/// <summary> /// Finalizes the initialization. /// </summary> protected override void FinalizeInitialization() { //shrink the array var tmp = new RichCell.HeightData[_recordedEntries]; Array.Copy(_heightData, tmp, _recordedEntries); _heightData = tmp; }
private int SetData(RichCell c, int selfIdx, int neighbourIdx, int dataIdx, bool dataRecorded) { RichCell.HeightData data; if (dataRecorded) { data = _heightData[dataIdx++]; } else { data = new RichCell.HeightData(); } c.SetHeightData(selfIdx, data); var n = GetNeighbourFromIdx(c, selfIdx); if (n != null) { //Neighbour values are reversed var neighbourData = new RichCell.HeightData { climbHeight = data.dropHeight, dropHeight = data.climbHeight, slope = data.slope }; n.SetHeightData(neighbourIdx, neighbourData); } return(dataIdx); }
protected override void FinalizeInitialization() { //shrink the array var tmp = new RichCell.HeightData[_recordedEntries]; Array.Copy(_heightData, tmp, _recordedEntries); _heightData = tmp; }
private void UpdateCellHeightData(RichCell reference, RichCell neighbour, float ledgeThreshold, int dx, int dz) { GetPerpendicularOffsets(dx, dz); var granularity = _matrix.granularity; var steps = _matrix.cellSize / granularity; var data = new RichCell.HeightData(); for (int o = 0; o < 3; o++) { var samplePos = reference.position + _offsets[o]; var fromHeight = _heightSampler.SampleHeight(samplePos, _matrix); var climbAccumulator = 0.0f; var dropAccumulator = 0.0f; for (int i = 0; i < steps; i++) { samplePos.x += (dx * granularity); samplePos.z += (dz * granularity); var toHeight = _heightSampler.SampleHeight(samplePos, _matrix); var heightDiff = toHeight - fromHeight; var absDiff = Mathf.Abs(heightDiff); //Initially we just record the slope as the height diff if (data.slope < absDiff) { data.slope = absDiff; } if (absDiff < ledgeThreshold) { if (data.dropHeight < dropAccumulator) { data.dropHeight = dropAccumulator; } else if (data.climbHeight < climbAccumulator) { data.climbHeight = climbAccumulator; } dropAccumulator = 0f; climbAccumulator = 0f; } if (heightDiff > 0f) { climbAccumulator += heightDiff; if (data.dropHeight < dropAccumulator) { data.dropHeight = dropAccumulator; } dropAccumulator = 0f; } else if (heightDiff < 0f) { dropAccumulator += absDiff; if (data.climbHeight < climbAccumulator) { data.climbHeight = climbAccumulator; } climbAccumulator = 0f; } fromHeight = toHeight; } //Make sure we get the last accumulation recorded if (data.dropHeight < dropAccumulator) { data.dropHeight = dropAccumulator; } else if (data.climbHeight < climbAccumulator) { data.climbHeight = climbAccumulator; } } /* end for each offset */ //Set the slope to an angular value var mod = (dx != 0 && dz != 0) ? Consts.SquareRootTwo : 1f; data.slope = Mathf.Atan(data.slope / (granularity * mod)) * Mathf.Rad2Deg; //Set the data reference.SetHeightData(dx, dz, data); reference.CalculateWorst(); //Create the neighbour data as the reverse of this, i.e. drop = climb and vice versa var neighbourData = new RichCell.HeightData(data.slope, data.dropHeight, data.climbHeight); neighbour.SetHeightData(-dx, -dz, neighbourData); neighbour.CalculateWorst(); }
private int SetData(RichCell c, int selfIdx, int neighbourIdx, int dataIdx, bool dataRecorded) { RichCell.HeightData data; if (dataRecorded) { data = _heightData[dataIdx++]; } else { data = new RichCell.HeightData(); } c.SetHeightData(selfIdx, data); var n = GetNeighbourFromIdx(c, selfIdx); if (n != null) { //Neighbour values are reversed var neighbourData = new RichCell.HeightData { climbHeight = data.dropHeight, dropHeight = data.climbHeight, slope = data.slope }; n.SetHeightData(neighbourIdx, neighbourData); } return dataIdx; }
private void UpdateCellHeightData(RichCell reference, RichCell neighbour, float ledgeThreshold, int dx, int dz) { var heightSampler = GetHeightSampler(); var offsets = GetPerpendicularOffsets(dx, dz); var granularity = _matrix.granularity; var steps = _matrix.cellSize / granularity; var data = new RichCell.HeightData(); for (int o = 0; o < 3; o++) { var samplePos = reference.position + offsets[o]; var fromHeight = heightSampler.SampleHeight(samplePos, _matrix); var climbAccumulator = 0.0f; var dropAccumulator = 0.0f; for (int i = 0; i < steps; i++) { samplePos.x += (dx * granularity); samplePos.z += (dz * granularity); var toHeight = heightSampler.SampleHeight(samplePos, _matrix); var heightDiff = toHeight - fromHeight; var absDiff = Mathf.Abs(heightDiff); //Initially we just record the slope as the height diff if (data.slope < absDiff) { data.slope = absDiff; } if (absDiff < ledgeThreshold) { if (data.dropHeight < dropAccumulator) { data.dropHeight = dropAccumulator; } else if (data.climbHeight < climbAccumulator) { data.climbHeight = climbAccumulator; } dropAccumulator = 0f; climbAccumulator = 0f; } if (heightDiff > 0f) { climbAccumulator += heightDiff; if (data.dropHeight < dropAccumulator) { data.dropHeight = dropAccumulator; } dropAccumulator = 0f; } else if (heightDiff < 0f) { dropAccumulator += absDiff; if (data.climbHeight < climbAccumulator) { data.climbHeight = climbAccumulator; } climbAccumulator = 0f; } fromHeight = toHeight; } //Make sure we get the last accumulation recorded if (data.dropHeight < dropAccumulator) { data.dropHeight = dropAccumulator; } else if (data.climbHeight < climbAccumulator) { data.climbHeight = climbAccumulator; } } /* end for each offset */ //Set the slope to an angular value var mod = (dx != 0 && dz != 0) ? Consts.SquareRootTwo : 1f; data.slope = Mathf.Atan(data.slope / (granularity * mod)) * Mathf.Rad2Deg; //Set the data reference.SetHeightData(dx, dz, data); reference.CalculateWorst(); //Create the neighbour data as the reverse of this, i.e. drop = climb and vice versa var neighbourData = new RichCell.HeightData(data.slope, data.dropHeight, data.climbHeight); neighbour.SetHeightData(-dx, -dz, neighbourData); neighbour.CalculateWorst(); }