riscv
/
yosys
mirror of https://github.com/YosysHQ/yosys.git
1
0
Fork 0
Code Issues Projects Releases Wiki Activity
yosys/frontends/ast/simplify.cc

5732 lines
196 KiB
C++
Raw Permalink Blame History

/*
* 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.
*
* ---
*
* This is the AST frontend library.
*
* The AST frontend library is not a frontend on it's own but provides a
* generic abstract syntax tree (AST) abstraction for HDL code and can be
* used by HDL frontends. See "ast.h" for an overview of the API and the
* Verilog frontend for an usage example.
*
*/
#include "kernel/log.h"
#include "libs/sha1/sha1.h"
#include "frontends/verilog/verilog_frontend.h"
#include "ast.h"
#include <sstream>
#include <stdarg.h>
#include <stdlib.h>
#include <math.h>
// For std::gcd in C++17
// #include <numeric>
YOSYS_NAMESPACE_BEGIN
using namespace AST;
using namespace AST_INTERNAL;
// gcd computed by Euclidian division.
// To be replaced by C++17 std::gcd
template<class I> I gcd(I a, I b) {
while (b != 0) {
I tmp = b;
b = a%b;
a = tmp;
}
return std::abs(a);
}
void AstNode::set_in_lvalue_flag(bool flag, bool no_descend)
{
if (flag != in_lvalue_from_above) {
in_lvalue_from_above = flag;
if (!no_descend)
fixup_hierarchy_flags();
}
}
void AstNode::set_in_param_flag(bool flag, bool no_descend)
{
if (flag != in_param_from_above) {
in_param_from_above = flag;
if (!no_descend)
fixup_hierarchy_flags();
}
}
void AstNode::fixup_hierarchy_flags(bool force_descend)
{
// With forced descend, we disable the implicit
// descend from within the set_* functions, instead
// we do an explicit descend at the end of this function
in_param = in_param_from_above;
switch (type) {
case AST_PARAMETER:
case AST_LOCALPARAM:
case AST_DEFPARAM:
case AST_PARASET:
case AST_PREFIX:
in_param = true;
for (auto child : children)
child->set_in_param_flag(true, force_descend);
break;
case AST_REPLICATE:
case AST_WIRE:
case AST_GENIF:
case AST_GENCASE:
for (auto child : children)
child->set_in_param_flag(in_param, force_descend);
if (children.size() >= 1)
children[0]->set_in_param_flag(true, force_descend);
break;
case AST_GENFOR:
case AST_FOR:
for (auto child : children)
child->set_in_param_flag(in_param, force_descend);
if (children.size() >= 2)
children[1]->set_in_param_flag(true, force_descend);
break;
default:
in_param = in_param_from_above;
for (auto child : children)
child->set_in_param_flag(in_param, force_descend);
}
for (auto attr : attributes)
attr.second->set_in_param_flag(true, force_descend);
in_lvalue = in_lvalue_from_above;
switch (type) {
case AST_ASSIGN:
case AST_ASSIGN_EQ:
case AST_ASSIGN_LE:
if (children.size() >= 1)
children[0]->set_in_lvalue_flag(true, force_descend);
if (children.size() >= 2)
children[1]->set_in_lvalue_flag(in_lvalue, force_descend);
break;
default:
for (auto child : children)
child->set_in_lvalue_flag(in_lvalue, force_descend);
}
if (force_descend) {
for (auto child : children)
child->fixup_hierarchy_flags(true);
for (auto attr : attributes)
attr.second->fixup_hierarchy_flags(true);
}
}
// Process a format string and arguments for $display, $write, $sprintf, etc
Fmt AstNode::processFormat(int stage, bool sformat_like, int default_base, size_t first_arg_at, bool may_fail) {
std::vector<VerilogFmtArg> args;
for (size_t index = first_arg_at; index < children.size(); index++) {
AstNode *node_arg = children[index];
while (node_arg->simplify(true, stage, -1, false)) { }
VerilogFmtArg arg = {};
arg.filename = filename;
arg.first_line = location.first_line;
if (node_arg->type == AST_CONSTANT && node_arg->is_string) {
arg.type = VerilogFmtArg::STRING;
arg.str = node_arg->bitsAsConst().decode_string();
// and in case this will be used as an argument...
arg.sig = node_arg->bitsAsConst();
arg.signed_ = false;
} else if (node_arg->type == AST_IDENTIFIER && node_arg->str == "$time") {
arg.type = VerilogFmtArg::TIME;
} else if (node_arg->type == AST_IDENTIFIER && node_arg->str == "$realtime") {
arg.type = VerilogFmtArg::TIME;
arg.realtime = true;
} else if (node_arg->type == AST_CONSTANT) {
arg.type = VerilogFmtArg::INTEGER;
arg.sig = node_arg->bitsAsConst();
arg.signed_ = node_arg->is_signed;
} else if (may_fail) {
log_file_info(filename, location.first_line, "Skipping system task `%s' with non-constant argument at position %zu.\n", str.c_str(), index + 1);
return Fmt();
} else {
log_file_error(filename, location.first_line, "Failed to evaluate system task `%s' with non-constant argument at position %zu.\n", str.c_str(), index + 1);
}
args.push_back(arg);
}
Fmt fmt;
fmt.parse_verilog(args, sformat_like, default_base, /*task_name=*/str, current_module->name);
return fmt;
}
void AstNode::annotateTypedEnums(AstNode *template_node)
{
//check if enum
if (template_node->attributes.count(ID::enum_type)) {
//get reference to enum node:
std::string enum_type = template_node->attributes[ID::enum_type]->str.c_str();
// log("enum_type=%s (count=%lu)\n", enum_type.c_str(), current_scope.count(enum_type));
// log("current scope:\n");
// for (auto &it : current_scope)
// log(" %s\n", it.first.c_str());
log_assert(current_scope.count(enum_type) == 1);
AstNode *enum_node = current_scope.at(enum_type);
log_assert(enum_node->type == AST_ENUM);
while (enum_node->simplify(true, 1, -1, false)) { }
//get width from 1st enum item:
log_assert(enum_node->children.size() >= 1);
AstNode *enum_item0 = enum_node->children[0];
log_assert(enum_item0->type == AST_ENUM_ITEM);
int width;
if (!enum_item0->range_valid)
width = 1;
else if (enum_item0->range_swapped)
width = enum_item0->range_right - enum_item0->range_left + 1;
else
width = enum_item0->range_left - enum_item0->range_right + 1;
log_assert(width > 0);
//add declared enum items:
for (auto enum_item : enum_node->children){
log_assert(enum_item->type == AST_ENUM_ITEM);
//get is_signed
bool is_signed;
if (enum_item->children.size() == 1){
is_signed = false;
} else if (enum_item->children.size() == 2){
log_assert(enum_item->children[1]->type == AST_RANGE);
is_signed = enum_item->children[1]->is_signed;
} else {
log_error("enum_item children size==%zu, expected 1 or 2 for %s (%s)\n",
(size_t) enum_item->children.size(),
enum_item->str.c_str(), enum_node->str.c_str()
);
}
//start building attribute string
std::string enum_item_str = "\\enum_value_";
//get enum item value
if(enum_item->children[0]->type != AST_CONSTANT){
log_error("expected const, got %s for %s (%s)\n",
type2str(enum_item->children[0]->type).c_str(),
enum_item->str.c_str(), enum_node->str.c_str()
);
}
RTLIL::Const val = enum_item->children[0]->bitsAsConst(width, is_signed);
enum_item_str.append(val.as_string());
//set attribute for available val to enum item name mappings
set_attribute(enum_item_str.c_str(), mkconst_str(enum_item->str));
}
}
}
static AstNode *make_range(int left, int right, bool is_signed = false)
{
// generate a pre-validated range node for a fixed signal range.
auto range = new AstNode(AST_RANGE);
range->range_left = left;
range->range_right = right;
range->range_valid = true;
range->children.push_back(AstNode::mkconst_int(left, true));
range->children.push_back(AstNode::mkconst_int(right, true));
range->is_signed = is_signed;
return range;
}
static int range_width(AstNode *node, AstNode *rnode)
{
log_assert(rnode->type==AST_RANGE);
if (!rnode->range_valid) {
node->input_error("Non-constant range in declaration of %s\n", node->str.c_str());
}
// note: range swapping has already been checked for
return rnode->range_left - rnode->range_right + 1;
}
static int add_dimension(AstNode *node, AstNode *rnode)
{
int width = range_width(node, rnode);
node->dimensions.push_back({ rnode->range_right, width, rnode->range_swapped });
return width;
}
[[noreturn]] static void struct_array_packing_error(AstNode *node)
{
node->input_error("Unpacked array in packed struct/union member %s\n", node->str.c_str());
}
static int size_packed_struct(AstNode *snode, int base_offset)
{
// Struct members will be laid out in the structure contiguously from left to right.
// Union members all have zero offset from the start of the union.
// Determine total packed size and assign offsets. Store these in the member node.
bool is_union = (snode->type == AST_UNION);
int offset = 0;
int packed_width = -1;
// examine members from last to first
for (auto it = snode->children.rbegin(); it != snode->children.rend(); ++it) {
auto node = *it;
int width;
if (node->type == AST_STRUCT || node->type == AST_UNION) {
// embedded struct or union
width = size_packed_struct(node, base_offset + offset);
}
else {
log_assert(node->type == AST_STRUCT_ITEM);
if (node->children.size() > 0 && node->children[0]->type == AST_RANGE) {
// member width e.g. bit [7:0] a
width = range_width(node, node->children[0]);
if (node->children.size() == 2) {
// Unpacked array. Note that this is a Yosys extension; only packed data types
// and integer data types are allowed in packed structs / unions in SystemVerilog.
if (node->children[1]->type == AST_RANGE) {
// Unpacked array, e.g. bit [63:0] a [0:3]
// Pretend it's declared as a packed array, e.g. bit [0:3][63:0] a
auto rnode = node->children[1];
if (rnode->children.size() == 1) {
// C-style array size, e.g. bit [63:0] a [4]
node->dimensions.push_back({ 0, rnode->range_left, true });
width *= rnode->range_left;
} else {
width *= add_dimension(node, rnode);
}
add_dimension(node, node->children[0]);
}
else {
// The Yosys extension for unpacked arrays in packed structs / unions
// only supports memories, i.e. e.g. logic [7:0] a [256] - see above.
struct_array_packing_error(node);
}
} else {
// Vector
add_dimension(node, node->children[0]);
}
// range nodes are now redundant
for (AstNode *child : node->children)
delete child;
node->children.clear();
}
else if (node->children.size() > 0 && node->children[0]->type == AST_MULTIRANGE) {
// Packed array, e.g. bit [3:0][63:0] a
if (node->children.size() != 1) {
// The Yosys extension for unpacked arrays in packed structs / unions
// only supports memories, i.e. e.g. logic [7:0] a [256] - see above.
struct_array_packing_error(node);
}
width = 1;
for (auto rnode : node->children[0]->children) {
width *= add_dimension(node, rnode);
}
// range nodes are now redundant
for (AstNode *child : node->children)
delete child;
node->children.clear();
}
else if (node->range_left < 0) {
// 1 bit signal: bit, logic or reg
width = 1;
node->dimensions.push_back({ 0, width, false });
}
else {
// already resolved and compacted
width = node->range_left - node->range_right + 1;
}
if (is_union) {
node->range_right = base_offset;
node->range_left = base_offset + width - 1;
}
else {
node->range_right = base_offset + offset;
node->range_left = base_offset + offset + width - 1;
}
node->range_valid = true;
}
if (is_union) {
// check that all members have the same size
if (packed_width == -1) {
// first member
packed_width = width;
}
else {
if (packed_width != width)
node->input_error("member %s of a packed union has %d bits, expecting %d\n", node->str.c_str(), width, packed_width);
}
}
else {
offset += width;
}
}
int width = is_union ? packed_width : offset;
snode->range_right = base_offset;
snode->range_left = base_offset + width - 1;
snode->range_valid = true;
snode->dimensions.push_back({ 0, width, false });
return width;
}
static AstNode *node_int(int ival)
{
return AstNode::mkconst_int(ival, true);
}
static AstNode *multiply_by_const(AstNode *expr_node, int stride)
{
return new AstNode(AST_MUL, expr_node, node_int(stride));
}
static AstNode *normalize_index(AstNode *expr, AstNode *decl_node, int dimension)
{
expr = expr->clone();
int offset = decl_node->dimensions[dimension].range_right;
if (offset) {
expr = new AstNode(AST_SUB, expr, node_int(offset));
}
// Packed dimensions are normally indexed by lsb, while unpacked dimensions are normally indexed by msb.
if ((dimension < decl_node->unpacked_dimensions) ^ decl_node->dimensions[dimension].range_swapped) {
// Swap the index if the dimension is declared the "wrong" way.
int left = decl_node->dimensions[dimension].range_width - 1;
expr = new AstNode(AST_SUB, node_int(left), expr);
}
return expr;
}
static AstNode *index_offset(AstNode *offset, AstNode *rnode, AstNode *decl_node, int dimension, int &stride)
{
stride /= decl_node->dimensions[dimension].range_width;
auto right = normalize_index(rnode->children.back(), decl_node, dimension);
auto add_offset = stride > 1 ? multiply_by_const(right, stride) : right;
return offset ? new AstNode(AST_ADD, offset, add_offset) : add_offset;
}
static AstNode *index_msb_offset(AstNode *lsb_offset, AstNode *rnode, AstNode *decl_node, int dimension, int stride)
{
log_assert(rnode->children.size() <= 2);
// Offset to add to LSB
AstNode *add_offset;
if (rnode->children.size() == 1) {
// Index, e.g. s.a[i]
add_offset = node_int(stride - 1);
}
else {
// rnode->children.size() == 2
// Slice, e.g. s.a[i:j]
auto left = normalize_index(rnode->children[0], decl_node, dimension);
auto right = normalize_index(rnode->children[1], decl_node, dimension);
add_offset = new AstNode(AST_SUB, left, right);
if (stride > 1) {
// offset = (msb - lsb + 1)*stride - 1
auto slice_width = new AstNode(AST_ADD, add_offset, node_int(1));
add_offset = new AstNode(AST_SUB, multiply_by_const(slice_width, stride), node_int(1));
}
}
return new AstNode(AST_ADD, lsb_offset, add_offset);
}
AstNode *AstNode::make_index_range(AstNode *decl_node, bool unpacked_range)
{
// Work out the range in the packed array that corresponds to a struct member
// taking into account any range operations applicable to the current node
// such as array indexing or slicing
if (children.empty()) {
// no range operations apply, return the whole width
return make_range(decl_node->range_left - decl_node->range_right, 0);
}
log_assert(children.size() == 1);
// Range operations
AstNode *rnode = children[0];
AstNode *offset = NULL;
int dim = unpacked_range ? 0 : decl_node->unpacked_dimensions;
int max_dim = unpacked_range ? decl_node->unpacked_dimensions : GetSize(decl_node->dimensions);
int stride = 1;
for (int i = dim; i < max_dim; i++) {
stride *= decl_node->dimensions[i].range_width;
}
// Calculate LSB offset for the final index / slice
if (rnode->type == AST_RANGE) {
offset = index_offset(offset, rnode, decl_node, dim, stride);
}
else if (rnode->type == AST_MULTIRANGE) {
// Add offset for each dimension
AstNode *mrnode = rnode;
int stop_dim = std::min(GetSize(mrnode->children), max_dim);
for (; dim < stop_dim; dim++) {
rnode = mrnode->children[dim];
offset = index_offset(offset, rnode, decl_node, dim, stride);
}
dim--; // Step back to the final index / slice
}
else {
input_error("Unsupported range operation for %s\n", str.c_str());
}
AstNode *index_range = new AstNode(AST_RANGE);
if (!unpacked_range && (stride > 1 || GetSize(rnode->children) == 2)) {
// Calculate MSB offset for the final index / slice of packed dimensions.
AstNode *msb_offset = index_msb_offset(offset->clone(), rnode, decl_node, dim, stride);
index_range->children.push_back(msb_offset);
}
index_range->children.push_back(offset);
return index_range;
}
AstNode *AstNode::get_struct_member() const
{
AstNode *member_node;
if (attributes.count(ID::wiretype) && (member_node = attributes.at(ID::wiretype)) &&
(member_node->type == AST_STRUCT_ITEM || member_node->type == AST_STRUCT || member_node->type == AST_UNION))
{
return member_node;
}
return nullptr;
}
static void add_members_to_scope(AstNode *snode, std::string name)
{
// add all the members in a struct or union to local scope
// in case later referenced in assignments
log_assert(snode->type==AST_STRUCT || snode->type==AST_UNION);
for (auto *node : snode->children) {
auto member_name = name + "." + node->str;
current_scope[member_name] = node;
if (node->type != AST_STRUCT_ITEM) {
// embedded struct or union
add_members_to_scope(node, name + "." + node->str);
}
}
}
static AstNode *make_packed_struct(AstNode *template_node, std::string &name, decltype(AstNode::attributes) &attributes)
{
// create a wire for the packed struct
auto wnode = new AstNode(AST_WIRE, make_range(template_node->range_left, 0));
wnode->str = name;
wnode->is_logic = true;
wnode->range_valid = true;
wnode->is_signed = template_node->is_signed;
for (auto &pair : attributes) {
wnode->set_attribute(pair.first, pair.second->clone());
}
// resolve packed dimension
while (wnode->simplify(true, 1, -1, false)) {}
// make sure this node is the one in scope for this name
current_scope[name] = wnode;
// add all the struct members to scope under the wire's name
add_members_to_scope(template_node, name);
return wnode;
}
static void prepend_ranges(AstNode *&range, AstNode *range_add)
{
// Convert range to multirange.
if (range->type == AST_RANGE)
range = new AstNode(AST_MULTIRANGE, range);
// Add range or ranges.
if (range_add->type == AST_RANGE)
range->children.insert(range->children.begin(), range_add->clone());
else {
int i = 0;
for (auto child : range_add->children)
range->children.insert(range->children.begin() + i++, child->clone());
}
}
// check if a node or its children contains an assignment to the given variable
static bool node_contains_assignment_to(const AstNode* node, const AstNode* var)
{
if (node->type == AST_ASSIGN_EQ || node->type == AST_ASSIGN_LE) {
// current node is iteslf an assignment
log_assert(node->children.size() >= 2);
const AstNode* lhs = node->children[0];
if (lhs->type == AST_IDENTIFIER && lhs->str == var->str)
return false;
}
for (const AstNode* child : node->children) {
// if this child shadows the given variable
if (child != var && child->str == var->str && child->type == AST_WIRE)
break; // skip the remainder of this block/scope
// depth-first short circuit
if (!node_contains_assignment_to(child, var))
return false;
}
return true;
}
static std::string prefix_id(const std::string &prefix, const std::string &str)
{
log_assert(!prefix.empty() && (prefix.front() == '$' || prefix.front() == '\\'));
log_assert(!str.empty() && (str.front() == '$' || str.front() == '\\'));
log_assert(prefix.back() == '.');
if (str.front() == '\\')
return prefix + str.substr(1);
return prefix + str;
}
// direct access to this global should be limited to the following two functions
static const RTLIL::Design *simplify_design_context = nullptr;
void AST::set_simplify_design_context(const RTLIL::Design *design)
{
log_assert(!simplify_design_context || !design);
simplify_design_context = design;
}
// lookup the module with the given name in the current design context
static const RTLIL::Module* lookup_module(const std::string &name)
{
return simplify_design_context->module(name);
}
const RTLIL::Module* AstNode::lookup_cell_module()
{
log_assert(type == AST_CELL);
auto reprocess_after = [this] (const std::string &modname) {
if (!attributes.count(ID::reprocess_after))
set_attribute(ID::reprocess_after, AstNode::mkconst_str(modname));
};
const AstNode *celltype = nullptr;
for (const AstNode *child : children)
if (child->type == AST_CELLTYPE) {
celltype = child;
break;
}
log_assert(celltype != nullptr);
const RTLIL::Module *module = lookup_module(celltype->str);
if (!module)
module = lookup_module("$abstract" + celltype->str);
if (!module) {
if (celltype->str.at(0) != '$')
reprocess_after(celltype->str);
return nullptr;
}
// build a mapping from true param name to param value
size_t para_counter = 0;
dict<RTLIL::IdString, RTLIL::Const> cell_params_map;
for (AstNode *child : children) {
if (child->type != AST_PARASET)
continue;
if (child->str.empty() && para_counter >= module->avail_parameters.size())
return nullptr; // let hierarchy handle this error
IdString paraname = child->str.empty() ? module->avail_parameters[para_counter++] : child->str;
const AstNode *value = child->children[0];
if (value->type != AST_REALVALUE && value->type != AST_CONSTANT)
return nullptr; // let genrtlil handle this error
cell_params_map[paraname] = value->asParaConst();
}
// put the parameters in order and generate the derived module name
std::vector<std::pair<RTLIL::IdString, RTLIL::Const>> named_parameters;
for (RTLIL::IdString param : module->avail_parameters) {
auto it = cell_params_map.find(param);
if (it != cell_params_map.end())
named_parameters.emplace_back(it->first, it->second);
}
std::string modname = celltype->str;
if (cell_params_map.size()) // not named_parameters to cover hierarchical defparams
modname = derived_module_name(celltype->str, named_parameters);
// try to find the resolved module
module = lookup_module(modname);
if (!module) {
reprocess_after(modname);
return nullptr;
}
return module;
}
// returns whether an expression contains an unbased unsized literal; does not
// check the literal exists in a self-determined context
static bool contains_unbased_unsized(const AstNode *node)
{
if (node->type == AST_CONSTANT)
return node->is_unsized;
for (const AstNode *child : node->children)
if (contains_unbased_unsized(child))
return true;
return false;
}
// adds a wire to the current module with the given name that matches the
// dimensions of the given wire reference
void add_wire_for_ref(const RTLIL::Wire *ref, const std::string &str)
{
AstNode *left = AstNode::mkconst_int(ref->width - 1 + ref->start_offset, true);
AstNode *right = AstNode::mkconst_int(ref->start_offset, true);
if (ref->upto)
std::swap(left, right);
AstNode *range = new AstNode(AST_RANGE, left, right);
AstNode *wire = new AstNode(AST_WIRE, range);
wire->is_signed = ref->is_signed;
wire->is_logic = true;
wire->str = str;
current_ast_mod->children.push_back(wire);
current_scope[str] = wire;
}
enum class IdentUsage {
NotReferenced, // target variable is neither read or written in the block
Assigned, // target variable is always assigned before use
SyncRequired, // target variable may be used before it has been assigned
};
// determines whether a local variable a block is always assigned before it is
// used, meaning the nosync attribute can automatically be added to that
// variable
static IdentUsage always_asgn_before_use(const AstNode *node, const std::string &target)
{
// This variable has been referenced before it has necessarily been assigned
// a value in this procedure.
if (node->type == AST_IDENTIFIER && node->str == target)
return IdentUsage::SyncRequired;
// For case statements (which are also used for if/else), we check each
// possible branch. If the variable is assigned in all branches, then it is
// assigned, and a sync isn't required. If it used before assignment in any
// branch, then a sync is required.
if (node->type == AST_CASE) {
bool all_defined = true;
bool any_used = false;
bool has_default = false;
for (const AstNode *child : node->children) {
if (child->type == AST_COND && child->children.at(0)->type == AST_DEFAULT)
has_default = true;
IdentUsage nested = always_asgn_before_use(child, target);
if (nested != IdentUsage::Assigned && child->type == AST_COND)
all_defined = false;
if (nested == IdentUsage::SyncRequired)
any_used = true;
}
if (any_used)
return IdentUsage::SyncRequired;
else if (all_defined && has_default)
return IdentUsage::Assigned;
else
return IdentUsage::NotReferenced;
}
// Check if this is an assignment to the target variable. For simplicity, we
// don't analyze sub-ranges of the variable.
if (node->type == AST_ASSIGN_EQ) {
const AstNode *ident = node->children.at(0);
if (ident->type == AST_IDENTIFIER && ident->str == target)
return IdentUsage::Assigned;
}
for (const AstNode *child : node->children) {
IdentUsage nested = always_asgn_before_use(child, target);
if (nested != IdentUsage::NotReferenced)
return nested;
}
return IdentUsage::NotReferenced;
}
AstNode *AstNode::clone_at_zero()
{
int width_hint;
bool sign_hint;
AstNode *pointee;
switch (type) {
case AST_IDENTIFIER:
if (id2ast)
pointee = id2ast;
else if (current_scope.count(str))
pointee = current_scope[str];
else
break;
if (pointee->type != AST_WIRE &&
pointee->type != AST_AUTOWIRE &&
pointee->type != AST_MEMORY)
break;
YS_FALLTHROUGH
case AST_MEMRD:
detectSignWidth(width_hint, sign_hint);
return mkconst_int(0, sign_hint, width_hint);
default:
break;
}
AstNode *that = new AstNode;
*that = *this;
for (auto &it : that->children)
it = it->clone_at_zero();
for (auto &it : that->attributes)
it.second = it.second->clone();
that->set_in_lvalue_flag(false);
that->set_in_param_flag(false);
that->fixup_hierarchy_flags();
return that;
}
static bool try_determine_range_width(AstNode *range, int &result_width)
{
log_assert(range->type == AST_RANGE);
if (range->children.size() == 1) {
result_width = 1;
return true;
}
AstNode *left_at_zero_ast = range->children[0]->clone_at_zero();
AstNode *right_at_zero_ast = range->children[1]->clone_at_zero();
while (left_at_zero_ast->simplify(true, 1, -1, false)) {}
while (right_at_zero_ast->simplify(true, 1, -1, false)) {}
bool ok = false;
if (left_at_zero_ast->type == AST_CONSTANT
&& right_at_zero_ast->type == AST_CONSTANT) {
ok = true;
result_width = abs(int(left_at_zero_ast->integer - right_at_zero_ast->integer)) + 1;
}
delete left_at_zero_ast;
delete right_at_zero_ast;
return ok;
}
static const std::string auto_nosync_prefix = "\\AutoNosync";
// mark a local variable in an always_comb block for automatic nosync
// consideration
static void mark_auto_nosync(AstNode *block, const AstNode *wire)
{
log_assert(block->type == AST_BLOCK);
log_assert(wire->type == AST_WIRE);
block->set_attribute(auto_nosync_prefix + wire->str, AstNode::mkconst_int(1, false));
}
// block names can be prefixed with an explicit scope during elaboration
static bool is_autonamed_block(const std::string &str) {
size_t last_dot = str.rfind('.');
// unprefixed names: autonamed if the first char is a dollar sign
if (last_dot == std::string::npos)
return str.at(0) == '$'; // e.g., `$fordecl_block$1`
// prefixed names: autonamed if the final chunk begins with a dollar sign
return str.rfind(".$") == last_dot; // e.g., `\foo.bar.$fordecl_block$1`
}
// check a procedural block for auto-nosync markings, remove them, and add
// nosync to local variables as necessary
static void check_auto_nosync(AstNode *node)
{
std::vector<RTLIL::IdString> attrs_to_drop;
for (const auto& elem : node->attributes) {
// skip attributes that don't begin with the prefix
if (elem.first.compare(0, auto_nosync_prefix.size(),
auto_nosync_prefix.c_str()))
continue;
// delete and remove the attribute once we're done iterating
attrs_to_drop.push_back(elem.first);
// find the wire based on the attribute
std::string wire_name = elem.first.substr(auto_nosync_prefix.size());
auto it = current_scope.find(wire_name);
if (it == current_scope.end())
continue;
// analyze the usage of the local variable in this block
IdentUsage ident_usage = always_asgn_before_use(node, wire_name);
if (ident_usage != IdentUsage::Assigned)
continue;
// mark the wire with `nosync`
AstNode *wire = it->second;
log_assert(wire->type == AST_WIRE);
wire->set_attribute(ID::nosync, AstNode::mkconst_int(1, false));
}
// remove the attributes we've "consumed"
for (const RTLIL::IdString &str : attrs_to_drop) {
auto it = node->attributes.find(str);
delete it->second;
node->attributes.erase(it);
}
// check local variables in any nested blocks
for (AstNode *child : node->children)
check_auto_nosync(child);
}
// convert the AST into a simpler AST that has all parameters substituted by their
// values, unrolled for-loops, expanded generate blocks, etc. when this function
// is done with an AST it can be converted into RTLIL using genRTLIL().
//
// this function also does all name resolving and sets the id2ast member of all
// nodes that link to a different node using names and lexical scoping.
bool AstNode::simplify(bool const_fold, int stage, int width_hint, bool sign_hint)
{
static int recursion_counter = 0;
static bool deep_recursion_warning = false;
if (recursion_counter++ == 1000 && deep_recursion_warning) {
log_warning("Deep recursion in AST simplifier.\nDoes this design contain overly long or deeply nested expressions, or excessive recursion?\n");
deep_recursion_warning = false;
}
static bool unevaluated_tern_branch = false;
AstNode *newNode = NULL;
bool did_something = false;
#if 0
log("-------------\n");
log("AST simplify[%d] depth %d at %s:%d on %s %p:\n", stage, recursion_counter, filename.c_str(), location.first_line, type2str(type).c_str(), this);
log("const_fold=%d, stage=%d, width_hint=%d, sign_hint=%d\n",
int(const_fold), int(stage), int(width_hint), int(sign_hint));
// dumpAst(NULL, "> ");
#endif
if (stage == 0)
{
log_assert(type == AST_MODULE || type == AST_INTERFACE);
deep_recursion_warning = true;
while (simplify(const_fold, 1, width_hint, sign_hint)) { }
if (!flag_nomem2reg && !get_bool_attribute(ID::nomem2reg))
{
dict<AstNode*, pool<std::string>> mem2reg_places;
dict<AstNode*, uint32_t> mem2reg_candidates, dummy_proc_flags;
uint32_t flags = flag_mem2reg ? AstNode::MEM2REG_FL_ALL : 0;
mem2reg_as_needed_pass1(mem2reg_places, mem2reg_candidates, dummy_proc_flags, flags);
pool<AstNode*> mem2reg_set;
for (auto &it : mem2reg_candidates)
{
AstNode *mem = it.first;
uint32_t memflags = it.second;
bool this_nomeminit = flag_nomeminit;
log_assert((memflags & ~0x00ffff00) == 0);
if (mem->get_bool_attribute(ID::nomem2reg))
continue;
if (mem->get_bool_attribute(ID::nomeminit) || get_bool_attribute(ID::nomeminit))
this_nomeminit = true;
if (memflags & AstNode::MEM2REG_FL_FORCED)
goto silent_activate;
if (memflags & AstNode::MEM2REG_FL_EQ2)
goto verbose_activate;
if (memflags & AstNode::MEM2REG_FL_SET_ASYNC)
goto verbose_activate;
if ((memflags & AstNode::MEM2REG_FL_SET_INIT) && (memflags & AstNode::MEM2REG_FL_SET_ELSE) && this_nomeminit)
goto verbose_activate;
if (memflags & AstNode::MEM2REG_FL_CMPLX_LHS)
goto verbose_activate;
if ((memflags & AstNode::MEM2REG_FL_CONST_LHS) && !(memflags & AstNode::MEM2REG_FL_VAR_LHS))
goto verbose_activate;
// log("Note: Not replacing memory %s with list of registers (flags=0x%08lx).\n", mem->str.c_str(), long(memflags));
continue;
verbose_activate:
if (mem2reg_set.count(mem) == 0) {
std::string message = stringf("Replacing memory %s with list of registers.", mem->str.c_str());
bool first_element = true;
for (auto &place : mem2reg_places[it.first]) {
message += stringf("%s%s", first_element ? " See " : ", ", place.c_str());
first_element = false;
}
log_warning("%s\n", message.c_str());
}
silent_activate:
// log("Note: Replacing memory %s with list of registers (flags=0x%08lx).\n", mem->str.c_str(), long(memflags));
mem2reg_set.insert(mem);
}
for (auto node : mem2reg_set)
{
int mem_width, mem_size, addr_bits;
node->meminfo(mem_width, mem_size, addr_bits);
int data_range_left = node->children[0]->range_left;
int data_range_right = node->children[0]->range_right;
if (node->children[0]->range_swapped)
std::swap(data_range_left, data_range_right);
for (int i = 0; i < mem_size; i++) {
AstNode *reg = new AstNode(AST_WIRE, new AstNode(AST_RANGE,
mkconst_int(data_range_left, true), mkconst_int(data_range_right, true)));
reg->str = stringf("%s[%d]", node->str.c_str(), i);
reg->is_reg = true;
reg->is_signed = node->is_signed;
for (auto &it : node->attributes)
if (it.first != ID::mem2reg)
reg->set_attribute(it.first, it.second->clone());
reg->filename = node->filename;
reg->location = node->location;
children.push_back(reg);
while (reg->simplify(true, 1, -1, false)) { }
}
}
AstNode *async_block = NULL;
while (mem2reg_as_needed_pass2(mem2reg_set, this, NULL, async_block)) { }
vector<AstNode*> delnodes;
mem2reg_remove(mem2reg_set, delnodes);
for (auto node : delnodes)
delete node;
}
while (simplify(const_fold, 2, width_hint, sign_hint)) { }
recursion_counter--;
return false;
}
current_filename = filename;
// we do not look inside a task or function
// (but as soon as a task or function is instantiated we process the generated AST as usual)
if (type == AST_FUNCTION || type == AST_TASK) {
recursion_counter--;
return false;
}
// deactivate all calls to non-synthesis system tasks
// note that $display, $finish, and $stop are used for synthesis-time DRC so they're not in this list
if ((type == AST_FCALL || type == AST_TCALL) && (str == "$strobe" || str == "$monitor" || str == "$time" ||
str == "$dumpfile" || str == "$dumpvars" || str == "$dumpon" || str == "$dumpoff" || str == "$dumpall")) {
log_file_warning(filename, location.first_line, "Ignoring call to system %s %s.\n", type == AST_FCALL ? "function" : "task", str.c_str());
delete_children();
str = std::string();
}
if ((type == AST_TCALL) &&
(str == "$display" || str == "$displayb" || str == "$displayh" || str == "$displayo" ||
str == "$write" || str == "$writeb" || str == "$writeh" || str == "$writeo"))
{
if (!current_always) {
log_file_warning(filename, location.first_line, "System task `%s' outside initial or always block is unsupported.\n", str.c_str());
delete_children();
str = std::string();
} else {
// simplify the expressions and convert them to a special cell later in genrtlil
for (auto node : children)
while (node->simplify(true, stage, -1, false)) {}
if (current_always->type == AST_INITIAL && !flag_nodisplay && stage == 2) {
int default_base = 10;
if (str.back() == 'b')
default_base = 2;
else if (str.back() == 'o')
default_base = 8;
else if (str.back() == 'h')
default_base = 16;
// when $display()/$write() functions are used in an initial block, print them during synthesis
Fmt fmt = processFormat(stage, /*sformat_like=*/false, default_base, /*first_arg_at=*/0, /*may_fail=*/true);
if (str.substr(0, 8) == "$display")
fmt.append_literal("\n");
log("%s", fmt.render().c_str());
}
return false;
}
}
// activate const folding if this is anything that must be evaluated statically (ranges, parameters, attributes, etc.)
if (type == AST_WIRE || type == AST_PARAMETER || type == AST_LOCALPARAM || type == AST_ENUM_ITEM || type == AST_DEFPARAM || type == AST_PARASET || type == AST_RANGE || type == AST_PREFIX || type == AST_TYPEDEF)
const_fold = true;
if (type == AST_IDENTIFIER && current_scope.count(str) > 0 && (current_scope[str]->type == AST_PARAMETER || current_scope[str]->type == AST_LOCALPARAM || current_scope[str]->type == AST_ENUM_ITEM))
const_fold = true;
std::map<std::string, AstNode*> backup_scope;
// create name resolution entries for all objects with names
// also merge multiple declarations for the same wire (e.g. "output foobar; reg foobar;")
if (type == AST_MODULE || type == AST_INTERFACE) {
current_scope.clear();
std::set<std::string> existing;
int counter = 0;
label_genblks(existing, counter);
std::map<std::string, AstNode*> this_wire_scope;
for (size_t i = 0; i < children.size(); i++) {
AstNode *node = children[i];
if (node->type == AST_WIRE) {
if (node->children.size() == 1 && node->children[0]->type == AST_RANGE) {
for (auto c : node->children[0]->children) {
if (!c->is_simple_const_expr()) {
if (attributes.count(ID::dynports))
delete attributes.at(ID::dynports);
set_attribute(ID::dynports, AstNode::mkconst_int(1, true));
}
}
}
if (this_wire_scope.count(node->str) > 0) {
AstNode *first_node = this_wire_scope[node->str];
if (first_node->is_input && node->is_reg)
goto wires_are_incompatible;
if (!node->is_input && !node->is_output && node->is_reg && node->children.size() == 0)
goto wires_are_compatible;
if (first_node->children.size() == 0 && node->children.size() == 1 && node->children[0]->type == AST_RANGE) {
AstNode *r = node->children[0];
if (r->range_valid && r->range_left == 0 && r->range_right == 0) {
delete r;
node->children.pop_back();
}
}
if (first_node->children.size() != node->children.size())
goto wires_are_incompatible;
for (size_t j = 0; j < node->children.size(); j++) {
AstNode *n1 = first_node->children[j], *n2 = node->children[j];
if (n1->type == AST_RANGE && n2->type == AST_RANGE && n1->range_valid && n2->range_valid) {
if (n1->range_left != n2->range_left)
goto wires_are_incompatible;
if (n1->range_right != n2->range_right)
goto wires_are_incompatible;
} else if (*n1 != *n2)
goto wires_are_incompatible;
}
if (first_node->range_left != node->range_left)
goto wires_are_incompatible;
if (first_node->range_right != node->range_right)
goto wires_are_incompatible;
if (first_node->port_id == 0 && (node->is_input || node->is_output))
goto wires_are_incompatible;
wires_are_compatible:
if (node->is_input)
first_node->is_input = true;
if (node->is_output)
first_node->is_output = true;
if (node->is_reg)
first_node->is_reg = true;
if (node->is_logic)
first_node->is_logic = true;
if (node->is_signed)
first_node->is_signed = true;
for (auto &it : node->attributes) {
if (first_node->attributes.count(it.first) > 0)
delete first_node->attributes[it.first];
first_node->set_attribute(it.first, it.second->clone());
}
children.erase(children.begin()+(i--));
did_something = true;
delete node;
continue;
wires_are_incompatible:
if (stage > 1)
input_error("Incompatible re-declaration of wire %s.\n", node->str.c_str());
continue;
}
this_wire_scope[node->str] = node;
}
// these nodes appear at the top level in a module and can define names
if (node->type == AST_PARAMETER || node->type == AST_LOCALPARAM || node->type == AST_WIRE || node->type == AST_AUTOWIRE || node->type == AST_GENVAR ||
node->type == AST_MEMORY || node->type == AST_FUNCTION || node->type == AST_TASK || node->type == AST_DPI_FUNCTION || node->type == AST_CELL ||
node->type == AST_TYPEDEF) {
backup_scope[node->str] = current_scope[node->str];
current_scope[node->str] = node;
}
if (node->type == AST_ENUM) {
current_scope[node->str] = node;
for (auto enode : node->children) {
log_assert(enode->type==AST_ENUM_ITEM);
if (current_scope.count(enode->str) == 0)
current_scope[enode->str] = enode;
else
input_error("enum item %s already exists\n", enode->str.c_str());
}
}
}
for (size_t i = 0; i < children.size(); i++) {
AstNode *node = children[i];
if (node->type == AST_PARAMETER || node->type == AST_LOCALPARAM || node->type == AST_WIRE || node->type == AST_AUTOWIRE || node->type == AST_MEMORY || node->type == AST_TYPEDEF)
while (node->simplify(true, 1, -1, false))
did_something = true;
if (node->type == AST_ENUM) {
for (auto enode : node->children){
log_assert(enode->type==AST_ENUM_ITEM);
while (node->simplify(true, 1, -1, false))
did_something = true;
}
}
}
for (AstNode *child : children)
if (child->type == AST_ALWAYS &&
child->attributes.count(ID::always_comb))
check_auto_nosync(child);
}
// create name resolution entries for all objects with names
if (type == AST_PACKAGE) {
//add names to package scope
for (size_t i = 0; i < children.size(); i++) {
AstNode *node = children[i];
// these nodes appear at the top level in a package and can define names
if (node->type == AST_PARAMETER || node->type == AST_LOCALPARAM || node->type == AST_TYPEDEF || node->type == AST_FUNCTION || node->type == AST_TASK) {
current_scope[node->str] = node;
}
if (node->type == AST_ENUM) {
current_scope[node->str] = node;
for (auto enode : node->children) {
log_assert(enode->type==AST_ENUM_ITEM);
if (current_scope.count(enode->str) == 0)
current_scope[enode->str] = enode;
else
input_error("enum item %s already exists in package\n", enode->str.c_str());
}
}
}
}
auto backup_current_block = current_block;
auto backup_current_block_child = current_block_child;
auto backup_current_top_block = current_top_block;
auto backup_current_always = current_always;
auto backup_current_always_clocked = current_always_clocked;
if (type == AST_ALWAYS || type == AST_INITIAL)
{
if (current_always != nullptr)
input_error("Invalid nesting of always blocks and/or initializations.\n");
current_always = this;
current_always_clocked = false;
if (type == AST_ALWAYS)
for (auto child : children) {
if (child->type == AST_POSEDGE || child->type == AST_NEGEDGE)
current_always_clocked = true;
if (child->type == AST_EDGE && GetSize(child->children) == 1 &&
child->children[0]->type == AST_IDENTIFIER && child->children[0]->str == "\\$global_clock")
current_always_clocked = true;
}
}
if (type == AST_CELL) {
bool lookup_suggested = false;
for (AstNode *child : children) {
// simplify any parameters to constants
if (child->type == AST_PARASET)
while (child->simplify(true, 1, -1, false)) { }
// look for patterns which _may_ indicate ambiguity requiring
// resolution of the underlying module
if (child->type == AST_ARGUMENT) {
if (child->children.size() != 1)
continue;
const AstNode *value = child->children[0];
if (value->type == AST_IDENTIFIER) {
const AstNode *elem = value->id2ast;
if (elem == nullptr) {
if (current_scope.count(value->str))
elem = current_scope.at(value->str);
else
continue;
}
if (elem->type == AST_MEMORY)
// need to determine is the is a read or wire
lookup_suggested = true;
else if (elem->type == AST_WIRE && elem->is_signed && !value->children.empty())
// this may be a fully sliced signed wire which needs
// to be indirected to produce an unsigned connection
lookup_suggested = true;
}
else if (contains_unbased_unsized(value))
// unbased unsized literals extend to width of the context
lookup_suggested = true;
}
}
const RTLIL::Module *module = nullptr;
if (lookup_suggested)
module = lookup_cell_module();
if (module) {
size_t port_counter = 0;
for (AstNode *child : children) {
if (child->type != AST_ARGUMENT)
continue;
// determine the full name of port this argument is connected to
RTLIL::IdString port_name;
if (child->str.size())
port_name = child->str;
else {
if (port_counter >= module->ports.size())
input_error("Cell instance has more ports than the module!\n");
port_name = module->ports[port_counter++];
}
// find the port's wire in the underlying module
const RTLIL::Wire *ref = module->wire(port_name);
if (ref == nullptr)
input_error("Cell instance refers to port %s which does not exist in module %s!.\n",
log_id(port_name), log_id(module->name));
// select the argument, if present
log_assert(child->children.size() <= 1);
if (child->children.empty())
continue;
AstNode *arg = child->children[0];
// plain identifiers never need indirection; this also prevents
// adding infinite levels of indirection
if (arg->type == AST_IDENTIFIER && arg->children.empty())
continue;
// only add indirection for standard inputs or outputs
if (ref->port_input == ref->port_output)
continue;
did_something = true;
// create the indirection wire
std::stringstream sstr;
sstr << "$indirect$" << ref->name.c_str() << "$" << RTLIL::encode_filename(filename) << ":" << location.first_line << "$" << (autoidx++);
std::string tmp_str = sstr.str();
add_wire_for_ref(ref, tmp_str);
AstNode *asgn = new AstNode(AST_ASSIGN);
current_ast_mod->children.push_back(asgn);
AstNode *ident = new AstNode(AST_IDENTIFIER);
ident->str = tmp_str;
child->children[0] = ident->clone();
if (ref->port_input && !ref->port_output) {
asgn->children.push_back(ident);
asgn->children.push_back(arg);
} else {
log_assert(!ref->port_input && ref->port_output);
asgn->children.push_back(arg);
asgn->children.push_back(ident);
}
asgn->fixup_hierarchy_flags();
}
}
}
int backup_width_hint = width_hint;
bool backup_sign_hint = sign_hint;
bool detect_width_simple = false;
bool child_0_is_self_determined = false;
bool child_1_is_self_determined = false;
bool child_2_is_self_determined = false;
bool children_are_self_determined = false;
bool reset_width_after_children = false;
switch (type)
{
case AST_ASSIGN_EQ:
case AST_ASSIGN_LE:
case AST_ASSIGN:
while (!children[0]->basic_prep && children[0]->simplify(false, stage, -1, false) == true)
did_something = true;
while (!children[1]->basic_prep && children[1]->simplify(false, stage, -1, false) == true)
did_something = true;
children[0]->detectSignWidth(backup_width_hint, backup_sign_hint);
children[1]->detectSignWidth(width_hint, sign_hint);
width_hint = max(width_hint, backup_width_hint);
child_0_is_self_determined = true;
// test only once, before optimizations and memory mappings but after assignment LHS was mapped to an identifier
if (children[0]->id2ast && !children[0]->was_checked) {
if ((type == AST_ASSIGN_LE || type == AST_ASSIGN_EQ) && children[0]->id2ast->is_logic)
children[0]->id2ast->is_reg = true; // if logic type is used in a block asignment
if ((type == AST_ASSIGN_LE || type == AST_ASSIGN_EQ) && !children[0]->id2ast->is_reg)
log_warning("wire '%s' is assigned in a block at %s.\n", children[0]->str.c_str(), loc_string().c_str());
if (type == AST_ASSIGN && children[0]->id2ast->is_reg) {
bool is_rand_reg = false;
if (children[1]->type == AST_FCALL) {
if (children[1]->str == "\\$anyconst")
is_rand_reg = true;
if (children[1]->str == "\\$anyseq")
is_rand_reg = true;
if (children[1]->str == "\\$allconst")
is_rand_reg = true;
if (children[1]->str == "\\$allseq")
is_rand_reg = true;
}
if (!is_rand_reg)
log_warning("reg '%s' is assigned in a continuous assignment at %s.\n", children[0]->str.c_str(), loc_string().c_str());
}
children[0]->was_checked = true;
}
break;
case AST_STRUCT:
case AST_UNION:
if (!basic_prep) {
for (auto *node : children) {
// resolve any ranges
while (!node->basic_prep && node->simplify(true, stage, -1, false)) {
did_something = true;
}
}
// determine member offsets and widths
size_packed_struct(this, 0);
// instance rather than just a type in a typedef or outer struct?
if (!str.empty() && str[0] == '\\') {
// instance so add a wire for the packed structure
auto wnode = make_packed_struct(this, str, attributes);
log_assert(current_ast_mod);
current_ast_mod->children.push_back(wnode);
}
basic_prep = true;
}
break;
case AST_STRUCT_ITEM:
if (is_custom_type) {
log_assert(children.size() >= 1);
log_assert(children[0]->type == AST_WIRETYPE);
// Pretend it's just a wire in order to resolve the type.
type = AST_WIRE;
while (is_custom_type && simplify(const_fold, stage, width_hint, sign_hint)) {};
if (type == AST_WIRE)
type = AST_STRUCT_ITEM;
did_something = true;
}
log_assert(!is_custom_type);
break;
case AST_ENUM:
//log("\nENUM %s: %d child %d\n", str.c_str(), basic_prep, children[0]->basic_prep);
if (!basic_prep) {
for (auto item_node : children) {
while (!item_node->basic_prep && item_node->simplify(false, stage, -1, false))
did_something = true;
}
// allocate values (called more than once)
allocateDefaultEnumValues();
}
break;
case AST_PARAMETER:
case AST_LOCALPARAM:
// if parameter is implicit type which is the typename of a struct or union,
// save information about struct in wiretype attribute
if (children[0]->type == AST_IDENTIFIER && current_scope.count(children[0]->str) > 0) {
auto item_node = current_scope[children[0]->str];
if (item_node->type == AST_STRUCT || item_node->type == AST_UNION) {
set_attribute(ID::wiretype, item_node->clone());
size_packed_struct(attributes[ID::wiretype], 0);
add_members_to_scope(attributes[ID::wiretype], str);
}
}
while (!children[0]->basic_prep && children[0]->simplify(false, stage, -1, false) == true)
did_something = true;
children[0]->detectSignWidth(width_hint, sign_hint);
if (children.size() > 1 && children[1]->type == AST_RANGE) {
while (!children[1]->basic_prep && children[1]->simplify(false, stage, -1, false) == true)
did_something = true;
if (!children[1]->range_valid)
input_error("Non-constant width range on parameter decl.\n");
width_hint = max(width_hint, children[1]->range_left - children[1]->range_right + 1);
}
break;
case AST_ENUM_ITEM:
while (!children[0]->basic_prep && children[0]->simplify(false, stage, -1, false))
did_something = true;
children[0]->detectSignWidth(width_hint, sign_hint);
if (children.size() > 1 && children[1]->type == AST_RANGE) {
while (!children[1]->basic_prep && children[1]->simplify(false, stage, -1, false))
did_something = true;
if (!children[1]->range_valid)
input_error("Non-constant width range on enum item decl.\n");
width_hint = max(width_hint, children[1]->range_left - children[1]->range_right + 1);
}
break;
case AST_CAST_SIZE: {
int width = 1;
AstNode *node;
AstNode *child = children[0];
if (child->type == AST_WIRE) {
if (child->children.size() == 0) {
// Base type (e.g., int)
width = child->range_left - child->range_right +1;
node = mkconst_int(width, child->is_signed);
} else {
// User defined type
log_assert(child->children[0]->type == AST_WIRETYPE);
const std::string &type_name = child->children[0]->str;
if (!current_scope.count(type_name))
input_error("Unknown identifier `%s' used as type name\n", type_name.c_str());
AstNode *resolved_type_node = current_scope.at(type_name);
if (resolved_type_node->type != AST_TYPEDEF)
input_error("`%s' does not name a type\n", type_name.c_str());
log_assert(resolved_type_node->children.size() == 1);
AstNode *template_node = resolved_type_node->children[0];
// Ensure typedef itself is fully simplified
while (template_node->simplify(const_fold, stage, width_hint, sign_hint)) {};
switch (template_node->type)
{
case AST_WIRE: {
if (template_node->children.size() > 0 && template_node->children[0]->type == AST_RANGE)
width = range_width(this, template_node->children[0]);
child->delete_children();
node = mkconst_int(width, true);
break;
}
case AST_STRUCT:
case AST_UNION: {
child->delete_children();
width = size_packed_struct(template_node, 0);
node = mkconst_int(width, false);
break;
}
default:
log_error("Don't know how to translate static cast of type %s\n", type2str(template_node->type).c_str());
}
}
delete child;
children.erase(children.begin());
children.insert(children.begin(), node);
}
detect_width_simple = true;
children_are_self_determined = true;
break;
}
case AST_TO_BITS:
case AST_TO_SIGNED:
case AST_TO_UNSIGNED:
case AST_SELFSZ:
case AST_CONCAT:
case AST_REPLICATE:
case AST_REDUCE_AND:
case AST_REDUCE_OR:
case AST_REDUCE_XOR:
case AST_REDUCE_XNOR:
case AST_REDUCE_BOOL:
detect_width_simple = true;
children_are_self_determined = true;
break;
case AST_NEG:
case AST_BIT_NOT:
case AST_POS:
case AST_BIT_AND:
case AST_BIT_OR:
case AST_BIT_XOR:
case AST_BIT_XNOR:
case AST_ADD:
case AST_SUB:
case AST_MUL:
case AST_DIV:
case AST_MOD:
detect_width_simple = true;
break;
case AST_SHIFT_LEFT:
case AST_SHIFT_RIGHT:
case AST_SHIFT_SLEFT:
case AST_SHIFT_SRIGHT:
case AST_POW:
detect_width_simple = true;
child_1_is_self_determined = true;
break;
case AST_LT:
case AST_LE:
case AST_EQ:
case AST_NE:
case AST_EQX:
case AST_NEX:
case AST_GE:
case AST_GT:
width_hint = -1;
sign_hint = true;
for (auto child : children) {
while (!child->basic_prep && child->simplify(false, stage, -1, false) == true)
did_something = true;
child->detectSignWidthWorker(width_hint, sign_hint);
}
reset_width_after_children = true;
break;
case AST_LOGIC_AND:
case AST_LOGIC_OR:
case AST_LOGIC_NOT:
detect_width_simple = true;
children_are_self_determined = true;
break;
case AST_TERNARY:
child_0_is_self_determined = true;
break;
case AST_MEMRD:
detect_width_simple = true;
children_are_self_determined = true;
break;
case AST_FCALL:
case AST_TCALL:
children_are_self_determined = true;
break;
default:
width_hint = -1;
sign_hint = false;
}
if (detect_width_simple && width_hint < 0) {
if (type == AST_REPLICATE)
while (children[0]->simplify(true, stage, -1, false) == true)
did_something = true;
for (auto child : children)
while (!child->basic_prep && child->simplify(false, stage, -1, false) == true)
did_something = true;
detectSignWidth(width_hint, sign_hint);
}
if (type == AST_FCALL && str == "\\$past")
detectSignWidth(width_hint, sign_hint);
if (type == AST_TERNARY) {
if (width_hint < 0) {
while (!children[0]->basic_prep && children[0]->simplify(true, stage, -1, false))
did_something = true;
bool backup_unevaluated_tern_branch = unevaluated_tern_branch;
AstNode *chosen = get_tern_choice().first;
unevaluated_tern_branch = backup_unevaluated_tern_branch || chosen == children[2];
while (!children[1]->basic_prep && children[1]->simplify(false, stage, -1, false))
did_something = true;
unevaluated_tern_branch = backup_unevaluated_tern_branch || chosen == children[1];
while (!children[2]->basic_prep && children[2]->simplify(false, stage, -1, false))
did_something = true;
unevaluated_tern_branch = backup_unevaluated_tern_branch;
detectSignWidth(width_hint, sign_hint);
}
int width_hint_left, width_hint_right;
bool sign_hint_left, sign_hint_right;
bool found_real_left, found_real_right;
children[1]->detectSignWidth(width_hint_left, sign_hint_left, &found_real_left);
children[2]->detectSignWidth(width_hint_right, sign_hint_right, &found_real_right);
if (found_real_left || found_real_right) {
child_1_is_self_determined = true;
child_2_is_self_determined = true;
}
}
if (type == AST_CONDX && children.size() > 0 && children.at(0)->type == AST_CONSTANT) {
for (auto &bit : children.at(0)->bits)
if (bit == State::Sz || bit == State::Sx)
bit = State::Sa;
}
if (type == AST_CONDZ && children.size() > 0 && children.at(0)->type == AST_CONSTANT) {
for (auto &bit : children.at(0)->bits)
if (bit == State::Sz)
bit = State::Sa;
}
if (const_fold && type == AST_CASE)
{
detectSignWidth(width_hint, sign_hint);
while (children[0]->simplify(const_fold, stage, width_hint, sign_hint)) { }
if (children[0]->type == AST_CONSTANT && children[0]->bits_only_01()) {
children[0]->is_signed = sign_hint;
RTLIL::Const case_expr = children[0]->bitsAsConst(width_hint, sign_hint);
std::vector<AstNode*> new_children;
new_children.push_back(children[0]);
for (int i = 1; i < GetSize(children); i++) {
AstNode *child = children[i];
log_assert(child->type == AST_COND || child->type == AST_CONDX || child->type == AST_CONDZ);
for (auto v : child->children) {
if (v->type == AST_DEFAULT)
goto keep_const_cond;
if (v->type == AST_BLOCK)
continue;
while (v->simplify(const_fold, stage, width_hint, sign_hint)) { }
if (v->type == AST_CONSTANT && v->bits_only_01()) {
RTLIL::Const case_item_expr = v->bitsAsConst(width_hint, sign_hint);
RTLIL::Const match = const_eq(case_expr, case_item_expr, sign_hint, sign_hint, 1);
log_assert(match.size() == 1);
if (match.front() == RTLIL::State::S1) {
while (i+1 < GetSize(children))
delete children[++i];
goto keep_const_cond;
}
continue;
}
goto keep_const_cond;
}
if (0)
keep_const_cond:
new_children.push_back(child);
else
delete child;
}
new_children.swap(children);
}
}
dict<std::string, pool<int>> backup_memwr_visible;
dict<std::string, pool<int>> final_memwr_visible;
if (type == AST_CASE && stage == 2) {
backup_memwr_visible = current_memwr_visible;
final_memwr_visible = current_memwr_visible;
}
// simplify all children first
// (iterate by index as e.g. auto wires can add new children in the process)
for (size_t i = 0; i < children.size(); i++) {
bool did_something_here = true;
bool backup_flag_autowire = flag_autowire;
bool backup_unevaluated_tern_branch = unevaluated_tern_branch;
if ((type == AST_GENFOR || type == AST_FOR) && i >= 3)
break;
if ((type == AST_GENIF || type == AST_GENCASE) && i >= 1)
break;
if (type == AST_GENBLOCK)
break;
if (type == AST_CELLARRAY && children[i]->type == AST_CELL)
continue;
if (type == AST_BLOCK && !str.empty())
break;
if (type == AST_PREFIX && i >= 1)
break;
if (type == AST_DEFPARAM && i == 0)
flag_autowire = true;
if (type == AST_TERNARY && i > 0 && !unevaluated_tern_branch) {
AstNode *chosen = get_tern_choice().first;
unevaluated_tern_branch = chosen && chosen != children[i];
}
while (did_something_here && i < children.size()) {
bool const_fold_here = const_fold;
int width_hint_here = width_hint;
bool sign_hint_here = sign_hint;
if (i == 0 && (type == AST_REPLICATE || type == AST_WIRE))
const_fold_here = true;
if (type == AST_PARAMETER || type == AST_LOCALPARAM)
const_fold_here = true;
if (type == AST_BLOCK) {
current_block = this;
current_block_child = children[i];
}
if ((type == AST_ALWAYS || type == AST_INITIAL) && children[i]->type == AST_BLOCK)
current_top_block = children[i];
if (i == 0 && child_0_is_self_determined)
width_hint_here = -1, sign_hint_here = false;
if (i == 1 && child_1_is_self_determined)
width_hint_here = -1, sign_hint_here = false;
if (i == 2 && child_2_is_self_determined)
width_hint_here = -1, sign_hint_here = false;
if (children_are_self_determined)
width_hint_here = -1, sign_hint_here = false;
did_something_here = children[i]->simplify(const_fold_here, stage, width_hint_here, sign_hint_here);
if (did_something_here)
did_something = true;
}
if (stage == 2 && children[i]->type == AST_INITIAL && current_ast_mod != this) {
current_ast_mod->children.push_back(children[i]);
children.erase(children.begin() + (i--));
did_something = true;
}
flag_autowire = backup_flag_autowire;
unevaluated_tern_branch = backup_unevaluated_tern_branch;
if (stage == 2 && type == AST_CASE) {
for (auto &x : current_memwr_visible) {
for (int y : x.second)
final_memwr_visible[x.first].insert(y);
}
current_memwr_visible = backup_memwr_visible;
}
}
for (auto &attr : attributes) {
while (attr.second->simplify(true, stage, -1, false))
did_something = true;
}
if (type == AST_CASE && stage == 2) {
current_memwr_visible = final_memwr_visible;
}
if (type == AST_ALWAYS && stage == 2) {
current_memwr_visible.clear();
current_memwr_count.clear();
}
if (reset_width_after_children) {
width_hint = backup_width_hint;
sign_hint = backup_sign_hint;
if (width_hint < 0)
detectSignWidth(width_hint, sign_hint);
}
current_block = backup_current_block;
current_block_child = backup_current_block_child;
current_top_block = backup_current_top_block;
current_always = backup_current_always;
current_always_clocked = backup_current_always_clocked;
for (auto it = backup_scope.begin(); it != backup_scope.end(); it++) {
if (it->second == NULL)
current_scope.erase(it->first);
else
current_scope[it->first] = it->second;
}
current_filename = filename;
if (type == AST_MODULE || type == AST_INTERFACE)
current_scope.clear();
// convert defparam nodes to cell parameters
if (type == AST_DEFPARAM && !children.empty())
{
if (children[0]->type != AST_IDENTIFIER)
input_error("Module name in defparam contains non-constant expressions!\n");
string modname, paramname = children[0]->str;
size_t pos = paramname.rfind('.');
while (pos != 0 && pos != std::string::npos)
{
modname = paramname.substr(0, pos);
if (current_scope.count(modname))
break;
pos = paramname.rfind('.', pos - 1);
}
if (pos == std::string::npos)
input_error("Can't find object for defparam `%s`!\n", RTLIL::unescape_id(paramname).c_str());
paramname = "\\" + paramname.substr(pos+1);
if (current_scope.at(modname)->type != AST_CELL)
input_error("Defparam argument `%s . %s` does not match a cell!\n",
RTLIL::unescape_id(modname).c_str(), RTLIL::unescape_id(paramname).c_str());
AstNode *paraset = new AstNode(AST_PARASET, children[1]->clone(), GetSize(children) > 2 ? children[2]->clone() : NULL);
paraset->str = paramname;
AstNode *cell = current_scope.at(modname);
cell->children.insert(cell->children.begin() + 1, paraset);
delete_children();
}
// resolve typedefs
if (type == AST_TYPEDEF) {
log_assert(children.size() == 1);
auto type_node = children[0];
log_assert(type_node->type == AST_WIRE || type_node->type == AST_MEMORY || type_node->type == AST_STRUCT || type_node->type == AST_UNION);
while (type_node->simplify(const_fold, stage, width_hint, sign_hint)) {
did_something = true;
}
log_assert(!type_node->is_custom_type);
}
// resolve types of wires
if (type == AST_WIRE || type == AST_MEMORY) {
if (is_custom_type) {
log_assert(children.size() >= 1);
log_assert(children[0]->type == AST_WIRETYPE);
auto type_name = children[0]->str;
if (!current_scope.count(type_name)) {
input_error("Unknown identifier `%s' used as type name\n", type_name.c_str());
}
AstNode *resolved_type_node = current_scope.at(type_name);
if (resolved_type_node->type != AST_TYPEDEF)
input_error("`%s' does not name a type\n", type_name.c_str());
log_assert(resolved_type_node->children.size() == 1);
AstNode *template_node = resolved_type_node->children[0];
// Resolve the typedef from the bottom up, recursing within the current
// block of code. Defer further simplification until the complete type is
// resolved.
while (template_node->is_custom_type && template_node->simplify(const_fold, stage, width_hint, sign_hint)) {};
if (!str.empty() && str[0] == '\\' && (template_node->type == AST_STRUCT || template_node->type == AST_UNION)) {
// replace instance with wire representing the packed structure
newNode = make_packed_struct(template_node, str, attributes);
newNode->set_attribute(ID::wiretype, mkconst_str(resolved_type_node->str));
// add original input/output attribute to resolved wire
newNode->is_input = this->is_input;
newNode->is_output = this->is_output;
current_scope[str] = this;
goto apply_newNode;
}
// Prepare replacement node.
newNode = template_node->clone();
newNode->str = str;
newNode->set_attribute(ID::wiretype, mkconst_str(resolved_type_node->str));
newNode->is_input = is_input;
newNode->is_output = is_output;
newNode->is_wand = is_wand;
newNode->is_wor = is_wor;
for (auto &pair : attributes)
newNode->set_attribute(pair.first, pair.second->clone());
// if an enum then add attributes to support simulator tracing
newNode->annotateTypedEnums(template_node);
bool add_packed_dimensions = (type == AST_WIRE && GetSize(children) > 1) || (type == AST_MEMORY && GetSize(children) > 2);
// Cannot add packed dimensions if unpacked dimensions are already specified.
if (add_packed_dimensions && newNode->type == AST_MEMORY)
input_error("Cannot extend unpacked type `%s' with packed dimensions\n", type_name.c_str());
// Add packed dimensions.
if (add_packed_dimensions) {
AstNode *packed = children[1];
if (newNode->children.empty())
newNode->children.insert(newNode->children.begin(), packed->clone());
else
prepend_ranges(newNode->children[0], packed);
}
// Add unpacked dimensions.
if (type == AST_MEMORY) {
AstNode *unpacked = children.back();
if (GetSize(newNode->children) < 2)
newNode->children.push_back(unpacked->clone());
else
prepend_ranges(newNode->children[1], unpacked);
newNode->type = type;
}
// Prepare to generate dimensions metadata for the resolved type.
newNode->dimensions.clear();
newNode->unpacked_dimensions = 0;
goto apply_newNode;
}
}
// resolve types of parameters
if (type == AST_LOCALPARAM || type == AST_PARAMETER) {
if (is_custom_type) {
log_assert(children.size() >= 2);
log_assert(children[1]->type == AST_WIRETYPE);
// Pretend it's just a wire in order to resolve the type in the code block above.
AstNodeType param_type = type;
type = AST_WIRE;
AstNode *expr = children[0];
children.erase(children.begin());
while (is_custom_type && simplify(const_fold, stage, width_hint, sign_hint)) {};
type = param_type;
children.insert(children.begin(), expr);
if (children[1]->type == AST_MEMORY)
input_error("unpacked array type `%s' cannot be used for a parameter\n", children[1]->str.c_str());
fixup_hierarchy_flags();
did_something = true;
}
log_assert(!is_custom_type);
}
// resolve constant prefixes
if (type == AST_PREFIX) {
if (children[0]->type != AST_CONSTANT) {
// dumpAst(NULL, "> ");
input_error("Index in generate block prefix syntax is not constant!\n");
}
if (children[1]->type == AST_PREFIX)
children[1]->simplify(const_fold, stage, width_hint, sign_hint);
log_assert(children[1]->type == AST_IDENTIFIER);
newNode = children[1]->clone();
const char *second_part = children[1]->str.c_str();
if (second_part[0] == '\\')
second_part++;
newNode->str = stringf("%s[%d].%s", str.c_str(), children[0]->integer, second_part);
goto apply_newNode;
}
// evaluate TO_BITS nodes
if (type == AST_TO_BITS) {
if (children[0]->type != AST_CONSTANT)
input_error("Left operand of to_bits expression is not constant!\n");
if (children[1]->type != AST_CONSTANT)
input_error("Right operand of to_bits expression is not constant!\n");
RTLIL::Const new_value = children[1]->bitsAsConst(children[0]->bitsAsConst().as_int(), children[1]->is_signed);
newNode = mkconst_bits(new_value.to_bits(), children[1]->is_signed);
goto apply_newNode;
}
// annotate constant ranges
if (type == AST_RANGE) {
bool old_range_valid = range_valid;
range_valid = false;
range_swapped = false;
range_left = -1;
range_right = 0;
log_assert(children.size() >= 1);
if (children[0]->type == AST_CONSTANT) {
range_valid = true;
range_left = children[0]->integer;
if (children.size() == 1)
range_right = range_left;
}
if (children.size() >= 2) {
if (children[1]->type == AST_CONSTANT)
range_right = children[1]->integer;
else
range_valid = false;
}
if (old_range_valid != range_valid)
did_something = true;
if (range_valid && range_right > range_left) {
std::swap(range_left, range_right);
range_swapped = true;
}
}
// annotate wires with their ranges
if (type == AST_WIRE) {
if (children.size() > 0) {
if (children[0]->range_valid) {
if (!range_valid)
did_something = true;
range_valid = true;
range_swapped = children[0]->range_swapped;
range_left = children[0]->range_left;
range_right = children[0]->range_right;
bool force_upto = false, force_downto = false;
if (attributes.count(ID::force_upto)) {
AstNode *val = attributes[ID::force_upto];
if (val->type != AST_CONSTANT)
input_error("Attribute `force_upto' with non-constant value!\n");
force_upto = val->asAttrConst().as_bool();
}
if (attributes.count(ID::force_downto)) {
AstNode *val = attributes[ID::force_downto];
if (val->type != AST_CONSTANT)
input_error("Attribute `force_downto' with non-constant value!\n");
force_downto = val->asAttrConst().as_bool();
}
if (force_upto && force_downto)
input_error("Attributes `force_downto' and `force_upto' cannot be both set!\n");
if ((force_upto && !range_swapped) || (force_downto && range_swapped)) {
std::swap(range_left, range_right);
range_swapped = force_upto;
}
}
} else {
if (!range_valid)
did_something = true;
range_valid = true;
range_swapped = false;
range_left = 0;
range_right = 0;
}
}
// Resolve packed and unpacked ranges in declarations.
if ((type == AST_WIRE || type == AST_MEMORY) && dimensions.empty()) {
if (!children.empty()) {
// Unpacked ranges first, then packed ranges.
for (int i = std::min(GetSize(children), 2) - 1; i >= 0; i--) {
if (children[i]->type == AST_MULTIRANGE) {
int width = 1;
for (auto range : children[i]->children) {
width *= add_dimension(this, range);
if (i) unpacked_dimensions++;
}
delete children[i];
int left = width - 1, right = 0;
if (i)
std::swap(left, right);
children[i] = new AstNode(AST_RANGE, mkconst_int(left, true), mkconst_int(right, true));
fixup_hierarchy_flags();
did_something = true;
} else if (children[i]->type == AST_RANGE) {
add_dimension(this, children[i]);
if (i) unpacked_dimensions++;
}
}
} else {
// 1 bit signal: bit, logic or reg
dimensions.push_back({ 0, 1, false });
}
}
// Resolve multidimensional array access.
if (type == AST_IDENTIFIER && !basic_prep && id2ast && (id2ast->type == AST_WIRE || id2ast->type == AST_MEMORY) &&
children.size() > 0 && (children[0]->type == AST_RANGE || children[0]->type == AST_MULTIRANGE))
{
int dims_sel = children[0]->type == AST_MULTIRANGE ? children[0]->children.size() : 1;
// Save original number of dimensions for $size() etc.
integer = dims_sel;
// Split access into unpacked and packed parts.
AstNode *unpacked_range = nullptr;
AstNode *packed_range = nullptr;
if (id2ast->unpacked_dimensions) {
if (id2ast->unpacked_dimensions > 1) {
// Flattened range for access to unpacked dimensions.
unpacked_range = make_index_range(id2ast, true);
} else {
// Index into one-dimensional unpacked part; unlink simple range node.
AstNode *&range = children[0]->type == AST_MULTIRANGE ? children[0]->children[0] : children[0];
unpacked_range = range;
range = nullptr;
}
}
if (dims_sel > id2ast->unpacked_dimensions) {
if (GetSize(id2ast->dimensions) - id2ast->unpacked_dimensions > 1) {
// Flattened range for access to packed dimensions.
packed_range = make_index_range(id2ast, false);
} else {
// Index into one-dimensional packed part; unlink simple range node.
AstNode *&range = children[0]->type == AST_MULTIRANGE ? children[0]->children[dims_sel - 1] : children[0];
packed_range = range;
range = nullptr;
}
}
for (auto &it : children)
delete it;
children.clear();
if (unpacked_range)
children.push_back(unpacked_range);
if (packed_range)
children.push_back(packed_range);
fixup_hierarchy_flags();
basic_prep = true;
did_something = true;
}
// trim/extend parameters
if (type == AST_PARAMETER || type == AST_LOCALPARAM || type == AST_ENUM_ITEM) {
if (children.size() > 1 && children[1]->type == AST_RANGE) {
if (!children[1]->range_valid)
input_error("Non-constant width range on parameter decl.\n");
int width = std::abs(children[1]->range_left - children[1]->range_right) + 1;
if (children[0]->type == AST_REALVALUE) {
RTLIL::Const constvalue = children[0]->realAsConst(width);
log_file_warning(filename, location.first_line, "converting real value %e to binary %s.\n",
children[0]->realvalue, log_signal(constvalue));
delete children[0];
children[0] = mkconst_bits(constvalue.to_bits(), sign_hint);
fixup_hierarchy_flags();
did_something = true;
}
if (children[0]->type == AST_CONSTANT) {
if (width != int(children[0]->bits.size())) {
RTLIL::SigSpec sig(children[0]->bits);
sig.extend_u0(width, children[0]->is_signed);
AstNode *old_child_0 = children[0];
children[0] = mkconst_bits(sig.as_const().to_bits(), is_signed);
delete old_child_0;
fixup_hierarchy_flags();
}
children[0]->is_signed = is_signed;
}
range_valid = true;
range_swapped = children[1]->range_swapped;
range_left = children[1]->range_left;
range_right = children[1]->range_right;
} else
if (children.size() > 1 && children[1]->type == AST_REALVALUE && children[0]->type == AST_CONSTANT) {
double as_realvalue = children[0]->asReal(sign_hint);
delete children[0];
children[0] = new AstNode(AST_REALVALUE);
children[0]->realvalue = as_realvalue;
fixup_hierarchy_flags();
did_something = true;
}
}
if (type == AST_IDENTIFIER && !basic_prep) {
// check if a plausible struct member sss.mmmm
if (!str.empty() && str[0] == '\\' && current_scope.count(str)) {
auto item_node = current_scope[str];
if (item_node->type == AST_STRUCT_ITEM || item_node->type == AST_STRUCT || item_node->type == AST_UNION) {
// Traverse any hierarchical path until the full name for the referenced struct/union is found.
std::string sname;
bool found_sname = false;
for (std::string::size_type pos = 0; (pos = str.find('.', pos)) != std::string::npos; pos++) {
sname = str.substr(0, pos);
if (current_scope.count(sname)) {
auto stype = current_scope[sname]->type;
if (stype == AST_WIRE || stype == AST_PARAMETER || stype == AST_LOCALPARAM) {
found_sname = true;
break;
}
}
}
if (found_sname) {
// structure member, rewrite this node to reference the packed struct wire
auto range = make_index_range(item_node);
newNode = new AstNode(AST_IDENTIFIER, range);
newNode->str = sname;
// save type and original number of dimensions for $size() etc.
newNode->set_attribute(ID::wiretype, item_node->clone());
if (!item_node->dimensions.empty() && children.size() > 0) {
if (children[0]->type == AST_RANGE)
newNode->integer = 1;
else if (children[0]->type == AST_MULTIRANGE)
newNode->integer = children[0]->children.size();
}
newNode->basic_prep = true;
if (item_node->is_signed)
newNode = new AstNode(AST_TO_SIGNED, newNode);
goto apply_newNode;
}
}
}
}
// annotate identifiers using scope resolution and create auto-wires as needed
if (type == AST_IDENTIFIER) {
if (current_scope.count(str) == 0) {
AstNode *current_scope_ast = (current_ast_mod == nullptr) ? current_ast : current_ast_mod;
str = try_pop_module_prefix();
for (auto node : current_scope_ast->children) {
//log("looking at mod scope child %s\n", type2str(node->type).c_str());
switch (node->type) {
case AST_PARAMETER:
case AST_LOCALPARAM:
case AST_WIRE:
case AST_AUTOWIRE:
case AST_GENVAR:
case AST_MEMORY:
case AST_FUNCTION:
case AST_TASK:
case AST_DPI_FUNCTION:
//log("found child %s, %s\n", type2str(node->type).c_str(), node->str.c_str());
if (str == node->str) {
//log("add %s, type %s to scope\n", str.c_str(), type2str(node->type).c_str());
current_scope[node->str] = node;
}
break;
case AST_ENUM:
current_scope[node->str] = node;
for (auto enum_node : node->children) {
log_assert(enum_node->type==AST_ENUM_ITEM);
if (str == enum_node->str) {
//log("\nadding enum item %s to scope\n", str.c_str());
current_scope[str] = enum_node;
}
}
break;
default:
break;
}
}
}
if (current_scope.count(str) == 0) {
if (current_ast_mod == nullptr) {
input_error("Identifier `%s' is implicitly declared outside of a module.\n", str.c_str());
} else if (flag_autowire || str == "\\$global_clock") {
AstNode *auto_wire = new AstNode(AST_AUTOWIRE);
auto_wire->str = str;
current_ast_mod->children.push_back(auto_wire);
current_scope[str] = auto_wire;
did_something = true;
} else {
input_error("Identifier `%s' is implicitly declared and `default_nettype is set to none.\n", str.c_str());
}
}
if (id2ast != current_scope[str]) {
id2ast = current_scope[str];
did_something = true;
}
}
// split memory access with bit select to individual statements
if (type == AST_IDENTIFIER && children.size() == 2 && children[0]->type == AST_RANGE && children[1]->type == AST_RANGE && !in_lvalue && stage == 2)
{
if (id2ast == NULL || id2ast->type != AST_MEMORY || children[0]->children.size() != 1)
input_error("Invalid bit-select on memory access!\n");
int mem_width, mem_size, addr_bits;
id2ast->meminfo(mem_width, mem_size, addr_bits);
int data_range_left = id2ast->children[0]->range_left;
int data_range_right = id2ast->children[0]->range_right;
if (id2ast->children[0]->range_swapped)
std::swap(data_range_left, data_range_right);
std::stringstream sstr;
sstr << "$mem2bits$" << str << "$" << RTLIL::encode_filename(filename) << ":" << location.first_line << "$" << (autoidx++);
std::string wire_id = sstr.str();
AstNode *wire = new AstNode(AST_WIRE, new AstNode(AST_RANGE, mkconst_int(data_range_left, true), mkconst_int(data_range_right, true)));
wire->str = wire_id;
if (current_block)
wire->set_attribute(ID::nosync, AstNode::mkconst_int(1, false));
current_ast_mod->children.push_back(wire);
while (wire->simplify(true, 1, -1, false)) { }
AstNode *data = clone();
delete data->children[1];
data->children.pop_back();
AstNode *assign = new AstNode(AST_ASSIGN_EQ, new AstNode(AST_IDENTIFIER), data);
assign->children[0]->str = wire_id;
assign->children[0]->was_checked = true;
if (current_block)
{
size_t assign_idx = 0;
while (assign_idx < current_block->children.size() && current_block->children[assign_idx] != current_block_child)
assign_idx++;
log_assert(assign_idx < current_block->children.size());
current_block->children.insert(current_block->children.begin()+assign_idx, assign);
wire->is_reg = true;
}
else
{
AstNode *proc = new AstNode(AST_ALWAYS, new AstNode(AST_BLOCK));
proc->children[0]->children.push_back(assign);
current_ast_mod->children.push_back(proc);
}
newNode = new AstNode(AST_IDENTIFIER, children[1]->clone());
newNode->str = wire_id;
newNode->integer = integer; // save original number of dimensions for $size() etc.
newNode->id2ast = wire;
goto apply_newNode;
}
if (type == AST_WHILE)
input_error("While loops are only allowed in constant functions!\n");
if (type == AST_REPEAT)
{
AstNode *count = children[0];
AstNode *body = children[1];
// eval count expression
while (count->simplify(true, stage, 32, true)) { }
if (count->type != AST_CONSTANT)
input_error("Repeat loops outside must have constant repeat counts!\n");
// convert to a block with the body repeated n times
type = AST_BLOCK;
children.clear();
for (int i = 0; i < count->bitsAsConst().as_int(); i++)
children.insert(children.begin(), body->clone());
delete count;
delete body;
did_something = true;
}
// unroll for loops and generate-for blocks
if ((type == AST_GENFOR || type == AST_FOR) && children.size() != 0)
{
AstNode *init_ast = children[0];
AstNode *while_ast = children[1];
AstNode *next_ast = children[2];
AstNode *body_ast = children[3];
while (body_ast->type == AST_GENBLOCK && body_ast->str.empty() &&
body_ast->children.size() == 1 && body_ast->children.at(0)->type == AST_GENBLOCK)
body_ast = body_ast->children.at(0);
const char* loop_type_str = "procedural";
const char* var_type_str = "register";
AstNodeType var_type = AST_WIRE;
if (type == AST_GENFOR) {
loop_type_str = "generate";
var_type_str = "genvar";
var_type = AST_GENVAR;
}
if (init_ast->type != AST_ASSIGN_EQ)
input_error("Unsupported 1st expression of %s for-loop!\n", loop_type_str);
if (next_ast->type != AST_ASSIGN_EQ)
input_error("Unsupported 3rd expression of %s for-loop!\n", loop_type_str);
if (init_ast->children[0]->id2ast == NULL || init_ast->children[0]->id2ast->type != var_type)
input_error("Left hand side of 1st expression of %s for-loop is not a %s!\n", loop_type_str, var_type_str);
if (next_ast->children[0]->id2ast == NULL || next_ast->children[0]->id2ast->type != var_type)
input_error("Left hand side of 3rd expression of %s for-loop is not a %s!\n", loop_type_str, var_type_str);
if (init_ast->children[0]->id2ast != next_ast->children[0]->id2ast)
input_error("Incompatible left-hand sides in 1st and 3rd expression of %s for-loop!\n", loop_type_str);
// eval 1st expression
AstNode *varbuf = init_ast->children[1]->clone();
{
int expr_width_hint = -1;
bool expr_sign_hint = true;
varbuf->detectSignWidth(expr_width_hint, expr_sign_hint);
while (varbuf->simplify(true, stage, 32, true)) { }
}
if (varbuf->type != AST_CONSTANT)
input_error("Right hand side of 1st expression of %s for-loop is not constant!\n", loop_type_str);
auto resolved = current_scope.at(init_ast->children[0]->str);
if (resolved->range_valid) {
int const_size = varbuf->range_left - varbuf->range_right;
int resolved_size = resolved->range_left - resolved->range_right;
if (const_size < resolved_size) {
for (int i = const_size; i < resolved_size; i++)
varbuf->bits.push_back(resolved->is_signed ? varbuf->bits.back() : State::S0);
varbuf->range_left = resolved->range_left;
varbuf->range_right = resolved->range_right;
varbuf->range_swapped = resolved->range_swapped;
varbuf->range_valid = resolved->range_valid;
}
}
varbuf = new AstNode(AST_LOCALPARAM, varbuf);
varbuf->str = init_ast->children[0]->str;
AstNode *backup_scope_varbuf = current_scope[varbuf->str];
current_scope[varbuf->str] = varbuf;
size_t current_block_idx = 0;
if (type == AST_FOR) {
while (current_block_idx < current_block->children.size() &&
current_block->children[current_block_idx] != current_block_child)
current_block_idx++;
}
while (1)
{
// eval 2nd expression
AstNode *buf = while_ast->clone();
{
int expr_width_hint = -1;
bool expr_sign_hint = true;
buf->detectSignWidth(expr_width_hint, expr_sign_hint);
while (buf->simplify(true, stage, expr_width_hint, expr_sign_hint)) { }
}
if (buf->type != AST_CONSTANT)
input_error("2nd expression of %s for-loop is not constant!\n", loop_type_str);
if (buf->integer == 0) {
delete buf;
break;
}
delete buf;
// expand body
int index = varbuf->children[0]->integer;
log_assert(body_ast->type == AST_GENBLOCK || body_ast->type == AST_BLOCK);
log_assert(!body_ast->str.empty());
buf = body_ast->clone();
std::stringstream sstr;
sstr << buf->str << "[" << index << "].";
std::string prefix = sstr.str();
// create a scoped localparam for the current value of the loop variable
AstNode *local_index = varbuf->clone();
size_t pos = local_index->str.rfind('.');
if (pos != std::string::npos) // remove outer prefix
local_index->str = "\\" + local_index->str.substr(pos + 1);
local_index->str = prefix_id(prefix, local_index->str);
current_scope[local_index->str] = local_index;
current_ast_mod->children.push_back(local_index);
buf->expand_genblock(prefix);
if (type == AST_GENFOR) {
for (size_t i = 0; i < buf->children.size(); i++) {
buf->children[i]->simplify(const_fold, stage, -1, false);
current_ast_mod->children.push_back(buf->children[i]);
}
} else {
for (size_t i = 0; i < buf->children.size(); i++)
current_block->children.insert(current_block->children.begin() + current_block_idx++, buf->children[i]);
}
buf->children.clear();
delete buf;
// eval 3rd expression
buf = next_ast->children[1]->clone();
buf->set_in_param_flag(true);
{
int expr_width_hint = -1;
bool expr_sign_hint = true;
buf->detectSignWidth(expr_width_hint, expr_sign_hint);
while (buf->simplify(true, stage, expr_width_hint, expr_sign_hint)) { }
}
if (buf->type != AST_CONSTANT)
input_error("Right hand side of 3rd expression of %s for-loop is not constant (%s)!\n", loop_type_str, type2str(buf->type).c_str());
delete varbuf->children[0];
varbuf->children[0] = buf;
}
if (type == AST_FOR) {
AstNode *buf = next_ast->clone();
delete buf->children[1];
buf->children[1] = varbuf->children[0]->clone();
current_block->children.insert(current_block->children.begin() + current_block_idx++, buf);
}
current_scope[varbuf->str] = backup_scope_varbuf;
delete varbuf;
delete_children();
did_something = true;
}
// check for local objects in unnamed block
if (type == AST_BLOCK && str.empty())
{
for (size_t i = 0; i < children.size(); i++)
if (children[i]->type == AST_WIRE || children[i]->type == AST_MEMORY || children[i]->type == AST_PARAMETER || children[i]->type == AST_LOCALPARAM || children[i]->type == AST_TYPEDEF)
{
log_assert(!VERILOG_FRONTEND::sv_mode);
children[i]->input_error("Local declaration in unnamed block is only supported in SystemVerilog mode!\n");
}
}
// transform block with name
if (type == AST_BLOCK && !str.empty())
{
expand_genblock(str + ".");
// if this is an autonamed block is in an always_comb
if (current_always && current_always->attributes.count(ID::always_comb)
&& is_autonamed_block(str))
// track local variables in this block so we can consider adding
// nosync once the block has been fully elaborated
for (AstNode *child : children)
if (child->type == AST_WIRE &&
!child->attributes.count(ID::nosync))
mark_auto_nosync(this, child);
std::vector<AstNode*> new_children;
for (size_t i = 0; i < children.size(); i++)
if (children[i]->type == AST_WIRE || children[i]->type == AST_MEMORY || children[i]->type == AST_PARAMETER || children[i]->type == AST_LOCALPARAM || children[i]->type == AST_TYPEDEF) {
children[i]->simplify(false, stage, -1, false);
current_ast_mod->children.push_back(children[i]);
current_scope[children[i]->str] = children[i];
} else
new_children.push_back(children[i]);
children.swap(new_children);
did_something = true;
str.clear();
}
// simplify unconditional generate block
if (type == AST_GENBLOCK && children.size() != 0)
{
if (!str.empty()) {
expand_genblock(str + ".");
}
for (size_t i = 0; i < children.size(); i++) {
children[i]->simplify(const_fold, stage, -1, false);
current_ast_mod->children.push_back(children[i]);
}
children.clear();
did_something = true;
}
// simplify generate-if blocks
if (type == AST_GENIF && children.size() != 0)
{
AstNode *buf = children[0]->clone();
while (buf->simplify(true, stage, width_hint, sign_hint)) { }
if (buf->type != AST_CONSTANT) {
// for (auto f : log_files)
// dumpAst(f, "verilog-ast> ");
input_error("Condition for generate if is not constant!\n");
}
if (buf->asBool() != 0) {
delete buf;
buf = children[1]->clone();
} else {
delete buf;
buf = children.size() > 2 ? children[2]->clone() : NULL;
}
if (buf)
{
if (buf->type != AST_GENBLOCK)
buf = new AstNode(AST_GENBLOCK, buf);
if (!buf->str.empty()) {
buf->expand_genblock(buf->str + ".");
}
for (size_t i = 0; i < buf->children.size(); i++) {
buf->children[i]->simplify(const_fold, stage, -1, false);
current_ast_mod->children.push_back(buf->children[i]);
}
buf->children.clear();
delete buf;
}
delete_children();
did_something = true;
}
// simplify generate-case blocks
if (type == AST_GENCASE && children.size() != 0)
{
AstNode *buf = children[0]->clone();
while (buf->simplify(true, stage, width_hint, sign_hint)) { }
if (buf->type != AST_CONSTANT) {
// for (auto f : log_files)
// dumpAst(f, "verilog-ast> ");
input_error("Condition for generate case is not constant!\n");
}
bool ref_signed = buf->is_signed;
RTLIL::Const ref_value = buf->bitsAsConst();
delete buf;
AstNode *selected_case = NULL;
for (size_t i = 1; i < children.size(); i++)
{
log_assert(children.at(i)->type == AST_COND || children.at(i)->type == AST_CONDX || children.at(i)->type == AST_CONDZ);
AstNode *this_genblock = NULL;
for (auto child : children.at(i)->children) {
log_assert(this_genblock == NULL);
if (child->type == AST_GENBLOCK)
this_genblock = child;
}
for (auto child : children.at(i)->children)
{
if (child->type == AST_DEFAULT) {
if (selected_case == NULL)
selected_case = this_genblock;
continue;
}
if (child->type == AST_GENBLOCK)
continue;
buf = child->clone();
buf->set_in_param_flag(true);
while (buf->simplify(true, stage, width_hint, sign_hint)) { }
if (buf->type != AST_CONSTANT) {
// for (auto f : log_files)
// dumpAst(f, "verilog-ast> ");
input_error("Expression in generate case is not constant!\n");
}
bool is_selected = RTLIL::const_eq(ref_value, buf->bitsAsConst(), ref_signed && buf->is_signed, ref_signed && buf->is_signed, 1).as_bool();
delete buf;
if (is_selected) {
selected_case = this_genblock;
i = children.size();
break;
}
}
}
if (selected_case != NULL)
{
log_assert(selected_case->type == AST_GENBLOCK);
buf = selected_case->clone();
if (!buf->str.empty()) {
buf->expand_genblock(buf->str + ".");
}
for (size_t i = 0; i < buf->children.size(); i++) {
buf->children[i]->simplify(const_fold, stage, -1, false);
current_ast_mod->children.push_back(buf->children[i]);
}
buf->children.clear();
delete buf;
}
delete_children();
did_something = true;
}
// unroll cell arrays
if (type == AST_CELLARRAY)
{
if (!children.at(0)->range_valid)
input_error("Non-constant array range on cell array.\n");
newNode = new AstNode(AST_GENBLOCK);
int num = max(children.at(0)->range_left, children.at(0)->range_right) - min(children.at(0)->range_left, children.at(0)->range_right) + 1;
for (int i = 0; i < num; i++) {
int idx = children.at(0)->range_left > children.at(0)->range_right ? children.at(0)->range_right + i : children.at(0)->range_right - i;
AstNode *new_cell = children.at(1)->clone();
newNode->children.push_back(new_cell);
new_cell->str += stringf("[%d]", idx);
if (new_cell->type == AST_PRIMITIVE) {
input_error("Cell arrays of primitives are currently not supported.\n");
} else {
log_assert(new_cell->children.at(0)->type == AST_CELLTYPE);
new_cell->children.at(0)->str = stringf("$array:%d:%d:%s", i, num, new_cell->children.at(0)->str.c_str());
}
}
goto apply_newNode;
}
// replace primitives with assignments
if (type == AST_PRIMITIVE)
{
if (children.size() < 2)
input_error("Insufficient number of arguments for primitive `%s'!\n", str.c_str());
std::vector<AstNode*> children_list;
for (auto child : children) {
log_assert(child->type == AST_ARGUMENT);
log_assert(child->children.size() == 1);
children_list.push_back(child->children[0]);
child->children.clear();
delete child;
}
children.clear();
if (str == "bufif0" || str == "bufif1" || str == "notif0" || str == "notif1")
{
if (children_list.size() != 3)
input_error("Invalid number of arguments for primitive `%s'!\n", str.c_str());
std::vector<RTLIL::State> z_const(1, RTLIL::State::Sz);
AstNode *mux_input = children_list.at(1);
if (str == "notif0" || str == "notif1") {
mux_input = new AstNode(AST_BIT_NOT, mux_input);
}
AstNode *node = new AstNode(AST_TERNARY, children_list.at(2));
if (str == "bufif0") {
node->children.push_back(AstNode::mkconst_bits(z_const, false));
node->children.push_back(mux_input);
} else {
node->children.push_back(mux_input);
node->children.push_back(AstNode::mkconst_bits(z_const, false));
}
str.clear();
type = AST_ASSIGN;
children.push_back(children_list.at(0));
children.back()->was_checked = true;
children.push_back(node);
fixup_hierarchy_flags();
did_something = true;
}
else if (str == "buf" || str == "not")
{
AstNode *input = children_list.back();
if (str == "not")
input = new AstNode(AST_BIT_NOT, input);
newNode = new AstNode(AST_GENBLOCK);
for (auto it = children_list.begin(); it != std::prev(children_list.end()); it++) {
newNode->children.push_back(new AstNode(AST_ASSIGN, *it, input->clone()));
newNode->children.back()->was_checked = true;
}
delete input;
did_something = true;
}
else
{
AstNodeType op_type = AST_NONE;
bool invert_results = false;
if (str == "and")
op_type = AST_BIT_AND;
if (str == "nand")
op_type = AST_BIT_AND, invert_results = true;
if (str == "or")
op_type = AST_BIT_OR;
if (str == "nor")
op_type = AST_BIT_OR, invert_results = true;
if (str == "xor")
op_type = AST_BIT_XOR;
if (str == "xnor")
op_type = AST_BIT_XOR, invert_results = true;
log_assert(op_type != AST_NONE);
AstNode *node = children_list[1];
if (op_type != AST_POS)
for (size_t i = 2; i < children_list.size(); i++) {
node = new AstNode(op_type, node, children_list[i]);
node->location = location;
}
if (invert_results)
node = new AstNode(AST_BIT_NOT, node);
str.clear();
type = AST_ASSIGN;
children.push_back(children_list[0]);
children.back()->was_checked = true;
children.push_back(node);
fixup_hierarchy_flags();
did_something = true;
}
}
// replace dynamic ranges in left-hand side expressions (e.g. "foo[bar] <= 1'b1;") with
// either a big case block that selects the correct single-bit assignment, or mask and
// shift operations.
if (type == AST_ASSIGN_EQ || type == AST_ASSIGN_LE)
{
if (children[0]->type != AST_IDENTIFIER || children[0]->children.size() == 0)
goto skip_dynamic_range_lvalue_expansion;
if (children[0]->children[0]->range_valid || did_something)
goto skip_dynamic_range_lvalue_expansion;
if (children[0]->id2ast == NULL || children[0]->id2ast->type != AST_WIRE)
goto skip_dynamic_range_lvalue_expansion;
if (!children[0]->id2ast->range_valid)
goto skip_dynamic_range_lvalue_expansion;
AST::AstNode *member_node = children[0]->get_struct_member();
int wire_width = member_node ?
member_node->range_left - member_node->range_right + 1 :
children[0]->id2ast->range_left - children[0]->id2ast->range_right + 1;
int wire_offset = children[0]->id2ast->range_right;
int result_width = 1;
AstNode *shift_expr = NULL;
AstNode *range = children[0]->children[0];
if (!try_determine_range_width(range, result_width))
input_error("Unsupported expression on dynamic range select on signal `%s'!\n", str.c_str());
if (range->children.size() >= 2)
shift_expr = range->children[1]->clone();
else
shift_expr = range->children[0]->clone();
bool use_case_method = children[0]->id2ast->get_bool_attribute(ID::nowrshmsk);
if (!use_case_method && current_always->detect_latch(children[0]->str))
use_case_method = true;
if (use_case_method) {
// big case block
int stride = 1;
long long bitno_div = stride;
int case_width_hint;
bool case_sign_hint;
shift_expr->detectSignWidth(case_width_hint, case_sign_hint);
int max_width = case_width_hint;
if (member_node) { // Member in packed struct/union
// Clamp chunk to range of member within struct/union.
log_assert(!wire_offset && !children[0]->id2ast->range_swapped);
// When the (* nowrshmsk *) attribute is set, a CASE block is generated below
// to select the indexed bit slice. When a multirange array is indexed, the
// start of each possible slice is separated by the bit stride of the last
// index dimension, and we can optimize the CASE block accordingly.
// The dimension of the original array expression is saved in the 'integer' field.
int dims = children[0]->integer;
stride = wire_width;
for (int dim = 0; dim < dims; dim++) {
stride /= member_node->dimensions[dim].range_width;
}
bitno_div = stride;
} else {
// Extract (index)*(width) from non_opt_range pattern ((@selfsz@((index)*(width)))+(0)).
AstNode *lsb_expr =
shift_expr->type == AST_ADD && shift_expr->children[0]->type == AST_SELFSZ &&
shift_expr->children[1]->type == AST_CONSTANT && shift_expr->children[1]->integer == 0 ?
shift_expr->children[0]->children[0] :
shift_expr;
// Extract stride from indexing of two-dimensional packed arrays and
// variable slices on the form dst[i*stride +: width] = src.
if (lsb_expr->type == AST_MUL &&
(lsb_expr->children[0]->type == AST_CONSTANT ||
lsb_expr->children[1]->type == AST_CONSTANT))
{
int stride_ix = lsb_expr->children[1]->type == AST_CONSTANT;
stride = (int)lsb_expr->children[stride_ix]->integer;
bitno_div = stride != 0 ? stride : 1;
// Check whether i*stride can overflow.
int i_width;
bool i_sign;
lsb_expr->children[1 - stride_ix]->detectSignWidth(i_width, i_sign);
int stride_width;
bool stride_sign;
lsb_expr->children[stride_ix]->detectSignWidth(stride_width, stride_sign);
max_width = std::max(i_width, stride_width);
// Stride width calculated from actual stride value.
stride_width = std::ceil(std::log2(std::abs(stride)));
if (i_width + stride_width > max_width) {
// For (truncated) i*stride to be within the range of dst, the following must hold:
// i*stride ≡ bitno (mod shift_mod), i.e.
// i*stride = k*shift_mod + bitno
//
// The Diophantine equation on the form ax + by = c:
// stride*i - shift_mod*k = bitno
// has solutions iff c is a multiple of d = gcd(a, b), i.e.
// bitno mod gcd(stride, shift_mod) = 0
//
// long long is at least 64 bits in C++11
long long shift_mod = 1ll << (max_width - case_sign_hint);
// std::gcd requires C++17
// bitno_div = std::gcd(stride, shift_mod);
bitno_div = gcd((long long)stride, shift_mod);
}
}
}
// long long is at least 64 bits in C++11
long long max_offset = (1ll << (max_width - case_sign_hint)) - 1;
long long min_offset = case_sign_hint ? -(1ll << (max_width - 1)) : 0;
// A temporary register holds the result of the (possibly complex) rvalue expression,
// avoiding repetition in each AST_COND below.
int rvalue_width;
bool rvalue_sign;
children[1]->detectSignWidth(rvalue_width, rvalue_sign);
AstNode *rvalue = mktemp_logic("$bitselwrite$rvalue$", current_ast_mod, true, rvalue_width - 1, 0, rvalue_sign);
AstNode *caseNode = new AstNode(AST_CASE, shift_expr);
newNode = new AstNode(AST_BLOCK,
new AstNode(AST_ASSIGN_EQ, rvalue, children[1]->clone()),
caseNode);
did_something = true;
for (int i = 1 - result_width; i < wire_width; i++) {
// Out of range indexes are handled in genrtlil.cc
int start_bit = wire_offset + i;
int end_bit = start_bit + result_width - 1;
// Check whether the current index can be generated by shift_expr.
if (start_bit < min_offset || start_bit > max_offset)
continue;
if (start_bit%bitno_div != 0 || (stride == 0 && start_bit != 0))
continue;
AstNode *cond = new AstNode(AST_COND, mkconst_int(start_bit, case_sign_hint, max_width));
AstNode *lvalue = children[0]->clone();
lvalue->delete_children();
if (member_node)
lvalue->set_attribute(ID::wiretype, member_node->clone());
lvalue->children.push_back(new AstNode(AST_RANGE,
mkconst_int(end_bit, true), mkconst_int(start_bit, true)));
cond->children.push_back(new AstNode(AST_BLOCK, new AstNode(type, lvalue, rvalue->clone())));
caseNode->children.push_back(cond);
}
} else {
// mask and shift operations
// dst = (dst & ~(width'1 << lsb)) | unsigned'(width'(src)) << lsb)
AstNode *lvalue = children[0]->clone();
lvalue->delete_children();
if (member_node)
lvalue->set_attribute(ID::wiretype, member_node->clone());
AstNode *old_data = lvalue->clone();
if (type == AST_ASSIGN_LE)
old_data->lookahead = true;
int shift_width_hint;
bool shift_sign_hint;
shift_expr->detectSignWidth(shift_width_hint, shift_sign_hint);
// All operations are carried out in a new block.
newNode = new AstNode(AST_BLOCK);
// Temporary register holding the result of the bit- or part-select position expression.
AstNode *pos = mktemp_logic("$bitselwrite$pos$", current_ast_mod, true, shift_width_hint - 1, 0, shift_sign_hint);
newNode->children.push_back(new AstNode(AST_ASSIGN_EQ, pos, shift_expr));
// Calculate lsb from position.
AstNode *shift_val = pos->clone();
// If the expression is signed, we must add an extra bit for possible negation of the most negative number.
// If the expression is unsigned, we must add an extra bit for sign.
shift_val = new AstNode(AST_CAST_SIZE, mkconst_int(shift_width_hint + 1, true), shift_val);
if (!shift_sign_hint)
shift_val = new AstNode(AST_TO_SIGNED, shift_val);
// offset the shift amount by the lower bound of the dimension
if (wire_offset != 0)
shift_val = new AstNode(AST_SUB, shift_val, mkconst_int(wire_offset, true));
// reflect the shift amount if the dimension is swapped
if (children[0]->id2ast->range_swapped)
shift_val = new AstNode(AST_SUB, mkconst_int(wire_width - result_width, true), shift_val);
// AST_SHIFT uses negative amounts for shifting left
shift_val = new AstNode(AST_NEG, shift_val);
// dst = (dst & ~(width'1 << lsb)) | unsigned'(width'(src)) << lsb)
did_something = true;
AstNode *bitmask = mkconst_bits(std::vector<RTLIL::State>(result_width, State::S1), false);
newNode->children.push_back(
new AstNode(type,
lvalue,
new AstNode(AST_BIT_OR,
new AstNode(AST_BIT_AND,
old_data,
new AstNode(AST_BIT_NOT,
new AstNode(AST_SHIFT,
bitmask,
shift_val->clone()))),
new AstNode(AST_SHIFT,
new AstNode(AST_TO_UNSIGNED,
new AstNode(AST_CAST_SIZE,
mkconst_int(result_width, true),
children[1]->clone())),
shift_val))));
newNode->fixup_hierarchy_flags(true);
}
goto apply_newNode;
}
skip_dynamic_range_lvalue_expansion:;
// found right-hand side identifier for memory -> replace with memory read port
if (stage > 1 && type == AST_IDENTIFIER && id2ast != NULL && id2ast->type == AST_MEMORY && !in_lvalue &&
children.size() == 1 && children[0]->type == AST_RANGE && children[0]->children.size() == 1) {
if (integer < (unsigned)id2ast->unpacked_dimensions)
input_error("Insufficient number of array indices for %s.\n", log_id(str));
newNode = new AstNode(AST_MEMRD, children[0]->children[0]->clone());
newNode->str = str;
newNode->id2ast = id2ast;
goto apply_newNode;
}
// assignment with nontrivial member in left-hand concat expression -> split assignment
if ((type == AST_ASSIGN_EQ || type == AST_ASSIGN_LE) && children[0]->type == AST_CONCAT && width_hint > 0)
{
bool found_nontrivial_member = false;
for (auto child : children[0]->children) {
if (child->type == AST_IDENTIFIER && child->id2ast != NULL && child->id2ast->type == AST_MEMORY)
found_nontrivial_member = true;
}
if (found_nontrivial_member)
{
newNode = new AstNode(AST_BLOCK);
AstNode *wire_tmp = new AstNode(AST_WIRE, new AstNode(AST_RANGE, mkconst_int(width_hint-1, true), mkconst_int(0, true)));
wire_tmp->str = stringf("$splitcmplxassign$%s:%d$%d", RTLIL::encode_filename(filename).c_str(), location.first_line, autoidx++);
current_ast_mod->children.push_back(wire_tmp);
current_scope[wire_tmp->str] = wire_tmp;
wire_tmp->set_attribute(ID::nosync, AstNode::mkconst_int(1, false));
while (wire_tmp->simplify(true, 1, -1, false)) { }
wire_tmp->is_logic = true;
AstNode *wire_tmp_id = new AstNode(AST_IDENTIFIER);
wire_tmp_id->str = wire_tmp->str;
newNode->children.push_back(new AstNode(AST_ASSIGN_EQ, wire_tmp_id, children[1]->clone()));
newNode->children.back()->was_checked = true;
int cursor = 0;
for (auto child : children[0]->children)
{
int child_width_hint = -1;
bool child_sign_hint = true;
child->detectSignWidth(child_width_hint, child_sign_hint);
AstNode *rhs = wire_tmp_id->clone();
rhs->children.push_back(new AstNode(AST_RANGE, AstNode::mkconst_int(cursor+child_width_hint-1, true), AstNode::mkconst_int(cursor, true)));
newNode->children.push_back(new AstNode(type, child->clone(), rhs));
cursor += child_width_hint;
}
goto apply_newNode;
}
}
// assignment with memory in left-hand side expression -> replace with memory write port
if (stage > 1 && (type == AST_ASSIGN_EQ || type == AST_ASSIGN_LE) && children[0]->type == AST_IDENTIFIER &&
children[0]->id2ast && children[0]->id2ast->type == AST_MEMORY && children[0]->id2ast->children.size() >= 2 &&
children[0]->id2ast->children[0]->range_valid && children[0]->id2ast->children[1]->range_valid &&
(children[0]->children.size() == 1 || children[0]->children.size() == 2) && children[0]->children[0]->type == AST_RANGE)
{
if (children[0]->integer < (unsigned)children[0]->id2ast->unpacked_dimensions)
input_error("Insufficient number of array indices for %s.\n", log_id(str));
std::stringstream sstr;
sstr << "$memwr$" << children[0]->str << "$" << RTLIL::encode_filename(filename) << ":" << location.first_line << "$" << (autoidx++);
std::string id_addr = sstr.str() + "_ADDR", id_data = sstr.str() + "_DATA", id_en = sstr.str() + "_EN";
int mem_width, mem_size, addr_bits;
bool mem_signed = children[0]->id2ast->is_signed;
children[0]->id2ast->meminfo(mem_width, mem_size, addr_bits);
newNode = new AstNode(AST_BLOCK);
AstNode *defNode = new AstNode(AST_BLOCK);
int data_range_left = children[0]->id2ast->children[0]->range_left;
int data_range_right = children[0]->id2ast->children[0]->range_right;
int mem_data_range_offset = std::min(data_range_left, data_range_right);
int addr_width_hint = -1;
bool addr_sign_hint = true;
children[0]->children[0]->children[0]->detectSignWidthWorker(addr_width_hint, addr_sign_hint);
addr_bits = std::max(addr_bits, addr_width_hint);
std::vector<RTLIL::State> x_bits_addr, x_bits_data, set_bits_en;
for (int i = 0; i < addr_bits; i++)
x_bits_addr.push_back(RTLIL::State::Sx);
for (int i = 0; i < mem_width; i++)
x_bits_data.push_back(RTLIL::State::Sx);
for (int i = 0; i < mem_width; i++)
set_bits_en.push_back(RTLIL::State::S1);
AstNode *node_addr = nullptr;
if (children[0]->children[0]->children[0]->isConst()) {
node_addr = children[0]->children[0]->children[0]->clone();
} else {
AstNode *wire_addr = new AstNode(AST_WIRE, new AstNode(AST_RANGE, mkconst_int(addr_bits-1, true), mkconst_int(0, true)));
wire_addr->str = id_addr;
wire_addr->was_checked = true;
current_ast_mod->children.push_back(wire_addr);
current_scope[wire_addr->str] = wire_addr;
while (wire_addr->simplify(true, 1, -1, false)) { }
AstNode *assign_addr = new AstNode(AST_ASSIGN_EQ, new AstNode(AST_IDENTIFIER), mkconst_bits(x_bits_addr, false));
assign_addr->children[0]->str = id_addr;
assign_addr->children[0]->was_checked = true;
defNode->children.push_back(assign_addr);
assign_addr = new AstNode(AST_ASSIGN_EQ, new AstNode(AST_IDENTIFIER), children[0]->children[0]->children[0]->clone());
assign_addr->children[0]->str = id_addr;
assign_addr->children[0]->was_checked = true;
newNode->children.push_back(assign_addr);
node_addr = new AstNode(AST_IDENTIFIER);
node_addr->str = id_addr;
}
AstNode *node_data = nullptr;
if (children[0]->children.size() == 1 && children[1]->isConst()) {
node_data = children[1]->clone();
} else {
AstNode *wire_data = new AstNode(AST_WIRE, new AstNode(AST_RANGE, mkconst_int(mem_width-1, true), mkconst_int(0, true)));
wire_data->str = id_data;
wire_data->was_checked = true;
wire_data->is_signed = mem_signed;
current_ast_mod->children.push_back(wire_data);
current_scope[wire_data->str] = wire_data;
while (wire_data->simplify(true, 1, -1, false)) { }
AstNode *assign_data = new AstNode(AST_ASSIGN_EQ, new AstNode(AST_IDENTIFIER), mkconst_bits(x_bits_data, false));
assign_data->children[0]->str = id_data;
assign_data->children[0]->was_checked = true;
defNode->children.push_back(assign_data);
node_data = new AstNode(AST_IDENTIFIER);
node_data->str = id_data;
}
AstNode *wire_en = new AstNode(AST_WIRE, new AstNode(AST_RANGE, mkconst_int(mem_width-1, true), mkconst_int(0, true)));
wire_en->str = id_en;
wire_en->was_checked = true;
current_ast_mod->children.push_back(wire_en);
current_scope[wire_en->str] = wire_en;
while (wire_en->simplify(true, 1, -1, false)) { }
AstNode *assign_en_first = new AstNode(AST_ASSIGN_EQ, new AstNode(AST_IDENTIFIER), mkconst_int(0, false, mem_width));
assign_en_first->children[0]->str = id_en;
assign_en_first->children[0]->was_checked = true;
defNode->children.push_back(assign_en_first);
AstNode *node_en = new AstNode(AST_IDENTIFIER);
node_en->str = id_en;
if (!defNode->children.empty())
current_top_block->children.insert(current_top_block->children.begin(), defNode);
else
delete defNode;
AstNode *assign_data = nullptr;
AstNode *assign_en = nullptr;
if (children[0]->children.size() == 2)
{
if (children[0]->children[1]->range_valid)
{
int offset = children[0]->children[1]->range_right;
int width = children[0]->children[1]->range_left - offset + 1;
offset -= mem_data_range_offset;
std::vector<RTLIL::State> padding_x(offset, RTLIL::State::Sx);
assign_data = new AstNode(AST_ASSIGN_EQ, new AstNode(AST_IDENTIFIER),
new AstNode(AST_CONCAT, mkconst_bits(padding_x, false), children[1]->clone()));
assign_data->children[0]->str = id_data;
assign_data->children[0]->was_checked = true;
for (int i = 0; i < mem_width; i++)
set_bits_en[i] = offset <= i && i < offset+width ? RTLIL::State::S1 : RTLIL::State::S0;
assign_en = new AstNode(AST_ASSIGN_EQ, new AstNode(AST_IDENTIFIER), mkconst_bits(set_bits_en, false));
assign_en->children[0]->str = id_en;
assign_en->children[0]->was_checked = true;
}
else
{
AstNode *the_range = children[0]->children[1];
AstNode *offset_ast;
int width;
if (!try_determine_range_width(the_range, width))
input_error("Unsupported expression on dynamic range select on signal `%s'!\n", str.c_str());
if (the_range->children.size() >= 2)
offset_ast = the_range->children[1]->clone();
else
offset_ast = the_range->children[0]->clone();
if (mem_data_range_offset)
offset_ast = new AstNode(AST_SUB, offset_ast, mkconst_int(mem_data_range_offset, true));
assign_data = new AstNode(AST_ASSIGN_EQ, new AstNode(AST_IDENTIFIER),
new AstNode(AST_SHIFT_LEFT, children[1]->clone(), offset_ast->clone()));
assign_data->children[0]->str = id_data;
assign_data->children[0]->was_checked = true;
for (int i = 0; i < mem_width; i++)
set_bits_en[i] = i < width ? RTLIL::State::S1 : RTLIL::State::S0;
assign_en = new AstNode(AST_ASSIGN_EQ, new AstNode(AST_IDENTIFIER),
new AstNode(AST_SHIFT_LEFT, mkconst_bits(set_bits_en, false), offset_ast->clone()));
assign_en->children[0]->str = id_en;
assign_en->children[0]->was_checked = true;
delete offset_ast;
}
}
else
{
if (!(children[0]->children.size() == 1 && children[1]->isConst())) {
assign_data = new AstNode(AST_ASSIGN_EQ, new AstNode(AST_IDENTIFIER), children[1]->clone());
assign_data->children[0]->str = id_data;
assign_data->children[0]->was_checked = true;
}
assign_en = new AstNode(AST_ASSIGN_EQ, new AstNode(AST_IDENTIFIER), mkconst_bits(set_bits_en, false));
assign_en->children[0]->str = id_en;
assign_en->children[0]->was_checked = true;
}
if (assign_data)
newNode->children.push_back(assign_data);
if (assign_en)
newNode->children.push_back(assign_en);
AstNode *wrnode;
if (current_always->type == AST_INITIAL)
wrnode = new AstNode(AST_MEMINIT, node_addr, node_data, node_en, mkconst_int(1, false));
else
wrnode = new AstNode(AST_MEMWR, node_addr, node_data, node_en);
wrnode->str = children[0]->str;
wrnode->id2ast = children[0]->id2ast;
wrnode->location = location;
if (wrnode->type == AST_MEMWR) {
int portid = current_memwr_count[wrnode->str]++;
wrnode->children.push_back(mkconst_int(portid, false));
std::vector<RTLIL::State> priority_mask;
for (int i = 0; i < portid; i++) {
bool has_prio = current_memwr_visible[wrnode->str].count(i);
priority_mask.push_back(State(has_prio));
}
wrnode->children.push_back(mkconst_bits(priority_mask, false));
current_memwr_visible[wrnode->str].insert(portid);
current_always->children.push_back(wrnode);
} else {
current_ast_mod->children.push_back(wrnode);
}
if (newNode->children.empty()) {
delete newNode;
newNode = new AstNode();
}
goto apply_newNode;
}
// replace function and task calls with the code from the function or task
if ((type == AST_FCALL || type == AST_TCALL) && !str.empty())
{
if (type == AST_FCALL)
{
if (str == "\\$initstate")
{
int myidx = autoidx++;
AstNode *wire = new AstNode(AST_WIRE);
wire->str = stringf("$initstate$%d_wire", myidx);
current_ast_mod->children.push_back(wire);
while (wire->simplify(true, 1, -1, false)) { }
AstNode *cell = new AstNode(AST_CELL, new AstNode(AST_CELLTYPE), new AstNode(AST_ARGUMENT, new AstNode(AST_IDENTIFIER)));
cell->str = stringf("$initstate$%d", myidx);
cell->children[0]->str = "$initstate";
cell->children[1]->str = "\\Y";
cell->children[1]->children[0]->str = wire->str;
cell->children[1]->children[0]->id2ast = wire;
current_ast_mod->children.push_back(cell);
while (cell->simplify(true, 1, -1, false)) { }
newNode = new AstNode(AST_IDENTIFIER);
newNode->str = wire->str;
newNode->id2ast = wire;
goto apply_newNode;
}
if (str == "\\$past")
{
if (width_hint < 0)
goto replace_fcall_later;
int num_steps = 1;
if (GetSize(children) != 1 && GetSize(children) != 2)
input_error("System function %s got %d arguments, expected 1 or 2.\n",
RTLIL::unescape_id(str).c_str(), int(children.size()));
if (!current_always_clocked)
input_error("System function %s is only allowed in clocked blocks.\n",
RTLIL::unescape_id(str).c_str());
if (GetSize(children) == 2)
{
AstNode *buf = children[1]->clone();
while (buf->simplify(true, stage, -1, false)) { }
if (buf->type != AST_CONSTANT)
input_error("Failed to evaluate system function `%s' with non-constant value.\n", str.c_str());
num_steps = buf->asInt(true);
delete buf;
}
AstNode *block = nullptr;
for (auto child : current_always->children)
if (child->type == AST_BLOCK)
block = child;
log_assert(block != nullptr);
if (num_steps == 0) {
newNode = children[0]->clone();
goto apply_newNode;
}
int myidx = autoidx++;
AstNode *outreg = nullptr;
for (int i = 0; i < num_steps; i++)
{
AstNode *reg = new AstNode(AST_WIRE, new AstNode(AST_RANGE,
mkconst_int(width_hint-1, true), mkconst_int(0, true)));
reg->str = stringf("$past$%s:%d$%d$%d", RTLIL::encode_filename(filename).c_str(), location.first_line, myidx, i);
reg->is_reg = true;
reg->is_signed = sign_hint;
current_ast_mod->children.push_back(reg);
while (reg->simplify(true, 1, -1, false)) { }
AstNode *regid = new AstNode(AST_IDENTIFIER);
regid->str = reg->str;
regid->id2ast = reg;
regid->was_checked = true;
AstNode *rhs = nullptr;
if (outreg == nullptr) {
rhs = children.at(0)->clone();
} else {
rhs = new AstNode(AST_IDENTIFIER);
rhs->str = outreg->str;
rhs->id2ast = outreg;
}
block->children.push_back(new AstNode(AST_ASSIGN_LE, regid, rhs));
outreg = reg;
}
newNode = new AstNode(AST_IDENTIFIER);
newNode->str = outreg->str;
newNode->id2ast = outreg;
goto apply_newNode;
}
if (str == "\\$stable" || str == "\\$rose" || str == "\\$fell" || str == "\\$changed")
{
if (GetSize(children) != 1)
input_error("System function %s got %d arguments, expected 1.\n",
RTLIL::unescape_id(str).c_str(), int(children.size()));
if (!current_always_clocked)
input_error("System function %s is only allowed in clocked blocks.\n",
RTLIL::unescape_id(str).c_str());
AstNode *present = children.at(0)->clone();
AstNode *past = clone();
past->str = "\\$past";
if (str == "\\$stable")
newNode = new AstNode(AST_EQ, past, present);
else if (str == "\\$changed")
newNode = new AstNode(AST_NE, past, present);
else if (str == "\\$rose")
newNode = new AstNode(AST_LOGIC_AND,
new AstNode(AST_LOGIC_NOT, new AstNode(AST_BIT_AND, past, mkconst_int(1,false))),
new AstNode(AST_BIT_AND, present, mkconst_int(1,false)));
else if (str == "\\$fell")
newNode = new AstNode(AST_LOGIC_AND,
new AstNode(AST_BIT_AND, past, mkconst_int(1,false)),
new AstNode(AST_LOGIC_NOT, new AstNode(AST_BIT_AND, present, mkconst_int(1,false))));
else
log_abort();
goto apply_newNode;
}
// $anyconst and $anyseq are mapped in AstNode::genRTLIL()
if (str == "\\$anyconst" || str == "\\$anyseq" || str == "\\$allconst" || str == "\\$allseq") {
recursion_counter--;
return false;
}
if (str == "\\$clog2")
{
if (children.size() != 1)
input_error("System function %s got %d arguments, expected 1.\n",
RTLIL::unescape_id(str).c_str(), int(children.size()));
AstNode *buf = children[0]->clone();
while (buf->simplify(true, stage, width_hint, sign_hint)) { }
if (buf->type != AST_CONSTANT)
input_error("Failed to evaluate system function `%s' with non-constant value.\n", str.c_str());
RTLIL::Const arg_value = buf->bitsAsConst();
if (arg_value.as_bool())
arg_value = const_sub(arg_value, 1, false, false, GetSize(arg_value));
delete buf;
uint32_t result = 0;
for (size_t i = 0; i < arg_value.size(); i++)
if (arg_value.at(i) == RTLIL::State::S1)
result = i + 1;
newNode = mkconst_int(result, true);
goto apply_newNode;
}
if (str == "\\$dimensions" || str == "\\$unpacked_dimensions" ||
str == "\\$increment" || str == "\\$size" || str == "\\$bits" || str == "\\$high" || str == "\\$low" || str == "\\$left" || str == "\\$right")
{
int dim = 1;
if (str == "\\$dimensions" || str == "\\$unpacked_dimensions" || str == "\\$bits") {
if (children.size() != 1)
input_error("System function %s got %d arguments, expected 1.\n",
RTLIL::unescape_id(str).c_str(), int(children.size()));
} else {
if (children.size() != 1 && children.size() != 2)
input_error("System function %s got %d arguments, expected 1 or 2.\n",
RTLIL::unescape_id(str).c_str(), int(children.size()));
if (children.size() == 2) {
AstNode *buf = children[1]->clone();
// Evaluate constant expression
while (buf->simplify(true, stage, width_hint, sign_hint)) { }
dim = buf->asInt(false);
delete buf;
}
}
AstNode *buf = children[0]->clone();
int mem_depth = 1;
int result, high = 0, low = 0, left = 0, right = 0, width = 1; // defaults for a simple wire
int expr_dimensions = 0, expr_unpacked_dimensions = 0;
AstNode *id_ast = NULL;
buf->detectSignWidth(width_hint, sign_hint);
if (buf->type == AST_IDENTIFIER) {
id_ast = buf->id2ast;
if (id_ast == NULL && current_scope.count(buf->str))
id_ast = current_scope.at(buf->str);
if (!id_ast)
input_error("Failed to resolve identifier %s for width detection!\n", buf->str.c_str());
if (id_ast->type == AST_WIRE || id_ast->type == AST_MEMORY) {
// Check for item in packed struct / union
AstNode *item_node = buf->get_struct_member();
if (item_node)
id_ast = item_node;
// The dimension of the original array expression is saved in the 'integer' field
dim += buf->integer;
int dims = GetSize(id_ast->dimensions);
// TODO: IEEE Std 1800-2017 20.7: "If the first argument to an array query function would cause $dimensions to return 0
// or if the second argument is out of range, then 'x shall be returned."
if (dim < 1 || dim > dims)
input_error("Dimension %d out of range in `%s', as it only has %d dimensions!\n", dim, id_ast->str.c_str(), dims);
expr_dimensions = dims - dim + 1;
expr_unpacked_dimensions = std::max(id_ast->unpacked_dimensions - dim + 1, 0);
right = low = id_ast->dimensions[dim - 1].range_right;
left = high = low + id_ast->dimensions[dim - 1].range_width - 1;
if (id_ast->dimensions[dim - 1].range_swapped) {
std::swap(left, right);
}
for (int i = dim; i < dims; i++) {
mem_depth *= id_ast->dimensions[i].range_width;
}
}
width = high - low + 1;
} else {
width = width_hint;
right = low = 0;
left = high = width - 1;
expr_dimensions = 1;
}
delete buf;
if (str == "\\$dimensions")
result = expr_dimensions;
else if (str == "\\$unpacked_dimensions")
result = expr_unpacked_dimensions;
else if (str == "\\$high")
result = high;
else if (str == "\\$low")
result = low;
else if (str == "\\$left")
result = left;
else if (str == "\\$right")
result = right;
else if (str == "\\$increment")
result = left >= right ? 1 : -1;
else if (str == "\\$size")
result = width;
else { // str == "\\$bits"
result = width * mem_depth;
}
newNode = mkconst_int(result, true);
goto apply_newNode;
}
if (str == "\\$ln" || str == "\\$log10" || str == "\\$exp" || str == "\\$sqrt" || str == "\\$pow" ||
str == "\\$floor" || str == "\\$ceil" || str == "\\$sin" || str == "\\$cos" || str == "\\$tan" ||
str == "\\$asin" || str == "\\$acos" || str == "\\$atan" || str == "\\$atan2" || str == "\\$hypot" ||
str == "\\$sinh" || str == "\\$cosh" || str == "\\$tanh" || str == "\\$asinh" || str == "\\$acosh" || str == "\\$atanh" ||
str == "\\$rtoi" || str == "\\$itor")
{
bool func_with_two_arguments = str == "\\$pow" || str == "\\$atan2" || str == "\\$hypot";
double x = 0, y = 0;
if (func_with_two_arguments) {
if (children.size() != 2)
input_error("System function %s got %d arguments, expected 2.\n",
RTLIL::unescape_id(str).c_str(), int(children.size()));
} else {
if (children.size() != 1)
input_error("System function %s got %d arguments, expected 1.\n",
RTLIL::unescape_id(str).c_str(), int(children.size()));
}
if (children.size() >= 1) {
while (children[0]->simplify(true, stage, width_hint, sign_hint)) { }
if (!children[0]->isConst())
input_error("Failed to evaluate system function `%s' with non-constant argument.\n",
RTLIL::unescape_id(str).c_str());
int child_width_hint = width_hint;
bool child_sign_hint = sign_hint;
children[0]->detectSignWidth(child_width_hint, child_sign_hint);
x = children[0]->asReal(child_sign_hint);
}
if (children.size() >= 2) {
while (children[1]->simplify(true, stage, width_hint, sign_hint)) { }
if (!children[1]->isConst())
input_error("Failed to evaluate system function `%s' with non-constant argument.\n",
RTLIL::unescape_id(str).c_str());
int child_width_hint = width_hint;
bool child_sign_hint = sign_hint;
children[1]->detectSignWidth(child_width_hint, child_sign_hint);
y = children[1]->asReal(child_sign_hint);
}
if (str == "\\$rtoi") {
newNode = AstNode::mkconst_int(x, true);
} else {
newNode = new AstNode(AST_REALVALUE);
if (str == "\\$ln") newNode->realvalue = ::log(x);
else if (str == "\\$log10") newNode->realvalue = ::log10(x);
else if (str == "\\$exp") newNode->realvalue = ::exp(x);
else if (str == "\\$sqrt") newNode->realvalue = ::sqrt(x);
else if (str == "\\$pow") newNode->realvalue = ::pow(x, y);
else if (str == "\\$floor") newNode->realvalue = ::floor(x);
else if (str == "\\$ceil") newNode->realvalue = ::ceil(x);
else if (str == "\\$sin") newNode->realvalue = ::sin(x);
else if (str == "\\$cos") newNode->realvalue = ::cos(x);
else if (str == "\\$tan") newNode->realvalue = ::tan(x);
else if (str == "\\$asin") newNode->realvalue = ::asin(x);
else if (str == "\\$acos") newNode->realvalue = ::acos(x);
else if (str == "\\$atan") newNode->realvalue = ::atan(x);
else if (str == "\\$atan2") newNode->realvalue = ::atan2(x, y);
else if (str == "\\$hypot") newNode->realvalue = ::hypot(x, y);
else if (str == "\\$sinh") newNode->realvalue = ::sinh(x);
else if (str == "\\$cosh") newNode->realvalue = ::cosh(x);
else if (str == "\\$tanh") newNode->realvalue = ::tanh(x);
else if (str == "\\$asinh") newNode->realvalue = ::asinh(x);
else if (str == "\\$acosh") newNode->realvalue = ::acosh(x);
else if (str == "\\$atanh") newNode->realvalue = ::atanh(x);
else if (str == "\\$itor") newNode->realvalue = x;
else log_abort();
}
goto apply_newNode;
}
if (str == "\\$sformatf") {
Fmt fmt = processFormat(stage, /*sformat_like=*/true);
newNode = AstNode::mkconst_str(fmt.render());
goto apply_newNode;
}
if (str == "\\$countbits") {
if (children.size() < 2)
input_error("System function %s got %d arguments, expected at least 2.\n",
RTLIL::unescape_id(str).c_str(), int(children.size()));
std::vector<RTLIL::State> control_bits;
// Determine which bits to count
for (size_t i = 1; i < children.size(); i++) {
AstNode *node = children[i];
while (node->simplify(true, stage, -1, false)) { }
if (node->type != AST_CONSTANT)
input_error("Failed to evaluate system function `%s' with non-constant control bit argument.\n", str.c_str());
if (node->bits.size() != 1)
input_error("Failed to evaluate system function `%s' with control bit width != 1.\n", str.c_str());
control_bits.push_back(node->bits[0]);
}
// Detect width of exp (first argument of $countbits)
int exp_width = -1;
bool exp_sign = false;
AstNode *exp = children[0];
exp->detectSignWidth(exp_width, exp_sign, NULL);
newNode = mkconst_int(0, false);
for (int i = 0; i < exp_width; i++) {
// Generate nodes for: exp << i >> ($size(exp) - 1)
// ^^ ^^
AstNode *lsh_node = new AstNode(AST_SHIFT_LEFT, exp->clone(), mkconst_int(i, false));
AstNode *rsh_node = new AstNode(AST_SHIFT_RIGHT, lsh_node, mkconst_int(exp_width - 1, false));
AstNode *or_node = nullptr;
for (RTLIL::State control_bit : control_bits) {
// Generate node for: (exp << i >> ($size(exp) - 1)) === control_bit
// ^^^
AstNode *eq_node = new AstNode(AST_EQX, rsh_node->clone(), mkconst_bits({control_bit}, false));
// Or the result for each checked bit value
if (or_node)
or_node = new AstNode(AST_LOGIC_OR, or_node, eq_node);
else
or_node = eq_node;
}
// We should have at least one element in control_bits,
// because we checked for the number of arguments above
log_assert(or_node != nullptr);
delete rsh_node;
// Generate node for adding with result of previous bit
newNode = new AstNode(AST_ADD, newNode, or_node);
}
goto apply_newNode;
}
if (str == "\\$countones" || str == "\\$isunknown" || str == "\\$onehot" || str == "\\$onehot0") {
if (children.size() != 1)
input_error("System function %s got %d arguments, expected 1.\n",
RTLIL::unescape_id(str).c_str(), int(children.size()));
AstNode *countbits = clone();
countbits->str = "\\$countbits";
if (str == "\\$countones") {
countbits->children.push_back(mkconst_bits({RTLIL::State::S1}, false));
newNode = countbits;
} else if (str == "\\$isunknown") {
countbits->children.push_back(mkconst_bits({RTLIL::Sx}, false));
countbits->children.push_back(mkconst_bits({RTLIL::Sz}, false));
newNode = new AstNode(AST_GT, countbits, mkconst_int(0, false));
} else if (str == "\\$onehot") {
countbits->children.push_back(mkconst_bits({RTLIL::State::S1}, false));
newNode = new AstNode(AST_EQ, countbits, mkconst_int(1, false));
} else if (str == "\\$onehot0") {
countbits->children.push_back(mkconst_bits({RTLIL::State::S1}, false));
newNode = new AstNode(AST_LE, countbits, mkconst_int(1, false));
} else {
log_abort();
}
goto apply_newNode;
}
if (current_scope.count(str) != 0 && current_scope[str]->type == AST_DPI_FUNCTION)
{
AstNode *dpi_decl = current_scope[str];
std::string rtype, fname;
std::vector<std::string> argtypes;
std::vector<AstNode*> args;
rtype = RTLIL::unescape_id(dpi_decl->children.at(0)->str);
fname = RTLIL::unescape_id(dpi_decl->children.at(1)->str);
for (int i = 2; i < GetSize(dpi_decl->children); i++)
{
if (i-2 >= GetSize(children))
input_error("Insufficient number of arguments in DPI function call.\n");
argtypes.push_back(RTLIL::unescape_id(dpi_decl->children.at(i)->str));
args.push_back(children.at(i-2)->clone());
while (args.back()->simplify(true, stage, -1, false)) { }
if (args.back()->type != AST_CONSTANT && args.back()->type != AST_REALVALUE)
input_error("Failed to evaluate DPI function with non-constant argument.\n");
}
newNode = dpi_call(rtype, fname, argtypes, args);
for (auto arg : args)
delete arg;
goto apply_newNode;
}
if (current_scope.count(str) == 0)
str = try_pop_module_prefix();
if (current_scope.count(str) == 0 || current_scope[str]->type != AST_FUNCTION)
input_error("Can't resolve function name `%s'.\n", str.c_str());
}
if (type == AST_TCALL)
{
if (str == "$finish" || str == "$stop")
{
if (!current_always || current_always->type != AST_INITIAL)
input_error("System task `%s' outside initial block is unsupported.\n", str.c_str());
input_error("System task `%s' executed.\n", str.c_str());
}
if (str == "\\$readmemh" || str == "\\$readmemb")
{
if (GetSize(children) < 2 || GetSize(children) > 4)
input_error("System function %s got %d arguments, expected 2-4.\n",
RTLIL::unescape_id(str).c_str(), int(children.size()));
AstNode *node_filename = children[0]->clone();
while (node_filename->simplify(true, stage, width_hint, sign_hint)) { }
if (node_filename->type != AST_CONSTANT)
input_error("Failed to evaluate system function `%s' with non-constant 1st argument.\n", str.c_str());
AstNode *node_memory = children[1]->clone();
while (node_memory->simplify(true, stage, width_hint, sign_hint)) { }
if (node_memory->type != AST_IDENTIFIER || node_memory->id2ast == nullptr || node_memory->id2ast->type != AST_MEMORY)
input_error("Failed to evaluate system function `%s' with non-memory 2nd argument.\n", str.c_str());
int start_addr = -1, finish_addr = -1;
if (GetSize(children) > 2) {
AstNode *node_addr = children[2]->clone();
while (node_addr->simplify(true, stage, width_hint, sign_hint)) { }
if (node_addr->type != AST_CONSTANT)
input_error("Failed to evaluate system function `%s' with non-constant 3rd argument.\n", str.c_str());
start_addr = int(node_addr->asInt(false));
}
if (GetSize(children) > 3) {
AstNode *node_addr = children[3]->clone();
while (node_addr->simplify(true, stage, width_hint, sign_hint)) { }
if (node_addr->type != AST_CONSTANT)
input_error("Failed to evaluate system function `%s' with non-constant 4th argument.\n", str.c_str());
finish_addr = int(node_addr->asInt(false));
}
bool unconditional_init = false;
if (current_always->type == AST_INITIAL) {
pool<AstNode*> queue;
log_assert(current_always->children[0]->type == AST_BLOCK);
queue.insert(current_always->children[0]);
while (!unconditional_init && !queue.empty()) {
pool<AstNode*> next_queue;
for (auto n : queue)
for (auto c : n->children) {
if (c == this)
unconditional_init = true;
next_queue.insert(c);
}
next_queue.swap(queue);
}
}
newNode = readmem(str == "\\$readmemh", node_filename->bitsAsConst().decode_string(), node_memory->id2ast, start_addr, finish_addr, unconditional_init);
delete node_filename;
delete node_memory;
goto apply_newNode;
}
if (current_scope.count(str) == 0)
str = try_pop_module_prefix();
if (current_scope.count(str) == 0 || current_scope[str]->type != AST_TASK)
input_error("Can't resolve task name `%s'.\n", str.c_str());
}
std::stringstream sstr;
sstr << str << "$func$" << RTLIL::encode_filename(filename) << ":" << location.first_line << "$" << (autoidx++) << '.';
std::string prefix = sstr.str();
AstNode *decl = current_scope[str];
if (unevaluated_tern_branch && decl->is_recursive_function())
goto replace_fcall_later;
decl = decl->clone();
decl->replace_result_wire_name_in_function(str, "$result"); // enables recursion
decl->expand_genblock(prefix);
if (decl->type == AST_FUNCTION && !decl->attributes.count(ID::via_celltype))
{
bool require_const_eval = decl->has_const_only_constructs();
bool all_args_const = true;
for (auto child : children) {
while (child->simplify(true, 1, -1, false)) { }
if (child->type != AST_CONSTANT && child->type != AST_REALVALUE)
all_args_const = false;
}
if (all_args_const) {
AstNode *func_workspace = decl->clone();
func_workspace->set_in_param_flag(true);
func_workspace->str = prefix_id(prefix, "$result");
newNode = func_workspace->eval_const_function(this, in_param || require_const_eval);
delete func_workspace;
if (newNode) {
delete decl;
goto apply_newNode;
}
}
if (in_param)
input_error("Non-constant function call in constant expression.\n");
if (require_const_eval)
input_error("Function %s can only be called with constant arguments.\n", str.c_str());
}
size_t arg_count = 0;
dict<std::string, AstNode*> wire_cache;
vector<AstNode*> new_stmts;
vector<AstNode*> output_assignments;
if (current_block == NULL)
{
log_assert(type == AST_FCALL);
AstNode *wire = NULL;
std::string res_name = prefix_id(prefix, "$result");
for (auto child : decl->children)
if (child->type == AST_WIRE && child->str == res_name)
wire = child->clone();
log_assert(wire != NULL);
wire->port_id = 0;
wire->is_input = false;
wire->is_output = false;
current_scope[wire->str] = wire;
current_ast_mod->children.push_back(wire);
while (wire->simplify(true, 1, -1, false)) { }
AstNode *lvalue = new AstNode(AST_IDENTIFIER);
lvalue->str = wire->str;
AstNode *always = new AstNode(AST_ALWAYS, new AstNode(AST_BLOCK,
new AstNode(AST_ASSIGN_EQ, lvalue, clone())));
always->children[0]->children[0]->was_checked = true;
current_ast_mod->children.push_back(always);
goto replace_fcall_with_id;
}
if (decl->attributes.count(ID::via_celltype))
{
std::string celltype = decl->attributes.at(ID::via_celltype)->asAttrConst().decode_string();
std::string outport = str;
if (celltype.find(' ') != std::string::npos) {
int pos = celltype.find(' ');
outport = RTLIL::escape_id(celltype.substr(pos+1));
celltype = RTLIL::escape_id(celltype.substr(0, pos));
} else
celltype = RTLIL::escape_id(celltype);
AstNode *cell = new AstNode(AST_CELL, new AstNode(AST_CELLTYPE));
cell->str = prefix.substr(0, GetSize(prefix)-1);
cell->children[0]->str = celltype;
for (auto attr : decl->attributes)
if (attr.first.str().rfind("\\via_celltype_defparam_", 0) == 0)
{
AstNode *cell_arg = new AstNode(AST_PARASET, attr.second->clone());
cell_arg->str = RTLIL::escape_id(attr.first.substr(strlen("\\via_celltype_defparam_")));
cell->children.push_back(cell_arg);
}
for (auto child : decl->children)
if (child->type == AST_WIRE && (child->is_input || child->is_output || (type == AST_FCALL && child->str == str)))
{
AstNode *wire = child->clone();
wire->port_id = 0;
wire->is_input = false;
wire->is_output = false;
current_ast_mod->children.push_back(wire);
while (wire->simplify(true, 1, -1, false)) { }
AstNode *wire_id = new AstNode(AST_IDENTIFIER);
wire_id->str = wire->str;
if ((child->is_input || child->is_output) && arg_count < children.size())
{
AstNode *arg = children[arg_count++]->clone();
AstNode *assign = child->is_input ?
new AstNode(AST_ASSIGN_EQ, wire_id->clone(), arg) :
new AstNode(AST_ASSIGN_EQ, arg, wire_id->clone());
assign->children[0]->was_checked = true;
for (auto it = current_block->children.begin(); it != current_block->children.end(); it++) {
if (*it != current_block_child)
continue;
current_block->children.insert(it, assign);
break;
}
}
AstNode *cell_arg = new AstNode(AST_ARGUMENT, wire_id);
cell_arg->str = child->str == str ? outport : child->str;
cell->children.push_back(cell_arg);
}
current_ast_mod->children.push_back(cell);
goto replace_fcall_with_id;
}
for (auto child : decl->children)
if (child->type == AST_WIRE || child->type == AST_MEMORY || child->type == AST_PARAMETER || child->type == AST_LOCALPARAM || child->type == AST_ENUM_ITEM)
{
AstNode *wire = nullptr;
if (wire_cache.count(child->str))
{
wire = wire_cache.at(child->str);
bool contains_value = wire->type == AST_LOCALPARAM;
if (wire->children.size() == contains_value) {
for (auto c : child->children)
wire->children.push_back(c->clone());
} else if (!child->children.empty()) {
while (child->simplify(true, stage, -1, false)) { }
if (GetSize(child->children) == GetSize(wire->children) - contains_value) {
for (int i = 0; i < GetSize(child->children); i++)
if (*child->children.at(i) != *wire->children.at(i + contains_value))
goto tcall_incompatible_wires;
} else {
tcall_incompatible_wires:
input_error("Incompatible re-declaration of wire %s.\n", child->str.c_str());
}
}
}
else
{
wire = child->clone();
wire->port_id = 0;
wire->is_input = false;
wire->is_output = false;
wire->is_reg = true;
wire->set_attribute(ID::nosync, AstNode::mkconst_int(1, false));
if (child->type == AST_ENUM_ITEM)
wire->set_attribute(ID::enum_base_type, child->attributes[ID::enum_base_type]);
wire_cache[child->str] = wire;
current_scope[wire->str] = wire;
current_ast_mod->children.push_back(wire);
}
while (wire->simplify(true, 1, -1, false)) { }
if ((child->is_input || child->is_output) && arg_count < children.size())
{
AstNode *arg = children[arg_count++]->clone();
// convert purely constant arguments into localparams
if (child->is_input && child->type == AST_WIRE && arg->type == AST_CONSTANT && node_contains_assignment_to(decl, child)) {
wire->type = AST_LOCALPARAM;
if (wire->attributes.count(ID::nosync))
delete wire->attributes.at(ID::nosync);
wire->attributes.erase(ID::nosync);
wire->children.insert(wire->children.begin(), arg->clone());
// args without a range implicitly have width 1
if (wire->children.back()->type != AST_RANGE) {
// check if this wire is redeclared with an explicit size
bool uses_explicit_size = false;
for (const AstNode *other_child : decl->children)
if (other_child->type == AST_WIRE && child->str == other_child->str
&& !other_child->children.empty()
&& other_child->children.back()->type == AST_RANGE) {
uses_explicit_size = true;
break;
}
if (!uses_explicit_size) {
AstNode* range = new AstNode();
range->type = AST_RANGE;
wire->children.push_back(range);
range->children.push_back(mkconst_int(0, true));
range->children.push_back(mkconst_int(0, true));
}
}
wire->fixup_hierarchy_flags();
// updates the sizing
while (wire->simplify(true, 1, -1, false)) { }
delete arg;
continue;
}
AstNode *wire_id = new AstNode(AST_IDENTIFIER);
wire_id->str = wire->str;
AstNode *assign = child->is_input ?
new AstNode(AST_ASSIGN_EQ, wire_id, arg) :
new AstNode(AST_ASSIGN_EQ, arg, wire_id);
assign->children[0]->was_checked = true;
if (child->is_input)
new_stmts.push_back(assign);
else
output_assignments.push_back(assign);
}
}
for (auto child : decl->children)
if (child->type != AST_WIRE && child->type != AST_MEMORY && child->type != AST_PARAMETER && child->type != AST_LOCALPARAM)
new_stmts.push_back(child->clone());
new_stmts.insert(new_stmts.end(), output_assignments.begin(), output_assignments.end());
for (auto it = current_block->children.begin(); ; it++) {
log_assert(it != current_block->children.end());
if (*it == current_block_child) {
current_block->children.insert(it, new_stmts.begin(), new_stmts.end());
break;
}
}
replace_fcall_with_id:
delete decl;
if (type == AST_FCALL) {
delete_children();
type = AST_IDENTIFIER;
str = prefix_id(prefix, "$result");
}
if (type == AST_TCALL)
str = "";
did_something = true;
}
replace_fcall_later:;
// perform const folding when activated
if (const_fold)
{
bool string_op;
std::vector<RTLIL::State> tmp_bits;
RTLIL::Const (*const_func)(const RTLIL::Const&, const RTLIL::Const&, bool, bool, int);
RTLIL::Const dummy_arg;
switch (type)
{
case AST_IDENTIFIER:
if (current_scope.count(str) > 0 && (current_scope[str]->type == AST_PARAMETER || current_scope[str]->type == AST_LOCALPARAM || current_scope[str]->type == AST_ENUM_ITEM)) {
if (current_scope[str]->children[0]->type == AST_CONSTANT) {
if (children.size() != 0 && children[0]->type == AST_RANGE && children[0]->range_valid) {
std::vector<RTLIL::State> data;
bool param_upto = current_scope[str]->range_valid && current_scope[str]->range_swapped;
int param_offset = current_scope[str]->range_valid ? current_scope[str]->range_right : 0;
int param_width = current_scope[str]->range_valid ? current_scope[str]->range_left - current_scope[str]->range_right + 1 :
GetSize(current_scope[str]->children[0]->bits);
int tmp_range_left = children[0]->range_left, tmp_range_right = children[0]->range_right;
if (param_upto) {
tmp_range_left = (param_width + 2*param_offset) - children[0]->range_right - 1;
tmp_range_right = (param_width + 2*param_offset) - children[0]->range_left - 1;
}
AstNode *member_node = get_struct_member();
int chunk_offset = member_node ? member_node->range_right : 0;
log_assert(!(chunk_offset && param_upto));
for (int i = tmp_range_right; i <= tmp_range_left; i++) {
int index = i - param_offset;
if (0 <= index && index < param_width)
data.push_back(current_scope[str]->children[0]->bits[chunk_offset + index]);
else
data.push_back(RTLIL::State::Sx);
}
newNode = mkconst_bits(data, false);
} else
if (children.size() == 0)
newNode = current_scope[str]->children[0]->clone();
} else
if (current_scope[str]->children[0]->isConst())
newNode = current_scope[str]->children[0]->clone();
}
break;
case AST_BIT_NOT:
if (children[0]->type == AST_CONSTANT) {
RTLIL::Const y = RTLIL::const_not(children[0]->bitsAsConst(width_hint, sign_hint), dummy_arg, sign_hint, false, width_hint);
newNode = mkconst_bits(y.to_bits(), sign_hint);
}
break;
case AST_TO_SIGNED:
case AST_TO_UNSIGNED:
if (children[0]->type == AST_CONSTANT) {
RTLIL::Const y = children[0]->bitsAsConst(width_hint, sign_hint);
newNode = mkconst_bits(y.to_bits(), type == AST_TO_SIGNED);
}
break;
if (0) { case AST_BIT_AND: const_func = RTLIL::const_and; }
if (0) { case AST_BIT_OR: const_func = RTLIL::const_or; }
if (0) { case AST_BIT_XOR: const_func = RTLIL::const_xor; }
if (0) { case AST_BIT_XNOR: const_func = RTLIL::const_xnor; }
if (children[0]->type == AST_CONSTANT && children[1]->type == AST_CONSTANT) {
RTLIL::Const y = const_func(children[0]->bitsAsConst(width_hint, sign_hint),
children[1]->bitsAsConst(width_hint, sign_hint), sign_hint, sign_hint, width_hint);
newNode = mkconst_bits(y.to_bits(), sign_hint);
}
break;
if (0) { case AST_REDUCE_AND: const_func = RTLIL::const_reduce_and; }
if (0) { case AST_REDUCE_OR: const_func = RTLIL::const_reduce_or; }
if (0) { case AST_REDUCE_XOR: const_func = RTLIL::const_reduce_xor; }
if (0) { case AST_REDUCE_XNOR: const_func = RTLIL::const_reduce_xnor; }
if (0) { case AST_REDUCE_BOOL: const_func = RTLIL::const_reduce_bool; }
if (children[0]->type == AST_CONSTANT) {
RTLIL::Const y = const_func(RTLIL::Const(children[0]->bits), dummy_arg, false, false, -1);
newNode = mkconst_bits(y.to_bits(), false);
}
break;
case AST_LOGIC_NOT:
if (children[0]->type == AST_CONSTANT) {
RTLIL::Const y = RTLIL::const_logic_not(RTLIL::Const(children[0]->bits), dummy_arg, children[0]->is_signed, false, -1);
newNode = mkconst_bits(y.to_bits(), false);
} else
if (children[0]->isConst()) {
newNode = mkconst_int(children[0]->asReal(sign_hint) == 0, false, 1);
}
break;
if (0) { case AST_LOGIC_AND: const_func = RTLIL::const_logic_and; }
if (0) { case AST_LOGIC_OR: const_func = RTLIL::const_logic_or; }
if (children[0]->type == AST_CONSTANT && children[1]->type == AST_CONSTANT) {
RTLIL::Const y = const_func(RTLIL::Const(children[0]->bits), RTLIL::Const(children[1]->bits),
children[0]->is_signed, children[1]->is_signed, -1);
newNode = mkconst_bits(y.to_bits(), false);
} else
if (children[0]->isConst() && children[1]->isConst()) {
if (type == AST_LOGIC_AND)
newNode = mkconst_int((children[0]->asReal(sign_hint) != 0) && (children[1]->asReal(sign_hint) != 0), false, 1);
else
newNode = mkconst_int((children[0]->asReal(sign_hint) != 0) || (children[1]->asReal(sign_hint) != 0), false, 1);
}
break;
if (0) { case AST_SHIFT_LEFT: const_func = RTLIL::const_shl; }
if (0) { case AST_SHIFT_RIGHT: const_func = RTLIL::const_shr; }
if (0) { case AST_SHIFT_SLEFT: const_func = RTLIL::const_sshl; }
if (0) { case AST_SHIFT_SRIGHT: const_func = RTLIL::const_sshr; }
if (0) { case AST_POW: const_func = RTLIL::const_pow; }
if (children[0]->type == AST_CONSTANT && children[1]->type == AST_CONSTANT) {
RTLIL::Const y = const_func(children[0]->bitsAsConst(width_hint, sign_hint),
RTLIL::Const(children[1]->bits), sign_hint, type == AST_POW ? children[1]->is_signed : false, width_hint);
newNode = mkconst_bits(y.to_bits(), sign_hint);
} else
if (type == AST_POW && children[0]->isConst() && children[1]->isConst()) {
newNode = new AstNode(AST_REALVALUE);
newNode->realvalue = pow(children[0]->asReal(sign_hint), children[1]->asReal(sign_hint));
}
break;
if (0) { case AST_LT: const_func = RTLIL::const_lt; }
if (0) { case AST_LE: const_func = RTLIL::const_le; }
if (0) { case AST_EQ: const_func = RTLIL::const_eq; }
if (0) { case AST_NE: const_func = RTLIL::const_ne; }
if (0) { case AST_EQX: const_func = RTLIL::const_eqx; }
if (0) { case AST_NEX: const_func = RTLIL::const_nex; }
if (0) { case AST_GE: const_func = RTLIL::const_ge; }
if (0) { case AST_GT: const_func = RTLIL::const_gt; }
if (children[0]->type == AST_CONSTANT && children[1]->type == AST_CONSTANT) {
int cmp_width = max(children[0]->bits.size(), children[1]->bits.size());
bool cmp_signed = children[0]->is_signed && children[1]->is_signed;
RTLIL::Const y = const_func(children[0]->bitsAsConst(cmp_width, cmp_signed),
children[1]->bitsAsConst(cmp_width, cmp_signed), cmp_signed, cmp_signed, 1);
newNode = mkconst_bits(y.to_bits(), false);
} else
if (children[0]->isConst() && children[1]->isConst()) {
bool cmp_signed = (children[0]->type == AST_REALVALUE || children[0]->is_signed) && (children[1]->type == AST_REALVALUE || children[1]->is_signed);
switch (type) {
case AST_LT: newNode = mkconst_int(children[0]->asReal(cmp_signed) < children[1]->asReal(cmp_signed), false, 1); break;
case AST_LE: newNode = mkconst_int(children[0]->asReal(cmp_signed) <= children[1]->asReal(cmp_signed), false, 1); break;
case AST_EQ: newNode = mkconst_int(children[0]->asReal(cmp_signed) == children[1]->asReal(cmp_signed), false, 1); break;
case AST_NE: newNode = mkconst_int(children[0]->asReal(cmp_signed) != children[1]->asReal(cmp_signed), false, 1); break;
case AST_EQX: newNode = mkconst_int(children[0]->asReal(cmp_signed) == children[1]->asReal(cmp_signed), false, 1); break;
case AST_NEX: newNode = mkconst_int(children[0]->asReal(cmp_signed) != children[1]->asReal(cmp_signed), false, 1); break;
case AST_GE: newNode = mkconst_int(children[0]->asReal(cmp_signed) >= children[1]->asReal(cmp_signed), false, 1); break;
case AST_GT: newNode = mkconst_int(children[0]->asReal(cmp_signed) > children[1]->asReal(cmp_signed), false, 1); break;
default: log_abort();
}
}
break;
if (0) { case AST_ADD: const_func = RTLIL::const_add; }
if (0) { case AST_SUB: const_func = RTLIL::const_sub; }
if (0) { case AST_MUL: const_func = RTLIL::const_mul; }
if (0) { case AST_DIV: const_func = RTLIL::const_div; }
if (0) { case AST_MOD: const_func = RTLIL::const_mod; }
if (children[0]->type == AST_CONSTANT && children[1]->type == AST_CONSTANT) {
RTLIL::Const y = const_func(children[0]->bitsAsConst(width_hint, sign_hint),
children[1]->bitsAsConst(width_hint, sign_hint), sign_hint, sign_hint, width_hint);
newNode = mkconst_bits(y.to_bits(), sign_hint);
} else
if (children[0]->isConst() && children[1]->isConst()) {
newNode = new AstNode(AST_REALVALUE);
switch (type) {
case AST_ADD: newNode->realvalue = children[0]->asReal(sign_hint) + children[1]->asReal(sign_hint); break;
case AST_SUB: newNode->realvalue = children[0]->asReal(sign_hint) - children[1]->asReal(sign_hint); break;
case AST_MUL: newNode->realvalue = children[0]->asReal(sign_hint) * children[1]->asReal(sign_hint); break;
case AST_DIV: newNode->realvalue = children[0]->asReal(sign_hint) / children[1]->asReal(sign_hint); break;
case AST_MOD: newNode->realvalue = fmod(children[0]->asReal(sign_hint), children[1]->asReal(sign_hint)); break;
default: log_abort();
}
}
break;
if (0) { case AST_SELFSZ: const_func = RTLIL::const_pos; }
if (0) { case AST_POS: const_func = RTLIL::const_pos; }
if (0) { case AST_NEG: const_func = RTLIL::const_neg; }
if (children[0]->type == AST_CONSTANT) {
RTLIL::Const y = const_func(children[0]->bitsAsConst(width_hint, sign_hint), dummy_arg, sign_hint, false, width_hint);
newNode = mkconst_bits(y.to_bits(), sign_hint);
} else
if (children[0]->isConst()) {
newNode = new AstNode(AST_REALVALUE);
if (type == AST_NEG)
newNode->realvalue = -children[0]->asReal(sign_hint);
else
newNode->realvalue = +children[0]->asReal(sign_hint);
}
break;
case AST_TERNARY:
if (children[0]->isConst())
{
auto pair = get_tern_choice();
AstNode *choice = pair.first;
AstNode *not_choice = pair.second;
if (choice != NULL) {
if (choice->type == AST_CONSTANT) {
int other_width_hint = width_hint;
bool other_sign_hint = sign_hint, other_real = false;
not_choice->detectSignWidth(other_width_hint, other_sign_hint, &other_real);
if (other_real) {
newNode = new AstNode(AST_REALVALUE);
choice->detectSignWidth(width_hint, sign_hint);
newNode->realvalue = choice->asReal(sign_hint);
} else {
RTLIL::Const y = choice->bitsAsConst(width_hint, sign_hint);
if (choice->is_string && y.size() % 8 == 0 && sign_hint == false)
newNode = mkconst_str(y.to_bits());
else
newNode = mkconst_bits(y.to_bits(), sign_hint);
}
} else
if (choice->isConst()) {
newNode = choice->clone();
}
} else if (children[1]->type == AST_CONSTANT && children[2]->type == AST_CONSTANT) {
RTLIL::Const a = children[1]->bitsAsConst(width_hint, sign_hint);
RTLIL::Const b = children[2]->bitsAsConst(width_hint, sign_hint);
log_assert(a.size() == b.size());
for (size_t i = 0; i < a.size(); i++)
if (a[i] != b[i])
a.bits()[i] = RTLIL::State::Sx;
newNode = mkconst_bits(a.to_bits(), sign_hint);
} else if (children[1]->isConst() && children[2]->isConst()) {
newNode = new AstNode(AST_REALVALUE);
if (children[1]->asReal(sign_hint) == children[2]->asReal(sign_hint))
newNode->realvalue = children[1]->asReal(sign_hint);
else
// IEEE Std 1800-2012 Sec. 11.4.11 states that the entry in Table 7-1 for
// the data type in question should be returned if the ?: is ambiguous. The
// value in Table 7-1 for the 'real' type is 0.0.
newNode->realvalue = 0.0;
}
}
break;
case AST_CAST_SIZE:
if (children.at(0)->type == AST_CONSTANT && children.at(1)->type == AST_CONSTANT) {
int width = children[0]->bitsAsConst().as_int();
RTLIL::Const val;
if (children[1]->is_unsized)
val = children[1]->bitsAsUnsizedConst(width);
else
val = children[1]->bitsAsConst(width);
newNode = mkconst_bits(val.to_bits(), children[1]->is_signed);
}
break;
case AST_CONCAT:
string_op = !children.empty();
for (auto it = children.begin(); it != children.end(); it++) {
if ((*it)->type != AST_CONSTANT)
goto not_const;
if (!(*it)->is_string)
string_op = false;
tmp_bits.insert(tmp_bits.end(), (*it)->bits.begin(), (*it)->bits.end());
}
newNode = string_op ? mkconst_str(tmp_bits) : mkconst_bits(tmp_bits, false);
break;
case AST_REPLICATE:
if (children.at(0)->type != AST_CONSTANT || children.at(1)->type != AST_CONSTANT)
goto not_const;
for (int i = 0; i < children[0]->bitsAsConst().as_int(); i++)
tmp_bits.insert(tmp_bits.end(), children.at(1)->bits.begin(), children.at(1)->bits.end());
newNode = children.at(1)->is_string ? mkconst_str(tmp_bits) : mkconst_bits(tmp_bits, false);
break;
default:
not_const:
break;
}
}
// if any of the above set 'newNode' -> use 'newNode' as template to update 'this'
if (newNode) {
apply_newNode:
// fprintf(stderr, "----\n");
// dumpAst(stderr, "- ");
// newNode->dumpAst(stderr, "+ ");
log_assert(newNode != NULL);
newNode->filename = filename;
newNode->location = location;
newNode->cloneInto(this);
fixup_hierarchy_flags();
delete newNode;
did_something = true;
}
if (!did_something)
basic_prep = true;
recursion_counter--;
return did_something;
}
void AstNode::replace_result_wire_name_in_function(const std::string &from, const std::string &to)
{
for (AstNode *child : children)
child->replace_result_wire_name_in_function(from, to);
if (str == from && type != AST_FCALL && type != AST_TCALL)
str = to;
}
// replace a readmem[bh] TCALL ast node with a block of memory assignments
AstNode *AstNode::readmem(bool is_readmemh, std::string mem_filename, AstNode *memory, int start_addr, int finish_addr, bool unconditional_init)
{
int mem_width, mem_size, addr_bits;
memory->meminfo(mem_width, mem_size, addr_bits);
AstNode *block = new AstNode(AST_BLOCK);
AstNode *meminit = nullptr;
int next_meminit_cursor=0;
vector<State> meminit_bits;
vector<State> en_bits;
int meminit_size=0;
for (int i = 0; i < mem_width; i++)
en_bits.push_back(State::S1);
std::ifstream f;
f.open(mem_filename.c_str());
if (f.fail()) {
#ifdef _WIN32
char slash = '\\';
#else
char slash = '/';
#endif
std::string path = filename.substr(0, filename.find_last_of(slash)+1);
f.open(path + mem_filename.c_str());
yosys_input_files.insert(path + mem_filename);
} else {
yosys_input_files.insert(mem_filename);
}
if (f.fail() || GetSize(mem_filename) == 0)
input_error("Can not open file `%s` for %s.\n", mem_filename.c_str(), str.c_str());
log_assert(GetSize(memory->children) == 2 && memory->children[1]->type == AST_RANGE && memory->children[1]->range_valid);
int range_left = memory->children[1]->range_left, range_right = memory->children[1]->range_right;
int range_min = min(range_left, range_right), range_max = max(range_left, range_right);
if (start_addr < 0)
start_addr = range_min;
if (finish_addr < 0)
finish_addr = range_max + 1;
bool in_comment = false;
int increment = start_addr <= finish_addr ? +1 : -1;
int cursor = start_addr;
while (!f.eof())
{
std::string line, token;
std::getline(f, line);
for (int i = 0; i < GetSize(line); i++) {
if (in_comment && line.compare(i, 2, "*/") == 0) {
line[i] = ' ';
line[i+1] = ' ';
in_comment = false;
continue;
}
if (!in_comment && line.compare(i, 2, "/*") == 0)
in_comment = true;
if (in_comment)
line[i] = ' ';
}
while (1)
{
token = next_token(line, " \t\r\n");
if (token.empty() || token.compare(0, 2, "//") == 0)
break;
if (token[0] == '@') {
token = token.substr(1);
const char *nptr = token.c_str();
char *endptr;
cursor = strtol(nptr, &endptr, 16);
if (!*nptr || *endptr)
input_error("Can not parse address `%s` for %s.\n", nptr, str.c_str());
continue;
}
AstNode *value = VERILOG_FRONTEND::const2ast(stringf("%d'%c", mem_width, is_readmemh ? 'h' : 'b') + token);
if (unconditional_init)
{
if (meminit == nullptr || cursor != next_meminit_cursor)
{
if (meminit != nullptr) {
meminit->children[1] = AstNode::mkconst_bits(meminit_bits, false);
meminit->children[3] = AstNode::mkconst_int(meminit_size, false);
}
meminit = new AstNode(AST_MEMINIT);
meminit->children.push_back(AstNode::mkconst_int(cursor, false));
meminit->children.push_back(nullptr);
meminit->children.push_back(AstNode::mkconst_bits(en_bits, false));
meminit->children.push_back(nullptr);
meminit->str = memory->str;
meminit->id2ast = memory;
meminit_bits.clear();
meminit_size = 0;
current_ast_mod->children.push_back(meminit);
next_meminit_cursor = cursor;
}
meminit_size++;
next_meminit_cursor++;
meminit_bits.insert(meminit_bits.end(), value->bits.begin(), value->bits.end());
delete value;
}
else
{
block->children.push_back(new AstNode(AST_ASSIGN_EQ, new AstNode(AST_IDENTIFIER, new AstNode(AST_RANGE, AstNode::mkconst_int(cursor, false))), value));
block->children.back()->children[0]->str = memory->str;
block->children.back()->children[0]->id2ast = memory;
block->children.back()->children[0]->was_checked = true;
}
cursor += increment;
if ((cursor == finish_addr+increment) || (increment > 0 && cursor > range_max) || (increment < 0 && cursor < range_min))
break;
}
if ((cursor == finish_addr+increment) || (increment > 0 && cursor > range_max) || (increment < 0 && cursor < range_min))
break;
}
if (meminit != nullptr) {
meminit->children[1] = AstNode::mkconst_bits(meminit_bits, false);
meminit->children[3] = AstNode::mkconst_int(meminit_size, false);
}
return block;
}
// annotate the names of all wires and other named objects in a named generate
// or procedural block; nested blocks are themselves annotated such that the
// prefix is carried forward, but resolution of their children is deferred
void AstNode::expand_genblock(const std::string &prefix)
{
if (type == AST_IDENTIFIER || type == AST_FCALL || type == AST_TCALL || type == AST_WIRETYPE || type == AST_PREFIX) {
log_assert(!str.empty());
// search starting in the innermost scope and then stepping outward
for (size_t ppos = prefix.size() - 1; ppos; --ppos) {
if (prefix.at(ppos) != '.') continue;
std::string new_prefix = prefix.substr(0, ppos + 1);
auto attempt_resolve = [&new_prefix](const std::string &ident) -> std::string {
std::string new_name = prefix_id(new_prefix, ident);
if (current_scope.count(new_name))
return new_name;
return {};
};
// attempt to resolve the full identifier
std::string resolved = attempt_resolve(str);
if (!resolved.empty()) {
str = resolved;
break;
}
// attempt to resolve hierarchical prefixes within the identifier,
// as the prefix could refer to a local scope which exists but
// hasn't yet been elaborated
for (size_t spos = str.size() - 1; spos; --spos) {
if (str.at(spos) != '.') continue;
resolved = attempt_resolve(str.substr(0, spos));
if (!resolved.empty()) {
str = resolved + str.substr(spos);
ppos = 1; // break outer loop
break;
}
}
}
}
auto prefix_node = [&prefix](AstNode* child) {
if (child->str.empty()) return;
std::string new_name = prefix_id(prefix, child->str);
if (child->type == AST_FUNCTION)
child->replace_result_wire_name_in_function(child->str, new_name);
else
child->str = new_name;
current_scope[new_name] = child;
};
for (size_t i = 0; i < children.size(); i++) {
AstNode *child = children[i];
switch (child->type) {
case AST_WIRE:
case AST_MEMORY:
case AST_STRUCT:
case AST_UNION:
case AST_PARAMETER:
case AST_LOCALPARAM:
case AST_FUNCTION:
case AST_TASK:
case AST_CELL:
case AST_TYPEDEF:
case AST_ENUM_ITEM:
case AST_GENVAR:
prefix_node(child);
break;
case AST_BLOCK:
case AST_GENBLOCK:
if (!child->str.empty())
prefix_node(child);
break;
case AST_ENUM:
current_scope[child->str] = child;
for (auto enode : child->children){
log_assert(enode->type == AST_ENUM_ITEM);
prefix_node(enode);
}
break;
default:
break;
}
}
for (size_t i = 0; i < children.size(); i++) {
AstNode *child = children[i];
// AST_PREFIX member names should not be prefixed; we recurse into them
// as normal to ensure indices and ranges are properly resolved, and
// then restore the previous string
if (type == AST_PREFIX && i == 1) {
std::string backup_scope_name = child->str;
child->expand_genblock(prefix);
child->str = backup_scope_name;
continue;
}
// functions/tasks may reference wires, constants, etc. in this scope
if (child->type == AST_FUNCTION || child->type == AST_TASK)
continue;
// named blocks pick up the current prefix and will expanded later
if ((child->type == AST_GENBLOCK || child->type == AST_BLOCK) && !child->str.empty())
continue;
child->expand_genblock(prefix);
}
}
// add implicit AST_GENBLOCK names according to IEEE 1364-2005 Section 12.4.3 or
// IEEE 1800-2017 Section 27.6
void AstNode::label_genblks(std::set<std::string>& existing, int &counter)
{
switch (type) {
case AST_GENIF:
case AST_GENFOR:
case AST_GENCASE:
// seeing a proper generate control flow construct increments the
// counter once
++counter;
for (AstNode *child : children)
child->label_genblks(existing, counter);
break;
case AST_GENBLOCK: {
// if this block is unlabeled, generate its corresponding unique name
for (int padding = 0; str.empty(); ++padding) {
std::string candidate = "\\genblk";
for (int i = 0; i < padding; ++i)
candidate += '0';
candidate += std::to_string(counter);
if (!existing.count(candidate))
str = candidate;
}
// within a genblk, the counter starts fresh
std::set<std::string> existing_local = existing;
int counter_local = 0;
for (AstNode *child : children)
child->label_genblks(existing_local, counter_local);
break;
}
default:
// track names which could conflict with implicit genblk names
if (str.rfind("\\genblk", 0) == 0)
existing.insert(str);
for (AstNode *child : children)
child->label_genblks(existing, counter);
break;
}
}
// helper function for mem2reg_as_needed_pass1
static void mark_memories_assign_lhs_complex(dict<AstNode*, pool<std::string>> &mem2reg_places,
dict<AstNode*, uint32_t> &mem2reg_candidates, AstNode *that)
{
for (auto &child : that->children)
mark_memories_assign_lhs_complex(mem2reg_places, mem2reg_candidates, child);
if (that->type == AST_IDENTIFIER && that->id2ast && that->id2ast->type == AST_MEMORY) {
AstNode *mem = that->id2ast;
if (!(mem2reg_candidates[mem] & AstNode::MEM2REG_FL_CMPLX_LHS))
mem2reg_places[mem].insert(stringf("%s:%d", RTLIL::encode_filename(that->filename).c_str(), that->location.first_line));
mem2reg_candidates[mem] |= AstNode::MEM2REG_FL_CMPLX_LHS;
}
}
// find memories that should be replaced by registers
void AstNode::mem2reg_as_needed_pass1(dict<AstNode*, pool<std::string>> &mem2reg_places,
dict<AstNode*, uint32_t> &mem2reg_candidates, dict<AstNode*, uint32_t> &proc_flags, uint32_t &flags)
{
uint32_t children_flags = 0;
int lhs_children_counter = 0;
if (type == AST_TYPEDEF)
return; // don't touch content of typedefs
if (type == AST_ASSIGN || type == AST_ASSIGN_LE || type == AST_ASSIGN_EQ)
{
// mark all memories that are used in a complex expression on the left side of an assignment
for (auto &lhs_child : children[0]->children)
mark_memories_assign_lhs_complex(mem2reg_places, mem2reg_candidates, lhs_child);
if (children[0]->type == AST_IDENTIFIER && children[0]->id2ast && children[0]->id2ast->type == AST_MEMORY)
{
AstNode *mem = children[0]->id2ast;
// activate mem2reg if this is assigned in an async proc
if (flags & AstNode::MEM2REG_FL_ASYNC) {
if (!(mem2reg_candidates[mem] & AstNode::MEM2REG_FL_SET_ASYNC))
mem2reg_places[mem].insert(stringf("%s:%d", RTLIL::encode_filename(filename).c_str(), location.first_line));
mem2reg_candidates[mem] |= AstNode::MEM2REG_FL_SET_ASYNC;
}
// remember if this is assigned blocking (=)
if (type == AST_ASSIGN_EQ) {
if (!(proc_flags[mem] & AstNode::MEM2REG_FL_EQ1))
mem2reg_places[mem].insert(stringf("%s:%d", RTLIL::encode_filename(filename).c_str(), location.first_line));
proc_flags[mem] |= AstNode::MEM2REG_FL_EQ1;
}
// for proper (non-init) writes: remember if this is a constant index or not
if ((flags & MEM2REG_FL_INIT) == 0) {
if (children[0]->children.size() && children[0]->children[0]->type == AST_RANGE && children[0]->children[0]->children.size()) {
if (children[0]->children[0]->children[0]->type == AST_CONSTANT)
mem2reg_candidates[mem] |= AstNode::MEM2REG_FL_CONST_LHS;
else
mem2reg_candidates[mem] |= AstNode::MEM2REG_FL_VAR_LHS;
}
}
// remember where this is
if (flags & MEM2REG_FL_INIT) {
if (!(mem2reg_candidates[mem] & AstNode::MEM2REG_FL_SET_INIT))
mem2reg_places[mem].insert(stringf("%s:%d", RTLIL::encode_filename(filename).c_str(), location.first_line));
mem2reg_candidates[mem] |= AstNode::MEM2REG_FL_SET_INIT;
} else {
if (!(mem2reg_candidates[mem] & AstNode::MEM2REG_FL_SET_ELSE))
mem2reg_places[mem].insert(stringf("%s:%d", RTLIL::encode_filename(filename).c_str(), location.first_line));
mem2reg_candidates[mem] |= AstNode::MEM2REG_FL_SET_ELSE;
}
}
lhs_children_counter = 1;
}
if (type == AST_IDENTIFIER && id2ast && id2ast->type == AST_MEMORY)
{
AstNode *mem = id2ast;
if (integer < (unsigned)mem->unpacked_dimensions)
input_error("Insufficient number of array indices for %s.\n", log_id(str));
// flag if used after blocking assignment (in same proc)
if ((proc_flags[mem] & AstNode::MEM2REG_FL_EQ1) && !(mem2reg_candidates[mem] & AstNode::MEM2REG_FL_EQ2)) {
mem2reg_places[mem].insert(stringf("%s:%d", RTLIL::encode_filename(filename).c_str(), location.first_line));
mem2reg_candidates[mem] |= AstNode::MEM2REG_FL_EQ2;
}
}
// also activate if requested, either by using mem2reg attribute or by declaring array as 'wire' instead of 'reg' or 'logic'
if (type == AST_MEMORY && (get_bool_attribute(ID::mem2reg) || (flags & AstNode::MEM2REG_FL_ALL) || !(is_reg || is_logic)))
mem2reg_candidates[this] |= AstNode::MEM2REG_FL_FORCED;
if ((type == AST_MODULE || type == AST_INTERFACE) && get_bool_attribute(ID::mem2reg))
children_flags |= AstNode::MEM2REG_FL_ALL;
dict<AstNode*, uint32_t> *proc_flags_p = NULL;
if (type == AST_ALWAYS) {
int count_edge_events = 0;
for (auto child : children)
if (child->type == AST_POSEDGE || child->type == AST_NEGEDGE)
count_edge_events++;
if (count_edge_events != 1)
children_flags |= AstNode::MEM2REG_FL_ASYNC;
proc_flags_p = new dict<AstNode*, uint32_t>;
}
else if (type == AST_INITIAL) {
children_flags |= AstNode::MEM2REG_FL_INIT;
proc_flags_p = new dict<AstNode*, uint32_t>;
}
uint32_t backup_flags = flags;
flags |= children_flags;
log_assert((flags & ~0x000000ff) == 0);
for (auto child : children)
{
if (lhs_children_counter > 0) {
lhs_children_counter--;
if (child->children.size() && child->children[0]->type == AST_RANGE && child->children[0]->children.size()) {
for (auto c : child->children[0]->children) {
if (proc_flags_p)
c->mem2reg_as_needed_pass1(mem2reg_places, mem2reg_candidates, *proc_flags_p, flags);
else
c->mem2reg_as_needed_pass1(mem2reg_places, mem2reg_candidates, proc_flags, flags);
}
}
} else
if (proc_flags_p)
child->mem2reg_as_needed_pass1(mem2reg_places, mem2reg_candidates, *proc_flags_p, flags);
else
child->mem2reg_as_needed_pass1(mem2reg_places, mem2reg_candidates, proc_flags, flags);
}
flags &= ~children_flags | backup_flags;
if (proc_flags_p) {
#ifndef NDEBUG
for (auto it : *proc_flags_p)
log_assert((it.second & ~0xff000000) == 0);
#endif
delete proc_flags_p;
}
}
bool AstNode::mem2reg_check(pool<AstNode*> &mem2reg_set)
{
if (type != AST_IDENTIFIER || !id2ast || !mem2reg_set.count(id2ast))
return false;
if (children.empty() || children[0]->type != AST_RANGE || GetSize(children[0]->children) != 1)
input_error("Invalid array access.\n");
return true;
}
void AstNode::mem2reg_remove(pool<AstNode*> &mem2reg_set, vector<AstNode*> &delnodes)
{
log_assert(mem2reg_set.count(this) == 0);
if (mem2reg_set.count(id2ast))
id2ast = nullptr;
for (size_t i = 0; i < children.size(); i++) {
if (mem2reg_set.count(children[i]) > 0) {
delnodes.push_back(children[i]);
children.erase(children.begin() + (i--));
} else {
children[i]->mem2reg_remove(mem2reg_set, delnodes);
}
}
}
// actually replace memories with registers
bool AstNode::mem2reg_as_needed_pass2(pool<AstNode*> &mem2reg_set, AstNode *mod, AstNode *block, AstNode *&async_block)
{
bool did_something = false;
if (type == AST_BLOCK)
block = this;
if (type == AST_FUNCTION || type == AST_TASK)
return false;
if (type == AST_TYPEDEF)
return false;
if (type == AST_MEMINIT && id2ast && mem2reg_set.count(id2ast))
{
log_assert(children[0]->type == AST_CONSTANT);
log_assert(children[1]->type == AST_CONSTANT);
log_assert(children[2]->type == AST_CONSTANT);
log_assert(children[3]->type == AST_CONSTANT);
int cursor = children[0]->asInt(false);
Const data = children[1]->bitsAsConst();
Const en = children[2]->bitsAsConst();
int length = children[3]->asInt(false);
if (length != 0)
{
AstNode *block = new AstNode(AST_INITIAL, new AstNode(AST_BLOCK));
mod->children.push_back(block);
block = block->children[0];
int wordsz = GetSize(data) / length;
for (int i = 0; i < length; i++) {
int pos = 0;
while (pos < wordsz) {
if (en[pos] != State::S1) {
pos++;
} else {
int epos = pos + 1;
while (epos < wordsz && en[epos] == State::S1)
epos++;
int clen = epos - pos;
AstNode *range = new AstNode(AST_RANGE, AstNode::mkconst_int(cursor+i, false));
if (pos != 0 || epos != wordsz) {
int left;
int right;
AstNode *mrange = id2ast->children[0];
if (mrange->range_left < mrange->range_right) {
right = mrange->range_right - pos;
left = mrange->range_right - epos + 1;
} else {
right = mrange->range_right + pos;
left = mrange->range_right + epos - 1;
}
range = new AstNode(AST_MULTIRANGE, range, new AstNode(AST_RANGE, AstNode::mkconst_int(left, true), AstNode::mkconst_int(right, true)));
}
AstNode *target = new AstNode(AST_IDENTIFIER, range);
target->str = str;
target->id2ast = id2ast;
target->was_checked = true;
block->children.push_back(new AstNode(AST_ASSIGN_EQ, target, mkconst_bits(data.extract(i*wordsz + pos, clen).to_bits(), false)));
pos = epos;
}
}
}
}
AstNode *newNode = new AstNode(AST_NONE);
newNode->cloneInto(this);
delete newNode;
did_something = true;
}
if (type == AST_ASSIGN && block == NULL && children[0]->mem2reg_check(mem2reg_set))
{
if (async_block == NULL) {
async_block = new AstNode(AST_ALWAYS, new AstNode(AST_BLOCK));
mod->children.push_back(async_block);
}
AstNode *newNode = clone();
newNode->type = AST_ASSIGN_EQ;
newNode->children[0]->was_checked = true;
async_block->children[0]->children.push_back(newNode);
newNode = new AstNode(AST_NONE);
newNode->cloneInto(this);
delete newNode;
did_something = true;
}
if ((type == AST_ASSIGN_LE || type == AST_ASSIGN_EQ) && children[0]->mem2reg_check(mem2reg_set) &&
children[0]->children[0]->children[0]->type != AST_CONSTANT)
{
std::stringstream sstr;
sstr << "$mem2reg_wr$" << children[0]->str << "$" << RTLIL::encode_filename(filename) << ":" << location.first_line << "$" << (autoidx++);
std::string id_addr = sstr.str() + "_ADDR", id_data = sstr.str() + "_DATA";
int mem_width, mem_size, addr_bits;
bool mem_signed = children[0]->id2ast->is_signed;
children[0]->id2ast->meminfo(mem_width, mem_size, addr_bits);
AstNode *wire_addr = new AstNode(AST_WIRE, new AstNode(AST_RANGE, mkconst_int(addr_bits-1, true), mkconst_int(0, true)));
wire_addr->str = id_addr;
wire_addr->is_reg = true;
wire_addr->was_checked = true;
wire_addr->set_attribute(ID::nosync, AstNode::mkconst_int(1, false));
mod->children.push_back(wire_addr);
while (wire_addr->simplify(true, 1, -1, false)) { }
AstNode *wire_data = new AstNode(AST_WIRE, new AstNode(AST_RANGE, mkconst_int(mem_width-1, true), mkconst_int(0, true)));
wire_data->str = id_data;
wire_data->is_reg = true;
wire_data->was_checked = true;
wire_data->is_signed = mem_signed;
wire_data->set_attribute(ID::nosync, AstNode::mkconst_int(1, false));
mod->children.push_back(wire_data);
while (wire_data->simplify(true, 1, -1, false)) { }
log_assert(block != NULL);
size_t assign_idx = 0;
while (assign_idx < block->children.size() && block->children[assign_idx] != this)
assign_idx++;
log_assert(assign_idx < block->children.size());
AstNode *assign_addr = new AstNode(AST_ASSIGN_EQ, new AstNode(AST_IDENTIFIER), children[0]->children[0]->children[0]->clone());
assign_addr->children[0]->str = id_addr;
assign_addr->children[0]->was_checked = true;
block->children.insert(block->children.begin()+assign_idx+1, assign_addr);
AstNode *case_node = new AstNode(AST_CASE, new AstNode(AST_IDENTIFIER));
case_node->children[0]->str = id_addr;
for (int i = 0; i < mem_size; i++) {
if (children[0]->children[0]->children[0]->type == AST_CONSTANT && int(children[0]->children[0]->children[0]->integer) != i)
continue;
AstNode *cond_node = new AstNode(AST_COND, AstNode::mkconst_int(i, false, addr_bits), new AstNode(AST_BLOCK));
AstNode *assign_reg = new AstNode(type, new AstNode(AST_IDENTIFIER), new AstNode(AST_IDENTIFIER));
if (children[0]->children.size() == 2)
assign_reg->children[0]->children.push_back(children[0]->children[1]->clone());
assign_reg->children[0]->str = stringf("%s[%d]", children[0]->str.c_str(), i);
assign_reg->children[1]->str = id_data;
cond_node->children[1]->children.push_back(assign_reg);
case_node->children.push_back(cond_node);
}
// fixup on the full hierarchy below case_node
case_node->fixup_hierarchy_flags(true);
block->children.insert(block->children.begin()+assign_idx+2, case_node);
children[0]->delete_children();
children[0]->range_valid = false;
children[0]->id2ast = NULL;
children[0]->str = id_data;
type = AST_ASSIGN_EQ;
children[0]->was_checked = true;
fixup_hierarchy_flags();
did_something = true;
}
if (mem2reg_check(mem2reg_set))
{
AstNode *bit_part_sel = NULL;
if (children.size() == 2)
bit_part_sel = children[1]->clone();
if (children[0]->children[0]->type == AST_CONSTANT)
{
int id = children[0]->children[0]->integer;
int left = id2ast->children[1]->children[0]->integer;
int right = id2ast->children[1]->children[1]->integer;
bool valid_const_access =
(left <= id && id <= right) ||
(right <= id && id <= left);
if (valid_const_access)
{
str = stringf("%s[%d]", str.c_str(), id);
delete_children();
range_valid = false;
id2ast = NULL;
}
else
{
int width;
if (bit_part_sel)
{
// bit_part_sel->dumpAst(nullptr, "? ");
if (bit_part_sel->children.size() == 1)
width = 0;
else
width = bit_part_sel->children[0]->integer -
bit_part_sel->children[1]->integer;
delete bit_part_sel;
bit_part_sel = nullptr;
}
else
{
width = id2ast->children[0]->children[0]->integer -
id2ast->children[0]->children[1]->integer;
}
width = abs(width) + 1;
delete_children();
std::vector<RTLIL::State> x_bits;
for (int i = 0; i < width; i++)
x_bits.push_back(RTLIL::State::Sx);
AstNode *constant = AstNode::mkconst_bits(x_bits, false);
constant->cloneInto(this);
delete constant;
}
}
else
{
std::stringstream sstr;
sstr << "$mem2reg_rd$" << str << "$" << RTLIL::encode_filename(filename) << ":" << location.first_line << "$" << (autoidx++);
std::string id_addr = sstr.str() + "_ADDR", id_data = sstr.str() + "_DATA";
int mem_width, mem_size, addr_bits;
bool mem_signed = id2ast->is_signed;
id2ast->meminfo(mem_width, mem_size, addr_bits);
AstNode *wire_addr = new AstNode(AST_WIRE, new AstNode(AST_RANGE, mkconst_int(addr_bits-1, true), mkconst_int(0, true)));
wire_addr->str = id_addr;
wire_addr->is_reg = true;
wire_addr->was_checked = true;
if (block)
wire_addr->set_attribute(ID::nosync, AstNode::mkconst_int(1, false));
mod->children.push_back(wire_addr);
while (wire_addr->simplify(true, 1, -1, false)) { }
AstNode *wire_data = new AstNode(AST_WIRE, new AstNode(AST_RANGE, mkconst_int(mem_width-1, true), mkconst_int(0, true)));
wire_data->str = id_data;
wire_data->is_reg = true;
wire_data->was_checked = true;
wire_data->is_signed = mem_signed;
if (block)
wire_data->set_attribute(ID::nosync, AstNode::mkconst_int(1, false));
mod->children.push_back(wire_data);
while (wire_data->simplify(true, 1, -1, false)) { }
AstNode *assign_addr = new AstNode(block ? AST_ASSIGN_EQ : AST_ASSIGN, new AstNode(AST_IDENTIFIER), children[0]->children[0]->clone());
assign_addr->children[0]->str = id_addr;
assign_addr->children[0]->was_checked = true;
AstNode *case_node = new AstNode(AST_CASE, new AstNode(AST_IDENTIFIER));
case_node->children[0]->str = id_addr;
for (int i = 0; i < mem_size; i++) {
if (children[0]->children[0]->type == AST_CONSTANT && int(children[0]->children[0]->integer) != i)
continue;
AstNode *cond_node = new AstNode(AST_COND, AstNode::mkconst_int(i, false, addr_bits), new AstNode(AST_BLOCK));
AstNode *assign_reg = new AstNode(AST_ASSIGN_EQ, new AstNode(AST_IDENTIFIER), new AstNode(AST_IDENTIFIER));
assign_reg->children[0]->str = id_data;
assign_reg->children[0]->was_checked = true;
assign_reg->children[1]->str = stringf("%s[%d]", str.c_str(), i);
cond_node->children[1]->children.push_back(assign_reg);
case_node->children.push_back(cond_node);
}
std::vector<RTLIL::State> x_bits;
for (int i = 0; i < mem_width; i++)
x_bits.push_back(RTLIL::State::Sx);
AstNode *cond_node = new AstNode(AST_COND, new AstNode(AST_DEFAULT), new AstNode(AST_BLOCK));
AstNode *assign_reg = new AstNode(AST_ASSIGN_EQ, new AstNode(AST_IDENTIFIER), AstNode::mkconst_bits(x_bits, false));
assign_reg->children[0]->str = id_data;
assign_reg->children[0]->was_checked = true;
cond_node->children[1]->children.push_back(assign_reg);
case_node->children.push_back(cond_node);
// fixup on the full hierarchy below case_node
case_node->fixup_hierarchy_flags(true);
if (block)
{
size_t assign_idx = 0;
while (assign_idx < block->children.size() && !block->children[assign_idx]->contains(this))
assign_idx++;
log_assert(assign_idx < block->children.size());
block->children.insert(block->children.begin()+assign_idx, case_node);
block->children.insert(block->children.begin()+assign_idx, assign_addr);
}
else
{
AstNode *proc = new AstNode(AST_ALWAYS, new AstNode(AST_BLOCK, case_node));
mod->children.push_back(proc);
mod->children.push_back(assign_addr);
mod->fixup_hierarchy_flags();
}
delete_children();
range_valid = false;
id2ast = NULL;
str = id_data;
}
if (bit_part_sel) {
children.push_back(bit_part_sel);
fixup_hierarchy_flags();
}
did_something = true;
}
log_assert(id2ast == NULL || mem2reg_set.count(id2ast) == 0);
auto children_list = children;
for (size_t i = 0; i < children_list.size(); i++)
if (children_list[i]->mem2reg_as_needed_pass2(mem2reg_set, mod, block, async_block))
did_something = true;
return did_something;
}
// calculate memory dimensions
void AstNode::meminfo(int &mem_width, int &mem_size, int &addr_bits)
{
log_assert(type == AST_MEMORY);
mem_width = children[0]->range_left - children[0]->range_right + 1;
mem_size = children[1]->range_left - children[1]->range_right;
if (mem_size < 0)
mem_size *= -1;
mem_size += min(children[1]->range_left, children[1]->range_right) + 1;
addr_bits = 1;
while ((1 << addr_bits) < mem_size)
addr_bits++;
}
bool AstNode::detect_latch(const std::string &var)
{
switch (type)
{
case AST_ALWAYS:
for (auto &c : children)
{
switch (c->type)
{
case AST_POSEDGE:
case AST_NEGEDGE:
return false;
case AST_EDGE:
break;
case AST_BLOCK:
if (!c->detect_latch(var))
return false;
break;
default:
log_abort();
}
}
return true;
case AST_BLOCK:
for (auto &c : children)
if (!c->detect_latch(var))
return false;
return true;
case AST_CASE:
{
bool r = true;
for (auto &c : children) {
if (c->type == AST_COND) {
if (c->children.at(1)->detect_latch(var))
return true;
r = false;
}
if (c->type == AST_DEFAULT) {
if (c->children.at(0)->detect_latch(var))
return true;
r = false;
}
}
return r;
}
case AST_ASSIGN_EQ:
case AST_ASSIGN_LE:
if (children.at(0)->type == AST_IDENTIFIER &&
children.at(0)->children.empty() && children.at(0)->str == var)
return false;
return true;
default:
return true;
}
}
bool AstNode::has_const_only_constructs()
{
if (type == AST_WHILE || type == AST_REPEAT)
return true;
for (auto child : children)
if (child->has_const_only_constructs())
return true;
return false;
}
bool AstNode::is_simple_const_expr()
{
if (type == AST_IDENTIFIER)
return false;
for (auto child : children)
if (!child->is_simple_const_expr())
return false;
return true;
}
// helper function for AstNode::eval_const_function()
bool AstNode::replace_variables(std::map<std::string, AstNode::varinfo_t> &variables, AstNode *fcall, bool must_succeed)
{
if (type == AST_IDENTIFIER && variables.count(str)) {
int offset = variables.at(str).offset, width = variables.at(str).val.size();
if (!children.empty()) {
if (children.size() != 1 || children.at(0)->type != AST_RANGE) {
if (!must_succeed)
return false;
input_error("Memory access in constant function is not supported\n%s: ...called from here.\n",
fcall->loc_string().c_str());
}
if (!children.at(0)->replace_variables(variables, fcall, must_succeed))
return false;
while (simplify(true, 1, -1, false)) { }
if (!children.at(0)->range_valid) {
if (!must_succeed)
return false;
input_error("Non-constant range\n%s: ... called from here.\n",
fcall->loc_string().c_str());
}
offset = min(children.at(0)->range_left, children.at(0)->range_right);
width = min(std::abs(children.at(0)->range_left - children.at(0)->range_right) + 1, width);
}
offset -= variables.at(str).offset;
if (variables.at(str).range_swapped)
offset = -offset;
std::vector<RTLIL::State> &var_bits = variables.at(str).val.bits();
std::vector<RTLIL::State> new_bits(var_bits.begin() + offset, var_bits.begin() + offset + width);
AstNode *newNode = mkconst_bits(new_bits, variables.at(str).is_signed);
newNode->cloneInto(this);
delete newNode;
return true;
}
for (auto &child : children)
if (!child->replace_variables(variables, fcall, must_succeed))
return false;
return true;
}
// attempt to statically evaluate a functions with all-const arguments
AstNode *AstNode::eval_const_function(AstNode *fcall, bool must_succeed)
{
std::map<std::string, AstNode*> backup_scope = current_scope;
std::map<std::string, AstNode::varinfo_t> variables;
std::vector<AstNode*> to_delete;
AstNode *block = new AstNode(AST_BLOCK);
AstNode *result = nullptr;
size_t argidx = 0;
for (auto child : children)
{
block->children.push_back(child->clone());
}
block->set_in_param_flag(true);
while (!block->children.empty())
{
AstNode *stmt = block->children.front();
#if 0
log("-----------------------------------\n");
for (auto &it : variables)
log("%20s %40s\n", it.first.c_str(), log_signal(it.second.val));
stmt->dumpAst(NULL, "stmt> ");
#endif
if (stmt->type == AST_WIRE)
{
while (stmt->simplify(true, 1, -1, false)) { }
if (!stmt->range_valid) {
if (!must_succeed)
goto finished;
stmt->input_error("Can't determine size of variable %s\n%s: ... called from here.\n",
stmt->str.c_str(), fcall->loc_string().c_str());
}
AstNode::varinfo_t &variable = variables[stmt->str];
int width = abs(stmt->range_left - stmt->range_right) + 1;
// if this variable has already been declared as an input, check the
// sizes match if it already had an explicit size
if (variable.arg && variable.explicitly_sized && variable.val.size() != width) {
input_error("Incompatible re-declaration of constant function wire %s.\n", stmt->str.c_str());
}
variable.val = RTLIL::Const(RTLIL::State::Sx, width);
variable.offset = stmt->range_swapped ? stmt->range_left : stmt->range_right;
variable.range_swapped = stmt->range_swapped;
variable.is_signed = stmt->is_signed;
variable.explicitly_sized = stmt->children.size() &&
stmt->children.back()->type == AST_RANGE;
// identify the argument corresponding to this wire, if applicable
if (stmt->is_input && argidx < fcall->children.size()) {
variable.arg = fcall->children.at(argidx++);
}
// load the constant arg's value into this variable
if (variable.arg) {
if (variable.arg->type == AST_CONSTANT) {
variable.val = variable.arg->bitsAsConst(width);
} else {
log_assert(variable.arg->type == AST_REALVALUE);
variable.val = variable.arg->realAsConst(width);
}
}
current_scope[stmt->str] = stmt;
block->children.erase(block->children.begin());
to_delete.push_back(stmt);
continue;
}
log_assert(variables.count(str) != 0);
if (stmt->type == AST_LOCALPARAM)
{
while (stmt->simplify(true, 1, -1, false)) { }
current_scope[stmt->str] = stmt;
block->children.erase(block->children.begin());
to_delete.push_back(stmt);
continue;
}
if (stmt->type == AST_ASSIGN_EQ)
{
if (stmt->children.at(0)->type == AST_IDENTIFIER && stmt->children.at(0)->children.size() != 0 &&
stmt->children.at(0)->children.at(0)->type == AST_RANGE)
if (!stmt->children.at(0)->children.at(0)->replace_variables(variables, fcall, must_succeed))
goto finished;
if (!stmt->children.at(1)->replace_variables(variables, fcall, must_succeed))
goto finished;
while (stmt->simplify(true, 1, -1, false)) { }
if (stmt->type != AST_ASSIGN_EQ)
continue;
if (stmt->children.at(1)->type != AST_CONSTANT) {
if (!must_succeed)
goto finished;
stmt->input_error("Non-constant expression in constant function\n%s: ... called from here. X\n",
fcall->loc_string().c_str());
}
if (stmt->children.at(0)->type != AST_IDENTIFIER) {
if (!must_succeed)
goto finished;
stmt->input_error("Unsupported composite left hand side in constant function\n%s: ... called from here.\n",
fcall->loc_string().c_str());
}
if (!variables.count(stmt->children.at(0)->str)) {
if (!must_succeed)
goto finished;
stmt->input_error("Assignment to non-local variable in constant function\n%s: ... called from here.\n",
fcall->loc_string().c_str());
}
if (stmt->children.at(0)->children.empty()) {
variables[stmt->children.at(0)->str].val = stmt->children.at(1)->bitsAsConst(variables[stmt->children.at(0)->str].val.size());
} else {
AstNode *range = stmt->children.at(0)->children.at(0);
if (!range->range_valid) {
if (!must_succeed)
goto finished;
range->input_error("Non-constant range\n%s: ... called from here.\n", fcall->loc_string().c_str());
}
int offset = min(range->range_left, range->range_right);
int width = std::abs(range->range_left - range->range_right) + 1;
varinfo_t &v = variables[stmt->children.at(0)->str];
RTLIL::Const r = stmt->children.at(1)->bitsAsConst(v.val.size());
for (int i = 0; i < width; i++) {
int index = i + offset - v.offset;
if (v.range_swapped)
index = -index;
v.val.bits().at(index) = r.at(i);
}
}
delete block->children.front();
block->children.erase(block->children.begin());
continue;
}
if (stmt->type == AST_FOR)
{
block->children.insert(block->children.begin(), stmt->children.at(0));
stmt->children.at(3)->children.push_back(stmt->children.at(2));
stmt->children.erase(stmt->children.begin() + 2);
stmt->children.erase(stmt->children.begin());
stmt->type = AST_WHILE;
continue;
}
if (stmt->type == AST_WHILE)
{
AstNode *cond = stmt->children.at(0)->clone();
if (!cond->replace_variables(variables, fcall, must_succeed))
goto finished;
cond->set_in_param_flag(true);
while (cond->simplify(true, 1, -1, false)) { }
if (cond->type != AST_CONSTANT) {
if (!must_succeed)
goto finished;
stmt->input_error("Non-constant expression in constant function\n%s: ... called from here.\n",
fcall->loc_string().c_str());
}
if (cond->asBool()) {
block->children.insert(block->children.begin(), stmt->children.at(1)->clone());
} else {
delete block->children.front();
block->children.erase(block->children.begin());
}
delete cond;
continue;
}
if (stmt->type == AST_REPEAT)
{
AstNode *num = stmt->children.at(0)->clone();
if (!num->replace_variables(variables, fcall, must_succeed))
goto finished;
num->set_in_param_flag(true);
while (num->simplify(true, 1, -1, false)) { }
if (num->type != AST_CONSTANT) {
if (!must_succeed)
goto finished;
stmt->input_error("Non-constant expression in constant function\n%s: ... called from here.\n",
fcall->loc_string().c_str());
}
block->children.erase(block->children.begin());
for (int i = 0; i < num->bitsAsConst().as_int(); i++)
block->children.insert(block->children.begin(), stmt->children.at(1)->clone());
delete stmt;
delete num;
continue;
}
if (stmt->type == AST_CASE)
{
AstNode *expr = stmt->children.at(0)->clone();
if (!expr->replace_variables(variables, fcall, must_succeed))
goto finished;
expr->set_in_param_flag(true);
while (expr->simplify(true, 1, -1, false)) { }
AstNode *sel_case = NULL;
for (size_t i = 1; i < stmt->children.size(); i++)
{
bool found_match = false;
log_assert(stmt->children.at(i)->type == AST_COND || stmt->children.at(i)->type == AST_CONDX || stmt->children.at(i)->type == AST_CONDZ);
if (stmt->children.at(i)->children.front()->type == AST_DEFAULT) {
sel_case = stmt->children.at(i)->children.back();
continue;
}
for (size_t j = 0; j+1 < stmt->children.at(i)->children.size() && !found_match; j++)
{
AstNode *cond = stmt->children.at(i)->children.at(j)->clone();
if (!cond->replace_variables(variables, fcall, must_succeed))
goto finished;
cond = new AstNode(AST_EQ, expr->clone(), cond);
cond->set_in_param_flag(true);
while (cond->simplify(true, 1, -1, false)) { }
if (cond->type != AST_CONSTANT) {
if (!must_succeed)
goto finished;
stmt->input_error("Non-constant expression in constant function\n%s: ... called from here.\n",
fcall->loc_string().c_str());
}
found_match = cond->asBool();
delete cond;
}
if (found_match) {
sel_case = stmt->children.at(i)->children.back();
break;
}
}
block->children.erase(block->children.begin());
if (sel_case)
block->children.insert(block->children.begin(), sel_case->clone());
delete stmt;
delete expr;
continue;
}
if (stmt->type == AST_BLOCK)
{
if (!stmt->str.empty())
stmt->expand_genblock(stmt->str + ".");
block->children.erase(block->children.begin());
block->children.insert(block->children.begin(), stmt->children.begin(), stmt->children.end());
stmt->children.clear();
block->fixup_hierarchy_flags();
delete stmt;
continue;
}
if (!must_succeed)
goto finished;
stmt->input_error("Unsupported language construct in constant function\n%s: ... called from here.\n",
fcall->loc_string().c_str());
log_abort();
}
result = AstNode::mkconst_bits(variables.at(str).val.to_bits(), variables.at(str).is_signed);
finished:
delete block;
current_scope = backup_scope;
for (auto it : to_delete) {
delete it;
}
to_delete.clear();
return result;
}
void AstNode::allocateDefaultEnumValues()
{
log_assert(type==AST_ENUM);
log_assert(children.size() > 0);
if (children.front()->attributes.count(ID::enum_base_type))
return; // already elaborated
int last_enum_int = -1;
for (auto node : children) {
log_assert(node->type==AST_ENUM_ITEM);
node->set_attribute(ID::enum_base_type, mkconst_str(str));
for (size_t i = 0; i < node->children.size(); i++) {
switch (node->children[i]->type) {
case AST_NONE:
// replace with auto-incremented constant
delete node->children[i];
node->children[i] = AstNode::mkconst_int(++last_enum_int, true);
break;
case AST_CONSTANT:
// explicit constant (or folded expression)
// TODO: can't extend 'x or 'z item
last_enum_int = node->children[i]->integer;
break;
default:
// ignore ranges
break;
}
// TODO: range check
}
}
}
bool AstNode::is_recursive_function() const
{
std::set<const AstNode *> visited;
std::function<bool(const AstNode *node)> visit = [&](const AstNode *node) {
if (visited.count(node))
return node == this;
visited.insert(node);
if (node->type == AST_FCALL) {
auto it = current_scope.find(node->str);
if (it != current_scope.end() && visit(it->second))
return true;
}
for (const AstNode *child : node->children) {
if (visit(child))
return true;
}
return false;
};
log_assert(type == AST_FUNCTION);
return visit(this);
}
std::pair<AstNode*, AstNode*> AstNode::get_tern_choice()
{
if (!children[0]->isConst())
return {};
bool found_sure_true = false;
bool found_maybe_true = false;
if (children[0]->type == AST_CONSTANT)
for (auto &bit : children[0]->bits) {
if (bit == RTLIL::State::S1)
found_sure_true = true;
if (bit > RTLIL::State::S1)
found_maybe_true = true;
}
else
found_sure_true = children[0]->asReal(true) != 0;
AstNode *choice = nullptr, *not_choice = nullptr;
if (found_sure_true)
choice = children[1], not_choice = children[2];
else if (!found_maybe_true)
choice = children[2], not_choice = children[1];
return {choice, not_choice};
}
std::string AstNode::try_pop_module_prefix() const
{
AstNode *current_scope_ast = (current_ast_mod == nullptr) ? current_ast : current_ast_mod;
size_t pos = str.find('.', 1);
if (str[0] == '\\' && pos != std::string::npos) {
std::string new_str = "\\" + str.substr(pos + 1);
if (current_scope.count(new_str)) {
std::string prefix = str.substr(0, pos);
auto it = current_scope_ast->attributes.find(ID::hdlname);
if ((it != current_scope_ast->attributes.end() && it->second->str == prefix.substr(1))
|| prefix == current_scope_ast->str)
return new_str;
}
}
return str;
}
YOSYS_NAMESPACE_END
Reference in New Issue View Git Blame Copy Permalink