yosys/frontends/verilog/verilog_parser.y

3480 lines
98 KiB
Plaintext

/*
* yosys -- Yosys Open SYnthesis Suite
*
* Copyright (C) 2012 Claire Xenia Wolf <claire@yosyshq.com>
*
* Permission to use, copy, modify, and/or distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*
* ---
*
* The Verilog frontend.
*
* This frontend is using the AST frontend library (see frontends/ast/).
* Thus this frontend does not generate RTLIL code directly but creates an
* AST directly from the Verilog parse tree and then passes this AST to
* the AST frontend library.
*
* ---
*
* This is the actual bison parser for Verilog code. The AST ist created directly
* from the bison reduce functions here. Note that this code uses a few global
* variables to hold the state of the AST generator and therefore this parser is
* not reentrant.
*
*/
%require "3.0"
%{
#include <list>
#include <stack>
#include <string.h>
#include "frontends/verilog/verilog_frontend.h"
#include "frontends/verilog/verilog_parser.tab.hh"
#include "kernel/log.h"
#define YYLEX_PARAM &yylval, &yylloc
USING_YOSYS_NAMESPACE
using namespace AST;
using namespace VERILOG_FRONTEND;
YOSYS_NAMESPACE_BEGIN
namespace VERILOG_FRONTEND {
int port_counter;
dict<std::string, int> port_stubs;
dict<IdString, AstNode*> *attr_list, default_attr_list;
std::stack<dict<IdString, AstNode*> *> attr_list_stack;
dict<IdString, AstNode*> *albuf;
std::vector<UserTypeMap> user_type_stack;
dict<std::string, AstNode*> pkg_user_types;
std::vector<AstNode*> ast_stack;
struct AstNode *astbuf1, *astbuf2, *astbuf3;
struct AstNode *current_function_or_task;
struct AstNode *current_ast, *current_ast_mod;
int current_function_or_task_port_id;
std::vector<char> case_type_stack;
bool do_not_require_port_stubs;
bool default_nettype_wire;
bool sv_mode, formal_mode, lib_mode, specify_mode;
bool noassert_mode, noassume_mode, norestrict_mode;
bool assume_asserts_mode, assert_assumes_mode;
bool current_wire_rand, current_wire_const;
bool current_modport_input, current_modport_output;
std::istream *lexin;
}
YOSYS_NAMESPACE_END
#define SET_AST_NODE_LOC(WHICH, BEGIN, END) \
do { (WHICH)->location.first_line = (BEGIN).first_line; \
(WHICH)->location.first_column = (BEGIN).first_column; \
(WHICH)->location.last_line = (END).last_line; \
(WHICH)->location.last_column = (END).last_column; } while(0)
#define SET_RULE_LOC(LHS, BEGIN, END) \
do { (LHS).first_line = (BEGIN).first_line; \
(LHS).first_column = (BEGIN).first_column; \
(LHS).last_line = (END).last_line; \
(LHS).last_column = (END).last_column; } while(0)
int frontend_verilog_yylex(YYSTYPE *yylval_param, YYLTYPE *yyloc_param);
static void append_attr(AstNode *ast, dict<IdString, AstNode*> *al)
{
for (auto &it : *al) {
if (ast->attributes.count(it.first) > 0)
delete ast->attributes[it.first];
ast->attributes[it.first] = it.second;
}
delete al;
}
static void append_attr_clone(AstNode *ast, dict<IdString, AstNode*> *al)
{
for (auto &it : *al) {
if (ast->attributes.count(it.first) > 0)
delete ast->attributes[it.first];
ast->attributes[it.first] = it.second->clone();
}
}
static void free_attr(dict<IdString, AstNode*> *al)
{
for (auto &it : *al)
delete it.second;
delete al;
}
struct specify_target {
char polarity_op;
AstNode *dst, *dat;
};
struct specify_triple {
AstNode *t_min, *t_avg, *t_max;
};
struct specify_rise_fall {
specify_triple rise;
specify_triple fall;
};
static void addWiretypeNode(std::string *name, AstNode *node)
{
log_assert(node);
node->is_custom_type = true;
node->children.push_back(new AstNode(AST_WIRETYPE));
node->children.back()->str = *name;
delete name;
}
static void addTypedefNode(std::string *name, AstNode *node)
{
log_assert(node);
auto *tnode = new AstNode(AST_TYPEDEF, node);
tnode->str = *name;
auto &user_types = user_type_stack.back();
user_types[*name] = tnode;
if (current_ast_mod && current_ast_mod->type == AST_PACKAGE) {
// typedef inside a package so we need the qualified name
auto qname = current_ast_mod->str + "::" + (*name).substr(1);
pkg_user_types[qname] = tnode;
}
delete name;
ast_stack.back()->children.push_back(tnode);
}
static void enterTypeScope()
{
user_type_stack.push_back(UserTypeMap());
}
static void exitTypeScope()
{
user_type_stack.pop_back();
}
static bool isInLocalScope(const std::string *name)
{
// tests if a name was declared in the current block scope
auto &user_types = user_type_stack.back();
return (user_types.count(*name) > 0);
}
static AstNode *getTypeDefinitionNode(std::string type_name)
{
// check current scope then outer scopes for a name
for (auto it = user_type_stack.rbegin(); it != user_type_stack.rend(); ++it) {
if (it->count(type_name) > 0) {
// return the definition nodes from the typedef statement
auto typedef_node = (*it)[type_name];
log_assert(typedef_node->type == AST_TYPEDEF);
return typedef_node->children[0];
}
}
// The lexer recognized the name as a TOK_USER_TYPE, but now we can't find it anymore?
log_error("typedef for user type `%s' not found", type_name.c_str());
}
static AstNode *copyTypeDefinition(std::string type_name)
{
// return a copy of the template from a typedef definition
auto typedef_node = getTypeDefinitionNode(type_name);
return typedef_node->clone();
}
static AstNode *makeRange(int msb = 31, int lsb = 0, bool isSigned = true)
{
auto range = new AstNode(AST_RANGE);
range->children.push_back(AstNode::mkconst_int(msb, true));
range->children.push_back(AstNode::mkconst_int(lsb, true));
range->is_signed = isSigned;
return range;
}
static void addRange(AstNode *parent, int msb = 31, int lsb = 0, bool isSigned = true)
{
auto range = makeRange(msb, lsb, isSigned);
parent->children.push_back(range);
}
static AstNode *checkRange(AstNode *type_node, AstNode *range_node)
{
if (type_node->range_left >= 0 && type_node->range_right >= 0) {
// type already restricts the range
if (range_node) {
frontend_verilog_yyerror("integer/genvar types cannot have packed dimensions.");
}
else {
range_node = makeRange(type_node->range_left, type_node->range_right, false);
}
}
if (range_node && range_node->children.size() != 2) {
frontend_verilog_yyerror("wire/reg/logic packed dimension must be of the form: [<expr>:<expr>], [<expr>+:<expr>], or [<expr>-:<expr>]");
}
return range_node;
}
static void rewriteRange(AstNode *rangeNode)
{
if (rangeNode->type == AST_RANGE && rangeNode->children.size() == 1) {
// SV array size [n], rewrite as [0:n-1]
rangeNode->children.push_back(new AstNode(AST_SUB, rangeNode->children[0], AstNode::mkconst_int(1, true)));
rangeNode->children[0] = AstNode::mkconst_int(0, false);
}
}
static void rewriteAsMemoryNode(AstNode *node, AstNode *rangeNode)
{
node->type = AST_MEMORY;
if (rangeNode->type == AST_MULTIRANGE) {
for (auto *itr : rangeNode->children)
rewriteRange(itr);
} else
rewriteRange(rangeNode);
node->children.push_back(rangeNode);
}
static void checkLabelsMatch(const char *element, const std::string *before, const std::string *after)
{
if (!before && after)
frontend_verilog_yyerror("%s missing where end label (%s) was given.",
element, after->c_str() + 1);
if (before && after && *before != *after)
frontend_verilog_yyerror("%s (%s) and end label (%s) don't match.",
element, before->c_str() + 1, after->c_str() + 1);
}
// This transforms a loop like
// for (genvar i = 0; i < 10; i++) begin : blk
// to
// genvar _i;
// for (_i = 0; _i < 10; _i++) begin : blk
// localparam i = _i;
// where `_i` is actually some auto-generated name.
static void rewriteGenForDeclInit(AstNode *loop)
{
// check if this generate for loop contains an inline declaration
log_assert(loop->type == AST_GENFOR);
AstNode *decl = loop->children[0];
if (decl->type == AST_ASSIGN_EQ)
return;
log_assert(decl->type == AST_GENVAR);
log_assert(loop->children.size() == 5);
// identify each component of the loop
AstNode *init = loop->children[1];
AstNode *cond = loop->children[2];
AstNode *incr = loop->children[3];
AstNode *body = loop->children[4];
log_assert(init->type == AST_ASSIGN_EQ);
log_assert(incr->type == AST_ASSIGN_EQ);
log_assert(body->type == AST_GENBLOCK);
// create a unique name for the genvar
std::string old_str = decl->str;
std::string new_str = stringf("$genfordecl$%d$%s", autoidx++, old_str.c_str());
// rename and move the genvar declaration to the containing description
decl->str = new_str;
loop->children.erase(loop->children.begin());
log_assert(current_ast_mod != nullptr);
current_ast_mod->children.push_back(decl);
// create a new localparam with old name so that the items in the loop
// can simply use the old name and shadow it as necessary
AstNode *indirect = new AstNode(AST_LOCALPARAM);
indirect->str = old_str;
AstNode *ident = new AstNode(AST_IDENTIFIER);
ident->str = new_str;
indirect->children.push_back(ident);
body->children.insert(body->children.begin(), indirect);
// only perform the renaming for the initialization, guard, and
// incrementation to enable proper shadowing of the synthetic localparam
std::function<void(AstNode*)> substitute = [&](AstNode *node) {
if (node->type == AST_IDENTIFIER && node->str == old_str)
node->str = new_str;
for (AstNode *child : node->children)
substitute(child);
};
substitute(init);
substitute(cond);
substitute(incr);
}
%}
%define api.prefix {frontend_verilog_yy}
%define api.pure
/* The union is defined in the header, so we need to provide all the
* includes it requires
*/
%code requires {
#include <map>
#include <string>
#include "frontends/verilog/verilog_frontend.h"
}
%union {
std::string *string;
struct YOSYS_NAMESPACE_PREFIX AST::AstNode *ast;
YOSYS_NAMESPACE_PREFIX dict<YOSYS_NAMESPACE_PREFIX RTLIL::IdString, YOSYS_NAMESPACE_PREFIX AST::AstNode*> *al;
struct specify_target *specify_target_ptr;
struct specify_triple *specify_triple_ptr;
struct specify_rise_fall *specify_rise_fall_ptr;
bool boolean;
char ch;
int integer;
YOSYS_NAMESPACE_PREFIX AST::AstNodeType ast_node_type;
}
%token <string> TOK_STRING TOK_ID TOK_CONSTVAL TOK_REALVAL TOK_PRIMITIVE
%token <string> TOK_SVA_LABEL TOK_SPECIFY_OPER TOK_MSG_TASKS
%token <string> TOK_BASE TOK_BASED_CONSTVAL TOK_UNBASED_UNSIZED_CONSTVAL
%token <string> TOK_USER_TYPE TOK_PKG_USER_TYPE
%token TOK_ASSERT TOK_ASSUME TOK_RESTRICT TOK_COVER TOK_FINAL
%token ATTR_BEGIN ATTR_END DEFATTR_BEGIN DEFATTR_END
%token TOK_MODULE TOK_ENDMODULE TOK_PARAMETER TOK_LOCALPARAM TOK_DEFPARAM
%token TOK_PACKAGE TOK_ENDPACKAGE TOK_PACKAGESEP
%token TOK_INTERFACE TOK_ENDINTERFACE TOK_MODPORT TOK_VAR TOK_WILDCARD_CONNECT
%token TOK_INPUT TOK_OUTPUT TOK_INOUT TOK_WIRE TOK_WAND TOK_WOR TOK_REG TOK_LOGIC
%token TOK_INTEGER TOK_SIGNED TOK_ASSIGN TOK_ALWAYS TOK_INITIAL
%token TOK_ALWAYS_FF TOK_ALWAYS_COMB TOK_ALWAYS_LATCH
%token TOK_BEGIN TOK_END TOK_IF TOK_ELSE TOK_FOR TOK_WHILE TOK_REPEAT
%token TOK_DPI_FUNCTION TOK_POSEDGE TOK_NEGEDGE TOK_OR TOK_AUTOMATIC
%token TOK_CASE TOK_CASEX TOK_CASEZ TOK_ENDCASE TOK_DEFAULT
%token TOK_FUNCTION TOK_ENDFUNCTION TOK_TASK TOK_ENDTASK TOK_SPECIFY
%token TOK_IGNORED_SPECIFY TOK_ENDSPECIFY TOK_SPECPARAM TOK_SPECIFY_AND TOK_IGNORED_SPECIFY_AND
%token TOK_GENERATE TOK_ENDGENERATE TOK_GENVAR TOK_REAL
%token TOK_SYNOPSYS_FULL_CASE TOK_SYNOPSYS_PARALLEL_CASE
%token TOK_SUPPLY0 TOK_SUPPLY1 TOK_TO_SIGNED TOK_TO_UNSIGNED
%token TOK_POS_INDEXED TOK_NEG_INDEXED TOK_PROPERTY TOK_ENUM TOK_TYPEDEF
%token TOK_RAND TOK_CONST TOK_CHECKER TOK_ENDCHECKER TOK_EVENTUALLY
%token TOK_INCREMENT TOK_DECREMENT TOK_UNIQUE TOK_UNIQUE0 TOK_PRIORITY
%token TOK_STRUCT TOK_PACKED TOK_UNSIGNED TOK_INT TOK_BYTE TOK_SHORTINT TOK_LONGINT TOK_UNION
%token TOK_BIT_OR_ASSIGN TOK_BIT_AND_ASSIGN TOK_BIT_XOR_ASSIGN TOK_ADD_ASSIGN
%token TOK_SUB_ASSIGN TOK_DIV_ASSIGN TOK_MOD_ASSIGN TOK_MUL_ASSIGN
%token TOK_SHL_ASSIGN TOK_SHR_ASSIGN TOK_SSHL_ASSIGN TOK_SSHR_ASSIGN
%token TOK_BIND TOK_TIME_SCALE
%type <ast> range range_or_multirange non_opt_range non_opt_multirange
%type <ast> wire_type expr basic_expr concat_list rvalue lvalue lvalue_concat_list non_io_wire_type io_wire_type
%type <string> opt_label opt_sva_label tok_prim_wrapper hierarchical_id hierarchical_type_id integral_number
%type <string> type_name
%type <ast> opt_enum_init enum_type struct_type enum_struct_type func_return_type typedef_base_type
%type <boolean> opt_property always_comb_or_latch always_or_always_ff
%type <boolean> opt_signedness_default_signed opt_signedness_default_unsigned
%type <integer> integer_atom_type integer_vector_type
%type <al> attr case_attr
%type <ast> struct_union
%type <ast_node_type> asgn_binop
%type <ast> genvar_identifier
%type <specify_target_ptr> specify_target
%type <specify_triple_ptr> specify_triple specify_opt_triple
%type <specify_rise_fall_ptr> specify_rise_fall
%type <ast> specify_if specify_condition
%type <ch> specify_edge
// operator precedence from low to high
%left OP_LOR
%left OP_LAND
%left '|' OP_NOR
%left '^' OP_XNOR
%left '&' OP_NAND
%left OP_EQ OP_NE OP_EQX OP_NEX
%left '<' OP_LE OP_GE '>'
%left OP_SHL OP_SHR OP_SSHL OP_SSHR
%left '+' '-'
%left '*' '/' '%'
%left OP_POW
%precedence OP_CAST
%precedence UNARY_OPS
%define parse.error verbose
%define parse.lac full
%precedence FAKE_THEN
%precedence TOK_ELSE
%debug
%locations
%%
input: {
ast_stack.clear();
ast_stack.push_back(current_ast);
} design {
ast_stack.pop_back();
log_assert(GetSize(ast_stack) == 0);
for (auto &it : default_attr_list)
delete it.second;
default_attr_list.clear();
};
design:
module design |
defattr design |
task_func_decl design |
param_decl design |
localparam_decl design |
typedef_decl design |
package design |
interface design |
bind_directive design |
%empty;
attr:
{
if (attr_list != nullptr)
attr_list_stack.push(attr_list);
attr_list = new dict<IdString, AstNode*>;
for (auto &it : default_attr_list)
(*attr_list)[it.first] = it.second->clone();
} attr_opt {
$$ = attr_list;
if (!attr_list_stack.empty()) {
attr_list = attr_list_stack.top();
attr_list_stack.pop();
} else
attr_list = nullptr;
};
attr_opt:
attr_opt ATTR_BEGIN opt_attr_list ATTR_END {
SET_RULE_LOC(@$, @2, @$);
}|
%empty;
defattr:
DEFATTR_BEGIN {
if (attr_list != nullptr)
attr_list_stack.push(attr_list);
attr_list = new dict<IdString, AstNode*>;
for (auto &it : default_attr_list)
delete it.second;
default_attr_list.clear();
} opt_attr_list {
attr_list->swap(default_attr_list);
delete attr_list;
if (!attr_list_stack.empty()) {
attr_list = attr_list_stack.top();
attr_list_stack.pop();
} else
attr_list = nullptr;
} DEFATTR_END;
opt_attr_list:
attr_list | %empty;
attr_list:
attr_assign |
attr_list ',' attr_assign;
attr_assign:
hierarchical_id {
if (attr_list->count(*$1) != 0)
delete (*attr_list)[*$1];
(*attr_list)[*$1] = AstNode::mkconst_int(1, false);
delete $1;
} |
hierarchical_id '=' expr {
if (attr_list->count(*$1) != 0)
delete (*attr_list)[*$1];
(*attr_list)[*$1] = $3;
delete $1;
};
hierarchical_id:
TOK_ID {
$$ = $1;
} |
hierarchical_id TOK_PACKAGESEP TOK_ID {
if ($3->compare(0, 1, "\\") == 0)
*$1 += "::" + $3->substr(1);
else
*$1 += "::" + *$3;
delete $3;
$$ = $1;
} |
hierarchical_id '.' TOK_ID {
if ($3->compare(0, 1, "\\") == 0)
*$1 += "." + $3->substr(1);
else
*$1 += "." + *$3;
delete $3;
$$ = $1;
};
hierarchical_type_id:
TOK_USER_TYPE
| TOK_PKG_USER_TYPE // package qualified type name
| '(' TOK_USER_TYPE ')' { $$ = $2; } // non-standard grammar
;
module:
attr TOK_MODULE {
enterTypeScope();
} TOK_ID {
do_not_require_port_stubs = false;
AstNode *mod = new AstNode(AST_MODULE);
ast_stack.back()->children.push_back(mod);
ast_stack.push_back(mod);
current_ast_mod = mod;
port_stubs.clear();
port_counter = 0;
mod->str = *$4;
append_attr(mod, $1);
} module_para_opt module_args_opt ';' module_body TOK_ENDMODULE opt_label {
if (port_stubs.size() != 0)
frontend_verilog_yyerror("Missing details for module port `%s'.",
port_stubs.begin()->first.c_str());
SET_AST_NODE_LOC(ast_stack.back(), @2, @$);
ast_stack.pop_back();
log_assert(ast_stack.size() == 1);
checkLabelsMatch("Module name", $4, $11);
current_ast_mod = NULL;
delete $4;
delete $11;
exitTypeScope();
};
module_para_opt:
'#' '(' { astbuf1 = nullptr; } module_para_list { if (astbuf1) delete astbuf1; } ')' | %empty;
module_para_list:
single_module_para | module_para_list ',' single_module_para;
single_module_para:
%empty |
attr TOK_PARAMETER {
if (astbuf1) delete astbuf1;
astbuf1 = new AstNode(AST_PARAMETER);
astbuf1->children.push_back(AstNode::mkconst_int(0, true));
append_attr(astbuf1, $1);
} param_type single_param_decl |
attr TOK_LOCALPARAM {
if (astbuf1) delete astbuf1;
astbuf1 = new AstNode(AST_LOCALPARAM);
astbuf1->children.push_back(AstNode::mkconst_int(0, true));
append_attr(astbuf1, $1);
} param_type single_param_decl |
single_param_decl;
module_args_opt:
'(' ')' | %empty | '(' module_args optional_comma ')';
module_args:
module_arg | module_args ',' module_arg;
optional_comma:
',' | %empty;
module_arg_opt_assignment:
'=' expr {
if (ast_stack.back()->children.size() > 0 && ast_stack.back()->children.back()->type == AST_WIRE) {
if (ast_stack.back()->children.back()->is_input) {
AstNode *n = ast_stack.back()->children.back();
if (n->attributes.count(ID::defaultvalue))
delete n->attributes.at(ID::defaultvalue);
n->attributes[ID::defaultvalue] = $2;
} else {
AstNode *wire = new AstNode(AST_IDENTIFIER);
wire->str = ast_stack.back()->children.back()->str;
if (ast_stack.back()->children.back()->is_reg || ast_stack.back()->children.back()->is_logic)
ast_stack.back()->children.push_back(new AstNode(AST_INITIAL, new AstNode(AST_BLOCK, new AstNode(AST_ASSIGN_LE, wire, $2))));
else
ast_stack.back()->children.push_back(new AstNode(AST_ASSIGN, wire, $2));
}
} else
frontend_verilog_yyerror("SystemVerilog interface in module port list cannot have a default value.");
} |
%empty;
module_arg:
TOK_ID {
if (ast_stack.back()->children.size() > 0 && ast_stack.back()->children.back()->type == AST_WIRE) {
AstNode *node = ast_stack.back()->children.back()->clone();
node->str = *$1;
node->port_id = ++port_counter;
ast_stack.back()->children.push_back(node);
SET_AST_NODE_LOC(node, @1, @1);
} else {
if (port_stubs.count(*$1) != 0)
frontend_verilog_yyerror("Duplicate module port `%s'.", $1->c_str());
port_stubs[*$1] = ++port_counter;
}
delete $1;
} module_arg_opt_assignment |
TOK_ID {
astbuf1 = new AstNode(AST_INTERFACEPORT);
astbuf1->children.push_back(new AstNode(AST_INTERFACEPORTTYPE));
astbuf1->children[0]->str = *$1;
delete $1;
} TOK_ID { /* SV interfaces */
if (!sv_mode)
frontend_verilog_yyerror("Interface found in port list (%s). This is not supported unless read_verilog is called with -sv!", $3->c_str());
astbuf2 = astbuf1->clone(); // really only needed if multiple instances of same type.
astbuf2->str = *$3;
delete $3;
astbuf2->port_id = ++port_counter;
ast_stack.back()->children.push_back(astbuf2);
delete astbuf1; // really only needed if multiple instances of same type.
} module_arg_opt_assignment |
attr wire_type range TOK_ID {
AstNode *node = $2;
node->str = *$4;
SET_AST_NODE_LOC(node, @4, @4);
node->port_id = ++port_counter;
AstNode *range = checkRange(node, $3);
if (range != NULL)
node->children.push_back(range);
if (!node->is_input && !node->is_output)
frontend_verilog_yyerror("Module port `%s' is neither input nor output.", $4->c_str());
if (node->is_reg && node->is_input && !node->is_output && !sv_mode)
frontend_verilog_yyerror("Input port `%s' is declared as register.", $4->c_str());
ast_stack.back()->children.push_back(node);
append_attr(node, $1);
delete $4;
} module_arg_opt_assignment |
'.' '.' '.' {
do_not_require_port_stubs = true;
};
package:
attr TOK_PACKAGE {
enterTypeScope();
} TOK_ID {
AstNode *mod = new AstNode(AST_PACKAGE);
ast_stack.back()->children.push_back(mod);
ast_stack.push_back(mod);
current_ast_mod = mod;
mod->str = *$4;
append_attr(mod, $1);
} ';' package_body TOK_ENDPACKAGE opt_label {
ast_stack.pop_back();
checkLabelsMatch("Package name", $4, $9);
current_ast_mod = NULL;
delete $4;
delete $9;
exitTypeScope();
};
package_body:
package_body package_body_stmt | %empty;
package_body_stmt:
typedef_decl | localparam_decl | param_decl | task_func_decl;
interface:
TOK_INTERFACE {
enterTypeScope();
} TOK_ID {
do_not_require_port_stubs = false;
AstNode *intf = new AstNode(AST_INTERFACE);
ast_stack.back()->children.push_back(intf);
ast_stack.push_back(intf);
current_ast_mod = intf;
port_stubs.clear();
port_counter = 0;
intf->str = *$3;
delete $3;
} module_para_opt module_args_opt ';' interface_body TOK_ENDINTERFACE {
if (port_stubs.size() != 0)
frontend_verilog_yyerror("Missing details for module port `%s'.",
port_stubs.begin()->first.c_str());
ast_stack.pop_back();
log_assert(ast_stack.size() == 1);
current_ast_mod = NULL;
exitTypeScope();
};
interface_body:
interface_body interface_body_stmt | %empty;
interface_body_stmt:
param_decl | localparam_decl | typedef_decl | defparam_decl | wire_decl | always_stmt | assign_stmt |
modport_stmt | bind_directive;
bind_directive:
TOK_BIND {
AstNode *bnode = new AstNode(AST_BIND);
ast_stack.back()->children.push_back(bnode);
ast_stack.push_back(bnode);
}
bind_target {
// bind_target should have added at least one child
log_assert(ast_stack.back()->children.size() >= 1);
}
TOK_ID {
// The single_cell parser in cell_list_no_array uses astbuf1 as
// a sort of template for constructing cells.
astbuf1 = new AstNode(AST_CELL);
astbuf1->children.push_back(new AstNode(AST_CELLTYPE));
astbuf1->children[0]->str = *$5;
delete $5;
}
cell_parameter_list_opt cell_list_no_array ';' {
// cell_list should have added at least one more child
log_assert(ast_stack.back()->children.size() >= 2);
delete astbuf1;
ast_stack.pop_back();
};
// bind_target matches the target of the bind (everything before
// bind_instantiation in the IEEE 1800 spec).
//
// We can't use the BNF from the spec directly because it's ambiguous:
// something like "bind foo bar_i (.*)" can either be interpreted with "foo" as
// a module or interface identifier (matching bind_target_scope in the spec) or
// by considering foo as a degenerate hierarchical identifier with no '.'
// characters, followed by no bit select (which matches bind_target_instance in
// the spec).
//
// Instead, we resolve everything as an instance name and then deal with the
// ambiguity when converting to RTLIL / in the hierarchy pass.
bind_target:
bind_target_instance opt_bind_target_instance_list;
// An optional list of target instances for a bind statement, introduced by a
// colon.
opt_bind_target_instance_list:
':' bind_target_instance_list |
%empty;
bind_target_instance_list:
bind_target_instance |
bind_target_instance_list ',' bind_target_instance;
// A single target instance for a bind statement. The top of ast_stack will be
// the bind node where we should add it.
bind_target_instance:
hierarchical_id {
auto *node = new AstNode(AST_IDENTIFIER);
node->str = *$1;
delete $1;
ast_stack.back()->children.push_back(node);
};
mintypmax_expr:
expr { delete $1; } |
expr ':' expr ':' expr { delete $1; delete $3; delete $5; };
non_opt_delay:
'#' TOK_ID { delete $2; } |
'#' TOK_CONSTVAL { delete $2; } |
'#' TOK_REALVAL { delete $2; } |
// our `expr` doesn't have time_scale, so we need the parenthesized variant
'#' TOK_TIME_SCALE |
'#' '(' TOK_TIME_SCALE ')' |
'#' '(' mintypmax_expr ')' |
'#' '(' mintypmax_expr ',' mintypmax_expr ')' |
'#' '(' mintypmax_expr ',' mintypmax_expr ',' mintypmax_expr ')';
delay:
non_opt_delay | %empty;
io_wire_type:
{ astbuf3 = new AstNode(AST_WIRE); current_wire_rand = false; current_wire_const = false; }
wire_type_token_io wire_type_const_rand opt_wire_type_token wire_type_signedness
{ $$ = astbuf3; SET_RULE_LOC(@$, @2, @$); };
non_io_wire_type:
{ astbuf3 = new AstNode(AST_WIRE); current_wire_rand = false; current_wire_const = false; }
wire_type_const_rand wire_type_token wire_type_signedness
{ $$ = astbuf3; SET_RULE_LOC(@$, @2, @$); };
wire_type:
io_wire_type |
non_io_wire_type;
wire_type_token_io:
TOK_INPUT {
astbuf3->is_input = true;
} |
TOK_OUTPUT {
astbuf3->is_output = true;
} |
TOK_INOUT {
astbuf3->is_input = true;
astbuf3->is_output = true;
};
wire_type_signedness:
TOK_SIGNED { astbuf3->is_signed = true; } |
TOK_UNSIGNED { astbuf3->is_signed = false; } |
%empty;
wire_type_const_rand:
TOK_RAND TOK_CONST {
current_wire_rand = true;
current_wire_const = true;
} |
TOK_CONST {
current_wire_const = true;
} |
TOK_RAND {
current_wire_rand = true;
} |
%empty;
opt_wire_type_token:
wire_type_token | %empty;
wire_type_token:
// nets
net_type {
} |
net_type logic_type {
} |
// regs
TOK_REG {
astbuf3->is_reg = true;
} |
TOK_VAR TOK_REG {
astbuf3->is_reg = true;
} |
// logics
TOK_VAR {
astbuf3->is_logic = true;
} |
TOK_VAR logic_type {
astbuf3->is_logic = true;
} |
logic_type {
astbuf3->is_logic = true;
} |
TOK_GENVAR {
astbuf3->type = AST_GENVAR;
astbuf3->is_reg = true;
astbuf3->is_signed = true;
astbuf3->range_left = 31;
astbuf3->range_right = 0;
};
net_type:
TOK_WOR {
astbuf3->is_wor = true;
} |
TOK_WAND {
astbuf3->is_wand = true;
} |
TOK_WIRE;
logic_type:
TOK_LOGIC {
} |
integer_atom_type {
astbuf3->range_left = $1 - 1;
astbuf3->range_right = 0;
astbuf3->is_signed = true;
} |
hierarchical_type_id {
addWiretypeNode($1, astbuf3);
};
integer_atom_type:
TOK_INTEGER { $$ = 32; } |
TOK_INT { $$ = 32; } |
TOK_SHORTINT { $$ = 16; } |
TOK_LONGINT { $$ = 64; } |
TOK_BYTE { $$ = 8; } ;
integer_vector_type:
TOK_LOGIC { $$ = TOK_LOGIC; } |
TOK_REG { $$ = TOK_REG; } ;
non_opt_range:
'[' expr ':' expr ']' {
$$ = new AstNode(AST_RANGE);
$$->children.push_back($2);
$$->children.push_back($4);
} |
'[' expr TOK_POS_INDEXED expr ']' {
$$ = new AstNode(AST_RANGE);
AstNode *expr = new AstNode(AST_SELFSZ, $2);
$$->children.push_back(new AstNode(AST_SUB, new AstNode(AST_ADD, expr->clone(), $4), AstNode::mkconst_int(1, true)));
$$->children.push_back(new AstNode(AST_ADD, expr, AstNode::mkconst_int(0, true)));
} |
'[' expr TOK_NEG_INDEXED expr ']' {
$$ = new AstNode(AST_RANGE);
AstNode *expr = new AstNode(AST_SELFSZ, $2);
$$->children.push_back(new AstNode(AST_ADD, expr, AstNode::mkconst_int(0, true)));
$$->children.push_back(new AstNode(AST_SUB, new AstNode(AST_ADD, expr->clone(), AstNode::mkconst_int(1, true)), $4));
} |
'[' expr ']' {
$$ = new AstNode(AST_RANGE);
$$->children.push_back($2);
};
non_opt_multirange:
non_opt_range non_opt_range {
$$ = new AstNode(AST_MULTIRANGE, $1, $2);
} |
non_opt_multirange non_opt_range {
$$ = $1;
$$->children.push_back($2);
};
range:
non_opt_range {
$$ = $1;
} |
%empty {
$$ = NULL;
};
range_or_multirange:
range { $$ = $1; } |
non_opt_multirange { $$ = $1; };
module_body:
module_body module_body_stmt |
/* the following line makes the generate..endgenrate keywords optional */
module_body gen_stmt |
module_body gen_block |
module_body ';' |
%empty;
module_body_stmt:
task_func_decl | specify_block | param_decl | localparam_decl | typedef_decl | defparam_decl | specparam_declaration | wire_decl | assign_stmt | cell_stmt |
enum_decl | struct_decl | bind_directive |
always_stmt | TOK_GENERATE module_gen_body TOK_ENDGENERATE | defattr | assert_property | checker_decl | ignored_specify_block;
checker_decl:
TOK_CHECKER TOK_ID ';' {
AstNode *node = new AstNode(AST_GENBLOCK);
node->str = *$2;
ast_stack.back()->children.push_back(node);
ast_stack.push_back(node);
} module_body TOK_ENDCHECKER {
delete $2;
ast_stack.pop_back();
};
task_func_decl:
attr TOK_DPI_FUNCTION TOK_ID TOK_ID {
current_function_or_task = new AstNode(AST_DPI_FUNCTION, AstNode::mkconst_str(*$3), AstNode::mkconst_str(*$4));
current_function_or_task->str = *$4;
append_attr(current_function_or_task, $1);
ast_stack.back()->children.push_back(current_function_or_task);
delete $3;
delete $4;
} opt_dpi_function_args ';' {
current_function_or_task = NULL;
} |
attr TOK_DPI_FUNCTION TOK_ID '=' TOK_ID TOK_ID {
current_function_or_task = new AstNode(AST_DPI_FUNCTION, AstNode::mkconst_str(*$5), AstNode::mkconst_str(*$3));
current_function_or_task->str = *$6;
append_attr(current_function_or_task, $1);
ast_stack.back()->children.push_back(current_function_or_task);
delete $3;
delete $5;
delete $6;
} opt_dpi_function_args ';' {
current_function_or_task = NULL;
} |
attr TOK_DPI_FUNCTION TOK_ID ':' TOK_ID '=' TOK_ID TOK_ID {
current_function_or_task = new AstNode(AST_DPI_FUNCTION, AstNode::mkconst_str(*$7), AstNode::mkconst_str(*$3 + ":" + RTLIL::unescape_id(*$5)));
current_function_or_task->str = *$8;
append_attr(current_function_or_task, $1);
ast_stack.back()->children.push_back(current_function_or_task);
delete $3;
delete $5;
delete $7;
delete $8;
} opt_dpi_function_args ';' {
current_function_or_task = NULL;
} |
attr TOK_TASK opt_automatic TOK_ID {
current_function_or_task = new AstNode(AST_TASK);
current_function_or_task->str = *$4;
append_attr(current_function_or_task, $1);
ast_stack.back()->children.push_back(current_function_or_task);
ast_stack.push_back(current_function_or_task);
current_function_or_task_port_id = 1;
delete $4;
} task_func_args_opt ';' task_func_body TOK_ENDTASK {
current_function_or_task = NULL;
ast_stack.pop_back();
} |
attr TOK_FUNCTION opt_automatic func_return_type TOK_ID {
current_function_or_task = new AstNode(AST_FUNCTION);
current_function_or_task->str = *$5;
append_attr(current_function_or_task, $1);
ast_stack.back()->children.push_back(current_function_or_task);
ast_stack.push_back(current_function_or_task);
AstNode *outreg = new AstNode(AST_WIRE);
outreg->str = *$5;
outreg->is_signed = false;
outreg->is_reg = true;
if ($4 != NULL) {
outreg->children.push_back($4);
outreg->is_signed = $4->is_signed;
$4->is_signed = false;
outreg->is_custom_type = $4->type == AST_WIRETYPE;
}
current_function_or_task->children.push_back(outreg);
current_function_or_task_port_id = 1;
delete $5;
} task_func_args_opt ';' task_func_body TOK_ENDFUNCTION {
current_function_or_task = NULL;
ast_stack.pop_back();
};
func_return_type:
hierarchical_type_id {
$$ = new AstNode(AST_WIRETYPE);
$$->str = *$1;
delete $1;
} |
opt_type_vec opt_signedness_default_unsigned {
$$ = makeRange(0, 0, $2);
} |
opt_type_vec opt_signedness_default_unsigned non_opt_range {
$$ = $3;
$$->is_signed = $2;
} |
integer_atom_type opt_signedness_default_signed {
$$ = makeRange($1 - 1, 0, $2);
};
opt_type_vec:
%empty
| TOK_REG
| TOK_LOGIC
;
opt_signedness_default_signed:
%empty { $$ = true; }
| TOK_SIGNED { $$ = true; }
| TOK_UNSIGNED { $$ = false; }
;
opt_signedness_default_unsigned:
%empty { $$ = false; }
| TOK_SIGNED { $$ = true; }
| TOK_UNSIGNED { $$ = false; }
;
dpi_function_arg:
TOK_ID TOK_ID {
current_function_or_task->children.push_back(AstNode::mkconst_str(*$1));
delete $1;
delete $2;
} |
TOK_ID {
current_function_or_task->children.push_back(AstNode::mkconst_str(*$1));
delete $1;
};
opt_dpi_function_args:
'(' dpi_function_args ')' |
%empty;
dpi_function_args:
dpi_function_args ',' dpi_function_arg |
dpi_function_args ',' |
dpi_function_arg |
%empty;
opt_automatic:
TOK_AUTOMATIC |
%empty;
task_func_args_opt:
'(' ')' | %empty | '(' {
albuf = nullptr;
astbuf1 = nullptr;
astbuf2 = nullptr;
} task_func_args optional_comma {
delete astbuf1;
if (astbuf2 != NULL)
delete astbuf2;
free_attr(albuf);
} ')';
task_func_args:
task_func_port | task_func_args ',' task_func_port;
task_func_port:
attr wire_type range {
bool prev_was_input = true;
bool prev_was_output = false;
if (albuf) {
prev_was_input = astbuf1->is_input;
prev_was_output = astbuf1->is_output;
delete astbuf1;
if (astbuf2 != NULL)
delete astbuf2;
free_attr(albuf);
}
albuf = $1;
astbuf1 = $2;
astbuf2 = checkRange(astbuf1, $3);
if (!astbuf1->is_input && !astbuf1->is_output) {
if (!sv_mode)
frontend_verilog_yyerror("task/function argument direction missing");
astbuf1->is_input = prev_was_input;
astbuf1->is_output = prev_was_output;
}
} wire_name |
{
if (!astbuf1) {
if (!sv_mode)
frontend_verilog_yyerror("task/function argument direction missing");
albuf = new dict<IdString, AstNode*>;
astbuf1 = new AstNode(AST_WIRE);
current_wire_rand = false;
current_wire_const = false;
astbuf1->is_input = true;
astbuf2 = NULL;
}
} wire_name;
task_func_body:
task_func_body behavioral_stmt |
%empty;
/*************************** specify parser ***************************/
specify_block:
TOK_SPECIFY specify_item_list TOK_ENDSPECIFY;
specify_item_list:
specify_item specify_item_list |
%empty;
specify_item:
specify_if '(' specify_edge expr TOK_SPECIFY_OPER specify_target ')' '=' specify_rise_fall ';' {
AstNode *en_expr = $1;
char specify_edge = $3;
AstNode *src_expr = $4;
string *oper = $5;
specify_target *target = $6;
specify_rise_fall *timing = $9;
if (specify_edge != 0 && target->dat == nullptr)
frontend_verilog_yyerror("Found specify edge but no data spec.\n");
AstNode *cell = new AstNode(AST_CELL);
ast_stack.back()->children.push_back(cell);
cell->str = stringf("$specify$%d", autoidx++);
cell->children.push_back(new AstNode(AST_CELLTYPE));
cell->children.back()->str = target->dat ? "$specify3" : "$specify2";
SET_AST_NODE_LOC(cell, en_expr ? @1 : @2, @10);
char oper_polarity = 0;
char oper_type = oper->at(0);
if (oper->size() == 3) {
oper_polarity = oper->at(0);
oper_type = oper->at(1);
}
cell->children.push_back(new AstNode(AST_PARASET, AstNode::mkconst_int(oper_type == '*', false, 1)));
cell->children.back()->str = "\\FULL";
cell->children.push_back(new AstNode(AST_PARASET, AstNode::mkconst_int(oper_polarity != 0, false, 1)));
cell->children.back()->str = "\\SRC_DST_PEN";
cell->children.push_back(new AstNode(AST_PARASET, AstNode::mkconst_int(oper_polarity == '+', false, 1)));
cell->children.back()->str = "\\SRC_DST_POL";
cell->children.push_back(new AstNode(AST_PARASET, timing->rise.t_min));
cell->children.back()->str = "\\T_RISE_MIN";
cell->children.push_back(new AstNode(AST_PARASET, timing->rise.t_avg));
cell->children.back()->str = "\\T_RISE_TYP";
cell->children.push_back(new AstNode(AST_PARASET, timing->rise.t_max));
cell->children.back()->str = "\\T_RISE_MAX";
cell->children.push_back(new AstNode(AST_PARASET, timing->fall.t_min));
cell->children.back()->str = "\\T_FALL_MIN";
cell->children.push_back(new AstNode(AST_PARASET, timing->fall.t_avg));
cell->children.back()->str = "\\T_FALL_TYP";
cell->children.push_back(new AstNode(AST_PARASET, timing->fall.t_max));
cell->children.back()->str = "\\T_FALL_MAX";
cell->children.push_back(new AstNode(AST_ARGUMENT, en_expr ? en_expr : AstNode::mkconst_int(1, false, 1)));
cell->children.back()->str = "\\EN";
cell->children.push_back(new AstNode(AST_ARGUMENT, src_expr));
cell->children.back()->str = "\\SRC";
cell->children.push_back(new AstNode(AST_ARGUMENT, target->dst));
cell->children.back()->str = "\\DST";
if (target->dat)
{
cell->children.push_back(new AstNode(AST_PARASET, AstNode::mkconst_int(specify_edge != 0, false, 1)));
cell->children.back()->str = "\\EDGE_EN";
cell->children.push_back(new AstNode(AST_PARASET, AstNode::mkconst_int(specify_edge == 'p', false, 1)));
cell->children.back()->str = "\\EDGE_POL";
cell->children.push_back(new AstNode(AST_PARASET, AstNode::mkconst_int(target->polarity_op != 0, false, 1)));
cell->children.back()->str = "\\DAT_DST_PEN";
cell->children.push_back(new AstNode(AST_PARASET, AstNode::mkconst_int(target->polarity_op == '+', false, 1)));
cell->children.back()->str = "\\DAT_DST_POL";
cell->children.push_back(new AstNode(AST_ARGUMENT, target->dat));
cell->children.back()->str = "\\DAT";
}
delete oper;
delete target;
delete timing;
} |
TOK_ID '(' specify_edge expr specify_condition ',' specify_edge expr specify_condition ',' specify_triple specify_opt_triple ')' ';' {
if (*$1 != "$setup" && *$1 != "$hold" && *$1 != "$setuphold" && *$1 != "$removal" && *$1 != "$recovery" &&
*$1 != "$recrem" && *$1 != "$skew" && *$1 != "$timeskew" && *$1 != "$fullskew" && *$1 != "$nochange")
frontend_verilog_yyerror("Unsupported specify rule type: %s\n", $1->c_str());
AstNode *src_pen = AstNode::mkconst_int($3 != 0, false, 1);
AstNode *src_pol = AstNode::mkconst_int($3 == 'p', false, 1);
AstNode *src_expr = $4, *src_en = $5 ? $5 : AstNode::mkconst_int(1, false, 1);
AstNode *dst_pen = AstNode::mkconst_int($7 != 0, false, 1);
AstNode *dst_pol = AstNode::mkconst_int($7 == 'p', false, 1);
AstNode *dst_expr = $8, *dst_en = $9 ? $9 : AstNode::mkconst_int(1, false, 1);
specify_triple *limit = $11;
specify_triple *limit2 = $12;
AstNode *cell = new AstNode(AST_CELL);
ast_stack.back()->children.push_back(cell);
cell->str = stringf("$specify$%d", autoidx++);
cell->children.push_back(new AstNode(AST_CELLTYPE));
cell->children.back()->str = "$specrule";
SET_AST_NODE_LOC(cell, @1, @14);
cell->children.push_back(new AstNode(AST_PARASET, AstNode::mkconst_str(*$1)));
cell->children.back()->str = "\\TYPE";
cell->children.push_back(new AstNode(AST_PARASET, limit->t_min));
cell->children.back()->str = "\\T_LIMIT_MIN";
cell->children.push_back(new AstNode(AST_PARASET, limit->t_avg));
cell->children.back()->str = "\\T_LIMIT_TYP";
cell->children.push_back(new AstNode(AST_PARASET, limit->t_max));
cell->children.back()->str = "\\T_LIMIT_MAX";
cell->children.push_back(new AstNode(AST_PARASET, limit2 ? limit2->t_min : AstNode::mkconst_int(0, true)));
cell->children.back()->str = "\\T_LIMIT2_MIN";
cell->children.push_back(new AstNode(AST_PARASET, limit2 ? limit2->t_avg : AstNode::mkconst_int(0, true)));
cell->children.back()->str = "\\T_LIMIT2_TYP";
cell->children.push_back(new AstNode(AST_PARASET, limit2 ? limit2->t_max : AstNode::mkconst_int(0, true)));
cell->children.back()->str = "\\T_LIMIT2_MAX";
cell->children.push_back(new AstNode(AST_PARASET, src_pen));
cell->children.back()->str = "\\SRC_PEN";
cell->children.push_back(new AstNode(AST_PARASET, src_pol));
cell->children.back()->str = "\\SRC_POL";
cell->children.push_back(new AstNode(AST_PARASET, dst_pen));
cell->children.back()->str = "\\DST_PEN";
cell->children.push_back(new AstNode(AST_PARASET, dst_pol));
cell->children.back()->str = "\\DST_POL";
cell->children.push_back(new AstNode(AST_ARGUMENT, src_en));
cell->children.back()->str = "\\SRC_EN";
cell->children.push_back(new AstNode(AST_ARGUMENT, src_expr));
cell->children.back()->str = "\\SRC";
cell->children.push_back(new AstNode(AST_ARGUMENT, dst_en));
cell->children.back()->str = "\\DST_EN";
cell->children.push_back(new AstNode(AST_ARGUMENT, dst_expr));
cell->children.back()->str = "\\DST";
delete $1;
delete limit;
delete limit2;
};
specify_opt_triple:
',' specify_triple {
$$ = $2;
} |
%empty {
$$ = nullptr;
};
specify_if:
TOK_IF '(' expr ')' {
$$ = $3;
} |
%empty {
$$ = nullptr;
};
specify_condition:
TOK_SPECIFY_AND expr {
$$ = $2;
} |
%empty {
$$ = nullptr;
};
specify_target:
expr {
$$ = new specify_target;
$$->polarity_op = 0;
$$->dst = $1;
$$->dat = nullptr;
} |
'(' expr ':' expr ')'{
$$ = new specify_target;
$$->polarity_op = 0;
$$->dst = $2;
$$->dat = $4;
} |
'(' expr TOK_NEG_INDEXED expr ')'{
$$ = new specify_target;
$$->polarity_op = '-';
$$->dst = $2;
$$->dat = $4;
} |
'(' expr TOK_POS_INDEXED expr ')'{
$$ = new specify_target;
$$->polarity_op = '+';
$$->dst = $2;
$$->dat = $4;
};
specify_edge:
TOK_POSEDGE { $$ = 'p'; } |
TOK_NEGEDGE { $$ = 'n'; } |
%empty { $$ = 0; };
specify_rise_fall:
specify_triple {
$$ = new specify_rise_fall;
$$->rise = *$1;
$$->fall.t_min = $1->t_min->clone();
$$->fall.t_avg = $1->t_avg->clone();
$$->fall.t_max = $1->t_max->clone();
delete $1;
} |
'(' specify_triple ',' specify_triple ')' {
$$ = new specify_rise_fall;
$$->rise = *$2;
$$->fall = *$4;
delete $2;
delete $4;
} |
'(' specify_triple ',' specify_triple ',' specify_triple ')' {
$$ = new specify_rise_fall;
$$->rise = *$2;
$$->fall = *$4;
delete $2;
delete $4;
delete $6;
log_file_warning(current_filename, get_line_num(), "Path delay expressions beyond rise/fall not currently supported. Ignoring.\n");
} |
'(' specify_triple ',' specify_triple ',' specify_triple ',' specify_triple ',' specify_triple ',' specify_triple ')' {
$$ = new specify_rise_fall;
$$->rise = *$2;
$$->fall = *$4;
delete $2;
delete $4;
delete $6;
delete $8;
delete $10;
delete $12;
log_file_warning(current_filename, get_line_num(), "Path delay expressions beyond rise/fall not currently supported. Ignoring.\n");
} |
'(' specify_triple ',' specify_triple ',' specify_triple ',' specify_triple ',' specify_triple ',' specify_triple ',' specify_triple ',' specify_triple ',' specify_triple ',' specify_triple ',' specify_triple ',' specify_triple ')' {
$$ = new specify_rise_fall;
$$->rise = *$2;
$$->fall = *$4;
delete $2;
delete $4;
delete $6;
delete $8;
delete $10;
delete $12;
delete $14;
delete $16;
delete $18;
delete $20;
delete $22;
delete $24;
log_file_warning(current_filename, get_line_num(), "Path delay expressions beyond rise/fall not currently supported. Ignoring.\n");
}
specify_triple:
expr {
$$ = new specify_triple;
$$->t_min = $1;
$$->t_avg = $1->clone();
$$->t_max = $1->clone();
} |
expr ':' expr ':' expr {
$$ = new specify_triple;
$$->t_min = $1;
$$->t_avg = $3;
$$->t_max = $5;
};
/******************** ignored specify parser **************************/
ignored_specify_block:
TOK_IGNORED_SPECIFY ignored_specify_item_opt TOK_ENDSPECIFY |
TOK_IGNORED_SPECIFY TOK_ENDSPECIFY ;
ignored_specify_item_opt:
ignored_specify_item_opt ignored_specify_item |
ignored_specify_item ;
ignored_specify_item:
specparam_declaration
// | pulsestyle_declaration
// | showcancelled_declaration
| path_declaration
| system_timing_declaration
;
specparam_declaration:
TOK_SPECPARAM list_of_specparam_assignments ';' |
TOK_SPECPARAM specparam_range list_of_specparam_assignments ';' ;
// IEEE 1364-2005 calls this sinmply 'range' but the current 'range' rule allows empty match
// and the 'non_opt_range' rule allows index ranges not allowed by 1364-2005
// exxxxtending this for SV specparam would change this anyhow
specparam_range:
'[' ignspec_constant_expression ':' ignspec_constant_expression ']' ;
list_of_specparam_assignments:
specparam_assignment | list_of_specparam_assignments ',' specparam_assignment;
specparam_assignment:
ignspec_id '=' ignspec_expr ;
ignspec_opt_cond:
TOK_IF '(' ignspec_expr ')' | %empty;
path_declaration :
simple_path_declaration ';'
// | edge_sensitive_path_declaration
// | state_dependent_path_declaration
;
simple_path_declaration :
ignspec_opt_cond parallel_path_description '=' path_delay_value |
ignspec_opt_cond full_path_description '=' path_delay_value
;
path_delay_value :
'(' ignspec_expr list_of_path_delay_extra_expressions ')'
| ignspec_expr
| ignspec_expr list_of_path_delay_extra_expressions
;
list_of_path_delay_extra_expressions :
',' ignspec_expr
| ',' ignspec_expr list_of_path_delay_extra_expressions
;
specify_edge_identifier :
TOK_POSEDGE | TOK_NEGEDGE ;
parallel_path_description :
'(' specify_input_terminal_descriptor opt_polarity_operator '=' '>' specify_output_terminal_descriptor ')' |
'(' specify_edge_identifier specify_input_terminal_descriptor '=' '>' '(' specify_output_terminal_descriptor opt_polarity_operator ':' ignspec_expr ')' ')' |
'(' specify_edge_identifier specify_input_terminal_descriptor '=' '>' '(' specify_output_terminal_descriptor TOK_POS_INDEXED ignspec_expr ')' ')' ;
full_path_description :
'(' list_of_path_inputs '*' '>' list_of_path_outputs ')' |
'(' specify_edge_identifier list_of_path_inputs '*' '>' '(' list_of_path_outputs opt_polarity_operator ':' ignspec_expr ')' ')' |
'(' specify_edge_identifier list_of_path_inputs '*' '>' '(' list_of_path_outputs TOK_POS_INDEXED ignspec_expr ')' ')' ;
// This was broken into 2 rules to solve shift/reduce conflicts
list_of_path_inputs :
specify_input_terminal_descriptor opt_polarity_operator |
specify_input_terminal_descriptor more_path_inputs opt_polarity_operator ;
more_path_inputs :
',' specify_input_terminal_descriptor |
more_path_inputs ',' specify_input_terminal_descriptor ;
list_of_path_outputs :
specify_output_terminal_descriptor |
list_of_path_outputs ',' specify_output_terminal_descriptor ;
opt_polarity_operator :
'+' | '-' | %empty;
// Good enough for the time being
specify_input_terminal_descriptor :
ignspec_id ;
// Good enough for the time being
specify_output_terminal_descriptor :
ignspec_id ;
system_timing_declaration :
ignspec_id '(' system_timing_args ')' ';' ;
system_timing_arg :
TOK_POSEDGE ignspec_id |
TOK_NEGEDGE ignspec_id |
ignspec_expr ;
system_timing_args :
system_timing_arg |
system_timing_args TOK_IGNORED_SPECIFY_AND system_timing_arg |
system_timing_args ',' system_timing_arg ;
// for the time being this is OK, but we may write our own expr here.
// as I'm not sure it is legal to use a full expr here (probably not)
// On the other hand, other rules requiring constant expressions also use 'expr'
// (such as param assignment), so we may leave this as-is, perhaps adding runtime checks for constant-ness
ignspec_constant_expression:
expr { delete $1; };
ignspec_expr:
expr { delete $1; } |
expr ':' expr ':' expr {
delete $1;
delete $3;
delete $5;
};
ignspec_id:
TOK_ID { delete $1; }
range_or_multirange { delete $3; };
/**********************************************************************/
param_signed:
TOK_SIGNED {
astbuf1->is_signed = true;
} | TOK_UNSIGNED {
astbuf1->is_signed = false;
} | %empty;
param_integer:
type_atom {
astbuf1->is_reg = false;
};
param_real:
TOK_REAL {
astbuf1->children.push_back(new AstNode(AST_REALVALUE));
};
param_range:
range {
if ($1 != NULL) {
astbuf1->children.push_back($1);
}
};
param_integer_type: param_integer param_signed;
param_range_type:
type_vec param_signed {
addRange(astbuf1, 0, 0);
} |
type_vec param_signed non_opt_range {
astbuf1->children.push_back($3);
};
param_implicit_type: param_signed param_range;
param_type:
param_integer_type | param_real | param_range_type | param_implicit_type |
hierarchical_type_id {
astbuf1->is_custom_type = true;
astbuf1->children.push_back(new AstNode(AST_WIRETYPE));
astbuf1->children.back()->str = *$1;
delete $1;
};
param_decl:
attr TOK_PARAMETER {
astbuf1 = new AstNode(AST_PARAMETER);
astbuf1->children.push_back(AstNode::mkconst_int(0, true));
append_attr(astbuf1, $1);
} param_type param_decl_list ';' {
delete astbuf1;
};
localparam_decl:
attr TOK_LOCALPARAM {
astbuf1 = new AstNode(AST_LOCALPARAM);
astbuf1->children.push_back(AstNode::mkconst_int(0, true));
append_attr(astbuf1, $1);
} param_type param_decl_list ';' {
delete astbuf1;
};
param_decl_list:
single_param_decl | param_decl_list ',' single_param_decl;
single_param_decl:
single_param_decl_ident '=' expr {
AstNode *decl = ast_stack.back()->children.back();
log_assert(decl->type == AST_PARAMETER || decl->type == AST_LOCALPARAM);
delete decl->children[0];
decl->children[0] = $3;
} |
single_param_decl_ident {
AstNode *decl = ast_stack.back()->children.back();
if (decl->type != AST_PARAMETER) {
log_assert(decl->type == AST_LOCALPARAM);
frontend_verilog_yyerror("localparam initialization is missing!");
}
if (!sv_mode)
frontend_verilog_yyerror("Parameter defaults can only be omitted in SystemVerilog mode!");
delete decl->children[0];
decl->children.erase(decl->children.begin());
};
single_param_decl_ident:
TOK_ID {
AstNode *node;
if (astbuf1 == nullptr) {
if (!sv_mode)
frontend_verilog_yyerror("In pure Verilog (not SystemVerilog), parameter/localparam with an initializer must use the parameter/localparam keyword");
node = new AstNode(AST_PARAMETER);
node->children.push_back(AstNode::mkconst_int(0, true));
} else {
node = astbuf1->clone();
}
node->str = *$1;
ast_stack.back()->children.push_back(node);
delete $1;
SET_AST_NODE_LOC(node, @1, @1);
};
defparam_decl:
TOK_DEFPARAM defparam_decl_list ';';
defparam_decl_list:
single_defparam_decl | defparam_decl_list ',' single_defparam_decl;
single_defparam_decl:
range rvalue '=' expr {
AstNode *node = new AstNode(AST_DEFPARAM);
node->children.push_back($2);
node->children.push_back($4);
if ($1 != NULL)
node->children.push_back($1);
ast_stack.back()->children.push_back(node);
};
/////////
// enum
/////////
enum_type: TOK_ENUM {
static int enum_count;
// create parent node for the enum
astbuf2 = new AstNode(AST_ENUM);
ast_stack.back()->children.push_back(astbuf2);
astbuf2->str = std::string("$enum");
astbuf2->str += std::to_string(enum_count++);
// create the template for the names
astbuf1 = new AstNode(AST_ENUM_ITEM);
astbuf1->children.push_back(AstNode::mkconst_int(0, true));
} enum_base_type '{' enum_name_list optional_comma '}' {
// create template for the enum vars
auto tnode = astbuf1->clone();
delete astbuf1;
astbuf1 = tnode;
tnode->type = AST_WIRE;
tnode->attributes[ID::enum_type] = AstNode::mkconst_str(astbuf2->str);
// drop constant but keep any range
delete tnode->children[0];
tnode->children.erase(tnode->children.begin());
$$ = astbuf1;
};
enum_base_type: type_atom type_signing
| type_vec type_signing range { if ($3) astbuf1->children.push_back($3); }
| %empty { astbuf1->is_reg = true; addRange(astbuf1); }
;
type_atom:
integer_atom_type {
astbuf1->is_reg = true;
astbuf1->is_signed = true;
addRange(astbuf1, $1 - 1, 0);
};
type_vec: TOK_REG { astbuf1->is_reg = true; } // unsigned
| TOK_LOGIC { astbuf1->is_logic = true; } // unsigned
;
type_signing:
TOK_SIGNED { astbuf1->is_signed = true; }
| TOK_UNSIGNED { astbuf1->is_signed = false; }
| %empty
;
enum_name_list: enum_name_decl
| enum_name_list ',' enum_name_decl
;
enum_name_decl:
TOK_ID opt_enum_init {
// put in fn
log_assert(astbuf1);
log_assert(astbuf2);
auto node = astbuf1->clone();
node->str = *$1;
delete $1;
SET_AST_NODE_LOC(node, @1, @1);
delete node->children[0];
node->children[0] = $2 ? $2 : new AstNode(AST_NONE);
astbuf2->children.push_back(node);
}
;
opt_enum_init:
'=' basic_expr { $$ = $2; } // TODO: restrict this
| %empty { $$ = NULL; }
;
enum_var_list:
enum_var
| enum_var_list ',' enum_var
;
enum_var: TOK_ID {
log_assert(astbuf1);
log_assert(astbuf2);
auto node = astbuf1->clone();
ast_stack.back()->children.push_back(node);
node->str = *$1;
delete $1;
SET_AST_NODE_LOC(node, @1, @1);
node->is_enum = true;
}
;
enum_decl: enum_type enum_var_list ';' { delete $1; }
;
//////////////////
// struct or union
//////////////////
struct_decl: struct_type struct_var_list ';' { delete astbuf2; }
;
struct_type: struct_union { astbuf2 = $1; } struct_body { $$ = astbuf2; }
;
struct_union:
TOK_STRUCT { $$ = new AstNode(AST_STRUCT); }
| TOK_UNION { $$ = new AstNode(AST_UNION); }
;
struct_body: opt_packed '{' struct_member_list '}'
;
opt_packed:
TOK_PACKED opt_signed_struct |
%empty { frontend_verilog_yyerror("Only PACKED supported at this time"); };
opt_signed_struct:
TOK_SIGNED { astbuf2->is_signed = true; }
| TOK_UNSIGNED { astbuf2->is_signed = false; }
| %empty // default is unsigned
;
struct_member_list: struct_member
| struct_member_list struct_member
;
struct_member: struct_member_type member_name_list ';' { delete astbuf1; }
;
member_name_list:
member_name
| member_name_list ',' member_name
;
member_name: TOK_ID {
astbuf1->str = $1->substr(1);
delete $1;
astbuf3 = astbuf1->clone();
SET_AST_NODE_LOC(astbuf3, @1, @1);
astbuf2->children.push_back(astbuf3);
} range { if ($3) astbuf3->children.push_back($3); }
;
struct_member_type: { astbuf1 = new AstNode(AST_STRUCT_ITEM); } member_type_token
;
member_type_token:
member_type
| hierarchical_type_id {
// use a clone of the typedef definition nodes
auto template_node = copyTypeDefinition(*$1);
delete $1;
switch (template_node->type) {
case AST_WIRE:
template_node->type = AST_STRUCT_ITEM;
break;
case AST_STRUCT:
case AST_UNION:
break;
default:
frontend_verilog_yyerror("Invalid type for struct member: %s", type2str(template_node->type).c_str());
}
delete astbuf1;
astbuf1 = template_node;
}
| {
delete astbuf1;
} struct_union {
// stash state on ast_stack
ast_stack.push_back(astbuf2);
astbuf2 = $2;
} struct_body {
astbuf1 = astbuf2;
// recover state
astbuf2 = ast_stack.back();
ast_stack.pop_back();
}
;
member_type: type_atom type_signing
| type_vec type_signing range_or_multirange { if ($3) astbuf1->children.push_back($3); }
;
struct_var_list: struct_var
| struct_var_list ',' struct_var
;
struct_var: TOK_ID { auto *var_node = astbuf2->clone();
var_node->str = *$1;
delete $1;
SET_AST_NODE_LOC(var_node, @1, @1);
ast_stack.back()->children.push_back(var_node);
}
;
/////////
// wire
/////////
wire_decl:
attr wire_type range {
albuf = $1;
astbuf1 = $2;
astbuf2 = checkRange(astbuf1, $3);
} delay wire_name_list {
delete astbuf1;
if (astbuf2 != NULL)
delete astbuf2;
free_attr(albuf);
} ';' |
attr TOK_SUPPLY0 TOK_ID {
ast_stack.back()->children.push_back(new AstNode(AST_WIRE));
ast_stack.back()->children.back()->str = *$3;
append_attr(ast_stack.back()->children.back(), $1);
ast_stack.back()->children.push_back(new AstNode(AST_ASSIGN, new AstNode(AST_IDENTIFIER), AstNode::mkconst_int(0, false, 1)));
ast_stack.back()->children.back()->children[0]->str = *$3;
delete $3;
} opt_supply_wires ';' |
attr TOK_SUPPLY1 TOK_ID {
ast_stack.back()->children.push_back(new AstNode(AST_WIRE));
ast_stack.back()->children.back()->str = *$3;
append_attr(ast_stack.back()->children.back(), $1);
ast_stack.back()->children.push_back(new AstNode(AST_ASSIGN, new AstNode(AST_IDENTIFIER), AstNode::mkconst_int(1, false, 1)));
ast_stack.back()->children.back()->children[0]->str = *$3;
delete $3;
} opt_supply_wires ';';
opt_supply_wires:
%empty |
opt_supply_wires ',' TOK_ID {
AstNode *wire_node = ast_stack.back()->children.at(GetSize(ast_stack.back()->children)-2)->clone();
AstNode *assign_node = ast_stack.back()->children.at(GetSize(ast_stack.back()->children)-1)->clone();
wire_node->str = *$3;
assign_node->children[0]->str = *$3;
ast_stack.back()->children.push_back(wire_node);
ast_stack.back()->children.push_back(assign_node);
delete $3;
};
wire_name_list:
wire_name_and_opt_assign | wire_name_list ',' wire_name_and_opt_assign;
wire_name_and_opt_assign:
wire_name {
bool attr_anyconst = false;
bool attr_anyseq = false;
bool attr_allconst = false;
bool attr_allseq = false;
if (ast_stack.back()->children.back()->get_bool_attribute(ID::anyconst)) {
delete ast_stack.back()->children.back()->attributes.at(ID::anyconst);
ast_stack.back()->children.back()->attributes.erase(ID::anyconst);
attr_anyconst = true;
}
if (ast_stack.back()->children.back()->get_bool_attribute(ID::anyseq)) {
delete ast_stack.back()->children.back()->attributes.at(ID::anyseq);
ast_stack.back()->children.back()->attributes.erase(ID::anyseq);
attr_anyseq = true;
}
if (ast_stack.back()->children.back()->get_bool_attribute(ID::allconst)) {
delete ast_stack.back()->children.back()->attributes.at(ID::allconst);
ast_stack.back()->children.back()->attributes.erase(ID::allconst);
attr_allconst = true;
}
if (ast_stack.back()->children.back()->get_bool_attribute(ID::allseq)) {
delete ast_stack.back()->children.back()->attributes.at(ID::allseq);
ast_stack.back()->children.back()->attributes.erase(ID::allseq);
attr_allseq = true;
}
if (current_wire_rand || attr_anyconst || attr_anyseq || attr_allconst || attr_allseq) {
AstNode *wire = new AstNode(AST_IDENTIFIER);
AstNode *fcall = new AstNode(AST_FCALL);
wire->str = ast_stack.back()->children.back()->str;
fcall->str = current_wire_const ? "\\$anyconst" : "\\$anyseq";
if (attr_anyconst)
fcall->str = "\\$anyconst";
if (attr_anyseq)
fcall->str = "\\$anyseq";
if (attr_allconst)
fcall->str = "\\$allconst";
if (attr_allseq)
fcall->str = "\\$allseq";
fcall->attributes[ID::reg] = AstNode::mkconst_str(RTLIL::unescape_id(wire->str));
ast_stack.back()->children.push_back(new AstNode(AST_ASSIGN, wire, fcall));
}
} |
wire_name '=' expr {
AstNode *wire = new AstNode(AST_IDENTIFIER);
wire->str = ast_stack.back()->children.back()->str;
if (astbuf1->is_input) {
if (astbuf1->attributes.count(ID::defaultvalue))
delete astbuf1->attributes.at(ID::defaultvalue);
astbuf1->attributes[ID::defaultvalue] = $3;
}
else if (astbuf1->is_reg || astbuf1->is_logic){
AstNode *assign = new AstNode(AST_ASSIGN_LE, wire, $3);
AstNode *block = new AstNode(AST_BLOCK, assign);
AstNode *init = new AstNode(AST_INITIAL, block);
SET_AST_NODE_LOC(assign, @1, @3);
SET_AST_NODE_LOC(block, @1, @3);
SET_AST_NODE_LOC(init, @1, @3);
ast_stack.back()->children.push_back(init);
}
else {
AstNode *assign = new AstNode(AST_ASSIGN, wire, $3);
SET_AST_NODE_LOC(assign, @1, @3);
ast_stack.back()->children.push_back(assign);
}
};
wire_name:
TOK_ID range_or_multirange {
if (astbuf1 == nullptr)
frontend_verilog_yyerror("Internal error - should not happen - no AST_WIRE node.");
AstNode *node = astbuf1->clone();
node->str = *$1;
append_attr_clone(node, albuf);
if (astbuf2 != NULL)
node->children.push_back(astbuf2->clone());
if ($2 != NULL) {
if (node->is_input || node->is_output)
frontend_verilog_yyerror("input/output/inout ports cannot have unpacked dimensions.");
if (!astbuf2 && !node->is_custom_type) {
addRange(node, 0, 0, false);
}
rewriteAsMemoryNode(node, $2);
}
if (current_function_or_task) {
if (node->is_input || node->is_output)
node->port_id = current_function_or_task_port_id++;
} else if (ast_stack.back()->type == AST_GENBLOCK) {
if (node->is_input || node->is_output)
frontend_verilog_yyerror("Cannot declare module port `%s' within a generate block.", $1->c_str());
} else {
if (do_not_require_port_stubs && (node->is_input || node->is_output) && port_stubs.count(*$1) == 0) {
port_stubs[*$1] = ++port_counter;
}
if (port_stubs.count(*$1) != 0) {
if (!node->is_input && !node->is_output)
frontend_verilog_yyerror("Module port `%s' is neither input nor output.", $1->c_str());
if (node->is_reg && node->is_input && !node->is_output && !sv_mode)
frontend_verilog_yyerror("Input port `%s' is declared as register.", $1->c_str());
node->port_id = port_stubs[*$1];
port_stubs.erase(*$1);
} else {
if (node->is_input || node->is_output)
frontend_verilog_yyerror("Module port `%s' is not declared in module header.", $1->c_str());
}
}
//FIXME: for some reason, TOK_ID has a location which always points to one column *after* the real last column...
SET_AST_NODE_LOC(node, @1, @1);
ast_stack.back()->children.push_back(node);
delete $1;
};
assign_stmt:
TOK_ASSIGN delay assign_expr_list ';';
assign_expr_list:
assign_expr | assign_expr_list ',' assign_expr;
assign_expr:
lvalue '=' expr {
AstNode *node = new AstNode(AST_ASSIGN, $1, $3);
SET_AST_NODE_LOC(node, @$, @$);
ast_stack.back()->children.push_back(node);
};
type_name: TOK_ID // first time seen
| TOK_USER_TYPE { if (isInLocalScope($1)) frontend_verilog_yyerror("Duplicate declaration of TYPEDEF '%s'", $1->c_str()+1); }
;
typedef_decl:
TOK_TYPEDEF typedef_base_type range type_name range_or_multirange ';' {
astbuf1 = $2;
astbuf2 = checkRange(astbuf1, $3);
if (astbuf2)
astbuf1->children.push_back(astbuf2);
if ($5 != NULL) {
if (!astbuf2) {
addRange(astbuf1, 0, 0, false);
}
rewriteAsMemoryNode(astbuf1, $5);
}
addTypedefNode($4, astbuf1); }
| TOK_TYPEDEF enum_struct_type type_name ';' { addTypedefNode($3, $2); }
;
typedef_base_type:
hierarchical_type_id {
$$ = new AstNode(AST_WIRE);
$$->is_logic = true;
addWiretypeNode($1, $$);
} |
integer_vector_type opt_signedness_default_unsigned {
$$ = new AstNode(AST_WIRE);
if ($1 == TOK_REG) {
$$->is_reg = true;
} else {
$$->is_logic = true;
}
$$->is_signed = $2;
} |
integer_atom_type opt_signedness_default_signed {
$$ = new AstNode(AST_WIRE);
$$->is_logic = true;
$$->is_signed = $2;
$$->range_left = $1 - 1;
$$->range_right = 0;
};
enum_struct_type:
enum_type
| struct_type
;
cell_stmt:
attr TOK_ID {
astbuf1 = new AstNode(AST_CELL);
append_attr(astbuf1, $1);
astbuf1->children.push_back(new AstNode(AST_CELLTYPE));
astbuf1->children[0]->str = *$2;
delete $2;
} cell_parameter_list_opt cell_list ';' {
delete astbuf1;
} |
attr tok_prim_wrapper delay {
astbuf1 = new AstNode(AST_PRIMITIVE);
astbuf1->str = *$2;
append_attr(astbuf1, $1);
delete $2;
} prim_list ';' {
delete astbuf1;
};
tok_prim_wrapper:
TOK_PRIMITIVE {
$$ = $1;
} |
TOK_OR {
$$ = new std::string("or");
};
cell_list:
single_cell |
cell_list ',' single_cell;
single_cell:
single_cell_no_array | single_cell_arraylist;
single_cell_no_array:
TOK_ID {
astbuf2 = astbuf1->clone();
if (astbuf2->type != AST_PRIMITIVE)
astbuf2->str = *$1;
delete $1;
ast_stack.back()->children.push_back(astbuf2);
} '(' cell_port_list ')' {
SET_AST_NODE_LOC(astbuf2, @1, @$);
}
single_cell_arraylist:
TOK_ID non_opt_range {
astbuf2 = astbuf1->clone();
if (astbuf2->type != AST_PRIMITIVE)
astbuf2->str = *$1;
delete $1;
ast_stack.back()->children.push_back(new AstNode(AST_CELLARRAY, $2, astbuf2));
} '(' cell_port_list ')'{
SET_AST_NODE_LOC(astbuf2, @1, @$);
};
cell_list_no_array:
single_cell_no_array |
cell_list_no_array ',' single_cell_no_array;
prim_list:
single_prim |
prim_list ',' single_prim;
single_prim:
single_cell |
/* no name */ {
astbuf2 = astbuf1->clone();
ast_stack.back()->children.push_back(astbuf2);
} '(' cell_port_list ')' {
SET_AST_NODE_LOC(astbuf2, @1, @$);
}
cell_parameter_list_opt:
'#' '(' cell_parameter_list ')' | %empty;
cell_parameter_list:
cell_parameter | cell_parameter_list ',' cell_parameter;
cell_parameter:
%empty |
expr {
AstNode *node = new AstNode(AST_PARASET);
astbuf1->children.push_back(node);
node->children.push_back($1);
} |
'.' TOK_ID '(' ')' {
// just ignore empty parameters
} |
'.' TOK_ID '(' expr ')' {
AstNode *node = new AstNode(AST_PARASET);
node->str = *$2;
astbuf1->children.push_back(node);
node->children.push_back($4);
delete $2;
};
cell_port_list:
cell_port_list_rules {
// remove empty args from end of list
while (!astbuf2->children.empty()) {
AstNode *node = astbuf2->children.back();
if (node->type != AST_ARGUMENT) break;
if (!node->children.empty()) break;
if (!node->str.empty()) break;
astbuf2->children.pop_back();
delete node;
}
// check port types
bool has_positional_args = false;
bool has_named_args = false;
for (auto node : astbuf2->children) {
if (node->type != AST_ARGUMENT) continue;
if (node->str.empty())
has_positional_args = true;
else
has_named_args = true;
}
if (has_positional_args && has_named_args)
frontend_verilog_yyerror("Mix of positional and named cell ports.");
};
cell_port_list_rules:
cell_port | cell_port_list_rules ',' cell_port;
cell_port:
attr {
AstNode *node = new AstNode(AST_ARGUMENT);
astbuf2->children.push_back(node);
free_attr($1);
} |
attr expr {
AstNode *node = new AstNode(AST_ARGUMENT);
astbuf2->children.push_back(node);
node->children.push_back($2);
free_attr($1);
} |
attr '.' TOK_ID '(' expr ')' {
AstNode *node = new AstNode(AST_ARGUMENT);
node->str = *$3;
astbuf2->children.push_back(node);
node->children.push_back($5);
delete $3;
free_attr($1);
} |
attr '.' TOK_ID '(' ')' {
AstNode *node = new AstNode(AST_ARGUMENT);
node->str = *$3;
astbuf2->children.push_back(node);
delete $3;
free_attr($1);
} |
attr '.' TOK_ID {
AstNode *node = new AstNode(AST_ARGUMENT);
node->str = *$3;
astbuf2->children.push_back(node);
node->children.push_back(new AstNode(AST_IDENTIFIER));
node->children.back()->str = *$3;
delete $3;
free_attr($1);
} |
attr TOK_WILDCARD_CONNECT {
if (!sv_mode)
frontend_verilog_yyerror("Wildcard port connections are only supported in SystemVerilog mode.");
astbuf2->attributes[ID::wildcard_port_conns] = AstNode::mkconst_int(1, false);
free_attr($1);
};
always_comb_or_latch:
TOK_ALWAYS_COMB {
$$ = false;
} |
TOK_ALWAYS_LATCH {
$$ = true;
};
always_or_always_ff:
TOK_ALWAYS {
$$ = false;
} |
TOK_ALWAYS_FF {
$$ = true;
};
always_stmt:
attr always_or_always_ff {
AstNode *node = new AstNode(AST_ALWAYS);
append_attr(node, $1);
if ($2)
node->attributes[ID::always_ff] = AstNode::mkconst_int(1, false);
ast_stack.back()->children.push_back(node);
ast_stack.push_back(node);
} always_cond {
AstNode *block = new AstNode(AST_BLOCK);
ast_stack.back()->children.push_back(block);
ast_stack.push_back(block);
} behavioral_stmt {
SET_AST_NODE_LOC(ast_stack.back(), @6, @6);
ast_stack.pop_back();
SET_AST_NODE_LOC(ast_stack.back(), @2, @$);
ast_stack.pop_back();
SET_RULE_LOC(@$, @2, @$);
} |
attr always_comb_or_latch {
AstNode *node = new AstNode(AST_ALWAYS);
append_attr(node, $1);
if ($2)
node->attributes[ID::always_latch] = AstNode::mkconst_int(1, false);
else
node->attributes[ID::always_comb] = AstNode::mkconst_int(1, false);
ast_stack.back()->children.push_back(node);
ast_stack.push_back(node);
AstNode *block = new AstNode(AST_BLOCK);
ast_stack.back()->children.push_back(block);
ast_stack.push_back(block);
} behavioral_stmt {
ast_stack.pop_back();
ast_stack.pop_back();
} |
attr TOK_INITIAL {
AstNode *node = new AstNode(AST_INITIAL);
append_attr(node, $1);
ast_stack.back()->children.push_back(node);
ast_stack.push_back(node);
AstNode *block = new AstNode(AST_BLOCK);
ast_stack.back()->children.push_back(block);
ast_stack.push_back(block);
} behavioral_stmt {
ast_stack.pop_back();
ast_stack.pop_back();
};
always_cond:
'@' '(' always_events ')' |
'@' '(' '*' ')' |
'@' ATTR_BEGIN ')' |
'@' '(' ATTR_END |
'@' '*' |
%empty;
always_events:
always_event |
always_events TOK_OR always_event |
always_events ',' always_event;
always_event:
TOK_POSEDGE expr {
AstNode *node = new AstNode(AST_POSEDGE);
SET_AST_NODE_LOC(node, @1, @1);
ast_stack.back()->children.push_back(node);
node->children.push_back($2);
} |
TOK_NEGEDGE expr {
AstNode *node = new AstNode(AST_NEGEDGE);
SET_AST_NODE_LOC(node, @1, @1);
ast_stack.back()->children.push_back(node);
node->children.push_back($2);
} |
expr {
AstNode *node = new AstNode(AST_EDGE);
ast_stack.back()->children.push_back(node);
node->children.push_back($1);
};
opt_label:
':' TOK_ID {
$$ = $2;
} |
%empty {
$$ = NULL;
};
opt_sva_label:
TOK_SVA_LABEL ':' {
$$ = $1;
} |
%empty {
$$ = NULL;
};
opt_property:
TOK_PROPERTY {
$$ = true;
} |
TOK_FINAL {
$$ = false;
} |
%empty {
$$ = false;
};
modport_stmt:
TOK_MODPORT TOK_ID {
AstNode *modport = new AstNode(AST_MODPORT);
ast_stack.back()->children.push_back(modport);
ast_stack.push_back(modport);
modport->str = *$2;
delete $2;
} modport_args_opt {
ast_stack.pop_back();
log_assert(ast_stack.size() == 2);
} ';'
modport_args_opt:
'(' ')' | '(' modport_args optional_comma ')';
modport_args:
modport_arg | modport_args ',' modport_arg;
modport_arg:
modport_type_token modport_member |
modport_member
modport_member:
TOK_ID {
AstNode *modport_member = new AstNode(AST_MODPORTMEMBER);
ast_stack.back()->children.push_back(modport_member);
modport_member->str = *$1;
modport_member->is_input = current_modport_input;
modport_member->is_output = current_modport_output;
delete $1;
}
modport_type_token:
TOK_INPUT {current_modport_input = 1; current_modport_output = 0;} | TOK_OUTPUT {current_modport_input = 0; current_modport_output = 1;}
assert:
opt_sva_label TOK_ASSERT opt_property '(' expr ')' ';' {
if (noassert_mode) {
delete $5;
} else {
AstNode *node = new AstNode(assume_asserts_mode ? AST_ASSUME : AST_ASSERT, $5);
SET_AST_NODE_LOC(node, @1, @6);
if ($1 != nullptr)
node->str = *$1;
ast_stack.back()->children.push_back(node);
}
if ($1 != nullptr)
delete $1;
} |
opt_sva_label TOK_ASSUME opt_property '(' expr ')' ';' {
if (noassume_mode) {
delete $5;
} else {
AstNode *node = new AstNode(assert_assumes_mode ? AST_ASSERT : AST_ASSUME, $5);
SET_AST_NODE_LOC(node, @1, @6);
if ($1 != nullptr)
node->str = *$1;
ast_stack.back()->children.push_back(node);
}
if ($1 != nullptr)
delete $1;
} |
opt_sva_label TOK_ASSERT opt_property '(' TOK_EVENTUALLY expr ')' ';' {
if (noassert_mode) {
delete $6;
} else {
AstNode *node = new AstNode(assume_asserts_mode ? AST_FAIR : AST_LIVE, $6);
SET_AST_NODE_LOC(node, @1, @7);
if ($1 != nullptr)
node->str = *$1;
ast_stack.back()->children.push_back(node);
}
if ($1 != nullptr)
delete $1;
} |
opt_sva_label TOK_ASSUME opt_property '(' TOK_EVENTUALLY expr ')' ';' {
if (noassume_mode) {
delete $6;
} else {
AstNode *node = new AstNode(assert_assumes_mode ? AST_LIVE : AST_FAIR, $6);
SET_AST_NODE_LOC(node, @1, @7);
if ($1 != nullptr)
node->str = *$1;
ast_stack.back()->children.push_back(node);
}
if ($1 != nullptr)
delete $1;
} |
opt_sva_label TOK_COVER opt_property '(' expr ')' ';' {
AstNode *node = new AstNode(AST_COVER, $5);
SET_AST_NODE_LOC(node, @1, @6);
if ($1 != nullptr) {
node->str = *$1;
delete $1;
}
ast_stack.back()->children.push_back(node);
} |
opt_sva_label TOK_COVER opt_property '(' ')' ';' {
AstNode *node = new AstNode(AST_COVER, AstNode::mkconst_int(1, false));
SET_AST_NODE_LOC(node, @1, @5);
if ($1 != nullptr) {
node->str = *$1;
delete $1;
}
ast_stack.back()->children.push_back(node);
} |
opt_sva_label TOK_COVER ';' {
AstNode *node = new AstNode(AST_COVER, AstNode::mkconst_int(1, false));
SET_AST_NODE_LOC(node, @1, @2);
if ($1 != nullptr) {
node->str = *$1;
delete $1;
}
ast_stack.back()->children.push_back(node);
} |
opt_sva_label TOK_RESTRICT opt_property '(' expr ')' ';' {
if (norestrict_mode) {
delete $5;
} else {
AstNode *node = new AstNode(AST_ASSUME, $5);
SET_AST_NODE_LOC(node, @1, @6);
if ($1 != nullptr)
node->str = *$1;
ast_stack.back()->children.push_back(node);
}
if (!$3)
log_file_warning(current_filename, get_line_num(), "SystemVerilog does not allow \"restrict\" without \"property\".\n");
if ($1 != nullptr)
delete $1;
} |
opt_sva_label TOK_RESTRICT opt_property '(' TOK_EVENTUALLY expr ')' ';' {
if (norestrict_mode) {
delete $6;
} else {
AstNode *node = new AstNode(AST_FAIR, $6);
SET_AST_NODE_LOC(node, @1, @7);
if ($1 != nullptr)
node->str = *$1;
ast_stack.back()->children.push_back(node);
}
if (!$3)
log_file_warning(current_filename, get_line_num(), "SystemVerilog does not allow \"restrict\" without \"property\".\n");
if ($1 != nullptr)
delete $1;
};
assert_property:
opt_sva_label TOK_ASSERT TOK_PROPERTY '(' expr ')' ';' {
AstNode *node = new AstNode(assume_asserts_mode ? AST_ASSUME : AST_ASSERT, $5);
SET_AST_NODE_LOC(node, @1, @6);
ast_stack.back()->children.push_back(node);
if ($1 != nullptr) {
ast_stack.back()->children.back()->str = *$1;
delete $1;
}
} |
opt_sva_label TOK_ASSUME TOK_PROPERTY '(' expr ')' ';' {
AstNode *node = new AstNode(AST_ASSUME, $5);
SET_AST_NODE_LOC(node, @1, @6);
ast_stack.back()->children.push_back(node);
if ($1 != nullptr) {
ast_stack.back()->children.back()->str = *$1;
delete $1;
}
} |
opt_sva_label TOK_ASSERT TOK_PROPERTY '(' TOK_EVENTUALLY expr ')' ';' {
AstNode *node = new AstNode(assume_asserts_mode ? AST_FAIR : AST_LIVE, $6);
SET_AST_NODE_LOC(node, @1, @7);
ast_stack.back()->children.push_back(node);
if ($1 != nullptr) {
ast_stack.back()->children.back()->str = *$1;
delete $1;
}
} |
opt_sva_label TOK_ASSUME TOK_PROPERTY '(' TOK_EVENTUALLY expr ')' ';' {
AstNode *node = new AstNode(AST_FAIR, $6);
SET_AST_NODE_LOC(node, @1, @7);
ast_stack.back()->children.push_back(node);
if ($1 != nullptr) {
ast_stack.back()->children.back()->str = *$1;
delete $1;
}
} |
opt_sva_label TOK_COVER TOK_PROPERTY '(' expr ')' ';' {
AstNode *node = new AstNode(AST_COVER, $5);
SET_AST_NODE_LOC(node, @1, @6);
ast_stack.back()->children.push_back(node);
if ($1 != nullptr) {
ast_stack.back()->children.back()->str = *$1;
delete $1;
}
} |
opt_sva_label TOK_RESTRICT TOK_PROPERTY '(' expr ')' ';' {
if (norestrict_mode) {
delete $5;
} else {
AstNode *node = new AstNode(AST_ASSUME, $5);
SET_AST_NODE_LOC(node, @1, @6);
ast_stack.back()->children.push_back(node);
if ($1 != nullptr) {
ast_stack.back()->children.back()->str = *$1;
delete $1;
}
}
} |
opt_sva_label TOK_RESTRICT TOK_PROPERTY '(' TOK_EVENTUALLY expr ')' ';' {
if (norestrict_mode) {
delete $6;
} else {
AstNode *node = new AstNode(AST_FAIR, $6);
SET_AST_NODE_LOC(node, @1, @7);
ast_stack.back()->children.push_back(node);
if ($1 != nullptr) {
ast_stack.back()->children.back()->str = *$1;
delete $1;
}
}
};
simple_behavioral_stmt:
attr lvalue '=' delay expr {
AstNode *node = new AstNode(AST_ASSIGN_EQ, $2, $5);
ast_stack.back()->children.push_back(node);
SET_AST_NODE_LOC(node, @2, @5);
append_attr(node, $1);
} |
attr lvalue TOK_INCREMENT {
AstNode *node = new AstNode(AST_ASSIGN_EQ, $2, new AstNode(AST_ADD, $2->clone(), AstNode::mkconst_int(1, true)));
ast_stack.back()->children.push_back(node);
SET_AST_NODE_LOC(node, @2, @3);
append_attr(node, $1);
} |
attr lvalue TOK_DECREMENT {
AstNode *node = new AstNode(AST_ASSIGN_EQ, $2, new AstNode(AST_SUB, $2->clone(), AstNode::mkconst_int(1, true)));
ast_stack.back()->children.push_back(node);
SET_AST_NODE_LOC(node, @2, @3);
append_attr(node, $1);
} |
attr lvalue OP_LE delay expr {
AstNode *node = new AstNode(AST_ASSIGN_LE, $2, $5);
ast_stack.back()->children.push_back(node);
SET_AST_NODE_LOC(node, @2, @5);
append_attr(node, $1);
} |
attr lvalue asgn_binop delay expr {
AstNode *expr_node = $5;
if ($3 == AST_SHIFT_LEFT || $3 == AST_SHIFT_RIGHT ||
$3 == AST_SHIFT_SLEFT || $3 == AST_SHIFT_SRIGHT) {
expr_node = new AstNode(AST_TO_UNSIGNED, expr_node);
SET_AST_NODE_LOC(expr_node, @5, @5);
}
AstNode *op_node = new AstNode($3, $2->clone(), expr_node);
AstNode *node = new AstNode(AST_ASSIGN_EQ, $2, op_node);
SET_AST_NODE_LOC(op_node, @2, @5);
SET_AST_NODE_LOC(node, @2, @5);
ast_stack.back()->children.push_back(node);
append_attr(node, $1);
};
asgn_binop:
TOK_BIT_OR_ASSIGN { $$ = AST_BIT_OR; } |
TOK_BIT_AND_ASSIGN { $$ = AST_BIT_AND; } |
TOK_BIT_XOR_ASSIGN { $$ = AST_BIT_XOR; } |
TOK_ADD_ASSIGN { $$ = AST_ADD; } |
TOK_SUB_ASSIGN { $$ = AST_SUB; } |
TOK_DIV_ASSIGN { $$ = AST_DIV; } |
TOK_MOD_ASSIGN { $$ = AST_MOD; } |
TOK_MUL_ASSIGN { $$ = AST_MUL; } |
TOK_SHL_ASSIGN { $$ = AST_SHIFT_LEFT; } |
TOK_SHR_ASSIGN { $$ = AST_SHIFT_RIGHT; } |
TOK_SSHL_ASSIGN { $$ = AST_SHIFT_SLEFT; } |
TOK_SSHR_ASSIGN { $$ = AST_SHIFT_SRIGHT; } ;
for_initialization:
TOK_ID '=' expr {
AstNode *ident = new AstNode(AST_IDENTIFIER);
ident->str = *$1;
AstNode *node = new AstNode(AST_ASSIGN_EQ, ident, $3);
ast_stack.back()->children.push_back(node);
SET_AST_NODE_LOC(node, @1, @3);
delete $1;
} |
non_io_wire_type range TOK_ID {
frontend_verilog_yyerror("For loop variable declaration is missing initialization!");
} |
non_io_wire_type range TOK_ID '=' expr {
if (!sv_mode)
frontend_verilog_yyerror("For loop inline variable declaration is only supported in SystemVerilog mode!");
// loop variable declaration
AstNode *wire = $1;
AstNode *range = checkRange(wire, $2);
if (range != nullptr)
wire->children.push_back(range);
SET_AST_NODE_LOC(wire, @1, @3);
SET_AST_NODE_LOC(range, @2, @2);
AstNode *ident = new AstNode(AST_IDENTIFIER);
ident->str = *$3;
wire->str = *$3;
delete $3;
AstNode *loop = ast_stack.back();
AstNode *parent = ast_stack.at(ast_stack.size() - 2);
log_assert(parent->children.back() == loop);
// loop variable initialization
AstNode *asgn = new AstNode(AST_ASSIGN_EQ, ident, $5);
loop->children.push_back(asgn);
SET_AST_NODE_LOC(asgn, @3, @5);
SET_AST_NODE_LOC(ident, @3, @3);
// inject a wrapping block to declare the loop variable and
// contain the current loop
AstNode *wrapper = new AstNode(AST_BLOCK);
wrapper->str = "$fordecl_block$" + std::to_string(autoidx++);
wrapper->children.push_back(wire);
wrapper->children.push_back(loop);
parent->children.back() = wrapper; // replaces `loop`
};
// this production creates the obligatory if-else shift/reduce conflict
behavioral_stmt:
defattr | assert | wire_decl | param_decl | localparam_decl | typedef_decl |
non_opt_delay behavioral_stmt |
simple_behavioral_stmt ';' |
attr ';' {
free_attr($1);
} |
attr hierarchical_id {
AstNode *node = new AstNode(AST_TCALL);
node->str = *$2;
delete $2;
ast_stack.back()->children.push_back(node);
ast_stack.push_back(node);
append_attr(node, $1);
} opt_arg_list ';'{
ast_stack.pop_back();
} |
attr TOK_MSG_TASKS {
AstNode *node = new AstNode(AST_TCALL);
node->str = *$2;
delete $2;
ast_stack.back()->children.push_back(node);
ast_stack.push_back(node);
append_attr(node, $1);
} opt_arg_list ';'{
ast_stack.pop_back();
} |
attr TOK_BEGIN {
enterTypeScope();
} opt_label {
AstNode *node = new AstNode(AST_BLOCK);
ast_stack.back()->children.push_back(node);
ast_stack.push_back(node);
append_attr(node, $1);
if ($4 != NULL)
node->str = *$4;
} behavioral_stmt_list TOK_END opt_label {
exitTypeScope();
checkLabelsMatch("Begin label", $4, $8);
AstNode *node = ast_stack.back();
// In SystemVerilog, unnamed blocks with block item declarations
// create an implicit hierarchy scope
if (sv_mode && node->str.empty())
for (const AstNode* child : node->children)
if (child->type == AST_WIRE || child->type == AST_MEMORY || child->type == AST_PARAMETER
|| child->type == AST_LOCALPARAM || child->type == AST_TYPEDEF) {
node->str = "$unnamed_block$" + std::to_string(autoidx++);
break;
}
SET_AST_NODE_LOC(ast_stack.back(), @2, @8);
delete $4;
delete $8;
ast_stack.pop_back();
} |
attr TOK_FOR '(' {
AstNode *node = new AstNode(AST_FOR);
ast_stack.back()->children.push_back(node);
ast_stack.push_back(node);
append_attr(node, $1);
} for_initialization ';' expr {
ast_stack.back()->children.push_back($7);
} ';' simple_behavioral_stmt ')' {
AstNode *block = new AstNode(AST_BLOCK);
block->str = "$for_loop$" + std::to_string(autoidx++);
ast_stack.back()->children.push_back(block);
ast_stack.push_back(block);
} behavioral_stmt {
SET_AST_NODE_LOC(ast_stack.back(), @13, @13);
ast_stack.pop_back();
SET_AST_NODE_LOC(ast_stack.back(), @2, @13);
ast_stack.pop_back();
} |
attr TOK_WHILE '(' expr ')' {
AstNode *node = new AstNode(AST_WHILE);
ast_stack.back()->children.push_back(node);
ast_stack.push_back(node);
append_attr(node, $1);
AstNode *block = new AstNode(AST_BLOCK);
ast_stack.back()->children.push_back($4);
ast_stack.back()->children.push_back(block);
ast_stack.push_back(block);
} behavioral_stmt {
SET_AST_NODE_LOC(ast_stack.back(), @7, @7);
ast_stack.pop_back();
ast_stack.pop_back();
} |
attr TOK_REPEAT '(' expr ')' {
AstNode *node = new AstNode(AST_REPEAT);
ast_stack.back()->children.push_back(node);
ast_stack.push_back(node);
append_attr(node, $1);
AstNode *block = new AstNode(AST_BLOCK);
ast_stack.back()->children.push_back($4);
ast_stack.back()->children.push_back(block);
ast_stack.push_back(block);
} behavioral_stmt {
SET_AST_NODE_LOC(ast_stack.back(), @7, @7);
ast_stack.pop_back();
ast_stack.pop_back();
} |
attr TOK_IF '(' expr ')' {
AstNode *node = new AstNode(AST_CASE);
AstNode *block = new AstNode(AST_BLOCK);
AstNode *cond = new AstNode(AST_COND, AstNode::mkconst_int(1, false, 1), block);
SET_AST_NODE_LOC(cond, @4, @4);
ast_stack.back()->children.push_back(node);
node->children.push_back(new AstNode(AST_REDUCE_BOOL, $4));
node->children.push_back(cond);
ast_stack.push_back(node);
ast_stack.push_back(block);
append_attr(node, $1);
} behavioral_stmt {
SET_AST_NODE_LOC(ast_stack.back(), @7, @7);
} optional_else {
ast_stack.pop_back();
SET_AST_NODE_LOC(ast_stack.back(), @2, @9);
ast_stack.pop_back();
} |
case_attr case_type '(' expr ')' {
AstNode *node = new AstNode(AST_CASE, $4);
ast_stack.back()->children.push_back(node);
ast_stack.push_back(node);
append_attr(node, $1);
SET_AST_NODE_LOC(ast_stack.back(), @4, @4);
} opt_synopsys_attr case_body TOK_ENDCASE {
SET_AST_NODE_LOC(ast_stack.back(), @2, @9);
case_type_stack.pop_back();
ast_stack.pop_back();
};
case_attr:
attr {
$$ = $1;
} |
attr TOK_UNIQUE0 {
(*$1)[ID::parallel_case] = AstNode::mkconst_int(1, false);
$$ = $1;
} |
attr TOK_PRIORITY {
(*$1)[ID::full_case] = AstNode::mkconst_int(1, false);
$$ = $1;
} |
attr TOK_UNIQUE {
(*$1)[ID::full_case] = AstNode::mkconst_int(1, false);
(*$1)[ID::parallel_case] = AstNode::mkconst_int(1, false);
$$ = $1;
};
case_type:
TOK_CASE {
case_type_stack.push_back(0);
} |
TOK_CASEX {
case_type_stack.push_back('x');
} |
TOK_CASEZ {
case_type_stack.push_back('z');
};
opt_synopsys_attr:
opt_synopsys_attr TOK_SYNOPSYS_FULL_CASE {
if (ast_stack.back()->attributes.count(ID::full_case) == 0)
ast_stack.back()->attributes[ID::full_case] = AstNode::mkconst_int(1, false);
} |
opt_synopsys_attr TOK_SYNOPSYS_PARALLEL_CASE {
if (ast_stack.back()->attributes.count(ID::parallel_case) == 0)
ast_stack.back()->attributes[ID::parallel_case] = AstNode::mkconst_int(1, false);
} |
%empty;
behavioral_stmt_list:
behavioral_stmt_list behavioral_stmt |
%empty;
optional_else:
TOK_ELSE {
AstNode *block = new AstNode(AST_BLOCK);
AstNode *cond = new AstNode(AST_COND, new AstNode(AST_DEFAULT), block);
SET_AST_NODE_LOC(cond, @1, @1);
ast_stack.pop_back();
ast_stack.back()->children.push_back(cond);
ast_stack.push_back(block);
} behavioral_stmt {
SET_AST_NODE_LOC(ast_stack.back(), @3, @3);
} |
%empty %prec FAKE_THEN;
case_body:
case_body case_item |
%empty;
case_item:
{
AstNode *node = new AstNode(
case_type_stack.size() && case_type_stack.back() == 'x' ? AST_CONDX :
case_type_stack.size() && case_type_stack.back() == 'z' ? AST_CONDZ : AST_COND);
ast_stack.back()->children.push_back(node);
ast_stack.push_back(node);
} case_select {
AstNode *block = new AstNode(AST_BLOCK);
ast_stack.back()->children.push_back(block);
ast_stack.push_back(block);
case_type_stack.push_back(0);
} behavioral_stmt {
case_type_stack.pop_back();
SET_AST_NODE_LOC(ast_stack.back(), @4, @4);
ast_stack.pop_back();
ast_stack.pop_back();
};
gen_case_body:
gen_case_body gen_case_item |
%empty;
gen_case_item:
{
AstNode *node = new AstNode(
case_type_stack.size() && case_type_stack.back() == 'x' ? AST_CONDX :
case_type_stack.size() && case_type_stack.back() == 'z' ? AST_CONDZ : AST_COND);
ast_stack.back()->children.push_back(node);
ast_stack.push_back(node);
} case_select {
case_type_stack.push_back(0);
SET_AST_NODE_LOC(ast_stack.back(), @2, @2);
} gen_stmt_block {
case_type_stack.pop_back();
ast_stack.pop_back();
};
case_select:
case_expr_list ':' |
TOK_DEFAULT;
case_expr_list:
TOK_DEFAULT {
AstNode *node = new AstNode(AST_DEFAULT);
SET_AST_NODE_LOC(node, @1, @1);
ast_stack.back()->children.push_back(node);
} |
TOK_SVA_LABEL {
AstNode *node = new AstNode(AST_IDENTIFIER);
SET_AST_NODE_LOC(node, @1, @1);
ast_stack.back()->children.push_back(node);
ast_stack.back()->children.back()->str = *$1;
delete $1;
} |
expr {
ast_stack.back()->children.push_back($1);
} |
case_expr_list ',' expr {
ast_stack.back()->children.push_back($3);
};
rvalue:
hierarchical_id '[' expr ']' '.' rvalue {
$$ = new AstNode(AST_PREFIX, $3, $6);
$$->str = *$1;
SET_AST_NODE_LOC($$, @1, @6);
delete $1;
} |
hierarchical_id range {
$$ = new AstNode(AST_IDENTIFIER, $2);
$$->str = *$1;
SET_AST_NODE_LOC($$, @1, @1);
delete $1;
if ($2 == nullptr && ($$->str == "\\$initstate" ||
$$->str == "\\$anyconst" || $$->str == "\\$anyseq" ||
$$->str == "\\$allconst" || $$->str == "\\$allseq"))
$$->type = AST_FCALL;
} |
hierarchical_id non_opt_multirange {
$$ = new AstNode(AST_IDENTIFIER, $2);
$$->str = *$1;
SET_AST_NODE_LOC($$, @1, @1);
delete $1;
};
lvalue:
rvalue {
$$ = $1;
} |
'{' lvalue_concat_list '}' {
$$ = $2;
};
lvalue_concat_list:
expr {
$$ = new AstNode(AST_CONCAT);
$$->children.push_back($1);
} |
expr ',' lvalue_concat_list {
$$ = $3;
$$->children.push_back($1);
};
opt_arg_list:
'(' arg_list optional_comma ')' |
%empty;
arg_list:
arg_list2 |
%empty;
arg_list2:
single_arg |
arg_list ',' single_arg;
single_arg:
expr {
ast_stack.back()->children.push_back($1);
};
module_gen_body:
module_gen_body gen_stmt_or_module_body_stmt |
module_gen_body gen_block |
%empty;
gen_stmt_or_module_body_stmt:
gen_stmt | module_body_stmt |
attr ';' {
free_attr($1);
};
genvar_identifier:
TOK_ID {
$$ = new AstNode(AST_IDENTIFIER);
$$->str = *$1;
delete $1;
};
genvar_initialization:
TOK_GENVAR genvar_identifier {
frontend_verilog_yyerror("Generate for loop variable declaration is missing initialization!");
} |
TOK_GENVAR genvar_identifier '=' expr {
if (!sv_mode)
frontend_verilog_yyerror("Generate for loop inline variable declaration is only supported in SystemVerilog mode!");
AstNode *node = new AstNode(AST_GENVAR);
node->is_reg = true;
node->is_signed = true;
node->range_left = 31;
node->range_right = 0;
node->str = $2->str;
node->children.push_back(checkRange(node, nullptr));
ast_stack.back()->children.push_back(node);
SET_AST_NODE_LOC(node, @1, @4);
node = new AstNode(AST_ASSIGN_EQ, $2, $4);
ast_stack.back()->children.push_back(node);
SET_AST_NODE_LOC(node, @1, @4);
} |
genvar_identifier '=' expr {
AstNode *node = new AstNode(AST_ASSIGN_EQ, $1, $3);
ast_stack.back()->children.push_back(node);
SET_AST_NODE_LOC(node, @1, @3);
};
// this production creates the obligatory if-else shift/reduce conflict
gen_stmt:
TOK_FOR '(' {
AstNode *node = new AstNode(AST_GENFOR);
ast_stack.back()->children.push_back(node);
ast_stack.push_back(node);
} genvar_initialization ';' expr {
ast_stack.back()->children.push_back($6);
} ';' simple_behavioral_stmt ')' gen_stmt_block {
SET_AST_NODE_LOC(ast_stack.back(), @1, @11);
rewriteGenForDeclInit(ast_stack.back());
ast_stack.pop_back();
} |
TOK_IF '(' expr ')' {
AstNode *node = new AstNode(AST_GENIF);
ast_stack.back()->children.push_back(node);
ast_stack.push_back(node);
ast_stack.back()->children.push_back($3);
} gen_stmt_block opt_gen_else {
SET_AST_NODE_LOC(ast_stack.back(), @1, @7);
ast_stack.pop_back();
} |
case_type '(' expr ')' {
AstNode *node = new AstNode(AST_GENCASE, $3);
ast_stack.back()->children.push_back(node);
ast_stack.push_back(node);
} gen_case_body TOK_ENDCASE {
case_type_stack.pop_back();
SET_AST_NODE_LOC(ast_stack.back(), @1, @7);
ast_stack.pop_back();
} |
TOK_MSG_TASKS {
AstNode *node = new AstNode(AST_TECALL);
node->str = *$1;
delete $1;
ast_stack.back()->children.push_back(node);
ast_stack.push_back(node);
} opt_arg_list ';'{
SET_AST_NODE_LOC(ast_stack.back(), @1, @3);
ast_stack.pop_back();
};
gen_block:
TOK_BEGIN {
enterTypeScope();
} opt_label {
AstNode *node = new AstNode(AST_GENBLOCK);
node->str = $3 ? *$3 : std::string();
ast_stack.back()->children.push_back(node);
ast_stack.push_back(node);
} module_gen_body TOK_END opt_label {
exitTypeScope();
checkLabelsMatch("Begin label", $3, $7);
delete $3;
delete $7;
SET_AST_NODE_LOC(ast_stack.back(), @1, @7);
ast_stack.pop_back();
};
// result is wrapped in a genblock only if necessary
gen_stmt_block:
{
AstNode *node = new AstNode(AST_GENBLOCK);
ast_stack.back()->children.push_back(node);
ast_stack.push_back(node);
} gen_stmt_or_module_body_stmt {
SET_AST_NODE_LOC(ast_stack.back(), @2, @2);
ast_stack.pop_back();
} | gen_block;
opt_gen_else:
TOK_ELSE gen_stmt_block | %empty %prec FAKE_THEN;
expr:
basic_expr {
$$ = $1;
} |
basic_expr '?' attr expr ':' expr {
$$ = new AstNode(AST_TERNARY);
$$->children.push_back($1);
$$->children.push_back($4);
$$->children.push_back($6);
SET_AST_NODE_LOC($$, @1, @$);
append_attr($$, $3);
};
basic_expr:
rvalue {
$$ = $1;
} |
'(' expr ')' integral_number {
if ($4->compare(0, 1, "'") != 0)
frontend_verilog_yyerror("Cast operation must be applied on sized constants e.g. (<expr>)<constval> , while %s is not a sized constant.", $4->c_str());
AstNode *bits = $2;
AstNode *val = const2ast(*$4, case_type_stack.size() == 0 ? 0 : case_type_stack.back(), !lib_mode);
if (val == NULL)
log_error("Value conversion failed: `%s'\n", $4->c_str());
$$ = new AstNode(AST_TO_BITS, bits, val);
delete $4;
} |
hierarchical_id integral_number {
if ($2->compare(0, 1, "'") != 0)
frontend_verilog_yyerror("Cast operation must be applied on sized constants, e.g. <ID>\'d0, while %s is not a sized constant.", $2->c_str());
AstNode *bits = new AstNode(AST_IDENTIFIER);
bits->str = *$1;
SET_AST_NODE_LOC(bits, @1, @1);
AstNode *val = const2ast(*$2, case_type_stack.size() == 0 ? 0 : case_type_stack.back(), !lib_mode);
SET_AST_NODE_LOC(val, @2, @2);
if (val == NULL)
log_error("Value conversion failed: `%s'\n", $2->c_str());
$$ = new AstNode(AST_TO_BITS, bits, val);
delete $1;
delete $2;
} |
integral_number {
$$ = const2ast(*$1, case_type_stack.size() == 0 ? 0 : case_type_stack.back(), !lib_mode);
SET_AST_NODE_LOC($$, @1, @1);
if ($$ == NULL)
log_error("Value conversion failed: `%s'\n", $1->c_str());
delete $1;
} |
TOK_REALVAL {
$$ = new AstNode(AST_REALVALUE);
char *p = (char*)malloc(GetSize(*$1) + 1), *q;
for (int i = 0, j = 0; j < GetSize(*$1); j++)
if ((*$1)[j] != '_')
p[i++] = (*$1)[j], p[i] = 0;
$$->realvalue = strtod(p, &q);
SET_AST_NODE_LOC($$, @1, @1);
log_assert(*q == 0);
delete $1;
free(p);
} |
TOK_STRING {
$$ = AstNode::mkconst_str(*$1);
SET_AST_NODE_LOC($$, @1, @1);
delete $1;
} |
hierarchical_id attr {
AstNode *node = new AstNode(AST_FCALL);
node->str = *$1;
delete $1;
ast_stack.push_back(node);
SET_AST_NODE_LOC(node, @1, @1);
append_attr(node, $2);
} '(' arg_list optional_comma ')' {
$$ = ast_stack.back();
ast_stack.pop_back();
} |
TOK_TO_SIGNED attr '(' expr ')' {
$$ = new AstNode(AST_TO_SIGNED, $4);
append_attr($$, $2);
} |
TOK_TO_UNSIGNED attr '(' expr ')' {
$$ = new AstNode(AST_TO_UNSIGNED, $4);
append_attr($$, $2);
} |
'(' expr ')' {
$$ = $2;
} |
'(' expr ':' expr ':' expr ')' {
delete $2;
$$ = $4;
delete $6;
} |
'{' concat_list '}' {
$$ = $2;
} |
'{' expr '{' concat_list '}' '}' {
$$ = new AstNode(AST_REPLICATE, $2, $4);
} |
'~' attr basic_expr %prec UNARY_OPS {
$$ = new AstNode(AST_BIT_NOT, $3);
SET_AST_NODE_LOC($$, @1, @3);
append_attr($$, $2);
} |
basic_expr '&' attr basic_expr {
$$ = new AstNode(AST_BIT_AND, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr OP_NAND attr basic_expr {
$$ = new AstNode(AST_BIT_NOT, new AstNode(AST_BIT_AND, $1, $4));
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr '|' attr basic_expr {
$$ = new AstNode(AST_BIT_OR, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr OP_NOR attr basic_expr {
$$ = new AstNode(AST_BIT_NOT, new AstNode(AST_BIT_OR, $1, $4));
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr '^' attr basic_expr {
$$ = new AstNode(AST_BIT_XOR, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr OP_XNOR attr basic_expr {
$$ = new AstNode(AST_BIT_XNOR, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
'&' attr basic_expr %prec UNARY_OPS {
$$ = new AstNode(AST_REDUCE_AND, $3);
SET_AST_NODE_LOC($$, @1, @3);
append_attr($$, $2);
} |
OP_NAND attr basic_expr %prec UNARY_OPS {
$$ = new AstNode(AST_REDUCE_AND, $3);
SET_AST_NODE_LOC($$, @1, @3);
append_attr($$, $2);
$$ = new AstNode(AST_LOGIC_NOT, $$);
} |
'|' attr basic_expr %prec UNARY_OPS {
$$ = new AstNode(AST_REDUCE_OR, $3);
SET_AST_NODE_LOC($$, @1, @3);
append_attr($$, $2);
} |
OP_NOR attr basic_expr %prec UNARY_OPS {
$$ = new AstNode(AST_REDUCE_OR, $3);
SET_AST_NODE_LOC($$, @1, @3);
append_attr($$, $2);
$$ = new AstNode(AST_LOGIC_NOT, $$);
SET_AST_NODE_LOC($$, @1, @3);
} |
'^' attr basic_expr %prec UNARY_OPS {
$$ = new AstNode(AST_REDUCE_XOR, $3);
SET_AST_NODE_LOC($$, @1, @3);
append_attr($$, $2);
} |
OP_XNOR attr basic_expr %prec UNARY_OPS {
$$ = new AstNode(AST_REDUCE_XNOR, $3);
SET_AST_NODE_LOC($$, @1, @3);
append_attr($$, $2);
} |
basic_expr OP_SHL attr basic_expr {
$$ = new AstNode(AST_SHIFT_LEFT, $1, new AstNode(AST_TO_UNSIGNED, $4));
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr OP_SHR attr basic_expr {
$$ = new AstNode(AST_SHIFT_RIGHT, $1, new AstNode(AST_TO_UNSIGNED, $4));
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr OP_SSHL attr basic_expr {
$$ = new AstNode(AST_SHIFT_SLEFT, $1, new AstNode(AST_TO_UNSIGNED, $4));
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr OP_SSHR attr basic_expr {
$$ = new AstNode(AST_SHIFT_SRIGHT, $1, new AstNode(AST_TO_UNSIGNED, $4));
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr '<' attr basic_expr {
$$ = new AstNode(AST_LT, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr OP_LE attr basic_expr {
$$ = new AstNode(AST_LE, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr OP_EQ attr basic_expr {
$$ = new AstNode(AST_EQ, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr OP_NE attr basic_expr {
$$ = new AstNode(AST_NE, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr OP_EQX attr basic_expr {
$$ = new AstNode(AST_EQX, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr OP_NEX attr basic_expr {
$$ = new AstNode(AST_NEX, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr OP_GE attr basic_expr {
$$ = new AstNode(AST_GE, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr '>' attr basic_expr {
$$ = new AstNode(AST_GT, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr '+' attr basic_expr {
$$ = new AstNode(AST_ADD, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr '-' attr basic_expr {
$$ = new AstNode(AST_SUB, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr '*' attr basic_expr {
$$ = new AstNode(AST_MUL, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr '/' attr basic_expr {
$$ = new AstNode(AST_DIV, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr '%' attr basic_expr {
$$ = new AstNode(AST_MOD, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr OP_POW attr basic_expr {
$$ = new AstNode(AST_POW, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
'+' attr basic_expr %prec UNARY_OPS {
$$ = new AstNode(AST_POS, $3);
SET_AST_NODE_LOC($$, @1, @3);
append_attr($$, $2);
} |
'-' attr basic_expr %prec UNARY_OPS {
$$ = new AstNode(AST_NEG, $3);
SET_AST_NODE_LOC($$, @1, @3);
append_attr($$, $2);
} |
basic_expr OP_LAND attr basic_expr {
$$ = new AstNode(AST_LOGIC_AND, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
basic_expr OP_LOR attr basic_expr {
$$ = new AstNode(AST_LOGIC_OR, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
append_attr($$, $3);
} |
'!' attr basic_expr %prec UNARY_OPS {
$$ = new AstNode(AST_LOGIC_NOT, $3);
SET_AST_NODE_LOC($$, @1, @3);
append_attr($$, $2);
} |
TOK_SIGNED OP_CAST '(' expr ')' {
if (!sv_mode)
frontend_verilog_yyerror("Static cast is only supported in SystemVerilog mode.");
$$ = new AstNode(AST_TO_SIGNED, $4);
SET_AST_NODE_LOC($$, @1, @4);
} |
TOK_UNSIGNED OP_CAST '(' expr ')' {
if (!sv_mode)
frontend_verilog_yyerror("Static cast is only supported in SystemVerilog mode.");
$$ = new AstNode(AST_TO_UNSIGNED, $4);
SET_AST_NODE_LOC($$, @1, @4);
} |
basic_expr OP_CAST '(' expr ')' {
if (!sv_mode)
frontend_verilog_yyerror("Static cast is only supported in SystemVerilog mode.");
$$ = new AstNode(AST_CAST_SIZE, $1, $4);
SET_AST_NODE_LOC($$, @1, @4);
};
concat_list:
expr {
$$ = new AstNode(AST_CONCAT, $1);
} |
expr ',' concat_list {
$$ = $3;
$$->children.push_back($1);
};
integral_number:
TOK_CONSTVAL { $$ = $1; } |
TOK_UNBASED_UNSIZED_CONSTVAL { $$ = $1; } |
TOK_BASE TOK_BASED_CONSTVAL {
$1->append(*$2);
$$ = $1;
delete $2;
} |
TOK_CONSTVAL TOK_BASE TOK_BASED_CONSTVAL {
$1->append(*$2).append(*$3);
$$ = $1;
delete $2;
delete $3;
};