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gnu / gcc / 93ac832f1846e4867aa6537f76f510fab8e3e87d / . / gcc / jit / libgccjit++.h
blob: 82831ff5da0488c84a565d33da6aec7343149055 [file] [log] [blame]
/* A C++ API for libgccjit, purely as inline wrapper functions.
Copyright (C) 2014-2021 Free Software Foundation, Inc.
This file is part of GCC.
GCC is free software; you can redistribute it and/or modify it
under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 3, or (at your option)
any later version.
GCC 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 for more details.
You should have received a copy of the GNU General Public License
along with GCC; see the file COPYING3. If not see
<http://www.gnu.org/licenses/>. */
#ifndef LIBGCCJIT_PLUS_PLUS_H
#define LIBGCCJIT_PLUS_PLUS_H
#include "libgccjit.h"
#include <limits>
#include <ostream>
#include <vector>
/****************************************************************************
C++ API
****************************************************************************/
namespace gccjit
{
/* Indentation indicates inheritance. */
class context;
class error;
class object;
class location;
class field;
class type;
class struct_;
class function;
class block;
class rvalue;
class lvalue;
class param;
class case_;
class extended_asm;
class timer;
class auto_time;
namespace version {};
/* Errors within the API become C++ exceptions of this class. */
class error
{
};
class object
{
public:
context get_context () const;
std::string get_debug_string () const;
protected:
object ();
object (gcc_jit_object *obj);
gcc_jit_object *get_inner_object () const;
private:
gcc_jit_object *m_inner_obj;
};
inline std::ostream& operator << (std::ostream& stream, const object &obj);
/* Some client code will want to supply source code locations, others
won't. To avoid doubling the number of entrypoints, everything
accepting a location also has a default argument. To do this, the
other classes need to see that "location" has a default constructor,
hence we need to declare it first. */
class location : public object
{
public:
location ();
location (gcc_jit_location *loc);
gcc_jit_location *get_inner_location () const;
};
class context
{
public:
static context acquire ();
context ();
context (gcc_jit_context *ctxt);
gccjit::context new_child_context ();
gcc_jit_context *get_inner_context () { return m_inner_ctxt; }
void release ();
gcc_jit_result *compile ();
void compile_to_file (enum gcc_jit_output_kind output_kind,
const char *output_path);
void dump_to_file (const std::string &path,
bool update_locations);
void set_logfile (FILE *logfile,
int flags,
int verbosity);
void dump_reproducer_to_file (const char *path);
void set_str_option (enum gcc_jit_str_option opt,
const char *value);
void set_int_option (enum gcc_jit_int_option opt,
int value);
void set_bool_option (enum gcc_jit_bool_option opt,
int value);
void set_bool_allow_unreachable_blocks (int bool_value);
void set_bool_use_external_driver (int bool_value);
void add_command_line_option (const char *optname);
void add_driver_option (const char *optname);
void set_timer (gccjit::timer t);
gccjit::timer get_timer () const;
location
new_location (const std::string &filename,
int line,
int column);
type get_type (enum gcc_jit_types kind);
type get_int_type (size_t num_bytes, int is_signed);
/* A way to map a specific int type, using the compiler to
get the details automatically e.g.:
gccjit::type type = get_int_type <my_int_type_t> (); */
template <typename T>
type get_int_type ();
type new_array_type (type element_type, int num_elements,
location loc = location ());
field new_field (type type_, const std::string &name,
location loc = location ());
field new_bitfield (type type_, int width, const std::string &name,
location loc = location ());
struct_ new_struct_type (const std::string &name,
std::vector<field> &fields,
location loc = location ());
struct_ new_opaque_struct_type (const std::string &name,
location loc = location ());
param new_param (type type_,
const std::string &name,
location loc = location ());
function new_function (enum gcc_jit_function_kind kind,
type return_type,
const std::string &name,
std::vector<param> &params,
int is_variadic,
location loc = location ());
function get_builtin_function (const std::string &name);
lvalue new_global (enum gcc_jit_global_kind kind,
type type_,
const std::string &name,
location loc = location ());
rvalue new_rvalue (type numeric_type,
int value) const;
rvalue new_rvalue (type numeric_type,
long value) const;
rvalue zero (type numeric_type) const;
rvalue one (type numeric_type) const;
rvalue new_rvalue (type numeric_type,
double value) const;
rvalue new_rvalue (type pointer_type,
void *value) const;
rvalue new_rvalue (const std::string &value) const;
rvalue new_rvalue (type vector_type,
std::vector<rvalue> elements) const;
/* Generic unary operations... */
rvalue new_unary_op (enum gcc_jit_unary_op op,
type result_type,
rvalue a,
location loc = location ());
/* ...and shorter ways to spell the various specific kinds of
unary op. */
rvalue new_minus (type result_type,
rvalue a,
location loc = location ());
rvalue new_bitwise_negate (type result_type,
rvalue a,
location loc = location ());
rvalue new_logical_negate (type result_type,
rvalue a,
location loc = location ());
/* Generic binary operations... */
rvalue new_binary_op (enum gcc_jit_binary_op op,
type result_type,
rvalue a, rvalue b,
location loc = location ());
/* ...and shorter ways to spell the various specific kinds of
binary op. */
rvalue new_plus (type result_type,
rvalue a, rvalue b,
location loc = location ());
rvalue new_minus (type result_type,
rvalue a, rvalue b,
location loc = location ());
rvalue new_mult (type result_type,
rvalue a, rvalue b,
location loc = location ());
rvalue new_divide (type result_type,
rvalue a, rvalue b,
location loc = location ());
rvalue new_modulo (type result_type,
rvalue a, rvalue b,
location loc = location ());
rvalue new_bitwise_and (type result_type,
rvalue a, rvalue b,
location loc = location ());
rvalue new_bitwise_xor (type result_type,
rvalue a, rvalue b,
location loc = location ());
rvalue new_bitwise_or (type result_type,
rvalue a, rvalue b,
location loc = location ());
rvalue new_logical_and (type result_type,
rvalue a, rvalue b,
location loc = location ());
rvalue new_logical_or (type result_type,
rvalue a, rvalue b,
location loc = location ());
/* Generic comparisons... */
rvalue new_comparison (enum gcc_jit_comparison op,
rvalue a, rvalue b,
location loc = location ());
/* ...and shorter ways to spell the various specific kinds of
comparison. */
rvalue new_eq (rvalue a, rvalue b,
location loc = location ());
rvalue new_ne (rvalue a, rvalue b,
location loc = location ());
rvalue new_lt (rvalue a, rvalue b,
location loc = location ());
rvalue new_le (rvalue a, rvalue b,
location loc = location ());
rvalue new_gt (rvalue a, rvalue b,
location loc = location ());
rvalue new_ge (rvalue a, rvalue b,
location loc = location ());
/* The most general way of creating a function call. */
rvalue new_call (function func,
std::vector<rvalue> &args,
location loc = location ());
/* In addition, we provide a series of overloaded "new_call" methods
for specific numbers of args (from 0 - 6), to avoid the need for
client code to manually build a vector. */
rvalue new_call (function func,
location loc = location ());
rvalue new_call (function func,
rvalue arg0,
location loc = location ());
rvalue new_call (function func,
rvalue arg0, rvalue arg1,
location loc = location ());
rvalue new_call (function func,
rvalue arg0, rvalue arg1, rvalue arg2,
location loc = location ());
rvalue new_call (function func,
rvalue arg0, rvalue arg1, rvalue arg2,
rvalue arg3,
location loc = location ());
rvalue new_call (function func,
rvalue arg0, rvalue arg1, rvalue arg2,
rvalue arg3, rvalue arg4,
location loc = location ());
rvalue new_call (function func,
rvalue arg0, rvalue arg1, rvalue arg2,
rvalue arg3, rvalue arg4, rvalue arg5,
location loc = location ());
rvalue new_cast (rvalue expr,
type type_,
location loc = location ());
lvalue new_array_access (rvalue ptr,
rvalue index,
location loc = location ());
case_ new_case (rvalue min_value,
rvalue max_value,
block dest_block);
void add_top_level_asm (const char *asm_stmts,
location loc = location ());
private:
gcc_jit_context *m_inner_ctxt;
};
class field : public object
{
public:
field ();
field (gcc_jit_field *inner);
gcc_jit_field *get_inner_field () const;
};
class type : public object
{
public:
type ();
type (gcc_jit_type *inner);
gcc_jit_type *get_inner_type () const;
type get_pointer ();
type get_const ();
type get_volatile ();
type get_aligned (size_t alignment_in_bytes);
type get_vector (size_t num_units);
// Shortcuts for getting values of numeric types:
rvalue zero ();
rvalue one ();
};
class struct_ : public type
{
public:
struct_ ();
struct_ (gcc_jit_struct *inner);
gcc_jit_struct *get_inner_struct () const;
};
class function : public object
{
public:
function ();
function (gcc_jit_function *func);
gcc_jit_function *get_inner_function () const;
void dump_to_dot (const std::string &path);
param get_param (int index) const;
block new_block ();
block new_block (const std::string &name);
lvalue new_local (type type_,
const std::string &name,
location loc = location ());
rvalue get_address (location loc = location ());
/* A series of overloaded operator () with various numbers of arguments
for a very terse way of creating a call to this function. The call
is created within the same context as the function itself, which may
not be what you want. */
rvalue operator() (location loc = location ());
rvalue operator() (rvalue arg0,
location loc = location ());
rvalue operator() (rvalue arg0, rvalue arg1,
location loc = location ());
rvalue operator() (rvalue arg0, rvalue arg1, rvalue arg2,
location loc = location ());
};
class block : public object
{
public:
block ();
block (gcc_jit_block *inner);
gcc_jit_block *get_inner_block () const;
function get_function () const;
void add_eval (rvalue rvalue,
location loc = location ());
void add_assignment (lvalue lvalue,
rvalue rvalue,
location loc = location ());
void add_assignment_op (lvalue lvalue,
enum gcc_jit_binary_op op,
rvalue rvalue,
location loc = location ());
/* A way to add a function call to the body of a function being
defined, with various numbers of args. */
rvalue add_call (function other,
location loc = location ());
rvalue add_call (function other,
rvalue arg0,
location loc = location ());
rvalue add_call (function other,
rvalue arg0, rvalue arg1,
location loc = location ());
rvalue add_call (function other,
rvalue arg0, rvalue arg1, rvalue arg2,
location loc = location ());
rvalue add_call (function other,
rvalue arg0, rvalue arg1, rvalue arg2, rvalue arg3,
location loc = location ());
void add_comment (const std::string &text,
location loc = location ());
void end_with_conditional (rvalue boolval,
block on_true,
block on_false,
location loc = location ());
void end_with_jump (block target,
location loc = location ());
void end_with_return (rvalue rvalue,
location loc = location ());
void end_with_return (location loc = location ());
void end_with_switch (rvalue expr,
block default_block,
std::vector <case_> cases,
location loc = location ());
extended_asm add_extended_asm (const std::string &asm_template,
location loc = location ());
extended_asm end_with_extended_asm_goto (const std::string &asm_template,
std::vector<block> goto_blocks,
block *fallthrough_block,
location loc = location ());
};
class rvalue : public object
{
public:
rvalue ();
rvalue (gcc_jit_rvalue *inner);
gcc_jit_rvalue *get_inner_rvalue () const;
type get_type ();
rvalue access_field (field field,
location loc = location ());
lvalue dereference_field (field field,
location loc = location ());
lvalue dereference (location loc = location ());
rvalue cast_to (type type_,
location loc = location ());
/* Array access. */
lvalue operator[] (rvalue index);
lvalue operator[] (int index);
};
class lvalue : public rvalue
{
public:
lvalue ();
lvalue (gcc_jit_lvalue *inner);
gcc_jit_lvalue *get_inner_lvalue () const;
lvalue access_field (field field,
location loc = location ());
rvalue get_address (location loc = location ());
lvalue set_initializer (const void *blob, size_t num_bytes);
};
class param : public lvalue
{
public:
param ();
param (gcc_jit_param *inner);
gcc_jit_param *get_inner_param () const;
};
class case_ : public object
{
public:
case_ ();
case_ (gcc_jit_case *inner);
gcc_jit_case *get_inner_case () const;
};
class extended_asm : public object
{
public:
extended_asm ();
extended_asm (gcc_jit_extended_asm *inner);
extended_asm &
set_volatile_flag (bool flag);
extended_asm &
set_inline_flag (bool flag);
extended_asm&
add_output_operand (const std::string &asm_symbolic_name,
const std::string &constraint,
gccjit::lvalue dest);
extended_asm&
add_output_operand (const std::string &constraint,
gccjit::lvalue dest);
extended_asm&
add_input_operand (const std::string &asm_symbolic_name,
const std::string &constraint,
gccjit::rvalue src);
extended_asm&
add_input_operand (const std::string &constraint,
gccjit::rvalue src);
extended_asm&
add_clobber (const std::string &victim);
gcc_jit_extended_asm *get_inner_extended_asm () const;
};
/* Overloaded operators, for those who want the most terse API
(at the possible risk of being a little too magical).
In each case, the first parameter is used to determine which context
owns the resulting expression, and, where appropriate, what the
latter's type is. */
/* Unary operators. */
rvalue operator- (rvalue a); // unary minus
rvalue operator~ (rvalue a); // unary bitwise negate
rvalue operator! (rvalue a); // unary logical negate
/* Binary operators. */
rvalue operator+ (rvalue a, rvalue b);
rvalue operator- (rvalue a, rvalue b);
rvalue operator* (rvalue a, rvalue b);
rvalue operator/ (rvalue a, rvalue b);
rvalue operator% (rvalue a, rvalue b);
rvalue operator& (rvalue a, rvalue b); // bitwise and
rvalue operator^ (rvalue a, rvalue b); // bitwise_xor
rvalue operator| (rvalue a, rvalue b); // bitwise_or
rvalue operator&& (rvalue a, rvalue b); // logical_and
rvalue operator|| (rvalue a, rvalue b); // logical_or
/* Comparisons. */
rvalue operator== (rvalue a, rvalue b);
rvalue operator!= (rvalue a, rvalue b);
rvalue operator< (rvalue a, rvalue b);
rvalue operator<= (rvalue a, rvalue b);
rvalue operator> (rvalue a, rvalue b);
rvalue operator>= (rvalue a, rvalue b);
/* Dereferencing. */
lvalue operator* (rvalue ptr);
class timer
{
public:
timer ();
timer (gcc_jit_timer *inner_timer);
void push (const char *item_name);
void pop (const char *item_name);
void print (FILE *f_out) const;
void release ();
gcc_jit_timer *get_inner_timer () const;
private:
gcc_jit_timer *m_inner_timer;
};
class auto_time
{
public:
auto_time (timer t, const char *item_name);
auto_time (context ctxt, const char *item_name);
~auto_time ();
private:
timer m_timer;
const char *m_item_name;
};
}
/****************************************************************************
Implementation of the API
****************************************************************************/
namespace gccjit {
// class context
inline context context::acquire ()
{
return context (gcc_jit_context_acquire ());
}
inline context::context () : m_inner_ctxt (NULL) {}
inline context::context (gcc_jit_context *inner) : m_inner_ctxt (inner)
{
if (!inner)
throw error ();
}
inline gccjit::context
context::new_child_context ()
{
return context (gcc_jit_context_new_child_context (m_inner_ctxt));
}
inline void
context::release ()
{
gcc_jit_context_release (m_inner_ctxt);
m_inner_ctxt = NULL;
}
inline gcc_jit_result *
context::compile ()
{
gcc_jit_result *result = gcc_jit_context_compile (m_inner_ctxt);
if (!result)
throw error ();
return result;
}
inline void
context::compile_to_file (enum gcc_jit_output_kind output_kind,
const char *output_path)
{
gcc_jit_context_compile_to_file (m_inner_ctxt,
output_kind,
output_path);
}
inline void
context::dump_to_file (const std::string &path,
bool update_locations)
{
gcc_jit_context_dump_to_file (m_inner_ctxt,
path.c_str (),
update_locations);
}
inline void
context::set_logfile (FILE *logfile,
int flags,
int verbosity)
{
gcc_jit_context_set_logfile (m_inner_ctxt,
logfile,
flags,
verbosity);
}
inline void
context::dump_reproducer_to_file (const char *path)
{
gcc_jit_context_dump_reproducer_to_file (m_inner_ctxt,
path);
}
inline void
context::set_str_option (enum gcc_jit_str_option opt,
const char *value)
{
gcc_jit_context_set_str_option (m_inner_ctxt, opt, value);
}
inline void
context::set_int_option (enum gcc_jit_int_option opt,
int value)
{
gcc_jit_context_set_int_option (m_inner_ctxt, opt, value);
}
inline void
context::set_bool_option (enum gcc_jit_bool_option opt,
int value)
{
gcc_jit_context_set_bool_option (m_inner_ctxt, opt, value);
}
inline void
context::set_bool_allow_unreachable_blocks (int bool_value)
{
gcc_jit_context_set_bool_allow_unreachable_blocks (m_inner_ctxt,
bool_value);
}
inline void
context::set_bool_use_external_driver (int bool_value)
{
gcc_jit_context_set_bool_use_external_driver (m_inner_ctxt,
bool_value);
}
inline void
context::add_command_line_option (const char *optname)
{
gcc_jit_context_add_command_line_option (m_inner_ctxt, optname);
}
inline void
context::add_driver_option (const char *optname)
{
gcc_jit_context_add_driver_option (m_inner_ctxt, optname);
}
inline void
context::set_timer (gccjit::timer t)
{
gcc_jit_context_set_timer (m_inner_ctxt, t.get_inner_timer ());
}
inline gccjit::timer
context::get_timer () const
{
return gccjit::timer (gcc_jit_context_get_timer (m_inner_ctxt));
}
inline location
context::new_location (const std::string &filename,
int line,
int column)
{
return location (gcc_jit_context_new_location (m_inner_ctxt,
filename.c_str (),
line,
column));
}
inline type
context::get_type (enum gcc_jit_types kind)
{
return type (gcc_jit_context_get_type (m_inner_ctxt, kind));
}
inline type
context::get_int_type (size_t num_bytes, int is_signed)
{
return type (gcc_jit_context_get_int_type (m_inner_ctxt,
num_bytes,
is_signed));
}
template <typename T>
inline type
context::get_int_type ()
{
return get_int_type (sizeof (T), std::numeric_limits<T>::is_signed);
}
inline type
context::new_array_type (type element_type, int num_elements, location loc)
{
return type (gcc_jit_context_new_array_type (
m_inner_ctxt,
loc.get_inner_location (),
element_type.get_inner_type (),
num_elements));
}
inline field
context::new_field (type type_, const std::string &name, location loc)
{
return field (gcc_jit_context_new_field (m_inner_ctxt,
loc.get_inner_location (),
type_.get_inner_type (),
name.c_str ()));
}
inline field
context::new_bitfield (type type_, int width, const std::string &name,
location loc)
{
return field (gcc_jit_context_new_bitfield (m_inner_ctxt,
loc.get_inner_location (),
type_.get_inner_type (),
width,
name.c_str ()));
}
inline struct_
context::new_struct_type (const std::string &name,
std::vector<field> &fields,
location loc)
{
/* Treat std::vector as an array, relying on it not being resized: */
field *as_array_of_wrappers = &fields[0];
/* Treat the array as being of the underlying pointers, relying on
the wrapper type being such a pointer internally. */
gcc_jit_field **as_array_of_ptrs =
reinterpret_cast<gcc_jit_field **> (as_array_of_wrappers);
return struct_ (gcc_jit_context_new_struct_type (m_inner_ctxt,
loc.get_inner_location (),
name.c_str (),
fields.size (),
as_array_of_ptrs));
}
inline struct_
context::new_opaque_struct_type (const std::string &name,
location loc)
{
return struct_ (gcc_jit_context_new_opaque_struct (
m_inner_ctxt,
loc.get_inner_location (),
name.c_str ()));
}
inline param
context::new_param (type type_,
const std::string &name,
location loc)
{
return param (gcc_jit_context_new_param (m_inner_ctxt,
loc.get_inner_location (),
type_.get_inner_type (),
name.c_str ()));
}
inline function
context::new_function (enum gcc_jit_function_kind kind,
type return_type,
const std::string &name,
std::vector<param> &params,
int is_variadic,
location loc)
{
/* Treat std::vector as an array, relying on it not being resized: */
param *as_array_of_wrappers = &params[0];
/* Treat the array as being of the underlying pointers, relying on
the wrapper type being such a pointer internally. */
gcc_jit_param **as_array_of_ptrs =
reinterpret_cast<gcc_jit_param **> (as_array_of_wrappers);
return function (gcc_jit_context_new_function (m_inner_ctxt,
loc.get_inner_location (),
kind,
return_type.get_inner_type (),
name.c_str (),
params.size (),
as_array_of_ptrs,
is_variadic));
}
inline function
context::get_builtin_function (const std::string &name)
{
return function (gcc_jit_context_get_builtin_function (m_inner_ctxt,
name.c_str ()));
}
inline lvalue
context::new_global (enum gcc_jit_global_kind kind,
type type_,
const std::string &name,
location loc)
{
return lvalue (gcc_jit_context_new_global (m_inner_ctxt,
loc.get_inner_location (),
kind,
type_.get_inner_type (),
name.c_str ()));
}
inline rvalue
context::new_rvalue (type numeric_type,
int value) const
{
return rvalue (
gcc_jit_context_new_rvalue_from_int (m_inner_ctxt,
numeric_type.get_inner_type (),
value));
}
inline rvalue
context::new_rvalue (type numeric_type,
long value) const
{
return rvalue (
gcc_jit_context_new_rvalue_from_long (m_inner_ctxt,
numeric_type.get_inner_type (),
value));
}
inline rvalue
context::zero (type numeric_type) const
{
return rvalue (gcc_jit_context_zero (m_inner_ctxt,
numeric_type.get_inner_type ()));
}
inline rvalue
context::one (type numeric_type) const
{
return rvalue (gcc_jit_context_one (m_inner_ctxt,
numeric_type.get_inner_type ()));
}
inline rvalue
context::new_rvalue (type numeric_type,
double value) const
{
return rvalue (
gcc_jit_context_new_rvalue_from_double (m_inner_ctxt,
numeric_type.get_inner_type (),
value));
}
inline rvalue
context::new_rvalue (type pointer_type,
void *value) const
{
return rvalue (
gcc_jit_context_new_rvalue_from_ptr (m_inner_ctxt,
pointer_type.get_inner_type (),
value));
}
inline rvalue
context::new_rvalue (const std::string &value) const
{
return rvalue (
gcc_jit_context_new_string_literal (m_inner_ctxt, value.c_str ()));
}
inline rvalue
context::new_rvalue (type vector_type,
std::vector<rvalue> elements) const
{
/* Treat std::vector as an array, relying on it not being resized: */
rvalue *as_array_of_wrappers = &elements[0];
/* Treat the array as being of the underlying pointers, relying on
the wrapper type being such a pointer internally. */
gcc_jit_rvalue **as_array_of_ptrs =
reinterpret_cast<gcc_jit_rvalue **> (as_array_of_wrappers);
return rvalue (
gcc_jit_context_new_rvalue_from_vector (m_inner_ctxt,
NULL,
vector_type.get_inner_type (),
elements.size (),
as_array_of_ptrs));
}
inline rvalue
context::new_unary_op (enum gcc_jit_unary_op op,
type result_type,
rvalue a,
location loc)
{
return rvalue (gcc_jit_context_new_unary_op (m_inner_ctxt,
loc.get_inner_location (),
op,
result_type.get_inner_type (),
a.get_inner_rvalue ()));
}
inline rvalue
context::new_minus (type result_type,
rvalue a,
location loc)
{
return rvalue (new_unary_op (GCC_JIT_UNARY_OP_MINUS,
result_type, a, loc));
}
inline rvalue
context::new_bitwise_negate (type result_type,
rvalue a,
location loc)
{
return rvalue (new_unary_op (GCC_JIT_UNARY_OP_BITWISE_NEGATE,
result_type, a, loc));
}
inline rvalue
context::new_logical_negate (type result_type,
rvalue a,
location loc)
{
return rvalue (new_unary_op (GCC_JIT_UNARY_OP_LOGICAL_NEGATE,
result_type, a, loc));
}
inline rvalue
context::new_binary_op (enum gcc_jit_binary_op op,
type result_type,
rvalue a, rvalue b,
location loc)
{
return rvalue (gcc_jit_context_new_binary_op (m_inner_ctxt,
loc.get_inner_location (),
op,
result_type.get_inner_type (),
a.get_inner_rvalue (),
b.get_inner_rvalue ()));
}
inline rvalue
context::new_plus (type result_type,
rvalue a, rvalue b,
location loc)
{
return new_binary_op (GCC_JIT_BINARY_OP_PLUS,
result_type, a, b, loc);
}
inline rvalue
context::new_minus (type result_type,
rvalue a, rvalue b,
location loc)
{
return new_binary_op (GCC_JIT_BINARY_OP_MINUS,
result_type, a, b, loc);
}
inline rvalue
context::new_mult (type result_type,
rvalue a, rvalue b,
location loc)
{
return new_binary_op (GCC_JIT_BINARY_OP_MULT,
result_type, a, b, loc);
}
inline rvalue
context::new_divide (type result_type,
rvalue a, rvalue b,
location loc)
{
return new_binary_op (GCC_JIT_BINARY_OP_DIVIDE,
result_type, a, b, loc);
}
inline rvalue
context::new_modulo (type result_type,
rvalue a, rvalue b,
location loc)
{
return new_binary_op (GCC_JIT_BINARY_OP_MODULO,
result_type, a, b, loc);
}
inline rvalue
context::new_bitwise_and (type result_type,
rvalue a, rvalue b,
location loc)
{
return new_binary_op (GCC_JIT_BINARY_OP_BITWISE_AND,
result_type, a, b, loc);
}
inline rvalue
context::new_bitwise_xor (type result_type,
rvalue a, rvalue b,
location loc)
{
return new_binary_op (GCC_JIT_BINARY_OP_BITWISE_XOR,
result_type, a, b, loc);
}
inline rvalue
context::new_bitwise_or (type result_type,
rvalue a, rvalue b,
location loc)
{
return new_binary_op (GCC_JIT_BINARY_OP_BITWISE_OR,
result_type, a, b, loc);
}
inline rvalue
context::new_logical_and (type result_type,
rvalue a, rvalue b,
location loc)
{
return new_binary_op (GCC_JIT_BINARY_OP_LOGICAL_AND,
result_type, a, b, loc);
}
inline rvalue
context::new_logical_or (type result_type,
rvalue a, rvalue b,
location loc)
{
return new_binary_op (GCC_JIT_BINARY_OP_LOGICAL_OR,
result_type, a, b, loc);
}
inline rvalue
context::new_comparison (enum gcc_jit_comparison op,
rvalue a, rvalue b,
location loc)
{
return rvalue (gcc_jit_context_new_comparison (m_inner_ctxt,
loc.get_inner_location (),
op,
a.get_inner_rvalue (),
b.get_inner_rvalue ()));
}
inline rvalue
context::new_eq (rvalue a, rvalue b,
location loc)
{
return new_comparison (GCC_JIT_COMPARISON_EQ,
a, b, loc);
}
inline rvalue
context::new_ne (rvalue a, rvalue b,
location loc)
{
return new_comparison (GCC_JIT_COMPARISON_NE,
a, b, loc);
}
inline rvalue
context::new_lt (rvalue a, rvalue b,
location loc)
{
return new_comparison (GCC_JIT_COMPARISON_LT,
a, b, loc);
}
inline rvalue
context::new_le (rvalue a, rvalue b,
location loc)
{
return new_comparison (GCC_JIT_COMPARISON_LE,
a, b, loc);
}
inline rvalue
context::new_gt (rvalue a, rvalue b,
location loc)
{
return new_comparison (GCC_JIT_COMPARISON_GT,
a, b, loc);
}
inline rvalue
context::new_ge (rvalue a, rvalue b,
location loc)
{
return new_comparison (GCC_JIT_COMPARISON_GE,
a, b, loc);
}
inline rvalue
context::new_call (function func,
std::vector<rvalue> &args,
location loc)
{
/* Treat std::vector as an array, relying on it not being resized: */
rvalue *as_array_of_wrappers = &args[0];
/* Treat the array as being of the underlying pointers, relying on
the wrapper type being such a pointer internally. */
gcc_jit_rvalue **as_array_of_ptrs =
reinterpret_cast<gcc_jit_rvalue **> (as_array_of_wrappers);
return gcc_jit_context_new_call (m_inner_ctxt,
loc.get_inner_location (),
func.get_inner_function (),
args.size (),
as_array_of_ptrs);
}
inline rvalue
context::new_call (function func,
location loc)
{
std::vector<rvalue> args;
return new_call (func, args, loc);
}
inline rvalue
context::new_call (function func,
rvalue arg0,
location loc)
{
std::vector<rvalue> args(1);
args[0] = arg0;
return new_call (func, args, loc);
}
inline rvalue
context::new_call (function func,
rvalue arg0, rvalue arg1,
location loc)
{
std::vector<rvalue> args(2);
args[0] = arg0;
args[1] = arg1;
return new_call (func, args, loc);
}
inline rvalue
context::new_call (function func,
rvalue arg0, rvalue arg1, rvalue arg2,
location loc)
{
std::vector<rvalue> args(3);
args[0] = arg0;
args[1] = arg1;
args[2] = arg2;
return new_call (func, args, loc);
}
inline rvalue
context::new_call (function func,
rvalue arg0, rvalue arg1, rvalue arg2,
rvalue arg3,
location loc)
{
std::vector<rvalue> args(4);
args[0] = arg0;
args[1] = arg1;
args[2] = arg2;
args[3] = arg3;
return new_call (func, args, loc);
}
inline rvalue
context::new_call (function func,
rvalue arg0, rvalue arg1, rvalue arg2,
rvalue arg3, rvalue arg4,
location loc)
{
std::vector<rvalue> args(5);
args[0] = arg0;
args[1] = arg1;
args[2] = arg2;
args[3] = arg3;
args[4] = arg4;
return new_call (func, args, loc);
}
inline rvalue
context::new_call (function func,
rvalue arg0, rvalue arg1, rvalue arg2,
rvalue arg3, rvalue arg4, rvalue arg5,
location loc)
{
std::vector<rvalue> args(6);
args[0] = arg0;
args[1] = arg1;
args[2] = arg2;
args[3] = arg3;
args[4] = arg4;
args[5] = arg5;
return new_call (func, args, loc);
}
inline rvalue
context::new_cast (rvalue expr,
type type_,
location loc)
{
return rvalue (gcc_jit_context_new_cast (m_inner_ctxt,
loc.get_inner_location (),
expr.get_inner_rvalue (),
type_.get_inner_type ()));
}
inline lvalue
context::new_array_access (rvalue ptr,
rvalue index,
location loc)
{
return lvalue (gcc_jit_context_new_array_access (m_inner_ctxt,
loc.get_inner_location (),
ptr.get_inner_rvalue (),
index.get_inner_rvalue ()));
}
inline case_
context::new_case (rvalue min_value,
rvalue max_value,
block dest_block)
{
return case_ (gcc_jit_context_new_case (m_inner_ctxt,
min_value.get_inner_rvalue (),
max_value.get_inner_rvalue (),
dest_block.get_inner_block ()));
}
inline void
context::add_top_level_asm (const char *asm_stmts, location loc)
{
gcc_jit_context_add_top_level_asm (m_inner_ctxt,
loc.get_inner_location (),
asm_stmts);
}
// class object
inline context
object::get_context () const
{
return context (gcc_jit_object_get_context (m_inner_obj));
}
inline std::string
object::get_debug_string () const
{
return gcc_jit_object_get_debug_string (m_inner_obj);
}
inline object::object () : m_inner_obj (NULL) {}
inline object::object (gcc_jit_object *obj) : m_inner_obj (obj)
{
if (!obj)
throw error ();
}
inline gcc_jit_object *
object::get_inner_object () const
{
return m_inner_obj;
}
inline std::ostream&
operator << (std::ostream& stream, const object &obj)
{
return stream << obj.get_debug_string ();
}
// class location
inline location::location () : object () {}
inline location::location (gcc_jit_location *loc)
: object (gcc_jit_location_as_object (loc))
{}
inline gcc_jit_location *
location::get_inner_location () const
{
/* Manual downcast: */
return reinterpret_cast<gcc_jit_location *> (get_inner_object ());
}
// class field
inline field::field () : object () {}
inline field::field (gcc_jit_field *inner)
: object (gcc_jit_field_as_object (inner))
{}
inline gcc_jit_field *
field::get_inner_field () const
{
/* Manual downcast: */
return reinterpret_cast<gcc_jit_field *> (get_inner_object ());
}
// class type
inline type::type () : object () {}
inline type::type (gcc_jit_type *inner)
: object (gcc_jit_type_as_object (inner))
{}
inline gcc_jit_type *
type::get_inner_type () const
{
/* Manual downcast: */
return reinterpret_cast<gcc_jit_type *> (get_inner_object ());
}
inline type
type::get_pointer ()
{
return type (gcc_jit_type_get_pointer (get_inner_type ()));
}
inline type
type::get_const ()
{
return type (gcc_jit_type_get_const (get_inner_type ()));
}
inline type
type::get_volatile ()
{
return type (gcc_jit_type_get_volatile (get_inner_type ()));
}
inline type
type::get_aligned (size_t alignment_in_bytes)
{
return type (gcc_jit_type_get_aligned (get_inner_type (),
alignment_in_bytes));
}
inline type
type::get_vector (size_t num_units)
{
return type (gcc_jit_type_get_vector (get_inner_type (),
num_units));
}
inline rvalue
type::zero ()
{
return get_context ().new_rvalue (*this, 0);
}
inline rvalue
type::one ()
{
return get_context ().new_rvalue (*this, 1);
}
// class struct_
inline struct_::struct_ () : type (NULL) {}
inline struct_::struct_ (gcc_jit_struct *inner) :
type (gcc_jit_struct_as_type (inner))
{
}
inline gcc_jit_struct *
struct_::get_inner_struct () const
{
/* Manual downcast: */
return reinterpret_cast<gcc_jit_struct *> (get_inner_object ());
}
// class function
inline function::function () : object () {}
inline function::function (gcc_jit_function *inner)
: object (gcc_jit_function_as_object (inner))
{}
inline gcc_jit_function *
function::get_inner_function () const
{
/* Manual downcast: */
return reinterpret_cast<gcc_jit_function *> (get_inner_object ());
}
inline void
function::dump_to_dot (const std::string &path)
{
gcc_jit_function_dump_to_dot (get_inner_function (),
path.c_str ());
}
inline param
function::get_param (int index) const
{
return param (gcc_jit_function_get_param (get_inner_function (),
index));
}
inline block
function::new_block ()
{
return block (gcc_jit_function_new_block (get_inner_function (),
NULL));
}
inline block
function::new_block (const std::string &name)
{
return block (gcc_jit_function_new_block (get_inner_function (),
name.c_str ()));
}
inline lvalue
function::new_local (type type_,
const std::string &name,
location loc)
{
return lvalue (gcc_jit_function_new_local (get_inner_function (),
loc.get_inner_location (),
type_.get_inner_type (),
name.c_str ()));
}
inline rvalue
function::get_address (location loc)
{
return rvalue (gcc_jit_function_get_address (get_inner_function (),
loc.get_inner_location ()));
}
inline function
block::get_function () const
{
return function (gcc_jit_block_get_function ( get_inner_block ()));
}
inline void
block::add_eval (rvalue rvalue,
location loc)
{
gcc_jit_block_add_eval (get_inner_block (),
loc.get_inner_location (),
rvalue.get_inner_rvalue ());
}
inline void
block::add_assignment (lvalue lvalue,
rvalue rvalue,
location loc)
{
gcc_jit_block_add_assignment (get_inner_block (),
loc.get_inner_location (),
lvalue.get_inner_lvalue (),
rvalue.get_inner_rvalue ());
}
inline void
block::add_assignment_op (lvalue lvalue,
enum gcc_jit_binary_op op,
rvalue rvalue,
location loc)
{
gcc_jit_block_add_assignment_op (get_inner_block (),
loc.get_inner_location (),
lvalue.get_inner_lvalue (),
op,
rvalue.get_inner_rvalue ());
}
inline void
block::add_comment (const std::string &text,
location loc)
{
gcc_jit_block_add_comment (get_inner_block (),
loc.get_inner_location (),
text.c_str ());
}
inline void
block::end_with_conditional (rvalue boolval,
block on_true,
block on_false,
location loc)
{
gcc_jit_block_end_with_conditional (get_inner_block (),
loc.get_inner_location (),
boolval.get_inner_rvalue (),
on_true.get_inner_block (),
on_false.get_inner_block ());
}
inline void
block::end_with_jump (block target,
location loc)
{
gcc_jit_block_end_with_jump (get_inner_block (),
loc.get_inner_location (),
target.get_inner_block ());
}
inline void
block::end_with_return (rvalue rvalue,
location loc)
{
gcc_jit_block_end_with_return (get_inner_block (),
loc.get_inner_location (),
rvalue.get_inner_rvalue ());
}
inline void
block::end_with_return (location loc)
{
gcc_jit_block_end_with_void_return (get_inner_block (),
loc.get_inner_location ());
}
inline void
block::end_with_switch (rvalue expr,
block default_block,
std::vector <case_> cases,
location loc)
{
/* Treat std::vector as an array, relying on it not being resized: */
case_ *as_array_of_wrappers = &cases[0];
/* Treat the array as being of the underlying pointers, relying on
the wrapper type being such a pointer internally. */
gcc_jit_case **as_array_of_ptrs =
reinterpret_cast<gcc_jit_case **> (as_array_of_wrappers);
gcc_jit_block_end_with_switch (get_inner_block (),
loc.get_inner_location (),
expr.get_inner_rvalue (),
default_block.get_inner_block (),
cases.size (),
as_array_of_ptrs);
}
inline extended_asm
block::add_extended_asm (const std::string &asm_template,
location loc)
{
return gcc_jit_block_add_extended_asm (get_inner_block (),
loc.get_inner_location (),
asm_template.c_str ());
}
inline extended_asm
block::end_with_extended_asm_goto (const std::string &asm_template,
std::vector<block> goto_blocks,
block *fallthrough_block,
location loc)
{
/* Treat std::vector as an array, relying on it not being resized: */
block *as_array_of_wrappers = &goto_blocks[0];
/* Treat the array as being of the underlying pointers, relying on
the wrapper type being such a pointer internally. */
gcc_jit_block **as_array_of_ptrs =
reinterpret_cast<gcc_jit_block **> (as_array_of_wrappers);
return gcc_jit_block_end_with_extended_asm_goto
(get_inner_block (),
loc.get_inner_location (),
asm_template.c_str (),
goto_blocks.size (),
as_array_of_ptrs,
fallthrough_block ? fallthrough_block->get_inner_block () : NULL);
}
inline rvalue
block::add_call (function other,
location loc)
{
rvalue c = get_context ().new_call (other, loc);
add_eval (c);
return c;
}
inline rvalue
block::add_call (function other,
rvalue arg0,
location loc)
{
rvalue c = get_context ().new_call (other, arg0, loc);
add_eval (c);
return c;
}
inline rvalue
block::add_call (function other,
rvalue arg0, rvalue arg1,
location loc)
{
rvalue c = get_context ().new_call (other, arg0, arg1, loc);
add_eval (c);
return c;
}
inline rvalue
block::add_call (function other,
rvalue arg0, rvalue arg1, rvalue arg2,
location loc)
{
rvalue c = get_context ().new_call (other, arg0, arg1, arg2, loc);
add_eval (c);
return c;
}
inline rvalue
block::add_call (function other,
rvalue arg0, rvalue arg1, rvalue arg2, rvalue arg3,
location loc)
{
rvalue c = get_context ().new_call (other, arg0, arg1, arg2, arg3, loc);
add_eval (c);
return c;
}
inline rvalue
function::operator() (location loc)
{
return get_context ().new_call (*this, loc);
}
inline rvalue
function::operator() (rvalue arg0,
location loc)
{
return get_context ().new_call (*this,
arg0,
loc);
}
inline rvalue
function::operator() (rvalue arg0, rvalue arg1,
location loc)
{
return get_context ().new_call (*this,
arg0, arg1,
loc);
}
inline rvalue
function::operator() (rvalue arg0, rvalue arg1, rvalue arg2,
location loc)
{
return get_context ().new_call (*this,
arg0, arg1, arg2,
loc);
}
// class block
inline block::block () : object () {}
inline block::block (gcc_jit_block *inner)
: object (gcc_jit_block_as_object (inner))
{}
inline gcc_jit_block *
block::get_inner_block () const
{
/* Manual downcast: */
return reinterpret_cast<gcc_jit_block *> (get_inner_object ());
}
// class rvalue
inline rvalue::rvalue () : object () {}
inline rvalue::rvalue (gcc_jit_rvalue *inner)
: object (gcc_jit_rvalue_as_object (inner))
{}
inline gcc_jit_rvalue *
rvalue::get_inner_rvalue () const
{
/* Manual downcast: */
return reinterpret_cast<gcc_jit_rvalue *> (get_inner_object ());
}
inline type
rvalue::get_type ()
{
return type (gcc_jit_rvalue_get_type (get_inner_rvalue ()));
}
inline rvalue
rvalue::access_field (field field,
location loc)
{
return rvalue (gcc_jit_rvalue_access_field (get_inner_rvalue (),
loc.get_inner_location (),
field.get_inner_field ()));
}
inline lvalue
rvalue::dereference_field (field field,
location loc)
{
return lvalue (gcc_jit_rvalue_dereference_field (get_inner_rvalue (),
loc.get_inner_location (),
field.get_inner_field ()));
}
inline lvalue
rvalue::dereference (location loc)
{
return lvalue (gcc_jit_rvalue_dereference (get_inner_rvalue (),
loc.get_inner_location ()));
}
inline rvalue
rvalue::cast_to (type type_,
location loc)
{
return get_context ().new_cast (*this, type_, loc);
}
inline lvalue
rvalue::operator[] (rvalue index)
{
return get_context ().new_array_access (*this, index);
}
inline lvalue
rvalue::operator[] (int index)
{
context ctxt = get_context ();
type int_t = ctxt.get_int_type <int> ();
return ctxt.new_array_access (*this,
ctxt.new_rvalue (int_t,
index));
}
// class lvalue : public rvalue
inline lvalue::lvalue () : rvalue () {}
inline lvalue::lvalue (gcc_jit_lvalue *inner)
: rvalue (gcc_jit_lvalue_as_rvalue (inner))
{}
inline gcc_jit_lvalue *
lvalue::get_inner_lvalue () const
{
/* Manual downcast: */
return reinterpret_cast<gcc_jit_lvalue *> (get_inner_object ());
}
inline lvalue
lvalue::access_field (field field, location loc)
{
return lvalue (gcc_jit_lvalue_access_field (get_inner_lvalue (),
loc.get_inner_location (),
field.get_inner_field ()));
}
inline rvalue
lvalue::get_address (location loc)
{
return rvalue (gcc_jit_lvalue_get_address (get_inner_lvalue (),
loc.get_inner_location ()));
}
inline lvalue
lvalue::set_initializer (const void *blob, size_t num_bytes)
{
gcc_jit_global_set_initializer (get_inner_lvalue (),
blob,
num_bytes);
return *this;
}
// class param : public lvalue
inline param::param () : lvalue () {}
inline param::param (gcc_jit_param *inner)
: lvalue (gcc_jit_param_as_lvalue (inner))
{}
// class case_ : public object
inline case_::case_ () : object () {}
inline case_::case_ (gcc_jit_case *inner)
: object (gcc_jit_case_as_object (inner))
{
}
inline gcc_jit_case *
case_::get_inner_case () const
{
/* Manual downcast: */
return reinterpret_cast<gcc_jit_case *> (get_inner_object ());
}
// class extended_asm : public object
inline extended_asm::extended_asm () : object () {}
inline extended_asm::extended_asm (gcc_jit_extended_asm *inner)
: object (gcc_jit_extended_asm_as_object (inner))
{
}
inline extended_asm&
extended_asm::set_volatile_flag (bool flag)
{
gcc_jit_extended_asm_set_volatile_flag (get_inner_extended_asm (), flag);
return *this;
}
inline extended_asm&
extended_asm::set_inline_flag (bool flag)
{
gcc_jit_extended_asm_set_inline_flag (get_inner_extended_asm (), flag);
return *this;
}
inline extended_asm&
extended_asm::add_output_operand (const std::string &asm_symbolic_name,
const std::string &constraint,
gccjit::lvalue dest)
{
gcc_jit_extended_asm_add_output_operand
(get_inner_extended_asm (),
asm_symbolic_name.c_str (),
constraint.c_str (),
dest.get_inner_lvalue ());
return *this;
}
inline extended_asm&
extended_asm::add_output_operand (const std::string &constraint,
gccjit::lvalue dest)
{
gcc_jit_extended_asm_add_output_operand
(get_inner_extended_asm (),
NULL, /* asm_symbolic_name */
constraint.c_str (),
dest.get_inner_lvalue ());
return *this;
}
inline extended_asm&
extended_asm::add_input_operand (const std::string &asm_symbolic_name,
const std::string &constraint,
gccjit::rvalue src)
{
gcc_jit_extended_asm_add_input_operand
(get_inner_extended_asm (),
asm_symbolic_name.c_str (),
constraint.c_str (),
src.get_inner_rvalue ());
return *this;
}
inline extended_asm&
extended_asm::add_input_operand (const std::string &constraint,
gccjit::rvalue src)
{
gcc_jit_extended_asm_add_input_operand
(get_inner_extended_asm (),
NULL, /* asm_symbolic_name */
constraint.c_str (),
src.get_inner_rvalue ());
return *this;
}
inline extended_asm&
extended_asm::add_clobber (const std::string &victim)
{
gcc_jit_extended_asm_add_clobber (get_inner_extended_asm (),
victim.c_str ());
return *this;
}
inline gcc_jit_extended_asm *
extended_asm::get_inner_extended_asm () const
{
/* Manual downcast: */
return reinterpret_cast<gcc_jit_extended_asm *> (get_inner_object ());
}
/* Overloaded operators. */
// Unary operators
inline rvalue operator- (rvalue a)
{
return a.get_context ().new_minus (a.get_type (), a);
}
inline rvalue operator~ (rvalue a)
{
return a.get_context ().new_bitwise_negate (a.get_type (), a);
}
inline rvalue operator! (rvalue a)
{
return a.get_context ().new_logical_negate (a.get_type (), a);
}
// Binary operators
inline rvalue operator+ (rvalue a, rvalue b)
{
return a.get_context ().new_plus (a.get_type (), a, b);
}
inline rvalue operator- (rvalue a, rvalue b)
{
return a.get_context ().new_minus (a.get_type (), a, b);
}
inline rvalue operator* (rvalue a, rvalue b)
{
return a.get_context ().new_mult (a.get_type (), a, b);
}
inline rvalue operator/ (rvalue a, rvalue b)
{
return a.get_context ().new_divide (a.get_type (), a, b);
}
inline rvalue operator% (rvalue a, rvalue b)
{
return a.get_context ().new_modulo (a.get_type (), a, b);
}
inline rvalue operator& (rvalue a, rvalue b)
{
return a.get_context ().new_bitwise_and (a.get_type (), a, b);
}
inline rvalue operator^ (rvalue a, rvalue b)
{
return a.get_context ().new_bitwise_xor (a.get_type (), a, b);
}
inline rvalue operator| (rvalue a, rvalue b)
{
return a.get_context ().new_bitwise_or (a.get_type (), a, b);
}
inline rvalue operator&& (rvalue a, rvalue b)
{
return a.get_context ().new_logical_and (a.get_type (), a, b);
}
inline rvalue operator|| (rvalue a, rvalue b)
{
return a.get_context ().new_logical_or (a.get_type (), a, b);
}
/* Comparisons. */
inline rvalue operator== (rvalue a, rvalue b)
{
return a.get_context ().new_eq (a, b);
}
inline rvalue operator!= (rvalue a, rvalue b)
{
return a.get_context ().new_ne (a, b);
}
inline rvalue operator< (rvalue a, rvalue b)
{
return a.get_context ().new_lt (a, b);
}
inline rvalue operator<= (rvalue a, rvalue b)
{
return a.get_context ().new_le (a, b);
}
inline rvalue operator> (rvalue a, rvalue b)
{
return a.get_context ().new_gt (a, b);
}
inline rvalue operator>= (rvalue a, rvalue b)
{
return a.get_context ().new_ge (a, b);
}
/* Dereferencing. */
inline lvalue operator* (rvalue ptr)
{
return ptr.dereference ();
}
// class timer
inline
timer::timer ()
{
m_inner_timer = gcc_jit_timer_new ();
}
inline
timer::timer (gcc_jit_timer *inner_timer)
{
m_inner_timer = inner_timer;
}
inline void
timer::push (const char *item_name)
{
gcc_jit_timer_push (m_inner_timer, item_name);
}
inline void
timer::pop (const char *item_name)
{
gcc_jit_timer_pop (m_inner_timer, item_name);
}
inline void
timer::print (FILE *f_out) const
{
gcc_jit_timer_print (m_inner_timer, f_out);
}
inline gcc_jit_timer *
timer::get_inner_timer () const
{
return m_inner_timer;
}
inline void
timer::release ()
{
gcc_jit_timer_release (m_inner_timer);
m_inner_timer = NULL;
}
// class auto_time
inline
auto_time::auto_time (timer t, const char *item_name)
: m_timer (t),
m_item_name (item_name)
{
t.push (item_name);
}
inline
auto_time::auto_time (context ctxt, const char *item_name)
: m_timer (ctxt.get_timer ()),
m_item_name (item_name)
{
m_timer.push (item_name);
}
inline
auto_time::~auto_time ()
{
m_timer.pop (m_item_name);
}
namespace version
{
inline int
major_v ()
{
return gcc_jit_version_major ();
}
inline int
minor_v ()
{
return gcc_jit_version_minor ();
}
inline int
patchlevel_v ()
{
return gcc_jit_version_patchlevel ();
}
} // namespace version
} // namespace gccjit
#endif /* #ifndef LIBGCCJIT_PLUS_PLUS_H */