How can I allocate memory on Linux without overcommitting
That is a loaded question, or at least an incorrect one. The question is based on an incorrect assumption, which makes answering the stated question irrelevant at best, misleading at worst.
Memory overcommitment is a system-wide policy -- because it determines how much virtual memory is made available to processes --, and not something a process can decide for itself.
It is up to the system administrator to determine whether memory is overcommitted or not. In Linux, the policy is quite tunable (see e.g. /proc/sys/vm/overcommit_memory
in man 5 proc. There is nothing a process can do during
allocation that would affect the memory overcommit policy.
OP also seems interested in making their processes immune to the out-of-memory killer (OOM killer) in Linux. (OOM killer in Linux is a technique used to relieve memory pressure, by killing processes, and thus releasing their resources back to the system.)
This too is an incorrect approach, because the OOM killer is a heuristic process, whose purpose is not to "punish or kill badly behaving processes", but to keep the system operational. This facility is also quite tunable in Linux, and the system admin can even tune the likelihood of each process being killed in high memory pressure situations. Other than the amount of memory used by a process, it is not up to the process to affect whether the OOM killer will kill it during out-of-memory situations; it too is a policy issue managed by the system administrator, and not the processes themselves.
I assumed that the actual question the OP is trying to solve, is how to write Linux applications or services that can dynamically respond to memory pressure, other than just dying (due to SIGSEGV or by the OOM killer). The answer to this is you do not -- you let the system administrator worry about what is important to them, in the workload they have, instead --, unless your application or service is one that uses lots and lots of memory, and is therefore likely to unfairly killed during high memory pressure. (Especially if the dataset is sufficiently large to require enabling much larger amount of swap than would otherwise be enabled, causing a higher risk of a swap storm and late-but-too-strong OOM killer.)
The solution, or at least the approach that works, is to memory-lock the critical parts (or even the entire application/service, if it works on sensitive data that should not be swapped to disk), or to use a memory map with a dedicated backing file. (For the latter, here is an example I wrote in 2011, that manipulates a terabyte-sized data set.)
The OOM killer can still kill the process, and a SIGSEGV still occur (due to say an internal allocation by a library function that the kernel fails to provide RAM backing to), unless all of the application is locked to RAM, but at least the service/process is no longer unfairly targeted, just because it uses lots of memory.
It is possible to catch the SIGSEGV signal (that occurs when there is no memory available to back the virtual memory), but thus far I have not seen an use case that would warrant the code complexity and maintenance effort required.
In summary, the proper answer to the stated question is no, don't do that.