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/*
* Copyright (c) 1997, 2024, 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
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#ifndef SHARE_ASM_CODEBUFFER_HPP
#define SHARE_ASM_CODEBUFFER_HPP
#include "code/oopRecorder.hpp"
#include "code/relocInfo.hpp"
#include "compiler/compiler_globals.hpp"
#include "utilities/align.hpp"
#include "utilities/debug.hpp"
#include "utilities/growableArray.hpp"
#include "utilities/linkedlist.hpp"
#include "utilities/resizeableResourceHash.hpp"
#include "utilities/macros.hpp"
template <typename T>
static inline void put_native(address p, T x) {
memcpy((void*)p, &x, sizeof x);
}
class PhaseCFG;
class Compile;
class BufferBlob;
class CodeBuffer;
class Label;
class ciMethod;
class SharedStubToInterpRequest;
class CodeOffsets: public StackObj {
public:
enum Entries { Entry,
Verified_Entry,
Frame_Complete, // Offset in the code where the frame setup is (for forte stackwalks) is complete
OSR_Entry,
Exceptions, // Offset where exception handler lives
Deopt, // Offset where deopt handler lives
DeoptMH, // Offset where MethodHandle deopt handler lives
UnwindHandler, // Offset to default unwind handler
max_Entries };
// special value to note codeBlobs where profile (forte) stack walking is
// always dangerous and suspect.
enum { frame_never_safe = -1 };
private:
int _values[max_Entries];
public:
CodeOffsets() {
_values[Entry ] = 0;
_values[Verified_Entry] = 0;
_values[Frame_Complete] = frame_never_safe;
_values[OSR_Entry ] = 0;
_values[Exceptions ] = -1;
_values[Deopt ] = -1;
_values[DeoptMH ] = -1;
_values[UnwindHandler ] = -1;
}
int value(Entries e) { return _values[e]; }
void set_value(Entries e, int val) { _values[e] = val; }
};
// This class represents a stream of code and associated relocations.
// There are a few in each CodeBuffer.
// They are filled concurrently, and concatenated at the end.
class CodeSection {
friend class CodeBuffer;
public:
typedef int csize_t; // code size type; would be size_t except for history
private:
address _start; // first byte of contents (instructions)
address _mark; // user mark, usually an instruction beginning
address _end; // current end address
address _limit; // last possible (allocated) end address
relocInfo* _locs_start; // first byte of relocation information
relocInfo* _locs_end; // first byte after relocation information
relocInfo* _locs_limit; // first byte after relocation information buf
address _locs_point; // last relocated position (grows upward)
bool _locs_own; // did I allocate the locs myself?
bool _scratch_emit; // Buffer is used for scratch emit, don't relocate.
int _skipped_instructions_size;
char _index; // my section number (SECT_INST, etc.)
CodeBuffer* _outer; // enclosing CodeBuffer
// (Note: _locs_point used to be called _last_reloc_offset.)
CodeSection() {
_start = nullptr;
_mark = nullptr;
_end = nullptr;
_limit = nullptr;
_locs_start = nullptr;
_locs_end = nullptr;
_locs_limit = nullptr;
_locs_point = nullptr;
_locs_own = false;
_scratch_emit = false;
_skipped_instructions_size = 0;
debug_only(_index = (char)-1);
debug_only(_outer = (CodeBuffer*)badAddress);
}
void initialize_outer(CodeBuffer* outer, int index) {
_outer = outer;
_index = index;
}
void initialize(address start, csize_t size = 0) {
assert(_start == nullptr, "only one init step, please");
_start = start;
_mark = nullptr;
_end = start;
_limit = start + size;
_locs_point = start;
}
void initialize_locs(int locs_capacity);
void expand_locs(int new_capacity);
void initialize_locs_from(const CodeSection* source_cs);
// helper for CodeBuffer::expand()
void take_over_code_from(CodeSection* cs) {
_start = cs->_start;
_mark = cs->_mark;
_end = cs->_end;
_limit = cs->_limit;
_locs_point = cs->_locs_point;
_skipped_instructions_size = cs->_skipped_instructions_size;
}
public:
address start() const { return _start; }
address mark() const { return _mark; }
address end() const { return _end; }
address limit() const { return _limit; }
csize_t size() const { return (csize_t)(_end - _start); }
csize_t mark_off() const { assert(_mark != nullptr, "not an offset");
return (csize_t)(_mark - _start); }
csize_t capacity() const { return (csize_t)(_limit - _start); }
csize_t remaining() const { return (csize_t)(_limit - _end); }
relocInfo* locs_start() const { return _locs_start; }
relocInfo* locs_end() const { return _locs_end; }
int locs_count() const { return (int)(_locs_end - _locs_start); }
relocInfo* locs_limit() const { return _locs_limit; }
address locs_point() const { return _locs_point; }
csize_t locs_point_off() const{ return (csize_t)(_locs_point - _start); }
csize_t locs_capacity() const { return (csize_t)(_locs_limit - _locs_start); }
int index() const { return _index; }
bool is_allocated() const { return _start != nullptr; }
bool is_empty() const { return _start == _end; }
bool has_locs() const { return _locs_end != nullptr; }
// Mark scratch buffer.
void set_scratch_emit() { _scratch_emit = true; }
void clear_scratch_emit() { _scratch_emit = false; }
bool scratch_emit() { return _scratch_emit; }
CodeBuffer* outer() const { return _outer; }
// is a given address in this section? (2nd version is end-inclusive)
bool contains(address pc) const { return pc >= _start && pc < _end; }
bool contains2(address pc) const { return pc >= _start && pc <= _end; }
bool allocates(address pc) const { return pc >= _start && pc < _limit; }
bool allocates2(address pc) const { return pc >= _start && pc <= _limit; }
// checks if two CodeSections are disjoint
//
// limit is an exclusive address and can be the start of another
// section.
bool disjoint(CodeSection* cs) const { return cs->_limit <= _start || cs->_start >= _limit; }
void set_end(address pc) { assert(allocates2(pc), "not in CodeBuffer memory: " INTPTR_FORMAT " <= " INTPTR_FORMAT " <= " INTPTR_FORMAT, p2i(_start), p2i(pc), p2i(_limit)); _end = pc; }
void set_mark(address pc) { assert(contains2(pc), "not in codeBuffer");
_mark = pc; }
void set_mark() { _mark = _end; }
void clear_mark() { _mark = nullptr; }
void set_locs_end(relocInfo* p) {
assert(p <= locs_limit(), "locs data fits in allocated buffer");
_locs_end = p;
}
void set_locs_point(address pc) {
assert(pc >= locs_point(), "relocation addr may not decrease");
assert(allocates2(pc), "relocation addr " INTPTR_FORMAT " must be in this section from " INTPTR_FORMAT " to " INTPTR_FORMAT, p2i(pc), p2i(_start), p2i(_limit));
_locs_point = pc;
}
void register_skipped(int size) {
_skipped_instructions_size += size;
}
// Code emission
void emit_int8(uint8_t x1) {
address curr = end();
*((uint8_t*) curr++) = x1;
set_end(curr);
}
template <typename T>
void emit_native(T x) { put_native(end(), x); set_end(end() + sizeof x); }
void emit_int16(uint16_t x) { emit_native(x); }
void emit_int16(uint8_t x1, uint8_t x2) {
address curr = end();
*((uint8_t*) curr++) = x1;
*((uint8_t*) curr++) = x2;
set_end(curr);
}
void emit_int24(uint8_t x1, uint8_t x2, uint8_t x3) {
address curr = end();
*((uint8_t*) curr++) = x1;
*((uint8_t*) curr++) = x2;
*((uint8_t*) curr++) = x3;
set_end(curr);
}
void emit_int32(uint32_t x) { emit_native(x); }
void emit_int32(uint8_t x1, uint8_t x2, uint8_t x3, uint8_t x4) {
address curr = end();
*((uint8_t*) curr++) = x1;
*((uint8_t*) curr++) = x2;
*((uint8_t*) curr++) = x3;
*((uint8_t*) curr++) = x4;
set_end(curr);
}
void emit_int64(uint64_t x) { emit_native(x); }
void emit_float(jfloat x) { emit_native(x); }
void emit_double(jdouble x) { emit_native(x); }
void emit_address(address x) { emit_native(x); }
// Share a scratch buffer for relocinfo. (Hacky; saves a resource allocation.)
void initialize_shared_locs(relocInfo* buf, int length);
// Manage labels and their addresses.
address target(Label& L, address branch_pc);
// Emit a relocation.
void relocate(address at, RelocationHolder const& rspec, int format = 0);
void relocate(address at, relocInfo::relocType rtype, int format = 0, jint method_index = 0);
int alignment() const;
// Slop between sections, used only when allocating temporary BufferBlob buffers.
static csize_t end_slop() { return MAX2((int)sizeof(jdouble), (int)CodeEntryAlignment); }
csize_t align_at_start(csize_t off) const {
return (csize_t) align_up(off, alignment());
}
// Ensure there's enough space left in the current section.
// Return true if there was an expansion.
bool maybe_expand_to_ensure_remaining(csize_t amount);
#ifndef PRODUCT
void decode();
void print(const char* name);
#endif //PRODUCT
};
#ifndef PRODUCT
class AsmRemarkCollection;
class DbgStringCollection;
// The assumption made here is that most code remarks (or comments) added to
// the generated assembly code are unique, i.e. there is very little gain in
// trying to share the strings between the different offsets tracked in a
// buffer (or blob).
class AsmRemarks {
public:
AsmRemarks();
~AsmRemarks();
const char* insert(uint offset, const char* remstr);
bool is_empty() const;
void share(const AsmRemarks &src);
void clear();
uint print(uint offset, outputStream* strm = tty) const;
// For testing purposes only.
const AsmRemarkCollection* ref() const { return _remarks; }
private:
AsmRemarkCollection* _remarks;
};
// The assumption made here is that the number of debug strings (with a fixed
// address requirement) is a rather small set per compilation unit.
class DbgStrings {
public:
DbgStrings();
~DbgStrings();
const char* insert(const char* dbgstr);
bool is_empty() const;
void share(const DbgStrings &src);
void clear();
// For testing purposes only.
const DbgStringCollection* ref() const { return _strings; }
private:
DbgStringCollection* _strings;
};
#endif // not PRODUCT
#ifdef ASSERT
#include "utilities/copy.hpp"
class Scrubber {
public:
Scrubber(void* addr, size_t size) : _addr(addr), _size(size) {}
~Scrubber() {
Copy::fill_to_bytes(_addr, _size, badResourceValue);
}
private:
void* _addr;
size_t _size;
};
#endif // ASSERT
typedef GrowableArray<SharedStubToInterpRequest> SharedStubToInterpRequests;
// A CodeBuffer describes a memory space into which assembly
// code is generated. This memory space usually occupies the
// interior of a single BufferBlob, but in some cases it may be
// an arbitrary span of memory, even outside the code cache.
//
// A code buffer comes in two variants:
//
// (1) A CodeBuffer referring to an already allocated piece of memory:
// This is used to direct 'static' code generation (e.g. for interpreter
// or stubroutine generation, etc.). This code comes with NO relocation
// information.
//
// (2) A CodeBuffer referring to a piece of memory allocated when the
// CodeBuffer is allocated. This is used for nmethod generation.
//
// The memory can be divided up into several parts called sections.
// Each section independently accumulates code (or data) an relocations.
// Sections can grow (at the expense of a reallocation of the BufferBlob
// and recopying of all active sections). When the buffered code is finally
// written to an nmethod (or other CodeBlob), the contents (code, data,
// and relocations) of the sections are padded to an alignment and concatenated.
// Instructions and data in one section can contain relocatable references to
// addresses in a sibling section.
class CodeBuffer: public StackObj DEBUG_ONLY(COMMA private Scrubber) {
friend class CodeSection;
friend class StubCodeGenerator;
private:
// CodeBuffers must be allocated on the stack except for a single
// special case during expansion which is handled internally. This
// is done to guarantee proper cleanup of resources.
void* operator new(size_t size) throw() { return resource_allocate_bytes(size); }
void operator delete(void* p) { ShouldNotCallThis(); }
public:
typedef int csize_t; // code size type; would be size_t except for history
enum {
// Here is the list of all possible sections. The order reflects
// the final layout.
SECT_FIRST = 0,
SECT_CONSTS = SECT_FIRST, // Non-instruction data: Floats, jump tables, etc.
SECT_INSTS, // Executable instructions.
SECT_STUBS, // Outbound trampolines for supporting call sites.
SECT_LIMIT, SECT_NONE = -1
};
typedef LinkedListImpl<int> Offsets;
typedef ResizeableResourceHashtable<address, Offsets, AnyObj::C_HEAP, mtCompiler> SharedTrampolineRequests;
private:
enum {
sect_bits = 2, // assert (SECT_LIMIT <= (1<<sect_bits))
sect_mask = (1<<sect_bits)-1
};
const char* _name;
CodeSection _consts; // constants, jump tables
CodeSection _insts; // instructions (the main section)
CodeSection _stubs; // stubs (call site support), deopt, exception handling
CodeBuffer* _before_expand; // dead buffer, from before the last expansion
BufferBlob* _blob; // optional buffer in CodeCache for generated code
address _total_start; // first address of combined memory buffer
csize_t _total_size; // size in bytes of combined memory buffer
OopRecorder* _oop_recorder;
OopRecorder _default_oop_recorder; // override with initialize_oop_recorder
Arena* _overflow_arena;
address _last_insn; // used to merge consecutive memory barriers, loads or stores.
SharedStubToInterpRequests* _shared_stub_to_interp_requests; // used to collect requests for shared iterpreter stubs
SharedTrampolineRequests* _shared_trampoline_requests; // used to collect requests for shared trampolines
bool _finalize_stubs; // Indicate if we need to finalize stubs to make CodeBuffer final.
int _const_section_alignment;
#ifndef PRODUCT
AsmRemarks _asm_remarks;
DbgStrings _dbg_strings;
bool _collect_comments; // Indicate if we need to collect block comments at all.
address _decode_begin; // start address for decode
address decode_begin();
#endif
void initialize_misc(const char * name) {
// all pointers other than code_start/end and those inside the sections
assert(name != nullptr, "must have a name");
_name = name;
_before_expand = nullptr;
_blob = nullptr;
_oop_recorder = nullptr;
_overflow_arena = nullptr;
_last_insn = nullptr;
_finalize_stubs = false;
_shared_stub_to_interp_requests = nullptr;
_shared_trampoline_requests = nullptr;
_consts.initialize_outer(this, SECT_CONSTS);
_insts.initialize_outer(this, SECT_INSTS);
_stubs.initialize_outer(this, SECT_STUBS);
// Default is to align on 8 bytes. A compiler can change this
// if larger alignment (e.g., 32-byte vector masks) is required.
_const_section_alignment = (int) sizeof(jdouble);
#ifndef PRODUCT
_decode_begin = nullptr;
// Collect block comments, but restrict collection to cases where a disassembly is output.
_collect_comments = ( PrintAssembly
|| PrintStubCode
|| PrintMethodHandleStubs
|| PrintInterpreter
|| PrintSignatureHandlers
|| UnlockDiagnosticVMOptions
);
#endif
}
void initialize(address code_start, csize_t code_size) {
_total_start = code_start;
_total_size = code_size;
// Initialize the main section:
_insts.initialize(code_start, code_size);
assert(!_stubs.is_allocated(), "no garbage here");
assert(!_consts.is_allocated(), "no garbage here");
_oop_recorder = &_default_oop_recorder;
}
void initialize_section_size(CodeSection* cs, csize_t size);
// helper for CodeBuffer::expand()
void take_over_code_from(CodeBuffer* cs);
// ensure sections are disjoint, ordered, and contained in the blob
void verify_section_allocation();
// copies combined relocations to the blob, returns bytes copied
// (if target is null, it is a dry run only, just for sizing)
csize_t copy_relocations_to(CodeBlob* blob) const;
// copies combined code to the blob (assumes relocs are already in there)
void copy_code_to(CodeBlob* blob);
// moves code sections to new buffer (assumes relocs are already in there)
void relocate_code_to(CodeBuffer* cb) const;
// set up a model of the final layout of my contents
void compute_final_layout(CodeBuffer* dest) const;
// Expand the given section so at least 'amount' is remaining.
// Creates a new, larger BufferBlob, and rewrites the code & relocs.
void expand(CodeSection* which_cs, csize_t amount);
// Helper for expand.
csize_t figure_expanded_capacities(CodeSection* which_cs, csize_t amount, csize_t* new_capacity);
public:
// (1) code buffer referring to pre-allocated instruction memory
CodeBuffer(address code_start, csize_t code_size)
DEBUG_ONLY(: Scrubber(this, sizeof(*this)))
{
assert(code_start != nullptr, "sanity");
initialize_misc("static buffer");
initialize(code_start, code_size);
debug_only(verify_section_allocation();)
}
// (2) CodeBuffer referring to pre-allocated CodeBlob.
CodeBuffer(CodeBlob* blob);
// (3) code buffer allocating codeBlob memory for code & relocation
// info but with lazy initialization. The name must be something
// informative.
CodeBuffer(const char* name)
DEBUG_ONLY(: Scrubber(this, sizeof(*this)))
{
initialize_misc(name);
}
// (4) code buffer allocating codeBlob memory for code & relocation
// info. The name must be something informative and code_size must
// include both code and stubs sizes.
CodeBuffer(const char* name, csize_t code_size, csize_t locs_size)
DEBUG_ONLY(: Scrubber(this, sizeof(*this)))
{
initialize_misc(name);
initialize(code_size, locs_size);
}
~CodeBuffer();
// Initialize a CodeBuffer constructed using constructor 3. Using
// constructor 4 is equivalent to calling constructor 3 and then
// calling this method. It's been factored out for convenience of
// construction.
void initialize(csize_t code_size, csize_t locs_size);
CodeSection* consts() { return &_consts; }
CodeSection* insts() { return &_insts; }
CodeSection* stubs() { return &_stubs; }
const CodeSection* insts() const { return &_insts; }
// present sections in order; return null at end; consts is #0, etc.
CodeSection* code_section(int n) {
// This makes the slightly questionable but portable assumption
// that the various members (_consts, _insts, _stubs, etc.) are
// adjacent in the layout of CodeBuffer.
CodeSection* cs = &_consts + n;
assert(cs->index() == n || !cs->is_allocated(), "sanity");
return cs;
}
const CodeSection* code_section(int n) const { // yucky const stuff
return ((CodeBuffer*)this)->code_section(n);
}
static const char* code_section_name(int n);
int section_index_of(address addr) const;
bool contains(address addr) const {
// handy for debugging
return section_index_of(addr) > SECT_NONE;
}
// A stable mapping between 'locators' (small ints) and addresses.
static int locator_pos(int locator) { return locator >> sect_bits; }
static int locator_sect(int locator) { return locator & sect_mask; }
static int locator(int pos, int sect) { return (pos << sect_bits) | sect; }
int locator(address addr) const;
address locator_address(int locator) const {
if (locator < 0) return nullptr;
address start = code_section(locator_sect(locator))->start();
return start + locator_pos(locator);
}
// Heuristic for pre-packing the taken/not-taken bit of a predicted branch.
bool is_backward_branch(Label& L);
// Properties
const char* name() const { return _name; }
void set_name(const char* name) { _name = name; }
CodeBuffer* before_expand() const { return _before_expand; }
BufferBlob* blob() const { return _blob; }
void set_blob(BufferBlob* blob);
void free_blob(); // Free the blob, if we own one.
// Properties relative to the insts section:
address insts_begin() const { return _insts.start(); }
address insts_end() const { return _insts.end(); }
void set_insts_end(address end) { _insts.set_end(end); }
address insts_mark() const { return _insts.mark(); }
void set_insts_mark() { _insts.set_mark(); }
// is there anything in the buffer other than the current section?
bool is_pure() const { return insts_size() == total_content_size(); }
// size in bytes of output so far in the insts sections
csize_t insts_size() const { return _insts.size(); }
// same as insts_size(), except that it asserts there is no non-code here
csize_t pure_insts_size() const { assert(is_pure(), "no non-code");
return insts_size(); }
// capacity in bytes of the insts sections
csize_t insts_capacity() const { return _insts.capacity(); }
// number of bytes remaining in the insts section
csize_t insts_remaining() const { return _insts.remaining(); }
// is a given address in the insts section? (2nd version is end-inclusive)
bool insts_contains(address pc) const { return _insts.contains(pc); }
bool insts_contains2(address pc) const { return _insts.contains2(pc); }
// Record any extra oops required to keep embedded metadata alive
void finalize_oop_references(const methodHandle& method);
// Allocated size in all sections, when aligned and concatenated
// (this is the eventual state of the content in its final
// CodeBlob).
csize_t total_content_size() const;
// Combined offset (relative to start of first section) of given
// section, as eventually found in the final CodeBlob.
csize_t total_offset_of(const CodeSection* cs) const;
// allocated size of all relocation data, including index, rounded up
csize_t total_relocation_size() const;
int total_skipped_instructions_size() const;
csize_t copy_relocations_to(address buf, csize_t buf_limit, bool only_inst) const;
// allocated size of any and all recorded oops
csize_t total_oop_size() const {
OopRecorder* recorder = oop_recorder();
return (recorder == nullptr)? 0: recorder->oop_size();
}
// allocated size of any and all recorded metadata
csize_t total_metadata_size() const {
OopRecorder* recorder = oop_recorder();
return (recorder == nullptr)? 0: recorder->metadata_size();
}
// Configuration functions, called immediately after the CB is constructed.
// The section sizes are subtracted from the original insts section.
// Note: Call them in reverse section order, because each steals from insts.
void initialize_consts_size(csize_t size) { initialize_section_size(&_consts, size); }
void initialize_stubs_size(csize_t size) { initialize_section_size(&_stubs, size); }
// Override default oop recorder.
void initialize_oop_recorder(OopRecorder* r);
OopRecorder* oop_recorder() const { return _oop_recorder; }
address last_insn() const { return _last_insn; }
void set_last_insn(address a) { _last_insn = a; }
void clear_last_insn() { set_last_insn(nullptr); }
#ifndef PRODUCT
AsmRemarks &asm_remarks() { return _asm_remarks; }
DbgStrings &dbg_strings() { return _dbg_strings; }
void clear_strings() {
_asm_remarks.clear();
_dbg_strings.clear();
}
#endif
// Code generation
void relocate(address at, RelocationHolder const& rspec, int format = 0) {
_insts.relocate(at, rspec, format);
}
void relocate(address at, relocInfo::relocType rtype, int format = 0) {
_insts.relocate(at, rtype, format);
}
// Management of overflow storage for binding of Labels.
GrowableArray<int>* create_patch_overflow();
// NMethod generation
void copy_code_and_locs_to(CodeBlob* blob) {
assert(blob != nullptr, "sane");
copy_relocations_to(blob);
copy_code_to(blob);
}
void copy_values_to(nmethod* nm) {
if (!oop_recorder()->is_unused()) {
oop_recorder()->copy_values_to(nm);
}
}
void block_comment(ptrdiff_t offset, const char* comment) PRODUCT_RETURN;
const char* code_string(const char* str) PRODUCT_RETURN_(return nullptr;);
// Log a little info about section usage in the CodeBuffer
void log_section_sizes(const char* name);
// Make a set of stubs final. It can create/optimize stubs.
bool finalize_stubs();
// Request for a shared stub to the interpreter
void shared_stub_to_interp_for(ciMethod* callee, csize_t call_offset);
void set_const_section_alignment(int align) {
_const_section_alignment = align_up(align, HeapWordSize);
}
#ifndef PRODUCT
public:
// Printing / Decoding
// decodes from decode_begin() to code_end() and sets decode_begin to end
void decode();
void print();
#endif
// Directly disassemble code buffer.
void decode(address start, address end);
// The following header contains architecture-specific implementations
#include CPU_HEADER(codeBuffer)
};
// A Java method can have calls of Java methods which can be statically bound.
// Calls of Java methods need stubs to the interpreter. Calls sharing the same Java method
// can share a stub to the interpreter.
// A SharedStubToInterpRequest is a request for a shared stub to the interpreter.
class SharedStubToInterpRequest : public ResourceObj {
private:
ciMethod* _shared_method;
CodeBuffer::csize_t _call_offset; // The offset of the call in CodeBuffer
public:
SharedStubToInterpRequest(ciMethod* method = nullptr, CodeBuffer::csize_t call_offset = -1) : _shared_method(method),
_call_offset(call_offset) {}
ciMethod* shared_method() const { return _shared_method; }
CodeBuffer::csize_t call_offset() const { return _call_offset; }
};
inline bool CodeSection::maybe_expand_to_ensure_remaining(csize_t amount) {
if (remaining() < amount) { _outer->expand(this, amount); return true; }
return false;
}
#endif // SHARE_ASM_CODEBUFFER_HPP