HiPE and execution of HiPE compiled code only have limited support by the OTP team at Ericsson. The OTP team only does limited maintenance of HiPE and does not actively develop HiPE. HiPE is mainly supported by the HiPE team at Uppsala University.
The normal way to native-compile an Erlang module using HiPE is to include the atom native in the Erlang compiler options, as in:
1> c(my_module, [native]).
Options to the HiPE compiler are then passed as follows:
1> c(my_module, [native,{hipe,Options}]).
For on-line help in the Erlang shell, call
The HiPE compiler is in general compliant with the normal BEAM compiler, with respect to semantic behavior. There are however features in the BEAM compiler and the runtime system that have limited or no support for HiPE compiled modules.
Stack traces returned from
Source code line numbers in stack traces are also not supported by HiPE compiled functions.
Erlang call trace is not supported by HiPE. Calling
Modules compiled with HiPE cannot call
Modules compiled with HiPE cannot use
The HiPE compiler does in general produce faster code than the BEAM compiler. There are however some situation when HiPE compiled code will perform worse than BEAM code.
Every time a process changes from executing code in a HiPE compiled module to a BEAM compiled module (or vice versa), it will do a mode switch. This involves a certain amount of CPU overhead which can have a negative net impact if the process is switching back and forth without getting enough done in each mode.
The BEAM compiler can do an optimization when a receive statement is only waiting for messages containing a reference created before the receive. All messages that existed in the queue when the reference was created will be bypassed, as they cannot possibly contain the reference. HiPE currently has an optimization similar this, but it is not guaranteed to bypass all messages. In the worst case scenario, it cannot bypass any messages at all.
An example of this is when
The condition for determining whether a garbage collection is needed or not has changed in later releases. HiPE has not been updated regarding this which may cause premature garbage collections after BIF calls.
BEAM checks the reduction count and schedules out the executing process if needed both when calling a function and when returning from a function call that was not called using a tail call. HiPE only checks the reduction count when calling a function.
The runtime system might need to schedule out a process in order to reclaim memory. If the process isn't scheduled out soon after the process has entered this state, memory consumption will quickly grow. Maintaining this state is also quite expensive performance wise.
Processes executing code that performs large recursions and produce data after returning from recursive calls may have to be scheduled out when returning from a function call. Since HiPE does not check reductions on returns, processes executing such HiPE compiled code may cause huge peeks in memory consumption as well as severe performance degradation.
The process signaling improvements made in ERTS version
10.0 moved potentially significant amounts of work into the
receive statement from other places. In order to account for
this work, the reduction count should be bumped on the
executing process. Reductions are not bumped when entering
the