Caml1999I037xy-Stdlib__Int64$zero?%int64O@@@\@)int64.mliee@@@@@#one@@@@]@h##h#2@@A@@)minus_oneA@@@^@kQQkQf@@+B@@#negB@,@@@_0@@@`@@a*%int64_negAA @@@3n4n@@CC@@#addC@D@@@b@J@@@cN@@@d@@e@@f*%int64_addBA@@@@QqRq@@aD@@#subD@b@@@g@h@@@hl@@@i@@j@@k*%int64_subBA<@@@@otptH@@E@@#mulE@@@@l@@@@m@@@n@@o@@p*%int64_mulBAZ@@@@w^^w^@@F@@#divF@@@@q@@@@r@@@s@@t@@u*%int64_divBAx@@@@zz@@G@@,unsigned_divG@@@@v@@@@w@@@x@@y@@z@@  @  @@H@@#remH@@@@{@@@@|@@@}@@~@@*%int64_modBA@@@@F N NF N @@I@@,unsigned_remI@@@@@@@@@@@@@@@@L s sL s @@ J@@$succJ@ @@@@@@@@@R  R  6@@K@@$predK@@@@#@@@@@@!U v v"U v @@1L@@#absL@2@@@6@@@@@@4X  5X  @@DM@@'max_intMC@@@@A\ \ \B\ \ o@@QN@@'min_intNP@@@@N_  O_  @@^O@@&logandO@_@@@@e@@@i@@@@@@@*%int64_andBA9@@@@lb  mb 7@@|P@@%logorP@}@@@@@@@@@@@@@@)%int64_orBAW@@@@eUUeU@@Q@@&logxorQ@@@@@@@@@@@@@@@*%int64_xorBAu@@@@hh@@R@@&lognotR@@@@@@@@@@kk"@@S@@*shift_leftS@@@@@#intA@@@@@@@@@@*%int64_lslBA@@@@nEEnE@@T@@+shift_rightT@@@@@ @@@@@@@@@@*%int64_asrBAƠ@@@@rr4@@ U@@3shift_right_logicalU@ @@@@>@@@@@@@@@@*%int64_lsrBA@@@@xxZ@@'V@@&of_intV@V@@@,@@@@@-%int64_of_intAA@@@.~DD/~Dt@@>W@@&to_intW@?@@@q@@@@@-%int64_to_intAA@@@EF@@UX@@/unsigned_to_intX@V@@@&optionL@@@@@@@@@_NN`Nw@@oY@@(of_floatY@%floatD@@@v@@@@@3caml_int64_of_floatA@;caml_int64_of_float_unboxedA@Bz33{@'unboxed@@@'noalloc@@@@Z@@(to_floatZ@@@@4@@@@@3caml_int64_to_floatA@;caml_int64_to_float_unboxed.@AAZ@'unboxedAFAM@@ACAN@'noallocARAY@@AO@@[@@(of_int32[@%int32N@@@@@@@@Ð/%int64_of_int32AA@@@@@\@@(to_int32\@@@@@@@@@Ɛ/%int64_to_int32AA@@@777m@@]@@,of_nativeint]@)nativeintM@@@@@@@@ɐ3%int64_of_nativeintAAӠ@@@444v@@^@@,to_nativeint^@@@@@@@@@̐3%int64_to_nativeintAA@@@@@,_@@)of_string_@&stringQ@@@3@@@@@ϐ4caml_int64_of_stringAA@@@56 @@E`@@-of_string_opt`@@@@N@@@@@@@@@MN&@@]a@@)to_stringa@^@@@5@@@@@@`zzaz@@pb@@-bits_of_floatb@@@@u@@@@@ِ8caml_int64_bits_of_floatA@ caml_int64_bits_of_float_unboxedA@xyJc@'unboxedJOJV@@JLJW@'noallocJ[Jb@@JX@@c@@-float_of_bitsc@@@@2@@@@@ܐ8caml_int64_float_of_bitsA@ caml_int64_float_of_bits_unboxed,@A ~ ~ !@'unboxed    @@    @'noalloc   !@@  @@d@@!td;@@@A@@@@@@@!!!!@@@@e@A@'comparee@@@@@@@@@@@@@@@@!!!"@@f@@0unsigned_comparef@@@@@@@@(@@@@@@@@# # # #/@@g@@%equalg@/@@@@4@@@$boolE@@@@@@@@####@@!h@@#minh@H@@@@M@@@P@@@@@@@@'##(#$ @@7i@@#maxi@^@@@@c@@@f@@@@@@@@=$O$O>$O$c@@Mj@@+seeded_hashj@|@@@@z@@@@@@@@@@@U$$V$$@@ek@@$hashk@@@@@@@@@@g%%h%%@@wl@@@k:.-Stdlib__Int640l-J ~m-۠&Stdlib0Lku]8_٠8CamlinternalFormatBasics0%FU(Q/Tu@@@Caml1999T037YeTgLC-Stdlib__Int64*ocaml.text&_none_@@A  64-bit integers. This module provides operations on the type [int64] of signed 64-bit integers. Unlike the built-in [int] type, the type [int64] is guaranteed to be exactly 64-bit wide on all platforms. All arithmetic operations over [int64] are taken modulo 2{^64} Performance notice: values of type [int64] occupy more memory space than values of type [int], and arithmetic operations on [int64] are generally slower than those on [int]. Use [int64] only when the application requires exact 64-bit arithmetic. Literals for 64-bit integers are suffixed by L: {[ let zero: int64 = 0L let one: int64 = 1L let m_one: int64 = -1L ]} )int64.mliP77c@@@@@@3@@@@@@#intA;@@#intA@@@@@;@A@$charB;@@$charA@@@@@A@A@&stringQ;@@&stringA@@@@@G@@@%bytesC;@@%bytesA@@@@@M@@@%floatD;@@%floatA@@@@@S@@@$boolE;@@%falsec@@]@$trued@@c@@@A@@@@@d@A@$unitF;@@"()e@@n@@@A@@@@@o@A@ #exnG;@@@A@@@@@s@@@#effH;@@O@A@A@@@@@@|@@@,continuationI;@@Q@@P@B,continuationA@nY@@@@@@@@@%arrayJ;@@R@A%arrayA@@@@@@@@@ $listK;@@S@A"[]f@@@"::g@@@T@@@ @@A@Y@@@@@@@@&optionL;@@V@A$Noneh@@@$Somei@@@@@A@Y@@@@@@@@)nativeintM;@@)nativeintA@@@@@@@@%int32N;@@%int32A@@@@@@@@%int64O;@@%int64A@@@@@@@@&lazy_tP;@@X@A&lazy_tA@Y@@@@@@@@ 5extension_constructorR;@@5extension_constructorA@@@@@@@@*floatarrayS;@@*floatarrayA@@@@@@@@&iarrayT;@@Y@A&iarrayA@Y@@@@@@@@ *atomic_locU;@@Z@A*atomic_locA@@@@@@ @@@ .Assert_failure`#@@@@@J@@@@@@@@[@@A!=ocaml.warn_on_literal_pattern%@&@0Division_by_zero]#@@@A+ . .@+End_of_file\#$@@@A366@'FailureY#,@'@@A<??@0Invalid_argumentX#5@0@@AE$H#H@-Match_failureV#>@@=@9@;@@a@@AV5Y4Y@)Not_foundZ#O@@@A^=a<a@-Out_of_memoryW#W@@@AfEiDi@.Stack_overflow^#_@@@AnMqLq@.Sys_blocked_io_#g@@@AvUyTy@)Sys_error[#o@j@@A^]@:Undefined_recursive_modulea#x@@w@s@u@@h@@Aon@:Continuation_already_takenb#@@@Awv@&Stdlib@A$zeroee@гԠ%int64ee@@ @@@@@@e@)ocaml.doc7 The 64-bit integer 0. ff!@@@@@@@@@@@ΐ@@@@@@#oneh#'h#*@г %int64h#-h#2@@ @@@3@K8@A@@@h## @97 The 64-bit integer 1. i33i3O@@@@@@@ A@@@I@@@@@@!)minus_onekQU kQ^@гB%int64kQakQf@@ @@@3@8K6@A@@@kQQ @p8 The 64-bit integer -1. (lgg)lg@@@@@@@AB@@@<@@@@@@!#neg?n@n@б@г{%int64JnKn@@ @@@3LKKLLLLL@:M8@A@@г%int64YnZn@@ @@@@@@@@@@*%int64_negAA @@@injn@1 Unary negation. woxo@@@@@@@C@@@@@@@@@8#addqq@б@гˠ%int64qq@@ @@@3@Qf?@A@@б@гܠ%int64qq@@ @@@@@г預%int64qq@@ @@@@@@@@!@@@'@@$* @@*%int64_addBAb@@@@qq@!+ Addition. rr@@@@@@@D@@@2@@@@@@J#subtt@б@г-%int64t"t'@@ @@@3@cx?@A@@б@г>%int64 t+t0@@ @@@@@гK%int64t4t9@@ @@@@@@@@!@@@'@@$* @@*%int64_subBAĠ@@@@-t.tH@. Subtraction. ;uII@@@@@@!'min_int!A_  B_  @г{%int64J_  K_  @@ @@@3LKKLLLLL@8K6@A@@@T_   @ 5 The smallest representable 64-bit integer, -2{^63}. a`  b`  @@@@@@@zO@@@u@@@@@@!&logand"xb yb @б@г%int64b b @@ @@@3@:M8@A@@б@гŠ%int64b b @@ @@@@@гҠ%int64b #b (@@ @@@@@@@@!@@@'@@$* @@*%int64_andBAK@@@@b  b 7@ 6 Bitwise logical and. c88c8S@@@@@@@P@@@א@@@@@@J%logor#eU^eUc@б@г%int64eUfeUk@@ @@@3@cx?@A@@б@г'%int64eUoeUt@@ @@@@@г4%int64eUxeU}@@ @@@@@@@@!@@@'@@$* @@)%int64_orBA@@@@eUUeU@l5 Bitwise logical or. $f%f@@@@@@@=Q@@@}9@@@@@@J&logxor$<h=h@б@гx%int64GhHh@@ @@@3IHHIIIII@cx?@A@@б@г%int64XhYh@@ @@@@@г%int64ehfh@@ @@@@@@@@!@@@'@@$* @@*%int64_xorBA@@@@xhyh@ΐ? Bitwise logical exclusive or. ii@@@@@@@R@@@@@@@@@J&lognot%k k@б@гڠ%int64kk@@ @@@3@cx?@A@@г預%int64kk"@@ @@@@@@@@@@@k @; Bitwise logical negation. l##l#C@@@@@@@S@@@(䐠@@@@@@1*shift_left&nENnEX@б@г#%int64nE[nE`@@ @@@3@J_8@A@@б@г֠#intnEdnEg@@ @@@@@гA%int64nEknEp@@ @@@@@@@@!@@@'@@$* @@*%int64_lslBA@@@@#nEE$nE@y r [Int64.shift_left x y] shifts [x] to the left by [y] bits. The result is unspecified if [y < 0] or [y >= 64]. 1o2p@@@@@@@JT@@@F@@@@@@J+shift_right'IrJr @б@г%int64TrUr@@ @@@3VUUVVVVV@cx?@A@@б@г8#interfr@@ @@@@@г%int64rr sr%@@ @@@@@@@@!@@@'@@$* @@*%int64_asrBA@@@@rr4@ې [Int64.shift_right x y] shifts [x] to the right by [y] bits. This is an arithmetic shift: the sign bit of [x] is replicated and inserted in the vacated bits. The result is unspecified if [y < 0] or [y >= 64]. s55v@@@@@@@U@@@@@@@@@J3shift_right_logical(x x3@б@г砐%int64x6x;@@ @@@3@cx?@A@@б@г#intx?xB@@ @@@@@г%int64xFxK@@ @@@@@@@@!@@@'@@$* @@*%int64_lsrBA~@@@@xxZ@= [Int64.shift_right_logical x y] shifts [x] to the right by [y] bits. This is a logical shift: zeroes are inserted in the vacated bits regardless of the sign of [x]. The result is unspecified if [y < 0] or [y >= 64]. y[[| B@@@@@@@ V@@@N @@@@@@J&of_int) ~DM ~DS@б@г렐#int ~DV ~DY@@ @@@3        @cx?@A@@гX%int64 '~D] (~Db@@ @@@@@@@@@@-%int64_of_intAAΠ@@@ 6~DD 7~Dt@ P Convert the given integer (type [int]) to a 64-bit integer (type [int64]).  Duu E@@@@@@@ ]W@@@ Y@@@@@@7&to_int* \ ]@б@г%int64 g h@@ @@@3 i h h i i i i i@Pe>@A@@г I#int v w@@ @@@@@@@@@@-%int64_to_intAA@@@  @ې J Convert the given 64-bit integer (type [int64]) to an integer (type [int]). On 64-bit platforms, the 64-bit integer is taken modulo 2{^63}, i.e. the high-order bit is lost during the conversion. On 32-bit platforms, the 64-bit integer is taken modulo 2{^31}, i.e. the top 33 bits are lost during the conversion.   0L@@@@@@@ X@@@ @@@@@@7/unsigned_to_int+ NR Na@б@г砐%int64 Nd Ni@@ @@@3        @Pe>@A@@г &option Nq Nw@г #int Nm Np@@ @@@@@@@@@ @@@$@@!'@@@ NN@4 Same as {!to_int}, but interprets the argument as an {e unsigned} integer. Returns [None] if the unsigned value of the argument cannot fit into an [int]. @since 4.08  xx 1@@@@@@@ Y@@*@D @@@@@@@(of_float, 3< 3D@б@г ɠ%float 3G 3L@@ @@@3        @Yn8@A@@г N%int64 3P 3U@@ @@@@@@@@@@3caml_int64_of_floatA@;caml_int64_of_float_unboxedA@B .33 /@'unboxed 5 6@@ 9 :@'noalloc @ A@@ D@ 7 Convert the given floating-point number to a 64-bit integer, discarding the fractional part (truncate towards 0). If the truncated floating-point number is outside the range \[{!Int64.min_int}, {!Int64.max_int}\], no exception is raised, and an unspecified, platform-dependent integer is returned.  Q R@@@@@@@ jZ@,,@)(@'&@# @ o@@@@@@W=(to_float- r s@б@г %int64 } ~@@ @@@3  ~ ~     @p^@A@@г G%float  @@ @@@@@@@@@@3caml_int64_to_floatA@;caml_int64_to_float_unboxedo@A  AZ@'unboxed AF AM@@ AC AN@'noalloc AR AY@@ AO@  > Convert the given 64-bit integer to a floating-point number.  [[ [@@@@@@@ [@++@)(@'&@# @ ! ݐ@@@@@@V=(of_int32.  @б@г "%int32  @@ @@@3        @o]@A@@г +%int64  @@ @@@@@@@@@@/%int64_of_int32AA@@@  @ _ X Convert the given 32-bit integer (type [int32]) to a 64-bit integer (type [int64]).    5@@@@@@@ 0\@@@ p ,@@@@@@7(to_int32/ /7@ 07H@б@г k%int64 :7K ;7P@@ @@@3 < ; ; < < < < <@Pe>@A@@г %int32 I7T J7Y@@ @@@ @@@@@ @@/%int64_to_int32AA@@@ X77 Y7m@ Convert the given 64-bit integer (type [int64]) to a 32-bit integer (type [int32]). The 64-bit integer is taken modulo 2{^32}, i.e. the top 32 bits are lost during the conversion.  fnn g2@@@@@@@ ]@@@  {@@@@@@7,of_nativeint0 ~4= 4I@б@г Ơ)nativeint 4L 4U@@ @@@ 3        @Pe>@A@@г ɠ%int64 4Y 4^@@ @@@ @@@@@ @@3%int64_of_nativeintAA ?@@@ 44 4v@ \ Convert the given native integer (type [nativeint]) to a 64-bit integer (type [int64]).  ww @@@@@@@ ^@@@  ʐ@@@@@@7,to_nativeint1  @б@г %int64  @@ @@@3        @Pe>@A@@г $)nativeint  @@ @@@@@@@@@@3%int64_to_nativeintAA @@@  @ L Convert the given 64-bit integer (type [int64]) to a native integer. On 32-bit platforms, the 64-bit integer is taken modulo 2{^32}. On 64-bit platforms, the conversion is exact.   @@@@@@@ _@@@ ] @@@@@@7)of_string2  @б@г &string ' (@@ @@@3 ) ( ( ) ) ) ) )@Pe>@A@@г g%int64 6 7@@ @@@@@@@@@@4caml_int64_of_stringAA ݠ@@@ E F @  Convert the given string to a 64-bit integer. The string is read in decimal (by default, or if the string begins with [0u]) or in hexadecimal, octal or binary if the string begins with [0x], [0o] or [0b] respectively. The [0u] prefix reads the input as an unsigned integer in the range [[0, 2*Int64.max_int+1]]. If the input exceeds {!Int64.max_int} it is converted to the signed integer [Int64.min_int + input - Int64.max_int - 1]. The [_] (underscore) character can appear anywhere in the string and is ignored. @raise Failure if the given string is not a valid representation of an integer, or if the integer represented exceeds the range of integers representable in type [int64].  S!! T@@@@@@@ l`@@@  h@@@@@@7-of_string_opt3 k l@б@г =&string v w@@ @@@3 x w w x x x x x@Pe>@A@@г ٠&option   &@г %int64  @@ @@@@@@@@@ @@@$@@!'@@@ @ L Same as [of_string], but return [None] instead of raising. @since 4.05  '' fx@@@@@@@ a@@*@  @@@@@@@)to_string4 z~ z@б@г %int64 z z@@ @@@3        @Yn8@A@@г &string z z@@ @@@@@@@@@@@ zz @ = ? Return the string representation of its argument, in decimal.   @@@@@@@ b@@@ M @@@@@@1-bits_of_float5  @б@г Ҡ%float  @@ @@@3        @J_8@A@@г W%int64 & '@@ @@@@@@@@@@8caml_int64_bits_of_floatA@ caml_int64_bits_of_float_unboxedA@  6 7Jc@'unboxed =JO >JV@@ AJL BJW@'noalloc HJ[ IJb@@ LJX@  Return the internal representation of the given float according to the IEEE 754 floating-point 'double format' bit layout. Bit 63 of the result represents the sign of the float; bits 62 to 52 represent the (biased) exponent; bits 51 to 0 represent the mantissa.  Ydd Z _ |@@@@@@@ rc@++@)(@'&@# @  w@@@@@@V=-float_of_bits6 z ~  { ~ @б@г %int64  ~   ~ @@ @@@3        @o]@A@@г O%float  ~   ~ @@ @@@ @@@@@!@@8caml_int64_float_of_bitsA@ caml_int64_float_of_bits_unboxedw@A  ~ ~  !@'unboxed      @@      @'noalloc     !@@   @  Return the floating-point number whose internal representation, according to the IEEE 754 floating-point 'double format' bit layout, is the given [int64].  !! !!@@@@@@@ d@++@)(@'&@# @ ) 吠@@@@@@V=A+!t7A !! !!@@;@@@A &@@@#@@@@ !! !!@ I + An alias for the type of 64-bit integers. !!!!@@@@@@@@@e@@@Aг%int64 !!@@3      @r*;@@@A2@@@(@"@@@@&#@@@A%@@' m)%$@$$@@@$@$@@3!  !!!!!@@A32@'compare8.!!/!!@б@гP!t9!!:!!@@ @@@*3;::;;;;;@2[U@A@@б@гa!tJ!!K!!@@ @@@+@@г*#intW!"X!"@@ @@@,@@@@@-!@@@'@@.$* @@@e!!@ The comparison function for 64-bit integers, with the same specification as {!Stdlib.compare}. Along with the type [t], this function [compare] allows the module [Int64] to be passed as argument to the functors {!Set.Make} and {!Map.Make}. r""s"# @@@@@@@f@@@ @@@@@@C0unsigned_compare9# ## # @б@г!t# #"# ##@@ @@@/3@\q8@A@@б@г!t# #'# #(@@ @@@0@@г#int# #,# #/@@ @@@1@@@@@2!@@@'@@3$* @@@# # @  q Same as {!compare}, except that arguments are interpreted as {e unsigned} 64-bit integers. @since 4.08 #0#0##@@@@@@@g@@@ %ᐠ@@@@@@C%equal:####@б@г!t####@@ @@@43@\q8@A@@б@г!t####@@ @@@5@@г $bool ####@@ @@@6@@@@@7!@@@'@@8$* @@@##@ p 0 The equal function for int64s. @since 4.03 (##)##@@@@@@@Ah@@@ <@@@@@@C#min;?##@#$@б@гa!tJ#$K#$@@ @@@93LKKLLLLL@\q8@A@@б@гr!t[#$\#$@@ @@@:@@г!th#$ i#$ @@ @@@;@@@@@<!@@@'@@=$* @@@v##@ ː : Return the smaller of the two arguments. @since 4.13 $$$K$M@@@@@@@i@@@ @@@@@@C#max<$O$S$O$V@б@г!t$O$X$O$Y@@ @@@>3@\q8@A@@б@г͠!t$O$]$O$^@@ @@@?@@гڠ!t$O$b$O$c@@ @@@@@@@@@A!@@@'@@B$* @@@$O$O@& ; Return the greater of the two arguments. @since 4.13 $d$d$$@@@@@@@j@@@6򐠠@@@@@@C+seeded_hash=$$$$@б@гӠ#int$$$$@@ @@@C3@\q8@A@@б@г(!t$$$$@@ @@@D@@г#int$$$$@@ @@@E@@@@@F!@@@'@@G$* @@@,$$@ A seeded hash function for 64-bit ints, with the same output value as {!Hashtbl.seeded_hash}. This function allows this module to be passed as argument to the functor {!Hashtbl.MakeSeeded}. @since 5.1 9$$:%%@@@@@@@Rk@@@M@@@@@@C$hash>P%%Q%%@б@гr!t[%%\%%@@ @@@H3]\\]]]]]@\q8@A@@г=#intj%%k%%@@ @@@I@@@@@J@@@u%% @ʐ An unseeded hash function for 64-bit ints, with the same output value as {!Hashtbl.hash}. This function allows this module to be passed as argument to the functor {!Hashtbl.Make}. @since 5.1 %%&{&@@@@@@@l@@@@@@@@@1@@@~@^7@ @  w@ P @  @  W@ 7 @  @ ~ W@ 7 @  @  @ t _@ ? @  @  F@ @@x?@@@kD@@@[4@@{@U.@@@n8@@@e>@A@|@\#@@q@Q@@x@@3@z@A@ H************************************************************************A@@A@L@ H BMMBM@ H OCaml CC@ H DD3@ H Xavier Leroy, projet Cristal, INRIA Rocquencourt  E44 E4@ H FF@ H Copyright 1996 Institut National de Recherche en Informatique et GG@ H en Automatique. HHg@ H !Ihh"Ih@ H All rights reserved. This file is distributed under the terms of 'J(J@ H the GNU Lesser General Public License version 2.1, with the -K.KN@ H special exception on linking described in the file LICENSE. 3LOO4LO@ H 9M:M@ H************************************************************************?N@N5@ * 64-bit integers. This module provides operations on the type [int64] of signed 64-bit integers. Unlike the built-in [int] type, the type [int64] is guaranteed to be exactly 64-bit wide on all platforms. All arithmetic operations over [int64] are taken modulo 2{^64} Performance notice: values of type [int64] occupy more memory space than values of type [int], and arithmetic operations on [int64] are generally slower than those on [int]. Use [int64] only when the application requires exact 64-bit arithmetic. Literals for 64-bit integers are suffixed by L: {[ let zero: int64 = 0L let one: int64 = 1L let m_one: int64 = -1L ]} E8* The 64-bit integer 0. 8* The 64-bit integer 1. Z9* The 64-bit integer -1. &2* Unary negation. ڠ,* Addition. {/* Subtraction. 2* Multiplication.  * Integer division. @raise Division_by_zero if the second argument is zero. This division rounds the real quotient of its arguments towards zero, as specified for {!Stdlib.(/)}.  ^ y* Same as {!div}, except that arguments and result are interpreted as {e unsigned} 64-bit integers. @since 4.08   * Integer remainder. If [y] is not zero, the result of [Int64.rem x y] satisfies the following property: [x = Int64.add (Int64.mul (Int64.div x y) y) (Int64.rem x y)]. If [y = 0], [Int64.rem x y] raises [Division_by_zero].  y* Same as {!rem}, except that arguments and result are interpreted as {e unsigned} 64-bit integers. @since 4.08  N 9* Successor. [Int64.succ x] is [Int64.add x Int64.one].   ;* Predecessor. [Int64.pred x] is [Int64.sub x Int64.one].    l* [abs x] is the absolute value of [x]. On [min_int] this is [min_int] itself and thus remains negative.  | 9* The greatest representable 64-bit integer, 2{^63} - 1.  H 6* The smallest representable 64-bit integer, -2{^63}.  7* Bitwise logical and.  6* Bitwise logical or.  W * Bitwise logical exclusive or.  <* Bitwise logical negation.  s* [Int64.shift_left x y] shifts [x] to the left by [y] bits. The result is unspecified if [y < 0] or [y >= 64].  S * [Int64.shift_right x y] shifts [x] to the right by [y] bits. This is an arithmetic shift: the sign bit of [x] is replicated and inserted in the vacated bits. The result is unspecified if [y < 0] or [y >= 64].  * [Int64.shift_right_logical x y] shifts [x] to the right by [y] bits. This is a logical shift: zeroes are inserted in the vacated bits regardless of the sign of [x]. The result is unspecified if [y < 0] or [y >= 64].  Q* Convert the given integer (type [int]) to a 64-bit integer (type [int64]). I K* Convert the given 64-bit integer (type [int64]) to an integer (type [int]). On 64-bit platforms, the 64-bit integer is taken modulo 2{^63}, i.e. the high-order bit is lost during the conversion. On 32-bit platforms, the 64-bit integer is taken modulo 2{^31}, i.e. the top 33 bits are lost during the conversion.  * Same as {!to_int}, but interprets the argument as an {e unsigned} integer. Returns [None] if the unsigned value of the argument cannot fit into an [int]. @since 4.08  8* Convert the given floating-point number to a 64-bit integer, discarding the fractional part (truncate towards 0). If the truncated floating-point number is outside the range \[{!Int64.min_int}, {!Int64.max_int}\], no exception is raised, and an unspecified, platform-dependent integer is returned. E ?* Convert the given 64-bit integer to a floating-point number. ڠ Y* Convert the given 32-bit integer (type [int32]) to a 64-bit integer (type [int64]).  * Convert the given 64-bit integer (type [int64]) to a 32-bit integer (type [int32]). The 64-bit integer is taken modulo 2{^32}, i.e. the top 32 bits are lost during the conversion. 9 ]* Convert the given native integer (type [nativeint]) to a 64-bit integer (type [int64]).  * Convert the given 64-bit integer (type [int64]) to a native integer. On 32-bit platforms, the 64-bit integer is taken modulo 2{^32}. On 64-bit platforms, the conversion is exact.  * Convert the given string to a 64-bit integer. The string is read in decimal (by default, or if the string begins with [0u]) or in hexadecimal, octal or binary if the string begins with [0x], [0o] or [0b] respectively. The [0u] prefix reads the input as an unsigned integer in the range [[0, 2*Int64.max_int+1]]. If the input exceeds {!Int64.max_int} it is converted to the signed integer [Int64.min_int + input - Int64.max_int - 1]. The [_] (underscore) character can appear anywhere in the string and is ignored. @raise Failure if the given string is not a valid representation of an integer, or if the integer represented exceeds the range of integers representable in type [int64]. U M* Same as [of_string], but return [None] instead of raising. @since 4.05  @* Return the string representation of its argument, in decimal.  * Return the internal representation of the given float according to the IEEE 754 floating-point 'double format' bit layout. Bit 63 of the result represents the sign of the float; bits 62 to 52 represent the (biased) exponent; bits 51 to 0 represent the mantissa. X * Return the floating-point number whose internal representation, according to the IEEE 754 floating-point 'double format' bit layout, is the given [int64].  ,* An alias for the type of 64-bit integers.  * The comparison function for 64-bit integers, with the same specification as {!Stdlib.compare}. Along with the type [t], this function [compare] allows the module [Int64] to be passed as argument to the functors {!Set.Make} and {!Map.Make}. H r* Same as {!compare}, except that arguments are interpreted as {e unsigned} 64-bit integers. @since 4.08  1* The equal function for int64s. @since 4.03  ;* Return the smaller of the two arguments. @since 4.13 @ <* Return the greater of the two arguments. @since 4.13 蠠 * A seeded hash function for 64-bit ints, with the same output value as {!Hashtbl.seeded_hash}. This function allows this module to be passed as argument to the functor {!Hashtbl.MakeSeeded}. @since 5.1  * An unseeded hash function for 64-bit ints, with the same output value as {!Hashtbl.hash}. This function allows this module to be passed as argument to the functor {!Hashtbl.Make}. @since 5.1 J@?)../ocamlc0-strict-sequence(-absname"-w5+a-4-9-41-42-44-45-48"-g+-warn-error"+A*-bin-annot)-nostdlib*-principal"-o1stdlib__Int64.cmi"-cِ [/home/teraram/ci/builds/workspace/parallel-build/flambda/false/label/ocaml-manycores/stdlib @@0Aɽ+&3@@@8CamlinternalFormatBasics0%FU(Q/Tu&Stdlib0Lku]8_٠0l-J ~m-@0l-J ~m-Amp   ͐ @<@' ?  Y @  ;@@N@@Ґ@B@e@5@9@@6@/x  @X Q  Ȑ4\@r@ 4 ,~@@  P@@@ А @  aL}@@   J h@  ٰE@Ր!EP@@@@@@P@@