8049325: Introduce and clean up umbrella headers for the files in the cpu subdirectories.
Summary: Introduce and clean up umbrella headers for the files in the cpu subdirectories.
Reviewed-by: lfoltan, coleenp, dholmes
/*
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* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
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* 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).
*
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* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
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#ifndef CPU_X86_VM_FRAME_X86_INLINE_HPP
#define CPU_X86_VM_FRAME_X86_INLINE_HPP
#include "code/codeCache.hpp"
#include "code/vmreg.inline.hpp"
// Inline functions for Intel frames:
// Constructors:
inline frame::frame() {
_pc = NULL;
_sp = NULL;
_unextended_sp = NULL;
_fp = NULL;
_cb = NULL;
_deopt_state = unknown;
}
inline frame::frame(intptr_t* sp, intptr_t* fp, address pc) {
_sp = sp;
_unextended_sp = sp;
_fp = fp;
_pc = pc;
assert(pc != NULL, "no pc?");
_cb = CodeCache::find_blob(pc);
adjust_unextended_sp();
address original_pc = nmethod::get_deopt_original_pc(this);
if (original_pc != NULL) {
_pc = original_pc;
_deopt_state = is_deoptimized;
} else {
_deopt_state = not_deoptimized;
}
}
inline frame::frame(intptr_t* sp, intptr_t* unextended_sp, intptr_t* fp, address pc) {
_sp = sp;
_unextended_sp = unextended_sp;
_fp = fp;
_pc = pc;
assert(pc != NULL, "no pc?");
_cb = CodeCache::find_blob(pc);
adjust_unextended_sp();
address original_pc = nmethod::get_deopt_original_pc(this);
if (original_pc != NULL) {
_pc = original_pc;
assert(((nmethod*)_cb)->insts_contains(_pc), "original PC must be in nmethod");
_deopt_state = is_deoptimized;
} else {
_deopt_state = not_deoptimized;
}
}
inline frame::frame(intptr_t* sp, intptr_t* fp) {
_sp = sp;
_unextended_sp = sp;
_fp = fp;
_pc = (address)(sp[-1]);
// Here's a sticky one. This constructor can be called via AsyncGetCallTrace
// when last_Java_sp is non-null but the pc fetched is junk. If we are truly
// unlucky the junk value could be to a zombied method and we'll die on the
// find_blob call. This is also why we can have no asserts on the validity
// of the pc we find here. AsyncGetCallTrace -> pd_get_top_frame_for_signal_handler
// -> pd_last_frame should use a specialized version of pd_last_frame which could
// call a specilaized frame constructor instead of this one.
// Then we could use the assert below. However this assert is of somewhat dubious
// value.
// assert(_pc != NULL, "no pc?");
_cb = CodeCache::find_blob(_pc);
adjust_unextended_sp();
address original_pc = nmethod::get_deopt_original_pc(this);
if (original_pc != NULL) {
_pc = original_pc;
_deopt_state = is_deoptimized;
} else {
_deopt_state = not_deoptimized;
}
}
// Accessors
inline bool frame::equal(frame other) const {
bool ret = sp() == other.sp()
&& unextended_sp() == other.unextended_sp()
&& fp() == other.fp()
&& pc() == other.pc();
assert(!ret || ret && cb() == other.cb() && _deopt_state == other._deopt_state, "inconsistent construction");
return ret;
}
// Return unique id for this frame. The id must have a value where we can distinguish
// identity and younger/older relationship. NULL represents an invalid (incomparable)
// frame.
inline intptr_t* frame::id(void) const { return unextended_sp(); }
// Relationals on frames based
// Return true if the frame is younger (more recent activation) than the frame represented by id
inline bool frame::is_younger(intptr_t* id) const { assert(this->id() != NULL && id != NULL, "NULL frame id");
return this->id() < id ; }
// Return true if the frame is older (less recent activation) than the frame represented by id
inline bool frame::is_older(intptr_t* id) const { assert(this->id() != NULL && id != NULL, "NULL frame id");
return this->id() > id ; }
inline intptr_t* frame::link() const { return (intptr_t*) *(intptr_t **)addr_at(link_offset); }
inline void frame::set_link(intptr_t* addr) { *(intptr_t **)addr_at(link_offset) = addr; }
inline intptr_t* frame::unextended_sp() const { return _unextended_sp; }
// Return address:
inline address* frame::sender_pc_addr() const { return (address*) addr_at( return_addr_offset); }
inline address frame::sender_pc() const { return *sender_pc_addr(); }
// return address of param, zero origin index.
inline address* frame::native_param_addr(int idx) const { return (address*) addr_at( native_frame_initial_param_offset+idx); }
#ifdef CC_INTERP
inline interpreterState frame::get_interpreterState() const {
return ((interpreterState)addr_at( -((int)sizeof(BytecodeInterpreter))/wordSize ));
}
inline intptr_t* frame::sender_sp() const {
// Hmm this seems awfully expensive QQQ, is this really called with interpreted frames?
if (is_interpreted_frame()) {
assert(false, "should never happen");
return get_interpreterState()->sender_sp();
} else {
return addr_at(sender_sp_offset);
}
}
inline intptr_t** frame::interpreter_frame_locals_addr() const {
assert(is_interpreted_frame(), "must be interpreted");
return &(get_interpreterState()->_locals);
}
inline intptr_t* frame::interpreter_frame_bcx_addr() const {
assert(is_interpreted_frame(), "must be interpreted");
return (intptr_t*) &(get_interpreterState()->_bcp);
}
// Constant pool cache
inline ConstantPoolCache** frame::interpreter_frame_cache_addr() const {
assert(is_interpreted_frame(), "must be interpreted");
return &(get_interpreterState()->_constants);
}
// Method
inline Method** frame::interpreter_frame_method_addr() const {
assert(is_interpreted_frame(), "must be interpreted");
return &(get_interpreterState()->_method);
}
inline intptr_t* frame::interpreter_frame_mdx_addr() const {
assert(is_interpreted_frame(), "must be interpreted");
return (intptr_t*) &(get_interpreterState()->_mdx);
}
// top of expression stack
inline intptr_t* frame::interpreter_frame_tos_address() const {
assert(is_interpreted_frame(), "wrong frame type");
return get_interpreterState()->_stack + 1;
}
#else /* asm interpreter */
inline intptr_t* frame::sender_sp() const { return addr_at( sender_sp_offset); }
inline intptr_t** frame::interpreter_frame_locals_addr() const {
return (intptr_t**)addr_at(interpreter_frame_locals_offset);
}
inline intptr_t* frame::interpreter_frame_last_sp() const {
return *(intptr_t**)addr_at(interpreter_frame_last_sp_offset);
}
inline intptr_t* frame::interpreter_frame_bcx_addr() const {
return (intptr_t*)addr_at(interpreter_frame_bcx_offset);
}
inline intptr_t* frame::interpreter_frame_mdx_addr() const {
return (intptr_t*)addr_at(interpreter_frame_mdx_offset);
}
// Constant pool cache
inline ConstantPoolCache** frame::interpreter_frame_cache_addr() const {
return (ConstantPoolCache**)addr_at(interpreter_frame_cache_offset);
}
// Method
inline Method** frame::interpreter_frame_method_addr() const {
return (Method**)addr_at(interpreter_frame_method_offset);
}
// top of expression stack
inline intptr_t* frame::interpreter_frame_tos_address() const {
intptr_t* last_sp = interpreter_frame_last_sp();
if (last_sp == NULL) {
return sp();
} else {
// sp() may have been extended or shrunk by an adapter. At least
// check that we don't fall behind the legal region.
// For top deoptimized frame last_sp == interpreter_frame_monitor_end.
assert(last_sp <= (intptr_t*) interpreter_frame_monitor_end(), "bad tos");
return last_sp;
}
}
inline oop* frame::interpreter_frame_temp_oop_addr() const {
return (oop *)(fp() + interpreter_frame_oop_temp_offset);
}
#endif /* CC_INTERP */
inline int frame::pd_oop_map_offset_adjustment() const {
return 0;
}
inline int frame::interpreter_frame_monitor_size() {
return BasicObjectLock::size();
}
// expression stack
// (the max_stack arguments are used by the GC; see class FrameClosure)
inline intptr_t* frame::interpreter_frame_expression_stack() const {
intptr_t* monitor_end = (intptr_t*) interpreter_frame_monitor_end();
return monitor_end-1;
}
inline jint frame::interpreter_frame_expression_stack_direction() { return -1; }
// Entry frames
inline JavaCallWrapper** frame::entry_frame_call_wrapper_addr() const {
return (JavaCallWrapper**)addr_at(entry_frame_call_wrapper_offset);
}
// Compiled frames
inline int frame::local_offset_for_compiler(int local_index, int nof_args, int max_nof_locals, int max_nof_monitors) {
return (nof_args - local_index + (local_index < nof_args ? 1: -1));
}
inline int frame::monitor_offset_for_compiler(int local_index, int nof_args, int max_nof_locals, int max_nof_monitors) {
return local_offset_for_compiler(local_index, nof_args, max_nof_locals, max_nof_monitors);
}
inline int frame::min_local_offset_for_compiler(int nof_args, int max_nof_locals, int max_nof_monitors) {
return (nof_args - (max_nof_locals + max_nof_monitors*2) - 1);
}
inline bool frame::volatile_across_calls(Register reg) {
return true;
}
inline oop frame::saved_oop_result(RegisterMap* map) const {
oop* result_adr = (oop *)map->location(rax->as_VMReg());
guarantee(result_adr != NULL, "bad register save location");
return (*result_adr);
}
inline void frame::set_saved_oop_result(RegisterMap* map, oop obj) {
oop* result_adr = (oop *)map->location(rax->as_VMReg());
guarantee(result_adr != NULL, "bad register save location");
*result_adr = obj;
}
#endif // CPU_X86_VM_FRAME_X86_INLINE_HPP