253 51.5 型別狀態模式 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 254 51.6 embedded-hal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 254 51.7 probe-rs and cargo-embed Bare-Metal Rust The Bare-Metal Rust deep dive is a full day class on using Rust for bare-metal (embedded) development. Both microcontrollers and application processors are covered. 針對微控制器，您會需要預先購買 BBC not inlined upon use and have an actual associated memory location. This is useful for unsafe and embedded code, and the variable lives through the entirety of the program execution. When a globally-scoped

offset in each dimension into the final index. However, all the information we need for the loop is embedded in the type information of the arguments. This allows the compiler to move the iteration to compile called Sockets. Let's first create a simple server: julia> using Sockets julia> errormonitor(@async begin server = listen(2000) while true sock = accept(server) println("Hello World\n") end end) Task their usage is somewhat simpler than the raw Unix socket API. The first call to listen will create a server waiting for incoming connections on the specified port (2000) in this case. The same function may

offset in each dimension into the final index. However, all the information we need for the loop is embedded in the type information of the arguments. This allows the compiler to move the iteration to compile called Sockets. Let's first create a simple server: julia> using Sockets julia> errormonitor(@async begin server = listen(2000) while true sock = accept(server) println("Hello World\n") end end) Task their usage is somewhat simpler than the raw Unix socket API. The first call to listen will create a server waiting for incoming connections on the specified port (2000) in this case. The same function may

offset in each dimension into the final index. However, all the information we need for the loop is embedded in the type information of the arguments. This allows the compiler to move the iteration to compile called Sockets. Let's first create a simple server: julia> using Sockets julia> errormonitor(@async begin server = listen(2000) while true sock = accept(server) println("Hello World\n") end end) Task their usage is somewhat simpler than the raw Unix socket API. The first call to listen will create a server waiting for incoming connections on the specified port (2000) in this case. The same function may

offset in each dimension into the final index. However, all the information we need for the loop is embedded in the type information of the arguments. This allows the compiler to move the iteration to compile called Sockets. Let's first create a simple server: julia> using Sockets julia> errormonitor(@async begin server = listen(2000) while true sock = accept(server) println("Hello World\n") end end) Task their usage is somewhat simpler than the raw Unix socket API. The first call to listen will create a server waiting for incoming connections on the specified port (2000) in this case. The same function may

offset in each dimension into the final index. However, all the information we need for the loop is embedded in the type information of the arguments. This allows the compiler to move the iteration to compile called Sockets. Let's first create a simple server: julia> using Sockets julia> errormonitor(@async begin server = listen(2000) while true sock = accept(server) println("Hello World\n") end end) Task their usage is somewhat simpler than the raw Unix socket API. The first call to listen will create a server waiting for incoming connections on the specified port (2000) in this case. The same function may

offset in each dimension into the final index. However, all the information we need for the loop is embedded in the type information of the arguments. This allows the compiler to move the iteration to compile Sockets. Let's first create a simple server: julia> using Sockets julia> errormonitor(Threads.@spawn begin server = listen(2000) while true sock = accept(server) println("Hello World\n") end end) their usage is somewhat simpler than the raw Unix socket API. The first call to listen will create a server waiting for incoming connections on the specified port (2000) in this case. The same function may

offset in each dimension into the final index. However, all the information we need for the loop is embedded in the type information of the arguments. This allows the compiler to move the iteration to compile Sockets. Let's first create a simple server: julia> using Sockets julia> errormonitor(Threads.@spawn begin server = listen(2000) while true sock = accept(server) println("Hello World\n") end end) their usage is somewhat simpler than the raw Unix socket API. The first call to listen will create a server waiting for incoming connections on the specified port (2000) in this case. The same function may

offset in each dimension into the final index. However, all the information we need for the loop is embedded in the type information of the arguments. This allows the compiler to move the iteration to compile Sockets. Let's first create a simple server: julia> using Sockets julia> errormonitor(Threads.@spawn begin server = listen(2000) while true sock = accept(server) println("Hello World\n") end end) their usage is somewhat simpler than the raw Unix socket API. The first call to listen will create a server waiting for incoming connections on the specified port (2000) in this case. The same function may

offset in each dimension into the final index. However, all the information we need for the loop is embedded in the type information of the arguments. This allows the compiler to move the iteration to compile Sockets. Let's first create a simple server: julia> using Sockets julia> errormonitor(Threads.@spawn begin server = listen(2000) while true sock = accept(server) println("Hello World\n") end end) their usage is somewhat simpler than the raw Unix socket API. The first call to listen will create a server waiting for incoming connections on the specified port (2000) in this case. The same function may