2 * Copyright © 2010 Luca Barbieri
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25 * \file lower_variable_index_to_cond_assign.cpp
27 * Turns non-constant indexing into array types to a series of
28 * conditional moves of each element into a temporary.
30 * Pre-DX10 GPUs often don't have a native way to do this operation,
31 * and this works around that.
33 * The lowering process proceeds as follows. Each non-constant index
34 * found in an r-value is converted to a canonical form \c array[i]. Each
35 * element of the array is conditionally assigned to a temporary by comparing
36 * \c i to a constant index. This is done by cloning the canonical form and
37 * replacing all occurances of \c i with a constant. Each remaining occurance
38 * of the canonical form in the IR is replaced with a dereference of the
41 * L-values with non-constant indices are handled similarly. In this case,
42 * the RHS of the assignment is assigned to a temporary. The non-constant
43 * index is replace with the canonical form (just like for r-values). The
44 * temporary is conditionally assigned to each element of the canonical form
45 * by comparing \c i with each index. The same clone-and-replace scheme is
50 #include "ir_rvalue_visitor.h"
51 #include "ir_optimization.h"
52 #include "glsl_types.h"
53 #include "main/macros.h"
56 * Generate a comparison value for a block of indices
58 * Lowering passes for non-constant indexing of arrays, matrices, or vectors
59 * can use this to generate blocks of index comparison values.
61 * \param instructions List where new instructions will be appended
62 * \param index \c ir_variable containing the desired index
63 * \param base Base value for this block of comparisons
64 * \param components Number of unique index values to compare. This must
65 * be on the range [1, 4].
66 * \param mem_ctx ralloc memory context to be used for all allocations.
69 * An \c ir_rvalue that \b must be cloned for each use in conditional
73 compare_index_block(exec_list
*instructions
, ir_variable
*index
,
74 unsigned base
, unsigned components
, void *mem_ctx
)
76 ir_rvalue
*broadcast_index
= new(mem_ctx
) ir_dereference_variable(index
);
78 assert(index
->type
->is_scalar());
79 assert(index
->type
->base_type
== GLSL_TYPE_INT
);
80 assert(components
>= 1 && components
<= 4);
83 const ir_swizzle_mask m
= { 0, 0, 0, 0, components
, false };
84 broadcast_index
= new(mem_ctx
) ir_swizzle(broadcast_index
, m
);
87 /* Compare the desired index value with the next block of four indices.
89 ir_constant_data test_indices_data
;
90 memset(&test_indices_data
, 0, sizeof(test_indices_data
));
91 test_indices_data
.i
[0] = base
;
92 test_indices_data
.i
[1] = base
+ 1;
93 test_indices_data
.i
[2] = base
+ 2;
94 test_indices_data
.i
[3] = base
+ 3;
96 ir_constant
*const test_indices
=
97 new(mem_ctx
) ir_constant(broadcast_index
->type
,
100 ir_rvalue
*const condition_val
=
101 new(mem_ctx
) ir_expression(ir_binop_equal
,
102 &glsl_type::bool_type
[components
- 1],
106 ir_variable
*const condition
=
107 new(mem_ctx
) ir_variable(condition_val
->type
,
108 "dereference_condition",
110 instructions
->push_tail(condition
);
112 ir_rvalue
*const cond_deref
=
113 new(mem_ctx
) ir_dereference_variable(condition
);
114 instructions
->push_tail(new(mem_ctx
) ir_assignment(cond_deref
, condition_val
, 0));
120 is_array_or_matrix(const ir_instruction
*ir
)
122 return (ir
->type
->is_array() || ir
->type
->is_matrix());
126 * Replace a dereference of a variable with a specified r-value
128 * Each time a dereference of the specified value is replaced, the r-value
131 class deref_replacer
: public ir_rvalue_visitor
{
133 deref_replacer(const ir_variable
*variable_to_replace
, ir_rvalue
*value
)
134 : variable_to_replace(variable_to_replace
), value(value
),
137 assert(this->variable_to_replace
!= NULL
);
138 assert(this->value
!= NULL
);
141 virtual void handle_rvalue(ir_rvalue
**rvalue
)
143 ir_dereference_variable
*const dv
= (*rvalue
)->as_dereference_variable();
145 if ((dv
!= NULL
) && (dv
->var
== this->variable_to_replace
)) {
146 this->progress
= true;
147 *rvalue
= this->value
->clone(ralloc_parent(*rvalue
), NULL
);
151 const ir_variable
*variable_to_replace
;
157 * Find a variable index dereference of an array in an rvalue tree
159 class find_variable_index
: public ir_hierarchical_visitor
{
161 find_variable_index()
167 virtual ir_visitor_status
visit_enter(ir_dereference_array
*ir
)
169 if (is_array_or_matrix(ir
->array
)
170 && (ir
->array_index
->as_constant() == NULL
)) {
175 return visit_continue
;
179 * First array dereference found in the tree that has a non-constant index.
181 ir_dereference_array
*deref
;
184 struct assignment_generator
186 ir_instruction
* base_ir
;
187 ir_dereference
*rvalue
;
188 ir_variable
*old_index
;
190 unsigned int write_mask
;
193 assignment_generator()
197 void generate(unsigned i
, ir_rvalue
* condition
, exec_list
*list
) const
199 /* Just clone the rest of the deref chain when trying to get at the
200 * underlying variable.
202 void *mem_ctx
= ralloc_parent(base_ir
);
204 /* Clone the old r-value in its entirety. Then replace any occurances of
205 * the old variable index with the new constant index.
207 ir_dereference
*element
= this->rvalue
->clone(mem_ctx
, NULL
);
208 ir_constant
*const index
= new(mem_ctx
) ir_constant(i
);
209 deref_replacer
r(this->old_index
, index
);
213 /* Generate a conditional assignment to (or from) the constant indexed
216 ir_rvalue
*variable
= new(mem_ctx
) ir_dereference_variable(this->var
);
217 ir_assignment
*const assignment
= (is_write
)
218 ? new(mem_ctx
) ir_assignment(element
, variable
, condition
, write_mask
)
219 : new(mem_ctx
) ir_assignment(variable
, element
, condition
);
221 list
->push_tail(assignment
);
225 struct switch_generator
227 /* make TFunction a template parameter if you need to use other generators */
228 typedef assignment_generator TFunction
;
229 const TFunction
& generator
;
232 unsigned linear_sequence_max_length
;
233 unsigned condition_components
;
237 switch_generator(const TFunction
& generator
, ir_variable
*index
,
238 unsigned linear_sequence_max_length
,
239 unsigned condition_components
)
240 : generator(generator
), index(index
),
241 linear_sequence_max_length(linear_sequence_max_length
),
242 condition_components(condition_components
)
244 this->mem_ctx
= ralloc_parent(index
);
247 void linear_sequence(unsigned begin
, unsigned end
, exec_list
*list
)
252 /* If the array access is a read, read the first element of this subregion
253 * unconditionally. The remaining tests will possibly overwrite this
254 * value with one of the other array elements.
256 * This optimization cannot be done for writes because it will cause the
257 * first element of the subregion to be written possibly *in addition* to
258 * one of the other elements.
261 if (!this->generator
.is_write
) {
262 this->generator
.generate(begin
, 0, list
);
268 for (unsigned i
= first
; i
< end
; i
+= 4) {
269 const unsigned comps
= MIN2(condition_components
, end
- i
);
271 ir_rvalue
*const cond_deref
=
272 compare_index_block(list
, index
, i
, comps
, this->mem_ctx
);
275 this->generator
.generate(i
, cond_deref
->clone(this->mem_ctx
, NULL
),
278 for (unsigned j
= 0; j
< comps
; j
++) {
279 ir_rvalue
*const cond_swiz
=
280 new(this->mem_ctx
) ir_swizzle(cond_deref
->clone(this->mem_ctx
, NULL
),
283 this->generator
.generate(i
+ j
, cond_swiz
, list
);
289 void bisect(unsigned begin
, unsigned end
, exec_list
*list
)
291 unsigned middle
= (begin
+ end
) >> 1;
293 assert(index
->type
->is_integer());
295 ir_constant
*const middle_c
= (index
->type
->base_type
== GLSL_TYPE_UINT
)
296 ? new(this->mem_ctx
) ir_constant((unsigned)middle
)
297 : new(this->mem_ctx
) ir_constant((int)middle
);
300 ir_dereference_variable
*deref
=
301 new(this->mem_ctx
) ir_dereference_variable(this->index
);
303 ir_expression
*less
=
304 new(this->mem_ctx
) ir_expression(ir_binop_less
, glsl_type::bool_type
,
307 ir_if
*if_less
= new(this->mem_ctx
) ir_if(less
);
309 generate(begin
, middle
, &if_less
->then_instructions
);
310 generate(middle
, end
, &if_less
->else_instructions
);
312 list
->push_tail(if_less
);
315 void generate(unsigned begin
, unsigned end
, exec_list
*list
)
317 unsigned length
= end
- begin
;
318 if (length
<= this->linear_sequence_max_length
)
319 return linear_sequence(begin
, end
, list
);
321 return bisect(begin
, end
, list
);
326 * Visitor class for replacing expressions with ir_constant values.
329 class variable_index_to_cond_assign_visitor
: public ir_rvalue_visitor
{
331 variable_index_to_cond_assign_visitor(bool lower_input
,
336 this->progress
= false;
337 this->lower_inputs
= lower_input
;
338 this->lower_outputs
= lower_output
;
339 this->lower_temps
= lower_temp
;
340 this->lower_uniforms
= lower_uniform
;
349 bool storage_type_needs_lowering(ir_dereference_array
*deref
) const
351 /* If a variable isn't eventually the target of this dereference, then
352 * it must be a constant or some sort of anonymous temporary storage.
354 * FINISHME: Is this correct? Most drivers treat arrays of constants as
355 * FINISHME: uniforms. It seems like this should do the same.
357 const ir_variable
*const var
= deref
->array
->variable_referenced();
359 return this->lower_temps
;
363 case ir_var_temporary
:
364 return this->lower_temps
;
366 return this->lower_uniforms
;
368 case ir_var_const_in
:
369 return (var
->location
== -1) ? this->lower_temps
: this->lower_inputs
;
371 return (var
->location
== -1) ? this->lower_temps
: this->lower_outputs
;
373 return this->lower_temps
;
376 assert(!"Should not get here.");
380 bool needs_lowering(ir_dereference_array
*deref
) const
382 if (deref
== NULL
|| deref
->array_index
->as_constant()
383 || !is_array_or_matrix(deref
->array
))
386 return this->storage_type_needs_lowering(deref
);
389 ir_variable
*convert_dereference_array(ir_dereference_array
*orig_deref
,
390 ir_assignment
* orig_assign
,
391 ir_dereference
*orig_base
)
393 assert(is_array_or_matrix(orig_deref
->array
));
395 const unsigned length
= (orig_deref
->array
->type
->is_array())
396 ? orig_deref
->array
->type
->length
397 : orig_deref
->array
->type
->matrix_columns
;
399 void *const mem_ctx
= ralloc_parent(base_ir
);
401 /* Temporary storage for either the result of the dereference of
402 * the array, or the RHS that's being assigned into the
403 * dereference of the array.
408 var
= new(mem_ctx
) ir_variable(orig_assign
->rhs
->type
,
409 "dereference_array_value",
411 base_ir
->insert_before(var
);
413 ir_dereference
*lhs
= new(mem_ctx
) ir_dereference_variable(var
);
414 ir_assignment
*assign
= new(mem_ctx
) ir_assignment(lhs
,
418 base_ir
->insert_before(assign
);
420 var
= new(mem_ctx
) ir_variable(orig_deref
->type
,
421 "dereference_array_value",
423 base_ir
->insert_before(var
);
426 /* Store the index to a temporary to avoid reusing its tree. */
428 new(mem_ctx
) ir_variable(orig_deref
->array_index
->type
,
429 "dereference_array_index", ir_var_temporary
);
430 base_ir
->insert_before(index
);
432 ir_dereference
*lhs
= new(mem_ctx
) ir_dereference_variable(index
);
433 ir_assignment
*assign
=
434 new(mem_ctx
) ir_assignment(lhs
, orig_deref
->array_index
, NULL
);
435 base_ir
->insert_before(assign
);
437 orig_deref
->array_index
= lhs
->clone(mem_ctx
, NULL
);
439 assignment_generator ag
;
440 ag
.rvalue
= orig_base
;
441 ag
.base_ir
= base_ir
;
442 ag
.old_index
= index
;
446 ag
.write_mask
= orig_assign
->write_mask
;
451 switch_generator
sg(ag
, index
, 4, 4);
453 /* If the original assignment has a condition, respect that original
454 * condition! This is acomplished by wrapping the new conditional
455 * assignments in an if-statement that uses the original condition.
457 if ((orig_assign
!= NULL
) && (orig_assign
->condition
!= NULL
)) {
458 /* No need to clone the condition because the IR that it hangs on is
459 * going to be removed from the instruction sequence.
461 ir_if
*if_stmt
= new(mem_ctx
) ir_if(orig_assign
->condition
);
463 sg
.generate(0, length
, &if_stmt
->then_instructions
);
464 base_ir
->insert_before(if_stmt
);
468 sg
.generate(0, length
, &list
);
469 base_ir
->insert_before(&list
);
475 virtual void handle_rvalue(ir_rvalue
**pir
)
477 if (this->in_assignee
)
483 ir_dereference_array
* orig_deref
= (*pir
)->as_dereference_array();
484 if (needs_lowering(orig_deref
)) {
486 convert_dereference_array(orig_deref
, NULL
, orig_deref
);
488 *pir
= new(ralloc_parent(base_ir
)) ir_dereference_variable(var
);
489 this->progress
= true;
494 visit_leave(ir_assignment
*ir
)
496 ir_rvalue_visitor::visit_leave(ir
);
498 find_variable_index f
;
501 if ((f
.deref
!= NULL
) && storage_type_needs_lowering(f
.deref
)) {
502 convert_dereference_array(f
.deref
, ir
, ir
->lhs
);
504 this->progress
= true;
507 return visit_continue
;
512 lower_variable_index_to_cond_assign(exec_list
*instructions
,
518 variable_index_to_cond_assign_visitor
v(lower_input
,
523 /* Continue lowering until no progress is made. If there are multiple
524 * levels of indirection (e.g., non-constant indexing of array elements and
525 * matrix columns of an array of matrix), each pass will only lower one
526 * level of indirection.
528 bool progress_ever
= false;
531 visit_list_elements(&v
, instructions
);
532 progress_ever
= v
.progress
|| progress_ever
;
533 } while (v
.progress
);
535 return progress_ever
;