package atlas
import (
"testing"
"github.com/mdiluz/rove/pkg/maths"
"github.com/mdiluz/rove/proto/roveapi"
"github.com/stretchr/testify/assert"
)
func TestAtlas_NewAtlas(t *testing.T) {
a := NewChunkAtlas(1).(*chunkBasedAtlas)
assert.NotNil(t, a)
assert.Equal(t, 1, a.ChunkSize)
assert.Equal(t, 1, len(a.Chunks)) // Should start empty
}
func TestAtlas_toChunk(t *testing.T) {
a := NewChunkAtlas(1).(*chunkBasedAtlas)
assert.NotNil(t, a)
// Get a tile to spawn the chunks
a.QueryPosition(maths.Vector{X: -1, Y: -1})
a.QueryPosition(maths.Vector{X: 0, Y: 0})
assert.Equal(t, 2*2, len(a.Chunks))
// Chunks should look like:
// 2 | 3
// -----
// 0 | 1
chunkID := a.worldSpaceToChunkIndex(maths.Vector{X: 0, Y: 0})
assert.Equal(t, 3, chunkID)
chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: 0, Y: -1})
assert.Equal(t, 1, chunkID)
chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: -1, Y: -1})
assert.Equal(t, 0, chunkID)
chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: -1, Y: 0})
assert.Equal(t, 2, chunkID)
a = NewChunkAtlas(2).(*chunkBasedAtlas)
assert.NotNil(t, a)
// Get a tile to spawn the chunks
a.QueryPosition(maths.Vector{X: -2, Y: -2})
assert.Equal(t, 2*2, len(a.Chunks))
a.QueryPosition(maths.Vector{X: 1, Y: 1})
assert.Equal(t, 2*2, len(a.Chunks))
// Chunks should look like:
// 2 | 3
// -----
// 0 | 1
chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: 1, Y: 1})
assert.Equal(t, 3, chunkID)
chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: 1, Y: -2})
assert.Equal(t, 1, chunkID)
chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: -2, Y: -2})
assert.Equal(t, 0, chunkID)
chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: -2, Y: 1})
assert.Equal(t, 2, chunkID)
a = NewChunkAtlas(2).(*chunkBasedAtlas)
assert.NotNil(t, a)
// Get a tile to spawn a 4x4 grid of chunks
a.QueryPosition(maths.Vector{X: 3, Y: 3})
assert.Equal(t, 2*2, len(a.Chunks))
a.QueryPosition(maths.Vector{X: -3, Y: -3})
assert.Equal(t, 4*4, len(a.Chunks))
// Chunks should look like:
// 12| 13|| 14| 15
// ----------------
// 8 | 9 || 10| 11
// ================
// 4 | 5 || 6 | 7
// ----------------
// 0 | 1 || 2 | 3
chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: 1, Y: 3})
assert.Equal(t, 14, chunkID)
chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: 1, Y: -3})
assert.Equal(t, 2, chunkID)
chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: -1, Y: -1})
assert.Equal(t, 5, chunkID)
chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: -2, Y: 2})
assert.Equal(t, 13, chunkID)
a = NewChunkAtlas(3).(*chunkBasedAtlas)
assert.NotNil(t, a)
// Get a tile to spawn a 4x4 grid of chunks
a.QueryPosition(maths.Vector{X: 3, Y: 3})
assert.Equal(t, 2*2, len(a.Chunks))
// Chunks should look like:
// || 2| 3
// -------
// || 0| 1
// =======
chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: 1, Y: 1})
assert.Equal(t, 0, chunkID)
chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: 3, Y: 1})
assert.Equal(t, 1, chunkID)
chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: 1, Y: 4})
assert.Equal(t, 2, chunkID)
chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: 5, Y: 5})
assert.Equal(t, 3, chunkID)
}
func TestAtlas_toWorld(t *testing.T) {
a := NewChunkAtlas(1).(*chunkBasedAtlas)
assert.NotNil(t, a)
// Get a tile to spawn some chunks
a.QueryPosition(maths.Vector{X: -1, Y: -1})
assert.Equal(t, 2*2, len(a.Chunks))
// Chunks should look like:
// 2 | 3
// -----
// 0 | 1
assert.Equal(t, maths.Vector{X: -1, Y: -1}, a.chunkOriginInWorldSpace(0))
assert.Equal(t, maths.Vector{X: 0, Y: -1}, a.chunkOriginInWorldSpace(1))
a = NewChunkAtlas(2).(*chunkBasedAtlas)
assert.NotNil(t, a)
// Get a tile to spawn the chunks
a.QueryPosition(maths.Vector{X: -2, Y: -2})
assert.Equal(t, 2*2, len(a.Chunks))
a.QueryPosition(maths.Vector{X: 1, Y: 1})
assert.Equal(t, 2*2, len(a.Chunks))
// Chunks should look like:
// 2 | 3
// -----
// 0 | 1
assert.Equal(t, maths.Vector{X: -2, Y: -2}, a.chunkOriginInWorldSpace(0))
assert.Equal(t, maths.Vector{X: -2, Y: 0}, a.chunkOriginInWorldSpace(2))
a = NewChunkAtlas(2).(*chunkBasedAtlas)
assert.NotNil(t, a)
// Get a tile to spawn a 4x4 grid of chunks
a.QueryPosition(maths.Vector{X: 3, Y: 3})
assert.Equal(t, 2*2, len(a.Chunks))
a.QueryPosition(maths.Vector{X: -3, Y: -3})
assert.Equal(t, 4*4, len(a.Chunks))
// Chunks should look like:
// 12| 13|| 14| 15
// ----------------
// 8 | 9 || 10| 11
// ================
// 4 | 5 || 6 | 7
// ----------------
// 0 | 1 || 2 | 3
assert.Equal(t, maths.Vector{X: -4, Y: -4}, a.chunkOriginInWorldSpace(0))
assert.Equal(t, maths.Vector{X: 2, Y: -2}, a.chunkOriginInWorldSpace(7))
a = NewChunkAtlas(3).(*chunkBasedAtlas)
assert.NotNil(t, a)
// Get a tile to spawn a 4x4 grid of chunks
a.QueryPosition(maths.Vector{X: 3, Y: 3})
assert.Equal(t, 2*2, len(a.Chunks))
// Chunks should look like:
// || 2| 3
// -------
// || 0| 1
// =======
assert.Equal(t, maths.Vector{X: 0, Y: 0}, a.chunkOriginInWorldSpace(0))
}
func TestAtlas_GetSetTile(t *testing.T) {
a := NewChunkAtlas(10)
assert.NotNil(t, a)
// Set the origin tile and test it
a.SetTile(maths.Vector{X: 0, Y: 0}, roveapi.Tile_Gravel)
tile, _ := a.QueryPosition(maths.Vector{X: 0, Y: 0})
assert.Equal(t, roveapi.Tile_Gravel, tile)
// Set another tile and test it
a.SetTile(maths.Vector{X: 5, Y: -2}, roveapi.Tile_Rock)
tile, _ = a.QueryPosition(maths.Vector{X: 5, Y: -2})
assert.Equal(t, roveapi.Tile_Rock, tile)
}
func TestAtlas_GetSetObject(t *testing.T) {
a := NewChunkAtlas(10)
assert.NotNil(t, a)
// Set the origin tile to 1 and test it
a.SetObject(maths.Vector{X: 0, Y: 0}, Object{Type: roveapi.Object_RockLarge})
_, obj := a.QueryPosition(maths.Vector{X: 0, Y: 0})
assert.Equal(t, Object{Type: roveapi.Object_RockLarge}, obj)
// Set another tile to 1 and test it
a.SetObject(maths.Vector{X: 5, Y: -2}, Object{Type: roveapi.Object_RockSmall})
_, obj = a.QueryPosition(maths.Vector{X: 5, Y: -2})
assert.Equal(t, Object{Type: roveapi.Object_RockSmall}, obj)
}
func TestAtlas_Grown(t *testing.T) {
// Start with a small example
a := NewChunkAtlas(2).(*chunkBasedAtlas)
assert.NotNil(t, a)
assert.Equal(t, 1, len(a.Chunks))
// Set a few tiles to values
a.SetTile(maths.Vector{X: 0, Y: 0}, roveapi.Tile_Gravel)
a.SetTile(maths.Vector{X: -1, Y: -1}, roveapi.Tile_Rock)
a.SetTile(maths.Vector{X: 1, Y: -2}, roveapi.Tile_Sand)
// Check tile values
tile, _ := a.QueryPosition(maths.Vector{X: 0, Y: 0})
assert.Equal(t, roveapi.Tile_Gravel, tile)
tile, _ = a.QueryPosition(maths.Vector{X: -1, Y: -1})
assert.Equal(t, roveapi.Tile_Rock, tile)
tile, _ = a.QueryPosition(maths.Vector{X: 1, Y: -2})
assert.Equal(t, roveapi.Tile_Sand, tile)
tile, _ = a.QueryPosition(maths.Vector{X: 0, Y: 0})
assert.Equal(t, roveapi.Tile_Gravel, tile)
tile, _ = a.QueryPosition(maths.Vector{X: -1, Y: -1})
assert.Equal(t, roveapi.Tile_Rock, tile)
tile, _ = a.QueryPosition(maths.Vector{X: 1, Y: -2})
assert.Equal(t, roveapi.Tile_Sand, tile)
}
func TestAtlas_GetSetCorrect(t *testing.T) {
// Big stress test to ensure we do actually properly expand for all reasonable values
for i := 1; i <= 4; i++ {
for x := -i * 2; x < i*2; x++ {
for y := -i * 2; y < i*2; y++ {
a := NewChunkAtlas(i).(*chunkBasedAtlas)
assert.NotNil(t, a)
assert.Equal(t, 1, len(a.Chunks))
pos := maths.Vector{X: x, Y: y}
a.SetTile(pos, roveapi.Tile_Rock)
a.SetObject(pos, Object{Type: roveapi.Object_RockLarge})
tile, obj := a.QueryPosition(pos)
assert.Equal(t, roveapi.Tile_Rock, roveapi.Tile(tile))
assert.Equal(t, Object{Type: roveapi.Object_RockLarge}, obj)
}
}
}
}
func TestAtlas_WorldGen(t *testing.T) {
a := NewChunkAtlas(8)
// Spawn a large world
_, _ = a.QueryPosition(maths.Vector{X: 20, Y: 20})
}