UpsilonNumworks/Upsilon
1
0
Fork 0
mirror of https://github.com/UpsilonNumworks/Upsilon.git synced 2026-01-19 00:37:25 +01:00
Code Issues Packages Projects Releases Wiki Activity
Files
c4cd3ecffaaff9f04a33b00e14952562222b6c74
Upsilon/apps/shared/interactive_curve_view_range.cpp
Gabriel Ozouf c4cd3ecffa [poincare/zoom] Factor range sanitation 
Checking wether the range that has been computed is suitable is now
done in Poincare::Zoom by SanitizeRange.

Change-Id: Ib7ff73a3beae29996b1a773744021ad85c6ba946
2020-11-04 15:58:22 +01:00

205 lines
8.5 KiB
C++
Raw Blame History

#include "interactive_curve_view_range.h"
#include <ion.h>
#include <cmath>
#include <stddef.h>
#include <assert.h>
#include <poincare/preferences.h>
#include <poincare/zoom.h>
#include <algorithm>
using namespace Poincare;
namespace Shared {
uint32_t InteractiveCurveViewRange::rangeChecksum() {
float data[] = {xMin(), xMax(), yMin(), yMax()};
size_t dataLengthInBytes = sizeof(data);
assert((dataLengthInBytes & 0x3) == 0); // Assert that dataLengthInBytes is a multiple of 4
return Ion::crc32Word((uint32_t *)data, dataLengthInBytes/sizeof(uint32_t));
}
void InteractiveCurveViewRange::setXMin(float xMin) {
MemoizedCurveViewRange::protectedSetXMin(xMin, k_lowerMaxFloat, k_upperMaxFloat);
}
void InteractiveCurveViewRange::setXMax(float xMax) {
MemoizedCurveViewRange::protectedSetXMax(xMax, k_lowerMaxFloat, k_upperMaxFloat);
}
void InteractiveCurveViewRange::setYMin(float yMin) {
MemoizedCurveViewRange::protectedSetYMin(yMin, k_lowerMaxFloat, k_upperMaxFloat);
}
void InteractiveCurveViewRange::setYMax(float yMax) {
MemoizedCurveViewRange::protectedSetYMax(yMax, k_lowerMaxFloat, k_upperMaxFloat);
}
float InteractiveCurveViewRange::yGridUnit() const {
float res = MemoizedCurveViewRange::yGridUnit();
if (m_zoomNormalize) {
/* When m_zoomNormalize is active, both xGridUnit and yGridUnit will be the
* same. To declutter the X axis, we try a unit twice as large. We check
* that it allows enough graduations on the Y axis, but if the standard
* unit would lead to too many graduations on the X axis, we force the
* larger unit anyways. */
float numberOfUnits = (yMax() - yMin()) / res;
if (numberOfUnits > k_maxNumberOfXGridUnits || numberOfUnits / 2.f > k_minNumberOfYGridUnits) {
return 2 * res;
}
}
return res;
}
void InteractiveCurveViewRange::zoom(float ratio, float x, float y) {
float xMi = xMin();
float xMa = xMax();
float yMi = yMin();
float yMa = yMax();
m_zoomAuto = false;
if (ratio*std::fabs(xMa-xMi) < Range1D::k_minFloat || ratio*std::fabs(yMa-yMi) < Range1D::k_minFloat) {
return;
}
float centerX = std::isnan(x) || std::isinf(x) ? xCenter() : x;
float centerY = std::isnan(y) || std::isinf(y) ? yCenter() : y;
float newXMin = centerX*(1.0f-ratio)+ratio*xMi;
float newXMax = centerX*(1.0f-ratio)+ratio*xMa;
if (!std::isnan(newXMin) && !std::isnan(newXMax)) {
m_xRange.setMax(newXMax, k_lowerMaxFloat, k_upperMaxFloat);
MemoizedCurveViewRange::protectedSetXMin(newXMin, k_lowerMaxFloat, k_upperMaxFloat);
}
float newYMin = centerY*(1.0f-ratio)+ratio*yMi;
float newYMax = centerY*(1.0f-ratio)+ratio*yMa;
if (!std::isnan(newYMin) && !std::isnan(newYMax)) {
m_yRange.setMax(newYMax, k_lowerMaxFloat, k_upperMaxFloat);
MemoizedCurveViewRange::protectedSetYMin(newYMin, k_lowerMaxFloat, k_upperMaxFloat);
}
}
void InteractiveCurveViewRange::panWithVector(float x, float y) {
if (clipped(xMin() + x, false) != xMin() + x || clipped(xMax() + x, true) != xMax() + x || clipped(yMin() + y, false) != yMin() + y || clipped(yMax() + y, true) != yMax() + y || std::isnan(clipped(xMin() + x, false)) || std::isnan(clipped(xMax() + x, true)) || std::isnan(clipped(yMin() + y, false)) || std::isnan(clipped(yMax() + y, true))) {
return;
}
m_xRange.setMax(xMax()+x, k_lowerMaxFloat, k_upperMaxFloat);
MemoizedCurveViewRange::protectedSetXMin(xMin() + x, k_lowerMaxFloat, k_upperMaxFloat);
m_yRange.setMax(yMax()+y, k_lowerMaxFloat, k_upperMaxFloat);
MemoizedCurveViewRange::protectedSetYMin(yMin() + y, k_lowerMaxFloat, k_upperMaxFloat);
}
void InteractiveCurveViewRange::normalize() {
/* We center the ranges on the current range center, and put each axis so that
* 1cm = 2 current units. */
float newXMin = xMin(), newXMax = xMax(), newYMin = yMin(), newYMax = yMax();
const float unit = std::max(xGridUnit(), yGridUnit());
const float newXHalfRange = NormalizedXHalfRange(unit);
const float newYHalfRange = NormalizedYHalfRange(unit);
float normalizedYXRatio = newYHalfRange/newXHalfRange;
Zoom::SetToRatio(normalizedYXRatio, &newXMin, &newXMax, &newYMin, &newYMax);
m_xRange.setMin(newXMin, k_lowerMaxFloat, k_upperMaxFloat);
MemoizedCurveViewRange::protectedSetXMax(newXMax, k_lowerMaxFloat, k_upperMaxFloat);
m_yRange.setMin(newYMin, k_lowerMaxFloat, k_upperMaxFloat);
MemoizedCurveViewRange::protectedSetYMax(newYMax, k_lowerMaxFloat, k_upperMaxFloat);
assert(isOrthonormal());
setZoomNormalize(true);
}
void InteractiveCurveViewRange::setDefault() {
if (m_delegate == nullptr) {
return;
}
/* If m_zoomNormalize was left active, xGridUnit() would return the value of
* yGridUnit, even if the ranger were not truly normalized. */
m_zoomNormalize = false;
// Compute the interesting range
m_delegate->interestingRanges(this);
bool revertToNormalized = isOrthonormal(k_orthonormalTolerance);
// Add margins
float xRange = xMax() - xMin();
float yRange = yMax() - yMin();
m_xRange.setMin(m_delegate->addMargin(xMin(), xRange, false, true), k_lowerMaxFloat, k_upperMaxFloat);
// Use MemoizedCurveViewRange::protectedSetXMax to update xGridUnit
MemoizedCurveViewRange::protectedSetXMax(m_delegate->addMargin(xMax(), xRange, false, false), k_lowerMaxFloat, k_upperMaxFloat);
m_yRange.setMin(m_delegate->addMargin(yMin(), yRange, true, true), k_lowerMaxFloat, k_upperMaxFloat);
MemoizedCurveViewRange::protectedSetYMax(m_delegate->addMargin(yMax(), yRange, true, false), k_lowerMaxFloat, k_upperMaxFloat);
if (m_delegate->defaultRangeIsNormalized() || revertToNormalized) {
// Normalize the axes, so that a polar circle is displayed as a circle
normalize();
}
setZoomAuto(true);
}
void InteractiveCurveViewRange::centerAxisAround(Axis axis, float position) {
if (std::isnan(position)) {
return;
}
if (axis == Axis::X) {
float range = xMax() - xMin();
if (std::fabs(position/range) > k_maxRatioPositionRange) {
range = Range1D::defaultRangeLengthFor(position);
}
m_xRange.setMax(position + range/2.0f, k_lowerMaxFloat, k_upperMaxFloat);
MemoizedCurveViewRange::protectedSetXMin(position - range/2.0f, k_lowerMaxFloat, k_upperMaxFloat);
} else {
float range = yMax() - yMin();
if (std::fabs(position/range) > k_maxRatioPositionRange) {
range = Range1D::defaultRangeLengthFor(position);
}
m_yRange.setMax(position + range/2.0f, k_lowerMaxFloat, k_upperMaxFloat);
MemoizedCurveViewRange::protectedSetYMin(position - range/2.0f, k_lowerMaxFloat, k_upperMaxFloat);
}
}
void InteractiveCurveViewRange::panToMakePointVisible(float x, float y, float topMarginRatio, float rightMarginRatio, float bottomMarginRatio, float leftMarginRatio, float pixelWidth) {
if (!std::isinf(x) && !std::isnan(x)) {
const float xRange = xMax() - xMin();
const float leftMargin = leftMarginRatio * xRange;
if (x < xMin() + leftMargin) {
m_zoomAuto = false;
/* The panning increment is a whole number of pixels so that the caching
* for cartesian functions is not invalidated. */
const float newXMin = std::floor((x - leftMargin - xMin()) / pixelWidth) * pixelWidth + xMin();
m_xRange.setMax(newXMin + xRange, k_lowerMaxFloat, k_upperMaxFloat);
MemoizedCurveViewRange::protectedSetXMin(newXMin, k_lowerMaxFloat, k_upperMaxFloat);
}
const float rightMargin = rightMarginRatio * xRange;
if (x > xMax() - rightMargin) {
m_zoomAuto = false;
const float newXMax = std::ceil((x + rightMargin - xMax()) / pixelWidth) * pixelWidth + xMax();
m_xRange.setMax(newXMax, k_lowerMaxFloat, k_upperMaxFloat);
MemoizedCurveViewRange::protectedSetXMin(xMax() - xRange, k_lowerMaxFloat, k_upperMaxFloat);
}
}
if (!std::isinf(y) && !std::isnan(y)) {
const float yRange = yMax() - yMin();
const float bottomMargin = bottomMarginRatio * yRange;
if (y < yMin() + bottomMargin) {
m_zoomAuto = false;
const float newYMin = y - bottomMargin;
m_yRange.setMax(newYMin + yRange, k_lowerMaxFloat, k_upperMaxFloat);
MemoizedCurveViewRange::protectedSetYMin(newYMin, k_lowerMaxFloat, k_upperMaxFloat);
}
const float topMargin = topMarginRatio * yRange;
if (y > yMax() - topMargin) {
m_zoomAuto = false;
m_yRange.setMax(y + topMargin, k_lowerMaxFloat, k_upperMaxFloat);
MemoizedCurveViewRange::protectedSetYMin(yMax() - yRange, k_lowerMaxFloat, k_upperMaxFloat);
}
}
}
bool InteractiveCurveViewRange::isOrthonormal(float tolerance) const {
float ratio = (yMax() - yMin()) / (xMax() - xMin());
float ratioDifference = std::fabs(std::log(ratio / NormalYXRatio()));
return ratioDifference <= tolerance;
}
}
Reference in New Issue View Git Blame Copy Permalink