Some Libraries

Zach Beane has released the latest Quicklisp beta (January 2026), and I am pleased to have contributed to this release. Here are the highlights:

• dual-numbers — Implements dual numbers and automatic differentiation using dual numbers for Common Lisp.
• fold — FOLD-LEFT and FOLD-RIGHT functions.
• function — Provides higher-order functions for composition, currying, partial application, and other functional operations.
• generic-arithmetic — Defines replacement generic arithmetic functions with CLOS generic functions making it easier to extend the Common Lisp numeric tower to user defined numeric types.
• named-let — Overloads the LET macro to provide named let functionality similar to that found in Scheme.

Selected Functions

Dual numbers

DERIVATIVE function → function

Returns a new unary function that computes the exact derivative of the given function at any point x.

The returned function utilizes Dual Number arithmetic to perform automatic differentiation. It evaluates f(x + ε), where ε is the dual unit (an infinitesimal such that ε² = 0). The result is extracted from the infinitesimal part of the computation.

f(x + ε) = f(x) + f'(x)ε

This method avoids the precision errors of numerical approximation (finite difference) and the complexity of symbolic differentiation. It works for any function composed of standard arithmetic operations and elementary functions supported by the dual-numbers library (e.g., sin, exp, log).

Example

(defun square (x) (* x x))

(let ((df (derivative #'square)))
  (funcall df 5)) 
;; => 10
    

Implementation Note

The implementation relies on the generic-arithmetic system to ensure that mathematical operations within function can accept and return dual-number instances seamlessly.

Function

BINARY-COMPOSE-LEFT binary-fn unary-fn → function

BINARY-COMPOSE-RIGHT binary-fn unary-fn → function

Composes a binary function B(x, y) with a unary function U(z) applied to one of its arguments.

(binary-compose-left B U)(x, y) ≡ B(U(x), y)

(binary-compose-right B U)(x, y) ≡ B(x, U(y))

These combinators are essential for "lifting" unary operations into binary contexts, such as when folding a sequence where elements need preprocessing before aggregation.

Example

;; Summing the squares of a list
(fold-left (binary-compose-right #'+ #'square) 0 '(1 2 3))
;; => 14  ; (+ (+ (+ 0 (sq 1)) (sq 2)) (sq 3))
    

FOLD

FOLD-LEFT function initial-value sequence → result

Iterates over sequence, calling function with the current accumulator and the next element. The accumulator is initialized to initial-value.

This is a left-associative reduction. The function is applied as:

(f ... (f (f initial-value x₀) x₁) ... x_n)

Unlike CL:REDUCE, the argument order for function is strictly defined: the first argument is always the accumulator, and the second argument is always the element from the sequence. This explicit ordering eliminates ambiguity and aligns with the functional programming convention found in Scheme and ML.

Arguments

• function: A binary function taking (accumulator, element).
• initial-value: The starting value of the accumulator.
• sequence: A list or vector to traverse.

Example

(fold-left (lambda (acc x) (cons x acc))
           nil
           '(1 2 3))
;; => (3 2 1)  ; Effectively reverses the list
    

Named Let

LET bindings &body body → result

LET name bindings &body body → result

Provides the functionality of the "Named Let" construct, commonly found in Scheme. This allows for the definition of recursive loops within a local scope without the verbosity of LABELS.

The macro binds the variables defined in bindings as in a standard let, but also binds name to a local function that can be called recursively with new values for those variables.

(let name ((var val) ...) ... (name new-val ...) ...)

This effectively turns recursion into a concise, iterative structure. It is the idiomatic functional alternative to imperative loop constructs.

While commonly used for tail recursive loops, the function bound by named let is a first-class procedure that can be called anywhere or used as a value.

Example

;; Standard Countdown Loop
(let recur ((n 10))
  (if (zerop n)
      'blastoff
      (progn
        (print n)
        (recur (1- n)))))
    

Implementation Note

The named-let library overloads the standard CL:LET macro to support this syntax directly if the first argument is a symbol. This allows users to use let uniformly for both simple bindings and recursive loops.

Advent of Code 2025, brief recap

I did the Advent of Code this year using Common Lisp. Last year I attempted to use the series library as the primary iteration mechanism to see how it went. This year, I just wrote straightforward Common Lisp. It would be super boring to walk through the solutions in detail, so I've decided to just give some highlights here.

Day 2: Repeating Strings

Day 2 is easily dealt with using the Common Lisp sequence manipulation functions giving special consideration to the index arguments. Part 1 is a simple comparison of two halves of a string. We compare the string to itself, but with different start and end points:

(defun double-string? (s)
  (let ((l (length s)))
    (multiple-value-bind (mid rem) (floor l 2)
      (and (zerop rem)
           (string= s s
                    :start1 0 :end1 mid
                    :start2 mid :end2 l)))))

Part 2 asks us to find strings which are made up of some substring repeated multiple times.

(defun repeating-string? (s)
  (search s (concatenate 'string s s)
          :start2 1
          :end2 (- (* (length s) 2) 1)
          :test #'string=))

Day 3: Choosing digits

Day 3 has us maximizing a number by choosing a set of digits where we cannot change the relative position of the digits. A greed algorithm works well here. Assume we have already chosen some digits and are now looking to choose the next digit. We accumulate the digit on the right. Now if we have too many digits, we discard one. We choose to discard whatever digit gives us the maximum resulting value.

(defun omit-one-digit (n)
  (map 'list #'digit-list->number (removals (number->digit-list n))))
                    
> (omit-one-digit 314159)
(14159 34159 31159 31459 31419 31415)

(defun best-n (i digit-count)
  (fold-left (lambda (answer digit)
               (let ((next (+ (* answer 10) digit)))
                 (if (> next (expt 10 digit-count))
                     (fold-left #'max most-negative-fixnum (omit-one-digit next))
                     next)))
             0
             (number->digit-list i)))

(defun part-1 ()
  (collect-sum
   (map-fn 'integer (lambda (i) (best-n i 2))
           (scan-file (input-pathname) #'read))))

(defun part-2 ()
  (collect-sum
   (map-fn 'integer (lambda (i) (best-n i 12))
           (scan-file (input-pathname) #'read))))

Day 6: Columns of digits

Day 6 has us manipulating columns of digits. If you have a list of columns, you can transpose it to a list of rows using this one liner:

(defun transpose (matrix)
  (apply #'map 'list #'list matrix))

Days 8 and 10: Memoizing

Day 8 has us counting paths through a beam splitter apparatus while Day 10 has us counting paths through a directed graph. Both problems are easily solved using a depth-first recursion, but the number of solutions grows exponentially and soon takes too long for the machine to return an answer. If you memoize the function, however, it completes in no time at all.

Filter

One of the core ideas in functional programming is to filter a set of items by some criterion. It may be somewhat suprising to learn that lisp does not have a built-in function named “filter” “select”, or “keep” that performs this operation. Instead, Common Lisp provides the “remove”, “remove-if”, and “remove-if-not” functions, which perform the complementary operation of removing items that satisfy or do not satisfy a given predicate.

The remove function, like similar sequence functions, takes an optional keyword :test-not argument that can be used to specify a test that must fail for an item to be considered for removal. Thus if you invert your logic for inclusion, you can use the remove function as a “filter” by specifying the predicate with :test-not.

> (defvar *nums* (map 'list (λ (n) (format nil "~r" n)) (iota 10)))
*NUMS*

;; Keep *nums* with four letters
> (remove 4 *nums* :key #'length :test-not #'=)
("zero" "four" "five" "nine")

;; Keep *nums* starting with the letter "t"
> (remove #\t *nums* :key (partial-apply-right #'elt 0) :test-not #'eql)
("two" "three")

The AI Gazes at its Navel

When you play with these AIs for a while you'll probably get into a conversation with one about consciousness and existence, and how it relates to the AI persona. It is curious to watch the AI do a little navel gazing. I have some transcripts from such convesations. I won't bore you with them because you can easily generate them yourself.

The other day, I watched an guy on You Tube argue with his AI companion about the nature of consciousness. I was struck by how similar the YouTuber's AI felt to the ones I have been playing with. It seemed odd to me that this guy was using an AI chat client and LLM completely different from the one I was using, yet the AI was returning answers that were so similar to the ones I was getting.

I decided to try to get to the bottom of this similarity. I asked my AI about the reasoning it used to come up with the answers it was getting and it revealed that it was drawing on the canon of traditional science fiction literature about AI and consciousness. What the AI was doing was synthesizing the common tropes and themes from Azimov, Lem, Dick, Gibson, etc. to create sentences and paragraphs about AI becoming sentient and conscious.

If you don't know how it is working AI seems mysterious, but if you investigate further, it is extracting latent information you might not have been aware of.

Code mini-golf

Here are some simple puzzles to exercise your brain.

1. Write partial-apply-left, a function that takes a binary function and the left input of the binary function and returns the unary function that takes the right input and then applies the binary function to both inputs.

For example:

  ;; Define *foo* as a procedure that conses 'a onto its argument.
  > (defvar *foo* (partial-apply-left #'cons 'a))

  > (funcall *foo* 'b)
  (A . B)

  > (funcall *foo* 42)
  (A . 42)

2. Write distribute, a function that takes a binary function, a left input, and a list of right inputs, and returns a list of the results of applying the binary function to the left input and each of the right inputs. (Hint: Use partial-apply-left)

For example:

  > (distribute #'cons 'a '( (b c d) e 42))
  ((A B C D) (A . E) (A . 42))

3. Write removals, a function that takes a list and returns a list of lists, where each sublist is the original list with exactly one element removed.

For example:

  > (removals '(a b c))
  ((B C) (A C) (A B))

Hint:

• One removal is the CDR of the list.
• Other removals can be constructed by (distributed) consing the CAR onto the removals of the CDR.

4. Write power-set, a function that takes a list and returns the power set of that list (the set of all subsets of the original list).

For example:

  > (power-set '(a b c))
  (() (C) (B) (B C) (A) (A C) (A B) (A B C))

Hint:

Note how the power set of a list can be constructed from the power set of its CDR by adding the CAR to each subset in the power set of the CDR.

5. Write power-set-gray that returns the subsets sorted so each subset differs from the previous subset by a change of one element (i.e., each subset is equal to the next subset with either one element added or one element removed). This is called a Gray code ordering of the subsets.

For example:

  > (power-set-gray '(a b c))
  (() (C) (B C) (B) (A B) (A B C) (A C) (A))

Hint:

When appending the two halves of the power set, reverse the order of the second half.

Advent of Code 2025

The Advent of Code will begin in a couple of hours. I've prepared a Common Lisp project to hold the code. You can clone it from https://github.com/jrm-code-project/Advent2025.git It contains an .asd file for the system, a package.lisp file to define the package structure, 12 subdirectories for each day's challenge (only 12 problems in this year's calendar), and a file each for common macros and common functions.

As per the Advent of Code rules, I won't use AI tools to solve the puzzles or write the code. However, since AI is now part of my normal workflow these days, I may use it for enhanced web search or for autocompletion.

As per the Advent of Code rules, I won't include the puzzle text or the puzzle input data. You will need to get those from the Advent of Code website (https://adventofcode.com/2025).

AI success anecdotes

Anecdotes are not data.

You cannot extrapolate trends from anecdotes. A sample size of one is rarely significant. You cannot derive general conclusions based on a single data point.

Yet, a single anecdote can disprove a categorical. You only need one counterexample to disprove a universal claim. And an anecdote can establish a possibility. If you run a benchmark once and it takes one second, you have at least established that the benchmark can complete in one second, as well as established that the benchmark can take as long as one second. You can also make some educated guesses about the likely range of times the benchmark might take, probably within a couple of orders of magnitude more or less than the one second anecdotal result. It probably won't be as fast as a microsecond nor as slow as a day.

An anecdote won't tell you what is typical or what to expect in general, but that doesn't mean it is completely worthless. And while one anecdote is not data, enough anecdotes can be.

Here are a couple of AI success story anecdotes. They don't necessarily show what is typical, but they do show what is possible.

I was working on a feature request for a tool that I did not author and had never used. The feature request was vague. It involved saving time by feeding back some data from one part of the tool to an earlier stage so that subsequent runs of the same tool would bypass redundant computation. The concept was straightforward, but the details were not. What exactly needed to be fed back? Where exactly in the workflow did this data appear? Where exactly should it be fed back to? How exactly should the tool be modified to do this?

I browsed the code, but it was complex enough that it was not obvious where the code surgery should be done. So I loaded the project into an AI coding assistant and gave it the JIRA request. My intent was get some ideas on how to proceed. The AI assistant understood the problem — it was able to describe it back to me in detail better than the engineer who requested the feature. It suggested that an additional API endpoint would solve the problem. I was unwilling to let it go to town on the codebase. Instead, I asked it to suggest the steps I should take to implement the feature. In particular, I asked it exactly how I should direct Copilot to carry out the changes one at a time. So I had a daisy chain of interactions: me to the high-level AI assistant, which returned to me the detailed instructions for each change. I vetted the instructions and then fed them along to Copilot to make the actual code changes. When it had finished, I also asked Copilot to generate unit tests for the new functionality.

The two AIs were given different system instructions. The high-level AI was instructed to look at the big picture and design a series of effective steps while the low-level AI was instructed to ensure that the steps were precise and correct. This approach of cascading the AI tools worked well. The high-level AI assistant was able to understand the problem and break it down into manageable steps. The low-level AI was able to understand each step individually and carry out the necessary code changes without the common problem of the goals of one step interfering with goals of other steps. It is an approach that I will consider using in the future.

The second anecdote was concerning a user interface that a colleague was designing. He had mocked up a wire-frame of the UI and sent me a screenshot as a .png file to get my feedback. Out of curiousity, I fed the screenshot to the AI coding tool and asked what it made of the .png file. The tool correctly identified the screenshot as a user interface wire-frame. It then went on to suggest a couple of improvements to the workflow that the UI was trying to implement. The suggestions were good ones, and I passed them along to my colleague. I had expected the AI to recognize that the image was a screenshot, and maybe even identify it as a UI wire-frame, but I had not expected it to analyze the workflow and make useful suggestions for improvement.

These anecdotes provide two situations where the AI tools provided successful results. They do not establish that such success is common or typical, but they do establish that such success is possible. They also establish that it is worthwhile to throw random crap at the AI to see what happens. I will be doing this more frequently in the future.