llvm-project/llvm/unittests/ADT/IntervalMapTest.cpp

//===---- ADT/IntervalMapTest.cpp - IntervalMap unit tests ------*- C++ -*-===//
//
//                     The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//

#include "llvm/ADT/IntervalMap.h"
#include "gtest/gtest.h"

using namespace llvm;

namespace {

typedef IntervalMap<unsigned, unsigned> UUMap;
typedef IntervalMap<unsigned, unsigned, 4> UU4Map;

// Empty map tests
TEST(IntervalMapTest, EmptyMap) {
  UUMap::Allocator allocator;
  UUMap map(allocator);
  EXPECT_TRUE(map.empty());

  // Lookup on empty map.
  EXPECT_EQ(0u, map.lookup(0));
  EXPECT_EQ(7u, map.lookup(0, 7));
  EXPECT_EQ(0u, map.lookup(~0u-1));
  EXPECT_EQ(7u, map.lookup(~0u-1, 7));

  // Iterators.
  EXPECT_TRUE(map.begin() == map.begin());
  EXPECT_TRUE(map.begin() == map.end());
  EXPECT_TRUE(map.end() == map.end());
  EXPECT_FALSE(map.begin() != map.begin());
  EXPECT_FALSE(map.begin() != map.end());
  EXPECT_FALSE(map.end() != map.end());
  EXPECT_FALSE(map.begin().valid());
  EXPECT_FALSE(map.end().valid());
  UUMap::iterator I = map.begin();
  EXPECT_FALSE(I.valid());
  EXPECT_TRUE(I == map.end());
}

// Single entry map tests
TEST(IntervalMapTest, SingleEntryMap) {
  UUMap::Allocator allocator;
  UUMap map(allocator);
  map.insert(100, 150, 1);
  EXPECT_FALSE(map.empty());

  // Lookup around interval.
  EXPECT_EQ(0u, map.lookup(0));
  EXPECT_EQ(0u, map.lookup(99));
  EXPECT_EQ(1u, map.lookup(100));
  EXPECT_EQ(1u, map.lookup(101));
  EXPECT_EQ(1u, map.lookup(125));
  EXPECT_EQ(1u, map.lookup(149));
  EXPECT_EQ(1u, map.lookup(150));
  EXPECT_EQ(0u, map.lookup(151));
  EXPECT_EQ(0u, map.lookup(200));
  EXPECT_EQ(0u, map.lookup(~0u-1));

  // Iterators.
  EXPECT_TRUE(map.begin() == map.begin());
  EXPECT_FALSE(map.begin() == map.end());
  EXPECT_TRUE(map.end() == map.end());
  EXPECT_TRUE(map.begin().valid());
  EXPECT_FALSE(map.end().valid());

  // Iter deref.
  UUMap::iterator I = map.begin();
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(100u, I.start());
  EXPECT_EQ(150u, I.stop());
  EXPECT_EQ(1u, I.value());

  // Preincrement.
  ++I;
  EXPECT_FALSE(I.valid());
  EXPECT_FALSE(I == map.begin());
  EXPECT_TRUE(I == map.end());

  // PreDecrement.
  --I;
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(100u, I.start());
  EXPECT_EQ(150u, I.stop());
  EXPECT_EQ(1u, I.value());
  EXPECT_TRUE(I == map.begin());
  EXPECT_FALSE(I == map.end());
}

// Flat coalescing tests.
TEST(IntervalMapTest, RootCoalescing) {
  UUMap::Allocator allocator;
  UUMap map(allocator);
  map.insert(100, 150, 1);

  // Coalesce from the left.
  map.insert(90, 99, 1);
  EXPECT_EQ(1, std::distance(map.begin(), map.end()));
  EXPECT_EQ(90u, map.start());
  EXPECT_EQ(150u, map.stop());

  // Overlap left.
  map.insert(80, 100, 1);
  EXPECT_EQ(1, std::distance(map.begin(), map.end()));
  EXPECT_EQ(80u, map.start());
  EXPECT_EQ(150u, map.stop());

  // Inside.
  map.insert(100, 130, 1);
  EXPECT_EQ(1, std::distance(map.begin(), map.end()));
  EXPECT_EQ(80u, map.start());
  EXPECT_EQ(150u, map.stop());

  // Overlap both.
  map.insert(70, 160, 1);
  EXPECT_EQ(1, std::distance(map.begin(), map.end()));
  EXPECT_EQ(70u, map.start());
  EXPECT_EQ(160u, map.stop());

  // Overlap right.
  map.insert(80, 170, 1);
  EXPECT_EQ(1, std::distance(map.begin(), map.end()));
  EXPECT_EQ(70u, map.start());
  EXPECT_EQ(170u, map.stop());

  // Coalesce from the right.
  map.insert(170, 200, 1);
  EXPECT_EQ(1, std::distance(map.begin(), map.end()));
  EXPECT_EQ(70u, map.start());
  EXPECT_EQ(200u, map.stop());

  // Non-coalesce from the left.
  map.insert(60, 69, 2);
  EXPECT_EQ(2, std::distance(map.begin(), map.end()));
  EXPECT_EQ(60u, map.start());
  EXPECT_EQ(200u, map.stop());
  EXPECT_EQ(2u, map.lookup(69));
  EXPECT_EQ(1u, map.lookup(70));

  UUMap::iterator I = map.begin();
  EXPECT_EQ(60u, I.start());
  EXPECT_EQ(69u, I.stop());
  EXPECT_EQ(2u, I.value());
  ++I;
  EXPECT_EQ(70u, I.start());
  EXPECT_EQ(200u, I.stop());
  EXPECT_EQ(1u, I.value());
  ++I;
  EXPECT_FALSE(I.valid());

  // Non-coalesce from the right.
  map.insert(201, 210, 2);
  EXPECT_EQ(3, std::distance(map.begin(), map.end()));
  EXPECT_EQ(60u, map.start());
  EXPECT_EQ(210u, map.stop());
  EXPECT_EQ(2u, map.lookup(201));
  EXPECT_EQ(1u, map.lookup(200));
}

// Flat multi-coalescing tests.
TEST(IntervalMapTest, RootMultiCoalescing) {
  UUMap::Allocator allocator;
  UUMap map(allocator);
  map.insert(140, 150, 1);
  map.insert(160, 170, 1);
  map.insert(100, 110, 1);
  map.insert(120, 130, 1);
  EXPECT_EQ(4, std::distance(map.begin(), map.end()));
  EXPECT_EQ(100u, map.start());
  EXPECT_EQ(170u, map.stop());

  // Verify inserts.
  UUMap::iterator I = map.begin();
  EXPECT_EQ(100u, I.start());
  EXPECT_EQ(110u, I.stop());
  ++I;
  EXPECT_EQ(120u, I.start());
  EXPECT_EQ(130u, I.stop());
  ++I;
  EXPECT_EQ(140u, I.start());
  EXPECT_EQ(150u, I.stop());
  ++I;
  EXPECT_EQ(160u, I.start());
  EXPECT_EQ(170u, I.stop());
  ++I;
  EXPECT_FALSE(I.valid());


  // Coalesce left with followers.
  // [100;110] [120;130] [140;150] [160;170]
  map.insert(111, 115, 1);
  I = map.begin();
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(100u, I.start());
  EXPECT_EQ(115u, I.stop());
  ++I;
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(120u, I.start());
  EXPECT_EQ(130u, I.stop());
  ++I;
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(140u, I.start());
  EXPECT_EQ(150u, I.stop());
  ++I;
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(160u, I.start());
  EXPECT_EQ(170u, I.stop());
  ++I;
  EXPECT_FALSE(I.valid());

  // Coalesce right with followers.
  // [100;115] [120;130] [140;150] [160;170]
  map.insert(135, 139, 1);
  I = map.begin();
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(100u, I.start());
  EXPECT_EQ(115u, I.stop());
  ++I;
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(120u, I.start());
  EXPECT_EQ(130u, I.stop());
  ++I;
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(135u, I.start());
  EXPECT_EQ(150u, I.stop());
  ++I;
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(160u, I.start());
  EXPECT_EQ(170u, I.stop());
  ++I;
  EXPECT_FALSE(I.valid());

  // Coalesce left and right with followers.
  // [100;115] [120;130] [135;150] [160;170]
  map.insert(131, 134, 1);
  I = map.begin();
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(100u, I.start());
  EXPECT_EQ(115u, I.stop());
  ++I;
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(120u, I.start());
  EXPECT_EQ(150u, I.stop());
  ++I;
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(160u, I.start());
  EXPECT_EQ(170u, I.stop());
  ++I;
  EXPECT_FALSE(I.valid());

  // Coalesce multiple with overlap right.
  // [100;115] [120;150] [160;170]
  map.insert(116, 165, 1);
  I = map.begin();
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(100u, I.start());
  EXPECT_EQ(170u, I.stop());
  ++I;
  EXPECT_FALSE(I.valid());

  // Coalesce multiple with overlap left
  // [100;170]
  map.insert(180, 190, 1);
  map.insert(200, 210, 1);
  map.insert(220, 230, 1);
  // [100;170] [180;190] [200;210] [220;230]
  map.insert(160, 199, 1);
  I = map.begin();
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(100u, I.start());
  EXPECT_EQ(210u, I.stop());
  ++I;
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(220u, I.start());
  EXPECT_EQ(230u, I.stop());
  ++I;
  EXPECT_FALSE(I.valid());

  // Overwrite 2 from gap to gap.
  // [100;210] [220;230]
  map.insert(50, 250, 1);
  I = map.begin();
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(50u, I.start());
  EXPECT_EQ(250u, I.stop());
  ++I;
  EXPECT_FALSE(I.valid());

  // Coalesce at end of full root.
  // [50;250]
  map.insert(260, 270, 1);
  map.insert(280, 290, 1);
  map.insert(300, 310, 1);
  // [50;250] [260;270] [280;290] [300;310]
  map.insert(311, 320, 1);
  I = map.begin();
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(50u, I.start());
  EXPECT_EQ(250u, I.stop());
  ++I;
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(260u, I.start());
  EXPECT_EQ(270u, I.stop());
  ++I;
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(280u, I.start());
  EXPECT_EQ(290u, I.stop());
  ++I;
  ASSERT_TRUE(I.valid());
  EXPECT_EQ(300u, I.start());
  EXPECT_EQ(320u, I.stop());
  ++I;
  EXPECT_FALSE(I.valid());

  // Test clear() on non-branched map.
  map.clear();
  EXPECT_TRUE(map.empty());
  EXPECT_TRUE(map.begin() == map.end());
}

// Branched, non-coalescing tests.
TEST(IntervalMapTest, Branched) {
  UUMap::Allocator allocator;
  UUMap map(allocator);

  // Insert enough intervals to force a branched tree.
  // This creates 9 leaf nodes with 11 elements each, tree height = 1.
  for (unsigned i = 1; i < 100; ++i)
    map.insert(10*i, 10*i+5, i);

  // Tree limits.
  EXPECT_FALSE(map.empty());
  EXPECT_EQ(10u, map.start());
  EXPECT_EQ(995u, map.stop());

  // Tree lookup.
  for (unsigned i = 1; i < 100; ++i) {
    EXPECT_EQ(0u, map.lookup(10*i-1));
    EXPECT_EQ(i, map.lookup(10*i));
    EXPECT_EQ(i, map.lookup(10*i+5));
    EXPECT_EQ(0u, map.lookup(10*i+6));
  }

  // Forward iteration.
  UUMap::iterator I = map.begin();
  for (unsigned i = 1; i < 100; ++i) {
    ASSERT_TRUE(I.valid());
    EXPECT_EQ(10*i, I.start());
    EXPECT_EQ(10*i+5, I.stop());
    EXPECT_EQ(i, *I);
    ++I;
  }
  EXPECT_FALSE(I.valid());
  EXPECT_TRUE(I == map.end());

  // Backwards iteration.
  for (unsigned i = 99; i; --i) {
    --I;
    ASSERT_TRUE(I.valid());
    EXPECT_EQ(10*i, I.start());
    EXPECT_EQ(10*i+5, I.stop());
    EXPECT_EQ(i, *I);
  }
  EXPECT_TRUE(I == map.begin());

  // Test clear() on branched map.
  map.clear();
  EXPECT_TRUE(map.empty());
  EXPECT_TRUE(map.begin() == map.end());
}

// Branched, high, non-coalescing tests.
TEST(IntervalMapTest, Branched2) {
  UU4Map::Allocator allocator;
  UU4Map map(allocator);

  // Insert enough intervals to force a height >= 2 tree.
  for (unsigned i = 1; i < 1000; ++i)
    map.insert(10*i, 10*i+5, i);

  // Tree limits.
  EXPECT_FALSE(map.empty());
  EXPECT_EQ(10u, map.start());
  EXPECT_EQ(9995u, map.stop());

  // Tree lookup.
  for (unsigned i = 1; i < 1000; ++i) {
    EXPECT_EQ(0u, map.lookup(10*i-1));
    EXPECT_EQ(i, map.lookup(10*i));
    EXPECT_EQ(i, map.lookup(10*i+5));
    EXPECT_EQ(0u, map.lookup(10*i+6));
  }

  // Forward iteration.
  UU4Map::iterator I = map.begin();
  for (unsigned i = 1; i < 1000; ++i) {
    ASSERT_TRUE(I.valid());
    EXPECT_EQ(10*i, I.start());
    EXPECT_EQ(10*i+5, I.stop());
    EXPECT_EQ(i, *I);
    ++I;
  }
  EXPECT_FALSE(I.valid());
  EXPECT_TRUE(I == map.end());

  // Backwards iteration.
  for (unsigned i = 999; i; --i) {
    --I;
    ASSERT_TRUE(I.valid());
    EXPECT_EQ(10*i, I.start());
    EXPECT_EQ(10*i+5, I.stop());
    EXPECT_EQ(i, *I);
  }
  EXPECT_TRUE(I == map.begin());

  // Test clear() on branched map.
  map.clear();
  EXPECT_TRUE(map.empty());
  EXPECT_TRUE(map.begin() == map.end());
}

} // namespace
Add ADT/IntervalMap. This is a sorted interval map data structure for small keys and values with automatic coalescing and bidirectional iteration over coalesced intervals. Except for coalescing intervals, it provides similar functionality to std::map. It is however much more compact for small keys and values, and hopefully faster too. The container object itself can hold the first few intervals without any allocations, then it switches to a cache conscious B+-tree representation. A recycling allocator can be shared between many containers, even between containers holding different types. The IntervalMap is initially intended to be used with SlotIndex intervals for: - Backing store for LiveIntervalUnion that is smaller and faster than std::set. - Backing store for LiveInterval with less overhead than std::vector for typical intervals and O(N log N) merging of large intervals. 99% of virtual registers need 4 entries or less and would benefit from the small object optimization. - Backing store for LiveDebugVariable which doesn't exist yet, but will track debug variables during register allocation. This is a work in progress. Missing items are: - Performance metrics. - erase(). - insert() shrinkage. - clear(). - More performance metrics. - Simplification and detemplatization. llvm-svn: 119787 2010-11-19 12:47:19 +08:00			`//===---- ADT/IntervalMapTest.cpp - IntervalMap unit tests ------- C++ --===//`
			`//`
			`// The LLVM Compiler Infrastructure`
			`//`
			`// This file is distributed under the University of Illinois Open Source`
			`// License. See LICENSE.TXT for details.`
			`//`
			`//===----------------------------------------------------------------------===//`

			`#include "llvm/ADT/IntervalMap.h"`
			`#include "gtest/gtest.h"`

			`using namespace llvm;`

			`namespace {`

			`typedef IntervalMap<unsigned, unsigned> UUMap;`
Add B+-tree test case that creates a height 3 tree with a smaller root node. Change temporary debugging code to write a dot file directly. llvm-svn: 120171 2010-11-26 14:54:20 +08:00			`typedef IntervalMap<unsigned, unsigned, 4> UU4Map;`
Add ADT/IntervalMap. This is a sorted interval map data structure for small keys and values with automatic coalescing and bidirectional iteration over coalesced intervals. Except for coalescing intervals, it provides similar functionality to std::map. It is however much more compact for small keys and values, and hopefully faster too. The container object itself can hold the first few intervals without any allocations, then it switches to a cache conscious B+-tree representation. A recycling allocator can be shared between many containers, even between containers holding different types. The IntervalMap is initially intended to be used with SlotIndex intervals for: - Backing store for LiveIntervalUnion that is smaller and faster than std::set. - Backing store for LiveInterval with less overhead than std::vector for typical intervals and O(N log N) merging of large intervals. 99% of virtual registers need 4 entries or less and would benefit from the small object optimization. - Backing store for LiveDebugVariable which doesn't exist yet, but will track debug variables during register allocation. This is a work in progress. Missing items are: - Performance metrics. - erase(). - insert() shrinkage. - clear(). - More performance metrics. - Simplification and detemplatization. llvm-svn: 119787 2010-11-19 12:47:19 +08:00
			`// Empty map tests`
			`TEST(IntervalMapTest, EmptyMap) {`
			`UUMap::Allocator allocator;`
			`UUMap map(allocator);`
			`EXPECT_TRUE(map.empty());`

			`// Lookup on empty map.`
			`EXPECT_EQ(0u, map.lookup(0));`
			`EXPECT_EQ(7u, map.lookup(0, 7));`
			`EXPECT_EQ(0u, map.lookup(~0u-1));`
			`EXPECT_EQ(7u, map.lookup(~0u-1, 7));`

			`// Iterators.`
			`EXPECT_TRUE(map.begin() == map.begin());`
			`EXPECT_TRUE(map.begin() == map.end());`
			`EXPECT_TRUE(map.end() == map.end());`
			`EXPECT_FALSE(map.begin() != map.begin());`
			`EXPECT_FALSE(map.begin() != map.end());`
			`EXPECT_FALSE(map.end() != map.end());`
			`EXPECT_FALSE(map.begin().valid());`
			`EXPECT_FALSE(map.end().valid());`
			`UUMap::iterator I = map.begin();`
			`EXPECT_FALSE(I.valid());`
			`EXPECT_TRUE(I == map.end());`
			`}`

			`// Single entry map tests`
			`TEST(IntervalMapTest, SingleEntryMap) {`
			`UUMap::Allocator allocator;`
			`UUMap map(allocator);`
			`map.insert(100, 150, 1);`
			`EXPECT_FALSE(map.empty());`

			`// Lookup around interval.`
			`EXPECT_EQ(0u, map.lookup(0));`
			`EXPECT_EQ(0u, map.lookup(99));`
			`EXPECT_EQ(1u, map.lookup(100));`
			`EXPECT_EQ(1u, map.lookup(101));`
			`EXPECT_EQ(1u, map.lookup(125));`
			`EXPECT_EQ(1u, map.lookup(149));`
			`EXPECT_EQ(1u, map.lookup(150));`
			`EXPECT_EQ(0u, map.lookup(151));`
			`EXPECT_EQ(0u, map.lookup(200));`
			`EXPECT_EQ(0u, map.lookup(~0u-1));`

			`// Iterators.`
			`EXPECT_TRUE(map.begin() == map.begin());`
			`EXPECT_FALSE(map.begin() == map.end());`
			`EXPECT_TRUE(map.end() == map.end());`
			`EXPECT_TRUE(map.begin().valid());`
			`EXPECT_FALSE(map.end().valid());`

			`// Iter deref.`
			`UUMap::iterator I = map.begin();`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(100u, I.start());`
			`EXPECT_EQ(150u, I.stop());`
			`EXPECT_EQ(1u, I.value());`

			`// Preincrement.`
			`++I;`
			`EXPECT_FALSE(I.valid());`
			`EXPECT_FALSE(I == map.begin());`
			`EXPECT_TRUE(I == map.end());`

			`// PreDecrement.`
			`--I;`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(100u, I.start());`
			`EXPECT_EQ(150u, I.stop());`
			`EXPECT_EQ(1u, I.value());`
			`EXPECT_TRUE(I == map.begin());`
			`EXPECT_FALSE(I == map.end());`
			`}`

			`// Flat coalescing tests.`
			`TEST(IntervalMapTest, RootCoalescing) {`
			`UUMap::Allocator allocator;`
			`UUMap map(allocator);`
			`map.insert(100, 150, 1);`

			`// Coalesce from the left.`
			`map.insert(90, 99, 1);`
			`EXPECT_EQ(1, std::distance(map.begin(), map.end()));`
			`EXPECT_EQ(90u, map.start());`
			`EXPECT_EQ(150u, map.stop());`

			`// Overlap left.`
			`map.insert(80, 100, 1);`
			`EXPECT_EQ(1, std::distance(map.begin(), map.end()));`
			`EXPECT_EQ(80u, map.start());`
			`EXPECT_EQ(150u, map.stop());`

			`// Inside.`
			`map.insert(100, 130, 1);`
			`EXPECT_EQ(1, std::distance(map.begin(), map.end()));`
			`EXPECT_EQ(80u, map.start());`
			`EXPECT_EQ(150u, map.stop());`

			`// Overlap both.`
			`map.insert(70, 160, 1);`
			`EXPECT_EQ(1, std::distance(map.begin(), map.end()));`
			`EXPECT_EQ(70u, map.start());`
			`EXPECT_EQ(160u, map.stop());`

			`// Overlap right.`
			`map.insert(80, 170, 1);`
			`EXPECT_EQ(1, std::distance(map.begin(), map.end()));`
			`EXPECT_EQ(70u, map.start());`
			`EXPECT_EQ(170u, map.stop());`

			`// Coalesce from the right.`
			`map.insert(170, 200, 1);`
			`EXPECT_EQ(1, std::distance(map.begin(), map.end()));`
			`EXPECT_EQ(70u, map.start());`
			`EXPECT_EQ(200u, map.stop());`

			`// Non-coalesce from the left.`
			`map.insert(60, 69, 2);`
			`EXPECT_EQ(2, std::distance(map.begin(), map.end()));`
			`EXPECT_EQ(60u, map.start());`
			`EXPECT_EQ(200u, map.stop());`
			`EXPECT_EQ(2u, map.lookup(69));`
			`EXPECT_EQ(1u, map.lookup(70));`

			`UUMap::iterator I = map.begin();`
			`EXPECT_EQ(60u, I.start());`
			`EXPECT_EQ(69u, I.stop());`
			`EXPECT_EQ(2u, I.value());`
			`++I;`
			`EXPECT_EQ(70u, I.start());`
			`EXPECT_EQ(200u, I.stop());`
			`EXPECT_EQ(1u, I.value());`
			`++I;`
			`EXPECT_FALSE(I.valid());`

			`// Non-coalesce from the right.`
			`map.insert(201, 210, 2);`
			`EXPECT_EQ(3, std::distance(map.begin(), map.end()));`
			`EXPECT_EQ(60u, map.start());`
			`EXPECT_EQ(210u, map.stop());`
			`EXPECT_EQ(2u, map.lookup(201));`
			`EXPECT_EQ(1u, map.lookup(200));`
			`}`

			`// Flat multi-coalescing tests.`
			`TEST(IntervalMapTest, RootMultiCoalescing) {`
			`UUMap::Allocator allocator;`
			`UUMap map(allocator);`
			`map.insert(140, 150, 1);`
			`map.insert(160, 170, 1);`
			`map.insert(100, 110, 1);`
			`map.insert(120, 130, 1);`
			`EXPECT_EQ(4, std::distance(map.begin(), map.end()));`
			`EXPECT_EQ(100u, map.start());`
			`EXPECT_EQ(170u, map.stop());`

			`// Verify inserts.`
			`UUMap::iterator I = map.begin();`
			`EXPECT_EQ(100u, I.start());`
			`EXPECT_EQ(110u, I.stop());`
			`++I;`
			`EXPECT_EQ(120u, I.start());`
			`EXPECT_EQ(130u, I.stop());`
			`++I;`
			`EXPECT_EQ(140u, I.start());`
			`EXPECT_EQ(150u, I.stop());`
			`++I;`
			`EXPECT_EQ(160u, I.start());`
			`EXPECT_EQ(170u, I.stop());`
			`++I;`
			`EXPECT_FALSE(I.valid());`


			`// Coalesce left with followers.`
			`// [100;110] [120;130] [140;150] [160;170]`
			`map.insert(111, 115, 1);`
			`I = map.begin();`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(100u, I.start());`
			`EXPECT_EQ(115u, I.stop());`
			`++I;`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(120u, I.start());`
			`EXPECT_EQ(130u, I.stop());`
			`++I;`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(140u, I.start());`
			`EXPECT_EQ(150u, I.stop());`
			`++I;`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(160u, I.start());`
			`EXPECT_EQ(170u, I.stop());`
			`++I;`
			`EXPECT_FALSE(I.valid());`

			`// Coalesce right with followers.`
			`// [100;115] [120;130] [140;150] [160;170]`
			`map.insert(135, 139, 1);`
			`I = map.begin();`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(100u, I.start());`
			`EXPECT_EQ(115u, I.stop());`
			`++I;`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(120u, I.start());`
			`EXPECT_EQ(130u, I.stop());`
			`++I;`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(135u, I.start());`
			`EXPECT_EQ(150u, I.stop());`
			`++I;`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(160u, I.start());`
			`EXPECT_EQ(170u, I.stop());`
			`++I;`
			`EXPECT_FALSE(I.valid());`

			`// Coalesce left and right with followers.`
			`// [100;115] [120;130] [135;150] [160;170]`
			`map.insert(131, 134, 1);`
			`I = map.begin();`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(100u, I.start());`
			`EXPECT_EQ(115u, I.stop());`
			`++I;`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(120u, I.start());`
			`EXPECT_EQ(150u, I.stop());`
			`++I;`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(160u, I.start());`
			`EXPECT_EQ(170u, I.stop());`
			`++I;`
			`EXPECT_FALSE(I.valid());`

			`// Coalesce multiple with overlap right.`
			`// [100;115] [120;150] [160;170]`
			`map.insert(116, 165, 1);`
			`I = map.begin();`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(100u, I.start());`
			`EXPECT_EQ(170u, I.stop());`
			`++I;`
			`EXPECT_FALSE(I.valid());`

			`// Coalesce multiple with overlap left`
			`// [100;170]`
			`map.insert(180, 190, 1);`
			`map.insert(200, 210, 1);`
			`map.insert(220, 230, 1);`
			`// [100;170] [180;190] [200;210] [220;230]`
			`map.insert(160, 199, 1);`
			`I = map.begin();`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(100u, I.start());`
			`EXPECT_EQ(210u, I.stop());`
			`++I;`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(220u, I.start());`
			`EXPECT_EQ(230u, I.stop());`
			`++I;`
			`EXPECT_FALSE(I.valid());`

			`// Overwrite 2 from gap to gap.`
			`// [100;210] [220;230]`
			`map.insert(50, 250, 1);`
			`I = map.begin();`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(50u, I.start());`
			`EXPECT_EQ(250u, I.stop());`
			`++I;`
			`EXPECT_FALSE(I.valid());`

			`// Coalesce at end of full root.`
			`// [50;250]`
			`map.insert(260, 270, 1);`
			`map.insert(280, 290, 1);`
			`map.insert(300, 310, 1);`
			`// [50;250] [260;270] [280;290] [300;310]`
			`map.insert(311, 320, 1);`
			`I = map.begin();`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(50u, I.start());`
			`EXPECT_EQ(250u, I.stop());`
			`++I;`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(260u, I.start());`
			`EXPECT_EQ(270u, I.stop());`
			`++I;`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(280u, I.start());`
			`EXPECT_EQ(290u, I.stop());`
			`++I;`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(300u, I.start());`
			`EXPECT_EQ(320u, I.stop());`
			`++I;`
			`EXPECT_FALSE(I.valid());`
Implement IntervalMap::clear(). llvm-svn: 119872 2010-11-20 07:28:57 +08:00
			`// Test clear() on non-branched map.`
			`map.clear();`
			`EXPECT_TRUE(map.empty());`
			`EXPECT_TRUE(map.begin() == map.end());`
Add ADT/IntervalMap. This is a sorted interval map data structure for small keys and values with automatic coalescing and bidirectional iteration over coalesced intervals. Except for coalescing intervals, it provides similar functionality to std::map. It is however much more compact for small keys and values, and hopefully faster too. The container object itself can hold the first few intervals without any allocations, then it switches to a cache conscious B+-tree representation. A recycling allocator can be shared between many containers, even between containers holding different types. The IntervalMap is initially intended to be used with SlotIndex intervals for: - Backing store for LiveIntervalUnion that is smaller and faster than std::set. - Backing store for LiveInterval with less overhead than std::vector for typical intervals and O(N log N) merging of large intervals. 99% of virtual registers need 4 entries or less and would benefit from the small object optimization. - Backing store for LiveDebugVariable which doesn't exist yet, but will track debug variables during register allocation. This is a work in progress. Missing items are: - Performance metrics. - erase(). - insert() shrinkage. - clear(). - More performance metrics. - Simplification and detemplatization. llvm-svn: 119787 2010-11-19 12:47:19 +08:00			`}`

			`// Branched, non-coalescing tests.`
			`TEST(IntervalMapTest, Branched) {`
			`UUMap::Allocator allocator;`
			`UUMap map(allocator);`

			`// Insert enough intervals to force a branched tree.`
			`// This creates 9 leaf nodes with 11 elements each, tree height = 1.`
			`for (unsigned i = 1; i < 100; ++i)`
			`map.insert(10i, 10i+5, i);`

			`// Tree limits.`
			`EXPECT_FALSE(map.empty());`
			`EXPECT_EQ(10u, map.start());`
			`EXPECT_EQ(995u, map.stop());`

			`// Tree lookup.`
			`for (unsigned i = 1; i < 100; ++i) {`
			`EXPECT_EQ(0u, map.lookup(10*i-1));`
			`EXPECT_EQ(i, map.lookup(10*i));`
			`EXPECT_EQ(i, map.lookup(10*i+5));`
			`EXPECT_EQ(0u, map.lookup(10*i+6));`
			`}`

			`// Forward iteration.`
			`UUMap::iterator I = map.begin();`
			`for (unsigned i = 1; i < 100; ++i) {`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(10*i, I.start());`
			`EXPECT_EQ(10*i+5, I.stop());`
			`EXPECT_EQ(i, *I);`
			`++I;`
			`}`
			`EXPECT_FALSE(I.valid());`
			`EXPECT_TRUE(I == map.end());`

Support backwards iteration starting from end(). llvm-svn: 119871 2010-11-20 07:28:53 +08:00			`// Backwards iteration.`
			`for (unsigned i = 99; i; --i) {`
			`--I;`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(10*i, I.start());`
			`EXPECT_EQ(10*i+5, I.stop());`
			`EXPECT_EQ(i, *I);`
			`}`
			`EXPECT_TRUE(I == map.begin());`

Implement IntervalMap::clear(). llvm-svn: 119872 2010-11-20 07:28:57 +08:00			`// Test clear() on branched map.`
			`map.clear();`
			`EXPECT_TRUE(map.empty());`
			`EXPECT_TRUE(map.begin() == map.end());`
Add ADT/IntervalMap. This is a sorted interval map data structure for small keys and values with automatic coalescing and bidirectional iteration over coalesced intervals. Except for coalescing intervals, it provides similar functionality to std::map. It is however much more compact for small keys and values, and hopefully faster too. The container object itself can hold the first few intervals without any allocations, then it switches to a cache conscious B+-tree representation. A recycling allocator can be shared between many containers, even between containers holding different types. The IntervalMap is initially intended to be used with SlotIndex intervals for: - Backing store for LiveIntervalUnion that is smaller and faster than std::set. - Backing store for LiveInterval with less overhead than std::vector for typical intervals and O(N log N) merging of large intervals. 99% of virtual registers need 4 entries or less and would benefit from the small object optimization. - Backing store for LiveDebugVariable which doesn't exist yet, but will track debug variables during register allocation. This is a work in progress. Missing items are: - Performance metrics. - erase(). - insert() shrinkage. - clear(). - More performance metrics. - Simplification and detemplatization. llvm-svn: 119787 2010-11-19 12:47:19 +08:00			`}`

Add B+-tree test case that creates a height 3 tree with a smaller root node. Change temporary debugging code to write a dot file directly. llvm-svn: 120171 2010-11-26 14:54:20 +08:00			`// Branched, high, non-coalescing tests.`
			`TEST(IntervalMapTest, Branched2) {`
			`UU4Map::Allocator allocator;`
			`UU4Map map(allocator);`

			`// Insert enough intervals to force a height >= 2 tree.`
			`for (unsigned i = 1; i < 1000; ++i)`
			`map.insert(10i, 10i+5, i);`

			`// Tree limits.`
			`EXPECT_FALSE(map.empty());`
			`EXPECT_EQ(10u, map.start());`
			`EXPECT_EQ(9995u, map.stop());`

			`// Tree lookup.`
			`for (unsigned i = 1; i < 1000; ++i) {`
			`EXPECT_EQ(0u, map.lookup(10*i-1));`
			`EXPECT_EQ(i, map.lookup(10*i));`
			`EXPECT_EQ(i, map.lookup(10*i+5));`
			`EXPECT_EQ(0u, map.lookup(10*i+6));`
			`}`

			`// Forward iteration.`
			`UU4Map::iterator I = map.begin();`
			`for (unsigned i = 1; i < 1000; ++i) {`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(10*i, I.start());`
			`EXPECT_EQ(10*i+5, I.stop());`
			`EXPECT_EQ(i, *I);`
			`++I;`
			`}`
			`EXPECT_FALSE(I.valid());`
			`EXPECT_TRUE(I == map.end());`

			`// Backwards iteration.`
			`for (unsigned i = 999; i; --i) {`
			`--I;`
			`ASSERT_TRUE(I.valid());`
			`EXPECT_EQ(10*i, I.start());`
			`EXPECT_EQ(10*i+5, I.stop());`
			`EXPECT_EQ(i, *I);`
			`}`
			`EXPECT_TRUE(I == map.begin());`

			`// Test clear() on branched map.`
			`map.clear();`
			`EXPECT_TRUE(map.empty());`
			`EXPECT_TRUE(map.begin() == map.end());`
			`}`

Add ADT/IntervalMap. This is a sorted interval map data structure for small keys and values with automatic coalescing and bidirectional iteration over coalesced intervals. Except for coalescing intervals, it provides similar functionality to std::map. It is however much more compact for small keys and values, and hopefully faster too. The container object itself can hold the first few intervals without any allocations, then it switches to a cache conscious B+-tree representation. A recycling allocator can be shared between many containers, even between containers holding different types. The IntervalMap is initially intended to be used with SlotIndex intervals for: - Backing store for LiveIntervalUnion that is smaller and faster than std::set. - Backing store for LiveInterval with less overhead than std::vector for typical intervals and O(N log N) merging of large intervals. 99% of virtual registers need 4 entries or less and would benefit from the small object optimization. - Backing store for LiveDebugVariable which doesn't exist yet, but will track debug variables during register allocation. This is a work in progress. Missing items are: - Performance metrics. - erase(). - insert() shrinkage. - clear(). - More performance metrics. - Simplification and detemplatization. llvm-svn: 119787 2010-11-19 12:47:19 +08:00			`} // namespace`