The origin of the cargo cult metaphor

The cargo cult metaphor is commonly used by programmers. This metaphor was popularized by Richard Feynman's "cargo cult science" talk with a vivid description of South Seas cargo cults. However, this metaphor has three major problems. First, the pop-culture depiction of cargo cults is inaccurate and fictionalized, as I'll show. Second, the metaphor is overused and has contradictory meanings making it a lazy insult. Finally, cargo cults are portrayed as an amusing story of native misunderstanding but the background is much darker: cargo cults are a reaction to decades of oppression of Melanesian islanders and the destruction of their culture. For these reasons, the cargo cult metaphor is best avoided.

Members of the John Frum cargo cult, marching with bamboo "rifles". Photo adapted from The Open Encyclopedia of Anthropology, (CC BY-NC 4.0).

In this post, I'll describe some cargo cults from 1919 to the present. These cargo cults are completely different from the description of cargo cults you usually find on the internet, which I'll call the "pop-culture cargo cult." Cargo cults are extremely diverse, to the extent that anthropologists disagree on the cause, definition, or even if the term has value. I'll show that many of the popular views of cargo cults come from a 1962 "shockumentary" called Mondo Cane. Moreover, most online photos of cargo cults are fake.

Feynman and Cargo Cult Science

The cargo cult metaphor in science started with Professor Richard Feynman's well-known 1974 commencement address at Caltech.1 This speech, titled "Cargo Cult Science", was expanded into a chapter in his best-selling 1985 book "Surely You're Joking, Mr. Feynman". He said:

In the South Seas there is a cargo cult of people. During the war they saw airplanes land with lots of good materials, and they want the same thing to happen now. So they’ve arranged to make things like runways, to put fires along the sides of the runways, to make a wooden hut for a man to sit in, with two wooden pieces on his head like headphones and bars of bamboo sticking out like antennas—he’s the controller—and they wait for the airplanes to land. They’re doing everything right. The form is perfect. It looks exactly the way it looked before. But it doesn’t work. No airplanes land. So I call these things cargo cult science, because they follow all the apparent precepts and forms of scientific investigation, but they’re missing something essential, because the planes don’t land.

Richard Feynman giving the 1974 commencement address at Caltech. Photo from Wikimedia Commons.

But the standard anthropological definition of "cargo cult" is entirely different: 2

Cargo cults are strange religious movements in the South Pacific that appeared during the last few decades. In these movements, a prophet announces the imminence of the end of the world in a cataclysm which will destroy everything. Then the ancestors will return, or God, or some other liberating power, will appear, bringing all the goods the people desire, and ushering in a reign of eternal bliss.

An anthropology encyclopedia gives a similar definition:

A southwest Pacific example of messianic or millenarian movements once common throughout the colonial world, the modal cargo cult was an agitation or organised social movement of Melanesian villagers in pursuit of ‘cargo’ by means of renewed or invented ritual action that they hoped would induce ancestral spirits or other powerful beings to provide. Typically, an inspired prophet with messages from those spirits persuaded a community that social harmony and engagement in improvised ritual (dancing, marching, flag-raising) or revived cultural traditions would, for believers, bring them cargo.

As you may see, the pop-culture explanation of a cargo cult and the anthropological definition are completely different, apart from the presence of "cargo" of some sort. Have anthropologists buried cargo cults under layers of theory? Are they even discussing the same thing? My conclusion, after researching many primary sources, is that the anthropological description accurately describes the wide variety of cargo cults. The pop-culture cargo cult description, however, takes features of some cargo cults (the occasional runway) and combines this with movie scenes to yield an inaccurate and fictionalized dscription. It may be hard to believe that the description of cargo cults that you see on the internet is mostly wrong, but in the remainder of this article, I will explain this in detail.

Background on Melanesia

Cargo cults occur in a specific region of the South Pacific called Melanesia. I'll give a brief (oversimplified) description of Melanesia to provide important background. The Pacific Ocean islands are divided into three cultural areas: Polynesia, Micronesia, and Melanesia. Polynesia is the best known, including Hawaii, New Zealand, and Samoa. Micronesia, in the northwest, consists of thousands of small islands, of which Guam is the largest; the name "Micronesia" is Greek for "small island". Melanesia, the relevant area for this article, is a group of islands between Micronesia and Australia, including Fiji, Vanuatu, Solomon Islands, and New Guinea. (New Guinea is the world's second-largest island; confusingly, the country of Papua New Guinea occupies the eastern half of the island, while the western half is part of Indonesia.)

Major cultural areas of Oceania. Image by https://commons.wikimedia.org/wiki/File:Pacific_Culture_Areas.jpg.

The inhabitants of Melanesia typically lived in small villages of under 200 people, isolated by mountainous geography. They had a simple, subsistence economy, living off cultivated root vegetables, pigs, and hunting. People tended their own garden, without specialization into particular tasks. The people of Melanesia are dark-skinned, which will be important ("Melanesia" and "melanin" have the same root). Technologically, the Melanesians used stone, wood, and shell tools, without knowledge of metallurgy or even weaving. The Melanesian cultures were generally violent3 with everpresent tribal warfare and cannibalism.4

Due to the geographic separation of tribes, New Guinea became the most linguistically diverse country in the world, with over 800 distinct languages. Pidgin English was often the only way for tribes to communicate, and is now one of the official languages of New Guinea. This language, called Tok Pisin (i.e. "talk pidgin"), is now the most common language in Papua New Guinea, spoken by over two-thirds of the population.5

For the Melanesians, religion was a matter of ritual, rather than a moral framework. It is said that "to the Melanesian, a religion is above all a technology: it is the knowledge of how to bring the community into the correct relation, by rites and spells, with the divinities and spirit-beings and cosmic forces that can make or mar man's this-worldly wealth and well-being." This is important since, as will be seen, the Melanesians expected that the correct ritual would result in the arrival of cargo. Catholic and Protestant missionaries converted the inhabitants to Christianity, largely wiping out traditional religious practices and customs; Melanesia is now over 95% Christian. Christianity played a large role in cargo cults, as will be shown below.

European explorers first reached Melanesia in the 1500s, followed by colonization.6 By the end of the 1800s, control of the island of New Guinea was divided among Germany, Britain, and the Netherlands. Britain passed responsibility to Australia in 1906 and Australia gained the German part of New Guinea in World War I. As for the islands of Vanuatu, the British and French colonized them (under the name New Hebrides) in the 18th century.

The influx of Europeans was highly harmful to the Melanesians. "Native society was severely disrupted by war, by catastrophic epidemics of European diseases, by the introduction of alcohol, by the devastation of generations of warfare, and by the depredations of the labour recruiters."8 People were kidnapped and forced to work as laborers in other countries, a practice called blackbirding. Prime agricultural land was taken by planters to raise crops such as coconuts for export, with natives coerced into working for the planters.9 Up until 1919, employers were free to flog the natives for disobedience; afterward, flogging was technically forbidden but still took place. Colonial administrators jailed natives who stepped out of line.7

Cargo cults before World War II

While the pop-culture cargo cults explains them as a reaction to World War II, cargo cults started years earlier. One anthropologist stated, "Cargo cults long preceded [World War II], continued to occur during the war, and have continued to the present."

The first writings about cargo cult behavior date back to 1919, when it was called the "Vailala Madness":10

The natives were saying that the spirits of their ancestors had appeared to several in the villages and told them that all flour, rice, tobacco, and other trade belonged to the New Guinea people, and that the white man had no right whatever to these goods; in a short time all the white men were to be driven away, and then everything would be in the hands of the natives; a large ship was also shortly to appear bringing back the spirits of their departed relatives with quantities of cargo, and all the villages were to make ready to receive them.

The 1926 book In Unknown New Guinea also describes the Vialala Madness:11

[The leader proclaimed] that the ancestors were coming back in the persons of the white people in the country and that all the things introduced by the white people and the ships that brought them belonged really to their ancestors and themselves. [He claimed that] he himself was King George and his friend was the Governor. Christ had given him this authority and he was in communication with Christ through a hole near his village.

The Melanesians blamed the Europeans for the failure of cargo to arrive. In the 1930s, one story was that because the natives had converted to Christianity, God was sending the ancestors with cargo that was loaded on ships. However, the Europeans were going through the cargo holds and replacing the names on the crates so the cargo was fraudulently delivered to the Europeans instead of the rightful natives.

The Mambu Movement occurred in 1937. Mambu, the movement's prophet, claimed that "the Whites had deceived the natives. The ancestors lived inside a volcano on Manum Island, where they worked hard making goods for their descendants: loin-cloths, socks, metal axes, bush-knives, flashlights, mirrors, red dye, etc., even plank-houses, but the scoundrelly Whites took the cargoes. Now this was to stop. The ancestors themselves would bring the goods in a large ship." To stop this movement, the Government arrested Mambu, exiled him, and imprisoned him for six months in 1938.

To summarize, these early cargo cults believed that ships would bring cargo that rightfully belonged to the natives but had been stolen by the whites. The return of the cargo would be accompanied by the spirits of the ancestors. Moreover, Christianity often played a large role. A significant racial component was present, with natives driving out the whites or becoming white themselves.

Cargo cults in World War II and beyond

World War II caused tremendous social and economic upheavals in Melanesia. Much of Melanesia was occupied by Japan near the beginning of the war and the Japanese treated the inhabitants harshly. The American entry into the war led to heavy conflict in the area such as the arduous New Guinea campaign (1942-1945) and the Solomon Islands campaign. As the Americans and Japanese battled for control of the islands, the inhabitants were caught in the middle. Papua and New Guinea suffered over 15,000 civilian deaths, a shockingly high number for such a small region.12

The photo shows a long line of F4F Wildcats at Henderson Field, Guadalcanal, Solomon Islands, April 14, 1943. Solomon Islands was home to several cargo cults, both before and after World War II (see map). Source: US Navy photo 80-G-41099.

The impact of the Japanese occupation on cargo cults is usually ignored. One example from 1942 is a cargo belief that the Japanese soldiers were spirits of the dead, who were being sent by Jesus to liberate the people from European rule. The Japanese would bring the cargo by airplane since the Europeans were blocking the delivery of cargo by ship. This would be accompanied by storms and earthquakes, and the natives' skin would change from black to white. The natives were to build storehouses for the cargo and fill the storehouses with food for the ancestors. The leader of this movement, named Tagarab, explained that he had an iron rod that gave him messages about the future. Eventually, the Japanese shot Tagarab, bringing an end to this cargo cult.13

The largest and most enduring cargo cult is the John Frum movement, which started on the island of Tanna around 1941 and continues to the present. According to one story, a mythical person known as John Frum, master of the airplanes, would reveal himself and drive off the whites. He would provide houses, clothes, and food for the people of Tanna. The island of Tanna would flatten as the mountains filled up the valleys and everyone would have perfect health. In other areas, the followers of John Frum believed they "would receive a great quantity of goods, brought by a white steamer which would come from America." Families abandoned the Christian villages and moved to primitive shelters in the interior. They wildly spent much of their money and threw the rest into the sea. The government arrested and deported the leaders, but that failed to stop the movement. The identity of John Frum is unclear; he is sometimes said to be a white American while in other cases natives have claimed to be John Frum.14

The cargo cult of Kainantu17 arose around 1945 when a "spirit wind" caused people in the area to shiver and shake. Villages built large "cargo houses" and put stones, wood, and insect-marked leaves inside, representing European goods, rifles, and paper letters respectively. They killed pigs and anointed the objects, the house, and themselves with blood. The cargo house was to receive the visiting European spirit of the dead who would fill the house with goods. This cargo cult continued for about 5 years, diminishing as people became disillusioned by the failure of the goods to arrive.

The name "Cargo Cult" was first used in print in 1945, just after the end of World War II.15 The article blamed the problems on the teachings of missionaries, with the problems "accentuated a hundredfold" by World War II.

Stemming directly from religious teaching of equality, and its resulting sense of injustice, is what is generally known as “Vailala Madness,” or “Cargo Cult.” "In all cases the "Madness" takes the same form: A native, infected with the disorder, states that he has been visited by a relative long dead, who stated that a great number of ships loaded with "cargo" had been sent by the ancestor of the native for the benefit of the natives of a particular village or area. But the white man, being very cunning, knows how to intercept these ships and takes the "cargo" for his own use... Livestock has been destroyed, and gardens neglected in the expectation of the magic cargo arriving. The natives infected by the "Madness" sank into indolence and apathy regarding common hygiene."

In a 1946 episode, agents of the Australian government found a group of New Guinea highlanders who believed that the arrival of the whites signaled that the end of the world was at hand. The highlanders butchered all their pigs in the expectation that "Great Pigs" would appear from the sky in three days. At this time, the residents would exchange their black skin for white skin. They created mock radio antennas of bamboo and rope to receive news of the millennium.16

The New York Times described Cargo Cults in 1948 as "the belief that a convoy of cargo ships is on its way, laden with the fruits of the modern world, to outfit the leaf huts of the natives." The occupants of the British Solomon Islands were building warehouses along the beaches to hold these goods. Natives marched into a US Army camp, presented $3000 in US money, and asked the Army to drive out the British.

A 1951 paper described cargo cults: "The insistence that a 'cargo' of European goods is to be sent by the ancestors or deceased spirits; this may or may not be part of a general reaction against Europeans, with an overtly expressed desire to be free from alien domination. Usually the underlying theme is a belief that all trade goods were sent by ancestors or spirits as gifts for their descendants, but have been misappropriated on the way by Europeans."17

In 1959, The New York Times wrote about cargo cults: "Rare Disease and Strange Cult Disturb New Guinea Territory; Fatal Laughing Sickness Is Under Study by Medical Experts—Prophets Stir Delusions of Food Arrivals". The article states that "large native groups had been infected with the idea that they could expect the arrival of spirit ships carrying large supplies of food. In false anticipation of the arrival of the 'cargoes', 5000 to 7000 native have been known to consume their entire food reserve and create a famine." As for "laughing sickness", this is now known to be a prion disease transmitted by eating human brains. In some communities, this disease, also called Kuru, caused 50% of all deaths.

A detailed 1959 article in Scientific American, "Cargo Cults", described many different cargo cults.16 It lists various features of cargo cults, such as the return of the dead, skin color switching from black to white, threats against white rule, and belief in a coming messiah. The article finds a central theme in cargo cults: "The world is about to end in a terrible cataclysm. Thereafter God, the ancestors or some local culture hero will appear and inaugurate a blissful paradise on earth. Death, old age, illness and evil will be unknown. The riches of the white man will accrue to the Melanesians."

In 1960, the celebrated naturalist David Attenborough created a documentary The People of Paradise: Cargo Cult.18 Attenborough travels through the island of Tanna and encounters many artifacts of the John Frum cult, such as symbolic gates and crosses, painted brilliant scarlet and decorated with objects such as a shaving brush, a winged rat, and a small carved airplane. Attenborough interviews a cult leader who claims to have talked with the mythical John Frum, said to be a white American. The leader remains in communication with John Frum through a tall pole said to be a radio mast, and an unseen radio. (The "radio" consisted of an old woman with electrical wire wrapper around her waist, who would speak gibberish in a trance.)

"Symbols of the cargo cult." In the center, a representation of John Frum with "scarlet coat and a white European face" stands behind a brilliantly painted cross. A wooden airplane is on the right, while on the left (outside the photo) a cage contains a winged rat. From Journeys to the Past, which describes Attenborough's visit to the island of Tanna.

In 1963, famed anthropologist Margaret Mead brought cargo cults to the general public, writing Where Americans are Gods: The Strange Story of the Cargo Cults in the mass-market newspaper supplement Family Weekly. In just over a page, this article describes the history of cargo cults before, during, and after World War II.19 One cult sat around a table with vases of colorful flowers on them. Another cult threw away their money. Another cult watched for ships from hilltops, expecting John Frum to bring a fleet of ships bearing cargo from the land of the dead.

One of the strangest cargo cults was a group of 2000 people on New Hanover Island, "collecting money to buy President Johnson of the United States [who] would arrive with other Americans on the liner Queen Mary and helicopters next Tuesday." The islanders raised $2000, expecting American cargo to follow the president. Seeing the name Johnson on outboard motors confirmed their belief that President Johnson was personally sending cargo.20

A 1971 article in Time Magazine22 described how tribesmen brought US Army concrete survey markers down from a mountaintop while reciting the Roman Catholic rosary, dropping the heavy markers outside the Australian government office. They expected that "a fleet of 500 jet transports would disgorge thousands of sympathetic Americans bearing crates of knives, steel axes, rifles, mirrors and other wonders." Time magazine explained the “cargo cult” as "a conviction that if only the dark-skinned people can hit on the magic formula, they can, without working, acquire all the wealth and possessions that seem concentrated in the white world... They believe that everything has a deity who has to be contacted through ritual and who only then will deliver the cargo." Cult leaders tried "to duplicate the white man’s magic. They hacked airstrips in the rain forest, but no planes came. They built structures that look like white men’s banks, but no money materialized."21

National Geographic, in an article Head-hunters in Today's World (1972), mentioned a cargo-cult landing field with a replica of a radio aerial, created by villagers who hoped that it would attract airplanes bearing gifts. It also described a cult leader in South Papua who claimed to obtain airplanes and cans of food from a hole in the ground. If the people believed in him, their skins would turn white and he would lead them to freedom.

These sources and many others23 illustrate that cargo cults do not fit a simple story. Instead, cargo cults are extremely varied, happening across thousands of miles and many decades. The lack of common features between cargo cults leads some anthropologists to reject the idea of cargo cults as a meaningful term.24 In any case, most historical cargo cults have very little in common with the pop-culture description of a cargo cult.

Cargo beliefs were inspired by Christianity

Cargo cult beliefs are closely tied to Christianity, a factor that is ignored in pop-culture descriptions of cargo cults. Beginning in the mid-1800s, Christian missionaries set up churches in New Guinea to convert the inhabitants. As a result, cargo cults incorporated Christian ideas, but in very confusing ways. At first, the natives believed that missionaries had come to reveal the ritual secrets and restore the cargo. By enthusiastically joining the church, singing the hymns, and following the church's rituals, the people would be blessed by God, who would give them the cargo. This belief was common in the 1920s and 1930s, but as the years went on and the people didn't receive the cargo, they theorized that the missionaries had removed the first pages of the Bible to hide the cargo secrets.

A typical belief was that God created Adam and Eve in Paradise, "giving them cargo: tinned meat, steel tools, rice in bags, tobacco in tins, and matches, but not cotton clothing." When Adam and Eve offended God by having sexual intercourse, God threw them out of Paradise and took their cargo. Eventually, God sent the Flood but Noah was saved in a steamship and God gave back the cargo. Noah's son Ham offended God, so God took the cargo away from Ham and sent him to New Guinea, where he became the ancestor of the natives.

Other natives believed that God lived in Heaven, which was in the clouds and reachable by ladder from Sydney, Australia (source). God, along with the ancestors, created cargo in Heaven—"tinned meat, bags of rice, steel tools, cotton cloth, tinned tobacco, and a machine for making electric light"—which would be flown from Sydney and delivered to the natives, who thus needed to clear an airstrip (source).25

Another common belief was that symbolic radios could be used to communicate with Jesus. For instance, a Markham Valley cargo group in 1943 created large radio houses so they could be informed of the imminent Coming of Jesus, at which point the natives would expel the whites (source). The "radio" consisted of bamboo cylinders connected to a rope "aerial" strung between two poles. The houses contained a pole with rungs so the natives could climb to Jesus along with cane "flashlights" to see Jesus.

A tall mast with a flag and cross on top. This was claimed to be a special radio mast that enabled communication with John Frum. It was decorated with scarlet leaves and flowers. From Attenborough's Cargo Cult.

Mock radio antennas are also discussed in a 1943 report26 from a wartime patrol that found a bamboo "wireless house", 42 feet in diameter. It had two long poles outside and with an "aerial" of rope between them, connected to the "radio" inside, a bamboo cylinder. Villagers explained that the "radio" was to receive messages of the return of Jesus, who would provide weapons for the overthrow of white rule. The villagers constructed ladders outside the house so they could climb up to the Christian God after death. They would shed their skin like a snake, getting a new white skin, and then they would receive the "boats and white men's clothing, goods, etc."

Mondo Cane and the creation of the pop-culture cargo cult

As described above, cargo cults expected the cargo to arrive by ships much more often than airplanes. So why do pop-culture cargo cults have detailed descriptions of runways, airplanes, wooden headphones, and bamboo control towers?27 My hypothesis is that it came from a 1962 movie called Mondo Cane. This film was the first "shockumentary", showing extreme and shocking scenes from around the world. Although the film was highly controversial, it was shown at the Cannes Film Festival and was a box-office success.

The film made extensive use of New Guinea with multiple scandalous segments, such as a group of "love-struck" topless women chasing men,29 a woman breastfeeding a pig, and women in cages being fattened for marriage. The last segment in the movie showed "the cult of the cargo plane": natives forlornly watching planes at the airport, followed by scenes of a bamboo airplane sitting on a mountaintop "runway" along with bamboo control towers. The natives waited all day and then lit torches to illuminate the runway at nightfall. These scenes are very similar to the pop-culture descriptions of cargo cults so I suspect this movie is the source.

A still from the 1962 movie "Mondo Cane", showing a bamboo airplane sitting on a runway, with flaming torches acting as beacons. I have my doubts about its accuracy.

The film claims that all the scenes "are true and taken only from life", but many of the scenes are said to be staged. Since the cargo cult scenes are very different from anthropological reports and much more dramatic, I think they were also staged and exaggerated.28 It is known that the makers of Mondo Cane paid the Melanesian natives generously for the filming (source, source).

Did Feynman get his cargo cult ideas from Mondo Cane? It may seem implausible since the movie was released over a decade earlier. However, the movie became a cult classic, was periodically shown in theaters, and influenced academics.30 In particular, Mondo Cane showed at the famed Cameo theater in downtown Los Angeles on April 3, 1974, two months before Feynman's commencement speech. Mondo Cane seems like the type of offbeat movie that Feynman would see and the theater was just 11 miles from Caltech. While I can't prove that Feynman went to the showing, his description of a cargo cult strongly resembles the movie.31

Fake cargo-cult photos fill the internet

Fakes and hoaxes make researching cargo cults online difficult. There are numerous photos online of cargo cults, but many of these photos are completely made up. For instance, the photo below has illustrated cargo cults for articles such as Cargo Cult, UX personas are useless, A word on cargo cults, The UK Integrated Review and security sector innovation, and Don't be a cargo cult. However, this photo is from a Japanese straw festival and has nothing to do with cargo cults.

An airplane built from straw, one creation at a Japanese straw festival. I've labeled the photo with "Not cargo cult" to ensure it doesn't get reused in cargo cult articles.

Another example is the photo below, supposedly an antenna created by a cargo cult. However, it is actually a replica of the Jodrell Bank radio telescope, built in 2007 by a British farmer from six tons of straw (details). The farmer's replica ended up erroneously illustrating Cargo Cult Politics, The Cargo Cult & Beliefs, The Cargo Cult, Cargo Cults of the South Pacific, and Cargo Cult, among others.32

A British farmer created this replica radio telescope. Photo by Mike Peel, (CC BY-SA 4.0).

Other articles illustrate cargo cults with the aircraft below, suspiciously sleek and well-constructed. However, the photo actually shows a wooden wind tunnel model of the Buran spacecraft, abandoned at a Russian airfield as described in this article. Some uses of the photo are Are you guilty of “cargo cult” thinking without even knowing it? and The Cargo Cult of Wealth.

This is an abandoned Soviet wind tunnel model of the Buran spacecraft. Photo by Aleksandr Markin.

Many cargo cult articles use one of the photo below. I tracked them down to the 1970 movie "Chariots of the Gods" (link), a dubious documentary claiming that aliens have visited Earth throughout history. The segment on cargo cults is similar to Mondo Cane with cultists surrounding a mock plane on a mountaintop, lighting fires along the runway. However, it is clearly faked, probably in Africa: the people don't look like Pacific Islanders and are wearing wigs. One participant wears leopard skin (leopards don't live in the South Pacific). The vegetation is another giveaway: the plants are from Africa, not the South Pacific.33

Two photos of a straw plane from "Chariots of the Gods".

The point is that most of the images that illustrate cargo cults online are fake or wrong. Most internet photos and information about cargo cults have just been copied from page to page. (And now we have AI-generated cargo cult photos.) If a photo doesn't have a clear source (including who, when, and where), don't believe it.

Conclusions

The cargo cult metaphor should be avoided for three reasons. First, the metaphor is essentially meaningless and heavily overused. The influential "Jargon File" defined cargo-cult programming as "A style of (incompetent) programming dominated by ritual inclusion of code or program structures that serve no real purpose."34 Note that the metaphor in cargo-cult programming is the opposite of the metaphor in cargo-cult science: Feyman's cargo-cult science has no chance of working, while cargo-cult programming works but isn't understood. Moreover, both metaphors differ from the cargo-cult metaphor in other contexts, referring to the expectation of receiving valuables without working.35

The popular site Hacker News is an example of how "cargo cult" can be applied to anything: agile programming, artificial intelligence, cleaning your desk. Go, hatred of Perl, key rotation, layoffs, MBA programs, microservices, new drugs, quantum computing, static linking, test-driven development, and updating the copyright year are just a few things that are called "cargo cult".36 At this point, cargo cult is simply a lazy, meaningless attack.

The second problem with "cargo cult" is that the pop-culture description of cargo cults is historically inaccurate. Actual cargo cults are much more complex and include a much wider (and stranger) variety of behaviors. Cargo cults started before World War II and involve ships more often than airplanes. Cargo cults mix aspects of paganism and Christianity, often with apocalyptic ideas of the end of the current era, the overthrow of white rule, and the return of dead ancestors. The pop-culture description discards all this complexity, replacing it with a myth.

Finally, the cargo cult metaphor turns decades of harmful colonialism into a humorous anecdote. Feynman's description of cargo cults strips out the moral complexity: US soldiers show up with their cargo and planes, the indigenous residents amusingly misunderstand the situation, and everyone carries on. However, cargo cults really were a response to decades of colonial mistreatment, exploitation, and cultural destruction. Moreover, cargo cults were often harmful: expecting a bounty of cargo, villagers would throw away their money, kill their pigs, and stop tending their crops, resulting in famine. The pop-culture cargo cult erases the decades of colonial oppression, along with the cultural upheaval and deaths from World War II. Melanesians deserve to be more than the punch line in a cargo cult story.

Thus, it's time to move beyond the cargo cult metaphor.

Update: well, this sparked much more discussion on Hacker News than I expected. To answer some questions: Am I better or more virtuous than other people? No. Are you a bad person if you use the cargo cult metaphor? No. Is "cargo cult" one of many Hacker News comments that I'm tired of seeing? Yes (details). Am I criticizing Feynman? No. Do the Melanesians care about this? Probably not. Did I put way too much research into this? Yes. Is criticizing colonialism in the early 20th century woke? I have no response to that.

Notes and references

1. As an illustration of the popularity of Feynman's "Cargo Cult Science" commencement address, it has been on Hacker News at least 15 times. ↩

2. The first cargo cult definition above comes from The Trumpet Shall Sound; A Study of "Cargo" Cults in Melanesia. The second definition is from the Cargo Cult entry in The Open Encyclopedia of Anthropology. Written by Lamont Lindstrom, a professor who studies Melanesia, the entry comprehensively describes the history and variety of cargo cults, as well as current anthropological analysis.

   For an early anthropological theory of cargo cults, see An Empirical Case-Study: The Problem of Cargo Cults in "The Revolution in Anthropology" (Jarvie, 1964). This book categorizes cargo cults as an apocalyptic millenarian religious movement with a central tenet:

   When the millennium comes it will largely consist of the arrival of ships and/or aeroplanes loaded up with cargo; a cargo consisting either of material goods the natives long for (and which are delivered to the whites in this manner), or of the ancestors, or of both.

    ↩

3. European colonization brought pacification and a reduction in violence. The Cargo Cult: A Melanesian Type-Response to Change describes this pacification and termination of warfare as the Pax Imperii, suggesting that pacification came as a relief to the Melanesians: "They welcomed the cessation of many of the concomitants of warfare: the sneak attack, ambush, raiding, kidnapping of women and children, cannibalism, torture, extreme indignities inflicted on captives, and the continual need to be concerned with defense." That article calls the peace the Pax Imperii.

   Warfare among the Enga people of New Guinea is described in From Spears to M-16s: Testing the Imbalance of Power Hypothesis among the Enga. The Enga engaged in tribal warfare for reasons such as "theft of game from traps, quarrels over possessions, or work sharing within the group." The surviving losers were usually driven off the land and forced to settle elsewhere. In the 1930s and 1940s, the Australian administration banned tribal fighting and pacified much of the area. However, after the independence of Papua New Guinea in 1975, warfare increased along with the creation of criminal gangs known as Raskols (rascals). The situation worsened in the late 1980s with the introduction of shotguns and high-powered weapons to warfare. Now, Papua New Guinea has one of the highest crime rates in the world along with one of the lowest police-to-population ratios in the world. ↩

4. When you hear tales of cannibalism, some skepticism is warranted. However, cannibalism is proved by the prevalence of kuru, or "laughing sickness", a fatal prion disease (transmissible spongiform encephalopathy) spread by consuming human brains. Also see Headhunters in Today's World, a 1972 National Geographic article that describes the baking of heads and the eating of brains. ↩

5. A 1957 dictionary of Pidgin English can be found here. Linguistically, Tok Pisin is a creole, not a pidgin. ↩

6. The modern view is that countries such as Great Britain acquired colonies against the will of the colonized, but the situation was more complex in the 19th century. Many Pacific islands desperately wanted to become European colonies, but were turned down for years because the countries were viewed as undesiable burdens.

   For example, Fiji viewed colonization as the solution to the chaos caused by the influx of white settlers in the 1800s. Fijian political leaders attempted to cede the islands to a European power that could end the lawlessness, but were turned down. In 1874, the situation changed when Disraeli was elected British prime minister. His pro-imperial policies, along with the Royal Navy's interest in obtaining a coaling station, concerns about American expansion, and pressure from anti-slavery groups, led to the annexation of Fiji by Britain. The situation in Fiji didn't particularly improve from annexation. (Fiji obtained independence almost a century later, in 1970.)

   As an example of the cost of a colony, Australia was subsidizing Papua New Guinea (with a population of 2.5 million) with over 100 million dollars a year in the early 1970s. (source) ↩

7. When reading about colonial Melanesia, one notices a constant background of police activity. Even when police patrols were very rare (annual in some parts), they were typically accompanied by arbitrary arrests and imprisonment. The most common cause for arrest was adultery; it may seem strange that the police were so concerned with it, but it turns out that adultery was the most common cause of warfare between tribes, and the authorities were trying to reduce the level of warfare. Cargo cult activity could be punished by six months of imprisonment. Jailing tended to be ineffective in stopping cargo cults, however, as it was viewed as evidence that the Europeans were trying to stop the cult leaders from spreading the cargo secrets that they had uncovered. ↩

8. See The Trumpet Shall Sound. ↩

9. The government imposed a head tax, which for the most part could only be paid through employment. A 1924 report states, "The primary object of the head tax was not to collect revenue but to create among the natives a need for money, which would make labour for Europeans desirable and would force the natives to accept employment." ↩

10. The Papua Annual Report, 1919-20 includes a report on the "Vailala Madness", starting on page 118. It describes how villages with the "Vialala madness" had "ornamented flag-poles, long tables, and forms or benches, the tables being usually decorated with flowers in bottles of water in imitation of a white man's dining table." Village men would sit motionless with their backs to the tables. Their idleness infuriated the white men, who considered the villagers to be "fit subjects for a lunatic asylum." ↩

11. The Vailala Madness is also described in The Missionary Review of the World, 1924. The Vaialala Madness also involved seizure-like physical aspects, which typically didn't appear in later cargo cult behavior.

    The 1957 book The Trumpet Shall Sound: A Study of "Cargo" Cults in Melanesia is an extensive discussion of cargo cults, as well as earlier activity and movements. Chapter 4 covers the Vailala Madness in detail. ↩

12. The battles in the Pacific have been extensively described from the American and Japanese perspectives, but the indigenous residents of these islands are usually left out of the narratives. This review discusses two books that provide the Melanesian perspective.

    I came across the incredible story of Sergeant Major Vouza of the Native Constabulary. While this story is not directly related to cargo cults, I wanted to include it as it illustrates the dedication and suffering of the New Guinea natives during World War II. Vouza volunteered to scout behind enemy lines for the Marines at Guadalcanal but he was captured by the Japanese, tied to a tree, tortured, bayonetted, and left for dead. He chewed through his ropes, made his way through the enemy force, and warned the Marines of an impending enemy attack.

    

    SgtMaj Vouza, British Solomon Islands Constabulary. From The Guadalcanal Campaign, 1949.

    Vouza described the event in a letter:

    

    Letter from SgtMaj Vouza to Hector MacQuarrie, 1984. From The Guadalcanal Campaign.

     ↩

13. The Japanese occupation and the cargo cult started by Tagareb are described in detail in Road Belong Cargo, pages 98-110. ↩

14. See "John Frum Movement in Tanna", Oceania, March 1952. The New York Times described the John Frum movement in detail in a 1970 article: "On a Pacific island, they wait for the G.I. who became a God". A more modern article (2006) on John Frum is In John They Trust in the Smithsonian Magazine.

    As for the identity of John Frum, some claim that his name is short for "John from America". Others claim it is a modification of "John Broom" who would sweep away the whites. These claims lack evidence. ↩

15. The quote is from Pacific Islands Monthly, November 1945 (link). The National Library of Australia has an extensive collection of issues of Pacific Islands Monthly online. Searching these magazines for "cargo cult" provides an interesting look at how cargo cults were viewed as they happened. ↩

16. Scientific American had a long article titled Cargo Cults in May 1959, written by Peter Worsley, who also wrote the classic book The Trumpet Shall Sound: A Study of 'Cargo' Cults in Melanesia. The article lists the following features of cargo cults:

    • Myth of the return of the dead
    • Revival or modification of paganism
    • Introduction of Christian elements
    • Cargo myth
    • Belief that Negroes will become white men and vice versa
    • Belief in a coming messiah
    • Attempts to restore native political and economic control
    • Threats and violence against white men
    • Union of traditionally separate and unfriendly groups

    Different cargo cults contained different subsets of these features but no specific feature The article is reprinted here; the detailed maps show the wide distribution of cargo cults. ↩↩

17. See A Cargo Movement in the Eastern Central Highlands of New Guinea, Oceania, 1952. ↩↩

18. The Attenborough Cargo Cult documentary can be watched on YouTube.

    I'll summarize some highlights with timestamps:
    5:20: A gate, palisade, and a cross all painted brilliant red.
    6:38: A cross decorated with a wooden bird and a shaving brush.
    7:00: A tall pole claimed to be a special radio mast to talk with John Frum.
    8:25: Interview with trader Bob Paul. He describes "troops" marching with wooden guns around the whole island.
    12:00: Preparation and consumption of kava, the intoxicating beverage.
    13:08: Interview with a local about John Frum.
    14:16: John Frum described as a white man and a big fellow.
    16:29: Attenborough asks, "You say John Frum has not come for 19 years. Isn't this a long time for you to wait?" The leader responds, "No, I can wait. It's you waiting for two thousand years for Christ to come and I must wait over 19 years." Attenborough accepts this as a fair point.
    17:23: Another scarlet gate, on the way to the volcano, with a cross, figure, and model airplane.
    22:30: Interview with the leader. There's a discussion of the radio, but Attenborough is not allowed to see it.
    24:21: John Frum is described as a white American.

    The expedition is also described in David Attenborough's 1962 book Quest in Paradise.  ↩

19. I have to criticize Mead's article for centering Americans as the heroes, almost a parody of American triumphalism. The title sets the article's tone: "Where Americans are Gods..." The article explains, "The Americans were lavish. They gave away Uncle Sam's property with a generosity which appealed mightily... so many kind, generous people, all alike, with such magnificent cargoes! The American servicemen, in turn, enjoyed and indulged the islanders."

    The article views cargo cults as a temporary stage before moving to a prosperous American-style society as islanders realized that "American things could come [...] only by work, education, persistence." A movement leader named Paliau is approvingly quoted: "We would like to have the things Americans have. [...] We think Americans have all these things because they live under law, without endless quarrels. So we must first set up a new society."

    On the other hand, by most reports, the Americans treated the residents of Melanesia much better than the colonial administrators. Americans paid the natives much more (which was viewed as overpaying them by the planters). The Americans treated the natives with much more respect; natives worked with Americans almost as equals. Finally, it appeared to the natives that black soldiers were treated as equals to white soldiers. (Obviously, this wasn't entirely accurate.)

    The Melanesian experience with Americans also strengthened Melanesian demands for independence. Following the war, the reversion to colonial administration produced a lot of discontent in the natives, who realized that their situation could be much better. (See World War II and Melanesian self-determination.) ↩

20. The Johnson cult was analyzed in depth by Billings, an anthropologist who wrote about it in Cargo Cult as Theater: Political Performance in the Pacific. See also Australian Daily News, June 12, 1964, and Time Magazine, July 19, 1971. ↩

21. In one unusual case, the islanders built an airstrip and airplanes did come. Specifically, the Miyanmin people of New Guinea hacked an airstrip out of the forest in 1966 using hand tools. The airstrip was discovered by a patrol and turned out to be usable, so Baptist missionaries made monthly landings, bringing medicine and goods for a store. It is pointed out that the only thing preventing this activity from being considered a cargo cult is that in this case, it was effective. See A Small Footnote to the 'Big Walk', p. 59. ↩

22. See "New Guinea: Waiting for That Cargo", Time Magazine, July 19, 1971.  ↩

23. In this footnote, I'll list some interesting cargo cult stories that didn't fit into the body of the article.

    The 1964 US Bureau of Labor Statistics report on New Guinea describes cargo cults: "A simplified explanation of them is often given namely that contact with Western culture has given the indigene a desire for a better economic standard of living this desire has not been accompanied by the understanding that economic prosperity is achieved by human effort. The term cargo cult derives from the mystical expectation of the imminent arrival by sea or air of the good things of this earth. It is believed sufficient to build warehouses of leaves and prepare air strips to receive these goods. Activity in the food gardens and daily community routine chores is often neglected so that economic distress is engendered."

    Cargo Cult Activity in Tangu (Burridge) is a 1954 anthropological paper discussing stories of three cargo cults in Tangu, a region of New Guinea. The first involved dancing around a man in a trance, which was supposed to result in the appearance of "rice, canned meat, lava-lavas, knives, beads, etc." In the second story, villagers built a shed in a cemetery and then engaged in ritualized sex acts, expecting the shed to be filled with goods. However, the authorities forced the participants to dismantle the shed and throw it into the sea. In the third story, the protagonist is Mambu, who stowed away on a steamship to Australia, where he discovered the secrets of the white man's cargo. On his return, he collected money to help force the Europeans out, until he was jailed. He performed "miracles" by appearing outside jail as well as by producing money out of thin air.

    Reaction to Contact in the Eastern Highlands of New Guinea (Berndt, 1954) has a long story about Berebi, a leader who was promised a rifle, axes, cloth, knives, and valuable cowrie by a white spirit. Berebi convinces his villagers to build storehouses and they filled the houses with stones that would be replaced by goods. They take part in many pig sacrifices and various rituals, and endure attacks of shivering and paralysis, but they fail to receive any goods and Berebi concludes that the spirit deceived him. ↩

24. Many anthropologists view the idea of cargo cults as controversial. One anthropologist states, "What I want to suggest here is that, similarly, cargo cults do not exist, or at least their symptoms vanish when we start to doubt that we can arbitrarily extract a few features from context and label them an institution." See A Note on Cargo Cults and Cultural Constructions of Change (1988). The 1992 paper The Yali Movement in Retrospect: Rewriting History, Redefining 'Cargo Cult' summarizes the uneasiness that many anthropologists have with the term "cargo cult", viewing it as "tantamount to an invocation of colonial power relationships."

    The book Cargo, Cult, and Culture Critique (2004) states, "Some authors plead quite convincingly for the abolition of the term itself, not only because of its troublesome implications, but also because, in their view, cargo cults do not even exist as an identifiable object of study." One paper states that the phrase is both inaccurate and necessary, proposing that it be written crossed-out (sous rature in Derrida's post-modern language). Another paper states: "Cargo cults defy definition. They are inherently troublesome and problematic," but concludes that the term is useful precisely because of this troublesome nature.

    At first, I considered the idea of abandoning the label "cargo cult" to be absurd, but after reading the anthropological arguments, it makes more sense. In particular, the category "cargo cult" is excessively broad, lumping together unrelated things and forcing them into a Procrustean ideal: John Frum has very little in common with Vaialala Madness, let alone the Johnson Cult. I think that the term "cargo cult" became popular due to its catchy, alliterative name. (Journalists love alliterations such as "Digital Divide" or "Quiet Quitting".) ↩

25. It was clear to the natives that the ancestors, and not the Europeans, must have created the cargo because the local Europeans were unable to repair complex mechanical devices locally, but had to ship them off. These ships presumably took the broken devices back to the ancestral spirits to be repaired. Source: The Trumpet Shall Sound, p119. ↩

26. The report from the 1943 patrol is discussed in Berndt's "A Cargo Movement in the Eastern Central Highlands of New Guinea", Oceania, Mar. 1953 (link), page 227. These radio houses are also discussed in The Trumpet Shall Sound, page 199. ↩

27. Wooden airplanes are a staple of the pop-culture cargo cult story, but they are extremely rare in authentic cargo cults. I searched extensively, but could find just a few primary sources that involve airplanes.

    The closest match that I could find is Vanishing Peoples of the Earth, published by National Geographic in 1968, which mentions a New Guinea village that built a "crude wooden airplane", which they thought "offers the key to getting cargo".

    The photo below, from 1950, shows a cargo-house built in the shape of an airplane. (Note how abstract the construction is, compared to the realistic straw airplanes in faked photos.) The photographer mentioned that another cargo house was in the shape of a jeep, while in another village, the villagers gather in a circle at midnight to await the arrival of heavily laden cargo boats.

    

    The photo is from They Still Believe in Cargo Cult, Pacific Islands Monthly, May 1950.

    David Attenborough's Cargo Cult documentary shows a small wooden airplane, painted scarlet red. This model airplane is very small compared to the mock airplanes described in the pop-culture cargo cult.

    

    A closeup of the model airplane. From Attenborough's Cargo Cult documentary.

    The photo below shows the scale of the aircraft, directly in front of Attenborough. In the center, a figure of John Frum has a "scarlet coat and a white, European face." On the left, a cage contains a winged rat for some reason.

    

    David Attenborough visiting a John Frum monument on Tanna, near Sulfur Bay. From Attenborough's Cargo Cult documentary.

     ↩

28. The photo below shows another scene from the movie Mondo Cane that is very popular online in cargo cult articles. I suspect that the airplane is not authentic but was made for the movie.

    

    Screenshot from Mondo Cane, showing the cargo cultists posed in front of their airplane.

     ↩

29. The tale of women pursuing men was described in detail in the 1929 anthropological book The Sexual Life of Savages in North-Western Melanesia, specifically the section "Yausa—Orgiastic Assaults by Women" (pages 231-234). The anthropologist heard stories about these attacks from natives, but didn't observe them firsthand and remained skeptical. He concluded that "The most that can be said with certainty is that the yausa, if it happened at all, happened extremely rarely". Unlike the portrayal in Mondo Cane, these attacks on men were violent and extremely unpleasant (I won't go into details). Thus, it is very likely that this scene in Mondo Cane was staged, based on the stories. ↩

30. The movie Mondo Cane directly influenced the pop-culture cargo cult as shown by several books. The book River of Tears: The Rise of the Rio Tinto-Zinc Mining Corporation explains cargo cults and how one tribe built an "aeroplane on a hilltop to attract the white man's aeroplane and its cargo", citing Mondo Cane. Likewise, the book Introducing Social Change states that underdeveloped nations are moving directly from ships to airplanes without building railroads, bizarrely using the cargo cult scene in Mondo Cane as an example. Finally, the religious book Open Letter to God uses the cargo cult in Mondo Cane as an example of the suffering of godless people. ↩

31. Another possibility is that Feynman got his cargo cult ideas from the 1974 book Cows, Pigs, Wars and Witches: The Riddle of Culture. It has a chapter "Phantom Cargo", which starts with a description suspiciously similar to the scene in Mondo Cane:

    The scene is a jungle airstrip high in the mountains of New Guinea. Nearby are thatch-roofed hangars, a radio shack, and a beacon tower made of bamboo. On the ground is an airplane made of sticks and leaves. The airstrip is manned twenty-four hours a day by a group of natives wearing nose ornaments and shell armbands. At night they keep a bonfire going to serve as a beacon. They are expecting the arrival of an important flight: cargo planes filled with canned food, clothing, portable radios, wrist watches, and motorcycles. The planes will be piloted by ancestors who have come back to life. Why the delay? A man goes inside the radio shack and gives instructions into the tin-can microphone. The message goes out over an antenna constructed of string and vines: “Do you read me? Roger and out.” From time to time they watch a jet trail crossing the sky; occasionally they hear the sound of distant motors. The ancestors are overhead! They are looking for them. But the whites in the towns below are also sending messages. The ancestors are confused. They land at the wrong airport.

     ↩

32. Some other uses of the radio telescope photo as a cargo-cult item are Cargo cults, Melanesian cargo cults and the unquenchable thirst of consumerism, Cargo Cult : Correlation vs. Causation, Cargo Cult Agile, Stop looking for silver bullets, and Cargo Cult Investing. ↩

33. Chariots of the Gods claims to be showing a cargo cult from an isolated island in the South Pacific. However, the large succulent plants in the scene are Euphorbia ingens and tree aloe, which grow in southern Africa, not the South Pacific. The rock formations at the very beginning look a lot like Matobo Hills in Zimbabwe. Note that these "Stone Age" people are astounded by the modern world but ignore the cameraman who is walking among them.

    Many cargo cults articles use photos that can be traced back from this film, such as The Scrum Cargo Cult, Is Your UX Cargo Cult, The Remote South Pacific Island Where They Worship Planes, The Design of Everyday Games, Don’t be Fooled by the Bitcoin Core Cargo Cult, The Dying Art of Design, Retail Apocalypse Not, You Are Not Google, and Cargo Cults. The general theme of these articles is that you shouldn't copy what other people are doing without understanding it, which is somewhat ironic. ↩

34. The Jargon File defined "cargo-cult programming" in 1991:

    cargo-cult programming: n. A style of (incompetent) programming dominated by ritual inclusion of code or program structures that serve no real purpose. A cargo-cult programmer will usually explain the extra code as a way of working around some bug encountered in the past, but usually, neither the bug nor the reason the code avoided the bug were ever fully understood.

    The term cargo-cult is a reference to aboriginal religions that grew up in the South Pacific after World War II. The practices of these cults center on building elaborate mockups of airplanes and military style landing strips in the hope of bringing the return of the god-like airplanes that brought such marvelous cargo during the war. Hackish usage probably derives from Richard Feynman's characterization of certain practices as "cargo-cult science" in `Surely You're Joking, Mr. Feynman'.

    This definition of "cargo-cult programming" came from a 1991 Usenet post to alt.folklore.computers, quoting Kent Williams. The definition was added to the much-expanded 1991 Jargon File, which was published as The New Hacker's Dictionary in 1993. ↩

35. Overuse of the cargo cult metaphor isn't specific to programming, of course. The book Cargo Cult: Strange Stories of Desire from Melanesia and Beyond describes how "cargo cult" has been applied to everything from advertisements, social welfare policy, and shoplifting to the Mormons, Euro Disney, and the state of New Mexico.

    This book, by Lamont Linstrom, provides a thorough analysis of writings on cargo cults. It takes a questioning, somewhat trenchant look at these writings, illuminating the development of trends in these writings and the lack of objectivity. I recommend this book to anyone interested in the term "cargo cult" and its history. ↩

36. Some more things that have been called "cargo cult" on Hacker News: the American worldview, ChatGPT fiction, copy and pasting code, hiring, HR, priorities, psychiatry, quantitative tests, religion, SSRI medication, the tech industry, Uber, and young-earth creationism. ↩

Pi in the Pentium: reverse-engineering the constants in its floating-point unit

Intel released the powerful Pentium processor in 1993, establishing a long-running brand of high-performance processors.1 The Pentium includes a floating-point unit that can rapidly compute functions such as sines, cosines, logarithms, and exponentials. But how does the Pentium compute these functions? Earlier Intel chips used binary algorithms called CORDIC, but the Pentium switched to polynomials to approximate these transcendental functions much faster. The polynomials have carefully-optimized coefficients that are stored in a special ROM inside the chip's floating-point unit. Even though the Pentium is a complex chip with 3.1 million transistors, it is possible to see these transistors under a microscope and read out these constants. The first part of this post discusses how the floating point constant ROM is implemented in hardware. The second part explains how the Pentium uses these constants to evaluate sin, log, and other functions.

The photo below shows the Pentium's thumbnail-sized silicon die under a microscope. I've labeled the main functional blocks; the floating-point unit is in the lower right. The constant ROM (highlighted) is at the bottom of the floating-point unit. Above the floating-point unit, the microcode ROM holds micro-instructions, the individual steps for complex instructions. To execute an instruction such as sine, the microcode ROM directs the floating-point unit through dozens of steps to compute the approximation polynomial using constants from the constant ROM.

Die photo of the Intel Pentium processor with the floating point constant ROM highlighted in red. Click this image (or any other) for a larger version.

Finding pi in the constant ROM

In binary, pi is 11.00100100001111110... but what does this mean? To interpret this, the value 11 to the left of the binary point is simply 3 in binary. (The "binary point" is the same as a decimal point, except for binary.) The digits to the right of the binary point have the values 1/2, 1/4, 1/8, and so forth. Thus, the binary value `11.001001000011... corresponds to 3 + 1/8 + 1/64 + 1/4096 + 1/8192 + ..., which matches the decimal value of pi. Since pi is irrational, the bit sequence is infinite and non-repeating; the value in the ROM is truncated to 67 bits and stored as a floating point number.

A floating point number is represented by two parts: the exponent and the significand. Floating point numbers include very large numbers such as 6.02×10²³ and very small numbers such as 1.055×10⁻³⁴. In decimal, 6.02×10²³ has a significand (or mantissa) of 6.02, multiplied by a power of 10 with an exponent of 23. In binary, a floating point number is represented similarly, with a significand and exponent, except the significand is multiplied by a power of 2 rather than 10. For example, pi is represented in floating point as 1.1001001...×2¹.

The diagram below shows how pi is encoded in the Pentium chip. Zooming in shows the constant ROM. Zooming in on a small part of the ROM shows the rows of transistors that store the constants. The arrows point to the transistors representing the bit sequence 11001001, where a 0 bit is represented by a transistor (vertical white line) and a 1 bit is represented by no transistor (solid dark silicon). Each magnified black rectangle at the bottom has two potential transistors, storing two bits. The key point is that by looking at the pattern of stripes, we can determine the pattern of transistors and thus the value of each constant, pi in this case.

A portion of the floating-point ROM, showing the value of pi. Click this image (or any other) for a larger version.

The bits are spread out because each row of the ROM holds eight interleaved constants to improve the layout. Above the ROM bits, multiplexer circuitry selects the desired constant from the eight in the activated row. In other words, by selecting a row and then one of the eight constants in the row, one of the 304 constants in the ROM is accessed. The ROM stores many more digits of pi than shown here; the diagram shows 8 of the 67 significand bits.

Implementation of the constant ROM

The ROM is built from MOS (metal-oxide-semiconductor) transistors, the transistors used in all modern computers. The diagram below shows the structure of an MOS transistor. An integrated circuit is constructed from a silicon substrate. Regions of the silicon are doped with impurities to create "diffusion" regions with desired electrical properties. The transistor can be viewed as a switch, allowing current to flow between two diffusion regions called the source and drain. The transistor is controlled by the gate, made of a special type of silicon called polysilicon. Applying voltage to the gate lets current flow between the source and drain, which is otherwise blocked. Most computers use two types of MOS transistors: NMOS and PMOS. The two types have similar construction but reverse the doping; NMOS uses n-type diffusion regions as shown below, while PMOS uses p-type diffusion regions. Since the two types are complementary (C), circuits built with the two types of transistors are called CMOS.

Structure of a MOSFET in an integrated circuit.

The image below shows how a transistor in the ROM looks under the microscope. The pinkish regions are the doped silicon that forms the transistor's source and drain. The vertical white line is the polysilicon that forms the transistor's gate. For this photo, I removed the chip's three layers of metal, leaving just the underlying silicon and the polysilicon. The circles in the source and drain are tungsten contacts that connect the silicon to the metal layer above.

One transistor in the constant ROM.

The diagram below shows eight bits of storage. Each of the four pink silicon rectangles has two potential transistors. If a polysilicon gate crosses the silicon, a transistor is formed; otherwise there is no transistor. When a select line (horizontal polysilicon) is energized, it will turn on all the transistors in that row. If a transistor is present, the corresponding ROM bit is 0 because the transistor will pull the output line to ground. If a transistor is absent, the ROM bit is 1. Thus, the pattern of transistors determines the data stored in the ROM. The ROM holds 26144 bits (304 words of 86 bits) so it has 26144 potential transistors.

Eight bits of storage in the ROM.

The photo below shows the bottom layer of metal (M1): vertical metal wires that provide the ROM outputs and supply ground to the ROM. (These wires are represented by gray lines in the schematic above.) The polysilicon transistors (or gaps as appropriate) are barely visible between the metal lines. Most of the small circles are tungsten contacts to the silicon or polysilicon; compare with the photo above. Other circles are tungsten vias to the metal layer on top (M2), horizontal wiring that I removed for this photo. The smaller metal "tabs" act as jumpers between the horizontal metal select lines in M2 and the polysilicon select lines. The top metal layer (M3, not visible) has thicker vertical wiring for the chip's primary distribution power and ground. Thus, the three metal layers alternate between horizontal and vertical wiring, with vias between the layers.

A closeup of the ROM showing the bottom metal layer.

The ROM is implemented as two grids of cells (below): one to hold exponents and one to hold significands, as shown below. The exponent grid (on the left) has 38 rows and 144 columns of transistors, while the significand grid (on the right) has 38 rows and 544 columns. To make the layout work better, each row holds eight different constants; the bits are interleaved so the ROM holds the first bit of eight constants, then the second bit of eight constants, and so forth. Thus, with 38 rows, the ROM holds 304 constants; each constant has 18 bits in the exponent part and 68 bits in the significand section.

A diagram of the constant ROM and supporting circuitry. Most of the significand ROM has been cut out to make it fit.

The exponent part of each constant consists of 18 bits: a 17-bit exponent and one bit for the sign of the significand and thus the constant. There is no sign bit for the exponent because the exponent is stored with 65535 (0x0ffff) added to it, avoiding negative values. The 68-bit significand entry in the ROM consists of a mysterious flag bit2 followed by the 67-bit significand; the first bit of the significand is the integer part and the remainder is the fractional part.3 The complete contents of the ROM are in the appendix at the bottom of this post.

To select a particular constant, the "row select" circuitry between the two sections activates one of the 38 rows. That row provides 144+544 bits to the selection circuitry above the ROM. This circuitry has 86 multiplexers; each multiplexer selects one bit out of the group of 8, selecting the desired constant. The significand bits flow into the floating-point unit datapath circuitry above the ROM. The exponent circuitry, however, is in the upper-left corner of the floating-point unit, a considerable distance from the ROM, so the exponent bits travel through a bus to the exponent circuitry.

The row select circuitry consists of gates to decode the row number, along with high-current drivers to energize the selected row in the ROM. The photo below shows a closeup of two row driver circuits, next to some ROM cells. At the left, PMOS and NMOS transistors implement a gate to select the row. Next, larger NMOS and PMOS transistors form part of the driver. The large square structures are bipolar NPN transistors; the Pentium is unusual because it uses both bipolar transistors and CMOS, a technique called BiCMOS.4 Each driver occupies as much height as four rows of the ROM, so there are four drivers arranged horizontally; only one is visible in the photo.

ROM drivers implemented with BiCMOS.

Structure of the floating-point unit

The floating-point unit is structured with data flowing vertically through horizontal functional units, as shown below. The functional units—adders, shifters, registers, and comparators—are arranged in rows. This collection of functional units with data flowing through them is called the datapath.5

The datapath of the floating-point unit. The ROM is at the bottom.

Each functional unit is constructed from cells, one per bit, with the high-order bit on the left and the low-order bit on the right. Each cell has the same width—38.5 µm—so the functional units can be connected like Lego blocks snapping together, minimizing the wiring. The height of a functional unit varies as needed, depending on the complexity of the circuit. Functional units typically have 69 bits, but some are wider, so the edges of the datapath circuitry are ragged.

This cell-based construction explains why the ROM has eight constants per row. A ROM bit requires a single transistor, which is much narrower than, say, an adder. Thus, putting one bit in each 38.5 µm cell would waste most of the space. Compacting the ROM bits into a narrow block would also be inefficient, requiring diagonal wiring to connect each ROM bit to the corresponding datapath bit. By putting eight bits for eight different constants into each cell, the width of a ROM cell matches the rest of the datapath and the alignment of bits is preserved. Thus, the layout of the ROM in silicon is dense, efficient, and matches the width of the rest of the floating-point unit.

Polynomial approximation: don't use a Taylor series

Now I'll move from the hardware to the constants. If you look at the constant ROM contents in the appendix, you may notice that many constants are close to reciprocals or reciprocal factorials, but don't quite match. For instance, one constant is 0.1111111089, which is close to 1/9, but visibly wrong. Another constant is almost 1/13! (factorial) but wrong by 0.1%. What's going on?

The Pentium uses polynomials to approximate transcendental functions (sine, cosine, tangent, arctangent, and base-2 powers and logarithms). Intel's earlier floating-point units, from the 8087 to the 486, used an algorithm called CORDIC that generated results a bit at a time. However, the Pentium takes advantage of its fast multiplier and larger ROM and uses polynomials instead, computing results two to three times faster than the 486 algorithm.

You may recall from calculus that a Taylor series polynomial approximates a function near a point (typically 0). For example, the equation below gives the Taylor series for sine.

Using the five terms shown above generates a function that looks indistinguishable from sine in the graph below. However, it turns out that this approximation has too much error to be useful.

Plot of the sine function and the Taylor series approximation.

The problem is that a Taylor series is very accurate near 0, but the error soars near the edges of the argument range, as shown in the graph on the left below. When implementing a function, we want the function to be accurate everywhere, not just close to 0, so the Taylor series isn't good enough.

The absolute error for a Taylor-series approximation to sine (5 terms), over two different argument ranges.

One improvement is called range reduction: shrinking the argument to a smaller range so you're in the accurate flat part.6 The graph on the right looks at the Taylor series over the smaller range [-1/32, 1/32]. This decreases the error dramatically, by about 22 orders of magnitude (note the scale change). However, the error still shoots up at the edges of the range in exactly the same way. No matter how much you reduce the range, there is almost no error in the middle, but the edges have a lot of error.7

How can we get rid of the error near the edges? The trick is to tweak the coefficients of the Taylor series in a special way that will increase the error in the middle, but decrease the error at the edges by much more. Since we want to minimize the maximum error across the range (called minimax), this tradeoff is beneficial. Specifically, the coefficients can be optimized by a process called the Remez algorithm.8 As shown below, changing the coefficients by less than 1% dramatically improves the accuracy. The optimized function (blue) has much lower error over the full range, so it is a much better approximation than the Taylor series (orange).

Comparison of the absolute error from the Taylor series and a Remez-optimized polynomial, both with maximum term x⁹. This Remez polynomial is not one from the Pentium.

To summarize, a Taylor series is useful in calculus, but shouldn't be used to approximate a function. You get a much better approximation by modifying the coefficients very slightly with the Remez algorithm. This explains why the coefficients in the ROM almost, but not quite, match a Taylor series.

Arctan

I'll now look at the Pentium's constants for different transcendental functions. The constant ROM contains coefficients for two arctan polynomials, one for single precision and one for double precision. These polynomials almost match the Taylor series, but have been modified for accuracy. The ROM also holds the values for arctan(1/32) through arctan(32/32); the range reduction process uses these constants with a trig identity to reduce the argument range to [-1/64, 1/64].9 You can see the arctan constants in the Appendix.

The graph below shows the error for the Pentium's arctan polynomial (blue) versus the Taylor series of the same length (orange). The Pentium's polynomial is superior due to the Remez optimization. Although the Taylor series polynomial is much flatter in the middle, the error soars near the boundary. The Pentium's polynomial wiggles more but it maintains a low error across the whole range. The error in the Pentium polynomial blows up outside this range, but that doesn't matter.

Comparison of the Pentium's double-precision arctan polynomial to the Taylor series.

Trig functions

Sine and cosine each have two polynomial implementations, one with 4 terms in the ROM and one with 6 terms in the ROM. (Note that coefficients of 1 are not stored in the ROM.) The constant table also holds 16 constants such as sin(36/64) and cos(18/64) that are used for argument range reduction.10 The Pentium computes tangent by dividing the sine by the cosine. I'm not showing a graph because the Pentium's error came out worse than the Taylor series, so either I have an error in a coefficient or I'm doing something wrong.

Exponential

The Pentium has an instruction to compute a power of two.11 There are two sets of polynomial coefficients for exponential, one with 6 terms in the ROM and one with 11 terms in the ROM. Curiously, the polynomials in the ROM compute e^x, not 2^x. Thus, the Pentium must scale the argument by ln(2), a constant that is in the ROM. The error graph below shows the advantage of the Pentium's polynomial over the Taylor series polynomial.

The Pentium's 6-term exponential polynomial, compared with the Taylor series.

The polynomial handles the narrow argument range [-1/128, 1/128]. Observe that when computing a power of 2 in binary, exponentiating the integer part of the argument is trivial, since it becomes the result's exponent. Thus, the function only needs to handle the range [1, 2]. For range reduction, the constant ROM holds 64 values of the form 2^n/128-1. To reduce the range from [1, 2] to [-1/128, 1/128], the closest n/128 is subtracted from the argument and then the result is multiplied by the corresponding constant in the ROM. The constants are spaced irregularly, presumably for accuracy; some are in steps of 4/128 and others are in steps of 2/128.

Logarithm

The Pentium can compute base-2 logarithms.12 The coefficients define polynomials for the hyperbolic arctan, which is closely related to log. See the comments for details. The ROM also has 64 constants for range reduction: log₂(1+n/64) for odd n from 1 to 63. The unusual feature of these constants is that each constant is split into two pieces to increase the bits of accuracy: the top part has 40 bits of accuracy and the bottom part has 67 bits of accuracy, providing a 107-bit constant in total. The extra bits are required because logarithms are hard to compute accurately.

Other constants

The x87 floating-point instruction set provides direct access to a handful of constants—0, 1, pi, log₂(10), log₂(e), log₁₀(2), and log_e(2)—so these constants are stored in the ROM. (These logs are useful for changing the base for logs and exponentials.) The ROM holds other constants for internal use by the floating-point unit such as -1, 2, 7/8, 9/8, pi/2, pi/4, and 2log₂(e). The ROM also holds bitmasks for extracting part of a word, for instance accessing 4-bit BCD digits in a word. Although I can interpret most of the values, there are a few mysteries such as a mask with the inscrutable value 0x3e8287c. The ROM has 34 unused entries at the end; these entries hold words that include the descriptive hex value 0xbad or perhaps 0xbadfc for "bad float constant".

How I examined the ROM

To analyze the Pentium, I removed the metal and oxide layers with various chemicals (sulfuric acid, phosphoric acid, Whink). (I later discovered that simply sanding the die works surprisingly well.) Next, I took many photos of the ROM with a microscope. The feature size of this Pentium is 800 nm, just slightly larger than visible light (380-700 nm). Thus, the die can be examined under an optical microscope, but it is getting close to the limits. To determine the ROM contents, I tediously went through the ROM images, examining each of the 26144 bits and marking each transistor. After figuring out the ROM format, I wrote programs to combine simple functions in many different combinations to determine the mathematical expression such as arctan(19/32) or log₂(10). Because the polynomial constants are optimized and my ROM data has bit errors, my program needed checks for inexact matches, both numerically and bitwise. Finally, I had to determine how the constants would be used in algorithms.

Conclusions

By examining the Pentium's floating-point ROM under a microscope, it is possible to extract the 304 constants stored in the ROM. I was able to determine the meaning of most of these constants and deduce some of the floating-point algorithms used by the Pentium. These constants illustrate how polynomials can efficiently compute transcendental functions. Although Taylor series polynomials are well known, they are surprisingly inaccurate and should be avoided. Minor changes to the coefficients through the Remez algorithm, however, yield much better polynomials.

In a previous article, I examined the floating-point constants stored in the 8087 coprocessor. The Pentium has 304 constants in the Pentium, compared to just 42 in the 8087, supporting more efficient algorithms. Moreover, the 8087 was an external floating-point unit, while the Pentium's floating-point unit is part of the processor. The changes between the 8087 (1980, 65,000 transistors) and the Pentium (1993, 3.1 million transistors) are due to the exponential improvements in transistor count, as described by Moore's Law.

I plan to write more about the Pentium so follow me on Bluesky (@righto.com) or RSS for updates. (I'm no longer on Twitter.) I've also written about the Pentium division bug and the Pentium Navajo rug. Thanks to CuriousMarc for microscope help. Thanks to lifthrasiir and Alexia for identifying some constants.

Appendix: The constant ROM

The table below lists the 304 constants in the Pentium's floating-point ROM. The first four columns show the values stored in the ROM: the exponent, the sign bit, the flag bit, and the significand. To avoid negative exponents, exponents are stored with the constant 0x0ffff added. For example, the value 0x0fffe represents an exponent of -1, while 0x10000 represents an exponent of 1. The constant's approximate decimal value is in the "value" column.

Special-purpose values are colored. Specifically, "normal" numbers are in black. Constants with an exponent of all 0's are in blue, constants with an exponent of all 1's are in red, constants with an unusually large or small exponent are in green; these appear to be bitmasks rather than numbers. Unused entries are in gray. Inexact constants (due to Remez optimization) are represented with the approximation symbol "≈".

This information is from my reverse engineering, so there will be a few errors.

	exp	S	F	significand	value	meaning
0	00000	0	0	07878787878787878		BCD mask by 4's
1	00000	0	0	007f807f807f807f8		BCD mask by 8's
2	00000	0	0	00007fff80007fff8		BCD mask by 16's
3	00000	0	0	000000007fffffff8		BCD mask by 32's
4	00000	0	0	78000000000000000		4-bit mask
5	00000	0	0	18000000000000000		2-bit mask
6	00000	0	0	27000000000000000		?
7	00000	0	0	363c0000000000000		?
8	00000	0	0	3e8287c0000000000		?
9	00000	0	0	470de4df820000000		213×1016
10	00000	0	0	5c3bd5191b525a249		2123/1017
11	00000	0	0	00000000000000007		3-bit mask
12	1ffff	1	1	7ffffffffffffffff		all 1's
13	00000	0	0	0000007ffffffffff		mask for 32-bit float
14	00000	0	0	00000000000003fff		mask for 64-bit float
15	00000	0	0	00000000000000000		all 0's
16	0ffff	0	0	40000000000000000	1	1
17	10000	0	0	6a4d3c25e68dc57f2	3.3219280949	log2(10)
18	0ffff	0	0	5c551d94ae0bf85de	1.4426950409	log2(e)
19	10000	0	0	6487ed5110b4611a6	3.1415926536	pi
20	0ffff	0	0	6487ed5110b4611a6	1.5707963268	pi/2
21	0fffe	0	0	6487ed5110b4611a6	0.7853981634	pi/4
22	0fffd	0	0	4d104d427de7fbcc5	0.3010299957	log10(2)
23	0fffe	0	0	58b90bfbe8e7bcd5f	0.6931471806	ln(2)
24	1ffff	0	0	40000000000000000		+infinity
25	0bfc0	0	0	40000000000000000		1/4 of smallest 80-bit denormal?
26	1ffff	1	0	60000000000000000		NaN (not a number)
27	0ffff	1	0	40000000000000000	-1	-1
28	10000	0	0	40000000000000000	2	2
29	00000	0	0	00000000000000001		low bit
30	00000	0	0	00000000000000000		all 0's
31	00001	0	0	00000000000000000		single exponent bit
32	0fffe	0	0	58b90bfbe8e7bcd5e	0.6931471806	ln(2)
33	0fffe	0	0	40000000000000000	0.5	1/2! (exp Taylor series)
34	0fffc	0	0	5555555555555584f	0.1666666667	≈1/3!
35	0fffa	0	0	555555555397fffd4	0.0416666667	≈1/4!
36	0fff8	0	0	444444444250ced0c	0.0083333333	≈1/5!
37	0fff5	0	0	5b05c3dd3901cea50	0.0013888934	≈1/6!
38	0fff2	0	0	6806988938f4f2318	0.0001984134	≈1/7!
39	0fffe	0	0	40000000000000000	0.5	1/2! (exp Taylor series)
40	0fffc	0	0	5555555555555558e	0.1666666667	≈1/3!
41	0fffa	0	0	5555555555555558b	0.0416666667	≈1/4!
42	0fff8	0	0	444444444443db621	0.0083333333	≈1/5!
43	0fff5	0	0	5b05b05b05afd42f4	0.0013888889	≈1/6!
44	0fff2	0	0	68068068163b44194	0.0001984127	≈1/7!
45	0ffef	0	0	6806806815d1b6d8a	0.0000248016	≈1/8!
46	0ffec	0	0	5c778d8e0384c73ab	2.755731e-06	≈1/9!
47	0ffe9	0	0	49f93e0ef41d6086b	2.755731e-07	≈1/10!
48	0ffe5	0	0	6ba8b65b40f9c0ce8	2.506632e-08	≈1/11!
49	0ffe2	0	0	47c5b695d0d1289a8	2.088849e-09	≈1/12!
50	0fffd	0	0	6dfb23c651a2ef221	0.4296133384	266/128-1
51	0fffd	0	0	75feb564267c8bf6f	0.4609177942	270/128-1
52	0fffd	0	0	7e2f336cf4e62105d	0.4929077283	274/128-1
53	0fffe	0	0	4346ccda249764072	0.5255981507	278/128-1
54	0fffe	0	0	478d74c8abb9b15cc	0.5590044002	282/128-1
55	0fffe	0	0	4bec14fef2727c5cf	0.5931421513	286/128-1
56	0fffe	0	0	506333daef2b2594d	0.6280274219	290/128-1
57	0fffe	0	0	54f35aabcfedfa1f6	0.6636765803	294/128-1
58	0fffe	0	0	599d15c278afd7b60	0.7001063537	298/128-1
59	0fffe	0	0	5e60f4825e0e9123e	0.7373338353	2102/128-1
60	0fffe	0	0	633f8972be8a5a511	0.7753764925	2106/128-1
61	0fffe	0	0	68396a503c4bdc688	0.8142521755	2110/128-1
62	0fffe	0	0	6d4f301ed9942b846	0.8539791251	2114/128-1
63	0fffe	0	0	7281773c59ffb139f	0.8945759816	2118/128-1
64	0fffe	0	0	77d0df730ad13bb90	0.9360617935	2122/128-1
65	0fffe	0	0	7d3e0c0cf486c1748	0.9784560264	2126/128-1
66	0fffc	0	0	642e1f899b0626a74	0.1956643920	233/128-1
67	0fffc	0	0	6ad8abf253fe1928c	0.2086843236	235/128-1
68	0fffc	0	0	7195cda0bb0cb0b54	0.2218460330	237/128-1
69	0fffc	0	0	7865b862751c90800	0.2351510639	239/128-1
70	0fffc	0	0	7f48a09590037417f	0.2486009772	241/128-1
71	0fffd	0	0	431f5d950a896dc70	0.2621973504	243/128-1
72	0fffd	0	0	46a41ed1d00577251	0.2759417784	245/128-1
73	0fffd	0	0	4a32af0d7d3de672e	0.2898358734	247/128-1
74	0fffd	0	0	4dcb299fddd0d63b3	0.3038812652	249/128-1
75	0fffd	0	0	516daa2cf6641c113	0.3180796013	251/128-1
76	0fffd	0	0	551a4ca5d920ec52f	0.3324325471	253/128-1
77	0fffd	0	0	58d12d497c7fd252c	0.3469417862	255/128-1
78	0fffd	0	0	5c9268a5946b701c5	0.3616090206	257/128-1
79	0fffd	0	0	605e1b976dc08b077	0.3764359708	259/128-1
80	0fffd	0	0	6434634ccc31fc770	0.3914243758	261/128-1
81	0fffd	0	0	68155d44ca973081c	0.4065759938	263/128-1
82	0fffd	1	0	4cee3bed56eedb76c	-0.3005101637	2-66/128-1
83	0fffd	1	0	50c4875296f5bc8b2	-0.3154987885	2-70/128-1
84	0fffd	1	0	5485c64a56c12cc8a	-0.3301662380	2-74/128-1
85	0fffd	1	0	58326c4b169aca966	-0.3445193942	2-78/128-1
86	0fffd	1	0	5bcaea51f6197f61f	-0.3585649920	2-82/128-1
87	0fffd	1	0	5f4faef0468eb03de	-0.3723096215	2-86/128-1
88	0fffd	1	0	62c12658d30048af2	-0.3857597319	2-90/128-1
89	0fffd	1	0	661fba6cdf48059b2	-0.3989216343	2-94/128-1
90	0fffd	1	0	696bd2c8dfe7a5ffb	-0.4118015042	2-98/128-1
91	0fffd	1	0	6ca5d4d0ec1916d43	-0.4244053850	2-102/128-1
92	0fffd	1	0	6fce23bceb994e239	-0.4367391907	2-106/128-1
93	0fffd	1	0	72e520a481a4561a5	-0.4488087083	2-110/128-1
94	0fffd	1	0	75eb2a8ab6910265f	-0.4606196011	2-114/128-1
95	0fffd	1	0	78e09e696172efefc	-0.4721774108	2-118/128-1
96	0fffd	1	0	7bc5d73c5321bfb9e	-0.4834875605	2-122/128-1
97	0fffd	1	0	7e9b2e0c43fcf88c8	-0.4945553570	2-126/128-1
98	0fffc	1	0	53c94402c0c863f24	-0.1636449102	2-33/128-1
99	0fffc	1	0	58661eccf4ca790d2	-0.1726541162	2-35/128-1
100	0fffc	1	0	5cf6413b5d2cca73f	-0.1815662751	2-37/128-1
101	0fffc	1	0	6179ce61cdcdce7db	-0.1903824324	2-39/128-1
102	0fffc	1	0	65f0e8f35f84645cf	-0.1991036222	2-41/128-1
103	0fffc	1	0	6a5bb3437adf1164b	-0.2077308674	2-43/128-1
104	0fffc	1	0	6eba4f46e003a775a	-0.2162651800	2-45/128-1
105	0fffc	1	0	730cde94abb7410d5	-0.2247075612	2-47/128-1
106	0fffc	1	0	775382675996699ad	-0.2330590011	2-49/128-1
107	0fffc	1	0	7b8e5b9dc385331ad	-0.2413204794	2-51/128-1
108	0fffc	1	0	7fbd8abc1e5ee49f2	-0.2494929652	2-53/128-1
109	0fffd	1	0	41f097f679f66c1db	-0.2575774171	2-55/128-1
110	0fffd	1	0	43fcb5810d1604f37	-0.2655747833	2-57/128-1
111	0fffd	1	0	46032dbad3f462152	-0.2734860021	2-59/128-1
112	0fffd	1	0	48041035735be183c	-0.2813120013	2-61/128-1
113	0fffd	1	0	49ff6c57a12a08945	-0.2890536989	2-63/128-1
114	0fffd	1	0	555555555555535f0	-0.3333333333	≈-1/3 (arctan Taylor series)
115	0fffc	0	0	6666666664208b016	0.2	≈ 1/5
116	0fffc	1	0	492491e0653ac37b8	-0.1428571307	≈-1/7
117	0fffb	0	0	71b83f4133889b2f0	0.1110544094	≈ 1/9
118	0fffd	1	0	55555555555555543	-0.3333333333	≈-1/3 (arctan Taylor series)
119	0fffc	0	0	66666666666616b73	0.2	≈ 1/5
120	0fffc	1	0	4924924920fca4493	-0.1428571429	≈-1/7
121	0fffb	0	0	71c71c4be6f662c91	0.1111111089	≈ 1/9
122	0fffb	1	0	5d16e0bde0b12eee8	-0.0909075848	≈-1/11
123	0fffb	0	0	4e403be3e3c725aa0	0.0764169081	≈ 1/13
124	00000	0	0	40000000000000000		single bit mask
125	0fff9	0	0	7ff556eea5d892a14	0.0312398334	arctan(1/32)
126	0fffa	0	0	7fd56edcb3f7a71b6	0.0624188100	arctan(2/32)
127	0fffb	0	0	5fb860980bc43a305	0.0934767812	arctan(3/32)
128	0fffb	0	0	7f56ea6ab0bdb7196	0.1243549945	arctan(4/32)
129	0fffc	0	0	4f5bbba31989b161a	0.1549967419	arctan(5/32)
130	0fffc	0	0	5ee5ed2f396c089a4	0.1853479500	arctan(6/32)
131	0fffc	0	0	6e435d4a498288118	0.2153576997	arctan(7/32)
132	0fffc	0	0	7d6dd7e4b203758ab	0.2449786631	arctan(8/32)
133	0fffd	0	0	462fd68c2fc5e0986	0.2741674511	arctan(9/32)
134	0fffd	0	0	4d89dcdc1faf2f34e	0.3028848684	arctan(10/32)
135	0fffd	0	0	54c2b6654735276d5	0.3310960767	arctan(11/32)
136	0fffd	0	0	5bd86507937bc239c	0.3587706703	arctan(12/32)
137	0fffd	0	0	62c934e5286c95b6d	0.3858826694	arctan(13/32)
138	0fffd	0	0	6993bb0f308ff2db2	0.4124104416	arctan(14/32)
139	0fffd	0	0	7036d3253b27be33e	0.4383365599	arctan(15/32)
140	0fffd	0	0	76b19c1586ed3da2b	0.4636476090	arctan(16/32)
141	0fffd	0	0	7d03742d50505f2e3	0.4883339511	arctan(17/32)
142	0fffe	0	0	4195fa536cc33f152	0.5123894603	arctan(18/32)
143	0fffe	0	0	4495766fef4aa3da8	0.5358112380	arctan(19/32)
144	0fffe	0	0	47802eaf7bfacfcdb	0.5585993153	arctan(20/32)
145	0fffe	0	0	4a563964c238c37b1	0.5807563536	arctan(21/32)
146	0fffe	0	0	4d17c07338deed102	0.6022873461	arctan(22/32)
147	0fffe	0	0	4fc4fee27a5bd0f68	0.6231993299	arctan(23/32)
148	0fffe	0	0	525e3e8c9a7b84921	0.6435011088	arctan(24/32)
149	0fffe	0	0	54e3d5ee24187ae45	0.6632029927	arctan(25/32)
150	0fffe	0	0	5756261c5a6c60401	0.6823165549	arctan(26/32)
151	0fffe	0	0	59b598e48f821b48b	0.7008544079	arctan(27/32)
152	0fffe	0	0	5c029f15e118cf39e	0.7188299996	arctan(28/32)
153	0fffe	0	0	5e3daef574c579407	0.7362574290	arctan(29/32)
154	0fffe	0	0	606742dc562933204	0.7531512810	arctan(30/32)
155	0fffe	0	0	627fd7fd5fc7deaa4	0.7695264804	arctan(31/32)
156	0fffe	0	0	6487ed5110b4611a6	0.7853981634	arctan(32/32)
157	0fffc	1	0	55555555555555555	-0.1666666667	≈-1/3! (sin Taylor series)
158	0fff8	0	0	44444444444443e35	0.0083333333	≈ 1/5!
159	0fff2	1	0	6806806806773c774	-0.0001984127	≈-1/7!
160	0ffec	0	0	5c778e94f50956d70	2.755732e-06	≈ 1/9!
161	0ffe5	1	0	6b991122efa0532f0	-2.505209e-08	≈-1/11!
162	0ffde	0	0	58303f02614d5e4d8	1.604139e-10	≈ 1/13!
163	0fffd	1	0	7fffffffffffffffe	-0.5	≈-1/2! (cos Taylor series)
164	0fffa	0	0	55555555555554277	0.0416666667	≈ 1/4!
165	0fff5	1	0	5b05b05b05a18a1ba	-0.0013888889	≈-1/6!
166	0ffef	0	0	680680675b559f2cf	0.0000248016	≈ 1/8!
167	0ffe9	1	0	49f93af61f5349300	-2.755730e-07	≈-1/10!
168	0ffe2	0	0	47a4f2483514c1af8	2.085124e-09	≈ 1/12!
169	0fffc	1	0	55555555555555445	-0.1666666667	≈-1/3! (sin Taylor series)
170	0fff8	0	0	44444444443a3fdb6	0.0083333333	≈ 1/5!
171	0fff2	1	0	68068060b2044e9ae	-0.0001984127	≈-1/7!
172	0ffec	0	0	5d75716e60f321240	2.785288e-06	≈ 1/9!
173	0fffd	1	0	7fffffffffffffa28	-0.5	≈-1/2! (cos Taylor series)
174	0fffa	0	0	555555555539cfae6	0.0416666667	≈ 1/4!
175	0fff5	1	0	5b05b050f31b2e713	-0.0013888889	≈-1/6!
176	0ffef	0	0	6803988d56e3bff10	0.0000247989	≈ 1/8!
177	0fffe	0	0	44434312da70edd92	0.5333026735	sin(36/64)
178	0fffe	0	0	513ace073ce1aac13	0.6346070800	sin(44/64)
179	0fffe	0	0	5cedda037a95df6ee	0.7260086553	sin(52/64)
180	0fffe	0	0	672daa6ef3992b586	0.8060811083	sin(60/64)
181	0fffd	0	0	470df5931ae1d9460	0.2775567516	sin(18/64)
182	0fffd	0	0	5646f27e8bd65cbe4	0.3370200690	sin(22/64)
183	0fffd	0	0	6529afa7d51b12963	0.3951673302	sin(26/64)
184	0fffd	0	0	73a74b8f52947b682	0.4517714715	sin(30/64)
185	0fffe	0	0	6c4741058a93188ef	0.8459244992	cos(36/64)
186	0fffe	0	0	62ec41e9772401864	0.7728350058	cos(44/64)
187	0fffe	0	0	5806149bd58f7d46d	0.6876855622	cos(52/64)
188	0fffe	0	0	4bc044c9908390c72	0.5918050751	cos(60/64)
189	0fffe	0	0	7af8853ddbbe9ffd0	0.9607092430	cos(18/64)
190	0fffe	0	0	7882fd26b35b03d34	0.9414974631	cos(22/64)
191	0fffe	0	0	7594fc1cf900fe89e	0.9186091558	cos(26/64)
192	0fffe	0	0	72316fe3386a10d5a	0.8921336994	cos(30/64)
193	0ffff	0	0	48000000000000000	1.125	9/8
194	0fffe	0	0	70000000000000000	0.875	7/8
195	0ffff	0	0	5c551d94ae0bf85de	1.4426950409	log2(e)
196	10000	0	0	5c551d94ae0bf85de	2.8853900818	2log2(e)
197	0fffb	0	0	7b1c2770e81287c11	0.1202245867	≈1/(41⋅3⋅ln(2)) (atanh series for log)
198	0fff9	0	0	49ddb14064a5d30bd	0.0180336880	≈1/(42⋅5⋅ln(2))
199	0fff6	0	0	698879b87934f12e0	0.0032206148	≈1/(43⋅7⋅ln(2))
200	0fffa	0	0	51ff4ffeb20ed1749	0.0400377512	≈(ln(2)/2)2/3 (atanh series for log)
201	0fff6	0	0	5e8cd07eb1827434a	0.0028854387	≈(ln(2)/2)4/5
202	0fff3	0	0	40e54061b26dd6dc2	0.0002475567	≈(ln(2)/2)6/7
203	0ffef	0	0	61008a69627c92fb9	0.0000231271	≈(ln(2)/2)8/9
204	0ffec	0	0	4c41e6ced287a2468	2.272648e-06	≈(ln(2)/2)10/11
205	0ffe8	0	0	7dadd4ea3c3fee620	2.340954e-07	≈(ln(2)/2)12/13
206	0fff9	0	0	5b9e5a170b8000000	0.0223678130	log2(1+1/64) top bits
207	0fffb	0	0	43ace37e8a8000000	0.0660892054	log2(1+3/64) top bits
208	0fffb	0	0	6f210902b68000000	0.1085244568	log2(1+5/64) top bits
209	0fffc	0	0	4caba789e28000000	0.1497471195	log2(1+7/64) top bits
210	0fffc	0	0	6130af40bc0000000	0.1898245589	log2(1+9/64) top bits
211	0fffc	0	0	7527b930c98000000	0.2288186905	log2(1+11/64) top bits
212	0fffd	0	0	444c1f6b4c0000000	0.2667865407	log2(1+13/64) top bits
213	0fffd	0	0	4dc4933a930000000	0.3037807482	log2(1+15/64) top bits
214	0fffd	0	0	570068e7ef8000000	0.3398500029	log2(1+17/64) top bits
215	0fffd	0	0	6002958c588000000	0.3750394313	log2(1+19/64) top bits
216	0fffd	0	0	68cdd829fd8000000	0.4093909361	log2(1+21/64) top bits
217	0fffd	0	0	7164beb4a58000000	0.4429434958	log2(1+23/64) top bits
218	0fffd	0	0	79c9aa879d8000000	0.4757334310	log2(1+25/64) top bits
219	0fffe	0	0	40ff6a2e5e8000000	0.5077946402	log2(1+27/64) top bits
220	0fffe	0	0	450327ea878000000	0.5391588111	log2(1+29/64) top bits
221	0fffe	0	0	48f107509c8000000	0.5698556083	log2(1+31/64) top bits
222	0fffe	0	0	4cc9f1aad28000000	0.5999128422	log2(1+33/64) top bits
223	0fffe	0	0	508ec1fa618000000	0.6293566201	log2(1+35/64) top bits
224	0fffe	0	0	5440461c228000000	0.6582114828	log2(1+37/64) top bits
225	0fffe	0	0	57df3fd0780000000	0.6865005272	log2(1+39/64) top bits
226	0fffe	0	0	5b6c65a9d88000000	0.7142455177	log2(1+41/64) top bits
227	0fffe	0	0	5ee863e4d40000000	0.7414669864	log2(1+43/64) top bits
228	0fffe	0	0	6253dd2c1b8000000	0.7681843248	log2(1+45/64) top bits
229	0fffe	0	0	65af6b4ab30000000	0.7944158664	log2(1+47/64) top bits
230	0fffe	0	0	68fb9fce388000000	0.8201789624	log2(1+49/64) top bits
231	0fffe	0	0	6c39049af30000000	0.8454900509	log2(1+51/64) top bits
232	0fffe	0	0	6f681c731a0000000	0.8703647196	log2(1+53/64) top bits
233	0fffe	0	0	72896372a50000000	0.8948177633	log2(1+55/64) top bits
234	0fffe	0	0	759d4f80cb8000000	0.9188632373	log2(1+57/64) top bits
235	0fffe	0	0	78a450b8380000000	0.9425145053	log2(1+59/64) top bits
236	0fffe	0	0	7b9ed1c6ce8000000	0.9657842847	log2(1+61/64) top bits
237	0fffe	0	0	7e8d3845df0000000	0.9886846868	log2(1+63/64) top bits
238	0ffd0	1	0	6eb3ac8ec0ef73f7b	-1.229037e-14	log2(1+1/64) bottom bits
239	0ffcd	1	0	654c308b454666de9	-1.405787e-15	log2(1+3/64) bottom bits
240	0ffd2	0	0	5dd31d962d3728cbd	4.166652e-14	log2(1+5/64) bottom bits
241	0ffd3	0	0	70d0fa8f9603ad3a6	1.002010e-13	log2(1+7/64) bottom bits
242	0ffd1	0	0	765fba4491dcec753	2.628429e-14	log2(1+9/64) bottom bits
243	0ffd2	1	0	690370b4a9afdc5fb	-4.663533e-14	log2(1+11/64) bottom bits
244	0ffd4	0	0	5bae584b82d3cad27	1.628582e-13	log2(1+13/64) bottom bits
245	0ffd4	0	0	6f66cc899b64303f7	1.978889e-13	log2(1+15/64) bottom bits
246	0ffd4	1	0	4bc302ffa76fafcba	-1.345799e-13	log2(1+17/64) bottom bits
247	0ffd2	1	0	7579aa293ec16410a	-5.216949e-14	log2(1+19/64) bottom bits
248	0ffcf	0	0	509d7c40d7979ec5b	4.475041e-15	log2(1+21/64) bottom bits
249	0ffd3	1	0	4a981811ab5110ccf	-6.625289e-14	log2(1+23/64) bottom bits
250	0ffd4	1	0	596f9d730f685c776	-1.588702e-13	log2(1+25/64) bottom bits
251	0ffd4	1	0	680cc6bcb9bfa9853	-1.848298e-13	log2(1+27/64) bottom bits
252	0ffd4	0	0	5439e15a52a31604a	1.496156e-13	log2(1+29/64) bottom bits
253	0ffd4	0	0	7c8080ecc61a98814	2.211599e-13	log2(1+31/64) bottom bits
254	0ffd3	1	0	6b26f28dbf40b7bc0	-9.517022e-14	log2(1+33/64) bottom bits
255	0ffd5	0	0	554b383b0e8a55627	3.030245e-13	log2(1+35/64) bottom bits
256	0ffd5	0	0	47c6ef4a49bc59135	2.550034e-13	log2(1+37/64) bottom bits
257	0ffd5	0	0	4d75c658d602e66b0	2.751934e-13	log2(1+39/64) bottom bits
258	0ffd4	1	0	6b626820f81ca95da	-1.907530e-13	log2(1+41/64) bottom bits
259	0ffd3	0	0	5c833d56efe4338fe	8.216774e-14	log2(1+43/64) bottom bits
260	0ffd5	0	0	7c5a0375163ec8d56	4.417857e-13	log2(1+45/64) bottom bits
261	0ffd5	1	0	5050809db75675c90	-2.853343e-13	log2(1+47/64) bottom bits
262	0ffd4	1	0	7e12f8672e55de96c	-2.239526e-13	log2(1+49/64) bottom bits
263	0ffd5	0	0	435ebd376a70d849b	2.393466e-13	log2(1+51/64) bottom bits
264	0ffd2	1	0	6492ba487dfb264b3	-4.466345e-14	log2(1+53/64) bottom bits
265	0ffd5	1	0	674e5008e379faa7c	-3.670163e-13	log2(1+55/64) bottom bits
266	0ffd5	0	0	5077f1f5f0cc82aab	2.858817e-13	log2(1+57/64) bottom bits
267	0ffd2	0	0	5007eeaa99f8ef14d	3.554090e-14	log2(1+59/64) bottom bits
268	0ffd5	0	0	4a83eb6e0f93f7a64	2.647316e-13	log2(1+61/64) bottom bits
269	0ffd3	0	0	466c525173dae9cf5	6.254831e-14	log2(1+63/64) bottom bits
270	0badf	0	1	40badfc0badfc0bad		unused
271	0badf	0	1	40badfc0badfc0bad		unused
272	0badf	0	1	40badfc0badfc0bad		unused
273	0badf	0	1	40badfc0badfc0bad		unused
274	0badf	0	1	40badfc0badfc0bad		unused
275	0badf	0	1	40badfc0badfc0bad		unused
276	0badf	0	1	40badfc0badfc0bad		unused
277	0badf	0	1	40badfc0badfc0bad		unused
278	0badf	0	1	40badfc0badfc0bad		unused
279	0badf	0	1	40badfc0badfc0bad		unused
280	0badf	0	1	40badfc0badfc0bad		unused
281	0badf	0	1	40badfc0badfc0bad		unused
282	0badf	0	1	40badfc0badfc0bad		unused
283	0badf	0	1	40badfc0badfc0bad		unused
284	0badf	0	1	40badfc0badfc0bad		unused
285	0badf	0	1	40badfc0badfc0bad		unused
286	0badf	0	1	40badfc0badfc0bad		unused
287	0badf	0	1	40badfc0badfc0bad		unused
288	0badf	0	1	40badfc0badfc0bad		unused
289	0badf	0	1	40badfc0badfc0bad		unused
290	0badf	0	1	40badfc0badfc0bad		unused
291	0badf	0	1	40badfc0badfc0bad		unused
292	0badf	0	1	40badfc0badfc0bad		unused
293	0badf	0	1	40badfc0badfc0bad		unused
294	0badf	0	1	40badfc0badfc0bad		unused
295	0badf	0	1	40badfc0badfc0bad		unused
296	0badf	0	1	40badfc0badfc0bad		unused
297	0badf	0	1	40badfc0badfc0bad		unused
298	0badf	0	1	40badfc0badfc0bad		unused
299	0badf	0	1	40badfc0badfc0bad		unused
300	0badf	0	1	40badfc0badfc0bad		unused
301	0badf	0	1	40badfc0badfc0bad		unused
302	0badf	0	1	40badfc0badfc0bad		unused
303	0badf	0	1	40badfc0badfc0bad		unused

Notes and references

1. In this blog post, I'm looking at the "P5" version of the original Pentium processor. It can be hard to keep all the Pentiums straight since "Pentium" became a brand name with multiple microarchitectures, lines, and products. The original Pentium (1993) was followed by the Pentium Pro (1995), Pentium II (1997), and so on.

   The original Pentium used the P5 microarchitecture, a superscalar microarchitecture that was advanced but still executed instruction in order like traditional microprocessors. The original Pentium went through several substantial revisions. The first Pentium product was the 80501 (codenamed P5), containing 3.1 million transistors. The power consumption of these chips was disappointing, so Intel improved the chip, producing the 80502, codenamed P54C. The P5 and P54C look almost the same on the die, but the P54C added circuitry for multiprocessing, boosting the transistor count to 3.3 million. The biggest change to the original Pentium was the Pentium MMX, with part number 80503 and codename P55C. The Pentium MMX added 57 vector processing instructions and had 4.5 million transistors. The floating-point unit was rearranged in the MMX, but the constants are probably the same. ↩

2. I don't know what the flag bit in the ROM indicates; I'm arbitrarily calling it a flag. My wild guess is that it indicates ROM entries that should be excluded from the checksum when testing the ROM. ↩

3. Internally, the significand has one integer bit and the remainder is the fraction, so the binary point (decimal point) is after the first bit. However, this is not the only way to represent the significand. The x87 80-bit floating-point format (double extended-precision) uses the same approach. However, the 32-bit (single-precision) and 64-bit (double-precision) formats drop the first bit and use an "implied" one bit. This gives you one more bit of significand "for free" since in normal cases the first significand bit will be 1. ↩

4. An unusual feature of the Pentium is that it uses bipolar NPN transistors along with CMOS circuits, a technology called BiCMOS. By adding a few extra processing steps to the regular CMOS manufacturing process, bipolar transistors could be created. The Pentium uses BiCMOS circuits extensively since they reduced signal delays by up to 35%. Intel also used BiCMOS for the Pentium Pro, Pentium II, Pentium III, and Xeon processors (but not the Pentium MMX). However, as chip voltages dropped, the benefit from bipolar transistors dropped too and BiCMOS was eventually abandoned.

   In the constant ROM, BiCMOS circuits improve the performance of the row selection circuitry. Each row select line is very long and is connected to hundreds of transistors, so the capacitive load is large. Because of the fast and powerful NPN transistor, a BiCMOS driver provides lower delay for higher loads than a regular CMOS driver.

   

   A typical BiCMOS inverter. From A 3.3V 0.6µm BiCMOS superscalar microprocessor.

   This BiCMOS logic is also called BiNMOS or BinMOS because the output has a bipolar transistor and an NMOS transistor. For more on BiCMOS circuits in the Pentium, see my article Standard cells: Looking at individual gates in the Pentium processor. ↩

5. The integer processing unit of the Pentium is constructed similarly, with horizontal functional units stacked to form the datapath. Each cell in the integer unit is much wider than a floating-point cell (64 µm vs 38.5 µm). However, the integer unit is just 32 bits wide, compared to 69 (more or less) for the floating-point unit, so the floating-point unit is wider overall. ↩

6. I don't like referring to the argument's range since a function's output is the range, while its input is the domain. But the term range reduction is what people use, so I'll go with it. ↩

7. There's a reason why the error curve looks similar even if you reduce the range. The error from the Taylor series is approximately the next term in the Taylor series, so in this case the error is roughly -x¹¹/11! or O(x¹¹). This shows why range reduction is so powerful: if you reduce the range by a factor of 2, you reduce the error by the enormous factor of 2¹¹. But this also shows why the error curve keeps its shape: the curve is still x¹¹, just with different labels on the axes. ↩

8. The Pentium coefficients are probably obtained using the Remez algorithm; see Floating-Point Verification. The advantages of the Remez polynomial over the Taylor series are discussed in Better Function Approximations: Taylor vs. Remez. A description of Remez's algorithm is in Elementary Functions: Algorithms and Implementation, which has other relevant information on polynomial approximation and range reduction. For more on polynomial approximations, see Numerically Computing the Exponential Function with Polynomial Approximations and The Eight Useful Polynomial Approximations of Sinf(3),

   The Remez polynomial in the sine graph is not the Pentium polynomial; it was generated for illustration by lolremez, a useful tool. The specific polynomial is:

   9.9997938808335731e-1 ⋅ x - 1.6662438518867169e-1 ⋅ x³ + 8.3089850302282266e-3 ⋅ x⁵ - 1.9264997445395096e-4 ⋅ x⁷ + 2.1478735041839789e-6 ⋅ x⁹

   The graph below shows the error for this polynomial. Note that the error oscillates between an upper bound and a lower bound. This is the typical appearance of a Remez polynomial. In contrast, a Taylor series will have almost no error in the middle and shoot up at the edges. This Remez polynomial was optimized for the range [-π,π]; the error explodes outside that range. The key point is that the Remez polynomial distributes the error inside the range. This minimizes the maximum error (minimax).

   ↩

   Error from a Remez-optimized polynomial for sine.

9. I think the arctan argument is range-reduced to the range [-1/64, 1/64]. This can be accomplished with the trig identity arctan(x) = arctan((x-c)/(1+xc)) + arctan(c). The idea is that c is selected to be the value of the form n/32 closest to x. As a result, x-c will be in the desired range and the first arctan can be computed with the polynomial. The other term, arctan(c), is obtained from the lookup table in the ROM. The FPATAN (partial arctangent) instruction takes two arguments, x and y, and returns atan(y/x); this simplifies handling planar coordinates. In this case, the trig identity becomes arcan(y/x) = arctan((y-tx)/(x+ty)) + arctan c. The division operation can trigger the FDIV bug in some cases; see Computational Aspects of the Pentium Affair. ↩

10. The Pentium has several trig instructions: FSIN, FCOS, and FSINCOS return the sine, cosine, or both (which is almost as fast as computing either). FPTAN returns the "partial tangent" consisting of two numbers that must be divided to yield the tangent. (This was due to limitations in the original 8087 coprocessor.) The Pentium returns the tangent as the first number and the constant 1 as the second number, keeping the semantics of FPTAN while being more convenient.

    The range reduction is probably based on the trig identity sin(a+b) = sin(a)cos(b)+cos(a)sin(b). To compute sin(x), select b as the closest constant in the lookup table, n/64, and then generate a=x-b. The value a will be range-reduced, so sin(a) can be computed from the polynomial. The terms sin(b) and cos(b) are available from the lookup table. The desired value sin(x) can then be computed with multiplications and addition by using the trig identity. Cosine can be computed similarly. Note that cos(a+b) =cos(a)cos(b)-sin(a)sin(b); the terms on the right are the same as for sin(a+b), just combined differently. Thus, once the terms on the right have been computed, they can be combined to generate sine, cosine, or both. The Pentium computes the tangent by dividing the sine by the cosine. This can trigger the FDIV division bug; see Computational Aspects of the Pentium Affair.

    Also see Agner Fog's Instruction Timings; the timings for the various operations give clues as to how they are computed. For instance, FPTAN takes longer than FSINCOS because the tangent is generated by dividing the sine by the cosine. ↩

11. For exponentials, the F2XM1 instruction computes 2^x-1; subtracting 1 improves accuracy. Specifically, 2^x is close to 1 for the common case when x is close to 0, so subtracting 1 as a separate operation causes you to lose most of the bits of accuracy due to cancellation. On the other hand, if you want 2^x, explicitly adding 1 doesn't harm accuracy. This is an example of how the floating-point instructions are carefully designed to preserve accuracy. For details, see the book The 8087 Primer by the architects of the 8086 processor and the 8087 coprocessor. ↩

12. The Pentium has base-two logarithm instructions FYL2X and FYL2XP1. The FYL2X instruction computes y log₂(x) and the FYL2XP1 instruction computes y log₂(x+1) The instructions include a multiplication because most logarithm operations will need to multiply to change the base; performing the multiply with internal precision increases the accuracy. The "plus-one" instruction improves accuracy for arguments close to 1, such as interest calculations.

    My hypothesis for range reduction is that the input argument is scaled to fall between 1 and 2. (Taking the log of the exponent part of the argument is trivial since the base-2 log of a base-2 power is simply the exponent.) The argument can then be divided by the largest constant 1+n/64 less than the argument. This will reduce the argument to the range [1, 1+1/32]. The log polynomial can be evaluated on the reduced argument. Finally, the ROM constant for log₂(1+n/64) is added to counteract the division. The constant is split into two parts for greater accuracy.

    It took me a long time to figure out the log constants because they were split. The upper-part constants appeared to be pointlessly inaccurate since the bottom 27 bits are zeroed out. The lower-part constants appeared to be miniscule semi-random numbers around ±10^-13. Eventually, I figured out that the trick was to combine the constants. ↩