X-Git-Url: https://erislabs.net/gitweb/?a=blobdiff_plain;f=tests%2Ftest-sprintf-posix.h;h=ded5042ab0080be1890c6b5503386ef8e0476119;hb=f6fe750d033c40b403688dc3eee9dbff468aa8f3;hp=855f7aee63dc6396593aef48737869585b9a16ce;hpb=cf8538614458dcf303ea9bb2f03aacdb5ebe34ca;p=gnulib.git
diff --git a/tests/test-sprintf-posix.h b/tests/test-sprintf-posix.h
index 855f7aee6..ded5042ab 100644
--- a/tests/test-sprintf-posix.h
+++ b/tests/test-sprintf-posix.h
@@ -1,10 +1,10 @@
/* Test of POSIX compatible vsprintf() and sprintf() functions.
- Copyright (C) 2007 Free Software Foundation, Inc.
+ Copyright (C) 2007-2009 Free Software Foundation, Inc.
- This program is free software; you can redistribute it and/or modify
+ This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
- the Free Software Foundation; either version 2, or (at your option)
- any later version.
+ the Free Software Foundation; either version 3 of the License, or
+ (at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
@@ -12,21 +12,52 @@
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
- along with this program; if not, write to the Free Software Foundation,
- Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */
+ along with this program. If not, see . */
/* Written by Bruno Haible , 2007. */
-/* The Compaq (ex-DEC) C 6.4 compiler chokes on the expression 0.0 / 0.0. */
-#ifdef __DECC
-static double
-NaN ()
+#include "nan.h"
+
+/* The SGI MIPS floating-point format does not distinguish 0.0 and -0.0. */
+static int
+have_minus_zero ()
+{
+ static double plus_zero = 0.0;
+ double minus_zero = - plus_zero;
+ return memcmp (&plus_zero, &minus_zero, sizeof (double)) != 0;
+}
+
+/* HP cc on HP-UX 10.20 has a bug with the constant expression -0.0.
+ So we use -zerod instead. */
+double zerod = 0.0;
+
+/* On HP-UX 10.20, negating 0.0L does not yield -0.0L.
+ So we use minus_zerol instead.
+ IRIX cc can't put -0.0L into .data, but can compute at runtime.
+ Note that the expression -LDBL_MIN * LDBL_MIN does not work on other
+ platforms, such as when cross-compiling to PowerPC on MacOS X 10.5. */
+#if defined __hpux || defined __sgi
+static long double
+compute_minus_zerol (void)
{
- static double zero = 0.0;
- return zero / zero;
+ return -LDBL_MIN * LDBL_MIN;
}
+# define minus_zerol compute_minus_zerol ()
#else
-# define NaN() (0.0 / 0.0)
+long double minus_zerol = -0.0L;
+#endif
+
+/* Representation of an 80-bit 'long double' as an initializer for a sequence
+ of 'unsigned int' words. */
+#ifdef WORDS_BIGENDIAN
+# define LDBL80_WORDS(exponent,manthi,mantlo) \
+ { ((unsigned int) (exponent) << 16) | ((unsigned int) (manthi) >> 16), \
+ ((unsigned int) (manthi) << 16) | (unsigned int) (mantlo) >> 16), \
+ (unsigned int) (mantlo) << 16 \
+ }
+#else
+# define LDBL80_WORDS(exponent,manthi,mantlo) \
+ { mantlo, manthi, exponent }
#endif
static int
@@ -40,6 +71,27 @@ strmatch (const char *pattern, const char *string)
return 1;
}
+/* Test whether string[start_index..end_index-1] is a valid textual
+ representation of NaN. */
+static int
+strisnan (const char *string, size_t start_index, size_t end_index, int uppercase)
+{
+ if (start_index < end_index)
+ {
+ if (string[start_index] == '-')
+ start_index++;
+ if (start_index + 3 <= end_index
+ && memcmp (string + start_index, uppercase ? "NAN" : "nan", 3) == 0)
+ {
+ start_index += 3;
+ if (start_index == end_index
+ || (string[start_index] == '(' && string[end_index - 1] == ')'))
+ return 1;
+ }
+ }
+ return 0;
+}
+
static void
test_function (int (*my_sprintf) (char *, const char *, ...))
{
@@ -126,8 +178,9 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
{ /* Negative zero. */
char result[1000];
int retval =
- my_sprintf (result, "%a %d", -0.0, 33, 44, 55);
- ASSERT (strcmp (result, "-0x0p+0 33") == 0);
+ my_sprintf (result, "%a %d", -zerod, 33, 44, 55);
+ if (have_minus_zero ())
+ ASSERT (strcmp (result, "-0x0p+0 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -150,8 +203,10 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
{ /* NaN. */
char result[1000];
int retval =
- my_sprintf (result, "%a %d", NaN (), 33, 44, 55);
- ASSERT (strcmp (result, "nan 33") == 0);
+ my_sprintf (result, "%a %d", NaNd (), 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -345,10 +400,12 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
{ /* FLAG_ZERO with NaN. */
char result[1000];
int retval =
- my_sprintf (result, "%010a %d", NaN (), 33, 44, 55);
+ my_sprintf (result, "%050a %d", NaNd (), 33, 44, 55);
/* "0000000nan 33" is not a valid result; see
*/
- ASSERT (strcmp (result, " nan 33") == 0);
+ ASSERT (strlen (result) == 50 + 3
+ && strisnan (result, strspn (result, " "), strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -385,8 +442,9 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
{ /* Negative zero. */
char result[1000];
int retval =
- my_sprintf (result, "%La %d", -0.0L, 33, 44, 55);
- ASSERT (strcmp (result, "-0x0p+0 33") == 0);
+ my_sprintf (result, "%La %d", minus_zerol, 33, 44, 55);
+ if (have_minus_zero ())
+ ASSERT (strcmp (result, "-0x0p+0 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -409,10 +467,99 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
{ /* NaN. */
char result[1000];
int retval =
- my_sprintf (result, "%La %d", 0.0L / 0.0L, 33, 44, 55);
- ASSERT (strcmp (result, "nan 33") == 0);
+ my_sprintf (result, "%La %d", NaNl (), 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+#if CHECK_PRINTF_SAFE && ((defined __ia64 && LDBL_MANT_DIG == 64) || (defined __x86_64__ || defined __amd64__) || (defined __i386 || defined __i386__ || defined _I386 || defined _M_IX86 || defined _X86_))
+ { /* Quiet NaN. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0xFFFF, 0xC3333333, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%La %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ {
+ /* Signalling NaN. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0xFFFF, 0x83333333, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%La %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ /* The isnanl function should recognize Pseudo-NaNs, Pseudo-Infinities,
+ Pseudo-Zeroes, Unnormalized Numbers, and Pseudo-Denormals, as defined in
+ Intel IA-64 Architecture Software Developer's Manual, Volume 1:
+ Application Architecture.
+ Table 5-2 "Floating-Point Register Encodings"
+ Figure 5-6 "Memory to Floating-Point Register Data Translation"
+ */
+ { /* Pseudo-NaN. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0xFFFF, 0x40000001, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%La %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ { /* Pseudo-Infinity. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0xFFFF, 0x00000000, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%La %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ { /* Pseudo-Zero. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0x4004, 0x00000000, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%La %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ { /* Unnormalized number. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0x4000, 0x63333333, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%La %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ { /* Pseudo-Denormal. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0x0000, 0x83333333, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%La %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
ASSERT (retval == strlen (result));
}
+#endif
{ /* Rounding near the decimal point. */
char result[1000];
@@ -605,10 +752,12 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
{ /* FLAG_ZERO with NaN. */
char result[1000];
int retval =
- my_sprintf (result, "%010La %d", 0.0L / 0.0L, 33, 44, 55);
+ my_sprintf (result, "%050La %d", NaNl (), 33, 44, 55);
/* "0000000nan 33" is not a valid result; see
*/
- ASSERT (strcmp (result, " nan 33") == 0);
+ ASSERT (strlen (result) == 50 + 3
+ && strisnan (result, strspn (result, " "), strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -738,8 +887,9 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
{ /* Negative zero. */
char result[1000];
int retval =
- my_sprintf (result, "%f %d", -0.0, 33, 44, 55);
- ASSERT (strcmp (result, "-0.000000 33") == 0);
+ my_sprintf (result, "%f %d", -zerod, 33, 44, 55);
+ if (have_minus_zero ())
+ ASSERT (strcmp (result, "-0.000000 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -764,8 +914,10 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
{ /* NaN. */
char result[1000];
int retval =
- my_sprintf (result, "%f %d", NaN (), 33, 44, 55);
- ASSERT (strcmp (result, "nan 33") == 0);
+ my_sprintf (result, "%f %d", NaNd (), 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -837,8 +989,10 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
{ /* FLAG_ZERO with NaN. */
char result[1000];
int retval =
- my_sprintf (result, "%015f %d", NaN (), 33, 44, 55);
- ASSERT (strcmp (result, " nan 33") == 0);
+ my_sprintf (result, "%050f %d", NaNd (), 33, 44, 55);
+ ASSERT (strlen (result) == 50 + 3
+ && strisnan (result, strspn (result, " "), strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -850,6 +1004,22 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
ASSERT (retval == strlen (result));
}
+ { /* Precision with no rounding. */
+ char result[100];
+ int retval =
+ my_sprintf (result, "%.2f %d", 999.951, 33, 44, 55);
+ ASSERT (strcmp (result, "999.95 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ { /* Precision with rounding. */
+ char result[100];
+ int retval =
+ my_sprintf (result, "%.2f %d", 999.996, 33, 44, 55);
+ ASSERT (strcmp (result, "1000.00 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
{ /* A positive number. */
char result[1000];
int retval =
@@ -974,8 +1144,9 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
{ /* Negative zero. */
char result[1000];
int retval =
- my_sprintf (result, "%Lf %d", -0.0L, 33, 44, 55);
- ASSERT (strcmp (result, "-0.000000 33") == 0);
+ my_sprintf (result, "%Lf %d", minus_zerol, 33, 44, 55);
+ if (have_minus_zero ())
+ ASSERT (strcmp (result, "-0.000000 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -998,13 +1169,101 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
}
{ /* NaN. */
- static long double zero = 0.0L;
char result[1000];
int retval =
- my_sprintf (result, "%Lf %d", zero / zero, 33, 44, 55);
- ASSERT (strcmp (result, "nan 33") == 0);
+ my_sprintf (result, "%Lf %d", NaNl (), 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+#if CHECK_PRINTF_SAFE && ((defined __ia64 && LDBL_MANT_DIG == 64) || (defined __x86_64__ || defined __amd64__) || (defined __i386 || defined __i386__ || defined _I386 || defined _M_IX86 || defined _X86_))
+ { /* Quiet NaN. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0xFFFF, 0xC3333333, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%Lf %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ {
+ /* Signalling NaN. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0xFFFF, 0x83333333, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%Lf %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ /* The isnanl function should recognize Pseudo-NaNs, Pseudo-Infinities,
+ Pseudo-Zeroes, Unnormalized Numbers, and Pseudo-Denormals, as defined in
+ Intel IA-64 Architecture Software Developer's Manual, Volume 1:
+ Application Architecture.
+ Table 5-2 "Floating-Point Register Encodings"
+ Figure 5-6 "Memory to Floating-Point Register Data Translation"
+ */
+ { /* Pseudo-NaN. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0xFFFF, 0x40000001, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%Lf %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ { /* Pseudo-Infinity. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0xFFFF, 0x00000000, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%Lf %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ { /* Pseudo-Zero. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0x4004, 0x00000000, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%Lf %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
ASSERT (retval == strlen (result));
}
+ { /* Unnormalized number. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0x4000, 0x63333333, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%Lf %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ { /* Pseudo-Denormal. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0x0000, 0x83333333, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%Lf %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+#endif
{ /* Width. */
char result[1000];
@@ -1072,11 +1331,12 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
}
{ /* FLAG_ZERO with NaN. */
- static long double zero = 0.0L;
char result[1000];
int retval =
- my_sprintf (result, "%015Lf %d", zero / zero, 33, 44, 55);
- ASSERT (strcmp (result, " nan 33") == 0);
+ my_sprintf (result, "%050Lf %d", NaNl (), 33, 44, 55);
+ ASSERT (strlen (result) == 50 + 3
+ && strisnan (result, strspn (result, " "), strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1088,6 +1348,22 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
ASSERT (retval == strlen (result));
}
+ { /* Precision with no rounding. */
+ char result[100];
+ int retval =
+ my_sprintf (result, "%.2Lf %d", 999.951L, 33, 44, 55);
+ ASSERT (strcmp (result, "999.95 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ { /* Precision with rounding. */
+ char result[100];
+ int retval =
+ my_sprintf (result, "%.2Lf %d", 999.996L, 33, 44, 55);
+ ASSERT (strcmp (result, "1000.00 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
/* Test the support of the %F format directive. */
{ /* A positive number. */
@@ -1125,8 +1401,9 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
{ /* Negative zero. */
char result[1000];
int retval =
- my_sprintf (result, "%F %d", -0.0, 33, 44, 55);
- ASSERT (strcmp (result, "-0.000000 33") == 0);
+ my_sprintf (result, "%F %d", -zerod, 33, 44, 55);
+ if (have_minus_zero ())
+ ASSERT (strcmp (result, "-0.000000 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1151,8 +1428,10 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
{ /* NaN. */
char result[1000];
int retval =
- my_sprintf (result, "%F %d", NaN (), 33, 44, 55);
- ASSERT (strcmp (result, "NAN 33") == 0);
+ my_sprintf (result, "%F %d", NaNd (), 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 1)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1181,6 +1460,22 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
ASSERT (retval == strlen (result));
}
+ { /* Precision with no rounding. */
+ char result[100];
+ int retval =
+ my_sprintf (result, "%.2F %d", 999.951, 33, 44, 55);
+ ASSERT (strcmp (result, "999.95 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ { /* Precision with rounding. */
+ char result[100];
+ int retval =
+ my_sprintf (result, "%.2F %d", 999.996, 33, 44, 55);
+ ASSERT (strcmp (result, "1000.00 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
{ /* A positive number. */
char result[1000];
int retval =
@@ -1216,8 +1511,9 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
{ /* Negative zero. */
char result[1000];
int retval =
- my_sprintf (result, "%LF %d", -0.0L, 33, 44, 55);
- ASSERT (strcmp (result, "-0.000000 33") == 0);
+ my_sprintf (result, "%LF %d", minus_zerol, 33, 44, 55);
+ if (have_minus_zero ())
+ ASSERT (strcmp (result, "-0.000000 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1240,11 +1536,12 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
}
{ /* NaN. */
- static long double zero = 0.0L;
char result[1000];
int retval =
- my_sprintf (result, "%LF %d", zero / zero, 33, 44, 55);
- ASSERT (strcmp (result, "NAN 33") == 0);
+ my_sprintf (result, "%LF %d", NaNl (), 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 1)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1273,6 +1570,22 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
ASSERT (retval == strlen (result));
}
+ { /* Precision with no rounding. */
+ char result[100];
+ int retval =
+ my_sprintf (result, "%.2LF %d", 999.951L, 33, 44, 55);
+ ASSERT (strcmp (result, "999.95 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ { /* Precision with rounding. */
+ char result[100];
+ int retval =
+ my_sprintf (result, "%.2LF %d", 999.996L, 33, 44, 55);
+ ASSERT (strcmp (result, "1000.00 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
/* Test the support of the %e format directive. */
{ /* A positive number. */
@@ -1378,7 +1691,6 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
int retval =
my_sprintf (result, "%e", data[k].value);
const char *expected = data[k].string;
- ASSERT (result != NULL);
ASSERT (strcmp (result, expected) == 0
/* Some implementations produce exponents with 3 digits. */
|| (strlen (result) == strlen (expected) + 1
@@ -1412,9 +1724,10 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
{ /* Negative zero. */
char result[1000];
int retval =
- my_sprintf (result, "%e %d", -0.0, 33, 44, 55);
- ASSERT (strcmp (result, "-0.000000e+00 33") == 0
- || strcmp (result, "-0.000000e+000 33") == 0);
+ my_sprintf (result, "%e %d", -zerod, 33, 44, 55);
+ if (have_minus_zero ())
+ ASSERT (strcmp (result, "-0.000000e+00 33") == 0
+ || strcmp (result, "-0.000000e+000 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1439,8 +1752,10 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
{ /* NaN. */
char result[1000];
int retval =
- my_sprintf (result, "%e %d", NaN (), 33, 44, 55);
- ASSERT (strcmp (result, "nan 33") == 0);
+ my_sprintf (result, "%e %d", NaNd (), 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1528,8 +1843,10 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
{ /* FLAG_ZERO with NaN. */
char result[1000];
int retval =
- my_sprintf (result, "%015e %d", NaN (), 33, 44, 55);
- ASSERT (strcmp (result, " nan 33") == 0);
+ my_sprintf (result, "%050e %d", NaNd (), 33, 44, 55);
+ ASSERT (strlen (result) == 50 + 3
+ && strisnan (result, strspn (result, " "), strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1542,11 +1859,30 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
ASSERT (retval == strlen (result));
}
+ { /* Precision with no rounding. */
+ char result[100];
+ int retval =
+ my_sprintf (result, "%.4e %d", 999.951, 33, 44, 55);
+ ASSERT (strcmp (result, "9.9995e+02 33") == 0
+ || strcmp (result, "9.9995e+002 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ { /* Precision with rounding. */
+ char result[100];
+ int retval =
+ my_sprintf (result, "%.4e %d", 999.996, 33, 44, 55);
+ ASSERT (strcmp (result, "1.0000e+03 33") == 0
+ || strcmp (result, "1.0000e+003 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
{ /* A positive number. */
char result[1000];
int retval =
my_sprintf (result, "%Le %d", 12.75L, 33, 44, 55);
- ASSERT (strcmp (result, "1.275000e+01 33") == 0);
+ ASSERT (strcmp (result, "1.275000e+01 33") == 0
+ || strcmp (result, "1.275000e+001 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1554,7 +1890,8 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
char result[1000];
int retval =
my_sprintf (result, "%Le %d", 1234567.0L, 33, 44, 55);
- ASSERT (strcmp (result, "1.234567e+06 33") == 0);
+ ASSERT (strcmp (result, "1.234567e+06 33") == 0
+ || strcmp (result, "1.234567e+006 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1642,7 +1979,15 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
char result[1000];
int retval =
my_sprintf (result, "%Le", data[k].value);
- ASSERT (strcmp (result, data[k].string) == 0);
+ const char *expected = data[k].string;
+ ASSERT (strcmp (result, expected) == 0
+ /* Some implementations produce exponents with 3 digits. */
+ || (strlen (result) == strlen (expected) + 1
+ && memcmp (result, expected, strlen (expected) - 2) == 0
+ && result[strlen (expected) - 2] == '0'
+ && strcmp (result + strlen (expected) - 1,
+ expected + strlen (expected) - 2)
+ == 0));
ASSERT (retval == strlen (result));
}
}
@@ -1651,7 +1996,8 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
char result[1000];
int retval =
my_sprintf (result, "%Le %d", -0.03125L, 33, 44, 55);
- ASSERT (strcmp (result, "-3.125000e-02 33") == 0);
+ ASSERT (strcmp (result, "-3.125000e-02 33") == 0
+ || strcmp (result, "-3.125000e-002 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1659,15 +2005,18 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
char result[1000];
int retval =
my_sprintf (result, "%Le %d", 0.0L, 33, 44, 55);
- ASSERT (strcmp (result, "0.000000e+00 33") == 0);
+ ASSERT (strcmp (result, "0.000000e+00 33") == 0
+ || strcmp (result, "0.000000e+000 33") == 0);
ASSERT (retval == strlen (result));
}
{ /* Negative zero. */
char result[1000];
int retval =
- my_sprintf (result, "%Le %d", -0.0L, 33, 44, 55);
- ASSERT (strcmp (result, "-0.000000e+00 33") == 0);
+ my_sprintf (result, "%Le %d", minus_zerol, 33, 44, 55);
+ if (have_minus_zero ())
+ ASSERT (strcmp (result, "-0.000000e+00 33") == 0
+ || strcmp (result, "-0.000000e+000 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1690,19 +2039,108 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
}
{ /* NaN. */
- static long double zero = 0.0L;
char result[1000];
int retval =
- my_sprintf (result, "%Le %d", zero / zero, 33, 44, 55);
- ASSERT (strcmp (result, "nan 33") == 0);
+ my_sprintf (result, "%Le %d", NaNl (), 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+#if CHECK_PRINTF_SAFE && ((defined __ia64 && LDBL_MANT_DIG == 64) || (defined __x86_64__ || defined __amd64__) || (defined __i386 || defined __i386__ || defined _I386 || defined _M_IX86 || defined _X86_))
+ { /* Quiet NaN. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0xFFFF, 0xC3333333, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%Le %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ {
+ /* Signalling NaN. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0xFFFF, 0x83333333, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%Le %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ /* The isnanl function should recognize Pseudo-NaNs, Pseudo-Infinities,
+ Pseudo-Zeroes, Unnormalized Numbers, and Pseudo-Denormals, as defined in
+ Intel IA-64 Architecture Software Developer's Manual, Volume 1:
+ Application Architecture.
+ Table 5-2 "Floating-Point Register Encodings"
+ Figure 5-6 "Memory to Floating-Point Register Data Translation"
+ */
+ { /* Pseudo-NaN. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0xFFFF, 0x40000001, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%Le %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
ASSERT (retval == strlen (result));
}
+ { /* Pseudo-Infinity. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0xFFFF, 0x00000000, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%Le %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ { /* Pseudo-Zero. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0x4004, 0x00000000, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%Le %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ { /* Unnormalized number. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0x4000, 0x63333333, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%Le %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ { /* Pseudo-Denormal. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0x0000, 0x83333333, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%Le %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+#endif
{ /* Width. */
char result[1000];
int retval =
my_sprintf (result, "%15Le %d", 1.75L, 33, 44, 55);
- ASSERT (strcmp (result, " 1.750000e+00 33") == 0);
+ ASSERT (strcmp (result, " 1.750000e+00 33") == 0
+ || strcmp (result, " 1.750000e+000 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1710,7 +2148,8 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
char result[1000];
int retval =
my_sprintf (result, "%-15Le %d", 1.75L, 33, 44, 55);
- ASSERT (strcmp (result, "1.750000e+00 33") == 0);
+ ASSERT (strcmp (result, "1.750000e+00 33") == 0
+ || strcmp (result, "1.750000e+000 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1718,7 +2157,8 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
char result[1000];
int retval =
my_sprintf (result, "%+Le %d", 1.75L, 33, 44, 55);
- ASSERT (strcmp (result, "+1.750000e+00 33") == 0);
+ ASSERT (strcmp (result, "+1.750000e+00 33") == 0
+ || strcmp (result, "+1.750000e+000 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1726,7 +2166,8 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
char result[1000];
int retval =
my_sprintf (result, "% Le %d", 1.75L, 33, 44, 55);
- ASSERT (strcmp (result, " 1.750000e+00 33") == 0);
+ ASSERT (strcmp (result, " 1.750000e+00 33") == 0
+ || strcmp (result, " 1.750000e+000 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1734,7 +2175,8 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
char result[1000];
int retval =
my_sprintf (result, "%#Le %d", 1.75L, 33, 44, 55);
- ASSERT (strcmp (result, "1.750000e+00 33") == 0);
+ ASSERT (strcmp (result, "1.750000e+00 33") == 0
+ || strcmp (result, "1.750000e+000 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1742,7 +2184,8 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
char result[1000];
int retval =
my_sprintf (result, "%#.Le %d", 1.75L, 33, 44, 55);
- ASSERT (strcmp (result, "2.e+00 33") == 0);
+ ASSERT (strcmp (result, "2.e+00 33") == 0
+ || strcmp (result, "2.e+000 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1750,7 +2193,8 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
char result[1000];
int retval =
my_sprintf (result, "%#.Le %d", 9.75L, 33, 44, 55);
- ASSERT (strcmp (result, "1.e+01 33") == 0);
+ ASSERT (strcmp (result, "1.e+01 33") == 0
+ || strcmp (result, "1.e+001 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1758,7 +2202,8 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
char result[1000];
int retval =
my_sprintf (result, "%015Le %d", 1234.0L, 33, 44, 55);
- ASSERT (strcmp (result, "0001.234000e+03 33") == 0);
+ ASSERT (strcmp (result, "0001.234000e+03 33") == 0
+ || strcmp (result, "001.234000e+003 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1772,11 +2217,12 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
}
{ /* FLAG_ZERO with NaN. */
- static long double zero = 0.0L;
char result[1000];
int retval =
- my_sprintf (result, "%015Le %d", zero / zero, 33, 44, 55);
- ASSERT (strcmp (result, " nan 33") == 0);
+ my_sprintf (result, "%050Le %d", NaNl (), 33, 44, 55);
+ ASSERT (strlen (result) == 50 + 3
+ && strisnan (result, strspn (result, " "), strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1784,7 +2230,26 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
char result[1000];
int retval =
my_sprintf (result, "%.Le %d", 1234.0L, 33, 44, 55);
- ASSERT (strcmp (result, "1e+03 33") == 0);
+ ASSERT (strcmp (result, "1e+03 33") == 0
+ || strcmp (result, "1e+003 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ { /* Precision with no rounding. */
+ char result[100];
+ int retval =
+ my_sprintf (result, "%.4Le %d", 999.951L, 33, 44, 55);
+ ASSERT (strcmp (result, "9.9995e+02 33") == 0
+ || strcmp (result, "9.9995e+002 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ { /* Precision with rounding. */
+ char result[100];
+ int retval =
+ my_sprintf (result, "%.4Le %d", 999.996L, 33, 44, 55);
+ ASSERT (strcmp (result, "1.0000e+03 33") == 0
+ || strcmp (result, "1.0000e+003 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1924,8 +2389,9 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
{ /* Negative zero. */
char result[1000];
int retval =
- my_sprintf (result, "%g %d", -0.0, 33, 44, 55);
- ASSERT (strcmp (result, "-0 33") == 0);
+ my_sprintf (result, "%g %d", -zerod, 33, 44, 55);
+ if (have_minus_zero ())
+ ASSERT (strcmp (result, "-0 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -1950,8 +2416,10 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
{ /* NaN. */
char result[1000];
int retval =
- my_sprintf (result, "%g %d", NaN (), 33, 44, 55);
- ASSERT (strcmp (result, "nan 33") == 0);
+ my_sprintf (result, "%g %d", NaNd (), 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -2032,8 +2500,10 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
{ /* FLAG_ZERO with NaN. */
char result[1000];
int retval =
- my_sprintf (result, "%015g %d", NaN (), 33, 44, 55);
- ASSERT (strcmp (result, " nan 33") == 0);
+ my_sprintf (result, "%050g %d", NaNd (), 33, 44, 55);
+ ASSERT (strlen (result) == 50 + 3
+ && strisnan (result, strspn (result, " "), strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -2046,6 +2516,22 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
ASSERT (retval == strlen (result));
}
+ { /* Precision with no rounding. */
+ char result[100];
+ int retval =
+ my_sprintf (result, "%.5g %d", 999.951, 33, 44, 55);
+ ASSERT (strcmp (result, "999.95 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ { /* Precision with rounding. */
+ char result[100];
+ int retval =
+ my_sprintf (result, "%.5g %d", 999.996, 33, 44, 55);
+ ASSERT (strcmp (result, "1000 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
{ /* A positive number. */
char result[1000];
int retval =
@@ -2058,7 +2544,8 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
char result[1000];
int retval =
my_sprintf (result, "%Lg %d", 1234567.0L, 33, 44, 55);
- ASSERT (strcmp (result, "1.23457e+06 33") == 0);
+ ASSERT (strcmp (result, "1.23457e+06 33") == 0
+ || strcmp (result, "1.23457e+006 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -2146,7 +2633,16 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
char result[1000];
int retval =
my_sprintf (result, "%Lg", data[k].value);
- ASSERT (strcmp (result, data[k].string) == 0);
+ const char *expected = data[k].string;
+ ASSERT (strcmp (result, expected) == 0
+ /* Some implementations produce exponents with 3 digits. */
+ || (expected[strlen (expected) - 4] == 'e'
+ && strlen (result) == strlen (expected) + 1
+ && memcmp (result, expected, strlen (expected) - 2) == 0
+ && result[strlen (expected) - 2] == '0'
+ && strcmp (result + strlen (expected) - 1,
+ expected + strlen (expected) - 2)
+ == 0));
ASSERT (retval == strlen (result));
}
}
@@ -2170,8 +2666,9 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
{ /* Negative zero. */
char result[1000];
int retval =
- my_sprintf (result, "%Lg %d", -0.0L, 33, 44, 55);
- ASSERT (strcmp (result, "-0 33") == 0);
+ my_sprintf (result, "%Lg %d", minus_zerol, 33, 44, 55);
+ if (have_minus_zero ())
+ ASSERT (strcmp (result, "-0 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -2194,13 +2691,101 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
}
{ /* NaN. */
- static long double zero = 0.0L;
char result[1000];
int retval =
- my_sprintf (result, "%Lg %d", zero / zero, 33, 44, 55);
- ASSERT (strcmp (result, "nan 33") == 0);
+ my_sprintf (result, "%Lg %d", NaNl (), 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+#if CHECK_PRINTF_SAFE && ((defined __ia64 && LDBL_MANT_DIG == 64) || (defined __x86_64__ || defined __amd64__) || (defined __i386 || defined __i386__ || defined _I386 || defined _M_IX86 || defined _X86_))
+ { /* Quiet NaN. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0xFFFF, 0xC3333333, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%La %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ {
+ /* Signalling NaN. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0xFFFF, 0x83333333, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%La %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ /* The isnanl function should recognize Pseudo-NaNs, Pseudo-Infinities,
+ Pseudo-Zeroes, Unnormalized Numbers, and Pseudo-Denormals, as defined in
+ Intel IA-64 Architecture Software Developer's Manual, Volume 1:
+ Application Architecture.
+ Table 5-2 "Floating-Point Register Encodings"
+ Figure 5-6 "Memory to Floating-Point Register Data Translation"
+ */
+ { /* Pseudo-NaN. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0xFFFF, 0x40000001, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%Lg %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ { /* Pseudo-Infinity. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0xFFFF, 0x00000000, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%Lg %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ { /* Pseudo-Zero. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0x4004, 0x00000000, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%Lg %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ { /* Unnormalized number. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0x4000, 0x63333333, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%Lg %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+ { /* Pseudo-Denormal. */
+ static union { unsigned int word[4]; long double value; } x =
+ { LDBL80_WORDS (0x0000, 0x83333333, 0x00000000) };
+ char result[1000];
+ int retval =
+ my_sprintf (result, "%Lg %d", x.value, 33, 44, 55);
+ ASSERT (strlen (result) >= 3 + 3
+ && strisnan (result, 0, strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
ASSERT (retval == strlen (result));
}
+#endif
{ /* Width. */
char result[1000];
@@ -2254,7 +2839,8 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
char result[1000];
int retval =
my_sprintf (result, "%#.Lg %d", 9.75L, 33, 44, 55);
- ASSERT (strcmp (result, "1.e+01 33") == 0);
+ ASSERT (strcmp (result, "1.e+01 33") == 0
+ || strcmp (result, "1.e+001 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -2276,11 +2862,12 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
}
{ /* FLAG_ZERO with NaN. */
- static long double zero = 0.0L;
char result[1000];
int retval =
- my_sprintf (result, "%015Lg %d", zero / zero, 33, 44, 55);
- ASSERT (strcmp (result, " nan 33") == 0);
+ my_sprintf (result, "%050Lg %d", NaNl (), 33, 44, 55);
+ ASSERT (strlen (result) == 50 + 3
+ && strisnan (result, strspn (result, " "), strlen (result) - 3, 0)
+ && strcmp (result + strlen (result) - 3, " 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -2288,7 +2875,24 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
char result[1000];
int retval =
my_sprintf (result, "%.Lg %d", 1234.0L, 33, 44, 55);
- ASSERT (strcmp (result, "1e+03 33") == 0);
+ ASSERT (strcmp (result, "1e+03 33") == 0
+ || strcmp (result, "1e+003 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ { /* Precision with no rounding. */
+ char result[100];
+ int retval =
+ my_sprintf (result, "%.5Lg %d", 999.951L, 33, 44, 55);
+ ASSERT (strcmp (result, "999.95 33") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ { /* Precision with rounding. */
+ char result[100];
+ int retval =
+ my_sprintf (result, "%.5Lg %d", 999.996L, 33, 44, 55);
+ ASSERT (strcmp (result, "1000 33") == 0);
ASSERT (retval == strlen (result));
}
@@ -2323,4 +2927,173 @@ test_function (int (*my_sprintf) (char *, const char *, ...))
ASSERT (result[strlen (result) - 1] == '9');
ASSERT (retval == strlen (result));
}
+
+ /* Test the support of the left-adjust flag. */
+
+ {
+ char result[1000];
+ int retval =
+ my_sprintf (result, "a%*sc", -3, "b");
+ ASSERT (strcmp (result, "ab c") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ {
+ char result[1000];
+ int retval =
+ my_sprintf (result, "a%-*sc", 3, "b");
+ ASSERT (strcmp (result, "ab c") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ {
+ char result[1000];
+ int retval =
+ my_sprintf (result, "a%-*sc", -3, "b");
+ ASSERT (strcmp (result, "ab c") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ /* Test the support of large precision. */
+
+ {
+ char result[5000];
+ int retval =
+ my_sprintf (result, "%.4000d %d", 1234567, 99);
+ size_t i;
+ for (i = 0; i < 4000 - 7; i++)
+ ASSERT (result[i] == '0');
+ ASSERT (strcmp (result + 4000 - 7, "1234567 99") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ {
+ char result[5000];
+ int retval =
+ my_sprintf (result, "%.*d %d", 4000, 1234567, 99);
+ size_t i;
+ for (i = 0; i < 4000 - 7; i++)
+ ASSERT (result[i] == '0');
+ ASSERT (strcmp (result + 4000 - 7, "1234567 99") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ {
+ char result[5000];
+ int retval =
+ my_sprintf (result, "%.4000d %d", -1234567, 99);
+ size_t i;
+ ASSERT (result[0] == '-');
+ for (i = 0; i < 4000 - 7; i++)
+ ASSERT (result[1 + i] == '0');
+ ASSERT (strcmp (result + 1 + 4000 - 7, "1234567 99") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ {
+ char result[5000];
+ int retval =
+ my_sprintf (result, "%.4000u %d", 1234567, 99);
+ size_t i;
+ for (i = 0; i < 4000 - 7; i++)
+ ASSERT (result[i] == '0');
+ ASSERT (strcmp (result + 4000 - 7, "1234567 99") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ {
+ char result[5000];
+ int retval =
+ my_sprintf (result, "%.4000o %d", 1234567, 99);
+ size_t i;
+ for (i = 0; i < 4000 - 7; i++)
+ ASSERT (result[i] == '0');
+ ASSERT (strcmp (result + 4000 - 7, "4553207 99") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ {
+ char result[5000];
+ int retval =
+ my_sprintf (result, "%.4000x %d", 1234567, 99);
+ size_t i;
+ for (i = 0; i < 4000 - 6; i++)
+ ASSERT (result[i] == '0');
+ ASSERT (strcmp (result + 4000 - 6, "12d687 99") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ {
+ char result[5000];
+ int retval =
+ my_sprintf (result, "%#.4000x %d", 1234567, 99);
+ size_t i;
+ ASSERT (result[0] == '0');
+ ASSERT (result[1] == 'x');
+ for (i = 0; i < 4000 - 6; i++)
+ ASSERT (result[2 + i] == '0');
+ ASSERT (strcmp (result + 2 + 4000 - 6, "12d687 99") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ {
+ char input[5000];
+ char result[5000];
+ int retval;
+ size_t i;
+
+ for (i = 0; i < sizeof (input) - 1; i++)
+ input[i] = 'a' + ((1000000 / (i + 1)) % 26);
+ input[i] = '\0';
+ retval = my_sprintf (result, "%.4000s %d", input, 99);
+ ASSERT (memcmp (result, input, 4000) == 0);
+ ASSERT (strcmp (result + 4000, " 99") == 0);
+ ASSERT (retval == strlen (result));
+ }
+
+ /* Test the support of the %s format directive. */
+
+ /* To verify that these tests succeed, it is necessary to run them under
+ a tool that checks against invalid memory accesses, such as ElectricFence
+ or "valgrind --tool=memcheck". */
+ {
+ size_t i;
+
+ for (i = 1; i <= 8; i++)
+ {
+ char *block;
+ char result[5000];
+ int retval;
+
+ block = (char *) malloc (i);
+ memcpy (block, "abcdefgh", i);
+ retval = my_sprintf (result, "%.*s", (int) i, block);
+ ASSERT (memcmp (result, block, i) == 0);
+ ASSERT (result[i] == '\0');
+ ASSERT (retval == strlen (result));
+ free (block);
+ }
+ }
+#if HAVE_WCHAR_T
+ {
+ size_t i;
+
+ for (i = 1; i <= 8; i++)
+ {
+ wchar_t *block;
+ size_t j;
+ char result[5000];
+ int retval;
+
+ block = (wchar_t *) malloc (i * sizeof (wchar_t));
+ for (j = 0; j < i; j++)
+ block[j] = "abcdefgh"[j];
+ retval = my_sprintf (result, "%.*ls", (int) i, block);
+ ASSERT (memcmp (result, "abcdefgh", i) == 0);
+ ASSERT (result[i] == '\0');
+ ASSERT (retval == strlen (result));
+ free (block);
+ }
+ }
+#endif
}