SCORE (software)


SCORE is a scorewriter program, written in FORTRAN for MS-DOS by Stanford University Professor Leland Smith with a reputation for producing very high-quality results. It was widely used in engraving during the 1980s and 1990s and continues to have a small, dedicated following of engravers, many of whom hold the program in high regard due to its ability to position symbols precisely on the page. Several publications set using SCORE have earned Paul Revere and German Musikpresse engraving awards.
WWW Official Site

Program development

Mainframe origins

The first incarnation of SCORE was written by Leland Smith in 1967 as a means of entering music into the MUSIC V sound generating system running on the PDP-10 minicomputers at the Stanford Artificial Intelligence Laboratory.
The core concept of SCORE was to break music into a set of items with parameters that describe their characteristics. In this example of an early SCORE routine the beginnings of the parameter system can be seen:

BUZZ;
P2 RHY/4/2/8//REP 3,2//;
DF 1000.2;
P3 NOTES/P C4/B/C/O B3/C/FINE;
P4 LIT/P3%2/!-52;
P5.2 10,100.4 200,210.2 1,1;
P6 -9999.5;
P7 1000;
P8 FU/1/2//;
END;

As vector graphics terminals became available in the early 1970s, the parametric approach to describing musical information that had been designed for MUSIC V was adapted by Smith into a program he called MSS for printing musical scores.
The graphics plotters used for output were not able to plot curves so MSS did not use music fonts as they are understood today, instead using user-editable symbol libraries based on polygons, and text was generated from an internal character set.
The first printing of a complete musical work set entirely by computer was of Smith's Six Bagatelles for Piano which appeared in December 1971, printed at 100dpi on a CalComp plotter and reduced by a factor of five for printing at 8.5"x11".
Smith's Woodwind Trio was published using this system in 1973 and Richard Swift, reviewing it for Notes, drew attention to the "admirable clarity and ease of reading for performer and score reader, easily equivalent to the finest examples of contemporary music printing by other means. This new process claims the serious attention of commercial music publishers for its fine qualities, not the least of which is ease and cheapness of production."
The first book about music typeset entirely by computer to be published was his Handbook of Harmonic Analysis in 1979, created on the PDP-10 computer at SAIL using the PUB typesetting program in conjunction with MSS. The printing was done at double size on a Varian Data Machines Statos electrostatic plotter and then optically reduced by a factor of two for lithographic printing.
From its creation till 1985, all development of MSS was either done on the PDP-10 computers at Stanford or during residencies at IRCAM in the Pompidou Centre, Paris.

Commercial development

Between 1985 and 1986 MSS was ported to the Tandy 2000 running MS-DOS under its earlier name of SCORE. Since personal computers of the time had limited memory, SCORE versions 1 and 2 were limited to 16 staves, 12,800 vectors, and 800 and 780 items per file, respectively. In order to handle complex or lengthy works, users had to work on small portions of the score at any one time, naming their files sequentially. These were then laid out and tiled together before being sent to the printer. In order to save memory further on graphics operations, notation was displayed in 'stick figure' characters and symbols, which showed exactly the boundaries of the notation but lacked fine detail. There was an option to display the true symbols provided there was enough memory remaining to accommodate them.
SCORE version 1 was released in 1987 by Passport Designs and updated to version 2 in August 1988. A serious inconvenience in version 1 was that the only way of editing text once entered was to alter the ASCII character codes, requiring users to have a character chart handy.
The German music publisher Schott Music began using SCORE in 1988 and their in-house engraving typefaces became the basis for SCORE's symbol library. Version 2 also introduced the use of PostScript Type 1 fonts for page text.
In 1988, Passport Designs sent their programmer Perry Devine to work with Smith to make the program more user-friendly. They also hired professional engraver William Holab to rewrite the manuals, resulting in the release of version 3.0 in 1990. SCORE 3 allowed for 32 staves and 1420 items per file, and a maximum vector limit of 31,000.
The SCORE music publishing system is made up of the main program, SCORE, and these associated utilities:JUST, which aligns and justifies large scores with more than 32 staves per systemPAGE, which handles part extraction, and layout for multiple pages of music simultaneouslySPRINT, which sends typeset pages to PostScript printers or creates an EPS fileDRAW, which draws symbols for inclusion in the main or user-defined libraries
ESCORT and SCOREINPUT were sold separately and allowed MIDI input from a MIDI file and a MIDI keyboard, respectively. SCOREINPUT was created by Paul Nahay, Smith's former colleague on the music theory and composition faculty in the Department of Music at Stanford University. ESCORT was written by Les Music and Dave Bennett of Advanced Management Systems, Inc.
Ties with Passport Designs were severed in 1991, and all subsequent versions were distributed and sold by Smith's company, San Andreas Press.
Version 3.10 was released in 1993 and replaced SPRINT with SCORLAS and SCORDOT, which sent output to laser and dot matrix printers.
Version 3.11 was released in May 1994, and replaced ESCORT and SCOREINPUT with MIDISCOR and MIDISCORWRITE. MIDISCOR and MIDISCORWRITE were written by Stephen Gibson of Ararat Software. SCORE 3.11 was the final increment of version 3 and is still used commercially today as it is considered by some to be the most mature and stable version that was released.
The FinalScore utility was released in 1996, which converted PostScript output from the Finale programme into a standard SCORE file, however this became obsolete when Finale 2004 changed the way in which EPS files were created.
Version 4.0 was released in May 1998, and included automatic lute and guitar tablature systems, MIDI playback, group editing of items, a conditional editor, various user interface improvements relating to file access, and further mouse support. Many changes were introduced to make the program more accessible to new users, often making the program more cumbersome for existing professional users in the process - which is one of the reasons version 3 is still so highly regarded.
The last minor update, version 4.01, was released on October 16, 2001, although a special version called SCORLAP was released in May 2002 which addressed graphics redraw problems arising with some laptops.
WinScore, the Microsoft Windows version, was released to beta in March 2009 as version 5.00. Improvements included increasing the possible number of staves on pages, removing the limits on items and vectors per page, a WYSIWYG interface, use of colour, native MIDI input and playback, extending the number of parameters per item to 36, and integrating all previous SCORE utilities into the main program. WinScore suffered from memory leaks and other bugs which prevented its adoption by many users, and despite officially being released on December 8, 2012, it was still effectively in beta development at the time of its last update to 5.01 on November 1, 2013, six weeks before Smith's death.
The basis of SCORE was written in FORTRAN with all the mouse and graphics routines written in Intel assembly language. WinScore was created using a combination of Visual C++ and 32-bit DEC FORTRAN.

After Smith's death

Following Smith's death on December 17, 2013, both SCORE and WinScore are no longer sold and the website registrations have lapsed. At the beginning of 2021 Adobe Inc. announced that support for Type 1 PostScript fonts would end in January 2023.

Pricing

On release in 1987, SCORE version 1 cost, though by 1988 version 1.2 cost.
Version 2 in 1988 was.
Version 3 in 1991 was, and in 1993 Version 3.10 cost
Version 4 in 1999 was, and WinScore, in 2013, was.
In 1989, ESCORT version 1 sold for.
In 1993, SCOREINPUT cost.
In 1999 it cost to update SCORE from version 3.11 to 4.0.
In 2013 to update to WinScore from version 3 cost, and from version 4,.

Product reviews

Version 1 was announced in the press at the beginning of 1987 with an expected release date of April that year, and a predicted price tag of $500. Its release was noted in the Computer Music Journal issue of winter 1987.
Version 1.1 was reviewed by Computer Music Journal in autumn 1988. DRAW was not yet available, but had been promised. A later reviewer was told by technical support that making the DRAW programme available to users was an afterthought. On-screen help was described as "awkward and unenlightening", but the software "rewards determined effort to climb the learning curve with powerful abilities". "For routine music printing, it is probably more expensive, more complicated, and less accommodating than some of its competitors, but Score is more powerful than any of them."
Writing for Electronic Musician, Carter Scholz found the interface of version 2.0 "opaque and maddening" though concluded SCORE was an "amazing" "power tool" which "sets a new standard" for professionals for whom ease of use would be less important than the results which could be obtained. A math coprocessor was considered essential to prevent the program response being sluggish when handling the floating-point arithmetic for screen operations.
Keyboard's Jim Aikin agreed that a considerable investment of time was required to learn the package. Scholz had three months and admitted he had only "scratched the surface" of its capabilities. Aikin came to similar conclusions, suggesting improvements to the interface and input methods would make it more accessible.
PC Magazine, reviewing SCORE at the end of 1988, concluded that the software was aimed at accomplished musicians who were prepared to put in the time to learn it, and that the design of the program and manual were thorough and clear. Three years later the same magazine described the program as having "ushered in the era of true desktop music publishing" allowing musicians to turn out "engraver-quality printed music of any complexity", but still admitting that it had a "ruthlessly difficult interface", a "confusing amalgam of command line and function keys" which "never fully made the transition from the mainframe computers" where it originated. Editing music once entered was "cumbersome and daunting" and the poor documentation made the program even more inaccessible.
Reviewing version 2.10 in March 1990 for Notes, Garrett Bowles noted that SCORE surpassed any of the other contemporary notation programmes on notational complexity, text handling, part extraction, page layout, and spacing of items on the staff. On-screen help was now "excellent", as were the extensive manuals.
Karl Signell, writing in spring 1991, observed that version 3 had the most "ungraceful, counter-intuitive interface", but noted that it was faster than other programmes as well as producing one of the most professional looking scores.

Program use

Entering music symbolically

Music is usually entered using text codes from a standard ASCII keyboard, and several passes are required to enter all the information. After the page has been set up with appropriate staves, information is entered voice by voice as follows:
For example, to create these two bars of Bach's Fugue in C minor, BWV 847 from Book I of the Well-Tempered Clavier:
To create the staff:
The five passes of data entry:
These show the use of the following text codes - note that is a delimiter and marks the end of each pass:
Pass 1
Pass 2
After pass 2, numbers are displayed above each note to assist with assigning marks, beams and slurs. The image below also illustrates the results of the Show command to display the true vectors of all items, rather than the "stick figure" symbols that are usually used.
Pass 3
Pass 4
'''Pass 5'''

Editing music graphically/numerically

Once the music has been entered using the five-stage input process described above, the musical data is converted by SCORE into the following graphical items and stored as a series of numeric parameters:
CODE
number		Item type
1Notes
2Rests
3Clefs
4Lines and hairpins
5Slurs and tuplets
6Beams and tremolandi
7Trills, ottavas and pedals
8Staves
9Symbol library
10Numbers and rehearsal letters
11User symbol library
12Special shapes
13Invisible dummy item
14Barlines and brackets
15Graphics
16Text
17Key Signatures
18Time Signatures

Examples of the parameters associated with these items:
Name
1NotesStaff No.Horizontal PositionVertical Position Stem Direction / AccidentalNotehead TypeRhythmic DurationStem Length Flags / DotsHorizontal DisplacementArticulationsStaff DisplacementHorizontal Displacement of ArticulationVertical Displacement of ArticulationSize of NoteLedger Line ThicknessOrigin of StemSize of Articulation
4Lines / HairpinsStaff No.Left Horizontal PositionLeft Vertical PositionRight Vertical Position Right Horizontal PositionType of Line Length of Dash / Width of WaveRotation / Space between Dashes / Height of WaveThicknessLeft Bracket / ArrowheadRight Bracket / ArrowheadRotationPartial HairpinVertical Line OffsetsLine End Point OffsetLine End Point OffsetLine End Point Offset
5Slurs / Tuplets / EndingsStaff No.Left Horizontal PositionLeft Vertical PositionRight Vertical PositionRight Horizontal PositionCurvatureType of Slur Flattening FactorCentre PointDashed SlurHalf Slur / Reversed SlurThicknessPartial SlurPartial SlurNo. in MiddleHorizontal Displacement of No.Vertical Displacement of No.
6Beams / TremolandiStaff No.Left Horizontal PositionLeft Vertical Position Right Vertical PositionRight Horizontal PositionStem Direction No. Above Displacement1st Secondary Beam TremolandiLeft Position of 1st SecondaryRight Position of 1st Secondary2nd Secondary BeamLeft Position of 2nd Secondary Right Position of 2nd Secondary Horizontal Position of Number over BeamThicknessSize
10Numbers / Rehearsal LettersStaff No.Horizontal PositionVertical PositionNumber / LetterSizeFontCircle / Box AroundThickness of Number Thickness of Box / CircleHorizontal Size Vertical Size Vertical Position of NumberSpace between DigitsHorizontal Displacement of NumberMake Number JustifiableLetter after NumberExtended Numbers / Letters
14Barlines / BracketsStaff No.Horizontal PositionNo. of Staves ConnectedTypeThicknessHorizontal DisplacementPartial BracketSize of Space Origination PointEnd PointMarker for PAGESpace between Double or Repeat BarsSpace between Dots and Lines of Repeat Bars...Vertical Position of Repeat DotsSpecial Double Bar SpacingsSets Gap in Bar
14Barlines / BracketsStaff No.Horizontal PositionNo. of Staves ConnectedTypeThicknessHorizontal DisplacementPartial BracketSize of Space Origination PointEnd PointSize of Dots with Repeat BarsSpace between Double or Repeat BarsSpace between Dots and Lines of Repeat Bars...Vertical Position of Repeat DotsSpecial Double Bar SpacingsSets Gap in Bar
17Key SignaturesStaff No.Horizontal PositionVertical PositionNo. of AccidentalsClef TypeSpace Between AccidentalsIrregular Key SignaturesIrregular Key SignaturesIrregular Key SignaturesIrregular Key SignaturesIrregular Key SignaturesIrregular Key SignaturesIgnore Lineup and JustifyHorizontal DisplacementIrregular Key SignaturesIrregular Key SignaturesExtended Numbers / Letters

Here then is the numerical representation of the BWV 847 fugue theme example. Each line represents one graphical item as a CODE number and associated numeric parameters. The second number is the staff on which the item belongs, and the third is the horizontal position of the item along the full width of the paper, with 0 representing the left margin, and 200 representing the right margin. The fourth number often contains the vertical position on the staff - the bottom line of the staff is vertical position 3, the bottom space of the staff is 4, and so on.

8 1 0 0 0 200
3 1 1.5
17 1 9.416 0 -3
18 1 19.016 0 4 4
2 1 26.516 0 1 0 0.5
1 1 34.835 8 20 0 0.25
9 1 34.835 -3 54 1 0 0 0 0 0 0 0 0 -5
6 1 34.835 8 7 41.43 22
5 1 34.835 10 10 41.43 1.1093 -1
1 1 41.435 7 23 0 0.25
1 1 47.233 8 10 0 0.5 -1
6 1 47.233 7 5.5 55.55 11
1 1 55.551 5 10 0 0.5 0.5
1 1 64.122 6 20 0 0.5
6 1 64.122 6 7 78.24 21 0 0 11 72.44 78.24
1 1 72.441 8 20 0 0.25 1.33
5 1 72.441 10 10 78.24 1.1092 -1
1 1 78.239 7 20 0 0.25
1 1 84.037 8 20 0 0.5
6 1 84.037 8 9 92.36 21
1 1 92.355 9 20 0 0.5
14 1 100.842 1
1 1 104.174 5 10 0 0.5 3
6 1 104.174 8 8 119.09 11 0 0 11 112.49 119.09
1 1 112.493 8 10 0 0.25
5 1 112.493 6 4 119.09 -1.3092 -1
1 1 119.093 7 13 0 0.25 1
1 1 125.143 8 20 0 0.5
6 1 125.143 8 9 133.46 21
1 1 133.462 9 20 0 0.5
1 1 141.781 4 10 0 0.25
6 1 141.781 4 5 147.58 12
5 1 141.781 2 4 153.38 -1.5185 -1
1 1 147.578 5 10 0 0.25
1 1 153.376 6 10 0 1
1 1 165.476 5 10 0 0.25
6 1 165.476 5 4 171.27 12
5 1 165.476 2 2 171.27 -1.1092 -1
1 1 171.274 4 10 0 0.25
14 1 178.274 1
1 1 181.606 3 10 1 2 0 0 0 14
14 1 200 1 1

Unlike most music typesetting editors, understanding and manipulation of these numerical parameters are expected of SCORE users. To access the numeric parameters of items within SCORE, a user clicks on a graphical element, and a list of the parameters is displayed at the top of the editor - as shown in the first screenshot, where a slur is selected.
SCORE was creative in packing as much information as possible into each numeric parameter. For example, Parameter 5 of CODE 1 is described as "stem direction/accidental" but uses each place value to encode a different piece of information. Note that by SCORE default, only the top note of a chord has a stem, all the other notes are stemless. So a down-stemmed sharp would have a P5 of 22. An up-stemmed flat with a left offset of 2.5 would be 11.25. A stemless natural with a right offset of 3 would be 3.93, and if it were bracketed it would be 103.93.

Left digitFunction
0No brackets
1Bracketed accidental

Middle digitFunction
0No stem
1Stem up
2Stem down

Right digitFunction
0No accidental
1Flat
2Sharp
3Natural
4Double flat
5Double sharp
6Quarter-tone flat
7Three-quarter-tone flat
8Quarter-tone sharp
9Three-quarter-tone sharp

Digits after
decimal point		Function
.000 -.899Displace to left
.9000 -.9999Discard initial 9 and displace to right


Here are selected examples of items from the numeric parameter data of the fugue example:
CODE P2P3
3
Staff No.Horizontal Position
3
1.01.50

The key signature:
CODE P2P3P4P5
17
Staff No.Horizontal PositionVertical PositionNo. of Accidentals
17
1.09.5.00-3.00

The time signature:
CODE P2P3P4P5P6
18
Staff No.Horizontal PositionVertical PositionTop No.Bottom No.
18
1.019.6.004.004.00

The dynamic marking :
CODE P2P3P4P5P6
9
Staff No.Horizontal PositionVertical PositionLibrary No.Horizontal Size
9
1.021.17-2.0054.00*1.00

* See bottom right entry in the SCORE 3 symbol table above.
The rest in the first bar:
CODE P2P3P4P5P6P7
2
Staff No.Horizontal PositionVertical Position Type of RestDots Rhythmic Duration
2
1.026.60.001.00.00.500

The first B natural in the first bar:
CODE P2P3P4P5P6P7P8P9
1
Staff No.Horizontal PositionVertical PositionStem Direction / AccidentalNotehead TypeRhythmic DurationStem LengthFlags / Dots
1
1.032.967.0023.00.00.250.00.00

The second slur in the first bar:
CODE P2P3P4P5P6P7P8
5
Staff No.Left Horizontal PositionLeft Vertical PositionRight Vertical PositionRight Horizontal PositionCurvatureType of Slur
5
1.063.4310.0010.0067.781.118-1.00

The first barline:
CODE P2P3P4
14
Staff No.Horizontal PositionNo. of Staves Connected
14
1.089.541.00

The last note :
CODE P2P3P4P5P6P7P8P9P10P11
1
Staff No.Horizontal PositionVertical PositionStem Direction / AccidentalNotehead TypeRhythmic DurationStem LengthFlags / DotsHorizontal DisplacementArticulations
1
1.0166.183.0010.001.002.000.00.00.0014.00

Editing text

In version 1 PostScript text fonts were not used for printing, only the stick-figure characters used within the programme and an internal version of the Bodoni typeface, and text could only be edited by altering the ASCII codes for each character individually within the CODE16 parameters. Version 2 allowed the use of PostScript Type 1 fonts and provided a more convenient method of editing text, but unfortunately only a subset of the glyphs within the chosen font could be used by SCORE. Different fonts were selected by using an escape sequence at the start of the text. Escape codes _00 to _34 selected the Base 35 fonts of the Adobe PostScript Level 2 font set, and codes _35 to _89 could be assigned by the user. Some characters not available on a standard keyboard were obtained by using another escape sequence, for example:
¡¢£§¤'åÅ«»éôüç æã

To set the text "Fête-Dieu à Séville by Isaac Albéniz" in variants of Times Roman would require the sequence

_02F^^ete-Dieu >>a S<
where
It was only possible to use glyphs other than those already escaped within SCORE by manually editing the font files, re-encoding SCORE's font templates, or editing the final EPS file.

Conditional editing

With version 4, conditional editing was included in the main program. This allowed users to write conditional statements in a language similar to BASIC. Prior to this it had only been possible by using third party utilities: ScorEdit from Ararat Software, and EDITSCOR from Brodhead Music Typography.
For example,
will move all items on all staves which are beyond position 100, 20 steps to the left.
will delete all notes on staves lower than 4 and all rests on staves greater than or equal to 6.
If notes are on a staff above 3 and have tails, or notes are on staff 1 and to the right of position 100, then the notes will be given an accent and an X-shaped notehead.
Some functionality was limited in the implementation, such as nested parentheses being unsupported ), being unable to edit text, being unable to cross-compare and edit different items simultaneously, and being unable to read macros in sequence from a source file. Users wishing to employ these methods had to use the third party utilities described earlier.
WinScore allowed macros to be read in sequence from source files, but did not add any more functions.

Output

Music notation data is saved in a proprietary but open format:
The files are saved in binary format where the first word is the word count for the entire file. The word count is normally a 16-bit integer; however, if the word count exceeds about 31000, then a 32-bit integer is used. Saved files with less than 31000 words can be read back into the earlier versions of SCORE, except, of course, any new features of WinScore will be ignored. Files with greater than 31000 words cannot be read by the earlier versions of SCORE. The files are concluded with a 6-word trailer. The last word is -9999. The next word back is the count of the preceding trailer words. The next word back is the measurement code. The next back is the program version number. The next is the program serial number. The first word of the trailer is currently undefined. After the initial integer word count, the rest of the file consists entirely of 4-byte floating-point words. Each item is defined by a parameter count followed by its given parameters.

Files are usually given the extensions ".mus" or ".pag", though any extension is permitted..
SCORE creates PostScript graphics that can either be sent to a PostScript printer or saved as an Encapsulated PostScript file. For creating publications the EPS graphics can be imported into a desktop publishing program.

Extensions and utilities

There are a number of third party utilities which take advantage of the open file format to extend the programs' functionalities and share data with other notation programs. These are among the most notable:
DeveloperNameDatesVersionPurpose
Thomas BrodheadACCS2002-20132.01Accidentals editor using intelligent kerning, stacking and placement algorithms
Thomas BrodheadAFM2PSC2001-20081.02cAllows character glyphs which would be otherwise unavailable in SCORE to be substituted for existing characters
Thomas BrodheadBEAM1996-20133.05Uses a set of user-editable beam charts to make optimum beam angle and stem length choices, centre tuplet numbers over beams, handle cross-staff beaming, avoid rest collisions with beams, all while taking into account the surrounding musical context
Thomas BrodheadEDITSCOR1996-20133.51Conditional editor, allowing search-and-replace on text, comparison and editing of multiple items simultaneously, and the use of multiple macro files
Thomas BrodheadEPSFONTS2003-20132.19Embeds PostScript Type 1 fonts into SCORE-generated EPS files, removing the need for the fonts to be downloaded to the printer separately
Thomas BrodheadLABELS2003-20133.80Automates the creation of margin labels and margin barlines, converts between French and German score layouts, creates transposed cues and part extraction scores
Thomas BrodheadLJ1999-20131.26Lineup-and-Justify, allows the user to control all aspects of horizontal justification
Thomas BrodheadSEP1999-20101.06Separates voices on a single staff, correctly handling diverging rhythms and voice crossings
Thomas BrodheadSETCOLOR2007-20121.01Simplifies the coloring of items using RGB or CMYK
Thomas BrodheadSETGRAY20041.05Simplifies setting the grey level of items
Thomas BrodheadTRANSPOSE2010-20131.05aTransposes selected notes, correctly taking into account key signatures, accidentals, and other context
Thomas BrodheadVJ1999-20131.19Vertical Justification editor, allowing greater control of how vertical space is allocated
Stephen GibsonScorEdit1996-date3.80GUI-based conditional editor, allowing search-and-replace on text, comparison and editing of multiple items simultaneously, and the use of multiple macro files. Additional routines are provided for editing beam angles from a user-controlled library, removing or restoring unused staves, justification and report generation
Stephen GibsonMidiScorWrite1993-20002.60Transcribes Type 1 MIDI files and NIFF files into a SCORE-readable text file
Stephen GibsonMidiScor1993-20113.01Converts files created in SCORE and WinScore to standard MIDI files
Stephen GibsonFlist1993-20093.5Created lists of files to be processed with SCORLAS etc.
Jan de KloeSIP1992-20227.0.0.178Score Information Package with modules to edit score items, check consistency of notation and layout, verify note duration and time signatures, calculate the cost of a project based on user-controlled rates, convert Sibelius and Finale files to SCORE, import and export from MusicXML, as well as provide a central 'workbench' to manipulate SCORE files using tools provided by other third-party developers
Jan de KloeScoreEngine2007-20225.0.0.40A 32-bit GUI emulation of all the SCORE applications allowing work to be conducted on modern Windows operating systems without using DOSBox
Sergey Lebedev
Vyacheslav Tsypine
Pyotr Trubinov		LASCOR322002-20052.75GUI frontend for SCORLAS which fixes known SCORLAS bugs and allows the user to follow any file-naming scheme they wish
Christoph LübbeSCOREMID1993-19961.1Converts files created in SCORE to standard MIDI files
Jürgen SelkScorBox2011-2021A set of macros for the Macro Express application which allows SCORE to be run within DOSBox with flexibility and customisable menus, macros, and job chains
Thomas Weberseps4id2008-20101.0.4'SCORE EPS for InDesign' - edits SCORE-generated EPS files so they can be handled properly by Adobe InDesign CS3, and also explicitly closes all polygons to avoid cut-outs when EPS files are viewed at high magnifications

Use with modern systems

The MS-DOS versions of SCORE can still be run on modern operating systems through the use of virtual machines, though accommodations need to be made for their age. The most common MS-DOS emulators for SCORE are DOSBox in Windows, or Boxer in macOS.