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| with | |
| dau as ( | |
| -- This part of the query can be pretty much anything. | |
| -- The only requirement is that it have three columns: | |
| -- dt, user_id, inc_amt | |
| -- Where dt is a date and user_id is some unique identifier for a user. | |
| -- Each dt-user_id pair should be unique in this table. | |
| -- inc_amt represents the amount of value that this user created on dt. | |
| -- The most common case is | |
| -- inc_amt = incremental revenue from the user on dt | |
| -- If you want to do L28 growth accounting, user inc_amt=1. | |
| -- The version here derives everything from the tutorial.yammer_events | |
| -- data set provided for free by Mode. | |
| -- If you edit just this part to represent your data, the rest | |
| -- of the query should run just fine. | |
| -- The query here is a sample that works in the public Mode Analytics | |
| -- tutorial. | |
| select | |
| user_id, | |
| date(occurred_at) as dt, | |
| sum(user_type) as inc_amt | |
| from tutorial.yammer_events | |
| group by 1,2 | |
| ), | |
| -- First, set up WAU and MAU tables for future use | |
| wau as ( | |
| select | |
| date_trunc('week', dt) as week, | |
| user_id, | |
| sum(inc_amt) as inc_amt | |
| from dau | |
| group by 1,2 | |
| ), | |
| mau as ( | |
| select | |
| date_trunc('month',dt) as month, | |
| user_id, | |
| sum(inc_amt) as inc_amt | |
| from dau | |
| group by 1,2 | |
| ), | |
| -- This determines the cohort date of each user. In this case we are | |
| -- deriving it from DAU data but you can feel free to replace it with | |
| -- registration date if that's more appropriate. | |
| first_dt as ( | |
| select | |
| user_id, | |
| min(dt) as first_dt, | |
| date_trunc('week', min(dt)) as first_week, | |
| date_trunc('month', min(dt)) as first_month | |
| from dau | |
| group by 1 | |
| ), | |
| mau_decorated as ( | |
| select | |
| d.month, | |
| d.user_id, | |
| d.inc_amt, | |
| f.first_month | |
| from mau d, first_dt f | |
| where d.user_id = f.user_id | |
| and inc_amt > 0 | |
| ), | |
| -- This is MAU growth accounting. Note that this does not require any | |
| -- information about inc_amt. As discussed in the articles, these | |
| -- quantities satisfy some identities: | |
| -- MAU(t) = retained(t) + new(t) + resurrected(t) | |
| -- MAU(t - 1 month) = retained(t) + churned(t) | |
| mau_growth_accounting as ( | |
| select | |
| coalesce(tm.month, lm.month + interval '1 month') as month, | |
| count(distinct tm.user_id) as mau, | |
| count(distinct case when lm.user_id is not NULL then tm.user_id | |
| else NULL end) as retained, | |
| count(distinct case when tm.first_month = tm.month then tm.user_id | |
| else NULL end) as new, | |
| count(distinct case when tm.first_month != tm.month | |
| and lm.user_id is NULL then tm.user_id else NULL end | |
| ) as resurrected, | |
| -1*count(distinct case when tm.user_id is NULL then lm.user_id | |
| else NULL end) as churned | |
| from | |
| mau_decorated tm | |
| full outer join mau_decorated lm on ( | |
| tm.user_id = lm.user_id | |
| and tm.month = lm.month + interval '1 month' | |
| ) | |
| group by 1 | |
| order by 1 | |
| ), | |
| -- This generates the familiar monthly cohort retention dataset. | |
| mau_retention_by_cohort as ( | |
| select | |
| first_month, | |
| 12 * extract(year from age(month, first_month)) + | |
| extract(month from age(month, first_month)) as months_since_first, | |
| count(1) as active_users, | |
| sum(inc_amt) as inc_amt | |
| from mau_decorated | |
| group by 1,2 | |
| order by 1,2 | |
| ), | |
| -- This is the MRR growth accounting (or growth accounting of whatever | |
| -- value you put in inc_amt). These also satisfy some identities: | |
| -- MRR(t) = retained(t) + new(t) + resurrected(t) + expansion(t) | |
| -- MAU(t - 1 month) = retained(t) + churned(t) + contraction(t) | |
| mrr_growth_accounting as ( | |
| select | |
| coalesce(tm.month, lm.month + interval '1 month') as month, | |
| sum(tm.inc_amt) as rev, | |
| sum( | |
| case | |
| when tm.user_id is not NULL and lm.user_id is not NULL | |
| and tm.inc_amt >= lm.inc_amt then lm.inc_amt | |
| when tm.user_id is not NULL and lm.user_id is not NULL | |
| and tm.inc_amt < lm.inc_amt then tm.inc_amt | |
| else 0 | |
| end | |
| ) as retained, | |
| sum( | |
| case when tm.first_month = tm.month then tm.inc_amt | |
| else 0 end | |
| ) as new, | |
| sum( | |
| case when tm.month != tm.first_month and tm.user_id is not NULL | |
| and lm.user_id is not NULL and tm.inc_amt > lm.inc_amt | |
| and lm.inc_amt > 0 then tm.inc_amt - lm.inc_amt | |
| else 0 end | |
| ) as expansion, | |
| sum( | |
| case when tm.user_id is not NULL | |
| and (lm.user_id is NULL or lm.inc_amt = 0) | |
| and tm.inc_amt > 0 and tm.first_month != tm.month | |
| then tm.inc_amt | |
| else 0 end | |
| ) as resurrected, | |
| -1 * sum( | |
| case | |
| when tm.month != tm.first_month and tm.user_id is not NULL | |
| and lm.user_id is not NULL | |
| and tm.inc_amt < lm.inc_amt and tm.inc_amt > 0 | |
| then lm.inc_amt - tm.inc_amt | |
| else 0 end | |
| ) as contraction, | |
| -1 * sum( | |
| case when lm.inc_amt > 0 and (tm.user_id is NULL or tm.inc_amt = 0) | |
| then lm.inc_amt else 0 end | |
| ) as churned | |
| from | |
| mau_decorated tm | |
| full outer join mau_decorated lm on ( | |
| tm.user_id = lm.user_id | |
| and tm.month = lm.month + interval '1 month' | |
| ) | |
| group by 1 | |
| order by 1 | |
| ), | |
| -- These next tables are to compute LTV via the cohorts_cumulative table. | |
| -- The LTV here is being computed for weekly cohorts on weekly intervals. | |
| -- The queries can be modified to compute it for cohorts of any size | |
| -- on any time window frequency. | |
| wau_decorated as ( | |
| select | |
| week, | |
| w.user_id, | |
| w.inc_amt, | |
| f.first_week | |
| from wau w, first_dt f | |
| where w.user_id = f.user_id | |
| ), | |
| cohorts as ( | |
| select | |
| first_week, | |
| week as active_week, | |
| ceil(extract(DAYS from (week - first_week))/7.0) as weeks_since_first, | |
| count(distinct user_id) as users, | |
| sum(inc_amt) as inc_amt | |
| from wau_decorated | |
| group by 1,2,3 | |
| order by 1,2 | |
| ), | |
| cohort_sizes as ( | |
| select | |
| first_week, | |
| users, | |
| inc_amt | |
| from cohorts | |
| where weeks_since_first = 0 | |
| ), | |
| cohorts_cumulative as ( | |
| -- A semi-cartesian join accomplishes the cumulative behavior. | |
| select | |
| c1.first_week, | |
| c1.active_week, | |
| c1.weeks_since_first, | |
| c1.users, | |
| cs.users as cohort_num_users, | |
| 1.0 * c1.users/cs.users as retained_pctg, | |
| c1.inc_amt, | |
| sum(c2.inc_amt) as cum_amt, | |
| 1.0*sum(c2.inc_amt)/cs.users as cum_amt_per_user | |
| from | |
| cohorts c1, | |
| cohorts c2, | |
| cohort_sizes cs | |
| where | |
| c1.first_week = c2.first_week | |
| and c2.weeks_since_first <= c1.weeks_since_first | |
| and cs.first_week = c1.first_week | |
| group by 1,2,3,4,5,6,7 | |
| order by 1,2 | |
| ), | |
| -- monthly cumulative cohorts | |
| cohorts_m as ( | |
| select | |
| first_month, | |
| month as active_month, | |
| extract(month from month) - extract(month from first_month) | |
| + 12*(extract(year from month) - extract(year from first_month)) as months_since_first, | |
| count(distinct user_id) as users, | |
| sum(inc_amt) as inc_amt | |
| from mau_decorated | |
| group by 1,2,3 | |
| order by 1,2 | |
| ), | |
| cohort_sizes_m as ( | |
| select | |
| first_month, | |
| users, | |
| inc_amt | |
| from cohorts_m | |
| where months_since_first = 0 | |
| ), | |
| cohorts_cumulative_m as ( | |
| -- A semi-cartesian join accomplishes the cumulative behavior. | |
| select | |
| c1.first_month, | |
| c1.active_month, | |
| c1.months_since_first, | |
| c1.users, | |
| cs.users as cohort_num_users, | |
| 1.0 * c1.users/cs.users as retained_pctg, | |
| c1.inc_amt, | |
| sum(c2.inc_amt) as cum_amt, | |
| 1.0*sum(c2.inc_amt)/cs.users as cum_amt_per_user | |
| from | |
| cohorts_m c1, | |
| cohorts_m c2, | |
| cohort_sizes_m cs | |
| where | |
| c1.first_month = c2.first_month | |
| and c2.months_since_first <= c1.months_since_first | |
| and cs.first_month = c1.first_month | |
| group by 1,2,3,4,5,6,7 | |
| order by 1,2 | |
| ) | |
| -- For MAU retention by cohort, useful for the standard retention heatmap | |
| select * from mau_retention_by_cohort | |
| -- For cumulative LTV data use this | |
| select * from cohorts_cumulative | |
| -- For cumulative LTV with monthly cohorts use this | |
| select * from cohorts_cumulative_m | |
| -- For MAU growth accuonting use this | |
| select * from mau_growth_accounting | |
| -- For MRR growth accuonting use this | |
| select * from mrr_growth_accounting | |
| -- For use as weekly input in the 8-ball tool use this | |
| select | |
| first_week as cohort_week, | |
| active_week as activity_week, | |
| users, | |
| inc_amt as revenue | |
| from cohorts_cumulative | |
| -- For use as monthly input in the 8-ball tool use this | |
| select | |
| first_month as cohort_month, | |
| active_month as activity_month, | |
| users, | |
| inc_amt as revenue | |
| from cohorts_cumulative_m |
with
dau as (
-- This part of the query can be pretty much anything.
-- The only requirement is that it have three columns:
-- dt, user_id, inc_amt
-- Where dt is a date and user_id is some unique identifier for a user.
-- Each dt-user_id pair should be unique in this table.
-- inc_amt represents the amount of value that this user created on dt.
-- The most common case is
-- inc_amt = incremental revenue from the user on dt
-- If you want to do L28 growth accounting, user inc_amt=1.
-- The version here derives everything from the tutorial.yammer_events
-- data set provided for free by Mode.
-- If you edit just this part to represent your data, the rest
-- of the query should run just fine.
-- The query here is a sample that works in the public Mode Analytics
-- tutorial.
select
user_id,
date(occurred_at) as dt,
sum(user_type) as inc_amt
from tutorial.yammer_events
group by 1,2
),
-- First, set up WAU and MAU tables for future use
wau as (
select
dateadd(day, datediff(day, 0, dateadd(dd, 2 - datepart(dw, dt), dt)), 0) week,
-- date_trunc('week', dt) as week,
user_id,
sum(inc_amt) as inc_amt
from dau
group by --1,2
dateadd(day, datediff(day, 0, dateadd(dd, 2 - datepart(dw, dt), dt)), 0),
user_id
),
mau as (
select
dateadd(month, datediff(month, 0, dt), 0) month,
-- date_trunc('month',dt) as month,
user_id,
sum(inc_amt) as inc_amt
from dau
group by --1,2
dateadd(month, datediff(month, 0, dt), 0),
user_id
),
-- This determines the cohort date of each user. In this case we are
-- deriving it from DAU data but you can feel free to replace it with
-- registration date if that's more appropriate.
first_dt as (
select
user_id,
min(dt) as first_dt,
dateadd(month, datediff(week, 0, dateadd(dd, 2 - datepart(dw, min(dt)), min(dt))), 0) first_week,
dateadd(month, datediff(month, 0, min(dt)), 0) first_month
-- date_trunc('week', min(dt)) as first_week,
-- date_trunc('month', min(dt)) as first_month
from dau
group by --1
user_id
),
mau_decorated as (
select
d.month,
d.user_id,
d.inc_amt,
f.first_month
from mau d, first_dt f
where d.user_id = f.user_id
and inc_amt > 0
),
-- This is MAU growth accounting. Note that this does not require any
-- information about inc_amt. As discussed in the articles, these
-- quantities satisfy some identities:
-- MAU(t) = retained(t) + new(t) + resurrected(t)
-- MAU(t - 1 month) = retained(t) + churned(t)
mau_growth_accounting as (
select
coalesce(tm.month, dateadd(month, 1, lm.month)) as month,
count(distinct tm.user_id) as mau,
count(distinct case when lm.user_id is not NULL then tm.user_id else NULL end) as retained,
count(distinct case when tm.first_month = tm.month then tm.user_id else NULL end) as new,
count(distinct case when tm.first_month != tm.month and lm.user_id is NULL then tm.user_id else NULL end) as resurrected,
-1*count(distinct case when tm.user_id is NULL then lm.user_id else NULL end) as churned
from
mau_decorated tm
full outer join mau_decorated lm on tm.user_id = lm.user_id and tm.month = dateadd(month, 1, lm.month)
group by --1
coalesce(tm.month, dateadd(month, 1, lm.month))
),
-- This generates the familiar monthly cohort retention dataset.
mau_retention_by_cohort as (
select
first_month,
-- 12 * extract(year from age(month, first_month)) +
-- extract(month from age(month, first_month)) as months_since_first,
datediff(month, first_month, month) as months_since_first,
count(1) as active_users,
sum(inc_amt) as inc_amt
from mau_decorated
group by --1,2
first_month,
datediff(month, first_month, month)
-- order by 1,2
),
-- This is the MRR growth accounting (or growth accounting of whatever
-- value you put in inc_amt). These also satisfy some identities:
-- MRR(t) = retained(t) + new(t) + resurrected(t) + expansion(t)
-- MAU(t - 1 month) = retained(t) + churned(t) + contraction(t)
mrr_growth_accounting as (
select
coalesce(tm.month, dateadd(month, 1, lm.month)) as month,
sum(tm.inc_amt) as rev,
sum(
case
when tm.user_id is not NULL and lm.user_id is not NULL
and tm.inc_amt >= lm.inc_amt then lm.inc_amt
when tm.user_id is not NULL and lm.user_id is not NULL
and tm.inc_amt < lm.inc_amt then tm.inc_amt
else 0
end
) as retained,
sum(
case when tm.first_month = tm.month then tm.inc_amt
else 0 end
) as new,
sum(
case when tm.month != tm.first_month and tm.user_id is not NULL
and lm.user_id is not NULL and tm.inc_amt > lm.inc_amt
and lm.inc_amt > 0 then tm.inc_amt - lm.inc_amt
else 0 end
) as expansion,
sum(
case when tm.user_id is not NULL
and (lm.user_id is NULL or lm.inc_amt = 0)
and tm.inc_amt > 0 and tm.first_month != tm.month
then tm.inc_amt
else 0 end
) as resurrected,
-1 * sum(
case
when tm.month != tm.first_month and tm.user_id is not NULL
and lm.user_id is not NULL
and tm.inc_amt < lm.inc_amt and tm.inc_amt > 0
then lm.inc_amt - tm.inc_amt
else 0 end
) as contraction,
-1 * sum(
case when lm.inc_amt > 0 and (tm.user_id is NULL or tm.inc_amt = 0)
then lm.inc_amt else 0 end
) as churned
from
mau_decorated tm
full outer join mau_decorated lm on tm.user_id = lm.user_id and tm.month = dateadd(month, 1, lm.month)
group by --1
coalesce(tm.month, dateadd(month, 1, lm.month))
),
-- These next tables are to compute LTV via the cohorts_cumulative table.
-- The LTV here is being computed for weekly cohorts on weekly intervals.
-- The queries can be modified to compute it for cohorts of any size
-- on any time window frequency.
wau_decorated as (
select
week,
w.user_id,
w.inc_amt,
f.first_week
from wau w, first_dt f
where w.user_id = f.user_id
),
cohorts as (
select
first_week,
week as active_week,
-- ceil(extract(DAYS from (week - first_week))/7.0) as weeks_since_first,
datediff(week, first_week, week) as weeks_since_first,
count(distinct user_id) as users,
sum(inc_amt) as inc_amt
from wau_decorated
group by --1,2,3
first_week,
week,
datediff(week, first_week, week)
),
cohort_sizes as (
select
first_week,
users,
inc_amt
from cohorts
where weeks_since_first = 0
),
cohorts_cumulative as (
-- A semi-cartesian join accomplishes the cumulative behavior.
select
c1.first_week,
c1.active_week,
c1.weeks_since_first,
c1.users,
cs.users as cohort_num_users,
1.0 * c1.users/cs.users as retained_pctg,
c1.inc_amt,
sum(c2.inc_amt) as cum_amt,
sum(c2.inc_amt)/cs.users as cum_amt_per_user
from
cohorts c1,
cohorts c2,
cohort_sizes cs
where
c1.first_week = c2.first_week
and c2.weeks_since_first <= c1.weeks_since_first
and cs.first_week = c1.first_week
group by --1,2,3,4,5,6,7
c1.first_week,
c1.active_week,
c1.weeks_since_first,
c1.users,
cs.users,
1.0 * c1.users/cs.users,
c1.inc_amt
)
-- For MRR growth accuonting use this
select * from mrr_growth_accounting
go
-- For MAU growth accuonting use this
select * from mau_growth_accounting
go
-- For cumulative LTV data use this
select * from cohorts_cumulative
go
-- For MAU retention by cohort, useful for the standard retention heatmap
select * from mau_retention_by_cohort
go
-- For use as input in the 8-ball tool use this
select
first_week as cohort_week,
active_week as activity_week,
users,
inc_amt as revenue
from cohorts_cumulative
go
In Amazon Redshift there is no interval '1 month ' so you have to use dateadd(month,1,lm.month)
age() is no longer supported on Redshift, you have to use datediff(). mau_retention_by_cohort would look like,
-- This generates the familiar monthly cohort retention dataset.
mau_retention_by_cohort as (
select
first_month,
12 * datediff(year, month, first_month) + datediff(month, month, first_month) as months_since_first,
count(1) as active_users,
sum(inc_amt) as inc_amt
from mau_decorated
group by 1,2
order by 1,2
)
Updated the query to work with BigQuery SQL. Also added DAU Growth Accounting tables. (I had been looking at an app that's best measured using DAU)
dau as (
-- This part of the query can be pretty much anything.
-- The only requirement is that it have three columns:
-- dt, user_id, inc_amt
-- Where dt is a date and user_id is some unique identifier for a user.
-- Each dt-user_id pair should be unique in this table.
-- inc_amt represents the amount of value that this user created on dt.
-- The most common case is
-- inc_amt = incremental revenue from the user on dt
-- If you want to do L28 growth accounting, user inc_amt=1.
-- The version here derives everything from the tutorial.yammer_events
-- data set provided for free by Mode.
-- If you edit just this part to represent your data, the rest
-- of the query should run just fine.
-- The query here is a sample that works in a BigQuery Data Set
select
user_id,
date as dt,
daily_revenue as inc_amt
from `your_BQ_dataset.analytics_tables.formatted_data_table`
group by 1,2,3
),
-- First, set up WAU and MAU tables for future use
wau as (
select
date_trunc(dt, week) as week,
user_id,
sum(inc_amt) as inc_amt
from dau
group by 1,2
),
mau as (
select
date_trunc(dt, month) as month,
user_id,
sum(inc_amt) as inc_amt
from dau
group by 1,2
),
-- This determines the cohort date of each user. In this case we are
-- deriving it from DAU data but you can feel free to replace it with
-- registration date if that's more appropriate.
first_dt as (
select
user_id,
min(dt) as first_dt,
date_trunc(min(dt), week) as first_week,
date_trunc(min(dt), month) as first_month
from dau
group by 1
),
-- I edited this query for an app that is best measured using DAU,
-- so I added several other temp tables here
dau_decorated as (
select
d.dt,
d.user_id,
d.inc_amt,
f.first_dt
from dau d join first_dt f on d.user_id = f.user_id
where inc_amt > 0
),
dau_growth_accounting as (
select
coalesce(tm.dt, date_add(lm.dt, interval 1 day)) as day,
count(distinct tm.user_id) as dau,
count(distinct case when lm.user_id is not null then tm.user_id else null end) as retained,
count(distinct case when tm.first_dt = tm.dt then tm.user_id else null end) as new_users,
count(distinct case when tm.first_dt != tm.dt and lm.user_id is null then tm.user_id else null end
) as resurrected,
-1*count(distinct case when tm.user_id is null then lm.user_id else null end) as churned
from dau_decorated tm full outer join dau_decorated lm on (
tm.user_id = lm.user_id and tm.dt = date_add(lm.dt, interval 1 day))
group by 1
),
mau_decorated as (
select
d.month,
d.user_id,
d.inc_amt,
f.first_month
from mau d join first_dt f on d.user_id = f.user_id
where inc_amt > 0
),
-- This is MAU growth accounting. Note that this does not require any
-- information about inc_amt. As discussed in the articles, these
-- quantities satisfy some identities:
-- MAU(t) = retained(t) + new(t) + resurrected(t)
-- MAU(t - 1 month) = retained(t) + churned(t)
mau_growth_accounting as (
select
coalesce(tm.month, date_add(lm.month, interval 1 month)) as month,
count(distinct tm.user_id) as dau,
count(distinct case when lm.user_id is not null then tm.user_id else null end) as retained,
count(distinct case when tm.first_month = tm.month then tm.user_id else null end) as new_users,
count(distinct case when tm.first_month != tm.month and lm.user_id is null then tm.user_id else null end
) as resurrected,
-1*count(distinct case when tm.user_id is null then lm.user_id else null end) as churned
from mau_decorated tm full outer join mau_decorated lm on (
tm.user_id = lm.user_id and tm.month = date_add(lm.month, interval 1 month))
group by 1
),
-- This generates the familiar monthly cohort retention dataset.
mau_retention_by_cohort as (
select
first_month,
month,
date_diff(month, first_month, month) as months_since_first,
count(1) as active_users,
sum(inc_amt) as inc_amt
from mau_decorated
group by 1,2
order by 1,2
),
-- This is the MRR growth accounting (or growth accounting of whatever
-- value you put in inc_amt). These also satisfy some identities:
-- MRR(t) = retained(t) + new(t) + resurrected(t) + expansion(t)
-- MAU(t - 1 month) = retained(t) + churned(t) + contraction(t)
mrr_growth_accounting as (
select
coalesce(tm.month, date_add(lm.month, interval 1 month)) as month,
sum(tm.inc_amt) as rev,
sum(
case
when tm.user_id is not null and lm.user_id is not null
and tm.inc_amt >= lm.inc_amt then lm.inc_amt
when tm.user_id is not null and lm.user_id is not null
and tm.inc_amt < lm.inc_amt then tm.inc_amt
else 0
end
) as retained,
sum(
case
when tm.first_month = tm.month then inc_amt
else 0 end
) as new,
sum(
case
when tm.month != tm.first_month and tm.user_id is not null
and lm.user_id is not null and tm.inc_amt > lm.inc_amt
)
)
-- These next tables are to compute LTV via the cohorts_cumulative table.
-- The LTV here is being computed for weekly cohorts on weekly intervals.
-- The queries can be modified to compute it for cohorts of any size
-- on any time window frequency.
wau_decorated as (
select
week,
w.user_id,
w.inc_amt,
f.first_week
from wau w join first_dt f on w.user_id = f.user_id
),
cohorts as (
select
first_week,
week as active_week,
date_diff(week, first_week, week) as weeks_since_first,
count(distinct user_id) as users,
sum(inc_amt) as inc_amt
from wau_decorated
group by 1,2,3
order by 1,2
),
cohort_sizes as (
select
first_week,
users,
inc_amt
from cohorts
where weeks_since_first = 0
),
cohorts_cumulative as (
-- A semi-cartesian join accomplishes the cumulative behavior.
select
c1.first_week,
c1.active_week,
c1.weeks_since_first,
c1.users,
cs.users as cohort_num_users,
1.0 * c1.users/cs.users as retained_pctg,
c1.inc_amt,
sum(c2.inc_amt) as cum_amt,
1.0*sum(c2.inc_amt)/cs.users as cum_amt_per_user
from cohorts c1 join cohort_sizes cs on cs.first_week = c1.first_week
join cohorts c2 on c1.first_week = c2.first_week and c1.weeks_since_first = c2.weeks_since_first
group by 1,2,3,4,5,6,7
order by 1,2
),
-- monthly cumulative cohorts
cohorts_m as (
select
first_month,
month as active_month,
date_diff(month, first_month, week) as months_since_first,
count(distinct user_id) as users,
sum(inc_amt) as inc_amt
from mau_decorated
group by 1,2,3
order by 1,2
),
cohort_sizes_m as (
select
first_week,
users,
inc_amt
from cohorts_m
where months_since_first = 0
),
chorts_cumulative_m as (
-- A semi-cartesian join accomplishes the cumulative behavior.
select
c1.first_month,
c1.active_month,
c1.months_since_first,
c1.users,
cs.users as cohort_num_users,
1.0 * c1.users/cs.users as retained_pctg,
c1.inc_amt,
sum(c2.inc_amt) as cum_amt,
1.0*sum(c2.inc_amt)/cs.users as cum_amt_per_user
from cohorts_m c1 join cohort_sizes_m cs on cs.first_month = c1.first_month
join cohorts_m c2 on c1.first_month = c2.first_month and c1.months_since_first = c2.months_since_first
group by 1,2,3,4,5,6,7
order by 1,2
)
-- For MAU retention by cohort, useful for the standard retention heatmap
select * from mau_retention_by_cohort
-- For cumulative LTV data use this
select * from cohorts_cumulative
-- For cumulative LTV with monthly cohorts use this
select * from cohorts_cumulative_m
-- For DAU growth accuonting use this
select * from dau_growth_accounting
-- For MAU growth accuonting use this
select * from mau_growth_accounting
-- For MRR growth accuonting use this
select * from mrr_growth_accounting
-- For use as weekly input in the 8-ball tool use this
select
first_week as cohort_week,
active_week as activity_week,
users,
inc_amt as revenue
from cohorts_cumulative
Question about the formula to calculate months_since_first:
12 * extract(year from age(month, first_month)) + extract(month from age(month, first_month)) as months_since_first
Another commenter noted re: age() being deprecated in AWS Redshift. It seems like the datediff(month, first_month, month) would be sufficient, without adding the first part 12 * datediff(year, first_month, month). As far as I can tell, this would greatly inflate the actual number of months. (I'm not super familiar with redshift, but it seems like it can extract the number of months when the two timestamps span multiple years.
FWIW, I'm converting this to run with Snowflake, but I will wait to post the translated query here until I'm sure about the above.
hi, can I ask how to do the cdf in sql? I mean, for this charts
Awesome git! Does anyone have the python script behind the MAU charts used in the series of essays on Medium that this Github references? It is "Diligence at Social Capital Part 1 - 5" found here: https://medium.com/swlh/diligence-at-social-capital-part-1-accounting-for-user-growth-4a8a449fddfc
I think the group at Social Capital likely used Seaborn for charting most of that, and I found it fascinating and wanted to explore further.
here is the Microsoft SQL version.