| // Copyright 2013 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 <stdio.h> |
| #include <stdlib.h> |
| #include <string.h> |
| #include <cmath> |
| #include <limits> |
| |
| #include "src/v8.h" |
| |
| #include "src/arm64/decoder-arm64-inl.h" |
| #include "src/arm64/disasm-arm64.h" |
| #include "src/arm64/simulator-arm64.h" |
| #include "src/arm64/utils-arm64.h" |
| #include "src/macro-assembler.h" |
| #include "test/cctest/cctest.h" |
| #include "test/cctest/test-utils-arm64.h" |
| |
| using namespace v8::internal; |
| |
| // Test infrastructure. |
| // |
| // Tests are functions which accept no parameters and have no return values. |
| // The testing code should not perform an explicit return once completed. For |
| // example to test the mov immediate instruction a very simple test would be: |
| // |
| // TEST(mov_x0_one) { |
| // SETUP(); |
| // |
| // START(); |
| // __ mov(x0, Operand(1)); |
| // END(); |
| // |
| // RUN(); |
| // |
| // CHECK_EQUAL_64(1, x0); |
| // |
| // TEARDOWN(); |
| // } |
| // |
| // Within a START ... END block all registers but sp can be modified. sp has to |
| // be explicitly saved/restored. The END() macro replaces the function return |
| // so it may appear multiple times in a test if the test has multiple exit |
| // points. |
| // |
| // Once the test has been run all integer and floating point registers as well |
| // as flags are accessible through a RegisterDump instance, see |
| // utils-arm64.cc for more info on RegisterDump. |
| // |
| // We provide some helper assert to handle common cases: |
| // |
| // CHECK_EQUAL_32(int32_t, int_32t) |
| // CHECK_EQUAL_FP32(float, float) |
| // CHECK_EQUAL_32(int32_t, W register) |
| // CHECK_EQUAL_FP32(float, S register) |
| // CHECK_EQUAL_64(int64_t, int_64t) |
| // CHECK_EQUAL_FP64(double, double) |
| // CHECK_EQUAL_64(int64_t, X register) |
| // CHECK_EQUAL_64(X register, X register) |
| // CHECK_EQUAL_FP64(double, D register) |
| // |
| // e.g. CHECK_EQUAL_64(0.5, d30); |
| // |
| // If more advance computation is required before the assert then access the |
| // RegisterDump named core directly: |
| // |
| // CHECK_EQUAL_64(0x1234, core.xreg(0) & 0xffff); |
| |
| |
| #if 0 // TODO(all): enable. |
| static v8::Persistent<v8::Context> env; |
| |
| static void InitializeVM() { |
| if (env.IsEmpty()) { |
| env = v8::Context::New(); |
| } |
| } |
| #endif |
| |
| #define __ masm. |
| |
| #define BUF_SIZE 8192 |
| #define SETUP() SETUP_SIZE(BUF_SIZE) |
| |
| #define INIT_V8() \ |
| CcTest::InitializeVM(); \ |
| |
| #ifdef USE_SIMULATOR |
| |
| // Run tests with the simulator. |
| #define SETUP_SIZE(buf_size) \ |
| Isolate* isolate = Isolate::Current(); \ |
| HandleScope scope(isolate); \ |
| DCHECK(isolate != NULL); \ |
| byte* buf = new byte[buf_size]; \ |
| MacroAssembler masm(isolate, buf, buf_size); \ |
| Decoder<DispatchingDecoderVisitor>* decoder = \ |
| new Decoder<DispatchingDecoderVisitor>(); \ |
| Simulator simulator(decoder); \ |
| PrintDisassembler* pdis = NULL; \ |
| RegisterDump core; |
| |
| /* if (Cctest::trace_sim()) { \ |
| pdis = new PrintDisassembler(stdout); \ |
| decoder.PrependVisitor(pdis); \ |
| } \ |
| */ |
| |
| // Reset the assembler and simulator, so that instructions can be generated, |
| // but don't actually emit any code. This can be used by tests that need to |
| // emit instructions at the start of the buffer. Note that START_AFTER_RESET |
| // must be called before any callee-saved register is modified, and before an |
| // END is encountered. |
| // |
| // Most tests should call START, rather than call RESET directly. |
| #define RESET() \ |
| __ Reset(); \ |
| simulator.ResetState(); |
| |
| #define START_AFTER_RESET() \ |
| __ SetStackPointer(csp); \ |
| __ PushCalleeSavedRegisters(); \ |
| __ Debug("Start test.", __LINE__, TRACE_ENABLE | LOG_ALL); |
| |
| #define START() \ |
| RESET(); \ |
| START_AFTER_RESET(); |
| |
| #define RUN() \ |
| simulator.RunFrom(reinterpret_cast<Instruction*>(buf)) |
| |
| #define END() \ |
| __ Debug("End test.", __LINE__, TRACE_DISABLE | LOG_ALL); \ |
| core.Dump(&masm); \ |
| __ PopCalleeSavedRegisters(); \ |
| __ Ret(); \ |
| __ GetCode(NULL); |
| |
| #define TEARDOWN() \ |
| delete pdis; \ |
| delete[] buf; |
| |
| #else // ifdef USE_SIMULATOR. |
| // Run the test on real hardware or models. |
| #define SETUP_SIZE(buf_size) \ |
| Isolate* isolate = Isolate::Current(); \ |
| HandleScope scope(isolate); \ |
| DCHECK(isolate != NULL); \ |
| byte* buf = new byte[buf_size]; \ |
| MacroAssembler masm(isolate, buf, buf_size); \ |
| RegisterDump core; |
| |
| #define RESET() \ |
| __ Reset(); \ |
| /* Reset the machine state (like simulator.ResetState()). */ \ |
| __ Msr(NZCV, xzr); \ |
| __ Msr(FPCR, xzr); |
| |
| |
| #define START_AFTER_RESET() \ |
| __ SetStackPointer(csp); \ |
| __ PushCalleeSavedRegisters(); |
| |
| #define START() \ |
| RESET(); \ |
| START_AFTER_RESET(); |
| |
| #define RUN() \ |
| CpuFeatures::FlushICache(buf, masm.SizeOfGeneratedCode()); \ |
| { \ |
| void (*test_function)(void); \ |
| memcpy(&test_function, &buf, sizeof(buf)); \ |
| test_function(); \ |
| } |
| |
| #define END() \ |
| core.Dump(&masm); \ |
| __ PopCalleeSavedRegisters(); \ |
| __ Ret(); \ |
| __ GetCode(NULL); |
| |
| #define TEARDOWN() \ |
| delete[] buf; |
| |
| #endif // ifdef USE_SIMULATOR. |
| |
| #define CHECK_EQUAL_NZCV(expected) \ |
| CHECK(EqualNzcv(expected, core.flags_nzcv())) |
| |
| #define CHECK_EQUAL_REGISTERS(expected) \ |
| CHECK(EqualRegisters(&expected, &core)) |
| |
| #define CHECK_EQUAL_32(expected, result) \ |
| CHECK(Equal32(static_cast<uint32_t>(expected), &core, result)) |
| |
| #define CHECK_EQUAL_FP32(expected, result) \ |
| CHECK(EqualFP32(expected, &core, result)) |
| |
| #define CHECK_EQUAL_64(expected, result) \ |
| CHECK(Equal64(expected, &core, result)) |
| |
| #define CHECK_EQUAL_FP64(expected, result) \ |
| CHECK(EqualFP64(expected, &core, result)) |
| |
| #ifdef DEBUG |
| #define DCHECK_LITERAL_POOL_SIZE(expected) \ |
| CHECK((expected) == (__ LiteralPoolSize())) |
| #else |
| #define DCHECK_LITERAL_POOL_SIZE(expected) \ |
| ((void) 0) |
| #endif |
| |
| |
| TEST(stack_ops) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| // save csp. |
| __ Mov(x29, csp); |
| |
| // Set the csp to a known value. |
| __ Mov(x16, 0x1000); |
| __ Mov(csp, x16); |
| __ Mov(x0, csp); |
| |
| // Add immediate to the csp, and move the result to a normal register. |
| __ Add(csp, csp, Operand(0x50)); |
| __ Mov(x1, csp); |
| |
| // Add extended to the csp, and move the result to a normal register. |
| __ Mov(x17, 0xfff); |
| __ Add(csp, csp, Operand(x17, SXTB)); |
| __ Mov(x2, csp); |
| |
| // Create an csp using a logical instruction, and move to normal register. |
| __ Orr(csp, xzr, Operand(0x1fff)); |
| __ Mov(x3, csp); |
| |
| // Write wcsp using a logical instruction. |
| __ Orr(wcsp, wzr, Operand(0xfffffff8L)); |
| __ Mov(x4, csp); |
| |
| // Write csp, and read back wcsp. |
| __ Orr(csp, xzr, Operand(0xfffffff8L)); |
| __ Mov(w5, wcsp); |
| |
| // restore csp. |
| __ Mov(csp, x29); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x1000, x0); |
| CHECK_EQUAL_64(0x1050, x1); |
| CHECK_EQUAL_64(0x104f, x2); |
| CHECK_EQUAL_64(0x1fff, x3); |
| CHECK_EQUAL_64(0xfffffff8, x4); |
| CHECK_EQUAL_64(0xfffffff8, x5); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(mvn) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mvn(w0, 0xfff); |
| __ Mvn(x1, 0xfff); |
| __ Mvn(w2, Operand(w0, LSL, 1)); |
| __ Mvn(x3, Operand(x1, LSL, 2)); |
| __ Mvn(w4, Operand(w0, LSR, 3)); |
| __ Mvn(x5, Operand(x1, LSR, 4)); |
| __ Mvn(w6, Operand(w0, ASR, 11)); |
| __ Mvn(x7, Operand(x1, ASR, 12)); |
| __ Mvn(w8, Operand(w0, ROR, 13)); |
| __ Mvn(x9, Operand(x1, ROR, 14)); |
| __ Mvn(w10, Operand(w2, UXTB)); |
| __ Mvn(x11, Operand(x2, SXTB, 1)); |
| __ Mvn(w12, Operand(w2, UXTH, 2)); |
| __ Mvn(x13, Operand(x2, SXTH, 3)); |
| __ Mvn(x14, Operand(w2, UXTW, 4)); |
| __ Mvn(x15, Operand(w2, SXTW, 4)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0xfffff000, x0); |
| CHECK_EQUAL_64(0xfffffffffffff000UL, x1); |
| CHECK_EQUAL_64(0x00001fff, x2); |
| CHECK_EQUAL_64(0x0000000000003fffUL, x3); |
| CHECK_EQUAL_64(0xe00001ff, x4); |
| CHECK_EQUAL_64(0xf0000000000000ffUL, x5); |
| CHECK_EQUAL_64(0x00000001, x6); |
| CHECK_EQUAL_64(0x0, x7); |
| CHECK_EQUAL_64(0x7ff80000, x8); |
| CHECK_EQUAL_64(0x3ffc000000000000UL, x9); |
| CHECK_EQUAL_64(0xffffff00, x10); |
| CHECK_EQUAL_64(0x0000000000000001UL, x11); |
| CHECK_EQUAL_64(0xffff8003, x12); |
| CHECK_EQUAL_64(0xffffffffffff0007UL, x13); |
| CHECK_EQUAL_64(0xfffffffffffe000fUL, x14); |
| CHECK_EQUAL_64(0xfffffffffffe000fUL, x15); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(mov) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0xffffffffffffffffL); |
| __ Mov(x1, 0xffffffffffffffffL); |
| __ Mov(x2, 0xffffffffffffffffL); |
| __ Mov(x3, 0xffffffffffffffffL); |
| |
| __ Mov(x0, 0x0123456789abcdefL); |
| |
| __ movz(x1, 0xabcdL << 16); |
| __ movk(x2, 0xabcdL << 32); |
| __ movn(x3, 0xabcdL << 48); |
| |
| __ Mov(x4, 0x0123456789abcdefL); |
| __ Mov(x5, x4); |
| |
| __ Mov(w6, -1); |
| |
| // Test that moves back to the same register have the desired effect. This |
| // is a no-op for X registers, and a truncation for W registers. |
| __ Mov(x7, 0x0123456789abcdefL); |
| __ Mov(x7, x7); |
| __ Mov(x8, 0x0123456789abcdefL); |
| __ Mov(w8, w8); |
| __ Mov(x9, 0x0123456789abcdefL); |
| __ Mov(x9, Operand(x9)); |
| __ Mov(x10, 0x0123456789abcdefL); |
| __ Mov(w10, Operand(w10)); |
| |
| __ Mov(w11, 0xfff); |
| __ Mov(x12, 0xfff); |
| __ Mov(w13, Operand(w11, LSL, 1)); |
| __ Mov(x14, Operand(x12, LSL, 2)); |
| __ Mov(w15, Operand(w11, LSR, 3)); |
| __ Mov(x18, Operand(x12, LSR, 4)); |
| __ Mov(w19, Operand(w11, ASR, 11)); |
| __ Mov(x20, Operand(x12, ASR, 12)); |
| __ Mov(w21, Operand(w11, ROR, 13)); |
| __ Mov(x22, Operand(x12, ROR, 14)); |
| __ Mov(w23, Operand(w13, UXTB)); |
| __ Mov(x24, Operand(x13, SXTB, 1)); |
| __ Mov(w25, Operand(w13, UXTH, 2)); |
| __ Mov(x26, Operand(x13, SXTH, 3)); |
| __ Mov(x27, Operand(w13, UXTW, 4)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x0123456789abcdefL, x0); |
| CHECK_EQUAL_64(0x00000000abcd0000L, x1); |
| CHECK_EQUAL_64(0xffffabcdffffffffL, x2); |
| CHECK_EQUAL_64(0x5432ffffffffffffL, x3); |
| CHECK_EQUAL_64(x4, x5); |
| CHECK_EQUAL_32(-1, w6); |
| CHECK_EQUAL_64(0x0123456789abcdefL, x7); |
| CHECK_EQUAL_32(0x89abcdefL, w8); |
| CHECK_EQUAL_64(0x0123456789abcdefL, x9); |
| CHECK_EQUAL_32(0x89abcdefL, w10); |
| CHECK_EQUAL_64(0x00000fff, x11); |
| CHECK_EQUAL_64(0x0000000000000fffUL, x12); |
| CHECK_EQUAL_64(0x00001ffe, x13); |
| CHECK_EQUAL_64(0x0000000000003ffcUL, x14); |
| CHECK_EQUAL_64(0x000001ff, x15); |
| CHECK_EQUAL_64(0x00000000000000ffUL, x18); |
| CHECK_EQUAL_64(0x00000001, x19); |
| CHECK_EQUAL_64(0x0, x20); |
| CHECK_EQUAL_64(0x7ff80000, x21); |
| CHECK_EQUAL_64(0x3ffc000000000000UL, x22); |
| CHECK_EQUAL_64(0x000000fe, x23); |
| CHECK_EQUAL_64(0xfffffffffffffffcUL, x24); |
| CHECK_EQUAL_64(0x00007ff8, x25); |
| CHECK_EQUAL_64(0x000000000000fff0UL, x26); |
| CHECK_EQUAL_64(0x000000000001ffe0UL, x27); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(mov_imm_w) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(w0, 0xffffffffL); |
| __ Mov(w1, 0xffff1234L); |
| __ Mov(w2, 0x1234ffffL); |
| __ Mov(w3, 0x00000000L); |
| __ Mov(w4, 0x00001234L); |
| __ Mov(w5, 0x12340000L); |
| __ Mov(w6, 0x12345678L); |
| __ Mov(w7, (int32_t)0x80000000); |
| __ Mov(w8, (int32_t)0xffff0000); |
| __ Mov(w9, kWMinInt); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0xffffffffL, x0); |
| CHECK_EQUAL_64(0xffff1234L, x1); |
| CHECK_EQUAL_64(0x1234ffffL, x2); |
| CHECK_EQUAL_64(0x00000000L, x3); |
| CHECK_EQUAL_64(0x00001234L, x4); |
| CHECK_EQUAL_64(0x12340000L, x5); |
| CHECK_EQUAL_64(0x12345678L, x6); |
| CHECK_EQUAL_64(0x80000000L, x7); |
| CHECK_EQUAL_64(0xffff0000L, x8); |
| CHECK_EQUAL_32(kWMinInt, w9); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(mov_imm_x) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0xffffffffffffffffL); |
| __ Mov(x1, 0xffffffffffff1234L); |
| __ Mov(x2, 0xffffffff12345678L); |
| __ Mov(x3, 0xffff1234ffff5678L); |
| __ Mov(x4, 0x1234ffffffff5678L); |
| __ Mov(x5, 0x1234ffff5678ffffL); |
| __ Mov(x6, 0x12345678ffffffffL); |
| __ Mov(x7, 0x1234ffffffffffffL); |
| __ Mov(x8, 0x123456789abcffffL); |
| __ Mov(x9, 0x12345678ffff9abcL); |
| __ Mov(x10, 0x1234ffff56789abcL); |
| __ Mov(x11, 0xffff123456789abcL); |
| __ Mov(x12, 0x0000000000000000L); |
| __ Mov(x13, 0x0000000000001234L); |
| __ Mov(x14, 0x0000000012345678L); |
| __ Mov(x15, 0x0000123400005678L); |
| __ Mov(x18, 0x1234000000005678L); |
| __ Mov(x19, 0x1234000056780000L); |
| __ Mov(x20, 0x1234567800000000L); |
| __ Mov(x21, 0x1234000000000000L); |
| __ Mov(x22, 0x123456789abc0000L); |
| __ Mov(x23, 0x1234567800009abcL); |
| __ Mov(x24, 0x1234000056789abcL); |
| __ Mov(x25, 0x0000123456789abcL); |
| __ Mov(x26, 0x123456789abcdef0L); |
| __ Mov(x27, 0xffff000000000001L); |
| __ Mov(x28, 0x8000ffff00000000L); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0xffffffffffff1234L, x1); |
| CHECK_EQUAL_64(0xffffffff12345678L, x2); |
| CHECK_EQUAL_64(0xffff1234ffff5678L, x3); |
| CHECK_EQUAL_64(0x1234ffffffff5678L, x4); |
| CHECK_EQUAL_64(0x1234ffff5678ffffL, x5); |
| CHECK_EQUAL_64(0x12345678ffffffffL, x6); |
| CHECK_EQUAL_64(0x1234ffffffffffffL, x7); |
| CHECK_EQUAL_64(0x123456789abcffffL, x8); |
| CHECK_EQUAL_64(0x12345678ffff9abcL, x9); |
| CHECK_EQUAL_64(0x1234ffff56789abcL, x10); |
| CHECK_EQUAL_64(0xffff123456789abcL, x11); |
| CHECK_EQUAL_64(0x0000000000000000L, x12); |
| CHECK_EQUAL_64(0x0000000000001234L, x13); |
| CHECK_EQUAL_64(0x0000000012345678L, x14); |
| CHECK_EQUAL_64(0x0000123400005678L, x15); |
| CHECK_EQUAL_64(0x1234000000005678L, x18); |
| CHECK_EQUAL_64(0x1234000056780000L, x19); |
| CHECK_EQUAL_64(0x1234567800000000L, x20); |
| CHECK_EQUAL_64(0x1234000000000000L, x21); |
| CHECK_EQUAL_64(0x123456789abc0000L, x22); |
| CHECK_EQUAL_64(0x1234567800009abcL, x23); |
| CHECK_EQUAL_64(0x1234000056789abcL, x24); |
| CHECK_EQUAL_64(0x0000123456789abcL, x25); |
| CHECK_EQUAL_64(0x123456789abcdef0L, x26); |
| CHECK_EQUAL_64(0xffff000000000001L, x27); |
| CHECK_EQUAL_64(0x8000ffff00000000L, x28); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(orr) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0xf0f0); |
| __ Mov(x1, 0xf00000ff); |
| |
| __ Orr(x2, x0, Operand(x1)); |
| __ Orr(w3, w0, Operand(w1, LSL, 28)); |
| __ Orr(x4, x0, Operand(x1, LSL, 32)); |
| __ Orr(x5, x0, Operand(x1, LSR, 4)); |
| __ Orr(w6, w0, Operand(w1, ASR, 4)); |
| __ Orr(x7, x0, Operand(x1, ASR, 4)); |
| __ Orr(w8, w0, Operand(w1, ROR, 12)); |
| __ Orr(x9, x0, Operand(x1, ROR, 12)); |
| __ Orr(w10, w0, Operand(0xf)); |
| __ Orr(x11, x0, Operand(0xf0000000f0000000L)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0xf000f0ff, x2); |
| CHECK_EQUAL_64(0xf000f0f0, x3); |
| CHECK_EQUAL_64(0xf00000ff0000f0f0L, x4); |
| CHECK_EQUAL_64(0x0f00f0ff, x5); |
| CHECK_EQUAL_64(0xff00f0ff, x6); |
| CHECK_EQUAL_64(0x0f00f0ff, x7); |
| CHECK_EQUAL_64(0x0ffff0f0, x8); |
| CHECK_EQUAL_64(0x0ff00000000ff0f0L, x9); |
| CHECK_EQUAL_64(0xf0ff, x10); |
| CHECK_EQUAL_64(0xf0000000f000f0f0L, x11); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(orr_extend) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 1); |
| __ Mov(x1, 0x8000000080008080UL); |
| __ Orr(w6, w0, Operand(w1, UXTB)); |
| __ Orr(x7, x0, Operand(x1, UXTH, 1)); |
| __ Orr(w8, w0, Operand(w1, UXTW, 2)); |
| __ Orr(x9, x0, Operand(x1, UXTX, 3)); |
| __ Orr(w10, w0, Operand(w1, SXTB)); |
| __ Orr(x11, x0, Operand(x1, SXTH, 1)); |
| __ Orr(x12, x0, Operand(x1, SXTW, 2)); |
| __ Orr(x13, x0, Operand(x1, SXTX, 3)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x00000081, x6); |
| CHECK_EQUAL_64(0x00010101, x7); |
| CHECK_EQUAL_64(0x00020201, x8); |
| CHECK_EQUAL_64(0x0000000400040401UL, x9); |
| CHECK_EQUAL_64(0x00000000ffffff81UL, x10); |
| CHECK_EQUAL_64(0xffffffffffff0101UL, x11); |
| CHECK_EQUAL_64(0xfffffffe00020201UL, x12); |
| CHECK_EQUAL_64(0x0000000400040401UL, x13); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(bitwise_wide_imm) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0); |
| __ Mov(x1, 0xf0f0f0f0f0f0f0f0UL); |
| |
| __ Orr(x10, x0, Operand(0x1234567890abcdefUL)); |
| __ Orr(w11, w1, Operand(0x90abcdef)); |
| |
| __ Orr(w12, w0, kWMinInt); |
| __ Eor(w13, w0, kWMinInt); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0, x0); |
| CHECK_EQUAL_64(0xf0f0f0f0f0f0f0f0UL, x1); |
| CHECK_EQUAL_64(0x1234567890abcdefUL, x10); |
| CHECK_EQUAL_64(0xf0fbfdffUL, x11); |
| CHECK_EQUAL_32(kWMinInt, w12); |
| CHECK_EQUAL_32(kWMinInt, w13); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(orn) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0xf0f0); |
| __ Mov(x1, 0xf00000ff); |
| |
| __ Orn(x2, x0, Operand(x1)); |
| __ Orn(w3, w0, Operand(w1, LSL, 4)); |
| __ Orn(x4, x0, Operand(x1, LSL, 4)); |
| __ Orn(x5, x0, Operand(x1, LSR, 1)); |
| __ Orn(w6, w0, Operand(w1, ASR, 1)); |
| __ Orn(x7, x0, Operand(x1, ASR, 1)); |
| __ Orn(w8, w0, Operand(w1, ROR, 16)); |
| __ Orn(x9, x0, Operand(x1, ROR, 16)); |
| __ Orn(w10, w0, Operand(0xffff)); |
| __ Orn(x11, x0, Operand(0xffff0000ffffL)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0xffffffff0ffffff0L, x2); |
| CHECK_EQUAL_64(0xfffff0ff, x3); |
| CHECK_EQUAL_64(0xfffffff0fffff0ffL, x4); |
| CHECK_EQUAL_64(0xffffffff87fffff0L, x5); |
| CHECK_EQUAL_64(0x07fffff0, x6); |
| CHECK_EQUAL_64(0xffffffff87fffff0L, x7); |
| CHECK_EQUAL_64(0xff00ffff, x8); |
| CHECK_EQUAL_64(0xff00ffffffffffffL, x9); |
| CHECK_EQUAL_64(0xfffff0f0, x10); |
| CHECK_EQUAL_64(0xffff0000fffff0f0L, x11); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(orn_extend) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 1); |
| __ Mov(x1, 0x8000000080008081UL); |
| __ Orn(w6, w0, Operand(w1, UXTB)); |
| __ Orn(x7, x0, Operand(x1, UXTH, 1)); |
| __ Orn(w8, w0, Operand(w1, UXTW, 2)); |
| __ Orn(x9, x0, Operand(x1, UXTX, 3)); |
| __ Orn(w10, w0, Operand(w1, SXTB)); |
| __ Orn(x11, x0, Operand(x1, SXTH, 1)); |
| __ Orn(x12, x0, Operand(x1, SXTW, 2)); |
| __ Orn(x13, x0, Operand(x1, SXTX, 3)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0xffffff7f, x6); |
| CHECK_EQUAL_64(0xfffffffffffefefdUL, x7); |
| CHECK_EQUAL_64(0xfffdfdfb, x8); |
| CHECK_EQUAL_64(0xfffffffbfffbfbf7UL, x9); |
| CHECK_EQUAL_64(0x0000007f, x10); |
| CHECK_EQUAL_64(0x0000fefd, x11); |
| CHECK_EQUAL_64(0x00000001fffdfdfbUL, x12); |
| CHECK_EQUAL_64(0xfffffffbfffbfbf7UL, x13); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(and_) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0xfff0); |
| __ Mov(x1, 0xf00000ff); |
| |
| __ And(x2, x0, Operand(x1)); |
| __ And(w3, w0, Operand(w1, LSL, 4)); |
| __ And(x4, x0, Operand(x1, LSL, 4)); |
| __ And(x5, x0, Operand(x1, LSR, 1)); |
| __ And(w6, w0, Operand(w1, ASR, 20)); |
| __ And(x7, x0, Operand(x1, ASR, 20)); |
| __ And(w8, w0, Operand(w1, ROR, 28)); |
| __ And(x9, x0, Operand(x1, ROR, 28)); |
| __ And(w10, w0, Operand(0xff00)); |
| __ And(x11, x0, Operand(0xff)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x000000f0, x2); |
| CHECK_EQUAL_64(0x00000ff0, x3); |
| CHECK_EQUAL_64(0x00000ff0, x4); |
| CHECK_EQUAL_64(0x00000070, x5); |
| CHECK_EQUAL_64(0x0000ff00, x6); |
| CHECK_EQUAL_64(0x00000f00, x7); |
| CHECK_EQUAL_64(0x00000ff0, x8); |
| CHECK_EQUAL_64(0x00000000, x9); |
| CHECK_EQUAL_64(0x0000ff00, x10); |
| CHECK_EQUAL_64(0x000000f0, x11); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(and_extend) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0xffffffffffffffffUL); |
| __ Mov(x1, 0x8000000080008081UL); |
| __ And(w6, w0, Operand(w1, UXTB)); |
| __ And(x7, x0, Operand(x1, UXTH, 1)); |
| __ And(w8, w0, Operand(w1, UXTW, 2)); |
| __ And(x9, x0, Operand(x1, UXTX, 3)); |
| __ And(w10, w0, Operand(w1, SXTB)); |
| __ And(x11, x0, Operand(x1, SXTH, 1)); |
| __ And(x12, x0, Operand(x1, SXTW, 2)); |
| __ And(x13, x0, Operand(x1, SXTX, 3)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x00000081, x6); |
| CHECK_EQUAL_64(0x00010102, x7); |
| CHECK_EQUAL_64(0x00020204, x8); |
| CHECK_EQUAL_64(0x0000000400040408UL, x9); |
| CHECK_EQUAL_64(0xffffff81, x10); |
| CHECK_EQUAL_64(0xffffffffffff0102UL, x11); |
| CHECK_EQUAL_64(0xfffffffe00020204UL, x12); |
| CHECK_EQUAL_64(0x0000000400040408UL, x13); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ands) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x1, 0xf00000ff); |
| __ Ands(w0, w1, Operand(w1)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(NFlag); |
| CHECK_EQUAL_64(0xf00000ff, x0); |
| |
| START(); |
| __ Mov(x0, 0xfff0); |
| __ Mov(x1, 0xf00000ff); |
| __ Ands(w0, w0, Operand(w1, LSR, 4)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(ZFlag); |
| CHECK_EQUAL_64(0x00000000, x0); |
| |
| START(); |
| __ Mov(x0, 0x8000000000000000L); |
| __ Mov(x1, 0x00000001); |
| __ Ands(x0, x0, Operand(x1, ROR, 1)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(NFlag); |
| CHECK_EQUAL_64(0x8000000000000000L, x0); |
| |
| START(); |
| __ Mov(x0, 0xfff0); |
| __ Ands(w0, w0, Operand(0xf)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(ZFlag); |
| CHECK_EQUAL_64(0x00000000, x0); |
| |
| START(); |
| __ Mov(x0, 0xff000000); |
| __ Ands(w0, w0, Operand(0x80000000)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(NFlag); |
| CHECK_EQUAL_64(0x80000000, x0); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(bic) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0xfff0); |
| __ Mov(x1, 0xf00000ff); |
| |
| __ Bic(x2, x0, Operand(x1)); |
| __ Bic(w3, w0, Operand(w1, LSL, 4)); |
| __ Bic(x4, x0, Operand(x1, LSL, 4)); |
| __ Bic(x5, x0, Operand(x1, LSR, 1)); |
| __ Bic(w6, w0, Operand(w1, ASR, 20)); |
| __ Bic(x7, x0, Operand(x1, ASR, 20)); |
| __ Bic(w8, w0, Operand(w1, ROR, 28)); |
| __ Bic(x9, x0, Operand(x1, ROR, 24)); |
| __ Bic(x10, x0, Operand(0x1f)); |
| __ Bic(x11, x0, Operand(0x100)); |
| |
| // Test bic into csp when the constant cannot be encoded in the immediate |
| // field. |
| // Use x20 to preserve csp. We check for the result via x21 because the |
| // test infrastructure requires that csp be restored to its original value. |
| __ Mov(x20, csp); |
| __ Mov(x0, 0xffffff); |
| __ Bic(csp, x0, Operand(0xabcdef)); |
| __ Mov(x21, csp); |
| __ Mov(csp, x20); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x0000ff00, x2); |
| CHECK_EQUAL_64(0x0000f000, x3); |
| CHECK_EQUAL_64(0x0000f000, x4); |
| CHECK_EQUAL_64(0x0000ff80, x5); |
| CHECK_EQUAL_64(0x000000f0, x6); |
| CHECK_EQUAL_64(0x0000f0f0, x7); |
| CHECK_EQUAL_64(0x0000f000, x8); |
| CHECK_EQUAL_64(0x0000ff00, x9); |
| CHECK_EQUAL_64(0x0000ffe0, x10); |
| CHECK_EQUAL_64(0x0000fef0, x11); |
| |
| CHECK_EQUAL_64(0x543210, x21); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(bic_extend) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0xffffffffffffffffUL); |
| __ Mov(x1, 0x8000000080008081UL); |
| __ Bic(w6, w0, Operand(w1, UXTB)); |
| __ Bic(x7, x0, Operand(x1, UXTH, 1)); |
| __ Bic(w8, w0, Operand(w1, UXTW, 2)); |
| __ Bic(x9, x0, Operand(x1, UXTX, 3)); |
| __ Bic(w10, w0, Operand(w1, SXTB)); |
| __ Bic(x11, x0, Operand(x1, SXTH, 1)); |
| __ Bic(x12, x0, Operand(x1, SXTW, 2)); |
| __ Bic(x13, x0, Operand(x1, SXTX, 3)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0xffffff7e, x6); |
| CHECK_EQUAL_64(0xfffffffffffefefdUL, x7); |
| CHECK_EQUAL_64(0xfffdfdfb, x8); |
| CHECK_EQUAL_64(0xfffffffbfffbfbf7UL, x9); |
| CHECK_EQUAL_64(0x0000007e, x10); |
| CHECK_EQUAL_64(0x0000fefd, x11); |
| CHECK_EQUAL_64(0x00000001fffdfdfbUL, x12); |
| CHECK_EQUAL_64(0xfffffffbfffbfbf7UL, x13); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(bics) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x1, 0xffff); |
| __ Bics(w0, w1, Operand(w1)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(ZFlag); |
| CHECK_EQUAL_64(0x00000000, x0); |
| |
| START(); |
| __ Mov(x0, 0xffffffff); |
| __ Bics(w0, w0, Operand(w0, LSR, 1)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(NFlag); |
| CHECK_EQUAL_64(0x80000000, x0); |
| |
| START(); |
| __ Mov(x0, 0x8000000000000000L); |
| __ Mov(x1, 0x00000001); |
| __ Bics(x0, x0, Operand(x1, ROR, 1)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(ZFlag); |
| CHECK_EQUAL_64(0x00000000, x0); |
| |
| START(); |
| __ Mov(x0, 0xffffffffffffffffL); |
| __ Bics(x0, x0, Operand(0x7fffffffffffffffL)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(NFlag); |
| CHECK_EQUAL_64(0x8000000000000000L, x0); |
| |
| START(); |
| __ Mov(w0, 0xffff0000); |
| __ Bics(w0, w0, Operand(0xfffffff0)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(ZFlag); |
| CHECK_EQUAL_64(0x00000000, x0); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(eor) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0xfff0); |
| __ Mov(x1, 0xf00000ff); |
| |
| __ Eor(x2, x0, Operand(x1)); |
| __ Eor(w3, w0, Operand(w1, LSL, 4)); |
| __ Eor(x4, x0, Operand(x1, LSL, 4)); |
| __ Eor(x5, x0, Operand(x1, LSR, 1)); |
| __ Eor(w6, w0, Operand(w1, ASR, 20)); |
| __ Eor(x7, x0, Operand(x1, ASR, 20)); |
| __ Eor(w8, w0, Operand(w1, ROR, 28)); |
| __ Eor(x9, x0, Operand(x1, ROR, 28)); |
| __ Eor(w10, w0, Operand(0xff00ff00)); |
| __ Eor(x11, x0, Operand(0xff00ff00ff00ff00L)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0xf000ff0f, x2); |
| CHECK_EQUAL_64(0x0000f000, x3); |
| CHECK_EQUAL_64(0x0000000f0000f000L, x4); |
| CHECK_EQUAL_64(0x7800ff8f, x5); |
| CHECK_EQUAL_64(0xffff00f0, x6); |
| CHECK_EQUAL_64(0x0000f0f0, x7); |
| CHECK_EQUAL_64(0x0000f00f, x8); |
| CHECK_EQUAL_64(0x00000ff00000ffffL, x9); |
| CHECK_EQUAL_64(0xff0000f0, x10); |
| CHECK_EQUAL_64(0xff00ff00ff0000f0L, x11); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(eor_extend) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0x1111111111111111UL); |
| __ Mov(x1, 0x8000000080008081UL); |
| __ Eor(w6, w0, Operand(w1, UXTB)); |
| __ Eor(x7, x0, Operand(x1, UXTH, 1)); |
| __ Eor(w8, w0, Operand(w1, UXTW, 2)); |
| __ Eor(x9, x0, Operand(x1, UXTX, 3)); |
| __ Eor(w10, w0, Operand(w1, SXTB)); |
| __ Eor(x11, x0, Operand(x1, SXTH, 1)); |
| __ Eor(x12, x0, Operand(x1, SXTW, 2)); |
| __ Eor(x13, x0, Operand(x1, SXTX, 3)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x11111190, x6); |
| CHECK_EQUAL_64(0x1111111111101013UL, x7); |
| CHECK_EQUAL_64(0x11131315, x8); |
| CHECK_EQUAL_64(0x1111111511151519UL, x9); |
| CHECK_EQUAL_64(0xeeeeee90, x10); |
| CHECK_EQUAL_64(0xeeeeeeeeeeee1013UL, x11); |
| CHECK_EQUAL_64(0xeeeeeeef11131315UL, x12); |
| CHECK_EQUAL_64(0x1111111511151519UL, x13); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(eon) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0xfff0); |
| __ Mov(x1, 0xf00000ff); |
| |
| __ Eon(x2, x0, Operand(x1)); |
| __ Eon(w3, w0, Operand(w1, LSL, 4)); |
| __ Eon(x4, x0, Operand(x1, LSL, 4)); |
| __ Eon(x5, x0, Operand(x1, LSR, 1)); |
| __ Eon(w6, w0, Operand(w1, ASR, 20)); |
| __ Eon(x7, x0, Operand(x1, ASR, 20)); |
| __ Eon(w8, w0, Operand(w1, ROR, 28)); |
| __ Eon(x9, x0, Operand(x1, ROR, 28)); |
| __ Eon(w10, w0, Operand(0x03c003c0)); |
| __ Eon(x11, x0, Operand(0x0000100000001000L)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0xffffffff0fff00f0L, x2); |
| CHECK_EQUAL_64(0xffff0fff, x3); |
| CHECK_EQUAL_64(0xfffffff0ffff0fffL, x4); |
| CHECK_EQUAL_64(0xffffffff87ff0070L, x5); |
| CHECK_EQUAL_64(0x0000ff0f, x6); |
| CHECK_EQUAL_64(0xffffffffffff0f0fL, x7); |
| CHECK_EQUAL_64(0xffff0ff0, x8); |
| CHECK_EQUAL_64(0xfffff00fffff0000L, x9); |
| CHECK_EQUAL_64(0xfc3f03cf, x10); |
| CHECK_EQUAL_64(0xffffefffffff100fL, x11); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(eon_extend) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0x1111111111111111UL); |
| __ Mov(x1, 0x8000000080008081UL); |
| __ Eon(w6, w0, Operand(w1, UXTB)); |
| __ Eon(x7, x0, Operand(x1, UXTH, 1)); |
| __ Eon(w8, w0, Operand(w1, UXTW, 2)); |
| __ Eon(x9, x0, Operand(x1, UXTX, 3)); |
| __ Eon(w10, w0, Operand(w1, SXTB)); |
| __ Eon(x11, x0, Operand(x1, SXTH, 1)); |
| __ Eon(x12, x0, Operand(x1, SXTW, 2)); |
| __ Eon(x13, x0, Operand(x1, SXTX, 3)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0xeeeeee6f, x6); |
| CHECK_EQUAL_64(0xeeeeeeeeeeefefecUL, x7); |
| CHECK_EQUAL_64(0xeeececea, x8); |
| CHECK_EQUAL_64(0xeeeeeeeaeeeaeae6UL, x9); |
| CHECK_EQUAL_64(0x1111116f, x10); |
| CHECK_EQUAL_64(0x111111111111efecUL, x11); |
| CHECK_EQUAL_64(0x11111110eeececeaUL, x12); |
| CHECK_EQUAL_64(0xeeeeeeeaeeeaeae6UL, x13); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(mul) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x16, 0); |
| __ Mov(x17, 1); |
| __ Mov(x18, 0xffffffff); |
| __ Mov(x19, 0xffffffffffffffffUL); |
| |
| __ Mul(w0, w16, w16); |
| __ Mul(w1, w16, w17); |
| __ Mul(w2, w17, w18); |
| __ Mul(w3, w18, w19); |
| __ Mul(x4, x16, x16); |
| __ Mul(x5, x17, x18); |
| __ Mul(x6, x18, x19); |
| __ Mul(x7, x19, x19); |
| __ Smull(x8, w17, w18); |
| __ Smull(x9, w18, w18); |
| __ Smull(x10, w19, w19); |
| __ Mneg(w11, w16, w16); |
| __ Mneg(w12, w16, w17); |
| __ Mneg(w13, w17, w18); |
| __ Mneg(w14, w18, w19); |
| __ Mneg(x20, x16, x16); |
| __ Mneg(x21, x17, x18); |
| __ Mneg(x22, x18, x19); |
| __ Mneg(x23, x19, x19); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0, x0); |
| CHECK_EQUAL_64(0, x1); |
| CHECK_EQUAL_64(0xffffffff, x2); |
| CHECK_EQUAL_64(1, x3); |
| CHECK_EQUAL_64(0, x4); |
| CHECK_EQUAL_64(0xffffffff, x5); |
| CHECK_EQUAL_64(0xffffffff00000001UL, x6); |
| CHECK_EQUAL_64(1, x7); |
| CHECK_EQUAL_64(0xffffffffffffffffUL, x8); |
| CHECK_EQUAL_64(1, x9); |
| CHECK_EQUAL_64(1, x10); |
| CHECK_EQUAL_64(0, x11); |
| CHECK_EQUAL_64(0, x12); |
| CHECK_EQUAL_64(1, x13); |
| CHECK_EQUAL_64(0xffffffff, x14); |
| CHECK_EQUAL_64(0, x20); |
| CHECK_EQUAL_64(0xffffffff00000001UL, x21); |
| CHECK_EQUAL_64(0xffffffff, x22); |
| CHECK_EQUAL_64(0xffffffffffffffffUL, x23); |
| |
| TEARDOWN(); |
| } |
| |
| |
| static void SmullHelper(int64_t expected, int64_t a, int64_t b) { |
| SETUP(); |
| START(); |
| __ Mov(w0, a); |
| __ Mov(w1, b); |
| __ Smull(x2, w0, w1); |
| END(); |
| RUN(); |
| CHECK_EQUAL_64(expected, x2); |
| TEARDOWN(); |
| } |
| |
| |
| TEST(smull) { |
| INIT_V8(); |
| SmullHelper(0, 0, 0); |
| SmullHelper(1, 1, 1); |
| SmullHelper(-1, -1, 1); |
| SmullHelper(1, -1, -1); |
| SmullHelper(0xffffffff80000000, 0x80000000, 1); |
| SmullHelper(0x0000000080000000, 0x00010000, 0x00008000); |
| } |
| |
| |
| TEST(madd) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x16, 0); |
| __ Mov(x17, 1); |
| __ Mov(x18, 0xffffffff); |
| __ Mov(x19, 0xffffffffffffffffUL); |
| |
| __ Madd(w0, w16, w16, w16); |
| __ Madd(w1, w16, w16, w17); |
| __ Madd(w2, w16, w16, w18); |
| __ Madd(w3, w16, w16, w19); |
| __ Madd(w4, w16, w17, w17); |
| __ Madd(w5, w17, w17, w18); |
| __ Madd(w6, w17, w17, w19); |
| __ Madd(w7, w17, w18, w16); |
| __ Madd(w8, w17, w18, w18); |
| __ Madd(w9, w18, w18, w17); |
| __ Madd(w10, w18, w19, w18); |
| __ Madd(w11, w19, w19, w19); |
| |
| __ Madd(x12, x16, x16, x16); |
| __ Madd(x13, x16, x16, x17); |
| __ Madd(x14, x16, x16, x18); |
| __ Madd(x15, x16, x16, x19); |
| __ Madd(x20, x16, x17, x17); |
| __ Madd(x21, x17, x17, x18); |
| __ Madd(x22, x17, x17, x19); |
| __ Madd(x23, x17, x18, x16); |
| __ Madd(x24, x17, x18, x18); |
| __ Madd(x25, x18, x18, x17); |
| __ Madd(x26, x18, x19, x18); |
| __ Madd(x27, x19, x19, x19); |
| |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0, x0); |
| CHECK_EQUAL_64(1, x1); |
| CHECK_EQUAL_64(0xffffffff, x2); |
| CHECK_EQUAL_64(0xffffffff, x3); |
| CHECK_EQUAL_64(1, x4); |
| CHECK_EQUAL_64(0, x5); |
| CHECK_EQUAL_64(0, x6); |
| CHECK_EQUAL_64(0xffffffff, x7); |
| CHECK_EQUAL_64(0xfffffffe, x8); |
| CHECK_EQUAL_64(2, x9); |
| CHECK_EQUAL_64(0, x10); |
| CHECK_EQUAL_64(0, x11); |
| |
| CHECK_EQUAL_64(0, x12); |
| CHECK_EQUAL_64(1, x13); |
| CHECK_EQUAL_64(0xffffffff, x14); |
| CHECK_EQUAL_64(0xffffffffffffffff, x15); |
| CHECK_EQUAL_64(1, x20); |
| CHECK_EQUAL_64(0x100000000UL, x21); |
| CHECK_EQUAL_64(0, x22); |
| CHECK_EQUAL_64(0xffffffff, x23); |
| CHECK_EQUAL_64(0x1fffffffe, x24); |
| CHECK_EQUAL_64(0xfffffffe00000002UL, x25); |
| CHECK_EQUAL_64(0, x26); |
| CHECK_EQUAL_64(0, x27); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(msub) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x16, 0); |
| __ Mov(x17, 1); |
| __ Mov(x18, 0xffffffff); |
| __ Mov(x19, 0xffffffffffffffffUL); |
| |
| __ Msub(w0, w16, w16, w16); |
| __ Msub(w1, w16, w16, w17); |
| __ Msub(w2, w16, w16, w18); |
| __ Msub(w3, w16, w16, w19); |
| __ Msub(w4, w16, w17, w17); |
| __ Msub(w5, w17, w17, w18); |
| __ Msub(w6, w17, w17, w19); |
| __ Msub(w7, w17, w18, w16); |
| __ Msub(w8, w17, w18, w18); |
| __ Msub(w9, w18, w18, w17); |
| __ Msub(w10, w18, w19, w18); |
| __ Msub(w11, w19, w19, w19); |
| |
| __ Msub(x12, x16, x16, x16); |
| __ Msub(x13, x16, x16, x17); |
| __ Msub(x14, x16, x16, x18); |
| __ Msub(x15, x16, x16, x19); |
| __ Msub(x20, x16, x17, x17); |
| __ Msub(x21, x17, x17, x18); |
| __ Msub(x22, x17, x17, x19); |
| __ Msub(x23, x17, x18, x16); |
| __ Msub(x24, x17, x18, x18); |
| __ Msub(x25, x18, x18, x17); |
| __ Msub(x26, x18, x19, x18); |
| __ Msub(x27, x19, x19, x19); |
| |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0, x0); |
| CHECK_EQUAL_64(1, x1); |
| CHECK_EQUAL_64(0xffffffff, x2); |
| CHECK_EQUAL_64(0xffffffff, x3); |
| CHECK_EQUAL_64(1, x4); |
| CHECK_EQUAL_64(0xfffffffe, x5); |
| CHECK_EQUAL_64(0xfffffffe, x6); |
| CHECK_EQUAL_64(1, x7); |
| CHECK_EQUAL_64(0, x8); |
| CHECK_EQUAL_64(0, x9); |
| CHECK_EQUAL_64(0xfffffffe, x10); |
| CHECK_EQUAL_64(0xfffffffe, x11); |
| |
| CHECK_EQUAL_64(0, x12); |
| CHECK_EQUAL_64(1, x13); |
| CHECK_EQUAL_64(0xffffffff, x14); |
| CHECK_EQUAL_64(0xffffffffffffffffUL, x15); |
| CHECK_EQUAL_64(1, x20); |
| CHECK_EQUAL_64(0xfffffffeUL, x21); |
| CHECK_EQUAL_64(0xfffffffffffffffeUL, x22); |
| CHECK_EQUAL_64(0xffffffff00000001UL, x23); |
| CHECK_EQUAL_64(0, x24); |
| CHECK_EQUAL_64(0x200000000UL, x25); |
| CHECK_EQUAL_64(0x1fffffffeUL, x26); |
| CHECK_EQUAL_64(0xfffffffffffffffeUL, x27); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(smulh) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x20, 0); |
| __ Mov(x21, 1); |
| __ Mov(x22, 0x0000000100000000L); |
| __ Mov(x23, 0x12345678); |
| __ Mov(x24, 0x0123456789abcdefL); |
| __ Mov(x25, 0x0000000200000000L); |
| __ Mov(x26, 0x8000000000000000UL); |
| __ Mov(x27, 0xffffffffffffffffUL); |
| __ Mov(x28, 0x5555555555555555UL); |
| __ Mov(x29, 0xaaaaaaaaaaaaaaaaUL); |
| |
| __ Smulh(x0, x20, x24); |
| __ Smulh(x1, x21, x24); |
| __ Smulh(x2, x22, x23); |
| __ Smulh(x3, x22, x24); |
| __ Smulh(x4, x24, x25); |
| __ Smulh(x5, x23, x27); |
| __ Smulh(x6, x26, x26); |
| __ Smulh(x7, x26, x27); |
| __ Smulh(x8, x27, x27); |
| __ Smulh(x9, x28, x28); |
| __ Smulh(x10, x28, x29); |
| __ Smulh(x11, x29, x29); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0, x0); |
| CHECK_EQUAL_64(0, x1); |
| CHECK_EQUAL_64(0, x2); |
| CHECK_EQUAL_64(0x01234567, x3); |
| CHECK_EQUAL_64(0x02468acf, x4); |
| CHECK_EQUAL_64(0xffffffffffffffffUL, x5); |
| CHECK_EQUAL_64(0x4000000000000000UL, x6); |
| CHECK_EQUAL_64(0, x7); |
| CHECK_EQUAL_64(0, x8); |
| CHECK_EQUAL_64(0x1c71c71c71c71c71UL, x9); |
| CHECK_EQUAL_64(0xe38e38e38e38e38eUL, x10); |
| CHECK_EQUAL_64(0x1c71c71c71c71c72UL, x11); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(smaddl_umaddl) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x17, 1); |
| __ Mov(x18, 0xffffffff); |
| __ Mov(x19, 0xffffffffffffffffUL); |
| __ Mov(x20, 4); |
| __ Mov(x21, 0x200000000UL); |
| |
| __ Smaddl(x9, w17, w18, x20); |
| __ Smaddl(x10, w18, w18, x20); |
| __ Smaddl(x11, w19, w19, x20); |
| __ Smaddl(x12, w19, w19, x21); |
| __ Umaddl(x13, w17, w18, x20); |
| __ Umaddl(x14, w18, w18, x20); |
| __ Umaddl(x15, w19, w19, x20); |
| __ Umaddl(x22, w19, w19, x21); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(3, x9); |
| CHECK_EQUAL_64(5, x10); |
| CHECK_EQUAL_64(5, x11); |
| CHECK_EQUAL_64(0x200000001UL, x12); |
| CHECK_EQUAL_64(0x100000003UL, x13); |
| CHECK_EQUAL_64(0xfffffffe00000005UL, x14); |
| CHECK_EQUAL_64(0xfffffffe00000005UL, x15); |
| CHECK_EQUAL_64(0x1, x22); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(smsubl_umsubl) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x17, 1); |
| __ Mov(x18, 0xffffffff); |
| __ Mov(x19, 0xffffffffffffffffUL); |
| __ Mov(x20, 4); |
| __ Mov(x21, 0x200000000UL); |
| |
| __ Smsubl(x9, w17, w18, x20); |
| __ Smsubl(x10, w18, w18, x20); |
| __ Smsubl(x11, w19, w19, x20); |
| __ Smsubl(x12, w19, w19, x21); |
| __ Umsubl(x13, w17, w18, x20); |
| __ Umsubl(x14, w18, w18, x20); |
| __ Umsubl(x15, w19, w19, x20); |
| __ Umsubl(x22, w19, w19, x21); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(5, x9); |
| CHECK_EQUAL_64(3, x10); |
| CHECK_EQUAL_64(3, x11); |
| CHECK_EQUAL_64(0x1ffffffffUL, x12); |
| CHECK_EQUAL_64(0xffffffff00000005UL, x13); |
| CHECK_EQUAL_64(0x200000003UL, x14); |
| CHECK_EQUAL_64(0x200000003UL, x15); |
| CHECK_EQUAL_64(0x3ffffffffUL, x22); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(div) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x16, 1); |
| __ Mov(x17, 0xffffffff); |
| __ Mov(x18, 0xffffffffffffffffUL); |
| __ Mov(x19, 0x80000000); |
| __ Mov(x20, 0x8000000000000000UL); |
| __ Mov(x21, 2); |
| |
| __ Udiv(w0, w16, w16); |
| __ Udiv(w1, w17, w16); |
| __ Sdiv(w2, w16, w16); |
| __ Sdiv(w3, w16, w17); |
| __ Sdiv(w4, w17, w18); |
| |
| __ Udiv(x5, x16, x16); |
| __ Udiv(x6, x17, x18); |
| __ Sdiv(x7, x16, x16); |
| __ Sdiv(x8, x16, x17); |
| __ Sdiv(x9, x17, x18); |
| |
| __ Udiv(w10, w19, w21); |
| __ Sdiv(w11, w19, w21); |
| __ Udiv(x12, x19, x21); |
| __ Sdiv(x13, x19, x21); |
| __ Udiv(x14, x20, x21); |
| __ Sdiv(x15, x20, x21); |
| |
| __ Udiv(w22, w19, w17); |
| __ Sdiv(w23, w19, w17); |
| __ Udiv(x24, x20, x18); |
| __ Sdiv(x25, x20, x18); |
| |
| __ Udiv(x26, x16, x21); |
| __ Sdiv(x27, x16, x21); |
| __ Udiv(x28, x18, x21); |
| __ Sdiv(x29, x18, x21); |
| |
| __ Mov(x17, 0); |
| __ Udiv(w18, w16, w17); |
| __ Sdiv(w19, w16, w17); |
| __ Udiv(x20, x16, x17); |
| __ Sdiv(x21, x16, x17); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(1, x0); |
| CHECK_EQUAL_64(0xffffffff, x1); |
| CHECK_EQUAL_64(1, x2); |
| CHECK_EQUAL_64(0xffffffff, x3); |
| CHECK_EQUAL_64(1, x4); |
| CHECK_EQUAL_64(1, x5); |
| CHECK_EQUAL_64(0, x6); |
| CHECK_EQUAL_64(1, x7); |
| CHECK_EQUAL_64(0, x8); |
| CHECK_EQUAL_64(0xffffffff00000001UL, x9); |
| CHECK_EQUAL_64(0x40000000, x10); |
| CHECK_EQUAL_64(0xC0000000, x11); |
| CHECK_EQUAL_64(0x40000000, x12); |
| CHECK_EQUAL_64(0x40000000, x13); |
| CHECK_EQUAL_64(0x4000000000000000UL, x14); |
| CHECK_EQUAL_64(0xC000000000000000UL, x15); |
| CHECK_EQUAL_64(0, x22); |
| CHECK_EQUAL_64(0x80000000, x23); |
| CHECK_EQUAL_64(0, x24); |
| CHECK_EQUAL_64(0x8000000000000000UL, x25); |
| CHECK_EQUAL_64(0, x26); |
| CHECK_EQUAL_64(0, x27); |
| CHECK_EQUAL_64(0x7fffffffffffffffUL, x28); |
| CHECK_EQUAL_64(0, x29); |
| CHECK_EQUAL_64(0, x18); |
| CHECK_EQUAL_64(0, x19); |
| CHECK_EQUAL_64(0, x20); |
| CHECK_EQUAL_64(0, x21); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(rbit_rev) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x24, 0xfedcba9876543210UL); |
| __ Rbit(w0, w24); |
| __ Rbit(x1, x24); |
| __ Rev16(w2, w24); |
| __ Rev16(x3, x24); |
| __ Rev(w4, w24); |
| __ Rev32(x5, x24); |
| __ Rev(x6, x24); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x084c2a6e, x0); |
| CHECK_EQUAL_64(0x084c2a6e195d3b7fUL, x1); |
| CHECK_EQUAL_64(0x54761032, x2); |
| CHECK_EQUAL_64(0xdcfe98ba54761032UL, x3); |
| CHECK_EQUAL_64(0x10325476, x4); |
| CHECK_EQUAL_64(0x98badcfe10325476UL, x5); |
| CHECK_EQUAL_64(0x1032547698badcfeUL, x6); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(clz_cls) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x24, 0x0008000000800000UL); |
| __ Mov(x25, 0xff800000fff80000UL); |
| __ Mov(x26, 0); |
| __ Clz(w0, w24); |
| __ Clz(x1, x24); |
| __ Clz(w2, w25); |
| __ Clz(x3, x25); |
| __ Clz(w4, w26); |
| __ Clz(x5, x26); |
| __ Cls(w6, w24); |
| __ Cls(x7, x24); |
| __ Cls(w8, w25); |
| __ Cls(x9, x25); |
| __ Cls(w10, w26); |
| __ Cls(x11, x26); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(8, x0); |
| CHECK_EQUAL_64(12, x1); |
| CHECK_EQUAL_64(0, x2); |
| CHECK_EQUAL_64(0, x3); |
| CHECK_EQUAL_64(32, x4); |
| CHECK_EQUAL_64(64, x5); |
| CHECK_EQUAL_64(7, x6); |
| CHECK_EQUAL_64(11, x7); |
| CHECK_EQUAL_64(12, x8); |
| CHECK_EQUAL_64(8, x9); |
| CHECK_EQUAL_64(31, x10); |
| CHECK_EQUAL_64(63, x11); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(label) { |
| INIT_V8(); |
| SETUP(); |
| |
| Label label_1, label_2, label_3, label_4; |
| |
| START(); |
| __ Mov(x0, 0x1); |
| __ Mov(x1, 0x0); |
| __ Mov(x22, lr); // Save lr. |
| |
| __ B(&label_1); |
| __ B(&label_1); |
| __ B(&label_1); // Multiple branches to the same label. |
| __ Mov(x0, 0x0); |
| __ Bind(&label_2); |
| __ B(&label_3); // Forward branch. |
| __ Mov(x0, 0x0); |
| __ Bind(&label_1); |
| __ B(&label_2); // Backward branch. |
| __ Mov(x0, 0x0); |
| __ Bind(&label_3); |
| __ Bl(&label_4); |
| END(); |
| |
| __ Bind(&label_4); |
| __ Mov(x1, 0x1); |
| __ Mov(lr, x22); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x1, x0); |
| CHECK_EQUAL_64(0x1, x1); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(branch_at_start) { |
| INIT_V8(); |
| SETUP(); |
| |
| Label good, exit; |
| |
| // Test that branches can exist at the start of the buffer. (This is a |
| // boundary condition in the label-handling code.) To achieve this, we have |
| // to work around the code generated by START. |
| RESET(); |
| __ B(&good); |
| |
| START_AFTER_RESET(); |
| __ Mov(x0, 0x0); |
| END(); |
| |
| __ Bind(&exit); |
| START_AFTER_RESET(); |
| __ Mov(x0, 0x1); |
| END(); |
| |
| __ Bind(&good); |
| __ B(&exit); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x1, x0); |
| TEARDOWN(); |
| } |
| |
| |
| TEST(adr) { |
| INIT_V8(); |
| SETUP(); |
| |
| Label label_1, label_2, label_3, label_4; |
| |
| START(); |
| __ Mov(x0, 0x0); // Set to non-zero to indicate failure. |
| __ Adr(x1, &label_3); // Set to zero to indicate success. |
| |
| __ Adr(x2, &label_1); // Multiple forward references to the same label. |
| __ Adr(x3, &label_1); |
| __ Adr(x4, &label_1); |
| |
| __ Bind(&label_2); |
| __ Eor(x5, x2, Operand(x3)); // Ensure that x2,x3 and x4 are identical. |
| __ Eor(x6, x2, Operand(x4)); |
| __ Orr(x0, x0, Operand(x5)); |
| __ Orr(x0, x0, Operand(x6)); |
| __ Br(x2); // label_1, label_3 |
| |
| __ Bind(&label_3); |
| __ Adr(x2, &label_3); // Self-reference (offset 0). |
| __ Eor(x1, x1, Operand(x2)); |
| __ Adr(x2, &label_4); // Simple forward reference. |
| __ Br(x2); // label_4 |
| |
| __ Bind(&label_1); |
| __ Adr(x2, &label_3); // Multiple reverse references to the same label. |
| __ Adr(x3, &label_3); |
| __ Adr(x4, &label_3); |
| __ Adr(x5, &label_2); // Simple reverse reference. |
| __ Br(x5); // label_2 |
| |
| __ Bind(&label_4); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x0, x0); |
| CHECK_EQUAL_64(0x0, x1); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(adr_far) { |
| INIT_V8(); |
| |
| int max_range = 1 << (Instruction::ImmPCRelRangeBitwidth - 1); |
| SETUP_SIZE(max_range + 1000 * kInstructionSize); |
| |
| Label done, fail; |
| Label test_near, near_forward, near_backward; |
| Label test_far, far_forward, far_backward; |
| |
| START(); |
| __ Mov(x0, 0x0); |
| |
| __ Bind(&test_near); |
| __ Adr(x10, &near_forward, MacroAssembler::kAdrFar); |
| __ Br(x10); |
| __ B(&fail); |
| __ Bind(&near_backward); |
| __ Orr(x0, x0, 1 << 1); |
| __ B(&test_far); |
| |
| __ Bind(&near_forward); |
| __ Orr(x0, x0, 1 << 0); |
| __ Adr(x10, &near_backward, MacroAssembler::kAdrFar); |
| __ Br(x10); |
| |
| __ Bind(&test_far); |
| __ Adr(x10, &far_forward, MacroAssembler::kAdrFar); |
| __ Br(x10); |
| __ B(&fail); |
| __ Bind(&far_backward); |
| __ Orr(x0, x0, 1 << 3); |
| __ B(&done); |
| |
| for (unsigned i = 0; i < max_range / kInstructionSize + 1; ++i) { |
| if (i % 100 == 0) { |
| // If we do land in this code, we do not want to execute so many nops |
| // before reaching the end of test (especially if tracing is activated). |
| __ b(&fail); |
| } else { |
| __ nop(); |
| } |
| } |
| |
| |
| __ Bind(&far_forward); |
| __ Orr(x0, x0, 1 << 2); |
| __ Adr(x10, &far_backward, MacroAssembler::kAdrFar); |
| __ Br(x10); |
| |
| __ B(&done); |
| __ Bind(&fail); |
| __ Orr(x0, x0, 1 << 4); |
| __ Bind(&done); |
| |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0xf, x0); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(branch_cond) { |
| INIT_V8(); |
| SETUP(); |
| |
| Label wrong; |
| |
| START(); |
| __ Mov(x0, 0x1); |
| __ Mov(x1, 0x1); |
| __ Mov(x2, 0x8000000000000000L); |
| |
| // For each 'cmp' instruction below, condition codes other than the ones |
| // following it would branch. |
| |
| __ Cmp(x1, 0); |
| __ B(&wrong, eq); |
| __ B(&wrong, lo); |
| __ B(&wrong, mi); |
| __ B(&wrong, vs); |
| __ B(&wrong, ls); |
| __ B(&wrong, lt); |
| __ B(&wrong, le); |
| Label ok_1; |
| __ B(&ok_1, ne); |
| __ Mov(x0, 0x0); |
| __ Bind(&ok_1); |
| |
| __ Cmp(x1, 1); |
| __ B(&wrong, ne); |
| __ B(&wrong, lo); |
| __ B(&wrong, mi); |
| __ B(&wrong, vs); |
| __ B(&wrong, hi); |
| __ B(&wrong, lt); |
| __ B(&wrong, gt); |
| Label ok_2; |
| __ B(&ok_2, pl); |
| __ Mov(x0, 0x0); |
| __ Bind(&ok_2); |
| |
| __ Cmp(x1, 2); |
| __ B(&wrong, eq); |
| __ B(&wrong, hs); |
| __ B(&wrong, pl); |
| __ B(&wrong, vs); |
| __ B(&wrong, hi); |
| __ B(&wrong, ge); |
| __ B(&wrong, gt); |
| Label ok_3; |
| __ B(&ok_3, vc); |
| __ Mov(x0, 0x0); |
| __ Bind(&ok_3); |
| |
| __ Cmp(x2, 1); |
| __ B(&wrong, eq); |
| __ B(&wrong, lo); |
| __ B(&wrong, mi); |
| __ B(&wrong, vc); |
| __ B(&wrong, ls); |
| __ B(&wrong, ge); |
| __ B(&wrong, gt); |
| Label ok_4; |
| __ B(&ok_4, le); |
| __ Mov(x0, 0x0); |
| __ Bind(&ok_4); |
| |
| Label ok_5; |
| __ b(&ok_5, al); |
| __ Mov(x0, 0x0); |
| __ Bind(&ok_5); |
| |
| Label ok_6; |
| __ b(&ok_6, nv); |
| __ Mov(x0, 0x0); |
| __ Bind(&ok_6); |
| |
| END(); |
| |
| __ Bind(&wrong); |
| __ Mov(x0, 0x0); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x1, x0); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(branch_to_reg) { |
| INIT_V8(); |
| SETUP(); |
| |
| // Test br. |
| Label fn1, after_fn1; |
| |
| START(); |
| __ Mov(x29, lr); |
| |
| __ Mov(x1, 0); |
| __ B(&after_fn1); |
| |
| __ Bind(&fn1); |
| __ Mov(x0, lr); |
| __ Mov(x1, 42); |
| __ Br(x0); |
| |
| __ Bind(&after_fn1); |
| __ Bl(&fn1); |
| |
| // Test blr. |
| Label fn2, after_fn2; |
| |
| __ Mov(x2, 0); |
| __ B(&after_fn2); |
| |
| __ Bind(&fn2); |
| __ Mov(x0, lr); |
| __ Mov(x2, 84); |
| __ Blr(x0); |
| |
| __ Bind(&after_fn2); |
| __ Bl(&fn2); |
| __ Mov(x3, lr); |
| |
| __ Mov(lr, x29); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(core.xreg(3) + kInstructionSize, x0); |
| CHECK_EQUAL_64(42, x1); |
| CHECK_EQUAL_64(84, x2); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(compare_branch) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0); |
| __ Mov(x1, 0); |
| __ Mov(x2, 0); |
| __ Mov(x3, 0); |
| __ Mov(x4, 0); |
| __ Mov(x5, 0); |
| __ Mov(x16, 0); |
| __ Mov(x17, 42); |
| |
| Label zt, zt_end; |
| __ Cbz(w16, &zt); |
| __ B(&zt_end); |
| __ Bind(&zt); |
| __ Mov(x0, 1); |
| __ Bind(&zt_end); |
| |
| Label zf, zf_end; |
| __ Cbz(x17, &zf); |
| __ B(&zf_end); |
| __ Bind(&zf); |
| __ Mov(x1, 1); |
| __ Bind(&zf_end); |
| |
| Label nzt, nzt_end; |
| __ Cbnz(w17, &nzt); |
| __ B(&nzt_end); |
| __ Bind(&nzt); |
| __ Mov(x2, 1); |
| __ Bind(&nzt_end); |
| |
| Label nzf, nzf_end; |
| __ Cbnz(x16, &nzf); |
| __ B(&nzf_end); |
| __ Bind(&nzf); |
| __ Mov(x3, 1); |
| __ Bind(&nzf_end); |
| |
| __ Mov(x18, 0xffffffff00000000UL); |
| |
| Label a, a_end; |
| __ Cbz(w18, &a); |
| __ B(&a_end); |
| __ Bind(&a); |
| __ Mov(x4, 1); |
| __ Bind(&a_end); |
| |
| Label b, b_end; |
| __ Cbnz(w18, &b); |
| __ B(&b_end); |
| __ Bind(&b); |
| __ Mov(x5, 1); |
| __ Bind(&b_end); |
| |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(1, x0); |
| CHECK_EQUAL_64(0, x1); |
| CHECK_EQUAL_64(1, x2); |
| CHECK_EQUAL_64(0, x3); |
| CHECK_EQUAL_64(1, x4); |
| CHECK_EQUAL_64(0, x5); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(test_branch) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0); |
| __ Mov(x1, 0); |
| __ Mov(x2, 0); |
| __ Mov(x3, 0); |
| __ Mov(x16, 0xaaaaaaaaaaaaaaaaUL); |
| |
| Label bz, bz_end; |
| __ Tbz(w16, 0, &bz); |
| __ B(&bz_end); |
| __ Bind(&bz); |
| __ Mov(x0, 1); |
| __ Bind(&bz_end); |
| |
| Label bo, bo_end; |
| __ Tbz(x16, 63, &bo); |
| __ B(&bo_end); |
| __ Bind(&bo); |
| __ Mov(x1, 1); |
| __ Bind(&bo_end); |
| |
| Label nbz, nbz_end; |
| __ Tbnz(x16, 61, &nbz); |
| __ B(&nbz_end); |
| __ Bind(&nbz); |
| __ Mov(x2, 1); |
| __ Bind(&nbz_end); |
| |
| Label nbo, nbo_end; |
| __ Tbnz(w16, 2, &nbo); |
| __ B(&nbo_end); |
| __ Bind(&nbo); |
| __ Mov(x3, 1); |
| __ Bind(&nbo_end); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(1, x0); |
| CHECK_EQUAL_64(0, x1); |
| CHECK_EQUAL_64(1, x2); |
| CHECK_EQUAL_64(0, x3); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(far_branch_backward) { |
| INIT_V8(); |
| |
| // Test that the MacroAssembler correctly resolves backward branches to labels |
| // that are outside the immediate range of branch instructions. |
| int max_range = |
| std::max(Instruction::ImmBranchRange(TestBranchType), |
| std::max(Instruction::ImmBranchRange(CompareBranchType), |
| Instruction::ImmBranchRange(CondBranchType))); |
| |
| SETUP_SIZE(max_range + 1000 * kInstructionSize); |
| |
| START(); |
| |
| Label done, fail; |
| Label test_tbz, test_cbz, test_bcond; |
| Label success_tbz, success_cbz, success_bcond; |
| |
| __ Mov(x0, 0); |
| __ Mov(x1, 1); |
| __ Mov(x10, 0); |
| |
| __ B(&test_tbz); |
| __ Bind(&success_tbz); |
| __ Orr(x0, x0, 1 << 0); |
| __ B(&test_cbz); |
| __ Bind(&success_cbz); |
| __ Orr(x0, x0, 1 << 1); |
| __ B(&test_bcond); |
| __ Bind(&success_bcond); |
| __ Orr(x0, x0, 1 << 2); |
| |
| __ B(&done); |
| |
| // Generate enough code to overflow the immediate range of the three types of |
| // branches below. |
| for (unsigned i = 0; i < max_range / kInstructionSize + 1; ++i) { |
| if (i % 100 == 0) { |
| // If we do land in this code, we do not want to execute so many nops |
| // before reaching the end of test (especially if tracing is activated). |
| __ B(&fail); |
| } else { |
| __ Nop(); |
| } |
| } |
| __ B(&fail); |
| |
| __ Bind(&test_tbz); |
| __ Tbz(x10, 7, &success_tbz); |
| __ Bind(&test_cbz); |
| __ Cbz(x10, &success_cbz); |
| __ Bind(&test_bcond); |
| __ Cmp(x10, 0); |
| __ B(eq, &success_bcond); |
| |
| // For each out-of-range branch instructions, at least two instructions should |
| // have been generated. |
| CHECK_GE(7 * kInstructionSize, __ SizeOfCodeGeneratedSince(&test_tbz)); |
| |
| __ Bind(&fail); |
| __ Mov(x1, 0); |
| __ Bind(&done); |
| |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x7, x0); |
| CHECK_EQUAL_64(0x1, x1); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(far_branch_simple_veneer) { |
| INIT_V8(); |
| |
| // Test that the MacroAssembler correctly emits veneers for forward branches |
| // to labels that are outside the immediate range of branch instructions. |
| int max_range = |
| std::max(Instruction::ImmBranchRange(TestBranchType), |
| std::max(Instruction::ImmBranchRange(CompareBranchType), |
| Instruction::ImmBranchRange(CondBranchType))); |
| |
| SETUP_SIZE(max_range + 1000 * kInstructionSize); |
| |
| START(); |
| |
| Label done, fail; |
| Label test_tbz, test_cbz, test_bcond; |
| Label success_tbz, success_cbz, success_bcond; |
| |
| __ Mov(x0, 0); |
| __ Mov(x1, 1); |
| __ Mov(x10, 0); |
| |
| __ Bind(&test_tbz); |
| __ Tbz(x10, 7, &success_tbz); |
| __ Bind(&test_cbz); |
| __ Cbz(x10, &success_cbz); |
| __ Bind(&test_bcond); |
| __ Cmp(x10, 0); |
| __ B(eq, &success_bcond); |
| |
| // Generate enough code to overflow the immediate range of the three types of |
| // branches below. |
| for (unsigned i = 0; i < max_range / kInstructionSize + 1; ++i) { |
| if (i % 100 == 0) { |
| // If we do land in this code, we do not want to execute so many nops |
| // before reaching the end of test (especially if tracing is activated). |
| // Also, the branches give the MacroAssembler the opportunity to emit the |
| // veneers. |
| __ B(&fail); |
| } else { |
| __ Nop(); |
| } |
| } |
| __ B(&fail); |
| |
| __ Bind(&success_tbz); |
| __ Orr(x0, x0, 1 << 0); |
| __ B(&test_cbz); |
| __ Bind(&success_cbz); |
| __ Orr(x0, x0, 1 << 1); |
| __ B(&test_bcond); |
| __ Bind(&success_bcond); |
| __ Orr(x0, x0, 1 << 2); |
| |
| __ B(&done); |
| __ Bind(&fail); |
| __ Mov(x1, 0); |
| __ Bind(&done); |
| |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x7, x0); |
| CHECK_EQUAL_64(0x1, x1); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(far_branch_veneer_link_chain) { |
| INIT_V8(); |
| |
| // Test that the MacroAssembler correctly emits veneers for forward branches |
| // that target out-of-range labels and are part of multiple instructions |
| // jumping to that label. |
| // |
| // We test the three situations with the different types of instruction: |
| // (1)- When the branch is at the start of the chain with tbz. |
| // (2)- When the branch is in the middle of the chain with cbz. |
| // (3)- When the branch is at the end of the chain with bcond. |
| int max_range = |
| std::max(Instruction::ImmBranchRange(TestBranchType), |
| std::max(Instruction::ImmBranchRange(CompareBranchType), |
| Instruction::ImmBranchRange(CondBranchType))); |
| |
| SETUP_SIZE(max_range + 1000 * kInstructionSize); |
| |
| START(); |
| |
| Label skip, fail, done; |
| Label test_tbz, test_cbz, test_bcond; |
| Label success_tbz, success_cbz, success_bcond; |
| |
| __ Mov(x0, 0); |
| __ Mov(x1, 1); |
| __ Mov(x10, 0); |
| |
| __ B(&skip); |
| // Branches at the start of the chain for situations (2) and (3). |
| __ B(&success_cbz); |
| __ B(&success_bcond); |
| __ Nop(); |
| __ B(&success_bcond); |
| __ B(&success_cbz); |
| __ Bind(&skip); |
| |
| __ Bind(&test_tbz); |
| __ Tbz(x10, 7, &success_tbz); |
| __ Bind(&test_cbz); |
| __ Cbz(x10, &success_cbz); |
| __ Bind(&test_bcond); |
| __ Cmp(x10, 0); |
| __ B(eq, &success_bcond); |
| |
| skip.Unuse(); |
| __ B(&skip); |
| // Branches at the end of the chain for situations (1) and (2). |
| __ B(&success_cbz); |
| __ B(&success_tbz); |
| __ Nop(); |
| __ B(&success_tbz); |
| __ B(&success_cbz); |
| __ Bind(&skip); |
| |
| // Generate enough code to overflow the immediate range of the three types of |
| // branches below. |
| for (unsigned i = 0; i < max_range / kInstructionSize + 1; ++i) { |
| if (i % 100 == 0) { |
| // If we do land in this code, we do not want to execute so many nops |
| // before reaching the end of test (especially if tracing is activated). |
| // Also, the branches give the MacroAssembler the opportunity to emit the |
| // veneers. |
| __ B(&fail); |
| } else { |
| __ Nop(); |
| } |
| } |
| __ B(&fail); |
| |
| __ Bind(&success_tbz); |
| __ Orr(x0, x0, 1 << 0); |
| __ B(&test_cbz); |
| __ Bind(&success_cbz); |
| __ Orr(x0, x0, 1 << 1); |
| __ B(&test_bcond); |
| __ Bind(&success_bcond); |
| __ Orr(x0, x0, 1 << 2); |
| |
| __ B(&done); |
| __ Bind(&fail); |
| __ Mov(x1, 0); |
| __ Bind(&done); |
| |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x7, x0); |
| CHECK_EQUAL_64(0x1, x1); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(far_branch_veneer_broken_link_chain) { |
| INIT_V8(); |
| |
| // Check that the MacroAssembler correctly handles the situation when removing |
| // a branch from the link chain of a label and the two links on each side of |
| // the removed branch cannot be linked together (out of range). |
| // |
| // We test with tbz because it has a small range. |
| int max_range = Instruction::ImmBranchRange(TestBranchType); |
| int inter_range = max_range / 2 + max_range / 10; |
| |
| SETUP_SIZE(3 * inter_range + 1000 * kInstructionSize); |
| |
| START(); |
| |
| Label skip, fail, done; |
| Label test_1, test_2, test_3; |
| Label far_target; |
| |
| __ Mov(x0, 0); // Indicates the origin of the branch. |
| __ Mov(x1, 1); |
| __ Mov(x10, 0); |
| |
| // First instruction in the label chain. |
| __ Bind(&test_1); |
| __ Mov(x0, 1); |
| __ B(&far_target); |
| |
| for (unsigned i = 0; i < inter_range / kInstructionSize; ++i) { |
| if (i % 100 == 0) { |
| // Do not allow generating veneers. They should not be needed. |
| __ b(&fail); |
| } else { |
| __ Nop(); |
| } |
| } |
| |
| // Will need a veneer to point to reach the target. |
| __ Bind(&test_2); |
| __ Mov(x0, 2); |
| __ Tbz(x10, 7, &far_target); |
| |
| for (unsigned i = 0; i < inter_range / kInstructionSize; ++i) { |
| if (i % 100 == 0) { |
| // Do not allow generating veneers. They should not be needed. |
| __ b(&fail); |
| } else { |
| __ Nop(); |
| } |
| } |
| |
| // Does not need a veneer to reach the target, but the initial branch |
| // instruction is out of range. |
| __ Bind(&test_3); |
| __ Mov(x0, 3); |
| __ Tbz(x10, 7, &far_target); |
| |
| for (unsigned i = 0; i < inter_range / kInstructionSize; ++i) { |
| if (i % 100 == 0) { |
| // Allow generating veneers. |
| __ B(&fail); |
| } else { |
| __ Nop(); |
| } |
| } |
| |
| __ B(&fail); |
| |
| __ Bind(&far_target); |
| __ Cmp(x0, 1); |
| __ B(eq, &test_2); |
| __ Cmp(x0, 2); |
| __ B(eq, &test_3); |
| |
| __ B(&done); |
| __ Bind(&fail); |
| __ Mov(x1, 0); |
| __ Bind(&done); |
| |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x3, x0); |
| CHECK_EQUAL_64(0x1, x1); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(branch_type) { |
| INIT_V8(); |
| |
| SETUP(); |
| |
| Label fail, done; |
| |
| START(); |
| __ Mov(x0, 0x0); |
| __ Mov(x10, 0x7); |
| __ Mov(x11, 0x0); |
| |
| // Test non taken branches. |
| __ Cmp(x10, 0x7); |
| __ B(&fail, ne); |
| __ B(&fail, never); |
| __ B(&fail, reg_zero, x10); |
| __ B(&fail, reg_not_zero, x11); |
| __ B(&fail, reg_bit_clear, x10, 0); |
| __ B(&fail, reg_bit_set, x10, 3); |
| |
| // Test taken branches. |
| Label l1, l2, l3, l4, l5; |
| __ Cmp(x10, 0x7); |
| __ B(&l1, eq); |
| __ B(&fail); |
| __ Bind(&l1); |
| __ B(&l2, always); |
| __ B(&fail); |
| __ Bind(&l2); |
| __ B(&l3, reg_not_zero, x10); |
| __ B(&fail); |
| __ Bind(&l3); |
| __ B(&l4, reg_bit_clear, x10, 15); |
| __ B(&fail); |
| __ Bind(&l4); |
| __ B(&l5, reg_bit_set, x10, 1); |
| __ B(&fail); |
| __ Bind(&l5); |
| |
| __ B(&done); |
| |
| __ Bind(&fail); |
| __ Mov(x0, 0x1); |
| |
| __ Bind(&done); |
| |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x0, x0); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ldr_str_offset) { |
| INIT_V8(); |
| SETUP(); |
| |
| uint64_t src[2] = {0xfedcba9876543210UL, 0x0123456789abcdefUL}; |
| uint64_t dst[5] = {0, 0, 0, 0, 0}; |
| uintptr_t src_base = reinterpret_cast<uintptr_t>(src); |
| uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst); |
| |
| START(); |
| __ Mov(x17, src_base); |
| __ Mov(x18, dst_base); |
| __ Ldr(w0, MemOperand(x17)); |
| __ Str(w0, MemOperand(x18)); |
| __ Ldr(w1, MemOperand(x17, 4)); |
| __ Str(w1, MemOperand(x18, 12)); |
| __ Ldr(x2, MemOperand(x17, 8)); |
| __ Str(x2, MemOperand(x18, 16)); |
| __ Ldrb(w3, MemOperand(x17, 1)); |
| __ Strb(w3, MemOperand(x18, 25)); |
| __ Ldrh(w4, MemOperand(x17, 2)); |
| __ Strh(w4, MemOperand(x18, 33)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x76543210, x0); |
| CHECK_EQUAL_64(0x76543210, dst[0]); |
| CHECK_EQUAL_64(0xfedcba98, x1); |
| CHECK_EQUAL_64(0xfedcba9800000000UL, dst[1]); |
| CHECK_EQUAL_64(0x0123456789abcdefUL, x2); |
| CHECK_EQUAL_64(0x0123456789abcdefUL, dst[2]); |
| CHECK_EQUAL_64(0x32, x3); |
| CHECK_EQUAL_64(0x3200, dst[3]); |
| CHECK_EQUAL_64(0x7654, x4); |
| CHECK_EQUAL_64(0x765400, dst[4]); |
| CHECK_EQUAL_64(src_base, x17); |
| CHECK_EQUAL_64(dst_base, x18); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ldr_str_wide) { |
| INIT_V8(); |
| SETUP(); |
| |
| uint32_t src[8192]; |
| uint32_t dst[8192]; |
| uintptr_t src_base = reinterpret_cast<uintptr_t>(src); |
| uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst); |
| memset(src, 0xaa, 8192 * sizeof(src[0])); |
| memset(dst, 0xaa, 8192 * sizeof(dst[0])); |
| src[0] = 0; |
| src[6144] = 6144; |
| src[8191] = 8191; |
| |
| START(); |
| __ Mov(x22, src_base); |
| __ Mov(x23, dst_base); |
| __ Mov(x24, src_base); |
| __ Mov(x25, dst_base); |
| __ Mov(x26, src_base); |
| __ Mov(x27, dst_base); |
| |
| __ Ldr(w0, MemOperand(x22, 8191 * sizeof(src[0]))); |
| __ Str(w0, MemOperand(x23, 8191 * sizeof(dst[0]))); |
| __ Ldr(w1, MemOperand(x24, 4096 * sizeof(src[0]), PostIndex)); |
| __ Str(w1, MemOperand(x25, 4096 * sizeof(dst[0]), PostIndex)); |
| __ Ldr(w2, MemOperand(x26, 6144 * sizeof(src[0]), PreIndex)); |
| __ Str(w2, MemOperand(x27, 6144 * sizeof(dst[0]), PreIndex)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_32(8191, w0); |
| CHECK_EQUAL_32(8191, dst[8191]); |
| CHECK_EQUAL_64(src_base, x22); |
| CHECK_EQUAL_64(dst_base, x23); |
| CHECK_EQUAL_32(0, w1); |
| CHECK_EQUAL_32(0, dst[0]); |
| CHECK_EQUAL_64(src_base + 4096 * sizeof(src[0]), x24); |
| CHECK_EQUAL_64(dst_base + 4096 * sizeof(dst[0]), x25); |
| CHECK_EQUAL_32(6144, w2); |
| CHECK_EQUAL_32(6144, dst[6144]); |
| CHECK_EQUAL_64(src_base + 6144 * sizeof(src[0]), x26); |
| CHECK_EQUAL_64(dst_base + 6144 * sizeof(dst[0]), x27); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ldr_str_preindex) { |
| INIT_V8(); |
| SETUP(); |
| |
| uint64_t src[2] = {0xfedcba9876543210UL, 0x0123456789abcdefUL}; |
| uint64_t dst[6] = {0, 0, 0, 0, 0, 0}; |
| uintptr_t src_base = reinterpret_cast<uintptr_t>(src); |
| uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst); |
| |
| START(); |
| __ Mov(x17, src_base); |
| __ Mov(x18, dst_base); |
| __ Mov(x19, src_base); |
| __ Mov(x20, dst_base); |
| __ Mov(x21, src_base + 16); |
| __ Mov(x22, dst_base + 40); |
| __ Mov(x23, src_base); |
| __ Mov(x24, dst_base); |
| __ Mov(x25, src_base); |
| __ Mov(x26, dst_base); |
| __ Ldr(w0, MemOperand(x17, 4, PreIndex)); |
| __ Str(w0, MemOperand(x18, 12, PreIndex)); |
| __ Ldr(x1, MemOperand(x19, 8, PreIndex)); |
| __ Str(x1, MemOperand(x20, 16, PreIndex)); |
| __ Ldr(w2, MemOperand(x21, -4, PreIndex)); |
| __ Str(w2, MemOperand(x22, -4, PreIndex)); |
| __ Ldrb(w3, MemOperand(x23, 1, PreIndex)); |
| __ Strb(w3, MemOperand(x24, 25, PreIndex)); |
| __ Ldrh(w4, MemOperand(x25, 3, PreIndex)); |
| __ Strh(w4, MemOperand(x26, 41, PreIndex)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0xfedcba98, x0); |
| CHECK_EQUAL_64(0xfedcba9800000000UL, dst[1]); |
| CHECK_EQUAL_64(0x0123456789abcdefUL, x1); |
| CHECK_EQUAL_64(0x0123456789abcdefUL, dst[2]); |
| CHECK_EQUAL_64(0x01234567, x2); |
| CHECK_EQUAL_64(0x0123456700000000UL, dst[4]); |
| CHECK_EQUAL_64(0x32, x3); |
| CHECK_EQUAL_64(0x3200, dst[3]); |
| CHECK_EQUAL_64(0x9876, x4); |
| CHECK_EQUAL_64(0x987600, dst[5]); |
| CHECK_EQUAL_64(src_base + 4, x17); |
| CHECK_EQUAL_64(dst_base + 12, x18); |
| CHECK_EQUAL_64(src_base + 8, x19); |
| CHECK_EQUAL_64(dst_base + 16, x20); |
| CHECK_EQUAL_64(src_base + 12, x21); |
| CHECK_EQUAL_64(dst_base + 36, x22); |
| CHECK_EQUAL_64(src_base + 1, x23); |
| CHECK_EQUAL_64(dst_base + 25, x24); |
| CHECK_EQUAL_64(src_base + 3, x25); |
| CHECK_EQUAL_64(dst_base + 41, x26); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ldr_str_postindex) { |
| INIT_V8(); |
| SETUP(); |
| |
| uint64_t src[2] = {0xfedcba9876543210UL, 0x0123456789abcdefUL}; |
| uint64_t dst[6] = {0, 0, 0, 0, 0, 0}; |
| uintptr_t src_base = reinterpret_cast<uintptr_t>(src); |
| uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst); |
| |
| START(); |
| __ Mov(x17, src_base + 4); |
| __ Mov(x18, dst_base + 12); |
| __ Mov(x19, src_base + 8); |
| __ Mov(x20, dst_base + 16); |
| __ Mov(x21, src_base + 8); |
| __ Mov(x22, dst_base + 32); |
| __ Mov(x23, src_base + 1); |
| __ Mov(x24, dst_base + 25); |
| __ Mov(x25, src_base + 3); |
| __ Mov(x26, dst_base + 41); |
| __ Ldr(w0, MemOperand(x17, 4, PostIndex)); |
| __ Str(w0, MemOperand(x18, 12, PostIndex)); |
| __ Ldr(x1, MemOperand(x19, 8, PostIndex)); |
| __ Str(x1, MemOperand(x20, 16, PostIndex)); |
| __ Ldr(x2, MemOperand(x21, -8, PostIndex)); |
| __ Str(x2, MemOperand(x22, -32, PostIndex)); |
| __ Ldrb(w3, MemOperand(x23, 1, PostIndex)); |
| __ Strb(w3, MemOperand(x24, 5, PostIndex)); |
| __ Ldrh(w4, MemOperand(x25, -3, PostIndex)); |
| __ Strh(w4, MemOperand(x26, -41, PostIndex)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0xfedcba98, x0); |
| CHECK_EQUAL_64(0xfedcba9800000000UL, dst[1]); |
| CHECK_EQUAL_64(0x0123456789abcdefUL, x1); |
| CHECK_EQUAL_64(0x0123456789abcdefUL, dst[2]); |
| CHECK_EQUAL_64(0x0123456789abcdefUL, x2); |
| CHECK_EQUAL_64(0x0123456789abcdefUL, dst[4]); |
| CHECK_EQUAL_64(0x32, x3); |
| CHECK_EQUAL_64(0x3200, dst[3]); |
| CHECK_EQUAL_64(0x9876, x4); |
| CHECK_EQUAL_64(0x987600, dst[5]); |
| CHECK_EQUAL_64(src_base + 8, x17); |
| CHECK_EQUAL_64(dst_base + 24, x18); |
| CHECK_EQUAL_64(src_base + 16, x19); |
| CHECK_EQUAL_64(dst_base + 32, x20); |
| CHECK_EQUAL_64(src_base, x21); |
| CHECK_EQUAL_64(dst_base, x22); |
| CHECK_EQUAL_64(src_base + 2, x23); |
| CHECK_EQUAL_64(dst_base + 30, x24); |
| CHECK_EQUAL_64(src_base, x25); |
| CHECK_EQUAL_64(dst_base, x26); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(load_signed) { |
| INIT_V8(); |
| SETUP(); |
| |
| uint32_t src[2] = {0x80008080, 0x7fff7f7f}; |
| uintptr_t src_base = reinterpret_cast<uintptr_t>(src); |
| |
| START(); |
| __ Mov(x24, src_base); |
| __ Ldrsb(w0, MemOperand(x24)); |
| __ Ldrsb(w1, MemOperand(x24, 4)); |
| __ Ldrsh(w2, MemOperand(x24)); |
| __ Ldrsh(w3, MemOperand(x24, 4)); |
| __ Ldrsb(x4, MemOperand(x24)); |
| __ Ldrsb(x5, MemOperand(x24, 4)); |
| __ Ldrsh(x6, MemOperand(x24)); |
| __ Ldrsh(x7, MemOperand(x24, 4)); |
| __ Ldrsw(x8, MemOperand(x24)); |
| __ Ldrsw(x9, MemOperand(x24, 4)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0xffffff80, x0); |
| CHECK_EQUAL_64(0x0000007f, x1); |
| CHECK_EQUAL_64(0xffff8080, x2); |
| CHECK_EQUAL_64(0x00007f7f, x3); |
| CHECK_EQUAL_64(0xffffffffffffff80UL, x4); |
| CHECK_EQUAL_64(0x000000000000007fUL, x5); |
| CHECK_EQUAL_64(0xffffffffffff8080UL, x6); |
| CHECK_EQUAL_64(0x0000000000007f7fUL, x7); |
| CHECK_EQUAL_64(0xffffffff80008080UL, x8); |
| CHECK_EQUAL_64(0x000000007fff7f7fUL, x9); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(load_store_regoffset) { |
| INIT_V8(); |
| SETUP(); |
| |
| uint32_t src[3] = {1, 2, 3}; |
| uint32_t dst[4] = {0, 0, 0, 0}; |
| uintptr_t src_base = reinterpret_cast<uintptr_t>(src); |
| uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst); |
| |
| START(); |
| __ Mov(x16, src_base); |
| __ Mov(x17, dst_base); |
| __ Mov(x18, src_base + 3 * sizeof(src[0])); |
| __ Mov(x19, dst_base + 3 * sizeof(dst[0])); |
| __ Mov(x20, dst_base + 4 * sizeof(dst[0])); |
| __ Mov(x24, 0); |
| __ Mov(x25, 4); |
| __ Mov(x26, -4); |
| __ Mov(x27, 0xfffffffc); // 32-bit -4. |
| __ Mov(x28, 0xfffffffe); // 32-bit -2. |
| __ Mov(x29, 0xffffffff); // 32-bit -1. |
| |
| __ Ldr(w0, MemOperand(x16, x24)); |
| __ Ldr(x1, MemOperand(x16, x25)); |
| __ Ldr(w2, MemOperand(x18, x26)); |
| __ Ldr(w3, MemOperand(x18, x27, SXTW)); |
| __ Ldr(w4, MemOperand(x18, x28, SXTW, 2)); |
| __ Str(w0, MemOperand(x17, x24)); |
| __ Str(x1, MemOperand(x17, x25)); |
| __ Str(w2, MemOperand(x20, x29, SXTW, 2)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(1, x0); |
| CHECK_EQUAL_64(0x0000000300000002UL, x1); |
| CHECK_EQUAL_64(3, x2); |
| CHECK_EQUAL_64(3, x3); |
| CHECK_EQUAL_64(2, x4); |
| CHECK_EQUAL_32(1, dst[0]); |
| CHECK_EQUAL_32(2, dst[1]); |
| CHECK_EQUAL_32(3, dst[2]); |
| CHECK_EQUAL_32(3, dst[3]); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(load_store_float) { |
| INIT_V8(); |
| SETUP(); |
| |
| float src[3] = {1.0, 2.0, 3.0}; |
| float dst[3] = {0.0, 0.0, 0.0}; |
| uintptr_t src_base = reinterpret_cast<uintptr_t>(src); |
| uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst); |
| |
| START(); |
| __ Mov(x17, src_base); |
| __ Mov(x18, dst_base); |
| __ Mov(x19, src_base); |
| __ Mov(x20, dst_base); |
| __ Mov(x21, src_base); |
| __ Mov(x22, dst_base); |
| __ Ldr(s0, MemOperand(x17, sizeof(src[0]))); |
| __ Str(s0, MemOperand(x18, sizeof(dst[0]), PostIndex)); |
| __ Ldr(s1, MemOperand(x19, sizeof(src[0]), PostIndex)); |
| __ Str(s1, MemOperand(x20, 2 * sizeof(dst[0]), PreIndex)); |
| __ Ldr(s2, MemOperand(x21, 2 * sizeof(src[0]), PreIndex)); |
| __ Str(s2, MemOperand(x22, sizeof(dst[0]))); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_FP32(2.0, s0); |
| CHECK_EQUAL_FP32(2.0, dst[0]); |
| CHECK_EQUAL_FP32(1.0, s1); |
| CHECK_EQUAL_FP32(1.0, dst[2]); |
| CHECK_EQUAL_FP32(3.0, s2); |
| CHECK_EQUAL_FP32(3.0, dst[1]); |
| CHECK_EQUAL_64(src_base, x17); |
| CHECK_EQUAL_64(dst_base + sizeof(dst[0]), x18); |
| CHECK_EQUAL_64(src_base + sizeof(src[0]), x19); |
| CHECK_EQUAL_64(dst_base + 2 * sizeof(dst[0]), x20); |
| CHECK_EQUAL_64(src_base + 2 * sizeof(src[0]), x21); |
| CHECK_EQUAL_64(dst_base, x22); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(load_store_double) { |
| INIT_V8(); |
| SETUP(); |
| |
| double src[3] = {1.0, 2.0, 3.0}; |
| double dst[3] = {0.0, 0.0, 0.0}; |
| uintptr_t src_base = reinterpret_cast<uintptr_t>(src); |
| uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst); |
| |
| START(); |
| __ Mov(x17, src_base); |
| __ Mov(x18, dst_base); |
| __ Mov(x19, src_base); |
| __ Mov(x20, dst_base); |
| __ Mov(x21, src_base); |
| __ Mov(x22, dst_base); |
| __ Ldr(d0, MemOperand(x17, sizeof(src[0]))); |
| __ Str(d0, MemOperand(x18, sizeof(dst[0]), PostIndex)); |
| __ Ldr(d1, MemOperand(x19, sizeof(src[0]), PostIndex)); |
| __ Str(d1, MemOperand(x20, 2 * sizeof(dst[0]), PreIndex)); |
| __ Ldr(d2, MemOperand(x21, 2 * sizeof(src[0]), PreIndex)); |
| __ Str(d2, MemOperand(x22, sizeof(dst[0]))); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_FP64(2.0, d0); |
| CHECK_EQUAL_FP64(2.0, dst[0]); |
| CHECK_EQUAL_FP64(1.0, d1); |
| CHECK_EQUAL_FP64(1.0, dst[2]); |
| CHECK_EQUAL_FP64(3.0, d2); |
| CHECK_EQUAL_FP64(3.0, dst[1]); |
| CHECK_EQUAL_64(src_base, x17); |
| CHECK_EQUAL_64(dst_base + sizeof(dst[0]), x18); |
| CHECK_EQUAL_64(src_base + sizeof(src[0]), x19); |
| CHECK_EQUAL_64(dst_base + 2 * sizeof(dst[0]), x20); |
| CHECK_EQUAL_64(src_base + 2 * sizeof(src[0]), x21); |
| CHECK_EQUAL_64(dst_base, x22); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ldp_stp_float) { |
| INIT_V8(); |
| SETUP(); |
| |
| float src[2] = {1.0, 2.0}; |
| float dst[3] = {0.0, 0.0, 0.0}; |
| uintptr_t src_base = reinterpret_cast<uintptr_t>(src); |
| uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst); |
| |
| START(); |
| __ Mov(x16, src_base); |
| __ Mov(x17, dst_base); |
| __ Ldp(s31, s0, MemOperand(x16, 2 * sizeof(src[0]), PostIndex)); |
| __ Stp(s0, s31, MemOperand(x17, sizeof(dst[1]), PreIndex)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_FP32(1.0, s31); |
| CHECK_EQUAL_FP32(2.0, s0); |
| CHECK_EQUAL_FP32(0.0, dst[0]); |
| CHECK_EQUAL_FP32(2.0, dst[1]); |
| CHECK_EQUAL_FP32(1.0, dst[2]); |
| CHECK_EQUAL_64(src_base + 2 * sizeof(src[0]), x16); |
| CHECK_EQUAL_64(dst_base + sizeof(dst[1]), x17); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ldp_stp_double) { |
| INIT_V8(); |
| SETUP(); |
| |
| double src[2] = {1.0, 2.0}; |
| double dst[3] = {0.0, 0.0, 0.0}; |
| uintptr_t src_base = reinterpret_cast<uintptr_t>(src); |
| uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst); |
| |
| START(); |
| __ Mov(x16, src_base); |
| __ Mov(x17, dst_base); |
| __ Ldp(d31, d0, MemOperand(x16, 2 * sizeof(src[0]), PostIndex)); |
| __ Stp(d0, d31, MemOperand(x17, sizeof(dst[1]), PreIndex)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_FP64(1.0, d31); |
| CHECK_EQUAL_FP64(2.0, d0); |
| CHECK_EQUAL_FP64(0.0, dst[0]); |
| CHECK_EQUAL_FP64(2.0, dst[1]); |
| CHECK_EQUAL_FP64(1.0, dst[2]); |
| CHECK_EQUAL_64(src_base + 2 * sizeof(src[0]), x16); |
| CHECK_EQUAL_64(dst_base + sizeof(dst[1]), x17); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ldp_stp_offset) { |
| INIT_V8(); |
| SETUP(); |
| |
| uint64_t src[3] = {0x0011223344556677UL, 0x8899aabbccddeeffUL, |
| 0xffeeddccbbaa9988UL}; |
| uint64_t dst[7] = {0, 0, 0, 0, 0, 0, 0}; |
| uintptr_t src_base = reinterpret_cast<uintptr_t>(src); |
| uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst); |
| |
| START(); |
| __ Mov(x16, src_base); |
| __ Mov(x17, dst_base); |
| __ Mov(x18, src_base + 24); |
| __ Mov(x19, dst_base + 56); |
| __ Ldp(w0, w1, MemOperand(x16)); |
| __ Ldp(w2, w3, MemOperand(x16, 4)); |
| __ Ldp(x4, x5, MemOperand(x16, 8)); |
| __ Ldp(w6, w7, MemOperand(x18, -12)); |
| __ Ldp(x8, x9, MemOperand(x18, -16)); |
| __ Stp(w0, w1, MemOperand(x17)); |
| __ Stp(w2, w3, MemOperand(x17, 8)); |
| __ Stp(x4, x5, MemOperand(x17, 16)); |
| __ Stp(w6, w7, MemOperand(x19, -24)); |
| __ Stp(x8, x9, MemOperand(x19, -16)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x44556677, x0); |
| CHECK_EQUAL_64(0x00112233, x1); |
| CHECK_EQUAL_64(0x0011223344556677UL, dst[0]); |
| CHECK_EQUAL_64(0x00112233, x2); |
| CHECK_EQUAL_64(0xccddeeff, x3); |
| CHECK_EQUAL_64(0xccddeeff00112233UL, dst[1]); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, x4); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, dst[2]); |
| CHECK_EQUAL_64(0xffeeddccbbaa9988UL, x5); |
| CHECK_EQUAL_64(0xffeeddccbbaa9988UL, dst[3]); |
| CHECK_EQUAL_64(0x8899aabb, x6); |
| CHECK_EQUAL_64(0xbbaa9988, x7); |
| CHECK_EQUAL_64(0xbbaa99888899aabbUL, dst[4]); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, x8); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, dst[5]); |
| CHECK_EQUAL_64(0xffeeddccbbaa9988UL, x9); |
| CHECK_EQUAL_64(0xffeeddccbbaa9988UL, dst[6]); |
| CHECK_EQUAL_64(src_base, x16); |
| CHECK_EQUAL_64(dst_base, x17); |
| CHECK_EQUAL_64(src_base + 24, x18); |
| CHECK_EQUAL_64(dst_base + 56, x19); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ldp_stp_offset_wide) { |
| INIT_V8(); |
| SETUP(); |
| |
| uint64_t src[3] = {0x0011223344556677, 0x8899aabbccddeeff, |
| 0xffeeddccbbaa9988}; |
| uint64_t dst[7] = {0, 0, 0, 0, 0, 0, 0}; |
| uintptr_t src_base = reinterpret_cast<uintptr_t>(src); |
| uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst); |
| // Move base too far from the array to force multiple instructions |
| // to be emitted. |
| const int64_t base_offset = 1024; |
| |
| START(); |
| __ Mov(x20, src_base - base_offset); |
| __ Mov(x21, dst_base - base_offset); |
| __ Mov(x18, src_base + base_offset + 24); |
| __ Mov(x19, dst_base + base_offset + 56); |
| __ Ldp(w0, w1, MemOperand(x20, base_offset)); |
| __ Ldp(w2, w3, MemOperand(x20, base_offset + 4)); |
| __ Ldp(x4, x5, MemOperand(x20, base_offset + 8)); |
| __ Ldp(w6, w7, MemOperand(x18, -12 - base_offset)); |
| __ Ldp(x8, x9, MemOperand(x18, -16 - base_offset)); |
| __ Stp(w0, w1, MemOperand(x21, base_offset)); |
| __ Stp(w2, w3, MemOperand(x21, base_offset + 8)); |
| __ Stp(x4, x5, MemOperand(x21, base_offset + 16)); |
| __ Stp(w6, w7, MemOperand(x19, -24 - base_offset)); |
| __ Stp(x8, x9, MemOperand(x19, -16 - base_offset)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x44556677, x0); |
| CHECK_EQUAL_64(0x00112233, x1); |
| CHECK_EQUAL_64(0x0011223344556677UL, dst[0]); |
| CHECK_EQUAL_64(0x00112233, x2); |
| CHECK_EQUAL_64(0xccddeeff, x3); |
| CHECK_EQUAL_64(0xccddeeff00112233UL, dst[1]); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, x4); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, dst[2]); |
| CHECK_EQUAL_64(0xffeeddccbbaa9988UL, x5); |
| CHECK_EQUAL_64(0xffeeddccbbaa9988UL, dst[3]); |
| CHECK_EQUAL_64(0x8899aabb, x6); |
| CHECK_EQUAL_64(0xbbaa9988, x7); |
| CHECK_EQUAL_64(0xbbaa99888899aabbUL, dst[4]); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, x8); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, dst[5]); |
| CHECK_EQUAL_64(0xffeeddccbbaa9988UL, x9); |
| CHECK_EQUAL_64(0xffeeddccbbaa9988UL, dst[6]); |
| CHECK_EQUAL_64(src_base - base_offset, x20); |
| CHECK_EQUAL_64(dst_base - base_offset, x21); |
| CHECK_EQUAL_64(src_base + base_offset + 24, x18); |
| CHECK_EQUAL_64(dst_base + base_offset + 56, x19); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ldnp_stnp_offset) { |
| INIT_V8(); |
| SETUP(); |
| |
| uint64_t src[3] = {0x0011223344556677UL, 0x8899aabbccddeeffUL, |
| 0xffeeddccbbaa9988UL}; |
| uint64_t dst[7] = {0, 0, 0, 0, 0, 0, 0}; |
| uintptr_t src_base = reinterpret_cast<uintptr_t>(src); |
| uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst); |
| |
| START(); |
| __ Mov(x16, src_base); |
| __ Mov(x17, dst_base); |
| __ Mov(x18, src_base + 24); |
| __ Mov(x19, dst_base + 56); |
| __ Ldnp(w0, w1, MemOperand(x16)); |
| __ Ldnp(w2, w3, MemOperand(x16, 4)); |
| __ Ldnp(x4, x5, MemOperand(x16, 8)); |
| __ Ldnp(w6, w7, MemOperand(x18, -12)); |
| __ Ldnp(x8, x9, MemOperand(x18, -16)); |
| __ Stnp(w0, w1, MemOperand(x17)); |
| __ Stnp(w2, w3, MemOperand(x17, 8)); |
| __ Stnp(x4, x5, MemOperand(x17, 16)); |
| __ Stnp(w6, w7, MemOperand(x19, -24)); |
| __ Stnp(x8, x9, MemOperand(x19, -16)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x44556677, x0); |
| CHECK_EQUAL_64(0x00112233, x1); |
| CHECK_EQUAL_64(0x0011223344556677UL, dst[0]); |
| CHECK_EQUAL_64(0x00112233, x2); |
| CHECK_EQUAL_64(0xccddeeff, x3); |
| CHECK_EQUAL_64(0xccddeeff00112233UL, dst[1]); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, x4); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, dst[2]); |
| CHECK_EQUAL_64(0xffeeddccbbaa9988UL, x5); |
| CHECK_EQUAL_64(0xffeeddccbbaa9988UL, dst[3]); |
| CHECK_EQUAL_64(0x8899aabb, x6); |
| CHECK_EQUAL_64(0xbbaa9988, x7); |
| CHECK_EQUAL_64(0xbbaa99888899aabbUL, dst[4]); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, x8); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, dst[5]); |
| CHECK_EQUAL_64(0xffeeddccbbaa9988UL, x9); |
| CHECK_EQUAL_64(0xffeeddccbbaa9988UL, dst[6]); |
| CHECK_EQUAL_64(src_base, x16); |
| CHECK_EQUAL_64(dst_base, x17); |
| CHECK_EQUAL_64(src_base + 24, x18); |
| CHECK_EQUAL_64(dst_base + 56, x19); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ldp_stp_preindex) { |
| INIT_V8(); |
| SETUP(); |
| |
| uint64_t src[3] = {0x0011223344556677UL, 0x8899aabbccddeeffUL, |
| 0xffeeddccbbaa9988UL}; |
| uint64_t dst[5] = {0, 0, 0, 0, 0}; |
| uintptr_t src_base = reinterpret_cast<uintptr_t>(src); |
| uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst); |
| |
| START(); |
| __ Mov(x16, src_base); |
| __ Mov(x17, dst_base); |
| __ Mov(x18, dst_base + 16); |
| __ Ldp(w0, w1, MemOperand(x16, 4, PreIndex)); |
| __ Mov(x19, x16); |
| __ Ldp(w2, w3, MemOperand(x16, -4, PreIndex)); |
| __ Stp(w2, w3, MemOperand(x17, 4, PreIndex)); |
| __ Mov(x20, x17); |
| __ Stp(w0, w1, MemOperand(x17, -4, PreIndex)); |
| __ Ldp(x4, x5, MemOperand(x16, 8, PreIndex)); |
| __ Mov(x21, x16); |
| __ Ldp(x6, x7, MemOperand(x16, -8, PreIndex)); |
| __ Stp(x7, x6, MemOperand(x18, 8, PreIndex)); |
| __ Mov(x22, x18); |
| __ Stp(x5, x4, MemOperand(x18, -8, PreIndex)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x00112233, x0); |
| CHECK_EQUAL_64(0xccddeeff, x1); |
| CHECK_EQUAL_64(0x44556677, x2); |
| CHECK_EQUAL_64(0x00112233, x3); |
| CHECK_EQUAL_64(0xccddeeff00112233UL, dst[0]); |
| CHECK_EQUAL_64(0x0000000000112233UL, dst[1]); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, x4); |
| CHECK_EQUAL_64(0xffeeddccbbaa9988UL, x5); |
| CHECK_EQUAL_64(0x0011223344556677UL, x6); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, x7); |
| CHECK_EQUAL_64(0xffeeddccbbaa9988UL, dst[2]); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, dst[3]); |
| CHECK_EQUAL_64(0x0011223344556677UL, dst[4]); |
| CHECK_EQUAL_64(src_base, x16); |
| CHECK_EQUAL_64(dst_base, x17); |
| CHECK_EQUAL_64(dst_base + 16, x18); |
| CHECK_EQUAL_64(src_base + 4, x19); |
| CHECK_EQUAL_64(dst_base + 4, x20); |
| CHECK_EQUAL_64(src_base + 8, x21); |
| CHECK_EQUAL_64(dst_base + 24, x22); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ldp_stp_preindex_wide) { |
| INIT_V8(); |
| SETUP(); |
| |
| uint64_t src[3] = {0x0011223344556677, 0x8899aabbccddeeff, |
| 0xffeeddccbbaa9988}; |
| uint64_t dst[5] = {0, 0, 0, 0, 0}; |
| uintptr_t src_base = reinterpret_cast<uintptr_t>(src); |
| uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst); |
| // Move base too far from the array to force multiple instructions |
| // to be emitted. |
| const int64_t base_offset = 1024; |
| |
| START(); |
| __ Mov(x24, src_base - base_offset); |
| __ Mov(x25, dst_base + base_offset); |
| __ Mov(x18, dst_base + base_offset + 16); |
| __ Ldp(w0, w1, MemOperand(x24, base_offset + 4, PreIndex)); |
| __ Mov(x19, x24); |
| __ Mov(x24, src_base - base_offset + 4); |
| __ Ldp(w2, w3, MemOperand(x24, base_offset - 4, PreIndex)); |
| __ Stp(w2, w3, MemOperand(x25, 4 - base_offset, PreIndex)); |
| __ Mov(x20, x25); |
| __ Mov(x25, dst_base + base_offset + 4); |
| __ Mov(x24, src_base - base_offset); |
| __ Stp(w0, w1, MemOperand(x25, -4 - base_offset, PreIndex)); |
| __ Ldp(x4, x5, MemOperand(x24, base_offset + 8, PreIndex)); |
| __ Mov(x21, x24); |
| __ Mov(x24, src_base - base_offset + 8); |
| __ Ldp(x6, x7, MemOperand(x24, base_offset - 8, PreIndex)); |
| __ Stp(x7, x6, MemOperand(x18, 8 - base_offset, PreIndex)); |
| __ Mov(x22, x18); |
| __ Mov(x18, dst_base + base_offset + 16 + 8); |
| __ Stp(x5, x4, MemOperand(x18, -8 - base_offset, PreIndex)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x00112233, x0); |
| CHECK_EQUAL_64(0xccddeeff, x1); |
| CHECK_EQUAL_64(0x44556677, x2); |
| CHECK_EQUAL_64(0x00112233, x3); |
| CHECK_EQUAL_64(0xccddeeff00112233UL, dst[0]); |
| CHECK_EQUAL_64(0x0000000000112233UL, dst[1]); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, x4); |
| CHECK_EQUAL_64(0xffeeddccbbaa9988UL, x5); |
| CHECK_EQUAL_64(0x0011223344556677UL, x6); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, x7); |
| CHECK_EQUAL_64(0xffeeddccbbaa9988UL, dst[2]); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, dst[3]); |
| CHECK_EQUAL_64(0x0011223344556677UL, dst[4]); |
| CHECK_EQUAL_64(src_base, x24); |
| CHECK_EQUAL_64(dst_base, x25); |
| CHECK_EQUAL_64(dst_base + 16, x18); |
| CHECK_EQUAL_64(src_base + 4, x19); |
| CHECK_EQUAL_64(dst_base + 4, x20); |
| CHECK_EQUAL_64(src_base + 8, x21); |
| CHECK_EQUAL_64(dst_base + 24, x22); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ldp_stp_postindex) { |
| INIT_V8(); |
| SETUP(); |
| |
| uint64_t src[4] = {0x0011223344556677UL, 0x8899aabbccddeeffUL, |
| 0xffeeddccbbaa9988UL, 0x7766554433221100UL}; |
| uint64_t dst[5] = {0, 0, 0, 0, 0}; |
| uintptr_t src_base = reinterpret_cast<uintptr_t>(src); |
| uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst); |
| |
| START(); |
| __ Mov(x16, src_base); |
| __ Mov(x17, dst_base); |
| __ Mov(x18, dst_base + 16); |
| __ Ldp(w0, w1, MemOperand(x16, 4, PostIndex)); |
| __ Mov(x19, x16); |
| __ Ldp(w2, w3, MemOperand(x16, -4, PostIndex)); |
| __ Stp(w2, w3, MemOperand(x17, 4, PostIndex)); |
| __ Mov(x20, x17); |
| __ Stp(w0, w1, MemOperand(x17, -4, PostIndex)); |
| __ Ldp(x4, x5, MemOperand(x16, 8, PostIndex)); |
| __ Mov(x21, x16); |
| __ Ldp(x6, x7, MemOperand(x16, -8, PostIndex)); |
| __ Stp(x7, x6, MemOperand(x18, 8, PostIndex)); |
| __ Mov(x22, x18); |
| __ Stp(x5, x4, MemOperand(x18, -8, PostIndex)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x44556677, x0); |
| CHECK_EQUAL_64(0x00112233, x1); |
| CHECK_EQUAL_64(0x00112233, x2); |
| CHECK_EQUAL_64(0xccddeeff, x3); |
| CHECK_EQUAL_64(0x4455667700112233UL, dst[0]); |
| CHECK_EQUAL_64(0x0000000000112233UL, dst[1]); |
| CHECK_EQUAL_64(0x0011223344556677UL, x4); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, x5); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, x6); |
| CHECK_EQUAL_64(0xffeeddccbbaa9988UL, x7); |
| CHECK_EQUAL_64(0xffeeddccbbaa9988UL, dst[2]); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, dst[3]); |
| CHECK_EQUAL_64(0x0011223344556677UL, dst[4]); |
| CHECK_EQUAL_64(src_base, x16); |
| CHECK_EQUAL_64(dst_base, x17); |
| CHECK_EQUAL_64(dst_base + 16, x18); |
| CHECK_EQUAL_64(src_base + 4, x19); |
| CHECK_EQUAL_64(dst_base + 4, x20); |
| CHECK_EQUAL_64(src_base + 8, x21); |
| CHECK_EQUAL_64(dst_base + 24, x22); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ldp_stp_postindex_wide) { |
| INIT_V8(); |
| SETUP(); |
| |
| uint64_t src[4] = {0x0011223344556677, 0x8899aabbccddeeff, 0xffeeddccbbaa9988, |
| 0x7766554433221100}; |
| uint64_t dst[5] = {0, 0, 0, 0, 0}; |
| uintptr_t src_base = reinterpret_cast<uintptr_t>(src); |
| uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst); |
| // Move base too far from the array to force multiple instructions |
| // to be emitted. |
| const int64_t base_offset = 1024; |
| |
| START(); |
| __ Mov(x24, src_base); |
| __ Mov(x25, dst_base); |
| __ Mov(x18, dst_base + 16); |
| __ Ldp(w0, w1, MemOperand(x24, base_offset + 4, PostIndex)); |
| __ Mov(x19, x24); |
| __ Sub(x24, x24, base_offset); |
| __ Ldp(w2, w3, MemOperand(x24, base_offset - 4, PostIndex)); |
| __ Stp(w2, w3, MemOperand(x25, 4 - base_offset, PostIndex)); |
| __ Mov(x20, x25); |
| __ Sub(x24, x24, base_offset); |
| __ Add(x25, x25, base_offset); |
| __ Stp(w0, w1, MemOperand(x25, -4 - base_offset, PostIndex)); |
| __ Ldp(x4, x5, MemOperand(x24, base_offset + 8, PostIndex)); |
| __ Mov(x21, x24); |
| __ Sub(x24, x24, base_offset); |
| __ Ldp(x6, x7, MemOperand(x24, base_offset - 8, PostIndex)); |
| __ Stp(x7, x6, MemOperand(x18, 8 - base_offset, PostIndex)); |
| __ Mov(x22, x18); |
| __ Add(x18, x18, base_offset); |
| __ Stp(x5, x4, MemOperand(x18, -8 - base_offset, PostIndex)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x44556677, x0); |
| CHECK_EQUAL_64(0x00112233, x1); |
| CHECK_EQUAL_64(0x00112233, x2); |
| CHECK_EQUAL_64(0xccddeeff, x3); |
| CHECK_EQUAL_64(0x4455667700112233UL, dst[0]); |
| CHECK_EQUAL_64(0x0000000000112233UL, dst[1]); |
| CHECK_EQUAL_64(0x0011223344556677UL, x4); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, x5); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, x6); |
| CHECK_EQUAL_64(0xffeeddccbbaa9988UL, x7); |
| CHECK_EQUAL_64(0xffeeddccbbaa9988UL, dst[2]); |
| CHECK_EQUAL_64(0x8899aabbccddeeffUL, dst[3]); |
| CHECK_EQUAL_64(0x0011223344556677UL, dst[4]); |
| CHECK_EQUAL_64(src_base + base_offset, x24); |
| CHECK_EQUAL_64(dst_base - base_offset, x25); |
| CHECK_EQUAL_64(dst_base - base_offset + 16, x18); |
| CHECK_EQUAL_64(src_base + base_offset + 4, x19); |
| CHECK_EQUAL_64(dst_base - base_offset + 4, x20); |
| CHECK_EQUAL_64(src_base + base_offset + 8, x21); |
| CHECK_EQUAL_64(dst_base - base_offset + 24, x22); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ldp_sign_extend) { |
| INIT_V8(); |
| SETUP(); |
| |
| uint32_t src[2] = {0x80000000, 0x7fffffff}; |
| uintptr_t src_base = reinterpret_cast<uintptr_t>(src); |
| |
| START(); |
| __ Mov(x24, src_base); |
| __ Ldpsw(x0, x1, MemOperand(x24)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0xffffffff80000000UL, x0); |
| CHECK_EQUAL_64(0x000000007fffffffUL, x1); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ldur_stur) { |
| INIT_V8(); |
| SETUP(); |
| |
| int64_t src[2] = {0x0123456789abcdefUL, 0x0123456789abcdefUL}; |
| int64_t dst[5] = {0, 0, 0, 0, 0}; |
| uintptr_t src_base = reinterpret_cast<uintptr_t>(src); |
| uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst); |
| |
| START(); |
| __ Mov(x17, src_base); |
| __ Mov(x18, dst_base); |
| __ Mov(x19, src_base + 16); |
| __ Mov(x20, dst_base + 32); |
| __ Mov(x21, dst_base + 40); |
| __ Ldr(w0, MemOperand(x17, 1)); |
| __ Str(w0, MemOperand(x18, 2)); |
| __ Ldr(x1, MemOperand(x17, 3)); |
| __ Str(x1, MemOperand(x18, 9)); |
| __ Ldr(w2, MemOperand(x19, -9)); |
| __ Str(w2, MemOperand(x20, -5)); |
| __ Ldrb(w3, MemOperand(x19, -1)); |
| __ Strb(w3, MemOperand(x21, -1)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x6789abcd, x0); |
| CHECK_EQUAL_64(0x6789abcd0000L, dst[0]); |
| CHECK_EQUAL_64(0xabcdef0123456789L, x1); |
| CHECK_EQUAL_64(0xcdef012345678900L, dst[1]); |
| CHECK_EQUAL_64(0x000000ab, dst[2]); |
| CHECK_EQUAL_64(0xabcdef01, x2); |
| CHECK_EQUAL_64(0x00abcdef01000000L, dst[3]); |
| CHECK_EQUAL_64(0x00000001, x3); |
| CHECK_EQUAL_64(0x0100000000000000L, dst[4]); |
| CHECK_EQUAL_64(src_base, x17); |
| CHECK_EQUAL_64(dst_base, x18); |
| CHECK_EQUAL_64(src_base + 16, x19); |
| CHECK_EQUAL_64(dst_base + 32, x20); |
| |
| TEARDOWN(); |
| } |
| |
| |
| #if 0 // TODO(all) enable. |
| // TODO(rodolph): Adapt w16 Literal tests for RelocInfo. |
| TEST(ldr_literal) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Ldr(x2, 0x1234567890abcdefUL); |
| __ Ldr(w3, 0xfedcba09); |
| __ Ldr(d13, 1.234); |
| __ Ldr(s25, 2.5); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x1234567890abcdefUL, x2); |
| CHECK_EQUAL_64(0xfedcba09, x3); |
| CHECK_EQUAL_FP64(1.234, d13); |
| CHECK_EQUAL_FP32(2.5, s25); |
| |
| TEARDOWN(); |
| } |
| |
| |
| static void LdrLiteralRangeHelper(ptrdiff_t range_, |
| LiteralPoolEmitOption option, |
| bool expect_dump) { |
| DCHECK(range_ > 0); |
| SETUP_SIZE(range_ + 1024); |
| |
| Label label_1, label_2; |
| |
| size_t range = static_cast<size_t>(range_); |
| size_t code_size = 0; |
| size_t pool_guard_size; |
| |
| if (option == NoJumpRequired) { |
| // Space for an explicit branch. |
| pool_guard_size = sizeof(Instr); |
| } else { |
| pool_guard_size = 0; |
| } |
| |
| START(); |
| // Force a pool dump so the pool starts off empty. |
| __ EmitLiteralPool(JumpRequired); |
| DCHECK_LITERAL_POOL_SIZE(0); |
| |
| __ Ldr(x0, 0x1234567890abcdefUL); |
| __ Ldr(w1, 0xfedcba09); |
| __ Ldr(d0, 1.234); |
| __ Ldr(s1, 2.5); |
| DCHECK_LITERAL_POOL_SIZE(4); |
| |
| code_size += 4 * sizeof(Instr); |
| |
| // Check that the requested range (allowing space for a branch over the pool) |
| // can be handled by this test. |
| DCHECK((code_size + pool_guard_size) <= range); |
| |
| // Emit NOPs up to 'range', leaving space for the pool guard. |
| while ((code_size + pool_guard_size) < range) { |
| __ Nop(); |
| code_size += sizeof(Instr); |
| } |
| |
| // Emit the guard sequence before the literal pool. |
| if (option == NoJumpRequired) { |
| __ B(&label_1); |
| code_size += sizeof(Instr); |
| } |
| |
| DCHECK(code_size == range); |
| DCHECK_LITERAL_POOL_SIZE(4); |
| |
| // Possibly generate a literal pool. |
| __ CheckLiteralPool(option); |
| __ Bind(&label_1); |
| if (expect_dump) { |
| DCHECK_LITERAL_POOL_SIZE(0); |
| } else { |
| DCHECK_LITERAL_POOL_SIZE(4); |
| } |
| |
| // Force a pool flush to check that a second pool functions correctly. |
| __ EmitLiteralPool(JumpRequired); |
| DCHECK_LITERAL_POOL_SIZE(0); |
| |
| // These loads should be after the pool (and will require a new one). |
| __ Ldr(x4, 0x34567890abcdef12UL); |
| __ Ldr(w5, 0xdcba09fe); |
| __ Ldr(d4, 123.4); |
| __ Ldr(s5, 250.0); |
| DCHECK_LITERAL_POOL_SIZE(4); |
| END(); |
| |
| RUN(); |
| |
| // Check that the literals loaded correctly. |
| CHECK_EQUAL_64(0x1234567890abcdefUL, x0); |
| CHECK_EQUAL_64(0xfedcba09, x1); |
| CHECK_EQUAL_FP64(1.234, d0); |
| CHECK_EQUAL_FP32(2.5, s1); |
| CHECK_EQUAL_64(0x34567890abcdef12UL, x4); |
| CHECK_EQUAL_64(0xdcba09fe, x5); |
| CHECK_EQUAL_FP64(123.4, d4); |
| CHECK_EQUAL_FP32(250.0, s5); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ldr_literal_range_1) { |
| INIT_V8(); |
| LdrLiteralRangeHelper(kRecommendedLiteralPoolRange, |
| NoJumpRequired, |
| true); |
| } |
| |
| |
| TEST(ldr_literal_range_2) { |
| INIT_V8(); |
| LdrLiteralRangeHelper(kRecommendedLiteralPoolRange-sizeof(Instr), |
| NoJumpRequired, |
| false); |
| } |
| |
| |
| TEST(ldr_literal_range_3) { |
| INIT_V8(); |
| LdrLiteralRangeHelper(2 * kRecommendedLiteralPoolRange, |
| JumpRequired, |
| true); |
| } |
| |
| |
| TEST(ldr_literal_range_4) { |
| INIT_V8(); |
| LdrLiteralRangeHelper(2 * kRecommendedLiteralPoolRange-sizeof(Instr), |
| JumpRequired, |
| false); |
| } |
| |
| |
| TEST(ldr_literal_range_5) { |
| INIT_V8(); |
| LdrLiteralRangeHelper(kLiteralPoolCheckInterval, |
| JumpRequired, |
| false); |
| } |
| |
| |
| TEST(ldr_literal_range_6) { |
| INIT_V8(); |
| LdrLiteralRangeHelper(kLiteralPoolCheckInterval-sizeof(Instr), |
| JumpRequired, |
| false); |
| } |
| #endif |
| |
| TEST(add_sub_imm) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0x0); |
| __ Mov(x1, 0x1111); |
| __ Mov(x2, 0xffffffffffffffffL); |
| __ Mov(x3, 0x8000000000000000L); |
| |
| __ Add(x10, x0, Operand(0x123)); |
| __ Add(x11, x1, Operand(0x122000)); |
| __ Add(x12, x0, Operand(0xabc << 12)); |
| __ Add(x13, x2, Operand(1)); |
| |
| __ Add(w14, w0, Operand(0x123)); |
| __ Add(w15, w1, Operand(0x122000)); |
| __ Add(w16, w0, Operand(0xabc << 12)); |
| __ Add(w17, w2, Operand(1)); |
| |
| __ Sub(x20, x0, Operand(0x1)); |
| __ Sub(x21, x1, Operand(0x111)); |
| __ Sub(x22, x1, Operand(0x1 << 12)); |
| __ Sub(x23, x3, Operand(1)); |
| |
| __ Sub(w24, w0, Operand(0x1)); |
| __ Sub(w25, w1, Operand(0x111)); |
| __ Sub(w26, w1, Operand(0x1 << 12)); |
| __ Sub(w27, w3, Operand(1)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x123, x10); |
| CHECK_EQUAL_64(0x123111, x11); |
| CHECK_EQUAL_64(0xabc000, x12); |
| CHECK_EQUAL_64(0x0, x13); |
| |
| CHECK_EQUAL_32(0x123, w14); |
| CHECK_EQUAL_32(0x123111, w15); |
| CHECK_EQUAL_32(0xabc000, w16); |
| CHECK_EQUAL_32(0x0, w17); |
| |
| CHECK_EQUAL_64(0xffffffffffffffffL, x20); |
| CHECK_EQUAL_64(0x1000, x21); |
| CHECK_EQUAL_64(0x111, x22); |
| CHECK_EQUAL_64(0x7fffffffffffffffL, x23); |
| |
| CHECK_EQUAL_32(0xffffffff, w24); |
| CHECK_EQUAL_32(0x1000, w25); |
| CHECK_EQUAL_32(0x111, w26); |
| CHECK_EQUAL_32(0xffffffff, w27); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(add_sub_wide_imm) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0x0); |
| __ Mov(x1, 0x1); |
| |
| __ Add(x10, x0, Operand(0x1234567890abcdefUL)); |
| __ Add(x11, x1, Operand(0xffffffff)); |
| |
| __ Add(w12, w0, Operand(0x12345678)); |
| __ Add(w13, w1, Operand(0xffffffff)); |
| |
| __ Add(w18, w0, Operand(kWMinInt)); |
| __ Sub(w19, w0, Operand(kWMinInt)); |
| |
| __ Sub(x20, x0, Operand(0x1234567890abcdefUL)); |
| __ Sub(w21, w0, Operand(0x12345678)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x1234567890abcdefUL, x10); |
| CHECK_EQUAL_64(0x100000000UL, x11); |
| |
| CHECK_EQUAL_32(0x12345678, w12); |
| CHECK_EQUAL_64(0x0, x13); |
| |
| CHECK_EQUAL_32(kWMinInt, w18); |
| CHECK_EQUAL_32(kWMinInt, w19); |
| |
| CHECK_EQUAL_64(-0x1234567890abcdefUL, x20); |
| CHECK_EQUAL_32(-0x12345678, w21); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(add_sub_shifted) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0); |
| __ Mov(x1, 0x0123456789abcdefL); |
| __ Mov(x2, 0xfedcba9876543210L); |
| __ Mov(x3, 0xffffffffffffffffL); |
| |
| __ Add(x10, x1, Operand(x2)); |
| __ Add(x11, x0, Operand(x1, LSL, 8)); |
| __ Add(x12, x0, Operand(x1, LSR, 8)); |
| __ Add(x13, x0, Operand(x1, ASR, 8)); |
| __ Add(x14, x0, Operand(x2, ASR, 8)); |
| __ Add(w15, w0, Operand(w1, ASR, 8)); |
| __ Add(w18, w3, Operand(w1, ROR, 8)); |
| __ Add(x19, x3, Operand(x1, ROR, 8)); |
| |
| __ Sub(x20, x3, Operand(x2)); |
| __ Sub(x21, x3, Operand(x1, LSL, 8)); |
| __ Sub(x22, x3, Operand(x1, LSR, 8)); |
| __ Sub(x23, x3, Operand(x1, ASR, 8)); |
| __ Sub(x24, x3, Operand(x2, ASR, 8)); |
| __ Sub(w25, w3, Operand(w1, ASR, 8)); |
| __ Sub(w26, w3, Operand(w1, ROR, 8)); |
| __ Sub(x27, x3, Operand(x1, ROR, 8)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0xffffffffffffffffL, x10); |
| CHECK_EQUAL_64(0x23456789abcdef00L, x11); |
| CHECK_EQUAL_64(0x000123456789abcdL, x12); |
| CHECK_EQUAL_64(0x000123456789abcdL, x13); |
| CHECK_EQUAL_64(0xfffedcba98765432L, x14); |
| CHECK_EQUAL_64(0xff89abcd, x15); |
| CHECK_EQUAL_64(0xef89abcc, x18); |
| CHECK_EQUAL_64(0xef0123456789abccL, x19); |
| |
| CHECK_EQUAL_64(0x0123456789abcdefL, x20); |
| CHECK_EQUAL_64(0xdcba9876543210ffL, x21); |
| CHECK_EQUAL_64(0xfffedcba98765432L, x22); |
| CHECK_EQUAL_64(0xfffedcba98765432L, x23); |
| CHECK_EQUAL_64(0x000123456789abcdL, x24); |
| CHECK_EQUAL_64(0x00765432, x25); |
| CHECK_EQUAL_64(0x10765432, x26); |
| CHECK_EQUAL_64(0x10fedcba98765432L, x27); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(add_sub_extended) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0); |
| __ Mov(x1, 0x0123456789abcdefL); |
| __ Mov(x2, 0xfedcba9876543210L); |
| __ Mov(w3, 0x80); |
| |
| __ Add(x10, x0, Operand(x1, UXTB, 0)); |
| __ Add(x11, x0, Operand(x1, UXTB, 1)); |
| __ Add(x12, x0, Operand(x1, UXTH, 2)); |
| __ Add(x13, x0, Operand(x1, UXTW, 4)); |
| |
| __ Add(x14, x0, Operand(x1, SXTB, 0)); |
| __ Add(x15, x0, Operand(x1, SXTB, 1)); |
| __ Add(x16, x0, Operand(x1, SXTH, 2)); |
| __ Add(x17, x0, Operand(x1, SXTW, 3)); |
| __ Add(x18, x0, Operand(x2, SXTB, 0)); |
| __ Add(x19, x0, Operand(x2, SXTB, 1)); |
| __ Add(x20, x0, Operand(x2, SXTH, 2)); |
| __ Add(x21, x0, Operand(x2, SXTW, 3)); |
| |
| __ Add(x22, x1, Operand(x2, SXTB, 1)); |
| __ Sub(x23, x1, Operand(x2, SXTB, 1)); |
| |
| __ Add(w24, w1, Operand(w2, UXTB, 2)); |
| __ Add(w25, w0, Operand(w1, SXTB, 0)); |
| __ Add(w26, w0, Operand(w1, SXTB, 1)); |
| __ Add(w27, w2, Operand(w1, SXTW, 3)); |
| |
| __ Add(w28, w0, Operand(w1, SXTW, 3)); |
| __ Add(x29, x0, Operand(w1, SXTW, 3)); |
| |
| __ Sub(x30, x0, Operand(w3, SXTB, 1)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0xefL, x10); |
| CHECK_EQUAL_64(0x1deL, x11); |
| CHECK_EQUAL_64(0x337bcL, x12); |
| CHECK_EQUAL_64(0x89abcdef0L, x13); |
| |
| CHECK_EQUAL_64(0xffffffffffffffefL, x14); |
| CHECK_EQUAL_64(0xffffffffffffffdeL, x15); |
| CHECK_EQUAL_64(0xffffffffffff37bcL, x16); |
| CHECK_EQUAL_64(0xfffffffc4d5e6f78L, x17); |
| CHECK_EQUAL_64(0x10L, x18); |
| CHECK_EQUAL_64(0x20L, x19); |
| CHECK_EQUAL_64(0xc840L, x20); |
| CHECK_EQUAL_64(0x3b2a19080L, x21); |
| |
| CHECK_EQUAL_64(0x0123456789abce0fL, x22); |
| CHECK_EQUAL_64(0x0123456789abcdcfL, x23); |
| |
| CHECK_EQUAL_32(0x89abce2f, w24); |
| CHECK_EQUAL_32(0xffffffef, w25); |
| CHECK_EQUAL_32(0xffffffde, w26); |
| CHECK_EQUAL_32(0xc3b2a188, w27); |
| |
| CHECK_EQUAL_32(0x4d5e6f78, w28); |
| CHECK_EQUAL_64(0xfffffffc4d5e6f78L, x29); |
| |
| CHECK_EQUAL_64(256, x30); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(add_sub_negative) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0); |
| __ Mov(x1, 4687); |
| __ Mov(x2, 0x1122334455667788); |
| __ Mov(w3, 0x11223344); |
| __ Mov(w4, 400000); |
| |
| __ Add(x10, x0, -42); |
| __ Add(x11, x1, -687); |
| __ Add(x12, x2, -0x88); |
| |
| __ Sub(x13, x0, -600); |
| __ Sub(x14, x1, -313); |
| __ Sub(x15, x2, -0x555); |
| |
| __ Add(w19, w3, -0x344); |
| __ Add(w20, w4, -2000); |
| |
| __ Sub(w21, w3, -0xbc); |
| __ Sub(w22, w4, -2000); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(-42, x10); |
| CHECK_EQUAL_64(4000, x11); |
| CHECK_EQUAL_64(0x1122334455667700, x12); |
| |
| CHECK_EQUAL_64(600, x13); |
| CHECK_EQUAL_64(5000, x14); |
| CHECK_EQUAL_64(0x1122334455667cdd, x15); |
| |
| CHECK_EQUAL_32(0x11223000, w19); |
| CHECK_EQUAL_32(398000, w20); |
| |
| CHECK_EQUAL_32(0x11223400, w21); |
| CHECK_EQUAL_32(402000, w22); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(add_sub_zero) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0); |
| __ Mov(x1, 0); |
| __ Mov(x2, 0); |
| |
| Label blob1; |
| __ Bind(&blob1); |
| __ Add(x0, x0, 0); |
| __ Sub(x1, x1, 0); |
| __ Sub(x2, x2, xzr); |
| CHECK_EQ(0, __ SizeOfCodeGeneratedSince(&blob1)); |
| |
| Label blob2; |
| __ Bind(&blob2); |
| __ Add(w3, w3, 0); |
| CHECK_NE(0, __ SizeOfCodeGeneratedSince(&blob2)); |
| |
| Label blob3; |
| __ Bind(&blob3); |
| __ Sub(w3, w3, wzr); |
| CHECK_NE(0, __ SizeOfCodeGeneratedSince(&blob3)); |
| |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0, x0); |
| CHECK_EQUAL_64(0, x1); |
| CHECK_EQUAL_64(0, x2); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(claim_drop_zero) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| |
| Label start; |
| __ Bind(&start); |
| __ Claim(0); |
| __ Drop(0); |
| __ Claim(xzr, 8); |
| __ Drop(xzr, 8); |
| __ Claim(xzr, 0); |
| __ Drop(xzr, 0); |
| __ Claim(x7, 0); |
| __ Drop(x7, 0); |
| __ ClaimBySMI(xzr, 8); |
| __ DropBySMI(xzr, 8); |
| __ ClaimBySMI(xzr, 0); |
| __ DropBySMI(xzr, 0); |
| CHECK_EQ(0, __ SizeOfCodeGeneratedSince(&start)); |
| |
| END(); |
| |
| RUN(); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(neg) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0xf123456789abcdefL); |
| |
| // Immediate. |
| __ Neg(x1, 0x123); |
| __ Neg(w2, 0x123); |
| |
| // Shifted. |
| __ Neg(x3, Operand(x0, LSL, 1)); |
| __ Neg(w4, Operand(w0, LSL, 2)); |
| __ Neg(x5, Operand(x0, LSR, 3)); |
| __ Neg(w6, Operand(w0, LSR, 4)); |
| __ Neg(x7, Operand(x0, ASR, 5)); |
| __ Neg(w8, Operand(w0, ASR, 6)); |
| |
| // Extended. |
| __ Neg(w9, Operand(w0, UXTB)); |
| __ Neg(x10, Operand(x0, SXTB, 1)); |
| __ Neg(w11, Operand(w0, UXTH, 2)); |
| __ Neg(x12, Operand(x0, SXTH, 3)); |
| __ Neg(w13, Operand(w0, UXTW, 4)); |
| __ Neg(x14, Operand(x0, SXTW, 4)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0xfffffffffffffeddUL, x1); |
| CHECK_EQUAL_64(0xfffffedd, x2); |
| CHECK_EQUAL_64(0x1db97530eca86422UL, x3); |
| CHECK_EQUAL_64(0xd950c844, x4); |
| CHECK_EQUAL_64(0xe1db97530eca8643UL, x5); |
| CHECK_EQUAL_64(0xf7654322, x6); |
| CHECK_EQUAL_64(0x0076e5d4c3b2a191UL, x7); |
| CHECK_EQUAL_64(0x01d950c9, x8); |
| CHECK_EQUAL_64(0xffffff11, x9); |
| CHECK_EQUAL_64(0x0000000000000022UL, x10); |
| CHECK_EQUAL_64(0xfffcc844, x11); |
| CHECK_EQUAL_64(0x0000000000019088UL, x12); |
| CHECK_EQUAL_64(0x65432110, x13); |
| CHECK_EQUAL_64(0x0000000765432110UL, x14); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(adc_sbc_shift) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0); |
| __ Mov(x1, 1); |
| __ Mov(x2, 0x0123456789abcdefL); |
| __ Mov(x3, 0xfedcba9876543210L); |
| __ Mov(x4, 0xffffffffffffffffL); |
| |
| // Clear the C flag. |
| __ Adds(x0, x0, Operand(0)); |
| |
| __ Adc(x5, x2, Operand(x3)); |
| __ Adc(x6, x0, Operand(x1, LSL, 60)); |
| __ Sbc(x7, x4, Operand(x3, LSR, 4)); |
| __ Adc(x8, x2, Operand(x3, ASR, 4)); |
| __ Adc(x9, x2, Operand(x3, ROR, 8)); |
| |
| __ Adc(w10, w2, Operand(w3)); |
| __ Adc(w11, w0, Operand(w1, LSL, 30)); |
| __ Sbc(w12, w4, Operand(w3, LSR, 4)); |
| __ Adc(w13, w2, Operand(w3, ASR, 4)); |
| __ Adc(w14, w2, Operand(w3, ROR, 8)); |
| |
| // Set the C flag. |
| __ Cmp(w0, Operand(w0)); |
| |
| __ Adc(x18, x2, Operand(x3)); |
| __ Adc(x19, x0, Operand(x1, LSL, 60)); |
| __ Sbc(x20, x4, Operand(x3, LSR, 4)); |
| __ Adc(x21, x2, Operand(x3, ASR, 4)); |
| __ Adc(x22, x2, Operand(x3, ROR, 8)); |
| |
| __ Adc(w23, w2, Operand(w3)); |
| __ Adc(w24, w0, Operand(w1, LSL, 30)); |
| __ Sbc(w25, w4, Operand(w3, LSR, 4)); |
| __ Adc(w26, w2, Operand(w3, ASR, 4)); |
| __ Adc(w27, w2, Operand(w3, ROR, 8)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0xffffffffffffffffL, x5); |
| CHECK_EQUAL_64(1L << 60, x6); |
| CHECK_EQUAL_64(0xf0123456789abcddL, x7); |
| CHECK_EQUAL_64(0x0111111111111110L, x8); |
| CHECK_EQUAL_64(0x1222222222222221L, x9); |
| |
| CHECK_EQUAL_32(0xffffffff, w10); |
| CHECK_EQUAL_32(1 << 30, w11); |
| CHECK_EQUAL_32(0xf89abcdd, w12); |
| CHECK_EQUAL_32(0x91111110, w13); |
| CHECK_EQUAL_32(0x9a222221, w14); |
| |
| CHECK_EQUAL_64(0xffffffffffffffffL + 1, x18); |
| CHECK_EQUAL_64((1L << 60) + 1, x19); |
| CHECK_EQUAL_64(0xf0123456789abcddL + 1, x20); |
| CHECK_EQUAL_64(0x0111111111111110L + 1, x21); |
| CHECK_EQUAL_64(0x1222222222222221L + 1, x22); |
| |
| CHECK_EQUAL_32(0xffffffff + 1, w23); |
| CHECK_EQUAL_32((1 << 30) + 1, w24); |
| CHECK_EQUAL_32(0xf89abcdd + 1, w25); |
| CHECK_EQUAL_32(0x91111110 + 1, w26); |
| CHECK_EQUAL_32(0x9a222221 + 1, w27); |
| |
| // Check that adc correctly sets the condition flags. |
| START(); |
| __ Mov(x0, 1); |
| __ Mov(x1, 0xffffffffffffffffL); |
| // Clear the C flag. |
| __ Adds(x0, x0, Operand(0)); |
| __ Adcs(x10, x0, Operand(x1)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(ZCFlag); |
| CHECK_EQUAL_64(0, x10); |
| |
| START(); |
| __ Mov(x0, 1); |
| __ Mov(x1, 0x8000000000000000L); |
| // Clear the C flag. |
| __ Adds(x0, x0, Operand(0)); |
| __ Adcs(x10, x0, Operand(x1, ASR, 63)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(ZCFlag); |
| CHECK_EQUAL_64(0, x10); |
| |
| START(); |
| __ Mov(x0, 0x10); |
| __ Mov(x1, 0x07ffffffffffffffL); |
| // Clear the C flag. |
| __ Adds(x0, x0, Operand(0)); |
| __ Adcs(x10, x0, Operand(x1, LSL, 4)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(NVFlag); |
| CHECK_EQUAL_64(0x8000000000000000L, x10); |
| |
| // Check that sbc correctly sets the condition flags. |
| START(); |
| __ Mov(x0, 0); |
| __ Mov(x1, 0xffffffffffffffffL); |
| // Clear the C flag. |
| __ Adds(x0, x0, Operand(0)); |
| __ Sbcs(x10, x0, Operand(x1)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(ZFlag); |
| CHECK_EQUAL_64(0, x10); |
| |
| START(); |
| __ Mov(x0, 1); |
| __ Mov(x1, 0xffffffffffffffffL); |
| // Clear the C flag. |
| __ Adds(x0, x0, Operand(0)); |
| __ Sbcs(x10, x0, Operand(x1, LSR, 1)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(NFlag); |
| CHECK_EQUAL_64(0x8000000000000001L, x10); |
| |
| START(); |
| __ Mov(x0, 0); |
| // Clear the C flag. |
| __ Adds(x0, x0, Operand(0)); |
| __ Sbcs(x10, x0, Operand(0xffffffffffffffffL)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(ZFlag); |
| CHECK_EQUAL_64(0, x10); |
| |
| START() |
| __ Mov(w0, 0x7fffffff); |
| // Clear the C flag. |
| __ Adds(x0, x0, Operand(0)); |
| __ Ngcs(w10, w0); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(NFlag); |
| CHECK_EQUAL_64(0x80000000, x10); |
| |
| START(); |
| // Clear the C flag. |
| __ Adds(x0, x0, Operand(0)); |
| __ Ngcs(x10, 0x7fffffffffffffffL); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(NFlag); |
| CHECK_EQUAL_64(0x8000000000000000L, x10); |
| |
| START() |
| __ Mov(x0, 0); |
| // Set the C flag. |
| __ Cmp(x0, Operand(x0)); |
| __ Sbcs(x10, x0, Operand(1)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(NFlag); |
| CHECK_EQUAL_64(0xffffffffffffffffL, x10); |
| |
| START() |
| __ Mov(x0, 0); |
| // Set the C flag. |
| __ Cmp(x0, Operand(x0)); |
| __ Ngcs(x10, 0x7fffffffffffffffL); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(NFlag); |
| CHECK_EQUAL_64(0x8000000000000001L, x10); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(adc_sbc_extend) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| // Clear the C flag. |
| __ Adds(x0, x0, Operand(0)); |
| |
| __ Mov(x0, 0); |
| __ Mov(x1, 1); |
| __ Mov(x2, 0x0123456789abcdefL); |
| |
| __ Adc(x10, x1, Operand(w2, UXTB, 1)); |
| __ Adc(x11, x1, Operand(x2, SXTH, 2)); |
| __ Sbc(x12, x1, Operand(w2, UXTW, 4)); |
| __ Adc(x13, x1, Operand(x2, UXTX, 4)); |
| |
| __ Adc(w14, w1, Operand(w2, UXTB, 1)); |
| __ Adc(w15, w1, Operand(w2, SXTH, 2)); |
| __ Adc(w9, w1, Operand(w2, UXTW, 4)); |
| |
| // Set the C flag. |
| __ Cmp(w0, Operand(w0)); |
| |
| __ Adc(x20, x1, Operand(w2, UXTB, 1)); |
| __ Adc(x21, x1, Operand(x2, SXTH, 2)); |
| __ Sbc(x22, x1, Operand(w2, UXTW, 4)); |
| __ Adc(x23, x1, Operand(x2, UXTX, 4)); |
| |
| __ Adc(w24, w1, Operand(w2, UXTB, 1)); |
| __ Adc(w25, w1, Operand(w2, SXTH, 2)); |
| __ Adc(w26, w1, Operand(w2, UXTW, 4)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x1df, x10); |
| CHECK_EQUAL_64(0xffffffffffff37bdL, x11); |
| CHECK_EQUAL_64(0xfffffff765432110L, x12); |
| CHECK_EQUAL_64(0x123456789abcdef1L, x13); |
| |
| CHECK_EQUAL_32(0x1df, w14); |
| CHECK_EQUAL_32(0xffff37bd, w15); |
| CHECK_EQUAL_32(0x9abcdef1, w9); |
| |
| CHECK_EQUAL_64(0x1df + 1, x20); |
| CHECK_EQUAL_64(0xffffffffffff37bdL + 1, x21); |
| CHECK_EQUAL_64(0xfffffff765432110L + 1, x22); |
| CHECK_EQUAL_64(0x123456789abcdef1L + 1, x23); |
| |
| CHECK_EQUAL_32(0x1df + 1, w24); |
| CHECK_EQUAL_32(0xffff37bd + 1, w25); |
| CHECK_EQUAL_32(0x9abcdef1 + 1, w26); |
| |
| // Check that adc correctly sets the condition flags. |
| START(); |
| __ Mov(x0, 0xff); |
| __ Mov(x1, 0xffffffffffffffffL); |
| // Clear the C flag. |
| __ Adds(x0, x0, Operand(0)); |
| __ Adcs(x10, x0, Operand(x1, SXTX, 1)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(CFlag); |
| |
| START(); |
| __ Mov(x0, 0x7fffffffffffffffL); |
| __ Mov(x1, 1); |
| // Clear the C flag. |
| __ Adds(x0, x0, Operand(0)); |
| __ Adcs(x10, x0, Operand(x1, UXTB, 2)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(NVFlag); |
| |
| START(); |
| __ Mov(x0, 0x7fffffffffffffffL); |
| // Clear the C flag. |
| __ Adds(x0, x0, Operand(0)); |
| __ Adcs(x10, x0, Operand(1)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(NVFlag); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(adc_sbc_wide_imm) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0); |
| |
| // Clear the C flag. |
| __ Adds(x0, x0, Operand(0)); |
| |
| __ Adc(x7, x0, Operand(0x1234567890abcdefUL)); |
| __ Adc(w8, w0, Operand(0xffffffff)); |
| __ Sbc(x9, x0, Operand(0x1234567890abcdefUL)); |
| __ Sbc(w10, w0, Operand(0xffffffff)); |
| __ Ngc(x11, Operand(0xffffffff00000000UL)); |
| __ Ngc(w12, Operand(0xffff0000)); |
| |
| // Set the C flag. |
| __ Cmp(w0, Operand(w0)); |
| |
| __ Adc(x18, x0, Operand(0x1234567890abcdefUL)); |
| __ Adc(w19, w0, Operand(0xffffffff)); |
| __ Sbc(x20, x0, Operand(0x1234567890abcdefUL)); |
| __ Sbc(w21, w0, Operand(0xffffffff)); |
| __ Ngc(x22, Operand(0xffffffff00000000UL)); |
| __ Ngc(w23, Operand(0xffff0000)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x1234567890abcdefUL, x7); |
| CHECK_EQUAL_64(0xffffffff, x8); |
| CHECK_EQUAL_64(0xedcba9876f543210UL, x9); |
| CHECK_EQUAL_64(0, x10); |
| CHECK_EQUAL_64(0xffffffff, x11); |
| CHECK_EQUAL_64(0xffff, x12); |
| |
| CHECK_EQUAL_64(0x1234567890abcdefUL + 1, x18); |
| CHECK_EQUAL_64(0, x19); |
| CHECK_EQUAL_64(0xedcba9876f543211UL, x20); |
| CHECK_EQUAL_64(1, x21); |
| CHECK_EQUAL_64(0x100000000UL, x22); |
| CHECK_EQUAL_64(0x10000, x23); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(flags) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x0, 0); |
| __ Mov(x1, 0x1111111111111111L); |
| __ Neg(x10, Operand(x0)); |
| __ Neg(x11, Operand(x1)); |
| __ Neg(w12, Operand(w1)); |
| // Clear the C flag. |
| __ Adds(x0, x0, Operand(0)); |
| __ Ngc(x13, Operand(x0)); |
| // Set the C flag. |
| __ Cmp(x0, Operand(x0)); |
| __ Ngc(w14, Operand(w0)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0, x10); |
| CHECK_EQUAL_64(-0x1111111111111111L, x11); |
| CHECK_EQUAL_32(-0x11111111, w12); |
| CHECK_EQUAL_64(-1L, x13); |
| CHECK_EQUAL_32(0, w14); |
| |
| START(); |
| __ Mov(x0, 0); |
| __ Cmp(x0, Operand(x0)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(ZCFlag); |
| |
| START(); |
| __ Mov(w0, 0); |
| __ Cmp(w0, Operand(w0)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(ZCFlag); |
| |
| START(); |
| __ Mov(x0, 0); |
| __ Mov(x1, 0x1111111111111111L); |
| __ Cmp(x0, Operand(x1)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(NFlag); |
| |
| START(); |
| __ Mov(w0, 0); |
| __ Mov(w1, 0x11111111); |
| __ Cmp(w0, Operand(w1)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(NFlag); |
| |
| START(); |
| __ Mov(x1, 0x1111111111111111L); |
| __ Cmp(x1, Operand(0)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(CFlag); |
| |
| START(); |
| __ Mov(w1, 0x11111111); |
| __ Cmp(w1, Operand(0)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(CFlag); |
| |
| START(); |
| __ Mov(x0, 1); |
| __ Mov(x1, 0x7fffffffffffffffL); |
| __ Cmn(x1, Operand(x0)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(NVFlag); |
| |
| START(); |
| __ Mov(w0, 1); |
| __ Mov(w1, 0x7fffffff); |
| __ Cmn(w1, Operand(w0)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(NVFlag); |
| |
| START(); |
| __ Mov(x0, 1); |
| __ Mov(x1, 0xffffffffffffffffL); |
| __ Cmn(x1, Operand(x0)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(ZCFlag); |
| |
| START(); |
| __ Mov(w0, 1); |
| __ Mov(w1, 0xffffffff); |
| __ Cmn(w1, Operand(w0)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(ZCFlag); |
| |
| START(); |
| __ Mov(w0, 0); |
| __ Mov(w1, 1); |
| // Clear the C flag. |
| __ Adds(w0, w0, Operand(0)); |
| __ Ngcs(w0, Operand(w1)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(NFlag); |
| |
| START(); |
| __ Mov(w0, 0); |
| __ Mov(w1, 0); |
| // Set the C flag. |
| __ Cmp(w0, Operand(w0)); |
| __ Ngcs(w0, Operand(w1)); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_NZCV(ZCFlag); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(cmp_shift) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x18, 0xf0000000); |
| __ Mov(x19, 0xf000000010000000UL); |
| __ Mov(x20, 0xf0000000f0000000UL); |
| __ Mov(x21, 0x7800000078000000UL); |
| __ Mov(x22, 0x3c0000003c000000UL); |
| __ Mov(x23, 0x8000000780000000UL); |
| __ Mov(x24, 0x0000000f00000000UL); |
| __ Mov(x25, 0x00000003c0000000UL); |
| __ Mov(x26, 0x8000000780000000UL); |
| __ Mov(x27, 0xc0000003); |
| |
| __ Cmp(w20, Operand(w21, LSL, 1)); |
| __ Mrs(x0, NZCV); |
| |
| __ Cmp(x20, Operand(x22, LSL, 2)); |
| __ Mrs(x1, NZCV); |
| |
| __ Cmp(w19, Operand(w23, LSR, 3)); |
| __ Mrs(x2, NZCV); |
| |
| __ Cmp(x18, Operand(x24, LSR, 4)); |
| __ Mrs(x3, NZCV); |
| |
| __ Cmp(w20, Operand(w25, ASR, 2)); |
| __ Mrs(x4, NZCV); |
| |
| __ Cmp(x20, Operand(x26, ASR, 3)); |
| __ Mrs(x5, NZCV); |
| |
| __ Cmp(w27, Operand(w22, ROR, 28)); |
| __ Mrs(x6, NZCV); |
| |
| __ Cmp(x20, Operand(x21, ROR, 31)); |
| __ Mrs(x7, NZCV); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_32(ZCFlag, w0); |
| CHECK_EQUAL_32(ZCFlag, w1); |
| CHECK_EQUAL_32(ZCFlag, w2); |
| CHECK_EQUAL_32(ZCFlag, w3); |
| CHECK_EQUAL_32(ZCFlag, w4); |
| CHECK_EQUAL_32(ZCFlag, w5); |
| CHECK_EQUAL_32(ZCFlag, w6); |
| CHECK_EQUAL_32(ZCFlag, w7); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(cmp_extend) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(w20, 0x2); |
| __ Mov(w21, 0x1); |
| __ Mov(x22, 0xffffffffffffffffUL); |
| __ Mov(x23, 0xff); |
| __ Mov(x24, 0xfffffffffffffffeUL); |
| __ Mov(x25, 0xffff); |
| __ Mov(x26, 0xffffffff); |
| |
| __ Cmp(w20, Operand(w21, LSL, 1)); |
| __ Mrs(x0, NZCV); |
| |
| __ Cmp(x22, Operand(x23, SXTB, 0)); |
| __ Mrs(x1, NZCV); |
| |
| __ Cmp(x24, Operand(x23, SXTB, 1)); |
| __ Mrs(x2, NZCV); |
| |
| __ Cmp(x24, Operand(x23, UXTB, 1)); |
| __ Mrs(x3, NZCV); |
| |
| __ Cmp(w22, Operand(w25, UXTH)); |
| __ Mrs(x4, NZCV); |
| |
| __ Cmp(x22, Operand(x25, SXTH)); |
| __ Mrs(x5, NZCV); |
| |
| __ Cmp(x22, Operand(x26, UXTW)); |
| __ Mrs(x6, NZCV); |
| |
| __ Cmp(x24, Operand(x26, SXTW, 1)); |
| __ Mrs(x7, NZCV); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_32(ZCFlag, w0); |
| CHECK_EQUAL_32(ZCFlag, w1); |
| CHECK_EQUAL_32(ZCFlag, w2); |
| CHECK_EQUAL_32(NCFlag, w3); |
| CHECK_EQUAL_32(NCFlag, w4); |
| CHECK_EQUAL_32(ZCFlag, w5); |
| CHECK_EQUAL_32(NCFlag, w6); |
| CHECK_EQUAL_32(ZCFlag, w7); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ccmp) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(w16, 0); |
| __ Mov(w17, 1); |
| __ Cmp(w16, w16); |
| __ Ccmp(w16, w17, NCFlag, eq); |
| __ Mrs(x0, NZCV); |
| |
| __ Cmp(w16, w16); |
| __ Ccmp(w16, w17, NCFlag, ne); |
| __ Mrs(x1, NZCV); |
| |
| __ Cmp(x16, x16); |
| __ Ccmn(x16, 2, NZCVFlag, eq); |
| __ Mrs(x2, NZCV); |
| |
| __ Cmp(x16, x16); |
| __ Ccmn(x16, 2, NZCVFlag, ne); |
| __ Mrs(x3, NZCV); |
| |
| __ ccmp(x16, x16, NZCVFlag, al); |
| __ Mrs(x4, NZCV); |
| |
| __ ccmp(x16, x16, NZCVFlag, nv); |
| __ Mrs(x5, NZCV); |
| |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_32(NFlag, w0); |
| CHECK_EQUAL_32(NCFlag, w1); |
| CHECK_EQUAL_32(NoFlag, w2); |
| CHECK_EQUAL_32(NZCVFlag, w3); |
| CHECK_EQUAL_32(ZCFlag, w4); |
| CHECK_EQUAL_32(ZCFlag, w5); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ccmp_wide_imm) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(w20, 0); |
| |
| __ Cmp(w20, Operand(w20)); |
| __ Ccmp(w20, Operand(0x12345678), NZCVFlag, eq); |
| __ Mrs(x0, NZCV); |
| |
| __ Cmp(w20, Operand(w20)); |
| __ Ccmp(x20, Operand(0xffffffffffffffffUL), NZCVFlag, eq); |
| __ Mrs(x1, NZCV); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_32(NFlag, w0); |
| CHECK_EQUAL_32(NoFlag, w1); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ccmp_shift_extend) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(w20, 0x2); |
| __ Mov(w21, 0x1); |
| __ Mov(x22, 0xffffffffffffffffUL); |
| __ Mov(x23, 0xff); |
| __ Mov(x24, 0xfffffffffffffffeUL); |
| |
| __ Cmp(w20, Operand(w20)); |
| __ Ccmp(w20, Operand(w21, LSL, 1), NZCVFlag, eq); |
| __ Mrs(x0, NZCV); |
| |
| __ Cmp(w20, Operand(w20)); |
| __ Ccmp(x22, Operand(x23, SXTB, 0), NZCVFlag, eq); |
| __ Mrs(x1, NZCV); |
| |
| __ Cmp(w20, Operand(w20)); |
| __ Ccmp(x24, Operand(x23, SXTB, 1), NZCVFlag, eq); |
| __ Mrs(x2, NZCV); |
| |
| __ Cmp(w20, Operand(w20)); |
| __ Ccmp(x24, Operand(x23, UXTB, 1), NZCVFlag, eq); |
| __ Mrs(x3, NZCV); |
| |
| __ Cmp(w20, Operand(w20)); |
| __ Ccmp(x24, Operand(x23, UXTB, 1), NZCVFlag, ne); |
| __ Mrs(x4, NZCV); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_32(ZCFlag, w0); |
| CHECK_EQUAL_32(ZCFlag, w1); |
| CHECK_EQUAL_32(ZCFlag, w2); |
| CHECK_EQUAL_32(NCFlag, w3); |
| CHECK_EQUAL_32(NZCVFlag, w4); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(csel) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x16, 0); |
| __ Mov(x24, 0x0000000f0000000fUL); |
| __ Mov(x25, 0x0000001f0000001fUL); |
| __ Mov(x26, 0); |
| __ Mov(x27, 0); |
| |
| __ Cmp(w16, 0); |
| __ Csel(w0, w24, w25, eq); |
| __ Csel(w1, w24, w25, ne); |
| __ Csinc(w2, w24, w25, mi); |
| __ Csinc(w3, w24, w25, pl); |
| |
| __ csel(w13, w24, w25, al); |
| __ csel(x14, x24, x25, nv); |
| |
| __ Cmp(x16, 1); |
| __ Csinv(x4, x24, x25, gt); |
| __ Csinv(x5, x24, x25, le); |
| __ Csneg(x6, x24, x25, hs); |
| __ Csneg(x7, x24, x25, lo); |
| |
| __ Cset(w8, ne); |
| __ Csetm(w9, ne); |
| __ Cinc(x10, x25, ne); |
| __ Cinv(x11, x24, ne); |
| __ Cneg(x12, x24, ne); |
| |
| __ csel(w15, w24, w25, al); |
| __ csel(x18, x24, x25, nv); |
| |
| __ CzeroX(x24, ne); |
| __ CzeroX(x25, eq); |
| |
| __ CmovX(x26, x25, ne); |
| __ CmovX(x27, x25, eq); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x0000000f, x0); |
| CHECK_EQUAL_64(0x0000001f, x1); |
| CHECK_EQUAL_64(0x00000020, x2); |
| CHECK_EQUAL_64(0x0000000f, x3); |
| CHECK_EQUAL_64(0xffffffe0ffffffe0UL, x4); |
| CHECK_EQUAL_64(0x0000000f0000000fUL, x5); |
| CHECK_EQUAL_64(0xffffffe0ffffffe1UL, x6); |
| CHECK_EQUAL_64(0x0000000f0000000fUL, x7); |
| CHECK_EQUAL_64(0x00000001, x8); |
| CHECK_EQUAL_64(0xffffffff, x9); |
| CHECK_EQUAL_64(0x0000001f00000020UL, x10); |
| CHECK_EQUAL_64(0xfffffff0fffffff0UL, x11); |
| CHECK_EQUAL_64(0xfffffff0fffffff1UL, x12); |
| CHECK_EQUAL_64(0x0000000f, x13); |
| CHECK_EQUAL_64(0x0000000f0000000fUL, x14); |
| CHECK_EQUAL_64(0x0000000f, x15); |
| CHECK_EQUAL_64(0x0000000f0000000fUL, x18); |
| CHECK_EQUAL_64(0, x24); |
| CHECK_EQUAL_64(0x0000001f0000001fUL, x25); |
| CHECK_EQUAL_64(0x0000001f0000001fUL, x26); |
| CHECK_EQUAL_64(0, x27); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(csel_imm) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x18, 0); |
| __ Mov(x19, 0x80000000); |
| __ Mov(x20, 0x8000000000000000UL); |
| |
| __ Cmp(x18, Operand(0)); |
| __ Csel(w0, w19, -2, ne); |
| __ Csel(w1, w19, -1, ne); |
| __ Csel(w2, w19, 0, ne); |
| __ Csel(w3, w19, 1, ne); |
| __ Csel(w4, w19, 2, ne); |
| __ Csel(w5, w19, Operand(w19, ASR, 31), ne); |
| __ Csel(w6, w19, Operand(w19, ROR, 1), ne); |
| __ Csel(w7, w19, 3, eq); |
| |
| __ Csel(x8, x20, -2, ne); |
| __ Csel(x9, x20, -1, ne); |
| __ Csel(x10, x20, 0, ne); |
| __ Csel(x11, x20, 1, ne); |
| __ Csel(x12, x20, 2, ne); |
| __ Csel(x13, x20, Operand(x20, ASR, 63), ne); |
| __ Csel(x14, x20, Operand(x20, ROR, 1), ne); |
| __ Csel(x15, x20, 3, eq); |
| |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_32(-2, w0); |
| CHECK_EQUAL_32(-1, w1); |
| CHECK_EQUAL_32(0, w2); |
| CHECK_EQUAL_32(1, w3); |
| CHECK_EQUAL_32(2, w4); |
| CHECK_EQUAL_32(-1, w5); |
| CHECK_EQUAL_32(0x40000000, w6); |
| CHECK_EQUAL_32(0x80000000, w7); |
| |
| CHECK_EQUAL_64(-2, x8); |
| CHECK_EQUAL_64(-1, x9); |
| CHECK_EQUAL_64(0, x10); |
| CHECK_EQUAL_64(1, x11); |
| CHECK_EQUAL_64(2, x12); |
| CHECK_EQUAL_64(-1, x13); |
| CHECK_EQUAL_64(0x4000000000000000UL, x14); |
| CHECK_EQUAL_64(0x8000000000000000UL, x15); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(lslv) { |
| INIT_V8(); |
| SETUP(); |
| |
| uint64_t value = 0x0123456789abcdefUL; |
| int shift[] = {1, 3, 5, 9, 17, 33}; |
| |
| START(); |
| __ Mov(x0, value); |
| __ Mov(w1, shift[0]); |
| __ Mov(w2, shift[1]); |
| __ Mov(w3, shift[2]); |
| __ Mov(w4, shift[3]); |
| __ Mov(w5, shift[4]); |
| __ Mov(w6, shift[5]); |
| |
| __ lslv(x0, x0, xzr); |
| |
| __ Lsl(x16, x0, x1); |
| __ Lsl(x17, x0, x2); |
| __ Lsl(x18, x0, x3); |
| __ Lsl(x19, x0, x4); |
| __ Lsl(x20, x0, x5); |
| __ Lsl(x21, x0, x6); |
| |
| __ Lsl(w22, w0, w1); |
| __ Lsl(w23, w0, w2); |
| __ Lsl(w24, w0, w3); |
| __ Lsl(w25, w0, w4); |
| __ Lsl(w26, w0, w5); |
| __ Lsl(w27, w0, w6); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(value, x0); |
| CHECK_EQUAL_64(value << (shift[0] & 63), x16); |
| CHECK_EQUAL_64(value << (shift[1] & 63), x17); |
| CHECK_EQUAL_64(value << (shift[2] & 63), x18); |
| CHECK_EQUAL_64(value << (shift[3] & 63), x19); |
| CHECK_EQUAL_64(value << (shift[4] & 63), x20); |
| CHECK_EQUAL_64(value << (shift[5] & 63), x21); |
| CHECK_EQUAL_32(value << (shift[0] & 31), w22); |
| CHECK_EQUAL_32(value << (shift[1] & 31), w23); |
| CHECK_EQUAL_32(value << (shift[2] & 31), w24); |
| CHECK_EQUAL_32(value << (shift[3] & 31), w25); |
| CHECK_EQUAL_32(value << (shift[4] & 31), w26); |
| CHECK_EQUAL_32(value << (shift[5] & 31), w27); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(lsrv) { |
| INIT_V8(); |
| SETUP(); |
| |
| uint64_t value = 0x0123456789abcdefUL; |
| int shift[] = {1, 3, 5, 9, 17, 33}; |
| |
| START(); |
| __ Mov(x0, value); |
| __ Mov(w1, shift[0]); |
| __ Mov(w2, shift[1]); |
| __ Mov(w3, shift[2]); |
| __ Mov(w4, shift[3]); |
| __ Mov(w5, shift[4]); |
| __ Mov(w6, shift[5]); |
| |
| __ lsrv(x0, x0, xzr); |
| |
| __ Lsr(x16, x0, x1); |
| __ Lsr(x17, x0, x2); |
| __ Lsr(x18, x0, x3); |
| __ Lsr(x19, x0, x4); |
| __ Lsr(x20, x0, x5); |
| __ Lsr(x21, x0, x6); |
| |
| __ Lsr(w22, w0, w1); |
| __ Lsr(w23, w0, w2); |
| __ Lsr(w24, w0, w3); |
| __ Lsr(w25, w0, w4); |
| __ Lsr(w26, w0, w5); |
| __ Lsr(w27, w0, w6); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(value, x0); |
| CHECK_EQUAL_64(value >> (shift[0] & 63), x16); |
| CHECK_EQUAL_64(value >> (shift[1] & 63), x17); |
| CHECK_EQUAL_64(value >> (shift[2] & 63), x18); |
| CHECK_EQUAL_64(value >> (shift[3] & 63), x19); |
| CHECK_EQUAL_64(value >> (shift[4] & 63), x20); |
| CHECK_EQUAL_64(value >> (shift[5] & 63), x21); |
| |
| value &= 0xffffffffUL; |
| CHECK_EQUAL_32(value >> (shift[0] & 31), w22); |
| CHECK_EQUAL_32(value >> (shift[1] & 31), w23); |
| CHECK_EQUAL_32(value >> (shift[2] & 31), w24); |
| CHECK_EQUAL_32(value >> (shift[3] & 31), w25); |
| CHECK_EQUAL_32(value >> (shift[4] & 31), w26); |
| CHECK_EQUAL_32(value >> (shift[5] & 31), w27); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(asrv) { |
| INIT_V8(); |
| SETUP(); |
| |
| int64_t value = 0xfedcba98fedcba98UL; |
| int shift[] = {1, 3, 5, 9, 17, 33}; |
| |
| START(); |
| __ Mov(x0, value); |
| __ Mov(w1, shift[0]); |
| __ Mov(w2, shift[1]); |
| __ Mov(w3, shift[2]); |
| __ Mov(w4, shift[3]); |
| __ Mov(w5, shift[4]); |
| __ Mov(w6, shift[5]); |
| |
| __ asrv(x0, x0, xzr); |
| |
| __ Asr(x16, x0, x1); |
| __ Asr(x17, x0, x2); |
| __ Asr(x18, x0, x3); |
| __ Asr(x19, x0, x4); |
| __ Asr(x20, x0, x5); |
| __ Asr(x21, x0, x6); |
| |
| __ Asr(w22, w0, w1); |
| __ Asr(w23, w0, w2); |
| __ Asr(w24, w0, w3); |
| __ Asr(w25, w0, w4); |
| __ Asr(w26, w0, w5); |
| __ Asr(w27, w0, w6); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(value, x0); |
| CHECK_EQUAL_64(value >> (shift[0] & 63), x16); |
| CHECK_EQUAL_64(value >> (shift[1] & 63), x17); |
| CHECK_EQUAL_64(value >> (shift[2] & 63), x18); |
| CHECK_EQUAL_64(value >> (shift[3] & 63), x19); |
| CHECK_EQUAL_64(value >> (shift[4] & 63), x20); |
| CHECK_EQUAL_64(value >> (shift[5] & 63), x21); |
| |
| int32_t value32 = static_cast<int32_t>(value & 0xffffffffUL); |
| CHECK_EQUAL_32(value32 >> (shift[0] & 31), w22); |
| CHECK_EQUAL_32(value32 >> (shift[1] & 31), w23); |
| CHECK_EQUAL_32(value32 >> (shift[2] & 31), w24); |
| CHECK_EQUAL_32(value32 >> (shift[3] & 31), w25); |
| CHECK_EQUAL_32(value32 >> (shift[4] & 31), w26); |
| CHECK_EQUAL_32(value32 >> (shift[5] & 31), w27); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(rorv) { |
| INIT_V8(); |
| SETUP(); |
| |
| uint64_t value = 0x0123456789abcdefUL; |
| int shift[] = {4, 8, 12, 16, 24, 36}; |
| |
| START(); |
| __ Mov(x0, value); |
| __ Mov(w1, shift[0]); |
| __ Mov(w2, shift[1]); |
| __ Mov(w3, shift[2]); |
| __ Mov(w4, shift[3]); |
| __ Mov(w5, shift[4]); |
| __ Mov(w6, shift[5]); |
| |
| __ rorv(x0, x0, xzr); |
| |
| __ Ror(x16, x0, x1); |
| __ Ror(x17, x0, x2); |
| __ Ror(x18, x0, x3); |
| __ Ror(x19, x0, x4); |
| __ Ror(x20, x0, x5); |
| __ Ror(x21, x0, x6); |
| |
| __ Ror(w22, w0, w1); |
| __ Ror(w23, w0, w2); |
| __ Ror(w24, w0, w3); |
| __ Ror(w25, w0, w4); |
| __ Ror(w26, w0, w5); |
| __ Ror(w27, w0, w6); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(value, x0); |
| CHECK_EQUAL_64(0xf0123456789abcdeUL, x16); |
| CHECK_EQUAL_64(0xef0123456789abcdUL, x17); |
| CHECK_EQUAL_64(0xdef0123456789abcUL, x18); |
| CHECK_EQUAL_64(0xcdef0123456789abUL, x19); |
| CHECK_EQUAL_64(0xabcdef0123456789UL, x20); |
| CHECK_EQUAL_64(0x789abcdef0123456UL, x21); |
| CHECK_EQUAL_32(0xf89abcde, w22); |
| CHECK_EQUAL_32(0xef89abcd, w23); |
| CHECK_EQUAL_32(0xdef89abc, w24); |
| CHECK_EQUAL_32(0xcdef89ab, w25); |
| CHECK_EQUAL_32(0xabcdef89, w26); |
| CHECK_EQUAL_32(0xf89abcde, w27); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(bfm) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x1, 0x0123456789abcdefL); |
| |
| __ Mov(x10, 0x8888888888888888L); |
| __ Mov(x11, 0x8888888888888888L); |
| __ Mov(x12, 0x8888888888888888L); |
| __ Mov(x13, 0x8888888888888888L); |
| __ Mov(w20, 0x88888888); |
| __ Mov(w21, 0x88888888); |
| |
| __ bfm(x10, x1, 16, 31); |
| __ bfm(x11, x1, 32, 15); |
| |
| __ bfm(w20, w1, 16, 23); |
| __ bfm(w21, w1, 24, 15); |
| |
| // Aliases. |
| __ Bfi(x12, x1, 16, 8); |
| __ Bfxil(x13, x1, 16, 8); |
| END(); |
| |
| RUN(); |
| |
| |
| CHECK_EQUAL_64(0x88888888888889abL, x10); |
| CHECK_EQUAL_64(0x8888cdef88888888L, x11); |
| |
| CHECK_EQUAL_32(0x888888ab, w20); |
| CHECK_EQUAL_32(0x88cdef88, w21); |
| |
| CHECK_EQUAL_64(0x8888888888ef8888L, x12); |
| CHECK_EQUAL_64(0x88888888888888abL, x13); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(sbfm) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x1, 0x0123456789abcdefL); |
| __ Mov(x2, 0xfedcba9876543210L); |
| |
| __ sbfm(x10, x1, 16, 31); |
| __ sbfm(x11, x1, 32, 15); |
| __ sbfm(x12, x1, 32, 47); |
| __ sbfm(x13, x1, 48, 35); |
| |
| __ sbfm(w14, w1, 16, 23); |
| __ sbfm(w15, w1, 24, 15); |
| __ sbfm(w16, w2, 16, 23); |
| __ sbfm(w17, w2, 24, 15); |
| |
| // Aliases. |
| __ Asr(x18, x1, 32); |
| __ Asr(x19, x2, 32); |
| __ Sbfiz(x20, x1, 8, 16); |
| __ Sbfiz(x21, x2, 8, 16); |
| __ Sbfx(x22, x1, 8, 16); |
| __ Sbfx(x23, x2, 8, 16); |
| __ Sxtb(x24, w1); |
| __ Sxtb(x25, x2); |
| __ Sxth(x26, w1); |
| __ Sxth(x27, x2); |
| __ Sxtw(x28, w1); |
| __ Sxtw(x29, x2); |
| END(); |
| |
| RUN(); |
| |
| |
| CHECK_EQUAL_64(0xffffffffffff89abL, x10); |
| CHECK_EQUAL_64(0xffffcdef00000000L, x11); |
| CHECK_EQUAL_64(0x4567L, x12); |
| CHECK_EQUAL_64(0x789abcdef0000L, x13); |
| |
| CHECK_EQUAL_32(0xffffffab, w14); |
| CHECK_EQUAL_32(0xffcdef00, w15); |
| CHECK_EQUAL_32(0x54, w16); |
| CHECK_EQUAL_32(0x00321000, w17); |
| |
| CHECK_EQUAL_64(0x01234567L, x18); |
| CHECK_EQUAL_64(0xfffffffffedcba98L, x19); |
| CHECK_EQUAL_64(0xffffffffffcdef00L, x20); |
| CHECK_EQUAL_64(0x321000L, x21); |
| CHECK_EQUAL_64(0xffffffffffffabcdL, x22); |
| CHECK_EQUAL_64(0x5432L, x23); |
| CHECK_EQUAL_64(0xffffffffffffffefL, x24); |
| CHECK_EQUAL_64(0x10, x25); |
| CHECK_EQUAL_64(0xffffffffffffcdefL, x26); |
| CHECK_EQUAL_64(0x3210, x27); |
| CHECK_EQUAL_64(0xffffffff89abcdefL, x28); |
| CHECK_EQUAL_64(0x76543210, x29); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(ubfm) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x1, 0x0123456789abcdefL); |
| __ Mov(x2, 0xfedcba9876543210L); |
| |
| __ Mov(x10, 0x8888888888888888L); |
| __ Mov(x11, 0x8888888888888888L); |
| |
| __ ubfm(x10, x1, 16, 31); |
| __ ubfm(x11, x1, 32, 15); |
| __ ubfm(x12, x1, 32, 47); |
| __ ubfm(x13, x1, 48, 35); |
| |
| __ ubfm(w25, w1, 16, 23); |
| __ ubfm(w26, w1, 24, 15); |
| __ ubfm(w27, w2, 16, 23); |
| __ ubfm(w28, w2, 24, 15); |
| |
| // Aliases |
| __ Lsl(x15, x1, 63); |
| __ Lsl(x16, x1, 0); |
| __ Lsr(x17, x1, 32); |
| __ Ubfiz(x18, x1, 8, 16); |
| __ Ubfx(x19, x1, 8, 16); |
| __ Uxtb(x20, x1); |
| __ Uxth(x21, x1); |
| __ Uxtw(x22, x1); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x00000000000089abL, x10); |
| CHECK_EQUAL_64(0x0000cdef00000000L, x11); |
| CHECK_EQUAL_64(0x4567L, x12); |
| CHECK_EQUAL_64(0x789abcdef0000L, x13); |
| |
| CHECK_EQUAL_32(0x000000ab, w25); |
| CHECK_EQUAL_32(0x00cdef00, w26); |
| CHECK_EQUAL_32(0x54, w27); |
| CHECK_EQUAL_32(0x00321000, w28); |
| |
| CHECK_EQUAL_64(0x8000000000000000L, x15); |
| CHECK_EQUAL_64(0x0123456789abcdefL, x16); |
| CHECK_EQUAL_64(0x01234567L, x17); |
| CHECK_EQUAL_64(0xcdef00L, x18); |
| CHECK_EQUAL_64(0xabcdL, x19); |
| CHECK_EQUAL_64(0xefL, x20); |
| CHECK_EQUAL_64(0xcdefL, x21); |
| CHECK_EQUAL_64(0x89abcdefL, x22); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(extr) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x1, 0x0123456789abcdefL); |
| __ Mov(x2, 0xfedcba9876543210L); |
| |
| __ Extr(w10, w1, w2, 0); |
| __ Extr(x11, x1, x2, 0); |
| __ Extr(w12, w1, w2, 1); |
| __ Extr(x13, x2, x1, 2); |
| |
| __ Ror(w20, w1, 0); |
| __ Ror(x21, x1, 0); |
| __ Ror(w22, w2, 17); |
| __ Ror(w23, w1, 31); |
| __ Ror(x24, x2, 1); |
| __ Ror(x25, x1, 63); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x76543210, x10); |
| CHECK_EQUAL_64(0xfedcba9876543210L, x11); |
| CHECK_EQUAL_64(0xbb2a1908, x12); |
| CHECK_EQUAL_64(0x0048d159e26af37bUL, x13); |
| CHECK_EQUAL_64(0x89abcdef, x20); |
| CHECK_EQUAL_64(0x0123456789abcdefL, x21); |
| CHECK_EQUAL_64(0x19083b2a, x22); |
| CHECK_EQUAL_64(0x13579bdf, x23); |
| CHECK_EQUAL_64(0x7f6e5d4c3b2a1908UL, x24); |
| CHECK_EQUAL_64(0x02468acf13579bdeUL, x25); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fmov_imm) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s11, 1.0); |
| __ Fmov(d22, -13.0); |
| __ Fmov(s1, 255.0); |
| __ Fmov(d2, 12.34567); |
| __ Fmov(s3, 0.0); |
| __ Fmov(d4, 0.0); |
| __ Fmov(s5, kFP32PositiveInfinity); |
| __ Fmov(d6, kFP64NegativeInfinity); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_FP32(1.0, s11); |
| CHECK_EQUAL_FP64(-13.0, d22); |
| CHECK_EQUAL_FP32(255.0, s1); |
| CHECK_EQUAL_FP64(12.34567, d2); |
| CHECK_EQUAL_FP32(0.0, s3); |
| CHECK_EQUAL_FP64(0.0, d4); |
| CHECK_EQUAL_FP32(kFP32PositiveInfinity, s5); |
| CHECK_EQUAL_FP64(kFP64NegativeInfinity, d6); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fmov_reg) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s20, 1.0); |
| __ Fmov(w10, s20); |
| __ Fmov(s30, w10); |
| __ Fmov(s5, s20); |
| __ Fmov(d1, -13.0); |
| __ Fmov(x1, d1); |
| __ Fmov(d2, x1); |
| __ Fmov(d4, d1); |
| __ Fmov(d6, rawbits_to_double(0x0123456789abcdefL)); |
| __ Fmov(s6, s6); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_32(float_to_rawbits(1.0), w10); |
| CHECK_EQUAL_FP32(1.0, s30); |
| CHECK_EQUAL_FP32(1.0, s5); |
| CHECK_EQUAL_64(double_to_rawbits(-13.0), x1); |
| CHECK_EQUAL_FP64(-13.0, d2); |
| CHECK_EQUAL_FP64(-13.0, d4); |
| CHECK_EQUAL_FP32(rawbits_to_float(0x89abcdef), s6); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fadd) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s14, -0.0f); |
| __ Fmov(s15, kFP32PositiveInfinity); |
| __ Fmov(s16, kFP32NegativeInfinity); |
| __ Fmov(s17, 3.25f); |
| __ Fmov(s18, 1.0f); |
| __ Fmov(s19, 0.0f); |
| |
| __ Fmov(d26, -0.0); |
| __ Fmov(d27, kFP64PositiveInfinity); |
| __ Fmov(d28, kFP64NegativeInfinity); |
| __ Fmov(d29, 0.0); |
| __ Fmov(d30, -2.0); |
| __ Fmov(d31, 2.25); |
| |
| __ Fadd(s0, s17, s18); |
| __ Fadd(s1, s18, s19); |
| __ Fadd(s2, s14, s18); |
| __ Fadd(s3, s15, s18); |
| __ Fadd(s4, s16, s18); |
| __ Fadd(s5, s15, s16); |
| __ Fadd(s6, s16, s15); |
| |
| __ Fadd(d7, d30, d31); |
| __ Fadd(d8, d29, d31); |
| __ Fadd(d9, d26, d31); |
| __ Fadd(d10, d27, d31); |
| __ Fadd(d11, d28, d31); |
| __ Fadd(d12, d27, d28); |
| __ Fadd(d13, d28, d27); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_FP32(4.25, s0); |
| CHECK_EQUAL_FP32(1.0, s1); |
| CHECK_EQUAL_FP32(1.0, s2); |
| CHECK_EQUAL_FP32(kFP32PositiveInfinity, s3); |
| CHECK_EQUAL_FP32(kFP32NegativeInfinity, s4); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s5); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s6); |
| CHECK_EQUAL_FP64(0.25, d7); |
| CHECK_EQUAL_FP64(2.25, d8); |
| CHECK_EQUAL_FP64(2.25, d9); |
| CHECK_EQUAL_FP64(kFP64PositiveInfinity, d10); |
| CHECK_EQUAL_FP64(kFP64NegativeInfinity, d11); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d12); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d13); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fsub) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s14, -0.0f); |
| __ Fmov(s15, kFP32PositiveInfinity); |
| __ Fmov(s16, kFP32NegativeInfinity); |
| __ Fmov(s17, 3.25f); |
| __ Fmov(s18, 1.0f); |
| __ Fmov(s19, 0.0f); |
| |
| __ Fmov(d26, -0.0); |
| __ Fmov(d27, kFP64PositiveInfinity); |
| __ Fmov(d28, kFP64NegativeInfinity); |
| __ Fmov(d29, 0.0); |
| __ Fmov(d30, -2.0); |
| __ Fmov(d31, 2.25); |
| |
| __ Fsub(s0, s17, s18); |
| __ Fsub(s1, s18, s19); |
| __ Fsub(s2, s14, s18); |
| __ Fsub(s3, s18, s15); |
| __ Fsub(s4, s18, s16); |
| __ Fsub(s5, s15, s15); |
| __ Fsub(s6, s16, s16); |
| |
| __ Fsub(d7, d30, d31); |
| __ Fsub(d8, d29, d31); |
| __ Fsub(d9, d26, d31); |
| __ Fsub(d10, d31, d27); |
| __ Fsub(d11, d31, d28); |
| __ Fsub(d12, d27, d27); |
| __ Fsub(d13, d28, d28); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_FP32(2.25, s0); |
| CHECK_EQUAL_FP32(1.0, s1); |
| CHECK_EQUAL_FP32(-1.0, s2); |
| CHECK_EQUAL_FP32(kFP32NegativeInfinity, s3); |
| CHECK_EQUAL_FP32(kFP32PositiveInfinity, s4); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s5); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s6); |
| CHECK_EQUAL_FP64(-4.25, d7); |
| CHECK_EQUAL_FP64(-2.25, d8); |
| CHECK_EQUAL_FP64(-2.25, d9); |
| CHECK_EQUAL_FP64(kFP64NegativeInfinity, d10); |
| CHECK_EQUAL_FP64(kFP64PositiveInfinity, d11); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d12); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d13); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fmul) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s14, -0.0f); |
| __ Fmov(s15, kFP32PositiveInfinity); |
| __ Fmov(s16, kFP32NegativeInfinity); |
| __ Fmov(s17, 3.25f); |
| __ Fmov(s18, 2.0f); |
| __ Fmov(s19, 0.0f); |
| __ Fmov(s20, -2.0f); |
| |
| __ Fmov(d26, -0.0); |
| __ Fmov(d27, kFP64PositiveInfinity); |
| __ Fmov(d28, kFP64NegativeInfinity); |
| __ Fmov(d29, 0.0); |
| __ Fmov(d30, -2.0); |
| __ Fmov(d31, 2.25); |
| |
| __ Fmul(s0, s17, s18); |
| __ Fmul(s1, s18, s19); |
| __ Fmul(s2, s14, s14); |
| __ Fmul(s3, s15, s20); |
| __ Fmul(s4, s16, s20); |
| __ Fmul(s5, s15, s19); |
| __ Fmul(s6, s19, s16); |
| |
| __ Fmul(d7, d30, d31); |
| __ Fmul(d8, d29, d31); |
| __ Fmul(d9, d26, d26); |
| __ Fmul(d10, d27, d30); |
| __ Fmul(d11, d28, d30); |
| __ Fmul(d12, d27, d29); |
| __ Fmul(d13, d29, d28); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_FP32(6.5, s0); |
| CHECK_EQUAL_FP32(0.0, s1); |
| CHECK_EQUAL_FP32(0.0, s2); |
| CHECK_EQUAL_FP32(kFP32NegativeInfinity, s3); |
| CHECK_EQUAL_FP32(kFP32PositiveInfinity, s4); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s5); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s6); |
| CHECK_EQUAL_FP64(-4.5, d7); |
| CHECK_EQUAL_FP64(0.0, d8); |
| CHECK_EQUAL_FP64(0.0, d9); |
| CHECK_EQUAL_FP64(kFP64NegativeInfinity, d10); |
| CHECK_EQUAL_FP64(kFP64PositiveInfinity, d11); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d12); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d13); |
| |
| TEARDOWN(); |
| } |
| |
| |
| static void FmaddFmsubHelper(double n, double m, double a, |
| double fmadd, double fmsub, |
| double fnmadd, double fnmsub) { |
| SETUP(); |
| START(); |
| |
| __ Fmov(d0, n); |
| __ Fmov(d1, m); |
| __ Fmov(d2, a); |
| __ Fmadd(d28, d0, d1, d2); |
| __ Fmsub(d29, d0, d1, d2); |
| __ Fnmadd(d30, d0, d1, d2); |
| __ Fnmsub(d31, d0, d1, d2); |
| |
| END(); |
| RUN(); |
| |
| CHECK_EQUAL_FP64(fmadd, d28); |
| CHECK_EQUAL_FP64(fmsub, d29); |
| CHECK_EQUAL_FP64(fnmadd, d30); |
| CHECK_EQUAL_FP64(fnmsub, d31); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fmadd_fmsub_double) { |
| INIT_V8(); |
| |
| // It's hard to check the result of fused operations because the only way to |
| // calculate the result is using fma, which is what the simulator uses anyway. |
| // TODO(jbramley): Add tests to check behaviour against a hardware trace. |
| |
| // Basic operation. |
| FmaddFmsubHelper(1.0, 2.0, 3.0, 5.0, 1.0, -5.0, -1.0); |
| FmaddFmsubHelper(-1.0, 2.0, 3.0, 1.0, 5.0, -1.0, -5.0); |
| |
| // Check the sign of exact zeroes. |
| // n m a fmadd fmsub fnmadd fnmsub |
| FmaddFmsubHelper(-0.0, +0.0, -0.0, -0.0, +0.0, +0.0, +0.0); |
| FmaddFmsubHelper(+0.0, +0.0, -0.0, +0.0, -0.0, +0.0, +0.0); |
| FmaddFmsubHelper(+0.0, +0.0, +0.0, +0.0, +0.0, -0.0, +0.0); |
| FmaddFmsubHelper(-0.0, +0.0, +0.0, +0.0, +0.0, +0.0, -0.0); |
| FmaddFmsubHelper(+0.0, -0.0, -0.0, -0.0, +0.0, +0.0, +0.0); |
| FmaddFmsubHelper(-0.0, -0.0, -0.0, +0.0, -0.0, +0.0, +0.0); |
| FmaddFmsubHelper(-0.0, -0.0, +0.0, +0.0, +0.0, -0.0, +0.0); |
| FmaddFmsubHelper(+0.0, -0.0, +0.0, +0.0, +0.0, +0.0, -0.0); |
| |
| // Check NaN generation. |
| FmaddFmsubHelper(kFP64PositiveInfinity, 0.0, 42.0, |
| kFP64DefaultNaN, kFP64DefaultNaN, |
| kFP64DefaultNaN, kFP64DefaultNaN); |
| FmaddFmsubHelper(0.0, kFP64PositiveInfinity, 42.0, |
| kFP64DefaultNaN, kFP64DefaultNaN, |
| kFP64DefaultNaN, kFP64DefaultNaN); |
| FmaddFmsubHelper(kFP64PositiveInfinity, 1.0, kFP64PositiveInfinity, |
| kFP64PositiveInfinity, // inf + ( inf * 1) = inf |
| kFP64DefaultNaN, // inf + (-inf * 1) = NaN |
| kFP64NegativeInfinity, // -inf + (-inf * 1) = -inf |
| kFP64DefaultNaN); // -inf + ( inf * 1) = NaN |
| FmaddFmsubHelper(kFP64NegativeInfinity, 1.0, kFP64PositiveInfinity, |
| kFP64DefaultNaN, // inf + (-inf * 1) = NaN |
| kFP64PositiveInfinity, // inf + ( inf * 1) = inf |
| kFP64DefaultNaN, // -inf + ( inf * 1) = NaN |
| kFP64NegativeInfinity); // -inf + (-inf * 1) = -inf |
| } |
| |
| |
| static void FmaddFmsubHelper(float n, float m, float a, |
| float fmadd, float fmsub, |
| float fnmadd, float fnmsub) { |
| SETUP(); |
| START(); |
| |
| __ Fmov(s0, n); |
| __ Fmov(s1, m); |
| __ Fmov(s2, a); |
| __ Fmadd(s28, s0, s1, s2); |
| __ Fmsub(s29, s0, s1, s2); |
| __ Fnmadd(s30, s0, s1, s2); |
| __ Fnmsub(s31, s0, s1, s2); |
| |
| END(); |
| RUN(); |
| |
| CHECK_EQUAL_FP32(fmadd, s28); |
| CHECK_EQUAL_FP32(fmsub, s29); |
| CHECK_EQUAL_FP32(fnmadd, s30); |
| CHECK_EQUAL_FP32(fnmsub, s31); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fmadd_fmsub_float) { |
| INIT_V8(); |
| // It's hard to check the result of fused operations because the only way to |
| // calculate the result is using fma, which is what the simulator uses anyway. |
| // TODO(jbramley): Add tests to check behaviour against a hardware trace. |
| |
| // Basic operation. |
| FmaddFmsubHelper(1.0f, 2.0f, 3.0f, 5.0f, 1.0f, -5.0f, -1.0f); |
| FmaddFmsubHelper(-1.0f, 2.0f, 3.0f, 1.0f, 5.0f, -1.0f, -5.0f); |
| |
| // Check the sign of exact zeroes. |
| // n m a fmadd fmsub fnmadd fnmsub |
| FmaddFmsubHelper(-0.0f, +0.0f, -0.0f, -0.0f, +0.0f, +0.0f, +0.0f); |
| FmaddFmsubHelper(+0.0f, +0.0f, -0.0f, +0.0f, -0.0f, +0.0f, +0.0f); |
| FmaddFmsubHelper(+0.0f, +0.0f, +0.0f, +0.0f, +0.0f, -0.0f, +0.0f); |
| FmaddFmsubHelper(-0.0f, +0.0f, +0.0f, +0.0f, +0.0f, +0.0f, -0.0f); |
| FmaddFmsubHelper(+0.0f, -0.0f, -0.0f, -0.0f, +0.0f, +0.0f, +0.0f); |
| FmaddFmsubHelper(-0.0f, -0.0f, -0.0f, +0.0f, -0.0f, +0.0f, +0.0f); |
| FmaddFmsubHelper(-0.0f, -0.0f, +0.0f, +0.0f, +0.0f, -0.0f, +0.0f); |
| FmaddFmsubHelper(+0.0f, -0.0f, +0.0f, +0.0f, +0.0f, +0.0f, -0.0f); |
| |
| // Check NaN generation. |
| FmaddFmsubHelper(kFP32PositiveInfinity, 0.0f, 42.0f, |
| kFP32DefaultNaN, kFP32DefaultNaN, |
| kFP32DefaultNaN, kFP32DefaultNaN); |
| FmaddFmsubHelper(0.0f, kFP32PositiveInfinity, 42.0f, |
| kFP32DefaultNaN, kFP32DefaultNaN, |
| kFP32DefaultNaN, kFP32DefaultNaN); |
| FmaddFmsubHelper(kFP32PositiveInfinity, 1.0f, kFP32PositiveInfinity, |
| kFP32PositiveInfinity, // inf + ( inf * 1) = inf |
| kFP32DefaultNaN, // inf + (-inf * 1) = NaN |
| kFP32NegativeInfinity, // -inf + (-inf * 1) = -inf |
| kFP32DefaultNaN); // -inf + ( inf * 1) = NaN |
| FmaddFmsubHelper(kFP32NegativeInfinity, 1.0f, kFP32PositiveInfinity, |
| kFP32DefaultNaN, // inf + (-inf * 1) = NaN |
| kFP32PositiveInfinity, // inf + ( inf * 1) = inf |
| kFP32DefaultNaN, // -inf + ( inf * 1) = NaN |
| kFP32NegativeInfinity); // -inf + (-inf * 1) = -inf |
| } |
| |
| |
| TEST(fmadd_fmsub_double_nans) { |
| INIT_V8(); |
| // Make sure that NaN propagation works correctly. |
| double s1 = rawbits_to_double(0x7ff5555511111111); |
| double s2 = rawbits_to_double(0x7ff5555522222222); |
| double sa = rawbits_to_double(0x7ff55555aaaaaaaa); |
| double q1 = rawbits_to_double(0x7ffaaaaa11111111); |
| double q2 = rawbits_to_double(0x7ffaaaaa22222222); |
| double qa = rawbits_to_double(0x7ffaaaaaaaaaaaaa); |
| DCHECK(IsSignallingNaN(s1)); |
| DCHECK(IsSignallingNaN(s2)); |
| DCHECK(IsSignallingNaN(sa)); |
| DCHECK(IsQuietNaN(q1)); |
| DCHECK(IsQuietNaN(q2)); |
| DCHECK(IsQuietNaN(qa)); |
| |
| // The input NaNs after passing through ProcessNaN. |
| double s1_proc = rawbits_to_double(0x7ffd555511111111); |
| double s2_proc = rawbits_to_double(0x7ffd555522222222); |
| double sa_proc = rawbits_to_double(0x7ffd5555aaaaaaaa); |
| double q1_proc = q1; |
| double q2_proc = q2; |
| double qa_proc = qa; |
| DCHECK(IsQuietNaN(s1_proc)); |
| DCHECK(IsQuietNaN(s2_proc)); |
| DCHECK(IsQuietNaN(sa_proc)); |
| DCHECK(IsQuietNaN(q1_proc)); |
| DCHECK(IsQuietNaN(q2_proc)); |
| DCHECK(IsQuietNaN(qa_proc)); |
| |
| // Negated NaNs as it would be done on ARMv8 hardware. |
| double s1_proc_neg = rawbits_to_double(0xfffd555511111111); |
| double sa_proc_neg = rawbits_to_double(0xfffd5555aaaaaaaa); |
| double q1_proc_neg = rawbits_to_double(0xfffaaaaa11111111); |
| double qa_proc_neg = rawbits_to_double(0xfffaaaaaaaaaaaaa); |
| DCHECK(IsQuietNaN(s1_proc_neg)); |
| DCHECK(IsQuietNaN(sa_proc_neg)); |
| DCHECK(IsQuietNaN(q1_proc_neg)); |
| DCHECK(IsQuietNaN(qa_proc_neg)); |
| |
| // Quiet NaNs are propagated. |
| FmaddFmsubHelper(q1, 0, 0, q1_proc, q1_proc_neg, q1_proc_neg, q1_proc); |
| FmaddFmsubHelper(0, q2, 0, q2_proc, q2_proc, q2_proc, q2_proc); |
| FmaddFmsubHelper(0, 0, qa, qa_proc, qa_proc, qa_proc_neg, qa_proc_neg); |
| FmaddFmsubHelper(q1, q2, 0, q1_proc, q1_proc_neg, q1_proc_neg, q1_proc); |
| FmaddFmsubHelper(0, q2, qa, qa_proc, qa_proc, qa_proc_neg, qa_proc_neg); |
| FmaddFmsubHelper(q1, 0, qa, qa_proc, qa_proc, qa_proc_neg, qa_proc_neg); |
| FmaddFmsubHelper(q1, q2, qa, qa_proc, qa_proc, qa_proc_neg, qa_proc_neg); |
| |
| // Signalling NaNs are propagated, and made quiet. |
| FmaddFmsubHelper(s1, 0, 0, s1_proc, s1_proc_neg, s1_proc_neg, s1_proc); |
| FmaddFmsubHelper(0, s2, 0, s2_proc, s2_proc, s2_proc, s2_proc); |
| FmaddFmsubHelper(0, 0, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg); |
| FmaddFmsubHelper(s1, s2, 0, s1_proc, s1_proc_neg, s1_proc_neg, s1_proc); |
| FmaddFmsubHelper(0, s2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg); |
| FmaddFmsubHelper(s1, 0, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg); |
| FmaddFmsubHelper(s1, s2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg); |
| |
| // Signalling NaNs take precedence over quiet NaNs. |
| FmaddFmsubHelper(s1, q2, qa, s1_proc, s1_proc_neg, s1_proc_neg, s1_proc); |
| FmaddFmsubHelper(q1, s2, qa, s2_proc, s2_proc, s2_proc, s2_proc); |
| FmaddFmsubHelper(q1, q2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg); |
| FmaddFmsubHelper(s1, s2, qa, s1_proc, s1_proc_neg, s1_proc_neg, s1_proc); |
| FmaddFmsubHelper(q1, s2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg); |
| FmaddFmsubHelper(s1, q2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg); |
| FmaddFmsubHelper(s1, s2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg); |
| |
| // A NaN generated by the intermediate op1 * op2 overrides a quiet NaN in a. |
| FmaddFmsubHelper(0, kFP64PositiveInfinity, qa, |
| kFP64DefaultNaN, kFP64DefaultNaN, |
| kFP64DefaultNaN, kFP64DefaultNaN); |
| FmaddFmsubHelper(kFP64PositiveInfinity, 0, qa, |
| kFP64DefaultNaN, kFP64DefaultNaN, |
| kFP64DefaultNaN, kFP64DefaultNaN); |
| FmaddFmsubHelper(0, kFP64NegativeInfinity, qa, |
| kFP64DefaultNaN, kFP64DefaultNaN, |
| kFP64DefaultNaN, kFP64DefaultNaN); |
| FmaddFmsubHelper(kFP64NegativeInfinity, 0, qa, |
| kFP64DefaultNaN, kFP64DefaultNaN, |
| kFP64DefaultNaN, kFP64DefaultNaN); |
| } |
| |
| |
| TEST(fmadd_fmsub_float_nans) { |
| INIT_V8(); |
| // Make sure that NaN propagation works correctly. |
| float s1 = rawbits_to_float(0x7f951111); |
| float s2 = rawbits_to_float(0x7f952222); |
| float sa = rawbits_to_float(0x7f95aaaa); |
| float q1 = rawbits_to_float(0x7fea1111); |
| float q2 = rawbits_to_float(0x7fea2222); |
| float qa = rawbits_to_float(0x7feaaaaa); |
| DCHECK(IsSignallingNaN(s1)); |
| DCHECK(IsSignallingNaN(s2)); |
| DCHECK(IsSignallingNaN(sa)); |
| DCHECK(IsQuietNaN(q1)); |
| DCHECK(IsQuietNaN(q2)); |
| DCHECK(IsQuietNaN(qa)); |
| |
| // The input NaNs after passing through ProcessNaN. |
| float s1_proc = rawbits_to_float(0x7fd51111); |
| float s2_proc = rawbits_to_float(0x7fd52222); |
| float sa_proc = rawbits_to_float(0x7fd5aaaa); |
| float q1_proc = q1; |
| float q2_proc = q2; |
| float qa_proc = qa; |
| DCHECK(IsQuietNaN(s1_proc)); |
| DCHECK(IsQuietNaN(s2_proc)); |
| DCHECK(IsQuietNaN(sa_proc)); |
| DCHECK(IsQuietNaN(q1_proc)); |
| DCHECK(IsQuietNaN(q2_proc)); |
| DCHECK(IsQuietNaN(qa_proc)); |
| |
| // Negated NaNs as it would be done on ARMv8 hardware. |
| float s1_proc_neg = rawbits_to_float(0xffd51111); |
| float sa_proc_neg = rawbits_to_float(0xffd5aaaa); |
| float q1_proc_neg = rawbits_to_float(0xffea1111); |
| float qa_proc_neg = rawbits_to_float(0xffeaaaaa); |
| DCHECK(IsQuietNaN(s1_proc_neg)); |
| DCHECK(IsQuietNaN(sa_proc_neg)); |
| DCHECK(IsQuietNaN(q1_proc_neg)); |
| DCHECK(IsQuietNaN(qa_proc_neg)); |
| |
| // Quiet NaNs are propagated. |
| FmaddFmsubHelper(q1, 0, 0, q1_proc, q1_proc_neg, q1_proc_neg, q1_proc); |
| FmaddFmsubHelper(0, q2, 0, q2_proc, q2_proc, q2_proc, q2_proc); |
| FmaddFmsubHelper(0, 0, qa, qa_proc, qa_proc, qa_proc_neg, qa_proc_neg); |
| FmaddFmsubHelper(q1, q2, 0, q1_proc, q1_proc_neg, q1_proc_neg, q1_proc); |
| FmaddFmsubHelper(0, q2, qa, qa_proc, qa_proc, qa_proc_neg, qa_proc_neg); |
| FmaddFmsubHelper(q1, 0, qa, qa_proc, qa_proc, qa_proc_neg, qa_proc_neg); |
| FmaddFmsubHelper(q1, q2, qa, qa_proc, qa_proc, qa_proc_neg, qa_proc_neg); |
| |
| // Signalling NaNs are propagated, and made quiet. |
| FmaddFmsubHelper(s1, 0, 0, s1_proc, s1_proc_neg, s1_proc_neg, s1_proc); |
| FmaddFmsubHelper(0, s2, 0, s2_proc, s2_proc, s2_proc, s2_proc); |
| FmaddFmsubHelper(0, 0, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg); |
| FmaddFmsubHelper(s1, s2, 0, s1_proc, s1_proc_neg, s1_proc_neg, s1_proc); |
| FmaddFmsubHelper(0, s2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg); |
| FmaddFmsubHelper(s1, 0, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg); |
| FmaddFmsubHelper(s1, s2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg); |
| |
| // Signalling NaNs take precedence over quiet NaNs. |
| FmaddFmsubHelper(s1, q2, qa, s1_proc, s1_proc_neg, s1_proc_neg, s1_proc); |
| FmaddFmsubHelper(q1, s2, qa, s2_proc, s2_proc, s2_proc, s2_proc); |
| FmaddFmsubHelper(q1, q2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg); |
| FmaddFmsubHelper(s1, s2, qa, s1_proc, s1_proc_neg, s1_proc_neg, s1_proc); |
| FmaddFmsubHelper(q1, s2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg); |
| FmaddFmsubHelper(s1, q2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg); |
| FmaddFmsubHelper(s1, s2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg); |
| |
| // A NaN generated by the intermediate op1 * op2 overrides a quiet NaN in a. |
| FmaddFmsubHelper(0, kFP32PositiveInfinity, qa, |
| kFP32DefaultNaN, kFP32DefaultNaN, |
| kFP32DefaultNaN, kFP32DefaultNaN); |
| FmaddFmsubHelper(kFP32PositiveInfinity, 0, qa, |
| kFP32DefaultNaN, kFP32DefaultNaN, |
| kFP32DefaultNaN, kFP32DefaultNaN); |
| FmaddFmsubHelper(0, kFP32NegativeInfinity, qa, |
| kFP32DefaultNaN, kFP32DefaultNaN, |
| kFP32DefaultNaN, kFP32DefaultNaN); |
| FmaddFmsubHelper(kFP32NegativeInfinity, 0, qa, |
| kFP32DefaultNaN, kFP32DefaultNaN, |
| kFP32DefaultNaN, kFP32DefaultNaN); |
| } |
| |
| |
| TEST(fdiv) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s14, -0.0f); |
| __ Fmov(s15, kFP32PositiveInfinity); |
| __ Fmov(s16, kFP32NegativeInfinity); |
| __ Fmov(s17, 3.25f); |
| __ Fmov(s18, 2.0f); |
| __ Fmov(s19, 2.0f); |
| __ Fmov(s20, -2.0f); |
| |
| __ Fmov(d26, -0.0); |
| __ Fmov(d27, kFP64PositiveInfinity); |
| __ Fmov(d28, kFP64NegativeInfinity); |
| __ Fmov(d29, 0.0); |
| __ Fmov(d30, -2.0); |
| __ Fmov(d31, 2.25); |
| |
| __ Fdiv(s0, s17, s18); |
| __ Fdiv(s1, s18, s19); |
| __ Fdiv(s2, s14, s18); |
| __ Fdiv(s3, s18, s15); |
| __ Fdiv(s4, s18, s16); |
| __ Fdiv(s5, s15, s16); |
| __ Fdiv(s6, s14, s14); |
| |
| __ Fdiv(d7, d31, d30); |
| __ Fdiv(d8, d29, d31); |
| __ Fdiv(d9, d26, d31); |
| __ Fdiv(d10, d31, d27); |
| __ Fdiv(d11, d31, d28); |
| __ Fdiv(d12, d28, d27); |
| __ Fdiv(d13, d29, d29); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_FP32(1.625f, s0); |
| CHECK_EQUAL_FP32(1.0f, s1); |
| CHECK_EQUAL_FP32(-0.0f, s2); |
| CHECK_EQUAL_FP32(0.0f, s3); |
| CHECK_EQUAL_FP32(-0.0f, s4); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s5); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s6); |
| CHECK_EQUAL_FP64(-1.125, d7); |
| CHECK_EQUAL_FP64(0.0, d8); |
| CHECK_EQUAL_FP64(-0.0, d9); |
| CHECK_EQUAL_FP64(0.0, d10); |
| CHECK_EQUAL_FP64(-0.0, d11); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d12); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d13); |
| |
| TEARDOWN(); |
| } |
| |
| |
| static float MinMaxHelper(float n, |
| float m, |
| bool min, |
| float quiet_nan_substitute = 0.0) { |
| uint32_t raw_n = float_to_rawbits(n); |
| uint32_t raw_m = float_to_rawbits(m); |
| |
| if (std::isnan(n) && ((raw_n & kSQuietNanMask) == 0)) { |
| // n is signalling NaN. |
| return rawbits_to_float(raw_n | kSQuietNanMask); |
| } else if (std::isnan(m) && ((raw_m & kSQuietNanMask) == 0)) { |
| // m is signalling NaN. |
| return rawbits_to_float(raw_m | kSQuietNanMask); |
| } else if (quiet_nan_substitute == 0.0) { |
| if (std::isnan(n)) { |
| // n is quiet NaN. |
| return n; |
| } else if (std::isnan(m)) { |
| // m is quiet NaN. |
| return m; |
| } |
| } else { |
| // Substitute n or m if one is quiet, but not both. |
| if (std::isnan(n) && !std::isnan(m)) { |
| // n is quiet NaN: replace with substitute. |
| n = quiet_nan_substitute; |
| } else if (!std::isnan(n) && std::isnan(m)) { |
| // m is quiet NaN: replace with substitute. |
| m = quiet_nan_substitute; |
| } |
| } |
| |
| if ((n == 0.0) && (m == 0.0) && |
| (copysign(1.0, n) != copysign(1.0, m))) { |
| return min ? -0.0 : 0.0; |
| } |
| |
| return min ? fminf(n, m) : fmaxf(n, m); |
| } |
| |
| |
| static double MinMaxHelper(double n, |
| double m, |
| bool min, |
| double quiet_nan_substitute = 0.0) { |
| uint64_t raw_n = double_to_rawbits(n); |
| uint64_t raw_m = double_to_rawbits(m); |
| |
| if (std::isnan(n) && ((raw_n & kDQuietNanMask) == 0)) { |
| // n is signalling NaN. |
| return rawbits_to_double(raw_n | kDQuietNanMask); |
| } else if (std::isnan(m) && ((raw_m & kDQuietNanMask) == 0)) { |
| // m is signalling NaN. |
| return rawbits_to_double(raw_m | kDQuietNanMask); |
| } else if (quiet_nan_substitute == 0.0) { |
| if (std::isnan(n)) { |
| // n is quiet NaN. |
| return n; |
| } else if (std::isnan(m)) { |
| // m is quiet NaN. |
| return m; |
| } |
| } else { |
| // Substitute n or m if one is quiet, but not both. |
| if (std::isnan(n) && !std::isnan(m)) { |
| // n is quiet NaN: replace with substitute. |
| n = quiet_nan_substitute; |
| } else if (!std::isnan(n) && std::isnan(m)) { |
| // m is quiet NaN: replace with substitute. |
| m = quiet_nan_substitute; |
| } |
| } |
| |
| if ((n == 0.0) && (m == 0.0) && |
| (copysign(1.0, n) != copysign(1.0, m))) { |
| return min ? -0.0 : 0.0; |
| } |
| |
| return min ? fmin(n, m) : fmax(n, m); |
| } |
| |
| |
| static void FminFmaxDoubleHelper(double n, double m, double min, double max, |
| double minnm, double maxnm) { |
| SETUP(); |
| |
| START(); |
| __ Fmov(d0, n); |
| __ Fmov(d1, m); |
| __ Fmin(d28, d0, d1); |
| __ Fmax(d29, d0, d1); |
| __ Fminnm(d30, d0, d1); |
| __ Fmaxnm(d31, d0, d1); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_FP64(min, d28); |
| CHECK_EQUAL_FP64(max, d29); |
| CHECK_EQUAL_FP64(minnm, d30); |
| CHECK_EQUAL_FP64(maxnm, d31); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fmax_fmin_d) { |
| INIT_V8(); |
| // Use non-standard NaNs to check that the payload bits are preserved. |
| double snan = rawbits_to_double(0x7ff5555512345678); |
| double qnan = rawbits_to_double(0x7ffaaaaa87654321); |
| |
| double snan_processed = rawbits_to_double(0x7ffd555512345678); |
| double qnan_processed = qnan; |
| |
| DCHECK(IsSignallingNaN(snan)); |
| DCHECK(IsQuietNaN(qnan)); |
| DCHECK(IsQuietNaN(snan_processed)); |
| DCHECK(IsQuietNaN(qnan_processed)); |
| |
| // Bootstrap tests. |
| FminFmaxDoubleHelper(0, 0, 0, 0, 0, 0); |
| FminFmaxDoubleHelper(0, 1, 0, 1, 0, 1); |
| FminFmaxDoubleHelper(kFP64PositiveInfinity, kFP64NegativeInfinity, |
| kFP64NegativeInfinity, kFP64PositiveInfinity, |
| kFP64NegativeInfinity, kFP64PositiveInfinity); |
| FminFmaxDoubleHelper(snan, 0, |
| snan_processed, snan_processed, |
| snan_processed, snan_processed); |
| FminFmaxDoubleHelper(0, snan, |
| snan_processed, snan_processed, |
| snan_processed, snan_processed); |
| FminFmaxDoubleHelper(qnan, 0, |
| qnan_processed, qnan_processed, |
| 0, 0); |
| FminFmaxDoubleHelper(0, qnan, |
| qnan_processed, qnan_processed, |
| 0, 0); |
| FminFmaxDoubleHelper(qnan, snan, |
| snan_processed, snan_processed, |
| snan_processed, snan_processed); |
| FminFmaxDoubleHelper(snan, qnan, |
| snan_processed, snan_processed, |
| snan_processed, snan_processed); |
| |
| // Iterate over all combinations of inputs. |
| double inputs[] = { DBL_MAX, DBL_MIN, 1.0, 0.0, |
| -DBL_MAX, -DBL_MIN, -1.0, -0.0, |
| kFP64PositiveInfinity, kFP64NegativeInfinity, |
| kFP64QuietNaN, kFP64SignallingNaN }; |
| |
| const int count = sizeof(inputs) / sizeof(inputs[0]); |
| |
| for (int in = 0; in < count; in++) { |
| double n = inputs[in]; |
| for (int im = 0; im < count; im++) { |
| double m = inputs[im]; |
| FminFmaxDoubleHelper(n, m, |
| MinMaxHelper(n, m, true), |
| MinMaxHelper(n, m, false), |
| MinMaxHelper(n, m, true, kFP64PositiveInfinity), |
| MinMaxHelper(n, m, false, kFP64NegativeInfinity)); |
| } |
| } |
| } |
| |
| |
| static void FminFmaxFloatHelper(float n, float m, float min, float max, |
| float minnm, float maxnm) { |
| SETUP(); |
| |
| START(); |
| __ Fmov(s0, n); |
| __ Fmov(s1, m); |
| __ Fmin(s28, s0, s1); |
| __ Fmax(s29, s0, s1); |
| __ Fminnm(s30, s0, s1); |
| __ Fmaxnm(s31, s0, s1); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_FP32(min, s28); |
| CHECK_EQUAL_FP32(max, s29); |
| CHECK_EQUAL_FP32(minnm, s30); |
| CHECK_EQUAL_FP32(maxnm, s31); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fmax_fmin_s) { |
| INIT_V8(); |
| // Use non-standard NaNs to check that the payload bits are preserved. |
| float snan = rawbits_to_float(0x7f951234); |
| float qnan = rawbits_to_float(0x7fea8765); |
| |
| float snan_processed = rawbits_to_float(0x7fd51234); |
| float qnan_processed = qnan; |
| |
| DCHECK(IsSignallingNaN(snan)); |
| DCHECK(IsQuietNaN(qnan)); |
| DCHECK(IsQuietNaN(snan_processed)); |
| DCHECK(IsQuietNaN(qnan_processed)); |
| |
| // Bootstrap tests. |
| FminFmaxFloatHelper(0, 0, 0, 0, 0, 0); |
| FminFmaxFloatHelper(0, 1, 0, 1, 0, 1); |
| FminFmaxFloatHelper(kFP32PositiveInfinity, kFP32NegativeInfinity, |
| kFP32NegativeInfinity, kFP32PositiveInfinity, |
| kFP32NegativeInfinity, kFP32PositiveInfinity); |
| FminFmaxFloatHelper(snan, 0, |
| snan_processed, snan_processed, |
| snan_processed, snan_processed); |
| FminFmaxFloatHelper(0, snan, |
| snan_processed, snan_processed, |
| snan_processed, snan_processed); |
| FminFmaxFloatHelper(qnan, 0, |
| qnan_processed, qnan_processed, |
| 0, 0); |
| FminFmaxFloatHelper(0, qnan, |
| qnan_processed, qnan_processed, |
| 0, 0); |
| FminFmaxFloatHelper(qnan, snan, |
| snan_processed, snan_processed, |
| snan_processed, snan_processed); |
| FminFmaxFloatHelper(snan, qnan, |
| snan_processed, snan_processed, |
| snan_processed, snan_processed); |
| |
| // Iterate over all combinations of inputs. |
| float inputs[] = { FLT_MAX, FLT_MIN, 1.0, 0.0, |
| -FLT_MAX, -FLT_MIN, -1.0, -0.0, |
| kFP32PositiveInfinity, kFP32NegativeInfinity, |
| kFP32QuietNaN, kFP32SignallingNaN }; |
| |
| const int count = sizeof(inputs) / sizeof(inputs[0]); |
| |
| for (int in = 0; in < count; in++) { |
| float n = inputs[in]; |
| for (int im = 0; im < count; im++) { |
| float m = inputs[im]; |
| FminFmaxFloatHelper(n, m, |
| MinMaxHelper(n, m, true), |
| MinMaxHelper(n, m, false), |
| MinMaxHelper(n, m, true, kFP32PositiveInfinity), |
| MinMaxHelper(n, m, false, kFP32NegativeInfinity)); |
| } |
| } |
| } |
| |
| |
| TEST(fccmp) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s16, 0.0); |
| __ Fmov(s17, 0.5); |
| __ Fmov(d18, -0.5); |
| __ Fmov(d19, -1.0); |
| __ Mov(x20, 0); |
| |
| __ Cmp(x20, 0); |
| __ Fccmp(s16, s16, NoFlag, eq); |
| __ Mrs(x0, NZCV); |
| |
| __ Cmp(x20, 0); |
| __ Fccmp(s16, s16, VFlag, ne); |
| __ Mrs(x1, NZCV); |
| |
| __ Cmp(x20, 0); |
| __ Fccmp(s16, s17, CFlag, ge); |
| __ Mrs(x2, NZCV); |
| |
| __ Cmp(x20, 0); |
| __ Fccmp(s16, s17, CVFlag, lt); |
| __ Mrs(x3, NZCV); |
| |
| __ Cmp(x20, 0); |
| __ Fccmp(d18, d18, ZFlag, le); |
| __ Mrs(x4, NZCV); |
| |
| __ Cmp(x20, 0); |
| __ Fccmp(d18, d18, ZVFlag, gt); |
| __ Mrs(x5, NZCV); |
| |
| __ Cmp(x20, 0); |
| __ Fccmp(d18, d19, ZCVFlag, ls); |
| __ Mrs(x6, NZCV); |
| |
| __ Cmp(x20, 0); |
| __ Fccmp(d18, d19, NFlag, hi); |
| __ Mrs(x7, NZCV); |
| |
| __ fccmp(s16, s16, NFlag, al); |
| __ Mrs(x8, NZCV); |
| |
| __ fccmp(d18, d18, NFlag, nv); |
| __ Mrs(x9, NZCV); |
| |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_32(ZCFlag, w0); |
| CHECK_EQUAL_32(VFlag, w1); |
| CHECK_EQUAL_32(NFlag, w2); |
| CHECK_EQUAL_32(CVFlag, w3); |
| CHECK_EQUAL_32(ZCFlag, w4); |
| CHECK_EQUAL_32(ZVFlag, w5); |
| CHECK_EQUAL_32(CFlag, w6); |
| CHECK_EQUAL_32(NFlag, w7); |
| CHECK_EQUAL_32(ZCFlag, w8); |
| CHECK_EQUAL_32(ZCFlag, w9); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fcmp) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| |
| // Some of these tests require a floating-point scratch register assigned to |
| // the macro assembler, but most do not. |
| { |
| // We're going to mess around with the available scratch registers in this |
| // test. A UseScratchRegisterScope will make sure that they are restored to |
| // the default values once we're finished. |
| UseScratchRegisterScope temps(&masm); |
| masm.FPTmpList()->set_list(0); |
| |
| __ Fmov(s8, 0.0); |
| __ Fmov(s9, 0.5); |
| __ Mov(w18, 0x7f800001); // Single precision NaN. |
| __ Fmov(s18, w18); |
| |
| __ Fcmp(s8, s8); |
| __ Mrs(x0, NZCV); |
| __ Fcmp(s8, s9); |
| __ Mrs(x1, NZCV); |
| __ Fcmp(s9, s8); |
| __ Mrs(x2, NZCV); |
| __ Fcmp(s8, s18); |
| __ Mrs(x3, NZCV); |
| __ Fcmp(s18, s18); |
| __ Mrs(x4, NZCV); |
| __ Fcmp(s8, 0.0); |
| __ Mrs(x5, NZCV); |
| masm.FPTmpList()->set_list(d0.Bit()); |
| __ Fcmp(s8, 255.0); |
| masm.FPTmpList()->set_list(0); |
| __ Mrs(x6, NZCV); |
| |
| __ Fmov(d19, 0.0); |
| __ Fmov(d20, 0.5); |
| __ Mov(x21, 0x7ff0000000000001UL); // Double precision NaN. |
| __ Fmov(d21, x21); |
| |
| __ Fcmp(d19, d19); |
| __ Mrs(x10, NZCV); |
| __ Fcmp(d19, d20); |
| __ Mrs(x11, NZCV); |
| __ Fcmp(d20, d19); |
| __ Mrs(x12, NZCV); |
| __ Fcmp(d19, d21); |
| __ Mrs(x13, NZCV); |
| __ Fcmp(d21, d21); |
| __ Mrs(x14, NZCV); |
| __ Fcmp(d19, 0.0); |
| __ Mrs(x15, NZCV); |
| masm.FPTmpList()->set_list(d0.Bit()); |
| __ Fcmp(d19, 12.3456); |
| masm.FPTmpList()->set_list(0); |
| __ Mrs(x16, NZCV); |
| } |
| |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_32(ZCFlag, w0); |
| CHECK_EQUAL_32(NFlag, w1); |
| CHECK_EQUAL_32(CFlag, w2); |
| CHECK_EQUAL_32(CVFlag, w3); |
| CHECK_EQUAL_32(CVFlag, w4); |
| CHECK_EQUAL_32(ZCFlag, w5); |
| CHECK_EQUAL_32(NFlag, w6); |
| CHECK_EQUAL_32(ZCFlag, w10); |
| CHECK_EQUAL_32(NFlag, w11); |
| CHECK_EQUAL_32(CFlag, w12); |
| CHECK_EQUAL_32(CVFlag, w13); |
| CHECK_EQUAL_32(CVFlag, w14); |
| CHECK_EQUAL_32(ZCFlag, w15); |
| CHECK_EQUAL_32(NFlag, w16); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fcsel) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(x16, 0); |
| __ Fmov(s16, 1.0); |
| __ Fmov(s17, 2.0); |
| __ Fmov(d18, 3.0); |
| __ Fmov(d19, 4.0); |
| |
| __ Cmp(x16, 0); |
| __ Fcsel(s0, s16, s17, eq); |
| __ Fcsel(s1, s16, s17, ne); |
| __ Fcsel(d2, d18, d19, eq); |
| __ Fcsel(d3, d18, d19, ne); |
| __ fcsel(s4, s16, s17, al); |
| __ fcsel(d5, d18, d19, nv); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_FP32(1.0, s0); |
| CHECK_EQUAL_FP32(2.0, s1); |
| CHECK_EQUAL_FP64(3.0, d2); |
| CHECK_EQUAL_FP64(4.0, d3); |
| CHECK_EQUAL_FP32(1.0, s4); |
| CHECK_EQUAL_FP64(3.0, d5); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fneg) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s16, 1.0); |
| __ Fmov(s17, 0.0); |
| __ Fmov(s18, kFP32PositiveInfinity); |
| __ Fmov(d19, 1.0); |
| __ Fmov(d20, 0.0); |
| __ Fmov(d21, kFP64PositiveInfinity); |
| |
| __ Fneg(s0, s16); |
| __ Fneg(s1, s0); |
| __ Fneg(s2, s17); |
| __ Fneg(s3, s2); |
| __ Fneg(s4, s18); |
| __ Fneg(s5, s4); |
| __ Fneg(d6, d19); |
| __ Fneg(d7, d6); |
| __ Fneg(d8, d20); |
| __ Fneg(d9, d8); |
| __ Fneg(d10, d21); |
| __ Fneg(d11, d10); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_FP32(-1.0, s0); |
| CHECK_EQUAL_FP32(1.0, s1); |
| CHECK_EQUAL_FP32(-0.0, s2); |
| CHECK_EQUAL_FP32(0.0, s3); |
| CHECK_EQUAL_FP32(kFP32NegativeInfinity, s4); |
| CHECK_EQUAL_FP32(kFP32PositiveInfinity, s5); |
| CHECK_EQUAL_FP64(-1.0, d6); |
| CHECK_EQUAL_FP64(1.0, d7); |
| CHECK_EQUAL_FP64(-0.0, d8); |
| CHECK_EQUAL_FP64(0.0, d9); |
| CHECK_EQUAL_FP64(kFP64NegativeInfinity, d10); |
| CHECK_EQUAL_FP64(kFP64PositiveInfinity, d11); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fabs) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s16, -1.0); |
| __ Fmov(s17, -0.0); |
| __ Fmov(s18, kFP32NegativeInfinity); |
| __ Fmov(d19, -1.0); |
| __ Fmov(d20, -0.0); |
| __ Fmov(d21, kFP64NegativeInfinity); |
| |
| __ Fabs(s0, s16); |
| __ Fabs(s1, s0); |
| __ Fabs(s2, s17); |
| __ Fabs(s3, s18); |
| __ Fabs(d4, d19); |
| __ Fabs(d5, d4); |
| __ Fabs(d6, d20); |
| __ Fabs(d7, d21); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_FP32(1.0, s0); |
| CHECK_EQUAL_FP32(1.0, s1); |
| CHECK_EQUAL_FP32(0.0, s2); |
| CHECK_EQUAL_FP32(kFP32PositiveInfinity, s3); |
| CHECK_EQUAL_FP64(1.0, d4); |
| CHECK_EQUAL_FP64(1.0, d5); |
| CHECK_EQUAL_FP64(0.0, d6); |
| CHECK_EQUAL_FP64(kFP64PositiveInfinity, d7); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fsqrt) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s16, 0.0); |
| __ Fmov(s17, 1.0); |
| __ Fmov(s18, 0.25); |
| __ Fmov(s19, 65536.0); |
| __ Fmov(s20, -0.0); |
| __ Fmov(s21, kFP32PositiveInfinity); |
| __ Fmov(s22, -1.0); |
| __ Fmov(d23, 0.0); |
| __ Fmov(d24, 1.0); |
| __ Fmov(d25, 0.25); |
| __ Fmov(d26, 4294967296.0); |
| __ Fmov(d27, -0.0); |
| __ Fmov(d28, kFP64PositiveInfinity); |
| __ Fmov(d29, -1.0); |
| |
| __ Fsqrt(s0, s16); |
| __ Fsqrt(s1, s17); |
| __ Fsqrt(s2, s18); |
| __ Fsqrt(s3, s19); |
| __ Fsqrt(s4, s20); |
| __ Fsqrt(s5, s21); |
| __ Fsqrt(s6, s22); |
| __ Fsqrt(d7, d23); |
| __ Fsqrt(d8, d24); |
| __ Fsqrt(d9, d25); |
| __ Fsqrt(d10, d26); |
| __ Fsqrt(d11, d27); |
| __ Fsqrt(d12, d28); |
| __ Fsqrt(d13, d29); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_FP32(0.0, s0); |
| CHECK_EQUAL_FP32(1.0, s1); |
| CHECK_EQUAL_FP32(0.5, s2); |
| CHECK_EQUAL_FP32(256.0, s3); |
| CHECK_EQUAL_FP32(-0.0, s4); |
| CHECK_EQUAL_FP32(kFP32PositiveInfinity, s5); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s6); |
| CHECK_EQUAL_FP64(0.0, d7); |
| CHECK_EQUAL_FP64(1.0, d8); |
| CHECK_EQUAL_FP64(0.5, d9); |
| CHECK_EQUAL_FP64(65536.0, d10); |
| CHECK_EQUAL_FP64(-0.0, d11); |
| CHECK_EQUAL_FP64(kFP32PositiveInfinity, d12); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d13); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(frinta) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s16, 1.0); |
| __ Fmov(s17, 1.1); |
| __ Fmov(s18, 1.5); |
| __ Fmov(s19, 1.9); |
| __ Fmov(s20, 2.5); |
| __ Fmov(s21, -1.5); |
| __ Fmov(s22, -2.5); |
| __ Fmov(s23, kFP32PositiveInfinity); |
| __ Fmov(s24, kFP32NegativeInfinity); |
| __ Fmov(s25, 0.0); |
| __ Fmov(s26, -0.0); |
| __ Fmov(s27, -0.2); |
| |
| __ Frinta(s0, s16); |
| __ Frinta(s1, s17); |
| __ Frinta(s2, s18); |
| __ Frinta(s3, s19); |
| __ Frinta(s4, s20); |
| __ Frinta(s5, s21); |
| __ Frinta(s6, s22); |
| __ Frinta(s7, s23); |
| __ Frinta(s8, s24); |
| __ Frinta(s9, s25); |
| __ Frinta(s10, s26); |
| __ Frinta(s11, s27); |
| |
| __ Fmov(d16, 1.0); |
| __ Fmov(d17, 1.1); |
| __ Fmov(d18, 1.5); |
| __ Fmov(d19, 1.9); |
| __ Fmov(d20, 2.5); |
| __ Fmov(d21, -1.5); |
| __ Fmov(d22, -2.5); |
| __ Fmov(d23, kFP32PositiveInfinity); |
| __ Fmov(d24, kFP32NegativeInfinity); |
| __ Fmov(d25, 0.0); |
| __ Fmov(d26, -0.0); |
| __ Fmov(d27, -0.2); |
| |
| __ Frinta(d12, d16); |
| __ Frinta(d13, d17); |
| __ Frinta(d14, d18); |
| __ Frinta(d15, d19); |
| __ Frinta(d16, d20); |
| __ Frinta(d17, d21); |
| __ Frinta(d18, d22); |
| __ Frinta(d19, d23); |
| __ Frinta(d20, d24); |
| __ Frinta(d21, d25); |
| __ Frinta(d22, d26); |
| __ Frinta(d23, d27); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_FP32(1.0, s0); |
| CHECK_EQUAL_FP32(1.0, s1); |
| CHECK_EQUAL_FP32(2.0, s2); |
| CHECK_EQUAL_FP32(2.0, s3); |
| CHECK_EQUAL_FP32(3.0, s4); |
| CHECK_EQUAL_FP32(-2.0, s5); |
| CHECK_EQUAL_FP32(-3.0, s6); |
| CHECK_EQUAL_FP32(kFP32PositiveInfinity, s7); |
| CHECK_EQUAL_FP32(kFP32NegativeInfinity, s8); |
| CHECK_EQUAL_FP32(0.0, s9); |
| CHECK_EQUAL_FP32(-0.0, s10); |
| CHECK_EQUAL_FP32(-0.0, s11); |
| CHECK_EQUAL_FP64(1.0, d12); |
| CHECK_EQUAL_FP64(1.0, d13); |
| CHECK_EQUAL_FP64(2.0, d14); |
| CHECK_EQUAL_FP64(2.0, d15); |
| CHECK_EQUAL_FP64(3.0, d16); |
| CHECK_EQUAL_FP64(-2.0, d17); |
| CHECK_EQUAL_FP64(-3.0, d18); |
| CHECK_EQUAL_FP64(kFP64PositiveInfinity, d19); |
| CHECK_EQUAL_FP64(kFP64NegativeInfinity, d20); |
| CHECK_EQUAL_FP64(0.0, d21); |
| CHECK_EQUAL_FP64(-0.0, d22); |
| CHECK_EQUAL_FP64(-0.0, d23); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(frintm) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s16, 1.0); |
| __ Fmov(s17, 1.1); |
| __ Fmov(s18, 1.5); |
| __ Fmov(s19, 1.9); |
| __ Fmov(s20, 2.5); |
| __ Fmov(s21, -1.5); |
| __ Fmov(s22, -2.5); |
| __ Fmov(s23, kFP32PositiveInfinity); |
| __ Fmov(s24, kFP32NegativeInfinity); |
| __ Fmov(s25, 0.0); |
| __ Fmov(s26, -0.0); |
| __ Fmov(s27, -0.2); |
| |
| __ Frintm(s0, s16); |
| __ Frintm(s1, s17); |
| __ Frintm(s2, s18); |
| __ Frintm(s3, s19); |
| __ Frintm(s4, s20); |
| __ Frintm(s5, s21); |
| __ Frintm(s6, s22); |
| __ Frintm(s7, s23); |
| __ Frintm(s8, s24); |
| __ Frintm(s9, s25); |
| __ Frintm(s10, s26); |
| __ Frintm(s11, s27); |
| |
| __ Fmov(d16, 1.0); |
| __ Fmov(d17, 1.1); |
| __ Fmov(d18, 1.5); |
| __ Fmov(d19, 1.9); |
| __ Fmov(d20, 2.5); |
| __ Fmov(d21, -1.5); |
| __ Fmov(d22, -2.5); |
| __ Fmov(d23, kFP32PositiveInfinity); |
| __ Fmov(d24, kFP32NegativeInfinity); |
| __ Fmov(d25, 0.0); |
| __ Fmov(d26, -0.0); |
| __ Fmov(d27, -0.2); |
| |
| __ Frintm(d12, d16); |
| __ Frintm(d13, d17); |
| __ Frintm(d14, d18); |
| __ Frintm(d15, d19); |
| __ Frintm(d16, d20); |
| __ Frintm(d17, d21); |
| __ Frintm(d18, d22); |
| __ Frintm(d19, d23); |
| __ Frintm(d20, d24); |
| __ Frintm(d21, d25); |
| __ Frintm(d22, d26); |
| __ Frintm(d23, d27); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_FP32(1.0, s0); |
| CHECK_EQUAL_FP32(1.0, s1); |
| CHECK_EQUAL_FP32(1.0, s2); |
| CHECK_EQUAL_FP32(1.0, s3); |
| CHECK_EQUAL_FP32(2.0, s4); |
| CHECK_EQUAL_FP32(-2.0, s5); |
| CHECK_EQUAL_FP32(-3.0, s6); |
| CHECK_EQUAL_FP32(kFP32PositiveInfinity, s7); |
| CHECK_EQUAL_FP32(kFP32NegativeInfinity, s8); |
| CHECK_EQUAL_FP32(0.0, s9); |
| CHECK_EQUAL_FP32(-0.0, s10); |
| CHECK_EQUAL_FP32(-1.0, s11); |
| CHECK_EQUAL_FP64(1.0, d12); |
| CHECK_EQUAL_FP64(1.0, d13); |
| CHECK_EQUAL_FP64(1.0, d14); |
| CHECK_EQUAL_FP64(1.0, d15); |
| CHECK_EQUAL_FP64(2.0, d16); |
| CHECK_EQUAL_FP64(-2.0, d17); |
| CHECK_EQUAL_FP64(-3.0, d18); |
| CHECK_EQUAL_FP64(kFP64PositiveInfinity, d19); |
| CHECK_EQUAL_FP64(kFP64NegativeInfinity, d20); |
| CHECK_EQUAL_FP64(0.0, d21); |
| CHECK_EQUAL_FP64(-0.0, d22); |
| CHECK_EQUAL_FP64(-1.0, d23); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(frintn) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s16, 1.0); |
| __ Fmov(s17, 1.1); |
| __ Fmov(s18, 1.5); |
| __ Fmov(s19, 1.9); |
| __ Fmov(s20, 2.5); |
| __ Fmov(s21, -1.5); |
| __ Fmov(s22, -2.5); |
| __ Fmov(s23, kFP32PositiveInfinity); |
| __ Fmov(s24, kFP32NegativeInfinity); |
| __ Fmov(s25, 0.0); |
| __ Fmov(s26, -0.0); |
| __ Fmov(s27, -0.2); |
| |
| __ Frintn(s0, s16); |
| __ Frintn(s1, s17); |
| __ Frintn(s2, s18); |
| __ Frintn(s3, s19); |
| __ Frintn(s4, s20); |
| __ Frintn(s5, s21); |
| __ Frintn(s6, s22); |
| __ Frintn(s7, s23); |
| __ Frintn(s8, s24); |
| __ Frintn(s9, s25); |
| __ Frintn(s10, s26); |
| __ Frintn(s11, s27); |
| |
| __ Fmov(d16, 1.0); |
| __ Fmov(d17, 1.1); |
| __ Fmov(d18, 1.5); |
| __ Fmov(d19, 1.9); |
| __ Fmov(d20, 2.5); |
| __ Fmov(d21, -1.5); |
| __ Fmov(d22, -2.5); |
| __ Fmov(d23, kFP32PositiveInfinity); |
| __ Fmov(d24, kFP32NegativeInfinity); |
| __ Fmov(d25, 0.0); |
| __ Fmov(d26, -0.0); |
| __ Fmov(d27, -0.2); |
| |
| __ Frintn(d12, d16); |
| __ Frintn(d13, d17); |
| __ Frintn(d14, d18); |
| __ Frintn(d15, d19); |
| __ Frintn(d16, d20); |
| __ Frintn(d17, d21); |
| __ Frintn(d18, d22); |
| __ Frintn(d19, d23); |
| __ Frintn(d20, d24); |
| __ Frintn(d21, d25); |
| __ Frintn(d22, d26); |
| __ Frintn(d23, d27); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_FP32(1.0, s0); |
| CHECK_EQUAL_FP32(1.0, s1); |
| CHECK_EQUAL_FP32(2.0, s2); |
| CHECK_EQUAL_FP32(2.0, s3); |
| CHECK_EQUAL_FP32(2.0, s4); |
| CHECK_EQUAL_FP32(-2.0, s5); |
| CHECK_EQUAL_FP32(-2.0, s6); |
| CHECK_EQUAL_FP32(kFP32PositiveInfinity, s7); |
| CHECK_EQUAL_FP32(kFP32NegativeInfinity, s8); |
| CHECK_EQUAL_FP32(0.0, s9); |
| CHECK_EQUAL_FP32(-0.0, s10); |
| CHECK_EQUAL_FP32(-0.0, s11); |
| CHECK_EQUAL_FP64(1.0, d12); |
| CHECK_EQUAL_FP64(1.0, d13); |
| CHECK_EQUAL_FP64(2.0, d14); |
| CHECK_EQUAL_FP64(2.0, d15); |
| CHECK_EQUAL_FP64(2.0, d16); |
| CHECK_EQUAL_FP64(-2.0, d17); |
| CHECK_EQUAL_FP64(-2.0, d18); |
| CHECK_EQUAL_FP64(kFP64PositiveInfinity, d19); |
| CHECK_EQUAL_FP64(kFP64NegativeInfinity, d20); |
| CHECK_EQUAL_FP64(0.0, d21); |
| CHECK_EQUAL_FP64(-0.0, d22); |
| CHECK_EQUAL_FP64(-0.0, d23); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(frintz) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s16, 1.0); |
| __ Fmov(s17, 1.1); |
| __ Fmov(s18, 1.5); |
| __ Fmov(s19, 1.9); |
| __ Fmov(s20, 2.5); |
| __ Fmov(s21, -1.5); |
| __ Fmov(s22, -2.5); |
| __ Fmov(s23, kFP32PositiveInfinity); |
| __ Fmov(s24, kFP32NegativeInfinity); |
| __ Fmov(s25, 0.0); |
| __ Fmov(s26, -0.0); |
| |
| __ Frintz(s0, s16); |
| __ Frintz(s1, s17); |
| __ Frintz(s2, s18); |
| __ Frintz(s3, s19); |
| __ Frintz(s4, s20); |
| __ Frintz(s5, s21); |
| __ Frintz(s6, s22); |
| __ Frintz(s7, s23); |
| __ Frintz(s8, s24); |
| __ Frintz(s9, s25); |
| __ Frintz(s10, s26); |
| |
| __ Fmov(d16, 1.0); |
| __ Fmov(d17, 1.1); |
| __ Fmov(d18, 1.5); |
| __ Fmov(d19, 1.9); |
| __ Fmov(d20, 2.5); |
| __ Fmov(d21, -1.5); |
| __ Fmov(d22, -2.5); |
| __ Fmov(d23, kFP32PositiveInfinity); |
| __ Fmov(d24, kFP32NegativeInfinity); |
| __ Fmov(d25, 0.0); |
| __ Fmov(d26, -0.0); |
| |
| __ Frintz(d11, d16); |
| __ Frintz(d12, d17); |
| __ Frintz(d13, d18); |
| __ Frintz(d14, d19); |
| __ Frintz(d15, d20); |
| __ Frintz(d16, d21); |
| __ Frintz(d17, d22); |
| __ Frintz(d18, d23); |
| __ Frintz(d19, d24); |
| __ Frintz(d20, d25); |
| __ Frintz(d21, d26); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_FP32(1.0, s0); |
| CHECK_EQUAL_FP32(1.0, s1); |
| CHECK_EQUAL_FP32(1.0, s2); |
| CHECK_EQUAL_FP32(1.0, s3); |
| CHECK_EQUAL_FP32(2.0, s4); |
| CHECK_EQUAL_FP32(-1.0, s5); |
| CHECK_EQUAL_FP32(-2.0, s6); |
| CHECK_EQUAL_FP32(kFP32PositiveInfinity, s7); |
| CHECK_EQUAL_FP32(kFP32NegativeInfinity, s8); |
| CHECK_EQUAL_FP32(0.0, s9); |
| CHECK_EQUAL_FP32(-0.0, s10); |
| CHECK_EQUAL_FP64(1.0, d11); |
| CHECK_EQUAL_FP64(1.0, d12); |
| CHECK_EQUAL_FP64(1.0, d13); |
| CHECK_EQUAL_FP64(1.0, d14); |
| CHECK_EQUAL_FP64(2.0, d15); |
| CHECK_EQUAL_FP64(-1.0, d16); |
| CHECK_EQUAL_FP64(-2.0, d17); |
| CHECK_EQUAL_FP64(kFP64PositiveInfinity, d18); |
| CHECK_EQUAL_FP64(kFP64NegativeInfinity, d19); |
| CHECK_EQUAL_FP64(0.0, d20); |
| CHECK_EQUAL_FP64(-0.0, d21); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fcvt_ds) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s16, 1.0); |
| __ Fmov(s17, 1.1); |
| __ Fmov(s18, 1.5); |
| __ Fmov(s19, 1.9); |
| __ Fmov(s20, 2.5); |
| __ Fmov(s21, -1.5); |
| __ Fmov(s22, -2.5); |
| __ Fmov(s23, kFP32PositiveInfinity); |
| __ Fmov(s24, kFP32NegativeInfinity); |
| __ Fmov(s25, 0.0); |
| __ Fmov(s26, -0.0); |
| __ Fmov(s27, FLT_MAX); |
| __ Fmov(s28, FLT_MIN); |
| __ Fmov(s29, rawbits_to_float(0x7fc12345)); // Quiet NaN. |
| __ Fmov(s30, rawbits_to_float(0x7f812345)); // Signalling NaN. |
| |
| __ Fcvt(d0, s16); |
| __ Fcvt(d1, s17); |
| __ Fcvt(d2, s18); |
| __ Fcvt(d3, s19); |
| __ Fcvt(d4, s20); |
| __ Fcvt(d5, s21); |
| __ Fcvt(d6, s22); |
| __ Fcvt(d7, s23); |
| __ Fcvt(d8, s24); |
| __ Fcvt(d9, s25); |
| __ Fcvt(d10, s26); |
| __ Fcvt(d11, s27); |
| __ Fcvt(d12, s28); |
| __ Fcvt(d13, s29); |
| __ Fcvt(d14, s30); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_FP64(1.0f, d0); |
| CHECK_EQUAL_FP64(1.1f, d1); |
| CHECK_EQUAL_FP64(1.5f, d2); |
| CHECK_EQUAL_FP64(1.9f, d3); |
| CHECK_EQUAL_FP64(2.5f, d4); |
| CHECK_EQUAL_FP64(-1.5f, d5); |
| CHECK_EQUAL_FP64(-2.5f, d6); |
| CHECK_EQUAL_FP64(kFP64PositiveInfinity, d7); |
| CHECK_EQUAL_FP64(kFP64NegativeInfinity, d8); |
| CHECK_EQUAL_FP64(0.0f, d9); |
| CHECK_EQUAL_FP64(-0.0f, d10); |
| CHECK_EQUAL_FP64(FLT_MAX, d11); |
| CHECK_EQUAL_FP64(FLT_MIN, d12); |
| |
| // Check that the NaN payload is preserved according to ARM64 conversion |
| // rules: |
| // - The sign bit is preserved. |
| // - The top bit of the mantissa is forced to 1 (making it a quiet NaN). |
| // - The remaining mantissa bits are copied until they run out. |
| // - The low-order bits that haven't already been assigned are set to 0. |
| CHECK_EQUAL_FP64(rawbits_to_double(0x7ff82468a0000000), d13); |
| CHECK_EQUAL_FP64(rawbits_to_double(0x7ff82468a0000000), d14); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fcvt_sd) { |
| INIT_V8(); |
| // There are a huge number of corner-cases to check, so this test iterates |
| // through a list. The list is then negated and checked again (since the sign |
| // is irrelevant in ties-to-even rounding), so the list shouldn't include any |
| // negative values. |
| // |
| // Note that this test only checks ties-to-even rounding, because that is all |
| // that the simulator supports. |
| struct {double in; float expected;} test[] = { |
| // Check some simple conversions. |
| {0.0, 0.0f}, |
| {1.0, 1.0f}, |
| {1.5, 1.5f}, |
| {2.0, 2.0f}, |
| {FLT_MAX, FLT_MAX}, |
| // - The smallest normalized float. |
| {pow(2.0, -126), powf(2, -126)}, |
| // - Normal floats that need (ties-to-even) rounding. |
| // For normalized numbers: |
| // bit 29 (0x0000000020000000) is the lowest-order bit which will |
| // fit in the float's mantissa. |
| {rawbits_to_double(0x3ff0000000000000), rawbits_to_float(0x3f800000)}, |
| {rawbits_to_double(0x3ff0000000000001), rawbits_to_float(0x3f800000)}, |
| {rawbits_to_double(0x3ff0000010000000), rawbits_to_float(0x3f800000)}, |
| {rawbits_to_double(0x3ff0000010000001), rawbits_to_float(0x3f800001)}, |
| {rawbits_to_double(0x3ff0000020000000), rawbits_to_float(0x3f800001)}, |
| {rawbits_to_double(0x3ff0000020000001), rawbits_to_float(0x3f800001)}, |
| {rawbits_to_double(0x3ff0000030000000), rawbits_to_float(0x3f800002)}, |
| {rawbits_to_double(0x3ff0000030000001), rawbits_to_float(0x3f800002)}, |
| {rawbits_to_double(0x3ff0000040000000), rawbits_to_float(0x3f800002)}, |
| {rawbits_to_double(0x3ff0000040000001), rawbits_to_float(0x3f800002)}, |
| {rawbits_to_double(0x3ff0000050000000), rawbits_to_float(0x3f800002)}, |
| {rawbits_to_double(0x3ff0000050000001), rawbits_to_float(0x3f800003)}, |
| {rawbits_to_double(0x3ff0000060000000), rawbits_to_float(0x3f800003)}, |
| // - A mantissa that overflows into the exponent during rounding. |
| {rawbits_to_double(0x3feffffff0000000), rawbits_to_float(0x3f800000)}, |
| // - The largest double that rounds to a normal float. |
| {rawbits_to_double(0x47efffffefffffff), rawbits_to_float(0x7f7fffff)}, |
| |
| // Doubles that are too big for a float. |
| {kFP64PositiveInfinity, kFP32PositiveInfinity}, |
| {DBL_MAX, kFP32PositiveInfinity}, |
| // - The smallest exponent that's too big for a float. |
| {pow(2.0, 128), kFP32PositiveInfinity}, |
| // - This exponent is in range, but the value rounds to infinity. |
| {rawbits_to_double(0x47effffff0000000), kFP32PositiveInfinity}, |
| |
| // Doubles that are too small for a float. |
| // - The smallest (subnormal) double. |
| {DBL_MIN, 0.0}, |
| // - The largest double which is too small for a subnormal float. |
| {rawbits_to_double(0x3690000000000000), rawbits_to_float(0x00000000)}, |
| |
| // Normal doubles that become subnormal floats. |
| // - The largest subnormal float. |
| {rawbits_to_double(0x380fffffc0000000), rawbits_to_float(0x007fffff)}, |
| // - The smallest subnormal float. |
| {rawbits_to_double(0x36a0000000000000), rawbits_to_float(0x00000001)}, |
| // - Subnormal floats that need (ties-to-even) rounding. |
| // For these subnormals: |
| // bit 34 (0x0000000400000000) is the lowest-order bit which will |
| // fit in the float's mantissa. |
| {rawbits_to_double(0x37c159e000000000), rawbits_to_float(0x00045678)}, |
| {rawbits_to_double(0x37c159e000000001), rawbits_to_float(0x00045678)}, |
| {rawbits_to_double(0x37c159e200000000), rawbits_to_float(0x00045678)}, |
| {rawbits_to_double(0x37c159e200000001), rawbits_to_float(0x00045679)}, |
| {rawbits_to_double(0x37c159e400000000), rawbits_to_float(0x00045679)}, |
| {rawbits_to_double(0x37c159e400000001), rawbits_to_float(0x00045679)}, |
| {rawbits_to_double(0x37c159e600000000), rawbits_to_float(0x0004567a)}, |
| {rawbits_to_double(0x37c159e600000001), rawbits_to_float(0x0004567a)}, |
| {rawbits_to_double(0x37c159e800000000), rawbits_to_float(0x0004567a)}, |
| {rawbits_to_double(0x37c159e800000001), rawbits_to_float(0x0004567a)}, |
| {rawbits_to_double(0x37c159ea00000000), rawbits_to_float(0x0004567a)}, |
| {rawbits_to_double(0x37c159ea00000001), rawbits_to_float(0x0004567b)}, |
| {rawbits_to_double(0x37c159ec00000000), rawbits_to_float(0x0004567b)}, |
| // - The smallest double which rounds up to become a subnormal float. |
| {rawbits_to_double(0x3690000000000001), rawbits_to_float(0x00000001)}, |
| |
| // Check NaN payload preservation. |
| {rawbits_to_double(0x7ff82468a0000000), rawbits_to_float(0x7fc12345)}, |
| {rawbits_to_double(0x7ff82468bfffffff), rawbits_to_float(0x7fc12345)}, |
| // - Signalling NaNs become quiet NaNs. |
| {rawbits_to_double(0x7ff02468a0000000), rawbits_to_float(0x7fc12345)}, |
| {rawbits_to_double(0x7ff02468bfffffff), rawbits_to_float(0x7fc12345)}, |
| {rawbits_to_double(0x7ff000001fffffff), rawbits_to_float(0x7fc00000)}, |
| }; |
| int count = sizeof(test) / sizeof(test[0]); |
| |
| for (int i = 0; i < count; i++) { |
| double in = test[i].in; |
| float expected = test[i].expected; |
| |
| // We only expect positive input. |
| DCHECK(std::signbit(in) == 0); |
| DCHECK(std::signbit(expected) == 0); |
| |
| SETUP(); |
| START(); |
| |
| __ Fmov(d10, in); |
| __ Fcvt(s20, d10); |
| |
| __ Fmov(d11, -in); |
| __ Fcvt(s21, d11); |
| |
| END(); |
| RUN(); |
| CHECK_EQUAL_FP32(expected, s20); |
| CHECK_EQUAL_FP32(-expected, s21); |
| TEARDOWN(); |
| } |
| } |
| |
| |
| TEST(fcvtas) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s0, 1.0); |
| __ Fmov(s1, 1.1); |
| __ Fmov(s2, 2.5); |
| __ Fmov(s3, -2.5); |
| __ Fmov(s4, kFP32PositiveInfinity); |
| __ Fmov(s5, kFP32NegativeInfinity); |
| __ Fmov(s6, 0x7fffff80); // Largest float < INT32_MAX. |
| __ Fneg(s7, s6); // Smallest float > INT32_MIN. |
| __ Fmov(d8, 1.0); |
| __ Fmov(d9, 1.1); |
| __ Fmov(d10, 2.5); |
| __ Fmov(d11, -2.5); |
| __ Fmov(d12, kFP64PositiveInfinity); |
| __ Fmov(d13, kFP64NegativeInfinity); |
| __ Fmov(d14, kWMaxInt - 1); |
| __ Fmov(d15, kWMinInt + 1); |
| __ Fmov(s17, 1.1); |
| __ Fmov(s18, 2.5); |
| __ Fmov(s19, -2.5); |
| __ Fmov(s20, kFP32PositiveInfinity); |
| __ Fmov(s21, kFP32NegativeInfinity); |
| __ Fmov(s22, 0x7fffff8000000000UL); // Largest float < INT64_MAX. |
| __ Fneg(s23, s22); // Smallest float > INT64_MIN. |
| __ Fmov(d24, 1.1); |
| __ Fmov(d25, 2.5); |
| __ Fmov(d26, -2.5); |
| __ Fmov(d27, kFP64PositiveInfinity); |
| __ Fmov(d28, kFP64NegativeInfinity); |
| __ Fmov(d29, 0x7ffffffffffffc00UL); // Largest double < INT64_MAX. |
| __ Fneg(d30, d29); // Smallest double > INT64_MIN. |
| |
| __ Fcvtas(w0, s0); |
| __ Fcvtas(w1, s1); |
| __ Fcvtas(w2, s2); |
| __ Fcvtas(w3, s3); |
| __ Fcvtas(w4, s4); |
| __ Fcvtas(w5, s5); |
| __ Fcvtas(w6, s6); |
| __ Fcvtas(w7, s7); |
| __ Fcvtas(w8, d8); |
| __ Fcvtas(w9, d9); |
| __ Fcvtas(w10, d10); |
| __ Fcvtas(w11, d11); |
| __ Fcvtas(w12, d12); |
| __ Fcvtas(w13, d13); |
| __ Fcvtas(w14, d14); |
| __ Fcvtas(w15, d15); |
| __ Fcvtas(x17, s17); |
| __ Fcvtas(x18, s18); |
| __ Fcvtas(x19, s19); |
| __ Fcvtas(x20, s20); |
| __ Fcvtas(x21, s21); |
| __ Fcvtas(x22, s22); |
| __ Fcvtas(x23, s23); |
| __ Fcvtas(x24, d24); |
| __ Fcvtas(x25, d25); |
| __ Fcvtas(x26, d26); |
| __ Fcvtas(x27, d27); |
| __ Fcvtas(x28, d28); |
| __ Fcvtas(x29, d29); |
| __ Fcvtas(x30, d30); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(1, x0); |
| CHECK_EQUAL_64(1, x1); |
| CHECK_EQUAL_64(3, x2); |
| CHECK_EQUAL_64(0xfffffffd, x3); |
| CHECK_EQUAL_64(0x7fffffff, x4); |
| CHECK_EQUAL_64(0x80000000, x5); |
| CHECK_EQUAL_64(0x7fffff80, x6); |
| CHECK_EQUAL_64(0x80000080, x7); |
| CHECK_EQUAL_64(1, x8); |
| CHECK_EQUAL_64(1, x9); |
| CHECK_EQUAL_64(3, x10); |
| CHECK_EQUAL_64(0xfffffffd, x11); |
| CHECK_EQUAL_64(0x7fffffff, x12); |
| CHECK_EQUAL_64(0x80000000, x13); |
| CHECK_EQUAL_64(0x7ffffffe, x14); |
| CHECK_EQUAL_64(0x80000001, x15); |
| CHECK_EQUAL_64(1, x17); |
| CHECK_EQUAL_64(3, x18); |
| CHECK_EQUAL_64(0xfffffffffffffffdUL, x19); |
| CHECK_EQUAL_64(0x7fffffffffffffffUL, x20); |
| CHECK_EQUAL_64(0x8000000000000000UL, x21); |
| CHECK_EQUAL_64(0x7fffff8000000000UL, x22); |
| CHECK_EQUAL_64(0x8000008000000000UL, x23); |
| CHECK_EQUAL_64(1, x24); |
| CHECK_EQUAL_64(3, x25); |
| CHECK_EQUAL_64(0xfffffffffffffffdUL, x26); |
| CHECK_EQUAL_64(0x7fffffffffffffffUL, x27); |
| CHECK_EQUAL_64(0x8000000000000000UL, x28); |
| CHECK_EQUAL_64(0x7ffffffffffffc00UL, x29); |
| CHECK_EQUAL_64(0x8000000000000400UL, x30); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fcvtau) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s0, 1.0); |
| __ Fmov(s1, 1.1); |
| __ Fmov(s2, 2.5); |
| __ Fmov(s3, -2.5); |
| __ Fmov(s4, kFP32PositiveInfinity); |
| __ Fmov(s5, kFP32NegativeInfinity); |
| __ Fmov(s6, 0xffffff00); // Largest float < UINT32_MAX. |
| __ Fmov(d8, 1.0); |
| __ Fmov(d9, 1.1); |
| __ Fmov(d10, 2.5); |
| __ Fmov(d11, -2.5); |
| __ Fmov(d12, kFP64PositiveInfinity); |
| __ Fmov(d13, kFP64NegativeInfinity); |
| __ Fmov(d14, 0xfffffffe); |
| __ Fmov(s16, 1.0); |
| __ Fmov(s17, 1.1); |
| __ Fmov(s18, 2.5); |
| __ Fmov(s19, -2.5); |
| __ Fmov(s20, kFP32PositiveInfinity); |
| __ Fmov(s21, kFP32NegativeInfinity); |
| __ Fmov(s22, 0xffffff0000000000UL); // Largest float < UINT64_MAX. |
| __ Fmov(d24, 1.1); |
| __ Fmov(d25, 2.5); |
| __ Fmov(d26, -2.5); |
| __ Fmov(d27, kFP64PositiveInfinity); |
| __ Fmov(d28, kFP64NegativeInfinity); |
| __ Fmov(d29, 0xfffffffffffff800UL); // Largest double < UINT64_MAX. |
| __ Fmov(s30, 0x100000000UL); |
| |
| __ Fcvtau(w0, s0); |
| __ Fcvtau(w1, s1); |
| __ Fcvtau(w2, s2); |
| __ Fcvtau(w3, s3); |
| __ Fcvtau(w4, s4); |
| __ Fcvtau(w5, s5); |
| __ Fcvtau(w6, s6); |
| __ Fcvtau(w8, d8); |
| __ Fcvtau(w9, d9); |
| __ Fcvtau(w10, d10); |
| __ Fcvtau(w11, d11); |
| __ Fcvtau(w12, d12); |
| __ Fcvtau(w13, d13); |
| __ Fcvtau(w14, d14); |
| __ Fcvtau(w15, d15); |
| __ Fcvtau(x16, s16); |
| __ Fcvtau(x17, s17); |
| __ Fcvtau(x18, s18); |
| __ Fcvtau(x19, s19); |
| __ Fcvtau(x20, s20); |
| __ Fcvtau(x21, s21); |
| __ Fcvtau(x22, s22); |
| __ Fcvtau(x24, d24); |
| __ Fcvtau(x25, d25); |
| __ Fcvtau(x26, d26); |
| __ Fcvtau(x27, d27); |
| __ Fcvtau(x28, d28); |
| __ Fcvtau(x29, d29); |
| __ Fcvtau(w30, s30); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(1, x0); |
| CHECK_EQUAL_64(1, x1); |
| CHECK_EQUAL_64(3, x2); |
| CHECK_EQUAL_64(0, x3); |
| CHECK_EQUAL_64(0xffffffff, x4); |
| CHECK_EQUAL_64(0, x5); |
| CHECK_EQUAL_64(0xffffff00, x6); |
| CHECK_EQUAL_64(1, x8); |
| CHECK_EQUAL_64(1, x9); |
| CHECK_EQUAL_64(3, x10); |
| CHECK_EQUAL_64(0, x11); |
| CHECK_EQUAL_64(0xffffffff, x12); |
| CHECK_EQUAL_64(0, x13); |
| CHECK_EQUAL_64(0xfffffffe, x14); |
| CHECK_EQUAL_64(1, x16); |
| CHECK_EQUAL_64(1, x17); |
| CHECK_EQUAL_64(3, x18); |
| CHECK_EQUAL_64(0, x19); |
| CHECK_EQUAL_64(0xffffffffffffffffUL, x20); |
| CHECK_EQUAL_64(0, x21); |
| CHECK_EQUAL_64(0xffffff0000000000UL, x22); |
| CHECK_EQUAL_64(1, x24); |
| CHECK_EQUAL_64(3, x25); |
| CHECK_EQUAL_64(0, x26); |
| CHECK_EQUAL_64(0xffffffffffffffffUL, x27); |
| CHECK_EQUAL_64(0, x28); |
| CHECK_EQUAL_64(0xfffffffffffff800UL, x29); |
| CHECK_EQUAL_64(0xffffffff, x30); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fcvtms) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s0, 1.0); |
| __ Fmov(s1, 1.1); |
| __ Fmov(s2, 1.5); |
| __ Fmov(s3, -1.5); |
| __ Fmov(s4, kFP32PositiveInfinity); |
| __ Fmov(s5, kFP32NegativeInfinity); |
| __ Fmov(s6, 0x7fffff80); // Largest float < INT32_MAX. |
| __ Fneg(s7, s6); // Smallest float > INT32_MIN. |
| __ Fmov(d8, 1.0); |
| __ Fmov(d9, 1.1); |
| __ Fmov(d10, 1.5); |
| __ Fmov(d11, -1.5); |
| __ Fmov(d12, kFP64PositiveInfinity); |
| __ Fmov(d13, kFP64NegativeInfinity); |
| __ Fmov(d14, kWMaxInt - 1); |
| __ Fmov(d15, kWMinInt + 1); |
| __ Fmov(s17, 1.1); |
| __ Fmov(s18, 1.5); |
| __ Fmov(s19, -1.5); |
| __ Fmov(s20, kFP32PositiveInfinity); |
| __ Fmov(s21, kFP32NegativeInfinity); |
| __ Fmov(s22, 0x7fffff8000000000UL); // Largest float < INT64_MAX. |
| __ Fneg(s23, s22); // Smallest float > INT64_MIN. |
| __ Fmov(d24, 1.1); |
| __ Fmov(d25, 1.5); |
| __ Fmov(d26, -1.5); |
| __ Fmov(d27, kFP64PositiveInfinity); |
| __ Fmov(d28, kFP64NegativeInfinity); |
| __ Fmov(d29, 0x7ffffffffffffc00UL); // Largest double < INT64_MAX. |
| __ Fneg(d30, d29); // Smallest double > INT64_MIN. |
| |
| __ Fcvtms(w0, s0); |
| __ Fcvtms(w1, s1); |
| __ Fcvtms(w2, s2); |
| __ Fcvtms(w3, s3); |
| __ Fcvtms(w4, s4); |
| __ Fcvtms(w5, s5); |
| __ Fcvtms(w6, s6); |
| __ Fcvtms(w7, s7); |
| __ Fcvtms(w8, d8); |
| __ Fcvtms(w9, d9); |
| __ Fcvtms(w10, d10); |
| __ Fcvtms(w11, d11); |
| __ Fcvtms(w12, d12); |
| __ Fcvtms(w13, d13); |
| __ Fcvtms(w14, d14); |
| __ Fcvtms(w15, d15); |
| __ Fcvtms(x17, s17); |
| __ Fcvtms(x18, s18); |
| __ Fcvtms(x19, s19); |
| __ Fcvtms(x20, s20); |
| __ Fcvtms(x21, s21); |
| __ Fcvtms(x22, s22); |
| __ Fcvtms(x23, s23); |
| __ Fcvtms(x24, d24); |
| __ Fcvtms(x25, d25); |
| __ Fcvtms(x26, d26); |
| __ Fcvtms(x27, d27); |
| __ Fcvtms(x28, d28); |
| __ Fcvtms(x29, d29); |
| __ Fcvtms(x30, d30); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(1, x0); |
| CHECK_EQUAL_64(1, x1); |
| CHECK_EQUAL_64(1, x2); |
| CHECK_EQUAL_64(0xfffffffe, x3); |
| CHECK_EQUAL_64(0x7fffffff, x4); |
| CHECK_EQUAL_64(0x80000000, x5); |
| CHECK_EQUAL_64(0x7fffff80, x6); |
| CHECK_EQUAL_64(0x80000080, x7); |
| CHECK_EQUAL_64(1, x8); |
| CHECK_EQUAL_64(1, x9); |
| CHECK_EQUAL_64(1, x10); |
| CHECK_EQUAL_64(0xfffffffe, x11); |
| CHECK_EQUAL_64(0x7fffffff, x12); |
| CHECK_EQUAL_64(0x80000000, x13); |
| CHECK_EQUAL_64(0x7ffffffe, x14); |
| CHECK_EQUAL_64(0x80000001, x15); |
| CHECK_EQUAL_64(1, x17); |
| CHECK_EQUAL_64(1, x18); |
| CHECK_EQUAL_64(0xfffffffffffffffeUL, x19); |
| CHECK_EQUAL_64(0x7fffffffffffffffUL, x20); |
| CHECK_EQUAL_64(0x8000000000000000UL, x21); |
| CHECK_EQUAL_64(0x7fffff8000000000UL, x22); |
| CHECK_EQUAL_64(0x8000008000000000UL, x23); |
| CHECK_EQUAL_64(1, x24); |
| CHECK_EQUAL_64(1, x25); |
| CHECK_EQUAL_64(0xfffffffffffffffeUL, x26); |
| CHECK_EQUAL_64(0x7fffffffffffffffUL, x27); |
| CHECK_EQUAL_64(0x8000000000000000UL, x28); |
| CHECK_EQUAL_64(0x7ffffffffffffc00UL, x29); |
| CHECK_EQUAL_64(0x8000000000000400UL, x30); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fcvtmu) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s0, 1.0); |
| __ Fmov(s1, 1.1); |
| __ Fmov(s2, 1.5); |
| __ Fmov(s3, -1.5); |
| __ Fmov(s4, kFP32PositiveInfinity); |
| __ Fmov(s5, kFP32NegativeInfinity); |
| __ Fmov(s6, 0x7fffff80); // Largest float < INT32_MAX. |
| __ Fneg(s7, s6); // Smallest float > INT32_MIN. |
| __ Fmov(d8, 1.0); |
| __ Fmov(d9, 1.1); |
| __ Fmov(d10, 1.5); |
| __ Fmov(d11, -1.5); |
| __ Fmov(d12, kFP64PositiveInfinity); |
| __ Fmov(d13, kFP64NegativeInfinity); |
| __ Fmov(d14, kWMaxInt - 1); |
| __ Fmov(d15, kWMinInt + 1); |
| __ Fmov(s17, 1.1); |
| __ Fmov(s18, 1.5); |
| __ Fmov(s19, -1.5); |
| __ Fmov(s20, kFP32PositiveInfinity); |
| __ Fmov(s21, kFP32NegativeInfinity); |
| __ Fmov(s22, 0x7fffff8000000000UL); // Largest float < INT64_MAX. |
| __ Fneg(s23, s22); // Smallest float > INT64_MIN. |
| __ Fmov(d24, 1.1); |
| __ Fmov(d25, 1.5); |
| __ Fmov(d26, -1.5); |
| __ Fmov(d27, kFP64PositiveInfinity); |
| __ Fmov(d28, kFP64NegativeInfinity); |
| __ Fmov(d29, 0x7ffffffffffffc00UL); // Largest double < INT64_MAX. |
| __ Fneg(d30, d29); // Smallest double > INT64_MIN. |
| |
| __ Fcvtmu(w0, s0); |
| __ Fcvtmu(w1, s1); |
| __ Fcvtmu(w2, s2); |
| __ Fcvtmu(w3, s3); |
| __ Fcvtmu(w4, s4); |
| __ Fcvtmu(w5, s5); |
| __ Fcvtmu(w6, s6); |
| __ Fcvtmu(w7, s7); |
| __ Fcvtmu(w8, d8); |
| __ Fcvtmu(w9, d9); |
| __ Fcvtmu(w10, d10); |
| __ Fcvtmu(w11, d11); |
| __ Fcvtmu(w12, d12); |
| __ Fcvtmu(w13, d13); |
| __ Fcvtmu(w14, d14); |
| __ Fcvtmu(x17, s17); |
| __ Fcvtmu(x18, s18); |
| __ Fcvtmu(x19, s19); |
| __ Fcvtmu(x20, s20); |
| __ Fcvtmu(x21, s21); |
| __ Fcvtmu(x22, s22); |
| __ Fcvtmu(x23, s23); |
| __ Fcvtmu(x24, d24); |
| __ Fcvtmu(x25, d25); |
| __ Fcvtmu(x26, d26); |
| __ Fcvtmu(x27, d27); |
| __ Fcvtmu(x28, d28); |
| __ Fcvtmu(x29, d29); |
| __ Fcvtmu(x30, d30); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(1, x0); |
| CHECK_EQUAL_64(1, x1); |
| CHECK_EQUAL_64(1, x2); |
| CHECK_EQUAL_64(0, x3); |
| CHECK_EQUAL_64(0xffffffff, x4); |
| CHECK_EQUAL_64(0, x5); |
| CHECK_EQUAL_64(0x7fffff80, x6); |
| CHECK_EQUAL_64(0, x7); |
| CHECK_EQUAL_64(1, x8); |
| CHECK_EQUAL_64(1, x9); |
| CHECK_EQUAL_64(1, x10); |
| CHECK_EQUAL_64(0, x11); |
| CHECK_EQUAL_64(0xffffffff, x12); |
| CHECK_EQUAL_64(0, x13); |
| CHECK_EQUAL_64(0x7ffffffe, x14); |
| CHECK_EQUAL_64(1, x17); |
| CHECK_EQUAL_64(1, x18); |
| CHECK_EQUAL_64(0x0UL, x19); |
| CHECK_EQUAL_64(0xffffffffffffffffUL, x20); |
| CHECK_EQUAL_64(0x0UL, x21); |
| CHECK_EQUAL_64(0x7fffff8000000000UL, x22); |
| CHECK_EQUAL_64(0x0UL, x23); |
| CHECK_EQUAL_64(1, x24); |
| CHECK_EQUAL_64(1, x25); |
| CHECK_EQUAL_64(0x0UL, x26); |
| CHECK_EQUAL_64(0xffffffffffffffffUL, x27); |
| CHECK_EQUAL_64(0x0UL, x28); |
| CHECK_EQUAL_64(0x7ffffffffffffc00UL, x29); |
| CHECK_EQUAL_64(0x0UL, x30); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fcvtns) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s0, 1.0); |
| __ Fmov(s1, 1.1); |
| __ Fmov(s2, 1.5); |
| __ Fmov(s3, -1.5); |
| __ Fmov(s4, kFP32PositiveInfinity); |
| __ Fmov(s5, kFP32NegativeInfinity); |
| __ Fmov(s6, 0x7fffff80); // Largest float < INT32_MAX. |
| __ Fneg(s7, s6); // Smallest float > INT32_MIN. |
| __ Fmov(d8, 1.0); |
| __ Fmov(d9, 1.1); |
| __ Fmov(d10, 1.5); |
| __ Fmov(d11, -1.5); |
| __ Fmov(d12, kFP64PositiveInfinity); |
| __ Fmov(d13, kFP64NegativeInfinity); |
| __ Fmov(d14, kWMaxInt - 1); |
| __ Fmov(d15, kWMinInt + 1); |
| __ Fmov(s17, 1.1); |
| __ Fmov(s18, 1.5); |
| __ Fmov(s19, -1.5); |
| __ Fmov(s20, kFP32PositiveInfinity); |
| __ Fmov(s21, kFP32NegativeInfinity); |
| __ Fmov(s22, 0x7fffff8000000000UL); // Largest float < INT64_MAX. |
| __ Fneg(s23, s22); // Smallest float > INT64_MIN. |
| __ Fmov(d24, 1.1); |
| __ Fmov(d25, 1.5); |
| __ Fmov(d26, -1.5); |
| __ Fmov(d27, kFP64PositiveInfinity); |
| __ Fmov(d28, kFP64NegativeInfinity); |
| __ Fmov(d29, 0x7ffffffffffffc00UL); // Largest double < INT64_MAX. |
| __ Fneg(d30, d29); // Smallest double > INT64_MIN. |
| |
| __ Fcvtns(w0, s0); |
| __ Fcvtns(w1, s1); |
| __ Fcvtns(w2, s2); |
| __ Fcvtns(w3, s3); |
| __ Fcvtns(w4, s4); |
| __ Fcvtns(w5, s5); |
| __ Fcvtns(w6, s6); |
| __ Fcvtns(w7, s7); |
| __ Fcvtns(w8, d8); |
| __ Fcvtns(w9, d9); |
| __ Fcvtns(w10, d10); |
| __ Fcvtns(w11, d11); |
| __ Fcvtns(w12, d12); |
| __ Fcvtns(w13, d13); |
| __ Fcvtns(w14, d14); |
| __ Fcvtns(w15, d15); |
| __ Fcvtns(x17, s17); |
| __ Fcvtns(x18, s18); |
| __ Fcvtns(x19, s19); |
| __ Fcvtns(x20, s20); |
| __ Fcvtns(x21, s21); |
| __ Fcvtns(x22, s22); |
| __ Fcvtns(x23, s23); |
| __ Fcvtns(x24, d24); |
| __ Fcvtns(x25, d25); |
| __ Fcvtns(x26, d26); |
| __ Fcvtns(x27, d27); |
| // __ Fcvtns(x28, d28); |
| __ Fcvtns(x29, d29); |
| __ Fcvtns(x30, d30); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(1, x0); |
| CHECK_EQUAL_64(1, x1); |
| CHECK_EQUAL_64(2, x2); |
| CHECK_EQUAL_64(0xfffffffe, x3); |
| CHECK_EQUAL_64(0x7fffffff, x4); |
| CHECK_EQUAL_64(0x80000000, x5); |
| CHECK_EQUAL_64(0x7fffff80, x6); |
| CHECK_EQUAL_64(0x80000080, x7); |
| CHECK_EQUAL_64(1, x8); |
| CHECK_EQUAL_64(1, x9); |
| CHECK_EQUAL_64(2, x10); |
| CHECK_EQUAL_64(0xfffffffe, x11); |
| CHECK_EQUAL_64(0x7fffffff, x12); |
| CHECK_EQUAL_64(0x80000000, x13); |
| CHECK_EQUAL_64(0x7ffffffe, x14); |
| CHECK_EQUAL_64(0x80000001, x15); |
| CHECK_EQUAL_64(1, x17); |
| CHECK_EQUAL_64(2, x18); |
| CHECK_EQUAL_64(0xfffffffffffffffeUL, x19); |
| CHECK_EQUAL_64(0x7fffffffffffffffUL, x20); |
| CHECK_EQUAL_64(0x8000000000000000UL, x21); |
| CHECK_EQUAL_64(0x7fffff8000000000UL, x22); |
| CHECK_EQUAL_64(0x8000008000000000UL, x23); |
| CHECK_EQUAL_64(1, x24); |
| CHECK_EQUAL_64(2, x25); |
| CHECK_EQUAL_64(0xfffffffffffffffeUL, x26); |
| CHECK_EQUAL_64(0x7fffffffffffffffUL, x27); |
| // CHECK_EQUAL_64(0x8000000000000000UL, x28); |
| CHECK_EQUAL_64(0x7ffffffffffffc00UL, x29); |
| CHECK_EQUAL_64(0x8000000000000400UL, x30); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fcvtnu) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s0, 1.0); |
| __ Fmov(s1, 1.1); |
| __ Fmov(s2, 1.5); |
| __ Fmov(s3, -1.5); |
| __ Fmov(s4, kFP32PositiveInfinity); |
| __ Fmov(s5, kFP32NegativeInfinity); |
| __ Fmov(s6, 0xffffff00); // Largest float < UINT32_MAX. |
| __ Fmov(d8, 1.0); |
| __ Fmov(d9, 1.1); |
| __ Fmov(d10, 1.5); |
| __ Fmov(d11, -1.5); |
| __ Fmov(d12, kFP64PositiveInfinity); |
| __ Fmov(d13, kFP64NegativeInfinity); |
| __ Fmov(d14, 0xfffffffe); |
| __ Fmov(s16, 1.0); |
| __ Fmov(s17, 1.1); |
| __ Fmov(s18, 1.5); |
| __ Fmov(s19, -1.5); |
| __ Fmov(s20, kFP32PositiveInfinity); |
| __ Fmov(s21, kFP32NegativeInfinity); |
| __ Fmov(s22, 0xffffff0000000000UL); // Largest float < UINT64_MAX. |
| __ Fmov(d24, 1.1); |
| __ Fmov(d25, 1.5); |
| __ Fmov(d26, -1.5); |
| __ Fmov(d27, kFP64PositiveInfinity); |
| __ Fmov(d28, kFP64NegativeInfinity); |
| __ Fmov(d29, 0xfffffffffffff800UL); // Largest double < UINT64_MAX. |
| __ Fmov(s30, 0x100000000UL); |
| |
| __ Fcvtnu(w0, s0); |
| __ Fcvtnu(w1, s1); |
| __ Fcvtnu(w2, s2); |
| __ Fcvtnu(w3, s3); |
| __ Fcvtnu(w4, s4); |
| __ Fcvtnu(w5, s5); |
| __ Fcvtnu(w6, s6); |
| __ Fcvtnu(w8, d8); |
| __ Fcvtnu(w9, d9); |
| __ Fcvtnu(w10, d10); |
| __ Fcvtnu(w11, d11); |
| __ Fcvtnu(w12, d12); |
| __ Fcvtnu(w13, d13); |
| __ Fcvtnu(w14, d14); |
| __ Fcvtnu(w15, d15); |
| __ Fcvtnu(x16, s16); |
| __ Fcvtnu(x17, s17); |
| __ Fcvtnu(x18, s18); |
| __ Fcvtnu(x19, s19); |
| __ Fcvtnu(x20, s20); |
| __ Fcvtnu(x21, s21); |
| __ Fcvtnu(x22, s22); |
| __ Fcvtnu(x24, d24); |
| __ Fcvtnu(x25, d25); |
| __ Fcvtnu(x26, d26); |
| __ Fcvtnu(x27, d27); |
| // __ Fcvtnu(x28, d28); |
| __ Fcvtnu(x29, d29); |
| __ Fcvtnu(w30, s30); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(1, x0); |
| CHECK_EQUAL_64(1, x1); |
| CHECK_EQUAL_64(2, x2); |
| CHECK_EQUAL_64(0, x3); |
| CHECK_EQUAL_64(0xffffffff, x4); |
| CHECK_EQUAL_64(0, x5); |
| CHECK_EQUAL_64(0xffffff00, x6); |
| CHECK_EQUAL_64(1, x8); |
| CHECK_EQUAL_64(1, x9); |
| CHECK_EQUAL_64(2, x10); |
| CHECK_EQUAL_64(0, x11); |
| CHECK_EQUAL_64(0xffffffff, x12); |
| CHECK_EQUAL_64(0, x13); |
| CHECK_EQUAL_64(0xfffffffe, x14); |
| CHECK_EQUAL_64(1, x16); |
| CHECK_EQUAL_64(1, x17); |
| CHECK_EQUAL_64(2, x18); |
| CHECK_EQUAL_64(0, x19); |
| CHECK_EQUAL_64(0xffffffffffffffffUL, x20); |
| CHECK_EQUAL_64(0, x21); |
| CHECK_EQUAL_64(0xffffff0000000000UL, x22); |
| CHECK_EQUAL_64(1, x24); |
| CHECK_EQUAL_64(2, x25); |
| CHECK_EQUAL_64(0, x26); |
| CHECK_EQUAL_64(0xffffffffffffffffUL, x27); |
| // CHECK_EQUAL_64(0, x28); |
| CHECK_EQUAL_64(0xfffffffffffff800UL, x29); |
| CHECK_EQUAL_64(0xffffffff, x30); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fcvtzs) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s0, 1.0); |
| __ Fmov(s1, 1.1); |
| __ Fmov(s2, 1.5); |
| __ Fmov(s3, -1.5); |
| __ Fmov(s4, kFP32PositiveInfinity); |
| __ Fmov(s5, kFP32NegativeInfinity); |
| __ Fmov(s6, 0x7fffff80); // Largest float < INT32_MAX. |
| __ Fneg(s7, s6); // Smallest float > INT32_MIN. |
| __ Fmov(d8, 1.0); |
| __ Fmov(d9, 1.1); |
| __ Fmov(d10, 1.5); |
| __ Fmov(d11, -1.5); |
| __ Fmov(d12, kFP64PositiveInfinity); |
| __ Fmov(d13, kFP64NegativeInfinity); |
| __ Fmov(d14, kWMaxInt - 1); |
| __ Fmov(d15, kWMinInt + 1); |
| __ Fmov(s17, 1.1); |
| __ Fmov(s18, 1.5); |
| __ Fmov(s19, -1.5); |
| __ Fmov(s20, kFP32PositiveInfinity); |
| __ Fmov(s21, kFP32NegativeInfinity); |
| __ Fmov(s22, 0x7fffff8000000000UL); // Largest float < INT64_MAX. |
| __ Fneg(s23, s22); // Smallest float > INT64_MIN. |
| __ Fmov(d24, 1.1); |
| __ Fmov(d25, 1.5); |
| __ Fmov(d26, -1.5); |
| __ Fmov(d27, kFP64PositiveInfinity); |
| __ Fmov(d28, kFP64NegativeInfinity); |
| __ Fmov(d29, 0x7ffffffffffffc00UL); // Largest double < INT64_MAX. |
| __ Fneg(d30, d29); // Smallest double > INT64_MIN. |
| |
| __ Fcvtzs(w0, s0); |
| __ Fcvtzs(w1, s1); |
| __ Fcvtzs(w2, s2); |
| __ Fcvtzs(w3, s3); |
| __ Fcvtzs(w4, s4); |
| __ Fcvtzs(w5, s5); |
| __ Fcvtzs(w6, s6); |
| __ Fcvtzs(w7, s7); |
| __ Fcvtzs(w8, d8); |
| __ Fcvtzs(w9, d9); |
| __ Fcvtzs(w10, d10); |
| __ Fcvtzs(w11, d11); |
| __ Fcvtzs(w12, d12); |
| __ Fcvtzs(w13, d13); |
| __ Fcvtzs(w14, d14); |
| __ Fcvtzs(w15, d15); |
| __ Fcvtzs(x17, s17); |
| __ Fcvtzs(x18, s18); |
| __ Fcvtzs(x19, s19); |
| __ Fcvtzs(x20, s20); |
| __ Fcvtzs(x21, s21); |
| __ Fcvtzs(x22, s22); |
| __ Fcvtzs(x23, s23); |
| __ Fcvtzs(x24, d24); |
| __ Fcvtzs(x25, d25); |
| __ Fcvtzs(x26, d26); |
| __ Fcvtzs(x27, d27); |
| __ Fcvtzs(x28, d28); |
| __ Fcvtzs(x29, d29); |
| __ Fcvtzs(x30, d30); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(1, x0); |
| CHECK_EQUAL_64(1, x1); |
| CHECK_EQUAL_64(1, x2); |
| CHECK_EQUAL_64(0xffffffff, x3); |
| CHECK_EQUAL_64(0x7fffffff, x4); |
| CHECK_EQUAL_64(0x80000000, x5); |
| CHECK_EQUAL_64(0x7fffff80, x6); |
| CHECK_EQUAL_64(0x80000080, x7); |
| CHECK_EQUAL_64(1, x8); |
| CHECK_EQUAL_64(1, x9); |
| CHECK_EQUAL_64(1, x10); |
| CHECK_EQUAL_64(0xffffffff, x11); |
| CHECK_EQUAL_64(0x7fffffff, x12); |
| CHECK_EQUAL_64(0x80000000, x13); |
| CHECK_EQUAL_64(0x7ffffffe, x14); |
| CHECK_EQUAL_64(0x80000001, x15); |
| CHECK_EQUAL_64(1, x17); |
| CHECK_EQUAL_64(1, x18); |
| CHECK_EQUAL_64(0xffffffffffffffffUL, x19); |
| CHECK_EQUAL_64(0x7fffffffffffffffUL, x20); |
| CHECK_EQUAL_64(0x8000000000000000UL, x21); |
| CHECK_EQUAL_64(0x7fffff8000000000UL, x22); |
| CHECK_EQUAL_64(0x8000008000000000UL, x23); |
| CHECK_EQUAL_64(1, x24); |
| CHECK_EQUAL_64(1, x25); |
| CHECK_EQUAL_64(0xffffffffffffffffUL, x26); |
| CHECK_EQUAL_64(0x7fffffffffffffffUL, x27); |
| CHECK_EQUAL_64(0x8000000000000000UL, x28); |
| CHECK_EQUAL_64(0x7ffffffffffffc00UL, x29); |
| CHECK_EQUAL_64(0x8000000000000400UL, x30); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(fcvtzu) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Fmov(s0, 1.0); |
| __ Fmov(s1, 1.1); |
| __ Fmov(s2, 1.5); |
| __ Fmov(s3, -1.5); |
| __ Fmov(s4, kFP32PositiveInfinity); |
| __ Fmov(s5, kFP32NegativeInfinity); |
| __ Fmov(s6, 0x7fffff80); // Largest float < INT32_MAX. |
| __ Fneg(s7, s6); // Smallest float > INT32_MIN. |
| __ Fmov(d8, 1.0); |
| __ Fmov(d9, 1.1); |
| __ Fmov(d10, 1.5); |
| __ Fmov(d11, -1.5); |
| __ Fmov(d12, kFP64PositiveInfinity); |
| __ Fmov(d13, kFP64NegativeInfinity); |
| __ Fmov(d14, kWMaxInt - 1); |
| __ Fmov(d15, kWMinInt + 1); |
| __ Fmov(s17, 1.1); |
| __ Fmov(s18, 1.5); |
| __ Fmov(s19, -1.5); |
| __ Fmov(s20, kFP32PositiveInfinity); |
| __ Fmov(s21, kFP32NegativeInfinity); |
| __ Fmov(s22, 0x7fffff8000000000UL); // Largest float < INT64_MAX. |
| __ Fneg(s23, s22); // Smallest float > INT64_MIN. |
| __ Fmov(d24, 1.1); |
| __ Fmov(d25, 1.5); |
| __ Fmov(d26, -1.5); |
| __ Fmov(d27, kFP64PositiveInfinity); |
| __ Fmov(d28, kFP64NegativeInfinity); |
| __ Fmov(d29, 0x7ffffffffffffc00UL); // Largest double < INT64_MAX. |
| __ Fneg(d30, d29); // Smallest double > INT64_MIN. |
| |
| __ Fcvtzu(w0, s0); |
| __ Fcvtzu(w1, s1); |
| __ Fcvtzu(w2, s2); |
| __ Fcvtzu(w3, s3); |
| __ Fcvtzu(w4, s4); |
| __ Fcvtzu(w5, s5); |
| __ Fcvtzu(w6, s6); |
| __ Fcvtzu(w7, s7); |
| __ Fcvtzu(w8, d8); |
| __ Fcvtzu(w9, d9); |
| __ Fcvtzu(w10, d10); |
| __ Fcvtzu(w11, d11); |
| __ Fcvtzu(w12, d12); |
| __ Fcvtzu(w13, d13); |
| __ Fcvtzu(w14, d14); |
| __ Fcvtzu(x17, s17); |
| __ Fcvtzu(x18, s18); |
| __ Fcvtzu(x19, s19); |
| __ Fcvtzu(x20, s20); |
| __ Fcvtzu(x21, s21); |
| __ Fcvtzu(x22, s22); |
| __ Fcvtzu(x23, s23); |
| __ Fcvtzu(x24, d24); |
| __ Fcvtzu(x25, d25); |
| __ Fcvtzu(x26, d26); |
| __ Fcvtzu(x27, d27); |
| __ Fcvtzu(x28, d28); |
| __ Fcvtzu(x29, d29); |
| __ Fcvtzu(x30, d30); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(1, x0); |
| CHECK_EQUAL_64(1, x1); |
| CHECK_EQUAL_64(1, x2); |
| CHECK_EQUAL_64(0, x3); |
| CHECK_EQUAL_64(0xffffffff, x4); |
| CHECK_EQUAL_64(0, x5); |
| CHECK_EQUAL_64(0x7fffff80, x6); |
| CHECK_EQUAL_64(0, x7); |
| CHECK_EQUAL_64(1, x8); |
| CHECK_EQUAL_64(1, x9); |
| CHECK_EQUAL_64(1, x10); |
| CHECK_EQUAL_64(0, x11); |
| CHECK_EQUAL_64(0xffffffff, x12); |
| CHECK_EQUAL_64(0, x13); |
| CHECK_EQUAL_64(0x7ffffffe, x14); |
| CHECK_EQUAL_64(1, x17); |
| CHECK_EQUAL_64(1, x18); |
| CHECK_EQUAL_64(0x0UL, x19); |
| CHECK_EQUAL_64(0xffffffffffffffffUL, x20); |
| CHECK_EQUAL_64(0x0UL, x21); |
| CHECK_EQUAL_64(0x7fffff8000000000UL, x22); |
| CHECK_EQUAL_64(0x0UL, x23); |
| CHECK_EQUAL_64(1, x24); |
| CHECK_EQUAL_64(1, x25); |
| CHECK_EQUAL_64(0x0UL, x26); |
| CHECK_EQUAL_64(0xffffffffffffffffUL, x27); |
| CHECK_EQUAL_64(0x0UL, x28); |
| CHECK_EQUAL_64(0x7ffffffffffffc00UL, x29); |
| CHECK_EQUAL_64(0x0UL, x30); |
| |
| TEARDOWN(); |
| } |
| |
| |
| // Test that scvtf and ucvtf can convert the 64-bit input into the expected |
| // value. All possible values of 'fbits' are tested. The expected value is |
| // modified accordingly in each case. |
| // |
| // The expected value is specified as the bit encoding of the expected double |
| // produced by scvtf (expected_scvtf_bits) as well as ucvtf |
| // (expected_ucvtf_bits). |
| // |
| // Where the input value is representable by int32_t or uint32_t, conversions |
| // from W registers will also be tested. |
| static void TestUScvtfHelper(uint64_t in, |
| uint64_t expected_scvtf_bits, |
| uint64_t expected_ucvtf_bits) { |
| uint64_t u64 = in; |
| uint32_t u32 = u64 & 0xffffffff; |
| int64_t s64 = static_cast<int64_t>(in); |
| int32_t s32 = s64 & 0x7fffffff; |
| |
| bool cvtf_s32 = (s64 == s32); |
| bool cvtf_u32 = (u64 == u32); |
| |
| double results_scvtf_x[65]; |
| double results_ucvtf_x[65]; |
| double results_scvtf_w[33]; |
| double results_ucvtf_w[33]; |
| |
| SETUP(); |
| START(); |
| |
| __ Mov(x0, reinterpret_cast<int64_t>(results_scvtf_x)); |
| __ Mov(x1, reinterpret_cast<int64_t>(results_ucvtf_x)); |
| __ Mov(x2, reinterpret_cast<int64_t>(results_scvtf_w)); |
| __ Mov(x3, reinterpret_cast<int64_t>(results_ucvtf_w)); |
| |
| __ Mov(x10, s64); |
| |
| // Corrupt the top word, in case it is accidentally used during W-register |
| // conversions. |
| __ Mov(x11, 0x5555555555555555); |
| __ Bfi(x11, x10, 0, kWRegSizeInBits); |
| |
| // Test integer conversions. |
| __ Scvtf(d0, x10); |
| __ Ucvtf(d1, x10); |
| __ Scvtf(d2, w11); |
| __ Ucvtf(d3, w11); |
| __ Str(d0, MemOperand(x0)); |
| __ Str(d1, MemOperand(x1)); |
| __ Str(d2, MemOperand(x2)); |
| __ Str(d3, MemOperand(x3)); |
| |
| // Test all possible values of fbits. |
| for (int fbits = 1; fbits <= 32; fbits++) { |
| __ Scvtf(d0, x10, fbits); |
| __ Ucvtf(d1, x10, fbits); |
| __ Scvtf(d2, w11, fbits); |
| __ Ucvtf(d3, w11, fbits); |
| __ Str(d0, MemOperand(x0, fbits * kDRegSize)); |
| __ Str(d1, MemOperand(x1, fbits * kDRegSize)); |
| __ Str(d2, MemOperand(x2, fbits * kDRegSize)); |
| __ Str(d3, MemOperand(x3, fbits * kDRegSize)); |
| } |
| |
| // Conversions from W registers can only handle fbits values <= 32, so just |
| // test conversions from X registers for 32 < fbits <= 64. |
| for (int fbits = 33; fbits <= 64; fbits++) { |
| __ Scvtf(d0, x10, fbits); |
| __ Ucvtf(d1, x10, fbits); |
| __ Str(d0, MemOperand(x0, fbits * kDRegSize)); |
| __ Str(d1, MemOperand(x1, fbits * kDRegSize)); |
| } |
| |
| END(); |
| RUN(); |
| |
| // Check the results. |
| double expected_scvtf_base = rawbits_to_double(expected_scvtf_bits); |
| double expected_ucvtf_base = rawbits_to_double(expected_ucvtf_bits); |
| |
| for (int fbits = 0; fbits <= 32; fbits++) { |
| double expected_scvtf = expected_scvtf_base / pow(2.0, fbits); |
| double expected_ucvtf = expected_ucvtf_base / pow(2.0, fbits); |
| CHECK_EQUAL_FP64(expected_scvtf, results_scvtf_x[fbits]); |
| CHECK_EQUAL_FP64(expected_ucvtf, results_ucvtf_x[fbits]); |
| if (cvtf_s32) CHECK_EQUAL_FP64(expected_scvtf, results_scvtf_w[fbits]); |
| if (cvtf_u32) CHECK_EQUAL_FP64(expected_ucvtf, results_ucvtf_w[fbits]); |
| } |
| for (int fbits = 33; fbits <= 64; fbits++) { |
| double expected_scvtf = expected_scvtf_base / pow(2.0, fbits); |
| double expected_ucvtf = expected_ucvtf_base / pow(2.0, fbits); |
| CHECK_EQUAL_FP64(expected_scvtf, results_scvtf_x[fbits]); |
| CHECK_EQUAL_FP64(expected_ucvtf, results_ucvtf_x[fbits]); |
| } |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(scvtf_ucvtf_double) { |
| INIT_V8(); |
| // Simple conversions of positive numbers which require no rounding; the |
| // results should not depened on the rounding mode, and ucvtf and scvtf should |
| // produce the same result. |
| TestUScvtfHelper(0x0000000000000000, 0x0000000000000000, 0x0000000000000000); |
| TestUScvtfHelper(0x0000000000000001, 0x3ff0000000000000, 0x3ff0000000000000); |
| TestUScvtfHelper(0x0000000040000000, 0x41d0000000000000, 0x41d0000000000000); |
| TestUScvtfHelper(0x0000000100000000, 0x41f0000000000000, 0x41f0000000000000); |
| TestUScvtfHelper(0x4000000000000000, 0x43d0000000000000, 0x43d0000000000000); |
| // Test mantissa extremities. |
| TestUScvtfHelper(0x4000000000000400, 0x43d0000000000001, 0x43d0000000000001); |
| // The largest int32_t that fits in a double. |
| TestUScvtfHelper(0x000000007fffffff, 0x41dfffffffc00000, 0x41dfffffffc00000); |
| // Values that would be negative if treated as an int32_t. |
| TestUScvtfHelper(0x00000000ffffffff, 0x41efffffffe00000, 0x41efffffffe00000); |
| TestUScvtfHelper(0x0000000080000000, 0x41e0000000000000, 0x41e0000000000000); |
| TestUScvtfHelper(0x0000000080000001, 0x41e0000000200000, 0x41e0000000200000); |
| // The largest int64_t that fits in a double. |
| TestUScvtfHelper(0x7ffffffffffffc00, 0x43dfffffffffffff, 0x43dfffffffffffff); |
| // Check for bit pattern reproduction. |
| TestUScvtfHelper(0x0123456789abcde0, 0x43723456789abcde, 0x43723456789abcde); |
| TestUScvtfHelper(0x0000000012345678, 0x41b2345678000000, 0x41b2345678000000); |
| |
| // Simple conversions of negative int64_t values. These require no rounding, |
| // and the results should not depend on the rounding mode. |
| TestUScvtfHelper(0xffffffffc0000000, 0xc1d0000000000000, 0x43effffffff80000); |
| TestUScvtfHelper(0xffffffff00000000, 0xc1f0000000000000, 0x43efffffffe00000); |
| TestUScvtfHelper(0xc000000000000000, 0xc3d0000000000000, 0x43e8000000000000); |
| |
| // Conversions which require rounding. |
| TestUScvtfHelper(0x1000000000000000, 0x43b0000000000000, 0x43b0000000000000); |
| TestUScvtfHelper(0x1000000000000001, 0x43b0000000000000, 0x43b0000000000000); |
| TestUScvtfHelper(0x1000000000000080, 0x43b0000000000000, 0x43b0000000000000); |
| TestUScvtfHelper(0x1000000000000081, 0x43b0000000000001, 0x43b0000000000001); |
| TestUScvtfHelper(0x1000000000000100, 0x43b0000000000001, 0x43b0000000000001); |
| TestUScvtfHelper(0x1000000000000101, 0x43b0000000000001, 0x43b0000000000001); |
| TestUScvtfHelper(0x1000000000000180, 0x43b0000000000002, 0x43b0000000000002); |
| TestUScvtfHelper(0x1000000000000181, 0x43b0000000000002, 0x43b0000000000002); |
| TestUScvtfHelper(0x1000000000000200, 0x43b0000000000002, 0x43b0000000000002); |
| TestUScvtfHelper(0x1000000000000201, 0x43b0000000000002, 0x43b0000000000002); |
| TestUScvtfHelper(0x1000000000000280, 0x43b0000000000002, 0x43b0000000000002); |
| TestUScvtfHelper(0x1000000000000281, 0x43b0000000000003, 0x43b0000000000003); |
| TestUScvtfHelper(0x1000000000000300, 0x43b0000000000003, 0x43b0000000000003); |
| // Check rounding of negative int64_t values (and large uint64_t values). |
| TestUScvtfHelper(0x8000000000000000, 0xc3e0000000000000, 0x43e0000000000000); |
| TestUScvtfHelper(0x8000000000000001, 0xc3e0000000000000, 0x43e0000000000000); |
| TestUScvtfHelper(0x8000000000000200, 0xc3e0000000000000, 0x43e0000000000000); |
| TestUScvtfHelper(0x8000000000000201, 0xc3dfffffffffffff, 0x43e0000000000000); |
| TestUScvtfHelper(0x8000000000000400, 0xc3dfffffffffffff, 0x43e0000000000000); |
| TestUScvtfHelper(0x8000000000000401, 0xc3dfffffffffffff, 0x43e0000000000001); |
| TestUScvtfHelper(0x8000000000000600, 0xc3dffffffffffffe, 0x43e0000000000001); |
| TestUScvtfHelper(0x8000000000000601, 0xc3dffffffffffffe, 0x43e0000000000001); |
| TestUScvtfHelper(0x8000000000000800, 0xc3dffffffffffffe, 0x43e0000000000001); |
| TestUScvtfHelper(0x8000000000000801, 0xc3dffffffffffffe, 0x43e0000000000001); |
| TestUScvtfHelper(0x8000000000000a00, 0xc3dffffffffffffe, 0x43e0000000000001); |
| TestUScvtfHelper(0x8000000000000a01, 0xc3dffffffffffffd, 0x43e0000000000001); |
| TestUScvtfHelper(0x8000000000000c00, 0xc3dffffffffffffd, 0x43e0000000000002); |
| // Round up to produce a result that's too big for the input to represent. |
| TestUScvtfHelper(0x7ffffffffffffe00, 0x43e0000000000000, 0x43e0000000000000); |
| TestUScvtfHelper(0x7fffffffffffffff, 0x43e0000000000000, 0x43e0000000000000); |
| TestUScvtfHelper(0xfffffffffffffc00, 0xc090000000000000, 0x43f0000000000000); |
| TestUScvtfHelper(0xffffffffffffffff, 0xbff0000000000000, 0x43f0000000000000); |
| } |
| |
| |
| // The same as TestUScvtfHelper, but convert to floats. |
| static void TestUScvtf32Helper(uint64_t in, |
| uint32_t expected_scvtf_bits, |
| uint32_t expected_ucvtf_bits) { |
| uint64_t u64 = in; |
| uint32_t u32 = u64 & 0xffffffff; |
| int64_t s64 = static_cast<int64_t>(in); |
| int32_t s32 = s64 & 0x7fffffff; |
| |
| bool cvtf_s32 = (s64 == s32); |
| bool cvtf_u32 = (u64 == u32); |
| |
| float results_scvtf_x[65]; |
| float results_ucvtf_x[65]; |
| float results_scvtf_w[33]; |
| float results_ucvtf_w[33]; |
| |
| SETUP(); |
| START(); |
| |
| __ Mov(x0, reinterpret_cast<int64_t>(results_scvtf_x)); |
| __ Mov(x1, reinterpret_cast<int64_t>(results_ucvtf_x)); |
| __ Mov(x2, reinterpret_cast<int64_t>(results_scvtf_w)); |
| __ Mov(x3, reinterpret_cast<int64_t>(results_ucvtf_w)); |
| |
| __ Mov(x10, s64); |
| |
| // Corrupt the top word, in case it is accidentally used during W-register |
| // conversions. |
| __ Mov(x11, 0x5555555555555555); |
| __ Bfi(x11, x10, 0, kWRegSizeInBits); |
| |
| // Test integer conversions. |
| __ Scvtf(s0, x10); |
| __ Ucvtf(s1, x10); |
| __ Scvtf(s2, w11); |
| __ Ucvtf(s3, w11); |
| __ Str(s0, MemOperand(x0)); |
| __ Str(s1, MemOperand(x1)); |
| __ Str(s2, MemOperand(x2)); |
| __ Str(s3, MemOperand(x3)); |
| |
| // Test all possible values of fbits. |
| for (int fbits = 1; fbits <= 32; fbits++) { |
| __ Scvtf(s0, x10, fbits); |
| __ Ucvtf(s1, x10, fbits); |
| __ Scvtf(s2, w11, fbits); |
| __ Ucvtf(s3, w11, fbits); |
| __ Str(s0, MemOperand(x0, fbits * kSRegSize)); |
| __ Str(s1, MemOperand(x1, fbits * kSRegSize)); |
| __ Str(s2, MemOperand(x2, fbits * kSRegSize)); |
| __ Str(s3, MemOperand(x3, fbits * kSRegSize)); |
| } |
| |
| // Conversions from W registers can only handle fbits values <= 32, so just |
| // test conversions from X registers for 32 < fbits <= 64. |
| for (int fbits = 33; fbits <= 64; fbits++) { |
| __ Scvtf(s0, x10, fbits); |
| __ Ucvtf(s1, x10, fbits); |
| __ Str(s0, MemOperand(x0, fbits * kSRegSize)); |
| __ Str(s1, MemOperand(x1, fbits * kSRegSize)); |
| } |
| |
| END(); |
| RUN(); |
| |
| // Check the results. |
| float expected_scvtf_base = rawbits_to_float(expected_scvtf_bits); |
| float expected_ucvtf_base = rawbits_to_float(expected_ucvtf_bits); |
| |
| for (int fbits = 0; fbits <= 32; fbits++) { |
| float expected_scvtf = expected_scvtf_base / powf(2, fbits); |
| float expected_ucvtf = expected_ucvtf_base / powf(2, fbits); |
| CHECK_EQUAL_FP32(expected_scvtf, results_scvtf_x[fbits]); |
| CHECK_EQUAL_FP32(expected_ucvtf, results_ucvtf_x[fbits]); |
| if (cvtf_s32) CHECK_EQUAL_FP32(expected_scvtf, results_scvtf_w[fbits]); |
| if (cvtf_u32) CHECK_EQUAL_FP32(expected_ucvtf, results_ucvtf_w[fbits]); |
| break; |
| } |
| for (int fbits = 33; fbits <= 64; fbits++) { |
| break; |
| float expected_scvtf = expected_scvtf_base / powf(2, fbits); |
| float expected_ucvtf = expected_ucvtf_base / powf(2, fbits); |
| CHECK_EQUAL_FP32(expected_scvtf, results_scvtf_x[fbits]); |
| CHECK_EQUAL_FP32(expected_ucvtf, results_ucvtf_x[fbits]); |
| } |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(scvtf_ucvtf_float) { |
| INIT_V8(); |
| // Simple conversions of positive numbers which require no rounding; the |
| // results should not depened on the rounding mode, and ucvtf and scvtf should |
| // produce the same result. |
| TestUScvtf32Helper(0x0000000000000000, 0x00000000, 0x00000000); |
| TestUScvtf32Helper(0x0000000000000001, 0x3f800000, 0x3f800000); |
| TestUScvtf32Helper(0x0000000040000000, 0x4e800000, 0x4e800000); |
| TestUScvtf32Helper(0x0000000100000000, 0x4f800000, 0x4f800000); |
| TestUScvtf32Helper(0x4000000000000000, 0x5e800000, 0x5e800000); |
| // Test mantissa extremities. |
| TestUScvtf32Helper(0x0000000000800001, 0x4b000001, 0x4b000001); |
| TestUScvtf32Helper(0x4000008000000000, 0x5e800001, 0x5e800001); |
| // The largest int32_t that fits in a float. |
| TestUScvtf32Helper(0x000000007fffff80, 0x4effffff, 0x4effffff); |
| // Values that would be negative if treated as an int32_t. |
| TestUScvtf32Helper(0x00000000ffffff00, 0x4f7fffff, 0x4f7fffff); |
| TestUScvtf32Helper(0x0000000080000000, 0x4f000000, 0x4f000000); |
| TestUScvtf32Helper(0x0000000080000100, 0x4f000001, 0x4f000001); |
| // The largest int64_t that fits in a float. |
| TestUScvtf32Helper(0x7fffff8000000000, 0x5effffff, 0x5effffff); |
| // Check for bit pattern reproduction. |
| TestUScvtf32Helper(0x0000000000876543, 0x4b076543, 0x4b076543); |
| |
| // Simple conversions of negative int64_t values. These require no rounding, |
| // and the results should not depend on the rounding mode. |
| TestUScvtf32Helper(0xfffffc0000000000, 0xd4800000, 0x5f7ffffc); |
| TestUScvtf32Helper(0xc000000000000000, 0xde800000, 0x5f400000); |
| |
| // Conversions which require rounding. |
| TestUScvtf32Helper(0x0000800000000000, 0x57000000, 0x57000000); |
| TestUScvtf32Helper(0x0000800000000001, 0x57000000, 0x57000000); |
| TestUScvtf32Helper(0x0000800000800000, 0x57000000, 0x57000000); |
| TestUScvtf32Helper(0x0000800000800001, 0x57000001, 0x57000001); |
| TestUScvtf32Helper(0x0000800001000000, 0x57000001, 0x57000001); |
| TestUScvtf32Helper(0x0000800001000001, 0x57000001, 0x57000001); |
| TestUScvtf32Helper(0x0000800001800000, 0x57000002, 0x57000002); |
| TestUScvtf32Helper(0x0000800001800001, 0x57000002, 0x57000002); |
| TestUScvtf32Helper(0x0000800002000000, 0x57000002, 0x57000002); |
| TestUScvtf32Helper(0x0000800002000001, 0x57000002, 0x57000002); |
| TestUScvtf32Helper(0x0000800002800000, 0x57000002, 0x57000002); |
| TestUScvtf32Helper(0x0000800002800001, 0x57000003, 0x57000003); |
| TestUScvtf32Helper(0x0000800003000000, 0x57000003, 0x57000003); |
| // Check rounding of negative int64_t values (and large uint64_t values). |
| TestUScvtf32Helper(0x8000000000000000, 0xdf000000, 0x5f000000); |
| TestUScvtf32Helper(0x8000000000000001, 0xdf000000, 0x5f000000); |
| TestUScvtf32Helper(0x8000004000000000, 0xdf000000, 0x5f000000); |
| TestUScvtf32Helper(0x8000004000000001, 0xdeffffff, 0x5f000000); |
| TestUScvtf32Helper(0x8000008000000000, 0xdeffffff, 0x5f000000); |
| TestUScvtf32Helper(0x8000008000000001, 0xdeffffff, 0x5f000001); |
| TestUScvtf32Helper(0x800000c000000000, 0xdefffffe, 0x5f000001); |
| TestUScvtf32Helper(0x800000c000000001, 0xdefffffe, 0x5f000001); |
| TestUScvtf32Helper(0x8000010000000000, 0xdefffffe, 0x5f000001); |
| TestUScvtf32Helper(0x8000010000000001, 0xdefffffe, 0x5f000001); |
| TestUScvtf32Helper(0x8000014000000000, 0xdefffffe, 0x5f000001); |
| TestUScvtf32Helper(0x8000014000000001, 0xdefffffd, 0x5f000001); |
| TestUScvtf32Helper(0x8000018000000000, 0xdefffffd, 0x5f000002); |
| // Round up to produce a result that's too big for the input to represent. |
| TestUScvtf32Helper(0x000000007fffffc0, 0x4f000000, 0x4f000000); |
| TestUScvtf32Helper(0x000000007fffffff, 0x4f000000, 0x4f000000); |
| TestUScvtf32Helper(0x00000000ffffff80, 0x4f800000, 0x4f800000); |
| TestUScvtf32Helper(0x00000000ffffffff, 0x4f800000, 0x4f800000); |
| TestUScvtf32Helper(0x7fffffc000000000, 0x5f000000, 0x5f000000); |
| TestUScvtf32Helper(0x7fffffffffffffff, 0x5f000000, 0x5f000000); |
| TestUScvtf32Helper(0xffffff8000000000, 0xd3000000, 0x5f800000); |
| TestUScvtf32Helper(0xffffffffffffffff, 0xbf800000, 0x5f800000); |
| } |
| |
| |
| TEST(system_mrs) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| __ Mov(w0, 0); |
| __ Mov(w1, 1); |
| __ Mov(w2, 0x80000000); |
| |
| // Set the Z and C flags. |
| __ Cmp(w0, w0); |
| __ Mrs(x3, NZCV); |
| |
| // Set the N flag. |
| __ Cmp(w0, w1); |
| __ Mrs(x4, NZCV); |
| |
| // Set the Z, C and V flags. |
| __ Adds(w0, w2, w2); |
| __ Mrs(x5, NZCV); |
| |
| // Read the default FPCR. |
| __ Mrs(x6, FPCR); |
| END(); |
| |
| RUN(); |
| |
| // NZCV |
| CHECK_EQUAL_32(ZCFlag, w3); |
| CHECK_EQUAL_32(NFlag, w4); |
| CHECK_EQUAL_32(ZCVFlag, w5); |
| |
| // FPCR |
| // The default FPCR on Linux-based platforms is 0. |
| CHECK_EQUAL_32(0, w6); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(system_msr) { |
| INIT_V8(); |
| // All FPCR fields that must be implemented: AHP, DN, FZ, RMode |
| const uint64_t fpcr_core = 0x07c00000; |
| |
| // All FPCR fields (including fields which may be read-as-zero): |
| // Stride, Len |
| // IDE, IXE, UFE, OFE, DZE, IOE |
| const uint64_t fpcr_all = fpcr_core | 0x00379f00; |
| |
| SETUP(); |
| |
| START(); |
| __ Mov(w0, 0); |
| __ Mov(w1, 0x7fffffff); |
| |
| __ Mov(x7, 0); |
| |
| __ Mov(x10, NVFlag); |
| __ Cmp(w0, w0); // Set Z and C. |
| __ Msr(NZCV, x10); // Set N and V. |
| // The Msr should have overwritten every flag set by the Cmp. |
| __ Cinc(x7, x7, mi); // N |
| __ Cinc(x7, x7, ne); // !Z |
| __ Cinc(x7, x7, lo); // !C |
| __ Cinc(x7, x7, vs); // V |
| |
| __ Mov(x10, ZCFlag); |
| __ Cmn(w1, w1); // Set N and V. |
| __ Msr(NZCV, x10); // Set Z and C. |
| // The Msr should have overwritten every flag set by the Cmn. |
| __ Cinc(x7, x7, pl); // !N |
| __ Cinc(x7, x7, eq); // Z |
| __ Cinc(x7, x7, hs); // C |
| __ Cinc(x7, x7, vc); // !V |
| |
| // All core FPCR fields must be writable. |
| __ Mov(x8, fpcr_core); |
| __ Msr(FPCR, x8); |
| __ Mrs(x8, FPCR); |
| |
| // All FPCR fields, including optional ones. This part of the test doesn't |
| // achieve much other than ensuring that supported fields can be cleared by |
| // the next test. |
| __ Mov(x9, fpcr_all); |
| __ Msr(FPCR, x9); |
| __ Mrs(x9, FPCR); |
| __ And(x9, x9, fpcr_core); |
| |
| // The undefined bits must ignore writes. |
| // It's conceivable that a future version of the architecture could use these |
| // fields (making this test fail), but in the meantime this is a useful test |
| // for the simulator. |
| __ Mov(x10, ~fpcr_all); |
| __ Msr(FPCR, x10); |
| __ Mrs(x10, FPCR); |
| |
| END(); |
| |
| RUN(); |
| |
| // We should have incremented x7 (from 0) exactly 8 times. |
| CHECK_EQUAL_64(8, x7); |
| |
| CHECK_EQUAL_64(fpcr_core, x8); |
| CHECK_EQUAL_64(fpcr_core, x9); |
| CHECK_EQUAL_64(0, x10); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(system_nop) { |
| INIT_V8(); |
| SETUP(); |
| RegisterDump before; |
| |
| START(); |
| before.Dump(&masm); |
| __ Nop(); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_REGISTERS(before); |
| CHECK_EQUAL_NZCV(before.flags_nzcv()); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(zero_dest) { |
| INIT_V8(); |
| SETUP(); |
| RegisterDump before; |
| |
| START(); |
| // Preserve the system stack pointer, in case we clobber it. |
| __ Mov(x30, csp); |
| // Initialize the other registers used in this test. |
| uint64_t literal_base = 0x0100001000100101UL; |
| __ Mov(x0, 0); |
| __ Mov(x1, literal_base); |
| for (unsigned i = 2; i < x30.code(); i++) { |
| __ Add(Register::XRegFromCode(i), Register::XRegFromCode(i-1), x1); |
| } |
| before.Dump(&masm); |
| |
| // All of these instructions should be NOPs in these forms, but have |
| // alternate forms which can write into the stack pointer. |
| __ add(xzr, x0, x1); |
| __ add(xzr, x1, xzr); |
| __ add(xzr, xzr, x1); |
| |
| __ and_(xzr, x0, x2); |
| __ and_(xzr, x2, xzr); |
| __ and_(xzr, xzr, x2); |
| |
| __ bic(xzr, x0, x3); |
| __ bic(xzr, x3, xzr); |
| __ bic(xzr, xzr, x3); |
| |
| __ eon(xzr, x0, x4); |
| __ eon(xzr, x4, xzr); |
| __ eon(xzr, xzr, x4); |
| |
| __ eor(xzr, x0, x5); |
| __ eor(xzr, x5, xzr); |
| __ eor(xzr, xzr, x5); |
| |
| __ orr(xzr, x0, x6); |
| __ orr(xzr, x6, xzr); |
| __ orr(xzr, xzr, x6); |
| |
| __ sub(xzr, x0, x7); |
| __ sub(xzr, x7, xzr); |
| __ sub(xzr, xzr, x7); |
| |
| // Swap the saved system stack pointer with the real one. If csp was written |
| // during the test, it will show up in x30. This is done because the test |
| // framework assumes that csp will be valid at the end of the test. |
| __ Mov(x29, x30); |
| __ Mov(x30, csp); |
| __ Mov(csp, x29); |
| // We used x29 as a scratch register, so reset it to make sure it doesn't |
| // trigger a test failure. |
| __ Add(x29, x28, x1); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_REGISTERS(before); |
| CHECK_EQUAL_NZCV(before.flags_nzcv()); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(zero_dest_setflags) { |
| INIT_V8(); |
| SETUP(); |
| RegisterDump before; |
| |
| START(); |
| // Preserve the system stack pointer, in case we clobber it. |
| __ Mov(x30, csp); |
| // Initialize the other registers used in this test. |
| uint64_t literal_base = 0x0100001000100101UL; |
| __ Mov(x0, 0); |
| __ Mov(x1, literal_base); |
| for (int i = 2; i < 30; i++) { |
| __ Add(Register::XRegFromCode(i), Register::XRegFromCode(i-1), x1); |
| } |
| before.Dump(&masm); |
| |
| // All of these instructions should only write to the flags in these forms, |
| // but have alternate forms which can write into the stack pointer. |
| __ adds(xzr, x0, Operand(x1, UXTX)); |
| __ adds(xzr, x1, Operand(xzr, UXTX)); |
| __ adds(xzr, x1, 1234); |
| __ adds(xzr, x0, x1); |
| __ adds(xzr, x1, xzr); |
| __ adds(xzr, xzr, x1); |
| |
| __ ands(xzr, x2, ~0xf); |
| __ ands(xzr, xzr, ~0xf); |
| __ ands(xzr, x0, x2); |
| __ ands(xzr, x2, xzr); |
| __ ands(xzr, xzr, x2); |
| |
| __ bics(xzr, x3, ~0xf); |
| __ bics(xzr, xzr, ~0xf); |
| __ bics(xzr, x0, x3); |
| __ bics(xzr, x3, xzr); |
| __ bics(xzr, xzr, x3); |
| |
| __ subs(xzr, x0, Operand(x3, UXTX)); |
| __ subs(xzr, x3, Operand(xzr, UXTX)); |
| __ subs(xzr, x3, 1234); |
| __ subs(xzr, x0, x3); |
| __ subs(xzr, x3, xzr); |
| __ subs(xzr, xzr, x3); |
| |
| // Swap the saved system stack pointer with the real one. If csp was written |
| // during the test, it will show up in x30. This is done because the test |
| // framework assumes that csp will be valid at the end of the test. |
| __ Mov(x29, x30); |
| __ Mov(x30, csp); |
| __ Mov(csp, x29); |
| // We used x29 as a scratch register, so reset it to make sure it doesn't |
| // trigger a test failure. |
| __ Add(x29, x28, x1); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_REGISTERS(before); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(register_bit) { |
| // No code generation takes place in this test, so no need to setup and |
| // teardown. |
| |
| // Simple tests. |
| CHECK(x0.Bit() == (1UL << 0)); |
| CHECK(x1.Bit() == (1UL << 1)); |
| CHECK(x10.Bit() == (1UL << 10)); |
| |
| // AAPCS64 definitions. |
| CHECK(fp.Bit() == (1UL << kFramePointerRegCode)); |
| CHECK(lr.Bit() == (1UL << kLinkRegCode)); |
| |
| // Fixed (hardware) definitions. |
| CHECK(xzr.Bit() == (1UL << kZeroRegCode)); |
| |
| // Internal ABI definitions. |
| CHECK(jssp.Bit() == (1UL << kJSSPCode)); |
| CHECK(csp.Bit() == (1UL << kSPRegInternalCode)); |
| CHECK(csp.Bit() != xzr.Bit()); |
| |
| // xn.Bit() == wn.Bit() at all times, for the same n. |
| CHECK(x0.Bit() == w0.Bit()); |
| CHECK(x1.Bit() == w1.Bit()); |
| CHECK(x10.Bit() == w10.Bit()); |
| CHECK(jssp.Bit() == wjssp.Bit()); |
| CHECK(xzr.Bit() == wzr.Bit()); |
| CHECK(csp.Bit() == wcsp.Bit()); |
| } |
| |
| |
| TEST(stack_pointer_override) { |
| // This test generates some stack maintenance code, but the test only checks |
| // the reported state. |
| INIT_V8(); |
| SETUP(); |
| START(); |
| |
| // The default stack pointer in V8 is jssp, but for compatibility with W16, |
| // the test framework sets it to csp before calling the test. |
| CHECK(csp.Is(__ StackPointer())); |
| __ SetStackPointer(x0); |
| CHECK(x0.Is(__ StackPointer())); |
| __ SetStackPointer(jssp); |
| CHECK(jssp.Is(__ StackPointer())); |
| __ SetStackPointer(csp); |
| CHECK(csp.Is(__ StackPointer())); |
| |
| END(); |
| RUN(); |
| TEARDOWN(); |
| } |
| |
| |
| TEST(peek_poke_simple) { |
| INIT_V8(); |
| SETUP(); |
| START(); |
| |
| static const RegList x0_to_x3 = x0.Bit() | x1.Bit() | x2.Bit() | x3.Bit(); |
| static const RegList x10_to_x13 = x10.Bit() | x11.Bit() | |
| x12.Bit() | x13.Bit(); |
| |
| // The literal base is chosen to have two useful properties: |
| // * When multiplied by small values (such as a register index), this value |
| // is clearly readable in the result. |
| // * The value is not formed from repeating fixed-size smaller values, so it |
| // can be used to detect endianness-related errors. |
| uint64_t literal_base = 0x0100001000100101UL; |
| |
| // Initialize the registers. |
| __ Mov(x0, literal_base); |
| __ Add(x1, x0, x0); |
| __ Add(x2, x1, x0); |
| __ Add(x3, x2, x0); |
| |
| __ Claim(4); |
| |
| // Simple exchange. |
| // After this test: |
| // x0-x3 should be unchanged. |
| // w10-w13 should contain the lower words of x0-x3. |
| __ Poke(x0, 0); |
| __ Poke(x1, 8); |
| __ Poke(x2, 16); |
| __ Poke(x3, 24); |
| Clobber(&masm, x0_to_x3); |
| __ Peek(x0, 0); |
| __ Peek(x1, 8); |
| __ Peek(x2, 16); |
| __ Peek(x3, 24); |
| |
| __ Poke(w0, 0); |
| __ Poke(w1, 4); |
| __ Poke(w2, 8); |
| __ Poke(w3, 12); |
| Clobber(&masm, x10_to_x13); |
| __ Peek(w10, 0); |
| __ Peek(w11, 4); |
| __ Peek(w12, 8); |
| __ Peek(w13, 12); |
| |
| __ Drop(4); |
| |
| END(); |
| RUN(); |
| |
| CHECK_EQUAL_64(literal_base * 1, x0); |
| CHECK_EQUAL_64(literal_base * 2, x1); |
| CHECK_EQUAL_64(literal_base * 3, x2); |
| CHECK_EQUAL_64(literal_base * 4, x3); |
| |
| CHECK_EQUAL_64((literal_base * 1) & 0xffffffff, x10); |
| CHECK_EQUAL_64((literal_base * 2) & 0xffffffff, x11); |
| CHECK_EQUAL_64((literal_base * 3) & 0xffffffff, x12); |
| CHECK_EQUAL_64((literal_base * 4) & 0xffffffff, x13); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(peek_poke_unaligned) { |
| INIT_V8(); |
| SETUP(); |
| START(); |
| |
| // The literal base is chosen to have two useful properties: |
| // * When multiplied by small values (such as a register index), this value |
| // is clearly readable in the result. |
| // * The value is not formed from repeating fixed-size smaller values, so it |
| // can be used to detect endianness-related errors. |
| uint64_t literal_base = 0x0100001000100101UL; |
| |
| // Initialize the registers. |
| __ Mov(x0, literal_base); |
| __ Add(x1, x0, x0); |
| __ Add(x2, x1, x0); |
| __ Add(x3, x2, x0); |
| __ Add(x4, x3, x0); |
| __ Add(x5, x4, x0); |
| __ Add(x6, x5, x0); |
| |
| __ Claim(4); |
| |
| // Unaligned exchanges. |
| // After this test: |
| // x0-x6 should be unchanged. |
| // w10-w12 should contain the lower words of x0-x2. |
| __ Poke(x0, 1); |
| Clobber(&masm, x0.Bit()); |
| __ Peek(x0, 1); |
| __ Poke(x1, 2); |
| Clobber(&masm, x1.Bit()); |
| __ Peek(x1, 2); |
| __ Poke(x2, 3); |
| Clobber(&masm, x2.Bit()); |
| __ Peek(x2, 3); |
| __ Poke(x3, 4); |
| Clobber(&masm, x3.Bit()); |
| __ Peek(x3, 4); |
| __ Poke(x4, 5); |
| Clobber(&masm, x4.Bit()); |
| __ Peek(x4, 5); |
| __ Poke(x5, 6); |
| Clobber(&masm, x5.Bit()); |
| __ Peek(x5, 6); |
| __ Poke(x6, 7); |
| Clobber(&masm, x6.Bit()); |
| __ Peek(x6, 7); |
| |
| __ Poke(w0, 1); |
| Clobber(&masm, w10.Bit()); |
| __ Peek(w10, 1); |
| __ Poke(w1, 2); |
| Clobber(&masm, w11.Bit()); |
| __ Peek(w11, 2); |
| __ Poke(w2, 3); |
| Clobber(&masm, w12.Bit()); |
| __ Peek(w12, 3); |
| |
| __ Drop(4); |
| |
| END(); |
| RUN(); |
| |
| CHECK_EQUAL_64(literal_base * 1, x0); |
| CHECK_EQUAL_64(literal_base * 2, x1); |
| CHECK_EQUAL_64(literal_base * 3, x2); |
| CHECK_EQUAL_64(literal_base * 4, x3); |
| CHECK_EQUAL_64(literal_base * 5, x4); |
| CHECK_EQUAL_64(literal_base * 6, x5); |
| CHECK_EQUAL_64(literal_base * 7, x6); |
| |
| CHECK_EQUAL_64((literal_base * 1) & 0xffffffff, x10); |
| CHECK_EQUAL_64((literal_base * 2) & 0xffffffff, x11); |
| CHECK_EQUAL_64((literal_base * 3) & 0xffffffff, x12); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(peek_poke_endianness) { |
| INIT_V8(); |
| SETUP(); |
| START(); |
| |
| // The literal base is chosen to have two useful properties: |
| // * When multiplied by small values (such as a register index), this value |
| // is clearly readable in the result. |
| // * The value is not formed from repeating fixed-size smaller values, so it |
| // can be used to detect endianness-related errors. |
| uint64_t literal_base = 0x0100001000100101UL; |
| |
| // Initialize the registers. |
| __ Mov(x0, literal_base); |
| __ Add(x1, x0, x0); |
| |
| __ Claim(4); |
| |
| // Endianness tests. |
| // After this section: |
| // x4 should match x0[31:0]:x0[63:32] |
| // w5 should match w1[15:0]:w1[31:16] |
| __ Poke(x0, 0); |
| __ Poke(x0, 8); |
| __ Peek(x4, 4); |
| |
| __ Poke(w1, 0); |
| __ Poke(w1, 4); |
| __ Peek(w5, 2); |
| |
| __ Drop(4); |
| |
| END(); |
| RUN(); |
| |
| uint64_t x0_expected = literal_base * 1; |
| uint64_t x1_expected = literal_base * 2; |
| uint64_t x4_expected = (x0_expected << 32) | (x0_expected >> 32); |
| uint64_t x5_expected = ((x1_expected << 16) & 0xffff0000) | |
| ((x1_expected >> 16) & 0x0000ffff); |
| |
| CHECK_EQUAL_64(x0_expected, x0); |
| CHECK_EQUAL_64(x1_expected, x1); |
| CHECK_EQUAL_64(x4_expected, x4); |
| CHECK_EQUAL_64(x5_expected, x5); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(peek_poke_mixed) { |
| INIT_V8(); |
| SETUP(); |
| START(); |
| |
| // The literal base is chosen to have two useful properties: |
| // * When multiplied by small values (such as a register index), this value |
| // is clearly readable in the result. |
| // * The value is not formed from repeating fixed-size smaller values, so it |
| // can be used to detect endianness-related errors. |
| uint64_t literal_base = 0x0100001000100101UL; |
| |
| // Initialize the registers. |
| __ Mov(x0, literal_base); |
| __ Add(x1, x0, x0); |
| __ Add(x2, x1, x0); |
| __ Add(x3, x2, x0); |
| |
| __ Claim(4); |
| |
| // Mix with other stack operations. |
| // After this section: |
| // x0-x3 should be unchanged. |
| // x6 should match x1[31:0]:x0[63:32] |
| // w7 should match x1[15:0]:x0[63:48] |
| __ Poke(x1, 8); |
| __ Poke(x0, 0); |
| { |
| DCHECK(__ StackPointer().Is(csp)); |
| __ Mov(x4, __ StackPointer()); |
| __ SetStackPointer(x4); |
| |
| __ Poke(wzr, 0); // Clobber the space we're about to drop. |
| __ Drop(1, kWRegSize); |
| __ Peek(x6, 0); |
| __ Claim(1); |
| __ Peek(w7, 10); |
| __ Poke(x3, 28); |
| __ Poke(xzr, 0); // Clobber the space we're about to drop. |
| __ Drop(1); |
| __ Poke(x2, 12); |
| __ Push(w0); |
| |
| __ Mov(csp, __ StackPointer()); |
| __ SetStackPointer(csp); |
| } |
| |
| __ Pop(x0, x1, x2, x3); |
| |
| END(); |
| RUN(); |
| |
| uint64_t x0_expected = literal_base * 1; |
| uint64_t x1_expected = literal_base * 2; |
| uint64_t x2_expected = literal_base * 3; |
| uint64_t x3_expected = literal_base * 4; |
| uint64_t x6_expected = (x1_expected << 32) | (x0_expected >> 32); |
| uint64_t x7_expected = ((x1_expected << 16) & 0xffff0000) | |
| ((x0_expected >> 48) & 0x0000ffff); |
| |
| CHECK_EQUAL_64(x0_expected, x0); |
| CHECK_EQUAL_64(x1_expected, x1); |
| CHECK_EQUAL_64(x2_expected, x2); |
| CHECK_EQUAL_64(x3_expected, x3); |
| CHECK_EQUAL_64(x6_expected, x6); |
| CHECK_EQUAL_64(x7_expected, x7); |
| |
| TEARDOWN(); |
| } |
| |
| |
| // This enum is used only as an argument to the push-pop test helpers. |
| enum PushPopMethod { |
| // Push or Pop using the Push and Pop methods, with blocks of up to four |
| // registers. (Smaller blocks will be used if necessary.) |
| PushPopByFour, |
| |
| // Use Push<Size>RegList and Pop<Size>RegList to transfer the registers. |
| PushPopRegList |
| }; |
| |
| |
| // The maximum number of registers that can be used by the PushPopJssp* tests, |
| // where a reg_count field is provided. |
| static int const kPushPopJsspMaxRegCount = -1; |
| |
| // Test a simple push-pop pattern: |
| // * Claim <claim> bytes to set the stack alignment. |
| // * Push <reg_count> registers with size <reg_size>. |
| // * Clobber the register contents. |
| // * Pop <reg_count> registers to restore the original contents. |
| // * Drop <claim> bytes to restore the original stack pointer. |
| // |
| // Different push and pop methods can be specified independently to test for |
| // proper word-endian behaviour. |
| static void PushPopJsspSimpleHelper(int reg_count, |
| int claim, |
| int reg_size, |
| PushPopMethod push_method, |
| PushPopMethod pop_method) { |
| SETUP(); |
| |
| START(); |
| |
| // Registers in the TmpList can be used by the macro assembler for debug code |
| // (for example in 'Pop'), so we can't use them here. We can't use jssp |
| // because it will be the stack pointer for this test. |
| static RegList const allowed = ~(masm.TmpList()->list() | jssp.Bit()); |
| if (reg_count == kPushPopJsspMaxRegCount) { |
| reg_count = CountSetBits(allowed, kNumberOfRegisters); |
| } |
| // Work out which registers to use, based on reg_size. |
| Register r[kNumberOfRegisters]; |
| Register x[kNumberOfRegisters]; |
| RegList list = PopulateRegisterArray(NULL, x, r, reg_size, reg_count, |
| allowed); |
| |
| // The literal base is chosen to have two useful properties: |
| // * When multiplied by small values (such as a register index), this value |
| // is clearly readable in the result. |
| // * The value is not formed from repeating fixed-size smaller values, so it |
| // can be used to detect endianness-related errors. |
| uint64_t literal_base = 0x0100001000100101UL; |
| |
| { |
| DCHECK(__ StackPointer().Is(csp)); |
| __ Mov(jssp, __ StackPointer()); |
| __ SetStackPointer(jssp); |
| |
| int i; |
| |
| // Initialize the registers. |
| for (i = 0; i < reg_count; i++) { |
| // Always write into the X register, to ensure that the upper word is |
| // properly ignored by Push when testing W registers. |
| if (!x[i].IsZero()) { |
| __ Mov(x[i], literal_base * i); |
| } |
| } |
| |
| // Claim memory first, as requested. |
| __ Claim(claim, kByteSizeInBytes); |
| |
| switch (push_method) { |
| case PushPopByFour: |
| // Push high-numbered registers first (to the highest addresses). |
| for (i = reg_count; i >= 4; i -= 4) { |
| __ Push(r[i-1], r[i-2], r[i-3], r[i-4]); |
| } |
| // Finish off the leftovers. |
| switch (i) { |
| case 3: __ Push(r[2], r[1], r[0]); break; |
| case 2: __ Push(r[1], r[0]); break; |
| case 1: __ Push(r[0]); break; |
| default: DCHECK(i == 0); break; |
| } |
| break; |
| case PushPopRegList: |
| __ PushSizeRegList(list, reg_size); |
| break; |
| } |
| |
| // Clobber all the registers, to ensure that they get repopulated by Pop. |
| Clobber(&masm, list); |
| |
| switch (pop_method) { |
| case PushPopByFour: |
| // Pop low-numbered registers first (from the lowest addresses). |
| for (i = 0; i <= (reg_count-4); i += 4) { |
| __ Pop(r[i], r[i+1], r[i+2], r[i+3]); |
| } |
| // Finish off the leftovers. |
| switch (reg_count - i) { |
| case 3: __ Pop(r[i], r[i+1], r[i+2]); break; |
| case 2: __ Pop(r[i], r[i+1]); break; |
| case 1: __ Pop(r[i]); break; |
| default: DCHECK(i == reg_count); break; |
| } |
| break; |
| case PushPopRegList: |
| __ PopSizeRegList(list, reg_size); |
| break; |
| } |
| |
| // Drop memory to restore jssp. |
| __ Drop(claim, kByteSizeInBytes); |
| |
| __ Mov(csp, __ StackPointer()); |
| __ SetStackPointer(csp); |
| } |
| |
| END(); |
| |
| RUN(); |
| |
| // Check that the register contents were preserved. |
| // Always use CHECK_EQUAL_64, even when testing W registers, so we can test |
| // that the upper word was properly cleared by Pop. |
| literal_base &= (0xffffffffffffffffUL >> (64-reg_size)); |
| for (int i = 0; i < reg_count; i++) { |
| if (x[i].IsZero()) { |
| CHECK_EQUAL_64(0, x[i]); |
| } else { |
| CHECK_EQUAL_64(literal_base * i, x[i]); |
| } |
| } |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(push_pop_jssp_simple_32) { |
| INIT_V8(); |
| for (int claim = 0; claim <= 8; claim++) { |
| for (int count = 0; count <= 8; count++) { |
| PushPopJsspSimpleHelper(count, claim, kWRegSizeInBits, |
| PushPopByFour, PushPopByFour); |
| PushPopJsspSimpleHelper(count, claim, kWRegSizeInBits, |
| PushPopByFour, PushPopRegList); |
| PushPopJsspSimpleHelper(count, claim, kWRegSizeInBits, |
| PushPopRegList, PushPopByFour); |
| PushPopJsspSimpleHelper(count, claim, kWRegSizeInBits, |
| PushPopRegList, PushPopRegList); |
| } |
| // Test with the maximum number of registers. |
| PushPopJsspSimpleHelper(kPushPopJsspMaxRegCount, claim, kWRegSizeInBits, |
| PushPopByFour, PushPopByFour); |
| PushPopJsspSimpleHelper(kPushPopJsspMaxRegCount, claim, kWRegSizeInBits, |
| PushPopByFour, PushPopRegList); |
| PushPopJsspSimpleHelper(kPushPopJsspMaxRegCount, claim, kWRegSizeInBits, |
| PushPopRegList, PushPopByFour); |
| PushPopJsspSimpleHelper(kPushPopJsspMaxRegCount, claim, kWRegSizeInBits, |
| PushPopRegList, PushPopRegList); |
| } |
| } |
| |
| |
| TEST(push_pop_jssp_simple_64) { |
| INIT_V8(); |
| for (int claim = 0; claim <= 8; claim++) { |
| for (int count = 0; count <= 8; count++) { |
| PushPopJsspSimpleHelper(count, claim, kXRegSizeInBits, |
| PushPopByFour, PushPopByFour); |
| PushPopJsspSimpleHelper(count, claim, kXRegSizeInBits, |
| PushPopByFour, PushPopRegList); |
| PushPopJsspSimpleHelper(count, claim, kXRegSizeInBits, |
| PushPopRegList, PushPopByFour); |
| PushPopJsspSimpleHelper(count, claim, kXRegSizeInBits, |
| PushPopRegList, PushPopRegList); |
| } |
| // Test with the maximum number of registers. |
| PushPopJsspSimpleHelper(kPushPopJsspMaxRegCount, claim, kXRegSizeInBits, |
| PushPopByFour, PushPopByFour); |
| PushPopJsspSimpleHelper(kPushPopJsspMaxRegCount, claim, kXRegSizeInBits, |
| PushPopByFour, PushPopRegList); |
| PushPopJsspSimpleHelper(kPushPopJsspMaxRegCount, claim, kXRegSizeInBits, |
| PushPopRegList, PushPopByFour); |
| PushPopJsspSimpleHelper(kPushPopJsspMaxRegCount, claim, kXRegSizeInBits, |
| PushPopRegList, PushPopRegList); |
| } |
| } |
| |
| |
| // The maximum number of registers that can be used by the PushPopFPJssp* tests, |
| // where a reg_count field is provided. |
| static int const kPushPopFPJsspMaxRegCount = -1; |
| |
| // Test a simple push-pop pattern: |
| // * Claim <claim> bytes to set the stack alignment. |
| // * Push <reg_count> FP registers with size <reg_size>. |
| // * Clobber the register contents. |
| // * Pop <reg_count> FP registers to restore the original contents. |
| // * Drop <claim> bytes to restore the original stack pointer. |
| // |
| // Different push and pop methods can be specified independently to test for |
| // proper word-endian behaviour. |
| static void PushPopFPJsspSimpleHelper(int reg_count, |
| int claim, |
| int reg_size, |
| PushPopMethod push_method, |
| PushPopMethod pop_method) { |
| SETUP(); |
| |
| START(); |
| |
| // We can use any floating-point register. None of them are reserved for |
| // debug code, for example. |
| static RegList const allowed = ~0; |
| if (reg_count == kPushPopFPJsspMaxRegCount) { |
| reg_count = CountSetBits(allowed, kNumberOfFPRegisters); |
| } |
| // Work out which registers to use, based on reg_size. |
| FPRegister v[kNumberOfRegisters]; |
| FPRegister d[kNumberOfRegisters]; |
| RegList list = PopulateFPRegisterArray(NULL, d, v, reg_size, reg_count, |
| allowed); |
| |
| // The literal base is chosen to have two useful properties: |
| // * When multiplied (using an integer) by small values (such as a register |
| // index), this value is clearly readable in the result. |
| // * The value is not formed from repeating fixed-size smaller values, so it |
| // can be used to detect endianness-related errors. |
| // * It is never a floating-point NaN, and will therefore always compare |
| // equal to itself. |
| uint64_t literal_base = 0x0100001000100101UL; |
| |
| { |
| DCHECK(__ StackPointer().Is(csp)); |
| __ Mov(jssp, __ StackPointer()); |
| __ SetStackPointer(jssp); |
| |
| int i; |
| |
| // Initialize the registers, using X registers to load the literal. |
| __ Mov(x0, 0); |
| __ Mov(x1, literal_base); |
| for (i = 0; i < reg_count; i++) { |
| // Always write into the D register, to ensure that the upper word is |
| // properly ignored by Push when testing S registers. |
| __ Fmov(d[i], x0); |
| // Calculate the next literal. |
| __ Add(x0, x0, x1); |
| } |
| |
| // Claim memory first, as requested. |
| __ Claim(claim, kByteSizeInBytes); |
| |
| switch (push_method) { |
| case PushPopByFour: |
| // Push high-numbered registers first (to the highest addresses). |
| for (i = reg_count; i >= 4; i -= 4) { |
| __ Push(v[i-1], v[i-2], v[i-3], v[i-4]); |
| } |
| // Finish off the leftovers. |
| switch (i) { |
| case 3: __ Push(v[2], v[1], v[0]); break; |
| case 2: __ Push(v[1], v[0]); break; |
| case 1: __ Push(v[0]); break; |
| default: DCHECK(i == 0); break; |
| } |
| break; |
| case PushPopRegList: |
| __ PushSizeRegList(list, reg_size, CPURegister::kFPRegister); |
| break; |
| } |
| |
| // Clobber all the registers, to ensure that they get repopulated by Pop. |
| ClobberFP(&masm, list); |
| |
| switch (pop_method) { |
| case PushPopByFour: |
| // Pop low-numbered registers first (from the lowest addresses). |
| for (i = 0; i <= (reg_count-4); i += 4) { |
| __ Pop(v[i], v[i+1], v[i+2], v[i+3]); |
| } |
| // Finish off the leftovers. |
| switch (reg_count - i) { |
| case 3: __ Pop(v[i], v[i+1], v[i+2]); break; |
| case 2: __ Pop(v[i], v[i+1]); break; |
| case 1: __ Pop(v[i]); break; |
| default: DCHECK(i == reg_count); break; |
| } |
| break; |
| case PushPopRegList: |
| __ PopSizeRegList(list, reg_size, CPURegister::kFPRegister); |
| break; |
| } |
| |
| // Drop memory to restore jssp. |
| __ Drop(claim, kByteSizeInBytes); |
| |
| __ Mov(csp, __ StackPointer()); |
| __ SetStackPointer(csp); |
| } |
| |
| END(); |
| |
| RUN(); |
| |
| // Check that the register contents were preserved. |
| // Always use CHECK_EQUAL_FP64, even when testing S registers, so we can |
| // test that the upper word was properly cleared by Pop. |
| literal_base &= (0xffffffffffffffffUL >> (64-reg_size)); |
| for (int i = 0; i < reg_count; i++) { |
| uint64_t literal = literal_base * i; |
| double expected; |
| memcpy(&expected, &literal, sizeof(expected)); |
| CHECK_EQUAL_FP64(expected, d[i]); |
| } |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(push_pop_fp_jssp_simple_32) { |
| INIT_V8(); |
| for (int claim = 0; claim <= 8; claim++) { |
| for (int count = 0; count <= 8; count++) { |
| PushPopFPJsspSimpleHelper(count, claim, kSRegSizeInBits, |
| PushPopByFour, PushPopByFour); |
| PushPopFPJsspSimpleHelper(count, claim, kSRegSizeInBits, |
| PushPopByFour, PushPopRegList); |
| PushPopFPJsspSimpleHelper(count, claim, kSRegSizeInBits, |
| PushPopRegList, PushPopByFour); |
| PushPopFPJsspSimpleHelper(count, claim, kSRegSizeInBits, |
| PushPopRegList, PushPopRegList); |
| } |
| // Test with the maximum number of registers. |
| PushPopFPJsspSimpleHelper(kPushPopFPJsspMaxRegCount, claim, kSRegSizeInBits, |
| PushPopByFour, PushPopByFour); |
| PushPopFPJsspSimpleHelper(kPushPopFPJsspMaxRegCount, claim, kSRegSizeInBits, |
| PushPopByFour, PushPopRegList); |
| PushPopFPJsspSimpleHelper(kPushPopFPJsspMaxRegCount, claim, kSRegSizeInBits, |
| PushPopRegList, PushPopByFour); |
| PushPopFPJsspSimpleHelper(kPushPopFPJsspMaxRegCount, claim, kSRegSizeInBits, |
| PushPopRegList, PushPopRegList); |
| } |
| } |
| |
| |
| TEST(push_pop_fp_jssp_simple_64) { |
| INIT_V8(); |
| for (int claim = 0; claim <= 8; claim++) { |
| for (int count = 0; count <= 8; count++) { |
| PushPopFPJsspSimpleHelper(count, claim, kDRegSizeInBits, |
| PushPopByFour, PushPopByFour); |
| PushPopFPJsspSimpleHelper(count, claim, kDRegSizeInBits, |
| PushPopByFour, PushPopRegList); |
| PushPopFPJsspSimpleHelper(count, claim, kDRegSizeInBits, |
| PushPopRegList, PushPopByFour); |
| PushPopFPJsspSimpleHelper(count, claim, kDRegSizeInBits, |
| PushPopRegList, PushPopRegList); |
| } |
| // Test with the maximum number of registers. |
| PushPopFPJsspSimpleHelper(kPushPopFPJsspMaxRegCount, claim, kDRegSizeInBits, |
| PushPopByFour, PushPopByFour); |
| PushPopFPJsspSimpleHelper(kPushPopFPJsspMaxRegCount, claim, kDRegSizeInBits, |
| PushPopByFour, PushPopRegList); |
| PushPopFPJsspSimpleHelper(kPushPopFPJsspMaxRegCount, claim, kDRegSizeInBits, |
| PushPopRegList, PushPopByFour); |
| PushPopFPJsspSimpleHelper(kPushPopFPJsspMaxRegCount, claim, kDRegSizeInBits, |
| PushPopRegList, PushPopRegList); |
| } |
| } |
| |
| |
| // Push and pop data using an overlapping combination of Push/Pop and |
| // RegList-based methods. |
| static void PushPopJsspMixedMethodsHelper(int claim, int reg_size) { |
| SETUP(); |
| |
| // Registers x8 and x9 are used by the macro assembler for debug code (for |
| // example in 'Pop'), so we can't use them here. We can't use jssp because it |
| // will be the stack pointer for this test. |
| static RegList const allowed = |
| ~(x8.Bit() | x9.Bit() | jssp.Bit() | xzr.Bit()); |
| // Work out which registers to use, based on reg_size. |
| Register r[10]; |
| Register x[10]; |
| PopulateRegisterArray(NULL, x, r, reg_size, 10, allowed); |
| |
| // Calculate some handy register lists. |
| RegList r0_to_r3 = 0; |
| for (int i = 0; i <= 3; i++) { |
| r0_to_r3 |= x[i].Bit(); |
| } |
| RegList r4_to_r5 = 0; |
| for (int i = 4; i <= 5; i++) { |
| r4_to_r5 |= x[i].Bit(); |
| } |
| RegList r6_to_r9 = 0; |
| for (int i = 6; i <= 9; i++) { |
| r6_to_r9 |= x[i].Bit(); |
| } |
| |
| // The literal base is chosen to have two useful properties: |
| // * When multiplied by small values (such as a register index), this value |
| // is clearly readable in the result. |
| // * The value is not formed from repeating fixed-size smaller values, so it |
| // can be used to detect endianness-related errors. |
| uint64_t literal_base = 0x0100001000100101UL; |
| |
| START(); |
| { |
| DCHECK(__ StackPointer().Is(csp)); |
| __ Mov(jssp, __ StackPointer()); |
| __ SetStackPointer(jssp); |
| |
| // Claim memory first, as requested. |
| __ Claim(claim, kByteSizeInBytes); |
| |
| __ Mov(x[3], literal_base * 3); |
| __ Mov(x[2], literal_base * 2); |
| __ Mov(x[1], literal_base * 1); |
| __ Mov(x[0], literal_base * 0); |
| |
| __ PushSizeRegList(r0_to_r3, reg_size); |
| __ Push(r[3], r[2]); |
| |
| Clobber(&masm, r0_to_r3); |
| __ PopSizeRegList(r0_to_r3, reg_size); |
| |
| __ Push(r[2], r[1], r[3], r[0]); |
| |
| Clobber(&masm, r4_to_r5); |
| __ Pop(r[4], r[5]); |
| Clobber(&masm, r6_to_r9); |
| __ Pop(r[6], r[7], r[8], r[9]); |
| |
| // Drop memory to restore jssp. |
| __ Drop(claim, kByteSizeInBytes); |
| |
| __ Mov(csp, __ StackPointer()); |
| __ SetStackPointer(csp); |
| } |
| |
| END(); |
| |
| RUN(); |
| |
| // Always use CHECK_EQUAL_64, even when testing W registers, so we can test |
| // that the upper word was properly cleared by Pop. |
| literal_base &= (0xffffffffffffffffUL >> (64-reg_size)); |
| |
| CHECK_EQUAL_64(literal_base * 3, x[9]); |
| CHECK_EQUAL_64(literal_base * 2, x[8]); |
| CHECK_EQUAL_64(literal_base * 0, x[7]); |
| CHECK_EQUAL_64(literal_base * 3, x[6]); |
| CHECK_EQUAL_64(literal_base * 1, x[5]); |
| CHECK_EQUAL_64(literal_base * 2, x[4]); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(push_pop_jssp_mixed_methods_64) { |
| INIT_V8(); |
| for (int claim = 0; claim <= 8; claim++) { |
| PushPopJsspMixedMethodsHelper(claim, kXRegSizeInBits); |
| } |
| } |
| |
| |
| TEST(push_pop_jssp_mixed_methods_32) { |
| INIT_V8(); |
| for (int claim = 0; claim <= 8; claim++) { |
| PushPopJsspMixedMethodsHelper(claim, kWRegSizeInBits); |
| } |
| } |
| |
| |
| // Push and pop data using overlapping X- and W-sized quantities. |
| static void PushPopJsspWXOverlapHelper(int reg_count, int claim) { |
| // This test emits rather a lot of code. |
| SETUP_SIZE(BUF_SIZE * 2); |
| |
| // Work out which registers to use, based on reg_size. |
| Register tmp = x8; |
| static RegList const allowed = ~(tmp.Bit() | jssp.Bit()); |
| if (reg_count == kPushPopJsspMaxRegCount) { |
| reg_count = CountSetBits(allowed, kNumberOfRegisters); |
| } |
| Register w[kNumberOfRegisters]; |
| Register x[kNumberOfRegisters]; |
| RegList list = PopulateRegisterArray(w, x, NULL, 0, reg_count, allowed); |
| |
| // The number of W-sized slots we expect to pop. When we pop, we alternate |
| // between W and X registers, so we need reg_count*1.5 W-sized slots. |
| int const requested_w_slots = reg_count + reg_count / 2; |
| |
| // Track what _should_ be on the stack, using W-sized slots. |
| static int const kMaxWSlots = kNumberOfRegisters + kNumberOfRegisters / 2; |
| uint32_t stack[kMaxWSlots]; |
| for (int i = 0; i < kMaxWSlots; i++) { |
| stack[i] = 0xdeadbeef; |
| } |
| |
| // The literal base is chosen to have two useful properties: |
| // * When multiplied by small values (such as a register index), this value |
| // is clearly readable in the result. |
| // * The value is not formed from repeating fixed-size smaller values, so it |
| // can be used to detect endianness-related errors. |
| static uint64_t const literal_base = 0x0100001000100101UL; |
| static uint64_t const literal_base_hi = literal_base >> 32; |
| static uint64_t const literal_base_lo = literal_base & 0xffffffff; |
| static uint64_t const literal_base_w = literal_base & 0xffffffff; |
| |
| START(); |
| { |
| DCHECK(__ StackPointer().Is(csp)); |
| __ Mov(jssp, __ StackPointer()); |
| __ SetStackPointer(jssp); |
| |
| // Initialize the registers. |
| for (int i = 0; i < reg_count; i++) { |
| // Always write into the X register, to ensure that the upper word is |
| // properly ignored by Push when testing W registers. |
| if (!x[i].IsZero()) { |
| __ Mov(x[i], literal_base * i); |
| } |
| } |
| |
| // Claim memory first, as requested. |
| __ Claim(claim, kByteSizeInBytes); |
| |
| // The push-pop pattern is as follows: |
| // Push: Pop: |
| // x[0](hi) -> w[0] |
| // x[0](lo) -> x[1](hi) |
| // w[1] -> x[1](lo) |
| // w[1] -> w[2] |
| // x[2](hi) -> x[2](hi) |
| // x[2](lo) -> x[2](lo) |
| // x[2](hi) -> w[3] |
| // x[2](lo) -> x[4](hi) |
| // x[2](hi) -> x[4](lo) |
| // x[2](lo) -> w[5] |
| // w[3] -> x[5](hi) |
| // w[3] -> x[6](lo) |
| // w[3] -> w[7] |
| // w[3] -> x[8](hi) |
| // x[4](hi) -> x[8](lo) |
| // x[4](lo) -> w[9] |
| // ... pattern continues ... |
| // |
| // That is, registers are pushed starting with the lower numbers, |
| // alternating between x and w registers, and pushing i%4+1 copies of each, |
| // where i is the register number. |
| // Registers are popped starting with the higher numbers one-by-one, |
| // alternating between x and w registers, but only popping one at a time. |
| // |
| // This pattern provides a wide variety of alignment effects and overlaps. |
| |
| // ---- Push ---- |
| |
| int active_w_slots = 0; |
| for (int i = 0; active_w_slots < requested_w_slots; i++) { |
| DCHECK(i < reg_count); |
| // In order to test various arguments to PushMultipleTimes, and to try to |
| // exercise different alignment and overlap effects, we push each |
| // register a different number of times. |
| int times = i % 4 + 1; |
| if (i & 1) { |
| // Push odd-numbered registers as W registers. |
| if (i & 2) { |
| __ PushMultipleTimes(w[i], times); |
| } else { |
| // Use a register to specify the count. |
| __ Mov(tmp.W(), times); |
| __ PushMultipleTimes(w[i], tmp.W()); |
| } |
| // Fill in the expected stack slots. |
| for (int j = 0; j < times; j++) { |
| if (w[i].Is(wzr)) { |
| // The zero register always writes zeroes. |
| stack[active_w_slots++] = 0; |
| } else { |
| stack[active_w_slots++] = literal_base_w * i; |
| } |
| } |
| } else { |
| // Push even-numbered registers as X registers. |
| if (i & 2) { |
| __ PushMultipleTimes(x[i], times); |
| } else { |
| // Use a register to specify the count. |
| __ Mov(tmp, times); |
| __ PushMultipleTimes(x[i], tmp); |
| } |
| // Fill in the expected stack slots. |
| for (int j = 0; j < times; j++) { |
| if (x[i].IsZero()) { |
| // The zero register always writes zeroes. |
| stack[active_w_slots++] = 0; |
| stack[active_w_slots++] = 0; |
| } else { |
| stack[active_w_slots++] = literal_base_hi * i; |
| stack[active_w_slots++] = literal_base_lo * i; |
| } |
| } |
| } |
| } |
| // Because we were pushing several registers at a time, we probably pushed |
| // more than we needed to. |
| if (active_w_slots > requested_w_slots) { |
| __ Drop(active_w_slots - requested_w_slots, kWRegSize); |
| // Bump the number of active W-sized slots back to where it should be, |
| // and fill the empty space with a dummy value. |
| do { |
| stack[active_w_slots--] = 0xdeadbeef; |
| } while (active_w_slots > requested_w_slots); |
| } |
| |
| // ---- Pop ---- |
| |
| Clobber(&masm, list); |
| |
| // If popping an even number of registers, the first one will be X-sized. |
| // Otherwise, the first one will be W-sized. |
| bool next_is_64 = !(reg_count & 1); |
| for (int i = reg_count-1; i >= 0; i--) { |
| if (next_is_64) { |
| __ Pop(x[i]); |
| active_w_slots -= 2; |
| } else { |
| __ Pop(w[i]); |
| active_w_slots -= 1; |
| } |
| next_is_64 = !next_is_64; |
| } |
| DCHECK(active_w_slots == 0); |
| |
| // Drop memory to restore jssp. |
| __ Drop(claim, kByteSizeInBytes); |
| |
| __ Mov(csp, __ StackPointer()); |
| __ SetStackPointer(csp); |
| } |
| |
| END(); |
| |
| RUN(); |
| |
| int slot = 0; |
| for (int i = 0; i < reg_count; i++) { |
| // Even-numbered registers were written as W registers. |
| // Odd-numbered registers were written as X registers. |
| bool expect_64 = (i & 1); |
| uint64_t expected; |
| |
| if (expect_64) { |
| uint64_t hi = stack[slot++]; |
| uint64_t lo = stack[slot++]; |
| expected = (hi << 32) | lo; |
| } else { |
| expected = stack[slot++]; |
| } |
| |
| // Always use CHECK_EQUAL_64, even when testing W registers, so we can |
| // test that the upper word was properly cleared by Pop. |
| if (x[i].IsZero()) { |
| CHECK_EQUAL_64(0, x[i]); |
| } else { |
| CHECK_EQUAL_64(expected, x[i]); |
| } |
| } |
| DCHECK(slot == requested_w_slots); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(push_pop_jssp_wx_overlap) { |
| INIT_V8(); |
| for (int claim = 0; claim <= 8; claim++) { |
| for (int count = 1; count <= 8; count++) { |
| PushPopJsspWXOverlapHelper(count, claim); |
| PushPopJsspWXOverlapHelper(count, claim); |
| PushPopJsspWXOverlapHelper(count, claim); |
| PushPopJsspWXOverlapHelper(count, claim); |
| } |
| // Test with the maximum number of registers. |
| PushPopJsspWXOverlapHelper(kPushPopJsspMaxRegCount, claim); |
| PushPopJsspWXOverlapHelper(kPushPopJsspMaxRegCount, claim); |
| PushPopJsspWXOverlapHelper(kPushPopJsspMaxRegCount, claim); |
| PushPopJsspWXOverlapHelper(kPushPopJsspMaxRegCount, claim); |
| } |
| } |
| |
| |
| TEST(push_pop_csp) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| |
| DCHECK(csp.Is(__ StackPointer())); |
| |
| __ Mov(x3, 0x3333333333333333UL); |
| __ Mov(x2, 0x2222222222222222UL); |
| __ Mov(x1, 0x1111111111111111UL); |
| __ Mov(x0, 0x0000000000000000UL); |
| __ Claim(2); |
| __ PushXRegList(x0.Bit() | x1.Bit() | x2.Bit() | x3.Bit()); |
| __ Push(x3, x2); |
| __ PopXRegList(x0.Bit() | x1.Bit() | x2.Bit() | x3.Bit()); |
| __ Push(x2, x1, x3, x0); |
| __ Pop(x4, x5); |
| __ Pop(x6, x7, x8, x9); |
| |
| __ Claim(2); |
| __ PushWRegList(w0.Bit() | w1.Bit() | w2.Bit() | w3.Bit()); |
| __ Push(w3, w1, w2, w0); |
| __ PopWRegList(w10.Bit() | w11.Bit() | w12.Bit() | w13.Bit()); |
| __ Pop(w14, w15, w16, w17); |
| |
| __ Claim(2); |
| __ Push(w2, w2, w1, w1); |
| __ Push(x3, x3); |
| __ Pop(w18, w19, w20, w21); |
| __ Pop(x22, x23); |
| |
| __ Claim(2); |
| __ PushXRegList(x1.Bit() | x22.Bit()); |
| __ PopXRegList(x24.Bit() | x26.Bit()); |
| |
| __ Claim(2); |
| __ PushWRegList(w1.Bit() | w2.Bit() | w4.Bit() | w22.Bit()); |
| __ PopWRegList(w25.Bit() | w27.Bit() | w28.Bit() | w29.Bit()); |
| |
| __ Claim(2); |
| __ PushXRegList(0); |
| __ PopXRegList(0); |
| __ PushXRegList(0xffffffff); |
| __ PopXRegList(0xffffffff); |
| __ Drop(12); |
| |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x1111111111111111UL, x3); |
| CHECK_EQUAL_64(0x0000000000000000UL, x2); |
| CHECK_EQUAL_64(0x3333333333333333UL, x1); |
| CHECK_EQUAL_64(0x2222222222222222UL, x0); |
| CHECK_EQUAL_64(0x3333333333333333UL, x9); |
| CHECK_EQUAL_64(0x2222222222222222UL, x8); |
| CHECK_EQUAL_64(0x0000000000000000UL, x7); |
| CHECK_EQUAL_64(0x3333333333333333UL, x6); |
| CHECK_EQUAL_64(0x1111111111111111UL, x5); |
| CHECK_EQUAL_64(0x2222222222222222UL, x4); |
| |
| CHECK_EQUAL_32(0x11111111U, w13); |
| CHECK_EQUAL_32(0x33333333U, w12); |
| CHECK_EQUAL_32(0x00000000U, w11); |
| CHECK_EQUAL_32(0x22222222U, w10); |
| CHECK_EQUAL_32(0x11111111U, w17); |
| CHECK_EQUAL_32(0x00000000U, w16); |
| CHECK_EQUAL_32(0x33333333U, w15); |
| CHECK_EQUAL_32(0x22222222U, w14); |
| |
| CHECK_EQUAL_32(0x11111111U, w18); |
| CHECK_EQUAL_32(0x11111111U, w19); |
| CHECK_EQUAL_32(0x11111111U, w20); |
| CHECK_EQUAL_32(0x11111111U, w21); |
| CHECK_EQUAL_64(0x3333333333333333UL, x22); |
| CHECK_EQUAL_64(0x0000000000000000UL, x23); |
| |
| CHECK_EQUAL_64(0x3333333333333333UL, x24); |
| CHECK_EQUAL_64(0x3333333333333333UL, x26); |
| |
| CHECK_EQUAL_32(0x33333333U, w25); |
| CHECK_EQUAL_32(0x00000000U, w27); |
| CHECK_EQUAL_32(0x22222222U, w28); |
| CHECK_EQUAL_32(0x33333333U, w29); |
| TEARDOWN(); |
| } |
| |
| |
| TEST(push_queued) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| |
| DCHECK(__ StackPointer().Is(csp)); |
| __ Mov(jssp, __ StackPointer()); |
| __ SetStackPointer(jssp); |
| |
| MacroAssembler::PushPopQueue queue(&masm); |
| |
| // Queue up registers. |
| queue.Queue(x0); |
| queue.Queue(x1); |
| queue.Queue(x2); |
| queue.Queue(x3); |
| |
| queue.Queue(w4); |
| queue.Queue(w5); |
| queue.Queue(w6); |
| |
| queue.Queue(d0); |
| queue.Queue(d1); |
| |
| queue.Queue(s2); |
| |
| __ Mov(x0, 0x1234000000000000); |
| __ Mov(x1, 0x1234000100010001); |
| __ Mov(x2, 0x1234000200020002); |
| __ Mov(x3, 0x1234000300030003); |
| __ Mov(w4, 0x12340004); |
| __ Mov(w5, 0x12340005); |
| __ Mov(w6, 0x12340006); |
| __ Fmov(d0, 123400.0); |
| __ Fmov(d1, 123401.0); |
| __ Fmov(s2, 123402.0); |
| |
| // Actually push them. |
| queue.PushQueued(); |
| |
| Clobber(&masm, CPURegList(CPURegister::kRegister, kXRegSizeInBits, 0, 6)); |
| Clobber(&masm, CPURegList(CPURegister::kFPRegister, kDRegSizeInBits, 0, 2)); |
| |
| // Pop them conventionally. |
| __ Pop(s2); |
| __ Pop(d1, d0); |
| __ Pop(w6, w5, w4); |
| __ Pop(x3, x2, x1, x0); |
| |
| __ Mov(csp, __ StackPointer()); |
| __ SetStackPointer(csp); |
| |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x1234000000000000, x0); |
| CHECK_EQUAL_64(0x1234000100010001, x1); |
| CHECK_EQUAL_64(0x1234000200020002, x2); |
| CHECK_EQUAL_64(0x1234000300030003, x3); |
| |
| CHECK_EQUAL_32(0x12340004, w4); |
| CHECK_EQUAL_32(0x12340005, w5); |
| CHECK_EQUAL_32(0x12340006, w6); |
| |
| CHECK_EQUAL_FP64(123400.0, d0); |
| CHECK_EQUAL_FP64(123401.0, d1); |
| |
| CHECK_EQUAL_FP32(123402.0, s2); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(pop_queued) { |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| |
| DCHECK(__ StackPointer().Is(csp)); |
| __ Mov(jssp, __ StackPointer()); |
| __ SetStackPointer(jssp); |
| |
| MacroAssembler::PushPopQueue queue(&masm); |
| |
| __ Mov(x0, 0x1234000000000000); |
| __ Mov(x1, 0x1234000100010001); |
| __ Mov(x2, 0x1234000200020002); |
| __ Mov(x3, 0x1234000300030003); |
| __ Mov(w4, 0x12340004); |
| __ Mov(w5, 0x12340005); |
| __ Mov(w6, 0x12340006); |
| __ Fmov(d0, 123400.0); |
| __ Fmov(d1, 123401.0); |
| __ Fmov(s2, 123402.0); |
| |
| // Push registers conventionally. |
| __ Push(x0, x1, x2, x3); |
| __ Push(w4, w5, w6); |
| __ Push(d0, d1); |
| __ Push(s2); |
| |
| // Queue up a pop. |
| queue.Queue(s2); |
| |
| queue.Queue(d1); |
| queue.Queue(d0); |
| |
| queue.Queue(w6); |
| queue.Queue(w5); |
| queue.Queue(w4); |
| |
| queue.Queue(x3); |
| queue.Queue(x2); |
| queue.Queue(x1); |
| queue.Queue(x0); |
| |
| Clobber(&masm, CPURegList(CPURegister::kRegister, kXRegSizeInBits, 0, 6)); |
| Clobber(&masm, CPURegList(CPURegister::kFPRegister, kDRegSizeInBits, 0, 2)); |
| |
| // Actually pop them. |
| queue.PopQueued(); |
| |
| __ Mov(csp, __ StackPointer()); |
| __ SetStackPointer(csp); |
| |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x1234000000000000, x0); |
| CHECK_EQUAL_64(0x1234000100010001, x1); |
| CHECK_EQUAL_64(0x1234000200020002, x2); |
| CHECK_EQUAL_64(0x1234000300030003, x3); |
| |
| CHECK_EQUAL_64(0x0000000012340004, x4); |
| CHECK_EQUAL_64(0x0000000012340005, x5); |
| CHECK_EQUAL_64(0x0000000012340006, x6); |
| |
| CHECK_EQUAL_FP64(123400.0, d0); |
| CHECK_EQUAL_FP64(123401.0, d1); |
| |
| CHECK_EQUAL_FP32(123402.0, s2); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(jump_both_smi) { |
| INIT_V8(); |
| SETUP(); |
| |
| Label cond_pass_00, cond_pass_01, cond_pass_10, cond_pass_11; |
| Label cond_fail_00, cond_fail_01, cond_fail_10, cond_fail_11; |
| Label return1, return2, return3, done; |
| |
| START(); |
| |
| __ Mov(x0, 0x5555555500000001UL); // A pointer. |
| __ Mov(x1, 0xaaaaaaaa00000001UL); // A pointer. |
| __ Mov(x2, 0x1234567800000000UL); // A smi. |
| __ Mov(x3, 0x8765432100000000UL); // A smi. |
| __ Mov(x4, 0xdead); |
| __ Mov(x5, 0xdead); |
| __ Mov(x6, 0xdead); |
| __ Mov(x7, 0xdead); |
| |
| __ JumpIfBothSmi(x0, x1, &cond_pass_00, &cond_fail_00); |
| __ Bind(&return1); |
| __ JumpIfBothSmi(x0, x2, &cond_pass_01, &cond_fail_01); |
| __ Bind(&return2); |
| __ JumpIfBothSmi(x2, x1, &cond_pass_10, &cond_fail_10); |
| __ Bind(&return3); |
| __ JumpIfBothSmi(x2, x3, &cond_pass_11, &cond_fail_11); |
| |
| __ Bind(&cond_fail_00); |
| __ Mov(x4, 0); |
| __ B(&return1); |
| __ Bind(&cond_pass_00); |
| __ Mov(x4, 1); |
| __ B(&return1); |
| |
| __ Bind(&cond_fail_01); |
| __ Mov(x5, 0); |
| __ B(&return2); |
| __ Bind(&cond_pass_01); |
| __ Mov(x5, 1); |
| __ B(&return2); |
| |
| __ Bind(&cond_fail_10); |
| __ Mov(x6, 0); |
| __ B(&return3); |
| __ Bind(&cond_pass_10); |
| __ Mov(x6, 1); |
| __ B(&return3); |
| |
| __ Bind(&cond_fail_11); |
| __ Mov(x7, 0); |
| __ B(&done); |
| __ Bind(&cond_pass_11); |
| __ Mov(x7, 1); |
| |
| __ Bind(&done); |
| |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x5555555500000001UL, x0); |
| CHECK_EQUAL_64(0xaaaaaaaa00000001UL, x1); |
| CHECK_EQUAL_64(0x1234567800000000UL, x2); |
| CHECK_EQUAL_64(0x8765432100000000UL, x3); |
| CHECK_EQUAL_64(0, x4); |
| CHECK_EQUAL_64(0, x5); |
| CHECK_EQUAL_64(0, x6); |
| CHECK_EQUAL_64(1, x7); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(jump_either_smi) { |
| INIT_V8(); |
| SETUP(); |
| |
| Label cond_pass_00, cond_pass_01, cond_pass_10, cond_pass_11; |
| Label cond_fail_00, cond_fail_01, cond_fail_10, cond_fail_11; |
| Label return1, return2, return3, done; |
| |
| START(); |
| |
| __ Mov(x0, 0x5555555500000001UL); // A pointer. |
| __ Mov(x1, 0xaaaaaaaa00000001UL); // A pointer. |
| __ Mov(x2, 0x1234567800000000UL); // A smi. |
| __ Mov(x3, 0x8765432100000000UL); // A smi. |
| __ Mov(x4, 0xdead); |
| __ Mov(x5, 0xdead); |
| __ Mov(x6, 0xdead); |
| __ Mov(x7, 0xdead); |
| |
| __ JumpIfEitherSmi(x0, x1, &cond_pass_00, &cond_fail_00); |
| __ Bind(&return1); |
| __ JumpIfEitherSmi(x0, x2, &cond_pass_01, &cond_fail_01); |
| __ Bind(&return2); |
| __ JumpIfEitherSmi(x2, x1, &cond_pass_10, &cond_fail_10); |
| __ Bind(&return3); |
| __ JumpIfEitherSmi(x2, x3, &cond_pass_11, &cond_fail_11); |
| |
| __ Bind(&cond_fail_00); |
| __ Mov(x4, 0); |
| __ B(&return1); |
| __ Bind(&cond_pass_00); |
| __ Mov(x4, 1); |
| __ B(&return1); |
| |
| __ Bind(&cond_fail_01); |
| __ Mov(x5, 0); |
| __ B(&return2); |
| __ Bind(&cond_pass_01); |
| __ Mov(x5, 1); |
| __ B(&return2); |
| |
| __ Bind(&cond_fail_10); |
| __ Mov(x6, 0); |
| __ B(&return3); |
| __ Bind(&cond_pass_10); |
| __ Mov(x6, 1); |
| __ B(&return3); |
| |
| __ Bind(&cond_fail_11); |
| __ Mov(x7, 0); |
| __ B(&done); |
| __ Bind(&cond_pass_11); |
| __ Mov(x7, 1); |
| |
| __ Bind(&done); |
| |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0x5555555500000001UL, x0); |
| CHECK_EQUAL_64(0xaaaaaaaa00000001UL, x1); |
| CHECK_EQUAL_64(0x1234567800000000UL, x2); |
| CHECK_EQUAL_64(0x8765432100000000UL, x3); |
| CHECK_EQUAL_64(0, x4); |
| CHECK_EQUAL_64(1, x5); |
| CHECK_EQUAL_64(1, x6); |
| CHECK_EQUAL_64(1, x7); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(noreg) { |
| // This test doesn't generate any code, but it verifies some invariants |
| // related to NoReg. |
| CHECK(NoReg.Is(NoFPReg)); |
| CHECK(NoFPReg.Is(NoReg)); |
| CHECK(NoReg.Is(NoCPUReg)); |
| CHECK(NoCPUReg.Is(NoReg)); |
| CHECK(NoFPReg.Is(NoCPUReg)); |
| CHECK(NoCPUReg.Is(NoFPReg)); |
| |
| CHECK(NoReg.IsNone()); |
| CHECK(NoFPReg.IsNone()); |
| CHECK(NoCPUReg.IsNone()); |
| } |
| |
| |
| TEST(isvalid) { |
| // This test doesn't generate any code, but it verifies some invariants |
| // related to IsValid(). |
| CHECK(!NoReg.IsValid()); |
| CHECK(!NoFPReg.IsValid()); |
| CHECK(!NoCPUReg.IsValid()); |
| |
| CHECK(x0.IsValid()); |
| CHECK(w0.IsValid()); |
| CHECK(x30.IsValid()); |
| CHECK(w30.IsValid()); |
| CHECK(xzr.IsValid()); |
| CHECK(wzr.IsValid()); |
| |
| CHECK(csp.IsValid()); |
| CHECK(wcsp.IsValid()); |
| |
| CHECK(d0.IsValid()); |
| CHECK(s0.IsValid()); |
| CHECK(d31.IsValid()); |
| CHECK(s31.IsValid()); |
| |
| CHECK(x0.IsValidRegister()); |
| CHECK(w0.IsValidRegister()); |
| CHECK(xzr.IsValidRegister()); |
| CHECK(wzr.IsValidRegister()); |
| CHECK(csp.IsValidRegister()); |
| CHECK(wcsp.IsValidRegister()); |
| CHECK(!x0.IsValidFPRegister()); |
| CHECK(!w0.IsValidFPRegister()); |
| CHECK(!xzr.IsValidFPRegister()); |
| CHECK(!wzr.IsValidFPRegister()); |
| CHECK(!csp.IsValidFPRegister()); |
| CHECK(!wcsp.IsValidFPRegister()); |
| |
| CHECK(d0.IsValidFPRegister()); |
| CHECK(s0.IsValidFPRegister()); |
| CHECK(!d0.IsValidRegister()); |
| CHECK(!s0.IsValidRegister()); |
| |
| // Test the same as before, but using CPURegister types. This shouldn't make |
| // any difference. |
| CHECK(static_cast<CPURegister>(x0).IsValid()); |
| CHECK(static_cast<CPURegister>(w0).IsValid()); |
| CHECK(static_cast<CPURegister>(x30).IsValid()); |
| CHECK(static_cast<CPURegister>(w30).IsValid()); |
| CHECK(static_cast<CPURegister>(xzr).IsValid()); |
| CHECK(static_cast<CPURegister>(wzr).IsValid()); |
| |
| CHECK(static_cast<CPURegister>(csp).IsValid()); |
| CHECK(static_cast<CPURegister>(wcsp).IsValid()); |
| |
| CHECK(static_cast<CPURegister>(d0).IsValid()); |
| CHECK(static_cast<CPURegister>(s0).IsValid()); |
| CHECK(static_cast<CPURegister>(d31).IsValid()); |
| CHECK(static_cast<CPURegister>(s31).IsValid()); |
| |
| CHECK(static_cast<CPURegister>(x0).IsValidRegister()); |
| CHECK(static_cast<CPURegister>(w0).IsValidRegister()); |
| CHECK(static_cast<CPURegister>(xzr).IsValidRegister()); |
| CHECK(static_cast<CPURegister>(wzr).IsValidRegister()); |
| CHECK(static_cast<CPURegister>(csp).IsValidRegister()); |
| CHECK(static_cast<CPURegister>(wcsp).IsValidRegister()); |
| CHECK(!static_cast<CPURegister>(x0).IsValidFPRegister()); |
| CHECK(!static_cast<CPURegister>(w0).IsValidFPRegister()); |
| CHECK(!static_cast<CPURegister>(xzr).IsValidFPRegister()); |
| CHECK(!static_cast<CPURegister>(wzr).IsValidFPRegister()); |
| CHECK(!static_cast<CPURegister>(csp).IsValidFPRegister()); |
| CHECK(!static_cast<CPURegister>(wcsp).IsValidFPRegister()); |
| |
| CHECK(static_cast<CPURegister>(d0).IsValidFPRegister()); |
| CHECK(static_cast<CPURegister>(s0).IsValidFPRegister()); |
| CHECK(!static_cast<CPURegister>(d0).IsValidRegister()); |
| CHECK(!static_cast<CPURegister>(s0).IsValidRegister()); |
| } |
| |
| |
| TEST(cpureglist_utils_x) { |
| // This test doesn't generate any code, but it verifies the behaviour of |
| // the CPURegList utility methods. |
| |
| // Test a list of X registers. |
| CPURegList test(x0, x1, x2, x3); |
| |
| CHECK(test.IncludesAliasOf(x0)); |
| CHECK(test.IncludesAliasOf(x1)); |
| CHECK(test.IncludesAliasOf(x2)); |
| CHECK(test.IncludesAliasOf(x3)); |
| CHECK(test.IncludesAliasOf(w0)); |
| CHECK(test.IncludesAliasOf(w1)); |
| CHECK(test.IncludesAliasOf(w2)); |
| CHECK(test.IncludesAliasOf(w3)); |
| |
| CHECK(!test.IncludesAliasOf(x4)); |
| CHECK(!test.IncludesAliasOf(x30)); |
| CHECK(!test.IncludesAliasOf(xzr)); |
| CHECK(!test.IncludesAliasOf(csp)); |
| CHECK(!test.IncludesAliasOf(w4)); |
| CHECK(!test.IncludesAliasOf(w30)); |
| CHECK(!test.IncludesAliasOf(wzr)); |
| CHECK(!test.IncludesAliasOf(wcsp)); |
| |
| CHECK(!test.IncludesAliasOf(d0)); |
| CHECK(!test.IncludesAliasOf(d1)); |
| CHECK(!test.IncludesAliasOf(d2)); |
| CHECK(!test.IncludesAliasOf(d3)); |
| CHECK(!test.IncludesAliasOf(s0)); |
| CHECK(!test.IncludesAliasOf(s1)); |
| CHECK(!test.IncludesAliasOf(s2)); |
| CHECK(!test.IncludesAliasOf(s3)); |
| |
| CHECK(!test.IsEmpty()); |
| |
| CHECK(test.type() == x0.type()); |
| |
| CHECK(test.PopHighestIndex().Is(x3)); |
| CHECK(test.PopLowestIndex().Is(x0)); |
| |
| CHECK(test.IncludesAliasOf(x1)); |
| CHECK(test.IncludesAliasOf(x2)); |
| CHECK(test.IncludesAliasOf(w1)); |
| CHECK(test.IncludesAliasOf(w2)); |
| CHECK(!test.IncludesAliasOf(x0)); |
| CHECK(!test.IncludesAliasOf(x3)); |
| CHECK(!test.IncludesAliasOf(w0)); |
| CHECK(!test.IncludesAliasOf(w3)); |
| |
| CHECK(test.PopHighestIndex().Is(x2)); |
| CHECK(test.PopLowestIndex().Is(x1)); |
| |
| CHECK(!test.IncludesAliasOf(x1)); |
| CHECK(!test.IncludesAliasOf(x2)); |
| CHECK(!test.IncludesAliasOf(w1)); |
| CHECK(!test.IncludesAliasOf(w2)); |
| |
| CHECK(test.IsEmpty()); |
| } |
| |
| |
| TEST(cpureglist_utils_w) { |
| // This test doesn't generate any code, but it verifies the behaviour of |
| // the CPURegList utility methods. |
| |
| // Test a list of W registers. |
| CPURegList test(w10, w11, w12, w13); |
| |
| CHECK(test.IncludesAliasOf(x10)); |
| CHECK(test.IncludesAliasOf(x11)); |
| CHECK(test.IncludesAliasOf(x12)); |
| CHECK(test.IncludesAliasOf(x13)); |
| CHECK(test.IncludesAliasOf(w10)); |
| CHECK(test.IncludesAliasOf(w11)); |
| CHECK(test.IncludesAliasOf(w12)); |
| CHECK(test.IncludesAliasOf(w13)); |
| |
| CHECK(!test.IncludesAliasOf(x0)); |
| CHECK(!test.IncludesAliasOf(x9)); |
| CHECK(!test.IncludesAliasOf(x14)); |
| CHECK(!test.IncludesAliasOf(x30)); |
| CHECK(!test.IncludesAliasOf(xzr)); |
| CHECK(!test.IncludesAliasOf(csp)); |
| CHECK(!test.IncludesAliasOf(w0)); |
| CHECK(!test.IncludesAliasOf(w9)); |
| CHECK(!test.IncludesAliasOf(w14)); |
| CHECK(!test.IncludesAliasOf(w30)); |
| CHECK(!test.IncludesAliasOf(wzr)); |
| CHECK(!test.IncludesAliasOf(wcsp)); |
| |
| CHECK(!test.IncludesAliasOf(d10)); |
| CHECK(!test.IncludesAliasOf(d11)); |
| CHECK(!test.IncludesAliasOf(d12)); |
| CHECK(!test.IncludesAliasOf(d13)); |
| CHECK(!test.IncludesAliasOf(s10)); |
| CHECK(!test.IncludesAliasOf(s11)); |
| CHECK(!test.IncludesAliasOf(s12)); |
| CHECK(!test.IncludesAliasOf(s13)); |
| |
| CHECK(!test.IsEmpty()); |
| |
| CHECK(test.type() == w10.type()); |
| |
| CHECK(test.PopHighestIndex().Is(w13)); |
| CHECK(test.PopLowestIndex().Is(w10)); |
| |
| CHECK(test.IncludesAliasOf(x11)); |
| CHECK(test.IncludesAliasOf(x12)); |
| CHECK(test.IncludesAliasOf(w11)); |
| CHECK(test.IncludesAliasOf(w12)); |
| CHECK(!test.IncludesAliasOf(x10)); |
| CHECK(!test.IncludesAliasOf(x13)); |
| CHECK(!test.IncludesAliasOf(w10)); |
| CHECK(!test.IncludesAliasOf(w13)); |
| |
| CHECK(test.PopHighestIndex().Is(w12)); |
| CHECK(test.PopLowestIndex().Is(w11)); |
| |
| CHECK(!test.IncludesAliasOf(x11)); |
| CHECK(!test.IncludesAliasOf(x12)); |
| CHECK(!test.IncludesAliasOf(w11)); |
| CHECK(!test.IncludesAliasOf(w12)); |
| |
| CHECK(test.IsEmpty()); |
| } |
| |
| |
| TEST(cpureglist_utils_d) { |
| // This test doesn't generate any code, but it verifies the behaviour of |
| // the CPURegList utility methods. |
| |
| // Test a list of D registers. |
| CPURegList test(d20, d21, d22, d23); |
| |
| CHECK(test.IncludesAliasOf(d20)); |
| CHECK(test.IncludesAliasOf(d21)); |
| CHECK(test.IncludesAliasOf(d22)); |
| CHECK(test.IncludesAliasOf(d23)); |
| CHECK(test.IncludesAliasOf(s20)); |
| CHECK(test.IncludesAliasOf(s21)); |
| CHECK(test.IncludesAliasOf(s22)); |
| CHECK(test.IncludesAliasOf(s23)); |
| |
| CHECK(!test.IncludesAliasOf(d0)); |
| CHECK(!test.IncludesAliasOf(d19)); |
| CHECK(!test.IncludesAliasOf(d24)); |
| CHECK(!test.IncludesAliasOf(d31)); |
| CHECK(!test.IncludesAliasOf(s0)); |
| CHECK(!test.IncludesAliasOf(s19)); |
| CHECK(!test.IncludesAliasOf(s24)); |
| CHECK(!test.IncludesAliasOf(s31)); |
| |
| CHECK(!test.IncludesAliasOf(x20)); |
| CHECK(!test.IncludesAliasOf(x21)); |
| CHECK(!test.IncludesAliasOf(x22)); |
| CHECK(!test.IncludesAliasOf(x23)); |
| CHECK(!test.IncludesAliasOf(w20)); |
| CHECK(!test.IncludesAliasOf(w21)); |
| CHECK(!test.IncludesAliasOf(w22)); |
| CHECK(!test.IncludesAliasOf(w23)); |
| |
| CHECK(!test.IncludesAliasOf(xzr)); |
| CHECK(!test.IncludesAliasOf(wzr)); |
| CHECK(!test.IncludesAliasOf(csp)); |
| CHECK(!test.IncludesAliasOf(wcsp)); |
| |
| CHECK(!test.IsEmpty()); |
| |
| CHECK(test.type() == d20.type()); |
| |
| CHECK(test.PopHighestIndex().Is(d23)); |
| CHECK(test.PopLowestIndex().Is(d20)); |
| |
| CHECK(test.IncludesAliasOf(d21)); |
| CHECK(test.IncludesAliasOf(d22)); |
| CHECK(test.IncludesAliasOf(s21)); |
| CHECK(test.IncludesAliasOf(s22)); |
| CHECK(!test.IncludesAliasOf(d20)); |
| CHECK(!test.IncludesAliasOf(d23)); |
| CHECK(!test.IncludesAliasOf(s20)); |
| CHECK(!test.IncludesAliasOf(s23)); |
| |
| CHECK(test.PopHighestIndex().Is(d22)); |
| CHECK(test.PopLowestIndex().Is(d21)); |
| |
| CHECK(!test.IncludesAliasOf(d21)); |
| CHECK(!test.IncludesAliasOf(d22)); |
| CHECK(!test.IncludesAliasOf(s21)); |
| CHECK(!test.IncludesAliasOf(s22)); |
| |
| CHECK(test.IsEmpty()); |
| } |
| |
| |
| TEST(cpureglist_utils_s) { |
| // This test doesn't generate any code, but it verifies the behaviour of |
| // the CPURegList utility methods. |
| |
| // Test a list of S registers. |
| CPURegList test(s20, s21, s22, s23); |
| |
| // The type and size mechanisms are already covered, so here we just test |
| // that lists of S registers alias individual D registers. |
| |
| CHECK(test.IncludesAliasOf(d20)); |
| CHECK(test.IncludesAliasOf(d21)); |
| CHECK(test.IncludesAliasOf(d22)); |
| CHECK(test.IncludesAliasOf(d23)); |
| CHECK(test.IncludesAliasOf(s20)); |
| CHECK(test.IncludesAliasOf(s21)); |
| CHECK(test.IncludesAliasOf(s22)); |
| CHECK(test.IncludesAliasOf(s23)); |
| } |
| |
| |
| TEST(cpureglist_utils_empty) { |
| // This test doesn't generate any code, but it verifies the behaviour of |
| // the CPURegList utility methods. |
| |
| // Test an empty list. |
| // Empty lists can have type and size properties. Check that we can create |
| // them, and that they are empty. |
| CPURegList reg32(CPURegister::kRegister, kWRegSizeInBits, 0); |
| CPURegList reg64(CPURegister::kRegister, kXRegSizeInBits, 0); |
| CPURegList fpreg32(CPURegister::kFPRegister, kSRegSizeInBits, 0); |
| CPURegList fpreg64(CPURegister::kFPRegister, kDRegSizeInBits, 0); |
| |
| CHECK(reg32.IsEmpty()); |
| CHECK(reg64.IsEmpty()); |
| CHECK(fpreg32.IsEmpty()); |
| CHECK(fpreg64.IsEmpty()); |
| |
| CHECK(reg32.PopLowestIndex().IsNone()); |
| CHECK(reg64.PopLowestIndex().IsNone()); |
| CHECK(fpreg32.PopLowestIndex().IsNone()); |
| CHECK(fpreg64.PopLowestIndex().IsNone()); |
| |
| CHECK(reg32.PopHighestIndex().IsNone()); |
| CHECK(reg64.PopHighestIndex().IsNone()); |
| CHECK(fpreg32.PopHighestIndex().IsNone()); |
| CHECK(fpreg64.PopHighestIndex().IsNone()); |
| |
| CHECK(reg32.IsEmpty()); |
| CHECK(reg64.IsEmpty()); |
| CHECK(fpreg32.IsEmpty()); |
| CHECK(fpreg64.IsEmpty()); |
| } |
| |
| |
| TEST(printf) { |
| INIT_V8(); |
| SETUP_SIZE(BUF_SIZE * 2); |
| START(); |
| |
| char const * test_plain_string = "Printf with no arguments.\n"; |
| char const * test_substring = "'This is a substring.'"; |
| RegisterDump before; |
| |
| // Initialize x29 to the value of the stack pointer. We will use x29 as a |
| // temporary stack pointer later, and initializing it in this way allows the |
| // RegisterDump check to pass. |
| __ Mov(x29, __ StackPointer()); |
| |
| // Test simple integer arguments. |
| __ Mov(x0, 1234); |
| __ Mov(x1, 0x1234); |
| |
| // Test simple floating-point arguments. |
| __ Fmov(d0, 1.234); |
| |
| // Test pointer (string) arguments. |
| __ Mov(x2, reinterpret_cast<uintptr_t>(test_substring)); |
| |
| // Test the maximum number of arguments, and sign extension. |
| __ Mov(w3, 0xffffffff); |
| __ Mov(w4, 0xffffffff); |
| __ Mov(x5, 0xffffffffffffffff); |
| __ Mov(x6, 0xffffffffffffffff); |
| __ Fmov(s1, 1.234); |
| __ Fmov(s2, 2.345); |
| __ Fmov(d3, 3.456); |
| __ Fmov(d4, 4.567); |
| |
| // Test printing callee-saved registers. |
| __ Mov(x28, 0x123456789abcdef); |
| __ Fmov(d10, 42.0); |
| |
| // Test with three arguments. |
| __ Mov(x10, 3); |
| __ Mov(x11, 40); |
| __ Mov(x12, 500); |
| |
| // A single character. |
| __ Mov(w13, 'x'); |
| |
| // Check that we don't clobber any registers. |
| before.Dump(&masm); |
| |
| __ Printf(test_plain_string); // NOLINT(runtime/printf) |
| __ Printf("x0: %" PRId64 ", x1: 0x%08" PRIx64 "\n", x0, x1); |
| __ Printf("w5: %" PRId32 ", x5: %" PRId64"\n", w5, x5); |
| __ Printf("d0: %f\n", d0); |
| __ Printf("Test %%s: %s\n", x2); |
| __ Printf("w3(uint32): %" PRIu32 "\nw4(int32): %" PRId32 "\n" |
| "x5(uint64): %" PRIu64 "\nx6(int64): %" PRId64 "\n", |
| w3, w4, x5, x6); |
| __ Printf("%%f: %f\n%%g: %g\n%%e: %e\n%%E: %E\n", s1, s2, d3, d4); |
| __ Printf("0x%" PRIx32 ", 0x%" PRIx64 "\n", w28, x28); |
| __ Printf("%g\n", d10); |
| __ Printf("%%%%%s%%%c%%\n", x2, w13); |
| |
| // Print the stack pointer (csp). |
| DCHECK(csp.Is(__ StackPointer())); |
| __ Printf("StackPointer(csp): 0x%016" PRIx64 ", 0x%08" PRIx32 "\n", |
| __ StackPointer(), __ StackPointer().W()); |
| |
| // Test with a different stack pointer. |
| const Register old_stack_pointer = __ StackPointer(); |
| __ Mov(x29, old_stack_pointer); |
| __ SetStackPointer(x29); |
| // Print the stack pointer (not csp). |
| __ Printf("StackPointer(not csp): 0x%016" PRIx64 ", 0x%08" PRIx32 "\n", |
| __ StackPointer(), __ StackPointer().W()); |
| __ Mov(old_stack_pointer, __ StackPointer()); |
| __ SetStackPointer(old_stack_pointer); |
| |
| // Test with three arguments. |
| __ Printf("3=%u, 4=%u, 5=%u\n", x10, x11, x12); |
| |
| // Mixed argument types. |
| __ Printf("w3: %" PRIu32 ", s1: %f, x5: %" PRIu64 ", d3: %f\n", |
| w3, s1, x5, d3); |
| __ Printf("s1: %f, d3: %f, w3: %" PRId32 ", x5: %" PRId64 "\n", |
| s1, d3, w3, x5); |
| |
| END(); |
| RUN(); |
| |
| // We cannot easily test the output of the Printf sequences, and because |
| // Printf preserves all registers by default, we can't look at the number of |
| // bytes that were printed. However, the printf_no_preserve test should check |
| // that, and here we just test that we didn't clobber any registers. |
| CHECK_EQUAL_REGISTERS(before); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(printf_no_preserve) { |
| INIT_V8(); |
| SETUP(); |
| START(); |
| |
| char const * test_plain_string = "Printf with no arguments.\n"; |
| char const * test_substring = "'This is a substring.'"; |
| |
| __ PrintfNoPreserve(test_plain_string); |
| __ Mov(x19, x0); |
| |
| // Test simple integer arguments. |
| __ Mov(x0, 1234); |
| __ Mov(x1, 0x1234); |
| __ PrintfNoPreserve("x0: %" PRId64", x1: 0x%08" PRIx64 "\n", x0, x1); |
| __ Mov(x20, x0); |
| |
| // Test simple floating-point arguments. |
| __ Fmov(d0, 1.234); |
| __ PrintfNoPreserve("d0: %f\n", d0); |
| __ Mov(x21, x0); |
| |
| // Test pointer (string) arguments. |
| __ Mov(x2, reinterpret_cast<uintptr_t>(test_substring)); |
| __ PrintfNoPreserve("Test %%s: %s\n", x2); |
| __ Mov(x22, x0); |
| |
| // Test the maximum number of arguments, and sign extension. |
| __ Mov(w3, 0xffffffff); |
| __ Mov(w4, 0xffffffff); |
| __ Mov(x5, 0xffffffffffffffff); |
| __ Mov(x6, 0xffffffffffffffff); |
| __ PrintfNoPreserve("w3(uint32): %" PRIu32 "\nw4(int32): %" PRId32 "\n" |
| "x5(uint64): %" PRIu64 "\nx6(int64): %" PRId64 "\n", |
| w3, w4, x5, x6); |
| __ Mov(x23, x0); |
| |
| __ Fmov(s1, 1.234); |
| __ Fmov(s2, 2.345); |
| __ Fmov(d3, 3.456); |
| __ Fmov(d4, 4.567); |
| __ PrintfNoPreserve("%%f: %f\n%%g: %g\n%%e: %e\n%%E: %E\n", s1, s2, d3, d4); |
| __ Mov(x24, x0); |
| |
| // Test printing callee-saved registers. |
| __ Mov(x28, 0x123456789abcdef); |
| __ PrintfNoPreserve("0x%" PRIx32 ", 0x%" PRIx64 "\n", w28, x28); |
| __ Mov(x25, x0); |
| |
| __ Fmov(d10, 42.0); |
| __ PrintfNoPreserve("%g\n", d10); |
| __ Mov(x26, x0); |
| |
| // Test with a different stack pointer. |
| const Register old_stack_pointer = __ StackPointer(); |
| __ Mov(x29, old_stack_pointer); |
| __ SetStackPointer(x29); |
| // Print the stack pointer (not csp). |
| __ PrintfNoPreserve( |
| "StackPointer(not csp): 0x%016" PRIx64 ", 0x%08" PRIx32 "\n", |
| __ StackPointer(), __ StackPointer().W()); |
| __ Mov(x27, x0); |
| __ Mov(old_stack_pointer, __ StackPointer()); |
| __ SetStackPointer(old_stack_pointer); |
| |
| // Test with three arguments. |
| __ Mov(x3, 3); |
| __ Mov(x4, 40); |
| __ Mov(x5, 500); |
| __ PrintfNoPreserve("3=%u, 4=%u, 5=%u\n", x3, x4, x5); |
| __ Mov(x28, x0); |
| |
| // Mixed argument types. |
| __ Mov(w3, 0xffffffff); |
| __ Fmov(s1, 1.234); |
| __ Mov(x5, 0xffffffffffffffff); |
| __ Fmov(d3, 3.456); |
| __ PrintfNoPreserve("w3: %" PRIu32 ", s1: %f, x5: %" PRIu64 ", d3: %f\n", |
| w3, s1, x5, d3); |
| __ Mov(x29, x0); |
| |
| END(); |
| RUN(); |
| |
| // We cannot easily test the exact output of the Printf sequences, but we can |
| // use the return code to check that the string length was correct. |
| |
| // Printf with no arguments. |
| CHECK_EQUAL_64(strlen(test_plain_string), x19); |
| // x0: 1234, x1: 0x00001234 |
| CHECK_EQUAL_64(25, x20); |
| // d0: 1.234000 |
| CHECK_EQUAL_64(13, x21); |
| // Test %s: 'This is a substring.' |
| CHECK_EQUAL_64(32, x22); |
| // w3(uint32): 4294967295 |
| // w4(int32): -1 |
| // x5(uint64): 18446744073709551615 |
| // x6(int64): -1 |
| CHECK_EQUAL_64(23 + 14 + 33 + 14, x23); |
| // %f: 1.234000 |
| // %g: 2.345 |
| // %e: 3.456000e+00 |
| // %E: 4.567000E+00 |
| CHECK_EQUAL_64(13 + 10 + 17 + 17, x24); |
| // 0x89abcdef, 0x123456789abcdef |
| CHECK_EQUAL_64(30, x25); |
| // 42 |
| CHECK_EQUAL_64(3, x26); |
| // StackPointer(not csp): 0x00007fb037ae2370, 0x37ae2370 |
| // Note: This is an example value, but the field width is fixed here so the |
| // string length is still predictable. |
| CHECK_EQUAL_64(54, x27); |
| // 3=3, 4=40, 5=500 |
| CHECK_EQUAL_64(17, x28); |
| // w3: 4294967295, s1: 1.234000, x5: 18446744073709551615, d3: 3.456000 |
| CHECK_EQUAL_64(69, x29); |
| |
| TEARDOWN(); |
| } |
| |
| |
| // This is a V8-specific test. |
| static void CopyFieldsHelper(CPURegList temps) { |
| static const uint64_t kLiteralBase = 0x0100001000100101UL; |
| static const uint64_t src[] = {kLiteralBase * 1, |
| kLiteralBase * 2, |
| kLiteralBase * 3, |
| kLiteralBase * 4, |
| kLiteralBase * 5, |
| kLiteralBase * 6, |
| kLiteralBase * 7, |
| kLiteralBase * 8, |
| kLiteralBase * 9, |
| kLiteralBase * 10, |
| kLiteralBase * 11}; |
| static const uint64_t src_tagged = |
| reinterpret_cast<uint64_t>(src) + kHeapObjectTag; |
| |
| static const unsigned kTestCount = sizeof(src) / sizeof(src[0]) + 1; |
| uint64_t* dst[kTestCount]; |
| uint64_t dst_tagged[kTestCount]; |
| |
| // The first test will be to copy 0 fields. The destination (and source) |
| // should not be accessed in any way. |
| dst[0] = NULL; |
| dst_tagged[0] = kHeapObjectTag; |
| |
| // Allocate memory for each other test. Each test <n> will have <n> fields. |
| // This is intended to exercise as many paths in CopyFields as possible. |
| for (unsigned i = 1; i < kTestCount; i++) { |
| dst[i] = new uint64_t[i]; |
| memset(dst[i], 0, i * sizeof(kLiteralBase)); |
| dst_tagged[i] = reinterpret_cast<uint64_t>(dst[i]) + kHeapObjectTag; |
| } |
| |
| SETUP(); |
| START(); |
| |
| __ Mov(x0, dst_tagged[0]); |
| __ Mov(x1, 0); |
| __ CopyFields(x0, x1, temps, 0); |
| for (unsigned i = 1; i < kTestCount; i++) { |
| __ Mov(x0, dst_tagged[i]); |
| __ Mov(x1, src_tagged); |
| __ CopyFields(x0, x1, temps, i); |
| } |
| |
| END(); |
| RUN(); |
| TEARDOWN(); |
| |
| for (unsigned i = 1; i < kTestCount; i++) { |
| for (unsigned j = 0; j < i; j++) { |
| CHECK(src[j] == dst[i][j]); |
| } |
| delete [] dst[i]; |
| } |
| } |
| |
| |
| // This is a V8-specific test. |
| TEST(copyfields) { |
| INIT_V8(); |
| CopyFieldsHelper(CPURegList(x10)); |
| CopyFieldsHelper(CPURegList(x10, x11)); |
| CopyFieldsHelper(CPURegList(x10, x11, x12)); |
| CopyFieldsHelper(CPURegList(x10, x11, x12, x13)); |
| } |
| |
| |
| static void DoSmiAbsTest(int32_t value, bool must_fail = false) { |
| SETUP(); |
| |
| START(); |
| Label end, slow; |
| __ Mov(x2, 0xc001c0de); |
| __ Mov(x1, value); |
| __ SmiTag(x1); |
| __ SmiAbs(x1, &slow); |
| __ SmiUntag(x1); |
| __ B(&end); |
| |
| __ Bind(&slow); |
| __ Mov(x2, 0xbad); |
| |
| __ Bind(&end); |
| END(); |
| |
| RUN(); |
| |
| if (must_fail) { |
| // We tested an invalid conversion. The code must have jump on slow. |
| CHECK_EQUAL_64(0xbad, x2); |
| } else { |
| // The conversion is valid, check the result. |
| int32_t result = (value >= 0) ? value : -value; |
| CHECK_EQUAL_64(result, x1); |
| |
| // Check that we didn't jump on slow. |
| CHECK_EQUAL_64(0xc001c0de, x2); |
| } |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(smi_abs) { |
| INIT_V8(); |
| // Simple and edge cases. |
| DoSmiAbsTest(0); |
| DoSmiAbsTest(0x12345); |
| DoSmiAbsTest(0x40000000); |
| DoSmiAbsTest(0x7fffffff); |
| DoSmiAbsTest(-1); |
| DoSmiAbsTest(-12345); |
| DoSmiAbsTest(0x80000001); |
| |
| // Check that the most negative SMI is detected. |
| DoSmiAbsTest(0x80000000, true); |
| } |
| |
| |
| TEST(blr_lr) { |
| // A simple test to check that the simulator correcty handle "blr lr". |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| Label target; |
| Label end; |
| |
| __ Mov(x0, 0x0); |
| __ Adr(lr, &target); |
| |
| __ Blr(lr); |
| __ Mov(x0, 0xdeadbeef); |
| __ B(&end); |
| |
| __ Bind(&target); |
| __ Mov(x0, 0xc001c0de); |
| |
| __ Bind(&end); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(0xc001c0de, x0); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(barriers) { |
| // Generate all supported barriers, this is just a smoke test |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| |
| // DMB |
| __ Dmb(FullSystem, BarrierAll); |
| __ Dmb(FullSystem, BarrierReads); |
| __ Dmb(FullSystem, BarrierWrites); |
| __ Dmb(FullSystem, BarrierOther); |
| |
| __ Dmb(InnerShareable, BarrierAll); |
| __ Dmb(InnerShareable, BarrierReads); |
| __ Dmb(InnerShareable, BarrierWrites); |
| __ Dmb(InnerShareable, BarrierOther); |
| |
| __ Dmb(NonShareable, BarrierAll); |
| __ Dmb(NonShareable, BarrierReads); |
| __ Dmb(NonShareable, BarrierWrites); |
| __ Dmb(NonShareable, BarrierOther); |
| |
| __ Dmb(OuterShareable, BarrierAll); |
| __ Dmb(OuterShareable, BarrierReads); |
| __ Dmb(OuterShareable, BarrierWrites); |
| __ Dmb(OuterShareable, BarrierOther); |
| |
| // DSB |
| __ Dsb(FullSystem, BarrierAll); |
| __ Dsb(FullSystem, BarrierReads); |
| __ Dsb(FullSystem, BarrierWrites); |
| __ Dsb(FullSystem, BarrierOther); |
| |
| __ Dsb(InnerShareable, BarrierAll); |
| __ Dsb(InnerShareable, BarrierReads); |
| __ Dsb(InnerShareable, BarrierWrites); |
| __ Dsb(InnerShareable, BarrierOther); |
| |
| __ Dsb(NonShareable, BarrierAll); |
| __ Dsb(NonShareable, BarrierReads); |
| __ Dsb(NonShareable, BarrierWrites); |
| __ Dsb(NonShareable, BarrierOther); |
| |
| __ Dsb(OuterShareable, BarrierAll); |
| __ Dsb(OuterShareable, BarrierReads); |
| __ Dsb(OuterShareable, BarrierWrites); |
| __ Dsb(OuterShareable, BarrierOther); |
| |
| // ISB |
| __ Isb(); |
| |
| END(); |
| |
| RUN(); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(process_nan_double) { |
| INIT_V8(); |
| // Make sure that NaN propagation works correctly. |
| double sn = rawbits_to_double(0x7ff5555511111111); |
| double qn = rawbits_to_double(0x7ffaaaaa11111111); |
| DCHECK(IsSignallingNaN(sn)); |
| DCHECK(IsQuietNaN(qn)); |
| |
| // The input NaNs after passing through ProcessNaN. |
| double sn_proc = rawbits_to_double(0x7ffd555511111111); |
| double qn_proc = qn; |
| DCHECK(IsQuietNaN(sn_proc)); |
| DCHECK(IsQuietNaN(qn_proc)); |
| |
| SETUP(); |
| START(); |
| |
| // Execute a number of instructions which all use ProcessNaN, and check that |
| // they all handle the NaN correctly. |
| __ Fmov(d0, sn); |
| __ Fmov(d10, qn); |
| |
| // Operations that always propagate NaNs unchanged, even signalling NaNs. |
| // - Signalling NaN |
| __ Fmov(d1, d0); |
| __ Fabs(d2, d0); |
| __ Fneg(d3, d0); |
| // - Quiet NaN |
| __ Fmov(d11, d10); |
| __ Fabs(d12, d10); |
| __ Fneg(d13, d10); |
| |
| // Operations that use ProcessNaN. |
| // - Signalling NaN |
| __ Fsqrt(d4, d0); |
| __ Frinta(d5, d0); |
| __ Frintn(d6, d0); |
| __ Frintz(d7, d0); |
| // - Quiet NaN |
| __ Fsqrt(d14, d10); |
| __ Frinta(d15, d10); |
| __ Frintn(d16, d10); |
| __ Frintz(d17, d10); |
| |
| // The behaviour of fcvt is checked in TEST(fcvt_sd). |
| |
| END(); |
| RUN(); |
| |
| uint64_t qn_raw = double_to_rawbits(qn); |
| uint64_t sn_raw = double_to_rawbits(sn); |
| |
| // - Signalling NaN |
| CHECK_EQUAL_FP64(sn, d1); |
| CHECK_EQUAL_FP64(rawbits_to_double(sn_raw & ~kDSignMask), d2); |
| CHECK_EQUAL_FP64(rawbits_to_double(sn_raw ^ kDSignMask), d3); |
| // - Quiet NaN |
| CHECK_EQUAL_FP64(qn, d11); |
| CHECK_EQUAL_FP64(rawbits_to_double(qn_raw & ~kDSignMask), d12); |
| CHECK_EQUAL_FP64(rawbits_to_double(qn_raw ^ kDSignMask), d13); |
| |
| // - Signalling NaN |
| CHECK_EQUAL_FP64(sn_proc, d4); |
| CHECK_EQUAL_FP64(sn_proc, d5); |
| CHECK_EQUAL_FP64(sn_proc, d6); |
| CHECK_EQUAL_FP64(sn_proc, d7); |
| // - Quiet NaN |
| CHECK_EQUAL_FP64(qn_proc, d14); |
| CHECK_EQUAL_FP64(qn_proc, d15); |
| CHECK_EQUAL_FP64(qn_proc, d16); |
| CHECK_EQUAL_FP64(qn_proc, d17); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(process_nan_float) { |
| INIT_V8(); |
| // Make sure that NaN propagation works correctly. |
| float sn = rawbits_to_float(0x7f951111); |
| float qn = rawbits_to_float(0x7fea1111); |
| DCHECK(IsSignallingNaN(sn)); |
| DCHECK(IsQuietNaN(qn)); |
| |
| // The input NaNs after passing through ProcessNaN. |
| float sn_proc = rawbits_to_float(0x7fd51111); |
| float qn_proc = qn; |
| DCHECK(IsQuietNaN(sn_proc)); |
| DCHECK(IsQuietNaN(qn_proc)); |
| |
| SETUP(); |
| START(); |
| |
| // Execute a number of instructions which all use ProcessNaN, and check that |
| // they all handle the NaN correctly. |
| __ Fmov(s0, sn); |
| __ Fmov(s10, qn); |
| |
| // Operations that always propagate NaNs unchanged, even signalling NaNs. |
| // - Signalling NaN |
| __ Fmov(s1, s0); |
| __ Fabs(s2, s0); |
| __ Fneg(s3, s0); |
| // - Quiet NaN |
| __ Fmov(s11, s10); |
| __ Fabs(s12, s10); |
| __ Fneg(s13, s10); |
| |
| // Operations that use ProcessNaN. |
| // - Signalling NaN |
| __ Fsqrt(s4, s0); |
| __ Frinta(s5, s0); |
| __ Frintn(s6, s0); |
| __ Frintz(s7, s0); |
| // - Quiet NaN |
| __ Fsqrt(s14, s10); |
| __ Frinta(s15, s10); |
| __ Frintn(s16, s10); |
| __ Frintz(s17, s10); |
| |
| // The behaviour of fcvt is checked in TEST(fcvt_sd). |
| |
| END(); |
| RUN(); |
| |
| uint32_t qn_raw = float_to_rawbits(qn); |
| uint32_t sn_raw = float_to_rawbits(sn); |
| |
| // - Signalling NaN |
| CHECK_EQUAL_FP32(sn, s1); |
| CHECK_EQUAL_FP32(rawbits_to_float(sn_raw & ~kSSignMask), s2); |
| CHECK_EQUAL_FP32(rawbits_to_float(sn_raw ^ kSSignMask), s3); |
| // - Quiet NaN |
| CHECK_EQUAL_FP32(qn, s11); |
| CHECK_EQUAL_FP32(rawbits_to_float(qn_raw & ~kSSignMask), s12); |
| CHECK_EQUAL_FP32(rawbits_to_float(qn_raw ^ kSSignMask), s13); |
| |
| // - Signalling NaN |
| CHECK_EQUAL_FP32(sn_proc, s4); |
| CHECK_EQUAL_FP32(sn_proc, s5); |
| CHECK_EQUAL_FP32(sn_proc, s6); |
| CHECK_EQUAL_FP32(sn_proc, s7); |
| // - Quiet NaN |
| CHECK_EQUAL_FP32(qn_proc, s14); |
| CHECK_EQUAL_FP32(qn_proc, s15); |
| CHECK_EQUAL_FP32(qn_proc, s16); |
| CHECK_EQUAL_FP32(qn_proc, s17); |
| |
| TEARDOWN(); |
| } |
| |
| |
| static void ProcessNaNsHelper(double n, double m, double expected) { |
| DCHECK(std::isnan(n) || std::isnan(m)); |
| DCHECK(std::isnan(expected)); |
| |
| SETUP(); |
| START(); |
| |
| // Execute a number of instructions which all use ProcessNaNs, and check that |
| // they all propagate NaNs correctly. |
| __ Fmov(d0, n); |
| __ Fmov(d1, m); |
| |
| __ Fadd(d2, d0, d1); |
| __ Fsub(d3, d0, d1); |
| __ Fmul(d4, d0, d1); |
| __ Fdiv(d5, d0, d1); |
| __ Fmax(d6, d0, d1); |
| __ Fmin(d7, d0, d1); |
| |
| END(); |
| RUN(); |
| |
| CHECK_EQUAL_FP64(expected, d2); |
| CHECK_EQUAL_FP64(expected, d3); |
| CHECK_EQUAL_FP64(expected, d4); |
| CHECK_EQUAL_FP64(expected, d5); |
| CHECK_EQUAL_FP64(expected, d6); |
| CHECK_EQUAL_FP64(expected, d7); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(process_nans_double) { |
| INIT_V8(); |
| // Make sure that NaN propagation works correctly. |
| double sn = rawbits_to_double(0x7ff5555511111111); |
| double sm = rawbits_to_double(0x7ff5555522222222); |
| double qn = rawbits_to_double(0x7ffaaaaa11111111); |
| double qm = rawbits_to_double(0x7ffaaaaa22222222); |
| DCHECK(IsSignallingNaN(sn)); |
| DCHECK(IsSignallingNaN(sm)); |
| DCHECK(IsQuietNaN(qn)); |
| DCHECK(IsQuietNaN(qm)); |
| |
| // The input NaNs after passing through ProcessNaN. |
| double sn_proc = rawbits_to_double(0x7ffd555511111111); |
| double sm_proc = rawbits_to_double(0x7ffd555522222222); |
| double qn_proc = qn; |
| double qm_proc = qm; |
| DCHECK(IsQuietNaN(sn_proc)); |
| DCHECK(IsQuietNaN(sm_proc)); |
| DCHECK(IsQuietNaN(qn_proc)); |
| DCHECK(IsQuietNaN(qm_proc)); |
| |
| // Quiet NaNs are propagated. |
| ProcessNaNsHelper(qn, 0, qn_proc); |
| ProcessNaNsHelper(0, qm, qm_proc); |
| ProcessNaNsHelper(qn, qm, qn_proc); |
| |
| // Signalling NaNs are propagated, and made quiet. |
| ProcessNaNsHelper(sn, 0, sn_proc); |
| ProcessNaNsHelper(0, sm, sm_proc); |
| ProcessNaNsHelper(sn, sm, sn_proc); |
| |
| // Signalling NaNs take precedence over quiet NaNs. |
| ProcessNaNsHelper(sn, qm, sn_proc); |
| ProcessNaNsHelper(qn, sm, sm_proc); |
| ProcessNaNsHelper(sn, sm, sn_proc); |
| } |
| |
| |
| static void ProcessNaNsHelper(float n, float m, float expected) { |
| DCHECK(std::isnan(n) || std::isnan(m)); |
| DCHECK(std::isnan(expected)); |
| |
| SETUP(); |
| START(); |
| |
| // Execute a number of instructions which all use ProcessNaNs, and check that |
| // they all propagate NaNs correctly. |
| __ Fmov(s0, n); |
| __ Fmov(s1, m); |
| |
| __ Fadd(s2, s0, s1); |
| __ Fsub(s3, s0, s1); |
| __ Fmul(s4, s0, s1); |
| __ Fdiv(s5, s0, s1); |
| __ Fmax(s6, s0, s1); |
| __ Fmin(s7, s0, s1); |
| |
| END(); |
| RUN(); |
| |
| CHECK_EQUAL_FP32(expected, s2); |
| CHECK_EQUAL_FP32(expected, s3); |
| CHECK_EQUAL_FP32(expected, s4); |
| CHECK_EQUAL_FP32(expected, s5); |
| CHECK_EQUAL_FP32(expected, s6); |
| CHECK_EQUAL_FP32(expected, s7); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(process_nans_float) { |
| INIT_V8(); |
| // Make sure that NaN propagation works correctly. |
| float sn = rawbits_to_float(0x7f951111); |
| float sm = rawbits_to_float(0x7f952222); |
| float qn = rawbits_to_float(0x7fea1111); |
| float qm = rawbits_to_float(0x7fea2222); |
| DCHECK(IsSignallingNaN(sn)); |
| DCHECK(IsSignallingNaN(sm)); |
| DCHECK(IsQuietNaN(qn)); |
| DCHECK(IsQuietNaN(qm)); |
| |
| // The input NaNs after passing through ProcessNaN. |
| float sn_proc = rawbits_to_float(0x7fd51111); |
| float sm_proc = rawbits_to_float(0x7fd52222); |
| float qn_proc = qn; |
| float qm_proc = qm; |
| DCHECK(IsQuietNaN(sn_proc)); |
| DCHECK(IsQuietNaN(sm_proc)); |
| DCHECK(IsQuietNaN(qn_proc)); |
| DCHECK(IsQuietNaN(qm_proc)); |
| |
| // Quiet NaNs are propagated. |
| ProcessNaNsHelper(qn, 0, qn_proc); |
| ProcessNaNsHelper(0, qm, qm_proc); |
| ProcessNaNsHelper(qn, qm, qn_proc); |
| |
| // Signalling NaNs are propagated, and made quiet. |
| ProcessNaNsHelper(sn, 0, sn_proc); |
| ProcessNaNsHelper(0, sm, sm_proc); |
| ProcessNaNsHelper(sn, sm, sn_proc); |
| |
| // Signalling NaNs take precedence over quiet NaNs. |
| ProcessNaNsHelper(sn, qm, sn_proc); |
| ProcessNaNsHelper(qn, sm, sm_proc); |
| ProcessNaNsHelper(sn, sm, sn_proc); |
| } |
| |
| |
| static void DefaultNaNHelper(float n, float m, float a) { |
| DCHECK(std::isnan(n) || std::isnan(m) || std::isnan(a)); |
| |
| bool test_1op = std::isnan(n); |
| bool test_2op = std::isnan(n) || std::isnan(m); |
| |
| SETUP(); |
| START(); |
| |
| // Enable Default-NaN mode in the FPCR. |
| __ Mrs(x0, FPCR); |
| __ Orr(x1, x0, DN_mask); |
| __ Msr(FPCR, x1); |
| |
| // Execute a number of instructions which all use ProcessNaNs, and check that |
| // they all produce the default NaN. |
| __ Fmov(s0, n); |
| __ Fmov(s1, m); |
| __ Fmov(s2, a); |
| |
| if (test_1op) { |
| // Operations that always propagate NaNs unchanged, even signalling NaNs. |
| __ Fmov(s10, s0); |
| __ Fabs(s11, s0); |
| __ Fneg(s12, s0); |
| |
| // Operations that use ProcessNaN. |
| __ Fsqrt(s13, s0); |
| __ Frinta(s14, s0); |
| __ Frintn(s15, s0); |
| __ Frintz(s16, s0); |
| |
| // Fcvt usually has special NaN handling, but it respects default-NaN mode. |
| __ Fcvt(d17, s0); |
| } |
| |
| if (test_2op) { |
| __ Fadd(s18, s0, s1); |
| __ Fsub(s19, s0, s1); |
| __ Fmul(s20, s0, s1); |
| __ Fdiv(s21, s0, s1); |
| __ Fmax(s22, s0, s1); |
| __ Fmin(s23, s0, s1); |
| } |
| |
| __ Fmadd(s24, s0, s1, s2); |
| __ Fmsub(s25, s0, s1, s2); |
| __ Fnmadd(s26, s0, s1, s2); |
| __ Fnmsub(s27, s0, s1, s2); |
| |
| // Restore FPCR. |
| __ Msr(FPCR, x0); |
| |
| END(); |
| RUN(); |
| |
| if (test_1op) { |
| uint32_t n_raw = float_to_rawbits(n); |
| CHECK_EQUAL_FP32(n, s10); |
| CHECK_EQUAL_FP32(rawbits_to_float(n_raw & ~kSSignMask), s11); |
| CHECK_EQUAL_FP32(rawbits_to_float(n_raw ^ kSSignMask), s12); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s13); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s14); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s15); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s16); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d17); |
| } |
| |
| if (test_2op) { |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s18); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s19); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s20); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s21); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s22); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s23); |
| } |
| |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s24); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s25); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s26); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s27); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(default_nan_float) { |
| INIT_V8(); |
| float sn = rawbits_to_float(0x7f951111); |
| float sm = rawbits_to_float(0x7f952222); |
| float sa = rawbits_to_float(0x7f95aaaa); |
| float qn = rawbits_to_float(0x7fea1111); |
| float qm = rawbits_to_float(0x7fea2222); |
| float qa = rawbits_to_float(0x7feaaaaa); |
| DCHECK(IsSignallingNaN(sn)); |
| DCHECK(IsSignallingNaN(sm)); |
| DCHECK(IsSignallingNaN(sa)); |
| DCHECK(IsQuietNaN(qn)); |
| DCHECK(IsQuietNaN(qm)); |
| DCHECK(IsQuietNaN(qa)); |
| |
| // - Signalling NaNs |
| DefaultNaNHelper(sn, 0.0f, 0.0f); |
| DefaultNaNHelper(0.0f, sm, 0.0f); |
| DefaultNaNHelper(0.0f, 0.0f, sa); |
| DefaultNaNHelper(sn, sm, 0.0f); |
| DefaultNaNHelper(0.0f, sm, sa); |
| DefaultNaNHelper(sn, 0.0f, sa); |
| DefaultNaNHelper(sn, sm, sa); |
| // - Quiet NaNs |
| DefaultNaNHelper(qn, 0.0f, 0.0f); |
| DefaultNaNHelper(0.0f, qm, 0.0f); |
| DefaultNaNHelper(0.0f, 0.0f, qa); |
| DefaultNaNHelper(qn, qm, 0.0f); |
| DefaultNaNHelper(0.0f, qm, qa); |
| DefaultNaNHelper(qn, 0.0f, qa); |
| DefaultNaNHelper(qn, qm, qa); |
| // - Mixed NaNs |
| DefaultNaNHelper(qn, sm, sa); |
| DefaultNaNHelper(sn, qm, sa); |
| DefaultNaNHelper(sn, sm, qa); |
| DefaultNaNHelper(qn, qm, sa); |
| DefaultNaNHelper(sn, qm, qa); |
| DefaultNaNHelper(qn, sm, qa); |
| DefaultNaNHelper(qn, qm, qa); |
| } |
| |
| |
| static void DefaultNaNHelper(double n, double m, double a) { |
| DCHECK(std::isnan(n) || std::isnan(m) || std::isnan(a)); |
| |
| bool test_1op = std::isnan(n); |
| bool test_2op = std::isnan(n) || std::isnan(m); |
| |
| SETUP(); |
| START(); |
| |
| // Enable Default-NaN mode in the FPCR. |
| __ Mrs(x0, FPCR); |
| __ Orr(x1, x0, DN_mask); |
| __ Msr(FPCR, x1); |
| |
| // Execute a number of instructions which all use ProcessNaNs, and check that |
| // they all produce the default NaN. |
| __ Fmov(d0, n); |
| __ Fmov(d1, m); |
| __ Fmov(d2, a); |
| |
| if (test_1op) { |
| // Operations that always propagate NaNs unchanged, even signalling NaNs. |
| __ Fmov(d10, d0); |
| __ Fabs(d11, d0); |
| __ Fneg(d12, d0); |
| |
| // Operations that use ProcessNaN. |
| __ Fsqrt(d13, d0); |
| __ Frinta(d14, d0); |
| __ Frintn(d15, d0); |
| __ Frintz(d16, d0); |
| |
| // Fcvt usually has special NaN handling, but it respects default-NaN mode. |
| __ Fcvt(s17, d0); |
| } |
| |
| if (test_2op) { |
| __ Fadd(d18, d0, d1); |
| __ Fsub(d19, d0, d1); |
| __ Fmul(d20, d0, d1); |
| __ Fdiv(d21, d0, d1); |
| __ Fmax(d22, d0, d1); |
| __ Fmin(d23, d0, d1); |
| } |
| |
| __ Fmadd(d24, d0, d1, d2); |
| __ Fmsub(d25, d0, d1, d2); |
| __ Fnmadd(d26, d0, d1, d2); |
| __ Fnmsub(d27, d0, d1, d2); |
| |
| // Restore FPCR. |
| __ Msr(FPCR, x0); |
| |
| END(); |
| RUN(); |
| |
| if (test_1op) { |
| uint64_t n_raw = double_to_rawbits(n); |
| CHECK_EQUAL_FP64(n, d10); |
| CHECK_EQUAL_FP64(rawbits_to_double(n_raw & ~kDSignMask), d11); |
| CHECK_EQUAL_FP64(rawbits_to_double(n_raw ^ kDSignMask), d12); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d13); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d14); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d15); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d16); |
| CHECK_EQUAL_FP32(kFP32DefaultNaN, s17); |
| } |
| |
| if (test_2op) { |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d18); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d19); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d20); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d21); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d22); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d23); |
| } |
| |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d24); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d25); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d26); |
| CHECK_EQUAL_FP64(kFP64DefaultNaN, d27); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(default_nan_double) { |
| INIT_V8(); |
| double sn = rawbits_to_double(0x7ff5555511111111); |
| double sm = rawbits_to_double(0x7ff5555522222222); |
| double sa = rawbits_to_double(0x7ff55555aaaaaaaa); |
| double qn = rawbits_to_double(0x7ffaaaaa11111111); |
| double qm = rawbits_to_double(0x7ffaaaaa22222222); |
| double qa = rawbits_to_double(0x7ffaaaaaaaaaaaaa); |
| DCHECK(IsSignallingNaN(sn)); |
| DCHECK(IsSignallingNaN(sm)); |
| DCHECK(IsSignallingNaN(sa)); |
| DCHECK(IsQuietNaN(qn)); |
| DCHECK(IsQuietNaN(qm)); |
| DCHECK(IsQuietNaN(qa)); |
| |
| // - Signalling NaNs |
| DefaultNaNHelper(sn, 0.0, 0.0); |
| DefaultNaNHelper(0.0, sm, 0.0); |
| DefaultNaNHelper(0.0, 0.0, sa); |
| DefaultNaNHelper(sn, sm, 0.0); |
| DefaultNaNHelper(0.0, sm, sa); |
| DefaultNaNHelper(sn, 0.0, sa); |
| DefaultNaNHelper(sn, sm, sa); |
| // - Quiet NaNs |
| DefaultNaNHelper(qn, 0.0, 0.0); |
| DefaultNaNHelper(0.0, qm, 0.0); |
| DefaultNaNHelper(0.0, 0.0, qa); |
| DefaultNaNHelper(qn, qm, 0.0); |
| DefaultNaNHelper(0.0, qm, qa); |
| DefaultNaNHelper(qn, 0.0, qa); |
| DefaultNaNHelper(qn, qm, qa); |
| // - Mixed NaNs |
| DefaultNaNHelper(qn, sm, sa); |
| DefaultNaNHelper(sn, qm, sa); |
| DefaultNaNHelper(sn, sm, qa); |
| DefaultNaNHelper(qn, qm, sa); |
| DefaultNaNHelper(sn, qm, qa); |
| DefaultNaNHelper(qn, sm, qa); |
| DefaultNaNHelper(qn, qm, qa); |
| } |
| |
| |
| TEST(call_no_relocation) { |
| Address call_start; |
| Address return_address; |
| |
| INIT_V8(); |
| SETUP(); |
| |
| START(); |
| |
| Label function; |
| Label test; |
| |
| __ B(&test); |
| |
| __ Bind(&function); |
| __ Mov(x0, 0x1); |
| __ Ret(); |
| |
| __ Bind(&test); |
| __ Mov(x0, 0x0); |
| __ Push(lr, xzr); |
| { |
| Assembler::BlockConstPoolScope scope(&masm); |
| call_start = buf + __ pc_offset(); |
| __ Call(buf + function.pos(), RelocInfo::NONE64); |
| return_address = buf + __ pc_offset(); |
| } |
| __ Pop(xzr, lr); |
| END(); |
| |
| RUN(); |
| |
| CHECK_EQUAL_64(1, x0); |
| |
| // The return_address_from_call_start function doesn't currently encounter any |
| // non-relocatable sequences, so we check it here to make sure it works. |
| // TODO(jbramley): Once Crankshaft is complete, decide if we need to support |
| // non-relocatable calls at all. |
| CHECK(return_address == |
| Assembler::return_address_from_call_start(call_start)); |
| |
| TEARDOWN(); |
| } |
| |
| |
| static void AbsHelperX(int64_t value) { |
| int64_t expected; |
| |
| SETUP(); |
| START(); |
| |
| Label fail; |
| Label done; |
| |
| __ Mov(x0, 0); |
| __ Mov(x1, value); |
| |
| if (value != kXMinInt) { |
| expected = labs(value); |
| |
| Label next; |
| // The result is representable. |
| __ Abs(x10, x1); |
| __ Abs(x11, x1, &fail); |
| __ Abs(x12, x1, &fail, &next); |
| __ Bind(&next); |
| __ Abs(x13, x1, NULL, &done); |
| } else { |
| // labs is undefined for kXMinInt but our implementation in the |
| // MacroAssembler will return kXMinInt in such a case. |
| expected = kXMinInt; |
| |
| Label next; |
| // The result is not representable. |
| __ Abs(x10, x1); |
| __ Abs(x11, x1, NULL, &fail); |
| __ Abs(x12, x1, &next, &fail); |
| __ Bind(&next); |
| __ Abs(x13, x1, &done); |
| } |
| |
| __ Bind(&fail); |
| __ Mov(x0, -1); |
| |
| __ Bind(&done); |
| |
| END(); |
| RUN(); |
| |
| CHECK_EQUAL_64(0, x0); |
| CHECK_EQUAL_64(value, x1); |
| CHECK_EQUAL_64(expected, x10); |
| CHECK_EQUAL_64(expected, x11); |
| CHECK_EQUAL_64(expected, x12); |
| CHECK_EQUAL_64(expected, x13); |
| |
| TEARDOWN(); |
| } |
| |
| |
| static void AbsHelperW(int32_t value) { |
| int32_t expected; |
| |
| SETUP(); |
| START(); |
| |
| Label fail; |
| Label done; |
| |
| __ Mov(w0, 0); |
| // TODO(jbramley): The cast is needed to avoid a sign-extension bug in VIXL. |
| // Once it is fixed, we should remove the cast. |
| __ Mov(w1, static_cast<uint32_t>(value)); |
| |
| if (value != kWMinInt) { |
| expected = abs(value); |
| |
| Label next; |
| // The result is representable. |
| __ Abs(w10, w1); |
| __ Abs(w11, w1, &fail); |
| __ Abs(w12, w1, &fail, &next); |
| __ Bind(&next); |
| __ Abs(w13, w1, NULL, &done); |
| } else { |
| // abs is undefined for kWMinInt but our implementation in the |
| // MacroAssembler will return kWMinInt in such a case. |
| expected = kWMinInt; |
| |
| Label next; |
| // The result is not representable. |
| __ Abs(w10, w1); |
| __ Abs(w11, w1, NULL, &fail); |
| __ Abs(w12, w1, &next, &fail); |
| __ Bind(&next); |
| __ Abs(w13, w1, &done); |
| } |
| |
| __ Bind(&fail); |
| __ Mov(w0, -1); |
| |
| __ Bind(&done); |
| |
| END(); |
| RUN(); |
| |
| CHECK_EQUAL_32(0, w0); |
| CHECK_EQUAL_32(value, w1); |
| CHECK_EQUAL_32(expected, w10); |
| CHECK_EQUAL_32(expected, w11); |
| CHECK_EQUAL_32(expected, w12); |
| CHECK_EQUAL_32(expected, w13); |
| |
| TEARDOWN(); |
| } |
| |
| |
| TEST(abs) { |
| INIT_V8(); |
| AbsHelperX(0); |
| AbsHelperX(42); |
| AbsHelperX(-42); |
| AbsHelperX(kXMinInt); |
| AbsHelperX(kXMaxInt); |
| |
| AbsHelperW(0); |
| AbsHelperW(42); |
| AbsHelperW(-42); |
| AbsHelperW(kWMinInt); |
| AbsHelperW(kWMaxInt); |
| } |
| |
| |
| TEST(pool_size) { |
| INIT_V8(); |
| SETUP(); |
| |
| // This test does not execute any code. It only tests that the size of the |
| // pools is read correctly from the RelocInfo. |
| |
| Label exit; |
| __ b(&exit); |
| |
| const unsigned constant_pool_size = 312; |
| const unsigned veneer_pool_size = 184; |
| |
| __ RecordConstPool(constant_pool_size); |
| for (unsigned i = 0; i < constant_pool_size / 4; ++i) { |
| __ dc32(0); |
| } |
| |
| __ RecordVeneerPool(masm.pc_offset(), veneer_pool_size); |
| for (unsigned i = 0; i < veneer_pool_size / kInstructionSize; ++i) { |
| __ nop(); |
| } |
| |
| __ bind(&exit); |
| |
| HandleScope handle_scope(isolate); |
| CodeDesc desc; |
| masm.GetCode(&desc); |
| Handle<Code> code = isolate->factory()->NewCode(desc, 0, masm.CodeObject()); |
| |
| unsigned pool_count = 0; |
| int pool_mask = RelocInfo::ModeMask(RelocInfo::CONST_POOL) | |
| RelocInfo::ModeMask(RelocInfo::VENEER_POOL); |
| for (RelocIterator it(*code, pool_mask); !it.done(); it.next()) { |
| RelocInfo* info = it.rinfo(); |
| if (RelocInfo::IsConstPool(info->rmode())) { |
| DCHECK(info->data() == constant_pool_size); |
| ++pool_count; |
| } |
| if (RelocInfo::IsVeneerPool(info->rmode())) { |
| DCHECK(info->data() == veneer_pool_size); |
| ++pool_count; |
| } |
| } |
| |
| DCHECK(pool_count == 2); |
| |
| TEARDOWN(); |
| } |
