Elsevier

Cognition

Volume 97, Issue 2, September 2005, Pages 179-210
Cognition

Discussion
The evolution of the language faculty: Clarifications and implications

https://doi.org/10.1016/j.cognition.2005.02.005Get rights and content

Abstract

In this response to Pinker and Jackendoff's critique, we extend our previous framework for discussion of language evolution, clarifying certain distinctions and elaborating on a number of points. In the first half of the paper, we reiterate that profitable research into the biology and evolution of language requires fractionation of “language” into component mechanisms and interfaces, a non-trivial endeavor whose results are unlikely to map onto traditional disciplinary boundaries. Our terminological distinction between FLN and FLB is intended to help clarify misunderstandings and aid interdisciplinary rapprochement. By blurring this distinction, Pinker and Jackendoff mischaracterize our hypothesis 3 which concerns only FLN, not “language” as a whole. Many of their arguments and examples are thus irrelevant to this hypothesis. Their critique of the minimalist program is for the most part equally irrelevant, because very few of the arguments in our original paper were tied to this program; in an online appendix we detail the deep inaccuracies in their characterization of this program. Concerning evolution, we believe that Pinker and Jackendoff's emphasis on the past adaptive history of the language faculty is misplaced. Such questions are unlikely to be resolved empirically due to a lack of relevant data, and invite speculation rather than research. Preoccupation with the issue has retarded progress in the field by diverting research away from empirical questions, many of which can be addressed with comparative data. Moreover, offering an adaptive hypothesis as an alternative to our hypothesis concerning mechanisms is a logical error, as questions of function are independent of those concerning mechanism. The second half of our paper consists of a detailed response to the specific data discussed by Pinker and Jackendoff. Although many of their examples are irrelevant to our original paper and arguments, we find several areas of substantive disagreement that could be resolved by future empirical research. We conclude that progress in understanding the evolution of language will require much more empirical research, grounded in modern comparative biology, more interdisciplinary collaboration, and much less of the adaptive storytelling and phylogenetic speculation that has traditionally characterized the field.

Introduction

In a recent paper, we (Hauser, Chomsky, & Fitch, 2002) (HCF hereafter) offered a framework for research on language evolution, stressing the importance of an empirical, comparative and interdisciplinary approach to this problem, and of distinguishing between several different notions of “language” found in the literature on this subject. In their paper “The Faculty of Language: What's Special about it?” Steven Pinker and Ray Jackendoff (PJ hereafter) present a critique of this paper. In our response, we begin by noting the many areas of agreement between HCF and PJ, among them the need to fractionate language into its component mechanisms, the need for an empirical approach to test hypotheses about these mechanisms, the value of comparative data from diverse animal species for doing so, and the need for collaborative, inter-disciplinary work in this endeavor. However, several distinctions and hypotheses that formed the core of our original paper have been misunderstood by PJ. We first clarify these core ideas before addressing PJ's specific criticisms concerning empirical evidence. Many of their criticisms are based on a mischaracterization of the perspective we outlined; but several substantive areas of disagreement are discussed. This section allows us to clarify certain issues that were left open in HCF, or unmentioned due to space constraints.

One main thrust of PJ's critique results from their blurring the distinction we drew between broad and narrow interpretations of the term “faculty of language.” Although PJ endorse this distinction, many of their arguments appear to result directly from a failure to make it themselves, or to perceive where we were making it. We thus start by clarifying this distinction, and its importance.

It rapidly became clear in the conversations leading up to HCF that considerable confusion has resulted from the use of “language” to mean different things. We realized that positions that seemed absurd and incomprehensible, and chasms that seemed unbridgeable, were rendered quite manageable once the misunderstandings were cleared up. For many linguists, “language” delineates an abstract core of computational operations, central to language and probably unique to humans. For many biologists and psychologists, “language” has much more general and various meanings, roughly captured by “the communication system used by human beings.” Neither of these explananda are more correct or proper, but statements about one of them may be completely inapplicable to the other. To this end, we denoted “language” in a broad sense, including all of the many mechanisms involved in speech and language, regardless of their overlap with other cognitive domains or with other species, as the “faculty of language in the broad sense” or FLB. This term is meant to be inclusive, describing all of the capacities that support language independently of whether they are specific to language and uniquely human. Second, given that language as a whole is unique to our species, it seems likely that some subset of the mechanisms of FLB is both unique to humans, and to language itself. We dubbed this subset of mechanisms the faculty of language in the narrow sense (FLN). Although these mechanisms have traditionally been the focus of considerable discussion and debate, they are neither the only, nor necessarily the most, interesting problems for biolinguistic research. The contents of FLN are to be empirically determined, and could possibly be empty, if empirical findings showed that none of the mechanisms involved are uniquely human or unique to language, and that only the way they are integrated is specific to human language. The distinction itself is intended as a terminological aid to interdisciplinary discussion and rapprochement, and obviously does not constitute a testable hypothesis.

We believe that a long history of unproductive debate about language evolution has resulted from a failure to keep this distinction clear, and that PJ, while agreeing with its importance in principle, have not made it in practice. Only this can explain their disagreement with the hypothesis they attribute to HCF at the culmination of their introduction: “that recursion is the only aspect of language that is special to it, that it evolved for functions other than language, and that this nullifies ‘the argument from design’ that sees language as an adaptation”. In any interpretation that equates the last “language” in this sentence with FLB, we not only disagree with this hypothesis (which is not our own), but reject it as extremely implausible. Our focus on the mechanism of recursion in HCF was intended as a plausible, testable hypothesis about a core component of FLB, and likely FLN, not a blanket statement about “language as adaptation.” Here, we hope to clarify any possible misunderstanding by exploring these issues in greater detail.

As we argued in HCF, treating “language“ as a monolithic whole both confuses discussions of its evolution and blocks the consideration of useful sources of comparative data. A more productive approach begins by unpacking FLB into its myriad component mechanisms. These components include both peripheral mechanisms necessary for the externalization of language, and core linguistic computational/cognitive mechanisms. The proper fractionation of FLB into its components is obviously not trivial or given, and it would be naïve to suppose that the biologically appropriate fractionation will precisely mirror traditional disciplinary subdivisions within linguistics (phonetics, phonology, syntax, semantics, etc.). For example, “phonetics” is traditionally concerned with the sounds of spoken language, while “phonology” concerns more abstract questions involving the mapping between sounds and linguistic structures. Though distinct, both components of language presumably tap some of the same mechanisms. The “phon-” root of both terms reveals their original preoccupation with sound, but language can also be externalized through the visual and manual modality, as in signed languages, raising tricky questions about the precise borders of the sensory-motor component of language. While it would be a mistake to exclude visual/motor mechanisms from FLB, it is not a core component for the vast majority of humans. This is not an issue we attempted to answer in HCF, nor will we do so here. We raise it simply to illustrate the complexity of the issues raised when one attempts to properly fractionate FLB.

In HCF, we offered one potential cut through FLB, explicitly distinguishing the sensory-motor (SM: phonetics/phonology) and conceptual-intentional (CI: semantics/pragmatics) systems from the computational components of language that have been the traditional focus of study in modern linguistics, including syntax, morphology, a phonological component that interacts with SM systems, and a formal semantic component that interacts with the CI system. We make no claims that this is the only correct way to fractionate FLB, explicitly leaving room for other components (see Figure 1 in HCF). “We make no attempt to be comprehensive in our coverage of relevant or interesting topics and problems” (p. 1570). However, contrary to PJ's suggestion, our framework does not exclude the many important issues that arise in phonology, morphology, or the lexicon. Questions concerning how internal computations relate signal and meaning are explicitly raised in the initial theoretical discussion (p. 1571), and must be, by definition, part of an adequate theory of language.

Something about the faculty of language must be unique in order to explain the differences between humans and other animals—if only the particular combination of mechanisms in FLB. We thus made the further, and independent, terminological proposal to denote that subset of FLB that is both specific to language and to humans as FLN. To repeat a central point in our paper: FLN is composed of those components of the overall faculty of language (FLB) that are both unique to humans and unique to or clearly specialized for language. The contents of FLN are to be empirically determined. Possible outcomes of this empirical endeavor include that ALL components of FLB are shared either with other species, or with other non-linguistic cognitive domains in humans, and only their combination and organization are unique to humans and language. Alternatively, FLN may turn out to include a very rich set of interconnected mechanisms, as assumed in many earlier versions of generative grammar. The only “claims” we make regarding FLN are that (1) in order to avoid confusion, it is important to distinguish it from FLB, and (2) comparative data are necessary, for obvious logical reasons, to decide upon its contents. An equally obvious point is that research on non-linguistic cognitive domains (number, navigation, social intelligence, music, and others) is fundamental to the proper eventual delineation of FLN.

PJ's central complaint with HCF lies with our further hypothesis—stated clearly as such in the paper—that only a relatively compact, but powerful, component of the computational component of language falls into the FLN subset of FLB (Hypothesis 3 of HCF). “We propose in this hypothesis that FLN comprises only the core computational mechanisms of recursion as they appear in narrow syntax and the mapping to the interfaces.” (p. 1573). The term “FLN” thus served dual duties in HCF. To be precise, we suggest that a significant piece of the linguistic machinery entails recursive operations, and that these recursive operations must interface with SM and CI (and thus include aspects of phonology, formal semantics and the lexicon insofar as they satisfy the uniqueness condition of FLN, as defined). These mappings themselves could be complex (though we do not know) because of conditions imposed by the interfaces. But our hypothesis focuses on a known property of human language that provides its most powerful and unusual signature: discrete infinity. We offered this hypothesis as a starting point for discussion and research, “restricting attention to FLN as just defined but leaving the possibility of a more inclusive definition open to further empirical research” (p. 1571). We do not define FLN as recursion by theoretical fiat (note, we say “a key component”), which would contradict the aims of our paper, but offer this as a plausible, falsifiable hypothesis worthy of empirical exploration. We hypothesize that “at a minimum, then, FLN includes the capacity of recursion”, because this is what virtually all modern approaches to language (including those endorsed by PJ) have agreed upon, at a minimum. Whatever else might be necessary for human language, the mechanisms underlying discrete infinity are a critical capability of FLB, and quite plausibly of FLN.

PJ give a long and detailed critique of the Minimalist Program (MP), based on their interpretation of how the minimalist program informed our “overall vision of what language is like.” In fact, partly for reasons of space, HCF barely discussed MP. The framework advanced in HCF for the study of language evolution does not rise or fall with the fate of the minimalist program. Indeed, most of our points (e.g. the FLN/FLB distinction, the value of an empirical, hypothesis-testing approach, the importance of comparative data, etc.) apply equally to any of the various flavors of modern generative grammar. Like HCF, our discussion here will be largely non-committal as regards the virtues and faults of the various flavors of generative grammar currently available. The only assumption made in HCF, and here, about syntactic theory is the uncontroversial one that, minimally, it should have a place for recursion. We think researchers in fields outside linguistics should adopt a wait-and-see attitude as these intradisciplinary issues are sorted out. It is certainly not the case that our framework is based on a covert “presumption that the Minimalist Program is ultimately going to be vindicated,” and we are quite puzzled by PJ's assertion to this effect.

PJ see minimalism as providing “a rationale” and “motivation” for our hypothesis 3—the only obvious justification for their long and detailed critique of minimalism. This speculation is incorrect. A primary motivation for writing HCF was our recognition of some pervasive confusion that have led to persistent and unnecessary misunderstandings among researchers interested in the biology and evolution of language. Such misunderstanding has polarized debate unnecessarily, has helped to fuel dogmatic and even hostile stances, and has generally acted to block progress in this field, including especially the severing of possible collaborative projects between linguists, psychologists and biologists. It has contributed to a situation in which animal researchers interested in language almost automatically consider themselves anti-linguist, or anti-generative, while some linguists feel justified in being anti-cognitive or anti-evolutionary. The FLN/FLB distinction, we hoped, would help the field to see that there is no incompatibility between the hypotheses that FLB is an adaptation that shares much with animals, and that the mechanism(s) underlying FLN might be quite unique. We further realized that earlier statements that had been interpreted as anti-evolutionary were in fact compatible with contemporary (and perfectly orthodox) neo-Darwinian theory. This realization, not a covert acceptance of minimalist precepts, was the primary motivation for writing HCF, and phrasing our hypotheses as we did.

PJ's comments about MP are thus mostly irrelevant to most of the topics of HCF, and of the current paper, and due to space constraints we are unable to discuss them fully here. However, lest readers conclude that PJ's characterization of MP is accurate, we devote an online appendix to correcting their many misconceptions about this research program (www.wjh.harvard.edu/~mnkylab). Research in a minimalist framework has made considerably more progress than allowed by PJ, and this research has addressed many of the issues on PJ's list of “ignored” phenomena.

Although we stress the independence of the framework advanced in HCF from the minimalist program, we did suggest and maintain here that a core element of FLN may be structured by considerations of efficient use of the core computational mechanisms of recursion; this is the only place where the discussion in HCF ties in directly to the minimalist program. One implication of this proposal is that much of the complex technology of earlier versions of generative grammar might possibly be eliminated, without losing (and sometimes gaining) empirical coverage (see online appendix). The only practical implication of this additional suggestion is that the study of the evolution of language will be made easier if this proposal turns out to be true, as opposed to more baroque alternative possibilities. If most of FLB builds upon ancient foundations, shared with other animals, we will have a much better chance of understanding these foundations from a genetic and neuroscientific viewpoint, because of the much greater variety of deployable experimental methods. If other aspects of FLB are shared with other cognitive domains (e.g. number, navigation, music, social intelligence) or overarching principles of efficient computation, that will vastly improve our chances of gaining an empirical grip on these mechanisms. The fact that a minimalist FLN would be easier to implement neurally, easier to code genetically, and easier to evolve should hardly be counted as evidence against it. Thus, should the minimalist approach find increasing empirical support, it would be good news for biologists and psychologists.

The hypothesis set laid out in HCF might be interpreted as a set of mutually exclusive alternatives. This would be an error. The hypotheses described represent different perspectives and focus on different targets of analysis. The first two hypotheses concern FLB, and were intended to span the range of currently available hypotheses. In contrast, our hypothesis 3 explicitly concerns only FLN; it is a proposal about what mechanisms are uniquely human. In contrast, PJ emphasize the design features of language “as an adaptation for communication.” Crucially, questions of mechanism are distinct from and orthogonal to questions of adaptive function (Tinbergen, 1963), a point clearly distinguished by Hauser (1996). This is not to say that questions at one level do not inform questions at another, as they surely do, but rather, that these are different questions that each require answers. We think PJ's (and others') overly restrictive emphasis on adaptive function is misplaced and counter-productive.

The term “adaptation’ conceals a conceptual minefield, long recognized as such by practicing evolutionary biologists (Mayr, 1982, West-Eberhard, 1992, Williams, 1966). Definitions run from diachronic and historical (Gould & Vrba, 1982) to purely synchronic and contemporary (Reeve & Sherman, 1993). Without further specification, the statement that “language is an adaptation” is thus vague enough to have few empirical consequences. In our opinion, there is no question that language evolved, and is very useful to humans for a variety of reasons. We thought our viewpoint on this issue was made relatively clear in HCF: language evolved, shows signs of adaptive design, and comparative data and interdisciplinary cooperation will be necessary to figure out the details of the evolutionary process. We didn't belabor the point as it seems relatively obvious and is far from a new idea, (e.g. Hauser, 1996, Hewes, 1973, Jackendoff, 2002, Lenneberg, 1967, Lieberman, 1975, Nottebohm, 1976, Pinker and Bloom, 1990). To go further than this requires a more rigorous unpacking of the term “adaptation” with respect to language. We will discuss two aspects in turn, first addressing the current utility of language, then turning to past function(s).

Questions about current utility are (at least in principle) empirically testable. But questions about original function are of a different logical type. It is an unfortunate fact that the two main sources of data to address such historical issues, namely paleontological and comparative, are simply unavailable for behavioral traits unique to one species. This is one reason that some biologists advocate a purely synchronic interpretation of “adaptation” (Reeve & Sherman, 1993). For some behavioral traits there are fossil data available to test hypotheses (e.g. we know from fossils that humans adopted a bipedal posture before brain size expansion), and for some linguistic mechanisms there may be relevant comparative data (e.g. for vocal learning). But, considering language as an unfractionated whole, neither type of data is available: “language” does not fossilize and is unique to humans. Thus, from an empirical perspective, there are not and probably never will be data capable of discriminating among the many plausible speculations that have been offered about the original function(s) of language, as for music, mathematical reasoning or a host of other interesting human abilities. We of course do not question PJ's right to speculate along these lines, as long as it remains clear that these speculations are not confused with, or offered as alternatives to, testable hypotheses. However, in our opinion, preoccupation with such questions has served as an impediment to more useful empirical research on the evolution, development, and neurobiological underpinnings of language.

Empirically addressing specific hypotheses concerning adaptation requires equally specific hypotheses about function. As we discuss below, “communication” is far too vague to constitute such a hypothesis, and none of the other candidates on offer seem much better. So why argue about them? Consider the analogous question: “What is the brain for?” No one would question the assertion that the brain is an adaptation (in some broad and not particularly helpful sense), but it would seem senseless to demand that neuroscientists agree upon an answer before studying neural function and computation. Even more specific questions like “what is the cerebellum for?” have defied resolution for many decades without blocking detailed and productive empirical research on this neural subsystem. The question “what was the cerebellum originally for?” is hardly even a topic of discussion. This is not to deny the possible utility of adaptive hypotheses in guiding empirical research: suitably specific adaptive hypotheses can serve a useful function in focusing and inspiring empirical research (see Fitch 2000a, Hauser, 1996 and Section 2.3.2 below). However, there is no need at present for researchers interested in the biology and evolution of language to resolve these issues, or even take a stand on them.

PJ are additionally concerned with the question of what an adaptation is “for”. To them, it seems quite obvious that “language is an adaptation for communication.” To understand our skepticism about this claim, consider a parallel question: “What is bat echolocation for?” If we interpret the question as one about current utility—“what do today's bats use their echolocation abilities for and how does it contribute to genetic fitness?”—then there are many correct answers. For example, bats use echolocation to find and capture prey (feeding), to navigate, to find mates, and to engage in aerial dogfights with competitors. Bat echolocation is “for” many things, each subserving different aspects of survival and reproduction. Although the majority of pulses are probably used for finding and capturing food, they are simultaneously employed in navigation, and also signal the bat's presence to conspecifics. The question is akin to asking “what is primate vision for?” There are many correct answers, some of them perhaps conflicting, and it would seem odd to stipulate any one of them as “the purpose” of vision or of echolocation. It is hard for us to see the scientific value of framing the question this way.

Returning to language, and distinguishing rigorously between FLB and FLN, the question of “what is FLB for?” clearly has many answers if interpreted in terms of current utility. Today, FLB is used extensively in both communication, and in private thought. The communicative uses can be further subdivided: humans use language in just about every social interaction, including courtship and mating, aggressive interactions with competitors, caring for offspring, sharing information with kin, etc. Thus there can be little doubt that language is useful for communication with other humans, and communication must be one of the primary selective forces that influenced the evolution of FLB. In fact, one of us wrote an entire book on the evolution of communication (Hauser, 1996) based on this observation. But the private uses of language are equally varied and important, including functions like problem-solving, enhancing social intelligence by rehearsing the thoughts of others, memory aids, focusing attention, etc. They seem to extend into almost every domain of thought. Further, many cognitive scientists have speculated, in the Whorfian tradition, that specific details of language may alter thought, creating cross-cultural cognitive differences (Bowerman & Levinson, 2001); if true this would further complicate the relation between FLB and thought. Finally, the phonological component of private speech might help serialize private cognition, focus attention on one train of thought, and increase the capacity of short-term memory. Thus, the phonological component is not necessarily superfluous to “private” uses of language, as PJ assert.

Questions about the specific current utility of FLN are better defined. Accepting for a moment our provisional, tentative assignment to FLN of only recursion and mapping to the interfaces, it seems clear that the current utility of recursive mental operations is not limited to communication. In addition to its clear utility for cognitive functions like interpreting mathematical formulas that are not plausibly adaptations at all, recursive thought would appear to be quite useful in such functions as planning, problem solving, or social cognition that might themselves be adaptations. As an example of how recursion plausibly functions in spatial reasoning and navigation, consider such concepts as ((((the hole) in the tree) in the glade) by the stream) and ask whether there is an obvious limit to such embedding of place concepts within place concepts (… in the forest by the plain between the mountains in the north of the island…). Our proposal that aspects of FLN may function in spatial navigation did not concern dead reckoning or landmark recognition, as PJ assume, but processes of optimal computation already established in animal navigation, like efficient path integration and no backtracking (e.g. Gallistel & Cramer, 1996). Thus, questions of current utility, while empirically addressable, offer little reason to conclude that either FLB or FLN are useful only in communication.

There is a different way, also interesting, of interpreting the question “what is bat echolocation for?” as a question about functional origins: “What was echolocation for in the first echolocating bats?” This is clearly a different question, and requires different analyses and data if it is to be answered. One potential source of data is the fossil record, but for most traits, paleontological data tell us when a trait appeared, but not why. Analyses of the middle ear in bat fossils suggest that microchiropteran bats evolved echolocation very early in their evolutionary history (Novacek, 1985), but do not tell us what they used it for. And this is exceptional: in the case of behavioral traits like language, even this much fossil data is unavailable. A more promising approach to questions of original function is the comparative method, as emphasized in HCF. If a trait is shared, the first question is whether it evolved independently (“analogy”) in different lineages or is shared by common descent (“homology”). Homologous traits, those shared via common descent, play a central role in comparative biology because they are the key to reconstructing phylogeny (Hall, 1994). However, the existence of homology seriously complicates questions of adaptation, since traits that were adaptive in the common ancestor of some clade are not necessarily so for each species that makes up the clade (Harvey & Pagel, 1991). Thus, while homologous traits are indispensable in systematics, they are not necessarily the traits of choice for the study of function and adaptation.

Organisms can also come to have similar traits through convergent evolution (“analogy”—one form of homoplasy). The discovery and analysis of analogous mechanisms is an equally interesting and important arm of the comparative method, because analogy can provide crucial insights into the adaptive nature of natural selection, independent of inherited details (e.g. Lockwood and Fleagle, 1999, Sanderson and Hufford, 1996). The similarities in body form between dolphins and seals, or in the wings of birds and bats, are independently evolved responses to the physical constraints of swimming and flight respectively. Such similarities provide the surest sign of adaptations to these ways of life, and are crucial in distinguishing adaptation from mere inherited similarity (Gould, 1976). Other types of homoplasy, such as reversions and parallelism, also provide insights into the role of constraints in evolution (Wake, 1991, Wake, 1996). Thus, scientists interested in the study of adaptation seek to discover and explore cases of convergence. Returning to bats, if we look at other species which have independently evolved echolocation, echolocating birds appear to use it solely for navigation (Suthers & Hector, 1988), as does a separate bat lineage, the megachiropteran bat Rousettus (Möhres, 1956). Echolocating cetaceans certainly use echolocation for navigation, and perceptual abilities to use sound to sense space exist in other mammals, including cats and humans (Griffin, 1958). The one thing common to all of these species is navigation, making the hypothesis that bat echolocation originally functioned in navigation, and was only later specialized for feeding and communication, a plausible one. But while plausible, it is extremely difficult to test or falsify. The primary value of such hypotheses is to drive comparative work and to lead to more specific, testable hypotheses about mechanistic function.

Regarding the original function of FLB, we advocate a multi-component, multifunctional perspective in HCF, and PJ's commitment to a view of language as a complex adaptation would appear to entail a similar perspective. From this perspective, it seems unproductive to assume, or to seek, a single answer to the question “What was FLB originally for?” An approach to language evolution that fractionates FLB into its component parts is unlikely to come up with the same overarching function for all of these mechanisms. Moreover, if this question is asked, then surely comparative evidence is absolutely critical to a satisfying answer. For example, several researchers have argued that the evolution of major components of FLB were driven by sexual selection (e.g. Darwin, 1871, Miller, 2001, Pinker and Bloom, 1990). For vocal imitation this seems quite plausible (based on comparisons with birdsong or whale song). But, based on comparative data, sexual selection seems unlikely to have driven the communication of complex facts about the world. This aspect of FLB seems more plausibly driven by kin selection or some other non-sexual selection (Fitch, 2004).

Regarding FLN, we wrote: “It is possible, as we discuss below, that key computational capacities evolved for reasons other than communication, but after they proved to have utility in communication, were altered because of constraints imposed at both the periphery … and more central levels.” (pp 1569–1570). This statement clearly does not deny a communicative role to FLB or FLN. It does, however, suggest the difficulties inevitably involved in discussions of past function(s) of any unique components of FLB. PJ state that “Chomsky's positive argument that language is not ‘for’ communication” is based on the use of language as inner speech. In the passage to which they refer (Chomsky 2000, pp. 76–7, not 75), not only is their “positive argument” not proposed, it is explicitly rejected. To quote in full: “Furthermore, whatever merit there may be to guesses about selectional processes that might, or might not, have shaped human language, they do not crucially depend on the belief that the system is an outgrowth of some mode of communication. One can devise equally meritorious (that is, equally pointless) tales of the advantage conferred by a series of small mutations that facilitated planning and clarification of thought…—not that I am proposing this or any other story. There is a rich record of the unhappy fate of highly plausible stories about what might have happened, once something was learned about what did happen—and in cases where far more is understood” (emphasis added). In discussion elsewhere, the same points about frequency of “inner speech” are adduced to illustrate the pitfalls in trying to determine “function” or “purpose” of a biological system from frequency of use (Chomsky, 2003).

A “positive argument” has been made, most forcefully by prominent biologists, that communicative needs would not have provided “any great selective pressure to produce a system such as language” with its crucial relation to “development of abstract or productive thinking” (Luria, 1974), through its unique property of allowing “infinite combinations of symbols” and therefore “mental creation of possible worlds” (Jacob, 1982). Of course current utility is a poor guide to past function, and it is an open question whether Luria and Jacob are right to question what PJ declare a “truism.” But PJ's position on this matter seems obscure. On the one hand, they forcefully deny the Luria-Jacob position. However they also insist on this position, claiming that basic properties of language derive from prior systems of “recursive thought.” There are some concrete proposals about “recursive thought”: namely, generative grammars that yield structures at the CI interface (e.g. Heim and Kratzer, 1998, Larson and Segal, 1995). But that cannot be what PJ mean. Perhaps they have in mind a “language of thought,” which evolved prior to FLB and includes its basic internal computational mechanisms. But that assumption simply transfers the basic questions of evolution from language to a language of thought, and this new problem cannot even be posed until we are told what the language of thought is. Whatever they may have in mind, PJ's view appears to be that FLB both is and is not an “instrument for expression of thought.”

In conclusion, seeking a single adaptive function for “language”, treated as a monolithic whole, is more likely to produce confusion and misunderstanding than insight. Treating any complex biological character as if it had a single function is likely to be unproductive at best, if not meaningless. Second, our hypothesis 3 concerns FLN, whatever its contents turn out to be, and not “language;” questions about either its current utility or original function are logically separate from those concerning other components of FLB. Our assertion that FLN is not obviously “for” communication in today's humans, and that there are other equally plausible precursors in past hominids or primates, seems a rather mild one. It is only when FLN is confused with FLB, or current utility conflated with original function, that consideration of this possibility seems unreasonable, or to be “denying a truism.”

To recap, we take for granted that the large set of complex mechanisms entering into FLB are adaptive in some broad sense, having been shaped by natural selection for, among other things, communication with other humans. We find this idea neither controversial nor particularly helpful in empirical investigations of the biological nature of the language faculty (FLB). Neither Pinker nor Jackendoff have used their theoretical arguments about the adaptive nature of language to fuel empirical work, to our knowledge. However, once FLB is fractionated into component mechanisms (a crucial but difficult process), we enter a realm where specific mechanisms can be empirically interrogated at all levels (mechanistic, developmental, phylogenetic and functional). Each mechanism might have its own separate phylogenetic and functional history, and we expect diverse answers as progress is made in this research program. As a potential example of this process, we offered our hypothesis 3: that FLN is restricted to a simple but powerful recursive mapping capability by definition, unique to humans and unique to the language faculty. This recursive mechanism has some plausible precursors in cognitive domains other than communication. We think these are worthy of more detailed investigation. Thus, while accepting that FLB is an adaptation, we hypothesized that FLN is not an adaptation “for communication.” Note that there is absolutely no contradiction between these two statements, as long as the distinction between FLN and FLB is kept clear.

Accepting our terminology, and the necessity of recursion in syntax, there are two ways one could rationally disagree with this hypothesis. First, FLN may include more than the computations subserving recursion and mappings to the interfaces to SM and CI, as we suggest in several places in HCF. If so, our Hypothesis 3 can simply be restated as specific to the recursive machinery and associated mappings, rather than FLN in full, and all the same considerations will apply. But in either case our hypothesis concerns a specific subset of linguistic mechanisms, not “language” in a broad sense. Second and less trivially, we argued that the mechanisms of recursion and its mappings are simple enough to nullify the adaptationist's “argument from design,” a proposition one can question. This more interesting question demands a much better understanding of the neural, developmental and genetic mechanisms underlying recursion and its mappings than currently available. Perhaps the apparent computational simplicity of recursion masks an implementation rich in detailed, fine-tuned shaping of time-hewn parts. But the onus is clearly upon the proponent of this hypothesis to demonstrate this: a priori, there is nothing obvious about it. That recursion is useful is obvious; this does not automatically make it an adaptation in the evolutionary sense.

Section snippets

What's special: a reexamination of the evidence

Our introductory remarks have clarified why the FLB/FLN distinction is critical for productive discussion of language evolution, and what, precisely, we suggested in hypothesis 3 of HCF. By failing to carry through with this distinction, effectively attributing to us the position that “language” (FLB) is recursion, PJ set up an easily-refuted caricature of our hypothesis. Consider as an illustration their discussion of the genetics of language. PJ cite the data concerning the small but

Conclusion: where do we go from here?

PJ's critique offers a vivid illustration of the problems that can arise if we fail to distinguish the various components of FLB, or if we confuse statements about one component with those concerning another. We doubt that future researchers will need to make a point of distinguishing FLN from FLB at every mention of the word “language,” as we have done here. However, keeping the object of discussion clearly delineated would certainly help to avoid future misunderstandings of this sort.

Acknowledgements

We thank Stephen Anderson, Andrew Carstairs-McCarthy, Simon Kirby, Robert Ladd, Jacques Mehler, Massimo Piattelli-Palmarini, Michael Studdert-Kennedy and an anonymous reviewer for their comments on earlier versions of this paper.

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