--------------------------------------------------------------------------- -- An implementation of matrices for describing and working with affine -- transformations. -- @author Uli Schlachter -- @copyright 2015 Uli Schlachter -- @classmod gears.matrix --------------------------------------------------------------------------- local cairo = require("lgi").cairo local matrix = {} -- Metatable for matrix instances. This is set up near the end of the file. local matrix_mt = {} --- Create a new matrix instance -- @tparam number xx The xx transformation part. -- @tparam number yx The yx transformation part. -- @tparam number xy The xy transformation part. -- @tparam number yy The yy transformation part. -- @tparam number x0 The x0 transformation part. -- @tparam number y0 The y0 transformation part. -- @return A new matrix describing the given transformation. function matrix.create(xx, yx, xy, yy, x0, y0) return setmetatable({ xx = xx, xy = xy, x0 = x0, yx = yx, yy = yy, y0 = y0 }, matrix_mt) end --- Create a new translation matrix -- @tparam number x The translation in x direction. -- @tparam number y The translation in y direction. -- @return A new matrix describing the given transformation. function matrix.create_translate(x, y) return matrix.create(1, 0, 0, 1, x, y) end --- Create a new scaling matrix -- @tparam number sx The scaling in x direction. -- @tparam number sy The scaling in y direction. -- @return A new matrix describing the given transformation. function matrix.create_scale(sx, sy) return matrix.create(sx, 0, 0, sy, 0, 0) end --- Create a new rotation matrix -- @tparam number angle The angle of the rotation in radians. -- @return A new matrix describing the given transformation. function matrix.create_rotate(angle) local c, s = math.cos(angle), math.sin(angle) return matrix.create(c, s, -s, c, 0, 0) end --- Create a new rotation matrix rotating around a custom point -- @tparam number x The horizontal rotation point -- @tparam number y The vertical rotation point -- @tparam number angle The angle of the rotation in radians. -- @return A new matrix describing the given transformation. function matrix.create_rotate_at(x, y, angle) return matrix.create_translate( -x, -y ) * matrix.create_rotate ( angle ) * matrix.create_translate( x, y ) end --- Translate this matrix -- @tparam number x The translation in x direction. -- @tparam number y The translation in y direction. -- @return A new matrix describing the new transformation. function matrix:translate(x, y) return matrix.create_translate(x, y):multiply(self) end --- Scale this matrix -- @tparam number sx The scaling in x direction. -- @tparam number sy The scaling in y direction. -- @return A new matrix describing the new transformation. function matrix:scale(sx, sy) return matrix.create_scale(sx, sy):multiply(self) end --- Rotate this matrix -- @tparam number angle The angle of the rotation in radians. -- @return A new matrix describing the new transformation. function matrix:rotate(angle) return matrix.create_rotate(angle):multiply(self) end --- Rotate a shape from a custom point -- @tparam number x The horizontal rotation point -- @tparam number y The vertical rotation point -- @tparam number angle The angle (in radiant: -2*math.pi to 2*math.pi) -- @return A transformation object function matrix:rotate_at(x, y, angle) return self * matrix.create_rotate_at(x, y, angle) end --- Invert this matrix -- @return A new matrix describing the inverse transformation. function matrix:invert() -- Beware of math! (I just copied the algorithm from cairo's source code) local a, b, c, d, x0, y0 = self.xx, self.yx, self.xy, self.yy, self.x0, self.y0 local inv_det = 1/(a*d - b*c) return matrix.create(inv_det * d, inv_det * -b, inv_det * -c, inv_det * a, inv_det * (c * y0 - d * x0), inv_det * (b * x0 - a * y0)) end --- Multiply this matrix with another matrix. -- The resulting matrix describes a transformation that is equivalent to first -- applying this transformation and then the transformation from `other`. -- Note that this function can also be called by directly multiplicating two -- matrix instances: `a * b == a:multiply(b)`. -- @tparam gears.matrix|cairo.Matrix other The other matrix to multiply with. -- @return The multiplication result. function matrix:multiply(other) local ret = matrix.create(self.xx * other.xx + self.yx * other.xy, self.xx * other.yx + self.yx * other.yy, self.xy * other.xx + self.yy * other.xy, self.xy * other.yx + self.yy * other.yy, self.x0 * other.xx + self.y0 * other.xy + other.x0, self.x0 * other.yx + self.y0 * other.yy + other.y0) return ret end --- Check if two matrices are equal. -- Note that this function cal also be called by directly comparing two matrix -- instances: `a == b`. -- @tparam gears.matrix|cairo.Matrix other The matrix to compare with. -- @return True if this and the other matrix are equal. function matrix:equals(other) for _, k in pairs{ "xx", "xy", "yx", "yy", "x0", "y0" } do if self[k] ~= other[k] then return false end end return true end --- Get a string representation of this matrix -- @return A string showing this matrix in column form. function matrix:tostring() return string.format("[[%g, %g], [%g, %g], [%g, %g]]", self.xx, self.yx, self.xy, self.yy, self.x0, self.y0) end --- Transform a distance by this matrix. -- The difference to @{matrix:transform_point} is that the translation part of -- this matrix is ignored. -- @tparam number x The x coordinate of the point. -- @tparam number y The y coordinate of the point. -- @treturn number The x coordinate of the transformed point. -- @treturn number The x coordinate of the transformed point. function matrix:transform_distance(x, y) return self.xx * x + self.xy * y, self.yx * x + self.yy * y end --- Transform a point by this matrix. -- @tparam number x The x coordinate of the point. -- @tparam number y The y coordinate of the point. -- @treturn number The x coordinate of the transformed point. -- @treturn number The y coordinate of the transformed point. function matrix:transform_point(x, y) x, y = self:transform_distance(x, y) return self.x0 + x, self.y0 + y end --- Calculate a bounding rectangle for transforming a rectangle by a matrix. -- @tparam number x The x coordinate of the rectangle. -- @tparam number y The y coordinate of the rectangle. -- @tparam number width The width of the rectangle. -- @tparam number height The height of the rectangle. -- @treturn number X coordinate of the bounding rectangle. -- @treturn number Y coordinate of the bounding rectangle. -- @treturn number Width of the bounding rectangle. -- @treturn number Height of the bounding rectangle. function matrix:transform_rectangle(x, y, width, height) -- Transform all four corners of the rectangle local x1, y1 = self:transform_point(x, y) local x2, y2 = self:transform_point(x, y + height) local x3, y3 = self:transform_point(x + width, y + height) local x4, y4 = self:transform_point(x + width, y) -- Find the extremal points of the result x = math.min(x1, x2, x3, x4) y = math.min(y1, y2, y3, y4) width = math.max(x1, x2, x3, x4) - x height = math.max(y1, y2, y3, y4) - y return x, y, width, height end --- Convert to a cairo matrix -- @treturn cairo.Matrix A cairo matrix describing the same transformation. function matrix:to_cairo_matrix() local ret = cairo.Matrix() ret:init(self.xx, self.yx, self.xy, self.yy, self.x0, self.y0) return ret end --- Convert to a cairo matrix -- @tparam cairo.Matrix mat A cairo matrix describing the sought transformation -- @treturn gears.matrix A matrix instance describing the same transformation. function matrix.from_cairo_matrix(mat) return matrix.create(mat.xx, mat.yx, mat.xy, mat.yy, mat.x0, mat.y0) end matrix_mt.__index = matrix matrix_mt.__newindex = error matrix_mt.__eq = matrix.equals matrix_mt.__mul = matrix.multiply matrix_mt.__tostring = matrix.tostring --- A constant for the identity matrix. matrix.identity = matrix.create(1, 0, 0, 1, 0, 0) return matrix -- vim: filetype=lua:expandtab:shiftwidth=4:tabstop=8:softtabstop=4:textwidth=80