Mercurial > games > semicongine
view semiconginev2/old/mesh.nim @ 1218:56781cc0fc7c compiletime-tests
did: renamge main package
author | sam <sam@basx.dev> |
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date | Wed, 17 Jul 2024 21:01:37 +0700 |
parents | semicongine/old/mesh.nim@a3eb305bcac2 |
children |
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import std/hashes import std/options import std/typetraits import std/tables import std/strformat import std/enumerate import std/strutils import std/sequtils import ./core import ./collision import ./material const DEFAULT_POSITION_ATTRIBUTE = "position" var instanceCounter* = 0 type MeshIndexType* = enum None Tiny # up to 2^8 vertices # TODO: need to check and enable support for this Small # up to 2^16 vertices Big # up to 2^32 vertices MeshObject* = object name*: string vertexCount*: int case indexType*: MeshIndexType of None: discard of Tiny: tinyIndices*: seq[array[3, uint8]] of Small: smallIndices*: seq[array[3, uint16]] of Big: bigIndices*: seq[array[3, uint32]] material*: MaterialData transform*: Mat4 = Unit4 instanceTransforms*: seq[Mat4] applyMeshTransformToInstances*: bool = true # if true, the transform attribute for the shader will apply the instance transform AND the mesh transform, to each instance visible*: bool = true transformCache: seq[Mat4] vertexData: Table[string, DataList] instanceData: Table[string, DataList] dirtyAttributes: seq[string] Mesh* = ref MeshObject func Material*(mesh: MeshObject): MaterialData = mesh.material func `material=`*(mesh: var MeshObject, material: MaterialData) = for name, theType in material.theType.vertexAttributes: if mesh.vertexData.contains(name): assert mesh.vertexData[name].theType == theType, &"{material.theType} expected vertex attribute '{name}' to be '{theType}' but it is {mesh.vertexData[name].theType}" else: assert false, &"Mesh '{mesh.name}' is missing required vertex attribute '{name}: {theType}' for {material.theType}" for name, theType in material.theType.instanceAttributes: if name in [TRANSFORM_ATTRIB, MATERIALINDEX_ATTRIBUTE]: continue if mesh.instanceData.contains(name): assert mesh.instanceData[name].theType == theType, &"{material.theType} expected instance attribute '{name}' to be '{theType}' but it is {mesh.instanceData[name].theType}" else: assert false, &"Mesh '{mesh.name}' is missing required instance attribute '{name}: {theType}' for {material.theType}" mesh.material = material func InstanceCount*(mesh: MeshObject): int = mesh.instanceTransforms.len func IndicesCount*(mesh: MeshObject): int = ( case mesh.indexType of None: 0 of Tiny: mesh.tinyIndices.len of Small: mesh.smallIndices.len of Big: mesh.bigIndices.len ) * 3 func `$`*(mesh: MeshObject): string = if mesh.indexType == None: &"Mesh('{mesh.name}', vertexCount: {mesh.vertexCount}, instanceCount: {mesh.InstanceCount}, vertexData: {mesh.vertexData.keys().toSeq()}, instanceData: {mesh.instanceData.keys().toSeq()}, indexType: {mesh.indexType}, material: {mesh.material})" else: &"Mesh('{mesh.name}', vertexCount: {mesh.vertexCount}, indexCount: {mesh.IndicesCount}, instanceCount: {mesh.InstanceCount}, vertexData: {mesh.vertexData.keys().toSeq()}, instanceData: {mesh.instanceData.keys().toSeq()}, indexType: {mesh.indexType}, material: {mesh.material})" func `$`*(mesh: Mesh): string = $mesh[] func VertexAttributes*(mesh: MeshObject): seq[string] = mesh.vertexData.keys.toSeq func InstanceAttributes*(mesh: MeshObject): seq[string] = mesh.instanceData.keys.toSeq func Attributes*(mesh: MeshObject): seq[string] = mesh.VertexAttributes & mesh.InstanceAttributes func hash*(mesh: Mesh): Hash = hash(cast[ptr MeshObject](mesh)) converter ToVulkan*(indexType: MeshIndexType): VkIndexType = case indexType: of None: VK_INDEX_TYPE_NONE_KHR of Tiny: VK_INDEX_TYPE_UINT8_EXT of Small: VK_INDEX_TYPE_UINT16 of Big: VK_INDEX_TYPE_UINT32 proc InitVertexAttribute*[T](mesh: var MeshObject, attribute: string, value: seq[T]) = assert not mesh.vertexData.contains(attribute) and not mesh.instanceData.contains(attribute) mesh.vertexData[attribute] = InitDataList(thetype = GetDataType[T]()) mesh.vertexData[attribute].SetLen(mesh.vertexCount) mesh.vertexData[attribute] = value proc InitVertexAttribute*[T](mesh: var MeshObject, attribute: string, value: T) = InitVertexAttribute(mesh, attribute, newSeqWith(mesh.vertexCount, value)) proc InitVertexAttribute*[T](mesh: var MeshObject, attribute: string) = InitVertexAttribute(mesh = mesh, attribute = attribute, value = default(T)) proc InitVertexAttribute*(mesh: var MeshObject, attribute: string, datatype: DataType) = assert not mesh.vertexData.contains(attribute) and not mesh.instanceData.contains(attribute) mesh.vertexData[attribute] = InitDataList(thetype = datatype) mesh.vertexData[attribute].SetLen(mesh.vertexCount) proc InitVertexAttribute*(mesh: var MeshObject, attribute: string, data: DataList) = assert not mesh.vertexData.contains(attribute) and not mesh.instanceData.contains(attribute) mesh.vertexData[attribute] = data proc InitInstanceAttribute*[T](mesh: var MeshObject, attribute: string, value: seq[T]) = assert not mesh.vertexData.contains(attribute) and not mesh.instanceData.contains(attribute) mesh.instanceData[attribute] = InitDataList(thetype = GetDataType[T]()) mesh.instanceData[attribute].SetLen(mesh.InstanceCount) mesh.instanceData[attribute] = value proc InitInstanceAttribute*[T](mesh: var MeshObject, attribute: string, value: T) = InitInstanceAttribute(mesh, attribute, newSeqWith(mesh.InstanceCount, value)) proc InitInstanceAttribute*[T](mesh: var MeshObject, attribute: string) = InitInstanceAttribute(mesh = mesh, attribute = attribute, value = default(T)) proc InitInstanceAttribute*(mesh: var MeshObject, attribute: string, datatype: DataType) = assert not mesh.vertexData.contains(attribute) and not mesh.instanceData.contains(attribute) mesh.instanceData[attribute] = InitDataList(thetype = datatype) mesh.instanceData[attribute].SetLen(mesh.InstanceCount) proc InitInstanceAttribute*(mesh: var MeshObject, attribute: string, data: DataList) = assert not mesh.vertexData.contains(attribute) and not mesh.instanceData.contains(attribute) mesh.instanceData[attribute] = data proc NewMesh*( positions: openArray[Vec3f], indices: openArray[array[3, uint32|uint16|uint8]], colors: openArray[Vec4f] = [], uvs: openArray[Vec2f] = [], transform: Mat4 = Unit4, instanceTransforms: openArray[Mat4] = [Unit4], material = EMPTY_MATERIAL.InitMaterialData(), autoResize = true, name: string = "" ): Mesh = assert colors.len == 0 or colors.len == positions.len assert uvs.len == 0 or uvs.len == positions.len var theName = name if theName == "": theName = &"mesh-{instanceCounter}" inc instanceCounter # determine index type (uint8, uint16, uint32) var indexType = None if indices.len > 0: indexType = Big if autoResize and uint32(positions.len) < uint32(high(uint8)) and false: # TODO: check feature support indexType = Tiny elif autoResize and uint32(positions.len) < uint32(high(uint16)): indexType = Small result = Mesh( name: theName, indexType: indexType, vertexCount: positions.len, instanceTransforms: @instanceTransforms, transform: transform, ) result[].InitVertexAttribute(DEFAULT_POSITION_ATTRIBUTE, positions.toSeq) if colors.len > 0: result[].InitVertexAttribute("color", colors.toSeq) if uvs.len > 0: result[].InitVertexAttribute("uv", uvs.toSeq) # assert all indices are valid for i in indices: assert int(i[0]) < result[].vertexCount assert int(i[1]) < result[].vertexCount assert int(i[2]) < result[].vertexCount # cast index values to appropiate type if result[].indexType == Tiny and uint32(positions.len) < uint32(high(uint8)) and false: # TODO: check feature support for i, tri in enumerate(indices): result[].tinyIndices.add [uint8(tri[0]), uint8(tri[1]), uint8(tri[2])] elif result[].indexType == Small and uint32(positions.len) < uint32(high(uint16)): for i, tri in enumerate(indices): result[].smallIndices.add [uint16(tri[0]), uint16(tri[1]), uint16(tri[2])] elif result[].indexType == Big: for i, tri in enumerate(indices): result[].bigIndices.add [uint32(tri[0]), uint32(tri[1]), uint32(tri[2])] `material=`(result[], material) proc NewMesh*( positions: openArray[Vec3f], colors: openArray[Vec4f] = [], uvs: openArray[Vec2f] = [], transform: Mat4 = Unit4, instanceTransforms: openArray[Mat4] = [Unit4], material = EMPTY_MATERIAL.InitMaterialData(), name: string = "", ): Mesh = NewMesh( positions = positions, indices = newSeq[array[3, uint16]](), colors = colors, uvs = uvs, transform = transform, instanceTransforms = instanceTransforms, material = material, name = name, ) func AttributeSize*(mesh: MeshObject, attribute: string): uint64 = if mesh.vertexData.contains(attribute): mesh.vertexData[attribute].Size elif mesh.instanceData.contains(attribute): mesh.instanceData[attribute].Size else: 0 func AttributeType*(mesh: MeshObject, attribute: string): DataType = if mesh.vertexData.contains(attribute): mesh.vertexData[attribute].theType elif mesh.instanceData.contains(attribute): mesh.instanceData[attribute].theType else: raise newException(Exception, &"Attribute {attribute} is not defined for mesh {mesh}") func IndexSize*(mesh: MeshObject): uint64 = case mesh.indexType of None: 0'u64 of Tiny: uint64(mesh.tinyIndices.len * sizeof(get(genericParams(typeof(mesh.tinyIndices)), 0))) of Small: uint64(mesh.smallIndices.len * sizeof(get(genericParams(typeof(mesh.smallIndices)), 0))) of Big: uint64(mesh.bigIndices.len * sizeof(get(genericParams(typeof(mesh.bigIndices)), 0))) func rawData[T: seq](value: T): (pointer, uint64) = ( pointer(addr(value[0])), uint64(sizeof(get(genericParams(typeof(value)), 0)) * value.len) ) func GetRawIndexData*(mesh: MeshObject): (pointer, uint64) = case mesh.indexType: of None: raise newException(Exception, "Trying to get index data for non-indexed mesh") of Tiny: rawData(mesh.tinyIndices) of Small: rawData(mesh.smallIndices) of Big: rawData(mesh.bigIndices) func GetPointer*(mesh: var MeshObject, attribute: string): pointer = if mesh.vertexData.contains(attribute): mesh.vertexData[attribute].GetPointer() elif mesh.instanceData.contains(attribute): mesh.instanceData[attribute].GetPointer() else: raise newException(Exception, &"Attribute {attribute} is not defined for mesh {mesh}") proc GetAttribute[T: GPUType|int|uint|float](mesh: MeshObject, attribute: string): ref seq[T] = if mesh.vertexData.contains(attribute): mesh.vertexData[attribute][T] elif mesh.instanceData.contains(attribute): mesh.instanceData[attribute][T] else: raise newException(Exception, &"Attribute {attribute} is not defined for mesh {mesh}") proc GetAttribute[T: GPUType|int|uint|float](mesh: MeshObject, attribute: string, i: int): T = if mesh.vertexData.contains(attribute): mesh.vertexData[attribute][i, T] elif mesh.instanceData.contains(attribute): mesh.instanceData[attribute][i, T] else: raise newException(Exception, &"Attribute {attribute} is not defined for mesh {mesh}") template `[]`*(mesh: MeshObject, attribute: string, t: typedesc): ref seq[t] = GetAttribute[t](mesh, attribute) template `[]`*(mesh: MeshObject, attribute: string, i: int, t: typedesc): untyped = GetAttribute[t](mesh, attribute, i) template `[]=`*[T](mesh: MeshObject, attribute: string, value: seq[T]) = GetAttribute[t](mesh, attribute) template `[]=`*[T](mesh: MeshObject, attribute: string, i: int, value: T) = GetAttribute[t](mesh, attribute, i) template `[]`*(mesh: Mesh, attribute: string, t: typedesc): ref seq[t] = mesh[][attribute, t] template `[]`*(mesh: Mesh, attribute: string, i: int, t: typedesc): untyped = mesh[][attribute, i, t] proc UpdateAttributeData[T: GPUType|int|uint|float](mesh: var MeshObject, attribute: string, data: DataList) = if mesh.vertexData.contains(attribute): assert data.len == mesh.vertexCount assert data.theType == mesh.vertexData[attribute].theType mesh.vertexData[attribute] = data elif mesh.instanceData.contains(attribute): assert data.len == mesh.InstanceCount assert data.theType == mesh.instanceData[attribute].theType mesh.instanceData[attribute] = data else: raise newException(Exception, &"Attribute {attribute} is not defined for mesh {mesh}") if not mesh.dirtyAttributes.contains(attribute): mesh.dirtyAttributes.add attribute proc UpdateAttributeData[T: GPUType|int|uint|float](mesh: var MeshObject, attribute: string, data: seq[T]) = if mesh.vertexData.contains(attribute): assert data.len == mesh.vertexCount mesh.vertexData[attribute] = data elif mesh.instanceData.contains(attribute): assert data.len == mesh.InstanceCount mesh.instanceData[attribute] = data else: raise newException(Exception, &"Attribute {attribute} is not defined for mesh {mesh}") if not mesh.dirtyAttributes.contains(attribute): mesh.dirtyAttributes.add attribute proc UpdateAttributeData[T: GPUType|int|uint|float](mesh: var MeshObject, attribute: string, i: int, value: T) = if mesh.vertexData.contains(attribute): assert i < mesh.vertexData[attribute].len mesh.vertexData[attribute][i] = value elif mesh.instanceData.contains(attribute): assert i < mesh.instanceData[attribute].len mesh.instanceData[attribute][i] = value else: raise newException(Exception, &"Attribute {attribute} is not defined for mesh {mesh}") if not mesh.dirtyAttributes.contains(attribute): mesh.dirtyAttributes.add attribute proc `[]=`*[T: GPUType|int|uint|float](mesh: var MeshObject, attribute: string, data: DataList) = UpdateAttributeData[T](mesh, attribute, data) proc `[]=`*[T: GPUType|int|uint|float](mesh: Mesh, attribute: string, data: DataList) = UpdateAttributeData[t](mesh[], attribute, data) proc `[]=`*[T: GPUType|int|uint|float](mesh: var MeshObject, attribute: string, data: seq[T]) = UpdateAttributeData[T](mesh, attribute, data) proc `[]=`*[T: GPUType|int|uint|float](mesh: Mesh, attribute: string, data: seq[T]) = UpdateAttributeData[T](mesh[], attribute, data) proc `[]=`*[T: GPUType|int|uint|float](mesh: var MeshObject, attribute: string, value: T) = UpdateAttributeData[T](mesh, attribute, newSeqWith(mesh.vertexCount, value)) proc `[]=`*[T: GPUType|int|uint|float](mesh: Mesh, attribute: string, value: T) = UpdateAttributeData[T](mesh[], attribute, newSeqWith(mesh.vertexCount, value)) proc `[]=`*[T: GPUType|int|uint|float](mesh: var MeshObject, attribute: string, i: int, value: T) = UpdateAttributeData[T](mesh, attribute, i, value) proc `[]=`*[T: GPUType|int|uint|float](mesh: Mesh, attribute: string, i: int, value: T) = UpdateAttributeData[T](mesh[], attribute, i, value) proc RemoveAttribute*(mesh: var MeshObject, attribute: string) = if mesh.vertexData.contains(attribute): mesh.vertexData.del(attribute) elif mesh.instanceData.contains(attribute): mesh.instanceData.del(attribute) else: raise newException(Exception, &"Attribute {attribute} is not defined for mesh {mesh}") proc AppendIndicesData*(mesh: var MeshObject, v1, v2, v3: int) = case mesh.indexType of None: raise newException(Exception, "Mesh does not support indexed data") of Tiny: mesh.tinyIndices.add([uint8(v1), uint8(v2), uint8(v3)]) of Small: mesh.smallIndices.add([uint16(v1), uint16(v2), uint16(v3)]) of Big: mesh.bigIndices.add([uint32(v1), uint32(v2), uint32(v3)]) proc UpdateInstanceTransforms*(mesh: var MeshObject, attribute: string) = var currentTransforms: seq[Mat4] if mesh.applyMeshTransformToInstances: currentTransforms = mesh.instanceTransforms.mapIt(mesh.transform * it) else: currentTransforms = mesh.instanceTransforms if currentTransforms != mesh.transformCache: mesh[attribute] = currentTransforms mesh.transformCache = currentTransforms proc RenameAttribute*(mesh: var MeshObject, oldname, newname: string) = if mesh.vertexData.contains(oldname): mesh.vertexData[newname] = mesh.vertexData[oldname] mesh.vertexData.del oldname elif mesh.instanceData.contains(oldname): mesh.instanceData[newname] = mesh.vertexData[oldname] mesh.instanceData.del oldname else: raise newException(Exception, &"Attribute {oldname} is not defined for mesh {mesh}") func DirtyAttributes*(mesh: MeshObject): seq[string] = mesh.dirtyAttributes proc ClearDirtyAttributes*(mesh: var MeshObject) = mesh.dirtyAttributes.reset proc SetShaderMaterialIndices*(mesh: var MeshObject, shadername: string, values: seq[uint16], attributeName = MATERIALINDEX_ATTRIBUTE) = let indexAttribute = shadername & "_" & attributeName assert values.len == mesh.InstanceCount, &"Mesh {mesh}: While trying to set shader material indices for shader '{shadername}': indices have len {values.len}, but instance count is {mesh.InstanceCount}" mesh[indexAttribute] = values # MESH-TOOLS proc Transform*[T: GPUType](mesh: var MeshObject, attribute: string, transform: Mat4) = if mesh.vertexData.contains(attribute): for i in 0 ..< mesh.vertexData[attribute].len: mesh.vertexData[attribute][i] = transform * mesh.vertexData[attribute][i, T] elif mesh.instanceData.contains(attribute): for i in 0 ..< mesh.instanceData[attribute].len: mesh.instanceData[attribute][i] = transform * mesh.vertexData[attribute][i, T] else: raise newException(Exception, &"Attribute {attribute} is not defined for mesh {mesh}") mesh.dirtyAttributes.add attribute func GetMeshPoints*(mesh: MeshObject, positionAttribute = DEFAULT_POSITION_ATTRIBUTE): seq[Vec3f] = for p in mesh[positionAttribute, Vec3f][]: result.add mesh.transform * p func GetCollider*(mesh: MeshObject, positionAttribute = DEFAULT_POSITION_ATTRIBUTE): Collider = return mesh.GetMeshPoints(positionAttribute).CalculateCollider(Points) proc AsNonIndexedMesh*(mesh: MeshObject): MeshObject = if mesh.indexType == None: return mesh result = MeshObject( vertexCount: mesh.IndicesCount, indexType: None, transform: mesh.transform, instanceTransforms: mesh.instanceTransforms, visible: mesh.visible, ) for attribute, datalist in mesh.vertexData.pairs: result.InitVertexAttribute(attribute, datalist.theType) for attribute, datalist in mesh.instanceData.pairs: result.instanceData[attribute] = datalist.Copy() var i = 0 case mesh.indexType of Tiny: for indices in mesh.tinyIndices: for attribute, value in mesh.vertexData.pairs: result.vertexData[attribute].AppendFrom(i, mesh.vertexData[attribute], int(indices[0])) result.vertexData[attribute].AppendFrom(i + 1, mesh.vertexData[attribute], int(indices[1])) result.vertexData[attribute].AppendFrom(i + 2, mesh.vertexData[attribute], int(indices[2])) i += 3 of Small: for indices in mesh.smallIndices: for attribute, value in mesh.vertexData.pairs: result.vertexData[attribute].AppendFrom(i, value, int(indices[0])) result.vertexData[attribute].AppendFrom(i + 1, value, int(indices[1])) result.vertexData[attribute].AppendFrom(i + 2, value, int(indices[2])) i += 3 of Big: for indices in mesh.bigIndices: for attribute, value in mesh.vertexData.pairs: result.vertexData[attribute].AppendFrom(i, mesh.vertexData[attribute], int(indices[0])) result.vertexData[attribute].AppendFrom(i + 1, mesh.vertexData[attribute], int(indices[1])) result.vertexData[attribute].AppendFrom(i + 2, mesh.vertexData[attribute], int(indices[2])) i += 3 else: discard `material=`(result, mesh.material) # GENERATORS ============================================================================ proc Rect*(width = 1'f32, height = 1'f32, color = "ffffffff", material = EMPTY_MATERIAL.InitMaterialData()): Mesh = result = Mesh( vertexCount: 4, instanceTransforms: @[Unit4], indexType: Small, smallIndices: @[[0'u16, 1'u16, 2'u16], [2'u16, 3'u16, 0'u16]], name: &"rect-{instanceCounter}", ) inc instanceCounter let half_w = width / 2 half_h = height / 2 pos = @[NewVec3f(-half_w, -half_h), NewVec3f(half_w, -half_h), NewVec3f(half_w, half_h), NewVec3f(-half_w, half_h)] c = ToRGBA(color) result[].InitVertexAttribute(DEFAULT_POSITION_ATTRIBUTE, pos) result[].InitVertexAttribute("color", @[c, c, c, c]) result[].InitVertexAttribute("uv", @[NewVec2f(0, 0), NewVec2f(1, 0), NewVec2f(1, 1), NewVec2f(0, 1)]) `material=`(result[], material) proc Tri*(width = 1'f32, height = 1'f32, color = "ffffffff", material = EMPTY_MATERIAL.InitMaterialData()): Mesh = result = Mesh( vertexCount: 3, instanceTransforms: @[Unit4], name: &"tri-{instanceCounter}", ) inc instanceCounter let half_w = width / 2 half_h = height / 2 colorVec = ToRGBA(color) result[].InitVertexAttribute(DEFAULT_POSITION_ATTRIBUTE, @[NewVec3f(0, -half_h), NewVec3f(half_w, half_h), NewVec3f(-half_w, half_h)]) result[].InitVertexAttribute("color", @[colorVec, colorVec, colorVec]) `material=`(result[], material) proc CircleMesh*(nSegments: int): (seq[Vec3f], seq[array[3, uint16]]) = let rX = 0.5 rY = 0.5 step = (2'f32 * PI) / float32(nSegments) result[0] = @[NewVec3f(0, 0), NewVec3f(rX, 0)] for i in 1 .. nSegments: result[0].add NewVec3f(cos(float32(i) * step) * rX, sin(float32(i) * step) * rY) result[1].add [uint16(0), uint16(i), uint16(i + 1)] proc Circle*(width = 1'f32, height = 1'f32, nSegments = 12, color = "ffffffff", material = EMPTY_MATERIAL.InitMaterialData()): Mesh = assert nSegments >= 3 result = Mesh( vertexCount: 3 + nSegments, instanceTransforms: @[Unit4], indexType: Small, name: &"circle-{instanceCounter}", ) inc instanceCounter let rX = width / 2 rY = height / 2 c = ToRGBA(color) step = (2'f32 * PI) / float32(nSegments) var pos = @[NewVec3f(0, 0), NewVec3f(rX, 0)] col = @[c, c] uv = @[NewVec2f(0.5, 0.5), NewVec2f(rX, height / 2)] for i in 1 .. nSegments: pos.add NewVec3f(cos(float32(i) * step) * rX, sin(float32(i) * step) * rY) col.add c uv.add NewVec2f(cos(float32(i) * step) * 0.5 + 0.5, sin(float32(i) * step) * 0.5 + 0.5) result[].smallIndices.add [uint16(0), uint16(i), uint16(i + 1)] result[].InitVertexAttribute(DEFAULT_POSITION_ATTRIBUTE, pos) result[].InitVertexAttribute("color", col) result[].InitVertexAttribute("uv", uv) `material=`(result[], material) proc CircleMesh*(width = 1'f32, height = 1'f32, nSegments = 12): (seq[Vec3f], seq[array[3, uint16]]) = assert nSegments >= 3 result[0] = newSeq[Vec3f](3 + nSegments) let rX = width / 2 rY = height / 2 step = (2'f32 * PI) / float32(nSegments) result[0][0] = NewVec3f(0, 0) result[0][1] = NewVec3f(rX, 0) for i in 1 .. nSegments: result[0][i + 1] = NewVec3f(cos(float32(i) * step) * rX, sin(float32(i) * step) * rY) result[1].add [uint16(0), uint16(i), uint16(i + 1)] proc Grid*(columns, rows: uint16, cellSize = 1.0'f32, color = "ffffffff", material = EMPTY_MATERIAL.InitMaterialData()): Mesh = result = Mesh( vertexCount: int((rows + 1) * (columns + 1)), instanceTransforms: @[Unit4], indexType: Small, name: &"grid-{instanceCounter}", ) inc instanceCounter let color = ToRGBA(color) center_offset_x = -(float32(columns) * cellSize) / 2'f32 center_offset_y = -(float32(rows) * cellSize) / 2'f32 var pos: seq[Vec3f] col: seq[Vec4f] i = 0'u16 for h in 0'u16 .. rows: for w in 0'u16 .. columns: pos.add NewVec3f(center_offset_x + float32(w) * cellSize, center_offset_y + float32(h) * cellSize) col.add color if w > 0 and h > 0: result[].smallIndices.add [i, i - 1, i - rows - 2] result[].smallIndices.add [i, i - rows - 2, i - rows - 1] i.inc result[].InitVertexAttribute(DEFAULT_POSITION_ATTRIBUTE, pos) result[].InitVertexAttribute("color", col) `material=`(result[], material) proc MergeMeshData*(a: var Mesh, b: Mesh) = let originalOffset = a.vertexCount a.vertexCount = a.vertexCount + b.vertexCount assert a.indexType == b.indexType for key in a.vertexData.keys: assert key in b.vertexData, &"Mesh {b} is missing vertex data for '{key}'" for (key, value) in b.vertexData.pairs: a.vertexData[key].AppendValues(value) case a.indexType: of None: discard of Tiny: let offset = uint8(originalOffset) for i in b.tinyIndices: a.tinyIndices.add [i[0] + offset, i[1] + offset, i[2] + offset] of Small: let offset = uint16(originalOffset) for i in b.smallIndices: a.smallIndices.add [i[0] + offset, i[1] + offset, i[2] + offset] of Big: let offset = uint32(originalOffset) for i in b.bigIndices: a.bigIndices.add [i[0] + offset, i[1] + offset, i[2] + offset] # MESH TREES ============================================================================= type MeshTree* = ref object mesh*: Mesh transform*: Mat4 = Unit4 children*: seq[MeshTree] func toStringRec*(tree: MeshTree, theindent = 0): seq[string] = if tree.mesh.isNil: result.add "*" else: result.add indent($tree.mesh, theindent) for child in tree.children: result.add child.toStringRec(theindent + 4) func `$`*(tree: MeshTree): string = toStringRec(tree).join("\n") proc toSeq*(tree: MeshTree): seq[Mesh] = var queue = @[tree] while queue.len > 0: var current = queue.pop if not current.mesh.isNil: result.add current.mesh queue.add current.children proc updateTransforms*(tree: MeshTree, parentTransform = Unit4) = let currentTransform = parentTransform * tree.transform if not tree.mesh.isNil: tree.mesh.transform = currentTransform for child in tree.children: child.updateTransforms(currentTransform)