/
PExpr.h
847 lines (677 loc) · 27.7 KB
/
PExpr.h
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#ifndef __PExpr_H
#define __PExpr_H
/*
* Copyright (c) 1998-2011 Stephen Williams <steve@icarus.com>
*
* This source code is free software; you can redistribute it
* and/or modify it in source code form under the terms of the GNU
* General Public License as published by the Free Software
* Foundation; either version 2 of the License, or (at your option)
* any later version.
*
* This program 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 this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*/
# include <string>
# include <vector>
# include <valarray>
# include "netlist.h"
# include "verinum.h"
# include "LineInfo.h"
# include "pform_types.h"
class Design;
class Module;
class LexicalScope;
class NetNet;
class NetExpr;
class NetScope;
/*
* The PExpr class hierarchy supports the description of
* expressions. The parser can generate expression objects from the
* source, possibly reducing things that it knows how to reduce.
*/
class PExpr : public LineInfo {
public:
enum width_mode_t { SIZED, EXPAND, LOSSLESS, UNSIZED };
// Flag values that can be passed to elaborate_expr.
static const unsigned NO_FLAGS = 0x0;
static const unsigned NEED_CONST = 0x1;
static const unsigned SYS_TASK_ARG = 0x2;
static const unsigned ANNOTATABLE = 0x4;
PExpr();
virtual ~PExpr();
virtual void dump(ostream&) const;
// This method tests whether the expression contains any identifiers
// that have not been previously declared in the specified scope or
// in any containing scope. Any such identifiers are added to the
// specified scope as scalar nets of the specified type.
//
// This operation must be performed by the parser, to ensure that
// subsequent declarations do not affect the decision to create an
// implicit net.
virtual void declare_implicit_nets(LexicalScope*scope, NetNet::Type type);
// This method tests whether the expression contains any
// references to automatically allocated variables.
virtual bool has_aa_term(Design*des, NetScope*scope) const;
// This method tests the type and width that the expression wants
// to be. It should be called before elaborating an expression to
// figure out the type and width of the expression. It also figures
// out the minimum width that can be used to evaluate the expression
// without changing the result. This allows the expression width to
// be pruned when not all bits of the result are used.
//
// Normally mode should be initialised to SIZED before starting to
// test the width of an expression. In SIZED mode the expression
// width will be calculated strictly according to the IEEE standard
// rules for expression width.
// If the expression contains an unsized literal, mode will be
// changed to LOSSLESS. In LOSSLESS mode the expression width will
// be calculated as the minimum width necessary to avoid arithmetic
// overflow or underflow.
// If the expression both contains an unsized literal and contains
// an operation that coerces a vector operand to a different type
// (signed <-> unsigned), mode is changed to UNSIZED. UNSIZED mode
// is the same as LOSSLESS, except that the final expression width
// will be forced to be at least integer_width. This is necessary
// to ensure compatibility with the IEEE standard, which requires
// unsized literals to be treated as having the same width as an
// integer. The lossless width calculation is inadequate in this
// case because coercing an operand to a different type means that
// the expression no longer obeys the normal rules of arithmetic.
//
// If mode is initialised to EXPAND instead of SIZED, the expression
// width will be calculated as the minimum width necessary to avoid
// arithmetic overflow or underflow, even if it contains no unsized
// literals. mode will be changed LOSSLESS or UNSIZED as described
// above. This supports a non-standard mode of expression width
// calculation.
//
// When the final value of mode is UNSIZED, the width returned by
// this method is the calculated lossless width, but the width
// returned by a subsequent call to the expr_width method will be
// the final expression width.
virtual unsigned test_width(Design*des, NetScope*scope,
width_mode_t&mode);
// After the test_width method is complete, these methods
// return valid results.
ivl_variable_type_t expr_type() const { return expr_type_; }
unsigned expr_width() const { return expr_width_; }
unsigned min_width() const { return min_width_; }
bool has_sign() const { return signed_flag_; }
// This method allows the expression type (signed/unsigned)
// to be propagated down to any context-dependant operands.
void cast_signed(bool flag) { signed_flag_ = flag; }
// This is the more generic form of the elaborate_expr method
// below. The plan is to replace the simpler elaborate_expr
// method with this version, which can handle more advanced
// types. But for now, this is only implemented in special cases.
virtual NetExpr*elaborate_expr(Design*des, NetScope*scope,
ivl_type_t type, unsigned flags) const;
// Procedural elaboration of the expression. The expr_width is
// the required width of the expression.
//
// The sys_task_arg flag is true if expressions are allowed to
// be incomplete.
virtual NetExpr*elaborate_expr(Design*des, NetScope*scope,
unsigned expr_wid,
unsigned flags) const;
// This method elaborates the expression as gates, but
// restricted for use as l-values of continuous assignments.
virtual NetNet* elaborate_lnet(Design*des, NetScope*scope) const;
// This is similar to elaborate_lnet, except that the
// expression is evaluated to be bi-directional. This is
// useful for arguments to inout ports of module instances and
// ports of tran primitives.
virtual NetNet* elaborate_bi_net(Design*des, NetScope*scope) const;
// Expressions that can be in the l-value of procedural
// assignments can be elaborated with this method. If the
// is_force flag is true, then the set of valid l-value types
// is slightly modified to accommodate the Verilog force
// statement
virtual NetAssign_* elaborate_lval(Design*des,
NetScope*scope,
bool is_force) const;
// This attempts to evaluate a constant expression, and return
// a verinum as a result. If the expression cannot be
// evaluated, return 0.
virtual verinum* eval_const(Design*des, NetScope*sc) const;
// This method returns true if the expression represents a
// structural net that can have multiple drivers. This is
// used to test whether an input port connection can be
// collapsed to a single wire.
virtual bool is_collapsible_net(Design*des, NetScope*scope) const;
// This method returns true if that expression is the same as
// this expression. This method is used for comparing
// expressions that must be structurally "identical".
virtual bool is_the_same(const PExpr*that) const;
protected:
unsigned fix_width_(width_mode_t mode);
// The derived class test_width methods should fill these in.
ivl_variable_type_t expr_type_;
unsigned expr_width_;
unsigned min_width_;
bool signed_flag_;
private: // not implemented
PExpr(const PExpr&);
PExpr& operator= (const PExpr&);
};
ostream& operator << (ostream&, const PExpr&);
class PEConcat : public PExpr {
public:
PEConcat(const list<PExpr*>&p, PExpr*r =0);
~PEConcat();
virtual verinum* eval_const(Design*des, NetScope*sc) const;
virtual void dump(ostream&) const;
virtual void declare_implicit_nets(LexicalScope*scope, NetNet::Type type);
virtual bool has_aa_term(Design*des, NetScope*scope) const;
virtual unsigned test_width(Design*des, NetScope*scope,
width_mode_t&mode);
virtual NetNet* elaborate_lnet(Design*des, NetScope*scope) const;
virtual NetNet* elaborate_bi_net(Design*des, NetScope*scope) const;
virtual NetExpr*elaborate_expr(Design*des, NetScope*,
unsigned expr_wid,
unsigned flags) const;
virtual NetAssign_* elaborate_lval(Design*des,
NetScope*scope,
bool is_force) const;
virtual bool is_collapsible_net(Design*des, NetScope*scope) const;
private:
NetNet* elaborate_lnet_common_(Design*des, NetScope*scope,
bool bidirectional_flag) const;
private:
vector<PExpr*>parms_;
std::valarray<width_mode_t>width_modes_;
PExpr*repeat_;
NetScope*tested_scope_;
unsigned repeat_count_;
};
/*
* Event expressions are expressions that can be combined with the
* event "or" operator. These include "posedge foo" and similar, and
* also include named events. "edge" events are associated with an
* expression, whereas named events simply have a name, which
* represents an event variable.
*/
class PEEvent : public PExpr {
public:
enum edge_t {ANYEDGE, POSEDGE, NEGEDGE, POSITIVE};
// Use this constructor to create events based on edges or levels.
PEEvent(edge_t t, PExpr*e);
~PEEvent();
edge_t type() const;
PExpr* expr() const;
virtual void dump(ostream&) const;
virtual bool has_aa_term(Design*des, NetScope*scope) const;
private:
edge_t type_;
PExpr *expr_;
};
/*
* This holds a floating point constant in the source.
*/
class PEFNumber : public PExpr {
public:
explicit PEFNumber(verireal*vp);
~PEFNumber();
const verireal& value() const;
/* The eval_const method as applied to a floating point number
gets the *integer* value of the number. This accounts for
any rounding that is needed to get the value. */
virtual verinum* eval_const(Design*des, NetScope*sc) const;
virtual unsigned test_width(Design*des, NetScope*scope,
width_mode_t&mode);
virtual NetExpr*elaborate_expr(Design*des, NetScope*,
unsigned expr_wid,
unsigned flags) const;
virtual void dump(ostream&) const;
private:
verireal*value_;
};
class PEIdent : public PExpr {
public:
explicit PEIdent(perm_string, bool no_implicit_sig=false);
explicit PEIdent(const pform_name_t&);
~PEIdent();
// Add another name to the string of hierarchy that is the
// current identifier.
void append_name(perm_string);
virtual void dump(ostream&) const;
virtual void declare_implicit_nets(LexicalScope*scope, NetNet::Type type);
virtual bool has_aa_term(Design*des, NetScope*scope) const;
virtual unsigned test_width(Design*des, NetScope*scope,
width_mode_t&mode);
// Identifiers are allowed (with restrictions) is assign l-values.
virtual NetNet* elaborate_lnet(Design*des, NetScope*scope) const;
virtual NetNet* elaborate_bi_net(Design*des, NetScope*scope) const;
// Identifiers are also allowed as procedural assignment l-values.
virtual NetAssign_* elaborate_lval(Design*des,
NetScope*scope,
bool is_force) const;
virtual NetExpr*elaborate_expr(Design*des, NetScope*scope,
ivl_type_t type, unsigned flags) const;
virtual NetExpr*elaborate_expr(Design*des, NetScope*,
unsigned expr_wid,
unsigned flags) const;
// Elaborate the PEIdent as a port to a module. This method
// only applies to Ident expressions.
NetNet* elaborate_subport(Design*des, NetScope*sc) const;
verinum* eval_const(Design*des, NetScope*sc) const;
virtual bool is_collapsible_net(Design*des, NetScope*scope) const;
const pform_name_t& path() const { return path_; }
private:
pform_name_t path_;
bool no_implicit_sig_;
private:
// Common functions to calculate parts of part/bit
// selects. These methods return true if the expressions
// elaborate/calculate, or false if there is some sort of
// source error.
bool calculate_bits_(Design*, NetScope*, long&msb, bool&defined) const;
// The calculate_parts_ method calculates the range
// expressions of a part select for the current object. The
// part select expressions are elaborated and evaluated, and
// the values written to the msb/lsb arguments. If there are
// invalid bits (xz) in either expression, then the defined
// flag is set to *false*.
bool calculate_parts_(Design*, NetScope*, long&msb, long&lsb, bool&defined) const;
NetExpr* calculate_up_do_base_(Design*, NetScope*, bool need_const) const;
bool calculate_param_range_(Design*, NetScope*,
const NetExpr*msb_ex, long&msb,
const NetExpr*lsb_ex, long&lsb,
long length) const;
bool calculate_up_do_width_(Design*, NetScope*, unsigned long&wid) const;
// Evaluate the prefix indices. All but the final index in a
// chain of indices must be a single value and must evaluate
// to constants at compile time. For example:
// [x] - OK
// [1][2][x] - OK
// [1][x:y] - OK
// [2:0][x] - BAD
// [y][x] - BAD
// Leave the last index for special handling.
bool calculate_packed_indices_(Design*des, NetScope*scope, NetNet*net,
std::list<long>&prefix_indices) const;
private:
NetAssign_*elaborate_lval_net_word_(Design*, NetScope*, NetNet*) const;
bool elaborate_lval_net_bit_(Design*, NetScope*, NetAssign_*) const;
bool elaborate_lval_net_part_(Design*, NetScope*, NetAssign_*) const;
bool elaborate_lval_net_idx_(Design*, NetScope*, NetAssign_*,
index_component_t::ctype_t) const;
bool elaborate_lval_net_class_member_(Design*, NetScope*,
NetAssign_*,
const perm_string&) const;
bool elaborate_lval_net_packed_member_(Design*, NetScope*,
NetAssign_*,
const perm_string&) const;
bool elaborate_lval_darray_bit_(Design*, NetScope*,
NetAssign_*) const;
private:
NetExpr*elaborate_expr_param_(Design*des,
NetScope*scope,
const NetExpr*par,
NetScope*found_in,
const NetExpr*par_msb,
const NetExpr*par_lsb,
unsigned expr_wid,
unsigned flags) const;
NetExpr*elaborate_expr_param_part_(Design*des,
NetScope*scope,
const NetExpr*par,
NetScope*found_in,
const NetExpr*par_msb,
const NetExpr*par_lsb,
unsigned expr_wid) const;
NetExpr*elaborate_expr_param_idx_up_(Design*des,
NetScope*scope,
const NetExpr*par,
NetScope*found_in,
const NetExpr*par_msb,
const NetExpr*par_lsb,
bool need_const) const;
NetExpr*elaborate_expr_param_idx_do_(Design*des,
NetScope*scope,
const NetExpr*par,
NetScope*found_in,
const NetExpr*par_msb,
const NetExpr*par_lsb,
bool need_const) const;
NetExpr*elaborate_expr_net(Design*des,
NetScope*scope,
NetNet*net,
NetScope*found,
unsigned expr_wid,
unsigned flags) const;
NetExpr*elaborate_expr_net_word_(Design*des,
NetScope*scope,
NetNet*net,
NetScope*found,
unsigned expr_wid,
unsigned flags) const;
NetExpr*elaborate_expr_net_part_(Design*des,
NetScope*scope,
NetESignal*net,
NetScope*found,
unsigned expr_wid) const;
NetExpr*elaborate_expr_net_idx_up_(Design*des,
NetScope*scope,
NetESignal*net,
NetScope*found,
bool need_const) const;
NetExpr*elaborate_expr_net_idx_do_(Design*des,
NetScope*scope,
NetESignal*net,
NetScope*found,
bool need_const) const;
NetExpr*elaborate_expr_net_bit_(Design*des,
NetScope*scope,
NetESignal*net,
NetScope*found,
bool need_const) const;
private:
NetNet* elaborate_lnet_common_(Design*des, NetScope*scope,
bool bidirectional_flag) const;
bool eval_part_select_(Design*des, NetScope*scope, NetNet*sig,
long&midx, long&lidx) const;
};
class PENew : public PExpr {
public:
explicit PENew (PExpr*s);
~PENew();
virtual void dump(ostream&) const;
virtual unsigned test_width(Design*des, NetScope*scope,
width_mode_t&mode);
virtual NetExpr*elaborate_expr(Design*des, NetScope*scope,
ivl_type_t type, unsigned flags) const;
virtual NetExpr*elaborate_expr(Design*des, NetScope*,
unsigned expr_wid,
unsigned flags) const;
private:
PExpr*size_;
};
class PENewClass : public PExpr {
public:
explicit PENewClass ();
~PENewClass();
virtual void dump(ostream&) const;
// Class objects don't have a useful width, but the expression
// is IVL_VT_CLASS.
virtual unsigned test_width(Design*des, NetScope*scope,
width_mode_t&mode);
// Note that class (new) expressions only appear in context
// that uses this form of the elaborate_expr method. In fact,
// the type argument is going to be a netclas_t object.
virtual NetExpr*elaborate_expr(Design*des, NetScope*scope,
ivl_type_t type, unsigned flags) const;
private:
};
class PENull : public PExpr {
public:
explicit PENull();
~PENull();
virtual void dump(ostream&) const;
virtual unsigned test_width(Design*des, NetScope*scope,
width_mode_t&mode);
virtual NetExpr*elaborate_expr(Design*des, NetScope*scope,
ivl_type_t type, unsigned flags) const;
virtual NetExpr*elaborate_expr(Design*des, NetScope*,
unsigned expr_wid,
unsigned flags) const;
};
class PENumber : public PExpr {
public:
explicit PENumber(verinum*vp);
~PENumber();
const verinum& value() const;
virtual void dump(ostream&) const;
virtual unsigned test_width(Design*des, NetScope*scope,
width_mode_t&mode);
virtual NetEConst*elaborate_expr(Design*des, NetScope*,
unsigned expr_wid, unsigned) const;
virtual NetAssign_* elaborate_lval(Design*des,
NetScope*scope,
bool is_force) const;
virtual verinum* eval_const(Design*des, NetScope*sc) const;
virtual bool is_the_same(const PExpr*that) const;
private:
verinum*const value_;
};
/*
* This represents a string constant in an expression.
*
* The s parameter to the PEString constructor is a C string that this
* class instance will take for its own. The caller should not delete
* the string, the destructor will do it.
*/
class PEString : public PExpr {
public:
explicit PEString(char*s);
~PEString();
string value() const;
virtual void dump(ostream&) const;
virtual unsigned test_width(Design*des, NetScope*scope,
width_mode_t&mode);
virtual NetEConst*elaborate_expr(Design*des, NetScope*,
unsigned expr_wid, unsigned) const;
verinum* eval_const(Design*, NetScope*) const;
private:
char*text_;
};
class PEUnary : public PExpr {
public:
explicit PEUnary(char op, PExpr*ex);
~PEUnary();
virtual void dump(ostream&out) const;
virtual void declare_implicit_nets(LexicalScope*scope, NetNet::Type type);
virtual bool has_aa_term(Design*des, NetScope*scope) const;
virtual unsigned test_width(Design*des, NetScope*scope,
width_mode_t&mode);
virtual NetExpr*elaborate_expr(Design*des, NetScope*,
unsigned expr_wid,
unsigned flags) const;
virtual verinum* eval_const(Design*des, NetScope*sc) const;
public:
inline char get_op() const { return op_; }
inline PExpr*get_expr() const { return expr_; }
private:
NetExpr* elaborate_expr_bits_(NetExpr*operand, unsigned expr_wid) const;
private:
char op_;
PExpr*expr_;
};
class PEBinary : public PExpr {
public:
explicit PEBinary(char op, PExpr*l, PExpr*r);
~PEBinary();
virtual void dump(ostream&out) const;
virtual void declare_implicit_nets(LexicalScope*scope, NetNet::Type type);
virtual bool has_aa_term(Design*des, NetScope*scope) const;
virtual unsigned test_width(Design*des, NetScope*scope,
width_mode_t&mode);
virtual NetExpr*elaborate_expr(Design*des, NetScope*,
unsigned expr_wid,
unsigned flags) const;
virtual verinum* eval_const(Design*des, NetScope*sc) const;
protected:
char op_;
PExpr*left_;
PExpr*right_;
NetExpr*elaborate_expr_base_(Design*, NetExpr*lp, NetExpr*rp,
unsigned expr_wid) const;
NetExpr*elaborate_eval_expr_base_(Design*, NetExpr*lp, NetExpr*rp,
unsigned expr_wid) const;
NetExpr*elaborate_expr_base_bits_(Design*, NetExpr*lp, NetExpr*rp,
unsigned expr_wid) const;
NetExpr*elaborate_expr_base_div_(Design*, NetExpr*lp, NetExpr*rp,
unsigned expr_wid) const;
NetExpr*elaborate_expr_base_mult_(Design*, NetExpr*lp, NetExpr*rp,
unsigned expr_wid) const;
NetExpr*elaborate_expr_base_add_(Design*, NetExpr*lp, NetExpr*rp,
unsigned expr_wid) const;
};
/*
* Here are a few specialized classes for handling specific binary
* operators.
*/
class PEBComp : public PEBinary {
public:
explicit PEBComp(char op, PExpr*l, PExpr*r);
~PEBComp();
virtual unsigned test_width(Design*des, NetScope*scope,
width_mode_t&mode);
NetExpr* elaborate_expr(Design*des, NetScope*scope,
unsigned expr_wid, unsigned flags) const;
private:
unsigned l_width_;
unsigned r_width_;
};
/*
* This derived class is for handling logical expressions: && and ||.
*/
class PEBLogic : public PEBinary {
public:
explicit PEBLogic(char op, PExpr*l, PExpr*r);
~PEBLogic();
virtual unsigned test_width(Design*des, NetScope*scope,
width_mode_t&mode);
NetExpr* elaborate_expr(Design*des, NetScope*scope,
unsigned expr_wid, unsigned flags) const;
};
/*
* A couple of the binary operands have a special sub-expression rule
* where the expression width is carried entirely by the left
* expression, and the right operand is self-determined.
*/
class PEBLeftWidth : public PEBinary {
public:
explicit PEBLeftWidth(char op, PExpr*l, PExpr*r);
~PEBLeftWidth() =0;
virtual NetExpr*elaborate_expr_leaf(Design*des, NetExpr*lp, NetExpr*rp,
unsigned expr_wid) const =0;
protected:
virtual unsigned test_width(Design*des, NetScope*scope,
width_mode_t&mode);
virtual NetExpr*elaborate_expr(Design*des, NetScope*scope,
unsigned expr_wid,
unsigned flags) const;
};
class PEBPower : public PEBLeftWidth {
public:
explicit PEBPower(char op, PExpr*l, PExpr*r);
~PEBPower();
NetExpr*elaborate_expr_leaf(Design*des, NetExpr*lp, NetExpr*rp,
unsigned expr_wid) const;
};
class PEBShift : public PEBLeftWidth {
public:
explicit PEBShift(char op, PExpr*l, PExpr*r);
~PEBShift();
NetExpr*elaborate_expr_leaf(Design*des, NetExpr*lp, NetExpr*rp,
unsigned expr_wid) const;
};
/*
* This class supports the ternary (?:) operator. The operator takes
* three expressions, the test, the true result and the false result.
*/
class PETernary : public PExpr {
public:
explicit PETernary(PExpr*e, PExpr*t, PExpr*f);
~PETernary();
virtual void dump(ostream&out) const;
virtual void declare_implicit_nets(LexicalScope*scope, NetNet::Type type);
virtual bool has_aa_term(Design*des, NetScope*scope) const;
virtual unsigned test_width(Design*des, NetScope*scope,
width_mode_t&mode);
virtual NetExpr*elaborate_expr(Design*des, NetScope*,
unsigned expr_wid,
unsigned flags) const;
virtual verinum* eval_const(Design*des, NetScope*sc) const;
private:
NetExpr* elab_and_eval_alternative_(Design*des, NetScope*scope,
PExpr*expr, unsigned expr_wid,
unsigned flags) const;
private:
PExpr*expr_;
PExpr*tru_;
PExpr*fal_;
};
/*
* This class represents a parsed call to a function, including calls
* to system functions. The parameters in the parms list are the
* expressions that are passed as input to the ports of the function.
*/
class PECallFunction : public PExpr {
public:
explicit PECallFunction(const pform_name_t&n, const vector<PExpr *> &parms);
// Call of system function (name is not hierarchical)
explicit PECallFunction(perm_string n, const vector<PExpr *> &parms);
explicit PECallFunction(perm_string n);
// svector versions. Should be removed!
explicit PECallFunction(const pform_name_t&n, const list<PExpr *> &parms);
explicit PECallFunction(perm_string n, const list<PExpr *> &parms);
~PECallFunction();
virtual void dump(ostream &) const;
virtual void declare_implicit_nets(LexicalScope*scope, NetNet::Type type);
virtual bool has_aa_term(Design*des, NetScope*scope) const;
virtual NetExpr*elaborate_expr(Design*des, NetScope*scope,
unsigned expr_wid,
unsigned flags) const;
virtual unsigned test_width(Design*des, NetScope*scope,
width_mode_t&mode);
private:
pform_name_t path_;
vector<PExpr *> parms_;
bool check_call_matches_definition_(Design*des, NetScope*dscope) const;
NetExpr* cast_to_width_(NetExpr*expr, unsigned wid) const;
NetExpr*elaborate_expr_method_(Design*des, NetScope*scope,
unsigned expr_wid) const;
#if 0
NetExpr*elaborate_expr_string_method_(Design*des, NetScope*scope) const;
NetExpr*elaborate_expr_enum_method_(Design*des, NetScope*scope,
unsigned expr_wid) const;
#endif
NetExpr* elaborate_sfunc_(Design*des, NetScope*scope,
unsigned expr_wid,
unsigned flags) const;
NetExpr* elaborate_access_func_(Design*des, NetScope*scope, ivl_nature_t,
unsigned expr_wid) const;
unsigned test_width_sfunc_(Design*des, NetScope*scope,
width_mode_t&mode);
unsigned test_width_method_(Design*des, NetScope*scope,
width_mode_t&mode);
};
/*
* Support the SystemVerilog cast to size.
*/
class PECastSize : public PExpr {
public:
explicit PECastSize(unsigned expr_wid, PExpr*base);
~PECastSize();
void dump(ostream &out) const;
virtual NetExpr*elaborate_expr(Design*des, NetScope*scope,
unsigned expr_wid,
unsigned flags) const;
virtual unsigned test_width(Design*des, NetScope*scope,
width_mode_t&mode);
private:
unsigned size_;
PExpr* base_;
};
/*
* This class is used for error recovery. All methods do nothing and return
* null or default values.
*/
class PEVoid : public PExpr {
public:
explicit PEVoid();
~PEVoid();
virtual NetExpr*elaborate_expr(Design*des, NetScope*scope,
unsigned expr_wid,
unsigned flags) const;
};
#endif