/*
* Copyright (c) 2016, 2019, Oracle and/or its affiliates. All rights reserved.
* Copyright (c) 2016 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.
*
*/
// Major contributions by AHa, JL, LS
#ifndef CPU_S390_NATIVEINST_S390_HPP
#define CPU_S390_NATIVEINST_S390_HPP
#include "asm/macroAssembler.hpp"
#include "runtime/icache.hpp"
#include "runtime/os.hpp"
class NativeCall;
class NativeFarCall;
class NativeMovConstReg;
class NativeJump;
#ifndef COMPILER2
class NativeGeneralJump;
class NativeMovRegMem;
#endif
class NativeInstruction;
NativeCall* nativeCall_before(address return_address);
NativeCall* nativeCall_at(address instr);
NativeFarCall* nativeFarCall_before(address return_address);
NativeFarCall* nativeFarCall_at(address instr);
NativeMovConstReg* nativeMovConstReg_at(address address);
NativeMovConstReg* nativeMovConstReg_before(address address);
NativeJump* nativeJump_at(address address);
#ifndef COMPILER2
NativeMovRegMem* nativeMovRegMem_at (address address);
NativeGeneralJump* nativeGeneralJump_at(address address);
#endif
NativeInstruction* nativeInstruction_at(address address);
// We have interface for the following instructions:
// - NativeInstruction
// - NativeCall
// - NativeFarCall
// - NativeMovConstReg
// - NativeMovRegMem
// - NativeJump
// - NativeGeneralJump
// - NativeIllegalInstruction
// The base class for different kinds of native instruction abstractions.
// Provides the primitive operations to manipulate code relative to this.
//-------------------------------------
// N a t i v e I n s t r u c t i o n
//-------------------------------------
class NativeInstruction {
friend class Relocation;
public:
enum z_specific_constants {
nop_instruction_size = 2
};
bool is_illegal();
// Bcrl is currently the only accepted instruction here.
bool is_jump();
// We use an illtrap for marking a method as not_entrant or zombie.
bool is_sigill_zombie_not_entrant();
bool is_safepoint_poll() {
// Is the current instruction a POTENTIAL read access to the polling page?
// The instruction's current arguments are not checked!
return MacroAssembler::is_load_from_polling_page(addr_at(0));
}
address get_poll_address(void *ucontext) {
// Extract poll address from instruction and ucontext.
return MacroAssembler::get_poll_address(addr_at(0), ucontext);
}
uint get_poll_register() {
// Extract poll register from instruction.
return MacroAssembler::get_poll_register(addr_at(0));
}
public:
// The output of __ breakpoint_trap().
static int illegal_instruction();
// The address of the currently processed instruction.
address instruction_address() const { return addr_at(0); }
protected:
address addr_at(int offset) const { return address(this) + offset; }
// z/Architecture terminology
// halfword = 2 bytes
// word = 4 bytes
// doubleword = 8 bytes
unsigned short halfword_at(int offset) const { return *(unsigned short*)addr_at(offset); }
int word_at(int offset) const { return *(jint*)addr_at(offset); }
long long_at(int offset) const { return *(jlong*)addr_at(offset); }
void set_halfword_at(int offset, short i); // Deals with I-cache.
void set_word_at(int offset, int i); // Deals with I-cache.
void set_jlong_at(int offset, jlong i); // Deals with I-cache.
void set_addr_at(int offset, address x); // Deals with I-cache.
void print() const;
void print(const char* msg) const;
void dump() const;
void dump(const unsigned int range) const;
void dump(const unsigned int range, const char* msg) const;
public:
void verify();
// unit test stuff
static void test() {} // Override for testing.
friend NativeInstruction* nativeInstruction_at(address address) {
NativeInstruction* inst = (NativeInstruction*)address;
#ifdef ASSERT
inst->verify();
#endif
return inst;
}
};
//---------------------------------------------------
// N a t i v e I l l e g a l I n s t r u c t i o n
//---------------------------------------------------
class NativeIllegalInstruction: public NativeInstruction {
public:
enum z_specific_constants {
instruction_size = 2
};
// Insert illegal opcode at specific address.
static void insert(address code_pos);
};
//-----------------------
// N a t i v e C a l l
//-----------------------
// The NativeCall is an abstraction for accessing/manipulating call
// instructions. It is used to manipulate inline caches, primitive &
// dll calls, etc.
// A native call, as defined by this abstraction layer, consists of
// all instructions required to set up for and actually make the call.
//
// On z/Architecture, there exist three different forms of native calls:
// 1) Call with pc-relative address, 1 instruction
// The location of the target function is encoded as relative address
// in the call instruction. The short form (BRAS) allows for a
// 16-bit signed relative address (in 2-byte units). The long form
// (BRASL) allows for a 32-bit signed relative address (in 2-byte units).
// 2) Call with immediate address, 3 or 5 instructions.
// The location of the target function is given by an immediate
// constant which is loaded into a (scratch) register. Depending on
// the hardware capabilities, this takes 2 or 4 instructions.
// The call itself is then a "call by register"(BASR) instruction.
// 3) Call with address from constant pool, 2(3) instructions (with dynamic TOC)
// The location of the target function is stored in the constant pool
// during compilation. From there it is loaded into a (scratch) register.
// The call itself is then a "call by register"(BASR) instruction.
//
// When initially generating a call, the compiler uses form 2) (not
// patchable, target address constant, e.g. runtime calls) or 3) (patchable,
// target address might eventually get relocated). Later in the process,
// a call could be transformed into form 1) (also patchable) during ShortenBranches.
//
// If a call is/has to be patchable, the instruction sequence generated for it
// has to be constant in length. Excessive space, created e.g. by ShortenBranches,
// is allocated to lower addresses and filled with nops. That is necessary to
// keep the return address constant, no matter what form the call has.
// Methods dealing with such calls have "patchable" as part of their name.
class NativeCall: public NativeInstruction {
public:
static int get_IC_pos_in_java_to_interp_stub() {
return 0;
}
enum z_specific_constants {
instruction_size = 18, // Used in shared code for calls with reloc_info:
// value correct if !has_long_displacement_fast().
call_far_pcrelative_displacement_offset = 4, // Includes 2 bytes for the nop.
call_far_pcrelative_displacement_alignment = 4
};
// Maximum size (in bytes) of a call to an absolute address.
// Used when emitting call to deopt handler blob, which is a
// "load_const_call". The code pattern is:
// tmpReg := load_const(address); (* depends on CPU ArchLvl, but is otherwise constant *)
// call(tmpReg); (* basr, 2 bytes *)
static unsigned int max_instruction_size() {
return MacroAssembler::load_const_size() + MacroAssembler::call_byregister_size();
}
// address instruction_address() const { return addr_at(0); }
// For the ordering of the checks see note at nativeCall_before.
address next_instruction_address() const {
address iaddr = instruction_address();
if (MacroAssembler::is_load_const_call(iaddr)) {
// Form 2): load_const, BASR
return addr_at(MacroAssembler::load_const_call_size());
}
if (MacroAssembler::is_load_const_from_toc_call(iaddr)) {
// Form 3): load_const_from_toc (LARL+LG/LGRL), BASR.
return addr_at(MacroAssembler::load_const_from_toc_call_size());
}
if (MacroAssembler::is_call_far_pcrelative(iaddr)) {
// Form 1): NOP, BRASL
// The BRASL (Branch Relative And Save Long) is patched into the space created
// by the load_const_from_toc_call sequence (typically (LARL-LG)/LGRL - BASR.
// The BRASL must be positioned such that it's end is FW (4-byte) aligned (for atomic patching).
// It is achieved by aligning the end of the entire sequence on a 4byte boundary, by inserting
// a nop, if required, at the very beginning of the instruction sequence. The nop needs to
// be accounted for when calculating the next instruction address. The alignment takes place
// already when generating the original instruction sequence. The alignment requirement
// makes the size depend on location.
// The return address of the call must always be at the end of the instruction sequence.
// Inserting the extra alignment nop (or anything else) at the end is not an option.
// The patched-in brasl instruction is prepended with a nop to make it easier to
// distinguish from a load_const_from_toc_call sequence.
return addr_at(MacroAssembler::call_far_pcrelative_size());
}
((NativeCall*)iaddr)->print();
guarantee(false, "Not a NativeCall site");
return NULL;
}
address return_address() const {
return next_instruction_address();
}
address destination() const;
void set_destination_mt_safe(address dest);
void verify_alignment() {} // Yet another real do nothing guy :)
void verify();
// unit test stuff
static void test();
// Creation.
friend NativeCall* nativeCall_at(address instr) {
NativeCall* call;
// Make sure not to return garbage.
if (NativeCall::is_call_at(instr)) {
call = (NativeCall*)instr;
} else {
call = (NativeCall*)instr;
call->print();
guarantee(false, "Not a NativeCall site");
}
#ifdef ASSERT
call->verify();
#endif
return call;
}
// This is a very tricky function to implement. It involves stepping
// backwards in the instruction stream. On architectures with variable
// instruction length, this is a risky endeavor. From the return address,
// you do not know how far to step back to be at a location (your starting
// point) that will eventually bring you back to the return address.
// Furthermore, it may happen that there are multiple starting points.
//
// With only a few possible (allowed) code patterns, the risk is lower but
// does not diminish completely. Experience shows that there are code patterns
// which look like a load_const_from_toc_call @(return address-8), but in
// fact are a call_far_pcrelative @(return address-6). The other way around
// is possible as well, but was not knowingly observed so far.
//
// The unpredictability is caused by the pc-relative address field in both
// the call_far_pcrelative (BASR) and the load_const_from_toc (LGRL)
// instructions. This field can contain an arbitrary bit pattern.
//
// Here is a real-world example:
// Mnemonics: <not a valid sequence> LGRL r10,<addr> BASR r14,r10
// Hex code: eb01 9008 007a c498 ffff c4a8 c0e5 ffc1 0dea
// Mnemonics: AGSI <mem>,I8 LGRL r9,<addr> BRASL r14,<addr> correct
//
// If you first check for a load_const_from_toc_call @(-8), you will find
// a false positive. In this example, it is obviously false, because the
// preceding bytes do not form a valid instruction pattern. If you first
// check for call_far_pcrelative @(-6), you get a true positive - in this
// case.
//
// The following remedy has been implemented/enforced:
// 1) Everywhere, the permissible code patterns are checked in the same
// sequence: Form 2) - Form 3) - Form 1).
// 2) The call_far_pcrelative, which would ideally be just one BRASL
// instruction, is always prepended with a NOP. This measure avoids
// ambiguities with load_const_from_toc_call.
friend NativeCall* nativeCall_before(address return_address) {
NativeCall *call = NULL;
// Make sure not to return garbage
address instp = return_address - MacroAssembler::load_const_call_size();
if (MacroAssembler::is_load_const_call(instp)) { // Form 2)
call = (NativeCall*)(instp); // load_const + basr
} else {
instp = return_address - MacroAssembler::load_const_from_toc_call_size();
if (MacroAssembler::is_load_const_from_toc_call(instp)) { // Form 3)
call = (NativeCall*)(instp); // load_const_from_toc + basr
} else {
instp = return_address - MacroAssembler::call_far_pcrelative_size();
if (MacroAssembler::is_call_far_pcrelative(instp)) { // Form 1)
call = (NativeCall*)(instp); // brasl (or nop + brasl)
} else {
call = (NativeCall*)(instp);
call->print();
guarantee(false, "Not a NativeCall site");
}
}
}
#ifdef ASSERT
call->verify();
#endif
return call;
}
// Ordering of checks 2) 3) 1) is relevant!
static bool is_call_at(address a) {
// Check plain instruction sequence. Do not care about filler or alignment nops.
bool b = MacroAssembler::is_load_const_call(a) || // load_const + basr
MacroAssembler::is_load_const_from_toc_call(a) || // load_const_from_toc + basr
MacroAssembler::is_call_far_pcrelative(a); // nop + brasl
return b;
}
// Ordering of checks 2) 3) 1) is relevant!
static bool is_call_before(address a) {
// check plain instruction sequence. Do not care about filler or alignment nops.
bool b = MacroAssembler::is_load_const_call( a - MacroAssembler::load_const_call_size()) || // load_const + basr
MacroAssembler::is_load_const_from_toc_call(a - MacroAssembler::load_const_from_toc_call_size()) || // load_const_from_toc + basr
MacroAssembler::is_call_far_pcrelative( a - MacroAssembler::call_far_pcrelative_size()); // nop+brasl
return b;
}
static bool is_call_to(address instr, address target) {
// Check whether there is a `NativeCall' at the address `instr'
// calling to the address `target'.
return is_call_at(instr) && target == ((NativeCall *)instr)->destination();
}
bool is_pcrelative() {
return MacroAssembler::is_call_far_pcrelative((address)this);
}
};
//-----------------------------
// N a t i v e F a r C a l l
//-----------------------------
// The NativeFarCall is an abstraction for accessing/manipulating native
// call-anywhere instructions.
// Used to call native methods which may be loaded anywhere in the address
// space, possibly out of reach of a call instruction.
// Refer to NativeCall for a description of the supported call forms.
class NativeFarCall: public NativeInstruction {
public:
// We use MacroAssembler::call_far_patchable() for implementing a
// call-anywhere instruction.
static int instruction_size() { return MacroAssembler::call_far_patchable_size(); }
static int return_address_offset() { return MacroAssembler::call_far_patchable_ret_addr_offset(); }
// address instruction_address() const { return addr_at(0); }
address next_instruction_address() const {
return addr_at(instruction_size());
}
address return_address() const {
return addr_at(return_address_offset());
}
// Returns the NativeFarCall's destination.
address destination();
// Sets the NativeCall's destination, not necessarily mt-safe.
// Used when relocating code.
void set_destination(address dest, int toc_offset);
// Checks whether instr points at a NativeFarCall instruction.
static bool is_far_call_at(address instr) {
// Use compound inspection function which, in addition to instruction sequence,
// also checks for expected nops and for instruction alignment.
return MacroAssembler::is_call_far_patchable_at(instr);
}
// Does the NativeFarCall implementation use a pc-relative encoding
// of the call destination?
// Used when relocating code.
bool is_pcrelative() {
address iaddr = (address)this;
assert(is_far_call_at(iaddr), "unexpected call type");
return MacroAssembler::is_call_far_patchable_pcrelative_at(iaddr);
}
void verify();
// Unit tests
static void test();
// Instantiates a NativeFarCall object starting at the given instruction
// address and returns the NativeFarCall object.
inline friend NativeFarCall* nativeFarCall_at(address instr) {
NativeFarCall* call = (NativeFarCall*)instr;
#ifdef ASSERT
call->verify();
#endif
return call;
}
};
//-------------------------------------
// N a t i v e M o v C o n s t R e g
//-------------------------------------
// An interface for accessing/manipulating native set_oop imm, reg instructions.
// (Used to manipulate inlined data references, etc.)
// A native move of a constant into a register, as defined by this abstraction layer,
// deals with instruction sequences that load "quasi constant" oops into registers
// for addressing. For multiple causes, those "quasi constant" oops eventually need
// to be changed (i.e. patched). The reason is quite simple: objects might get moved
// around in storage. Pc-relative oop addresses have to be patched also if the
// reference location is moved. That happens when executable code is relocated.
class NativeMovConstReg: public NativeInstruction {
public:
enum z_specific_constants {
instruction_size = 10 // Used in shared code for calls with reloc_info.
};
// address instruction_address() const { return addr_at(0); }
// The current instruction might be located at an offset.
address next_instruction_address(int offset = 0) const;
// (The [set_]data accessor respects oop_type relocs also.)
intptr_t data() const;
// Patch data in code stream.
address set_data_plain(intptr_t x, CodeBlob *code);
// Patch data in code stream and oop pool if necessary.
void set_data(intptr_t x, relocInfo::relocType expected_type = relocInfo::none);
// Patch narrow oop constant in code stream.
void set_narrow_oop(intptr_t data);
void set_narrow_klass(intptr_t data);
void set_pcrel_addr(intptr_t addr, CompiledMethod *nm = NULL);
void set_pcrel_data(intptr_t data, CompiledMethod *nm = NULL);
void verify();
// unit test stuff
static void test();
// Creation.
friend NativeMovConstReg* nativeMovConstReg_at(address address) {
NativeMovConstReg* test = (NativeMovConstReg*)address;
#ifdef ASSERT
test->verify();
#endif
return test;
}
};
#ifdef COMPILER1
//---------------------------------
// N a t i v e M o v R e g M e m
//---------------------------------
// Interface to manipulate a code sequence that performs a memory access (load/store).
// The code is the patchable version of memory accesses generated by
// LIR_Assembler::reg2mem() and LIR_Assembler::mem2reg().
//
// Loading the offset for the mem access is target of the manipulation.
//
// The instruction sequence looks like this:
// iihf %r1,$bits1 ; load offset for mem access
// iilf %r1,$bits2
// [compress oop] ; optional, load only
// load/store %r2,0(%r1,%r2) ; memory access
class NativeMovRegMem;
inline NativeMovRegMem* nativeMovRegMem_at (address address);
class NativeMovRegMem: public NativeInstruction {
public:
enum z_specific_constants {
instruction_size = 12 // load_const used with access_field_id
};
int num_bytes_to_end_of_patch() const { return instruction_size; }
intptr_t offset() const {
return nativeMovConstReg_at(addr_at(0))->data();
}
void set_offset(intptr_t x) {
nativeMovConstReg_at(addr_at(0))->set_data(x);
}
void add_offset_in_bytes(intptr_t radd_offset) {
set_offset(offset() + radd_offset);
}
void verify();
private:
friend inline NativeMovRegMem* nativeMovRegMem_at(address address) {
NativeMovRegMem* test = (NativeMovRegMem*)address;
#ifdef ASSERT
test->verify();
#endif
return test;
}
};
#endif // COMPILER1
//-----------------------
// N a t i v e J u m p
//-----------------------
// An interface for accessing/manipulating native jumps
class NativeJump: public NativeInstruction {
public:
enum z_constants {
instruction_size = 2 // Size of z_illtrap().
};
// Maximum size (in bytes) of a jump to an absolute address.
// Used when emitting branch to an exception handler which is a "load_const_optimized_branch".
// Thus, a pessimistic estimate is obtained when using load_const.
// code pattern is:
// tmpReg := load_const(address); (* varying size *)
// jumpTo(tmpReg); (* bcr, 2 bytes *)
//
static unsigned int max_instruction_size() {
return MacroAssembler::load_const_size() + MacroAssembler::jump_byregister_size();
}
// address instruction_address() const { return addr_at(0); }
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