//
// The greedy strategy for combining samples is optimal.
template<class DestFloat>
-unsigned combine_many_samples(const Tap<float> *weights, unsigned src_size, unsigned src_samples, unsigned dst_samples, unique_ptr<Tap<DestFloat>[]> *bilinear_weights)
+unsigned combine_many_samples(const Tap<float> *weights, unsigned src_size, unsigned src_samples, unsigned dst_samples, Tap<DestFloat> **bilinear_weights)
{
float num_subtexels = src_size / movit_texel_subpixel_precision;
float inv_num_subtexels = movit_texel_subpixel_precision / src_size;
// Now that we know the right width, actually combine the samples.
unsigned src_bilinear_samples = src_samples - max_samples_saved;
- bilinear_weights->reset(new Tap<DestFloat>[dst_samples * src_bilinear_samples]);
+ if (*bilinear_weights != NULL) delete[] *bilinear_weights;
+ *bilinear_weights = new Tap<DestFloat>[dst_samples * src_bilinear_samples];
for (unsigned y = 0; y < dst_samples; ++y) {
- Tap<DestFloat> *bilinear_weights_ptr = bilinear_weights->get() + y * src_bilinear_samples;
+ Tap<DestFloat> *bilinear_weights_ptr = *bilinear_weights + y * src_bilinear_samples;
unsigned num_samples_saved = combine_samples(
weights + y * src_samples,
bilinear_weights_ptr,
GLenum type, internal_format;
void *pixels;
- assert((weights.bilinear_weights_fp16 == nullptr) != (weights.bilinear_weights_fp32 == nullptr));
- if (weights.bilinear_weights_fp32 != nullptr) {
+ assert((weights.bilinear_weights_fp16 == NULL) != (weights.bilinear_weights_fp32 == NULL));
+ if (weights.bilinear_weights_fp32 != NULL) {
type = GL_FLOAT;
internal_format = GL_RG32F;
- pixels = weights.bilinear_weights_fp32.get();
+ pixels = weights.bilinear_weights_fp32;
} else {
type = GL_HALF_FLOAT;
internal_format = GL_RG16F;
- pixels = weights.bilinear_weights_fp16.get();
+ pixels = weights.bilinear_weights_fp16;
}
if (int(weights.src_bilinear_samples) == last_texture_width &&
last_texture_internal_format = internal_format;
}
check_error();
+
+ delete[] weights.bilinear_weights_fp16;
+ delete[] weights.bilinear_weights_fp32;
}
ScalingWeights calculate_scaling_weights(unsigned src_size, unsigned dst_size, float zoom, float offset)
float radius_scaling_factor = min(scaling_factor, 1.0f);
int int_radius = lrintf(LANCZOS_RADIUS / radius_scaling_factor);
int src_samples = int_radius * 2 + 1;
- unique_ptr<Tap<float>[]> weights(new Tap<float>[dst_samples * src_samples]);
+ Tap<float> *weights = new Tap<float>[dst_samples * src_samples];
float subpixel_offset = offset - lrintf(offset); // The part not covered by whole_pixel_offset.
assert(subpixel_offset >= -0.5f && subpixel_offset <= 0.5f);
for (unsigned y = 0; y < dst_samples; ++y) {
// Our tolerance level for total error is a bit higher than the one for invididual
// samples, since one would assume overall errors in the shape don't matter as much.
const float max_error = 2.0f / (255.0f * 255.0f);
- unique_ptr<Tap<fp16_int_t>[]> bilinear_weights_fp16;
- int src_bilinear_samples = combine_many_samples(weights.get(), src_size, src_samples, dst_samples, &bilinear_weights_fp16);
- unique_ptr<Tap<float>[]> bilinear_weights_fp32 = NULL;
+ Tap<fp16_int_t> *bilinear_weights_fp16 = NULL;
+ int src_bilinear_samples = combine_many_samples(weights, src_size, src_samples, dst_samples, &bilinear_weights_fp16);
+ Tap<float> *bilinear_weights_fp32 = NULL;
double max_sum_sq_error_fp16 = 0.0;
for (unsigned y = 0; y < dst_samples; ++y) {
double sum_sq_error_fp16 = compute_sum_sq_error(
- weights.get() + y * src_samples, src_samples,
- bilinear_weights_fp16.get() + y * src_bilinear_samples, src_bilinear_samples,
+ weights + y * src_samples, src_samples,
+ bilinear_weights_fp16 + y * src_bilinear_samples, src_bilinear_samples,
src_size);
max_sum_sq_error_fp16 = std::max(max_sum_sq_error_fp16, sum_sq_error_fp16);
if (max_sum_sq_error_fp16 > max_error) {
}
if (max_sum_sq_error_fp16 > max_error) {
- bilinear_weights_fp16.reset();
- src_bilinear_samples = combine_many_samples(weights.get(), src_size, src_samples, dst_samples, &bilinear_weights_fp32);
+ delete[] bilinear_weights_fp16;
+ bilinear_weights_fp16 = NULL;
+ src_bilinear_samples = combine_many_samples(weights, src_size, src_samples, dst_samples, &bilinear_weights_fp32);
}
+ delete[] weights;
+
ScalingWeights ret;
ret.src_bilinear_samples = src_bilinear_samples;
ret.dst_samples = dst_samples;
ret.num_loops = num_loops;
- ret.bilinear_weights_fp16 = move(bilinear_weights_fp16);
- ret.bilinear_weights_fp32 = move(bilinear_weights_fp32);
+ ret.bilinear_weights_fp16 = bilinear_weights_fp16;
+ ret.bilinear_weights_fp32 = bilinear_weights_fp32;
return ret;
}