mstools/samples/spincube/paint.c - view

File: [WindowsNT SDKs] / mstools / samples / spincube / paint.c
Revision 1.1.1.1 (vendor branch): download - view: text, annotated - select for diffs
Thu Aug 9 18:23:17 2018 UTC (7 years, 9 months ago) by root
Branches: msft, MAIN
CVS tags: ntsdk-nov-1993, ntsdk-jul-1993, HEAD

Microsoft Windows NT Build 511 (SDK Final Release) 07-24-1993

/******************************************************************************\ * * MODULE: PAINT.C * * PURPOSE: This is the module responsible for painting the SPINCUBE * custom control. When Paint() is called we retrieve a * pointer to a SPINCUBEINFO structure, and then use it's * current rotation & translation values to transform the * polyhedron described by gNormalizedVertices & gaiFacets. * Once we've transformed the vertices, we draw the * background, which consists of a grey rectangle and a few * black lines (a crass attempt to render a perspective * view into a "room"), on the offscreen bitmap associated * with the control (i.e. pSCI->hbmCompat). Then we walk the * facet list of the transformed polyhedron (gXformedVertices * & gaiFacets), drawing only those facets whose outward * normal faces us (again, drawing on pSCI->hbmCompat). * Finally, we BitBlt the appropriate rectangle from our * offscreen bitmap to the screen itself. * * Drawing to the offscreen bitmap has two advantages over * drawing straight to the screen: * * 1. The actual drawing the user sees consists of only * a single BitBlt. Otherwise, the user would see us * both erase the polyhedron in it's old position and * draw it in it's new position (alot of flashing- not * very smooth animation). * * 2. When a spincube control with the SS_ERASE style * is brought to the foreground, all it's contents * i.e. the cube trails) are saved & can be re-Blted * to the screen. Otherwise, all this info would be * lost & there'd be a big blank spot in the middle * of the control! * * Interested persons should consult a text on 3 dimensional * graphics for more information (i.e. "Computer Graphics: * Principles and Practice", by Foley & van Dam). * * Notes: * * - A 3x2 tranformation matrix is used instead of a 3x3 * matrix, since the transformed z-values aren't needed. * (Normally these would be required for use in depth * sorting [for hidden surface removal], but since we * draw only a single convex polyhedron this is not * necessary.) * * - A simplified perspective viewing transformation * (which also precludes the need for the transformed z * coordinates). In a nutshell, the perspective scale * is as follows: * * p' = S x p * per * * where: * S = WindowDepth / * per (WindowDepth + fCurrentZTranslation) * * (WindowDepth is the greater of the control's window * height or window width.) * * * FUNCTIONS: Paint() - the paint routine * TransformVertices() - transforms vertices * ComputeRotationTransformation() - computes xformation * based on current x, y * and z rotation angles * * * Dan Knudson * Microsoft Developer Support * Copyright (c) 1992, 1993 Microsoft Corporation * \******************************************************************************/ #include <windows.h> #include <math.h> #include <stdlib.h> #include "spincube.h" #include "paint.h" /******************************************************************************\ * * FUNCTION: Paint * * INPUTS: hwnd - Handle of the window to draw into. * * COMMENTS: Draws window background & a polyhedron in the window. * \******************************************************************************/ void Paint (HWND hwnd) { PSPINCUBEINFO pSCI; RECT rect; int i; LONG lScaleFactor; PAINTSTRUCT ps; HRGN hrgnClip; HBRUSH hBrush, hBrushSave; int iX, iY, iCX, iCY; int facetIndex, numPoints; POINT polygn[MAX_POINTS_PER_FACET]; POINT vector1, vector2; COLORREF acrColor[6] = { 0x0000ff, 0x00ff00, 0xff0000, 0x00ffff, 0xff00ff, 0xffff00 }; pSCI = (PSPINCUBEINFO) GetWindowLong (hwnd, GWL_SPINCUBEDATA); BeginPaint (hwnd, &ps); if (memcmp((void *)&ps.rcPaint, (void *)&pSCI->rcCubeBoundary, sizeof(RECT)) & !REPAINT_BKGND(pSCI)) { // // We're not here because it's time to animate (i.e. this paint isn't // the result of a WM_TIMER), so just do the Blt & blow out of here... // BitBlt (ps.hdc, ps.rcPaint.left, ps.rcPaint.top, ps.rcPaint.right - ps.rcPaint.left, ps.rcPaint.bottom - ps.rcPaint.top, pSCI->hdcCompat, ps.rcPaint.left, ps.rcPaint.top, SRCCOPY); EndPaint (hwnd, &ps); return; } // // The rectangle we get back is in Desktop coordinates, so we need to // modify it to reflect coordinates relative to this window. // GetWindowRect (hwnd, &rect); rect.right -= rect.left; rect.bottom -= rect.top; rect.left = rect.top = 0; // // Determine a "best fit" scale factor for our polyhedron // if (!(lScaleFactor = rect.right > rect.bottom ? rect.bottom/12 : rect.right/12)) lScaleFactor = 1; TransformVertices (hwnd, &rect, pSCI, lScaleFactor); // // Draw the window frame & background // // Note: The chances are that we are coming through here because we // got a WM_TIMER message & it's time to redraw the cube to simulate // animation. In that case all we want to erase/redraw is that small // rectangle which bounded the polyhedron the last time. The less // drawing that actually gets done the better, since we wnat to // minimize the flicker on the screen. __BeginPaint__ is perfect for // this because it causes all drawing outside of the invalid region // to be "clipped" (no drawing is performed outside of the invalid // region), and it also validates the invalid region. // if (DO_ERASE(hwnd) || REPAINT_BKGND(pSCI)) { hrgnClip = CreateRectRgnIndirect (&ps.rcPaint); SelectClipRgn (pSCI->hdcCompat, hrgnClip); DeleteObject (hrgnClip); SelectObject (pSCI->hdcCompat, GetStockObject (GRAY_BRUSH)); Rectangle (pSCI->hdcCompat, (int)rect.left, (int)rect.top, (int)rect.right, (int)rect.bottom); iX = (rect.right - rect.left) / 4; iY = (rect.bottom - rect.top ) / 4; MoveToEx (pSCI->hdcCompat, (int)rect.left, (int)rect.top, NULL); LineTo (pSCI->hdcCompat, (int)rect.left + iX, (int)rect.top + iY); LineTo (pSCI->hdcCompat, (int)rect.left + iX, (int)rect.bottom - iY); LineTo (pSCI->hdcCompat, (int)rect.left, (int)rect.bottom); MoveToEx (pSCI->hdcCompat, (int)rect.right, (int)rect.top, NULL); LineTo (pSCI->hdcCompat, (int)rect.right - iX, (int)rect.top + iY); LineTo (pSCI->hdcCompat, (int)rect.right - iX, (int)rect.bottom- iY); LineTo (pSCI->hdcCompat, (int)rect.right, (int)rect.bottom); MoveToEx (pSCI->hdcCompat, (int)rect.left + iX, (int)rect.top + iY, NULL); LineTo (pSCI->hdcCompat, (int)rect.right - iX, (int)rect.top + iY); MoveToEx (pSCI->hdcCompat, (int)rect.left + iX, (int)rect.bottom - iY, NULL); LineTo (pSCI->hdcCompat, (int)rect.right - iX, (int)rect.bottom - iY); SelectClipRgn (pSCI->hdcCompat, NULL); pSCI->iOptions &= ~SPINCUBE_REPAINT_BKGND; } // // Draw the polyhedron. We'll walk through the facets list and compute // the normal for each facet- if the normal has z > 0, then the facet // faces us and we'll draw it. Note that this algorithim is ONLY valid // for scenes with a single, convex polyhedron. // // Note: Use GetDC here because the above call to BeginPaint will // probably not give us a DC with access to as much real estate as // we'd like (we wouldn't be able to draw outside of the invalid // region). We can party on the entire control window with the DC // returned by GetDC. // for (i = 0, facetIndex = 0; i < NUMFACETS; i++) { vector1.x = gXformedVertices[gaiFacets[facetIndex + 1]].x - gXformedVertices[gaiFacets[facetIndex]].x; vector1.y = gXformedVertices[gaiFacets[facetIndex + 1]].y - gXformedVertices[gaiFacets[facetIndex]].y; vector2.x = gXformedVertices[gaiFacets[facetIndex + 2]].x - gXformedVertices[gaiFacets[facetIndex + 1]].x; vector2.y = gXformedVertices[gaiFacets[facetIndex + 2]].y - gXformedVertices[gaiFacets[facetIndex + 1]].y; for (numPoints = 0; gaiFacets[facetIndex] != -1; numPoints++, facetIndex++) { polygn[numPoints].x = gXformedVertices[gaiFacets[facetIndex]].x; polygn[numPoints].y = gXformedVertices[gaiFacets[facetIndex]].y; } facetIndex++; /* skip over the -1's in the facets list */ if ((vector1.x*vector2.y - vector1.y*vector2.x) > 0) { hBrush = CreateSolidBrush (acrColor[i]); hBrushSave = (HBRUSH) SelectObject (pSCI->hdcCompat, hBrush); Polygon (pSCI->hdcCompat, &polygn[0], numPoints); SelectObject (pSCI->hdcCompat, hBrushSave); DeleteObject (hBrush); } } iX = pSCI->rcCubeBoundary.left < ps.rcPaint.left ? pSCI->rcCubeBoundary.left : ps.rcPaint.left; iY = pSCI->rcCubeBoundary.top < ps.rcPaint.top ? pSCI->rcCubeBoundary.top : ps.rcPaint.top; iCX = (pSCI->rcCubeBoundary.right > ps.rcPaint.right ? pSCI->rcCubeBoundary.right : ps.rcPaint.right) - iX; iCY = (pSCI->rcCubeBoundary.bottom > ps.rcPaint.bottom ? pSCI->rcCubeBoundary.bottom : ps.rcPaint.bottom) - iY; EndPaint (hwnd, &ps); ps.hdc = GetDC (hwnd); BitBlt (ps.hdc, iX, iY, iCX, iCY, pSCI->hdcCompat, iX, iY, SRCCOPY); ReleaseDC (hwnd, ps.hdc); } /******************************************************************************\ * * FUNCTION: TransformVertices * * INPUTS: hwnd - control window handle * pWindowRect - pointer to RECT describing control's dimensions * pSCI - pointer to control's SPINCUBEINFO structure * fScaleFactor - scale factor for use in this window * \******************************************************************************/ void TransformVertices (HWND hwnd, RECT *pWindowRect, PSPINCUBEINFO pSCI, LONG lScaleFactor) { int i; int iWindowDepth = pWindowRect->right > pWindowRect->bottom ? pWindowRect->right : pWindowRect->bottom; RECT WindowRect; float fDepthScale; int iNewTranslationInc = (rand() % 10) + 2; float fNewRotationInc = (float) 0.01 * ((rand() % 30) + 2); WindowRect.left = - (WindowRect.right = pWindowRect->right >> 1); WindowRect.top = - (WindowRect.bottom = pWindowRect->bottom >> 1); // // Initiailize the bounding rectangle with max/min vals // pSCI->rcCubeBoundary.left = pSCI->rcCubeBoundary.top = 100000; // big positive value pSCI->rcCubeBoundary.right = pSCI->rcCubeBoundary.bottom = -100000; // small negative value // // First scale, then rotate, then translate each vertex. // Keep track of the maximum & minimum values bounding the // vertices in the x,y plane for use later in bounds checking. // // Note: we don't bother computing z values after the scale, // as they are only really necessary for the rotation. If we // were doing real bounds checking we'd need it, but this code // simply uses the pSCI->iCurrentZTranslation to determine // the z-boundaries. // for (i = 0; i < NUMVERTICES; i++) { LONG tempX; // // Copy the static vertices into a temp array // gXformedVertices[i] = gNormalizedVertices[i]; // // The scale... // gXformedVertices[i].x *= lScaleFactor; gXformedVertices[i].y *= lScaleFactor; gXformedVertices[i].z *= lScaleFactor; // // The rotation... // ComputeRotationTransformation (pSCI->fCurrentXRotation, pSCI->fCurrentYRotation, pSCI->fCurrentZRotation); tempX = (LONG) (gM[0][0] * gXformedVertices[i].x + gM[0][1] * gXformedVertices[i].y + gM[0][2] * gXformedVertices[i].z); gXformedVertices[i].y = (LONG) (gM[1][0] * gXformedVertices[i].x + gM[1][1] * gXformedVertices[i].y + gM[1][2] * gXformedVertices[i].z); gXformedVertices[i].x = tempX; // // The translation... // gXformedVertices[i].x += pSCI->iCurrentXTranslation; gXformedVertices[i].y += pSCI->iCurrentYTranslation; // // Check if we have new max or min vals // if (pSCI->rcCubeBoundary.left > gXformedVertices[i].x) pSCI->rcCubeBoundary.left = gXformedVertices[i].x; if (pSCI->rcCubeBoundary.right < gXformedVertices[i].x) pSCI->rcCubeBoundary.right = gXformedVertices[i].x; if (pSCI->rcCubeBoundary.top > gXformedVertices[i].y) pSCI->rcCubeBoundary.top = gXformedVertices[i].y; if (pSCI->rcCubeBoundary.bottom < gXformedVertices[i].y) pSCI->rcCubeBoundary.bottom = gXformedVertices[i].y; } // // Now for some bounds checking, change translation & rotation increments // if we hit a "wall". Also so the gbHitBoundary flag so we remember // to flash the cube when we draw it. // if (pSCI->rcCubeBoundary.left < WindowRect.left) { pSCI->iCurrentXTranslationInc = iNewTranslationInc; pSCI->fCurrentZRotationInc = fNewRotationInc; } else if (pSCI->rcCubeBoundary.right > WindowRect.right) { pSCI->iCurrentXTranslationInc = -iNewTranslationInc; pSCI->fCurrentZRotationInc = -fNewRotationInc; } if (pSCI->rcCubeBoundary.top < WindowRect.top) { pSCI->iCurrentYTranslationInc = iNewTranslationInc; pSCI->fCurrentXRotationInc = fNewRotationInc; } else if (pSCI->rcCubeBoundary.bottom > WindowRect.bottom) { pSCI->iCurrentYTranslationInc = -iNewTranslationInc; pSCI->fCurrentXRotationInc = -fNewRotationInc; } if (pSCI->iCurrentZTranslation < (int) lScaleFactor<<1) { pSCI->iCurrentZTranslationInc = iNewTranslationInc; pSCI->fCurrentYRotationInc = fNewRotationInc; } else if (pSCI->iCurrentZTranslation > (iWindowDepth - (int) lScaleFactor)) { pSCI->iCurrentZTranslationInc = -iNewTranslationInc; pSCI->fCurrentYRotationInc = -fNewRotationInc; } // // Now a kludgy scale based on depth (iCurrentZTranslation) of the center // point of the polyhedron // fDepthScale = ((float) iWindowDepth) / ((float) (iWindowDepth + pSCI->iCurrentZTranslation)); pSCI->rcCubeBoundary.left = (LONG)(fDepthScale* pSCI->rcCubeBoundary.left ); pSCI->rcCubeBoundary.right = (LONG)(fDepthScale* pSCI->rcCubeBoundary.right ); pSCI->rcCubeBoundary.top = (LONG)(fDepthScale* pSCI->rcCubeBoundary.top ); pSCI->rcCubeBoundary.bottom= (LONG)(fDepthScale* pSCI->rcCubeBoundary.bottom); for (i = 0; i < NUMVERTICES; i++) { gXformedVertices[i].x = (LONG) (fDepthScale * gXformedVertices[i].x); gXformedVertices[i].y = (LONG) (fDepthScale * gXformedVertices[i].y); } // // If currently in motion then increment the current rotation & tranlation // if (IN_MOTION(hwnd)) { pSCI->fCurrentXRotation += pSCI->fCurrentXRotationInc; pSCI->fCurrentYRotation += pSCI->fCurrentYRotationInc; pSCI->fCurrentZRotation += pSCI->fCurrentZRotationInc; pSCI->iCurrentXTranslation += pSCI->iCurrentXTranslationInc; pSCI->iCurrentYTranslation += pSCI->iCurrentYTranslationInc; pSCI->iCurrentZTranslation += pSCI->iCurrentZTranslationInc; } // // Up to this point all coordinates are relative to a window whose // center is at (0,0). Now we'll translate appropriately... // pSCI->rcCubeBoundary.left += pWindowRect->right >> 1; pSCI->rcCubeBoundary.right += pWindowRect->right >> 1; pSCI->rcCubeBoundary.top += pWindowRect->bottom >> 1; pSCI->rcCubeBoundary.bottom += pWindowRect->bottom >> 1; for (i = 0; i < NUMVERTICES; i++) { gXformedVertices[i].x += pWindowRect->right >> 1; gXformedVertices[i].y += pWindowRect->bottom >> 1; } // // Since FillRect's are inclusive-exclusive (there'll be leftovers // from the last cube we drew otherwise)... // pSCI->rcCubeBoundary.right++; pSCI->rcCubeBoundary.bottom++; // // Finally, adjust the rcCubeBoundary such that it fits entirely within // the acutal control window. The reason for this is that when calling // InvalidateRect from SpincubeWndProc\case_WM_TIMER we may get // a different PAINSTRUCT.rcPaint (since InvalidateRect clips the passed // in rect to the window bounds) and our abouve test to memcmp() will // fail. // if (pSCI->rcCubeBoundary.left < 0) pSCI->rcCubeBoundary.left = 0; if (pSCI->rcCubeBoundary.top < 0) pSCI->rcCubeBoundary.top = 0; if (pSCI->rcCubeBoundary.right > pWindowRect->right) pSCI->rcCubeBoundary.right = pWindowRect->right; if (pSCI->rcCubeBoundary.bottom > pWindowRect->bottom) pSCI->rcCubeBoundary.bottom = pWindowRect->bottom; } /******************************************************************************\ * * FUNCTION: ComputeRotationTransformation * * INPUTS: fRotationX - Angle to rotate about X axis. * fRotationY - Angle to rotate about Y axis. * fRotationZ - Angle to rotate about Z axis. * * COMMENTS: Computes a 3x2 tranformation matrix which rotates about * the Z axis, the Y axis, and the X axis, respectively. * \******************************************************************************/ void ComputeRotationTransformation (float fRotationX, float fRotationY, float fRotationZ) { float sinX, cosX, sinY, cosY, sinZ, cosZ; sinX = (float) sin ((double) fRotationX); cosX = (float) cos ((double) fRotationX); sinY = (float) sin ((double) fRotationY); cosY = (float) cos ((double) fRotationY); sinZ = (float) sin ((double) fRotationZ); cosZ = (float) cos ((double) fRotationZ); gM[0][0] = cosY*cosZ; gM[0][1] = -cosY*sinZ; gM[0][2] = sinY; gM[1][0] = sinX*sinY*cosZ + cosX*sinZ; gM[1][1] = -sinX*sinY*sinZ + cosX*cosZ; gM[1][2] = -sinX*cosY; }

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