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author | John Voltz <john.voltz@gmail.com> | 2008-03-06 17:56:30 +0000 |
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committer | John Voltz <john.voltz@gmail.com> | 2008-03-06 17:56:30 +0000 |
commit | f2f36334e3b5720731eb2204c2fe63c1e782777d (patch) | |
tree | 5d7b0c79882ec20c12260107301ddb314b07df94 /package/cairo/old_patches | |
parent | 72746838f2c00bc5c82a2582c1a3a1a294868a53 (diff) | |
download | buildroot-novena-f2f36334e3b5720731eb2204c2fe63c1e782777d.tar.gz buildroot-novena-f2f36334e3b5720731eb2204c2fe63c1e782777d.zip |
updated cairo
Diffstat (limited to 'package/cairo/old_patches')
2 files changed, 182 insertions, 0 deletions
diff --git a/package/cairo/old_patches/0001-Add-autoconf-macro-AX_C_FLOAT_WORDS_BIGENDIAN.patch b/package/cairo/old_patches/0001-Add-autoconf-macro-AX_C_FLOAT_WORDS_BIGENDIAN.patch new file mode 100644 index 000000000..90718d497 --- /dev/null +++ b/package/cairo/old_patches/0001-Add-autoconf-macro-AX_C_FLOAT_WORDS_BIGENDIAN.patch @@ -0,0 +1,103 @@ +From nobody Mon Sep 17 00:00:00 2001 +From: Dan Amelang <dan@amelang.net> +Date: Sun Oct 29 21:30:08 2006 -0800 +Subject: [PATCH] Add autoconf macro AX_C_FLOAT_WORDS_BIGENDIAN + +The symbol that this macro defines (FLOAT_WORDS_BIGENDIAN) can be used +to make double arithmetic tricks portable. + +--- + + acinclude.m4 | 65 ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ + configure.in | 1 + + 2 files changed, 66 insertions(+), 0 deletions(-) + +3231d91b59a6c2e1c40bbaa8b143694b6c693662 +diff --git a/acinclude.m4 b/acinclude.m4 +index af73800..a0eb13a 100644 +--- a/acinclude.m4 ++++ b/acinclude.m4 +@@ -51,3 +51,68 @@ ifelse([$1],[],, + AM_CONDITIONAL(ENABLE_GTK_DOC, test x$enable_gtk_doc = xyes) + AM_CONDITIONAL(GTK_DOC_USE_LIBTOOL, test -n "$LIBTOOL") + ]) ++ ++# AX_C_FLOAT_WORDS_BIGENDIAN ([ACTION-IF-TRUE], [ACTION-IF-FALSE], ++# [ACTION-IF-UNKNOWN]) ++# ++# Checks the ordering of words within a multi-word float. This check ++# is necessary because on some systems (e.g. certain ARM systems), the ++# float word ordering can be different from the byte ordering. In a ++# multi-word float context, "big-endian" implies that the word containing ++# the sign bit is found in the memory location with the lowest address. ++# This implemenation was inspired by the AC_C_BIGENDIAN macro in autoconf. ++# ------------------------------------------------------------------------- ++AC_DEFUN([AX_C_FLOAT_WORDS_BIGENDIAN], ++ [AC_CACHE_CHECK(whether float word ordering is bigendian, ++ ax_cv_c_float_words_bigendian, [ ++ ++# The endianess is detected by first compiling C code that contains a special ++# double float value, then grepping the resulting object file for certain ++# strings of ascii values. The double is specially crafted to have a ++# binary representation that corresponds with a simple string. In this ++# implementation, the string "noonsees" was selected because the individual ++# word values ("noon" and "sees") are palindromes, thus making this test ++# byte-order agnostic. If grep finds the string "noonsees" in the object ++# file, the target platform stores float words in big-endian order. If grep ++# finds "seesnoon", float words are in little-endian order. If neither value ++# is found, the user is instructed to specify the ordering. ++ ++ax_cv_c_float_words_bigendian=unknown ++AC_COMPILE_IFELSE([AC_LANG_SOURCE([[ ++ ++double d = 90904234967036810337470478905505011476211692735615632014797120844053488865816695273723469097858056257517020191247487429516932130503560650002327564517570778480236724525140520121371739201496540132640109977779420565776568942592.0; ++ ++]])], [ ++ ++if grep noonsees conftest.$ac_objext >/dev/null ; then ++ ax_cv_c_float_words_bigendian=yes ++fi ++if grep seesnoon conftest.$ac_objext >/dev/null ; then ++ if test "$ax_cv_c_float_words_bigendian" = unknown; then ++ ax_cv_c_float_words_bigendian=no ++ else ++ ax_cv_c_float_words_bigendian=unknown ++ fi ++fi ++ ++])]) ++ ++case $ax_cv_c_float_words_bigendian in ++ yes) ++ m4_default([$1], ++ [AC_DEFINE([FLOAT_WORDS_BIGENDIAN], 1, ++ [Define to 1 if your system stores words within floats ++ with the most significant word first])]) ;; ++ no) ++ $2 ;; ++ *) ++ m4_default([$3], ++ [AC_MSG_ERROR([ ++ ++Unknown float word ordering. You need to manually preset ++ax_cv_c_float_words_bigendian=no (or yes) according to your system. ++ ++ ])]) ;; ++esac ++ ++])# AX_C_FLOAT_WORDS_BIGENDIAN +diff --git a/configure.in b/configure.in +index 2d2bf9f..797c7ce 100644 +--- a/configure.in ++++ b/configure.in +@@ -55,6 +55,7 @@ AC_PROG_CPP + AC_PROG_LIBTOOL dnl required version (1.4) DON'T REMOVE! + AC_STDC_HEADERS + AC_C_BIGENDIAN ++AX_C_FLOAT_WORDS_BIGENDIAN + + dnl =========================================================================== + dnl === Local macros +-- +1.2.6 + diff --git a/package/cairo/old_patches/0002-Change-_cairo_fixed_from_double-to-use-the-magic-number-technique.patch b/package/cairo/old_patches/0002-Change-_cairo_fixed_from_double-to-use-the-magic-number-technique.patch new file mode 100644 index 000000000..56d8b7e99 --- /dev/null +++ b/package/cairo/old_patches/0002-Change-_cairo_fixed_from_double-to-use-the-magic-number-technique.patch @@ -0,0 +1,79 @@ +From nobody Mon Sep 17 00:00:00 2001 +From: Dan Amelang <dan@amelang.net> +Date: Sun Oct 29 21:31:23 2006 -0800 +Subject: [PATCH] Change _cairo_fixed_from_double to use the "magic number" technique + +See long thread here: +http://lists.freedesktop.org/archives/cairo/2006-October/008285.html + +--- + + src/cairo-fixed.c | 48 +++++++++++++++++++++++++++++++++++++++++++++++- + 1 files changed, 47 insertions(+), 1 deletions(-) + +d88acddcabe770e17664b34a2d5f74d3926e1642 +diff --git a/src/cairo-fixed.c b/src/cairo-fixed.c +index 604c9e7..fe6c2dc 100644 +--- a/src/cairo-fixed.c ++++ b/src/cairo-fixed.c +@@ -42,10 +42,56 @@ _cairo_fixed_from_int (int i) + return i << 16; + } + ++/* This is the "magic number" approach to converting a double into fixed ++ * point as described here: ++ * ++ * http://www.stereopsis.com/sree/fpu2006.html (an overview) ++ * http://www.d6.com/users/checker/pdfs/gdmfp.pdf (in detail) ++ * ++ * The basic idea is to add a large enough number to the double that the ++ * literal floating point is moved up to the extent that it forces the ++ * double's value to be shifted down to the bottom of the mantissa (to make ++ * room for the large number being added in). Since the mantissa is, at a ++ * given moment in time, a fixed point integer itself, one can convert a ++ * float to various fixed point representations by moving around the point ++ * of a floating point number through arithmetic operations. This behavior ++ * is reliable on most modern platforms as it is mandated by the IEEE-754 ++ * standard for floating point arithmetic. ++ * ++ * For our purposes, a "magic number" must be carefully selected that is ++ * both large enough to produce the desired point-shifting effect, and also ++ * has no lower bits in its representation that would interfere with our ++ * value at the bottom of the mantissa. The magic number is calculated as ++ * follows: ++ * ++ * (2 ^ (MANTISSA_SIZE - FRACTIONAL_SIZE)) * 1.5 ++ * ++ * where in our case: ++ * - MANTISSA_SIZE for 64-bit doubles is 52 ++ * - FRACTIONAL_SIZE for 16.16 fixed point is 16 ++ * ++ * Although this approach provides a very large speedup of this function ++ * on a wide-array of systems, it does come with two caveats: ++ * ++ * 1) It uses banker's rounding as opposed to arithmetic rounding. ++ * 2) It doesn't function properly if the FPU is in single-precision ++ * mode. ++ */ ++#define CAIRO_MAGIC_NUMBER_FIXED_16_16 (103079215104.0) + cairo_fixed_t + _cairo_fixed_from_double (double d) + { +- return (cairo_fixed_t) floor (d * 65536 + 0.5); ++ union { ++ double d; ++ int32_t i[2]; ++ } u; ++ ++ u.d = d + CAIRO_MAGIC_NUMBER_FIXED_16_16; ++#ifdef FLOAT_WORDS_BIGENDIAN ++ return u.i[1]; ++#else ++ return u.i[0]; ++#endif + } + + cairo_fixed_t +-- +1.2.6 + |