declare @RandomString table (ID int not null,ItemValue varchar(500) not null)
insert into @RandomString(ID,ItemValue) values
declare @SearchCharReplacement table (Original varchar(500) not null,Replacement varchar(500) not null)
insert into @SearchCharReplacement(Original,Replacement) values
;With Replacements as (
ID,ItemValue,0 as RepCount
CHARINDEX(scr.Original,rs.ItemValue) > 0
), FinalReplacements as (
ID,ItemValue,ROW_NUMBER() OVER (PARTITION BY ID ORDER BY RepCount desc) as rn
set ItemValue = fr.ItemValue
rs.ID = fr.ID and
rn = 1
select * from @RandomString
What this does is it starts with the unaltered texts (the top select in
Replacements), then it attempts to apply any valid replacements (the second select in
Replacements). What it will do is to continue applying this second select, based on any results it produces, until no new rows are produced. This is called a Recursive Common Table Expression (CTE).
We then use a second CTE (a non-recursive one this time)
FinalReplacements to number all of the rows produced by the first CTE, assigning lower row numbers to rows which were produced last. Logically, these are the rows which were the result of applying the last applicable transform, and so will no longer contain any of the original characters to be replaced. So we can use the row number 1 to perform the update back against the original table.
This query does do more work than strictly necessary - for small numbers of rows of replacement characters, it's not likely to be too inefficient. We could clear it up by defining a single order in which to apply the replacements.