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solvespace/src/textscreens.cpp

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//-----------------------------------------------------------------------------
// The text-based browser window, used to view the structure of the model by
// groups and for other similar purposes.
//
// Copyright 2008-2013 Jonathan Westhues.
//-----------------------------------------------------------------------------
#include "solvespace.h"
//-----------------------------------------------------------------------------
// A navigation bar that always appears at the top of the window, with a
// link to bring us back home.
//-----------------------------------------------------------------------------
void TextWindow::ScreenHome(int link, uint32_t v) {
SS.TW.GoToScreen(Screen::LIST_OF_GROUPS);
}
void TextWindow::ShowHeader(bool withNav) {
ClearScreen();
const char *header;
std::string desc;
if(SS.GW.LockedInWorkplane()) {
header = "in plane: ";
desc = SK.GetEntity(SS.GW.ActiveWorkplane())->DescriptionString();
} else {
header = "drawing / constraining in 3d";
desc = "";
}
// Navigation buttons
if(withNav) {
Printf(false, " %Fl%Lh%fhome%E %Ft%s%E%s",
(&TextWindow::ScreenHome), header, desc.c_str());
} else {
Printf(false, " %Ft%s%E%s", header, desc.c_str());
}
// Leave space for the icons that are painted here.
Printf(false, "");
Printf(false, "");
}
//-----------------------------------------------------------------------------
// The screen that shows a list of every group in the sketch, with options
// to hide or show them, and to view them in detail. This is our home page.
//-----------------------------------------------------------------------------
void TextWindow::ScreenSelectGroup(int link, uint32_t v) {
GraphicsWindow::MenuEdit(Command::UNSELECT_ALL);
SS.TW.GoToScreen(Screen::GROUP_INFO);
SS.TW.shown.group.v = v;
}
void TextWindow::ScreenToggleGroupShown(int link, uint32_t v) {
hGroup hg = { v };
Group *g = SK.GetGroup(hg);
g->visible = !(g->visible);
// If a group was just shown, then it might not have been generated
// previously, so regenerate.
SS.GenerateAll();
}
void TextWindow::ScreenShowGroupsSpecial(int link, uint32_t v) {
bool state = link == 's';
for(hGroup hg : SK.groupOrder) {
Group *g = SK.GetGroup(hg);
g->visible = state;
}
SS.GW.persistentDirty = true;
}
void TextWindow::ScreenActivateGroup(int link, uint32_t v) {
SS.GW.activeGroup.v = v;
SK.GetGroup(SS.GW.activeGroup)->Activate();
SS.GW.ClearSuper();
}
void TextWindow::ReportHowGroupSolved(hGroup hg) {
SS.GW.ClearSuper();
SS.TW.GoToScreen(Screen::GROUP_SOLVE_INFO);
SS.TW.shown.group = hg;
SS.ScheduleShowTW();
}
void TextWindow::ScreenHowGroupSolved(int link, uint32_t v) {
if(SS.GW.activeGroup.v != v) {
ScreenActivateGroup(link, v);
}
SS.TW.GoToScreen(Screen::GROUP_SOLVE_INFO);
SS.TW.shown.group.v = v;
}
void TextWindow::ScreenShowConfiguration(int link, uint32_t v) {
SS.TW.GoToScreen(Screen::CONFIGURATION);
}
void TextWindow::ScreenShowEditView(int link, uint32_t v) {
SS.TW.GoToScreen(Screen::EDIT_VIEW);
}
void TextWindow::ScreenGoToWebsite(int link, uint32_t v) {
Platform::OpenInBrowser("http://solvespace.com/txtlink");
}
void TextWindow::ShowListOfGroups() {
const char *radioTrue = " " RADIO_TRUE " ",
*radioFalse = " " RADIO_FALSE " ",
*checkTrue = " " CHECK_TRUE " ",
*checkFalse = " " CHECK_FALSE " ";
Printf(true, "%Ft active");
Printf(false, "%Ft shown dof group-name%E");
bool afterActive = false;
bool backgroundParity = false;
for(hGroup hg : SK.groupOrder) {
Group *g = SK.GetGroup(hg);
std::string s = g->DescriptionString();
bool active = (g->h == SS.GW.activeGroup);
bool shown = g->visible;
bool ok = g->IsSolvedOkay();
bool warn = (g->type == Group::Type::DRAWING_WORKPLANE &&
g->polyError.how != PolyError::GOOD) ||
((g->type == Group::Type::EXTRUDE ||
g->type == Group::Type::LATHE) &&
SK.GetGroup(g->opA)->polyError.how != PolyError::GOOD);
int dof = g->solved.dof;
char sdof[16] = "ok ";
if(ok && dof > 0) {
if(dof > 999) {
strcpy(sdof, "###");
} else {
sprintf(sdof, "%-3d", dof);
}
}
std::string suffix;
if(g->forceToMesh || g->IsTriangleMeshAssembly()) {
suffix = " (∆)";
}
bool ref = (g->h == Group::HGROUP_REFERENCES);
Printf(false,
"%Bp%Fd "
"%Ft%s%Fb%D%f%Ll%s%E "
"%Fb%s%D%f%Ll%s%E "
"%Fp%D%f%s%Ll%s%E "
"%Fp%Ll%D%f%s%E%s",
// Alternate between light and dark backgrounds, for readability
backgroundParity ? 'd' : 'a',
// Link that activates the group
ref ? " " : "",
g->h.v, (&TextWindow::ScreenActivateGroup),
ref ? "" : (active ? radioTrue : radioFalse),
// Link that hides or shows the group
afterActive ? " - " : "",
g->h.v, (&TextWindow::ScreenToggleGroupShown),
afterActive ? "" : (shown ? checkTrue : checkFalse),
// Link to the errors, if a problem occurred while solving
ok ? (warn ? 'm' : (dof > 0 ? 'i' : 's')) : 'x',
g->h.v, (&TextWindow::ScreenHowGroupSolved),
ok ? ((warn && SS.checkClosedContour) ? "err" : sdof) : "",
ok ? "" : "ERR",
// Link to a screen that gives more details on the group
g->suppress ? 'g' : 'l',
g->h.v, (&TextWindow::ScreenSelectGroup), s.c_str(),
suffix.c_str());
if(active) afterActive = true;
backgroundParity = !backgroundParity;
}
Printf(true, " %Fl%Ls%fshow all%E / %Fl%Lh%fhide all%E",
&(TextWindow::ScreenShowGroupsSpecial),
&(TextWindow::ScreenShowGroupsSpecial));
Printf(true, " %Fl%Ls%fline styles%E /"
" %Fl%Ls%fview%E /"
" %Fl%Ls%fconfiguration%E",
&(TextWindow::ScreenShowListOfStyles),
&(TextWindow::ScreenShowEditView),
&(TextWindow::ScreenShowConfiguration));
}
//-----------------------------------------------------------------------------
// The screen that shows information about a specific group, and allows the
// user to edit various things about it.
//-----------------------------------------------------------------------------
void TextWindow::ScreenHoverGroupWorkplane(int link, uint32_t v) {
SS.GW.hover.Clear();
hGroup hg = { v };
SS.GW.hover.entity = hg.entity(0);
SS.GW.hover.emphasized = true;
}
void TextWindow::ScreenHoverEntity(int link, uint32_t v) {
SS.GW.hover.Clear();
hEntity he = { v };
SS.GW.hover.entity = he;
SS.GW.hover.emphasized = true;
}
void TextWindow::ScreenHoverRequest(int link, uint32_t v) {
SS.GW.hover.Clear();
hRequest hr = { v };
SS.GW.hover.entity = hr.entity(0);
SS.GW.hover.emphasized = true;
}
void TextWindow::ScreenHoverConstraint(int link, uint32_t v) {
if(!SS.GW.showConstraints) return;
hConstraint hc = { v };
SS.GW.hover.Clear();
SS.GW.hover.constraint = hc;
SS.GW.hover.emphasized = true;
}
void TextWindow::ScreenSelectEntity(int link, uint32_t v) {
SS.GW.ClearSelection();
GraphicsWindow::Selection sel = {};
hEntity he = { v };
sel.entity = he;
SS.GW.selection.Add(&sel);
}
void TextWindow::ScreenSelectRequest(int link, uint32_t v) {
SS.GW.ClearSelection();
GraphicsWindow::Selection sel = {};
hRequest hr = { v };
sel.entity = hr.entity(0);
SS.GW.selection.Add(&sel);
}
void TextWindow::ScreenSelectConstraint(int link, uint32_t v) {
SS.GW.ClearSelection();
GraphicsWindow::Selection sel = {};
sel.constraint.v = v;
SS.GW.selection.Add(&sel);
}
void TextWindow::ScreenChangeGroupOption(int link, uint32_t v) {
SS.UndoRemember();
Group *g = SK.GetGroup(SS.TW.shown.group);
switch(link) {
case 's': g->subtype = Group::Subtype::ONE_SIDED; break;
case 'S': g->subtype = Group::Subtype::TWO_SIDED; break;
case 'k': g->skipFirst = true; break;
case 'K': g->skipFirst = false; break;
case 'c':
if(g->type == Group::Type::EXTRUDE) {
// When an extrude group is first created, it's positioned for a union
// extrusion. If no constraints were added, flip it when we switch between
// union/assemble and difference/intersection modes to avoid manual work doing the same.
if(g->meshCombine != (Group::CombineAs)v && g->GetNumConstraints() == 0) {
// I apologise for this if statement
if((((Group::CombineAs::DIFFERENCE == g->meshCombine) ||
(Group::CombineAs::INTERSECTION == g->meshCombine)) &&
(Group::CombineAs::DIFFERENCE != (Group::CombineAs)v) &&
(Group::CombineAs::INTERSECTION != (Group::CombineAs)v)) ||
((Group::CombineAs::DIFFERENCE != g->meshCombine) &&
(Group::CombineAs::INTERSECTION != g->meshCombine) &&
((Group::CombineAs::DIFFERENCE == (Group::CombineAs)v) ||
(Group::CombineAs::INTERSECTION == (Group::CombineAs)v)))) {
g->ExtrusionForceVectorTo(g->ExtrusionGetVector().Negated());
}
}
}
g->meshCombine = (Group::CombineAs)v;
break;
case 'P': g->suppress = !(g->suppress); break;
case 'r': g->relaxConstraints = !(g->relaxConstraints); break;
case 'e': g->allowRedundant = !(g->allowRedundant); break;
case 'v': g->visible = !(g->visible); break;
case 'd': g->allDimsReference = !(g->allDimsReference); break;
case 'f': g->forceToMesh = !(g->forceToMesh); break;
}
SS.MarkGroupDirty(g->h);
SS.GW.ClearSuper();
}
void TextWindow::ScreenColor(int link, uint32_t v) {
SS.UndoRemember();
Group *g = SK.GetGroup(SS.TW.shown.group);
SS.TW.ShowEditControlWithColorPicker(3, g->color);
SS.TW.edit.meaning = Edit::GROUP_COLOR;
}
void TextWindow::ScreenOpacity(int link, uint32_t v) {
Group *g = SK.GetGroup(SS.TW.shown.group);
SS.TW.ShowEditControl(11, ssprintf("%.2f", g->color.alphaF()));
SS.TW.edit.meaning = Edit::GROUP_OPACITY;
SS.TW.edit.group = g->h;
}
void TextWindow::ScreenChangeExprA(int link, uint32_t v) {
Group *g = SK.GetGroup(SS.TW.shown.group);
SS.TW.ShowEditControl(10, ssprintf("%d", (int)g->valA));
SS.TW.edit.meaning = Edit::TIMES_REPEATED;
SS.TW.edit.group.v = v;
}
void TextWindow::ScreenChangeGroupName(int link, uint32_t v) {
Group *g = SK.GetGroup(SS.TW.shown.group);
SS.TW.ShowEditControl(12, g->DescriptionString().substr(5));
SS.TW.edit.meaning = Edit::GROUP_NAME;
SS.TW.edit.group.v = v;
}
void TextWindow::ScreenChangeGroupScale(int link, uint32_t v) {
Group *g = SK.GetGroup(SS.TW.shown.group);
SS.TW.ShowEditControl(13, ssprintf("%.3f", g->scale));
SS.TW.edit.meaning = Edit::GROUP_SCALE;
SS.TW.edit.group.v = v;
}
void TextWindow::ScreenChangeHelixPitch(int link, uint32_t v) {
Group *g = SK.GetGroup(SS.TW.shown.group);
double pitch = g->valB/SS.MmPerUnit();
SS.TW.ShowEditControl(3, ssprintf("%.8f", pitch));
SS.TW.edit.meaning = Edit::HELIX_PITCH;
SS.TW.edit.group.v = v;
}
void TextWindow::ScreenChangePitchOption(int link, uint32_t v) {
Group *g = SK.GetGroup(SS.TW.shown.group);
if(g->valB == 0.0) {
g->valB = SK.GetParam(g->h.param(7))->val * PI /
(SK.GetParam(g->h.param(3))->val);
} else {
g->valB = 0.0;
}
SS.GW.Invalidate();
}
void TextWindow::ScreenDeleteGroup(int link, uint32_t v) {
SS.UndoRemember();
hGroup hg = SS.TW.shown.group;
if(hg == SS.GW.activeGroup) {
SS.GW.activeGroup = SK.GetGroup(SS.GW.activeGroup)->PreviousGroup()->h;
}
// Reset the text window, since we're displaying information about
// the group that's about to get deleted.
SS.TW.ClearSuper();
// This is a major change, so let's re-solve everything.
SK.group.RemoveById(hg);
SS.GenerateAll(SolveSpaceUI::Generate::ALL);
// Reset the graphics window. This will also recreate the default
// group if it was removed.
SS.GW.ClearSuper();
}
void TextWindow::ShowGroupInfo() {
Group *g = SK.GetGroup(shown.group);
const char *s = "???";
if(shown.group == Group::HGROUP_REFERENCES) {
Printf(true, "%FtGROUP %E%s", g->DescriptionString().c_str());
goto list_items;
} else {
Printf(true, "%FtGROUP %E%s [%Fl%Ll%D%frename%E/%Fl%Ll%D%fdel%E]",
g->DescriptionString().c_str(),
g->h.v, &TextWindow::ScreenChangeGroupName,
g->h.v, &TextWindow::ScreenDeleteGroup);
}
if(g->type == Group::Type::LATHE) {
Printf(true, " %Ftlathe plane sketch");
} else if(g->type == Group::Type::EXTRUDE || g->type == Group::Type::ROTATE ||
g->type == Group::Type::TRANSLATE || g->type == Group::Type::REVOLVE ||
g->type == Group::Type::HELIX) {
if(g->type == Group::Type::EXTRUDE) {
s = "extrude plane sketch";
} else if(g->type == Group::Type::TRANSLATE) {
s = "translate original sketch";
} else if(g->type == Group::Type::HELIX) {
s = "create helical extrusion";
} else if(g->type == Group::Type::ROTATE) {
s = "rotate original sketch";
} else if(g->type == Group::Type::REVOLVE) {
s = "revolve original sketch";
}
Printf(true, " %Ft%s%E", s);
bool one = (g->subtype == Group::Subtype::ONE_SIDED);
Printf(false,
"%Ba %f%Ls%Fd%s one-sided%E "
"%f%LS%Fd%s two-sided%E",
&TextWindow::ScreenChangeGroupOption,
one ? RADIO_TRUE : RADIO_FALSE,
&TextWindow::ScreenChangeGroupOption,
!one ? RADIO_TRUE : RADIO_FALSE);
if(g->type == Group::Type::ROTATE || g->type == Group::Type::TRANSLATE) {
if(g->subtype == Group::Subtype::ONE_SIDED) {
bool skip = g->skipFirst;
Printf(false,
"%Bd %Ftstart %f%LK%Fd%s with original%E "
"%f%Lk%Fd%s with copy #1%E",
&ScreenChangeGroupOption,
!skip ? RADIO_TRUE : RADIO_FALSE,
&ScreenChangeGroupOption,
skip ? RADIO_TRUE : RADIO_FALSE);
}
int times = (int)(g->valA);
Printf(false, "%Bp %Ftrepeat%E %d time%s %Fl%Ll%D%f[change]%E",
(g->subtype == Group::Subtype::ONE_SIDED) ? 'a' : 'd',
times, times == 1 ? "" : "s",
g->h.v, &TextWindow::ScreenChangeExprA);
}
} else if(g->type == Group::Type::LINKED) {
Printf(true, " %Ftlink geometry from file%E");
Platform::Path relativePath = g->linkFile.RelativeTo(SS.saveFile.Parent());
if(relativePath.IsEmpty()) {
Printf(false, "%Ba '%s'", g->linkFile.raw.c_str());
} else {
Printf(false, "%Ba '%s'", relativePath.raw.c_str());
}
Printf(false, "%Bd %Ftscaled by%E %# %Fl%Ll%f%D[change]%E",
g->scale,
&TextWindow::ScreenChangeGroupScale, g->h.v);
} else if(g->type == Group::Type::DRAWING_3D) {
Printf(true, " %Ftsketch in 3d%E");
} else if(g->type == Group::Type::DRAWING_WORKPLANE) {
Printf(true, " %Ftsketch in new workplane%E");
} else {
Printf(true, "???");
}
Printf(false, "");
if(g->type == Group::Type::HELIX) {
Printf(false, "%Ft pitch - length per turn%E");
if (fabs(g->valB) != 0.0) {
Printf(false, " %Ba %# %Fl%Ll%f%D[change]%E",
g->valB / SS.MmPerUnit(),
&TextWindow::ScreenChangeHelixPitch, g->h.v);
} else {
Printf(false, " %Ba %# %E",
SK.GetParam(g->h.param(7))->val * PI /
( (SK.GetParam(g->h.param(3))->val) * SS.MmPerUnit() ),
&TextWindow::ScreenChangeHelixPitch, g->h.v);
}
Printf(false, " %Fd%f%LP%s fixed",
&TextWindow::ScreenChangePitchOption,
g->valB != 0 ? CHECK_TRUE : CHECK_FALSE);
Printf(false, ""); // blank line
}
if(g->type == Group::Type::EXTRUDE || g->type == Group::Type::LATHE ||
g->type == Group::Type::REVOLVE || g->type == Group::Type::LINKED ||
g->type == Group::Type::HELIX) {
bool un = (g->meshCombine == Group::CombineAs::UNION);
bool diff = (g->meshCombine == Group::CombineAs::DIFFERENCE);
bool intr = (g->meshCombine == Group::CombineAs::INTERSECTION);
bool asy = (g->meshCombine == Group::CombineAs::ASSEMBLE);
Printf(false, " %Ftsolid model as");
Printf(false, "%Ba %f%D%Lc%Fd%s union%E "
"%f%D%Lc%Fd%s assemble%E ",
&TextWindow::ScreenChangeGroupOption,
Group::CombineAs::UNION,
un ? RADIO_TRUE : RADIO_FALSE,
&TextWindow::ScreenChangeGroupOption,
Group::CombineAs::ASSEMBLE,
(asy ? RADIO_TRUE : RADIO_FALSE));
Printf(false, "%Ba %f%D%Lc%Fd%s difference%E "
"%f%D%Lc%Fd%s intersection%E ",
&TextWindow::ScreenChangeGroupOption,
Group::CombineAs::DIFFERENCE,
diff ? RADIO_TRUE : RADIO_FALSE,
&TextWindow::ScreenChangeGroupOption,
Group::CombineAs::INTERSECTION,
intr ? RADIO_TRUE : RADIO_FALSE);
if(g->type == Group::Type::EXTRUDE || g->type == Group::Type::LATHE ||
g->type == Group::Type::REVOLVE || g->type == Group::Type::HELIX) {
Printf(false,
"%Bd %Ftcolor %E%Bz %Bd (%@, %@, %@) %f%D%Lf%Fl[change]%E",
&g->color,
g->color.redF(), g->color.greenF(), g->color.blueF(),
ScreenColor, top[rows-1] + 2);
Printf(false, "%Bd %Ftopacity%E %@ %f%Lf%Fl[change]%E",
g->color.alphaF(),
&TextWindow::ScreenOpacity);
}
if(g->type == Group::Type::EXTRUDE || g->type == Group::Type::LATHE ||
g->type == Group::Type::REVOLVE || g->type == Group::Type::LINKED ||
g->type == Group::Type::HELIX) {
Printf(false, " %Fd%f%LP%s suppress this group's solid model",
&TextWindow::ScreenChangeGroupOption,
g->suppress ? CHECK_TRUE : CHECK_FALSE);
}
Printf(false, "");
}
Printf(false, " %f%Lv%Fd%s show entities from this group",
&TextWindow::ScreenChangeGroupOption,
g->visible ? CHECK_TRUE : CHECK_FALSE);
if(!g->IsForcedToMeshBySource() && !g->IsTriangleMeshAssembly()) {
Printf(false, " %f%Lf%Fd%s force NURBS surfaces to triangle mesh",
&TextWindow::ScreenChangeGroupOption,
g->forceToMesh ? CHECK_TRUE : CHECK_FALSE);
} else {
Printf(false, " (model already forced to triangle mesh)");
}
Printf(true, " %f%Lr%Fd%s relax constraints and dimensions",
&TextWindow::ScreenChangeGroupOption,
g->relaxConstraints ? CHECK_TRUE : CHECK_FALSE);
Printf(false, " %f%Le%Fd%s allow redundant constraints",
&TextWindow::ScreenChangeGroupOption,
g->allowRedundant ? CHECK_TRUE : CHECK_FALSE);
Printf(false, " %f%Ld%Fd%s treat all dimensions as reference",
&TextWindow::ScreenChangeGroupOption,
g->allDimsReference ? CHECK_TRUE : CHECK_FALSE);
if(g->booleanFailed) {
Printf(false, "");
Printf(false, "The Boolean operation failed. It may be ");
Printf(false, "possible to fix the problem by choosing ");
Printf(false, "'force NURBS surfaces to triangle mesh'.");
}
list_items:
Printf(false, "");
Printf(false, "%Ft requests in group");
int a = 0;
for(auto &r : SK.request) {
if(r.group == shown.group) {
std::string s = r.DescriptionString();
Printf(false, "%Bp %Fl%Ll%D%f%h%s%E",
(a & 1) ? 'd' : 'a',
r.h.v,
(&TextWindow::ScreenSelectRequest),
&(TextWindow::ScreenHoverRequest),
s.c_str());
a++;
}
}
if(a == 0) Printf(false, "%Ba (none)");
a = 0;
Printf(false, "");
Printf(false, "%Ft constraints in group (%d DOF)", g->solved.dof);
for(auto &c : SK.constraint) {
if(c.group == shown.group) {
std::string s = c.DescriptionString();
Printf(false, "%Bp %Fl%Ll%D%f%h%s%E %s",
(a & 1) ? 'd' : 'a',
c.h.v,
(&TextWindow::ScreenSelectConstraint),
(&TextWindow::ScreenHoverConstraint),
s.c_str(),
c.reference ? "(ref)" : "");
a++;
}
}
if(a == 0) Printf(false, "%Ba (none)");
}
//-----------------------------------------------------------------------------
// The screen that's displayed when the sketch fails to solve. A report of
// what failed, and (if the problem is a singular Jacobian) a list of
// constraints that could be removed to fix it.
//-----------------------------------------------------------------------------
void TextWindow::ScreenAllowRedundant(int link, uint32_t v) {
SS.UndoRemember();
Group *g = SK.GetGroup(SS.TW.shown.group);
g->allowRedundant = true;
SS.MarkGroupDirty(SS.TW.shown.group);
SS.TW.shown.screen = Screen::GROUP_INFO;
SS.TW.Show();
}
void TextWindow::ShowGroupSolveInfo() {
Group *g = SK.GetGroup(shown.group);
if(g->IsSolvedOkay()) {
// Go back to the default group info screen
shown.screen = Screen::GROUP_INFO;
Show();
return;
}
Printf(true, "%FtGROUP %E%s", g->DescriptionString().c_str());
switch(g->solved.how) {
case SolveResult::DIDNT_CONVERGE:
Printf(true, "%FxSOLVE FAILED!%Fd unsolvable constraints");
Printf(true, "the following constraints are incompatible");
break;
case SolveResult::REDUNDANT_DIDNT_CONVERGE:
Printf(true, "%FxSOLVE FAILED!%Fd unsolvable constraints");
Printf(true, "the following constraints are unsatisfied");
break;
case SolveResult::REDUNDANT_OKAY:
Printf(true, "%FxSOLVE FAILED!%Fd redundant constraints");
Printf(true, "remove any one of these to fix it");
break;
case SolveResult::TOO_MANY_UNKNOWNS:
Printf(true, "Too many unknowns in a single group!");
return;
default: ssassert(false, "Unexpected solve result");
}
for(int i = 0; i < g->solved.remove.n; i++) {
hConstraint hc = g->solved.remove[i];
Constraint *c = SK.constraint.FindByIdNoOops(hc);
if(!c) continue;
Printf(false, "%Bp %Fl%Ll%D%f%h%s%E",
(i & 1) ? 'd' : 'a',
c->h.v, (&TextWindow::ScreenSelectConstraint),
(&TextWindow::ScreenHoverConstraint),
c->DescriptionString().c_str());
}
if(g->solved.timeout) {
Printf(true, "%FxSome items in list have been omitted%Fd");
Printf(false, "%Fxbecause the operation timed out.%Fd");
}
Printf(true, "It may be possible to fix the problem ");
Printf(false, "by selecting Edit -> Undo.");
if(g->solved.how == SolveResult::REDUNDANT_OKAY) {
Printf(true, "It is possible to suppress this error ");
Printf(false, "by %Fl%f%Llallowing redundant constraints%E in ",
&TextWindow::ScreenAllowRedundant);
Printf(false, "this group.");
}
}
//-----------------------------------------------------------------------------
// When we're stepping a dimension. User specifies the finish value, and
// how many steps to take in between current and finish, re-solving each
// time.
//-----------------------------------------------------------------------------
void TextWindow::ScreenStepDimFinish(int link, uint32_t v) {
SS.TW.edit.meaning = Edit::STEP_DIM_FINISH;
std::string edit_value;
if(SS.TW.stepDim.isDistance) {
edit_value = SS.MmToString(SS.TW.stepDim.finish, true);
} else {
edit_value = ssprintf("%.3f", SS.TW.stepDim.finish);
}
SS.TW.ShowEditControl(12, edit_value);
}
void TextWindow::ScreenStepDimSteps(int link, uint32_t v) {
SS.TW.edit.meaning = Edit::STEP_DIM_STEPS;
SS.TW.ShowEditControl(12, ssprintf("%d", SS.TW.stepDim.steps));
}
void TextWindow::ScreenStepDimGo(int link, uint32_t v) {
hConstraint hc = SS.TW.shown.constraint;
Constraint *c = SK.constraint.FindByIdNoOops(hc);
if(c) {
SS.UndoRemember();
double start = c->valA, finish = SS.TW.stepDim.finish;
SS.TW.stepDim.time = GetMilliseconds();
SS.TW.stepDim.step = 1;
if(!SS.TW.stepDim.timer) {
SS.TW.stepDim.timer = Platform::CreateTimer();
}
SS.TW.stepDim.timer->onTimeout = [=] {
if(SS.TW.stepDim.step <= SS.TW.stepDim.steps) {
c->valA = start + ((finish - start)*SS.TW.stepDim.step)/SS.TW.stepDim.steps;
SS.MarkGroupDirty(c->group);
SS.GenerateAll();
if(!SS.ActiveGroupsOkay()) {
// Failed to solve, so quit
return;
}
SS.TW.stepDim.step++;
const int64_t STEP_MILLIS = 50;
int64_t time = GetMilliseconds();
if(time - SS.TW.stepDim.time < STEP_MILLIS) {
SS.TW.stepDim.timer->RunAfterNextFrame();
} else {
SS.TW.stepDim.timer->RunAfter((unsigned)(time - SS.TW.stepDim.time - STEP_MILLIS));
}
SS.TW.stepDim.time = time;
} else {
SS.TW.GoToScreen(Screen::LIST_OF_GROUPS);
SS.ScheduleShowTW();
}
SS.GW.Invalidate();
};
SS.TW.stepDim.timer->RunAfterNextFrame();
}
}
void TextWindow::ShowStepDimension() {
Constraint *c = SK.constraint.FindByIdNoOops(shown.constraint);
if(!c) {
shown.screen = Screen::LIST_OF_GROUPS;
Show();
return;
}
Printf(true, "%FtSTEP DIMENSION%E %s", c->DescriptionString().c_str());
if(stepDim.isDistance) {
Printf(true, "%Ba %Ftstart%E %s", SS.MmToString(c->valA).c_str());
Printf(false, "%Bd %Ftfinish%E %s %Fl%Ll%f[change]%E",
SS.MmToString(stepDim.finish).c_str(), &ScreenStepDimFinish);
} else {
Printf(true, "%Ba %Ftstart%E %@", c->valA);
Printf(false, "%Bd %Ftfinish%E %@ %Fl%Ll%f[change]%E",
stepDim.finish, &ScreenStepDimFinish);
}
Printf(false, "%Ba %Ftsteps%E %d %Fl%Ll%f%D[change]%E",
stepDim.steps, &ScreenStepDimSteps);
Printf(true, " %Fl%Ll%fstep dimension now%E", &ScreenStepDimGo);
Printf(true, "(or %Fl%Ll%fcancel operation%E)", &ScreenHome);
}
//-----------------------------------------------------------------------------
// When we're creating tangent arcs (as requests, not as some parametric
// thing). User gets to specify the radius, and whether the old untrimmed
// curves are kept or deleted.
//-----------------------------------------------------------------------------
void TextWindow::ScreenChangeTangentArc(int link, uint32_t v) {
switch(link) {
case 'r': {
SS.TW.edit.meaning = Edit::TANGENT_ARC_RADIUS;
SS.TW.ShowEditControl(3, SS.MmToString(SS.tangentArcRadius, true));
break;
}
case 'a': SS.tangentArcManual = !SS.tangentArcManual; break;
case 'm': SS.tangentArcModify = !SS.tangentArcModify; break;
}
}
void TextWindow::ShowTangentArc() {
Printf(true, "%FtTANGENT ARC PARAMETERS%E");
Printf(true, "%Ft radius of created arc%E");
if(SS.tangentArcManual) {
Printf(false, "%Ba %s %Fl%Lr%f[change]%E",
SS.MmToString(SS.tangentArcRadius).c_str(),
&(TextWindow::ScreenChangeTangentArc));
} else {
Printf(false, "%Ba automatic");
}
Printf(false, "");
Printf(false, " %Fd%f%La%s choose radius automatically%E",
&ScreenChangeTangentArc,
!SS.tangentArcManual ? CHECK_TRUE : CHECK_FALSE);
Printf(false, " %Fd%f%Lm%s modify original entities%E",
&ScreenChangeTangentArc,
SS.tangentArcModify ? CHECK_TRUE : CHECK_FALSE);
Printf(false, "");
Printf(false, "To create a tangent arc at a point,");
Printf(false, "select that point and then choose");
Printf(false, "Sketch -> Tangent Arc at Point.");
Printf(true, "(or %Fl%Ll%fback to home screen%E)", &ScreenHome);
}
//-----------------------------------------------------------------------------
// The edit control is visible, and the user just pressed enter.
//-----------------------------------------------------------------------------
void TextWindow::EditControlDone(std::string s) {
edit.showAgain = false;
switch(edit.meaning) {
case Edit::TIMES_REPEATED:
if(Expr *e = Expr::From(s, /*popUpError=*/true)) {
SS.UndoRemember();
double ev = e->Eval();
if((int)ev < 1) {
Error(_("Can't repeat fewer than 1 time."));
break;
}
if((int)ev > 999) {
Error(_("Can't repeat more than 999 times."));
break;
}
Group *g = SK.GetGroup(edit.group);
g->valA = ev;
if(g->type == Group::Type::ROTATE) {
// If the group does not contain any constraints, then
// set the numerical guess to space the copies uniformly
// over one rotation. Don't touch the guess if we're
// already constrained, because that would break
// convergence.
if(g->GetNumConstraints() == 0) {
double copies = (g->skipFirst) ? (ev + 1) : ev;
SK.GetParam(g->h.param(3))->val = PI/(2*copies);
}
}
SS.MarkGroupDirty(g->h);
}
break;
case Edit::GROUP_NAME:
if(s.empty()) {
Error(_("Group name cannot be empty"));
} else {
SS.UndoRemember();
Group *g = SK.GetGroup(edit.group);
g->name = s;
}
break;
case Edit::GROUP_SCALE:
if(Expr *e = Expr::From(s, /*popUpError=*/true)) {
double ev = e->Eval();
if(fabs(ev) < 1e-6) {
Error(_("Scale cannot be zero."));
} else {
Group *g = SK.GetGroup(edit.group);
g->scale = ev;
SS.MarkGroupDirty(g->h);
}
}
break;
case Edit::HELIX_PITCH: // stored in valB
if(Expr *e = Expr::From(s, /*popUpError=*/true)) {
double ev = e->Eval();
Group *g = SK.GetGroup(edit.group);
g->valB = ev * SS.MmPerUnit();
SS.MarkGroupDirty(g->h);
}
break;
case Edit::GROUP_COLOR: {
Vector rgb;
if(sscanf(s.c_str(), "%lf, %lf, %lf", &rgb.x, &rgb.y, &rgb.z)==3) {
rgb = rgb.ClampWithin(0, 1);
Group *g = SK.group.FindByIdNoOops(SS.TW.shown.group);
if(!g) break;
g->color = RgbaColor::FromFloat((float)rgb.x, (float)rgb.y, (float)rgb.z,
g->color.alphaF());
SS.MarkGroupDirty(g->h);
SS.GW.ClearSuper();
} else {
Error(_("Bad format: specify color as r, g, b"));
}
break;
}
case Edit::GROUP_OPACITY:
if(Expr *e = Expr::From(s, /*popUpError=*/true)) {
double alpha = e->Eval();
if(alpha < 0 || alpha > 1) {
Error(_("Opacity must be between zero and one."));
} else {
Group *g = SK.GetGroup(edit.group);
g->color.alpha = (int)(255.1f * alpha);
SS.MarkGroupDirty(g->h);
SS.GW.ClearSuper();
}
}
break;
case Edit::TTF_TEXT:
SS.UndoRemember();
if(Request *r = SK.request.FindByIdNoOops(edit.request)) {
r->str = s;
SS.MarkGroupDirty(r->group);
}
break;
case Edit::STEP_DIM_FINISH:
if(Expr *e = Expr::From(s, /*popUpError=*/true)) {
if(stepDim.isDistance) {
stepDim.finish = SS.ExprToMm(e);
} else {
stepDim.finish = e->Eval();
}
}
break;
case Edit::STEP_DIM_STEPS:
stepDim.steps = min(300, max(1, atoi(s.c_str())));
break;
case Edit::TANGENT_ARC_RADIUS:
if(Expr *e = Expr::From(s, /*popUpError=*/true)) {
if(e->Eval() < LENGTH_EPS) {
Error(_("Radius cannot be zero or negative."));
break;
}
SS.tangentArcRadius = SS.ExprToMm(e);
}
break;
default: {
int cnt = 0;
if(EditControlDoneForStyles(s)) cnt++;
if(EditControlDoneForConfiguration(s)) cnt++;
if(EditControlDoneForPaste(s)) cnt++;
if(EditControlDoneForView(s)) cnt++;
ssassert(cnt == 1, "Expected exactly one parameter to be edited");
break;
}
}
SS.GW.Invalidate();
SS.ScheduleShowTW();
if(!edit.showAgain) {
HideEditControl();
edit.meaning = Edit::NOTHING;
}
}
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