points less than 255, and from Unicode rules for larger code points. However, matches that would cross the Unicode rules/non-Unicode rules boundary (ords 255/256) will not succeed. m Treat string as (Ptr{UInt8}, UInt32), hn, length(hn))Chapter 29 Handling Operating System Variation When writing cross-platform applications or libraries, it is often necessary to allow for differences between operating 5, 5), 2:6) == dot(1:5, reshape(1:25, 5, 5), 2:6) true LinearAlgebra.cross – Function. cross(x, y) ×(x,y) Compute the cross product of two 3-vectors. Examples julia> a = [0;1;0] 3-element Vector{Int64}:

points less than 255, and from Unicode rules for larger code points. However, matches that would cross the Unicode rules/non-Unicode rules boundary (ords 255/256) will not succeed. m Treat string as auto-generate Julia code from a C header file. Chapter 28 Handling Operating System Variation When writing cross-platform applications or libraries, it is often necessary to allow for differences between operating Mark U+02716 ✖ \:heavy_multiplica- tion_x: Heavy Multiplication X U+02720 ✠ \maltese Maltese Cross U+02728 \:sparkles: Sparkles U+0272A ✪ \circledstar Circled White Star U+02733 ✳ \:eight_spoked_asterisk:

points less than 255, and from Unicode rules for larger code points. However, matches that would cross the Unicode rules/non-Unicode rules boundary (ords 255/256) will not succeed. m Treat string as (Ptr{UInt8}, UInt32), hn, length(hn))Chapter 29 Handling Operating System Variation When writing cross-platform applications or libraries, it is often necessary to allow for differences between operating 5, 5), 2:6) == dot(1:5, reshape(1:25, 5, 5), 2:6) true LinearAlgebra.cross – Function. cross(x, y) ×(x,y) Compute the cross product of two 3-vectors. Examples julia> a = [0;1;0] 3-element Vector{Int64}:

points less than 255, and from Unicode rules for larger code points. However, matches that would cross the Unicode rules/non-Unicode rules boundary (ords 255/256) will not succeed. m Treat string as (Ptr{UInt8}, UInt32), hn, length(hn))Chapter 29 Handling Operating System Variation When writing cross-platform applications or libraries, it is often necessary to allow for differences between operating 5, 5), 2:6) == dot(1:5, reshape(1:25, 5, 5), 2:6) true LinearAlgebra.cross – Function. cross(x, y) ×(x,y) Compute the cross product of two 3-vectors. Examples julia> a = [0;1;0] 3-element Vector{Int64}:

points less than 255, and from Unicode rules for larger code points. However, matches that would cross the Unicode rules/non-Unicode rules boundary (ords 255/256) will not succeed. m Treat string as (Ptr{UInt8}, UInt32), hn, length(hn))Chapter 29 Handling Operating System Variation When writing cross-platform applications or libraries, it is often necessary to allow for differences between operating 5, 5), 2:6) == dot(1:5, reshape(1:25, 5, 5), 2:6) true LinearAlgebra.cross – Function. cross(x, y) ×(x,y) Compute the cross product of two 3-vectors. Examples julia> a = [0;1;0] 3-element Vector{Int64}:

points less than 255, and from Unicode rules for larger code points. However, matches that would cross the Unicode rules/non-Unicode rules boundary (ords 255/256) will not succeed. m Treat string as (Ptr{UInt8}, UInt32), hn, length(hn))Chapter 29 Handling Operating System Variation When writing cross-platform applications or libraries, it is often necessary to allow for differences between operating 5, 5), 2:6) == dot(1:5, reshape(1:25, 5, 5), 2:6) true LinearAlgebra.cross – Function. cross(x, y) ×(x,y) Compute the cross product of two 3-vectors. Examples julia> a = [0;1;0] 3-element Vector{Int64}:

points less than 255, and from Unicode rules for larger code points. However, matches that would cross the Unicode rules/non-Unicode rules boundary (ords 255/256) will not succeed. m Treat string as (Ptr{UInt8}, UInt32), hn, length(hn))Chapter 28 Handling Operating System Variation When writing cross-platform applications or libraries, it is often necessary to allow for differences between operating 5, 5), 2:6) == dot(1:5, reshape(1:25, 5, 5), 2:6) true LinearAlgebra.cross – Function. cross(x, y) ×(x,y) Compute the cross product of two 3-vectors. Examples julia> a = [0;1;0] 3-element Vector{Int64}:

points less than 255, and from Unicode rules for larger code points. However, matches that would cross the Unicode rules/non-Unicode rules boundary (ords 255/256) will not succeed. m Treat string as (Ptr{UInt8}, UInt32), hn, length(hn))Chapter 28 Handling Operating System Variation When writing cross-platform applications or libraries, it is often necessary to allow for differences between operating 5, 5), 2:6) == dot(1:5, reshape(1:25, 5, 5), 2:6) true LinearAlgebra.cross – Function. cross(x, y) ×(x,y) Compute the cross product of two 3-vectors. Examples julia> a = [0;1;0] 3-element Vector{Int64}:

and from Unicode rules for larger code points. However, matches CHAPTER 7. STRINGS 60 that would cross the Unicode rules/non-Unicode rules boundary (ords 255/256) will not succeed. m Treat string as (Ptr{UInt8}, UInt32), hn, length(hn)) Chapter 28 Handling Operating System Variation When writing cross-platform applications or libraries, it is often necessary to allow for differences between operating Mark U+02716 ✖ \:heavy_multiplica- tion_x: Heavy Multiplication X U+02720 ✠ \maltese Maltese Cross U+02728 \:sparkles: Sparkles U+0272A ✪ \circledstar Circled White Star U+02733 ✳ \:eight_spoked_aster-

and from Unicode rules for larger code points. However, matches CHAPTER 7. STRINGS 60 that would cross the Unicode rules/non-Unicode rules boundary (ords 255/256) will not succeed. m Treat string as (Ptr{UInt8}, UInt32), hn, length(hn)) Chapter 28 Handling Operating System Variation When writing cross-platform applications or libraries, it is often necessary to allow for differences between operating Mark U+02716 ✖ \:heavy_multiplica- tion_x: Heavy Multiplication X U+02720 ✠ \maltese Maltese Cross U+02728 \:sparkles: Sparkles U+0272A ✪ \circledstar Circled White Star U+02733 ✳ \:eight_spoked_aster-