Optimize a SPIR-V binary file.
USAGE: spirv-opt [options] [<input>] -o <output>
The SPIR-V binary is read from <input>. If no file is specified,
or if <input> is "-", then the binary is read from standard input.
if <output> is "-", then the optimized output is written to
standard output.
NOTE: The optimizer is a work in progress.
Options (in lexicographical order):
--amd-ext-to-khr
Replaces the extensions VK_AMD_shader_ballot, VK_AMD_gcn_shader,
and VK_AMD_shader_trinary_minmax with equivalent code using core
instructions and capabilities.
--before-hlsl-legalization
Forwards this option to the validator. See the validator help
for details.
--ccp
Apply the conditional constant propagation transform. This will
propagate constant values throughout the program, and simplify
expressions and conditional jumps with known predicate
values. Performed on entry point call tree functions and
exported functions.
--cfg-cleanup
Cleanup the control flow graph. This will remove any unnecessary
code from the CFG like unreachable code. Performed on entry
point call tree functions and exported functions.
--combine-access-chains
Combines chained access chains to produce a single instruction
where possible.
--compact-ids
Remap result ids to a compact range starting from %1 and without
any gaps.
--convert-local-access-chains
Convert constant index access chain loads/stores into
equivalent load/stores with inserts and extracts. Performed
on function scope variables referenced only with load, store,
and constant index access chains in entry point call tree
functions.
--convert-relaxed-to-half
Convert all RelaxedPrecision arithmetic operations to half
precision, inserting conversion operations where needed.
Run after function scope variable load and store elimination
for better results. Simplify-instructions, redundancy-elimination
and DCE should be run after this pass to eliminate excess
conversions. This conversion is useful when the target platform
does not support RelaxedPrecision or ignores it. This pass also
removes all RelaxedPrecision decorations.
--copy-propagate-arrays
Does propagation of memory references when an array is a copy of
another. It will only propagate an array if the source is never
written to, and the only store to the target is the copy.
--decompose-initialized-variables
Decomposes initialized variable declarations into a declaration
followed by a store of the initial value. This is done to work
around known issues with some Vulkan drivers for initialize
variables.
--descriptor-scalar-replacement
Replaces every array variable |desc| that has a DescriptorSet
and Binding decorations with a new variable for each element of
the array. Suppose |desc| was bound at binding |b|. Then the
variable corresponding to |desc[i]| will have binding |b+i|.
The descriptor set will be the same. All accesses to |desc|
must be in OpAccessChain instructions with a literal index for
the first index.
--eliminate-dead-branches
Convert conditional branches with constant condition to the
indicated unconditional branch. Delete all resulting dead
code. Performed only on entry point call tree functions.
--eliminate-dead-code-aggressive
Delete instructions which do not contribute to a function's
output. Performed only on entry point call tree functions.
--eliminate-dead-const
Eliminate dead constants.
--eliminate-dead-functions
Deletes functions that cannot be reached from entry points or
exported functions.
--eliminate-dead-inserts
Deletes unreferenced inserts into composites, most notably
unused stores to vector components, that are not removed by
aggressive dead code elimination.
--eliminate-dead-variables
Deletes module scope variables that are not referenced.
--eliminate-insert-extract
DEPRECATED. This pass has been replaced by the simplification
pass, and that pass will be run instead.
See --simplify-instructions.
--eliminate-local-multi-store
Replace stores and loads of function scope variables that are
stored multiple times. Performed on variables referenceed only
with loads and stores. Performed only on entry point call tree
functions.
--eliminate-local-single-block
Perform single-block store/load and load/load elimination.
Performed only on function scope variables in entry point
call tree functions.
--eliminate-local-single-store
Replace stores and loads of function scope variables that are
only stored once. Performed on variables referenceed only with
loads and stores. Performed only on entry point call tree
functions.
--flatten-decorations
Replace decoration groups with repeated OpDecorate and
OpMemberDecorate instructions.
--fold-spec-const-op-composite
Fold the spec constants defined by OpSpecConstantOp or
OpSpecConstantComposite instructions to front-end constants
when possible.
--freeze-spec-const
Freeze the values of specialization constants to their default
values.
--graphics-robust-access
Clamp indices used to access buffers and internal composite
values, providing guarantees that satisfy Vulkan's
robustBufferAccess rules.
--if-conversion
Convert if-then-else like assignments into OpSelect.
--inline-entry-points-exhaustive
Exhaustively inline all function calls in entry point call tree
functions. Currently does not inline calls to functions with
early return in a loop.
--legalize-hlsl
Runs a series of optimizations that attempts to take SPIR-V
generated by an HLSL front-end and generates legal Vulkan SPIR-V.
The optimizations are:
wrap-opkill
eliminate-dead-branches
merge-return
inline-entry-points-exhaustive
eliminate-dead-functions
private-to-local
fix-storage-class
eliminate-local-single-block
eliminate-local-single-store
eliminate-dead-code-aggressive
scalar-replacement=0
eliminate-local-single-block
eliminate-local-single-store
eliminate-dead-code-aggressive
ssa-rewrite
eliminate-dead-code-aggressive
ccp
loop-unroll
eliminate-dead-branches
simplify-instructions
eliminate-dead-code-aggressive
copy-propagate-arrays
vector-dce
eliminate-dead-inserts
reduce-load-size
eliminate-dead-code-aggressive
Note this does not guarantee legal code. This option passes the
option --relax-logical-pointer to the validator.
--local-redundancy-elimination
Looks for instructions in the same basic block that compute the
same value, and deletes the redundant ones.
--loop-fission
Splits any top level loops in which the register pressure has
exceeded a given threshold. The threshold must follow the use of
this flag and must be a positive integer value.
--loop-fusion
Identifies adjacent loops with the same lower and upper bound.
If this is legal, then merge the loops into a single loop.
Includes heuristics to ensure it does not increase number of
registers too much, while reducing the number of loads from
memory. Takes an additional positive integer argument to set
the maximum number of registers.
--loop-invariant-code-motion
Identifies code in loops that has the same value for every
iteration of the loop, and move it to the loop pre-header.
--loop-unroll
Fully unrolls loops marked with the Unroll flag
--loop-unroll-partial
Partially unrolls loops marked with the Unroll flag. Takes an
additional non-0 integer argument to set the unroll factor, or
how many times a loop body should be duplicated
--loop-peeling
Execute few first (respectively last) iterations before
(respectively after) the loop if it can elide some branches.
--loop-peeling-threshold
Takes a non-0 integer argument to set the loop peeling code size
growth threshold. The threshold prevents the loop peeling
from happening if the code size increase created by
the optimization is above the threshold.
--max-id-bound=<n>
Sets the maximum value for the id bound for the module. The
default is the minimum value for this limit, 0x3FFFFF. See
section 2.17 of the Spir-V specification.
--merge-blocks
Join two blocks into a single block if the second has the
first as its only predecessor. Performed only on entry point
call tree functions.
--merge-return
Changes functions that have multiple return statements so they
have a single return statement.
For structured control flow it is assumed that the only
unreachable blocks in the function are trivial merge and continue
blocks.
A trivial merge block contains the label and an OpUnreachable
instructions, nothing else. A trivial continue block contain a
label and an OpBranch to the header, nothing else.
These conditions are guaranteed to be met after running
dead-branch elimination.
--loop-unswitch
Hoists loop-invariant conditionals out of loops by duplicating
the loop on each branch of the conditional and adjusting each
copy of the loop.
-O
Optimize for performance. Apply a sequence of transformations
in an attempt to improve the performance of the generated
code. For this version of the optimizer, this flag is equivalent
to specifying the following optimization code names:
wrap-opkill
eliminate-dead-branches
merge-return
inline-entry-points-exhaustive
eliminate-dead-functions
eliminate-dead-code-aggressive
private-to-local
eliminate-local-single-block
eliminate-local-single-store
eliminate-dead-code-aggressive
scalar-replacement=100
convert-local-access-chains
eliminate-local-single-block
eliminate-local-single-store
eliminate-dead-code-aggressive
ssa-rewrite
eliminate-dead-code-aggressive
ccp
eliminate-dead-code-aggressive
loop-unroll
eliminate-dead-branches
redundancy-elimination
combine-access-chains
simplify-instructions
scalar-replacement=100
convert-local-access-chains
eliminate-local-single-block
eliminate-local-single-store
eliminate-dead-code-aggressive
ssa-rewrite
eliminate-dead-code-aggressive
vector-dce
eliminate-dead-inserts
eliminate-dead-branches
simplify-instructions
if-conversion
copy-propagate-arrays
reduce-load-size
eliminate-dead-code-aggressive
merge-blocks
redundancy-elimination
eliminate-dead-branches
merge-blocks
simplify-instructions
-Os
Optimize for size. Apply a sequence of transformations in an
attempt to minimize the size of the generated code. For this
version of the optimizer, this flag is equivalent to specifying
the following optimization code names:
wrap-opkill
eliminate-dead-branches
merge-return
inline-entry-points-exhaustive
eliminate-dead-functions
private-to-local
scalar-replacement=0
ssa-rewrite
ccp
loop-unroll
eliminate-dead-branches
simplify-instructions
scalar-replacement=0
eliminate-local-single-store
if-conversion
simplify-instructions
eliminate-dead-code-aggressive
eliminate-dead-branches
merge-blocks
convert-local-access-chains
eliminate-local-single-block
eliminate-dead-code-aggressive
copy-propagate-arrays
vector-dce
eliminate-dead-inserts
eliminate-dead-members
eliminate-local-single-store
merge-blocks
ssa-rewrite
redundancy-elimination
simplify-instructions
eliminate-dead-code-aggressive
cfg-cleanup
NOTE: The specific transformations done by -O and -Os change
from release to release.
-Oconfig=<file>
Apply the sequence of transformations indicated in <file>.
This file contains a sequence of strings separated by whitespace
(tabs, newlines or blanks). Each string is one of the flags
accepted by spirv-opt. Optimizations will be applied in the
sequence they appear in the file. This is equivalent to
specifying all the flags on the command line. For example,
given the file opts.cfg with the content:
--inline-entry-points-exhaustive
--eliminate-dead-code-aggressive
The following two invocations to spirv-opt are equivalent:
$ spirv-opt -Oconfig=opts.cfg program.spv
$ spirv-opt --inline-entry-points-exhaustive \
--eliminate-dead-code-aggressive program.spv
Lines starting with the character '#' in the configuration
file indicate a comment and will be ignored.
The -O, -Os, and -Oconfig flags act as macros. Using one of them
is equivalent to explicitly inserting the underlying flags at
that position in the command line. For example, the invocation
'spirv-opt --merge-blocks -O ...' applies the transformation
--merge-blocks followed by all the transformations implied by
-O.
--preserve-bindings
Ensure that the optimizer preserves all bindings declared within
the module, even when those bindings are unused.
--preserve-spec-constants
Ensure that the optimizer preserves all specialization constants declared
within the module, even when those constants are unused.
--print-all
Print SPIR-V assembly to standard error output before each pass
and after the last pass.
--private-to-local
Change the scope of private variables that are used in a single
function to that function.
--reduce-load-size
Replaces loads of composite objects where not every component is
used by loads of just the elements that are used.
--redundancy-elimination
Looks for instructions in the same function that compute the
same value, and deletes the redundant ones.
--relax-block-layout
Forwards this option to the validator. See the validator help
for details.
--relax-float-ops
Decorate all float operations with RelaxedPrecision if not already
so decorated. This does not decorate types or variables.
--relax-logical-pointer
Forwards this option to the validator. See the validator help
for details.
--relax-struct-store
Forwards this option to the validator. See the validator help
for details.
--remove-duplicates
Removes duplicate types, decorations, capabilities and extension
instructions.
--replace-invalid-opcode
Replaces instructions whose opcode is valid for shader modules,
but not for the current shader stage. To have an effect, all
entry points must have the same execution model.
--ssa-rewrite
Replace loads and stores to function local variables with
operations on SSA IDs.
--scalar-block-layout
Forwards this option to the validator. See the validator help
for details.
--scalar-replacement[=<n>]
Replace aggregate function scope variables that are only accessed
via their elements with new function variables representing each
element. <n> is a limit on the size of the aggregates that will
be replaced. 0 means there is no limit. The default value is
100.
--set-spec-const-default-value "<spec id>:<default value> ..."
Set the default values of the specialization constants with
<spec id>:<default value> pairs specified in a double-quoted
string. <spec id>:<default value> pairs must be separated by
blank spaces, and in each pair, spec id and default value must
be separated with colon ':' without any blank spaces in between.
e.g.: --set-spec-const-default-value "1:100 2:400"
--simplify-instructions
Will simplify all instructions in the function as much as
possible.
--skip-block-layout
Forwards this option to the validator. See the validator help
for details.
--skip-validation
Will not validate the SPIR-V before optimizing. If the SPIR-V
is invalid, the optimizer may fail or generate incorrect code.
This options should be used rarely, and with caution.
--strength-reduction
Replaces instructions with equivalent and less expensive ones.
--strip-atomic-counter-memory
Removes AtomicCountMemory bit from memory semantics values.
--strip-debug
Remove all debug instructions.
--strip-reflect
Remove all reflection information. For now, this covers
reflection information defined by SPV_GOOGLE_hlsl_functionality1
and SPV_KHR_non_semantic_info
--target-env=<env>
Set the target environment. Without this flag the target
environment defaults to spv1.5. <env> must be one of
{vulkan1.1spv1.4|vulkan1.0|vulkan1.1|vulkan1.2|spv1.0|spv1.1
|spv1.2|spv1.3|spv1.4|spv1.5|opencl1.2embedded|opencl1.2
|opencl2.0embedded|opencl2.0|opencl2.1embedded|opencl2.1
|opencl2.2embedded|opencl2.2|opengl4.0|opengl4.1|opengl4.2
|opengl4.3|opengl4.5}
--time-report
Print the resource utilization of each pass (e.g., CPU time,
RSS) to standard error output. Currently it supports only Unix
systems. This option is the same as -ftime-report in GCC. It
prints CPU/WALL/USR/SYS time (and RSS if possible), but note that
USR/SYS time are returned by getrusage() and can have a small
error.
--upgrade-memory-model
Upgrades the Logical GLSL450 memory model to Logical VulkanKHR.
Transforms memory, image, atomic and barrier operations to conform
to that model's requirements.
--vector-dce
This pass looks for components of vectors that are unused, and
removes them from the vector. Note this would still leave around
lots of dead code that a pass of ADCE will be able to remove.
--workaround-1209
Rewrites instructions for which there are known driver bugs to
avoid triggering those bugs.
Current workarounds: Avoid OpUnreachable in loops.
--workgroup-scalar-block-layout
Forwards this option to the validator. See the validator help
for details.
--wrap-opkill
Replaces all OpKill instructions in functions that can be called
from a continue construct with a function call to a function
whose only instruction is an OpKill. This is done to enable
inlining on these functions.
--unify-const
Remove the duplicated constants.
--validate-after-all
Validate the module after each pass is performed.
-h, --help
Print this help.
--version
Display optimizer version information.