
__ EnterFrame(0);
__ Push(CODE_REG);
__ Push(THR);
__ TagAndPushPP();
__ ldr(CODE_REG, Address(R0, VMHandles::kOffsetOfRawPtrInHandle));
__ mov(THR, R1);
__ LoadPoolPointer(PP);
}
static void LeaveTestFrame(Assembler* assembler) {
__ PopAndUntagPP();
__ Pop(THR);
__ Pop(CODE_REG);
__ LeaveFrame();
}
// Loading immediate values with the object pool.
ASSEMBLER_TEST_GENERATE(LoadImmediatePPSmall, assembler) {
__ SetupDartSP();
EnterTestFrame(assembler);
__ LoadImmediate(R0, 42);
LeaveTestFrame(assembler);
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(LoadImmediatePPSmall, test) {
EXPECT_EQ(42, test->InvokeWithCodeAndThread<int64_t>());
}
ASSEMBLER_TEST_GENERATE(LoadImmediatePPMed, assembler) {
__ SetupDartSP();
EnterTestFrame(assembler);
__ LoadImmediate(R0, 0xf1234123);
LeaveTestFrame(assembler);
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(LoadImmediatePPMed, test) {
EXPECT_EQ(0xf1234123, test->InvokeWithCodeAndThread<int64_t>());
}
ASSEMBLER_TEST_GENERATE(LoadImmediatePPMed2, assembler) {
__ SetupDartSP();
EnterTestFrame(assembler);
__ LoadImmediate(R0, 0x4321f1234124);
LeaveTestFrame(assembler);
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(LoadImmediatePPMed2, test) {
EXPECT_EQ(0x4321f1234124, test->InvokeWithCodeAndThread<int64_t>());
}
ASSEMBLER_TEST_GENERATE(LoadImmediatePPLarge, assembler) {
__ SetupDartSP();
EnterTestFrame(assembler);
__ LoadImmediate(R0, 0x9287436598237465);
LeaveTestFrame(assembler);
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(LoadImmediatePPLarge, test) {
EXPECT_EQ(static_cast<int64_t>(0x9287436598237465),
test->InvokeWithCodeAndThread<int64_t>());
}
// LoadObject null.
ASSEMBLER_TEST_GENERATE(LoadObjectNull, assembler) {
__ SetupDartSP();
EnterTestFrame(assembler);
__ LoadObject(R0, Object::null_object());
LeaveTestFrame(assembler);
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(LoadObjectNull, test) {
EXPECT_EQ(Object::null(), test->InvokeWithCodeAndThread<RawObject*>());
}
ASSEMBLER_TEST_GENERATE(LoadObjectTrue, assembler) {
__ SetupDartSP();
EnterTestFrame(assembler);
__ LoadObject(R0, Bool::True());
LeaveTestFrame(assembler);
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(LoadObjectTrue, test) {
EXPECT_EQ(Bool::True().raw(), test->InvokeWithCodeAndThread<RawObject*>());
}
ASSEMBLER_TEST_GENERATE(LoadObjectFalse, assembler) {
__ SetupDartSP();
EnterTestFrame(assembler);
__ LoadObject(R0, Bool::False());
LeaveTestFrame(assembler);
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(LoadObjectFalse, test) {
EXPECT_EQ(Bool::False().raw(), test->InvokeWithCodeAndThread<RawObject*>());
}
ASSEMBLER_TEST_GENERATE(CSelTrue, assembler) {
__ LoadImmediate(R1, 42);
__ LoadImmediate(R2, 1234);
__ CompareRegisters(R1, R2);
__ csel(R0, R1, R2, LT);
__ ret();
}
ASSEMBLER_TEST_RUN(CSelTrue, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(CSelFalse, assembler) {
__ LoadImmediate(R1, 42);
__ LoadImmediate(R2, 1234);
__ CompareRegisters(R1, R2);
__ csel(R0, R1, R2, GE);
__ ret();
}
ASSEMBLER_TEST_RUN(CSelFalse, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(1234, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(CsincFalse, assembler) {
__ LoadImmediate(R1, 42);
__ LoadImmediate(R2, 1234);
__ CompareRegisters(R1, R2);
__ csinc(R0, R2, R1, GE);
__ ret();
}
ASSEMBLER_TEST_RUN(CsincFalse, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(43, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(CsincTrue, assembler) {
__ LoadImmediate(R1, 42);
__ LoadImmediate(R2, 1234);
__ CompareRegisters(R1, R2);
__ csinc(R0, R2, R1, LT);
__ ret();
}
ASSEMBLER_TEST_RUN(CsincTrue, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(1234, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(CsinvFalse, assembler) {
__ LoadImmediate(R1, 42);
__ LoadImmediate(R2, 1234);
__ CompareRegisters(R1, R2);
__ csinv(R0, R2, R1, GE);
__ ret();
}
ASSEMBLER_TEST_RUN(CsinvFalse, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(~42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(CsinvTrue, assembler) {
__ LoadImmediate(R1, 42);
__ LoadImmediate(R2, 1234);
__ CompareRegisters(R1, R2);
__ csinv(R0, R2, R1, LT);
__ ret();
}
ASSEMBLER_TEST_RUN(CsinvTrue, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(1234, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
// Floating point move immediate, to/from integer register.
ASSEMBLER_TEST_GENERATE(Fmovdi, assembler) {
__ LoadDImmediate(V0, 1.0);
__ ret();
}
ASSEMBLER_TEST_RUN(Fmovdi, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(1.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Fmovdi2, assembler) {
__ LoadDImmediate(V0, 123412983.1324524315);
__ ret();
}
ASSEMBLER_TEST_RUN(Fmovdi2, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_FLOAT_EQ(123412983.1324524315,
EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()),
0.0001f);
}
ASSEMBLER_TEST_GENERATE(Fmovrd, assembler) {
__ LoadDImmediate(V1, 1.0);
__ fmovrd(R0, V1);
__ ret();
}
ASSEMBLER_TEST_RUN(Fmovrd, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
const int64_t one = bit_cast<int64_t, double>(1.0);
EXPECT_EQ(one, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Fmovdr, assembler) {
__ LoadDImmediate(V1, 1.0);
__ fmovrd(R1, V1);
__ fmovdr(V0, R1);
__ ret();
}
ASSEMBLER_TEST_RUN(Fmovdr, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(1.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(FldrdFstrdPrePostIndex, assembler) {
__ SetupDartSP();
__ LoadDImmediate(V1, 42.0);
__ fstrd(V1, Address(SP, -1 * kWordSize, Address::PreIndex));
__ fldrd(V0, Address(SP, 1 * kWordSize, Address::PostIndex));
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(FldrdFstrdPrePostIndex, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(FldrsFstrsPrePostIndex, assembler) {
__ SetupDartSP();
__ LoadDImmediate(V1, 42.0);
__ fcvtsd(V2, V1);
__ fstrs(V2, Address(SP, -1 * kWordSize, Address::PreIndex));
__ fldrs(V3, Address(SP, 1 * kWordSize, Address::PostIndex));
__ fcvtds(V0, V3);
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(FldrsFstrsPrePostIndex, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(FldrqFstrqPrePostIndex, assembler) {
__ SetupDartSP();
__ LoadDImmediate(V1, 21.0);
__ LoadDImmediate(V2, 21.0);
__ LoadImmediate(R1, 42);
__ Push(R1);
__ PushDouble(V1);
__ PushDouble(V2);
__ fldrq(V3, Address(SP, 2 * kWordSize, Address::PostIndex));
__ Pop(R0);
__ fstrq(V3, Address(SP, -2 * kWordSize, Address::PreIndex));
__ PopDouble(V0);
__ PopDouble(V1);
__ faddd(V0, V0, V1);
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(FldrqFstrqPrePostIndex, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Fcvtzds, assembler) {
__ LoadDImmediate(V0, 42.0);
__ fcvtzds(R0, V0);
__ ret();
}
ASSEMBLER_TEST_RUN(Fcvtzds, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Scvtfdx, assembler) {
__ LoadImmediate(R0, 42);
__ scvtfdx(V0, R0);
__ ret();
}
ASSEMBLER_TEST_RUN(Scvtfdx, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Scvtfdw, assembler) {
// Fill upper 32-bits with garbage.
__ LoadImmediate(R0, 0x111111110000002A);
__ scvtfdw(V0, R0);
__ ret();
}
ASSEMBLER_TEST_RUN(Scvtfdw, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(FabsdPos, assembler) {
__ LoadDImmediate(V1, 42.0);
__ fabsd(V0, V1);
__ ret();
}
ASSEMBLER_TEST_RUN(FabsdPos, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(FabsdNeg, assembler) {
__ LoadDImmediate(V1, -42.0);
__ fabsd(V0, V1);
__ ret();
}
ASSEMBLER_TEST_RUN(FabsdNeg, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(FnegdPos, assembler) {
__ LoadDImmediate(V1, 42.0);
__ fnegd(V0, V1);
__ ret();
}
ASSEMBLER_TEST_RUN(FnegdPos, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(-42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(FnegdNeg, assembler) {
__ LoadDImmediate(V1, -42.0);
__ fnegd(V0, V1);
__ ret();
}
ASSEMBLER_TEST_RUN(FnegdNeg, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Fsqrtd, assembler) {
__ LoadDImmediate(V1, 64.0);
__ fsqrtd(V0, V1);
__ ret();
}
ASSEMBLER_TEST_RUN(Fsqrtd, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(8.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Fmuld, assembler) {
__ LoadDImmediate(V1, 84.0);
__ LoadDImmediate(V2, 0.5);
__ fmuld(V0, V1, V2);
__ ret();
}
ASSEMBLER_TEST_RUN(Fmuld, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Fdivd, assembler) {
__ LoadDImmediate(V1, 84.0);
__ LoadDImmediate(V2, 2.0);
__ fdivd(V0, V1, V2);
__ ret();
}
ASSEMBLER_TEST_RUN(Fdivd, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Faddd, assembler) {
__ LoadDImmediate(V1, 41.5);
__ LoadDImmediate(V2, 0.5);
__ faddd(V0, V1, V2);
__ ret();
}
ASSEMBLER_TEST_RUN(Faddd, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Fsubd, assembler) {
__ LoadDImmediate(V1, 42.5);
__ LoadDImmediate(V2, 0.5);
__ fsubd(V0, V1, V2);
__ ret();
}
ASSEMBLER_TEST_RUN(Fsubd, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(FldrdFstrdHeapTag, assembler) {
__ SetupDartSP();
__ LoadDImmediate(V0, 43.0);
__ LoadDImmediate(V1, 42.0);
__ AddImmediate(SP, SP, -1 * kWordSize);
__ add(R2, SP, Operand(1));
__ fstrd(V1, Address(R2, -1));
__ fldrd(V0, Address(R2, -1));
__ AddImmediate(SP, SP, 1 * kWordSize);
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(FldrdFstrdHeapTag, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(FldrdFstrdLargeIndex, assembler) {
__ SetupDartSP();
__ LoadDImmediate(V0, 43.0);
__ LoadDImmediate(V1, 42.0);
// Largest negative offset that can fit in the signed 9-bit immediate field.
__ fstrd(V1, Address(SP, -32 * kWordSize, Address::PreIndex));
// Largest positive kWordSize aligned offset that we can fit.
__ fldrd(V0, Address(SP, 31 * kWordSize, Address::PostIndex));
// Correction.
__ add(SP, SP, Operand(kWordSize)); // Restore SP.
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(FldrdFstrdLargeIndex, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(FldrdFstrdLargeOffset, assembler) {
__ SetupDartSP();
__ LoadDImmediate(V0, 43.0);
__ LoadDImmediate(V1, 42.0);
__ sub(SP, SP, Operand(512 * kWordSize));
__ fstrd(V1, Address(SP, 512 * kWordSize, Address::Offset));
__ add(SP, SP, Operand(512 * kWordSize));
__ fldrd(V0, Address(SP));
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(FldrdFstrdLargeOffset, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(FldrdFstrdExtReg, assembler) {
__ SetupDartSP();
__ LoadDImmediate(V0, 43.0);
__ LoadDImmediate(V1, 42.0);
__ movz(R2, Immediate(0xfff8), 0);
__ movk(R2, Immediate(0xffff), 1); // R2 <- -8 (int32_t).
// This should sign extend R2, and add to SP to get address,
// i.e. SP - kWordSize.
__ fstrd(V1, Address(SP, R2, SXTW));
__ sub(SP, SP, Operand(kWordSize));
__ fldrd(V0, Address(SP));
__ add(SP, SP, Operand(kWordSize));
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(FldrdFstrdExtReg, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(FldrdFstrdScaledReg, assembler) {
__ SetupDartSP();
__ LoadDImmediate(V0, 43.0);
__ LoadDImmediate(V1, 42.0);
__ movz(R2, Immediate(10), 0);
__ sub(SP, SP, Operand(10 * kWordSize));
// Store V1 into SP + R2 * kWordSize.
__ fstrd(V1, Address(SP, R2, UXTX, Address::Scaled));
__ fldrd(V0, Address(SP, R2, UXTX, Address::Scaled));
__ add(SP, SP, Operand(10 * kWordSize));
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(FldrdFstrdScaledReg, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(VinswVmovrs, assembler) {
__ LoadImmediate(R0, 42);
__ LoadImmediate(R1, 43);
__ LoadImmediate(R2, 44);
__ LoadImmediate(R3, 45);
__ vinsw(V0, 0, R0);
__ vinsw(V0, 1, R1);
__ vinsw(V0, 2, R2);
__ vinsw(V0, 3, R3);
__ vmovrs(R4, V0, 0);
__ vmovrs(R5, V0, 1);
__ vmovrs(R6, V0, 2);
__ vmovrs(R7, V0, 3);
__ add(R0, R4, Operand(R5));
__ add(R0, R0, Operand(R6));
__ add(R0, R0, Operand(R7));
__ ret();
}
ASSEMBLER_TEST_RUN(VinswVmovrs, test) {
EXPECT(test != NULL);
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(174, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(VinsxVmovrd, assembler) {
__ LoadImmediate(R0, 42);
__ LoadImmediate(R1, 43);
__ vinsx(V0, 0, R0);
__ vinsx(V0, 1, R1);
__ vmovrd(R2, V0, 0);
__ vmovrd(R3, V0, 1);
__ add(R0, R2, Operand(R3));
__ ret();
}
ASSEMBLER_TEST_RUN(VinsxVmovrd, test) {
EXPECT(test != NULL);
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(85, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vnot, assembler) {
__ LoadImmediate(R0, 0xfffffffe);
__ LoadImmediate(R1, 0xffffffff);
__ vinsw(V1, 0, R1);
__ vinsw(V1, 1, R0);
__ vinsw(V1, 2, R1);
__ vinsw(V1, 3, R0);
__ vnot(V0, V1);
__ vmovrs(R2, V0, 0);
__ vmovrs(R3, V0, 1);
__ vmovrs(R4, V0, 2);
__ vmovrs(R5, V0, 3);
__ add(R0, R2, Operand(R3));
__ add(R0, R0, Operand(R4));
__ add(R0, R0, Operand(R5));
__ ret();
}
ASSEMBLER_TEST_RUN(Vnot, test) {
EXPECT(test != NULL);
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(2, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vabss, assembler) {
__ LoadDImmediate(V1, 21.0);
__ LoadDImmediate(V2, -21.0);
__ fcvtsd(V1, V1);
__ fcvtsd(V2, V2);
__ veor(V3, V3, V3);
__ vinss(V3, 1, V1, 0);
__ vinss(V3, 3, V2, 0);
__ vabss(V4, V3);
__ vinss(V5, 0, V4, 1);
__ vinss(V6, 0, V4, 3);
__ fcvtds(V5, V5);
__ fcvtds(V6, V6);
__ faddd(V0, V5, V6);
__ ret();
}
ASSEMBLER_TEST_RUN(Vabss, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vabsd, assembler) {
__ LoadDImmediate(V1, 21.0);
__ LoadDImmediate(V2, -21.0);
__ vinsd(V3, 0, V1, 0);
__ vinsd(V3, 1, V2, 0);
__ vabsd(V4, V3);
__ vinsd(V5, 0, V4, 0);
__ vinsd(V6, 0, V4, 1);
__ faddd(V0, V5, V6);
__ ret();
}
ASSEMBLER_TEST_RUN(Vabsd, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vnegs, assembler) {
__ LoadDImmediate(V1, 42.0);
__ LoadDImmediate(V2, -84.0);
__ fcvtsd(V1, V1);
__ fcvtsd(V2, V2);
__ veor(V3, V3, V3);
__ vinss(V3, 1, V1, 0);
__ vinss(V3, 3, V2, 0);
__ vnegs(V4, V3);
__ vinss(V5, 0, V4, 1);
__ vinss(V6, 0, V4, 3);
__ fcvtds(V5, V5);
__ fcvtds(V6, V6);
__ faddd(V0, V5, V6);
__ ret();
}
ASSEMBLER_TEST_RUN(Vnegs, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vnegd, assembler) {
__ LoadDImmediate(V1, 42.0);
__ LoadDImmediate(V2, -84.0);
__ vinsd(V3, 0, V1, 0);
__ vinsd(V3, 1, V2, 0);
__ vnegd(V4, V3);
__ vinsd(V5, 0, V4, 0);
__ vinsd(V6, 0, V4, 1);
__ faddd(V0, V5, V6);
__ ret();
}
ASSEMBLER_TEST_RUN(Vnegd, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vadds, assembler) {
__ LoadDImmediate(V0, 0.0);
__ LoadDImmediate(V1, 1.0);
__ LoadDImmediate(V2, 2.0);
__ LoadDImmediate(V3, 3.0);
__ fcvtsd(V0, V0);
__ fcvtsd(V1, V1);
__ fcvtsd(V2, V2);
__ fcvtsd(V3, V3);
__ vinss(V4, 0, V0, 0);
__ vinss(V4, 1, V1, 0);
__ vinss(V4, 2, V2, 0);
__ vinss(V4, 3, V3, 0);
__ vadds(V5, V4, V4);
__ vinss(V0, 0, V5, 0);
__ vinss(V1, 0, V5, 1);
__ vinss(V2, 0, V5, 2);
__ vinss(V3, 0, V5, 3);
__ fcvtds(V0, V0);
__ fcvtds(V1, V1);
__ fcvtds(V2, V2);
__ fcvtds(V3, V3);
__ faddd(V0, V0, V1);
__ faddd(V0, V0, V2);
__ faddd(V0, V0, V3);
__ ret();
}
ASSEMBLER_TEST_RUN(Vadds, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(12.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vsubs, assembler) {
__ LoadDImmediate(V0, 0.0);
__ LoadDImmediate(V1, 1.0);
__ LoadDImmediate(V2, 2.0);
__ LoadDImmediate(V3, 3.0);
__ LoadDImmediate(V5, 0.0);
__ fcvtsd(V0, V0);
__ fcvtsd(V1, V1);
__ fcvtsd(V2, V2);
__ fcvtsd(V3, V3);
__ vinss(V4, 0, V0, 0);
__ vinss(V4, 1, V1, 0);
__ vinss(V4, 2, V2, 0);
__ vinss(V4, 3, V3, 0);
__ vsubs(V5, V5, V4);
__ vinss(V0, 0, V5, 0);
__ vinss(V1, 0, V5, 1);
__ vinss(V2, 0, V5, 2);
__ vinss(V3, 0, V5, 3);
__ fcvtds(V0, V0);
__ fcvtds(V1, V1);
__ fcvtds(V2, V2);
__ fcvtds(V3, V3);
__ faddd(V0, V0, V1);
__ faddd(V0, V0, V2);
__ faddd(V0, V0, V3);
__ ret();
}
ASSEMBLER_TEST_RUN(Vsubs, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(-6.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vmuls, assembler) {
__ LoadDImmediate(V0, 0.0);
__ LoadDImmediate(V1, 1.0);
__ LoadDImmediate(V2, 2.0);
__ LoadDImmediate(V3, 3.0);
__ fcvtsd(V0, V0);
__ fcvtsd(V1, V1);
__ fcvtsd(V2, V2);
__ fcvtsd(V3, V3);
__ vinss(V4, 0, V0, 0);
__ vinss(V4, 1, V1, 0);
__ vinss(V4, 2, V2, 0);
__ vinss(V4, 3, V3, 0);
__ vmuls(V5, V4, V4);
__ vinss(V0, 0, V5, 0);
__ vinss(V1, 0, V5, 1);
__ vinss(V2, 0, V5, 2);
__ vinss(V3, 0, V5, 3);
__ fcvtds(V0, V0);
__ fcvtds(V1, V1);
__ fcvtds(V2, V2);
__ fcvtds(V3, V3);
__ faddd(V0, V0, V1);
__ faddd(V0, V0, V2);
__ faddd(V0, V0, V3);
__ ret();
}
ASSEMBLER_TEST_RUN(Vmuls, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(14.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vdivs, assembler) {
__ LoadDImmediate(V0, 0.0);
__ LoadDImmediate(V1, 1.0);
__ LoadDImmediate(V2, 2.0);
__ LoadDImmediate(V3, 3.0);
__ fcvtsd(V0, V0);
__ fcvtsd(V1, V1);
__ fcvtsd(V2, V2);
__ fcvtsd(V3, V3);
__ vinss(V4, 0, V0, 0);
__ vinss(V4, 1, V1, 0);
__ vinss(V4, 2, V2, 0);
__ vinss(V4, 3, V3, 0);
__ vdivs(V5, V4, V4);
__ vinss(V0, 0, V5, 0);
__ vinss(V1, 0, V5, 1);
__ vinss(V2, 0, V5, 2);
__ vinss(V3, 0, V5, 3);
__ fcvtds(V0, V0);
__ fcvtds(V1, V1);
__ fcvtds(V2, V2);
__ fcvtds(V3, V3);
__ faddd(V0, V1, V1);
__ faddd(V0, V0, V2);
__ faddd(V0, V0, V3);
__ ret();
}
ASSEMBLER_TEST_RUN(Vdivs, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(4.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vaddd, assembler) {
__ LoadDImmediate(V0, 2.0);
__ LoadDImmediate(V1, 3.0);
__ vinsd(V4, 0, V0, 0);
__ vinsd(V4, 1, V1, 0);
__ vaddd(V5, V4, V4);
__ vinsd(V0, 0, V5, 0);
__ vinsd(V1, 0, V5, 1);
__ faddd(V0, V0, V1);
__ ret();
}
ASSEMBLER_TEST_RUN(Vaddd, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(10.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vsubd, assembler) {
__ LoadDImmediate(V0, 2.0);
__ LoadDImmediate(V1, 3.0);
__ LoadDImmediate(V5, 0.0);
__ vinsd(V4, 0, V0, 0);
__ vinsd(V4, 1, V1, 0);
__ vsubd(V5, V5, V4);
__ vinsd(V0, 0, V5, 0);
__ vinsd(V1, 0, V5, 1);
__ faddd(V0, V0, V1);
__ ret();
}
ASSEMBLER_TEST_RUN(Vsubd, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(-5.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vmuld, assembler) {
__ LoadDImmediate(V0, 2.0);
__ LoadDImmediate(V1, 3.0);
__ vinsd(V4, 0, V0, 0);
__ vinsd(V4, 1, V1, 0);
__ vmuld(V5, V4, V4);
__ vinsd(V0, 0, V5, 0);
__ vinsd(V1, 0, V5, 1);
__ faddd(V0, V0, V1);
__ ret();
}
ASSEMBLER_TEST_RUN(Vmuld, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(13.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vdivd, assembler) {
__ LoadDImmediate(V0, 2.0);
__ LoadDImmediate(V1, 3.0);
__ vinsd(V4, 0, V0, 0);
__ vinsd(V4, 1, V1, 0);
__ vdivd(V5, V4, V4);
__ vinsd(V0, 0, V5, 0);
__ vinsd(V1, 0, V5, 1);
__ faddd(V0, V0, V1);
__ ret();
}
ASSEMBLER_TEST_RUN(Vdivd, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(2.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vdupd, assembler) {
__ SetupDartSP();
__ LoadDImmediate(V0, 21.0);
__ vdupd(V1, V0, 0);
const int dword_bytes = 1 << Log2OperandSizeBytes(kDWord);
const int qword_bytes = 1 << Log2OperandSizeBytes(kQWord);
__ fstrq(V1, Address(SP, -1 * qword_bytes, Address::PreIndex));
__ fldrd(V2, Address(SP, 1 * dword_bytes, Address::PostIndex));
__ fldrd(V3, Address(SP, 1 * dword_bytes, Address::PostIndex));
__ faddd(V0, V2, V3);
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(Vdupd, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vdups, assembler) {
__ SetupDartSP();
__ LoadDImmediate(V0, 21.0);
__ fcvtsd(V0, V0);
__ vdups(V1, V0, 0);
const int sword_bytes = 1 << Log2OperandSizeBytes(kSWord);
const int qword_bytes = 1 << Log2OperandSizeBytes(kQWord);
__ fstrq(V1, Address(SP, -1 * qword_bytes, Address::PreIndex));
__ fldrs(V3, Address(SP, 1 * sword_bytes, Address::PostIndex));
__ fldrs(V2, Address(SP, 1 * sword_bytes, Address::PostIndex));
__ fldrs(V1, Address(SP, 1 * sword_bytes, Address::PostIndex));
__ fldrs(V0, Address(SP, 1 * sword_bytes, Address::PostIndex));
__ fcvtds(V0, V0);
__ fcvtds(V1, V1);
__ fcvtds(V2, V2);
__ fcvtds(V3, V3);
__ faddd(V0, V1, V1);
__ faddd(V0, V0, V2);
__ faddd(V0, V0, V3);
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(Vdups, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(84.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vinsd, assembler) {
__ SetupDartSP();
__ LoadDImmediate(V5, 42.0);
__ vinsd(V1, 1, V5, 0); // V1[1] <- V0[0].
const int dword_bytes = 1 << Log2OperandSizeBytes(kDWord);
const int qword_bytes = 1 << Log2OperandSizeBytes(kQWord);
__ fstrq(V1, Address(SP, -1 * qword_bytes, Address::PreIndex));
__ fldrd(V2, Address(SP, 1 * dword_bytes, Address::PostIndex));
__ fldrd(V3, Address(SP, 1 * dword_bytes, Address::PostIndex));
__ fmovdd(V0, V3);
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(Vinsd, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vinss, assembler) {
__ SetupDartSP();
__ LoadDImmediate(V0, 21.0);
__ fcvtsd(V0, V0);
__ vinss(V1, 3, V0, 0);
__ vinss(V1, 1, V0, 0);
const int sword_bytes = 1 << Log2OperandSizeBytes(kSWord);
const int qword_bytes = 1 << Log2OperandSizeBytes(kQWord);
__ fstrq(V1, Address(SP, -1 * qword_bytes, Address::PreIndex));
__ fldrs(V3, Address(SP, 1 * sword_bytes, Address::PostIndex));
__ fldrs(V2, Address(SP, 1 * sword_bytes, Address::PostIndex));
__ fldrs(V1, Address(SP, 1 * sword_bytes, Address::PostIndex));
__ fldrs(V0, Address(SP, 1 * sword_bytes, Address::PostIndex));
__ fcvtds(V0, V0);
__ fcvtds(V1, V1);
__ fcvtds(V2, V2);
__ fcvtds(V3, V3);
__ faddd(V0, V0, V1);
__ faddd(V0, V0, V2);
__ faddd(V0, V0, V3);
__ RestoreCSP();
__ ret();
}
ASSEMBLER_TEST_RUN(Vinss, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vand, assembler) {
__ LoadDImmediate(V1, 21.0);
__ LoadImmediate(R0, 0xffffffff);
// V0 <- (0, 0xffffffff, 0, 0xffffffff)
__ fmovdr(V0, R0);
__ vinss(V0, 2, V0, 0);
// V1 <- (21.0, 21.0, 21.0, 21.0)
__ fcvtsd(V1, V1);
__ vdups(V1, V1, 0);
__ vand(V2, V1, V0);
__ vinss(V3, 0, V2, 0);
__ vinss(V4, 0, V2, 1);
__ vinss(V5, 0, V2, 2);
__ vinss(V6, 0, V2, 3);
__ fcvtds(V3, V3);
__ fcvtds(V4, V4);
__ fcvtds(V5, V5);
__ fcvtds(V6, V6);
__ vaddd(V0, V3, V4);
__ vaddd(V0, V0, V5);
__ vaddd(V0, V0, V6);
__ ret();
}
ASSEMBLER_TEST_RUN(Vand, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vorr, assembler) {
__ LoadDImmediate(V1, 10.5);
__ fcvtsd(V1, V1);
// V0 <- (0, 10.5, 0, 10.5)
__ fmovdd(V0, V1);
__ vinss(V0, 2, V0, 0);
// V1 <- (10.5, 0, 10.5, 0)
__ veor(V1, V1, V1);
__ vinss(V1, 1, V0, 0);
__ vinss(V1, 3, V0, 0);
__ vorr(V2, V1, V0);
__ vinss(V3, 0, V2, 0);
__ vinss(V4, 0, V2, 1);
__ vinss(V5, 0, V2, 2);
__ vinss(V6, 0, V2, 3);
__ fcvtds(V3, V3);
__ fcvtds(V4, V4);
__ fcvtds(V5, V5);
__ fcvtds(V6, V6);
__ vaddd(V0, V3, V4);
__ vaddd(V0, V0, V5);
__ vaddd(V0, V0, V6);
__ ret();
}
ASSEMBLER_TEST_RUN(Vorr, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Veor, assembler) {
__ LoadImmediate(R1, 0xffffffff);
__ LoadImmediate(R2, ~21);
__ vinsw(V1, 0, R1);
__ vinsw(V1, 1, R2);
__ vinsw(V1, 2, R1);
__ vinsw(V1, 3, R2);
__ vinsw(V2, 0, R1);
__ vinsw(V2, 1, R1);
__ vinsw(V2, 2, R1);
__ vinsw(V2, 3, R1);
__ veor(V0, V1, V2);
__ vmovrs(R3, V0, 0);
__ vmovrs(R4, V0, 1);
__ vmovrs(R5, V0, 2);
__ vmovrs(R6, V0, 3);
__ add(R0, R3, Operand(R4));
__ add(R0, R0, Operand(R5));
__ add(R0, R0, Operand(R6));
__ ret();
}
ASSEMBLER_TEST_RUN(Veor, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vaddw, assembler) {
__ LoadImmediate(R4, 21);
__ vdupw(V1, R4);
__ vdupw(V2, R4);
__ vaddw(V0, V1, V2);
__ vmovrs(R0, V0, 0);
__ vmovrs(R1, V0, 1);
__ vmovrs(R2, V0, 2);
__ vmovrs(R3, V0, 3);
__ add(R0, R0, Operand(R1));
__ add(R0, R0, Operand(R2));
__ add(R0, R0, Operand(R3));
__ ret();
}
ASSEMBLER_TEST_RUN(Vaddw, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(168, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vsubw, assembler) {
__ LoadImmediate(R4, 31);
__ LoadImmediate(R5, 10);
__ vdupw(V1, R4);
__ vdupw(V2, R5);
__ vsubw(V0, V1, V2);
__ vmovrs(R0, V0, 0);
__ vmovrs(R1, V0, 1);
__ vmovrs(R2, V0, 2);
__ vmovrs(R3, V0, 3);
__ add(R0, R0, Operand(R1));
__ add(R0, R0, Operand(R2));
__ add(R0, R0, Operand(R3));
__ ret();
}
ASSEMBLER_TEST_RUN(Vsubw, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(84, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vaddx, assembler) {
__ LoadImmediate(R4, 21);
__ vdupx(V1, R4);
__ vdupx(V2, R4);
__ vaddx(V0, V1, V2);
__ vmovrd(R0, V0, 0);
__ vmovrd(R1, V0, 1);
__ add(R0, R0, Operand(R1));
__ ret();
}
ASSEMBLER_TEST_RUN(Vaddx, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(84, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vsubx, assembler) {
__ LoadImmediate(R4, 31);
__ LoadImmediate(R5, 10);
__ vdupx(V1, R4);
__ vdupx(V2, R5);
__ vsubx(V0, V1, V2);
__ vmovrd(R0, V0, 0);
__ vmovrd(R1, V0, 1);
__ add(R0, R0, Operand(R1));
__ ret();
}
ASSEMBLER_TEST_RUN(Vsubx, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(42, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vceqs, assembler) {
__ LoadDImmediate(V0, 42.0);
__ LoadDImmediate(V1, -42.0);
__ fcvtsd(V0, V0);
__ fcvtsd(V1, V1);
__ vdups(V2, V0, 0);
__ vinss(V3, 0, V0, 0);
__ vinss(V3, 1, V1, 0);
__ vinss(V3, 2, V0, 0);
__ vinss(V3, 3, V1, 0);
__ vceqs(V4, V2, V3);
__ vmovrs(R1, V4, 0);
__ vmovrs(R2, V4, 1);
__ vmovrs(R3, V4, 2);
__ vmovrs(R4, V4, 3);
__ addw(R0, R1, Operand(R2));
__ addw(R0, R0, Operand(R3));
__ addw(R0, R0, Operand(R4));
__ ret();
}
ASSEMBLER_TEST_RUN(Vceqs, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(0xfffffffe, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vceqd, assembler) {
__ LoadDImmediate(V0, 42.0);
__ LoadDImmediate(V1, -42.0);
__ vdupd(V2, V0, 0);
__ vinsd(V3, 0, V0, 0);
__ vinsd(V3, 1, V1, 0);
__ vceqd(V4, V2, V3);
__ vmovrd(R1, V4, 0);
__ vmovrd(R2, V4, 1);
__ add(R0, R1, Operand(R2));
__ ret();
}
ASSEMBLER_TEST_RUN(Vceqd, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(-1, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vcgts, assembler) {
__ LoadDImmediate(V0, 42.0);
__ LoadDImmediate(V1, -42.0);
__ fcvtsd(V0, V0);
__ fcvtsd(V1, V1);
__ vdups(V2, V0, 0);
__ vinss(V3, 0, V0, 0);
__ vinss(V3, 1, V1, 0);
__ vinss(V3, 2, V0, 0);
__ vinss(V3, 3, V1, 0);
__ vcgts(V4, V2, V3);
__ vmovrs(R1, V4, 0);
__ vmovrs(R2, V4, 1);
__ vmovrs(R3, V4, 2);
__ vmovrs(R4, V4, 3);
__ addw(R0, R1, Operand(R2));
__ addw(R0, R0, Operand(R3));
__ addw(R0, R0, Operand(R4));
__ ret();
}
ASSEMBLER_TEST_RUN(Vcgts, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(0xfffffffe, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vcgtd, assembler) {
__ LoadDImmediate(V0, 42.0);
__ LoadDImmediate(V1, -42.0);
__ vdupd(V2, V0, 0);
__ vinsd(V3, 0, V0, 0);
__ vinsd(V3, 1, V1, 0);
__ vcgtd(V4, V2, V3);
__ vmovrd(R1, V4, 0);
__ vmovrd(R2, V4, 1);
__ add(R0, R1, Operand(R2));
__ ret();
}
ASSEMBLER_TEST_RUN(Vcgtd, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(-1, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vcges, assembler) {
__ LoadDImmediate(V0, 42.0);
__ LoadDImmediate(V1, 43.0);
__ fcvtsd(V0, V0);
__ fcvtsd(V1, V1);
__ vdups(V2, V0, 0);
__ vinss(V3, 0, V0, 0);
__ vinss(V3, 1, V1, 0);
__ vinss(V3, 2, V0, 0);
__ vinss(V3, 3, V1, 0);
__ vcges(V4, V2, V3);
__ vmovrs(R1, V4, 0);
__ vmovrs(R2, V4, 1);
__ vmovrs(R3, V4, 2);
__ vmovrs(R4, V4, 3);
__ addw(R0, R1, Operand(R2));
__ addw(R0, R0, Operand(R3));
__ addw(R0, R0, Operand(R4));
__ ret();
}
ASSEMBLER_TEST_RUN(Vcges, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(0xfffffffe, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vcged, assembler) {
__ LoadDImmediate(V0, 42.0);
__ LoadDImmediate(V1, 43.0);
__ vdupd(V2, V0, 0);
__ vinsd(V3, 0, V0, 0);
__ vinsd(V3, 1, V1, 0);
__ vcged(V4, V2, V3);
__ vmovrd(R1, V4, 0);
__ vmovrd(R2, V4, 1);
__ add(R0, R1, Operand(R2));
__ ret();
}
ASSEMBLER_TEST_RUN(Vcged, test) {
typedef int64_t (*Int64Return)() DART_UNUSED;
EXPECT_EQ(-1, EXECUTE_TEST_CODE_INT64(Int64Return, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vmaxs, assembler) {
__ LoadDImmediate(V0, 10.5);
__ LoadDImmediate(V1, 10.0);
__ fcvtsd(V0, V0);
__ fcvtsd(V1, V1);
__ vdups(V2, V0, 0);
__ vinss(V3, 0, V0, 0);
__ vinss(V3, 1, V1, 0);
__ vinss(V3, 2, V0, 0);
__ vinss(V3, 3, V1, 0);
__ vmaxs(V4, V2, V3);
__ vinss(V0, 0, V4, 0);
__ vinss(V1, 0, V4, 1);
__ vinss(V2, 0, V4, 2);
__ vinss(V3, 0, V4, 3);
__ fcvtds(V0, V0);
__ fcvtds(V1, V1);
__ fcvtds(V2, V2);
__ fcvtds(V3, V3);
__ faddd(V0, V0, V1);
__ faddd(V0, V0, V2);
__ faddd(V0, V0, V3);
__ ret();
}
ASSEMBLER_TEST_RUN(Vmaxs, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vmaxd, assembler) {
__ LoadDImmediate(V0, 21.0);
__ LoadDImmediate(V1, 20.5);
__ vdupd(V2, V0, 0);
__ vinsd(V3, 0, V0, 0);
__ vinsd(V3, 1, V1, 0);
__ vmaxd(V4, V2, V3);
__ vinsd(V0, 0, V4, 0);
__ vinsd(V1, 0, V4, 1);
__ faddd(V0, V0, V1);
__ ret();
}
ASSEMBLER_TEST_RUN(Vmaxd, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vmins, assembler) {
__ LoadDImmediate(V0, 10.5);
__ LoadDImmediate(V1, 11.0);
__ fcvtsd(V0, V0);
__ fcvtsd(V1, V1);
__ vdups(V2, V0, 0);
__ vinss(V3, 0, V0, 0);
__ vinss(V3, 1, V1, 0);
__ vinss(V3, 2, V0, 0);
__ vinss(V3, 3, V1, 0);
__ vmins(V4, V2, V3);
__ vinss(V0, 0, V4, 0);
__ vinss(V1, 0, V4, 1);
__ vinss(V2, 0, V4, 2);
__ vinss(V3, 0, V4, 3);
__ fcvtds(V0, V0);
__ fcvtds(V1, V1);
__ fcvtds(V2, V2);
__ fcvtds(V3, V3);
__ faddd(V0, V0, V1);
__ faddd(V0, V0, V2);
__ faddd(V0, V0, V3);
__ ret();
}
ASSEMBLER_TEST_RUN(Vmins, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vmind, assembler) {
__ LoadDImmediate(V0, 21.0);
__ LoadDImmediate(V1, 21.5);
__ vdupd(V2, V0, 0);
__ vinsd(V3, 0, V0, 0);
__ vinsd(V3, 1, V1, 0);
__ vmind(V4, V2, V3);
__ vinsd(V0, 0, V4, 0);
__ vinsd(V1, 0, V4, 1);
__ faddd(V0, V0, V1);
__ ret();
}
ASSEMBLER_TEST_RUN(Vmind, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(42.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vsqrts, assembler) {
__ LoadDImmediate(V0, 64.0);
__ LoadDImmediate(V1, 49.0);
__ fcvtsd(V0, V0);
__ fcvtsd(V1, V1);
__ veor(V3, V3, V3);
__ vinss(V3, 1, V0, 0);
__ vinss(V3, 3, V1, 0);
__ vsqrts(V4, V3);
__ vinss(V5, 0, V4, 1);
__ vinss(V6, 0, V4, 3);
__ fcvtds(V5, V5);
__ fcvtds(V6, V6);
__ faddd(V0, V5, V6);
__ ret();
}
ASSEMBLER_TEST_RUN(Vsqrts, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(15.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
ASSEMBLER_TEST_GENERATE(Vsqrtd, assembler) {
__ LoadDImmediate(V0, 64.0);
__ LoadDImmediate(V1, 49.0);
__ vinsd(V3, 0, V0, 0);
__ vinsd(V3, 1, V1, 0);
__ vsqrtd(V4, V3);
__ vinsd(V5, 0, V4, 0);
__ vinsd(V6, 0, V4, 1);
__ faddd(V0, V5, V6);
__ ret();
}
ASSEMBLER_TEST_RUN(Vsqrtd, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
EXPECT_EQ(15.0, EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry()));
}
// This is the same function as in the Simulator.
static float arm_recip_estimate(float a) {
// From the ARM Architecture Reference Manual A2-85.
if (isinf(a) || (fabs(a) >= exp2f(126)))
return 0.0;
else if (a == 0.0)
return kPosInfinity;
else if (isnan(a))
return a;
uint32_t a_bits = bit_cast<uint32_t, float>(a);
// scaled = '0011 1111 1110' : a<22:0> : Zeros(29)
uint64_t scaled = (static_cast<uint64_t>(0x3fe) << 52) |
((static_cast<uint64_t>(a_bits) & 0x7fffff) << 29);
// result_exp = 253 - UInt(a<30:23>)
int32_t result_exp = 253 - ((a_bits >> 23) & 0xff);
ASSERT((result_exp >= 1) && (result_exp <= 252));
double scaled_d = bit_cast<double, uint64_t>(scaled);
ASSERT((scaled_d >= 0.5) && (scaled_d < 1.0));
// a in units of 1/512 rounded down.
int32_t q = static_cast<int32_t>(scaled_d * 512.0);
// reciprocal r.
double r = 1.0 / ((static_cast<double>(q) + 0.5) / 512.0);
// r in units of 1/256 rounded to nearest.
int32_t s = static_cast<int32_t>(256.0 * r + 0.5);
double estimate = static_cast<double>(s) / 256.0;
ASSERT((estimate >= 1.0) && (estimate <= (511.0 / 256.0)));
// result = sign : result_exp<7:0> : estimate<51:29>
int32_t result_bits =
(a_bits & 0x80000000) | ((result_exp & 0xff) << 23) |
((bit_cast<uint64_t, double>(estimate) >> 29) & 0x7fffff);
return bit_cast<float, int32_t>(result_bits);
}
ASSEMBLER_TEST_GENERATE(Vrecpes, assembler) {
__ LoadDImmediate(V1, 147.0);
__ fcvtsd(V1, V1);
__ vinss(V2, 0, V1, 0);
__ vinss(V2, 1, V1, 0);
__ vinss(V2, 2, V1, 0);
__ vinss(V2, 3, V1, 0);
__ vrecpes(V0, V2);
__ fcvtds(V0, V0);
__ ret();
}
ASSEMBLER_TEST_RUN(Vrecpes, test) {
EXPECT(test != NULL);
typedef double (*DoubleReturn)() DART_UNUSED;
float res = EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry());
EXPECT_FLOAT_EQ(arm_recip_estimate(147.0), res, 0.0001);
}
ASSEMBLER_TEST_GENERATE(Vrecpss, assembler) {
__ LoadDImmediate(V1, 5.0);
__ LoadDImmediate(V2, 10.0);
__ fcvtsd(V1, V1);
__ fcvtsd(V2, V2);
__ vrecpss(V0, V1, V2);
__ fcvtds(V0, V0);
__ ret();
}
ASSEMBLER_TEST_RUN(Vrecpss, test) {
EXPECT(test != NULL);
typedef double (*DoubleReturn)() DART_UNUSED;
double res = EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry());
EXPECT_FLOAT_EQ(2.0 - 10.0 * 5.0, res, 0.0001);
}
ASSEMBLER_TEST_GENERATE(VRecps, assembler) {
__ LoadDImmediate(V0, 1.0 / 10.5);
__ fcvtsd(V0, V0);
__ vdups(V1, V0, 0);
__ VRecps(V2, V1);
__ vinss(V0, 0, V2, 0);
__ vinss(V1, 0, V2, 1);
__ vinss(V2, 0, V2, 2);
__ vinss(V3, 0, V2, 3);
__ fcvtds(V0, V0);
__ fcvtds(V1, V1);
__ fcvtds(V2, V2);
__ fcvtds(V3, V3);
__ faddd(V0, V0, V1);
__ faddd(V0, V0, V2);
__ faddd(V0, V0, V3);
__ ret();
}
ASSEMBLER_TEST_RUN(VRecps, test) {
typedef double (*DoubleReturn)() DART_UNUSED;
double res = EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry());
EXPECT_FLOAT_EQ(42.0, res, 0.0001);
}
static float arm_reciprocal_sqrt_estimate(float a) {
// From the ARM Architecture Reference Manual A2-87.
if (isinf(a) || (fabs(a) >= exp2f(126)))
return 0.0;
else if (a == 0.0)
return kPosInfinity;
else if (isnan(a))
return a;
uint32_t a_bits = bit_cast<uint32_t, float>(a);
uint64_t scaled;
if (((a_bits >> 23) & 1) != 0) {
// scaled = '0 01111111101' : operand<22:0> : Zeros(29)
scaled = (static_cast<uint64_t>(0x3fd) << 52) |
((static_cast<uint64_t>(a_bits) & 0x7fffff) << 29);
} else {
// scaled = '0 01111111110' : operand<22:0> : Zeros(29)
scaled = (static_cast<uint64_t>(0x3fe) << 52) |
((static_cast<uint64_t>(a_bits) & 0x7fffff) << 29);
}
// result_exp = (380 - UInt(operand<30:23>) DIV 2;
int32_t result_exp = (380 - ((a_bits >> 23) & 0xff)) / 2;
double scaled_d = bit_cast<double, uint64_t>(scaled);
ASSERT((scaled_d >= 0.25) && (scaled_d < 1.0));
double r;
if (scaled_d < 0.5) {
// range 0.25 <= a < 0.5
// a in units of 1/512 rounded down.
int32_t q0 = static_cast<int32_t>(scaled_d * 512.0);
// reciprocal root r.
r = 1.0 / sqrt((static_cast<double>(q0) + 0.5) / 512.0);
} else {
// range 0.5 <= a < 1.0
// a in units of 1/256 rounded down.
int32_t q1 = static_cast<int32_t>(scaled_d * 256.0);
// reciprocal root r.
r = 1.0 / sqrt((static_cast<double>(q1) + 0.5) / 256.0);
}
// r in units of 1/256 rounded to nearest.
int32_t s = static_cast<int>(256.0 * r + 0.5);
double estimate = static_cast<double>(s) / 256.0;
ASSERT((estimate >= 1.0) && (estimate <= (511.0 / 256.0)));
// result = 0 : result_exp<7:0> : estimate<51:29>
int32_t result_bits =
((result_exp & 0xff) << 23) |
((bit_cast<uint64_t, double>(estimate) >> 29) & 0x7fffff);
return bit_cast<float, int32_t>(result_bits);
}
ASSEMBLER_TEST_GENERATE(Vrsqrtes, assembler) {
__ LoadDImmediate(V1, 147.0);
__ fcvtsd(V1, V1);
__ vrsqrtes(V0, V1);
__ fcvtds(V0, V0);
__ ret();
}
ASSEMBLER_TEST_RUN(Vrsqrtes, test) {
EXPECT(test != NULL);
typedef double (*DoubleReturn)() DART_UNUSED;
double res = EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry());
EXPECT_FLOAT_EQ(arm_reciprocal_sqrt_estimate(147.0), res, 0.0001);
}
ASSEMBLER_TEST_GENERATE(Vrsqrtss, assembler) {
__ LoadDImmediate(V1, 5.0);
__ LoadDImmediate(V2, 10.0);
__ fcvtsd(V1, V1);
__ fcvtsd(V2, V2);
__ vrsqrtss(V0, V1, V2);
__ fcvtds(V0, V0);
__ ret();
}
ASSEMBLER_TEST_RUN(Vrsqrtss, test) {
EXPECT(test != NULL);
typedef double (*DoubleReturn)() DART_UNUSED;
double res = EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry());
EXPECT_FLOAT_EQ((3.0 - 10.0 * 5.0) / 2.0, res, 0.0001);
}
ASSEMBLER_TEST_GENERATE(ReciprocalSqrt, assembler) {
__ LoadDImmediate(V1, 147000.0);
__ fcvtsd(V1, V1);
__ VRSqrts(V0, V1);
__ fcvtds(V0, V0);
__ ret();
}
ASSEMBLER_TEST_RUN(ReciprocalSqrt, test) {
EXPECT(test != NULL);
typedef double (*DoubleReturn)() DART_UNUSED;
double res = EXECUTE_TEST_CODE_DOUBLE(DoubleReturn, test->entry());
EXPECT_FLOAT_EQ(1.0 / sqrt(147000.0), res, 0.0001);
}
// Called from assembler_test.cc.
// LR: return address.
// R0: value.
// R1: growable array.
// R2: current thread.
ASSEMBLER_TEST_GENERATE(StoreIntoObject, assembler) {
__ SetupDartSP();
__ Push(CODE_REG);
__ Push(THR);
__ Push(LR);
__ mov(THR, R2);
__ StoreIntoObject(R1, FieldAddress(R1, GrowableObjectArray::data_offset()),
R0);
__ Pop(LR);
__ Pop(THR);
__ Pop(CODE_REG);
__ RestoreCSP();
__ ret();
}
} // namespace dart
#endif // defined(TARGET_ARCH_ARM64)