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Initial commit based on GLM 0.9.B.1 code

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This commit is contained in:
Christophe Riccio 2010-04-14 13:23:59 +01:00
commit 25b03fe24c
288 changed files with 50254 additions and 0 deletions
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14
CMakeLists.txt Normal file
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cmake_minimum_required(VERSION 2.6 FATAL_ERROR)
cmake_policy(VERSION 2.6)
project(glm)
add_definitions(-D_CRT_SECURE_NO_WARNINGS)
#add_definitions(-mfpmath=sse)
#add_definitions(-msse3)
#add_definitions(-Wextra)
add_subdirectory(glm)
add_subdirectory(doc)
add_subdirectory(sample)
add_subdirectory(test)

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set(NAME glm-doc)
file(GLOB ROOT_CPP src/*.cpp)
file(GLOB ROOT_XML src/*.xml)
file(GLOB ROOT_XSL src/*.xsl)
source_group("XML Files" FILES ${ROOT_XML})
source_group("XSL Files" FILES ${ROOT_XSL})
add_executable(${NAME} ${ROOT_CPP} ${ROOT_XML} ${ROOT_XSL})

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xalan -m -o ..\index.html ..\src\data.xml ..\src\news.xsl
xalan -m -o ..\download.html ..\src\data.xml ..\src\download.xsl
xalan -m -o ..\changelog.html ..\src\data.xml ..\src\changelog.xsl
xalan -m -o ..\issue.html ..\src\data.xml ..\src\issue.xsl
xalan -m -o ..\link.html ..\src\data.xml ..\src\link.xsl
xalan -m -o ..\goodies.html ..\src\data.xml ..\src\goodies.xsl
xalan -m -o ..\about.html ..\src\data.xml ..\src\about.xsl
xalan -m -o ..\code.html ..\src\data.xml ..\src\code.xsl
pause

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BODY,H1,H2,H3,H4,H5,H6,P,CENTER,TD,TH,UL,DL,DIV {
font-family: Geneva, Arial, Helvetica, sans-serif;
}
BODY,TD {
font-size: 90%;
}
H1 {
text-align: center;
font-size: 160%;
}
H2 {
font-size: 120%;
}
H3 {
font-size: 100%;
}
CAPTION {
font-weight: bold
}
DIV.qindex {
width: 100%;
background-color: #ff8000;/*#e8eef2;*/
border: 1px solid #ff8000;
text-align: center;
margin: 2px;
padding: 2px;
line-height: 140%;
}
DIV.navpath {
width: 100%;
background-color: #ff8000;/*e8eef2*/
border: 1px solid #ff8000;
text-align: center;
margin: 2px;
padding: 2px;
line-height: 140%;
}
DIV.navtab {
background-color: #ff8000;/*#e8eef2;*/
border: 1px solid #ff8000;
text-align: center;
margin: 2px;
margin-right: 15px;
padding: 2px;
}
TD.navtab {
font-size: 70%;
}
A.qindex {
text-decoration: none;
font-weight: bold;
color: #ff8000;
}
A.qindex:visited {
text-decoration: none;
font-weight: bold;
color: #ff8000
}
A.qindex:hover {
text-decoration: none;
background-color: #ffe0c0;
}
A.qindexHL {
text-decoration: none;
font-weight: bold;
background-color: #ffe0c0;
color: #ffffff;
border: 1px double #ffe0c0;
}
A.qindexHL:hover {
text-decoration: none;
background-color: #ffe0c0;
color: #ffffff;
}
A.qindexHL:visited {
text-decoration: none;
background-color: #ffe0c0;
color: #ffffff
}
A.el {
text-decoration: none;
font-weight: bold
}
A.elRef {
font-weight: bold
}
A.code:link {
text-decoration: none;
font-weight: normal;
color: #ff8000
}
A.code:visited {
text-decoration: none;
font-weight: normal;
color: #ff8000
}
A.codeRef:link {
font-weight: normal;
color: #ff8000
}
A.codeRef:visited {
font-weight: normal;
color: #ff8000
}
A:hover {
text-decoration: none;
background-color: #f2f2ff
}
DL.el {
margin-left: -1cm
}
.fragment {
font-family: monospace, fixed;
font-size: 95%;
}
PRE.fragment {
border: 1px solid #CCCCCC;
background-color: #f5f5f5;
margin-top: 4px;
margin-bottom: 4px;
margin-left: 2px;
margin-right: 8px;
padding-left: 6px;
padding-right: 6px;
padding-top: 4px;
padding-bottom: 4px;
}
DIV.ah {
background-color: black;
font-weight: bold;
color: #ffffff;
margin-bottom: 3px;
margin-top: 3px
}
DIV.groupHeader {
margin-left: 16px;
margin-top: 12px;
margin-bottom: 6px;
font-weight: bold;
}
DIV.groupText {
margin-left: 16px;
font-style: italic;
font-size: 90%
}
BODY {
background: white;
color: black;
margin-right: 20px;
margin-left: 20px;
}
TD.indexkey {
background-color: #fff0e0;/*#e8eef2;*/
font-weight : normal;
padding-right : 10px;
padding-top : 8px;
padding-left : 10px;
padding-bottom : 8px;
margin-left : 0px;
margin-right : 0px;
margin-top : 2px;
margin-bottom : 2px;
border: 0px solid #CCCCCC;
-moz-border-radius: 8px 8px 8px 8px;
}
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background-color: #fff0e0;/*#e8eef2;*/
font-style: italic;
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padding-top : 8px;
padding-left : 10px;
padding-bottom : 8px;
margin-left : 0px;
margin-right : 0px;
margin-top : 2px;
margin-bottom : 2px;
border: 0px solid #CCCCCC;
-moz-border-radius: 8px 8px 8px 8px;
}
TR.memlist {
background-color: #f0f0f0;
}
P.formulaDsp {
text-align: center;
}
IMG.formulaDsp {
}
IMG.formulaInl {
vertical-align: middle;
}
SPAN.keyword { color: #008000 }
SPAN.keywordtype { color: #604020 }
SPAN.keywordflow { color: #e08000 }
SPAN.comment { color: #800000 }
SPAN.preprocessor { color: #806020 }
SPAN.stringliteral { color: #002080 }
SPAN.charliteral { color: #008080 }
SPAN.vhdldigit { color: #ff00ff }
SPAN.vhdlchar { color: #000000 }
SPAN.vhdlkeyword { color: #700070 }
SPAN.vhdllogic { color: #ff0000 }
.mdescLeft {
padding: 0px 8px 4px 8px;
font-size: 80%;
font-style: italic;
background-color: #FAFAFA;
border-top: 1px none #E0E0E0;
border-right: 1px none #E0E0E0;
border-bottom: 1px none #E0E0E0;
border-left: 1px none #E0E0E0;
margin: 0px;
}
.mdescRight {
padding: 0px 8px 4px 8px;
font-size: 80%;
font-style: italic;
background-color: #FAFAFA;
border-top: 1px none #E0E0E0;
border-right: 1px none #E0E0E0;
border-bottom: 1px none #E0E0E0;
border-left: 1px none #E0E0E0;
margin: 0px;
}
.memItemLeft {
padding: 1px 0px 0px 8px;
margin: 4px;
border-top-width: 1px;
border-right-width: 1px;
border-bottom-width: 1px;
border-left-width: 1px;
border-top-color: #E0E0E0;
border-right-color: #E0E0E0;
border-bottom-color: #E0E0E0;
border-left-color: #E0E0E0;
border-top-style: solid;
border-right-style: none;
border-bottom-style: none;
border-left-style: none;
background-color: #FAFAFA;
font-size: 80%;
}
.memItemRight {
padding: 1px 8px 0px 8px;
margin: 4px;
border-top-width: 1px;
border-right-width: 1px;
border-bottom-width: 1px;
border-left-width: 1px;
border-top-color: #E0E0E0;
border-right-color: #E0E0E0;
border-bottom-color: #E0E0E0;
border-left-color: #E0E0E0;
border-top-style: solid;
border-right-style: none;
border-bottom-style: none;
border-left-style: none;
background-color: #FAFAFA;
font-size: 80%;
}
.memTemplItemLeft {
padding: 1px 0px 0px 8px;
margin: 4px;
border-top-width: 1px;
border-right-width: 1px;
border-bottom-width: 1px;
border-left-width: 1px;
border-top-color: #E0E0E0;
border-right-color: #E0E0E0;
border-bottom-color: #E0E0E0;
border-left-color: #E0E0E0;
border-top-style: none;
border-right-style: none;
border-bottom-style: none;
border-left-style: none;
background-color: #FAFAFA;
font-size: 80%;
}
.memTemplItemRight {
padding: 1px 8px 0px 8px;
margin: 4px;
border-top-width: 1px;
border-right-width: 1px;
border-bottom-width: 1px;
border-left-width: 1px;
border-top-color: #E0E0E0;
border-right-color: #E0E0E0;
border-bottom-color: #E0E0E0;
border-left-color: #E0E0E0;
border-top-style: none;
border-right-style: none;
border-bottom-style: none;
border-left-style: none;
background-color: #FAFAFA;
font-size: 80%;
}
.memTemplParams {
padding: 1px 0px 0px 8px;
margin: 4px;
border-top-width: 1px;
border-right-width: 1px;
border-bottom-width: 1px;
border-left-width: 1px;
border-top-color: #E0E0E0;
border-right-color: #E0E0E0;
border-bottom-color: #E0E0E0;
border-left-color: #E0E0E0;
border-top-style: solid;
border-right-style: none;
border-bottom-style: none;
border-left-style: none;
color: #606060;
background-color: #FAFAFA;
font-size: 80%;
}
.search {
color: #003399;
font-weight: bold;
}
FORM.search {
margin-bottom: 0px;
margin-top: 0px;
}
INPUT.search {
font-size: 75%;
color: #402000;
font-weight: normal;
background-color: #ffe0c0;
}
TD.tiny {
font-size: 75%;
}
a {
color: #402000;
}
a:visited {
color: #804000;
}
.dirtab {
padding: 4px;
border-collapse: collapse;
border: 1px solid #fff0e0;
}
TH.dirtab {
background: #fff0e0;
font-weight: bold;
}
HR {
height: 1px;
border: none;
border-top: 1px solid black;
}
/* Style for detailed member documentation */
.memtemplate {
font-size: 80%;
color: #606060;
font-weight: normal;
margin-left: 3px;
}
.memnav {
background-color: #ffe0c0;
border: 1px solid #ffe0c0;
text-align: center;
margin: 2px;
margin-right: 15px;
padding: 2px;
}
.memitem {
padding: 4px;
background-color: #fff0e0;
border-width: 1px;
border-style: solid;
border-color: #fff0e0;
-moz-border-radius: 8px 8px 8px 8px;
}
.memname {
white-space: nowrap;
font-weight: bold;
}
.memdoc{
padding-left: 10px;
}
.memproto {
background-color: #ffe0c0;
width: 100%;
border-width: 1px;
border-style: solid;
border-color: #ffe0c0;
font-weight: bold;
-moz-border-radius: 8px 8px 8px 8px;
}
.paramkey {
text-align: right;
}
.paramtype {
white-space: nowrap;
}
.paramname {
color: #602020;
font-style: italic;
white-space: nowrap;
}
/* End Styling for detailed member documentation */
/* for the tree view */
.ftvtree {
font-family: sans-serif;
margin:0.5em;
}
/* these are for tree view when used as main index */
.directory {
font-size: 9pt;
font-weight: bold;
}
.directory h3 {
margin: 0px;
margin-top: 1em;
font-size: 11pt;
}
/* The following two styles can be used to replace the root node title */
/* with an image of your choice. Simply uncomment the next two styles, */
/* specify the name of your image and be sure to set 'height' to the */
/* proper pixel height of your image. */
/* .directory h3.swap { */
/* height: 61px; */
/* background-repeat: no-repeat; */
/* background-image: url("yourimage.gif"); */
/* } */
/* .directory h3.swap span { */
/* display: none; */
/* } */
.directory > h3 {
margin-top: 0;
}
.directory p {
margin: 0px;
white-space: nowrap;
}
.directory div {
display: none;
margin: 0px;
}
.directory img {
vertical-align: -30%;
}
/* these are for tree view when not used as main index */
.directory-alt {
font-size: 100%;
font-weight: bold;
}
.directory-alt h3 {
margin: 0px;
margin-top: 1em;
font-size: 11pt;
}
.directory-alt > h3 {
margin-top: 0;
}
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margin: 0px;
white-space: nowrap;
}
.directory-alt div {
display: none;
margin: 0px;
}
.directory-alt img {
vertical-align: -30%;
}

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/* tabs styles, based on http://www.alistapart.com/articles/slidingdoors */
DIV.tabs
{
float : left;
width : 100%;
background : url("tab_b.gif") repeat-x bottom;
margin-bottom : 4px;
}
DIV.tabs UL
{
margin : 0px;
padding-left : 10px;
list-style : none;
}
DIV.tabs LI, DIV.tabs FORM
{
display : inline;
margin : 0px;
padding : 0px;
}
DIV.tabs FORM
{
float : right;
}
DIV.tabs A
{
float : left;
background : url("tab_r.gif") no-repeat right top;
border-bottom : 1px solid #FF8000;
font-size : x-small;
font-weight : bold;
text-decoration : none;
}
DIV.tabs A:hover
{
background-position: 100% -150px;
}
DIV.tabs A:link, DIV.tabs A:visited,
DIV.tabs A:active, DIV.tabs A:hover
{
color: #000000;/*#1A419D;*/
}
DIV.tabs SPAN
{
float : left;
display : block;
background : url("tab_l.gif") no-repeat left top;
padding : 5px 9px;
white-space : nowrap;
}
DIV.tabs INPUT
{
float : right;
display : inline;
font-size : 1em;
}
DIV.tabs TD
{
font-size : x-small;
font-weight : bold;
text-decoration : none;
}
/* Commented Backslash Hack hides rule from IE5-Mac \*/
DIV.tabs SPAN {float : none;}
/* End IE5-Mac hack */
DIV.tabs A:hover SPAN
{
background-position: 0% -150px;
}
DIV.tabs LI.current A
{
background-position: 100% -150px;
border-width : 0px;
}
DIV.tabs LI.current SPAN
{
background-position: 0% -150px;
padding-bottom : 6px;
}
DIV.navpath
{
background : none;
border : none;
border-bottom : 1px solid #FF8000;
}

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body
{
background-color:#fff8f0;
width:100%;
}
table
{
background-color:#ffffff;
width:800px;
margin-left:auto;
margin-right:auto;
}
table.principale
{
background-color:#ff8000;
border-style:none;
border-width:0px;
border-spacing:0px;
margin-top: 0px;
margin-bottom: 0px;
margin-right: 0px;
margin-left: 0px;
padding-right: 0px;
padding-left: 0px;
padding-bottom: 0px;
padding-top: 0px;
width:100%;
}
tr.principale
{
background-color:#ff8000;
border-style:none;
border-width:0px;
border-spacing:0px;
margin-top: 0px;
margin-bottom: 0px;
margin-right: 0px;
margin-left: 0px;
padding-right: 0px;
padding-left: 0px;
padding-bottom: 0px;
padding-top: 0px;
}
div.title1
{
text-align:center;
font-size:48px;
border-style:solid;
border-width:0px;
color:#000000;
}
div.title2
{
text-align:left;
font-size:20px;
font-weight:bold;
color:#000000;
}
div.title3
{
text-align:center;
font-size:16px;
border-style:none;
border-width:1px;
}
div.title4
{
text-align:left;
font-size:16px;
font-weight:bolder;
color:#FF8000;
}
div.title-date
{
text-align:right;
font-size:16px;
font-weight:bolder;
color:#FF8000;
}
div.menu1
{
text-align:center;
font-size:16px;
font-weight:bolder;
}
div.menu2
{
text-align:center;
font-size:16px;
}
div.news-separator
{
text-align:center;
color:#FF8000;
}
div.email
{
text-align:center;
}
div.image
{
text-align:right;
}
img.menu-img
{
text-align:center;
font-size:16px;
border-color:#000000;
border-style:solid;
border-width:0px;
}
div.paragraph
{
/*text-indent:32px; */
text-align:justify;
}
div.block
{
padding-right: 16px;
padding-left: 16px;
}
div.include
{
color:#0000FF;
}
spam.key
{
color:#0000FF;
}
div.comment
{
color:#008000;
}
td.page
{
vertical-align:top;
padding-right: 32px;
padding-left: 32px;
padding-bottom: 0px;
padding-top: 0px;
width:100%;
}
td.menu
{
vertical-align:top;
text-align:right;
border-width:0px;
border-right-style:solid;
border-color:#000000;
width:160px;
padding-right: 32px;
padding-left: 0px;
padding-bottom: 0px;
padding-top: 0px;
}
/*
a.menu
{
color:#FF8000;
font-weight:bolder;
}
*/
a.menu
{
color:#008000;
}
a
{
color:#008000;
}
div.issue-content
{
text-indent:32px;
}
div.issue-title
{
font-weight:bold;
}

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=============================
GLM 0.9.A.1 final: 2010-02-09
-----------------------------
- Removed deprecated features
- Internal redesign
=============================
GLM 0.8.4.4 final: 2010-01-25
-----------------------------
- Fixed warnings
=============================
GLM 0.8.4.3 final: 2009-11-16
-----------------------------
- Fixed Half float arithmetic
- Fixed setup defines
=============================
GLM 0.8.4.2 final: 2009-10-19
-----------------------------
- Fixed Half float adds
=============================
GLM 0.8.4.1 final: 2009-10-05
-----------------------------
- Updated documentation
- Fixed MacOS X build
=============================
GLM 0.8.4.0 final: 2009-09-16
-----------------------------
- Added GCC 4.4 and VC2010 support
- Added matrix optimizations
=============================
GLM 0.8.3.5 final: 2009-08-11
-----------------------------
- Fixed bugs
=============================
GLM 0.8.3.4 final: 2009-08-10
-----------------------------
- Updated GLM according GLSL 1.5 spec
- Fixed bugs
=============================
GLM 0.8.3.3 final: 2009-06-25
-----------------------------
- Fixed bugs
=============================
GLM 0.8.3.2 final: 2009-06-04
-----------------------------
- Added GLM_GTC_quaternion
- Added GLM_GTC_type_precision
=============================
GLM 0.8.3.1 final: 2009-05-21
-----------------------------
- Fixed old extension system.
=============================
GLM 0.8.3.0 final: 2009-05-06
-----------------------------
- Added stable extensions.
- Added new extension system.
=============================
GLM 0.8.2.3 final: 2009-04-01
-----------------------------
- Fixed bugs.
=============================
GLM 0.8.2.2 final: 2009-02-24
-----------------------------
- Fixed bugs.
=============================
GLM 0.8.2.1 final: 2009-02-13
-----------------------------
- Fixed bugs.
=============================
GLM 0.8.2 final: 2009-01-21
-----------------------------
- Fixed bugs.
=============================
GLM 0.8.1 final: 2008-10-30
-----------------------------
- Fixed bugs.
=============================
GLM 0.8.0 final: 2008-10-23
-----------------------------
- New method to use extension.
=============================
GLM 0.8.0 beta3: 2008-10-10
-----------------------------
- Added CMake support for GLM tests.
=============================
GLM 0.8.0 beta2: 2008-10-04
-----------------------------
- Improved half scalars and vectors support.
=============================
GLM 0.8.0 beta1: 2008-09-26
-----------------------------
- Improved GLSL conformance
- Added GLSL 1.30 support
- Improved API documentation
=============================
GLM 0.7.6 final: 2008-08-08
---------------------------
- Improved C++ standard comformance
- Added Static assert for types checking
===========================
GLM 0.7.5 final: 2008-07-05
---------------------------
- Added build message system with Visual Studio
- Pedantic build with GCC
===========================
GLM 0.7.4 final: 2008-06-01
---------------------------
- Added external dependencies system.
===========================
GLM 0.7.3 final: 2008-05-24
---------------------------
- Fixed bugs
- Added new extension group
===========================
GLM 0.7.2 final: 2008-04-27
---------------------------
- Updated documentation
- Added preprocessor options
===========================
GLM 0.7.1 final: 2008-03-24
---------------------------
- Disabled half on GCC
- Fixed extensions
===========================
GLM 0.7.0 final: 2008-03-22
---------------------------
- Changed to MIT license
- Added new documentation
===========================
GLM 0.6.4 : 2007-12-10
---------------------------
- Fixed swizzle operators
===========================
GLM 0.6.3 : 2007-11-05
---------------------------
- Fixed type data accesses
- Fixed 3DSMax sdk conflict
===========================
GLM 0.6.2 : 2007-10-08
---------------------------
- Fixed extension
===========================
GLM 0.6.1 : 2007-10-07
---------------------------
- Fixed a namespace error
- Added extensions
===========================
GLM 0.6.0 : 2007-09-16
---------------------------
- Added new extension namespace mecanium
- Added Automatic compiler detection
===========================
GLM 0.5.1 : 2007-02-19
---------------------------
- Fixed swizzle operators
===========================
GLM 0.5.0 : 2007-01-06
---------------------------
- Upgrated to GLSL 1.2
- Added swizzle operators
- Added setup settings
===========================
GLM 0.4.1 : 2006-05-22
---------------------------
- Added OpenGL examples
===========================
GLM 0.4.0 : 2006-05-17
---------------------------
- Added missing operators to vec* and mat*
- Added first GLSL 1.2 features
- Fixed windows.h before glm.h when windows.h required
===========================
GLM 0.3.2 : 2006-04-21
---------------------------
- Fixed texcoord components access.
- Fixed mat4 and imat4 division operators.
===========================
GLM 0.3.1 : 2006-03-28
---------------------------
- Added GCC 4.0 support under MacOS X.
- Added GCC 4.0 and 4.1 support under Linux.
- Added code optimisations.
===========================
GLM 0.3 : 2006-02-19
---------------------------
- Improved GLSL type conversion and construction compliance.
- Added experimental extensions.
- Added Doxygen Documentation.
- Added code optimisations.
- Fixed bugs.
===========================
GLM 0.2: 2005-05-05
---------------------------
- Improve adaptative from GLSL.
- Add experimental extensions based on OpenGL extension process.
- Fixe bugs.
===========================
GLM 0.1: 2005-02-21
---------------------------
- Add vec2, vec3, vec4 GLSL types
- Add ivec2, ivec3, ivec4 GLSL types
- Add bvec2, bvec3, bvec4 GLSL types
- Add mat2, mat3, mat4 GLSL types
- Add almost all functions
===========================
Christophe [Groove] Riccio, glm|AT|g-truc|DOT|net

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<a class="menu" href="./link.html">Links</a>
</div>
<hr />
<div class="menu2">
<a href="http://validator.w3.org/check/referer">
<img class="menu-img" src="http://www.w3.org/Icons/valid-xhtml11" alt="Valid XHTML 1.1!" />
</a>
</div>
<div class="menu2">
<a href="http://www.opengl.org">
<img class="menu-img" src="./common/opengl.jpg" alt="OpenGL"/>
</a>
</div>
<div class="menu2">
<a href="http://www.sourceforge.net">
<img class="menu-img" src="./common/sourceforge.gif" alt="SourceForge"/>
</a>
</div>
<div class="menu2">
<a href="http://www.g-truc.net">
<img class="menu-img" src="./common/g-truc.jpg" alt="G-Truc"/>
</a>
</div>
<hr />
</td>
<td class="page">
<xsl:apply-templates select="./glm/issues" />
</td>
</tr>
</table>
<div class="title3">
<xsl:value-of select="./glm/@copyright" />
<a href="http://www.g-truc.net">G-Truc Creation</a>
</div>
</body>
</html>
</xsl:template>
<xsl:template match="issues">
<div>
<div class="title2">Problématiques</div>
<br />
<xsl:apply-templates select="./issue" />
</div>
</xsl:template>
<xsl:template match="issue">
<div class="issue-title">
<xsl:value-of select="./@number"/>) <xsl:value-of select="./@title"/><br />
</div>
<div>
<xsl:apply-templates select="./entry" />
<br />
<div class="issue-content">
STATUE : <xsl:value-of select="./@statue"/>, <xsl:value-of select="./@date"/>
</div>
</div>
<br />
</xsl:template>
<xsl:template match="entry">
<div class="issue-content">
<xsl:value-of select="./@title"/>: <xsl:value-of select="."/>
</div>
</xsl:template>
</xsl:stylesheet>

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<?xml version="1.0" encoding="iso-8859-1"?>
<xsl:stylesheet version="1.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform">
<xsl:output method="html" media-type="text/html; charset=ISO-8859-1" />
<xsl:include href="./util.xsl" />
<xsl:template match="/">
<html>
<head>
<title>OpenGL Mathematics : Links</title>
<meta http-equiv="Content-Language" content="fr, be, ca, lu, ch" />
<meta http-equiv="Content-Type" content="application/xhtml+xml; charset=iso-8859-1" />
<meta name="copyright" content="&#65533; 2005 C-Truc Creation" />
<link href="./common/style.css" rel="stylesheet" media="screen, print, embossed" type="text/css" />
</head>
<body>
<div class="title1">
<img src="./common/title.png" alt="OpenGL Mathematics" />
</div>
<table>
<tr>
<td class="menu">
<div class="menu1">
<a class="menu" href="./glm/downloads/section/download/@link">
Download <xsl:value-of select="./glm/downloads/section/download/@name" />
</a>
</div>
<hr />
<div class="menu2">
<a class="menu" href="./index.html">News</a>
</div>
<div class="menu2">
<a class="menu" href="./download.html">Downloads</a>
</div>
<div class="menu2">
<a class="menu" href="./changelog.html">Changelog</a>
</div>
<div class="menu2">
<a class="menu" href="./glm-manual.pdf">User manual</a>
</div>
<div class="menu2">
<a class="menu" href="./html/index.html">API Documentation</a>
</div>
<div class="menu2">
<a class="menu" href="http://glf.svn.sourceforge.net/viewvc/glf">SVN Browse</a>
</div>
<div class="menu2">
<a class="menu" href="https://sourceforge.net/tracker/?group_id=129808&amp;atid=901445">Bug tracker</a>
</div>
<div class="menu2">
<a class="menu" href="https://sourceforge.net/tracker/?group_id=129808&amp;atid=715891">Feature requests</a>
</div>
<div class="menu2">
<a class="menu" href="./link.html">Links</a>
</div>
<hr />
<div class="menu2">
<a href="http://validator.w3.org/check/referer">
<img class="menu-img" src="http://www.w3.org/Icons/valid-xhtml11" alt="Valid XHTML 1.1!" />
</a>
</div>
<div class="menu2">
<a href="http://www.opengl.org">
<img class="menu-img" src="./common/opengl.jpg" alt="OpenGL"/>
</a>
</div>
<div class="menu2">
<a href="http://www.sourceforge.net">
<img class="menu-img" src="./common/sourceforge.gif" alt="SourceForge"/>
</a>
</div>
<div class="menu2">
<a href="http://www.g-truc.net">
<img class="menu-img" src="./common/g-truc.jpg" alt="G-Truc"/>
</a>
</div>
<hr />
</td>
<td class="page">
<xsl:apply-templates select="./glm/links" />
</td>
</tr>
</table>
<div class="title3">
<xsl:value-of select="./glm/@copyright" />
<a href="http://www.g-truc.net">G-Truc Creation</a>
</div>
</body>
</html>
</xsl:template>
<xsl:template match="links">
<div>
<div class="title2">Liens</div>
<div class="issue-content">
This page lists all the documents that helped to develop OpenGL Mathematics.
</div>
<br />
<xsl:apply-templates select="./link" />
</div>
</xsl:template>
<xsl:template match="link">
<div class="issue-title">
<a href="{./@link}">
<xsl:value-of select="./@name"/>
</a>
</div>
<div class="issue-content">
<xsl:value-of select="."/>
</div>
<br />
</xsl:template>
</xsl:stylesheet>

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<?xml version="1.0" encoding="iso-8859-1"?>
<xsl:stylesheet version="1.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform">
<xsl:output method="html" media-type="text/html; charset=ISO-8859-1" />
<xsl:include href="./util.xsl" />
<xsl:template match="/">
<html>
<head>
<title>OpenGL Mathematics: News</title>
<meta http-equiv="Content-Language" content="en" />
<meta http-equiv="Content-Type" content="application/xhtml+xml; charset=iso-8859-1" />
<meta name="copyright" content="G-Truc Creation" />
<link href="./common/style.css" rel="stylesheet" media="screen, print, embossed" type="text/css" />
</head>
<body>
<table>
<tr>
<td class="menu">
<xsl:apply-templates select="./glm/menu" />
</td>
<td class="page">
<!--div class="title1">OpenGL Mathematics</div-->
<div class="title1">
<img src="./common/title.png" alt="OpenGL Mathematics" />
</div>
<xsl:apply-templates select="./glm/about-short" />
<br />
<xsl:apply-templates select="./glm/page_news/news" />
<div class="title3">
<xsl:value-of select="./glm/@copyright" />
<a href="http://www.g-truc.net">G-Truc Creation</a>
</div>
</td>
</tr>
</table>
</body>
</html>
</xsl:template>
<xsl:template match="news">
<div>
<div class="title-date">
<xsl:value-of select="./@date" />
</div>
<div class="title4">
<xsl:value-of select="./@title" />
</div>
<div>
<xsl:if test="./paragraph">
<xsl:apply-templates select="./paragraph" />
</xsl:if>
<xsl:if test="./list">
<xsl:apply-templates select="./list" />
</xsl:if>
<xsl:apply-templates select="./source" />
<!--table style="width:100%;">
<tr style="width:100%;">
<td>
<xsl:if test="./paragraph">
<xsl:apply-templates select="./paragraph" />
</xsl:if>
<xsl:if test="./list">
<xsl:apply-templates select="./list" />
</xsl:if>
<xsl:apply-templates select="./source" />
</td>
<td style="text-align:right;">
<a ref="{./@image}"><img src="{./@image-mini}" alt=" " /></a>
</td>
</tr>
</table-->
</div>
<div class="news-separator">_________________</div>
<br />
</div>
</xsl:template>
</xsl:stylesheet>

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<?xml version="1.0" encoding="iso-8859-1"?>
<xsl:stylesheet version="1.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform">
<xsl:strip-space elements="*" />
<xsl:output
method="xml"
media-type="application/xhtml+xml; charset=iso-8859-1"
version="1.0"
encoding="iso-8859-1"
standalone="no"
omit-xml-declaration="no"
doctype-public="-//W3C//DTD XHTML 1.1//EN"
doctype-system="http://www.w3.org/TR/xhtml11/DTD/xhtml11.dtd"
indent="no" />
<xsl:template match="link">
<a href="{./@href}"><xsl:value-of select="." /></a>
</xsl:template>
<xsl:template match="image">
<xsl:choose>
<xsl:when test="./@href">
<xsl:element name="a">
<xsl:attribute name="class">menu-titre2</xsl:attribute>
<xsl:attribute name="href"><xsl:value-of select="./@href" /></xsl:attribute>
<xsl:element name="img">
<xsl:attribute name="src"><xsl:value-of select="@file" /></xsl:attribute>
<xsl:attribute name="alt"><xsl:value-of select="@file" /></xsl:attribute>
</xsl:element>
</xsl:element>
</xsl:when>
<xsl:otherwise>
<xsl:element name="img">
<xsl:attribute name="src"><xsl:value-of select="@file" /></xsl:attribute>
<xsl:attribute name="alt"><xsl:value-of select="@file" /></xsl:attribute>
</xsl:element>
</xsl:otherwise>
</xsl:choose>
</xsl:template>
<xsl:template match="image-list">
<div class="news-image">
<xsl:apply-templates select="./image-element" />
</div>
</xsl:template>
<xsl:template match="image-element">
<a href="{./@normal}">
<img src="{./@small}" alt="{./@title}" />
</a>
</xsl:template>
<xsl:template match="list">
<xsl:value-of select="./@nom" /><br />
<xsl:apply-templates select="./element"/>
<br />
</xsl:template>
<xsl:template match="element">
<xsl:apply-templates /><br />
</xsl:template>
<xsl:template match="paragraph">
<div class="paragraph"><xsl:text /><xsl:apply-templates /><xsl:text /></div><br />
</xsl:template>
<xsl:template match="about-short">
<div class="title3">
<xsl:apply-templates select="./element" />
</div>
<br />
</xsl:template>
<xsl:template match="source">
<xsl:value-of select="./@type"/>: <a href="{./@adresse}"><xsl:value-of select="."/></a><br />
</xsl:template>
<xsl:template match="menu">
<div class="menu1">
<br />
<div>
<a href="./goodies/logo1920x1200.png">
<img class="menu-img" src="./common/logo.png" alt="GLM Logo"/>
</a>
</div>
<br />
<div>
<a class="menu" href="{/glm/downloads/section/download/@link}">
Download <xsl:value-of select="/glm/downloads/section/download/@name" />
</a>
</div>
</div>
<br />
<xsl:apply-templates select="./menu-group"/>
<div class="menu1">
<img class="menu-img" src="./common/email.png" alt="contact"/>
</div>
<br />
<xsl:apply-templates select="./menu-link"/>
<br />
<!--div>
<script type="text/javascript" src="http://feedjit.com/map/?bc=FFFFFF&amp;tc=494949&amp;brd1=FFFFFF&amp;lnk=494949&amp;hc=FF8000&amp;dot=FF8000"></script>
<noscript>
<a href="http://feedjit.com/">Feedjit Live Blog Stats</a>
</noscript>
</div-->
</xsl:template>
<xsl:template match="menu-pic">
<div class="menu2">
<a href="{@href}">
<img class="menu-img" src="{@image}" alt="{@name}"/>
</a>
</div>
</xsl:template>
<xsl:template match="menu-link">
<xsl:apply-templates select="./menu-pic"/>
</xsl:template>
<xsl:template match="menu-image">
<div class="menu2">
<a href="./common/glm.jpg">
<img class="menu-img" src="./common/logo.jpg" alt="G-Truc"/>
</a>
</div>
</xsl:template>
<xsl:template match="menu-group">
<xsl:apply-templates select="./menu-entry"/>
<br />
</xsl:template>
<xsl:template match="menu-entry">
<div class="menu2">
<a href="{./@href}">
<xsl:value-of select="./@name"/>
</a>
</div>
</xsl:template>
</xsl:stylesheet>

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attribute
const
uniform
varying
break
continue
do
for
while
if
else
in
out
inout
float
int
void
bool
true
false
discard
return
mat2
mat3
mat4
mat2x2
mat3x3
mat4x4
mat2x3
mat3x2
mat2x4
mat4x2
mat3x4
mat4x3
vec2
vec3
vec4
ivec2
ivec3
ivec4
uvec2
uvec3
uvec4
bvec2
bvec3
bvec4
sampler1D
sampler2D
sampler3D
samplerCube
sampler1DShadow
sampler2DShadow
struct
asm
class
union
enum
typedef
template
this
packed
goto
switch
default
inline
noinline
volatile
public
static
extern
external
interface
long
short
double
half
fixed
unsigned
input
output
sampler2DRect
sampler3DRect
sampler2DRectShadow
sizeof
cast
namespace
using
hvec2
hvec3
hvec4
fvec2
fvec3
fvec4
dvec2
dvec3
dvec4
__uvec2GTX
__uvec3GTX
__uvec4GTX
__ivec2GTX
__ivec3GTX
__ivec4GTX
__hvec2GTX
__hvec3GTX
__hvec4GTX
__fvec2GTX
__fvec3GTX
__fvec4GTX
__dvec2GTX
__dvec3GTX
__dvec4GTX
on
final
abstract
limited
access
self
uchar
schar
uint
sint
int8
int16
int32
int64
sint8
sint16
sint32
sint64
uint8
uint16
uint32
uint64
float16
float32
float64
quat
hquat
fquat
dquat
__quatGTX
__hquatGTX
__fquatGTX
__dquatGTX
handle
handle8
handle16
handle32
handle64
flag
flag8
flag16
flag32
flag64
import
export
hmat2
hmat3
hmat4
fmat2
fmat3
fmat4
dmat2
dmat3
dmat4
hmat2x3
hmat3x2
hmat2x4
hmat4x2
hmat3x4
hmat4x3
fmat2x3
fmat3x2
fmat2x4
fmat4x2
fmat3x4
fmat4x3
dmat2x3
dmat3x2
dmat2x4
dmat4x2
dmat3x4
dmat4x3
__halfGTX
__hvec2GTX
__hvec3GTX
__hvec4GTX
__hmat2GTX
__hmat3GTX
__hmat4GTX
__fmat2GTX
__fmat3GTX
__fmat4GTX
__dmat2GTX
__dmat3GTX
__dmat4GTX
__hmat2x3GTX
__hmat3x2GTX
__hmat2x4GTX
__hmat4x2GTX
__hmat3x4GTX
__hmat4x3GTX
__fmat2x3GTX
__fmat3x2GTX
__fmat2x4GTX
__fmat4x2GTX
__fmat3x4GTX
__fmat4x3GTX
__dmat2x3GTX
__dmat3x2GTX
__dmat2x4GTX
__dmat4x2GTX
__dmat3x4GTX
__dmat4x3GTX
null
pi
epsilon
infinite
self
byte
word
dword
qword
new_object
new_array
delete_object
delete_array
__int8GTX
__int16GTX
__int32GTX
__int64GTX
__i8GTX
__i16GTX
__i32GTX
__i64GTX
__i8vec2GTX
__i8vec3GTX
__i8vec4GTX
__i16vec2GTX
__i16vec3GTX
__i16vec4GTX
__i32vec2GTX
__i32vec3GTX
__i32vec4GTX
__i64vec2GTX
__i64vec3GTX
__i64vec4GTX
__uint8GTX
__uint16GTX
__uint32GTX
__uint64GTX
__u8GTX
__u16GTX
__u32GTX
__u64GTX
__u8vec2GTX
__u8vec3GTX
__u8vec4GTX
__u16vec2GTX
__u16vec3GTX
__u16vec4GTX
__u32vec2GTX
__u32vec3GTX
__u32vec4GTX
__u64vec2GTX
__u64vec3GTX
__u64vec4GTX
__float16GTX
__float32GTX
__float64GTX
__f16GTX
__f32GTX
__f64GTX
__f16vec2GTX
__f16vec3GTX
__f16vec4GTX
__f32vec2GTX
__f32vec3GTX
__f32vec4GTX
__f64vec2GTX
__f64vec3GTX
__f64vec4GTX
__f16mat2GTX
__f16mat3GTX
__f16mat4GTX
__f16mat2x3GTX
__f16mat2x4GTX
__f16mat3x2GTX
__f16mat3x4GTX
__f16mat4x2GTX
__f16mat4x3GTX
__f32mat2GTX
__f32mat3GTX
__f32mat4GTX
__f32mat2x3GTX
__f32mat2x4GTX
__f32mat3x2GTX
__f32mat3x4GTX
__f32mat4x2GTX
__f32mat4x3GTX
__f64mat2GTX
__f64mat3GTX
__f64mat4GTX
__f64mat2x3GTX
__f64mat2x4GTX
__f64mat3x2GTX
__f64mat3x4GTX
__f64mat4x2GTX
__f64mat4x3GTX
__f16quatGTX
__f32quatGTX
__f64quatGTX
int8
int16
int32
int64
i8
i16
i32
i64
i8vec2
i8vec3
i8vec4
i16vec2
i16vec3
i16vec4
i32vec2
i32vec3
i32vec4
i64vec2
i64vec3
i64vec4
uint8
uint16
uint32
uint64
u8
u16
u32
u64
u8vec2
u8vec3
u8vec4
u16vec2
u16vec3
u16vec4
u32vec2
u32vec3
u32vec4
u64vec2
u64vec3
u64vec4
float16
float32
float64
f16
f32
f64
f16vec2
f16vec3
f16vec4
f32vec2
f32vec3
f32vec4
f64vec2
f64vec3
f64vec4
f16mat2
f16mat3
f16mat4
f16mat2x3
f16mat2x4
f16mat3x2
f16mat3x4
f16mat4x2
f16mat4x3
f32mat2
f32mat3
f32mat4
f32mat2x3
f32mat2x4
f32mat3x2
f32mat3x4
f32mat4x2
f32mat4x3
f64mat2
f64mat3
f64mat4
f64mat2x3
f64mat2x4
f64mat3x2
f64mat3x4
f64mat4x2
f64mat4x3
f16quat
f32quat
f64quat
bool1
bool2
bool3
bool4
bool1x1
bool2x2
bool3x3
bool4x4
bool2x3
bool2x4
bool3x2
bool3x4
bool4x2
bool4x3
int1
int2
int3
int4
int1x1
int2x2
int3x3
int4x4
int2x3
int2x4
int3x2
int3x4
int4x2
int4x3
half1
half2
half3
half4
half2x2
half3x3
half4x4
half2x3
half2x4
half3x2
half3x4
half4x2
half4x3
float1
float2
float3
float4
float1x1
float2x2
float3x3
float4x4
float2x3
float2x4
float3x2
float3x4
float4x2
float4x3
double1
double2
double3
double4
double1x1
double2x2
double3x3
double4x4
double2x3
double2x4
double3x2
double3x4
double4x2
double4x3
bool1GTX
bool2GTX
bool3GTX
bool4GTX
bool1x1GTX
bool2x2GTX
bool3x3GTX
bool4x4GTX
bool2x3GTX
bool2x4GTX
bool3x2GTX
bool3x4GTX
bool4x2GTX
bool4x3GTX
__int1GTX
__int2GTX
__int3GTX
__int4GTX
__int1x1GTX
__int2x2GTX
__int3x3GTX
__int4x4GTX
__int2x3GTX
__int2x4GTX
__int3x2GTX
__int3x4GTX
__int4x2GTX
__int4x3GTX
__half1GTX
__half2GTX
__half3GTX
__half4GTX
__half1x1GTX
__half2x2GTX
__half3x3GTX
__half4x4GTX
__half2x3GTX
__half2x4GTX
__half3x2GTX
__half3x4GTX
__half4x2GTX
__half4x3GTX
__float1GTX
__float2GTX
__float3GTX
__float4GTX
__float1x1GTX
__float2x2GTX
__float3x3GTX
__float4x4GTX
__float2x3GTX
__float2x4GTX
__float3x2GTX
__float3x4GTX
__float4x2GTX
__float4x3GTX
__double1GTX
__double2GTX
__double3GTX
__double4GTX
__double1x1GTX
__double2x2GTX
__double3x3GTX
__double4x4GTX
__double2x3GTX
__double2x4GTX
__double3x2GTX
__double3x4GTX
__double4x2GTX
__double4x3GTX

51
glm/CMakeLists.txt Normal file
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set(NAME glm)
file(GLOB ROOT_SOURCE *.cpp)
file(GLOB ROOT_INLINE *.inl)
file(GLOB ROOT_HEADER *.hpp)
file(GLOB_RECURSE CORE_SOURCE ./core/*.cpp)
file(GLOB_RECURSE CORE_INLINE ./core/*.inl)
file(GLOB_RECURSE CORE_HEADER ./core/*.hpp)
file(GLOB_RECURSE GTC_SOURCE ./gtc/*.cpp)
file(GLOB_RECURSE GTC_INLINE ./gtc/*.inl)
file(GLOB_RECURSE GTC_HEADER ./gtc/*.hpp)
file(GLOB_RECURSE GTX_SOURCE ./gtx/*.cpp)
file(GLOB_RECURSE GTX_INLINE ./gtx/*.inl)
file(GLOB_RECURSE GTX_HEADER ./gtx/*.hpp)
file(GLOB_RECURSE IMG_SOURCE ./img/*.cpp)
file(GLOB_RECURSE IMG_INLINE ./img/*.inl)
file(GLOB_RECURSE IMG_HEADER ./img/*.hpp)
file(GLOB_RECURSE VIRTREV_SOURCE ./virtrev/*.cpp)
file(GLOB_RECURSE VIRTREV_INLINE ./virtrev/*.inl)
file(GLOB_RECURSE VIRTREV_HEADER ./virtrev/*.hpp)
source_group("Core Files" FILES ${CORE_SOURCE})
source_group("Core Files" FILES ${CORE_INLINE})
source_group("Core Files" FILES ${CORE_HEADER})
source_group("GTC Files" FILES ${GTC_SOURCE})
source_group("GTC Files" FILES ${GTC_INLINE})
source_group("GTC Files" FILES ${GTC_HEADER})
source_group("GTX Files" FILES ${GTX_SOURCE})
source_group("GTX Files" FILES ${GTX_INLINE})
source_group("GTX Files" FILES ${GTX_HEADER})
source_group("IMG Files" FILES ${IMG_SOURCE})
source_group("IMG Files" FILES ${IMG_INLINE})
source_group("IMG Files" FILES ${IMG_HEADER})
source_group("VIRTREV Files" FILES ${VIRTREV_SOURCE})
source_group("VIRTREV Files" FILES ${VIRTREV_INLINE})
source_group("VIRTREV Files" FILES ${VIRTREV_HEADER})
include_directories(..)
add_executable(${NAME}
${ROOT_SOURCE} ${ROOT_INLINE} ${ROOT_HEADER}
${CORE_SOURCE} ${CORE_INLINE} ${CORE_HEADER}
${GTC_SOURCE} ${GTC_INLINE} ${GTC_HEADER}
${GTX_SOURCE} ${GTX_INLINE} ${GTX_HEADER}
${IMG_SOURCE} ${IMG_INLINE} ${IMG_HEADER}
${VIRTREV_SOURCE} ${VIRTREV_INLINE} ${VIRTREV_HEADER})

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-07-24
// Updated : 2008-08-31
// Licence : This source is under MIT License
// File : glm/core/_detail.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef glm_core_detail
#define glm_core_detail
#include "../setup.hpp"
#include <cassert>
//#define valType typename genType::value_type
//#define valType_cref typename genType::value_type const &
//#define genType_cref typename genType const &
namespace glm{
namespace detail{
class thalf;
#if(defined(GLM_COMPILER) && (GLM_COMPILER & GLM_COMPILER_VC))
typedef signed __int64 sint64;
typedef unsigned __int64 uint64;
#elif(defined(GLM_COMPILER) && (GLM_COMPILER & GLM_COMPILER_GCC))
__extension__ typedef signed long long sint64;
__extension__ typedef unsigned long long uint64;
#else//unknown compiler
typedef signed long sint64;
typedef unsigned long uint64;
#endif//GLM_COMPILER
template<bool C>
struct If
{
template<typename F, typename T>
static inline T apply(F functor, const T& val)
{
return functor(val);
}
};
template<>
struct If<false>
{
template<typename F, typename T>
static inline T apply(F, const T& val)
{
return val;
}
};
//template <typename T>
//struct traits
//{
// static const bool is_signed = false;
// static const bool is_float = false;
// static const bool is_vector = false;
// static const bool is_matrix = false;
// static const bool is_genType = false;
// static const bool is_genIType = false;
// static const bool is_genUType = false;
//};
//template <>
//struct traits<half>
//{
// static const bool is_float = true;
// static const bool is_genType = true;
//};
//template <>
//struct traits<float>
//{
// static const bool is_float = true;
// static const bool is_genType = true;
//};
//template <>
//struct traits<double>
//{
// static const bool is_float = true;
// static const bool is_genType = true;
//};
//template <typename genType>
//struct desc
//{
// typedef genType type;
// typedef genType * pointer;
// typedef genType const* const_pointer;
// typedef genType const *const const_pointer_const;
// typedef genType *const pointer_const;
// typedef genType & reference;
// typedef genType const& const_reference;
// typedef genType const& param_type;
// typedef typename genType::value_type value_type;
// typedef typename genType::size_type size_type;
// static const typename size_type value_size;
//};
//template <typename genType>
//const typename desc<genType>::size_type desc<genType>::value_size = genType::value_size();
union uif32
{
uif32() :
i(0)
{}
uif32(float f) :
f(f)
{}
uif32(unsigned int i) :
i(i)
{}
float f;
unsigned int i;
};
union uif64
{
uif64() :
i(0)
{}
uif64(double f) :
f(f)
{}
uif64(uint64 i) :
i(i)
{}
double f;
uint64 i;
};
typedef uif32 uif;
//////////////////
// int
template <typename T>
struct is_int
{
enum is_int_enum
{
YES = 0,
NO = 1
};
};
#define GLM_DETAIL_IS_INT(T) \
template <> \
struct is_int<T> \
{ \
enum is_int_enum \
{ \
YES = 1, \
NO = 0 \
}; \
}
//////////////////
// uint
template <typename T>
struct is_uint
{
enum is_uint_enum
{
YES = 0,
NO = 1
};
};
#define GLM_DETAIL_IS_UINT(T) \
template <> \
struct is_uint<T> \
{ \
enum is_uint_enum \
{ \
YES = 1, \
NO = 0 \
}; \
}
//GLM_DETAIL_IS_UINT(unsigned long long)
//////////////////
// float
template <typename T>
struct is_float
{
enum is_float_enum
{
YES = 0,
NO = 1
};
};
#define GLM_DETAIL_IS_FLOAT(T) \
template <> \
struct is_float<T> \
{ \
enum is_float_enum \
{ \
YES = 1, \
NO = 0 \
}; \
}
//////////////////
// bool
template <typename T>
struct is_bool
{
enum is_bool_enum
{
YES = 0,
NO = 1
};
};
template <>
struct is_bool<bool>
{
enum is_bool_enum
{
YES = 1,
NO = 0
};
};
//////////////////
// vector
template <typename T>
struct is_vector
{
enum is_vector_enum
{
YES = 0,
NO = 1
};
};
#define GLM_DETAIL_IS_VECTOR(T) \
template <> \
struct is_vector \
{ \
enum is_vector_enum \
{ \
YES = 1, \
NO = 0 \
}; \
}
//////////////////
// matrix
template <typename T>
struct is_matrix
{
enum is_matrix_enum
{
YES = 0,
NO = 1
};
};
#define GLM_DETAIL_IS_MATRIX(T) \
template <> \
struct is_matrix \
{ \
enum is_matrix_enum \
{ \
YES = 1, \
NO = 0 \
}; \
}
//////////////////
// type
template <typename T>
struct type
{
enum type_enum
{
is_float = is_float<T>::YES,
is_int = is_int<T>::YES,
is_uint = is_uint<T>::YES,
is_bool = is_bool<T>::YES
};
};
//////////////////
// type
typedef signed char int8;
typedef signed short int16;
typedef signed int int32;
typedef detail::sint64 int64;
typedef unsigned char uint8;
typedef unsigned short uint16;
typedef unsigned int uint32;
typedef detail::uint64 uint64;
typedef detail::thalf float16;
typedef float float32;
typedef double float64;
}//namespace detail
}//namespace glm
#endif//glm_core_detail

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2006-04-27
// Updated : 2006-04-27
// Licence : This source is under MIT License
// File : _swizzle.inl
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef __swizzle_inl__
#define __swizzle_inl__
#include "./_swizzle.h"
namespace glm
{
}
#endif//__swizzle_inl__

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int main()
{
}

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-03-08
// Updated : 2010-01-26
// Licence : This source is under MIT License
// File : glm/core/func_common.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef glm_core_func_common
#define glm_core_func_common
namespace glm
{
namespace test{
void main_core_func_common();
}//namespace test
namespace core{
namespace function{
//! Define common functions from Section 8.3 of GLSL 1.30.8 specification. Included in glm namespace.
namespace common{
//! Returns x if x >= 0; otherwise, it returns -x.
//! (From GLSL 1.30.08 specification, section 8.3)
template <typename genFIType>
genFIType abs(genFIType const & x);
//! Returns 1.0 if x > 0, 0.0 if x = 0, or -1.0 if x < 0.
//! (From GLSL 1.30.08 specification, section 8.3)
template <typename genFIType>
genFIType sign(genFIType const & x);
//! Returns a value equal to the nearest integer that is less then or equal to x.
//! (From GLSL 1.30.08 specification, section 8.3)
template <typename genType>
genType floor(genType const & x);
//! Returns a value equal to the nearest integer to x
//! whose absolute value is not larger than the absolute value of x.
//! (From GLSL 1.30.08 specification, section 8.3)
template <typename genType>
genType trunc(genType const & x);
//! Returns a value equal to the nearest integer to x.
//! The fraction 0.5 will round in a direction chosen by the
//! implementation, presumably the direction that is fastest.
//! This includes the possibility that round(x) returns the
//! same value as roundEven(x) for all values of x.
//! (From GLSL 1.30.08 specification, section 8.3)
template <typename genType>
genType round(genType const & x);
//! Returns a value equal to the nearest integer to x.
//! A fractional part of 0.5 will round toward the nearest even
//! integer. (Both 3.5 and 4.5 for x will return 4.0.)
//! (From GLSL 1.30.08 specification, section 8.3)
template <typename genType>
genType roundEven(genType const & x);
//! Returns a value equal to the nearest integer
//! that is greater than or equal to x.
//! (From GLSL 1.30.08 specification, section 8.3)
template <typename genType>
genType ceil(genType const & x);
//! Return x - floor(x).
//! (From GLSL 1.30.08 specification, section 8.3)
template <typename genType>
genType fract(genType const & x);
//! Modulus. Returns x - y * floor(x / y)
//! for each component in x using the floating point value y.
//! (From GLSL 1.30.08 specification, section 8.3)
template <typename genType>
genType mod(
genType const & x,
genType const & y);
//! Modulus. Returns x - y * floor(x / y)
//! for each component in x using the floating point value y.
//! (From GLSL 1.30.08 specification, section 8.3)
template <typename genType>
genType mod(
genType const & x,
typename genType::value_type const & y);
//! Returns the fractional part of x and sets i to the integer
//! part (as a whole number floating point value). Both the
//! return value and the output parameter will have the same
//! sign as x.
//! (From GLSL 1.30.08 specification, section 8.3)
template <typename genType>
genType modf(
genType const & x,
genType & i);
//! Returns y if y < x; otherwise, it returns x.
//! (From GLSL 1.30.08 specification, section 8.3)
template <typename genType>
genType min(
genType const & x,
genType const & y);
template <typename genType>
genType min(
genType const & x,
typename genType::value_type const & y);
//! Returns y if x < y; otherwise, it returns x.
//! (From GLSL 1.30.08 specification, section 8.3)
template <typename genType>
genType max(
genType const & x,
genType const & y);
template <typename genType>
genType max(
genType const & x,
typename genType::value_type const & y);
//! Returns min(max(x, minVal), maxVal) for each component in x
//! using the floating-point values minVal and maxVal.
//! (From GLSL 1.30.08 specification, section 8.3)
template <typename genType>
genType clamp(
genType const & x,
genType const & minVal,
genType const & maxVal);
template <typename genType>
genType clamp(
genType const & x,
typename genType::value_type const & minVal,
typename genType::value_type const & maxVal);
//! \return If genTypeU is a floating scalar or vector:
//! Returns x * (1.0 - a) + y * a, i.e., the linear blend of
//! x and y using the floating-point value a.
//! The value for a is not restricted to the range [0, 1].
//!
//! \return If genTypeU is a boolean scalar or vector:
//! Selects which vector each returned component comes
//! from. For a component of a that is false, the
//! corresponding component of x is returned. For a
//! component of a that is true, the corresponding
//! component of y is returned. Components of x and y that
//! are not selected are allowed to be invalid floating point
//! values and will have no effect on the results. Thus, this
//! provides different functionality than
//! genType mix(genType x, genType y, genType(a))
//! where a is a Boolean vector.
//!
//! From GLSL 1.30.08 specification, section 8.3
//!
//! \param[in] x Floating point scalar or vector.
//! \param[in] y Floating point scalar or vector.
//! \param[in] a Floating point or boolean scalar or vector.
//!
// \todo Test when 'a' is a boolean.
template <typename genTypeT, typename genTypeU>
genTypeT mix(genTypeT const & x, genTypeT const & y, genTypeU const & a);
//! Returns 0.0 if x < edge, otherwise it returns 1.0.
//! (From GLSL 1.30.08 specification, section 8.3)
template <typename genType>
genType step(
genType const & edge,
genType const & x);
template <typename genType>
genType step(
typename genType::value_type const & edge,
genType const & x);
//! Returns 0.0 if x <= edge0 and 1.0 if x >= edge1 and
//! performs smooth Hermite interpolation between 0 and 1
//! when edge0 < x < edge1. This is useful in cases where
//! you would want a threshold function with a smooth
//! transition. This is equivalent to:
//! genType t;
//! t = clamp ((x edge0) / (edge1 edge0), 0, 1);
//! return t * t * (3 2 * t);
//! Results are undefined if edge0 >= edge1.
//! (From GLSL 1.30.08 specification, section 8.3)
template <typename genType>
genType smoothstep(
genType const & edge0,
genType const & edge1,
genType const & x);
template <typename genType>
genType smoothstep(
typename genType::value_type const & edge0,
typename genType::value_type const & edge1,
genType const & x);
//! Returns true if x holds a NaN (not a number)
//! representation in the underlying implementation's set of
//! floating point representations. Returns false otherwise,
//! including for implementations with no NaN
//! representations.
//! (From GLSL 1.30.08 specification, section 8.3)
template <typename genType>
typename genType::bool_type isnan(genType const & x);
//! Returns true if x holds a positive infinity or negative
//! infinity representation in the underlying implementation's
//! set of floating point representations. Returns false
//! otherwise, including for implementations with no infinity
//! representations.
//! (From GLSL 1.30.08 specification, section 8.3)
template <typename genType>
typename genType::bool_type isinf(genType const & x);
//! Returns a signed or unsigned integer value representing
//! the encoding of a floating-point value. The floatingpoint
//! value's bit-level representation is preserved.
//! (From GLSL 4.00.08 specification, section 8.3)
template <typename genType, typename genIType>
genIType floatBitsToInt(genType const & value);
//! Returns a signed or unsigned integer value representing
//! the encoding of a floating-point value. The floatingpoint
//! value's bit-level representation is preserved.
//! (From GLSL 4.00.08 specification, section 8.3)
template <typename genType, typename genUType>
genUType floatBitsToInt(genType const & value);
//! Returns a floating-point value corresponding to a signed
//! or unsigned integer encoding of a floating-point value.
//! If an inf or NaN is passed in, it will not signal, and the
//! resulting floating point value is unspecified. Otherwise,
//! the bit-level representation is preserved.
//! (From GLSL 4.00.08 specification, section 8.3)
template <typename genType, typename genIUType>
genType intBitsToFloat(genIUType const & value);
//! Computes and returns a * b + c.
//! (From GLSL 4.00.08 specification, section 8.3)
template <typename genType>
genType fma(genType const & a, genType const & b, genType const & c);
//! Splits x into a floating-point significand in the range
//! [0.5, 1.0) and an integral exponent of two, such that:
//! x = significand * exp(2, exponent)
//! The significand is returned by the function and the
//! exponent is returned in the parameter exp. For a
//! floating-point value of zero, the significant and exponent
//! are both zero. For a floating-point value that is an
//! infinity or is not a number, the results are undefined.
//! (From GLSL 4.00.08 specification, section 8.3)
template <typename genType, typename genIType>
genType frexp(genType const & x, genIType & exp);
//! Builds a floating-point number from x and the
//! corresponding integral exponent of two in exp, returning:
//! significand * exp(2, exponent)
//! If this product is too large to be represented in the
//! floating-point type, the result is undefined.
//! (From GLSL 4.00.08 specification, section 8.3)
template <typename genType, typename genIType>
genType ldexp(genType const & x, genIType const & exp);
}//namespace common
}//namespace function
}//namespace core
using namespace core::function::common;
}//namespace glm
#include "func_common.inl"
#endif//glm_core_func_common

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-08-08
// Updated : 2010-02-04
// Licence : This source is under MIT License
// File : glm/core/func_exponential.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef glm_core_func_exponential
#define glm_core_func_exponential
namespace glm
{
namespace test{
void main_core_func_exponential();
}//namespace test
namespace core{
namespace function{
//! Define all exponential functions from Section 8.2 of GLSL 1.30.8 specification. Included in glm namespace.
namespace exponential{
//! Returns x raised to the y power.
//! (From GLSL 1.30.08 specification, section 8.2)
template <typename genType>
genType pow(genType const & x, genType const & y);
//! Returns the natural exponentiation of x, i.e., e^x.
//! (From GLSL 1.30.08 specification, section 8.2)
template <typename genType>
genType exp(genType const & x);
//! Returns the natural logarithm of x, i.e.,
//! returns the value y which satisfies the equation x = e^y.
//! Results are undefined if x <= 0.
//! (From GLSL 1.30.08 specification, section 8.2)
template <typename genType>
genType log(genType const & x);
//! Returns 2 raised to the x power.
//! (From GLSL 1.30.08 specification, section 8.2)
template <typename genType>
genType exp2(genType const & x);
//! Returns the base 2 log of x, i.e., returns the value y,
//! which satisfies the equation x = 2 ^ y.
//! (From GLSL 1.30.08 specification, section 8.2)
template <typename genType>
genType log2(genType const & x);
//! Returns the positive square root of x.
//! (From GLSL 1.30.08 specification, section 8.2)
template <typename genType>
genType sqrt(genType const & x);
//! Returns the reciprocal of the positive square root of x.
//! (From GLSL 1.30.08 specification, section 8.2)
template <typename genType>
genType inversesqrt(genType const & x);
}//namespace exponential
}//namespace function
}//namespace core
using namespace core::function::exponential;
}//namespace glm
#include "func_exponential.inl"
#endif//glm_core_func_exponential

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-08-03
// Updated : 2010-02-04
// Licence : This source is under MIT License
// File : glm/core/func_exponential.inl
///////////////////////////////////////////////////////////////////////////////////////////////////
namespace glm
{
namespace core{
namespace function{
namespace exponential{
// pow
template <typename genType>
inline genType pow
(
genType const & x,
genType const & y
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return ::std::pow(x, y);
}
template <typename T>
inline detail::tvec2<T> pow
(
detail::tvec2<T> const & x,
detail::tvec2<T> const & y
)
{
return detail::tvec2<T>(
pow(x.x, y.x),
pow(x.y, y.y));
}
template <typename T>
inline detail::tvec3<T> pow
(
detail::tvec3<T> const & x,
detail::tvec3<T> const & y
)
{
return detail::tvec3<T>(
pow(x.x, y.x),
pow(x.y, y.y),
pow(x.z, y.z));
}
template <typename T>
inline detail::tvec4<T> pow
(
detail::tvec4<T> const & x,
detail::tvec4<T> const & y
)
{
return detail::tvec4<T>(
pow(x.x, y.x),
pow(x.y, y.y),
pow(x.z, y.z),
pow(x.w, y.w));
}
// exp
template <typename genType>
inline genType exp
(
genType const & x
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return ::std::exp(x);
}
template <typename T>
inline detail::tvec2<T> exp
(
detail::tvec2<T> const & x
)
{
return detail::tvec2<T>(
exp(x.x),
exp(x.y));
}
template <typename T>
inline detail::tvec3<T> exp
(
detail::tvec3<T> const & x
)
{
return detail::tvec3<T>(
exp(x.x),
exp(x.y),
exp(x.z));
}
template <typename T>
inline detail::tvec4<T> exp
(
detail::tvec4<T> const & x
)
{
return detail::tvec4<T>(
exp(x.x),
exp(x.y),
exp(x.z),
exp(x.w));
}
// log
template <typename genType>
inline genType log
(
genType const & x
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return ::std::log(x);
}
template <typename T>
inline detail::tvec2<T> log
(
detail::tvec2<T> const & x
)
{
return detail::tvec2<T>(
log(x.x),
log(x.y));
}
template <typename T>
inline detail::tvec3<T> log
(
detail::tvec3<T> const & x
)
{
return detail::tvec3<T>(
log(x.x),
log(x.y),
log(x.z));
}
template <typename T>
inline detail::tvec4<T> log
(
detail::tvec4<T> const & x
)
{
return detail::tvec4<T>(
log(x.x),
log(x.y),
log(x.z),
log(x.w));
}
//exp2, ln2 = 0.69314718055994530941723212145818f
template <typename genType>
inline genType exp2
(
genType const & x
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return ::std::exp(genType(0.69314718055994530941723212145818) * x);
}
template <typename T>
inline detail::tvec2<T> exp2
(
detail::tvec2<T> const & x
)
{
return detail::tvec2<T>(
exp2(x.x),
exp2(x.y));
}
template <typename T>
inline detail::tvec3<T> exp2
(
detail::tvec3<T> const & x
)
{
return detail::tvec3<T>(
exp2(x.x),
exp2(x.y),
exp2(x.z));
}
template <typename T>
inline detail::tvec4<T> exp2
(
detail::tvec4<T> const & x
)
{
return detail::tvec4<T>(
exp2(x.x),
exp2(x.y),
exp2(x.z),
exp2(x.w));
}
// log2, ln2 = 0.69314718055994530941723212145818f
template <typename genType>
inline genType log2
(
genType const & x
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return ::std::log(x) / genType(0.69314718055994530941723212145818);
}
template <typename T>
inline detail::tvec2<T> log2
(
detail::tvec2<T> const & x
)
{
return detail::tvec2<T>(
log2(x.x),
log2(x.y));
}
template <typename T>
inline detail::tvec3<T> log2
(
detail::tvec3<T> const & x
)
{
return detail::tvec3<T>(
log2(x.x),
log2(x.y),
log2(x.z));
}
template <typename T>
inline detail::tvec4<T> log2
(
detail::tvec4<T> const & x
)
{
return detail::tvec4<T>(
log2(x.x),
log2(x.y),
log2(x.z),
log2(x.w));
}
// sqrt
template <typename genType>
inline genType sqrt
(
genType const & x
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return genType(::std::sqrt(double(x)));
}
template <typename T>
inline detail::tvec2<T> sqrt
(
detail::tvec2<T> const & x
)
{
return detail::tvec2<T>(
sqrt(x.x),
sqrt(x.y));
}
template <typename T>
inline detail::tvec3<T> sqrt
(
detail::tvec3<T> const & x
)
{
return detail::tvec3<T>(
sqrt(x.x),
sqrt(x.y),
sqrt(x.z));
}
template <typename T>
inline detail::tvec4<T> sqrt
(
detail::tvec4<T> const & x
)
{
return detail::tvec4<T>(
sqrt(x.x),
sqrt(x.y),
sqrt(x.z),
sqrt(x.w));
}
template <typename genType>
inline genType inversesqrt
(
genType const & x
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return genType(1) / ::std::sqrt(x);
}
template <typename T>
inline detail::tvec2<T> inversesqrt
(
detail::tvec2<T> const & x
)
{
return detail::tvec2<T>(
inversesqrt(x.x),
inversesqrt(x.y));
}
template <typename T>
inline detail::tvec3<T> inversesqrt
(
detail::tvec3<T> const & x
)
{
return detail::tvec3<T>(
inversesqrt(x.x),
inversesqrt(x.y),
inversesqrt(x.z));
}
template <typename T>
inline detail::tvec4<T> inversesqrt
(
detail::tvec4<T> const & x
)
{
return detail::tvec4<T>(
inversesqrt(x.x),
inversesqrt(x.y),
inversesqrt(x.z),
inversesqrt(x.w));
}
}//namespace exponential
}//namespace function
}//namespace core
}//namespace glm

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-08-03
// Updated : 2010-02-04
// Licence : This source is under MIT License
// File : glm/core/func_geometric.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef glm_core_func_geometric
#define glm_core_func_geometric
namespace glm
{
namespace test{
void main_core_func_geometric();
}//namespace test
namespace core{
namespace function{
//! Define all geometric functions from Section 8.4 of GLSL 1.30.8 specification. Included in glm namespace.
namespace geometric{
//! Returns the length of x, i.e., sqrt(x * x).
//! (From GLSL 1.30.08 specification, section 8.4)
template <typename genType>
typename genType::value_type length(
genType const & x);
//! Returns the distance betwwen p0 and p1, i.e., length(p0 - p1).
//! (From GLSL 1.30.08 specification, section 8.4)
template <typename genType>
typename genType::value_type distance(
genType const & p0,
genType const & p1);
//! Returns the dot product of x and y, i.e., result = x * y.
//! (From GLSL 1.30.08 specification, section 8.4)
template <typename genType>
typename genType::value_type dot(
genType const & x,
genType const & y);
//! Returns the cross product of x and y.
//! (From GLSL 1.30.08 specification, section 8.4)
template <typename T>
detail::tvec3<T> cross(
detail::tvec3<T> const & x,
detail::tvec3<T> const & y);
//! Returns a vector in the same direction as x but with length of 1.
//! (From GLSL 1.30.08 specification, section 8.4)
template <typename genType>
genType normalize(
genType const & x);
//! If dot(Nref, I) < 0.0, return N, otherwise, return -N.
//! (From GLSL 1.30.08 specification, section 8.4)
template <typename genType>
genType faceforward(
genType const & N,
genType const & I,
genType const & Nref);
//! For the incident vector I and surface orientation N,
//! returns the reflection direction : result = I - 2.0 * dot(N, I) * N.
//! (From GLSL 1.30.08 specification, section 8.4)
template <typename genType>
genType reflect(
genType const & I,
genType const & N);
//! For the incident vector I and surface normal N,
//! and the ratio of indices of refraction eta,
//! return the refraction vector.
//! (From GLSL 1.30.08 specification, section 8.4)
template <typename genType>
genType refract(
genType const & I,
genType const & N,
typename genType::value_type const & eta);
}//namespace geometric
}//namespace function
}//namespace core
using namespace core::function::geometric;
}//namespace glm
#include "func_geometric.inl"
#endif//glm_core_func_geometric

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-08-03
// Updated : 2010-02-04
// Licence : This source is under MIT License
// File : glm/core/func_geometric.inl
///////////////////////////////////////////////////////////////////////////////////////////////////
namespace glm
{
namespace core{
namespace function{
namespace geometric{
// length
template <typename genType>
inline genType length
(
genType const & x
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
genType sqr = x * x;
return sqrt(sqr);
}
template <typename T>
inline typename detail::tvec2<T>::value_type length
(
detail::tvec2<T> const & v
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
typename detail::tvec2<T>::value_type sqr = v.x * v.x + v.y * v.y;
return sqrt(sqr);
}
template <typename T>
inline typename detail::tvec3<T>::value_type length
(
detail::tvec3<T> const & v
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
typename detail::tvec3<T>::value_type sqr = v.x * v.x + v.y * v.y + v.z * v.z;
return sqrt(sqr);
}
template <typename T>
inline typename detail::tvec4<T>::value_type length
(
detail::tvec4<T> const & v
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
typename detail::tvec4<T>::value_type sqr = v.x * v.x + v.y * v.y + v.z * v.z + v.w * v.w;
return sqrt(sqr);
}
// distance
template <typename genType>
inline genType distance
(
genType const & p0,
genType const & p1
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return length(p1 - p0);
}
template <typename T>
inline typename detail::tvec2<T>::value_type distance
(
detail::tvec2<T> const & p0,
detail::tvec2<T> const & p1
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
return length(p1 - p0);
}
template <typename T>
inline typename detail::tvec3<T>::value_type distance
(
detail::tvec3<T> const & p0,
detail::tvec3<T> const & p1
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
return length(p1 - p0);
}
template <typename T>
inline typename detail::tvec4<T>::value_type distance
(
detail::tvec4<T> const & p0,
detail::tvec4<T> const & p1
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
return length(p1 - p0);
}
// dot
template <typename genType>
inline genType dot
(
genType const & x,
genType const & y
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return x * y;
}
template <typename T>
inline typename detail::tvec2<T>::value_type dot
(
detail::tvec2<T> const & x,
detail::tvec2<T> const & y
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
return x.x * y.x + x.y * y.y;
}
template <typename T>
inline T dot
(
detail::tvec3<T> const & x,
detail::tvec3<T> const & y
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
return x.x * y.x + x.y * y.y + x.z * y.z;
}
/* // SSE3
inline float dot(const tvec4<float>& x, const tvec4<float>& y)
{
float Result;
__asm
{
mov esi, x
mov edi, y
movaps xmm0, [esi]
mulps xmm0, [edi]
haddps( _xmm0, _xmm0 )
haddps( _xmm0, _xmm0 )
movss Result, xmm0
}
return Result;
}
*/
template <typename T>
inline T dot
(
detail::tvec4<T> const & x,
detail::tvec4<T> const & y
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
return x.x * y.x + x.y * y.y + x.z * y.z + x.w * y.w;
}
// cross
template <typename T>
inline detail::tvec3<T> cross
(
detail::tvec3<T> const & x,
detail::tvec3<T> const & y
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
return detail::tvec3<T>(
x.y * y.z - y.y * x.z,
x.z * y.x - y.z * x.x,
x.x * y.y - y.x * x.y);
}
// normalize
template <typename genType>
inline genType normalize
(
genType const & x
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return x < genType(0) ? genType(-1) : genType(1);
}
// According to issue 10 GLSL 1.10 specification, if length(x) == 0 then result is undefine and generate an error
template <typename T>
inline detail::tvec2<T> normalize
(
detail::tvec2<T> const & x
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
typename detail::tvec2<T>::value_type sqr = x.x * x.x + x.y * x.y;
return x * inversesqrt(sqr);
}
template <typename T>
inline detail::tvec3<T> normalize
(
detail::tvec3<T> const & x
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
typename detail::tvec3<T>::value_type sqr = x.x * x.x + x.y * x.y + x.z * x.z;
return x * inversesqrt(sqr);
}
template <typename T>
inline detail::tvec4<T> normalize
(
detail::tvec4<T> const & x
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
typename detail::tvec4<T>::value_type sqr = x.x * x.x + x.y * x.y + x.z * x.z + x.w * x.w;
return x * inversesqrt(sqr);
}
// faceforward
template <typename genType>
inline genType faceforward
(
genType const & N,
genType const & I,
genType const & Nref
)
{
return dot(Nref, I) < 0 ? N : -N;
}
// reflect
template <typename genType>
genType reflect
(
genType const & I,
genType const & N
)
{
return I - N * dot(N, I) * float(2);
}
// refract
template <typename genType>
inline genType refract
(
genType const & I,
genType const & N,
typename genType::value_type const & eta
)
{
//It could be a vector
//GLM_STATIC_ASSERT(detail::type<genType>::is_float);
typename genType::value_type dotValue = dot(N, I);
typename genType::value_type k = typename genType::value_type(1) - eta * eta * (typename genType::value_type(1) - dotValue * dotValue);
if(k < typename genType::value_type(0))
return genType(0);
else
return eta * I - (eta * dotValue + sqrt(k)) * N;
}
}//namespace geometric
}//namespace function
}//namespace core
}//namespace glm

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2010-03-17
// Updated : 2010-03-31
// Licence : This source is under MIT License
// File : glm/core/func_integer.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef glm_core_func_integer
#define glm_core_func_integer
namespace glm
{
namespace test{
void main_core_func_integer();
}//namespace test
namespace core{
namespace function{
//! Define integer functions from Section 8.8 of GLSL 4.00.8 specification.
namespace integer{
//! Adds 32-bit unsigned integer x and y, returning the sum
//! modulo pow(2, 32). The value carry is set to 0 if the sum was
//! less than pow(2, 32), or to 1 otherwise.
//!
//! (From GLSL 4.00.08 specification, section 8.8)
template <typename genUType>
genUType uaddCarry(
genUType const & x,
genUType const & y,
genUType & carry);
//! Subtracts the 32-bit unsigned integer y from x, returning
//! the difference if non-negative, or pow(2, 32) plus the difference
//! otherwise. The value borrow is set to 0 if x >= y, or to 1 otherwise.
//!
//! (From GLSL 4.00.08 specification, section 8.8)
template <typename genUType>
genUType usubBorrow(
genUType const & x,
genUType const & y,
genUType & borrow);
//! Multiplies 32-bit integers x and y, producing a 64-bit
//! result. The 32 least-significant bits are returned in lsb.
//! The 32 most-significant bits are returned in msb.
//! (From GLSL 4.00.08 specification, section 8.8)
template <typename genUType>
void umulExtended(
genUType const & x,
genUType const & y,
genUType & msb,
genUType & lsb);
//! Multiplies 32-bit integers x and y, producing a 64-bit
//! result. The 32 least-significant bits are returned in lsb.
//! The 32 most-significant bits are returned in msb.
//! (From GLSL 4.00.08 specification, section 8.8)
template <typename genIType>
void imulExtended(
genIType const & x,
genIType const & y,
genIType & msb,
genIType & lsb);
//! Extracts bits [offset, offset + bits - 1] from value,
//! returning them in the least significant bits of the result.
//! For unsigned data types, the most significant bits of the
//! result will be set to zero. For signed data types, the
//! most significant bits will be set to the value of bit offset + base 1.
//!
//! If bits is zero, the result will be zero. The result will be
//! undefined if offset or bits is negative, or if the sum of
//! offset and bits is greater than the number of bits used
//! to store the operand.
//!
//! (From GLSL 4.00.08 specification, section 8.8)
template <typename genIUType>
genIUType bitfieldExtract(
genIUType const & Value,
int const & Offset,
int const & Bits);
//! Returns the insertion the bits least-significant bits of insert into base.
//!
//! The result will have bits [offset, offset + bits - 1] taken
//! from bits [0, bits 1] of insert, and all other bits taken
//! directly from the corresponding bits of base. If bits is
//! zero, the result will simply be base. The result will be
//! undefined if offset or bits is negative, or if the sum of
//! offset and bits is greater than the number of bits used to
//! store the operand.
//!
//! (From GLSL 4.00.08 specification, section 8.8)
template <typename genIUType>
genIUType bitfieldInsert(
genIUType const & Base,
genIUType const & Insert,
int const & Offset,
int const & Bits);
//! Returns the reversal of the bits of value.
//! The bit numbered n of the result will be taken from bit (bits - 1) - n of value,
//! where bits is the total number of bits used to represent value.
//! (From GLSL 4.00.08 specification, section 8.8)
template <typename genIUType>
genIUType bitfieldReverse(genIUType const & value);
//! Returns the number of bits set to 1 in the binary representation of value.
//! (From GLSL 4.00.08 specification, section 8.8)
template <typename T, template <typename> class C>
typename C<T>::signed_type bitCount(C<T> const & Value);
//! Returns the bit number of the least significant bit set to
//! 1 in the binary representation of value.
//! If value is zero, -1 will be returned.
//! (From GLSL 4.00.08 specification, section 8.8)
template <typename T, template <typename> class C>
typename C<T>::signed_type findLSB(C<T> const & Value);
//! Returns the bit number of the most significant bit in the binary representation of value.
//! For positive integers, the result will be the bit number of the most significant bit set to 1.
//! For negative integers, the result will be the bit number of the most significant
//! bit set to 0. For a value of zero or negative one, -1 will be returned.
//! (From GLSL 4.00.08 specification, section 8.8)
template <typename T, template <typename> class C>
typename C<T>::signed_type findMSB(C<T> const & Value);
}//namespace integer
}//namespace function
}//namespace core
using namespace core::function::integer;
}//namespace glm
#include "func_integer.inl"
#endif//glm_core_func_integer

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2010-03-17
// Updated : 2010-03-31
// Licence : This source is under MIT License
// File : glm/core/func_integer.inl
///////////////////////////////////////////////////////////////////////////////////////////////////
namespace glm
{
namespace detail
{
}//namespace detail
namespace core{
namespace function{
namespace integer
{
// uaddCarry
template <typename genUType>
inline genUType uaddCarry
(
genUType const & x,
genUType const & y,
genUType & Carry
)
{
detail::highp_uint_t Value64 = detail::highp_uint_t(x) + detail::highp_uint_t(y);
genUType Result = genUType(Value64 % (1 << 32));
Carry = (Value64 % (1 << 32)) > 1 : 1 : 0;
return Result;
}
template <typename T>
inline detail::tvec2<T> uaddCarry
(
detail::tvec2<T> const & x,
detail::tvec2<T> const & y,
detail::tvec2<T> & Carry
)
{
return detail::tvec2<T>(
uaddCarry(x[0], y[0], Carry[0]),
uaddCarry(x[1], y[1], Carry[1]));
}
template <typename T>
inline detail::tvec3<T> uaddCarry
(
detail::tvec3<T> const & x,
detail::tvec3<T> const & y,
detail::tvec3<T> & Carry
)
{
return detail::tvec3<T>(
uaddCarry(x[0], y[0], Carry[0]),
uaddCarry(x[1], y[1], Carry[1]),
uaddCarry(x[2], y[2], Carry[2]));
}
template <typename T>
inline detail::tvec4<T> uaddCarry
(
detail::tvec4<T> const & x,
detail::tvec4<T> const & y,
detail::tvec4<T> & Carry
)
{
return detail::tvec4<T>(
uaddCarry(x[0], y[0], Carry[0]),
uaddCarry(x[1], y[1], Carry[1]),
uaddCarry(x[2], y[2], Carry[2]),
uaddCarry(x[3], y[3], Carry[3]));
}
// usubBorrow
template <typename genUType>
inline genUType usubBorrow
(
genUType const & x,
genUType const & y,
genUType & Borrow
)
{
Borrow = x >= y ? 0 : 1;
if(x > y)
return genUType(detail::highp_int_t(x) - detail::highp_int_t(y));
else
return genUType(detail::highp_int_t(1 << 32) + detail::highp_int_t(x) - detail::highp_int_t(y));
}
template <typename T>
inline detail::tvec2<T> usubBorrow
(
detail::tvec2<T> const & x,
detail::tvec2<T> const & y,
detail::tvec2<T> & Borrow
)
{
return detail::tvec2<T>(
usubBorrow(x[0], y[0], Borrow[0]),
usubBorrow(x[1], y[1], Borrow[1]));
}
template <typename T>
inline detail::tvec3<T> usubBorrow
(
detail::tvec3<T> const & x,
detail::tvec3<T> const & y,
detail::tvec3<T> & Borrow
)
{
return detail::tvec3<T>(
usubBorrow(x[0], y[0], Borrow[0]),
usubBorrow(x[1], y[1], Borrow[1]),
usubBorrow(x[2], y[2], Borrow[2]));
}
template <typename T>
inline detail::tvec4<T> usubBorrow
(
detail::tvec4<T> const & x,
detail::tvec4<T> const & y,
detail::tvec4<T> & Borrow
)
{
return detail::tvec4<T>(
usubBorrow(x[0], y[0], Borrow[0]),
usubBorrow(x[1], y[1], Borrow[1]),
usubBorrow(x[2], y[2], Borrow[2]),
usubBorrow(x[3], y[3], Borrow[3]));
}
// umulExtended
template <typename genUType>
inline void umulExtended
(
genUType const & x,
genUType const & y,
genUType & msb,
genUType & lsb
)
{
detail::highp_uint_t ValueX64 = x;
detail::highp_uint_t ValueY64 = y;
detail::highp_uint_t Value64 = ValueX64 * ValueY64;
msb = *(genUType*)&(Value64 & ((1 << 32) - 1));
lsb = *(genUType*)&(Value64 >> 32);
}
template <typename T>
inline detail::tvec2<T> umulExtended
(
detail::tvec2<T> const & x,
detail::tvec2<T> const & y,
detail::tvec2<T> & msb,
detail::tvec2<T> & lsb
)
{
return detail::tvec2<T>(
umulExtended(x[0], y[0], msb, lsb),
umulExtended(x[1], y[1], msb, lsb));
}
template <typename T>
inline detail::tvec3<T> umulExtended
(
detail::tvec3<T> const & x,
detail::tvec3<T> const & y,
detail::tvec3<T> & msb,
detail::tvec3<T> & lsb
)
{
return detail::tvec3<T>(
umulExtended(x[0], y[0], msb, lsb),
umulExtended(x[1], y[1], msb, lsb),
umulExtended(x[2], y[2], msb, lsb));
}
template <typename T>
inline detail::tvec4<T> umulExtended
(
detail::tvec4<T> const & x,
detail::tvec4<T> const & y,
detail::tvec4<T> & msb,
detail::tvec4<T> & lsb
)
{
return detail::tvec4<T>(
umulExtended(x[0], y[0], msb, lsb),
umulExtended(x[1], y[1], msb, lsb),
umulExtended(x[2], y[2], msb, lsb),
umulExtended(x[3], y[3], msb, lsb));
}
// imulExtended
template <typename genIType>
void imulExtended
(
genIType const & x,
genIType const & y,
genIType & msb,
genIType & lsb
)
{
detail::highp_int_t ValueX64 = x;
detail::highp_int_t ValueY64 = y;
detail::highp_int_t Value64 = ValueX64 * ValueY64;
msb = *(genIType*)&(Value64 & ((1 << 32) - 1));
lsb = *(genIType*)&(Value64 >> 32);
}
template <typename T>
inline detail::tvec2<T> imulExtended
(
detail::tvec2<T> const & x,
detail::tvec2<T> const & y,
detail::tvec2<T> & msb,
detail::tvec2<T> & lsb
)
{
return detail::tvec2<T>(
imulExtended(x[0], y[0], msb, lsb),
imulExtended(x[1], y[1], msb, lsb));
}
template <typename T>
inline detail::tvec3<T> imulExtended
(
detail::tvec3<T> const & x,
detail::tvec3<T> const & y,
detail::tvec3<T> & msb,
detail::tvec3<T> & lsb
)
{
return detail::tvec3<T>(
imulExtended(x[0], y[0], msb, lsb),
imulExtended(x[1], y[1], msb, lsb),
imulExtended(x[2], y[2], msb, lsb));
}
template <typename T>
inline detail::tvec4<T> imulExtended
(
detail::tvec4<T> const & x,
detail::tvec4<T> const & y,
detail::tvec4<T> & msb,
detail::tvec4<T> & lsb
)
{
return detail::tvec4<T>(
imulExtended(x[0], y[0], msb, lsb),
imulExtended(x[1], y[1], msb, lsb),
imulExtended(x[2], y[2], msb, lsb),
imulExtended(x[3], y[3], msb, lsb));
}
// bitfieldExtract
template <typename genIUType>
genIUType bitfieldExtract
(
genIUType const & Value,
int const & Offset,
int const & Bits
)
{
GLM_STATIC_ASSERT(std::numeric_limits<genIUType>::is_integer);
GLM_STATIC_ASSERT(Offset + Bits <= sizeof(genIUType));
genIUType Result = 0;
if(std::numeric_limits<genIUType>::is_signed)
Result |= (1 << (sizeof(genIUType) * 8 - 1)) & (1 << (Offset + Bits - 1));
genIUType Mask = 0;
for(std::size_t Bit = Offset; Bit < Bits; ++Bit)
Mask |= (1 << Bit);
return Result | ((Mask & Value) >> Offset);
}
template <typename T>
inline detail::tvec2<T> bitfieldExtract
(
detail::tvec2<T> const & Value,
int const & Offset,
int const & Bits
)
{
return detail::tvec2<T>(
bitfieldExtract(value[0]),
bitfieldExtract(value[1]));
}
template <typename T>
inline detail::tvec3<T> bitfieldExtract
(
detail::tvec3<T> const & Value,
int const & Offset,
int const & Bits
)
{
return detail::tvec3<T>(
bitfieldExtract(value[0]),
bitfieldExtract(value[1]),
bitfieldExtract(value[2]));
}
template <typename T>
inline detail::tvec4<T> bitfieldExtract
(
detail::tvec4<T> const & Value,
int const & Offset,
int const & Bits
)
{
return detail::tvec4<T>(
bitfieldExtract(value[0]),
bitfieldExtract(value[1]),
bitfieldExtract(value[2]),
bitfieldExtract(value[3]));
}
// bitfieldInsert
template <typename genIUType>
inline genIUType bitfieldInsert
(
genIUType const & Base,
genIUType const & Insert,
int const & Offset,
int const & Bits
)
{
GLM_STATIC_ASSERT(std::numeric_limits<genIUType>::is_integer);
GLM_STATIC_ASSERT(Offset + Bits <= sizeof(genIUType));
if(Bits == 0)
return Base;
genIUType Mask = 0;
for(std::size_t Bit = Offset; Bit < Offset + Bits; ++Bit)
Mask |= (1 << Bit);
return (Base & ~Mask) | (Insert & Mask);
}
template <typename T>
inline detail::tvec2<T> bitfieldInsert
(
detail::tvec2<T> const & Base,
detail::tvec2<T> const & Insert,
int const & Offset,
int const & Bits
)
{
return detail::tvec2<T>(
bitfieldInsert(value[0]),
bitfieldInsert(value[1]));
}
template <typename T>
inline detail::tvec3<T> bitfieldInsert
(
detail::tvec3<T> const & Base,
detail::tvec3<T> const & Insert,
int const & Offset,
int const & Bits
)
{
return detail::tvec3<T>(
bitfieldInsert(value[0]),
bitfieldInsert(value[1]),
bitfieldInsert(value[2]));
}
template <typename T>
inline detail::tvec4<T> bitfieldInsert
(
detail::tvec4<T> const & Base,
detail::tvec4<T> const & Insert,
int const & Offset,
int const & Bits
)
{
return detail::tvec4<T>(
bitfieldInsert(value[0]),
bitfieldInsert(value[1]),
bitfieldInsert(value[2]),
bitfieldInsert(value[3]));
}
// bitfieldReverse
template <typename genIUType>
inline genIUType bitfieldReverse(genIUType const & Value)
{
GLM_STATIC_ASSERT(std::numeric_limits<genIUType>::is_integer);
genIUType Result = 0;
for(std::size_t i = 0; i < sizeof(genIUType) * std::size_t(8); ++i)
if(Value & (1 << i))
Result |= (1 << (sizeof(genIUType) * std::size_t(8)) - 1 - i);
return Result;
}
template <typename T>
inline detail::tvec2<T> bitfieldReverse
(
detail::tvec2<T> const & value
)
{
return detail::tvec2<T>(
bitfieldReverse(value[0]),
bitfieldReverse(value[1]));
}
template <typename T>
inline detail::tvec3<T> bitfieldReverse
(
detail::tvec3<T> const & value
)
{
return detail::tvec3<T>(
bitfieldReverse(value[0]),
bitfieldReverse(value[1]),
bitfieldReverse(value[2]));
}
template <typename T>
inline detail::tvec4<T> bitfieldReverse
(
detail::tvec4<T> const & value
)
{
return detail::tvec4<T>(
bitfieldReverse(value[0]),
bitfieldReverse(value[1]),
bitfieldReverse(value[2]),
bitfieldReverse(value[3]));
}
// bitCount
template <typename genIUType>
int bitCount(genIUType const & Value)
{
GLM_STATIC_ASSERT(std::numeric_limits<genIUType>::is_integer);
int Count = 0;
for(std::size_t i = 0; i < sizeof(genIUType) * std::size_t(8); ++i)
{
if(Value & (1 << i))
++Count;
}
return Count;
}
template <typename T>
inline detail::tvec2<int> bitCount
(
detail::tvec2<T> const & value
)
{
return detail::tvec2<int>(
bitCount(value[0]),
bitCount(value[1]));
}
template <typename T>
inline detail::tvec3<int> bitCount
(
detail::tvec3<T> const & value
)
{
return detail::tvec3<int>(
bitCount(value[0]),
bitCount(value[1]),
bitCount(value[2]));
}
template <typename T>
inline detail::tvec4<int> bitCount
(
detail::tvec4<T> const & value
)
{
return detail::tvec4<int>(
bitCount(value[0]),
bitCount(value[1]),
bitCount(value[2]),
bitCount(value[3]));
}
// findLSB
template <typename genType>
inline int findLSB
(
genType const & Value
)
{
GLM_STATIC_ASSERT(std::numeric_limits<genIUType>::is_integer);
if(Value == 0)
return -1;
genType Bit;
for(Bit = genType(0); !(Value & (1 << Bit)); ++Bit){}
return Bit;
}
template <typename T>
inline detail::tvec2<int> findLSB
(
detail::tvec2<T> const & value
)
{
return detail::tvec2<int>(
findLSB(value[0]),
findLSB(value[1]));
}
template <typename T>
inline detail::tvec3<int> findLSB
(
detail::tvec3<T> const & value
)
{
return detail::tvec3<int>(
findLSB(value[0]),
findLSB(value[1]),
findLSB(value[2]));
}
template <typename T>
inline detail::tvec4<int> findLSB
(
detail::tvec4<T> const & value
)
{
return detail::tvec4<int>(
findLSB(value[0]),
findLSB(value[1]),
findLSB(value[2]),
findLSB(value[3]));
}
// findMSB
template <typename genType>
inline int findMSB
(
genType const & value
)
{
GLM_STATIC_ASSERT(std::numeric_limits<genIUType>::is_integer);
if(Value == 0)
return -1;
genType bit = genType(-1);
for(genType tmp = value; tmp; tmp >>= 1, ++bit){}
return bit;
}
template <typename T>
inline detail::tvec2<int> findMSB
(
detail::tvec2<T> const & value
)
{
return detail::tvec2<int>(
findMSB(value[0]),
findMSB(value[1]));
}
template <typename T>
inline detail::tvec3<int> findMSB
(
detail::tvec3<T> const & value
)
{
return detail::tvec3<int>(
findMSB(value[0]),
findMSB(value[1]),
findMSB(value[2]));
}
template <typename T>
inline detail::tvec4<int> findMSB
(
detail::tvec4<T> const & value
)
{
return detail::tvec4<int>(
findMSB(value[0]),
findMSB(value[1]),
findMSB(value[2]),
findMSB(value[3]));
}
}//namespace integer
}//namespace function
}//namespace core
}//namespace glm

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-08-03
// Updated : 2010-02-04
// Licence : This source is under MIT License
// File : glm/core/func_matrix.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef glm_core_func_matrix
#define glm_core_func_matrix
namespace glm
{
namespace test{
void main_core_func_matrix();
}//namespace test
namespace core{
namespace function{
//! Define all matrix functions from Section 8.5 of GLSL 1.30.8 specification. Included in glm namespace.
namespace matrix{
//! Multiply matrix x by matrix y component-wise, i.e.,
//! result[i][j] is the scalar product of x[i][j] and y[i][j].
//! (From GLSL 1.30.08 specification, section 8.5)
template <typename matType>
matType matrixCompMult(
matType const & x,
matType const & y);
//! Treats the first parameter c as a column vector
//! and the second parameter r as a row vector
//! and does a linear algebraic matrix multiply c * r.
//! (From GLSL 1.30.08 specification, section 8.5)
template <typename vecType, typename matType>
matType outerProduct(
vecType const & c,
vecType const & r);
//! Returns the transposed matrix of x
//! (From GLSL 1.30.08 specification, section 8.5)
template <typename matType>
typename matType::transpose_type transpose(
matType const & x);
//! Return the determinant of a mat2 matrix.
//! (From GLSL 1.50.09 specification, section 8.5)..
template <typename T>
typename detail::tmat2x2<T>::value_type determinant(
detail::tmat2x2<T> const & m);
//! Return the determinant of a mat3 matrix.
//! (From GLSL 1.50.09 specification, section 8.5).
template <typename T>
typename detail::tmat3x3<T>::value_type determinant(
detail::tmat3x3<T> const & m);
//! Return the determinant of a mat4 matrix.
//! (From GLSL 1.50.09 specification, section 8.5).
template <typename T>
typename detail::tmat4x4<T>::value_type determinant(
detail::tmat4x4<T> const & m);
//! Return the inverse of a mat2 matrix.
//! (From GLSL 1.40.07 specification, section 8.5).
template <typename T>
detail::tmat2x2<T> inverse(
detail::tmat2x2<T> const & m);
//! Return the inverse of a mat3 matrix.
//! (From GLSL 1.40.07 specification, section 8.5).
template <typename T>
detail::tmat3x3<T> inverse(
detail::tmat3x3<T> const & m);
//! Return the inverse of a mat4 matrix.
//! (From GLSL 1.40.07 specification, section 8.5).
template <typename T>
detail::tmat4x4<T> inverse(
detail::tmat4x4<T> const & m);
}//namespace matrix
}//namespace function
}//namespace core
using namespace core::function::matrix;
}//namespace glm
#include "func_matrix.inl"
#endif//glm_core_func_matrix

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-03-08
// Updated : 2010-02-04
// Licence : This source is under MIT License
// File : glm/core/func_matrix.inl
///////////////////////////////////////////////////////////////////////////////////////////////////
namespace glm
{
namespace core{
namespace function{
namespace matrix{
// matrixCompMult
template <typename matType>
inline matType matrixCompMult
(
matType const & x,
matType const & y
)
{
GLM_STATIC_ASSERT(detail::type<typename matType::value_type>::is_float);
matType result(matType::null);
for(typename matType::size_type i = 0; i < matType::col_size(); ++i)
result[i] = x[i] * y[i];
return result;
}
// outerProduct
template <typename T>
inline detail::tmat2x2<T> outerProduct
(
detail::tvec2<T> const & c,
detail::tvec2<T> const & r
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
detail::tmat2x2<T> m(detail::tmat2x2<T>::null);
m[0][0] = c[0] * r[0];
m[0][1] = c[1] * r[0];
m[1][0] = c[0] * r[1];
m[1][1] = c[1] * r[1];
return m;
}
template <typename T>
inline detail::tmat3x3<T> outerProduct
(
detail::tvec3<T> const & c,
detail::tvec3<T> const & r
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
detail::tmat3x3<T> m(detail::tmat3x3<T>::null);
for(typename detail::tmat3x3<T>::size_type i = 0; i < detail::tmat3x3<T>::col_size(); ++i)
m[i] = c * r[i];
return m;
}
template <typename T>
inline detail::tmat4x4<T> outerProduct
(
detail::tvec4<T> const & c,
detail::tvec4<T> const & r
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
detail::tmat4x4<T> m(detail::tmat4x4<T>::null);
for(typename detail::tmat4x4<T>::size_type i = 0; i < detail::tmat4x4<T>::col_size(); ++i)
m[i] = c * r[i];
return m;
}
template <typename T>
inline detail::tmat2x3<T> outerProduct
(
detail::tvec3<T> const & c,
detail::tvec2<T> const & r
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
detail::tmat2x3<T> m(detail::tmat2x3<T>::null);
m[0][0] = c.x * r.x;
m[0][1] = c.y * r.x;
m[0][2] = c.z * r.x;
m[1][0] = c.x * r.y;
m[1][1] = c.y * r.y;
m[1][2] = c.z * r.y;
return m;
}
template <typename T>
inline detail::tmat3x2<T> outerProduct
(
detail::tvec2<T> const & c,
detail::tvec3<T> const & r
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
detail::tmat3x2<T> m(detail::tmat3x2<T>::null);
m[0][0] = c.x * r.x;
m[0][1] = c.y * r.x;
m[1][0] = c.x * r.y;
m[1][1] = c.y * r.y;
m[2][0] = c.x * r.z;
m[2][1] = c.y * r.z;
return m;
}
template <typename T>
inline detail::tmat2x4<T> outerProduct
(
detail::tvec2<T> const & c,
detail::tvec4<T> const & r
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
detail::tmat2x4<T> m(detail::tmat2x4<T>::null);
m[0][0] = c.x * r.x;
m[0][1] = c.y * r.x;
m[0][2] = c.z * r.x;
m[0][3] = c.w * r.x;
m[1][0] = c.x * r.y;
m[1][1] = c.y * r.y;
m[1][2] = c.z * r.y;
m[1][3] = c.w * r.y;
return m;
}
template <typename T>
inline detail::tmat4x2<T> outerProduct
(
detail::tvec4<T> const & c,
detail::tvec2<T> const & r
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
detail::tmat4x2<T> m(detail::tmat4x2<T>::null);
m[0][0] = c.x * r.x;
m[0][1] = c.y * r.x;
m[1][0] = c.x * r.y;
m[1][1] = c.y * r.y;
m[2][0] = c.x * r.z;
m[2][1] = c.y * r.z;
m[3][0] = c.x * r.w;
m[3][1] = c.y * r.w;
return m;
}
template <typename T>
inline detail::tmat3x4<T> outerProduct
(
detail::tvec4<T> const & c,
detail::tvec3<T> const & r
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
detail::tmat3x4<T> m(detail::tmat3x4<T>::null);
m[0][0] = c.x * r.x;
m[0][1] = c.y * r.x;
m[0][2] = c.z * r.x;
m[0][3] = c.w * r.x;
m[1][0] = c.x * r.y;
m[1][1] = c.y * r.y;
m[1][2] = c.z * r.y;
m[1][3] = c.w * r.y;
m[2][0] = c.x * r.z;
m[2][1] = c.y * r.z;
m[2][2] = c.z * r.z;
m[2][3] = c.w * r.z;
return m;
}
template <typename T>
inline detail::tmat4x3<T> outerProduct
(
detail::tvec3<T> const & c,
detail::tvec4<T> const & r
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
detail::tmat4x3<T> m(detail::tmat4x3<T>::null);
m[0][0] = c.x * r.x;
m[0][1] = c.y * r.x;
m[0][2] = c.z * r.x;
m[1][0] = c.x * r.y;
m[1][1] = c.y * r.y;
m[1][2] = c.z * r.y;
m[2][0] = c.x * r.z;
m[2][1] = c.y * r.z;
m[2][2] = c.z * r.z;
m[3][0] = c.x * r.w;
m[3][1] = c.y * r.w;
m[3][2] = c.z * r.w;
return m;
}
template <typename T>
inline detail::tmat2x2<T> transpose
(
detail::tmat2x2<T> const & m
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
detail::tmat2x2<T> result(detail::tmat2x2<T>::null);
result[0][0] = m[0][0];
result[0][1] = m[1][0];
result[1][0] = m[0][1];
result[1][1] = m[1][1];
return result;
}
template <typename T>
inline detail::tmat3x3<T> transpose
(
detail::tmat3x3<T> const & m
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
detail::tmat3x3<T> result(detail::tmat3x3<T>::null);
result[0][0] = m[0][0];
result[0][1] = m[1][0];
result[0][2] = m[2][0];
result[1][0] = m[0][1];
result[1][1] = m[1][1];
result[1][2] = m[2][1];
result[2][0] = m[0][2];
result[2][1] = m[1][2];
result[2][2] = m[2][2];
return result;
}
template <typename T>
inline detail::tmat4x4<T> transpose
(
detail::tmat4x4<T> const & m
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
detail::tmat4x4<T> result(detail::tmat4x4<T>::null);
result[0][0] = m[0][0];
result[0][1] = m[1][0];
result[0][2] = m[2][0];
result[0][3] = m[3][0];
result[1][0] = m[0][1];
result[1][1] = m[1][1];
result[1][2] = m[2][1];
result[1][3] = m[3][1];
result[2][0] = m[0][2];
result[2][1] = m[1][2];
result[2][2] = m[2][2];
result[2][3] = m[3][2];
result[3][0] = m[0][3];
result[3][1] = m[1][3];
result[3][2] = m[2][3];
result[3][3] = m[3][3];
return result;
}
template <typename T>
inline detail::tmat2x3<T> transpose
(
detail::tmat3x2<T> const & m
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
detail::tmat2x3<T> result(detail::tmat2x3<T>::null);
result[0][0] = m[0][0];
result[0][1] = m[1][0];
result[0][2] = m[2][0];
result[1][0] = m[0][1];
result[1][1] = m[1][1];
result[1][2] = m[2][1];
return result;
}
template <typename T>
inline detail::tmat3x2<T> transpose
(
detail::tmat2x3<T> const & m
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
detail::tmat3x2<T> result(detail::tmat3x2<T>::null);
result[0][0] = m[0][0];
result[0][1] = m[1][0];
result[1][0] = m[0][1];
result[1][1] = m[1][1];
result[2][0] = m[0][2];
result[2][1] = m[1][2];
return result;
}
template <typename T>
inline detail::tmat2x4<T> transpose
(
detail::tmat4x2<T> const & m
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
detail::tmat2x4<T> result(detail::tmat2x4<T>::null);
result[0][0] = m[0][0];
result[0][1] = m[1][0];
result[0][2] = m[2][0];
result[0][3] = m[3][0];
result[1][0] = m[0][1];
result[1][1] = m[1][1];
result[1][2] = m[2][1];
result[1][3] = m[3][1];
return result;
}
template <typename T>
inline detail::tmat4x2<T> transpose
(
detail::tmat2x4<T> const & m
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
detail::tmat4x2<T> result(detail::tmat4x2<T>::null);
result[0][0] = m[0][0];
result[0][1] = m[1][0];
result[1][0] = m[0][1];
result[1][1] = m[1][1];
result[2][0] = m[0][2];
result[2][1] = m[1][2];
result[3][0] = m[0][3];
result[3][1] = m[1][3];
return result;
}
template <typename T>
inline detail::tmat3x4<T> transpose
(
detail::tmat4x3<T> const & m
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
detail::tmat3x4<T> result(detail::tmat3x4<T>::null);
result[0][0] = m[0][0];
result[0][1] = m[1][0];
result[0][2] = m[2][0];
result[0][3] = m[3][0];
result[1][0] = m[0][1];
result[1][1] = m[1][1];
result[1][2] = m[2][1];
result[1][3] = m[3][1];
result[2][0] = m[0][2];
result[2][1] = m[1][2];
result[2][2] = m[2][2];
result[2][3] = m[3][2];
return result;
}
template <typename T>
inline detail::tmat4x3<T> transpose
(
detail::tmat3x4<T> const & m
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
detail::tmat4x3<T> result(detail::tmat4x3<T>::null);
result[0][0] = m[0][0];
result[0][1] = m[1][0];
result[0][2] = m[2][0];
result[1][0] = m[0][1];
result[1][1] = m[1][1];
result[1][2] = m[2][1];
result[2][0] = m[0][2];
result[2][1] = m[1][2];
result[2][2] = m[2][2];
result[3][0] = m[0][3];
result[3][1] = m[1][3];
result[3][2] = m[2][3];
return result;
}
template <typename T>
inline typename detail::tmat2x2<T>::value_type determinant
(
detail::tmat2x2<T> const & m
)
{
return m[0][0] * m[1][1] - m[1][0] * m[0][1];
}
template <typename T>
inline typename detail::tmat3x3<T>::value_type determinant
(
detail::tmat3x3<T> const & m
)
{
return
+ m[0][0] * (m[1][1] * m[2][2] - m[2][1] * m[1][2])
- m[1][0] * (m[0][1] * m[2][2] - m[2][1] * m[0][2])
+ m[2][0] * (m[0][1] * m[1][2] - m[1][1] * m[0][2]);
}
template <typename T>
inline typename detail::tmat4x4<T>::value_type determinant
(
detail::tmat4x4<T> const & m
)
{
T SubFactor00 = m[2][2] * m[3][3] - m[3][2] * m[2][3];
T SubFactor01 = m[2][1] * m[3][3] - m[3][1] * m[2][3];
T SubFactor02 = m[2][1] * m[3][2] - m[3][1] * m[2][2];
T SubFactor03 = m[2][0] * m[3][3] - m[3][0] * m[2][3];
T SubFactor04 = m[2][0] * m[3][2] - m[3][0] * m[2][2];
T SubFactor05 = m[2][0] * m[3][1] - m[3][0] * m[2][1];
detail::tvec4<T> DetCof(
+ (m[1][1] * SubFactor00 - m[1][2] * SubFactor01 + m[1][3] * SubFactor02),
- (m[1][0] * SubFactor00 - m[1][2] * SubFactor03 + m[1][3] * SubFactor04),
+ (m[1][0] * SubFactor01 - m[1][1] * SubFactor03 + m[1][3] * SubFactor05),
- (m[1][0] * SubFactor02 - m[1][1] * SubFactor04 + m[1][2] * SubFactor05));
return m[0][0] * DetCof[0]
+ m[0][1] * DetCof[1]
+ m[0][2] * DetCof[2]
+ m[0][3] * DetCof[3];
}
template <typename T>
inline detail::tmat2x2<T> inverse
(
detail::tmat2x2<T> const & m
)
{
//valType Determinant = m[0][0] * m[1][1] - m[1][0] * m[0][1];
T Determinant = determinant(m);
detail::tmat2x2<T> Inverse(
+ m[1][1] / Determinant,
- m[1][0] / Determinant,
- m[0][1] / Determinant,
+ m[0][0] / Determinant);
return Inverse;
}
template <typename T>
inline detail::tmat3x3<T> inverse
(
detail::tmat3x3<T> const & m
)
{
//valType Determinant = m[0][0] * (m[1][1] * m[2][2] - m[2][1] * m[1][2])
// - m[1][0] * (m[0][1] * m[2][2] - m[2][1] * m[0][2])
// + m[2][0] * (m[0][1] * m[1][2] - m[1][1] * m[0][2]);
T Determinant = determinant(m);
detail::tmat3x3<T> Inverse(detail::tmat3x3<T>::null);
Inverse[0][0] = + (m[1][1] * m[2][2] - m[2][1] * m[1][2]);
Inverse[1][0] = - (m[1][0] * m[2][2] - m[2][0] * m[1][2]);
Inverse[2][0] = + (m[1][0] * m[2][1] - m[2][0] * m[1][1]);
Inverse[0][1] = - (m[0][1] * m[2][2] - m[2][1] * m[0][2]);
Inverse[1][1] = + (m[0][0] * m[2][2] - m[2][0] * m[0][2]);
Inverse[2][1] = - (m[0][0] * m[2][1] - m[2][0] * m[0][1]);
Inverse[0][2] = + (m[0][1] * m[1][2] - m[1][1] * m[0][2]);
Inverse[1][2] = - (m[0][0] * m[1][2] - m[1][0] * m[0][2]);
Inverse[2][2] = + (m[0][0] * m[1][1] - m[1][0] * m[0][1]);
Inverse /= Determinant;
return Inverse;
}
template <typename T>
inline detail::tmat4x4<T> inverse
(
detail::tmat4x4<T> const & m
)
{
T Coef00 = m[2][2] * m[3][3] - m[3][2] * m[2][3];
T Coef02 = m[1][2] * m[3][3] - m[3][2] * m[1][3];
T Coef03 = m[1][2] * m[2][3] - m[2][2] * m[1][3];
T Coef04 = m[2][1] * m[3][3] - m[3][1] * m[2][3];
T Coef06 = m[1][1] * m[3][3] - m[3][1] * m[1][3];
T Coef07 = m[1][1] * m[2][3] - m[2][1] * m[1][3];
T Coef08 = m[2][1] * m[3][2] - m[3][1] * m[2][2];
T Coef10 = m[1][1] * m[3][2] - m[3][1] * m[1][2];
T Coef11 = m[1][1] * m[2][2] - m[2][1] * m[1][2];
T Coef12 = m[2][0] * m[3][3] - m[3][0] * m[2][3];
T Coef14 = m[1][0] * m[3][3] - m[3][0] * m[1][3];
T Coef15 = m[1][0] * m[2][3] - m[2][0] * m[1][3];
T Coef16 = m[2][0] * m[3][2] - m[3][0] * m[2][2];
T Coef18 = m[1][0] * m[3][2] - m[3][0] * m[1][2];
T Coef19 = m[1][0] * m[2][2] - m[2][0] * m[1][2];
T Coef20 = m[2][0] * m[3][1] - m[3][0] * m[2][1];
T Coef22 = m[1][0] * m[3][1] - m[3][0] * m[1][1];
T Coef23 = m[1][0] * m[2][1] - m[2][0] * m[1][1];
detail::tvec4<T> const SignA(+1, -1, +1, -1);
detail::tvec4<T> const SignB(-1, +1, -1, +1);
detail::tvec4<T> Fac0(Coef00, Coef00, Coef02, Coef03);
detail::tvec4<T> Fac1(Coef04, Coef04, Coef06, Coef07);
detail::tvec4<T> Fac2(Coef08, Coef08, Coef10, Coef11);
detail::tvec4<T> Fac3(Coef12, Coef12, Coef14, Coef15);
detail::tvec4<T> Fac4(Coef16, Coef16, Coef18, Coef19);
detail::tvec4<T> Fac5(Coef20, Coef20, Coef22, Coef23);
detail::tvec4<T> Vec0(m[1][0], m[0][0], m[0][0], m[0][0]);
detail::tvec4<T> Vec1(m[1][1], m[0][1], m[0][1], m[0][1]);
detail::tvec4<T> Vec2(m[1][2], m[0][2], m[0][2], m[0][2]);
detail::tvec4<T> Vec3(m[1][3], m[0][3], m[0][3], m[0][3]);
detail::tvec4<T> Inv0 = SignA * (Vec1 * Fac0 - Vec2 * Fac1 + Vec3 * Fac2);
detail::tvec4<T> Inv1 = SignB * (Vec0 * Fac0 - Vec2 * Fac3 + Vec3 * Fac4);
detail::tvec4<T> Inv2 = SignA * (Vec0 * Fac1 - Vec1 * Fac3 + Vec3 * Fac5);
detail::tvec4<T> Inv3 = SignB * (Vec0 * Fac2 - Vec1 * Fac4 + Vec2 * Fac5);
detail::tmat4x4<T> Inverse(Inv0, Inv1, Inv2, Inv3);
detail::tvec4<T> Row0(Inverse[0][0], Inverse[1][0], Inverse[2][0], Inverse[3][0]);
T Determinant = glm::dot(m[0], Row0);
Inverse /= Determinant;
return Inverse;
}
}//namespace matrix
}//namespace function
}//namespace core
}//namespace glm

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-08-01
// Updated : 2008-09-10
// Licence : This source is under MIT License
// File : glm/core/func_noise.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef glm_core_func_noise
#define glm_core_func_noise
namespace glm
{
namespace test{
void main_core_func_noise();
}//namespace test
namespace core{
namespace function{
// Define all noise functions from Section 8.9 of GLSL 1.30.8 specification. Included in glm namespace.
namespace noise{
// Returns a 1D noise value based on the input value x.
// From GLSL 1.30.08 specification, section 8.9.
template <typename genType>
typename genType::value_type noise1(genType const & x);
// Returns a 2D noise value based on the input value x.
// From GLSL 1.30.08 specification, section 8.9.
template <typename genType>
detail::tvec2<typename genType::value_type> noise2(genType const & x);
// Returns a 3D noise value based on the input value x.
// From GLSL 1.30.08 specification, section 8.9.
template <typename genType>
detail::tvec3<typename genType::value_type> noise3(genType const & x);
// Returns a 4D noise value based on the input value x.
// From GLSL 1.30.08 specification, section 8.9.
template <typename genType>
detail::tvec4<typename genType::value_type> noise4(genType const & x);
}//namespace noise
}//namespace function
}//namespace core
using namespace core::function::noise;
}//namespace glm
#include "func_noise.inl"
#endif//glm_core_func_noise

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-08-01
// Updated : 2008-09-23
// Licence : This source is under MIT License
// File : glm/core/func_noise.inl
///////////////////////////////////////////////////////////////////////////////////////////////////
namespace glm
{
namespace core{
namespace function{
namespace noise{
// noise1
template <typename genType>
inline genType noise1
(
genType const & x
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
int iNbr = int(x + genType(3) / genType(2)) * 1103515245 + 12345;
return genType(int(iNbr / genType(65536)) % 32768) / genType(32767);
}
template <typename T>
inline typename detail::tvec2<T>::value_type noise1
(
detail::tvec2<T> const & x
)
{
T tmp(0);
for(typename detail::tvec2<T>::size_type i = 0; i < detail::tvec2<T>::value_size(); ++i)
tmp += x[i];
return noise1(tmp);
}
template <typename T>
inline typename detail::tvec3<T>::value_type noise1
(
detail::tvec3<T> const & x
)
{
T tmp(0);
for(typename detail::tvec3<T>::size_type i = 0; i < detail::tvec3<T>::value_size(); ++i)
tmp += x[i];
return noise1(tmp);
}
template <typename T>
inline typename detail::tvec4<T>::value_type noise1
(
detail::tvec4<T> const & x
)
{
T tmp(0);
for(typename detail::tvec4<T>::size_type i = 0; i < detail::tvec4<T>::value_size(); ++i)
tmp += x[i];
return noise1(tmp);
}
// noise2
template <typename genType>
inline detail::tvec2<genType> noise2
(
genType const & x
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
genType f1 = x * genType(1103515245) + genType(12345);
genType f2 = f1 * genType(1103515245) + genType(12345);
return detail::tvec2<genType>(
noise1(f1),
noise1(f2));
}
template <typename T>
inline detail::tvec2<T> noise2
(
detail::tvec2<T> const & x
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
T f0(0);
for(typename detail::tvec2<T>::size_type i = 0; i < detail::tvec2<T>::value_size(); ++i)
f0 += x[i];
T f1 = f0 * T(1103515245) + T(12345);
T f2 = f1 * T(1103515245) + T(12345);
return detail::tvec2<T>(
noise1(f1),
noise1(f2));
}
template <typename T>
inline detail::tvec2<T> noise2
(
detail::tvec3<T> const & x
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
T f0(0);
for(typename detail::tvec3<T>::size_type i = 0; i < detail::tvec3<T>::value_size(); ++i)
f0 += x[i];
T f1 = f0 * T(1103515245) + T(12345);
T f2 = f1 * T(1103515245) + T(12345);
return detail::tvec2<T>(
noise1(f1),
noise1(f2));
}
template <typename T>
inline detail::tvec2<T> noise2
(
detail::tvec4<T> const & x
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
T f0(0);
for(typename detail::tvec4<T>::size_type i = 0; i < detail::tvec4<T>::value_size(); ++i)
f0 += x[i];
T f1 = f0 * T(1103515245) + T(12345);
T f2 = f1 * T(1103515245) + T(12345);
return detail::tvec2<T>(
noise1(f1),
noise1(f2));
}
// noise3
template <typename genType>
inline detail::tvec3<genType> noise3
(
genType const & x
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
genType f1 = x * genType(1103515245) + genType(12345);
genType f2 = f1 * genType(1103515245) + genType(12345);
genType f3 = f2 * genType(1103515245) + genType(12345);
return detail::tvec3<genType>(
noise1(f1),
noise1(f2),
noise1(f3));
}
template <typename T>
inline detail::tvec3<T> noise3
(
detail::tvec2<T> const & x
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
T f0(0);
for(typename detail::tvec2<T>::size_type i = 0; i < detail::tvec2<T>::value_size(); ++i)
f0 += x[i];
T f1 = f0 * T(1103515245) + T(12345);
T f2 = f1 * T(1103515245) + T(12345);
T f3 = f2 * T(1103515245) + T(12345);
return detail::tvec3<T>(
noise1(f1),
noise1(f2),
noise1(f3));
}
template <typename T>
inline detail::tvec3<T> noise3
(
detail::tvec3<T> const & x
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
T f0(0);
for(typename detail::tvec3<T>::size_type i = 0; i < detail::tvec3<T>::value_size(); ++i)
f0 += x[i];
T f1 = f0 * T(1103515245) + T(12345);
T f2 = f1 * T(1103515245) + T(12345);
T f3 = f2 * T(1103515245) + T(12345);
return detail::tvec3<T>(
noise1(f1),
noise1(f2),
noise1(f3));
}
template <typename T>
inline detail::tvec3<T> noise3
(
detail::tvec4<T> const & x
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
T f0(0);
for(typename detail::tvec4<T>::size_type i = 0; i < detail::tvec4<T>::value_size(); ++i)
f0 += x[i];
T f1 = f0 * T(1103515245) + T(12345);
T f2 = f1 * T(1103515245) + T(12345);
T f3 = f2 * T(1103515245) + T(12345);
return detail::tvec3<T>(
noise1(f1),
noise1(f2),
noise1(f3));
}
// noise4
template <typename genType>
inline detail::tvec4<genType> noise4
(
genType const & x
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
genType f1 = x * genType(1103515245) + genType(12345);
genType f2 = f1 * genType(1103515245) + genType(12345);
genType f3 = f2 * genType(1103515245) + genType(12345);
genType f4 = f3 * genType(1103515245) + genType(12345);
return detail::tvec4<genType>(
noise1(f1),
noise1(f2),
noise1(f3),
noise1(f4));
}
template <typename T>
inline detail::tvec4<T> noise4
(
detail::tvec2<T> const & x
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
T f0(0);
for(typename detail::tvec2<T>::size_type i = 0; i < detail::tvec2<T>::value_size(); ++i)
f0 += x[i];
T f1 = f0 * T(1103515245) + T(12345);
T f2 = f1 * T(1103515245) + T(12345);
T f3 = f2 * T(1103515245) + T(12345);
T f4 = f3 * T(1103515245) + T(12345);
return detail::tvec4<T>(
noise1(f1),
noise1(f2),
noise1(f3),
noise1(f4));
}
template <typename T>
inline detail::tvec4<T> noise4
(
detail::tvec3<T> const & x
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
T f0(0);
for(typename detail::tvec3<T>::size_type i = 0; i < detail::tvec3<T>::value_size()(); ++i)
f0 += x[i];
T f1 = f0 * T(1103515245) + T(12345);
T f2 = f1 * T(1103515245) + T(12345);
T f3 = f2 * T(1103515245) + T(12345);
T f4 = f3 * T(1103515245) + T(12345);
return detail::tvec4<T>(
noise1(f1),
noise1(f2),
noise1(f3),
noise1(f4));
}
template <typename T>
inline detail::tvec4<T> noise4
(
detail::tvec4<T> const & x
)
{
GLM_STATIC_ASSERT(detail::type<T>::is_float);
T f0(0);
for(typename detail::tvec4<T>::size_type i = 0; i < detail::tvec4<T>::value_size()(); ++i)
f0 += x[i];
T f1 = f0 * T(1103515245) + T(12345);
T f2 = f1 * T(1103515245) + T(12345);
T f3 = f2 * T(1103515245) + T(12345);
T f4 = f3 * T(1103515245) + T(12345);
return detail::tvec4<T>(
noise1(f1),
noise1(f2),
noise1(f3),
noise1(f4));
}
}//namespace noise
}//namespace function
}//namespace core
}//namespace glm

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2010-03-17
// Updated : 2010-03-17
// Licence : This source is under MIT License
// File : glm/core/func_packing.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef glm_core_func_packing
#define glm_core_func_packing
namespace glm
{
namespace test{
void main_core_func_packing();
}//namespace test
namespace core{
namespace function{
//! Define packing functions from section 8.4 floating-point pack and unpack functions of GLSL 4.00.8 specification
namespace packing
{
uint packUnorm2x16(vec2 const & v);
uint packUnorm4x8(vec4 const & v);
uint packSnorm4x8(vec4 const & v);
vec2 unpackUnorm2x16(uint const & p);
vec4 unpackUnorm4x8(uint const & p);
vec4 unpackSnorm4x8(uint const & p);
double packDouble2x32(uvec2 const & v);
uvec2 unpackDouble2x32(double const & v);
}//namespace packing
}//namespace function
}//namespace core
using namespace core::function::packing;
}//namespace glm
#include "func_packing.inl"
#endif//glm_core_func_packing

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2010-03-17
// Updated : 2010-03-17
// Licence : This source is under MIT License
// File : glm/core/func_packing.inl
///////////////////////////////////////////////////////////////////////////////////////////////////
namespace glm
{
namespace detail
{
}//namespace detail
namespace core{
namespace function{
namespace packing{
}//namespace packing
}//namespace function
}//namespace core
}//namespace glm

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-08-01
// Updated : 2008-09-10
// Licence : This source is under MIT License
// File : glm/core/func_trigonometric.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef glm_core_func_trigonometric
#define glm_core_func_trigonometric
namespace glm
{
namespace test{
void main_core_func_trigonometric();
}//namespace test
namespace core{
namespace function{
//! Define Angle and trigonometry functions
//! from Section 8.1 of GLSL 1.30.8 specification.
//! Included in glm namespace.
namespace trigonometric{
//! Converts degrees to radians and returns the result.
//! (From GLSL 1.30.08 specification, section 8.1)
template <typename genType>
genType radians(genType const & degrees);
//! Converts radians to degrees and returns the result.
//! (From GLSL 1.30.08 specification, section 8.1)
template <typename genType>
genType degrees(genType const & radians);
//! The standard trigonometric sine function.
//! The values returned by this function will range from [-1, 1].
//! (From GLSL 1.30.08 specification, section 8.1)
template <typename genType>
genType sin(genType const & angle);
//! The standard trigonometric cosine function.
//! The values returned by this function will range from [-1, 1].
//! (From GLSL 1.30.08 specification, section 8.1)
template <typename genType>
genType cos(genType const & angle);
//! The standard trigonometric tangent function.
//! (From GLSL 1.30.08 specification, section 8.1)
template <typename genType>
genType tan(genType const & angle);
//! Arc sine. Returns an angle whose sine is x.
//! The range of values returned by this function is [-PI/2, PI/2].
//! Results are undefined if |x| > 1.
//! (From GLSL 1.30.08 specification, section 8.1)
template <typename genType>
genType asin(genType const & x);
//! Arc cosine. Returns an angle whose sine is x.
//! The range of values returned by this function is [0, PI].
//! Results are undefined if |x| > 1.
//! (From GLSL 1.30.08 specification, section 8.1)
template <typename genType>
genType acos(genType const & x);
//! Arc tangent. Returns an angle whose tangent is y/x.
//! The signs of x and y are used to determine what
//! quadrant the angle is in. The range of values returned
//! by this function is [-PI, PI]. Results are undefined
//! if x and y are both 0.
//! (From GLSL 1.30.08 specification, section 8.1)
template <typename genType>
genType atan(genType const & y, genType const & x);
//! Arc tangent. Returns an angle whose tangent is y_over_x.
//! The range of values returned by this function is [-PI/2, PI/2].
//! (From GLSL 1.30.08 specification, section 8.1)
template <typename genType>
genType atan(genType const & y_over_x);
//! Returns the hyperbolic sine function, (exp(x) - exp(-x)) / 2
//! (From GLSL 1.30.08 specification, section 8.1)
template <typename genType>
genType sinh(genType const & angle);
//! Returns the hyperbolic cosine function, (exp(x) + exp(-x)) / 2
//! (From GLSL 1.30.08 specification, section 8.1)
template <typename genType>
genType cosh(genType const & angle);
//! Returns the hyperbolic tangent function, sinh(angle) / cosh(angle)
//! (From GLSL 1.30.08 specification, section 8.1)
template <typename genType>
genType tanh(genType const & angle);
//! Arc hyperbolic sine; returns the inverse of sinh.
//! (From GLSL 1.30.08 specification, section 8.1)
template <typename genType>
genType asinh(genType const & x);
//! Arc hyperbolic cosine; returns the non-negative inverse
//! of cosh. Results are undefined if x < 1.
//! (From GLSL 1.30.08 specification, section 8.1)
template <typename genType>
genType acosh(genType const & x);
//! Arc hyperbolic tangent; returns the inverse of tanh.
//! Results are undefined if abs(x) >= 1.
//! (From GLSL 1.30.08 specification, section 8.1)
template <typename genType>
genType atanh(genType const & x);
}//namespace trigonometric
}//namespace function
}//namespace core
using namespace core::function::trigonometric;
}//namespace glm
#include "func_trigonometric.inl"
#endif//glm_core_func_trigonometric

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-08-03
// Updated : 2008-09-14
// Licence : This source is under MIT License
// File : glm/core/func_trigonometric.inl
///////////////////////////////////////////////////////////////////////////////////////////////////
namespace glm
{
namespace core{
namespace function{
namespace trigonometric{
// radians
template <typename genType>
inline genType radians
(
genType const & degrees
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
const genType pi = genType(3.1415926535897932384626433832795);
return degrees * (pi / genType(180));
}
template <typename T>
inline detail::tvec2<T> radians
(
detail::tvec2<T> const & degrees
)
{
return detail::tvec2<T>(
radians(degrees.x),
radians(degrees.y));
}
template <typename T>
inline detail::tvec3<T> radians
(
detail::tvec3<T> const & degrees
)
{
return detail::tvec3<T>(
radians(degrees.x),
radians(degrees.y),
radians(degrees.z));
}
template <typename T>
inline detail::tvec4<T> radians
(
detail::tvec4<T> const & degrees
)
{
return detail::tvec4<T>(
radians(degrees.x),
radians(degrees.y),
radians(degrees.z),
radians(degrees.w));
}
// degrees
template <typename genType>
inline genType degrees
(
genType const & radians
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
const genType pi = genType(3.1415926535897932384626433832795);
return radians * (genType(180) / pi);
}
template <typename T>
inline detail::tvec2<T> degrees
(
detail::tvec2<T> const & radians
)
{
return detail::tvec2<T>(
degrees(radians.x),
degrees(radians.y));
}
template <typename T>
inline detail::tvec3<T> degrees
(
detail::tvec3<T> const & radians
)
{
return detail::tvec3<T>(
degrees(radians.x),
degrees(radians.y),
degrees(radians.z));
}
template <typename T>
inline detail::tvec4<T> degrees
(
detail::tvec4<T> const & radians
)
{
return detail::tvec4<T>(
degrees(radians.x),
degrees(radians.y),
degrees(radians.z),
degrees(radians.w));
}
// sin
template <typename genType>
inline genType sin
(
genType const & angle
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return ::std::sin(angle);
}
template <typename T>
inline detail::tvec2<T> sin
(
detail::tvec2<T> const & angle
)
{
return detail::tvec2<T>(
sin(angle.x),
sin(angle.y));
}
template <typename T>
inline detail::tvec3<T> sin
(
detail::tvec3<T> const & angle
)
{
return detail::tvec3<T>(
sin(angle.x),
sin(angle.y),
sin(angle.z));
}
template <typename T>
inline detail::tvec4<T> sin
(
detail::tvec4<T> const & angle
)
{
return detail::tvec4<T>(
sin(angle.x),
sin(angle.y),
sin(angle.z),
sin(angle.w));
}
// cos
template <typename genType>
inline genType cos(genType const & angle)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return ::std::cos(angle);
}
template <typename T>
inline detail::tvec2<T> cos
(
detail::tvec2<T> const & angle
)
{
return detail::tvec2<T>(
cos(angle.x),
cos(angle.y));
}
template <typename T>
inline detail::tvec3<T> cos
(
detail::tvec3<T> const & angle
)
{
return detail::tvec3<T>(
cos(angle.x),
cos(angle.y),
cos(angle.z));
}
template <typename T>
inline detail::tvec4<T> cos
(
detail::tvec4<T> const & angle
)
{
return detail::tvec4<T>(
cos(angle.x),
cos(angle.y),
cos(angle.z),
cos(angle.w));
}
// tan
template <typename genType>
inline genType tan
(
genType const & angle
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return ::std::tan(angle);
}
template <typename T>
inline detail::tvec2<T> tan
(
detail::tvec2<T> const & angle
)
{
return detail::tvec2<T>(
tan(angle.x),
tan(angle.y));
}
template <typename T>
inline detail::tvec3<T> tan
(
detail::tvec3<T> const & angle
)
{
return detail::tvec3<T>(
tan(angle.x),
tan(angle.y),
tan(angle.z));
}
template <typename T>
inline detail::tvec4<T> tan
(
detail::tvec4<T> const & angle
)
{
return detail::tvec4<T>(
tan(angle.x),
tan(angle.y),
tan(angle.z),
tan(angle.w));
}
// asin
template <typename genType>
inline genType asin
(
genType const & x
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return ::std::asin(x);
}
template <typename T>
inline detail::tvec2<T> asin
(
detail::tvec2<T> const & x
)
{
return detail::tvec2<T>(
asin(x.x),
asin(x.y));
}
template <typename T>
inline detail::tvec3<T> asin
(
detail::tvec3<T> const & x
)
{
return detail::tvec3<T>(
asin(x.x),
asin(x.y),
asin(x.z));
}
template <typename T>
inline detail::tvec4<T> asin
(
detail::tvec4<T> const & x
)
{
return detail::tvec4<T>(
asin(x.x),
asin(x.y),
asin(x.z),
asin(x.w));
}
// acos
template <typename genType>
inline genType acos
(
genType const & x
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return ::std::acos(x);
}
template <typename T>
inline detail::tvec2<T> acos
(
detail::tvec2<T> const & x
)
{
return detail::tvec2<T>(
acos(x.x),
acos(x.y));
}
template <typename T>
inline detail::tvec3<T> acos
(
detail::tvec3<T> const & x
)
{
return detail::tvec3<T>(
acos(x.x),
acos(x.y),
acos(x.z));
}
template <typename T>
inline detail::tvec4<T> acos
(
detail::tvec4<T> const & x
)
{
return detail::tvec4<T>(
acos(x.x),
acos(x.y),
acos(x.z),
acos(x.w));
}
// atan
template <typename genType>
inline genType atan
(
genType const & y,
genType const & x
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return ::std::atan2(y, x);
}
template <typename T>
inline detail::tvec2<T> atan
(
detail::tvec2<T> const & y,
detail::tvec2<T> const & x
)
{
return detail::tvec2<T>(
atan(y.x, x.x),
atan(y.y, x.y));
}
template <typename T>
inline detail::tvec3<T> atan
(
detail::tvec3<T> const & y,
detail::tvec3<T> const & x
)
{
return detail::tvec3<T>(
atan(y.x, x.x),
atan(y.y, x.y),
atan(y.z, x.z));
}
template <typename T>
inline detail::tvec4<T> atan
(
detail::tvec4<T> const & y,
detail::tvec4<T> const & x
)
{
return detail::tvec4<T>(
atan(y.x, x.x),
atan(y.y, x.y),
atan(y.z, x.z),
atan(y.w, x.w));
}
template <typename genType>
inline genType atan
(
genType const & x
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return ::std::atan(x);
}
template <typename T>
inline detail::tvec2<T> atan
(
detail::tvec2<T> const & x
)
{
return detail::tvec2<T>(
atan(x.x),
atan(x.y));
}
template <typename T>
inline detail::tvec3<T> atan
(
detail::tvec3<T> const & x
)
{
return detail::tvec3<T>(
atan(x.x),
atan(x.y),
atan(x.z));
}
template <typename T>
inline detail::tvec4<T> atan
(
detail::tvec4<T> const & x
)
{
return detail::tvec4<T>(
atan(x.x),
atan(x.y),
atan(x.z),
atan(x.w));
}
// sinh
template <typename genType>
inline genType sinh
(
genType const & angle
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return std::sinh(angle);
}
template <typename T>
inline detail::tvec2<T> sinh
(
detail::tvec2<T> const & angle
)
{
return detail::tvec2<T>(
sinh(angle.x),
sinh(angle.y));
}
template <typename T>
inline detail::tvec3<T> sinh
(
detail::tvec3<T> const & angle
)
{
return detail::tvec3<T>(
sinh(angle.x),
sinh(angle.y),
sinh(angle.z));
}
template <typename T>
inline detail::tvec4<T> sinh
(
detail::tvec4<T> const & angle
)
{
return detail::tvec4<T>(
sinh(angle.x),
sinh(angle.y),
sinh(angle.z),
sinh(angle.w));
}
// cosh
template <typename genType>
inline genType cosh
(
genType const & angle
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return std::cosh(angle);
}
template <typename T>
inline detail::tvec2<T> cosh
(
detail::tvec2<T> const & angle
)
{
return detail::tvec2<T>(
cosh(angle.x),
cosh(angle.y));
}
template <typename T>
inline detail::tvec3<T> cosh
(
detail::tvec3<T> const & angle
)
{
return detail::tvec3<T>(
cosh(angle.x),
cosh(angle.y),
cosh(angle.z));
}
template <typename T>
inline detail::tvec4<T> cosh
(
detail::tvec4<T> const & angle
)
{
return detail::tvec4<T>(
cosh(angle.x),
cosh(angle.y),
cosh(angle.z),
cosh(angle.w));
}
// tanh
template <typename genType>
inline genType tanh
(
genType const & angle
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return std::tanh(angle);
}
template <typename T>
inline detail::tvec2<T> tanh
(
detail::tvec2<T> const & angle
)
{
return detail::tvec2<T>(
tanh(angle.x),
tanh(angle.y));
}
template <typename T>
inline detail::tvec3<T> tanh
(
detail::tvec3<T> const & angle
)
{
return detail::tvec3<T>(
tanh(angle.x),
tanh(angle.y),
tanh(angle.z));
}
template <typename T>
inline detail::tvec4<T> tanh
(
detail::tvec4<T> const & angle
)
{
return detail::tvec4<T>(
tanh(angle.x),
tanh(angle.y),
tanh(angle.z),
tanh(angle.w));
}
// asinh
template <typename genType>
inline genType asinh
(
genType const & x
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
return (x < genType(0) ? genType(-1) : (x > genType(0) ? genType(1) : genType(0))) * log(abs(x) + sqrt(genType(1) + x * x));
}
template <typename T>
inline detail::tvec2<T> asinh
(
detail::tvec2<T> const & x
)
{
return detail::tvec2<T>(
asinh(x.x),
asinh(x.y));
}
template <typename T>
inline detail::tvec3<T> asinh
(
detail::tvec3<T> const & x
)
{
return detail::tvec3<T>(
asinh(x.x),
asinh(x.y),
asinh(x.z));
}
template <typename T>
inline detail::tvec4<T> asinh
(
detail::tvec4<T> const & x
)
{
return detail::tvec4<T>(
asinh(x.x),
asinh(x.y),
asinh(x.z),
asinh(x.w));
}
// acosh
template <typename genType>
inline genType acosh
(
genType const & x
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
if(x < genType(1))
return genType(0);
return log(x + sqrt(x * x - genType(1)));
}
template <typename T>
inline detail::tvec2<T> acosh
(
detail::tvec2<T> const & x
)
{
return detail::tvec2<T>(
acosh(x.x),
acosh(x.y));
}
template <typename T>
inline detail::tvec3<T> acosh
(
detail::tvec3<T> const & x
)
{
return detail::tvec3<T>(
acosh(x.x),
acosh(x.y),
acosh(x.z));
}
template <typename T>
inline detail::tvec4<T> acosh
(
detail::tvec4<T> const & x
)
{
return detail::tvec4<T>(
acosh(x.x),
acosh(x.y),
acosh(x.z),
acosh(x.w));
}
// atanh
template <typename genType>
inline genType atanh
(
genType const & x
)
{
GLM_STATIC_ASSERT(detail::type<genType>::is_float);
if(abs(x) >= genType(1))
return 0;
return genType(0.5) * log((genType(1) + x) / (genType(1) - x));
}
template <typename T>
inline detail::tvec2<T> atanh
(
detail::tvec2<T> const & x
)
{
return detail::tvec2<T>(
atanh(x.x),
atanh(x.y));
}
template <typename T>
inline detail::tvec3<T> atanh
(
detail::tvec3<T> const & x
)
{
return detail::tvec3<T>(
atanh(x.x),
atanh(x.y),
atanh(x.z));
}
template <typename T>
inline detail::tvec4<T> atanh
(
detail::tvec4<T> const & x
)
{
return detail::tvec4<T>(
atanh(x.x),
atanh(x.y),
atanh(x.z),
atanh(x.w));
}
}//namespace trigonometric
}//namespace function
}//namespace core
}//namespace glm

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-08-03
// Updated : 2008-09-09
// Licence : This source is under MIT License
// File : glm/core/func_vector_relational.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef glm_core_func_vector_relational
#define glm_core_func_vector_relational
namespace glm
{
namespace test{
void main_core_func_vector_relational();
}//namespace test
namespace core{
namespace function{
//! Define vector relational functions from Section 8.3 of GLSL 1.30.8 specification.
//! Included in glm namespace.
namespace vector_relational
{
//! Returns the component-wise comparison result of x < y.
//! (From GLSL 1.30.08 specification, section 8.6)
template <typename T, template <typename> class vecType>
inline typename vecType<T>::bool_type lessThan
(
vecType<T> const & x,
vecType<T> const & y
)
{
GLM_STATIC_ASSERT(
detail::type<T>::is_float ||
detail::type<T>::is_int ||
detail::type<T>::is_uint);
typename vecType<bool>::bool_type Result(vecType<bool>::null);
for(typename vecType<bool>::size_type i = 0; i < vecType<bool>::value_size(); ++i)
Result[i] = x[i] < y[i];
return Result;
}
//! Returns the component-wise comparison of result x <= y.
//! (From GLSL 1.30.08 specification, section 8.6)
template <typename T, template <typename> class vecType>
inline typename vecType<T>::bool_type lessThanEqual
(
vecType<T> const & x,
vecType<T> const & y
)
{
GLM_STATIC_ASSERT(
detail::type<T>::is_float ||
detail::type<T>::is_int ||
detail::type<T>::is_uint);
typename vecType<bool>::bool_type Result(vecType<bool>::null);
for(typename vecType<bool>::size_type i = 0; i < vecType<bool>::value_size(); ++i)
Result[i] = x[i] <= y[i];
return Result;
}
//! Returns the component-wise comparison of result x > y.
//! (From GLSL 1.30.08 specification, section 8.6)
template <typename T, template <typename> class vecType>
inline typename vecType<T>::bool_type greaterThan
(
vecType<T> const & x,
vecType<T> const & y
)
{
GLM_STATIC_ASSERT(
detail::type<T>::is_float ||
detail::type<T>::is_int ||
detail::type<T>::is_uint);
typename vecType<bool>::bool_type Result(vecType<bool>::null);
for(typename vecType<bool>::size_type i = 0; i < vecType<bool>::value_size(); ++i)
Result[i] = x[i] > y[i];
return Result;
}
//! Returns the component-wise comparison of result x >= y.
//! (From GLSL 1.30.08 specification, section 8.6)
template <typename T, template <typename> class vecType>
inline typename vecType<T>::bool_type greaterThanEqual
(
vecType<T> const & x,
vecType<T> const & y
)
{
GLM_STATIC_ASSERT(
detail::type<T>::is_float ||
detail::type<T>::is_int ||
detail::type<T>::is_uint);
typename vecType<bool>::bool_type Result(vecType<bool>::null);
for(typename vecType<bool>::size_type i = 0; i < vecType<bool>::value_size(); ++i)
Result[i] = x[i] >= y[i];
return Result;
}
//! Returns the component-wise comparison of result x == y.
//! (From GLSL 1.30.08 specification, section 8.6)
template <typename T, template <typename> class vecType>
inline typename vecType<T>::bool_type equal
(
vecType<T> const & x,
vecType<T> const & y
)
{
GLM_STATIC_ASSERT(
detail::type<T>::is_float ||
detail::type<T>::is_int ||
detail::type<T>::is_uint ||
detail::type<T>::is_bool);
typename vecType<bool>::bool_type Result(vecType<bool>::null);
for(typename vecType<bool>::size_type i = 0; i < vecType<bool>::value_size(); ++i)
Result[i] = x[i] == y[i];
return Result;
}
//! Returns the component-wise comparison of result x != y.
//! (From GLSL 1.30.08 specification, section 8.6)
template <typename T, template <typename> class vecType>
inline typename vecType<T>::bool_type notEqual
(
vecType<T> const & x,
vecType<T> const & y
)
{
GLM_STATIC_ASSERT(
detail::type<T>::is_float ||
detail::type<T>::is_int ||
detail::type<T>::is_uint ||
detail::type<T>::is_bool);
typename vecType<bool>::bool_type Result(vecType<bool>::null);
for(typename vecType<bool>::size_type i = 0; i < vecType<bool>::value_size(); ++i)
Result[i] = x[i] != y[i];
return Result;
}
//! Returns true if any component of x is true.
//! (From GLSL 1.30.08 specification, section 8.6)
template <template <typename> class vecType>
inline bool any(vecType<bool> const & v)
{
bool Result = false;
for(typename vecType<bool>::size_type i = 0; i < vecType<bool>::value_size(); ++i)
Result = Result || v[i];
return Result;
}
//! Returns true if all components of x are true.
//! (From GLSL 1.30.08 specification, section 8.6)
template <template <typename> class vecType>
inline bool all(vecType<bool> const & v)
{
bool Result = true;
for(typename vecType<bool>::size_type i = 0; i < vecType<bool>::value_size(); ++i)
Result = Result && v[i];
return Result;
}
//! Returns the component-wise logical complement of x.
//! (From GLSL 1.30.08 specification, section 8.6)
template <template <typename> class vecType>
inline vecType<bool> not_(vecType<bool> const & v)
{
typename vecType<bool>::bool_type Result(vecType<bool>::null);
for(typename vecType<bool>::size_type i = 0; i < vecType<bool>::value_size(); ++i)
Result[i] = !v[i];
return Result;
}
}//namespace vector_relational
}//namespace function
}//namespace core
using namespace core::function::vector_relational;
}//namespace glm
#include "func_vector_relational.inl"
#endif//glm_core_func_vector_relational

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-08-03
// Updated : 2008-09-14
// Licence : This source is under MIT License
// File : glm/core/func_vector_relational.inl
///////////////////////////////////////////////////////////////////////////////////////////////////
namespace glm
{
namespace core{
namespace function{
namespace vector_relational{
}//namespace vector_relational
}//namespace function
}//namespace core
}//namespace glm

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-08-14
// Updated : 2008-08-14
// Licence : This source is under MIT License
// File : glm/core/hint.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef glm_core_type
#define glm_core_type
namespace glm
{
// Use dont_care, nicest and fastest to optimize implementations.
class dont_care {};
class nicest {};
class fastest {};
};
#endif//glm_core_type

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2009-05-11
// Updated : 2009-05-11
// Licence : This source is under MIT License
// File : glm/core/intrinsic_common.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef GLM_DETAIL_INTRINSIC_COMMON_INCLUDED
#define GLM_DETAIL_INTRINSIC_COMMON_INCLUDED
//#include <mmintrin.h>
//#include <emmintrin.h>
#include <xmmintrin.h>
#include <emmintrin.h>
__m128 _mm_abs_ps(__m128 x);
__m128 _mm_sgn_ps(__m128 x);
//floor
__m128 _mm_flr_ps(__m128 v);
//trunc
__m128 _mm_trc_ps(__m128 v);
//round
__m128 _mm_rnd_ps(__m128 v);
//roundEven
__m128 _mm_rde_ps(__m128 v);
__m128 _mm_ceil_ps(__m128 v);
__m128 _mm_frc_ps(__m128 x);
__m128 _mm_mod_ps(__m128 x, __m128 y);
__m128 _mm_modf_ps(__m128 x, __m128i & i);
//inline __m128 _mm_min_ps(__m128 x, __m128 y)
//inline __m128 _mm_max_ps(__m128 x, __m128 y)
__m128 _mm_clp_ps(__m128 v, __m128 minVal, __m128 maxVal);
__m128 _mm_mix_ps(__m128 v1, __m128 v2, __m128 a);
__m128 _mm_stp_ps(__m128 edge, __m128 x);
__m128 _mm_ssp_ps(__m128 edge0, __m128 edge1, __m128 x);
__m128 _mm_nan_ps(__m128 x);
__m128 _mm_inf_ps(__m128 x);
#include "intrinsic_common.inl"
#endif//GLM_DETAIL_INTRINSIC_COMMON_INCLUDED

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2009-05-08
// Updated : 2009-05-08
// Licence : This source is under MIT License
// File : glm/core/intrinsic_common.inl
///////////////////////////////////////////////////////////////////////////////////////////////////
namespace glm{
namespace detail{
union ieee754_QNAN
{
const float f;
struct
{
const unsigned int mantissa:23, exp:8, sign:1;
};
ieee754_QNAN() : f(0.0), mantissa(0x7FFFFF), exp(0xFF), sign(0x0) {}
};
static const __m128 zero = _mm_setzero_ps();
static const __m128 one = _mm_set_ps1(1.0f);
static const __m128 minus_one = _mm_set_ps1(-1.0f);
static const __m128 two = _mm_set_ps1(2.0f);
static const __m128 three = _mm_set_ps1(3.0f);
static const __m128 pi = _mm_set_ps1(3.1415926535897932384626433832795f);
static const __m128 hundred_eighty = _mm_set_ps1(180.f);
static const __m128 pi_over_hundred_eighty = _mm_set_ps1(0.017453292519943295769236907684886f);
static const __m128 hundred_eighty_over_pi = _mm_set_ps1(57.295779513082320876798154814105f);
static const ieee754_QNAN absMask;
static const __m128 abs4Mask = _mm_set_ps1(absMask.f);
//static const __m128 _epi32_sign_mask = _mm_castsi128_ps(_mm_set1_epi32(0x80000000));
//static const __m128 _epi32_inv_sign_mask = _mm_castsi128_ps(_mm_set1_epi32(0x7FFFFFFF));
//static const __m128 _epi32_mant_mask = _mm_castsi128_ps(_mm_set1_epi32(0x7F800000));
//static const __m128 _epi32_inv_mant_mask = _mm_castsi128_ps(_mm_set1_epi32(0x807FFFFF));
//static const __m128 _epi32_min_norm_pos = _mm_castsi128_ps(_mm_set1_epi32(0x00800000));
static const __m128 _epi32_0 = _mm_set_ps1(0);
static const __m128 _epi32_1 = _mm_set_ps1(1);
static const __m128 _epi32_2 = _mm_set_ps1(2);
static const __m128 _epi32_3 = _mm_set_ps1(3);
static const __m128 _epi32_4 = _mm_set_ps1(4);
static const __m128 _epi32_5 = _mm_set_ps1(5);
static const __m128 _epi32_6 = _mm_set_ps1(6);
static const __m128 _epi32_7 = _mm_set_ps1(7);
static const __m128 _epi32_8 = _mm_set_ps1(8);
static const __m128 _epi32_9 = _mm_set_ps1(9);
static const __m128 _epi32_127 = _mm_set_ps1(127);
//static const __m128 _epi32_ninf = _mm_castsi128_ps(_mm_set1_epi32(0xFF800000));
//static const __m128 _epi32_pinf = _mm_castsi128_ps(_mm_set1_epi32(0x7F800000));
static const __m128 _ps_1_3 = _mm_set_ps1(0.33333333333333333333333333333333f);
static const __m128 _ps_0p5 = _mm_set_ps1(0.5f);
static const __m128 _ps_1 = _mm_set_ps1(1.0f);
static const __m128 _ps_m1 = _mm_set_ps1(-1.0f);
static const __m128 _ps_2 = _mm_set_ps1(2.0f);
static const __m128 _ps_3 = _mm_set_ps1(3.0f);
static const __m128 _ps_127 = _mm_set_ps1(127.0f);
static const __m128 _ps_255 = _mm_set_ps1(255.0f);
static const __m128 _ps_2pow23 = _mm_set_ps1(8388608.0f);
static const __m128 _ps_1_0_0_0 = _mm_set_ps(1.0f, 0.0f, 0.0f, 0.0f);
static const __m128 _ps_0_1_0_0 = _mm_set_ps(0.0f, 1.0f, 0.0f, 0.0f);
static const __m128 _ps_0_0_1_0 = _mm_set_ps(0.0f, 0.0f, 1.0f, 0.0f);
static const __m128 _ps_0_0_0_1 = _mm_set_ps(0.0f, 0.0f, 0.0f, 1.0f);
static const __m128 _ps_pi = _mm_set_ps1(3.1415926535897932384626433832795f);
static const __m128 _ps_pi2 = _mm_set_ps1(6.283185307179586476925286766560f);
static const __m128 _ps_2_pi = _mm_set_ps1(0.63661977236758134307553505349006f);
static const __m128 _ps_pi_2 = _mm_set_ps1(1.5707963267948966192313216916398f);
static const __m128 _ps_4_pi = _mm_set_ps1(1.2732395447351626861510701069801f);
static const __m128 _ps_pi_4 = _mm_set_ps1(0.78539816339744830961566084581988f);
static const __m128 _ps_sincos_p0 = _mm_set_ps1(0.15707963267948963959e1f);
static const __m128 _ps_sincos_p1 = _mm_set_ps1(-0.64596409750621907082e0f);
static const __m128 _ps_sincos_p2 = _mm_set_ps1(0.7969262624561800806e-1f);
static const __m128 _ps_sincos_p3 = _mm_set_ps1(-0.468175413106023168e-2f);
static const __m128 _ps_tan_p0 = _mm_set_ps1(-1.79565251976484877988e7f);
static const __m128 _ps_tan_p1 = _mm_set_ps1(1.15351664838587416140e6f);
static const __m128 _ps_tan_p2 = _mm_set_ps1(-1.30936939181383777646e4f);
static const __m128 _ps_tan_q0 = _mm_set_ps1(-5.38695755929454629881e7f);
static const __m128 _ps_tan_q1 = _mm_set_ps1(2.50083801823357915839e7f);
static const __m128 _ps_tan_q2 = _mm_set_ps1(-1.32089234440210967447e6f);
static const __m128 _ps_tan_q3 = _mm_set_ps1(1.36812963470692954678e4f);
static const __m128 _ps_tan_poleval = _mm_set_ps1(3.68935e19f);
static const __m128 _ps_atan_t0 = _mm_set_ps1(-0.91646118527267623468e-1f);
static const __m128 _ps_atan_t1 = _mm_set_ps1(-0.13956945682312098640e1f);
static const __m128 _ps_atan_t2 = _mm_set_ps1(-0.94393926122725531747e2f);
static const __m128 _ps_atan_t3 = _mm_set_ps1(0.12888383034157279340e2f);
static const __m128 _ps_atan_s0 = _mm_set_ps1(0.12797564625607904396e1f);
static const __m128 _ps_atan_s1 = _mm_set_ps1(0.21972168858277355914e1f);
static const __m128 _ps_atan_s2 = _mm_set_ps1(0.68193064729268275701e1f);
static const __m128 _ps_atan_s3 = _mm_set_ps1(0.28205206687035841409e2f);
static const __m128 _ps_exp_hi = _mm_set_ps1(88.3762626647949f);
static const __m128 _ps_exp_lo = _mm_set_ps1(-88.3762626647949f);
static const __m128 _ps_exp_rln2 = _mm_set_ps1(1.4426950408889634073599f);
static const __m128 _ps_exp_p0 = _mm_set_ps1(1.26177193074810590878e-4f);
static const __m128 _ps_exp_p1 = _mm_set_ps1(3.02994407707441961300e-2f);
static const __m128 _ps_exp_q0 = _mm_set_ps1(3.00198505138664455042e-6f);
static const __m128 _ps_exp_q1 = _mm_set_ps1(2.52448340349684104192e-3f);
static const __m128 _ps_exp_q2 = _mm_set_ps1(2.27265548208155028766e-1f);
static const __m128 _ps_exp_q3 = _mm_set_ps1(2.00000000000000000009e0f);
static const __m128 _ps_exp_c1 = _mm_set_ps1(6.93145751953125e-1f);
static const __m128 _ps_exp_c2 = _mm_set_ps1(1.42860682030941723212e-6f);
static const __m128 _ps_exp2_hi = _mm_set_ps1(127.4999961853f);
static const __m128 _ps_exp2_lo = _mm_set_ps1(-127.4999961853f);
static const __m128 _ps_exp2_p0 = _mm_set_ps1(2.30933477057345225087e-2f);
static const __m128 _ps_exp2_p1 = _mm_set_ps1(2.02020656693165307700e1f);
static const __m128 _ps_exp2_p2 = _mm_set_ps1(1.51390680115615096133e3f);
static const __m128 _ps_exp2_q0 = _mm_set_ps1(2.33184211722314911771e2f);
static const __m128 _ps_exp2_q1 = _mm_set_ps1(4.36821166879210612817e3f);
static const __m128 _ps_log_p0 = _mm_set_ps1(-7.89580278884799154124e-1f);
static const __m128 _ps_log_p1 = _mm_set_ps1(1.63866645699558079767e1f);
static const __m128 _ps_log_p2 = _mm_set_ps1(-6.41409952958715622951e1f);
static const __m128 _ps_log_q0 = _mm_set_ps1(-3.56722798256324312549e1f);
static const __m128 _ps_log_q1 = _mm_set_ps1(3.12093766372244180303e2f);
static const __m128 _ps_log_q2 = _mm_set_ps1(-7.69691943550460008604e2f);
static const __m128 _ps_log_c0 = _mm_set_ps1(0.693147180559945f);
static const __m128 _ps_log2_c0 = _mm_set_ps1(1.44269504088896340735992f);
}//namespace detail
}//namespace glm
inline __m128 _mm_abs_ps(__m128 x)
{
return _mm_and_ps(glm::detail::abs4Mask, x);
}
inline __m128 _mm_sgn_ps(__m128 x)
{
//__m128 cmp0 = _mm_cmpeq_ps(x, zero);
//__m128 cmp1 = _mm_cmple_ps(x, zero);
//__m128 cmp2 = _mm_cmpge_ps(x, zero);
__m128 result;
__m128 cmp0 = _mm_cmpeq_ps(x, glm::detail::zero);
if(_mm_movemask_ps(cmp0) == 0)
result = glm::detail::zero;
else
{
__m128 cmp1 = _mm_cmpge_ps(x, glm::detail::zero);
//__m128 cmp2 = _mm_cmple_ps(x, glm::detail::zero);
if(_mm_movemask_ps(cmp1) > 0)
result = glm::detail::one;
else //if(_mm_movemask_ps(cmp2) > 0)
result = glm::detail::minus_one;
}
return result;
}
//floor
inline __m128 _mm_flr_ps(__m128 x)
{
__m128 rnd0 = _mm_rnd_ps(x);
__m128 cmp0 = _mm_cmplt_ps(x, rnd0);
__m128 and0 = _mm_and_ps(cmp0, glm::detail::_ps_1);
__m128 sub0 = _mm_sub_ps(rnd0, and0);
return sub0;
}
//trunc
inline __m128 _mm_trc_ps(__m128 v)
{
return __m128();
}
//round
inline __m128 _mm_rnd_ps(__m128 x)
{
__m128 and0;// = _mm_and_ps(glm::detail::_epi32_sign_mask, x);
__m128 or0 = _mm_or_ps(and0, glm::detail::_ps_2pow23);
__m128 add0 = _mm_add_ps(x, or0);
__m128 sub0 = _mm_sub_ps(add0, or0);
return sub0;
}
//roundEven
inline __m128 _mm_rde_ps(__m128 v)
{
}
inline __m128 _mm_ceil_ps(__m128 x)
{
__m128 rnd0 = _mm_rnd_ps(x);
__m128 cmp0 = _mm_cmpgt_ps(x, rnd0);
__m128 and0 = _mm_and_ps(cmp0, glm::detail::_ps_1);
__m128 add0 = _mm_add_ps(rnd0, and0);
return add0;
}
inline __m128 _mm_frc_ps(__m128 x)
{
__m128 flr0 = _mm_flr_ps(x);
__m128 sub0 = _mm_sub_ps(x, flr0);
return sub0;
}
inline __m128 _mm_mod_ps(__m128 x, __m128 y)
{
__m128 div0 = _mm_div_ps(x, y);
__m128 flr0 = _mm_flr_ps(div0);
__m128 mul0 = _mm_mul_ps(y, flr0);
__m128 sub0 = _mm_sub_ps(x, mul0);
return sub0;
}
inline __m128 _mm_modf_ps(__m128 x, __m128i & i)
{
}
//inline __m128 _mm_min_ps(__m128 x, __m128 y)
//inline __m128 _mm_max_ps(__m128 x, __m128 y)
inline __m128 _mm_clp_ps(__m128 v, __m128 minVal, __m128 maxVal)
{
__m128 min0 = _mm_min_ps(v, maxVal);
__m128 max0 = _mm_max_ps(min0, minVal);
return max0;
}
inline __m128 _mm_mix_ps(__m128 v1, __m128 v2, __m128 a)
{
__m128 sub0 = _mm_sub_ps(glm::detail::one, a);
__m128 mul0 = _mm_mul_ps(v1, sub0);
__m128 mul1 = _mm_mul_ps(v2, a);
__m128 add0 = _mm_add_ps(mul0, mul1);
return add0;
}
inline __m128 _mm_stp_ps(__m128 edge, __m128 x)
{
__m128 cmp = _mm_cmple_ps(x, edge);
if(_mm_movemask_ps(cmp) == 0)
return glm::detail::one;
else
return glm::detail::zero;
}
inline __m128 _mm_ssp_ps(__m128 edge0, __m128 edge1, __m128 x)
{
__m128 sub0 = _mm_sub_ps(x, edge0);
__m128 sub1 = _mm_sub_ps(edge1, edge0);
__m128 div0 = _mm_sub_ps(sub0, sub1);
__m128 clp0 = _mm_clp_ps(div0, glm::detail::zero, glm::detail::one);
__m128 mul0 = _mm_mul_ps(glm::detail::two, clp0);
__m128 sub2 = _mm_sub_ps(glm::detail::three, mul0);
__m128 mul1 = _mm_mul_ps(clp0, clp0);
__m128 mul2 = _mm_mul_ps(mul1, sub2);
return mul2;
}
inline __m128 _mm_nan_ps(__m128 x)
{
}
inline __m128 _mm_inf_ps(__m128 x)
{
}
// SSE scalar reciprocal sqrt using rsqrt op, plus one Newton-Rhaphson iteration
// By Elan Ruskin,
inline __m128 _mm_sqrt_wip_ss(__m128 const x)
{
__m128 recip = _mm_rsqrt_ss( x ); // "estimate" opcode
const static __m128 three = { 3, 3, 3, 3 }; // aligned consts for fast load
const static __m128 half = { 0.5,0.5,0.5,0.5 };
__m128 halfrecip = _mm_mul_ss( half, recip );
__m128 threeminus_xrr = _mm_sub_ss( three, _mm_mul_ss( x, _mm_mul_ss ( recip, recip ) ) );
return _mm_mul_ss( halfrecip, threeminus_xrr );
}

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/*
inline __m128 _mm_rsqrt_nr_ss(__m128 const x)
{
__m128 recip = _mm_rsqrt_ss( x ); // "estimate" opcode
const static __m128 three = { 3, 3, 3, 3 }; // aligned consts for fast load
const static __m128 half = { 0.5,0.5,0.5,0.5 };
__m128 halfrecip = _mm_mul_ss( half, recip );
__m128 threeminus_xrr = _mm_sub_ss( three, _mm_mul_ss( x, _mm_mul_ss ( recip, recip ) ) );
return _mm_mul_ss( halfrecip, threeminus_xrr );
}
inline __m128 __mm_normalize_fast_ps( float * RESTRICT vOut, float * RESTRICT vIn )
{
__m128 x = _mm_load_ss(&vIn[0]);
__m128 y = _mm_load_ss(&vIn[1]);
__m128 z = _mm_load_ss(&vIn[2]);
const __m128 l = // compute x*x + y*y + z*z
_mm_add_ss(
_mm_add_ss( _mm_mul_ss(x,x),
_mm_mul_ss(y,y)
),
_mm_mul_ss( z, z )
);
const __m128 rsqt = _mm_rsqrt_nr_ss( l );
_mm_store_ss( &vOut[0] , _mm_mul_ss( rsqt, x ) );
_mm_store_ss( &vOut[1] , _mm_mul_ss( rsqt, y ) );
_mm_store_ss( &vOut[2] , _mm_mul_ss( rsqt, z ) );
return _mm_mul_ss( l , rsqt );
}
*/

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2009-05-08
// Updated : 2009-05-08
// Licence : This source is under MIT License
// File : glm/core/intrinsic_geometric.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef glm_core_intrinsic_geometric
#define glm_core_intrinsic_geometric
#include "intrinsic_common.hpp"
//length
__m128 _mm_len_ps(__m128 x);
//distance
__m128 _mm_dst_ps(__m128 p0, __m128 p1);
//dot
__m128 _mm_dot_ps(__m128 v1, __m128 v2);
// SSE1
__m128 _mm_dot_ss(__m128 v1, __m128 v2);
//cross
__m128 _mm_xpd_ps(__m128 v1, __m128 v2);
//normalize
__m128 _mm_nrm_ps(__m128 v);
//faceforward
__m128 _mm_ffd_ps(__m128 N, __m128 I, __m128 Nref);
//reflect
__m128 _mm_rfe_ps(__m128 I, __m128 N);
//refract
__m128 _mm_rfa_ps(__m128 I, __m128 N, __m128 eta);
#include "intrinsic_geometric.inl"
#endif//glm_core_intrinsic_geometric

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2009-05-08
// Updated : 2009-05-08
// Licence : This source is under MIT License
// File : glm/core/intrinsic_geometric.inl
///////////////////////////////////////////////////////////////////////////////////////////////////
//length
inline __m128 _mm_len_ps(__m128 x)
{
__m128 dot0 = _mm_dot_ps(x, x);
__m128 sqt0 = _mm_sqrt_ps(dot0);
return sqt0;
}
//distance
inline __m128 _mm_dst_ps(__m128 p0, __m128 p1)
{
__m128 sub0 = _mm_sub_ps(p0, p1);
__m128 len0 = _mm_len_ps(sub0);
return len0;
}
//dot
inline __m128 _mm_dot_ps(__m128 v1, __m128 v2)
{
__m128 mul0 = _mm_mul_ps(v1, v2);
__m128 swp0 = _mm_shuffle_ps(mul0, mul0, _MM_SHUFFLE(2, 3, 0, 1));
__m128 add0 = _mm_add_ps(mul0, swp0);
__m128 swp1 = _mm_shuffle_ps(add0, add0, _MM_SHUFFLE(0, 1, 2, 3));
__m128 add1 = _mm_add_ps(add0, swp1);
return add1;
}
// SSE1
inline __m128 _mm_dot_ss(__m128 v1, __m128 v2)
{
__m128 mul0 = _mm_mul_ps(v1, v2);
__m128 mov0 = _mm_movehl_ps(mul0, mul0);
__m128 add0 = _mm_add_ps(mov0, mul0);
__m128 swp1 = _mm_shuffle_ps(add0, add0, 1);
__m128 add1 = _mm_add_ss(add0, swp1);
return add1;
}
//cross
inline __m128 _mm_xpd_ps(__m128 v1, __m128 v2)
{
__m128 swp0 = _mm_shuffle_ps(v1, v1, _MM_SHUFFLE(3, 0, 2, 1));
__m128 swp1 = _mm_shuffle_ps(v1, v1, _MM_SHUFFLE(3, 1, 0, 2));
__m128 swp2 = _mm_shuffle_ps(v2, v2, _MM_SHUFFLE(3, 0, 2, 1));
__m128 swp3 = _mm_shuffle_ps(v2, v2, _MM_SHUFFLE(3, 1, 0, 2));
__m128 mul0 = _mm_mul_ps(swp0, swp3);
__m128 mul1 = _mm_mul_ps(swp1, swp2);
__m128 sub0 = _mm_sub_ps(mul0, mul1);
return sub0;
}
//normalize
inline __m128 _mm_nrm_ps(__m128 v)
{
__m128 dot0 = _mm_dot_ps(v, v);
__m128 isr0 = _mm_rsqrt_ps(dot0);
__m128 mul0 = _mm_mul_ps(v, isr0);
return mul0;
}
//faceforward
inline __m128 _mm_ffd_ps(__m128 N, __m128 I, __m128 Nref)
{
//__m128 dot0 = _mm_dot_ps(v, v);
//__m128 neg0 = _mm_neg_ps(N);
//__m128 sgn0 = _mm_sgn_ps(dot0);
//__m128 mix0 = _mm_mix_ps(N, neg0, sgn0);
//return mix0;
__m128 dot0 = _mm_dot_ps(Nref, I);
__m128 sgn0 = _mm_sgn_ps(dot0);
__m128 mul0 = _mm_mul_ps(sgn0, glm::detail::minus_one);
__m128 mul1 = _mm_mul_ps(N, mul0);
return mul1;
}
//reflect
inline __m128 _mm_rfe_ps(__m128 I, __m128 N)
{
__m128 dot0 = _mm_dot_ps(N, I);
__m128 mul0 = _mm_mul_ps(N, I);
__m128 mul1 = _mm_mul_ps(mul0, glm::detail::two);
__m128 sub0 = _mm_sub_ps(I, mul1);
return sub0;
}
//refract
inline __m128 _mm_rfa_ps(__m128 I, __m128 N, __m128 eta)
{
__m128 dot0 = _mm_dot_ps(N, I);
__m128 mul0 = _mm_mul_ps(eta, eta);
__m128 mul1 = _mm_mul_ps(dot0, dot0);
__m128 sub0 = _mm_sub_ps(glm::detail::one, mul0);
__m128 sub1 = _mm_sub_ps(glm::detail::one, mul1);
__m128 mul2 = _mm_mul_ps(sub0, sub1);
if(_mm_movemask_ps(_mm_cmplt_ss(mul2, glm::detail::zero)) == 0)
return glm::detail::zero;
__m128 sqt0 = _mm_sqrt_ps(mul2);
__m128 mul3 = _mm_mul_ps(eta, dot0);
__m128 add0 = _mm_add_ps(mul3, sqt0);
__m128 mul4 = _mm_mul_ps(add0, N);
__m128 mul5 = _mm_mul_ps(eta, I);
__m128 sub2 = _mm_sub_ps(mul5, mul4);
return sub2;
}

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2009-06-05
// Updated : 2009-06-05
// Licence : This source is under MIT License
// File : glm/core/intrinsic_common.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef GLM_DETAIL_INTRINSIC_MATRIX_INCLUDED
#define GLM_DETAIL_INTRINSIC_MATRIX_INCLUDED
#include "../glm.hpp"
#include <xmmintrin.h>
#include <emmintrin.h>
void _mm_add_ps(__m128 in1[4], __m128 in2[4], __m128 out[4]);
void _mm_sub_ps(__m128 in1[4], __m128 in2[4], __m128 out[4]);
__m128 _mm_mul_ps(__m128 m[4], __m128 v);
__m128 _mm_mul_ps(__m128 v, __m128 m[4]);
void _mm_mul_ps(__m128 const in1[4], __m128 const in2[4], __m128 out[4]);
void _mm_transpose_ps(__m128 const in[4], __m128 out[4]);
void _mm_inverse_ps(__m128 const in[4], __m128 out[4]);
void _mm_rotate_ps(__m128 const in[4], float Angle, float const v[3], __m128 out[4]);
#include "intrinsic_matrix.inl"
#endif//GLM_DETAIL_INTRINSIC_MATRIX_INCLUDED

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2009-06-05
// Updated : 2009-06-05
// Licence : This source is under MIT License
// File : glm/core/intrinsic_common.inl
///////////////////////////////////////////////////////////////////////////////////////////////////
static const __m128 one = _mm_set_ps1(1.0f);
static const __m128 pi = _mm_set_ps1(3.141592653589793238462643383279f);
static const __m128 _m128_rad_ps = _mm_set_ps1(3.141592653589793238462643383279f / 180.f);
static const __m128 _m128_deg_ps = _mm_set_ps1(180.f / 3.141592653589793238462643383279f);
inline void _mm_add_ps(__m128 in1[4], __m128 in2[4], __m128 out[4])
{
{
out[0] = _mm_add_ps(in1[0], in2[0]);
out[1] = _mm_add_ps(in1[1], in2[1]);
out[2] = _mm_add_ps(in1[2], in2[2]);
out[3] = _mm_add_ps(in1[3], in2[3]);
}
}
inline void _mm_sub_ps(__m128 in1[4], __m128 in2[4], __m128 out[4])
{
{
out[0] = _mm_sub_ps(in1[0], in2[0]);
out[1] = _mm_sub_ps(in1[1], in2[1]);
out[2] = _mm_sub_ps(in1[2], in2[2]);
out[3] = _mm_sub_ps(in1[3], in2[3]);
}
}
inline __m128 _mm_mul_ps(__m128 m[4], __m128 v)
{
__m128 v0 = _mm_shuffle_ps(v, v, _MM_SHUFFLE(0, 0, 0, 0));
__m128 v1 = _mm_shuffle_ps(v, v, _MM_SHUFFLE(1, 1, 1, 1));
__m128 v2 = _mm_shuffle_ps(v, v, _MM_SHUFFLE(2, 2, 2, 2));
__m128 v3 = _mm_shuffle_ps(v, v, _MM_SHUFFLE(3, 3, 3, 3));
__m128 m0 = _mm_mul_ps(m[0], v0);
__m128 m1 = _mm_mul_ps(m[1], v1);
__m128 m2 = _mm_mul_ps(m[2], v2);
__m128 m3 = _mm_mul_ps(m[3], v3);
__m128 a0 = _mm_add_ps(m0, m1);
__m128 a1 = _mm_add_ps(m2, m3);
__m128 a2 = _mm_add_ps(a0, a1);
return a2;
}
inline __m128 _mm_mul_ps(__m128 v, __m128 m[4])
{
__m128 i0 = m[0];
__m128 i1 = m[1];
__m128 i2 = m[2];
__m128 i3 = m[3];
__m128 m0 = _mm_mul_ps(v, i0);
__m128 m1 = _mm_mul_ps(v, i1);
__m128 m2 = _mm_mul_ps(v, i2);
__m128 m3 = _mm_mul_ps(v, i3);
__m128 u0 = _mm_unpacklo_ps(m0, m1);
__m128 u1 = _mm_unpackhi_ps(m0, m1);
__m128 a0 = _mm_add_ps(u0, u1);
__m128 u2 = _mm_unpacklo_ps(m2, m3);
__m128 u3 = _mm_unpackhi_ps(m2, m3);
__m128 a1 = _mm_add_ps(u2, u3);
__m128 f0 = _mm_movelh_ps(a0, a1);
__m128 f1 = _mm_movehl_ps(a1, a0);
__m128 f2 = _mm_add_ps(f0, f1);
return f2;
}
inline void _mm_mul_ps(__m128 const in1[4], __m128 const in2[4], __m128 out[4])
{
{
__m128 e0 = _mm_shuffle_ps(in2[0], in2[0], _MM_SHUFFLE(0, 0, 0, 0));
__m128 e1 = _mm_shuffle_ps(in2[0], in2[0], _MM_SHUFFLE(1, 1, 1, 1));
__m128 e2 = _mm_shuffle_ps(in2[0], in2[0], _MM_SHUFFLE(2, 2, 2, 2));
__m128 e3 = _mm_shuffle_ps(in2[0], in2[0], _MM_SHUFFLE(3, 3, 3, 3));
__m128 m0 = _mm_mul_ps(in1[0], e0);
__m128 m1 = _mm_mul_ps(in1[1], e1);
__m128 m2 = _mm_mul_ps(in1[2], e2);
__m128 m3 = _mm_mul_ps(in1[3], e3);
__m128 a0 = _mm_add_ps(m0, m1);
__m128 a1 = _mm_add_ps(m2, m3);
__m128 a2 = _mm_add_ps(a0, a1);
out[0] = a2;
}
{
__m128 e0 = _mm_shuffle_ps(in2[1], in2[1], _MM_SHUFFLE(0, 0, 0, 0));
__m128 e1 = _mm_shuffle_ps(in2[1], in2[1], _MM_SHUFFLE(1, 1, 1, 1));
__m128 e2 = _mm_shuffle_ps(in2[1], in2[1], _MM_SHUFFLE(2, 2, 2, 2));
__m128 e3 = _mm_shuffle_ps(in2[1], in2[1], _MM_SHUFFLE(3, 3, 3, 3));
__m128 m0 = _mm_mul_ps(in1[0], e0);
__m128 m1 = _mm_mul_ps(in1[1], e1);
__m128 m2 = _mm_mul_ps(in1[2], e2);
__m128 m3 = _mm_mul_ps(in1[3], e3);
__m128 a0 = _mm_add_ps(m0, m1);
__m128 a1 = _mm_add_ps(m2, m3);
__m128 a2 = _mm_add_ps(a0, a1);
out[1] = a2;
}
{
__m128 e0 = _mm_shuffle_ps(in2[2], in2[2], _MM_SHUFFLE(0, 0, 0, 0));
__m128 e1 = _mm_shuffle_ps(in2[2], in2[2], _MM_SHUFFLE(1, 1, 1, 1));
__m128 e2 = _mm_shuffle_ps(in2[2], in2[2], _MM_SHUFFLE(2, 2, 2, 2));
__m128 e3 = _mm_shuffle_ps(in2[2], in2[2], _MM_SHUFFLE(3, 3, 3, 3));
__m128 m0 = _mm_mul_ps(in1[0], e0);
__m128 m1 = _mm_mul_ps(in1[1], e1);
__m128 m2 = _mm_mul_ps(in1[2], e2);
__m128 m3 = _mm_mul_ps(in1[3], e3);
__m128 a0 = _mm_add_ps(m0, m1);
__m128 a1 = _mm_add_ps(m2, m3);
__m128 a2 = _mm_add_ps(a0, a1);
out[2] = a2;
}
{
//(__m128&)_mm_shuffle_epi32(__m128i&)in2[0], _MM_SHUFFLE(3, 3, 3, 3))
__m128 e0 = _mm_shuffle_ps(in2[3], in2[3], _MM_SHUFFLE(0, 0, 0, 0));
__m128 e1 = _mm_shuffle_ps(in2[3], in2[3], _MM_SHUFFLE(1, 1, 1, 1));
__m128 e2 = _mm_shuffle_ps(in2[3], in2[3], _MM_SHUFFLE(2, 2, 2, 2));
__m128 e3 = _mm_shuffle_ps(in2[3], in2[3], _MM_SHUFFLE(3, 3, 3, 3));
__m128 m0 = _mm_mul_ps(in1[0], e0);
__m128 m1 = _mm_mul_ps(in1[1], e1);
__m128 m2 = _mm_mul_ps(in1[2], e2);
__m128 m3 = _mm_mul_ps(in1[3], e3);
__m128 a0 = _mm_add_ps(m0, m1);
__m128 a1 = _mm_add_ps(m2, m3);
__m128 a2 = _mm_add_ps(a0, a1);
out[3] = a2;
}
}
inline void _mm_transpose_ps(__m128 const in[4], __m128 out[4])
{
__m128 tmp0 = _mm_shuffle_ps(in[0], in[1], 0x44);
__m128 tmp2 = _mm_shuffle_ps(in[0], in[1], 0xEE);
__m128 tmp1 = _mm_shuffle_ps(in[2], in[3], 0x44);
__m128 tmp3 = _mm_shuffle_ps(in[2], in[3], 0xEE);
out[0] = _mm_shuffle_ps(tmp0, tmp1, 0x88);
out[1] = _mm_shuffle_ps(tmp0, tmp1, 0xDD);
out[2] = _mm_shuffle_ps(tmp2, tmp3, 0x88);
out[3] = _mm_shuffle_ps(tmp2, tmp3, 0xDD);
}
inline void _mm_inverse_ps(__m128 const in[4], __m128 out[4])
{
__m128 Fac0;
{
// valType SubFactor00 = m[2][2] * m[3][3] - m[3][2] * m[2][3];
// valType SubFactor00 = m[2][2] * m[3][3] - m[3][2] * m[2][3];
// valType SubFactor06 = m[1][2] * m[3][3] - m[3][2] * m[1][3];
// valType SubFactor13 = m[1][2] * m[2][3] - m[2][2] * m[1][3];
__m128 Swp0a = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(3, 3, 3, 3));
__m128 Swp0b = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(2, 2, 2, 2));
__m128 Swp00 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(2, 2, 2, 2));
__m128 Swp01 = _mm_shuffle_ps(Swp0a, Swp0a, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp02 = _mm_shuffle_ps(Swp0b, Swp0b, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp03 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(3, 3, 3, 3));
__m128 Mul00 = _mm_mul_ps(Swp00, Swp01);
__m128 Mul01 = _mm_mul_ps(Swp02, Swp03);
Fac0 = _mm_sub_ps(Mul00, Mul01);
bool stop = true;
}
__m128 Fac1;
{
// valType SubFactor01 = m[2][1] * m[3][3] - m[3][1] * m[2][3];
// valType SubFactor01 = m[2][1] * m[3][3] - m[3][1] * m[2][3];
// valType SubFactor07 = m[1][1] * m[3][3] - m[3][1] * m[1][3];
// valType SubFactor14 = m[1][1] * m[2][3] - m[2][1] * m[1][3];
__m128 Swp0a = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(3, 3, 3, 3));
__m128 Swp0b = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(1, 1, 1, 1));
__m128 Swp00 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(1, 1, 1, 1));
__m128 Swp01 = _mm_shuffle_ps(Swp0a, Swp0a, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp02 = _mm_shuffle_ps(Swp0b, Swp0b, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp03 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(3, 3, 3, 3));
__m128 Mul00 = _mm_mul_ps(Swp00, Swp01);
__m128 Mul01 = _mm_mul_ps(Swp02, Swp03);
Fac1 = _mm_sub_ps(Mul00, Mul01);
bool stop = true;
}
__m128 Fac2;
{
// valType SubFactor02 = m[2][1] * m[3][2] - m[3][1] * m[2][2];
// valType SubFactor02 = m[2][1] * m[3][2] - m[3][1] * m[2][2];
// valType SubFactor08 = m[1][1] * m[3][2] - m[3][1] * m[1][2];
// valType SubFactor15 = m[1][1] * m[2][2] - m[2][1] * m[1][2];
__m128 Swp0a = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(2, 2, 2, 2));
__m128 Swp0b = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(1, 1, 1, 1));
__m128 Swp00 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(1, 1, 1, 1));
__m128 Swp01 = _mm_shuffle_ps(Swp0a, Swp0a, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp02 = _mm_shuffle_ps(Swp0b, Swp0b, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp03 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(2, 2, 2, 2));
__m128 Mul00 = _mm_mul_ps(Swp00, Swp01);
__m128 Mul01 = _mm_mul_ps(Swp02, Swp03);
Fac2 = _mm_sub_ps(Mul00, Mul01);
bool stop = true;
}
__m128 Fac3;
{
// valType SubFactor03 = m[2][0] * m[3][3] - m[3][0] * m[2][3];
// valType SubFactor03 = m[2][0] * m[3][3] - m[3][0] * m[2][3];
// valType SubFactor09 = m[1][0] * m[3][3] - m[3][0] * m[1][3];
// valType SubFactor16 = m[1][0] * m[2][3] - m[2][0] * m[1][3];
__m128 Swp0a = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(3, 3, 3, 3));
__m128 Swp0b = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(0, 0, 0, 0));
__m128 Swp00 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(0, 0, 0, 0));
__m128 Swp01 = _mm_shuffle_ps(Swp0a, Swp0a, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp02 = _mm_shuffle_ps(Swp0b, Swp0b, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp03 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(3, 3, 3, 3));
__m128 Mul00 = _mm_mul_ps(Swp00, Swp01);
__m128 Mul01 = _mm_mul_ps(Swp02, Swp03);
Fac3 = _mm_sub_ps(Mul00, Mul01);
bool stop = true;
}
__m128 Fac4;
{
// valType SubFactor04 = m[2][0] * m[3][2] - m[3][0] * m[2][2];
// valType SubFactor04 = m[2][0] * m[3][2] - m[3][0] * m[2][2];
// valType SubFactor10 = m[1][0] * m[3][2] - m[3][0] * m[1][2];
// valType SubFactor17 = m[1][0] * m[2][2] - m[2][0] * m[1][2];
__m128 Swp0a = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(2, 2, 2, 2));
__m128 Swp0b = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(0, 0, 0, 0));
__m128 Swp00 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(0, 0, 0, 0));
__m128 Swp01 = _mm_shuffle_ps(Swp0a, Swp0a, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp02 = _mm_shuffle_ps(Swp0b, Swp0b, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp03 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(2, 2, 2, 2));
__m128 Mul00 = _mm_mul_ps(Swp00, Swp01);
__m128 Mul01 = _mm_mul_ps(Swp02, Swp03);
Fac4 = _mm_sub_ps(Mul00, Mul01);
bool stop = true;
}
__m128 Fac5;
{
// valType SubFactor05 = m[2][0] * m[3][1] - m[3][0] * m[2][1];
// valType SubFactor05 = m[2][0] * m[3][1] - m[3][0] * m[2][1];
// valType SubFactor12 = m[1][0] * m[3][1] - m[3][0] * m[1][1];
// valType SubFactor18 = m[1][0] * m[2][1] - m[2][0] * m[1][1];
__m128 Swp0a = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(1, 1, 1, 1));
__m128 Swp0b = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(0, 0, 0, 0));
__m128 Swp00 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(0, 0, 0, 0));
__m128 Swp01 = _mm_shuffle_ps(Swp0a, Swp0a, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp02 = _mm_shuffle_ps(Swp0b, Swp0b, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp03 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(1, 1, 1, 1));
__m128 Mul00 = _mm_mul_ps(Swp00, Swp01);
__m128 Mul01 = _mm_mul_ps(Swp02, Swp03);
Fac5 = _mm_sub_ps(Mul00, Mul01);
bool stop = true;
}
__m128 SignA = _mm_set_ps( 1.0f,-1.0f, 1.0f,-1.0f);
__m128 SignB = _mm_set_ps(-1.0f, 1.0f,-1.0f, 1.0f);
// m[1][0]
// m[0][0]
// m[0][0]
// m[0][0]
__m128 Temp0 = _mm_shuffle_ps(in[1], in[0], _MM_SHUFFLE(0, 0, 0, 0));
__m128 Vec0 = _mm_shuffle_ps(Temp0, Temp0, _MM_SHUFFLE(2, 2, 2, 0));
// m[1][1]
// m[0][1]
// m[0][1]
// m[0][1]
__m128 Temp1 = _mm_shuffle_ps(in[1], in[0], _MM_SHUFFLE(1, 1, 1, 1));
__m128 Vec1 = _mm_shuffle_ps(Temp1, Temp1, _MM_SHUFFLE(2, 2, 2, 0));
// m[1][2]
// m[0][2]
// m[0][2]
// m[0][2]
__m128 Temp2 = _mm_shuffle_ps(in[1], in[0], _MM_SHUFFLE(2, 2, 2, 2));
__m128 Vec2 = _mm_shuffle_ps(Temp2, Temp2, _MM_SHUFFLE(2, 2, 2, 0));
// m[1][3]
// m[0][3]
// m[0][3]
// m[0][3]
__m128 Temp3 = _mm_shuffle_ps(in[1], in[0], _MM_SHUFFLE(3, 3, 3, 3));
__m128 Vec3 = _mm_shuffle_ps(Temp3, Temp3, _MM_SHUFFLE(2, 2, 2, 0));
// col0
// + (Vec1[0] * Fac0[0] - Vec2[0] * Fac1[0] + Vec3[0] * Fac2[0]),
// - (Vec1[1] * Fac0[1] - Vec2[1] * Fac1[1] + Vec3[1] * Fac2[1]),
// + (Vec1[2] * Fac0[2] - Vec2[2] * Fac1[2] + Vec3[2] * Fac2[2]),
// - (Vec1[3] * Fac0[3] - Vec2[3] * Fac1[3] + Vec3[3] * Fac2[3]),
__m128 Mul00 = _mm_mul_ps(Vec1, Fac0);
__m128 Mul01 = _mm_mul_ps(Vec2, Fac1);
__m128 Mul02 = _mm_mul_ps(Vec3, Fac2);
__m128 Sub00 = _mm_sub_ps(Mul00, Mul01);
__m128 Add00 = _mm_add_ps(Sub00, Mul02);
__m128 Inv0 = _mm_mul_ps(SignB, Add00);
// col1
// - (Vec0[0] * Fac0[0] - Vec2[0] * Fac3[0] + Vec3[0] * Fac4[0]),
// + (Vec0[0] * Fac0[1] - Vec2[1] * Fac3[1] + Vec3[1] * Fac4[1]),
// - (Vec0[0] * Fac0[2] - Vec2[2] * Fac3[2] + Vec3[2] * Fac4[2]),
// + (Vec0[0] * Fac0[3] - Vec2[3] * Fac3[3] + Vec3[3] * Fac4[3]),
__m128 Mul03 = _mm_mul_ps(Vec0, Fac0);
__m128 Mul04 = _mm_mul_ps(Vec2, Fac3);
__m128 Mul05 = _mm_mul_ps(Vec3, Fac4);
__m128 Sub01 = _mm_sub_ps(Mul03, Mul04);
__m128 Add01 = _mm_add_ps(Sub01, Mul05);
__m128 Inv1 = _mm_mul_ps(SignA, Add01);
// col2
// + (Vec0[0] * Fac1[0] - Vec1[0] * Fac3[0] + Vec3[0] * Fac5[0]),
// - (Vec0[0] * Fac1[1] - Vec1[1] * Fac3[1] + Vec3[1] * Fac5[1]),
// + (Vec0[0] * Fac1[2] - Vec1[2] * Fac3[2] + Vec3[2] * Fac5[2]),
// - (Vec0[0] * Fac1[3] - Vec1[3] * Fac3[3] + Vec3[3] * Fac5[3]),
__m128 Mul06 = _mm_mul_ps(Vec0, Fac1);
__m128 Mul07 = _mm_mul_ps(Vec1, Fac3);
__m128 Mul08 = _mm_mul_ps(Vec3, Fac5);
__m128 Sub02 = _mm_sub_ps(Mul06, Mul07);
__m128 Add02 = _mm_add_ps(Sub02, Mul08);
__m128 Inv2 = _mm_mul_ps(SignB, Add02);
// col3
// - (Vec1[0] * Fac2[0] - Vec1[0] * Fac4[0] + Vec2[0] * Fac5[0]),
// + (Vec1[0] * Fac2[1] - Vec1[1] * Fac4[1] + Vec2[1] * Fac5[1]),
// - (Vec1[0] * Fac2[2] - Vec1[2] * Fac4[2] + Vec2[2] * Fac5[2]),
// + (Vec1[0] * Fac2[3] - Vec1[3] * Fac4[3] + Vec2[3] * Fac5[3]));
__m128 Mul09 = _mm_mul_ps(Vec0, Fac2);
__m128 Mul10 = _mm_mul_ps(Vec1, Fac4);
__m128 Mul11 = _mm_mul_ps(Vec2, Fac5);
__m128 Sub03 = _mm_sub_ps(Mul09, Mul10);
__m128 Add03 = _mm_add_ps(Sub03, Mul11);
__m128 Inv3 = _mm_mul_ps(SignA, Add03);
__m128 Row0 = _mm_shuffle_ps(Inv0, Inv1, _MM_SHUFFLE(0, 0, 0, 0));
__m128 Row1 = _mm_shuffle_ps(Inv2, Inv3, _MM_SHUFFLE(0, 0, 0, 0));
__m128 Row2 = _mm_shuffle_ps(Row0, Row1, _MM_SHUFFLE(2, 0, 2, 0));
// valType Determinant = m[0][0] * Inverse[0][0]
// + m[0][1] * Inverse[1][0]
// + m[0][2] * Inverse[2][0]
// + m[0][3] * Inverse[3][0];
__m128 Det0 = _mm_dot_ps(in[0], Row2);
__m128 Rcp0 = _mm_div_ps(one, Det0);
//__m128 Rcp0 = _mm_rcp_ps(Det0);
// Inverse /= Determinant;
out[0] = _mm_mul_ps(Inv0, Rcp0);
out[1] = _mm_mul_ps(Inv1, Rcp0);
out[2] = _mm_mul_ps(Inv2, Rcp0);
out[3] = _mm_mul_ps(Inv3, Rcp0);
}
inline void _mm_inverse_fast_ps(__m128 const in[4], __m128 out[4])
{
__m128 Fac0;
{
// valType SubFactor00 = m[2][2] * m[3][3] - m[3][2] * m[2][3];
// valType SubFactor00 = m[2][2] * m[3][3] - m[3][2] * m[2][3];
// valType SubFactor06 = m[1][2] * m[3][3] - m[3][2] * m[1][3];
// valType SubFactor13 = m[1][2] * m[2][3] - m[2][2] * m[1][3];
__m128 Swp0a = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(3, 3, 3, 3));
__m128 Swp0b = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(2, 2, 2, 2));
__m128 Swp00 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(2, 2, 2, 2));
__m128 Swp01 = _mm_shuffle_ps(Swp0a, Swp0a, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp02 = _mm_shuffle_ps(Swp0b, Swp0b, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp03 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(3, 3, 3, 3));
__m128 Mul00 = _mm_mul_ps(Swp00, Swp01);
__m128 Mul01 = _mm_mul_ps(Swp02, Swp03);
Fac0 = _mm_sub_ps(Mul00, Mul01);
bool stop = true;
}
__m128 Fac1;
{
// valType SubFactor01 = m[2][1] * m[3][3] - m[3][1] * m[2][3];
// valType SubFactor01 = m[2][1] * m[3][3] - m[3][1] * m[2][3];
// valType SubFactor07 = m[1][1] * m[3][3] - m[3][1] * m[1][3];
// valType SubFactor14 = m[1][1] * m[2][3] - m[2][1] * m[1][3];
__m128 Swp0a = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(3, 3, 3, 3));
__m128 Swp0b = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(1, 1, 1, 1));
__m128 Swp00 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(1, 1, 1, 1));
__m128 Swp01 = _mm_shuffle_ps(Swp0a, Swp0a, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp02 = _mm_shuffle_ps(Swp0b, Swp0b, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp03 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(3, 3, 3, 3));
__m128 Mul00 = _mm_mul_ps(Swp00, Swp01);
__m128 Mul01 = _mm_mul_ps(Swp02, Swp03);
Fac1 = _mm_sub_ps(Mul00, Mul01);
bool stop = true;
}
__m128 Fac2;
{
// valType SubFactor02 = m[2][1] * m[3][2] - m[3][1] * m[2][2];
// valType SubFactor02 = m[2][1] * m[3][2] - m[3][1] * m[2][2];
// valType SubFactor08 = m[1][1] * m[3][2] - m[3][1] * m[1][2];
// valType SubFactor15 = m[1][1] * m[2][2] - m[2][1] * m[1][2];
__m128 Swp0a = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(2, 2, 2, 2));
__m128 Swp0b = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(1, 1, 1, 1));
__m128 Swp00 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(1, 1, 1, 1));
__m128 Swp01 = _mm_shuffle_ps(Swp0a, Swp0a, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp02 = _mm_shuffle_ps(Swp0b, Swp0b, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp03 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(2, 2, 2, 2));
__m128 Mul00 = _mm_mul_ps(Swp00, Swp01);
__m128 Mul01 = _mm_mul_ps(Swp02, Swp03);
Fac2 = _mm_sub_ps(Mul00, Mul01);
bool stop = true;
}
__m128 Fac3;
{
// valType SubFactor03 = m[2][0] * m[3][3] - m[3][0] * m[2][3];
// valType SubFactor03 = m[2][0] * m[3][3] - m[3][0] * m[2][3];
// valType SubFactor09 = m[1][0] * m[3][3] - m[3][0] * m[1][3];
// valType SubFactor16 = m[1][0] * m[2][3] - m[2][0] * m[1][3];
__m128 Swp0a = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(3, 3, 3, 3));
__m128 Swp0b = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(0, 0, 0, 0));
__m128 Swp00 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(0, 0, 0, 0));
__m128 Swp01 = _mm_shuffle_ps(Swp0a, Swp0a, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp02 = _mm_shuffle_ps(Swp0b, Swp0b, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp03 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(3, 3, 3, 3));
__m128 Mul00 = _mm_mul_ps(Swp00, Swp01);
__m128 Mul01 = _mm_mul_ps(Swp02, Swp03);
Fac3 = _mm_sub_ps(Mul00, Mul01);
bool stop = true;
}
__m128 Fac4;
{
// valType SubFactor04 = m[2][0] * m[3][2] - m[3][0] * m[2][2];
// valType SubFactor04 = m[2][0] * m[3][2] - m[3][0] * m[2][2];
// valType SubFactor10 = m[1][0] * m[3][2] - m[3][0] * m[1][2];
// valType SubFactor17 = m[1][0] * m[2][2] - m[2][0] * m[1][2];
__m128 Swp0a = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(2, 2, 2, 2));
__m128 Swp0b = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(0, 0, 0, 0));
__m128 Swp00 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(0, 0, 0, 0));
__m128 Swp01 = _mm_shuffle_ps(Swp0a, Swp0a, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp02 = _mm_shuffle_ps(Swp0b, Swp0b, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp03 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(2, 2, 2, 2));
__m128 Mul00 = _mm_mul_ps(Swp00, Swp01);
__m128 Mul01 = _mm_mul_ps(Swp02, Swp03);
Fac4 = _mm_sub_ps(Mul00, Mul01);
bool stop = true;
}
__m128 Fac5;
{
// valType SubFactor05 = m[2][0] * m[3][1] - m[3][0] * m[2][1];
// valType SubFactor05 = m[2][0] * m[3][1] - m[3][0] * m[2][1];
// valType SubFactor12 = m[1][0] * m[3][1] - m[3][0] * m[1][1];
// valType SubFactor18 = m[1][0] * m[2][1] - m[2][0] * m[1][1];
__m128 Swp0a = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(1, 1, 1, 1));
__m128 Swp0b = _mm_shuffle_ps(in[3], in[2], _MM_SHUFFLE(0, 0, 0, 0));
__m128 Swp00 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(0, 0, 0, 0));
__m128 Swp01 = _mm_shuffle_ps(Swp0a, Swp0a, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp02 = _mm_shuffle_ps(Swp0b, Swp0b, _MM_SHUFFLE(2, 0, 0, 0));
__m128 Swp03 = _mm_shuffle_ps(in[2], in[1], _MM_SHUFFLE(1, 1, 1, 1));
__m128 Mul00 = _mm_mul_ps(Swp00, Swp01);
__m128 Mul01 = _mm_mul_ps(Swp02, Swp03);
Fac5 = _mm_sub_ps(Mul00, Mul01);
bool stop = true;
}
__m128 SignA = _mm_set_ps( 1.0f,-1.0f, 1.0f,-1.0f);
__m128 SignB = _mm_set_ps(-1.0f, 1.0f,-1.0f, 1.0f);
// m[1][0]
// m[0][0]
// m[0][0]
// m[0][0]
__m128 Temp0 = _mm_shuffle_ps(in[1], in[0], _MM_SHUFFLE(0, 0, 0, 0));
__m128 Vec0 = _mm_shuffle_ps(Temp0, Temp0, _MM_SHUFFLE(2, 2, 2, 0));
// m[1][1]
// m[0][1]
// m[0][1]
// m[0][1]
__m128 Temp1 = _mm_shuffle_ps(in[1], in[0], _MM_SHUFFLE(1, 1, 1, 1));
__m128 Vec1 = _mm_shuffle_ps(Temp1, Temp1, _MM_SHUFFLE(2, 2, 2, 0));
// m[1][2]
// m[0][2]
// m[0][2]
// m[0][2]
__m128 Temp2 = _mm_shuffle_ps(in[1], in[0], _MM_SHUFFLE(2, 2, 2, 2));
__m128 Vec2 = _mm_shuffle_ps(Temp2, Temp2, _MM_SHUFFLE(2, 2, 2, 0));
// m[1][3]
// m[0][3]
// m[0][3]
// m[0][3]
__m128 Temp3 = _mm_shuffle_ps(in[1], in[0], _MM_SHUFFLE(3, 3, 3, 3));
__m128 Vec3 = _mm_shuffle_ps(Temp3, Temp3, _MM_SHUFFLE(2, 2, 2, 0));
// col0
// + (Vec1[0] * Fac0[0] - Vec2[0] * Fac1[0] + Vec3[0] * Fac2[0]),
// - (Vec1[1] * Fac0[1] - Vec2[1] * Fac1[1] + Vec3[1] * Fac2[1]),
// + (Vec1[2] * Fac0[2] - Vec2[2] * Fac1[2] + Vec3[2] * Fac2[2]),
// - (Vec1[3] * Fac0[3] - Vec2[3] * Fac1[3] + Vec3[3] * Fac2[3]),
__m128 Mul00 = _mm_mul_ps(Vec1, Fac0);
__m128 Mul01 = _mm_mul_ps(Vec2, Fac1);
__m128 Mul02 = _mm_mul_ps(Vec3, Fac2);
__m128 Sub00 = _mm_sub_ps(Mul00, Mul01);
__m128 Add00 = _mm_add_ps(Sub00, Mul02);
__m128 Inv0 = _mm_mul_ps(SignB, Add00);
// col1
// - (Vec0[0] * Fac0[0] - Vec2[0] * Fac3[0] + Vec3[0] * Fac4[0]),
// + (Vec0[0] * Fac0[1] - Vec2[1] * Fac3[1] + Vec3[1] * Fac4[1]),
// - (Vec0[0] * Fac0[2] - Vec2[2] * Fac3[2] + Vec3[2] * Fac4[2]),
// + (Vec0[0] * Fac0[3] - Vec2[3] * Fac3[3] + Vec3[3] * Fac4[3]),
__m128 Mul03 = _mm_mul_ps(Vec0, Fac0);
__m128 Mul04 = _mm_mul_ps(Vec2, Fac3);
__m128 Mul05 = _mm_mul_ps(Vec3, Fac4);
__m128 Sub01 = _mm_sub_ps(Mul03, Mul04);
__m128 Add01 = _mm_add_ps(Sub01, Mul05);
__m128 Inv1 = _mm_mul_ps(SignA, Add01);
// col2
// + (Vec0[0] * Fac1[0] - Vec1[0] * Fac3[0] + Vec3[0] * Fac5[0]),
// - (Vec0[0] * Fac1[1] - Vec1[1] * Fac3[1] + Vec3[1] * Fac5[1]),
// + (Vec0[0] * Fac1[2] - Vec1[2] * Fac3[2] + Vec3[2] * Fac5[2]),
// - (Vec0[0] * Fac1[3] - Vec1[3] * Fac3[3] + Vec3[3] * Fac5[3]),
__m128 Mul06 = _mm_mul_ps(Vec0, Fac1);
__m128 Mul07 = _mm_mul_ps(Vec1, Fac3);
__m128 Mul08 = _mm_mul_ps(Vec3, Fac5);
__m128 Sub02 = _mm_sub_ps(Mul06, Mul07);
__m128 Add02 = _mm_add_ps(Sub02, Mul08);
__m128 Inv2 = _mm_mul_ps(SignB, Add02);
// col3
// - (Vec1[0] * Fac2[0] - Vec1[0] * Fac4[0] + Vec2[0] * Fac5[0]),
// + (Vec1[0] * Fac2[1] - Vec1[1] * Fac4[1] + Vec2[1] * Fac5[1]),
// - (Vec1[0] * Fac2[2] - Vec1[2] * Fac4[2] + Vec2[2] * Fac5[2]),
// + (Vec1[0] * Fac2[3] - Vec1[3] * Fac4[3] + Vec2[3] * Fac5[3]));
__m128 Mul09 = _mm_mul_ps(Vec0, Fac2);
__m128 Mul10 = _mm_mul_ps(Vec1, Fac4);
__m128 Mul11 = _mm_mul_ps(Vec2, Fac5);
__m128 Sub03 = _mm_sub_ps(Mul09, Mul10);
__m128 Add03 = _mm_add_ps(Sub03, Mul11);
__m128 Inv3 = _mm_mul_ps(SignA, Add03);
__m128 Row0 = _mm_shuffle_ps(Inv0, Inv1, _MM_SHUFFLE(0, 0, 0, 0));
__m128 Row1 = _mm_shuffle_ps(Inv2, Inv3, _MM_SHUFFLE(0, 0, 0, 0));
__m128 Row2 = _mm_shuffle_ps(Row0, Row1, _MM_SHUFFLE(2, 0, 2, 0));
// valType Determinant = m[0][0] * Inverse[0][0]
// + m[0][1] * Inverse[1][0]
// + m[0][2] * Inverse[2][0]
// + m[0][3] * Inverse[3][0];
__m128 Det0 = _mm_dot_ps(in[0], Row2);
__m128 Rcp0 = _mm_rcp_ps(Det0);
//__m128 Rcp0 = _mm_div_ps(one, Det0);
// Inverse /= Determinant;
out[0] = _mm_mul_ps(Inv0, Rcp0);
out[1] = _mm_mul_ps(Inv1, Rcp0);
out[2] = _mm_mul_ps(Inv2, Rcp0);
out[3] = _mm_mul_ps(Inv3, Rcp0);
}
void _mm_rotate_ps(__m128 const in[4], float Angle, float const v[3], __m128 out[4])
{
float a = glm::radians(Angle);
float c = cos(a);
float s = sin(a);
glm::vec4 AxisA(v[0], v[1], v[2], float(0));
__m128 AxisB = _mm_set_ps(AxisA.w, AxisA.z, AxisA.y, AxisA.x);
__m128 AxisC = _mm_nrm_ps(AxisB);
__m128 Cos0 = _mm_set_ss(c);
__m128 CosA = _mm_shuffle_ps(Cos0, Cos0, _MM_SHUFFLE(0, 0, 0, 0));
__m128 Sin0 = _mm_set_ss(s);
__m128 SinA = _mm_shuffle_ps(Sin0, Sin0, _MM_SHUFFLE(0, 0, 0, 0));
// detail::tvec3<valType> temp = (valType(1) - c) * axis;
__m128 Temp0 = _mm_sub_ps(one, CosA);
__m128 Temp1 = _mm_mul_ps(Temp0, AxisC);
//Rotate[0][0] = c + temp[0] * axis[0];
//Rotate[0][1] = 0 + temp[0] * axis[1] + s * axis[2];
//Rotate[0][2] = 0 + temp[0] * axis[2] - s * axis[1];
__m128 Axis0 = _mm_shuffle_ps(AxisC, AxisC, _MM_SHUFFLE(0, 0, 0, 0));
__m128 TmpA0 = _mm_mul_ps(Axis0, AxisC);
__m128 CosA0 = _mm_shuffle_ps(Cos0, Cos0, _MM_SHUFFLE(1, 1, 1, 0));
__m128 TmpA1 = _mm_add_ps(CosA0, TmpA0);
__m128 SinA0 = SinA;//_mm_set_ps(0.0f, s, -s, 0.0f);
__m128 TmpA2 = _mm_shuffle_ps(AxisC, AxisC, _MM_SHUFFLE(3, 1, 2, 3));
__m128 TmpA3 = _mm_mul_ps(SinA0, TmpA2);
__m128 TmpA4 = _mm_add_ps(TmpA1, TmpA3);
//Rotate[1][0] = 0 + temp[1] * axis[0] - s * axis[2];
//Rotate[1][1] = c + temp[1] * axis[1];
//Rotate[1][2] = 0 + temp[1] * axis[2] + s * axis[0];
__m128 Axis1 = _mm_shuffle_ps(AxisC, AxisC, _MM_SHUFFLE(1, 1, 1, 1));
__m128 TmpB0 = _mm_mul_ps(Axis1, AxisC);
__m128 CosA1 = _mm_shuffle_ps(Cos0, Cos0, _MM_SHUFFLE(1, 1, 0, 1));
__m128 TmpB1 = _mm_add_ps(CosA1, TmpB0);
__m128 SinB0 = SinA;//_mm_set_ps(-s, 0.0f, s, 0.0f);
__m128 TmpB2 = _mm_shuffle_ps(AxisC, AxisC, _MM_SHUFFLE(3, 0, 3, 2));
__m128 TmpB3 = _mm_mul_ps(SinA0, TmpB2);
__m128 TmpB4 = _mm_add_ps(TmpB1, TmpB3);
//Rotate[2][0] = 0 + temp[2] * axis[0] + s * axis[1];
//Rotate[2][1] = 0 + temp[2] * axis[1] - s * axis[0];
//Rotate[2][2] = c + temp[2] * axis[2];
__m128 Axis2 = _mm_shuffle_ps(AxisC, AxisC, _MM_SHUFFLE(2, 2, 2, 2));
__m128 TmpC0 = _mm_mul_ps(Axis2, AxisC);
__m128 CosA2 = _mm_shuffle_ps(Cos0, Cos0, _MM_SHUFFLE(1, 0, 1, 1));
__m128 TmpC1 = _mm_add_ps(CosA2, TmpC0);
__m128 SinC0 = SinA;//_mm_set_ps(s, -s, 0.0f, 0.0f);
__m128 TmpC2 = _mm_shuffle_ps(AxisC, AxisC, _MM_SHUFFLE(3, 3, 0, 1));
__m128 TmpC3 = _mm_mul_ps(SinA0, TmpC2);
__m128 TmpC4 = _mm_add_ps(TmpC1, TmpC3);
__m128 Result[4];
Result[0] = TmpA4;
Result[1] = TmpB4;
Result[2] = TmpC4;
Result[2] = _mm_set_ps(1, 0, 0, 0);
//detail::tmat4x4<valType> Result(detail::tmat4x4<valType>::null);
//Result[0] = m[0] * Rotate[0][0] + m[1] * Rotate[0][1] + m[2] * Rotate[0][2];
//Result[1] = m[0] * Rotate[1][0] + m[1] * Rotate[1][1] + m[2] * Rotate[1][2];
//Result[2] = m[0] * Rotate[2][0] + m[1] * Rotate[2][1] + m[2] * Rotate[2][2];
//Result[3] = m[3];
//return Result;
_mm_mul_ps(in, Result, out);
}

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2009-06-09
// Updated : 2009-06-09
// Licence : This source is under MIT License
// File : glm/core/intrinsic_vector_relational.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef GLM_DETAIL_INTRINSIC_VECTOR_RELATIONAL_INCLUDED
#define GLM_DETAIL_INTRINSIC_VECTOR_RELATIONAL_INCLUDED
#include <xmmintrin.h>
#include <emmintrin.h>
#include "intrinsic_vector_relational.inl"
#endif//GLM_DETAIL_INTRINSIC_VECTOR_RELATIONAL_INCLUDED

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2009-06-09
// Updated : 2009-06-09
// Licence : This source is under MIT License
// File : glm/core/intrinsic_vector_relational.inl
///////////////////////////////////////////////////////////////////////////////////////////////////
//
//// lessThan
//template <typename valType>
//inline typename detail::tvec2<valType>::bool_type lessThan
//(
// detail::tvec2<valType> const & x,
// detail::tvec2<valType> const & y
//)
//{
// GLM_STATIC_ASSERT(
// detail::type<valType>::is_float ||
// detail::type<valType>::is_int ||
// detail::type<valType>::is_uint);
//
// return typename detail::tvec2<bool>::bool_type(x.x < y.x, x.y < y.y);
//}
//
//template <typename valType>
//inline typename detail::tvec3<valType>::bool_type lessThan
//(
// detail::tvec3<valType> const & x,
// detail::tvec3<valType> const & y
//)
//{
// GLM_STATIC_ASSERT(
// detail::type<valType>::is_float ||
// detail::type<valType>::is_int ||
// detail::type<valType>::is_uint);
//
// return typename detail::tvec3<bool>::bool_type(x.x < y.x, x.y < y.y, x.z < y.z);
//}
//
//template <typename valType>
//inline typename detail::tvec4<valType>::bool_type lessThan
//(
// detail::tvec4<valType> const & x,
// detail::tvec4<valType> const & y
//)
//{
// GLM_STATIC_ASSERT(
// detail::type<valType>::is_float ||
// detail::type<valType>::is_int ||
// detail::type<valType>::is_uint);
//
// return typename detail::tvec4<bool>::bool_type(x.x < y.x, x.y < y.y, x.z < y.z, x.w < y.w);
//}
//
//// lessThanEqual
//template <typename valType>
//inline typename detail::tvec2<valType>::bool_type lessThanEqual
//(
// detail::tvec2<valType> const & x,
// detail::tvec2<valType> const & y
//)
//{
// GLM_STATIC_ASSERT(
// detail::type<valType>::is_float ||
// detail::type<valType>::is_int ||
// detail::type<valType>::is_uint);
//
// return typename detail::tvec2<bool>::bool_type(x.x <= y.x, x.y <= y.y);
//}
//
//template <typename valType>
//inline typename detail::tvec3<valType>::bool_type lessThanEqual
//(
// detail::tvec3<valType> const & x,
// detail::tvec3<valType> const & y
//)
//{
// GLM_STATIC_ASSERT(
// detail::type<valType>::is_float ||
// detail::type<valType>::is_int ||
// detail::type<valType>::is_uint);
//
// return typename detail::tvec3<bool>::bool_type(x.x <= y.x, x.y <= y.y, x.z <= y.z);
//}
//
//template <typename valType>
//inline typename detail::tvec4<valType>::bool_type lessThanEqual
//(
// detail::tvec4<valType> const & x,
// detail::tvec4<valType> const & y
//)
//{
// GLM_STATIC_ASSERT(
// detail::type<valType>::is_float ||
// detail::type<valType>::is_int ||
// detail::type<valType>::is_uint);
//
// return typename detail::tvec4<bool>::bool_type(x.x <= y.x, x.y <= y.y, x.z <= y.z, x.w <= y.w);
//}
//
//// greaterThan
//template <typename valType>
//inline typename detail::tvec2<valType>::bool_type greaterThan
//(
// detail::tvec2<valType> const & x,
// detail::tvec2<valType> const & y
//)
//{
// GLM_STATIC_ASSERT(
// detail::type<valType>::is_float ||
// detail::type<valType>::is_int ||
// detail::type<valType>::is_uint);
//
// return typename detail::tvec2<bool>::bool_type(x.x > y.x, x.y > y.y);
//}
//
//template <typename valType>
//inline typename detail::tvec3<valType>::bool_type greaterThan
//(
// detail::tvec3<valType> const & x,
// detail::tvec3<valType> const & y
//)
//{
// GLM_STATIC_ASSERT(
// detail::type<valType>::is_float ||
// detail::type<valType>::is_int ||
// detail::type<valType>::is_uint);
//
// return typename detail::tvec3<bool>::bool_type(x.x > y.x, x.y > y.y, x.z > y.z);
//}
//
//template <typename valType>
//inline typename detail::tvec4<valType>::bool_type greaterThan
//(
// detail::tvec4<valType> const & x,
// detail::tvec4<valType> const & y
//)
//{
// GLM_STATIC_ASSERT(
// detail::type<valType>::is_float ||
// detail::type<valType>::is_int ||
// detail::type<valType>::is_uint);
//
// return typename detail::tvec4<bool>::bool_type(x.x > y.x, x.y > y.y, x.z > y.z, x.w > y.w);
//}
//
//// greaterThanEqual
//template <typename valType>
//inline typename detail::tvec2<valType>::bool_type greaterThanEqual
//(
// detail::tvec2<valType> const & x,
// detail::tvec2<valType> const & y
//)
//{
// GLM_STATIC_ASSERT(
// detail::type<valType>::is_float ||
// detail::type<valType>::is_int ||
// detail::type<valType>::is_uint);
//
// return typename detail::tvec2<bool>::bool_type(x.x >= y.x, x.y >= y.y);
//}
//
//template <typename valType>
//inline typename detail::tvec3<valType>::bool_type greaterThanEqual
//(
// detail::tvec3<valType> const & x,
// detail::tvec3<valType> const & y
//)
//{
// GLM_STATIC_ASSERT(
// detail::type<valType>::is_float ||
// detail::type<valType>::is_int ||
// detail::type<valType>::is_uint);
//
// return typename detail::tvec3<bool>::bool_type(x.x >= y.x, x.y >= y.y, x.z >= y.z);
//}
//
//template <typename valType>
//inline typename detail::tvec4<valType>::bool_type greaterThanEqual
//(
// detail::tvec4<valType> const & x,
// detail::tvec4<valType> const & y
//)
//{
// GLM_STATIC_ASSERT(
// detail::type<valType>::is_float ||
// detail::type<valType>::is_int ||
// detail::type<valType>::is_uint);
//
// return typename detail::tvec4<bool>::bool_type(x.x >= y.x, x.y >= y.y, x.z >= y.z, x.w >= y.w);
//}
//
//// equal
//template <typename valType>
//inline typename detail::tvec2<valType>::bool_type equal
//(
// detail::tvec2<valType> const & x,
// detail::tvec2<valType> const & y
//)
//{
// GLM_STATIC_ASSERT(
// detail::type<valType>::is_float ||
// detail::type<valType>::is_int ||
// detail::type<valType>::is_uint ||
// detail::type<valType>::is_bool);
//
// return typename detail::tvec2<valType>::bool_type(x.x == y.x, x.y == y.y);
//}
//
//template <typename valType>
//inline typename detail::tvec3<valType>::bool_type equal
//(
// detail::tvec3<valType> const & x,
// detail::tvec3<valType> const & y
//)
//{
// GLM_STATIC_ASSERT(
// detail::type<valType>::is_float ||
// detail::type<valType>::is_int ||
// detail::type<valType>::is_uint ||
// detail::type<valType>::is_bool);
//
// return typename detail::tvec3<valType>::bool_type(x.x == y.x, x.y == y.y, x.z == y.z);
//}
//
//template <typename valType>
//inline typename detail::tvec4<valType>::bool_type equal
//(
// detail::tvec4<valType> const & x,
// detail::tvec4<valType> const & y
//)
//{
// GLM_STATIC_ASSERT(
// detail::type<valType>::is_float ||
// detail::type<valType>::is_int ||
// detail::type<valType>::is_uint ||
// detail::type<valType>::is_bool);
//
// return typename detail::tvec4<valType>::bool_type(x.x == y.x, x.y == y.y, x.z == y.z, x.w == y.w);
//}
//
//// notEqual
//template <typename valType>
//inline typename detail::tvec2<valType>::bool_type notEqual
//(
// detail::tvec2<valType> const & x,
// detail::tvec2<valType> const & y
//)
//{
// GLM_STATIC_ASSERT(
// detail::type<valType>::is_float ||
// detail::type<valType>::is_int ||
// detail::type<valType>::is_uint ||
// detail::type<valType>::is_bool);
//
// return typename detail::tvec2<valType>::bool_type(x.x != y.x, x.y != y.y);
//}
//
//template <typename valType>
//inline typename detail::tvec3<valType>::bool_type notEqual
//(
// detail::tvec3<valType> const & x,
// detail::tvec3<valType> const & y
//)
//{
// GLM_STATIC_ASSERT(
// detail::type<valType>::is_float ||
// detail::type<valType>::is_int ||
// detail::type<valType>::is_uint ||
// detail::type<valType>::is_bool);
//
// return typename detail::tvec3<valType>::bool_type(x.x != y.x, x.y != y.y, x.z != y.z);
//}
//
//template <typename valType>
//inline typename detail::tvec4<valType>::bool_type notEqual
//(
// detail::tvec4<valType> const & x,
// detail::tvec4<valType> const & y
//)
//{
// GLM_STATIC_ASSERT(
// detail::type<valType>::is_float ||
// detail::type<valType>::is_int ||
// detail::type<valType>::is_uint ||
// detail::type<valType>::is_bool);
//
// return typename detail::tvec4<valType>::bool_type(x.x != y.x, x.y != y.y, x.z != y.z, x.w != y.w);
//}
//
//// any
//inline bool any(detail::tvec2<bool> const & x)
//{
// return x.x || x.y;
//}
//
//inline bool any(detail::tvec3<bool> const & x)
//{
// return x.x || x.y || x.z;
//}
//
//inline bool any(detail::tvec4<bool> const & x)
//{
// return x.x || x.y || x.z || x.w;
//}
//
//// all
//inline bool all(const detail::tvec2<bool>& x)
//{
// return x.x && x.y;
//}
//
//inline bool all(const detail::tvec3<bool>& x)
//{
// return x.x && x.y && x.z;
//}
//
//inline bool all(const detail::tvec4<bool>& x)
//{
// return x.x && x.y && x.z && x.w;
//}
//
//// not
//inline detail::tvec2<bool>::bool_type not_
//(
// detail::tvec2<bool> const & v
//)
//{
// return detail::tvec2<bool>::bool_type(!v.x, !v.y);
//}
//
//inline detail::tvec3<bool>::bool_type not_
//(
// detail::tvec3<bool> const & v
//)
//{
// return detail::tvec3<bool>::bool_type(!v.x, !v.y, !v.z);
//}
//
//inline detail::tvec4<bool>::bool_type not_
//(
// detail::tvec4<bool> const & v
//)
//{
// return detail::tvec4<bool>::bool_type(!v.x, !v.y, !v.z, !v.w);
//}

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-01-08
// Updated : 2008-01-08
// Licence : This source is under MIT License
// File : glm/core/type.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef glm_core_type
#define glm_core_type
#include "type_half.hpp"
#include "type_float.hpp"
#include "type_int.hpp"
#include "type_gentype.hpp"
#include "type_vec1.hpp"
#include "type_vec2.hpp"
#include "type_vec3.hpp"
#include "type_vec4.hpp"
#include "type_mat2x2.hpp"
#include "type_mat2x3.hpp"
#include "type_mat2x4.hpp"
#include "type_mat3x2.hpp"
#include "type_mat3x3.hpp"
#include "type_mat3x4.hpp"
#include "type_mat4x2.hpp"
#include "type_mat4x3.hpp"
#include "type_mat4x4.hpp"
namespace glm{
namespace core{
namespace type
{
//////////////////////////
// Float definition
#if(defined(GLM_PRECISION) && GLM_PRECISION & GLM_PRECISION_HIGHP_FLOAT)
typedef precision::highp_vec2 vec2;
typedef precision::highp_vec3 vec3;
typedef precision::highp_vec4 vec4;
typedef precision::highp_mat2x2 mat2x2;
typedef precision::highp_mat2x3 mat2x3;
typedef precision::highp_mat2x4 mat2x4;
typedef precision::highp_mat3x2 mat3x2;
typedef precision::highp_mat3x3 mat3x3;
typedef precision::highp_mat3x4 mat3x4;
typedef precision::highp_mat4x2 mat4x2;
typedef precision::highp_mat4x3 mat4x3;
typedef precision::highp_mat4x4 mat4x4;
#elif(defined(GLM_PRECISION) && GLM_PRECISION & GLM_PRECISION_MEDIUMP_FLOAT)
typedef precision::mediump_vec2 vec2;
typedef precision::mediump_vec3 vec3;
typedef precision::mediump_vec4 vec4;
typedef precision::mediump_mat2x2 mat2x2;
typedef precision::mediump_mat2x3 mat2x3;
typedef precision::mediump_mat2x4 mat2x4;
typedef precision::mediump_mat3x2 mat3x2;
typedef precision::mediump_mat3x3 mat3x3;
typedef precision::mediump_mat3x4 mat3x4;
typedef precision::mediump_mat4x2 mat4x2;
typedef precision::mediump_mat4x3 mat4x3;
typedef precision::mediump_mat4x4 mat4x4;
#elif(defined(GLM_PRECISION) && GLM_PRECISION & GLM_PRECISION_LOWP_FLOAT)
typedef precision::lowp_vec2 vec2;
typedef precision::lowp_vec3 vec3;
typedef precision::lowp_vec4 vec4;
typedef precision::lowp_mat2x2 mat2x2;
typedef precision::lowp_mat2x3 mat2x3;
typedef precision::lowp_mat2x4 mat2x4;
typedef precision::lowp_mat3x2 mat3x2;
typedef precision::lowp_mat3x3 mat3x3;
typedef precision::lowp_mat3x4 mat3x4;
typedef precision::lowp_mat4x2 mat4x2;
typedef precision::lowp_mat4x3 mat4x3;
typedef precision::lowp_mat4x4 mat4x4;
#else
//! 2 components vector of floating-point numbers.
//! From GLSL 1.30.8 specification, section 4.1.5 Vectors.
typedef precision::mediump_vec2 vec2;
//! 3 components vector of floating-point numbers.
//! From GLSL 1.30.8 specification, section 4.1.5 Vectors.
typedef precision::mediump_vec3 vec3;
//! 4 components vector of floating-point numbers.
//! From GLSL 1.30.8 specification, section 4.1.5 Vectors.
typedef precision::mediump_vec4 vec4;
//! 2 columns of 2 components matrix of floating-point numbers.
//! (From GLSL 1.30.8 specification, section 4.1.6 Matrices)
typedef precision::mediump_mat2x2 mat2x2;
//! 2 columns of 3 components matrix of floating-point numbers.
//! (From GLSL 1.30.8 specification, section 4.1.6 Matrices)
typedef precision::mediump_mat2x3 mat2x3;
//! 2 columns of 4 components matrix of floating-point numbers.
//! (From GLSL 1.30.8 specification, section 4.1.6 Matrices)
typedef precision::mediump_mat2x4 mat2x4;
//! 3 columns of 2 components matrix of floating-point numbers.
//! (From GLSL 1.30.8 specification, section 4.1.6 Matrices)
typedef precision::mediump_mat3x2 mat3x2;
//! 3 columns of 3 components matrix of floating-point numbers.
//! (From GLSL 1.30.8 specification, section 4.1.6 Matrices)
typedef precision::mediump_mat3x3 mat3x3;
//! 3 columns of 4 components matrix of floating-point numbers.
//! (From GLSL 1.30.8 specification, section 4.1.6 Matrices)
typedef precision::mediump_mat3x4 mat3x4;
//! 4 columns of 2 components matrix of floating-point numbers.
//! (From GLSL 1.30.8 specification, section 4.1.6 Matrices)
typedef precision::mediump_mat4x2 mat4x2;
//! 4 columns of 3 components matrix of floating-point numbers.
//! (From GLSL 1.30.8 specification, section 4.1.6 Matrices)
typedef precision::mediump_mat4x3 mat4x3;
//! 4 columns of 4 components matrix of floating-point numbers.
//! (From GLSL 1.30.8 specification, section 4.1.6 Matrices)
typedef precision::mediump_mat4x4 mat4x4;
#endif//GLM_PRECISION
//! 2 columns of 2 components matrix of floating-point numbers.
//! (From GLSL 1.30.8 specification, section 4.1.6 Matrices)
typedef mat2x2 mat2;
//! 3 columns of 3 components matrix of floating-point numbers.
//! (From GLSL 1.30.8 specification, section 4.1.6 Matrices)
typedef mat3x3 mat3;
//! 4 columns of 4 components matrix of floating-point numbers.
//! (From GLSL 1.30.8 specification, section 4.1.6 Matrices)
typedef mat4x4 mat4;
//////////////////////////
// Signed integer definition
#if(defined(GLM_PRECISION) && GLM_PRECISION & GLM_PRECISION_HIGHP_INT)
typedef precision::highp_ivec2 ivec2;
typedef precision::highp_ivec3 ivec3;
typedef precision::highp_ivec4 ivec4;
#elif(defined(GLM_PRECISION) && GLM_PRECISION & GLM_PRECISION_MEDIUMP_INT)
typedef precision::mediump_ivec2 ivec2;
typedef precision::mediump_ivec3 ivec3;
typedef precision::mediump_ivec4 ivec4;
#elif(defined(GLM_PRECISION) && GLM_PRECISION & GLM_PRECISION_LOWP_INT)
typedef precision::lowp_ivec2 ivec2;
typedef precision::lowp_ivec3 ivec3;
typedef precision::lowp_ivec4 ivec4;
#else
//! 2 components vector of signed integer numbers.
//! From GLSL 1.30.8 specification, section 4.1.5 Vectors.
typedef precision::mediump_ivec2 ivec2;
//! 3 components vector of signed integer numbers.
//! From GLSL 1.30.8 specification, section 4.1.5 Vectors.
typedef precision::mediump_ivec3 ivec3;
//! 4 components vector of signed integer numbers.
//! From GLSL 1.30.8 specification, section 4.1.5 Vectors.
typedef precision::mediump_ivec4 ivec4;
#endif//GLM_PRECISION
//////////////////////////
// Unsigned integer definition
#if(defined(GLM_PRECISION) && GLM_PRECISION & GLM_PRECISION_HIGHP_UINT)
typedef precision::highp_uvec2 uvec2;
typedef precision::highp_uvec3 uvec3;
typedef precision::highp_uvec4 uvec4;
#elif(defined(GLM_PRECISION) && GLM_PRECISION & GLM_PRECISION_MEDIUMP_UINT)
typedef precision::mediump_uvec2 uvec2;
typedef precision::mediump_uvec3 uvec3;
typedef precision::mediump_uvec4 uvec4;
#elif(defined(GLM_PRECISION) && GLM_PRECISION & GLM_PRECISION_LOWP_UINT)
typedef precision::lowp_uvec2 uvec2;
typedef precision::lowp_uvec3 uvec3;
typedef precision::lowp_uvec4 uvec4;
#else
//! 2 components vector of unsigned integer numbers.
//! From GLSL 1.30.8 specification, section 4.1.5 Vectors.
typedef precision::mediump_uvec2 uvec2;
//! 3 components vector of unsigned integer numbers.
//! From GLSL 1.30.8 specification, section 4.1.5 Vectors.
typedef precision::mediump_uvec3 uvec3;
//! 4 components vector of unsigned integer numbers.
//! From GLSL 1.30.8 specification, section 4.1.5 Vectors.
typedef precision::mediump_uvec4 uvec4;
#endif//GLM_PRECISION
//////////////////////////
// Boolean definition
//! 2 components vector of boolean.
//! From GLSL 1.30.8 specification, section 4.1.5 Vectors.
typedef detail::tvec2<bool> bvec2;
//! 3 components vector of boolean.
//! From GLSL 1.30.8 specification, section 4.1.5 Vectors.
typedef detail::tvec3<bool> bvec3;
//! 4 components vector of boolean.
//! From GLSL 1.30.8 specification, section 4.1.5 Vectors.
typedef detail::tvec4<bool> bvec4;
//////////////////////////
// Double definition
//! Vector of 2 double-precision floating-point numbers.
//! From GLSL 4.00.8 specification, section 4.1 Basic Types.
typedef detail::tvec2<double> dvec2;
//! Vector of 3 double-precision floating-point numbers.
//! From GLSL 4.00.8 specification, section 4.1 Basic Types.
typedef detail::tvec3<double> dvec3;
//! Vector of 4 double-precision floating-point numbers.
//! From GLSL 4.00.8 specification, section 4.1 Basic Types.
typedef detail::tvec4<double> dvec4;
//! 2 * 2 matrix of double-precision floating-point numbers.
//! From GLSL 4.00.8 specification, section 4.1 Basic Types.
typedef detail::tmat2x2<double> dmat2;
//! 3 * 3 matrix of double-precision floating-point numbers.
//! From GLSL 4.00.8 specification, section 4.1 Basic Types.
typedef detail::tmat3x3<double> dmat3;
//! 4 * 4 matrix of double-precision floating-point numbers.
//! From GLSL 4.00.8 specification, section 4.1 Basic Types.
typedef detail::tmat4x4<double> dmat4;
//! 2 * 2 matrix of double-precision floating-point numbers.
//! From GLSL 4.00.8 specification, section 4.1 Basic Types.
typedef detail::tmat2x2<double> dmat2x2;
//! 2 * 3 matrix of double-precision floating-point numbers.
//! From GLSL 4.00.8 specification, section 4.1 Basic Types.
typedef detail::tmat2x3<double> dmat2x3;
//! 2 * 4 matrix of double-precision floating-point numbers.
//! From GLSL 4.00.8 specification, section 4.1 Basic Types.
typedef detail::tmat2x4<double> dmat2x4;
//! 3 * 2 matrix of double-precision floating-point numbers.
//! From GLSL 4.00.8 specification, section 4.1 Basic Types.
typedef detail::tmat3x2<double> dmat3x2;
//! 3 * 3 matrix of double-precision floating-point numbers.
//! From GLSL 4.00.8 specification, section 4.1 Basic Types.
typedef detail::tmat3x3<double> dmat3x3;
//! 3 * 4 matrix of double-precision floating-point numbers.
//! From GLSL 4.00.8 specification, section 4.1 Basic Types.
typedef detail::tmat3x4<double> dmat3x4;
//! 4 * 2 matrix of double-precision floating-point numbers.
//! From GLSL 4.00.8 specification, section 4.1 Basic Types.
typedef detail::tmat4x2<double> dmat4x2;
//! 4 * 3 matrix of double-precision floating-point numbers.
//! From GLSL 4.00.8 specification, section 4.1 Basic Types.
typedef detail::tmat4x3<double> dmat4x3;
//! 4 * 4 matrix of double-precision floating-point numbers.
//! From GLSL 4.00.8 specification, section 4.1 Basic Types.
typedef detail::tmat4x4<double> dmat4x4;
}//namespace type
}//namespace core
}//namespace glm
#endif//glm_core_type

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-08-22
// Updated : 2010-02-08
// Licence : This source is under MIT License
// File : glm/core/type_float.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef glm_core_type_float
#define glm_core_type_float
#include "type_half.hpp"
#include "../setup.hpp"
namespace glm
{
namespace detail
{
GLM_DETAIL_IS_FLOAT(detail::thalf);
GLM_DETAIL_IS_FLOAT(float);
GLM_DETAIL_IS_FLOAT(double);
GLM_DETAIL_IS_FLOAT(long double);
}
//namespace detail
namespace core{
namespace type{
namespace precision
{
#ifdef GLM_USE_HALF_SCALAR
typedef detail::thalf lowp_float_t;
#else//GLM_USE_HALF_SCALAR
typedef float lowp_float_t;
#endif//GLM_USE_HALF_SCALAR
typedef float mediump_float_t;
typedef double highp_float_t;
//! Low precision floating-point numbers.
//! There is no garanty on the actual precision.
//! From GLSL 1.30.8 specification
typedef lowp_float_t lowp_float;
//! Medium precision floating-point numbers.
//! There is no garanty on the actual precision.
//! From GLSL 1.30.8 specification
typedef mediump_float_t mediump_float;
//! High precision floating-point numbers.
//! There is no garanty on the actual precision.
//! From GLSL 1.30.8 specification
typedef highp_float_t highp_float;
}
//namespace precision
#ifndef GLM_PRECISION
typedef precision::mediump_float float_t;
#elif(GLM_PRECISION & GLM_PRECISION_HIGHP_FLOAT)
typedef precision::highp_float float_t;
#elif(GLM_PRECISION & GLM_PRECISION_MEDIUMP_FLOAT)
typedef precision::mediump_float float_t;
#elif(GLM_PRECISION & GLM_PRECISION_LOWP_FLOAT)
typedef precision::lowp_float float_t;
#else
# pragma message("GLM message: Precisson undefined for float numbers.");
typedef precision::mediump_float float_t;
#endif//GLM_PRECISION
}//namespace type
}//namespace core
}//namespace glm
#endif//glm_core_type_float

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-10-05
// Updated : 2010-01-26
// Licence : This source is under MIT License
// File : glm/core/type_gentype.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef glm_core_type_gentype
#define glm_core_type_gentype
#include "type_size.hpp"
namespace glm
{
enum profile
{
nice,
fast,
simd
};
namespace detail
{
template
<
typename VALTYPE,
template <typename> class TYPE
>
struct genType
{
public:
enum ctor{null};
typedef VALTYPE value_type;
typedef VALTYPE & value_reference;
typedef VALTYPE * value_pointer;
typedef VALTYPE const * value_const_pointer;
typedef TYPE<bool> bool_type;
typedef sizeType size_type;
static bool is_vector();
static bool is_matrix();
typedef TYPE<VALTYPE> type;
typedef TYPE<VALTYPE> * pointer;
typedef TYPE<VALTYPE> const * const_pointer;
typedef TYPE<VALTYPE> const * const const_pointer_const;
typedef TYPE<VALTYPE> * const pointer_const;
typedef TYPE<VALTYPE> & reference;
typedef TYPE<VALTYPE> const & const_reference;
typedef TYPE<VALTYPE> const & param_type;
//////////////////////////////////////
// Address (Implementation details)
value_const_pointer value_address() const{return value_pointer(this);}
value_pointer value_address(){return value_pointer(this);}
//protected:
// enum kind
// {
// GEN_TYPE,
// VEC_TYPE,
// MAT_TYPE
// };
// typedef typename TYPE::kind kind;
};
template
<
typename VALTYPE,
template <typename> class TYPE
>
bool genType<VALTYPE, TYPE>::is_vector()
{
return true;
}
/*
template <typename valTypeT, unsigned int colT, unsigned int rowT, profile proT = nice>
class base
{
public:
//////////////////////////////////////
// Traits
typedef sizeType size_type;
typedef valTypeT value_type;
typedef base<value_type, colT, rowT> class_type;
typedef base<bool, colT, rowT> bool_type;
typedef base<value_type, rowT, 1> col_type;
typedef base<value_type, colT, 1> row_type;
typedef base<value_type, rowT, colT> transpose_type;
static size_type col_size();
static size_type row_size();
static size_type value_size();
static bool is_scalar();
static bool is_vector();
static bool is_matrix();
private:
// Data
col_type value[colT];
public:
//////////////////////////////////////
// Constructors
base();
base(class_type const & m);
explicit base(value_type const & x);
explicit base(value_type const * const x);
explicit base(col_type const * const x);
//////////////////////////////////////
// Conversions
template <typename vU, uint cU, uint rU, profile pU>
explicit base(base<vU, cU, rU, pU> const & m);
//////////////////////////////////////
// Accesses
col_type& operator[](size_type i);
col_type const & operator[](size_type i) const;
//////////////////////////////////////
// Unary updatable operators
class_type& operator= (class_type const & x);
class_type& operator+= (value_type const & x);
class_type& operator+= (class_type const & x);
class_type& operator-= (value_type const & x);
class_type& operator-= (class_type const & x);
class_type& operator*= (value_type const & x);
class_type& operator*= (class_type const & x);
class_type& operator/= (value_type const & x);
class_type& operator/= (class_type const & x);
class_type& operator++ ();
class_type& operator-- ();
};
*/
}//namespace detail
}//namespace glm
//#include "type_gentype.inl"
#endif//glm_core_type_gentype

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-10-05
// Updated : 2008-10-05
// Licence : This source is under MIT License
// File : glm/core/type_gentype.inl
///////////////////////////////////////////////////////////////////////////////////////////////////
namespace glm{
namespace detail{
/////////////////////////////////
// Static functions
template <typename vT, uint cT, uint rT, profile pT>
typename base<vT, cT, rT, pT>::size_type base<vT, cT, rT, pT>::col_size()
{
return cT;
}
template <typename vT, uint cT, uint rT, profile pT>
typename base<vT, cT, rT, pT>::size_type base<vT, cT, rT, pT>::row_size()
{
return rT;
}
template <typename vT, uint cT, uint rT, profile pT>
typename base<vT, cT, rT, pT>::size_type base<vT, cT, rT, pT>::value_size()
{
return rT * cT;
}
template <typename vT, uint cT, uint rT, profile pT>
bool base<vT, cT, rT, pT>::is_scalar()
{
return rT == 1 && cT == 1;
}
template <typename vT, uint cT, uint rT, profile pT>
bool base<vT, cT, rT, pT>::is_vector()
{
return rT == 1;
}
template <typename vT, uint cT, uint rT, profile pT>
bool base<vT, cT, rT, pT>::is_matrix()
{
return rT != 1;
}
/////////////////////////////////
// Constructor
template <typename vT, uint cT, uint rT, profile pT>
base<vT, cT, rT, pT>::base()
{
memset(&this->value, 0, cT * rT * sizeof(vT));
}
template <typename vT, uint cT, uint rT, profile pT>
base<vT, cT, rT, pT>::base
(
typename base<vT, cT, rT, pT>::class_type const & m
)
{
for
(
typename genType<vT, cT, rT, pT>::size_type i = typename base<vT, cT, rT, pT>::size_type(0);
i < base<vT, cT, rT, pT>::col_size();
++i
)
{
this->value[i] = m[i];
}
}
template <typename vT, uint cT, uint rT, profile pT>
base<vT, cT, rT, pT>::base
(
typename base<vT, cT, rT, pT>::value_type const & x
)
{
if(rT == 1) // vector
{
for
(
typename base<vT, cT, rT, pT>::size_type i = typename base<vT, cT, rT, pT>::size_type(0);
i < base<vT, cT, rT, pT>::col_size();
++i
)
{
this->value[i][rT] = x;
}
}
else // matrix
{
memset(&this->value, 0, cT * rT * sizeof(vT));
typename base<vT, cT, rT, pT>::size_type stop = cT < rT ? cT : rT;
for
(
typename base<vT, cT, rT, pT>::size_type i = typename base<vT, cT, rT, pT>::size_type(0);
i < stop;
++i
)
{
this->value[i][i] = x;
}
}
}
template <typename vT, uint cT, uint rT, profile pT>
base<vT, cT, rT, pT>::base
(
typename base<vT, cT, rT, pT>::value_type const * const x
)
{
memcpy(&this->value, &x.value, cT * rT * sizeof(vT));
}
template <typename vT, uint cT, uint rT, profile pT>
base<vT, cT, rT, pT>::base
(
typename base<vT, cT, rT, pT>::col_type const * const x
)
{
for
(
typename base<vT, cT, rT, pT>::size_type i = typename base<vT, cT, rT, pT>::size_type(0);
i < base<vT, cT, rT, pT>::col_size();
++i
)
{
this->value[i] = x[i];
}
}
template <typename vT, uint cT, uint rT, profile pT>
template <typename vU, uint cU, uint rU, profile pU>
base<vT, cT, rT, pT>::base
(
base<vU, cU, rU, pU> const & m
)
{
for
(
typename base<vT, cT, rT, pT>::size_type i = typename base<vT, cT, rT, pT>::size_type(0);
i < base<vT, cT, rT, pT>::col_size();
++i
)
{
this->value[i] = base<vT, cT, rT, pT>(m[i]);
}
}
//////////////////////////////////////
// Accesses
template <typename vT, uint cT, uint rT, profile pT>
typename base<vT, cT, rT, pT>::col_type& base<vT, cT, rT, pT>::operator[]
(
typename base<vT, cT, rT, pT>::size_type i
)
{
return this->value[i];
}
template <typename vT, uint cT, uint rT, profile pT>
typename base<vT, cT, rT, pT>::col_type const & base<vT, cT, rT, pT>::operator[]
(
typename base<vT, cT, rT, pT>::size_type i
) const
{
return this->value[i];
}
//////////////////////////////////////
// Unary updatable operators
template <typename vT, uint cT, uint rT, profile pT>
typename base<vT, cT, rT, pT>::class_type& base<vT, cT, rT, pT>::operator=
(
typename base<vT, cT, rT, pT>::class_type const & x
)
{
memcpy(&this->value, &x.value, cT * rT * sizeof(vT));
return *this;
}
template <typename vT, uint cT, uint rT, profile pT>
typename base<vT, cT, rT, pT>::class_type& base<vT, cT, rT, pT>::operator+=
(
typename base<vT, cT, rT, pT>::value_type const & x
)
{
typename base<vT, cT, rT, pT>::size_type stop_col = x.col_size();
typename base<vT, cT, rT, pT>::size_type stop_row = x.row_size();
for(typename base<vT, cT, rT, pT>::size_type j = 0; j < stop_col; ++j)
for(typename base<vT, cT, rT, pT>::size_type i = 0; i < stop_row; ++i)
this->value[j][i] += x;
return *this;
}
template <typename vT, uint cT, uint rT, profile pT>
typename base<vT, cT, rT, pT>::class_type& base<vT, cT, rT, pT>::operator+=
(
typename base<vT, cT, rT, pT>::class_type const & x
)
{
typename base<vT, cT, rT, pT>::size_type stop_col = x.col_size();
typename base<vT, cT, rT, pT>::size_type stop_row = x.row_size();
for(typename base<vT, cT, rT, pT>::size_type j = 0; j < stop_col; ++j)
for(typename base<vT, cT, rT, pT>::size_type i = 0; i < stop_row; ++i)
this->value[j][i] += x[j][i];
return *this;
}
template <typename vT, uint cT, uint rT, profile pT>
typename base<vT, cT, rT, pT>::class_type& base<vT, cT, rT, pT>::operator-=
(
typename base<vT, cT, rT, pT>::value_type const & x
)
{
typename base<vT, cT, rT, pT>::size_type stop_col = x.col_size();
typename base<vT, cT, rT, pT>::size_type stop_row = x.row_size();
for(typename base<vT, cT, rT, pT>::size_type j = 0; j < stop_col; ++j)
for(typename base<vT, cT, rT, pT>::size_type i = 0; i < stop_row; ++i)
this->value[j][i] -= x;
return *this;
}
template <typename vT, uint cT, uint rT, profile pT>
typename base<vT, cT, rT, pT>::class_type& base<vT, cT, rT, pT>::operator-=
(
typename base<vT, cT, rT, pT>::class_type const & x
)
{
typename base<vT, cT, rT, pT>::size_type stop_col = x.col_size();
typename base<vT, cT, rT, pT>::size_type stop_row = x.row_size();
for(typename base<vT, cT, rT, pT>::size_type j = 0; j < stop_col; ++j)
for(typename base<vT, cT, rT, pT>::size_type i = 0; i < stop_row; ++i)
this->value[j][i] -= x[j][i];
return *this;
}
template <typename vT, uint cT, uint rT, profile pT>
typename base<vT, cT, rT, pT>::class_type& base<vT, cT, rT, pT>::operator*=
(
typename base<vT, cT, rT, pT>::value_type const & x
)
{
typename base<vT, cT, rT, pT>::size_type stop_col = x.col_size();
typename base<vT, cT, rT, pT>::size_type stop_row = x.row_size();
for(typename base<vT, cT, rT, pT>::size_type j = 0; j < stop_col; ++j)
for(typename base<vT, cT, rT, pT>::size_type i = 0; i < stop_row; ++i)
this->value[j][i] *= x;
return *this;
}
template <typename vT, uint cT, uint rT, profile pT>
typename base<vT, cT, rT, pT>::class_type& base<vT, cT, rT, pT>::operator*=
(
typename base<vT, cT, rT, pT>::class_type const & x
)
{
typename base<vT, cT, rT, pT>::size_type stop_col = x.col_size();
typename base<vT, cT, rT, pT>::size_type stop_row = x.row_size();
for(typename base<vT, cT, rT, pT>::size_type j = 0; j < stop_col; ++j)
for(typename base<vT, cT, rT, pT>::size_type i = 0; i < stop_row; ++i)
this->value[j][i] *= x[j][i];
return *this;
}
template <typename vT, uint cT, uint rT, profile pT>
typename base<vT, cT, rT, pT>::class_type& base<vT, cT, rT, pT>::operator/=
(
typename base<vT, cT, rT, pT>::value_type const & x
)
{
typename base<vT, cT, rT, pT>::size_type stop_col = x.col_size();
typename base<vT, cT, rT, pT>::size_type stop_row = x.row_size();
for(typename base<vT, cT, rT, pT>::size_type j = 0; j < stop_col; ++j)
for(typename base<vT, cT, rT, pT>::size_type i = 0; i < stop_row; ++i)
this->value[j][i] /= x;
return *this;
}
template <typename vT, uint cT, uint rT, profile pT>
typename base<vT, cT, rT, pT>::class_type& base<vT, cT, rT, pT>::operator/=
(
typename base<vT, cT, rT, pT>::class_type const & x
)
{
typename base<vT, cT, rT, pT>::size_type stop_col = x.col_size();
typename base<vT, cT, rT, pT>::size_type stop_row = x.row_size();
for(typename base<vT, cT, rT, pT>::size_type j = 0; j < stop_col; ++j)
for(typename base<vT, cT, rT, pT>::size_type i = 0; i < stop_row; ++i)
this->value[j][i] /= x[j][i];
return *this;
}
template <typename vT, uint cT, uint rT, profile pT>
typename base<vT, cT, rT, pT>::class_type& base<vT, cT, rT, pT>::operator++ ()
{
typename base<vT, cT, rT, pT>::size_type stop_col = col_size();
typename base<vT, cT, rT, pT>::size_type stop_row = row_size();
for(typename base<vT, cT, rT, pT>::size_type j = 0; j < stop_col; ++j)
for(typename base<vT, cT, rT, pT>::size_type i = 0; i < stop_row; ++i)
++this->value[j][i];
return *this;
}
template <typename vT, uint cT, uint rT, profile pT>
typename base<vT, cT, rT, pT>::class_type& base<vT, cT, rT, pT>::operator-- ()
{
typename base<vT, cT, rT, pT>::size_type stop_col = col_size();
typename base<vT, cT, rT, pT>::size_type stop_row = row_size();
for(typename base<vT, cT, rT, pT>::size_type j = 0; j < stop_col; ++j)
for(typename base<vT, cT, rT, pT>::size_type i = 0; i < stop_row; ++i)
--this->value[j][i];
return *this;
}
} //namespace detail
} //namespace glm

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-08-17
// Updated : 2010-02-17
// Licence : This source is under MIT License
// File : glm/core/type_half.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef glm_core_type_half
#define glm_core_type_half
#include <cstdlib>
namespace glm
{
namespace test
{
bool main_type_half();
}//namespace test
namespace detail
{
typedef short hdata;
float toFloat32(hdata value);
hdata toFloat16(float const & value);
class thalf
{
public:
// Constructors
thalf();
thalf(thalf const & s);
template <typename U>
explicit thalf(U const & s);
// Cast
//operator float();
operator float() const;
//operator double();
//operator double() const;
// Unary updatable operators
thalf& operator= (thalf const & s);
thalf& operator+=(thalf const & s);
thalf& operator-=(thalf const & s);
thalf& operator*=(thalf const & s);
thalf& operator/=(thalf const & s);
thalf& operator++();
thalf& operator--();
float toFloat() const{return toFloat32(data);}
hdata _data() const{return data;}
private:
hdata data;
};
thalf operator+ (thalf const & s1, thalf const & s2);
thalf operator- (thalf const & s1, thalf const & s2);
thalf operator* (thalf const & s1, thalf const & s2);
thalf operator/ (thalf const & s1, thalf const & s2);
// Unary constant operators
thalf operator- (thalf const & s);
thalf operator-- (thalf const & s, int);
thalf operator++ (thalf const & s, int);
}//namespace detail
}//namespace glm
#include "type_half.inl"
#endif//glm_core_type_half

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-08-17
// Updated : 2009-11-12
// Licence : This source is under MIT License
// File : glm/core/type_half.inl
///////////////////////////////////////////////////////////////////////////////////////////////////
// Copyright:
// This half implementation is based on OpenEXR which is Copyright (c) 2002,
// Industrial Light & Magic, a division of Lucas Digital Ltd. LLC
///////////////////////////////////////////////////////////////////////////////////////////////////
#include "_detail.hpp"
namespace glm{
namespace detail
{
inline float overflow()
{
volatile float f = 1e10;
for(int i = 0; i < 10; ++i)
f *= f; // this will overflow before
// the for­loop terminates
return f;
}
inline float toFloat32(hdata value)
{
int s = (value >> 15) & 0x00000001;
int e = (value >> 10) & 0x0000001f;
int m = value & 0x000003ff;
if(e == 0)
{
if(m == 0)
{
//
// Plus or minus zero
//
detail::uif result;
result.i = s << 31;
return result.f;
}
else
{
//
// Denormalized number -- renormalize it
//
while(!(m & 0x00000400))
{
m <<= 1;
e -= 1;
}
e += 1;
m &= ~0x00000400;
}
}
else if(e == 31)
{
if(m == 0)
{
//
// Positive or negative infinity
//
uif result;
result.i = (s << 31) | 0x7f800000;
return result.f;
}
else
{
//
// Nan -- preserve sign and significand bits
//
uif result;
result.i = (s << 31) | 0x7f800000 | (m << 13);
return result.f;
}
}
//
// Normalized number
//
e = e + (127 - 15);
m = m << 13;
//
// Assemble s, e and m.
//
uif Result;
Result.i = (s << 31) | (e << 23) | m;
return Result.f;
}
inline hdata toFloat16(float const & f)
{
uif Entry;
Entry.f = f;
int i = Entry.i;
//
// Our floating point number, f, is represented by the bit
// pattern in integer i. Disassemble that bit pattern into
// the sign, s, the exponent, e, and the significand, m.
// Shift s into the position where it will go in in the
// resulting half number.
// Adjust e, accounting for the different exponent bias
// of float and half (127 versus 15).
//
register int s = (i >> 16) & 0x00008000;
register int e = ((i >> 23) & 0x000000ff) - (127 - 15);
register int m = i & 0x007fffff;
//
// Now reassemble s, e and m into a half:
//
if(e <= 0)
{
if(e < -10)
{
//
// E is less than -10. The absolute value of f is
// less than half_MIN (f may be a small normalized
// float, a denormalized float or a zero).
//
// We convert f to a _halfGTX zero.
//
return 0;
}
//
// E is between -10 and 0. F is a normalized float,
// whose magnitude is less than __half_NRM_MIN.
//
// We convert f to a denormalized _halfGTX.
//
m = (m | 0x00800000) >> (1 - e);
//
// Round to nearest, round "0.5" up.
//
// Rounding may cause the significand to overflow and make
// our number normalized. Because of the way a half's bits
// are laid out, we don't have to treat this case separately;
// the code below will handle it correctly.
//
if(m & 0x00001000)
m += 0x00002000;
//
// Assemble the _halfGTX from s, e (zero) and m.
//
return hdata(s | (m >> 13));
}
else if(e == 0xff - (127 - 15))
{
if(m == 0)
{
//
// F is an infinity; convert f to a half
// infinity with the same sign as f.
//
return hdata(s | 0x7c00);
}
else
{
//
// F is a NAN; we produce a half NAN that preserves
// the sign bit and the 10 leftmost bits of the
// significand of f, with one exception: If the 10
// leftmost bits are all zero, the NAN would turn
// into an infinity, so we have to set at least one
// bit in the significand.
//
m >>= 13;
return hdata(s | 0x7c00 | m | (m == 0));
}
}
else
{
//
// E is greater than zero. F is a normalized float.
// We try to convert f to a normalized half.
//
//
// Round to nearest, round "0.5" up
//
if(m & 0x00001000)
{
m += 0x00002000;
if(m & 0x00800000)
{
m = 0; // overflow in significand,
e += 1; // adjust exponent
}
}
//
// Handle exponent overflow
//
if (e > 30)
{
overflow(); // Cause a hardware floating point overflow;
return hdata(s | 0x7c00);
// if this returns, the half becomes an
} // infinity with the same sign as f.
//
// Assemble the half from s, e and m.
//
return hdata(s | (e << 10) | (m >> 13));
}
}
inline thalf::thalf() :
data(0)
{}
inline thalf::thalf(thalf const & s) :
data(s.data)
{}
template <typename U>
inline thalf::thalf(U const & s) :
data(toFloat16(float(s)))
{}
// Cast
//inline half::operator float()
//{
// return toFloat();
//}
inline thalf::operator float() const
{
return toFloat();
}
//inline half::operator double()
//{
// return double(toFloat());
//}
//inline half::operator double() const
//{
// return double(toFloat());
//}
// Unary updatable operators
inline thalf& thalf::operator= (thalf const & s)
{
data = s.data;
return *this;
}
inline thalf& thalf::operator+=(thalf const & s)
{
data = toFloat16(toFloat32(data) + toFloat32(s.data));
return *this;
}
inline thalf& thalf::operator-=(thalf const & s)
{
data = toFloat16(toFloat32(data) - toFloat32(s.data));
return *this;
}
inline thalf& thalf::operator*=(thalf const & s)
{
data = toFloat16(toFloat32(data) * toFloat32(s.data));
return *this;
}
inline thalf& thalf::operator/=(thalf const & s)
{
data = toFloat16(toFloat32(data) / toFloat32(s.data));
return *this;
}
inline thalf& thalf::operator++()
{
float Casted = toFloat32(data);
data = toFloat16(++Casted);
return *this;
}
inline thalf& thalf::operator--()
{
float Casted = toFloat32(data);
data = toFloat16(--Casted);
return *this;
}
//////////////////////////////////////
// Binary arithmetic operators
inline detail::thalf operator+ (detail::thalf const & s1, detail::thalf const & s2)
{
return detail::thalf(float(s1) + float(s2));
}
inline detail::thalf operator- (detail::thalf const & s1, detail::thalf const & s2)
{
return detail::thalf(float(s1) - float(s2));
}
inline detail::thalf operator* (detail::thalf const & s1, detail::thalf const & s2)
{
return detail::thalf(float(s1) * float(s2));
}
inline detail::thalf operator/ (detail::thalf const & s1, detail::thalf const & s2)
{
return detail::thalf(float(s1) / float(s2));
}
// Unary constant operators
inline detail::thalf operator- (detail::thalf const & s)
{
return detail::thalf(-float(s));
}
inline detail::thalf operator-- (detail::thalf const & s, int)
{
return detail::thalf(float(s) - 1.0f);
}
inline detail::thalf operator++ (detail::thalf const & s, int)
{
return detail::thalf(float(s) + 1.0f);
}
}//namespace detail
}//namespace glm

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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2008-08-22
// Updated : 2008-09-17
// Licence : This source is under MIT License
// File : glm/core/type_int.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef glm_core_type_int
#define glm_core_type_int
#include "../setup.hpp"
#include "_detail.hpp"
namespace glm
{
namespace detail
{
#if defined(GLM_COMPILER) && (GLM_COMPILER & GLM_COMPILER_VC)
typedef signed __int64 highp_int_t;
typedef unsigned __int64 highp_uint_t;
#elif(defined(GLM_COMPILER) && (GLM_COMPILER & GLM_COMPILER_GCC))
__extension__ typedef signed long long highp_int_t;
__extension__ typedef unsigned long long highp_uint_t;
//# if GLM_MODEL == GLM_MODEL_64
// typedef signed long highp_int_t;
// typedef unsigned long highp_uint_t;
//# elif GLM_MODEL == GLM_MODEL_32
// __extension__ typedef signed long long highp_int_t;
// __extension__ typedef unsigned long long highp_uint_t;
//# endif//GLM_MODEL
#elif(defined(GLM_COMPILER_BC))
typedef Int64 highp_int_t;
typedef Uint64 highp_uint_t;
#else
typedef signed long long highp_int_t;
typedef unsigned long long highp_uint_t;
#endif//GLM_COMPILER
GLM_DETAIL_IS_INT(signed char);
GLM_DETAIL_IS_INT(signed short);
GLM_DETAIL_IS_INT(signed int);
GLM_DETAIL_IS_INT(signed long);
GLM_DETAIL_IS_INT(highp_int_t);
GLM_DETAIL_IS_UINT(unsigned char);
GLM_DETAIL_IS_UINT(unsigned short);
GLM_DETAIL_IS_UINT(unsigned int);
GLM_DETAIL_IS_UINT(unsigned long);
GLM_DETAIL_IS_UINT(highp_uint_t);
typedef signed short lowp_int_t;
typedef signed int mediump_int_t;
typedef detail::highp_int_t highp_int_t;
typedef unsigned short lowp_uint_t;
typedef unsigned int mediump_uint_t;
typedef detail::highp_uint_t highp_uint_t;
}
//namespace detail
namespace core{
namespace type{
namespace precision
{
//! Low precision signed integer.
//! There is no garanty on the actual precision.
//! From GLSL 1.30.8 specification.
typedef detail::lowp_int_t lowp_int;
//! Medium precision signed integer.
//! There is no garanty on the actual precision.
//! From GLSL 1.30.8 specification.
typedef detail::mediump_int_t mediump_int;
//! High precision signed integer.
//! There is no garanty on the actual precision.
//! From GLSL 1.30.8 specification.
typedef detail::highp_int_t highp_int;
//! Low precision unsigned integer.
//! There is no garanty on the actual precision.
//! From GLSL 1.30.8 specification.
typedef detail::lowp_uint_t lowp_uint;
//! Medium precision unsigned integer.
//! There is no garanty on the actual precision.
//! From GLSL 1.30.8 specification.
typedef detail::mediump_uint_t mediump_uint;
//! High precision unsigned integer.
//! There is no garanty on the actual precision.
//! From GLSL 1.30.8 specification.
typedef detail::highp_uint_t highp_uint;
}
//namespace precision
#ifndef GLM_PRECISION
typedef precision::mediump_int int_t;
#elif(GLM_PRECISION & GLM_PRECISION_HIGHP_INT)
typedef precision::highp_int int_t;
#elif(GLM_PRECISION & GLM_PRECISION_MEDIUMP_INT)
typedef precision::mediump_int int_t;
#elif(GLM_PRECISION & GLM_PRECISION_LOWP_INT)
typedef precision::lowp_int int_t;
#else
typedef mediump_int int_t;
# pragma message("GLM message: Precisson undefined for signed integer number.");
#endif//GLM_PRECISION
#ifndef GLM_PRECISION
typedef precision::mediump_uint uint_t;
#elif(GLM_PRECISION & GLM_PRECISION_HIGHP_UINT)
typedef precision::highp_uint uint_t;
#elif(GLM_PRECISION & GLM_PRECISION_MEDIUMP_UINT)
typedef precision::mediump_uint uint_t;
#elif(GLM_PRECISION & GLM_PRECISION_LOWP_UINT)
typedef precision::lowp_uint uint_t;
#else
typedef precision::mediump_uint uint_t;
# pragma message("GLM message: Precisson undefined for unsigned integer number.");
#endif//GLM_PRECISION
//! Unsigned integer.
//! From GLSL 1.30.8 specification section 4.1.3 Integers.
typedef uint_t uint;
}//namespace type
}//namespace core
}//namespace glm
#endif//glm_core_type_int

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glm/core/type_mat.hpp Normal file
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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2010-01-26
// Updated : 2010-01-26
// Licence : This source is under MIT License
// File : glm/core/type_mat.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef glm_core_type_mat
#define glm_core_type_mat
#include "type_gentype.hpp"
namespace glm{
namespace detail
{
//template
//<
// typename T,
// template <typename> class C,
// template <typename> class R
//>
//struct matType
//{
// enum ctor{null};
// typedef T value_type;
// typedef std::size_t size_type;
// typedef C<T> col_type;
// typedef R<T> row_type;
// static size_type const col_size;
// static size_type const row_size;
//};
//template
//<
// typename T,
// template <typename> class C,
// template <typename> class R
//>
//typename matType<T, C, R>::size_type const
//matType<T, C, R>::col_size = matType<T, C, R>::col_type::value_size;
//template
//<
// typename T,
// template <typename> class C,
// template <typename> class R
//>
//typename matType<T, C, R>::size_type const
//matType<T, C, R>::row_size = matType<T, C, R>::row_type::value_size;
}//namespace detail
}//namespace glm
#endif//glm_core_type_mat

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glm/core/type_mat.inl Normal file
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245
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///////////////////////////////////////////////////////////////////////////////////////////////////
// OpenGL Mathematics Copyright (c) 2005 - 2010 G-Truc Creation (www.g-truc.net)
///////////////////////////////////////////////////////////////////////////////////////////////////
// Created : 2005-01-27
// Updated : 2010-02-11
// Licence : This source is under MIT License
// File : glm/core/type_mat2x2.hpp
///////////////////////////////////////////////////////////////////////////////////////////////////
#ifndef glm_core_type_mat2x2
#define glm_core_type_mat2x2
#include "type_mat.hpp"
namespace glm
{
namespace test
{
void main_mat2x2();
}//namespace test
namespace detail
{
template <typename T> struct tvec1;
template <typename T> struct tvec2;
template <typename T> struct tvec3;
template <typename T> struct tvec4;
template <typename T> struct tmat2x2;
template <typename T> struct tmat2x3;
template <typename T> struct tmat2x4;
template <typename T> struct tmat3x2;
template <typename T> struct tmat3x3;
template <typename T> struct tmat3x4;
template <typename T> struct tmat4x2;
template <typename T> struct tmat4x3;
template <typename T> struct tmat4x4;
//!< \brief Template for 2 * 2 matrix of floating-point numbers.
template <typename T>
struct tmat2x2
{
enum ctor{null};
typedef T value_type;
typedef std::size_t size_type;
typedef tvec2<T> col_type;
typedef tvec2<T> row_type;
static size_type col_size();
static size_type row_size();
typedef tmat2x2<T> type;
typedef tmat2x2<T> transpose_type;
public:
// Implementation detail
tmat2x2<T> _inverse() const;
private:
// Data
col_type value[2];
public:
// Constructors
tmat2x2();
tmat2x2(
tmat2x2 const & m);
explicit tmat2x2(
ctor Null);
explicit tmat2x2(
value_type const & x);
explicit tmat2x2(
value_type const & x1, value_type const & y1,
value_type const & x2, value_type const & y2);
explicit tmat2x2(
col_type const & v1,
col_type const & v2);
// Conversions
template <typename U>
explicit tmat2x2(tmat2x2<U> const & m);
explicit tmat2x2(tmat3x3<T> const & x);
explicit tmat2x2(tmat4x4<T> const & x);
explicit tmat2x2(tmat2x3<T> const & x);
explicit tmat2x2(tmat3x2<T> const & x);
explicit tmat2x2(tmat2x4<T> const & x);
explicit tmat2x2(tmat4x2<T> const & x);
explicit tmat2x2(tmat3x4<T> const & x);
explicit tmat2x2(tmat4x3<T> const & x);
//////////////////////////////////////
// Accesses
col_type & operator[](size_type i);
col_type const & operator[](size_type i) const;
// Unary updatable operators
tmat2x2<T> & operator=(tmat2x2<T> const & m);
template <typename U>
tmat2x2<T> & operator=(tmat2x2<U> const & m);
template <typename U>
tmat2x2<T> & operator+=(U const & s);
template <typename U>
tmat2x2<T> & operator+=(tmat2x2<U> const & m);
template <typename U>
tmat2x2<T> & operator-=(U const & s);
template <typename U>
tmat2x2<T> & operator-=(tmat2x2<U> const & m);
template <typename U>
tmat2x2<T> & operator*=(U const & s);
template <typename U>
tmat2x2<T> & operator*=(tmat2x2<U> const & m);
template <typename U>
tmat2x2<T> & operator/=(U const & s);
template <typename U>
tmat2x2<T> & operator/=(tmat2x2<U> const & m);
tmat2x2<T> & operator++();
tmat2x2<T> & operator--();
};
// Binary operators
template <typename T>
tmat2x2<T> operator+ (
tmat2x2<T> const & m,
typename tmat2x2<T>::value_type const & s);
template <typename T>
tmat2x2<T> operator+ (
typename tmat2x2<T>::value_type const & s,
tmat2x2<T> const & m);
template <typename T>
tmat2x2<T> operator+ (
tmat2x2<T> const & m1,
tmat2x2<T> const & m2);
template <typename T>
tmat2x2<T> operator- (
tmat2x2<T> const & m,
typename tmat2x2<T>::value_type const & s);
template <typename T>
tmat2x2<T> operator- (
typename tmat2x2<T>::value_type const & s,
tmat2x2<T> const & m);
template <typename T>
tmat2x2<T> operator- (
tmat2x2<T> const & m1,
tmat2x2<T> const & m2);
template <typename T>
tmat2x2<T> operator* (
tmat2x2<T> const & m,
typename tmat2x2<T>::value_type const & s);
template <typename T>
tmat2x2<T> operator* (
typename tmat2x2<T>::value_type const & s,
tmat2x2<T> const & m);
template <typename T>
typename tmat2x2<T>::row_type operator* (
tmat2x2<T> const & m,
typename tmat2x2<T>::col_type const & s);
template <typename T>
typename tmat2x2<T>::col_type operator* (
typename tmat2x2<T>::row_type,
tmat2x2<T> const & m);
template <typename T>
tmat2x2<T> operator* (
tmat2x2<T> const & m1,
tmat2x2<T> const & m2);
template <typename T>
tmat2x2<T> operator/ (
tmat2x2<T> const & m,
typename tmat2x2<T>::value_type const & s);
template <typename T>
tmat2x2<T> operator/ (
typename tmat2x2<T>::value_type const & s,
tmat2x2<T> const & m);
template <typename T>
typename tmat2x2<T>::row_type operator/ (
tmat2x2<T> const & m,
typename tmat2x2<T>::col_type const & v);
template <typename T>
typename tmat2x2<T>::col_type operator/ (
typename tmat2x2<T>::row_type & v,
tmat2x2<T> const & m);
template <typename T>
tmat2x2<T> operator/ (
tmat2x2<T> const & m1,
tmat2x2<T> const & m2);
// Unary constant operators
template <typename T>
tmat2x2<T> const operator- (
tmat2x2<T> const & m);
template <typename T>
tmat2x2<T> const operator-- (
tmat2x2<T> const & m,
int);
template <typename T>
tmat2x2<T> const operator++ (
tmat2x2<T> const & m,
int);
} //namespace detail
namespace core{
namespace type{
namespace precision
{
//! 2 columns of 2 components matrix of low precision floating-point numbers.
//! There is no garanty on the actual precision.
//! (From GLSL 1.30.8 specification, section 4.1.6 Matrices and section 4.5 Precision and Precision Qualifiers)
typedef detail::tmat2x2<lowp_float> lowp_mat2x2;
//! 2 columns of 2 components matrix of medium precision floating-point numbers.
//! There is no garanty on the actual precision.
//! (From GLSL 1.30.8 specification, section 4.1.6 Matrices and section 4.5 Precision and Precision Qualifiers)
typedef detail::tmat2x2<mediump_float> mediump_mat2x2;
//! 2 columns of 2 components matrix of high precision floating-point numbers.
//! There is no garanty on the actual precision.
//! (From GLSL 1.30.8 specification, section 4.1.6 Matrices and section 4.5 Precision and Precision Qualifiers)
typedef detail::tmat2x2<highp_float> highp_mat2x2;
}
//namespace precision
}//namespace type
}//namespace core
} //namespace glm
#include "type_mat2x2.inl"
#endif //glm_core_type_mat2x2

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