Discrete Fourier transform (DFT) is an important transformation technique in signal processing tasks. Due to its ultrahigh computing complexity as $O(\!N^{\!2}\!)$ , $N$ - point DFT is usually implemented in the format of fast Fourier transformation (FFT) with the complexity of $O(N\log N)$ . Despite this significant reduction in complexity, the hardware cost of the multiplication-intensive $N$ - point FFT is still very prohibitive, particularly for many large-scale applications that require large $N$ . This brief, for the first time , proposes high-accuracy low-complexity scaling-free stochastic DFT/FFT designs. With the use of the stochastic computing technique, the hardware complexity of the DFT/FFT designs is significantly reduced. More importantly, this brief presents the scaling-free stochastic adder and the random number generator sharing scheme, which enable a significant reduction in accuracy loss and hardware cost. Analysis results show that the proposed stochastic DFT/FFT designs achieve much better hardware performance and accuracy performance than state-of-the-art stochastic design.