# Configure **Concrete** can be customized using `Configuration`s: ```python from concrete import fhe import numpy as np configuration = fhe.Configuration(p_error=0.01, dataflow_parallelize=True) @fhe.compiler({"x": "encrypted"}) def f(x): return x + 42 inputset = range(10) circuit = f.compile(inputset, configuration=configuration) ``` You can overwrite individual options as kwargs to the `compile` method: ```python from concrete import fhe import numpy as np @fhe.compiler({"x": "encrypted"}) def f(x): return x + 42 inputset = range(10) circuit = f.compile(inputset, p_error=0.01, dataflow_parallelize=True) ``` Or you can combine both: ```python from concrete import fhe import numpy as np configuration = fhe.Configuration(p_error=0.01) @fhe.compiler({"x": "encrypted"}) def f(x): return x + 42 inputset = range(10) circuit = f.compile(inputset, configuration=configuration, loop_parallelize=True) ``` {% hint style="info" %} Additional kwargs to `compile` functions take higher precedence. So if you set the option in both `configuration` and `compile` methods, the value in the `compile` method will be used. {% endhint %} ## Options * **show\_graph**: Optional\[bool] = None * Print computation graph during compilation. `True` means always print, `False` means never print, `None` means print depending on verbose configuration below. * **show\_mlir**: Optional\[bool] = None * Print MLIR during compilation. `True` means always print, `False` means never print, `None` means print depending on verbose configuration below. * **show\_optimizer**: Optional\[bool] = None * Print optimizer output during compilation. `True` means always print, `False` means never print, `None` means print depending on verbose configuration below. * **show\_statistics**: Optional\[bool] = None * Print circuit statistics during compilation. `True` means always print, `False` means never print, `None` means print depending on verbose configuration below. * **verbose**: bool = False * Print details related to compilation. * **dump\_artifacts\_on\_unexpected\_failures**: bool = True * Export debugging artifacts automatically on compilation failures. * **auto\_adjust\_rounders**: bool = False * Adjust rounders automatically. * **p\_error**: Optional\[float] = None * Error probability for individual table lookups. If set, all table lookups will have the probability of a non-exact result smaller than the set value. See [Exactness](../core-features/table\_lookups.md#table-lookup-exactness) to learn more. * **global\_p\_error**: Optional\[float] = None * Global error probability for the whole circuit. If set, the whole circuit will have the probability of a non-exact result smaller than the set value. See [Exactness](../core-features/table\_lookups.md#table-lookup-exactness) to learn more. * **single\_precision**: bool = False * Use single precision for the whole circuit. * **parameter\_selection\_strategy**: (fhe.ParameterSelectionStrategy) = fhe.ParameterSelectionStrategy.MULTI * Set how cryptographic parameters are selected. * **multi\_parameter\_strategy**: fhe.MultiParameterStrategy = fhe.MultiParameterStrategy.PRECISION * Set the level of circuit partionning when using `fhe.ParameterSelectionStrategy.MULTI`. * `PRECISION`: all TLU with same input precision have their own parameters. * `PRECISION_AND_NORM2`: all TLU with same input precision and output [norm2](../../compilers/concrete-optimizer/v0-parameters/) have their own parameters. * **loop\_parallelize**: bool = True * Enable loop parallelization in the compiler. * **dataflow\_parallelize**: bool = False * Enable dataflow parallelization in the compiler. * **auto\_parallelize**: bool = False * Enable auto parallelization in the compiler. * **enable\_unsafe\_features**: bool = False * Enable unsafe features. * **use\_insecure\_key\_cache**: bool = False _(Unsafe)_ * Use the insecure key cache. * **insecure\_key\_cache\_location**: Optional\[Union\[Path, str]] = None * Location of insecure key cache. * **show\_progress**: bool = False, * Display a progress bar during circuit execution * **progress\_title**: str = "", * Title of the progress bar * **progress\_tag**: Union\[bool, int] = False, * How many nested tag elements to display with the progress bar. `True` means all tag elements and `False` disables the display. `2` will display `elmt1.elmt2` * **fhe\_simulation**: bool = False * Enable FHE simulation. Can be enabled later using `circuit.enable_fhe_simulation()`. * **fhe\_execution**: bool = True * Enable FHE execution. Can be enabled later using `circuit.enable_fhe_execution()`. * **compiler\_debug\_mode**: bool = False, * Enable/disable debug mode of the compiler. This can show a lot of information, including passes and pattern rewrites. * **compiler\_verbose\_mode**: bool = False, * Enable/disable verbose mode of the compiler. This mainly shows logs from the compiler, and is less verbose than the debug mode. * **comparison\_strategy\_preference**: Optional\[Union\[ComparisonStrategy, str, List\[Union\[ComparisonStrategy, str]]]] = None * Specify preference for comparison strategies, can be a single strategy or an ordered list of strategies. See [Comparisons](../core-features/comparisons.md) to learn more. * **bitwise\_strategy\_preference**: Optional\[Union\[BitwiseStrategy, str, List\[Union\[BitwiseStrategy, str]]]] = None * Specify preference for bitwise strategies, can be a single strategy or an ordered list of strategies. See [Bitwise](../core-features/bitwise.md) to learn more. * **shifts\_with\_promotion**: bool = True, * Enable promotions in encrypted shifts instead of casting in runtime. See [Bitwise#Shifts](../core-features/bitwise.md#Shifts) to learn more. * **composable**: bool = False, * Specify that the function must be composable with itself. * **relu\_on\_bits\_threshold**: int = 7, * Bit-width to start implementing the ReLU extension with [fhe.bits](../core-features/bit\_extraction.md). * **relu\_on\_bits\_chunk\_size**: int = 3, * Chunk size of the ReLU extension when [fhe.bits](../core-features/bit\_extraction.md) implementation is used. * **if\_then\_else\_chunk\_size**: int = 3 * Chunk size to use when converting `fhe.if_then_else` extension. * **rounding\_exactness** : Exactness = `fhe.Exactness.EXACT` * Set default exactness mode for the rounding operation: * `EXACT`: threshold for rounding up or down is exactly centered between upper and lower value, * `APPROXIMATE`: faster but threshold for rounding up or down is approximately centered with pseudo-random shift. * Precise and more complete behavior is described in [fhe.rounding\_bit\_pattern](../core-features/rounding.md). * **approximate\_rounding\_config** : ApproximateRoundingConfig = `fhe.ApproximateRoundingConfig()`: * Provide more fine control on [approximate rounding](../core-features/rounding.md#approximate-rounding-features): * to enable exact cliping, * or/and approximate clipping which make overflow protection faster.