// Implementation of the random builtin. #include "config.h" // IWYU pragma: keep #include #include #include #include #include #include "builtin.h" #include "builtin_random.h" #include "common.h" #include "fallback.h" // IWYU pragma: keep #include "io.h" #include "wutil.h" // IWYU pragma: keep /// The random builtin generates random numbers. int builtin_random(parser_t &parser, io_streams_t &streams, wchar_t **argv) { wchar_t *cmd = argv[0]; int argc = builtin_count_args(argv); help_only_cmd_opts_t opts; int optind; int retval = parse_help_only_cmd_opts(opts, &optind, argc, argv, parser, streams); if (retval != STATUS_CMD_OK) return retval; if (opts.print_help) { builtin_print_help(parser, streams, cmd, streams.out); return STATUS_CMD_OK; } static bool seeded = false; static std::minstd_rand engine; if (!seeded) { // seed engine with 2*32 bits of random data // for the 64 bits of internal state of minstd_rand std::random_device rd; std::seed_seq seed{rd(), rd()}; engine.seed(seed); seeded = true; } int arg_count = argc - optind; long long start, end; unsigned long long step; bool choice = false; if (arg_count >= 1 && !wcscmp(argv[optind], L"choice")) { if (arg_count == 1) { streams.err.append_format(L"%ls: nothing to choose from\n", cmd); return STATUS_INVALID_ARGS; } choice = true; start = 1; step = 1; end = arg_count - 1; } else { bool parse_error = false; auto parse_ll = [&](const wchar_t *str) { long long ll = fish_wcstoll(str); if (errno) { streams.err.append_format(L"%ls: %ls is not a valid integer\n", cmd, str); parse_error = true; } return ll; }; auto parse_ull = [&](const wchar_t *str) { unsigned long long ull = fish_wcstoull(str); if (errno) { streams.err.append_format(L"%ls: %ls is not a valid integer\n", cmd, str); parse_error = true; } return ull; }; if (arg_count == 0) { start = 0; end = 32767; step = 1; } else if (arg_count == 1) { long long seed = parse_ll(argv[optind]); if (parse_error) return STATUS_INVALID_ARGS; engine.seed(static_cast(seed)); return STATUS_CMD_OK; } else if (arg_count == 2) { start = parse_ll(argv[optind]); step = 1; end = parse_ll(argv[optind + 1]); } else if (arg_count == 3) { start = parse_ll(argv[optind]); step = parse_ull(argv[optind + 1]); end = parse_ll(argv[optind + 2]); } else { streams.err.append_format(BUILTIN_ERR_TOO_MANY_ARGUMENTS, cmd); return STATUS_INVALID_ARGS; } if (parse_error) { return STATUS_INVALID_ARGS; } else if (start >= end) { streams.err.append_format(L"%ls: END must be greater than START\n", cmd); return STATUS_INVALID_ARGS; } else if (step == 0) { streams.err.append_format(L"%ls: STEP must be a positive integer\n", cmd); return STATUS_INVALID_ARGS; } } // only for negative argument auto safe_abs = [](long long ll) -> unsigned long long { return -static_cast(ll); }; long long real_end; if (start >= 0 || end < 0) { // 0 <= start <= end long long diff = end - start; // 0 <= diff <= LL_MAX real_end = start + static_cast(diff / step); } else { // start < 0 <= end unsigned long long abs_start = safe_abs(start); unsigned long long diff = (end + abs_start); real_end = diff / step - abs_start; } if (!choice && start == real_end) { streams.err.append_format(L"%ls: range contains only one possible value\n", cmd); return STATUS_INVALID_ARGS; } std::uniform_int_distribution dist(start, real_end); long long random = dist(engine); long long result; if (start >= 0) { // 0 <= start <= random <= end long long diff = random - start; // 0 < step * diff <= end - start <= LL_MAX result = start + static_cast(diff * step); } else if (random < 0) { // start <= random < 0 long long diff = random - start; result = diff * step - safe_abs(start); } else { // start < 0 <= random unsigned long long abs_start = safe_abs(start); unsigned long long diff = (random + abs_start); result = diff * step - abs_start; } if (choice) { streams.out.append_format(L"%ls\n", argv[optind + result]); } else { streams.out.append_format(L"%lld\n", result); } return STATUS_CMD_OK; }