//: The goal of this skeleton is to make programs more easy to understand and //: more malleable, easy to rewrite in radical ways without accidentally //: breaking some corner case. Tests further both goals. They help //: understandability by letting one make small changes and get feedback. What //: if I wrote this line like so? What if I removed this function call, is it //: really necessary? Just try it, see if the tests pass. Want to explore //: rewriting this bit in this way? Tests put many refactorings on a firmer //: footing. //: //: But the usual way we write tests seems incomplete. Refactorings tend to //: work in the small, but don't help with changes to function boundaries. If //: you want to extract a new function you have to manually test-drive it to //: create tests for it. If you want to inline a function its tests are no //: longer valid. In both cases you end up having to reorganize code as well as //: tests, an error-prone activity. //: //: This file tries to fix this problem by supporting domain-driven testing //: We try to focus on the domain of inputs the program should work on. All //: tests invoke the program in a single way: by calling run() with different //: inputs. The program operates on the input and logs _facts_ it deduces to a //: trace: //: trace("label") << "fact 1: " << val; //: //: The tests check for facts: //: :(scenario foo) //: 34 # call run() with this input //: +label: fact 1: 34 # trace should have logged this at the end //: -label: fact 1: 35 # trace should never contain such a line //: //: Since we never call anything but the run() function directly, we never have //: to rewrite the tests when we reorganize the internals of the program. We //: just have to make sure our rewrite deduces the same facts about the domain, //: and that's something we're going to have to do anyway. //: //: To avoid the combinatorial explosion of integration tests, we organize the //: program into different layers, and each fact is logged to the trace with a //: specific label. Individual tests can focus on specific labels. In essence, //: validating the facts logged with a specific label is identical to calling //: some internal subsystem. //: //: Traces interact salubriously with layers. Thanks to our ordering //: directives, each layer can contain its own tests. They may rely on other //: layers, but when a test fails its usually due to breakage in the same //: layer. When multiple tests fail, it's usually useful to debug the very //: first test to fail. This is in contrast with the traditional approach, //: where changes can cause breakages in faraway subsystems, and picking the //: right test to debug can be an important skill to pick up. //: //: A final wrinkle is for recursive functions; it's often useful to segment //: calls of different depth in the trace: //: +eval/1: => 34 # the topmost call to eval should have logged this line //: (look at new_trace_frame below) //: //: To build robust tests, trace facts about your domain rather than details of //: how you computed them. //: //: More details: http://akkartik.name/blog/tracing-tests //: //: --- //: //: Between layers and domain-driven testing, programming starts to look like a //: fundamentally different activity. Instead of a) superficial, b) local rules //: on c) code [like http://blog.bbv.ch/2013/06/05/clean-code-cheat-sheet], //: we allow programmers to engage with the a) deep, b) global structure of the //: c) domain. If you can systematically track discontinuities in the domain //: you don't care if the code used gotos as long as it passed the tests. If //: tests become more robust to run it becomes easier to try out radically //: different implementations for the same program. If code is super-easy to //: rewrite, it becomes less important what indentation style it uses, or that //: the objects are appropriately encapsulated, or that the functions are //: referentially transparent. //: //: Instead of plumbing, programming becomes building and gradually refining a //: map of the environment the program must operate under. Whether a program is //: 'correct' at a given point in time is a red herring; what matters is //: avoiding regression by monotonically nailing down the more 'eventful' parts //: of the terrain. It helps readers new and old and rewards curiosity to //: organize large programs in self-similar hiearchies of example scenarios //: colocated with the code that makes them work. //: //: "Programming properly should be regarded as an activity by which //: programmers form a mental model, rather than as production of a program." //: -- Peter Naur (http://alistair.cockburn.us/ASD+book+extract%3A+%22Naur,+Ehn,+Musashi%22) :(before "int main") // End Tracing // hack to ensure most code in this layer comes before anything else :(before "End Tracing") bool Hide_warnings = false; :(before "End Setup") //? cerr << "AAA setup\n"; //? 2 Hide_warnings = false; :(before "End Tracing") struct trace_stream { vector > > past_lines; // [(layer label, frame, line)] map frame; // accumulator for current line ostringstream* curr_stream; string curr_layer; string dump_layer; trace_stream() :curr_stream(NULL) {} ~trace_stream() { if (curr_stream) delete curr_stream; } ostringstream& stream(string layer) { newline(); curr_stream = new ostringstream; curr_layer = layer; return *curr_stream; } // be sure to call this before messing with curr_stream or curr_layer or frame void newline() { if (!curr_stream) return; string curr_contents = curr_stream->str(); curr_contents.erase(curr_contents.find_last_not_of("\r\n")+1); past_lines.push_back(pair >(curr_layer, pair(frame[curr_layer], curr_contents))); if (curr_layer == dump_layer || curr_layer == "dump" || dump_layer == "all" || (!Hide_warnings && curr_layer == "warn")) cerr << curr_layer << '/' << frame[curr_layer] << ": " << curr_contents << '\n'; delete curr_stream; curr_stream = NULL; } // Useful for debugging. string readable_contents(string layer) { // missing layer = everything, frame, hierarchical layers newline(); ostringstream output; string real_layer, frame; parse_layer_and_frame(layer, &real_layer, &frame); for (vector > >::iterator p = past_lines.begin(); p != past_lines.end(); ++p) if (layer.empty() || prefix_match(real_layer, p->first)) output << p->first << "/" << p->second.first << ": " << p->second.second << '\n'; return output.str(); } // Useful for a newcomer to visualize the program at work. void dump_browseable_contents(string layer) { ofstream dump("dump"); dump << "
start
\n"; for (vector > >::iterator p = past_lines.begin(); p != past_lines.end(); ++p) { if (p->first != layer) continue; dump << "
"; dump << p->second.second; dump << "
\n"; } dump.close(); } }; trace_stream* Trace_stream = NULL; // Top-level helper. IMPORTANT: can't nest. #define trace(layer) !Trace_stream ? cerr /*print nothing*/ : Trace_stream->stream(layer) // Warnings should go straight to cerr by default since calls to trace() have // some unfriendly constraints (they delay printing, they can't nest) #define raise ((!Trace_stream || !Hide_warnings) ? cerr /*do print*/ : Trace_stream->stream("warn")) // A separate helper for debugging. We should only trace domain-specific // facts. For everything else use log. #define xlog if (false) log // To turn on logging replace 'xlog' with 'log'. #define log cerr :(before "End Types") // raise << die exits after printing -- unless Hide_warnings is set. struct die {}; :(before "End Tracing") ostream& operator<<(ostream& os, unused die) { if (Hide_warnings) return os; os << "dying"; if (Trace_stream) Trace_stream->newline(); exit(1); } #define CLEAR_TRACE delete Trace_stream, Trace_stream = new trace_stream; #define DUMP(layer) if (Trace_stream) cerr << Trace_stream->readable_contents(layer); // Trace_stream is a resource, lease_tracer uses RAII to manage it. string Trace_file; static string Trace_dir = ".traces/"; struct lease_tracer { lease_tracer() { Trace_stream = new trace_stream; } ~lease_tracer() { //? cerr << "write to file? " << Trace_file << "$\n"; //? 2 if (!Trace_file.empty()) { //? cerr << "writing\n"; //? 2 ofstream fout((Trace_dir+Trace_file).c_str()); fout << Trace_stream->readable_contents(""); fout.close(); } delete Trace_stream, Trace_stream = NULL, Trace_file = ""; } }; // To transparently save traces, start tests with the TEST() macro. #define TEST(name) void test_##name() { Trace_file = #name; #define START_TRACING_UNTIL_END_OF_SCOPE lease_tracer leased_tracer; :(before "End Test Setup") START_TRACING_UNTIL_END_OF_SCOPE //? Trace_stream->dump_layer = "all"; //? 1 :(before "End Tracing") void trace_all(const string& label, const list& in) { for (list::const_iterator p = in.begin(); p != in.end(); ++p) trace(label) << *p; } bool check_trace_contents(string FUNCTION, string FILE, int LINE, string expected) { // missing layer == anywhere, frame, hierarchical layers vector expected_lines = split(expected, ""); index_t curr_expected_line = 0; while (curr_expected_line < expected_lines.size() && expected_lines[curr_expected_line].empty()) ++curr_expected_line; if (curr_expected_line == expected_lines.size()) return true; Trace_stream->newline(); string layer, frame, contents; parse_layer_frame_contents(expected_lines[curr_expected_line], &layer, &frame, &contents); for (vector > >::iterator p = Trace_stream->past_lines.begin(); p != Trace_stream->past_lines.end(); ++p) { if (!layer.empty() && !prefix_match(layer, p->first)) continue; if (!frame.empty() && strtol(frame.c_str(), NULL, 0) != p->second.first) continue; if (contents != p->second.second) continue; ++curr_expected_line; while (curr_expected_line < expected_lines.size() && expected_lines[curr_expected_line].empty()) ++curr_expected_line; if (curr_expected_line == expected_lines.size()) return true; parse_layer_frame_contents(expected_lines[curr_expected_line], &layer, &frame, &contents); } ++Num_failures; cerr << "\nF " << FUNCTION << "(" << FILE << ":" << LINE << "): missing [" << contents << "] in trace:\n"; DUMP(layer); Passed = false; return false; } void parse_layer_frame_contents(const string& orig, string* layer, string* frame, string* contents) { string layer_and_frame; parse_contents(orig, ": ", &layer_and_frame, contents); parse_layer_and_frame(layer_and_frame, layer, frame); } void parse_contents(const string& s, const string& delim, string* prefix, string* contents) { index_t pos = s.find(delim); if (pos == NOT_FOUND) { *prefix = ""; *contents = s; } else { *prefix = s.substr(0, pos); *contents = s.substr(pos+delim.size()); } } void parse_layer_and_frame(const string& orig, string* layer, string* frame) { index_t last_slash = orig.rfind('/'); if (last_slash == NOT_FOUND || orig.find_last_not_of("0123456789") != last_slash) { *layer = orig; *frame = ""; } else { *layer = orig.substr(0, last_slash); *frame = orig.substr(last_slash+1); } } bool check_trace_contents(string FUNCTION, string FILE, int LINE, string layer, string expected) { // empty layer == everything, multiple layers, hierarchical layers vector expected_lines = split(expected, ""); index_t curr_expected_line = 0; while (curr_expected_line < expected_lines.size() && expected_lines[curr_expected_line].empty()) ++curr_expected_line; if (curr_expected_line == expected_lines.size()) return true; Trace_stream->newline(); vector layers = split(layer, ","); for (vector > >::iterator p = Trace_stream->past_lines.begin(); p != Trace_stream->past_lines.end(); ++p) { if (!layer.empty() && !any_prefix_match(layers, p->first)) continue; if (p->second.second != expected_lines[curr_expected_line]) continue; ++curr_expected_line; while (curr_expected_line < expected_lines.size() && expected_lines[curr_expected_line].empty()) ++curr_expected_line; if (curr_expected_line == expected_lines.size()) return true; } ++Num_failures; cerr << "\nF " << FUNCTION << "(" << FILE << ":" << LINE << "): missing [" << expected_lines[curr_expected_line] << "] in trace:\n"; DUMP(layer); Passed = false; return false; } #define CHECK_TRACE_CONTENTS(...) check_trace_contents(__FUNCTION__, __FILE__, __LINE__, __VA_ARGS__) int trace_count(string layer) { return trace_count(layer, ""); } int trace_count(string layer, string line) { Trace_stream->newline(); long result = 0; vector layers = split(layer, ","); for (vector > >::iterator p = Trace_stream->past_lines.begin(); p != Trace_stream->past_lines.end(); ++p) { if (any_prefix_match(layers, p->first)) if (line == "" || p->second.second == line) ++result; } return result; } int trace_count(string layer, int frame, string line) { Trace_stream->newline(); long result = 0; vector layers = split(layer, ","); for (vector > >::iterator p = Trace_stream->past_lines.begin(); p != Trace_stream->past_lines.end(); ++p) { if (any_prefix_match(layers, p->first) && p->second.first == frame) if (line == "" || p->second.second == line) ++result; } return result; } #define CHECK_TRACE_WARNS() CHECK(trace_count("warn") > 0) #define CHECK_TRACE_DOESNT_WARN() \ if (trace_count("warn") > 0) { \ ++Num_failures; \ cerr << "\nF " << __FUNCTION__ << "(" << __FILE__ << ":" << __LINE__ << "): unexpected warnings\n"; \ DUMP("warn"); \ Passed = false; \ return; \ } bool trace_doesnt_contain(string layer, string line) { return trace_count(layer, line) == 0; } bool trace_doesnt_contain(string expected) { vector tmp = split(expected, ": "); return trace_doesnt_contain(tmp[0], tmp[1]); } bool trace_doesnt_contain(string layer, int frame, string line) { return trace_count(layer, frame, line) == 0; } #define CHECK_TRACE_DOESNT_CONTAIN(...) CHECK(trace_doesnt_contain(__VA_ARGS__)) // manage layer counts in Trace_stream using RAII struct lease_trace_frame { string layer; lease_trace_frame(string l) :layer(l) { if (!Trace_stream) return; Trace_stream->newline(); ++Trace_stream->frame[layer]; } ~lease_trace_frame() { if (!Trace_stream) return; Trace_stream->newline(); --Trace_stream->frame[layer]; } }; #define new_trace_frame(layer) lease_trace_frame leased_frame(layer); bool check_trace_contents(string FUNCTION, string FILE, int LINE, string layer, int frame, string expected) { // multiple layers, hierarchical layers vector expected_lines = split(expected, ""); // hack: doesn't handle newlines in embedded in lines index_t curr_expected_line = 0; while (curr_expected_line < expected_lines.size() && expected_lines[curr_expected_line].empty()) ++curr_expected_line; if (curr_expected_line == expected_lines.size()) return true; Trace_stream->newline(); vector layers = split(layer, ","); for (vector > >::iterator p = Trace_stream->past_lines.begin(); p != Trace_stream->past_lines.end(); ++p) { if (!layer.empty() && !any_prefix_match(layers, p->first)) continue; if (p->second.first != frame) continue; if (p->second.second != expected_lines[curr_expected_line]) continue; ++curr_expected_line; while (curr_expected_line < expected_lines.size() && expected_lines[curr_expected_line].empty()) ++curr_expected_line; if (curr_expected_line == expected_lines.size()) return true; } ++Num_failures; cerr << "\nF " << FUNCTION << "(" << FILE << ":" << LINE << "): missing [" << expected_lines[curr_expected_line] << "] in trace/" << frame << ":\n"; DUMP(layer); Passed = false; return false; } #define CHECK_TRACE_TOP(layer, expected) CHECK_TRACE_CONTENTS(layer, 1, expected) vector split(string s, string delim) { vector result; index_t begin=0, end=s.find(delim); while (true) { if (end == NOT_FOUND) { result.push_back(string(s, begin, NOT_FOUND)); break; } result.push_back(string(s, begin, end-begin)); begin = end+delim.size(); end = s.find(delim, begin); } return result; } bool any_prefix_match(const vector& pats, const string& needle) { if (pats.empty()) return false; if (*pats[0].rbegin() != '/') // prefix match not requested return find(pats.begin(), pats.end(), needle) != pats.end(); // first pat ends in a '/'; assume all pats do. for (vector::const_iterator p = pats.begin(); p != pats.end(); ++p) if (headmatch(needle, *p)) return true; return false; } bool prefix_match(const string& pat, const string& needle) { if (*pat.rbegin() != '/') // prefix match not requested return pat == needle; return headmatch(needle, pat); } bool headmatch(const string& s, const string& pat) { if (pat.size() > s.size()) return false; return std::mismatch(pat.begin(), pat.end(), s.begin()).first == pat.end(); } :(before "End Includes") #include using std::vector; #include using std::list; #include using std::pair; #include using std::map; #include using std::set; #include #include using std::istream; using std::ostream; using std::cin; using std::cout; using std::cerr; #include using std::istringstream; using std::ostringstream; #include using std::ifstream; using std::ofstream; #define unused __attribute__((unused))