GQE Kernel Configuration APIs¶

These APIs are software APIs that can be used to genreate configuration bits for hardware kernels listed above.

class xf::database::gqe::KernelCommand¶

#include "xf_database/kernel_command.hpp"

Overview¶

Class for generating configuration bits of gqePart , gqeJoin and gqeFilter kernels.

Methods¶

KernelCommand¶

KernelCommand ()

constructor of KernelCommand class. The kernel command used buffer is allocated on host. Some default settings are provided.

setScanColEnable¶

void setScanColEnable (
    int krn_id,
    int table_id,
    std::vector <int8_t> index
    )

scan valid cols.

Parameters:

krn_id	0 for gqeJoin, 1 for gqePart, 2 for gqeFilter.
table_id	0 for left table, 1 for right table.
index	valid input column ids.

setRowIDValidEnable¶

void setRowIDValidEnable (
    int krn_id,
    int table_id,
    bool gen_rowID_en,
    bool valid_en
    )

set gen_rowIDEnable and validEnable flag.

Parameters:

krn_id	0 for gqeJoin, 1 for gqePart, 2 for gqeFilter.
table_id	0 for left table, 1 for right table.
gen_rowID_en	enable flag for using GQE to generate row IDs internally. 1 for enable, 0 for disable.
valid_en	enable flag for getting valid bits from off-chip memory or enabing every row internally. 1 for valid bits from off-chip memory, 0 for enabling every row.

setBypassOn¶

void setBypassOn ()

set bypass on.

setBloomfilterOn¶

void setBloomfilterOn (ap_uint <35> bf_size)

set bloom-filter on.

Parameters:

bf_size

size of bloom-filter in bits, we need 35 bits to represent a range between 1 to 16 Gbits.

setDualKeyOn¶

void setDualKeyOn ()

set dual key on.

setJoinType¶

void setJoinType (int jointype)

set join type.

Parameters:

jointype

Join type, default is INNER_JOIN.

setJoinWriteColEnable¶

void setJoinWriteColEnable (
    int krn_id,
    int table_id,
    std::vector <int8_t> index
    )

enables output columns for gqeJoin/Filter.

Parameters:

krn_id	0 for gqeJoin, 1 for gqePart, 2 for gqeFilter.
table_id	0 for left table, 1 for right table.
index	output column ids.

setPartWriteColEnable¶

void setPartWriteColEnable (
    int krn_id,
    int table_id,
    std::vector <int8_t> index
    )

enables output columns for gqePart.

Parameters:

krn_id	0 for gqeJoin, 1 for gqePart, 2 for gqeFilter
table_id	0 for left table, 1 for right table
index	output column ids

setFilter¶

void setFilter (
    int table_id,
    std::string filter_string
    )

set Filter string.

The string uses a , b , c , d to refer to first to the fourth column, and supports comparison and logical operator like C++. Parentheses can be used to group logic, but notice that the underlying hardware module does not support comparing one column with multiple constant boundaries in OR relationship. Integral constants will be extracted from expression.

For example, an expression could be (a < 10 && b < 20) || (c >= d) .

Parameters:

table_id	0 for left table, 1 for right table
filter_string	filter expression string

getConfigBits¶

ap_uint <512>* getConfigBits () const

return config bit array.

class xf::database::gqe::AggrCommand¶

#include "xf_database/aggr_command.hpp"

Overview¶

Class for generating configuration bits of gqeAggr kernel.

Methods¶

AggrCommand¶

AggrCommand ()

construct of AggrCommand .

The aggregate command used buffer is allocated on host. Some default settings are provided.

Scan¶

void Scan (std::vector <int8_t> index)

scan valid cols and shuffle for evaluation 1.

Parameters:

index

input valid column ids

setEvaluation¶

setEvaluation overload (1)¶

void setEvaluation (
    int eval_id,
    std::string s0,
    std::vector <int32_t> index,
    int post_div = nosf
    )

set Evaluation string.

Parameters:

eval_id	most support two evaluations
s0	evaluation string for special strm format (not support ‘/’)
index	evaluation constants for each strm, default 0
post_div	post division alu operation, nosf for no division, sf10 for “a/10”, sf100 for “a/100”, sf1k for “a/1000”, sf10k for “a/10000” (a is result of evaluation expression)

setEvaluation overload (2)¶

void setEvaluation (
    int eval_id,
    std::string eval_str
    )

set Evaluation string.

Parameters:

eval_id	most two evaluations
eval_str	evaluation expression string

setFilter¶

setFilter overload (1)¶

void setFilter (std::string filter_string)

set Filter string.

The string uses a , b , c , d to refer to first to the fourth column, and supports comparison and logical operator like C++. Parentheses can be used to group logic, but notice that the underlying hardware module does not support comparing one column with multiple constant boundaries in OR relationship. Integral constants will be extracted from expression.

For example, an expression could be (a < 10 && b < 20) || (c >= d) .

Parameters:

filter_string

filter expression string

setShuffle0¶

void setShuffle0 (std::vector <int8_t> index)

set shuffle0 column ids.

Parameters:

index

shuffle0 key list,move evaluation keys to first 4 locations

setShuffle1¶

void setShuffle1 (std::vector <int8_t> index)

set shuffle1 column ids.

Parameters:

index

shuffle1 key list,move filter keys to first 4 locations

setShuffle2¶

void setShuffle2 (std::vector <int8_t> index)

set shuffle2 column ids.

Parameters:

index

set column indexes of keys

setShuffle3¶

void setShuffle3 (std::vector <int8_t> index)

set shuffle3 column ids.

Parameters:

index

set column indexes of payloads

setGroupAggr¶

void setGroupAggr (
    int ind,
    ap_uint <4> aggr_op
    )

set Group Aggregation type of setting index

Parameters:

ind	set index of column
aggr_op	Aggregation type of setting index

setGroupAggrs¶

void setGroupAggrs (std::vector <ap_uint <4>> index)

set Group Aggregation types

Parameters:

index

list of Aggregation types, starting from the first column, align with columns in shuffle3

setMerge¶

void setMerge (
    int m_id,
    std::vector <uint8_t> index
    )

set Merge column index in setting round of merge

merge flow : four list : key, count, aggr_l and aggr_h, each one has size 8 key is aligned with shuffle2, count, aggr_l and aggr_h are aligned with shuffle3 and setGroupAggr merge 0,1,2 merge key into the other three merge 3,4 merge count pld into other two

Parameters:

m_id	round id of column merge
index	merge colum list in current round

columnMerge¶

void columnMerge (std::vector <ap_uint <4>> index)

set Merge codes in each round of merge

merge flow : four list : key, count, aggr_h, aggr_l (each one has size 8) key is aligned with shuffle2, count, aggr_h and aggr_l are aligned with shuffle3 and setGroupAggr merge 0,1,2 merge key into the other three merge 3,4 merge count pld into other two

Parameters:

index

coded merging indexes

setDirectAggrs¶

void setDirectAggrs (std::vector <uint8_t> index)

set demux direct aggregations

Parameters:

index

columns of using direct aggregations

setWriteCol¶

void setWriteCol (std::vector <int8_t> index)

set output column ids.

Parameters:

index

output column ids

getConfigBits¶

ap_uint <W>* getConfigBits () const

return config bit array.

getConfigOutBits¶

ap_uint <W>* getConfigOutBits ()

return config out bit array.