Mercurial > hg > graal-compiler
view src/share/vm/opto/regmask.cpp @ 6972:bd7a7ce2e264
6830717: replay of compilations would help with debugging
Summary: When java process crashed in compiler thread, repeat the compilation process will help finding root cause. This is done with using SA dump application class data and replay data from core dump, then use debug version of jvm to recompile the problematic java method.
Reviewed-by: kvn, twisti, sspitsyn
Contributed-by: yumin.qi@oracle.com
| author | minqi |
|---|---|
| date | Mon, 12 Nov 2012 14:03:53 -0800 |
| parents | 8c92982cbbc4 |
| children | a7114d3d712e |
line wrap: on
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/* * Copyright (c) 1997, 2012, 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 "opto/compile.hpp" #include "opto/regmask.hpp" #ifdef TARGET_ARCH_MODEL_x86_32 # include "adfiles/ad_x86_32.hpp" #endif #ifdef TARGET_ARCH_MODEL_x86_64 # include "adfiles/ad_x86_64.hpp" #endif #ifdef TARGET_ARCH_MODEL_sparc # include "adfiles/ad_sparc.hpp" #endif #ifdef TARGET_ARCH_MODEL_zero # include "adfiles/ad_zero.hpp" #endif #ifdef TARGET_ARCH_MODEL_arm # include "adfiles/ad_arm.hpp" #endif #ifdef TARGET_ARCH_MODEL_ppc # include "adfiles/ad_ppc.hpp" #endif #define RM_SIZE _RM_SIZE /* a constant private to the class RegMask */ //-------------Non-zero bit search methods used by RegMask--------------------- // Find lowest 1, or return 32 if empty int find_lowest_bit( uint32 mask ) { int n = 0; if( (mask & 0xffff) == 0 ) { mask >>= 16; n += 16; } if( (mask & 0xff) == 0 ) { mask >>= 8; n += 8; } if( (mask & 0xf) == 0 ) { mask >>= 4; n += 4; } if( (mask & 0x3) == 0 ) { mask >>= 2; n += 2; } if( (mask & 0x1) == 0 ) { mask >>= 1; n += 1; } if( mask == 0 ) { n = 32; } return n; } // Find highest 1, or return 32 if empty int find_hihghest_bit( uint32 mask ) { int n = 0; if( mask > 0xffff ) { mask >>= 16; n += 16; } if( mask > 0xff ) { mask >>= 8; n += 8; } if( mask > 0xf ) { mask >>= 4; n += 4; } if( mask > 0x3 ) { mask >>= 2; n += 2; } if( mask > 0x1 ) { mask >>= 1; n += 1; } if( mask == 0 ) { n = 32; } return n; } //------------------------------dump------------------------------------------- #ifndef PRODUCT void OptoReg::dump( int r ) { switch( r ) { case Special: tty->print("r---"); break; case Bad: tty->print("rBAD"); break; default: if( r < _last_Mach_Reg ) tty->print(Matcher::regName[r]); else tty->print("rS%d",r); break; } } #endif //============================================================================= const RegMask RegMask::Empty( # define BODY(I) 0, FORALL_BODY # undef BODY 0 ); //============================================================================= bool RegMask::is_vector(uint ireg) { return (ireg == Op_VecS || ireg == Op_VecD || ireg == Op_VecX || ireg == Op_VecY); } int RegMask::num_registers(uint ireg) { switch(ireg) { case Op_VecY: return 8; case Op_VecX: return 4; case Op_VecD: case Op_RegD: case Op_RegL: #ifdef _LP64 case Op_RegP: #endif return 2; } // Op_VecS and the rest ideal registers. return 1; } //------------------------------find_first_pair-------------------------------- // Find the lowest-numbered register pair in the mask. Return the // HIGHEST register number in the pair, or BAD if no pairs. OptoReg::Name RegMask::find_first_pair() const { verify_pairs(); for( int i = 0; i < RM_SIZE; i++ ) { if( _A[i] ) { // Found some bits int bit = _A[i] & -_A[i]; // Extract low bit // Convert to bit number, return hi bit in pair return OptoReg::Name((i<<_LogWordBits)+find_lowest_bit(bit)+1); } } return OptoReg::Bad; } //------------------------------ClearToPairs----------------------------------- // Clear out partial bits; leave only bit pairs void RegMask::clear_to_pairs() { for( int i = 0; i < RM_SIZE; i++ ) { int bits = _A[i]; bits &= ((bits & 0x55555555)<<1); // 1 hi-bit set for each pair bits |= (bits>>1); // Smear 1 hi-bit into a pair _A[i] = bits; } verify_pairs(); } //------------------------------SmearToPairs----------------------------------- // Smear out partial bits; leave only bit pairs void RegMask::smear_to_pairs() { for( int i = 0; i < RM_SIZE; i++ ) { int bits = _A[i]; bits |= ((bits & 0x55555555)<<1); // Smear lo bit hi per pair bits |= ((bits & 0xAAAAAAAA)>>1); // Smear hi bit lo per pair _A[i] = bits; } verify_pairs(); } //------------------------------is_aligned_pairs------------------------------- bool RegMask::is_aligned_pairs() const { // Assert that the register mask contains only bit pairs. for( int i = 0; i < RM_SIZE; i++ ) { int bits = _A[i]; while( bits ) { // Check bits for pairing int bit = bits & -bits; // Extract low bit // Low bit is not odd means its mis-aligned. if( (bit & 0x55555555) == 0 ) return false; bits -= bit; // Remove bit from mask // Check for aligned adjacent bit if( (bits & (bit<<1)) == 0 ) return false; bits -= (bit<<1); // Remove other halve of pair } } return true; } //------------------------------is_bound1-------------------------------------- // Return TRUE if the mask contains a single bit int RegMask::is_bound1() const { if( is_AllStack() ) return false; int bit = -1; // Set to hold the one bit allowed for( int i = 0; i < RM_SIZE; i++ ) { if( _A[i] ) { // Found some bits if( bit != -1 ) return false; // Already had bits, so fail bit = _A[i] & -_A[i]; // Extract 1 bit from mask if( bit != _A[i] ) return false; // Found many bits, so fail } } // True for both the empty mask and for a single bit return true; } //------------------------------is_bound2-------------------------------------- // Return TRUE if the mask contains an adjacent pair of bits and no other bits. int RegMask::is_bound_pair() const { if( is_AllStack() ) return false; int bit = -1; // Set to hold the one bit allowed for( int i = 0; i < RM_SIZE; i++ ) { if( _A[i] ) { // Found some bits if( bit != -1 ) return false; // Already had bits, so fail bit = _A[i] & -(_A[i]); // Extract 1 bit from mask if( (bit << 1) != 0 ) { // Bit pair stays in same word? if( (bit | (bit<<1)) != _A[i] ) return false; // Require adjacent bit pair and no more bits } else { // Else its a split-pair case if( bit != _A[i] ) return false; // Found many bits, so fail i++; // Skip iteration forward if( _A[i] != 1 ) return false; // Require 1 lo bit in next word } } } // True for both the empty mask and for a bit pair return true; } static int low_bits[3] = { 0x55555555, 0x11111111, 0x01010101 }; //------------------------------find_first_set--------------------------------- // Find the lowest-numbered register set in the mask. Return the // HIGHEST register number in the set, or BAD if no sets. // Works also for size 1. OptoReg::Name RegMask::find_first_set(int size) const { verify_sets(size); for (int i = 0; i < RM_SIZE; i++) { if (_A[i]) { // Found some bits int bit = _A[i] & -_A[i]; // Extract low bit // Convert to bit number, return hi bit in pair return OptoReg::Name((i<<_LogWordBits)+find_lowest_bit(bit)+(size-1)); } } return OptoReg::Bad; } //------------------------------clear_to_sets---------------------------------- // Clear out partial bits; leave only aligned adjacent bit pairs void RegMask::clear_to_sets(int size) { if (size == 1) return; assert(2 <= size && size <= 8, "update low bits table"); assert(is_power_of_2(size), "sanity"); int low_bits_mask = low_bits[size>>2]; for (int i = 0; i < RM_SIZE; i++) { int bits = _A[i]; int sets = (bits & low_bits_mask); for (int j = 1; j < size; j++) { sets = (bits & (sets<<1)); // filter bits which produce whole sets } sets |= (sets>>1); // Smear 1 hi-bit into a set if (size > 2) { sets |= (sets>>2); // Smear 2 hi-bits into a set if (size > 4) { sets |= (sets>>4); // Smear 4 hi-bits into a set } } _A[i] = sets; } verify_sets(size); } //------------------------------smear_to_sets---------------------------------- // Smear out partial bits to aligned adjacent bit sets void RegMask::smear_to_sets(int size) { if (size == 1) return; assert(2 <= size && size <= 8, "update low bits table"); assert(is_power_of_2(size), "sanity"); int low_bits_mask = low_bits[size>>2]; for (int i = 0; i < RM_SIZE; i++) { int bits = _A[i]; int sets = 0; for (int j = 0; j < size; j++) { sets |= (bits & low_bits_mask); // collect partial bits bits = bits>>1; } sets |= (sets<<1); // Smear 1 lo-bit into a set if (size > 2) { sets |= (sets<<2); // Smear 2 lo-bits into a set if (size > 4) { sets |= (sets<<4); // Smear 4 lo-bits into a set } } _A[i] = sets; } verify_sets(size); } //------------------------------is_aligned_set-------------------------------- bool RegMask::is_aligned_sets(int size) const { if (size == 1) return true; assert(2 <= size && size <= 8, "update low bits table"); assert(is_power_of_2(size), "sanity"); int low_bits_mask = low_bits[size>>2]; // Assert that the register mask contains only bit sets. for (int i = 0; i < RM_SIZE; i++) { int bits = _A[i]; while (bits) { // Check bits for pairing int bit = bits & -bits; // Extract low bit // Low bit is not odd means its mis-aligned. if ((bit & low_bits_mask) == 0) return false; // Do extra work since (bit << size) may overflow. int hi_bit = bit << (size-1); // high bit int set = hi_bit + ((hi_bit-1) & ~(bit-1)); // Check for aligned adjacent bits in this set if ((bits & set) != set) return false; bits -= set; // Remove this set } } return true; } //------------------------------is_bound_set----------------------------------- // Return TRUE if the mask contains one adjacent set of bits and no other bits. // Works also for size 1. int RegMask::is_bound_set(int size) const { if( is_AllStack() ) return false; assert(1 <= size && size <= 8, "update low bits table"); int bit = -1; // Set to hold the one bit allowed for (int i = 0; i < RM_SIZE; i++) { if (_A[i] ) { // Found some bits if (bit != -1) return false; // Already had bits, so fail bit = _A[i] & -_A[i]; // Extract 1 bit from mask int hi_bit = bit << (size-1); // high bit if (hi_bit != 0) { // Bit set stays in same word? int set = hi_bit + ((hi_bit-1) & ~(bit-1)); if (set != _A[i]) return false; // Require adjacent bit set and no more bits } else { // Else its a split-set case if (((-1) & ~(bit-1)) != _A[i]) return false; // Found many bits, so fail i++; // Skip iteration forward and check high part assert(size <= 8, "update next code"); // The lower 24 bits should be 0 since it is split case and size <= 8. int set = bit>>24; set = set & -set; // Remove sign extension. set = (((set << size) - 1) >> 8); if (_A[i] != set) return false; // Require 1 lo bit in next word } } } // True for both the empty mask and for a bit set return true; } //------------------------------is_UP------------------------------------------ // UP means register only, Register plus stack, or stack only is DOWN bool RegMask::is_UP() const { // Quick common case check for DOWN (any stack slot is legal) if( is_AllStack() ) return false; // Slower check for any stack bits set (also DOWN) if( overlap(Matcher::STACK_ONLY_mask) ) return false; // Not DOWN, so must be UP return true; } //------------------------------Size------------------------------------------- // Compute size of register mask in bits uint RegMask::Size() const { extern uint8 bitsInByte[256]; uint sum = 0; for( int i = 0; i < RM_SIZE; i++ ) sum += bitsInByte[(_A[i]>>24) & 0xff] + bitsInByte[(_A[i]>>16) & 0xff] + bitsInByte[(_A[i]>> 8) & 0xff] + bitsInByte[ _A[i] & 0xff]; return sum; } #ifndef PRODUCT //------------------------------print------------------------------------------ void RegMask::dump( ) const { tty->print("["); RegMask rm = *this; // Structure copy into local temp OptoReg::Name start = rm.find_first_elem(); // Get a register if( OptoReg::is_valid(start) ) { // Check for empty mask rm.Remove(start); // Yank from mask OptoReg::dump(start); // Print register OptoReg::Name last = start; // Now I have printed an initial register. // Print adjacent registers as "rX-rZ" instead of "rX,rY,rZ". // Begin looping over the remaining registers. while( 1 ) { // OptoReg::Name reg = rm.find_first_elem(); // Get a register if( !OptoReg::is_valid(reg) ) break; // Empty mask, end loop rm.Remove(reg); // Yank from mask if( last+1 == reg ) { // See if they are adjacent // Adjacent registers just collect into long runs, no printing. last = reg; } else { // Ending some kind of run if( start == last ) { // 1-register run; no special printing } else if( start+1 == last ) { tty->print(","); // 2-register run; print as "rX,rY" OptoReg::dump(last); } else { // Multi-register run; print as "rX-rZ" tty->print("-"); OptoReg::dump(last); } tty->print(","); // Seperate start of new run start = last = reg; // Start a new register run OptoReg::dump(start); // Print register } // End of if ending a register run or not } // End of while regmask not empty if( start == last ) { // 1-register run; no special printing } else if( start+1 == last ) { tty->print(","); // 2-register run; print as "rX,rY" OptoReg::dump(last); } else { // Multi-register run; print as "rX-rZ" tty->print("-"); OptoReg::dump(last); } if( rm.is_AllStack() ) tty->print("..."); } tty->print("]"); } #endif