860 lines
30 KiB
Tcl
860 lines
30 KiB
Tcl
# Run this TCL script using "testfixture" in order get a report that shows
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# how much disk space is used by a particular data to actually store data
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# versus how much space is unused.
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#
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if {[catch {
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# Get the name of the database to analyze
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#
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#set argv $argv0
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if {[llength $argv]!=1} {
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puts stderr "Usage: $argv0 database-name"
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exit 1
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}
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set file_to_analyze [lindex $argv 0]
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if {![file exists $file_to_analyze]} {
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puts stderr "No such file: $file_to_analyze"
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exit 1
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}
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if {![file readable $file_to_analyze]} {
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puts stderr "File is not readable: $file_to_analyze"
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exit 1
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}
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if {[file size $file_to_analyze]<512} {
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puts stderr "Empty or malformed database: $file_to_analyze"
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exit 1
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}
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# Maximum distance between pages before we consider it a "gap"
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#
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set MAXGAP 3
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# Open the database
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#
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sqlite3 db [lindex $argv 0]
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set DB [btree_open [lindex $argv 0] 1000 0]
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# In-memory database for collecting statistics. This script loops through
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# the tables and indices in the database being analyzed, adding a row for each
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# to an in-memory database (for which the schema is shown below). It then
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# queries the in-memory db to produce the space-analysis report.
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#
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sqlite3 mem :memory:
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set tabledef\
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{CREATE TABLE space_used(
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name clob, -- Name of a table or index in the database file
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tblname clob, -- Name of associated table
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is_index boolean, -- TRUE if it is an index, false for a table
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nentry int, -- Number of entries in the BTree
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leaf_entries int, -- Number of leaf entries
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payload int, -- Total amount of data stored in this table or index
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ovfl_payload int, -- Total amount of data stored on overflow pages
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ovfl_cnt int, -- Number of entries that use overflow
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mx_payload int, -- Maximum payload size
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int_pages int, -- Number of interior pages used
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leaf_pages int, -- Number of leaf pages used
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ovfl_pages int, -- Number of overflow pages used
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int_unused int, -- Number of unused bytes on interior pages
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leaf_unused int, -- Number of unused bytes on primary pages
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ovfl_unused int, -- Number of unused bytes on overflow pages
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gap_cnt int -- Number of gaps in the page layout
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);}
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mem eval $tabledef
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proc integerify {real} {
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return [expr int($real)]
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}
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mem function int integerify
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# Quote a string for use in an SQL query. Examples:
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#
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# [quote {hello world}] == {'hello world'}
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# [quote {hello world's}] == {'hello world''s'}
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#
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proc quote {txt} {
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regsub -all ' $txt '' q
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return '$q'
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}
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# This proc is a wrapper around the btree_cursor_info command. The
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# second argument is an open btree cursor returned by [btree_cursor].
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# The first argument is the name of an array variable that exists in
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# the scope of the caller. If the third argument is non-zero, then
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# info is returned for the page that lies $up entries upwards in the
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# tree-structure. (i.e. $up==1 returns the parent page, $up==2 the
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# grandparent etc.)
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#
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# The following entries in that array are filled in with information retrieved
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# using [btree_cursor_info]:
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#
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# $arrayvar(page_no) = The page number
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# $arrayvar(entry_no) = The entry number
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# $arrayvar(page_entries) = Total number of entries on this page
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# $arrayvar(cell_size) = Cell size (local payload + header)
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# $arrayvar(page_freebytes) = Number of free bytes on this page
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# $arrayvar(page_freeblocks) = Number of free blocks on the page
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# $arrayvar(payload_bytes) = Total payload size (local + overflow)
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# $arrayvar(header_bytes) = Header size in bytes
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# $arrayvar(local_payload_bytes) = Local payload size
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# $arrayvar(parent) = Parent page number
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#
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proc cursor_info {arrayvar csr {up 0}} {
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upvar $arrayvar a
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foreach [list a(page_no) \
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a(entry_no) \
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a(page_entries) \
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a(cell_size) \
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a(page_freebytes) \
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a(page_freeblocks) \
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a(payload_bytes) \
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a(header_bytes) \
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a(local_payload_bytes) \
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a(parent) \
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a(first_ovfl) ] [btree_cursor_info $csr $up] break
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}
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# Determine the page-size of the database. This global variable is used
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# throughout the script.
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#
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set pageSize [db eval {PRAGMA page_size}]
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# Analyze every table in the database, one at a time.
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#
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# The following query returns the name and root-page of each table in the
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# database, including the sqlite_master table.
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#
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set sql {
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SELECT name, rootpage FROM sqlite_master
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WHERE type='table' AND rootpage>0
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UNION ALL
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SELECT 'sqlite_master', 1
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ORDER BY 1
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}
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set wideZero [expr {10000000000 - 10000000000}]
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foreach {name rootpage} [db eval $sql] {
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puts stderr "Analyzing table $name..."
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# Code below traverses the table being analyzed (table name $name), using the
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# btree cursor $cursor. Statistics related to table $name are accumulated in
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# the following variables:
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#
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set total_payload $wideZero ;# Payload space used by all entries
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set total_ovfl $wideZero ;# Payload space on overflow pages
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set unused_int $wideZero ;# Unused space on interior nodes
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set unused_leaf $wideZero ;# Unused space on leaf nodes
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set unused_ovfl $wideZero ;# Unused space on overflow pages
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set cnt_ovfl $wideZero ;# Number of entries that use overflows
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set cnt_leaf_entry $wideZero ;# Number of leaf entries
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set cnt_int_entry $wideZero ;# Number of interor entries
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set mx_payload $wideZero ;# Maximum payload size
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set ovfl_pages $wideZero ;# Number of overflow pages used
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set leaf_pages $wideZero ;# Number of leaf pages
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set int_pages $wideZero ;# Number of interior pages
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set gap_cnt 0 ;# Number of holes in the page sequence
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set prev_pgno 0 ;# Last page number seen
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# As the btree is traversed, the array variable $seen($pgno) is set to 1
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# the first time page $pgno is encountered.
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#
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catch {unset seen}
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# The following loop runs once for each entry in table $name. The table
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# is traversed using the btree cursor stored in variable $csr
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#
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set csr [btree_cursor $DB $rootpage 0]
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for {btree_first $csr} {![btree_eof $csr]} {btree_next $csr} {
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incr cnt_leaf_entry
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# Retrieve information about the entry the btree-cursor points to into
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# the array variable $ci (cursor info).
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#
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cursor_info ci $csr
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# Check if the payload of this entry is greater than the current
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# $mx_payload statistic for the table. Also increase the $total_payload
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# statistic.
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#
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if {$ci(payload_bytes)>$mx_payload} {set mx_payload $ci(payload_bytes)}
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incr total_payload $ci(payload_bytes)
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# If this entry uses overflow pages, then update the $cnt_ovfl,
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# $total_ovfl, $ovfl_pages and $unused_ovfl statistics.
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#
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set ovfl [expr {$ci(payload_bytes)-$ci(local_payload_bytes)}]
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if {$ovfl} {
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incr cnt_ovfl
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incr total_ovfl $ovfl
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set n [expr {int(ceil($ovfl/($pageSize-4.0)))}]
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incr ovfl_pages $n
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incr unused_ovfl [expr {$n*($pageSize-4) - $ovfl}]
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set pglist [btree_ovfl_info $DB $csr]
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} else {
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set pglist {}
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}
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# If this is the first table entry analyzed for the page, then update
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# the page-related statistics $leaf_pages and $unused_leaf. Also, if
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# this page has a parent page that has not been analyzed, retrieve
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# info for the parent and update statistics for it too.
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#
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if {![info exists seen($ci(page_no))]} {
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set seen($ci(page_no)) 1
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incr leaf_pages
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incr unused_leaf $ci(page_freebytes)
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set pglist "$ci(page_no) $pglist"
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# Now check if the page has a parent that has not been analyzed. If
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# so, update the $int_pages, $cnt_int_entry and $unused_int statistics
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# accordingly. Then check if the parent page has a parent that has
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# not yet been analyzed etc.
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#
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# set parent $ci(parent_page_no)
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for {set up 1} \
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{$ci(parent)!=0 && ![info exists seen($ci(parent))]} {incr up} \
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{
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# Mark the parent as seen.
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#
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set seen($ci(parent)) 1
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# Retrieve info for the parent and update statistics.
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cursor_info ci $csr $up
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incr int_pages
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incr cnt_int_entry $ci(page_entries)
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incr unused_int $ci(page_freebytes)
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# parent pages come before their first child
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set pglist "$ci(page_no) $pglist"
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}
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}
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# Check the page list for fragmentation
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#
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foreach pg $pglist {
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if {$pg!=$prev_pgno+1 && $prev_pgno>0} {
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incr gap_cnt
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}
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set prev_pgno $pg
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}
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}
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btree_close_cursor $csr
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# Handle the special case where a table contains no data. In this case
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# all statistics are zero, except for the number of leaf pages (1) and
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# the unused bytes on leaf pages ($pageSize - 8).
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#
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# An exception to the above is the sqlite_master table. If it is empty
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# then all statistics are zero except for the number of leaf pages (1),
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# and the number of unused bytes on leaf pages ($pageSize - 112).
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#
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if {[llength [array names seen]]==0} {
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set leaf_pages 1
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if {$rootpage==1} {
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set unused_leaf [expr {$pageSize-112}]
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} else {
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set unused_leaf [expr {$pageSize-8}]
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}
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}
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# Insert the statistics for the table analyzed into the in-memory database.
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#
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set sql "INSERT INTO space_used VALUES("
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append sql [quote $name]
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append sql ",[quote $name]"
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append sql ",0"
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append sql ",[expr {$cnt_leaf_entry+$cnt_int_entry}]"
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append sql ",$cnt_leaf_entry"
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append sql ",$total_payload"
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append sql ",$total_ovfl"
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append sql ",$cnt_ovfl"
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append sql ",$mx_payload"
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append sql ",$int_pages"
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append sql ",$leaf_pages"
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append sql ",$ovfl_pages"
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append sql ",$unused_int"
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append sql ",$unused_leaf"
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append sql ",$unused_ovfl"
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append sql ",$gap_cnt"
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append sql );
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mem eval $sql
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}
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# Analyze every index in the database, one at a time.
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#
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# The query below returns the name, associated table and root-page number
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# for every index in the database.
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#
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set sql {
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SELECT name, tbl_name, rootpage FROM sqlite_master WHERE type='index'
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ORDER BY 2, 1
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}
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foreach {name tbl_name rootpage} [db eval $sql] {
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puts stderr "Analyzing index $name of table $tbl_name..."
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# Code below traverses the index being analyzed (index name $name), using the
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# btree cursor $cursor. Statistics related to index $name are accumulated in
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# the following variables:
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#
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set total_payload $wideZero ;# Payload space used by all entries
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set total_ovfl $wideZero ;# Payload space on overflow pages
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set unused_leaf $wideZero ;# Unused space on leaf nodes
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set unused_ovfl $wideZero ;# Unused space on overflow pages
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set cnt_ovfl $wideZero ;# Number of entries that use overflows
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set cnt_leaf_entry $wideZero ;# Number of leaf entries
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set mx_payload $wideZero ;# Maximum payload size
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set ovfl_pages $wideZero ;# Number of overflow pages used
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set leaf_pages $wideZero ;# Number of leaf pages
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set gap_cnt 0 ;# Number of holes in the page sequence
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set prev_pgno 0 ;# Last page number seen
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# As the btree is traversed, the array variable $seen($pgno) is set to 1
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# the first time page $pgno is encountered.
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#
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catch {unset seen}
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# The following loop runs once for each entry in index $name. The index
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# is traversed using the btree cursor stored in variable $csr
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#
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set csr [btree_cursor $DB $rootpage 0]
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for {btree_first $csr} {![btree_eof $csr]} {btree_next $csr} {
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incr cnt_leaf_entry
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# Retrieve information about the entry the btree-cursor points to into
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# the array variable $ci (cursor info).
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#
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cursor_info ci $csr
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# Check if the payload of this entry is greater than the current
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# $mx_payload statistic for the table. Also increase the $total_payload
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# statistic.
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#
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set payload [btree_keysize $csr]
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if {$payload>$mx_payload} {set mx_payload $payload}
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incr total_payload $payload
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# If this entry uses overflow pages, then update the $cnt_ovfl,
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# $total_ovfl, $ovfl_pages and $unused_ovfl statistics.
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#
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set ovfl [expr {$payload-$ci(local_payload_bytes)}]
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if {$ovfl} {
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incr cnt_ovfl
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incr total_ovfl $ovfl
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set n [expr {int(ceil($ovfl/($pageSize-4.0)))}]
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incr ovfl_pages $n
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incr unused_ovfl [expr {$n*($pageSize-4) - $ovfl}]
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}
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# If this is the first table entry analyzed for the page, then update
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# the page-related statistics $leaf_pages and $unused_leaf.
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#
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if {![info exists seen($ci(page_no))]} {
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set seen($ci(page_no)) 1
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incr leaf_pages
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incr unused_leaf $ci(page_freebytes)
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set pg $ci(page_no)
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if {$prev_pgno>0 && $pg!=$prev_pgno+1} {
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incr gap_cnt
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}
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set prev_pgno $ci(page_no)
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}
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}
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btree_close_cursor $csr
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# Handle the special case where a index contains no data. In this case
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# all statistics are zero, except for the number of leaf pages (1) and
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# the unused bytes on leaf pages ($pageSize - 8).
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#
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if {[llength [array names seen]]==0} {
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set leaf_pages 1
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set unused_leaf [expr {$pageSize-8}]
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}
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# Insert the statistics for the index analyzed into the in-memory database.
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#
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set sql "INSERT INTO space_used VALUES("
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append sql [quote $name]
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append sql ",[quote $tbl_name]"
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append sql ",1"
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append sql ",$cnt_leaf_entry"
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append sql ",$cnt_leaf_entry"
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append sql ",$total_payload"
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append sql ",$total_ovfl"
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append sql ",$cnt_ovfl"
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append sql ",$mx_payload"
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append sql ",0"
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append sql ",$leaf_pages"
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append sql ",$ovfl_pages"
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append sql ",0"
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append sql ",$unused_leaf"
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append sql ",$unused_ovfl"
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append sql ",$gap_cnt"
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append sql );
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mem eval $sql
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}
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# Generate a single line of output in the statistics section of the
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# report.
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#
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proc statline {title value {extra {}}} {
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set len [string length $title]
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set dots [string range {......................................} $len end]
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set len [string length $value]
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set sp2 [string range { } $len end]
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if {$extra ne ""} {
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set extra " $extra"
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}
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puts "$title$dots $value$sp2$extra"
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}
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# Generate a formatted percentage value for $num/$denom
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#
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proc percent {num denom {of {}}} {
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if {$denom==0.0} {return ""}
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set v [expr {$num*100.0/$denom}]
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set of {}
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if {$v==100.0 || $v<0.001 || ($v>1.0 && $v<99.0)} {
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return [format {%5.1f%% %s} $v $of]
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} elseif {$v<0.1 || $v>99.9} {
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return [format {%7.3f%% %s} $v $of]
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} else {
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return [format {%6.2f%% %s} $v $of]
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}
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}
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proc divide {num denom} {
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if {$denom==0} {return 0.0}
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return [format %.2f [expr double($num)/double($denom)]]
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}
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# Generate a subreport that covers some subset of the database.
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# the $where clause determines which subset to analyze.
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#
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proc subreport {title where} {
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global pageSize file_pgcnt
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# Query the in-memory database for the sum of various statistics
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# for the subset of tables/indices identified by the WHERE clause in
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# $where. Note that even if the WHERE clause matches no rows, the
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# following query returns exactly one row (because it is an aggregate).
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#
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# The results of the query are stored directly by SQLite into local
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# variables (i.e. $nentry, $nleaf etc.).
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#
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mem eval "
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SELECT
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int(sum(nentry)) AS nentry,
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int(sum(leaf_entries)) AS nleaf,
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int(sum(payload)) AS payload,
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int(sum(ovfl_payload)) AS ovfl_payload,
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max(mx_payload) AS mx_payload,
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int(sum(ovfl_cnt)) as ovfl_cnt,
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int(sum(leaf_pages)) AS leaf_pages,
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int(sum(int_pages)) AS int_pages,
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int(sum(ovfl_pages)) AS ovfl_pages,
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int(sum(leaf_unused)) AS leaf_unused,
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int(sum(int_unused)) AS int_unused,
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int(sum(ovfl_unused)) AS ovfl_unused,
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int(sum(gap_cnt)) AS gap_cnt
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FROM space_used WHERE $where" {} {}
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# Output the sub-report title, nicely decorated with * characters.
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#
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puts ""
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set len [string length $title]
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set stars [string repeat * [expr 65-$len]]
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puts "*** $title $stars"
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puts ""
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# Calculate statistics and store the results in TCL variables, as follows:
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#
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# total_pages: Database pages consumed.
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# total_pages_percent: Pages consumed as a percentage of the file.
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# storage: Bytes consumed.
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# payload_percent: Payload bytes used as a percentage of $storage.
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# total_unused: Unused bytes on pages.
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# avg_payload: Average payload per btree entry.
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# avg_fanout: Average fanout for internal pages.
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# avg_unused: Average unused bytes per btree entry.
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# ovfl_cnt_percent: Percentage of btree entries that use overflow pages.
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#
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set total_pages [expr {$leaf_pages+$int_pages+$ovfl_pages}]
|
|
set total_pages_percent [percent $total_pages $file_pgcnt]
|
|
set storage [expr {$total_pages*$pageSize}]
|
|
set payload_percent [percent $payload $storage {of storage consumed}]
|
|
set total_unused [expr {$ovfl_unused+$int_unused+$leaf_unused}]
|
|
set avg_payload [divide $payload $nleaf]
|
|
set avg_unused [divide $total_unused $nleaf]
|
|
if {$int_pages>0} {
|
|
# TODO: Is this formula correct?
|
|
set nTab [mem eval "
|
|
SELECT count(*) FROM (
|
|
SELECT DISTINCT tblname FROM space_used WHERE $where AND is_index=0
|
|
)
|
|
"]
|
|
set avg_fanout [mem eval "
|
|
SELECT (sum(leaf_pages+int_pages)-$nTab)/sum(int_pages) FROM space_used
|
|
WHERE $where AND is_index = 0
|
|
"]
|
|
set avg_fanout [format %.2f $avg_fanout]
|
|
}
|
|
set ovfl_cnt_percent [percent $ovfl_cnt $nleaf {of all entries}]
|
|
|
|
# Print out the sub-report statistics.
|
|
#
|
|
statline {Percentage of total database} $total_pages_percent
|
|
statline {Number of entries} $nleaf
|
|
statline {Bytes of storage consumed} $storage
|
|
statline {Bytes of payload} $payload $payload_percent
|
|
statline {Average payload per entry} $avg_payload
|
|
statline {Average unused bytes per entry} $avg_unused
|
|
if {[info exists avg_fanout]} {
|
|
statline {Average fanout} $avg_fanout
|
|
}
|
|
if {$total_pages>1} {
|
|
set fragmentation [percent $gap_cnt [expr {$total_pages-1}] {fragmentation}]
|
|
statline {Fragmentation} $fragmentation
|
|
}
|
|
statline {Maximum payload per entry} $mx_payload
|
|
statline {Entries that use overflow} $ovfl_cnt $ovfl_cnt_percent
|
|
if {$int_pages>0} {
|
|
statline {Index pages used} $int_pages
|
|
}
|
|
statline {Primary pages used} $leaf_pages
|
|
statline {Overflow pages used} $ovfl_pages
|
|
statline {Total pages used} $total_pages
|
|
if {$int_unused>0} {
|
|
set int_unused_percent \
|
|
[percent $int_unused [expr {$int_pages*$pageSize}] {of index space}]
|
|
statline "Unused bytes on index pages" $int_unused $int_unused_percent
|
|
}
|
|
statline "Unused bytes on primary pages" $leaf_unused \
|
|
[percent $leaf_unused [expr {$leaf_pages*$pageSize}] {of primary space}]
|
|
statline "Unused bytes on overflow pages" $ovfl_unused \
|
|
[percent $ovfl_unused [expr {$ovfl_pages*$pageSize}] {of overflow space}]
|
|
statline "Unused bytes on all pages" $total_unused \
|
|
[percent $total_unused $storage {of all space}]
|
|
return 1
|
|
}
|
|
|
|
# Calculate the overhead in pages caused by auto-vacuum.
|
|
#
|
|
# This procedure calculates and returns the number of pages used by the
|
|
# auto-vacuum 'pointer-map'. If the database does not support auto-vacuum,
|
|
# then 0 is returned. The two arguments are the size of the database file in
|
|
# pages and the page size used by the database (in bytes).
|
|
proc autovacuum_overhead {filePages pageSize} {
|
|
|
|
# Read the value of meta 4. If non-zero, then the database supports
|
|
# auto-vacuum. It would be possible to use "PRAGMA auto_vacuum" instead,
|
|
# but that would not work if the SQLITE_OMIT_PRAGMA macro was defined
|
|
# when the library was built.
|
|
set meta4 [lindex [btree_get_meta $::DB] 4]
|
|
|
|
# If the database is not an auto-vacuum database or the file consists
|
|
# of one page only then there is no overhead for auto-vacuum. Return zero.
|
|
if {0==$meta4 || $filePages==1} {
|
|
return 0
|
|
}
|
|
|
|
# The number of entries on each pointer map page. The layout of the
|
|
# database file is one pointer-map page, followed by $ptrsPerPage other
|
|
# pages, followed by a pointer-map page etc. The first pointer-map page
|
|
# is the second page of the file overall.
|
|
set ptrsPerPage [expr double($pageSize/5)]
|
|
|
|
# Return the number of pointer map pages in the database.
|
|
return [expr int(ceil( ($filePages-1.0)/($ptrsPerPage+1.0) ))]
|
|
}
|
|
|
|
|
|
# Calculate the summary statistics for the database and store the results
|
|
# in TCL variables. They are output below. Variables are as follows:
|
|
#
|
|
# pageSize: Size of each page in bytes.
|
|
# file_bytes: File size in bytes.
|
|
# file_pgcnt: Number of pages in the file.
|
|
# file_pgcnt2: Number of pages in the file (calculated).
|
|
# av_pgcnt: Pages consumed by the auto-vacuum pointer-map.
|
|
# av_percent: Percentage of the file consumed by auto-vacuum pointer-map.
|
|
# inuse_pgcnt: Data pages in the file.
|
|
# inuse_percent: Percentage of pages used to store data.
|
|
# free_pgcnt: Free pages calculated as (<total pages> - <in-use pages>)
|
|
# free_pgcnt2: Free pages in the file according to the file header.
|
|
# free_percent: Percentage of file consumed by free pages (calculated).
|
|
# free_percent2: Percentage of file consumed by free pages (header).
|
|
# ntable: Number of tables in the db.
|
|
# nindex: Number of indices in the db.
|
|
# nautoindex: Number of indices created automatically.
|
|
# nmanindex: Number of indices created manually.
|
|
# user_payload: Number of bytes of payload in table btrees
|
|
# (not including sqlite_master)
|
|
# user_percent: $user_payload as a percentage of total file size.
|
|
|
|
set file_bytes [file size $file_to_analyze]
|
|
set file_pgcnt [expr {$file_bytes/$pageSize}]
|
|
|
|
set av_pgcnt [autovacuum_overhead $file_pgcnt $pageSize]
|
|
set av_percent [percent $av_pgcnt $file_pgcnt]
|
|
|
|
set sql {SELECT sum(leaf_pages+int_pages+ovfl_pages) FROM space_used}
|
|
set inuse_pgcnt [expr int([mem eval $sql])]
|
|
set inuse_percent [percent $inuse_pgcnt $file_pgcnt]
|
|
|
|
set free_pgcnt [expr $file_pgcnt-$inuse_pgcnt-$av_pgcnt]
|
|
set free_percent [percent $free_pgcnt $file_pgcnt]
|
|
set free_pgcnt2 [lindex [btree_get_meta $DB] 0]
|
|
set free_percent2 [percent $free_pgcnt2 $file_pgcnt]
|
|
|
|
set file_pgcnt2 [expr {$inuse_pgcnt+$free_pgcnt2+$av_pgcnt}]
|
|
|
|
set ntable [db eval {SELECT count(*)+1 FROM sqlite_master WHERE type='table'}]
|
|
set nindex [db eval {SELECT count(*) FROM sqlite_master WHERE type='index'}]
|
|
set sql {SELECT count(*) FROM sqlite_master WHERE name LIKE 'sqlite_autoindex%'}
|
|
set nautoindex [db eval $sql]
|
|
set nmanindex [expr {$nindex-$nautoindex}]
|
|
|
|
# set total_payload [mem eval "SELECT sum(payload) FROM space_used"]
|
|
set user_payload [mem one {SELECT int(sum(payload)) FROM space_used
|
|
WHERE NOT is_index AND name NOT LIKE 'sqlite_master'}]
|
|
set user_percent [percent $user_payload $file_bytes]
|
|
|
|
# Output the summary statistics calculated above.
|
|
#
|
|
puts "/** Disk-Space Utilization Report For $file_to_analyze"
|
|
catch {
|
|
puts "*** As of [clock format [clock seconds] -format {%Y-%b-%d %H:%M:%S}]"
|
|
}
|
|
puts ""
|
|
statline {Page size in bytes} $pageSize
|
|
statline {Pages in the whole file (measured)} $file_pgcnt
|
|
statline {Pages in the whole file (calculated)} $file_pgcnt2
|
|
statline {Pages that store data} $inuse_pgcnt $inuse_percent
|
|
statline {Pages on the freelist (per header)} $free_pgcnt2 $free_percent2
|
|
statline {Pages on the freelist (calculated)} $free_pgcnt $free_percent
|
|
statline {Pages of auto-vacuum overhead} $av_pgcnt $av_percent
|
|
statline {Number of tables in the database} $ntable
|
|
statline {Number of indices} $nindex
|
|
statline {Number of named indices} $nmanindex
|
|
statline {Automatically generated indices} $nautoindex
|
|
statline {Size of the file in bytes} $file_bytes
|
|
statline {Bytes of user payload stored} $user_payload $user_percent
|
|
|
|
# Output table rankings
|
|
#
|
|
puts ""
|
|
puts "*** Page counts for all tables with their indices ********************"
|
|
puts ""
|
|
mem eval {SELECT tblname, count(*) AS cnt,
|
|
int(sum(int_pages+leaf_pages+ovfl_pages)) AS size
|
|
FROM space_used GROUP BY tblname ORDER BY size+0 DESC, tblname} {} {
|
|
statline [string toupper $tblname] $size [percent $size $file_pgcnt]
|
|
}
|
|
|
|
# Output subreports
|
|
#
|
|
if {$nindex>0} {
|
|
subreport {All tables and indices} 1
|
|
}
|
|
subreport {All tables} {NOT is_index}
|
|
if {$nindex>0} {
|
|
subreport {All indices} {is_index}
|
|
}
|
|
foreach tbl [mem eval {SELECT name FROM space_used WHERE NOT is_index
|
|
ORDER BY name}] {
|
|
regsub ' $tbl '' qn
|
|
set name [string toupper $tbl]
|
|
set n [mem eval "SELECT count(*) FROM space_used WHERE tblname='$qn'"]
|
|
if {$n>1} {
|
|
subreport "Table $name and all its indices" "tblname='$qn'"
|
|
subreport "Table $name w/o any indices" "name='$qn'"
|
|
subreport "Indices of table $name" "tblname='$qn' AND is_index"
|
|
} else {
|
|
subreport "Table $name" "name='$qn'"
|
|
}
|
|
}
|
|
|
|
# Output instructions on what the numbers above mean.
|
|
#
|
|
puts {
|
|
*** Definitions ******************************************************
|
|
|
|
Page size in bytes
|
|
|
|
The number of bytes in a single page of the database file.
|
|
Usually 1024.
|
|
|
|
Number of pages in the whole file
|
|
}
|
|
puts \
|
|
" The number of $pageSize-byte pages that go into forming the complete
|
|
database"
|
|
puts \
|
|
{
|
|
Pages that store data
|
|
|
|
The number of pages that store data, either as primary B*Tree pages or
|
|
as overflow pages. The number at the right is the data pages divided by
|
|
the total number of pages in the file.
|
|
|
|
Pages on the freelist
|
|
|
|
The number of pages that are not currently in use but are reserved for
|
|
future use. The percentage at the right is the number of freelist pages
|
|
divided by the total number of pages in the file.
|
|
|
|
Pages of auto-vacuum overhead
|
|
|
|
The number of pages that store data used by the database to facilitate
|
|
auto-vacuum. This is zero for databases that do not support auto-vacuum.
|
|
|
|
Number of tables in the database
|
|
|
|
The number of tables in the database, including the SQLITE_MASTER table
|
|
used to store schema information.
|
|
|
|
Number of indices
|
|
|
|
The total number of indices in the database.
|
|
|
|
Number of named indices
|
|
|
|
The number of indices created using an explicit CREATE INDEX statement.
|
|
|
|
Automatically generated indices
|
|
|
|
The number of indices used to implement PRIMARY KEY or UNIQUE constraints
|
|
on tables.
|
|
|
|
Size of the file in bytes
|
|
|
|
The total amount of disk space used by the entire database files.
|
|
|
|
Bytes of user payload stored
|
|
|
|
The total number of bytes of user payload stored in the database. The
|
|
schema information in the SQLITE_MASTER table is not counted when
|
|
computing this number. The percentage at the right shows the payload
|
|
divided by the total file size.
|
|
|
|
Percentage of total database
|
|
|
|
The amount of the complete database file that is devoted to storing
|
|
information described by this category.
|
|
|
|
Number of entries
|
|
|
|
The total number of B-Tree key/value pairs stored under this category.
|
|
|
|
Bytes of storage consumed
|
|
|
|
The total amount of disk space required to store all B-Tree entries
|
|
under this category. The is the total number of pages used times
|
|
the pages size.
|
|
|
|
Bytes of payload
|
|
|
|
The amount of payload stored under this category. Payload is the data
|
|
part of table entries and the key part of index entries. The percentage
|
|
at the right is the bytes of payload divided by the bytes of storage
|
|
consumed.
|
|
|
|
Average payload per entry
|
|
|
|
The average amount of payload on each entry. This is just the bytes of
|
|
payload divided by the number of entries.
|
|
|
|
Average unused bytes per entry
|
|
|
|
The average amount of free space remaining on all pages under this
|
|
category on a per-entry basis. This is the number of unused bytes on
|
|
all pages divided by the number of entries.
|
|
|
|
Fragmentation
|
|
|
|
The percentage of pages in the table or index that are not
|
|
consecutive in the disk file. Many filesystems are optimized
|
|
for sequential file access so smaller fragmentation numbers
|
|
sometimes result in faster queries, especially for larger
|
|
database files that do not fit in the disk cache.
|
|
|
|
Maximum payload per entry
|
|
|
|
The largest payload size of any entry.
|
|
|
|
Entries that use overflow
|
|
|
|
The number of entries that user one or more overflow pages.
|
|
|
|
Total pages used
|
|
|
|
This is the number of pages used to hold all information in the current
|
|
category. This is the sum of index, primary, and overflow pages.
|
|
|
|
Index pages used
|
|
|
|
This is the number of pages in a table B-tree that hold only key (rowid)
|
|
information and no data.
|
|
|
|
Primary pages used
|
|
|
|
This is the number of B-tree pages that hold both key and data.
|
|
|
|
Overflow pages used
|
|
|
|
The total number of overflow pages used for this category.
|
|
|
|
Unused bytes on index pages
|
|
|
|
The total number of bytes of unused space on all index pages. The
|
|
percentage at the right is the number of unused bytes divided by the
|
|
total number of bytes on index pages.
|
|
|
|
Unused bytes on primary pages
|
|
|
|
The total number of bytes of unused space on all primary pages. The
|
|
percentage at the right is the number of unused bytes divided by the
|
|
total number of bytes on primary pages.
|
|
|
|
Unused bytes on overflow pages
|
|
|
|
The total number of bytes of unused space on all overflow pages. The
|
|
percentage at the right is the number of unused bytes divided by the
|
|
total number of bytes on overflow pages.
|
|
|
|
Unused bytes on all pages
|
|
|
|
The total number of bytes of unused space on all primary and overflow
|
|
pages. The percentage at the right is the number of unused bytes
|
|
divided by the total number of bytes.
|
|
}
|
|
|
|
# Output a dump of the in-memory database. This can be used for more
|
|
# complex offline analysis.
|
|
#
|
|
puts "**********************************************************************"
|
|
puts "The entire text of this report can be sourced into any SQL database"
|
|
puts "engine for further analysis. All of the text above is an SQL comment."
|
|
puts "The data used to generate this report follows:"
|
|
puts "*/"
|
|
puts "BEGIN;"
|
|
puts $tabledef
|
|
unset -nocomplain x
|
|
mem eval {SELECT * FROM space_used} x {
|
|
puts -nonewline "INSERT INTO space_used VALUES"
|
|
set sep (
|
|
foreach col $x(*) {
|
|
set v $x($col)
|
|
if {$v=="" || ![string is double $v]} {set v [quote $v]}
|
|
puts -nonewline $sep$v
|
|
set sep ,
|
|
}
|
|
puts ");"
|
|
}
|
|
puts "COMMIT;"
|
|
|
|
} err]} {
|
|
puts "ERROR: $err"
|
|
puts $errorInfo
|
|
exit 1
|
|
}
|