absl/strings/internal/str_format/parser_test.cc - mirrors/cros/chromiumos/third_party/webrtc-apm - Git at Google

 #include "absl/strings/internal/str_format/parser.h"

 #include <string.h>
 #include "gtest/gtest.h"
 #include "absl/base/macros.h"

 namespace absl {
 namespace str_format_internal {

 namespace {

 TEST(LengthModTest, Names) {
   struct Expectation {
     int line;
     LengthMod::Id id;
     const char *name;
   };
   const Expectation kExpect[] = {
     {__LINE__, LengthMod::none, ""  },
     {__LINE__, LengthMod::h,    "h" },
     {__LINE__, LengthMod::hh,   "hh"},
     {__LINE__, LengthMod::l,    "l" },
     {__LINE__, LengthMod::ll,   "ll"},
     {__LINE__, LengthMod::L,    "L" },
     {__LINE__, LengthMod::j,    "j" },
     {__LINE__, LengthMod::z,    "z" },
     {__LINE__, LengthMod::t,    "t" },
     {__LINE__, LengthMod::q,    "q" },
   };
   EXPECT_EQ(ABSL_ARRAYSIZE(kExpect), LengthMod::kNumValues);
   for (auto e : kExpect) {
     SCOPED_TRACE(e.line);
     LengthMod mod = LengthMod::FromId(e.id);
     EXPECT_EQ(e.id, mod.id());
     EXPECT_EQ(e.name, mod.name());
   }
 }

 TEST(ConversionCharTest, Names) {
   struct Expectation {
     ConversionChar::Id id;
     char name;
   };
   // clang-format off
   const Expectation kExpect[] = {
 #define X(c) {ConversionChar::c, #c[0]}
     X(c), X(C), X(s), X(S),                          // text
     X(d), X(i), X(o), X(u), X(x), X(X),              // int
     X(f), X(F), X(e), X(E), X(g), X(G), X(a), X(A),  // float
     X(n), X(p),                                      // misc
 #undef X
     {ConversionChar::none, '\0'},
   };
   // clang-format on
   EXPECT_EQ(ABSL_ARRAYSIZE(kExpect), ConversionChar::kNumValues);
   for (auto e : kExpect) {
     SCOPED_TRACE(e.name);
     ConversionChar v = ConversionChar::FromId(e.id);
     EXPECT_EQ(e.id, v.id());
     EXPECT_EQ(e.name, v.Char());
   }
 }

 class ConsumeUnboundConversionTest : public ::testing::Test {
  public:
   typedef UnboundConversion Props;
   string_view Consume(string_view* src) {
     int next = 0;
     const char* prev_begin = src->data();
     o = UnboundConversion();  // refresh
     ConsumeUnboundConversion(src, &o, &next);
     return {prev_begin, static_cast<size_t>(src->data() - prev_begin)};
   }

   bool Run(const char *fmt, bool force_positional = false) {
     string_view src = fmt;
     int next = force_positional ? -1 : 0;
     o = UnboundConversion();  // refresh
     return ConsumeUnboundConversion(&src, &o, &next) && src.empty();
   }
   UnboundConversion o;
 };

 TEST_F(ConsumeUnboundConversionTest, ConsumeSpecification) {
   struct Expectation {
     int line;
     string_view src;
     string_view out;
     string_view src_post;
   };
   const Expectation kExpect[] = {
     {__LINE__, "",     "",     ""  },
     {__LINE__, "b",    "",     "b" },  // 'b' is invalid
     {__LINE__, "ba",   "",     "ba"},  // 'b' is invalid
     {__LINE__, "l",    "",     "l" },  // just length mod isn't okay
     {__LINE__, "d",    "d",    ""  },  // basic
     {__LINE__, "d ",   "d",    " " },  // leave suffix
     {__LINE__, "dd",   "d",    "d" },  // don't be greedy
     {__LINE__, "d9",   "d",    "9" },  // leave non-space suffix
     {__LINE__, "dzz",  "d",    "zz"},  // length mod as suffix
     {__LINE__, "1$*2$d", "1$*2$d", ""  },  // arg indexing and * allowed.
     {__LINE__, "0-14.3hhd", "0-14.3hhd", ""},  // precision, width
     {__LINE__, " 0-+#14.3hhd", " 0-+#14.3hhd", ""},  // flags
   };
   for (const auto& e : kExpect) {
     SCOPED_TRACE(e.line);
     string_view src = e.src;
     EXPECT_EQ(e.src, src);
     string_view out = Consume(&src);
     EXPECT_EQ(e.out, out);
     EXPECT_EQ(e.src_post, src);
   }
 }

 TEST_F(ConsumeUnboundConversionTest, BasicConversion) {
   EXPECT_FALSE(Run(""));
   EXPECT_FALSE(Run("z"));

   EXPECT_FALSE(Run("dd"));  // no excess allowed

   EXPECT_TRUE(Run("d"));
   EXPECT_EQ('d', o.conv.Char());
   EXPECT_FALSE(o.width.is_from_arg());
   EXPECT_LT(o.width.value(), 0);
   EXPECT_FALSE(o.precision.is_from_arg());
   EXPECT_LT(o.precision.value(), 0);
   EXPECT_EQ(1, o.arg_position);
   EXPECT_EQ(LengthMod::none, o.length_mod.id());
 }

 TEST_F(ConsumeUnboundConversionTest, ArgPosition) {
   EXPECT_TRUE(Run("d"));
   EXPECT_EQ(1, o.arg_position);
   EXPECT_TRUE(Run("3$d"));
   EXPECT_EQ(3, o.arg_position);
   EXPECT_TRUE(Run("1$d"));
   EXPECT_EQ(1, o.arg_position);
   EXPECT_TRUE(Run("1$d", true));
   EXPECT_EQ(1, o.arg_position);
   EXPECT_TRUE(Run("123$d"));
   EXPECT_EQ(123, o.arg_position);
   EXPECT_TRUE(Run("123$d", true));
   EXPECT_EQ(123, o.arg_position);
   EXPECT_TRUE(Run("10$d"));
   EXPECT_EQ(10, o.arg_position);
   EXPECT_TRUE(Run("10$d", true));
   EXPECT_EQ(10, o.arg_position);

   // Position can't be zero.
   EXPECT_FALSE(Run("0$d"));
   EXPECT_FALSE(Run("0$d", true));
   EXPECT_FALSE(Run("1$*0$d"));
   EXPECT_FALSE(Run("1$.*0$d"));

   // Position can't start with a zero digit at all. That is not a 'decimal'.
   EXPECT_FALSE(Run("01$p"));
   EXPECT_FALSE(Run("01$p", true));
   EXPECT_FALSE(Run("1$*01$p"));
   EXPECT_FALSE(Run("1$.*01$p"));
 }

 TEST_F(ConsumeUnboundConversionTest, WidthAndPrecision) {
   EXPECT_TRUE(Run("14d"));
   EXPECT_EQ('d', o.conv.Char());
   EXPECT_FALSE(o.width.is_from_arg());
   EXPECT_EQ(14, o.width.value());
   EXPECT_FALSE(o.precision.is_from_arg());
   EXPECT_LT(o.precision.value(), 0);

   EXPECT_TRUE(Run("14.d"));
   EXPECT_FALSE(o.width.is_from_arg());
   EXPECT_FALSE(o.precision.is_from_arg());
   EXPECT_EQ(14, o.width.value());
   EXPECT_EQ(0, o.precision.value());

   EXPECT_TRUE(Run(".d"));
   EXPECT_FALSE(o.width.is_from_arg());
   EXPECT_LT(o.width.value(), 0);
   EXPECT_FALSE(o.precision.is_from_arg());
   EXPECT_EQ(0, o.precision.value());

   EXPECT_TRUE(Run(".5d"));
   EXPECT_FALSE(o.width.is_from_arg());
   EXPECT_LT(o.width.value(), 0);
   EXPECT_FALSE(o.precision.is_from_arg());
   EXPECT_EQ(5, o.precision.value());

   EXPECT_TRUE(Run(".0d"));
   EXPECT_FALSE(o.width.is_from_arg());
   EXPECT_LT(o.width.value(), 0);
   EXPECT_FALSE(o.precision.is_from_arg());
   EXPECT_EQ(0, o.precision.value());

   EXPECT_TRUE(Run("14.5d"));
   EXPECT_FALSE(o.width.is_from_arg());
   EXPECT_FALSE(o.precision.is_from_arg());
   EXPECT_EQ(14, o.width.value());
   EXPECT_EQ(5, o.precision.value());

   EXPECT_TRUE(Run("*.*d"));
   EXPECT_TRUE(o.width.is_from_arg());
   EXPECT_EQ(1, o.width.get_from_arg());
   EXPECT_TRUE(o.precision.is_from_arg());
   EXPECT_EQ(2, o.precision.get_from_arg());
   EXPECT_EQ(3, o.arg_position);

   EXPECT_TRUE(Run("*d"));
   EXPECT_TRUE(o.width.is_from_arg());
   EXPECT_EQ(1, o.width.get_from_arg());
   EXPECT_FALSE(o.precision.is_from_arg());
   EXPECT_LT(o.precision.value(), 0);
   EXPECT_EQ(2, o.arg_position);

   EXPECT_TRUE(Run(".*d"));
   EXPECT_FALSE(o.width.is_from_arg());
   EXPECT_LT(o.width.value(), 0);
   EXPECT_TRUE(o.precision.is_from_arg());
   EXPECT_EQ(1, o.precision.get_from_arg());
   EXPECT_EQ(2, o.arg_position);

   // mixed implicit and explicit: didn't specify arg position.
   EXPECT_FALSE(Run("*23$.*34$d"));

   EXPECT_TRUE(Run("12$*23$.*34$d"));
   EXPECT_EQ(12, o.arg_position);
   EXPECT_TRUE(o.width.is_from_arg());
   EXPECT_EQ(23, o.width.get_from_arg());
   EXPECT_TRUE(o.precision.is_from_arg());
   EXPECT_EQ(34, o.precision.get_from_arg());

   EXPECT_TRUE(Run("2$*5$.*9$d"));
   EXPECT_EQ(2, o.arg_position);
   EXPECT_TRUE(o.width.is_from_arg());
   EXPECT_EQ(5, o.width.get_from_arg());
   EXPECT_TRUE(o.precision.is_from_arg());
   EXPECT_EQ(9, o.precision.get_from_arg());

   EXPECT_FALSE(Run(".*0$d")) << "no arg 0";

   // Large values
   EXPECT_TRUE(Run("999999999.999999999d"));
   EXPECT_FALSE(o.width.is_from_arg());
   EXPECT_EQ(999999999, o.width.value());
   EXPECT_FALSE(o.precision.is_from_arg());
   EXPECT_EQ(999999999, o.precision.value());

   EXPECT_FALSE(Run("1000000000.999999999d"));
   EXPECT_FALSE(Run("999999999.1000000000d"));
   EXPECT_FALSE(Run("9999999999d"));
   EXPECT_FALSE(Run(".9999999999d"));
 }

 TEST_F(ConsumeUnboundConversionTest, Flags) {
   static const char kAllFlags[] = "-+ #0";
   static const int kNumFlags = ABSL_ARRAYSIZE(kAllFlags) - 1;
   for (int rev = 0; rev < 2; ++rev) {
     for (int i = 0; i < 1 << kNumFlags; ++i) {
       std::string fmt;
       for (int k = 0; k < kNumFlags; ++k)
         if ((i >> k) & 1) fmt += kAllFlags[k];
       // flag order shouldn't matter
       if (rev == 1) { std::reverse(fmt.begin(), fmt.end()); }
       fmt += 'd';
       SCOPED_TRACE(fmt);
       EXPECT_TRUE(Run(fmt.c_str()));
       EXPECT_EQ(fmt.find('-') == std::string::npos, !o.flags.left);
       EXPECT_EQ(fmt.find('+') == std::string::npos, !o.flags.show_pos);
       EXPECT_EQ(fmt.find(' ') == std::string::npos, !o.flags.sign_col);
       EXPECT_EQ(fmt.find('#') == std::string::npos, !o.flags.alt);
       EXPECT_EQ(fmt.find('0') == std::string::npos, !o.flags.zero);
     }
   }
 }

 TEST_F(ConsumeUnboundConversionTest, BasicFlag) {
   // Flag is on
   for (const char* fmt : {"d", "llx", "G", "1$X"}) {
     SCOPED_TRACE(fmt);
     EXPECT_TRUE(Run(fmt));
     EXPECT_TRUE(o.flags.basic);
   }

   // Flag is off
   for (const char* fmt : {"3d", ".llx", "-G", "1$#X"}) {
     SCOPED_TRACE(fmt);
     EXPECT_TRUE(Run(fmt));
     EXPECT_FALSE(o.flags.basic);
   }
 }

 struct SummarizeConsumer {
   std::string* out;
   explicit SummarizeConsumer(std::string* out) : out(out) {}

   bool Append(string_view s) {
     *out += "[" + std::string(s) + "]";
     return true;
   }

   bool ConvertOne(const UnboundConversion& conv, string_view s) {
     *out += "{";
     *out += std::string(s);
     *out += ":";
     *out += std::to_string(conv.arg_position) + "$";
     if (conv.width.is_from_arg()) {
       *out += std::to_string(conv.width.get_from_arg()) + "$*";
     }
     if (conv.precision.is_from_arg()) {
       *out += "." + std::to_string(conv.precision.get_from_arg()) + "$*";
     }
     *out += conv.conv.Char();
     *out += "}";
     return true;
   }
 };

 std::string SummarizeParsedFormat(const ParsedFormatBase& pc) {
   std::string out;
   if (!pc.ProcessFormat(SummarizeConsumer(&out))) out += "!";
   return out;
 }

 class ParsedFormatTest : public testing::Test {};

 TEST_F(ParsedFormatTest, ValueSemantics) {
   ParsedFormatBase p1({}, true, {});  // empty format
   EXPECT_EQ("", SummarizeParsedFormat(p1));

   ParsedFormatBase p2 = p1;  // copy construct (empty)
   EXPECT_EQ(SummarizeParsedFormat(p1), SummarizeParsedFormat(p2));

   p1 = ParsedFormatBase("hello%s", true, {Conv::s});  // move assign
   EXPECT_EQ("[hello]{s:1$s}", SummarizeParsedFormat(p1));

   ParsedFormatBase p3 = p1;  // copy construct (nonempty)
   EXPECT_EQ(SummarizeParsedFormat(p1), SummarizeParsedFormat(p3));

   using std::swap;
   swap(p1, p2);
   EXPECT_EQ("", SummarizeParsedFormat(p1));
   EXPECT_EQ("[hello]{s:1$s}", SummarizeParsedFormat(p2));
   swap(p1, p2);  // undo

   p2 = p1;  // copy assign
   EXPECT_EQ(SummarizeParsedFormat(p1), SummarizeParsedFormat(p2));
 }

 struct ExpectParse {
   const char* in;
   std::initializer_list<Conv> conv_set;
   const char* out;
 };

 TEST_F(ParsedFormatTest, Parsing) {
   // Parse should be equivalent to that obtained by ConversionParseIterator.
   // No need to retest the parsing edge cases here.
   const ExpectParse kExpect[] = {
       {"", {}, ""},
       {"ab", {}, "[ab]"},
       {"a%d", {Conv::d}, "[a]{d:1$d}"},
       {"a%+d", {Conv::d}, "[a]{+d:1$d}"},
       {"a% d", {Conv::d}, "[a]{ d:1$d}"},
       {"a%b %d", {}, "[a]!"},  // stop after error
   };
   for (const auto& e : kExpect) {
     SCOPED_TRACE(e.in);
     EXPECT_EQ(e.out,
               SummarizeParsedFormat(ParsedFormatBase(e.in, false, e.conv_set)));
   }
 }

 TEST_F(ParsedFormatTest, ParsingFlagOrder) {
   const ExpectParse kExpect[] = {
       {"a%+ 0d", {Conv::d}, "[a]{+ 0d:1$d}"},
       {"a%+0 d", {Conv::d}, "[a]{+0 d:1$d}"},
       {"a%0+ d", {Conv::d}, "[a]{0+ d:1$d}"},
       {"a% +0d", {Conv::d}, "[a]{ +0d:1$d}"},
       {"a%0 +d", {Conv::d}, "[a]{0 +d:1$d}"},
       {"a% 0+d", {Conv::d}, "[a]{ 0+d:1$d}"},
       {"a%+   0+d", {Conv::d}, "[a]{+   0+d:1$d}"},
   };
   for (const auto& e : kExpect) {
     SCOPED_TRACE(e.in);
     EXPECT_EQ(e.out,
               SummarizeParsedFormat(ParsedFormatBase(e.in, false, e.conv_set)));
   }
 }

 }  // namespace
 }  // namespace str_format_internal
 }  // namespace absl
	#include "absl/strings/internal/str_format/parser.h"

	#include <string.h>
	#include "gtest/gtest.h"
	#include "absl/base/macros.h"

	namespace absl {
	namespace str_format_internal {

	namespace {

	TEST(LengthModTest, Names) {
	struct Expectation {
	int line;
	LengthMod::Id id;
	const char *name;
	};
	const Expectation kExpect[] = {
	{__LINE__, LengthMod::none, "" },
	{__LINE__, LengthMod::h, "h" },
	{__LINE__, LengthMod::hh, "hh"},
	{__LINE__, LengthMod::l, "l" },
	{__LINE__, LengthMod::ll, "ll"},
	{__LINE__, LengthMod::L, "L" },
	{__LINE__, LengthMod::j, "j" },
	{__LINE__, LengthMod::z, "z" },
	{__LINE__, LengthMod::t, "t" },
	{__LINE__, LengthMod::q, "q" },
	};
	EXPECT_EQ(ABSL_ARRAYSIZE(kExpect), LengthMod::kNumValues);
	for (auto e : kExpect) {
	SCOPED_TRACE(e.line);
	LengthMod mod = LengthMod::FromId(e.id);
	EXPECT_EQ(e.id, mod.id());
	EXPECT_EQ(e.name, mod.name());
	}
	}

	TEST(ConversionCharTest, Names) {
	struct Expectation {
	ConversionChar::Id id;
	char name;
	};
	// clang-format off
	const Expectation kExpect[] = {
	#define X(c) {ConversionChar::c, #c[0]}
	X(c), X(C), X(s), X(S), // text
	X(d), X(i), X(o), X(u), X(x), X(X), // int
	X(f), X(F), X(e), X(E), X(g), X(G), X(a), X(A), // float
	X(n), X(p), // misc
	#undef X
	{ConversionChar::none, '\0'},
	};
	// clang-format on
	EXPECT_EQ(ABSL_ARRAYSIZE(kExpect), ConversionChar::kNumValues);
	for (auto e : kExpect) {
	SCOPED_TRACE(e.name);
	ConversionChar v = ConversionChar::FromId(e.id);
	EXPECT_EQ(e.id, v.id());
	EXPECT_EQ(e.name, v.Char());
	}
	}

	class ConsumeUnboundConversionTest : public ::testing::Test {
	public:
	typedef UnboundConversion Props;
	string_view Consume(string_view* src) {
	int next = 0;
	const char* prev_begin = src->data();
	o = UnboundConversion(); // refresh
	ConsumeUnboundConversion(src, &o, &next);
	return {prev_begin, static_cast<size_t>(src->data() - prev_begin)};
	}

	bool Run(const char *fmt, bool force_positional = false) {
	string_view src = fmt;
	int next = force_positional ? -1 : 0;
	o = UnboundConversion(); // refresh
	return ConsumeUnboundConversion(&src, &o, &next) && src.empty();
	}
	UnboundConversion o;
	};

	TEST_F(ConsumeUnboundConversionTest, ConsumeSpecification) {
	struct Expectation {
	int line;
	string_view src;
	string_view out;
	string_view src_post;
	};
	const Expectation kExpect[] = {
	{__LINE__, "", "", "" },
	{__LINE__, "b", "", "b" }, // 'b' is invalid
	{__LINE__, "ba", "", "ba"}, // 'b' is invalid
	{__LINE__, "l", "", "l" }, // just length mod isn't okay
	{__LINE__, "d", "d", "" }, // basic
	{__LINE__, "d ", "d", " " }, // leave suffix
	{__LINE__, "dd", "d", "d" }, // don't be greedy
	{__LINE__, "d9", "d", "9" }, // leave non-space suffix
	{__LINE__, "dzz", "d", "zz"}, // length mod as suffix
	{__LINE__, "1$2$d", "1$2$d", "" }, // arg indexing and * allowed.
	{__LINE__, "0-14.3hhd", "0-14.3hhd", ""}, // precision, width
	{__LINE__, " 0-+#14.3hhd", " 0-+#14.3hhd", ""}, // flags
	};
	for (const auto& e : kExpect) {
	SCOPED_TRACE(e.line);
	string_view src = e.src;
	EXPECT_EQ(e.src, src);
	string_view out = Consume(&src);
	EXPECT_EQ(e.out, out);
	EXPECT_EQ(e.src_post, src);
	}
	}

	TEST_F(ConsumeUnboundConversionTest, BasicConversion) {
	EXPECT_FALSE(Run(""));
	EXPECT_FALSE(Run("z"));

	EXPECT_FALSE(Run("dd")); // no excess allowed

	EXPECT_TRUE(Run("d"));
	EXPECT_EQ('d', o.conv.Char());
	EXPECT_FALSE(o.width.is_from_arg());
	EXPECT_LT(o.width.value(), 0);
	EXPECT_FALSE(o.precision.is_from_arg());
	EXPECT_LT(o.precision.value(), 0);
	EXPECT_EQ(1, o.arg_position);
	EXPECT_EQ(LengthMod::none, o.length_mod.id());
	}

	TEST_F(ConsumeUnboundConversionTest, ArgPosition) {
	EXPECT_TRUE(Run("d"));
	EXPECT_EQ(1, o.arg_position);
	EXPECT_TRUE(Run("3$d"));
	EXPECT_EQ(3, o.arg_position);
	EXPECT_TRUE(Run("1$d"));
	EXPECT_EQ(1, o.arg_position);
	EXPECT_TRUE(Run("1$d", true));
	EXPECT_EQ(1, o.arg_position);
	EXPECT_TRUE(Run("123$d"));
	EXPECT_EQ(123, o.arg_position);
	EXPECT_TRUE(Run("123$d", true));
	EXPECT_EQ(123, o.arg_position);
	EXPECT_TRUE(Run("10$d"));
	EXPECT_EQ(10, o.arg_position);
	EXPECT_TRUE(Run("10$d", true));
	EXPECT_EQ(10, o.arg_position);

	// Position can't be zero.
	EXPECT_FALSE(Run("0$d"));
	EXPECT_FALSE(Run("0$d", true));
	EXPECT_FALSE(Run("1$*0$d"));
	EXPECT_FALSE(Run("1$.*0$d"));

	// Position can't start with a zero digit at all. That is not a 'decimal'.
	EXPECT_FALSE(Run("01$p"));
	EXPECT_FALSE(Run("01$p", true));
	EXPECT_FALSE(Run("1$*01$p"));
	EXPECT_FALSE(Run("1$.*01$p"));
	}

	TEST_F(ConsumeUnboundConversionTest, WidthAndPrecision) {
	EXPECT_TRUE(Run("14d"));
	EXPECT_EQ('d', o.conv.Char());
	EXPECT_FALSE(o.width.is_from_arg());
	EXPECT_EQ(14, o.width.value());
	EXPECT_FALSE(o.precision.is_from_arg());
	EXPECT_LT(o.precision.value(), 0);

	EXPECT_TRUE(Run("14.d"));
	EXPECT_FALSE(o.width.is_from_arg());
	EXPECT_FALSE(o.precision.is_from_arg());
	EXPECT_EQ(14, o.width.value());
	EXPECT_EQ(0, o.precision.value());

	EXPECT_TRUE(Run(".d"));
	EXPECT_FALSE(o.width.is_from_arg());
	EXPECT_LT(o.width.value(), 0);
	EXPECT_FALSE(o.precision.is_from_arg());
	EXPECT_EQ(0, o.precision.value());

	EXPECT_TRUE(Run(".5d"));
	EXPECT_FALSE(o.width.is_from_arg());
	EXPECT_LT(o.width.value(), 0);
	EXPECT_FALSE(o.precision.is_from_arg());
	EXPECT_EQ(5, o.precision.value());

	EXPECT_TRUE(Run(".0d"));
	EXPECT_FALSE(o.width.is_from_arg());
	EXPECT_LT(o.width.value(), 0);
	EXPECT_FALSE(o.precision.is_from_arg());
	EXPECT_EQ(0, o.precision.value());

	EXPECT_TRUE(Run("14.5d"));
	EXPECT_FALSE(o.width.is_from_arg());
	EXPECT_FALSE(o.precision.is_from_arg());
	EXPECT_EQ(14, o.width.value());
	EXPECT_EQ(5, o.precision.value());

	EXPECT_TRUE(Run(".d"));
	EXPECT_TRUE(o.width.is_from_arg());
	EXPECT_EQ(1, o.width.get_from_arg());
	EXPECT_TRUE(o.precision.is_from_arg());
	EXPECT_EQ(2, o.precision.get_from_arg());
	EXPECT_EQ(3, o.arg_position);

	EXPECT_TRUE(Run("*d"));
	EXPECT_TRUE(o.width.is_from_arg());
	EXPECT_EQ(1, o.width.get_from_arg());
	EXPECT_FALSE(o.precision.is_from_arg());
	EXPECT_LT(o.precision.value(), 0);
	EXPECT_EQ(2, o.arg_position);

	EXPECT_TRUE(Run(".*d"));
	EXPECT_FALSE(o.width.is_from_arg());
	EXPECT_LT(o.width.value(), 0);
	EXPECT_TRUE(o.precision.is_from_arg());
	EXPECT_EQ(1, o.precision.get_from_arg());
	EXPECT_EQ(2, o.arg_position);

	// mixed implicit and explicit: didn't specify arg position.
	EXPECT_FALSE(Run("23$.34$d"));

	EXPECT_TRUE(Run("12$23$.34$d"));
	EXPECT_EQ(12, o.arg_position);
	EXPECT_TRUE(o.width.is_from_arg());
	EXPECT_EQ(23, o.width.get_from_arg());
	EXPECT_TRUE(o.precision.is_from_arg());
	EXPECT_EQ(34, o.precision.get_from_arg());

	EXPECT_TRUE(Run("2$5$.9$d"));
	EXPECT_EQ(2, o.arg_position);
	EXPECT_TRUE(o.width.is_from_arg());
	EXPECT_EQ(5, o.width.get_from_arg());
	EXPECT_TRUE(o.precision.is_from_arg());
	EXPECT_EQ(9, o.precision.get_from_arg());

	EXPECT_FALSE(Run(".*0$d")) << "no arg 0";

	// Large values
	EXPECT_TRUE(Run("999999999.999999999d"));
	EXPECT_FALSE(o.width.is_from_arg());
	EXPECT_EQ(999999999, o.width.value());
	EXPECT_FALSE(o.precision.is_from_arg());
	EXPECT_EQ(999999999, o.precision.value());

	EXPECT_FALSE(Run("1000000000.999999999d"));
	EXPECT_FALSE(Run("999999999.1000000000d"));
	EXPECT_FALSE(Run("9999999999d"));
	EXPECT_FALSE(Run(".9999999999d"));
	}

	TEST_F(ConsumeUnboundConversionTest, Flags) {
	static const char kAllFlags[] = "-+ #0";
	static const int kNumFlags = ABSL_ARRAYSIZE(kAllFlags) - 1;
	for (int rev = 0; rev < 2; ++rev) {
	for (int i = 0; i < 1 << kNumFlags; ++i) {
	std::string fmt;
	for (int k = 0; k < kNumFlags; ++k)
	if ((i >> k) & 1) fmt += kAllFlags[k];
	// flag order shouldn't matter
	if (rev == 1) { std::reverse(fmt.begin(), fmt.end()); }
	fmt += 'd';
	SCOPED_TRACE(fmt);
	EXPECT_TRUE(Run(fmt.c_str()));
	EXPECT_EQ(fmt.find('-') == std::string::npos, !o.flags.left);
	EXPECT_EQ(fmt.find('+') == std::string::npos, !o.flags.show_pos);
	EXPECT_EQ(fmt.find(' ') == std::string::npos, !o.flags.sign_col);
	EXPECT_EQ(fmt.find('#') == std::string::npos, !o.flags.alt);
	EXPECT_EQ(fmt.find('0') == std::string::npos, !o.flags.zero);
	}
	}
	}

	TEST_F(ConsumeUnboundConversionTest, BasicFlag) {
	// Flag is on
	for (const char* fmt : {"d", "llx", "G", "1$X"}) {
	SCOPED_TRACE(fmt);
	EXPECT_TRUE(Run(fmt));
	EXPECT_TRUE(o.flags.basic);
	}

	// Flag is off
	for (const char* fmt : {"3d", ".llx", "-G", "1$#X"}) {
	SCOPED_TRACE(fmt);
	EXPECT_TRUE(Run(fmt));
	EXPECT_FALSE(o.flags.basic);
	}
	}

	struct SummarizeConsumer {
	std::string* out;
	explicit SummarizeConsumer(std::string* out) : out(out) {}

	bool Append(string_view s) {
	*out += "[" + std::string(s) + "]";
	return true;
	}

	bool ConvertOne(const UnboundConversion& conv, string_view s) {
	*out += "{";
	*out += std::string(s);
	*out += ":";
	*out += std::to_string(conv.arg_position) + "$";
	if (conv.width.is_from_arg()) {
	out += std::to_string(conv.width.get_from_arg()) + "$";
	}
	if (conv.precision.is_from_arg()) {
	out += "." + std::to_string(conv.precision.get_from_arg()) + "$";
	}
	*out += conv.conv.Char();
	*out += "}";
	return true;
	}
	};

	std::string SummarizeParsedFormat(const ParsedFormatBase& pc) {
	std::string out;
	if (!pc.ProcessFormat(SummarizeConsumer(&out))) out += "!";
	return out;
	}

	class ParsedFormatTest : public testing::Test {};

	TEST_F(ParsedFormatTest, ValueSemantics) {
	ParsedFormatBase p1({}, true, {}); // empty format
	EXPECT_EQ("", SummarizeParsedFormat(p1));

	ParsedFormatBase p2 = p1; // copy construct (empty)
	EXPECT_EQ(SummarizeParsedFormat(p1), SummarizeParsedFormat(p2));

	p1 = ParsedFormatBase("hello%s", true, {Conv::s}); // move assign
	EXPECT_EQ("[hello]{s:1$s}", SummarizeParsedFormat(p1));

	ParsedFormatBase p3 = p1; // copy construct (nonempty)
	EXPECT_EQ(SummarizeParsedFormat(p1), SummarizeParsedFormat(p3));

	using std::swap;
	swap(p1, p2);
	EXPECT_EQ("", SummarizeParsedFormat(p1));
	EXPECT_EQ("[hello]{s:1$s}", SummarizeParsedFormat(p2));
	swap(p1, p2); // undo

	p2 = p1; // copy assign
	EXPECT_EQ(SummarizeParsedFormat(p1), SummarizeParsedFormat(p2));
	}

	struct ExpectParse {
	const char* in;
	std::initializer_list<Conv> conv_set;
	const char* out;
	};

	TEST_F(ParsedFormatTest, Parsing) {
	// Parse should be equivalent to that obtained by ConversionParseIterator.
	// No need to retest the parsing edge cases here.
	const ExpectParse kExpect[] = {
	{"", {}, ""},
	{"ab", {}, "[ab]"},
	{"a%d", {Conv::d}, "[a]{d:1$d}"},
	{"a%+d", {Conv::d}, "[a]{+d:1$d}"},
	{"a% d", {Conv::d}, "[a]{ d:1$d}"},
	{"a%b %d", {}, "[a]!"}, // stop after error
	};
	for (const auto& e : kExpect) {
	SCOPED_TRACE(e.in);
	EXPECT_EQ(e.out,
	SummarizeParsedFormat(ParsedFormatBase(e.in, false, e.conv_set)));
	}
	}

	TEST_F(ParsedFormatTest, ParsingFlagOrder) {
	const ExpectParse kExpect[] = {
	{"a%+ 0d", {Conv::d}, "[a]{+ 0d:1$d}"},
	{"a%+0 d", {Conv::d}, "[a]{+0 d:1$d}"},
	{"a%0+ d", {Conv::d}, "[a]{0+ d:1$d}"},
	{"a% +0d", {Conv::d}, "[a]{ +0d:1$d}"},
	{"a%0 +d", {Conv::d}, "[a]{0 +d:1$d}"},
	{"a% 0+d", {Conv::d}, "[a]{ 0+d:1$d}"},
	{"a%+ 0+d", {Conv::d}, "[a]{+ 0+d:1$d}"},
	};
	for (const auto& e : kExpect) {
	SCOPED_TRACE(e.in);
	EXPECT_EQ(e.out,
	SummarizeParsedFormat(ParsedFormatBase(e.in, false, e.conv_set)));
	}
	}

	} // namespace
	} // namespace str_format_internal
	} // namespace absl