yosys/backends/cxxrtl/cxxrtl_backend.cc

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/*
* yosys -- Yosys Open SYnthesis Suite
*
* Copyright (C) 2019-2020 whitequark <whitequark@whitequark.org>
*
* 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.
*
*/
#include "kernel/rtlil.h"
#include "kernel/register.h"
#include "kernel/sigtools.h"
#include "kernel/utils.h"
#include "kernel/celltypes.h"
#include "kernel/mem.h"
#include "kernel/log.h"
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#include "kernel/fmt.h"
USING_YOSYS_NAMESPACE
PRIVATE_NAMESPACE_BEGIN
// [[CITE]]
// Peter Eades; Xuemin Lin; W. F. Smyth, "A Fast Effective Heuristic For The Feedback Arc Set Problem"
// Information Processing Letters, Vol. 47, pp 319-323, 1993
// https://pdfs.semanticscholar.org/c7ed/d9acce96ca357876540e19664eb9d976637f.pdf
// A topological sort (on a cell/wire graph) is always possible in a fully flattened RTLIL design without
// processes or logic loops where every wire has a single driver. Logic loops are illegal in RTLIL and wires
// with multiple drivers can be split by the `splitnets` pass; however, interdependencies between processes
// or module instances can create strongly connected components without introducing evaluation nondeterminism.
// We wish to support designs with such benign SCCs (as well as designs with multiple drivers per wire), so
// we sort the graph in a way that minimizes feedback arcs. If there are no feedback arcs in the sorted graph,
// then a more efficient evaluation method is possible, since eval() will always immediately converge.
template<class T>
struct Scheduler {
struct Vertex {
T *data;
Vertex *prev, *next;
pool<Vertex*, hash_ptr_ops> preds, succs;
Vertex() : data(NULL), prev(this), next(this) {}
Vertex(T *data) : data(data), prev(NULL), next(NULL) {}
bool empty() const
{
log_assert(data == NULL);
if (next == this) {
log_assert(prev == next);
return true;
}
return false;
}
void link(Vertex *list)
{
log_assert(prev == NULL && next == NULL);
next = list;
prev = list->prev;
list->prev->next = this;
list->prev = this;
}
void unlink()
{
log_assert(prev->next == this && next->prev == this);
prev->next = next;
next->prev = prev;
next = prev = NULL;
}
int delta() const
{
return succs.size() - preds.size();
}
};
std::vector<Vertex*> vertices;
Vertex *sources = new Vertex;
Vertex *sinks = new Vertex;
dict<int, Vertex*> bins;
~Scheduler()
{
delete sources;
delete sinks;
for (auto bin : bins)
delete bin.second;
for (auto vertex : vertices)
delete vertex;
}
Vertex *add(T *data)
{
Vertex *vertex = new Vertex(data);
vertices.push_back(vertex);
return vertex;
}
void relink(Vertex *vertex)
{
if (vertex->succs.empty())
vertex->link(sinks);
else if (vertex->preds.empty())
vertex->link(sources);
else {
int delta = vertex->delta();
if (!bins.count(delta))
bins[delta] = new Vertex;
vertex->link(bins[delta]);
}
}
Vertex *remove(Vertex *vertex)
{
vertex->unlink();
for (auto pred : vertex->preds) {
if (pred == vertex)
continue;
log_assert(pred->succs[vertex]);
pred->unlink();
pred->succs.erase(vertex);
relink(pred);
}
for (auto succ : vertex->succs) {
if (succ == vertex)
continue;
log_assert(succ->preds[vertex]);
succ->unlink();
succ->preds.erase(vertex);
relink(succ);
}
vertex->preds.clear();
vertex->succs.clear();
return vertex;
}
std::vector<Vertex*> schedule()
{
std::vector<Vertex*> s1, s2r;
for (auto vertex : vertices)
relink(vertex);
bool bins_empty = false;
while (!(sinks->empty() && sources->empty() && bins_empty)) {
while (!sinks->empty())
s2r.push_back(remove(sinks->next));
while (!sources->empty())
s1.push_back(remove(sources->next));
// Choosing u in this implementation isn't O(1), but the paper handwaves which data structure they suggest
// using to get O(1) relinking *and* find-max-key ("it is clear"... no it isn't), so this code uses a very
// naive implementation of find-max-key.
bins_empty = true;
bins.template sort<std::greater<int>>();
for (auto bin : bins) {
if (!bin.second->empty()) {
bins_empty = false;
s1.push_back(remove(bin.second->next));
break;
}
}
}
s1.insert(s1.end(), s2r.rbegin(), s2r.rend());
return s1;
}
};
bool is_unary_cell(RTLIL::IdString type)
{
return type.in(
ID($not), ID($logic_not), ID($reduce_and), ID($reduce_or), ID($reduce_xor), ID($reduce_xnor), ID($reduce_bool),
ID($pos), ID($neg));
}
bool is_binary_cell(RTLIL::IdString type)
{
return type.in(
ID($and), ID($or), ID($xor), ID($xnor), ID($logic_and), ID($logic_or),
ID($shl), ID($sshl), ID($shr), ID($sshr), ID($shift), ID($shiftx),
ID($eq), ID($ne), ID($eqx), ID($nex), ID($gt), ID($ge), ID($lt), ID($le),
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ID($add), ID($sub), ID($mul), ID($div), ID($mod), ID($modfloor), ID($divfloor));
}
bool is_extending_cell(RTLIL::IdString type)
{
return !type.in(
ID($logic_not), ID($logic_and), ID($logic_or),
ID($reduce_and), ID($reduce_or), ID($reduce_xor), ID($reduce_xnor), ID($reduce_bool));
}
bool is_inlinable_cell(RTLIL::IdString type)
{
return is_unary_cell(type) || is_binary_cell(type) || type.in(
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ID($mux), ID($concat), ID($slice), ID($pmux), ID($bmux), ID($demux));
}
bool is_ff_cell(RTLIL::IdString type)
{
return type.in(
ID($dff), ID($dffe), ID($sdff), ID($sdffe), ID($sdffce),
ID($adff), ID($adffe), ID($dffsr), ID($dffsre),
ID($aldff), ID($aldffe),
ID($dlatch), ID($adlatch), ID($dlatchsr), ID($sr));
}
bool is_internal_cell(RTLIL::IdString type)
{
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return !type.isPublic() && !type.begins_with("$paramod");
}
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
bool is_effectful_cell(RTLIL::IdString type)
{
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return type.isPublic() || type == ID($print);
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
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}
bool is_cxxrtl_blackbox_cell(const RTLIL::Cell *cell)
{
RTLIL::Module *cell_module = cell->module->design->module(cell->type);
log_assert(cell_module != nullptr);
return cell_module->get_bool_attribute(ID(cxxrtl_blackbox));
}
bool is_memwr_process(const RTLIL::Process *process)
{
for (auto sync : process->syncs)
if (!sync->mem_write_actions.empty())
return true;
return false;
}
enum class CxxrtlPortType {
UNKNOWN = 0, // or mixed comb/sync
COMB = 1,
SYNC = 2,
};
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
CxxrtlPortType cxxrtl_port_type(RTLIL::Module *module, RTLIL::IdString port)
{
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
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RTLIL::Wire *output_wire = module->wire(port);
log_assert(output_wire != nullptr);
bool is_comb = output_wire->get_bool_attribute(ID(cxxrtl_comb));
bool is_sync = output_wire->get_bool_attribute(ID(cxxrtl_sync));
if (is_comb && is_sync)
log_cmd_error("Port `%s.%s' is marked as both `cxxrtl_comb` and `cxxrtl_sync`.\n",
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
log_id(module), log_signal(output_wire));
else if (is_comb)
return CxxrtlPortType::COMB;
else if (is_sync)
return CxxrtlPortType::SYNC;
return CxxrtlPortType::UNKNOWN;
}
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
CxxrtlPortType cxxrtl_port_type(const RTLIL::Cell *cell, RTLIL::IdString port)
{
RTLIL::Module *cell_module = cell->module->design->module(cell->type);
if (cell_module == nullptr || !cell_module->get_bool_attribute(ID(cxxrtl_blackbox)))
return CxxrtlPortType::UNKNOWN;
return cxxrtl_port_type(cell_module, port);
}
bool is_cxxrtl_comb_port(const RTLIL::Cell *cell, RTLIL::IdString port)
{
return cxxrtl_port_type(cell, port) == CxxrtlPortType::COMB;
}
bool is_cxxrtl_sync_port(const RTLIL::Cell *cell, RTLIL::IdString port)
{
return cxxrtl_port_type(cell, port) == CxxrtlPortType::SYNC;
}
struct FlowGraph {
struct Node {
enum class Type {
CONNECT,
CELL_SYNC,
CELL_EVAL,
PRINT_SYNC,
PROCESS_SYNC,
PROCESS_CASE,
MEM_RDPORT,
MEM_WRPORTS,
};
Type type;
RTLIL::SigSig connect = {};
const RTLIL::Cell *cell = nullptr;
std::vector<const RTLIL::Cell*> print_sync_cells;
const RTLIL::Process *process = nullptr;
const Mem *mem = nullptr;
int portidx;
};
std::vector<Node*> nodes;
cxxrtl: localize wires with multiple comb drivers, too. Before this commit, any wire that was not driven by an output port of exactly one comb cell would not be localized, even if there were no feedback arcs through that wire. This would cause the wire to become buffered and require (often quite a few) extraneous delta cycles during evaluation. To alleviate this problem, -O5 was running `splitnets -driver`. However, this solution was mistaken. Because `splitnets -driver` followed by `opt_clean -purge` would produce more nets with multiple drivers, it would have to be iterated to fixpoint. Moreover, even if this was done, it would not be sufficient because `opt_clean -purge` does not currently remove wires with the `\init` attribute (and it is not desirable to remove such wires, since they correspond to registers and may be useful for debugging). The proper solution is to consider the condition in which a wire may be localized. Specifically, if there are no feedback arcs through this wire, and no part of the wire is driven by an output of a sync cell, then the wire holds no state and is localizable. After this commit, the original condition for not localizing a wire is replaced by a check for any sync cell driving it. This makes it unnecessary to run `splitnets -driver` in the majority of cases to get a design with no buffered wires, and -O5 no longer includes that pass. As a result, Minerva SRAM SoC no longer has any buffered wires, and runs ~27% faster. In addition, this commit prepares the flow graph for introduction of sync outputs of black boxes. Co-authored-by: Jean-François Nguyen <jf@lambdaconcept.com>
2020-04-21 08:33:42 -05:00
dict<const RTLIL::Wire*, pool<Node*, hash_ptr_ops>> wire_comb_defs, wire_sync_defs, wire_uses;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
dict<Node*, pool<const RTLIL::Wire*>, hash_ptr_ops> node_comb_defs, node_sync_defs, node_uses;
dict<const RTLIL::Wire*, bool> wire_def_inlinable;
dict<const RTLIL::Wire*, dict<Node*, bool, hash_ptr_ops>> wire_use_inlinable;
dict<RTLIL::SigBit, bool> bit_has_state;
~FlowGraph()
{
for (auto node : nodes)
delete node;
}
void add_defs(Node *node, const RTLIL::SigSpec &sig, bool is_ff, bool inlinable)
{
for (auto chunk : sig.chunks())
cxxrtl: localize wires with multiple comb drivers, too. Before this commit, any wire that was not driven by an output port of exactly one comb cell would not be localized, even if there were no feedback arcs through that wire. This would cause the wire to become buffered and require (often quite a few) extraneous delta cycles during evaluation. To alleviate this problem, -O5 was running `splitnets -driver`. However, this solution was mistaken. Because `splitnets -driver` followed by `opt_clean -purge` would produce more nets with multiple drivers, it would have to be iterated to fixpoint. Moreover, even if this was done, it would not be sufficient because `opt_clean -purge` does not currently remove wires with the `\init` attribute (and it is not desirable to remove such wires, since they correspond to registers and may be useful for debugging). The proper solution is to consider the condition in which a wire may be localized. Specifically, if there are no feedback arcs through this wire, and no part of the wire is driven by an output of a sync cell, then the wire holds no state and is localizable. After this commit, the original condition for not localizing a wire is replaced by a check for any sync cell driving it. This makes it unnecessary to run `splitnets -driver` in the majority of cases to get a design with no buffered wires, and -O5 no longer includes that pass. As a result, Minerva SRAM SoC no longer has any buffered wires, and runs ~27% faster. In addition, this commit prepares the flow graph for introduction of sync outputs of black boxes. Co-authored-by: Jean-François Nguyen <jf@lambdaconcept.com>
2020-04-21 08:33:42 -05:00
if (chunk.wire) {
if (is_ff) {
// A sync def means that a wire holds design state because it is driven directly by
// a flip-flop output. Such a wire can never be unbuffered.
cxxrtl: localize wires with multiple comb drivers, too. Before this commit, any wire that was not driven by an output port of exactly one comb cell would not be localized, even if there were no feedback arcs through that wire. This would cause the wire to become buffered and require (often quite a few) extraneous delta cycles during evaluation. To alleviate this problem, -O5 was running `splitnets -driver`. However, this solution was mistaken. Because `splitnets -driver` followed by `opt_clean -purge` would produce more nets with multiple drivers, it would have to be iterated to fixpoint. Moreover, even if this was done, it would not be sufficient because `opt_clean -purge` does not currently remove wires with the `\init` attribute (and it is not desirable to remove such wires, since they correspond to registers and may be useful for debugging). The proper solution is to consider the condition in which a wire may be localized. Specifically, if there are no feedback arcs through this wire, and no part of the wire is driven by an output of a sync cell, then the wire holds no state and is localizable. After this commit, the original condition for not localizing a wire is replaced by a check for any sync cell driving it. This makes it unnecessary to run `splitnets -driver` in the majority of cases to get a design with no buffered wires, and -O5 no longer includes that pass. As a result, Minerva SRAM SoC no longer has any buffered wires, and runs ~27% faster. In addition, this commit prepares the flow graph for introduction of sync outputs of black boxes. Co-authored-by: Jean-François Nguyen <jf@lambdaconcept.com>
2020-04-21 08:33:42 -05:00
wire_sync_defs[chunk.wire].insert(node);
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
node_sync_defs[node].insert(chunk.wire);
} else {
// A comb def means that a wire doesn't hold design state. It might still be connected,
// indirectly, to a flip-flop output.
cxxrtl: localize wires with multiple comb drivers, too. Before this commit, any wire that was not driven by an output port of exactly one comb cell would not be localized, even if there were no feedback arcs through that wire. This would cause the wire to become buffered and require (often quite a few) extraneous delta cycles during evaluation. To alleviate this problem, -O5 was running `splitnets -driver`. However, this solution was mistaken. Because `splitnets -driver` followed by `opt_clean -purge` would produce more nets with multiple drivers, it would have to be iterated to fixpoint. Moreover, even if this was done, it would not be sufficient because `opt_clean -purge` does not currently remove wires with the `\init` attribute (and it is not desirable to remove such wires, since they correspond to registers and may be useful for debugging). The proper solution is to consider the condition in which a wire may be localized. Specifically, if there are no feedback arcs through this wire, and no part of the wire is driven by an output of a sync cell, then the wire holds no state and is localizable. After this commit, the original condition for not localizing a wire is replaced by a check for any sync cell driving it. This makes it unnecessary to run `splitnets -driver` in the majority of cases to get a design with no buffered wires, and -O5 no longer includes that pass. As a result, Minerva SRAM SoC no longer has any buffered wires, and runs ~27% faster. In addition, this commit prepares the flow graph for introduction of sync outputs of black boxes. Co-authored-by: Jean-François Nguyen <jf@lambdaconcept.com>
2020-04-21 08:33:42 -05:00
wire_comb_defs[chunk.wire].insert(node);
node_comb_defs[node].insert(chunk.wire);
}
cxxrtl: localize wires with multiple comb drivers, too. Before this commit, any wire that was not driven by an output port of exactly one comb cell would not be localized, even if there were no feedback arcs through that wire. This would cause the wire to become buffered and require (often quite a few) extraneous delta cycles during evaluation. To alleviate this problem, -O5 was running `splitnets -driver`. However, this solution was mistaken. Because `splitnets -driver` followed by `opt_clean -purge` would produce more nets with multiple drivers, it would have to be iterated to fixpoint. Moreover, even if this was done, it would not be sufficient because `opt_clean -purge` does not currently remove wires with the `\init` attribute (and it is not desirable to remove such wires, since they correspond to registers and may be useful for debugging). The proper solution is to consider the condition in which a wire may be localized. Specifically, if there are no feedback arcs through this wire, and no part of the wire is driven by an output of a sync cell, then the wire holds no state and is localizable. After this commit, the original condition for not localizing a wire is replaced by a check for any sync cell driving it. This makes it unnecessary to run `splitnets -driver` in the majority of cases to get a design with no buffered wires, and -O5 no longer includes that pass. As a result, Minerva SRAM SoC no longer has any buffered wires, and runs ~27% faster. In addition, this commit prepares the flow graph for introduction of sync outputs of black boxes. Co-authored-by: Jean-François Nguyen <jf@lambdaconcept.com>
2020-04-21 08:33:42 -05:00
}
for (auto bit : sig.bits())
bit_has_state[bit] |= is_ff;
// Only comb defs of an entire wire in the right order can be inlined.
if (!is_ff && sig.is_wire()) {
// Only a single def of a wire can be inlined. (Multiple defs of a wire are unsound, but we
// handle them anyway to avoid assertion failures later.)
if (!wire_def_inlinable.count(sig.as_wire()))
wire_def_inlinable[sig.as_wire()] = inlinable;
else
wire_def_inlinable[sig.as_wire()] = false;
}
}
void add_uses(Node *node, const RTLIL::SigSpec &sig)
{
for (auto chunk : sig.chunks())
if (chunk.wire) {
wire_uses[chunk.wire].insert(node);
node_uses[node].insert(chunk.wire);
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
// Only a single use of an entire wire in the right order can be inlined. (But the use can include
// other chunks.) This is tracked per-node because a wire used by multiple nodes can still be inlined
// if all but one of those nodes is dead.
if (!wire_use_inlinable[chunk.wire].count(node))
wire_use_inlinable[chunk.wire][node] = true;
else
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
wire_use_inlinable[chunk.wire][node] = false;
}
}
bool is_inlinable(const RTLIL::Wire *wire) const
{
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
// Can the wire be inlined at all?
if (wire_def_inlinable.count(wire))
return wire_def_inlinable.at(wire);
return false;
}
bool is_inlinable(const RTLIL::Wire *wire, const pool<Node*, hash_ptr_ops> &nodes) const
{
// Can the wire be inlined, knowing that the given nodes are reachable?
if (nodes.size() != 1)
return false;
Node *node = *nodes.begin();
log_assert(node_uses.at(node).count(wire));
if (is_inlinable(wire) && wire_use_inlinable.count(wire) && wire_use_inlinable.at(wire).count(node))
return wire_use_inlinable.at(wire).at(node);
return false;
}
// Connections
void add_connect_defs_uses(Node *node, const RTLIL::SigSig &conn)
{
add_defs(node, conn.first, /*is_ff=*/false, /*inlinable=*/true);
add_uses(node, conn.second);
}
Node *add_node(const RTLIL::SigSig &conn)
{
Node *node = new Node;
node->type = Node::Type::CONNECT;
node->connect = conn;
nodes.push_back(node);
add_connect_defs_uses(node, conn);
return node;
}
// Cells
void add_cell_sync_defs(Node *node, const RTLIL::Cell *cell)
{
// To understand why this node type is necessary and why it produces comb defs, consider a cell
// with input \i and sync output \o, used in a design such that \i is connected to \o. This does
// not result in a feedback arc because the output is synchronous. However, a naive implementation
// of code generation for cells that assigns to inputs, evaluates cells, assigns from outputs
// would not be able to immediately converge...
//
// wire<1> i_tmp;
// cell->p_i = i_tmp.curr;
// cell->eval();
// i_tmp.next = cell->p_o.curr;
//
// ... since the wire connecting the input and output ports would not be localizable. To solve
// this, the cell is split into two scheduling nodes; one exclusively for sync outputs, and
// another for inputs and all non-sync outputs. This way the generated code can be rearranged...
//
// value<1> i_tmp;
// i_tmp = cell->p_o.curr;
// cell->p_i = i_tmp;
// cell->eval();
//
// eliminating the unnecessary delta cycle. Conceptually, the CELL_SYNC node type is a series of
// connections of the form `connect \lhs \cell.\sync_output`; the right-hand side of these is not
2020-06-07 23:08:09 -05:00
// expressible as a wire in RTLIL. If it was expressible, then `\cell.\sync_output` would have
// a sync def, and this node would be an ordinary CONNECT node, with `\lhs` having a comb def.
// Because it isn't, a special node type is used, the right-hand side does not appear anywhere,
// and the left-hand side has a comb def.
for (auto conn : cell->connections())
if (cell->output(conn.first))
if (is_cxxrtl_sync_port(cell, conn.first)) {
// See note regarding inlinability below.
add_defs(node, conn.second, /*is_ff=*/false, /*inlinable=*/false);
}
}
void add_cell_eval_defs_uses(Node *node, const RTLIL::Cell *cell)
{
for (auto conn : cell->connections()) {
if (cell->output(conn.first)) {
if (is_inlinable_cell(cell->type))
add_defs(node, conn.second, /*is_ff=*/false, /*inlinable=*/true);
else if (is_ff_cell(cell->type))
add_defs(node, conn.second, /*is_ff=*/true, /*inlinable=*/false);
else if (is_internal_cell(cell->type))
add_defs(node, conn.second, /*is_ff=*/false, /*inlinable=*/false);
else if (!is_cxxrtl_sync_port(cell, conn.first)) {
// Although at first it looks like outputs of user-defined cells may always be inlined, the reality is
// more complex. Fully sync outputs produce no defs and so don't participate in inlining. Fully comb
// outputs are assigned in a different way depending on whether the cell's eval() immediately converged.
// Unknown/mixed outputs could be inlined, but should be rare in practical designs and don't justify
// the infrastructure required to inline outputs of cells with many of them.
add_defs(node, conn.second, /*is_ff=*/false, /*inlinable=*/false);
}
}
if (cell->input(conn.first))
add_uses(node, conn.second);
}
}
Node *add_node(const RTLIL::Cell *cell)
{
log_assert(cell->known());
bool has_fully_sync_outputs = false;
for (auto conn : cell->connections())
if (cell->output(conn.first) && is_cxxrtl_sync_port(cell, conn.first)) {
has_fully_sync_outputs = true;
break;
}
if (has_fully_sync_outputs) {
Node *node = new Node;
node->type = Node::Type::CELL_SYNC;
node->cell = cell;
nodes.push_back(node);
add_cell_sync_defs(node, cell);
}
Node *node = new Node;
node->type = Node::Type::CELL_EVAL;
node->cell = cell;
nodes.push_back(node);
add_cell_eval_defs_uses(node, cell);
return node;
}
Node *add_print_sync_node(std::vector<const RTLIL::Cell*> cells)
{
Node *node = new Node;
node->type = Node::Type::PRINT_SYNC;
node->print_sync_cells = cells;
nodes.push_back(node);
return node;
}
// Processes
void add_case_rule_defs_uses(Node *node, const RTLIL::CaseRule *case_)
{
for (auto &action : case_->actions) {
add_defs(node, action.first, /*is_ff=*/false, /*inlinable=*/false);
add_uses(node, action.second);
}
for (auto sub_switch : case_->switches) {
add_uses(node, sub_switch->signal);
for (auto sub_case : sub_switch->cases) {
for (auto &compare : sub_case->compare)
add_uses(node, compare);
add_case_rule_defs_uses(node, sub_case);
}
}
}
void add_sync_rules_defs_uses(Node *node, const RTLIL::Process *process)
{
for (auto sync : process->syncs) {
for (auto &action : sync->actions) {
if (sync->type == RTLIL::STp || sync->type == RTLIL::STn || sync->type == RTLIL::STe)
add_defs(node, action.first, /*is_ff=*/true, /*inlinable=*/false);
else
add_defs(node, action.first, /*is_ff=*/false, /*inlinable=*/false);
add_uses(node, action.second);
}
for (auto &memwr : sync->mem_write_actions) {
add_uses(node, memwr.address);
add_uses(node, memwr.data);
add_uses(node, memwr.enable);
}
}
}
Node *add_node(const RTLIL::Process *process)
{
Node *node = new Node;
node->type = Node::Type::PROCESS_SYNC;
node->process = process;
nodes.push_back(node);
add_sync_rules_defs_uses(node, process);
node = new Node;
node->type = Node::Type::PROCESS_CASE;
node->process = process;
nodes.push_back(node);
add_case_rule_defs_uses(node, &process->root_case);
return node;
}
// Memories
void add_node(const Mem *mem) {
for (int i = 0; i < GetSize(mem->rd_ports); i++) {
auto &port = mem->rd_ports[i];
Node *node = new Node;
node->type = Node::Type::MEM_RDPORT;
node->mem = mem;
node->portidx = i;
nodes.push_back(node);
add_defs(node, port.data, /*is_ff=*/port.clk_enable, /*inlinable=*/false);
add_uses(node, port.clk);
add_uses(node, port.en);
add_uses(node, port.arst);
add_uses(node, port.srst);
add_uses(node, port.addr);
bool transparent = false;
for (int j = 0; j < GetSize(mem->wr_ports); j++) {
auto &wrport = mem->wr_ports[j];
if (port.transparency_mask[j]) {
// Our implementation of transparent read ports reads en, addr and data from every write port
// the read port is transparent with.
add_uses(node, wrport.en);
add_uses(node, wrport.addr);
add_uses(node, wrport.data);
transparent = true;
}
}
// Also we read the read address twice in this case (prevent inlining).
if (transparent)
add_uses(node, port.addr);
}
if (!mem->wr_ports.empty()) {
Node *node = new Node;
node->type = Node::Type::MEM_WRPORTS;
node->mem = mem;
nodes.push_back(node);
for (auto &port : mem->wr_ports) {
add_uses(node, port.clk);
add_uses(node, port.en);
add_uses(node, port.addr);
add_uses(node, port.data);
}
}
}
};
std::vector<std::string> split_by(const std::string &str, const std::string &sep)
{
std::vector<std::string> result;
size_t prev = 0;
while (true) {
size_t curr = str.find_first_of(sep, prev);
if (curr == std::string::npos) {
std::string part = str.substr(prev);
if (!part.empty()) result.push_back(part);
break;
} else {
std::string part = str.substr(prev, curr - prev);
if (!part.empty()) result.push_back(part);
prev = curr + 1;
}
}
return result;
}
std::string escape_cxx_string(const std::string &input)
{
std::string output = "\"";
for (auto c : input) {
if (::isprint(c)) {
if (c == '\\')
output.push_back('\\');
output.push_back(c);
} else {
char l = c & 0xf, h = (c >> 4) & 0xf;
output.append("\\x");
output.push_back((h < 10 ? '0' + h : 'a' + h - 10));
output.push_back((l < 10 ? '0' + l : 'a' + l - 10));
}
}
output.push_back('"');
if (output.find('\0') != std::string::npos) {
output.insert(0, "std::string {");
output.append(stringf(", %zu}", input.size()));
}
return output;
}
template<class T>
std::string get_hdl_name(T *object)
{
if (object->has_attribute(ID::hdlname))
return object->get_string_attribute(ID::hdlname);
else
return object->name.str().substr(1);
}
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
struct WireType {
enum Type {
// Non-referenced wire; is not a part of the design.
UNUSED,
// Double-buffered wire; is a class member, and holds design state.
BUFFERED,
// Single-buffered wire; is a class member, but holds no state.
MEMBER,
// Single-buffered wire; is a class member, and is computed on demand.
OUTLINE,
// Local wire; is a local variable in eval method.
LOCAL,
// Inline wire; is an unnamed temporary in eval method.
INLINE,
// Alias wire; is replaced with aliasee, except in debug info.
ALIAS,
// Const wire; is replaced with constant, except in debug info.
CONST,
};
Type type = UNUSED;
const RTLIL::Cell *cell_subst = nullptr; // for INLINE
RTLIL::SigSpec sig_subst = {}; // for INLINE, ALIAS, and CONST
WireType() = default;
WireType(Type type) : type(type) {
log_assert(type == UNUSED || type == BUFFERED || type == MEMBER || type == OUTLINE || type == LOCAL);
}
WireType(Type type, const RTLIL::Cell *cell) : type(type), cell_subst(cell) {
log_assert(type == INLINE && is_inlinable_cell(cell->type));
}
WireType(Type type, RTLIL::SigSpec sig) : type(type), sig_subst(sig) {
log_assert(type == INLINE || (type == ALIAS && sig.is_wire()) || (type == CONST && sig.is_fully_const()));
}
bool is_buffered() const { return type == BUFFERED; }
bool is_member() const { return type == BUFFERED || type == MEMBER || type == OUTLINE; }
bool is_outline() const { return type == OUTLINE; }
bool is_named() const { return is_member() || type == LOCAL; }
bool is_local() const { return type == LOCAL || type == INLINE; }
bool is_exact() const { return type == ALIAS || type == CONST; }
};
// Tests for a SigSpec that is a valid clock input, clocks have to have a backing wire and be a single bit
// using this instead of sig.is_wire() solves issues when the clock is a slice instead of a full wire
bool is_valid_clock(const RTLIL::SigSpec& sig) {
return sig.is_chunk() && sig.is_bit() && sig[0].wire;
}
struct CxxrtlWorker {
bool split_intf = false;
std::string intf_filename;
std::string design_ns = "cxxrtl_design";
std::string print_output = "std::cout";
std::ostream *impl_f = nullptr;
std::ostream *intf_f = nullptr;
bool print_wire_types = false;
bool print_debug_wire_types = false;
bool run_hierarchy = false;
bool run_flatten = false;
bool run_proc = false;
bool unbuffer_internal = false;
bool unbuffer_public = false;
bool localize_internal = false;
bool localize_public = false;
bool inline_internal = false;
bool inline_public = false;
bool debug_info = false;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
bool debug_member = false;
bool debug_alias = false;
bool debug_eval = false;
std::ostringstream f;
std::string indent;
int temporary = 0;
dict<const RTLIL::Module*, SigMap> sigmaps;
dict<const RTLIL::Module*, std::vector<Mem>> mod_memories;
pool<std::pair<const RTLIL::Module*, RTLIL::IdString>> writable_memories;
pool<const RTLIL::Wire*> edge_wires;
dict<const RTLIL::Wire*, RTLIL::Const> wire_init;
dict<RTLIL::SigBit, RTLIL::SyncType> edge_types;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
dict<const RTLIL::Module*, std::vector<FlowGraph::Node>> schedule, debug_schedule;
dict<const RTLIL::Wire*, WireType> wire_types, debug_wire_types;
dict<RTLIL::SigBit, bool> bit_has_state;
dict<const RTLIL::Module*, pool<std::string>> blackbox_specializations;
dict<const RTLIL::Module*, bool> eval_converges;
void inc_indent() {
indent += "\t";
}
void dec_indent() {
indent.resize(indent.size() - 1);
}
// RTLIL allows any characters in names other than whitespace. This presents an issue for generating C++ code
// because C++ identifiers may be only alphanumeric, cannot clash with C++ keywords, and cannot clash with cxxrtl
// identifiers. This issue can be solved with a name mangling scheme. We choose a name mangling scheme that results
// in readable identifiers, does not depend on an up-to-date list of C++ keywords, and is easy to apply. Its rules:
// 1. All generated identifiers start with `_`.
// 1a. Generated identifiers for public names (beginning with `\`) start with `p_`.
// 1b. Generated identifiers for internal names (beginning with `$`) start with `i_`.
// 2. An underscore is escaped with another underscore, i.e. `__`.
// 3. Any other non-alnum character is escaped with underscores around its lowercase hex code, e.g. `@` as `_40_`.
std::string mangle_name(const RTLIL::IdString &name)
{
std::string mangled;
bool first = true;
for (char c : name.str()) {
if (first) {
first = false;
if (c == '\\')
mangled += "p_";
else if (c == '$')
mangled += "i_";
else
log_assert(false);
} else {
if (isalnum(c)) {
mangled += c;
} else if (c == '_') {
mangled += "__";
} else {
char l = c & 0xf, h = (c >> 4) & 0xf;
mangled += '_';
mangled += (h < 10 ? '0' + h : 'a' + h - 10);
mangled += (l < 10 ? '0' + l : 'a' + l - 10);
mangled += '_';
}
}
}
return mangled;
}
std::string mangle_module_name(const RTLIL::IdString &name, bool is_blackbox = false)
{
// Class namespace.
if (is_blackbox)
return "bb_" + mangle_name(name);
return mangle_name(name);
}
std::string mangle_memory_name(const RTLIL::IdString &name)
{
// Class member namespace.
return "memory_" + mangle_name(name);
}
std::string mangle_cell_name(const RTLIL::IdString &name)
{
// Class member namespace.
return "cell_" + mangle_name(name);
}
std::string mangle_wire_name(const RTLIL::IdString &name)
{
// Class member namespace.
return mangle_name(name);
}
std::string mangle(const RTLIL::Module *module)
{
return mangle_module_name(module->name, /*is_blackbox=*/module->get_bool_attribute(ID(cxxrtl_blackbox)));
}
std::string mangle(const Mem *mem)
{
return mangle_memory_name(mem->memid);
}
std::string mangle(const RTLIL::Memory *memory)
{
return mangle_memory_name(memory->name);
}
std::string mangle(const RTLIL::Cell *cell)
{
return mangle_cell_name(cell->name);
}
std::string mangle(const RTLIL::Wire *wire)
{
return mangle_wire_name(wire->name);
}
std::string mangle(RTLIL::SigBit sigbit)
{
log_assert(sigbit.wire != NULL);
if (sigbit.wire->width == 1)
return mangle(sigbit.wire);
return mangle(sigbit.wire) + "_" + std::to_string(sigbit.offset);
}
std::vector<std::string> template_param_names(const RTLIL::Module *module)
{
if (!module->has_attribute(ID(cxxrtl_template)))
return {};
if (module->attributes.at(ID(cxxrtl_template)).flags != RTLIL::CONST_FLAG_STRING)
log_cmd_error("Attribute `cxxrtl_template' of module `%s' is not a string.\n", log_id(module));
std::vector<std::string> param_names = split_by(module->get_string_attribute(ID(cxxrtl_template)), " \t");
for (const auto &param_name : param_names) {
// Various lowercase prefixes (p_, i_, cell_, ...) are used for member variables, so require
// parameters to start with an uppercase letter to avoid name conflicts. (This is the convention
// in both Verilog and C++, anyway.)
if (!isupper(param_name[0]))
log_cmd_error("Attribute `cxxrtl_template' of module `%s' includes a parameter `%s', "
"which does not start with an uppercase letter.\n",
log_id(module), param_name.c_str());
}
return param_names;
}
std::string template_params(const RTLIL::Module *module, bool is_decl)
{
std::vector<std::string> param_names = template_param_names(module);
if (param_names.empty())
return "";
std::string params = "<";
bool first = true;
for (const auto &param_name : param_names) {
if (!first)
params += ", ";
first = false;
if (is_decl)
params += "size_t ";
params += param_name;
}
params += ">";
return params;
}
std::string template_args(const RTLIL::Cell *cell)
{
RTLIL::Module *cell_module = cell->module->design->module(cell->type);
log_assert(cell_module != nullptr);
if (!cell_module->get_bool_attribute(ID(cxxrtl_blackbox)))
return "";
std::vector<std::string> param_names = template_param_names(cell_module);
if (param_names.empty())
return "";
std::string params = "<";
bool first = true;
for (const auto &param_name : param_names) {
if (!first)
params += ", ";
first = false;
params += "/*" + param_name + "=*/";
RTLIL::IdString id_param_name = '\\' + param_name;
if (!cell->hasParam(id_param_name))
log_cmd_error("Cell `%s.%s' does not have a parameter `%s', which is required by the templated module `%s'.\n",
log_id(cell->module), log_id(cell), param_name.c_str(), log_id(cell_module));
RTLIL::Const param_value = cell->getParam(id_param_name);
if (((param_value.flags & ~RTLIL::CONST_FLAG_SIGNED) != 0) || param_value.as_int() < 0)
log_cmd_error("Parameter `%s' of cell `%s.%s', which is required by the templated module `%s', "
"is not a positive integer.\n",
param_name.c_str(), log_id(cell->module), log_id(cell), log_id(cell_module));
params += std::to_string(cell->getParam(id_param_name).as_int());
}
params += ">";
return params;
}
std::string fresh_temporary()
{
return stringf("tmp_%d", temporary++);
}
void dump_attrs(const RTLIL::AttrObject *object)
{
for (auto attr : object->attributes) {
f << indent << "// " << attr.first.str() << ": ";
if (attr.second.flags & RTLIL::CONST_FLAG_STRING) {
f << attr.second.decode_string();
} else {
f << attr.second.as_int(/*is_signed=*/attr.second.flags & RTLIL::CONST_FLAG_SIGNED);
}
f << "\n";
}
}
void dump_const_init(const RTLIL::Const &data, int width, int offset = 0, bool fixed_width = false)
{
const int CHUNK_SIZE = 32;
f << "{";
while (width > 0) {
int chunk_width = min(width, CHUNK_SIZE);
uint32_t chunk = data.extract(offset, chunk_width).as_int();
if (fixed_width)
f << stringf("0x%.*xu", (3 + chunk_width) / 4, chunk);
else
f << stringf("%#xu", chunk);
if (width > CHUNK_SIZE)
f << ',';
offset += CHUNK_SIZE;
width -= CHUNK_SIZE;
}
f << "}";
}
void dump_const(const RTLIL::Const &data, int width, int offset = 0, bool fixed_width = false)
{
f << "value<" << width << ">";
dump_const_init(data, width, offset, fixed_width);
}
void dump_const(const RTLIL::Const &data)
{
dump_const(data, data.size());
}
bool dump_sigchunk(const RTLIL::SigChunk &chunk, bool is_lhs, bool for_debug = false)
{
if (chunk.wire == NULL) {
dump_const(chunk.data, chunk.width, chunk.offset);
return false;
} else {
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
const auto &wire_type = (for_debug ? debug_wire_types : wire_types)[chunk.wire];
switch (wire_type.type) {
case WireType::BUFFERED:
f << mangle(chunk.wire) << (is_lhs ? ".next" : ".curr");
break;
case WireType::MEMBER:
case WireType::LOCAL:
case WireType::OUTLINE:
f << mangle(chunk.wire);
break;
case WireType::INLINE:
log_assert(!is_lhs);
if (wire_type.cell_subst != nullptr) {
dump_cell_expr(wire_type.cell_subst, for_debug);
break;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
}
YS_FALLTHROUGH
case WireType::ALIAS:
case WireType::CONST:
log_assert(!is_lhs);
return dump_sigspec(wire_type.sig_subst.extract(chunk.offset, chunk.width), is_lhs, for_debug);
case WireType::UNUSED:
log_assert(is_lhs);
f << "value<" << chunk.width << ">()";
return false;
}
if (chunk.width == chunk.wire->width && chunk.offset == 0)
return false;
else if (chunk.width == 1)
f << ".slice<" << chunk.offset << ">()";
else
f << ".slice<" << chunk.offset+chunk.width-1 << "," << chunk.offset << ">()";
return true;
}
}
bool dump_sigspec(const RTLIL::SigSpec &sig, bool is_lhs, bool for_debug = false)
{
if (sig.empty()) {
f << "value<0>()";
return false;
} else if (sig.is_chunk()) {
return dump_sigchunk(sig.as_chunk(), is_lhs, for_debug);
} else {
bool first = true;
auto chunks = sig.chunks();
for (auto it = chunks.rbegin(); it != chunks.rend(); it++) {
if (!first)
f << ".concat(";
bool is_complex = dump_sigchunk(*it, is_lhs, for_debug);
if (!is_lhs && it->width == 1) {
size_t repeat = 1;
while ((it + repeat) != chunks.rend() && *(it + repeat) == *it)
repeat++;
if (repeat > 1) {
if (is_complex)
f << ".val()";
f << ".repeat<" << repeat << ">()";
}
it += repeat - 1;
}
if (!first)
f << ")";
first = false;
}
return true;
}
}
void dump_sigspec_lhs(const RTLIL::SigSpec &sig, bool for_debug = false)
{
dump_sigspec(sig, /*is_lhs=*/true, for_debug);
}
void dump_sigspec_rhs(const RTLIL::SigSpec &sig, bool for_debug = false)
{
// In the contexts where we want template argument deduction to occur for `template<size_t Bits> ... value<Bits>`,
// it is necessary to have the argument to already be a `value<N>`, since template argument deduction and implicit
// type conversion are mutually exclusive. In these contexts, we use dump_sigspec_rhs() to emit an explicit
// type conversion, but only if the expression needs it.
bool is_complex = dump_sigspec(sig, /*is_lhs=*/false, for_debug);
if (is_complex)
f << ".val()";
}
2023-06-27 20:51:17 -05:00
void dump_print(const RTLIL::Cell *cell)
{
Fmt fmt = {};
fmt.parse_rtlil(cell);
f << indent << "if (";
dump_sigspec_rhs(cell->getPort(ID::EN));
f << " == value<1>{1u}) {\n";
inc_indent();
f << indent << print_output;
fmt.emit_cxxrtl(f, [this](const RTLIL::SigSpec &sig) { dump_sigspec_rhs(sig); });
f << ";\n";
dec_indent();
f << indent << "}\n";
}
void dump_sync_print(std::vector<const RTLIL::Cell*> &cells)
{
log_assert(!cells.empty());
const auto &trg = cells[0]->getPort(ID::TRG);
const auto &trg_polarity = cells[0]->getParam(ID::TRG_POLARITY);
f << indent << "if (";
for (int i = 0; i < trg.size(); i++) {
RTLIL::SigBit trg_bit = trg[i];
trg_bit = sigmaps[trg_bit.wire->module](trg_bit);
log_assert(trg_bit.wire);
if (i != 0)
f << " || ";
if (trg_polarity[i] == State::S1)
f << "posedge_";
else
f << "negedge_";
f << mangle(trg_bit);
}
f << ") {\n";
inc_indent();
std::sort(cells.begin(), cells.end(), [](const RTLIL::Cell *a, const RTLIL::Cell *b) {
return a->getParam(ID::PRIORITY).as_int() > b->getParam(ID::PRIORITY).as_int();
});
for (auto cell : cells) {
log_assert(cell->getParam(ID::TRG_ENABLE).as_bool());
log_assert(cell->getPort(ID::TRG) == trg);
log_assert(cell->getParam(ID::TRG_POLARITY) == trg_polarity);
std::vector<const RTLIL::Cell*> inlined_cells;
collect_cell_eval(cell, /*for_debug=*/false, inlined_cells);
dump_inlined_cells(inlined_cells);
dump_print(cell);
}
dec_indent();
f << indent << "}\n";
2023-06-27 20:51:17 -05:00
}
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
void dump_inlined_cells(const std::vector<const RTLIL::Cell*> &cells)
{
if (cells.empty()) {
f << indent << "// connection\n";
} else if (cells.size() == 1) {
dump_attrs(cells.front());
f << indent << "// cell " << cells.front()->name.str() << "\n";
} else {
f << indent << "// cells";
for (auto cell : cells)
f << " " << cell->name.str();
f << "\n";
}
}
void collect_sigspec_rhs(const RTLIL::SigSpec &sig, bool for_debug, std::vector<const RTLIL::Cell*> &cells)
{
for (auto chunk : sig.chunks()) {
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
if (!chunk.wire)
continue;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
const auto &wire_type = wire_types[chunk.wire];
switch (wire_type.type) {
case WireType::INLINE:
if (wire_type.cell_subst != nullptr) {
collect_cell_eval(wire_type.cell_subst, for_debug, cells);
break;
}
YS_FALLTHROUGH
case WireType::ALIAS:
collect_sigspec_rhs(wire_type.sig_subst, for_debug, cells);
break;
default:
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
break;
}
}
}
void dump_connect_expr(const RTLIL::SigSig &conn, bool for_debug = false)
{
dump_sigspec_rhs(conn.second, for_debug);
}
void dump_connect(const RTLIL::SigSig &conn, bool for_debug = false)
{
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
std::vector<const RTLIL::Cell*> inlined_cells;
collect_sigspec_rhs(conn.second, for_debug, inlined_cells);
dump_inlined_cells(inlined_cells);
f << indent;
dump_sigspec_lhs(conn.first, for_debug);
f << " = ";
dump_connect_expr(conn, for_debug);
f << ";\n";
}
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
void collect_connect(const RTLIL::SigSig &conn, bool for_debug, std::vector<const RTLIL::Cell*> &cells)
{
collect_sigspec_rhs(conn.second, for_debug, cells);
}
void dump_cell_sync(const RTLIL::Cell *cell, bool for_debug = false)
{
const char *access = is_cxxrtl_blackbox_cell(cell) ? "->" : ".";
f << indent << "// cell " << cell->name.str() << " syncs\n";
for (auto conn : cell->connections())
if (cell->output(conn.first))
if (is_cxxrtl_sync_port(cell, conn.first)) {
f << indent;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
dump_sigspec_lhs(conn.second, for_debug);
f << " = " << mangle(cell) << access << mangle_wire_name(conn.first) << ".curr;\n";
}
}
void dump_cell_expr(const RTLIL::Cell *cell, bool for_debug = false)
{
// Unary cells
if (is_unary_cell(cell->type)) {
f << cell->type.substr(1);
if (is_extending_cell(cell->type))
f << '_' << (cell->getParam(ID::A_SIGNED).as_bool() ? 's' : 'u');
f << "<" << cell->getParam(ID::Y_WIDTH).as_int() << ">(";
dump_sigspec_rhs(cell->getPort(ID::A), for_debug);
f << ")";
// Binary cells
} else if (is_binary_cell(cell->type)) {
f << cell->type.substr(1);
if (is_extending_cell(cell->type))
f << '_' << (cell->getParam(ID::A_SIGNED).as_bool() ? 's' : 'u') <<
(cell->getParam(ID::B_SIGNED).as_bool() ? 's' : 'u');
f << "<" << cell->getParam(ID::Y_WIDTH).as_int() << ">(";
dump_sigspec_rhs(cell->getPort(ID::A), for_debug);
f << ", ";
dump_sigspec_rhs(cell->getPort(ID::B), for_debug);
f << ")";
// Muxes
} else if (cell->type == ID($mux)) {
f << "(";
dump_sigspec_rhs(cell->getPort(ID::S), for_debug);
f << " ? ";
dump_sigspec_rhs(cell->getPort(ID::B), for_debug);
f << " : ";
dump_sigspec_rhs(cell->getPort(ID::A), for_debug);
f << ")";
// Parallel (one-hot) muxes
} else if (cell->type == ID($pmux)) {
int width = cell->getParam(ID::WIDTH).as_int();
int s_width = cell->getParam(ID::S_WIDTH).as_int();
for (int part = 0; part < s_width; part++) {
f << "(";
dump_sigspec_rhs(cell->getPort(ID::S).extract(part), for_debug);
f << " ? ";
dump_sigspec_rhs(cell->getPort(ID::B).extract(part * width, width), for_debug);
f << " : ";
}
dump_sigspec_rhs(cell->getPort(ID::A), for_debug);
for (int part = 0; part < s_width; part++) {
f << ")";
}
2022-01-24 09:02:29 -06:00
// Big muxes
} else if (cell->type == ID($bmux)) {
dump_sigspec_rhs(cell->getPort(ID::A), for_debug);
f << ".bmux<";
f << cell->getParam(ID::WIDTH).as_int();
f << ">(";
dump_sigspec_rhs(cell->getPort(ID::S), for_debug);
f << ").val()";
// Demuxes
} else if (cell->type == ID($demux)) {
dump_sigspec_rhs(cell->getPort(ID::A), for_debug);
f << ".demux<";
f << GetSize(cell->getPort(ID::Y));
f << ">(";
dump_sigspec_rhs(cell->getPort(ID::S), for_debug);
f << ").val()";
// Concats
} else if (cell->type == ID($concat)) {
dump_sigspec_rhs(cell->getPort(ID::B), for_debug);
f << ".concat(";
dump_sigspec_rhs(cell->getPort(ID::A), for_debug);
f << ").val()";
// Slices
} else if (cell->type == ID($slice)) {
dump_sigspec_rhs(cell->getPort(ID::A), for_debug);
f << ".slice<";
f << cell->getParam(ID::OFFSET).as_int() + cell->getParam(ID::Y_WIDTH).as_int() - 1;
f << ",";
f << cell->getParam(ID::OFFSET).as_int();
f << ">().val()";
} else {
log_assert(false);
}
}
void dump_cell_eval(const RTLIL::Cell *cell, bool for_debug = false)
{
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
std::vector<const RTLIL::Cell*> inlined_cells;
collect_cell_eval(cell, for_debug, inlined_cells);
dump_inlined_cells(inlined_cells);
// Elidable cells
if (is_inlinable_cell(cell->type)) {
f << indent;
dump_sigspec_lhs(cell->getPort(ID::Y), for_debug);
f << " = ";
dump_cell_expr(cell, for_debug);
f << ";\n";
2023-06-27 20:51:17 -05:00
// $print cell
} else if (cell->type == ID($print)) {
log_assert(!for_debug);
// Sync $print cells are grouped into PRINT_SYNC nodes in the FlowGraph.
log_assert(!cell->getParam(ID::TRG_ENABLE).as_bool());
f << indent << "auto " << mangle(cell) << "_curr = ";
2023-06-27 20:51:17 -05:00
dump_sigspec_rhs(cell->getPort(ID::EN));
f << ".concat(";
dump_sigspec_rhs(cell->getPort(ID::ARGS));
f << ").val();\n";
f << indent << "if (" << mangle(cell) << " != " << mangle(cell) << "_curr) {\n";
2023-06-27 20:51:17 -05:00
inc_indent();
dump_print(cell);
f << indent << mangle(cell) << " = " << mangle(cell) << "_curr;\n";
2023-06-27 20:51:17 -05:00
dec_indent();
f << indent << "}\n";
// Flip-flops
} else if (is_ff_cell(cell->type)) {
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
log_assert(!for_debug);
// Clocks might be slices of larger signals but should only ever be single bit
if (cell->hasPort(ID::CLK) && is_valid_clock(cell->getPort(ID::CLK))) {
// Edge-sensitive logic
RTLIL::SigBit clk_bit = cell->getPort(ID::CLK)[0];
clk_bit = sigmaps[clk_bit.wire->module](clk_bit);
if (clk_bit.wire) {
f << indent << "if (" << (cell->getParam(ID::CLK_POLARITY).as_bool() ? "posedge_" : "negedge_")
<< mangle(clk_bit) << ") {\n";
} else {
f << indent << "if (false) {\n";
}
inc_indent();
if (cell->hasPort(ID::EN)) {
f << indent << "if (";
dump_sigspec_rhs(cell->getPort(ID::EN));
f << " == value<1> {" << cell->getParam(ID::EN_POLARITY).as_bool() << "u}) {\n";
inc_indent();
}
f << indent;
dump_sigspec_lhs(cell->getPort(ID::Q));
f << " = ";
dump_sigspec_rhs(cell->getPort(ID::D));
f << ";\n";
if (cell->hasPort(ID::EN) && cell->type != ID($sdffce)) {
dec_indent();
f << indent << "}\n";
}
if (cell->hasPort(ID::SRST)) {
f << indent << "if (";
dump_sigspec_rhs(cell->getPort(ID::SRST));
f << " == value<1> {" << cell->getParam(ID::SRST_POLARITY).as_bool() << "u}) {\n";
inc_indent();
f << indent;
dump_sigspec_lhs(cell->getPort(ID::Q));
f << " = ";
dump_const(cell->getParam(ID::SRST_VALUE));
f << ";\n";
dec_indent();
f << indent << "}\n";
}
if (cell->hasPort(ID::EN) && cell->type == ID($sdffce)) {
dec_indent();
f << indent << "}\n";
}
dec_indent();
f << indent << "}\n";
} else if (cell->hasPort(ID::EN)) {
// Level-sensitive logic
f << indent << "if (";
dump_sigspec_rhs(cell->getPort(ID::EN));
f << " == value<1> {" << cell->getParam(ID::EN_POLARITY).as_bool() << "u}) {\n";
inc_indent();
f << indent;
dump_sigspec_lhs(cell->getPort(ID::Q));
f << " = ";
dump_sigspec_rhs(cell->getPort(ID::D));
f << ";\n";
dec_indent();
f << indent << "}\n";
}
if (cell->hasPort(ID::ARST)) {
// Asynchronous reset (entire coarse cell at once)
f << indent << "if (";
dump_sigspec_rhs(cell->getPort(ID::ARST));
f << " == value<1> {" << cell->getParam(ID::ARST_POLARITY).as_bool() << "u}) {\n";
inc_indent();
f << indent;
dump_sigspec_lhs(cell->getPort(ID::Q));
f << " = ";
dump_const(cell->getParam(ID::ARST_VALUE));
f << ";\n";
dec_indent();
f << indent << "}\n";
}
if (cell->hasPort(ID::ALOAD)) {
// Asynchronous load
f << indent << "if (";
dump_sigspec_rhs(cell->getPort(ID::ALOAD));
f << " == value<1> {" << cell->getParam(ID::ALOAD_POLARITY).as_bool() << "u}) {\n";
inc_indent();
f << indent;
dump_sigspec_lhs(cell->getPort(ID::Q));
f << " = ";
dump_sigspec_rhs(cell->getPort(ID::AD));
f << ";\n";
dec_indent();
f << indent << "}\n";
}
if (cell->hasPort(ID::SET)) {
// Asynchronous set (for individual bits)
f << indent;
dump_sigspec_lhs(cell->getPort(ID::Q));
f << " = ";
dump_sigspec_lhs(cell->getPort(ID::Q));
f << ".update(";
dump_const(RTLIL::Const(RTLIL::S1, cell->getParam(ID::WIDTH).as_int()));
f << ", ";
dump_sigspec_rhs(cell->getPort(ID::SET));
f << (cell->getParam(ID::SET_POLARITY).as_bool() ? "" : ".bit_not()") << ");\n";
}
if (cell->hasPort(ID::CLR)) {
// Asynchronous clear (for individual bits; priority over set)
f << indent;
dump_sigspec_lhs(cell->getPort(ID::Q));
f << " = ";
dump_sigspec_lhs(cell->getPort(ID::Q));
f << ".update(";
dump_const(RTLIL::Const(RTLIL::S0, cell->getParam(ID::WIDTH).as_int()));
f << ", ";
dump_sigspec_rhs(cell->getPort(ID::CLR));
f << (cell->getParam(ID::CLR_POLARITY).as_bool() ? "" : ".bit_not()") << ");\n";
}
// Internal cells
} else if (is_internal_cell(cell->type)) {
log_cmd_error("Unsupported internal cell `%s'.\n", cell->type.c_str());
// User cells
} else {
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
log_assert(!for_debug);
log_assert(cell->known());
bool buffered_inputs = false;
const char *access = is_cxxrtl_blackbox_cell(cell) ? "->" : ".";
for (auto conn : cell->connections())
if (cell->input(conn.first)) {
RTLIL::Module *cell_module = cell->module->design->module(cell->type);
log_assert(cell_module != nullptr && cell_module->wire(conn.first));
RTLIL::Wire *cell_module_wire = cell_module->wire(conn.first);
f << indent << mangle(cell) << access << mangle_wire_name(conn.first);
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
if (!is_cxxrtl_blackbox_cell(cell) && wire_types[cell_module_wire].is_buffered()) {
buffered_inputs = true;
f << ".next";
}
f << " = ";
dump_sigspec_rhs(conn.second);
f << ";\n";
if (getenv("CXXRTL_VOID_MY_WARRANTY") && conn.second.is_wire()) {
// Until we have proper clock tree detection, this really awful hack that opportunistically
// propagates prev_* values for clocks can be used to estimate how much faster a design could
// be if only one clock edge was simulated by replacing:
// top.p_clk = value<1>{0u}; top.step();
// top.p_clk = value<1>{1u}; top.step();
// with:
// top.prev_p_clk = value<1>{0u}; top.p_clk = value<1>{1u}; top.step();
// Don't rely on this; it will be removed without warning.
if (edge_wires[conn.second.as_wire()] && edge_wires[cell_module_wire]) {
f << indent << mangle(cell) << access << "prev_" << mangle(cell_module_wire) << " = ";
f << "prev_" << mangle(conn.second.as_wire()) << ";\n";
}
}
}
auto assign_from_outputs = [&](bool cell_converged) {
for (auto conn : cell->connections()) {
if (cell->output(conn.first)) {
if (conn.second.empty())
continue; // ignore disconnected ports
if (is_cxxrtl_sync_port(cell, conn.first))
continue; // fully sync ports are handled in CELL_SYNC nodes
f << indent;
dump_sigspec_lhs(conn.second);
f << " = " << mangle(cell) << access << mangle_wire_name(conn.first);
// Similarly to how there is no purpose to buffering cell inputs, there is also no purpose to buffering
// combinatorial cell outputs in case the cell converges within one cycle. (To convince yourself that
// this optimization is valid, consider that, since the cell converged within one cycle, it would not
// have any buffered wires if they were not output ports. Imagine inlining the cell's eval() function,
// and consider the fate of the localized wires that used to be output ports.)
//
// It is not possible to know apriori whether the cell (which may be late bound) will converge immediately.
// Because of this, the choice between using .curr (appropriate for buffered outputs) and .next (appropriate
// for unbuffered outputs) is made at runtime.
if (cell_converged && is_cxxrtl_comb_port(cell, conn.first))
f << ".next;\n";
else
f << ".curr;\n";
}
}
};
if (buffered_inputs) {
// If we have any buffered inputs, there's no chance of converging immediately.
f << indent << mangle(cell) << access << "eval();\n";
f << indent << "converged = false;\n";
assign_from_outputs(/*cell_converged=*/false);
} else {
f << indent << "if (" << mangle(cell) << access << "eval()) {\n";
inc_indent();
assign_from_outputs(/*cell_converged=*/true);
dec_indent();
f << indent << "} else {\n";
inc_indent();
f << indent << "converged = false;\n";
assign_from_outputs(/*cell_converged=*/false);
dec_indent();
f << indent << "}\n";
}
}
}
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
void collect_cell_eval(const RTLIL::Cell *cell, bool for_debug, std::vector<const RTLIL::Cell*> &cells)
{
cells.push_back(cell);
for (auto port : cell->connections())
if (cell->input(port.first))
collect_sigspec_rhs(port.second, for_debug, cells);
}
void dump_assign(const RTLIL::SigSig &sigsig, bool for_debug = false)
{
f << indent;
dump_sigspec_lhs(sigsig.first, for_debug);
f << " = ";
dump_sigspec_rhs(sigsig.second, for_debug);
f << ";\n";
}
void dump_case_rule(const RTLIL::CaseRule *rule, bool for_debug = false)
{
for (auto action : rule->actions)
dump_assign(action, for_debug);
for (auto switch_ : rule->switches)
dump_switch_rule(switch_, for_debug);
}
void dump_switch_rule(const RTLIL::SwitchRule *rule, bool for_debug = false)
{
// The switch attributes are printed before the switch condition is captured.
dump_attrs(rule);
std::string signal_temp = fresh_temporary();
f << indent << "const value<" << rule->signal.size() << "> &" << signal_temp << " = ";
dump_sigspec(rule->signal, /*is_lhs=*/false, for_debug);
f << ";\n";
bool first = true;
for (auto case_ : rule->cases) {
// The case attributes (for nested cases) are printed before the if/else if/else statement.
dump_attrs(rule);
f << indent;
if (!first)
f << "} else ";
first = false;
if (!case_->compare.empty()) {
f << "if (";
bool first = true;
for (auto &compare : case_->compare) {
if (!first)
f << " || ";
first = false;
if (compare.is_fully_def()) {
f << signal_temp << " == ";
dump_sigspec(compare, /*is_lhs=*/false, for_debug);
} else if (compare.is_fully_const()) {
RTLIL::Const compare_mask, compare_value;
for (auto bit : compare.as_const()) {
switch (bit) {
case RTLIL::S0:
case RTLIL::S1:
compare_mask.bits.push_back(RTLIL::S1);
compare_value.bits.push_back(bit);
break;
case RTLIL::Sx:
case RTLIL::Sz:
case RTLIL::Sa:
compare_mask.bits.push_back(RTLIL::S0);
compare_value.bits.push_back(RTLIL::S0);
break;
default:
log_assert(false);
}
}
f << "and_uu<" << compare.size() << ">(" << signal_temp << ", ";
dump_const(compare_mask);
f << ") == ";
dump_const(compare_value);
} else {
log_assert(false);
}
}
f << ") ";
}
f << "{\n";
inc_indent();
dump_case_rule(case_, for_debug);
dec_indent();
}
f << indent << "}\n";
}
void dump_process_case(const RTLIL::Process *proc, bool for_debug = false)
{
dump_attrs(proc);
f << indent << "// process " << proc->name.str() << " case\n";
// The case attributes (for root case) are always empty.
log_assert(proc->root_case.attributes.empty());
dump_case_rule(&proc->root_case, for_debug);
}
void dump_process_syncs(const RTLIL::Process *proc, bool for_debug = false)
{
dump_attrs(proc);
f << indent << "// process " << proc->name.str() << " syncs\n";
for (auto sync : proc->syncs) {
log_assert(!for_debug || sync->type == RTLIL::STa);
RTLIL::SigBit sync_bit;
if (!sync->signal.empty()) {
sync_bit = sync->signal[0];
sync_bit = sigmaps[sync_bit.wire->module](sync_bit);
if (!sync_bit.is_wire())
continue; // a clock, or more commonly a reset, can be tied to a constant driver
}
pool<std::string> events;
switch (sync->type) {
case RTLIL::STp:
log_assert(sync_bit.wire != nullptr);
events.insert("posedge_" + mangle(sync_bit));
break;
case RTLIL::STn:
log_assert(sync_bit.wire != nullptr);
events.insert("negedge_" + mangle(sync_bit));
break;
case RTLIL::STe:
log_assert(sync_bit.wire != nullptr);
events.insert("posedge_" + mangle(sync_bit));
events.insert("negedge_" + mangle(sync_bit));
break;
case RTLIL::STa:
events.insert("true");
break;
case RTLIL::ST0:
case RTLIL::ST1:
case RTLIL::STg:
case RTLIL::STi:
log_assert(false);
}
if (!events.empty()) {
f << indent << "if (";
bool first = true;
for (auto &event : events) {
if (!first)
f << " || ";
first = false;
f << event;
}
f << ") {\n";
inc_indent();
for (auto &action : sync->actions)
dump_assign(action, for_debug);
for (auto &memwr : sync->mem_write_actions) {
RTLIL::Memory *memory = proc->module->memories.at(memwr.memid);
std::string valid_index_temp = fresh_temporary();
f << indent << "auto " << valid_index_temp << " = memory_index(";
dump_sigspec_rhs(memwr.address);
f << ", " << memory->start_offset << ", " << memory->size << ");\n";
// See below for rationale of having both the assert and the condition.
//
// If assertions are disabled, out of bounds writes are defined to do nothing.
f << indent << "CXXRTL_ASSERT(" << valid_index_temp << ".valid && \"out of bounds write\");\n";
f << indent << "if (" << valid_index_temp << ".valid) {\n";
inc_indent();
f << indent << mangle(memory) << ".update(" << valid_index_temp << ".index, ";
dump_sigspec_rhs(memwr.data);
f << ", ";
dump_sigspec_rhs(memwr.enable);
f << ");\n";
dec_indent();
f << indent << "}\n";
}
dec_indent();
f << indent << "}\n";
}
}
}
void dump_mem_rdport(const Mem *mem, int portidx, bool for_debug = false)
{
auto &port = mem->rd_ports[portidx];
dump_attrs(&port);
f << indent << "// memory " << mem->memid.str() << " read port " << portidx << "\n";
if (port.clk_enable) {
log_assert(!for_debug);
RTLIL::SigBit clk_bit = port.clk[0];
clk_bit = sigmaps[clk_bit.wire->module](clk_bit);
if (clk_bit.wire) {
f << indent << "if (" << (port.clk_polarity ? "posedge_" : "negedge_")
<< mangle(clk_bit) << ") {\n";
} else {
f << indent << "if (false) {\n";
}
inc_indent();
}
std::vector<const RTLIL::Cell*> inlined_cells_addr;
collect_sigspec_rhs(port.addr, for_debug, inlined_cells_addr);
if (!inlined_cells_addr.empty())
dump_inlined_cells(inlined_cells_addr);
std::string valid_index_temp = fresh_temporary();
f << indent << "auto " << valid_index_temp << " = memory_index(";
// Almost all non-elidable cells cannot appear in debug_eval(), but $memrd is an exception; asynchronous
// memory read ports can.
dump_sigspec_rhs(port.addr, for_debug);
f << ", " << mem->start_offset << ", " << mem->size << ");\n";
bool has_enable = port.clk_enable && !port.en.is_fully_ones();
if (has_enable) {
std::vector<const RTLIL::Cell*> inlined_cells_en;
collect_sigspec_rhs(port.en, for_debug, inlined_cells_en);
if (!inlined_cells_en.empty())
dump_inlined_cells(inlined_cells_en);
f << indent << "if (";
dump_sigspec_rhs(port.en);
f << ") {\n";
inc_indent();
}
// The generated code has two bounds checks; one in an assertion, and another that guards the read.
// This is done so that the code does not invoke undefined behavior under any conditions, but nevertheless
// loudly crashes if an illegal condition is encountered. The assert may be turned off with -DCXXRTL_NDEBUG
// not only for release builds, but also to make sure the simulator (which is presumably embedded in some
// larger program) will never crash the code that calls into it.
//
// If assertions are disabled, out of bounds reads are defined to return zero.
f << indent << "CXXRTL_ASSERT(" << valid_index_temp << ".valid && \"out of bounds read\");\n";
f << indent << "if(" << valid_index_temp << ".valid) {\n";
inc_indent();
if (!mem->wr_ports.empty()) {
std::string lhs_temp = fresh_temporary();
f << indent << "value<" << mem->width << "> " << lhs_temp << " = "
<< mangle(mem) << "[" << valid_index_temp << ".index];\n";
bool transparent = false;
for (auto bit : port.transparency_mask)
if (bit)
transparent = true;
if (transparent) {
std::string addr_temp = fresh_temporary();
f << indent << "const value<" << port.addr.size() << "> &" << addr_temp << " = ";
dump_sigspec_rhs(port.addr);
f << ";\n";
for (int i = 0; i < GetSize(mem->wr_ports); i++) {
auto &wrport = mem->wr_ports[i];
if (!port.transparency_mask[i])
continue;
f << indent << "if (" << addr_temp << " == ";
dump_sigspec_rhs(wrport.addr);
f << ") {\n";
inc_indent();
f << indent << lhs_temp << " = " << lhs_temp;
f << ".update(";
dump_sigspec_rhs(wrport.data);
f << ", ";
dump_sigspec_rhs(wrport.en);
f << ");\n";
dec_indent();
f << indent << "}\n";
}
}
f << indent;
dump_sigspec_lhs(port.data);
f << " = " << lhs_temp << ";\n";
} else {
f << indent;
dump_sigspec_lhs(port.data);
f << " = " << mangle(mem) << "[" << valid_index_temp << ".index];\n";
}
dec_indent();
f << indent << "} else {\n";
inc_indent();
f << indent;
dump_sigspec_lhs(port.data);
f << " = value<" << mem->width << "> {};\n";
dec_indent();
f << indent << "}\n";
if (has_enable && !port.ce_over_srst) {
dec_indent();
f << indent << "}\n";
}
if (port.srst != State::S0) {
// Synchronous reset
std::vector<const RTLIL::Cell*> inlined_cells_srst;
collect_sigspec_rhs(port.srst, for_debug, inlined_cells_srst);
if (!inlined_cells_srst.empty())
dump_inlined_cells(inlined_cells_srst);
f << indent << "if (";
dump_sigspec_rhs(port.srst);
f << " == value<1> {1u}) {\n";
inc_indent();
f << indent;
dump_sigspec_lhs(port.data);
f << " = ";
dump_const(port.srst_value);
f << ";\n";
dec_indent();
f << indent << "}\n";
}
if (has_enable && port.ce_over_srst) {
dec_indent();
f << indent << "}\n";
}
if (port.clk_enable) {
dec_indent();
f << indent << "}\n";
}
if (port.arst != State::S0) {
// Asynchronous reset
std::vector<const RTLIL::Cell*> inlined_cells_arst;
collect_sigspec_rhs(port.arst, for_debug, inlined_cells_arst);
if (!inlined_cells_arst.empty())
dump_inlined_cells(inlined_cells_arst);
f << indent << "if (";
dump_sigspec_rhs(port.arst);
f << " == value<1> {1u}) {\n";
inc_indent();
f << indent;
dump_sigspec_lhs(port.data);
f << " = ";
dump_const(port.arst_value);
f << ";\n";
dec_indent();
f << indent << "}\n";
}
}
void dump_mem_wrports(const Mem *mem, bool for_debug = false)
{
log_assert(!for_debug);
for (int portidx = 0; portidx < GetSize(mem->wr_ports); portidx++) {
auto &port = mem->wr_ports[portidx];
dump_attrs(&port);
f << indent << "// memory " << mem->memid.str() << " write port " << portidx << "\n";
if (port.clk_enable) {
RTLIL::SigBit clk_bit = port.clk[0];
clk_bit = sigmaps[clk_bit.wire->module](clk_bit);
if (clk_bit.wire) {
f << indent << "if (" << (port.clk_polarity ? "posedge_" : "negedge_")
<< mangle(clk_bit) << ") {\n";
} else {
f << indent << "if (false) {\n";
}
inc_indent();
}
std::vector<const RTLIL::Cell*> inlined_cells_addr;
collect_sigspec_rhs(port.addr, for_debug, inlined_cells_addr);
if (!inlined_cells_addr.empty())
dump_inlined_cells(inlined_cells_addr);
std::string valid_index_temp = fresh_temporary();
f << indent << "auto " << valid_index_temp << " = memory_index(";
dump_sigspec_rhs(port.addr);
f << ", " << mem->start_offset << ", " << mem->size << ");\n";
// See above for rationale of having both the assert and the condition.
//
// If assertions are disabled, out of bounds writes are defined to do nothing.
f << indent << "CXXRTL_ASSERT(" << valid_index_temp << ".valid && \"out of bounds write\");\n";
f << indent << "if (" << valid_index_temp << ".valid) {\n";
inc_indent();
std::vector<const RTLIL::Cell*> inlined_cells;
collect_sigspec_rhs(port.data, for_debug, inlined_cells);
collect_sigspec_rhs(port.en, for_debug, inlined_cells);
if (!inlined_cells.empty())
dump_inlined_cells(inlined_cells);
f << indent << mangle(mem) << ".update(" << valid_index_temp << ".index, ";
dump_sigspec_rhs(port.data);
f << ", ";
dump_sigspec_rhs(port.en);
f << ", " << portidx << ");\n";
dec_indent();
f << indent << "}\n";
if (port.clk_enable) {
dec_indent();
f << indent << "}\n";
}
}
}
void dump_wire(const RTLIL::Wire *wire, bool is_local)
{
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
const auto &wire_type = wire_types[wire];
if (!wire_type.is_named() || wire_type.is_local() != is_local)
return;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
dump_attrs(wire);
f << indent;
if (wire->port_input && wire->port_output)
f << "/*inout*/ ";
else if (wire->port_input)
f << "/*input*/ ";
else if (wire->port_output)
f << "/*output*/ ";
f << (wire_type.is_buffered() ? "wire" : "value");
if (wire->module->has_attribute(ID(cxxrtl_blackbox)) && wire->has_attribute(ID(cxxrtl_width))) {
f << "<" << wire->get_string_attribute(ID(cxxrtl_width)) << ">";
} else {
f << "<" << wire->width << ">";
}
f << " " << mangle(wire) << ";\n";
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
if (edge_wires[wire]) {
if (!wire_type.is_buffered()) {
f << indent << "value<" << wire->width << "> prev_" << mangle(wire) << ";\n";
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
}
for (auto edge_type : edge_types) {
if (edge_type.first.wire == wire) {
std::string prev, next;
if (!wire_type.is_buffered()) {
prev = "prev_" + mangle(edge_type.first.wire);
next = mangle(edge_type.first.wire);
} else {
prev = mangle(edge_type.first.wire) + ".curr";
next = mangle(edge_type.first.wire) + ".next";
}
prev += ".slice<" + std::to_string(edge_type.first.offset) + ">().val()";
next += ".slice<" + std::to_string(edge_type.first.offset) + ">().val()";
if (edge_type.second != RTLIL::STn) {
f << indent << "bool posedge_" << mangle(edge_type.first) << "() const {\n";
inc_indent();
f << indent << "return !" << prev << " && " << next << ";\n";
dec_indent();
f << indent << "}\n";
}
if (edge_type.second != RTLIL::STp) {
f << indent << "bool negedge_" << mangle(edge_type.first) << "() const {\n";
inc_indent();
f << indent << "return " << prev << " && !" << next << ";\n";
dec_indent();
f << indent << "}\n";
}
}
}
}
}
void dump_debug_wire(const RTLIL::Wire *wire, bool is_local)
{
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
const auto &wire_type = wire_types[wire];
if (wire_type.is_member())
return;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
const auto &debug_wire_type = debug_wire_types[wire];
if (!debug_wire_type.is_named() || debug_wire_type.is_local() != is_local)
return;
dump_attrs(wire);
f << indent;
if (debug_wire_type.is_outline())
f << "/*outline*/ ";
f << "value<" << wire->width << "> " << mangle(wire) << ";\n";
}
void dump_reset_method(RTLIL::Module *module)
{
int mem_init_idx = 0;
inc_indent();
for (auto wire : module->wires()) {
const auto &wire_type = wire_types[wire];
if (!wire_type.is_named() || wire_type.is_local()) continue;
if (!wire_init.count(wire)) continue;
f << indent << mangle(wire) << " = ";
if (wire_types[wire].is_buffered()) {
f << "wire<" << wire->width << ">";
} else {
f << "value<" << wire->width << ">";
}
dump_const_init(wire_init.at(wire), wire->width);
f << ";\n";
if (edge_wires[wire] && !wire_types[wire].is_buffered()) {
f << indent << "prev_" << mangle(wire) << " = ";
dump_const(wire_init.at(wire), wire->width);
f << ";\n";
}
}
for (auto &mem : mod_memories[module]) {
for (auto &init : mem.inits) {
if (init.removed)
continue;
dump_attrs(&init);
int words = GetSize(init.data) / mem.width;
f << indent << "static const value<" << mem.width << "> ";
f << "mem_init_" << ++mem_init_idx << "[" << words << "] {";
inc_indent();
for (int n = 0; n < words; n++) {
if (n % 4 == 0)
f << "\n" << indent;
else
f << " ";
dump_const(init.data, mem.width, n * mem.width, /*fixed_width=*/true);
f << ",";
}
dec_indent();
f << "\n";
f << indent << "};\n";
f << indent << "std::copy(std::begin(mem_init_" << mem_init_idx << "), ";
f << "std::end(mem_init_" << mem_init_idx << "), ";
f << "&" << mangle(&mem) << ".data[" << stringf("%#x", init.addr.as_int()) << "]);\n";
}
}
for (auto cell : module->cells()) {
if (is_internal_cell(cell->type))
continue;
f << indent << mangle(cell);
RTLIL::Module *cell_module = module->design->module(cell->type);
if (cell_module->get_bool_attribute(ID(cxxrtl_blackbox))) {
f << "->reset();\n";
} else {
f << ".reset();\n";
}
}
dec_indent();
}
void dump_eval_method(RTLIL::Module *module)
{
inc_indent();
f << indent << "bool converged = " << (eval_converges.at(module) ? "true" : "false") << ";\n";
if (!module->get_bool_attribute(ID(cxxrtl_blackbox))) {
for (auto wire : module->wires()) {
if (edge_wires[wire]) {
for (auto edge_type : edge_types) {
if (edge_type.first.wire == wire) {
if (edge_type.second != RTLIL::STn) {
f << indent << "bool posedge_" << mangle(edge_type.first) << " = ";
f << "this->posedge_" << mangle(edge_type.first) << "();\n";
}
if (edge_type.second != RTLIL::STp) {
f << indent << "bool negedge_" << mangle(edge_type.first) << " = ";
f << "this->negedge_" << mangle(edge_type.first) << "();\n";
}
}
}
}
}
for (auto wire : module->wires())
dump_wire(wire, /*is_local=*/true);
for (auto node : schedule[module]) {
switch (node.type) {
case FlowGraph::Node::Type::CONNECT:
dump_connect(node.connect);
break;
case FlowGraph::Node::Type::CELL_SYNC:
dump_cell_sync(node.cell);
break;
case FlowGraph::Node::Type::CELL_EVAL:
dump_cell_eval(node.cell);
break;
case FlowGraph::Node::Type::PRINT_SYNC:
dump_sync_print(node.print_sync_cells);
break;
case FlowGraph::Node::Type::PROCESS_CASE:
dump_process_case(node.process);
break;
case FlowGraph::Node::Type::PROCESS_SYNC:
dump_process_syncs(node.process);
break;
case FlowGraph::Node::Type::MEM_RDPORT:
dump_mem_rdport(node.mem, node.portidx);
break;
case FlowGraph::Node::Type::MEM_WRPORTS:
dump_mem_wrports(node.mem);
break;
}
}
}
f << indent << "return converged;\n";
dec_indent();
}
void dump_debug_eval_method(RTLIL::Module *module)
{
inc_indent();
for (auto wire : module->wires())
dump_debug_wire(wire, /*is_local=*/true);
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
for (auto node : debug_schedule[module]) {
switch (node.type) {
case FlowGraph::Node::Type::CONNECT:
dump_connect(node.connect, /*for_debug=*/true);
break;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
case FlowGraph::Node::Type::CELL_SYNC:
dump_cell_sync(node.cell, /*for_debug=*/true);
break;
case FlowGraph::Node::Type::CELL_EVAL:
dump_cell_eval(node.cell, /*for_debug=*/true);
break;
case FlowGraph::Node::Type::PROCESS_CASE:
dump_process_case(node.process, /*for_debug=*/true);
break;
case FlowGraph::Node::Type::PROCESS_SYNC:
dump_process_syncs(node.process, /*for_debug=*/true);
break;
case FlowGraph::Node::Type::MEM_RDPORT:
dump_mem_rdport(node.mem, node.portidx, /*for_debug=*/true);
break;
case FlowGraph::Node::Type::MEM_WRPORTS:
dump_mem_wrports(node.mem, /*for_debug=*/true);
break;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
default:
log_abort();
}
}
dec_indent();
}
void dump_commit_method(RTLIL::Module *module)
{
inc_indent();
f << indent << "bool changed = false;\n";
for (auto wire : module->wires()) {
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
const auto &wire_type = wire_types[wire];
if (wire_type.type == WireType::MEMBER && edge_wires[wire])
f << indent << "prev_" << mangle(wire) << " = " << mangle(wire) << ";\n";
if (wire_type.is_buffered())
f << indent << "if (" << mangle(wire) << ".commit()) changed = true;\n";
}
if (!module->get_bool_attribute(ID(cxxrtl_blackbox))) {
for (auto &mem : mod_memories[module]) {
if (!writable_memories.count({module, mem.memid}))
continue;
f << indent << "if (" << mangle(&mem) << ".commit()) changed = true;\n";
}
for (auto cell : module->cells()) {
if (is_internal_cell(cell->type))
continue;
const char *access = is_cxxrtl_blackbox_cell(cell) ? "->" : ".";
f << indent << "if (" << mangle(cell) << access << "commit()) changed = true;\n";
}
}
f << indent << "return changed;\n";
dec_indent();
}
void dump_debug_info_method(RTLIL::Module *module)
{
size_t count_public_wires = 0;
size_t count_member_wires = 0;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
size_t count_undriven = 0;
size_t count_driven_sync = 0;
size_t count_driven_comb = 0;
size_t count_mixed_driver = 0;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
size_t count_alias_wires = 0;
size_t count_const_wires = 0;
size_t count_inline_wires = 0;
size_t count_skipped_wires = 0;
inc_indent();
f << indent << "assert(path.empty() || path[path.size() - 1] == ' ');\n";
for (auto wire : module->wires()) {
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
const auto &debug_wire_type = debug_wire_types[wire];
2020-12-12 18:54:12 -06:00
if (!wire->name.isPublic())
continue;
count_public_wires++;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
switch (debug_wire_type.type) {
case WireType::BUFFERED:
case WireType::MEMBER: {
// Member wire
std::vector<std::string> flags;
if (wire->port_input && wire->port_output)
flags.push_back("INOUT");
else if (wire->port_output)
flags.push_back("OUTPUT");
else if (wire->port_input)
flags.push_back("INPUT");
bool has_driven_sync = false;
bool has_driven_comb = false;
bool has_undriven = false;
if (!module->get_bool_attribute(ID(cxxrtl_blackbox))) {
for (auto bit : SigSpec(wire))
if (!bit_has_state.count(bit))
has_undriven = true;
else if (bit_has_state[bit])
has_driven_sync = true;
else
has_driven_comb = true;
} else if (wire->port_output) {
switch (cxxrtl_port_type(module, wire->name)) {
case CxxrtlPortType::SYNC:
has_driven_sync = true;
break;
case CxxrtlPortType::COMB:
has_driven_comb = true;
break;
case CxxrtlPortType::UNKNOWN:
has_driven_sync = has_driven_comb = true;
break;
}
} else {
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
has_undriven = true;
}
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
if (has_undriven)
flags.push_back("UNDRIVEN");
if (!has_driven_sync && !has_driven_comb && has_undriven)
count_undriven++;
if (has_driven_sync)
flags.push_back("DRIVEN_SYNC");
if (has_driven_sync && !has_driven_comb && !has_undriven)
count_driven_sync++;
if (has_driven_comb)
flags.push_back("DRIVEN_COMB");
if (!has_driven_sync && has_driven_comb && !has_undriven)
count_driven_comb++;
if (has_driven_sync + has_driven_comb + has_undriven > 1)
count_mixed_driver++;
f << indent << "items.add(path + " << escape_cxx_string(get_hdl_name(wire));
f << ", debug_item(" << mangle(wire) << ", " << wire->start_offset;
bool first = true;
for (auto flag : flags) {
if (first) {
first = false;
f << ", ";
} else {
f << "|";
}
f << "debug_item::" << flag;
}
f << "));\n";
count_member_wires++;
break;
}
case WireType::ALIAS: {
// Alias of a member wire
const RTLIL::Wire *aliasee = debug_wire_type.sig_subst.as_wire();
f << indent << "items.add(path + " << escape_cxx_string(get_hdl_name(wire));
f << ", debug_item(";
// If the aliasee is an outline, then the alias must be an outline, too; otherwise downstream
// tooling has no way to find out about the outline.
if (debug_wire_types[aliasee].is_outline())
f << "debug_eval_outline";
else
f << "debug_alias()";
f << ", " << mangle(aliasee) << ", " << wire->start_offset << "));\n";
count_alias_wires++;
break;
}
case WireType::CONST: {
// Wire tied to a constant
f << indent << "static const value<" << wire->width << "> const_" << mangle(wire) << " = ";
dump_const(debug_wire_type.sig_subst.as_const());
f << ";\n";
f << indent << "items.add(path + " << escape_cxx_string(get_hdl_name(wire));
f << ", debug_item(const_" << mangle(wire) << ", " << wire->start_offset << "));\n";
count_const_wires++;
break;
}
case WireType::OUTLINE: {
// Localized or inlined, but rematerializable wire
f << indent << "items.add(path + " << escape_cxx_string(get_hdl_name(wire));
f << ", debug_item(debug_eval_outline, " << mangle(wire) << ", " << wire->start_offset << "));\n";
count_inline_wires++;
break;
}
default: {
// Localized or inlined wire with no debug information
count_skipped_wires++;
break;
}
}
}
if (!module->get_bool_attribute(ID(cxxrtl_blackbox))) {
for (auto &mem : mod_memories[module]) {
if (!mem.memid.isPublic())
continue;
f << indent << "items.add(path + " << escape_cxx_string(mem.packed ? get_hdl_name(mem.cell) : get_hdl_name(mem.mem));
f << ", debug_item(" << mangle(&mem) << ", ";
f << mem.start_offset << "));\n";
}
for (auto cell : module->cells()) {
if (is_internal_cell(cell->type))
continue;
const char *access = is_cxxrtl_blackbox_cell(cell) ? "->" : ".";
f << indent << mangle(cell) << access << "debug_info(items, ";
f << "path + " << escape_cxx_string(get_hdl_name(cell) + ' ') << ");\n";
}
}
dec_indent();
log_debug("Debug information statistics for module `%s':\n", log_id(module));
log_debug(" Public wires: %zu, of which:\n", count_public_wires);
log_debug(" Member wires: %zu, of which:\n", count_member_wires);
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
log_debug(" Undriven: %zu (incl. inputs)\n", count_undriven);
log_debug(" Driven sync: %zu\n", count_driven_sync);
log_debug(" Driven comb: %zu\n", count_driven_comb);
log_debug(" Mixed driver: %zu\n", count_mixed_driver);
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
if (!module->get_bool_attribute(ID(cxxrtl_blackbox))) {
log_debug(" Inline wires: %zu\n", count_inline_wires);
log_debug(" Alias wires: %zu\n", count_alias_wires);
log_debug(" Const wires: %zu\n", count_const_wires);
log_debug(" Other wires: %zu%s\n", count_skipped_wires,
count_skipped_wires > 0 ? " (debug unavailable)" : "");
}
}
void dump_metadata_map(const dict<RTLIL::IdString, RTLIL::Const> &metadata_map)
{
if (metadata_map.empty()) {
f << "metadata_map()";
return;
}
f << "metadata_map({\n";
inc_indent();
for (auto metadata_item : metadata_map) {
if (!metadata_item.first.begins_with("\\"))
continue;
f << indent << "{ " << escape_cxx_string(metadata_item.first.str().substr(1)) << ", ";
if (metadata_item.second.flags & RTLIL::CONST_FLAG_REAL) {
f << std::showpoint << std::stod(metadata_item.second.decode_string()) << std::noshowpoint;
} else if (metadata_item.second.flags & RTLIL::CONST_FLAG_STRING) {
f << escape_cxx_string(metadata_item.second.decode_string());
} else {
f << metadata_item.second.as_int(/*is_signed=*/metadata_item.second.flags & RTLIL::CONST_FLAG_SIGNED);
if (!(metadata_item.second.flags & RTLIL::CONST_FLAG_SIGNED))
f << "u";
}
f << " },\n";
}
dec_indent();
f << indent << "})";
}
void dump_module_intf(RTLIL::Module *module)
{
dump_attrs(module);
if (module->get_bool_attribute(ID(cxxrtl_blackbox))) {
if (module->has_attribute(ID(cxxrtl_template)))
f << indent << "template" << template_params(module, /*is_decl=*/true) << "\n";
f << indent << "struct " << mangle(module) << " : public module {\n";
inc_indent();
for (auto wire : module->wires()) {
if (wire->port_id != 0)
dump_wire(wire, /*is_local=*/false);
}
f << "\n";
f << indent << "void reset() override {\n";
dump_reset_method(module);
f << indent << "}\n";
f << "\n";
f << indent << "bool eval() override {\n";
dump_eval_method(module);
f << indent << "}\n";
f << "\n";
f << indent << "bool commit() override {\n";
dump_commit_method(module);
f << indent << "}\n";
f << "\n";
if (debug_info) {
f << indent << "void debug_info(debug_items &items, std::string path = \"\") override {\n";
dump_debug_info_method(module);
f << indent << "}\n";
f << "\n";
}
f << indent << "static std::unique_ptr<" << mangle(module);
f << template_params(module, /*is_decl=*/false) << "> ";
f << "create(std::string name, metadata_map parameters, metadata_map attributes);\n";
dec_indent();
f << indent << "}; // struct " << mangle(module) << "\n";
f << "\n";
if (blackbox_specializations.count(module)) {
// If templated black boxes are used, the constructor of any module which includes the black box cell
// (which calls the declared but not defined in the generated code `create` function) may only be used
// if (a) the create function is defined in the same translation unit, or (b) the create function has
// a forward-declared explicit specialization.
//
// Option (b) makes it possible to have the generated code and the black box implementation in different
// translation units, which is convenient. Of course, its downside is that black boxes must predefine
// a specialization for every combination of parameters the generated code may use; but since the main
// purpose of templated black boxes is abstracting over datapath width, it is expected that there would
// be very few such combinations anyway.
for (auto specialization : blackbox_specializations[module]) {
f << indent << "template<>\n";
f << indent << "std::unique_ptr<" << mangle(module) << specialization << "> ";
f << mangle(module) << specialization << "::";
f << "create(std::string name, metadata_map parameters, metadata_map attributes);\n";
f << "\n";
}
}
} else {
f << indent << "struct " << mangle(module) << " : public module {\n";
inc_indent();
for (auto wire : module->wires())
dump_wire(wire, /*is_local=*/false);
for (auto wire : module->wires())
dump_debug_wire(wire, /*is_local=*/false);
bool has_memories = false;
for (auto &mem : mod_memories[module]) {
dump_attrs(&mem);
f << indent << "memory<" << mem.width << "> " << mangle(&mem)
<< " { " << mem.size << "u };\n";
has_memories = true;
}
if (has_memories)
f << "\n";
bool has_cells = false;
for (auto cell : module->cells()) {
if (cell->type == ID($print) && !cell->getParam(ID::TRG_ENABLE).as_bool()) {
// comb $print cell -- store the last EN/ARGS values to know when they change.
dump_attrs(cell);
f << indent << "value<" << (1 + cell->getParam(ID::ARGS_WIDTH).as_int()) << "> " << mangle(cell) << ";\n";
}
if (is_internal_cell(cell->type))
continue;
dump_attrs(cell);
RTLIL::Module *cell_module = module->design->module(cell->type);
log_assert(cell_module != nullptr);
if (cell_module->get_bool_attribute(ID(cxxrtl_blackbox))) {
f << indent << "std::unique_ptr<" << mangle(cell_module) << template_args(cell) << "> ";
f << mangle(cell) << " = " << mangle(cell_module) << template_args(cell);
f << "::create(" << escape_cxx_string(get_hdl_name(cell)) << ", ";
dump_metadata_map(cell->parameters);
f << ", ";
dump_metadata_map(cell->attributes);
f << ");\n";
} else {
f << indent << mangle(cell_module) << " " << mangle(cell) << " {interior()};\n";
}
has_cells = true;
}
if (has_cells)
f << "\n";
f << indent << mangle(module) << "(interior) {}\n";
f << indent << mangle(module) << "() {\n";
inc_indent();
f << indent << "reset();\n";
dec_indent();
f << indent << "};\n";
f << "\n";
f << indent << "void reset() override;\n";
f << indent << "bool eval() override;\n";
f << indent << "bool commit() override;\n";
if (debug_info) {
if (debug_eval) {
f << "\n";
f << indent << "void debug_eval();\n";
for (auto wire : module->wires())
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
if (debug_wire_types[wire].is_outline()) {
f << indent << "debug_outline debug_eval_outline { std::bind(&"
<< mangle(module) << "::debug_eval, this) };\n";
break;
}
}
f << "\n";
f << indent << "void debug_info(debug_items &items, std::string path = \"\") override;\n";
}
dec_indent();
f << indent << "}; // struct " << mangle(module) << "\n";
f << "\n";
}
}
void dump_module_impl(RTLIL::Module *module)
{
if (module->get_bool_attribute(ID(cxxrtl_blackbox)))
return;
f << indent << "void " << mangle(module) << "::reset() {\n";
dump_reset_method(module);
f << indent << "}\n";
f << "\n";
f << indent << "bool " << mangle(module) << "::eval() {\n";
dump_eval_method(module);
f << indent << "}\n";
f << "\n";
f << indent << "bool " << mangle(module) << "::commit() {\n";
dump_commit_method(module);
f << indent << "}\n";
f << "\n";
if (debug_info) {
if (debug_eval) {
f << indent << "void " << mangle(module) << "::debug_eval() {\n";
dump_debug_eval_method(module);
f << indent << "}\n";
f << "\n";
}
f << indent << "CXXRTL_EXTREMELY_COLD\n";
f << indent << "void " << mangle(module) << "::debug_info(debug_items &items, std::string path) {\n";
dump_debug_info_method(module);
f << indent << "}\n";
f << "\n";
}
}
void dump_design(RTLIL::Design *design)
{
RTLIL::Module *top_module = nullptr;
std::vector<RTLIL::Module*> modules;
TopoSort<RTLIL::Module*> topo_design;
bool has_prints = false;
for (auto module : design->modules()) {
if (!design->selected_module(module))
continue;
if (module->get_bool_attribute(ID(cxxrtl_blackbox)))
modules.push_back(module); // cxxrtl blackboxes first
if (module->get_blackbox_attribute() || module->get_bool_attribute(ID(cxxrtl_blackbox)))
continue;
if (module->get_bool_attribute(ID::top))
top_module = module;
topo_design.node(module);
for (auto cell : module->cells()) {
if (cell->type == ID($print))
has_prints = true;
if (is_internal_cell(cell->type) || is_cxxrtl_blackbox_cell(cell))
continue;
RTLIL::Module *cell_module = design->module(cell->type);
log_assert(cell_module != nullptr);
topo_design.edge(cell_module, module);
}
}
bool no_loops = topo_design.sort();
log_assert(no_loops);
modules.insert(modules.end(), topo_design.sorted.begin(), topo_design.sorted.end());
if (split_intf) {
// The only thing more depraved than include guards, is mangling filenames to turn them into include guards.
std::string include_guard = design_ns + "_header";
std::transform(include_guard.begin(), include_guard.end(), include_guard.begin(), ::toupper);
f << "#ifndef " << include_guard << "\n";
f << "#define " << include_guard << "\n";
f << "\n";
if (top_module != nullptr && debug_info) {
f << "#include <backends/cxxrtl/cxxrtl_capi.h>\n";
f << "\n";
f << "#ifdef __cplusplus\n";
f << "extern \"C\" {\n";
f << "#endif\n";
f << "\n";
f << "cxxrtl_toplevel " << design_ns << "_create();\n";
f << "\n";
f << "#ifdef __cplusplus\n";
f << "}\n";
f << "#endif\n";
f << "\n";
} else {
f << "// The CXXRTL C API is not available because the design is built without debug information.\n";
f << "\n";
}
f << "#ifdef __cplusplus\n";
f << "\n";
f << "#include <backends/cxxrtl/cxxrtl.h>\n";
f << "\n";
f << "using namespace cxxrtl;\n";
f << "\n";
f << "namespace " << design_ns << " {\n";
f << "\n";
for (auto module : modules)
dump_module_intf(module);
f << "} // namespace " << design_ns << "\n";
f << "\n";
f << "#endif // __cplusplus\n";
f << "\n";
f << "#endif\n";
*intf_f << f.str(); f.str("");
}
if (split_intf)
f << "#include \"" << intf_filename << "\"\n";
else
f << "#include <backends/cxxrtl/cxxrtl.h>\n";
if (has_prints)
f << "#include <iostream>\n";
f << "\n";
f << "#if defined(CXXRTL_INCLUDE_CAPI_IMPL) || \\\n";
f << " defined(CXXRTL_INCLUDE_VCD_CAPI_IMPL)\n";
f << "#include <backends/cxxrtl/cxxrtl_capi.cc>\n";
f << "#endif\n";
f << "\n";
f << "#if defined(CXXRTL_INCLUDE_VCD_CAPI_IMPL)\n";
f << "#include <backends/cxxrtl/cxxrtl_vcd_capi.cc>\n";
f << "#endif\n";
f << "\n";
f << "using namespace cxxrtl_yosys;\n";
f << "\n";
f << "namespace " << design_ns << " {\n";
f << "\n";
for (auto module : modules) {
if (!split_intf)
dump_module_intf(module);
dump_module_impl(module);
}
f << "} // namespace " << design_ns << "\n";
f << "\n";
if (top_module != nullptr && debug_info) {
f << "extern \"C\"\n";
f << "cxxrtl_toplevel " << design_ns << "_create() {\n";
inc_indent();
std::string top_type = design_ns + "::" + mangle(top_module);
f << indent << "return new _cxxrtl_toplevel { ";
f << "std::unique_ptr<" << top_type << ">(new " + top_type + ")";
f << " };\n";
dec_indent();
f << "}\n";
}
*impl_f << f.str(); f.str("");
}
// Edge-type sync rules require us to emit edge detectors, which require coordination between
// eval and commit phases. To do this we need to collect them upfront.
//
// Note that the simulator commit phase operates at wire granularity but edge-type sync rules
// operate at wire bit granularity; it is possible to have code similar to:
// wire [3:0] clocks;
// always @(posedge clocks[0]) ...
// To handle this we track edge sensitivity both for wires and wire bits.
void register_edge_signal(SigMap &sigmap, RTLIL::SigSpec signal, RTLIL::SyncType type)
{
signal = sigmap(signal);
if (signal.is_fully_const())
return; // a clock, or more commonly a reset, can be tied to a constant driver
log_assert(is_valid_clock(signal));
log_assert(type == RTLIL::STp || type == RTLIL::STn || type == RTLIL::STe);
RTLIL::SigBit sigbit = signal[0];
if (!edge_types.count(sigbit))
edge_types[sigbit] = type;
else if (edge_types[sigbit] != type)
edge_types[sigbit] = RTLIL::STe;
// Cannot use as_wire because signal might not be a full wire, instead extract the wire from the sigbit
edge_wires.insert(sigbit.wire);
}
void analyze_design(RTLIL::Design *design)
{
bool has_feedback_arcs = false;
bool has_buffered_comb_wires = false;
for (auto module : design->modules()) {
if (!design->selected_module(module))
continue;
SigMap &sigmap = sigmaps[module];
sigmap.set(module);
std::vector<Mem> &memories = mod_memories[module];
memories = Mem::get_all_memories(module);
for (auto &mem : memories) {
mem.narrow();
mem.coalesce_inits();
}
if (module->get_bool_attribute(ID(cxxrtl_blackbox))) {
for (auto port : module->ports) {
RTLIL::Wire *wire = module->wire(port);
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
if (wire->port_input && !wire->port_output) {
wire_types[wire] = debug_wire_types[wire] = {WireType::MEMBER};
} else if (wire->port_input || wire->port_output) {
wire_types[wire] = debug_wire_types[wire] = {WireType::BUFFERED};
}
if (wire->has_attribute(ID(cxxrtl_edge))) {
RTLIL::Const edge_attr = wire->attributes[ID(cxxrtl_edge)];
if (!(edge_attr.flags & RTLIL::CONST_FLAG_STRING) || (int)edge_attr.decode_string().size() != GetSize(wire))
log_cmd_error("Attribute `cxxrtl_edge' of port `%s.%s' is not a string with one character per bit.\n",
log_id(module), log_signal(wire));
std::string edges = wire->get_string_attribute(ID(cxxrtl_edge));
for (int i = 0; i < GetSize(wire); i++) {
RTLIL::SigSpec wire_sig = wire;
switch (edges[i]) {
case '-': break;
case 'p': register_edge_signal(sigmap, wire_sig[i], RTLIL::STp); break;
case 'n': register_edge_signal(sigmap, wire_sig[i], RTLIL::STn); break;
case 'a': register_edge_signal(sigmap, wire_sig[i], RTLIL::STe); break;
default:
log_cmd_error("Attribute `cxxrtl_edge' of port `%s.%s' contains specifiers "
"other than '-', 'p', 'n', or 'a'.\n",
log_id(module), log_signal(wire));
}
}
}
}
// Black boxes converge by default, since their implementations are quite unlikely to require
// internal propagation of comb signals.
eval_converges[module] = true;
continue;
}
for (auto wire : module->wires())
if (wire->has_attribute(ID::init))
wire_init[wire] = wire->attributes.at(ID::init);
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
// Construct a flow graph where each node is a basic computational operation generally corresponding
// to a fragment of the RTLIL netlist.
FlowGraph flow;
for (auto conn : module->connections())
flow.add_node(conn);
for (auto cell : module->cells()) {
if (!cell->known())
log_cmd_error("Unknown cell `%s'.\n", log_id(cell->type));
if (cell->is_mem_cell())
continue;
RTLIL::Module *cell_module = design->module(cell->type);
if (cell_module &&
cell_module->get_blackbox_attribute() &&
!cell_module->get_bool_attribute(ID(cxxrtl_blackbox)))
log_cmd_error("External blackbox cell `%s' is not marked as a CXXRTL blackbox.\n", log_id(cell->type));
if (cell_module &&
cell_module->get_bool_attribute(ID(cxxrtl_blackbox)) &&
cell_module->get_bool_attribute(ID(cxxrtl_template)))
blackbox_specializations[cell_module].insert(template_args(cell));
flow.add_node(cell);
// Various DFF cells are treated like posedge/negedge processes, see above for details.
if (cell->type.in(ID($dff), ID($dffe), ID($adff), ID($adffe), ID($aldff), ID($aldffe), ID($dffsr), ID($dffsre), ID($sdff), ID($sdffe), ID($sdffce))) {
if (is_valid_clock(cell->getPort(ID::CLK)))
register_edge_signal(sigmap, cell->getPort(ID::CLK),
cell->parameters[ID::CLK_POLARITY].as_bool() ? RTLIL::STp : RTLIL::STn);
}
2023-06-27 20:51:17 -05:00
// $print cells may be triggered on posedge/negedge events.
if (cell->type == ID($print) && cell->getParam(ID::TRG_ENABLE).as_bool()) {
for (size_t i = 0; i < (size_t)cell->getParam(ID::TRG_WIDTH).as_int(); i++) {
RTLIL::SigBit trg = cell->getPort(ID::TRG).extract(i, 1);
if (is_valid_clock(trg))
register_edge_signal(sigmap, trg,
cell->parameters[ID::TRG_POLARITY][i] == RTLIL::S1 ? RTLIL::STp : RTLIL::STn);
}
}
}
for (auto &mem : memories) {
flow.add_node(&mem);
// Clocked memory cells are treated like posedge/negedge processes as well.
for (auto &port : mem.rd_ports) {
if (port.clk_enable)
if (is_valid_clock(port.clk))
register_edge_signal(sigmap, port.clk,
port.clk_polarity ? RTLIL::STp : RTLIL::STn);
// For read ports, also move initial value to wire_init (if any).
for (int i = 0; i < GetSize(port.data); i++) {
if (port.init_value[i] != State::Sx) {
SigBit bit = port.data[i];
if (bit.wire) {
auto &init = wire_init[bit.wire];
if (init == RTLIL::Const()) {
init = RTLIL::Const(State::Sx, GetSize(bit.wire));
}
init[bit.offset] = port.init_value[i];
}
}
}
}
for (auto &port : mem.wr_ports) {
if (port.clk_enable)
if (is_valid_clock(port.clk))
register_edge_signal(sigmap, port.clk,
port.clk_polarity ? RTLIL::STp : RTLIL::STn);
}
if (!mem.wr_ports.empty())
writable_memories.insert({module, mem.memid});
}
for (auto proc : module->processes) {
flow.add_node(proc.second);
for (auto sync : proc.second->syncs) {
switch (sync->type) {
// Edge-type sync rules require pre-registration.
case RTLIL::STp:
case RTLIL::STn:
case RTLIL::STe:
register_edge_signal(sigmap, sync->signal, sync->type);
break;
// Level-type sync rules require no special handling.
case RTLIL::ST0:
case RTLIL::ST1:
case RTLIL::STa:
break;
case RTLIL::STg:
log_cmd_error("Global clock is not supported.\n");
// Handling of init-type sync rules is delegated to the `proc_init` pass, so we can use the wire
// attribute regardless of input.
case RTLIL::STi:
log_assert(false);
}
for (auto &memwr : sync->mem_write_actions) {
writable_memories.insert({module, memwr.memid});
}
}
}
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
// Construct a linear order of the flow graph that minimizes the amount of feedback arcs. A flow graph
// without feedback arcs can generally be evaluated in a single pass, i.e. it always requires only
// a single delta cycle.
Scheduler<FlowGraph::Node> scheduler;
dict<FlowGraph::Node*, Scheduler<FlowGraph::Node>::Vertex*, hash_ptr_ops> node_vertex_map;
for (auto node : flow.nodes)
node_vertex_map[node] = scheduler.add(node);
for (auto node_comb_def : flow.node_comb_defs) {
auto vertex = node_vertex_map[node_comb_def.first];
for (auto wire : node_comb_def.second)
for (auto succ_node : flow.wire_uses[wire]) {
auto succ_vertex = node_vertex_map[succ_node];
vertex->succs.insert(succ_vertex);
succ_vertex->preds.insert(vertex);
}
}
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
// Find out whether the order includes any feedback arcs.
std::vector<FlowGraph::Node*> node_order;
pool<FlowGraph::Node*, hash_ptr_ops> evaluated_nodes;
pool<const RTLIL::Wire*> feedback_wires;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
for (auto vertex : scheduler.schedule()) {
auto node = vertex->data;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
node_order.push_back(node);
// Any wire that is an output of node vo and input of node vi where vo is scheduled later than vi
// is a feedback wire. Feedback wires indicate apparent logic loops in the design, which may be
// caused by a true logic loop, but usually are a benign result of dependency tracking that works
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
// on wire, not bit, level. Nevertheless, feedback wires cannot be unbuffered.
evaluated_nodes.insert(node);
for (auto wire : flow.node_comb_defs[node])
for (auto succ_node : flow.wire_uses[wire])
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
if (evaluated_nodes[succ_node])
feedback_wires.insert(wire);
}
if (!feedback_wires.empty()) {
has_feedback_arcs = true;
log("Module `%s' contains feedback arcs through wires:\n", log_id(module));
for (auto wire : feedback_wires)
log(" %s\n", log_id(wire));
}
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
// Conservatively assign wire types. Assignment of types BUFFERED and MEMBER is final, but assignment
// of type LOCAL may be further refined to UNUSED or INLINE.
for (auto wire : module->wires()) {
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
auto &wire_type = wire_types[wire];
wire_type = {WireType::BUFFERED};
if (feedback_wires[wire]) continue;
if (wire->port_output && !module->get_bool_attribute(ID::top)) continue;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
if (!wire->name.isPublic() && !unbuffer_internal) continue;
if (wire->name.isPublic() && !unbuffer_public) continue;
cxxrtl: localize wires with multiple comb drivers, too. Before this commit, any wire that was not driven by an output port of exactly one comb cell would not be localized, even if there were no feedback arcs through that wire. This would cause the wire to become buffered and require (often quite a few) extraneous delta cycles during evaluation. To alleviate this problem, -O5 was running `splitnets -driver`. However, this solution was mistaken. Because `splitnets -driver` followed by `opt_clean -purge` would produce more nets with multiple drivers, it would have to be iterated to fixpoint. Moreover, even if this was done, it would not be sufficient because `opt_clean -purge` does not currently remove wires with the `\init` attribute (and it is not desirable to remove such wires, since they correspond to registers and may be useful for debugging). The proper solution is to consider the condition in which a wire may be localized. Specifically, if there are no feedback arcs through this wire, and no part of the wire is driven by an output of a sync cell, then the wire holds no state and is localizable. After this commit, the original condition for not localizing a wire is replaced by a check for any sync cell driving it. This makes it unnecessary to run `splitnets -driver` in the majority of cases to get a design with no buffered wires, and -O5 no longer includes that pass. As a result, Minerva SRAM SoC no longer has any buffered wires, and runs ~27% faster. In addition, this commit prepares the flow graph for introduction of sync outputs of black boxes. Co-authored-by: Jean-François Nguyen <jf@lambdaconcept.com>
2020-04-21 08:33:42 -05:00
if (flow.wire_sync_defs.count(wire) > 0) continue;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
wire_type = {WireType::MEMBER};
if (edge_wires[wire]) continue;
if (wire->get_bool_attribute(ID::keep)) continue;
if (wire->port_input || wire->port_output) continue;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
if (!wire->name.isPublic() && !localize_internal) continue;
if (wire->name.isPublic() && !localize_public) continue;
wire_type = {WireType::LOCAL};
}
// Discover nodes reachable from primary outputs (i.e. members) and collect reachable wire users.
pool<FlowGraph::Node*, hash_ptr_ops> worklist;
for (auto node : flow.nodes) {
if (node->type == FlowGraph::Node::Type::CELL_EVAL && is_effectful_cell(node->cell->type))
worklist.insert(node); // node has effects
else if (node->type == FlowGraph::Node::Type::PRINT_SYNC)
worklist.insert(node); // node is sync $print
else if (node->type == FlowGraph::Node::Type::MEM_WRPORTS)
worklist.insert(node); // node is memory write
else if (node->type == FlowGraph::Node::Type::PROCESS_SYNC && is_memwr_process(node->process))
worklist.insert(node); // node is memory write
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
else if (flow.node_sync_defs.count(node))
worklist.insert(node); // node is a flip-flop
else if (flow.node_comb_defs.count(node)) {
for (auto wire : flow.node_comb_defs[node])
if (wire_types[wire].is_member())
worklist.insert(node); // node drives public wires
}
}
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
dict<const RTLIL::Wire*, pool<FlowGraph::Node*, hash_ptr_ops>> live_wires;
pool<FlowGraph::Node*, hash_ptr_ops> live_nodes;
while (!worklist.empty()) {
auto node = worklist.pop();
live_nodes.insert(node);
for (auto wire : flow.node_uses[node]) {
live_wires[wire].insert(node);
for (auto pred_node : flow.wire_comb_defs[wire])
if (!live_nodes[pred_node])
worklist.insert(pred_node);
}
}
// Refine wire types taking into account the amount of uses from reachable nodes only.
for (auto wire : module->wires()) {
auto &wire_type = wire_types[wire];
if (!wire_type.is_local()) continue;
if (live_wires[wire].empty()) {
wire_type = {WireType::UNUSED}; // wire never used
continue;
}
if (!wire->name.isPublic() && !inline_internal) continue;
if (wire->name.isPublic() && !inline_public) continue;
if (flow.is_inlinable(wire, live_wires[wire])) {
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
if (flow.wire_comb_defs[wire].size() > 1)
log_cmd_error("Wire %s.%s has multiple drivers!\n", log_id(module), log_id(wire));
log_assert(flow.wire_comb_defs[wire].size() == 1);
FlowGraph::Node *node = *flow.wire_comb_defs[wire].begin();
switch (node->type) {
case FlowGraph::Node::Type::CELL_EVAL:
if (!is_inlinable_cell(node->cell->type)) continue;
wire_type = {WireType::INLINE, node->cell}; // wire replaced with cell
break;
case FlowGraph::Node::Type::CONNECT:
wire_type = {WireType::INLINE, node->connect.second}; // wire replaced with sig
break;
default: continue;
}
live_nodes.erase(node);
}
}
// Emit reachable nodes in eval().
// Accumulate sync $print cells per trigger condition.
dict<std::pair<RTLIL::SigSpec, RTLIL::Const>, std::vector<const RTLIL::Cell*>> sync_print_cells;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
for (auto node : node_order)
if (live_nodes[node]) {
if (node->type == FlowGraph::Node::Type::CELL_EVAL &&
node->cell->type == ID($print) &&
node->cell->getParam(ID::TRG_ENABLE).as_bool())
sync_print_cells[make_pair(node->cell->getPort(ID::TRG), node->cell->getParam(ID::TRG_POLARITY))].push_back(node->cell);
else
schedule[module].push_back(*node);
}
for (auto &it : sync_print_cells) {
auto node = flow.add_print_sync_node(it.second);
schedule[module].push_back(*node);
}
// For maximum performance, the state of the simulation (which is the same as the set of its double buffered
// wires, since using a singly buffered wire for any kind of state introduces a race condition) should contain
// no wires attached to combinatorial outputs. Feedback wires, by definition, make that impossible. However,
// it is possible that a design with no feedback arcs would end up with doubly buffered wires in such cases
// as a wire with multiple drivers where one of them is combinatorial and the other is synchronous. Such designs
// also require more than one delta cycle to converge.
pool<const RTLIL::Wire*> buffered_comb_wires;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
for (auto wire : module->wires())
if (wire_types[wire].is_buffered() && !feedback_wires[wire] && flow.wire_comb_defs[wire].size() > 0)
buffered_comb_wires.insert(wire);
if (!buffered_comb_wires.empty()) {
has_buffered_comb_wires = true;
log("Module `%s' contains buffered combinatorial wires:\n", log_id(module));
for (auto wire : buffered_comb_wires)
log(" %s\n", log_id(wire));
}
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
// Record whether eval() requires only one delta cycle in this module.
eval_converges[module] = feedback_wires.empty() && buffered_comb_wires.empty();
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
if (debug_info) {
// Annotate wire bits with the type of their driver; this is exposed in the debug metadata.
for (auto item : flow.bit_has_state)
bit_has_state.insert(item);
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
// Assign debug information wire types to public wires according to the chosen debug level.
// Unlike with optimized wire types, all assignments here are final.
for (auto wire : module->wires()) {
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
const auto &wire_type = wire_types[wire];
auto &debug_wire_type = debug_wire_types[wire];
if (!debug_info) continue;
if (wire->port_input || wire_type.is_buffered())
debug_wire_type = wire_type; // wire contains state
else if (!wire->name.isPublic())
continue; // internal and stateless
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
if (!debug_member) continue;
if (wire_type.is_member())
debug_wire_type = wire_type; // wire is a member
if (!debug_alias) continue;
const RTLIL::Wire *it = wire;
while (flow.is_inlinable(it)) {
log_assert(flow.wire_comb_defs[it].size() == 1);
FlowGraph::Node *node = *flow.wire_comb_defs[it].begin();
if (node->type != FlowGraph::Node::Type::CONNECT) break; // not an alias
RTLIL::SigSpec rhs = node->connect.second;
if (rhs.is_fully_const()) {
debug_wire_type = {WireType::CONST, rhs}; // wire replaced with const
} else if (rhs.is_wire()) {
if (wire_types[rhs.as_wire()].is_member())
debug_wire_type = {WireType::ALIAS, rhs}; // wire replaced with wire
else if (debug_eval && rhs.as_wire()->name.isPublic())
debug_wire_type = {WireType::ALIAS, rhs}; // wire replaced with outline
it = rhs.as_wire(); // and keep looking
continue;
}
break;
}
if (!debug_eval) continue;
if (!debug_wire_type.is_exact() && !wire_type.is_member())
debug_wire_type = {WireType::OUTLINE}; // wire is local or inlined
}
// Discover nodes reachable from primary outputs (i.e. outlines) up until primary inputs (i.e. members)
// and collect reachable wire users.
pool<FlowGraph::Node*, hash_ptr_ops> worklist;
for (auto node : flow.nodes) {
if (flow.node_comb_defs.count(node))
for (auto wire : flow.node_comb_defs[node])
if (debug_wire_types[wire].is_outline())
worklist.insert(node); // node drives outline
}
dict<const RTLIL::Wire*, pool<FlowGraph::Node*, hash_ptr_ops>> debug_live_wires;
pool<FlowGraph::Node*, hash_ptr_ops> debug_live_nodes;
while (!worklist.empty()) {
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
auto node = worklist.pop();
debug_live_nodes.insert(node);
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
for (auto wire : flow.node_uses[node]) {
if (debug_wire_types[wire].is_member())
continue; // node uses member
if (debug_wire_types[wire].is_exact())
continue; // node uses alias or const
debug_live_wires[wire].insert(node);
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
for (auto pred_node : flow.wire_comb_defs[wire])
if (!debug_live_nodes[pred_node])
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
worklist.insert(pred_node);
}
}
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
// Assign debug information wire types to internal wires used by reachable nodes. This is similar
// to refining optimized wire types with the exception that the assignments here are first and final.
for (auto wire : module->wires()) {
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
const auto &wire_type = wire_types[wire];
auto &debug_wire_type = debug_wire_types[wire];
if (wire->name.isPublic()) continue;
if (debug_live_wires[wire].empty()) {
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
continue; // wire never used
} else if (flow.is_inlinable(wire, debug_live_wires[wire])) {
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
log_assert(flow.wire_comb_defs[wire].size() == 1);
FlowGraph::Node *node = *flow.wire_comb_defs[wire].begin();
switch (node->type) {
case FlowGraph::Node::Type::CELL_EVAL:
if (!is_inlinable_cell(node->cell->type)) continue;
debug_wire_type = {WireType::INLINE, node->cell}; // wire replaced with cell
break;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
case FlowGraph::Node::Type::CONNECT:
debug_wire_type = {WireType::INLINE, node->connect.second}; // wire replaced with sig
break;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
default: continue;
}
debug_live_nodes.erase(node);
} else if (wire_type.is_member() || wire_type.type == WireType::LOCAL) {
debug_wire_type = wire_type; // wire not inlinable
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
} else {
log_assert(wire_type.type == WireType::INLINE ||
wire_type.type == WireType::UNUSED);
if (flow.wire_comb_defs[wire].size() == 0) {
if (wire_init.count(wire)) { // wire never modified
debug_wire_type = {WireType::CONST, wire_init.at(wire)};
} else {
debug_wire_type = {WireType::CONST, RTLIL::SigSpec(RTLIL::S0, wire->width)};
}
} else {
debug_wire_type = {WireType::LOCAL}; // wire used only for debug
}
}
}
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
// Emit reachable nodes in debug_eval().
for (auto node : node_order)
if (debug_live_nodes[node])
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
debug_schedule[module].push_back(*node);
}
auto show_wire_type = [&](const RTLIL::Wire* wire, const WireType &wire_type) {
const char *type_str;
switch (wire_type.type) {
case WireType::UNUSED: type_str = "UNUSED"; break;
case WireType::BUFFERED: type_str = "BUFFERED"; break;
case WireType::MEMBER: type_str = "MEMBER"; break;
case WireType::OUTLINE: type_str = "OUTLINE"; break;
case WireType::LOCAL: type_str = "LOCAL"; break;
case WireType::INLINE: type_str = "INLINE"; break;
case WireType::ALIAS: type_str = "ALIAS"; break;
case WireType::CONST: type_str = "CONST"; break;
default: type_str = "(invalid)";
}
if (wire_type.sig_subst.empty())
log_debug(" %s: %s\n", log_signal((RTLIL::Wire*)wire), type_str);
else
log_debug(" %s: %s = %s\n", log_signal((RTLIL::Wire*)wire), type_str, log_signal(wire_type.sig_subst));
};
if (print_wire_types && !wire_types.empty()) {
log_debug("Wire types:\n");
for (auto wire_type : wire_types)
show_wire_type(wire_type.first, wire_type.second);
}
if (print_debug_wire_types && !debug_wire_types.empty()) {
log_debug("Debug wire types:\n");
for (auto debug_wire_type : debug_wire_types)
show_wire_type(debug_wire_type.first, debug_wire_type.second);
}
}
if (has_feedback_arcs || has_buffered_comb_wires) {
// Although both non-feedback buffered combinatorial wires and apparent feedback wires may be eliminated
// by optimizing the design, if after `proc; flatten` there are any feedback wires remaining, it is very
// likely that these feedback wires are indicative of a true logic loop, so they get emphasized in the message.
const char *why_pessimistic = nullptr;
if (has_feedback_arcs)
why_pessimistic = "feedback wires";
else if (has_buffered_comb_wires)
why_pessimistic = "buffered combinatorial wires";
log_warning("Design contains %s, which require delta cycles during evaluation.\n", why_pessimistic);
if (!run_flatten)
log("Flattening may eliminate %s from the design.\n", why_pessimistic);
if (!run_proc)
log("Converting processes to netlists may eliminate %s from the design.\n", why_pessimistic);
}
}
void check_design(RTLIL::Design *design, bool &has_sync_init)
{
has_sync_init = false;
for (auto module : design->modules()) {
if (module->get_blackbox_attribute() && !module->has_attribute(ID(cxxrtl_blackbox)))
continue;
if (!design->selected_whole_module(module))
if (design->selected_module(module))
log_cmd_error("Can't handle partially selected module `%s'!\n", id2cstr(module->name));
if (!design->selected_module(module))
continue;
for (auto proc : module->processes)
for (auto sync : proc.second->syncs)
if (sync->type == RTLIL::STi)
has_sync_init = true;
}
}
void prepare_design(RTLIL::Design *design)
{
bool did_anything = false;
bool has_sync_init;
log_push();
check_design(design, has_sync_init);
if (run_hierarchy) {
Pass::call(design, "hierarchy -auto-top");
did_anything = true;
}
if (run_flatten) {
Pass::call(design, "flatten");
did_anything = true;
}
if (run_proc) {
Pass::call(design, "proc");
did_anything = true;
} else if (has_sync_init) {
// We're only interested in proc_init, but it depends on proc_prune and proc_clean, so call those
// in case they weren't already. (This allows `yosys foo.v -o foo.cc` to work.)
Pass::call(design, "proc_prune");
Pass::call(design, "proc_clean");
Pass::call(design, "proc_init");
did_anything = true;
}
// Recheck the design if it was modified.
if (did_anything)
check_design(design, has_sync_init);
log_assert(!has_sync_init);
log_pop();
if (did_anything)
log_spacer();
analyze_design(design);
}
};
struct CxxrtlBackend : public Backend {
static const int DEFAULT_OPT_LEVEL = 6;
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
static const int DEFAULT_DEBUG_LEVEL = 4;
CxxrtlBackend() : Backend("cxxrtl", "convert design to C++ RTL simulation") { }
2020-06-18 18:34:52 -05:00
void help() override
{
// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|
log("\n");
log(" write_cxxrtl [options] [filename]\n");
log("\n");
log("Write C++ code that simulates the design. The generated code requires a driver\n");
log("that instantiates the design, toggles its clock, and interacts with its ports.\n");
log("\n");
log("The following driver may be used as an example for a design with a single clock\n");
log("driving rising edge triggered flip-flops:\n");
2020-04-05 05:03:23 -05:00
log("\n");
log(" #include \"top.cc\"\n");
log("\n");
log(" int main() {\n");
log(" cxxrtl_design::p_top top;\n");
log(" top.step();\n");
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log(" while (1) {\n");
log(" /* user logic */\n");
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log(" top.p_clk.set(false);\n");
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log(" top.step();\n");
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log(" top.p_clk.set(true);\n");
log(" top.step();\n");
2020-04-05 05:03:23 -05:00
log(" }\n");
log(" }\n");
log("\n");
log("Note that CXXRTL simulations, just like the hardware they are simulating, are\n");
log("subject to race conditions. If, in the example above, the user logic would run\n");
log("simultaneously with the rising edge of the clock, the design would malfunction.\n");
log("\n");
log("This backend supports replacing parts of the design with black boxes implemented\n");
log("in C++. If a module marked as a CXXRTL black box, its implementation is ignored,\n");
log("and the generated code consists only of an interface and a factory function.\n");
log("The driver must implement the factory function that creates an implementation of\n");
log("the black box, taking into account the parameters it is instantiated with.\n");
log("\n");
log("For example, the following Verilog code defines a CXXRTL black box interface for\n");
log("a synchronous debug sink:\n");
log("\n");
log(" (* cxxrtl_blackbox *)\n");
log(" module debug(...);\n");
log(" (* cxxrtl_edge = \"p\" *) input clk;\n");
log(" input en;\n");
log(" input [7:0] i_data;\n");
log(" (* cxxrtl_sync *) output [7:0] o_data;\n");
log(" endmodule\n");
log("\n");
log("For this HDL interface, this backend will generate the following C++ interface:\n");
log("\n");
log(" struct bb_p_debug : public module {\n");
log(" value<1> p_clk;\n");
log(" bool posedge_p_clk() const { /* ... */ }\n");
log(" value<1> p_en;\n");
log(" value<8> p_i_data;\n");
log(" wire<8> p_o_data;\n");
log("\n");
log(" bool eval() override;\n");
log(" bool commit() override;\n");
log("\n");
log(" static std::unique_ptr<bb_p_debug>\n");
log(" create(std::string name, metadata_map parameters, metadata_map attributes);\n");
log(" };\n");
log("\n");
log("The `create' function must be implemented by the driver. For example, it could\n");
log("always provide an implementation logging the values to standard error stream:\n");
log("\n");
log(" namespace cxxrtl_design {\n");
log("\n");
log(" struct stderr_debug : public bb_p_debug {\n");
log(" bool eval() override {\n");
log(" if (posedge_p_clk() && p_en)\n");
log(" fprintf(stderr, \"debug: %%02x\\n\", p_i_data.data[0]);\n");
log(" p_o_data.next = p_i_data;\n");
log(" return bb_p_debug::eval();\n");
log(" }\n");
log(" };\n");
log("\n");
log(" std::unique_ptr<bb_p_debug>\n");
log(" bb_p_debug::create(std::string name, cxxrtl::metadata_map parameters,\n");
log(" cxxrtl::metadata_map attributes) {\n");
log(" return std::make_unique<stderr_debug>();\n");
log(" }\n");
log("\n");
log(" }\n");
log("\n");
log("For complex applications of black boxes, it is possible to parameterize their\n");
log("port widths. For example, the following Verilog code defines a CXXRTL black box\n");
log("interface for a configurable width debug sink:\n");
log("\n");
log(" (* cxxrtl_blackbox, cxxrtl_template = \"WIDTH\" *)\n");
log(" module debug(...);\n");
log(" parameter WIDTH = 8;\n");
log(" (* cxxrtl_edge = \"p\" *) input clk;\n");
log(" input en;\n");
log(" (* cxxrtl_width = \"WIDTH\" *) input [WIDTH - 1:0] i_data;\n");
log(" (* cxxrtl_width = \"WIDTH\" *) output [WIDTH - 1:0] o_data;\n");
log(" endmodule\n");
log("\n");
log("For this parametric HDL interface, this backend will generate the following C++\n");
log("interface (only the differences are shown):\n");
log("\n");
log(" template<size_t WIDTH>\n");
log(" struct bb_p_debug : public module {\n");
log(" // ...\n");
log(" value<WIDTH> p_i_data;\n");
log(" wire<WIDTH> p_o_data;\n");
log(" // ...\n");
log(" static std::unique_ptr<bb_p_debug<WIDTH>>\n");
log(" create(std::string name, metadata_map parameters, metadata_map attributes);\n");
log(" };\n");
log("\n");
log("The `create' function must be implemented by the driver, specialized for every\n");
log("possible combination of template parameters. (Specialization is necessary to\n");
log("enable separate compilation of generated code and black box implementations.)\n");
log("\n");
log(" template<size_t SIZE>\n");
log(" struct stderr_debug : public bb_p_debug<SIZE> {\n");
log(" // ...\n");
log(" };\n");
log("\n");
log(" template<>\n");
log(" std::unique_ptr<bb_p_debug<8>>\n");
log(" bb_p_debug<8>::create(std::string name, cxxrtl::metadata_map parameters,\n");
log(" cxxrtl::metadata_map attributes) {\n");
log(" return std::make_unique<stderr_debug<8>>();\n");
log(" }\n");
log("\n");
log("The following attributes are recognized by this backend:\n");
log("\n");
log(" cxxrtl_blackbox\n");
log(" only valid on modules. if specified, the module contents are ignored,\n");
log(" and the generated code includes only the module interface and a factory\n");
log(" function, which will be called to instantiate the module.\n");
log("\n");
log(" cxxrtl_edge\n");
log(" only valid on inputs of black boxes. must be one of \"p\", \"n\", \"a\".\n");
log(" if specified on signal `clk`, the generated code includes edge detectors\n");
log(" `posedge_p_clk()` (if \"p\"), `negedge_p_clk()` (if \"n\"), or both (if\n");
log(" \"a\"), simplifying implementation of clocked black boxes.\n");
log("\n");
log(" cxxrtl_template\n");
log(" only valid on black boxes. must contain a space separated sequence of\n");
log(" identifiers that have a corresponding black box parameters. for each\n");
log(" of them, the generated code includes a `size_t` template parameter.\n");
log("\n");
log(" cxxrtl_width\n");
log(" only valid on ports of black boxes. must be a constant expression, which\n");
log(" is directly inserted into generated code.\n");
log("\n");
log(" cxxrtl_comb, cxxrtl_sync\n");
log(" only valid on outputs of black boxes. if specified, indicates that every\n");
log(" bit of the output port is driven, correspondingly, by combinatorial or\n");
log(" synchronous logic. this knowledge is used for scheduling optimizations.\n");
log(" if neither is specified, the output will be pessimistically treated as\n");
log(" driven by both combinatorial and synchronous logic.\n");
log("\n");
2020-04-05 05:03:23 -05:00
log("The following options are supported by this backend:\n");
log("\n");
log(" -print-wire-types, -print-debug-wire-types\n");
log(" enable additional debug logging, for pass developers.\n");
log("\n");
log(" -header\n");
log(" generate separate interface (.h) and implementation (.cc) files.\n");
log(" if specified, the backend must be called with a filename, and filename\n");
log(" of the interface is derived from filename of the implementation.\n");
log(" otherwise, interface and implementation are generated together.\n");
log("\n");
log(" -namespace <ns-name>\n");
log(" place the generated code into namespace <ns-name>. if not specified,\n");
log(" \"cxxrtl_design\" is used.\n");
log("\n");
log(" -print-output <stream>\n");
log(" $print cells in the generated code direct their output to <stream>.\n");
log(" must be one of \"std::cout\", \"std::cerr\". if not specified,\n");
log(" \"std::cout\" is used.\n");
log("\n");
log(" -nohierarchy\n");
log(" use design hierarchy as-is. in most designs, a top module should be\n");
log(" present as it is exposed through the C API and has unbuffered outputs\n");
log(" for improved performance; it will be determined automatically if absent.\n");
log("\n");
log(" -noflatten\n");
log(" don't flatten the design. fully flattened designs can evaluate within\n");
log(" one delta cycle if they have no combinatorial feedback.\n");
log(" note that the debug interface and waveform dumps use full hierarchical\n");
log(" names for all wires even in flattened designs.\n");
log("\n");
log(" -noproc\n");
log(" don't convert processes to netlists. in most designs, converting\n");
log(" processes significantly improves evaluation performance at the cost of\n");
log(" slight increase in compilation time.\n");
log("\n");
log(" -O <level>\n");
log(" set the optimization level. the default is -O%d. higher optimization\n", DEFAULT_OPT_LEVEL);
log(" levels dramatically decrease compile and run time, and highest level\n");
log(" possible for a design should be used.\n");
log("\n");
log(" -O0\n");
log(" no optimization.\n");
log("\n");
log(" -O1\n");
2020-12-21 01:24:26 -06:00
log(" unbuffer internal wires if possible.\n");
log("\n");
log(" -O2\n");
2020-12-21 01:24:26 -06:00
log(" like -O1, and localize internal wires if possible.\n");
log("\n");
log(" -O3\n");
log(" like -O2, and inline internal wires if possible.\n");
log("\n");
log(" -O4\n");
log(" like -O3, and unbuffer public wires not marked (*keep*) if possible.\n");
log("\n");
log(" -O5\n");
log(" like -O4, and localize public wires not marked (*keep*) if possible.\n");
log("\n");
log(" -O6\n");
log(" like -O5, and inline public wires not marked (*keep*) if possible.\n");
log("\n");
log(" -g <level>\n");
log(" set the debug level. the default is -g%d. higher debug levels provide\n", DEFAULT_DEBUG_LEVEL);
log(" more visibility and generate more code, but do not pessimize evaluation.\n");
log("\n");
log(" -g0\n");
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
log(" no debug information. the C API is disabled.\n");
log("\n");
log(" -g1\n");
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
log(" include bare minimum of debug information necessary to access all design\n");
log(" state. the C API is enabled.\n");
log("\n");
log(" -g2\n");
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
log(" like -g1, but include debug information for all public wires that are\n");
log(" directly accessible through the C++ interface.\n");
log("\n");
log(" -g3\n");
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
log(" like -g2, and include debug information for public wires that are tied\n");
log(" to a constant or another public wire.\n");
log("\n");
log(" -g4\n");
log(" like -g3, and compute debug information on demand for all public wires\n");
log(" that were optimized out.\n");
log("\n");
}
2020-06-18 18:34:52 -05:00
void execute(std::ostream *&f, std::string filename, std::vector<std::string> args, RTLIL::Design *design) override
{
bool print_wire_types = false;
bool print_debug_wire_types = false;
bool nohierarchy = false;
bool noflatten = false;
bool noproc = false;
int opt_level = DEFAULT_OPT_LEVEL;
int debug_level = DEFAULT_DEBUG_LEVEL;
CxxrtlWorker worker;
log_header(design, "Executing CXXRTL backend.\n");
size_t argidx;
for (argidx = 1; argidx < args.size(); argidx++)
{
if (args[argidx] == "-print-wire-types") {
print_wire_types = true;
continue;
}
if (args[argidx] == "-print-debug-wire-types") {
print_debug_wire_types = true;
continue;
}
if (args[argidx] == "-nohierarchy") {
nohierarchy = true;
continue;
}
if (args[argidx] == "-noflatten") {
noflatten = true;
continue;
}
if (args[argidx] == "-noproc") {
noproc = true;
continue;
}
if (args[argidx] == "-Og") {
log_warning("The `-Og` option has been removed. Use `-g3` instead for complete "
"design coverage regardless of optimization level.\n");
continue;
}
if (args[argidx] == "-O" && argidx+1 < args.size() && args[argidx+1] == "g") {
argidx++;
log_warning("The `-Og` option has been removed. Use `-g3` instead for complete "
"design coverage regardless of optimization level.\n");
continue;
}
if (args[argidx] == "-O" && argidx+1 < args.size()) {
opt_level = std::stoi(args[++argidx]);
continue;
}
if (args[argidx].substr(0, 2) == "-O" && args[argidx].size() == 3 && isdigit(args[argidx][2])) {
opt_level = std::stoi(args[argidx].substr(2));
continue;
}
if (args[argidx] == "-g" && argidx+1 < args.size()) {
debug_level = std::stoi(args[++argidx]);
continue;
}
if (args[argidx].substr(0, 2) == "-g" && args[argidx].size() == 3 && isdigit(args[argidx][2])) {
debug_level = std::stoi(args[argidx].substr(2));
continue;
}
if (args[argidx] == "-header") {
worker.split_intf = true;
continue;
}
if (args[argidx] == "-namespace" && argidx+1 < args.size()) {
worker.design_ns = args[++argidx];
continue;
}
if (args[argidx] == "-print-output" && argidx+1 < args.size()) {
worker.print_output = args[++argidx];
if (!(worker.print_output == "std::cout" || worker.print_output == "std::cerr")) {
log_cmd_error("Invalid output stream \"%s\".\n", worker.print_output.c_str());
worker.print_output = "std::cout";
}
continue;
}
break;
}
extra_args(f, filename, args, argidx);
worker.print_wire_types = print_wire_types;
worker.print_debug_wire_types = print_debug_wire_types;
worker.run_hierarchy = !nohierarchy;
worker.run_flatten = !noflatten;
worker.run_proc = !noproc;
switch (opt_level) {
// the highest level here must match DEFAULT_OPT_LEVEL
case 6:
worker.inline_public = true;
YS_FALLTHROUGH
case 5:
worker.localize_public = true;
YS_FALLTHROUGH
case 4:
worker.unbuffer_public = true;
YS_FALLTHROUGH
case 3:
worker.inline_internal = true;
YS_FALLTHROUGH
case 2:
worker.localize_internal = true;
YS_FALLTHROUGH
case 1:
worker.unbuffer_internal = true;
YS_FALLTHROUGH
case 0:
break;
default:
log_cmd_error("Invalid optimization level %d.\n", opt_level);
}
switch (debug_level) {
// the highest level here must match DEFAULT_DEBUG_LEVEL
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
case 4:
worker.debug_eval = true;
YS_FALLTHROUGH
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
case 3:
worker.debug_alias = true;
YS_FALLTHROUGH
cxxrtl: completely rewrite netlist layout code. The exact shape of C++ code emitted by CXXRTL has a critical effect on performance, both compile-time and runtime. CXXRTL's performance greatly improved when it started localizing and inlining wires, not only because this assists the optimizer and register allocator, but also because inlining code into edge-triggered regions cuts the time spent in eval() by at least a factor of two. However, the logic of netlist layout has always been ad-hoc, fragile, and very hard to understand and modify. After commit ece25a45, which introduced outlining, the same logic started being applied to two distinct netlists at once instead of one, which barely worked. This commit does four major changes: * There is now a single unambiguous source of truth (per subgraph) for the layout of any emitted wire. * Netlist layout is now done entirely during analysis using well known graph algorithms; no graph operations happen when emitting. * Netlist layout now happens completely separately for eval() and debug_eval() subgraphs. * Unreachable (within subgraph scope) netlist nodes are now neither emitted nor considered for wire inlining decisions. The netlist layout code should also now closely match the described semantics. As a part of this large cleanup, it includes many miscellaneous improvements: * The "bare minimum" debug level introduced in commit dd6a761d was split into two levels; -g1 now emits debug information *only* for inputs and state wires, and -g2 now emits debug information for all public members. The old behavior matches -g2. This is done to avoid bloat on low optimization levels. * Debug aliases and inlined connections are now handled separately, and complex RHS never interferes with inlined connections. * Aliases to outlined wires now carry a pointer to the outline. * Cell sync outputs can now be emitted in debug_eval(). * Black box debug information now includes comb/sync driver flags. * The comment emitted for inlined cells is now accurate. * Debug information statistics now has less noise. * Netlist layout code is now much better documented. Due to more precise inlining decisions, unmodified (i.e. with no Yosys script being used) netlists now have much more logic inlined into edge-triggered regions. On Minerva SoC SRAM, this improves runtime by 20-25% across compilers and optimization levels. Due to more precise reachability analysis, much less C++ code is now emitted, especially at the maximum debug level. On Minerva SoC SRAM, this improves clang compile time by 30-50% depending on options. gcc is not affected.
2020-12-21 15:00:46 -06:00
case 2:
worker.debug_member = true;
YS_FALLTHROUGH
case 1:
worker.debug_info = true;
YS_FALLTHROUGH
case 0:
break;
default:
log_cmd_error("Invalid debug information level %d.\n", debug_level);
}
std::ofstream intf_f;
if (worker.split_intf) {
if (filename == "<stdout>")
log_cmd_error("Option -header must be used with a filename.\n");
worker.intf_filename = filename.substr(0, filename.rfind('.')) + ".h";
intf_f.open(worker.intf_filename, std::ofstream::trunc);
if (intf_f.fail())
log_cmd_error("Can't open file `%s' for writing: %s\n",
worker.intf_filename.c_str(), strerror(errno));
worker.intf_f = &intf_f;
}
worker.impl_f = f;
worker.prepare_design(design);
worker.dump_design(design);
}
} CxxrtlBackend;
PRIVATE_NAMESPACE_END