Blender 3.0 Reference Manual Welcome to the manual for Blender, the free and open source 3D creation suite. 起步⼊⾨ Sections 起步⼊⾨ 使⽤者介⾯ 編輯器 Scenes & Objects 建模 Sculpting & Painting Grease Pencil Animation application bundle, create a folder named config in the LOCAL directory. ./Blender.app/Contents/Resources/3.0/config/ Updating on macOS On macOS there are various ways of updating Blender. This section covers is the main interface for organizing and using assets. The Asset Browser was introduced in Blender 3.0, and will be improved and expanded over multiple upcoming releases. See also Asset Libraries For

the sqrt and + functions can be composed like this:CHAPTER 8. FUNCTIONS 85 julia> (sqrt ∘ +)(3, 6) 3.0 This adds the numbers first, then finds the square root of the result. The next example composes 3.7416573867739413 julia> 1:3 .|> x -> x^2 |> sum |> sqrt 3-element Vector{Float64}: 1.0 2.0 3.0CHAPTER 8. FUNCTIONS 86 8.18 Dot Syntax for Vectorizing Functions In technical-computing languages can be applied to all elements in the vector A like so: julia> A = [1.0, 2.0, 3.0] 3-element Vector{Float64}: 1.0 2.0 3.0 julia> sin.(A) 3-element Vector{Float64}: 0.8414709848078965 0.9092974268256817

the sqrt and + functions can be composed like this:CHAPTER 8. FUNCTIONS 85 julia> (sqrt ∘ +)(3, 6) 3.0 This adds the numbers first, then finds the square root of the result. The next example composes 3.7416573867739413 julia> 1:3 .|> x -> x^2 |> sum |> sqrt 3-element Vector{Float64}: 1.0 2.0 3.0CHAPTER 8. FUNCTIONS 86 8.18 Dot Syntax for Vectorizing Functions In technical-computing languages can be applied to all elements in the vector A like so: julia> A = [1.0, 2.0, 3.0] 3-element Vector{Float64}: 1.0 2.0 3.0 julia> sin.(A) 3-element Vector{Float64}: 0.8414709848078965 0.9092974268256817

\circ. For example, the sqrt and + functions can be composed like this: julia> (sqrt ∘ +)(3, 6) 3.0 This adds the numbers first, then finds the square root of the result. The next example composes 3.7416573867739413 julia> 1:3 .|> x -> x^2 |> sum |> sqrt 3-element Vector{Float64}: 1.0 2.0 3.0 9.18 Dot Syntax for Vectorizing Functions In technical-computing languages, it is common to have can be applied to all elements in the vector A like so: julia> A = [1.0, 2.0, 3.0] 3-element Vector{Float64}: 1.0 2.0 3.0 julia> sin.(A) 3-element Vector{Float64}: 0.8414709848078965 0.9092974268256817

\circ. For example, the sqrt and + functions can be composed like this: julia> (sqrt ∘ +)(3, 6) 3.0 This adds the numbers first, then finds the square root of the result. The next example composes 3.7416573867739413 julia> 1:3 .|> x -> x^2 |> sum |> sqrt 3-element Vector{Float64}: 1.0 2.0 3.0 9.18 Dot Syntax for Vectorizing Functions In technical-computing languages, it is common to have can be applied to all elements in the vector A like so: julia> A = [1.0, 2.0, 3.0] 3-element Vector{Float64}: 1.0 2.0 3.0 julia> sin.(A) 3-element Vector{Float64}: 0.8414709848078965 0.9092974268256817

\circ. For example, the sqrt and + functions can be composed like this: julia> (sqrt ∘ +)(3, 6) 3.0 This adds the numbers first, then finds the square root of the result. The next example composes 3.7416573867739413 julia> 1:3 .|> x -> x^2 |> sum |> sqrt 3-element Vector{Float64}: 1.0 2.0 3.0 9.18 Dot Syntax for Vectorizing Functions In technical-computing languages, it is common to have can be applied to all elements in the vector A like so: julia> A = [1.0, 2.0, 3.0] 3-element Vector{Float64}: 1.0 2.0 3.0 julia> sin.(A) 3-element Vector{Float64}: 0.8414709848078965 0.9092974268256817

\circ. For example, the sqrt and + functions can be composed like this: julia> (sqrt ∘ +)(3, 6) 3.0 This adds the numbers first, then finds the square root of the result. The next example composes 3.7416573867739413 julia> 1:3 .|> x -> x^2 |> sum |> sqrt 3-element Vector{Float64}: 1.0 2.0 3.0 9.18 Dot Syntax for Vectorizing Functions In technical-computing languages, it is common to have can be applied to all elements in the vector A like so: julia> A = [1.0, 2.0, 3.0] 3-element Vector{Float64}: 1.0 2.0 3.0 julia> sin.(A) 3-element Vector{Float64}: 0.8414709848078965 0.9092974268256817

\circ. For example, the sqrt and + functions can be composed like this: julia> (sqrt ∘ +)(3, 6) 3.0 This adds the numbers first, then finds the square root of the result. The next example composes 3.7416573867739413 julia> 1:3 .|> x -> x^2 |> sum |> sqrt 3-element Vector{Float64}: 1.0 2.0 3.0 9.18 Dot Syntax for Vectorizing Functions In technical-computing languages, it is common to have can be applied to all elements in the vector A like so: julia> A = [1.0, 2.0, 3.0] 3-element Vector{Float64}: 1.0 2.0 3.0 julia> sin.(A) 3-element Vector{Float64}: 0.8414709848078965 0.9092974268256817

\circ. For example, the sqrt and + functions can be composed like this: julia> (sqrt ∘ +)(3, 6) 3.0 This adds the numbers first, then finds the square root of the result. The next example composes 3.7416573867739413 julia> 1:3 .|> x -> x^2 |> sum |> sqrt 3-element Vector{Float64}: 1.0 2.0 3.0 9.18 Dot Syntax for Vectorizing Functions In technical-computing languages, it is common to have can be applied to all elements in the vector A like so: julia> A = [1.0, 2.0, 3.0] 3-element Vector{Float64}: 1.0 2.0 3.0 julia> sin.(A) 3-element Vector{Float64}: 0.8414709848078965 0.9092974268256817

\circ. For example, the sqrt and + functions can be composed like this: julia> (sqrt ∘ +)(3, 6) 3.0 This adds the numbers first, then finds the square root of the result. The next example composes 3.7416573867739413 julia> 1:3 .|> x -> x^2 |> sum |> sqrt 3-element Vector{Float64}: 1.0 2.0 3.0 9.18 Dot Syntax for Vectorizing Functions In technical-computing languages, it is common to have can be applied to all elements in the vector A like so: julia> A = [1.0, 2.0, 3.0] 3-element Vector{Float64}: 1.0 2.0 3.0 julia> sin.(A) 3-element Vector{Float64}: 0.8414709848078965 0.9092974268256817