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I get this build error when I try to compile:

1>c:\users\student\documents\visual studio 2012\projects\openglproject1\openglproject1\mat.h(495): error C4716: 'Angel::mat4::operator*=' : must return a value

What does it mean I must do? The program is

#define _CRT_SECURE_NO_WARNINGS
#include "Angel.h"

typedef Angel::vec4 point4;
typedef Angel::vec4 color4;

const int NumVertices = 36; //(6 faces)(2 triangles/face)(3 vertices/triangle)

point4 points[NumVertices];
color4 colors[NumVertices];

point4 vertices[8] = {
    point4( -0.5, -0.5,  0.5, 1.0 ),
    point4( -0.5,  0.5,  0.5, 1.0 ),
    point4(  0.5,  0.5,  0.5, 1.0 ),
    point4(  0.5, -0.5,  0.5, 1.0 ),
    point4( -0.5, -0.5, -0.5, 1.0 ),
    point4( -0.5,  0.5, -0.5, 1.0 ),
    point4(  0.5,  0.5, -0.5, 1.0 ),
    point4(  0.5, -0.5, -0.5, 1.0 )
};

// RGBA olors
color4 vertex_colors[8] = {
    color4( 0.0, 0.0, 0.0, 1.0 ),  // black
    color4( 1.0, 0.0, 0.0, 1.0 ),  // red
    color4( 1.0, 1.0, 0.0, 1.0 ),  // yellow
    color4( 0.0, 1.0, 0.0, 1.0 ),  // green
    color4( 0.0, 0.0, 1.0, 1.0 ),  // blue
    color4( 1.0, 0.0, 1.0, 1.0 ),  // magenta
    color4( 1.0, 1.0, 1.0, 1.0 ),  // white
    color4( 0.0, 1.0, 1.0, 1.0 )   // cyan
};


// Parameters controlling the size of the Robot's arm
const GLfloat BASE_HEIGHT      = 2.0;
const GLfloat BASE_WIDTH       = 5.0;
const GLfloat LOWER_ARM_HEIGHT = 5.0;
const GLfloat LOWER_ARM_WIDTH  = 0.5;
const GLfloat UPPER_ARM_HEIGHT = 5.0;
const GLfloat UPPER_ARM_WIDTH  = 0.5;

// Shader transformation matrices
mat4  model_view;
GLuint ModelView, Projection;

// Array of rotation angles (in degrees) for each rotation axis
enum { Base = 0, LowerArm = 1, UpperArm = 2, NumAngles = 3 };
int      Axis = Base;
GLfloat  Theta[NumAngles] = { 0.0 };

// Menu option values
const int  Quit = 4;


//----------------------------------------------------------------------------

int Index = 0;

void
quad( int a, int b, int c, int d )
{
    colors[Index] = vertex_colors[a]; points[Index] = vertices[a]; Index++;
    colors[Index] = vertex_colors[a]; points[Index] = vertices[b]; Index++;
    colors[Index] = vertex_colors[a]; points[Index] = vertices[c]; Index++;
    colors[Index] = vertex_colors[a]; points[Index] = vertices[a]; Index++;
    colors[Index] = vertex_colors[a]; points[Index] = vertices[c]; Index++;
    colors[Index] = vertex_colors[a]; points[Index] = vertices[d]; Index++;
}

void
colorcube()
{
    quad( 1, 0, 3, 2 );
    quad( 2, 3, 7, 6 );
    quad( 3, 0, 4, 7 );
    quad( 6, 5, 1, 2 );
    quad( 4, 5, 6, 7 );
    quad( 5, 4, 0, 1 );
}

//----------------------------------------------------------------------------

/* Define the three parts */
/* Note use of push/pop to return modelview matrix
to its state before functions were entered and use
rotation, translation, and scaling to create instances
of symbols (cube and cylinder */

void
base()
{
    mat4 instance = ( Translate( 0.0, 0.5 * BASE_HEIGHT, 0.0 ) *
         Scale( BASE_WIDTH,
            BASE_HEIGHT,
            BASE_WIDTH ) );

    glUniformMatrix4fv( ModelView, 1, GL_TRUE, model_view * instance );

    glDrawArrays( GL_TRIANGLES, 0, NumVertices );
}

//----------------------------------------------------------------------------

void
upper_arm()
{
    mat4 instance = ( Translate( 0.0, 0.5 * UPPER_ARM_HEIGHT, 0.0 ) *
              Scale( UPPER_ARM_WIDTH,
                 UPPER_ARM_HEIGHT,
                 UPPER_ARM_WIDTH ) );

    glUniformMatrix4fv( ModelView, 1, GL_TRUE, model_view * instance );
    glDrawArrays( GL_TRIANGLES, 0, NumVertices );
}

//----------------------------------------------------------------------------

void
lower_arm()
{
    mat4 instance = ( Translate( 0.0, 0.5 * LOWER_ARM_HEIGHT, 0.0 ) *
              Scale( LOWER_ARM_WIDTH,
                 LOWER_ARM_HEIGHT,
                 LOWER_ARM_WIDTH ) );

    glUniformMatrix4fv( ModelView, 1, GL_TRUE, model_view * instance );
    glDrawArrays( GL_TRIANGLES, 0, NumVertices );
}

//----------------------------------------------------------------------------

void
display( void )
{
    glClear( GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT );

    // Accumulate ModelView Matrix as we traverse the tree
    model_view = RotateY(Theta[Base] );
    base();

    model_view *= ( Translate(0.0, BASE_HEIGHT, 0.0) *
            RotateZ(Theta[LowerArm]) );
    lower_arm();

    model_view *= ( Translate(0.0, LOWER_ARM_HEIGHT, 0.0) *
            RotateZ(Theta[UpperArm]) );
    upper_arm();

    glutSwapBuffers();
}

//----------------------------------------------------------------------------

void
init( void )
{
    colorcube();

    // Create a vertex array object
    GLuint vao;
    glGenVertexArrays( 1, &vao );
    glBindVertexArray( vao );

    // Create and initialize a buffer object
    GLuint buffer;
    glGenBuffers( 1, &buffer );
    glBindBuffer( GL_ARRAY_BUFFER, buffer );
    glBufferData( GL_ARRAY_BUFFER, sizeof(points) + sizeof(colors),
          NULL, GL_DYNAMIC_DRAW );
    glBufferSubData( GL_ARRAY_BUFFER, 0, sizeof(points), points );
    glBufferSubData( GL_ARRAY_BUFFER, sizeof(points), sizeof(colors), colors );

    // Load shaders and use the resulting shader program
    GLuint program = InitShader( "vshader81.glsl", "fshader81.glsl" );
    glUseProgram( program );

    GLuint vPosition = glGetAttribLocation( program, "vPosition" );
    glEnableVertexAttribArray( vPosition );
    glVertexAttribPointer( vPosition, 4, GL_FLOAT, GL_FALSE, 0,
               BUFFER_OFFSET(0) );

    GLuint vColor = glGetAttribLocation( program, "vColor" );
    glEnableVertexAttribArray( vColor );
    glVertexAttribPointer( vColor, 4, GL_FLOAT, GL_FALSE, 0,
               BUFFER_OFFSET(sizeof(points)) );

    ModelView = glGetUniformLocation( program, "ModelView" );
    Projection = glGetUniformLocation( program, "Projection" );

    glEnable( GL_DEPTH );
    glPolygonMode( GL_FRONT_AND_BACK, GL_LINE );

    glClearColor( 1.0, 1.0, 1.0, 1.0 ); 
}

//----------------------------------------------------------------------------

void
mouse( int button, int state, int x, int y )
{

    if ( button == GLUT_LEFT_BUTTON && state == GLUT_DOWN ) {
    // Incrase the joint angle
    Theta[Axis] += 5.0;
    if ( Theta[Axis] > 360.0 ) { Theta[Axis] -= 360.0; }
    }

    if ( button == GLUT_RIGHT_BUTTON && state == GLUT_DOWN ) {
    // Decrase the joint angle
    Theta[Axis] -= 5.0;
    if ( Theta[Axis] < 0.0 ) { Theta[Axis] += 360.0; }
    }

    glutPostRedisplay();
}

//----------------------------------------------------------------------------

void
menu( int option )
{
    if ( option == Quit ) {
    exit( EXIT_SUCCESS );
    }
    else {
    Axis = option;
    }
}

//----------------------------------------------------------------------------

void
reshape( int width, int height )
{
    glViewport( 0, 0, width, height );

    GLfloat  left = -10.0, right = 10.0;
    GLfloat  bottom = -5.0, top = 15.0;
    GLfloat  zNear = -10.0, zFar = 10.0;

    GLfloat aspect = GLfloat(width)/height;

    if ( aspect > 1.0 ) {
    left *= aspect;
    right *= aspect;
    }
    else {
    bottom /= aspect;
    top /= aspect;
    }

    mat4 projection = Ortho( left, right, bottom, top, zNear, zFar );
    glUniformMatrix4fv( Projection, 1, GL_TRUE, projection );

    model_view = mat4( 1.0 );  // An Identity matrix
}

//----------------------------------------------------------------------------

void
keyboard( unsigned char key, int x, int y )
{
    switch( key ) {
    case 033: // Escape Key
    case 'q': case 'Q':
        exit( EXIT_SUCCESS );
        break;
    }
}

//----------------------------------------------------------------------------

int
main( int argc, char **argv )
{
    glutInit( &argc, argv );
    glutInitDisplayMode( GLUT_DOUBLE | GLUT_RGB | GLUT_DEPTH );
    glutInitWindowSize( 512, 512 );
    glutInitContextVersion( 3, 2 );
    glutInitContextProfile( GLUT_CORE_PROFILE );
    glutCreateWindow( "robot" );

    glewInit();

    init();

    glutDisplayFunc( display );
    glutReshapeFunc( reshape );
    glutKeyboardFunc( keyboard );
    glutMouseFunc( mouse );

    glutCreateMenu( menu );
    // Set the menu values to the relevant rotation axis values (or Quit)
    glutAddMenuEntry( "base", Base );
    glutAddMenuEntry( "lower arm", LowerArm );
    glutAddMenuEntry( "upper arm", UpperArm );
    glutAddMenuEntry( "quit", Quit );
    glutAttachMenu( GLUT_MIDDLE_BUTTON );

    glutMainLoop();
    return 0;
}

Update 1

Adding return *this to the end of the function made the thing build. I don't think it's self-evident:

//////////////////////////////////////////////////////////////////////////////
//
//  --- mat.h ---
//
//////////////////////////////////////////////////////////////////////////////

#ifndef __ANGEL_MAT_H__
#define __ANGEL_MAT_H__

#include "vec.h"

namespace Angel {

//----------------------------------------------------------------------------
//
//  mat2 - 2D square matrix
//

class mat2 {

    vec2  _m[2];

   public:
    //
    //  --- Constructors and Destructors ---
    //

    mat2( const GLfloat d = GLfloat(1.0) )  // Create a diagional matrix
    { _m[0].x = d;  _m[1].y = d;   }

    mat2( const vec2& a, const vec2& b )
    { _m[0] = a;  _m[1] = b;  }

    mat2( GLfloat m00, GLfloat m10, GLfloat m01, GLfloat m11 )
    { _m[0] = vec2( m00, m01 ); _m[1] = vec2( m10, m11 ); }

    mat2( const mat2& m ) {
    if ( *this != m ) {
        _m[0] = m._m[0];
        _m[1] = m._m[1];
    } 
    }

    //
    //  --- Indexing Operator ---
    //

    vec2& operator [] ( int i ) { return _m[i]; }
    const vec2& operator [] ( int i ) const { return _m[i]; }

    //
    //  --- (non-modifying) Arithmatic Operators ---
    //

    mat2 operator + ( const mat2& m ) const
    { return mat2( _m[0]+m[0], _m[1]+m[1] ); }

    mat2 operator - ( const mat2& m ) const
    { return mat2( _m[0]-m[0], _m[1]-m[1] ); }

    mat2 operator * ( const GLfloat s ) const 
    { return mat2( s*_m[0], s*_m[1] ); }

    mat2 operator / ( const GLfloat s ) const {
#ifdef DEBUG
    if ( std::fabs(s) < DivideByZeroTolerance ) {
        std::cerr << "[" << __FILE__ << ":" << __LINE__ << "] "
              << "Division by zero" << std::endl;
        return mat2();
    }
#endif // DEBUG

    GLfloat r = GLfloat(1.0) / s;
    return *this * r;
    }

    friend mat2 operator * ( const GLfloat s, const mat2& m )
    { return m * s; }

    mat2 operator * ( const mat2& m ) const {
    mat2  a( 0.0 );

    for ( int i = 0; i < 2; ++i ) {
        for ( int j = 0; j < 2; ++j ) {
        for ( int k = 0; k < 2; ++k ) {
            a[i][j] += _m[i][k] * m[k][j];
        }
        }
    }

    return a;
    }

    //
    //  --- (modifying) Arithmetic Operators ---
    //

    mat2& operator += ( const mat2& m ) {
    _m[0] += m[0];  _m[1] += m[1];  
    return *this;
    }

    mat2& operator -= ( const mat2& m ) {
    _m[0] -= m[0];  _m[1] -= m[1];  
    return *this;
    }

    mat2& operator *= ( const GLfloat s ) {
    _m[0] *= s;  _m[1] *= s;   
    return *this;
    }

    mat2& operator *= ( const mat2& m ) {
    mat2  a( 0.0 );

    for ( int i = 0; i < 2; ++i ) {
        for ( int j = 0; j < 2; ++j ) {
        for ( int k = 0; k < 2; ++k ) {
            a[i][j] += _m[i][k] * m[k][j];
        }
        }
    }

    *this = a;
    }

    mat2& operator /= ( const GLfloat s ) {
#ifdef DEBUG
    if ( std::fabs(s) < DivideByZeroTolerance ) {
        std::cerr << "[" << __FILE__ << ":" << __LINE__ << "] "
              << "Division by zero" << std::endl;
        return mat2();
    }
#endif // DEBUG

    GLfloat r = GLfloat(1.0) / s;
    return *this *= r;
    }

    //
    //  --- Matrix / Vector operators ---
    //

    vec2 operator * ( const vec2& v ) const {  // m * v
    return vec2( _m[0][0]*v.x + _m[0][1]*v.y,
             _m[1][0]*v.x + _m[1][1]*v.y );
    }

    //
    //  --- Insertion and Extraction Operators ---
    //

    friend std::ostream& operator << ( std::ostream& os, const mat2& m )
    { return os << std::endl << m[0] << std::endl << m[1] << std::endl; }

    friend std::istream& operator >> ( std::istream& is, mat2& m )
    { return is >> m._m[0] >> m._m[1] ; }

    //
    //  --- Conversion Operators ---
    //

    operator const GLfloat* () const
    { return static_cast<const GLfloat*>( &_m[0].x ); }

    operator GLfloat* ()
    { return static_cast<GLfloat*>( &_m[0].x ); }
};

//
//  --- Non-class mat2 Methods ---
//

inline
mat2 matrixCompMult( const mat2& A, const mat2& B ) {
    return mat2( A[0][0]*B[0][0], A[0][1]*B[0][1],
         A[1][0]*B[1][0], A[1][1]*B[1][1] );
}

inline
mat2 transpose( const mat2& A ) {
    return mat2( A[0][0], A[1][0],
         A[0][1], A[1][1] );
}

//----------------------------------------------------------------------------
//
//  mat3 - 3D square matrix 
//

class mat3 {

    vec3  _m[3];

   public:
    //
    //  --- Constructors and Destructors ---
    //

    mat3( const GLfloat d = GLfloat(1.0) )  // Create a diagional matrix
    { _m[0].x = d;  _m[1].y = d;  _m[2].z = d;   }

    mat3( const vec3& a, const vec3& b, const vec3& c )
    { _m[0] = a;  _m[1] = b;  _m[2] = c;  }

    mat3( GLfloat m00, GLfloat m10, GLfloat m20,
      GLfloat m01, GLfloat m11, GLfloat m21,
      GLfloat m02, GLfloat m12, GLfloat m22 ) 
    {
        _m[0] = vec3( m00, m01, m02 );
        _m[1] = vec3( m10, m11, m12 );
        _m[2] = vec3( m20, m21, m22 );
    }

    mat3( const mat3& m )
    {
        if ( *this != m ) {
        _m[0] = m._m[0];
        _m[1] = m._m[1];
        _m[2] = m._m[2];
        } 
    }

    //
    //  --- Indexing Operator ---
    //

    vec3& operator [] ( int i ) { return _m[i]; }
    const vec3& operator [] ( int i ) const { return _m[i]; }

    //
    //  --- (non-modifying) Arithmatic Operators ---
    //

    mat3 operator + ( const mat3& m ) const
    { return mat3( _m[0]+m[0], _m[1]+m[1], _m[2]+m[2] ); }

    mat3 operator - ( const mat3& m ) const
    { return mat3( _m[0]-m[0], _m[1]-m[1], _m[2]-m[2] ); }

    mat3 operator * ( const GLfloat s ) const 
    { return mat3( s*_m[0], s*_m[1], s*_m[2] ); }

    mat3 operator / ( const GLfloat s ) const {
#ifdef DEBUG
    if ( std::fabs(s) < DivideByZeroTolerance ) {
        std::cerr << "[" << __FILE__ << ":" << __LINE__ << "] "
              << "Division by zero" << std::endl;
        return mat3();
    }
#endif // DEBUG

    GLfloat r = GLfloat(1.0) / s;
    return *this * r;
    }

    friend mat3 operator * ( const GLfloat s, const mat3& m )
    { return m * s; }

    mat3 operator * ( const mat3& m ) const {
    mat3  a( 0.0 );

    for ( int i = 0; i < 3; ++i ) {
        for ( int j = 0; j < 3; ++j ) {
        for ( int k = 0; k < 3; ++k ) {
            a[i][j] += _m[i][k] * m[k][j];
        }
        }
    }

    return a;
    }

    //
    //  --- (modifying) Arithmetic Operators ---
    //

    mat3& operator += ( const mat3& m ) {
    _m[0] += m[0];  _m[1] += m[1];  _m[2] += m[2]; 
    return *this;
    }

    mat3& operator -= ( const mat3& m ) {
    _m[0] -= m[0];  _m[1] -= m[1];  _m[2] -= m[2]; 
    return *this;
    }

    mat3& operator *= ( const GLfloat s ) {
    _m[0] *= s;  _m[1] *= s;  _m[2] *= s; 
    return *this;
    }

    mat3& operator *= ( const mat3& m ) {
    mat3  a( 0.0 );

    for ( int i = 0; i < 3; ++i ) {
        for ( int j = 0; j < 3; ++j ) {
        for ( int k = 0; k < 3; ++k ) {
            a[i][j] += _m[i][k] * m[k][j];
        }
        }
    }

    *this = a;
    }

    mat3& operator /= ( const GLfloat s ) {
#ifdef DEBUG
    if ( std::fabs(s) < DivideByZeroTolerance ) {
        std::cerr << "[" << __FILE__ << ":" << __LINE__ << "] "
              << "Division by zero" << std::endl;
        return mat3();
    }
#endif // DEBUG

    GLfloat r = GLfloat(1.0) / s;
    return *this *= r;
    }

    //
    //  --- Matrix / Vector operators ---
    //

    vec3 operator * ( const vec3& v ) const {  // m * v
    return vec3( _m[0][0]*v.x + _m[0][1]*v.y + _m[0][2]*v.z,
             _m[1][0]*v.x + _m[1][1]*v.y + _m[1][2]*v.z,
             _m[2][0]*v.x + _m[2][1]*v.y + _m[2][2]*v.z );
    }

    //
    //  --- Insertion and Extraction Operators ---
    //

    friend std::ostream& operator << ( std::ostream& os, const mat3& m ) {
    return os << std::endl 
          << m[0] << std::endl
          << m[1] << std::endl
          << m[2] << std::endl;
    }

    friend std::istream& operator >> ( std::istream& is, mat3& m )
    { return is >> m._m[0] >> m._m[1] >> m._m[2] ; }

    //
    //  --- Conversion Operators ---
    //

    operator const GLfloat* () const
    { return static_cast<const GLfloat*>( &_m[0].x ); }

    operator GLfloat* ()
    { return static_cast<GLfloat*>( &_m[0].x ); }
};

//
//  --- Non-class mat3 Methods ---
//

inline
mat3 matrixCompMult( const mat3& A, const mat3& B ) {
    return mat3( A[0][0]*B[0][0], A[0][1]*B[0][1], A[0][2]*B[0][2],
         A[1][0]*B[1][0], A[1][1]*B[1][1], A[1][2]*B[1][2],
         A[2][0]*B[2][0], A[2][1]*B[2][1], A[2][2]*B[2][2] );
}

inline
mat3 transpose( const mat3& A ) {
    return mat3( A[0][0], A[1][0], A[2][0],
         A[0][1], A[1][1], A[2][1],
         A[0][2], A[1][2], A[2][2] );
}

//----------------------------------------------------------------------------
//
//  mat4.h - 4D square matrix
//

class mat4 {

    vec4  _m[4];

   public:
    //
    //  --- Constructors and Destructors ---
    //

    mat4( const GLfloat d = GLfloat(1.0) )  // Create a diagional matrix
    { _m[0].x = d;  _m[1].y = d;  _m[2].z = d;  _m[3].w = d; }

    mat4( const vec4& a, const vec4& b, const vec4& c, const vec4& d )
    { _m[0] = a;  _m[1] = b;  _m[2] = c;  _m[3] = d; }

    mat4( GLfloat m00, GLfloat m10, GLfloat m20, GLfloat m30,
      GLfloat m01, GLfloat m11, GLfloat m21, GLfloat m31,
      GLfloat m02, GLfloat m12, GLfloat m22, GLfloat m32,
      GLfloat m03, GLfloat m13, GLfloat m23, GLfloat m33 )
    {
        _m[0] = vec4( m00, m01, m02, m03 );
        _m[1] = vec4( m10, m11, m12, m13 );
        _m[2] = vec4( m20, m21, m22, m23 );
        _m[3] = vec4( m30, m31, m32, m33 );
    }

    mat4( const mat4& m )
    {
        if ( *this != m ) {
        _m[0] = m._m[0];
        _m[1] = m._m[1];
        _m[2] = m._m[2];
        _m[3] = m._m[3];
        } 
    }

    //
    //  --- Indexing Operator ---
    //

    vec4& operator [] ( int i ) { return _m[i]; }
    const vec4& operator [] ( int i ) const { return _m[i]; }

    //
    //  --- (non-modifying) Arithematic Operators ---
    //

    mat4 operator + ( const mat4& m ) const
    { return mat4( _m[0]+m[0], _m[1]+m[1], _m[2]+m[2], _m[3]+m[3] ); }

    mat4 operator - ( const mat4& m ) const
    { return mat4( _m[0]-m[0], _m[1]-m[1], _m[2]-m[2], _m[3]-m[3] ); }

    mat4 operator * ( const GLfloat s ) const 
    { return mat4( s*_m[0], s*_m[1], s*_m[2], s*_m[3] ); }

    mat4 operator / ( const GLfloat s ) const {
#ifdef DEBUG
    if ( std::fabs(s) < DivideByZeroTolerance ) {
        std::cerr << "[" << __FILE__ << ":" << __LINE__ << "] "
              << "Division by zero" << std::endl;
        return mat4();
    }
#endif // DEBUG

    GLfloat r = GLfloat(1.0) / s;
    return *this * r;
    }

    friend mat4 operator * ( const GLfloat s, const mat4& m )
    { return m * s; }

    mat4 operator * ( const mat4& m ) const {
    mat4  a( 0.0 );

    for ( int i = 0; i < 4; ++i ) {
        for ( int j = 0; j < 4; ++j ) {
        for ( int k = 0; k < 4; ++k ) {
            a[i][j] += _m[i][k] * m[k][j];
        }
        }
    }

    return a;
    }

    //
    //  --- (modifying) Arithematic Operators ---
    //

    mat4& operator += ( const mat4& m ) {
    _m[0] += m[0];  _m[1] += m[1];  _m[2] += m[2];  _m[3] += m[3];
    return *this;
    }

    mat4& operator -= ( const mat4& m ) {
    _m[0] -= m[0];  _m[1] -= m[1];  _m[2] -= m[2];  _m[3] -= m[3];
    return *this;
    }

    mat4& operator *= ( const GLfloat s ) {
    _m[0] *= s;  _m[1] *= s;  _m[2] *= s;  _m[3] *= s;
    return *this;
    }

    mat4& operator *= ( const mat4& m ) {
    mat4  a( 0.0 );

    for ( int i = 0; i < 4; ++i ) {
        for ( int j = 0; j < 4; ++j ) {
        for ( int k = 0; k < 4; ++k ) {
            a[i][j] += _m[i][k] * m[k][j];
        }
        }
    }

    *this = a;
    return *this;
    }

    mat4& operator /= ( const GLfloat s ) {
#ifdef DEBUG
    if ( std::fabs(s) < DivideByZeroTolerance ) {
        std::cerr << "[" << __FILE__ << ":" << __LINE__ << "] "
              << "Division by zero" << std::endl;
        return mat4();
    }
#endif // DEBUG

    GLfloat r = GLfloat(1.0) / s;
    return *this *= r;
    }

    //
    //  --- Matrix / Vector operators ---
    //

    vec4 operator * ( const vec4& v ) const {  // m * v
    return vec4( _m[0][0]*v.x + _m[0][1]*v.y + _m[0][2]*v.z + _m[0][3]*v.w,
             _m[1][0]*v.x + _m[1][1]*v.y + _m[1][2]*v.z + _m[1][3]*v.w,
             _m[2][0]*v.x + _m[2][1]*v.y + _m[2][2]*v.z + _m[2][3]*v.w,
             _m[3][0]*v.x + _m[3][1]*v.y + _m[3][2]*v.z + _m[3][3]*v.w
        );
    }

    //
    //  --- Insertion and Extraction Operators ---
    //

    friend std::ostream& operator << ( std::ostream& os, const mat4& m ) {
    return os << std::endl 
          << m[0] << std::endl
          << m[1] << std::endl
          << m[2] << std::endl
          << m[3] << std::endl;
    }

    friend std::istream& operator >> ( std::istream& is, mat4& m )
    { return is >> m._m[0] >> m._m[1] >> m._m[2] >> m._m[3]; }

    //
    //  --- Conversion Operators ---
    //

    operator const GLfloat* () const
    { return static_cast<const GLfloat*>( &_m[0].x ); }

    operator GLfloat* ()
    { return static_cast<GLfloat*>( &_m[0].x ); }
};

//
//  --- Non-class mat4 Methods ---
//

inline
mat4 matrixCompMult( const mat4& A, const mat4& B ) {
    return mat4(
    A[0][0]*B[0][0], A[0][1]*B[0][1], A[0][2]*B[0][2], A[0][3]*B[0][3],
    A[1][0]*B[1][0], A[1][1]*B[1][1], A[1][2]*B[1][2], A[1][3]*B[1][3],
    A[2][0]*B[2][0], A[2][1]*B[2][1], A[2][2]*B[2][2], A[2][3]*B[2][3],
    A[3][0]*B[3][0], A[3][1]*B[3][1], A[3][2]*B[3][2], A[3][3]*B[3][3] );
}

inline
mat4 transpose( const mat4& A ) {
    return mat4( A[0][0], A[1][0], A[2][0], A[3][0],
         A[0][1], A[1][1], A[2][1], A[3][1],
         A[0][2], A[1][2], A[2][2], A[3][2],
         A[0][3], A[1][3], A[2][3], A[3][3] );
}

//////////////////////////////////////////////////////////////////////////////
//
//  Helpful Matrix Methods
//
//////////////////////////////////////////////////////////////////////////////

#define Error( str ) do { std::cerr << "[" __FILE__ ":" << __LINE__ << "] " \
                    << str << std::endl; } while(0)

inline
vec4 mvmult( const mat4& a, const vec4& b )
{
    Error( "replace with vector matrix multiplcation operator" );

    vec4 c;
    int i, j;
    for(i=0; i<4; i++) {
    c[i] =0.0;
    for(j=0;j<4;j++) c[i]+=a[i][j]*b[j];
    }
    return c;
}

//----------------------------------------------------------------------------
//
//  Rotation matrix generators
//

inline
mat4 RotateX( const GLfloat theta )
{
    GLfloat angle = DegreesToRadians * theta;

    mat4 c;
    c[2][2] = c[1][1] = cos(angle);
    c[2][1] = sin(angle);
    c[1][2] = -c[2][1];
    return c;
}

inline
mat4 RotateY( const GLfloat theta )
{
    GLfloat angle = DegreesToRadians * theta;

    mat4 c;
    c[2][2] = c[0][0] = cos(angle);
    c[0][2] = sin(angle);
    c[2][0] = -c[0][2];
    return c;
}

inline
mat4 RotateZ( const GLfloat theta )
{
    GLfloat angle = DegreesToRadians * theta;

    mat4 c;
    c[0][0] = c[1][1] = cos(angle);
    c[1][0] = sin(angle);
    c[0][1] = -c[1][0];
    return c;
}

//----------------------------------------------------------------------------
//
//  Translation matrix generators
//

inline
mat4 Translate( const GLfloat x, const GLfloat y, const GLfloat z )
{
    mat4 c;
    c[0][3] = x;
    c[1][3] = y;
    c[2][3] = z;
    return c;
}

inline
mat4 Translate( const vec3& v )
{
    return Translate( v.x, v.y, v.z );
}

...


}  // namespace Angel

#endif // __ANGEL_MAT_H__
share|improve this question

closed as too localized by atk, nvoigt, Ziyao Wei, Nathan Hughes, samayo Jun 23 '13 at 15:22

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4  
Wherever you declare/define operator *= it must return a value. Its not in the code you posted here. The message is pretty self explanatory tbh. –  Borgleader Jun 22 '13 at 1:12
2  
The error is on line 495 of mat.h, which you haven't shown us. –  Keith Thompson Jun 22 '13 at 1:13

1 Answer 1

up vote 2 down vote accepted

c:\users\student\documents\visual studio 2012\projects\openglproject1\openglproject1\mat.h(495): error C4716: 'Angel::mat4::operator*=' : must return a value

means that on line 495 of file c:\users\student\documents\visual studio 2012\projects\openglproject1\openglproject1\mat.h, you have defined a *= operator in the Angel::mat4 class that doesn't return a value. However, the operator must return a value in order to compile.

Add an appropriate return statement, and it'll compile.

share|improve this answer
1  
It also could be that his return type is void. –  Borgleader Jun 22 '13 at 1:19
    
@Borgleader: If the return type were void there would be no error. But the convention for a compound assignment operator is to have return type Angel::mat4& and end with return *this; –  Ben Voigt Jun 22 '13 at 1:21
    
Hmm I thought it was enforced that they returned a value. My bad. –  Borgleader Jun 22 '13 at 1:23
    
@Borgleader, I believe MSVC enforces it. I think the standard says you don't have to do anything, but others will at least warn. –  chris Jun 22 '13 at 2:14

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