mirror of
https://github.com/fish-shell/fish-shell
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264 lines
9.3 KiB
C++
264 lines
9.3 KiB
C++
// Implementation of the math builtin.
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#include "config.h" // IWYU pragma: keep
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#include "builtin_math.h"
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#include <algorithm>
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#include <cerrno>
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#include <cmath>
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#include <cstddef>
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#include <cstring>
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#include <limits>
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#include <string>
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#include "builtin.h"
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#include "common.h"
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#include "fallback.h" // IWYU pragma: keep
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#include "io.h"
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#include "tinyexpr.h"
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#include "wgetopt.h"
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#include "wutil.h" // IWYU pragma: keep
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// The maximum number of points after the decimal that we'll print.
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static constexpr int kDefaultScale = 6;
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// The end of the range such that every integer is representable as a double.
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// i.e. this is the first value such that x + 1 == x (or == x + 2, depending on rounding mode).
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static constexpr double kMaximumContiguousInteger =
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double(1LLU << std::numeric_limits<double>::digits);
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struct math_cmd_opts_t {
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bool print_help = false;
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int scale = kDefaultScale;
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};
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// This command is atypical in using the "+" (REQUIRE_ORDER) option for flag parsing.
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// This is needed because of the minus, `-`, operator in math expressions.
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static const wchar_t *const short_options = L"+:hs:";
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static const struct woption long_options[] = {{L"scale", required_argument, nullptr, 's'},
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{L"help", no_argument, nullptr, 'h'},
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{nullptr, 0, nullptr, 0}};
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static int parse_cmd_opts(math_cmd_opts_t &opts, int *optind, //!OCLINT(high ncss method)
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int argc, wchar_t **argv, parser_t &parser, io_streams_t &streams) {
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const wchar_t *cmd = L"math";
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int opt;
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wgetopter_t w;
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while ((opt = w.wgetopt_long(argc, argv, short_options, long_options, nullptr)) != -1) {
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switch (opt) {
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case 's': {
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// "max" is the special value that tells us to pick the maximum scale.
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if (std::wcscmp(w.woptarg, L"max") == 0) {
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opts.scale = 15;
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} else {
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opts.scale = fish_wcstoi(w.woptarg);
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if (errno || opts.scale < 0 || opts.scale > 15) {
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streams.err.append_format(_(L"%ls: '%ls' is not a valid scale value\n"),
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cmd, w.woptarg);
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return STATUS_INVALID_ARGS;
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}
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}
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break;
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}
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case 'h': {
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opts.print_help = true;
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break;
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}
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case ':': {
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builtin_missing_argument(parser, streams, cmd, argv[w.woptind - 1]);
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return STATUS_INVALID_ARGS;
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}
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case '?': {
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// For most commands this is an error. We ignore it because a math expression
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// can begin with a minus sign.
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*optind = w.woptind - 1;
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return STATUS_CMD_OK;
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}
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default: {
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DIE("unexpected retval from wgetopt_long");
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}
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}
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}
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*optind = w.woptind;
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return STATUS_CMD_OK;
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}
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// We read from stdin if we are the second or later process in a pipeline.
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static bool math_args_from_stdin(const io_streams_t &streams) {
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return streams.stdin_is_directly_redirected;
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}
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/// Get the arguments from stdin.
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static const wchar_t *math_get_arg_stdin(wcstring *storage, const io_streams_t &streams) {
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std::string arg;
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for (;;) {
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char ch = '\0';
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long rc = read_blocked(streams.stdin_fd, &ch, 1);
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if (rc < 0) return nullptr; // failure
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if (rc == 0) { // EOF
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if (arg.empty()) return nullptr;
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break;
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}
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if (ch == '\n') break; // we're done
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arg += ch;
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}
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*storage = str2wcstring(arg);
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return storage->c_str();
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}
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/// Return the next argument from argv.
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static const wchar_t *math_get_arg_argv(int *argidx, wchar_t **argv) {
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return argv && argv[*argidx] ? argv[(*argidx)++] : nullptr;
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}
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/// Get the arguments from argv or stdin based on the execution context. This mimics how builtin
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/// `string` does it.
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static const wchar_t *math_get_arg(int *argidx, wchar_t **argv, wcstring *storage,
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const io_streams_t &streams) {
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if (math_args_from_stdin(streams)) {
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return math_get_arg_stdin(storage, streams);
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}
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return math_get_arg_argv(argidx, argv);
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}
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static const wchar_t *math_describe_error(const te_error_t &error) {
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if (error.position == 0) return L"NO ERROR?!?";
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switch (error.type) {
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case TE_ERROR_NONE:
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DIE("Error has no position");
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case TE_ERROR_UNKNOWN_FUNCTION:
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return _(L"Unknown function");
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case TE_ERROR_MISSING_CLOSING_PAREN:
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return _(L"Missing closing parenthesis");
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case TE_ERROR_MISSING_OPENING_PAREN:
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return _(L"Missing opening parenthesis");
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case TE_ERROR_TOO_FEW_ARGS:
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return _(L"Too few arguments");
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case TE_ERROR_TOO_MANY_ARGS:
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return _(L"Too many arguments");
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case TE_ERROR_MISSING_OPERATOR:
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return _(L"Missing operator");
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case TE_ERROR_UNEXPECTED_TOKEN:
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return _(L"Unexpected token");
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case TE_ERROR_LOGICAL_OPERATOR:
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return _(L"Logical operations are not supported, use `test` instead");
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case TE_ERROR_UNKNOWN:
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return _(L"Expression is bogus");
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default:
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return L"Unknown error";
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}
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}
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/// Return a formatted version of the value \p v respecting the given \p opts.
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static wcstring format_double(double v, const math_cmd_opts_t &opts) {
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// As a special-case, a scale of 0 means to truncate to an integer
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// instead of rounding.
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if (opts.scale == 0) {
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v = trunc(v);
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return format_string(L"%.*f", opts.scale, v);
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}
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wcstring ret = format_string(L"%.*f", opts.scale, v);
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// If we contain a decimal separator, trim trailing zeros after it, and then the separator
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// itself if there's nothing after it. Detect a decimal separator as a non-digit.
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const wchar_t *const digits = L"0123456789";
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if (ret.find_first_not_of(digits) != wcstring::npos) {
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while (ret.back() == L'0') {
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ret.pop_back();
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}
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if (!std::wcschr(digits, ret.back())) {
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ret.pop_back();
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}
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}
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// If we trimmed everything it must have just been zero.
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if (ret.empty()) {
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ret.push_back(L'0');
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}
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return ret;
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}
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/// Evaluate math expressions.
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static int evaluate_expression(const wchar_t *cmd, const parser_t &parser, io_streams_t &streams,
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const math_cmd_opts_t &opts, wcstring &expression) {
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UNUSED(parser);
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int retval = STATUS_CMD_OK;
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te_error_t error;
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std::string narrow_str = wcs2string(expression);
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// Switch locale while computing stuff.
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// This means that the "." is always the radix character,
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// so numbers work the same across locales.
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char *saved_locale = strdup(setlocale(LC_NUMERIC, nullptr));
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setlocale(LC_NUMERIC, "C");
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double v = te_interp(narrow_str.c_str(), &error);
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if (error.position == 0) {
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// Check some runtime errors after the fact.
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// TODO: Really, this should be done in tinyexpr
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// (e.g. infinite is the result of "x / 0"),
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// but that's much more work.
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const char *error_message = nullptr;
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if (std::isinf(v)) {
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error_message = "Result is infinite";
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} else if (std::isnan(v)) {
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error_message = "Result is not a number";
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} else if (std::abs(v) >= kMaximumContiguousInteger) {
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error_message = "Result magnitude is too large";
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}
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if (error_message) {
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streams.err.append_format(L"%ls: Error: %s\n", cmd, error_message);
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streams.err.append_format(L"'%ls'\n", expression.c_str());
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retval = STATUS_CMD_ERROR;
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} else {
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streams.out.append(format_double(v, opts));
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streams.out.push_back(L'\n');
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}
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} else {
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streams.err.append_format(L"%ls: Error: %ls\n", cmd, math_describe_error(error));
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streams.err.append_format(L"'%ls'\n", expression.c_str());
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streams.err.append_format(L"%*ls%ls\n", error.position - 1, L" ", L"^");
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retval = STATUS_CMD_ERROR;
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}
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setlocale(LC_NUMERIC, saved_locale);
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free(saved_locale);
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return retval;
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}
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/// The math builtin evaluates math expressions.
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maybe_t<int> builtin_math(parser_t &parser, io_streams_t &streams, wchar_t **argv) {
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wchar_t *cmd = argv[0];
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int argc = builtin_count_args(argv);
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math_cmd_opts_t opts;
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int optind;
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// Is this really the right way to handle no expression present?
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// if (argc == 0) return STATUS_CMD_OK;
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int retval = parse_cmd_opts(opts, &optind, argc, argv, parser, streams);
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if (retval != STATUS_CMD_OK) return retval;
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if (opts.print_help) {
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builtin_print_help(parser, streams, cmd);
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return STATUS_CMD_OK;
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}
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wcstring expression;
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wcstring storage;
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while (const wchar_t *arg = math_get_arg(&optind, argv, &storage, streams)) {
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if (!expression.empty()) expression.push_back(L' ');
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expression.append(arg);
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}
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if (expression.empty()) {
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streams.err.append_format(BUILTIN_ERR_MIN_ARG_COUNT1, L"math", 1, 0);
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return STATUS_CMD_ERROR;
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}
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return evaluate_expression(cmd, parser, streams, opts, expression);
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}
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