jdk8-mips64-public/hotspot: src/cpu/x86/vm/vm_version

src/cpu/x86/vm/vm_version_x86.cpp@7c2285d86b8d (annotated)

src/cpu/x86/vm/vm_version_x86.cpp

Mon, 03 Jul 2017 15:57:11 -0700

author: asaha
date: Mon, 03 Jul 2017 15:57:11 -0700
changeset 8984: 7c2285d86b8d
parent 8729: 402618d5afc9
parent 8966: c0f6c987718c
child 9041: 95a08233f46c
child 9788: 44ef77ad417c
permissions: -rw-r--r--

Merge

 /*
  * Copyright (c) 1997, 2014, Oracle and/or its affiliates. All rights reserved.
  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
  *
  * This code is free software; you can redistribute it and/or modify it
  * under the terms of the GNU General Public License version 2 only, as
  * published by the Free Software Foundation.
  *
  * This code is distributed in the hope that it will be useful, but WITHOUT
  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
  * version 2 for more details (a copy is included in the LICENSE file that
  * accompanied this code).
  *
  * You should have received a copy of the GNU General Public License version
  * 2 along with this work; if not, write to the Free Software Foundation,
  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
  *
  * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
  * or visit www.oracle.com if you need additional information or have any
  * questions.
  *
  */
 #include "precompiled.hpp"
 #include "asm/macroAssembler.hpp"
 #include "asm/macroAssembler.inline.hpp"
 #include "memory/resourceArea.hpp"
 #include "runtime/java.hpp"
 #include "runtime/stubCodeGenerator.hpp"
 #include "vm_version_x86.hpp"
 #ifdef TARGET_OS_FAMILY_linux
 # include "os_linux.inline.hpp"
 #endif
 #ifdef TARGET_OS_FAMILY_solaris
 # include "os_solaris.inline.hpp"
 #endif
 #ifdef TARGET_OS_FAMILY_windows
 # include "os_windows.inline.hpp"
 #endif
 #ifdef TARGET_OS_FAMILY_bsd
 # include "os_bsd.inline.hpp"
 #endif
 int VM_Version::_cpu;
 int VM_Version::_model;
 int VM_Version::_stepping;
 int VM_Version::_cpuFeatures;
 const char*           VM_Version::_features_str = "";
 VM_Version::CpuidInfo VM_Version::_cpuid_info   = { 0, };
 // Address of instruction which causes SEGV
 address VM_Version::_cpuinfo_segv_addr = 0;
 // Address of instruction after the one which causes SEGV
 address VM_Version::_cpuinfo_cont_addr = 0;
 static BufferBlob* stub_blob;
 static const int stub_size = 600;
 extern "C" {
   typedef void (*get_cpu_info_stub_t)(void*);
 }
 static get_cpu_info_stub_t get_cpu_info_stub = NULL;
 class VM_Version_StubGenerator: public StubCodeGenerator {
  public:
   VM_Version_StubGenerator(CodeBuffer *c) : StubCodeGenerator(c) {}
   address generate_get_cpu_info() {
     // Flags to test CPU type.
     const uint32_t HS_EFL_AC           = 0x40000;
     const uint32_t HS_EFL_ID           = 0x200000;
     // Values for when we don't have a CPUID instruction.
     const int      CPU_FAMILY_SHIFT = 8;
     const uint32_t CPU_FAMILY_386   = (3 << CPU_FAMILY_SHIFT);
     const uint32_t CPU_FAMILY_486   = (4 << CPU_FAMILY_SHIFT);
     Label detect_486, cpu486, detect_586, std_cpuid1, std_cpuid4;
     Label sef_cpuid, ext_cpuid, ext_cpuid1, ext_cpuid5, ext_cpuid7, done;
     StubCodeMark mark(this, "VM_Version", "get_cpu_info_stub");
 #   define __ _masm->
     address start = __ pc();
     //
     // void get_cpu_info(VM_Version::CpuidInfo* cpuid_info);
     //
     // LP64: rcx and rdx are first and second argument registers on windows
     __ push(rbp);
 #ifdef _LP64
     __ mov(rbp, c_rarg0); // cpuid_info address
 #else
     __ movptr(rbp, Address(rsp, 8)); // cpuid_info address
 #endif
     __ push(rbx);
     __ push(rsi);
     __ pushf();          // preserve rbx, and flags
     __ pop(rax);
     __ push(rax);
     __ mov(rcx, rax);
     //
     // if we are unable to change the AC flag, we have a 386
     //
     __ xorl(rax, HS_EFL_AC);
     __ push(rax);
     __ popf();
     __ pushf();
     __ pop(rax);
     __ cmpptr(rax, rcx);
     __ jccb(Assembler::notEqual, detect_486);
     __ movl(rax, CPU_FAMILY_386);
     __ movl(Address(rbp, in_bytes(VM_Version::std_cpuid1_offset())), rax);
     __ jmp(done);
     //
     // If we are unable to change the ID flag, we have a 486 which does
     // not support the "cpuid" instruction.
     //
     __ bind(detect_486);
     __ mov(rax, rcx);
     __ xorl(rax, HS_EFL_ID);
     __ push(rax);
     __ popf();
     __ pushf();
     __ pop(rax);
     __ cmpptr(rcx, rax);
     __ jccb(Assembler::notEqual, detect_586);
     __ bind(cpu486);
     __ movl(rax, CPU_FAMILY_486);
     __ movl(Address(rbp, in_bytes(VM_Version::std_cpuid1_offset())), rax);
     __ jmp(done);
     //
     // At this point, we have a chip which supports the "cpuid" instruction
     //
     __ bind(detect_586);
     __ xorl(rax, rax);
     __ cpuid();
     __ orl(rax, rax);
     __ jcc(Assembler::equal, cpu486);   // if cpuid doesn't support an input
                                         // value of at least 1, we give up and
                                         // assume a 486
     __ lea(rsi, Address(rbp, in_bytes(VM_Version::std_cpuid0_offset())));
     __ movl(Address(rsi, 0), rax);
     __ movl(Address(rsi, 4), rbx);
     __ movl(Address(rsi, 8), rcx);
     __ movl(Address(rsi,12), rdx);
     __ cmpl(rax, 0xa);                  // Is cpuid(0xB) supported?
     __ jccb(Assembler::belowEqual, std_cpuid4);
     //
     // cpuid(0xB) Processor Topology
     //
     __ movl(rax, 0xb);
     __ xorl(rcx, rcx);   // Threads level
     __ cpuid();
     __ lea(rsi, Address(rbp, in_bytes(VM_Version::tpl_cpuidB0_offset())));
     __ movl(Address(rsi, 0), rax);
     __ movl(Address(rsi, 4), rbx);
     __ movl(Address(rsi, 8), rcx);
     __ movl(Address(rsi,12), rdx);
     __ movl(rax, 0xb);
     __ movl(rcx, 1);     // Cores level
     __ cpuid();
     __ push(rax);
     __ andl(rax, 0x1f);  // Determine if valid topology level
     __ orl(rax, rbx);    // eax[4:0] | ebx[0:15] == 0 indicates invalid level
     __ andl(rax, 0xffff);
     __ pop(rax);
     __ jccb(Assembler::equal, std_cpuid4);
     __ lea(rsi, Address(rbp, in_bytes(VM_Version::tpl_cpuidB1_offset())));
     __ movl(Address(rsi, 0), rax);
     __ movl(Address(rsi, 4), rbx);
     __ movl(Address(rsi, 8), rcx);
     __ movl(Address(rsi,12), rdx);
     __ movl(rax, 0xb);
     __ movl(rcx, 2);     // Packages level
     __ cpuid();
     __ push(rax);
     __ andl(rax, 0x1f);  // Determine if valid topology level
     __ orl(rax, rbx);    // eax[4:0] | ebx[0:15] == 0 indicates invalid level
     __ andl(rax, 0xffff);
     __ pop(rax);
     __ jccb(Assembler::equal, std_cpuid4);
     __ lea(rsi, Address(rbp, in_bytes(VM_Version::tpl_cpuidB2_offset())));
     __ movl(Address(rsi, 0), rax);
     __ movl(Address(rsi, 4), rbx);
     __ movl(Address(rsi, 8), rcx);
     __ movl(Address(rsi,12), rdx);
     //
     // cpuid(0x4) Deterministic cache params
     //
     __ bind(std_cpuid4);
     __ movl(rax, 4);
     __ cmpl(rax, Address(rbp, in_bytes(VM_Version::std_cpuid0_offset()))); // Is cpuid(0x4) supported?
     __ jccb(Assembler::greater, std_cpuid1);
     __ xorl(rcx, rcx);   // L1 cache
     __ cpuid();
     __ push(rax);
     __ andl(rax, 0x1f);  // Determine if valid cache parameters used
     __ orl(rax, rax);    // eax[4:0] == 0 indicates invalid cache
     __ pop(rax);
     __ jccb(Assembler::equal, std_cpuid1);
     __ lea(rsi, Address(rbp, in_bytes(VM_Version::dcp_cpuid4_offset())));
     __ movl(Address(rsi, 0), rax);
     __ movl(Address(rsi, 4), rbx);
     __ movl(Address(rsi, 8), rcx);
     __ movl(Address(rsi,12), rdx);
     //
     // Standard cpuid(0x1)
     //
     __ bind(std_cpuid1);
     __ movl(rax, 1);
     __ cpuid();
     __ lea(rsi, Address(rbp, in_bytes(VM_Version::std_cpuid1_offset())));
     __ movl(Address(rsi, 0), rax);
     __ movl(Address(rsi, 4), rbx);
     __ movl(Address(rsi, 8), rcx);
     __ movl(Address(rsi,12), rdx);
     //
     // Check if OS has enabled XGETBV instruction to access XCR0
     // (OSXSAVE feature flag) and CPU supports AVX
     //
     __ andl(rcx, 0x18000000); // cpuid1 bits osxsave | avx
     __ cmpl(rcx, 0x18000000);
     __ jccb(Assembler::notEqual, sef_cpuid); // jump if AVX is not supported
     //
     // XCR0, XFEATURE_ENABLED_MASK register
     //
     __ xorl(rcx, rcx);   // zero for XCR0 register
     __ xgetbv();
     __ lea(rsi, Address(rbp, in_bytes(VM_Version::xem_xcr0_offset())));
     __ movl(Address(rsi, 0), rax);
     __ movl(Address(rsi, 4), rdx);
     __ andl(rax, 0x6); // xcr0 bits sse | ymm
     __ cmpl(rax, 0x6);
     __ jccb(Assembler::notEqual, sef_cpuid); // jump if AVX is not supported
     //
     // Some OSs have a bug when upper 128bits of YMM
     // registers are not restored after a signal processing.
     // Generate SEGV here (reference through NULL)
     // and check upper YMM bits after it.
     //
     VM_Version::set_avx_cpuFeatures(); // Enable temporary to pass asserts
     intx saved_useavx = UseAVX;
     intx saved_usesse = UseSSE;
     UseAVX = 1;
     UseSSE = 2;
     // load value into all 32 bytes of ymm7 register
     __ movl(rcx, VM_Version::ymm_test_value());
     __ movdl(xmm0, rcx);
     __ pshufd(xmm0, xmm0, 0x00);
     __ vinsertf128h(xmm0, xmm0, xmm0);
     __ vmovdqu(xmm7, xmm0);
 #ifdef _LP64
     __ vmovdqu(xmm8,  xmm0);
     __ vmovdqu(xmm15, xmm0);
 #endif
     __ xorl(rsi, rsi);
     VM_Version::set_cpuinfo_segv_addr( __ pc() );
     // Generate SEGV
     __ movl(rax, Address(rsi, 0));
     VM_Version::set_cpuinfo_cont_addr( __ pc() );
     // Returns here after signal. Save xmm0 to check it later.
     __ lea(rsi, Address(rbp, in_bytes(VM_Version::ymm_save_offset())));
     __ vmovdqu(Address(rsi,  0), xmm0);
     __ vmovdqu(Address(rsi, 32), xmm7);
 #ifdef _LP64
     __ vmovdqu(Address(rsi, 64), xmm8);
     __ vmovdqu(Address(rsi, 96), xmm15);
 #endif
     VM_Version::clean_cpuFeatures();
     UseAVX = saved_useavx;
     UseSSE = saved_usesse;
     //
     // cpuid(0x7) Structured Extended Features
     //
     __ bind(sef_cpuid);
     __ movl(rax, 7);
     __ cmpl(rax, Address(rbp, in_bytes(VM_Version::std_cpuid0_offset()))); // Is cpuid(0x7) supported?
     __ jccb(Assembler::greater, ext_cpuid);
     __ xorl(rcx, rcx);
     __ cpuid();
     __ lea(rsi, Address(rbp, in_bytes(VM_Version::sef_cpuid7_offset())));
     __ movl(Address(rsi, 0), rax);
     __ movl(Address(rsi, 4), rbx);
     //
     // Extended cpuid(0x80000000)
     //
     __ bind(ext_cpuid);
     __ movl(rax, 0x80000000);
     __ cpuid();
     __ cmpl(rax, 0x80000000);     // Is cpuid(0x80000001) supported?
     __ jcc(Assembler::belowEqual, done);
     __ cmpl(rax, 0x80000004);     // Is cpuid(0x80000005) supported?
     __ jccb(Assembler::belowEqual, ext_cpuid1);
     __ cmpl(rax, 0x80000006);     // Is cpuid(0x80000007) supported?
     __ jccb(Assembler::belowEqual, ext_cpuid5);
     __ cmpl(rax, 0x80000007);     // Is cpuid(0x80000008) supported?
     __ jccb(Assembler::belowEqual, ext_cpuid7);
     //
     // Extended cpuid(0x80000008)
     //
     __ movl(rax, 0x80000008);
     __ cpuid();
     __ lea(rsi, Address(rbp, in_bytes(VM_Version::ext_cpuid8_offset())));
     __ movl(Address(rsi, 0), rax);
     __ movl(Address(rsi, 4), rbx);
     __ movl(Address(rsi, 8), rcx);
     __ movl(Address(rsi,12), rdx);
     //
     // Extended cpuid(0x80000007)
     //
     __ bind(ext_cpuid7);
     __ movl(rax, 0x80000007);
     __ cpuid();
     __ lea(rsi, Address(rbp, in_bytes(VM_Version::ext_cpuid7_offset())));
     __ movl(Address(rsi, 0), rax);
     __ movl(Address(rsi, 4), rbx);
     __ movl(Address(rsi, 8), rcx);
     __ movl(Address(rsi,12), rdx);
     //
     // Extended cpuid(0x80000005)
     //
     __ bind(ext_cpuid5);
     __ movl(rax, 0x80000005);
     __ cpuid();
     __ lea(rsi, Address(rbp, in_bytes(VM_Version::ext_cpuid5_offset())));
     __ movl(Address(rsi, 0), rax);
     __ movl(Address(rsi, 4), rbx);
     __ movl(Address(rsi, 8), rcx);
     __ movl(Address(rsi,12), rdx);
     //
     // Extended cpuid(0x80000001)
     //
     __ bind(ext_cpuid1);
     __ movl(rax, 0x80000001);
     __ cpuid();
     __ lea(rsi, Address(rbp, in_bytes(VM_Version::ext_cpuid1_offset())));
     __ movl(Address(rsi, 0), rax);
     __ movl(Address(rsi, 4), rbx);
     __ movl(Address(rsi, 8), rcx);
     __ movl(Address(rsi,12), rdx);
     //
     // return
     //
     __ bind(done);
     __ popf();
     __ pop(rsi);
     __ pop(rbx);
     __ pop(rbp);
     __ ret(0);
 #   undef __
     return start;
   };
 };
 void VM_Version::get_cpu_info_wrapper() {
   get_cpu_info_stub(&_cpuid_info);
 }
 #ifndef CALL_TEST_FUNC_WITH_WRAPPER_IF_NEEDED
   #define CALL_TEST_FUNC_WITH_WRAPPER_IF_NEEDED(f) f()
 #endif
 void VM_Version::get_processor_features() {
   _cpu = 4; // 486 by default
   _model = 0;
   _stepping = 0;
   _cpuFeatures = 0;
   _logical_processors_per_package = 1;
   // i486 internal cache is both I&D and has a 16-byte line size
   _L1_data_cache_line_size = 16;
   if (!Use486InstrsOnly) {
     // Get raw processor info
     // Some platforms (like Win*) need a wrapper around here
     // in order to properly handle SEGV for YMM registers test.
     CALL_TEST_FUNC_WITH_WRAPPER_IF_NEEDED(get_cpu_info_wrapper);
     assert_is_initialized();
     _cpu = extended_cpu_family();
     _model = extended_cpu_model();
     _stepping = cpu_stepping();
     if (cpu_family() > 4) { // it supports CPUID
       _cpuFeatures = feature_flags();
       // Logical processors are only available on P4s and above,
       // and only if hyperthreading is available.
       _logical_processors_per_package = logical_processor_count();
       _L1_data_cache_line_size = L1_line_size();
     }
   }
   _supports_cx8 = supports_cmpxchg8();
   // xchg and xadd instructions
   _supports_atomic_getset4 = true;
   _supports_atomic_getadd4 = true;
   LP64_ONLY(_supports_atomic_getset8 = true);
   LP64_ONLY(_supports_atomic_getadd8 = true);
 #ifdef _LP64
   // OS should support SSE for x64 and hardware should support at least SSE2.
   if (!VM_Version::supports_sse2()) {
     vm_exit_during_initialization("Unknown x64 processor: SSE2 not supported");
   }
   // in 64 bit the use of SSE2 is the minimum
   if (UseSSE < 2) UseSSE = 2;
 #endif
 #ifdef AMD64
   // flush_icache_stub have to be generated first.
   // That is why Icache line size is hard coded in ICache class,
   // see icache_x86.hpp. It is also the reason why we can't use
   // clflush instruction in 32-bit VM since it could be running
   // on CPU which does not support it.
   //
   // The only thing we can do is to verify that flushed
   // ICache::line_size has correct value.
   guarantee(_cpuid_info.std_cpuid1_edx.bits.clflush != 0, "clflush is not supported");
   // clflush_size is size in quadwords (8 bytes).
   guarantee(_cpuid_info.std_cpuid1_ebx.bits.clflush_size == 8, "such clflush size is not supported");
 #endif
   // If the OS doesn't support SSE, we can't use this feature even if the HW does
   if (!os::supports_sse())
     _cpuFeatures &= ~(CPU_SSE|CPU_SSE2|CPU_SSE3|CPU_SSSE3|CPU_SSE4A|CPU_SSE4_1|CPU_SSE4_2);
   if (UseSSE < 4) {
     _cpuFeatures &= ~CPU_SSE4_1;
     _cpuFeatures &= ~CPU_SSE4_2;
   }
   if (UseSSE < 3) {
     _cpuFeatures &= ~CPU_SSE3;
     _cpuFeatures &= ~CPU_SSSE3;
     _cpuFeatures &= ~CPU_SSE4A;
   }
   if (UseSSE < 2)
     _cpuFeatures &= ~CPU_SSE2;
   if (UseSSE < 1)
     _cpuFeatures &= ~CPU_SSE;
   if (UseAVX < 2)
     _cpuFeatures &= ~CPU_AVX2;
   if (UseAVX < 1)
     _cpuFeatures &= ~CPU_AVX;
   if (!UseAES && !FLAG_IS_DEFAULT(UseAES))
     _cpuFeatures &= ~CPU_AES;
   if (logical_processors_per_package() == 1) {
     // HT processor could be installed on a system which doesn't support HT.
     _cpuFeatures &= ~CPU_HT;
   }
   char buf[256];
   jio_snprintf(buf, sizeof(buf), "(%u cores per cpu, %u threads per core) family %d model %d stepping %d%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s",
                cores_per_cpu(), threads_per_core(),
                cpu_family(), _model, _stepping,
                (supports_cmov() ? ", cmov" : ""),
                (supports_cmpxchg8() ? ", cx8" : ""),
                (supports_fxsr() ? ", fxsr" : ""),
                (supports_mmx()  ? ", mmx"  : ""),
                (supports_sse()  ? ", sse"  : ""),
                (supports_sse2() ? ", sse2" : ""),
                (supports_sse3() ? ", sse3" : ""),
                (supports_ssse3()? ", ssse3": ""),
                (supports_sse4_1() ? ", sse4.1" : ""),
                (supports_sse4_2() ? ", sse4.2" : ""),
                (supports_popcnt() ? ", popcnt" : ""),
                (supports_avx()    ? ", avx" : ""),
                (supports_avx2()   ? ", avx2" : ""),
                (supports_aes()    ? ", aes" : ""),
                (supports_clmul()  ? ", clmul" : ""),
                (supports_erms()   ? ", erms" : ""),
                (supports_rtm()    ? ", rtm" : ""),
                (supports_mmx_ext() ? ", mmxext" : ""),
                (supports_3dnow_prefetch() ? ", 3dnowpref" : ""),
                (supports_lzcnt()   ? ", lzcnt": ""),
                (supports_sse4a()   ? ", sse4a": ""),
                (supports_ht() ? ", ht": ""),
                (supports_tsc() ? ", tsc": ""),
                (supports_tscinv_bit() ? ", tscinvbit": ""),
                (supports_tscinv() ? ", tscinv": ""),
                (supports_bmi1() ? ", bmi1" : ""),
                (supports_bmi2() ? ", bmi2" : ""),
                (supports_adx() ? ", adx" : ""));
   _features_str = strdup(buf);
   // UseSSE is set to the smaller of what hardware supports and what
   // the command line requires.  I.e., you cannot set UseSSE to 2 on
   // older Pentiums which do not support it.
   if (UseSSE > 4) UseSSE=4;
   if (UseSSE < 0) UseSSE=0;
   if (!supports_sse4_1()) // Drop to 3 if no SSE4 support
     UseSSE = MIN2((intx)3,UseSSE);
   if (!supports_sse3()) // Drop to 2 if no SSE3 support
     UseSSE = MIN2((intx)2,UseSSE);
   if (!supports_sse2()) // Drop to 1 if no SSE2 support
     UseSSE = MIN2((intx)1,UseSSE);
   if (!supports_sse ()) // Drop to 0 if no SSE  support
     UseSSE = 0;
   if (UseAVX > 2) UseAVX=2;
   if (UseAVX < 0) UseAVX=0;
   if (!supports_avx2()) // Drop to 1 if no AVX2 support
     UseAVX = MIN2((intx)1,UseAVX);
   if (!supports_avx ()) // Drop to 0 if no AVX  support
     UseAVX = 0;
   // Use AES instructions if available.
   if (supports_aes()) {
     if (FLAG_IS_DEFAULT(UseAES)) {
       UseAES = true;
     }
   } else if (UseAES) {
     if (!FLAG_IS_DEFAULT(UseAES))
       warning("AES instructions are not available on this CPU");
     FLAG_SET_DEFAULT(UseAES, false);
   }
   // Use CLMUL instructions if available.
   if (supports_clmul()) {
     if (FLAG_IS_DEFAULT(UseCLMUL)) {
       UseCLMUL = true;
     }
   } else if (UseCLMUL) {
     if (!FLAG_IS_DEFAULT(UseCLMUL))
       warning("CLMUL instructions not available on this CPU (AVX may also be required)");
     FLAG_SET_DEFAULT(UseCLMUL, false);
   }
   if (UseCLMUL && (UseSSE > 2)) {
     if (FLAG_IS_DEFAULT(UseCRC32Intrinsics)) {
       UseCRC32Intrinsics = true;
     }
   } else if (UseCRC32Intrinsics) {
     if (!FLAG_IS_DEFAULT(UseCRC32Intrinsics))
       warning("CRC32 Intrinsics requires CLMUL instructions (not available on this CPU)");
     FLAG_SET_DEFAULT(UseCRC32Intrinsics, false);
   }
   // The AES intrinsic stubs require AES instruction support (of course)
   // but also require sse3 mode for instructions it use.
   if (UseAES && (UseSSE > 2)) {
     if (FLAG_IS_DEFAULT(UseAESIntrinsics)) {
       UseAESIntrinsics = true;
     }
   } else if (UseAESIntrinsics) {
     if (!FLAG_IS_DEFAULT(UseAESIntrinsics))
       warning("AES intrinsics are not available on this CPU");
     FLAG_SET_DEFAULT(UseAESIntrinsics, false);
   }
   if (UseSHA) {
     warning("SHA instructions are not available on this CPU");
     FLAG_SET_DEFAULT(UseSHA, false);
   }
   if (UseSHA1Intrinsics || UseSHA256Intrinsics || UseSHA512Intrinsics) {
     warning("SHA intrinsics are not available on this CPU");
     FLAG_SET_DEFAULT(UseSHA1Intrinsics, false);
     FLAG_SET_DEFAULT(UseSHA256Intrinsics, false);
     FLAG_SET_DEFAULT(UseSHA512Intrinsics, false);
   }
   // Adjust RTM (Restricted Transactional Memory) flags
   if (!supports_rtm() && UseRTMLocking) {
     // Can't continue because UseRTMLocking affects UseBiasedLocking flag
     // setting during arguments processing. See use_biased_locking().
     // VM_Version_init() is executed after UseBiasedLocking is used
     // in Thread::allocate().
     vm_exit_during_initialization("RTM instructions are not available on this CPU");
   }
 #if INCLUDE_RTM_OPT
   if (UseRTMLocking) {
     if (is_intel_family_core()) {
       if ((_model == CPU_MODEL_HASWELL_E3) ||
           (_model == CPU_MODEL_HASWELL_E7 && _stepping < 3) ||
           (_model == CPU_MODEL_BROADWELL  && _stepping < 4)) {
         if (!UnlockExperimentalVMOptions) {
           vm_exit_during_initialization("UseRTMLocking is only available as experimental option on this platform. It must be enabled via -XX:+UnlockExperimentalVMOptions flag.");
         } else {
           warning("UseRTMLocking is only available as experimental option on this platform.");
         }
       }
     }
     if (!FLAG_IS_CMDLINE(UseRTMLocking)) {
       // RTM locking should be used only for applications with
       // high lock contention. For now we do not use it by default.
       vm_exit_during_initialization("UseRTMLocking flag should be only set on command line");
     }
     if (!is_power_of_2(RTMTotalCountIncrRate)) {
       warning("RTMTotalCountIncrRate must be a power of 2, resetting it to 64");
       FLAG_SET_DEFAULT(RTMTotalCountIncrRate, 64);
     }
     if (RTMAbortRatio < 0 || RTMAbortRatio > 100) {
       warning("RTMAbortRatio must be in the range 0 to 100, resetting it to 50");
       FLAG_SET_DEFAULT(RTMAbortRatio, 50);
     }
   } else { // !UseRTMLocking
     if (UseRTMForStackLocks) {
       if (!FLAG_IS_DEFAULT(UseRTMForStackLocks)) {
         warning("UseRTMForStackLocks flag should be off when UseRTMLocking flag is off");
       }
       FLAG_SET_DEFAULT(UseRTMForStackLocks, false);
     }
     if (UseRTMDeopt) {
       FLAG_SET_DEFAULT(UseRTMDeopt, false);
     }
     if (PrintPreciseRTMLockingStatistics) {
       FLAG_SET_DEFAULT(PrintPreciseRTMLockingStatistics, false);
     }
   }
 #else
   if (UseRTMLocking) {
     // Only C2 does RTM locking optimization.
     // Can't continue because UseRTMLocking affects UseBiasedLocking flag
     // setting during arguments processing. See use_biased_locking().
     vm_exit_during_initialization("RTM locking optimization is not supported in this VM");
   }
 #endif
 #ifdef COMPILER2
   if (UseFPUForSpilling) {
     if (UseSSE < 2) {
       // Only supported with SSE2+
       FLAG_SET_DEFAULT(UseFPUForSpilling, false);
     }
   }
   if (MaxVectorSize > 0) {
     if (!is_power_of_2(MaxVectorSize)) {
       warning("MaxVectorSize must be a power of 2");
       FLAG_SET_DEFAULT(MaxVectorSize, 32);
     }
     if (MaxVectorSize > 32) {
       FLAG_SET_DEFAULT(MaxVectorSize, 32);
     }
     if (MaxVectorSize > 16 && (UseAVX == 0 || !os_supports_avx_vectors())) {
       // 32 bytes vectors (in YMM) are only supported with AVX+
       FLAG_SET_DEFAULT(MaxVectorSize, 16);
     }
     if (UseSSE < 2) {
       // Vectors (in XMM) are only supported with SSE2+
       FLAG_SET_DEFAULT(MaxVectorSize, 0);
     }
 #ifdef ASSERT
     if (supports_avx() && PrintMiscellaneous && Verbose && TraceNewVectors) {
       tty->print_cr("State of YMM registers after signal handle:");
       int nreg = 2 LP64_ONLY(+2);
       const char* ymm_name[4] = {"0", "7", "8", "15"};
       for (int i = 0; i < nreg; i++) {
         tty->print("YMM%s:", ymm_name[i]);
         for (int j = 7; j >=0; j--) {
           tty->print(" %x", _cpuid_info.ymm_save[i*8 + j]);
         }
         tty->cr();
       }
     }
 #endif
   }
 #ifdef _LP64
   if (FLAG_IS_DEFAULT(UseMultiplyToLenIntrinsic)) {
     UseMultiplyToLenIntrinsic = true;
   }
   if (FLAG_IS_DEFAULT(UseSquareToLenIntrinsic)) {
     UseSquareToLenIntrinsic = true;
   }
   if (FLAG_IS_DEFAULT(UseMulAddIntrinsic)) {
     UseMulAddIntrinsic = true;
   }
   if (FLAG_IS_DEFAULT(UseMontgomeryMultiplyIntrinsic)) {
     UseMontgomeryMultiplyIntrinsic = true;
   }
   if (FLAG_IS_DEFAULT(UseMontgomerySquareIntrinsic)) {
     UseMontgomerySquareIntrinsic = true;
   }
 #else
   if (UseMultiplyToLenIntrinsic) {
     if (!FLAG_IS_DEFAULT(UseMultiplyToLenIntrinsic)) {
       warning("multiplyToLen intrinsic is not available in 32-bit VM");
     }
     FLAG_SET_DEFAULT(UseMultiplyToLenIntrinsic, false);
   }
   if (UseSquareToLenIntrinsic) {
     if (!FLAG_IS_DEFAULT(UseSquareToLenIntrinsic)) {
       warning("squareToLen intrinsic is not available in 32-bit VM");
     }
     FLAG_SET_DEFAULT(UseSquareToLenIntrinsic, false);
   }
   if (UseMulAddIntrinsic) {
     if (!FLAG_IS_DEFAULT(UseMulAddIntrinsic)) {
       warning("mulAdd intrinsic is not available in 32-bit VM");
     }
     FLAG_SET_DEFAULT(UseMulAddIntrinsic, false);
   }
   if (UseMontgomeryMultiplyIntrinsic) {
     if (!FLAG_IS_DEFAULT(UseMontgomeryMultiplyIntrinsic)) {
       warning("montgomeryMultiply intrinsic is not available in 32-bit VM");
     }
     FLAG_SET_DEFAULT(UseMontgomeryMultiplyIntrinsic, false);
   }
   if (UseMontgomerySquareIntrinsic) {
     if (!FLAG_IS_DEFAULT(UseMontgomerySquareIntrinsic)) {
       warning("montgomerySquare intrinsic is not available in 32-bit VM");
     }
     FLAG_SET_DEFAULT(UseMontgomerySquareIntrinsic, false);
   }
 #endif
 #endif // COMPILER2
   // On new cpus instructions which update whole XMM register should be used
   // to prevent partial register stall due to dependencies on high half.
   //
   // UseXmmLoadAndClearUpper == true  --> movsd(xmm, mem)
   // UseXmmLoadAndClearUpper == false --> movlpd(xmm, mem)
   // UseXmmRegToRegMoveAll == true  --> movaps(xmm, xmm), movapd(xmm, xmm).
   // UseXmmRegToRegMoveAll == false --> movss(xmm, xmm),  movsd(xmm, xmm).
   if( is_amd() ) { // AMD cpus specific settings
     if( supports_sse2() && FLAG_IS_DEFAULT(UseAddressNop) ) {
       // Use it on new AMD cpus starting from Opteron.
       UseAddressNop = true;
     }
     if( supports_sse2() && FLAG_IS_DEFAULT(UseNewLongLShift) ) {
       // Use it on new AMD cpus starting from Opteron.
       UseNewLongLShift = true;
     }
     if( FLAG_IS_DEFAULT(UseXmmLoadAndClearUpper) ) {
       if( supports_sse4a() ) {
         UseXmmLoadAndClearUpper = true; // use movsd only on '10h' Opteron
       } else {
         UseXmmLoadAndClearUpper = false;
       }
     }
     if( FLAG_IS_DEFAULT(UseXmmRegToRegMoveAll) ) {
       if( supports_sse4a() ) {
         UseXmmRegToRegMoveAll = true; // use movaps, movapd only on '10h'
       } else {
         UseXmmRegToRegMoveAll = false;
       }
     }
     if( FLAG_IS_DEFAULT(UseXmmI2F) ) {
       if( supports_sse4a() ) {
         UseXmmI2F = true;
       } else {
         UseXmmI2F = false;
       }
     }
     if( FLAG_IS_DEFAULT(UseXmmI2D) ) {
       if( supports_sse4a() ) {
         UseXmmI2D = true;
       } else {
         UseXmmI2D = false;
       }
     }
     if( FLAG_IS_DEFAULT(UseSSE42Intrinsics) ) {
       if( supports_sse4_2() && UseSSE >= 4 ) {
         UseSSE42Intrinsics = true;
       }
     }
     // some defaults for AMD family 15h
     if ( cpu_family() == 0x15 ) {
       // On family 15h processors default is no sw prefetch
       if (FLAG_IS_DEFAULT(AllocatePrefetchStyle)) {
         AllocatePrefetchStyle = 0;
       }
       // Also, if some other prefetch style is specified, default instruction type is PREFETCHW
       if (FLAG_IS_DEFAULT(AllocatePrefetchInstr)) {
         AllocatePrefetchInstr = 3;
       }
       // On family 15h processors use XMM and UnalignedLoadStores for Array Copy
       if (supports_sse2() && FLAG_IS_DEFAULT(UseXMMForArrayCopy)) {
         UseXMMForArrayCopy = true;
       }
       if (supports_sse2() && FLAG_IS_DEFAULT(UseUnalignedLoadStores)) {
         UseUnalignedLoadStores = true;
       }
     }
 #ifdef COMPILER2
     if (MaxVectorSize > 16) {
       // Limit vectors size to 16 bytes on current AMD cpus.
       FLAG_SET_DEFAULT(MaxVectorSize, 16);
     }
 #endif // COMPILER2
   }
   if( is_intel() ) { // Intel cpus specific settings
     if( FLAG_IS_DEFAULT(UseStoreImmI16) ) {
       UseStoreImmI16 = false; // don't use it on Intel cpus
     }
     if( cpu_family() == 6 || cpu_family() == 15 ) {
       if( FLAG_IS_DEFAULT(UseAddressNop) ) {
         // Use it on all Intel cpus starting from PentiumPro
         UseAddressNop = true;
       }
     }
     if( FLAG_IS_DEFAULT(UseXmmLoadAndClearUpper) ) {
       UseXmmLoadAndClearUpper = true; // use movsd on all Intel cpus
     }
     if( FLAG_IS_DEFAULT(UseXmmRegToRegMoveAll) ) {
       if( supports_sse3() ) {
         UseXmmRegToRegMoveAll = true; // use movaps, movapd on new Intel cpus
       } else {
         UseXmmRegToRegMoveAll = false;
       }
     }
     if( cpu_family() == 6 && supports_sse3() ) { // New Intel cpus
 #ifdef COMPILER2
       if( FLAG_IS_DEFAULT(MaxLoopPad) ) {
         // For new Intel cpus do the next optimization:
         // don't align the beginning of a loop if there are enough instructions
         // left (NumberOfLoopInstrToAlign defined in c2_globals.hpp)
         // in current fetch line (OptoLoopAlignment) or the padding
         // is big (> MaxLoopPad).
         // Set MaxLoopPad to 11 for new Intel cpus to reduce number of
         // generated NOP instructions. 11 is the largest size of one
         // address NOP instruction '0F 1F' (see Assembler::nop(i)).
         MaxLoopPad = 11;
       }
 #endif // COMPILER2
       if (FLAG_IS_DEFAULT(UseXMMForArrayCopy)) {
         UseXMMForArrayCopy = true; // use SSE2 movq on new Intel cpus
       }
       if (supports_sse4_2() && supports_ht()) { // Newest Intel cpus
         if (FLAG_IS_DEFAULT(UseUnalignedLoadStores)) {
           UseUnalignedLoadStores = true; // use movdqu on newest Intel cpus
         }
       }
       if (supports_sse4_2() && UseSSE >= 4) {
         if (FLAG_IS_DEFAULT(UseSSE42Intrinsics)) {
           UseSSE42Intrinsics = true;
         }
       }
     }
     if ((cpu_family() == 0x06) &&
         ((extended_cpu_model() == 0x36) || // Centerton
          (extended_cpu_model() == 0x37) || // Silvermont
          (extended_cpu_model() == 0x4D))) {
 #ifdef COMPILER2
       if (FLAG_IS_DEFAULT(OptoScheduling)) {
         OptoScheduling = true;
       }
 #endif
       if (supports_sse4_2()) { // Silvermont
         if (FLAG_IS_DEFAULT(UseUnalignedLoadStores)) {
           UseUnalignedLoadStores = true; // use movdqu on newest Intel cpus
         }
       }
     }
     if(FLAG_IS_DEFAULT(AllocatePrefetchInstr) && supports_3dnow_prefetch()) {
       AllocatePrefetchInstr = 3;
     }
   }
   // Use count leading zeros count instruction if available.
   if (supports_lzcnt()) {
     if (FLAG_IS_DEFAULT(UseCountLeadingZerosInstruction)) {
       UseCountLeadingZerosInstruction = true;
     }
    } else if (UseCountLeadingZerosInstruction) {
     warning("lzcnt instruction is not available on this CPU");
     FLAG_SET_DEFAULT(UseCountLeadingZerosInstruction, false);
   }
   // Use count trailing zeros instruction if available
   if (supports_bmi1()) {
     // tzcnt does not require VEX prefix
     if (FLAG_IS_DEFAULT(UseCountTrailingZerosInstruction)) {
       if (!UseBMI1Instructions && !FLAG_IS_DEFAULT(UseBMI1Instructions)) {
         // Don't use tzcnt if BMI1 is switched off on command line.
         UseCountTrailingZerosInstruction = false;
       } else {
         UseCountTrailingZerosInstruction = true;
       }
     }
   } else if (UseCountTrailingZerosInstruction) {
     warning("tzcnt instruction is not available on this CPU");
     FLAG_SET_DEFAULT(UseCountTrailingZerosInstruction, false);
   }
   // BMI instructions (except tzcnt) use an encoding with VEX prefix.
   // VEX prefix is generated only when AVX > 0.
   if (supports_bmi1() && supports_avx()) {
     if (FLAG_IS_DEFAULT(UseBMI1Instructions)) {
       UseBMI1Instructions = true;
     }
   } else if (UseBMI1Instructions) {
     warning("BMI1 instructions are not available on this CPU (AVX is also required)");
     FLAG_SET_DEFAULT(UseBMI1Instructions, false);
   }
   if (supports_bmi2() && supports_avx()) {
     if (FLAG_IS_DEFAULT(UseBMI2Instructions)) {
       UseBMI2Instructions = true;
     }
   } else if (UseBMI2Instructions) {
     warning("BMI2 instructions are not available on this CPU (AVX is also required)");
     FLAG_SET_DEFAULT(UseBMI2Instructions, false);
   }
   // Use population count instruction if available.
   if (supports_popcnt()) {
     if (FLAG_IS_DEFAULT(UsePopCountInstruction)) {
       UsePopCountInstruction = true;
     }
   } else if (UsePopCountInstruction) {
     warning("POPCNT instruction is not available on this CPU");
     FLAG_SET_DEFAULT(UsePopCountInstruction, false);
   }
   // Use fast-string operations if available.
   if (supports_erms()) {
     if (FLAG_IS_DEFAULT(UseFastStosb)) {
       UseFastStosb = true;
     }
   } else if (UseFastStosb) {
     warning("fast-string operations are not available on this CPU");
     FLAG_SET_DEFAULT(UseFastStosb, false);
   }
 #ifdef COMPILER2
   if (FLAG_IS_DEFAULT(AlignVector)) {
     // Modern processors allow misaligned memory operations for vectors.
     AlignVector = !UseUnalignedLoadStores;
   }
 #endif // COMPILER2
   assert(0 <= ReadPrefetchInstr && ReadPrefetchInstr <= 3, "invalid value");
   assert(0 <= AllocatePrefetchInstr && AllocatePrefetchInstr <= 3, "invalid value");
   // set valid Prefetch instruction
   if( ReadPrefetchInstr < 0 ) ReadPrefetchInstr = 0;
   if( ReadPrefetchInstr > 3 ) ReadPrefetchInstr = 3;
   if( ReadPrefetchInstr == 3 && !supports_3dnow_prefetch() ) ReadPrefetchInstr = 0;
   if( !supports_sse() && supports_3dnow_prefetch() ) ReadPrefetchInstr = 3;
   if( AllocatePrefetchInstr < 0 ) AllocatePrefetchInstr = 0;
   if( AllocatePrefetchInstr > 3 ) AllocatePrefetchInstr = 3;
   if( AllocatePrefetchInstr == 3 && !supports_3dnow_prefetch() ) AllocatePrefetchInstr=0;
   if( !supports_sse() && supports_3dnow_prefetch() ) AllocatePrefetchInstr = 3;
   // Allocation prefetch settings
   intx cache_line_size = prefetch_data_size();
   if( cache_line_size > AllocatePrefetchStepSize )
     AllocatePrefetchStepSize = cache_line_size;
   assert(AllocatePrefetchLines > 0, "invalid value");
   if( AllocatePrefetchLines < 1 )     // set valid value in product VM
     AllocatePrefetchLines = 3;
   assert(AllocateInstancePrefetchLines > 0, "invalid value");
   if( AllocateInstancePrefetchLines < 1 ) // set valid value in product VM
     AllocateInstancePrefetchLines = 1;
   AllocatePrefetchDistance = allocate_prefetch_distance();
   AllocatePrefetchStyle    = allocate_prefetch_style();
   if (is_intel() && cpu_family() == 6 && supports_sse3()) {
     if (AllocatePrefetchStyle == 2) { // watermark prefetching on Core
 #ifdef _LP64
       AllocatePrefetchDistance = 384;
 #else
       AllocatePrefetchDistance = 320;
 #endif
     }
     if (supports_sse4_2() && supports_ht()) { // Nehalem based cpus
       AllocatePrefetchDistance = 192;
       AllocatePrefetchLines = 4;
     }
 #ifdef COMPILER2
     if (supports_sse4_2()) {
       if (FLAG_IS_DEFAULT(UseFPUForSpilling)) {
         FLAG_SET_DEFAULT(UseFPUForSpilling, true);
       }
     }
 #endif
   }
   assert(AllocatePrefetchDistance % AllocatePrefetchStepSize == 0, "invalid value");
 #ifdef _LP64
   // Prefetch settings
   PrefetchCopyIntervalInBytes = prefetch_copy_interval_in_bytes();
   PrefetchScanIntervalInBytes = prefetch_scan_interval_in_bytes();
   PrefetchFieldsAhead         = prefetch_fields_ahead();
 #endif
   if (FLAG_IS_DEFAULT(ContendedPaddingWidth) &&
      (cache_line_size > ContendedPaddingWidth))
      ContendedPaddingWidth = cache_line_size;
 #ifndef PRODUCT
   if (PrintMiscellaneous && Verbose) {
     tty->print_cr("Logical CPUs per core: %u",
                   logical_processors_per_package());
     tty->print_cr("L1 data cache line size: %u", L1_data_cache_line_size());
     tty->print("UseSSE=%d", (int) UseSSE);
     if (UseAVX > 0) {
       tty->print("  UseAVX=%d", (int) UseAVX);
     }
     if (UseAES) {
       tty->print("  UseAES=1");
     }
 #ifdef COMPILER2
     if (MaxVectorSize > 0) {
       tty->print("  MaxVectorSize=%d", (int) MaxVectorSize);
     }
 #endif
     tty->cr();
     tty->print("Allocation");
     if (AllocatePrefetchStyle <= 0 || UseSSE == 0 && !supports_3dnow_prefetch()) {
       tty->print_cr(": no prefetching");
     } else {
       tty->print(" prefetching: ");
       if (UseSSE == 0 && supports_3dnow_prefetch()) {
         tty->print("PREFETCHW");
       } else if (UseSSE >= 1) {
         if (AllocatePrefetchInstr == 0) {
           tty->print("PREFETCHNTA");
         } else if (AllocatePrefetchInstr == 1) {
           tty->print("PREFETCHT0");
         } else if (AllocatePrefetchInstr == 2) {
           tty->print("PREFETCHT2");
         } else if (AllocatePrefetchInstr == 3) {
           tty->print("PREFETCHW");
         }
       }
       if (AllocatePrefetchLines > 1) {
         tty->print_cr(" at distance %d, %d lines of %d bytes", (int) AllocatePrefetchDistance, (int) AllocatePrefetchLines, (int) AllocatePrefetchStepSize);
       } else {
         tty->print_cr(" at distance %d, one line of %d bytes", (int) AllocatePrefetchDistance, (int) AllocatePrefetchStepSize);
       }
     }
     if (PrefetchCopyIntervalInBytes > 0) {
       tty->print_cr("PrefetchCopyIntervalInBytes %d", (int) PrefetchCopyIntervalInBytes);
     }
     if (PrefetchScanIntervalInBytes > 0) {
       tty->print_cr("PrefetchScanIntervalInBytes %d", (int) PrefetchScanIntervalInBytes);
     }
     if (PrefetchFieldsAhead > 0) {
       tty->print_cr("PrefetchFieldsAhead %d", (int) PrefetchFieldsAhead);
     }
     if (ContendedPaddingWidth > 0) {
       tty->print_cr("ContendedPaddingWidth %d", (int) ContendedPaddingWidth);
     }
   }
 #endif // !PRODUCT
 }
 bool VM_Version::use_biased_locking() {
 #if INCLUDE_RTM_OPT
   // RTM locking is most useful when there is high lock contention and
   // low data contention.  With high lock contention the lock is usually
   // inflated and biased locking is not suitable for that case.
   // RTM locking code requires that biased locking is off.
   // Note: we can't switch off UseBiasedLocking in get_processor_features()
   // because it is used by Thread::allocate() which is called before
   // VM_Version::initialize().
   if (UseRTMLocking && UseBiasedLocking) {
     if (FLAG_IS_DEFAULT(UseBiasedLocking)) {
       FLAG_SET_DEFAULT(UseBiasedLocking, false);
     } else {
       warning("Biased locking is not supported with RTM locking; ignoring UseBiasedLocking flag." );
       UseBiasedLocking = false;
     }
   }
 #endif
   return UseBiasedLocking;
 }
 void VM_Version::initialize() {
   ResourceMark rm;
   // Making this stub must be FIRST use of assembler
   stub_blob = BufferBlob::create("get_cpu_info_stub", stub_size);
   if (stub_blob == NULL) {
     vm_exit_during_initialization("Unable to allocate get_cpu_info_stub");
   }
   CodeBuffer c(stub_blob);
   VM_Version_StubGenerator g(&c);
   get_cpu_info_stub = CAST_TO_FN_PTR(get_cpu_info_stub_t,
                                      g.generate_get_cpu_info());
   get_processor_features();
 }

Mercurial > jdk8-mips64-public > hotspot / annotate

src/cpu/x86/vm/vm_version_x86.cpp@7c2285d86b8d (annotated)

src/cpu/x86/vm/vm_version_x86.cpp