The machine instructions generated by a high-level language will be appropriate for the calling conventions for libraries providing those calls you make, including any system calls (albeit these are usually wrapped in a userspace library somewhere, so specifics about how to make a system call might not be necessary).
Additionally, it will be appropriate for the targetted instruction set architecture, with a few exceptions (care must be taken for example, about assumptions regarding pointer sizes, primitive types, structure layouts, class implementations in C++ etc.).
The file format will dictate the necessary hooks/publically visible functions and data to enable the operating system to execute your code as a process, and to bootstrap the process to the required state. If you're familiar with development for C/C++ under Windows, the concept of subsystem dictates the level of bootstrapping, resources provided, and entry point signature (normally
main(int, char **) on most systems).
There are some good examples of how the choice of high-level language, instruction set architecture, and executable file format might affect the ability to run a binary on any given system:
Assembly languages must code for a specific ISA. They use instructions that are specific to a family of CPU types. These instructions may work on other families of CPUs, if those CPUs support the given instruction set. For instance x86 code will work to a degree, on an amd64 operating system, and definitely work on an amd64 CPU running an x86 operating system.
C abstracts much of the specifics of an ISA. A few obvious exceptions include pointer sizes and endianness. Various well-known interfaces, will be provided to an expected level via libc, such as
fopen, and others. These include the expected register and stack states in order to make these calls, enabling C code to work on different operating systems and architectures without change. Other interfaces can be provided, either directly or by wrapping platform-specific into the expected interface to increase the portability of C code.
Python, and other similar "virtualized" languages operate at yet another level of abstraction, and again with a few exceptions, for instance features that don't exist on particular platforms, or character encoding differences, can run without modification on numerous systems. This is achieved by providing a uniform interface for many different ISA and operating system combinations, at the expense of performance and executable size.