8214451: PPC64/s390: Clean up unused CRC32 prototype and function
Reviewed-by: mdoerr, lucy
/*
* Copyright (c) 2016, 2018, Oracle and/or its affiliates. All rights reserved.
* Copyright (c) 2016, 2018, SAP SE. 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.
*
*/
#ifndef CPU_S390_VM_MACROASSEMBLER_S390_HPP
#define CPU_S390_VM_MACROASSEMBLER_S390_HPP
#include "asm/assembler.hpp"
#include "oops/accessDecorators.hpp"
#define MODERN_IFUN(name) ((void (MacroAssembler::*)(Register, int64_t, Register, Register))&MacroAssembler::name)
#define CLASSIC_IFUN(name) ((void (MacroAssembler::*)(Register, int64_t, Register, Register))&MacroAssembler::name)
#define MODERN_FFUN(name) ((void (MacroAssembler::*)(FloatRegister, int64_t, Register, Register))&MacroAssembler::name)
#define CLASSIC_FFUN(name) ((void (MacroAssembler::*)(FloatRegister, int64_t, Register, Register))&MacroAssembler::name)
class MacroAssembler: public Assembler {
public:
MacroAssembler(CodeBuffer* code) : Assembler(code) {}
//
// Optimized instruction emitters
//
// Move register if destination register and target register are different.
void lr_if_needed(Register rd, Register rs);
void lgr_if_needed(Register rd, Register rs);
void llgfr_if_needed(Register rd, Register rs);
void ldr_if_needed(FloatRegister rd, FloatRegister rs);
void move_reg_if_needed(Register dest, BasicType dest_type, Register src, BasicType src_type);
void move_freg_if_needed(FloatRegister dest, BasicType dest_type, FloatRegister src, BasicType src_type);
void freg2mem_opt(FloatRegister reg,
int64_t disp,
Register index,
Register base,
void (MacroAssembler::*modern) (FloatRegister, int64_t, Register, Register),
void (MacroAssembler::*classic)(FloatRegister, int64_t, Register, Register),
Register scratch = Z_R0);
void freg2mem_opt(FloatRegister reg,
const Address &a, bool is_double = true);
void mem2freg_opt(FloatRegister reg,
int64_t disp,
Register index,
Register base,
void (MacroAssembler::*modern) (FloatRegister, int64_t, Register, Register),
void (MacroAssembler::*classic)(FloatRegister, int64_t, Register, Register),
Register scratch = Z_R0);
void mem2freg_opt(FloatRegister reg,
const Address &a, bool is_double = true);
void reg2mem_opt(Register reg,
int64_t disp,
Register index,
Register base,
void (MacroAssembler::*modern) (Register, int64_t, Register, Register),
void (MacroAssembler::*classic)(Register, int64_t, Register, Register),
Register scratch = Z_R0);
// returns offset of the store instruction
int reg2mem_opt(Register reg, const Address &a, bool is_double = true);
void mem2reg_opt(Register reg,
int64_t disp,
Register index,
Register base,
void (MacroAssembler::*modern) (Register, int64_t, Register, Register),
void (MacroAssembler::*classic)(Register, int64_t, Register, Register));
void mem2reg_opt(Register reg, const Address &a, bool is_double = true);
void mem2reg_signed_opt(Register reg, const Address &a);
// AND immediate and set condition code, works for 64 bit immediates/operation as well.
void and_imm(Register r, long mask, Register tmp = Z_R0, bool wide = false);
// 1's complement, 32bit or 64bit. Optimized to exploit distinct operands facility.
// Note: The condition code is neither preserved nor correctly set by this code!!!
// Note: (wide == false) does not protect the high order half of the target register
// from alternation. It only serves as optimization hint for 32-bit results.
void not_(Register r1, Register r2 = noreg, bool wide = false); // r1 = ~r2
// Expanded support of all "rotate_then_<logicalOP>" instructions.
//
// Generalize and centralize rotate_then_<logicalOP> emitter.
// Functional description. For details, see Principles of Operation, Chapter 7, "Rotate Then Insert..."
// - Bits in a register are numbered left (most significant) to right (least significant), i.e. [0..63].
// - Bytes in a register are numbered left (most significant) to right (least significant), i.e. [0..7].
// - Register src is rotated to the left by (nRotate&0x3f) positions.
// - Negative values for nRotate result in a rotation to the right by abs(nRotate) positions.
// - The bits in positions [lBitPos..rBitPos] of the _ROTATED_ src operand take part in the
// logical operation performed on the contents (in those positions) of the dst operand.
// - The logical operation that is performed on the dst operand is one of
// o insert the selected bits (replacing the original contents of those bit positions)
// o and the selected bits with the corresponding bits of the dst operand
// o or the selected bits with the corresponding bits of the dst operand
// o xor the selected bits with the corresponding bits of the dst operand
// - For clear_dst == true, the destination register is cleared before the bits are inserted.
// For clear_dst == false, only the bit positions that get data inserted from src
// are changed. All other bit positions remain unchanged.
// - For test_only == true, the result of the logicalOP is only used to set the condition code, dst remains unchanged.
// For test_only == false, the result of the logicalOP replaces the selected bits of dst.
// - src32bit and dst32bit indicate the respective register is used as 32bit value only.
// Knowledge can simplify code generation.
//
// Here is an important performance note, valid for all <logicalOP>s except "insert":
// Due to the too complex nature of the operation, it cannot be done in a single cycle.
// Timing constraints require the instructions to be cracked into two micro-ops, taking
// one or two cycles each to execute. In some cases, an additional pipeline bubble might get added.
// Macroscopically, that makes up for a three- or four-cycle instruction where you would
// expect just a single cycle.
// It is thus not beneficial from a performance point of view to exploit those instructions.
// Other reasons (code compactness, register pressure, ...) might outweigh this penalty.
//
unsigned long create_mask(int lBitPos, int rBitPos);
void rotate_then_mask(Register dst, Register src, int lBitPos, int rBitPos,
int nRotate, bool src32bit, bool dst32bit, bool oneBits);
void rotate_then_insert(Register dst, Register src, int lBitPos, int rBitPos, int nRotate,
bool clear_dst);
void rotate_then_and(Register dst, Register src, int lBitPos, int rBitPos, int nRotate,
bool test_only);
void rotate_then_or(Register dst, Register src, int lBitPos, int rBitPos, int nRotate,
bool test_onlyt);
void rotate_then_xor(Register dst, Register src, int lBitPos, int rBitPos, int nRotate,
bool test_only);
void add64(Register r1, RegisterOrConstant inc);
// Helper function to multiply the 64bit contents of a register by a 16bit constant.
// The optimization tries to avoid the mghi instruction, since it uses the FPU for
// calculation and is thus rather slow.
//
// There is no handling for special cases, e.g. cval==0 or cval==1.
//
// Returns len of generated code block.
unsigned int mul_reg64_const16(Register rval, Register work, int cval);
// Generic operation r1 := r2 + imm.
void add2reg(Register r1, int64_t imm, Register r2 = noreg);
// Generic operation r := b + x + d.
void add2reg_with_index(Register r, int64_t d, Register x, Register b = noreg);
// Add2mem* methods for direct memory increment.
void add2mem_32(const Address &a, int64_t imm, Register tmp);
void add2mem_64(const Address &a, int64_t imm, Register tmp);
// *((int8_t*)(dst)) |= imm8
inline void or2mem_8(Address& dst, int64_t imm8);
// Load values by size and signedness.
void load_sized_value(Register dst, Address src, size_t size_in_bytes, bool is_signed);
void store_sized_value(Register src, Address dst, size_t size_in_bytes);
// Load values with large offsets to base address.
private:
int split_largeoffset(int64_t si20_offset, Register tmp, bool fixed_codelen, bool accumulate);
public:
void load_long_largeoffset(Register t, int64_t si20, Register a, Register tmp);
void load_float_largeoffset(FloatRegister t, int64_t si20, Register a, Register tmp);
void load_double_largeoffset(FloatRegister t, int64_t si20, Register a, Register tmp);
private:
long toc_distance();
public:
void load_toc(Register Rtoc);
void load_long_pcrelative(Register Rdst, address dataLocation);
static int load_long_pcrelative_size() { return 6; }
void load_addr_pcrelative(Register Rdst, address dataLocation);
static int load_addr_pcrel_size() { return 6; } // Just a LARL.
// Load a value from memory and test (set CC).
void load_and_test_byte (Register dst, const Address &a);
void load_and_test_short (Register dst, const Address &a);
void load_and_test_int (Register dst, const Address &a);
void load_and_test_int2long(Register dst, const Address &a);
void load_and_test_long (Register dst, const Address &a);
// Test a bit in memory. Result is reflected in CC.
void testbit(const Address &a, unsigned int bit);
// Test a bit in a register. Result is reflected in CC.
void testbit(Register r, unsigned int bitPos);
void prefetch_read(Address a);
void prefetch_update(Address a);
// Clear a register, i.e. load const zero into reg. Return len (in bytes) of
// generated instruction(s).
// whole_reg: Clear 64 bits if true, 32 bits otherwise.
// set_cc: Use instruction that sets the condition code, if true.
int clear_reg(Register r, bool whole_reg = true, bool set_cc = true);
#ifdef ASSERT
int preset_reg(Register r, unsigned long pattern, int pattern_len);
#endif
// Clear (store zeros) a small piece of memory.
// CAUTION: Do not use this for atomic memory clearing. Use store_const() instead.
// addr: Address descriptor of memory to clear.
// Index register will not be used!
// size: Number of bytes to clear.
void clear_mem(const Address& addr, unsigned size);
// Move immediate values to memory. Currently supports 32 and 64 bit stores,
// but may be extended to 16 bit store operation, if needed.
// For details, see implementation in *.cpp file.
int store_const(const Address &dest, long imm,
unsigned int lm, unsigned int lc,
Register scratch = Z_R0);
inline int store_const(const Address &dest, long imm,
Register scratch = Z_R0, bool is_long = true);
// Move/initialize arbitrarily large memory area. No check for destructive overlap.
// Being interruptible, these instructions need a retry-loop.
void move_long_ext(Register dst, Register src, unsigned int pad);
void compare_long_ext(Register left, Register right, unsigned int pad);
void compare_long_uni(Register left, Register right, unsigned int pad);
void search_string(Register end, Register start);
void search_string_uni(Register end, Register start);
// Translate instructions
// Being interruptible, these instructions need a retry-loop.
void translate_oo(Register dst, Register src, uint mask);
void translate_ot(Register dst, Register src, uint mask);
void translate_to(Register dst, Register src, uint mask);
void translate_tt(Register dst, Register src, uint mask);
// Crypto instructions.
// Being interruptible, these instructions need a retry-loop.
void cksm(Register crcBuff, Register srcBuff);
void km( Register dstBuff, Register srcBuff);
void kmc(Register dstBuff, Register srcBuff);
void kimd(Register srcBuff);
void klmd(Register srcBuff);
void kmac(Register srcBuff);
// nop padding
void align(int modulus);
void align_address(int modulus);
//
// Constants, loading constants, TOC support
//
// Load generic address: d <- base(a) + index(a) + disp(a).
inline void load_address(Register d, const Address &a);
// Load absolute address (and try to optimize).
void load_absolute_address(Register d, address addr);
// Address of Z_ARG1 and argument_offset.
// If temp_reg == arg_slot, arg_slot will be overwritten.
Address argument_address(RegisterOrConstant arg_slot,
Register temp_reg = noreg,
int64_t extra_slot_offset = 0);
// Load a narrow ptr constant (oop or klass ptr).
void load_narrow_oop( Register t, narrowOop a);
void load_narrow_klass(Register t, Klass* k);
static bool is_load_const_32to64(address pos);
static bool is_load_narrow_oop(address pos) { return is_load_const_32to64(pos); }
static bool is_load_narrow_klass(address pos) { return is_load_const_32to64(pos); }
static int load_const_32to64_size() { return 6; }
static bool load_narrow_oop_size() { return load_const_32to64_size(); }
static bool load_narrow_klass_size() { return load_const_32to64_size(); }
static int patch_load_const_32to64(address pos, int64_t a);
static int patch_load_narrow_oop(address pos, oop o);
static int patch_load_narrow_klass(address pos, Klass* k);
// cOops. CLFI exploit.
void compare_immediate_narrow_oop(Register oop1, narrowOop oop2);
void compare_immediate_narrow_klass(Register op1, Klass* op2);
static bool is_compare_immediate32(address pos);
static bool is_compare_immediate_narrow_oop(address pos);
static bool is_compare_immediate_narrow_klass(address pos);
static int compare_immediate_narrow_size() { return 6; }
static int compare_immediate_narrow_oop_size() { return compare_immediate_narrow_size(); }
static int compare_immediate_narrow_klass_size() { return compare_immediate_narrow_size(); }
static int patch_compare_immediate_32(address pos, int64_t a);
static int patch_compare_immediate_narrow_oop(address pos, oop o);
static int patch_compare_immediate_narrow_klass(address pos, Klass* k);
// Load a 32bit constant into a 64bit register.
void load_const_32to64(Register t, int64_t x, bool sign_extend=true);
// Load a 64 bit constant.
void load_const(Register t, long a);
inline void load_const(Register t, void* a);
inline void load_const(Register t, Label& L);
inline void load_const(Register t, const AddressLiteral& a);
// Get the 64 bit constant from a `load_const' sequence.
static long get_const(address load_const);
// Patch the 64 bit constant of a `load_const' sequence. This is a low level
// procedure. It neither flushes the instruction cache nor is it atomic.
static void patch_const(address load_const, long x);
static int load_const_size() { return 12; }
// Turn a char into boolean. NOTE: destroys r.
void c2bool(Register r, Register t = Z_R0);
// Optimized version of load_const for constants that do not need to be
// loaded by a sequence of instructions of fixed length and that do not
// need to be patched.
int load_const_optimized_rtn_len(Register t, long x, bool emit);
inline void load_const_optimized(Register t, long x);
inline void load_const_optimized(Register t, void* a);
inline void load_const_optimized(Register t, Label& L);
inline void load_const_optimized(Register t, const AddressLiteral& a);
public:
//----------------------------------------------------------
// oops in code -------------
// including compressed oops support -------------
//----------------------------------------------------------
// Metadata in code that we have to keep track of.
AddressLiteral allocate_metadata_address(Metadata* obj); // allocate_index
AddressLiteral constant_metadata_address(Metadata* obj); // find_index
// allocate_index
AddressLiteral allocate_oop_address(jobject obj);
// find_index
AddressLiteral constant_oop_address(jobject obj);
// Uses allocate_oop_address.
inline void set_oop (jobject obj, Register d);
// Uses constant_oop_address.
inline void set_oop_constant(jobject obj, Register d);
// Uses constant_metadata_address.
inline bool set_metadata_constant(Metadata* md, Register d);
virtual RegisterOrConstant delayed_value_impl(intptr_t* delayed_value_addr,
Register tmp,
int offset);
//
// branch, jump
//
// Use one generic function for all branch patches.
static unsigned long patched_branch(address dest_pos, unsigned long inst, address inst_pos);
void pd_patch_instruction(address branch, address target, const char* file, int line);
// Extract relative address from "relative" instructions.
static long get_pcrel_offset(unsigned long inst);
static long get_pcrel_offset(address pc);
static address get_target_addr_pcrel(address pc);
static inline bool is_call_pcrelative_short(unsigned long inst);
static inline bool is_call_pcrelative_long(unsigned long inst);
static inline bool is_branch_pcrelative_short(unsigned long inst);
static inline bool is_branch_pcrelative_long(unsigned long inst);
static inline bool is_compareandbranch_pcrelative_short(unsigned long inst);
static inline bool is_branchoncount_pcrelative_short(unsigned long inst);
static inline bool is_branchonindex32_pcrelative_short(unsigned long inst);
static inline bool is_branchonindex64_pcrelative_short(unsigned long inst);
static inline bool is_branchonindex_pcrelative_short(unsigned long inst);
static inline bool is_branch_pcrelative16(unsigned long inst);
static inline bool is_branch_pcrelative32(unsigned long inst);
static inline bool is_branch_pcrelative(unsigned long inst);
static inline bool is_load_pcrelative_long(unsigned long inst);
static inline bool is_misc_pcrelative_long(unsigned long inst);
static inline bool is_pcrelative_short(unsigned long inst);
static inline bool is_pcrelative_long(unsigned long inst);
// PCrelative TOC access. Variants with address argument.
static inline bool is_load_pcrelative_long(address iLoc);
static inline bool is_pcrelative_short(address iLoc);
static inline bool is_pcrelative_long(address iLoc);
static inline bool is_pcrelative_instruction(address iloc);
static inline bool is_load_addr_pcrel(address a);
static void patch_target_addr_pcrel(address pc, address con);
static void patch_addr_pcrel(address pc, address con) {
patch_target_addr_pcrel(pc, con); // Just delegate. This is only for nativeInst_s390.cpp.
}
//---------------------------------------------------------
// Some macros for more comfortable assembler programming.
//---------------------------------------------------------
// NOTE: pass NearLabel T to signal that the branch target T will be bound to a near address.
void compare32_and_branch(Register r1, RegisterOrConstant x2, branch_condition cond, Label& target);
void compareU32_and_branch(Register r1, RegisterOrConstant x2, branch_condition cond, Label& target);
void compare64_and_branch(Register r1, RegisterOrConstant x2, branch_condition cond, Label& target);
void compareU64_and_branch(Register r1, RegisterOrConstant x2, branch_condition cond, Label& target);
void branch_optimized(Assembler::branch_condition cond, address branch_target);
void branch_optimized(Assembler::branch_condition cond, Label& branch_target);
void compare_and_branch_optimized(Register r1,
Register r2,
Assembler::branch_condition cond,
address branch_addr,
bool len64,
bool has_sign);
void compare_and_branch_optimized(Register r1,
jlong x2,
Assembler::branch_condition cond,
Label& branch_target,
bool len64,
bool has_sign);
void compare_and_branch_optimized(Register r1,
Register r2,
Assembler::branch_condition cond,
Label& branch_target,
bool len64,
bool has_sign);
//
// Support for frame handling
//
// Specify the register that should be stored as the return pc in the
// current frame (default is R14).
inline void save_return_pc(Register pc = Z_R14);
inline void restore_return_pc();
// Get current PC.
address get_PC(Register result);
// Get current PC + offset. Offset given in bytes, must be even!
address get_PC(Register result, int64_t offset);
// Get size of instruction at pc (which must point to valid code).
void instr_size(Register size, Register pc);
// Accessing, and in particular modifying, a stack location is only safe if
// the stack pointer (Z_SP) is set such that the accessed stack location is
// in the reserved range.
//
// From a performance point of view, it is desirable not to change the SP
// first and then immediately use it to access the freshly reserved space.
// That opens a small gap, though. If, just after storing some value (the
// frame pointer) into the to-be-reserved space, an interrupt is caught,
// the handler might use the space beyond Z_SP for it's own purpose.
// If that happens, the stored value might get altered.
// Resize current frame either relatively wrt to current SP or absolute.
void resize_frame_sub(Register offset, Register fp, bool load_fp=true);
void resize_frame_abs_with_offset(Register newSP, Register fp, int offset, bool load_fp);
void resize_frame_absolute(Register addr, Register fp, bool load_fp);
void resize_frame(RegisterOrConstant offset, Register fp, bool load_fp=true);
// Push a frame of size bytes, if copy_sp is false, old_sp must already
// contain a copy of Z_SP.
void push_frame(Register bytes, Register old_sp, bool copy_sp = true, bool bytes_with_inverted_sign = false);
// Push a frame of size `bytes'. no abi space provided.
// Don't rely on register locking, instead pass a scratch register
// (Z_R0 by default).
// CAUTION! passing registers >= Z_R2 may produce bad results on
// old CPUs!
unsigned int push_frame(unsigned int bytes, Register scratch = Z_R0);
// Push a frame of size `bytes' with abi160 on top.
unsigned int push_frame_abi160(unsigned int bytes);
// Pop current C frame.
void pop_frame();
// Pop current C frame and restore return PC register (Z_R14).
void pop_frame_restore_retPC(int frame_size_in_bytes);
//
// Calls
//
private:
address _last_calls_return_pc;
public:
// Support for VM calls. This is the base routine called by the
// different versions of call_VM_leaf. The interpreter may customize
// this version by overriding it for its purposes (e.g., to
// save/restore additional registers when doing a VM call).
void call_VM_leaf_base(address entry_point);
void call_VM_leaf_base(address entry_point, bool allow_relocation);
// It is imperative that all calls into the VM are handled via the
// call_VM macros. They make sure that the stack linkage is setup
// correctly. Call_VM's correspond to ENTRY/ENTRY_X entry points
// while call_VM_leaf's correspond to LEAF entry points.
//
// This is the base routine called by the different versions of
// call_VM. The interpreter may customize this version by overriding
// it for its purposes (e.g., to save/restore additional registers
// when doing a VM call).
// If no last_java_sp is specified (noreg) then SP will be used instead.
virtual void call_VM_base(
Register oop_result, // Where an oop-result ends up if any; use noreg otherwise.
Register last_java_sp, // To set up last_Java_frame in stubs; use noreg otherwise.
address entry_point, // The entry point.
bool check_exception); // Flag which indicates if exception should be checked.
virtual void call_VM_base(
Register oop_result, // Where an oop-result ends up if any; use noreg otherwise.
Register last_java_sp, // To set up last_Java_frame in stubs; use noreg otherwise.
address entry_point, // The entry point.
bool allow_relocation, // Flag to request generation of relocatable code.
bool check_exception); // Flag which indicates if exception should be checked.
// Call into the VM.
// Passes the thread pointer (in Z_ARG1) as a prepended argument.
// Makes sure oop return values are visible to the GC.
void call_VM(Register oop_result, address entry_point, bool check_exceptions = true);
void call_VM(Register oop_result, address entry_point, Register arg_1, bool check_exceptions = true);
void call_VM(Register oop_result, address entry_point, Register arg_1, Register arg_2, bool check_exceptions = true);
void call_VM(Register oop_result, address entry_point, Register arg_1, Register arg_2,
Register arg_3, bool check_exceptions = true);
void call_VM_static(Register oop_result, address entry_point, bool check_exceptions = true);
void call_VM_static(Register oop_result, address entry_point, Register arg_1, Register arg_2,
Register arg_3, bool check_exceptions = true);
// Overloaded with last_java_sp.
void call_VM(Register oop_result, Register last_java_sp, address entry_point, bool check_exceptions = true);
void call_VM(Register oop_result, Register last_java_sp, address entry_point,
Register arg_1, bool check_exceptions = true);
void call_VM(Register oop_result, Register last_java_sp, address entry_point,
Register arg_1, Register arg_2, bool check_exceptions = true);
void call_VM(Register oop_result, Register last_java_sp, address entry_point,
Register arg_1, Register arg_2, Register arg_3, bool check_exceptions = true);
void call_VM_leaf(address entry_point);
void call_VM_leaf(address entry_point, Register arg_1);
void call_VM_leaf(address entry_point, Register arg_1, Register arg_2);
void call_VM_leaf(address entry_point, Register arg_1, Register arg_2, Register arg_3);
// Really static VM leaf call (never patched).
void call_VM_leaf_static(address entry_point);
void call_VM_leaf_static(address entry_point, Register arg_1);
void call_VM_leaf_static(address entry_point, Register arg_1, Register arg_2);
void call_VM_leaf_static(address entry_point, Register arg_1, Register arg_2, Register arg_3);
// Call a C function via its function entry. Updates and returns _last_calls_return_pc.
inline address call(Register function_entry);
inline address call_c(Register function_entry);
address call_c(address function_entry);
// Variant for really static (non-relocatable) calls which are never patched.
address call_c_static(address function_entry);
// TOC or pc-relative call + emits a runtime_call relocation.
address call_c_opt(address function_entry);
inline address call_stub(Register function_entry);
inline address call_stub(address function_entry);
// Get the pc where the last call will return to. Returns _last_calls_return_pc.
inline address last_calls_return_pc();
private:
static bool is_call_far_patchable_variant0_at(address instruction_addr); // Dynamic TOC: load target addr from CP and call.
static bool is_call_far_patchable_variant2_at(address instruction_addr); // PC-relative call, prefixed with NOPs.
public:
bool call_far_patchable(address target, int64_t toc_offset);
static bool is_call_far_patchable_at(address inst_start); // All supported forms of patchable calls.
static bool is_call_far_patchable_pcrelative_at(address inst_start); // Pc-relative call with leading nops.
static bool is_call_far_pcrelative(address instruction_addr); // Pure far pc-relative call, with one leading size adjustment nop.
static void set_dest_of_call_far_patchable_at(address inst_start, address target, int64_t toc_offset);
static address get_dest_of_call_far_patchable_at(address inst_start, address toc_start);
void align_call_far_patchable(address pc);
// PCrelative TOC access.
// This value is independent of code position - constant for the lifetime of the VM.
static int call_far_patchable_size() {
return load_const_from_toc_size() + call_byregister_size();
}
static int call_far_patchable_ret_addr_offset() { return call_far_patchable_size(); }
static bool call_far_patchable_requires_alignment_nop(address pc) {
int size = call_far_patchable_size();
return ((intptr_t)(pc + size) & 0x03L) != 0;
}
// END OF PCrelative TOC access.
static int jump_byregister_size() { return 2; }
static int jump_pcrelative_size() { return 4; }
static int jump_far_pcrelative_size() { return 6; }
static int call_byregister_size() { return 2; }
static int call_pcrelative_size() { return 4; }
static int call_far_pcrelative_size() { return 2 + 6; } // Prepend each BRASL with a nop.
static int call_far_pcrelative_size_raw() { return 6; } // Prepend each BRASL with a nop.
//
// Java utilities
//
// These routines should emit JVMTI PopFrame and ForceEarlyReturn handling code.
// The implementation is only non-empty for the InterpreterMacroAssembler,
// as only the interpreter handles PopFrame and ForceEarlyReturn requests.
virtual void check_and_handle_popframe(Register java_thread);
virtual void check_and_handle_earlyret(Register java_thread);
// Polling page support.
enum poll_mask {
mask_stackbang = 0xde, // 222 (dec)
mask_safepoint = 0x6f, // 111 (dec)
mask_profiling = 0xba // 186 (dec)
};
// Read from the polling page.
void load_from_polling_page(Register polling_page_address, int64_t offset = 0);
// Check if given instruction is a read from the polling page
// as emitted by load_from_polling_page.
static bool is_load_from_polling_page(address instr_loc);
// Extract poll address from instruction and ucontext.
static address get_poll_address(address instr_loc, void* ucontext);
// Extract poll register from instruction.
static uint get_poll_register(address instr_loc);
// Check if safepoint requested and if so branch
void safepoint_poll(Label& slow_path, Register temp_reg);
// Stack overflow checking
void bang_stack_with_offset(int offset);
// Check for reserved stack access in method being exited. If the reserved
// stack area was accessed, protect it again and throw StackOverflowError.
// Uses Z_R1.
void reserved_stack_check(Register return_pc);
// Atomics
// -- none?
void tlab_allocate(Register obj, // Result: pointer to object after successful allocation
Register var_size_in_bytes, // Object size in bytes if unknown at compile time; invalid otherwise.
int con_size_in_bytes, // Object size in bytes if known at compile time.
Register t1, // temp register
Label& slow_case); // Continuation point if fast allocation fails.
// Emitter for interface method lookup.
// input: recv_klass, intf_klass, itable_index
// output: method_result
// kills: itable_index, temp1_reg, Z_R0, Z_R1
void lookup_interface_method(Register recv_klass,
Register intf_klass,
RegisterOrConstant itable_index,
Register method_result,
Register temp1_reg,
Label& no_such_interface,
bool return_method = true);
// virtual method calling
void lookup_virtual_method(Register recv_klass,
RegisterOrConstant vtable_index,
Register method_result);
// Factor out code to call ic_miss_handler.
unsigned int call_ic_miss_handler(Label& ICM, int trapMarker, int requiredSize, Register scratch);
void nmethod_UEP(Label& ic_miss);
// Emitters for "partial subtype" checks.
// Test sub_klass against super_klass, with fast and slow paths.
// The fast path produces a tri-state answer: yes / no / maybe-slow.
// One of the three labels can be NULL, meaning take the fall-through.
// If super_check_offset is -1, the value is loaded up from super_klass.
// No registers are killed, except temp_reg and temp2_reg.
// If super_check_offset is not -1, temp1_reg is not used and can be noreg.
void check_klass_subtype_fast_path(Register sub_klass,
Register super_klass,
Register temp1_reg,
Label* L_success,
Label* L_failure,
Label* L_slow_path,
RegisterOrConstant super_check_offset = RegisterOrConstant(-1));
// The rest of the type check; must be wired to a corresponding fast path.
// It does not repeat the fast path logic, so don't use it standalone.
// The temp_reg can be noreg, if no temps are available.
// It can also be sub_klass or super_klass, meaning it's OK to kill that one.
// Updates the sub's secondary super cache as necessary.
void check_klass_subtype_slow_path(Register Rsubklass,
Register Rsuperklas,
Register Rarray_ptr, // tmp
Register Rlength, // tmp
Label* L_success,
Label* L_failure);
// Simplified, combined version, good for typical uses.
// Falls through on failure.
void check_klass_subtype(Register sub_klass,
Register super_klass,
Register temp1_reg,
Register temp2_reg,
Label& L_success);
// Increment a counter at counter_address when the eq condition code is set.
// Kills registers tmp1_reg and tmp2_reg and preserves the condition code.
void increment_counter_eq(address counter_address, Register tmp1_reg, Register tmp2_reg);
// Biased locking support
// Upon entry,obj_reg must contain the target object, and mark_reg
// must contain the target object's header.
// Destroys mark_reg if an attempt is made to bias an anonymously
// biased lock. In this case a failure will go either to the slow
// case or fall through with the notEqual condition code set with
// the expectation that the slow case in the runtime will be called.
// In the fall-through case where the CAS-based lock is done,
// mark_reg is not destroyed.
void biased_locking_enter(Register obj_reg, Register mark_reg, Register temp_reg,
Register temp2_reg, Label& done, Label* slow_case = NULL);
// Upon entry, the base register of mark_addr must contain the oop.
// Destroys temp_reg.
// If allow_delay_slot_filling is set to true, the next instruction
// emitted after this one will go in an annulled delay slot if the
// biased locking exit case failed.
void biased_locking_exit(Register mark_addr, Register temp_reg, Label& done);
void compiler_fast_lock_object(Register oop, Register box, Register temp1, Register temp2, bool try_bias = UseBiasedLocking);
void compiler_fast_unlock_object(Register oop, Register box, Register temp1, Register temp2, bool try_bias = UseBiasedLocking);
void resolve_jobject(Register value, Register tmp1, Register tmp2);
// Support for last Java frame (but use call_VM instead where possible).
private:
void set_last_Java_frame(Register last_Java_sp, Register last_Java_pc, bool allow_relocation);
void reset_last_Java_frame(bool allow_relocation);
void set_top_ijava_frame_at_SP_as_last_Java_frame(Register sp, Register tmp1, bool allow_relocation);
public:
inline void set_last_Java_frame(Register last_java_sp, Register last_Java_pc);
inline void set_last_Java_frame_static(Register last_java_sp, Register last_Java_pc);
inline void reset_last_Java_frame(void);
inline void reset_last_Java_frame_static(void);
inline void set_top_ijava_frame_at_SP_as_last_Java_frame(Register sp, Register tmp1);
inline void set_top_ijava_frame_at_SP_as_last_Java_frame_static(Register sp, Register tmp1);
void set_thread_state(JavaThreadState new_state);
// Read vm result from thread.
void get_vm_result (Register oop_result);
void get_vm_result_2(Register result);
// Vm result is currently getting hijacked to for oop preservation.
void set_vm_result(Register oop_result);
// Support for NULL-checks
//
// Generates code that causes a NULL OS exception if the content of reg is NULL.
// If the accessed location is M[reg + offset] and the offset is known, provide the
// offset. No explicit code generation is needed if the offset is within a certain
// range (0 <= offset <= page_size).
//
// %%%%%% Currently not done for z/Architecture
void null_check(Register reg, Register tmp = Z_R0, int64_t offset = -1);
static bool needs_explicit_null_check(intptr_t offset); // Implemented in shared file ?!
static bool uses_implicit_null_check(void* address);
// Klass oop manipulations if compressed.
void encode_klass_not_null(Register dst, Register src = noreg);
void decode_klass_not_null(Register dst, Register src);
void decode_klass_not_null(Register dst);
void load_klass(Register klass, Address mem);
void load_klass(Register klass, Register src_oop);
void load_prototype_header(Register Rheader, Register Rsrc_oop);
void store_klass(Register klass, Register dst_oop, Register ck = noreg); // Klass will get compressed if ck not provided.
void store_klass_gap(Register s, Register dst_oop);
// This function calculates the size of the code generated by
// decode_klass_not_null(register dst)
// when (Universe::heap() != NULL). Hence, if the instructions
// it generates change, then this method needs to be updated.
static int instr_size_for_decode_klass_not_null();
void encode_heap_oop(Register oop);
void encode_heap_oop_not_null(Register oop);
static int get_oop_base_pow2_offset(uint64_t oop_base);
int get_oop_base(Register Rbase, uint64_t oop_base);
int get_oop_base_complement(Register Rbase, uint64_t oop_base);
void compare_heap_oop(Register Rop1, Address mem, bool maybeNULL);
void compare_klass_ptr(Register Rop1, int64_t disp, Register Rbase, bool maybeNULL);
// Access heap oop, handle encoding and GC barriers.
private:
void access_store_at(BasicType type, DecoratorSet decorators,
const Address& addr, Register val,
Register tmp1, Register tmp2, Register tmp3);
void access_load_at(BasicType type, DecoratorSet decorators,
const Address& addr, Register dst,
Register tmp1, Register tmp2, Label *is_null = NULL);
public:
// tmp1 and tmp2 are used with decorators ON_PHANTOM_OOP_REF or ON_WEAK_OOP_REF.
void load_heap_oop(Register dest, const Address &a,
Register tmp1, Register tmp2,
DecoratorSet decorators = 0, Label *is_null = NULL);
void store_heap_oop(Register Roop, const Address &a,
Register tmp1, Register tmp2, Register tmp3,
DecoratorSet decorators = 0);
void oop_encoder(Register Rdst, Register Rsrc, bool maybeNULL,
Register Rbase = Z_R1, int pow2_offset = -1, bool only32bitValid = false);
void oop_decoder(Register Rdst, Register Rsrc, bool maybeNULL,
Register Rbase = Z_R1, int pow2_offset = -1);
void resolve_oop_handle(Register result);
void load_mirror(Register mirror, Register method);
//--------------------------
//--- Operations on arrays.
//--------------------------
unsigned int Clear_Array(Register cnt_arg, Register base_pointer_arg, Register src_addr, Register src_len);
unsigned int Clear_Array_Const(long cnt, Register base);
unsigned int Clear_Array_Const_Big(long cnt, Register base_pointer_arg, Register src_addr, Register src_len);
unsigned int CopyRawMemory_AlignedDisjoint(Register src_reg, Register dst_reg,
Register cnt_reg,
Register tmp1_reg, Register tmp2_reg);
//-------------------------------------------
// Special String Intrinsics Implementation.
//-------------------------------------------
// Intrinsics for CompactStrings
// Restores: src, dst
// Uses: cnt
// Kills: tmp, Z_R0, Z_R1.
// Early clobber: result.
// Boolean precise controls accuracy of result value.
unsigned int string_compress(Register result, Register src, Register dst, Register cnt,
Register tmp, bool precise);
// Inflate byte[] to char[].
unsigned int string_inflate_trot(Register src, Register dst, Register cnt, Register tmp);
// Inflate byte[] to char[].
// Restores: src, dst
// Uses: cnt
// Kills: tmp, Z_R0, Z_R1.
unsigned int string_inflate(Register src, Register dst, Register cnt, Register tmp);
// Inflate byte[] to char[], length known at compile time.
// Restores: src, dst
// Kills: tmp, Z_R0, Z_R1.
// Note:
// len is signed int. Counts # characters, not bytes.
unsigned int string_inflate_const(Register src, Register dst, Register tmp, int len);
// Kills src.
unsigned int has_negatives(Register result, Register src, Register cnt,
Register odd_reg, Register even_reg, Register tmp);
unsigned int string_compare(Register str1, Register str2, Register cnt1, Register cnt2,
Register odd_reg, Register even_reg, Register result, int ae);
unsigned int array_equals(bool is_array_equ, Register ary1, Register ary2, Register limit,
Register odd_reg, Register even_reg, Register result, bool is_byte);
unsigned int string_indexof(Register result, Register haystack, Register haycnt,
Register needle, Register needlecnt, int needlecntval,
Register odd_reg, Register even_reg, int ae);
unsigned int string_indexof_char(Register result, Register haystack, Register haycnt,
Register needle, jchar needleChar, Register odd_reg, Register even_reg, bool is_byte);
// Emit an oop const to the constant pool and set a relocation info
// with address current_pc. Return the TOC offset of the constant.
int store_const_in_toc(AddressLiteral& val);
int store_oop_in_toc(AddressLiteral& oop);
// Emit an oop const to the constant pool via store_oop_in_toc, or
// emit a scalar const to the constant pool via store_const_in_toc,
// and load the constant into register dst.
bool load_const_from_toc(Register dst, AddressLiteral& a, Register Rtoc = noreg);
// Get CPU version dependent size of load_const sequence.
// The returned value is valid only for code sequences
// generated by load_const, not load_const_optimized.
static int load_const_from_toc_size() {
return load_long_pcrelative_size();
}
bool load_oop_from_toc(Register dst, AddressLiteral& a, Register Rtoc = noreg);
static intptr_t get_const_from_toc(address pc);
static void set_const_in_toc(address pc, unsigned long new_data, CodeBlob *cb);
// Dynamic TOC.
static bool is_load_const(address a);
static bool is_load_const_from_toc_pcrelative(address a);
static bool is_load_const_from_toc(address a) { return is_load_const_from_toc_pcrelative(a); }
// PCrelative TOC access.
static bool is_call_byregister(address a) { return is_z_basr(*(short*)a); }
static bool is_load_const_from_toc_call(address a);
static bool is_load_const_call(address a);
static int load_const_call_size() { return load_const_size() + call_byregister_size(); }
static int load_const_from_toc_call_size() { return load_const_from_toc_size() + call_byregister_size(); }
// Offset is +/- 2**32 -> use long.
static long get_load_const_from_toc_offset(address a);
void generate_type_profiling(const Register Rdata,
const Register Rreceiver_klass,
const Register Rwanted_receiver_klass,
const Register Rmatching_row,
bool is_virtual_call);
// Bit operations for single register operands.
inline void lshift(Register r, int places, bool doubl = true); // <<
inline void rshift(Register r, int places, bool doubl = true); // >>
//
// Debugging
//
// Assert on CC (condition code in CPU state).
void asm_assert(bool check_equal, const char* msg, int id) PRODUCT_RETURN;
void asm_assert_low(const char *msg, int id) PRODUCT_RETURN;
void asm_assert_high(const char *msg, int id) PRODUCT_RETURN;
void asm_assert_eq(const char* msg, int id) { asm_assert(true, msg, id); }
void asm_assert_ne(const char* msg, int id) { asm_assert(false, msg, id); }
void asm_assert_static(bool check_equal, const char* msg, int id) PRODUCT_RETURN;
private:
// Emit assertions.
void asm_assert_mems_zero(bool check_equal, bool allow_relocation, int size, int64_t mem_offset,
Register mem_base, const char* msg, int id) PRODUCT_RETURN;
public:
inline void asm_assert_mem4_is_zero(int64_t mem_offset, Register mem_base, const char* msg, int id) {
asm_assert_mems_zero(true, true, 4, mem_offset, mem_base, msg, id);
}
inline void asm_assert_mem8_is_zero(int64_t mem_offset, Register mem_base, const char* msg, int id) {
asm_assert_mems_zero(true, true, 8, mem_offset, mem_base, msg, id);
}
inline void asm_assert_mem4_isnot_zero(int64_t mem_offset, Register mem_base, const char* msg, int id) {
asm_assert_mems_zero(false, true, 4, mem_offset, mem_base, msg, id);
}
inline void asm_assert_mem8_isnot_zero(int64_t mem_offset, Register mem_base, const char* msg, int id) {
asm_assert_mems_zero(false, true, 8, mem_offset, mem_base, msg, id);
}
inline void asm_assert_mem4_is_zero_static(int64_t mem_offset, Register mem_base, const char* msg, int id) {
asm_assert_mems_zero(true, false, 4, mem_offset, mem_base, msg, id);
}
inline void asm_assert_mem8_is_zero_static(int64_t mem_offset, Register mem_base, const char* msg, int id) {
asm_assert_mems_zero(true, false, 8, mem_offset, mem_base, msg, id);
}
inline void asm_assert_mem4_isnot_zero_static(int64_t mem_offset, Register mem_base, const char* msg, int id) {
asm_assert_mems_zero(false, false, 4, mem_offset, mem_base, msg, id);
}
inline void asm_assert_mem8_isnot_zero_static(int64_t mem_offset, Register mem_base, const char* msg, int id) {
asm_assert_mems_zero(false, false, 8, mem_offset, mem_base, msg, id);
}
void asm_assert_frame_size(Register expected_size, Register tmp, const char* msg, int id) PRODUCT_RETURN;
// Verify Z_thread contents.
void verify_thread();
// Only if +VerifyOops.
void verify_oop(Register reg, const char* s = "broken oop");
// TODO: verify_method and klass metadata (compare against vptr?).
void _verify_method_ptr(Register reg, const char * msg, const char * file, int line) {}
void _verify_klass_ptr(Register reg, const char * msg, const char * file, int line) {}
#define verify_method_ptr(reg) _verify_method_ptr(reg, "broken method " #reg, __FILE__, __LINE__)
#define verify_klass_ptr(reg) _verify_klass_ptr(reg, "broken klass " #reg, __FILE__, __LINE__)
private:
// Generate printout in stop().
static const char* stop_types[];
enum {
stop_stop = 0,
stop_untested = 1,
stop_unimplemented = 2,
stop_shouldnotreachhere = 3,
stop_end = 4
};
// Prints msg and stops execution.
void stop(int type, const char* msg, int id = 0);
address stop_chain(address reentry, int type, const char* msg, int id, bool allow_relocation); // Non-relocateable code only!!
void stop_static(int type, const char* msg, int id); // Non-relocateable code only!!
public:
// Prints msg and stops.
address stop_chain( address reentry, const char* msg = "", int id = 0) { return stop_chain(reentry, stop_stop, msg, id, true); }
address stop_chain_static(address reentry, const char* msg = "", int id = 0) { return stop_chain(reentry, stop_stop, msg, id, false); }
void stop_static (const char* msg = "", int id = 0) { stop_static(stop_stop, msg, id); }
void stop (const char* msg = "", int id = 0) { stop(stop_stop, msg, id); }
void untested (const char* msg = "", int id = 0) { stop(stop_untested, msg, id); }
void unimplemented(const char* msg = "", int id = 0) { stop(stop_unimplemented, msg, id); }
void should_not_reach_here(const char* msg = "", int id = -1) { stop(stop_shouldnotreachhere, msg, id); }
// Factor out part of stop into subroutine to save space.
void stop_subroutine();
// Prints msg, but don't stop.
void warn(const char* msg);
//-----------------------------
//--- basic block tracing code
//-----------------------------
void trace_basic_block(uint i);
void init_basic_block_trace();
// Number of bytes a basic block gets larger due to the tracing code macro (worst case).
// Currently, worst case is 48 bytes. 64 puts us securely on the safe side.
static int basic_blck_trace_blk_size_incr() { return 64; }
// Write pattern 0x0101010101010101 in region [low-before, high+after].
// Low and high may be the same registers. Before and after are
// the numbers of 8-byte words.
void zap_from_to(Register low, Register high, Register tmp1 = Z_R0, Register tmp2 = Z_R1,
int before = 0, int after = 0) PRODUCT_RETURN;
// Emitters for CRC32 calculation.
// A note on invertCRC:
// Unfortunately, internal representation of crc differs between CRC32 and CRC32C.
// CRC32 holds it's current crc value in the externally visible representation.
// CRC32C holds it's current crc value in internal format, ready for updating.
// Thus, the crc value must be bit-flipped before updating it in the CRC32 case.
// In the CRC32C case, it must be bit-flipped when it is given to the outside world (getValue()).
// The bool invertCRC parameter indicates whether bit-flipping is required before updates.
private:
void fold_byte_crc32(Register crc, Register table, Register val, Register tmp);
void fold_8bit_crc32(Register crc, Register table, Register tmp);
void update_byte_crc32( Register crc, Register val, Register table);
void update_byteLoop_crc32(Register crc, Register buf, Register len, Register table,
Register data);
void update_1word_crc32(Register crc, Register buf, Register table, int bufDisp, int bufInc,
Register t0, Register t1, Register t2, Register t3);
public:
void kernel_crc32_singleByteReg(Register crc, Register val, Register table,
bool invertCRC);
void kernel_crc32_singleByte(Register crc, Register buf, Register len, Register table, Register tmp,
bool invertCRC);
void kernel_crc32_1byte(Register crc, Register buf, Register len, Register table,
Register t0, Register t1, Register t2, Register t3,
bool invertCRC);
void kernel_crc32_1word(Register crc, Register buf, Register len, Register table,
Register t0, Register t1, Register t2, Register t3,
bool invertCRC);
// Emitters for BigInteger.multiplyToLen intrinsic
// note: length of result array (zlen) is passed on the stack
private:
void add2_with_carry(Register dest_hi, Register dest_lo,
Register src1, Register src2);
void multiply_64_x_64_loop(Register x, Register xstart,
Register x_xstart,
Register y, Register y_idx, Register z,
Register carry, Register product,
Register idx, Register kdx);
void multiply_add_128_x_128(Register x_xstart, Register y, Register z,
Register yz_idx, Register idx,
Register carry, Register product, int offset);
void multiply_128_x_128_loop(Register x_xstart,
Register y, Register z,
Register yz_idx, Register idx,
Register jdx,
Register carry, Register product,
Register carry2);
public:
void multiply_to_len(Register x, Register xlen,
Register y, Register ylen,
Register z,
Register tmp1, Register tmp2,
Register tmp3, Register tmp4, Register tmp5);
};
/**
* class SkipIfEqual:
*
* Instantiating this class will result in assembly code being output that will
* jump around any code emitted between the creation of the instance and it's
* automatic destruction at the end of a scope block, depending on the value of
* the flag passed to the constructor, which will be checked at run-time.
*/
class SkipIfEqual {
private:
MacroAssembler* _masm;
Label _label;
public:
SkipIfEqual(MacroAssembler*, const bool* flag_addr, bool value, Register _rscratch);
~SkipIfEqual();
};
#ifdef ASSERT
// Return false (e.g. important for our impl. of virtual calls).
inline bool AbstractAssembler::pd_check_instruction_mark() { return false; }
#endif
#endif // CPU_S390_VM_MACROASSEMBLER_S390_HPP