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The time estimator's speed/acceleration limits were indexed by time mode only, reading slot 0 of the per-(extruder x volume-type) arrays the multi-extruder profiles already carry (H2C 0.4: 8 entries, H2D 0.4: 10). Every move was therefore modelled with the first machine slot's limits regardless of which nozzle variant was printing - estimation fidelity only, since emitted feedrates/accelerations are decided on the slicing side. Now the estimator resolves the machine slot of the nozzle currently mounted in the active extruder: the nozzle grouping context is handed to the processor BEFORE the streaming replay (new member + setter - deliberately separate from the post-stream result-field handover that gates the richer change-time model, whose timing is unchanged), the occupancy recorder is populated on every filament change (bookkeeping decoupled from the gated time model; recorder writes have no time effect), and get_machine_config_idx maps (volume type x extruder type x extruder) to the slot via the printer's variant layout, newly carried on the processor result. The feedrate/acceleration getters gain a slot parameter indexing [slot*2 + mode]; jerk and the print/travel/retract accelerations stay mode-only. Reloaded sliced projects re-estimate with the result's saved grouping context; imported bare g-code degrades to slot 0 - the historical read. M201/M203 write the parsed value into EVERY slot's mode entry (a firmware envelope change is global), which keeps per-slot reads in lockstep with the mode-only reads they replace: the fleet emits envelope lines before any motion, so estimates - hence the estimated time header, M73 lines, and every other byte - are unchanged (20/20 pinned-slice byte gate bit-identical, incl. the sequential repro sliced twice). Fidelity improves where envelope emission is off or a migrating per-layer plan moves filaments across variants. Tests: a stub-driven processor case proving the slot follows the active nozzle through the exact production path (T..H.. commands, fallback recorder bookkeeping, 4x time ratio on the slow variant), that emitted M201/M203 reach every slot, and that a missing context degrades to slot 0. Suites green (libslic3r 48998/169, fff_print 667/62).
421 lines
20 KiB
C++
421 lines
20 KiB
C++
#include <catch2/catch_all.hpp>
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#include "libslic3r/libslic3r.h"
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#include "libslic3r/GCode/GCodeProcessor.hpp"
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#include "libslic3r/MultiNozzleUtils.hpp"
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#include "libslic3r/PrintConfig.hpp"
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#include "test_utils.hpp"
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#include <fstream>
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#include <map>
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#include <memory>
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using namespace Slic3r;
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using Catch::Matchers::WithinAbs;
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// Regression coverage for filament/tool-change time being folded into the first
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// pending motion block (an extrusion move) instead of the tool-change move, and
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// for that delay being dropped entirely when too few motion blocks precede the
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// change. See BambuStudio "seperate flush time from other types" (c54a8333c7)
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// and the follow-up "unprocessed addtional time" fix (27ef0b1bef).
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namespace {
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constexpr size_t NORMAL = static_cast<size_t>(PrintEstimatedStatistics::ETimeMode::Normal);
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FullPrintConfig make_config(double load_time, double unload_time, double tool_change_time)
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{
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FullPrintConfig config; // default-initialized with the built-in defaults
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config.gcode_flavor.value = gcfMarlinFirmware;
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// Two filaments, both assigned to the same (single) extruder, so a T1 after
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// T0 is a same-extruder filament swap that costs unload + load time.
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config.filament_diameter.values = {1.75, 1.75};
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config.filament_map.values = {1, 1};
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config.machine_load_filament_time.value = load_time;
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config.machine_unload_filament_time.value = unload_time;
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config.machine_tool_change_time.value = tool_change_time;
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return config;
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}
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void run_processor(GCodeProcessor& proc, const FullPrintConfig& config, const char* gcode)
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{
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// reserved_tag() selects between two tag tables based on this shared static, and
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// other tests in the binary mutate it -- pin it so our "; FEATURE:" role tags are
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// parsed deterministically regardless of test execution order.
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GCodeProcessor::s_IsBBLPrinter = true;
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ScopedTemporaryFile temp(".gcode");
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{
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std::ofstream os(temp.string());
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os << gcode;
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}
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proc.apply_config(config);
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// No producer marker in the gcode, so process_file keeps our applied config.
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proc.process_file(temp.string());
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}
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// Estimated time per extrusion role, grouped exactly the way libvgcode builds the
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// feature-type legend: sum MoveVertex.time over EMoveType::Extrude moves keyed by
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// extrusion_role (see ViewerImpl.cpp:1017 -- only Extrude moves are counted).
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std::map<ExtrusionRole, double> role_times(const GCodeProcessorResult& r)
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{
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std::map<ExtrusionRole, double> m;
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for (const auto& mv : r.moves)
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if (mv.type == EMoveType::Extrude)
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m[mv.extrusion_role] += mv.time[NORMAL];
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return m;
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}
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// Sum of estimated time attributed to tool-change moves.
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double sum_tool_change_time(const GCodeProcessorResult& r)
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{
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double t = 0.0;
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for (const auto& mv : r.moves)
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if (mv.type == EMoveType::Tool_change)
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t += mv.time[NORMAL];
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return t;
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}
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// Total filament-change delay, accumulated independently of the timing machinery.
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double filament_change_delay(const GCodeProcessorResult& r)
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{
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const auto& s = r.print_statistics;
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return s.total_filament_load_time + s.total_filament_unload_time + s.total_tool_change_time;
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}
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} // namespace
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TEST_CASE("Filament-change time is attributed to tool-change moves, not extrusion roles", "[GCodeTiming]")
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{
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// Relative extrusion (M83) so every "E5" is a real 5mm extrusion move rather
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// than a zero-delta travel. Two real travels precede T0 so its delay is flushed
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// cleanly. The extrusions after T0 span several roles (Outer wall, Sparse infill,
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// Inner wall); the first pending block at T1 is an "Outer wall" move, so the
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// buggy code folds the T1 delay into that role. The per-role check below verifies
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// EVERY role stays clean, not just one, and catches any role-to-role misattribution.
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const char* gcode =
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"M83\n"
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"; FEATURE: Outer wall\n"
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"G1 X10 Y10 Z0.2 F600\n"
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"G1 X0 Y0 F6000\n"
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"T0\n"
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"; FEATURE: Outer wall\n"
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"G1 X50 Y0 E5 F1800\n"
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"G1 X50 Y50 E5\n"
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"; FEATURE: Sparse infill\n"
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"G1 X0 Y50 E5\n"
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"G1 X0 Y0 E5\n"
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"T1\n"
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"; FEATURE: Inner wall\n"
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"G1 X50 Y0 E5\n"
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"G1 X50 Y50 E5\n";
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GCodeProcessor proc_zero;
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run_processor(proc_zero, make_config(0.0, 0.0, 0.0), gcode);
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const GCodeProcessorResult& r_zero = proc_zero.get_result();
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const double load = 10.0;
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const double unload = 5.0;
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GCodeProcessor proc_delay;
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run_processor(proc_delay, make_config(load, unload, 0.0), gcode);
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const GCodeProcessorResult& r_delay = proc_delay.get_result();
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const double delay = filament_change_delay(r_delay);
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// Preconditions: the filament changes were charged, and cost nothing in the
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// zero-time baseline.
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REQUIRE(delay > 0.0);
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REQUIRE_THAT(filament_change_delay(r_zero), WithinAbs(0.0, 1e-9));
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// The delay must not inflate the time of ANY extrusion role. Compare the full
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// per-role breakdown (exactly how the feature-type legend is built) between the
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// zero-delay and delayed runs -- every role must match to within tolerance.
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const auto roles_zero = role_times(r_zero);
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const auto roles_delay = role_times(r_delay);
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// Guard: the gcode must genuinely exercise multiple distinct roles (Outer wall,
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// Sparse infill, Inner wall), otherwise this check would silently cover only one.
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REQUIRE(roles_zero.size() >= 3);
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REQUIRE(roles_zero.size() == roles_delay.size());
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for (const auto& [role, zero_time] : roles_zero) {
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INFO("extrusion role index = " << static_cast<int>(role));
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REQUIRE(roles_delay.count(role) == 1);
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REQUIRE_THAT(roles_delay.at(role), WithinAbs(zero_time, 1e-2));
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}
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// The delay must instead land on the tool-change moves, so per-move consumers
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// (layer-time view, layer slider) stay consistent.
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REQUIRE_THAT(sum_tool_change_time(r_delay), WithinAbs(delay, 1e-2));
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// Both tool changes occur on layer 1, so the delay must also be reflected in
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// the first-layer time.
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const double first_layer_delta = proc_delay.get_first_layer_time(PrintEstimatedStatistics::ETimeMode::Normal)
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- proc_zero.get_first_layer_time(PrintEstimatedStatistics::ETimeMode::Normal);
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REQUIRE_THAT(first_layer_delta, WithinAbs(delay, 1e-2));
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}
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TEST_CASE("Filament-change time is not dropped when few motion blocks precede the change", "[GCodeTiming]")
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{
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// Only a single motion block precedes T0, so the buggy code's "fewer than two
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// pending blocks" early-out discards that filament-change delay entirely,
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// making the total print time inconsistent with the reported statistics.
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const char* gcode =
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"; FEATURE: Outer wall\n"
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"G1 X10 Y10 Z0.2 F600\n"
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"T0\n"
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"G1 X50 Y0 E5 F1800\n"
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"G1 X50 Y50 E5\n"
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"T1\n"
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"G1 X0 Y50 E5\n"
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"G1 X0 Y0 E5\n";
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GCodeProcessor proc_zero;
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run_processor(proc_zero, make_config(0.0, 0.0, 0.0), gcode);
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const double load = 10.0;
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const double unload = 5.0;
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GCodeProcessor proc_delay;
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run_processor(proc_delay, make_config(load, unload, 0.0), gcode);
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const GCodeProcessorResult& r_delay = proc_delay.get_result();
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const double delay = filament_change_delay(r_delay);
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REQUIRE(delay > 0.0);
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// Every second of reported filament-change delay must be present in the total
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// estimated print time; none may be silently dropped.
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const double total_delta = proc_delay.get_time(PrintEstimatedStatistics::ETimeMode::Normal)
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- proc_zero.get_time(PrintEstimatedStatistics::ETimeMode::Normal);
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REQUIRE_THAT(total_delta, WithinAbs(delay, 1e-2));
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}
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TEST_CASE("Back-to-back tool changes buffer then merge into one tool-change block", "[GCodeTiming]")
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{
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// T0 is the very first line: the block queue is empty when its delay is synchronized,
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// so with only the single (artificial) tool-change block queued the delay can't be
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// attributed yet and is buffered. T1 follows immediately with no motion between; its
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// synchronize now sees two tool-change blocks queued, so its own delay joins the buffered
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// T0 entry at application time, the two same-type entries merge into one, and the sum
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// lands entirely on the first tool-change block. The trailing travels leave both runs
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// with >= 2 blocks so their end-of-file flush is identical and cancels in every delta.
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const char* gcode =
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"T0\n" // first charged change (load only); empty queue -> buffers (Tool_change,10)
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"T1\n" // same-extruder swap (unload+load); merges with buffered T0 entry to (Tool_change,25)
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"G1 X10 Y0 Z0.2 F6000\n" // travels: keep >= 2 blocks queued at EOF (flushed identically by both runs)
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"G1 X10 Y10\n"
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"G1 X0 Y10\n";
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GCodeProcessor proc_zero;
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run_processor(proc_zero, make_config(0.0, 0.0, 0.0), gcode);
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const GCodeProcessorResult& r_zero = proc_zero.get_result();
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GCodeProcessor proc_delay;
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run_processor(proc_delay, make_config(10.0, 5.0, 0.0), gcode);
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const GCodeProcessorResult& r_delay = proc_delay.get_result();
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// T0 load 10 + T1 unload 5 + T1 load 10 = 25.
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const double delay = filament_change_delay(r_delay);
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REQUIRE(delay > 0.0);
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REQUIRE_THAT(delay, WithinAbs(25.0, 1e-6));
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REQUIRE_THAT(filament_change_delay(r_zero), WithinAbs(0.0, 1e-9));
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// The whole buffered-then-merged delay must reach the total print time.
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const double total_delta = proc_delay.get_time(PrintEstimatedStatistics::ETimeMode::Normal)
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- proc_zero.get_time(PrintEstimatedStatistics::ETimeMode::Normal);
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REQUIRE_THAT(total_delta, WithinAbs(delay, 1e-2));
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// ...and must land on the tool-change moves, not on any extrusion role.
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REQUIRE_THAT(sum_tool_change_time(r_delay), WithinAbs(25.0, 1e-2));
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REQUIRE_THAT(sum_tool_change_time(r_zero), WithinAbs(0.0, 1e-9));
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// Characterization (documents the current merge-collapse behavior, not a correctness
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// requirement): the two buffered same-type entries combine onto the FIRST artificial
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// tool-change block; the second receives nothing. Had the merge regressed, the 10 and 15
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// would land on separate moves instead of 25 and 0.
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std::vector<double> tc;
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for (const auto& mv : r_delay.moves)
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if (mv.type == EMoveType::Tool_change)
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tc.push_back(mv.time[NORMAL]);
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REQUIRE(tc.size() >= 2);
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REQUIRE_THAT(tc[0], WithinAbs(25.0, 1e-2));
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REQUIRE_THAT(tc[1], WithinAbs(0.0, 1e-9));
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}
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TEST_CASE("Trailing tool change at end of file is drained, not dropped", "[GCodeTiming]")
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{
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// A tool change is the last line of the file, with only its single artificial block
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// queued. Its delay is buffered (fewer than two blocks) and there is no later motion to
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// flush it, so only the finalization pass can attribute it. Without the end-of-file drain
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// the delay would be stranded in the buffer and the total print time would disagree with
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// the reported filament-change statistics.
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const char* gcode =
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"G1 X10 Y0 Z0.2 F6000\n" // three travels -> three blocks queued (no E, so no filament is selected)
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"G1 X10 Y10\n"
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"G1 X0 Y10\n"
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"G4 S0\n" // dwell with S present -> full flush; queue and buffer now empty
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"T0\n"; // trailing change, nothing after: buffers (Tool_change,10), one block queued
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GCodeProcessor proc_zero;
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run_processor(proc_zero, make_config(0.0, 0.0, 0.0), gcode);
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const GCodeProcessorResult& r_zero = proc_zero.get_result();
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GCodeProcessor proc_delay;
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run_processor(proc_delay, make_config(10.0, 5.0, 0.0), gcode);
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const GCodeProcessorResult& r_delay = proc_delay.get_result();
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// T0 is the first charged change on an empty extruder, so it costs the load time only.
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const double delay = filament_change_delay(r_delay);
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REQUIRE(delay > 0.0);
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REQUIRE_THAT(delay, WithinAbs(10.0, 1e-6));
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// The trailing change's delay must survive to the total: the zero run buffers nothing and
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// drops its artificial block, so the motion cancels and the delta is exactly the drained delay.
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const double total_delta = proc_delay.get_time(PrintEstimatedStatistics::ETimeMode::Normal)
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- proc_zero.get_time(PrintEstimatedStatistics::ETimeMode::Normal);
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REQUIRE_THAT(total_delta, WithinAbs(delay, 1e-2));
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// The size-1 drain runs the body, so the delay lands on the artificial tool-change move.
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REQUIRE_THAT(sum_tool_change_time(r_delay), WithinAbs(10.0, 1e-2));
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REQUIRE_THAT(sum_tool_change_time(r_zero), WithinAbs(0.0, 1e-9));
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}
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TEST_CASE("Carried-forward tool-change delay reaches the total without polluting roles", "[GCodeTiming]")
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{
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// A wildcard dwell delay is buffered ahead of the tool-change delay, so when the blocks
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// are next flushed the dwell's (Noop) entry consumes the artificial tool-change block and
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// the tool-change entry finds no matching block and carries forward. It stays unmatched
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// through the remaining extrusion moves and is only resolved at finalization, where the
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// end-of-file fold adds it to the machine total and the custom-gcode cache -- never to a
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// move vertex, so it cannot leak into an extrusion role's time.
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const char* gcode =
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"M83\n"
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"G4 S3\n" // empty queue -> buffers (Noop,3) [wildcard delay]
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"T0\n" // one block queued -> buffers (Tool_change,10) behind the dwell
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"; FEATURE: Inner wall\n"
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"G1 X20 Y0 Z0.2 E5 F1800\n" // extrusion m1: queue is [artificial_TC0, m1]
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"G4 S0\n" // flush: (Noop,3) consumes artificial_TC0; (Tool_change,10) carries forward
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"G1 X20 Y20 E5\n" // extrusion m2
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"G1 X0 Y20 E5\n"; // extrusion m3: at EOF queue is [m2, m3], buffer is [(Tool_change,10)]
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GCodeProcessor proc_zero;
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run_processor(proc_zero, make_config(0.0, 0.0, 0.0), gcode);
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const GCodeProcessorResult& r_zero = proc_zero.get_result();
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GCodeProcessor proc_delay;
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run_processor(proc_delay, make_config(10.0, 5.0, 0.0), gcode);
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const GCodeProcessorResult& r_delay = proc_delay.get_result();
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// T0 is the first charged change (load only); the fixed dwell delays are not in these counters.
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const double delay = filament_change_delay(r_delay);
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REQUIRE(delay > 0.0);
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REQUIRE_THAT(delay, WithinAbs(10.0, 1e-6));
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// The stranded tool-change delay must be drained into the total, not dropped. The 3s dwell
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// is identical in both runs and cancels along with all motion, leaving exactly the delay.
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const double total_delta = proc_delay.get_time(PrintEstimatedStatistics::ETimeMode::Normal)
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- proc_zero.get_time(PrintEstimatedStatistics::ETimeMode::Normal);
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REQUIRE_THAT(total_delta, WithinAbs(delay, 1e-2));
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// Pollution safety: the drained delay must NOT appear in any extrusion role. Every role's
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// time must match between the zero and delayed runs -- this is what the total-only fold buys.
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const auto rz = role_times(r_zero);
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const auto rd = role_times(r_delay);
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REQUIRE(rz.size() >= 1);
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REQUIRE(rz.size() == rd.size());
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for (const auto& [role, zero_time] : rz) {
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INFO("extrusion role index = " << static_cast<int>(role));
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REQUIRE(rd.count(role) == 1);
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REQUIRE_THAT(rd.at(role), WithinAbs(zero_time, 1e-2));
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}
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}
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TEST_CASE("Per-slot machine limits follow the active nozzle", "[GCodeTiming][MultiNozzle]")
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{
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// Single physical extruder carrying two nozzle variants: machine slot 0 (Standard) caps X/Y
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// speed at 200 mm/s, slot 1 (High Flow) at 50 mm/s. The estimator must clamp each move by the
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// slot of the nozzle the active filament occupies -- resolved from the grouping context handed
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// over before the replay plus the occupancy recorder, i.e. the exact in-slicer streaming path.
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FullPrintConfig config = make_config(0.0, 0.0, 0.0);
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config.extruder_type.values = {static_cast<int>(etDirectDrive)};
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config.printer_extruder_id.values = {1, 1};
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config.printer_extruder_variant.values = {"Direct Drive Standard", "Direct Drive High Flow"};
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// Slot-major layout: [slot0-Normal, slot0-Stealth, slot1-Normal, slot1-Stealth].
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config.machine_max_speed_x.values = {200., 200., 50., 50.};
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config.machine_max_speed_y.values = {200., 200., 50., 50.};
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config.machine_max_speed_z.values = {200., 200., 50., 50.};
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config.machine_max_speed_e.values = {200., 200., 50., 50.};
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// Keep acceleration and jerk far from limiting so move times are speed-dominated.
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for (auto *accel : {&config.machine_max_acceleration_x, &config.machine_max_acceleration_y,
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&config.machine_max_acceleration_z, &config.machine_max_acceleration_e})
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accel->values = {100000., 100000., 100000., 100000.};
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config.machine_max_acceleration_travel.values = {100000., 100000.};
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config.machine_max_acceleration_extruding.values = {100000., 100000.};
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config.machine_max_jerk_x.values = {10000., 10000.};
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config.machine_max_jerk_y.values = {10000., 10000.};
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config.machine_max_jerk_z.values = {10000., 10000.};
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config.machine_max_jerk_e.values = {10000., 10000.};
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// Grouping stub: filament 0 lives on the Standard nozzle (slot 0), filament 1 on the
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// High Flow nozzle (slot 1), both mounted on extruder 0.
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std::vector<MultiNozzleUtils::NozzleInfo> nozzles;
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{
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MultiNozzleUtils::NozzleInfo n;
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n.diameter = "0.4";
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n.volume_type = nvtStandard; n.extruder_id = 0; n.group_id = 0; nozzles.push_back(n);
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n.volume_type = nvtHighFlow; n.extruder_id = 0; n.group_id = 1; nozzles.push_back(n);
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}
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std::vector<int> filament_nozzle_map = {0, 1};
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std::vector<unsigned int> used_filaments = {0, 1};
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auto group = MultiNozzleUtils::LayeredNozzleGroupResult::create(filament_nozzle_map, nozzles, used_filaments);
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REQUIRE(group.has_value());
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auto context = std::make_shared<MultiNozzleUtils::LayeredNozzleGroupResult>(*group);
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|
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// Two identical 100 mm X travels, one per filament; T..H.. carries the target nozzle id.
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// The trailing 1 mm move keeps two blocks queued at finalize, so the measured move's time is
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// flushed (a lone final block is never attributed); it adds 1 mm to the second bucket.
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const char* gcode =
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"M83\n"
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"T0 H0\n"
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"G1 X100 F30000\n"
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"T1 H1\n"
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"G1 X0 F30000\n"
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"G1 X1 F30000\n";
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// Travel time accumulated after each tool-change move (bucket 0 = before any T).
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auto travel_times_by_tool = [](const GCodeProcessorResult& r) {
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std::vector<double> out(1, 0.0);
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for (const auto& mv : r.moves) {
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if (mv.type == EMoveType::Tool_change)
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out.push_back(0.0);
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else if (mv.type == EMoveType::Travel)
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out.back() += mv.time[NORMAL];
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}
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return out;
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};
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|
|
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SECTION("the move on the High Flow nozzle is clamped by its own slot") {
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GCodeProcessor proc;
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proc.initialize_from_context(context);
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run_processor(proc, config, gcode);
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auto times = travel_times_by_tool(proc.get_result());
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REQUIRE(times.size() == 3);
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|
REQUIRE_THAT(times[1], Catch::Matchers::WithinRel(100.0 / 200.0, 0.10));
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REQUIRE_THAT(times[2], Catch::Matchers::WithinRel(101.0 / 50.0, 0.10));
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|
}
|
|
SECTION("an emitted envelope line reaches every slot") {
|
|
const std::string enveloped = std::string("M201 X20000\nM203 X80\n") + gcode;
|
|
GCodeProcessor proc;
|
|
proc.initialize_from_context(context);
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|
run_processor(proc, config, enveloped.c_str());
|
|
auto times = travel_times_by_tool(proc.get_result());
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|
REQUIRE(times.size() == 3);
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|
REQUIRE_THAT(times[1], Catch::Matchers::WithinRel(100.0 / 80.0, 0.10));
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|
REQUIRE_THAT(times[2], Catch::Matchers::WithinRel(101.0 / 80.0, 0.10));
|
|
}
|
|
SECTION("no grouping context degrades to slot 0") {
|
|
GCodeProcessor proc;
|
|
run_processor(proc, config, gcode);
|
|
auto times = travel_times_by_tool(proc.get_result());
|
|
REQUIRE(times.size() == 3);
|
|
REQUIRE_THAT(times[1], Catch::Matchers::WithinRel(100.0 / 200.0, 0.10));
|
|
REQUIRE_THAT(times[2], Catch::Matchers::WithinRel(101.0 / 200.0, 0.10));
|
|
}
|
|
}
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