#include <aclnnop/aclnn_mean.h>
#include <aclnnop/aclnn_mm.h>
#include <aclnnop/aclnn_mul.h>
+#include <aclnnop/aclnn_mv.h>
#include <aclnnop/aclnn_permute.h>
#include <aclnnop/aclnn_pow.h>
#include <aclnnop/aclnn_pow_tensor_tensor.h>
// Step1.2: prepare rope_yarn_ramp, if this part updated, should update theta_scale_tensor.
// TODO: acl_yarn_ramp_tensor use rope cache.
- bool yarn_ramp_tensor_updated = false;
- acl_tensor_ptr acl_yarn_ramp_tensor;
+ bool yarn_ramp_tensor_updated = false;
+ acl_tensor_ptr acl_yarn_ramp_tensor;
if (ext_factor != 0 && (theta_scale_updated || ctx.rope_cache.theta_scale_length != theta_scale_length ||
ctx.rope_cache.freq_scale != freq_scale)) {
yarn_ramp_tensor_updated = true;
if (ctx.rope_cache.yarn_ramp_cache != nullptr) {
ACL_CHECK(aclrtFree(ctx.rope_cache.yarn_ramp_cache));
}
- ACL_CHECK(aclrtMalloc(&ctx.rope_cache.yarn_ramp_cache, theta_scale_length * sizeof(float), ACL_MEM_MALLOC_HUGE_FIRST));
+ ACL_CHECK(aclrtMalloc(&ctx.rope_cache.yarn_ramp_cache, theta_scale_length * sizeof(float),
+ ACL_MEM_MALLOC_HUGE_FIRST));
// -rope_yarn_ramp
// const float y = (i0 / 2 - low) / MAX(0.001f, high - low);
// return MIN(1, MAX(0, y)) - 1;
- acl_yarn_ramp_tensor =
- ggml_cann_create_tensor(ctx.rope_cache.yarn_ramp_cache, ACL_FLOAT, sizeof(float), theta_scale_ne, theta_scale_nb, 1);
+ acl_yarn_ramp_tensor = ggml_cann_create_tensor(ctx.rope_cache.yarn_ramp_cache, ACL_FLOAT, sizeof(float),
+ theta_scale_ne, theta_scale_nb, 1);
float zero_value = 0, one_value = 1;
float denom_safe_value = MAX(0.001f, corr_dims[1] - corr_dims[0]);
acl_scalar_ptr low = ggml_cann_create_scalar(&corr_dims[0], aclDataType::ACL_FLOAT);
GGML_CANN_CALL_ACLNN_OP(ctx, InplaceMuls, acl_yarn_ramp_tensor.get(), freq_scale_1_sc.get());
GGML_CANN_CALL_ACLNN_OP(ctx, InplaceAdds, acl_yarn_ramp_tensor.get(), freq_scale_sc.get(), one.get());
} else {
- acl_yarn_ramp_tensor =
- ggml_cann_create_tensor(ctx.rope_cache.yarn_ramp_cache, ACL_FLOAT, sizeof(float), theta_scale_ne, theta_scale_nb, 1);
+ acl_yarn_ramp_tensor = ggml_cann_create_tensor(ctx.rope_cache.yarn_ramp_cache, ACL_FLOAT, sizeof(float),
+ theta_scale_ne, theta_scale_nb, 1);
}
// Step 1.3: update theta_scale_tensor according to ext_factor or freq_scale.
if (ext_factor != 0) {
GGML_CANN_CALL_ACLNN_OP(ctx, ArgMax, acl_src.get(), 3, false, acl_dst.get());
}
-void ggml_cann_conv_transpose_1d(ggml_backend_cann_context& ctx, ggml_tensor* dst){
+void ggml_cann_conv_transpose_1d(ggml_backend_cann_context & ctx, ggml_tensor * dst) {
ggml_tensor * src0 = dst->src[0];
ggml_tensor * src1 = dst->src[1];
// stride
- int64_t s0 = ((const int32_t*)(dst->op_params))[0];
+ int64_t s0 = ((const int32_t *) (dst->op_params))[0];
- acl_tensor_ptr acl_input = ggml_cann_create_tensor(src1, src1->ne, src1->nb, 3, ACL_FORMAT_NCL);
+ acl_tensor_ptr acl_input = ggml_cann_create_tensor(src1, src1->ne, src1->nb, 3, ACL_FORMAT_NCL);
acl_tensor_ptr acl_weight = ggml_cann_create_tensor(src0, src0->ne, src0->nb, 3, ACL_FORMAT_NCL);
- acl_tensor_ptr acl_dst = ggml_cann_create_tensor(dst, dst->ne, dst->nb, 3, ACL_FORMAT_NCL);
+ acl_tensor_ptr acl_dst = ggml_cann_create_tensor(dst, dst->ne, dst->nb, 3, ACL_FORMAT_NCL);
// get base information of input and kernel
- int64_t input_len = *(src1->ne);
- int64_t dst_len = *(dst->ne);
+ int64_t input_len = *(src1->ne);
+ int64_t dst_len = *(dst->ne);
int64_t kernel_size = *(src0->ne);
// set the max kernel size for each conv
// compute the partition of kernel
int64_t part_num = 1;
- part_num = (kernel_size + max_kernel_size - 1) / max_kernel_size;
+ part_num = (kernel_size + max_kernel_size - 1) / max_kernel_size;
int64_t strideVal[1];
- strideVal[0] = s0;
- acl_int_array_ptr stride = ggml_cann_create_int_array(strideVal, 1);
- int64_t paddingVal[] = {0};
- acl_int_array_ptr padding = ggml_cann_create_int_array(paddingVal, 1);
- int64_t dilationVal[] = {1};
- acl_int_array_ptr dilation = ggml_cann_create_int_array(dilationVal, 1);
- bool transposed = true;
- int64_t groups = 1;
- int8_t cubeMathType = 0;
+ strideVal[0] = s0;
+ acl_int_array_ptr stride = ggml_cann_create_int_array(strideVal, 1);
+ int64_t paddingVal[] = { 0 };
+ acl_int_array_ptr padding = ggml_cann_create_int_array(paddingVal, 1);
+ int64_t dilationVal[] = { 1 };
+ acl_int_array_ptr dilation = ggml_cann_create_int_array(dilationVal, 1);
+ bool transposed = true;
+ int64_t groups = 1;
+ int8_t cubeMathType = 0;
#ifdef ASCEND_310P
cubeMathType = 1;
#endif
auto weight_type = ggml_cann_type_mapping(src0->type);
- auto dst_type = ggml_cann_type_mapping(dst->type);
+ auto dst_type = ggml_cann_type_mapping(dst->type);
// slice the kernel to make each conv available
- int64_t slice_dim = -1;
+ int64_t slice_dim = -1;
int64_t slice_start = 0;
- int64_t slice_end = max_kernel_size;
- int64_t slice_step = 1;
- int64_t interval = max_kernel_size;
+ int64_t slice_end = max_kernel_size;
+ int64_t slice_step = 1;
+ int64_t interval = max_kernel_size;
- int64_t left_pad_len = dilationVal[0] * (max_kernel_size - 1) + 1 - 2 * paddingVal[0];
+ int64_t left_pad_len = dilationVal[0] * (max_kernel_size - 1) + 1 - 2 * paddingVal[0];
int64_t right_pad_len = 0;
- acl_scalar_ptr alpha = nullptr;
- float alphaValue = 1.0;
- alpha = ggml_cann_create_scalar(&alphaValue, aclDataType::ACL_FLOAT);
+ acl_scalar_ptr alpha = nullptr;
+ float alphaValue = 1.0;
+ alpha = ggml_cann_create_scalar(&alphaValue, aclDataType::ACL_FLOAT);
// set zero to destination
GGML_CANN_CALL_ACLNN_OP(ctx, InplaceZero, acl_dst.get());
- for(int k = 0; k < part_num; k++){
-
+ for (int k = 0; k < part_num; k++) {
// create part kernel tensor and slice from big kernel
slice_start = max_kernel_size * k;
- if(k == part_num - 1){
+ if (k == part_num - 1) {
slice_end = kernel_size;
- interval = kernel_size - max_kernel_size * k;
- }else{
- slice_end = max_kernel_size * (k+1);
+ interval = kernel_size - max_kernel_size * k;
+ } else {
+ slice_end = max_kernel_size * (k + 1);
}
int64_t part_ne[4];
- for(int i = 0; i < 4; i++) {
+ for (int i = 0; i < 4; i++) {
part_ne[i] = *(src0->ne + i);
}
part_ne[0] = interval;
ggml_cann_pool_alloc part_kernel_allocator;
part_kernel_allocator.alloc(ctx.pool(), part_nb[3]);
- void* part_kernel_buf = part_kernel_allocator.get();
+ void * part_kernel_buf = part_kernel_allocator.get();
- acl_tensor_ptr part_kernel = ggml_cann_create_tensor(part_kernel_buf, weight_type,
- ggml_element_size(src0), part_ne, part_nb, 3, ACL_FORMAT_NCL);
+ acl_tensor_ptr part_kernel = ggml_cann_create_tensor(part_kernel_buf, weight_type, ggml_element_size(src0),
+ part_ne, part_nb, 3, ACL_FORMAT_NCL);
- GGML_CANN_CALL_ACLNN_OP(ctx, Slice, acl_weight.get(), slice_dim, slice_start, slice_end, slice_step, part_kernel.get());
+ GGML_CANN_CALL_ACLNN_OP(ctx, Slice, acl_weight.get(), slice_dim, slice_start, slice_end, slice_step,
+ part_kernel.get());
// create the part conv result tensor
int64_t part_dst_ne[4];
- for(int i = 0; i < 4; i++){
+ for (int i = 0; i < 4; i++) {
part_dst_ne[i] = *(dst->ne + i);
}
part_dst_ne[0] = (input_len - 1) * strideVal[0] - 2 * paddingVal[0] + dilationVal[0] * (part_ne[0] - 1) + 1;
}
ggml_cann_pool_alloc part_dst_allocator;
part_dst_allocator.alloc(ctx.pool(), part_dst_nb[3]);
- void* part_dst_buf = part_dst_allocator.get();
+ void * part_dst_buf = part_dst_allocator.get();
acl_tensor_ptr acl_part_dst = ggml_cann_create_tensor(part_dst_buf, dst_type, ggml_element_size(dst),
- part_dst_ne, part_dst_nb, 3, ACL_FORMAT_NCL);
+ part_dst_ne, part_dst_nb, 3, ACL_FORMAT_NCL);
GGML_CANN_CALL_ACLNN_OP(ctx, InplaceZero, acl_part_dst.get());
// compute part conv transpose 1d
GGML_CANN_CALL_ACLNN_OP(ctx, Convolution, acl_input.get(), part_kernel.get(), nullptr, stride.get(),
- padding.get(), dilation.get(), transposed, padding.get(), groups, acl_part_dst.get(), cubeMathType);
+ padding.get(), dilation.get(), transposed, padding.get(), groups, acl_part_dst.get(),
+ cubeMathType);
// compute the position of part result in final result
int64_t global_start = slice_start;
- int64_t global_end = std::min((input_len - 1) * strideVal[0] + slice_end, dst_len);
+ int64_t global_end = std::min((input_len - 1) * strideVal[0] + slice_end, dst_len);
- left_pad_len = global_start;
+ left_pad_len = global_start;
right_pad_len = dst_len - global_end;
- std::vector<int64_t> padDataVal = {left_pad_len,right_pad_len};
- acl_int_array_ptr padData = ggml_cann_create_int_array(padDataVal.data(), 2);
+ std::vector<int64_t> padDataVal = { left_pad_len, right_pad_len };
+ acl_int_array_ptr padData = ggml_cann_create_int_array(padDataVal.data(), 2);
- acl_scalar_ptr pad_value = nullptr;
- float pad_valueVal = 0.0;
- pad_value = ggml_cann_create_scalar(&pad_valueVal, aclDataType::ACL_FLOAT);
+ acl_scalar_ptr pad_value = nullptr;
+ float pad_valueVal = 0.0;
+ pad_value = ggml_cann_create_scalar(&pad_valueVal, aclDataType::ACL_FLOAT);
int64_t conv_result_ne[4];
- for(int i = 0; i < 4; i++){
+ for (int i = 0; i < 4; i++) {
conv_result_ne[i] = *(dst->ne + i);
}
ggml_cann_pool_alloc conv_result_allocator;
conv_result_allocator.alloc(ctx.pool(), conv_result_nb[3]);
- void* conv_result_buf = conv_result_allocator.get();
+ void * conv_result_buf = conv_result_allocator.get();
acl_tensor_ptr conv_result = ggml_cann_create_tensor(conv_result_buf, dst_type, ggml_element_size(dst),
- conv_result_ne, conv_result_nb, 3, ACL_FORMAT_NCL);
+ conv_result_ne, conv_result_nb, 3, ACL_FORMAT_NCL);
GGML_CANN_CALL_ACLNN_OP(ctx, InplaceZero, conv_result.get());
- GGML_CANN_CALL_ACLNN_OP(ctx, ConstantPadNd, acl_part_dst.get(), padData.get(), pad_value.get(), conv_result.get());
+ GGML_CANN_CALL_ACLNN_OP(ctx, ConstantPadNd, acl_part_dst.get(), padData.get(), pad_value.get(),
+ conv_result.get());
GGML_CANN_CALL_ACLNN_OP(ctx, InplaceAdd, acl_dst.get(), conv_result.get(), alpha.get());
}
}
// we want a view: ne_w = { nc, 1, nr } // [K, 1, C]
// so that reversed dims -> [C, 1, K] which matches
// [out_channels, in_channels/groups, kernel_size]
- int64_t w_ne[GGML_MAX_DIMS] = { nc, 1, nr, 1 }; // [K, 1 input ch. per group, C groups]
+ int64_t w_ne[GGML_MAX_DIMS] = { nc, 1, nr, 1 }; // [K, 1 input ch. per group, C groups]
// Layout: src1 data is [K, C] with
// offset(k, c) = k*nb0 + c*nb1
// We want offset_w(k, 0, c) = k*nb0 + c*nb1,
// so we can reuse nb0 and nb1, and set nb2 = nb1.
- size_t w_nb[GGML_MAX_DIMS] = { src1->nb[0], src1->nb[1], src1->nb[1], src1->nb[3] }; // same as src1
+ size_t w_nb[GGML_MAX_DIMS] = { src1->nb[0], src1->nb[1], src1->nb[1], src1->nb[3] }; // same as src1
- acl_tensor_ptr acl_w = ggml_cann_create_tensor(
- src1->data, ggml_cann_type_mapping(src1->type), ggml_type_size(src1->type), w_ne, w_nb, 3, ACL_FORMAT_NCL);
+ acl_tensor_ptr acl_w = ggml_cann_create_tensor(src1->data, ggml_cann_type_mapping(src1->type),
+ ggml_type_size(src1->type), w_ne, w_nb, 3, ACL_FORMAT_NCL);
// 3) Output: dst is { d_inner, n_t, n_s } (CLN)
//
// nb_y[0] = nr * sizeof(float); // step in L
// nb_y[1] = sizeof(float); // step in C
// nb_y[2] = nr * n_t * sizeof(float); // step in N
- int64_t y_ne[GGML_MAX_DIMS] = { n_t, nr, n_s, 1 }; // [L_out, C, N]
- size_t y_nb[GGML_MAX_DIMS] = { dst->ne[0] * sizeof(float), sizeof(float), dst->ne[0] * dst->ne[1] * sizeof(float), dst->nb[3] }; // [nr, 1, nr * n_t]
+ int64_t y_ne[GGML_MAX_DIMS] = { n_t, nr, n_s, 1 }; // [L_out, C, N]
+ size_t y_nb[GGML_MAX_DIMS] = { dst->ne[0] * sizeof(float), sizeof(float), dst->ne[0] * dst->ne[1] * sizeof(float),
+ dst->nb[3] }; // [nr, 1, nr * n_t]
- acl_tensor_ptr acl_y = ggml_cann_create_tensor(
- dst->data, ggml_cann_type_mapping(dst->type), ggml_type_size(dst->type), y_ne, y_nb, 3, ACL_FORMAT_NCL);
+ acl_tensor_ptr acl_y = ggml_cann_create_tensor(dst->data, ggml_cann_type_mapping(dst->type),
+ ggml_type_size(dst->type), y_ne, y_nb, 3, ACL_FORMAT_NCL);
// --- Conv1d parameters: depthwise, stride 1, no padding ("valid") ---
int64_t strideVal[1] = { 1 };
cubeMathType = 1;
#endif
- GGML_CANN_CALL_ACLNN_OP(ctx,
- Convolution,
+ GGML_CANN_CALL_ACLNN_OP(ctx, Convolution,
acl_x.get(), // input: N, C, L_in = ncs
acl_w.get(), // weight: [C, 1, K] with groups=nr
nullptr, // bias
- stride.get(),
- padding.get(),
- dilation.get(),
- transposed,
- padding.get(), // output padding (unused for non-transposed)
- groups,
- acl_y.get(),
- cubeMathType);
+ stride.get(), padding.get(), dilation.get(), transposed,
+ padding.get(), // output padding (unused for non-transposed)
+ groups, acl_y.get(), cubeMathType);
}
-
void ggml_cann_op_add_rms_norm_fused(ggml_backend_cann_context & ctx,
ggml_tensor * add_node,
ggml_tensor * rms_norm_node) {
eps, // double type
acl_yout.get(), acl_rstd.get(), acl_xout.get());
}
+
+void ggml_cann_gated_linear_attn(ggml_backend_cann_context & ctx, ggml_tensor * dst) {
+ ggml_tensor * k = dst->src[0];
+ ggml_tensor * v = dst->src[1];
+ ggml_tensor * q = dst->src[2];
+ ggml_tensor * g = dst->src[3];
+ ggml_tensor * s = dst->src[4];
+
+ int64_t B = dst->src[4]->ne[1];
+ int64_t T = dst->src[0]->ne[2];
+ int64_t H = dst->src[0]->ne[1];
+ int64_t C = dst->ne[0];
+ int64_t D = C / H;
+ int64_t L = T / B;
+
+ int64_t ne_qkg[2] = { 1, D };
+ int64_t ne_s[2] = { D, D };
+ int64_t ne_st[2] = { ne_s[1], ne_s[0] };
+ int64_t ne_vo[2] = { D, 1 };
+ int64_t ne_q[1] = { D };
+ size_t nb_base = ggml_type_size(k->type);
+ size_t nb_qkg[2] = { nb_base, nb_base };
+ size_t nb_s[2] = { nb_base, D * nb_base };
+ size_t nb_st[2] = { nb_s[1], nb_s[0] };
+ size_t nb_vo[2] = { nb_base, D * nb_base };
+ size_t nb_q[1] = { nb_base };
+
+ const float scale = ggml_get_op_params_f32(dst, 0);
+
+ acl_tensor_ptr acl_s = ggml_cann_create_tensor(s, s->ne, s->nb, 2, ACL_FORMAT_ND);
+ acl_tensor_ptr new_state = ggml_cann_create_tensor(dst, s->ne, s->nb, 2, ACL_FORMAT_ND, (B * L * H * D) * nb_base);
+ cann_copy(ctx, acl_s.get(), new_state.get());
+
+ for (int64_t b = 0; b < B; b++) {
+ for (int64_t h = 0; h < H; h++) {
+ size_t s_offset = (b * (H * D * D) + h * (D * D)) * nb_base;
+ // D * D
+ acl_tensor_ptr acl_s_new =
+ ggml_cann_create_tensor(dst, ne_s, nb_s, 2, ACL_FORMAT_ND, (B * L * H * D) * nb_base + s_offset);
+ acl_tensor_ptr acl_s_new_t =
+ ggml_cann_create_tensor(dst, ne_st, nb_st, 2, ACL_FORMAT_ND, (B * L * H * D) * nb_base + s_offset);
+ for (int64_t l = 0; l < L; l++) {
+ size_t qkvgo_offset = (b * (L * H * D) + l * (H * D) + h * (D)) * nb_base;
+ // D * 1
+ acl_tensor_ptr acl_k = ggml_cann_create_tensor(k, ne_qkg, nb_qkg, 2, ACL_FORMAT_ND, qkvgo_offset);
+ acl_tensor_ptr acl_g = ggml_cann_create_tensor(g, ne_qkg, nb_qkg, 2, ACL_FORMAT_ND, qkvgo_offset);
+ // D
+ acl_tensor_ptr acl_q = ggml_cann_create_tensor(q, ne_q, nb_q, 1, ACL_FORMAT_ND, qkvgo_offset);
+ // 1 * D
+ acl_tensor_ptr acl_v = ggml_cann_create_tensor(v, ne_vo, nb_vo, 2, ACL_FORMAT_ND, qkvgo_offset);
+ // D
+ acl_tensor_ptr acl_o = ggml_cann_create_tensor(dst, ne_q, nb_q, 1, ACL_FORMAT_ND, qkvgo_offset);
+ // k ⊗ v
+ size_t buf_size = D * D * nb_base;
+ ggml_cann_pool_alloc buffer_allocator(ctx.pool(), buf_size);
+ acl_tensor_ptr tmp_tensor = ggml_cann_create_tensor(
+ buffer_allocator.get(), ggml_cann_type_mapping(k->type), nb_base, ne_s, nb_s, 2);
+ aclnn_mul(ctx, acl_k.get(), acl_v.get(), tmp_tensor.get());
+ //s_new = g ⊗ s_old + k ⊗ v
+ aclnn_mul(ctx, acl_s_new.get(), acl_g.get(), nullptr);
+ aclnn_add(ctx, acl_s_new.get(), tmp_tensor.get(), nullptr);
+ // compute output
+ GGML_CANN_CALL_ACLNN_OP(ctx, Mv, acl_s_new_t.get(), acl_q.get(), acl_o.get(), 1);
+ aclnn_muls(ctx, acl_o.get(), scale, nullptr, true);
+ }
+ }
+ }
+}
*/
void ggml_cann_flash_attn_ext(ggml_backend_cann_context & ctx, ggml_tensor * dst);
-/*
- * @brief A generic wrapper for ACL resources with custom deleter support.
- */
-using any_acl_resource = std::unique_ptr<void, std::function<void(void *)>>;
-
/**
- * @brief Trait structure used to define how to destroy a given ACL resource type.
+ * @brief Forward Gated Linear Attention on the CANN backend.
*
- * @tparam T ACL resource type.
- */
-template <typename T> struct acl_resource_traits;
-
-/**
- * @brief Specialization for aclTensor, defines how to destroy an aclTensor resource.
- */
-template <> struct acl_resource_traits<aclTensor> {
- static void destroy(void * p) { ACL_CHECK(aclDestroyTensor(static_cast<aclTensor *>(p))); }
-};
-
-/**
- * @brief Specialization for aclIntArray, defines how to destroy an aclIntArray resource.
- */
-template <> struct acl_resource_traits<aclIntArray> {
- static void destroy(void * p) { ACL_CHECK(aclDestroyIntArray(static_cast<aclIntArray *>(p))); }
-};
-
-/**
- * @brief Specialization for aclScalar, defines how to destroy an aclScalar resource.
- */
-template <> struct acl_resource_traits<aclScalar> {
- static void destroy(void * p) { ACL_CHECK(aclDestroyScalar(static_cast<aclScalar *>(p))); }
-};
-
-/**
- * @brief Specialization for aclTensorList, defines how to destroy an aclTensorList resource.
- */
-template <> struct acl_resource_traits<aclTensorList> {
- static void destroy(void * p) { ACL_CHECK(aclDestroyTensorList(static_cast<aclTensorList *>(p))); }
-};
-
-/**
- * @brief Creates a generic ACL resource wrapper with proper destruction logic.
+ * Expects dst->src[0..4] = {k, v, q, g, s} with shape conventions:
+ * k, v, q, g: [D] with outer dims T x H batched as ne[2]=T, ne[1]=H
+ * s: initial state [B, H, D, D], where B is batch and D=C/H
+ * dst holds both outputs (o) and updated state; a scale factor is read from op params.
*
- * @tparam T ACL resource type.
- * @param ptr Raw pointer to ACL resource.
- * @return any_acl_resource Smart pointer that handles destruction.
- */
-template <typename T> any_acl_resource make_acl_resource(T * ptr) {
- return any_acl_resource(static_cast<void *>(ptr), [](void * p) { acl_resource_traits<T>::destroy(p); });
-}
-
-/**
- * @brief Registers multiple ACL resources into a vector for lifetime management.
+ * The kernel updates per time step l: S_new = g ⊗ S_old + k ⊗ v, then computes o = (S_new^T q) * scale.
*
- * @tparam Args Variadic list of ACL resource types.
- * @param vec Target vector to hold ACL resources.
- * @param args Raw pointers to ACL resources.
+ * @param ctx Backend context providing stream/allocator utilities.
+ * @param dst Output tensor; src deps are k, v, q, g, s as above.
*/
-template <typename... Args> void register_acl_resources(std::vector<any_acl_resource> & vec, Args *... args) {
- (vec.emplace_back(make_acl_resource(args)), ...);
-}
+void ggml_cann_gated_linear_attn(ggml_backend_cann_context & ctx, ggml_tensor * dst);
/**
* @brief Launches an asynchronous task using the memory allocator.
* same stream are executed in queue order.
*/
-#define GGML_CANN_CALL_ACLNN_OP(CTX, OP_NAME, ...) \
- do { \
- uint64_t workspaceSize = 0; \
- aclOpExecutor * executor; \
- void * workspaceAddr = nullptr; \
- ACL_CHECK(aclnn##OP_NAME##GetWorkspaceSize(__VA_ARGS__, &workspaceSize, &executor)); \
- /* workspace should alloced in main thread to keep malloc order when using vmm. */ \
- if (workspaceSize > 0) { \
- ggml_cann_pool_alloc workspace_allocator(CTX.pool(), workspaceSize); \
- workspaceAddr = workspace_allocator.get(); \
- } \
- ACL_CHECK(aclnn##OP_NAME(workspaceAddr, workspaceSize, executor, CTX.stream())); \
- } while (0)
+# define GGML_CANN_CALL_ACLNN_OP(CTX, OP_NAME, ...) \
+ do { \
+ uint64_t workspaceSize = 0; \
+ aclOpExecutor * executor; \
+ void * workspaceAddr = nullptr; \
+ ACL_CHECK(aclnn##OP_NAME##GetWorkspaceSize(__VA_ARGS__, &workspaceSize, &executor)); \
+ /* workspace should alloced in main thread to keep malloc order when using vmm. */ \
+ if (workspaceSize > 0) { \
+ ggml_cann_pool_alloc workspace_allocator(CTX.pool(), workspaceSize); \
+ workspaceAddr = workspace_allocator.get(); \
+ } \
+ ACL_CHECK(aclnn##OP_NAME(workspaceAddr, workspaceSize, executor, CTX.stream())); \
+ } while (0)
/**
* @brief Performs sparse expert-based matrix multiplication using the CANN backend.
* @param rms_norm_tensor The RMS_NORM operation node, contains the gamma weights
* and epsilon parameter.
*/
-void ggml_cann_op_add_rms_norm_fused(ggml_backend_cann_context & ctx, ggml_tensor * add_node, ggml_tensor * rms_norm_node);
+void ggml_cann_op_add_rms_norm_fused(ggml_backend_cann_context & ctx,
+ ggml_tensor * add_node,
+ ggml_tensor * rms_norm_node);
/**
* @brief Check whether a tensor is a weight tensor for matrix multiplication.
* @see ggml_cann_op_unary
* @see GGML_CANN_CALL_ACLNN_OP
*/
-#define GGML_CANN_CALL_OP_UNARY(OP_NAME) \
- do { \
- auto lambda = [](ggml_backend_cann_context & ctx, aclTensor * acl_src, aclTensor * acl_dst) { \
- GGML_CANN_CALL_ACLNN_OP(ctx, OP_NAME, acl_src, acl_dst); \
- }; \
- ggml_cann_op_unary(lambda, ctx, dst); \
- } while (0)
+# define GGML_CANN_CALL_OP_UNARY(OP_NAME) \
+ do { \
+ auto lambda = [](ggml_backend_cann_context & ctx, aclTensor * acl_src, aclTensor * acl_dst) { \
+ GGML_CANN_CALL_ACLNN_OP(ctx, OP_NAME, acl_src, acl_dst); \
+ }; \
+ ggml_cann_op_unary(lambda, ctx, dst); \
+ } while (0)
/**
* @brief Helper macro to call a gated unary ACL operator via ggml_cann_op_unary_gated.
* @see ggml_cann_op_unary_gated
* @see GGML_CANN_CALL_ACLNN_OP
*/
-#define GGML_CANN_CALL_OP_UNARY_GATED(OP_NAME) \
- do { \
- auto lambda = [](ggml_backend_cann_context & ctx, aclTensor * acl_src, aclTensor * acl_dst) { \
- GGML_CANN_CALL_ACLNN_OP(ctx, OP_NAME, acl_src, acl_dst); \
- }; \
- ggml_cann_op_unary_gated(lambda, ctx, dst); \
- } while (0)
+# define GGML_CANN_CALL_OP_UNARY_GATED(OP_NAME) \
+ do { \
+ auto lambda = [](ggml_backend_cann_context & ctx, aclTensor * acl_src, aclTensor * acl_dst) { \
+ GGML_CANN_CALL_ACLNN_OP(ctx, OP_NAME, acl_src, acl_dst); \
+ }; \
+ ggml_cann_op_unary_gated(lambda, ctx, dst); \
+ } while (0)
#endif // CANN_ACLNN_OPS
overview / pkg / ggml / sources / ggml / commitdiff