8227260: JNI upcalls should bypass class initialization barrier in c2i adapter
Reviewed-by: eosterlund, dholmes, mdoerr
/*
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#ifndef CPU_S390_MACROASSEMBLER_S390_INLINE_HPP
#define CPU_S390_MACROASSEMBLER_S390_INLINE_HPP
#include "asm/assembler.inline.hpp"
#include "asm/macroAssembler.hpp"
#include "asm/codeBuffer.hpp"
#include "code/codeCache.hpp"
#include "runtime/thread.hpp"
// Simplified shift operations for single register operands, constant shift amount.
inline void MacroAssembler::lshift(Register r, int places, bool is_DW) {
if (is_DW) {
z_sllg(r, r, places);
} else {
z_sll(r, places);
}
}
inline void MacroAssembler::rshift(Register r, int places, bool is_DW) {
if (is_DW) {
z_srlg(r, r, places);
} else {
z_srl(r, places);
}
}
// *((int8_t*)(dst)) |= imm8
inline void MacroAssembler::or2mem_8(Address& dst, int64_t imm8) {
if (Displacement::is_shortDisp(dst.disp())) {
z_oi(dst, imm8);
} else {
z_oiy(dst, imm8);
}
}
inline int MacroAssembler::store_const(const Address &dest, long imm, Register scratch, bool is_long) {
unsigned int lm = is_long ? 8 : 4;
unsigned int lc = is_long ? 8 : 4;
return store_const(dest, imm, lm, lc, scratch);
}
// Do not rely on add2reg* emitter.
// Depending on CmdLine switches and actual parameter values,
// the generated code may alter the condition code, which is counter-intuitive
// to the semantics of the "load address" (LA/LAY) instruction.
// Generic address loading d <- base(a) + index(a) + disp(a)
inline void MacroAssembler::load_address(Register d, const Address &a) {
if (Displacement::is_shortDisp(a.disp())) {
z_la(d, a.disp(), a.indexOrR0(), a.baseOrR0());
} else if (Displacement::is_validDisp(a.disp())) {
z_lay(d, a.disp(), a.indexOrR0(), a.baseOrR0());
} else {
guarantee(false, "displacement = " SIZE_FORMAT_HEX ", out of range for LA/LAY", a.disp());
}
}
inline void MacroAssembler::load_const(Register t, void* x) {
load_const(t, (long)x);
}
// Load a 64 bit constant encoded by a `Label'.
// Works for bound as well as unbound labels. For unbound labels, the
// code will become patched as soon as the label gets bound.
inline void MacroAssembler::load_const(Register t, Label& L) {
load_const(t, target(L));
}
inline void MacroAssembler::load_const(Register t, const AddressLiteral& a) {
assert(t != Z_R0, "R0 not allowed");
// First relocate (we don't change the offset in the RelocationHolder,
// just pass a.rspec()), then delegate to load_const(Register, long).
relocate(a.rspec());
load_const(t, (long)a.value());
}
inline void MacroAssembler::load_const_optimized(Register t, long x) {
(void) load_const_optimized_rtn_len(t, x, true);
}
inline void MacroAssembler::load_const_optimized(Register t, void* a) {
load_const_optimized(t, (long)a);
}
inline void MacroAssembler::load_const_optimized(Register t, Label& L) {
load_const_optimized(t, target(L));
}
inline void MacroAssembler::load_const_optimized(Register t, const AddressLiteral& a) {
assert(t != Z_R0, "R0 not allowed");
assert((relocInfo::relocType)a.rspec().reloc()->type() == relocInfo::none,
"cannot relocate optimized load_consts");
load_const_optimized(t, a.value());
}
inline void MacroAssembler::set_oop(jobject obj, Register d) {
load_const(d, allocate_oop_address(obj));
}
inline void MacroAssembler::set_oop_constant(jobject obj, Register d) {
load_const(d, constant_oop_address(obj));
}
// Adds MetaData constant md to TOC and loads it from there.
// md is added to the oop_recorder, but no relocation is added.
inline bool MacroAssembler::set_metadata_constant(Metadata* md, Register d) {
AddressLiteral a = constant_metadata_address(md);
return load_const_from_toc(d, a, d); // Discards the relocation.
}
inline bool MacroAssembler::is_call_pcrelative_short(unsigned long inst) {
return is_equal(inst, BRAS_ZOPC); // off 16, len 16
}
inline bool MacroAssembler::is_call_pcrelative_long(unsigned long inst) {
return is_equal(inst, BRASL_ZOPC); // off 16, len 32
}
inline bool MacroAssembler::is_branch_pcrelative_short(unsigned long inst) {
// Branch relative, 16-bit offset.
return is_equal(inst, BRC_ZOPC); // off 16, len 16
}
inline bool MacroAssembler::is_branch_pcrelative_long(unsigned long inst) {
// Branch relative, 32-bit offset.
return is_equal(inst, BRCL_ZOPC); // off 16, len 32
}
inline bool MacroAssembler::is_compareandbranch_pcrelative_short(unsigned long inst) {
// Compare and branch relative, 16-bit offset.
return is_equal(inst, CRJ_ZOPC, CMPBRANCH_MASK) || is_equal(inst, CGRJ_ZOPC, CMPBRANCH_MASK) ||
is_equal(inst, CIJ_ZOPC, CMPBRANCH_MASK) || is_equal(inst, CGIJ_ZOPC, CMPBRANCH_MASK) ||
is_equal(inst, CLRJ_ZOPC, CMPBRANCH_MASK) || is_equal(inst, CLGRJ_ZOPC, CMPBRANCH_MASK) ||
is_equal(inst, CLIJ_ZOPC, CMPBRANCH_MASK) || is_equal(inst, CLGIJ_ZOPC, CMPBRANCH_MASK);
}
inline bool MacroAssembler::is_branchoncount_pcrelative_short(unsigned long inst) {
// Branch relative on count, 16-bit offset.
return is_equal(inst, BRCT_ZOPC) || is_equal(inst, BRCTG_ZOPC); // off 16, len 16
}
inline bool MacroAssembler::is_branchonindex32_pcrelative_short(unsigned long inst) {
// Branch relative on index (32bit), 16-bit offset.
return is_equal(inst, BRXH_ZOPC) || is_equal(inst, BRXLE_ZOPC); // off 16, len 16
}
inline bool MacroAssembler::is_branchonindex64_pcrelative_short(unsigned long inst) {
// Branch relative on index (64bit), 16-bit offset.
return is_equal(inst, BRXHG_ZOPC) || is_equal(inst, BRXLG_ZOPC); // off 16, len 16
}
inline bool MacroAssembler::is_branchonindex_pcrelative_short(unsigned long inst) {
return is_branchonindex32_pcrelative_short(inst) ||
is_branchonindex64_pcrelative_short(inst);
}
inline bool MacroAssembler::is_branch_pcrelative16(unsigned long inst) {
return is_branch_pcrelative_short(inst) ||
is_compareandbranch_pcrelative_short(inst) ||
is_branchoncount_pcrelative_short(inst) ||
is_branchonindex_pcrelative_short(inst);
}
inline bool MacroAssembler::is_branch_pcrelative32(unsigned long inst) {
return is_branch_pcrelative_long(inst);
}
inline bool MacroAssembler::is_branch_pcrelative(unsigned long inst) {
return is_branch_pcrelative16(inst) ||
is_branch_pcrelative32(inst);
}
inline bool MacroAssembler::is_load_pcrelative_long(unsigned long inst) {
// Load relative, 32-bit offset.
return is_equal(inst, LRL_ZOPC, REL_LONG_MASK) || is_equal(inst, LGRL_ZOPC, REL_LONG_MASK); // off 16, len 32
}
inline bool MacroAssembler::is_misc_pcrelative_long(unsigned long inst) {
// Load address, execute relative, 32-bit offset.
return is_equal(inst, LARL_ZOPC, REL_LONG_MASK) || is_equal(inst, EXRL_ZOPC, REL_LONG_MASK); // off 16, len 32
}
inline bool MacroAssembler::is_pcrelative_short(unsigned long inst) {
return is_branch_pcrelative16(inst) ||
is_call_pcrelative_short(inst);
}
inline bool MacroAssembler::is_pcrelative_long(unsigned long inst) {
return is_branch_pcrelative32(inst) ||
is_call_pcrelative_long(inst) ||
is_load_pcrelative_long(inst) ||
is_misc_pcrelative_long(inst);
}
inline bool MacroAssembler::is_load_pcrelative_long(address iLoc) {
unsigned long inst;
unsigned int len = get_instruction(iLoc, &inst);
return (len == 6) && is_load_pcrelative_long(inst);
}
inline bool MacroAssembler::is_pcrelative_short(address iLoc) {
unsigned long inst;
unsigned int len = get_instruction(iLoc, &inst);
return ((len == 4) || (len == 6)) && is_pcrelative_short(inst);
}
inline bool MacroAssembler::is_pcrelative_long(address iLoc) {
unsigned long inst;
unsigned int len = get_instruction(iLoc, &inst);
return (len == 6) && is_pcrelative_long(inst);
}
// Dynamic TOC. Test for any pc-relative instruction.
inline bool MacroAssembler::is_pcrelative_instruction(address iloc) {
unsigned long inst;
get_instruction(iloc, &inst);
return is_pcrelative_short(inst) ||
is_pcrelative_long(inst);
}
inline bool MacroAssembler::is_load_addr_pcrel(address a) {
return is_equal(a, LARL_ZOPC, LARL_MASK);
}
// Save the return pc in the register that should be stored as the return pc
// in the current frame (default is R14).
inline void MacroAssembler::save_return_pc(Register pc) {
z_stg(pc, _z_abi16(return_pc), Z_SP);
}
inline void MacroAssembler::restore_return_pc() {
z_lg(Z_R14, _z_abi16(return_pc), Z_SP);
}
// Call a function with given entry.
inline address MacroAssembler::call(Register function_entry) {
assert(function_entry != Z_R0, "function_entry cannot be Z_R0");
Assembler::z_basr(Z_R14, function_entry);
_last_calls_return_pc = pc();
return _last_calls_return_pc;
}
// Call a C function via a function entry.
inline address MacroAssembler::call_c(Register function_entry) {
return call(function_entry);
}
// Call a stub function via a function descriptor, but don't save TOC before
// call, don't setup TOC and ENV for call, and don't restore TOC after call
inline address MacroAssembler::call_stub(Register function_entry) {
return call_c(function_entry);
}
inline address MacroAssembler::call_stub(address function_entry) {
return call_c(function_entry);
}
// Get the pc where the last emitted call will return to.
inline address MacroAssembler::last_calls_return_pc() {
return _last_calls_return_pc;
}
inline void MacroAssembler::set_last_Java_frame(Register last_Java_sp, Register last_Java_pc) {
set_last_Java_frame(last_Java_sp, last_Java_pc, true);
}
inline void MacroAssembler::set_last_Java_frame_static(Register last_Java_sp, Register last_Java_pc) {
set_last_Java_frame(last_Java_sp, last_Java_pc, false);
}
inline void MacroAssembler::reset_last_Java_frame(void) {
reset_last_Java_frame(true);
}
inline void MacroAssembler::reset_last_Java_frame_static(void) {
reset_last_Java_frame(false);
}
inline void MacroAssembler::set_top_ijava_frame_at_SP_as_last_Java_frame(Register sp, Register tmp1) {
set_top_ijava_frame_at_SP_as_last_Java_frame(sp, tmp1, true);
}
inline void MacroAssembler::set_top_ijava_frame_at_SP_as_last_Java_frame_static(Register sp, Register tmp1) {
set_top_ijava_frame_at_SP_as_last_Java_frame(sp, tmp1, true);
}
#endif // CPU_S390_MACROASSEMBLER_S390_INLINE_HPP