|Version 15 (modified by Michael D. Adams, 9 years ago) (diff)|
GHC Commentary: The Code Generator
Storage manager representations
The code generator needs to know the layout of heap objects, because it generates code that accesses and constructs those heap objects. The runtime also needs to know about the layout of heap objects, because it contains the garbage collector. How can we share the definition of storage layout such that the code generator and the runtime both have access to it, and so that we don't have to keep two independent definitions in sync?
Currently we solve the problem this way:
- C types representing heap objects are defined in the C header files, see for example includes/Closures.h.
- A C program, includes/mkDerivedConstants.c, #includes the runtime headers. This program is built and run when you type make or make boot in includes/. It is run twice: once to generate includes\DerivedConstants.h, and again to generate includes/GHCConstants.h.
- The file DerivedConstants.h contains lots of #defines like this:
#define OFFSET_StgTSO_why_blocked 18which says that the offset to the why_blocked field of an StgTSO is 18 bytes. This file is #included into includes/Cmm.h, so these offests are available to the hand-written .cmm files.
- The file GHCConstants.h contains similar definitions:
oFFSET_StgTSO_why_blocked = 18::IntThis time the definitions are in Haskell syntax, and this file is #included directly into compiler/main/Constants.lhs. This is the way that these offsets are made available to GHC's code generator.
Generated Cmm Naming Convention
Labels generated by the code generator are of the form <name>_<type> where <name> is <Module>_<name> for external names and <unique> for internal names. <type> is one of the following:
- Info table
- Static reference table
- Static reference table descriptor
- Entry code (function, closure)
- Slow entry code (if any)
- Direct return address
- Vector table
- Case alternative (tag n)
- Default case alternative
- Large bitmap vector
- Static closure
- Dynamic Constructor entry code
- Dynamic Constructor info table
- Static Constructor entry code
- Static Constructor info table
- Selector info table
- Selector entry code
- Cost centre
- Cost centre stack
Many of these distinctions are only for documentation reasons. For example, _ret is only distinguished from _entry to make it easy to tell whether a code fragment is a return point or a closure/function entry.
Top level, only exports codeGen.
Called from HscMain for each module that needs to be converted from Stg to Cmm.
For each such module codeGen does three things:
- cgTopBinding for the StgBinding
- cgTyCon for the TyCon (These are constructors not constructor calls).
- mkModuleInit for the module
mkModuleInit generates several boilerplate initialization functions that:
- regiser the module,
- creates an Hpc table,
- setup its profiling info (InitConstCentres, code coverage info initHpc), and
- calls the initialization functions of the modules it imports.
If neither SCC profiling or HPC are used, then the initialization code short circuits to return.
If the module has already been initialized, the initialization function just returns.
The Ghc.TopHandler and Ghc.Prim modules get special treatment.
cgTopBinding is a small wrapper around cgTopRhs which in turn disptaches to:
- cgTopRhsCons for StgRhsCons (these are bindings of constructor applications not constructors themselves) and
- cgTopRhsClosure for StgRhsClosure.
cgTopRhsCons and cgTopRhsClosure are located in CgCon and CgClosure which are the primary modules called by CodeGen.
The monad that most of codeGen operates inside
- (could be Writer?)
Called by CgClosure and CgCon.
Since everything in STG is an expression, almost everything branches off from here.
This module exports only one function cgExpr, which for the most part just dispatches to other functions to handle each specific constructor in StgExpr.
Here are the core functions that each constructor is disptached to (though some may have little helper functions called in addition to the core function):
- Calls to cgTailCall in CgTailCall
- Calls to cgReturnDataCon in CgCon
- Calls to cgLit in CgUtil and performPrimReturn in CgTailCall
- Is a bit more complicated see below.
- Calls to cgCase in CgCase
- Calls to cgRhs in CgExpr
- Calls to cgLetNoEscapeBindings in CgExpr, but with a little bit of wrapping by nukeDeadBindings and saveVolatileVarsAndRegs.
- Calls to emitSetCCC in CgProf
- Calls to cgTickBox in CgHpc
- Does not have a case because it is only for CoreToStg's work.
Some of these cases call to functions defined in cgExpr. This is because they need a little bit of wrapping and processing before calling out to their main worker function.
- For StgRhsCon calls out to buildDynCon in CgCon.
- For StgRhsClosure calls out to mkRhsClosure. In turn, mkRhsClosure calls out to cgStdRhsClosure for selectors and thunks, and calls out to cgRhsClosure in the default case. Both these are defined in CgClosure.
- Wraps a call to cgLetNoEscapeRhs with addBindsC depending on whether it is called on a recursive or a non-recursive binding. In turn cgLetNoEscapeRhs wraps cgLetNoEscapeClosure defined in CgLetNoEscapeClosure.
StgOpApp has a number of sub-cases.
- StgPrimOp of a TagToEnumOp
- StgPrimOp that is primOpOutOfLine
- StgPrimOp that returns Void
- StgPrimOp that returns a single primitive
- StgPrimOp that returns an unboxed tuple
- StgPrimOp that returns an enumeration type
(It appears that non-foreign-call, inline PrimOps are not allowed to return complex data types (e.g. a |Maybe|), but this fact needs to be verified.)
Each of these cases centers around one of these three core calls:
- emitForeignCall in CgForeignCall
- tailCallPrimOp in CgTailCall
- cgPrimOp in CgPrimOp
There is also a little bit of argument and return marshelling with the following functions
- Argument marshelling
- shimForeignCallArg, getArgAmods
- Return marshelling
- dataReturnConvPrim, primRepToCgRep, newUnboxedTupleRegs
- Performing the return
- emitReturnInstr, performReturn, returnUnboxedTuple, ccallReturnUnboxedTuple
In summary the modules that get called in order to handle a specific expression case are:
Also called for top level bindings by CodeGen
- for StgConApp and the StgRhsCon part of StgLet
- for the StgRhsClosure part of StgLet
Core code generation
- for StgApp, StgLit, and StgOpApp
- for StgOpApp
- for StgLetNoEscape
- for StgCase
Profiling and Code coverage related
- for StgSCC
- for StgTick
Utility modules that happen to have the functions for code generation
- for StgOpApp
- for cgLit
Note that the first two are the same modules that are called for top level bindings by CodeGen, and the last two are really utility modules, but they happen to have the functions needed for those code generation cases.
Memory and Register Management
- Module for CgBindings which maps variable names to all the volitile or stable locations where they are stored (e.g. register, stack slot, computed from other expressions, etc.) Provides the addBindC, modifyBindC and getCgIdInfo functions for adding, modifying and looking up bindings.
- Mostly utility functions for allocating and freeing stack slots. But also has things on setting up update frames.
- Functions for allocating objects that appear on the heap such as closures and constructors. Also includes code for stack and heap checks and emitSetDynHdr.
Function Calls and Parameter Passing
(Note: these will largely go away once CPS conversion is fully implemented.)
- CgPrimOp, CgTailCall, CgForeignCall
- Handle different types of calls.
- Use by the others in this category to determine liveness and to select in what registers and stack locations arguments and return values get stored.
- Utility functions for making bitmaps (e.g. mkBitmap with type [Bool] -> Bitmap)
- Stores info about closures and bindings. Includes information about memory layout, how to call a binding (LambdaFormInfo) and information used to build the info table (ClosureInfo).
- Storage manager representation of closures. Part of ClosureInfo but kept separate to "keep nhc happy."
Special runtime support
- Ticky-ticky profiling
- Cost-centre profiling
- Support for the Haskell Program Coverage (hpc) toolkit, inside GHC.
- Code generation for GranSim (GRAN) and parallel (PAR). All the functions are dead stubs except granYield and granFetchAndReschedule.