; NOTE: Assertions have been autogenerated by utils/update_analyze_test_checks.py ; RUN: opt -disable-output "-passes=print" < %s 2>&1 | FileCheck %s declare i1 @cond() define i32 @test_simple_case(i32 %start, i32 %len) { ; CHECK-LABEL: 'test_simple_case' ; CHECK-NEXT: Classifying expressions for: @test_simple_case ; CHECK-NEXT: %iv = phi i32 [ %start, %entry ], [ %iv.next, %backedge ] ; CHECK-NEXT: --> {%start,+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %iv.minus.1 = add i32 %iv, -1 ; CHECK-NEXT: --> {(-1 + %start),+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %iv.next = add i32 %iv, -1 ; CHECK-NEXT: --> {(-1 + %start),+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %loop_cond = call i1 @cond() ; CHECK-NEXT: --> %loop_cond U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: Determining loop execution counts for: @test_simple_case ; CHECK-NEXT: Loop %loop: Unpredictable backedge-taken count. ; CHECK-NEXT: exit count for loop: %start ; CHECK-NEXT: exit count for range_check_block: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: exit count for backedge: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: Loop %loop: constant max backedge-taken count is i32 -1 ; CHECK-NEXT: Loop %loop: symbolic max backedge-taken count is %start ; CHECK-NEXT: symbolic max exit count for loop: %start ; CHECK-NEXT: symbolic max exit count for range_check_block: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: symbolic max exit count for backedge: ***COULDNOTCOMPUTE*** ; entry: br label %loop loop: %iv = phi i32 [%start, %entry], [%iv.next, %backedge] %zero_check = icmp ne i32 %iv, 0 br i1 %zero_check, label %range_check_block, label %failed_1 range_check_block: %iv.minus.1 = add i32 %iv, -1 %range_check = icmp ult i32 %iv.minus.1, %len br i1 %range_check, label %backedge, label %failed_2 backedge: %iv.next = add i32 %iv, -1 %loop_cond = call i1 @cond() br i1 %loop_cond, label %done, label %loop done: ret i32 %iv failed_1: ret i32 -1 failed_2: ret i32 -2 } define i32 @test_litter_conditions(i32 %start, i32 %len) { ; CHECK-LABEL: 'test_litter_conditions' ; CHECK-NEXT: Classifying expressions for: @test_litter_conditions ; CHECK-NEXT: %iv = phi i32 [ %start, %entry ], [ %iv.next, %backedge ] ; CHECK-NEXT: --> {%start,+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %fake_1 = call i1 @cond() ; CHECK-NEXT: --> %fake_1 U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %and_1 = and i1 %zero_check, %fake_1 ; CHECK-NEXT: --> (%zero_check umin %fake_1) U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %iv.minus.1 = add i32 %iv, -1 ; CHECK-NEXT: --> {(-1 + %start),+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %fake_2 = call i1 @cond() ; CHECK-NEXT: --> %fake_2 U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %and_2 = and i1 %range_check, %fake_2 ; CHECK-NEXT: --> (%range_check umin %fake_2) U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %iv.next = add i32 %iv, -1 ; CHECK-NEXT: --> {(-1 + %start),+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %loop_cond = call i1 @cond() ; CHECK-NEXT: --> %loop_cond U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: Determining loop execution counts for: @test_litter_conditions ; CHECK-NEXT: Loop %loop: Unpredictable backedge-taken count. ; CHECK-NEXT: exit count for loop: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: exit count for range_check_block: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: exit count for backedge: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: Loop %loop: constant max backedge-taken count is i32 -1 ; CHECK-NEXT: Loop %loop: symbolic max backedge-taken count is %start ; CHECK-NEXT: symbolic max exit count for loop: %start ; CHECK-NEXT: symbolic max exit count for range_check_block: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: symbolic max exit count for backedge: ***COULDNOTCOMPUTE*** ; entry: br label %loop loop: %iv = phi i32 [%start, %entry], [%iv.next, %backedge] %zero_check = icmp ne i32 %iv, 0 %fake_1 = call i1 @cond() %and_1 = and i1 %zero_check, %fake_1 br i1 %and_1, label %range_check_block, label %failed_1 range_check_block: %iv.minus.1 = add i32 %iv, -1 %range_check = icmp ult i32 %iv.minus.1, %len %fake_2 = call i1 @cond() %and_2 = and i1 %range_check, %fake_2 br i1 %and_2, label %backedge, label %failed_2 backedge: %iv.next = add i32 %iv, -1 %loop_cond = call i1 @cond() br i1 %loop_cond, label %done, label %loop done: ret i32 %iv failed_1: ret i32 -1 failed_2: ret i32 -2 } define i32 @test_litter_conditions_bad_context(i32 %start, i32 %len) { ; CHECK-LABEL: 'test_litter_conditions_bad_context' ; CHECK-NEXT: Classifying expressions for: @test_litter_conditions_bad_context ; CHECK-NEXT: %iv = phi i32 [ %start, %entry ], [ %iv.next, %backedge ] ; CHECK-NEXT: --> {%start,+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %fake_1 = call i1 @cond() ; CHECK-NEXT: --> %fake_1 U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %and_1 = and i1 %zero_check, %fake_1 ; CHECK-NEXT: --> (%zero_check umin %fake_1) U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %iv.minus.1 = add i32 %iv, -1 ; CHECK-NEXT: --> {(-1 + %start),+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %fake_2 = call i1 @cond() ; CHECK-NEXT: --> %fake_2 U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %and_2 = and i1 %range_check, %fake_2 ; CHECK-NEXT: --> (%range_check umin %fake_2) U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %iv.next = add i32 %iv, -1 ; CHECK-NEXT: --> {(-1 + %start),+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %loop_cond = call i1 @cond() ; CHECK-NEXT: --> %loop_cond U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: Determining loop execution counts for: @test_litter_conditions_bad_context ; CHECK-NEXT: Loop %loop: Unpredictable backedge-taken count. ; CHECK-NEXT: exit count for loop: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: exit count for range_check_block: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: exit count for backedge: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: Loop %loop: constant max backedge-taken count is i32 -1 ; CHECK-NEXT: Loop %loop: symbolic max backedge-taken count is %start ; CHECK-NEXT: symbolic max exit count for loop: %start ; CHECK-NEXT: symbolic max exit count for range_check_block: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: symbolic max exit count for backedge: ***COULDNOTCOMPUTE*** ; entry: br label %loop loop: %iv = phi i32 [%start, %entry], [%iv.next, %backedge] %zero_check = icmp ne i32 %iv, 0 %fake_1 = call i1 @cond() %and_1 = and i1 %zero_check, %fake_1 %iv.minus.1 = add i32 %iv, -1 %range_check = icmp ult i32 %iv.minus.1, %len %fake_2 = call i1 @cond() %and_2 = and i1 %range_check, %fake_2 br i1 %and_1, label %range_check_block, label %failed_1 range_check_block: br i1 %and_2, label %backedge, label %failed_2 backedge: %iv.next = add i32 %iv, -1 %loop_cond = call i1 @cond() br i1 %loop_cond, label %done, label %loop done: ret i32 %iv failed_1: ret i32 -1 failed_2: ret i32 -2 } define i32 @test_and_conditions(i32 %start, i32 %len) { ; CHECK-LABEL: 'test_and_conditions' ; CHECK-NEXT: Classifying expressions for: @test_and_conditions ; CHECK-NEXT: %iv = phi i32 [ %start, %entry ], [ %iv.next, %backedge ] ; CHECK-NEXT: --> {%start,+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %iv.minus.1 = add i32 %iv, -1 ; CHECK-NEXT: --> {(-1 + %start),+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %both_checks = and i1 %zero_check, %range_check ; CHECK-NEXT: --> (%range_check umin %zero_check) U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %iv.next = add i32 %iv, -1 ; CHECK-NEXT: --> {(-1 + %start),+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %loop_cond = call i1 @cond() ; CHECK-NEXT: --> %loop_cond U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: Determining loop execution counts for: @test_and_conditions ; CHECK-NEXT: Loop %loop: Unpredictable backedge-taken count. ; CHECK-NEXT: exit count for loop: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: exit count for backedge: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: Loop %loop: constant max backedge-taken count is i32 -1 ; CHECK-NEXT: Loop %loop: symbolic max backedge-taken count is %start ; CHECK-NEXT: symbolic max exit count for loop: %start ; CHECK-NEXT: symbolic max exit count for backedge: ***COULDNOTCOMPUTE*** ; entry: br label %loop loop: %iv = phi i32 [%start, %entry], [%iv.next, %backedge] %zero_check = icmp ne i32 %iv, 0 %iv.minus.1 = add i32 %iv, -1 %range_check = icmp ult i32 %iv.minus.1, %len %both_checks = and i1 %zero_check, %range_check br i1 %both_checks, label %backedge, label %failed backedge: %iv.next = add i32 %iv, -1 %loop_cond = call i1 @cond() br i1 %loop_cond, label %done, label %loop done: ret i32 %iv failed: ret i32 -3 } define i32 @test_mixup_constant_symbolic(i32 %end, i32 %len) { ; CHECK-LABEL: 'test_mixup_constant_symbolic' ; CHECK-NEXT: Classifying expressions for: @test_mixup_constant_symbolic ; CHECK-NEXT: %iv = phi i32 [ 0, %entry ], [ %iv.next, %backedge ] ; CHECK-NEXT: --> {0,+,1}<%loop> U: [0,1001) S: [0,1001) Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %iv.next = add i32 %iv, 1 ; CHECK-NEXT: --> {1,+,1}<%loop> U: [1,1002) S: [1,1002) Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %loop_cond = call i1 @cond() ; CHECK-NEXT: --> %loop_cond U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: Determining loop execution counts for: @test_mixup_constant_symbolic ; CHECK-NEXT: Loop %loop: Unpredictable backedge-taken count. ; CHECK-NEXT: exit count for loop: %end ; CHECK-NEXT: exit count for range_check_block: i32 1000 ; CHECK-NEXT: exit count for backedge: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: Loop %loop: constant max backedge-taken count is i32 1000 ; CHECK-NEXT: Loop %loop: symbolic max backedge-taken count is (1000 umin %end) ; CHECK-NEXT: symbolic max exit count for loop: %end ; CHECK-NEXT: symbolic max exit count for range_check_block: i32 1000 ; CHECK-NEXT: symbolic max exit count for backedge: ***COULDNOTCOMPUTE*** ; entry: br label %loop loop: %iv = phi i32 [0, %entry], [%iv.next, %backedge] %zero_check = icmp ne i32 %iv, %end br i1 %zero_check, label %range_check_block, label %failed_1 range_check_block: %range_check = icmp ult i32 %iv, 1000 br i1 %range_check, label %backedge, label %failed_2 backedge: %iv.next = add i32 %iv, 1 %loop_cond = call i1 @cond() br i1 %loop_cond, label %done, label %loop done: ret i32 %iv failed_1: ret i32 -1 failed_2: ret i32 -2 } define i32 @test_mixup_constant_symbolic_merged(i32 %end, i32 %len) { ; CHECK-LABEL: 'test_mixup_constant_symbolic_merged' ; CHECK-NEXT: Classifying expressions for: @test_mixup_constant_symbolic_merged ; CHECK-NEXT: %iv = phi i32 [ 0, %entry ], [ %iv.next, %backedge ] ; CHECK-NEXT: --> {0,+,1}<%loop> U: [0,1001) S: [0,1001) Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %and = and i1 %zero_check, %range_check ; CHECK-NEXT: --> (%range_check umin %zero_check) U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %iv.next = add i32 %iv, 1 ; CHECK-NEXT: --> {1,+,1}<%loop> U: [1,1002) S: [1,1002) Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %loop_cond = call i1 @cond() ; CHECK-NEXT: --> %loop_cond U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: Determining loop execution counts for: @test_mixup_constant_symbolic_merged ; CHECK-NEXT: Loop %loop: Unpredictable backedge-taken count. ; CHECK-NEXT: exit count for loop: (1000 umin %end) ; CHECK-NEXT: exit count for backedge: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: Loop %loop: constant max backedge-taken count is i32 1000 ; CHECK-NEXT: Loop %loop: symbolic max backedge-taken count is (1000 umin %end) ; CHECK-NEXT: symbolic max exit count for loop: (1000 umin %end) ; CHECK-NEXT: symbolic max exit count for backedge: ***COULDNOTCOMPUTE*** ; entry: br label %loop loop: %iv = phi i32 [0, %entry], [%iv.next, %backedge] %zero_check = icmp ne i32 %iv, %end %range_check = icmp ult i32 %iv, 1000 %and = and i1 %zero_check, %range_check br i1 %and, label %backedge, label %failed_1 backedge: %iv.next = add i32 %iv, 1 %loop_cond = call i1 @cond() br i1 %loop_cond, label %done, label %loop done: ret i32 %iv failed_1: ret i32 -1 } define i32 @test_two_phis(i32 %start_1, i32 %start_2, i32 %len) { ; CHECK-LABEL: 'test_two_phis' ; CHECK-NEXT: Classifying expressions for: @test_two_phis ; CHECK-NEXT: %iv_1 = phi i32 [ %start_1, %entry ], [ %iv_1.next, %backedge ] ; CHECK-NEXT: --> {%start_1,+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %iv_2 = phi i32 [ %start_2, %entry ], [ %iv_2.next, %backedge ] ; CHECK-NEXT: --> {%start_2,+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %scam_1 = call i1 @cond() ; CHECK-NEXT: --> %scam_1 U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %c1 = and i1 %zero_check_1, %scam_1 ; CHECK-NEXT: --> (%zero_check_1 umin %scam_1) U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %scam_2 = call i1 @cond() ; CHECK-NEXT: --> %scam_2 U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %c2 = and i1 %zero_check_2, %scam_2 ; CHECK-NEXT: --> (%zero_check_2 umin %scam_2) U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %iv.minus.1 = add i32 %iv_1, -1 ; CHECK-NEXT: --> {(-1 + %start_1),+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %iv_1.next = add i32 %iv_1, -1 ; CHECK-NEXT: --> {(-1 + %start_1),+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %iv_2.next = add i32 %iv_2, -1 ; CHECK-NEXT: --> {(-1 + %start_2),+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %loop_cond = call i1 @cond() ; CHECK-NEXT: --> %loop_cond U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: Determining loop execution counts for: @test_two_phis ; CHECK-NEXT: Loop %loop: Unpredictable backedge-taken count. ; CHECK-NEXT: exit count for loop: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: exit count for zero_check_block: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: exit count for range_check_block: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: exit count for backedge: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: Loop %loop: constant max backedge-taken count is i32 -1 ; CHECK-NEXT: Loop %loop: symbolic max backedge-taken count is (%start_1 umin_seq %start_2) ; CHECK-NEXT: symbolic max exit count for loop: %start_1 ; CHECK-NEXT: symbolic max exit count for zero_check_block: %start_2 ; CHECK-NEXT: symbolic max exit count for range_check_block: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: symbolic max exit count for backedge: ***COULDNOTCOMPUTE*** ; entry: br label %loop loop: %iv_1 = phi i32 [%start_1, %entry], [%iv_1.next, %backedge] %iv_2 = phi i32 [%start_2, %entry], [%iv_2.next, %backedge] %scam_1 = call i1 @cond() %zero_check_1 = icmp ne i32 %iv_1, 0 %c1 = and i1 %zero_check_1, %scam_1 br i1 %c1, label %zero_check_block, label %failed_1 zero_check_block: %scam_2 = call i1 @cond() %zero_check_2 = icmp ne i32 %iv_2, 0 %c2 = and i1 %zero_check_2, %scam_2 br i1 %c2, label %range_check_block, label %failed_1 range_check_block: %iv.minus.1 = add i32 %iv_1, -1 %range_check = icmp ult i32 %iv.minus.1, %len br i1 %range_check, label %backedge, label %failed_2 backedge: %iv_1.next = add i32 %iv_1, -1 %iv_2.next = add i32 %iv_2, -1 %loop_cond = call i1 @cond() br i1 %loop_cond, label %done, label %loop done: ret i32 %iv_2 failed_1: ret i32 -1 failed_2: ret i32 -2 } define i32 @test_two_phis_simple(i32 %start_1, i32 %start_2, i32 %len) { ; CHECK-LABEL: 'test_two_phis_simple' ; CHECK-NEXT: Classifying expressions for: @test_two_phis_simple ; CHECK-NEXT: %iv_1 = phi i32 [ %start_1, %entry ], [ %iv_1.next, %backedge ] ; CHECK-NEXT: --> {%start_1,+,-1}<%loop> U: full-set S: full-set Exits: ((-1 * (%start_1 umin_seq %start_2)) + %start_1) LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %iv_2 = phi i32 [ %start_2, %entry ], [ %iv_2.next, %backedge ] ; CHECK-NEXT: --> {%start_2,+,-1}<%loop> U: full-set S: full-set Exits: ((-1 * (%start_1 umin_seq %start_2)) + %start_2) LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %iv_1.next = add i32 %iv_1, -1 ; CHECK-NEXT: --> {(-1 + %start_1),+,-1}<%loop> U: full-set S: full-set Exits: (-1 + (-1 * (%start_1 umin_seq %start_2)) + %start_1) LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %iv_2.next = add i32 %iv_2, -1 ; CHECK-NEXT: --> {(-1 + %start_2),+,-1}<%loop> U: full-set S: full-set Exits: (-1 + (-1 * (%start_1 umin_seq %start_2)) + %start_2) LoopDispositions: { %loop: Computable } ; CHECK-NEXT: Determining loop execution counts for: @test_two_phis_simple ; CHECK-NEXT: Loop %loop: backedge-taken count is (%start_1 umin_seq %start_2) ; CHECK-NEXT: exit count for loop: %start_1 ; CHECK-NEXT: exit count for backedge: %start_2 ; CHECK-NEXT: Loop %loop: constant max backedge-taken count is i32 -1 ; CHECK-NEXT: Loop %loop: symbolic max backedge-taken count is (%start_1 umin_seq %start_2) ; CHECK-NEXT: symbolic max exit count for loop: %start_1 ; CHECK-NEXT: symbolic max exit count for backedge: %start_2 ; CHECK-NEXT: Loop %loop: Trip multiple is 1 ; entry: br label %loop loop: %iv_1 = phi i32 [%start_1, %entry], [%iv_1.next, %backedge] %iv_2 = phi i32 [%start_2, %entry], [%iv_2.next, %backedge] %zero_check_1 = icmp ne i32 %iv_1, 0 br i1 %zero_check_1, label %backedge, label %exit backedge: %zero_check_2 = icmp ne i32 %iv_2, 0 %iv_1.next = add i32 %iv_1, -1 %iv_2.next = add i32 %iv_2, -1 br i1 %zero_check_2, label %loop, label %exit exit: ret i32 0 } define i32 @test_two_phis_arithmetic_and(i32 %start_1, i32 %start_2, i32 %len) { ; CHECK-LABEL: 'test_two_phis_arithmetic_and' ; CHECK-NEXT: Classifying expressions for: @test_two_phis_arithmetic_and ; CHECK-NEXT: %iv_1 = phi i32 [ %start_1, %entry ], [ %iv_1.next, %backedge ] ; CHECK-NEXT: --> {%start_1,+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %iv_2 = phi i32 [ %start_2, %entry ], [ %iv_2.next, %backedge ] ; CHECK-NEXT: --> {%start_2,+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %scam_1 = call i1 @cond() ; CHECK-NEXT: --> %scam_1 U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %c1 = and i1 %zero_check_1, %scam_1 ; CHECK-NEXT: --> (%zero_check_1 umin %scam_1) U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %scam_2 = call i1 @cond() ; CHECK-NEXT: --> %scam_2 U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %c2 = and i1 %zero_check_2, %scam_2 ; CHECK-NEXT: --> (%zero_check_2 umin %scam_2) U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %merged_cond = and i1 %c1, %c2 ; CHECK-NEXT: --> (%zero_check_1 umin %zero_check_2 umin %scam_1 umin %scam_2) U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %iv.minus.1 = add i32 %iv_1, -1 ; CHECK-NEXT: --> {(-1 + %start_1),+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %iv_1.next = add i32 %iv_1, -1 ; CHECK-NEXT: --> {(-1 + %start_1),+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %iv_2.next = add i32 %iv_2, -1 ; CHECK-NEXT: --> {(-1 + %start_2),+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %loop_cond = call i1 @cond() ; CHECK-NEXT: --> %loop_cond U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: Determining loop execution counts for: @test_two_phis_arithmetic_and ; CHECK-NEXT: Loop %loop: Unpredictable backedge-taken count. ; CHECK-NEXT: exit count for loop: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: exit count for range_check_block: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: exit count for backedge: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: Loop %loop: constant max backedge-taken count is i32 -1 ; CHECK-NEXT: Loop %loop: symbolic max backedge-taken count is (%start_1 umin %start_2) ; CHECK-NEXT: symbolic max exit count for loop: (%start_1 umin %start_2) ; CHECK-NEXT: symbolic max exit count for range_check_block: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: symbolic max exit count for backedge: ***COULDNOTCOMPUTE*** ; entry: br label %loop loop: %iv_1 = phi i32 [%start_1, %entry], [%iv_1.next, %backedge] %iv_2 = phi i32 [%start_2, %entry], [%iv_2.next, %backedge] %scam_1 = call i1 @cond() %zero_check_1 = icmp ne i32 %iv_1, 0 %c1 = and i1 %zero_check_1, %scam_1 %scam_2 = call i1 @cond() %zero_check_2 = icmp ne i32 %iv_2, 0 %c2 = and i1 %zero_check_2, %scam_2 %merged_cond = and i1 %c1, %c2 br i1 %merged_cond, label %range_check_block, label %failed_1 range_check_block: %iv.minus.1 = add i32 %iv_1, -1 %range_check = icmp ult i32 %iv.minus.1, %len br i1 %range_check, label %backedge, label %failed_2 backedge: %iv_1.next = add i32 %iv_1, -1 %iv_2.next = add i32 %iv_2, -1 %loop_cond = call i1 @cond() br i1 %loop_cond, label %done, label %loop done: ret i32 %iv_2 failed_1: ret i32 -1 failed_2: ret i32 -2 } ; TODO: Symbolic max can be start1 umax_seq start2 define i32 @test_two_phis_logical_or(i32 %start_1, i32 %start_2, i32 %len) { ; CHECK-LABEL: 'test_two_phis_logical_or' ; CHECK-NEXT: Classifying expressions for: @test_two_phis_logical_or ; CHECK-NEXT: %iv_1 = phi i32 [ %start_1, %entry ], [ %iv_1.next, %backedge ] ; CHECK-NEXT: --> {%start_1,+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %iv_2 = phi i32 [ %start_2, %entry ], [ %iv_2.next, %backedge ] ; CHECK-NEXT: --> {%start_2,+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %scam_1 = call i1 @cond() ; CHECK-NEXT: --> %scam_1 U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %c1 = and i1 %zero_check_1, %scam_1 ; CHECK-NEXT: --> (%zero_check_1 umin %scam_1) U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %scam_2 = call i1 @cond() ; CHECK-NEXT: --> %scam_2 U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %c2 = and i1 %zero_check_2, %scam_2 ; CHECK-NEXT: --> (%zero_check_2 umin %scam_2) U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %merged_cond = select i1 %c1, i1 true, i1 %c2 ; CHECK-NEXT: --> (true + ((true + (%zero_check_1 umin %scam_1)) umin_seq (true + (%zero_check_2 umin %scam_2)))) U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %iv.minus.1 = add i32 %iv_1, -1 ; CHECK-NEXT: --> {(-1 + %start_1),+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %iv_1.next = add i32 %iv_1, -1 ; CHECK-NEXT: --> {(-1 + %start_1),+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %iv_2.next = add i32 %iv_2, -1 ; CHECK-NEXT: --> {(-1 + %start_2),+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %loop_cond = call i1 @cond() ; CHECK-NEXT: --> %loop_cond U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: Determining loop execution counts for: @test_two_phis_logical_or ; CHECK-NEXT: Loop %loop: Unpredictable backedge-taken count. ; CHECK-NEXT: exit count for loop: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: exit count for range_check_block: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: exit count for backedge: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: Loop %loop: Unpredictable constant max backedge-taken count. ; CHECK-NEXT: Loop %loop: Unpredictable symbolic max backedge-taken count. ; CHECK-NEXT: symbolic max exit count for loop: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: symbolic max exit count for range_check_block: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: symbolic max exit count for backedge: ***COULDNOTCOMPUTE*** ; entry: br label %loop loop: %iv_1 = phi i32 [%start_1, %entry], [%iv_1.next, %backedge] %iv_2 = phi i32 [%start_2, %entry], [%iv_2.next, %backedge] %scam_1 = call i1 @cond() %zero_check_1 = icmp ne i32 %iv_1, 0 %c1 = and i1 %zero_check_1, %scam_1 %scam_2 = call i1 @cond() %zero_check_2 = icmp ne i32 %iv_2, 0 %c2 = and i1 %zero_check_2, %scam_2 %merged_cond = select i1 %c1, i1 true, i1 %c2 br i1 %merged_cond, label %range_check_block, label %failed_1 range_check_block: %iv.minus.1 = add i32 %iv_1, -1 %range_check = icmp ult i32 %iv.minus.1, %len br i1 %range_check, label %backedge, label %failed_2 backedge: %iv_1.next = add i32 %iv_1, -1 %iv_2.next = add i32 %iv_2, -1 %loop_cond = call i1 @cond() br i1 %loop_cond, label %done, label %loop done: ret i32 %iv_2 failed_1: ret i32 -1 failed_2: ret i32 -2 } define i32 @test_two_phis_logical_and(i32 %start_1, i32 %start_2, i32 %len) { ; CHECK-LABEL: 'test_two_phis_logical_and' ; CHECK-NEXT: Classifying expressions for: @test_two_phis_logical_and ; CHECK-NEXT: %iv_1 = phi i32 [ %start_1, %entry ], [ %iv_1.next, %backedge ] ; CHECK-NEXT: --> {%start_1,+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %iv_2 = phi i32 [ %start_2, %entry ], [ %iv_2.next, %backedge ] ; CHECK-NEXT: --> {%start_2,+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %scam_1 = call i1 @cond() ; CHECK-NEXT: --> %scam_1 U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %c1 = and i1 %zero_check_1, %scam_1 ; CHECK-NEXT: --> (%zero_check_1 umin %scam_1) U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %scam_2 = call i1 @cond() ; CHECK-NEXT: --> %scam_2 U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %c2 = and i1 %zero_check_2, %scam_2 ; CHECK-NEXT: --> (%zero_check_2 umin %scam_2) U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %merged_cond = select i1 %c1, i1 %c2, i1 false ; CHECK-NEXT: --> ((%zero_check_1 umin %scam_1) umin_seq (%zero_check_2 umin %scam_2)) U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: %iv.minus.1 = add i32 %iv_1, -1 ; CHECK-NEXT: --> {(-1 + %start_1),+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %iv_1.next = add i32 %iv_1, -1 ; CHECK-NEXT: --> {(-1 + %start_1),+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %iv_2.next = add i32 %iv_2, -1 ; CHECK-NEXT: --> {(-1 + %start_2),+,-1}<%loop> U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Computable } ; CHECK-NEXT: %loop_cond = call i1 @cond() ; CHECK-NEXT: --> %loop_cond U: full-set S: full-set Exits: <> LoopDispositions: { %loop: Variant } ; CHECK-NEXT: Determining loop execution counts for: @test_two_phis_logical_and ; CHECK-NEXT: Loop %loop: Unpredictable backedge-taken count. ; CHECK-NEXT: exit count for loop: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: exit count for range_check_block: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: exit count for backedge: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: Loop %loop: constant max backedge-taken count is i32 -1 ; CHECK-NEXT: Loop %loop: symbolic max backedge-taken count is (%start_1 umin_seq %start_2) ; CHECK-NEXT: symbolic max exit count for loop: (%start_1 umin_seq %start_2) ; CHECK-NEXT: symbolic max exit count for range_check_block: ***COULDNOTCOMPUTE*** ; CHECK-NEXT: symbolic max exit count for backedge: ***COULDNOTCOMPUTE*** ; entry: br label %loop loop: %iv_1 = phi i32 [%start_1, %entry], [%iv_1.next, %backedge] %iv_2 = phi i32 [%start_2, %entry], [%iv_2.next, %backedge] %scam_1 = call i1 @cond() %zero_check_1 = icmp ne i32 %iv_1, 0 %c1 = and i1 %zero_check_1, %scam_1 %scam_2 = call i1 @cond() %zero_check_2 = icmp ne i32 %iv_2, 0 %c2 = and i1 %zero_check_2, %scam_2 %merged_cond = select i1 %c1, i1 %c2, i1 false br i1 %merged_cond, label %range_check_block, label %failed_1 range_check_block: %iv.minus.1 = add i32 %iv_1, -1 %range_check = icmp ult i32 %iv.minus.1, %len br i1 %range_check, label %backedge, label %failed_2 backedge: %iv_1.next = add i32 %iv_1, -1 %iv_2.next = add i32 %iv_2, -1 %loop_cond = call i1 @cond() br i1 %loop_cond, label %done, label %loop done: ret i32 %iv_2 failed_1: ret i32 -1 failed_2: ret i32 -2 }