/* SPDX-License-Identifier: BSD-3-Clause */ /* Copyright(c) 2007-2022 Intel Corporation */ /** *************************************************************************** * @file lac_mem.h * * @defgroup LacMem Memory * * @ingroup LacCommon * * Memory re-sizing functions and memory accessor macros. * ***************************************************************************/ #ifndef LAC_MEM_H #define LAC_MEM_H /*************************************************************************** * Include header files ***************************************************************************/ #include "cpa.h" #include "qat_utils.h" #include "lac_common.h" /** ******************************************************************************* * @ingroup LacMem * These macros are used to Endian swap variables from IA to QAT. * * @param[out] x The variable to be swapped. * * @retval none ******************************************************************************/ #if (BYTE_ORDER == LITTLE_ENDIAN) #define LAC_MEM_WR_64(x) QAT_UTILS_HOST_TO_NW_64(x) #define LAC_MEM_WR_32(x) QAT_UTILS_HOST_TO_NW_32(x) #define LAC_MEM_WR_16(x) QAT_UTILS_HOST_TO_NW_16(x) #define LAC_MEM_RD_64(x) QAT_UTILS_NW_TO_HOST_64(x) #define LAC_MEM_RD_32(x) QAT_UTILS_NW_TO_HOST_32(x) #define LAC_MEM_RD_16(x) QAT_UTILS_NW_TO_HOST_16(x) #else #define LAC_MEM_WR_64(x) (x) #define LAC_MEM_WR_32(x) (x) #define LAC_MEM_WR_16(x) (x) #define LAC_MEM_RD_64(x) (x) #define LAC_MEM_RD_32(x) (x) #define LAC_MEM_RD_16(x) (x) #endif /* ******************************************************************************* * Shared Memory Macros (memory accessible by Acceleration Engines, e.g. QAT) ******************************************************************************* */ /** ******************************************************************************* * @ingroup LacMem * This macro can be used to write to a variable that will be read by the * QAT. The macro will automatically detect the size of the target variable and * will select the correct method for performing the write. The data is cast to * the type of the field that it will be written to. * This macro swaps data if required. * * @param[out] var The variable to be written. Can be a field of a struct. * * @param[in] data The value to be written. Will be cast to the size of the * target. * * @retval none ******************************************************************************/ #define LAC_MEM_SHARED_WRITE_SWAP(var, data) \ do { \ switch (sizeof(var)) { \ case 1: \ (var) = (Cpa8U)(data); \ break; \ case 2: \ (var) = (Cpa16U)(data); \ (var) = LAC_MEM_WR_16(((Cpa16U)var)); \ break; \ case 4: \ (var) = (Cpa32U)(data); \ (var) = LAC_MEM_WR_32(((Cpa32U)var)); \ break; \ case 8: \ (var) = (Cpa64U)(data); \ (var) = LAC_MEM_WR_64(((Cpa64U)var)); \ break; \ default: \ break; \ } \ } while (0) /** ******************************************************************************* * @ingroup LacMem * This macro can be used to read a variable that was written by the QAT. * The macro will automatically detect the size of the data to be read and will * select the correct method for performing the read. The value read from the * variable is cast to the size of the data type it will be stored in. * This macro swaps data if required. * * @param[in] var The variable to be read. Can be a field of a struct. * * @param[out] data The variable to hold the result of the read. Data read * will be cast to the size of this variable * * @retval none ******************************************************************************/ #define LAC_MEM_SHARED_READ_SWAP(var, data) \ do { \ switch (sizeof(var)) { \ case 1: \ (data) = (var); \ break; \ case 2: \ (data) = LAC_MEM_RD_16(((Cpa16U)var)); \ break; \ case 4: \ (data) = LAC_MEM_RD_32(((Cpa32U)var)); \ break; \ case 8: \ (data) = LAC_MEM_RD_64(((Cpa64U)var)); \ break; \ default: \ break; \ } \ } while (0) /** ******************************************************************************* * @ingroup LacMem * This macro can be used to write a pointer to a QAT request. The fields * for pointers in the QAT request and response messages are always 64 bits * * @param[out] var The variable to be written to. Can be a field of a struct. * * @param[in] data The value to be written. Will be cast to size of target * variable * * @retval none ******************************************************************************/ /* cast pointer to scalar of same size of the native pointer */ #define LAC_MEM_SHARED_WRITE_FROM_PTR(var, data) \ ((var) = (Cpa64U)(LAC_ARCH_UINT)(data)) /* Note: any changes to this macro implementation should also be made to the * similar LAC_MEM_CAST_PTR_TO_UINT64 macro */ /** ******************************************************************************* * @ingroup LacMem * This macro can be used to read a pointer from a QAT response. The fields * for pointers in the QAT request and response messages are always 64 bits * * @param[in] var The variable to be read. Can be a field of a struct. * * @param[out] data The variable to hold the result of the read. Data read * will be cast to the size of this variable * * @retval none ******************************************************************************/ /* Cast back to native pointer */ #define LAC_MEM_SHARED_READ_TO_PTR(var, data) \ ((data) = (void *)(LAC_ARCH_UINT)(var)) /** ******************************************************************************* * @ingroup LacMem * This macro safely casts a pointer to a Cpa64U type. * * @param[in] pPtr The pointer to be cast. * * @retval pointer cast to Cpa64U ******************************************************************************/ #define LAC_MEM_CAST_PTR_TO_UINT64(pPtr) ((Cpa64U)(pPtr)) /** ******************************************************************************* * @ingroup LacMem * This macro uses an QAT Utils macro to convert from a virtual address to *a * physical address for internally allocated memory. * * @param[in] pVirtAddr The address to be converted. * * @retval The converted physical address ******************************************************************************/ #define LAC_OS_VIRT_TO_PHYS_INTERNAL(pVirtAddr) \ (QAT_UTILS_MMU_VIRT_TO_PHYS(pVirtAddr)) /** ******************************************************************************* * @ingroup LacMem * This macro should be called on all externally allocated memory it calls * SalMem_virt2PhysExternal function which allows a user * to set the virt2phys function used by an instance. * Defaults to virt to phys for kernel. * * @param[in] genService Generic sal_service_t structure. * @param[in] pVirtAddr The address to be converted. * * @retval The converted physical address ******************************************************************************/ #define LAC_OS_VIRT_TO_PHYS_EXTERNAL(genService, pVirtAddr) \ ((SalMem_virt2PhysExternal(pVirtAddr, &(genService)))) /** ******************************************************************************* * @ingroup LacMem * This macro can be used to write an address variable that will be read by * the QAT. The macro will perform the necessary virt2phys address translation * This macro is only to be called on memory allocated internally by the driver. * * @param[out] var The address variable to write. Can be a field of a struct. * * @param[in] pPtr The pointer variable to containing the address to be * written * * @retval none ******************************************************************************/ #define LAC_MEM_SHARED_WRITE_VIRT_TO_PHYS_PTR_INTERNAL(var, pPtr) \ do { \ Cpa64U physAddr = 0; \ physAddr = LAC_MEM_CAST_PTR_TO_UINT64( \ LAC_OS_VIRT_TO_PHYS_INTERNAL(pPtr)); \ var = physAddr; \ } while (0) /** ******************************************************************************* * @ingroup LacMem * This macro can be used to write an address variable that will be read by * the QAT. The macro will perform the necessary virt2phys address translation * This macro is to be used on memory allocated externally by the user. It calls * the user supplied virt2phys address translation. * * @param[in] pService The pointer to the service * @param[out] var The address variable to write. Can be a field of a struct * @param[in] pPtr The pointer variable to containing the address to be * written * * @retval none ******************************************************************************/ #define LAC_MEM_SHARED_WRITE_VIRT_TO_PHYS_PTR_EXTERNAL(pService, var, pPtr) \ do { \ Cpa64U physAddr = 0; \ physAddr = LAC_MEM_CAST_PTR_TO_UINT64( \ LAC_OS_VIRT_TO_PHYS_EXTERNAL(pService, pPtr)); \ var = physAddr; \ } while (0) /* ******************************************************************************* * OS Memory Macros ******************************************************************************* */ /** ******************************************************************************* * @ingroup LacMem * This function and associated macro allocates the memory for the given * size and stores the address of the memory allocated in the pointer. * * @param[out] ppMemAddr address of pointer where address will be stored * @param[in] sizeBytes the size of the memory to be allocated. * * @retval CPA_STATUS_RESOURCE Macro failed to allocate Memory * @retval CPA_STATUS_SUCCESS Macro executed successfully * ******************************************************************************/ static __inline CpaStatus LacMem_OsMemAlloc(void **ppMemAddr, Cpa32U sizeBytes) { *ppMemAddr = malloc(sizeBytes, M_QAT, M_WAITOK); return CPA_STATUS_SUCCESS; } /** ******************************************************************************* * @ingroup LacMem * This function and associated macro allocates the contiguous * memory for the given * size and stores the address of the memory allocated in the pointer. * * @param[out] ppMemAddr address of pointer where address will be stored * @param[in] sizeBytes the size of the memory to be allocated. * @param[in] alignmentBytes the alignment * @param[in] node node to allocate from * * @retval CPA_STATUS_RESOURCE Macro failed to allocate Memory * @retval CPA_STATUS_SUCCESS Macro executed successfully * ******************************************************************************/ static __inline CpaStatus LacMem_OsContigAlignMemAlloc(void **ppMemAddr, Cpa32U sizeBytes, Cpa32U alignmentBytes, Cpa32U node) { if ((alignmentBytes & (alignmentBytes - 1)) != 0) /* if is not power of 2 */ { *ppMemAddr = NULL; QAT_UTILS_LOG("alignmentBytes MUST be the power of 2\n"); return CPA_STATUS_INVALID_PARAM; } *ppMemAddr = qatUtilsMemAllocContiguousNUMA(sizeBytes, node, alignmentBytes); if (NULL == *ppMemAddr) { return CPA_STATUS_RESOURCE; } return CPA_STATUS_SUCCESS; } /** ******************************************************************************* * @ingroup LacMem * Macro from the malloc() function * ******************************************************************************/ #define LAC_OS_MALLOC(sizeBytes) malloc(sizeBytes, M_QAT, M_WAITOK) /** ******************************************************************************* * @ingroup LacMem * Macro from the LacMem_OsContigAlignMemAlloc function * ******************************************************************************/ #define LAC_OS_CAMALLOC(ppMemAddr, sizeBytes, alignmentBytes, node) \ LacMem_OsContigAlignMemAlloc((void *)ppMemAddr, \ sizeBytes, \ alignmentBytes, \ node) /** ******************************************************************************* * @ingroup LacMem * Macro for declaration static const unsigned int constant. One provides * the compilation time computation with the highest bit set in the * sizeof(TYPE) value. The constant is being put by the linker by default in * .rodata section * * E.g. Statement LAC_DECLARE_HIGHEST_BIT_OF(lac_mem_blk_t) * results in following entry: * static const unsigned int highest_bit_of_lac_mem_blk_t = 3 * * CAUTION!! * Macro is prepared only for type names NOT-containing ANY * special characters. Types as amongst others: * - void * * - unsigned long * - unsigned int * are strictly forbidden and will result in compilation error. * Use typedef to provide one-word type name for MACRO's usage. ******************************************************************************/ #define LAC_DECLARE_HIGHEST_BIT_OF(TYPE) \ static const unsigned int highest_bit_of_##TYPE = \ (sizeof(TYPE) & 0x80000000 ? 31 : (sizeof(TYPE) & 0x40000000 ? 30 : (sizeof(TYPE) & 0x20000000 ? 29 : ( \ sizeof(TYPE) & 0x10000000 ? 28 : ( \ sizeof(TYPE) & 0x08000000 ? 27 : ( \ sizeof(TYPE) & 0x04000000 ? 26 : ( \ sizeof(TYPE) & 0x02000000 ? 25 : ( \ sizeof(TYPE) & 0x01000000 ? 24 : ( \ sizeof(TYPE) & 0x00800000 ? \ 23 : \ (sizeof(TYPE) & 0x00400000 ? 22 : ( \ sizeof( \ TYPE) & \ 0x00200000 ? \ 21 : \ ( \ sizeof(TYPE) & 0x00100000 ? 20 : (sizeof(TYPE) & 0x00080000 ? 19 : ( \ sizeof( \ TYPE) & \ 0x00040000 ? \ 18 : \ ( \ sizeof(TYPE) & 0x00020000 ? 17 : ( \ sizeof(TYPE) & 0x00010000 ? 16 : (sizeof(TYPE) & \ 0x00008000 ? \ 15 : \ (sizeof(TYPE) & 0x00004000 ? 14 : ( \ sizeof(TYPE) & 0x00002000 ? 13 : \ ( \ sizeof(TYPE) & 0x00001000 ? 12 : ( \ sizeof(TYPE) & 0x00000800 ? 11 : ( \ sizeof(TYPE) & 0x00000400 ? 10 : \ ( \ sizeof(TYPE) & \ 0x00000200 ? \ 9 : \ (sizeof( \ TYPE) & \ 0x00000100 ? \ 8 : \ (sizeof(TYPE) & 0x00000080 ? 7 : \ ( \ sizeof(TYPE) & 0x00000040 ? \ 6 : \ ( \ sizeof(TYPE) & 0x00000020 ? 5 : \ ( \ sizeof(TYPE) & 0x00000010 ? 4 : \ ( \ sizeof(TYPE) & 0x00000008 ? 3 : \ ( \ sizeof(TYPE) & 0x00000004 ? 2 : \ ( \ sizeof(TYPE) & 0x00000002 ? 1 : ( \ sizeof(TYPE) & 0x00000001 ? 0 : 32))))))))))))))))) /*16*/))))))))))))))) /* 31 */ /** ******************************************************************************* * @ingroup LacMem * This function and associated macro frees the memory at the given address * and resets the pointer to NULL * * @param[out] ppMemAddr address of pointer where mem address is stored. * If pointer is NULL, the function will exit silently * * @retval void * ******************************************************************************/ static __inline void LacMem_OsMemFree(void **ppMemAddr) { free(*ppMemAddr, M_QAT); *ppMemAddr = NULL; } /** ******************************************************************************* * @ingroup LacMem * This function and associated macro frees the contiguous memory at the * given address and resets the pointer to NULL * * @param[out] ppMemAddr address of pointer where mem address is stored. * If pointer is NULL, the function will exit silently * * @retval void * ******************************************************************************/ static __inline void LacMem_OsContigAlignMemFree(void **ppMemAddr) { if (NULL != *ppMemAddr) { qatUtilsMemFreeNUMA(*ppMemAddr); *ppMemAddr = NULL; } } #define LAC_OS_FREE(pMemAddr) LacMem_OsMemFree((void *)&pMemAddr) #define LAC_OS_CAFREE(pMemAddr) LacMem_OsContigAlignMemFree((void *)&pMemAddr) /** ******************************************************************************* * @ingroup LacMem * Copies user data to a working buffer of the correct size (required by * PKE services) * * @description * This function produces a correctly sized working buffer from the input * user buffer. If the original buffer is too small a new buffer shall * be allocated and memory is copied (left padded with zeros to the *required * length). * * The returned working buffer is guaranteed to be of the desired size for * QAT. * * When this function is called pInternalMem describes the user_buffer and * when the function returns pInternalMem describes the working buffer. * This is because pInternalMem describes the memory that will be sent to * QAT. * * The caller must keep the original buffer pointer. The alllocated buffer *is * freed (as necessary) using icp_LacBufferRestore(). * * @param[in] instanceHandle Handle to crypto instance so pke_resize mem pool *can * be located * @param[in] pUserBuffer Pointer on the user buffer * @param[in] userLen length of the user buffer * @param[in] workingLen length of the working (correctly sized) buffer * @param[in/out] pInternalMem pointer to boolean if TRUE on input then * user_buffer is internally allocated memory * if false then it is externally allocated. * This value gets updated by the function * if the returned pointer references internally * allocated memory. * * @return a pointer to the working (correctly sized) buffer or NULL if the * allocation failed * * @note the working length cannot be smaller than the user buffer length * * @warning the working buffer may be the same or different from the original * user buffer; the caller should make no assumptions in this regard * * @see icp_LacBufferRestore() * ******************************************************************************/ Cpa8U *icp_LacBufferResize(CpaInstanceHandle instanceHandle, Cpa8U *pUserBuffer, Cpa32U userLen, Cpa32U workingLen, CpaBoolean *pInternalMemory); /** ******************************************************************************* * @ingroup LacMem * Restores a user buffer * * @description * This function restores a user buffer and releases its * corresponding working buffer. The working buffer, assumed to be * previously obtained using icp_LacBufferResize(), is freed as necessary. * * The contents are copied in the process. * * @note the working length cannot be smaller than the user buffer length * * @param[out] pUserBuffer Pointer on the user buffer * @param[in] userLen length of the user buffer * @param[in] pWorkingBuffer Pointer on the working buffer * @param[in] workingLen working buffer length * @param[in] copyBuf if set _TRUE the data in the workingBuffer * will be copied to the userBuffer before the * workingBuffer is freed. * * @return the status of the operation * * @see icp_LacBufferResize() * ******************************************************************************/ CpaStatus icp_LacBufferRestore(Cpa8U *pUserBuffer, Cpa32U userLen, Cpa8U *pWorkingBuffer, Cpa32U workingLen, CpaBoolean copyBuf); /** ******************************************************************************* * @ingroup LacMem * Uses an instance specific user supplied virt2phys function to convert a * virtual address to a physical address. * * @description * Uses an instance specific user supplied virt2phys function to convert a * virtual address to a physical address. A client of QA API can set the * virt2phys function for an instance by using the * cpaXxSetAddressTranslation() function. If the client does not set the * virt2phys function and the instance is in kernel space then OS specific * virt2phys function will be used. In user space the virt2phys function * MUST be set by the user. * * @param[in] pVirtAddr the virtual addr to be converted * @param[in] pServiceGen Pointer on the sal_service_t structure * so client supplied virt2phys function can be * called. * * @return the physical address * ******************************************************************************/ CpaPhysicalAddr SalMem_virt2PhysExternal(void *pVirtAddr, void *pServiceGen); #endif /* LAC_MEM_H */