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COMMENT REDUCE INTERACTIVE LESSON NUMBER 5 David R. Stoutemyer University of Hawaii COMMENT This is lesson 5 of 7 REDUCE lessons. There are at least two good reasons for wanting to save REDUCE expression assignments on secondary storage: 1. So that one can logout, then resume computation at a later time. 2. So that needed storage space can be cleared without irrecoverably losing the values of variables which are not needed in the next expression but will be needed later. Using trivial small expressions, the following sequence illustrates how this could be done: OFF NAT, OUT TEMP, F1 := (F + G)**2, G1 := G*F1, OUT T, CLEAR F1, H1 := H*G1, OUT TEMP, CLEAR G1, H2 := F*H1, CLEAR H1, SHUT TEMP, IN TEMP, F1, ON NAT, F1 . ON NAT yields the natural output style with raised exponents, which is unsuitable for subsequent input. The OUT-statement causes subsequent output to be directed to the file named in the statement, until overridden by a different OUT-statement or until the file is closed by a SHUT-statement. File T is the terminal, and any other name designates a file on secondary storage. Such names must comply with the local file-naming conventions as well as with the REDUCE syntax. If the output is not of lasting importance, I find that including something like "TEMPORARY" or "SCRATCH" in the name helps remind me to delete it later. Successive OUT-statements to the same file will append rather than overwrite output if and only if there is no intervening SHUT- statement for that file. The SHUT-statement also has the effect of an implied OUT T. Note: 1. The generated output is the simplified expression rather than the raw form entered at the terminal. 2. Each output assignment automatically has a dollar-sign appended so that it is legal input and so that (perhaps lengthy) output will not unavoidably be generated at the terminal when the file is read in later. 3. Output cannot be sent simultaneously to 2 or more files. 4. Statements entered at the terminal which do not generate output -- such as declarations, LET rules, and procedure definitions -- do not appear in the secondary storage file. 5. One could get declarations, procedure definitions, rules, etc. written on secondary storage from the terminal by typing statements such as WRITE " ALGEBRAIC PROCEDURE ... ... " . This could serve as a means of generating permanent copies of LET rules, procedures, etc., but it is quite awkward compared with the usual way, which is to generate a file containing the REDUCE program by using a text editor, then load the program by using the IN-statement. If you have refrained from learning a local text editor and the operating- system file-management commands, hesitate no longer. A half dozen of the most basic commands will enable you to produce (and modify!) programs more conveniently than any other method. To keep from confusing the editor from REDUCE, I suggest that your first text-editing exercise be to create an IN file for (re)defining the function FACTORIAL(n). 5. The reason I didn't actually execute the above sequence of statements is that when the input to REDUCE comes from a batch file, both the input and output are sent to the output file, (which is convenient for producing a file containing both the input and output of a demonstration.) Consequently, you would have seen none of the statements between the "OUT TEMP" and "OUT T" as well as between the second "OUT TEMP" and the "SHUT TEMP", until the IN statement was executed. The example is confusing enough without having things scrambled from the order you would type them. To clarify all of this, I encourage you to actually execute the above sequence, with an appropriately chosen file name and using semicolons rather than commas. Afterwards, to return to the lesson, type CONT; PAUSE; COMMENT Suppose you and your colleagues developed or obtained a set of REDUCE files containing supplementary packages such as trigono- metric simplification, Laplace transforms, etc. It would be a waste of time (and perhaps paper) to have these files printed at the terminal every time they were loaded, so this printing can be suppressed by inserting the statement "OFF ECHO" at the beginning of the file, together with the statement "ON ECHO" at the end of the file. The lessons have amply demonstrated the PAUSE-statement, which is useful for insertion in batch files at the top-level or within functions when input from the user is necessary or desired. It often happens that after generating an expression, one decides that it would be convenient to use it as the body of a function definition, with one or more of the indeterminates therein as parameters. This can be done as follows (say yes to the define operator prompt); (1-(V/C)**2)**(1/2); FOR ALL V SAVEAS F(V); F(5); COMMENT Here the indeterminate V became a parameter of F. Alternatively, we can save the previous expression as an indeterminate; SAVEAS FOF5; FOF5; COMMENT I find this technique more convenient than referring to the special variable WS; PAUSE; COMMENT The FOR-loop provides a convenient way to form finite sums or products with specific integer index limits. However, this need is so ubiquitous that REDUCE provides even more convenient syntax of the forms FOR index := initial STEP increment UNTIL final SUM expression, FOR index := initial STEP increment UNTIL final PRODUCT expression. As before, ":" is an acceptable abbreviation for "STEP 1 UNTIL". As an example of their use, here is a very concise definition of a function which computes Taylor-series expansions of symbolic expressions:; ALGEBRAIC PROCEDURE TAYLOR(EX, X, PT, N); COMMENT This function returns the degree N Taylor-series expansion of expression EX with respect to indeterminate X, expanded about expression PT. For a series-like appearance, display the answer under the influence of FACTOR X, ON RAT, and perhaps also ON DIV; SUB(X=PT, EX) + FOR K:=1:N SUM(SUB(X=PT, DF(EX,X,K))*(X-PT)**K / FOR J:=1:K PRODUCT J); CLEAR A, X; FACTOR X; ON RAT, DIV; G1 := TAYLOR(E**X, X, 0, 4); G2 := TAYLOR(E**COS(X)*COS(SIN(X)), X, 0, 3); %This illustrates the Zero denominator limitation, continue anyway; TAYLOR(LOG(X), X, 0, 4); COMMENT It would, of course, be more efficient to compute each derivative and factorial from the preceding one. (Similarly for (X-PT)**K if and only if PT NEQ 0). The Fourier series expansion of our example E**COS(X)*COS(SIN(X)) is 1 + cos(x) + cos(2*x)/2 + cos(3*x)/(3*2) + ... . Use the above SUM and PRODUCT features to generate the partial sum of this series through terms of order COS(6*X); PAUSE; COMMENT Closed-form solutions are often unobtainable for nontrivial problems, even using computer algebra. When this is the case, truncated symbolic series solutions are often worth trying before resorting to approximate numerical solutions. When we combine truncated series it is pointless (and worse yet, misleading) to retain terms of higher order than is justified by the constituents. For example, if we wish to multiply together the truncated series G1 and G2 generated above, there is no point in retaining terms higher than third degree in X. We can avoid even generating such terms as follows; LET X**4 = 0; G3 := G1*G2; COMMENT Replacing X**4 with 0 has the effect of also replacing all higher powers of X with 0. We could, of course, use our TAYLOR function to compute G3 directly, but differentiation is time consuming compared to truncated polynomial algebra. Moreover, our TAYLOR function requires a closed-form expression to begin with, whereas iterative techniques often permit us to construct symbolic series solutions even when we have no such closed form. Now consider the truncated series; CLEAR Y; FACTOR Y; H1 := TAYLOR(COS Y, Y, 0, 6); COMMENT Suppose we regard terms of order X**N in G1 as being comparable to terms of order Y**(2*N) in H1, and we want to form (G1*H1)**2. This can be done as follows; LET Y**7 = 0; F1 := (G1*H1)**2; COMMENT Note however that any terms of the form C*X**M*Y**N with 2*M+N > 6 are inconsistent with the accuracy of the constituent series, and we have generated several such misleading terms by independently truncating powers of X and Y. To avoid generating such junk, we can specify that a term be replaced by 0 whenever a weighted sum of exponents of specified indeterminates and functional forms exceeds a specified weight level. In our example this is done as follows; WEIGHT X=2, Y=1; WTLEVEL 6; F1 := F1; COMMENT variables not mentioned in a WEIGHT declaration have a weight of 0, and the default weight-level is 2; PAUSE; COMMENT In lesson 2 I promised to show you ways to overcome the lack in most REDUCE implementations of automatic numerical techniques for approximating fractional powers and transcendental functions of numerical values. One way is to provide a supplementary LET rule for numerical arguments. For example, since our TAYLOR function would reveal that the Taylor series for cos x is 1 - x**2/2! + x**4/4! - ...; FOR ALL X SUCH THAT NUMBERP X LET ABS(X)=X,ABS(-X)=X; EPSRECIP := 1024 $ ON ROUNDED; WHILE 1.0 + 1.0/EPSRECIP NEQ 1.0 DO EPSRECIP := EPSRECIP + EPSRECIP; FOR ALL X SUCH THAT NUMBERP NUM X AND NUMBERP DEN X LET COS X = BEGIN COMMENT X is integer, real, or a rational number. This rule returns the Taylor-series approximation to COS X, truncated when the last included term is less than (1/EPSRECIP) of the returned answer. EPSRECIP is a global variable initialized to a value that is appropriate to the local floating-point precision. Arbitrarily larger values are justifiable when X is exact and ROUNDED is off. No angle reduction is performed, so this function is not recommended for ABS(X) >= about PI/2; INTEGER K; SCALAR MXSQ, TERM, ANS; K := 1; MXSQ := -X*X; TERM := MXSQ/2; ANS := TERM + 1; WHILE ABS(NUM TERM)*EPSRECIP*DEN(ANS)-ABS(NUM ANS)*DEN(TERM)>0 DO << TERM:= TERM*MXSQ/K/(K+1); ANS:= TERM + ANS; K := K+2 >>; RETURN ANS END; COS(F) + COS(1/2); OFF ROUNDED; COS(1/2); COMMENT As an exercise, write a similar rule for the SIN or LOG, or replace the COS rule with an improved one which uses angle reduction so that angles outside a modest range are represented as equivalent angles within the range, before computing the Taylor series; PAUSE; COMMENT There is a REDUCE compiler, and you may wish to learn the local incantations for using it. However, even if rules such as the above ones are compiled, they will be slow compared to the implementation-dependent hand-coded ones used by most FORTRAN-like systems, so REDUCE provides a way to generate FORTRAN programs which can then be compiled and executed in a subsequent job step. This is useful when there is a lot of floating-point computation or when we wish to exploit an existing FORTRAN program. Suppose, for example, that we wish to utilize an existing FORTRAN subroutine which uses the Newton-Rapheson iteration Xnew := Xold - SUB(X=Xold, F(X)/DF(F(X),X)) to attempt an approximate solution to the equation F(X)=0. Most such subroutines require the user to provide a FORTRAN function or subroutine which, given Xold, returns F(X)/DF(F(X),X) evaluated at X=Xold. If F(X) is complicated, manual symbolic derivation of DF(F(X),X) is a tedious and error-prone process. We can get REDUCE to relieve us of this responsibility as is illustrated below for the trivial example F(X) = X*E**X - 1: ON FORT, ROUNDED, OUT FONDFFILE, WRITE " REAL FUNCTION FONDF(XOLD)", WRITE " REAL XOLD, F", F := XOLD*E**XOLD - 1.0, FONDF := F/DF(F,XOLD), WRITE " RETURN", WRITE " END", SHUT FONDFFILE . COMMENT Under the influence of ON FORT, the output generated by assignments is printed as valid FORTRAN assignment statements, using as many continuation lines as necessary up to the amount specified by the global variable !*CARDNO, which is initially set to 20. The output generated by an expression which is not an assignment is a corresponding assignment to a variable named ANS. In either case, expressions which would otherwise exceed !*CARDNO continuation lines are evaluated piecewise, using ANS as an intermediate variable. Try executing the above sequence, using an appropriate filename and using semicolons rather than commas at the end of the lines, then print the file after the lesson to see how it worked; PAUSE; OFF FORT, ROUNDED; COMMENT To make this technique usable by non-REDUCE programmers, we could write a more general REDUCE program which given merely the expression F by the user, outputs not only the function FONDF, but also any necessary Job-control commands and an appropriate main program for calling the Newton-Rapheson subroutine and printing the results. Sometimes it is desirable to modify or supplement the syntax of REDUCE. For example: 1. Electrical engineers may prefer to input J as the representation of (-1)**(1/2). 2. Many users may prefer to input LN to denote natural logarithms. 3. A user with previous exposure to the PL/I-FORMAC computer- algebra system might prefer to use DERIV instead of DF to request differentiation. Such lexical macros can be established by the DEFINE declaration:; CLEAR X,J; DEFINE J=I, LN=LOG, DERIV=DF; COMMENT Now watch!; N := 3; G1 := SUB(X=LN(J**3*X), DERIV(X**2,X)); COMMENT Each "equation" in a DEFINE declaration must be of the form "name = item", where each item is an expression, an operator, or a REDUCE-reserved word such as "FOR". Such replacements take place during the lexical scanning, before any evaluation, LET rules, or built-in simplification. Think of a good application for this facility, then try it; PAUSE; COMMENT When REDUCE is being run in batch mode, it is preferable to have REDUCE make reasonable decisions and proceed when it encounters apparently undeclared operators, divisions by zero, etc. In interactive mode, it is preferable to pause and query the user. ON INT specifies the latter style, and OFF INT specifies the former. Under the influence of OFF INT, we can also have most error messages suppressed by specifying OFF MSG. This is sometimes useful when we expect abnormal conditions and do not want our listing marred by the associated messages. INT is automatically turned off during input from a batch file in response to an IN-command from a terminal. Some implementations permit the user to dynamically request more storage by executing a command of the form CORE number, where the number is an integer specifying the total desired core in some units such as bytes, words, kilobytes, or kilowords; PAUSE; COMMENT Some implementations have a trace command for debugging, which employs the syntax TR functionname1, functionname2, ..., functionnameN . An analogous command named UNTR removes function names from trace status; PAUSE; COMMENT Some implementations have an assignment-tracing command for debugging, which employs the syntax TRST functionname1, functionname2, ..., functionnameN. An analogous command named UNTRST removes functionnames from this status. All assignments in the designated functions are reported, except for assignments to array elements. Such functions must be uncompiled and must have a top-level BEGIN-block. To apply both TRST and TR to a function simultaneously, it is crucial to request them in that order, and it is necessary to relinquish the two kinds of tracing in the opposite order; PAUSE; COMMENT The REDUCE algebraic algorithms are written in a subset of REDUCE called RLISP. In turn, the more sophisticated features of RLISP are written in a small subset of RLISP which is written in a subset of LISP that is relatively common to most LISP systems. RLISP is ideal for implementing algebraic algorithms, but the RLISP environment is not most suitable for the routine use of these algorithms in the natural mathematical style of the preceding lessons. Accordingly, REDUCE jobs are initially in a mode called ALGEBRAIC, which provides the user with the environment illustrated in the preceding lessons, while insulating him from accidental interaction with the numerous functions, global variables, etc. necessary for implementing the built-in algebra. In contrast, the underlying RLISP system together with all of the algebraic simplification algorithms written therein is called SYMBOLIC mode. As we have seen, algebraic-mode rules and procedures can be used to extend the built-in algebraic capabilities. However, some extensions can be accomplished most easily or efficiently by descending to SYMBOLIC mode. To make REDUCE operate in symbolic mode, we merely execute the top level mode-declaration statement consisting of the word SYMBOLIC. We can subsequently switch back by executing the statement consisting of the word ALGEBRAIC. RLISP has the semantics of LISP with the syntax of our by-now-familiar algebraic-mode REDUCE, so RLISP provides a natural tool for many applications besides computer algebra, such as games, theorem-proving, natural-language translation, computer-aided instruction, and artificial intelligence in general. For this reason, it is possible to run RLISP without any of the symbolic-mode algebraic algorithms that are written in RLISP, and it is advisable to thus save space when the application does not involve computer algebra. We have now discussed virtually every feature that is available in algebraic mode, so lesson 6 will deal solely with RLISP, and lesson 7 will deal with communication between ALGEBRAIC and SYMBOLIC mode for mathematical purposes. However, I suggest that you proceed to those lessons only if and when: 1. You have consolidated and fully absorbed the information in lessons 1 through 5 by considerable practice beyond the exercises therein. (The exercises were intended to also suggest good related project ideas.) 2. You feel the need for a facility which you believe is impossible or quite awkward to implement solely in ALGEBRAIC mode. 3. You have read the pamphlet "Introduction to LISP", by D. Lurie, or an equivalent. 4. You are familiar with definition of Standard LISP, as described in the "Standard LISP Report" which was published in the October 1979 SIGPLAN Notices. Remember, when you decide to take lesson 6, it is better to do so from a RLISP job than from a REDUCE job. Also, don't forget to print your newly generated FORTRAN file and to delete any temporary files created by this lesson. ;END;