RU2128855C1 - Device for information sorting - Google Patents

Abstract

FIELD: automation and computer engineering, in particular, information processing equipment for compiling vocabularies, databases, design of information retrieval systems. SUBSTANCE: device has input and output channels, two stack memory units, comparison gate, memory unit, control unit, memory devices, counters, registers, comparators, stack, commutators, code generator, bus generator, NOR gate, AND gate. Goal of invention is achieved by selection of words from data flow which conform to conditions with respect to known samples. Device provides sorting of input data while they are entered. Ordered output array can have ascending or descending order. In addition device provides selection of words from input flow using their comparison to samples with respect to greater than, less than or equal to relations. EFFECT: increased functional capabilities. 9 dwg

Description

 The invention relates to technical means of automation and computer technology and can be used in information processing devices, in particular, for compiling dictionaries, reference books, creating databases, in information retrieval systems.

 It is known "Device for sorting numbers" (A.S. N 1304015, 1987 Bull. 14), which allows you to arrange an array of numbers in ascending and descending order.

 Also known is the "Information Sorting Device" (a.c. N 1594521, 1990 Bull. 355), which makes it possible to organize data arrays.

 As a prototype, the "Information Sorting Device" was selected (positive decision dated March 26, 94 by application number 93015991), which allows one to organize data.

 A disadvantage of the known device is the limited functionality of a single ordering operation.

 The goal is to expand functionality without significantly increasing the cost of equipment.

 The invention allows to organize, in addition to the data sequencing mode, a mode for selecting words from a data stream based on comparing them with predetermined patterns without a significant increase in hardware costs.

 The solution is achieved by the fact that in the information sorting device containing the first and second stacked memory blocks, a comparison element, a control unit, input and output channels, a random access memory unit, a switching and identification unit, the first to fifth control outputs of the control unit are connected respectively from the first to fifth control inputs of the RAM block, the information input of which is connected to the input channel, the control output of the RAM block is connected to the fourth control input of the unit control, the information output of the random access memory unit is connected to the first information input of the comparison element and the second information input of the switching and identification unit, the first control output of the latter is connected to the fourteenth control input of the control unit, the first to third control inputs of the switching and identification unit are connected respectively from the tenth according to the twelfth control outputs of the control unit, the second information output of the switching and identification unit is connected to the output channel, the first information output of the switching and identification unit is connected to the information input of the second stack memory block, the first and second control inputs of the latter are connected respectively to the sixth and seventh control outputs of the control unit, the first and second control outputs of the second stack memory block are connected to the tenth and eleventh control inputs, respectively control unit, the first and second control inputs of the first stack memory block are connected respectively with the eighth and ninth control in the outputs of the control unit, the first and second control outputs of the first stack memory block are connected respectively to the twelfth and thirteenth control inputs of the control unit, the information output of the first stack memory block is connected to the first information input of the switching and identification unit and to the second information input of the comparison element, from the first to the third control outputs of the latter are connected respectively from the fifth to seventh control inputs of the control unit, from the first to third control inputs " ZAGR "," ChTPR "," WHAT ", as well as the eighth and ninth control inputs" RESET "and" START "of the control unit are external inputs of the device, the thirteenth and fourteenth control outputs" GT "and" SIN "of the control unit are external outputs of the device , introduced the sixteenth external control input "RSEL" of the control unit, from the fifteenth to seventeenth control outputs of which are connected to the third to fifth control inputs of the first stack memory block, respectively, the third control output of the latter is connected to the fifteenth control the main input of the control unit, the eighteenth control output and the seventeenth control input of which are connected respectively to the fourth control input and the second control output of the switching and identification unit, the third information output of the latter is connected to the information input of the first stack memory unit, the third and fourth information inputs of the switching and identification unit connected respectively to the input channel and the information output of the second stack memory block.

 VHK - the input channel is used to receive data.

 BOP - the block of random access memory serves for temporary storage of the accepted word or number.

 ES - an element for comparing the characters of a received word and already ordered words or patterns.

 SBP2 - the second stacked memory block is used to store part of an ordered array and organize ordering.

 SBP1 - the first stacked memory block is used to store part of an ordered array and organize ordering or storage of an array of samples in the sampling mode.

 БКиИ - switching and identification block serves for switching information from various sources to the information input of blocks СБП2 СБП1 and to the output channel, as well as to determine the word boundaries of an ordered array and to identify masked characters of the sample.

 OUT - the output channel is used to output data.

 BU - control unit is used to control other units of the device.

The theory of normal algorithms is universal with respect to any algorithmic schemes / 1 /. A Markov algorithm is a finite sequence of formulas of the form
S _ → T, (1)
where S is the sample;
T is a substitution;
S and T are arbitrary words in a fixed alphabet.

 The formula works by detecting a fragment in the word that matches the sample and replacing the detected fragment with a substitution word.

 The ordering of words, for example, on the basis of alphabetical order in the theory of normal algorithms, occupies a special place, since it relates to difficult tasks in which formulas / products / containing patterns with operations specified in their structure are used. In this case, we are talking about the operation of comparing "more", "less" and "equal". Substitution in formulas of the form / 1 / also has its own specifics and is an auxiliary service word indicating the position of a word among other words in a given ordering rule, and for word selection this service word is an index of a word that meets given selection rules.

The proposed device is based on a modified algorithm that contains a sample and a substitution with the above features. The information sorting device implements formulas of the following form:
S ₁ ⊗ S ₂ _ → T ₁ / T ₂ (2)
S ₁ ⊗ ′ S ₂ _ → T ₂ / T ₃ , (3)
where S ₁ and S ₂ are the comparants of the sample; ⊗ - a symbol denoting the operation of comparing to "more", "less" and "equal"; ⊗ ′ is a symbol denoting the operation of comparing by “more” and “less” with “equal” taking into account the mask of the sample when matching / which is shown as the sample compand in the formula of the form / 1 //, as well as the comparison of the length of the companions; T ₁ - position indicator in a partially ordered array of one of the comparands depending on the result of comparation or comparison of word lengths; T ₂ - pointer to the next / current / compendium or the rules for constructing a sample based on the results of word comparison; _ → - separators in the form of service characters that are not included in the main alphabet; T ₃ is a fragment of the substitution, meaning the issuance of the received word to the output channel;
In the proposed device, the meaning of the substitution fragment T ₂ is to receive the next character from the input channel.

 A formula of the form / 2 / defines a recursive implementation of the ordering process; formula of the form / 3 / - selection process.

In FIG. 1 is a structural diagram of an information sorting device;
in FIG. 2 presents a variant of the technical implementation of the RAM block;
in FIG. 3 - a variant of the technical implementation of the comparison element;
in FIG. 4 is an embodiment of a technical implementation of a second plug memory unit;
in FIG. 3 is an embodiment of a technical implementation of a first stack memory block;
in FIG. 6 is an embodiment of a technical implementation of a switching and identification unit;
in FIG. 7 is a meaningful graph diagram of the algorithm (hereinafter referred to as GAW) of the operation of the control unit.

 Information sorting device / FIG. 1 / contains an input channel 1, a RAM block 2, a comparison element 3, a first stack memory block 4, a second stack memory block 5, a switching and identification unit 6, an output channel 7, a control unit 8.

 To describe the operation algorithm of control unit 8, the following identifiers are used.

 1. 3AGR - signal recording to the device.

 2. ChTPR - a signal of the device issuing an ordered array in increasing order.

 3. SO - the signal from the device issuing an ordered array in descending order.

 4. OBSH - a zeroing signal received at the input of the counter of the BOP unit.

 5. INSC - a signal for incrementing the contents of the counter of the BOP unit.

 6. ZPRG - a signal of writing to the register of the RG block of the BOP information from the counter of the midrange of the BOP block.

 7. ZPOZU - write / non-read signal OZN block BOP.

 8. VK1 - signal selection chip OZN block BOP / inverse /.

 9. COP - a sign of the end of a word located in the BOP unit.

 10. MORE - a sign that the I2 symbol is larger than the I3 symbol.

 11. LESS - a sign that the I2 symbol is less than the I3 symbol.

 12. EQUAL - a sign that the I2 symbol is equal to the I3 symbol.

 13. ZNS1 - write signal to the stack of the SBP1 block.

 14. ЧТС1 - read signal from the stack of SBP1 block.

 15. OBSCHA - signal for resetting the counter of the address of the NAV unit SBP1.

 16. ZPRGA - signal write to the register of the RGA block SBP1 information from the counter of the address of the NAV block SBP1.

 17. VK2 - signal selection chip RAM block SBP1 / inversion /.

 18. S1PN - a sign that the SBP1 block is full.

 19. S1PT - a sign that the SBP1 block is empty.

 20. KM - a sign of the end of the array located in block SBP1 in selection mode.

 21. ZPS2 - write signal to the stack of the SBP2 block.

 22. ЧТС2 - read signal from the stack of SBP2 block.

 23. C2PN - a sign that the stack of the SBP2 block is full.

 24. C2PT - a sign that the SBP2 block stack is empty.

 25. RSEL is an external sign of the selection regime.

 26. RESET - device reset signal.

 27. START - device start signal.

 28. A0 - address supplied to the input of the switch KM2 block BCI.

 29. A1 - address 1, supplied to the input of the switch KM1 block BCI.

 30. A2 - address 2 supplied to the input of the switch KM1 block BCI.

 31. RV - permission signal for the issuance of information to the output channel.

 32. HS - a sign of the boundary between the words of an ordered array or array of samples.

 33. MS - a sign of a masked character in the selection mode.

 34. GT - signal readiness of the device.

 35. SYN - external output clock signal.

 36. I1 - input RAM of the BOP unit.

 37. I2 - the output of the RAM unit BOP.

 38. FROM - the output of RAM block SBP1.

 39. I4 - the output of the stack block SBP2.

 40. I5 - the output of the switch of the BKiI block, arriving at the input of the SBP2 stack.

 41. I6 - output data of the bus driver ShF block БКиИ.

 42. I7 - output data of the KM2 switch block БКиИ.

 The operation of the device control algorithm.

 A meaningful GAW control is shown in FIG. 7 and reflects the operation of the control unit / FIG. 1/.

 At the signal "RESET" (node 2 GAW) / Fig. 1 / the information stored in blocks SBP1 and SBP2 is reset by the commands “OBSCHA” and “TTS2” (node 4 GAU) until the block SBP2 is empty and the sign “C2PT” (node 5 GAU) is set / Fig. 1/.

 The signal "START" (node 5 GAW) is the transition to the node 113 GAW, otherwise the node 5 GAW.

 In node 6 GAW, the analysis of the signal "WHAT" is carried out, this signal is used to go to node 63 GAW.

 In the node 7 of the GAW, the analysis of the signal "ChTPR" is carried out, this signal is used to transfer to the node 58 GAW.

 At the GAW node 8, the “ZAGR” signal is analyzed, by which the input word is loaded into the BOP / Fig. 1 /, otherwise the transition to block 6 GAW.

 In block 9 of the GAW, the command "OSCH: = 1" resets the counter of the BOP unit / Fig. 2 /. Until the signal “ZAGR” is removed (GAU block 10), by the command “RAM: = 1”, the input symbol is recorded in RAM at the address stored in the MF counter / Fig. 2 / and the issuance of an external synchronization signal "SIN" / block 11 GAW /. In block 12 GAW on the command "INSC: = 1" the contents of the MF counter / Fig. 2 / increases by one.

 In block 13 of the GAW, by the command "ZPRG: = 1", the state of the MF counter is recorded in the register RG / Fig. 2 /, in this case, equal to the number of characters in the received word.

 In block 14 GAW analyzes the sign of emptiness of block SBP1 "C1PT". On this basis, the transition to block 16 of the algorithm.

 In the block 15 GAW by the command "OSCH: = 1" the MF counter is reset to zero / Fig. 2 /, by the commands "CTS1: = 1", "A1: = 1", "A2: = 1", "ZPS2: = 1", the character is written from the SBP1 block to the SBP2 block, the transition to the GSA block 19 is carried out.

 In block 16 GAW analyzes the sign of emptiness block SBP2 / Fig. 1 / "C2PT", on the basis of the transition to the GAU block 40, otherwise the word is written from SBP2 to SBP1 / Fig. 1/.

 In block 17, the sign of the boundary between words in the stacked blocks of memory "HS", identified by a special service code, is analyzed. On the basis of the transition to block 15 GAW.

 In the block 18 of the GAW, the commands “ЧТС2: = 1”, “ЗПС2: = 1” record the next character from SBP2 to SBP1 / Fig. 1 /, the transition to block 17 GAW.

 In block 19 of the GAW, a sign is analyzed that I2 is less than I3 “LESS”, issued by the comparison element / Fig. 3 /. On the basis of the transition to the block 20 GAW, otherwise the block 35 GAW.

 In the block 20 GAW analyzes the sign of the boundary between the words in the stacked blocks of memory / Fig. 1 / "GS", by which the transition to block 22 GAW.

 In block 21, the GAW records the symbol from SBP2 to SBP1 / Fig. 1 / by the commands "ЧТС2: = 1", "ЗПС1: = 1", transition to block 20 GAW.

 In the block 22 GAW analyzed the sign of "C2PT" emptiness SBP2 / Fig. 1 /, by which the transition to block 40 GAW.

 In the block 23 of the GAW, the commands “ЧТС2: = 1”, “ЗПС1: = 1” record the character from SBP2 to SBP1 / Fig. 1/.

 In the block 24 GAW analyzes the sign of the word boundary in the stacked blocks of memory "GS", by which the transition to block 25 GAW, otherwise block 23 GAW.

 In the block 25 GAW by the command "OSSH: = 1" is the zeroing of the midrange of the BOP unit / Fig. 2 /, by the commands "CTS1", "ZPS2", "A1", "A2", the character is recorded from SBP1 in SBP2 / Fig. 1/.

 In block 26 of the GAW, a sign is analyzed that I2 is less than I3 “LESS”, by which the transition to block 20 of the GAW is carried out.

 In the block 27 GAW analyzes the sign that I2 is equal to I3 "EQUAL", on the basis of the transition to block 31 GAW.

 In the GAU block 28, the “MORE” sign is analyzed that I2 is greater than I3, by which the transition to the GAU block 29 is performed, otherwise the GAU block 26 and the signs are checked again.

 In the block 29 GAW analyzes the sign of "GS", by which the transition to block 40 GAW.

 In the block 30 GAU for the commands "CTS1: = 1", "A1: = 1", "A2: = 1", "ZPS2: = 1" the symbol from SBP1 is recorded in SBP2 / Fig. 1 /, the transition to block 29 GAW.

 In block 31 GAW at the command "INSC: = 1" increases by one the contents of the midrange / Fig. 2 /, for the commands "CTS1", "A1", "A2", "ZPS2" the symbol from SBP1 is recorded in SBP2 / Fig.1 /.

 In the block 32 GAW analyzes the sign of "GS" or the void SBP2 "C2PT" / Fig. 1 /, by which the transition to block 34 GAW.

 In block 33, the sign of the end of the word is analyzed in the BOP "KS" / Fig. 1 /, issued in case of equality of the states of the MF and the RG / Fig. 2 /. On the basis of the transition to block 20 GAW, otherwise to block 26 GAW.

 In the block 34 GAW analyzes the sign of "COP", which is the transition to block 40 GAW, otherwise block 29 GAW.

 In block 35 GAW analyzes the sign "EQUAL", if "EQUAL = 0", the transition to block 44 GAW.

 In block 36 GAW at the command "INSC: = 1" the contents of the midrange / Fig. 2 / increases by one. By the command "CTS1: = 1", "A1: = 1", "A2: = 1", "ZPS2: = 1" the symbol from SBP1 is recorded in SBP2 / Fig. 1/.

 In the block 37 GAW analyzes the sign of the word boundary in SBP1, SBP2 or the void block SBP2 / Fig. 1 / "GS" and "C2PT", by which the transition to block 39 GAW.

 In block 38 of the GAW, the sign of “KS” is analyzed / FIG. 1 /, by which the transition to block 20 GAW, otherwise block 19 GAW.

 In the block 39 GAW analyzes the sign "KS", if "KS = 0", the transition to block 45 GAW.

 In block 40, the GAW by the command "OSCH" resets the MF / Fig. 2 /, by the commands "ZPS2: = 1", "A2: = 1" in SBP2 / Fig. 1 / the service code of the word boundary is recorded, while the signal "A2" addresses the output of the FC code generator using the switch KC1 / Fig. 6 /.

 In block 41 of the GAW, the sign of “KS” is analyzed / FIG. 1 /, by which the transition to block 71 GAW.

 In block 42 GAW is a record of the symbol from RAM addressed to the MF / Fig. 2 / by the commands "ZPS2: = 1", "A1: = 1", while the signal "A1" commutes I2 to the output of the CM / Fig. 6 /.

 In block 43 GAW by the command "INSC: = 1" there is an increase by one unit of the content of the midrange counter / Fig. 2 /, transition to block 41 GAW.

 In block 44 of the GAW, the MORE sign is analyzed / FIG. 1/. If "MORE = 0", the transition to block 19 GAW.

 In the block 45 GAW analyzed the sign of "GS" or "C2PT" / Fig. 1 /, on this basis, the transition to block 47 GAW.

 In block 46 of the GAW, by the commands "CTS1: = 1", "ZPS2: = 1", "A1: = 1", "A2: = 1", the character from SBP1 is recorded in SBP2 / Fig. 1 /, the transition to block 45 GAW.

 In the block 47 GAW analyzes the sign of emptiness SBP1 "S1PT" / Fig. 1 /, on the basis of the transition to block 40 GAW.

 In block 48 of the GAW, the command "OSCH: = 1" resets the MF counter / Fig. 2 /, according to the commands "CTS1", "ZPS2", "A1", "A2", the character from SBP1 is recorded in SBP2 / Fig. 1/.

 In block 49 of the GAW, the sign that I2 is less than I3 is “LESS” / FIG. 1 /, on the basis of the transition to block 56 GAW.

 In the block 50 GAW analyzes the sign "EQUAL", on the basis of the transition to block 52 GAW.

 In the block 51, the GAW analyzes the MORE sign / FIG. 1 /, on the basis of the transition to block GAW, otherwise block 49 GAW.

 In block 52 GAW by the command "INSC: = 1" there is an increase in the content of the midrange / Fig. 2 / per unit, according to the commands "ЧТС1: = 1", "ЗПС2: = 1", "А1: = 1", "А2: = 1" the symbol from SBP1 is recorded in SBP2 / Fig. 1/.

 In block 53 of the GAW, the sign of “GS” or “C2PT” is analyzed. If the sign is equal to zero, the transition to block 55 GAW.

 In the block 54 GAW analyzes the sign of the end of the word in BOP "KS" / Fig. 1 /, on the basis of the transition to block 40 GAW, otherwise to block 45 GAW.

 In block 55 GAW analyzed the sign of "COP". If "KS = 0", the transition to block 49 GAW.

 In the block 56 GAW analyzes the sign of the boundary between the words in SBP1, SBP2 "HS" / Fig. 1 /, by which the transition to block 40 GAW.

 In block 57 of the GAW, the symbol “SBP2: = 1”, “ZPS1: = 1” rewrites the symbol from SBP2 to SBP1 / Fig. 1 /, the transition to block 56 GAW.

 In the block 58 GAW analyzes the sign of emptiness SBP2 "C2PT", which is the transition to block 60 GAW.

 In block 59 of the GAW, the symbol from SBP2 to SBP1 is rewritten by the commands "CTS2: = 1", "ZPS1: = 1" 1 /, the transition to block 58 GAW.

 In the block 60 GAW analyzed the sign of "CHTR" / Fig. 1 /, by which the transition to block 61 GAW, otherwise block 60 GAW.

 In the block 61 GAW analyzes the sign of emptiness SBP1 "S1PT" / Fig. 1 /, on the basis of the transition to block 115 GAW.

 In block 62 GAW, the issuance of a symbol from SBP1 to VHKH by the commands "CTS1: = 1", "PB: = 1" and at the same time the signal "SYN: = 1".

 In block 63 of the GAW, the sign “C1PT” / FIG. 1 /, on the basis of the transition to block 65 GAW.

 In block 64 of the GAW, the commands “ЧТС1: = 1”, “ЗПС2: = 1”, “А1: = 1”, “А2: = 1” record the character from SBP1 to SBP2 / Fig. 1 /, the transition to block 63 GAW.

 In the block 65 GAW analyzes the presence of the signal "WHAT", the signal goes to block 66 GAW, otherwise block 65 GAW.

 In block 66 GAW, the symptom "C2PT" is analyzed, according to the sign, a transition to block 115 GAW is performed.

 In block 67, the sign of "GS" is analyzed, according to which the transition to block 69 of the GAW is carried out.

 In block 68 of the GAW, the symbol “SBP2: = 1”, “ZPS1: = 1” rewrites the symbol from SBP2 to SBP1 / Fig. 1 /, the transition to block 67 GAW.

 In the block 69 GAW analyzes the sign of emptiness SBP1 "S1PT" / Fig. 1 /, it is the transition to block 65 GAW.

 In block 70 GAW is the issuance of a symbol from SBP1 to OUT TO / Fig. 1 / by the commands "RV: = 1", "ЧТС1: = 1" and issuing the signal "SIN", the transition to block 69 GAW.

 In block 71 of the GAW, the presence of the “ZAGR” signal is analyzed. If "ZAGR = 0", the transition to block 71 GAW.

 In the block 72 of the GAW, the command “CALCULATION: = 1” resets the contents of the ACH counter / Fig. 5/.

 In the block 73T of the GAW, by the commands "ZPS1: = 1", "Ao: = 1", a symbol from the HCC is loaded into SBP1, which is gated by the signal "SYN" / Fig. 1/.

 In block 74, the GAW, by the INSCA command, increases the contents of the ACH / FIG. 5/.

 In the block 75 GAW analyzes the presence of the signal "ZAGR", which is the transition to block 77 GAW.

 In block 76 of the GAW, with the command "ZPRGA: = 1", the contents of the control system are recorded in the register of the RSA / Fig. 5/.

 In the block 77 GAW analyzes the presence of the signal "WHAT". If "WHAT = 0", the transition to block 79 GAW.

 In the block 78 of the GAW, the command “OCC: = 1” resets the contents of the ACH / Fig. 5 /, the transition to block 63 GAW.

 In the block 79 GAW analyzes the presence of the signal "CHTR", if "CHTR = 0", the transition to block 81 GAW.

 In the block 80 of the GAW, the command “CALCULATION: = 1” resets the contents of the ACH / Fig. 5 /, the transition to block 58 GAW.

 In block 81 of the GAW, the presence of the “ZAGR” signal is analyzed. If "ZAGR = 0", the transition to block 81 GAW.

 In block 82 of the GAW, the command “OSCH: = 1" resets the contents of the midrange / Fig. 2 /.

 In block 83 GAW analyzes the presence of the signal "ZAGR". If "ZAGR = 0", the transition to block 86 GAW.

 In block 84 of the GAW, the command from the input channel / FIG. 1 /, which is gated by the "SYN" signal.

 In the block 85 GAW by the command "INSC: = 1" the contents of the midrange / Fig. 2 / increases by one, the transition to block 83 GAW.

 In the block 86 of the GAW, by the command "SPG: = 1", the contents of the midrange are recorded in the WG equal to the number of characters in the received word / Fig. 1/.

 In the block 87 of the GAW, the commands “OSCH: = 1”, “OSCH: = 1” reset the contents of the midrange / Fig. 2 / NAV / Fig. 5/.

 In the block 88 GAW analyzes the sign "MORE", by which the transition to block 117 GAW.

 In the block 89 GAW analyzes the sign “LESS”, by which the transition to block 114 GAW.

 In the block 90 GAW analyzes the sign of the end of the word in the BOP "KS" / ftg. 1 /, on the basis of the transition to block 114 GAW.

 In the block 91 GAW analyzes the sign of the boundary between the words in SBP1 "HS" / Fig. 1 /, by which the transition to block 117 GAW.

 In block 92 GAW for the commands "INSCH", "INSCHA" the contents of the midrange and midrange / Fig. 2, 5 / increases by one, the transition to block 88 GAW.

 In block 93 of the GAW, the commands “OSCH”, “INSCA” reset the contents of the midrange / Fig. 2 / and increases by one the contents of the SCA / Fig. 5/.

 In the block 94 GAW analyzes the sign "LESS", by which the transition to block 118 GAW.

 In block 95 the sign “MORE” is analyzed, according to which the transition to block 114 GAW is carried out.

 In the block 96 GAW analyzes the sign of "GS", by which the transition to block 114 GAW.

 In the block 97 GAW analyzes the sign of "COP", which is the transition to block 118 GAW.

 In the block 98 GAW for the commands "INSC: = 1", "INSCA: = 1" increases by one the contents of the midrange / Fig. 2 / and NAV / Fig. 5/.

 In the block 99 GAW on the commands "OSSH", "INSCHA" the contents of the midrange are reset to zero / Fig. 2 /, increases by one the contents of the SCA / Fig. 5/.

 In the block 100 GAW analyzes the sign of the end of the array of samples in SBP1 "KM" / Fig. 5 /, on the basis of the transition to block 114.

 In block 101 GAW analyzes the sign "EQUAL" or the masked symbol "MS". If the sign is equal to zero, the transition to block 118 GAW.

 In block 102, by the commands "INSCH", "INSCA" the content of the midrange / FIG. 2 / and the contents of the SCA / Fig. 5/.

 In the block 103 GAW analyzes the sign of "GO" or "KM", on the basis of the transition to block 105 GAW.

 In the block 104 GAW analyzes the sign of "CS", on the basis of the transition to block 118 GAW, otherwise block 101 GAW.

 In the block 105 GAW analyzed the sign of "COP". If "KS = 0", the transition to block 118 GAW.

 In the block 106 GAW command "OSCH" the contents of the midrange is reset / Fig. 2 /.

 In the block 107 GAW on the commands "A1: = 1", "ZPS2: = 1" in SBP2 is recorded character from the BOP / Fig. 1/.

 In the block 108 GAW by the command "INSC: = 1" the content of the midrange increases by one / Fig. 1/.

 In block 109 of the GAW, the sign of “KS” is analyzed. If "KS = 0", the transition to block 107 GAW.

 In the block 110 GAW by the commands "A2: = 1", "ZPS2: = 1" is written the code of the boundary between the words on the stack SBP2 / Fig. fourteen/.

 In block 111, the sign “C1PN” or “C2PN” is analyzed. If the sign is zero, the transition to block 114 GAW.

 In block 112 of the GAW, the command “SHOP: = 1” resets the contents of the NW / FIG. 5 /, an external “GT” signal is issued, and a transition to the GAU block 58 is performed.

 In the block 113 GAW analyzes the presence of the signal "RSEL", which is the transition to block 71 GAW, otherwise block 6 GAW.

 In the block 114 GAW signal is issued "SIN", the transition to block 77 GAW.

 In the block 115 GAW analyzes the sign of SBP1 or SBP2 is full of "S1PNN or S2PN" / Fig. 1/. If the sign is zero, go to block 6.

 At a GAU block 116, a GT signal is issued / FIG. 1/.

 In the block 117 GAW analyzes the sign of "GS or KM", by which the transition to block 94 GAW, otherwise to block 93 GAW, from which the transition to block 117 GAW.

 In the block 118 GAW, the sign “GS or KM” is analyzed, according to which the transition to block 100 GAW is performed, otherwise to block 99 GAW, from which the transition to block 118 GAW is performed.

 The operation of the information sorting device is as follows.

 External control signals "ZAGR", "CHTPR", "WHAT", "START", "RSEL", "RESET", are sent to control unit 8, "GT", "SIN" from control unit 8. The input channel is an interface through which words arrive character by character. The output channel is an interface for issuing words.

 In sequencing mode, the main idea of the work is as follows.

 Data is streamlined as it becomes available. At the input of the sorting device, the current word is entered and written into the BOP character by character, where the symbol is a component of the word having a fixed length. The beginning of the sorted array is the first character of the smallest word / number /, the end is the last character of the largest, and the array is stored in blocks SBP1, SBP2. The indicated blocks are organized in the form of LIFO queues / last came - first left /, and the beginning of the ordered array is the first to come in SBP2, and the end is the first to come in SBP1. A search is made for the weight place of the current word in the array of already ordered data by character-by-character comparisons by the ES comparison element of the current word with the words in the array of ordered data. A weighted word is such a position of the current word in an ordered array, when the word closest to it, which is one position earlier, is less than or equal to it, and the word which is located one position later is greater than or equal to it. Search for the weight of the current word is as follows. The first character of the current word is compared by the ES comparison element with the first character of the first word from SBP1 / Fig. 1/. If the result of the comparison is equality, the second characters are compared, etc. until the result of the comparison is “MORE” or “LESS,” or one of the words does not end. Moreover, the compared characters are overwritten from SBP1 to SBP2. The result of comparing two words: if the words ended at the same time, they are equal if the signal “MORE = 1” / t was issued by the comparison element. e. the word symbol from BOP is larger than the word symbol from SBP1 /, or the word of block SBP1 has ended, but the word BOP is not - the current word located in the BOP is larger than the one examined from the ordered array. If the comparison element gives the signal "LESS = 1" / ie. the word character from BOP is less than the character from SBP1 /, or the current word has ended, and the word being studied from SBP1 is not - the current word is larger than the word studied. Further, if the current word is equal to the word studied, it is written after it in SBP2, if the current word is larger, it is compared with the next largest word studied, until the current word is equal to the next word from SBP1, SBP2, then it is written down after the next word studied, or not becomes smaller than the next one, then the current word from the BOP is written in front of it, or the end of the array is not reached, then the word from the BOP is written to the end. If the current word is less than the studied one, then it is compared with the next, the closest smaller one studied, until it becomes equal to the next, or more than it, then the word from the BOP is written to the array behind the studied word / i.e. a position closer to the end of the array /, or the beginning of the array will not be reached, when the beginning is reached, the word from the BOP is written to the array first.

 The above-described entries in the BOP, search for a weight place, and write to the stacked memory blocks storing an ordered array occur character by character, are repeated n times, where n is the number of words to be ordered. After that, the ordered information is issued to the output channel in increasing or decreasing order.

 In selection mode, the work is as follows.

 Data selection occurs from the input word stream based on the results of their comparison with the samples. At the input of the device, samples demarcated by symbols with codes 11 ... 1 are entered and written into SBP1, and first, samples are sent - the lower and upper boundaries, and then the samples are matched to equal, in which individual positions of the symbols of the sample can be masked by writing characters with codes 00 ... 0 into them.

 Next, the current word to be processed is entered and written into the BOP character-by-character at the input of the device. A comparison of the adopted word with the samples is carried out. The comparison with the first sample is performed by more, while the first character of the current word is compared with the first character of the sample, etc., until the comparison result is larger or the sample ends first, and then the word is considered larger than the sample, or the comparison result less or the word in the BOP does not end, then the word is considered less than or equal to the sample and does not satisfy the selection condition / t.k. the first sample should be the lower boundary /.

 If the word is larger than the pattern, it is compared with the second pattern by less, while the first character of the current word is compared with the first character of the pattern, etc., until the result of the comparison becomes smaller or the word ends first, and then it is considered that the word is less sample, or the result of the comparison does not become larger or the sample does not end, then the word is considered greater or equal to the sample and unsatisfying condition.

 If the word is smaller than the pattern, it is compared with the third, etc. samples until it becomes equal to the sample. An equalization on is as follows. Starting with the first characters, the word and the pattern are compared, until the result of their comparison is "equal" and they do not end simultaneously, otherwise the word and the pattern are considered not equal. In this case, the symbols are considered equal even if the symbol of the sample is equal to the special service code mask.

 If the word is equal to the pattern, it is selected, i.e. is recorded in SBP2, if it is not equal to any sample, the word is considered unsatisfying.

 Further, if the word does not satisfy the condition, the next word is again loaded into the BOP and matching, etc.

 At the end of the work, the selected words are issued in chronological or opposite order.

 Block 2 RAM contains a midrange counter, a register RG, random access memory RAM and a comparator KP / Fig. 2 /. To the inverse input of RAM, the choice of the crystal is fed by the constant "0" / not VK /. Input information I1 goes to the RAM data input. The signal "OSCH = 1" is the zeroing of the counter. By the signal "RAM = 1" the input symbol is written into RAM at the address stored in the counter. By the signal "INSC = 1" the content of the counter is increased by one. By the signal "ZPRG = 1", issued at the end of the word download, the contents of the counter, in this case equal to the number of characters of the word, are written into the register. If "ZPOZU = 0", the symbol located at the address stored in the counter is output to the output of RAM I2. The comparator KP, the inputs of which are the outputs of the register and counter, determines the sign of the end of the word "KS" with the equality of these codes.

 The comparison element 3 contains a comparator KP / Fig. 3 /, which compares the symbols I2 and IZ coming to its input and gives the signals "MORE = 1" if I2 is greater than IZ, "LESS = 1" if I2 is less than IZ and "EQUAL = 1" if I2 is equal to IZ.

 The second stack memory unit 5 comprises a stack / FIG. 4 / and is used to store part of an ordered array or selected words. By the signal "ZPS2 = 1", the I5 symbol is written to the top of the stack, by the signal "CTS2 = 1", the symbol to the I4 output is read from the top of the stack. In this case, the signals “C2PN = 1” are issued by the stack if the stack is full, and “C2PT = 1” if empty.

 The first stacked memory block 4 contains an NAV address counter, RAM random access memory, an RGA address register, a KP comparator, AND OR-NOT elements / Fig. 3 /. Information I7 is fed to the input of RAM data. According to the signal "ZPS1 = 1", which is input to the NAV and the write input to RAM, the I7 symbol is written to the RAM at the address stored in the NAV along the rising edge, the contents of which increase by one on the falling edge. According to the signal “ЧТС1 = 1”, the content of the NAV decreases by one on the falling edge, while the signal “ЗПС1 = 0” reads from the RAM the symbol FROM addressed by the contents of the NAV from the RAM. By the signal "CALCULATION = 1" the contents of the ACH are reset. By the signal "ZPRGA = 1", issued at the end of the recording of the array of samples in the selection mode, the contents of the SCA is recorded in the RGA. To the inverse input of RAM, the choice of the crystal "not VK" is supplied by the constant "O". The comparator KP compares the contents of the SCA and the DGA, the outputs of which are fed to its inputs and, if they are equal, gives the sign of the end of the array "KM = 1". Elements AND and OR DO NOT give signs, respectively, the stack is full of "C1PN" and the stack of "C1PT".

 Block 6 switching and identification contains a bus driver ShF with three states at the output, switches KM1, KM2, code generator FC, elements AND, OR-NOT / Fig. 6 /. Serves for issuing a sorted array to the output channel OUT / FIG. 1 / and switching information from various sources to the inputs of SBP1, SBP2, as well as to determine the word boundary "GS" and the masked symbol "MS" in SBP1. By the signal "RV = 1" information from the input of the IF I3 is fed to its output I6. When "PB = 0", its output is in a high impedance state. Signals A1 and A2 are sent to the address inputs KM1, I5 is its output, to which input information I3 is transmitted via "A1 = 1", "A2 = 1", A2 is transmitted through "A1 = 1", "A2 = 0", or the service code of the boundary between the words generated by the FC code generator is transmitted, the specified connection is made by "A1 = 0", "A2 = 1". The signal AO arrives at the address input KM2, I7 is its output, to which the input information I4 is transmitted if "AO = 0" or I1 if "AO = 1". The AND and OR elements do not give signals, respectively, the boundaries between the words "HS" when the I3 symbol is equal to the code 11 ... 1 and the masked symbol when the I3 is equal to the code 00 ... 0.

 The control unit 8 is synthesized based on the GAW control / Fig. 7 / in a known manner / 2 /.

Sources of information
1. Markov A.A., Nagorny N.M. Theory of Algorithms -Moscow: Science, -318 p. The main edition of the physical and mathematical literature, 1984

 2. Baranov S. I. Synthesis of microprogram automata. -Energy. Leningrad branch. 1974 -184 p.

 3. Lebedev O.N. Memory chips and their application. -Moscow: Radio and communications, 1990 -184 p.

 4. Application N 93015991 / positive decision of March 26, 94 // prototype /.

 5. A.S. USSR N 1304015 / analogue.

 6. A.S. USSR N 1594521 / analogue.

Claims (1)

 An information sorting device comprising first and second stacked memory blocks, a comparison element, a control unit, input and output channels, a random access memory unit, a switching and identification unit, wherein the first to fifth control outputs of the control unit are connected respectively from the first to fifth control inputs of the block RAM, the information input of which is connected to the input channel, the control output of the RAM block is connected to the fourth control input of the control unit, the information output b RAM lock is connected to the first information input of the comparison element and the second information input of the switching and identification unit, the first control output of the last connection to the fourteenth control input of the control unit, the first to third control inputs of the switching and identification unit are connected from the tenth to twelfth control outputs of the block, respectively control, the second information output of the switching and identification unit is connected to the output channel, the first information output of the unit switching and identification is connected to the information input of the second stacked memory block, the first and second control inputs of the latter are connected respectively to the sixth and seventh control outputs of the control unit, the first and second control outputs of the second stacked memory block are connected respectively to the tenth and eleventh control inputs of the control unit, the first and the second control inputs of the first stack memory block are connected respectively to the eighth and ninth control outputs of the control unit, the first and The control outputs of the first stacked memory block are connected respectively to the twelfth and thirteenth control inputs of the control unit, the information output of the first stacked memory block is connected to the first information input of the switching and identification unit and the second information input of the comparison element, from the first to third control outputs of the last connected respectively to the fifth to seventh control inputs of the control unit, from the first to third control inputs "ZAGR", "ChTPR", "WHAT", as well as the eighth and the control inputs “RESET” and “START” of the control unit are external inputs of the device, the thirteenth and fourteenth control outputs of “GT” and “SIN” of the control unit are external outputs of the device, characterized in that the sixteenth external control input of “RSEL” is inserted into it a control unit, from the fifteenth to seventeenth control outputs of which are connected to the third to fifth control inputs of the first stack memory block, respectively, the third control output of the latter is connected to the fifteenth control input the control unit, the eighteenth control output and the seventeenth control input of which are connected respectively to the fourth control input and the second control output of the switching and identification unit, the third information output of the latter is connected to the information input of the first stack memory unit, the third and fourth information inputs of the switching and identification unit are connected respectively, with the input channel and the information output of the second stack memory block.

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