Julia SSA-form IR
With the new IR representation, the compiler learned to handle four new IR nodes, Phi nodes, Pi nodes as well as PhiC nodes and Upsilon nodes (the latter two are only used for exception handling).
Phi nodes are part of generic SSA abstraction (see the link above if you’re not familiar with the concept). In the Julia IR, these nodes are represented as:
where we ensure that both vectors always have the same length. In the canonical representation (the one handled by codegen and the interpreter), the edge values indicate come-from statement numbers (i.e. if edge has an entry of , there must be a goto
, gotoifnot
or implicit fall through from statement 15
that targets this phi node). Values are either SSA values or constants. It is also possible for a value to be unassigned if the variable was not defined on this path. However, undefinedness checks get explicitly inserted and represented as booleans after middle end optimizations, so code generators may assume that any use of a Phi node will have an assigned value in the corresponding slot. It is also legal for the mapping to be incomplete, i.e. for a Phi node to have missing incoming edges. In that case, it must be dynamically guaranteed that the corresponding value will not be used.
PiNodes encode statically proven information that may be implicitly assumed in basic blocks dominated by a given pi node. They are conceptually equivalent to the technique introduced in the paper or the predicate info nodes in LLVM. To see how they work, consider, e.g.
%x::Union{Int, Float64} # %x is some Union{Int, Float64} typed ssa value
if isa(x, Int)
# use x
else
# use x
end
Pi nodes are generally ignored in the interpreter, since they don’t have any effect on the values, but they may sometimes lead to code generation in the compiler (e.g. to change from an implicitly union split representation to a plain unboxed representation). The main usefulness of PiNodes stems from the fact that path conditions of the values can be accumulated simply by def-use chain walking that is generally done for most optimizations that care about these conditions anyway.
Exception handling complicates the SSA story moderately, because exception handling introduces additional control flow edges into the IR across which values must be tracked. One approach to do so, which is followed by LLVM is to make calls which may throw exceptions into basic block terminators and add an explicit control flow edge to the catch handler:
invoke @function_that_may_throw() to label %regular unwind to %catch
# Control flow continues here
catch:
# Exceptions go here
However, this is problematic in a language like julia where at the start of the optimization pipeline, we do not know which calls throw. We would have to conservatively assume that every call (which in julia is every statement) throws. This would have several negative effects. On the one hand, it would essentially reduce the scope of every basic block to a single call, defeating the purpose of having operations be performed at the basic block level. On the other hand, every catch basic block would have n*m
phi node arguments (n
, the number of statements in the critical region, m
the number of live values through the catch block). To work around this, we use a combination of Upsilon
and PhiC
(the C standing for , written φᶜ
in the IR pretty printer, because unicode subscript c is not available) nodes. There are several ways to think of these nodes, but perhaps the easiest is to think of each PhiC
as a load from a unique store-many, read-once slot, with Upsilon
being the corresponding store operation. The PhiC
has an operand list of all the upsilon nodes that store to its implicit slot. The Upsilon
nodes however, do not record which PhiC
node they store to. This is done for more natural integration with the rest of the SSA IR. E.g. if there are no more uses of a PhiC
node, it is safe to delete it, and the same is true of an Upsilon
node. In most IR passes, PhiC
nodes can be treated like Phi
nodes. One can follow use-def chains through them, and they can be lifted to new PhiC
nodes and new Upsilon
nodes (in the same places as the original Upsilon
nodes). The result of this scheme is that the number of Upsilon
nodes (and PhiC
arguments) is proportional to the number of assigned values to a particular variable (before SSA conversion), rather than the number of statements in the critical region.
To see this scheme in action, consider the function
1 ─ nothing::Nothing
2 ─ %2 = $(Expr(:enter, #4))
3 ─ %3 = ϒ (false)
│ %4 = ϒ (#undef)
│ %5 = ϒ (1)
│ %6 = ϒ (true)
│ invoke Main.opaque()::Any
│ %9 = ϒ (true)
│ invoke Main.error()::Union{}
└── $(Expr(:unreachable))::Union{}
4 ┄ %13 = φᶜ (%3, %6, %9)::Bool
│ %14 = φᶜ (%4, %7, %10)::Core.Compiler.MaybeUndef(Int64)
│ %15 = φᶜ (%5)::Core.Const(1)
└── $(Expr(:leave, 1))
5 ─ $(Expr(:pop_exception, :(%2)))::Any
│ $(Expr(:throw_undef_if_not, :y, :(%13)))::Any
│ %19 = Core.tuple(%15, %14)
└── return %19
Note in particular that every value live into the critical region gets an upsilon node at the top of the critical region. This is because catch blocks are considered to have an invisible control flow edge from outside the function. As a result, no SSA value dominates the catch blocks, and all incoming values have to come through a φᶜ
node.
The main SSAIR
data structure is worthy of discussion. It draws inspiration from LLVM and Webkit’s B3 IR. The core of the data structure is a flat vector of statements. Each statement is implicitly assigned an SSA value based on its position in the vector (i.e. the result of the statement at idx 1 can be accessed using SSAValue(1)
etc). For each SSA value, we additionally maintain its type. Since, SSA values are definitionally assigned only once, this type is also the result type of the expression at the corresponding index. However, while this representation is rather efficient (since the assignments don’t need to be explicitly encoded), it of course carries the drawback that order is semantically significant, so reorderings and insertions change statement numbers. Additionally, we do not keep use lists (i.e. it is impossible to walk from a def to all its uses without explicitly computing this map–def lists however are trivial since you can look up the corresponding statement from the index), so the LLVM-style RAUW (replace-all-uses-with) operation is unavailable.
Instead, we do the following:
- We keep a separate buffer of nodes to insert (including the position to insert them at, the type of the corresponding value and the node itself). These nodes are numbered by their occurrence in the insertion buffer, allowing their values to be immediately used elsewhere in the IR (i.e. if there are 12 statements in the original statement list, the first new statement will be accessible as
SSAValue(13)
). - RAUW style operations are performed by setting the corresponding statement index to the replacement value.
- Statements are erased by setting the corresponding statement to
nothing
(this is essentially just a special-case convention of the above.
There is a compact!
function that compacts the above data structure by performing the insertion of nodes in the appropriate place, trivial copy propagation, and renaming of uses to any changed SSA values. However, the clever part of this scheme is that this compaction can be done lazily as part of the subsequent pass. Most optimization passes need to walk over the entire list of statements, performing analysis or modifications along the way. We provide an IncrementalCompact
iterator that can be used to iterate over the statement list. It will perform any necessary compaction and return the new index of the node, as well as the node itself. It is legal at this point to walk def-use chains, as well as make any modifications or deletions to the IR (insertions are disallowed however).