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nLab > Latest Changes: commutativity of limits and colimits

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- CommentRowNumber1.
- CommentAuthorMarc Hoyois
- CommentTimeJan 12th 2014
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Author: Marc Hoyois
Format: MarkdownItexAdded to [[commutativity of limits and colimits]] the case of coproducts commuting with connected limits in a topos, and the generalization to higher topoi. This particular instance of commutativity is not mentioned very often, probably because it's not very impressive in Set, but its generalization to higher topoi (for which I couldn't find a reference) is more interesting. For instance, cofiltered limits commute with taking quotients by an ∞-group in an ∞-topos.

Added to commutativity of limits and colimits the case of coproducts commuting with connected limits in a topos, and the generalization to higher topoi. This particular instance of commutativity is not mentioned very often, probably because it’s not very impressive in Set, but its generalization to higher topoi (for which I couldn’t find a reference) is more interesting. For instance, cofiltered limits commute with taking quotients by an ∞-group in an ∞-topos.
- CommentRowNumber2.
- CommentAuthorZhen Lin
- CommentTimeJan 13th 2014
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Author: Zhen Lin
Format: MarkdownItexI can believe the claim for finite connected limits – that property is really just inherited from $Set$. But why is true in the general case?

I can believe the claim for finite connected limits – that property is really just inherited from $Set$ . But why is true in the general case?
- CommentRowNumber3.
- CommentAuthorMarc Hoyois
- CommentTimeJan 13th 2014
- PermaLink
Author: Marc Hoyois
Format: MarkdownItexI meant Grothendieck topos, was that the issue? Here's a proof of the general case. If $A$ is an ∞-groupoid, the colimit functor $\mathbf{H}^A\to\mathbf{H}$ can be identified with the forgetful functor $\mathbf{H}_{/Disc(A)}\to\mathbf{H}$, by the ∞-Giraud axioms. If $C$ is an ∞-category such that $\lim_C Disc(A)\simeq Disc(A)$ (e.g. if A is n-truncated and C is n-connected), then that forgetful functor creates $C$-limits.

I meant Grothendieck topos, was that the issue?

Here’s a proof of the general case. If $A$ is an ∞-groupoid, the colimit functor $\mathbf{H}^A\to\mathbf{H}$ can be identified with the forgetful functor $\mathbf{H}_{/Disc(A)}\to\mathbf{H}$ , by the ∞-Giraud axioms. If $C$ is an ∞-category such that $\lim_C Disc(A)\simeq Disc(A)$ (e.g. if A is n-truncated and C is n-connected), then that forgetful functor creates $C$ -limits.
- CommentRowNumber4.
- CommentAuthorZhen Lin
- CommentTimeJan 13th 2014
- PermaLink
Author: Zhen Lin
Format: MarkdownItexNot being expert in $\infty$-categories, I will take your word for it. In the ordinary case, you are saying that the forgetful functor $\mathcal{E}_{/ \Delta X} \to \mathcal{E}$ creates connected limits (which is well-known) and identifying $\mathcal{E}_{/ \Delta X}$ with $\mathcal{E}^X$. This is true so long as $\mathcal{E}$ is an infinitary extensive category.

Not being expert in $\infty$ -categories, I will take your word for it. In the ordinary case, you are saying that the forgetful functor $\mathcal{E}_{/ \Delta X} \to \mathcal{E}$ creates connected limits (which is well-known) and identifying $\mathcal{E}_{/ \Delta X}$ with $\mathcal{E}^X$ . This is true so long as $\mathcal{E}$ is an infinitary extensive category.
- CommentRowNumber5.
- CommentAuthorDavidRoberts
- CommentTimeDec 17th 2017
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Author: DavidRoberts
Format: MarkdownItexAt <https://ncatlab.org/nlab/show/commutativity+of+limits+and+colimits#ColimitsStableByBaseChange> surely one could also list regular extensive categories? Just checking I'm not being stupid (could be the case...)

At https://ncatlab.org/nlab/show/commutativity+of+limits+and+colimits#ColimitsStableByBaseChange surely one could also list regular extensive categories? Just checking I’m not being stupid (could be the case…)
- CommentRowNumber6.
- CommentAuthorMike Shulman
- CommentTimeDec 18th 2017
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Author: Mike Shulman
Format: MarkdownItexYes... but why is that section there at all? It's not an example of commutativity of limits and colimits. And we already have [[universal colimit]].

Yes… but why is that section there at all? It’s not an example of commutativity of limits and colimits. And we already have universal colimit.
- CommentRowNumber7.
- CommentAuthorUrs
- CommentTimeDec 18th 2017
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Author: Urs
Format: MarkdownItex> It’s not an example of commutativity of limits and colimits. Are we talking about $$ \underset{d \in D}{colim} (F(d) \times_Z Y) \stackrel{\simeq}{\longrightarrow} (\underset{d \in D}{colim} F(d)) \times_Z Y $$ ?

It’s not an example of commutativity of limits and colimits.

Are we talking about
$\underset{d \in D}{colim} (F(d) \times_Z Y) \stackrel{\simeq}{\longrightarrow} (\underset{d \in D}{colim} F(d)) \times_Z Y$
?
- CommentRowNumber8.
- CommentAuthorDavidRoberts
- CommentTimeDec 18th 2017
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Author: DavidRoberts
Format: MarkdownItexI thought so.

I thought so.
- CommentRowNumber9.
- CommentAuthorMike Shulman
- CommentTimeDec 18th 2017
- PermaLink
Author: Mike Shulman
Format: MarkdownItexYes, that's what we're talking about.

Yes, that’s what we’re talking about.
- CommentRowNumber10.
- CommentAuthorDavidRoberts
- CommentTimeDec 18th 2017
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Author: DavidRoberts
Format: MarkdownItexSo how is it not an example?

So how is it not an example?
- CommentRowNumber11.
- CommentAuthorMike Shulman
- CommentTimeDec 18th 2017
- PermaLink
Author: Mike Shulman
Format: MarkdownItexHow *is* it an example? Commutativity of limits and colimits means $colim^D \circ lim^E = lim^E \circ colim^D$ as functors on a diagram category $C^{D\times E}$.

How is it an example? Commutativity of limits and colimits means $colim^D \circ lim^E = lim^E \circ colim^D$ as functors on a diagram category $C^{D\times E}$ .
- CommentRowNumber12.
- CommentAuthorDavidRoberts
- CommentTimeDec 18th 2017
- (edited Dec 18th 2017)
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Author: DavidRoberts
Format: MarkdownItexAh, I see your point. Not immediately obvious, if at all true.

Ah, I see your point. Not immediately obvious, if at all true.
- CommentRowNumber13.
- CommentAuthorRichard Williamson
- CommentTimeDec 18th 2017
- (edited Dec 18th 2017)
- PermaLink
Author: Richard Williamson
Format: MarkdownItexSurely, if $E$ is $\bullet \rightarrow \bullet \leftarrow \bullet$, and $J : D \times E \rightarrow C$ sends $(d, \bullet \rightarrow \bullet \leftarrow \bullet)$ to $F(d) \rightarrow Z \leftarrow Y$, and does the obvious levelwise thing on arrows in $D$ (i.e. constant on $Z$ and $Y$), then the equation $colim^{D} \circ lim^{E}(J) = lim^{E} \circ \colim^{D}(J)$ expresses exactly that $ \underset{d \in D}{colim} (F(d) \times_Z Y) \stackrel{\simeq}{\longrightarrow} (\underset{d \in D}{colim} F(d)) \times_Z Y$?

Surely, if $E$ is $\bullet \rightarrow \bullet \leftarrow \bullet$ , and $J : D \times E \rightarrow C$ sends $(d, \bullet \rightarrow \bullet \leftarrow \bullet)$ to $F(d) \rightarrow Z \leftarrow Y$ , and does the obvious levelwise thing on arrows in $D$ (i.e. constant on $Z$ and $Y$ ), then the equation $colim^{D} \circ lim^{E}(J) = lim^{E} \circ \colim^{D}(J)$ expresses exactly that $\underset{d \in D}{colim} (F(d) \times_Z Y) \stackrel{\simeq}{\longrightarrow} (\underset{d \in D}{colim} F(d)) \times_Z Y$ ?
- CommentRowNumber14.
- CommentAuthorMike Shulman
- CommentTimeDec 18th 2017
- PermaLink
Author: Mike Shulman
Format: MarkdownItex@Richard: only if the colimit of a constant $D$-diagram is equal to the object that it's constant at. For 1-colimits this is true if $D$ is connected; for $\infty$-colimits it's only true if $D$ has a contractible nerve.

@Richard: only if the colimit of a constant $D$ -diagram is equal to the object that it’s constant at. For 1-colimits this is true if $D$ is connected; for $\infty$ -colimits it’s only true if $D$ has a contractible nerve.
- CommentRowNumber15.
- CommentAuthorDavidRoberts
- CommentTimeDec 19th 2017
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Author: DavidRoberts
Format: MarkdownItexI'm only interested in the case of 1-categories, which is not treated at [[universal colimit]].

I’m only interested in the case of 1-categories, which is not treated at universal colimit.
- CommentRowNumber16.
- CommentAuthorMike Shulman
- CommentTimeDec 19th 2017
- PermaLink
Author: Mike Shulman
Format: MarkdownItexWell, it should be. Just copy and paste the definition given and remove all the $\infty$s.

Well, it should be. Just copy and paste the definition given and remove all the $\infty$ s.
- CommentRowNumber17.
- CommentAuthorUrs
- CommentTimeDec 19th 2017
- (edited Dec 19th 2017)
- PermaLink
Author: Urs
Format: MarkdownItexWhile it's not generally an example of the functorial commutaticity $$ \underset{\underset{D}{\longrightarrow}}{\lim} \circ \underset{\underset{C}{\longleftarrow}}{\lim} \simeq \underset{\underset{C}{\longleftarrow}}{\lim} \circ \underset{\underset{D}{\longrightarrow}}{\lim} \;\colon\; \mathcal{C}^{C \times D} \to \mathcal{C} $$ the formula $$ \underset{d \in D}{colim} (F(d) \times_Z Y) \stackrel{\simeq}{\longrightarrow} (\underset{d \in D}{colim} F(d)) \times_Z Y $$ is still syntactically an exchange of the order of taking limits and colimits and as such is something that a reader may appreciate finding discussed on this page. So I vote for leaving the material there. But I added the warning: [here](https://ncatlab.org/nlab/show/commutativity+of+limits+and+colimits#BewareThatUniversalColimitsAreNotStrictlySpeakingColimitsCommutingWithPullback)

While it’s not generally an example of the functorial commutaticity
$\underset{\underset{D}{\longrightarrow}}{\lim} \circ \underset{\underset{C}{\longleftarrow}}{\lim} \simeq \underset{\underset{C}{\longleftarrow}}{\lim} \circ \underset{\underset{D}{\longrightarrow}}{\lim} \;\colon\; \mathcal{C}^{C \times D} \to \mathcal{C}$
the formula
$\underset{d \in D}{colim} (F(d) \times_Z Y) \stackrel{\simeq}{\longrightarrow} (\underset{d \in D}{colim} F(d)) \times_Z Y$
is still syntactically an exchange of the order of taking limits and colimits and as such is something that a reader may appreciate finding discussed on this page.

So I vote for leaving the material there. But I added the warning: here
- CommentRowNumber18.
- CommentAuthorMike Shulman
- CommentTimeDec 19th 2017
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Author: Mike Shulman
Format: MarkdownItexI agree that a reader may appreciate finding something about it, but I think what they should find is a link to the place where it is properly discussed.

I agree that a reader may appreciate finding something about it, but I think what they should find is a link to the place where it is properly discussed.
- CommentRowNumber19.
- CommentAuthorUrs
- CommentTimeDec 19th 2017
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Author: Urs
Format: MarkdownItexSounds hardly objectionable. Maybe I am missing what is under debate.

Sounds hardly objectionable. Maybe I am missing what is under debate.
- CommentRowNumber20.
- CommentAuthorDavidRoberts
- CommentTimeDec 19th 2017
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Author: DavidRoberts
Format: MarkdownItexI just wanted to expand the list of examples, wherever the list is given. I was trying to find alternative hypotheses for a result of Todd's (at this point, [Lemma 1.5 here](https://ncatlab.org/toddtrimble/published/Initial+algebras+and+terminal+coalgebras)) and double checking before adding to the page on colimits/limits.

I just wanted to expand the list of examples, wherever the list is given. I was trying to find alternative hypotheses for a result of Todd’s (at this point, Lemma 1.5 here) and double checking before adding to the page on colimits/limits.
- CommentRowNumber21.
- CommentAuthorRichard Williamson
- CommentTimeDec 19th 2017
- PermaLink
Author: Richard Williamson
Format: MarkdownItexRe #14: Thanks, Mike! To me, though, it seems more like the definition at [[commutativity of limits and colimits]] should not necessarily be taken as the default one in the non-connected case. Take a coproduct, for instance. Using the fold arrows out of the coproduct, one recovers the canonical arrow we are discussing, and it seems to me that the latter one is actually the one that more 'correctly' expresses a useful notion of commutativity of limits and colimits. As Urs put it, syntactically it seems equally justifiable as well. Great that the warning has been added to the page, that is the most important thing I think.

Re #14: Thanks, Mike!

To me, though, it seems more like the definition at commutativity of limits and colimits should not necessarily be taken as the default one in the non-connected case. Take a coproduct, for instance. Using the fold arrows out of the coproduct, one recovers the canonical arrow we are discussing, and it seems to me that the latter one is actually the one that more ’correctly’ expresses a useful notion of commutativity of limits and colimits. As Urs put it, syntactically it seems equally justifiable as well.

Great that the warning has been added to the page, that is the most important thing I think.
- CommentRowNumber22.
- CommentAuthorMike Shulman
- CommentTimeDec 19th 2017
- PermaLink
Author: Mike Shulman
Format: MarkdownItexIf anyone can formulate a general notion of "commutativity of limits and colimits" that includes pullback-stability of colimits and also all the other examples on the page, I'd love to hear it. Otherwise, I'd like to move the former to a different page. Having precise definitions and categorizing things appropriately helps to alleviate just this sort of confusion.

If anyone can formulate a general notion of “commutativity of limits and colimits” that includes pullback-stability of colimits and also all the other examples on the page, I’d love to hear it. Otherwise, I’d like to move the former to a different page. Having precise definitions and categorizing things appropriately helps to alleviate just this sort of confusion.
- CommentRowNumber23.
- CommentAuthorRichard Williamson
- CommentTimeDec 19th 2017
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Author: Richard Williamson
Format: MarkdownItexAs long as $C$ has an initial object, maybe we can just formally add an initial object $\emptyset$ to $D$ and send $(\emptyset, \bullet \rightarrow \bullet \leftarrow \bullet)$ to $\emptyset \rightarrow Z \leftarrow Y$? Haven't checked carefully...

As long as $C$ has an initial object, maybe we can just formally add an initial object $\emptyset$ to $D$ and send $(\emptyset, \bullet \rightarrow \bullet \leftarrow \bullet)$ to $\emptyset \rightarrow Z \leftarrow Y$ ? Haven’t checked carefully…
- CommentRowNumber24.
- CommentAuthorMarc Hoyois
- CommentTimeDec 20th 2017
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Author: Marc Hoyois
Format: MarkdownItexI think universal colimits is an example of [[distributivity of limits over colimits]], for the functor $(a\to b\leftarrow c) \to Cat $ sending $a$ to the given indexing category and $b,c$ to the point.

I think universal colimits is an example of distributivity of limits over colimits, for the functor $(a\to b\leftarrow c) \to Cat$ sending $a$ to the given indexing category and $b,c$ to the point.
- CommentRowNumber25.
- CommentAuthorDavidRoberts
- CommentTimeDec 20th 2017
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Author: DavidRoberts
Format: MarkdownItexFWIW I added the example I originally asked about.

FWIW I added the example I originally asked about.
- CommentRowNumber26.
- CommentAuthorRichard Williamson
- CommentTimeDec 20th 2017
- PermaLink
Author: Richard Williamson
Format: MarkdownItexRe #24, I think is indeed the construction I was getting at in #21. Seems more relevant than plain commutativity in the non-connected case. But maybe #23 provides an alternative way to see it as an actual instance of plain commutativity if one insists on that (one can always add an initial object to $C$ as well, of course, and then just use the forgetful functor back to $C$ at the end). If I have not made a mistake, then #23 should also work in the $\infty$-case.

Re #24, I think is indeed the construction I was getting at in #21. Seems more relevant than plain commutativity in the non-connected case. But maybe #23 provides an alternative way to see it as an actual instance of plain commutativity if one insists on that (one can always add an initial object to $C$ as well, of course, and then just use the forgetful functor back to $C$ at the end). If I have not made a mistake, then #23 should also work in the $\infty$ -case.
- CommentRowNumber27.
- CommentAuthorMike Shulman
- CommentTimeDec 26th 2017
- PermaLink
Author: Mike Shulman
Format: MarkdownItexYes, I think #24 works. Good job Marc! I think #23 works as long as the pullback of $\emptyset \to Z\leftarrow Y$ in $C$ is $\emptyset$, i.e. as long as we already know that initial objects are stable under pullback (which is equivalent to the initial object being [[strict initial object|strict]]). But if we don't yet know whether the initial object of $C$ is strict, and we want to formulate the condition for its being pullback-stable, then #23 doesn't work to write that as a commutativity condition. I don't think it helps to add a new initial object to $C$ either, since then the colimit of the modified diagram would be the new initial object rather than the "real" one in $C$ that we want to be talking about. Given that pullback-stability of colimits is an instance of distributivity, but is also *sometimes* an instance of commutativity, and the technicalities of regarding it as the latter are a little subtle, I still think we should move all substantial discussion and examples of pullback-stability to [[universal colimit]]. We can include explanations at [[commutativity of limits and colimits]] and [[distributivity of limits over colimits]] of how (and when) they specialize to pullback-stability, and links to these discussions from [[universal colimit]]. Objections?

Yes, I think #24 works. Good job Marc!

I think #23 works as long as the pullback of $\emptyset \to Z\leftarrow Y$ in $C$ is $\emptyset$ , i.e. as long as we already know that initial objects are stable under pullback (which is equivalent to the initial object being strict). But if we don’t yet know whether the initial object of $C$ is strict, and we want to formulate the condition for its being pullback-stable, then #23 doesn’t work to write that as a commutativity condition. I don’t think it helps to add a new initial object to $C$ either, since then the colimit of the modified diagram would be the new initial object rather than the “real” one in $C$ that we want to be talking about.

Given that pullback-stability of colimits is an instance of distributivity, but is also sometimes an instance of commutativity, and the technicalities of regarding it as the latter are a little subtle, I still think we should move all substantial discussion and examples of pullback-stability to universal colimit. We can include explanations at commutativity of limits and colimits and distributivity of limits over colimits of how (and when) they specialize to pullback-stability, and links to these discussions from universal colimit. Objections?
- CommentRowNumber28.
- CommentAuthorMike Shulman
- CommentTimeDec 26th 2017
- PermaLink
Author: Mike Shulman
Format: MarkdownItexI went ahead and added #24 as an example to [[distributivity of limits over colimits]].

I went ahead and added #24 as an example to distributivity of limits over colimits.
- CommentRowNumber29.
- CommentAuthorDavidRoberts
- CommentTimeDec 26th 2017
- PermaLink
Author: DavidRoberts
Format: MarkdownItexRe #27 good idea, thanks.

Re #27 good idea, thanks.
- CommentRowNumber30.
- CommentAuthorMike Shulman
- CommentTimeFeb 25th 2018
- PermaLink
Author: Mike Shulman
Format: MarkdownItexI implemented my suggestion at #27, and also moved the definition into a "Definition" section and added a section on preservation by functor categories and localizations (explaining in particular why filtered colimits commute with finite limits in all toposes).

I implemented my suggestion at #27, and also moved the definition into a “Definition” section and added a section on preservation by functor categories and localizations (explaining in particular why filtered colimits commute with finite limits in all toposes).
- CommentRowNumber31.
- CommentAuthorUrs
- CommentTimeJun 14th 2018
- PermaLink
Author: Urs
Format: MarkdownItextocuched the section [Sifted colimits commute with finite products](https://ncatlab.org/nlab/show/commutativity+of+limits+and+colimits#SiftedColimitsCommuteWithFiniteProducts). Added hyperlinks and pointer to the reference given. <a href="https://ncatlab.org/nlab/revision/diff/commutativity+of+limits+and+colimits/24">diff</a>, <a href="https://ncatlab.org/nlab/revision/commutativity+of+limits+and+colimits/24">v24</a>, <a href="https://ncatlab.org/nlab/show/commutativity+of+limits+and+colimits">current</a>

tocuched the section Sifted colimits commute with finite products. Added hyperlinks and pointer to the reference given.

diff, v24, current
- CommentRowNumber32.
- CommentAuthorvarkor
- CommentTimeMay 30th 2022
- PermaLink
Author: varkor
Format: MarkdownItexAdded some references. <a href="https://ncatlab.org/nlab/revision/diff/commutativity+of+limits+and+colimits/27">diff</a>, <a href="https://ncatlab.org/nlab/revision/commutativity+of+limits+and+colimits/27">v27</a>, <a href="https://ncatlab.org/nlab/show/commutativity+of+limits+and+colimits">current</a>

Added some references.

diff, v27, current
- CommentRowNumber33.
- CommentAuthorvarkor
- CommentTimeMay 30th 2022
- PermaLink
Author: varkor
Format: MarkdownItexOne thing I'm not sure about is that Eckmann and Hilton state: > The transformation w, together with the question when w is an equivalence, have already been considered by Roos [8], under the heading of the distributivity of lim with respect to lim but on [[distributivity of limits over colimits]], Roos is cited as defining *distributivity* rather than *commutativity*. So either Eckmann and Hilton are misinformed, or the nLab page is incorrect.

One thing I’m not sure about is that Eckmann and Hilton state:

The transformation w, together with the question when w is an equivalence, have already been considered by Roos [8], under the heading of the distributivity of lim with respect to lim

but on distributivity of limits over colimits, Roos is cited as defining distributivity rather than commutativity. So either Eckmann and Hilton are misinformed, or the nLab page is incorrect.
- CommentRowNumber34.
- CommentAuthorvarkor
- CommentTimeMay 30th 2022
- PermaLink
Author: varkor
Format: MarkdownItexIt strikes me that commutation of limits and colimits can be seen as a kind of limit–colimit coincidence, which is essentially an [[absolute colimit]] phenomenon (see Mike's [answer to this MO question](https://mathoverflow.net/a/267324), for instance). Does this suggest that the enriched perspective of absolute weighted (co)limits could shed some light on commutation of limits and colimits?

It strikes me that commutation of limits and colimits can be seen as a kind of limit–colimit coincidence, which is essentially an absolute colimit phenomenon (see Mike’s answer to this MO question, for instance). Does this suggest that the enriched perspective of absolute weighted (co)limits could shed some light on commutation of limits and colimits?
- CommentRowNumber35.
- CommentAuthorUrs
- CommentTimeMay 1st 2023
- PermaLink
Author: Urs
Format: MarkdownItexadded pointer to * [[Saunders MacLane]], §IX.2 in: *[[Categories for the Working Mathematician]]*, Graduate texts in mathematics, Springer (1971) [[doi:10.1007/978-1-4757-4721-8](https://link.springer.com/book/10.1007/978-1-4757-4721-8)] <a href="https://ncatlab.org/nlab/revision/diff/commutativity+of+limits+and+colimits/30">diff</a>, <a href="https://ncatlab.org/nlab/revision/commutativity+of+limits+and+colimits/30">v30</a>, <a href="https://ncatlab.org/nlab/show/commutativity+of+limits+and+colimits">current</a>
added pointer to
- Saunders MacLane, §IX.2 in: Categories for the Working Mathematician, Graduate texts in mathematics, Springer (1971) [doi:10.1007/978-1-4757-4721-8]
diff, v30, current

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