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Results 821 - 830 of 1,073 for INPUT (0.02 sec)

  1. docs/de/docs/advanced/events.md

    ///
    
    /// tip | "Tipp"
    
    Beachten Sie, dass wir in diesem Fall eine Standard-Python-Funktion `open()` verwenden, die mit einer Datei interagiert.
    
    Es handelt sich also um I/O (Input/Output), welches „Warten“ erfordert, bis Dinge auf die Festplatte geschrieben werden.
    
    Aber `open()` verwendet nicht `async` und `await`.
    
    Registered: Sun Nov 03 07:19:11 UTC 2024
    - Last Modified: Sun Oct 06 20:36:54 UTC 2024
    - 9.1K bytes
    - Viewed (0)
  2. docs/distributed/DESIGN.md

            if cardinality <= 0 {
                    return -1
            }
            sip := siphash.New(id[:])
            sip.Write([]byte(key))
            return int(sip.Sum64() % uint64(cardinality))
    }
    ```
    
    Registered: Sun Nov 03 19:28:11 UTC 2024
    - Last Modified: Tue Aug 15 23:04:20 UTC 2023
    - 8K bytes
    - Viewed (0)
  3. docs/es/docs/async.md

    Luego, 🤖 cogerá la primera tarea finalizada (digamos, nuestro "archivo lento" 📝) y continuará con lo que tenía que hacer con esa tarea.
    
    Esa "espera de otra cosa" normalmente se refiere a operaciones <abbr title = "Input and Output, en español: Entrada y Salida.">I/O</abbr> que son relativamente "lentas" (en relación a la velocidad del procesador y memoria RAM), como por ejemplo esperar por:
    
    * los datos de cliente que se envían a través de la red
    Registered: Sun Nov 03 07:19:11 UTC 2024
    - Last Modified: Mon Aug 19 18:15:21 UTC 2024
    - 24.9K bytes
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  4. src/cmd/asm/internal/asm/asm.go

    		switch p.arch.Family {
    		case sys.MIPS, sys.MIPS64:
    			prog.From = a[0]
    			prog.Reg = p.getRegister(prog, op, &a[1])
    			prog.To = a[2]
    		case sys.Loong64:
    			switch {
    			// Loong64 atomic instructions with one input and two outputs.
    			case arch.IsLoong64AMO(op):
    				prog.From = a[0]
    				prog.To = a[1]
    				prog.RegTo2 = a[2].Reg
    			default:
    				prog.From = a[0]
    				prog.Reg = p.getRegister(prog, op, &a[1])
    Registered: Tue Nov 05 11:13:11 UTC 2024
    - Last Modified: Mon Oct 21 14:11:44 UTC 2024
    - 25.5K bytes
    - Viewed (0)
  5. gradlew

    #
    #   readarray ARGS < <( xargs -n1 <<<"$var" ) &&
    #   set -- "${ARGS[@]}" "$@"
    #
    # but POSIX shell has neither arrays nor command substitution, so instead we
    # post-process each arg (as a line of input to sed) to backslash-escape any
    # character that might be a shell metacharacter, then use eval to reverse
    # that process (while maintaining the separation between arguments), and wrap
    Registered: Fri Nov 01 11:42:11 UTC 2024
    - Last Modified: Sun Dec 24 09:00:26 UTC 2023
    - 8.5K bytes
    - Viewed (0)
  6. guava/src/com/google/common/collect/RangeMap.java

       * returned from {@link #asMapOfRanges} will be different if there were existing entries which
       * connect to the given range and value.
       *
       * <p>Even if the input range is empty, if it is connected on both sides by ranges mapped to the
       * same value those two ranges will be coalesced.
       *
       * <p><b>Note:</b> coalescing requires calling {@code .equals()} on any connected values, which
    Registered: Fri Nov 01 12:43:10 UTC 2024
    - Last Modified: Thu Feb 22 21:19:52 UTC 2024
    - 7.7K bytes
    - Viewed (0)
  7. src/test/java/org/codelibs/opensearch/extension/analysis/NGramSynonymTokenizer.java

                return false;
            }
            return true;
        }
    
        int readCharFromBuffer() throws IOException {
            if (readBufferIndex >= readBufferLen) {
                readBufferLen = input.read(readBuffer);
                if (readBufferLen == -1) {
                    return -1;
                }
                readBufferIndex = 0;
            }
            final int c = readBuffer[readBufferIndex++];
    Registered: Fri Nov 08 09:08:12 UTC 2024
    - Last Modified: Thu Feb 22 01:36:54 UTC 2024
    - 17K bytes
    - Viewed (0)
  8. cmd/admin-handlers.go

    function main() {
    	for file in $(ls -1); do
    		dest_file=$(echo "$file" | cut -d ":" -f1)
    		mv "$file" "$dest_file"
    	done
    
    	# Read content of inspect-input.txt
    	MINIO_OPTS=$(grep "Server command line args" <./inspect-input.txt | sed "s/Server command line args: //g" | sed -r "s#%s:\/\/#\.\/#g")
    
    	# Start MinIO instance using the options
    Registered: Sun Nov 03 19:28:11 UTC 2024
    - Last Modified: Fri Oct 04 11:32:32 UTC 2024
    - 99.7K bytes
    - Viewed (0)
  9. docs/de/docs/async.md

    Dann nimmt es 🤖 die erste erledigte Aufgabe (sagen wir, unsere „Langsam-Datei“ 📝) und bearbeitet sie weiter.
    
    Das „Warten auf etwas anderes“ bezieht sich normalerweise auf <abbr title="Input and Output – Eingabe und Ausgabe">I/O</abbr>-Operationen, die relativ „langsam“ sind (im Vergleich zur Geschwindigkeit des Prozessors und des Arbeitsspeichers), wie etwa das Warten darauf, dass:
    
    Registered: Sun Nov 03 07:19:11 UTC 2024
    - Last Modified: Tue Aug 06 04:48:30 UTC 2024
    - 26.6K bytes
    - Viewed (0)
  10. tensorflow/c/eager/c_api_experimental_test.cc

      TF_Operation* id = TF_FinishOperation(id_descr, status);
      ASSERT_TRUE(TF_GetCode(status) == TF_OK) << TF_Message(status);
      TF_Output input{arg, 0};
      TF_Output output{id, 0};
      TF_Function* fn =
          TF_GraphToFunction(function_graph, "ident", 0, 1, &id, 1, &input, 1,
                             &output, nullptr, nullptr, "test", status);
      ASSERT_TRUE(TF_GetCode(status) == TF_OK) << TF_Message(status);
    Registered: Tue Nov 05 12:39:12 UTC 2024
    - Last Modified: Thu Aug 03 03:14:26 UTC 2023
    - 31.5K bytes
    - Viewed (0)
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