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746 lines
31 KiB
746 lines
31 KiB
<!DOCTYPE html PUBLIC "-//W3C//DTD HTML 4.01 Transitional//EN">
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<html>
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<head>
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<meta content="text/html; charset=ISO-8859-1" http-equiv="content-type">
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<title>KSpread Development Notes</title>
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</head>
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<body>
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<h1>KSpread Development Notes</h1>
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<p>Maintainer: Ariya Hidayat (<a href="mailto:ariya@kde.org">ariya@kde.org</a>)</p>
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<p>Some portions by Tomas Mecir (<a href="mailto: mecirt@gmail.com">mecirt@gmail.com</a>)</p>
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<p>Revision: September 2004.</p>
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<h2>Introduction</h2>
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<p>This document contains information about internal structure of KSpread
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as well as some notes of upcoming redesign. The sources for this document
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are mainly the discussions which take place in koffice-devel mailing-list
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and the source code itself.</p>
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<h2>Document/View Architecture</h2>
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<p>tqStatus: IN PROGRESS.</p>
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<p>MVC (Model/View/Controller) means that the application consists of three
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big parts, the <i>Model</i> which holds the data structure and objects,
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the <i>View</i> which shows the model to the user and the <i>Controller</i>
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which handles user inputs and changes the model accordingly. Like other
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office applications, KSpread uses the Document/View architecture, a slightly
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different variant of MVC where the View and Controller are put together
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as one part.</p>
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<p>In order of its complexity scale, KSpread code has to be well separated,
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i.e. the <i>Document</i> and the <i>View</i>. We may also call them as
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<i>back-end</i> and <i>front-end</i> respectively. Right now part of which
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should belong to the Document sometimes has access to the View. For example,
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a cell stores information about its metrics in pixels (which is zoom dependent),
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knows whether it is visible to the user or not (which is view dependent), etc.
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This needs to be changed.</p>
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<p>One easy way to decide whether some stuff or relationship must really really
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alienated in the Document is to imagine that somebody wants to create another
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View (front-end) to the Document object model (back-end) that is being worked
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on. Say, one decent guy would like to copy the look-and-feel of classic Lotus
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1-2-3 (for whatever reason we are not really interested in here); so basically
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to some extent he can take most part of the KSpread back-end and glue a new
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user interface around the code.</p>
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<h2>Dependency Handling</h2>
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<p>tqStatus: IN PROGRESS.</p>
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<p>When a cell holds a formula, then it is likely that it depends on other
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cell(s) for calculating the result. For example, if cell A11 has the formula
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"=SUM(A1:A10)", this means that values in cells A1, A2, A3, until
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A10 must be correctly calculated first before the sum can be obtained for
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cell A11. This is called <i>dependency</i>.</p>
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<p>As for now, KSpread tries to manage dependency by storing the dependent
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cells or ranges in the cell itself. This is not too efficient. If a cell
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is very simple, i.e. stored only value, not formula, such scheme will just
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waste a couple of bytes of pointers for the dependency data structure.
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It is much more wiser to simply create one <i>dependency manager</i> for each
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worksheet; it should be responsible for maintaining and handling cell
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dependencies for that sheet. Also KSpread always stores ranges which depend
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on one particular cell and ranges whose one of its dependent is that cell
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(and these are all in the cell structure itself). This is not necessary as
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that information is redundant. The dependency manager should be able to handle
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both cases.</p>
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<p>Let us have a look at this simple example:</p>
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<table cellspacing="0" cellpadding="3" border="1">
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<tr>
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<td align="center"> </td>
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<td align="center">A</td>
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<td align="center">B</td>
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<td align="center">C</td>
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<td align="center">D</td>
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</tr>
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<tr>
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<td align="center">1</td>
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<td align="right">14</td>
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<td align="right">36</td>
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<td align="right"> </td>
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<td align="right"> </td>
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</tr>
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<tr>
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<td align="center">2</td>
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<td align="right">3</td>
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<td align="right"> </td>
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<td align="right"> </td>
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<td align="right"> </td>
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</tr>
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<tr>
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<td align="center">3</td>
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<td align="right">77</td>
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<td align="right"> </td>
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<td align="right"> </td>
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<td align="right"> </td>
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</tr>
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<tr>
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<td align="center">4</td>
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<td align="right">=SUM(<b>A1:A3</b>)</td>
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<td align="right">=A4+SUM(<b>B1:B3</b>)</td>
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<td align="right">=100*<b>B4</b></td>
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<td align="right"> </td>
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</tr>
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</table>
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<p>Such sheet should produce dependencies like:</p>
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<table cellspacing="0" cellpadding="3" border="1">
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<tr>
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<td><b>Reference</b></td>
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<td><b>Dependent(s)</b></td>
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</tr>
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<tr>
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<td>A4</td>
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<td>A1:A3</td>
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</tr>
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<tr>
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<td>B4</td>
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<td>A4 and B1:B3</td>
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</tr>
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<tr>
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<td>C4</td>
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<td>B4</td>
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</tr>
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</table>
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<p>When we want to recalculate cell B4, from the dependencies shown above we
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may know that first we need to know values of cell A4 and range B1:B3. Further on,
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cell A4 needs to know values of cells in range A1:A3. Therefore, <i>given one reference
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cell</i> (e.g. B4), the dependency manager must be able to <i>return all
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dependents, cells and/or ranges</i> (e.g. A4, B1:B3). Do we need to go
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recursively when searching for dependencies? That really depends on the
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implementation, but it is not a big problem, though.</p>
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<p>In another case, say the user has changed cell A3 so we need to update the
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calculation. We should not recalculate the whole sheet because it wastes time.
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We just need to recalculate cells that depend on A3, in this case A4, B4 and C4.
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So the dependency manager has another responsibility: <i>given a cell</i>
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it should <i>find all cells and/or ranges which depend on that particular
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cell</i>. It is a matter of iterating over all dependencies and checking
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whether the cell is within the dependent(s) and returning the reference cell.
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In this example, cell A3 is in the range A1:A3, a dependent range of cell A4.
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Hence, we just return A4. Recursive or not, we can either continue finding
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dependents of A4 or just stop here.</p>
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<p>Note also that dependency manager should not store cell pointers, but rather
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only the location of the cell (i.e. the sheet that owns the cell, row number and
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column number). This is because on some cases the dependent cell may not exist
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yet. As illustrated in the example, dependents of cell B4 are A4, B1, B2 and B3
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but here cells B2 and B3 are still empty. Of course, when we just want to
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know which cells we need to recalculate for one reference cell, the dependency
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manager is allowed to return only non-empty cells (e.g. A4 and B1 in our case)
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as empty cells have no effect and will not be recalculated anyway.</p>
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<p>By the same manner, dependency manager can also held responsible when
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chart comes into play. Any charts placed in the sheet (that are actually KChart
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parts) depend on some values of the cells. An action by the user to changing
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those cells, directly or indirectly, should trigger the update of the respective
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charts.</p>
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<p>Inter-sheet dependencies can be well handled if we store the owner of
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each dependent. This is not shown yet in the explanation above to avoid
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unnecessary complication. But let have one example now: if Sheet2!A1 is
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"=SUM(Sheet1!A1:A10)" then changing Sheet1!A1 (the dependent)
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means updating Sheet2!A1 (the reference). Of course during recalculation we
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must take care that all sheets in the document must be processed, even though
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only one single cell in one sheet has been changed.</p>
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<p>Implementation-wise, there will be one instance of the dependency manager
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for each sheet. This class will fully manage all dependencies and trigger cell
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recalculation. An important part of this concept is this: The cell itself knows
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<em>nothing</em> about dependencies, and it doesn't care about them either.
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The cell will just inform about the fact, that its value has been changed,
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and the dependency manager will do the rest. In addition, this gives us
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recursive dependency calculation at almost no cost.</p>
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<h2>Manipulators</h2>
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<p>tqStatus: PLANNED.</p>
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<p>Currently, every operation on a cell or on a range of cells is quite complex.
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You need to ensure correct tqrepainting, recalculation, iterate on a range and so on.</p>
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<p>To address this issue, manipulators shall be implemented. A manipulator will
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implement one operation (formatting change, sequence fill, ..., ...).</p>
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<p>Basically, usage of a manipulator should look like this:</p>
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<p><pre>
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Manipulator *manip = manipulatorManager::self()->getManip ("seqfill");
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manip->setArgument ("type", 1);
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... (more setArgument's)
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manip->exec (selection);
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</pre></p>
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<p>That's all...</p>
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<p>What concerns manipulator implementation, you'll derive from the base
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manipulator and reimplement constructor and methods initialize()
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(called just before the operation starts), processCell(), and maybe
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done(). The constructor or initialize() would set some properties for
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the cell-walking algorithm, and then it won't care about it anymore.
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The base class will walk the range and call processCell() for each
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cell, possibly creating it if it doesn't exist (if the manipulator
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wants so).There will also be some methods that can be used to process
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the whole range or row/column at once, if the manipulator wants to do so
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(useful for, say, formatting manipulators that will be able to set attributes
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of a whole range or row/col, in accordance with thoughts about format storage
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below.</p>
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<p>In addition, the manipulator can implement the undo/redo functionality
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- the base manipulator will provide some common stuff needed to
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accomplish this.</p>
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<h2>Selection handling</h2>
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<p>tqStatus: PLANNED</p>
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<p>The selection shall be an instance of some RangeList class,
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or however we want to call it - this will contain a list of
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cells/ranges/rows/whatever - like current selection, but will contain
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more entries. This will allow easy implementation of CTRL-selections and so,
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because thanks to manipulators, each operation will automatically support these.</p>
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<h2>Repaint Triggering</h2>
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<p>tqStatus: PLANNED</p>
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<p>As mentioned above, the interface between the core and the GUI needs to be kept
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at minimum. Also, the number of tqrepaints needs to be as low as possible, and tqrepaints
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should be groupped whenever possible. To achieve all this, the following approach
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can be used:</p>
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<p>When a cell is changed, it calls some method in KSpread::Sheet - valueChanged()
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or formattingChanged(). These methods then trigger everything necessary, like
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a call to the painting routine or dependency calculation.</p>
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<p>This simple system would work on itself, but it would be slow. If you do
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a sequence fill on A1:A1000 and you have a SUM(A1:A1000) somewhere, why would
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you want to compute that SUM 1000 times, when you can simply compute it after
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the sequence fill has been finished? Hence, the sheet will offer some more
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methods - disableUpdates(), enableUpdates(), rangeListChanged() and
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rangeListFormattingChanged(). All these will be used (solely?) by manipulators,
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preferably by the base manipulator class, so that we don't have to call these
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functions in each operation. After a call to disableUpdates(), there will
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be no tqrepainting and no dependency calculation. Note that a call to
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enableUpdates() won't cause any tqrepaints either, as the sheet cannot remember
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all the calls (due to loss of range information). Hence, the base manipulator
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class needs to call the correct rangeList*Changed method to trigger an
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update in an effective way. The base manipulator needs to be configurable by
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the manipulators that derive from it, so that it knows whether it changed
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cell's content or formatting.</p>
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<h2>Formula Engine</h2>
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<p>tqStatus: FINISHED.</p>
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<p>This formula engine is just an expression evaluator. To offer better
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performance, the expression is first compiled into byte codes which will
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be executed later by a virtual machine.</p>
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<p>Before compilation, the expression is separated into pieces, called tokens.
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This step, which is also known as lexical analysis, takes places at once
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and will produce sequence of tokens. They are however not stored and used only
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for the purpose of the subsequent step.
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Tokens are supplied to the parser, also known as syntax analyzer. In this
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design, the parser is also a code generator. It involve the generation
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of byte codes which represents the expression.
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Evaluating the formula expression is now basically running the virtual
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machine to execute compiled byte codes. No more scanning or parsing
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are performed during evaluation, this saves time a lot.</p>
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<p>The virtual machine itself (and of course the byte codes) are designed to be
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as simple as possible. This is supposed to be stack-based, i.e. the virtual
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machine has an execution stack of values which would be manipulated
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as each byte code is processed. Beside the stack, there will be a list of
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constant (sometimes also called as "constants pool") to hold Boolean,
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integer, floating-point or string values. When a certain byte code needs
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a constant for the operand, an index is specified which should be used
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to look up the constant in the constants pool.</p>
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<p>There are only few byte code, sufficient enough to perform calculation.
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Yes, this is really minimalist but yet does the job fairly well.
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The following provides brief description for each type of bytecode.</p>
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<blockquote>
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<p><i>Nop</i> means no operation.</p>
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<p><i>Load</i> means loads a constant and push it to the stack. The constant can
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be found at constant pools, at position by 'index', it could be a Boolean,
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integer, floating-point or string value.</p>
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<p><i>Ref</i> means gets a value from a reference. Member variable 'index' will
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refers to a string value in the constant pools, i.e. the name of the reference.
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Typically the reference is either a cell (e.g. A1), range of cells (A1:B10)
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or possibly function name. Example: expression A2+B2 will be compiled as:<br>
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Constants:<br>
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#0: "A2"<br>
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#1: "B2"<br>
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Codes:<br>
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Ref #0<br>
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Ref #1<br>
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Add
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</p>
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<p><i>Function</i>.
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Example: expression "sin(x)" will be compiled as:<br>
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Constants:<br>
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#0: "sin"<br>
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#1: "x"<br>
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Codes:<br>
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Ref #0<br>
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Ref #1<br>
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Function 1
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</p>
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<p><i>Neg</i> is a unary operator, a value is popped from stack and negated and then
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pushed back to the stack. If it is not number (Boolean or string), it
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will be converted first.</p>
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<p><i>Add, Sub, Mul, Div and Pow</i> are binary operators, two values are popped from
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stack and processed (added, subtracted, multiplied, divided, or power) and
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the result is pushed to the stack.</p>
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<p><i>Concat</i> is string operation, two values are popped from stack (and converted
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to string if they are not string values), concatenated, and the result is
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pushed to the stack.</p>
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<p><i>Not</i> is a logical operation, a value is popped from stack and its Boolean
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not is pushed into the stack. When it is not Boolean value, there will be
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a cast.</p>
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<p><i>Equal, Less, and Greater</i> are comparison operators, two values are
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popped from stack and compared appropriately. The result, which is a Boolean
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value, is pushed into the stack. To simplify, there no "not equal"
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comparison because it can be regarded as "equal" followed by
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"not" byte codes. Same goes for "less than or equal to" and
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"greater than or equal to".</p>
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</blockquote>
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<p>The expression scanner is based on finite state acceptor. The state denotes
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the position of cursor, e.g. inside a cell token, inside an identifier, etc.
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State transition is following by emitting the associated token to the
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result buffer. Rather than showing the state diagrams here, it is much more
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convenience and less complicated to browse the scanner source code and try
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to follow its algorithm from there.</p>
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<p>The parser is designed using one of bottom-up parsing technique, namely
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based on Polish notation. Instead of ordering the tokens in suffix Polish
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form, the parser (which is also the code generator) simply outputs
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byte codes. In its operation, the parser requires the knowledge of operator
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precedence to correctly translate untqparenthesized infix expression and
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thus requires the use of a syntax stack.</p>
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<p>The parser algorithm is given as follows:</p>
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<blockquote>
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Repeat the following steps:<br>
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Step 1: Get next token<br>
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Step 2: If it is an identifier<br>
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- push it to syntax stack<br>
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- generated "Ref"<br>
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Step 3: If it is a Boolean, integer, float or string value<br>
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- push it to syntax stack<br>
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- generated "Load"<br>
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Step 4: If it is an operator<br>
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- check for reduce rules<br>
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<br>
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- when no more rules applies, push token to the syntax stack<br>
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</blockquote>
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<p>The reduce rules are:</p>
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<p>Rule A: <i>function argument</i>:
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if token is semicolon or right tqparenthesis,
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if syntax stack looks as:
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<ul type="square">
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<li>non-operator <--- top</li>
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<li>operator ;</li>
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<li>non-operator</li>
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<li>operator (</li>
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<li>identifier</li>
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</ul>
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then reduce to
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<ul type="circle">
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<li>non operator</li>
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<li>operator (</li>
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<li>identifier</li>
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<li>increase number of function arguments</li>
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</ul>
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</p>
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<p>Rule B: last function argument<br>
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if syntax stack looks as:<br>
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<ul type="square">
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<li>operator )</li>
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<li>non-operator</li>
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<li>operator (</li>
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<li>identifier</li>
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</ul>
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|
then reduce to:<br>
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<ul type="circle">
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<li>non-operator</li>
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<li>generated "Function" + number of function arguments</li>
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</ul>
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</p>
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<p>Rule C: function without argument<br>
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if syntax stack looks as:<br>
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<ul type="square">
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<li>operator )</li>
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<li>operator (</li>
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<li>identifier</li>
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</ul>
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then reduce to:<br>
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<ul type="circle">
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<li>non-operator (dummy)</li>
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</ul>
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</p>
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<p>Rule D: tqparenthesis removal<br>
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if syntax stack looks as:<br>
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<ul type="square">
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<li>operator (</li>
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<li>non-operator</li>
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<li>operator )</li>
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</ul>
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then reduce to:<br>
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<ul type="circle">
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<li>non-operator</li>
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</ul>
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</p>
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<p>Rule E: binary operator<br>
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if syntax stack looks as:<br>
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<ul type="square">
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<li>non-operator</li>
|
|
<li>binary operator</li>
|
|
<li>non-operator</li>
|
|
<li>and if the precedence of the binary operator in the syntax stack
|
|
is greater or equals to the precedence of token</li>
|
|
</ul>
|
|
then reduce to:<br>
|
|
<ul type="circle">
|
|
<li>non-operator</li>
|
|
<li>and generated appropriate byte code for the binary operator</li>
|
|
</ul>
|
|
</p>
|
|
|
|
<p>Rule F: unary operator<br>
|
|
if syntax stack looks as:<br>
|
|
<ul type="square">
|
|
<li>non-operator</li>
|
|
<li>unary operator</li>
|
|
<li>operator</li>
|
|
</ul>
|
|
then reduce to:<br>
|
|
<ul type="circle">
|
|
<li>operator</li>
|
|
<li>and generated "Neg" if unary operator is '-'</li>
|
|
</ul>
|
|
</p>
|
|
|
|
<p>Percent operator is a special case and not handled the above mentioned rule.
|
|
When the parser finds the percent operator, it checks whether there's a non-operator
|
|
token right before the percent. If yes, then the following code is generated:
|
|
<tt>load 0.01</tt> followed by <tt>multiply</tt>.</p>
|
|
|
|
<h2>Value</h2>
|
|
|
|
<p>tqStatus: FINISHED.<br>
|
|
</p>
|
|
|
|
<p>to be written.</p>
|
|
|
|
<h2>Commands Based on KCommand<br>
|
|
</h2>
|
|
|
|
<p>tqStatus: IN PROGRESS.</p>
|
|
|
|
<p>Until lately, to implement undo and redo, KSpread creates corresponding
|
|
KSpreadUndo classes for each action and runs them when the user undoes
|
|
those actions. KSpreadUndo also has redo function whose job is to redo
|
|
again the action after being undone.</p>
|
|
|
|
<p>All this needs to be converted to manipulators - these will be KCommand,
|
|
hence we should be able to undo/redo every operation (provided that the
|
|
corresponding manipulator provides methods to store/recall the undo information).</p>
|
|
|
|
<h2>Cell Storage</h2>
|
|
<p>tqStatus: PLANNED.</p>
|
|
|
|
<p>Cells are grouped together, and then hashed.</p>
|
|
|
|
<h2>Format Storage</h2>
|
|
<p>tqStatus: PLANNED.</p>
|
|
|
|
<p>Formatting specifies how a cell should look like. It involves font
|
|
attributes like bold or italics, vertical and horizontal tqalignment,
|
|
rotation angle, shading, background color and so on. Each cell can have
|
|
its own format, but bear also in mind that a whole row or column format
|
|
should also apply.</p>
|
|
|
|
<p>Current way of storing formatting information is rather inefficient:
|
|
pack it together inside the cell. The reason is because most of cells
|
|
are either very plain (no formatting) and/or only have partial attribute
|
|
(e.g. only marked as bold, no font family or color is specified).
|
|
Therefore the approximately 20 bytes used to hold formatting information
|
|
are quite a waste of memory. Even worse, this requires that the cell
|
|
must exist even if it is not in use. As illustration, imagine a worksheet
|
|
where within range A1:B20 only 5 cells are not empty. When the user
|
|
selects this range and changes the background color to yellow, then
|
|
those 5 cells must store this information in their data structure but
|
|
how about the other 35 cells? Since the formatting is attached to the cell,
|
|
there is no choice but to create them. Doing this, just for the sake of
|
|
storing format, is actually not really good.</p>
|
|
|
|
<p>A new way to store formatting information is proposed below.</p>
|
|
|
|
<p>For each type of format a user can use, we have the corresponding
|
|
<i>formatting piece</i>, for example "bold on", "bold off",
|
|
"font Arial", "left-border 1 px", etc. Whenever the user
|
|
applies formatting to a range (could also be a whole column, row, or worksheet),
|
|
we save appropriate respective formatting piece in a stack. Say the user has
|
|
marked column B as bold, row 2 as italics, and set range A1:C5 with
|
|
yellow background color. Our formatting stack would look like:
|
|
</p>
|
|
|
|
<table cellspacing="0" cellpadding="3" border="1">
|
|
<tr>
|
|
<td><b>Range</b></td>
|
|
<td><b>Formatting Piece</b></td>
|
|
</tr>
|
|
<tr>
|
|
<td>Column B</td>
|
|
<td>Bold on</td>
|
|
</tr>
|
|
<tr>
|
|
<td>Row 2</td>
|
|
<td>Italics on</td>
|
|
</tr>
|
|
<tr>
|
|
<td>A1:C5</td>
|
|
<td>Yellow background</td>
|
|
</tr>
|
|
</table>
|
|
|
|
<p>Now let try to figure out the overall format of cell B2. From the first
|
|
we know it should be bold, from the second it should be italics, and last
|
|
it should have yellow background. This complete format is the one which
|
|
we used to render cell B2 on screen. In similar fashion, we can know that
|
|
cell A1 on the other only specifies the yellow background, because the first
|
|
and second pieces do not apply there.</p>
|
|
|
|
<p>Another possible way to see the format storage is by using 3-D perspective.
|
|
For each formatting piece, imagine there is a surface which covers the
|
|
formatted range (the xy-plane). The formatting information is simply attached
|
|
to the surface (say, as surface attribute). Every surface is stacked together,
|
|
its depth (the z-axis) denotes the sequence, i.e. the first surface is the
|
|
deepest. For the example above, we can view the pieces as one surface specifies
|
|
"bold on" which is a vertical of column B, one surface specifies
|
|
"italics on" which is a horizontal band of row 2 and one last surface
|
|
which specifies "yellow background" stretched in the range A1:C5.
|
|
How to find complete format for A2? This is now a matter of surface
|
|
determination. Traversing in the direction of z-axis from B2 reveals
|
|
that we hit the last and second surfaces only; thereby we can know the complete
|
|
format is "italics, yellow background".</p>
|
|
|
|
<p>It is clear that a format storage corresponds to one sheet only. For each
|
|
sheet, there should be one format storage. Cells can still have accessors to
|
|
its formatting information, these simply become wrapper for proper calls to the
|
|
format storage. Since each formatting piece holds information about the applied
|
|
range, we must take care that the formatting storage is correctly updated
|
|
whenever cells, rows or columns are inserted and deleted.</p>
|
|
|
|
<p>In order to avoid low performance, we must use a smart way to iterate over
|
|
all formatting pieces whenever we want to find out complete format for given
|
|
cell(s). When the sheet gets very complex, it is likely that we will have
|
|
many many formatting pieces that are not even overlap. This means, when we
|
|
need formatting of cell A1, it is no use to check formatting pieces of range
|
|
Z1:Z10 or A100:B100 which do not include cell A1 and are even very far from A1.
|
|
One possible solution is to arrange the formatting pieces in a quad-tree.
|
|
Because one piece can cover a very large area, it is possible that it will
|
|
be in more than one leaf in the quad-tree. <i>Details on the possible use of
|
|
quad-tree or other methods should be explored further more</i>.</p>
|
|
|
|
<h2>Default Toolbars</h2>
|
|
<p>tqStatus: IN PROGRESS.</p>
|
|
|
|
<p>Relevant mailing-list threads:</p>
|
|
|
|
<ul>
|
|
<li><a href="http://lists.kde.org/?l=kde-usability&m=110751297906231&w=2">
|
|
http://lists.kde.org/?l=kde-usability&m=110751297906231&w=2</a></li>
|
|
<li><a href="http://lists.kde.org/?l=koffice-devel&m=110723903332496&w=2">
|
|
http://lists.kde.org/?l=koffice-devel&m=110723903332496&w=2</a></li>
|
|
</ul>
|
|
|
|
<p>Toolbars are utilized to place most frequently used actions. It is
|
|
important to present the user with default toolbars which make
|
|
sense, i.e. they do not contain unnecessary buttons. In-depth usability
|
|
analysis and/or further discussions are needed to make decision which
|
|
buttons need to be in the toolbar and which don't.</p>
|
|
|
|
<p>For reference, here is a list of default shown toolbars in
|
|
some spreadsheet applications:</p>
|
|
|
|
<p><b>Microsoft Excel 2002</b>:</p>
|
|
|
|
<ul>
|
|
<li><em>Standard toolbar</em>: New, Open, Save, Search, Print, Print Preview,
|
|
Spelling, Cut, Copy, Paste, Format Painter, Undo, Redo, Insert Hyperlink,
|
|
Autosum, Sort Ascending, Sort Descending, Chart Wizard, Drawing, Zoom, Help</li>
|
|
<li><em>Formating toolbar:</em>: Font, Font Size, Bold, Italic, Align Left,
|
|
Align Center, Align Right, Merge and Center, Format Currency, Format Percent,
|
|
Comma Style, Increase Precision, Decrease Precision, Increase Indent,
|
|
Decrease Indent, Merge Cells, Unmerge Cells, Merge Across, Borders,
|
|
Fill Color, Font Color</li>
|
|
</ul>
|
|
|
|
|
|
<p><b>OpenOffice 2.0</b>:</p>
|
|
|
|
<ul>
|
|
<li><em>Standard toolbar</em>: New, Open, Save, E-mail, Edit, PDF, Print,
|
|
Page Preview, Spellcheck, Cut, Copy, Paste, Format Paintbrush, Undo, Redo,
|
|
Hyperlink, Sort Ascending, Sort Descending, Insert Chart, Navigator, Styles,
|
|
Gallery, Zoom</li>
|
|
<li><em>Format Object toolbar:</em> Font Name, Font Size, Bold, Italic,
|
|
Underline, Font Color, Align Left, Align Center, Align Right, Justified,
|
|
Merge Cells, Format as Currency, Format as Percent, Format Standard,
|
|
Increase Precision, Decrease Precision, Increase Indent, Decrease Indent,
|
|
Borders, Line Style, Line Color, Background Color, Align Top, Align Center
|
|
Vertically, Align Bottom </li>
|
|
</ul>
|
|
|
|
<p><b>Gnumeric 1.4</b>:</p>
|
|
|
|
<ul>
|
|
<li><em>Standard toolbar</em>: New, Open, Save, Print, Print Preview,
|
|
Cut, Copy, Paste, Undo, Redo, Hyperlink, Autosum, Function/Formula,
|
|
Insert Chart, Zoom</li>
|
|
<li><em>Format toolbar:</em> Font Family, Font Size, Bold, Italic,
|
|
Underline, Align Left, Align Center, Align Right, Merge and Center,
|
|
Merge Cells, Split Cell, Format Currency, Format Percent, Thousand Separator,
|
|
Increase Precision, Decrease Precision, Decrease Indent, Increase Indent,
|
|
Borders, Background, Foreground</li>
|
|
</ul>
|
|
|
|
<h2>Test Framework</h2>
|
|
<p>tqStatus: IN PROGRESS.</p>
|
|
|
|
<p>Relevant mailing-list threads:</p>
|
|
|
|
|
|
<ul>
|
|
<li><a href="http://lists.kde.org/?l=kde-cvs&m=109511244721480&w=2">
|
|
http://lists.kde.org/?l=kde-cvs&m=109511244721480&w=2</a></li>
|
|
<li><a href="http://lists.kde.org/?l=koffice-devel&m=109518196922944&w=2">
|
|
http://lists.kde.org/?l=koffice-devel&m=109518196922944&w=2</a></li>
|
|
</ul>
|
|
|
|
<p>It is well known that writing clean and easily understandable module will lead
|
|
to better maintenance. However testing that particular module everytime there is
|
|
a significant change requires considerable amount of time and effort. Since KSpread
|
|
and other applications of its scale consist of hundreds of modules, in this case
|
|
automatic testing of each module will help a lot, not to mention that it might
|
|
catch bug as early as possible.</p>
|
|
|
|
<p>KSpread has a simple test framework to facilitate such kind of test. This can
|
|
be activated using the shortcut <tt>Ctrl+Shift+T</tt>. This test is however
|
|
not accessible via menu, because it is intended to be used only by the developers.
|
|
Ideally, there should be tests for all modules contained in KSpread. It is
|
|
the responsibility of the developer to create the corresponding <tt>tester</tt>
|
|
for the code that he or she is working on. All tests should be kept in
|
|
<tt>koffice/kspread/tests/</tt>.</p>
|
|
|
|
<p>Making a new tester is not difficult. The easiest way is to copy an already
|
|
existing tester and modify it. Basically, it must be a subclass of class Tester
|
|
(see <tt>koffice/kspread/tests/tester.h</tt>). Just reimplement the virtual
|
|
function <tt>run()</tt> and it is ready. In order to make it possible to run
|
|
the new tester, add an instance of the class in TestRunner
|
|
(for details, see <tt>koffice/kspread/tests/testrunner.cc</tt>).</p>
|
|
|
|
<p>A tester must be self-contained, it should not use any test data from
|
|
current document. If necessary, it must create (or hard code) the data by
|
|
itself.</p>
|
|
|
|
<p>Whenever parts of KSpread features are improved or rewritten, it is always
|
|
a good idea to run the related tests to ensure that all the changes do not do
|
|
any harm. However, bear in mind that there is no 100% guarantee that the new
|
|
code is bug-free.</p>
|
|
|
|
<p>Also, if there is a bug which is not caught by the tester (i.e. it does not
|
|
fail the tester, but the bug is confirmed), then the relevant tester must be
|
|
modified to include one or more test cases similar to the offending bug.
|
|
When the bug is finally fixed, from that point the test should always pass all
|
|
test cases.</p>
|
|
|
|
</p>
|
|
|
|
<h2>Coding Style</h2>
|
|
<p>tqStatus: IN PROGRESS.</p>
|
|
|
|
<p>(to be written in details).</p>
|
|
|
|
<p>Write <b>clean code</b>. To be correct is better than to be fast.
|
|
KSpread source code is known to grow very fast in its early days and but later
|
|
on also more difficult to understand.</p>
|
|
|
|
<p>Put comment as documentation for classes and member functions. There is still
|
|
lack of documentation as for now, whoever understands something about the
|
|
classes and functions should write the documentation.</p>
|
|
|
|
<p>In complex source files, list of header includes can be very long. Unless
|
|
there is special reason not do it, try to group them together, i.e. standard
|
|
C/C++ headers come first, followed by TQt headers, and then KDE headers,
|
|
KOffice core/UI headers and application specific headers. For each group,
|
|
sort the header files alphabetically. </p>
|
|
|
|
<p>Write test cases. This will ease further maintenance. See also the section on Test
|
|
Framework above.</p>
|
|
|
|
<p>Do not use the term <i>table</i>. It was incorrectly invented quite likely
|
|
because of the term <i>Tabelle</i> (German, literally means table). The correct
|
|
term is <i>sheet</i> or <i>worksheet</i>. The English version of Microsoft
|
|
uses <i>sheet</i> while the German version uses <i>Tabelle</i>.</p>
|
|
|
|
<p>Use <a href="http://developer.kde.org/documentation/library/kdeqt/kde3arch/devel-binarycompatibility.htm">d-pointer</a> trick (also known pimpl) whenever possible. Such practice will help when later on
|
|
we want to expose the API and need to maintain binary compatibility. But the
|
|
most important thing is to separate the interface and the implementation.
|
|
Furthermore, build time is reduced since modification on the implementation
|
|
would not cause tons of recompile.</p>
|
|
|
|
<p>When creating a new class, use namespace KSpread. Do not use KSpread prefix
|
|
anymore. Example: use <tt>KSpread::Foo</tt> instead of <tt>KSpreadFoo</tt>.
|
|
Also source file name should not contain kspread prefix anymore, i.e.
|
|
<tt>foo.h</tt> and <tt>foo.cc</tt> (but not <tt>kspread_foo.h</tt> and
|
|
<tt>kspread_foo.cc</tt>) for the above example.</p>
|
|
|
|
</body></html>
|