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2.5.10 Tracing Evaluation

The standard way in which Mathematica works is to take any expression you give as input, evaluate the expression completely, and then return the result. When you are trying to understand what Mathematica is doing, however, it is often worthwhile to look not just at the final result of evaluation, but also at intermediate steps in the evaluation process.

Tracing the evaluation of expressions.

The expression 1 + 1 is evaluated immediately to 2.

In[1]:= Trace[1 + 1]

Out[1]=

The 2^3 is evaluated before the addition is done.

In[2]:= Trace[2^3 + 4]

Out[2]=

The evaluation of each subexpression is shown in a separate sublist.

In[3]:= Trace[2^3 + 4^2 + 1]

Out[3]=

Trace[expr] gives a list which includes all the intermediate expressions involved in the evaluation of expr. Except in rather simple cases, however, the number of intermediate expressions generated in this way is typically very large, and the list returned by Trace is difficult to understand.

Trace[expr, form] allows you to "filter" the expressions that Trace records, keeping only those which match the pattern form.

Here is a recursive definition of a factorial function.

In[4]:= fac[n_] := n fac[n-1]; fac[1] = 1

Out[4]=

This gives all the intermediate expressions generated in the evaluation of fac[3]. The result is quite complicated.

In[5]:= Trace[fac[3]]

Out[5]=

This shows only intermediate expressions of the form fac[n_].

In[6]:= Trace[fac[3], fac[n_]]

Out[6]=

You can specify any pattern in Trace.

In[7]:= Trace[fac[10], fac[n_/;n > 5]]

Out[7]=

Trace[expr, form] effectively works by intercepting every expression that is about to be evaluated during the evaluation of expr, and picking out those that match the pattern form.

If you want to trace "calls" to a function like fac, you can do so simply by telling Trace to pick out expressions of the form fac[n_]. You can also use patterns like f[n_, 2] to pick out calls with particular argument structure.

A typical Mathematica program, however, consists not only of "function calls" like fac[n], but also of other elements, such as assignments to variables, control structures, and so on. All of these elements are represented as expressions. As a result, you can use patterns in Trace to pick out any kind of Mathematica program element. Thus, for example, you can use a pattern like k = _ to pick out all assignments to the symbol k.

This shows the sequence of assignments made for k.

In[8]:= Trace[(k=2; For[i=1, i<4, i++, k = i/k]; k), k=_]

Out[8]=

Trace[expr, form] can pick out expressions that occur at any time in the evaluation of expr. The expressions need not, for example, appear directly in the form of expr that you give. They may instead occur, say, during the evaluation of functions that are called as part of the evaluation of expr.

Here is a function definition.

In[9]:= h[n_] := (k=n/2; Do[k = i/k, {i, n}]; k)

You can look for expressions generated during the evaluation of h.

In[10]:= Trace[h[3], k=_]

Out[10]=

Trace allows you to monitor intermediate steps in the evaluation not only of functions that you define, but also of some functions that are built into Mathematica. You should realize, however, that the specific sequence of intermediate steps followed by built-in Mathematica functions depends in detail on their implementation and optimization in a particular version of Mathematica.

Some ways to use Trace.

The function Trace returns a list that represents the "history" of a Mathematica computation. The expressions in the list are given in the order that they were generated during the computation. In most cases, the list returned by Trace has a nested structure, which represents the "structure" of the computation.

The basic idea is that each sublist in the list returned by Trace represents the "evaluation chain" for a particular Mathematica expression. The elements of this chain correspond to different forms of the same expression. Usually, however, the evaluation of one expression requires the evaluation of a number of other expressions, often subexpressions. Each subsidiary evaluation is represented by a sublist in the structure returned by Trace.

Here is a sequence of assignments.

In[11]:= a[1] = a[2]; a[2] = a[3]; a[3] = a[4]

Out[11]=

This yields an evaluation chain reflecting the sequence of transformations for a[i] used.

In[12]:= Trace[a[1]]

Out[12]=

The successive forms generated in the simplification of y + x + y show up as successive elements in its evaluation chain.

In[13]:= Trace[y + x + y]

Out[13]=

Each argument of the function f has a separate evaluation chain, given in a sublist.

In[14]:= Trace[f[1 + 1, 2 + 3, 4 + 5]]

Out[14]=

The evaluation chain for each subexpression is given in a separate sublist.

In[15]:= Trace[x x + y y]

Out[15]=

Tracing the evaluation of a nested expression yields a nested list.

In[16]:= Trace[f[f[f[1 + 1]]]]

Out[16]=

There are two basic ways that subsidiary evaluations can be required during the evaluation of a Mathematica expression. The first way is that the expression may contain subexpressions, each of which has to be evaluated. The second way is that there may be rules for the evaluation of the expression that involve other expressions which themselves must be evaluated. Both kinds of subsidiary evaluations are represented by sublists in the structure returned by Trace.

The subsidiary evaluations here come from evaluation of the arguments of f and g.

In[17]:= Trace[f[g[1 + 1], 2 + 3]]

Out[17]=

Here is a function with a condition attached.

In[18]:= fe[n_] := n + 1 /; EvenQ[n]

The evaluation of fe[6] involves a subsidiary evaluation associated with the condition.

In[19]:= Trace[fe[6]]

Out[19]=

You often get nested lists when you trace the evaluation of functions that are defined "recursively" in terms of other instances of themselves. The reason is typically that each new instance of the function appears as a subexpression in the expressions obtained by evaluating previous instances of the function.

Thus, for example, with the definition fac[n_] := n fac[n-1], the evaluation of fac[6] yields the expression 6 fac[5], which contains fac[5] as a subexpression.

The successive instances of fac generated appear in successively nested sublists.

In[20]:= Trace[fac[6], fac[_]]

Out[20]=

With this definition, fp[n-1] is obtained directly as the value of fp[n].

In[21]:= fp[n_] := fp[n - 1] /; n > 1

fp[n] never appears in a subexpression, so no sublists are generated.

In[22]:= Trace[fp[6], fp[_]]

Out[22]=

Here is the recursive definition of the Fibonacci numbers.

In[23]:= fib[n_] := fib[n - 1] + fib[n - 2]

Here are the end conditions for the recursion.

In[24]:= fib[0] = fib[1] = 1

Out[24]=

This shows all the steps in the recursive evaluation of fib[5].

In[25]:= Trace[fib[5], fib[_]]

Out[25]=

Each step in the evaluation of any Mathematica expression can be thought of as the result of applying a particular transformation rule. As discussed in Section 2.4.10, all the rules that Mathematica knows are associated with specific symbols or "tags". You can use Trace[expr, f] to see all the steps in the evaluation of expr that are performed using transformation rules associated with the symbol f. In this case, Trace gives not only the expressions to which each rule is applied, but also the results of applying the rules.

In general, Trace[expr, form] picks out all the steps in the evaluation of expr where form matches either the expression about to be evaluated, or the tag associated with the rule used.

Tracing evaluations associated with particular tags.

This shows only intermediate expressions that match fac[_].

In[26]:= Trace[fac[3], fac[_]]

Out[26]=

This shows all evaluations that use transformation rules associated with the symbol fac.

In[27]:= Trace[fac[3], fac]

Out[27]=

Here is a rule for the log function.

In[28]:= log[x_ y_] := log[x] + log[y]

This traces the evaluation of log[a b c d], showing all transformations associated with log.

In[29]:= Trace[log[a b c d], log]

Out[29]=

Switching off tracing inside certain forms.

Trace[expr, form] allows you to trace expressions matching form generated at any point in the evaluation of expr. Sometimes, you may want to trace only expressions generated during certain parts of the evaluation of expr.

By setting the option TraceOn -> oform, you can specify that tracing should be done only during the evaluation of forms which match oform. Similarly, by setting TraceOff -> oform, you can specify that tracing should be switched off during the evaluation of forms which match oform.

This shows all steps in the evaluation.

In[30]:= Trace[log[fac[2] x]]

Out[30]=

This shows only those steps that occur during the evaluation of fac.

In[31]:= Trace[log[fac[2] x], TraceOn -> fac]

Out[31]=

This shows only those steps that do not occur during the evaluation of fac.

In[32]:= Trace[log[fac[2] x], TraceOff -> fac]

Out[32]=

Applying rules to expressions encountered during evaluation.

This tells Trace to return only the arguments of fib used in the evaluation of fib[5].

In[33]:= Trace[fib[5], fib[n_] -> n]

Out[33]=

A powerful aspect of the Mathematica Trace function is that the object it returns is basically a standard Mathematica expression which you can manipulate using other Mathematica functions. One important point to realize, however, is that Trace wraps all expressions that appear in the list it produces with HoldForm to prevent them from being evaluated. The HoldForm is not displayed in standard Mathematica output format, but it is still present in the internal structure of the expression.

This shows the expressions generated at intermediate stages in the evaluation process.

In[34]:= Trace[1 + 3^2]

Out[34]=

The expressions are wrapped with HoldForm to prevent them from evaluating.

In[35]:= Trace[1 + 3^2] // InputForm

Out[35]//InputForm= {{HoldForm[3^2], HoldForm[9]}, HoldForm[1 + 9], HoldForm[10]}

In standard Mathematica output format, it is sometimes difficult to tell which lists are associated with the structure returned by Trace, and which are expressions being evaluated.

In[36]:= Trace[{1 + 1, 2 + 3}]

Out[36]=

Looking at the input form resolves any ambiguities.

In[37]:= InputForm[%]

Out[37]//InputForm= {{HoldForm[1 + 1], HoldForm[2]}, {HoldForm[2 + 3], HoldForm[5]}, HoldForm[{2, 5}]}

When you use a transformation rule in Trace, the result is evaluated before being wrapped with HoldForm.

In[38]:= Trace[fac[4], fac[n_] -> n + 1]

Out[38]=

For sophisticated computations, the list structures returned by Trace can be quite complicated. When you use Trace[expr, form], Trace will include as elements in the lists only those expressions which match the pattern form. But whatever pattern you give, the nesting structure of the lists remains the same.

This shows all occurrences of fib[_] in the evaluation of fib[3].

In[39]:= Trace[fib[3], fib[_]]

Out[39]=

This shows only occurrences of fib[1], but the nesting of the lists is the same as for fib[_].

In[40]:= Trace[fib[3], fib[1]]

Out[40]=

You can set the option TraceDepth -> n to tell Trace to include only lists nested at most n levels deep. In this way, you can often pick out the "big steps" in a computation, without seeing the details. Note that by setting TraceDepth or TraceOff you can avoid looking at many of the steps in a computation, and thereby significantly speed up the operation of Trace for that computation.

This shows only steps that appear in lists nested at most two levels deep.

In[41]:= Trace[fib[3], fib[_], TraceDepth->2]

Out[41]=

Restricting the depth of tracing.

When you use Trace[expr, form], you get a list of all the expressions which match form produced during the evaluation of expr. Sometimes it is useful to see not only these expressions, but also the results that were obtained by evaluating them. You can do this by setting the option TraceForward -> True in Trace.

This shows not only expressions which match fac[_], but also the results of evaluating those expressions.

In[42]:= Trace[fac[4], fac[_], TraceForward->True]

Out[42]=

Expressions picked out using Trace[expr, form] typically lie in the middle of an evaluation chain. By setting TraceForward -> True, you tell Trace to include also the expression obtained at the end of the evaluation chain. If you set TraceForward -> All, Trace will include all the expressions that occur after the expression matching form on the evaluation chain.

With TraceForward->All, all elements on the evaluation chain after the one that matches fac[_] are included.

In[43]:= Trace[fac[4], fac[_], TraceForward->All]

Out[43]=

By setting the option TraceForward, you can effectively see what happens to a particular form of expression during an evaluation. Sometimes, however, you want to find out not what happens to a particular expression, but instead how that expression was generated. You can do this by setting the option TraceBackward. What TraceBackward does is to show you what preceded a particular form of expression on an evaluation chain.

This shows that the number 120 came from the evaluation of fac[5] during the evaluation of fac[10].

In[44]:= Trace[fac[10], 120, TraceBackward->True]

Out[44]=

Here is the whole evaluation chain associated with the generation of the number 120.

In[45]:= Trace[fac[10], 120, TraceBackward->All]

Out[45]=

TraceForward and TraceBackward allow you to look forward and backward in a particular evaluation chain. Sometimes, you may also want to look at the evaluation chains within which the particular evaluation chain occurs. You can do this using TraceAbove. If you set the option TraceAbove -> True, then Trace will include the initial and final expressions in all the relevant evaluation chains. With TraceAbove -> All, Trace includes all the expressions in all these evaluation chains.

This includes the initial and final expressions in all evaluation chains which contain the chain that contains 120.

In[46]:= Trace[fac[7], 120, TraceAbove->True]

Out[46]=

This shows all the ways that fib[2] is generated during the evaluation of fib[5].

In[47]:= Trace[fib[5], fib[2], TraceAbove->True]

Out[47]=

Option settings for including extra steps in trace lists.

The basic way that Trace[expr, ... ] works is to intercept each expression encountered during the evaluation of expr, and then to use various criteria to determine whether this expression should be recorded. Normally, however, Trace intercepts expressions only after function arguments have been evaluated. By setting TraceOriginal -> True, you can get Trace also to look at expressions before function arguments have been evaluated.

This includes expressions which match fac[_] both before and after argument evaluation.

In[48]:= Trace[fac[3], fac[_], TraceOriginal -> True]

Out[48]=

The list structure produced by Trace normally includes only expressions that constitute steps in non-trivial evaluation chains. Thus, for example, individual symbols that evaluate to themselves are not normally included. Nevertheless, if you set TraceOriginal -> True, then Trace looks at absolutely every expression involved in the evaluation process, including those that have trivial evaluation chains.

In this case, Trace includes absolutely all expressions, even those with trivial evaluation chains.

In[49]:= Trace[fac[1], TraceOriginal -> True]

Out[49]=

Additional options for Trace.

When you use Trace to study the execution of a program, there is an issue about how local variables in the program should be treated. As discussed in Section 2.6.3, Mathematica scoping constructs such as Module create symbols with new names to represent local variables. Thus, even if you called a variable x in the original code for your program, the variable may effectively be renamed x$nnn when the program is executed.

Trace[expr, form] is set up so that by default a symbol x that appears in form will match all symbols with names of the form x$nnn that arise in the execution of expr. As a result, you can for example use Trace[expr, x = _] to trace assignment to all variables, local and global, that were named x in your original program.

Preventing the matching of local variables.

In some cases, you may want to trace only the global variable x, and not any local variables that were originally named x. You can do this by setting the option MatchLocalNames -> False.

This traces assignments to all variables with names of the form x$nnn.

In[50]:= Trace[Module[{x}, x = 5], x = _]

Out[50]=

This traces assignments only to the specific global variable x.

In[51]:= Trace[Module[{x}, x = 5], x = _,

MatchLocalNames -> False]

Out[51]=

The function Trace performs a complete computation, then returns a structure which represents the history of the computation. Particularly in very long computations, it is however sometimes useful to see traces of the computation as it proceeds. The function TracePrint works essentially like Trace, except that it prints expressions when it encounters them, rather than saving up all of the expressions to create a list structure.

This prints expressions encountered in the evaluation of fib[3].

In[52]:= TracePrint[fib[3], fib[_]]

Out[52]=

The sequence of expressions printed by TracePrint corresponds to the sequence of expressions given in the list structure returned by Trace. Indentation in the output from TracePrint corresponds to nesting in the list structure from Trace. You can use the Trace options TraceOn, TraceOff and TraceForward in TracePrint. However, since TracePrint produces output as it goes, it cannot support the option TraceBackward. In addition, TracePrint is set up so that TraceOriginal is effectively always set to True.

Functions for tracing evaluation.

This enters a dialog when fac[5] is encountered during the evaluation of fac[10].

In[53]:= TraceDialog[fac[10], fac[5]]

Out[54]=

Inside the dialog you can for example find out where you are by looking at the "stack".

In[54]:= Stack[ ]

Out[55]=

This returns from the dialog, and gives the final result from the evaluation of fac[10].

In[55]:= Return[ ]

Out[53]=

The function TraceDialog effectively allows you to stop in the middle of a computation, and interact with the Mathematica environment that exists at that time. You can for example find values of intermediate variables in the computation, and even reset those values. There are however a number of subtleties, mostly associated with pattern and module variables.

What TraceDialog does is to call the function Dialog on a sequence of expressions. The Dialog function is discussed in detail in Section 2.13.2. When you call Dialog, you are effectively starting a subsidiary Mathematica session with its own sequence of input and output lines.

In general, you may need to apply arbitrary functions to the expressions you get while tracing an evaluation. TraceScan[f, expr, ... ] applies f to each expression that arises. The expression is wrapped with HoldForm to prevent it from evaluating.

In TraceScan[f, expr, ... ], the function f is applied to expressions before they are evaluated. TraceScan[f, expr, patt, fp] applies f before evaluation, and fp after evaluation.