6857159: local schedule failed with checkcast of Thread.currentThread()
Reviewed-by: kvn
/*
* Copyright 1997-2009 Sun Microsystems, Inc. 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 Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
* CA 95054 USA or visit www.sun.com if you need additional information or
* have any questions.
*
*/
// FORMS.HPP - ADL Parser Generic and Utility Forms Classes
#define TRUE 1
#define FALSE 0
// DEFINITIONS OF LEGAL ATTRIBUTE TYPES
#define INS_ATTR 0
#define OP_ATTR 1
// DEFINITIONS OF LEGAL CONSTRAINT TYPES
// Class List
class Form;
class InstructForm;
class MachNodeForm;
class OperandForm;
class OpClassForm;
class AttributeForm;
class RegisterForm;
class PipelineForm;
class SourceForm;
class EncodeForm;
class Component;
class Constraint;
class Predicate;
class MatchRule;
class Attribute;
class Effect;
class ExpandRule;
class RewriteRule;
class ConstructRule;
class FormatRule;
class Peephole;
class EncClass;
class Interface;
class RegInterface;
class ConstInterface;
class MemInterface;
class CondInterface;
class Opcode;
class InsEncode;
class RegDef;
class RegClass;
class AllocClass;
class ResourceForm;
class PipeClassForm;
class PeepMatch;
class PeepConstraint;
class PeepReplace;
class MatchList;
class ArchDesc;
//------------------------------FormDict---------------------------------------
// Dictionary containing Forms, and objects derived from forms
class FormDict {
private:
Dict _form; // map names, char*, to their Form* or NULL
// Disable public use of constructor, copy-ctor, operator =, operator ==
FormDict( );
FormDict &operator =( const FormDict & );
// == compares two dictionaries; they must have the same keys (their keys
// must match using CmpKey) and they must have the same values (pointer
// comparison). If so 1 is returned, if not 0 is returned.
bool operator ==(const FormDict &d) const; // Compare dictionaries for equal
public:
// cmp is a key comparision routine. hash is a routine to hash a key.
// FormDict( CmpKey cmp, Hash hash );
FormDict( CmpKey cmp, Hash hash, Arena *arena );
FormDict( const FormDict & fd ); // Deep-copy guts
~FormDict();
// Return # of key-value pairs in dict
int Size(void) const;
// Insert inserts the given key-value pair into the dictionary. The prior
// value of the key is returned; NULL if the key was not previously defined.
const Form *Insert(const char *name, Form *form); // A new key-value
// Find finds the value of a given key; or NULL if not found.
// The dictionary is NOT changed.
const Form *operator [](const char *name) const; // Do a lookup
void dump();
};
// ***** Master Class for ADL Parser Forms *****
//------------------------------Form-------------------------------------------
class Form {
public:
static Arena *arena; // arena used by forms
private:
static Arena *generate_arena(); // allocate arena used by forms
protected:
int _ftype; // Indicator for derived class type
public:
// Public Data
Form *_next; // Next pointer for form lists
int _linenum; // Line number for debugging
// Dynamic type check for common forms.
virtual OpClassForm *is_opclass() const;
virtual OperandForm *is_operand() const;
virtual InstructForm *is_instruction() const;
virtual MachNodeForm *is_machnode() const;
virtual AttributeForm *is_attribute() const;
virtual Effect *is_effect() const;
virtual ResourceForm *is_resource() const;
virtual PipeClassForm *is_pipeclass() const;
// Check if this form is an operand usable for cisc-spilling
virtual bool is_cisc_reg(FormDict &globals) const { return false; }
virtual bool is_cisc_mem(FormDict &globals) const { return false; }
// Public Methods
Form(int formType=0, int line=0)
: _next(NULL), _linenum(line), _ftype(formType) { };
~Form() {};
virtual bool ideal_only() const {
assert(0,"Check of ideal status on non-instruction/operand form.\n");
return FALSE;
}
// Check constraints after parsing
virtual bool verify() { return true; }
virtual void dump() { output(stderr); } // Debug printer
// Write info to output files
virtual void output(FILE *fp) { fprintf(fp,"Form Output"); }
public:
// ADLC types, match the last character on ideal operands and instructions
enum DataType {
none = 0, // Not a simple type
idealI = 1, // Integer type
idealP = 2, // Pointer types, oop(s)
idealL = 3, // Long type
idealF = 4, // Float type
idealD = 5, // Double type
idealB = 6, // Byte type
idealC = 7, // Char type
idealS = 8, // String type
idealN = 9 // Narrow oop types
};
// Convert ideal name to a DataType, return DataType::none if not a 'ConX'
Form::DataType ideal_to_const_type(const char *ideal_type_name) const;
// Convert ideal name to a DataType, return DataType::none if not a 'sRegX
Form::DataType ideal_to_sReg_type(const char *name) const;
// Convert ideal name to a DataType, return DataType::none if not a 'RegX
Form::DataType ideal_to_Reg_type(const char *name) const;
// Convert ideal name to a DataType, return DataType::none if not a 'LoadX
Form::DataType is_load_from_memory(const char *opType) const;
// Convert ideal name to a DataType, return DataType::none if not a 'StoreX
Form::DataType is_store_to_memory(const char *opType) const;
// ADLC call types, matched with ideal world
enum CallType {
invalid_type = 0, // invalid call type
JAVA_STATIC = 1, // monomorphic entry
JAVA_DYNAMIC = 2, // possibly megamorphic, inline cache call
JAVA_COMPILED = 3, // callee will be compiled java
JAVA_INTERP = 4, // callee will be executed by interpreter
JAVA_NATIVE = 5, // native entrypoint
JAVA_RUNTIME = 6, // runtime entrypoint
JAVA_LEAF = 7 // calling leaf
};
// Interface types for operands and operand classes
enum InterfaceType {
no_interface = 0, // unknown or inconsistent interface type
constant_interface = 1, // interface to constants
register_interface = 2, // interface to registers
memory_interface = 3, // interface to memory
conditional_interface = 4 // interface for condition codes
};
virtual Form::InterfaceType interface_type(FormDict &globals) const;
enum CiscSpillInfo {
Not_cisc_spillable = AdlcVMDeps::Not_cisc_spillable,
Maybe_cisc_spillable = 0,
Is_cisc_spillable = 1
// ...
};
// LEGAL FORM TYPES
enum {
INS,
OPER,
OPCLASS,
SRC,
ADEF,
REG,
PIPE,
CNST,
PRED,
ATTR,
MAT,
ENC,
FOR,
EXP,
REW,
EFF,
RDEF,
RCL,
ACL,
RES,
PCL,
PDEF,
REGL,
RESL,
STAL,
COMP,
PEEP,
RESO
};
};
//------------------------------FormList---------------------------------------
class FormList {
private:
Form *_root;
Form *_tail;
Form *_cur;
int _justReset; // Set immediately after reset
Form *_cur2; // Nested iterator
int _justReset2;
public:
void addForm(Form * entry) {
if (_tail==NULL) { _root = _tail = _cur = entry;}
else { _tail->_next = entry; _tail = entry;}
};
Form * current() { return _cur; };
Form * iter() { if (_justReset) _justReset = 0;
else if (_cur) _cur = _cur->_next;
return _cur;};
void reset() { if (_root) {_cur = _root; _justReset = 1;} };
// Second iterator, state is internal
Form * current2(){ return _cur2; };
Form * iter2() { if (_justReset2) _justReset2 = 0;
else if (_cur2) _cur2 = _cur2->_next;
return _cur2;};
void reset2() { if (_root) {_cur2 = _root; _justReset2 = 1;} };
int count() {
int count = 0; reset();
for( Form *cur; (cur = iter()) != NULL; ) { ++count; };
return count;
}
void dump() {
reset();
Form *cur;
for(; (cur = iter()) != NULL; ) {
cur->dump();
};
}
bool verify() {
bool verified = true;
reset();
Form *cur;
for(; (cur = iter()) != NULL; ) {
if ( ! cur->verify() ) verified = false;
};
return verified;
}
void output(FILE* fp) {
reset();
Form *cur;
for( ; (cur = iter()) != NULL; ) {
cur->output(fp);
};
}
FormList() { _justReset = 1; _justReset2 = 1; _root = NULL; _tail = NULL; _cur = NULL; _cur2 = NULL;};
~FormList();
};
//------------------------------NameList---------------------------------------
// Extendable list of pointers, <char *>
class NameList {
friend class PreserveIter;
private:
int _cur; // Insert next entry here; count of entries
int _max; // Number of spaces allocated
const char **_names; // Array of names
protected:
int _iter; // position during iteration
bool _justReset; // Set immediately after reset
public:
static const char *_signal; // reserved user-defined string
static const char *_signal2; // reserved user-defined string
static const char *_signal3; // reserved user-defined string
enum { Not_in_list = -1 };
void addName(const char *name);
void add_signal();
void clear(); // Remove all entries
int count() const;
void reset(); // Reset iteration
const char *iter(); // after reset(), first element : else next
const char *current(); // return current element in iteration.
const char *peek(int skip = 1); // returns element + skip in iteration if there is one
bool current_is_signal(); // Return 'true' if current entry is signal
bool is_signal(const char *entry); // Return true if entry is a signal
bool search(const char *); // Search for a name in the list
int index(const char *); // Return index of name in list
const char *name (intptr_t index);// Return name at index in list
void dump(); // output to stderr
void output(FILE *fp); // Output list of names to 'fp'
NameList();
~NameList();
};
// Convenience class to preserve iteration state since iterators are
// internal instead of being external.
class PreserveIter {
private:
NameList* _list;
int _iter;
bool _justReset;
public:
PreserveIter(NameList* nl) {
_list = nl;
_iter = _list->_iter;
_justReset = _list->_justReset;
}
~PreserveIter() {
_list->_iter = _iter;
_list->_justReset = _justReset;
}
};
//------------------------------NameAndList------------------------------------
// Storage for a name and an associated list of names
class NameAndList {
private:
const char *_name;
NameList _list;
public:
NameAndList(char *name);
~NameAndList();
// Add to entries in list
void add_entry(const char *entry);
// Access the name and its associated list.
const char *name() const;
void reset();
const char *iter();
int count() { return _list.count(); }
// Return the "index" entry in the list, zero-based
const char *operator[](int index);
void dump(); // output to stderr
void output(FILE *fp); // Output list of names to 'fp'
};
//------------------------------ComponentList---------------------------------
// Component lists always have match rule operands first, followed by parameter
// operands which do not appear in the match list (in order of declaration).
class ComponentList : private NameList {
private:
int _matchcnt; // Count of match rule operands
public:
// This is a batch program. (And I have a destructor bug!)
void operator delete( void *ptr ) {}
void insert(Component *component, bool mflag);
void insert(const char *name, const char *opType, int usedef, bool mflag);
int count();
int match_count() { return _matchcnt; } // Get count of match rule opers
Component *iter(); // after reset(), first element : else next
Component *match_iter(); // after reset(), first element : else next
Component *post_match_iter(); // after reset(), first element : else next
void reset(); // Reset iteration
Component *current(); // return current element in iteration.
// Return element at "position", else NULL
Component *operator[](int position);
Component *at(int position) { return (*this)[position]; }
// Return first component having this name.
const Component *search(const char *name);
// Return number of USEs + number of DEFs
int num_operands();
// Return zero-based position in list; -1 if not in list.
int operand_position(const char *name, int usedef);
// Find position for this name, regardless of use/def information
int operand_position(const char *name);
// Find position for this name when looked up for output via "format"
int operand_position_format(const char *name);
// Find position for the Label when looked up for output via "format"
int label_position();
// Find position for the Method when looked up for output via "format"
int method_position();
void dump(); // output to stderr
void output(FILE *fp); // Output list of names to 'fp'
ComponentList();
~ComponentList();
};
//------------------------------SourceForm-------------------------------------
class SourceForm : public Form {
private:
public:
// Public Data
char *_code; // Buffer for storing code text
// Public Methods
SourceForm(char* code);
~SourceForm();
virtual const char* classname() { return "SourceForm"; }
void dump(); // Debug printer
void output(FILE *fp); // Write output files
};
class HeaderForm : public SourceForm {
public:
HeaderForm(char* code) : SourceForm(code) { }
virtual const char* classname() { return "HeaderForm"; }
};
class PreHeaderForm : public SourceForm {
public:
PreHeaderForm(char* code) : SourceForm(code) { }
virtual const char* classname() { return "PreHeaderForm"; }
};
//------------------------------Expr------------------------------------------
#define STRING_BUFFER_LENGTH 2048
// class Expr represents integer expressions containing constants and addition
// Value must be in range zero through maximum positive integer. 32bits.
// Expected use: instruction and operand costs
class Expr {
public:
enum {
Zero = 0,
Max = 0x7fffffff
};
const char *_external_name; // if !NULL, then print this instead of _expr
const char *_expr;
int _min_value;
int _max_value;
Expr();
Expr(const char *cost);
Expr(const char *name, const char *expression, int min_value, int max_value);
Expr *clone() const;
bool is_unknown() const { return (this == Expr::get_unknown()); }
bool is_zero() const { return (_min_value == Expr::Zero && _max_value == Expr::Zero); }
bool less_than_or_equal(const Expr *c) const { return (_max_value <= c->_min_value); }
void add(const Expr *c);
void add(const char *c);
void add(const char *c, ArchDesc &AD); // check if 'c' is defined in <arch>.ad
void set_external_name(const char *name) { _external_name = name; }
const char *as_string() const { return (_external_name != NULL ? _external_name : _expr); }
void print() const;
void print_define(FILE *fp) const;
void print_assert(FILE *fp) const;
static Expr *get_unknown(); // Returns pointer to shared unknown cost instance
static char *buffer() { return &external_buffer[0]; }
static bool init_buffers(); // Fill buffers with 0
static bool check_buffers(); // if buffer use may have overflowed, assert
private:
static Expr *_unknown_expr;
static char string_buffer[STRING_BUFFER_LENGTH];
static char external_buffer[STRING_BUFFER_LENGTH];
static bool _init_buffers;
const char *compute_expr(const Expr *c1, const Expr *c2); // cost as string after adding 'c1' and 'c2'
int compute_min (const Expr *c1, const Expr *c2); // minimum after adding 'c1' and 'c2'
int compute_max (const Expr *c1, const Expr *c2); // maximum after adding 'c1' and 'c2'
const char *compute_external(const Expr *c1, const Expr *c2); // external name after adding 'c1' and 'c2'
};
//------------------------------ExprDict---------------------------------------
// Dictionary containing Exprs
class ExprDict {
private:
Dict _expr; // map names, char*, to their Expr* or NULL
NameList _defines; // record the order of definitions entered with define call
// Disable public use of constructor, copy-ctor, operator =, operator ==
ExprDict( );
ExprDict( const ExprDict & ); // Deep-copy guts
ExprDict &operator =( const ExprDict & );
// == compares two dictionaries; they must have the same keys (their keys
// must match using CmpKey) and they must have the same values (pointer
// comparison). If so 1 is returned, if not 0 is returned.
bool operator ==(const ExprDict &d) const; // Compare dictionaries for equal
public:
// cmp is a key comparision routine. hash is a routine to hash a key.
ExprDict( CmpKey cmp, Hash hash, Arena *arena );
~ExprDict();
// Return # of key-value pairs in dict
int Size(void) const;
// define inserts the given key-value pair into the dictionary,
// and records the name in order for later output, ...
const Expr *define(const char *name, Expr *expr);
// Insert inserts the given key-value pair into the dictionary. The prior
// value of the key is returned; NULL if the key was not previously defined.
const Expr *Insert(const char *name, Expr *expr); // A new key-value
// Find finds the value of a given key; or NULL if not found.
// The dictionary is NOT changed.
const Expr *operator [](const char *name) const; // Do a lookup
void print_defines(FILE *fp);
void print_asserts(FILE *fp);
void dump();
};